C# Language Specification

C#
Language Specification

Notice
© 1999-2001 Microsoft Corporation. All rights reserved.
Microsoft, Windows, Visual Basic, Visual C#, and Visual C++ are either registered trademarks or trademarks of Microsoft Corporation in the U.S.A. and/or other countries/regions.
Other product and company names mentioned herein may be the trademarks of their respective owners.

Table of Contents
1. Introduction 1
1.1 Getting started 1
1.2 Types 2
1.2.1 Predefined types 4
1.2.2 Conversions 6
1.2.3 Array types 6
1.2.4 Type system unification 8
1.3 Variables and parameters 9
1.4 Automatic memory management 12
1.5 Expressions 14
1.6 Statements 15
1.7 Classes 18
1.7.1 Constants 20
1.7.2 Fields 20
1.7.3 Methods 21
1.7.4 Properties 22
1.7.5 Events 23
1.7.6 Operators 24
1.7.7 Indexers 25
1.7.8 Instance constructors 26
1.7.9 Destructors 27
1.7.10 Static constructors 28
1.7.11 Inheritance 28
1.8 Structs 29
1.9 Interfaces 30
1.10 Delegates 31
1.11 Enums 32
1.12 Namespaces and assemblies 33
1.13 Versioning 35
1.14 Attributes 37
2. Lexical structure 39
2.1 Programs 39
2.2 Grammars 39
2.2.1 Grammar notation 39
2.2.2 Lexical grammar 40
2.2.3 Syntactic grammar 40
2.3 Lexical analysis 40
2.3.1 Line terminators 41
2.3.2 White space 41
2.3.3 Comments 42
2.4 Tokens 43
2.4.1 Unicode character escape sequences 43
2.4.2 Identifiers 44
2.4.3 Keywords 45
2.4.4 Literals 46
2.4.4.1 Boolean literals 46
2.4.4.2 Integer literals 46
2.4.4.3 Real literals 47
2.4.4.4 Character literals 48
2.4.4.5 String literals 49
2.4.4.6 The null literal 51
2.4.5 Operators and punctuators 51
2.5 Pre-processing directives 51
2.5.1 Conditional compilation symbols 52
2.5.2 Pre-processing expressions 53
2.5.3 Declaration directives 53
2.5.4 Conditional compilation directives 54
2.5.5 Line directives 56
2.5.6 Diagnostic directives 57
2.5.7 Region directives 57
3. Basic concepts 59
3.1 Application Startup 59
3.2 Application termination 60
3.3 Declarations 60
3.4 Members 62
3.4.1 Namespace members 62
3.4.2 Struct members 63
3.4.3 Enumeration members 63
3.4.4 Class members 63
3.4.5 Interface members 63
3.4.6 Array members 64
3.4.7 Delegate members 64
3.5 Member access 64
3.5.1 Declared accessibility 64
3.5.2 Accessibility domains 65
3.5.3 Protected access for instance members 67
3.5.4 Accessibility constraints 68
3.6 Signatures and overloading 68
3.7 Scopes 69
3.7.1 Name hiding 71
3.7.1.1 Hiding through nesting 72
3.7.1.2 Hiding through inheritance 72
3.8 Namespace and type names 74
3.8.1 Fully qualified names 75
3.9 Automatic memory management 75
3.10 Execution order 78
4. Types 79
4.1 Value types 79
4.1.1 Default constructors 80
4.1.2 Struct types 81
4.1.3 Simple types 81
4.1.4 Integral types 82
4.1.5 Floating point types 83
4.1.6 The decimal type 84
4.1.7 The bool type 85
4.1.8 Enumeration types 85
4.2 Reference types 85
4.2.1 Class types 86
4.2.2 The object type 86
4.2.3 The string type 86
4.2.4 Interface types 86
4.2.5 Array types 87
4.2.6 Delegate types 87
4.3 Boxing and unboxing 87
4.3.1 Boxing conversions 87
4.3.2 Unboxing conversions 88
5. Variables 89
5.1 Variable categories 89
5.1.1 Static variables 89
5.1.2 Instance variables 89
5.1.2.1 Instance variables in classes 90
5.1.2.2 Instance variables in structs 90
5.1.3 Array elements 90
5.1.4 Value parameters 90
5.1.5 Reference parameters 90
5.1.6 Output parameters 90
5.1.7 Local variables 91
5.2 Default values 91
5.3 Definite assignment 92
5.3.1 Initially assigned variables 93
5.3.2 Initially unassigned variables 93
5.3.3 Precise rules for determining definite assignment 93
5.3.3.1 General rules for statements 94
5.3.3.2 Block statements, checked, and unchecked statements 94
5.3.3.3 Expression statements 94
5.3.3.4 Declaration statements 94
5.3.3.5 If statements 94
5.3.3.6 Switch statements 95
5.3.3.7 While statements 95
5.3.3.8 Do statements 95
5.3.3.9 For statements 96
5.3.3.10 Break, continue, and goto statements 96
5.3.3.11 Throw statements 96
5.3.3.12 Return statements 96
5.3.3.13 Try-catch statements 96
5.3.3.14 Try-finally statements 97
5.3.3.15 Try-catch-finally statements 97
5.3.3.16 Foreach statements 98
5.3.3.17 Using statements 98
5.3.3.18 Lock statements 98
5.3.3.19 General rules for simple expressions 99
5.3.3.20 General rules for expressions with embedded expressions 99
5.3.3.21 Invocation expressions and object creation expressions 99
5.3.3.22 Simple assignment expressions 100
5.3.3.23 && expressions 100
5.3.3.24 || expressions 101
5.3.3.25 ! expressions 101
5.3.3.26 ?: expressions 102
5.4 Variable references 102
5.5 Atomicity of variable references 102
6. Conversions 103
6.1 Implicit conversions 103
6.1.1 Identity conversion 103
6.1.2 Implicit numeric conversions 103
6.1.3 Implicit enumeration conversions 104
6.1.4 Implicit reference conversions 104
6.1.5 Boxing conversions 104
6.1.6 Implicit constant expression conversions 105
6.1.7 User-defined implicit conversions 105
6.2 Explicit conversions 105
6.2.1 Explicit numeric conversions 105
6.2.2 Explicit enumeration conversions 107
6.2.3 Explicit reference conversions 107
6.2.4 Unboxing conversions 108
6.2.5 User-defined explicit conversions 108
6.3 Standard conversions 108
6.3.1 Standard implicit conversions 108
6.3.2 Standard explicit conversions 108
6.4 User-defined conversions 108
6.4.1 Permitted user-defined conversions 109
6.4.2 Evaluation of user-defined conversions 109
6.4.3 User-defined implicit conversions 110
6.4.4 User-defined explicit conversions 110
7. Expressions 113
7.1 Expression classifications 113
7.1.1 Values of expressions 114
7.2 Operators 114
7.2.1 Operator precedence and associativity 114
7.2.2 Operator overloading 115
7.2.3 Unary operator overload resolution 116
7.2.4 Binary operator overload resolution 117
7.2.5 Candidate user-defined operators 117
7.2.6 Numeric promotions 117
7.2.6.1 Unary numeric promotions 118
7.2.6.2 Binary numeric promotions 118
7.3 Member lookup 119
7.3.1 Base types 119
7.4 Function members 119
7.4.1 Argument lists 122
7.4.2 Overload resolution 124
7.4.2.1 Applicable function member 125
7.4.2.2 Better function member 125
7.4.2.3 Better conversion 126
7.4.3 Function member invocation 126
7.4.3.1 Invocations on boxed instances 127
7.5 Primary expressions 128
7.5.1 Literals 128
7.5.2 Simple names 128
7.5.2.1 Invariant meaning in blocks 129
7.5.3 Parenthesized expressions 130
7.5.4 Member access 130
7.5.4.1 Identical simple names and type names 132
7.5.5 Invocation expressions 132
7.5.5.1 Method invocations 133
7.5.5.2 Delegate invocations 133
7.5.6 Element access 134
7.5.6.1 Array access 134
7.5.6.2 Indexer access 135
7.5.7 This access 135
7.5.8 Base access 136
7.5.9 Postfix increment and decrement operators 136
7.5.10 new operator 137
7.5.10.1 Object creation expressions 137
7.5.10.2 Array creation expressions 138
7.5.10.3 Delegate creation expressions 140
7.5.11 The typeof operator 141
7.5.12 The checked and unchecked operators 142
7.6 Unary operators 144
7.6.1 Unary plus operator 145
7.6.2 Unary minus operator 145
7.6.3 Logical negation operator 146
7.6.4 Bitwise complement operator 146
7.6.5 Prefix increment and decrement operators 146
7.6.6 Cast expressions 147
7.7 Arithmetic operators 148
7.7.1 Multiplication operator 148
7.7.2 Division operator 149
7.7.3 Remainder operator 150
7.7.4 Addition operator 150
7.7.5 Subtraction operator 152
7.8 Shift operators 154
7.9 Relational and type testing operators 155
7.9.1 Integer comparison operators 156
7.9.2 Floating-point comparison operators 156
7.9.3 Decimal comparison operators 157
7.9.4 Boolean equality operators 157
7.9.5 Enumeration comparison operators 157
7.9.6 Reference type equality operators 158
7.9.7 String equality operators 159
7.9.8 Delegate equality operators 159
7.9.9 The is operator 160
7.9.10 The as operator 160
7.10 Logical operators 161
7.10.1 Integer logical operators 161
7.10.2 Enumeration logical operators 161
7.10.3 Boolean logical operators 162
7.11 Conditional logical operators 162
7.11.1 Boolean conditional logical operators 163
7.11.2 User-defined conditional logical operators 163
7.12 Conditional operator 163
7.13 Assignment operators 164
7.13.1 Simple assignment 165
7.13.2 Compound assignment 167
7.13.3 Event assignment 167
7.14 Expression 168
7.15 Constant expressions 168
7.16 Boolean expressions 169
8. Statements 171
8.1 End points and reachability 171
8.2 Blocks 173
8.2.1 Statement lists 173
8.3 The empty statement 173
8.4 Labeled statements 174
8.5 Declaration statements 174
8.5.1 Local variable declarations 175
8.5.2 Local constant declarations 175
8.6 Expression statements 176
8.7 Selection statements 176
8.7.1 The if statement 177
8.7.2 The switch statement 177
8.8 Iteration statements 181
8.8.1 The while statement 181
8.8.2 The do statement 181
8.8.3 The for statement 182
8.8.4 The foreach statement 183
8.9 Jump statements 185
8.9.1 The break statement 186
8.9.2 The continue statement 187
8.9.3 The goto statement 187
8.9.4 The return statement 188
8.9.5 The throw statement 189
8.10 The try statement 190
8.11 The checked and unchecked statements 192
8.12 The lock statement 193
8.13 The using statement 193
9. Namespaces 197
9.1 Compilation units 197
9.2 Namespace declarations 197
9.3 Using directives 198
9.3.1 Using alias directives 199
9.3.2 Using namespace directives 201
9.4 Namespace members 203
9.5 Type declarations 203
10. Classes 205
10.1 Class declarations 205
10.1.1 Class modifiers 205
10.1.1.1 Abstract classes 205
10.1.1.2 Sealed classes 206
10.1.2 Class base specification 206
10.1.2.1 Base classes 207
10.1.2.2 Interface implementations 208
10.1.3 Class body 208
10.2 Class members 208
10.2.1 Inheritance 209
10.2.2 The new modifier 210
10.2.3 Access modifiers 210
10.2.4 Constituent types 210
10.2.5 Static and instance members 210
10.2.6 Nested types 211
10.2.6.1 Fully qualified name 211
10.2.6.2 Declared accessibility 212
10.2.6.3 Hiding 212
10.2.6.4 this access 213
10.2.6.5 Access to private and protected members of the containing type 213
10.2.7 Reserved member names 214
10.2.7.1 Member names reserved for properties 215
10.2.7.2 Member names reserved for events 215
10.2.7.3 Member names reserved for indexers 216
10.2.7.4 Member names reserved for destructors 216
10.3 Constants 216
10.4 Fields 217
10.4.1 Static and instance fields 219
10.4.2 Readonly fields 219
10.4.2.1 Using static readonly fields for constants 219
10.4.2.2 Versioning of constants and static readonly fields 220
10.4.3 Volatile fields 220
10.4.4 Field initialization 221
10.4.5 Variable initializers 222
10.4.5.1 Static field initialization 223
10.4.5.2 Instance field initialization 224
10.5 Methods 224
10.5.1 Method parameters 226
10.5.1.1 Value parameters 227
10.5.1.2 Reference parameters 227
10.5.1.3 Output parameters 228
10.5.1.4 Parameter arrays 229
10.5.2 Static and instance methods 231
10.5.3 Virtual methods 231
10.5.4 Override methods 233
10.5.5 Sealed methods 235
10.5.6 Abstract methods 235
10.5.7 External methods 237
10.5.8 Method body 237
10.5.9 Method overloading 238
10.6 Properties 238
10.6.1 Static and instance properties 239
10.6.2 Accessors 239
10.6.3 Virtual, sealed, override, and abstract accessors 244
10.7 Events 245
10.7.1 Field-like events 247
10.7.2 Event accessors 248
10.7.3 Static and instance events 249
10.7.4 Virtual, sealed, override, and abstract accessors 250
10.8 Indexers 250
10.8.1 Indexer overloading 253
10.9 Operators 253
10.9.1 Unary operators 255
10.9.2 Binary operators 256
10.9.3 Conversion operators 256
10.10 Instance constructors 257
10.10.1 Constructor initializers 258
10.10.2 Instance variable initializers 259
10.10.3 Constructor execution 259
10.10.4 Default constructors 261
10.10.5 Private constructors 262
10.10.6 Optional instance constructor parameters 262
10.11 Static constructors 262
10.12 Destructors 264
11. Structs 267
11.1 Struct declarations 267
11.1.1 Struct modifiers 267
11.1.2 Struct interfaces 268
11.1.3 Struct body 268
11.2 Struct members 268
11.3 Class and struct differences 268
11.3.1 Value semantics 269
11.3.2 Inheritance 269
11.3.3 Assignment 269
11.3.4 Default values 270
11.3.5 Boxing and unboxing 270
11.3.6 Meaning of this 271
11.3.7 Field initializers 271
11.3.8 Constructors 271
11.3.9 Destructors 271
11.3.10 Static Constructors 272
11.4 Struct examples 272
11.4.1 Database integer type 272
11.4.2 Database boolean type 274
12. Arrays 277
12.1 Array types 277
12.1.1 The System.Array type 278
12.2 Array creation 278
12.3 Array element access 278
12.4 Array members 278
12.5 Array covariance 278
12.6 Array initializers 279
13. Interfaces 281
13.1 Interface declarations 281
13.1.1 Interface modifiers 281
13.1.2 Base interfaces 281
13.1.3 Interface body 282
13.2 Interface members 282
13.2.1 Interface methods 283
13.2.2 Interface properties 283
13.2.3 Interface events 284
13.2.4 Interface indexers 284
13.2.5 Interface member access 284
13.3 Fully qualified interface member names 286
13.4 Interface implementations 286
13.4.1 Explicit interface member implementations 287
13.4.2 Interface mapping 289
13.4.3 Interface implementation inheritance 291
13.4.4 Interface re-implementation 293
13.4.5 Abstract classes and interfaces 294
14. Enums 297
14.1 Enum declarations 297
14.2 Enum modifiers 298
14.3 Enum members 298
14.4 Enum values and operations 300
15. Delegates 301
15.1 Delegate declarations 301
15.2 Delegate instantiation 303
15.3 Delegate invocation 303
16. Exceptions 307
16.1 Causes of exceptions 307
16.2 The System.Exception class 307
16.3 How exceptions are handled 307
16.4 Common Exception Classes 308
17. Attributes 311
17.1 Attribute classes 311
17.1.1 Attribute usage 311
17.1.2 Positional and named parameters 312
17.1.3 Attribute parameter types 313
17.2 Attribute specification 313
17.3 Attribute instances 317
17.3.1 Compilation of an attribute 317
17.3.2 Run-time retrieval of an attribute instance 317
17.4 Reserved attributes 318
17.4.1 The AttributeUsage attribute 318
17.4.2 The Conditional attribute 319
17.4.3 The Obsolete attribute 320
17.5 Attributes for Interoperation 321
17.5.1 Interoperation with COM and Win32 components 321
17.5.2 Interoperation with other .NET languages 321
17.5.2.1 The IndexerName attribute 321
A. Unsafe code 323
A.1 Unsafe contexts 323
A.2 Pointer types 325
A.3 Fixed and moveable variables 328
A.4 Pointer conversions 328
A.5 Pointers in expressions 329
A.5.1 Pointer indirection 330
A.5.2 Pointer member access 330
A.5.3 Pointer element access 331
A.5.4 The address-of operator 332
A.5.5 Pointer increment and decrement 332
A.5.6 Pointer arithmetic 333
A.5.7 Pointer comparison 333
A.5.8 The sizeof operator 334
A.6 The fixed statement 334
A.7 Stack allocation 337
A.8 Dynamic memory allocation 338
B. Documentation comments 341
B.1 Introduction 341
B.2 Recommended tags 342
B.2.1 342
B.2.2 343
B.2.3 343
B.2.4 343
B.2.5 344
B.2.6 345
B.2.7 345
B.2.8 346
B.2.9 346
B.2.10 347
B.2.11 347
B.2.12 347
B.2.13 348
B.2.14

348
B.2.15 349
B.3 Processing the documentation file 349
B.3.1 ID string format 349
B.3.2 ID string examples 350
B.4 An example 353
B.4.1 C# source code 353
B.4.2 Resulting XML 356
C. Grammar 359
C.1 Lexical grammar 359
C.1.1 Line terminators 359
C.1.2 White space 359
C.1.3 Comments 359
C.1.4 Tokens 360
C.1.5 Unicode character escape sequences 360
C.1.6 Identifiers 360
C.1.7 Keywords 362
C.1.8 Literals 362
C.1.9 Operators and punctuators 364
C.1.10 Pre-processing directives 364
C.2 Syntactic grammar 366
C.2.1 Basic concepts 366
C.2.2 Types 366
C.2.3 Variables 368
C.2.4 Expressions 368
C.2.5 Statements 371
17.5.3 Namespaces 374
C.2.6 Classes 375
C.2.7 Structs 381
C.2.8 Arrays 381
C.2.9 Interfaces 382
C.2.10 Enums 383
C.2.11 Delegates 383
C.2.12 Attributes 384
C.3 Grammar extensions for unsafe code 385
C.3.1 Unsafe contexts 385
C.3.1.1 Pointer types 386
C.3.1.2 Pointers in expressions 386
C.3.1.3 Pointer indirection 387
C.3.1.4 Pointer member access 387
C.3.1.5 The address-of operator 387
C.3.1.6 The sizeof operator 387
C.3.1.7 The fixed statement 387
C.3.1.8 Stack allocation 387
D. References 389

1. Introduction
C# is a simple, modern, object oriented, and type-safe programming language derived from C and C++. It will immediately be familiar to C and C++ programmers. C# aims to combine the high productivity of Visual Basic and the raw power of C++.
Visual C# .NET is Microsoft’s C# development tool. It includes an interactive development environment, visual designers for building Windows and Web applications, a compiler, and a debugger. Visual C# .NET is part of a suite of products, called Visual Studio .NET, that also includes Visual Basic .NET, Visual C++ .NET, and the JScript scripting language. All of these languages provide access to the Microsoft .NET Framework, which includes a common execution engine and a rich class library. The.NET Framework defines a “Common Language Specification” (CLS), a sort of lingua franca that ensures seamless interoperability between CLS-compliant languages and class libraries. For C# developers, this means that even though C# is a new language, it has complete access to the same rich class libraries that are used by seasoned tools such as Visual Basic .NET and Visual C++ .NET. C# itself does not include a class library.
The rest of this chapter describes the essential features of the language. While later chapters describe rules and exceptions in a detail-oriented and sometimes mathematical manner, this chapter strives for clarity and brevity at the expense of completeness. The intent is to provide the reader with an introduction to the language that will facilitate the writing of early programs and the reading of later chapters.
1.1 Getting started
The canonical “hello, world” program can be written as follows:
using System;
class Hello
{
static void Main() {
Console.WriteLine("hello, world");
}
}
The source code for a C# program is typically stored in one or more text files with a file extension of .cs, as in hello.cs. Using the command-line compiler provided with Visual Studio .NET, such a program can be compiled with the command line directive
csc hello.cs
which produces an application named hello.exe. The output produced by this application when it is run is:
hello, world
Close examination of this program is illuminating:
• The using System; directive references a namespace called System that is provided by the Microsoft .NET Framework class library. This namespace contains the Console class referred to in the Main method. Namespaces provide a hierarchical means of organizing the elements of one or more programs. A “using” directive enables unqualified use of the types that are members of the namespace. The “hello, world” program uses Console.WriteLine as shorthand for System.Console.WriteLine. (For the sake of brevity, most examples in this specification omit the using System; directive.)
• The Main method is a member of the class Hello. It has the static modifier, and so it is a method on the class Hello rather than on instances of this class.
• The entry point for an application—the method that is called to begin execution—is always a static method named Main.
• The “hello, world” output is produced using a class library. The language does not itself provide a class library. Instead, it uses a class library that is also used by Visual Basic .NET and Visual C++ .NET.
For C and C++ developers, it is interesting to note a few things that do not appear in the “hello, world” program.
• The program does not use a global method for Main. Methods and variables are not supported at the global level; such elements are always contained within type declarations (e.g., class and struct declarations).
• The program does not use either “::” or “->” operators. The “::” is not an operator at all, and the “->” operator is used in only a small fraction of programs – those that employ unsafe code (§A). The separator “.” is used in compound names such as Console.WriteLine.
• The program does not contain forward declarations. Forward declarations are never needed, as declaration order is not significant.
• The program does not use #include to import program text. Dependencies among programs are handled symbolically rather than textually. This approach eliminates barriers between applications written using different languages. For example, the Console class need not be written in C#.
1.2 Types
C# supports two kinds of types: value types and reference types. Value types include simple types (e.g., char, int, and float), enum types, and struct types. Reference types include class types, interface types, delegate types, and array types.
Value types differ from reference types in that variables of the value types directly contain their data, whereas variables of the reference types store references to objects. With reference types, it is possible for two variables to reference the same object, and thus possible for operations on one variable to affect the object referenced by the other variable. With value types, the variables each have their own copy of the data, and it is not possible for operations on one to affect the other.
The example
class Class1
{
public int Value = 0;
}
class Test
{
static void Main() {
int val1 = 0;
int val2 = val1;
val2 = 123;
Class1 ref1 = new Class1();
Class1 ref2 = ref1;
ref2.Value = 123;
Console.WriteLine("Values: {0}, {1}", val1, val2);
Console.WriteLine("Refs: {0}, {1}", ref1.Value, ref2.Value);
}
}
shows this difference. The output produced is
Values: 0, 123
Refs: 123, 123
The assignment to the local variable val1 does not impact the local variable val2 because both local variables are of a value type (the type int) and each local variable of a value type has its own storage. In contrast, the assignment ref2.Value = 123; affects the object that both ref1 and ref2 reference.
The lines
Console.WriteLine("Values: {0}, {1}", val1, val2);
Console.WriteLine("Refs: {0}, {1}", ref1.Value, ref2.Value);
deserve further comment, as they demonstrate some of the string formatting behavior of Console.WriteLine, which takes a variable number of arguments. The first argument is a string, which may contain numbered placeholders like {0} and {1}. Each placeholder refers to a trailing argument with {0} referring to the second argument, {1} referring to the third argument, and so on. Before the output is sent to the console, each placeholder is replaced with the formatted value of its corresponding argument.
Developers can define new value types through enum and struct declarations, and can define new reference types via class, interface, and delegate declarations. The example
public enum Color
{
Red, Blue, Green
}
public struct Point
{
public int x, y;
}
public interface IBase
{
void F();
}
public interface IDerived: IBase
{
void G();
}
public class A
{
protected virtual void H() {
Console.WriteLine("A.H");
}
}
public class B: A, IDerived
{
public void F() {
Console.WriteLine("B.F, implementation of IDerived.F");
}
public void G() {
Console.WriteLine("B.G, implementation of IDerived.G");
}
override protected void H() {
Console.WriteLine("B.H, override of A.H");
}
}
public delegate void EmptyDelegate();
shows an example of each kind of type declaration. Later sections describe type declarations in detail.
1.2.1 Predefined types
C# provides a set of predefined types, most of which will be familiar to C and C++ developers.
The predefined reference types are object and string. The type object is the ultimate base type of all other types. The type string is used to represent Unicode string values. Values of type string are immutable.
The predefined value types include signed and unsigned integral types, floating point types, and the types bool, char, and decimal. The signed integral types are sbyte, short, int, and long; the unsigned integral types are byte, ushort, uint, and ulong; and the floating point types are float and double.
The bool type is used to represent boolean values: values that are either true or false. The inclusion of bool makes it easier to write self-documenting code, and also helps eliminate the all-too-common C++ coding error in which a developer mistakenly uses “=” when “==” should have been used. In C#, the example
int i = ...;
F(i);
if (i = 0) // Bug: the test should be (i == 0)
G();
results in a compile-time error because the expression i = 0 is of type int, and if statements require an expression of type bool.
The char type is used to represent Unicode characters. A variable of type char represents a single 16-bit Unicode character.
The decimal type is appropriate for calculations in which rounding errors caused by floating point representations are unacceptable. Common examples include financial calculations such as tax computations and currency conversions. The decimal type provides 28 significant digits.
The table below lists the predefined types, and shows how to write literal values for each of them.

Type Description Example
object The ultimate base type of all other types object o = null;
string String type; a string is a sequence of Unicode characters string s = "hello";
sbyte 8-bit signed integral type sbyte val = 12;
short 16-bit signed integral type short val = 12;
int 32-bit signed integral type int val = 12;
long 64-bit signed integral type long val1 = 12;
long val2 = 34L;
byte 8-bit unsigned integral type byte val1 = 12;
ushort 16-bit unsigned integral type ushort val1 = 12;
uint 32-bit unsigned integral type uint val1 = 12;
uint val2 = 34U;
ulong 64-bit unsigned integral type ulong val1 = 12;
ulong val2 = 34U;
ulong val3 = 56L;
ulong val4 = 78UL;
float Single-precision floating point type float val = 1.23F;
double Double-precision floating point type double val1 = 1.23;
double val2 = 4.56D;
bool Boolean type; a bool value is either true or false bool val1 = true;
bool val2 = false;
char Character type; a char value is a Unicode character char val = 'h';
decimal Precise decimal type with 28 significant digits decimal val = 1.23M;

Each of the predefined types is shorthand for a system-provided type. For example, the keyword int refers to the struct System.Int32. As a matter of style, use of the keyword is favored over use of the complete system type name.
Predefined value types such as int are treated specially in a few ways but are for the most part treated exactly like other structs. Operator overloading enables developers to define new struct types that behave much like the predefined value types. For instance, a Digit struct can support the same mathematical operations as the predefined integral types, and can define conversions between Digit and predefined types.
The predefined types employ operator overloading themselves. For example, the comparison operators == and != have different semantics for different predefined types:
• Two expressions of type int are considered equal if they represent the same integer value.
• Two expressions of type object are considered equal if both refer to the same object, or if both are null.
• Two expressions of type string are considered equal if the string instances have identical lengths and identical characters in each character position, or if both are null.
The example
class Test
{
static void Main() {
string s = "Test";
string t = string.Copy(s);
Console.WriteLine(s == t);
Console.WriteLine((object)s == (object)t);
}
}
produces the output
True
False
because the first comparison compares two expressions of type string, and the second comparison compares two expressions of type object.
1.2.2 Conversions
The predefined types also have predefined conversions. For instance, conversions exist between the predefined types int and long. C# differentiates between two kinds of conversions: implicit conversions and explicit conversions. Implicit conversions are supplied for conversions that can safely be performed without careful scrutiny. For instance, the conversion from int to long is an implicit conversion. This conversion always succeeds, and never results in a loss of information. Implicit conversions can be performed implicitly, as shown in the example
class Test
{
static void Main() {
int intValue = 123;
long longValue = intValue;
Console.WriteLine("{0}, {1}", intValue, longValue);
}
}
which implicitly converts an int to a long.
In contrast, explicit conversions are performed with a cast expression. The example
class Test
{
static void Main() {
long longValue = Int64.MaxValue;
int intValue = (int) longValue;
Console.WriteLine("(int) {0} = {1}", longValue, intValue);
}
}
uses an explicit conversion to convert a long to an int. The output is:
(int) 9223372036854775807 = -1
because an overflow occurs. Cast expressions permit the use of both implicit and explicit conversions.
1.2.3 Array types
Arrays may be single-dimensional or multi-dimensional. Both “rectangular” and “jagged” arrays are supported.
Single-dimensional arrays are the most common type. The example
class Test
{
static void Main() {
int[] arr = new int[5];
for (int i = 0; i < arr.Length; i++)
arr[i] = i * i;
for (int i = 0; i < arr.Length; i++)
Console.WriteLine("arr[{0}] = {1}", i, arr[i]);
}
}
creates a single-dimensional array of int values, initializes the array elements, and then prints each of them out. The output produced is:
arr[0] = 0
arr[1] = 1
arr[2] = 4
arr[3] = 9
arr[4] = 16
The type int[] used in the previous example is an array type. Array types are written using a non-array-type followed by one or more rank specifiers. The example
class Test
{
static void Main() {
int[] a1; // single-dimensional array of int
int[,] a2; // 2-dimensional array of int
int[,,] a3; // 3-dimensional array of int
int[][] j2; // "jagged" array: array of (array of int)
int[][][] j3; // array of (array of (array of int))
}
}
shows a variety of local variable declarations that use array types with int as the element type.
Array types are reference types, and so the declaration of an array variable merely sets aside space for the reference to the array. Array instances are actually created via array initializers and array creation expressions. The example
class Test
{
static void Main() {
int[] a1 = new int[] {1, 2, 3};
int[,] a2 = new int[,] {{1, 2, 3}, {4, 5, 6}};
int[,,] a3 = new int[10, 20, 30];
int[][] j2 = new int[3][];
j2[0] = new int[] {1, 2, 3};
j2[1] = new int[] {1, 2, 3, 4, 5, 6};
j2[2] = new int[] {1, 2, 3, 4, 5, 6, 7, 8, 9};
}
}
shows a variety of array creation expressions. The variables a1, a2 and a3 denote rectangular arrays, and the variable j2 denotes a jagged array. It should be no surprise that these terms are based on the shapes of the arrays. Rectangular arrays always have a rectangular shape. Given the length of each dimension of the array, its rectangular shape is clear. For example, the lengths of a3’s three dimensions are 10, 20, and 30 respectively, and it is easy to see that this array contains 10*20*30 elements.
In contrast, the variable j2 denotes a “jagged” array, or an “array of arrays”. Specifically, j2 denotes an array of an array of int, or a single-dimensional array of type int[]. Each of these int[] variables can be initialized individually, and this allows the array to take on a jagged shape. The example gives each of the int[] arrays a different length. Specifically, the length of j2[0] is 3, the length of j2[1] is 6, and the length of j2[2] is 9.
The element type and shape of an array—including whether it is jagged or rectangular, and the number of dimensions it has—are part of its type. On the other hand, the size of the array—as represented by the length of each of its dimensions—is not part of an array’s type. This split is made clear in the language syntax, as the length of each dimension is specified in the array creation expression rather than in the array type. For instance the declaration
int[,,] a3 = new int[10, 20, 30];
has an array type of int[,,] and an array creation expression of new int[10, 20, 30].
For local variable and field declarations, a shorthand form is permitted so that it is not necessary to re-state the array type. For instance, the example
int[] a1 = new int[] {1, 2, 3};
can be shortened to
int[] a1 = {1, 2, 3};
without any change in program semantics.
The context in which an array initializer such as {1, 2, 3} is used determines the type of the array being initialized. The example
class Test
{
static void Main() {
short[] a = {1, 2, 3};
int[] b = {1, 2, 3};
long[] c = {1, 2, 3};
}
}
shows that the same array initializer syntax can be used for several different array types. Because context is required to determine the type of an array initializer, it is not possible to use an array initializer in an expression context without explicitly stating the type of the array.
1.2.4 Type system unification
C# provides a “unified type system”. All types—including value types—derive from the type object. It is possible to call object methods on any value, even values of “primitive” types such as int. The example
class Test
{
static void Main() {
Console.WriteLine(3.ToString());
}
}
calls the object-defined ToString method on an integer literal, resulting in the output “3”.
The example
class Test
{
static void Main() {
int i = 123;
object o = i; // boxing
int j = (int) o; // unboxing
}
}
is more interesting. An int value can be converted to object and back again to int. This example shows both boxing and unboxing. When a variable of a value type needs to be converted to a reference type, an object box is allocated to hold the value, and the value is copied into the box. Unboxing is just the opposite. When an object box is cast back to its original value type, the value is copied out of the box and into the appropriate storage location.
This type system unification provides value types with the benefits of object-ness without introducing unnecessary overhead. For programs that don’t need int values to act like objects, int values are simply 32-bit values. For programs that need int values to behave like objects, this capability is available on demand. This ability to treat value types as objects bridges the gap between value types and reference types that exists in most languages. For example, a Stack class can provide Push and Pop methods that take and return object values.
public class Stack
{
public object Pop() {...}
public void Push(object o) {...}
}
Because C# has a unified type system, the Stack class can be used with elements of any type, including value types like int.
1.3 Variables and parameters
Variables represent storage locations. Every variable has a type that determines what values can be stored in the variable. Local variables are variables that are declared in methods, properties, or indexers. A local variable is defined by specifying a type name and a declarator that specifies the variable name and an optional initial value, as in:
int a;
int b = 1;
but it is also possible for a local variable declaration to include multiple declarators. The declarations of a and b can be rewritten as:
int a, b = 1;
A variable must be assigned before its value can be obtained. The example
class Test
{
static void Main() {
int a;
int b = 1;
int c = a + b; // error, a not yet assigned
...
}
}
results in a compile-time error because it attempts to use the variable a before it is assigned a value. The rules governing definite assignment are defined in §5.3.
A field (§10.4) is a variable that is associated with a class or struct, or an instance of a class or struct. A field declared with the static modifier defines a static variable, and a field declared without this modifier defines an instance variable. A static field is associated with a type, whereas an instance variable is associated with an instance. The example
using Personnel.Data;
class Employee
{
private static DataSet ds;
public string Name;
public decimal Salary;
...
}
shows an Employee class that has a private static variable and two public instance variables.
Formal parameter declarations also define variables. There are four kinds of parameters: value parameters, reference parameters, output parameters, and parameter arrays.
A value parameter is used for “in” parameter passing, in which the value of an argument is passed into a method, and modifications of the parameter do not impact the original argument. A value parameter refers to its own variable, one that is distinct from the corresponding argument. This variable is initialized by copying the value of the corresponding argument. The example
class Test {
static void F(int p) {
Console.WriteLine("p = {0}", p);
p++;
}
static void Main() {
int a = 1;
Console.WriteLine("pre: a = {0}", a);
F(a);
Console.WriteLine("post: a = {0}", a);
}
}
shows a method F that has a value parameter named p. The output produced is:
pre: a = 1
p = 1
post: a = 1
even though the value parameter p is modified.
A reference parameter is used for “by reference” parameter passing, in which the parameter acts as an alias for a caller-provided argument. A reference parameter does not itself define a variable, but rather refers to the variable of the corresponding argument. Modifications of a reference impact the corresponding argument. A reference parameter is declared with a ref modifier. The example
class Test {
static void Swap(ref int a, ref int b) {
int t = a;
a = b;
b = t;
}
static void Main() {
int x = 1;
int y = 2;

Console.WriteLine("pre: x = {0}, y = {1}", x, y);
Swap(ref x, ref y);
Console.WriteLine("post: x = {0}, y = {1}", x, y);
}
}
shows a Swap method that has two reference parameters. The output of the program is:
pre: x = 1, y = 2
post: x = 2, y = 1
The ref keyword must be used in both the declaration of the formal parameter and in uses of it. The use of ref at the call site calls special attention to the parameter so that a developer reading the code will understand that the value of the argument could change as a result of the call.
An output parameter is similar to a reference parameter, except that the initial value of the caller-provided argument is unimportant. An output parameter is declared with an out modifier. The example
class Test {
static void Divide(int a, int b, out int result, out int remainder) {
result = a / b;
remainder = a % b;
}
static void Main() {
for (int i = 1; i < 10; i++)
for (int j = 1; j < 10; j++) {
int ans, r;
Divide(i, j, out ans, out r);
Console.WriteLine("{0} / {1} = {2}r{3}", i, j, ans, r);
}
}
}
shows a Divide method that includes two output parameters—one for the result of the division and another for the remainder.
For value, reference, and output parameters, there is a one-to-one correspondence between caller-provided arguments and the parameters used to represent them. A parameter array enables a many-to-one relationship: many arguments can be represented by a single parameter array. In other words, parameter arrays enable variable length argument lists.
A parameter array is declared with a params modifier. There can be only one parameter array for a given method, and it must be the right-most parameter. The type of a parameter array is always a single dimensional array type. A caller can either pass a single argument of this array type, or any number of arguments of the element type of this array type. For instance, the example
class Test
{
static void F(params int[] args) {
Console.WriteLine("# of arguments: {0}", args.Length);
for (int i = 0; i < args.Length; i++)
Console.WriteLine("\targs[{0}] = {1}", i, args[i]);
}
static void Main() {
F();
F(1);
F(1, 2);
F(1, 2, 3);
F(new int[] {1, 2, 3, 4});
}
}
shows a method F that takes a variable number of int arguments, and several invocations of this method. The output is:
# of arguments: 0
# of arguments: 1
args[0] = 1
# of arguments: 2
args[0] = 1
args[1] = 2
# of arguments: 3
args[0] = 1
args[1] = 2
args[2] = 3
# of arguments: 4
args[0] = 1
args[1] = 2
args[2] = 3
args[3] = 4
Most of the examples presented in this introduction use the WriteLine method of the Console class. The argument substitution behavior of this method, as exhibited in the example
int a = 1, b = 2;
Console.WriteLine("a = {0}, b = {1}", a, b);
is accomplished using a parameter array. The WriteLine method provides several overloaded methods for the common cases in which a small number of arguments are passed, and one method that uses a parameter array.
namespace System
{
public class Console
{
public static void WriteLine(string s) {...}
public static void WriteLine(string s, object a) {...}
public static void WriteLine(string s, object a, object b) {...}
...
public static void WriteLine(string s, params object[] args) {...}
}
}
1.4 Automatic memory management
Manual memory management requires developers to manage the allocation and de-allocation of blocks of memory. Manual memory management is both time-consuming and difficult. In C#, automatic memory management is provided so that developers are freed from this burdensome task. In the vast majority of cases, automatic memory management increases code quality and enhances developer productivity without negatively impacting either expressiveness or performance.
The example
public class Stack
{
private Node first = null;
public bool Empty {
get {
return (first == null);
}
}
public object Pop() {
if (first == null)
throw new Exception("Can't Pop from an empty Stack.");
else {
object temp = first.Value;
first = first.Next;
return temp;
}
}
public void Push(object o) {
first = new Node(o, first);
}
class Node
{
public Node Next;
public object Value;
public Node(object value): this(value, null) {}
public Node(object value, Node next) {
Next = next;
Value = value;
}
}
}
shows a Stack class implemented as a linked list of Node instances. Node instances are created in the Push method and are garbage collected when no longer needed. A Node instance becomes eligible for garbage collection when it is no longer possible for any code to access it. For instance, when an item is removed from the Stack, the associated Node instance becomes eligible for garbage collection.
The example
class Test
{
static void Main() {
Stack s = new Stack();
for (int i = 0; i < 10; i++)
s.Push(i);
s = null;
}
}
shows code that uses the Stack class. A Stack is created and initialized with 10 elements, and then assigned the value null. Once the variable s is assigned null, the Stack and the associated 10 Node instances become eligible for garbage collection. The garbage collector is permitted to clean up immediately, but is not required to do so.
The garbage collector underlying C# may work by moving objects around in memory, but this motion is invisible to most C# developers. For developers who are generally content with automatic memory management but sometimes need fine-grained control or that extra bit of performance, C# provides the ability to write “unsafe” code. Such code can deal directly with pointer types and object addresses. However, C# requires the programmer to fix objects to temporarily prevent the garbage collector from moving them.
This “unsafe” code feature is in fact a “safe” feature from the perspective of both developers and users. Unsafe code must be clearly marked in the code with the modifier unsafe, so developers can't possibly use unsafe language features accidentally, and the compiler and the execution engine work together to ensure that unsafe code cannot masquerade as safe code. These restrictions limit the use of unsafe code to situations in which the code is trusted.
The example
class Test
{
unsafe static void WriteLocations(byte[] arr) {
fixed (byte *pArray = arr) {
byte *pElem = pArray;
for (int i = 0; i < arr.Length; i++) {
byte value = *pElem;
Console.WriteLine("arr[{0}] at 0x{1:X} is {2}",
i, (uint)pElem, value);
pElem++;
}
}
}
static void Main() {
byte[] arr = new byte[] {1, 2, 3, 4, 5};
WriteLocations(arr);
}
}
shows an unsafe method named WriteLocations that fixes an array instance and uses pointer manipulation to iterate over the elements. The index, value, and location of each array element are written to the console. One possible example of output:
arr[0] at 0x8E0360 is 1
arr[1] at 0x8E0361 is 2
arr[2] at 0x8E0362 is 3
arr[3] at 0x8E0363 is 4
arr[4] at 0x8E0364 is 5
but of course the exact memory locations may be different in different executions of the application.
1.5 Expressions
C# includes unary operators, binary operators, and one ternary operator. The following table summarizes the operators, listing them in order of precedence from highest to lowest:

Section Category Operators
7.5
Primary x.y f(x) a[x] x++ x-- new
typeof checked unchecked
7.6
Unary + - ! ~ ++x --x (T)x
7.7
Multiplicative * / %
7.7
Additive + -
7.8
Shift << >>
7.9
Relational and type testing < > <= >= is as
7.9
Equality == !=
7.10
Logical AND &
7.10
Logical XOR ^
7.10
Logical OR |
7.11
Conditional AND &&
7.11
Conditional OR ||
7.12
Conditional ?:
7.13
Assignment = *= /= %= += -= <<= >>= &= ^= |=

When an expression contains multiple operators, the precedence of the operators controls the order in which the individual operators are evaluated. For example, the expression x + y * z is evaluated as x + (y * z) because the * operator has higher precedence than the + operator.
When an operand occurs between two operators with the same precedence, the associativity of the operators controls the order in which the operations are performed:
• Except for the assignment operators, all binary operators are left-associative, meaning that operations are performed from left to right. For example, x + y + z is evaluated as (x + y) + z.
• The assignment operators and the conditional operator (?:) are right-associative, meaning that operations are performed from right to left. For example, x = y = z is evaluated as x = (y = z).
Precedence and associativity can be controlled using parentheses. For example, x + y * z first multiplies y by z and then adds the result to x, but (x + y) * z first adds x and y and then multiplies the result by z.
1.6 Statements
C# borrows most of its statements directly from C and C++, though there are some noteworthy additions and modifications. The table below lists the kinds of statements that can be used, and provides an example for each.

Statement Example
Statement lists and block statements static void Main() {
F();
G();
{
H();
I();
}
}
Labeled statements and goto statements static void Main(string[] args) {
if (args.Length == 0)
goto done;
Console.WriteLine(args.Length);

done:
Console.WriteLine("Done");
}
Local constant declarations static void Main() {
const float pi = 3.14f;
const int r = 123;
Console.WriteLine(pi * r * r);
}
Local variable declarations static void Main() {
int a;
int b = 2, c = 3;
a = 1;
Console.WriteLine(a + b + c);
}
Expression statements static int F(int a, int b) {
return a + b;
}
static void Main() {
F(1, 2); // Expression statement
}
if statements static void Main(string[] args) {
if (args.Length == 0)
Console.WriteLine("No args");
else
Console.WriteLine("Args");
}
switch statements static void Main(string[] args) {
switch (args.Length) {
case 0:
Console.WriteLine("No args");
break;
case 1:
Console.WriteLine("One arg ");
break;
default:
int n = args.Length;
Console.WriteLine("{0} args", n);
break;
}
}
while statements static void Main(string[] args) {
int i = 0;
while (i < args.Length) {
Console.WriteLine(args[i]);
i++;
}
}
do statements static void Main() {
string s;
do { s = Console.ReadLine(); }
while (s != "Exit");
}
for statements static void Main(string[] args) {
for (int i = 0; i < args.length; i++)
Console.WriteLine(args[i]);
}
foreach statements static void Main(string[] args) {
foreach (string s in args)
Console.WriteLine(s);
}
break statements static void Main(string[] args) {
int i = 0;
while (true) {
if (i == args.Length)
break;
Console.WriteLine(args[i++]);
}
}
continue statements static void Main(string[] args) {
int i = 0;
while (true) {
Console.WriteLine(args[i++]);
if (i < args.Length)
continue;
break;
}
}
return statements static int F(int a, int b) {
return a + b;
}
static void Main() {
Console.WriteLine(F(1, 2));
return;
}
throw statements and try statements static int F(int a, int b) {
if (b == 0)
throw new Exception("Divide by zero");
return a / b;
}
static void Main() {
try {
Console.WriteLine(F(5, 0));
}
catch(Exception e) {
Console.WriteLine("Error");
}
}
checked and unchecked statements static void Main() {
int x = Int32.MaxValue;

Console.WriteLine(x + 1); // Overflow

checked {
Console.WriteLine(x + 1); // Exception
}

unchecked {
Console.WriteLine(x + 1); // Overflow
}
}
lock statements static void Main() {
A a = ...;
lock(a) {
a.P = a.P + 1;
}
}
using statements static void Main() {
using (Resource r = new Resource()) {
r.F();
}
}

1.7 Classes
Class declarations define new reference types. A class can inherit from another class, and can implement interfaces.
Class members can include constants, fields, methods, properties, events, indexers, operators, instance constructors, destructors, static constructors, and nested type declarations. Each member has an associated accessibility, which controls the regions of program text that are able to access the member. There are five possible forms of accessibility. These are summarized in the table below.

Form Intuitive meaning
public Access not limited
protected Access limited to the containing class or types derived from the containing class
internal Access limited to this program
protected internal Access limited to this program or types derived from the containing class
private Access limited to the containing type

The example
class MyClass
{
public MyClass() {
Console.WriteLine("Instance constructor");
}
public MyClass(int value) {
MyField = value;
Console.WriteLine("Instance constructor");
}
~MyClass() {
Console.WriteLine("Destructor");
}
public const int MyConst = 12;
public int MyField = 34;
public void MyMethod(){
Console.WriteLine("MyClass.MyMethod");
}
public int MyProperty {
get {
return MyField;
}
set {
MyField = value;
}
}
public int this[int index] {
get {
return 0;
}
set {
Console.WriteLine("this[{0}] = {1}", index, value);
}
}
public event EventHandler MyEvent;
public static MyClass operator+(MyClass a, MyClass b) {
return new MyClass(a.MyField + b.MyField);
}
internal class MyNestedClass
{}
}
shows a class that contains each kind of member. The example
class Test
{
static void Main() {
// Instance constructor usage
MyClass a = new MyClass();
MyClass b = new MyClass(123);
// Constant usage
Console.WriteLine("MyConst = {0}", MyClass.MyConst);
// Field usage
a.MyField++;
Console.WriteLine("a.MyField = {0}", a.MyField);
// Method usage
a.MyMethod();
// Property usage
a.MyProperty++;
Console.WriteLine("a.MyProperty = {0}", a.MyProperty);
// Indexer usage
a[3] = a[1] = a[2];
Console.WriteLine("a[3] = {0}", a[3]);
// Event usage
a.MyEvent += new EventHandler(MyHandler);
// Overloaded operator usage
MyClass c = a + b;
}
static void MyHandler(object sender, EventArgs e) {
Console.WriteLine("Test.MyHandler");
}
internal class MyNestedClass
{}
}
shows uses of these members.
1.7.1 Constants
A constant is a class member that represents a constant value: a value that can be computed at compile-time. Constants are permitted to depend on other constants within the same program as long as there are no circular dependencies. The rules governing constant expressions are defined in §7.15. The example
class Constants
{
public const int A = 1;
public const int B = A + 1;
}
shows a class named Constants that has two public constants.
Even though constants are considered static members, a constant declaration neither requires nor allows the static modifier. Constants can be accessed through the class, as in
class Test
{
static void Main() {
Console.WriteLine("{0}, {1}", Constants.A, Constants.B);
}
}
which prints out the values of Constants.A and Constants.B.
1.7.2 Fields
A field is a member that represents a variable associated with an object or class. The example
class Color
{
internal ushort redPart;
internal ushort bluePart;
internal ushort greenPart;
public Color(ushort red, ushort blue, ushort green) {
redPart = red;
bluePart = blue;
greenPart = green;
}
...
}
shows a Color class that has internal instance fields named redPart, bluePart, and greenPart. Fields can also be static, as shown in the example
class Color
{
public static Color Red = new Color(0xFF, 0, 0);
public static Color Blue = new Color(0, 0xFF, 0);
public static Color Green = new Color(0, 0, 0xFF);
public static Color White = new Color(0xFF, 0xFF, 0xFF);
...
}
which shows static fields for Red, Blue, Green, and White.
The use of static fields in this manner is not ideal. The fields are initialized at some point before they are used, but after this initialization there is nothing to stop a client from changing them. Such a modification could cause unpredictable errors in other programs that use Color and assume that the values do not change. Readonly fields can be used to prevent such problems. Assignments to a readonly field can only occur as part of the declaration, or in an instance constructor or static constructor in the same class. A static readonly field can be assigned in a static constructor, and a non-static readonly field can be assigned in an instance constructor. Thus, the Color class can be enhanced by adding the readonly modifier to the static fields:
class Color
{
internal ushort redPart;
internal ushort bluePart;
internal ushort greenPart;
public Color(ushort red, ushort blue, ushort green) {
redPart = red;
bluePart = blue;
greenPart = green;
}
public static readonly Color Red = new Color(0xFF, 0, 0);
public static readonly Color Blue = new Color(0, 0xFF, 0);
public static readonly Color Green = new Color(0, 0, 0xFF);
public static readonly Color White = new Color(0xFF, 0xFF, 0xFF);
}
1.7.3 Methods
A method is a member that implements a computation or action that can be performed by an object or class. Methods have a list of formal parameters (which may be empty), a return value (unless the method’s return-type is void), and are either static or non-static. Static methods are accessed through the class. Non-static methods, which are also called instance methods, are accessed through instances of the class. The example
public class Stack
{
public static Stack Clone(Stack s) {...}
public static Stack Flip(Stack s) {...}
public object Pop() {...}
public void Push(object o) {...}
public override string ToString() {...}
...
}
class Test
{
static void Main() {
Stack s = new Stack();
for (int i = 1; i < 10; i++)
s.Push(i);
Stack flipped = Stack.Flip(s);
Stack cloned = Stack.Clone(s);
Console.WriteLine("Original stack: " + s.ToString());
Console.WriteLine("Flipped stack: " + flipped.ToString());
Console.WriteLine("Cloned stack: " + cloned.ToString());
}
}
shows a Stack that has several static methods (Clone and Flip) and several instance methods (Push, Pop, and ToString).
Methods can be overloaded, which means that multiple methods may have the same name so long as they have unique signatures. The signature of a method consists of the name of the method and the number, modifiers, and types of its formal parameters. The signature of a method does not include the return type. The example
class Test
{
static void F() {
Console.WriteLine("F()");
}
static void F(object o) {
Console.WriteLine("F(object)");
}
static void F(int value) {
Console.WriteLine("F(int)");
}
static void F(ref int value) {
Console.WriteLine("F(ref int)");
}
static void F(int a, int b) {
Console.WriteLine("F(int, int)");
}
static void F(int[] values) {
Console.WriteLine("F(int[])");
}
static void Main() {
F();
F(1);
int i = 10;
F(ref i);
F((object)1);
F(1, 2);
F(new int[] {1, 2, 3});
}
}
shows a class with a number of methods named F. The output produced is
F()
F(int)
F(ref int)
F(object)
F(int, int)
F(int[])
1.7.4 Properties
A property is a member that provides access to a characteristic of an object or a class. Examples of properties include the length of a string, the size of a font, the caption of a window, the name of a customer, and so on. Properties are a natural extension of fields. Both are named members with associated types, and the syntax for accessing fields and properties is the same. However, unlike fields, properties do not denote storage locations. Instead, properties have accessors that specify the statements to be executed when their values are read or written.
Properties are defined with property declarations. The first part of a property declaration looks quite similar to a field declaration. The second part includes a get accessor and/or a set accessor. In the example below, the Button class defines a Caption property.
public class Button
{
private string caption;
public string Caption {
get {
return caption;
}
set {
caption = value;
Repaint();
}
}
}
Properties that can be both read and written, such as Caption, include both get and set accessors. The get accessor is called when the property’s value is read; the set accessor is called when the property’s value is written. In a set accessor, the new value for the property is made available via an implicit parameter named value.
The declaration of properties is real value of properties is seen when they are used. For example, the Caption property can be read and written in the same way that fields can be read and written:
Button b = new Button();
b.Caption = "ABC"; // set; causes repaint
string s = b.Caption; // get
b.Caption += "DEF"; // get & set; causes repaint
1.7.5 Events
An event is a member that enables an object or class to provide notifications. A class defines an event by providing an event declaration, which resembles a field declaration, though with an added event keyword, and an optional set of event accessors. The type of this declaration must be a delegate type.
An instance of a delegate type encapsulates one or more callable entities. For instance methods, a callable entity consists of an instance and a method on that instance. For static methods, a callable entity consists of just a method. Given a delegate instance and an appropriate set of arguments, one can invoke all of that delegate instance’s methods with that set of arguments.
In the example
public delegate void EventHandler(object sender, System.EventArgs e);
public class Button
{
public event EventHandler Click;
public void Reset() {
Click = null;
}
}
the Button class defines a Click event of type EventHandler. Inside the Button class, the Click member is exactly like a private field of type EventHandler. However, outside the Button class, the Click member can only be used on the left hand side of the += and -= operators. The += operator adds a handler for the event, and the -= operator removes a handler for the event. The example
public class Form1
{
public Form1() {
// Add Button1_Click as an event handler for Button1’s Click event
Button1.Click += new EventHandler(Button1_Click);
}
Button Button1 = new Button();
void Button1_Click(object sender, EventArgs e) {
Console.WriteLine("Button1 was clicked!");
}
public void Disconnect() {
Button1.Click -= new EventHandler(Button1_Click);
}
}
shows a Form1 class that adds Button1_Click as an event handler for Button1’s Click event. In the Disconnect method, the event handler is removed.
For a simple event declaration such as
public event EventHandler Click;
the compiler automatically provides the implementation underlying the += and -= operators.
An implementer who wants more control can get it by explicitly providing add and remove accessors. For example, the Button class could be rewritten as follows:
public class Button
{
private EventHandler handler;
public event EventHandler Click {
add { handler += value; }
remove { handler -= value; }
}
}
This change has no effect on client code, but allows the Button class more implementation flexibility. For example, the event handler for Click need not be represented by a field.
1.7.6 Operators
An operator is a member that defines the meaning of an expression operator that can be applied to instances of the class. There are three kinds of operators that can be defined: unary operators, binary operators, and conversion operators.
The following example defines a Digit type that represents decimal digits—integral values between 0 and 9.
public struct Digit
{
byte value;
public Digit(byte value) {
if (value < 0 || value > 9) throw new ArgumentException();
this.value = value;
}
public Digit(int value): this((byte) value) {}
public static implicit operator byte(Digit d) {
return d.value;
}
public static explicit operator Digit(byte b) {
return new Digit(b);
}
public static Digit operator+(Digit a, Digit b) {
return new Digit(a.value + b.value);
}
public static Digit operator-(Digit a, Digit b) {
return new Digit(a.value - b.value);
}
public static bool operator==(Digit a, Digit b) {
return a.value == b.value;
}
public static bool operator!=(Digit a, Digit b) {
return a.value != b.value;
}
public override bool Equals(object value) {
if (value == null) return false;
if (GetType() == value.GetType()) return this == (Digit)value;
return false;
}
public override int GetHashCode() {
return value.GetHashCode();
}
public override string ToString() {
return value.ToString();
}
}
class Test
{
static void Main() {
Digit a = (Digit) 5;
Digit b = (Digit) 3;
Digit plus = a + b;
Digit minus = a – b;
bool equals = (a == b);
Console.WriteLine("{0} + {1} = {2}", a, b, plus);
Console.WriteLine("{0} - {1} = {2}", a, b, minus);
Console.WriteLine("{0} == {1} = {2}", a, b, equals);
}
}
The Digit type defines the following operators:
• An implicit conversion operator from Digit to byte.
• An explicit conversion operator from byte to Digit.
• An addition operator that adds two Digit values and returns a Digit value.
• A subtraction operator that subtracts one Digit value from another, and returns a Digit value.
• The equality (==) and inequality (!=) operators, which compare two Digit values.
1.7.7 Indexers
An indexer is a member that enables an object to be indexed in the same way as an array. Whereas properties enable field-like access, indexers enable array-like access.
As an example, consider the Stack class presented earlier. The designer of this class might want to expose array-like access so that it is possible to inspect or alter the items on the stack without performing unnecessary Push and Pop operations. That is, Stack is implemented as a linked list, but it also provides the convenience of array access.
Indexer declarations are similar to property declarations, with the main differences being that indexers are nameless (the “name” used in the declaration is this, since this is being indexed) and that indexers include indexing parameters. The indexing parameters are provided between square brackets. The example
public class Stack
{
private Node GetNode(int index) {
Node temp = first;
while (index > 0) {
temp = temp.Next;
index--;
}
return temp;
}
public object this[int index] {
get {
if (!ValidIndex(index))
throw new Exception("Index out of range.");
else
return GetNode(index).Value;
}
set {
if (!ValidIndex(index))
throw new Exception("Index out of range.");
else
GetNode(index).Value = value;
}
}
...
}
class Test
{
static void Main() {
Stack s = new Stack();
s.Push(1);
s.Push(2);
s.Push(3);
s[0] = 33; // Changes the top item from 3 to 33
s[1] = 22; // Changes the middle item from 2 to 22
s[2] = 11; // Changes the bottom item from 1 to 11
}
}
shows an indexer for the Stack class.
1.7.8 Instance constructors
An instance constructor is a member that implements the actions required to initialize an instance of a class.
The example
class Point
{
public double x, y;
public Point() {
this.x = 0;
this.y = 0;
}
public Point(double x, double y) {
this.x = x;
this.y = y;
}
public static double Distance(Point a, Point b) {
double xdiff = a.x – b.x;
double ydiff = a.y – b.y;
return Math.Sqrt(xdiff * xdiff + ydiff * ydiff);
}
public override string ToString() {
return string.Format("({0}, {1})", x, y);
}
}
class Test
{
static void Main() {
Point a = new Point();
Point b = new Point(3, 4);
double d = Point.Distance(a, b);
Console.WriteLine("Distance from {0} to {1} is {2}", a, b, d);
}
}
shows a Point class that provides two public instance constructors. One instance constructor takes no arguments, and the other takes two double arguments.
If no instance constructor is supplied for a class, then an empty instance constructor with no parameters is automatically provided.
1.7.9 Destructors
A destructor is a member that implements the actions required to destruct an instance of a class. Destructors cannot have parameters, cannot have accessibility modifiers, and cannot be called explicitly. The destructor for an instance is called automatically during garbage collection.
The example
class Point
{
public double x, y;
public Point(double x, double y) {
this.x = x;
this.y = y;
}
~Point() {
Console.WriteLine("Destructed {0}", this);
}
public override string ToString() {
return string.Format("({0}, {1})", x, y);
}
}
shows a Point class with a destructor.
1.7.10 Static constructors
A static constructor is a member that implements the actions required to initialize a class. Static constructors cannot have parameters, cannot have accessibility modifiers, and cannot be called explicitly. The static constructor for a class is called automatically.
The example
using Personnel.Data;
class Employee
{
private static DataSet ds;
static Employee() {
ds = new DataSet(...);
}
public string Name;
public decimal Salary;
...
}
shows an Employee class with a static constructor that initializes a static field.
1.7.11 Inheritance
Classes support single inheritance, and the type object is the ultimate base class for all classes.
The classes shown in earlier examples all implicitly derive from object. The example
class A
{
public void F() { Console.WriteLine("A.F"); }
}
shows a class A that implicitly derives from object. The example
class B: A
{
public void G() { Console.WriteLine("B.G"); }
}
class Test
{
static void Main() {
B b = new B();
b.F(); // Inherited from A
b.G(); // Introduced in B

A a = b; // Treat a B as an A
a.F();
}
}
shows a class B that derives from A. The class B inherits A’s F method, and introduces a G method of its own.
Methods, properties, and indexers can be virtual, which means that their implementation can be overridden in derived classes. The example
class A
{
public virtual void F() { Console.WriteLine("A.F"); }
}
class B: A
{
public override void F() {
base.F();
Console.WriteLine("B.F");
}
}
class Test
{
static void Main() {
B b = new B();
b.F();
A a = b;
a.F();
}
}
shows a class A with a virtual method F, and a class B that overrides F. The overriding method in B contains a call, base.F(), which calls the overridden method in A.
A class can indicate that it is incomplete, and is intended only as a base class for other classes, by including the abstract modifier. Such a class is called an abstract class. An abstract class can specify abstract members—members that a non-abstract derived class must implement. The example
abstract class A
{
public abstract void F();
}
class B: A
{
public override void F() { Console.WriteLine("B.F"); }
}
class Test
{
static void Main() {
B b = new B();
b.F();
A a = b;
a.F();
}
}
introduces an abstract method F in the abstract class A. The non-abstract class B provides an implementation for this method.
1.8 Structs
The list of similarities between classes and structs is long—structs can implement interfaces, and can have the same kinds of members as classes. Structs differ from classes in several important ways, however: structs are value types rather than reference types, and inheritance is not supported for structs. Struct values are stored “on the stack” or “in-line”. Careful programmers can sometimes enhance performance through judicious use of structs.
For example, the use of a struct rather than a class for a Point can make a large difference in the number of memory allocations performed at runtime. The program below creates and initializes an array of 100 points. With Point implemented as a class, 101 separate objects are instantiated—one for the array and one each for the 100 elements.
class Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
class Test
{
static void Main() {
Point[] points = new Point[100];
for (int i = 0; i < 100; i++)
points[i] = new Point(i, i*i);
}
}
If Point is instead implemented as a struct, as in
struct Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
then only one object is instantiated—the one for the array. The Point instances are allocated in-line within the array. This optimization can be misused. Using structs instead of classes can also make an application run slower, or take up more memory, as passing a struct instance as a value parameter causes a copy of the struct to be created. There is no substitute for careful data structure and algorithm design.
1.9 Interfaces
An interface defines a contract. A class or struct that implements an interface must adhere to its contract. Interfaces can contain methods, properties, events and indexers.
The example
interface IExample
{
string this[int index] { get; set; }
event EventHandler E;
void F(int value);
string P { get; set; }
}
public delegate void EventHandler(object sender, EventArgs e);
shows an interface that contains an indexer, an event E, a method F, and a property P.
Interfaces may employ multiple inheritance. In the example
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
interface IListBox: IControl
{
void SetItems(string[] items);
}
interface IComboBox: ITextBox, IListBox {}
the interface IComboBox inherits from both ITextBox and IListBox.
Classes and structs can implement multiple interfaces. In the example
interface IDataBound
{
void Bind(Binder b);
}
public class EditBox: Control, IControl, IDataBound
{
public void Paint() {...}
public void Bind(Binder b) {...}
}
the class EditBox derives from the class Control and implements both IControl and IDataBound.
In previous example, the Paint method from the IControl interface and the Bind method from IDataBound interface are implemented using public members on the EditBox class. C# provides an alternative way of implementing these methods that allows the implementing class to avoid having these members be public. Interface members can be implemented using a qualified name. For example, the EditBox class could instead be implemented by providing IControl.Paint and IDataBound.Bind methods.
public class EditBox: IControl, IDataBound
{
void IControl.Paint() {...}
void IDataBound.Bind(Binder b) {...}
}
Interface members implemented in this way are called explicit interface members because each member explicitly designates the interface member being implemented. Explicit interface members can only be called via the interface. For example, the EditBox’s implementation of the Paint method can be called only by casting to the IControl interface.
class Test
{
static void Main() {
EditBox editbox = new EditBox();
editbox.Paint(); // error: no such method
IControl control = editbox;
control.Paint(); // calls EditBox’s Paint implementation
}
}
1.10 Delegates
Delegates enable scenarios that some other languages have addressed with function pointers. However, unlike function pointers, delegates are object-oriented, type-safe, and secure.
A delegate declaration defines a class that is derived from the class System.Delegate. A delegate instance encapsulates one or more methods, each of which is referred to as a callable entity. For instance methods, a callable entity consists of an instance and a method on that instance. For static methods, a callable entity consists of just a method. Given a delegate instance and an appropriate set of arguments, one can invoke all of that delegate instance’s methods with that set of arguments.
An interesting and useful property of a delegate instance is that it does not know or care about the classes of the methods it encapsulates; all that matters is that those methods be compatible (§15.1) with the delegate’s type. This makes delegates perfectly suited for “anonymous” invocation. This is a powerful capability.
There are three steps in defining and using delegates: declaration, instantiation, and invocation. Delegates are declared using delegate declaration syntax. The example
delegate void SimpleDelegate();
declares a delegate named SimpleDelegate that takes no arguments and returns void.
The example
class Test
{
static void F() {
System.Console.WriteLine("Test.F");
}
static void Main() {
SimpleDelegate d = new SimpleDelegate(F);
d();
}
}
creates a SimpleDelegate instance and then immediately calls it.
There is not much point in instantiating a delegate for a method and then immediately calling it via the delegate, as it would be simpler to call the method directly. Delegates really show their usefulness when their anonymity is used. The example
void MultiCall(SimpleDelegate d, int count) {
for (int i = 0; i < count; i++)
d();
}
}
shows a MultiCall method that repeatedly calls a SimpleDelegate. The MultiCall method doesn’t know or care about the type of target method for the SimpleDelegate, what accessibility the method has, or whether or not the method is static. All that matters is that the target method is compatible (§15.1) with SimpleDelegate.
1.11 Enums
An enum type declaration defines a type name for a related group of symbolic constants. Enums are used for “multiple choice” scenarios, in which a runtime decision is made from a fixed number of choices that are known at compile-time.
The example
enum Color
{
Red,
Blue,
Green
}
class Shape
{
public void Fill(Color color) {
switch(color) {
case Color.Red:
...
break;
case Color.Blue:
...
break;
case Color.Green:
...
break;
default:
break;
}
}
}
shows a Color enum and a method that uses this enum. The signature of the Fill method makes it clear that the shape can be filled with one of the given colors.
The use of enums is superior to the use of integer constants—as is common in languages without enums—because the use of enums makes the code more readable and self-documenting. The self-documenting nature of the code also makes it possible for the development tool to assist with code writing and other “designer” activities. For example, the use of Color rather than int for a parameter type enables smart code editors to suggest Color values.
1.12 Namespaces and assemblies
The programs presented so far have stood on their own except for dependence on a few system-provided classes such as System.Console. It is far more common, however, for real-world applications to consist of several different pieces, each compiled separately. For example, a corporate application might depend on several different components, including some developed internally and some purchased from independent software vendors.
Namespaces and assemblies enable this component-based system. Namespaces provide a logical organizational system. Namespaces are used both as an “internal” organization system for a program, and as an “external” organization system—a way of presenting program elements that are exposed to other programs.
Assemblies are used for physical packaging and deployment. An assembly may contain types, the executable code used to implement these types, and references to other assemblies.
There are two main kinds of assemblies: applications and libraries. Applications have a main entry point and usually have a file extension of .exe; libraries do not have a main entry point, and usually have a file extension of .dll.
To demonstrate the use of namespaces and assemblies, this section revisits the “hello, world” program presented earlier, and splits it into two pieces: a class library that provides messages and a console application that displays them.
The class library will contain a single class named HelloMessage. The example
// HelloLibrary.cs
namespace Microsoft.CSharp.Introduction
{
public class HelloMessage
{
public string Message {
get {
return "hello, world";
}
}
}
}
shows the HelloMessage class in a namespace named Microsoft.CSharp.Introduction. The HelloMessage class provides a read-only property named Message. Namespaces can nest, and the declaration
namespace Microsoft.CSharp.Introduction
{...}
is shorthand for several levels of namespace nesting:
namespace Microsoft
{
namespace CSharp
{
namespace Introduction
{...}
}
}
The next step in the componentization of “hello, world” is to write a console application that uses the HelloMessage class. The fully qualified name for the class—Microsoft.CSharp.Introduction.HelloMessage—could be used, but this name is quite long and unwieldy. An easier way is to use a using namespace directive, which makes it possible to use all of the types in a namespace without qualification. The example
// HelloApp.cs
using Microsoft.CSharp.Introduction;
class HelloApp
{
static void Main() {
HelloMessage m = new HelloMessage();
System.Console.WriteLine(m.Message);
}
}
shows a using namespace directive that refers to the Microsoft.CSharp.Introduction namespace. The occurrences of HelloMessage are shorthand for Microsoft.CSharp.Introduction.HelloMessage.
C# also enables the definition and use of aliases. A using alias directive defines an alias for a type. Such aliases can be useful in situation in which name collisions occur between two class libraries, or when a small number of types from a much larger namespace are being used. The example
using MessageSource = Microsoft.CSharp.Introduction.HelloMessage;
shows a using alias directive that defines MessageSource as an alias for the HelloMessage class.
The code we have written can be compiled into a class library containing the class HelloMessage and an application containing the class HelloApp. The details of this compilation step might differ based on the compiler or tool being used. Using the command-line compiler provided in Visual Studio .NET, the correct invocations are
csc /target:library HelloLibrary.cs
which produces a class library HelloLibrary.dll and
csc /reference:HelloLibrary.dll HelloApp.cs
which produces the application HelloApp.exe.
1.13 Versioning
Versioning is the process of evolving a component over time in a compatible manner. A new version of a component is source compatible with a previous version if code that depends on the previous version can, when recompiled, work with the new version. In contrast, a new version of a component is binary compatible if an application that depended on the old version can, without recompilation, work with the new version.
Most languages do not support binary compatibility at all, and many do little to facilitate source compatibility. In fact, some languages contain flaws that make it impossible, in general, to evolve a class over time without breaking at least some client code.
As an example, consider the situation of a base class author who ships a class named Base. In the first version, Base contains no F method. A component named Derived derives from Base, and introduces an F. This Derived class, along with the class Base on which it depends, is released to customers, who deploy to numerous clients and servers.
// Author A
namespace A
{
public class Base // version 1
{
}
}
// Author B
namespace B
{
class Derived: A.Base
{
public virtual void F() {
System.Console.WriteLine("Derived.F");
}
}
}
So far, so good. But now the versioning trouble begins. The author of Base produces a new version, giving it its own F method.
// Author A
namespace A
{
public class Base // version 2
{
public virtual void F() { // added in version 2
System.Console.WriteLine("Base.F");
}
}
}
This new version of Base should be both source and binary compatible with the initial version. (If it weren’t possible to simply add a method then a base class could never evolve.) Unfortunately, the new F in Base makes the meaning of Derived’s F unclear. Did Derived mean to override Base’s F? This seems unlikely, since when Derived was compiled, Base did not even have an F! Further, if Derived’s F does override Base’s F, then it must adhere to the contract specified by Base—a contract that was unspecified when Derived was written? In some cases, this is impossible. For example, the contract of Base’s F might require that overrides of it always call the base. Derived’s F could not possibly adhere to such a contract.
C# addresses this versioning problem by requiring developers to state their intent clearly. In the original code example, the code was clear, since Base did not even have an F. Clearly, Derived’s F is intended as a new method rather than an override of a base method, since no base method named F exists.
If Base adds an F and ships a new version, then the intent of a binary version of Derived is still clear—Derived’s F is semantically unrelated, and should not be treated as an override.
However, when Derived is recompiled, the meaning is unclear—the author of Derived may intend its F to override Base’s F, or to hide it. Since the intent is unclear, the compiler produces a warning, and by default makes Derived’s F hide Base’s F. This course of action duplicates the semantics for the case in which Derived is not recompiled. The warning that is generated alerts Derived’s author to the presence of the F method in Base.
If Derived’s F is semantically unrelated to Base’s F, then Derived’s author can express this intent—and, in effect, turn off the warning—by using the new keyword in the declaration of F.
// Author A
namespace A
{
public class Base // version 2
{
public virtual void F() { // added in version 2
System.Console.WriteLine("Base.F");
}
}
}
// Author B
namespace B
{
class Derived: A.Base // version 2a: new
{
new public virtual void F() {
System.Console.WriteLine("Derived.F");
}
}
}
On the other hand, Derived’s author might investigate further, and decide that Derived’s F should override Base’s F. This intent can be specified by using the override keyword, as shown below.
// Author A
namespace A
{
public class Base // version 2
{
public virtual void F() { // added in version 2
System.Console.WriteLine("Base.F");
}
}
}
// Author B
namespace B
{
class Derived: A.Base // version 2b: override
{
public override void F() {
base.F();
System.Console.WriteLine("Derived.F");
}
}
}
The author of Derived has one other option, and that is to change the name of F, thus completely avoiding the name collision. Though this change would break source and binary compatibility for Derived, the importance of this compatibility varies depending on the scenario. If Derived is not exposed to other programs, then changing the name of F is likely a good idea, as it would improve the readability of the program—there would no longer be any confusion about the meaning of F.
1.14 Attributes
C# is an imperative language, but like all imperative languages it does have some declarative elements. For example, the accessibility of a method in a class is specified by declaring it public, protected, internal, protected internal, or private. Through its support for attributes, C# generalizes this capability, so that programmers can invent new kinds of declarative information, attach this declarative information to various program entities, and retrieve this declarative information at run-time. Programs specify this additional declarative information by defining and using attributes.
For instance, a framework might define a HelpAttribute attribute that can be placed on program elements such as classes and methods, enabling developers to provide a mapping from program elements to documentation for them. The example
[AttributeUsage(AttributeTargets.All)]
public class HelpAttribute: Attribute
{
public HelpAttribute(string url) {
this.url = url;
}
public string Topic = null;
private string url;
public string Url {
get { return url; }
}
}
defines an attribute class named HelpAttribute, or Help for short, that has one positional parameter (string url) and one named argument (string Topic). Positional parameters are defined by the formal parameters for public instance constructors of the attribute class, and named parameters are defined by public non-static read-write fields and properties of the attribute class.
The example
[Help("http://www.microsoft.com/.../Class1.htm")]
public class Class1
{
[Help("http://www.microsoft.com/.../Class1.htm", Topic = "F")]
public void F() {}
}
shows several uses of the attribute.
Attribute information for a given program element can be retrieved at run-time by using reflection support. The example
class Test
{
static void Main() {
Type type = typeof(Class1);
object[] arr = type.GetCustomAttributes(typeof(HelpAttribute), true);
if (arr.Length == 0)
Console.WriteLine("Class1 has no Help attribute.");
else {
HelpAttribute ha = (HelpAttribute) arr[0];
Console.WriteLine("Url = {0}, Topic = {1}", ha.Url, ha.Topic);
}
}
}
checks to see if Class1 has a Help attribute, and writes out the associated Topic and Url values if the attribute is present.

2. Lexical structure
This chapter defines the lexical structure of C# programs.
2.1 Programs
A C# program consists of one or more source files. A source file is an ordered sequence of Unicode characters. Source files typically have a one-to-one correspondence with files in a file system, but this correspondence is not required. For mamixal portability, it is recommended that files in a file system be encoded with the UTF-8 encoding.
Conceptually speaking, a program is compiled using three steps:
1. Transliteration, which converts a file from a particular character repertoire and encoding scheme into a sequence of Unicode characters.
2. Lexical analysis, which translates a stream of Unicode input characters into a stream of tokens.
3. Syntactic analysis, which translates the stream of tokens into executable code.
2.2 Grammars
This specification presents the syntax of the C# programming language using two grammars. The lexical grammar (§2.2.2) defines how Unicode characters are combined to form line terminators, white space, comments, tokens, and pre-processing directives. The syntactic grammar (§2.2.3) defines how the tokens resulting from the lexical grammar are combined to form C# programs.
2.2.1 Grammar notation
The lexical and syntactic grammars are presented using grammar productions. Each grammar production defines a non-terminal symbol and the possible expansions of that non-terminal symbol into sequences of non-terminal or terminal symbols. In grammar productions, non-terminal symbols are shown in italic type, and terminal symbols are shown in a fixed-width font.
The first line of a grammar production is the name of the non-terminal symbol being defined, followed by a colon. Each successive indented line contains a possible expansion of the non-terminal given as a sequence of non-terminal or terminal symbols. For example, the production:
while-statement:
while ( boolean-expression ) embedded-statement
defines a while-statement to consist of the token while, followed by the token “(”, followed by a boolean-expression, followed by the token “)”, followed by an embedded-statement.
When there is more than one possible expansion of a non-terminal symbol, the alternatives are listed on separate lines. For example, the production:
statement-list:
statement
statement-list statement
defines a statement-list to either consist of a statement or consist of a statement-list followed by a statement. In other words, the definition is recursive and specifies that a statement list consists of one or more statements.
A subscripted suffix “opt” is used to indicate an optional symbol. The production:
block:
{ statement-listopt }
is shorthand for:
block:
{ }
{ statement-list }
and defines a block to consist of an optional statement-list enclosed in “{” and “}” tokens.
Alternatives are normally listed on separate lines, though in cases where there are many alternatives, the phrase “one of” may precede a list of expansions given on a single line. This is simply shorthand for listing each of the alternatives on a separate line. For example, the production:
real-type-suffix: one of
F f D d M m
is shorthand for:
real-type-suffix:
F
f
D
d
M
m
2.2.2 Lexical grammar
The lexical grammar of C# is presented in §2.3, §2.4, and §2.5. The terminal symbols of the lexical grammar are the characters of the Unicode character set, and the lexical grammar specifies how characters are combined to form tokens (§2.4), white space (§2.3.2), comments (§2.3.3), and pre-processing directives (§2.5).
Every source file in a C# program must conform to the input production of the lexical grammar (§2.3).
2.2.3 Syntactic grammar
The syntactic grammar of C# is presented in the chapters and appendices that follow this chapter. The terminal symbols of the syntactic grammar are the tokens defined by the lexical grammar, and the syntactic grammar specifies how tokens are combined to form C# programs.
Every source file in a C# program must conform to the compilation-unit production of the syntactic grammar (§9.1).
2.3 Lexical analysis
The input production defines the lexical structure of a C# source file. Each source file in a C# program must conform to this lexical grammar production.
input:
input-sectionopt
input-section:
input-section-part
input-section input-section-part
input-section-part:
input-elementsopt new-line
pp-directive
input-elements:
input-element
input-elements input-element
input-element:
whitespace
comment
token
Five basic elements make up the lexical structure of a C# source file: Line terminators (§2.3.1), white space (§2.3.2), comments (§2.3.3), tokens (§2.4), and pre-processing directives (§2.5). Of these basic elements, only tokens are significant in the syntactic grammar of a C# program (§2.2.3).
The lexical processing of a C# source file consists of reducing the file into a sequence of tokens which becomes the input to the syntactic analysis. Line terminators, white space, and comments can serve to separate tokens, and pre-processing directives can cause sections of the source file to be skipped, but otherwise these lexical elements have no impact on the syntactic structure of a C# program.
When several lexical grammar productions match a sequence of characters in a source file, the lexical processing always forms the longest possible lexical element. For example, the character sequence // is processed as the beginning of a single-line comment because that lexical element is longer than a single / token.
2.3.1 Line terminators
Line terminators divide the characters of a C# source file into lines.
new-line:
Carriage return character (U+000D)
Line feed character (U+000A)
Carriage return character (U+000D) followed by line feed character (U+000A)
Line separator character (U+2028)
Paragraph separator character (U+2029)
For compatibility with source code editing tools that add end-of-file markers, and to enable a source file to be viewed as a sequence of properly terminated lines, the following transformations are applied, in order, to every source file in a C# program:
• If the last character of the source file is a Control-Z character (U+001A), this character is deleted.
• A carriage-return character (U+000D) is added to the end of the source file if the source file is non-empty and if the last character of the source file is not a carriage return (U+000D), a line feed (U+000A), a line separator (U+2028), or a paragraph separator (U+2029).
2.3.2 White space
White space is defined as any character with Unicode class Zs (which includes the space character) as well as the horizontal tab character, the vertical tab character, and the form feed character.
whitespace:
Any character with Unicode class Zs
Horizontal tab character (U+0009)
Vertical tab character (U+000B)
Form feed character (U+000C)
2.3.3 Comments
Two forms of comments are supported: single-line comments and delimited comments. Single-line comments start with the characters // and extend to the end of the source line. Delimited comments start with the characters /* and end with the characters */. Delimited comments may span multiple lines.
comment:
single-line-comment
delimited-comment
single-line-comment:
// input-charactersopt
input-characters:
input-character
input-characters input-character
input-character:
Any Unicode character except a new-line-character
new-line-character:
Carriage return character (U+000D)
Line feed character (U+000A)
Line separator character (U+2028)
Paragraph separator character (U+2029)
delimited-comment:
/* delimited-comment-charactersopt */
delimited-comment-characters:
delimited-comment-character
delimited-comment-characters delimited-comment-character
delimited-comment-character:
not-asterisk
* not-slash
not-asterisk:
Any Unicode character except *
not-slash:
Any Unicode character except /
Comments do not nest. The character sequences /* and */ have no special meaning within a // comment, and the character sequences // and /* have no special meaning within a delimited comment.
Comments are not processed within character and string literals.
The example
/* Hello, world program
This program writes “hello, world” to the console
*/
class Hello
{
static void Main() {
System.Console.WriteLine("hello, world");
}
}
includes a delimited comment.
The example
// Hello, world program
// This program writes “hello, world” to the console
//
class Hello // any name will do for this class
{
static void Main() { // this method must be named "Main"
System.Console.WriteLine("hello, world");
}
}
shows several single-line comments.
2.4 Tokens
There are several kinds of tokens: identifiers, keywords, literals, operators, and punctuators. White space and comments are not tokens, though they may act as separators for tokens.
token:
identifier
keyword
integer-literal
real-literal
character-literal
string-literal
operator-or-punctuator
2.4.1 Unicode character escape sequences
A Unicode character escape sequence represents a Unicode character. Unicode character escape sequences are processed in identifiers (§2.4.2), character literals (§2.4.4.4), and regular string literals (§2.4.4.5). A Unicode character escape is not processed in any other location (for example, to form an operator, punctuator, or keyword).
unicode-escape-sequence:
\u hex-digit hex-digit hex-digit hex-digit
\U hex-digit hex-digit hex-digit hex-digit hex-digit hex-digit hex-digit hex-digit
A Unicode escape sequence represents the single Unicode character formed by the hexadecimal number following the “\u” or “\U” characters. Since C# uses a 16-bit encoding of Unicode characters in characters and string values, a Unicode character in the range U+10000 to U+10FFFF is not permitted in a character literal and is represented using two Unicode surrogate characters in a string literal. Unicode characters with code points above 0x10FFFF are not supported.
Multiple translations are not performed. For instance, the string literal “\u005Cu005C” is equivalent to “\u005C” rather than “\\”. (The Unicode value \u005C is the character “\”.)
The example
class Class1
{
static void Test(bool \u0066) {
char c = '\u0066';
if (\u0066)
System.Console.WriteLine(c.ToString());
}
}
shows several uses of \u0066, which is the character escape sequence for the letter “f”. The program is equivalent to
class Class1
{
static void Test(bool f) {
char c = 'f';
if (f)
System.Console.WriteLine(c.ToString());
}
}
2.4.2 Identifiers
The rules for identifiers given in this section correspond exactly to those recommended by the Unicode 3.0 standard, Technical Report 15, Annex 7, except that underscore is allowed as an initial character (as is traditional in the C programming language), Unicode escape characters are permitted in identifiers, and the “@” character is allowed as a prefix to enable keywords to be used as identifiers.
identifier:
available-identifier
@ identifier-or-keyword
available-identifier:
An identifier-or-keyword that is not a keyword
identifier-or-keyword:
identifier-start-character identifier-part-charactersopt
identifier-start-character:
letter-character
_ (the underscore character U+005F)
identifier-part-characters:
identifier-part-character
identifier-part-characters identifier-part-character
identifier-part-character:
letter-character
decimal-digit-character
connecting-character
combining-character
formatting-character
letter-character:
A Unicode character of classes Lu, Ll, Lt, Lm, Lo, or Nl
A unicode-escape-sequence representing a character of classes Lu, Ll, Lt, Lm, Lo, or Nl
combining-character:
A Unicode character of classes Mn or Mc
A unicode-escape-sequence representing a character of classes Mn or Mc
decimal-digit-character:
A Unicode character of the class Nd
A unicode-escape-sequence representing a character of the class Nd
connecting-character:
A Unicode character of the class Pc
A unicode-escape-sequence representing a character of the class Pc
formatting-character:
A Unicode character of the class Cf
A unicode-escape-sequence representing a character of the class Cf
Examples of valid identifiers include “identifier1”, “_identifier2”, and “@if”.
An identifier in a conforming program must be in the canonical format defined by Unicode Normalization Form C, as defined by Unicode Standard Annex 15. The behavior when encountering an identifier not in Normalization Form C is implementation-defined; however, a diagnostic is not required.
The prefix “@” enables the use of keywords as identifiers, which is useful when interfacing with other programming languages. The character @ is not actually part of the identifier, so the identifier might be seen in other languages as a normal identifier, without the prefix. An identifier with an @ prefix is called a verbatim identifier. Use of the @ prefix for identifiers that are not keywords is permitted, but strongly discouraged as a matter of style.
The example:
class @class
{
public static void @static(bool @bool) {
if (@bool)
System.Console.WriteLine("true");
else
System.Console.WriteLine("false");
}
}
class Class1
{
static void M() {
cl\u0061ss.st\u0061tic(true);
}
}
defines a class named “class” with a static method named “static” that takes a parameter named “bool”. Note that since Unicode escapes are not permitted in keywords, the token “cl\u0061ss” is an identifier, and is the same identifier as “@class”.
Two identifiers are considered the same if they are identical after the following transformations are applied, in order:
• The prefix “@”, if used, is removed.
• Each unicode-escape-sequence is transformed into its corresponding Unicode character
Identifiers containing two consecutive underscore characters are reserved for use by the implementation. For example, an implementation might provide extended keywords that begin with two underscores.
2.4.3 Keywords
A keyword is an identifier-like sequence of characters that is reserved, and cannot be used as an identifier except when prefaced by the @ character.
keyword: one of
abstract as base bool break
byte case catch char checked
class const continue decimal default
delegate do double else enum
event explicit extern false finally
fixed float for foreach goto
if implicit in int interface
internal is lock long namespace
new null object operator out
override params private protected public
readonly ref return sbyte sealed
short sizeof stackalloc static string
struct switch this throw true
try typeof uint ulong unchecked
unsafe ushort using virtual void
volatile while
In some places in the grammar, specific identifiers have special meaning, but are not keywords. For example, within a property declaration, the “get” and “set” identifiers have special meaning (§10.6.2). An identifier other than get or set is never permitted in these locations, so this use does not conflict with a use of these words as identifiers.
2.4.4 Literals
A literal is a source code representation of a value.
literal:
boolean-literal
integer-literal
real-literal
character-literal
string-literal
null-literal
2.4.4.1 Boolean literals
There are two boolean literal values: true and false.
boolean-literal:
true
false
The type of a boolean-literal is bool.
2.4.4.2 Integer literals
Integer literals are used to write values of types int, uint, long, and ulong. Integer literals have two possible forms: decimal and hexadecimal.
integer-literal:
decimal-integer-literal
hexadecimal-integer-literal
decimal-integer-literal:
decimal-digits integer-type-suffixopt
decimal-digits:
decimal-digit
decimal-digits decimal-digit
decimal-digit: one of
0 1 2 3 4 5 6 7 8 9
integer-type-suffix: one of
U u L l UL Ul uL ul LU Lu lU lu
hexadecimal-integer-literal:
0x hex-digits integer-type-suffixopt
0X hex-digits integer-type-suffixopt
hex-digits:
hex-digit
hex-digits hex-digit
hex-digit: one of
0 1 2 3 4 5 6 7 8 9 A B C D E F a b c d e f
The type of an integer literal is determined as follows:
• If the literal has no suffix, it has the first of these types in which its value can be represented: int, uint, long, ulong.
• If the literal is suffixed by U or u, it has the first of these types in which its value can be represented: uint, ulong.
• If the literal is suffixed by L or l, it has the first of these types in which its value can be represented: long, ulong.
• If the literal is suffixed by UL, Ul, uL, ul, LU, Lu, lU, or lu, it is of type ulong.
If the value represented by an integer literal is outside the range of the ulong type, a compile-time error occurs.
As a matter of style, it is suggested that “L” be used instead of “l” when writing literals of type long, since it is easy to confuse the letter “l” with the digit “1”.
To permit the smallest possible int and long values to be written as decimal integer literals, the following two rules exist:
• When a decimal-integer-literal with the value 2147483648 (231) and no integer-type-suffix appears as the token immediately following a unary minus operator token (§7.6.2), the result is a constant of type int with the value −2147483648 (−231). In all other situations, such a decimal-integer-literal is of type uint.
• When a decimal-integer-literal with the value 9223372036854775808 (263) and no integer-type-suffix appears as the token immediately following a unary minus operator token (§7.6.2), the result is a constant of type long with the value −9223372036854775808 (−263). In all other situations, such a decimal-integer-literal is of type ulong.
2.4.4.3 Real literals
Real literals are used to write values of types float, double, and decimal.
real-literal:
decimal-digits . decimal-digits exponent-partopt real-type-suffixopt
. decimal-digits exponent-partopt real-type-suffixopt
decimal-digits exponent-part real-type-suffixopt
decimal-digits real-type-suffix
exponent-part:
e signopt decimal-digits
E signopt decimal-digits
sign: one of
+ -
real-type-suffix: one of
F f D d M m
If no real-type-suffix is specified, the type of the real literal is double. Otherwise, the real type suffix determines the type of the real literal, as follows:
• A real literal suffixed by F or f is of type float. For example, the literals 1f, 1.5f, 1e10f, and 123.456F are all of type float.
• A real literal suffixed by D or d is of type double. For example, the literals 1d, 1.5d, 1e10d, and 123.456D are all of type double.
• A real literal suffixed by M or m is of type decimal. For example, the literals 1m, 1.5m, 1e10m, and 123.456M are all of type decimal. This literal is converted to a decimal value by taking the exact value, and, if necessary, rounding to the nearest representable value using banker's rounding. Any scale apparent in the literal is preserved unless the value is rounded or the value is zero (in which latter case the sign and scale will be 0). Hence, the literal 2.900m will be parsed to form the decimal with sign 0, coefficient 2900, and scale 3.
If the specified literal cannot be represented in the indicated type, then a compile-time error occurs.
The value of a real literal of type float or double is determined by using the IEEE “round to nearest” mode.
2.4.4.4 Character literals
A character literal represents a single character, and usually consists of a character in quotes, as in 'a'.
character-literal:
' character '
character:
single-character
simple-escape-sequence
hexadecimal-escape-sequence
unicode-escape-sequence
single-character:
Any character except ' (U+0027), \ (U+005C), and new-line-character
simple-escape-sequence: one of
\' \" \\ \0 \a \b \f \n \r \t \v
hexadecimal-escape-sequence:
\x hex-digit hex-digitopt hex-digitopt hex-digitopt
A character that follows a backslash character (\) in a character must be one of the following characters: ', ", \, 0, a, b, f, n, r, t, u, U, x, v. Otherwise, a compile-time error occurs.
A simple escape sequence represents a Unicode character encoding, as described in the table below.

Escape sequence Character name Unicode encoding
\' Single quote 0x0027
\" Double quote 0x0022
\\ Backslash 0x005C
\0 Null 0x0000
\a Alert 0x0007
\b Backspace 0x0008
\f Form feed 0x000C
\n New line 0x000A
\r Carriage return 0x000D
\t Horizontal tab 0x0009
\v Vertical tab 0x000B

A hexadecimal escape sequence represents a single Unicode character, with the value formed by the hexadecimal number following “\x”.
If the value represented by a character literal is greater than U+FFFF, a compile-time error occurs.
A Unicode character escape sequence (§2.4.1) in a character literal must be in the range U+0000 to U+FFFF.
The type of a character-literal is char.
2.4.4.5 String literals
C# supports two forms of string literals: regular string literals and verbatim string literals.
A regular string literal consists of zero or more characters enclosed in double quotes, as in "hello", and may include both simple escape sequences (such as \t for the tab character), hexadecimal escape sequences, and Unicode escape sequences.
A verbatim string literal consists of an @ character followed by a double-quote character, zero or more characters, and a closing double-quote character. A simple example is @"hello". In a verbatim string literal, the characters between the delimiters are interpreted verbatim, the only exception being a quote-escape-sequence. In particular, simple escape sequences, hexadecimal escape sequences, and Unicode character escape sequences are not processed in verbatim string literals. A verbatim string literal may span multiple lines.
string-literal:
regular-string-literal
verbatim-string-literal
regular-string-literal:
" regular-string-literal-charactersopt "
regular-string-literal-characters:
regular-string-literal-character
regular-string-literal-characters regular-string-literal-character
regular-string-literal-character:
single-regular-string-literal-character
simple-escape-sequence
hexadecimal-escape-sequence
unicode-escape-sequence
single-regular-string-literal-character:
Any character except " (U+0022), \ (U+005C), and new-line-character
verbatim-string-literal:
@" verbatim -string-literal-charactersopt "
verbatim-string-literal-characters:
verbatim-string-literal-character
verbatim-string-literal-characters verbatim-string-literal-character
verbatim-string-literal-character:
single-verbatim-string-literal-character
quote-escape-sequence
single-verbatim-string-literal-character:
any character except "
quote-escape-sequence:
""
A character that follows a backslash character (\) in a regular-string-literal-character must be one of the following characters: ', ", \, 0, a, b, f, n, r, t, u, U, x, v. Otherwise, a compile-time error occurs.
The example
string a = "hello, world"; // hello, world
string b = @"hello, world"; // hello, world
string c = "hello \t world"; // hello world
string d = @"hello \t world"; // hello \t world
string e = "Joe said \"Hello\" to me"; // Joe said "Hello" to me
string f = @"Joe said ""Hello"" to me"; // Joe said "Hello" to me
string g = "\\\\server\\share\\file.txt"; // \\server\share\file.txt
string h = @"\\server\share\file.txt"; // \\server\share\file.txt
string i = "one\ntwo\nthree";
string j = @"one
two
three";
shows a variety of string literals. The last string literal, j, is a verbatim string literal that spans multiple lines. The characters between the quotation marks, including white space such as newline characters, are preserved verbatim.
Since a hexadecimal escape sequence can have a variable number of hex digits, the string literal "\x123" contains a single character with hex value 123. To create a string containing the two characters with hex values 0012 and 0003, respectively, one could write "\x00120003" or "\x0012" + "\x0003" instead.
The type of a string-literal is string.
Each string literal does not necessarily result in a new string instance. When two or more string literals that are equivalent according to the string equality operator (§7.9.7) appear in the same assembly, these string literals refer to the same string instance. For instance, the output produced by
class Test
{
static void Main() {
object a = "hello";
object b = "hello";
System.Console.WriteLine(a == b);
}
}
is True because the two literals refer to the same string instance.
2.4.4.6 The null literal
null-literal:
null
The type of a null-literal is the null type.
2.4.5 Operators and punctuators
There are several kinds of operators and punctuators. Operators are used in expressions to describe operations involving one or more operands. For example, the expression a + b uses the + operator to add the two operands a and b. Punctuators are for grouping and separating.
operator-or-punctuator: one of
{ } [ ] ( ) . , : ;
+ - * / % & | ^ ! ~
= < > ? ++ -- && || << >>
== != <= >= += -= *= /= %= &=
|= ^= <<= >>= ->
2.5 Pre-processing directives
The pre-processing directives provide the ability to conditionally skip sections of source files, to report error and warning conditions, and to delineate distinct regions of source code. The term “pre-processing directives” is used only for consistency with the C and C++ programming languages. In C#, there is no separate pre-processing step; pre-processing directives are processed as part of the lexical analysis phase.
pp-directive:
pp-declaration
pp-conditional
pp-line
pp-diagnostic
pp-region
pp-new-line:
whitespaceopt single-line-commentopt new-line
The following pre-processing directives are available:
• #define and #undef, which are used to define and undefine conditional compilation symbols (§2.5.3).
• #if, #elif, #else, and #endif, which are used to conditionally skip sections of source code (§2.5.4).
• #line, which is used to control line numbers emitted for errors and warnings (§2.5.5).
• #error and #warning, which are used to issue errors and warnings (§2.5.6).
• #region and #endregion, which are used to explicitly mark sections of source code (§2.5.7).
A pre-processing directive always occupies a separate line of source code and always begins with a # character and a pre-processing directive name. Whitespace may occur before the # character and between the # character and the directive name.
A source line containing a #define, #undef, #if, #elif, #else, #endif, or #line directive may end with a single-line comment. Delimited comments (the /* */ style of comments) are not permitted on source lines containing pre-processing directives.
Pre-processing directives are not tokens and are not part of the syntactic grammar of C#. However, pre-processing directives can be used to include or exclude sequences of tokens and can in that way affect the meaning of a C# program. For example, the program:
#define A
#undef B
class C
{
#if A
void F() {}
#else
void G() {}
#endif
#if B
void H() {}
#else
void I() {}
#endif
}
produces the exact same sequence of tokens as the program:
class C
{
void F() {}
void I() {}
}
Thus, whereas the two programs are lexically quite different, they are syntactically identical.
2.5.1 Conditional compilation symbols
The conditional compilation functionality provided by the #if, #elif, #else, and #endif directives is controlled through pre-processing expressions (§2.5.1) and conditional compilation symbols.
conditional-symbol:
Any identifier-or-keyword except true or false
A conditional compilation symbol has two possible states: defined or undefined. At the beginning of the lexical processing of a source file, a conditional compilation symbol is undefined unless it has been explicitly defined by an external mechanism (such as a command-line compiler option). When a #define directive is processed, the conditional compilation symbol named in the directive becomes defined in that source file. The symbol remains defined until an #undef directive for that same symbol is processed, or until the end of the source file is reached. An implication of this is that #define and #undef directives in one source file have no effect on other source files in the same program.
When referenced in a pre-processing expression, a defined conditional compilation symbol has the boolean value true, and an undefined conditional compilation symbol has the boolean value false. There is no requirement that conditional compilation symbols be explicitly declared before they are referenced in pre-processing expressions. Instead, undeclared symbols are simply undefined and thus have the value false.
The name space for conditional compilation symbols is distinct and separate from all other named entities in a C# program. Conditional compilation symbols can only be referenced in #define and #undef directives and in pre-processing expressions.
2.5.2 Pre-processing expressions
Pre-processing expressions can occur in #if and #elif directives. The !, ==, !=, && and || operators are permitted in pre-processing expressions, and parentheses may be used for grouping.
pp-expression:
whitespaceopt pp-or-expression whitespaceopt
pp-or-expression:
pp-and-expression
pp-or-expression whitespaceopt || whitespaceopt pp-and-expression
pp-and-expression:
pp-equality-expression
pp-and-expression whitespaceopt && whitespaceopt pp-equality-expression
pp-equality-expression:
pp-unary-expression
pp-equality-expression whitespaceopt == whitespaceopt pp-unary-expression
pp-equality-expression whitespaceopt != whitespaceopt pp-unary-expression
pp-unary-expression:
pp-primary-expression
! whitespaceopt pp-unary-expression
pp-primary-expression:
true
false
conditional-symbol
( whitespaceopt pp-expression whitespaceopt )
When referenced in a pre-processing expression, a defined conditional compilation symbol has the boolean value true, and an undefined conditional compilation symbol has the boolean value false.
Evaluation of a pre-processing expression always yields a boolean value. The rules of evaluation for a pre-processing expression are the same as those for a constant expression (§7.15), except that the only user-defined entities that can be referenced are conditional compilation symbols.
2.5.3 Declaration directives
The declaration directives are used to define or undefine conditional compilation symbols.
pp-declaration:
whitespaceopt # whitespaceopt define whitespace conditional-symbol pp-new-line
whitespaceopt # whitespaceopt undef whitespace conditional-symbol pp-new-line
The processing of a #define directive causes the given conditional compilation symbol to become defined, starting with the source line that follows the directive. Likewise, the processing of an #undef directive causes the given conditional compilation symbol to become undefined, starting with the source line that follows the directive.
Any #define and #undef directives in a source file must occur before the first token (§2.4) in the source file, or otherwise a compile-time error occurs. In intuitive terms, #define and #undef directives must precede any “real code” in the source file.
The example:
#define Enterprise
#if Professional || Enterprise
#define Advanced
#endif
namespace Megacorp.Data
{
#if Advanced
class PivotTable {...}
#endif
}
is valid because the #define directives precede the first token (the namespace keyword) in the source file.
A #define may define a conditional compilation symbol that is already defined, without there being any intervening #undef for that symbol. The example below defines a conditional compilation symbol A and then defines it again.
#define A
#define A
An #undef directive may undefine a conditional compilation symbol that is not defined. The example below defines a conditional compilation symbol and then undefines it twice; the second #undef has no effect but is still valid.
#define A
#undef A
#undef A
2.5.4 Conditional compilation directives
The conditional compilation directives are used to conditionally include or exclude portions of a source file.
pp-conditional:
pp-if-section pp-elif-sectionsopt pp-else-sectionopt pp-endif
pp-if-section:
whitespaceopt # whitespaceopt if whitespace pp-expression pp-new-line conditional-sectionopt
pp-elif-sections:
pp-elif-section
pp-elif-sections pp-elif-section
pp-elif-section:
whitespaceopt # whitespaceopt elif whitespace pp-expression pp-new-line conditional-sectionopt
pp-else-section:
whitespaceopt # whitespaceopt else pp-new-line conditional-sectionopt
pp-endif-line:
whitespaceopt # whitespaceopt endif pp-new-line
conditional-section:
input-section
skipped-section
skipped-section:
skipped-section-part
skipped-section skipped-section-part
skipped-section-part:
skipped-charactersopt new-line
pp-directive
skipped-characters:
whitespaceopt not-number-sign input-charactersopt
not-number-sign:
Any input-character except #
As indicated by the syntax, conditional compilation directives must be written as sets consisting of, in order, an #if directive, zero or more #elif directives, zero or one #else directive, and an #endif directive. Between the directives are conditional sections of source code. Each section is controlled by the immediately preceding directive. A conditional section may itself contain nested conditional compilation directives provided these directives form complete sets.
A pp-conditional selects at most one of the contained conditional-sections for normal lexical processing:
• The pp-expressions of the #if and #elif directives are evaluated in order until one yields true. If an expression yields true, the conditional-section of the corresponding directive is selected.
• If all pp-expressions yield false, and if an #else directive is present, the conditional-section of the #else directive is selected.
• Otherwise, no conditional-section is selected.
The selected conditional-section, if any, is processed as a normal input-section: the source code contained in the section must adhere to the lexical grammar; tokens are generated from the source code in the section; and pre-processing directives in the section have the prescribed effects.
The remaining conditional-sections, if any, are processed as skipped-sections: except for pre-processing directives, the source code in the section need not adhere to the lexical grammar; no tokens are generated from the source code in the section; and pre-processing directives in the section must be lexically correct but are not otherwise processed. Within a conditional-section that is being processed as a skipped-section, any nested conditional-sections (contained in nested #if...#endif and #region...#endregion constructs) are also processed as skipped-sections.
The following example illustrates how conditional compilation directives can nest:
#define Debug // Debugging on
#undef Trace // Tracing off
class PurchaseTransaction
{
void Commit() {
#if Debug
CheckConsistency();
#if Trace
WriteToLog(this.ToString());
#endif
#endif
CommitHelper();
}
}
Except for pre-processing directives, skipped source code is not subject to lexical analysis. For example, the following is valid despite the unterminated comment in the #else section:
#define Debug // Debugging on
class PurchaseTransaction
{
void Commit() {
#if Debug
CheckConsistency();
#else
/* Do something else
#endif
}
}
Note, however, that pre-processing directives are required to be lexically correct even in skipped sections of source code.
Pre-processing directives are not processed when they appear inside multi-line input elements. For example, the program:
class Hello
{
static void Main() {
System.Console.WriteLine(@"hello,
#if Debug
world
#else
Nebraska
#endif
");
}
}
produces the output:
hello,
#if Debug
world
#else
Nebraska
#endif
In peculiar cases, the set of pre-processing directives that are processed might depend on the evaluation of the pp-expression. The example:
#if X
/*
#else
/* */ class Q { }
#endif
always produces the same token stream (class Q { }), regardless of whether X is defined or not. If X is defined, the only processed directives are #if and #endif, due to the multi-line comment. If X is undefined, then three directives (#if, #else, #endif) are part of the directive set.
2.5.5 Line directives
Line directives may be used to alter the line numbers and source file names that are reported by the compiler in output such as warnings and errors.
pp-line:
whitespaceopt # whitespaceopt line whitespace line-indicator pp-new-line
line-indicator:
decimal-digits whitespace file-name
decimal-digits
default
file-name:
" file-name-characters "
file-name-characters:
file-name-character
file-name-characters file-name-character
file-name-character:
Any input-character except "
When no #line directives are present, the compiler reports true line numbers and source file names in its output. The #line directive is most commonly used in meta-programming tools that generate C# source code from some other text input. When processing a #line directive that includes a line-indicator that is not default, the compiler treats the line after the directive as having the given line number (and file name, if specified).
A #line default directive reverses the effect of all preceding #line directives. The compiler reports true line information for subsequent lines, precisely as if no #line directives had been processed.
Note that the file-name of a #line directive differs from an ordinary string literal in that escape characters are not processed; the ‘\’ character simply designates an ordinary backslash character within a file-name.
2.5.6 Diagnostic directives
The diagnostic directives are used to explicitly generate error and warning messages that are reported in the same way as other compile-time errors and warnings.
pp-diagnostic:
whitespaceopt # whitespaceopt error pp-message
whitespaceopt # whitespaceopt warning pp-message
pp-message:
new-line
whitespace input-charactersopt new-line
The example:
#warning Code review needed before check-in
#if Debug && Retail
#error A build can't be both debug and retail
#endif
class Test {...}
always produces a warning (“Code review needed before check-in”), and produces a compile-time error (“A build can’t be both debug and retail”) if the conditional symbols Debug and Retail are both defined.
2.5.7 Region directives
The region directives are used to explicitly mark regions of source code.
pp-region:
pp-start-region conditional-sectionopt pp-end-region
pp-start-region:
whitespaceopt # whitespaceopt region pp-message
pp-end-region:
whitespaceopt # whitespaceopt endregion pp-message
No semantic meaning is attached to a region; regions are intended for use by the programmer or automated tools to mark a section of source code. The message specified in a #region or #endregion directive likewise has no semantic meaning; it merely serves to identify the region. Matching #region and #endregion directives may have different pp-messages.
The lexical processing of a region:
#region
...
#endregion
corresponds exactly to the lexical processing of a conditional compilation directive of the form:
#if true
...
#endif

3. Basic concepts
This chapter defines basic concepts that are required for understanding subsequent chapters.
3.1 Application Startup
An assembly that has an entry point is called an application. When an application is run, a new application domain is created. Several different instantiations of an application may exist on the same machine at the same time, and each has its own application domain.
An application domain enables application isolation by acting as a container for application state. An application domain acts as a container and boundary for the types defined in the application and the class libraries it uses. Types loaded into one application domain are distinct from the same type loaded into another application domain, and instances of objects are not directly shared between application domains. For instance, each application domain has its own copy of static variables for these types, and a static constructor for a type is run at most once per application domain. Implementations are free to provide implementation-specific policy or mechanisms for the creation and destruction of application domains.
Application startup occurs when the execution environment calls a designated method, which is referred to as the application's entry point. This entry point method is always named Main, and can have one of the following signatures:
static void Main() {...}
static void Main(string[] args) {...}
static int Main() {...}
static int Main(string[] args) {...}
As shown, the entry point may optionally return an int value. This return value is used in application termination (§3.2).
The entry point may optionally have one formal parameter, and this formal parameter may have any name. If such a parameter is declared, it must obey the following constraints:
• The value of this parameter must not be null.
• Let args be the name of the parameter. If the length of the array designated by args is greater than zero, the array members args[0] through args[args.Length-1], inclusive, must refer to strings, called application parameters, which are given implementation-defined values by the host environment prior to application startup. The intent is to supply to the application information determined prior to application startup from elsewhere in the hosted environment. If the host environment is not capable of supplying strings with letters in both uppercase and lowercase, the implementation shall ensure that the strings are received in lowercase. On systems supporting a command line, application parameters correspond to what are generally known as command-line arguments.
Since C# supports method overloading, a class or struct may contain multiple definitions of some method, provided each has a different signature. However, within a single program, no class or struct shall contain more than one method called Main whose definition qualifies it to be used as an application entry point. Other overloaded versions of Main are permitted, provided they have more than one parameter, or their only parameter is other than type string[].
An application can be made up of multiple classes or structs. It is possible for more than one of these classes or structs to contain a method called Main whose definition qualifies it to be used as an application entry point. In such cases, one of these Main methods must be chosen as the entry point so that application startup can occur. This choice of an entry point is beyond the scope of this specification—no mechanism for specifying or determining an entry point is provided.
In C#, every method must be defined as a member of a class or struct. Ordinarily, the declared accessibility (§3.5.1) of a method is determined by the access modifiers (§10.2.3) specified in its declaration, and similarly the declared accessibility of a type is determined by the access modifiers specified in its declaration. In order for a given method of a given type to be callable, both the type and the member must be accessible. However, the application entry point is a special case. Specifically, the execution environment can access the application's entry point regardless of its declared accessibility and regardless of the declared accessibility of its enclosing type declarations.
In all other respects, entry point methods behave like those that are not entry points.
3.2 Application termination
Application termination returns control to the execution environment.
If the return type of the application’s entry point method is int, the value returned serves as the application's termination status code. The purpose of this code is to allow communication of success or failure to the execution environment.
If the return type of the entry point method is void, reaching the right brace (}) which terminates that method, or executing a return statement that has no expression, results in a termination status code of 0.
Prior to an application’s termination, destructors for all of its objects that have not yet been garbage collected are called, unless such cleanup has been suppressed. (The means of suppression are outside the scope of this specification.)
3.3 Declarations
Declarations in a C# program define the constituent elements of the program. C# programs are organized using namespaces (§9), which can contain type declarations and nested namespace declarations. Type declarations (§9.5) are used to define classes (§10), structs (§11), interfaces (§13), enums (§14), and delegates (§15). The kinds of members permitted in a type declaration depend on the form of the type declaration. For instance, class declarations can contain declarations for constants (§10.3), fields (§10.4), methods (§10.5), properties (§10.6), events (§10.7), indexers (§10.8), operators (§10.9), instance constructors (§10.10), static constructors (§10.11), destructors (§10.12), and nested types.
A declaration defines a name in the declaration space to which the declaration belongs. Except for overloaded members (§3.6), it is a compile-time error to have two or more declarations that introduce members with the same name in a declaration space. It is never possible for a declaration space to contain different kinds of members with the same name. For example, a declaration space can never contain a field and a method by the same name.
There are several different types of declaration spaces, as described in the following.
• Within all source files of a program, namespace-member-declarations with no enclosing namespace-declaration are members of a single combined declaration space called the global declaration space.
• Within all source files of a program, namespace-member-declarations within namespace-declarations that have the same fully qualified namespace name are members of a single combined declaration space.
• Each class, struct, or interface declaration creates a new declaration space. Names are introduced into this declaration space through class-member-declarations, struct-member-declarations, or interface-member-declarations. Except for overloaded instance constructor declarations and static constructor declarations, a class or struct member declaration cannot introduce a member by the same name as the class or struct. A class, struct, or interface permits the declaration of overloaded methods and indexers. Furthermore, a class or struct permits the declaration of overloaded instance constructors and overloaded operators. For example, a class, struct, or interface may contain multiple method declarations with the same name, provided these method declarations differ in their signature (§3.6). Note that base classes do not contribute to the declaration space of a class, and base interfaces do not contribute to the declaration space of an interface. Thus, a derived class or interface is allowed to declare a member with the same name as an inherited member. Such a member is said to hide the inherited member.
• Each enumeration declaration creates a new declaration space. Names are introduced into this declaration space through enum-member-declarations.
• Each block or switch-block creates a different declaration space for local variables. Names are introduced into this declaration space through local-variable-declarations. If a block is the body of an instance constructor, method declaration, operator declaration, or a get or set accessor for an indexer declaration, the parameters declared in such a declaration are members of the block’s local variable declaration space. The local variable declaration space of a block includes any nested blocks. Thus, within a nested block it is not possible to declare a local variable with the same name as a local variable in an enclosing block.
• Each block or switch-block creates a separate declaration space for labels. Names are introduced into this declaration space through labeled-statements, and the names are referenced through goto-statements. The label declaration space of a block includes any nested blocks. Thus, within a nested block it is not possible to declare a label with the same name as a label in an enclosing block.
The textual order in which names are declared is generally of no significance. In particular, textual order is not significant for the declaration and use of namespaces, constants, methods, properties, events, indexers, operators, instance constructors, destructors, types, static constructors, and types. Declaration order is significant in the following ways:
• Declaration order for field declarations and local variable declarations determines the order in which their initializers (if any) are executed.
• Local variables must be defined before they are used (§3.7).
• Declaration order for enum member declarations (§14.3) is significant when constant-expression values are omitted.
The declaration space of a namespace is “open ended”, and two namespace declarations with the same fully qualified name contribute to the same declaration space. For example
namespace Megacorp.Data
{
class Customer
{
...
}
}
namespace Megacorp.Data
{
class Order
{
...
}
}
The two namespace declarations above contribute to the same declaration space, in this case declaring two classes with the fully qualified names Megacorp.Data.Customer and Megacorp.Data.Order. Because the two declarations contribute to the same declaration space, it would have caused a compile-time error if each contained a declaration of a class with the same name.
The declaration space of a block includes any nested blocks. Thus, in the following example, the F and G methods result in a compile-time error because the name i is declared in the outer block and cannot be redeclared in the inner block. However, the H and I methods are valid since the two i’s are declared in separate non-nested blocks.
class A
{
void F() {
int i = 0;
if (true) {
int i = 1;
}
}
void G() {
if (true) {
int i = 0;
}
int i = 1;
}
void H() {
if (true) {
int i = 0;
}
if (true) {
int i = 1;
}
}
void I() {
for (int i = 0; i < 10; i++)
H();
for (int i = 0; i < 10; i++)
H();
}
}
3.4 Members
Namespaces and types have members. The members of an entity are generally available through the use of a qualified name that starts with a reference to the entity, followed by a “.” token, followed by the name of the member.
Members of a type are either declared in the type or inherited from the base class of the type. When a type inherits from a base class, all members of the base class, except instance constructors, destructors and static constructors, become members of the derived type. The declared accessibility of a base class member does not control whether the member is inherited—inheritance extends to any member that isn’t an instance constructor, static constructor, or destructor. However, an inherited member may not be accessible in a derived type, either because of its declared accessibility (§3.5.1) or because it is hidden by a declaration in the type itself (§3.7.1.2).
3.4.1 Namespace members
Namespaces and types that have no enclosing namespace are members of the global namespace. This corresponds directly to the names declared in the global declaration space.
Namespaces and types declared within a namespace are members of that namespace. This corresponds directly to the names declared in the declaration space of the namespace.
Namespaces have no access restrictions. It is not possible to declare private, protected, or internal namespaces, and namespace names are always publicly accessible.
3.4.2 Struct members
The members of a struct are the members declared in the struct and the members inherited from class object.
The members of a simple type correspond directly to the members of the struct type aliased by the simple type:
• The members of sbyte are the members of the System.SByte struct.
• The members of byte are the members of the System.Byte struct.
• The members of short are the members of the System.Int16 struct.
• The members of ushort are the members of the System.UInt16 struct.
• The members of int are the members of the System.Int32 struct.
• The members of uint are the members of the System.UInt32 struct.
• The members of long are the members of the System.Int64 struct.
• The members of ulong are the members of the System.UInt64 struct.
• The members of char are the members of the System.Char struct.
• The members of float are the members of the System.Single struct.
• The members of double are the members of the System.Double struct.
• The members of decimal are the members of the System.Decimal struct.
• The members of bool are the members of the System.Boolean struct.
3.4.3 Enumeration members
The members of an enumeration are the constants declared in the enumeration and the members inherited from class object.
3.4.4 Class members
The members of a class are the members declared in the class and the members inherited from the base class (except for class object which has no base class). The members inherited from the base class include the constants, fields, methods, properties, events, indexers, operators, and types of the base class, but not the instance constructors, destructors and static constructors of the base class. Base class members are inherited without regard to their accessibility.
A class declaration may contain declarations of constants, fields, methods, properties, events, indexers, operators, instance constructors, destructors, static constructors and types.
The members of object and string correspond directly to the members of the class types they alias:
• The members of object are the members of the System.Object class.
• The members of string are the members of the System.String class.
3.4.5 Interface members
The members of an interface are the members declared in the interface and in all base interfaces of the interface, and the members inherited from class object.
3.4.6 Array members
The members of an array are the members inherited from class System.Array.
3.4.7 Delegate members
The members of a delegate are the members inherited from class System.Delegate.
3.5 Member access
Declarations of members allow control over member access. The accessibility of a member is established by the declared accessibility (§3.5.1) of the member combined with the accessibility of the immediately containing type, if any.
When access to a particular member is allowed, the member is said to be accessible. Conversely, when access to a particular member is disallowed, the member is said to be inaccessible. Access to a member is permitted when the textual location in which the access takes place is included in the accessibility domain (§3.5.2) of the member.
3.5.1 Declared accessibility
The declared accessibility of a member can be one of the following:
• Public, which is selected by including a public modifier in the member declaration. The intuitive meaning of public is “access not limited”.
• Protected internal (meaning protected or internal), which is selected by including both a protected and an internal modifier in the member declaration. The intuitive meaning of protected internal is “access limited to this program or types derived from the containing class”.
• Protected, which is selected by including a protected modifier in the member declaration. The intuitive meaning of protected is “access limited to the containing class or types derived from the containing class”.
• Internal, which is selected by including an internal modifier in the member declaration. The intuitive meaning of internal is “access limited to this program”.
• Private, which is selected by including a private modifier in the member declaration. The intuitive meaning of private is “access limited to the containing type”.
Depending on the context in which a member declaration takes place, only certain types of declared accessibility are permitted. Furthermore, when a member declaration does not include any access modifiers, the context in which the declaration takes place determines the default declared accessibility.
• Namespaces implicitly have public declared accessibility. No access modifiers are allowed on namespace declarations.
• Types declared in compilation units or namespaces can have public or internal declared accessibility and default to internal declared accessibility.
• Class members can have any of the five kinds of declared accessibility and default to private declared accessibility. (Note that a type declared as a member of a class can have any of the five kinds of declared accessibility, whereas a type declared as a member of a namespace can have only public or internal declared accessibility.)
• Struct members can have public, internal, or private declared accessibility and default to private declared accessibility because structs are implicitly sealed. Struct members cannot have protected or protected internal declared accessibility. (Note that a type declared as a member of a struct can have public, internal, or private declared accessibility, whereas a type declared as a member of a namespace can have only public or internal declared accessibility.)
• Interface members implicitly have public declared accessibility. No access modifiers are allowed on interface member declarations.
• Enumeration members implicitly have public declared accessibility. No access modifiers are allowed on enumeration member declarations.
3.5.2 Accessibility domains
The accessibility domain of a member consists of the (possibly disjoint) sections of program text in which access to the member is permitted. For purposes of defining the accessibility domain of a member, a member is said to be top-level if it is not declared within a type, and a member is said to be nested if it is declared within another type. Furthermore, the program text of a program is defined as all program text contained in all source files of the program, and the program text of a type is defined as all program text contained between the opening and closing “{” and “}” tokens in the class-body, struct-body, interface-body, or enum-body of the type (including, possibly, types that are nested within the type).
The accessibility domain of a predefined type (such as object, int, or double) is unlimited.
The accessibility domain of a top-level type T declared in a program P is defined as follows:
• If the declared accessibility of T is public, the accessibility domain of T is the program text of P and any program that references P.
• If the declared accessibility of T is internal, the accessibility domain of T is the program text of P.
From these definitions it follows that the accessibility domain of a top-level type is always at least the program text of the program in which the type is declared.
The accessibility domain of a nested member M declared in a type T within a program P is defined as follows (noting that M may itself possibly be a type):
• If the declared accessibility of M is public, the accessibility domain of M is the accessibility domain of T.
• If the declared accessibility of M is protected internal, let D be the union of the program text of P and the program text of any type derived from T, which is declared outside P. The accessibility domain of M is the intersection of the accessibility domain of T with D.
• If the declared accessibility of M is protected, let D be the union of the program text of T and the program text of any type derived from T. The accessibility domain of M is the intersection of the accessibility domain of T with D.
• If the declared accessibility of M is internal, the accessibility domain of M is the intersection of the accessibility domain of T with the program text of P.
• If the declared accessibility of M is private, the accessibility domain of M is the program text of T.
From these definitions it follows that the accessibility domain of a nested member is always at least the program text of the type in which the member is declared. Furthermore, it follows that the accessibility domain of a member is never more inclusive than the accessibility domain of the type in which the member is declared.
In intuitive terms, when a type or member M is accessed, the following steps are evaluated to ensure that the access is permitted:
• First, if M is declared within a type (as opposed to a compilation unit or a namespace), a compile-time error occurs if that type is not accessible.
• Then, if M is public, the access is permitted.
• Otherwise, if M is protected internal, the access is permitted if it occurs within the program in which M is declared, or if it occurs within a class derived from the class in which M is declared and takes place through the derived class type (§3.5.3).
• Otherwise, if M is protected, the access is permitted if it occurs within the class in which M is declared, or if it occurs within a class derived from the class in which M is declared and takes place through the derived class type (§3.5.3).
• Otherwise, if M is internal, the access is permitted if it occurs within the program in which M is declared.
• Otherwise, if M is private, the access is permitted if it occurs within the type in which M is declared.
• Otherwise, the type or member is inaccessible, and a compile-time error occurs.
In the example
public class A
{
public static int X;
internal static int Y;
private static int Z;
}
internal class B
{
public static int X;
internal static int Y;
private static int Z;
public class C
{
public static int X;
internal static int Y;
private static int Z;
}
private class D
{
public static int X;
internal static int Y;
private static int Z;
}
}
the classes and members have the following accessibility domains:
• The accessibility domain of A and A.X is unlimited.
• The accessibility domain of A.Y, B, B.X, B.Y, B.C, B.C.X, and B.C.Y is the program text of the containing program.
• The accessibility domain of A.Z is the program text of A.
• The accessibility domain of B.Z and B.D is the program text of B, including the program text of B.C and B.D.
• The accessibility domain of B.C.Z is the program text of B.C.
• The accessibility domain of B.D.X, B.D.Y, and B.D.Z is the program text of B.D.
As the example illustrates, the accessibility domain of a member is never larger than that of a containing type. For example, even though all X members have public declared accessibility, all but A.X have accessibility domains that are constrained by a containing type.
As described in §3.4, all members of a base class, except for instance constructors, destructors and static constructors, are inherited by derived types. This includes even private members of a base class. However, the accessibility domain of a private member includes only the program text of the type in which the member is declared. In the example
class A
{
int x;
static void F(B b) {
b.x = 1; // Ok
}
}
class B: A
{
static void F(B b) {
b.x = 1; // Error, x not accessible
}
}
the B class inherits the private member x from the A class. Because the member is private, it is only accessible within the class-body of A. Thus, the access to b.x succeeds in the A.F method, but fails in the B.F method.
3.5.3 Protected access for instance members
When a protected instance member is accessed outside the program text of the class in which it is declared, and when a protected internal instance member is accessed outside the program text of the program in which it is declared, the access is required to take place through an instance of the derived class type in which the access occurs. Let B be a base class that declares a protected instance member M, and let D be a class that derives from B. Within the class-body of D, access to M can take one of the following forms:
• An unqualified type-name or primary-expression of the form M.
• A primary-expression of the form E.M, provided the type of E is D or a class derived from D.
• A primary-expression of the form base.M.
In addition to these forms of access, a derived class can access a protected instance constructor of a base class in a constructor-initializer (§10.10.1).
In the example
public class A
{
protected int x;
static void F(A a, B b) {
a.x = 1; // Ok
b.x = 1; // Ok
}
}
public class B: A
{
static void F(A a, B b) {
a.x = 1; // Error, must access through instance of B
b.x = 1; // Ok
}
}
within A, it is possible to access x through instances of both A and B, since in either case the access takes place through an instance of A or a class derived from A. However, within B, it is not possible to access x through an instance of A, since A does not derive from B.
3.5.4 Accessibility constraints
Several constructs in the C# language require a type to be at least as accessible as a member or another type. A type T is said to be at least as accessible as a member or type M if the accessibility domain of T is a superset of the accessibility domain of M. In other words, T is at least as accessible as M if T is accessible in all contexts where M is accessible.
The following accessibility constraints exist:
• The direct base class of a class type must be at least as accessible as the class type itself.
• The explicit base interfaces of an interface type must be at least as accessible as the interface type itself.
• The return type and parameter types of a delegate type must be at least as accessible as the delegate type itself.
• The type of a constant must be at least as accessible as the constant itself.
• The type of a field must be at least as accessible as the field itself.
• The return type and parameter types of a method must be at least as accessible as the method itself.
• The type of a property must be at least as accessible as the property itself.
• The type of an event must be at least as accessible as the event itself.
• The type and parameter types of an indexer must be at least as accessible as the indexer itself.
• The return type and parameter types of an operator must be at least as accessible as the operator itself.
• The parameter types of an instance constructor must be at least as accessible as the instance constructor itself.
In the example
class A {...}
public class B: A {...}
the B class results in a compile-time error because A is not at least as accessible as B.
Likewise, in the example
class A {...}
public class B
{
A F() {...}
internal A G() {...}
public A H() {...}
}
the H method in B results in a compile-time error because the return type A is not at least as accessible as the method.
3.6 Signatures and overloading
Methods, instance constructors, indexers, and operators are characterized by their signatures:
• The signature of a method consists of the name of the method and the type and kind (value, reference, or output) of each of its formal parameters, considered in the order left to right. The signature of a method specifically does not include the return type, nor does it include the params modifier that may be specified for the right-most parameter.
• The signature of an instance constructor consists of the type and kind (value, reference, or output) of each of its formal parameters, considered in the order left to right. The signature of an instance constructor specifically does not include the params modifier that may be specified for the right-most parameter.
• The signature of an indexer consists of the type of each of its formal parameters, considered in the order left to right. The signature of an indexer specifically does not include the element type.
• The signature of an operator consists of the name of the operator and the type of each of its formal parameters, considered in the order left to right. The signature of an operator specifically does not include the result type.
Signatures are the enabling mechanism for overloading of members in classes, structs, and interfaces:
• Overloading of methods permits a class, struct, or interface to declare multiple methods with the same name, provided their signatures are unique.
• Overloading of instance constructors permits a class or struct to declare multiple instance constructors, provided their signatures are unique.
• Overloading of indexers permits a class, struct, or interface to declare multiple indexers, provided their signatures are unique.
• Overloading of operators permits a class or struct to declare multiple operators with the same name, provided their signatures are unique.
The following example shows a set of overloaded method declarations along with their signatures.
interface ITest
{
void F(); // F()
void F(int x); // F(int)
void F(ref int x); // F(ref int)
void F(out int x); // F(out int)
void F(int x, int y); // F(int, int)
int F(string s); // F(string)
int F(int x); // F(int) error
void F(string[] a); // F(string[])
void F(params string[] a); // F(string[]) error
}
Note that any ref and out parameter modifiers (§10.5.1) are part of a signature. Thus, F(int), F(ref int), and F(out int) are all unique signatures. Also, note that the return type and the params modifier are not part of a signature, so it is not possible to overload solely based on return type or on the inclusion or exclusion of the params modifier. Because of these restrictions, the declarations of the methods F(int) and F(params string[]) in the example above result in a compile-time error.
3.7 Scopes
The scope of a name is the region of program text within which it is possible to refer to the entity declared by the name without qualification of the name. Scopes can be nested, and an inner scope may redeclare the meaning of a name from an outer scope. (This does not, however, remove the restriction imposed by §3.3 that within a nested block it is not possible to declare a local variable with the same name as a local variable in an enclosing block.) The name from the outer scope is then said to be hidden in the region of program text covered by the inner scope, and access to the outer name is only possible by qualifying the name.
• The scope of a namespace member declared by a namespace-member-declaration (§9.4) with no enclosing namespace-declaration is the entire program text.
• The scope of a namespace member declared by a namespace-member-declaration within a namespace-declaration whose fully qualified name is N is the namespace-body of every namespace-declaration whose fully qualified name is N or starts with N, followed by a period.
• The scope of a name defined or imported by a using-directive (§9.3) extends over the namespace-member-declarations of the compilation-unit or namespace-body in which the using-directive occurs. A using-directive may make zero or more namespace or type names available within a particular compilation-unit or namespace-body, but does not contribute any new members to the underlying declaration space. In other words, a using-directive is not transitive but rather affects only the compilation-unit or namespace-body in which it occurs.
• The scope of a member declared by a class-member-declaration (§10.2) is the class-body in which the declaration occurs. In addition, the scope of a class member extends to the class-body of those derived classes that are included in the accessibility domain (§3.5.2) of the member.
• The scope of a member declared by a struct-member-declaration (§11.2) is the struct-body in which the declaration occurs.
• The scope of a member declared by an enum-member-declaration (§14.3) is the enum-body in which the declaration occurs.
• The scope of a parameter declared in a method-declaration (§10.5) is the method-body of that method-declaration.
• The scope of a parameter declared in an indexer-declaration (§10.8) is the accessor-declarations of that indexer-declaration.
• The scope of a parameter declared in an operator-declaration (§10.9) is the block of that operator-declaration.
• The scope of a parameter declared in a constructor-declaration (§10.10) is the constructor-initializer and block of that constructor-declaration.
• The scope of a label declared in a labeled-statement (§8.4) is the block in which the declaration occurs.
• The scope of a local variable declared in a local-variable-declaration (§8.5.1) is the block in which the declaration occurs. It is a compile-time error to refer to a local variable in a textual position that precedes its local-variable-declarator.
• The scope of a local variable declared in a switch-block of a switch statement (§8.7.2) is the switch-block.
• The scope of a local variable declared in a for-initializer of a for statement (§8.8.3) is the for-initializer, the for-condition, the for-iterator, and the contained statement of the for statement.
• The scope of a local constant declared in a local-constant-declaration (§8.5.2) is the block in which the declaration occurs. It is a compile-time error to refer to a local constant in a textual position that precedes its constant-declarator.
Within the scope of a namespace, class, struct, or enumeration member it is possible to refer to the member in a textual position that precedes the declaration of the member. For example
class A
{
void F() {
i = 1;
}
int i = 0;
}
Here, it is valid for F to refer to i before it is declared.
Within the scope of a local variable, it is a compile-time error to refer to the local variable in a textual position that precedes the local-variable-declarator of the local variable. For example
class A
{
int i = 0;
void F() {
i = 1; // Error, use precedes declaration
int i;
i = 2;
}
void G() {
int j = (j = 1); // Valid
}
void H() {
int a = 1, b = ++a; // Valid
}
}
In the F method above, the first assignment to i specifically does not refer to the field declared in the outer scope. Rather, it refers to the local variable and it results in a compile-time error because it textually precedes the declaration of the variable. In the G method, the use of j in the initializer for the declaration of j is valid because the use does not precede the local-variable-declarator. In the H method, a subsequent local-variable-declarator refers to a local variable declared in an earlier local-variable-declarator within the same local-variable-declaration.
The scoping rules for local variables are designed to guarantee that the meaning of a name used in an expression context is always the same within a block. If the scope of a local variable was to extend only from its declaration to the end of the block, then in the example above, the first assignment would assign to the instance variable and the second assignment would assign to the local variable, possibly leading to compile-time errors if the statements of the block were later to be rearranged.
The meaning of a name within a block may differ based on the context in which the name is used. In the example
class A {}
class Test
{
static void Main() {
string A = "hello, world";
string s = A; // expression context
Type t = typeof(A); // type context
Console.WriteLine(s); // writes "hello, world"
Console.WriteLine(t); // writes "A"
}
}
the name A is used in an expression context to refer to the local variable A and in a type context to refer to the class A.
3.7.1 Name hiding
The scope of an entity typically encompasses more program text than the declaration space of the entity. In particular, the scope of an entity may include declarations that introduce new declaration spaces containing entities of the same name. Such declarations cause the original entity to become hidden. Conversely, an entity is said to be visible when it is not hidden.
Name hiding occurs when scopes overlap through nesting and when scopes overlap through inheritance. The characteristics of the two types of hiding are described in the following sections.
3.7.1.1 Hiding through nesting
Name hiding through nesting can occur as a result of nesting namespaces or types within namespaces, as a result of nesting types within classes or structs, and as a result of parameter and local variable declarations.
In the example
class A
{
int i = 0;
void F() {
int i = 1;
}
void G() {
i = 1;
}
}
within the F method, the instance variable i is hidden by the local variable i, but within the G method, i still refers to the instance variable.
When a name in an inner scope hides a name in an outer scope, it hides all overloaded occurrences of that name. In the example
class Outer
{
static void F(int i) {}
static void F(string s) {}
class Inner
{
void G() {
F(1); // Invokes Outer.Inner.F
F("Hello"); // Error
}
static void F(long l) {}
}
}
the call F(1) invokes the F declared in Inner because all outer occurrences of F are hidden by the inner declaration. For the same reason, the call F("Hello") results in a compile-time error.
3.7.1.2 Hiding through inheritance
Name hiding through inheritance occurs when classes or structs redeclare names that were inherited from base classes. This type of name hiding takes one of the following forms:
• A constant, field, property, event, or type introduced in a class or struct hides all base class members with the same name.
• A method introduced in a class or struct hides all non-method base class members with the same name, and all base class methods with the same signature (method name and parameter count, modifiers, and types).
• An indexer introduced in a class or struct hides all base class indexers with the same signature (parameter count and types).
The rules governing operator declarations (§10.9) make it impossible for a derived class to declare an operator with the same signature as an operator in a base class. Thus, operators never hide one another.
Contrary to hiding a name from an outer scope, hiding an accessible name from an inherited scope causes a warning to be reported. In the example
class Base
{
public void F() {}
}
class Derived: Base
{
public void F() {} // Warning, hiding an inherited name
}
the declaration of F in Derived causes a warning to be reported. Hiding an inherited name is specifically not an error, since that would preclude separate evolution of base classes. For example, the above situation might have come about because a later version of Base introduced an F method that wasn’t present in an earlier version of the class. Had the above situation been an error, then any change made to a base class in a separately versioned class library could potentially cause derived classes to become invalid.
The warning caused by hiding an inherited name can be eliminated through use of the new modifier:
class Base
{
public void F() {}
}
class Derived: Base
{
new public void F() {}
}
The new modifier indicates that the F in Derived is “new”, and that it is indeed intended to hide the inherited member.
A declaration of a new member hides an inherited member only within the scope of the new member.
class Base
{
public static void F() {}
}
class Derived: Base
{
new private static void F() {} // Hides Base.F in Derived only
}
class MoreDerived: Derived
{
static void G() { F(); } // Invokes Base.F
}
In the example above, the declaration of F in Derived hides the F that was inherited from Base, but since the new F in Derived has private access, its scope does not extend to MoreDerived. Thus, the call F() in MoreDerived.G is valid and will invoke Base.F.
3.8 Namespace and type names
Several contexts in a C# program require a namespace-name or a type-name to be specified. Either form of name is written as one or more identifiers separated by “.” tokens.
namespace-name:
namespace-or-type-name
type-name:
namespace-or-type-name
namespace-or-type-name:
identifier
namespace-or-type-name . identifier
A type-name is a namespace-or-type-name that refers to a type. Following resolution as described below, the namespace-or-type-name of a type-name must refer to a type, or otherwise a compile-time error occurs.
A namespace-name is a namespace-or-type-name that refers to a namespace. Following resolution as described below, the namespace-or-type-name of a namespace-name must refer to a namespace, or otherwise a compile-time error occurs.
The meaning of a namespace-or-type-name is determined as follows:
• If the namespace-or-type-name consists of a single identifier:
o If the namespace-or-type-name appears within the body of a class or struct declaration, then starting with that class or struct declaration and continuing with each enclosing class or struct declaration (if any), if a member with the given name exists, is accessible, and denotes a type, then the namespace-or-type-name refers to that member. Note that non-type members (constants, fields, methods, properties, indexers, operators, instance constructors, destructors, and static constructors) are ignored when determining the meaning of a namespace-or-type-name.
o Otherwise, starting with the namespace in which the namespace-or-type-name occurs (if any), continuing with each enclosing namespace (if any), and ending with the global namespace, the following steps are evaluated until an entity is located:
• If the namespace contains a namespace member with the given name, then the namespace-or-type-name refers to that member and, depending on the member, is classified as a namespace or a type.
• Otherwise, if the namespace has a corresponding namespace declaration enclosing the location where the namespace-or-type-name occurs, then:
o If the namespace declaration contains a using-alias-directive that associates the given name with an imported namespace or type, then the namespace-or-type-name refers to that namespace or type.
o Otherwise, if the namespaces imported by the using-namespace-directives of the namespace declaration contain exactly one type with the given name, then the namespace-or-type-name refers to that type.
o Otherwise, if the namespaces imported by the using-namespace-directives of the namespace declaration contain more than one type with the given name, then the namespace-or-type-name is ambiguous and a compile-time error.
o Otherwise, the namespace-or-type-name is undefined and a compile-time error occurs.
• Otherwise, the namespace-or-type-name is of the form N.I, where N is a namespace-or-type-name consisting of all identifiers but the rightmost one, and I is the rightmost identifier. N is first resolved as a namespace-or-type-name. If the resolution of N is not successful, a compile-time error occurs. Otherwise, N.I is resolved as follows:
o If N is a namespace and I is the name of an accessible member of that namespace, then N.I refers to that member and, depending on the member, is classified as a namespace or a type.
o If N is a class or struct type and I is the name of an accessible type in N, then N.I refers to that type.
o Otherwise, N.I is an invalid namespace-or-type-name, and a compile-time error occurs.
3.8.1 Fully qualified names
Every namespace and type has a fully qualified name which uniquely identifies the namespace or type amongst all others. The fully qualified name of a namespace or type N is determined as follows:
• If N is a member of the global namespace, its fully qualified name is N.
• Otherwise, its fully qualified name is S.N, where S is the fully qualified name of the namespace or type in which N is declared.
In other words, the fully qualified name of N is the complete hierarchical path of identifiers that lead to N, starting from the global namespace. Because every member of a namespace or type must have a unique name, it follows that the fully qualified name of a namespace or type is always unique.
The example below shows several namespace and type declarations along with their associated fully qualified names.
class A {} // A
namespace X // X
{
class B // X.B
{
class C {} // X.B.C
}
namespace Y // X.Y
{
class D {} // X.Y.D
}
}
namespace X.Y // X.Y
{
class E {} // X.Y.E
}
3.9 Automatic memory management
C# employs automatic memory management, which frees developers from manually allocating and freeing the memory occupied by objects. Automatic memory management policies are implemented by a garbage collector. The memory management life cycle of an object is as follows:
1. When the object is created, memory is allocated for it, the constructor is run, and the object is considered live.
2. If the object, or any part of it, cannot be accessed by any possible continuation of execution, other than the running of destructors, the object is considered no longer in use, and it becomes eligible for destruction. Implementations may choose to analyze code to determine which references to an object may be used in the future. For instance, if a local variable that is in scope is the only existing reference to an object, but that local variable is never referred to in any possible continuation of execution from the current execution point in the procedure, an implementation may (but is not required to) treat the object as no longer in use.
3. Once the object is eligible for destruction, at some unspecified later time the destructor (§10.12) (if any) for the object is run. Unless overridden by explicit calls, the destructor for the object is run once only.
4. Once the destructor for an object is run, if that object, or any part of it, cannot be accessed by any possible continuation of execution, including the running of destructors, the object is considered inaccessible and the object becomes eligible for collection.
5. Finally, at some time after the object becomes eligible for collection, the garbage collector frees the memory associated with that object.
The garbage collector maintains information about object usage, and uses this information to make memory management decisions, such as where in memory to locate a newly created object, when to relocate an object, and when an object is no longer in use or inaccessible.
Like other languages that assume the existence of a garbage collector, C# is designed so that the garbage collector may implement a wide range of memory management policies. For instance, C# does not require that destructors be run or that objects be collected as soon as they are eligible, or that destructors be run in any particular order, or on any particular thread.
The behavior of the garbage collector can be controlled, to some degree, via static methods on the class System.GC. This class can be used to request a collection to occur, destructors to be run (or not run), and so forth.
Since the garbage collector is allowed wide latitude in deciding when to collect objects and run destructors, a conforming implementation may produce output that differs from that shown by the following code. The program
class A
{
~A() {
Console.WriteLine("Destruct instance of A");
}
}
class B
{
object Ref;
public B(object o) {
Ref = o;
}
~B() {
Console.WriteLine("Destruct instance of B");
}
}
class Test
{
static void Main() {
B b = new B(new A());
b = null;
GC.Collect();
GC.WaitForPendingFinalizers();
}
}
creates an instance of class A and an instance of class B. These objects become eligible for garbage collection when the variable b is assigned the value null, since after this time it is impossible for any user-written code to access them. The output could be either
Destruct instance of A
Destruct instance of B
or
Destruct instance of B
Destruct instance of A
because the language imposes no constraints on the order in which objects are garbage collected.
In subtle cases, the distinction between “eligible for destruction” and “eligible for collection” can be important. For example,
class A
{
~A() {
Console.WriteLine("Destruct instance of A");
}
public void F() {
Console.WriteLine("A.F");
Test.RefA = this;
}
}
class B
{
public A Ref;
~B() {
Console.WriteLine("Destruct instance of B");
Ref.F();
}
}
class Test
{
public static A RefA;
public static B RefB;
static void Main() {
RefB = new B();
RefA = new A();
RefB.Ref = RefA;
RefB = null;
RefA = null;
// A and B now eligible for destruction
GC.Collect();
GC.WaitForPendingFinalizers();
// B now eligible for collection, but A is not
if (RefA != null)
Console.WriteLine("RefA is not null");
}
}
In the above program, if the garbage collector chooses to run the destructor of B before the destructor of A, then the output of this program might be:
Destruct instance of A
Destruct instance of B
A.F
RefA is not null
Note that although the instance of A was not in use and A's destructor was run, it is still possible for methods of A (in this case, F) to be called from another destructor. Also, note that running of a destructor may cause an object to become usable from the mainline program again. In this case, the running of B's destructor caused an instance of A that was previously not in use to become accessible from the live reference RefA. After the call to WaitForPendingFinalizers, the instance of B is eligible for collection, but the instance of A is not, because of the reference RefA.
To avoid confusion and unexpected behavior, it is generally a good idea for destructors to only perform cleanup on data stored in their object's own fields, and not to perform any actions on referenced objects or static fields.
3.10 Execution order
Execution shall proceed such that the side effects of each executing thread are preserved at critical execution points. A side effect is defined as a read or write of a volatile field, a write to a non-volatile variable, a write to an external resource, and the throwing of an exception. The critical execution points at which the order of these side effects must be preserved are references to volatile fields (§10.4.3), lock statements (§8.12), and thread creation and termination. An implementation is free to change the order of execution of a C# program, subject to the following constraints:
• Data dependence is preserved within a thread of execution. That is, the value of each variable is computed as if all statements in the thread were executed in original program order.
• Initialization ordering rules are preserved (§10.4.4 and §10.4.5).
• The ordering of side effects is preserved with respect to volatile reads and writes (§10.4.3). Additionally, an implementation need not evaluate part of an expression if it can deduce that that expression’s value is not used and that no needed side effects are produced (including any caused by calling a method or accessing a volatile field). When program execution is interrupted by an asynchronous event (such as an exception thrown by another thread), it is not guaranteed that the observable side effects are visible in the original program order.

4. Types
The types of the C# language are divided into two categories: value types and reference types.
type:
value-type
reference-type
A third category of types, pointers, is available only in unsafe code. This is discussed further in §A.2.
Value types differ from reference types in that variables of the value types directly contain their data, whereas variables of the reference types store references to their data, the latter being known as objects. With reference types, it is possible for two variables to reference the same object, and thus possible for operations on one variable to affect the object referenced by the other variable. With value types, the variables each have their own copy of the data, and it is not possible for operations on one to affect the other.
C#’s type system is unified such that a value of any type can be treated as an object. Every type in C# directly or indirectly derives from the object class type, and object is the ultimate base class of all types. Values of reference types are treated as objects simply by viewing the values as type object. Values of value types are treated as objects by performing boxing and unboxing operations (§4.3).
4.1 Value types
A value type is either a struct type or an enumeration type. C# provides a set of predefined struct types called the simple types. The simple types are identified through reserved words.
value-type:
struct-type
enum-type
struct-type:
type-name
simple-type
simple-type:
numeric-type
bool
numeric-type:
integral-type
floating-point-type
decimal
integral-type:
sbyte
byte
short
ushort
int
uint
long
ulong
char
floating-point-type:
float
double
enum-type:
type-name
All value types implicitly inherit from class object. It is not possible for any type to derive from a value type, and value types are thus implicitly sealed (§10.1.1.2).
A variable of a value type always contains a value of that type. Unlike reference types, it is not possible for a value of a value type to be null or to reference an object of a more derived type.
Assignment to a variable of a value type creates a copy of the value being assigned. This differs from assignment to a variable of a reference type, which copies the reference but not the object identified by the reference.
4.1.1 Default constructors
All value types implicitly declare a public parameterless instance constructor called the default constructor. The default constructor returns a zero-initialized instance known as the default value for the value type:
• For all simple-types, the default value is the value produced by a bit pattern of all zeros:
o For sbyte, byte, short, ushort, int, uint, long, and ulong, the default value is 0.
o For char, the default value is '\x0000'.
o For float, the default value is 0.0f.
o For double, the default value is 0.0d.
o For decimal, the default value is 0.0m.
o For bool, the default value is false.
• For an enum-type E, the default value is 0.
• For a struct-type, the default value is the value produced by setting all value type fields to their default value and all reference type fields to null.
Like any other instance constructor, the default constructor of a value type is invoked using the new operator. (Note: for efficiency reasons, this requirement is not intended to actually have the implementation generate a constructor call.) In the example below, the variables i and j are both initialized to zero.
class A
{
void F() {
int i = 0;
int j = new int();
}
}
Because every value type implicitly has a public parameterless instance constructor, it is not possible for a struct type to contain an explicit declaration of a parameterless constructor. A struct type is however permitted to declare parameterized instance constructors (§11.3.8). For example
struct Point
{
int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
Given the above declaration, the statements
Point p1 = new Point();
Point p2 = new Point(0, 0);
both create a Point with x and y initialized to zero.
4.1.2 Struct types
A struct type is a value type that can declare constants, fields, methods, properties, indexers, operators, instance constructors, static constructors, and nested types. Struct types are described in §11.
4.1.3 Simple types
C# provides a set of predefined struct types called the simple types. The simple types are identified through reserved words, but these reserved words are simply aliases for predefined struct types in the System namespace, as described in the table below.

Reserved word Aliased type
sbyte System.SByte
byte System.Byte
short System.Int16
ushort System.UInt16
int System.Int32
uint System.UInt32
long System.Int64
ulong System.UInt64
char System.Char
float System.Single
double System.Double
bool System.Boolean
decimal System.Decimal

Because a simple type aliases a struct type, every simple type has members. For example, int has the members declared in System.Int32 and the members inherited from System.Object, and the following statements are permitted:
int i = int.MaxValue; // System.Int32.MaxValue constant
string s = i.ToString(); // System.Int32.ToString() instance method
string t = 123.ToString(); // System.Int32.ToString() instance method
The simple types differ from other struct types in that they permit certain additional operations:
• Most simple types permit values to be created by writing literals (§2.4.4). For example, 123 is a literal of type int and 'a' is a literal of type char. C# makes no provision for literals of other struct types, and non-default values of other struct types are ultimately always created through instance constructors of those struct types.
• When the operands of an expression are all simple type constants, it is possible for the compiler to evaluate the expression at compile-time. Such an expression is known as a constant-expression (§7.15). Expressions involving operators defined by other struct types are not considered constant expressions.
• Through const declarations it is possible to declare constants of the simple types (§10.3). It is not possible to have constants of other struct types, but a similar effect is provided by static readonly fields.
• Conversions involving simple types can participate in evaluation of conversion operators defined by other struct types, but a user-defined conversion operator can never participate in evaluation of another user-defined operator (§6.4.2).
4.1.4 Integral types
C# supports nine integral types: sbyte, byte, short, ushort, int, uint, long, ulong, and char. The integral types have the following sizes and ranges of values:
• The sbyte type represents signed 8-bit integers with values between –128 and 127.
• The byte type represents unsigned 8-bit integers with values between 0 and 255.
• The short type represents signed 16-bit integers with values between –32768 and 32767.
• The ushort type represents unsigned 16-bit integers with values between 0 and 65535.
• The int type represents signed 32-bit integers with values between –2147483648 and 2147483647.
• The uint type represents unsigned 32-bit integers with values between 0 and 4294967295.
• The long type represents signed 64-bit integers with values between –9223372036854775808 and 9223372036854775807.
• The ulong type represents unsigned 64-bit integers with values between 0 and 18446744073709551615.
• The char type represents unsigned 16-bit integers with values between 0 and 65535. The set of possible values for the char type corresponds to the Unicode character set. Although char has the same representation as ushort, not all operations permitted on one type are permitted on the other.
The integral-type unary and binary operators always operate with signed 32-bit precision, unsigned 32-bit precision, signed 64-bit precision, or unsigned 64-bit precision:
• For the unary + and ~ operators, the operand is converted to type T, where T is the first of int, uint, long, and ulong that can fully represent all possible values of the operand. The operation is then performed using the precision of type T, and the type of the result is T.
• For the unary—operator, the operand is converted to type T, where T is the first of int and long that can fully represent all possible values of the operand. The operation is then performed using the precision of type T, and the type of the result is T. The unary—operator cannot be applied to operands of type ulong.
• For the binary +, –, *, /, %, &, ^, |, ==, !=, >, <, >=, and <= operators, the operands are converted to type T, where T is the first of int, uint, long, and ulong that can fully represent all possible values of both operands. The operation is then performed using the precision of type T, and the type of the result is T (or bool for the relational operators). It is not permitted for one operand to be of type long and the other to be of type ulong with the binary operators.
• For the binary << and >> operators, the left operand is converted to type T, where T is the first of int, uint, long, and ulong that can fully represent all possible values of the operand. The operation is then performed using the precision of type T, and the type of the result is T.
The char type is classified as an integral type, but it differs from the other integral types in two ways:
• There are no implicit conversions from other types to the char type. In particular, even though the sbyte, byte, and ushort types have ranges of values that are fully representable using the char type, implicit conversions from sbyte, byte, or ushort to char do not exist.
• Constants of the char type must be written as character-literals or as integer-literals in combination with a cast to type char. For example, (char)10 is the same as '\x000A'.
The checked and unchecked operators and statements are used to control overflow checking for integral-type arithmetic operations and conversions (§7.5.12). In a checked context, an overflow produces a compile-time error or causes a System.OverflowException to be thrown. In an unchecked context, overflows are ignored and any high-order bits that do not fit in the destination type are discarded.
4.1.5 Floating point types
C# supports two floating point types: float and double. The float and double types are represented using the 32-bit single-precision and 64-bit double-precision IEEE 754 formats, which provide the following sets of values:
• Positive zero and negative zero. In most situations, positive zero and negative zero behave identically as the simple value zero, but certain operations distinguish between the two (§7.7.2).
• Positive infinity and negative infinity. Infinities are produced by such operations as dividing a non-zero number by zero. For example, 1.0 / 0.0 yields positive infinity, and –1.0 / 0.0 yields negative infinity.
• The Not-a-Number value, often abbreviated NaN. NaN’s are produced by invalid floating-point operations, such as dividing zero by zero.
• The finite set of non-zero values of the form s × m × 2e, where s is 1 or −1, and m and e are determined by the particular floating-point type: For float, 0 < m < 224 and −149 ≤ e ≤ 104, and for double, 0 < m < 253 and −1075 ≤ e ≤ 970. Denormalized floating-point numbers are considered valid non-zero values.
The float type can represent values ranging from approximately 1.5 × 10−45 to 3.4 × 1038 with a precision of 7 digits.
The double type can represent values ranging from approximately 5.0 × 10−324 to 1.7 × 10308 with a precision of 15-16 digits.
If one of the operands of a binary operator is of a floating-point type, then the other operand must be of an integral type or a floating-point type, and the operation is evaluated as follows:
• If one of the operands is of an integral type, then that operand is converted to the floating-point type of the other operand.
• Then, if either of the operands is of type double, the other operand is converted to double, the operation is performed using at least double range and precision, and the type of the result is double (or bool for the relational operators).
• Otherwise, the operation is performed using at least float range and precision, and the type of the result is float (or bool for the relational operators).
The floating-point operators, including the assignment operators, never produce exceptions. Instead, in exceptional situations, floating-point operations produce zero, infinity, or NaN, as described below:
• If the result of a floating-point operation is too small for the destination format, the result of the operation becomes positive zero or negative zero.
• If the result of a floating-point operation is too large for the destination format, the result of the operation becomes positive infinity or negative infinity.
• If a floating-point operation is invalid, the result of the operation becomes NaN.
• If one or both operands of a floating-point operation is NaN, the result of the operation becomes NaN.
Floating-point operations may be performed with higher precision than the result type of the operation. For example, some hardware architectures support an “extended” or “long double” floating-point type with greater range and precision than the double type, and implicitly perform all floating-point operations using this higher precision type. Only at excessive cost in performance can such hardware architectures be made to perform floating-point operations with less precision, and rather than require an implementation to forfeit both performance and precision, C# allows a higher precision type to be used for all floating-point operations. Other than delivering more precise results, this rarely has any measurable effects. However, in expressions of the form x * y / z, where the multiplication produces a result that is outside the double range, but the subsequent division brings the temporary result back into the double range, the fact that the expression is evaluated in a higher range format may cause a finite result to be produced instead of an infinity.
4.1.6 The decimal type
The decimal type is a 128-bit data type suitable for financial and monetary calculations. The decimal type can represent values ranging from 1.0 × 10−28 to approximately 7.9 × 1028 with 28-29 significant digits.
The finite set of values of type decimal are of the form –1s × c × 10-e, where the sign s is 0 or 1, the coefficient c is given by 0 ≤ c < 296, and the scale e is such that 0 ≤ e ≤ 28.The decimal type does not support signed zeros, infinities, or NaN's.A decimal is represented as a 96-bit integer scaled by a power of ten. For decimals with an absolute value less than 1.0m, the value is exact to the 28th decimal place, but no further. For decimals with an absolute value greater than or equal to 1.0m, the value is exact to 28 or 29 digits. Contrary to the float and double data types, decimal fractional numbers such as 0.1 can be represented exactly in the decimal representation. In the float and double representations, such numbers are often infinite fractions, making those representations more prone to round-off errors.
If one of the operands of a binary operator is of type decimal, then the other operand must be of an integral type or of type decimal. If an integral type operand is present, it is converted to decimal before the operation is performed.
The result of an operation on values of type decimal is that which would result from calculating an exact result and then rounding to fit the representation. Results are rounded to the nearest representable value, and, when a result is equally close to two representable values, to the value that has an even number in the least significant digit position (this is known as “banker’s rounding”). That is, results are exact to 28 or 29 digits, but to no more than 28 decimal places. A zero result always has a sign of 0 and a scale of 0.If a decimal arithmetic operation produces a value that is too small for the decimal format after rounding, the result of the operation becomes zero. If a decimal arithmetic operation produces a result that is too large for the decimal format, a System.OverflowException is thrown.
The decimal type has greater precision but smaller range than the floating-point types. Thus, conversions from the floating-point types to decimal might produce overflow exceptions, and conversions from decimal to the floating-point types might cause loss of precision. For these reasons, no implicit conversions exist between the floating-point types and decimal, and without explicit casts, it is not possible to mix floating-point and decimal operands in the same expression.
4.1.7 The bool type
The bool type represents boolean logical quantities. The possible values of type bool are true and false.
No standard conversions exist between bool and other types. In particular, the bool type is distinct and separate from the integral types, and a bool value cannot be used in place of an integral value, and vice versa.
In the C and C++ languages, a zero integral value or a null pointer can be converted to the boolean value false, and a non-zero integral value or a non-null pointer can be converted to the boolean value true. In C#, such conversions are accomplished by explicitly comparing an integral value to zero or explicitly comparing an object reference to null.
4.1.8 Enumeration types
An enumeration type is a distinct type with named constants. Every enumeration type has an underlying type, which must be byte, sbyte, short, ushort, int, uint, long or ulong. Enumeration types are defined through enumeration declarations (§14.1).
4.2 Reference types
A reference type is a class type, an interface type, an array type, or a delegate type.
reference-type:
class-type
interface-type
array-type
delegate-type
class-type:
type-name
object
string
interface-type:
type-name
array-type:
non-array-type rank-specifiers
non-array-type:
type
rank-specifiers:
rank-specifier
rank-specifiers rank-specifier
rank-specifier:
[ dim-separatorsopt ]
dim-separators:
,
dim-separators ,
delegate-type:
type-name
A reference type value is a reference to an instance of the type, the latter known as an object. The special value null is compatible with all reference types and indicates the absence of an instance.
4.2.1 Class types
A class type defines a data structure that contains data members (constants and fields), function members (methods, properties, events, indexers, operators, instance constructors, destructors and static constructors), and nested types. Class types support inheritance, a mechanism whereby derived classes can extend and specialize base classes. Instances of class types are created using object-creation-expressions (§7.5.10.1).
Class types are described in §10.
4.2.2 The object type
The object class type is the ultimate base class of all other types. Every type in C# directly or indirectly derives from the object class type.
The object keyword is simply an alias for the predefined System.Object class.
4.2.3 The string type
The string type is a sealed class type that inherits directly from object. Instances of the string class represent Unicode character strings.
Values of the string type can be written as string literals (§2.4.4).
The string keyword is simply an alias for the predefined System.String class.
4.2.4 Interface types
An interface defines a contract. A class or struct that implements an interface must adhere to its contract. An interface may inherit from multiple base interfaces, and a class or struct may implement multiple interfaces.
Interface types are described in §13.
4.2.5 Array types
An array is a data structure that contains zero or more variables which are accessed through computed indices. The variables contained in an array, also called the elements of the array, are all of the same type, and this type is called the element type of the array.
Array types are described in §12.
4.2.6 Delegate types
A delegate is a data structure that refers to one or more methods, and for instance methods, it also refers to their corresponding object instances.
The closest equivalent of a delegate in C or C++ is a function pointer, but whereas a function pointer can only reference static functions, a delegate can reference both static and instance methods. In the latter case, the delegate stores not only a reference to the method’s entry point, but also a reference to the object on which to invoke the method.
Delegate types are described in §15.
4.3 Boxing and unboxing
Boxing and unboxing is a central concept in C#’s type system. It provides a bridge between value-types and reference-types by permitting any value of a value-type to be converted to and from type object. Boxing and unboxing enables a unified view of the type system wherein a value of any type can ultimately be treated as an object.
4.3.1 Boxing conversions
A boxing conversion permits any value-type to be implicitly converted to the type object or to any interface-type implemented by the value-type. Boxing a value of a value-type consists of allocating an object instance and copying the value-type value into that instance.
The actual process of boxing a value of a value-type is best explained by imagining the existence of a boxing class for that type. For any value-type T, the boxing class behaves as if it were declared as follows:
sealed class T_Box
{
T value;
public T_Box(T t) {
value = t;
}
}
Boxing of a value v of type T now consists of executing the expression new T_Box(v), and returning the resulting instance as a value of type object. Thus, the statements
int i = 123;
object box = i;
conceptually correspond to
int i = 123;
object box = new int_Box(i);
Boxing classes like T_Box and int_Box above don’t actually exist and the dynamic type of a boxed value isn’t actually a class type. Instead, a boxed value of type T has the dynamic type T, and a dynamic type check using the is operator can simply reference type T. For example,
int i = 123;
object box = i;
if (box is int) {
Console.Write("Box contains an int");
}
will output the string “Box contains an int” on the console.
A boxing conversion implies making a copy of the value being boxed. This is different from a conversion of a reference-type to type object, in which the value continues to reference the same instance and simply is regarded as the less derived type object. For example, given the declaration
struct Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
the following statements
Point p = new Point(10, 10);
object box = p;
p.x = 20;
Console.Write(((Point)box).x);
will output the value 10 on the console because the implicit boxing operation that occurs in the assignment of p to box causes the value of p to be copied. Had Point been declared a class instead, the value 20 would be output because p and box would reference the same instance.
4.3.2 Unboxing conversions
An unboxing conversion permits an explicit conversion from type object to any value-type or from any interface-type to any value-type that implements the interface-type. An unboxing operation consists of first checking that the object instance is a boxed value of the given value-type, and then copying the value out of the instance.
Referring to the imaginary boxing class described in the previous section, an unboxing conversion of an object box to a value-type T consists of executing the expression ((T_Box)box).value. Thus, the statements
object box = 123;
int i = (int)box;
conceptually correspond to
object box = new int_Box(123);
int i = ((int_Box)box).value;
For an unboxing conversion to a given value-type to succeed at run-time, the value of the source operand must be a reference to an object that was previously created by boxing a value of that value-type. If the source operand is null, a System.NullReferenceException is thrown; if the source operand is a reference to an incompatible object, a System.InvalidCastException is thrown.

5. Variables
Variables represent storage locations. Every variable has a type that determines what values can be stored in the variable. C# is a type-safe language, and the C# compiler guarantees that values stored in variables are always of the appropriate type. The value of a variable can be changed through assignment or through use of the ++ and operators.
A variable must be definitely assigned (§5.3) before its value can be obtained.
As described in the following sections, variables are either initially assigned or initially unassigned. An initially assigned variable has a well-defined initial value and is always considered definitely assigned. An initially unassigned variable has no initial value. For an initially unassigned variable to be considered definitely assigned at a certain location, an assignment to the variable must occur in every possible execution path leading to that location.
5.1 Variable categories
C# defines seven categories of variables: static variables, instance variables, array elements, value parameters, reference parameters, output parameters, and local variables. The sections that follow describe each of these categories.
In the example
class A
{
public static int x;
int y;
void F(int[] v, int a, ref int b, out int c) {
int i = 1;
c = a + b++;
}
}
x is a static variable, y is an instance variable, v[0] is an array element, a is a value parameter, b is a reference parameter, c is an output parameter, and i is a local variable.
5.1.1 Static variables
A field declared with the static modifier is called a static variable. A static variable comes into existence before execution of the static constructor (§10.11) for its containing type, and ceases to exist when the associated application domain ceases to exist.
The initial value of a static variable is the default value (§5.2) of the variable’s type.
For the purpose of definite assignment checking, a static variable is considered initially assigned.
5.1.2 Instance variables
A field declared without the static modifier is called an instance variable.
5.1.2.1 Instance variables in classes
An instance variable of a class comes into existence when a new instance of that class is created, and ceases to exist when there are no references to that instance and the instance’s destructor (if any) has executed.
The initial value of an instance variable of a class is the default value (§5.2) of the variable’s type.
For the purpose of definite assignment checking, an instance variable of a class is considered initially assigned.
5.1.2.2 Instance variables in structs
An instance variable of a struct has exactly the same lifetime as the struct variable to which it belongs. In other words, when a variable of a struct type comes into existence or ceases to exist, so too do the instance variables of the struct.
The initial assignment state of an instance variable of a struct is the same as that of the containing struct variable. In other words, when a struct variable is considered initially assigned, so too are its instance variables, and when a struct variable is considered initially unassigned, its instance variables are likewise unassigned.
5.1.3 Array elements
The elements of an array come into existence when an array instance is created, and cease to exist when there are no references to that array instance.
The initial value of each of the elements of an array is the default value (§5.2) of the type of the array elements.
For the purpose of definite assignment checking, an array element is considered initially assigned.
5.1.4 Value parameters
A parameter declared without a ref or out modifier is a value parameter.
A value parameter comes into existence upon invocation of the function member (§7.4) to which the parameter belongs, and is initialized with the value of the argument given in the invocation. A value parameter ceases to exist upon return of the function member.
For the purpose of definite assignment checking, a value parameter is considered initially assigned.
5.1.5 Reference parameters
A parameter declared with a ref modifier is a reference parameter.
A reference parameter does not create a new storage location. Instead, a reference parameter represents the same storage location as the variable given as the argument in the function member invocation. Thus, the value of a reference parameter is always the same as the underlying variable.
The following definite assignment rules apply to reference parameters. Note the different rules for output parameters described in §5.1.6.
• A variable must be definitely assigned (§5.3) before it can be passed as a reference parameter in a function member invocation.
• Within a function member, a reference parameter is considered initially assigned.
Within an instance method or instance accessor of a struct type, the this keyword behaves exactly as a reference parameter of the struct type (§7.5.7).
5.1.6 Output parameters
A parameter declared with an out modifier is an output parameter.
An output parameter does not create a new storage location. Instead, an output parameter represents the same storage location as the variable given as the argument in the function member invocation. Thus, the value of an output parameter is always the same as the underlying variable.
The following definite assignment rules apply to output parameters. Note the different rules for reference parameters described in §5.1.5.
• A variable need not be definitely assigned before it can be passed as an output parameter in a function member invocation.
• Following the normal completion of a function member invocation, each variable that was passed as an output parameter is considered assigned in that execution path.
• Within a function member, an output parameter is considered initially unassigned.
• Every output parameter of a function member must be definitely assigned (§5.3) before the function member returns normally.
Within an instance constructor of a struct type, the this keyword behaves exactly as an output parameter of the struct type (§7.5.7).
5.1.7 Local variables
A local variable is declared by a local-variable-declaration, which may occur in a block, a for-statement, a switch-statement, or a using-statement.
The lifetime of a local variable is the portion of program execution during which storage is guaranteed to be reserved for it. This lifetime extends from entry into the block, for-statement, switch-statement, or using-statement with which it is associated, until execution of that block, for-statement, switch-statement, or using-statement ends in any way. (Entering an enclosed block or calling a method suspends, but does not end, execution of the current block, for-statement, switch-statement, or using-statement.) If the parent block, for-statement, switch-statement, or using-statement is entered recursively, a new instance of the local variable is created each time, and its local-variable-initializer, if any, is evaluated each time.
The actual lifetime of a local variable is implementation-dependent. For example, a compiler might statically determine that a local variable in a block is only used for a small portion of that block. Using this analysis, the compiler could generate code that results in the variable’s storage having a shorter lifetime than its containing block.
A local variable is not automatically initialized and thus has no default value. For the purpose of definite assignment checking, a local variable is considered initially unassigned. A local-variable-declaration may include a local-variable-initializer, in which case the variable is considered definitely assigned in its entire scope, except within the expression provided in the local-variable-initializer.
Within the scope of a local variable, it is a compile-time error to refer to the local variable in a textual position that precedes its local-variable-declarator.
A local variable is also declared by a foreach-statement and by a specific-catch-clause for a try-statement. For a foreach-statement, the local variable is an iteration variable. For a specific-catch-clause, the local variable is an exception variable. A local variable declared by a foreach-statement or specific-catch-clause is considered definitely assigned in its entire scope.
5.2 Default values
The following categories of variables are automatically initialized to their default values:
• Static variables.
• Instance variables of class instances.
• Array elements.
The default value of a variable depends on the type of the variable and is determined as follows:
• For a variable of a value-type, the default value is the same as the value computed by the value-type’s default constructor (§4.1.1).
• For a variable of a reference-type, the default value is null.
Initialization to default values is typically done by having the memory manager or garbage collector initialize memory to all-bits-zero before it is allocated for use. For this reason, it is typically convenient for an implementation to use all-bits-zero to represent the null reference.
5.3 Definite assignment
At a given location in the executable code of a function member, a variable is said to be definitely assigned if the compiler can prove, by static flow analysis, that the variable has been automatically initialized or has been the target of at least one assignment. The rules of definite assignment are:
• An initially assigned variable (§5.3.1) is always considered definitely assigned.
• An initially unassigned variable (§5.3.2) is considered definitely assigned at a given location if all possible execution paths leading to that location contain at least one of the following:
o A simple assignment (§7.13.1) in which the variable is the left operand.
o An invocation expression (§7.5.5) or object creation expression (§7.5.10.1) that passes the variable as an output parameter.
o For a local variable, a local variable declaration (§8.5) that includes a variable initializer.
The definite assignment states of instance variables of a struct-type variable are tracked individually as well as collectively. In additional to the rules above, the following rules apply to struct-type variables and their instance variables:
• An instance variable is considered definitely assigned if its containing struct-type variable is considered definitely assigned.
• A struct-type variable is considered definitely assigned if each of its instance variables is considered definitely assigned.
Definite assignment is a requirement in the following contexts:
• A variable must be definitely assigned at each location where its value is obtained. This ensures that undefined values never occur. The occurrence of a variable in an expression is considered to obtain the value of the variable, except when
o the variable is the left operand of a simple assignment,
o the variable is passed as an output parameter, or
o the variable is a struct-type variable and occurs as the left operand of a member access.
• A variable must be definitely assigned at each location where it is passed as a reference parameter. This ensures that the function member being invoked can consider the reference parameter initially assigned.
• All output parameters of a function member must be definitely assigned at each location where the function member returns (through a return statement or through execution reaching the end of the function member body). This ensures that function members do no return undefined values in output parameters, thus enabling the compiler to consider a function member invocation that takes a variable as an output parameter equivalent to an assignment to the variable.
• The this variable of an instance constructor of a struct-type must be definitely assigned at each location where the constructor returns.
5.3.1 Initially assigned variables
The following categories of variables are classified as initially assigned:
• Static variables.
• Instance variables of class instances.
• Instance variables of initially assigned struct variables.
• Array elements.
• Value parameters.
• Reference parameters.
• Variables declared in a catch clause or a foreach statement.
5.3.2 Initially unassigned variables
The following categories of variables are classified as initially unassigned:
• Instance variables of initially unassigned struct variables.
• Output parameters, including the this variable of instance constructors for structs.
• Local variables, except those declared in a catch clause or a foreach statement.
5.3.3 Precise rules for determining definite assignment
In order to determine that each used variable is definitely assigned, the compiler must use a process that is equivalent to the one described in this section.
The compiler processes the body of each function member that has one or more initially unassigned variables. For each initially unassigned variable v, the compiler determines a definite assignment state for v at each of the following points in the function member:
• At the beginning of each statement
• At the end point (§8.1) of each statement
• On each arc which transfers control to another statement or to the end point of a statement
• At the beginning of each expression
• At the end of each expression
The definite assignment state of v can be either:
• Definitely assigned. This indicates that on all possible control flows to this point, v has been assigned a value.
• Not definitely assigned. For the state of a variable at the end of an expression of type bool, the state of a variable the isn’t definitely assigned may (but doesn’t necessarily) fall into one of the following sub-states:
o Definitely assigned after true expression. This state indicates that v is definitely assigned if the boolean expression evaluated as true, but is not necessarily assigned if the boolean expression evaluated as false.
o Definitely assigned after false expression. This state indicates that v is definitely assigned if the boolean expression evaluated as false, but is not necessarily assigned if the boolean expression evaluated as true.
The following rules govern how the state of a variable v is determined at each location.
5.3.3.1 General rules for statements
• v is not definitely assigned at the beginning of a function member body.
• v is definitely assigned at the beginning of any unreachable statement.
• The definite assignment state of v at the beginning of any other statement is determined by checking the definite assignment state of v on all control flow transfers that target the beginning of that statement. If (and only if) v is definitely assigned on all such control flow transfers, then v is definitely assigned at the beginning of the statement. The set of possible control flow transfers is determined in the same way as for checking statement reachability (§8.1).
• The definite assignment state of v at the end point of a block, checked, unchecked, if, while, do, for, foreach, lock, using, or switch statement is determined by checking the definite assignment state of v on all control flow transfers that target the end point of that statement. If v is definitely assigned on all such control flow transfers, then v is definitely assigned at the end point of the statement. Otherwise; v is not definitely assigned at the end point of the statement. The set of possible control flow transfers is determined in the same way as for checking statement reachability (§8.1).
5.3.3.2 Block statements, checked, and unchecked statements
The definite assignment state of v on the control transfer to the first statement of the statement list in the block (or to the end point of the block, if the statement list is empty) is the same as the definite assignment statement of v before the block, checked, or unchecked statement.
5.3.3.3 Expression statements
For an expression statement stmt that consists of the expression expr:
• v has the same definite assignment state at the beginning of expr as at the beginning of stmt.
• If v if definitely assigned at the end of expr, it is definitely assigned at the end point of stmt; otherwise; it is not definitely assigned at the end point of stmt.
5.3.3.4 Declaration statements
• If stmt is a declaration statement without initializers, then v has the same definite assignment state at the end point of stmt as at the beginning of stmt.
• If stmt is a declaration statement with initializers, then the definite assignment state for v is determined as if stmt were a statement list, with one assignment statement for each declaration with an initializer (in the order of declaration).
5.3.3.5 If statements
For an if statement stmt of the form:
if (expr) then-stmt else else-stmt
• v has the same definite assignment state at the beginning of expr as at the beginning of stmt.
• If v is definitely assigned at the end of expr, then it is definitely assigned on the control flow transfer to then-stmt and to either else-stmt or to the end-point of stmt if there is no else clause.
• If v has the state “definitely assigned after true expression” at the end of expr, then it is definitely assigned on the control flow transfer to then-stmt, and not definitely assigned on the control flow transfer to either else-stmt or to the end-point of stmt if there is no else clause.
• If v has the state “definitely assigned after false expression” at the end of expr, then it is definitely assigned on the control flow transfer to else-stmt, and not definitely assigned on the control flow transfer to then-stmt. It is definitely assigned at the end-point of stmt if and only if it is definitely assigned at the end-point of then-stmt.
• Otherwise, v is considered not definitely assigned on the control flow transfer to either the then-stmt or else-stmt, or to the end-point of stmt if there is no else clause.
5.3.3.6 Switch statements
In a switch statement stmt with a controlling expression expr:
• The definite assignment state of v at the beginning of expr is the same as the state of v at the beginning of stmt.
• The definite assignment state of v on the control flow transfer to a reachable switch block statement list is the same as the definite assignment state of v at the end of expr.
5.3.3.7 While statements
For a while statement stmt of the form:
while (expr) while-body
• v has the same definite assignment state at the beginning of expr as at the beginning of stmt.
• If v is definitely assigned at the end of expr, then it is definitely assigned on the control flow transfer to while-body and to the end point of stmt.
• If v has the state “definitely assigned after true expression” at the end of expr, then it is definitely assigned on the control flow transfer to while-body, but not definitely assigned at the end-point of stmt.
• If v has the state “definitely assigned after false expression” at the end of expr, then it is definitely assigned on the control flow transfer to the end point of stmt.
5.3.3.8 Do statements
For a do statement stmt of the form:
do do-body while (expr);
• v has the same definite assignment state on the control flow transfer from the beginning of stmt to do-body as at the beginning of stmt.
• v has the same definite assignment state at the beginning of expr as at the end point of do-body.
• If v is definitely assigned at the end of expr, then it is definitely assigned on the end point of stmt.
• If v has the state “definitely assigned after false expression” at the end of expr, then it is definitely assigned on the control flow transfer to the end point of stmt.
5.3.3.9 For statements
Definite assignment checking for a for statement of the form:
for (for-initializer; for-condition; for-iterator) embedded-statement
is done as if the statement were written:
{
for-initializer;
while (for-condition) {
embedded-statement;
for-iterator;
}
}
If the for-condition is omitted from the for statement, then evaluation of definite assignment proceeds as if for-condition were replaced with true in the above expansion.
5.3.3.10 Break, continue, and goto statements
The definite assignment state of v on the control flow transfer caused by a break, continue, or goto statement is the same as the definite assignment state of v at the beginning of the statement.
5.3.3.11 Throw statements
For a statement stmt of the form
throw expr ;
The definite assignment state of v at the beginning of expr is the same as the definite assignment state of v at the beginning of stmt.
5.3.3.12 Return statements
For a statement stmt of the form
return expr ;
• The definite assignment state of v at the beginning of expr is the same as the definite assignment state of v at the beginning of stmt.
• If v is an output parameter, then it must be definitely assigned either:
o after expr
o or at the end of the finally block of a try-finally or try-catch-finally that encloses the return statement.
5.3.3.13 Try-catch statements
For a statement stmt of the form:
try try-block
catch(…) catch-block-1
…
catch(…) catch-block-n
• The definite assignment state of v at the beginning of try-block is the same as the definite assignment state of v at the beginning of stmt.
• The definite assignment state of v at the beginning of catch-block-i (for any i) is the same as the definite assignment state of v at the beginning of stmt.
• The definite assignment state of v at the end-point of stmt is definitely assigned if (and only if) v is definitely assigned at the end-point of try-block and every catch-block-i (for every i from 1 to n).
5.3.3.14 Try-finally statements
For a try statement stmt of the form:
try try-block finally finally-block
• The definite assignment state of v at the beginning of try-block is the same as the definite assignment state of v at the beginning of stmt.
• The definite assignment state of v at the beginning of finally-block is the same as the definite assignment state of v at the beginning of stmt.
• The definite assignment state of v at the end-point of stmt is definitely assigned if (and only if) either:
o v is definitely assigned at the end-point of try-block
o v is definitely assigned at the end-point of finally-block
If a control flow transfer (for example, a goto statement) is made that begins within try-block, and ends outside of try-block, then v is also considered definitely assigned on that control flow transfer if v is definitely assigned at the end-point of finally-block. (This is not an only if—if v is definitely assigned for another reason on this control flow transfer, then it is still considered definitely assigned.)
5.3.3.15 Try-catch-finally statements
Definite assignment analysis for a try-catch-finally statement of the form:
try try-block
catch(…) catch-block-1
…
catch(…) catch-block-n
finally finally-block
is done as if the statement were a try-finally statement enclosing a try-catch statement:
try {
try try-block
catch(…) catch-block-1
…
catch(…) catch-block-n
}
finally finally-block
The following example demonstrates how the different blocks of a try statement (§8.10) affect definite assignment.
class A
{
static void F() {
int i, j;
try {
goto LABEL:
// neither i nor j definitely assigned
i = 1;
// i definitely assigned
}
catch {
// neither i nor j definitely assigned
i = 3;
// i definitely assigned
}
finally {
// neither i nor j definitely assigned
j = 5;
// j definitely assigned
}
// i and j definitely assigned
LABEL:
// j definitely assigned

}
}
5.3.3.16 Foreach statements
For a foreach statement stmt of the form:
foreach (type identifier in expr) embedded-statement
• The definite assignment state of v at the beginning of expr is the same as the state of v at the beginning of stmt.
• The definite assignment state of v on the control flow transfer to embedded-statement or to the end point of stmt is the same as the state of v at the end of expr.
5.3.3.17 Using statements
For a using statement stmt of the form:
using (resource-acquisition) embedded-statement
• The definite assignment state of v at the beginning of resource-acquisition is the same as the state of v at the beginning of stmt.
• The definite assignment state of v on the control flow transfer to embedded-statement is the same as the state of v at the end of resource-acquisition.
5.3.3.18 Lock statements
For a lock statement stmt of the form:
lock (expr) embedded-statement
• The definite assignment state of v at the beginning of expr is the same as the state of v at the beginning of stmt.
• The definite assignment state of v on the control flow transfer to embedded-statement is the same as the state of v at the end of expr.
5.3.3.19 General rules for simple expressions
The following rule applies to these kinds of expressions: literals (§7.5.1), simple names (§7.5.2), member access expressions (§7.5.4), non-indexed base access expressions (§7.5.8), and typeof expressions (§7.5.11).
• The definite assignment state of v at the end of such an expression is the same as the definite assignment state of v at the beginning of the expression.
5.3.3.20 General rules for expressions with embedded expressions
The following rules apply to these kinds of expressions: parenthesized expressions (§7.5.3), element access expressions (§7.5.6), base access expressions with indexing (§7.5.8), increment and decrement expressions(§7.5.9, §7.6.5), cast expressions (§7.6.6), unary +, -, ~, * expressions, binary +, -, *, /, %, <<, >>, <, <=, >, >=, ==, !=, is, as, &, |, ^ expressions (§7.7, §7.8, §7.9, §7.10), compound assignment expressions (§7.13.2), checked and unchecked expressions (§7.5.12), array and delegate creation expressions (§7.5.10).
Each of these expressions has one or more sub-expressions that are unconditionally evaluated in a fixed order. For example, the binary % operator evaluates the left hand side of the operator, then the right hand side. An indexing operation evaluates the indexed expression, and then evaluates each of the index expressions, in order from left to right. For an expression expr, which has sub-expressions expr1, expr2, ..., exprn, evaluated in that order:
• The definite assignment state of v at the beginning of expr1 is the same as the definite assignment state at the beginning of expr.
• The definite assignment state of v at the beginning of expri (i greater than one) is the same as the definite assignment state at the end of expri-1.
• The definite assignment state of v at the end of expr is the same as the definite assignment state at the end of exprn.
5.3.3.21 Invocation expressions and object creation expressions
For an invocation expression expr of the form:
primary-expression (arg1, arg2, …, argn)
or an object creation expression of the form:
new type (arg1, arg2, …, argn)
• For an invocation expression, the definite assignment state of v before primary-expression is the same as the state of v before expr.
• For an invocation expression, the definite assignment state of v before arg1 is the same as the state of v after primary-expression.
• For an object creation expression, the definite assignment state of v before arg1 is the same as the state of v before expr.
• For each argument argi, the definite assignment state of v after argi is determined by the normal expression rules, ignoring any ref or out modifiers.
• For each argument argi for any i greater than one, the definite assignment state of v before argi is the same as the state of v after argi-1.
• If the variable v is passed as an out argument (i.e., an argument of the form “out v”) in any of the arguments, then the state of v after expr is definitely assigned. Otherwise; the state of v after expr is the same as the state of v after argn.
5.3.3.22 Simple assignment expressions
For an expression expr of the form w = expr-rhs:
• The definite assignment state of v before expr-rhs is the same as the definite assignment state of v before expr.
• If w is the same variable as v, then the definite assignment state of v after expr is definitely assigned. Otherwise, the definite assignment state of v after expr is the same as the definite assignment state of v after expr-rhs.
5.3.3.23 && expressions
For an expression expr of the form expr-first && expr-second:
• The definite assignment state of v before expr-first is the same as the definite assignment state of v before expr.
• The definite assignment state of v before expr-second is definitely assigned if the state of v after expr-first is either definitely assigned or “definitely assigned after true expression”. Otherwise, it is not definitely assigned.
• The definite assignment statement of v after expr is determined by:
o If the state of v after expr-first is definitely assigned, then the state of v after expr is definitely assigned.
o Otherwise, if the state of v after expr-second is definitely assigned, and the state of v after expr-first is “definitely assigned after false expression”, then the state of v after expr is definitely assigned.
o Otherwise, if the state of v after expr-second is definitely assigned or “definitely assigned after true expression”, then the state of v after expr is “definitely assigned after true expression”.
o Otherwise, if the state of v after expr-first is “definitely assigned after false expression”, and the state of v after expr-second is “definitely assigned after false expression”, then the state of v after expr is “definitely assigned after false expression”.
o Otherwise, the state of v after expr is not definitely assigned.
In the example
class A
{
static void F(int x, int y) {
int i;
if (x >= 0 && (i = y) >= 0) {
// i definitely assigned
}
else {
// i not definitely assigned
}
// i not definitely assigned
}
}
the variable i is considered definitely assigned in one of the embedded statements of an if statement but not in the other. In the if statement in method F, the variable i is definitely assigned in the first embedded statement because execution of the expression (i = y) always precedes execution of this embedded statement. In contrast, the variable i is not definitely assigned in the second embedded statement, since x >= 0 might have tested false, resulting in the variable i's being unassigned.
5.3.3.24 || expressions
For an expression expr of the form expr-first || expr-second:
• The definite assignment state of v before expr-first is the same as the definite assignment state of v before expr.
• The definite assignment state of v before expr-second is definitely assigned if the state of v after expr-first is either definitely assigned or “definitely assigned after false expression”. Otherwise, it is not definitely assigned.
• The definite assignment statement of v after expr is determined by:
o If the state of v after expr-first is definitely assigned, then the state of v after expr is definitely assigned.
o Otherwise, if the state of v after expr-second is definitely assigned, and the state of v after expr-first is “definitely assigned after true expression”, then the state of v after expr is definitely assigned.
o Otherwise, if the state of v after expr-second is definitely assigned or “definitely assigned after false expression”, then the state of v after expr is “definitely assigned after false expression”.
o Otherwise, if the state of v after expr-first is “definitely assigned after true expression”, and the state of v after expr-second is “definitely assigned after true expression”, then the state of v after expr is “definitely assigned after true expression”.
o Otherwise, the state of v after expr is not definitely assigned.
In the example
class A
{
static void G(int x, int y) {
int i;
if (x >= 0 || (i = y) >= 0) {
// i not definitely assigned
}
else {
// i definitely assigned
}
// i not definitely assigned
}
}
the variable i is considered definitely assigned in one of the embedded statements of an if statement but not in the other. In the if statement in method G, the variable i is definitely assigned in the second embedded statement because execution of the expression (i = y) always precedes execution of this embedded statement. In contrast, the variable i is not definitely assigned in the first embedded statement, since x >= 0 might have tested false, resulting in the variable i's being unassigned.
5.3.3.25 ! expressions
For an expression expr of the form ! expr-operand:
• The definite assignment state of v before expr-operand is the same as the definite assignment state of v before expr.
• The definite assignment state of v after expr is determined by:
o If the state of v after expr-operand is definitely assigned, then the state of v after expr is definitely assigned.
o If the state of v after expr-operand is not definitely assigned, then the state of v after expr is not definitely assigned.
o If the state of v after expr-operand is “definitely assigned after false expression”, then the state of v after expr is “definitely assigned after true expression”.
o If the state of v after expr-operand is “definitely assigned after true expression”, then the state of v after expr is “definitely assigned after false expression”.
5.3.3.26 ?: expressions
For an expression expr of the form expr-cond ? expr-true : expr-false:
• The definite assignment state of v before expr-cond is the same as the state of v before expr.
• The definite assignment state of v before expr-true is definitely assigned if and only if the state of v after expr-cond is definitely assigned or “definitely assigned after true expression”.
• The definite assignment state of v before expr-false is definitely assigned if and only if the state of v after expr-cond is definitely assigned or “definitely assigned after false expression”.
5.4 Variable references
A variable-reference is an expression that is classified as a variable. A variable-reference denotes a storage location that can be accessed both to fetch the current value and to store a new value. In C and C++, a variable-reference is known as an lvalue.
variable-reference:
expression
5.5 Atomicity of variable references
Reads and writes of the following data types shall be atomic: bool, char, byte, sbyte, short, ushort, uint, int, float, and reference types. In addition, reads and writes of enum types with an underlying type in the previous list shall also be atomic. Reads and writes of other types, including long, ulong, double, and decimal, as well as user-defined types, need not be atomic. Aside from the library functions designed for that purpose, there is no guarantee of atomic read-modify-write, such as in the case of increment or decrement.

6. Conversions
A conversion enables an expression of one type to be treated as another type. Conversions can be implicit or explicit, and this determines whether an explicit cast is required. For instance, an the conversion from type int to type long is implicit, so expressions of type int can implicitly be treated as type long. The opposite conversion, from type long to type int, is explicit and so an explicit cast is required.
int a = 123;
long b = a; // implicit conversion from int to long
int c = (int) b; // explicit conversion from long to int
Some conversions are defined by the language. Programs may also define their own conversions (§6.4).
6.1 Implicit conversions
The following conversions are classified as implicit conversions:
• Identity conversions
• Implicit numeric conversions
• Implicit enumeration conversions.
• Implicit reference conversions
• Boxing conversions
• Implicit constant expression conversions
• User-defined implicit conversions
Implicit conversions can occur in a variety of situations, including function member invocations (§7.4.3), cast expressions (§7.6.6), and assignments (§7.13).
The pre-defined implicit conversions always succeed and never cause exceptions to be thrown. Properly designed user-defined implicit conversions should exhibit these characteristics as well.
6.1.1 Identity conversion
An identity conversion converts from any type to the same type. This conversion exists only such that an entity that already has a required type can be said to be convertible to that type.
6.1.2 Implicit numeric conversions
The implicit numeric conversions are:
• From sbyte to short, int, long, float, double, or decimal.
• From byte to short, ushort, int, uint, long, ulong, float, double, or decimal.
• From short to int, long, float, double, or decimal.
• From ushort to int, uint, long, ulong, float, double, or decimal.
• From int to long, float, double, or decimal.
• From uint to long, ulong, float, double, or decimal.
• From long to float, double, or decimal.
• From ulong to float, double, or decimal.
• From char to ushort, int, uint, long, ulong, float, double, or decimal.
• From float to double.
Conversions from int, uint, or long to float and from long to double may cause a loss of precision, but will never cause a loss of magnitude. The other implicit numeric conversions never lose any information.
There are no implicit conversions to the char type. This in particular means that values of the other integral types do not automatically convert to the char type.
6.1.3 Implicit enumeration conversions
An implicit enumeration conversion permits the decimal-integer-literal 0 to be converted to any enum-type.
6.1.4 Implicit reference conversions
The implicit reference conversions are:
• From any reference-type to object.
• From any class-type S to any class-type T, provided S is derived from T.
• From any class-type S to any interface-type T, provided S implements T.
• From any interface-type S to any interface-type T, provided S is derived from T.
• From an array-type S with an element type SE to an array-type T with an element type TE, provided all of the following are true:
o S and T differ only in element type. (In other words, S and T have the same number of dimensions.)
o Both SE and TE are reference-types.
o An implicit reference conversion exists from SE to TE.
• From any array-type to System.Array.
• From any delegate-type to System.Delegate.
• From any array-type or delegate-type to System.ICloneable.
• From the null type to any reference-type.
The implicit reference conversions are those conversions between reference-types that can be proven to always succeed, and therefore require no checks at run-time.
Reference conversions, implicit or explicit, never change the referential identity of the object being converted. In other words, while a reference conversion may change the type of the reference, it never changes the type or value of the object being referred to.
6.1.5 Boxing conversions
A boxing conversion permits any value-type to be implicitly converted to the type object, System.ValueType or to any interface-type implemented by the value-type. Boxing a value of a value-type consists of allocating an object instance and copying the value-type value into that instance.
Boxing conversions are described further in §4.3.1.
6.1.6 Implicit constant expression conversions
An implicit constant expression conversion permits the following conversions:
• A constant-expression (§7.15) of type int can be converted to type sbyte, byte, short, ushort, uint, or ulong, provided the value of the constant-expression is within the range of the destination type.
• A constant-expression of type long can be converted to type ulong, provided the value of the constant-expression is not negative.
6.1.7 User-defined implicit conversions
A user-defined implicit conversion consists of an optional standard implicit conversion, followed by execution of a user-defined implicit conversion operator, followed by another optional standard implicit conversion. The exact rules for evaluating user-defined conversions are described in §6.4.3.
6.2 Explicit conversions
The following conversions are classified as explicit conversions:
• All implicit conversions.
• Explicit numeric conversions.
• Explicit enumeration conversions.
• Explicit reference conversions.
• Explicit interface conversions.
• Unboxing conversions.
• User-defined explicit conversions.
Explicit conversions can occur in cast expressions (§7.6.6).
The set of explicit conversions includes all implicit conversions. This means that redundant cast expressions are allowed.
The explicit conversions are conversions that cannot be proven to always succeed, conversions that are known to possibly lose information, and conversions across domains of types sufficiently different to merit explicit notation.
6.2.1 Explicit numeric conversions
The explicit numeric conversions are the conversions from a numeric-type to another numeric-type for which an implicit numeric conversion (§6.1.2) does not already exist:
• From sbyte to byte, ushort, uint, ulong, or char.
• From byte to sbyte and char.
• From short to sbyte, byte, ushort, uint, ulong, or char.
• From ushort to sbyte, byte, short, or char.
• From int to sbyte, byte, short, ushort, uint, ulong, or char.
• From uint to sbyte, byte, short, ushort, int, or char.
• From long to sbyte, byte, short, ushort, int, uint, ulong, or char.
• From ulong to sbyte, byte, short, ushort, int, uint, long, or char.
• From char to sbyte, byte, or short.
• From float to sbyte, byte, short, ushort, int, uint, long, ulong, char, or decimal.
• From double to sbyte, byte, short, ushort, int, uint, long, ulong, char, float, or decimal.
• From decimal to sbyte, byte, short, ushort, int, uint, long, ulong, char, float, or double.
Because the explicit conversions include all implicit and explicit numeric conversions, it is always possible to convert from any numeric-type to any other numeric-type using a cast expression (§7.6.6).
The explicit numeric conversions possibly lose information or possibly cause exceptions to be thrown. An explicit numeric conversion is processed as follows:
• For a conversion from an integral type to another integral type, the processing depends on the overflow checking context (§7.5.12) in which the conversion takes place:
o In a checked context, the conversion succeeds if the value of the source operand is within the range of the destination type, but throws an System.OverflowException if the value of the source operand is outside the range of the destination type.
o In an unchecked context, the conversion always succeeds, and proceeds as follows.
• If the source type is larger than the destination type, then the source value is truncated by discarding its “extra” most significant bits. The result is then treated as a value of the destination type.
• If the source type is smaller than the destination type, then the source value is either sign-extended or zero-extended so that it is the same size as the destination type. Sign-extension is used if the source type is signed; zero-extension is used if the source type is unsigned. The result is then treated as a value of the destination type.
• If the source type is the same size as the destination type, then the source value is treated as a value of the destination type.
• For a conversion from decimal to an integral type, the source value is rounded towards zero to the nearest integral value, and this integral value becomes the result of the conversion. If the resulting integral value is outside the range of the destination type, a System.OverflowException is thrown.
• For a conversion from float or double to an integral type, the processing depends on the overflow checking context (§7.5.12) in which the conversion takes place:
o In a checked context, the conversion proceeds as follows:
• If the value of the source operand is within the range of the destination type, then it is rounded towards zero to the nearest integral value of the destination type, and this integral value is the result of the conversion.
• Otherwise, a System.OverflowException is thrown.
o In an unchecked context, the conversion always succeeds, and proceeds as follows.
• If the value of the source operand is within the range of the destination type, then it is rounded towards zero to the nearest integral value of the destination type, and this integral value is the result of the conversion.
• Otherwise, the result of the conversion is an unspecified value of the destination type.
• For a conversion from double to float, the double value is rounded to the nearest float value. If the double value is too small to represent as a float, the result becomes positive zero or negative zero. If the double value is too large to represent as a float, the result becomes positive infinity or negative infinity. If the double value is NaN, the result is also NaN.
• For a conversion from float or double to decimal, the source value is converted to decimal representation and rounded to the nearest number after the 28th decimal place if required (§4.1.6). If the source value is too small to represent as a decimal, the result becomes zero. If the source value is NaN, infinity, or too large to represent as a decimal, a System. OverflowException is thrown.
• For a conversion from decimal to float or double, the decimal value is rounded to the nearest double or float value. While this conversion may lose precision, it never causes an exception to be thrown.
6.2.2 Explicit enumeration conversions
The explicit enumeration conversions are:
• From sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, or decimal to any enum-type.
• From any enum-type to sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, or decimal.
• From any enum-type to any other enum-type.
An explicit enumeration conversion between two types is processed by treating any participating enum-type as the underlying type of that enum-type, and then performing an implicit or explicit numeric conversion between the resulting types. For example, given an enum-type E with and underlying type of int, a conversion from E to byte is processed as an explicit numeric conversion (§6.2.1) from int to byte, and a conversion from byte to E is processed as an implicit numeric conversion (§6.1.2) from byte to int.
6.2.3 Explicit reference conversions
The explicit reference conversions are:
• From object to any reference-type.
• From any class-type S to any class-type T, provided S is a base class of T.
• From any class-type S to any interface-type T, provided S is not sealed and provided S does not implement T.
• From any interface-type S to any class-type T, provided T is not sealed or provided T implements S.
• From any interface-type S to any interface-type T, provided S is not derived from T.
• From an array-type S with an element type SE to an array-type T with an element type TE, provided all of the following are true:
o S and T differ only in element type. In other words, S and T have the same number of dimensions.
o Both SE and TE are reference-types.
o An explicit reference conversion exists from SE to TE.
• From System.Array and the interfaces it implements to any array-type.
• From System.Delegate and the interfaces it implements to any delegate-type.
The explicit reference conversions are those conversions between reference-types that require run-time checks to ensure they are correct.
For an explicit reference conversion to succeed at run-time, the value of the source operand must be null, or the actual type of the object referenced by the source operand must be a type that can be converted to the destination type by an implicit reference conversion (§6.1.4). If an explicit reference conversion fails, a System.InvalidCastException is thrown.
Reference conversions, implicit or explicit, never change the referential identity of the object being converted. In other words, while a reference conversion may change the type of a value, it never changes the value itself.
6.2.4 Unboxing conversions
An unboxing conversion permits an explicit conversion from type object or System.ValueType to any value-type or from any interface-type to any value-type that implements the interface-type. An unboxing operation consists of first checking that the object instance is a boxed value of the given value-type, and then copying the value out of the instance.
Unboxing conversions are described further in §4.3.2.
6.2.5 User-defined explicit conversions
A user-defined explicit conversion consists of an optional standard explicit conversion, followed by execution of a user-defined implicit or explicit conversion operator, followed by another optional standard explicit conversion. The exact rules for evaluating user-defined conversions are described in §6.4.4.
6.3 Standard conversions
The standard conversions are those pre-defined conversions that can occur as part of a user-defined conversion.
6.3.1 Standard implicit conversions
The following implicit conversions are classified as standard implicit conversions:
• Identity conversions (§6.1.1)
• Implicit numeric conversions (§6.1.2)
• Implicit reference conversions (§6.1.4)
• Boxing conversions (§6.1.5)
• Implicit constant expression conversions (§6.1.6)
The standard implicit conversions specifically exclude user-defined implicit conversions.
6.3.2 Standard explicit conversions
The standard explicit conversions are all standard implicit conversions plus the subset of the explicit conversions for which an opposite standard implicit conversion exists. In other words, if a standard implicit conversion exists from a type A to a type B, then a standard explicit conversion exists from type A to type B and from type B to type A.
6.4 User-defined conversions
C# allows the pre-defined implicit and explicit conversions to be augmented by user-defined conversions. User-defined conversions are introduced by declaring conversion operators (§10.9.3) in class and struct types.
6.4.1 Permitted user-defined conversions
C# permits only certain user-defined conversions to be declared. In particular, it is not possible to redefine an already existing implicit or explicit conversion. A class or struct is permitted to declare a conversion from a source type S to a target type T only if all of the following are true:
• S and T are different types.
• Either S or T is the class or struct type in which the operator declaration takes place.
• Neither S nor T is object or an interface-type.
• T is not a base class of S, and S is not a base class of T.
The restrictions that apply to user-defined conversions are discussed further in §10.9.3.
6.4.2 Evaluation of user-defined conversions
A user-defined conversion converts a value from its type, called the source type, to another type, called the target type. Evaluation of a user-defined conversion centers on finding the most specific user-defined conversion operator for the particular source and target types. This determination is broken into several steps:
• Finding the set of classes and structs from which user-defined conversion operators will be considered. This set consists of the source type and its base classes and the target type and its base classes (with the implicit assumptions that only classes and structs can declare user-defined operators, and that non-class types have no base classes).
• From that set of types, determining which user-defined conversion operators are applicable. For a conversion operator to be applicable, it must be possible to perform a standard conversion (§6.3) from the source type to the operand type of the operator, and it must be possible to perform a standard conversion from the result type of the operator to the target type.
• From the set of applicable user-defined operators, determining which operator is unambiguously the most specific. In general terms, the most specific operator is the operator whose operand type is “closest” to the source type and whose result type is “closest” to the target type. The exact rules for establishing the most specific user-defined conversion operator are defined in the following sections.
Once a most specific user-defined conversion operator has been identified, the actual execution of the user-defined conversion involves up to three steps:
• First, if required, performing a standard conversion from the source type to the operand type of the user-defined conversion operator.
• Next, invoking the user-defined conversion operator to perform the conversion.
• Finally, if required, performing a standard conversion from the result type of the user-defined conversion operator to the target type.
Evaluation of a user-defined conversion never involves more than one user-defined conversion operator. In other words, a conversion from type S to type T will never first execute a user-defined conversion from S to X and then execute a user-defined conversion from X to T.
Exact definitions of evaluation of user-defined implicit or explicit conversions are given in the following sections. The definitions make use of the following terms:
• If a standard implicit conversion (§6.3.1) exists from a type A to a type B, and if neither A nor B are interface-types, then A is said to be encompassed by B, and B is said to encompass A.
• The most encompassing type in a set of types is the one type that encompasses all other types in the set. If no single type encompasses all other types, then the set has no most encompassing type. In more intuitive terms, the most encompassing type is the “largest” type in the set—the one type to which each of the other types can be implicitly converted.
• The most encompassed type in a set of types is the one type that is encompassed by all other types in the set. If no single type is encompassed by all other types, then the set has no most encompassed type. In more intuitive terms, the most encompassed type is the “smallest” type in the set—the one type that can be implicitly converted to each of the other types.
6.4.3 User-defined implicit conversions
A user-defined implicit conversion from type S to type T is processed as follows:
• Find the set of types, D, from which user-defined conversion operators will be considered. This set consists of S (if S is a class or struct), the base classes of S (if S is a class), T (if T is a class or struct), and the base classes of T (if T is a class).
• Find the set of applicable user-defined conversion operators, U. This set consists of the user-defined implicit conversion operators declared by the classes or structs in D that convert from a type encompassing S to a type encompassed by T. If U is empty, the conversion is undefined and a compile-time error occurs.
• Find the most specific source type, SX, of the operators in U:
o If any of the operators in U convert from S, then SX is S.
o Otherwise, SX is the most encompassed type in the combined set of source types of the operators in U. If no most encompassed type can be found, then the conversion is ambiguous and a compile-time error occurs.
• Find the most specific target type, TX, of the operators in U:
o If any of the operators in U convert to T, then TX is T.
o Otherwise, TX is the most encompassing type in the combined set of target types of the operators in U. If no most encompassing type can be found, then the conversion is ambiguous and a compile-time error occurs.
• If U contains exactly one user-defined conversion operator that converts from SX to TX, then this is the most specific conversion operator. If no such operator exists, or if more than one such operator exists, then the conversion is ambiguous and a compile-time error occurs. Otherwise, the user-defined conversion is applied:
o If S is not SX, then a standard implicit conversion from S to SX is performed.
o The most specific user-defined conversion operator is invoked to convert from SX to TX.
o If TX is not T, then a standard implicit conversion from TX to T is performed.
6.4.4 User-defined explicit conversions
A user-defined explicit conversion from type S to type T is processed as follows:
• Find the set of types, D, from which user-defined conversion operators will be considered. This set consists of S (if S is a class or struct), the base classes of S (if S is a class), T (if T is a class or struct), and the base classes of T (if T is a class).
• Find the set of applicable user-defined conversion operators, U. This set consists of the user-defined implicit or explicit conversion operators declared by the classes or structs in D that convert from a type encompassing or encompassed by S to a type encompassing or encompassed by T. If U is empty, the conversion is undefined and a compile-time error occurs.
• Find the most specific source type, SX, of the operators in U:
o If any of the operators in U convert from S, then SX is S.
o Otherwise, if any of the operators in U convert from types that encompass S, then SX is the most encompassed type in the combined set of source types of those operators. If no most encompassed type can be found, then the conversion is ambiguous and a compile-time error occurs.
o Otherwise, SX is the most encompassing type in the combined set of source types of the operators in U. If no most encompassing type can be found, then the conversion is ambiguous and a compile-time error occurs.
• Find the most specific target type, TX, of the operators in U:
o If any of the operators in U convert to T, then TX is T.
o Otherwise, if any of the operators in U convert to types that are encompassed by T, then TX is the most encompassing type in the combined set of source types of those operators. If no most encompassing type can be found, then the conversion is ambiguous and a compile-time error occurs.
o Otherwise, TX is the most encompassed type in the combined set of target types of the operators in U. If no most encompassed type can be found, then the conversion is ambiguous and a compile-time error occurs.
• If U contains exactly one user-defined conversion operator that converts from SX to TX, then this is the most specific conversion operator. If no such operator exists, or if more than one such operator exists, then the conversion is ambiguous and a compile-time error occurs. Otherwise, the user-defined conversion is applied:
o If S is not SX, then a standard explicit conversion from S to SX is performed.
o The most specific user-defined conversion operator is invoked to convert from SX to TX.
o If TX is not T, then a standard explicit conversion from TX to T is performed.

7. Expressions
An expression is a sequence of operators and operands that specifies computation of a value, or that designates a variable or constant. This chapter defines the syntax, order of evaluation of operands and operators, and meaning of expressions.
7.1 Expression classifications
An expression is classified as one of the following:
• A value. Every value has an associated type.
• A variable. Every variable has an associated type, namely the declared type of the variable.
• A namespace. An expression with this classification can only appear as the left hand side of a member-access (§7.5.4). In any other context, an expression classified as a namespace causes a compile-time error.
• A type. An expression with this classification can only appear as the left hand side of a member-access (§7.5.4), or as an operand for the as operator (§7.9.10), the is operator (§7.9.9), or the typeof operator (§7.5.11). In any other context, an expression classified as a type causes a compile-time error.
• A method group, which is a set of overloaded methods resulting from a member lookup (§7.3). A method group may have an associated instance expression. When an instance method is invoked, the result of evaluating the instance expression becomes the instance represented by this (§7.5.7). A method group is only permitted in an invocation-expression (§7.5.5) or a delegate-creation-expression (§7.5.10.3). In any other context, an expression classified as a method group causes a compile-time error.
• A property access. Every property access has an associated type, namely the type of the property. Furthermore, a property access may have an associated instance expression. When an accessor (the get or set block) of an instance property access is invoked, the result of evaluating the instance expression becomes the instance represented by this (§7.5.7).
• An event access. Every event access has an associated type, namely the type of the event. Furthermore, an event access may have an associated instance expression. An event access may appear as the left hand operand of the += and -= operators (§7.13.3). In any other context, an expression classified as an event access causes a compile-time error.
• An indexer access. Every indexer access has an associated type, namely the element type of the indexer. Furthermore, an indexer access has an associated instance expression and an associated argument list. When an accessor (the get or set block) of an indexer access is invoked, the result of evaluating the instance expression becomes the instance represented by this (§7.5.7), and the result of evaluating the argument list becomes the parameter list of the invocation.
• Nothing. This occurs when the expression is an invocation of a method with a return type of void. An expression classified as nothing is only valid in the context of a statement-expression (§8.6).
The final result of an expression is never a namespace, type, method group, or event access. Rather, as noted above, these categories of expressions are intermediate constructs that are only permitted in certain contexts.
A property access or indexer access is always reclassified as a value by performing an invocation of the get-accessor or the set-accessor. The particular accessor is determined by the context of the property or indexer access: If the access is the target of an assignment, the set-accessor is invoked to assign a new value (§7.13.1). Otherwise, the get-accessor is invoked to obtain the current value (§7.1.1).
7.1.1 Values of expressions
Most of the constructs that involve an expression ultimately require the expression to denote a value. In such cases, if the actual expression denotes a namespace, a type, a method group, or nothing, a compile-time error occurs. However, if the expression denotes a property access, an indexer access, or a variable, the value of the property, indexer, or variable is implicitly substituted:
• The value of a variable is simply the value currently stored in the storage location identified by the variable. A variable must be considered definitely assigned (§5.3) before its value can be obtained, or otherwise a compile-time error occurs.
• The value of a property access expression is obtained by invoking the get-accessor of the property. If the property has no get-accessor, a compile-time error occurs. Otherwise, a function member invocation (§7.4.3) is performed, and the result of the invocation becomes the value of the property access expression.
• The value of an indexer access expression is obtained by invoking the get-accessor of the indexer. If the indexer has no get-accessor, a compile-time error occurs. Otherwise, a function member invocation (§7.4.3) is performed with the argument list associated with the indexer access expression, and the result of the invocation becomes the value of the indexer access expression.
7.2 Operators
Expressions are constructed from operands and operators. The operators of an expression indicate which operations to apply to the operands. Examples of operators include +, -, *, /, and new. Examples of operands include literals, fields, local variables, and expressions.
There are three types of operators:
• Unary operators. The unary operators take one operand and use either prefix notation (such as –x) or postfix notation (such as x++).
• Binary operators. The binary operators take two operands and all use infix notation (such as x + y).
• Ternary operator. Only one ternary operator, ?:, exists. The ternary operator takes three operands and uses infix notation (c? x: y).
The order of evaluation of operators in an expression is determined by the precedence and associativity of the operators (§7.2.1).
Operands in an expression are evaluated from left to right. For example, in F(i) + G(i++) * H(i), method F is called using the old value of i, then method G is called with the old value of i, and, finally, method H is called with the new value of i. This is separate from and unrelated to operator precedence.
Certain operators can be overloaded. Operator overloading permits user-defined operator implementations to be specified for operations where one or both of the operands are of a user-defined class or struct type (§7.2.2).
7.2.1 Operator precedence and associativity
When an expression contains multiple operators, the precedence of the operators control the order in which the individual operators are evaluated. For example, the expression x + y * z is evaluated as x + (y * z) because the * operator has higher precedence than the + operator. The precedence of an operator is established by the definition of its associated grammar production. For example, an additive-expression consists of a sequence of multiplicative-expressions separated by + or - operators, thus giving the + and - operators lower precedence than the *, /, and % operators.
The following table summarizes all operators in order of precedence from highest to lowest:

Section Category Operators
7.5
Primary x.y f(x) a[x] x++ x-- new
typeof checked unchecked
7.6
Unary + - ! ~ ++x --x (T)x
7.7
Multiplicative * / %
7.7
Additive + -
7.8
Shift << >>
7.9
Relational and type testing < > <= >= is as
7.9
Equality == !=
7.10
Logical AND &
7.10
Logical XOR ^
7.10
Logical OR |
7.11
Conditional AND &&
7.11
Conditional OR ||
7.12
Conditional ?:
7.13
Assignment = *= /= %= += -= <<= >>= &= ^= |=

When an operand occurs between two operators with the same precedence, the associativity of the operators controls the order in which the operations are performed:
• Except for the assignment operators, all binary operators are left-associative, meaning that operations are performed from left to right. For example, x + y + z is evaluated as (x + y) + z.
• The assignment operators and the conditional operator (?:) are right-associative, meaning that operations are performed from right to left. For example, x = y = z is evaluated as x = (y = z).
Precedence and associativity can be controlled using parentheses. For example, x + y * z first multiplies y by z and then adds the result to x, but (x + y) * z first adds x and y and then multiplies the result by z.
7.2.2 Operator overloading
All unary and binary operators have predefined implementations that are automatically available in any expression. In addition to the predefined implementations, user-defined implementations can be introduced by including operator declarations in classes and structs (§10.9). User-defined operator implementations always take precedence over predefined operator implementations: Only when no applicable user-defined operator implementations exist will the predefined operator implementations be considered.
The overloadable unary operators are:
+ - ! ~ ++ -- true false
Although true and false are not used explicitly in expressions, they are considered operators because they are invoked in several expression contexts: boolean expressions (§7.16) and expressions involving the conditional (§7.12), and conditional logical operators (§7.11).
The overloadable binary operators are:
+ - * / % & | ^ << >> == != > < >= <=
Only the operators listed above can be overloaded. In particular, it is not possible to overload member access, method invocation, or the =, &&, ||, ?:, checked, unchecked, new, typeof, as, and is operators.
When a binary operator is overloaded, the corresponding assignment operator (if any) is also implicitly overloaded. For example, an overload of operator * is also an overload of operator *=. This is described further in §7.13. Note that the assignment operator itself (=) cannot be overloaded. An assignment always performs a simple bit-wise copy of a value into a variable.
Cast operations, such as (T)x, are overloaded by providing user-defined conversions (§6.4).
Element access, such as a[x], is not considered an overloadable operator. Instead, user-defined indexing is supported through indexers (§10.8).
In expressions, operators are referenced using operator notation, and in declarations, operators are referenced using functional notation. The following table shows the relationship between operator and functional notations for unary and binary operators. In the first entry, op denotes any overloadable unary prefix operator. In the second entry, op denotes the unary postfix ++ and -- operators. In the third entry, op denotes any overloadable binary operator.

Operator notation Functional notation
op x operator op(x)
x op operator op(x)
x op y operator op(x, y)

User-defined operator declarations always require at least one of the parameters to be of the class or struct type that contains the operator declaration. Thus, it is not possible for a user-defined operator to have the same signature as a predefined operator.
User-defined operator declarations cannot modify the syntax, precedence, or associativity of an operator. For example, the / operator is always a binary operator, always has the precedence level specified in §7.2.1, and is always left-associative.
While it is possible for a user-defined operator to perform any computation it pleases, implementations that produce results other than those that are intuitively expected are strongly discouraged. For example, an implementation of operator == should compare the two operands for equality and return an appropriate result.
The descriptions of individual operators in §7.5 through §7.13 specify the predefined implementations of the operators and any additional rules that apply to each operator. The descriptions make use of the terms unary operator overload resolution, binary operator overload resolution, and numeric promotion, definitions of which are found in the following sections.
7.2.3 Unary operator overload resolution
An operation of the form op x or x op, where op is an overloadable unary operator, and x is an expression of type X, is processed as follows:
• The set of candidate user-defined operators provided by X for the operation operator op(x) is determined using the rules of §7.2.5.
• If the set is not empty, then this becomes the set of candidate operators for the operation. Otherwise, the predefined unary operator op implementations become the set of candidate operators for the operation. The predefined implementations of a given operator are specified in the description of the operator (§7.5 and §7.6).
• The overload resolution rules of §7.4.2 are applied to the set of candidate operators to select the best operator with respect to the argument list (x), and this operator becomes the result of the overload resolution process. If overload resolution fails to select a single best operator, a compile-time error occurs.
7.2.4 Binary operator overload resolution
An operation of the form x op y, where op is an overloadable binary operator, x is an expression of type X, and y is an expression of type Y, is processed as follows:
• The set of candidate user-defined operators provided by X and Y for the operation operator op(x, y) is determined. The set consists of the union of the candidate operators provided by X and the candidate operators provided by Y, each determined using the rules of §7.2.5. If X and Y are the same type, or if X and Y are derived from a common base type, then shared candidate operators only occur in the combined set once.
• If the set is not empty, then this becomes the set of candidate operators for the operation. Otherwise, the predefined binary operator op implementations become the set of candidate operators for the operation. The predefined implementations of a given operator are specified in the description of the operator (§7.7 through §7.13).
• The overload resolution rules of §7.4.2 are applied to the set of candidate operators to select the best operator with respect to the argument list (x, y), and this operator becomes the result of the overload resolution process. If overload resolution fails to select a single best operator, a compile-time error occurs.
7.2.5 Candidate user-defined operators
Given a type T and an operation operator op(A), where op is an overloadable operator and A is an argument list, the set of candidate user-defined operators provided by T for operator op(A) is determined as follows:
• For all operator op declarations in T, if at least one operator is applicable (§7.4.2.1) with respect to the argument list A, then the set of candidate operators consists of all applicable operator op declarations in T.
• Otherwise, if T is object, the set of candidate operators is empty.
• Otherwise, the set of candidate operators provided by T is the set of candidate operators provided by the direct base class of T.
7.2.6 Numeric promotions
Numeric promotion consists of automatically performing certain implicit conversions of the operands of the predefined unary and binary numeric operators. Numeric promotion is not a distinct mechanism, but rather an effect of applying overload resolution to the predefined operators. Numeric promotion specifically does not affect evaluation of user-defined operators, although user-defined operators can be implemented to exhibit similar effects.
As an example of numeric promotion, consider the predefined implementations of the binary * operator:
int operator *(int x, int y);
uint operator *(uint x, uint y);
long operator *(long x, long y);
ulong operator *(ulong x, ulong y);
float operator *(float x, float y);
double operator *(double x, double y);
decimal operator *(decimal x, decimal y);
When overload resolution rules (§7.4.2) are applied to this set of operators, the effect is to select the first of the operators for which implicit conversions exist from the operand types. For example, for the operation b * s, where b is a byte and s is a short, overload resolution selects operator *(int, int) as the best operator. Thus, the effect is that b and s are converted to int, and the type of the result is int. Likewise, for the operation i * d, where i is an int and d is a double, overload resolution selects operator *(double, double) as the best operator.
7.2.6.1 Unary numeric promotions
Unary numeric promotion occurs for the operands of the predefined +, –, and ~ unary operators. Unary numeric promotion simply consists of converting operands of type sbyte, byte, short, ushort, or char to type int. Additionally, for the unary – operator, unary numeric promotion converts operands of type uint to type long.
7.2.6.2 Binary numeric promotions
Binary numeric promotion occurs for the operands of the predefined +, –, *, /, %, &, |, ^, ==, !=, >, <, >=, and <= binary operators. Binary numeric promotion implicitly converts both operands to a common type which, in case of the non-relational operators, also becomes the result type of the operation. Binary numeric promotion consists of applying the following rules, in the order they appear here:
• If either operand is of type decimal, the other operand is converted to type decimal, or a compile-time error occurs if the other operand is of type float or double.
• Otherwise, if either operand is of type double, the other operand is converted to type double.
• Otherwise, if either operand is of type float, the other operand is converted to type float.
• Otherwise, if either operand is of type ulong, the other operand is converted to type ulong, or a compile-time error occurs if the other operand is of type sbyte, short, int, or long.
• Otherwise, if either operand is of type long, the other operand is converted to type long.
• Otherwise, if either operand is of type uint and the other operand is of type sbyte, short, or int, both operands are converted to type long.
• Otherwise, if either operand is of type uint, the other operand is converted to type uint.
• Otherwise, both operands are converted to type int.
Note that the first rule disallows any operations that mix the decimal type with the double and float types. The rule follows from the fact that there are no implicit conversions between the decimal type and the double and float types.
Also note that it is not possible for an operand to be of type ulong when the other operand is of a signed integral type. The reason is that no integral type exists that can represent the full range of ulong as well as the signed integral types.
In both of the above cases, a cast expression can be used to explicitly convert one operand to a type that is compatible with the other operand.
In the example
decimal AddPercent(decimal x, double percent) {
return x * (1.0 + percent / 100.0);
}
a compile-time error occurs because a decimal cannot be multiplied by a double. The error is resolved by explicitly converting the second operand to decimal:
decimal AddPercent(decimal x, double percent) {
return x * (decimal)(1.0 + percent / 100.0);
}
7.3 Member lookup
A member lookup is the process whereby the meaning of a name in the context of a type is determined. A member lookup may occur as part of evaluating a simple-name (§7.5.2) or a member-access (§7.5.4) in an expression.
A member lookup of a name N in a type T is processed as follows:
• First, the set of all accessible (§3.5) members named N declared in T and the base types (§7.3.1) of T is constructed. Declarations that include an override modifier are excluded from the set. If no members named N exist and are accessible, then the lookup produces no match, and the following steps are not evaluated.
• Next, members that are hidden by other members are removed from the set. For every member S.M in the set, where S is the type in which the member M is declared, the following rules are applied:
o If M is a constant, field, property, event, type, or enumeration member, then all members declared in a base type of S are removed from the set.
o If M is a method, then all non-method members declared in a base type of S are removed from the set, and all methods with the same signature as M declared in a base type of S are removed from the set.
• Finally, having removed hidden members, the result of the lookup is determined:
o If the set consists of a single non-method member, then this member is the result of the lookup.
o Otherwise, if the set contains only methods, then this group of methods is the result of the lookup.
o Otherwise, the lookup is ambiguous, and a compile-time error occurs (this situation can only occur for a member lookup in an interface that has multiple direct base interfaces).
For member lookups in types other than interfaces, and member lookups in interfaces that are strictly single-inheritance (each interface in the inheritance chain has exactly zero or one direct base interface), the effect of the lookup rules is simply that derived members hide base members with the same name or signature. Such single-inheritance lookups are never ambiguous. The ambiguities that can possibly arise from member lookups in multiple-inheritance interfaces are described in §13.2.5.
7.3.1 Base types
For purposes of member lookup, a type T is considered to have the following base types:
• If T is object, then T has no base type.
• If T is a value-type, the base type of T is the class type object.
• If T is a class-type, the base types of T are the base classes of T, including the class type object.
• If T is an interface-type, the base types of T are the base interfaces of T and the class type object.
• If T is an array-type, the base types of T are the class types System.Array and object.
• If T is a delegate-type, the base types of T are the class types System.Delegate and object.
7.4 Function members
Function members are members that contain executable statements. Function members are always members of types and cannot be members of namespaces. C# defines the following categories of function members:
• Methods
• Properties
• Events
• Indexers
• User-defined operators
• Instance constructors
• Static constructors
• Destructors
Except for static constructors and destructors (which cannot be invoked explicitly), the statements contained in function members are executed through function member invocations. The actual syntax for writing a function member invocation depends on the particular function member category.
The argument list (§7.4.1) of a function member invocation provides actual values or variable references for the parameters of the function member.
Invocations of methods, indexers, operators and instance constructors employ overload resolution to determine which of a candidate set of function members to invoke. This process is described in §7.4.2.
Once a particular function member has been identified at compile-time, possibly through overload resolution, the actual run-time process of invoking the function member is described in §7.4.3.
The following table summarizes the processing that takes place in constructs involving the six categories of function members that can be explicitly invoked. In the table, e, x, y, and value indicate expressions classified as variables or values, T indicates an expression classified as a type, F is the simple name of a method, and P is the simple name of a property.

Construct Example Description
Method invocation F(x, y) Overload resolution is applied to select the best method F in the containing class or struct. The method is invoked with the argument list (x, y). If the method is not static, the instance expression is this.
T.F(x, y) Overload resolution is applied to select the best method F in the class or struct T. A compile-time error occurs if the method is not static. The method is invoked with the argument list (x, y).
e.F(x, y) Overload resolution is applied to select the best method F in the class, struct, or interface given by the type of e. A compile-time error occurs if the method is static. The method is invoked with the instance expression e and the argument list (x, y).
Property access P The get accessor of the property P in the containing class or struct is invoked. A compile-time error occurs if P is write-only. If P is not static, the instance expression is this.
P = value The set accessor of the property P in the containing class or struct is invoked with the argument list (value). A compile-time error occurs if P is read-only. If P is not static, the instance expression is this.
T.P The get accessor of the property P in the class or struct T is invoked. A compile-time error occurs if P is not static or if P is write-only.
T.P = value The set accessor of the property P in the class or struct T is invoked with the argument list (value). A compile-time error occurs if P is not static or if P is read-only.
e.P The get accessor of the property P in the class, struct, or interface given by the type of e is invoked with the instance expression e. A compile-time error occurs if P is static or if P is write-only.
e.P = value The set accessor of the property P in the class, struct, or interface given by the type of e is invoked with the instance expression e and the argument list (value). A compile-time error occurs if P is static or if P is read-only.
Event access E += value The add accessor of the event E in the containing class or struct is invoked. If E is not static, the instance expression is this.
E -= value The remove accessor of the event E in the containing class or struct is invoked. If E is not static, the instance expression is this.
T.E += value The add accessor of the event E in the class or struct T is invoked. A compile-time error occurs if E is not static.
T.E -= value The remove accessor of the event E in the class or struct T is invoked. A compile-time error occurs if E is not static.
e.E += value The add accessor of the event E in the class, struct, or interface given by the type of e is invoked with the instance expression e. A compile-time error occurs if E is static.
e.E -= value The remove accessor of the event E in the class, struct, or interface given by the type of e is invoked with the instance expression e. A compile-time error occurs if E is static.
Indexer access e[x, y] Overload resolution is applied to select the best indexer in the class, struct, or interface given by the type of e. The get accessor of the indexer is invoked with the instance expression e and the argument list (x, y). A compile-time error occurs if the indexer is write-only.
e[x, y] = value Overload resolution is applied to select the best indexer in the class, struct, or interface given by the type of e. The set accessor of the indexer is invoked with the instance expression e and the argument list (x, y, value). A compile-time error occurs if the indexer is read-only.
Operator invocation -x Overload resolution is applied to select the best unary operator in the class or struct given by the type of x. The selected operator is invoked with the argument list (x).
x + y Overload resolution is applied to select the best binary operator in the classes or structs given by the types of x and y. The selected operator is invoked with the argument list (x, y).
Constructor invocation new T(x, y) Overload resolution is applied to select the best constructor in the class or struct T. The constructor is invoked with the argument list (x, y).

7.4.1 Argument lists
Every function member invocation includes an argument list which provides actual values or variable references for the parameters of the function member. The syntax for specifying the argument list of a function member invocation depends on the function member category:
• For methods, instance constructors, and delegates, the arguments are specified as an argument-list, as described below.
• For properties, the argument list is empty when invoking the get accessor, and consists of the expression specified as the right operand of the assignment operator when invoking the set accessor.
• For events, the argument list consists of the expression specified as the right operand of the += or -= operator.
• For indexers, the argument list consists of the expressions specified between the square brackets in the indexer access. When invoking the set accessor, the argument list additionally includes the expression specified as the right operand of the assignment operator.
• For user-defined operators, the argument list consists of the single operand of the unary operator or the two operands of the binary operator.
The arguments properties (§10.6), events (§10.7), indexers (§10.8), and user-defined operators (§10.9) are always passed as value parameters (§10.5.1.1). Reference and output parameters are not supported for these categories of function members.
The arguments of a method, instance constructor, or delegate invocation are specified as an argument-list:
argument-list:
argument
argument-list , argument
argument:
expression
ref variable-reference
out variable-reference
An argument-list consists of one or more arguments, separated by commas. Each argument can take one of the following forms:
• An expression, indicating that the argument is passed as a value parameter (§10.5.1.1).
• The keyword ref followed by a variable-reference (§5.3.3), indicating that the argument is passed as a reference parameter (§10.5.1.2). A variable must be definitely assigned (§5.3) before it can be passed as a reference parameter. A volatile field (§10.4.3) cannot be passed as a reference parameter.
• The keyword out followed by a variable-reference (§5.3.3), indicating that the argument is passed as an output parameter (§10.5.1.3). A variable is considered definitely assigned (§5.3) following a function member invocation in which the variable is passed as an output parameter. A volatile field (§10.4.3) cannot be passed as an output parameter.
During the run-time processing of a function member invocation (§7.4.3), the expressions or variable references of an argument list are evaluated in order, from left to right, as follows:
• For a value parameter, the argument expression is evaluated and an implicit conversion (§6.1) to the corresponding parameter type is performed. The resulting value becomes the initial value of the value parameter in the function member invocation.
• For a reference or output parameter, the variable reference is evaluated and the resulting storage location becomes the storage location represented by the parameter in the function member invocation. If the variable reference given as a reference or output parameter is an array element of a reference-type, a run-time check is performed to ensure that the element type of the array is identical to the type of the parameter. If this check fails, a System.ArrayTypeMismatchException is thrown.
Methods, indexers, and instance constructors may declare their right-most parameter to be a parameter array (§10.5.1.4). Such function members are invoked either in their normal form or in their expanded form depending on which is applicable (§7.4.2.1):
• When a function member with a parameter array is invoked in its normal form, the argument given for the parameter array must be a single expression of a type that is implicitly convertible (§6.1) to the parameter array type. In this case, the parameter array acts precisely like a value parameter.
• When a function member with a parameter array is invoked in its expanded form, the invocation must specify zero or more arguments for the parameter array, where each argument is an expression of a type that is implicitly convertible (§6.1) to the element type of the parameter array. In this case, the invocation creates an instance of the parameter array type with a length corresponding to the number of arguments, initializes the elements of the array instance with the given argument values, and uses the newly created array instance as the actual argument.
The expressions of an argument list are always evaluated in the order they are written. Thus, the example
class Test
{
static void F(int x, int y, int z) {
System.Console.WriteLine("x = {0}, y = {1}, z = {2}", x, y, z);
}
static void Main() {
int i = 0;
F(i++, i++, i++);
}
}
produces the output
x = 0, y = 1, z = 2
The array co-variance rules (§12.5) permit a value of an array type A[] to be a reference to an instance of an array type B[], provided an implicit reference conversion exists from B to A. Because of these rules, when an array element of a reference-type is passed as a reference or output parameter, a run-time check is required to ensure that the actual element type of the array is identical to that of the parameter. In the example
class Test
{
static void F(ref object x) {...}
static void Main() {
object[] a = new object[10];
object[] b = new string[10];
F(ref a[0]); // Ok
F(ref b[1]); // ArrayTypeMismatchException
}
}
the second invocation of F causes a System.ArrayTypeMismatchException to be thrown because the actual element type of b is string and not object.
When a function member with a parameter array is invoked in its expanded form, the invocation is processed exactly as if an array creation expression with an array initializer (§7.5.10.2) was inserted around the expanded parameters. For example, given the declaration
void F(int x, int y, params object[] args);
the following invocations of the expanded form of the method
F(10, 20);
F(10, 20, 30, 40);
F(10, 20, 1, "hello", 3.0);
correspond exactly to
F(10, 20, new object[] {});
F(10, 20, new object[] {30, 40});
F(10, 20, new object[] {1, "hello", 3.0});
Note in particular that an empty array is created when there are zero arguments given for the parameter array.
7.4.2 Overload resolution
Overload resolution is a compile-time mechanism for selecting the best function member to invoke given an argument list and a set of candidate function members. Overload resolution selects the function member to invoke in the following distinct contexts within C#:
• Invocation of a method named in an invocation-expression (§7.5.5).
• Invocation of an instance constructor named in an object-creation-expression (§7.5.10.1).
• Invocation of an indexer accessor through an element-access (§7.5.6).
• Invocation of a predefined or user-defined operator referenced in an expression (§7.2.3 and §7.2.4).
Each of these contexts defines the set of candidate function members and the list of arguments in its own unique way, as described in detail in the sections listed above. For example, the set of candidates for a method invocation does not include methods marked override (§7.3), and methods in a base class are not candidates if any method in a derived class is applicable (§7.5.5.1).
Once the candidate function members and the argument list have been identified, the selection of the best function member is the same in all cases:
• Given the set of applicable candidate function members, the best function member in that set is located. If the set contains only one function member, then that function member is the best function member. Otherwise, the best function member is the one function member that is better than all other function members with respect to the given argument list, provided that each function member is compared to all other function members using the rules in §7.4.2.2. If there is not exactly one function member that is better than all other function members, then the function member invocation is ambiguous and a compile-time error occurs.
The following sections define the exact meanings of the terms applicable function member and better function member.
7.4.2.1 Applicable function member
A function member is said to be an applicable function member with respect to an argument list A when all of the following are true:
• The number of arguments in A is identical to the number of parameters in the function member declaration.
• For each argument in A, the parameter passing mode of the argument (i.e., value, ref, or out) is identical to the parameter passing mode of the corresponding parameter, and
o for a value parameter or a parameter array, an implicit conversion (§6.1) exists from the type of the argument to the type of the corresponding parameter, or
o for a ref or out parameter, the type of the argument is identical to the type of the corresponding parameter.
For a function member that includes a parameter array, if the function member is applicable by the above rules, it is said to be applicable in its normal form. If a function member that includes a parameter array is not applicable in its normal form, the function member may instead be applicable in its expanded form:
• The expanded form is constructed by replacing the parameter array in the function member declaration with zero or more value parameters of the element type of the parameter array such that the number of arguments in the argument list A matches the total number of parameters. If A has fewer arguments than the number of fixed parameters in the function member declaration, the expanded form of the function member cannot be constructed and is thus not applicable.
• If the class, struct, or interface in which the function member is declared already contains another applicable function member with the same signature as the expanded form, the expanded form is not applicable.
• Otherwise, the expanded form is applicable if for each argument in A the parameter passing mode of the argument is identical to the parameter passing mode of the corresponding parameter, and
o for a fixed value parameter or a value parameter created by the expansion, an implicit conversion (§6.1) exists from the type of the argument to the type of the corresponding parameter, or
o for a ref or out parameter, the type of the argument is identical to the type of the corresponding parameter.
7.4.2.2 Better function member
Given an argument list A with a set of argument types A1, A2, ..., AN and two applicable function members MP and MQ with parameter types P1, P2, ..., PN and Q1, Q2, ..., QN, MP is defined to be a better function member than MQ if
• for each argument, the implicit conversion from AX to PX is not worse than the implicit conversion from AX to QX, and
• for at least one argument, the conversion from AX to PX is better than the conversion from AX to QX.
When performing this evaluation, if MP or MQ is applicable in its expanded form, then PX or QX refers to a parameter in the expanded form of the parameter list.
7.4.2.3 Better conversion
Given an implicit conversion C1 that converts from a type S to a type T1, and an implicit conversion C2 that converts from a type S to a type T2, the better conversion of the two conversions is determined as follows:
• If T1 and T2 are the same type, neither conversion is better.
• If S is T1, C1 is the better conversion.
• If S is T2, C2 is the better conversion.
• If an implicit conversion from T1 to T2 exists, and no implicit conversion from T2 to T1 exists, C1 is the better conversion.
• If an implicit conversion from T2 to T1 exists, and no implicit conversion from T1 to T2 exists, C2 is the better conversion.
• If T1 is sbyte and T2 is byte, ushort, uint, or ulong, C1 is the better conversion.
• If T2 is sbyte and T1 is byte, ushort, uint, or ulong, C2 is the better conversion.
• If T1 is short and T2 is ushort, uint, or ulong, C1 is the better conversion.
• If T2 is short and T1 is ushort, uint, or ulong, C2 is the better conversion.
• If T1 is int and T2 is uint, or ulong, C1 is the better conversion.
• If T2 is int and T1 is uint, or ulong, C2 is the better conversion.
• If T1 is long and T2 is ulong, C1 is the better conversion.
• If T2 is long and T1 is ulong, C2 is the better conversion.
• Otherwise, neither conversion is better.
If an implicit conversion C1 is defined by these rules to be a better conversion than an implicit conversion C2, then it is also the case that C2 is a worse conversion than C1.
7.4.3 Function member invocation
This section describes the process that takes place at run-time to invoke a particular function member. It is assumed that a compile-time process has already determined the particular member to invoke, possibly by applying overload resolution to a set of candidate function members.
For purposes of describing the invocation process, function members are divided into two categories:
• Static function members. These are instance constructors, static methods, static property accessors, and user-defined operators. Static function members are always non-virtual.
• Instance function members. These are instance methods, instance property accessors, and indexer accessors. Instance function members are either non-virtual or virtual, and are always invoked on a particular instance. The instance is computed by an instance expression, and it becomes accessible within the function member as this (§7.5.7).
The run-time processing of a function member invocation consists of the following steps, where M is the function member and, if M is an instance member, E is the instance expression:
• If M is a static function member:
o The argument list is evaluated as described in §7.4.1.
o M is invoked.
• If M is an instance function member declared in a value-type:
o E is evaluated. If this evaluation causes an exception, then no further steps are executed.
o If E is not classified as a variable, then a temporary local variable of E’s type is created and the value of E is assigned to that variable. E is then reclassified as a reference to that temporary local variable. The temporary variable is accessible as this within M, but not in any other way. Thus, only when E is a true variable is it possible for the caller to observe the changes that M makes to this.
o The argument list is evaluated as described in §7.4.1.
o M is invoked. The variable referenced by E becomes the variable referenced by this.
• If M is an instance function member declared in a reference-type:
o E is evaluated. If this evaluation causes an exception, then no further steps are executed.
o The argument list is evaluated as described in §7.4.1.
o If the type of E is a value-type, a boxing conversion (§4.3.1) is performed to convert E to type object, and E is considered to be of type object in the following steps.
o The value of E is checked to be valid. If the value of E is null, a System.NullReferenceException is thrown and no further steps are executed.
o The function member implementation to invoke is determined:
• If the compile-time type of E is an interface, the function member to invoke is the implementation of M provided by the run-time type of the instance referenced by E. This function member is determined by applying the interface mapping rules (§13.4.2) to determine the implementation of M provided by the run-time type of the instance referenced by E.
• Otherwise, if M is a virtual function member, the function member to invoke is the implementation of M provided by the run-time type of the instance referenced by E. This function member is determined by applying the rules for determining the most derived implementation (§10.5.3) of M with respect to the run-time type of the instance referenced by E.
• Otherwise, M is a non-virtual function member, and the function member to invoke is M itself.
o The function member implementation determined in the step above is invoked. The object referenced by E becomes the object referenced by this.
7.4.3.1 Invocations on boxed instances
A function member implemented in a value-type can be invoked through a boxed instance of that value-type in the following situations:
• When the function member is an override of a method inherited from type object and is invoked through an instance expression of type object.
• When the function member is an implementation of an interface function member and is invoked through an instance expression of an interface-type.
• When the function member is invoked through a delegate.
In these situations, the boxed instance is considered to contain a variable of the value-type, and this variable becomes the variable referenced by this within the function member invocation. This in particular means that when a function member is invoked on a boxed instance, it is possible for the function member to modify the value contained in the boxed instance.
7.5 Primary expressions
Primary expressions include the simplest forms of expressions.
primary-expression:
primary-no-array-creation-expression
array-creation-expression
primary-no-array-creation-expression:
literal
simple-name
parenthesized-expression
member-access
invocation-expression
element-access
this-access
base-access
post-increment-expression
post-decrement-expression
object-creation-expression
delegate-creation-expression
typeof-expression
sizeof-expression
checked-expression
unchecked-expression
Primary expressions are divided between array-creation-expressions and primary-no-array-creation-expressions. Treating array-creation-expression in this way, rather than listing it along with the other simple expression forms, enables the grammar to disallow potentially confusing code such as
object o = new int[3][1];
which would otherwise be interpreted as
object o = (new int[3])[1];
7.5.1 Literals
A primary-expression that consists of a literal (§2.4.4) is classified as a value.
7.5.2 Simple names
A simple-name consists of a single identifier.
simple-name:
identifier
A simple-name is evaluated and classified as follows:
• If the simple-name appears within a block and if the block contains a local variable or parameter with the given name, then the simple-name refers to that local variable or parameter and is classified as a variable.
• Otherwise, for each type T, starting with the immediately enclosing class, struct, or enumeration declaration and continuing with each enclosing outer class or struct declaration (if any), if a member lookup of the simple-name in T produces a match:
o If T is the immediately enclosing class or struct type and the lookup identifies one or more methods, the result is a method group with an associated instance expression of this.
o If T is the immediately enclosing class or struct type, if the lookup identifies an instance member, and if the reference occurs within the block of an instance method, an instance accessor, or an instance constructor, the result is the same as a member access (§7.5.4) of the form this.E, where E is the simple-name.
o Otherwise, the result is the same as a member access (§7.5.4) of the form T.E, where E is the simple-name. In this case, it is a compile-time error for the simple-name to refer to an instance member.
• Otherwise, starting with the namespace in which the simple-name occurs, continuing with each enclosing namespace (if any), and ending with the global namespace, the following steps are evaluated until an entity is located:
o If the namespace contains a namespace member with the given name, then the simple-name refers to that member and, depending on the member, is classified as a namespace or a type.
o Otherwise, if the namespace has a corresponding namespace declaration enclosing the location where the simple-name occurs, then:
• If the namespace declaration contains a using-alias-directive that associates the given name with an imported namespace or type, then the simple-name refers to that namespace or type.
• Otherwise, if the namespaces imported by the using-namespace-directives of the namespace declaration contain exactly one type with the given name, then the simple-name refers to that type.
• Otherwise, if the namespaces imported by the using-namespace-directives of the namespace declaration contain more than one type with the given name, then the simple-name is ambiguous and a compile-time error occurs.
• Otherwise, the name given by the simple-name is undefined and a compile-time error occurs.
7.5.2.1 Invariant meaning in blocks
For each occurrence of a given identifier as a simple-name in an expression, every other occurrence of the same identifier as a simple-name in an expression within the immediately enclosing block (§8.2) or switch-block (§8.7.2) must refer to the same entity. This rule ensures that the meaning of a name in the context of an expression is always the same within a block.
The example
class Test
{
double x;
void F(bool b) {
x = 1.0;
if (b) {
int x = 1;
}
}
}
results in a compile-time error because x refers to different entities within the outer block (the extent of which includes the nested block in the if statement). In contrast, the example
class Test
{
double x;
void F(bool b) {
if (b) {
x = 1.0;
}
else {
int x = 1;
}
}
}
is permitted because the name x is never used in the outer block.
Note that the rule of invariant meaning applies only to simple names. It is perfectly valid for the same identifier to have one meaning as a simple name and another meaning as right operand of a member access (§7.5.4). For example:
struct Point
{
int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
The example above illustrates a common pattern of using the names of fields as parameter names in an instance constructor. In the example, the simple names x and y refer to the parameters, but that does not prevent the member access expressions this.x and this.y from accessing the fields.
7.5.3 Parenthesized expressions
A parenthesized-expression consists of an expression enclosed in parentheses.
parenthesized-expression:
( expression )
A parenthesized-expression is evaluated by evaluating the expression within the parentheses. If the expression within the parentheses denotes a namespace, type, or method group, a compile-time error occurs. Otherwise, the result of the parenthesized-expression is the result of the evaluation of the contained expression.
7.5.4 Member access
A member-access consists of a primary-expression or a predefined-type, followed by a “.” token, followed by an identifier.
member-access:
primary-expression . identifier
predefined-type . identifier
predefined-type: one of
bool byte char decimal double float int long
object sbyte short string uint ulong ushort
A member-access of the form E.I, where E is a primary-expression or a predefined-type and I is an identifier, is evaluated and classified as follows:
• If E is a namespace and I is the name of an accessible member of that namespace, then the result is that member and, depending on the member, is classified as a namespace or a type.
• If E is a predefined-type or a primary-expression classified as a type, and a member lookup (§7.3) of I in E produces a match, then E.I is evaluated and classified as follows:
o If I identifies a type, then the result is that type.
o If I identifies one or more methods, then the result is a method group with no associated instance expression.
o If I identifies a static property, then the result is a property access with no associated instance expression.
o If I identifies a static field:
• If the field is readonly and the reference occurs outside the static constructor of the class or struct in which the field is declared, then the result is a value, namely the value of the static field I in E.
• Otherwise, the result is a variable, namely the static field I in E.
o If I identifies a static event:
• If the reference occurs within the class or struct in which the event is declared, and the event was declared without event-accessor-declarations (§10.7), then E.I is processed exactly as if I was a static field.
• Otherwise, the result is an event access with no associated instance expression.
o If I identifies a constant, then the result is a value, namely the value of that constant.
o If I identifies an enumeration member, then the result is a value, namely the value of that enumeration member.
o Otherwise, E.I is an invalid member reference, and a compile-time error occurs.
• If E is a property access, indexer access, variable, or value, the type of which is T, and a member lookup (§7.3) of I in T produces a match, then E.I is evaluated and classified as follows:
o First, if E is a property or indexer access, then the value of the property or indexer access is obtained (§7.1.1) and E is reclassified as a value.
o If I identifies one or more methods, then the result is a method group with an associated instance expression of E.
o If I identifies an instance property, then the result is a property access with an associated instance expression of E.
o If T is a class-type and I identifies an instance field of that class-type:
• If the value of E is null, then a System.NullReferenceException is thrown.
• Otherwise, if the field is readonly and the reference occurs outside an instance constructor of the class in which the field is declared, then the result is a value, namely the value of the field I in the object referenced by E.
• Otherwise, the result is a variable, namely the field I in the object referenced by E.
o If T is a struct-type and I identifies an instance field of that struct-type:
• If E is a value, or if the field is readonly and the reference occurs outside an instance constructor of the struct in which the field is declared, then the result is a value, namely the value of the field I in the struct instance given by E.
• Otherwise, the result is a variable, namely the field I in the struct instance given by E.
o If I identifies an instance event:
• If the reference occurs within the class or struct in which the event is declared, and the event was declared without event-accessor-declarations (§10.7), then E.I is processed exactly as if I was an instance field.
• Otherwise, the result is an event access with an associated instance expression of E.
• Otherwise, E.I is an invalid member reference, and a compile-time error occurs.
7.5.4.1 Identical simple names and type names
In a member access of the form E.I, if E is a single identifier, and if the meaning of E as a simple-name (§7.5.2) is a constant, field, property, local variable, or parameter with the same type as the meaning of E as a type-name (§3.8), then both possible meanings of E are permitted. The two possible meanings of E.I are never ambiguous, since I must necessarily be a member of the type E in both cases. In other words, the rule simply permits access to the static members and nested types of E where a compile-time error would otherwise have occurred. For example:
struct Color
{
public static readonly Color White = new Color(...);
public static readonly Color Black = new Color(...);
public Color Complement() {...}
}
class A
{
public Color Color; // Field Color of type Color
void F() {
Color = Color.Black; // References Color.Black static member
Color = Color.Complement(); // Invokes Complement() on Color field
}
static void G() {
Color c = Color.White; // References Color.White static member
}
}
Within the A class, those occurrences of the Color identifier that reference the Color type are underlined, and those that reference the Color field are not underlined.
7.5.5 Invocation expressions
An invocation-expression is used to invoke a method.
invocation-expression:
primary-expression ( argument-listopt )
The primary-expression of an invocation-expression must be a method group or a value of a delegate-type. If the primary-expression is a method group, the invocation-expression is a method invocation (§7.5.5.1). If the primary-expression is a value of a delegate-type, the invocation-expression is a delegate invocation (§7.5.5.2). If the primary-expression is neither a method group nor a value of a delegate-type, a compile-time error occurs.
The optional argument-list (§7.4.1) provides values or variable references for the parameters of the method.
The result of evaluating an invocation-expression is classified as follows:
• If the invocation-expression invokes a method or delegate that returns void, the result is nothing. An expression that is classified as nothing cannot be an operand of any operator, and is permitted only in the context of a statement-expression (§8.6).
• Otherwise, the result is a value of the type returned by the method or delegate.
7.5.5.1 Method invocations
For a method invocation, the primary-expression of the invocation-expression must be a method group. The method group identifies the one method to invoke or the set of overloaded methods from which to choose a specific method to invoke. In the latter case, determination of the specific method to invoke is based on the context provided by the types of the arguments in the argument-list.
The compile-time processing of a method invocation of the form M(A), where M is a method group and A is an optional argument-list, consists of the following steps:
• The set of candidate methods for the method invocation is constructed. Starting with the set of methods associated with M, which were found by a previous member lookup (§7.3), the set is reduced to those methods that are applicable with respect to the argument list A. The set reduction consists of applying the following rules to each method T.N in the set, where T is the type in which the method N is declared:
o If N is not applicable with respect to A (§7.4.2.1), then N is removed from the set.
o If N is applicable with respect to A (§7.4.2.1), then all methods declared in a base type of T are removed from the set.
• If the resulting set of candidate methods is empty, then no applicable methods exist, and a compile-time error occurs. If the candidate methods are not all declared in the same type, the method invocation is ambiguous, and a compile-time error occurs (this latter situation can only occur for an invocation of a method in an interface that has multiple direct base interfaces, as described in §13.2.5).
• The best method of the set of candidate methods is identified using the overload resolution rules of §7.4.2. If a single best method cannot be identified, the method invocation is ambiguous, and a compile-time error occurs.
• Given a best method, the invocation of the method is validated in the context of the method group: If the best method is a static method, the method group must have resulted from a simple-name or a member-access through a type. If the best method is an instance method, the method group must have resulted from a simple-name, a member-access through a variable or value, or a base-access. If neither requirement is satisfied, a compile-time error occurs.
Once a method has been selected and validated at compile-time by the above steps, the actual run-time invocation is processed according to the rules of function member invocation described in §7.4.3.
The intuitive effect of the resolution rules described above is as follows: To locate the particular method invoked by a method invocation, start with the type indicated by the method invocation and proceed up the inheritance chain until at least one applicable, accessible, non-override method declaration is found. Then perform overload resolution on the set of applicable, accessible, non-override methods declared in that type and invoke the method thus selected.
7.5.5.2 Delegate invocations
For a delegate invocation, the primary-expression of the invocation-expression must be a value of a delegate-type. Furthermore, considering the delegate-type to be a function member with the same parameter list as the delegate-type, the delegate-type must be applicable (§7.4.2.1) with respect to the argument-list of the invocation-expression.
The run-time processing of a delegate invocation of the form D(A), where D is a primary-expression of a delegate-type and A is an optional argument-list, consists of the following steps:
• D is evaluated. If this evaluation causes an exception, no further steps are executed.
• The value of D is checked to be valid. If the value of D is null, a System.NullReferenceException is thrown and no further steps are executed.
• Otherwise, D is a reference to a delegate instance. A function member invocation (§7.4.3) is performed on the method referenced by the delegate. If the method is an instance method, the instance of the invocation becomes the instance referenced by the delegate.
7.5.6 Element access
An element-access consists of a primary-no-array-creation-expression, followed by a “[“ token, followed by an expression-list, followed by a “]” token. The expression-list consists of one or more expressions, separated by commas.
element-access:
primary-no-array-creation-expression [ expression-list ]
expression-list:
expression
expression-list , expression
If the primary-no-array-creation-expression of an element-access is a value of an array-type, the element-access is an array access (§7.5.6.1). Otherwise, the primary-no-array-creation-expression must be a variable or value of a class, struct, or interface type that has one or more indexer members, in which case the element-access is an indexer access (§7.5.6.2).
7.5.6.1 Array access
For an array access, the primary-no-array-creation-expression of the element-access must be a value of an array-type. The number of expressions in the expression-list must be the same as the rank of the array-type, and each expression must be of type int, uint, long, ulong, or of a type that can be implicitly converted to one or more of these types.
The result of evaluating an array access is a variable of the element type of the array, namely the array element selected by the value(s) of the expression(s) in the expression-list.
The run-time processing of an array access of the form P[A], where P is a primary-no-array-creation-expression of an array-type and A is an expression-list, consists of the following steps:
• P is evaluated. If this evaluation causes an exception, no further steps are executed.
• The index expressions of the expression-list are evaluated in order, from left to right. Following evaluation of each index expression, an implicit conversion (§6.1) to one of the following types is performed: int, uint, long, ulong. The first type in this list for which an implicit conversion exists is chosen. For instance, if the index expression is of type short then an implicit conversion to int is performed, since implicit conversions from short to int and from short to long are possible. If evaluation of an index expression or the subsequent implicit conversion causes an exception, then no further index expressions are evaluated and no further steps are executed.
• The value of P is checked to be valid. If the value of P is null, a System.NullReferenceException is thrown and no further steps are executed.
• The value of each expression in the expression-list is checked against the actual bounds of each dimension of the array instance referenced by P. If one or more values are out of range, a System.IndexOutOfRangeException is thrown and no further steps are executed.
• The location of the array element given by the index expression(s) is computed, and this location becomes the result of the array access.
7.5.6.2 Indexer access
For an indexer access, the primary-no-array-creation-expression of the element-access must be a variable or value of a class, struct, or interface type, and this type must implement one or more indexers that are applicable with respect to the expression-list of the element-access.
The compile-time processing of an indexer access of the form P[A], where P is a primary-no-array-creation-expression of a class, struct, or interface type T, and A is an expression-list, consists of the following steps:
• The set of indexers provided by T is constructed. The set consists of all indexers declared in T or a base type of T that are not override declarations and are accessible in the current context (§3.5).
• The set is reduced to those indexers that are applicable and not hidden by other indexers. The following rules are applied to each indexer S.I in the set, where S is the type in which the indexer I is declared:
o If I is not applicable with respect to A (§7.4.2.1), then I is removed from the set.
o If I is applicable with respect to A (§7.4.2.1), then all indexers declared in a base type of S are removed from the set.
• If the resulting set of candidate indexers is empty, then no applicable indexers exist, and a compile-time error occurs. If the candidate indexers are not all declared in the same type, the indexer access is ambiguous, and a compile-time error occurs (this latter situation can only occur for an indexer access on an instance of an interface that has multiple direct base interfaces).
• The best indexer of the set of candidate indexers is identified using the overload resolution rules of §7.4.2. If a single best indexer cannot be identified, the indexer access is ambiguous, and a compile-time error occurs.
• The index expressions of the expression-list are evaluated in order, from left to right. The result of processing the indexer access is an expression classified as an indexer access. The indexer access expression references the indexer determined in the step above, and has an associated instance expression of P and an associated argument list of A.
Depending on the context in which it is used, an indexer access causes invocation of either the get-accessor or the set-accessor of the indexer. If the indexer access is the target of an assignment, the set-accessor is invoked to assign a new value (§7.13.1). In all other cases, the get-accessor is invoked to obtain the current value (§7.1.1).
7.5.7 This access
A this-access consists of the reserved word this.
this-access:
this
A this-access is permitted only in the block of an instance method, an instance accessor, or an instance constructor. It has one of the following meanings:
• When this is used in a primary-expression within an instance method or instance accessor of a class, it is classified as a value. The type of the value is the class within which the usage occurs, and the value is a reference to the object for which the method or accessor was invoked.
• When this is used in a primary-expression within an instance method or instance accessor of a struct, it is classified as a variable. The type of the variable is the struct within which the usage occurs, and the variable represents the struct for which the method or accessor was invoked. The this variable of an instance method of a struct behaves exactly the same as a ref parameter of the struct type.
• When this is used in a primary-expression within an instance constructor of a class, it is classified as a value. The type of the value is the class within which the usage occurs, and the value is a reference to the object being constructed.
• When this is used in a primary-expression within an instance constructor of a struct, it is classified as a variable. The type of the variable is the struct within which the usage occurs, and the variable represents the struct being constructed. The this variable of an instance constructor of a struct behaves exactly the same as an out parameter of the struct type—this in particular means that the variable must be definitely assigned in every execution path of the instance constructor.
Use of this in a primary-expression in a context other than the ones listed above is a compile-time error. In particular, it is not possible to refer to this in a static method, a static property accessor, or in a variable-initializer of a field declaration.
7.5.8 Base access
A base-access consists of the reserved word base followed by either a “.” token and an identifier or an expression-list enclosed in square brackets:
base-access:
base . identifier
base [ expression-list ]
A base-access is used to access base class members that are hidden by similarly named members in the current class or struct. A base-access is permitted only in the block of an instance method, an instance accessor, or an instance constructor. When base.I occurs in a class or struct, I must denote a member of the base class of that class or struct. Likewise, when base[E] occurs in a class, an applicable indexer must exist in the base class.
At compile-time, base-access expressions of the form base.I and base[E] are evaluated exactly as if they were written ((B)this).I and ((B)this)[E], where B is the base class of the class or struct in which the construct occurs. Thus, base.I and base[E] correspond to this.I and this[E], except this is viewed as an instance of the base class.
When a base-access references a virtual function member (a method, property, or indexer), the determination of which function member to invoke at run-time (§7.4.3) is changed. The function member that is invoked is determined by finding the most derived implementation (§10.5.3) of the function member with respect to B (instead of with respect to the run-time type of this, as would be usual in a non-base access). Thus, within an override of a virtual function member, a base-access can be used to invoke the inherited implementation of the function member. If the function member referenced by a base-access is abstract, a compile-time error occurs.
7.5.9 Postfix increment and decrement operators
post-increment-expression:
primary-expression ++
post-decrement-expression:
primary-expression --
The operand of a postfix increment or decrement operation must be an expression classified as a variable, a property access, or an indexer access. The result of the operation is a value of the same type as the operand.
If the operand of a postfix increment or decrement operation is a property or indexer access, the property or indexer must have both a get and a set accessor. If this is not the case, a compile-time error occurs.
Unary operator overload resolution (§7.2.3) is applied to select a specific operator implementation. Predefined ++ and -- operators exist for the following types: sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, decimal, and any enum type. The predefined ++ operators return the value produced by adding 1 to the operand, and the predefined -- operators return the value produced by subtracting 1 from the operand.
The run-time processing of a postfix increment or decrement operation of the form x++ or x-- consists of the following steps:
• If x is classified as a variable:
o x is evaluated to produce the variable.
o The value of x is saved.
o The selected operator is invoked with the saved value of x as its argument.
o The value returned by the operator is stored in the location given by the evaluation of x.
o The saved value of x becomes the result of the operation.
• If x is classified as a property or indexer access:
o The instance expression (if x is not static) and the argument list (if x is an indexer access) associated with x are evaluated, and the results are used in the subsequent get and set accessor invocations.
o The get accessor of x is invoked and the returned value is saved.
o The selected operator is invoked with the saved value of x as its argument.
o The set accessor of x is invoked with the value returned by the operator as its value argument.
o The saved value of x becomes the result of the operation.
The ++ and -- operators also support prefix notation, as described in §7.6.5. The result of x++ or x-- is the value of x before the operation, whereas the result of ++x or --x is the value of x after the operation. In either case, x itself has the same value after the operation.
An operator ++ or operator -- implementation can be invoked using either postfix or prefix notation. It is not possible to have separate operator implementations for the two notations.
7.5.10 new operator
The new operator is used to create new instances of types.
There are three forms of new expressions:
• Object creation expressions are used to create new instances of class types and value types.
• Array creation expressions are used to create new instances of array types.
• Delegate creation expressions are used to create new instances of delegate types.
The new operator implies creation of an instance of a type, but does not necessarily imply dynamic allocation of memory. In particular, instances of value types require no additional memory beyond the variables in which they reside, and no dynamic allocations occur when new is used to create instances of value types.
7.5.10.1 Object creation expressions
An object-creation-expression is used to create a new instance of a class-type or a value-type.
object-creation-expression:
new type ( argument-listopt )
The type of an object-creation-expression must be a class-type or a value-type. The type cannot be an abstract class-type.
The optional argument-list (§7.4.1) is permitted only if the type is a class-type or a struct-type.
The compile-time processing of an object-creation-expression of the form new T(A), where T is a class-type or a value-type and A is an optional argument-list, consists of the following steps:
• If T is a value-type and A is not present:
o The object-creation-expression is a default constructor invocation. The result of the object-creation-expression is a value of type T, namely the default value for T as defined in §4.1.1.
• Otherwise, if T is a class-type or a struct-type:
o If T is an abstract class-type, a compile-time error occurs.
o The instance constructor to invoke is determined using the overload resolution rules of §7.4.2. The set of candidate instance constructors consists of all accessible instance constructors declared in T which are applicable with respect to A (§7.4.2.1). If the set is empty, or if a single best constructor cannot be identified, a compile-time error occurs.
o The result of the object-creation-expression is a value of type T, namely the value produced by invoking the instance constructor determined in the step above.
• Otherwise, the object-creation-expression is invalid, and a compile-time error occurs.
The run-time processing of an object-creation-expression of the form new T(A), where T is class-type or a struct-type and A is an optional argument-list, consists of the following steps:
• If T is a class-type:
o A new instance of class T is allocated. If there is not enough memory available to allocate the new instance, a System.OutOfMemoryException is thrown and no further steps are executed.
o All fields of the new instance are initialized to their default values (§5.2).
o The instance constructor is invoked according to the rules of function member invocation (§7.4.3). A reference to the newly allocated instance is automatically passed to the instance constructor and the instance can be accessed from within the instance constructor as this.
• If T is a struct-type:
o An instance of type T is created by allocating a temporary local variable. Since an instance constructor of a struct-type is required to definitely assign a value to each field of the instance being created, no initialization of the temporary variable is necessary.
o The instance constructor is invoked according to the rules of function member invocation (§7.4.3). A reference to the newly allocated instance is automatically passed to the instance constructor and the instance can be accessed from within the instance constructor as this.
7.5.10.2 Array creation expressions
An array-creation-expression is used to create a new instance of an array-type.
array-creation-expression:
new non-array-type [ expression-list ] rank-specifiersopt array-initializeropt
new array-type array-initializer
An array creation expression of the first form allocates an array instance of the type that results from deleting each of the individual expressions from the expression list. For example, the array creation expression new int[10, 20] produces an array instance of type int[,], and the array creation expression new int[10][,] produces an array of type int[][,]. Each expression in the expression list must be of type int, uint, long, or ulong, or of a type that can be implicitly converted to one or more of these types. The value of each expression determines the length of the corresponding dimension in the newly allocated array instance. Since the length of an array dimension must be nonnegative, it is a compile-time error to specify a constant-expression length that evaluates to a negative value.
Except in an unsafe context (§A.1), the layout of arrays is unspecified.
If an array creation expression of the first form includes an array initializer, each expression in the expression list must be a constant and the rank and dimension lengths specified by the expression list must match those of the array initializer.
In an array creation expression of the second form, the rank of the specified array type must match that of the array initializer. The individual dimension lengths are inferred from the number of elements in each of the corresponding nesting levels of the array initializer. Thus, the expression
new int[,] {{0, 1}, {2, 3}, {4, 5}}
exactly corresponds to
new int[3, 2] {{0, 1}, {2, 3}, {4, 5}}
Array initializers are described further in §12.6.
The result of evaluating an array creation expression is classified as a value, namely a reference to the newly allocated array instance. The run-time processing of an array creation expression consists of the following steps:
• The dimension length expressions of the expression-list are evaluated in order, from left to right. Following evaluation of each expression, an implicit conversion (§6.1) to one of the following types is performed: int, uint, long, ulong. The first type in this list for which an implicit conversion exists is chosen. If evaluation of an expression or the subsequent implicit conversion causes an exception, then no further expressions are evaluated and no further steps are executed.
• The computed values for the dimension lengths are validated as follows. If one or more of the values are less than zero, a System.OverflowException is thrown and no further steps are executed.
• An array instance with the given dimension lengths is allocated. If there is not enough memory available to allocate the new instance, a System.OutOfMemoryException is thrown and no further steps are executed.
• All elements of the new array instance are initialized to their default values (§5.2).
• If the array creation expression contains an array initializer, then each expression in the array initializer is evaluated and assigned to its corresponding array element. The evaluations and assignments are performed in the order the expressions are written in the array initializer—in other words, elements are initialized in increasing index order, with the rightmost dimension increasing first. If evaluation of a given expression or the subsequent assignment to the corresponding array element causes an exception, then no further elements are initialized (and the remaining elements will thus have their default values).
An array creation expression permits instantiation of an array with elements of an array type, but the elements of such an array must be manually initialized. For example, the statement
int[][] a = new int[100][];
creates a single-dimensional array with 100 elements of type int[]. The initial value of each element is null. It is not possible for the same array creation expression to also instantiate the sub-arrays, and the statement
int[][] a = new int[100][5]; // Error
results in a compile-time error. Instantiation of the sub-arrays must instead be performed manually, as in
int[][] a = new int[100][];
for (int i = 0; i < 100; i++) a[i] = new int[5];
When an array of arrays has a “rectangular” shape, that is when the sub-arrays are all of the same length, it is more efficient to use a multi-dimensional array. In the example above, instantiation of the array of arrays creates 101 objects—one outer array and 100 sub-arrays. In contrast,
int[,] = new int[100, 5];
creates only a single object, a two-dimensional array, and accomplishes the allocation in a single statement.
7.5.10.3 Delegate creation expressions
A delegate-creation-expression is used to create a new instance of a delegate-type.
delegate-creation-expression:
new delegate-type ( expression )
The argument of a delegate creation expression must be a method group (7.1) or a value of a delegate-type. If the argument is a method group, it identifies the method and, for an instance method, the object for which to create a delegate. If the argument is a value of a delegate-type, it identifies a delegate instance of which to create a copy.
The compile-time processing of a delegate-creation-expression of the form new D(E), where D is a delegate-type and E is an expression, consists of the following steps:
• If E is a method group:
o The set of methods identified by E must include exactly one method that is compatible (§15.1) with D, and this method becomes the one to which the newly created delegate refers. If no matching method exists, or if more than one matching method exists, a compile-time error occurs. If the selected method is an instance method, the instance expression associated with E determines the target object of the delegate.
o As in a method invocation, the selected method must be compatible with the context of the method group: If the method is a static method, the method group must have resulted from a simple-name or a member-access through a type. If the method is an instance method, the method group must have resulted from a simple-name or a member-access through a variable or value. If the selected method does not match the context of the method group, a compile-time error occurs.
o The result is a value of type D, namely a newly created delegate that refers to the selected method and target object.
• Otherwise, if E is a value of a delegate-type:
o D and E must be compatible (§15.1); otherwise, a compile-time error occurs.
o The result is a value of type D, namely a newly created delegate that refers to the same invocation list as E.
• Otherwise, the delegate creation expression is invalid, and a compile-time error occurs.
The run-time processing of a delegate-creation-expression of the form new D(E), where D is a delegate-type and E is an expression, consists of the following steps:
• If E is a method group:
o If the method selected at compile-time is a static method, the target object of the delegate is null. Otherwise, the selected method is an instance method, and the target object of the delegate is determined from the instance expression associated with E:
• The instance expression is evaluated. If this evaluation causes an exception, no further steps are executed.
• If the instance expression is of a reference-type, the value computed by the instance expression becomes the target object. If the target object is null, a System.NullReferenceException is thrown and no further steps are executed.
• If the instance expression is of a value-type, a boxing operation (§4.3.1) is performed to convert the value to an object, and this object becomes the target object.
o A new instance of the delegate type D is allocated. If there is not enough memory available to allocate the new instance, a System.OutOfMemoryException is thrown and no further steps are executed.
o The new delegate instance is initialized with a reference to the method that was determined at compile-time and a reference to the target object computed above.
• If E is a value of a delegate-type:
o E is evaluated. If this evaluation causes an exception, no further steps are executed.
o If the value of E is null, a System.NullReferenceException is thrown and no further steps are executed.
o A new instance of the delegate type D is allocated. If there is not enough memory available to allocate the new instance, a System.OutOfMemoryException is thrown and no further steps are executed.
o The new delegate instance is initialized with references to the same invocation list as the delegate instance given by E.
The method and object to which a delegate refers are determined when the delegate is instantiated and then remain constant for the entire lifetime of the delegate. In other words, it is not possible to change the target method or object of a delegate once it has been created. (When two delegates are combined or one is removed from another, a new delegate results; no existing delegate has its content changed.)
It is not possible to create a delegate that refers to a property, indexer, user-defined operator, instance constructor, destructor, or static constructor.
As described above, when a delegate is created from a method group, the formal parameter list and return type of the delegate determine which of the overloaded methods to select. In the example
delegate double DoubleFunc(double x);
class A
{
DoubleFunc f = new DoubleFunc(Square);
static float Square(float x) {
return x * x;
}
static double Square(double x) {
return x * x;
}
}
the A.f field is initialized with a delegate that refers to the second Square method because that method exactly matches the formal parameter list and return type of DoubleFunc. Had the second Square method not been present, a compile-time error would have occurred.
7.5.11 The typeof operator
The typeof operator is used to obtain the System.Type object for a type.
typeof-expression:
typeof ( type )
typeof ( void )
The first form of typeof-expression consists of a typeof keyword followed by a parenthesized type. The result of an expression of this form is the System.Type object for the indicated type. There is only one System.Type object for any given type.
The second form of typeof-expression consists of a typeof keyword followed by a parenthesized void keyword. The result of this form is a System.Type object that represents the lack of a type. The type object returned is distinct from the type object returned for any type. This special type object is useful in class libraries that allow reflection onto methods in the language, where those methods wish to have a way to represent the return type of any method, including void methods, with an instance of System.Type.
The example
using System;
class Test
{
static void Main() {
Type[] t = {
typeof(int),
typeof(System.Int32),
typeof(string),
typeof(double[]),
typeof(void)
};
for (int i = 0; i < t.Length; i++) {
Console.WriteLine(t[i].FullName);
}
}
}
produces the following output:
System.Int32
System.Int32
System.String
System.Double[]
System.Void
Note that int and System.Int32 are the same type.
7.5.12 The checked and unchecked operators
The checked and unchecked operators are used to control the overflow checking context for integral-type arithmetic operations and conversions.
checked-expression:
checked ( expression )
unchecked-expression:
unchecked ( expression )
The checked operator evaluates the contained expression in a checked context, and the unchecked operator evaluates the contained expression in an unchecked context. A checked-expression or unchecked-expression corresponds exactly to a parenthesized-expression (§7.5.3), except that the contained expression is evaluated in the given overflow checking context.
The overflow checking context can also be controlled through the checked and unchecked statements (§8.11).
The following operations are affected by the overflow checking context established by the checked and unchecked operators and statements:
• The predefined ++ and -- unary operators (§7.5.9 and §7.6.5), when the operand is of an integral type.
• The predefined - unary operator (§7.6.2), when the operand is of an integral type.
• The predefined +, -, *, and / binary operators (§7.7), when both operands are of integral types.
• Explicit numeric conversions (§6.2.1) from one integral type to another integral type, and from float or double to an integral type.
When one of the above operations produce a result that is too large to represent in the destination type, the context in which the operation is performed controls the resulting behavior:
• In a checked context, if the operation is a constant expression (§7.15), a compile-time error occurs. Otherwise, when the operation is performed at run-time, a System.OverflowException is thrown.
• In an unchecked context, the result is truncated by discarding any high-order bits that do not fit in the destination type.
For non-constant expressions (expressions that are evaluated at run-time) that are not enclosed by any checked or unchecked operators or statements, the default overflow checking context is unchecked unless external factors (such as compiler switches and execution environment configuration) call for checked evaluation.
For constant expressions (expressions that can be fully evaluated at compile-time), the default overflow checking context is always checked. Unless a constant expression is explicitly placed in an unchecked context, overflows that occur during the compile-time evaluation of the expression always cause compile-time errors.
In the example
class Test
{
static readonly int x = 1000000;
static readonly int y = 1000000;
static int F() {
return checked(x * y); // Throws OverflowException
}
static int G() {
return unchecked(x * y); // Returns -727379968
}
static int H() {
return x * y; // Depends on default
}
}
no compile-time errors are reported since neither of the expressions can be evaluated at compile-time. At run-time, the F() method throws a System.OverflowException, and the G() method returns –727379968 (the lower 32 bits of the out-of-range result). The behavior of the H() method depends on the default overflow checking context for the compilation, but it is either the same as F() or the same as G().
In the example
class Test
{
const int x = 1000000;
const int y = 1000000;
static int F() {
return checked(x * y); // Compile error, overflow
}
static int G() {
return unchecked(x * y); // Returns -727379968
}
static int H() {
return x * y; // Compile error, overflow
}
}
the overflows that occur when evaluating the constant expressions in F() and H() cause compile-time errors to be reported because the expressions are evaluated in a checked context. An overflow also occurs when evaluating the constant expression in G(), but since the evaluation takes place in an unchecked context, the overflow is not reported.
The checked and unchecked operators only affect the overflow checking context for those operations that are textually contained within the “(” and “)” tokens. The operators have no effect on function members that are invoked as a result of evaluating the contained expression. In the example
class Test
{
static int Multiply(int x, int y) {
return x * y;
}
static int F() {
return checked(Multiply(1000000, 1000000));
}
}
the use of checked in F does not affect the evaluation of x * y in Multiply(), so x * y is evaluated in the default overflow checking context.
The unchecked operator is convenient when writing constants of the signed integral types in hexadecimal notation. For example:
class Test
{
public const int AllBits = unchecked((int)0xFFFFFFFF);
public const int HighBit = unchecked((int)0x80000000);
}
Both of the hexadecimal constants above are of type uint. Because the constants are outside the int range, without the unchecked operator, the casts to int would produce compile-time errors.
The checked and unchecked operators and statements allow programmers to control certain aspects of some numeric calculations. However, the behavior of some numeric operators depends on their operands’ data types. For example, multiplying two decimals always results in an exception on overflow even within an explicitly unchecked construct. Similarly, multiplying two floats never results in an exception on overflow even within an explicitly checked construct. In addition, other operators are never affected by the mode of checking, whether default or explicit. As a service to programmers, it is recommended that the compiler issue a warning when there is an arithmetic expression within an explicitly checked or unchecked context (by operator or statement), that cannot possibly be affected by the specified mode of checking. Since such a warning is not required, the compiler has flexibility in determining the circumstances that merit the issuance of such warnings.
7.6 Unary operators
The +, -, !, ~, *, ++, --, and cast operators are called the unary operators.
unary-expression:
primary-expression
+ unary-expression
- unary-expression
! unary-expression
~ unary-expression
* unary-expression
pre-increment-expression
pre-decrement-expression
cast-expression
7.6.1 Unary plus operator
For an operation of the form +x, unary operator overload resolution (§7.2.3) is applied to select a specific operator implementation. The operand is converted to the parameter type of the selected operator, and the type of the result is the return type of the operator. The predefined unary plus operators are:
int operator +(int x);
uint operator +(uint x);
long operator +(long x);
ulong operator +(ulong x);
float operator +(float x);
double operator +(double x);
decimal operator +(decimal x);
For each of these operators, the result is simply the value of the operand.
7.6.2 Unary minus operator
For an operation of the form –x, unary operator overload resolution (§7.2.3) is applied to select a specific operator implementation. The operand is converted to the parameter type of the selected operator, and the type of the result is the return type of the operator. The predefined negation operators are:
• Integer negation:
int operator –(int x);
long operator –(long x);
The result is computed by subtracting x from zero. In a checked context, if the value of x is the maximum negative int or long, a System.OverflowException is thrown. In an unchecked context, if the value of x is the maximum negative int or long, the result is that same value and the overflow is not reported.
If the operand of the negation operator is of type uint, it is converted to type long, and the type of the result is long. An exception is the rule that permits the int value −2147483648 (−231) to be written as a decimal integer literal (§2.4.4.2).
If the operand of the negation operator is of type ulong, a compile-time error occurs. An exception is the rule that permits the long value −9223372036854775808 (−263) to be written as decimal integer literal (§2.4.4.2).
• Floating-point negation:
float operator –(float x);
double operator –(double x);
The result is the value of x with its sign inverted. If x is NaN, the result is also NaN.
• Decimal negation:
decimal operator –(decimal x);
The result is computed by subtracting x from zero. Decimal negation is equivalent to using the unary minus operator of type System.Decimal.
7.6.3 Logical negation operator
For an operation of the form !x, unary operator overload resolution (§7.2.3) is applied to select a specific operator implementation. The operand is converted to the parameter type of the selected operator, and the type of the result is the return type of the operator. Only one predefined logical negation operator exists:
bool operator !(bool x);
This operator computes the logical negation of the operand: If the operand is true, the result is false. If the operand is false, the result is true.
7.6.4 Bitwise complement operator
For an operation of the form ~x, unary operator overload resolution (§7.2.3) is applied to select a specific operator implementation. The operand is converted to the parameter type of the selected operator, and the type of the result is the return type of the operator. The predefined bitwise complement operators are:
int operator ~(int x);
uint operator ~(uint x);
long operator ~(long x);
ulong operator ~(ulong x);
For each of these operators, the result of the operation is the bitwise complement of x.
Every enumeration type E implicitly provides the following bitwise complement operator:
E operator ~(E x);
The result of evaluating ~x, where x is an expression of an enumeration type E with an underlying type U, is exactly the same as evaluating (E)(~(U)x).
7.6.5 Prefix increment and decrement operators
pre-increment-expression:
++ unary-expression
pre-decrement-expression:
-- unary-expression
The operand of a prefix increment or decrement operation must be an expression classified as a variable, a property access, or an indexer access. The result of the operation is a value of the same type as the operand.
If the operand of a prefix increment or decrement operation is a property or indexer access, the property or indexer must have both a get and a set accessor. If this is not the case, a compile-time error occurs.
Unary operator overload resolution (§7.2.3) is applied to select a specific operator implementation. Predefined ++ and -- operators exist for the following types: sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, decimal, and any enum type. The predefined ++ operators return the value produced by adding 1 to the operand, and the predefined -- operators return the value produced by subtracting 1 from the operand.
The run-time processing of a prefix increment or decrement operation of the form ++x or --x consists of the following steps:
• If x is classified as a variable:
o x is evaluated to produce the variable.
o The selected operator is invoked with the value of x as its argument.
o The value returned by the operator is stored in the location given by the evaluation of x.
o The value returned by the operator becomes the result of the operation.
• If x is classified as a property or indexer access:
o The instance expression (if x is not static) and the argument list (if x is an indexer access) associated with x are evaluated, and the results are used in the subsequent get and set accessor invocations.
o The get accessor of x is invoked.
o The selected operator is invoked with the value returned by the get accessor as its argument.
o The set accessor of x is invoked with the value returned by the operator as its value argument.
o The value returned by the operator becomes the result of the operation.
The ++ and -- operators also support postfix notation, as described in §7.5.9. The result of x++ or x-- is the value of x before the operation, whereas the result of ++x or --x is the value of x after the operation. In either case, x itself has the same value after the operation.
An operator ++ or operator -- implementation can be invoked using either postfix or prefix notation. It is not possible to have separate operator implementations for the two notations.
7.6.6 Cast expressions
A cast-expression is used to explicitly convert an expression to a given type.
cast-expression:
( type ) unary-expression
A cast-expression of the form (T)E, where T is a type and E is a unary-expression, performs an explicit conversion (§6.2) of the value of E to type T. If no explicit conversion exists from the type of E to T, a compile-time error occurs. Otherwise, the result is the value produced by the explicit conversion. The result is always classified as a value, even if E denotes a variable.
The grammar for a cast-expression leads to certain syntactic ambiguities. For example, the expression (x)–y could either be interpreted as a cast-expression (a cast of –y to type x) or as an additive-expression combined with a parenthesized-expression (which computes the value x – y).
To resolve cast-expression ambiguities, the following rule exists: A sequence of one or more tokens (§2.4) enclosed in parentheses is considered the start of a cast-expression only if at least one of the following are true:
• The sequence of tokens is correct grammar for a type, but not for an expression.
• The sequence of tokens is correct grammar for a type, and the token immediately following the closing parentheses is the token “~”, the token “!”, the token “(”, an identifier (§2.4.1), a literal (§2.4.4), or any keyword (§2.4.3) except as and is.
The term “correct grammar” above means only that the sequence of tokens must conform to the particular grammatical production. It specifically does not consider the actual meaning of any constituent identifiers. For example, if x and y are identifiers, then x.y is correct grammar for a type, even if x.y doesn’t actually denote a type.
From the disambiguation rule it follows that, if x and y are identifiers, (x)y, (x)(y), and (x)(-y) are cast-expressions, but (x)-y is not, even if x identifies a type. However, if x is a keyword that identifies a predefined type (such as int), then all four forms are cast-expressions (because such a keyword could not possibly be an expression by itself).
7.7 Arithmetic operators
The *, /, %, +, and – operators are called the arithmetic operators.
multiplicative-expression:
unary-expression
multiplicative-expression * unary-expression
multiplicative-expression / unary-expression
multiplicative-expression % unary-expression
additive-expression:
multiplicative-expression
additive-expression + multiplicative-expression
additive-expression – multiplicative-expression
7.7.1 Multiplication operator
For an operation of the form x * y, binary operator overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined multiplication operators are listed below. The operators all compute the product of x and y.
• Integer multiplication:
int operator *(int x, int y);
uint operator *(uint x, uint y);
long operator *(long x, long y);
ulong operator *(ulong x, ulong y);
In a checked context, if the product is outside the range of the result type, a System.OverflowException is thrown. In an unchecked context, overflows are not reported and any significant high-order bits outside the range of the result type are discarded.
• Floating-point multiplication:
float operator *(float x, float y);
double operator *(double x, double y);
The product is computed according to the rules of IEEE 754 arithmetic. The following table lists the results of all possible combinations of nonzero finite values, zeros, infinities, and NaN’s. In the table, x and y are positive finite values. z is the result of x * y. If the result is too large for the destination type, z is infinity. If the result is too small for the destination type, z is zero.

+y –y +0 –0 +∞ –∞ NaN
+x +z –z +0 –0 +∞ –∞ NaN
–x –z +z –0 +0 –∞ +∞ NaN
+0 +0 –0 +0 –0 NaN NaN NaN
–0 –0 +0 –0 +0 NaN NaN NaN
+∞ +∞ –∞ NaN NaN +∞ –∞ NaN
–∞ –∞ +∞ NaN NaN –∞ +∞ NaN
NaN NaN NaN NaN NaN NaN NaN NaN

• Decimal multiplication:
decimal operator *(decimal x, decimal y);
If the resulting value is too large to represent in the decimal format, a System.OverflowException is thrown. If the result value is too small to represent in the decimal format, the result is zero. Decimal multiplication is equivalent to using the multiplication operator of type System.Decimal.
7.7.2 Division operator
For an operation of the form x / y, binary operator overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined division operators are listed below. The operators all compute the quotient of x and y.
• Integer division:
int operator /(int x, int y);
uint operator /(uint x, uint y);
long operator /(long x, long y);
ulong operator /(ulong x, ulong y);
If the value of the right operand is zero, a System.DivideByZeroException is thrown.
The division rounds the result towards zero, and the absolute value of the result is the largest possible integer that is less than the absolute value of the quotient of the two operands. The result is zero or positive when the two operands have the same sign and zero or negative when the two operands have opposite signs.
If the left operand is the maximum negative int or long value and the right operand is –1, an overflow occurs and a System.OverflowException is thrown.
• Floating-point division:
float operator /(float x, float y);
double operator /(double x, double y);
The quotient is computed according to the rules of IEEE 754 arithmetic. The following table lists the results of all possible combinations of nonzero finite values, zeros, infinities, and NaN’s. In the table, x and y are positive finite values. z is the result of x / y. If the result is too large for the destination type, z is infinity. If the result is too small for the destination type, z is zero.

+y –y +0 –0 +∞ –∞ NaN
+x +z –z +∞ –∞ +0 –0 NaN
–x –z +z –∞ +∞ –0 +0 NaN
+0 +0 –0 NaN NaN +0 –0 NaN
–0 –0 +0 NaN NaN –0 +0 NaN
+∞ +∞ –∞ +∞ –∞ NaN NaN NaN
–∞ –∞ +∞ –∞ +∞ NaN NaN NaN
NaN NaN NaN NaN NaN NaN NaN NaN

• Decimal division:
decimal operator /(decimal x, decimal y);
If the value of the right operand is zero, a System.DivideByZeroException is thrown. If the resulting value is too large to represent in the decimal format, a System.OverflowException is thrown. If the result value is too small to represent in the decimal format, the result is zero. Decimal division is equivalent to using the division operator of type System.Decimal.
7.7.3 Remainder operator
For an operation of the form x % y, binary operator overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined remainder operators are listed below. The operators all compute the remainder of the division between x and y.
• Integer remainder:
int operator %(int x, int y);
uint operator %(uint x, uint y);
long operator %(long x, long y);
ulong operator %(ulong x, ulong y);
The result of x % y is the value produced by x – (x / y) * y. If y is zero, a System.DivideByZeroException is thrown. The remainder operator never causes an overflow.
• Floating-point remainder:
float operator %(float x, float y);
double operator %(double x, double y);
The following table lists the results of all possible combinations of nonzero finite values, zeros, infinities, and NaN’s. In the table, x and y are positive finite values. z is the result of x % y and is computed as x – n * y, where n is the largest possible integer that is less than or equal to x / y. This method of computing the remainder is analogous to that used for integer operands, but differs from the IEEE 754 definition (in which n is the integer closest to x / y).

+y –y +0 –0 +∞ –∞ NaN
+x +z +z NaN NaN x x NaN
–x –z –z NaN NaN –x –x NaN
+0 +0 +0 NaN NaN +0 +0 NaN
–0 –0 –0 NaN NaN –0 –0 NaN
+∞ NaN NaN NaN NaN NaN NaN NaN
–∞ NaN NaN NaN NaN NaN NaN NaN
NaN NaN NaN NaN NaN NaN NaN NaN

• Decimal remainder:
decimal operator %(decimal x, decimal y);
If the value of the right operand is zero, a System.DivideByZeroException is thrown. If the resulting value is too large to represent in the decimal format, a System.OverflowException is thrown. If the result value is too small to represent in the decimal format, the result is zero. Decimal remainder is equivalent to using the remainder operator of type Decimal.
7.7.4 Addition operator
For an operation of the form x + y, binary operator overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined addition operators are listed below. For numeric and enumeration types, the predefined addition operators compute the sum of the two operands. When one or both operands are of type string, the predefined addition operators concatenate the string representation of the operands.
• Integer addition:
int operator +(int x, int y);
uint operator +(uint x, uint y);
long operator +(long x, long y);
ulong operator +(ulong x, ulong y);
In a checked context, if the sum is outside the range of the result type, a System.OverflowException is thrown. In an unchecked context, overflows are not reported and any significant high-order bits outside the range of the result type are discarded.
• Floating-point addition:
float operator +(float x, float y);
double operator +(double x, double y);
The sum is computed according to the rules of IEEE 754 arithmetic. The following table lists the results of all possible combinations of nonzero finite values, zeros, infinities, and NaN’s. In the table, x and y are nonzero finite values, and z is the result of x + y. If x and y have the same magnitude but opposite signs, z is positive zero. If x + y is too large to represent in the destination type, z is an infinity with the same sign as x + y. If x + y is too small to represent in the destination type, z is a zero with the same sign as x + y.

y +0 –0 +∞ –∞ NaN
x z x x +∞ –∞ NaN
+0 y +0 +0 +∞ –∞ NaN
–0 y +0 –0 +∞ –∞ NaN
+∞ +∞ +∞ +∞ +∞ NaN NaN
–∞ –∞ –∞ –∞ NaN –∞ NaN
NaN NaN NaN NaN NaN NaN NaN

• Decimal addition:
decimal operator +(decimal x, decimal y);
If the resulting value is too large to represent in the decimal format, a System.OverflowException is thrown. Decimal addition is equivalent to using the addition operator of type System.Decimal.
• Enumeration addition. Every enumeration type implicitly provides the following predefined operators, where E is the enum type, and U is the underlying type of E:
E operator +(E x, U y);
E operator +(U x, E y);
The operators are evaluated exactly as (E)((U)x + (U)y).
• String concatenation:
string operator +(string x, string y);
string operator +(string x, object y);
string operator +(object x, string y);
The binary + operator performs string concatenation when one or both operands are of type string. If an operand of string concatenation is null, an empty string is substituted. Otherwise, any non-string argument is converted to its string representation by invoking the virtual ToString() method inherited from type object. If ToString returns null, an empty string is substituted.
The example
using System;
class Test
{
static void Main() {
string s = null;
Console.WriteLine("s = >" + s + "<"); // displays s = ><
int i = 1;
Console.WriteLine("i = " + i); // displays i = 1
float f = 1.2300E+15F;
Console.WriteLine("f = " + f); // displays f = 1.23E+15
decimal d = 2.900m;
Console.WriteLine("d = " + d); // displays d = 2.900
}
}
produces the output:
s = ><
i = 1
f = 1.23E15
d = 2.900
The result of the string concatenation operator is a string that consists of the characters of the left operand followed by the characters of the right operand. The string concatenation operator never returns a null value. A System.OutOfMemoryException may be thrown if there is not enough memory available to allocate the resulting string.
• Delegate combination. Every delegate type implicitly provides the following predefined operator, where D is the delegate type:
D operator +(D x, D y);
The binary + operator performs delegate combination when both operands are of some delegate type D. (If the operands have different delegate types, a compile-time error occurs.) If the first operand is null, the result of the operation is the value of the second operand (even if that operand is also null). Otherwise, if the second operand is null, then the result of the operation is the value of the first operand. Otherwise, the result of the operation is a new delegate instance that, when invoked, invokes the first operand and then invokes the second operand.
7.7.5 Subtraction operator
For an operation of the form x – y, binary operator overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined subtraction operators are listed below. The operators all subtract y from x.
• Integer subtraction:
int operator –(int x, int y);
uint operator –(uint x, uint y);
long operator –(long x, long y);
ulong operator –(ulong x, ulong y);
In a checked context, if the difference is outside the range of the result type, a System.OverflowException is thrown. In an unchecked context, overflows are not reported and any significant high-order bits outside the range of the result type are discarded.
• Floating-point subtraction:
float operator –(float x, float y);
double operator –(double x, double y);
The difference is computed according to the rules of IEEE 754 arithmetic. The following table lists the results of all possible combinations of nonzero finite values, zeros, infinities, and NaN’s. In the table, x and y are nonzero finite values, and z is the result of x – y. If x and y are equal, z is positive zero. If x – y is too large to represent in the destination type, z is an infinity with the same sign as x – y. If x – y is too small to represent in the destination type, z is a zero with the same sign as x – y.

y +0 –0 +∞ –∞ NaN
x z x x –∞ +∞ NaN
+0 –y +0 +0 –∞ +∞ NaN
–0 –y –0 +0 –∞ +∞ NaN
+∞ +∞ +∞ +∞ NaN +∞ NaN
–∞ –∞ –∞ –∞ –∞ NaN NaN
NaN NaN NaN NaN NaN NaN NaN

• Decimal subtraction:
decimal operator –(decimal x, decimal y);
If the resulting value is too large to represent in the decimal format, a System.OverflowException is thrown. Decimal subtraction is equivalent to using the subtraction operator of type System.Decimal.
• Enumeration subtraction. Every enumeration type implicitly provides the following predefined operator, where E is the enum type, and U is the underlying type of E:
U operator –(E x, E y);
This operator is evaluated exactly as (U)((U)x – (U)y). In other words, the operator computes the difference between the ordinal values of x and y, and the type of the result is the underlying type of the enumeration.
E operator –(E x, U y);
This operator is evaluated exactly as (E)((U)x – y). In other words, the operator subtracts a value from the underlying type of the enumeration, yielding a value of the enumeration.
• Delegate removal. Every delegate type implicitly provides the following predefined operator, where D is the delegate type:
D operator –(D x, D y);
The binary - operator performs delegate removal when both operands are of a delegate type D. (If the operands have different delegate types, a compile-time error occurs.) If the first operand is null, the result of the operation is null. Otherwise, if the second operand is null, then the result of the operation is the value of the first operand. Otherwise, both operands represent invocation lists (§15.1) having one or more entries, and the result is a new invocation list consisting of the first operand’s list with the second operand’s entries removed from it, provided the second operand’s list is a proper contiguous subset of the first’s. (For determining subset equality, corresponding entries are compared as for the delegate equality operator.) Otherwise, the result is the value of the left operand. Neither of the operands’ lists is changed in the process. If the second operand’s list matches multiple subsets of contiguous entries in the first operand’s list, the right-most matching subset of contiguous entries is removed. If removal results in an empty list, the result is null.
The example
delegate void D(int x);
class C
{
public static void M1(int i) { /* … */ }
public static void M2(int i) { /* … */ }
}
class Test
{
static void Main() {
D cd1 = new D(C.M1);
D cd2 = new D(C.M2);
D cd3 = cd1 + cd2 + cd2 + cd1; // M1 + M2 + M2 + M1
cd3 -= cd1; // => M1 + M2 + M2
cd3 = cd1 + cd2 + cd2 + cd1; // M1 + M2 + M2 + M1
cd3 -= cd1 + cd2; // => M2 + M1
cd3 = cd1 + cd2 + cd2 + cd1; // M1 + M2 + M2 + M1
cd3 -= cd2 + cd2; // => M1 + M1
cd3 = cd1 + cd2 + cd2 + cd1; // M1 + M2 + M2 + M1
cd3 -= cd2 + cd1; // => M1 + M2
cd3 = cd1 + cd2 + cd2 + cd1; // M1 + M2 + M2 + M1
cd3 -= cd1 + cd1; // => M1 + M2 + M2 + M1
}
}
shows a variety of delegate subtractions.
7.8 Shift operators
The << and >> operators are used to perform bit shifting operations.
shift-expression:
additive-expression
shift-expression << additive-expression
shift-expression >> additive-expression
For an operation of the form x << count or x >> count, binary operator overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
When declaring an overloaded shift operator, the type of the first operand must always be the class or struct containing the operator declaration, and the type of the second operand must always be int.
The predefined shift operators are listed below.
• Shift left:
int operator <<(int x, int count);
uint operator <<(uint x, int count);
long operator <<(long x, int count);
ulong operator <<(ulong x, int count);
The << operator shifts x left by a number of bits computed as described below.
The high-order bits outside the range of the result type of x are discarded, the remaining bits are shifted left, and the low-order empty bit positions are set to zero.
• Shift right:
int operator >>(int x, int count);
uint operator >>(uint x, int count);
long operator >>(long x, int count);
ulong operator >>(ulong x, int count);
The >> operator shifts x right by a number of bits computed as described below.
When x is of type int or long, the low-order bits of x are discarded, the remaining bits are shifted right, and the high-order empty bit positions are set to zero if x is non-negative and set to one if x is negative.
When x is of type uint or ulong, the low-order bits of x are discarded, the remaining bits are shifted right, and the high-order empty bit positions are set to zero.
For the predefined operators, the number of bits to shift is computed as follows:
• When the type of x is int or uint, the shift count is given by the low-order five bits of count. In other words, the shift count is computed from count & 0x1F.
• When the type of x is long or ulong, the shift count is given by the low-order six bits of count. In other words, the shift count is computed from count & 0x3F.
If the resulting shift count is zero, the shift operators simply return the value of x.
Shift operations never cause overflows and produce the same results in checked and unchecked contexts.
When the left operand of the >> operator is of a signed integral type, the operator performs an arithmetic shift right wherein the value of the most significant bit (the sign bit) of the operand is propagated to the high-order empty bit positions. When the left operand of the >> operator is of an unsigned integral type, the operator performs a logical shift right wherein high-order empty bit positions are always set to zero. To perform the opposite operation of that inferred from the operand type, explicit casts can be used. For example, if x is a variable of type int, the operation unchecked((int)((uint)x >> y)) performs a logical shift right of x.
7.9 Relational and type testing operators
The ==, !=, <, >, <=, >=, is and as operators are called the relational and type testing operators.
relational-expression:
shift-expression
relational-expression < shift-expression
relational-expression > shift-expression
relational-expression <= shift-expression
relational-expression >= shift-expression
relational-expression is type
relational-expression as type
equality-expression:
relational-expression
equality-expression == relational-expression
equality-expression != relational-expression
The is operator is described in §7.9.9 and the as operator is described in §7.9.10.
The ==, !=, <, >, <= and >= operators are comparison operators. For an operation of the form x op y, where op is a comparison operator, overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined comparison operators are described in the following sections. All predefined comparison operators return a result of type bool, as described in the following table.

Operation Result
x == y true if x is equal to y, false otherwise
x != y true if x is not equal to y, false otherwise
x < y true if x is less than y, false otherwise
x > y true if x is greater than y, false otherwise
x <= y true if x is less than or equal to y, false otherwise
x >= y true if x is greater than or equal to y, false otherwise

7.9.1 Integer comparison operators
The predefined integer comparison operators are:
bool operator ==(int x, int y);
bool operator ==(uint x, uint y);
bool operator ==(long x, long y);
bool operator ==(ulong x, ulong y);
bool operator !=(int x, int y);
bool operator !=(uint x, uint y);
bool operator !=(long x, long y);
bool operator !=(ulong x, ulong y);
bool operator <(int x, int y);
bool operator <(uint x, uint y);
bool operator <(long x, long y);
bool operator <(ulong x, ulong y);
bool operator >(int x, int y);
bool operator >(uint x, uint y);
bool operator >(long x, long y);
bool operator >(ulong x, ulong y);
bool operator <=(int x, int y);
bool operator <=(uint x, uint y);
bool operator <=(long x, long y);
bool operator <=(ulong x, ulong y);
bool operator >=(int x, int y);
bool operator >=(uint x, uint y);
bool operator >=(long x, long y);
bool operator >=(ulong x, ulong y);
Each of these operators compares the numeric values of the two integer operands and returns a bool value that indicates whether the particular relation is true or false.
7.9.2 Floating-point comparison operators
The predefined floating-point comparison operators are:
bool operator ==(float x, float y);
bool operator ==(double x, double y);
bool operator !=(float x, float y);
bool operator !=(double x, double y);
bool operator <(float x, float y);
bool operator <(double x, double y);
bool operator >(float x, float y);
bool operator >(double x, double y);
bool operator <=(float x, float y);
bool operator <=(double x, double y);
bool operator >=(float x, float y);
bool operator >=(double x, double y);
The operators compare the operands according to the rules of the IEEE 754 standard:
• If either operand is NaN, the result is false for all operators except !=, for which the result is true. For any two operands, x != y always produces the same result as !(x == y). However, when one or both operands are NaN, the <, >, <=, and >= operators do not produce the same results as the logical negation of the opposite operator. For example, if either of x and y is NaN, then x < y is false, but !(x >= y) is true.
• When neither operand is NaN, the operators compare the values of the two floating-point operands with respect to the ordering
–∞ < –max < ... < –min < –0.0 == +0.0 < +min < ... < +max < +∞
where min and max are the smallest and largest positive finite values that can be represented in the given floating-point format. Notable effects of this ordering are:
o Negative and positive zeros are considered equal.
o A negative infinity is considered less than all other values, but equal to another negative infinity.
o A positive infinity is considered greater than all other values, but equal to another positive infinity.
7.9.3 Decimal comparison operators
The predefined decimal comparison operators are:
bool operator ==(decimal x, decimal y);
bool operator !=(decimal x, decimal y);
bool operator <(decimal x, decimal y);
bool operator >(decimal x, decimal y);
bool operator <=(decimal x, decimal y);
bool operator >=(decimal x, decimal y);
Each of these operators compare the numeric values of the two decimal operands and return a bool value that indicates whether the particular relation is true or false. Each decimal comparison is equivalent to using the corresponding relational or equality operator of type System.Decimal.
7.9.4 Boolean equality operators
The predefined boolean equality operators are:
bool operator ==(bool x, bool y);
bool operator !=(bool x, bool y);
The result of == is true if both x and y are true or if both x and y are false. Otherwise, the result is false.
The result of != is false if both x and y are true or if both x and y are false. Otherwise, the result is true. When the operands are of type bool, the != operator produces the same result as the ^ operator.
7.9.5 Enumeration comparison operators
Every enumeration type implicitly provides the following predefined comparison operators:
bool operator ==(E x, E y);
bool operator !=(E x, E y);
bool operator <(E x, E y);
bool operator >(E x, E y);
bool operator <=(E x, E y);
bool operator >=(E x, E y);
The result of evaluating x op y, where x and y are expressions of an enumeration type E with an underlying type U, and op is one of the comparison operators, is exactly the same as evaluating ((U)x) op ((U)y). In other words, the enumeration type comparison operators simply compare the underlying integral values of the two operands.
7.9.6 Reference type equality operators
The predefined reference type equality operators are:
bool operator ==(object x, object y);
bool operator !=(object x, object y);
The operators return the result of comparing the two references for equality or non-equality.
Since the predefined reference type equality operators accept operands of type object, they apply to all types that do not declare applicable operator == and operator != members. Conversely, any applicable user-defined equality operators effectively hide the predefined reference type equality operators.
The predefined reference type equality operators require the operands to be reference-type values or the value null. Furthermore, they require that a standard implicit conversion (§6.3.1) exists from the type of either operand to the type of the other operand. Unless both of these conditions are true, a compile-time error occurs. Notable implications of these rules are:
• It is a compile-time error to use the predefined reference type equality operators to compare two references that are known to be different at compile-time. For example, if the compile-time types of the operands are two class types A and B, and if neither A nor B derives from the other, then it would be impossible for the two operands to reference the same object. Thus, the operation is considered a compile-time error.
• The predefined reference type equality operators do not permit value type operands to be compared. Therefore, unless a struct type declares its own equality operators, it is not possible to compare values of that struct type.
• The predefined reference type equality operators never cause boxing operations to occur for their operands. It would be meaningless to perform such boxing operations, since references to the newly allocated boxed instances would necessarily differ from all other references.
For an operation of the form x == y or x != y, if any applicable operator == or operator != exists, the operator overload resolution (§7.2.4) rules will select that operator instead of the predefined reference type equality operator. However, it is always possible to select the predefined reference type equality operator by explicitly casting one or both of the operands to type object. The example
using System;
class Test
{
static void Main() {
string s = "Test";
string t = string.Copy(s);
Console.WriteLine(s == t);
Console.WriteLine((object)s == t);
Console.WriteLine(s == (object)t);
Console.WriteLine((object)s == (object)t);
}
}
produces the output
True
False
False
False
The s and t variables refer to two distinct string instances containing the same characters. The first comparison outputs True because the predefined string equality operator (§7.9.7) is selected when both operands are of type string. The remaining comparisons all output False because the predefined reference type equality operator is selected when one or both of the operands are of type object.
Note that the above technique is not meaningful for value types. The example
class Test
{
static void Main() {
int i = 123;
int j = 123;
System.Console.WriteLine((object)i == (object)j);
}
}
outputs False because the casts create references to two separate instances of boxed int values.
7.9.7 String equality operators
The predefined string equality operators are:
bool operator ==(string x, string y);
bool operator !=(string x, string y);
Two string values are considered equal when one of the following is true:
• Both values are null.
• Both values are non-null references to string instances that have identical lengths and identical characters in each character position.
The string equality operators compare string values rather than string references. When two separate string instances contain the exact same sequence of characters, the values of the strings are equal, but the references are different. As described in §7.9.6, the reference type equality operators can be used to compare string references instead of string values.
7.9.8 Delegate equality operators
Every delegate type implicitly provides the following predefined comparison operators:
bool operator ==(System.Delegate x, System.Delegate y);
bool operator !=(System.Delegate x, System.Delegate y);
Two delegate instances are considered equal as follows:
• If either of the delegate instances is null, they are equal if and only if both are null.
• If either of the delegate instances has an invocation list (§15.1) containing one entry, they are equal if and only if the other also has an invocation list containing one entry, and either:
• both refer to the same static method, or
• both refer to the same non-static method on the same target object.
• If either of the delegate instances has an invocation list containing two or more entries, those instances are equal if and only if their invocation lists are the same length, and each entry in one’s invocation list is equal to the corresponding entry, in order, in the other’s invocation list.
Note that delegates of different types can be considered equal by the above definition, as long as they have the same return type and parameter types.
7.9.9 The is operator
The is operator is used to dynamically check if the run-time type of an object is compatible with a given type. The result of the operation e is T, where e is an expression and T is a type, is a boolean value indicating whether e can successfully be converted to type T by a reference conversion, a boxing conversion, or an unboxing conversion. The operation is evaluated as follows:
• If the compile-time type of e is the same as T, or if an implicit reference conversion (§6.1.4) or boxing conversion (§6.1.5) exists from the compile-time type of e to T:
o If e is of a reference type, the result of the operation is equivalent to evaluating e != null.
o If e is of a value type, the result of the operation is true.
• Otherwise, if an explicit reference conversion (§6.2.3) or unboxing conversion (§6.2.4) exists from the compile-time type of e to T, a dynamic type check is performed:
o If the value of e is null, the result is false.
o Otherwise, let R be the run-time type of the instance referenced by e. If R and T are the same type, if R is a reference type and an implicit reference conversion from R to T exists, or if R is a value type and T is an interface type that is implemented by R, the result is true.
o Otherwise, the result is false.
• Otherwise, no reference or boxing conversion of e to type T is possible, and the result of the operation is false.
Note that the is operator only considers reference conversions, boxing conversions, and unboxing conversions. Other conversions, such as user defined conversions, are not considered by the is operator.
7.9.10 The as operator
The as operator is used to explicitly convert a value to a given reference type using a reference conversion or a boxing conversion. Unlike a cast expression (§7.6.6), the as operator never throws an exception. Instead, if the indicated conversion is not possible, the resulting value is null.
In an operation of the form e as T, e must be an expression and T must be a reference type. The type of the result is T, and the result is always classified as a value. The operation is evaluated as follows:
• If the compile-time type of e is the same as T, the result is simply the value of e.
• Otherwise, if an implicit reference conversion (§6.1.4) or boxing conversion (§6.1.5) exists from the compile-time type of e to T, this conversion is performed and becomes the result of the operation.
• Otherwise, if an explicit reference conversion (§6.2.3) exists from the compile-time type of e to T, a dynamic type check is performed:
o If the value of e is null, the result is the value null with the compile-time type T.
o Otherwise, let R be the run-time type of the instance referenced by e. If R and T are the same type, if R is a reference type and an implicit reference conversion from R to T exists, or if R is a value type and T is an interface type that is implemented by R, the result is the reference given by e with the compile-time type T.
o Otherwise, the result is the value null with the compile-time type T.
• Otherwise, the indicated conversion is never possible, and a compile-time error occurs.
Note that the as operator only performs reference conversions and boxing conversions. Other conversions, such as user defined conversions, are not possible with the as operator and should instead be performed using cast expressions.
7.10 Logical operators
The &, ^, and | operators are called the logical operators.
and-expression:
equality-expression
and-expression & equality-expression
exclusive-or-expression:
and-expression
exclusive-or-expression ^ and-expression
inclusive-or-expression:
exclusive-or-expression
inclusive-or-expression | exclusive-or-expression
For an operation of the form x op y, where op is one of the logical operators, overload resolution (§7.2.4) is applied to select a specific operator implementation. The operands are converted to the parameter types of the selected operator, and the type of the result is the return type of the operator.
The predefined logical operators are described in the following sections.
7.10.1 Integer logical operators
The predefined integer logical operators are:
int operator &(int x, int y);
uint operator &(uint x, uint y);
long operator &(long x, long y);
ulong operator &(ulong x, ulong y);
int operator |(int x, int y);
uint operator |(uint x, uint y);
long operator |(long x, long y);
ulong operator |(ulong x, ulong y);
int operator ^(int x, int y);
uint operator ^(uint x, uint y);
long operator ^(long x, long y);
ulong operator ^(ulong x, ulong y);
The & operator computes the bitwise logical AND of the two operands, the | operator computes the bitwise logical OR of the two operands, and the ^ operator computes the bitwise logical exclusive OR of the two operands. No overflows are possible from these operations.
7.10.2 Enumeration logical operators
Every enumeration type E implicitly provides the following predefined logical operators:
E operator &(E x, E y);
E operator |(E x, E y);
E operator ^(E x, E y);
The result of evaluating x op y, where x and y are expressions of an enumeration type E with an underlying type U, and op is one of the logical operators, is exactly the same as evaluating (E)((U)x op (U)y). In other words, the enumeration type logical operators simply perform the logical operation on the underlying type of the two operands.
7.10.3 Boolean logical operators
The predefined boolean logical operators are:
bool operator &(bool x, bool y);
bool operator |(bool x, bool y);
bool operator ^(bool x, bool y);
The result of x & y is true if both x and y are true. Otherwise, the result is false.
The result of x | y is true if either x or y is true. Otherwise, the result is false.
The result of x ^ y is true if x is true and y is false, or x is false and y is true. Otherwise, the result is false. When the operands are of type bool, the ^ operator computes the same result as the != operator.
7.11 Conditional logical operators
The && and || operators are called the conditional logical operators. They are also called the “short-circuiting” logical operators.
conditional-and-expression:
inclusive-or-expression
conditional-and-expression && inclusive-or-expression
conditional-or-expression:
conditional-and-expression
conditional-or-expression || conditional-and-expression
The && and || operators are conditional versions of the & and | operators:
• The operation x && y corresponds to the operation x & y, except that y is evaluated only if x is true.
• The operation x || y corresponds to the operation x | y, except that y is evaluated only if x is false.
An operation of the form x && y or x || y is processed by applying overload resolution (§7.2.4) as if the operation was written x & y or x | y. Then,
• If overload resolution fails to find a single best operator, or if overload resolution selects one of the predefined integer logical operators, a compile-time error occurs.
• Otherwise, if the selected operator is one of the predefined boolean logical operators (§7.10.2), the operation is processed as described in §7.11.1.
• Otherwise, the selected operator is a user-defined operator, and the operation is processed as described in §7.11.2.
It is not possible to directly overload the conditional logical operators. However, because the conditional logical operators are evaluated in terms of the regular logical operators, overloads of the regular logical operators are, with certain restrictions, also considered overloads of the conditional logical operators. This is described further in §7.11.2.
7.11.1 Boolean conditional logical operators
When the operands of && or || are of type bool, or when the operands are of types that do not define an applicable operator & or operator |, but do define implicit conversions to bool, the operation is processed as follows:
• The operation x && y is evaluated as x? y: false. In other words, x is first evaluated and converted to type bool. Then, if x is true, y is evaluated and converted to type bool, and this becomes the result of the operation. Otherwise, the result of the operation is false.
• The operation x || y is evaluated as x? true: y. In other words, x is first evaluated and converted to type bool. Then, if x is true, the result of the operation is true. Otherwise, y is evaluated and converted to type bool, and this becomes the result of the operation.
7.11.2 User-defined conditional logical operators
When the operands of && or || are of types that declare an applicable user-defined operator & or operator |, both of the following must be true, where T is the type in which the selected operator is declared:
• The return type and the type of each parameter of the selected operator must be T. In other words, the operator must compute the logical AND or the logical OR of two operands of type T, and must return a result of type T.
• T must contain declarations of operator true and operator false.
A compile-time error occurs if either of these requirements is not satisfied. Otherwise, the && or || operation is evaluated by combining the user-defined operator true or operator false with the selected user-defined operator:
• The operation x && y is evaluated as T.false(x)? x: T.&(x, y), where T.false(x) is an invocation of the operator false declared in T, and T.&(x, y) is an invocation of the selected operator &. In other words, x is first evaluated and operator false is invoked on the result to determine if x is definitely false. Then, if x is definitely false, the result of the operation is the value previously computed for x. Otherwise, y is evaluated, and the selected operator & is invoked on the value previously computed for x and the value computed for y to produce the result of the operation.
• The operation x || y is evaluated as T.true(x)? x: T.|(x, y), where T.true(x) is an invocation of the operator true declared in T, and T.|(x, y) is an invocation of the selected operator |. In other words, x is first evaluated and operator true is invoked on the result to determine if x is definitely true. Then, if x is definitely true, the result of the operation is the value previously computed for x. Otherwise, y is evaluated, and the selected operator | is invoked on the value previously computed for x and the value computed for y to produce the result of the operation.
In either of these operations, the expression given by x is only evaluated once, and the expression given by y is either not evaluated or evaluated exactly once.
For an example of a type that implements operator true and operator false, see §11.4.2.
7.12 Conditional operator
The ?: operator is called the conditional operator. It is at times also called the ternary operator.
conditional-expression:
conditional-or-expression
conditional-or-expression ? expression : expression
A conditional expression of the form b? x: y first evaluates the condition b. Then, if b is true, x is evaluated and becomes the result of the operation. Otherwise, y is evaluated and becomes the result of the operation. A conditional expression never evaluates both x and y.
The conditional operator is right-associative, meaning that operations are grouped from right to left. For example, an expression of the form a? b: c? d: e is evaluated as a? b: (c? d: e).
The first operand of the ?: operator must be an expression of a type that can be implicitly converted to bool, or an expression of a type that implements operator true. If neither requirement is satisfied, a compile-time error occurs.
The second and third operands of the ?: operator control the type of the conditional expression. Let X and Y be the types of the second and third operands. Then,
• If X and Y are the same type, then this is the type of the conditional expression.
• Otherwise, if an implicit conversion (§6.1) exists from X to Y, but not from Y to X, then Y is the type of the conditional expression.
• Otherwise, if an implicit conversion (§6.1) exists from Y to X, but not from X to Y, then X is the type of the conditional expression.
• Otherwise, no expression type can be determined, and a compile-time error occurs.
The run-time processing of a conditional expression of the form b? x: y consists of the following steps:
• First, b is evaluated, and the bool value of b is determined:
o If an implicit conversion from the type of b to bool exists, then this implicit conversion is performed to produce a bool value.
o Otherwise, the operator true defined by the type of b is invoked to produce a bool value.
• If the bool value produced by the step above is true, then x is evaluated and converted to the type of the conditional expression, and this becomes the result of the conditional expression.
• Otherwise, y is evaluated and converted to the type of the conditional expression, and this becomes the result of the conditional expression.
7.13 Assignment operators
The assignment operators assign a new value to a variable, a property, an event, or an indexer element.
assignment:
unary-expression assignment-operator expression
assignment-operator: one of
= += -= *= /= %= &= |= ^= <<= >>=
The left operand of an assignment must be an expression classified as a variable, a property access, an indexer access, or an event access.
The = operator is called the simple assignment operator. It assigns the value of the right operand to the variable, property, or indexer element given by the left operand. The left operand of the simple assignment operator may not be an event access (except as described in §10.7.1). The simple assignment operator is described in §7.13.1.
The operators formed by prefixing a binary operator with an = character are called the compound assignment operators. These operators perform the indicated operation on the two operands, and then assign the resulting value to the variable, property, or indexer element given by the left operand. The compound assignment operators are described in §7.13.2.
The += and -= operators with an event access expression as the left operand are called the event assignment operators. No other assignment operator is valid with an event access as the left operand. The event assignment operators are described in §7.13.3.
The assignment operators are right-associative, meaning that operations are grouped from right to left. For example, an expression of the form a = b = c is evaluated as a = (b = c).
7.13.1 Simple assignment
The = operator is called the simple assignment operator. In a simple assignment, the right operand must be an expression of a type that is implicitly convertible to the type of the left operand. The operation assigns the value of the right operand to the variable, property, or indexer element given by the left operand.
The result of a simple assignment expression is the value assigned to the left operand. The result has the same type as the left operand and is always classified as a value.
If the left operand is a property or indexer access, the property or indexer must have a set accessor. If this is not the case, a compile-time error occurs.
The run-time processing of a simple assignment of the form x = y consists of the following steps:
• If x is classified as a variable:
o x is evaluated to produce the variable.
o y is evaluated and, if required, converted to the type of x through an implicit conversion (§6.1).
o If the variable given by x is an array element of a reference-type, a run-time check is performed to ensure that the value computed for y is compatible with the array instance of which x is an element. The check succeeds if y is null, or if an implicit reference conversion (§6.1.4) exists from the actual type of the instance referenced by y to the actual element type of the array instance containing x. Otherwise, a System.ArrayTypeMismatchException is thrown.
o The value resulting from the evaluation and conversion of y is stored into the location given by the evaluation of x.
• If x is classified as a property or indexer access:
o The instance expression (if x is not static) and the argument list (if x is an indexer access) associated with x are evaluated, and the results are used in the subsequent set accessor invocation.
o y is evaluated and, if required, converted to the type of x through an implicit conversion (§6.1).
o The set accessor of x is invoked with the value computed for y as its value argument.
The array co-variance rules (§12.5) permit a value of an array type A[] to be a reference to an instance of an array type B[], provided an implicit reference conversion exists from B to A. Because of these rules, assignment to an array element of a reference-type requires a run-time check to ensure that the value being assigned is compatible with the array instance. In the example
string[] sa = new string[10];
object[] oa = sa;
oa[0] = null; // Ok
oa[1] = "Hello"; // Ok
oa[2] = new ArrayList(); // ArrayTypeMismatchException
the last assignment causes a System.ArrayTypeMismatchException to be thrown because an instance of ArrayList cannot be stored in an element of a string[].
When a property or indexer declared in a struct-type is the target of an assignment, the instance expression associated with the property or indexer access must be classified as a variable. If the instance expression is classified as a value, a compile-time error occurs. Because of §7.5.4, the same rule also applies to fields.
Given the declarations:
struct Point
{
int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
public int X {
get { return x; }
set { x = value; }
}
public int Y {
get { return y; }
set { y = value; }
}
}
struct Rectangle
{
Point a, b;
public Rectangle(Point a, Point b) {
this.a = a;
this.b = b;
}
public Point A {
get { return a; }
set { a = value; }
}
public Point B {
get { return b; }
set { b = value; }
}
}
in the example
Point p = new Point();
p.X = 100;
p.Y = 100;
Rectangle r = new Rectangle();
r.A = new Point(10, 10);
r.B = p;
the assignments to p.X, p.Y, r.A, and r.B are permitted because p and r are variables. However, in the example
Rectangle r = new Rectangle();
r.A.X = 10;
r.A.Y = 10;
r.B.X = 100;
r.B.Y = 100;
the assignments are all invalid, since r.A and r.B are not variables.
7.13.2 Compound assignment
An operation of the form x op= y is processed by applying binary operator overload resolution (§7.2.4) as if the operation was written x op y. Then,
• If the return type of the selected operator is implicitly convertible to the type of x, the operation is evaluated as x = x op y, except that x is evaluated only once.
• Otherwise, if the selected operator is a predefined operator, if the return type of the selected operator is explicitly convertible to the type of x, and if y is implicitly convertible to the type of x, then the operation is evaluated as x = (T)(x op y), where T is the type of x, except that x is evaluated only once.
• Otherwise, the compound assignment is invalid, and a compile-time error occurs.
The term “evaluated only once” means that in the evaluation of x op y, the results of any constituent expressions of x are temporarily saved and then reused when performing the assignment to x. For example, in the assignment A()[B()] += C(), where A is a method returning int[], and B and C are methods returning int, the methods are invoked only once, in the order A, B, C.
When the left operand of a compound assignment is a property access or indexer access, the property or indexer must have both a get accessor and a set accessor. If this is not the case, a compile-time error occurs.
The second rule above permits x op= y to be evaluated as x = (T)(x op y) in certain contexts. The rule exists such that the predefined operators can be used as compound operators when the left operand is of type sbyte, byte, short, ushort, or char. Even when both arguments are of one of those types, the predefined operators produce a result of type int, as described in §7.2.6.2. Thus, without a cast it would not be possible to assign the result to the left operand.
The intuitive effect of the rule for predefined operators is simply that x op= y is permitted if both of x op y and x = y are permitted. In the example
byte b = 0;
char ch = '\0';
int i = 0;
b += 1; // Ok
b += 1000; // Error, b = 1000 not permitted
b += i; // Error, b = i not permitted
b += (byte)i; // Ok
ch += 1; // Error, ch = 1 not permitted
ch += (char)1; // Ok
the intuitive reason for each error is that a corresponding simple assignment would also have been an error.
7.13.3 Event assignment
If the left operand of a += or -= operator is classified as an event access, then the expression is evaluated as follows:
• The instance expression, if any, of the event access is evaluated.
• The right operand of the += or -= operator is evaluated, and, if required, converted to the type of the left operand through an implicit conversion (§6.1).
• An event accessor of the event is invoked, with argument list consisting of the right operand, after evaluation and, if necessary, conversion. If the operator was +=, the add accessor is invoked; if the operator was -=, the remove accessor is invoked.
An event assignment expression does not yield a value. Thus, an event assignment expression is valid only in the context of a statement-expression (§8.6).
7.14 Expression
An expression is either a conditional-expression or an assignment.
expression:
conditional-expression
assignment
7.15 Constant expressions
A constant-expression is an expression that can be fully evaluated at compile-time.
constant-expression:
expression
The type of a constant expression can be one of the following: sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, decimal, bool, string, any enumeration type, or the null type. The following constructs are permitted in constant expressions:
• Literals (including the null literal).
• References to const members of class and struct types.
• References to members of enumeration types.
• Parenthesized sub-expressions, which are themselves constant expressions.
• Cast expressions, provided the target type is one of the types listed above.
• The predefined +, –, !, and ~ unary operators.
• The predefined +, –, *, /, %, <<, >>, &, |, ^, &&, ||, ==, !=, <, >, <=, and >= binary operators, provided each operand is of a type listed above.
• The ?: conditional operator.
Whenever an expression is of one of the types listed above and contains only the constructs listed above, the expression is evaluated at compile-time. This is true even if the expression is a sub-expression of a larger expression that contains non-constant constructs.
The compile-time evaluation of constant expressions uses the same rules as run-time evaluation of non-constant expressions, except that where run-time evaluation would have thrown an exception, compile-time evaluation causes a compile-time error to occur.
Unless a constant expression is explicitly placed in an unchecked context, overflows that occur in integral-type arithmetic operations and conversions during the compile-time evaluation of the expression always cause compile-time errors (§7.5.12).
Constant expressions occur in the contexts listed below. In these contexts, a compile-time error occurs if an expression cannot be fully evaluated at compile-time.
• Constant declarations (§10.3).
• Enumeration member declarations (§14.3).
• case labels of a switch statement (§8.7.2).
• goto case statements (§8.9.3).
• Dimension lengths in an array creation expression (§7.5.10.2) that includes an initializer.
• Attributes (§17).
An implicit constant expression conversion (§6.1.6) permits a constant expression of type int to be converted to sbyte, byte, short, ushort, uint, or ulong, provided the value of the constant expression is within the range of the destination type.
7.16 Boolean expressions
A boolean-expression is an expression that yields a result of type bool.
boolean-expression:
expression
The controlling conditional expression of an if-statement (§8.7.1), while-statement (§8.8.1), do-statement (§8.8.2), or for-statement (§8.8.3) is a boolean-expression. The controlling conditional expression of the ?: operator (§7.12) follows the same rules as a boolean-expression, but for reasons of operator precedence is classified as a conditional-or-expression.
A boolean-expression is required to be of a type that can be implicitly converted to bool or of a type that implements operator true. If neither requirement is satisfied, a compile-time error occurs.
When a boolean expression is of a type that cannot be implicitly converted to bool but does implement operator true, then following evaluation of the expression, the operator true implementation provided by that type is invoked to produce a bool value.
The DBBool struct type in §11.4.2 provides an example of a type that implements operator true and operator false.

8. Statements
C# provides a variety of statements. Most of these statements will be familiar to developers who have programmed in C and C++.
statement:
labeled-statement
declaration-statement
embedded-statement
embedded-statement:
block
empty-statement
expression-statement
selection-statement
iteration-statement
jump-statement
try-statement
checked-statement
unchecked-statement
lock-statement
using-statement
The embedded-statement nonterminal is used for statements that appear within other statements. The use of embedded-statement rather than statement excludes the use of declaration statements and labeled statements in these contexts. For example, the code
void F(bool b) {
if (b)
int i = 44;
}
results in a compile-time error because an if statement requires an embedded-statement rather than a statement for its if branch. If this code were permitted, then the variable i would be declared, but it could never be used.
8.1 End points and reachability
Every statement has an end point. In intuitive terms, the end point of a statement is the location that immediately follows the statement. The execution rules for composite statements (statements that contain embedded statements) specify the action that is taken when control reaches the end point of an embedded statement. For example, when control reaches the end point of a statement in a block, control is transferred to the next statement in the block.
If a statement can possibly be reached by execution, the statement is said to be reachable. Conversely, if there is no possibility that a statement will be executed, the statement is said to be unreachable.
In the example
void F() {
Console.WriteLine("reachable");
goto Label;
Console.WriteLine("unreachable");
Label:
Console.WriteLine("reachable");
}
the second invocation of Console.WriteLine is unreachable because there is no possibility that the statement will be executed.
A warning is reported if the compiler determines that a statement is unreachable. It is specifically not an error for a statement to be unreachable.
To determine whether a particular statement or end point is reachable, the compiler performs flow analysis according to the reachability rules defined for each statement. The flow analysis takes into account the values of constant expressions (§7.15) that control the behavior of statements, but the possible values of non-constant expressions are not considered. In other words, for purposes of control flow analysis, a non-constant expression of a given type is considered to have any possible value of that type.
In the example
void F() {
const int i = 1;
if (i == 2) Console.WriteLine("unreachable");
}
the boolean expression of the if statement is a constant expression because both operands of the == operator are constants. As the constant expression is evaluated at compile-time, producing the value false, the Console.WriteLine invocation is considered unreachable. However, if i is changed to be a local variable
void F() {
int i = 1;
if (i == 2) Console.WriteLine("reachable");
}
the Console.WriteLine invocation is considered reachable, even though it will in reality never be executed.
The block of a function member is always considered reachable. By successively evaluating the reachability rules of each statement in a block, the reachability of any given statement can be determined.
In the example
void F(int x) {
Console.WriteLine("start");
if (x < 0) Console.WriteLine("negative");
}
the reachability of the second Console.WriteLine is determined as follows:
• The first Console.WriteLine expression statement is reachable because the block of the F method is reachable.
• The end point of the first Console.WriteLine expression statement is reachable because that statement is reachable.
• The if statement is reachable because the end point of the first Console.WriteLine expression statement is reachable.
• The second Console.WriteLine expression statement is reachable because the boolean expression of the if statement does not have the constant value false.
There are two situations in which it is a compile-time error for the end point of a statement to be reachable:
• Because the switch statement does not permit a switch section to “fall through” to the next switch section, it is a compile-time error for the end point of the statement list of a switch section to be reachable. If this error occurs, it is typically an indication that a break statement is missing.
• It is a compile-time error for the end point of the block of a function member that computes a value to be reachable. If this error occurs, it is typically an indication that a return statement is missing.
8.2 Blocks
A block permits multiple statements to be written in contexts where a single statement is allowed.
block:
{ statement-listopt }
A block consists of an optional statement-list (§8.2.1), enclosed in braces. If the statement list is omitted, the block is said to be empty.
A block may contain declaration statements (§8.5). The scope of a local variable or constant declared in a block is the block.
Within a block, the meaning of a name used in an expression context must always be the same (§7.5.2.1).
A block is executed as follows:
• If the block is empty, control is transferred to the end point of the block.
• If the block is not empty, control is transferred to the statement list. When and if control reaches the end point of the statement list, control is transferred to the end point of the block.
The statement list of a block is reachable if the block itself is reachable.
The end point of a block is reachable if the block is empty or if the end point of the statement list is reachable.
8.2.1 Statement lists
A statement list consists of one or more statements written in sequence. Statement lists occur in blocks (§8.2) and in switch-blocks (§8.7.2).
statement-list:
statement
statement-list statement
A statement list is executed by transferring control to the first statement. When and if control reaches the end point of a statement, control is transferred to the next statement. When and if control reaches the end point of the last statement, control is transferred to the end point of the statement list.
A statement in a statement list is reachable if at least one of the following is true:
• The statement is the first statement and the statement list itself is reachable.
• The end point of the preceding statement is reachable.
• The statement is a labeled statement and the label is referenced by a reachable goto statement.
The end point of a statement list is reachable if the end point of the last statement in the list is reachable.
8.3 The empty statement
An empty-statement does nothing.
empty-statement:
;
An empty statement is used when there are no operations to perform in a context where a statement is required.
Execution of an empty statement simply transfers control to the end point of the statement. Thus, the end point of an empty statement is reachable if the empty statement is reachable.
An empty statement can be used when writing a while statement with a null body:
bool ProcessMessage() {...}
void ProcessMessages() {
while (ProcessMessage())
;
}
Also, an empty statement can be used to declare a label just before the closing “}” of a block:
void F() {
...
if (done) goto exit;
...
exit: ;
}
8.4 Labeled statements
A labeled-statement permits a statement to be prefixed by a label. Labeled statements are permitted in blocks, but are not permitted as embedded statements.
labeled-statement:
identifier : statement
A labeled statement declares a label with the name given by the identifier. The scope of a label is the block in which the label is declared, including any nested blocks. It is a compile-time error for two labels with the same name to have overlapping scopes.
A label can be referenced from goto statements (§8.9.3) within the scope of the label. This means that goto statements can transfer control within blocks and out of blocks, but never into blocks.
Labels have their own declaration space and do not interfere with other identifiers. The example
int F(int x) {
if (x >= 0) goto x;
x = -x;
x: return x;
}
is valid and uses the name x as both a parameter and a label.
Execution of a labeled statement corresponds exactly to execution of the statement following the label.
In addition to the reachability provided by normal flow of control, a labeled statement is reachable if the label is referenced by a reachable goto statement. (Exception: If a goto statement is inside a try that includes a finally block, and the labeled statement is outside the try, and the end point of the finally block is unreachable, then the labeled statement is not reachable from that goto statement.)
8.5 Declaration statements
A declaration-statement declares a local variable or constant. Declaration statements are permitted in blocks, but are not permitted as embedded statements.
declaration-statement:
local-variable-declaration ;
local-constant-declaration ;
8.5.1 Local variable declarations
A local-variable-declaration declares one or more local variables.
local-variable-declaration:
type local- variable-declarators
local-variable-declarators:
local-variable-declarator
local-variable-declarators , local-variable-declarator
local-variable-declarator:
identifier
identifier = local-variable-initializer
local-variable-initializer:
expression
array-initializer
The type of a local-variable-declaration specifies the type of the variables introduced by the declaration. The type is followed by a list of local-variable-declarators, each of which introduces a new variable. A local-variable-declarator consists of an identifier that names the variable, optionally followed by an “=” token and a local-variable-initializer that gives the initial value of the variable.
The value of a local variable is obtained in an expression using a simple-name (§7.5.2), and the value of a local variable is modified using an assignment (§7.13). A local variable must be definitely assigned (§5.3) at each location where its value is obtained.
The scope of a local variable declared in a local-variable-declaration is the block in which the declaration occurs. It is a compile-time error to refer to a local variable in a textual position that precedes the local-variable-declarator of the local variable. Within the scope of a local variable, it is a compile-time error to declare another local variable or constant with the same name.
A local variable declaration that declares multiple variables is equivalent to multiple declarations of single variables with the same type. Furthermore, a variable initializer in a local variable declaration corresponds exactly to an assignment statement that is inserted immediately after the declaration.
The example
void F() {
int x = 1, y, z = x * 2;
}
corresponds exactly to
void F() {
int x; x = 1;
int y;
int z; z = x * 2;
}
8.5.2 Local constant declarations
A local-constant-declaration declares one or more local constants.
local-constant-declaration:
const type constant-declarators
constant-declarators:
constant-declarator
constant-declarators , constant-declarator
constant-declarator:
identifier = constant-expression
The type of a local-constant-declaration specifies the type of the constants introduced by the declaration. The type is followed by a list of constant-declarators, each of which introduces a new constant. A constant-declarator consists of an identifier that names the constant, followed by an “=” token, followed by a constant-expression (§7.15) that gives the value of the constant.
The type and constant-expression of a local constant declaration must follow the same rules as those of a constant member declaration (§10.3).
The value of a local constant is obtained in an expression using a simple-name (§7.5.2).
The scope of a local constant is the block in which the declaration occurs. It is a compile-time error to refer to a local constant in a textual position that precedes its constant-declarator. Within the scope of a local constant, it is a compile-time error to declare another local variable or constant with the same name.
A local constant declaration that declares multiple constants is equivalent to multiple declarations of single constants with the same type.
8.6 Expression statements
An expression-statement evaluates a given expression. The value computed by the expression, if any, is discarded.
expression-statement:
statement-expression ;
statement-expression:
invocation-expression
object-creation-expression
assignment
post-increment-expression
post-decrement-expression
pre-increment-expression
pre-decrement-expression
Not all expressions are permitted as statement-expressions. In particular, expressions such as x + y and x == 1 that merely compute a value (which will be discarded), are not permitted as statement-expressions.
Execution of an expression-statement evaluates the contained statement-expression and then transfers control to the end point of the expression-statement. The end point of an expression-statement is reachable if that expression-statement is reachable.
8.7 Selection statements
Selection statements select one of a number of possible statements for execution based on the value of an expression.
selection-statement:
if-statement
switch-statement
8.7.1 The if statement
The if statement selects a statement for execution based on the value of a boolean expression.
if-statement:
if ( boolean-expression ) embedded-statement
if ( boolean-expression ) embedded-statement else embedded-statement
boolean-expression:
expression
An else part is associated with the lexically nearest preceding if statement that is allowed by the syntax. Thus, an if statement of the form
if (x) if (y) F(); else G();
is equivalent to
if (x) {
if (y) {
F();
}
else {
G();
}
}
An if statement is executed as follows:
• The boolean-expression (§7.16) is evaluated.
• If the boolean expression yields true, control is transferred to the first embedded statement. When and if control reaches the end point of that statement, control is transferred to the end point of the if statement.
• If the boolean expression yields false and if an else part is present, control is transferred to the second embedded statement. When and if control reaches the end point of that statement, control is transferred to the end point of the if statement.
• If the boolean expression yields false and if an else part is not present, control is transferred to the end point of the if statement.
The first embedded statement of an if statement is reachable if the if statement is reachable and the boolean expression does not have the constant value false.
The second embedded statement of an if statement, if present, is reachable if the if statement is reachable and the boolean expression does not have the constant value true.
The end point of an if statement is reachable if the end point of at least one of its embedded statements is reachable. In addition, the end point of an if statement with no else part is reachable if the if statement is reachable and the boolean expression does not have the constant value true.
8.7.2 The switch statement
The switch statement selects for execution a statement list having an associated switch label that corresponds to the value of the switch expression.
switch-statement:
switch ( expression ) switch-block
switch-block:
{ switch-sectionsopt }
switch-sections:
switch-section
switch-sections switch-section
switch-section:
switch-labels statement-list
switch-labels:
switch-label
switch-labels switch-label
switch-label:
case constant-expression :
default :
A switch-statement consists of the keyword switch, followed by a parenthesized expression (called the switch expression), followed by a switch-block. The switch-block consists of zero or more switch-sections, enclosed in braces. Each switch-section consists of one or more switch-labels followed by a statement-list (§8.2.1).
The governing type of a switch statement is established by the switch expression. If the type of the switch expression is sbyte, byte, short, ushort, int, uint, long, ulong, char, string, or an enum-type, then that is the governing type of the switch statement. Otherwise, exactly one user-defined implicit conversion (§6.4) must exist from the type of the switch expression to one of the following possible governing types: sbyte, byte, short, ushort, int, uint, long, ulong, char, string. If no such implicit conversion exists, or if more than one such implicit conversion exists, a compile-time error occurs.
The constant expression of each case label must denote a value of a type that is implicitly convertible (§6.1) to the governing type of the switch statement. A compile-time error occurs if two or more case labels in the same switch statement specify the same constant value.
There can be at most one default label in a switch statement.
A switch statement is executed as follows:
• The switch expression is evaluated and converted to the governing type.
• If one of the constants specified in a case label in the same switch statement is equal to the value of the switch expression, control is transferred to the statement list following the matched case label.
• If none of the constants specified in case labels in the same switch statement, is equal to the value of the switch expression, and if a default label is present, control is transferred to the statement list following the default label.
• If none of the constants specified in case labels in the same switch statement, is equal to the value of the switch expression, and if no default label is present, control is transferred to the end point of the switch statement.
If the end point of the statement list of a switch section is reachable, a compile-time error occurs. This is known as the “no fall through” rule. The example
switch (i) {
case 0:
CaseZero();
break;
case 1:
CaseOne();
break;
default:
CaseOthers();
break;
}
is valid because no switch section has a reachable end point. Unlike C and C++, execution of a switch section is not permitted to “fall through” to the next switch section, and the example
switch (i) {
case 0:
CaseZero();
case 1:
CaseZeroOrOne();
default:
CaseAny();
}
results in a compile-time error. When execution of a switch section is to be followed by execution of another switch section, an explicit goto case or goto default statement must be used:
switch (i) {
case 0:
CaseZero();
goto case 1;
case 1:
CaseZeroOrOne();
goto default;
default:
CaseAny();
break;
}
Multiple labels are permitted in a switch-section. The example
switch (i) {
case 0:
CaseZero();
break;
case 1:
CaseOne();
break;
case 2:
default:
CaseTwo();
break;
}
is valid. The example does not violate the “no fall through” rule because the labels case 2: and default: are part of the same switch-section.
The “no fall through” rule prevents a common class of bugs that occur in C and C++ when break statements are accidentally omitted. Also, because of this rule, the switch sections of a switch statement can be arbitrarily rearranged without affecting the behavior of the statement. For example, the sections of the switch statement above can be reversed without affecting the behavior of the statement:
switch (i) {
default:
CaseAny();
break;
case 1:
CaseZeroOrOne();
goto default;
case 0:
CaseZero();
goto case 1;
}
The statement list of a switch section typically ends in a break, goto case, or goto default statement, but any construct that renders the end point of the statement list unreachable is permitted. For example, a while statement controlled by the boolean expression true is known to never reach its end point. Likewise, a throw or return statement always transfers control elsewhere and never reaches its end point. Thus, the following example is valid:
switch (i) {
case 0:
while (true) F();
case 1:
throw new ArgumentException();
case 2:
return;
}
The governing type of a switch statement may be the type string. For example:
void DoCommand(string command) {
switch (command.ToLower()) {
case "run":
DoRun();
break;
case "save":
DoSave();
break;
case "quit":
DoQuit();
break;
default:
InvalidCommand(command);
break;
}
}
Like the string equality operators (§7.9.7), the switch statement is case sensitive and will execute a given switch section only if the switch expression string exactly matches a case label constant.
When the governing type of a switch statement is string, the value null is permitted as a case label constant.
The statement-lists of a switch-block may contain declaration statements (§8.5). The scope of a local variable or constant declared in a switch block is the switch block.
Within a switch block, the meaning of a name used in an expression context must always be the same (§7.5.2.1).
The statement list of a given switch section is reachable if the switch statement is reachable and at least one of the following is true:
• The switch expression is a non-constant value.
• The switch expression is a constant value that matches a case label in the switch section.
• The switch expression is a constant value that doesn’t match any case label, and the switch section contains the default label.
• A switch label of the switch section is referenced by a reachable goto case or goto default statement.
The end point of a switch statement is reachable if at least one of the following is true:
• The switch statement contains a reachable break statement that exits the switch statement.
• The switch statement is reachable, the switch expression is a non-constant value, and no default label is present.
• The switch statement is reachable, the switch expression is a constant value that doesn’t match any case label, and no default label is present.
8.8 Iteration statements
Iteration statements repeatedly execute an embedded statement.
iteration-statement:
while-statement
do-statement
for-statement
foreach-statement
8.8.1 The while statement
The while statement conditionally executes an embedded statement zero or more times.
while-statement:
while ( boolean-expression ) embedded-statement
A while statement is executed as follows:
• The boolean-expression (§7.16) is evaluated.
• If the boolean expression yields true, control is transferred to the embedded statement. When and if control reaches the end point of the embedded statement (possibly from execution of a continue statement), control is transferred to the beginning of the while statement.
• If the boolean expression yields false, control is transferred to the end point of the while statement.
Within the embedded statement of a while statement, a break statement (§8.9.1) may be used to transfer control to the end point of the while statement (thus ending iteration of the embedded statement), and a continue statement (§8.9.2) may be used to transfer control to the end point of the embedded statement (thus performing another iteration of the while statement).
The embedded statement of a while statement is reachable if the while statement is reachable and the boolean expression does not have the constant value false.
The end point of a while statement is reachable if at least one of the following is true:
• The while statement contains a reachable break statement that exits the while statement.
• The while statement is reachable and the boolean expression does not have the constant value true.
8.8.2 The do statement
The do statement conditionally executes an embedded statement one or more times.
do-statement:
do embedded-statement while ( boolean-expression ) ;
A do statement is executed as follows:
• Control is transferred to the embedded statement.
• When and if control reaches the end point of the embedded statement (possibly from execution of a continue statement), the boolean-expression (§7.16) is evaluated. If the boolean expression yields true, control is transferred to the beginning of the do statement. Otherwise, control is transferred to the end point of the do statement.
Within the embedded statement of a do statement, a break statement (§8.9.1) may be used to transfer control to the end point of the do statement (thus ending iteration of the embedded statement), and a continue statement (§8.9.2) may be used to transfer control to the end point of the embedded statement (thus performing another iteration of the do statement).
The embedded statement of a do statement is reachable if the do statement is reachable.
The end point of a do statement is reachable if at least one of the following is true:
• The do statement contains a reachable break statement that exits the do statement.
• The end point of the embedded statement is reachable and the boolean expression does not have the constant value true.
8.8.3 The for statement
The for statement evaluates a sequence of initialization expressions and then, while a condition is true, repeatedly executes an embedded statement and evaluates a sequence of iteration expressions.
for-statement:
for ( for-initializeropt ; for-conditionopt ; for-iteratoropt ) embedded-statement
for-initializer:
local-variable-declaration
statement-expression-list
for-condition:
boolean-expression
for-iterator:
statement-expression-list
statement-expression-list:
statement-expression
statement-expression-list , statement-expression
The for-initializer, if present, consists of either a local-variable-declaration (§8.5.1) or a list of statement-expressions (§8.6) separated by commas. The scope of a local variable declared by a for-initializer starts at the local-variable-declarator for the variable and extends to the end of the embedded statement. The scope includes the for-condition and the for-iterator.
The for-condition, if present, must be a boolean-expression (§7.16).
The for-iterator, if present, consists of a list of statement-expressions (§8.6) separated by commas.
A for statement is executed as follows:
• If a for-initializer is present, the variable initializers or statement expressions are executed in the order they are written. This step is only performed once.
• If a for-condition is present, it is evaluated.
• If the for-condition is not present or if the evaluation yields true, control is transferred to the embedded statement. When and if control reaches the end point of the embedded statement (possibly from execution of a continue statement), the expressions of the for-iterator, if any, are evaluated in sequence, and then another iteration is performed, starting with evaluation of the for-condition in the step above.
• If the for-condition is present and the evaluation yields false, control is transferred to the end point of the for statement.
Within the embedded statement of a for statement, a break statement (§8.9.1) may be used to transfer control to the end point of the for statement (thus ending iteration of the embedded statement), and a continue statement (§8.9.2) may be used to transfer control to the end point of the embedded statement (thus executing another iteration of the for statement).
The embedded statement of a for statement is reachable if one of the following is true:
• The for statement is reachable and no for-condition is present.
• The for statement is reachable and a for-condition is present and does not have the constant value false.
The end point of a for statement is reachable if at least one of the following is true:
• The for statement contains a reachable break statement that exits the for statement.
• The for statement is reachable and a for-condition is present and does not have the constant value true.
8.8.4 The foreach statement
The foreach statement enumerates the elements of a collection, executing an embedded statement for each element of the collection.
foreach-statement:
foreach ( type identifier in expression ) embedded-statement
The type and identifier of a foreach statement declare the iteration variable of the statement. The iteration variable corresponds to a read-only local variable with a scope that extends over the embedded statement. During execution of a foreach statement, the iteration variable represents the collection element for which an iteration is currently being performed. A compile-time error occurs if the embedded statement attempts to modifythe iteration variable (via assignment or the ++ and operators) or pass the iteration variable as a ref or out parameter.
The type of the expression of a foreach statement must be a collection type (as defined below), and an explicit conversion (§6.2) must exist from the element type of the collection to the type of the iteration variable.
A type C is said to be a collection type if it implements the System.IEnumerable interface or implements the collection pattern by meeting all of the following criteria:
• C contains a public instance method with the signature GetEnumerator() that returns a struct-type, class-type, or interface-type, which is called E in the following text.
• E contains a public instance method with the signature MoveNext() and the return type bool.
• E contains a public instance property named Current that permits reading the current value. The type of this property is said to be the element type of the collection type.
The System.Array type (§12.1.1) is a collection type, and since all array types derive from System.Array, any array type expression is permitted in a foreach statement. The order in which foreach traverses the elements of an array is defined as follows. The elements of single-dimensional arrays are traversed in increasing index order, starting with index 0 and ending with index Length – 1. The elements of multi-dimensional arrays elements are traversed such that the indices of the rightmost dimension are increased first, then the next left dimension, and so on to the left.
A foreach statement is executed as follows:
• The collection expression is evaluated to produce an instance of the collection type. This instance is referred to as c in the following. If c is of a reference-type and has the value null, a System.NullReferenceException is thrown.
• If the collection type C implements the collection pattern defined above and E implements the System.IDisposable interface then:
o An enumerator instance is obtained by evaluating the method invocation c.GetEnumerator(). The returned enumerator is stored in a temporary local variable, in the following referred to as enumerator. It is not possible for the embedded statement to access this temporary variable. If enumerator is of a reference-type and has the value null, a System.NullReferenceException is thrown.
o A try-statement (§8.10) consisting of a try block followed by a finally block is executed:
• The try block consists of the execution of the core iteration steps, as described below.
• The finally block disposes the enumerator by converting enumerator to System.IDisposable and calling the Dispose method. Because E implements Sytsem.IDisposable, the conversion is guaranteed to succeed.
• Otherwise, if the collection type C implements the collection pattern defined above and E does not implement the System.IDisposable interface then:
o An enumerator instance is obtained by evaluating the method invocation c.GetEnumerator(). The returned enumerator is stored in a temporary local variable, in the following referred to as enumerator. It is not possible for the embedded statement to access this temporary variable. If enumerator is of a reference-type and has the value null, a System.NullReferenceException is thrown.
o The core execution steps are executed, as described below.
• Otherwise, C implements System.IEnumerable, and statement execution proceeds as follows:
o An enumerable instance is obtained by casting c to the System.IEnumerable interface. The returned instance is stored in a temporary local variable, in the following referred to as enumerable. It is not possible for the embedded statement to access this temporary variable.
o An enumerator instance is obtained by evaluating the method invocation enumerable.GetEnumerator(). The returned enumerator is stored in a temporary local variable, in the following referred to as enumerator. It is not possible for the embedded statement to access this temporary variable. If enumerator has the value null, a System.NullReferenceException is thrown.
o A try-statement (§8.10) consisting of a try block followed by a finally block is executed:
• The try block consists of the execution of the core iteration steps, as described below.
• The finally block consists of the following steps:
o Evaluate the expression (enumerator as System.IDisposable) and store the result in a temporary local variable, in the following referred to as disposable.
o If disposable is non-null then call its Dispose method.
The embedded statement of a foreach statement is reachable if the foreach statement is reachable. Likewise, the end point of a foreach statement is reachable if the foreach statement is reachable.
The core iteration steps, which are referred to above, are as follows:
• The enumerator is advanced to the next element by evaluating the method invocation enumerator.MoveNext().
• If the value returned by enumerator.MoveNext() is true, the following steps are performed:
o The current enumerator value is obtained by evaluating the property access enumerator.Current, and the value is converted to the type of the iteration variable by an explicit conversion (§6.2). The resulting value is stored in the iteration variable such that it can be accessed in the embedded statement.
o Control is transferred to the embedded statement. When and if control reaches the end point of the embedded statement (possibly from execution of a continue statement), another foreach iteration is performed, starting with the step above that advances the enumerator.
• If the value returned by e.MoveNext() is false, control is transferred to the end point of the foreach statement.
The following example prints out each value in a two-dimensional array, in element order:
class Test
{
static void Main() {
double[,] values = { {1.2, 2.3, 3.4, 4.5},
{5.6, 6.7, 7.8, 8.9} };
foreach (double elementValue in values)
Console.Write("{0} ", elementValue);
Console.WriteLine();
}
}
The output is:
1.2 2.3 3.4 4.5 5.6 6.7 7.8 8.9
8.9 Jump statements
Jump statements unconditionally transfer control.
jump-statement:
break-statement
continue-statement
goto-statement
return-statement
throw-statement
The location to which a jump statement transfers control is called the target of the jump statement.
When a jump statement occurs within a block, and when the target of the jump statement is outside that block, the jump statement is said to exit the block. While a jump statement may transfer control out of a block, it can never transfer control into a block.
Execution of jump statements is complicated by the presence of intervening try statements. In the absence of such try statements, a jump statement unconditionally transfers control from the jump statement to its target. In the presence of such intervening try statements, execution is more complex. If the jump statement exits one or more try blocks with associated finally blocks, control is initially transferred to the finally block of the innermost try statement. When and if control reaches the end point of a finally block, control is transferred to the finally block of the next enclosing try statement. This process is repeated until the finally blocks of all intervening try statements have been executed.
In the example
class Test
{
static void Main() {
while (true) {
try {
try {
Console.WriteLine("Before break");
break;
}
finally {
Console.WriteLine("Innermost finally block");
}
}
finally {
Console.WriteLine("Outermost finally block");
}
}
Console.WriteLine("After break");
}
}
the finally blocks associated with two try statements are executed before control is transferred to the target of the jump statement.
The example produces the output:
Before break
Innermost finally block
Outermost finally block
After break
8.9.1 The break statement
The break statement exits the nearest enclosing switch, while, do, for, or foreach statement.
break-statement:
break ;
The target of a break statement is the end point of the nearest enclosing switch, while, do, for, or foreach statement. If a break statement is not enclosed by a switch, while, do, for, or foreach statement, a compile-time error occurs.
When multiple switch, while, do, for, or foreach statements are nested within each other, a break statement applies only to the innermost statement. To transfer control across multiple nesting levels, a goto statement (§8.9.3) must be used.
A break statement cannot exit a finally block (§8.10). When a break statement occurs within a finally block, the target of the break statement must be within the same finally block. Otherwise, a compile-time error occurs.
A break statement is executed as follows:
• If the break statement exits one or more try blocks with associated finally blocks, control is initially transferred to the finally block of the innermost try statement. When and if control reaches the end point of a finally block, control is transferred to the finally block of the next enclosing try statement. This process is repeated until the finally blocks of all intervening try statements have been executed.
• Control is transferred to the target of the break statement.
Because a break statement unconditionally transfers control elsewhere, the end point of a break statement is never reachable.
8.9.2 The continue statement
The continue statement starts a new iteration of the nearest enclosing while, do, for, or foreach statement.
continue-statement:
continue ;
The target of a continue statement is the end point of the embedded statement of the nearest enclosing while, do, for, or foreach statement. If a continue statement is not enclosed by a while, do, for, or foreach statement, a compile-time error occurs.
When multiple while, do, for, or foreach statements are nested within each other, a continue statement applies only to the innermost statement. To transfer control across multiple nesting levels, a goto statement (§8.9.3) must be used.
A continue statement cannot exit a finally block (§8.10). When a continue statement occurs within a finally block, the target of the continue statement must be within the same finally block. Otherwise a compile-time error occurs.
A continue statement is executed as follows:
• If the continue statement exits one or more try blocks with associated finally blocks, control is initially transferred to the finally block of the innermost try statement. When and if control reaches the end point of a finally block, control is transferred to the finally block of the next enclosing try statement. This process is repeated until the finally blocks of all intervening try statements have been executed.
• Control is transferred to the target of the continue statement.
Because a continue statement unconditionally transfers control elsewhere, the end point of a continue statement is never reachable.
8.9.3 The goto statement
The goto statement transfers control to a statement that is marked by a label.
goto-statement:
goto identifier ;
goto case constant-expression ;
goto default ;
The target of a goto identifier statement is the labeled statement with the given label. If a label with the given name does not exist in the current function member, or if the goto statement is not within the scope of the label, a compile-time error occurs. This rule permits the use of a goto statement to transfer control out of a nested scope, but not into a nested scope. In the example
class Test
{
static void Main(string[] args) {
string[,] table = { {"red", "blue", "green"},
{"Monday", "Wednesday", "Friday"} };
foreach (string str in args) {
int row, colm;
for (row = 0; row <= 1; ++row) {
for (colm = 0; colm <= 2; ++colm) {
if (str == table[row,colm]) {
goto done;
}
}
}
Console.WriteLine("{0} not found", str);
continue;
done:
Console.WriteLine("Found {0} at [{1}][{2}]", str, row, colm);
}
}
}a goto statement is used to transfer control out of a nested scope.
The target of a goto case statement is the statement list in the immediately enclosing switch statement (§8.7.2) which contains a case label with the given constant value. If the goto case statement is not enclosed by a switch statement, if the constant-expression is not implicitly convertible (§6.1) to the governing type of the nearest enclosing switch statement, or if the nearest enclosing switch statement does not contain a case label with the given constant value, a compile-time error occurs.
The target of a goto default statement is the statement list in the immediately enclosing switch statement (§8.7.2) which contains a default label. If the goto default statement is not enclosed by a switch statement, or if the nearest enclosing switch statement does not contain a default label, a compile-time error occurs.
A goto statement cannot exit a finally block (§8.10). When a goto statement occurs within a finally block, the target of the goto statement must be within the same finally block, or otherwise a compile-time error occurs.
A goto statement is executed as follows:
• If the goto statement exits one or more try blocks with associated finally blocks, control is initially transferred to the finally block of the innermost try statement. When and if control reaches the end point of a finally block, control is transferred to the finally block of the next enclosing try statement. This process is repeated until the finally blocks of all intervening try statements have been executed.
• Control is transferred to the target of the goto statement.
Because a goto statement unconditionally transfers control elsewhere, the end point of a goto statement is never reachable.
8.9.4 The return statement
The return statement returns control to the caller of the function member in which the return statement appears.
return-statement:
return expressionopt ;
A return statement with no expression can be used only in a function member that does not compute a value, that is, a method with the return type void, the set accessor of a property or indexer, the add and remove accessors of an event, an instance constructor, a destructor or a static constructor.
A return statement with an expression can be used only in a function member that computes a value, that is, a method with a non-void return type, the get accessor of a property or indexer, or a user-defined operator. An implicit conversion (§6.1) must exist from the type of the expression to the return type of the containing function member.
It is a compile-time error for a return statement to appear in a finally block (§8.10).
A return statement is executed as follows:
• If the return statement specifies an expression, the expression is evaluated and the resulting value is converted to the return type of the containing function member by an implicit conversion. The result of the conversion becomes the value returned to the caller.
• If the return statement is enclosed by one or more try blocks with associated finally blocks, control is initially transferred to the finally block of the innermost try statement. When and if control reaches the end point of a finally block, control is transferred to the finally block of the next enclosing try statement. This process is repeated until the finally blocks of all enclosing try statements have been executed.
• Control is returned to the caller of the containing function member.
Because a return statement unconditionally transfers control elsewhere, the end point of a return statement is never reachable.
8.9.5 The throw statement
The throw statement throws an exception.
throw-statement:
throw expressionopt ;
A throw statement with an expression throws the value produced by evaluating the expression. The expression must denote a value of the class type System.Exception or of a class type that derives from System.Exception. If evaluation of the expression produces null, a System.NullReferenceException is thrown instead.
A throw statement with no expression can be used only in a catch block, in which case it re-throws the exception that is currently being handled by the catch block.
Because a throw statement unconditionally transfers control elsewhere, the end point of a throw statement is never reachable.
When an exception is thrown, control is transferred to the first catch clause in an enclosing try statement that can handle the exception. The process that takes place from the point of the exception being thrown to the point of transferring control to a suitable exception handler is known as exception propagation. Propagation of an exception consists of repeatedly evaluating the following steps until a catch clause that matches the exception is found. In this description, the throw point is initially the location at which the exception is thrown.
• In the current function member, each try statement that encloses the throw point is examined. For each statement S, starting with the innermost try statement and ending with the outermost try statement, the following steps are evaluated:
o If the try block of S encloses the throw point and if S has one or more catch clauses, the catch clauses are examined in order of appearance to locate a suitable handler for the exception. The first catch clause that specifies the exception type or a base type of the exception type is considered a match. A general catch clause (§8.10) is considered a match for any exception type. If a matching catch clause is located, the exception propagation is completed by transferring control to the block of that catch clause.
o Otherwise, if the try block or a catch block of S encloses the throw point and if S has a finally block, control is transferred to the finally block. If the finally block throws another exception, processing of the current exception is terminated. Otherwise, when control reaches the end point of the finally block, processing of the current exception is continued.
• If an exception handler was not located in the current function member invocation, the function member invocation is terminated. The steps above are then repeated for the caller of the function member with a throw point corresponding to the statement from which the function member was invoked.
• If the exception processing terminates all function member invocations in the current thread, indicating that the thread has no handler for the exception, then the thread is itself terminated. The impact of such termination is implementation-defined.
8.10 The try statement
The try statement provides a mechanism for catching exceptions that occur during execution of a block. The try statement furthermore provides the ability to specify a block of code that is always executed when control leaves the try statement.
try-statement:
try block catch-clauses
try block finally-clause
try block catch-clauses finally-clause
catch-clauses:
specific-catch-clauses general-catch-clauseopt
specific-catch-clausesopt general-catch-clause
specific-catch-clauses:
specific-catch-clause
specific-catch-clauses specific-catch-clause
specific-catch-clause:
catch ( class-type identifieropt ) block
general-catch-clause:
catch block
finally-clause:
finally block
There are three possible forms of try statements:
• A try block followed by one or more catch blocks.
• A try block followed by a finally block.
• A try block followed by one or more catch blocks followed by a finally block.
When a catch clause specifies a class-type, the type must be System.Exception or a type that derives from System.Exception.
When a catch clause specifies both a class-type and an identifier, an exception variable of the given name and type is declared. The exception variable corresponds to a local variable with a scope that extends over the catch block. During execution of the catch block, the exception variable represents the exception currently being handled. For the purpose of definite assignment checking, the exception variable is considered definitely assigned in its entire scope.
Unless a catch clause includes an exception variable name, it is impossible to access the exception object in the catch block.
A catch clause that specifies neither an exception type nor an exception variable name is called a general catch clause. A try statement can only have one general catch clause, and if one is present it must be the last catch clause.
Though the throw statement is restricted to throwing exceptions of type System.Exception or a type that derives from System.Exception, other languages are not bound by this rule, and so may throw exceptions of other types. A general catch clause can be used to catch such exceptions, and a throw statement with no expression can be used to re-throw them.
In order to locate a handler for an exception, catch clauses are examined in lexical order. A compile-time error occurs if a catch clause specifies a type that is the same as or derived from a type that was specified in an earlier catch clause for the same try. Without this restriction it would be possible to write unreachable catch clauses.
Within a catch block, a throw statement (§8.9.5) with no expression can be used to re-throw the exception that was caught by the catch block. Assignments to an exception variable do not alter the exception that is re-thrown.
In the example
class Test
{
static void F() {
try {
G();
}
catch (Exception e) {
Console.WriteLine("Exception in F: " + e.Message);
e = new Exception("F");
throw; // re-throw
}
}
static void G() {
throw new Exception("G");
}
static void Main() {
try {
F();
}
catch (Exception e) {
Console.WriteLine("Exception in Main: " + e.Message);
}
}
}
the method F catches an exception, writes some diagnostic information to the console, alters the exception variable, and re-throws the exception. The exception that is re-thrown is the original exception, so the output produced is:
Exception in F: G
Exception in Main: G
If the first catch block had thrown e instead of rethrowing the current exception, the output produced is would be as follows:
Exception in F: G
Exception in Main: F
It is a compile-time error for a break, continue, or goto statement to transfer control out of a finally block. When a break, continue, or goto statement occurs in a finally block, the target of the statement must be within the same finally block, or otherwise a compile-time error occurs.
It is a compile-time error for a return statement to occur in a finally block.
A try statement is executed as follows:
• Control is transferred to the try block.
• When and if control reaches the end point of the try block:
o If the try statement has a finally block, the finally block is executed.
o Control is transferred to the end point of the try statement.
• If an exception is propagated to the try statement during execution of the try block:
o The catch clauses, if any, are examined in order of appearance to locate a suitable handler for the exception. The first catch clause that specifies the exception type or a base type of the exception type is considered a match. A general catch clause is considered a match for any exception type. If a matching catch clause is located:
• If the matching catch clause declares an exception variable, the exception object is assigned to the exception variable.
• Control is transferred to the matching catch block.
• When and if control reaches the end point of the catch block:
o If the try statement has a finally block, the finally block is executed.
o Control is transferred to the end point of the try statement.
• If an exception is propagated to the try statement during execution of the catch block:
o If the try statement has a finally block, the finally block is executed.
o The exception is propagated to the next enclosing try statement.
o If the try statement has no catch clauses or if no catch clause matches the exception:
• If the try statement has a finally block, the finally block is executed.
• The exception is propagated to the next enclosing try statement.
The statements of a finally block are always executed when control leaves a try statement. This is true whether the control transfer occurs as a result of normal execution, as a result of executing a break, continue, goto, or return statement, or as a result of propagating an exception out of the try statement.
If an exception is thrown during execution of a finally block, the exception is propagated to the next enclosing try statement. If another exception was in the process of being propagated, that exception is lost. The process of propagating an exception is discussed further in the description of the throw statement (§8.9.5).
The try block of a try statement is reachable if the try statement is reachable.
A catch block of a try statement is reachable if the try statement is reachable.
The finally block of a try statement is reachable if the try statement is reachable.
The end point of a try statement is reachable if both of the following are true:
• The end point of the try block is reachable or the end point of at least one catch block is reachable.
• If a finally block is present, the end point of the finally block is reachable.
8.11 The checked and unchecked statements
The checked and unchecked statements are used to control the overflow checking context for integral-type arithmetic operations and conversions.
checked-statement:
checked block
unchecked-statement:
unchecked block
The checked statement causes all expressions in the block to be evaluated in a checked context, and the unchecked statement causes all expressions in the block to be evaluated in an unchecked context.
The checked and unchecked statements are precisely equivalent to the checked and unchecked operators (§7.5.12), except that they operate on blocks instead of expressions.
8.12 The lock statement
The lock statement obtains the mutual-exclusion lock for a given object, executes a statement, and then releases the lock.
lock-statement:
lock ( expression ) embedded-statement
The expression of a lock statement must denote a value of a reference-type. An implicit boxing conversion (§6.1.5) is never performed for the expression of a lock statement, and thus it is a compile-time error for the expression to denote a value of a value-type.
A lock statement of the form
lock (x) ...
where x is an expression of a reference-type, is precisely equivalent to
System.Threading.Monitor.Enter(x);
try {
...
}
finally {
System.Threading.Monitor.Exit(x);
}
except that x is only evaluated once.
The System.Type object of a class can conveniently be used as the mutual-exclusion lock for static methods of the class. For example:
class Cache
{
public static void Add(object x) {
lock (typeof(Cache)) {
...
}
}
public static void Remove(object x) {
lock (typeof(Cache)) {
...
}
}
}
8.13 The using statement
The using statement obtains one or more resources, executes a statement, and then disposes of the resource.
using-statement:
using ( resource-acquisition ) embedded-statement
resource-acquisition:
local-variable-declaration
expression
A resource is a class or struct that implements System.IDisposable, which includes a single parameterless method named Dispose. Code that is using a resource can call Dispose to indicate that the resource is no longer needed. If Dispose is not called, then automatic disposal eventually occurs as a consequence of garbage collection.
If the form of resource-acquisition is local-variable-declaration then the type of the local-variable-declaration must be System.IDisposable or a type that can be implicitly converted to System.IDisposable. If the form of resource-acquisition is expression then this expression must be System.IDisposable or a type that can be implicitly converted to System.IDisposable.
Local variables declared in a resource-acquisition are read-only, and must include an initializer. A compile-time error occurs if the embedded statement attempts to modify these local variables (via assignment or the ++ and operators) or pass them as ref or out parameters.
A using statement is translated into three parts: acquisition, usage, and disposal. Usage of the resource is implicitly enclosed in a try statement that includes a finally clause. This finally clause disposes of the resource. If a null resource is acquired, then no call to Dispose is made, and no exception is thrown.
For example, a using statement of the form
using (R r1 = new R()) {
r1.F();
}
is precisely equivalent to
R r1 = new R();
try {
r1.F();
}
finally {
if (r1 != null) ((IDisposable)r1).Dispose();
}
A resource-acquisition may acquire multiple resources of a given type. This is equivalent to nested using statements. For example, a using statement of the form
using (R r1 = new R(), r2 = new R()) {
r1.F();
r2.F();
}
is precisely equivalent to:
using (R r1 = new R())
using (R r2 = new R()) {
r1.F();
r2.F();
}
which is, by expansion, precisely equivalent to:
R r1 = new R();
try {
R r2 = new R();
try {
r1.F();
r2.F();
}
finally {
if (r2 != null) ((IDisposable)r2).Dispose();
}
}
finally {
if (r1 != null) ((IDisposable)r1).Dispose();
}

9. Namespaces
C# programs are organized using namespaces. Namespaces are used both as an “internal” organization system for a program, and as an “external” organization system—a way of presenting program elements that are exposed to other programs.
Using directives (§9.3) are provided to facilitate the use of namespaces.
9.1 Compilation units
A compilation-unit defines the overall structure of a source file. A compilation unit consists of zero or more using-directives followed by zero or more global-attributes followed by zero or more namespace-member-declarations.
compilation-unit:
using-directivesopt global-attributesopt namespace-member-declarationsopt
A C# program consists of one or more compilation units, each contained in a separate source file. When a C# program is compiled, all of the compilation units are processed together. Thus, compilation units can depend on each other, possibly in a circular fashion.
The using-directives of a compilation unit affect the global-attributes and namespace-member-declarations of that compilation unit, but have no effect on other compilation units.
The global-attributes (§17) of a compilation unit permit the specification of attributes for the target assembly and module. Assemblies and modules act as physical containers for types. An assembly may consist of several physically separate modules.
The namespace-member-declarations of each compilation unit of a program contribute members to a single declaration space called the global namespace. For example:
File A.cs:
class A {}
File B.cs:
class B {}
The two compilation units contribute to the single global namespace, in this case declaring two classes with the fully qualified names A and B. Because the two compilation units contribute to the same declaration space, it would have been an error if each contained a declaration of a member with the same name.
9.2 Namespace declarations
A namespace-declaration consists of the keyword namespace, followed by a namespace name and body, optionally followed by a semicolon.
namespace-declaration:
namespace qualified-identifier namespace-body ;opt
qualified-identifier:
identifier
qualified-identifier . identifier
namespace-body:
{ using-directivesopt namespace-member-declarationsopt }
A namespace-declaration may occur as a top-level declaration in a compilation-unit or as a member declaration within another namespace-declaration. When a namespace-declaration occurs as a top-level declaration in a compilation-unit, the namespace becomes a member of the global namespace. When a namespace-declaration occurs within another namespace-declaration, the inner namespace becomes a member of the outer namespace. In either case, the name of a namespace must be unique within the containing namespace.
Namespaces are implicitly public and the declaration of a namespace cannot include any access modifiers.
Within a namespace-body, the optional using-directives import the names of other namespaces and types, allowing them to be referenced directly instead of through qualified names. The optional namespace-member-declarations contribute members to the declaration space of the namespace. Note that all using-directives must appear before any member declarations.
The qualified-identifier of a namespace-declaration may be a single identifier or a sequence of identifiers separated by “.” tokens. The latter form permits a program to define a nested namespace without lexically nesting several namespace declarations. For example,
namespace N1.N2
{
class A {}
class B {}
}
is semantically equivalent to
namespace N1
{
namespace N2
{
class A {}
class B {}
}
}
Namespaces are open-ended, and two namespace declarations with the same fully qualified name contribute to the same declaration space (§3.3). In the example
namespace N1.N2
{
class A {}
}
namespace N1.N2
{
class B {}
}
the two namespace declarations above contribute to the same declaration space, in this case declaring two classes with the fully qualified names N1.N2.A and N1.N2.B. Because the two declarations contribute to the same declaration space, it would have been an error if each contained a declaration of a member with the same name.
9.3 Using directives
Using directives facilitate the use of namespaces and types defined in other namespaces. Using directives impact the name resolution process of namespace-or-type-names (§3.8) and simple-names (§7.5.2), but unlike declarations, using directives do not contribute new members to the underlying declaration spaces of the compilation units or namespaces within which they are used.
using-directives:
using-directive
using-directives using-directive
using-directive:
using-alias-directive
using-namespace-directive
A using-alias-directive (§9.3.1) introduces an alias for a namespace or type.
A using-namespace-directive (§9.3.2) imports the type members of a namespace.
The scope of a using-directive extends over the namespace-member-declarations of its immediately containing compilation unit or namespace body. The scope of a using-directive specifically does not include its peer using-directives. Thus, peer using-directives do not affect each other, and the order in which they are written is insignificant.
9.3.1 Using alias directives
A using-alias-directive introduces an identifier that serves as an alias for a namespace or type within the immediately enclosing compilation unit or namespace body.
using-alias-directive:
using identifier = namespace-or-type-name ;
Within member declarations in a compilation unit or namespace body that contains a using-alias-directive, the identifier introduced by the using-alias-directive can be used to reference the given namespace or type. For example:
namespace N1.N2
{
class A {}
}
namespace N3
{
using A = N1.N2.A;
class B: A {}
}
Above, within member declarations in the N3 namespace, A is an alias for N1.N2.A, and thus class N3.B derives from class N1.N2.A. The same effect can be obtained by creating an alias R for N1.N2 and then referencing R.A:
namespace N3
{
using R = N1.N2;
class B: R.A {}
}
The identifier of a using-alias-directive must be unique within the declaration space of the compilation unit or namespace that immediately contains the using-alias-directive. For example:
namespace N3
{
class A {}
}
namespace N3
{
using A = N1.N2.A; // Error, A already exists
}
Above, N3 already contains a member A, so it is a compile-time error for a using-alias-directive to use that identifier. Likewise, it is a compile-time error for two or more using-alias-directives in the same compilation unit or namespace body to declare aliases by the same name.
A using-alias-directive makes an alias available within a particular compilation unit or namespace body, but it does not contribute any new members to the underlying declaration space. In other words, a using-alias-directive is not transitive but rather affects only the compilation unit or namespace body in which it occurs. In the example
namespace N3
{
using R = N1.N2;
}
namespace N3
{
class B: R.A {} // Error, R unknown
}
the scope of the using-alias-directive that introduces R only extends to member declarations in the namespace body in which it is contained, so R is unknown in the second namespace declaration. However, placing the using-alias-directive in the containing compilation unit causes the alias to become available within both namespace declarations:
using R = N1.N2;
namespace N3
{
class B: R.A {}
}
namespace N3
{
class C: R.A {}
}
Just like regular members, names introduced by using-alias-directives are hidden by similarly named members in nested scopes. In the example
using R = N1.N2;
namespace N3
{
class R {}
class B: R.A {} // Error, R has no member A
}
the reference to R.A in the declaration of B causes a compile-time error because R refers to N3.R, not N1.N2.
The order in which using-alias-directives are written has no significance, and resolution of the namespace-or-type-name referenced by a using-alias-directive is neither affected by the using-alias-directive itself nor by other using-directives in the immediately containing compilation unit or namespace body. In other words, the namespace-or-type-name of a using-alias-directive is resolved as if the immediately containing compilation unit or namespace body had no using-directives. In the example
namespace N1.N2 {}
namespace N3
{
using R1 = N1; // OK
using R2 = N1.N2; // OK
using R3 = R1.N2; // Error, R1 unknown
}
the last using-alias-directive results in a compile-time error because it is not affected by the first using-alias-directive.
A using-alias-directive can create an alias for any namespace or type, including the namespace within which it appears and any namespace or type nested within that namespace.
Accessing a namespace or type through an alias yields exactly the same result as accessing the namespace or type through its declared name. For example, given
namespace N1.N2
{
class A {}
}
namespace N3
{
using R1 = N1;
using R2 = N1.N2;
class B
{
N1.N2.A a; // refers to N1.N2.A
R1.N2.A b; // refers to N1.N2.A
R2.A c; // refers to N1.N2.A
}
}
the names N1.N2.A, R1.N2.A, and R2.A are equivalent and all refer to the class whose fully qualified name is N1.N2.A.
9.3.2 Using namespace directives
A using-namespace-directive imports the types contained in a namespace into the immediately enclosing compilation unit or namespace body, enabling the identifier of each type to be used without qualification.
using-namespace-directive:
using namespace-name ;
Within member declarations in a compilation unit or namespace body that contains a using-namespace-directive, the types contained in the given namespace can be referenced directly. For example:
namespace N1.N2
{
class A {}
}
namespace N3
{
using N1.N2;
class B: A {}
}
Above, within member declarations in the N3 namespace, the type members of N1.N2 are directly available, and thus class N3.B derives from class N1.N2.A.
A using-namespace-directive imports the types contained in the given namespace, but specifically does not import nested namespaces. In the example
namespace N1.N2
{
class A {}
}
namespace N3
{
using N1;
class B: N2.A {} // Error, N2 unknown
}
the using-namespace-directive imports the types contained in N1, but not the namespaces nested in N1. Thus, the reference to N2.A in the declaration of B results in a compile-time error because no members named N2 are in scope.
Unlike a using-alias-directive, a using-namespace-directive may import types whose identifiers are already defined within the enclosing compilation unit or namespace body. In effect, names imported by a using-namespace-directive are hidden by similarly named members in the enclosing compilation unit or namespace body. For example:
namespace N1.N2
{
class A {}
class B {}
}
namespace N3
{
using N1.N2;
class A {}
}
Here, within member declarations in the N3 namespace, A refers to N3.A rather than N1.N2.A.
When more than one namespace imported by using-namespace-directives in the same compilation unit or namespace body contain types by the same name, references to that name are considered ambiguous. In the example
namespace N1
{
class A {}
}
namespace N2
{
class A {}
}
namespace N3
{
using N1;
using N2;
class B: A {} // Error, A is ambiguous
}
both N1 and N2 contain a member A, and because N3 imports both, referencing A in N3 is a compile-time error. In this situation, the conflict can be resolved either through qualification of references to A, or by introducing a using-alias-directive that picks a particular A. For example:
namespace N3
{
using N1;
using N2;
using A = N1.A;
class B: A {} // A means N1.A
}
Like a using-alias-directive, a using-namespace-directive does not contribute any new members to the underlying declaration space of the compilation unit or namespace, but rather affects only the compilation unit or namespace body in which it appears.
The namespace-name referenced by a using-namespace-directive is resolved in the same way as the namespace-or-type-name referenced by a using-alias-directive. Thus, using-namespace-directives in the same compilation unit or namespace body do not affect each other and can be written in any order.
9.4 Namespace members
A namespace-member-declaration is either a namespace-declaration (§9.2) or a type-declaration (§9.5).
namespace-member-declarations:
namespace-member-declaration
namespace-member-declarations namespace-member-declaration
namespace-member-declaration:
namespace-declaration
type-declaration
A compilation unit or a namespace body can contain namespace-member-declarations, and such declarations contribute new members to the underlying declaration space of the containing compilation unit or namespace body.
9.5 Type declarations
A type-declaration is a class-declaration (§10.1), a struct-declaration (§11.1), an interface-declaration (§13.1), an enum-declaration (§14.1), or a delegate-declaration (§15.1).
type-declaration:
class-declaration
struct-declaration
interface-declaration
enum-declaration
delegate-declaration
A type-declaration can occur as a top-level declaration in a compilation unit or as a member declaration within a namespace, class, or struct.
When a type declaration for a type T occurs as a top-level declaration in a compilation unit, the fully qualified name of the newly declared type is simply T. When a type declaration for a type T occurs within a namespace, class, or struct, the fully qualified name of the newly declared type is N.T, where N is the fully qualified name of the containing namespace, class, or struct.
A type declared within a class or struct is called a nested type (§10.2.6).
The permitted access modifiers and the default access for a type declaration depend on the context in which the declaration takes place (§3.5.1):
• Types declared in compilation units or namespaces can have public or internal access. The default is internal access.
• Types declared in classes can have public, protected internal, protected, internal, or private access. The default is private access.
• Types declared in structs can have public, internal, or private access. The default is private access.

10. Classes
A class is a data structure that may contain data members (constants and fields), function members (methods, properties, events, indexers, operators, instance constructors, destructors and static constructors), and nested types. Class types support inheritance, a mechanism whereby a derived class can extend and specialize a base class.
10.1 Class declarations
A class-declaration is a type-declaration (§9.5) that declares a new class.
class-declaration:
attributesopt class-modifiersopt class identifier class-baseopt class-body ;opt
A class-declaration consists of an optional set of attributes (§17), followed by an optional set of class-modifiers (§10.1.1), followed by the keyword class and an identifier that names the class, followed by an optional class-base specification (§10.1.2), followed by a class-body (§10.1.3), optionally followed by a semicolon.
10.1.1 Class modifiers
A class-declaration may optionally include a sequence of class modifiers:
class-modifiers:
class-modifier
class-modifiers class-modifier
class-modifier:
new
public
protected
internal
private
abstract
sealed
It is a compile-time error for the same modifier to appear multiple times in a class declaration.
The new modifier is permitted on nested classes. It specifies that the class hides an inherited member by the same name, as described in §10.2.2. It is a compile-time error for the new modifier to appear on a class declaration that is not a nested class declaration.
The public, protected, internal, and private modifiers control the accessibility of the class. Depending on the context in which the class declaration occurs, some of these modifiers may not be permitted (§3.5.1).
The abstract and sealed modifiers are discussed in the following sections.
10.1.1.1 Abstract classes
The abstract modifier is used to indicate that a class is incomplete and that it is intended to be used only as a base class. An abstract class differs from a non-abstract class is the following ways:
• An abstract class cannot be instantiated directly, and it is a compile-time error to use the new operator on an abstract class. While it is possible to have variables and values whose compile-time types are abstract, such variables and values will necessarily either be null or contain references to instances of non-abstract classes derived from the abstract types.
• An abstract class is permitted (but not required) to contain abstract members.
• An abstract class cannot be sealed.
When a non-abstract class is derived from an abstract class, the non-abstract class must include actual implementations of all inherited abstract members. Such implementations are provided by overriding the abstract members. In the example
abstract class A
{
public abstract void F();
}
abstract class B: A
{
public void G() {}
}
class C: B
{
public override void F() {
// actual implementation of F
}
}
the abstract class A introduces an abstract method F. Class B introduces an additional method G, but since it doesn’t provide an implementation of F, B must also be declared abstract. Class C overrides F and provides an actual implementation. Since there are no abstract members in C, C is permitted (but not required) to be non-abstract.
10.1.1.2 Sealed classes
The sealed modifier is used to prevent derivation from a class. A compile-time error occurs if a sealed class is specified as the base class of another class.
A sealed class cannot also be an abstract class.
The sealed modifier is primarily used to prevent unintended derivation, but it also enables certain run-time optimizations. In particular, because a sealed class is known to never have any derived classes, it is possible to transform virtual function member invocations on sealed class instances into non-virtual invocations.
10.1.2 Class base specification
A class declaration may include a class-base specification, which defines the direct base class of the class and the interfaces (13) implemented by the class.
class-base:
: class-type
: interface-type-list
: class-type , interface-type-list
interface-type-list:
interface-type
interface-type-list , interface-type
10.1.2.1 Base classes
When a class-type is included in the class-base, it specifies the direct base class of the class being declared. If a class declaration has no class-base, or if the class-base lists only interface types, the direct base class is assumed to be object. A class inherits members from its direct base class, as described in §10.2.1.
In the example
class A {}
class B: A {}
class A is said to be the direct base class of B, and B is said to be derived from A. Since A does not explicitly specify a direct base class, its direct base class is implicitly object.
The direct base class of a class type must be at least as accessible as the class type itself (§3.5.4). For example, it is a compile-time error for a public class to derive from a private or internal class.
The direct base class of a class type must not be any of the following types: System.Array, System.Delegate, System.Enum, or System.ValueType.
The base classes of a class are the direct base class and its base classes. In other words, the set of base classes is the transitive closure of the direct base class relationship. Referring to the example above, the base classes of B are A and object.
Except for class object, every class has exactly one direct base class. The object class has no direct base class and is the ultimate base class of all other classes.
When a class B derives from a class A, it is a compile-time error for A to depend on B. A class directly depends on its direct base class (if any) and directly depends on the class within which it is immediately nested (if any). Given this definition, the complete set of classes upon which a class depends is the transitive closure of the directly depends on relationship.
The example
class A: B {}
class B: C {}
class C: A {}
results in a compile-time error because the classes circularly depend on themselves. Likewise, the example
class A: B.C {}
class B: A
{
public class C {}
}
results in a compile-time error because A depends on B.C (its direct base class), which depends on B (its immediately enclosing class), which circularly depends on A.
Note that a class does not depend on the classes that are nested within it. In the example
class A
{
class B: A {}
}
B depends on A (because A is both its direct base class and its immediately enclosing class), but A does not depend on B (since B is neither a base class nor an enclosing class of A). Thus, the example is valid.
It is not possible to derive from a sealed class. The example
sealed class A {}
class B: A {} // Error, cannot derive from a sealed class
produces a compile-time error because class B attempts to derive from the sealed class A.
10.1.2.2 Interface implementations
A class-base specification may include a list of interface types, in which case the class is said to implement the given interface types. Interface implementations are discussed further in §13.4.
10.1.3 Class body
The class-body of a class defines the members of the class.
class-body:
{ class-member-declarationsopt }
10.2 Class members
The members of a class consist of the members introduced by its class-member-declarations and the members inherited from the direct base class.
class-member-declarations:
class-member-declaration
class-member-declarations class-member-declaration
class-member-declaration:
constant-declaration
field-declaration
method-declaration
property-declaration
event-declaration
indexer-declaration
operator-declaration
constructor-declaration
destructor-declaration
static-constructor-declaration
type-declaration
The members of a class are divided into the following categories:
• Constants, which represent constant values associated with the class (§10.3).
• Fields, which are the variables of the class (§10.4).
• Methods, which implement the computations and actions that can be performed by the class (§10.5).
• Properties, which define named characteristics associated with reading and writing those characteristics (§10.6).
• Events, which define notifications that can be generated by the class (§10.7).
• Indexers, which permit instances of the class to be indexed in the same way as arrays (§10.8).
• Operators, which define the expression operators that can be applied to instances of the class (§10.9).
• Instance constructors, which implement the actions required to initialize instances of the class (§10.10)
• Destructors, which implement the actions to be performed before instances of the class are permanently discarded (§10.12).
• Static constructors, which implement the actions required to initialize the class itself (§10.11).
• Types, which represent the types that are local to the class (§9.5).
Members that can contain executable code are collectively known as the function members of the class (7.4). The function members of a class are the methods, properties, events, indexers, operators, instance constructors, destructors, and static constructors of that class.
A class-declaration creates a new declaration space (§3.3), and the class-member-declarations immediately contained by the class-declaration introduce new members into this declaration space. The following rules apply to class-member-declarations:
• Instance constructors, destructors and static constructors must have the same name as the immediately enclosing class. All other members must have names that differ from the name of the immediately enclosing class.
• The name of a constant, field, property, event, or type must differ from the names of all other members declared in the same class.
• The name of a method must differ from the names of all other non-methods declared in the same class. In addition, the signature (§3.6) of a method must differ from the signatures of all other methods declared in the same class.
• The signature of an instance constructor must differ from the signatures of all other instance constructors declared in the same class.
• The signature of an indexer must differ from the signatures of all other indexers declared in the same class.
• The signature of an operator must differ from the signatures of all other operators declared in the same class.
The inherited members of a class (§10.2.1) are not part of the declaration space of a class. Thus, a derived class is allowed to declare a member with the same name or signature as an inherited member (which in effect hides the inherited member).
10.2.1 Inheritance
A class inherits the members of its direct base class. Inheritance means that a class implicitly contains all members of its direct base class, except for the instance constructors, destructors and static constructors of the base class. Some important aspects of inheritance are:
• Inheritance is transitive. If C is derived from B, and B is derived from A, then C inherits the members declared in B as well as the members declared in A.
• A derived class extends its direct base class. A derived class can add new members to those it inherits, but it cannot remove the definition of an inherited member.
• Instance constructors, destructors, and static constructors are not inherited, but all other members are, regardless of their declared accessibility (§3.5). However, depending on their declared accessibility, inherited members might not be accessible in a derived class.
• A derived class can hide (§3.7.1.2) inherited members by declaring new members with the same name or signature. Note however that hiding an inherited member does not remove the member—it merely makes the member inaccessible in the derived class.
• An instance of a class contains a set of all instance fields declared in the class and its base classes, and an implicit conversion (§6.1.4) exists from a derived class type to any of its base class types. Thus, a reference to an instance of some derived class can be treated as a reference to an instance of any of its base classes.
• A class can declare virtual methods, properties, and indexers, and derived classes can override the implementation of these function members. This enables classes to exhibit polymorphic behavior wherein the actions performed by a function member invocation varies depending on the run-time type of the instance through which the function member is invoked.
10.2.2 The new modifier
A class-member-declaration is permitted to declare a member with the same name or signature as an inherited member. When this occurs, the derived class member is said to hide the base class member. Hiding an inherited member is not considered an error, but it does cause the compiler to issue a warning. To suppress the warning, the declaration of the derived class member can include a new modifier to indicate that the derived member is intended to hide the base member. This topic is discussed further in §3.7.1.2.
If a new modifier is included in a declaration that doesn’t hide an inherited member, a warning is issued. This warning is suppressed by removing the new modifier.
10.2.3 Access modifiers
A class-member-declaration can have any one of the five possible kinds of declared accessibility (§3.5.1): public, protected internal, protected, internal, or private. Except for the protected internal combination, it is a compile-time error to specify more than one access modifier. When a class-member-declaration does not include any access modifiers, private is assumed.
10.2.4 Constituent types
Types that are used in the declaration of a member are called the constituent types of the member. Possible constituent types are the type of a constant, field, property, event, or indexer, the return type of a method or operator, and the parameter types of a method, indexer, operator, or instance constructor. The constituent types of a member must be at least as accessible as the member itself (§3.5.4).
10.2.5 Static and instance members
Members of a class are either static members or instance members. Generally speaking, it is useful to think of static members as belonging to classes and instance members as belonging to objects (instances of classes).
When a field, method, property, event, operator, or constructor declaration includes a static modifier, it declares a static member. In addition, a constant or type declaration implicitly declares a static member. Static members have the following characteristics:
• When a static member is referenced in a member-access (§7.5.4) of the form E.M, E must denote a type that has a member M. It is a compile-time error for E to denote an instance.
• A static field identifies exactly one storage location. No matter how many instances of a class are created, there is only ever one copy of a static field.
• A static function member does not operate on a specific instance, and it is a compile-time error to refer to this in such a function member.
When a field, method, property, event, indexer, constructor, or destructor declaration does not include a static modifier, it declares an instance member. (An instance member is sometimes called a non-static member.) Instance members have the following characteristics:
• When an instance member is referenced in a member-access (§7.5.4) of the form E.M, E must denote an instance of a type that has a member M. It is a compile-time error for E to denote a type.
• Every instance of a class contains a separate set of all instance fields of the class.
• An instance function member operates on a given instance of the class, and this instance can be accessed as this (§7.5.7).
The following example illustrates the rules for accessing static and instance members:
class Test
{
int x;
static int y;
void F() {
x = 1; // Ok, same as this.x = 1
y = 1; // Ok, same as Test.y = 1
}
static void G() {
x = 1; // Error, cannot access this.x
y = 1; // Ok, same as Test.y = 1
}
static void Main() {
Test t = new Test();
t.x = 1; // Ok
t.y = 1; // Error, cannot access static member through instance
Test.x = 1; // Error, cannot access instance member through type
Test.y = 1; // Ok
}
}
The F method shows that in an instance function member, a simple-name (§7.5.2) can be used to access both instance members and static members. The G method shows that in a static function member, it is a compile-time error to access an instance member through a simple-name. The Main method shows that in a member-access (§7.5.4), instance members must be accessed through instances, and static members must be accessed through types.
10.2.6 Nested types
A type declared within a class or struct is called a nested type. A type that is declared within a compilation unit or namespace is called a non-nested type.
In the example
class A
{
class B
{
static void F() {
Console.WriteLine("A.B.F");
}
}
}
class B is a nested type because it is declared within class A, and class A is a non-nested type because it is declared within a compilation unit.
10.2.6.1 Fully qualified name
The fully qualified name (§3.8.1) for a nested type is S.N where S is the fully qualified name of the type in which N is declared.
10.2.6.2 Declared accessibility
Non-nested types can have public or internal declared accessibility and default to internal declared accessibility. Nested types can have these forms of declared accessibility plus one or more additional forms of declared accessibility, depending on whether the containing type is a class or struct:
• A nested type that is declared in a class can have any of the five forms of declared accessibility (public, protected internal, protected, internal, or private) and, like other class members, defaults to private declared accessibility.
• A nested type that is declared in a struct can have any of three forms of declared accessibility (public, internal, or private) and, like other struct members, defaults to private declared accessibility.
The example
public class List
{
// Private data structure
private class Node
{
public object Data;
public Node Next;
public Node(object data, Node next) {
this.Data = data;
this.Next = next;
}
}
private Node first = null;
private Node last = null;
// Public interface
public void AddToFront(object o) {...}
public void AddToBack(object o) {...}
public object RemoveFromFront() {...}
public object AddToFront() {...}
public int Count { get {...} }
}
declares a private nested class Node.
10.2.6.3 Hiding
A nested type may hide (§3.7.1) a base member. The new modifier is permitted on nested type declarations so that hiding can be expressed explicitly. The example
class Base
{
public static void M() {
Console.WriteLine("C.M");
}
}
class Derived: Base
{
new public class M
{
public static void F() {
Console.WriteLine("Derived.M.F");
}
}
}
class Test
{
static void Main() {
Derived.M.F();
}
}
shows a nested class M that hides the method M defined in Base.
10.2.6.4 this access
A nested type and its containing type do not have a special relationship with regard to this-access (§7.5.7). Specifically, this within a nested type cannot be used to refer to instance members of the containing type. In cases where a nested type needs access to the instance members of its containing type, access can be provided by providing the this for the instance of the containing type as a constructor argument for the nested type. In the example
class C
{
int i = 123;
public void F() {
Nested n = new Nested(this);
n.G();
}
public class Nested {
C this_c;
public Nested(C c) {
this_c = c;
}
public void G() {
Console.WriteLine(this_c.i);
}
}
}
class Test {
static void Main() {
C c = new C();
c.F();
}
}
shows this technique. A C instance creates an instance of Nested and passes its own this to Nested’s constructor in order to provide subsequent access to C’s instance members.
10.2.6.5 Access to private and protected members of the containing type
A nested type has access to all of the members that are accessible to its containing type, including members of the containing type that have private and protected declared accessibility. The example
class C
{
private static void F() {
Console.WriteLine("C.F");
}
public class Nested
{
public static void G() {
F();
}
}
}
class Test
{
static void Main() {
C.Nested.G();
}
}
shows a class C that contains a nested class Nested. Within Nested, the method G calls the static method F defined in C, and F has private declared accessibility.
A nested type also may access protected members defined in a base type of its containing type. In the example
class Base
{
protected void F() {
Console.WriteLine("Base.F");
}
}
class Derived: Base
{
public class Nested
{
public void G() {
Derived d = new Derived();
d.F(); // ok
}
}
}
class Test
{
static void Main() {
Derived.Nested n = new Derived.Nested();
n.G();
}
}
the nested class Derived.Nested accesses the protected method F defined in Derived’s base class, Base, by calling through an instance of Derived.
10.2.7 Reserved member names
To facilitate the underlying C# runtime implementation, for each source member declaration that is a property, event, or indexer, the implementation must reserve two method signatures based on the kind of the member declaration, its name, and its type. It is a compile-time error for a program to declare a member whose signature matches one of these reserved signatures, even if the underlying runtime implementation does not make use of these reservations.
The reserved names do not introduce declarations, thus they do not participate in member lookup. However, a declaration’s associated reserved method signatures do participate in inheritance (§10.2.1), and can be hidden with the new modifier (§10.2.2).
The reservation of these names serves three purposes:
• To allow the underlying implementation to use an ordinary identifier as a method name for get or set access to the C# language feature.
• To allow other languages to interoperate using an ordinary identifier as a method name for get or set access to the C# language feature.
• To help ensure that the source accepted by one conforming compiler is accepted by another, by making the specifics of reserved member names consistent across all C# implementations.
The declaration of a destructor (§10.12) also causes a signature to be reserved (§10.2.7.4).
10.2.7.1 Member names reserved for properties
For a property P (§10.6) of type T, the following signatures are reserved:
T get_P();
void set_P(T value);
Both signatures are reserved, even if the property is read-only or write-only.
In the example
class A {
public int P {
get { return 123; }
}
}
class B: A {
new public int get_P() {
return 456;
}
new public void set_P(int value) {
}
}
class Test
{
static void Main() {
B b = new B();
A a = b;
Console.WriteLine(a.P);
Console.WriteLine(b.P);
Console.WriteLine(b.get_P());
}
}
a class A defines a read-only property P, thus reserving signatures for get_P and set_P methods. A class B derives from A and hides both of these reserved signatures. The example produces the output:
123
123
456
10.2.7.2 Member names reserved for events
For an event E (§10.7) of delegate type T, the following signatures are reserved:
void add_E(T handler);
void remove_E(T handler);
10.2.7.3 Member names reserved for indexers
For an indexer (§10.8) of type T with parameter-list L, the following signatures are reserved:
T get_Item(L);
void set_Item(L, T value);
Both signatures are reserved, even if the indexer is read-only or write-only.
10.2.7.4 Member names reserved for destructors
For a class containing a destructor (§10.12), the following signature is reserved:
void Finalize();
10.3 Constants
A constant is a class member that represents a constant value: a value that can be computed at compile-time. A constant-declaration introduces one or more constants of a given type.
constant-declaration:
attributesopt constant-modifiersopt const type constant-declarators ;
constant-modifiers:
constant-modifier
constant-modifiers constant-modifier
constant-modifier:
new
public
protected
internal
private
constant-declarators:
constant-declarator
constant-declarators , constant-declarator
constant-declarator:
identifier = constant-expression
A constant-declaration may include a set of attributes (§17), a new modifier (§10.2.2), and a valid combination of the four access modifiers (§10.2.3). The attributes and modifiers apply to all of the members declared by the constant-declaration. Even though constants are considered static members, a constant-declaration neither requires nor allows a static modifier. It is a compile-time error for the same modifier to appear multiple times in a constant declaration.
The type of a constant-declaration specifies the type of the members introduced by the declaration. The type is followed by a list of constant-declarators, each of which introduces a new member. A constant-declarator consists of an identifier that names the member, followed by an “=” token, followed by a constant-expression (§7.15) that gives the value of the member.
The type specified in a constant declaration must be sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, decimal, bool, string, an enum-type, or a reference-type. Each constant-expression must yield a value of the target type or of a type that can be converted to the target type by an implicit conversion (§6.1).
The type of a constant must be at least as accessible as the constant itself (§3.5.4).
The value of a constant is obtained in an expression using a simple-name (§7.5.2) or a member-access (§7.5.4).
A constant can itself participate in a constant-expression. Thus, a constant may be used in any construct that requires a constant-expression. Examples of such constructs include case labels, goto case statements, enum member declarations, attributes, and other constant declarations.
As described in §7.15, a constant-expression is an expression that can be fully evaluated at compile-time. Since the only way to create a non-null value of a reference-type other than string is to apply the new operator, and since the new operator is not permitted in a constant-expression, the only possible value for constants of reference-types other than string is null.
When a symbolic name for a constant value is desired, but when the type of the value is not permitted in a constant declaration, or when the value cannot be computed at compile-time by a constant-expression, a readonly field (§10.4.2) may be used instead.
A constant declaration that declares multiple constants is equivalent to multiple declarations of single constants with the same attributes, modifiers, and type. For example
class A
{
public const double X = 1.0, Y = 2.0, Z = 3.0;
}
is equivalent to
class A
{
public const double X = 1.0;
public const double Y = 2.0;
public const double Z = 3.0;
}
Constants are permitted to depend on other constants within the same program as long as the dependencies are not of a circular nature. The compiler automatically arranges to evaluate the constant declarations in the appropriate order. In the example
class A
{
public const int X = B.Z + 1;
public const int Y = 10;
}
class B
{
public const int Z = A.Y + 1;
}
the compiler first evaluates A.Y, then evaluates B.Z, and finally evaluates A.X, producing the values 10, 11, and 12. Constant declarations may depend on constants from other programs, but such dependencies are only possible in one direction. Referring to the example above, if A and B were declared in separate programs, it would be possible for A.X to depend on B.Z, but B.Z could then not simultaneously depend on A.Y.
10.4 Fields
A field is a member that represents a variable associated with an object or class. A field-declaration introduces one or more fields of a given type.
field-declaration:
attributesopt field-modifiersopt type variable-declarators ;
field-modifiers:
field-modifier
field-modifiers field-modifier
field-modifier:
new
public
protected
internal
private
static
readonly
volatile
variable-declarators:
variable-declarator
variable-declarators , variable-declarator
variable-declarator:
identifier
identifier = variable-initializer
variable-initializer:
expression
array-initializer
A field-declaration may include a set of attributes (§17), a new modifier (§10.2.2), a valid combination of the four access modifiers (§10.2.3), a static modifier (§10.4.1). In addition, a field-declaration may include a readonly modifier (§10.4.2) or a volatile modifier (§10.4.3) but not both. The attributes and modifiers apply to all of the members declared by the field-declaration. It is a compile-time error for the same modifier to appear multiple times in a field declaration.
The type of a field-declaration specifies the type of the members introduced by the declaration. The type is followed by a list of variable-declarators, each of which introduces a new member. A variable-declarator consists of an identifier that names the member, optionally followed by an “=” token and a variable-initializer (§10.4.5) that gives the initial value of the member.
The type of a field must be at least as accessible as the field itself (§3.5.4).
The value of a field is obtained in an expression using a simple-name (§7.5.2) or a member-access (§7.5.4). The value of a non-readonly field is modified using an assignment (§7.13). The value of a non-readonly field can be both obtained and modified using postfix increment and decrement operators (§7.5.9) and prefix increment and decrement operators (§7.6.5).
A field declaration that declares multiple fields is equivalent to multiple declarations of single fields with the same attributes, modifiers, and type. For example
class A
{
public static int X = 1, Y, Z = 100;
}
is equivalent to
class A
{
public static int X = 1;
public static int Y;
public static int Z = 100;
}
10.4.1 Static and instance fields
When a field declaration includes a static modifier, the fields introduced by the declaration are static fields. When no static modifier is present, the fields introduced by the declaration are instance fields. Static fields and instance fields are two of the several kinds of variables (§5) supported by C#, and at times they are referred to as static variables and instance variables, respectively.
A static field is not part of a specific instance; instead, it identifies exactly one storage location. No matter how many instances of a class are created, there is only ever one copy of a static field for the associated application domain.
An instance field belongs to an instance. Every instance of a class contains a separate set of all instance fields of the class.
When a field is referenced in a member-access (§7.5.4) of the form E.M, if M is a static field, E must denote a type that has a field M, and if M is an instance field, E must denote an instance of a type that has a field M.
The differences between static and instance members are discussed further in §10.2.5.
10.4.2 Readonly fields
When a field-declaration includes a readonly modifier, the fields introduced by the declaration are readonly fields. Direct assignments to readonly fields can only occur as part of the declaration or in an instance constructor (for readonly non-static fields) or static constructor (for readonly static fields) in the same class. (A readonly field can be assigned multiple times in these contexts.) Specifically, direct assignments to a readonly field are permitted only in the following contexts:
• In the variable-declarator that introduces the field (by including a variable-initializer in the declaration).
• For an instance field, in the instance constructors of the class that contains the field declaration, or for a static field, in the static constructor of the class the that contains the field declaration. These are also the only contexts in which it is valid to pass a readonly field as an out or ref parameter.
Attempting to assign to a readonly field or pass it as an out or ref parameter in any other context results in a compile-time error.
10.4.2.1 Using static readonly fields for constants
A static readonly field is useful when a symbolic name for a constant value is desired, but when the type of the value is not permitted in a const declaration, or when the value cannot be computed at compile-time. In the example
public class Color
{
public static readonly Color Black = new Color(0, 0, 0);
public static readonly Color White = new Color(255, 255, 255);
public static readonly Color Red = new Color(255, 0, 0);
public static readonly Color Green = new Color(0, 255, 0);
public static readonly Color Blue = new Color(0, 0, 255);
private byte red, green, blue;
public Color(byte r, byte g, byte b) {
red = r;
green = g;
blue = b;
}
}
the Black, White, Red, Green, and Blue members cannot be declared as const members because their values cannot be computed at compile-time. However, declaring them as static readonly fields instead has much the same effect.
10.4.2.2 Versioning of constants and static readonly fields
Constants and readonly fields have different binary versioning semantics. When an expression references a constant, the value of the constant is obtained at compile-time, but when an expression references a readonly field, the value of the field is not obtained until run-time. Consider an application that consists of two separate programs:
using System;
namespace Program1
{
public class Utils
{
public static readonly int X = 1;
}
}
namespace Program2
{
class Test
{
static void Main() {
Console.WriteLine(Program1.Utils.X);
}
}
}
The Program1 and Program2 namespaces denote two programs that are compiled separately. Because Program1.Utils.X is declared as a static readonly field, the value output by the Console.WriteLine statement is not known at compile-time, but rather is obtained at run-time. Thus, if the value of X is changed and Program1 is recompiled, the Console.WriteLine statement will output the new value even if Program2 isn’t recompiled. However, had X been a constant, the value of X would have been obtained at the time Program2 was compiled, and would remain unaffected by changes in Program1 until Program2 is recompiled.
10.4.3 Volatile fields
When a field-declaration includes a volatile modifier, the fields introduced by the declaration are volatile fields.
For non-volatile fields, optimization techniques that reorder instructions can lead to unexpected and unpredictable results in multi-threaded programs that access fields without synchronization such as that provided by the lock-statement (§8.12). These optimizations can be performed by the compiler, by the runtime system, or by hardware. For volatile fields, such reordering optimizations are restricted:
• A read of a volatile field is called a volatile read. A volatile read has “acquire semantics”: a volatile read is guaranteed to occur prior to any references to memory that occur after it in the instruction sequence.
• A write of a volatile field is called a volatile write. A volatile write has “release semantics”: a volatile write is guaranteed to happen after any memory references prior to the write instruction in the instruction sequence.
These restrictions ensure that all threads will observe volatile writes performed by any other thread in the order they were performed. A conforming implementation is not required to provide a single total ordering of volatile writes as seen from all threads of execution. The type of a volatile field must be one of the following:
• A reference-type.
• The type byte, sbyte, short, ushort, int, uint, char, float, or bool.
• An enum-type with an enum base type of byte, sbyte, short, ushort, int, or uint.
The example
using System.Threading;
class Test
{
public static int result;
public static volatile bool finished;
static void Thread2() {
result = 143;
finished = true;
}
static void Main() {
finished = false;
// Run Thread2() in a new thread
new Thread(new ThreadStart(Thread2)).Start();
// Wait for Thread2 to signal that it has a result by setting
// finished to true.
for (;;) {
if (finished) {
Console.WriteLine("result = {0}", result);
return;
}
}
}
}
yields the result:
result = 143
In this example, the method Main starts a new thread running the method Thread2. The method stores a value into a non-volatile field result, then stores true in the volatile field finished. The main thread waits for the field finished to be set to true, then reads the field result. Since result has been declared volatile, the main thread must read the value 143 from the field result. If the field finished had not been declared volatile, then it would be permissible for the store to result be visible to the main thread after the store to finished, and hence for the main thread to read the value 0 from the field result. Declaring finished as a volatile field prevents such inconsistencies.
10.4.4 Field initialization
The initial value of a field, whether it be a static field or an instance field, is the default value (§5.2) of the field’s type. It is not possible to observe the value of a field before this default initialization has occurred, and a field is thus never “uninitialized”. The example
using System;
class Test
{
static bool b;
int i;
static void Main() {
Test t = new Test();
Console.WriteLine("b = {0}, i = {1}", b, t.i);
}
}
produces the output
b = False, i = 0
because b and i are both automatically initialized to default values.
10.4.5 Variable initializers
Field declarations may include variable-initializers. For static fields, variable initializers correspond to assignment statements that are executed during class initialization. For instance fields, variable initializers correspond to assignment statements that are executed when an instance of the class is created.
The example
using System;
class Test
{
static double x = Math.Sqrt(2.0);
int i = 100;
string s = "Hello";
static void Main() {
Test a = new Test();
Console.WriteLine("x = {0}, i = {1}, s = {2}", x, a.i, a.s);
}
}
produces the output
x = 1.4142135623731, i = 100, s = Hello
because an assignment to x occurs when static field initializers execute and assignments to i and s occur when the instance field initializers execute.
The default value initialization described in §10.4.4 occurs for all fields, including fields that have variable initializers. Thus, when a class is initialized, all of its static fields are first initialized to their default values, and then the static field initializers are executed in textual order. Likewise, when an instance of a class is created, all of its instance fields are first initialized to their default values, and then the instance field initializers are executed in textual order.
It is possible for static fields with variable initializers to be observed in their default value state. However, this is strongly discouraged as a matter of style. The example
using System;
class Test
{
static int a = b + 1;
static int b = a + 1;
static void Main() {
Console.WriteLine("a = {0}, b = {1}", a, b);
}
}
exhibits this behavior. Despite the circular definitions of a and b, the program is valid. It results in the output
a = 1, b = 2
because the static fields a and b are initialized to 0 (the default value for int) before their initializers are executed. When the initializer for a runs, the value of b is zero, and so a is initialized to 1. When the initializer for b runs, the value of a is already 1, and so b is initialized to 2.
10.4.5.1 Static field initialization
The static field variable initializers of a class correspond to a sequence of assignments that are executed in the textual order in which they appear in the class declaration. If a static constructor (§10.11) exists in the class, execution of the static field initializers occurs immediately prior to executing that static constructor. Otherwise, the static field initializers are executed at an implementation-dependent time prior to the first use of a static field of that class. The example
using System;
class Test
{
static void Main() {
Console.WriteLine("{0} {1}", B.Y, A.X);
}
public static int f(string s) {
Console.WriteLine(s);
return 1;
}
}
class A
{
public static int X = Test.f("Init A");
}
class B
{
public static int Y = Test.f("Init B");
}
might produce either the output:
Init A
Init B
1 1
or the output:
Init B
Init A
1 1
because the execution of X's initializer and Y's initializer could occur in either order; they are only constrained to occur before the references to those fields. However, in the example:
using System;
class Test {
static void Main() {
Console.WriteLine("{0} {1}", B.Y, A.X);
}
public static int f(string s) {
Console.WriteLine(s);
return 1;
}
}
class A
{
static A() {}
public static int X = Test.f("Init A");
}
class B
{
static B() {}
public static int Y = Test.f("Init B");
}
the output must be:
Init B
Init A
1 1
because the rules for when static constructors execute provide that B's static constructor (and hence B's static field initializers) must run before A's static constructor and field initializers.]
10.4.5.2 Instance field initialization
The instance field variable initializers of a class correspond to a sequence of assignments that are executed immediately upon entry to any one of the instance constructors (§10.10.1) of the class. The variable initializers are executed in the textual order in which they appear in the class declaration. The class instance creation and initialization process is described further in §10.10.
A variable initializer for an instance field cannot reference the instance being created. Thus, it is a compile-time error to reference this in a variable initializer, as it is a compile-time error for a variable initializer to reference any instance member through a simple-name. In the example
class A
{
int x = 1;
int y = x + 1; // Error, reference to instance member of this
}
the variable initializer for y results in a compile-time error because it references a member of the instance being created.
10.5 Methods
A method is a member that implements a computation or action that can be performed by an object or class. Methods are declared using method-declarations:
method-declaration:
method-header method-body
method-header:
attributesopt method-modifiersopt return-type member-name ( formal-parameter-listopt )
method-modifiers:
method-modifier
method-modifiers method-modifier
method-modifier:
new
public
protected
internal
private
static
virtual
sealed
override
abstract
extern
return-type:
type
void
member-name:
identifier
interface-type . identifier
method-body:
block
;
A method-declaration may include a set of attributes (§17) and a valid combination of the four access modifiers (§10.2.3), the new (§10.2.2), static (§10.5.2), virtual (§10.5.3), override (§10.5.4), sealed (§10.5.5), abstract (§10.5.6), and extern (§10.5.7) modifiers.
A declaration has a valid combination of modifiers if all of the following are true:
• The declaration includes a valid combination of access modifiers (§10.2.3).
• The declaration does not include the same modifier multiple times.
• The declaration includes at most one of the following modifiers: static, virtual, and override.
• The declaration includes at most one of the following modifiers: new and override.
• If the declaration includes the abstract modifier, then the declaration does not include any of the following modifiers: static, virtual, or extern.
• If the declaration includes the private modifier, then the declaration does not include any of the following modifiers: virtual, override, or abstract.
• If the declaration includes the sealed modifier, then the declaration also includes the override modifier.
The return-type of a method declaration specifies the type of the value computed and returned by the method. The return-type is void if the method does not return a value.
The member-name specifies the name of the method. Unless the method is an explicit interface member implementation (§13.4.1), the member-name is simply an identifier. For an explicit interface member implementation, the member-name consists of an interface-type followed by a “.” and an identifier.
The optional formal-parameter-list specifies the parameters of the method (§10.5.1).
The return-type and each of the types referenced in the formal-parameter-list of a method must be at least as accessible as the method itself (§3.5.4).
For abstract and extern methods, the method-body consists simply of a semicolon. For all other methods, the method-body consists of a block which specifies the statements to execute when the method is invoked.
The name and the formal parameter list of a method define the signature (§3.6) of the method. Specifically, the signature of a method consists of its name and the number, modifiers, and types of its formal parameters. The return type is not part of a method’s signature, nor are the names of the formal parameters.
The name of a method must differ from the names of all other non-methods declared in the same class. In addition, the signature of a method must differ from the signatures of all other methods declared in the same class.
10.5.1 Method parameters
The parameters of a method, if any, are declared by the method’s formal-parameter-list.
formal-parameter-list:
fixed-parameters
fixed-parameters , parameter-array
parameter-array
fixed-parameters:
fixed-parameter
fixed-parameters , fixed-parameter
fixed-parameter:
attributesopt parameter-modifieropt type identifier
parameter-modifier:
ref
out
parameter-array:
attributesopt params array-type identifier
The formal parameter list consists of one or more comma-separated parameters of which only the last may be a parameter-array.
A fixed-parameter consists of an optional set of attributes (§17), an optional ref or out modifier, a type, and an identifier. Each fixed-parameter declares a parameter of the given type with the given name.
A parameter-array consists of an optional set of attributes (§17), a params modifier, an array-type, and an identifier. A parameter array declares a single parameter of the given array type with the given name. The array-type of a parameter array must be a single-dimensional array type (§12.1). In a method invocation, a parameter array permits either a single argument of the given array type to be specified, or it permits zero or more arguments of the array element type to be specified. Parameter arrays are further described in §10.5.1.4.
A method declaration creates a separate declaration space for parameters and local variables. Names are introduced into this declaration space by the formal parameter list of the method and by local variable declarations in the block of the method. All names in the declaration space of a method must be unique. Thus, it is a compile-time error for a parameter or local variable to have the same name as another parameter or local variable.
A method invocation (§7.5.5.1) creates a copy, specific to that invocation, of the formal parameters and local variables of the method, and the argument list of the invocation assigns values or variable references to the newly created formal parameters. Within the block of a method, formal parameters can be referenced by their identifiers in simple-name expressions (§7.5.2).
There are four kinds of formal parameters:
• Value parameters, which are declared without any modifiers.
• Reference parameters, which are declared with the ref modifier.
• Output parameters, which are declared with the out modifier.
• Parameter arrays, which are declared with the params modifier.
As described in §3.6, the ref and out modifiers are part of a method’s signature, but the params modifier is not.
10.5.1.1 Value parameters
A parameter declared with no modifiers is a value parameter. A value parameter corresponds to a local variable that gets its initial value from the corresponding argument supplied in the method invocation.
When a formal parameter is a value parameter, the corresponding argument in a method invocation must be an expression of a type that is implicitly convertible (§6.1) to the formal parameter type.
A method is permitted to assign new values to a value parameter. Such assignments only affect the local storage location represented by the value parameter—they have no effect on the actual argument given in the method invocation.
10.5.1.2 Reference parameters
A parameter declared with a ref modifier is a reference parameter. Unlike a value parameter, a reference parameter does not create a new storage location. Instead, a reference parameter represents the same storage location as the variable given as the argument in the method invocation.
When a formal parameter is a reference parameter, the corresponding argument in a method invocation must consist of the keyword ref followed by a variable-reference (§5.3.3) of the same type as the formal parameter. A variable must be definitely assigned before it can be passed as a reference parameter.
Within a method, a reference parameter is always considered definitely assigned.
The example
using System;
class Test
{
static void Swap(ref int x, ref int y) {
int temp = x;
x = y;
y = temp;
}
static void Main() {
int i = 1, j = 2;
Swap(ref i, ref j);
Console.WriteLine("i = {0}, j = {1}", i, j);
}
}
produces the output
i = 2, j = 1
For the invocation of Swap in Main, x represents i and y represents j. Thus, the invocation has the effect of swapping the values of i and j.
In a method that takes reference parameters it is possible for multiple names to represent the same storage location. In the example
class A
{
string s;
void F(ref string a, ref string b) {
s = "One";
a = "Two";
b = "Three";
}
void G() {
F(ref s, ref s);
}
}
the invocation of F in G passes a reference to s for both a and b. Thus, for that invocation, the names s, a, and b all refer to the same storage location, and the three assignments all modify the instance field s.
10.5.1.3 Output parameters
A parameter declared with an out modifier is an output parameter. Similar to a reference parameter, an output parameter does not create a new storage location. Instead, an output parameter represents the same storage location as the variable given as the argument in the method invocation.
When a formal parameter is an output parameter, the corresponding argument in a method invocation must consist of the keyword out followed by a variable-reference (§5.3.3) of the same type as the formal parameter. A variable need not be definitely assigned before it can be passed as an output parameter, but following an invocation where a variable was passed as an output parameter, the variable is considered definitely assigned.
Within a method, just like a local variable, an output parameter is initially considered unassigned and must be definitely assigned before its value is used.
Every output parameter of a method must be definitely assigned before the method returns.
Output parameters are typically used in methods that produce multiple return values. For example:
using System;
class Test
{
static void SplitPath(string path, out string dir, out string name) {
int i = path.Length;
while (i > 0) {
char ch = path[i – 1];
if (ch == '\\' || ch == '/' || ch == ':') break;
i--;
}
dir = path.Substring(0, i);
name = path.Substring(i);
}
static void Main() {
string dir, name;
SplitPath("c:\\Windows\\System\\hello.txt", out dir, out name);
Console.WriteLine(dir);
Console.WriteLine(name);
}
}
The example produces the output:
c:\Windows\System\
hello.txt
Note that the dir and name variables can be unassigned before they are passed to SplitPath, and that they are considered definitely assigned following the call.
10.5.1.4 Parameter arrays
A parameter declared with a params modifier is a parameter array. If a formal parameter list includes a parameter array, it must be the right-most parameter in the list and it must be of a single-dimensional array type. For example, the types string[] and string[][] can be used as the type of a parameter array, but the type string[,] can not. It is not possible to combine the params modifier with the ref and out modifiers.
A parameter array permits arguments to be specified in one of two ways in a method invocation:
• The argument given for a parameter array can be a single expression of a type that is implicitly convertible (§6.1) to the parameter array type. In this case, the parameter array acts precisely like a value parameter.
• Alternatively, the invocation can specify zero or more arguments for the parameter array, where each argument is an expression of a type that is implicitly convertible (§6.1) to the element type of the parameter array. In this case, the invocation creates an instance of the parameter array type with a length corresponding to the number of arguments, initializes the elements of the array instance with the given argument values, and uses the newly created array instance as the actual argument.
Except for allowing a variable number of arguments in an invocation, a parameter array is precisely equivalent to a value parameter (§10.5.1.1) of the same type.
The example
using System;
class Test
{
static void F(params int[] args) {
Console.Write("Array contains {0} elements:", args.Length);
foreach (int i in args)
Console.Write(" {0}", i);
Console.WriteLine();
}
static void Main() {
int[] arr = {1, 2, 3};
F(arr);
F(10, 20, 30, 40);
F();
}
}
produces the output
Array contains 3 elements: 1 2 3
Array contains 4 elements: 10 20 30 40
Array contains 0 elements:
The first invocation of F simply passes the array a as a value parameter. The second invocation of F automatically creates a four-element int[] with the given element values and passes that array instance as a value parameter. Likewise, the third invocation of F creates a zero-element int[] and passes that instance as a value parameter. The second and third invocations are precisely equivalent to writing:
F(new int[] {10, 20, 30, 40});
F(new int[] {});
When performing overload resolution, a method with a parameter array may be applicable either in its normal form or in its expanded form (§7.4.2.1). The expanded form of a method is available only if the normal form of the method is not applicable and only if a method with the same signature as the expanded form is not already declared in the same type.
The example
using System;
class Test
{
static void F(params object[] a) {
Console.WriteLine("F(object[])");
}
static void F() {
Console.WriteLine("F()");
}
static void F(object a0, object a1) {
Console.WriteLine("F(object,object)");
}
static void Main() {
F();
F(1);
F(1, 2);
F(1, 2, 3);
F(1, 2, 3, 4);
}
}
produces the output
F();
F(object[]);
F(object,object);
F(object[]);
F(object[]);
In the example, two of the possible expanded forms of the method with a parameter array are already included in the class as regular methods. These expanded forms are therefore not considered when performing overload resolution, and the first and third method invocations thus select the regular methods. When a class declares a method with a parameter array, it is not uncommon to also include some of the expanded forms as regular methods. By doing so it is possible to avoid the allocation of an array instance that occurs when an expanded form of a method with a parameter array is invoked.
When the type of a parameter array is object[], a potential ambiguity arises between the normal form of the method and the expended form for a single object parameter. The reason for the ambiguity is that an object[] is itself implicitly convertible to type object. The ambiguity presents no problem, however, since it can be resolved by inserting a cast if needed.
The example
using System;
class Test
{
static void F(params object[] args) {
foreach (object o in a) {
Console.Write(o.GetType().FullName);
Console.Write(" ");
}
Console.WriteLine();
}
static void Main() {
object[] a = {1, "Hello", 123.456};
object o = a;
F(a);
F((object)a);
F(o);
F((object[])o);
}
}
produces the output
System.Int32 System.String System.Double
System.Object[]
System.Object[]
System.Int32 System.String System.Double
In the first and last invocations of F, the normal form of F is applicable because an implicit conversion exists from the argument type to the parameter type (both are of type object[]). Thus, overload resolution selects the normal form of F, and the argument is passed as a regular value parameter. In the second and third invocations, the normal form of F is not applicable because no implicit conversion exists from the argument type to the parameter type (type object cannot be implicitly converted to type object[]). However, the expanded form of F is applicable, so it is selected by overload resolution. As a result, a one-element object[] is created by the invocation, and the single element of the array is initialized with the given argument value (which itself is a reference to an object[]).
10.5.2 Static and instance methods
When a method declaration includes a static modifier, the method is said to be a static method. When no static modifier is present, the method is said to be an instance method.
A static method does not operate on a specific instance, and it is a compile-time error to refer to this in a static method.
An instance method operates on a given instance of a class, and this instance can be accessed as this (§7.5.7).
When a method is referenced in a member-access (§7.5.4) of the form E.M, if M is a static method, E must denote a type that has a method M, and if M is an instance method, E must denote an instance of a type that has a method M.
The differences between static and instance members are further discussed in §10.2.5.
10.5.3 Virtual methods
When an instance method declaration includes a virtual modifier, the method is said to be a virtual method. When no virtual modifier is present, the method is said to be a non-virtual method.
The implementation of a non-virtual method is invariant: The implementation is the same whether the method is invoked on an instance of the class in which it is declared or an instance of a derived class. In contrast, the implementation of a virtual method can be superseded by derived classes. The process of superseding the implementation of an inherited virtual method is known as overriding the method (§10.5.4).
In a virtual method invocation, the run-time type of the instance for which the invocation takes place determines the actual method implementation to invoke. In a non-virtual method invocation, the compile-time type of the instance is the determining factor. In precise terms, when a method named N is invoked with an argument list A on an instance with a compile-time type C and a run-time type R (where R is either C or a class derived from C), the invocation is processed as follows:
• First, overload resolution is applied to C, N, and A, to select a specific method M from the set of methods declared in and inherited by C. This is described in §7.5.5.1.
• Then, if M is a non-virtual method, M is invoked.
• Otherwise, M is a virtual method, and the most derived implementation of M with respect to R is invoked.
For every virtual method declared in or inherited by a class, there exists a most derived implementation of the method with respect to that class. The most derived implementation of a virtual method M with respect to a class R is determined as follows:
• If R contains the introducing virtual declaration of M, then this is the most derived implementation of M.
• Otherwise, if R contains an override of M, then this is the most derived implementation of M.
• Otherwise, the most derived implementation of M is the same as that of the direct base class of R.
The following example illustrates the differences between virtual and non-virtual methods:
using System;
class A
{
public void F() { Console.WriteLine("A.F"); }
public virtual void G() { Console.WriteLine("A.G"); }
}
class B: A
{
new public void F() { Console.WriteLine("B.F"); }
public override void G() { Console.WriteLine("B.G"); }
}
class Test
{
static void Main() {
B b = new B();
A a = b;
a.F();
b.F();
a.G();
b.G();
}
}
In the example, A introduces a non-virtual method F and a virtual method G. The class B introduces a new non-virtual method F, thus hiding the inherited F, and also overrides the inherited method G. The example produces the output:
A.F
B.F
B.G
B.G
Notice that the statement a.G() invokes B.G, not A.G. This is because the run-time type of the instance (which is B), not the compile-time type of the instance (which is A), determines the actual method implementation to invoke.
Because methods are allowed to hide inherited methods, it is possible for a class to contain several virtual methods with the same signature. This does not present an ambiguity problem, since all but the most derived method are hidden. In the example
using System;
class A
{
public virtual void F() { Console.WriteLine("A.F"); }
}
class B: A
{
public override void F() { Console.WriteLine("B.F"); }
}
class C: B
{
new public virtual void F() { Console.WriteLine("C.F"); }
}
class D: C
{
public override void F() { Console.WriteLine("D.F"); }
}
class Test
{
static void Main() {
D d = new D();
A a = d;
B b = d;
C c = d;
a.F();
b.F();
c.F();
d.F();
}
}
the C and D classes contain two virtual methods with the same signature: The one introduced by A and the one introduced by C. The method introduced by C hides the method inherited from A. Thus, the override declaration in D overrides the method introduced by C, and it is not possible for D to override the method introduced by A. The example produces the output:
B.F
B.F
D.F
D.F
Note that it is possible to invoke the hidden virtual method by accessing an instance of D through a less derived type in which the method is not hidden.
10.5.4 Override methods
When an instance method declaration includes an override modifier, the method is said to be an override method. An override method overrides an inherited virtual method with the same signature. Whereas a virtual method declaration introduces a new method, an override method declaration specializes an existing inherited virtual method by providing a new implementation of the method.
The method overridden by an override declaration is known as the overridden base method. For an override method M declared in a class C, the overridden base method is determined by examining each base class of C, starting with the direct base class of C and continuing with each successive direct base class, until an accessible method with the same signature as M is located. For the purposes of locating the overridden base method, a method is considered accessible if it is public, if it is protected, if it is protected internal, or if it is internal and declared in the same program as C.
A compile-time error occurs unless all of the following are true for an override declaration:
• An overridden base method can be located as described above.
• The overridden base method is a virtual, abstract, or override method. In other words, the overridden base method cannot be static or non-virtual.
• The overridden base method is not a sealed method.
• The override declaration and the overridden base method have the same declared accessibility. In other words, an override declaration cannot change the accessibility of the virtual method.
An override declaration can access the overridden base method using a base-access (§7.5.8). In the example
class A
{
int x;
public virtual void PrintFields() {
Console.WriteLine("x = {0}", x);
}
}
class B: A
{
int y;
public override void PrintFields() {
base.PrintFields();
Console.WriteLine("y = {0}", y);
}
}
the base.PrintFields() invocation in B invokes the PrintFields method declared in A. A base-access disables the virtual invocation mechanism and simply treats the base method as a non-virtual method. Had the invocation in B been written ((A)this).PrintFields(), it would recursively invoke the PrintFields method declared in B, not the one declared in A, since PrintFields is virtual and the run-time type of ((A)this) is B.
Only by including an override modifier can a method override another method. In all other cases, a method with the same signature as an inherited method simply hides the inherited method. In the example
class A
{
public virtual void F() {}
}
class B: A
{
public virtual void F() {} // Warning, hiding inherited F()
}
the F method in B does not include an override modifier and therefore does not override the F method in A. Rather, the F method in B hides the method in A, and a warning is reported because the declaration does not include a new modifier.
In the example
class A
{
public virtual void F() {}
}
class B: A
{
new private void F() {} // Hides A.F within B
}
class C: B
{
public override void F() {} // Ok, overrides A.F
}
the F method in B hides the virtual F method inherited from A. Since the new F in B has private access, its scope only includes the class body of B and does not extend to C. Therefore, the declaration of F in C is permitted to override the F inherited from A.
10.5.5 Sealed methods
When an instance method declaration includes a sealed modifier, the method is said to be a sealed method. A sealed method overrides an inherited virtual method with the same signature.
An override method can also be marked with the sealed modifier. Use of this modifier prevents a derived class from further overriding the method.
The example
using System;
class A
{
public virtual void F() {
Console.WriteLine("A.F");
}
public virtual void G() {
Console.WriteLine("A.G");
}
}
class B: A
{
sealed override public void F() {
Console.WriteLine("B.F");
}
override public void G() {
Console.WriteLine("B.G");
}
}
class C: B
{
override public void G() {
Console.WriteLine("C.G");
}
}
the class B provides two override methods: an F method that has the sealed modifier and a G method that does not. B’s use of the sealed modifier prevents C from further overriding F.
10.5.6 Abstract methods
When an instance method declaration includes an abstract modifier, the method is said to be an abstract method. Although an abstract method is implicitly also a virtual method, it cannot have the virtual modifier.
An abstract method declaration introduces a new virtual method but does not provide an implementation of the method. Instead, non-abstract derived classes are required to provide their own implementation by overriding the method. Because an abstract method provides no actual implementation, the method-body of an abstract method simply consists of a semicolon.
Abstract method declarations are only permitted in abstract classes (§10.1.1.1).
In the example
public abstract class Shape
{
public abstract void Paint(Graphics g, Rectangle r);
}
public class Ellipse: Shape
{
public override void Paint(Graphics g, Rectangle r) {
g.DrawEllipse(r);
}
}
public class Box: Shape
{
public override void Paint(Graphics g, Rectangle r) {
g.DrawRect(r);
}
}
the Shape class defines the abstract notion of a geometrical shape object that can paint itself. The Paint method is abstract because there is no meaningful default implementation. The Ellipse and Box classes are concrete Shape implementations. Because these classes are non-abstract, they are required to override the Paint method and provide an actual implementation.
It is a compile-time error for a base-access (§7.5.8) to reference an abstract method. In the example
abstract class A
{
public abstract void F();
}
class B: A
{
public override void F() {
base.F(); // Error, base.F is abstract
}
}
a compile-time error is reported for the base.F() invocation because it references an abstract method.
An abstract method declaration is permitted to override a virtual method. This allows an abstract class to force re-implementation of the method in derived classes, and makes the original implementation of the method unavailable. In the example
using System;
class A
{
public virtual void F() {
Console.WriteLine("A.F");
}
}
abstract class B: A
{
public abstract override void F();
}
class C: B
{
public override void F() {
Console.WriteLine("C.F");
}
}
class A declares a virtual method, class B overrides this method with an abstract method, and class C overrides the abstract method to provide its own implementation.
10.5.7 External methods
When a method declaration includes an extern modifier, the method is said to be an external method. External methods are implemented externally, using a language other than C#. Because an external method declaration provides no actual implementation, the method-body of an external method simply consists of a semicolon.
The extern modifier is typically used in conjunction with a DllImport attribute (§17.5.1), allowing external methods to be implemented by DLLs (Dynamic Link Libraries). The execution environment may support other mechanisms whereby implementations of external methods can be provided.
When an external method includes a DllImport attribute, the method declaration must also include a static modifier. This example demonstrates the use of the extern modifier and the DllImport attribute:
using System.Text;
using System.Security.Permissions;
using System.Runtime.InteropServices;
class Path
{
[DllImport("kernel32", setLastError=true)]
static extern bool CreateDirectory(string name, SecurityAttribute sa);
[DllImport("kernel32", setLastError=true)]
static extern bool RemoveDirectory(string name);
[DllImport("kernel32", setLastError=true)]
static extern int GetCurrentDirectory(int bufSize, StringBuilder buf);
[DllImport("kernel32", setLastError=true)]
static extern bool SetCurrentDirectory(string name);
}
10.5.8 Method body
The method-body of a method declaration consists of either a block or a semicolon.
Abstract and external method declarations do not provide a method implementation, so their method bodies simply consist of a semicolon. For any other method, the method body is a block (§8.2) that contains the statements to execute when the method is invoked.
When the return type of a method is void, return statements (§8.9.4) in the method body are not permitted to specify an expression. If execution of the method body of a void method completes normally (that is, control flows off the end of the method body), the method simply returns to its caller.
When the return type of a method is not void, each return statement in the method body must specify an expression of a type that is implicitly convertible to the return type. The endpoint of the method body of a value-returning method must not be reachable. In other words, in a value-returning method, control is not permitted to flow off the end of the method body.
In the example
class A
{
public int F() {} // Error, return value required
public int G() {
return 1;
}
public int H(bool b) {
if (b) {
return 1;
}
else {
return 0;
}
}
}
the value-returning F method results in a compile-time error because control can flow off the end of the method body. The G and H methods are correct because all possible execution paths end in a return statement that specifies a return value.
10.5.9 Method overloading
The method overload resolution rules are described in §7.4.2.
10.6 Properties
A property is a member that provides access to a characteristic of an object or a class. Examples of properties include the length of a string, the size of a font, the caption of a window, the name of a customer, and so on. Properties are a natural extension of fields—both are named members with associated types, and the syntax for accessing fields and properties is the same. However, unlike fields, properties do not denote storage locations. Instead, properties have accessors that specify the statements to be executed when their values are read or written. Properties thus provide a mechanism for associating actions with the reading and writing of an object’s attributes; furthermore, they permit such attributes to be computed.
Properties are declared using property-declarations:
property-declaration:
attributesopt property-modifiersopt type member-name { accessor-declarations }
property-modifiers:
property-modifier
property-modifiers property-modifier
property-modifier:
new
public
protected
internal
private
static
virtual
sealed
override
abstract
extern
member-name:
identifier
interface-type . identifier
A property-declaration may include a set of attributes (§17) and a valid combination of the four access modifiers (§10.2.3), the new (§10.2.2), static (§10.5.2), virtual (§10.5.3), override (§10.5.4), sealed (§10.5.5), abstract (§10.5.6), and extern (§10.5.7) modifiers.
Property declarations are subject to the same rules as method declarations (§10.5) with regard to valid combinations of modifiers.
The type of a property declaration specifies the type of the property introduced by the declaration, and the member-name specifies the name of the property. Unless the property is an explicit interface member implementation, the member-name is simply an identifier. For an explicit interface member implementation (§13.4.1), the member-name consists of an interface-type followed by a “.” and an identifier.
The type of a property must be at least as accessible as the property itself (§3.5.4).
The accessor-declarations, which must be enclosed in “{” and “}” tokens, declare the accessors (§10.6.2) of the property. The accessors specify the executable statements associated with reading and writing the property.
Even though the syntax for accessing a property is the same as that for a field, a property is not classified as a variable. Thus, it is not possible to pass a property as a ref or out argument.
When a property declaration includes an extern modifier, the property is said to be an external property. Because an external property declaration provides no actual implementation, each of its accessor-declarations consists of a semicolon.
10.6.1 Static and instance properties
When a property declaration includes a static modifier, the property is said to be a static property. When no static modifier is present, the property is said to be an instance property.
A static property is not associated with a specific instance, and it is a compile-time error to refer to this in the accessors of a static property.
An instance property is associated with a given instance of a class, and this instance can be accessed as this (§7.5.7) in the accessors of the property.
When a property is referenced in a member-access (§7.5.4) of the form E.M, if M is a static property, E must denote a type that has a property M, and if M is an instance property, E must denote an instance that has a property M.
The differences between static and instance members are further discussed in §10.2.5.
10.6.2 Accessors
The accessor-declarations of a property specify the executable statements associated with reading and writing the property.
accessor-declarations:
get-accessor-declaration set-accessor-declarationopt
set-accessor-declaration get-accessor-declarationopt
get-accessor-declaration:
attributesopt get accessor-body
set-accessor-declaration:
attributesopt set accessor-body
accessor-body:
block
;
The accessor declarations consist of a get-accessor-declaration, a set-accessor-declaration, or both. Each accessor declaration consists of the token get or set followed by an accessor-body. For abstract and extern properties, the accessor-body for each accessor specified is simply a semicolon. For other properties, the accessor-body for each accessor specified is a block which contains the statements to be executed when the corresponding accessor is invoked.
A get accessor corresponds to a parameterless method with a return value of the property type. Except as the target of an assignment, when a property is referenced in an expression, the get accessor of the property is invoked to compute the value of the property (§7.1.1). The body of a get accessor must conform to the rules for value-returning methods described in §10.5.8. In particular, all return statements in the body of a get accessor must specify an expression that is implicitly convertible to the property type. Furthermore, the endpoint of a get accessor must not be reachable.
A set accessor corresponds to a method with a single value parameter of the property type and a void return type. The implicit parameter of a set accessor is always named value. When a property is referenced as the target of an assignment (§7.13), or as the operand of ++ or -- (§7.5.9,§7.6.5), the set accessor is invoked with an argument (whose value is that of the right-hand side of the assignment or the operand of the ++ or -- operator) that provides the new value (§7.13.1). The body of a set accessor must conform to the rules for void methods described in §10.5.8. In particular, return statements in the set accessor body are not permitted to specify an expression. Since a set accessor implicitly has a parameter named value, it is a compile-time error for a local variable declaration in a set accessor to have that name.
Based on the presence or absence of the get and set accessors, a property is classified as follows:
• A property that includes both a get accessor and a set accessor is said to be a read-write property.
• A property that has only a get accessor is said to be a read-only property. It is a compile-time error for a read-only property to be the target of an assignment.
• A property that has only a set accessor is said to be a write-only property. Except as the target of an assignment, it is a compile-time error to reference a write-only property in an expression.
In the example
public class Button: Control
{
private string caption;
public string Caption {
get {
return caption;
}
set {
if (caption != value) {
caption = value;
Repaint();
}
}
}
public override void Paint(Graphics g, Rectangle r) {
// Painting code goes here
}
}
the Button control declares a public Caption property. The get accessor of the Caption property returns the string stored in the private caption field. The set accessor checks if the new value is different from the current value, and if so, it stores the new value and repaints the control. Properties often follow the pattern shown above: The get accessor simply returns a value stored in a private field, and the set accessor modifies the private field and then performs any additional actions required to fully update the state of the object.
Given the Button class above, the following is an example of use of the Caption property:
Button okButton = new Button();
okButton.Caption = "OK"; // Invokes set accessor
string s = okButton.Caption; // Invokes get accessor
Here, the set accessor is invoked by assigning a value to the property, and the get accessor is invoked by referencing the property in an expression.
The get and set accessors of a property are not distinct members, and it is not possible to declare the accessors of a property separately. As such, it is not possible for the two accessors of a read-write property to have different accessibility. The example
class A
{
private string name;
public string Name { // Error, duplicate member name
get { return name; }
}
public string Name { // Error, duplicate member name
set { name = value; }
}
}
does not declare a single read-write property. Rather, it declares two properties with the same name, one read-only and one write-only. Since two members declared in the same class cannot have the same name, the example causes a compile-time error to occur.
When a derived class declares a property by the same name as an inherited property, the derived property hides the inherited property with respect to both reading and writing. In the example
class A
{
public int P {
set {...}
}
}
class B: A
{
new public int P {
get {...}
}
}
the P property in B hides the P property in A with respect to both reading and writing. Thus, in the statements
B b = new B();
b.P = 1; // Error, B.P is read-only
((A)b).P = 1; // Ok, reference to A.P
the assignment to b.P causes a compile-time error because the read-only P property in B hides the write-only P property in A. Note, however, that a cast can be used to access the hidden P property.
Unlike public fields, properties provide a separation between an object’s internal state and its public interface. Consider the example:
class Label
{
private int x, y;
private string caption;
public Label(int x, int y, string caption) {
this.x = x;
this.y = y;
this.caption = caption;
}
public int X {
get { return x; }
}
public int Y {
get { return y; }
}
public Point Location {
get { return new Point(x, y); }
}
public string Caption {
get { return caption; }
}
}
Here, the Label class uses two int fields, x and y, to store its location. The location is publicly exposed both as an X and a Y property and as a Location property of type Point. If, in a future version of Label, it becomes more convenient to store the location as a Point internally, the change can be made without affecting the public interface of the class:
class Label
{
private Point location;
private string caption;
public Label(int x, int y, string caption) {
this.location = new Point(x, y);
this.caption = caption;
}
public int X {
get { return location.x; }
}
public int Y {
get { return location.y; }
}
public Point Location {
get { return location; }
}
public string Caption {
get { return caption; }
}
}
Had x and y instead been public readonly fields, it would have been impossible to make such a change to the Label class.
Exposing state through properties is not necessarily any less efficient than exposing fields directly. In particular, when a property is non-virtual and contains only a small amount of code, the execution environment may replace calls to accessors with the actual code of the accessors. This process is known as inlining, and it makes property access as efficient as field access, yet preserves the increased flexibility of properties.
Since invoking a get accessor is conceptually equivalent to reading the value of a field, it is considered bad programming style for get accessors to have observable side-effects. In the example
class Counter
{
private int next;
public int Next {
get { return next++; }
}
}
the value of the Next property depends on the number of times the property has previously been accessed. Thus, accessing the property produces an observable side-effect, and the property should be implemented as a method instead.
The “no side-effects” convention for get accessors doesn’t mean that get accessors should always be written to simply return values stored in fields. Indeed, get accessors often compute the value of a property by accessing multiple fields or invoking methods. However, a properly designed get accessor performs no actions that cause observable changes in the state of the object.
Properties can be used to delay initialization of a resource until the moment it is first referenced. For example:
using System.IO;
public class Console
{
private static TextReader reader;
private static TextWriter writer;
private static TextWriter error;
public static TextReader In {
get {
if (reader == null) {
reader = new StreamReader(Console.OpenStandardInput());
}
return reader;
}
}
public static TextWriter Out {
get {
if (writer == null) {
writer = new StreamWriter(Console.OpenStandardOutput());
}
return writer;
}
}
public static TextWriter Error {
get {
if (error == null) {
error = new StreamWriter(Console.OpenStandardError());
}
return error;
}
}
}
The Console class contains three properties, In, Out, and Error, that represent the standard input, output, and error devices, respectively. By exposing these members as properties, the Console class can delay their initialization until they are actually used. For example, upon first referencing the Out property, as in
Console.Out.WriteLine("hello, world");
the underlying TextWriter for the output device is created. But if the application makes no reference to the In and Error properties, then no objects are created for those devices.
10.6.3 Virtual, sealed, override, and abstract accessors
A virtual property declaration specifies that the accessors of the property are virtual. The virtual modifier applies to both accessors of a read-write property—it is not possible for only one accessor of a read-write property to be virtual.
An abstract property declaration specifies that the accessors of the property are virtual, but does not provide an actual implementation of the accessors. Instead, non-abstract derived classes are required to provide their own implementation for the accessors by overriding the property. Because an accessor for an abstract property declaration provides no actual implementation, its accessor-body simply consists of a semicolon.
A property declaration that includes both the abstract and override modifiers specifies that the property is abstract and overrides a base property. The accessors of such a property are also abstract.
Abstract property declarations are only permitted in abstract classes (§10.1.1.1).The accessors of an inherited virtual property can be overridden in a derived class by including a property declaration that specifies an override directive. This is known as an overriding property declaration. An overriding property declaration does not declare a new property. Instead, it simply specializes the implementations of the accessors of an existing virtual property.
An overriding property declaration must specify the exact same accessibility modifiers, type, and name as the inherited property. If the inherited property has only a single accessor (i.e., if the inherited property is read-only or write-only), the overriding property must include only that accessor. If the inherited property includes both accessors (i.e., if the inherited property is read-write), the overriding property can include either a single accessor or both accessors.
An overriding property declaration may include the sealed modifier. Use of this modifier prevents a derived class from further overriding the property. The accessors of a sealed property are also sealed.
Except for differences in declaration and invocation syntax, virtual, sealed, override, and abstract accessors behave exactly like virtual, sealed, override and abstract methods. Specifically, the rules described in §10.5.3, §10.5.4, §10.5.5, and §10.5.6 apply as if accessors were methods of a corresponding form:
• A get accessor corresponds to a parameterless method with a return value of the property type and the same modifiers as the containing property.
• A set accessor corresponds to a method with a single value parameter of the property type, a void return type, and the same modifiers as the containing property.
In the example
abstract class A
{
int y;
public virtual int X {
get { return 0; }
}
public virtual int Y {
get { return y; }
set { y = value; }
}
public abstract int Z { get; set; }
}
X is a virtual read-only property, Y is a virtual read-write property, and Z is an abstract read-write property. Because Z is abstract, the containing class A must also be declared abstract.
A class that derives from A is show below:
class B: A
{
int z;
public override int X {
get { return base.X + 1; }
}
public override int Y {
set { base.Y = value < 0? 0: value; }
}
public override int Z {
get { return z; }
set { z = value; }
}
}
Here, the declarations of X, Y, and Z are overriding property declarations. Each property declaration exactly matches the accessibility modifiers, type, and name of the corresponding inherited property. The get accessor of X and the set accessor of Y use the base keyword to access the inherited accessors. The declaration of Z overrides both abstract accessors—thus, there are no outstanding abstract function members in B, and B is permitted to be a non-abstract class.
10.7 Events
An event is a member that enables an object or class to provide notifications. Clients can attach executable code for events by supplying event handlers.
Events are declared using event-declarations:
event-declaration:
attributesopt event-modifiersopt event type variable-declarators ;
attributesopt event-modifiersopt event type member-name { event-accessor-declarations }
event-modifiers:
event-modifier
event-modifiers event-modifier
event-modifier:
new
public
protected
internal
private
static
virtual
sealed
override
abstract
extern
event-accessor-declarations:
add-accessor-declaration remove-accessor-declaration
remove-accessor-declaration add-accessor-declaration
add-accessor-declaration:
attributesopt add block
remove-accessor-declaration:
attributesopt remove block
An event-declaration may include a set of attributes (§17) and a valid combination of the four access modifiers (§10.2.3), the new (§10.2.2), static (§10.5.2), virtual (§10.5.3), override (§10.5.4), sealed (§10.5.5), abstract (§10.5.6), and extern (§10.5.7) modifiers.
Event declarations are subject to the same rules as method declarations (§10.5) with regard to valid combinations of modifiers.
An event declaration may include event-accessor-declarations. However, if it does not, for non-extern, non-abstract events, the compiler shall supply them automatically (§10.7.1); for extern events, the accessors are provided externally.
An event declaration that omits event-accessor-declarations defines one or more events—one for each of the variable-declarators. The attributes and modifiers apply to all of the members declared by such an event-declaration.
It is a compile-time error for an event-declaration to include both the abstract modifier and event-accessor-declarations.
When an event declaration includes an extern modifier, the event is said to be an external event. Because an external event declaration provides no actual implementation, it is a compile-time error for it to include both the extern modifier and event-accessor-declarations.
The type of an event declaration must be a delegate-type (§4.2), and that delegate-type must be at least as accessible as the event itself (§3.5.4).
An event can be used as the left hand operand of the += and -= operators (§7.13.3). These operators are used to attach or remove event handlers to or from an event, and the access modifiers of the event control the contexts in which such operations are permitted.
Since += and -= are the only operations that are permitted on an event outside the type that declares the event, external code can add and remove handlers for an event, but cannot in any other way obtain or modify the underlying list of event handlers.
In an operation of the form x += y or x -= y, when x is an event and the reference takes place outside the type that contains the declaration of x, the result of the operation has type void (as opposed to the type of x). This rule prohibits external code from indirectly examining the underlying delegate of an event.
The following example shows how event handlers are attached to instances of the Button class:
public delegate void EventHandler(object sender, EventArgs e);
public class Button: Control
{
public event EventHandler Click;
}
public class LoginDialog: Form
{
Button OkButton;
Button CancelButton;
public LoginDialog() {
OkButton = new Button(...);
OkButton.Click += new EventHandler(OkButtonClick);
CancelButton = new Button(...);
CancelButton.Click += new EventHandler(CancelButtonClick);
}
void OkButtonClick(object sender, EventArgs e) {
// Handle OkButton.Click event
}
void CancelButtonClick(object sender, EventArgs e) {
// Handle CancelButton.Click event
}
}
Here, the instance constructor for LoginDialog creates two Button instances and attaches event handlers to the Click events.
10.7.1 Field-like events
Within the program text of the class or struct that contains the declaration of an event, certain events can be used like fields. To be used in this way, an event must not be abstract or extern, and must not explicitly include event-accessor-declarations. Such an event can be used in any context that permits a field. The field contains a delegate (§15) which refers to the list of event handlers that have been added to the event. If no event handlers have been added, the field contains null.
In the example
public delegate void EventHandler(object sender, EventArgs e);
public class Button: Control
{
public event EventHandler Click;
protected void OnClick(EventArgs e) {
if (Click != null) Click(this, e);
}
public void Reset() {
Click = null;
}
}
Click is used as a field within the Button class. As the example demonstrates, the field can be examined, modified, and used in delegate invocation expressions. The OnClick method in the Button class “raises” the Click event. The notion of raising an event is precisely equivalent to invoking the delegate represented by the event—thus, there are no special language constructs for raising events. Note that the delegate invocation is preceded by a check that ensures the delegate is non-null.
Outside the declaration of the Button class, the Click member can only be used on the left-hand side of the += and –= operators, as in
b.Click += new EventHandler(…);
which appends a delegate to the invocation list of the Click event, and
b.Click –= new EventHandler(…);
which removes a delegate from the invocation list of the Click event.
When compiling a field-like event, the compiler automatically creates storage to hold the delegate, and creates accessors for the event that add or remove event handlers to the delegate field. In order to be thread-safe, the addition or removal operations are done while holding the lock (§8.12) on the containing object for an instance event, or the type object (§7.5.11) for a static event.
Thus, an instance event declaration of the form:
class X {
public event D Ev;
}
could be compiled to something equivalent to:
class X {
private D __Ev; // field to hold the delegate
public event D Ev {
add {
lock(this) { __Ev = __Ev + value; }
}
remove {
lock(this) { __Ev = __Ev - value; }
}
}
}
Within the class X, references to Ev are compiled to reference the hidden field __Ev instead. The name “__Ev” is arbitrary; the hidden field could have any name or no name at all.
Similarly, a static event declaration of the form:
class X {
public static event D Ev;
}
could be compiled to something equivalent to:
class X {
private static D __Ev; // field to hold the delegate
public static event D Ev {
add {
lock(typeof(X)) { __Ev = __Ev + value; }
}
remove {
lock(typeof(X)) { __Ev = __Ev - value; }
}
}
}
10.7.2 Event accessors
Event declarations typically omit event-accessor-declarations, as in the Button example above. whereOne situation for doing so involves the case in which the storage cost of one field per event is not acceptable. In such cases, a class can include event-accessor-declarations and use a private mechanism for storing the list of event handlers.
The event-accessor-declarations of an event specify the executable statements associated with adding and removing event handlers.
The accessor declarations consist of an add-accessor-declaration and a remove-accessor-declaration. Each accessor declaration consists of the token add or remove followed by a block. The block associated with an add-accessor-declaration specifies the statements to execute when an event handler is added, and the block associated with a remove-accessor-declaration specifies the statements to execute when an event handler is removed.
Each add-accessor-declaration and remove-accessor-declaration corresponds to a method with a single value parameter of the event type and a void return type. The implicit parameter of an event accessor is named value. When an event is used in an event assignment, the appropriate event accessor is used. If the assignment operator is += then the add accessor is used, and if the assignment operator is -= then the remove accessor is used. In either case, the right hand operand of the assignment operator is used as the argument to the event accessor. The block of an add-accessor-declaration or a remove-accessor-declaration must conform to the rules for void methods described in §10.5.8. In particular, return statements in such a block are not permitted to specify an expression.
Since an event accessor implicitly has a parameter named value, it is a compile-time error for a local variable declared in an event accessor to have that name.
In the example
class Control: Component
{
// Unique keys for events
static readonly object mouseDownEventKey = new object();
static readonly object mouseUpEventKey = new object();
// Return event handler associated with key
protected delegate GetEventHandler(object key) {...}
// Add event handler associated with key
protected void AddEventHandler(object key, Delegate handler) {...}
// Remove event handler associated with key
protected void RemoveEventHandler(object key, Delegate handler) {...}
// MouseDown event
public event MouseEventHandler MouseDown {
add { AddEventHandler(mouseDownEventKey, value); }
remove { RemoveEventHandler(mouseDownEventKey, value); }
}
// MouseUp event
public event MouseEventHandler MouseUp {
add { AddEventHandler(mouseUpEventKey, value); }
remove { RemoveEventHandler(mouseUpEventKey, value); }
}
// Invoke the MouseUp event
protected void OnMouseUp(MouseEventArgs args) {
MouseEventHandler handler;
handler = (MouseEventHandler)GetEventHandler(mouseUpEventKey);
if (handler != null)
handler(this, args);
}
}
the Control class implements an internal storage mechanism for events. The AddEventHandler method associates a delegate value with a key, the GetEventHandler method returns the delegate currently associated with a key, and the RemoveEventHandler method removes a delegate as an event handler for the specified event. Presumably, the underlying storage mechanism is designed such that there is no cost for associating a null delegate value with a key, and thus unhandled events consume no storage.
10.7.3 Static and instance events
When an event declaration includes a static modifier, the event is said to be a static event. When no static modifier is present, the event is said to be an instance event.
A static event is not associated with a specific instance, and it is a compile-time error to refer to this in the accessors of a static event.
An instance event is associated with a given instance of a class, and this instance can be accessed as this (§7.5.7) in the accessors of the event.
When an event is referenced in a member-access (§7.5.4) of the form E.M, if M is a static event, E must denote a type, and if M is an instance event, E must denote an instance.
The differences between static and instance members are discussed further in §10.2.5.
10.7.4 Virtual, sealed, override, and abstract accessors
A virtual event declaration specifies that the accessors of the event are virtual. The virtual modifier applies to both accessors of an event.
An abstract event declaration specifies that the accessors of the event are virtual, but does not provide an actual implementation of the accessors. Instead, non-abstract derived classes are required to provide their own implementation for the accessors by overriding the event. Because an accessor for an abstract event declaration provides no actual implementation, its accessor-body simply consists of a semicolon.
An event declaration that includes both the abstract and override modifiers specifies that the event is abstract and overrides a base event. The accessors of such an event are also abstract.
Abstract event declarations are only permitted in abstract classes (§10.1.1.1).
The accessors of an inherited virtual event can be overridden in a derived class by including an event declaration that specifies an override modifier. This is known as an overriding event declaration. An overriding event declaration does not declare a new event. Instead, it simply specializes the implementations of the accessors of an existing virtual event.
An overriding event declaration must specify the exact same accessibility modifiers, type, and name as the overridden event.
An overriding event declaration may include the sealed modifier. Use of this modifier prevents a derived class from further overriding the event. The accessors of a sealed event are also sealed.
It is a compile-time error for an overriding event declaration to include a new modifier.
Except for differences in declaration and invocation syntax, virtual, sealed, override, and abstract accessors behave exactly like virtual, sealed, override and abstract methods. Specifically, the rules described in §10.5.3, §10.5.4, §10.5.5, and §10.5.6 apply as if accessors were methods of a corresponding form. Each accessor corresponds to a method with a single value parameter of the event type, a void return type, and the same modifiers as the containing event.
10.8 Indexers
An indexer is a member that enables an object to be indexed in the same way as an array. Indexers are declared using indexer-declarations:
indexer-declaration:
attributesopt indexer-modifiersopt indexer-declarator { accessor-declarations }
indexer-modifiers:
indexer-modifier
indexer-modifiers indexer-modifier
indexer-modifier:
new
public
protected
internal
private
virtual
sealed
override
abstract
extern
indexer-declarator:
type this [ formal-parameter-list ]
type interface-type . this [ formal-parameter-list ]
An indexer-declaration may include a set of attributes (§17) and a valid combination of the four access modifiers (§10.2.3), the new (§10.2.2), virtual (§10.5.3), override (§10.5.4), sealed (§10.5.5), abstract (§10.5.6), and extern (§10.5.7) modifiers.
Indexer declarations are subject to the same rules as method declarations (§10.5) with regard to valid combinations of modifiers, with the one exception being that the static modifier is not permitted on an indexer declaration.
The type of an indexer declaration specifies the element type of the indexer introduced by the declaration. Unless the indexer is an explicit interface member implementation, the type is followed by the keyword this. For an explicit interface member implementation, the type is followed by an interface-type, a “.”, and the keyword this. Unlike other members, indexers do not have user-defined names.
The formal-parameter-list specifies the parameters of the indexer. The formal parameter list of an indexer corresponds to that of a method (§10.5.1), except that at least one parameter must be specified, and that the ref and out parameter modifiers are not permitted.
The type of an indexer and each of the types referenced in the formal-parameter-list must be at least as accessible as the indexer itself (§3.5.4).
The accessor-declarations (§10.6.2) which must be enclosed in “{” and “}” tokens, declare the accessors of the indexer. The accessors specify the executable statements associated with reading and writing indexer elements.
Even though the syntax for accessing an indexer element is the same as that for an array element, an indexer element is not classified as a variable. Thus, it is not possible to pass an indexer element as a ref or out argument.
The formal parameter list of an indexer defines the signature (§3.6) of the indexer. Specifically, the signature of an indexer consists of the number and types of its formal parameters. The element type and names of the formal parameters are not part of an indexer’s signature.
The signature of an indexer must differ from the signatures of all other indexers declared in the same class.
Indexers and properties are very similar in concept, but differ in the following ways:
• A property is identified by its name, whereas an indexer is identified by its signature.
• A property is accessed through a simple-name (§7.5.2) or a member-access (§7.5.4), whereas an indexer element is accessed through an element-access (§7.5.6.2).
• A property can be a static member, whereas an indexer is always an instance member.
• A get accessor of a property corresponds to a method with no parameters, whereas a get accessor of an indexer corresponds to a method with the same formal parameter list as the indexer.
• A set accessor of a property corresponds to a method with a single parameter named value, whereas a set accessor of an indexer corresponds to a method with the same formal parameter list as the indexer, plus an additional parameter named value.
• It is a compile-time error for an indexer accessor to declare a local variable with the same name as an indexer parameter.
• In an overriding property declaration, the inherited property is accessed using the syntax base.P, where P is the property name. In an overriding indexer declaration, the inherited indexer is accessed using the syntax base[E], where E is a comma separated list of expressions.
Aside from these differences, all rules defined in §10.6.2 and §10.6.3 apply to indexer accessors as well as to property accessors.
When an indexer declaration includes an extern modifier, the indexer is said to be an external indexer. Because an external indexer declaration provides no actual implementation, each of its accessor-declarations consists of a semicolon.
The example below declares a BitArray class that implements an indexer for accessing the individual bits in the bit array.
using System;
class BitArray
{
int[] bits;
int length;
public BitArray(int length) {
if (length < 0) throw new ArgumentException();
bits = new int[((length - 1) >> 5) + 1];
this.length = length;
}
public int Length {
get { return length; }
}
public bool this[int index] {
get {
if (index < 0 || index >= length) {
throw new IndexOutOfRangeException();
}
return (bits[index >> 5] & 1 << index) != 0;
}
set {
if (index < 0 || index >= length) {
throw new IndexOutOfRangeException();
}
if (value) {
bits[index >> 5] |= 1 << index;
}
else {
bits[index >> 5] &= ~(1 << index);
}
}
}
}
An instance of the BitArray class consumes substantially less memory than a corresponding bool[] (since each value of the former occupies only one bit instead of the latter’s one byte), but it permits the same operations as a bool[].
The following CountPrimes class uses a BitArray and the classical “sieve” algorithm to compute the number of primes between 1 and a given maximum:
class CountPrimes
{
static int Count(int max) {
BitArray flags = new BitArray(max + 1);
int count = 1;
for (int i = 2; i <= max; i++) {
if (!flags[i]) {
for (int j = i * 2; j <= max; j += i) flags[j] = true;
count++;
}
}
return count;
}
static void Main(string[] args) {
int max = int.Parse(args[0]);
int count = Count(max);
Console.WriteLine("Found {0} primes between 1 and {1}", count, max);
}
}
Note that the syntax for accessing elements of the BitArray is precisely the same as for a bool[].
The following example shows a 26 by 10 grid class that has an indexer with two parameters. The first parameter is required to be an upper- or lowercase letter in the range A–Z, and the second is required to be an integer in the range 0–9.
class Grid
{
const int NumRows = 26;
const int NumCols = 10;
int[,] cells = new int[NumRows, NumCols];
public int this[char c, int colm] {
get {
c = Char.ToUpper(c);
if (c < 'A' || c > 'Z')
throw new ArgumentException();
if (colm < 0 || colm >= NumCols)
throw new IndexOutOfRangeException();
return cells[c - 'A', colm];
}
set {
c = Char.ToUpper(c);
if (c < 'A' || c > 'Z')
throw new ArgumentException();
if (colm < 0 || colm >= NumCols)
throw new IndexOutOfRangeException();
cells[c - 'A', colm] = value;
}
}
}
10.8.1 Indexer overloading
The indexer overload resolution rules are described in §7.4.2.
10.9 Operators
An operator is a member that defines the meaning of an expression operator that can be applied to instances of the class. Operators are declared using operator-declarations:
operator-declaration:
attributesopt operator-modifiers operator-declarator operator-body
operator-modifiers:
operator-modifier
operator-modifiers operator-modifier
operator-modifier:
public
static
extern
operator-declarator:
unary-operator-declarator
binary-operator-declarator
conversion-operator-declarator
unary-operator-declarator:
type operator overloadable-unary-operator ( type identifier )
overloadable-unary-operator: one of
+ - ! ~ ++ -- true false
binary-operator-declarator:
type operator overloadable-binary-operator ( type identifier , type identifier )
overloadable-binary-operator: one of
+ - * / % & | ^ << >> == != > < >= <=
conversion-operator-declarator:
implicit operator type ( type identifier )
explicit operator type ( type identifier )
operator-body:
block
;
There are three categories of overloadable operators: Unary operators (§10.9.1), binary operators (§10.9.2), and conversion operators (§10.9.3).
When an operator declaration includes an extern modifier, the operator is said to be an external operator. Because an external operator provides no actual implementation, its operator-body consists of a semi-colon. For all other operators, the operator-body consists of a block, which specifies the statements to execute when the operator is invoked. The block of an operator must conform to the rules for value-returning methods described in §10.5.8.
The following rules apply to all operator declarations:
• An operator declaration must include both a public and a static modifier.
• The parameter(s) of an operator must be value parameters. It is a compile-time error for an operator declaration to specify ref or out parameters.
• The signature of an operator (§10.9.1, §10.9.2, §10.9.3) must differ from the signatures of all other operators declared in the same class.
• All types referenced in an operator declaration must be at least as accessible as the operator itself (§3.5.4).
• It is a compile-time error for the same modifier to appear multiple times in an operator declaration.
Each operator category imposes additional restrictions, as described in the following sections.
Like other members, operators declared in a base class are inherited by derived classes. Because operator declarations always require the class or struct in which the operator is declared to participate in the signature of the operator, it is not possible for an operator declared in a derived class to hide an operator declared in a base class. Thus, the new modifier is never required, and therefore never permitted, in an operator declaration.
Additional information on unary and binary operators can be found in §7.2.
Additional information on conversion operators can be found in §6.4.
10.9.1 Unary operators
The following rules apply to unary operator declarations, where T denotes the class or struct type that contains the operator declaration:
• A unary +, -, !, or ~ operator must take a single parameter of type T and can return any type.
• A unary ++ or -- operator must take a single parameter of type T and must return type T.
• A unary true or false operator must take a single parameter of type T and must return type bool.
The signature of a unary operator consists of the operator token (+, -, !, ~, ++, --, true, or false) and the type of the single formal parameter. The return type is not part of a unary operator’s signature, nor is the name of the formal parameter.
The true and false unary operators require pair-wise declaration. A compile-time error occurs if a class declares one of these operators without also declaring the other. The true and false operators are described further in §7.16.
The following example shows an implementation and subsequent usage of operator++ for an integer vector class:
class IntVector
{
public int Length { ... } // read-only property
public int this[int index] { ... } // read-write indexer
public IntVector(int vectorLength) { ... }
public static IntVector operator++(IntVector iv) {
IntVector temp = new IntVector(iv.Length);
for (int i = 0; i < iv.Length; ++i)
temp[i] = iv[i] + 1;
return temp;
}
}
class Test
{
public static void Main() {
IntVector iv1 = new IntVector(4); // vector of 4x0
IntVector iv2;
iv2 = iv1++; // iv2 contains 4x0, iv1 contains 4x1
iv2 = ++iv1; // iv2 contains 4x2, iv1 contains 4x2
}
Note that the operator returns the value produced by adding 1 to the operand, just like the postfix increment and decrement operators (§7.5.9), and the prefix increment and decrement operators (§7.6.5). Unlike in C++, this method need not, and, in fact, must not, modify the value of its operand directly.
10.9.2 Binary operators
A binary operator must take two parameters, at least one of which must have the class or struct type in which the operator is declared. A binary operator can return any type.
The signature of a binary operator consists of the operator token (+, -, *, /, %, &, |, ^, <<, >>, ==, !=, >, <, >=, or <=) and the types of the two formal parameters. The return type and names of the formal parameters are not part of a binary operator’s signature.
Certain binary operators require pair-wise declaration. For every declaration of either operator of a pair, there must be a matching declaration of the other operator of the pair. Two operator declarations match when they have the same return type and the same type for each parameter. The following operators require pair-wise declaration:
• operator == and operator !=
• operator > and operator <
• operator >= and operator <=
10.9.3 Conversion operators
A conversion operator declaration introduces a user-defined conversion (§6.4) which augments the pre-defined implicit and explicit conversions.
A conversion operator declaration that includes the implicit keyword introduces a user-defined implicit conversion. Implicit conversions can occur in a variety of situations, including function member invocations, cast expressions, and assignments. This is described further in §6.1.
A conversion operator declaration that includes the explicit keyword introduces a user-defined explicit conversion. Explicit conversions can occur in cast expressions, and are described further in §6.2.
A conversion operator converts from a source type, indicated by the parameter type of the conversion operator, to a target type, indicated by the return type of the conversion operator. A class or struct is permitted to declare a conversion from a source type S to a target type T provided all of the following are true:
• S and T are different types.
• Either S or T is the class or struct type in which the operator declaration takes place.
• Neither S nor T is object or an interface-type.
• T is not a base class of S, and S is not a base class of T.
From the second rule it follows that a conversion operator must convert either to or from the class or struct type in which the operator is declared. For example, it is possible for a class or struct type C to define a conversion from C to int and from int to C, but not from int to bool.
It is not possible to redefine a pre-defined conversion. Thus, conversion operators are not allowed to convert from or to object because implicit and explicit conversions already exist between object and all other types. Likewise, neither the source nor the target types of a conversion can be a base type of the other, since a conversion would then already exist.
User-defined conversions are not allowed to convert from or to interface-types. This restriction in particular ensures that no user-defined transformations occur when converting to an interface-type, and that a conversion to an interface-type succeeds only if the object being converted actually implements the specified interface-type.
The signature of a conversion operator consists of the source type and the target type. (Note that this is the only form of member for which the return type participates in the signature.) The implicit or explicit classification of a conversion operator is not part of the operator’s signature. Thus, a class or struct cannot declare both an implicit and an explicit conversion operator with the same source and target types.
In general, user-defined implicit conversions should be designed to never throw exceptions and never lose information. If a user-defined conversion can give rise to exceptions (for example, because the source argument is out of range) or loss of information (such as discarding high-order bits), then that conversion should be defined as an explicit conversion.
In the example
using System;
public struct Digit
{
byte value;
public Digit(byte value) {
if (value < 0 || value > 9) throw new ArgumentException();
this.value = value;
}
public static implicit operator byte(Digit d) {
return d.value;
}
public static explicit operator Digit(byte b) {
return new Digit(b);
}
}
the conversion from Digit to byte is implicit because it never throws exceptions or loses information, but the conversion from byte to Digit is explicit since Digit can only represent a subset of the possible values of a byte.
10.10 Instance constructors
An instance constructor is a member that implements the actions required to initialize an instance of a class. Instance constructors are declared using constructor-declarations:
constructor-declaration:
attributesopt constructor-modifiersopt constructor-declarator constructor-body
constructor-modifiers:
constructor-modifier
constructor-modifiers constructor-modifier
constructor-modifier:
public
protected
internal
private
extern
constructor-declarator:
identifier ( formal-parameter-listopt ) constructor-initializeropt
constructor-initializer:
: base ( argument-listopt )
: this ( argument-listopt )
constructor-body:
block
;
A constructor-declaration may include a set of attributes (§17), a valid combination of the four access modifiers (§10.2.3), and an extern (§10.5.7) modifier. A constructor declaration is not permitted to include the same modifier multiple times.
The identifier of a constructor-declarator must name the class in which the constructor is declared. If any other name is specified, a compile-time error occurs.
The optional formal-parameter-list of an instance constructor is subject to the same rules as the formal-parameter-list of a method (§10.5). The formal parameter list defines the signature (§3.6) of an instance constructor and governs the process whereby overload resolution (§7.4.2) selects a particular instance constructor in an invocation.
Each of the types referenced in the formal-parameter-list of an instance constructor must be at least as accessible as the constructor itself (§3.5.4).
The optional constructor-initializer specifies another instance constructor to invoke before executing the statements given in the constructor-body of this instance constructor. This is described further in §10.10.1.
When a constructor declaration includes an extern modifier, the constructor is said to be an external constructor. Because an external constructor declaration provides no actual implementation, its constructor-body consists of a semicolon. For all other constructors, the constructor-body consists of a block which specifies the statements to initialize a new instance of the class. This corresponds exactly to the block of an instance method with a void return type (§10.5.8).
Instance constructors are not inherited. Thus, a class has no instance constructors other than those actually declared in the class. If a class contains no instance constructor declarations, a default instance constructor is automatically provided (§10.10.4).
Instance constructors are invoked by object-creation-expressions (§7.5.10.1) and through constructor-initializers.
10.10.1 Constructor initializers
All instance constructors (except those for class object) implicitly include an invocation of another instance constructor immediately before the constructor-body. The constructor to implicitly invoke is determined by the constructor-initializer:
• A instance constructor initializer of the form base(argument-listopt) causes an instance constructor from the direct base class to be invoked. The constructor is selected using the argument-list and overload resolution rules of §7.4.2. The set of candidate instance constructors consists of all accessible instance constructors declared in the direct base class. If the set is empty, or if a single best instance constructor cannot be identified, a compile-time error occurs.
• An instance constructor initializer of the form this(argument-listopt) causes an instance constructor from the class itself to be invoked. The constructor is selected using the argument-list and overload resolution rules of §7.4.2. The set of candidate instance constructors consists of all accessible instance constructors declared in the class itself. If the set is empty, or if a single best instance constructor cannot be identified, a compile-time error occurs. If an instance constructor declaration includes a constructor initializer that invokes the constructor itself, a compile-time error occurs.
If an instance constructor has no instance constructor initializer, an instance constructor initializer of the form base() is implicitly provided. Thus, an instance constructor declaration of the form
C(...) {...}
is equivalent to
C(...): base() {...}
The scope of the parameters given by the formal-parameter-list of an instance constructor declaration includes the instance constructor initializer of that declaration. Thus, an instance constructor initializer is permitted to access the parameters of the instance constructor. For example:
class A
{
public A(int x, int y) {}
}
class B: A
{
public B(int x, int y): base(x + y, x - y) {}
}
An instance constructor initializer cannot access the instance being created. Therefore it is a compile-time error to reference this in an argument expression of the instance constructor initializer, as it is a compile-time error for an argument expression to reference any instance member through a simple-name.
10.10.2 Instance variable initializers
When an instance constructor has no instance constructor initializer, or when it has an instance constructor initializer of the form base(...), it implicitly performs the initializations specified by the variable-initializers of the instance fields declared in the class. This corresponds to a sequence of assignments that are executed immediately upon entry to the instance constructor and before the implicit invocation of the direct base class instance constructor. The variable initializers are executed in the textual order in which they appear in the class declaration.
10.10.3 Constructor execution
Variable initializers are transformed into assignment statements, and these assignment statements are executed before the invocation of the base class instance constructor. This ordering ensures that all instance fields are initialized by their variable initializers before any statements that have access to that instance are executed.
In the example
using System;
class A
{
public A() {
PrintFields();
}
public virtual void PrintFields() {}
}
class B: A
{
int x = 1;
int y;
public B() {
y = -1;
}
public override void PrintFields() {
Console.WriteLine("x = {0}, y = {1}", x, y);
}
}
class T
{
static void Main() {
B b = new B();
}
}
the following output is produced:
x = 1, y = 0
The value of x is 1 because the variable initializer is executed before the base class instance constructor is invoked. However, the value of y is 0 (the default value of an int) because the assignment to y is not executed until after the base class constructor returns.
It is useful to think of instance variable initializers and constructor initializers as statements that are automatically inserted before the constructor-body of an instance constructor. The example
using System;
using System.Collections;
class A
{
int x = 1, y = -1, count;
public A() {
count = 0;
}
public A(int n) {
count = n;
}
}
class B: A
{
double sqrt2 = Math.Sqrt(2.0);
ArrayList items = new ArrayList(100);
int max;
public B(): this(100) {
items.Add("default");
}
public B(int n): base(n – 1) {
max = n;
}
}
contains several variable initializers and also contains constructor initializers of both forms (base and this). The example corresponds to the code shown below, where each comment indicates an automatically inserted statement (the syntax used for the automatically inserted constructor invocations isn’t valid, but merely serves to illustrate the mechanism).
using System.Collections;
class A
{
int x, y, count;
public A() {
x = 1; // Variable initializer
y = -1; // Variable initializer
object(); // Invoke object() constructor
count = 0;
}
public A(int n) {
x = 1; // Variable initializer
y = -1; // Variable initializer
object(); // Invoke object() constructor
count = n;
}
}
class B: A
{
double sqrt2;
ArrayList items;
int max;
public B(): this(100) {
B(100); // Invoke B(int) constructor
items.Add("default");
}
public B(int n): base(n – 1) {
sqrt2 = Math.Sqrt(2.0); // Variable initializer
items = new ArrayList(100); // Variable initializer
A(n – 1); // Invoke A(int) constructor
max = n;
}
}
10.10.4 Default constructors
If a class contains no instance constructor declarations, a default instance constructor is automatically provided. The default constructor simply invokes the parameterless constructor of the direct base class. If the direct base class does not have an accessible parameterless instance constructor, a compile-time error occurs. If the class is abstract then the declared accessibility for the default constructor is protected. Otherwise, the declared accessibility for the default constructor is public. Thus, the default constructor is always of the form
protected C(): base() {}
or
public C(): base() {}
where C is the name of the class.
In the example
class Message
{
object sender;
string text;
}
a default constructor is provided because the class contains no instance constructor declarations. Thus, the example is precisely equivalent to
class Message
{
object sender;
string text;
public Message(): base() {}
}
10.10.5 Private constructors
When a class declares only private instance constructors, it is not possible for other classes to derive from the class or create instances of the class (an exception being classes nested within the class). Private instance constructors are commonly used in classes that contain only static members. For example:
public class Trig
{
private Trig() {} // Prevent instantiation
public const double PI = 3.14159265358979323846;
public static double Sin(double x) {...}
public static double Cos(double x) {...}
public static double Tan(double x) {...}
}
The Trig class groups related methods and constants, but is not intended to be instantiated. Therefore it declares a single empty private instance constructor. At least one instance constructor must be declared to suppress the automatic generation of a default constructor.
10.10.6 Optional instance constructor parameters
The this(...) form of an instance constructor initializer is commonly used in conjunction with overloading to implement optional instance constructor parameters. In the example
class Text
{
public Text(): this(0, 0, null) {}
public Text(int x, int y): this(x, y, null) {}
public Text(int x, int y, string s) {
// Actual constructor implementation
}
}
the first two instance constructors merely provide the default values for the missing arguments. Both use a this(...) constructor initializer to invoke the third instance constructor, which actually does the work of initializing the new instance. The effect is that of optional instance constructor parameters:
Text t1 = new Text(); // Same as Text(0, 0, null)
Text t2 = new Text(5, 10); // Same as Text(5, 10, null)
Text t3 = new Text(5, 20, "Hello");
10.11 Static constructors
A static constructor is a member that implements the actions required to initialize a class. Static constructors are declared using static-constructor-declarations:
static-constructor-declaration:
attributesopt static-constructor-modifiers identifier ( ) static-constructor-body
static-constructor-body:
block
;
static-constructor-modifiers:
externopt static
static externopt
A static-constructor-declaration may include a set of attributes (§17) and an extern (§10.5.7) modifier.
The identifier of a static-constructor-declaration must name the class in which the static constructor is declared. If any other name is specified, a compile-time error occurs.
When a static constructor declaration includes an extern modifier, the static constructor is said to be an external static constructor. Because an external static constructor declaration provides no actual implementation, its static-constructor-body consists of a semicolon. For all other static constructor declarations, the static-constructor-body consists of a block which specifies the statements to execute in order to initialize the class. This corresponds exactly to the method-body of a static method with a void return type (§10.5.8).
Static constructors are not inherited, and cannot be called directly.
The static constructor for a class executes at most once in a given application domain. The execution of a static constructor is triggered by the first of the following events to occur within an application domain:
• An instance of the class is created.
• Any of the static members of the class are referenced.
If a class contains the Main method (§3.1) in which execution begins, the static constructor for that class executes before the Main method is called. If a class contains any static fields with initializers, those initializers are executed in textual order immediately prior to executing the static constructor.
The example
using System;
class Test
{
static void Main() {
A.F();
B.F();
}
}
class A
{
static A() {
Console.WriteLine("Init A");
}
public static void F() {
Console.WriteLine("A.F");
}
}
class B
{
static B() {
Console.WriteLine("Init B");
}
public static void F() {
Console.WriteLine("B.F");
}
}
must produce the output:
Init A
A.F
Init B
B.F
because the execution of A's static constructor is triggered by the call to A.F, and the execution of B's static constructor is triggered by the call to B.F.
It is possible to construct circular dependencies that allow static fields with variable initializers to be observed in their default value state.
The example
using System;
class A
{
public static int X;
static A() { X = B.Y + 1;}
}
class B
{
public static int Y = A.X + 1;
static B() {}
static void Main() {
Console.WriteLine("X = {0}, Y = {1}", A.X, B.Y);
}
}
produces the output
X = 1, Y = 2
To execute the Main method, the system first runs the initializer for B.Y, prior to class B's static constructor. Y's initializer causes A's static constructor to be run because the value of A.X is referenced. The static constructor of A in turn proceeds to compute the value of X, and in doing so fetches the default value of Y, which is zero. A.X is thus initialized to 1. The process of running A's static field initializers and static constructor then completes, returning to the calculation of the initial value of Y, the result of which becomes
10.12 Destructors
A destructor is a member that implements the actions required to destruct an instance of a class. A destructors is declared using a destructor-declaration:
destructor-declaration:
attributesopt externopt ~ identifier ( ) destructor-body
destructor-body:
block
;
A destructor-declaration may include a set of attributes (§17) and an extern modifier.
The identifier of a destructor-declarator must name the class in which the destructor is declared. If any other name is specified, a compile-time error occurs.
When a destructor declaration includes an extern modifier, the destructor is said to be an external destructor. Because an external destructor declaration provides no actual implementation, its destructor-body consists of a semicolon. For all other destructors, the destructor-body consists of a block which specifies the statements to execute in order to destruct an instance of the class. A destructor-body corresponds exactly to the method-body of an instance method with a void return type (§10.5.8).
Destructors are not inherited. Thus, a class has no destructors other than the one which may be declared in it.
Since a destructor is required to have no parameters, it cannot be overloaded. Thus, a class can have, at most, one destructor.
Destructors are invoked automatically, and cannot be invoked explicitly. An instance becomes eligible for destruction when it is no longer possible for any code to use the instance. Execution of the destructor for the instance may occur at any time after the instance becomes eligible for destruction. When an instance is destructed, the destructors in its inheritance chain are called, in order, from most derived to least derived. A destructor may be executed on any thread. For further discussion of the rules that govern when and how a destructor is executed, see §3.9.
The output of the example
using System;
class A
{
~A() {
Console.WriteLine("A's destructor");
}
}
class B: A
{
~B() {
Console.WriteLine("B's destructor");
}
}
class Test
{
static void Main() {
B b = new B();
b = null;
GC.Collect();
GC.WaitForPendingFinalizers();
}
}
is
B’s destructor
A’s destructor
since destructors in an inheritance chain are called in order, from most derived to least derived.
Destructors are implemented by overriding the virtual method Finalize on System.Object. C# programs are not permitted to override this method or call it (or overrides of it) directly. For instance, the program
class A
{
override protected void Finalize() {} // error
public void F() {
this.Finalize(); // error
}
}
produces two compile-time errors. The compiler behaves as if this method, and overrides of it, do not exist at all. Thus, this program:
class A
{
void Finalize() {} // permitted
}
is valid, and the method shown hides System.Object’s Finalize method.
For a discussion of the behavior when an exception is thrown from a destructor, see §16.3.

11. Structs
Structs are similar to classes in that they represent data structures that can contain data members and function members. Unlike classes, structs are value types and do not require heap allocation. A variable of a struct type directly contains the data of the struct, whereas a variable of a class type contains a reference to the data, the latter known as an object.
Structs are particularly useful for small data structures that have value semantics. Complex numbers, points in a coordinate system, or key-value pairs in a dictionary are all good examples of structs. Key to these data structures is that they have few data members, that they do not require use of inheritance or referential identity, and that they can be conveniently implemented using value semantics where assignment copies the value instead of the reference.
As described in §4.1.3, the simple types provided by C#, such as int, double, and bool, are in fact all struct types. Just as these predefined types are structs, so it is possible to use structs and operator overloading to implement new “primitive” types in the C# language. Two examples of such types are given in at the end of this chapter (§11.4).
11.1 Struct declarations
A struct-declaration is a type-declaration (§9.5) that declares a new struct:
struct-declaration:
attributesopt struct-modifiersopt struct identifier struct-interfacesopt struct-body ;opt
A struct-declaration consists of an optional set of attributes (§17), followed by an optional set of struct-modifiers (§11.1.1), followed by the keyword struct and an identifier that names the struct, followed by an optional struct-interfaces specification (§11.1.2), followed by a struct-body (§11.1.3), optionally followed by a semicolon.
11.1.1 Struct modifiers
A struct-declaration may optionally include a sequence of struct modifiers:
struct-modifiers:
struct-modifier
struct-modifiers struct-modifier
struct-modifier:
new
public
protected
internal
private
It is a compile-time error for the same modifier to appear multiple times in a struct declaration.
The modifiers of a struct declaration have the same meaning as those of a class declaration (§10.1.1).
11.1.2 Struct interfaces
A struct declaration may include a struct-interfaces specification, in which case the struct is said to implement the given interface types.
struct-interfaces:
: interface-type-list
Interface implementations are discussed further in §13.4.
11.1.3 Struct body
The struct-body of a struct defines the members of the struct.
struct-body:
{ struct-member-declarationsopt }
11.2 Struct members
The members of a struct consist of the members introduced by its struct-member-declarations and the members inherited from System.ValueType, which, in turn, inherits from object.
struct-member-declarations:
struct-member-declaration
struct-member-declarations struct-member-declaration
struct-member-declaration:
constant-declaration
field-declaration
method-declaration
property-declaration
event-declaration
indexer-declaration
operator-declaration
constructor-declaration
static-constructor-declaration
type-declaration
Except for the differences noted in §11.3, the descriptions of class members provided in §10.2 through §10.11 apply to struct members as well.
11.3 Class and struct differences
Structs differ from classes in several important ways:
• Structs are value types (§11.3.1).
• All struct types implicitly inherit from class object (§11.3.2).
• Assignment to a variable of a struct type creates a copy of the value being assigned (§11.3.3).
• The default value of a struct is the value produced by setting all value type fields to their default value and all reference type fields to null (§11.3.4).
• Boxing and unboxing operations are used to convert between a struct type and object (§11.3.5).
• The meaning of this is different for structs (§11.3.6).
• Instance field declarations for a struct are not permitted to include variable initializers (§11.3.7).
• A struct is not permitted to declare a parameterless instance constructor (§11.3.8).
• A struct is not permitted to declare a destructor (§11.3.9).
11.3.1 Value semantics
Structs are value types (§4.1) and are said to have value semantics. Classes, on the other hand, are reference types (§4.2) and are said to have reference semantics.
A variable of a struct type directly contains the data of the struct, whereas a variable of a class type contains a reference to the data, the latter known as an object.
With classes, it is possible for two variables to reference the same object, and thus possible for operations on one variable to affect the object referenced by the other variable. With structs, the variables each have their own copy of the data, and it is not possible for operations on one to affect the other. Furthermore, because structs are not reference types, it is not possible for values of a struct type to be null.
Given the declaration
struct Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
the code fragment
Point a = new Point(10, 10);
Point b = a;
a.x = 100;
System.Console.WriteLine(b.x);
outputs the value 10. The assignment of a to b creates a copy of the value, and b is thus unaffected by the assignment to a.x. Had Point instead been declared as a class, the output would be 100 because a and b would reference the same object.
11.3.2 Inheritance
All struct types implicitly inherit from class object. A struct declaration may specify a list of implemented interfaces, but it is not possible for a struct declaration to specify a base class.
Struct types are never abstract and are always implicitly sealed. The abstract and sealed modifiers are therefore not permitted in a struct declaration.
Since inheritance isn’t supported for structs, the declared accessibility of a struct member cannot be protected or protected internal.
Function members in a struct cannot be abstract or virtual, and the override modifier is allowed only to override methods inherited from the System.ValueType or object type.
11.3.3 Assignment
Assignment to a variable of a struct type creates a copy of the value being assigned. This differs from assignment to a variable of a class type, which copies the reference but not the object identified by the reference.
Similar to an assignment, when a struct is passed as a value parameter or returned as the result of a function member, a copy of the struct is created. A struct may be passed by reference to a function member using a ref or out parameter.
When a property or indexer of a struct is the target of an assignment, the instance expression associated with the property or indexer access must be classified as a variable. If the instance expression is classified as a value, a compile-time error occurs. This is described in further detail in §7.13.1.
11.3.4 Default values
As described in §5.2, several kinds of variables are automatically initialized to their default value when they are created. For variables of class types and other reference types, this default value is null. However, since structs are value types that cannot be null, the default value of a struct is the value produced by setting all value type fields to their default value and all reference type fields to null.
Referring to the Point struct declared above, the example
Point[] arr = new Point[100];
initializes each Point in the array to the value produced by setting the x and y fields to zero.
The default value of a struct corresponds to the value returned by the default constructor of the struct (§4.1.1). Unlike a class, a struct is not permitted to declare a parameterless instance constructor. Instead, every struct implicitly has a parameterless instance constructor which always returns the value that results from “zeroing out” the fields of the struct.
Structs should be designed to consider the default initialization state a valid state. In the example
using System;
struct KeyValuePair
{
string key;
string value;
public KeyValuePair(string key, string value) {
if (key == null || value == null) throw new ArgumentException();
this.key = key;
this.value = value;
}
}
the user-defined instance constructor protects against null values only where it is explicitly called. In cases where a KeyValuePair variable is subject to default value initialization, the key and value fields will be null, and the struct must be prepared to handle this state.
11.3.5 Boxing and unboxing
A value of a class type can be converted to type object or to an interface type that is implemented by the class simply by treating the reference as another type at compile-time. Likewise, a value of type object or a value of an interface type can be converted back to a class type without changing the reference (but of course a run-time type check is required in this case).
Since structs are not reference types, these operations are implemented differently for struct types. When a value of a struct type is converted to type object or to an interface type that is implemented by the struct, a boxing operation takes place. Likewise, when a value of type object or a value of an interface type is converted back to a struct type, an unboxing operation takes place. A key difference from the same operations on class types is that boxing and unboxing copies the struct value either into or out of the boxed instance. Thus, following a boxing or unboxing operation, changes made to the unboxed struct are not reflected in the boxed struct.
For further details on boxing and unboxing, see §4.3.
11.3.6 Meaning of this
Within an instance constructor or instance function member of a class, this is classified as a value. Thus, while this can be used to refer to the instance for which the function member was invoked, it is not possible to assign to this in a function member of a class.
Within an instance constructor of a struct, this corresponds to an out parameter of the struct type, and within an instance function member of a struct, this corresponds to a ref parameter of the struct type. In both cases, this is classified as a variable, and it is possible to modify the entire struct for which the function member was invoked by assigning to this or by passing this as a ref or out parameter.
11.3.7 Field initializers
As described in §11.3.4, the default value of a struct consists of the value that results from setting all value type fields to their default value and all reference type fields to null. For this reason, a struct does not permit instance field declarations to include variable initializers, and the following example produces compile-time errors:
struct Point
{
public int x = 1; // Error, initializer not permitted
public int y = 1; // Error, initializer not permitted
}
This restriction applies only to instance fields. Static fields of a struct are permitted to include variable initializers.
11.3.8 Constructors
Unlike a class, a struct is not permitted to declare a parameterless instance constructor. Instead, every struct implicitly has a parameterless instance constructor which always returns the value that results from setting all value type fields to their default value and all reference type fields to null (§4.1.1).
A struct instance constructor is not permitted to include a constructor initializer of the form base(...).
The this variable of a struct instance constructor corresponds to an out parameter of the struct type, and similar to an out parameter, this must be definitely assigned (§5.3) at every location where the instance constructor returns.
A struct can declare instance constructors having parameters. In the example
struct Point
{
int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
the struct Point declares a instance constructor with two int parameters. Given this declaration, the statements
Point p1 = new Point();
Point p2 = new Point(0, 0);
both create a Point with x and y initialized to zero.
11.3.9 Destructors
A struct is not permitted to declare a destructor.
11.3.10 Static Constructors
Static constructors for structs follow most of the same rules as for classes. The execution of a static constructor for a struct is triggered by the first of the following events to occur within an application domain:
• Any of the instance members of the class are referenced.
• Any of the static members of the class are referenced.
• Any of the explicitly declared constructors of the struct is called.
[Note: Note that default values (§11.3.4) of struct types can be created without triggering the static constructor, for example as an array element or by calling the default constructor. end note]
11.4 Struct examples
Struct examples are provided in the following sections.
11.4.1 Database integer type
The DBInt struct below implements an integer type that can represent the complete set of values of the int type, plus an additional state that indicates an unknown value. A type with these characteristics is commonly used in databases.
using System;
public struct DBInt
{
// The Null member represents an unknown DBInt value.
public static readonly DBInt Null = new DBInt();
// When the defined field is true, this DBInt represents a known value
// which is stored in the value field. When the defined field is false,
// this DBInt represents an unknown value, and the value field is 0.
int value;
bool defined;
// Private instance constructor. Creates a DBInt with a known value.
DBInt(int value) {
this.value = value;
this.defined = true;
}
// The IsNull property is true if this DBInt represents an unknown value.
public bool IsNull { get { return !defined; } }
// The Value property is the known value of this DBInt, or 0 if this
// DBInt represents an unknown value.
public int Value { get { return value; } }
// Implicit conversion from int to DBInt.
public static implicit operator DBInt(int x) {
return new DBInt(x);
}
// Explicit conversion from DBInt to int. Throws an exception if the
// given DBInt represents an unknown value.
public static explicit operator int(DBInt x) {
if (!x.defined) throw new InvalidOperationException();
return x.value;
}
public static DBInt operator +(DBInt x) {
return x;
}
public static DBInt operator -(DBInt x) {
return x.defined? -x.value: Null;
}
public static DBInt operator +(DBInt x, DBInt y) {
return x.defined && y.defined? x.value + y.value: Null;
}
public static DBInt operator -(DBInt x, DBInt y) {
return x.defined && y.defined? x.value - y.value: Null;
}
public static DBInt operator *(DBInt x, DBInt y) {
return x.defined && y.defined? x.value * y.value: Null;
}
public static DBInt operator /(DBInt x, DBInt y) {
return x.defined && y.defined? x.value / y.value: Null;
}
public static DBInt operator %(DBInt x, DBInt y) {
return x.defined && y.defined? x.value % y.value: Null;
}
public static DBBool operator ==(DBInt x, DBInt y) {
return x.defined && y.defined? x.value == y.value: DBBool.Null;
}
public static DBBool operator !=(DBInt x, DBInt y) {
return x.defined && y.defined? x.value != y.value: DBBool.Null;
}
public static DBBool operator >(DBInt x, DBInt y) {
return x.defined && y.defined? x.value > y.value: DBBool.Null;
}
public static DBBool operator <(DBInt x, DBInt y) {
return x.defined && y.defined? x.value < y.value: DBBool.Null;
}
public static DBBool operator >=(DBInt x, DBInt y) {
return x.defined && y.defined? x.value >= y.value: DBBool.Null;
}
public static DBBool operator <=(DBInt x, DBInt y) {
return x.defined && y.defined? x.value <= y.value: DBBool.Null;
}
public override bool Equals(object o) {
try {
return (bool) (this == (DBInt) o);
}
catch {
return false;
}
}
public override int GetHashCode() {
if (defined)
return value;
else
return 0;
}
public override string ToString() {
if (defined)
return value.ToString();
else
return "DBInt.Null";
}}
11.4.2 Database boolean type
The DBBool struct below implements a three-valued logical type. The possible values of this type are DBBool.True, DBBool.False, and DBBool.Null, where the Null member indicates an unknown value. Such three-valued logical types are commonly used in databases.
using System;
public struct DBBool
{
// The three possible DBBool values.
public static readonly DBBool Null = new DBBool(0);
public static readonly DBBool False = new DBBool(-1);
public static readonly DBBool True = new DBBool(1);
// Private field that stores –1, 0, 1 for False, Null, True.
sbyte value;
// Private instance constructor. The value parameter must be –1, 0, or 1.
DBBool(int value) {
this.value = (sbyte)value;
}
// Properties to examine the value of a DBBool. Return true if this
// DBBool has the given value, false otherwise.
public bool IsNull { get { return value == 0; } }
public bool IsFalse { get { return value < 0; } }
public bool IsTrue { get { return value > 0; } }
// Implicit conversion from bool to DBBool. Maps true to DBBool.True and
// false to DBBool.False.
public static implicit operator DBBool(bool x) {
return x? True: False;
}
// Explicit conversion from DBBool to bool. Throws an exception if the
// given DBBool is Null, otherwise returns true or false.
public static explicit operator bool(DBBool x) {
if (x.value == 0) throw new InvalidOperationException();
return x.value > 0;
}
// Equality operator. Returns Null if either operand is Null, otherwise
// returns True or False.
public static DBBool operator ==(DBBool x, DBBool y) {
if (x.value == 0 || y.value == 0) return Null;
return x.value == y.value? True: False;
}
// Inequality operator. Returns Null if either operand is Null, otherwise
// returns True or False.
public static DBBool operator !=(DBBool x, DBBool y) {
if (x.value == 0 || y.value == 0) return Null;
return x.value != y.value? True: False;
}
// Logical negation operator. Returns True if the operand is False, Null
// if the operand is Null, or False if the operand is True.
public static DBBool operator !(DBBool x) {
return new DBBool(-x.value);
}
// Logical AND operator. Returns False if either operand is False,
// otherwise Null if either operand is Null, otherwise True.
public static DBBool operator &(DBBool x, DBBool y) {
return new DBBool(x.value < y.value? x.value: y.value);
}
// Logical OR operator. Returns True if either operand is True, otherwise
// Null if either operand is Null, otherwise False.
public static DBBool operator |(DBBool x, DBBool y) {
return new DBBool(x.value > y.value? x.value: y.value);
}
// Definitely true operator. Returns true if the operand is True, false
// otherwise.
public static bool operator true(DBBool x) {
return x.value > 0;
}
// Definitely false operator. Returns true if the operand is False, false
// otherwise.
public static bool operator false(DBBool x) {
return x.value < 0;
}
public override bool Equals(object o) {
try {
return (bool) (this == (DBBool) o);
}
catch {
return false;
}
}
public override int GetHashCode() {
return value;
}
public override string ToString() {
switch (value) {
case -1:
return "DBBool.False";
case 0:
return "DBBool.Null";
case 1:
return "DBBool.True";
default:
throw new InvalidOperationException();
}
}}

12. Arrays
An array is a data structure that contains a number of variables which are accessed through computed indices. The variables contained in an array, also called the elements of the array, are all of the same type, and this type is called the element type of the array.
An array has a rank which determines the number of indices associated with each array element. The rank of an array is also referred to as the dimensions of the array. An array with a rank of one is called a single-dimensional array, and an array with a rank greater than one is called a multi-dimensional array. Multi-dimensional arrays of specific sizes are often referred to by size, as two-dimensional arrays, three-dimensional arrays, and so on.
Each dimension of an array has an associated length which is an integral number greater than or equal to zero. The dimension lengths are not part of the type of the array, but rather are established when an instance of the array type is created at run-time. The length of a dimension determines the valid range of indices for that dimension: For a dimension of length N, indices can range from 0 to N – 1 inclusive. The total number of elements in an array is the product of the lengths of each dimension in the array. If one or more of the dimensions of an array have a length of zero, the array is said to be empty.
The element type of an array can be any type, including an array type.
12.1 Array types
An array type is written as a non-array-type followed by one or more rank-specifiers:
array-type:
non-array-type rank-specifiers
non-array-type:
type
rank-specifiers:
rank-specifier
rank-specifiers rank-specifier
rank-specifier:
[ dim-separatorsopt ]
dim-separators:
,
dim-separators ,
A non-array-type is any type that is not itself an array-type.
The rank of an array type is given by the leftmost rank-specifier in the array-type: A rank-specifier indicates that the array is an array with a rank of one plus the number of “,” tokens in the rank-specifier.
The element type of an array type is the type that results from deleting the leftmost rank-specifier:
• An array type of the form T[R] is an array with rank R and a non-array element type T.
• An array type of the form T[R][R1]...[RN] is an array with rank R and an element type T[R1]...[RN].
In effect, the rank-specifiers are read from left to right before the final non-array element type. For example, the type int[][,,][,] is a single-dimensional array of three-dimensional arrays of two-dimensional arrays of int.
At run-time, a value of an array type can be null or a reference to an instance of that array type.
12.1.1 The System.Array type
The System.Array type is the abstract base type of all array types. An implicit reference conversion (§6.1.4) exists from any array type to System.Array, and an explicit reference conversion (§6.2.3) exists from System.Array to any array type. Note that System.Array itself is not an array-type. Rather, it is a class-type from which all array-types are derived.
At run-time, a value of type System.Array can be null or a reference to an instance of any array type.
12.2 Array creation
Array instances are created by array-creation-expressions (§7.5.10.2) or by field or local variable declarations that include an array-initializer (§12.6).
When an array instance is created, the rank and length of each dimension are established and then remain constant for the entire lifetime of the instance. In other words, it is not possible to change the rank of an existing array instance, nor is it possible to resize its dimensions.
An array instance is always of an array type. The System.Array type is an abstract type that cannot be instantiated.
Elements of arrays created by array-creation-expressions are always initialized to their default value (§5.2).
12.3 Array element access
Array elements are accessed using element-access expressions (§7.5.6.1) of the form A[I1, I2, ..., IN], where A is an expression of an array type and each IX is an expression of type int, uint, long, ulong, or of a type that can be implicitly converted to one or more of these types. The result of an array element access is a variable, namely the array element selected by the indices.
The elements of an array can be enumerated using a foreach statement (§8.8.4).
12.4 Array members
Every array type inherits the members declared by the System.Array type.
12.5 Array covariance
For any two reference-types A and B, if an implicit reference conversion (§6.1.4) or explicit reference conversion (§6.2.3) exists from A to B, then the same reference conversion also exists from the array type A[R] to the array type B[R], where R is any given rank-specifier (but the same for both array types). This relationship is known as array covariance. Array covariance in particular means that a value of an array type A[R] may actually be a reference to an instance of an array type B[R], provided an implicit reference conversion exists from B to A.
Because of array covariance, assignments to elements of reference type arrays include a run-time check which ensures that the value being assigned to the array element is actually of a permitted type (§7.13.1). For example:
class Test
{
static void Fill(object[] array, int index, int count, object value) {
for (int i = index; i < index + count; i++) array[i] = value;
}
static void Main() {
string[] strings = new string[100];
Fill(strings, 0, 100, "Undefined");
Fill(strings, 0, 10, null);
Fill(strings, 90, 10, 0);
}
}
The assignment to array[i] in the Fill method implicitly includes a run-time check which ensures that the object referenced by value is either null or an instance of a type that is compatible with the actual element type of array. In Main, the first two invocations of Fill succeed, but the third invocation causes a System.ArrayTypeMismatchException to be thrown upon executing the first assignment to array[i]. The exception occurs because a boxed int cannot be stored in a string array.
Array covariance specifically does not extend to arrays of value-types. For example, no conversion exists that permits an int[] to be treated as an object[].
12.6 Array initializers
Array initializers may be specified in field declarations (§10.4), local variable declarations (§8.5.1), and array creation expressions (§7.5.10.2):
array-initializer:
{ variable-initializer-listopt }
{ variable-initializer-list , }
variable-initializer-list:
variable-initializer
variable-initializer-list , variable-initializer
variable-initializer:
expression
array-initializer
An array initializer consists of a sequence of variable initializers, enclosed by “{”and “}” tokens and separated by “,” tokens. Each variable initializer is an expression or, in the case of a multi-dimensional array, a nested array initializer.
The context in which an array initializer is used determines the type of the array being initialized. In an array creation expression, the array type immediately precedes the initializer. In a field or variable declaration, the array type is the type of the field or variable being declared. When an array initializer is used in a field or variable declaration, such as:
int[] arr = {0, 2, 4, 6, 8};
it is simply shorthand for an equivalent array creation expression:
int[] arr = new int[] {0, 2, 4, 6, 8};
For a single-dimensional array, the array initializer must consist of a sequence of expressions that are assignment compatible with the element type of the array. The expressions initialize array elements in increasing order, starting with the element at index zero. The number of expressions in the array initializer determines the length of the array instance being created. For example, the array initializer above creates an int[] instance of length 5 and then initializes the instance with the following values:
a[0] = 0; a[1] = 2; a[2] = 4; a[3] = 6; a[4] = 8;
For a multi-dimensional array, the array initializer must have as many levels of nesting as there are dimensions in the array. The outermost nesting level corresponds to the leftmost dimension and the innermost nesting level corresponds to the rightmost dimension. The length of each dimension of the array is determined by the number of elements at the corresponding nesting level in the array initializer. For each nested array initializer, the number of elements must be the same as the other array initializers at the same level. The example:
int[,] b = {{0, 1}, {2, 3}, {4, 5}, {6, 7}, {8, 9}};
creates a two-dimensional array with a length of five for the leftmost dimension and a length of two for the rightmost dimension:
int[,] b = new int[5, 2];
and then initializes the array instance with the following values:
b[0, 0] = 0; b[0, 1] = 1;
b[1, 0] = 2; b[1, 1] = 3;
b[2, 0] = 4; b[2, 1] = 5;
b[3, 0] = 6; b[3, 1] = 7;
b[4, 0] = 8; b[4, 1] = 9;
When an array creation expression includes both explicit dimension lengths and an array initializer, the lengths must be constant expressions and the number of elements at each nesting level must match the corresponding dimension length. Some examples:
int i = 3;
int[] x = new int[3] {0, 1, 2}; // OK
int[] y = new int[i] {0, 1, 2}; // Error, i not a constant
int[] z = new int[3] {0, 1, 2, 3}; // Error, length/initializer mismatch
Here, the initializer for y results in a compile-time error because the dimension length expression is not a constant, and the initializer for z results in a compile-time error because the length and the number of elements in the initializer do not agree.

13. Interfaces
An interface defines a contract. A class or struct that implements an interface must adhere to its contract. An interface may inherit from multiple base interfaces, and a class or struct may implement multiple interfaces.
Interfaces can contain methods, properties, events, and indexers. The interface itself does not provide implementations for the members that it defines. The interface merely specifies the members that must be supplied by classes or interfaces that implement the interface.
13.1 Interface declarations
An interface-declaration is a type-declaration (§9.5) that declares a new interface type.
interface-declaration:
attributesopt interface-modifiersopt interface identifier interface-baseopt interface-body ;opt
An interface-declaration consists of an optional set of attributes (§17), followed by an optional set of interface-modifiers (§13.1.1), followed by the keyword interface and an identifier that names the interface, optionally followed by an optional interface-base specification (§13.1.2), followed by a interface-body (§13.1.3), optionally followed by a semicolon.
13.1.1 Interface modifiers
An interface-declaration may optionally include a sequence of interface modifiers:
interface-modifiers:
interface-modifier
interface-modifiers interface-modifier
interface-modifier:
new
public
protected
internal
private
It is a compile-time error for the same modifier to appear multiple times in an interface declaration.
The new modifier is only permitted on nested interfaces. It specifies that the interface hides an inherited member by the same name, as described in §10.2.2.
The public, protected, internal, and private modifiers control the accessibility of the interface. Depending on the context in which the interface declaration occurs, only some of these modifiers may be permitted (§3.5.1).
13.1.2 Base interfaces
An interface can inherit from zero or more interfaces, which are called the explicit base interfaces of the interface. When an interface has more than zero explicit base interfaces, then in the declaration of the interface, the interface identifier is followed by a colon and a comma separated list of base interface identifiers.
interface-base:
: interface-type-list
The explicit base interfaces of an interface must be at least as accessible as the interface itself (§3.5.4). For example, it is a compile-time error to specify a private or internal interface in the interface-base of a public interface.
It is a compile-time error for an interface to directly or indirectly inherit from itself.
The base interfaces of an interface are the explicit base interfaces and their base interfaces. In other words, the set of base interfaces is the complete transitive closure of the explicit base interfaces, their explicit base interfaces, and so on. An interface inherits all members of its base interfaces. In the example
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
interface IListBox: IControl
{
void SetItems(string[] items);
}
interface IComboBox: ITextBox, IListBox {}
the base interfaces of IComboBox are IControl, ITextBox, and IListBox.
In other words, the IComboBox interface above inherits members SetText and SetItems as well as Paint.
A class or struct that implements an interface also implicitly implements all of the interface’s base interfaces.
13.1.3 Interface body
The interface-body of an interface defines the members of the interface.
interface-body:
{ interface-member-declarationsopt }
13.2 Interface members
The members of an interface are the members inherited from the base interfaces and the members declared by the interface itself.
interface-member-declarations:
interface-member-declaration
interface-member-declarations interface-member-declaration
interface-member-declaration:
interface-method-declaration
interface-property-declaration
interface-event-declaration
interface-indexer-declaration
An interface declaration may declare zero or more members. The members of an interface must be methods, properties, events, or indexers. An interface cannot contain constants, fields, operators, instance constructors, destructors, or types, nor can an interface contain static members of any kind.
All interface members implicitly have public access. It is a compile-time error for interface member declarations to include any modifiers. In particular, it is a compile-time error for an interface member to include any of the following modifiers: abstract, public, protected, internal, private, virtual, override, or static.
The example
public delegate void StringListEvent(IStringList sender);
public interface IStringList
{
void Add(string s);
int Count { get; }
event StringListEvent Changed;
string this[int index] { get; set; }
}
declares an interface that contains one each of the possible kinds of members: A method, a property, an event, and an indexer.
An interface-declaration creates a new declaration space (§3.3), and the interface-member-declarations immediately contained by the interface-declaration introduce new members into this declaration space. The following rules apply to interface-member-declarations:
• The name of a method must differ from the names of all properties and events declared in the same interface. In addition, the signature (§3.6) of a method must differ from the signatures of all other methods declared in the same interface.
• The name of a property or event must differ from the names of all other members declared in the same interface.
• The signature of an indexer must differ from the signatures of all other indexers declared in the same interface.
The inherited members of an interface are specifically not part of the declaration space of the interface. Thus, an interface is allowed to declare a member with the same name or signature as an inherited member. When this occurs, the derived interface member is said to hide the base interface member. Hiding an inherited member is not considered an error, but it does cause the compiler to issue a warning. To suppress the warning, the declaration of the derived interface member must include a new modifier to indicate that the derived member is intended to hide the base member. This topic is discussed further in §3.7.1.2.
If a new modifier is included in a declaration that doesn’t hide an inherited member, a warning is issued to that effect. This warning is suppressed by removing the new modifier.
13.2.1 Interface methods
Interface methods are declared using interface-method-declarations:
interface-method-declaration:
attributesopt newopt return-type identifier ( formal-parameter-listopt ) ;
The attributes, return-type, identifier, and formal-parameter-list of an interface method declaration have the same meaning as those of a method declaration in a class (§10.5). An interface method declaration is not permitted to specify a method body, and the declaration therefore always ends with a semicolon.
13.2.2 Interface properties
Interface properties are declared using interface-property-declarations:
interface-property-declaration:
attributesopt newopt type identifier { interface-accessors }
interface-accessors:
attributesopt get ;
attributesopt set ;
attributesopt get ; attributesopt set ;
attributesopt set ; attributesopt get ;
The attributes, type, and identifier of an interface property declaration have the same meaning as those of a property declaration in a class (§10.6).
The accessors of an interface property declaration correspond to the accessors of a class property declaration (§10.6.2), except that the accessor body must always be a semicolon. Thus, the accessors simply indicate whether the property is read-write, read-only, or write-only.
13.2.3 Interface events
Interface events are declared using interface-event-declarations:
interface-event-declaration:
attributesopt newopt event type identifier ;
The attributes, type, and identifier of an interface event declaration have the same meaning as those of an event declaration in a class (§10.7).
13.2.4 Interface indexers
Interface indexers are declared using interface-indexer-declarations:
interface-indexer-declaration:
attributesopt newopt type this [ formal-parameter-list ] { interface-accessors }
The attributes, type, and formal-parameter-list of an interface indexer declaration have the same meaning as those of an indexer declaration in a class (§10.8).
The accessors of an interface indexer declaration correspond to the accessors of a class indexer declaration (§10.8), except that the accessor body must always be a semicolon. Thus, the accessors simply indicate whether the indexer is read-write, read-only, or write-only.
13.2.5 Interface member access
Interface members are accessed through member access (§7.5.4) and indexer access (§7.5.6.2) expressions of the form I.M and I[A], where I is an instance of an interface type, M is a method, property, or event of that interface type, and A is an indexer argument list.
For interfaces that are strictly single-inheritance (each interface in the inheritance chain has exactly zero or one direct base interface), the effects of the member lookup (§7.3), method invocation (§7.5.5.1), and indexer access (§7.5.6.2) rules are exactly the same as for classes and structs: More derived members hide less derived members with the same name or signature. However, for multiple-inheritance interfaces, ambiguities can occur when two or more unrelated base interfaces declare members with the same name or signature. This section shows several examples of such situations. In all cases, explicit casts can be used to resolve the ambiguities.
In the example
interface IList
{
int Count { get; set; }
}
interface ICounter
{
void Count(int i);
}
interface IListCounter: IList, ICounter {}
class C
{
void Test(IListCounter x) {
x.Count(1); // Error
x.Count = 1; // Error
((IList)x).Count = 1; // Ok, invokes IList.Count.set
((ICounter)x).Count(1); // Ok, invokes ICounter.Count
}
}
the first two statements cause compile-time errors because the member lookup (§7.3) of Count in IListCounter is ambiguous. As illustrated by the example, the ambiguity is resolved by casting x to the appropriate base interface type. Such casts have no run-time costs—they merely consist of viewing the instance as a less derived type at compile-time.
In the example
interface IInteger
{
void Add(int i);
}
interface IDouble
{
void Add(double d);
}
interface INumber: IInteger, IDouble {}
class C
{
void Test(INumber n) {
n.Add(1); // Error, both Add methods are applicable
n.Add(1.0); // Ok, only IDouble.Add is applicable
((IInteger)n).Add(1); // Ok, only IInteger.Add is a candidate
((IDouble)n).Add(1); // Ok, only IDouble.Add is a candidate
}
}
the invocation n.Add(1) is ambiguous because a method invocation (§7.5.5.1) requires all overloaded candidate methods to be declared in the same type. However, the invocation n.Add(1.0) is permitted because only IDouble.Add is applicable. When explicit casts are inserted, there is only one candidate method, and thus no ambiguity.
In the example
interface IBase
{
void F(int i);
}
interface ILeft: IBase
{
new void F(int i);
}
interface IRight: IBase
{
void G();
}
interface IDerived: ILeft, IRight {}
class A
{
void Test(IDerived d) {
d.F(1); // Invokes ILeft.F
((IBase)d).F(1); // Invokes IBase.F
((ILeft)d).F(1); // Invokes ILeft.F
((IRight)d).F(1); // Invokes IBase.F
}
}
the IBase.F member is hidden by the ILeft.F member. The invocation d.F(1) thus selects ILeft.F, even though IBase.F appears to not be hidden in the access path that leads through IRight.
The intuitive rule for hiding in multiple-inheritance interfaces is simply this: If a member is hidden in any access path, it is hidden in all access paths. Because the access path from IDerived to ILeft to IBase hides IBase.F, the member is also hidden in the access path from IDerived to IRight to IBase.
13.3 Fully qualified interface member names
An interface member is sometimes referred to by its fully qualified name. The fully qualified name of an interface member consists of the name of the interface in which the member is declared, followed by a dot, followed by the name of the member. The fully qualified name of a member references the interface in which the member is declared. For example, given the declarations
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
the fully qualified name of Paint is IControl.Paint and the fully qualified name of SetText is ITextBox.SetText.
In the example above, it is not possible to refer to Paint as ITextBox.Paint.
When an interface is part of a namespace, the fully qualified name of an interface member includes the namespace name. For example
namespace System
{
public interface ICloneable
{
object Clone();
}
}
Here, the fully qualified name of the Clone method is System.ICloneable.Clone.
13.4 Interface implementations
Interfaces may be implemented by classes and structs. To indicate that a class or struct implements an interface, the interface identifier is included in the base class list of the class or struct.
interface ICloneable
{
object Clone();
}
interface IComparable
{
int CompareTo(object other);
}
class ListEntry: ICloneable, IComparable
{
public object Clone() {...}
public int CompareTo(object other) {...}
}
A class or struct that implements an interface also implicitly implements all of the interface’s base interfaces. This is true even if the class or struct doesn’t explicitly list all base interfaces in the base class list.
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
class TextBox: ITextBox
{
public void Paint() {...}
public void SetText(string text) {...}
}
Here, class TextBox implements both IControl and ITextBox.
13.4.1 Explicit interface member implementations
For purposes of implementing interfaces, a class or struct may declare explicit interface member implementations. An explicit interface member implementation is a method, property, event, or indexer declaration that references a fully qualified interface member name. For example
interface ICloneable
{
object Clone();
}
interface IComparable
{
int CompareTo(object other);
}
class ListEntry: ICloneable, IComparable
{
object ICloneable.Clone() {...}
int IComparable.CompareTo(object other) {...}
}
Here, ICloneable.Clone and IComparable.CompareTo are explicit interface member implementations.
In some cases, the name of an interface member may not be appropriate for the implementing class, in which case the interface member may be implemented using explicit interface member implementation. A class implementing a file abstraction, for example, would likely implement a Close member function that has the effect of releasing the file resource, and implement the Dispose method of the IDisposable interface using explicit interface member implementation:
interface IDisposable {
void Dispose();
}
class MyFile: IDisposable {
void IDisposable.Dispose() {
Close();
}
public void Close() {
// Do what's necessary to close the file
System.GC.SuppressFinalize(this);
}
}
It is not possible to access an explicit interface member implementation through its fully qualified name in a method invocation, property access, or indexer access. An explicit interface member implementation can only be accessed through an interface instance, and is in that case referenced simply by its member name.
It is a compile-time error for an explicit interface member implementation to include access modifiers, and it is a compile-time error to include the abstract, virtual, override, or static modifiers.
Explicit interface member implementations have different accessibility characteristics than other members. Because explicit interface member implementations are never accessible through their fully qualified name in a method invocation or a property access, they are in a sense private. However, since they can be accessed through an interface instance, they are in a sense also public.
Explicit interface member implementations serve two primary purposes:
• Because explicit interface member implementations are not accessible through class or struct instances, they allow interface implementations to be excluded from the public interface of a class or struct. This is particularly useful when a class or struct implements an internal interface that is of no interest to a consumer of the class or struct.
• Explicit interface member implementations allow disambiguation of interface members with the same signature. Without explicit interface member implementations it would be impossible for a class or struct to have different implementations of interface members with the same signature and return type, as would it be impossible for a class or struct to have any implementation at all of interface members with the same signature but with different return types.
For an explicit interface member implementation to be valid, the class or struct must name an interface in its base class list that contains a member whose fully qualified name, type, and parameter types exactly match those of the explicit interface member implementation. Thus, in the following class
class Shape: ICloneable
{
object ICloneable.Clone() {...}
int IComparable.CompareTo(object other) {...} // invalid
}
the declaration of IComparable.CompareTo results in a compile-time error because IComparable is not listed in the base class list of Shape and is not a base interface of ICloneable. Likewise, in the declarations
class Shape: ICloneable
{
object ICloneable.Clone() {...}
}
class Ellipse: Shape
{
object ICloneable.Clone() {...} // invalid
}
the declaration of ICloneable.Clone in Ellipse results in a compile-time error because ICloneable is not explicitly listed in the base class list of Ellipse.
The fully qualified name of an interface member must reference the interface in which the member was declared. Thus, in the declarations
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
class TextBox: ITextBox
{
void IControl.Paint() {...}
void ITextBox.SetText(string text) {...}
}
the explicit interface member implementation of Paint must be written as IControl.Paint.
13.4.2 Interface mapping
A class or struct must provide implementations of all members of the interfaces that are listed in the base class list of the class or struct. The process of locating implementations of interface members in an implementing class or struct is known as interface mapping.
Interface mapping for a class or struct C locates an implementation for each member of each interface specified in the base class list of C. The implementation of a particular interface member I.M, where I is the interface in which the member M is declared, is determined by examining each class or struct S, starting with C and repeating for each successive base class of C, until a match is located:
• If S contains a declaration of an explicit interface member implementation that matches I and M, then this member is the implementation of I.M.
• Otherwise, if S contains a declaration of a non-static public member that matches M, then this member is the implementation of I.M.
A compile-time error occurs if implementations cannot be located for all members of all interfaces specified in the base class list of C. Note that the members of an interface include those members that are inherited from base interfaces.
For purposes of interface mapping, a class member A matches an interface member B when:
• A and B are methods, and the name, type, and formal parameter lists of A and B are identical.
• A and B are properties, the name and type of A and B are identical, and A has the same accessors as B (A is permitted to have additional accessors if it is not an explicit interface member implementation).
• A and B are events, and the name and type of A and B are identical.
• A and B are indexers, the type and formal parameter lists of A and B are identical, and A has the same accessors as B (A is permitted to have additional accessors if it is not an explicit interface member implementation).
Notable implications of the interface mapping algorithm are:
• Explicit interface member implementations take precedence over other members in the same class or struct when determining the class or struct member that implements an interface member.
• Neither non-public nor static members participate in interface mapping.
In the example
interface ICloneable
{
object Clone();
}
class C: ICloneable
{
object ICloneable.Clone() {...}
public object Clone() {...}
}
the ICloneable.Clone member of C becomes the implementation of Clone in ICloneable because explicit interface member implementations take precedence over other members.
If a class or struct implements two or more interfaces containing a member with the same name, type, and parameter types, it is possible to map each of those interface members onto a single class or struct member. For example
interface IControl
{
void Paint();
}
interface IForm
{
void Paint();
}
class Page: IControl, IForm
{
public void Paint() {...}
}
Here, the Paint methods of both IControl and IForm are mapped onto the Paint method in Page. It is of course also possible to have separate explicit interface member implementations for the two methods.
If a class or struct implements an interface that contains hidden members, then some members must necessarily be implemented through explicit interface member implementations. For example
interface IBase
{
int P { get; }
}
interface IDerived: IBase
{
new int P();
}
An implementation of this interface would require at least one explicit interface member implementation, and would take one of the following forms
class C: IDerived
{
int IBase.P { get {...} }
int IDerived.P() {...}
}
class C: IDerived
{
public int P { get {...} }
int IDerived.P() {...}
}
class C: IDerived
{
int IBase.P { get {...} }
public int P() {...}
}
When a class implements multiple interfaces that have the same base interface, there can be only one implementation of the base interface. In the example
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
interface IListBox: IControl
{
void SetItems(string[] items);
}
class ComboBox: IControl, ITextBox, IListBox
{
void IControl.Paint() {...}
void ITextBox.SetText(string text) {...}
void IListBox.SetItems(string[] items) {...}
}
it is not possible to have separate implementations for the IControl named in the base class list, the IControl inherited by ITextBox, and the IControl inherited by IListBox. Indeed, there is no notion of a separate identity for these interfaces. Rather, the implementations of ITextBox and IListBox share the same implementation of IControl, and ComboBox is simply considered to implement three interfaces, IControl, ITextBox, and IListBox.
The members of a base class participate in interface mapping. In the example
interface Interface1
{
void F();
}
class Class1
{
public void F() {}
public void G() {}
}
class Class2: Class1, Interface1
{
new public void G() {}
}
the method F in Class1 is used in Class2's implementation of Interface1.
13.4.3 Interface implementation inheritance
A class inherits all interface implementations provided by its base classes.
Without explicitly re-implementing an interface, a derived class cannot in any way alter the interface mappings it inherits from its base classes. For example, in the declarations
interface IControl
{
void Paint();
}
class Control: IControl
{
public void Paint() {...}
}
class TextBox: Control
{
new public void Paint() {...}
}
the Paint method in TextBox hides the Paint method in Control, but it does not alter the mapping of Control.Paint onto IControl.Paint, and calls to Paint through class instances and interface instances will have the following effects
Control c = new Control();
TextBox t = new TextBox();
IControl ic = c;
IControl it = t;
c.Paint(); // invokes Control.Paint();
t.Paint(); // invokes TextBox.Paint();
ic.Paint(); // invokes Control.Paint();
it.Paint(); // invokes Control.Paint();
However, when an interface method is mapped onto a virtual method in a class, it is possible for derived classes to override the virtual method and alter the implementation of the interface. For example, rewriting the declarations above to
interface IControl
{
void Paint();
}
class Control: IControl
{
public virtual void Paint() {...}
}
class TextBox: Control
{
public override void Paint() {...}
}
the following effects will now be observed
Control c = new Control();
TextBox t = new TextBox();
IControl ic = c;
IControl it = t;
c.Paint(); // invokes Control.Paint();
t.Paint(); // invokes TextBox.Paint();
ic.Paint(); // invokes Control.Paint();
it.Paint(); // invokes TextBox.Paint();
Since explicit interface member implementations cannot be declared virtual, it is not possible to override an explicit interface member implementation. However, it is perfectly valid for an explicit interface member implementation to call another method, and that other method can be declared virtual to allow derived classes to override it. For example
interface IControl
{
void Paint();
}
class Control: IControl
{
void IControl.Paint() { PaintControl(); }
protected virtual void PaintControl() {...}
}
class TextBox: Control
{
protected override void PaintControl() {...}
}
Here, classes derived from Control can specialize the implementation of IControl.Paint by overriding the PaintControl method.
13.4.4 Interface re-implementation
A class that inherits an interface implementation is permitted to re-implement the interface by including it in the base class list.
A re-implementation of an interface follows exactly the same interface mapping rules as an initial implementation of an interface. Thus, the inherited interface mapping has no effect whatsoever on the interface mapping established for the re-implementation of the interface. For example, in the declarations
interface IControl
{
void Paint();
}
class Control: IControl
{
void IControl.Paint() {...}
}
class MyControl: Control, IControl
{
public void Paint() {}
}
the fact that Control maps IControl.Paint onto Control.IControl.Paint doesn’t affect the re-implementation in MyControl, which maps IControl.Paint onto MyControl.Paint.
Inherited public member declarations and inherited explicit interface member declarations participate in the interface mapping process for re-implemented interfaces. For example
interface IMethods
{
void F();
void G();
void H();
void I();
}
class Base: IMethods
{
void IMethods.F() {}
void IMethods.G() {}
public void H() {}
public void I() {}
}
class Derived: Base, IMethods
{
public void F() {}
void IMethods.H() {}
}
Here, the implementation of IMethods in Derived maps the interface methods onto Derived.F, Base.IMethods.G, Derived.IMethods.H, and Base.I.
When a class implements an interface, it implicitly also implements all of the interface’s base interfaces. Likewise, a re-implementation of an interface is also implicitly a re-implementation of all of the interface’s base interfaces. For example
interface IBase
{
void F();
}
interface IDerived: IBase
{
void G();
}
class C: IDerived
{
void IBase.F() {...}
void IDerived.G() {...}
}
class D: C, IDerived
{
public void F() {...}
public void G() {...}
}
Here, the re-implementation of IDerived also re-implements IBase, mapping IBase.F onto D.F.
13.4.5 Abstract classes and interfaces
Like a non-abstract class, an abstract class must provide implementations of all members of the interfaces that are listed in the base class list of the class. However, an abstract class is permitted to map interface methods onto abstract methods. For example
interface IMethods
{
void F();
void G();
}
abstract class C: IMethods
{
public abstract void F();
public abstract void G();
}
Here, the implementation of IMethods maps F and G onto abstract methods, which must be overridden in non-abstract classes that derive from C.
Note that explicit interface member implementations cannot be abstract, but explicit interface member implementations are of course permitted to call abstract methods. For example
interface IMethods
{
void F();
void G();
}
abstract class C: IMethods
{
void IMethods.F() { FF(); }
void IMethods.G() { GG(); }
protected abstract void FF();
protected abstract void GG();
}
Here, non-abstract classes that derive from C would be required to override FF and GG, thus providing the actual implementation of IMethods.

14. Enums
An enum type is a distinct type that declares a set of named constants.
The example
enum Color
{
Red,
Green,
Blue
}
declares an enum type named Color with members Red, Green, and Blue.
14.1 Enum declarations
An enum declaration declares a new enum type. An enum declaration begins with the keyword enum, and defines the name, accessibility, underlying type, and members of the enum.
enum-declaration:
attributesopt enum-modifiersopt enum identifier enum-baseopt enum-body ;opt
enum-base:
: integral-type
enum-body:
{ enum-member-declarationsopt }
{ enum-member-declarations , }
Each enum type has a corresponding integral type called the underlying type of the enum type. This underlying type must be able to represent all the enumerator values defined in the enumeration. An enum declaration may explicitly declare an underlying type of byte, sbyte, short, ushort, int, uint, long or ulong. Note that char cannot be used as an underlying type. An enum declaration that does not explicitly declare an underlying type has an underlying type of int.
Enum member declarations are separated the comma (“,”) character, and a comma is permitted but not required after the last one. Both of the enum declarations in the example
enum Color1
{
Red,
Green,
Blue
}
enum Color2
{
Red,
Green,
Blue,
}
are valid.
The example
enum Color: long
{
Red,
Green,
Blue
}
declares an enum with an underlying type of long. A developer might choose to use an underlying type of long, as in the example, to enable the use of values that are in the range of long but not in the range of int, or to preserve this option for the future.
14.2 Enum modifiers
An enum-declaration may optionally include a sequence of enum modifiers:
enum-modifiers:
enum-modifier
enum-modifiers enum-modifier
enum-modifier:
new
public
protected
internal
private
It is a compile-time error for the same modifier to appear multiple times in an enum declaration.
The modifiers of an enum declaration have the same meaning as those of a class declaration (§10.1.1). Note, however, that the abstract and sealed modifiers are not permitted in an enum declaration. Enums cannot be abstract and do not permit derivation.
14.3 Enum members
The body of an enum type declaration defines zero or more enum members, which are the named constants of the enum type. No two enum members can have the same name.
enum-member-declarations:
enum-member-declaration
enum-member-declarations , enum-member-declaration
enum-member-declaration:
attributesopt identifier
attributesopt identifier = constant-expression
Each enum member has an associated constant value. The type of this value is the underlying type for the containing enum. The constant value for each enum member must be in the range of the underlying type for the enum. The example
enum Color: uint
{
Red = -1,
Green = -2,
Blue = -3
}
produces a compile-time error because the constant values -1, -2, and –3 are not in the range of the underlying integral type uint.
Multiple enum members may share the same associated value. The example
enum Color
{
Red,
Green,
Blue,

Max = Blue
}
shows an enum that has two enum members—Blue and Max—that have the same associated value.
The associated value of an enum member is assigned either implicitly or explicitly. If the declaration of the enum member has a constant-expression initializer, the value of that constant expression, implicitly converted to the underlying type of the enum, is the associated value of the enum member. If the declaration of the enum member has no initializer, its associated value is set implicitly, as follows:
• If the enum member is the first enum member declared in the enum type, its associated value is zero.
• Otherwise, the associated value of the enum member is obtained by increasing the associated value of the textually preceding enum member by one. This increased value must be within the range of values that can be represented by the underlying type.
The example
enum Color
{
Red,
Green = 10,
Blue
}
class Test
{
static void Main() {
Console.WriteLine(StringFromColor(Color.Red));
Console.WriteLine(StringFromColor(Color.Green));
Console.WriteLine(StringFromColor(Color.Blue));
}
static string StringFromColor(Color c) {
switch (c) {
case Color.Red:
return String.Format("Red = {0}", (int) c);
case Color.Green:
return String.Format("Green = {0}", (int) c);
case Color.Blue:
return String.Format("Blue = {0}", (int) c);
default:
return "Invalid color";
}
}
}
prints out the enum member names and their associated values. The output is:
Red = 0
Green = 10
Blue = 11
for the following reasons:
• the enum member Red is automatically assigned the value zero (since it has no initializer and is the first enum member);
• the enum member Green is explicitly given the value 10;
• and the enum member Blue is automatically assigned the value one greater than the member that textually precedes it.
The associated value of an enum member may not, directly or indirectly, use the value of its own associated enum member. Other than this circularity restriction, enum member initializers may freely refer to other enum member initializers, regardless of their textual position. Within an enum member initializer, values of other enum members are always treated as having the type of their underlying type, so that casts are not necessary when referring to other enum members.
The example
enum Circular
{
A = B,
B
}
produces a compile-time error because the declarations of A and B are circular. A depends on B explicitly, and B depends on A implicitly.
Enum members are named and scoped in a manner exactly analogous to fields within classes. The scope of an enum member is the body of its containing enum type. Within that scope, enum members can be referred to by their simple name. From all other code, the name of an enum member must be qualified with the name of its enum type. Enum members do not have any declared accessibility—an enum member is accessible if its containing enum type is accessible.
14.4 Enum values and operations
Each enum type defines a distinct type; an explicit enumeration conversion (§6.2.2) is required to convert between an enum type and an integral type, or between two enum types. The set of values that an enum type can take on is not limited by its enum members. In particular, any value of the underlying type of an enum can be cast to the enum type, and is a distinct valid value of that enum type.
Enum members have the type of their containing enum type (except within other enum member initializers: see §14.3). The value of an enum member declared in enum type E with associated value v is (E)v.
The following operators can be used on values of enum types: ==, !=, <, >, <=, >= (§7.9.5), + (§7.7.4), (§7.7.5), ^, &, | (§7.10.2), ~ (§7.6.4), ++, -- (§7.5.9 and §7.6.5), and sizeof (§A.5.4).
Every enum type automatically derives from the class System.Enum. Thus, inherited methods and properties of this class can be used on values of an enum type.

15. Delegates
Delegates enable scenarios that other languages—such as C++, Pascal, and Modula—have addressed with function pointers. Unlike C++ function pointers, delegates are fully object oriented; unlike C++ pointers to member functions, delegates encapsulate both an object instance and a method.
A delegate declaration defines a class that derives from the class System.Delegate. A delegate instance encapsulates one or more methods, each of which is referred to as a callable entity. For instance methods, a callable entity consists of an instance and a method on the instance. For static methods, a callable entity consists of just a method. Given a delegate instance and an appropriate set of arguments, one can invoke all of that delegate's instance's methods with that set of arguments.
An interesting and useful property of a delegate instance is that it does not know or care about the classes of the methods it encapsulates; all that matters is that the methods are compatible (§15.1) with the delegate's type. This makes delegates perfectly suited for “anonymous” invocation.
15.1 Delegate declarations
A delegate-declaration is a type-declaration (§9.5) that declares a new delegate type.
delegate-declaration:
attributesopt delegate-modifiersopt delegate return-type identifier ( formal-parameter-listopt ) ;
delegate-modifiers:
delegate-modifier
delegate-modifiers delegate-modifier
delegate-modifier:
new
public
protected
internal
private
It is a compile-time error for the same modifier to appear multiple times in a delegate declaration.
The new modifier is only permitted on delegates declared within another type. It specifies that the delegate hides an inherited member by the same name, as described in §10.2.2.
The public, protected, internal, and private modifiers control the accessibility of the delegate type. Depending on the context in which the delegate declaration occurs, some of these modifiers may not be permitted (§3.5.1).
The delegate's type name is identifier.
The optional formal-parameter-list specifies the parameters of the delegate, and return-type indicates the return type of the delegate. A method and a delegate type are compatible if both of the following are true:
• They have the same number or parameters, with the same types, in the same order, with the same parameter modifiers.
• Their return types are the same.
Delegate types in C# are name equivalent, not structurally equivalent. (However, note that instances of two distinct but structurally equivalent delegate types may compare as equal (§7.9.8).) Specifically, two different delegate types that have the same parameter lists and signature and return type are considered different delegate types.
For example:
delegate int D1(int i, double d);
class A
{
public static int M1(int a, double b) { /* ... */ }
}
class B
{
delegate int D2(int c, double d);
public static int M1(int f, double g) { /* ... */ }
public static void M2(int k, double l) { /* ... */ }
public static int M3(int g) { /* ... */ }
public static void M4(int g) { /* ... */ }
}
The delegate types D1 and D2 are both compatible with the methods A.M1 and B.M1, since they have the same return type and parameter list; however, these delegate types are two different types, so they are not interchangeable. The delegate types D1 and D2 are incompatible with the methods B.M2, B.M3, and B.M4, since they have different return types or parameter lists.
The only way to declare a delegate type is via a delegate-declaration. A delegate type is a class type that is derived from System.Delegate. Delegate types are implicitly sealed, so it is not permissible to derive any type from a delegate type. It is also not permissible to derive a non-delegate class type from System.Delegate. Note that System.Delegate is not itself a delegate type; it is a class type from which all delegate types are derived.
C# provides special syntax for delegate instantiation and invocation. Except for instantiation, any operation that can be applied to a class or class instance can also be applied to a delegate class or instance, respectively. In particular, it is possible to access members of the System.Delegate type via the usual member access syntax.
The set of methods encapsulated by a delegate instance is called an invocation list. When a delegate instance is created (§15.2) from a single method, it encapsulates that method, and its invocation list contains only one entry. However, when two non-null delegate instances are combined, their invocation lists are concatenated—in the order left operand then right operand—to form a new invocation list, which contains two or more entries.
Delegates are combined using the binary + (§7.7.4) and += operators (§7.13.2). A delegate can be removed from a combination of delegates, using the binary - (§7.7.5) and -= operators (§7.13.2). Delegates can be compared for equality (§7.9.8).
The example
delegate void D(int x);
class C
{
public static void M1(int i) { /* … */ }
public static void M2(int i) { /* … */ }
}
class Test
{
static void Main() {
D cd1 = new D(C.M1); // M1
D cd2 = new D(C.M2); // M2
D cd3 = cd1 + cd2; // M1 + M2
D cd4 = cd3 + cd1; // M1 + M2 + M1
D cd5 = cd4 + cd3; // M1 + M2 + M1 + M1 + M2
}
}
shows the instantiation of a number of delegates, and their corresponding invocation lists. When cd1 and cd2 are instantiated, they each encapsulate one method. When cd3 is instantiated, it has an invocation list of two methods, M1 and M2, in that order. cd4’s invocation list contains M1, M2, and M1, in that order. Finally, cd5’s invocation list contains M1, M2, M1, M1, and M2, in that order. For more examples of combining (as well as removing) delegates, see §15.3.
15.2 Delegate instantiation
An instance of a delegate is created by a delegate-creation-expression (§7.5.10.3). The newly created delegate instance then refers to either:
• The static method referenced in the delegate-creation-expression, or
• The target object (which cannot be null) and instance method referenced in the delegate-creation-expression, or
• Another delegate
For example:
delegate void D(int x);
class C
{
public static void M1(int i) { /* ... */}
public void M2(int i) { /* ... */}
}
class Test
{
static void Main() {
D cd1 = new D(C.M1); // static method
Test t = new C();
D cd2 = new D(t.M2); // instance method
D cd3 = new D(cd2); // another delegate
}
}
Once instantiated, delegate instances always refer to the same target object and method. When two delegates are combined, or one is removed from another, a new delegate results with its own invocation list; the invocation lists of the delegates combined or removed remain unchanged.
15.3 Delegate invocation
C# provides special syntax for invoking a delegate. When a non-null delegate instance whose invocation list contains one entry is invoked, it invokes the one method with the same arguments it was given, and returns the same value as the referred to method. See §7.5.5.2 for detailed information on delegate invocation. If an exception occurs during the invocation of such a delegate, and the exception is not caught within the method that was invoked, the search for an exception catch clause continues in the method that called the delegate, as if that method had directly called the method to which the delegate referred.
Invocation of a delegate instance whose invocation list contains multiple entries proceeds by invoking each of the methods on the invocation list, synchronously, in order. Each method so called is passed the same set of arguments as was given to the delegate instance. If such a delegate invocation includes reference parameters (§10.5.1.2), each method invocation will occur with a reference to the same variable; changes to that variable by one method in the invocation list will be visible to methods further down the invocation list. If the delegate invocation includes output parameters or a return value, their final value will come from the invocation of the last delegate in the list.
If an exception occurs during processing of the invocation of such a delegate, and the exception is not caught within the method that was invoked, the search for an exception catch clause continues in the method that called the delegate, and any methods further down the invocation list are not invoked.
Attempting to invoke a delegate instance whose value is null results in an exception of type System.NullReferenceException.
The following example shows how to instantiate, combine, remove, and invoke delegates:
delegate void D(int x);
class C
{
public static void M1(int i) {
Console.WriteLine("C.M1: " + i);
}
public static void M2(int i) {
Console.WriteLine("C.M2: " + i);
}
public void M3(int i) {
Console.WriteLine("C.M3: " + i);
}
}
class Test
{
static void Main() {
D cd1 = new D(C.M1);
cd1(-1); // call M1
D cd2 = new D(C.M2);
cd2(-2); // call M2
D cd3 = cd1 + cd2;
cd3(10); // call M1 then M2
cd3 += cd1;
cd3(20); // call M1, M2, then M1
C c = new C();
D cd4 = new D(c.M3);
cd3 += cd4;
cd3(30); // call M1, M2, M1, then M3
cd3 -= cd1; // remove last M1
cd3(40); // call M1, M2, then M3
cd3 -= cd4;
cd3(50); // call M1 then M2
cd3 -= cd2;
cd3(60); // call M1
cd3 -= cd2; // impossible removal is benign
cd3(60); // call M1
cd3 -= cd1; // invocation list is empty
// cd3(70); // System.NullReferenceException thrown
cd3 -= cd1; // impossible removal is benign
}
}
As shown in the statement cd3 += cd1;, a delegate can be present in an invocation list multiple times. In this case, it is simply invoked once per occurrence. In an invocation list such as this, when that delegate is removed, the last occurrence in the invocation list is the one actually removed.
Immediately prior to the execution of the final statement, cd3 -= cd1;, the delegate cd3 refers to an empty invocation list. Attempting to remove a delegate from an empty list (or to remove a non-existent delegate from a non-empty list) is not an error.
The output produced is:
C.M1: -1
C.M2: -2
C.M1: 10
C.M2: 10
C.M1: 20
C.M2: 20
C.M1: 20
C.M1: 30
C.M2: 30
C.M1: 30
C.M3: 30
C.M1: 40
C.M2: 40
C.M3: 40
C.M1: 50
C.M2: 50
C.M1: 60
C.M1: 60
16. Exceptions
Exceptions in C# provide a structured, uniform, and type-safe way of handling both system level and application level error conditions. The exception mechanism is C# is quite similar to that of C++, with a few important differences:
• In C#, all exceptions must be represented by an instance of a class type derived from System.Exception. In C++, any value of any type can be used to represent an exception.
• In C#, a finally block (§8.10) can be used to write termination code that executes in both normal execution and exceptional conditions. Such code is difficult to write in C++ without duplicating code.
• In C#, system-level exceptions such as overflow, divide-by-zero, and null dereferences have well defined exception classes and are on a par with application-level error conditions.
16.1 Causes of exceptions
Exception can be thrown in two different ways.
• A throw statement (§8.9.5) throws an exception immediately and unconditionally. Control never reaches the statement immediately following the throw.
• Certain exceptional conditions that arise during the processing of C# statements and expression cause an exception in certain circumstances when the operation cannot be completed normally. For example, an integer division operation (§7.7.2) throws a System.DivideByZeroException if the denominator is zero. See §16.4 for a list of the various exceptions that can occur in this way.
16.2 The System.Exception class
The System.Exception class is the base type of all exceptions. This class has a few notable properties that all exceptions share:
• Message is a read-only property of type string that contains a human-readable description of the reason for the exception.
• InnerException is a read-only property of type Exception. If its value is non-null, it refers to the exception that caused the current exception. Otherwise, its value is null, indicating that this exception was not caused by another exception. (The number of exception objects chained together in this manner can be arbitrary.)
The value of these properties can be specified in calls to the instance constructor for System.Exception.
16.3 How exceptions are handled
Exceptions are handled by a try statement (§8.10).
When an exception occurs, the system searches for the nearest catch clause that can handle the exception, as determined by the run-time type of the exception. First, the current method is searched for a lexically enclosing try statement, and the associated catch clauses of the try statement are considered in order. If that fails, the method that called the current method is searched for a lexically enclosing try statement that encloses the point of the call to the current method. This search continues until a catch clause is found that can handle the current exception, by naming an exception class that is of the same class, or a base class, of the run-time type of the exception being thrown. A catch clause that doesn’t name an exception class can handle any exception.
Once a matching catch clause is found, the system prepares to transfer control to the first statement of the catch clause. Before execution of the catch clause begins, the system first executes, in order, any finally clauses that were associated with try statements more nested that than the one that caught the exception.
If no matching catch clause is found, one of two things occurs:
• If the search for a matching catch clause reaches a static constructor (§10.11) or static field initializer, then a System.TypeInitializationException is thrown at the point that triggered the invocation of the static constructor. The inner exception of the System.TypeInitializationException contains the exception that was originally thrown.
• If the search for matching catch clauses reaches the code that initially started the thread, then execution of the thread is terminated. The impact of such termination is implementation-defined.
Exceptions that occur during destructor execution are worth special mention. If an exception occurs during destructor execution and is not caught, then the execution of that destructor is terminated and the destructor of the base class (if any) is called. If there is no base class (as in the case of System.Object) or if there is no base class destructor, then the exception is discarded.
16.4 Common Exception Classes
The following exceptions are thrown by certain C# operations.

System.ArithmeticException A base class for exceptions that occur during arithmetic operations, such as System.DivideByZeroException and System.OverflowException.
System.ArrayTypeMismatchException Thrown when a store into an array fails because the actual type of the stored element is incompatible with the actual type of the array.
System.DivideByZeroException Thrown when an attempt to divide an integral value by zero occurs.
System.IndexOutOfRangeException Thrown when an attempt to index an array via an index that is less than zero or outside the bounds of the array.
System.InvalidCastException Thrown when an explicit conversion from a base type or interface to a derived types fails at run time.
System.MulticastNotSupportedException Thrown when an attempt to combine two non-null delegates fails, because the delegate type does not have a void return type.
System.NullReferenceException Thrown when a null reference is used in a way that causes the referenced object to be required.
System.OutOfMemoryException Thrown when an attempt to allocate memory (via new) fails.
System.OverflowException Thrown when an arithmetic operation in a checked context overflows.
System.StackOverflowException Thrown when the execution stack is exhausted by having too many pending method calls; typically indicative of very deep or unbounded recursion.
System.TypeInitializationException Thrown when a static constructor throws an exception, and no catch clauses exists to catch it.


17. Attributes
Much of the C# language enables the programmer to specify declarative information about the entities defined in the program. For example, the accessibility of a method in a class is specified by decorating it with the method-modifiers public, protected, internal, and private.
C# enables programmers to invent new kinds of declarative information, called attributes. Programmers can then attach attributes to various program entities, and retrieve attribute information in a run-time environment. For instance, a framework might define a HelpAttribute attribute that can be placed on certain program elements (such as classes and methods) to provide a mapping from those program elements to documentation.
Attributes are defined through the declaration of attribute classes (§17.1), which may have positional and named parameters (§17.1.2). Attributes are attached to entities in a C# program using attribute specification (§•), and can be retrieved at run-time as attribute instances (§17.3).
17.1 Attribute classes
A class that derives from the abstract class System.Attribute, whether directly or indirectly, is an attribute class. The declaration of an attribute class defines a new kind of attribute that can be placed on a declaration. By convention, attribute classes are named with a suffix of Attribute. Uses of an attribute may either include or omit this suffix.
17.1.1 Attribute usage
The AttributeUsage attribute (§17.4.1) is used to describe how an attribute class can be used.
AttributeUsage has a positional parameter (§17.1.2) that enables an attribute class to specify the kinds of declarations on which it can be used. The example
[AttributeUsage(AttributeTargets.Class | AttributeTargets.Interface)]
public class SimpleAttribute: Attribute
{}
defines an attribute class named SimpleAttribute that can be placed only on class-declarations and interface-declarations. The example
[Simple] class Class1 {...}
[Simple] interface Interface1 {...}
shows several uses of the Simple attribute. Although this attribute is defined with the name SimpleAttribute, when it is used the Attribute suffix may be omitted, resulting in the short name Simple. The example above is semantically equivalent to:
[SimpleAttribute] class Class1 {...}
[SimpleAttribute] interface Interface1 {...}
AttributeUsage has a named parameter (§17.1.2) called AllowMultiple that indicates whether the attribute can be specified more than once for a given entity. If AllowMultiple for an attribute class is true, then it is a multi-use attribute class, and can be specified more than once on an entity. If AllowMultiple for an attribute class is false or unspecified, then it is a single-use attribute class, and can be specified at most once on an entity.
The example
using System;
[AttributeUsage(AttributeTargets.Class, AllowMultiple = true)]
public class AuthorAttribute: Attribute {
public AuthorAttribute(string name) {
this.name = name;
}
public string Name {
get { return name; }
}
private string name;
}
defines a multi-use attribute class named AuthorAttribute. The example
[Author("Brian Kernighan"), Author("Dennis Ritchie")]
class Class1 {...}
shows a class declaration with two uses of the Author attribute.
AttributeUsage has a named parameter called Inherited that indicates whether the attribute, when specified on a base class, is also inherited by classes that derive from that base class. If Inherited for an attribute class is true, then that attribute is inherited. If Inherited for an attribute class is false or it is unspecified, then that attribute is not inherited.
An attribute class X not having an AttributeUsage attribute attached to it, as in
using System;
class X: Attribute { … }
is equivalent to the following:
using System;
[AttributeUsage(AttributeTargets.All, AllowMultiple = false, Inherited = true)]
class X: Attribute { … }
17.1.2 Positional and named parameters
Attribute classes can have positional parameters and named parameters. Each public instance constructor for an attribute class defines a valid sequence of positional parameters for the attribute class. Each non-static public read-write field and property for an attribute class defines a named parameter for the attribute class.
The example
[AttributeUsage(AttributeTargets.Class)]
public class HelpAttribute: Attribute
{
public HelpAttribute(string url) { // url is a positional parameter
...
}
public string Topic { // Topic is a named parameter
get {...}
set {...}
}
public string Url { get {...} }
}
defines an attribute class named HelpAttribute that has one positional parameter (string url) and one named parameter (string Topic). Although it is non-static and public, the Url property does not define a named parameter because it is not read-write.
The example
[Help("http://www.microsoft.com/.../Class1.htm")]
class Class1 {
}
[Help("http://www.microsoft.com/.../Misc.htm", Topic ="Class2")]
class Class2 {
}
shows several uses of the attribute.
17.1.3 Attribute parameter types
The types of positional and named parameters for an attribute class are limited to the attribute parameter types, which are:
• The types bool, byte, char, double, float, int, long, short, string.
• The type object.
• The type System.Type.
• An enum type provided it has public accessibility and the types in which it is nested (if any) also have public accessibility.
• Single-dimensional arrays of the above types.
17.2 Attribute specification
Attribute specification is the application of a previously defined attribute to a declaration. An attribute is a piece of additional declarative information that is specified for a declaration. Attributes can be specified at global scope (to specify attributes on the containing assembly or module) and for type-declarations (§9.5), class-member-declarations (§10.2), interface-member-declarations (§13.2), enum-member-declarations (§14.3), accessor-declarations for properties (§10.6.2), event-accessor-declarations (§10.7.1), and formal-parameter-lists (§10.5.1).
Attributes are specified in attribute sections. An attribute section consists of a pair of square brackets, which surround a comma-separated list of one or more attributes. The order in which attributes are specified in such a list, and the order in which sections appear, is not significant. For instance, the attribute specifications [A][B], [B][A], [A, B], and [B, A] are equivalent.
global-attributes:
global-attribute-sections
global-attribute-sections:
global-attribute-section
global-attribute-sections global-attribute-section
global-attribute-section:
[ global-attribute-target-specifier attribute-list ]
[ global-attribute-target-specifier attribute-list ,]
global-attribute-target-specifier:
global-attribute-target :
global-attribute-target:
assembly
module
attributes:
attribute-sections
attribute-sections:
attribute-section
attribute-sections attribute-section
attribute-section:
[ attribute-target-specifieropt attribute-list ]
[ attribute-target-specifieropt attribute-list , ]
attribute-target-specifier:
attribute-target :
attribute-target:
field
event
method
param
property
return
type
attribute-list:
attribute
attribute-list , attribute
attribute:
attribute-name attribute-argumentsopt
attribute-name:
type-name
attribute-arguments:
( positional-argument-listopt )
( positional-argument-list , named-argument-list )
( named-argument-list )
positional-argument-list:
positional-argument
positional-argument-list , positional-argument
positional-argument:
attribute-argument-expression
named-argument-list:
named-argument
named-argument-list , named-argument
named-argument:
identifier = attribute-argument-expression
attribute-argument-expression:
expression
An attribute consists of an attribute-name and an optional list of positional and named arguments. The positional arguments (if any) precede the named arguments. A positional argument consists of an attribute-argument-expression; a named argument consists of a name, followed by an equal sign, followed by an attribute-argument-expression. The order of named arguments is not significant.
The attribute-name identifies an attribute class. If the form of attribute-name is type-name then this name must refer to an attribute class. Otherwise, a compile-time error occurs. The example
class Class1 {}
[Class1] class Class2 {} // Error
produces a compile-time error because it attempts to use Class1, which is not an attribute class, as an attribute class.
Certain contexts permit the specification of an attribute on more than one target. A program can explicitly specify the target by including an attribute-target-specifier. When an attribute is placed at the global level, a global-attribute-target-specifier is required. In all other locations, a reasonable default is applied, but an attribute-target-specifier can be used to affirm or override the default in certain ambiguous cases (or to just affirm the default in non-ambiguous cases). Thus, attribute-target-specifiers can typically be omitted except at the global level. The potentially ambiguous contexts are resolved as follows:
• An attribute specified at global scope can apply either to the target assembly or the target module. No default exists for this context, so an attribute-target-specifier is always required in this context. The presence of the assembly attribute-target-specifier indicates that the attribute applies to the target assembly; the presence of the module attribute-target-specifier indicates that the attribute applies to the target module.
• An attribute specified on a delegate declaration can apply either to the delegate being declared or to its return value. In the absence of an attribute-target-specifier, the attribute applies to the delegate. The presence of the type attribute-target-specifier indicates that the attribute applies to the delegate; the presence of the return attribute-target-specifier indicates that the attribute applies to the return value.
• An attribute specified on a method declaration can apply either to the method being declared or to its return value. In the absence of an attribute-target-specifier, the attribute applies to the method. The presence of the method attribute-target-specifier indicates that the attribute applies to the method; the presence of the return attribute-target-specifier indicates that the attribute applies to the return value.
• An attribute specified on an operator declaration can apply either to the operator being declared or to its return value. In the absence of an attribute-target-specifier, the attribute applies to the operator. The presence of the method attribute-target-specifier indicates that the attribute applies to the operator; the presence of the return attribute-target-specifier indicates that the attribute applies to the return value.
• An attribute specified on an event declaration that omits event accessors can apply to the event being declared, to the associated field (if the event is not abstract), or to the associated add and remove methods. In the absence of an attribute-target-specifier, the attribute applies to the event. The presence of the event attribute-target-specifier indicates that the attribute applies to the event; the presence of the field attribute-target-specifier indicates that the attribute applies to the field; and the presence of the method attribute-target-specifier indicates that the attribute applies to the methods.
• An attribute specified on a get accessor declaration for a property or indexer declaration can apply either to the associated method or to its return value. In the absence of an attribute-target-specifier, the attribute applies to the method. The presence of the method attribute-target-specifier indicates that the attribute applies to the method; the presence of the return attribute-target-specifier indicates that the attribute applies to the return value.
• An attribute specified on a set accessor for a property or indexer declaration can apply either to the associated method or to its implicit “value” parameter. In the absence of an attribute-target-specifier, the attribute applies to the method. The presence of the method attribute-target-specifier indicates that the attribute applies to the method; the presence of the param attribute-target-specifier indicates that the attribute applies to the parameter.
• An attribute specified on an add or remove accessor declaration for an event declaration can apply either to the associated method or to its lone parameter. In the absence of an attribute-target-specifier, the attribute applies to the method. The presence of the method attribute-target-specifier indicates that the attribute applies to the method; the presence of the param attribute-target-specifier indicates that the attribute applies to the parameter.
In other contexts, inclusion of an attribute-target-specifier is permitted but unnecessary. For instance, a class declaration may either include or omit the type attribute-target-specifier:
[type: Author("Brian Kernighan")]
class Class1 {}
[Author("Dennis Ritchie")]
class Class2 {}
It is a compile-time error to specify an invalid attribute-target-specifier. For instance, the param attribute-target-specifier cannot be used on a class declaration:
[param: Author("Brian Kernighan")]
class Class1 {}
An implementation may accept additional attribute target specifiers with implementation-defined semantics. However, an implementation that does not recognize such a target shall issue a warning.
By convention, attribute classes are named with a suffix of Attribute. An attribute-name of the form type-name may either include or omit this suffix. An exact match between the attribute-name and the name of the attribute class is preferred. The example
[AttributeUsage(AttributeTargets.All)]
public class X: Attribute
{}
[AttributeUsage(AttributeTargets.All)]
public class XAttribute: Attribute
{}
[X] // refers to X
class Class1 {}
[XAttribute] // refers to XAttribute
class Class2 {}
shows two attribute classes named X and XAttribute. The attribute [X] refers to the class named X, and the attribute [XAttribute] refers to the attribute class named [XAttribute]. If the declaration for class X is removed, then both attributes refer to the attribute class named XAttribute:
[AttributeUsage(AttributeTargets.All)]
public class XAttribute: Attribute
{}
[X] // refers to XAttribute
class Class1 {}
[XAttribute] // refers to XAttribute
class Class2 {}
It is a compile-time error to use a single-use attribute class more than once on the same entity. The example
[AttributeUsage(AttributeTargets.Class)]
public class HelpStringAttribute: Attribute
{
string value;
public HelpStringAttribute(string value) {
this.value = value;
}
public string Value { get {...} }
}
[HelpString("Description of Class1")]
[HelpString("Another description of Class1")]
public class Class1 {}
produces a compile-time error because it attempts to use HelpString, which is a single-use attribute class, more than once on the declaration of Class1.
An expression E is an attribute-argument-expression if all of the following statements are true:
• The type of E is an attribute parameter type (§17.1.3).
• At compile-time, the value of E can be resolved to one of the following:
o A constant-expression (§7.15).
o A typeof-expression (§7.5.11).
o An array-creation-expression (§7.5.10.2) of the form new T[] {E, E, ..., E}, where T is an attribute parameter type and each E is an attribute-argument-expression.
17.3 Attribute instances
An attribute instance is an instance that represents an attribute at run-time. An attribute is defined with an attribute class, positional arguments, and named arguments. An attribute instance is an instance of the attribute class that is initialized with the positional and named arguments.
Retrieval of an attribute instance involves both compile-time and run-time processing, as described in the following sections.
17.3.1 Compilation of an attribute
The compilation of an attribute with attribute class T, positional-argument-list P and named-argument-list N, consists of the following steps:
• Follow the compile-time processing steps for compiling an object-creation-expression of the form new T(P). These steps either result in a compile-time error, or determine a constructor on T that can be invoked at run-time. Call this instance constructor C.
• If C does not have public accessibility, then a compile-time error occurs.
• For each named-argument Arg in N:
o Let Name be the identifier of the named-argument Arg.
o Name must identify a non-static read-write public field or property on T. If T has no such field or property, then a compile-time error occurs.
• Keep the following information for run-time instantiation of the attribute: the attribute class T, the instance constructor C on T, the positional-argument-list P and the named-argument-list N.
17.3.2 Run-time retrieval of an attribute instance
Compilation of an attribute yields an attribute class T, an instance constructor C on T, a positional-argument-list P and a named-argument-list N. Given this information, an attribute instance can be retrieved at run-time using the following steps:
• Follow the run-time processing steps for executing an object-creation-expression of the form new T(P), using the instance constructor C as determined at compile-time. These steps either result in an exception, or produce an instance of T. Call this instance O.
• For each named-argument Arg in N, in order:
o Let Name be the identifier of the named-argument Arg. If Name does not identify a non-static public read-write field or property on O, then an exception is thrown.
o Let Value be the result of evaluating the attribute-argument-expression of Arg.
o If Name identifies a field on O, then set this field to the value Value.
o Otherwise, Name identifies a property on O. Set this property to the value Value.
o The result is O, an instance of the attribute class T that has been initialized with the positional-argument-list P and the named-argument-list N.
17.4 Reserved attributes
A small number of attributes affect the language in some way. These attributes include:
• System.AttributeUsageAttribute (§17.4.1), which is used to describe the ways in which an attribute class can be used.
• System.ConditionalAttribute (§17.4.2), which is used to define conditional methods.
• System.ObsoleteAttribute (§17.4.3), which is used to mark a member as obsolete.
17.4.1 The AttributeUsage attribute
The AttributeUsage attribute is used to describe the manner in which the attribute class can be used.
A class that is decorated with the AttributeUsage attribute must derive from System.Attribute, either directly or indirectly. Otherwise, a compile-time error occurs.
[AttributeUsage(AttributeTargets.Class)]
public class AttributeUsageAttribute: Attribute
{
public AttributeUsageAttribute(AttributeTargets validOn) {...}
public virtual bool AllowMultiple { get {...} set {...} }
public virtual bool Inherited { get {...} set {...} }
public virtual AttributeTargets ValidOn { get {...} }
}
public enum AttributeTargets
{
Assembly = 0x0001,
Module = 0x0002,
Class = 0x0004,
Struct = 0x0008,
Enum = 0x0010,
Constructor = 0x0020,
Method = 0x0040,
Property = 0x0080,
Field = 0x0100,
Event = 0x0200,
Interface = 0x0400,
Parameter = 0x0800,
Delegate = 0x1000,
ReturnValue = 0x2000,
All = Assembly | Module | Class | Struct | Enum | Constructor |
Method | Property | Field | Event | Interface | Parameter |
Delegate | ReturnValue,
ClassMembers = Class | Struct | Enum | Constructor | Method |
Property | Field | Event | Delegate | Interface,
}

17.4.2 The Conditional attribute
The Conditional attribute enables the definition of conditional methods. The Conditional attribute indicates a condition by testing a conditional compilation symbol. Calls to a conditional method are either included or omitted depending on whether this symbol is defined at the point of the call. If the symbol is defined, then the call is included; otherwise, the call is omitted.
[AttributeUsage(AttributeTargets.Method, AllowMultiple = true)]
public class ConditionalAttribute: Attribute
{
public ConditionalAttribute(string conditionalSymbol) {...}
public string ConditionalSymbol { get {...} }
}
A conditional method is subject to the following restrictions:
• The conditional method must be a method in a class-declaration.
• The conditional method must not be an override method.
• The conditional method must have a return type of void.
• The conditional method must not be marked with the override modifier. A conditional method may be marked with the virtual modifier, however. Overrides of such a method are implicitly conditional, and must not be explicitly marked with a Conditional attribute.
• The conditional method must not be an implementation of an interface method. Otherwise, a compile-time error occurs.
In addition, a compile-time error occurs if a conditional method is used in a delegate-creation-expression. The example
#define DEBUG
using System.Diagnostics;
class Class1
{
[Conditional("DEBUG")]
public static void M() {
Console.WriteLine("Executed Class1.M");
}
}
class Class2
{
public static void Test() {
Class1.M();
}
}
declares Class1.M as a conditional method. Class2's Test method calls this method. Since the conditional compilation symbol DEBUG is defined, if Class2.Test is called, it will call M. If the symbol DEBUG had not been defined, then Class2.Test would not call Class1.M.
It is important to note that the inclusion or exclusion of a call to a conditional method is controlled by the conditional compilation symbols at the point of the call. In the example
// Begin class1.cs
using System.Diagnostics;
class Class1
{
[Conditional("DEBUG")]
public static void F() {
Console.WriteLine("Executed Class1.F");
}
}
// End class1.cs

// Begin class2.cs
#define DEBUG
using System.Diagnostics;
class Class2
{
public static void G() {
Class1.F(); // F is called
}
}
// End class2.cs

// Begin class3.cs
#undef DEBUG
class Class3
{
public static void H() {
Class1.F(); // F is not called
}
}
// End class3.cs
the classes Class2 and Class3 each contain calls to the conditional method Class1.F, which is conditional based on whether DEBUG is defined. Since this symbol is defined in the context of Class2 but not Class3, the call to F in Class2 is included, while the call to F in Class3 is omitted.
17.4.3 The Obsolete attribute
The Obsolete attribute is used to mark program types and members that should no longer be used.
[AttributeUsage(AttributeTargets.Class |
AttributeTargets.Struct |
AttributeTargets.Enum |
AttributeTargets.Interface |
AttributeTargets.Delegate |
AttributeTargets.Method |
AttributeTargets.Constructor |
AttributeTargets.Property |
AttributeTargets.Field |
AttributeTargets.Event)]
public class ObsoleteAttribute: Attribute
{
public ObsoleteAttribute() {...}
public ObsoleteAttribute(string message) {...}
public ObsoleteAttribute(string message, bool error) {...}
public string Message { get {...} }
public bool IsError { get {...} }
}
If a program uses a type or member that is decorated with the Obsolete attribute, then the compiler shall issue a warning or error in order to alert the developer, so the offending code can be fixed. Specifically, the compiler shall issue a warning if no error parameter is provided, or if the error parameter is provided and has the value false. The compiler shall issue a compile-time error if the error parameter is specified and has the value true.
In the example
[Obsolete("This class is obsolete; use class B instead")]
class A
{
public void F() {}
}
class B
{
public void F() {}
}
class Test
{
static void Main() {
A a = new A(); // warning
a.F();
}
}
the class A is decorated with the Obsolete attribute. Each use of A in Main results in a warning that includes the specified message, “This class is obsolete; use class B instead.”
17.5 Attributes for Interoperation
Note: This section is applicable only to the Microsoft .NET implementation of C#.
17.5.1 Interoperation with COM and Win32 components
The .NET runtime provides a large number of attributes that enable C# programs to interoperate with components written in COM and Win32 DLLs. For example, the DllImport attribute can be used on a static extern method to indicate that the implementation of the method is to be found in a Win32 DLL. These attributes are found in the System.Runtime.InteropServices namespace, and detailed documentation for these attributes is found in the .NET runtime documentation.
17.5.2 Interoperation with other .NET languages
17.5.2.1 The IndexerName attribute
Indexers are implemented in .NET using indexed properties, and have a name in the .NET metadata. If no IndexerName attribute is present for an indexer, then the name Item is used by default. The IndexerName attribute enables a developer to override this default and specify a different name.
namespace System.Runtime.CompilerServices.CSharp
{
[AttributeUsage(AttributeTargets.Property)]
public class IndexerNameAttribute: System.Attribute
{
public IndexerNameAttribute(string indexerName) {...}
public string Value { get {...} }
}
}
A. Unsafe code
The core C# language, as defined in the preceding chapters, differs notably from C and C++ in its omission of pointers as a data type. C# instead provides references and the ability to create objects that are managed by a garbage collector. This design, coupled with other features, makes C# a much safer language than C or C++. In the core C# language it is simply not possible to have an uninitialized variable, a “dangling” pointer, or an expression that indexes an array beyond its bounds. Whole categories of bugs that routinely plague C and C++ programs are thus eliminated.
While practically every pointer type construct in C or C++ has a reference type counterpart in C#, there are nonetheless situations where access to pointer types becomes a necessity. For example, interfacing with the underlying operating system, accessing a memory-mapped device, or implementing a time-critical algorithm may not be possible or practical without access to pointers. To address this need, C# provides the ability to write unsafe code.
In unsafe code it is possible to declare and operate on pointers, to perform conversions between pointers and integral types, to take the address of variables, and so forth. In a sense, writing unsafe code is much like writing C code within a C# program.
Unsafe code is in fact a “safe” feature from the perspective of both developers and users. Unsafe code must be clearly marked with the modifier unsafe, so developers can’t possibly use unsafe features accidentally, and the execution engine works to ensure that unsafe code cannot be executed in an untrusted environment.
A.1 Unsafe contexts
The unsafe features of C# are available only in unsafe contexts. An unsafe context is introduced by including an unsafe modifier in the declaration of a type or member, or by employing an unsafe-statement:
• A declaration of a class, struct, interface, or delegate may include an unsafe modifier, in which case the entire textual extent of that type declaration (including the body of the class, struct, or interface) is considered an unsafe context.
• A declaration of a field, method, property, event, indexer, operator, constructor, destructor, or static constructor may include an unsafe modifier, in which case the entire textual extent of that member declaration is considered an unsafe context.
• An unsafe-statement enables the use of an unsafe context within a block. The entire textual extent of the associated block is considered an unsafe context.
The associated grammar extensions are shown below. For brevity, ellipses (...) are used to represent productions that appear in preceding chapters.
class-modifier:
...
unsafe
struct-modifier:
...
unsafe
interface-modifier:
...
unsafe
delegate-modifier:
...
unsafe
field-modifier:
...
unsafe
method-modifier:
...
unsafe
property-modifier:
...
unsafe
event-modifier:
...
unsafe
indexer-modifier:
...
unsafe
operator-modifier:
...
unsafe
constructor-modifier:
...
unsafe
destructor-declaration:
attributesopt externopt unsafeopt ~ identifier ( ) destructor-body
attributesopt unsafeopt externopt ~ identifier ( ) destructor-body
static-constructor-modifiers:
unsafeopt externopt static
unsafeopt static externopt
externopt unsafeopt static
static unsafeopt externopt
externopt static unsafeopt
static externopt unsafeopt
embedded-statement:
...
unsafe-statement
unsafe-statement:
unsafe block
In the example
public unsafe struct Node
{
public int Value;
public Node* Left;
public Node* Right;
}
the unsafe modifier specified in the struct declaration causes the entire textual extent of the struct declaration to become an unsafe context. Thus, it is possible to declare the Left and Right fields to be of a pointer type. The example above could also be written
public struct Node
{
public int Value;
public unsafe Node* Left;
public unsafe Node* Right;
}
Here, the unsafe modifiers in the field declarations cause those declarations to be considered unsafe contexts.
Other than establishing an unsafe context, thus permitting the use of pointer types, the unsafe modifier has no effect on a type or a member. In the example
public class A
{
public unsafe virtual void F() {
char* p;
...
}
}
public class B: A
{
public override void F() {
base.F();
...
}
}
the unsafe modifier on the F method in A simply causes the textual extent of F to become an unsafe context in which the unsafe features of the language can be used. In the override of F in B, there is no need to re-specify the unsafe modifier—unless, of course, the F method in B itself needs access to unsafe features.
The situation is slightly different when a pointer type is part of the method’s signature
public unsafe class A
{
public virtual void F(char* p) {...}
}
public class B: A
{
public unsafe override void F(char* p) {...}
}
Here, because F’s signature includes a pointer type, it can only be written in an unsafe context. However, the unsafe context can be introduced by either making the entire class unsafe, as is the case in A, or by including an unsafe modifier in the method declaration, as is the case in B.
A.2 Pointer types
In an unsafe context, a type (§4) may be a pointer-type as well as a value-type or a reference-type.
type:
value-type
reference-type
pointer-type
A pointer-type is written as an unmanaged-type or the keyword void, followed by a * token:
pointer-type:
unmanaged-type *
void *
unmanaged-type:
type
The type specified before the * in a pointer type is called the referent type of the pointer type. It represents the type of the variable to which a value of the pointer type points.
Unlike references (values of reference types), pointers are not tracked by the garbage collector—the garbage collector has no knowledge of pointers and the data to which they point. For this reason a pointer is not permitted to point to a reference or to a struct that contains references, and the referent type of a pointer must be an unmanaged-type.
An unmanaged-type is any type that isn’t a reference-type and doesn’t contain reference-type fields at any level of nesting. In other words, an unmanaged-type is one of the following:
• sbyte, byte, short, ushort, int, uint, long, ulong, char, float, double, decimal, or bool.
• Any enum-type.
• Any pointer-type.
• Any user-defined struct-type that contains fields of unmanaged-types only.
The intuitive rule for mixing of pointers and references is that referents of references (objects) are permitted to contain pointers, but referents of pointers are not permitted to contain references.
Some examples of pointer types are given in the table below:

Example Description
byte* Pointer to byte
char* Pointer to char
int** Pointer to pointer to int
int*[] Single-dimensional array of pointers to int
void* Pointer to unknown type

For a given implementation, all pointer types must have the same size and representation.
Unlike C and C++, when multiple pointers are declared in the same declaration, in C# the * is written along with the underlying type only, not as a prefix punctuator on each pointer name. The example
int* pi, pj; // NOT as int *pi, *pj;
declares two variables, named pi and pj, of type int*.
The value of a pointer having type T* represents the address of a variable of type T. The pointer indirection operator * (A.5.1) may be used to access this variable. For example, given
a variable P of type int*, the expression *P denotes the int variable found at the address contained in P.
Like an object reference, a pointer may be null. Applying the indirection operator to a null pointer results in implementation-defined behavior. A pointer with the value null is represented by all-bits-zero.
The void* type represents a pointer to an unknown type. Because the referent type is unknown, the indirection operator cannot be applied to a pointer of type void*, nor can any arithmetic be performed on such a pointer. However, a pointer of type void* can be cast to any other pointer type (and vice versa).
Pointer types are a separate category of types. Unlike reference types and value types, pointer types do not inherit from object and no conversions exist between pointer types and object. In particular, boxing and unboxing (§4.3) are not supported for pointers. However, conversions are permitted between different pointer types and between pointer types and the integral types. This is described in §A.4.
A pointer-type may be used as the type of a volatile field (§10.4.3).
Although pointers can be passed as ref or out parameters, doing so can cause undefined behavior, since the pointer may well be set to point to a local variable which no longer exists when the called method returns, or the fixed object to which it used to point, is no longer fixed. For example:
using System;
class Test
{
static int value = 20;
unsafe static void F(out int* pi1, ref int* pi2) {
int i = 10;
pi1 = &i;
fixed (int* pj = &value) {
// ...
pi2 = pj;
}
}
unsafe static void Main() {
int* px1;
int i = 10;
int* px2 = &i;
F(out px1, ref px2);
Console.WriteLine("*px1 = {0}, *px2 = {1}",
*px1, *px2); // undefined behavior
}
}
A method can return a value of some type, and that type can be a pointer. For example, when given a pointer to a contiguous sequence of int values, the sequence's element count, and some other int value, the following method returns the address of the indicated value in that array, if a match occurs; otherwise it returns null:
unsafe static int* Find(int* pi, int size, int value) {
for (int i = 0; i < size; ++i) {
if (*pi == value)
return pi;
++pi;
}
return null;
}
In an unsafe context, several constructs are available for operating on pointers:
• The * operator may be used to perform pointer indirection (§A.5.1).
• The -> operator may be used to access a member of a struct through a pointer (§A.5.2).
• The [] operator may be used to index a pointer (§A.5.3).
• The & operator may be used to obtain the address of a variable (§A.5.4).
• The ++ and -- operators may be used to increment and decrement pointers (§A.5.5).
• The + and - operators may be used to perform pointer arithmetic (§A.5.6).
• The ==, !=, <, >, <=, and => operators may be used to compare pointers (§A.5.7).
• The stackalloc operator may be used to allocate memory from the call stack (§A.7).
• The fixed statement may be used to temporarily fix a variable so its address can be obtained (§A.6).
A.3 Fixed and moveable variables
The address-of operator (§A.5.4) and the fixed statement (§A.6) divide variables into two categories: Fixed variables and moveable variables.
Fixed variables reside in storage locations that are unaffected by operation of the garbage collector. Examples of fixed variables include local variables, value parameters, and variables created by dereferencing pointers. Moveable variables on the other hand reside in storage locations that are subject to relocation or disposal by the garbage collector. Examples of moveable variables include fields in objects and elements of arrays.
The & operator (§A.5.4) permits the address of a fixed variable to be obtained without restrictions. However, because a moveable variable is subject to relocation or disposal by the garbage collector, the address of a moveable variable can only be obtained using a fixed statement (§A.6), and the address remains valid only for the duration of that fixed statement.
In precise terms, a fixed variable is one of the following:
• A variable resulting from a simple-name (§7.5.2) that refers to a local variable or a value parameter.
• A variable resulting from a member-access (§7.5.4) of the form V.I, where V is a fixed variable of a struct-type.
• A variable resulting from a pointer-indirection-expression (§A.5.1) of the form *P, a pointer-member-access (§A.5.2) of the form P->I, or a pointer-element-access (§A.5.3) of the form P[E].
All other variables are classified as moveable variables.
Note that a static field is classified as a moveable variable. Also note that a ref or out parameter is classified as a moveable variable, even if the argument given for the parameter is a fixed variable. Finally, note that a variable produced by dereferencing a pointer is always classified as a fixed variable.
A.4 Pointer conversions
In an unsafe context, the set of available implicit conversions (§6.1) is extended to include the following implicit pointer conversions:
• From any pointer-type to the type void*.
• From the null type to any pointer-type.
Additionally, in an unsafe context, the set of available explicit conversions (§6.2) is extended to include the following explicit pointer conversions:
• From any pointer-type to any other pointer-type.
• From sbyte, byte, short, ushort, int, uint, long, or ulong to any pointer-type.
• From any pointer-type to sbyte, byte, short, ushort, int, uint, long, or ulong.
Finally, in an unsafe context, the set of standard implicit conversions (§6.3.1) includes the following pointer conversion:
• From any pointer-type to the type void*.
Conversions between two pointer types never change the actual pointer value. In other words, a conversion from one pointer type to another has no effect on the underlying address given by the pointer.
When one pointer type is converted to another, if the resulting pointer is not correctly aligned for the pointed-to type, the behavior is undefined if the result is dereferenced. In general, the concept “correctly aligned” is transitive: if a pointer to type A is correctly aligned for a pointer to type B, which, in turn, is correctly aligned for a pointer to type C, then a pointer to type A is correctly aligned for a pointer to type C.
Consider the following case in which a variable having one type is accessed via a pointer to a different type:
char c = 'A';
char* pc = &c;
void* pv = pc;
int* pi = (int*)pv;
int i = *pi; // undefined
*pi = 123456; // undefined
When a pointer type is converted to a pointer to byte, the result points to the lowest addressed byte of the variable. Successive increments of the result, up to the size of the variable, yield pointers to the remaining bytes of that variable. For example, the following method displays each of the eight bytes in a double as a hexadecimal value:
using System;
class Test
{
unsafe static void Main() {
double d = 123.456e23;
byte* pb = (byte*)&d;
for (int i = 0; i < sizeof(double); ++i)
Console.Write(" {0,2:X}", (uint)(*pb++));
}
}
Of course, the output produced depends on endianness.
Mappings between pointers and integers are implementation-defined. However, on 32- and 64-bit CPU architectures with a linear address space, conversions of pointers to or from integral types typically behave exactly like a conversion of uint or ulong values, respectively, to or from those integral types.
A.5 Pointers in expressions
In an unsafe context an expression may yield a result of a pointer type, but outside an unsafe context it is a compile-time error for an expression to be of a pointer type. In precise terms, outside an unsafe context a compile-time error occurs if any simple-name (§7.5.2), member-access (§7.5.4), invocation-expression (§7.5.5), or element-access (§7.5.6) is of a pointer type.
In an unsafe context, the primary-no-array-creation-expression (§7.5) and unary-expression (§7.6) productions permit the following additional constructs:
primary-no-array-creation-expression:
...
pointer-member-access
pointer-element-access
sizeof-expression
unary-expression:
...
pointer-indirection-expression
addressof-expression
These constructs are described in the following sections. The precedence and associativity of the unsafe operators is implied by the grammar.
A.5.1 Pointer indirection
A pointer-indirection-expression consists of an asterisk (*) followed by a unary-expression.
pointer-indirection-expression:
* unary-expression
The unary * operator denotes pointer indirection and is used to obtain the variable to which a pointer points. The result of evaluating *P, where P is an expression of a pointer type T*, is a variable of type T. It is a compile-time error to apply the unary * operator to an expression of type void* or to an expression that isn’t of a pointer type.
The effect of applying the unary * operator to a null pointer is implementation-defined. In particular, there is no guarantee that this operation throws a System.NullReferenceException.
If an invalid value has been assigned to the pointer, the behavior of the unary * operator is undefined. Among the invalid values for dereferencing a pointer by the unary * operator are an address inappropriately aligned for the type pointed to (see example in §A.4), and the address of a variable after the end of its lifetime.
For purposes of definite assignment analysis, a variable produced by evaluating an expression of the form *P is considered initially assigned (§5.3.1).
A.5.2 Pointer member access
A pointer-member-access consists of a primary-expression, followed by a “->” token, followed by an identifier.
pointer-member-access:
primary-expression -> identifier
In a pointer member access of the form P->I, P must be an expression of a pointer type other than void*, and I must denote an accessible member of the type to which P points.
A pointer member access of the form P->I is evaluated exactly as (*P).I. For a description of the pointer indirection operator (*), see §A.5.1. For a description of the member access operator (.), see §7.5.4.
In the example
struct Point
{
public int x;
public int y;
public override string ToString() {
return "(" + x + "," + y + ")";
}
}
class Test
{
unsafe static void Main() {
Point point;
Point* p = &point;
p->x = 10;
p->y = 20;
Console.WriteLine(p->ToString());
}
}
the -> operator is used to access fields and invoke a method of a struct through a pointer. Because the operation P->I is precisely equivalent to (*P).I, the Main method could equally well have been written:
class Test
{
unsafe static void Main() {
Point point;
Point* p = &point;
(*p).x = 10;
(*p).y = 20;
Console.WriteLine((*p).ToString());
}
}
A.5.3 Pointer element access
A pointer-element-access consists of a primary-no-array-creation-expression followed by an expression enclosed in “[” and “]”.
pointer-element-access:
primary-no-array-creation-expression [ expression ]
In a pointer element access of the form P[E], P must be an expression of a pointer type other than void*, and E must be an expression of a type that can be implicitly converted to int, uint, long, or ulong.
A pointer element access of the form P[E] is evaluated exactly as *(P + E). For a description of the pointer indirection operator (*), see §A.5.1. For a description of the pointer addition operator (+), see §A.5.6.
In the example
class Test
{
unsafe static void Main() {
char* p = stackalloc char[256];
for (int i = 0; i < 256; i++) p[i] = (char)i;
}
}
a pointer element access is used to initialize the character buffer in a for loop. Because the operation P[E] is precisely equivalent to *(P + E), the example could equally well have been written:
class Test
{
unsafe static void Main() {
char* p = stackalloc char[256];
for (int i = 0; i < 256; i++) *(p + i) = (char)i;
}
}
The pointer element access operator does not check for out-of-bounds errors and the effects of accessing an out-of-bounds element are undefined.
A.5.4 The address-of operator
An addressof-expression consists of an ampersand (&) followed by a unary-expression.
addressof-expression:
& unary-expression
Given an expression E which is of a type T and is classified as a fixed variable (§A.3), the construct &E computes the address of the variable given by E. The type of the result is T* and is classified as a value. A compile-time error occurs if E is not classified as a variable, if E is classified as a volatile field, or if E denotes a moveable variable. In the last case, a fixed statement (§A.6) can be used to temporarily “fix” the variable before obtaining its address.
The & operator does not require its argument to be definitely assigned, but following an & operation, the variable to which the operator is applied is considered definitely assigned in the execution path in which the operation occurs. It is the responsibility of the programmer to ensure that correct initialization of the variable actually does take place in this situation.
In the example
using System;
unsafe class Test
{
static void Main() {
int i;
int* p = &i;
*p = 123;
Console.WriteLine(i);
}
}
i is considered definitely assigned following the &i operation used to initialize p. The assignment to *p in effect initializes i, but the inclusion of this initialization is the responsibility of the programmer, and no compile-time error would occur if the assignment was removed.
The rules of definite assignment for the & operator exist such that redundant initialization of local variables can be avoided. For example, many external APIs take a pointer to a structure which is filled in by the API. Calls to such APIs typically pass the address of a local struct variable, and without the rule, redundant initialization of the struct variable would be required.
As stated earlier (§7.5.4), outside an instance constructor or static constructor for a struct or class that defines a readonly field, that field is considered a value, not a variable. As such, its address cannot be taken. Similarly, the address of a constant cannot be taken.
A.5.5 Pointer increment and decrement
In an unsafe context, the ++ operator (§7.5.9) and the operator (§7.6.5) can be applied to pointer variables of all types except void*. Thus, for every pointer type T*, the following operators are implicitly defined:
T* operator ++(T* x);
T* operator --(T* x);
The operators produce the same results asx+1 and x-1, respectively (§A.5.6). In other words, for a pointer variable of type T*, the ++ operator adds sizeof(T) to the address contained in the variable, and the operator subtracts sizeof(T) from the address contained in the variable.
If a pointer increment or decrement operation overflows the domain of the pointer type, the result is implementation-defined, but no exceptions are produced.
A.5.6 Pointer arithmetic
In an unsafe context, the + operator (§7.7.4) and - operator (§7.7.5) can be applied to values of all pointer types except void*. Thus, for every pointer type T*, the following operators are implicitly defined:
T* operator +(T* x, int y);
T* operator +(T* x, uint y);
T* operator +(T* x, long y);
T* operator +(T* x, ulong y);
T* operator +(int x, T* y);
T* operator +(uint x, T* y);
T* operator +(long x, T* y);
T* operator +(ulong x, T* y);
T* operator –(T* x, int y);
T* operator –(T* x, uint y);
T* operator –(T* x, long y);
T* operator –(T* x, ulong y);
long operator –(T* x, T* y);
Given an expression P of a pointer type T* and an expression N of type int, uint, long, or ulong, the expressions P + N and N + P compute the pointer value of type T* that results from adding N * sizeof(T) to the address given by P. Likewise, the expression P - N computes the pointer value of type T* that results from subtracting N * sizeof(T) from the address given by P.
Given two expressions, P and Q, of a pointer type T*, the expression P – Q computes the difference between the addresses given by P and Q and then divides the difference by sizeof(T). The type of the result is always long. In effect, P - Q is computed as ((long)(P) - (long)(Q)) / sizeof(T).
For example, this program:
using System;
class Test
{
unsafe static void Main() {
int* values = stackalloc int[20];
int* p = &values[1];
int* q = &values[15];
Console.WriteLine("p - q = {0}", p - q);
Console.WriteLine("q - p = {0}", q - p);
}
}
produces the output:
p - q = -14
q - p = 14
If a pointer arithmetic operation overflows the domain of the pointer type, the result is truncated in an implementation-defined fashion, but no exceptions are produced.
A.5.7 Pointer comparison
In an unsafe context, the ==, !=, <, >, <=, and => operators (§7.9) can be applied to values of all pointer types. The pointer comparison operators are:
bool operator ==(void* x, void* y);
bool operator !=(void* x, void* y);
bool operator <(void* x, void* y);
bool operator >(void* x, void* y);
bool operator <=(void* x, void* y);
bool operator >=(void* x, void* y);
Because an implicit conversion exists from any pointer type to the void* type, operands of any pointer type can be compared using these operators. The comparison operators compare the addresses given by the two operands as if they were unsigned integers.
A.5.8 The sizeof operator
The sizeof operator returns the number of bytes occupied by a variable of a given type. The type specified as an operand to sizeof must be an unmanaged-type (§A.2).
sizeof-expression:
sizeof ( unmanaged-type )
The result of the sizeof operator is a value of type int. For certain predefined types, the sizeof operator yields a constant value as shown in the table below.

Expression Result
sizeof(sbyte) 1
sizeof(byte) 1
sizeof(short) 2
sizeof(ushort) 2
sizeof(int) 4
sizeof(uint) 4
sizeof(long) 8
sizeof(ulong) 8
sizeof(char) 2
sizeof(float) 4
sizeof(double) 8
sizeof(bool) 1

For all other types, the result of the sizeof operator is implementation-defined and is classified as a value, not a constant.
The order in which members are packed into a struct is unspecified.
For alignment purposes, there may be unnamed padding at the beginning of a struct, within a struct, and at the end of the struct. The contents of the bits used as padding are indeterminate.
When applied to an operand that has struct type, the result is the total number of bytes in a variable of that type, including any padding.
A.6 The fixed statement
In an unsafe context, the embedded-statement (§8) production permits an additional construct, the fixed statement, which is used to “fix” a moveable variable such that its address remains constant for the duration of the statement.
embedded-statement:
...
fixed-statement
fixed-statement:
fixed ( pointer-type fixed-pointer-declarators ) embedded-statement
fixed-pointer-declarators:
fixed-pointer-declarator
fixed-pointer-declarators , fixed-pointer-declarator
fixed-pointer-declarator:
identifier = fixed-pointer-initializer
fixed-pointer-initializer:
& variable-reference
expression
Each fixed-pointer-declarator declares a local variable of the given pointer-type and initializes the local variable with the address computed by the corresponding fixed-pointer-initializer. A local variable declared in a fixed statement is accessible in any fixed-pointer-initializers occurring to the right of the declaration, and in the embedded-statement of the fixed statement. A local variable declared by a fixed statement is considered read-only. A compile-time error occurs if the embedded statement attempts to modify this local variable (via assignment or the ++ and operators) or pass it as a ref or out parameter.
A fixed-pointer-initializer can be one of the following:
• The token “&” followed by a variable-reference (§5.3.3) to a moveable variable (§A.3) of an unmanaged type T, provided the type T* is implicitly convertible to the pointer type given in the fixed statement. In this case, the initializer computes the address of the given variable, and the variable is guaranteed to remain at a fixed address for the duration of the fixed statement.
• An expression of an array-type with elements of an unmanaged type T, provided the type T* is implicitly convertible to the pointer type given in the fixed statement. In this case, the initializer computes the address of the first element in the array, and the entire array is guaranteed to remain at a fixed address for the duration of the fixed statement. The behavior of the fixed statement is implementation-defined if the array expression is null or if the array has zero elements.
• An expression of type string, provided the type char* is implicitly convertible to the pointer type given in the fixed statement. In this case, the initializer computes the address of the first character in the string, and the entire string is guaranteed to remain at a fixed address for the duration of the fixed statement. The behavior of the fixed statement is implementation-defined if the string expression is null.
For each address computed by a fixed-pointer-initializer the fixed statement ensures that the variable referenced by the address is not subject to relocation or disposal by the garbage collector for the duration of the fixed statement. For example, if the address computed by a fixed-pointer-initializer references a field of an object or an element of an array instance, the fixed statement guarantees that the containing object instance is not relocated or disposed of during the lifetime of the statement.
It is the programmer’s responsibility to ensure that pointers created by fixed statements do not survive beyond execution of those statements. For example, when pointers created by fixed statements are passed to external APIs, it is the programmer’s responsibility to ensure that the APIs retain no memory of these pointers.
Fixed objects may cause fragmentation of the heap (because they can’t be moved). For that reason, objects should be fixed only when absolutely necessary and then only for the shortest amount of time possible.
The example
unsafe class Test
{
static int x;
int y;
static void F(int* p) {
*p = 1;
}
static void Main() {
Test t = new Test();
int[] arr = new int[10];
fixed (int* p = &x) F(p);
fixed (int* p = &t.y) F(p);
fixed (int* p = &arr[0]) F(p);
fixed (int* p = arr) F(p);
}
}
demonstrates several uses of the fixed statement. The first statement fixes and obtains the address of a static field, the second statement fixes and obtains the address of an instance field, and the third statement fixes and obtains the address of an array element. In each case it would have been an error to use the regular & operator since the variables are all classified as moveable variables.
The third and fourth fixed statements in the example above produce identical results. In general, for an array instance arr, specifying &arr[0] in a fixed statement is the same as simply specifying arr.
Here’s another example of the fixed statement, this time using string:
class Test
{
static string name = "xx";
unsafe static void F(char* p) {
for (int i = 0; p[i] != '\0'; ++i)
Console.WriteLine(p[i]);
}
unsafe static void Main() {
fixed (char* p = name) F(p);
fixed (char* p = "xx") F(p);
}
}
In an unsafe context array elements of single-dimensional arrays are stored in increasing index order, starting with index 0 and ending with index Length – 1. For multi-dimensional arrays, array elements are stored such that the indices of the rightmost dimension are increased first, then the next left dimension, and so on to the left. Within a fixed statement that obtains a pointer p to an array instance a, the pointer values ranging from p to p + arr.Length - 1 represent addresses of the elements in the array. Likewise, the variables ranging from p[0] to p[arr.Length - 1] represent the actual array elements. Given the way in which arrays are stored, we can treat an array of any dimension as though it were linear.
The example
class Test
{
static void Main() {
int[,,] a = new int[2,3,4];
unsafe {
fixed (int* p = a) {
for (int i = 0; i < a.Length; ++i) // treat as linear
p[i] = i;
}
}

for (int i = 0; i < 2; ++i)
for (int j = 0; j < 3; ++j) {
for (int k = 0; k < 4; ++k)
Console.Write("[{0},{1},{2}] = {3,2} ", i, j, k, a[i,j,k]);
Console.WriteLine();
}
}
}
produces the output:
[0,0,0] = 0 [0,0,1] = 1 [0,0,2] = 2 [0,0,3] = 3
[0,1,0] = 4 [0,1,1] = 5 [0,1,2] = 6 [0,1,3] = 7
[0,2,0] = 8 [0,2,1] = 9 [0,2,2] = 10 [0,2,3] = 11
[1,0,0] = 12 [1,0,1] = 13 [1,0,2] = 14 [1,0,3] = 15
[1,1,0] = 16 [1,1,1] = 17 [1,1,2] = 18 [1,1,3] = 19
[1,2,0] = 20 [1,2,1] = 21 [1,2,2] = 22 [1,2,3] = 23
In the example
unsafe class Test
{
static void Fill(int* p, int count, int value) {
for (; count != 0; count--) *p++ = value;
}
static void Main() {
int[] arr = new int[100];
fixed (int* p = arr) Fill(p, 100, -1);
}
}
a fixed statement is used to fix an array so its address can be passed to a method that takes a pointer.
A char* value produced by fixing a string instance always points to a null-terminated string. Within a fixed statement that obtains a pointer p to a string instance s, the pointer values ranging from p to p + s.Length - 1 represent addresses of the characters in the string, and the pointer value p + s.Length always points to a null character (the character with value '\0').
Modifying objects of managed type through fixed pointers can results in undefined behavior. Because strings are immutable, it is the programmer’s responsibility to ensure that the characters referenced by a pointer to a fixed string are not modified.
The automatic null-termination of strings is particularly convenient when calling external APIs that expect “C-style” strings. Note, however, that a string instance is permitted to contain null characters. If such null characters are present, the string will appear truncated when treated as a null-terminated char*.
A.7 Stack allocation
In an unsafe context, a local variable declaration (§8.5.1) may include a stack allocation initializer which allocates memory from the call stack.
local-variable-initializer:
expression
array-initializer
stackalloc-initializer
stackalloc-initializer:
stackalloc unmanaged-type [ expression ]
The unmanaged-type indicates the type of the items that will be stored in the newly allocated location, and the expression indicates the number of these items. Taken together, these specify the required allocation size. Since the size of a stack allocation cannot be negative, it is a compile-time error to specify the number of items as a constant-expression that evaluates to a negative value.
A stack allocation initializer of the form stackalloc T[E] requires T to be an unmanaged type (§A.2) and E to be an expression of type int. The construct allocates E * sizeof(T) bytes from the call stack and returns a pointer, of type T*, to the newly allocated block. If E is a negative value, then the behavior is undefined. If E is zero, then no allocation is made, and the pointer returned is implementation-defined. If there is not enough memory available to allocate a block of the given size, a System.StackOverflowException is thrown.
The content of the newly allocated memory is undefined.
There is no way to explicitly free memory allocated using stackalloc. Instead, all stack allocated memory blocks created during the execution of a function member are automatically discarded when the function member returns. This corresponds to the alloca function, an extension commonly found in C and C++ implementations.
Stack allocation initializers are not permitted in catch or finally blocks (§8.10).
In the example
using System;
class Test
{
unsafe static string IntToString(int value) {
char* buffer = stackalloc char[16];
char* p = buffer + 16;
int n = value >= 0? value: -value;
do {
*--p = (char)(n % 10 + '0');
n /= 10;
} while (n != 0);
if (value < 0) *--p = '-';
return new string(p, 0, (int)(buffer + 16 - p));
}
static void Main() {
Console.WriteLine(IntToString(12345));
Console.WriteLine(IntToString(-999));
}
}
a stackalloc initializer is used in the IntToString method to allocate a buffer of 16 characters on the stack. The buffer is automatically discarded when the method returns.
A.8 Dynamic memory allocation
Except for the stackalloc operator, C# provides no predefined constructs for managing non-garbage collected memory. Such services are typically provided by supporting class libraries or imported directly from the underlying operating system. For example, the Memory class below illustrates how the heap functions of an underlying operating system might be accessed from C#:
using System.Runtime.InteropServices;
public unsafe class Memory
{
// Handle for the process heap. This handle is used in all calls to the
// HeapXXX APIs in the methods below.
static int ph = GetProcessHeap();
// Private instance constructor to prevent instantiation.
private Memory() {}
// Allocates a memory block of the given size. The allocated memory is
// automatically initialized to zero.
public static void* Alloc(int size) {
void* result = HeapAlloc(ph, HEAP_ZERO_MEMORY, size);
if (result == null) throw new OutOfMemoryException();
return result;
}
// Copies count bytes from src to dst. The source and destination
// blocks are permitted to overlap.
public static void Copy(void* src, void* dst, int count) {
byte* ps = (byte*)src;
byte* pd = (byte*)dst;
if (ps > pd) {
for (; count != 0; count--) *pd++ = *ps++;
}
else if (ps < pd) {
for (ps += count, pd += count; count != 0; count--) *--pd = *--ps;
}
}
// Frees a memory block.
public static void Free(void* block) {
if (!HeapFree(ph, 0, block)) throw new InvalidOperationException();
}
// Re-allocates a memory block. If the reallocation request is for a
// larger size, the additional region of memory is automatically
// initialized to zero.
public static void* ReAlloc(void* block, int size) {
void* result = HeapReAlloc(ph, HEAP_ZERO_MEMORY, block, size);
if (result == null) throw new OutOfMemoryException();
return result;
}
// Returns the size of a memory block.
public static int SizeOf(void* block) {
int result = HeapSize(ph, 0, block);
if (result == -1) throw new InvalidOperationException();
return result;
}
// Heap API flags
const int HEAP_ZERO_MEMORY = 0x00000008;
// Heap API functions
[DllImport("kernel32")]
static extern int GetProcessHeap();
[DllImport("kernel32")]
static extern void* HeapAlloc(int hHeap, int flags, int size);
[DllImport("kernel32")]
static extern bool HeapFree(int hHeap, int flags, void* block);
[DllImport("kernel32")]
static extern void* HeapReAlloc(int hHeap, int flags,
void* block, int size);
[DllImport("kernel32")]
static extern int HeapSize(int hHeap, int flags, void* block);
}
An example that uses the Memory class is given below:
class Test
{
unsafe static void Main() {
byte* buffer = (byte*)Memory.Alloc(256);
for (int i = 0; i < 256; i++) buffer[i] = (byte)i;
byte[] array = new byte[256];
fixed (byte* p = array) Memory.Copy(buffer, p, 256);
Memory.Free(buffer);
for (int i = 0; i < 256; i++) Console.WriteLine(array[i]);
}
}
The example allocates 256 bytes of memory through Memory.Alloc and initializes the memory block with values increasing from 0 to 255. It then allocates a 256 element byte array and uses Memory.Copy to copy the contents of the memory block into the byte array. Finally, the memory block is freed using Memory.Free and the contents of the byte array are output on the console.

B. Documentation comments
C# provides a mechanism for programmers to document their code using a special comment syntax that contains XML text. In source code files, comments having a certain form can be used to direct a tool to produce XML from those comments and the source code elements, which they precede. Comments using such syntax are called documentation comments, and are single-line comments of the form ///… They must immediately precede a user-defined type (such as a class, delegate, or interface) or a member (such as a field, event, property, or method). The XML generation tool is called the documentation generator. (This generator could be, but need not be, the C# compiler itself.) The output produced by the documentation generator is called the documentation file. A documentation file is used as input to a documentation viewer; a tool intended to produce some sort of visual display of type information and its associated documentation.
This specification suggests a set of tags to be used in documentation comments, but use of these tags is not required, and other tags may be used if desired, as long the rules of well-formed XML are followed.
B.1 Introduction
Comments having a special form can be used to direct a tool to produce XML from those comments and the source code elements, which they precede. Such comments are single-line comments of the form ///… They must immediately precede a user-defined type (such as a class, delegate, or interface) or a member (such as a field, event, property, or method) that they annotate.
Syntax:
single-line-doc-comment::
/// input-charactersopt
In a single-line-doc-comment, if there is a whitespace character following the /// characters on each of the single-line-doc-comments adjacent to the current single-line-doc-comment, then that whitespace character is not included in the XML output.
Example:
/// Class Point models a point in a two-dimensional
/// plane.
///
public class Point
{
/// method draw renders the point.
void draw() {…}
}
The text within documentation comments must be well formed according to the rules of XML (http://www.w3.org/TR/REC-xml). If the XML is ill formed, a warning is generated and the documentation file will contain a comment saying that an error was encountered.
Although developers are free to create their own set of tags, a recommended set is defined in §B.2. Some of the recommended tags have special meanings:
• The tag is used to describe parameters. If such a tag is used, the documentation generator must verify that the specified parameter exists and that all parameters are described in documentation comments. If such verification fails, the documentation generator issues a warning.
• The cref attribute can be attached to any tag to provide a reference to a code element. The documentation generator must verify that this code element exists. If the verification fails, the documentation generator issues a warning. When looking for a name described in a cref attribute, the documentation generator must respect namespace visibility according to using statements appearing within the source code.
• The

tag is intended to be used by a documentation viewer to display additional information about a type or member.
Note carefully that the documentation file does not provide full information about the type and members (for example, it does not contain any type information). To get such information about a type or member, the documentation file must be used in conjunction with reflection on the actual type or member.
B.2 Recommended tags
The documentation generator must accept and process any tag that is valid according to the rules of XML. The following tags provide commonly used functionality in user documentation. (Of course, other tags are possible.)

Tag Reference Purpose
§B.2.1
Set text in a code-like font
§B.2.2
Set one or more lines of source code or program output
§B.2.3
Indicate an example
§B.2.4
Identifies the exceptions a method can throw
§B.2.5
Create a list or table
§B.2.6
Permit structure to be added to text
§B.2.7
Describe a parameter for a method or constructor
§B.2.8
Identify that a word is a parameter name
§B.2.9
Document the security accessibility of a member
§B.2.10
Describe a type
§B.2.11
Describe the return value of a method
§B.2.12
Specify a link
§B.2.13
Generate a See Also entry

§B.2.14
Describe a member of a type
§B.2.15
Describe a property

B.2.1
This tag provides a mechanism to indicate that a fragment of text within a description should be set a special font such as that used for a block of code. (For lines of actual code, use (§B.2.2).)
Syntax:
text to be set like code
Example:
/// Class Point models a point in a two-dimensional
/// plane.
public class Point
{
// …
}
B.2.2
This tag is used to set one or more lines of source code or program output in some special font. (For small code fragments in narrative, use (§B.2.1).)
Syntax:
source code or program output
Example:
///

This method changes the point's location by
/// the given x- and y-offsets.
/// For example:
///
/// Point p = new Point(3,5);
/// p.Translate(-1,3);
///
/// results in p's having the value (2,8).
///
///

public void Translate(int xor, int yor) {
X += xor;
Y += yor;
}
B.2.3
This tag allows example code within a comment, to specify how a method or other library member may be used. Ordinarily, this would also involve use of the tag (§B.2.2) as well.
Syntax:
description
Example:
See (§B.2.2) for an example.
B.2.4
This tag provides a way to document the exceptions a method can throw.
Syntax:
description
where
cref="member"
The name of a member. The documentation generator checks that the given member exists and translates member to the canonical element name in the documentation file.
description
A description of the circumstances in which the exception is thrown.
Example:
public class DataBaseOperations
{
///
///
public static void ReadRecord(int flag) {
if (flag == 1)
throw new MasterFileFormatCorruptException();
else if (flag == 2)
throw new MasterFileLockedOpenException();
// …
}
}
B.2.5
This tag is used to create a list or table of items. It may contain a block to define the heading row of either a table or definition list. (When defining a table, only an entry for term in the heading need be supplied.)
Each item in the list is specified with an block. When creating a definition list, both term and description must be specified. However, for a table, bulleted list, or numbered list, only description need be specified.
Syntax:


term
description


term
description

…

term
description


where
term
The term to define, whose definition is in description.
description

Either an item in a bullet or numbered list, or the definition of a term.
Example:
public class MyClass
{
/// Here is an example of a bulleted list:
///
///
/// Item 1.
///
///
/// Item 2.
///
///
///
public static void Main () {
// …
}
}
B.2.6
This tag is for use inside other tags, such as (§B.2.10) or (§B.2.11), and permits structure to be added to text.
Syntax:
content
where
content
The text of the paragraph.
Example:
///

This is the entry point of the Point class testing program.
/// This program tests each method and operator, and
/// is intended to be run after any non-trvial maintenance has
/// been performed on the Point class.

public static void Main() {
// …
}
B.2.7
This tag is used to describe a parameter for a method, constructor, or indexer.
Syntax:
description
where
name
The name of the parameter.
description
A description of the parameter.
Example:
///

This method changes the point's location to
/// the given coordinates.

/// xor is the new x-coordinate.
/// yor is the new y-coordinate.
public void Move(int xor, int yor) {
X = xor;
Y = yor;
}
B.2.8
This tag is used to indicate that a word is a parameter. The documentation file can be processed to format this parameter in some distinct way.
Syntax:

where
name
The name of the parameter.
Example:
///

This constructor initializes the new Point to
/// (,).

/// xor is the new Point's x-coordinate.
/// yor is the new Point's y-coordinate.
public Point(int xor, int yor) {
X = xor;
Y = yor;
}
B.2.9
This tag allows the security accessibility of a member to be documented.
Syntax:
description
where
cref="member"
The name of a member. The documentation generator checks that the given code element exists and translates member to the canonical element name in the documentation file.
description
A description of the access to the member.
Example:
/// Everyone can
/// access this method.
public static void Test() {
// …
}
B.2.10
This tag is used to specify overview information about a type. (Use

(§B.2.14) to describe the members of a type.)
Syntax:
description
where
description
The text of the remarks.
Example:
/// Class Point models a point in a two-dimensional plane.
public class Point
{
// …
}
B.2.11
This tag is used to describe the return value of a method.
Syntax:
description
where
description
A description of the return value.
Example:
///

Report a point's location as a string.

/// A string representing a point's location, in the form (x,y),
/// without any leading, training, or embedded whitespace.
public override string ToString() {
return "(" + X + "," + Y + ")";
}
B.2.12
This tag allows a link to be specified within text. (Use (§B.2.13) to indicate text that is to appear in a See Also section.)
Syntax:

where
cref="member"
The name of a member. The documentation generator checks that the given code element exists and passes member to the element name in the documentation file.
Example:
///

This method changes the point's location to
/// the given coordinates.

///
public void Move(int xor, int yor) {
X = xor;
Y = yor;
}
///

This method changes the point's location by
/// the given x- and y-offsets.
///

///
public void Translate(int xor, int yor) {
X += xor;
Y += yor;
}
B.2.13
This tag allows an entry to be generated for the See Also section. (Use (§B.2.12) to specify a link from within text.)
Syntax:

where
cref="member"
The name of a member. The documentation generator checks that the given code element exists and passes member to the element name in the documentation file.
Example:
///

This method determines whether two Points have the same
/// location.

///
///
public override bool Equals(object o) {
// …
}
B.2.14

This tag can be used to describe a member for a type. (Use (§B.2.10) to describe the type itself.)
Syntax:

description

where
description
A summary of the member.
Example:
///

This constructor initializes the new Point to (0,0).

public Point() : this(0,0) {
}
B.2.15
This tag allows a property to be described.
Syntax:
property description
where
property description
A description for the property.
Example:
/// Property X represents the point's x-coordinate.
public int X
{
get { return x; }
set { x = value; }
}
B.3 Processing the documentation file
The documentation generator generates an ID string for each element in the source code that is tagged with a documentation comment. This ID string uniquely identifies a source element. A documentation viewer can use an ID string to identify the corresponding metadata/reflection item to which the documentation applies.
The documentation file is not a hierarchical representation of the source code; rather, it is a flat list with a generated ID string for each element.
B.3.1 ID string format
The documentation generator observes the following rules when it generates the ID strings:
• No white space is placed in the string.
• The first part of the string identifies the kind of member being documented, via a single character followed by a colon. The following kinds of members are defined:
Character Description
E Event
F Field
M Method (including constructors, destructors, and operators)
N Namespace
P Property (including indexers)
T Type (such as class, delegate, enum, interface, and struct)
! Error string; the rest of the string provides information about the error. For example, the documentation generator generates error information for links that cannot be resolved.
• The second part of the string is the fully qualified name of the element, starting at the root of the namespace. The name of the element, its enclosing type(s), and namespace are separated by periods. If the name of the item itself has periods, they are replaced by the NUMBER SIGN # (U+000D). (It is assumed that no element has this character in its name.)
• For methods and properties with arguments, the argument list follows, enclosed in parentheses. For those without arguments, the parentheses are omitted. The arguments are separated by commas. The encoding of each argument is the same as a CLI signature, as follows: Arguments are represented by their fully qualified name. For example, int becomes System.Int32, string becomes System.String, object becomes System.Object, and so on. Arguments having the out or ref modifier have a '@' following their type name. Arguments passed by value or via params have no special notation. Arguments that are arrays are represented as [lowerbound:size, …, lowerbound:size] where the number of commas is the rank – 1, and the lower bounds and size of each dimension, if known, are represented in decimal. If a lower bound or size is not specified, it is omitted. If the lower bound and size for a particular dimension are omitted, the ':' is omitted as well. Jagged arrays are represented by one "[]" per level. Arguments that have pointer types other than void are represented using a '*' following the type name. A void pointer is represented using a type name of "System.Void".
B.3.2 ID string examples
The following examples each show a fragment of C# code, along with the ID string produced from each source element capable of having a documentation comment:
• Types are represented using their fully qualified name.
enum Color {Red, Blue, Green};
namespace Acme
{
interface IProcess { /* … */ }
struct ValueType { /* … */ }
class Widget: Iprocess
{
public class NestedClass { /* … */ }
public interface IMenuItem { /* … */ }
public delegate void Del(int i);
public enum Direction {North, South, East, West};
}
}
"T:Color"
"T:Acme.IProcess"
"T:Acme.ValueType"
"T:Acme.Widget"
"T:Acme.Widget.NestedClass"
"T:Acme.Widget.IMenuItem"
"T:Acme.Widget.Del"
"T:Acme.Widget.Direction"
• Fields are represented by their fully qualified name.
namespace Acme
{
struct ValueType
{
private int total;
}
class Widget: Iprocess
{
public class NestedClass
{
private int value;
}
private string message;
private static Color defaultColor;
private const double PI = 3.14159;
protected readonly double monthlyAverage;
private long[] array1;
private Widget[,] array2;
private unsafe int *pCount;
private unsafe float **ppValues;
}
}
"F:Acme.ValueType.total"
"F:Acme.Widget.NestedClass.value"
"F:Acme.Widget.message"
"F:Acme.Widget.defaultColor"
"F:Acme.Widget.PI"
"F:Acme.Widget.monthlyAverage"
"F:Acme.Widget.array1"
"F:Acme.Widget.array2"
"F:Acme.Widget.pCount"
"F:Acme.Widget.ppValues"
• Constructors.
namespace Acme
{
class Widget: Iprocess
{
static Widget() { /* … */ }
public Widget() { /* … */ }
public Widget(string s) { /* … */ }
}
}
"M:Acme.Widget.#cctor"
"M:Acme.Widget.#ctor"
"M:Acme.Widget.#ctor(System.String)"
• Destructors.
namespace Acme
{
class Widget: Iprocess
{
~Widget() { /* … */ }
}
}
"M:Acme.Widget.Finalize"
• Methods.
namespace Acme
{
struct ValueType
{
public void M(int i) { /* … */ }
}
class Widget: IProcess
{
public class NestedClass
{
public void M(int i) { /* … */ }
}
public static void M0() { /* … */ }
public void M1(char c, out float f, ref ValueType v) { /* … */ }
public void M2(short[] x1, int[,] x2, long[][] x3) { /* … */ }
public void M3(long[][] x3, Widget[][,,] x4) { /* … */ }
public unsafe void M4(char *pc, Color **pf) { /* … */ }
public unsafe void M5(void *pv, double *[][,] pd) { /* … */ }
public void M6(int i, params object[] args) { /* … */ }
}
}
"M:Acme.ValueType.M(System.Int32)"
"M:Acme.Widget.NestedClass.M(System.Int32)"
"M:Acme.Widget.M0"
"M:Acme.Widget.M1(System.Char,System.Single@,Acme.ValueType@)"
"M:Acme.Widget.M2(System.Int16[],System.Int32[0:,0:],System.Int64[][])"
"M:Acme.Widget.M3(System.Int64[][],Acme.Widget[0:,0:,0:][])"
"M:Acme.Widget.M4(System.Char*,Color**)"
"M:Acme.Widget.M5(System.Void*,System.Double*[0:,0:][])"
"M:Acme.Widget.M6(System.Int32,System.Object[])"

• Properties and indexers.
namespace Acme
{
class Widget: Iprocess
{
public int Width {get { /* … */ } set { /* … */ }}
public int this[int i] {get { /* … */ } set { /* … */ }}
public int this[string s, int i] {get { /* … */ } set { /* … */ }}
}
}
"P:Acme.Widget.Width"
"P:Acme.Widget.Item(System.Int32)"
"P:Acme.Widget.Item(System.String,System.Int32)"
• Events
namespace Acme
{
class Widget: Iprocess
{
public event Del AnEvent;
}
}
"E:Acme.Widget.AnEvent"
• Unary operators.
namespace Acme
{
class Widget: Iprocess
{
public static Widget operator+(Widget x) { /* … */ }
}
}
"M:Acme.Widget.op_UnaryPlus(Acme.Widget)"
The complete set of unary operator function names used is as follows: op_UnaryPlus, , op_UnaryNegation, op_Negation, op_OnesComplement, , op_Increment, , op_Decrement, , op_True, and d op_False.
• Binary operators.
namespace Acme
{
class Widget: Iprocess
{
public static Widget operator+(Widget x1, Widget x2) { return x1; }
}
}
"M:Acme.Widget.op_Addition(Acme.Widget,Acme.Widget)"
The complete set of binary operator function names used is as follows: op_Addition, op_Subtraction, op_Multiply, op_Division, op_Modulus, op_BitwiseAnd, op_BitwiseOr, op_ExclusiveOr, op_LeftShift, op_RightShift, op_Equality, op_Inequality, op_LessThan, op_LessThanOrEqual, op_GreaterThan, and op_GreaterThanOrEqual.
• Conversion operators have a trailing '~' followed by the return type.
namespace Acme
{
class Widget: Iprocess
{
public static explicit operator int(Widget x) { /* … */ }
public static implicit operator long(Widget x) { /* … */ }
}
}
"M:Acme.Widget.op_Explicit(Acme.Widget)~System.Int32"
"M:Acme.Widget.op_Implicit(Acme.Widget)~System.Int64"
B.4 An example
B.4.1 C# source code
The following example shows the source code of a Point class:
namespace Graphics
{

/// Class Point models a point in a two-dimensional plane.
///
public class Point
{
///

Instance variable x represents the point's
/// x-coordinate.

private int x;
///

Instance variable y represents the point's
/// y-coordinate.

private int y;
/// Property X represents the point's x-coordinate.
public int X
{
get { return x; }
set { x = value; }
}
/// Property Y represents the point's y-coordinate.
public int Y
{
get { return y; }
set { y = value; }
}
///

This constructor initializes the new Point to
/// (0,0).

public Point() : this(0,0) {}
///

This constructor initializes the new Point to
/// (,).

/// xor is the new Point's x-coordinate.
/// yor is the new Point's y-coordinate.
public Point(int xor, int yor) {
X = xor;
Y = yor;
}
///

This method changes the point's location to
/// the given coordinates.

/// xor is the new x-coordinate.
/// yor is the new y-coordinate.
///
public void Move(int xor, int yor) {
X = xor;
Y = yor;
}
///

This method changes the point's location by
/// the given x- and y-offsets.
/// For example:
///
/// Point p = new Point(3,5);
/// p.Translate(-1,3);
///
/// results in p's having the value (2,8).
///
///

/// xor is the relative x-offset.
/// yor is the relative y-offset.
///
public void Translate(int xor, int yor) {
X += xor;
Y += yor;
}
///

This method determines whether two Points have the same
/// location.

/// o is the object to be compared to the current object.
///
/// True if the Points have the same location and they have
/// the exact same type; otherwise, false.
///
///
public override bool Equals(object o) {
if (o == null) {
return false;
}
if (this == o) {
return true;
}
if (GetType() == o.GetType()) {
Point p = (Point)o;
return (X == p.X) && (Y == p.Y);
}
return false;
}
///

Report a point's location as a string.

/// A string representing a point's location, in the form (x,y),
/// without any leading, training, or embedded whitespace.
public override string ToString() {
return "(" + X + "," + Y + ")";
}
///

This operator determines whether two Points have the same
/// location.

/// p1 is the first Point to be compared.
/// p2 is the second Point to be compared.
/// True if the Points have the same location and they have
/// the exact same type; otherwise, false.
///
///
public static bool operator==(Point p1, Point p2) {
if ((object)p1 == null || (object)p2 == null) {
return false;
}

if (p1.GetType() == p2.GetType()) {
return (p1.X == p2.X) && (p1.Y == p2.Y);
}

return false;
}
///

This operator determines whether two Points have the same
/// location.

/// p1 is the first Point to be compared.
/// p2 is the second Point to be compared.
/// True if the Points do not have the same location and the
/// exact same type; otherwise, false.
///
///
public static bool operator!=(Point p1, Point p2) {
return !(p1 == p2);
}
///

This is the entry point of the Point class testing
/// program.
/// This program tests each method and operator, and
/// is intended to be run after any non-trvial maintenance has
/// been performed on the Point class.

public static void Main() {
// class test code goes here
}
}
}
B.4.2 Resulting XML
Here is the output produced by one documentation generator when given the source code for class Point, shown above:



Point



Class Point models a point in a two-dimensional
plane.

Instance variable x represents the point's
x-coordinate.

Instance variable y represents the point's
y-coordinate.

This constructor initializes the new Point to
(0,0).

This constructor initializes the new Point to
(,).

xor is the new Point's x-coordinate.
yor is the new Point's y-coordinate.

This method changes the point's location to
the given coordinates.

xor is the new x-coordinate.
yor is the new y-coordinate.


name="M:Graphics.Point.Translate(System.Int32,System.Int32)">

This method changes the point's location by
the given x- and y-offsets.
For example:

Point p = new Point(3,5);
p.Translate(-1,3);

results in p's having the value (2,8).

xor is the relative x-offset.
yor is the relative y-offset.

This method determines whether two Points have the same
location.

o is the object to be compared to the current
object.

True if the Points have the same location and they have
the exact same type; otherwise, false.
cref="M:Graphics.Point.op_Equality(Graphics.Point,Graphics.Point)"/>
cref="M:Graphics.Point.op_Inequality(Graphics.Point,Graphics.Point)"/>

Report a point's location as a string.

A string representing a point's location, in the form
(x,y),
without any leading, training, or embedded whitespace.

name="M:Graphics.Point.op_Equality(Graphics.Point,Graphics.Point)">

This operator determines whether two Points have the
same
location.

p1 is the first Point to be compared.
p2 is the second Point to be compared.
True if the Points have the same location and they have
the exact same type; otherwise, false.

cref="M:Graphics.Point.op_Inequality(Graphics.Point,Graphics.Point)"/>

name="M:Graphics.Point.op_Inequality(Graphics.Point,Graphics.Point)">

This operator determines whether two Points have the
same
location.

p1 is the first Point to be compared.
p2 is the second Point to be compared.
True if the Points do not have the same location and
the
exact same type; otherwise, false.

cref="M:Graphics.Point.op_Equality(Graphics.Point,Graphics.Point)"/>

This is the entry point of the Point class testing
program.
This program tests each method and operator, and
is intended to be run after any non-trvial maintenance has
been performed on the Point class.

Property X represents the point's
x-coordinate.


Property Y represents the point's
y-coordinate.




C. Grammar
This appendix contains summaries of the lexical and syntactic grammars found in the main document, and of the grammar extensions for unsafe code. Grammar productions appear here in the same order that they appear in the main document.
C.1 Lexical grammar
input:
input-sectionopt
input-section:
input-section-part
input-section input-section-part
input-section-part:
input-elementsopt new-line
pp-directive
input-elements:
input-element
input-elements input-element
input-element:
whitespace
comment
token
C.1.1 Line terminators
new-line:
Carriage return character (U+000D)
Line feed character (U+000A)
Carriage return character (U+000D) followed by line feed character (U+000A)
Line separator character (U+2028)
Paragraph separator character (U+2029)
C.1.2 White space
whitespace:
Any character with Unicode class Zs
Horizontal tab character (U+0009)
Vertical tab character (U+000B)
Form feed character (U+000C)
C.1.3 Comments
comment:
single-line-comment
delimited-comment
single-line-comment:
// input-charactersopt
input-characters:
input-character
input-characters input-character
input-character:
Any Unicode character except a new-line-character
new-line-character:
Carriage return character (U+000D)
Line feed character (U+000A)
Line separator character (U+2028)
Paragraph separator character (U+2029)
delimited-comment:
/* delimited-comment-charactersopt */
delimited-comment-characters:
delimited-comment-character
delimited-comment-characters delimited-comment-character
delimited-comment-character:
not-asterisk
* not-slash
not-asterisk:
Any Unicode character except *
not-slash:
Any Unicode character except /
C.1.4 Tokens
token:
identifier
keyword
integer-literal
real-literal
character-literal
string-literal
operator-or-punctuator
C.1.5 Unicode character escape sequences
unicode-escape-sequence:
\u hex-digit hex-digit hex-digit hex-digit
\U hex-digit hex-digit hex-digit hex-digit hex-digit hex-digit hex-digit hex-digit
C.1.6 Identifiers
identifier:
available-identifier
@ identifier-or-keyword
available-identifier:
An identifier-or-keyword that is not a keyword
identifier-or-keyword:
identifier-start-character identifier-part-charactersopt
identifier-start-character:
letter-character
_ (the underscore character U+005F)
identifier-part-characters:
identifier-part-character
identifier-part-characters identifier-part-character
identifier-part-character:
letter-character
decimal-digit-character
connecting-character
combining-character
formatting-character
letter-character:
A Unicode character of classes Lu, Ll, Lt, Lm, Lo, or Nl
A unicode-escape-sequence representing a character of classes Lu, Ll, Lt, Lm, Lo, or Nl
combining-character:
A Unicode character of classes Mn or Mc
A unicode-escape-sequence representing a character of classes Mn or Mc
decimal-digit-character:
A Unicode character of the class Nd
A unicode-escape-sequence representing a character of the class Nd
connecting-character:
A Unicode character of the class Pc
A unicode-escape-sequence representing a character of the class Pc
formatting-character:
A Unicode character of the class Cf
A unicode-escape-sequence representing a character of the class Cf
C.1.7 Keywords
keyword: one of
abstract as base bool break
byte case catch char checked
class const continue decimal default
delegate do double else enum
event explicit extern false finally
fixed float for foreach goto
if implicit in int interface
internal is lock long namespace
new null object operator out
override params private protected public
readonly ref return sbyte sealed
short sizeof stackalloc static string
struct switch this throw true
try typeof uint ulong unchecked
unsafe ushort using virtual void
volatile while
C.1.8 Literals
literal:
boolean-literal
integer-literal
real-literal
character-literal
string-literal
null-literal
boolean-literal:
true
false
integer-literal:
decimal-integer-literal
hexadecimal-integer-literal
decimal-integer-literal:
decimal-digits integer-type-suffixopt
decimal-digits:
decimal-digit
decimal-digits decimal-digit
decimal-digit: one of
0 1 2 3 4 5 6 7 8 9
integer-type-suffix: one of
U u L l UL Ul uL ul LU Lu lU lu
hexadecimal-integer-literal:
0x hex-digits integer-type-suffixopt
0X hex-digits integer-type-suffixopt
hex-digits:
hex-digit
hex-digits hex-digit
hex-digit: one of
0 1 2 3 4 5 6 7 8 9 A B C D E F a b c d e f
real-literal:
decimal-digits . decimal-digits exponent-partopt real-type-suffixopt
. decimal-digits exponent-partopt real-type-suffixopt
decimal-digits exponent-part real-type-suffixopt
decimal-digits real-type-suffix
exponent-part:
e signopt decimal-digits
E signopt decimal-digits
sign: one of
+ -
real-type-suffix: one of
F f D d M m
character-literal:
' character '
character:
single-character
simple-escape-sequence
hexadecimal-escape-sequence
unicode-escape-sequence
single-character:
Any character except ' (U+0027), \ (U+005C), and new-line-character
simple-escape-sequence: one of
\' \" \\ \0 \a \b \f \n \r \t \v
hexadecimal-escape-sequence:
\x hex-digit hex-digitopt hex-digitopt hex-digitopt
string-literal:
regular-string-literal
verbatim-string-literal
regular-string-literal:
" regular-string-literal-charactersopt "
regular-string-literal-characters:
regular-string-literal-character
regular-string-literal-characters regular-string-literal-character
regular-string-literal-character:
single-regular-string-literal-character
simple-escape-sequence
hexadecimal-escape-sequence
unicode-escape-sequence
single-regular-string-literal-character:
Any character except " (U+0022), \ (U+005C), and new-line-character
verbatim-string-literal:
@" verbatim -string-literal-charactersopt "
verbatim-string-literal-characters:
verbatim-string-literal-character
verbatim-string-literal-characters verbatim-string-literal-character
verbatim-string-literal-character:
single-verbatim-string-literal-character
quote-escape-sequence
single-verbatim-string-literal-character:
any character except "
quote-escape-sequence:
""
null-literal:
null
C.1.9 Operators and punctuators
operator-or-punctuator: one of
{ } [ ] ( ) . , : ;
+ - * / % & | ^ ! ~
= < > ? ++ -- && || << >>
== != <= >= += -= *= /= %= &=
|= ^= <<= >>= ->
C.1.10 Pre-processing directives
pp-directive:
pp-declaration
pp-conditional
pp-line
pp-diagnostic
pp-region
pp-new-line:
whitespaceopt single-line-commentopt new-line
conditional-symbol:
Any identifier-or-keyword except true or false
pp-expression:
whitespaceopt pp-or-expression whitespaceopt
pp-or-expression:
pp-and-expression
pp-or-expression whitespaceopt || whitespaceopt pp-and-expression
pp-and-expression:
pp-equality-expression
pp-and-expression whitespaceopt && whitespaceopt pp-equality-expression
pp-equality-expression:
pp-unary-expression
pp-equality-expression whitespaceopt == whitespaceopt pp-unary-expression
pp-equality-expression whitespaceopt != whitespaceopt pp-unary-expression
pp-unary-expression:
pp-primary-expression
! whitespaceopt pp-unary-expression
pp-primary-expression:
true
false
conditional-symbol
( whitespaceopt pp-expression whitespaceopt )
pp-declaration:
whitespaceopt # whitespaceopt define whitespace conditional-symbol pp-new-line
whitespaceopt # whitespaceopt undef whitespace conditional-symbol pp-new-line
pp-conditional:
pp-if-section pp-elif-sectionsopt pp-else-sectionopt pp-endif
pp-if-section:
whitespaceopt # whitespaceopt if whitespace pp-expression pp-new-line conditional-sectionopt
pp-elif-sections:
pp-elif-section
pp-elif-sections pp-elif-section
pp-elif-section:
whitespaceopt # whitespaceopt elif whitespace pp-expression pp-new-line conditional-sectionopt
pp-else-section:
whitespaceopt # whitespaceopt else pp-new-line conditional-sectionopt
pp-endif-line:
whitespaceopt # whitespaceopt endif pp-new-line
conditional-section:
input-section
skipped-section
skipped-section:
skipped-section-part
skipped-section skipped-section-part
skipped-section-part:
skipped-charactersopt new-line
pp-directive
skipped-characters:
whitespaceopt not-number-sign input-charactersopt
not-number-sign:
Any input-character except #
pp-line:
whitespaceopt # whitespaceopt line whitespace line-indicator pp-new-line
line-indicator:
decimal-digitswhitespace file-name
decimal-digits
default
file-name:
" file-name-characters "
file-name-characters:
file-name-character
file-name-characters file-name-character
file-name-character:
Any input-character except "
pp-diagnostic:
whitespaceopt # whitespaceopt error pp-message
whitespaceopt # whitespaceopt warning pp-message
pp-message:
new-line
whitespace input-charactersopt new-line
pp-region:
pp-start-region conditional-sectionopt pp-end-region
pp-start-region:
whitespaceopt # whitespaceopt region pp-message
pp-end-region:
whitespaceopt # whitespaceopt endregion pp-message
C.2 Syntactic grammar
C.2.1 Basic concepts
namespace-name:
namespace-or-type-name
type-name:
namespace-or-type-name
namespace-or-type-name:
identifier
namespace-or-type-name . identifier
C.2.2 Types
type:
value-type
reference-type
value-type:
struct-type
enum-type
struct-type:
type-name
simple-type
simple-type:
numeric-type
bool
numeric-type:
integral-type
floating-point-type
decimal
integral-type:
sbyte
byte
short
ushort
int
uint
long
ulong
char
floating-point-type:
float
double
enum-type:
type-name
reference-type:
class-type
interface-type
array-type
delegate-type
class-type:
type-name
object
string
interface-type:
type-name
array-type:
non-array-type rank-specifiers
non-array-type:
type
rank-specifiers:
rank-specifier
rank-specifiers rank-specifier
rank-specifier:
[ dim-separatorsopt ]
dim-separators:
,
dim-separators ,
delegate-type:
type-name
C.2.3 Variables
variable-reference:
expression
C.2.4 Expressions
argument-list:
argument
argument-list , argument
argument:
expression
ref variable-reference
out variable-reference
primary-expression:
primary-no-array-creation-expression
array-creation-expression
primary-no-array-creation-expression:
literal
simple-name
parenthesized-expression
member-access
invocation-expression
element-access
this-access
base-access
post-increment-expression
post-decrement-expression
object-creation-expression
delegate-creation-expression
typeof-expression
sizeof-expression
checked-expression
unchecked-expression
simple-name:
identifier
parenthesized-expression:
( expression )
member-access:
primary-expression . identifier
predefined-type . identifier
predefined-type: one of
bool byte char decimal double float int long
object sbyte short string uint ulong ushort
invocation-expression:
primary-expression ( argument-listopt )
element-access:
primary-no-array-creation-expression [ expression-list ]
expression-list:
expression
expression-list , expression
this-access:
this
base-access:
base . identifier
base [ expression-list ]
post-increment-expression:
primary-expression ++
post-decrement-expression:
primary-expression --
object-creation-expression:
new type ( argument-listopt )
array-creation-expression:
new non-array-type [ expression-list ] rank-specifiersopt array-initializeropt
new array-type array-initializer
delegate-creation-expression:
new delegate-type ( expression )
typeof-expression:
typeof ( type )
typeof ( void )
checked-expression:
checked ( expression )
unchecked-expression:
unchecked ( expression )
unary-expression:
primary-expression
+ unary-expression
- unary-expression
! unary-expression
~ unary-expression
* unary-expression
pre-increment-expression
pre-decrement-expression
cast-expression
pre-increment-expression:
++ unary-expression
pre-decrement-expression:
-- unary-expression
cast-expression:
( type ) unary-expression
multiplicative-expression:
unary-expression
multiplicative-expression * unary-expression
multiplicative-expression / unary-expression
multiplicative-expression % unary-expression
additive-expression:
multiplicative-expression
additive-expression + multiplicative-expression
additive-expression – multiplicative-expression
shift-expression:
additive-expression
shift-expression << additive-expression
shift-expression >> additive-expression
relational-expression:
shift-expression
relational-expression < shift-expression
relational-expression > shift-expression
relational-expression <= shift-expression
relational-expression >= shift-expression
relational-expression is type
relational-expression as type
equality-expression:
relational-expression
equality-expression == relational-expression
equality-expression != relational-expression
and-expression:
equality-expression
and-expression & equality-expression
exclusive-or-expression:
and-expression
exclusive-or-expression ^ and-expression
inclusive-or-expression:
exclusive-or-expression
inclusive-or-expression | exclusive-or-expression
conditional-and-expression:
inclusive-or-expression
conditional-and-expression && inclusive-or-expression
conditional-or-expression:
conditional-and-expression
conditional-or-expression || conditional-and-expression
conditional-expression:
conditional-or-expression
conditional-or-expression ? expression : expression
assignment:
unary-expression assignment-operator expression
assignment-operator: one of
= += -= *= /= %= &= |= ^= <<= >>=
expression:
conditional-expression
assignment
constant-expression:
expression
boolean-expression:
expression
C.2.5 Statements
statement:
labeled-statement
declaration-statement
embedded-statement
embedded-statement:
block
empty-statement
expression-statement
selection-statement
iteration-statement
jump-statement
try-statement
checked-statement
unchecked-statement
lock-statement
using-statement
block:
{ statement-listopt }
statement-list:
statement
statement-list statement
empty-statement:
;
labeled-statement:
identifier : statement
declaration-statement:
local-variable-declaration ;
local-constant-declaration ;
local-variable-declaration:
type local-variable-declarators
local-variable-declarators:
local-variable-declarator
local-variable-declarators , local-variable-declarator
local-variable-declarator:
identifier
identifier = local-variable-initializer
local-variable-initializer:
expression
array-initializer
local-constant-declaration:
const type constant-declarators
constant-declarators:
constant-declarator
constant-declarators , constant-declarator
constant-declarator:
identifier = constant-expression
expression-statement:
statement-expression ;
statement-expression:
invocation-expression
object-creation-expression
assignment
post-increment-expression
post-decrement-expression
pre-increment-expression
pre-decrement-expression
selection-statement:
if-statement
switch-statement
if-statement:
if ( boolean-expression ) embedded-statement
if ( boolean-expression ) embedded-statement else embedded-statement
boolean-expression:
expression
switch-statement:
switch ( expression ) switch-block
switch-block:
{ switch-sectionsopt }
switch-sections:
switch-section
switch-sections switch-section
switch-section:
switch-labels statement-list
switch-labels:
switch-label
switch-labels switch-label
switch-label:
case constant-expression :
default :
iteration-statement:
while-statement
do-statement
for-statement
foreach-statement
while-statement:
while ( boolean-expression ) embedded-statement
do-statement:
do embedded-statement while ( boolean-expression ) ;
for-statement:
for ( for-initializeropt ; for-conditionopt ; for-iteratoropt ) embedded-statement
for-initializer:
local-variable-declaration
statement-expression-list
for-condition:
boolean-expression
for-iterator:
statement-expression-list
statement-expression-list:
statement-expression
statement-expression-list , statement-expression
foreach-statement:
foreach ( type identifier in expression ) embedded-statement
jump-statement:
break-statement
continue-statement
goto-statement
return-statement
throw-statement
break-statement:
break ;
continue-statement:
continue ;
goto-statement:
goto identifier ;
goto case constant-expression ;
goto default ;
return-statement:
return expressionopt ;
throw-statement:
throw expressionopt ;
try-statement:
try block catch-clauses
try block finally-clause
try block catch-clauses finally-clause
catch-clauses:
specific-catch-clauses general-catch-clauseopt
specific-catch-clausesopt general-catch-clause
specific-catch-clauses:
specific-catch-clause
specific-catch-clauses specific-catch-clause
specific-catch-clause:
catch ( class-type identifieropt ) block
general-catch-clause:
catch block
finally-clause:
finally block
checked-statement:
checked block
unchecked-statement:
unchecked block
lock-statement:
lock ( expression ) embedded-statement
using-statement:
using ( resource-acquisition ) embedded-statement
resource-acquisition:
local-variable-declaration
expression
17.5.3 Namespaces
compilation-unit:
using-directivesopt global-attributesopt namespace-member-declarationsopt
namespace-declaration:
namespace qualified-identifier namespace-body ;opt
qualified-identifier:
identifier
qualified-identifier . identifier
namespace-body:
{ using-directivesopt namespace-member-declarationsopt }
using-directives:
using-directive
using-directives using-directive
using-directive:
using-alias-directive
using-namespace-directive
using-alias-directive:
using identifier = namespace-or-type-name ;
using-namespace-directive:
using namespace-name ;
namespace-member-declarations:
namespace-member-declaration
namespace-member-declarations namespace-member-declaration
namespace-member-declaration:
namespace-declaration
type-declaration
type-declaration:
class-declaration
struct-declaration
interface-declaration
enum-declaration
delegate-declaration
C.2.6 Classes
class-declaration:
attributesopt class-modifiersopt class identifier class-baseopt class-body ;opt
class-modifiers:
class-modifier
class-modifiers class-modifier
class-modifier:
new
public
protected
internal
private
abstract
sealed
class-base:
: class-type
: interface-type-list
: class-type , interface-type-list
interface-type-list:
interface-type
interface-type-list , interface-type
class-body:
{ class-member-declarationsopt }
class-member-declarations:
class-member-declaration
class-member-declarations class-member-declaration
class-member-declaration:
constant-declaration
field-declaration
method-declaration
property-declaration
event-declaration
indexer-declaration
operator-declaration
constructor-declaration
destructor-declaration
static-constructor-declaration
type-declaration
constant-declaration:
attributesopt constant-modifiersopt const type constant-declarators ;
constant-modifiers:
constant-modifier
constant-modifiers constant-modifier
constant-modifier:
new
public
protected
internal
private
constant-declarators:
constant-declarator
constant-declarators , constant-declarator
constant-declarator:
identifier = constant-expression
field-declaration:
attributesopt field-modifiersopt type variable-declarators ;
field-modifiers:
field-modifier
field-modifiers field-modifier
field-modifier:
new
public
protected
internal
private
static
readonly
volatile
variable-declarators:
variable-declarator
variable-declarators , variable-declarator
variable-declarator:
identifier
identifier = variable-initializer
variable-initializer:
expression
array-initializer
method-declaration:
method-header method-body
method-header:
attributesopt method-modifiersopt return-type member-name ( formal-parameter-listopt )
method-modifiers:
method-modifier
method-modifiers method-modifier
method-modifier:
new
public
protected
internal
private
static
virtual
sealed
override
abstract
extern
return-type:
type
void
member-name:
identifier
interface-type . identifier
method-body:
block
;
formal-parameter-list:
fixed-parameters
fixed-parameters , parameter-array
parameter-array
fixed-parameters:
fixed-parameter
fixed-parameters , fixed-parameter
fixed-parameter:
attributesopt parameter-modifieropt type identifier
parameter-modifier:
ref
out
parameter-array:
attributesopt params array-type identifier
property-declaration:
attributesopt property-modifiersopt type member-name { accessor-declarations }
property-modifiers:
property-modifier
property-modifiers property-modifier
property-modifier:
new
public
protected
internal
private
static
virtual
sealed
override
abstract
extern
member-name:
identifier
interface-type . identifier
accessor-declarations:
get-accessor-declaration set-accessor-declarationopt
set-accessor-declaration get-accessor-declarationopt
get-accessor-declaration:
attributesopt get accessor-body
set-accessor-declaration:
attributesopt set accessor-body
accessor-body:
block
;
event-declaration:
attributesopt event-modifiersopt event type variable-declarators ;
attributesopt event-modifiersopt event type member-name { event-accessor-declarations }
event-modifiers:
event-modifier
event-modifiers event-modifier
event-modifier:
new
public
protected
internal
private
static
virtual
sealed
override
abstract
extern
event-accessor-declarations:
add-accessor-declaration remove-accessor-declaration
remove-accessor-declaration add-accessor-declaration
add-accessor-declaration:
attributesopt add block
remove-accessor-declaration:
attributesopt remove block
indexer-declaration:
attributesopt indexer-modifiersopt indexer-declarator { accessor-declarations }
indexer-modifiers:
indexer-modifier
indexer-modifiers indexer-modifier
indexer-modifier:
new
public
protected
internal
private
virtual
sealed
override
abstract
extern
indexer-declarator:
type this [ formal-parameter-list ]
type interface-type . this [ formal-parameter-list ]
operator-declaration:
attributesopt operator-modifiers operator-declarator operator-body
operator-modifiers:
operator-modifier
operator-modifiers operator-modifier
operator-modifier:
public
static
extern
operator-declarator:
unary-operator-declarator
binary-operator-declarator
conversion-operator-declarator
unary-operator-declarator:
type operator overloadable-unary-operator ( type identifier )
overloadable-unary-operator: one of
+ - ! ~ ++ -- true false
binary-operator-declarator:
type operator overloadable-binary-operator ( type identifier , type identifier )
overloadable-binary-operator: one of
+ - * / % & | ^ << >> == != > < >= <=
conversion-operator-declarator:
implicit operator type ( type identifier )
explicit operator type ( type identifier )
operator-body:
block
;
constructor-declaration:
attributesopt constructor-modifiersopt constructor-declarator constructor-body
constructor-modifiers:
constructor-modifier
constructor-modifiers constructor-modifier
constructor-modifier:
public
protected
internal
private
extern
constructor-declarator:
identifier ( formal-parameter-listopt ) constructor-initializeropt
constructor-initializer:
: base ( argument-listopt )
: this ( argument-listopt )
constructor-body:
block
;
static-constructor-declaration:
attributesopt static-constructor-modifiers identifier ( ) static-constructor-body
static-constructor-body:
block
;
static-constructor-modifiers:
externopt static
static externopt
destructor-declaration:
attributesopt externopt ~ identifier ( ) destructor-body
destructor-body:
block
;
C.2.7 Structs
struct-declaration:
attributesopt struct-modifiersopt struct identifier struct-interfacesopt struct-body ;opt
struct-modifiers:
struct-modifier
struct-modifiers struct-modifier
struct-modifier:
new
public
protected
internal
private
struct-interfaces:
: interface-type-list
struct-body:
{ struct-member-declarationsopt }
struct-member-declarations:
struct-member-declaration
struct-member-declarations struct-member-declaration
struct-member-declaration:
constant-declaration
field-declaration
method-declaration
property-declaration
event-declaration
indexer-declaration
operator-declaration
constructor-declaration
static-constructor-declaration
type-declaration
C.2.8 Arrays
array-type:
non-array-type rank-specifiers
non-array-type:
type
rank-specifiers:
rank-specifier
rank-specifiers rank-specifier
rank-specifier:
[ dim-separatorsopt ]
dim-separators:
,
dim-separators ,
array-initializer:
{ variable-initializer-listopt }
{ variable-initializer-list , }
variable-initializer-list:
variable-initializer
variable-initializer-list , variable-initializer
variable-initializer:
expression
array-initializer
C.2.9 Interfaces
interface-declaration:
attributesopt interface-modifiersopt interface identifier interface-baseopt interface-body ;opt
interface-modifiers:
interface-modifier
interface-modifiers interface-modifier
interface-modifier:
new
public
protected
internal
private
interface-base:
: interface-type-list
interface-body:
{ interface-member-declarationsopt }
interface-member-declarations:
interface-member-declaration
interface-member-declarations interface-member-declaration
interface-member-declaration:
interface-method-declaration
interface-property-declaration
interface-event-declaration
interface-indexer-declaration
interface-method-declaration:
attributesopt newopt return-type identifier ( formal-parameter-listopt ) ;
interface-property-declaration:
attributesopt newopt type identifier { interface-accessors }
interface-accessors:
attributesopt get ;
attributesopt set ;
attributesopt get ; attributesopt set ;
attributesopt set ; attributesopt get ;
interface-event-declaration:
attributesopt newopt event type identifier ;
interface-indexer-declaration:
attributesopt newopt type this [ formal-parameter-list ] { interface-accessors }
C.2.10 Enums
enum-declaration:
attributesopt enum-modifiersopt enum identifier enum-baseopt enum-body ;opt
enum-base:
: integral-type
enum-body:
{ enum-member-declarationsopt }
{ enum-member-declarations , }
enum-modifiers:
enum-modifier
enum-modifiers enum-modifier
enum-modifier:
new
public
protected
internal
private
enum-member-declarations:
enum-member-declaration
enum-member-declarations , enum-member-declaration
enum-member-declaration:
attributesopt identifier
attributesopt identifier = constant-expression
C.2.11 Delegates
delegate-declaration:
attributesopt delegate-modifiersopt delegate return-type identifier ( formal-parameter-listopt ) ;
delegate-modifiers:
delegate-modifier
delegate-modifiers delegate-modifier
delegate-modifier:
new
public
protected
internal
private
C.2.12 Attributes
global-attributes:
global-attribute-sections
global-attribute-sections:
global-attribute-section
global-attribute-sections global-attribute-section
global-attribute-section:
[ global-attribute-target-specifier attribute-list ]
[ global-attribute-target-specifier attribute-list ,]
global-attribute-target-specifier:
global-attribute-target :
global-attribute-target:
assembly
module
attributes:
attribute-sections
attribute-sections:
attribute-section
attribute-sections attribute-section
attribute-section:
[ attribute-target-specifieropt attribute-list ]
[ attribute-target-specifieropt attribute-list , ]
attribute-target-specifier:
attribute-target :
attribute-target:
field
event
method
param
property
return
type
attribute-list:
attribute
attribute-list , attribute
attribute:
attribute-name attribute-argumentsopt
attribute-name:
type-name
attribute-arguments:
( positional-argument-listopt )
( positional-argument-list , named-argument-list )
( named-argument-list )
positional-argument-list:
positional-argument
positional-argument-list , positional-argument
positional-argument:
attribute-argument-expression
named-argument-list:
named-argument
named-argument-list , named-argument
named-argument:
identifier = attribute-argument-expression
attribute-argument-expression:
expression
C.3 Grammar extensions for unsafe code
C.3.1 Unsafe contexts
class-modifier:
...
unsafe
struct-modifier:
...
unsafe
interface-modifier:
...
unsafe
delegate-modifier:
...
unsafe
field-modifier:
...
unsafe
method-modifier:
...
unsafe
property-modifier:
...
unsafe
event-modifier:
...
unsafe
indexer-modifier:
...
unsafe
operator-modifier:
...
unsafe
constructor-modifier:
...
unsafe
destructor-declaration:
attributesopt externopt unsafeopt ~ identifier ( ) destructor-body
attributesopt unsafeopt externopt ~ identifier ( ) destructor-body
static-constructor-modifiers:
unsafeopt externopt static
unsafeopt static externopt
externopt unsafeopt static
static unsafeopt externopt
externopt static unsafeopt
static externopt unsafeopt
embedded-statement:
...
unsafe-statement
unsafe-statement:
unsafe block
C.3.1.1 Pointer types
type:
value-type
reference-type
pointer-type
pointer-type:
unmanaged-type *
void *
unmanaged-type:
type
C.3.1.2 Pointers in expressions
primary-no-array-creation-expression:
...
pointer-member-access
pointer-element-access
sizeof-expression
unary-expression:
...
pointer-indirection-expression
addressof-expression
C.3.1.3 Pointer indirection
pointer-indirection-expression:
* unary-expression
C.3.1.4 Pointer member access
pointer-member-access:
primary-expression -> identifier
pointer-element-access:
primary-no-array-creation-expression [ expression ]
C.3.1.5 The address-of operator
addressof-expression:
& unary-expression
C.3.1.6 The sizeof operator
sizeof-expression:
sizeof ( unmanaged-type )
C.3.1.7 The fixed statement
embedded-statement:
...
fixed-statement
fixed-statement:
fixed ( pointer-type fixed-pointer-declarators ) embedded-statement
fixed-pointer-declarators:
fixed-pointer-declarator
fixed-pointer-declarators , fixed-pointer-declarator
fixed-pointer-declarator:
identifier = fixed-pointer-initializer
fixed-pointer-initializer:
& variable-reference
expression
C.3.1.8 Stack allocation
local-variable-initializer:
expression
array-initializer
stackalloc-initializer
stackalloc-initializer:
stackalloc unmanaged-type [ expression ]

D. References
Unicode Consortium. The Unicode Standard, Version 3.0. Addison-Wesley, Reading, Massachusetts, 2000, ISBN 0-201-616335-5.
IEEE. IEEE Standard for Binary Floating-Point Arithmetic. ANSI/IEEE Standard 754-1985. Available from http://www.ieee.org.
ISO/IEC. C++. ANSI/ISO/IEC 14882:1998.