17.5.3 Virtual methods
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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implementation of a virtual method can be superseded by derived classes.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 (§17.5.4).
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, and A, to select a
specific method M from the set of methods
declared in and inherited by C. This is described in §14.5.5.1.
? Then, if M is a non-virtual method, M is invoked.
? Otherwise, M is a virtual method, and the most derived implementation of
M with respect to R is invoked.
For every virtual method declared in or inherited by a class, there exists
a most derived implementation of the
method with respect to that class. The most derived implementation of a
virtual method M with respect to a class R
is determined as follows:
? If R contains the introducing virtual declaration of M, then this is the
most derived implementation of M.
? Otherwise, if R contains an override of M, then this is the most derived
implementation of M.
? Otherwise, the most derived implementation of M is the same as that of
the direct base class of R.
[Example: The following example illustrates the differences between virtual
and non-virtual methods:
C# LANGUAGE SPECIFICATION
234
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 nonvirtual
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. end example]
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. [Example: 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"); }
}
Chapter 17 Classes
235
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. end example]
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 (§17.5.4).
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, and A, to select a
specific method M from the set of methods
declared in and inherited by C. This is described in §14.5.5.1.
? Then, if M is a non-virtual method, M is invoked.
? Otherwise, M is a virtual method, and the most derived implementation of
M with respect to R is invoked.
For every virtual method declared in or inherited by a class, there exists
a most derived implementation of the
method with respect to that class. The most derived implementation of a
virtual method M with respect to a class R
is determined as follows:
? If R contains the introducing virtual declaration of M, then this is the
most derived implementation of M.
? Otherwise, if R contains an override of M, then this is the most derived
implementation of M.
? Otherwise, the most derived implementation of M is the same as that of
the direct base class of R.
[Example: The following example illustrates the differences between virtual
and non-virtual methods:
C# LANGUAGE SPECIFICATION
234
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 nonvirtual
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. end example]
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. [Example: 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"); }
}
Chapter 17 Classes
235
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. end example]
- 17.5.3 Virtual methods
- 17.5.3 Virtual methods
- CLR call Virtual Methods
- virtual methods in tolua++
- mock non-virtual methods
- Java 多态 (polymorphism) Virtual Methods
- 17.5 Methods
- 17.5 Methods
- 17.5.4 Override methods
- 17.5.5 Sealed methods
- 17.5.6 Abstract methods
- 17.5.4 Override methods
- 17.5.5 Sealed methods
- 17.5.6 Abstract methods
- 8.7.3 Methods
- 4.4.3 Framework Methods
- 3 Decomposition Methods
- METHODS
- 17.3 Constants
- 17.4 Fields
- 17.5 Methods
- 17.5.1 Method parameters
- 17.5.2 Static and instance methods
- 17.5.3 Virtual methods
- 17.5.4 Override methods
- 17.5.5 Sealed methods
- 使用Arcgis Engine开发时发现.Net help中有些小错误
- Java Bean 与 EJB的区别
- 17.5.6 Abstract methods
- 17.5.8 Method body
- 17.5.9 Method overloading
- web2.0人民的力量?
