Component Extensions for Runtime Platforms

  • [アーティクル]

 

The latest version of this topic can be found at Component Extensions for Runtime Platforms.

Visual C++ provides language extensions to help you program against runtime platforms. By using Visual C++ component extensions (C++/CX), you can program Windows 8.x Store apps and components that compile to native code. Although you can create Windows 8.x Store apps by programming directly against the Windows Runtime COM interfaces, by using C++/CX, you can work with constructors, exceptions, and other modern C++ programming idioms. To enable C++ programming in a managed execution environment on the .NET platform, you can use C++/CLI.

Two runtimes, one set of extensions

C++/CX is a subset of C++/CLI. For extensions that are common to C++/CX and C++/CLI, the semantics depend on whether you are targeting the common language runtime (CLR) or the Windows Runtime. To compile your app to run on the Windows Runtime, specify the /ZW compiler option. To compile it to run on the CLR, specify the /clr compiler option. These switches are set automatically when you use Visual Studio to create a project.

For more information about how to create Windows 8.x Store apps in C++, see Roadmap for Windows Runtime apps using C++.

C++/CLI extends the ISO/ANSI C++ standard, and is defined under the Ecma C++/CLI Standard. For more information, see .NET Programming with C++/CLI (Visual C++).

Data Type Keywords

The language extensions include aggregate keywords, which are keywords that consist of two tokens separated by white space. The tokens might have one meaning when they are used separately, and another meaning when they are used together. For example, the word "ref" is an ordinary identifier, and the word "class" is a keyword that declares a native class. But when these words are combined to form ref class, the resulting aggregate keyword declares an entity that is known as a runtime class.

The extensions also include context-sensitive keywords. A keyword is treated as context-sensitive depending on the kind of statement that contains it, and its placement in that statement. For example, the token "property" can be an identifier, or it can declare a special kind of public class member.

The following table lists keywords in the C++ language extension.

Keyword Context sensitive Purpose Reference
ref class

 ref struct		 No Declares a class. Classes and Structs
value class

 value struct		 No Declares a value class. Classes and Structs
interface class

 interface struct		 No Declares an interface. interface class
enum class

 enum struct		 No Declares an enumeration. enum class
property Yes Declares a property. property
delegate Yes Declares a delegate. delegate (C++ Component Extensions)
event Yes Declares an event. event

Override Specifiers

You can use the following keywords to qualify override behavior for derivation. Although the new keyword is not an extension of C++, it is listed here because it can be used in an additional context. Some specifiers are also valid for native programming. For more information, see How to: Declare Override Specifiers in Native Compilations (C++/CLI).

Keyword Context Sensitive Purpose Reference
abstract Yes Indicates that functions or classes are abstract. abstract
new No Indicates that a function is not an override of a base class version. new (new slot in vtable)
override Yes Indicates that a method must be an override of a base-class version. override
sealed Yes Prevents classes from being used as base classes. sealed

Keywords for Generics

The following keywords have been added to support generic types. For more information, see Generics.

Keyword Context sensitive Purpose
generic No Declares a generic type.
where Yes Specifies the constraints that are applied to a generic type parameter.

Miscellaneous Keywords

The following keywords have been added to the C++ extensions.

Keyword Context sensitive Purpose Reference
finally Yes Indicates default exception handlings behavior. Exception Handling
for each, in No Enumerates elements of a collection. for each, in
gcnew No Allocates types on the garbage-collected heap. Use instead of new and delete. ref new, gcnew
ref new Yes Allocates a Windows Runtime type. Use instead of new and delete. ref new, gcnew
initonly Yes Indicates that a member can only be initialized at declaration or in a static constructor. initonly (C++/CLI)
literal Yes Creates a literal variable. literal
nullptr No Indicates that a handle or pointer does not point at an object. nullptr

Template Constructs

The following language constructs are implemented as templates, instead of as keywords. If you specify the /ZW compiler option, they are defined in the lang namespace. If you specify the /clr compiler option, they are defined in the cli namespace.

Keyword Purpose Reference
array Declares an array. Arrays
interior_ptr (CLR only) Points to data in a reference type. interior_ptr (C++/CLI)
pin_ptr (CLR only) Points to CLR reference types to temporarily suppress the garbage-collection system. pin_ptr (C++/CLI)
safe_cast Determines and executes the optimal casting method for a runtime type. safe_cast
typeid (CLR only) Retrieves a System.Type object that describes the given type or object. typeid

Declarators

The following type declarators instruct the runtime to automatically manage the lifetime and deletion of allocated objects.

Operator Purpose Reference
^ Declares a handle to an object; that is, a pointer to a Windows Runtime or CLR object that is automatically deleted when it is no longer usable. Handle to Object Operator (^)
% Declares a tracking reference; that is, a reference to a Windows Runtime or CLR object that is automatically deleted when it is no longer usable. Tracking Reference Operator

This section lists additional programming constructs, and topics that pertain to the CLR.

Topic Description
__identifier (C++/CLI) (Windows Runtime and CLR) Enables the use of keywords as identifiers.
Variable Argument Lists (...) (C++/CLI) (Windows Runtime and CLR) Enables a function to take a variable number of arguments.
.NET Framework Equivalents to C++ Native Types (C++/CLI) Lists the CLR types that are used in place of C++ integral types.
appdomain __declspec modifier __declspec modifier that mandates that static and global variables exist per appdomain.
C-Style Casts with /clr (C++/CLI) Describes how C-style casts are interpreted.
__clrcall calling convention Indicates the CLR-compliant calling convention.
__cplusplus_cli Predefined Macros
Custom Attributes Describes how to define your own CLR attributes.
Exception Handling Provides an overview of exception handling.
Explicit Overrides Demonstrates how member functions can override arbitrary members.
Friend Assemblies (C++) Discusses how a client assembly can access all types in an assembly component.
Boxing Demonstrates the conditions in which values types are boxed.
Compiler Support for Type Traits Discusses how to detect characteristics of types at compile time.
managed, unmanaged pragmas Demonstrates how managed and unmanaged functions can co-exist in the same module.
process __declspec modifier __declspec modifier that mandates that static and global variables exist per process.
Reflection (C++/CLI) Demonstrates the CLR version of run-time type information.
String Discusses compiler conversion of string literals to String.
Type Forwarding (C++/CLI) Enables the movement of a type in a shipping assembly to another assembly so that client code does not have to be recompiled.
User-Defined Attributes Demonstrates user-defined attributes.
#using Directive Imports external assemblies.
XML Documentation Explains XML-based code documentation by using /doc (Process Documentation Comments) (C/C++)

See Also

.NET Programming with C++/CLI (Visual C++)
Native and .NET Interoperability