include/swift/AST/AccessorKinds.def - third_party/swift - Git at Google

 //===--- AccessorKinds.def - Swift accessor metaprogramming -----*- C++ -*-===//
 //
 // This source file is part of the Swift.org open source project
 //
 // Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
 // Licensed under Apache License v2.0 with Runtime Library Exception
 //
 // See https://swift.org/LICENSE.txt for license information
 // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines macros used for macro-metaprogramming with accessor kinds.
 //
 //===----------------------------------------------------------------------===//

 #if defined(ACCESSOR) && defined(ACCESSOR_KEYWORD)
 #error do not define both ACCESSOR and ACCESSOR_KEYWORD
 #elif !defined(ACCESSOR) && !defined(ACCESSOR_KEYWORD)
 #error must define either ACCESSOR or ACCESSOR_KEYWORD
 #endif

 /// ACCESSOR(ID)
 ///   There is an accessor with the enumerator value AccessorKind::ID.
 #if !defined(ACCESSOR) && defined(ACCESSOR_KEYWORD)
 #define ACCESSOR(ID)
 #endif

 /// SINGLETON_ACCESSOR(ID, KEYWORD)
 ///   The given accessor has only one matching accessor keyword.
 ///
 /// Defaults to ACCESSOR(ID) or ACCESSOR_KEYWORD(KEYWORD), depending on which
 /// is defined.
 #ifndef SINGLETON_ACCESSOR
 #if defined(ACCESSOR_KEYWORD)
 #define SINGLETON_ACCESSOR(ID, KEYWORD) ACCESSOR_KEYWORD(KEYWORD)
 #else
 #define SINGLETON_ACCESSOR(ID, KEYWORD) ACCESSOR(ID)
 #endif
 #endif

 /// OBSERVING_ACCESSOR(ID, KEYWORD)
 ///   The given accessor is an observing accessor.
 ///
 ///   Defaults to SINGLETON_ACCESSOR(ID, KEYWORD).
 #ifndef OBSERVING_ACCESSOR
 #define OBSERVING_ACCESSOR(ID, KEYWORD) SINGLETON_ACCESSOR(ID, KEYWORD)
 #endif

 /// OPAQUE_ACCESSOR(ID, KEYWORD)
 ///   The given accessor is used in the opaque access pattern and is created
 ///   for (mutable) storage whenever its implementation is unknown, such as
 ///   when it is resilient, overridable, or accessed through a protocol.
 ///
 ///   Defaults to SINGLETON_ACCESSOR(ID, KEYWORD).
 #ifndef OPAQUE_ACCESSOR
 #define OPAQUE_ACCESSOR(ID, KEYWORD) SINGLETON_ACCESSOR(ID, KEYWORD)
 #endif

 /// OBJC_ACCESSOR(ID, KEYWORD)
 ///   The given accessor is used in Objective-C, i.e. it is a getter or setter.
 ///
 ///   Defaults to OPAQUE_ACCESSOR(ID, KEYWORD).
 #ifndef OBJC_ACCESSOR
 #define OBJC_ACCESSOR(ID, KEYWORD) OPAQUE_ACCESSOR(ID, KEYWORD)
 #endif

 /// COROUTINE_ACCESSOR(ID, KEYWORD)
 ///   The given accessor is a coroutine accessor, i.e. a reader or modifier.
 ///
 ///   Defaults to OPAQUE_ACCESSOR(ID, KEYWORD).
 #ifndef COROUTINE_ACCESSOR
 #define COROUTINE_ACCESSOR(ID, KEYWORD) OPAQUE_ACCESSOR(ID, KEYWORD)
 #endif

 /// ANY_ADDRESSOR(ID, KEYWORD)
 ///   The given keyword corresponds to an addressor of the given kind.
 ///
 ///   Defaults to SINGLETON_ACCESSOR(ID, KEYWORD).
 #ifndef ANY_ADDRESSOR
 #define ANY_ADDRESSOR(ID, KEYWORD) \
   SINGLETON_ACCESSOR(ID, KEYWORD)
 #endif

 /// IMMUTABLE_ADDRESSOR(ID, KEYWORD)
 ///   The given keyword corresponds to an immutable addressor of the given kind.
 ///
 ///   DEfaults to ANY_ADDRESSOR(ID, KEYWORD).
 #ifndef IMMUTABLE_ADDRESSOR
 #define IMMUTABLE_ADDRESSOR(ID, KEYWORD) \
   ANY_ADDRESSOR(ID, KEYWORD)
 #endif

 /// MUTABLE_ADDRESSOR(ID, KEYWORD)
 ///   The given keyword corresponds to a mutable addressor of the given kind.
 ///
 ///   DEfaults to ANY_ADDRESSOR(ID, KEYWORD).
 #ifndef MUTABLE_ADDRESSOR
 #define MUTABLE_ADDRESSOR(ID, KEYWORD) \
   ANY_ADDRESSOR(ID, KEYWORD)
 #endif

 // Suppress entries for accessors which can't be written in source code.
 #ifndef SUPPRESS_ARTIFICIAL_ACCESSORS
 #define SUPPRESS_ARTIFICIAL_ACCESSORS 0
 #endif

 /// This is a getter: a function that is called when a value is loaded
 /// from the storage.  It returns an owned value of the storage type.
 ///
 /// If the storage is not implemented with a getter, a getter can
 /// always be synthesized.  However, this will not be true when
 /// move-only types are introduced.
 OBJC_ACCESSOR(Get, get)

 /// This is a setter: a function that is called when a value is assigned
 /// to the storage.  It takes a value of the storage type as its
 /// primary parameter, in addition to any index values that may be
 /// required for a subscript.
 ///
 /// If the storage is not implemented with a setter, a setter can
 /// always be synthesized if the storage is mutable at all.
 OBJC_ACCESSOR(Set, set)

 /// This is a read accessor: a yield-once coroutine which is called when a
 /// value is loaded from the storage, like a getter, but which works
 /// by yielding a borrowed value of the storage type.
 ///
 /// If the storage is not implemented with a read accessor then
 /// one can always be synthesized (even if the storage type is move-only).
 COROUTINE_ACCESSOR(Read, _read)

 /// This is a modify accessor: a yield-once coroutine which is called when a
 /// the storage is modified which works by yielding an inout value
 /// of the storage type.
 ///
 /// If the storage is not implemented with a modify accessor then
 /// one can be synthesized if the storage is mutable at all.
 COROUTINE_ACCESSOR(Modify, _modify)

 /// This is a willSet observer: a function which "decorates" an
 /// underlying assignment operation by being called prior to the
 /// operation when a value is assigned to the storage.
 ///
 /// willSet is essentially sugar for implementing a certain common
 /// setter idiom.
 OBSERVING_ACCESSOR(WillSet, willSet)

 /// This is a didSet observer: a function which "decorates" an
 /// underlying assignment operation by being called after the
 /// operation when a value is assigned to the storage.
 ///
 /// didSet is essentially sugar for implementing a certain common
 /// setter idiom.
 OBSERVING_ACCESSOR(DidSet, didSet)

 /// This is an address-family accessor: a function that is called when
 /// a value is loaded from the storage, like a getter, but which works
 /// by returning a pointer to an immutable value of the storage type.
 /// This kind of accessor also has an addressor kind.
 ///
 /// Addressors are a way of proving more efficient access to storage
 /// when it is already stored in memory (but not as a stored member
 /// of the type).
 IMMUTABLE_ADDRESSOR(Address, unsafeAddress)

 /// This is a mutableAddress-family accessor: a function that is
 /// called when the storage is modified and which works by returning
 /// a pointer to a mutable value of the storage type.
 /// This kind of accessor also has an addressor kind.
 ///
 /// Addressors are a way of proving more efficient access to storage
 /// when it is already stored in memory (but not as a stored member
 /// of the type).
 MUTABLE_ADDRESSOR(MutableAddress, unsafeMutableAddress)

 #ifdef LAST_ACCESSOR
 LAST_ACCESSOR(MutableAddress)
 #undef LAST_ACCESSOR
 #endif

 #undef IMMUTABLE_ADDRESSOR
 #undef MUTABLE_ADDRESSOR
 #undef ANY_ADDRESSOR
 #undef OBJC_ACCESSOR
 #undef OPAQUE_ACCESSOR
 #undef COROUTINE_ACCESSOR
 #undef OBSERVING_ACCESSOR
 #undef SINGLETON_ACCESSOR
 #undef ACCESSOR
 #undef ACCESSOR_KEYWORD
 #undef SUPPRESS_ARTIFICIAL_ACCESSORS
	//===--- AccessorKinds.def - Swift accessor metaprogramming ------ C++ --===//
	//
	// This source file is part of the Swift.org open source project
	//
	// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
	// Licensed under Apache License v2.0 with Runtime Library Exception
	//
	// See https://swift.org/LICENSE.txt for license information
	// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines macros used for macro-metaprogramming with accessor kinds.
	//
	//===----------------------------------------------------------------------===//

	#if defined(ACCESSOR) && defined(ACCESSOR_KEYWORD)
	#error do not define both ACCESSOR and ACCESSOR_KEYWORD
	#elif !defined(ACCESSOR) && !defined(ACCESSOR_KEYWORD)
	#error must define either ACCESSOR or ACCESSOR_KEYWORD
	#endif

	/// ACCESSOR(ID)
	/// There is an accessor with the enumerator value AccessorKind::ID.
	#if !defined(ACCESSOR) && defined(ACCESSOR_KEYWORD)
	#define ACCESSOR(ID)
	#endif

	/// SINGLETON_ACCESSOR(ID, KEYWORD)
	/// The given accessor has only one matching accessor keyword.
	///
	/// Defaults to ACCESSOR(ID) or ACCESSOR_KEYWORD(KEYWORD), depending on which
	/// is defined.
	#ifndef SINGLETON_ACCESSOR
	#if defined(ACCESSOR_KEYWORD)
	#define SINGLETON_ACCESSOR(ID, KEYWORD) ACCESSOR_KEYWORD(KEYWORD)
	#else
	#define SINGLETON_ACCESSOR(ID, KEYWORD) ACCESSOR(ID)
	#endif
	#endif

	/// OBSERVING_ACCESSOR(ID, KEYWORD)
	/// The given accessor is an observing accessor.
	///
	/// Defaults to SINGLETON_ACCESSOR(ID, KEYWORD).
	#ifndef OBSERVING_ACCESSOR
	#define OBSERVING_ACCESSOR(ID, KEYWORD) SINGLETON_ACCESSOR(ID, KEYWORD)
	#endif

	/// OPAQUE_ACCESSOR(ID, KEYWORD)
	/// The given accessor is used in the opaque access pattern and is created
	/// for (mutable) storage whenever its implementation is unknown, such as
	/// when it is resilient, overridable, or accessed through a protocol.
	///
	/// Defaults to SINGLETON_ACCESSOR(ID, KEYWORD).
	#ifndef OPAQUE_ACCESSOR
	#define OPAQUE_ACCESSOR(ID, KEYWORD) SINGLETON_ACCESSOR(ID, KEYWORD)
	#endif

	/// OBJC_ACCESSOR(ID, KEYWORD)
	/// The given accessor is used in Objective-C, i.e. it is a getter or setter.
	///
	/// Defaults to OPAQUE_ACCESSOR(ID, KEYWORD).
	#ifndef OBJC_ACCESSOR
	#define OBJC_ACCESSOR(ID, KEYWORD) OPAQUE_ACCESSOR(ID, KEYWORD)
	#endif

	/// COROUTINE_ACCESSOR(ID, KEYWORD)
	/// The given accessor is a coroutine accessor, i.e. a reader or modifier.
	///
	/// Defaults to OPAQUE_ACCESSOR(ID, KEYWORD).
	#ifndef COROUTINE_ACCESSOR
	#define COROUTINE_ACCESSOR(ID, KEYWORD) OPAQUE_ACCESSOR(ID, KEYWORD)
	#endif

	/// ANY_ADDRESSOR(ID, KEYWORD)
	/// The given keyword corresponds to an addressor of the given kind.
	///
	/// Defaults to SINGLETON_ACCESSOR(ID, KEYWORD).
	#ifndef ANY_ADDRESSOR
	#define ANY_ADDRESSOR(ID, KEYWORD) \
	SINGLETON_ACCESSOR(ID, KEYWORD)
	#endif

	/// IMMUTABLE_ADDRESSOR(ID, KEYWORD)
	/// The given keyword corresponds to an immutable addressor of the given kind.
	///
	/// DEfaults to ANY_ADDRESSOR(ID, KEYWORD).
	#ifndef IMMUTABLE_ADDRESSOR
	#define IMMUTABLE_ADDRESSOR(ID, KEYWORD) \
	ANY_ADDRESSOR(ID, KEYWORD)
	#endif

	/// MUTABLE_ADDRESSOR(ID, KEYWORD)
	/// The given keyword corresponds to a mutable addressor of the given kind.
	///
	/// DEfaults to ANY_ADDRESSOR(ID, KEYWORD).
	#ifndef MUTABLE_ADDRESSOR
	#define MUTABLE_ADDRESSOR(ID, KEYWORD) \
	ANY_ADDRESSOR(ID, KEYWORD)
	#endif

	// Suppress entries for accessors which can't be written in source code.
	#ifndef SUPPRESS_ARTIFICIAL_ACCESSORS
	#define SUPPRESS_ARTIFICIAL_ACCESSORS 0
	#endif

	/// This is a getter: a function that is called when a value is loaded
	/// from the storage. It returns an owned value of the storage type.
	///
	/// If the storage is not implemented with a getter, a getter can
	/// always be synthesized. However, this will not be true when
	/// move-only types are introduced.
	OBJC_ACCESSOR(Get, get)

	/// This is a setter: a function that is called when a value is assigned
	/// to the storage. It takes a value of the storage type as its
	/// primary parameter, in addition to any index values that may be
	/// required for a subscript.
	///
	/// If the storage is not implemented with a setter, a setter can
	/// always be synthesized if the storage is mutable at all.
	OBJC_ACCESSOR(Set, set)

	/// This is a read accessor: a yield-once coroutine which is called when a
	/// value is loaded from the storage, like a getter, but which works
	/// by yielding a borrowed value of the storage type.
	///
	/// If the storage is not implemented with a read accessor then
	/// one can always be synthesized (even if the storage type is move-only).
	COROUTINE_ACCESSOR(Read, _read)

	/// This is a modify accessor: a yield-once coroutine which is called when a
	/// the storage is modified which works by yielding an inout value
	/// of the storage type.
	///
	/// If the storage is not implemented with a modify accessor then
	/// one can be synthesized if the storage is mutable at all.
	COROUTINE_ACCESSOR(Modify, _modify)

	/// This is a willSet observer: a function which "decorates" an
	/// underlying assignment operation by being called prior to the
	/// operation when a value is assigned to the storage.
	///
	/// willSet is essentially sugar for implementing a certain common
	/// setter idiom.
	OBSERVING_ACCESSOR(WillSet, willSet)

	/// This is a didSet observer: a function which "decorates" an
	/// underlying assignment operation by being called after the
	/// operation when a value is assigned to the storage.
	///
	/// didSet is essentially sugar for implementing a certain common
	/// setter idiom.
	OBSERVING_ACCESSOR(DidSet, didSet)

	/// This is an address-family accessor: a function that is called when
	/// a value is loaded from the storage, like a getter, but which works
	/// by returning a pointer to an immutable value of the storage type.
	/// This kind of accessor also has an addressor kind.
	///
	/// Addressors are a way of proving more efficient access to storage
	/// when it is already stored in memory (but not as a stored member
	/// of the type).
	IMMUTABLE_ADDRESSOR(Address, unsafeAddress)

	/// This is a mutableAddress-family accessor: a function that is
	/// called when the storage is modified and which works by returning
	/// a pointer to a mutable value of the storage type.
	/// This kind of accessor also has an addressor kind.
	///
	/// Addressors are a way of proving more efficient access to storage
	/// when it is already stored in memory (but not as a stored member
	/// of the type).
	MUTABLE_ADDRESSOR(MutableAddress, unsafeMutableAddress)

	#ifdef LAST_ACCESSOR
	LAST_ACCESSOR(MutableAddress)
	#undef LAST_ACCESSOR
	#endif

	#undef IMMUTABLE_ADDRESSOR
	#undef MUTABLE_ADDRESSOR
	#undef ANY_ADDRESSOR
	#undef OBJC_ACCESSOR
	#undef OPAQUE_ACCESSOR
	#undef COROUTINE_ACCESSOR
	#undef OBSERVING_ACCESSOR
	#undef SINGLETON_ACCESSOR
	#undef ACCESSOR
	#undef ACCESSOR_KEYWORD
	#undef SUPPRESS_ARTIFICIAL_ACCESSORS