C# (pronounced "See Sharp") is a simple, modern, object-oriented, and type-safe programming language. C# has its roots in the C family of languages and will be immediately familiar to C, C++, and Java programmers. C# is standardized by ECMA International as the ECMA-334 standard and by ISO/IEC as the ISO/IEC 23270 standard. Microsoft's C# compiler for the .NET Framework is a conforming implementation of both of these standards.
C# is an object-oriented language, but C# further includes support for component-oriented programming. Contemporary software design increasingly relies on software components in the form of self-contained and self-describing packages of functionality. Key to such components is that they present a programming model with properties, methods, and events; they have attributes that provide declarative information about the component; and they incorporate their own documentation. C# provides language constructs to directly support these concepts, making C# a very natural language in which to create and use software components.
Several C# features aid in the construction of robust and durable applications: Garbage collection automatically reclaims memory occupied by unused objects; exception handling provides a structured and extensible approach to error detection and recovery; and the type-safe design of the language makes it impossible to read from uninitialized variables, to index arrays beyond their bounds, or to perform unchecked type casts.
C# has a unified type system. All C# types, including primitive types such as int
and double
, inherit from a single root object
type. Thus, all types share a set of common operations, and values of any type can be stored, transported, and operated upon in a consistent manner. Furthermore, C# supports both user-defined reference types and value types, allowing dynamic allocation of objects as well as in-line storage of lightweight structures.
To ensure that C# programs and libraries can evolve over time in a compatible manner, much emphasis has been placed on versioning in C#'s design. Many programming languages pay little attention to this issue, and, as a result, programs written in those languages break more often than necessary when newer versions of dependent libraries are introduced. Aspects of C#'s design that were directly influenced by versioning considerations include the separate virtual
and override
modifiers, the rules for method overload resolution, and support for explicit interface member declarations.
The rest of this chapter describes the essential features of the C# language. Although 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.
The "Hello, World" program is traditionally used to introduce a programming language. Here it is in C#:
using System;
class Hello
{
static void Main() {
Console.WriteLine("Hello, World");
}
}
C# source files typically have the file extension .cs
. Assuming that the "Hello, World" program is stored in the file hello.cs
, the program can be compiled with the Microsoft C# compiler using the command line
csc hello.cs
which produces an executable assembly named hello.exe
. The output produced by this application when it is run is
Hello, World
The "Hello, World" program starts with a using
directive that references the System
namespace. Namespaces provide a hierarchical means of organizing C# programs and libraries. Namespaces contain types and other namespaces—for example, the System
namespace contains a number of types, such as the Console
class referenced in the program, and a number of other namespaces, such as IO
and Collections
. A using
directive that references a given namespace enables unqualified use of the types that are members of that namespace. Because of the using
directive, the program can use Console.WriteLine
as shorthand for System.Console.WriteLine
.
The Hello
class declared by the "Hello, World" program has a single member, the method named Main
. The Main
method is declared with the static
modifier. While instance methods can reference a particular enclosing object instance using the keyword this
, static methods operate without reference to a particular object. By convention, a static method named Main
serves as the entry point of a program.
The output of the program is produced by the WriteLine
method of the Console
class in the System
namespace. This class is provided by the .NET Framework class libraries, which, by default, are automatically referenced by the Microsoft C# compiler. Note that C# itself does not have a separate runtime library. Instead, the .NET Framework is the runtime library of C#.
The key organizational concepts in C# are programs, namespaces, types, members, and assemblies. C# programs consist of one or more source files. Programs declare types, which contain members and can be organized into namespaces. Classes and interfaces are examples of types. Fields, methods, properties, and events are examples of members. When C# programs are compiled, they are physically packaged into assemblies. Assemblies typically have the file extension .exe
or .dll
, depending on whether they implement applications or libraries.
The example
using System;
namespace Acme.Collections
{
public class Stack
{
Entry top;
public void Push(object data) {
top = new Entry(top, data);
}
public object Pop() {
if (top == null) throw new InvalidOperationException();
object result = top.data;
top = top.next;
return result;
}
class Entry
{
public Entry next;
public object data;
public Entry(Entry next, object data) {
this.next = next;
this.data = data;
}
}
}
}
declares a class named Stack
in a namespace called Acme.Collections
. The fully qualified name of this class is Acme.Collections.Stack
. The class contains several members: a field named top
, two methods named Push
and Pop
, and a nested class named Entry
. The Entry
class further contains three members: a field named next
, a field named data
, and a constructor. Assuming that the source code of the example is stored in the file acme.cs
, the command line
csc /t:library acme.cs
compiles the example as a library (code without a Main
entry point) and produces an assembly named acme.dll
.
Assemblies contain executable code in the form of Intermediate Language (IL) instructions, and symbolic information in the form of metadata. Before it is executed, the IL code in an assembly is automatically converted to processor-specific code by the Just-In-Time (JIT) compiler of .NET Common Language Runtime.
Because an assembly is a self-describing unit of functionality containing both code and metadata, there is no need for #include
directives and header files in C#. The public types and members contained in a particular assembly are made available in a C# program simply by referencing that assembly when compiling the program. For example, this program uses the Acme.Collections.Stack
class from the acme.dll
assembly:
using System;
using Acme.Collections;
class Test
{
static void Main() {
Stack s = new Stack();
s.Push(1);
s.Push(10);
s.Push(100);
Console.WriteLine(s.Pop());
Console.WriteLine(s.Pop());
Console.WriteLine(s.Pop());
}
}
If the program is stored in the file test.cs
, when test.cs
is compiled, the acme.dll
assembly can be referenced using the compiler's /r
option:
csc /r:acme.dll test.cs
This creates an executable assembly named test.exe
, which, when run, produces the output:
100
10
1
C# permits the source text of a program to be stored in several source files. When a multi-file C# program is compiled, all of the source files are processed together, and the source files can freely reference each other—conceptually, it is as if all the source files were concatenated into one large file before being processed. Forward declarations are never needed in C# because, with very few exceptions, declaration order is insignificant. C# does not limit a source file to declaring only one public type nor does it require the name of the source file to match a type declared in the source file.
There are two kinds of types in C#: value types and reference types. Variables of value types directly contain their data whereas variables of 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 (except in the case of ref
and out
parameter variables).
C#'s value types are further divided into simple types, enum types, struct types, and nullable types, and C#'s reference types are further divided into class types, interface types, array types, and delegate types.
The following table provides an overview of C#'s type system.
Category | Description | |
---|---|---|
Value types | Simple types | Signed integral: sbyte , short , int , long |
Unsigned integral: byte , ushort , uint , ulong |
||
Unicode characters: char |
||
IEEE floating point: float , double |
||
High-precision decimal: decimal |
||
Boolean: bool |
||
Enum types | User-defined types of the form enum E {...} |
|
Struct types | User-defined types of the form struct S {...} |
|
Nullable types | Extensions of all other value types with a null value |
|
Reference types | Class types | Ultimate base class of all other types: object |
Unicode strings: string |
||
User-defined types of the form class C {...} |
||
Interface types | User-defined types of the form interface I {...} |
|
Array types | Single- and multi-dimensional, for example, int[] and int[,] |
|
Delegate types | User-defined types of the form e.g. delegate int D(...) |
The eight integral types provide support for 8-bit, 16-bit, 32-bit, and 64-bit values in signed or unsigned form.
The two floating point types, float
and double
, are represented using the 32-bit single-precision and 64-bit double-precision IEEE 754 formats.
The decimal
type is a 128-bit data type suitable for financial and monetary calculations.
C#'s bool
type is used to represent boolean values—values that are either true
or false
.
Character and string processing in C# uses Unicode encoding. The char
type represents a UTF-16 code unit, and the string
type represents a sequence of UTF-16 code units.
The following table summarizes C#'s numeric types.
Category | Bits | Type | Range/Precision |
---|---|---|---|
Signed integral | 8 | sbyte |
-128...127 |
16 | short |
-32,768...32,767 | |
32 | int |
-2,147,483,648...2,147,483,647 | |
64 | long |
-9,223,372,036,854,775,808...9,223,372,036,854,775,807 | |
Unsigned integral | 8 | byte |
0...255 |
16 | ushort |
0...65,535 | |
32 | uint |
0...4,294,967,295 | |
64 | ulong |
0...18,446,744,073,709,551,615 | |
Floating point | 32 | float |
1.5 × 10^−45 to 3.4 × 10^38, 7-digit precision |
64 | double |
5.0 × 10^−324 to 1.7 × 10^308, 15-digit precision | |
Decimal | 128 | decimal |
1.0 × 10^−28 to 7.9 × 10^28, 28-digit precision |
C# programs use type declarations to create new types. A type declaration specifies the name and the members of the new type. Five of C#'s categories of types are user-definable: class types, struct types, interface types, enum types, and delegate types.
A class type defines a data structure that contains data members (fields) and function members (methods, properties, and others). Class types support single inheritance and polymorphism, mechanisms whereby derived classes can extend and specialize base classes.
A struct type is similar to a class type in that it represents a structure with data members and function members. However, unlike classes, structs are value types and do not require heap allocation. Struct types do not support user-specified inheritance, and all struct types implicitly inherit from type object
.
An interface type defines a contract as a named set of public function members. A class or struct that implements an interface must provide implementations of the interface's function members. An interface may inherit from multiple base interfaces, and a class or struct may implement multiple interfaces.
A delegate type represents references to methods with a particular parameter list and return type. Delegates make it possible to treat methods as entities that can be assigned to variables and passed as parameters. Delegates are similar to the concept of function pointers found in some other languages, but unlike function pointers, delegates are object-oriented and type-safe.
Class, struct, interface and delegate types all support generics, whereby they can be parameterized with other types.
An enum type is a distinct type with named constants. Every enum type has an underlying type, which must be one of the eight integral types. The set of values of an enum type is the same as the set of values of the underlying type.
C# supports single- and multi-dimensional arrays of any type. Unlike the types listed above, array types do not have to be declared before they can be used. Instead, array types are constructed by following a type name with square brackets. For example, int[]
is a single-dimensional array of int
, int[,]
is a two-dimensional array of int
, and int[][]
is a single-dimensional array of single-dimensional arrays of int
.
Nullable types also do not have to be declared before they can be used. For each non-nullable value type T
there is a corresponding nullable type T?
, which can hold an additional value null
. For instance, int?
is a type that can hold any 32 bit integer or the value null
.
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. In the following example, an int
value is converted to object
and back again to int
.
using System;
class Test
{
static void Main() {
int i = 123;
object o = i; // Boxing
int j = (int)o; // Unboxing
}
}
When a value of a value type is converted to type object
, an object instance, also called a "box," is allocated to hold the value, and the value is copied into that box. Conversely, when an object
reference is cast to a value type, a check is made that the referenced object is a box of the correct value type, and, if the check succeeds, the value in the box is copied out.
C#'s unified type system effectively means that value types can become objects "on demand." Because of the unification, general-purpose libraries that use type object
can be used with both reference types and value types.
There are several kinds of variables in C#, including fields, array elements, local variables, and parameters. Variables represent storage locations, and every variable has a type that determines what values can be stored in the variable, as shown by the following table.
Type of Variable | Possible Contents |
---|---|
Non-nullable value type | A value of that exact type |
Nullable value type | A null value or a value of that exact type |
object |
A null reference, a reference to an object of any reference type, or a reference to a boxed value of any value type |
Class type | A null reference, a reference to an instance of that class type, or a reference to an instance of a class derived from that class type |
Interface type | A null reference, a reference to an instance of a class type that implements that interface type, or a reference to a boxed value of a value type that implements that interface type |
Array type | A null reference, a reference to an instance of that array type, or a reference to an instance of a compatible array type |
Delegate type | A null reference or a reference to an instance of that delegate type |
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.
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.
Most 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.
The following table summarizes C#'s operators, listing the operator categories in order of precedence from highest to lowest. Operators in the same category have equal precedence.
Category | Expression | Description |
---|---|---|
Primary | x.m |
Member access |
x(...) |
Method and delegate invocation | |
x[...] |
Array and indexer access | |
x++ |
Post-increment | |
x-- |
Post-decrement | |
new T(...) |
Object and delegate creation | |
new T(...){...} |
Object creation with initializer | |
new {...} |
Anonymous object initializer | |
new T[...] |
Array creation | |
typeof(T) |
Obtain System.Type object for T |
|
checked(x) |
Evaluate expression in checked context | |
unchecked(x) |
Evaluate expression in unchecked context | |
default(T) |
Obtain default value of type T |
|
delegate {...} |
Anonymous function (anonymous method) | |
Unary | +x |
Identity |
-x |
Negation | |
!x |
Logical negation | |
~x |
Bitwise negation | |
++x |
Pre-increment | |
--x |
Pre-decrement | |
(T)x |
Explicitly convert x to type T |
|
await x |
Asynchronously wait for x to complete |
|
Multiplicative | x * y |
Multiplication |
x / y |
Division | |
x % y |
Remainder | |
Additive | x + y |
Addition, string concatenation, delegate combination |
x - y |
Subtraction, delegate removal | |
Shift | x << y |
Shift left |
x >> y |
Shift right | |
Relational and type testing | x < y |
Less than |
x > y |
Greater than | |
x <= y |
Less than or equal | |
x >= y |
Greater than or equal | |
x is T |
Return true if x is a T , false otherwise |
|
x as T |
Return x typed as T , or null if x is not a T |
|
Equality | x == y |
Equal |
x != y |
Not equal | |
Logical AND | x & y |
Integer bitwise AND, boolean logical AND |
Logical XOR | x ^ y |
Integer bitwise XOR, boolean logical XOR |
Logical OR | `x | y` |
Conditional AND | x && y |
Evaluates y only if x is true |
Conditional OR | `x | |
Null coalescing | X ?? y |
Evaluates to y if x is null , to x otherwise |
Conditional | x ? y : z |
Evaluates y if x is true , z if x is false |
Assignment or anonymous function | x = y |
Assignment |
x op= y |
Compound assignment; supported operators are *= /= %= += -= <<= >>= &= ^= ` |
|
(T x) => y |
Anonymous function (lambda expression) |
The actions of a program are expressed using statements. C# supports several different kinds of statements, a number of which are defined in terms of embedded statements.
A block permits multiple statements to be written in contexts where a single statement is allowed. A block consists of a list of statements written between the delimiters {
and }
.
Declaration statements are used to declare local variables and constants.
Expression statements are used to evaluate expressions. Expressions that can be used as statements include method invocations, object allocations using the new
operator, assignments using =
and the compound assignment operators, increment and decrement operations using the ++
and --
operators and await expressions.
Selection statements are used to select one of a number of possible statements for execution based on the value of some expression. In this group are the if
and switch
statements.
Iteration statements are used to repeatedly execute an embedded statement. In this group are the while
, do
, for
, and foreach
statements.
Jump statements are used to transfer control. In this group are the break
, continue
, goto
, throw
, return
, and yield
statements.
The try
...catch
statement is used to catch exceptions that occur during execution of a block, and the try
...finally
statement is used to specify finalization code that is always executed, whether an exception occurred or not.
The checked
and unchecked
statements are used to control the overflow checking context for integral-type arithmetic operations and conversions.
The lock
statement is used to obtain the mutual-exclusion lock for a given object, execute a statement, and then release the lock.
The using
statement is used to obtain a resource, execute a statement, and then dispose of that resource.
Below are examples of each kind of statement
Local variable declarations
static void Main() {
int a;
int b = 2, c = 3;
a = 1;
Console.WriteLine(a + b + c);
}
Local constant declaration
static void Main() {
const float pi = 3.1415927f;
const int r = 25;
Console.WriteLine(pi * r * r);
}
Expression statement
static void Main() {
int i;
i = 123; // Expression statement
Console.WriteLine(i); // Expression statement
i++; // Expression statement
Console.WriteLine(i); // Expression statement
}
if
statement
static void Main(string[] args) {
if (args.Length == 0) {
Console.WriteLine("No arguments");
}
else {
Console.WriteLine("One or more arguments");
}
}
switch
statement
static void Main(string[] args) {
int n = args.Length;
switch (n) {
case 0:
Console.WriteLine("No arguments");
break;
case 1:
Console.WriteLine("One argument");
break;
default:
Console.WriteLine("{0} arguments", n);
break;
}
}
while
statement
static void Main(string[] args) {
int i = 0;
while (i < args.Length) {
Console.WriteLine(args[i]);
i++;
}
}
do
statement
static void Main() {
string s;
do {
s = Console.ReadLine();
if (s != null) Console.WriteLine(s);
} while (s != null);
}
for
statement
static void Main(string[] args) {
for (int i = 0; i < args.Length; i++) {
Console.WriteLine(args[i]);
}
}
foreach
statement
static void Main(string[] args) {
foreach (string s in args) {
Console.WriteLine(s);
}
}
break
statement
static void Main() {
while (true) {
string s = Console.ReadLine();
if (s == null) break;
Console.WriteLine(s);
}
}
continue
statement
static void Main(string[] args) {
for (int i = 0; i < args.Length; i++) {
if (args[i].StartsWith("/")) continue;
Console.WriteLine(args[i]);
}
}
goto
statement
static void Main(string[] args) {
int i = 0;
goto check;
loop:
Console.WriteLine(args[i++]);
check:
if (i < args.Length) goto loop;
}
return
statement
static int Add(int a, int b) {
return a + b;
}
static void Main() {
Console.WriteLine(Add(1, 2));
return;
}
yield
statement
static IEnumerable<int> Range(int from, int to) {
for (int i = from; i < to; i++) {
yield return i;
}
yield break;
}
static void Main() {
foreach (int x in Range(-10,10)) {
Console.WriteLine(x);
}
}
throw
and try
statements
static double Divide(double x, double y) {
if (y == 0) throw new DivideByZeroException();
return x / y;
}
static void Main(string[] args) {
try {
if (args.Length != 2) {
throw new Exception("Two numbers required");
}
double x = double.Parse(args[0]);
double y = double.Parse(args[1]);
Console.WriteLine(Divide(x, y));
}
catch (Exception e) {
Console.WriteLine(e.Message);
}
finally {
Console.WriteLine("Good bye!");
}
}
checked
and unchecked
statements
static void Main() {
int i = int.MaxValue;
checked {
Console.WriteLine(i + 1); // Exception
}
unchecked {
Console.WriteLine(i + 1); // Overflow
}
}
lock
statement
class Account
{
decimal balance;
public void Withdraw(decimal amount) {
lock (this) {
if (amount > balance) {
throw new Exception("Insufficient funds");
}
balance -= amount;
}
}
}
using
statement
static void Main() {
using (TextWriter w = File.CreateText("test.txt")) {
w.WriteLine("Line one");
w.WriteLine("Line two");
w.WriteLine("Line three");
}
}
Classes are the most fundamental of C#'s types. A class is a data structure that combines state (fields) and actions (methods and other function members) in a single unit. A class provides a definition for dynamically created instances of the class, also known as objects. Classes support inheritance and polymorphism, mechanisms whereby derived classes can extend and specialize base classes.
New classes are created using class declarations. A class declaration starts with a header that specifies the attributes and modifiers of the class, the name of the class, the base class (if given), and the interfaces implemented by the class. The header is followed by the class body, which consists of a list of member declarations written between the delimiters {
and }
.
The following is a declaration of a simple class named Point
:
public class Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
Instances of classes are created using the new
operator, which allocates memory for a new instance, invokes a constructor to initialize the instance, and returns a reference to the instance. The following statements create two Point
objects and store references to those objects in two variables:
Point p1 = new Point(0, 0);
Point p2 = new Point(10, 20);
The memory occupied by an object is automatically reclaimed when the object is no longer in use. It is neither necessary nor possible to explicitly deallocate objects in C#.
The members of a class are either static members or instance members. Static members belong to classes, and instance members belong to objects (instances of classes).
The following table provides an overview of the kinds of members a class can contain.
Member | Description |
---|---|
Constants | Constant values associated with the class |
Fields | Variables of the class |
Methods | Computations and actions that can be performed by the class |
Properties | Actions associated with reading and writing named properties of the class |
Indexers | Actions associated with indexing instances of the class like an array |
Events | Notifications that can be generated by the class |
Operators | Conversions and expression operators supported by the class |
Constructors | Actions required to initialize instances of the class or the class itself |
Destructors | Actions to perform before instances of the class are permanently discarded |
Types | Nested types declared by the class |
Each member of a class 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 following table.
Accessibility | Meaning |
---|---|
public |
Access not limited |
protected |
Access limited to this class or classes derived from this class |
internal |
Access limited to this program |
protected internal |
Access limited to this program or classes derived from this class |
private |
Access limited to this class |
A class definition may specify a set of type parameters by following the class name with angle brackets enclosing a list of type parameter names. The type parameters can the be used in the body of the class declarations to define the members of the class. In the following example, the type parameters of Pair
are TFirst
and TSecond
:
public class Pair<TFirst,TSecond>
{
public TFirst First;
public TSecond Second;
}
A class type that is declared to take type parameters is called a generic class type. Struct, interface and delegate types can also be generic.
When the generic class is used, type arguments must be provided for each of the type parameters:
Pair<int,string> pair = new Pair<int,string> { First = 1, Second = "two" };
int i = pair.First; // TFirst is int
string s = pair.Second; // TSecond is string
A generic type with type arguments provided, like Pair<int,string>
above, is called a constructed type.
A class declaration may specify a base class by following the class name and type parameters with a colon and the name of the base class. Omitting a base class specification is the same as deriving from type object
. In the following example, the base class of Point3D
is Point
, and the base class of Point
is object
:
public class Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
public class Point3D: Point
{
public int z;
public Point3D(int x, int y, int z): base(x, y) {
this.z = z;
}
}
A class inherits the members of its base class. Inheritance means that a class implicitly contains all members of its base class, except for the instance and static constructors, and the destructors of the base class. A derived class can add new members to those it inherits, but it cannot remove the definition of an inherited member. In the previous example, Point3D
inherits the x
and y
fields from Point
, and every Point3D
instance contains three fields, x
, y
, and z
.
An implicit conversion exists from a class type to any of its base class types. Therefore, a variable of a class type can reference an instance of that class or an instance of any derived class. For example, given the previous class declarations, a variable of type Point
can reference either a Point
or a Point3D
:
Point a = new Point(10, 20);
Point b = new Point3D(10, 20, 30);
A field is a variable that is associated with a class or with an instance of a class.
A field declared with the static
modifier defines a static field. 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 field declared without the static
modifier defines an instance field. Every instance of a class contains a separate copy of all the instance fields of that class.
In the following example, each instance of the Color
class has a separate copy of the r
, g
, and b
instance fields, but there is only one copy of the Black
, White
, Red
, Green
, and Blue
static fields:
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 r, g, b;
public Color(byte r, byte g, byte b) {
this.r = r;
this.g = g;
this.b = b;
}
}
As shown in the previous example, read-only fields may be declared with a readonly
modifier. Assignment to a readonly
field can only occur as part of the field's declaration or in a constructor in the same class.
A method is a member that implements a computation or action that can be performed by an object or class. Static methods are accessed through the class. Instance methods are accessed through instances of the class.
Methods have a (possibly empty) list of parameters, which represent values or variable references passed to the method, and a return type, which specifies the type of the value computed and returned by the method. A method's return type is void
if it does not return a value.
Like types, methods may also have a set of type parameters, for which type arguments must be specified when the method is called. Unlike types, the type arguments can often be inferred from the arguments of a method call and need not be explicitly given.
The signature of a method must be unique in the class in which the method is declared. The signature of a method consists of the name of the method, the number of type parameters and the number, modifiers, and types of its parameters. The signature of a method does not include the return type.
Parameters are used to pass values or variable references to methods. The parameters of a method get their actual values from the arguments that are specified when the method is invoked. There are four kinds of parameters: value parameters, reference parameters, output parameters, and parameter arrays.
A value parameter is used for input parameter passing. A value parameter corresponds to a local variable that gets its initial value from the argument that was passed for the parameter. Modifications to a value parameter do not affect the argument that was passed for the parameter.
Value parameters can be optional, by specifying a default value so that corresponding arguments can be omitted.
A reference parameter is used for both input and output parameter passing. The argument passed for a reference parameter must be a variable, and during execution of the method, the reference parameter represents the same storage location as the argument variable. A reference parameter is declared with the ref
modifier. The following example shows the use of ref
parameters.
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("{0} {1}", i, j); // Outputs "2 1"
}
}
An output parameter is used for output parameter passing. 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 the out
modifier. The following example shows the use of out
parameters.
using System;
class Test
{
static void Divide(int x, int y, out int result, out int remainder) {
result = x / y;
remainder = x % y;
}
static void Main() {
int res, rem;
Divide(10, 3, out res, out rem);
Console.WriteLine("{0} {1}", res, rem); // Outputs "3 1"
}
}
A parameter array permits a variable number of arguments to be passed to a method. A parameter array is declared with the params
modifier. Only the last parameter of a method can be a parameter array, and the type of a parameter array must be a single-dimensional array type. The Write
and WriteLine
methods of the System.Console
class are good examples of parameter array usage. They are declared as follows.
public class Console
{
public static void Write(string fmt, params object[] args) {...}
public static void WriteLine(string fmt, params object[] args) {...}
...
}
Within a method that uses a parameter array, the parameter array behaves exactly like a regular parameter of an array type. However, in an invocation of a method with a parameter array, it is possible to pass either a single argument of the parameter array type or any number of arguments of the element type of the parameter array. In the latter case, an array instance is automatically created and initialized with the given arguments. This example
Console.WriteLine("x={0} y={1} z={2}", x, y, z);
is equivalent to writing the following.
string s = "x={0} y={1} z={2}";
object[] args = new object[3];
args[0] = x;
args[1] = y;
args[2] = z;
Console.WriteLine(s, args);
A method's body specifies the statements to execute when the method is invoked.
A method body can declare variables that are specific to the invocation of the method. Such variables are called local variables. A local variable declaration specifies a type name, a variable name, and possibly an initial value. The following example declares a local variable i
with an initial value of zero and a local variable j
with no initial value.
using System;
class Squares
{
static void Main() {
int i = 0;
int j;
while (i < 10) {
j = i * i;
Console.WriteLine("{0} x {0} = {1}", i, j);
i = i + 1;
}
}
}
C# requires a local variable to be definitely assigned before its value can be obtained. For example, if the declaration of the previous i
did not include an initial value, the compiler would report an error for the subsequent usages of i
because i
would not be definitely assigned at those points in the program.
A method can use return
statements to return control to its caller. In a method returning void
, return
statements cannot specify an expression. In a method returning non-void
, return
statements must include an expression that computes the return value.
A method declared with a static
modifier is a static method. A static method does not operate on a specific instance and can only directly access static members.
A method declared without a static
modifier is an instance method. An instance method operates on a specific instance and can access both static and instance members. The instance on which an instance method was invoked can be explicitly accessed as this
. It is an error to refer to this
in a static method.
The following Entity
class has both static and instance members.
class Entity
{
static int nextSerialNo;
int serialNo;
public Entity() {
serialNo = nextSerialNo++;
}
public int GetSerialNo() {
return serialNo;
}
public static int GetNextSerialNo() {
return nextSerialNo;
}
public static void SetNextSerialNo(int value) {
nextSerialNo = value;
}
}
Each Entity
instance contains a serial number (and presumably some other information that is not shown here). The Entity
constructor (which is like an instance method) initializes the new instance with the next available serial number. Because the constructor is an instance member, it is permitted to access both the serialNo
instance field and the nextSerialNo
static field.
The GetNextSerialNo
and SetNextSerialNo
static methods can access the nextSerialNo
static field, but it would be an error for them to directly access the serialNo
instance field.
The following example shows the use of the Entity
class.
using System;
class Test
{
static void Main() {
Entity.SetNextSerialNo(1000);
Entity e1 = new Entity();
Entity e2 = new Entity();
Console.WriteLine(e1.GetSerialNo()); // Outputs "1000"
Console.WriteLine(e2.GetSerialNo()); // Outputs "1001"
Console.WriteLine(Entity.GetNextSerialNo()); // Outputs "1002"
}
}
Note that the SetNextSerialNo
and GetNextSerialNo
static methods are invoked on the class whereas the GetSerialNo
instance method is invoked on instances of the class.
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.
When a virtual method is invoked, the run-time type of the instance for which that invocation takes place determines the actual method implementation to invoke. In a nonvirtual method invocation, the compile-time type of the instance is the determining factor.
A virtual method can be overridden in a derived class. When an instance method declaration includes an override
modifier, the 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 that method.
An abstract method is a virtual method with no implementation. An abstract method is declared with the abstract
modifier and is permitted only in a class that is also declared abstract
. An abstract method must be overridden in every non-abstract derived class.
The following example declares an abstract class, Expression
, which represents an expression tree node, and three derived classes, Constant
, VariableReference
, and Operation
, which implement expression tree nodes for constants, variable references, and arithmetic operations. (This is similar to, but not to be confused with the expression tree types introduced in Expression tree types).
using System;
using System.Collections;
public abstract class Expression
{
public abstract double Evaluate(Hashtable vars);
}
public class Constant: Expression
{
double value;
public Constant(double value) {
this.value = value;
}
public override double Evaluate(Hashtable vars) {
return value;
}
}
public class VariableReference: Expression
{
string name;
public VariableReference(string name) {
this.name = name;
}
public override double Evaluate(Hashtable vars) {
object value = vars[name];
if (value == null) {
throw new Exception("Unknown variable: " + name);
}
return Convert.ToDouble(value);
}
}
public class Operation: Expression
{
Expression left;
char op;
Expression right;
public Operation(Expression left, char op, Expression right) {
this.left = left;
this.op = op;
this.right = right;
}
public override double Evaluate(Hashtable vars) {
double x = left.Evaluate(vars);
double y = right.Evaluate(vars);
switch (op) {
case '+': return x + y;
case '-': return x - y;
case '*': return x * y;
case '/': return x / y;
}
throw new Exception("Unknown operator");
}
}
The previous four classes can be used to model arithmetic expressions. For example, using instances of these classes, the expression x + 3
can be represented as follows.
Expression e = new Operation(
new VariableReference("x"),
'+',
new Constant(3));
The Evaluate
method of an Expression
instance is invoked to evaluate the given expression and produce a double
value. The method takes as an argument a Hashtable
that contains variable names (as keys of the entries) and values (as values of the entries). The Evaluate
method is a virtual abstract method, meaning that non-abstract derived classes must override it to provide an actual implementation.
A Constant
's implementation of Evaluate
simply returns the stored constant. A VariableReference
's implementation looks up the variable name in the hashtable and returns the resulting value. An Operation
's implementation first evaluates the left and right operands (by recursively invoking their Evaluate
methods) and then performs the given arithmetic operation.
The following program uses the Expression
classes to evaluate the expression x * (y + 2)
for different values of x
and y
.
using System;
using System.Collections;
class Test
{
static void Main() {
Expression e = new Operation(
new VariableReference("x"),
'*',
new Operation(
new VariableReference("y"),
'+',
new Constant(2)
)
);
Hashtable vars = new Hashtable();
vars["x"] = 3;
vars["y"] = 5;
Console.WriteLine(e.Evaluate(vars)); // Outputs "21"
vars["x"] = 1.5;
vars["y"] = 9;
Console.WriteLine(e.Evaluate(vars)); // Outputs "16.5"
}
}
Method overloading permits multiple methods in the same class to have the same name as long as they have unique signatures. When compiling an invocation of an overloaded method, the compiler uses overload resolution to determine the specific method to invoke. Overload resolution finds the one method that best matches the arguments or reports an error if no single best match can be found. The following example shows overload resolution in effect. The comment for each invocation in the Main
method shows which method is actually invoked.
class Test
{
static void F() {
Console.WriteLine("F()");
}
static void F(object x) {
Console.WriteLine("F(object)");
}
static void F(int x) {
Console.WriteLine("F(int)");
}
static void F(double x) {
Console.WriteLine("F(double)");
}
static void F<T>(T x) {
Console.WriteLine("F<T>(T)");
}
static void F(double x, double y) {
Console.WriteLine("F(double, double)");
}
static void Main() {
F(); // Invokes F()
F(1); // Invokes F(int)
F(1.0); // Invokes F(double)
F("abc"); // Invokes F(object)
F((double)1); // Invokes F(double)
F((object)1); // Invokes F(object)
F<int>(1); // Invokes F<T>(T)
F(1, 1); // Invokes F(double, double)
}
}
As shown by the example, a particular method can always be selected by explicitly casting the arguments to the exact parameter types and/or explicitly supplying type arguments.
Members that contain executable code are collectively known as the function members of a class. The preceding section describes methods, which are the primary kind of function members. This section describes the other kinds of function members supported by C#: constructors, properties, indexers, events, operators, and destructors.
The following code shows a generic class called List<T>
, which implements a growable list of objects. The class contains several examples of the most common kinds of function members.
public class List<T> {
// Constant...
const int defaultCapacity = 4;
// Fields...
T[] items;
int count;
// Constructors...
public List(int capacity = defaultCapacity) {
items = new T[capacity];
}
// Properties...
public int Count {
get { return count; }
}
public int Capacity {
get {
return items.Length;
}
set {
if (value < count) value = count;
if (value != items.Length) {
T[] newItems = new T[value];
Array.Copy(items, 0, newItems, 0, count);
items = newItems;
}
}
}
// Indexer...
public T this[int index] {
get {
return items[index];
}
set {
items[index] = value;
OnChanged();
}
}
// Methods...
public void Add(T item) {
if (count == Capacity) Capacity = count * 2;
items[count] = item;
count++;
OnChanged();
}
protected virtual void OnChanged() {
if (Changed != null) Changed(this, EventArgs.Empty);
}
public override bool Equals(object other) {
return Equals(this, other as List<T>);
}
static bool Equals(List<T> a, List<T> b) {
if (a == null) return b == null;
if (b == null || a.count != b.count) return false;
for (int i = 0; i < a.count; i++) {
if (!object.Equals(a.items[i], b.items[i])) {
return false;
}
}
return true;
}
// Event...
public event EventHandler Changed;
// Operators...
public static bool operator ==(List<T> a, List<T> b) {
return Equals(a, b);
}
public static bool operator !=(List<T> a, List<T> b) {
return !Equals(a, b);
}
}
C# supports both instance and static constructors. An instance constructor is a member that implements the actions required to initialize an instance of a class. A static constructor is a member that implements the actions required to initialize a class itself when it is first loaded.
A constructor is declared like a method with no return type and the same name as the containing class. If a constructor declaration includes a static
modifier, it declares a static constructor. Otherwise, it declares an instance constructor.
Instance constructors can be overloaded. For example, the List<T>
class declares two instance constructors, one with no parameters and one that takes an int
parameter. Instance constructors are invoked using the new
operator. The following statements allocate two List<string>
instances using each of the constructors of the List
class.
List<string> list1 = new List<string>();
List<string> list2 = new List<string>(10);
Unlike other members, instance constructors are not inherited, and a class has no instance constructors other than those actually declared in the class. If no instance constructor is supplied for a class, then an empty one with no parameters is automatically provided.
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.
A property is declared like a field, except that the declaration ends with a get
accessor and/or a set
accessor written between the delimiters {
and }
instead of ending in a semicolon. A property that has both a get
accessor and a set
accessor is a read-write property, a property that has only a get
accessor is a read-only property, and a property that has only a set
accessor is a write-only property.
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.
A set
accessor corresponds to a method with a single parameter named value
and no return type. When a property is referenced as the target of an assignment or as the operand of ++
or --
, the set
accessor is invoked with an argument that provides the new value.
The List<T>
class declares two properties, Count
and Capacity
, which are read-only and read-write, respectively. The following is an example of use of these properties.
List<string> names = new List<string>();
names.Capacity = 100; // Invokes set accessor
int i = names.Count; // Invokes get accessor
int j = names.Capacity; // Invokes get accessor
Similar to fields and methods, C# supports both instance properties and static properties. Static properties are declared with the static
modifier, and instance properties are declared without it.
The accessor(s) of a property can be virtual. When a property declaration includes a virtual
, abstract
, or override
modifier, it applies to the accessor(s) of the property.
An indexer is a member that enables objects to be indexed in the same way as an array. An indexer is declared like a property except that the name of the member is this
followed by a parameter list written between the delimiters [
and ]
. The parameters are available in the accessor(s) of the indexer. Similar to properties, indexers can be read-write, read-only, and write-only, and the accessor(s) of an indexer can be virtual.
The List
class declares a single read-write indexer that takes an int
parameter. The indexer makes it possible to index List
instances with int
values. For example
List<string> names = new List<string>();
names.Add("Liz");
names.Add("Martha");
names.Add("Beth");
for (int i = 0; i < names.Count; i++) {
string s = names[i];
names[i] = s.ToUpper();
}
Indexers can be overloaded, meaning that a class can declare multiple indexers as long as the number or types of their parameters differ.
An event is a member that enables a class or object to provide notifications. An event is declared like a field except that the declaration includes an event
keyword and the type must be a delegate type.
Within a class that declares an event member, the event behaves just like a field of a delegate type (provided the event is not abstract and does not declare accessors). The field stores a reference to a delegate that represents the event handlers that have been added to the event. If no event handles are present, the field is null
.
The List<T>
class declares a single event member called Changed
, which indicates that a new item has been added to the list. The Changed
event is raised by the OnChanged
virtual method, which first checks whether the event is null
(meaning that no handlers are present). 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.
Clients react to events through event handlers. Event handlers are attached using the +=
operator and removed using the -=
operator. The following example attaches an event handler to the Changed
event of a List<string>
.
using System;
class Test
{
static int changeCount;
static void ListChanged(object sender, EventArgs e) {
changeCount++;
}
static void Main() {
List<string> names = new List<string>();
names.Changed += new EventHandler(ListChanged);
names.Add("Liz");
names.Add("Martha");
names.Add("Beth");
Console.WriteLine(changeCount); // Outputs "3"
}
}
For advanced scenarios where control of the underlying storage of an event is desired, an event declaration can explicitly provide add
and remove
accessors, which are somewhat similar to the set
accessor of a property.
An operator is a member that defines the meaning of applying a particular expression operator to instances of a class. Three kinds of operators can be defined: unary operators, binary operators, and conversion operators. All operators must be declared as public
and static
.
The List<T>
class declares two operators, operator==
and operator!=
, and thus gives new meaning to expressions that apply those operators to List
instances. Specifically, the operators define equality of two List<T>
instances as comparing each of the contained objects using their Equals
methods. The following example uses the ==
operator to compare two List<int>
instances.
using System;
class Test
{
static void Main() {
List<int> a = new List<int>();
a.Add(1);
a.Add(2);
List<int> b = new List<int>();
b.Add(1);
b.Add(2);
Console.WriteLine(a == b); // Outputs "True"
b.Add(3);
Console.WriteLine(a == b); // Outputs "False"
}
}
The first Console.WriteLine
outputs True
because the two lists contain the same number of objects with the same values in the same order. Had List<T>
not defined operator==
, the first Console.WriteLine
would have output False
because a
and b
reference different List<int>
instances.
A destructor is a member that implements the actions required to destruct an instance of a class. Destructors cannot have parameters, they cannot have accessibility modifiers, and they cannot be invoked explicitly. The destructor for an instance is invoked automatically during garbage collection.
The garbage collector is allowed wide latitude in deciding when to collect objects and run destructors. Specifically, the timing of destructor invocations is not deterministic, and destructors may be executed on any thread. For these and other reasons, classes should implement destructors only when no other solutions are feasible.
The using
statement provides a better approach to object destruction.
Like classes, structs are data structures that can contain data members and function members, but unlike classes, structs are value types and do not require heap allocation. A variable of a struct type directly stores the data of the struct, whereas a variable of a class type stores a reference to a dynamically allocated object. Struct types do not support user-specified inheritance, and all struct types implicitly inherit from type 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. The use of structs rather than classes for small data structures can make a large difference in the number of memory allocations an application performs. For example, the following program 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);
}
}
An alternative is to make Point
a struct.
struct Point
{
public int x, y;
public Point(int x, int y) {
this.x = x;
this.y = y;
}
}
Now, only one object is instantiated—the one for the array—and the Point
instances are stored in-line in the array.
Struct constructors are invoked with the new
operator, but that does not imply that memory is being allocated. Instead of dynamically allocating an object and returning a reference to it, a struct constructor simply returns the struct value itself (typically in a temporary location on the stack), and this value is then copied as necessary.
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. For example, the output produced by the following code fragment depends on whether Point
is a class or a struct.
Point a = new Point(10, 10);
Point b = a;
a.x = 20;
Console.WriteLine(b.x);
If Point
is a class, the output is 20
because a
and b
reference the same object. If Point
is a struct, the output is 10
because the assignment of a
to b
creates a copy of the value, and this copy is unaffected by the subsequent assignment to a.x
.
The previous example highlights two of the limitations of structs. First, copying an entire struct is typically less efficient than copying an object reference, so assignment and value parameter passing can be more expensive with structs than with reference types. Second, except for ref
and out
parameters, it is not possible to create references to structs, which rules out their usage in a number of situations.
An array is a data structure that contains a number of variables that 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 reference types, and the declaration of an array variable simply sets aside space for a reference to an array instance. Actual array instances are created dynamically at run-time using the new
operator. The new
operation specifies the length of the new array instance, which is then fixed for the lifetime of the instance. The indices of the elements of an array range from 0
to Length - 1
. The new
operator automatically initializes the elements of an array to their default value, which, for example, is zero for all numeric types and null
for all reference types.
The following example creates an array of int
elements, initializes the array, and prints out the contents of the array.
using System;
class Test
{
static void Main() {
int[] a = new int[10];
for (int i = 0; i < a.Length; i++) {
a[i] = i * i;
}
for (int i = 0; i < a.Length; i++) {
Console.WriteLine("a[{0}] = {1}", i, a[i]);
}
}
}
This example creates and operates on a single-dimensional array. C# also supports multi-dimensional arrays. The number of dimensions of an array type, also known as the rank of the array type, is one plus the number of commas written between the square brackets of the array type. The following example allocates a one-dimensional, a two-dimensional, and a three-dimensional array.
int[] a1 = new int[10];
int[,] a2 = new int[10, 5];
int[,,] a3 = new int[10, 5, 2];
The a1
array contains 10 elements, the a2
array contains 50 (10 × 5) elements, and the a3
array contains 100 (10 × 5 × 2) elements.
The element type of an array can be any type, including an array type. An array with elements of an array type is sometimes called a jagged array because the lengths of the element arrays do not all have to be the same. The following example allocates an array of arrays of int
:
int[][] a = new int[3][];
a[0] = new int[10];
a[1] = new int[5];
a[2] = new int[20];
The first line creates an array with three elements, each of type int[]
and each with an initial value of null
. The subsequent lines then initialize the three elements with references to individual array instances of varying lengths.
The new
operator permits the initial values of the array elements to be specified using an array initializer, which is a list of expressions written between the delimiters {
and }
. The following example allocates and initializes an int[]
with three elements.
int[] a = new int[] {1, 2, 3};
Note that the length of the array is inferred from the number of expressions between {
and }
. Local variable and field declarations can be shortened further such that the array type does not have to be restated.
int[] a = {1, 2, 3};
Both of the previous examples are equivalent to the following:
int[] t = new int[3];
t[0] = 1;
t[1] = 2;
t[2] = 3;
int[] a = t;
An interface defines a contract that can be implemented by classes and structs. An interface can contain methods, properties, events, and indexers. An interface does not provide implementations of the members it defines—it merely specifies the members that must be supplied by classes or structs that implement the interface.
Interfaces may employ multiple inheritance. In the following example, the interface IComboBox
inherits from both ITextBox
and IListBox
.
interface IControl
{
void Paint();
}
interface ITextBox: IControl
{
void SetText(string text);
}
interface IListBox: IControl
{
void SetItems(string[] items);
}
interface IComboBox: ITextBox, IListBox {}
Classes and structs can implement multiple interfaces. In the following example, the class EditBox
implements both IControl
and IDataBound
.
interface IDataBound
{
void Bind(Binder b);
}
public class EditBox: IControl, IDataBound
{
public void Paint() {...}
public void Bind(Binder b) {...}
}
When a class or struct implements a particular interface, instances of that class or struct can be implicitly converted to that interface type. For example
EditBox editBox = new EditBox();
IControl control = editBox;
IDataBound dataBound = editBox;
In cases where an instance is not statically known to implement a particular interface, dynamic type casts can be used. For example, the following statements use dynamic type casts to obtain an object's IControl
and IDataBound
interface implementations. Because the actual type of the object is EditBox
, the casts succeed.
object obj = new EditBox();
IControl control = (IControl)obj;
IDataBound dataBound = (IDataBound)obj;
In the previous EditBox
class, the Paint
method from the IControl
interface and the Bind
method from the IDataBound
interface are implemented using public
members. C# also supports explicit interface member implementations, using which the class or struct can avoid making the members public
. An explicit interface member implementation is written using the fully qualified interface member name. For example, the EditBox
class could implement the IControl.Paint
and IDataBound.Bind
methods using explicit interface member implementations as follows.
public class EditBox: IControl, IDataBound
{
void IControl.Paint() {...}
void IDataBound.Bind(Binder b) {...}
}
Explicit interface members can only be accessed via the interface type. For example, the implementation of IControl.Paint
provided by the previous EditBox
class can only be invoked by first converting the EditBox
reference to the IControl
interface type.
EditBox editBox = new EditBox();
editBox.Paint(); // Error, no such method
IControl control = editBox;
control.Paint(); // Ok
An enum type is a distinct value type with a set of named constants. The following example declares and uses an enum type named Color
with three constant values, Red
, Green
, and Blue
.
using System;
enum Color
{
Red,
Green,
Blue
}
class Test
{
static void PrintColor(Color color) {
switch (color) {
case Color.Red:
Console.WriteLine("Red");
break;
case Color.Green:
Console.WriteLine("Green");
break;
case Color.Blue:
Console.WriteLine("Blue");
break;
default:
Console.WriteLine("Unknown color");
break;
}
}
static void Main() {
Color c = Color.Red;
PrintColor(c);
PrintColor(Color.Blue);
}
}
Each enum type has a corresponding integral type called the underlying type of the enum type. An enum type that does not explicitly declare an underlying type has an underlying type of int
. An enum type's storage format and range of possible values are determined by its underlying type. 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.
The following example declares an enum type named Alignment
with an underlying type of sbyte
.
enum Alignment: sbyte
{
Left = -1,
Center = 0,
Right = 1
}
As shown by the previous example, an enum member declaration can include a constant expression that specifies the value of the member. The constant value for each enum member must be in the range of the underlying type of the enum. When an enum member declaration does not explicitly specify a value, the member is given the value zero (if it is the first member in the enum type) or the value of the textually preceding enum member plus one.
Enum values can be converted to integral values and vice versa using type casts. For example
int i = (int)Color.Blue; // int i = 2;
Color c = (Color)2; // Color c = Color.Blue;
The default value of any enum type is the integral value zero converted to the enum type. In cases where variables are automatically initialized to a default value, this is the value given to variables of enum types. In order for the default value of an enum type to be easily available, the literal 0
implicitly converts to any enum type. Thus, the following is permitted.
Color c = 0;
A delegate type represents references to methods with a particular parameter list and return type. Delegates make it possible to treat methods as entities that can be assigned to variables and passed as parameters. Delegates are similar to the concept of function pointers found in some other languages, but unlike function pointers, delegates are object-oriented and type-safe.
The following example declares and uses a delegate type named Function
.
using System;
delegate double Function(double x);
class Multiplier
{
double factor;
public Multiplier(double factor) {
this.factor = factor;
}
public double Multiply(double x) {
return x * factor;
}
}
class Test
{
static double Square(double x) {
return x * x;
}
static double[] Apply(double[] a, Function f) {
double[] result = new double[a.Length];
for (int i = 0; i < a.Length; i++) result[i] = f(a[i]);
return result;
}
static void Main() {
double[] a = {0.0, 0.5, 1.0};
double[] squares = Apply(a, Square);
double[] sines = Apply(a, Math.Sin);
Multiplier m = new Multiplier(2.0);
double[] doubles = Apply(a, m.Multiply);
}
}
An instance of the Function
delegate type can reference any method that takes a double
argument and returns a double
value. The Apply
method applies a given Function
to the elements of a double[]
, returning a double[]
with the results. In the Main
method, Apply
is used to apply three different functions to a double[]
.
A delegate can reference either a static method (such as Square
or Math.Sin
in the previous example) or an instance method (such as m.Multiply
in the previous example). A delegate that references an instance method also references a particular object, and when the instance method is invoked through the delegate, that object becomes this
in the invocation.
Delegates can also be created using anonymous functions, which are "inline methods" that are created on the fly. Anonymous functions can see the local variables of the surrounding methods. Thus, the multiplier example above can be written more easily without using a Multiplier
class:
double[] doubles = Apply(a, (double x) => x * 2.0);
An interesting and useful property of a delegate is that it does not know or care about the class of the method it references; all that matters is that the referenced method has the same parameters and return type as the delegate.
Types, members, and other entities in a C# program support modifiers that control certain aspects of their behavior. For example, the accessibility of a method is controlled using the public
, protected
, internal
, and private
modifiers. C# generalizes this capability such that user-defined types of declarative information can be attached to program entities and retrieved at run-time. Programs specify this additional declarative information by defining and using attributes.
The following example declares a HelpAttribute
attribute that can be placed on program entities to provide links to their associated documentation.
using System;
public class HelpAttribute: Attribute
{
string url;
string topic;
public HelpAttribute(string url) {
this.url = url;
}
public string Url {
get { return url; }
}
public string Topic {
get { return topic; }
set { topic = value; }
}
}
All attribute classes derive from the System.Attribute
base class provided by the .NET Framework. Attributes can be applied by giving their name, along with any arguments, inside square brackets just before the associated declaration. If an attribute's name ends in Attribute
, that part of the name can be omitted when the attribute is referenced. For example, the HelpAttribute
attribute can be used as follows.
[Help("http://msdn.microsoft.com/.../MyClass.htm")]
public class Widget
{
[Help("http://msdn.microsoft.com/.../MyClass.htm", Topic = "Display")]
public void Display(string text) {}
}
This example attaches a HelpAttribute
to the Widget
class and another HelpAttribute
to the Display
method in the class. The public constructors of an attribute class control the information that must be provided when the attribute is attached to a program entity. Additional information can be provided by referencing public read-write properties of the attribute class (such as the reference to the Topic
property previously).
The following example shows how attribute information for a given program entity can be retrieved at run-time using reflection.
using System;
using System.Reflection;
class Test
{
static void ShowHelp(MemberInfo member) {
HelpAttribute a = Attribute.GetCustomAttribute(member,
typeof(HelpAttribute)) as HelpAttribute;
if (a == null) {
Console.WriteLine("No help for {0}", member);
}
else {
Console.WriteLine("Help for {0}:", member);
Console.WriteLine(" Url={0}, Topic={1}", a.Url, a.Topic);
}
}
static void Main() {
ShowHelp(typeof(Widget));
ShowHelp(typeof(Widget).GetMethod("Display"));
}
}
When a particular attribute is requested through reflection, the constructor for the attribute class is invoked with the information provided in the program source, and the resulting attribute instance is returned. If additional information was provided through properties, those properties are set to the given values before the attribute instance is returned.