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.
A class_declaration is a type_declaration (Type declarations) that declares a new class.
class_declaration
: attributes? class_modifier* 'partial'? 'class' identifier type_parameter_list?
class_base? type_parameter_constraints_clause* class_body ';'?
;
A class_declaration consists of an optional set of attributes (Attributes), followed by an optional set of class_modifiers (Class modifiers), followed by an optional partial
modifier, followed by the keyword class
and an identifier that names the class, followed by an optional type_parameter_list (Type parameters), followed by an optional class_base specification (Class base specification) , followed by an optional set of type_parameter_constraints_clauses (Type parameter constraints), followed by a class_body (Class body), optionally followed by a semicolon.
A class declaration cannot supply type_parameter_constraints_clauses unless it also supplies a type_parameter_list.
A class declaration that supplies a type_parameter_list is a generic class declaration. Additionally, any class nested inside a generic class declaration or a generic struct declaration is itself a generic class declaration, since type parameters for the containing type must be supplied to create a constructed type.
A class_declaration may optionally include a sequence of class modifiers:
class_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
| 'abstract'
| 'sealed'
| 'static'
| class_modifier_unsafe
;
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 The new modifier. 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 (Declared accessibility).
The abstract
, sealed
and static
modifiers are discussed in the following sections.
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 in 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 benull
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, thereby overriding those 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.
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.
The static
modifier is used to mark the class being declared as a static class. A static class cannot be instantiated, cannot be used as a type and can contain only static members. Only a static class can contain declarations of extension methods (Extension methods).
A static class declaration is subject to the following restrictions:
- A static class may not include a
sealed
orabstract
modifier. Note, however, that since a static class cannot be instantiated or derived from, it behaves as if it was both sealed and abstract. - A static class may not include a class_base specification (Class base specification) and cannot explicitly specify a base class or a list of implemented interfaces. A static class implicitly inherits from type
object
. - A static class can only contain static members (Static and instance members). Note that constants and nested types are classified as static members.
- A static class cannot have members with
protected
orprotected internal
declared accessibility.
It is a compile-time error to violate any of these restrictions.
A static class has no instance constructors. It is not possible to declare an instance constructor in a static class, and no default instance constructor (Default constructors) is provided for a static class.
The members of a static class are not automatically static, and the member declarations must explicitly include a static
modifier (except for constants and nested types). When a class is nested within a static outer class, the nested class is not a static class unless it explicitly includes a static
modifier.
Referencing static class types
A namespace_or_type_name (Namespace and type names) is permitted to reference a static class if
- The namespace_or_type_name is the
T
in a namespace_or_type_name of the formT.I
, or - The namespace_or_type_name is the
T
in a typeof_expression (Argument lists1) of the formtypeof(T)
.
A primary_expression (Function members) is permitted to reference a static class if
- The primary_expression is the
E
in a member_access (Compile-time checking of dynamic overload resolution) of the formE.I
.
In any other context it is a compile-time error to reference a static class. For example, it is an error for a static class to be used as a base class, a constituent type (Nested types) of a member, a generic type argument, or a type parameter constraint. Likewise, a static class cannot be used in an array type, a pointer type, a new
expression, a cast expression, an is
expression, an as
expression, a sizeof
expression, or a default value expression.
The partial
modifier is used to indicate that this class_declaration is a partial type declaration. Multiple partial type declarations with the same name within an enclosing namespace or type declaration combine to form one type declaration, following the rules specified in Partial types.
Having the declaration of a class distributed over separate segments of program text can be useful if these segments are produced or maintained in different contexts. For instance, one part of a class declaration may be machine generated, whereas the other is manually authored. Textual separation of the two prevents updates by one from conflicting with updates by the other.
A type parameter is a simple identifier that denotes a placeholder for a type argument supplied to create a constructed type. A type parameter is a formal placeholder for a type that will be supplied later. By constrast, a type argument (Type arguments) is the actual type that is substituted for the type parameter when a constructed type is created.
type_parameter_list
: '<' type_parameters '>'
;
type_parameters
: attributes? type_parameter
| type_parameters ',' attributes? type_parameter
;
type_parameter
: identifier
;
Each type parameter in a class declaration defines a name in the declaration space (Declarations) of that class. Thus, it cannot have the same name as another type parameter or a member declared in that class. A type parameter cannot have the same name as the type itself.
A class declaration may include a class_base specification, which defines the direct base class of the class and the interfaces (Interfaces) directly implemented by the class.
class_base
: ':' class_type
| ':' interface_type_list
| ':' class_type ',' interface_type_list
;
interface_type_list
: interface_type (',' interface_type)*
;
The base class specified in a class declaration can be a constructed class type (Constructed types). A base class cannot be a type parameter on its own, though it can involve the type parameters that are in scope.
class Extend<V>: V {} // Error, type parameter used as base class
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 Inheritance.
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
.
For a constructed class type, if a base class is specified in the generic class declaration, the base class of the constructed type is obtained by substituting, for each type_parameter in the base class declaration, the corresponding type_argument of the constructed type. Given the generic class declarations
class B<U,V> {...}
class G<T>: B<string,T[]> {...}
the base class of the constructed type G<int>
would be B<string,int[]>
.
The direct base class of a class type must be at least as accessible as the class type itself (Accessibility domains). 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.MulticastDelegate
, System.Enum
, or System.ValueType
. Furthermore, a generic class declaration cannot use System.Attribute
as a direct or indirect base class.
While determining the meaning of the direct base class specification A
of a class B
, the direct base class of B
is temporarily assumed to be object
. Intuitively this ensures that the meaning of a base class specification cannot recursively depend on itself. The example:
class A<T> {
public class B {}
}
class C : A<C.B> {}
is in error since in the base class specification A<C.B>
the direct base class of C
is considered to be object
, and hence (by the rules of Namespace and type names) C
is not considered to have a member B
.
The base classes of a class type 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
. In the example
class A {...}
class B<T>: A {...}
class C<T>: B<IComparable<T>> {...}
class D<T>: C<T[]> {...}
the base classes of D<int>
are C<int[]>
, B<IComparable<int[]>>
, A
, and object
.
Except for class object
, every class type 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 reflexive and transitive closure of the directly depends on relationship.
The example
class A: A {}
is erroneous because the class depends on itself. Likewise, the example
class A: B {}
class B: C {}
class C: A {}
is in error because the classes circularly depend on themselves. Finally, 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. In the example
sealed class A {}
class B: A {} // Error, cannot derive from a sealed class
class B
is in error because it attempts to derive from the sealed
class A
.
A class_base specification may include a list of interface types, in which case the class is said to directly implement the given interface types. Interface implementations are discussed further in Interface implementations.
Generic type and method declarations can optionally specify type parameter constraints by including type_parameter_constraints_clauses.
type_parameter_constraints_clause
: 'where' type_parameter ':' type_parameter_constraints
;
type_parameter_constraints
: primary_constraint
| secondary_constraints
| constructor_constraint
| primary_constraint ',' secondary_constraints
| primary_constraint ',' constructor_constraint
| secondary_constraints ',' constructor_constraint
| primary_constraint ',' secondary_constraints ',' constructor_constraint
;
primary_constraint
: class_type
| 'class'
| 'struct'
;
secondary_constraints
: interface_type
| type_parameter
| secondary_constraints ',' interface_type
| secondary_constraints ',' type_parameter
;
constructor_constraint
: 'new' '(' ')'
;
Each type_parameter_constraints_clause consists of the token where
, followed by the name of a type parameter, followed by a colon and the list of constraints for that type parameter. There can be at most one where
clause for each type parameter, and the where
clauses can be listed in any order. Like the get
and set
tokens in a property accessor, the where
token is not a keyword.
The list of constraints given in a where
clause can include any of the following components, in this order: a single primary constraint, one or more secondary constraints, and the constructor constraint, new()
.
A primary constraint can be a class type or the reference type constraint class
or the value type constraint struct
. A secondary constraint can be a type_parameter or interface_type.
The reference type constraint specifies that a type argument used for the type parameter must be a reference type. All class types, interface types, delegate types, array types, and type parameters known to be a reference type (as defined below) satisfy this constraint.
The value type constraint specifies that a type argument used for the type parameter must be a non-nullable value type. All non-nullable struct types, enum types, and type parameters having the value type constraint satisfy this constraint. Note that although classified as a value type, a nullable type (Nullable types) does not satisfy the value type constraint. A type parameter having the value type constraint cannot also have the constructor_constraint.
Pointer types are never allowed to be type arguments and are not considered to satisfy either the reference type or value type constraints.
If a constraint is a class type, an interface type, or a type parameter, that type specifies a minimal "base type" that every type argument used for that type parameter must support. Whenever a constructed type or generic method is used, the type argument is checked against the constraints on the type parameter at compile-time. The type argument supplied must satisfy the conditions described in Satisfying constraints.
A class_type constraint must satisfy the following rules:
- The type must be a class type.
- The type must not be
sealed
. - The type must not be one of the following types:
System.Array
,System.Delegate
,System.Enum
, orSystem.ValueType
. - The type must not be
object
. Because all types derive fromobject
, such a constraint would have no effect if it were permitted. - At most one constraint for a given type parameter can be a class type.
A type specified as an interface_type constraint must satisfy the following rules:
- The type must be an interface type.
- A type must not be specified more than once in a given
where
clause.
In either case, the constraint can involve any of the type parameters of the associated type or method declaration as part of a constructed type, and can involve the type being declared.
Any class or interface type specified as a type parameter constraint must be at least as accessible (Accessibility constraints) as the generic type or method being declared.
A type specified as a type_parameter constraint must satisfy the following rules:
- The type must be a type parameter.
- A type must not be specified more than once in a given
where
clause.
In addition there must be no cycles in the dependency graph of type parameters, where dependency is a transitive relation defined by:
- If a type parameter
T
is used as a constraint for type parameterS
thenS
depends onT
. - If a type parameter
S
depends on a type parameterT
andT
depends on a type parameterU
thenS
depends onU
.
Given this relation, it is a compile-time error for a type parameter to depend on itself (directly or indirectly).
Any constraints must be consistent among dependent type parameters. If type parameter S
depends on type parameter T
then:
T
must not have the value type constraint. Otherwise,T
is effectively sealed soS
would be forced to be the same type asT
, eliminating the need for two type parameters.- If
S
has the value type constraint thenT
must not have a class_type constraint. - If
S
has a class_type constraintA
andT
has a class_type constraintB
then there must be an identity conversion or implicit reference conversion fromA
toB
or an implicit reference conversion fromB
toA
. - If
S
also depends on type parameterU
andU
has a class_type constraintA
andT
has a class_type constraintB
then there must be an identity conversion or implicit reference conversion fromA
toB
or an implicit reference conversion fromB
toA
.
It is valid for S
to have the value type constraint and T
to have the reference type constraint. Effectively this limits T
to the types System.Object
, System.ValueType
, System.Enum
, and any interface type.
If the where
clause for a type parameter includes a constructor constraint (which has the form new()
), it is possible to use the new
operator to create instances of the type (Object creation expressions). Any type argument used for a type parameter with a constructor constraint must have a public parameterless constructor (this constructor implicitly exists for any value type) or be a type parameter having the value type constraint or constructor constraint (see Type parameter constraints for details).
The following are examples of constraints:
interface IPrintable
{
void Print();
}
interface IComparable<T>
{
int CompareTo(T value);
}
interface IKeyProvider<T>
{
T GetKey();
}
class Printer<T> where T: IPrintable {...}
class SortedList<T> where T: IComparable<T> {...}
class Dictionary<K,V>
where K: IComparable<K>
where V: IPrintable, IKeyProvider<K>, new()
{
...
}
The following example is in error because it causes a circularity in the dependency graph of the type parameters:
class Circular<S,T>
where S: T
where T: S // Error, circularity in dependency graph
{
...
}
The following examples illustrate additional invalid situations:
class Sealed<S,T>
where S: T
where T: struct // Error, T is sealed
{
...
}
class A {...}
class B {...}
class Incompat<S,T>
where S: A, T
where T: B // Error, incompatible class-type constraints
{
...
}
class StructWithClass<S,T,U>
where S: struct, T
where T: U
where U: A // Error, A incompatible with struct
{
...
}
The effective base class of a type parameter T
is defined as follows:
- If
T
has no primary constraints or type parameter constraints, its effective base class isobject
. - If
T
has the value type constraint, its effective base class isSystem.ValueType
. - If
T
has a class_type constraintC
but no type_parameter constraints, its effective base class isC
. - If
T
has no class_type constraint but has one or more type_parameter constraints, its effective base class is the most encompassed type (Lifted conversion operators) in the set of effective base classes of its type_parameter constraints. The consistency rules ensure that such a most encompassed type exists. - If
T
has both a class_type constraint and one or more type_parameter constraints, its effective base class is the most encompassed type (Lifted conversion operators) in the set consisting of the class_type constraint ofT
and the effective base classes of its type_parameter constraints. The consistency rules ensure that such a most encompassed type exists. - If
T
has the reference type constraint but no class_type constraints, its effective base class isobject
.
For the purpose of these rules, if T has a constraint V
that is a value_type, use instead the most specific base type of V
that is a class_type. This can never happen in an explicitly given constraint, but may occur when the constraints of a generic method are implicitly inherited by an overriding method declaration or an explicit implementation of an interface method.
These rules ensure that the effective base class is always a class_type.
The effective interface set of a type parameter T
is defined as follows:
- If
T
has no secondary_constraints, its effective interface set is empty. - If
T
has interface_type constraints but no type_parameter constraints, its effective interface set is its set of interface_type constraints. - If
T
has no interface_type constraints but has type_parameter constraints, its effective interface set is the union of the effective interface sets of its type_parameter constraints. - If
T
has both interface_type constraints and type_parameter constraints, its effective interface set is the union of its set of interface_type constraints and the effective interface sets of its type_parameter constraints.
A type parameter is known to be a reference type if it has the reference type constraint or its effective base class is not object
or System.ValueType
.
Values of a constrained type parameter type can be used to access the instance members implied by the constraints. In the example
interface IPrintable
{
void Print();
}
class Printer<T> where T: IPrintable
{
void PrintOne(T x) {
x.Print();
}
}
the methods of IPrintable
can be invoked directly on x
because T
is constrained to always implement IPrintable
.
The class_body of a class defines the members of that class.
class_body
: '{' class_member_declaration* '}'
;
A type declaration can be split across multiple partial type declarations. The type declaration is constructed from its parts by following the rules in this section, whereupon it is treated as a single declaration during the remainder of the compile-time and run-time processing of the program.
A class_declaration, struct_declaration or interface_declaration represents a partial type declaration if it includes a partial
modifier. partial
is not a keyword, and only acts as a modifier if it appears immediately before one of the keywords class
, struct
or interface
in a type declaration, or before the type void
in a method declaration. In other contexts it can be used as a normal identifier.
Each part of a partial type declaration must include a partial
modifier. It must have the same name and be declared in the same namespace or type declaration as the other parts. The partial
modifier indicates that additional parts of the type declaration may exist elsewhere, but the existence of such additional parts is not a requirement; it is valid for a type with a single declaration to include the partial
modifier.
All parts of a partial type must be compiled together such that the parts can be merged at compile-time into a single type declaration. Partial types specifically do not allow already compiled types to be extended.
Nested types may be declared in multiple parts by using the partial
modifier. Typically, the containing type is declared using partial
as well, and each part of the nested type is declared in a different part of the containing type.
The partial
modifier is not permitted on delegate or enum declarations.
The attributes of a partial type are determined by combining, in an unspecified order, the attributes of each of the parts. If an attribute is placed on multiple parts, it is equivalent to specifying the attribute multiple times on the type. For example, the two parts:
[Attr1, Attr2("hello")]
partial class A {}
[Attr3, Attr2("goodbye")]
partial class A {}
are equivalent to a declaration such as:
[Attr1, Attr2("hello"), Attr3, Attr2("goodbye")]
class A {}
Attributes on type parameters combine in a similar fashion.
When a partial type declaration includes an accessibility specification (the public
, protected
, internal
, and private
modifiers) it must agree with all other parts that include an accessibility specification. If no part of a partial type includes an accessibility specification, the type is given the appropriate default accessibility (Declared accessibility).
If one or more partial declarations of a nested type include a new
modifier, no warning is reported if the nested type hides an inherited member (Hiding through inheritance).
If one or more partial declarations of a class include an abstract
modifier, the class is considered abstract (Abstract classes). Otherwise, the class is considered non-abstract.
If one or more partial declarations of a class include a sealed
modifier, the class is considered sealed (Sealed classes). Otherwise, the class is considered unsealed.
Note that a class cannot be both abstract and sealed.
When the unsafe
modifier is used on a partial type declaration, only that particular part is considered an unsafe context (Unsafe contexts).
If a generic type is declared in multiple parts, each part must state the type parameters. Each part must have the same number of type parameters, and the same name for each type parameter, in order.
When a partial generic type declaration includes constraints (where
clauses), the constraints must agree with all other parts that include constraints. Specifically, each part that includes constraints must have constraints for the same set of type parameters, and for each type parameter the sets of primary, secondary, and constructor constraints must be equivalent. Two sets of constraints are equivalent if they contain the same members. If no part of a partial generic type specifies type parameter constraints, the type parameters are considered unconstrained.
The example
partial class Dictionary<K,V>
where K: IComparable<K>
where V: IKeyProvider<K>, IPersistable
{
...
}
partial class Dictionary<K,V>
where V: IPersistable, IKeyProvider<K>
where K: IComparable<K>
{
...
}
partial class Dictionary<K,V>
{
...
}
is correct because those parts that include constraints (the first two) effectively specify the same set of primary, secondary, and constructor constraints for the same set of type parameters, respectively.
When a partial class declaration includes a base class specification it must agree with all other parts that include a base class specification. If no part of a partial class includes a base class specification, the base class becomes System.Object
(Base classes).
The set of base interfaces for a type declared in multiple parts is the union of the base interfaces specified on each part. A particular base interface may only be named once on each part, but it is permitted for multiple parts to name the same base interface(s). There must only be one implementation of the members of any given base interface.
In the example
partial class C: IA, IB {...}
partial class C: IC {...}
partial class C: IA, IB {...}
the set of base interfaces for class C
is IA
, IB
, and IC
.
Typically, each part provides an implementation of the interface(s) declared on that part; however, this is not a requirement. A part may provide the implementation for an interface declared on a different part:
partial class X
{
int IComparable.CompareTo(object o) {...}
}
partial class X: IComparable
{
...
}
With the exception of partial methods (Partial methods), the set of members of a type declared in multiple parts is simply the union of the set of members declared in each part. The bodies of all parts of the type declaration share the same declaration space (Declarations), and the scope of each member (Scopes) extends to the bodies of all the parts. The accessibility domain of any member always includes all the parts of the enclosing type; a private
member declared in one part is freely accessible from another part. It is a compile-time error to declare the same member in more than one part of the type, unless that member is a type with the partial
modifier.
partial class A
{
int x; // Error, cannot declare x more than once
partial class Inner // Ok, Inner is a partial type
{
int y;
}
}
partial class A
{
int x; // Error, cannot declare x more than once
partial class Inner // Ok, Inner is a partial type
{
int z;
}
}
The ordering of members within a type is rarely significant to C# code, but may be significant when interfacing with other languages and environments. In these cases, the ordering of members within a type declared in multiple parts is undefined.
Partial methods can be defined in one part of a type declaration and implemented in another. The implementation is optional; if no part implements the partial method, the partial method declaration and all calls to it are removed from the type declaration resulting from the combination of the parts.
Partial methods cannot define access modifiers, but are implicitly private
. Their return type must be void
, and their parameters cannot have the out
modifier. The identifier partial
is recognized as a special keyword in a method declaration only if it appears right before the void
type; otherwise it can be used as a normal identifier. A partial method cannot explicitly implement interface methods.
There are two kinds of partial method declarations: If the body of the method declaration is a semicolon, the declaration is said to be a defining partial method declaration. If the body is given as a block, the declaration is said to be an implementing partial method declaration. Across the parts of a type declaration there can be only one defining partial method declaration with a given signature, and there can be only one implementing partial method declaration with a given signature. If an implementing partial method declaration is given, a corresponding defining partial method declaration must exist, and the declarations must match as specified in the following:
- The declarations must have the same modifiers (although not necessarily in the same order), method name, number of type parameters and number of parameters.
- Corresponding parameters in the declarations must have the same modifiers (although not necessarily in the same order) and the same types (modulo differences in type parameter names).
- Corresponding type parameters in the declarations must have the same constraints (modulo differences in type parameter names).
An implementing partial method declaration can appear in the same part as the corresponding defining partial method declaration.
Only a defining partial method participates in overload resolution. Thus, whether or not an implementing declaration is given, invocation expressions may resolve to invocations of the partial method. Because a partial method always returns void
, such invocation expressions will always be expression statements. Furthermore, because a partial method is implicitly private
, such statements will always occur within one of the parts of the type declaration within which the partial method is declared.
If no part of a partial type declaration contains an implementing declaration for a given partial method, any expression statement invoking it is simply removed from the combined type declaration. Thus the invocation expression, including any constituent expressions, has no effect at run-time. The partial method itself is also removed and will not be a member of the combined type declaration.
If an implementing declaration exist for a given partial method, the invocations of the partial methods are retained. The partial method gives rise to a method declaration similar to the implementing partial method declaration except for the following:
- The
partial
modifier is not included - The attributes in the resulting method declaration are the combined attributes of the defining and the implementing partial method declaration in unspecified order. Duplicates are not removed.
- The attributes on the parameters of the resulting method declaration are the combined attributes of the corresponding parameters of the defining and the implementing partial method declaration in unspecified order. Duplicates are not removed.
If a defining declaration but not an implementing declaration is given for a partial method M, the following restrictions apply:
- It is a compile-time error to create a delegate to method (Delegate creation expressions).
- It is a compile-time error to refer to
M
inside an anonymous function that is converted to an expression tree type (Evaluation of anonymous function conversions to expression tree types). - Expressions occurring as part of an invocation of
M
do not affect the definite assignment state (Definite assignment), which can potentially lead to compile-time errors. M
cannot be the entry point for an application (Application Startup).
Partial methods are useful for allowing one part of a type declaration to customize the behavior of another part, e.g., one that is generated by a tool. Consider the following partial class declaration:
partial class Customer
{
string name;
public string Name {
get { return name; }
set {
OnNameChanging(value);
name = value;
OnNameChanged();
}
}
partial void OnNameChanging(string newName);
partial void OnNameChanged();
}
If this class is compiled without any other parts, the defining partial method declarations and their invocations will be removed, and the resulting combined class declaration will be equivalent to the following:
class Customer
{
string name;
public string Name {
get { return name; }
set { name = value; }
}
}
Assume that another part is given, however, which provides implementing declarations of the partial methods:
partial class Customer
{
partial void OnNameChanging(string newName)
{
Console.WriteLine("Changing " + name + " to " + newName);
}
partial void OnNameChanged()
{
Console.WriteLine("Changed to " + name);
}
}
Then the resulting combined class declaration will be equivalent to the following:
class Customer
{
string name;
public string Name {
get { return name; }
set {
OnNameChanging(value);
name = value;
OnNameChanged();
}
}
void OnNameChanging(string newName)
{
Console.WriteLine("Changing " + name + " to " + newName);
}
void OnNameChanged()
{
Console.WriteLine("Changed to " + name);
}
}
Although each part of an extensible type must be declared within the same namespace, the parts are typically written within different namespace declarations. Thus, different using
directives (Using directives) may be present for each part. When interpreting simple names (Type inference) within one part, only the using
directives of the namespace declaration(s) enclosing that part are considered. This may result in the same identifier having different meanings in different parts:
namespace N
{
using List = System.Collections.ArrayList;
partial class A
{
List x; // x has type System.Collections.ArrayList
}
}
namespace N
{
using List = Widgets.LinkedList;
partial class A
{
List y; // y has type Widgets.LinkedList
}
}
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_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 type are divided into the following categories:
- Constants, which represent constant values associated with the class (Constants).
- Fields, which are the variables of the class (Fields).
- Methods, which implement the computations and actions that can be performed by the class (Methods).
- Properties, which define named characteristics and the actions associated with reading and writing those characteristics (Properties).
- Events, which define notifications that can be generated by the class (Events).
- Indexers, which permit instances of the class to be indexed in the same way (syntactically) as arrays (Indexers).
- Operators, which define the expression operators that can be applied to instances of the class (Operators).
- Instance constructors, which implement the actions required to initialize instances of the class (Instance constructors)
- Destructors, which implement the actions to be performed before instances of the class are permanently discarded (Destructors).
- Static constructors, which implement the actions required to initialize the class itself (Static constructors).
- Types, which represent the types that are local to the class (Nested types).
Members that can contain executable code are collectively known as the function members of the class type. The function members of a class type are the methods, properties, events, indexers, operators, instance constructors, destructors, and static constructors of that class type.
A class_declaration creates a new declaration space (Declarations), 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 (Signatures and overloading) of a method must differ from the signatures of all other methods declared in the same class, and two methods declared in the same class may not have signatures that differ solely by
ref
andout
. - The signature of an instance constructor must differ from the signatures of all other instance constructors declared in the same class, and two constructors declared in the same class may not have signatures that differ solely by
ref
andout
. - 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 type (Inheritance) 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).
Each class declaration has an associated bound type (Bound and unbound types), the instance type. For a generic class declaration, the instance type is formed by creating a constructed type (Constructed types) from the type declaration, with each of the supplied type arguments being the corresponding type parameter. Since the instance type uses the type parameters, it can only be used where the type parameters are in scope; that is, inside the class declaration. The instance type is the type of this
for code written inside the class declaration. For non-generic classes, the instance type is simply the declared class. The following shows several class declarations along with their instance types:
class A<T> // instance type: A<T>
{
class B {} // instance type: A<T>.B
class C<U> {} // instance type: A<T>.C<U>
}
class D {} // instance type: D
The non-inherited members of a constructed type are obtained by substituting, for each type_parameter in the member declaration, the corresponding type_argument of the constructed type. The substitution process is based on the semantic meaning of type declarations, and is not simply textual substitution.
For example, given the generic class declaration
class Gen<T,U>
{
public T[,] a;
public void G(int i, T t, Gen<U,T> gt) {...}
public U Prop { get {...} set {...} }
public int H(double d) {...}
}
the constructed type Gen<int[],IComparable<string>>
has the following members:
public int[,][] a;
public void G(int i, int[] t, Gen<IComparable<string>,int[]> gt) {...}
public IComparable<string> Prop { get {...} set {...} }
public int H(double d) {...}
The type of the member a
in the generic class declaration Gen
is "two-dimensional array of T
", so the type of the member a
in the constructed type above is "two-dimensional array of one-dimensional array of int
", or int[,][]
.
Within instance function members, the type of this
is the instance type (The instance type) of the containing declaration.
All members of a generic class can use type parameters from any enclosing class, either directly or as part of a constructed type. When a particular closed constructed type (Open and closed types) is used at run-time, each use of a type parameter is replaced with the actual type argument supplied to the constructed type. For example:
class C<V>
{
public V f1;
public C<V> f2 = null;
public C(V x) {
this.f1 = x;
this.f2 = this;
}
}
class Application
{
static void Main() {
C<int> x1 = new C<int>(1);
Console.WriteLine(x1.f1); // Prints 1
C<double> x2 = new C<double>(3.1415);
Console.WriteLine(x2.f1); // Prints 3.1415
}
}
A class inherits the members of its direct base class type. Inheritance means that a class implicitly contains all members of its direct base class type, 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 fromB
, andB
is derived fromA
, thenC
inherits the members declared inB
as well as the members declared inA
. - 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 (Member access). However, depending on their declared accessibility, inherited members might not be accessible in a derived class.
- A derived class can hide (Hiding through inheritance) inherited members by declaring new members with the same name or signature. Note however that hiding an inherited member does not remove that member—it merely makes that member inaccessible directly through 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 (Implicit reference conversions) 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 that function member is invoked.
The inherited member of a constructed class type are the members of the immediate base class type (Base classes), which is found by substituting the type arguments of the constructed type for each occurrence of the corresponding type parameters in the class_base specification. These members, in turn, are transformed by substituting, for each type_parameter in the member declaration, the corresponding type_argument of the class_base specification.
class B<U>
{
public U F(long index) {...}
}
class D<T>: B<T[]>
{
public T G(string s) {...}
}
In the above example, the constructed type D<int>
has a non-inherited member public int G(string s)
obtained by substituting the type argument int
for the type parameter T
. D<int>
also has an inherited member from the class declaration B
. This inherited member is determined by first determining the base class type B<int[]>
of D<int>
by substituting int
for T
in the base class specification B<T[]>
. Then, as a type argument to B
, int[]
is substituted for U
in public U F(long index)
, yielding the inherited member public int[] F(long index)
.
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 Hiding through inheritance.
If a new
modifier is included in a declaration that doesn't hide an inherited member, a warning to that effect is issued. This warning is suppressed by removing the new
modifier.
A class_member_declaration can have any one of the five possible kinds of declared accessibility (Declared accessibility): 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.
Types that are used in the declaration of a member are called the constituent types of that 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 that member itself (Accessibility constraints).
Members of a class are either static members or instance members. Generally speaking, it is useful to think of static members as belonging to class types and instance members as belonging to objects (instances of class types).
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
M
is referenced in a member_access (Member access) of the formE.M
,E
must denote a type containingM
. It is a compile-time error forE
to denote an instance. - A static field identifies exactly one storage location to be shared by all instances of a given closed class type. No matter how many instances of a given closed class type are created, there is only ever one copy of a static field.
- A static function member (method, property, event, operator, or constructor) 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
M
is referenced in a member_access (Member access) of the formE.M
,E
must denote an instance of a type containingM
. It is a binding-time error forE
to denote a type. - Every instance of a class contains a separate set of all instance fields of the class.
- An instance function member (method, property, indexer, instance constructor, or destructor) operates on a given instance of the class, and this instance can be accessed as
this
(This access).
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 (Simple names) 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 (Member access), instance members must be accessed through instances, and static members must be accessed through types.
A type declared within a class or struct declaration 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
using System;
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.
The fully qualified name (Fully qualified names) for a nested type is S.N
where S
is the fully qualified name of the type in which type N
is declared.
Non-nested types can have public
or internal
declared accessibility and have internal
declared accessibility by default. Nested types can have these forms of declared accessibility too, 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 five forms of declared accessibility (
public
,protected internal
,protected
,internal
, orprivate
) and, like other class members, defaults toprivate
declared accessibility. - A nested type that is declared in a struct can have any of three forms of declared accessibility (
public
,internal
, orprivate
) and, like other struct members, defaults toprivate
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 RemoveFromBack() {...}
public int Count { get {...} }
}
declares a private nested class Node
.
A nested type may hide (Name hiding) a base member. The new
modifier is permitted on nested type declarations so that hiding can be expressed explicitly. The example
using System;
class Base
{
public static void M() {
Console.WriteLine("Base.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
.
A nested type and its containing type do not have a special relationship with regard to this_access (This access). 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. The following example
using System;
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. An instance of C
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.
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
using System;
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
using System;
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
.
A generic class declaration can contain nested type declarations. The type parameters of the enclosing class can be used within the nested types. A nested type declaration can contain additional type parameters that apply only to the nested type.
Every type declaration contained within a generic class declaration is implicitly a generic type declaration. When writing a reference to a type nested within a generic type, the containing constructed type, including its type arguments, must be named. However, from within the outer class, the nested type can be used without qualification; the instance type of the outer class can be implicitly used when constructing the nested type. The following example shows three different correct ways to refer to a constructed type created from Inner
; the first two are equivalent:
class Outer<T>
{
class Inner<U>
{
public static void F(T t, U u) {...}
}
static void F(T t) {
Outer<T>.Inner<string>.F(t, "abc"); // These two statements have
Inner<string>.F(t, "abc"); // the same effect
Outer<int>.Inner<string>.F(3, "abc"); // This type is different
Outer.Inner<string>.F(t, "abc"); // Error, Outer needs type arg
}
}
Although it is bad programming style, a type parameter in a nested type can hide a member or type parameter declared in the outer type:
class Outer<T>
{
class Inner<T> // Valid, hides Outer's T
{
public T t; // Refers to Inner's T
}
}
To facilitate the underlying C# run-time 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 run-time 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 (Inheritance), and can be hidden with the new
modifier (The new modifier).
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 (Destructors) also causes a signature to be reserved (Member names reserved for destructors).
For a property P
(Properties) 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
using System;
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
For an event E
(Events) of delegate type T
, the following signatures are reserved:
void add_E(T handler);
void remove_E(T handler);
For an indexer (Indexers) 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.
Furthermore the member name Item
is reserved.
For a class containing a destructor (Destructors), the following signature is reserved:
void Finalize();
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
: attributes? constant_modifier* 'const' type constant_declarators ';'
;
constant_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
;
constant_declarators
: constant_declarator (',' constant_declarator)*
;
constant_declarator
: identifier '=' constant_expression
;
A constant_declaration may include a set of attributes (Attributes), a new
modifier (The new modifier), and a valid combination of the four access modifiers (Access modifiers). 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 an 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 (Constant expressions) 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 (Implicit conversions).
The type of a constant must be at least as accessible as the constant itself (Accessibility constraints).
The value of a constant is obtained in an expression using a simple_name (Simple names) or a member_access (Member access).
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 Constant expressions, 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 that 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 (Readonly fields) 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
.
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
: attributes? field_modifier* type variable_declarators ';'
;
field_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
| 'static'
| 'readonly'
| 'volatile'
| field_modifier_unsafe
;
variable_declarators
: variable_declarator (',' variable_declarator)*
;
variable_declarator
: identifier ('=' variable_initializer)?
;
variable_initializer
: expression
| array_initializer
;
A field_declaration may include a set of attributes (Attributes), a new
modifier (The new modifier), a valid combination of the four access modifiers (Access modifiers), and a static
modifier (Static and instance fields). In addition, a field_declaration may include a readonly
modifier (Readonly fields) or a volatile
modifier (Volatile fields) but not both. The attributes and modifiers apply to all of the members declared by the field_declaration. It is an 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 that member, optionally followed by an "=
" token and a variable_initializer (Variable initializers) that gives the initial value of that member.
The type of a field must be at least as accessible as the field itself (Accessibility constraints).
The value of a field is obtained in an expression using a simple_name (Simple names) or a member_access (Member access). The value of a non-readonly field is modified using an assignment (Assignment operators). The value of a non-readonly field can be both obtained and modified using postfix increment and decrement operators (Postfix increment and decrement operators) and prefix increment and decrement operators (Prefix increment and decrement operators).
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;
}
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 (Variables) 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 is shared amongst all instances of a closed type (Open and closed types). No matter how many instances of a closed class type are created, there is only ever one copy of a static field for the associated application domain.
For example:
class C<V>
{
static int count = 0;
public C() {
count++;
}
public static int Count {
get { return count; }
}
}
class Application
{
static void Main() {
C<int> x1 = new C<int>();
Console.WriteLine(C<int>.Count); // Prints 1
C<double> x2 = new C<double>();
Console.WriteLine(C<int>.Count); // Prints 1
C<int> x3 = new C<int>();
Console.WriteLine(C<int>.Count); // Prints 2
}
}
An instance field belongs to an instance. Specifically, every instance of a class contains a separate set of all the instance fields of that class.
When a field is referenced in a member_access (Member access) of the form E.M
, if M
is a static field, E
must denote a type containing M
, and if M
is an instance field, E must denote an instance of a type containing M
.
The differences between static and instance members are discussed further in Static and instance members.
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 that declaration or in an instance constructor or static constructor in the same class. (A readonly field can be assigned to 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; for a static field, in the static constructor of the class that contains the field declaration. These are also the only contexts in which it is valid to pass a
readonly
field as anout
orref
parameter.
Attempting to assign to a readonly
field or pass it as an out
or ref
parameter in any other context is a compile-time error.
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 static readonly
instead has much the same effect.
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.
When a field_declaration includes a volatile
modifier, the fields introduced by that 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 (The lock statement). These optimizations can be performed by the compiler, by the run-time 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"; that is, it 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"; that is, it 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 in which 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
,bool
,System.IntPtr
, orSystem.UIntPtr
. - An enum_type having an enum base type of
byte
,sbyte
,short
,ushort
,int
, oruint
.
The example
using System;
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;
}
}
}
}
produces the output:
result = 143
In this example, the method Main
starts a new thread that runs the method Thread2
. This method stores a value into a non-volatile field called 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 finished
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
to 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 any such inconsistency.
The initial value of a field, whether it be a static field or an instance field, is the default value (Default values) 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.
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 Field initialization occurs for all fields, including fields that have variable initializers. Thus, when a class is initialized, all static fields in that class 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 instance fields in that instance 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
.
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 (Static constructors) 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 (as defined in Static constructors) provide that B
's static constructor (and hence B
's static field initializers) must run before A
's static constructor and field initializers.
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 (Constructor initializers) of that 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 Instance constructors.
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.
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
: attributes? method_modifier* 'partial'? return_type member_name type_parameter_list?
'(' formal_parameter_list? ')' type_parameter_constraints_clause*
;
method_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
| 'static'
| 'virtual'
| 'sealed'
| 'override'
| 'abstract'
| 'extern'
| 'async'
| method_modifier_unsafe
;
return_type
: type
| 'void'
;
member_name
: identifier
| interface_type '.' identifier
;
method_body
: block
| '=>' expression ';'
| ';'
;
A method_declaration may include a set of attributes (Attributes) and a valid combination of the four access modifiers (Access modifiers), the new
(The new modifier), static
(Static and instance methods), virtual
(Virtual methods), override
(Override methods), sealed
(Sealed methods), abstract
(Abstract methods), and extern
(External methods) 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 (Access modifiers).
- The declaration does not include the same modifier multiple times.
- The declaration includes at most one of the following modifiers:
static
,virtual
, andoverride
. - The declaration includes at most one of the following modifiers:
new
andoverride
. - If the declaration includes the
abstract
modifier, then the declaration does not include any of the following modifiers:static
,virtual
,sealed
orextern
. - If the declaration includes the
private
modifier, then the declaration does not include any of the following modifiers:virtual
,override
, orabstract
. - If the declaration includes the
sealed
modifier, then the declaration also includes theoverride
modifier. - If the declaration includes the
partial
modifier, then it does not include any of the following modifiers:new
,public
,protected
,internal
,private
,virtual
,sealed
,override
,abstract
, orextern
.
A method that has the async
modifier is an async function and follows the rules described in Async functions.
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. If the declaration includes the partial
modifier, then the return type must be void
.
The member_name specifies the name of the method. Unless the method is an explicit interface member implementation (Explicit interface member implementations), 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 type_parameter_list specifies the type parameters of the method (Type parameters). If a type_parameter_list is specified the method is a generic method. If the method has an extern
modifier, a type_parameter_list cannot be specified.
The optional formal_parameter_list specifies the parameters of the method (Method parameters).
The optional type_parameter_constraints_clauses specify constraints on individual type parameters (Type parameter constraints) and may only be specified if a type_parameter_list is also supplied, and the method does not have an override
modifier.
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 (Accessibility constraints).
The method_body is either a semicolon, a statement body or an expression body. A statement body consists of a block, which specifies the statements to execute when the method is invoked. An expression body consists of =>
followed by an expression and a semicolon, and denotes a single expression to perform when the method is invoked.
For abstract
and extern
methods, the method_body consists simply of a semicolon. For partial
methods the method_body may consist of either a semicolon, a block body or an expression body. For all other methods, the method_body is either a block body or an expression body.
If the method_body consists of a semicolon, then the declaration may not include the async
modifier.
The name, the type parameter list and the formal parameter list of a method define the signature (Signatures and overloading) of the method. Specifically, the signature of a method consists of its name, the number of type parameters and the number, modifiers, and types of its formal parameters. For these purposes, any type parameter of the method that occurs in the type of a formal parameter is identified not by its name, but by its ordinal position in the type argument list of the method.The return type is not part of a method's signature, nor are the names of the type parameters or 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, and two methods declared in the same class may not have signatures that differ solely by ref
and out
.
The method's type_parameters are in scope throughout the method_declaration, and can be used to form types throughout that scope in return_type, method_body, and type_parameter_constraints_clauses but not in attributes.
All formal parameters and type parameters must have different names.
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_parameter)*
;
fixed_parameter
: attributes? parameter_modifier? type identifier default_argument?
;
default_argument
: '=' expression
;
parameter_modifier
: 'ref'
| 'out'
| 'this'
;
parameter_array
: attributes? '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 (Attributes), an optional ref
, out
or this
modifier, a type, an identifier and an optional default_argument. Each fixed_parameter declares a parameter of the given type with the given name. The this
modifier designates the method as an extension method and is only allowed on the first parameter of a static method. Extension methods are further described in Extension methods.
A fixed_parameter with a default_argument is known as an optional parameter, whereas a fixed_parameter without a default_argument is a required parameter. A required parameter may not appear after an optional parameter in a formal_parameter_list.
A ref
or out
parameter cannot have a default_argument. The expression in a default_argument must be one of the following:
- a constant_expression
- an expression of the form
new S()
whereS
is a value type - an expression of the form
default(S)
whereS
is a value type
The expression must be implicitly convertible by an identity or nullable conversion to the type of the parameter.
If optional parameters occur in an implementing partial method declaration (Partial methods) , an explicit interface member implementation (Explicit interface member implementations) or in a single-parameter indexer declaration (Indexers) the compiler should give a warning, since these members can never be invoked in a way that permits arguments to be omitted.
A parameter_array consists of an optional set of attributes (Attributes), 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 (Array types). 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 described further in Parameter arrays.
A parameter_array may occur after an optional parameter, but cannot have a default value -- the omission of arguments for a parameter_array would instead result in the creation of an empty array.
The following example illustrates different kinds of parameters:
public void M(
ref int i,
decimal d,
bool b = false,
bool? n = false,
string s = "Hello",
object o = null,
T t = default(T),
params int[] a
) { }
In the formal_parameter_list for M
, i
is a required ref parameter, d
is a required value parameter, b
, s
, o
and t
are optional value parameters and a
is a parameter array.
A method declaration creates a separate declaration space for parameters, type parameters and local variables. Names are introduced into this declaration space by the type parameter list and the formal parameter list of the method and by local variable declarations in the block of the method. It is an error for two members of a method declaration space to have the same name. It is an error for the method declaration space and the local variable declaration space of a nested declaration space to contain elements with the same name.
A method invocation (Method invocations) 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 (Simple names).
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 Signatures and overloading, the ref
and out
modifiers are part of a method's signature, but the params
modifier is not.
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 that is implicitly convertible (Implicit conversions) 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.
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 (Precise rules for determining definite assignment) 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.
A method declared as an iterator (Iterators) cannot have reference parameters.
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
.
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 (Precise rules for determining definite assignment) 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.
A method declared as a partial method (Partial methods) or an iterator (Iterators) cannot have output parameters.
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.
A parameter declared with a params
modifier is a parameter array. If a formal parameter list includes a parameter array, it must be the last 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 modifiers ref
and out
.
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 that is implicitly convertible (Implicit conversions) 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 that is implicitly convertible (Implicit conversions) 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 (Value parameters) 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 (Applicable function member). The expanded form of a method is available only if the normal form of the method is not applicable and only if an applicable 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 args) {
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[]
).
When a method declaration includes a static
modifier, that 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 that instance can be accessed as this
(This access).
When a method is referenced in a member_access (Member access) of the form E.M
, if M
is a static method, E
must denote a type containing M
, and if M
is an instance method, E
must denote an instance of a type containing M
.
The differences between static and instance members are discussed further in Static and instance members.
When an instance method declaration includes a virtual
modifier, that 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 that method (Override methods).
In a virtual method invocation, the run-time type of the instance for which that 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
, andA
, to select a specific methodM
from the set of methods declared in and inherited byC
. This is described in Method invocations. - Then, if
M
is a non-virtual method,M
is invoked. - Otherwise,
M
is a virtual method, and the most derived implementation ofM
with respect toR
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 introducingvirtual
declaration ofM
, then this is the most derived implementation ofM
. - Otherwise, if
R
contains anoverride
ofM
, then this is the most derived implementation ofM
. - Otherwise, the most derived implementation of
M
with respect toR
is the same as the most derived implementation ofM
with respect to the direct base class ofR
.
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.
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 that 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 type of C
, starting with the direct base class type of C
and continuing with each successive direct base class type, until in a given base class type at least one accessible method is located which has the same signature as M
after substitution of type arguments. 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.
- There is exactly one such overridden base method. This restriction has effect only if the base class type is a constructed type where the substitution of type arguments makes the signature of two methods the same.
- 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 method and the overridden base method have the same return type.
- 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. However, if the overridden base method is protected internal and it is declared in a different assembly than the assembly containing the override method then the override method's declared accessibility must be protected.
- The override declaration does not specify type-parameter-constraints-clauses. Instead the constraints are inherited from the overridden base method. Note that constraints that are type parameters in the overridden method may be replaced by type arguments in the inherited constraint. This can lead to constraints that are not legal when explicitly specified, such as value types or sealed types.
The following example demonstrates how the overriding rules work for generic classes:
abstract class C<T>
{
public virtual T F() {...}
public virtual C<T> G() {...}
public virtual void H(C<T> x) {...}
}
class D: C<string>
{
public override string F() {...} // Ok
public override C<string> G() {...} // Ok
public override void H(C<T> x) {...} // Error, should be C<string>
}
class E<T,U>: C<U>
{
public override U F() {...} // Ok
public override C<U> G() {...} // Ok
public override void H(C<T> x) {...} // Error, should be C<U>
}
An override declaration can access the overridden base method using a base_access (Base access). 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 body of 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
.
When an instance method declaration includes a sealed
modifier, that method is said to be a sealed method. If an instance method declaration includes the sealed
modifier, it must also include the override
modifier. Use of the sealed
modifier prevents a derived class from further overriding the method.
In 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
.
When an instance method declaration includes an abstract
modifier, that method is said to be an abstract method. Although an abstract method is implicitly also a virtual method, it cannot have the modifier virtual
.
An abstract method declaration introduces a new virtual method but does not provide an implementation of that method. Instead, non-abstract derived classes are required to provide their own implementation by overriding that 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 (Abstract classes).
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 (Base access) 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.
When a method declaration includes an extern
modifier, that method is said to be an external method. External methods are implemented externally, typically 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. An external method may not be generic.
The extern
modifier is typically used in conjunction with a DllImport
attribute (Interoperation with COM and Win32 components), 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);
}
When a method declaration includes a partial
modifier, that method is said to be a partial method. Partial methods can only be declared as members of partial types (Partial types), and are subject to a number of restrictions. Partial methods are further described in Partial methods.
When the first parameter of a method includes the this
modifier, that method is said to be an extension method. Extension methods can only be declared in non-generic, non-nested static classes. The first parameter of an extension method can have no modifiers other than this
, and the parameter type cannot be a pointer type.
The following is an example of a static class that declares two extension methods:
public static class Extensions
{
public static int ToInt32(this string s) {
return Int32.Parse(s);
}
public static T[] Slice<T>(this T[] source, int index, int count) {
if (index < 0 || count < 0 || source.Length - index < count)
throw new ArgumentException();
T[] result = new T[count];
Array.Copy(source, index, result, 0, count);
return result;
}
}
An extension method is a regular static method. In addition, where its enclosing static class is in scope, an extension method can be invoked using instance method invocation syntax (Extension method invocations), using the receiver expression as the first argument.
The following program uses the extension methods declared above:
static class Program
{
static void Main() {
string[] strings = { "1", "22", "333", "4444" };
foreach (string s in strings.Slice(1, 2)) {
Console.WriteLine(s.ToInt32());
}
}
}
The Slice
method is available on the string[]
, and the ToInt32
method is available on string
, because they have been declared as extension methods. The meaning of the program is the same as the following, using ordinary static method calls:
static class Program
{
static void Main() {
string[] strings = { "1", "22", "333", "4444" };
foreach (string s in Extensions.Slice(strings, 1, 2)) {
Console.WriteLine(Extensions.ToInt32(s));
}
}
}
The method_body of a method declaration consists of either a block body, an expression body or a semicolon.
The result type of a method is void
if the return type is void
, or if the method is async and the return type is System.Threading.Tasks.Task
. Otherwise, the result type of a non-async method is its return type, and the result type of an async method with return type System.Threading.Tasks.Task<T>
is T
.
When a method has a void
result type and a block body, return
statements (The return statement) in the block are not permitted to specify an expression. If execution of the block of a void method completes normally (that is, control flows off the end of the method body), that method simply returns to its current caller.
When a method has a void
result and an expression body, the expression E
must be a statement_expression, and the body is exactly equivalent to a block body of the form { E; }
.
When a method has a non-void result type and a block body, each return
statement in the block must specify an expression that is implicitly convertible to the result type. The endpoint of a block body of a value-returning method must not be reachable. In other words, in a value-returning method with a block body, control is not permitted to flow off the end of the method body.
When a method has a non-void result type and an expression body, the expression must be implicitly convertible to the result type, and the body is exactly equivalent to a block body of the form { return E; }
.
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;
}
}
public int I(bool b) => b ? 1 : 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. The I
method is correct, because its body is equivalent to a statement block with just a single return statement in it.
The method overload resolution rules are described in Type inference.
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
: attributes? property_modifier* type member_name property_body
;
property_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
| 'static'
| 'virtual'
| 'sealed'
| 'override'
| 'abstract'
| 'extern'
| property_modifier_unsafe
;
property_body
: '{' accessor_declarations '}' property_initializer?
| '=>' expression ';'
;
property_initializer
: '=' variable_initializer ';'
;
A property_declaration may include a set of attributes (Attributes) and a valid combination of the four access modifiers (Access modifiers), the new
(The new modifier), static
(Static and instance methods), virtual
(Virtual methods), override
(Override methods), sealed
(Sealed methods), abstract
(Abstract methods), and extern
(External methods) modifiers.
Property declarations are subject to the same rules as method declarations (Methods) 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 (Explicit interface member implementations), 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 (Accessibility constraints).
A property_body may either consist of an accessor body or an expression body. In an accessor body, accessor_declarations, which must be enclosed in "{
" and "}
" tokens, declare the accessors (Accessors) of the property. The accessors specify the executable statements associated with reading and writing the property.
An expression body consisting of =>
followed by an expression E
and a semicolon is exactly equivalent to the statement body { get { return E; } }
, and can therefore only be used to specify getter-only properties where the result of the getter is given by a single expression.
A property_initializer may only be given for an automatically implemented property (Automatically implemented properties), and causes the initialization of the underlying field of such properties with the value given by the expression.
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.
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 that instance can be accessed as this
(This access) in the accessors of that property.
When a property is referenced in a member_access (Member access) of the form E.M
, if M
is a static property, E
must denote a type containing M
, and if M
is an instance property, E must denote an instance of a type containing M
.
The differences between static and instance members are discussed further in Static and instance members.
The accessor_declarations of a property specify the executable statements associated with reading and writing that property.
accessor_declarations
: get_accessor_declaration set_accessor_declaration?
| set_accessor_declaration get_accessor_declaration?
;
get_accessor_declaration
: attributes? accessor_modifier? 'get' accessor_body
;
set_accessor_declaration
: attributes? accessor_modifier? 'set' accessor_body
;
accessor_modifier
: 'protected'
| 'internal'
| 'private'
| 'protected' 'internal'
| 'internal' 'protected'
;
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 optional accessor_modifier and an accessor_body.
The use of accessor_modifiers is governed by the following restrictions:
- An accessor_modifier may not be used in an interface or in an explicit interface member implementation.
- For a property or indexer that has no
override
modifer, an accessor_modifier is permitted only if the property or indexer has both aget
andset
accessor, and then is permitted only on one of those accessors. - For a property or indexer that includes an
override
modifer, an accessor must match the accessor_modifier, if any, of the accessor being overridden. - The accessor_modifier must declare an accessibility that is strictly more restrictive than the declared accessibility of the property or indexer itself. To be precise:
- If the property or indexer has a declared accessibility of
public
, the accessor_modifier may be eitherprotected internal
,internal
,protected
, orprivate
. - If the property or indexer has a declared accessibility of
protected internal
, the accessor_modifier may be eitherinternal
,protected
, orprivate
. - If the property or indexer has a declared accessibility of
internal
orprotected
, the accessor_modifier must beprivate
. - If the property or indexer has a declared accessibility of
private
, no accessor_modifier may be used.
- If the property or indexer has a declared accessibility of
For abstract
and extern
properties, the accessor_body for each accessor specified is simply a semicolon. A non-abstract, non-extern property may have each accessor_body be a semicolon, in which case it is an automatically implemented property (Automatically implemented properties). An automatically implemented property must have at least a get accessor. For the accessors of any other non-abstract, non-extern property, the accessor_body is a block which specifies 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 (Values of expressions). The body of a get
accessor must conform to the rules for value-returning methods described in Method body. 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 (Assignment operators), or as the operand of ++
or --
(Postfix increment and decrement operators, Prefix increment and decrement operators), 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 (Simple assignment). The body of a set
accessor must conform to the rules for void
methods described in Method body. 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 or constant 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 aset
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 that 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 to be reported, since 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.
An automatically implemented property (or auto-property for short), is a non-abstract non-extern property with semicolon-only accessor bodies. Auto-properties must have a get accessor and can optionally have a set accessor.
When a property is specified as an automatically implemented property, a hidden backing field is automatically available for the property, and the accessors are implemented to read from and write to that backing field. If the auto-property has no set accessor, the backing field is considered readonly
(Readonly fields). Just like a readonly
field, a getter-only auto-property can also be assigned to in the body of a constructor of the enclosing class. Such an assignment assigns directly to the readonly backing field of the property.
An auto-property may optionally have a property_initializer, which is applied directly to the backing field as a variable_initializer (Variable initializers).
The following example:
public class Point {
public int X { get; set; } = 0;
public int Y { get; set; } = 0;
}
is equivalent to the following declaration:
public class Point {
private int __x = 0;
private int __y = 0;
public int X { get { return __x; } set { __x = value; } }
public int Y { get { return __y; } set { __y = value; } }
}
The following example:
public class ReadOnlyPoint
{
public int X { get; }
public int Y { get; }
public ReadOnlyPoint(int x, int y) { X = x; Y = y; }
}
is equivalent to the following declaration:
public class ReadOnlyPoint
{
private readonly int __x;
private readonly int __y;
public int X { get { return __x; } }
public int Y { get { return __y; } }
public ReadOnlyPoint(int x, int y) { __x = x; __y = y; }
}
Notice that the assignments to the readonly field are legal, because they occur within the constructor.
If an accessor has an accessor_modifier, the accessibility domain (Accessibility domains) of the accessor is determined using the declared accessibility of the accessor_modifier. If an accessor does not have an accessor_modifier, the accessibility domain of the accessor is determined from the declared accessibility of the property or indexer.
The presence of an accessor_modifier never affects member lookup (Operators) or overload resolution (Overload resolution). The modifiers on the property or indexer always determine which property or indexer is bound to, regardless of the context of the access.
Once a particular property or indexer has been selected, the accessibility domains of the specific accessors involved are used to determine if that usage is valid:
- If the usage is as a value (Values of expressions), the
get
accessor must exist and be accessible. - If the usage is as the target of a simple assignment (Simple assignment), the
set
accessor must exist and be accessible. - If the usage is as the target of compound assignment (Compound assignment), or as the target of the
++
or--
operators (Function members.9, Invocation expressions), both theget
accessors and theset
accessor must exist and be accessible.
In the following example, the property A.Text
is hidden by the property B.Text
, even in contexts where only the set
accessor is called. In contrast, the property B.Count
is not accessible to class M
, so the accessible property A.Count
is used instead.
class A
{
public string Text {
get { return "hello"; }
set { }
}
public int Count {
get { return 5; }
set { }
}
}
class B: A
{
private string text = "goodbye";
private int count = 0;
new public string Text {
get { return text; }
protected set { text = value; }
}
new protected int Count {
get { return count; }
set { count = value; }
}
}
class M
{
static void Main() {
B b = new B();
b.Count = 12; // Calls A.Count set accessor
int i = b.Count; // Calls A.Count get accessor
b.Text = "howdy"; // Error, B.Text set accessor not accessible
string s = b.Text; // Calls B.Text get accessor
}
}
An accessor that is used to implement an interface may not have an accessor_modifier. If only one accessor is used to implement an interface, the other accessor may be declared with an accessor_modifier:
public interface I
{
string Prop { get; }
}
public class C: I
{
public Prop {
get { return "April"; } // Must not have a modifier here
internal set {...} // Ok, because I.Prop has no set accessor
}
}
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 (Abstract classes).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 Virtual methods, Override methods, Sealed methods, and Abstract methods 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, avoid
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.
When a property is declared as an override
, any overridden accessors must be accessible to the overriding code. In addition, the declared accessibility of both the property or indexer itself, and of the accessors, must match that of the overridden member and accessors. For example:
public class B
{
public virtual int P {
protected set {...}
get {...}
}
}
public class D: B
{
public override int P {
protected set {...} // Must specify protected here
get {...} // Must not have a modifier here
}
}
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
: attributes? event_modifier* 'event' type variable_declarators ';'
| attributes? event_modifier* 'event' type member_name '{' event_accessor_declarations '}'
;
event_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
| 'static'
| 'virtual'
| 'sealed'
| 'override'
| 'abstract'
| 'extern'
| event_modifier_unsafe
;
event_accessor_declarations
: add_accessor_declaration remove_accessor_declaration
| remove_accessor_declaration add_accessor_declaration
;
add_accessor_declaration
: attributes? 'add' block
;
remove_accessor_declaration
: attributes? 'remove' block
;
An event_declaration may include a set of attributes (Attributes) and a valid combination of the four access modifiers (Access modifiers), the new
(The new modifier), static
(Static and instance methods), virtual
(Virtual methods), override
(Override methods), sealed
(Sealed methods), abstract
(Abstract methods), and extern
(External methods) modifiers.
Event declarations are subject to the same rules as method declarations (Methods) with regard to valid combinations of modifiers.
The type of an event declaration must be a delegate_type (Reference types), and that delegate_type must be at least as accessible as the event itself (Accessibility constraints).
An event declaration may include event_accessor_declarations. However, if it does not, for non-extern, non-abstract events, the compiler supplies them automatically (Field-like events); 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 brace-delimited 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 an error for it to include both the extern
modifier and event_accessor_declarations.
It is a compile-time error for a variable_declarator of an event declaration with an abstract
or external
modifier to include a variable_initializer.
An event can be used as the left-hand operand of the +=
and -=
operators (Event assignment). These operators are used, respectively, to attach event handlers to or to remove event handlers 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 having the type of x
, with the value of x
after the assignment). 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 LoginDialog
instance constructor creates two Button
instances and attaches event handlers to the Click
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 (Delegates) 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. The addition and removal operations are thread safe, and may (but are not required to) be done while holding the lock (The lock statement) on the containing object for an instance event, or the type object (Anonymous object creation expressions) for a static event.
Thus, an instance event declaration of the form:
class X
{
public event D Ev;
}
will be compiled to something equivalent to:
class X
{
private D __Ev; // field to hold the delegate
public event D Ev {
add {
/* add the delegate in a thread safe way */
}
remove {
/* remove the delegate in a thread safe way */
}
}
}
Within the class X
, references to Ev
on the left-hand side of the +=
and -=
operators cause the add and remove accessors to be invoked. All other references to Ev
are compiled to reference the hidden field __Ev
instead (Member access). The name "__Ev
" is arbitrary; the hidden field could have any name or no name at all.
Event declarations typically omit event_accessor_declarations, as in the Button
example above. One 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. Specifically, 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 Method body. 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 or constant 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.
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
(This access) in the accessors of that event.
When an event is referenced in a member_access (Member access) of the form E.M
, if M
is a static event, E
must denote a type containing M
, and if M
is an instance event, E must denote an instance of a type containing M
.
The differences between static and instance members are discussed further in Static and instance members.
A virtual
event declaration specifies that the accessors of that 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 abstract event declaration provides no actual implementation, it cannot provide brace-delimited event_accessor_declarations.
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 (Abstract classes).
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 Virtual methods, Override methods, Sealed methods, and Abstract methods 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.
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
: attributes? indexer_modifier* indexer_declarator indexer_body
;
indexer_modifier
: 'new'
| 'public'
| 'protected'
| 'internal'
| 'private'
| 'virtual'
| 'sealed'
| 'override'
| 'abstract'
| 'extern'
| indexer_modifier_unsafe
;
indexer_declarator
: type 'this' '[' formal_parameter_list ']'
| type interface_type '.' 'this' '[' formal_parameter_list ']'
;
indexer_body
: '{' accessor_declarations '}'
| '=>' expression ';'
;
An indexer_declaration may include a set of attributes (Attributes) and a valid combination of the four access modifiers (Access modifiers), the new
(The new modifier), virtual
(Virtual methods), override
(Override methods), sealed
(Sealed methods), abstract
(Abstract methods), and extern
(External methods) modifiers.
Indexer declarations are subject to the same rules as method declarations (Methods) with regard to valid combinations of modifiers, with the one exception being that the static modifier is not permitted on an indexer declaration.
The modifiers virtual
, override
, and abstract
are mutually exclusive except in one case. The abstract
and override
modifiers may be used together so that an abstract indexer can override a virtual one.
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 (Method parameters), 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 (Accessibility constraints).
An indexer_body may either consist of an accessor body or an expression body. In an accessor body, accessor_declarations, which must be enclosed in "{
" and "}
" tokens, declare the accessors (Accessors) of the property. The accessors specify the executable statements associated with reading and writing the property.
An expression body consisting of "=>
" followed by an expression E
and a semicolon is exactly equivalent to the statement body { get { return E; } }
, and can therefore only be used to specify getter-only indexers where the result of the getter is given by a single expression.
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 (Signatures and overloading) 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 (Simple names) or a member_access (Member access), whereas an indexer element is accessed through an element_access (Indexer access).
- 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 aget
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 namedvalue
, whereas aset
accessor of an indexer corresponds to a method with the same formal parameter list as the indexer, plus an additional parameter namedvalue
. - 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
, whereP
is the property name. In an overriding indexer declaration, the inherited indexer is accessed using the syntaxbase[E]
, whereE
is a comma separated list of expressions. - There is no concept of an "automatically implemented indexer". It is an error to have a non-abstract, non-external indexer with semicolon accessors.
Aside from these differences, all rules defined in Accessors and Automatically implemented properties 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 * 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.
using System;
class Grid
{
const int NumRows = 26;
const int NumCols = 10;
int[,] cells = new int[NumRows, NumCols];
public int this[char c, int col] {
get {
c = Char.ToUpper(c);
if (c < 'A' || c > 'Z') {
throw new ArgumentException();
}
if (col < 0 || col >= NumCols) {
throw new IndexOutOfRangeException();
}
return cells[c - 'A', col];
}
set {
c = Char.ToUpper(c);
if (c < 'A' || c > 'Z') {
throw new ArgumentException();
}
if (col < 0 || col >= NumCols) {
throw new IndexOutOfRangeException();
}
cells[c - 'A', col] = value;
}
}
}
The indexer overload resolution rules are described in Type inference.
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
: attributes? operator_modifier+ operator_declarator operator_body
;
operator_modifier
: 'public'
| 'static'
| 'extern'
| operator_modifier_unsafe
;
operator_declarator
: unary_operator_declarator
| binary_operator_declarator
| conversion_operator_declarator
;
unary_operator_declarator
: type 'operator' overloadable_unary_operator '(' type identifier ')'
;
overloadable_unary_operator
: '+' | '-' | '!' | '~' | '++' | '--' | 'true' | 'false'
;
binary_operator_declarator
: type 'operator' overloadable_binary_operator '(' type identifier ',' type identifier ')'
;
overloadable_binary_operator
: '+' | '-' | '*' | '/' | '%' | '&' | '|' | '^' | '<<'
| 'right_shift' | '==' | '!=' | '>' | '<' | '>=' | '<='
;
conversion_operator_declarator
: 'implicit' 'operator' type '(' type identifier ')'
| 'explicit' 'operator' type '(' type identifier ')'
;
operator_body
: block
| '=>' expression ';'
| ';'
;
There are three categories of overloadable operators: Unary operators (Unary operators), binary operators (Binary operators), and conversion operators (Conversion operators).
The operator_body is either a semicolon, a statement body or an expression body. A statement body consists of a block, which specifies the statements to execute when the operator is invoked. The block must conform to the rules for value-returning methods described in Method body. An expression body consists of =>
followed by an expression and a semicolon, and denotes a single expression to perform when the operator is invoked.
For extern
operators, the operator_body consists simply of a semicolon. For all other operators, the operator_body is either a block body or an expression body.
The following rules apply to all operator declarations:
- An operator declaration must include both a
public
and astatic
modifier. - The parameter(s) of an operator must be value parameters (Value parameters). It is a compile-time error for an operator declaration to specify
ref
orout
parameters. - The signature of an operator (Unary operators, Binary operators, Conversion operators) 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 (Accessibility constraints).
- It is an 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 Operators.
Additional information on conversion operators can be found in User-defined conversions.
The following rules apply to unary operator declarations, where T
denotes the instance type of the class or struct that contains the operator declaration:
- A unary
+
,-
,!
, or~
operator must take a single parameter of typeT
orT?
and can return any type. - A unary
++
or--
operator must take a single parameter of typeT
orT?
and must return that same type or a type derived from it. - A unary
true
orfalse
operator must take a single parameter of typeT
orT?
and must return typebool
.
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 User-defined conditional logical operators and Boolean expressions.
The following example shows an implementation and subsequent usage of operator ++
for an integer vector class:
public class IntVector
{
public IntVector(int length) {...}
public int Length {...} // read-only property
public int this[int index] {...} // read-write indexer
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
{
static void Main() {
IntVector iv1 = new IntVector(4); // vector of 4 x 0
IntVector iv2;
iv2 = iv1++; // iv2 contains 4 x 0, iv1 contains 4 x 1
iv2 = ++iv1; // iv2 contains 4 x 2, iv1 contains 4 x 2
}
}
Note how the operator method returns the value produced by adding 1 to the operand, just like the postfix increment and decrement operators (Postfix increment and decrement operators), and the prefix increment and decrement operators (Prefix increment and decrement operators). Unlike in C++, this method need not modify the value of its operand directly. In fact, modifying the operand value would violate the standard semantics of the postfix increment operator.
The following rules apply to binary operator declarations, where T
denotes the instance type of the class or struct that contains the operator declaration:
- A binary non-shift operator must take two parameters, at least one of which must have type
T
orT?
, and can return any type. - A binary
<<
or>>
operator must take two parameters, the first of which must have typeT
orT?
and the second of which must have typeint
orint?
, and 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 the 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 ==
andoperator !=
operator >
andoperator <
operator >=
andoperator <=
A conversion operator declaration introduces a user-defined conversion (User-defined conversions) 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 Implicit conversions.
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 Explicit conversions.
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.
For a given source type S
and target type T
, if S
or T
are nullable types, let S0
and T0
refer to their underlying types, otherwise S0
and T0
are equal to S
and T
respectively. 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:
S0
andT0
are different types.- Either
S0
orT0
is the class or struct type in which the operator declaration takes place. - Neither
S0
norT0
is an interface_type. - Excluding user-defined conversions, a conversion does not exist from
S
toT
or fromT
toS
.
For the purposes of these rules, any type parameters associated with S
or T
are considered to be unique types that have no inheritance relationship with other types, and any constraints on those type parameters are ignored.
In the example
class C<T> {...}
class D<T>: C<T>
{
public static implicit operator C<int>(D<T> value) {...} // Ok
public static implicit operator C<string>(D<T> value) {...} // Ok
public static implicit operator C<T>(D<T> value) {...} // Error
}
the first two operator declarations are permitted because, for the purposes of Indexers.3, T
and int
and string
respectively are considered unique types with no relationship. However, the third operator is an error because C<T>
is the base class of D<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 directly 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.
However, it is possible to declare operators on generic types that, for particular type arguments, specify conversions that already exist as pre-defined conversions. In the example
struct Convertible<T>
{
public static implicit operator Convertible<T>(T value) {...}
public static explicit operator T(Convertible<T> value) {...}
}
when type object
is specified as a type argument for T
, the second operator declares a conversion that already exists (an implicit, and therefore also an explicit, conversion exists from any type to type object
).
In cases where a pre-defined conversion exists between two types, any user-defined conversions between those types are ignored. Specifically:
- If a pre-defined implicit conversion (Implicit conversions) exists from type
S
to typeT
, all user-defined conversions (implicit or explicit) fromS
toT
are ignored. - If a pre-defined explicit conversion (Explicit conversions) exists from type
S
to typeT
, any user-defined explicit conversions fromS
toT
are ignored. Furthermore:
If T
is an interface type, user-defined implicit conversions from S
to T
are ignored.
Otherwise, user-defined implicit conversions from S
to T
are still considered.
For all types but object
, the operators declared by the Convertible<T>
type above do not conflict with pre-defined conversions. For example:
void F(int i, Convertible<int> n) {
i = n; // Error
i = (int)n; // User-defined explicit conversion
n = i; // User-defined implicit conversion
n = (Convertible<int>)i; // User-defined implicit conversion
}
However, for type object
, pre-defined conversions hide the user-defined conversions in all cases but one:
void F(object o, Convertible<object> n) {
o = n; // Pre-defined boxing conversion
o = (object)n; // Pre-defined boxing conversion
n = o; // User-defined implicit conversion
n = (Convertible<object>)o; // Pre-defined unboxing conversion
}
User-defined conversions are not allowed to convert from or to interface_types. In particular, this restriction 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
.
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
: attributes? constructor_modifier* constructor_declarator constructor_body
;
constructor_modifier
: 'public'
| 'protected'
| 'internal'
| 'private'
| 'extern'
| constructor_modifier_unsafe
;
constructor_declarator
: identifier '(' formal_parameter_list? ')' constructor_initializer?
;
constructor_initializer
: ':' 'base' '(' argument_list? ')'
| ':' 'this' '(' argument_list? ')'
;
constructor_body
: block
| ';'
;
A constructor_declaration may include a set of attributes (Attributes), a valid combination of the four access modifiers (Access modifiers), and an extern
(External methods) 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 instance 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 (Methods). The formal parameter list defines the signature (Signatures and overloading) of an instance constructor and governs the process whereby overload resolution (Type inference) 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 (Accessibility constraints).
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 Constructor initializers.
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 (Method body).
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 (Default constructors).
Instance constructors are invoked by object_creation_expressions (Object creation expressions) and through 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:
- An instance constructor initializer of the form
base(argument_list)
orbase()
causes an instance constructor from the direct base class to be invoked. That constructor is selected using argument_list if present and the overload resolution rules of Overload resolution. The set of candidate instance constructors consists of all accessible instance constructors contained in the direct base class, or the default constructor (Default constructors), if no instance constructors are declared in the direct base class. If this 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-list)
orthis()
causes an instance constructor from the class itself to be invoked. The constructor is selected using argument_list if present and the overload resolution rules of Overload resolution. The set of candidate instance constructors consists of all accessible instance constructors declared in the class itself. If this 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 constructor initializer, a constructor initializer of the form base()
is implicitly provided. Thus, an instance constructor declaration of the form
C(...) {...}
is exactly equivalent to
C(...): base() {...}
The scope of the parameters given by the formal_parameter_list of an instance constructor declaration includes the constructor initializer of that declaration. Thus, a constructor initializer is permitted to access the parameters of the 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 constructor initializer, as is it a compile-time error for an argument expression to reference any instance member through a simple_name.
When an instance constructor has no constructor initializer, or it has a constructor initializer of the form base(...)
, that constructor implicitly performs the initializations specified by the variable_initializers of the instance fields declared in its class. This corresponds to a sequence of assignments that are executed immediately upon entry to the constructor and before the implicit invocation of the direct base class constructor. The variable initializers are executed in the textual order in which they appear in the class declaration.
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.
Given 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);
}
}
when new B()
is used to create an instance of 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. 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; it 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;
}
}
If a class contains no instance constructor declarations, a default instance constructor is automatically provided. That default constructor simply invokes the parameterless constructor of the direct base class. 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. If overload resolution is unable to determine a unique best candidate for the base class constructor initializer then a compile-time error occurs.
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() {}
}
When a class T
declares only private instance constructors, it is not possible for classes outside the program text of T
to derive from T
or to directly create instances of T
. Thus, if a class contains only static members and isn't intended to be instantiated, adding an empty private instance constructor will prevent instantiation. 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.
The this(...)
form of 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 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");
A static constructor is a member that implements the actions required to initialize a closed class type. Static constructors are declared using static_constructor_declarations:
static_constructor_declaration
: attributes? static_constructor_modifiers identifier '(' ')' static_constructor_body
;
static_constructor_modifiers
: 'extern'? 'static'
| 'static' 'extern'?
| static_constructor_modifiers_unsafe
;
static_constructor_body
: block
| ';'
;
A static_constructor_declaration may include a set of attributes (Attributes) and an extern
modifier (External methods).
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 (Method body).
Static constructors are not inherited, and cannot be called directly.
The static constructor for a closed class type 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 type is created.
- Any of the static members of the class type are referenced.
If a class contains the Main
method (Application Startup) in which execution begins, the static constructor for that class executes before the Main
method is called.
To initialize a new closed class type, first a new set of static fields (Static and instance fields) for that particular closed type is created. Each of the static fields is initialized to its default value (Default values). Next, the static field initializers (Static field initialization) are executed for those static fields. Finally, the static constructor is executed.
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 2.
Because the static constructor is executed exactly once for each closed constructed class type, it is a convenient place to enforce run-time checks on the type parameter that cannot be checked at compile-time via constraints (Type parameter constraints). For example, the following type uses a static constructor to enforce that the type argument is an enum:
class Gen<T> where T: struct
{
static Gen() {
if (!typeof(T).IsEnum) {
throw new ArgumentException("T must be an enum");
}
}
}
A destructor is a member that implements the actions required to destruct an instance of a class. A destructor is declared using a destructor_declaration:
destructor_declaration
: attributes? 'extern'? '~' identifier '(' ')' destructor_body
| destructor_declaration_unsafe
;
destructor_body
: block
| ';'
;
A destructor_declaration may include a set of attributes (Attributes).
The identifier of a destructor_declaration 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 (Method body).
Destructors are not inherited. Thus, a class has no destructors other than the one which may be declared in that class.
Since a destructor is required to have no parameters, it cannot be overloaded, so 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 that 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 that instance's 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 Automatic memory management.
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
}
}
contains two 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 How exceptions are handled.
A function member (Function members) implemented using an iterator block (Blocks) is called an iterator.
An iterator block may be used as the body of a function member as long as the return type of the corresponding function member is one of the enumerator interfaces (Enumerator interfaces) or one of the enumerable interfaces (Enumerable interfaces). It can occur as a method_body, operator_body or accessor_body, whereas events, instance constructors, static constructors and destructors cannot be implemented as iterators.
When a function member is implemented using an iterator block, it is a compile-time error for the formal parameter list of the function member to specify any ref
or out
parameters.
The enumerator interfaces are the non-generic interface System.Collections.IEnumerator
and all instantiations of the generic interface System.Collections.Generic.IEnumerator<T>
. For the sake of brevity, in this chapter these interfaces are referenced as IEnumerator
and IEnumerator<T>
, respectively.
The enumerable interfaces are the non-generic interface System.Collections.IEnumerable
and all instantiations of the generic interface System.Collections.Generic.IEnumerable<T>
. For the sake of brevity, in this chapter these interfaces are referenced as IEnumerable
and IEnumerable<T>
, respectively.
An iterator produces a sequence of values, all of the same type. This type is called the yield type of the iterator.
- The yield type of an iterator that returns
IEnumerator
orIEnumerable
isobject
. - The yield type of an iterator that returns
IEnumerator<T>
orIEnumerable<T>
isT
.
When a function member returning an enumerator interface type is implemented using an iterator block, invoking the function member does not immediately execute the code in the iterator block. Instead, an enumerator object is created and returned. This object encapsulates the code specified in the iterator block, and execution of the code in the iterator block occurs when the enumerator object's MoveNext
method is invoked. An enumerator object has the following characteristics:
- It implements
IEnumerator
andIEnumerator<T>
, whereT
is the yield type of the iterator. - It implements
System.IDisposable
. - It is initialized with a copy of the argument values (if any) and instance value passed to the function member.
- It has four potential states, before, running, suspended, and after, and is initially in the before state.
An enumerator object is typically an instance of a compiler-generated enumerator class that encapsulates the code in the iterator block and implements the enumerator interfaces, but other methods of implementation are possible. If an enumerator class is generated by the compiler, that class will be nested, directly or indirectly, in the class containing the function member, it will have private accessibility, and it will have a name reserved for compiler use (Identifiers).
An enumerator object may implement more interfaces than those specified above.
The following sections describe the exact behavior of the MoveNext
, Current
, and Dispose
members of the IEnumerable
and IEnumerable<T>
interface implementations provided by an enumerator object.
Note that enumerator objects do not support the IEnumerator.Reset
method. Invoking this method causes a System.NotSupportedException
to be thrown.
The MoveNext
method of an enumerator object encapsulates the code of an iterator block. Invoking the MoveNext
method executes code in the iterator block and sets the Current
property of the enumerator object as appropriate. The precise action performed by MoveNext
depends on the state of the enumerator object when MoveNext
is invoked:
- If the state of the enumerator object is before, invoking
MoveNext
:- Changes the state to running.
- Initializes the parameters (including
this
) of the iterator block to the argument values and instance value saved when the enumerator object was initialized. - Executes the iterator block from the beginning until execution is interrupted (as described below).
- If the state of the enumerator object is running, the result of invoking
MoveNext
is unspecified. - If the state of the enumerator object is suspended, invoking
MoveNext
:- Changes the state to running.
- Restores the values of all local variables and parameters (including this) to the values saved when execution of the iterator block was last suspended. Note that the contents of any objects referenced by these variables may have changed since the previous call to MoveNext.
- Resumes execution of the iterator block immediately following the
yield return
statement that caused the suspension of execution and continues until execution is interrupted (as described below).
- If the state of the enumerator object is after, invoking
MoveNext
returnsfalse
.
When MoveNext
executes the iterator block, execution can be interrupted in four ways: By a yield return
statement, by a yield break
statement, by encountering the end of the iterator block, and by an exception being thrown and propagated out of the iterator block.
- When a
yield return
statement is encountered (The yield statement):- The expression given in the statement is evaluated, implicitly converted to the yield type, and assigned to the
Current
property of the enumerator object. - Execution of the iterator body is suspended. The values of all local variables and parameters (including
this
) are saved, as is the location of thisyield return
statement. If theyield return
statement is within one or moretry
blocks, the associatedfinally
blocks are not executed at this time. - The state of the enumerator object is changed to suspended.
- The
MoveNext
method returnstrue
to its caller, indicating that the iteration successfully advanced to the next value.
- The expression given in the statement is evaluated, implicitly converted to the yield type, and assigned to the
- When a
yield break
statement is encountered (The yield statement):- If the
yield break
statement is within one or moretry
blocks, the associatedfinally
blocks are executed. - The state of the enumerator object is changed to after.
- The
MoveNext
method returnsfalse
to its caller, indicating that the iteration is complete.
- If the
- When the end of the iterator body is encountered:
- The state of the enumerator object is changed to after.
- The
MoveNext
method returnsfalse
to its caller, indicating that the iteration is complete.
- When an exception is thrown and propagated out of the iterator block:
- Appropriate
finally
blocks in the iterator body will have been executed by the exception propagation. - The state of the enumerator object is changed to after.
- The exception propagation continues to the caller of the
MoveNext
method.
- Appropriate
An enumerator object's Current
property is affected by yield return
statements in the iterator block.
When an enumerator object is in the suspended state, the value of Current
is the value set by the previous call to MoveNext
. When an enumerator object is in the before, running, or after states, the result of accessing Current
is unspecified.
For an iterator with a yield type other than object
, the result of accessing Current
through the enumerator object's IEnumerable
implementation corresponds to accessing Current
through the enumerator object's IEnumerator<T>
implementation and casting the result to object
.
The Dispose
method is used to clean up the iteration by bringing the enumerator object to the after state.
- If the state of the enumerator object is before, invoking
Dispose
changes the state to after. - If the state of the enumerator object is running, the result of invoking
Dispose
is unspecified. - If the state of the enumerator object is suspended, invoking
Dispose
:- Changes the state to running.
- Executes any finally blocks as if the last executed
yield return
statement were ayield break
statement. If this causes an exception to be thrown and propagated out of the iterator body, the state of the enumerator object is set to after and the exception is propagated to the caller of theDispose
method. - Changes the state to after.
- If the state of the enumerator object is after, invoking
Dispose
has no affect.
When a function member returning an enumerable interface type is implemented using an iterator block, invoking the function member does not immediately execute the code in the iterator block. Instead, an enumerable object is created and returned. The enumerable object's GetEnumerator
method returns an enumerator object that encapsulates the code specified in the iterator block, and execution of the code in the iterator block occurs when the enumerator object's MoveNext
method is invoked. An enumerable object has the following characteristics:
- It implements
IEnumerable
andIEnumerable<T>
, whereT
is the yield type of the iterator. - It is initialized with a copy of the argument values (if any) and instance value passed to the function member.
An enumerable object is typically an instance of a compiler-generated enumerable class that encapsulates the code in the iterator block and implements the enumerable interfaces, but other methods of implementation are possible. If an enumerable class is generated by the compiler, that class will be nested, directly or indirectly, in the class containing the function member, it will have private accessibility, and it will have a name reserved for compiler use (Identifiers).
An enumerable object may implement more interfaces than those specified above. In particular, an enumerable object may also implement IEnumerator
and IEnumerator<T>
, enabling it to serve as both an enumerable and an enumerator. In that type of implementation, the first time an enumerable object's GetEnumerator
method is invoked, the enumerable object itself is returned. Subsequent invocations of the enumerable object's GetEnumerator
, if any, return a copy of the enumerable object. Thus, each returned enumerator has its own state and changes in one enumerator will not affect another.
An enumerable object provides an implementation of the GetEnumerator
methods of the IEnumerable
and IEnumerable<T>
interfaces. The two GetEnumerator
methods share a common implementation that acquires and returns an available enumerator object. The enumerator object is initialized with the argument values and instance value saved when the enumerable object was initialized, but otherwise the enumerator object functions as described in Enumerator objects.
This section describes a possible implementation of iterators in terms of standard C# constructs. The implementation described here is based on the same principles used by the Microsoft C# compiler, but it is by no means a mandated implementation or the only one possible.
The following Stack<T>
class implements its GetEnumerator
method using an iterator. The iterator enumerates the elements of the stack in top to bottom order.
using System;
using System.Collections;
using System.Collections.Generic;
class Stack<T>: IEnumerable<T>
{
T[] items;
int count;
public void Push(T item) {
if (items == null) {
items = new T[4];
}
else if (items.Length == count) {
T[] newItems = new T[count * 2];
Array.Copy(items, 0, newItems, 0, count);
items = newItems;
}
items[count++] = item;
}
public T Pop() {
T result = items[--count];
items[count] = default(T);
return result;
}
public IEnumerator<T> GetEnumerator() {
for (int i = count - 1; i >= 0; --i) yield return items[i];
}
}
The GetEnumerator
method can be translated into an instantiation of a compiler-generated enumerator class that encapsulates the code in the iterator block, as shown in the following.
class Stack<T>: IEnumerable<T>
{
...
public IEnumerator<T> GetEnumerator() {
return new __Enumerator1(this);
}
class __Enumerator1: IEnumerator<T>, IEnumerator
{
int __state;
T __current;
Stack<T> __this;
int i;
public __Enumerator1(Stack<T> __this) {
this.__this = __this;
}
public T Current {
get { return __current; }
}
object IEnumerator.Current {
get { return __current; }
}
public bool MoveNext() {
switch (__state) {
case 1: goto __state1;
case 2: goto __state2;
}
i = __this.count - 1;
__loop:
if (i < 0) goto __state2;
__current = __this.items[i];
__state = 1;
return true;
__state1:
--i;
goto __loop;
__state2:
__state = 2;
return false;
}
public void Dispose() {
__state = 2;
}
void IEnumerator.Reset() {
throw new NotSupportedException();
}
}
}
In the preceding translation, the code in the iterator block is turned into a state machine and placed in the MoveNext
method of the enumerator class. Furthermore, the local variable i
is turned into a field in the enumerator object so it can continue to exist across invocations of MoveNext
.
The following example prints a simple multiplication table of the integers 1 through 10. The FromTo
method in the example returns an enumerable object and is implemented using an iterator.
using System;
using System.Collections.Generic;
class Test
{
static IEnumerable<int> FromTo(int from, int to) {
while (from <= to) yield return from++;
}
static void Main() {
IEnumerable<int> e = FromTo(1, 10);
foreach (int x in e) {
foreach (int y in e) {
Console.Write("{0,3} ", x * y);
}
Console.WriteLine();
}
}
}
The FromTo
method can be translated into an instantiation of a compiler-generated enumerable class that encapsulates the code in the iterator block, as shown in the following.
using System;
using System.Threading;
using System.Collections;
using System.Collections.Generic;
class Test
{
...
static IEnumerable<int> FromTo(int from, int to) {
return new __Enumerable1(from, to);
}
class __Enumerable1:
IEnumerable<int>, IEnumerable,
IEnumerator<int>, IEnumerator
{
int __state;
int __current;
int __from;
int from;
int to;
int i;
public __Enumerable1(int __from, int to) {
this.__from = __from;
this.to = to;
}
public IEnumerator<int> GetEnumerator() {
__Enumerable1 result = this;
if (Interlocked.CompareExchange(ref __state, 1, 0) != 0) {
result = new __Enumerable1(__from, to);
result.__state = 1;
}
result.from = result.__from;
return result;
}
IEnumerator IEnumerable.GetEnumerator() {
return (IEnumerator)GetEnumerator();
}
public int Current {
get { return __current; }
}
object IEnumerator.Current {
get { return __current; }
}
public bool MoveNext() {
switch (__state) {
case 1:
if (from > to) goto case 2;
__current = from++;
__state = 1;
return true;
case 2:
__state = 2;
return false;
default:
throw new InvalidOperationException();
}
}
public void Dispose() {
__state = 2;
}
void IEnumerator.Reset() {
throw new NotSupportedException();
}
}
}
The enumerable class implements both the enumerable interfaces and the enumerator interfaces, enabling it to serve as both an enumerable and an enumerator. The first time the GetEnumerator
method is invoked, the enumerable object itself is returned. Subsequent invocations of the enumerable object's GetEnumerator
, if any, return a copy of the enumerable object. Thus, each returned enumerator has its own state and changes in one enumerator will not affect another. The Interlocked.CompareExchange
method is used to ensure thread-safe operation.
The from
and to
parameters are turned into fields in the enumerable class. Because from
is modified in the iterator block, an additional __from
field is introduced to hold the initial value given to from
in each enumerator.
The MoveNext
method throws an InvalidOperationException
if it is called when __state
is 0
. This protects against use of the enumerable object as an enumerator object without first calling GetEnumerator
.
The following example shows a simple tree class. The Tree<T>
class implements its GetEnumerator
method using an iterator. The iterator enumerates the elements of the tree in infix order.
using System;
using System.Collections.Generic;
class Tree<T>: IEnumerable<T>
{
T value;
Tree<T> left;
Tree<T> right;
public Tree(T value, Tree<T> left, Tree<T> right) {
this.value = value;
this.left = left;
this.right = right;
}
public IEnumerator<T> GetEnumerator() {
if (left != null) foreach (T x in left) yield x;
yield value;
if (right != null) foreach (T x in right) yield x;
}
}
class Program
{
static Tree<T> MakeTree<T>(T[] items, int left, int right) {
if (left > right) return null;
int i = (left + right) / 2;
return new Tree<T>(items[i],
MakeTree(items, left, i - 1),
MakeTree(items, i + 1, right));
}
static Tree<T> MakeTree<T>(params T[] items) {
return MakeTree(items, 0, items.Length - 1);
}
// The output of the program is:
// 1 2 3 4 5 6 7 8 9
// Mon Tue Wed Thu Fri Sat Sun
static void Main() {
Tree<int> ints = MakeTree(1, 2, 3, 4, 5, 6, 7, 8, 9);
foreach (int i in ints) Console.Write("{0} ", i);
Console.WriteLine();
Tree<string> strings = MakeTree(
"Mon", "Tue", "Wed", "Thu", "Fri", "Sat", "Sun");
foreach (string s in strings) Console.Write("{0} ", s);
Console.WriteLine();
}
}
The GetEnumerator
method can be translated into an instantiation of a compiler-generated enumerator class that encapsulates the code in the iterator block, as shown in the following.
class Tree<T>: IEnumerable<T>
{
...
public IEnumerator<T> GetEnumerator() {
return new __Enumerator1(this);
}
class __Enumerator1 : IEnumerator<T>, IEnumerator
{
Node<T> __this;
IEnumerator<T> __left, __right;
int __state;
T __current;
public __Enumerator1(Node<T> __this) {
this.__this = __this;
}
public T Current {
get { return __current; }
}
object IEnumerator.Current {
get { return __current; }
}
public bool MoveNext() {
try {
switch (__state) {
case 0:
__state = -1;
if (__this.left == null) goto __yield_value;
__left = __this.left.GetEnumerator();
goto case 1;
case 1:
__state = -2;
if (!__left.MoveNext()) goto __left_dispose;
__current = __left.Current;
__state = 1;
return true;
__left_dispose:
__state = -1;
__left.Dispose();
__yield_value:
__current = __this.value;
__state = 2;
return true;
case 2:
__state = -1;
if (__this.right == null) goto __end;
__right = __this.right.GetEnumerator();
goto case 3;
case 3:
__state = -3;
if (!__right.MoveNext()) goto __right_dispose;
__current = __right.Current;
__state = 3;
return true;
__right_dispose:
__state = -1;
__right.Dispose();
__end:
__state = 4;
break;
}
}
finally {
if (__state < 0) Dispose();
}
return false;
}
public void Dispose() {
try {
switch (__state) {
case 1:
case -2:
__left.Dispose();
break;
case 3:
case -3:
__right.Dispose();
break;
}
}
finally {
__state = 4;
}
}
void IEnumerator.Reset() {
throw new NotSupportedException();
}
}
}
The compiler generated temporaries used in the foreach
statements are lifted into the __left
and __right
fields of the enumerator object. The __state
field of the enumerator object is carefully updated so that the correct Dispose()
method will be called correctly if an exception is thrown. Note that it is not possible to write the translated code with simple foreach
statements.
A method (Methods) or anonymous function (Anonymous function expressions) with the async
modifier is called an async function. In general, the term async is used to describe any kind of function that has the async
modifier.
It is a compile-time error for the formal parameter list of an async function to specify any ref
or out
parameters.
The return_type of an async method must be either void
or a task type. The task types are System.Threading.Tasks.Task
and types constructed from System.Threading.Tasks.Task<T>
. For the sake of brevity, in this chapter these types are referenced as Task
and Task<T>
, respectively. An async method returning a task type is said to be task-returning.
The exact definition of the task types is implementation defined, but from the language's point of view a task type is in one of the states incomplete, succeeded or faulted. A faulted task records a pertinent exception. A succeeded Task<T>
records a result of type T
. Task types are awaitable, and can therefore be the operands of await expressions (Await expressions).
An async function invocation has the ability to suspend evaluation by means of await expressions (Await expressions) in its body. Evaluation may later be resumed at the point of the suspending await expression by means of a resumption delegate. The resumption delegate is of type System.Action
, and when it is invoked, evaluation of the async function invocation will resume from the await expression where it left off. The current caller of an async function invocation is the original caller if the function invocation has never been suspended, or the most recent caller of the resumption delegate otherwise.
Invocation of a task-returning async function causes an instance of the returned task type to be generated. This is called the return task of the async function. The task is initially in an incomplete state.
The async function body is then evaluated until it is either suspended (by reaching an await expression) or terminates, at which point control is returned to the caller, along with the return task.
When the body of the async function terminates, the return task is moved out of the incomplete state:
- If the function body terminates as the result of reaching a return statement or the end of the body, any result value is recorded in the return task, which is put into a succeeded state.
- If the function body terminates as the result of an uncaught exception (The throw statement) the exception is recorded in the return task which is put into a faulted state.
If the return type of the async function is void
, evaluation differs from the above in the following way: Because no task is returned, the function instead communicates completion and exceptions to the current thread's synchronization context. The exact definition of synchronization context is implementation-dependent, but is a representation of "where" the current thread is running. The synchronization context is notified when evaluation of a void-returning async function commences, completes successfully, or causes an uncaught exception to be thrown.
This allows the context to keep track of how many void-returning async functions are running under it, and to decide how to propagate exceptions coming out of them.