include/core/SkLazyPtr.h - skia - Git at Google

 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkLazyPtr_DEFINED
 #define SkLazyPtr_DEFINED

 /** Declare a lazily-chosen static pointer (or array of pointers) of type T.
  *
  *  Example usage:
  *
  *  Foo* GetSingletonFoo() {
  *      SK_DECLARE_STATIC_LAZY_PTR(Foo, singleton);  // Created with SkNEW, destroyed with SkDELETE.
  *      return singleton.get();
  *  }
  *
  *  These macros take an optional T* (*Create)() and void (*Destroy)(T*) at the end.
  *  If not given, we'll use SkNEW and SkDELETE.
  *  These options are most useful when T doesn't have a public constructor or destructor.
  *  Create comes first, so you may use a custom Create with a default Destroy, but not vice versa.
  *
  *  Foo* CustomCreate() { return ...; }
  *  void CustomDestroy(Foo* ptr) { ... }
  *  Foo* GetSingletonFooWithCustomCleanup() {
  *      SK_DECLARE_STATIC_LAZY_PTR(Foo, singleton, CustomCreate, CustomDestroy);
  *      return singleton.get();
  *  }
  *
  *  If you have a bunch of related static pointers of the same type, you can
  *  declare an array of lazy pointers together, and we'll pass the index to Create().
  *
  *  Foo* CreateFoo(int i) { return ...; }
  *  Foo* GetCachedFoo(Foo::Enum enumVal) {
  *      SK_DECLARE_STATIC_LAZY_PTR_ARRAY(Foo, Foo::kEnumCount, cachedFoos, CreateFoo);
  *      return cachedFoos[enumVal];
  *  }
  *
  *
  *  You can think of SK_DECLARE_STATIC_LAZY_PTR as a cheaper specialization of
  *  SkOnce.  There is no mutex or extra storage used past the pointer itself.
  *
  *  We may call Create more than once, but all threads will see the same pointer
  *  returned from get().  Any extra calls to Create will be cleaned up.
  *
  *  These macros must be used in a global scope, not in function scope or as a class member.
  */

 #define SK_DECLARE_STATIC_LAZY_PTR(T, name, ...) \
     namespace {} static Private::SkStaticLazyPtr<T, ##__VA_ARGS__> name

 #define SK_DECLARE_STATIC_LAZY_PTR_ARRAY(T, name, N, ...) \
     namespace {} static Private::SkStaticLazyPtrArray<T, N, ##__VA_ARGS__> name

 // namespace {} forces these macros to only be legal in global scopes.  Chrome has thread-safety
 // problems with them in function-local statics because it uses -fno-threadsafe-statics, and even
 // in builds with threadsafe statics, those threadsafe statics are just unnecessary overhead.

 // Everything below here is private implementation details.  Don't touch, don't even look.

 #include "SkAtomics.h"

 // See FIXME below.
 class SkFontConfigInterfaceDirect;

 namespace Private {

 // Set *dst to ptr if *dst is NULL.  Returns value of *dst, destroying ptr if not swapped in.
 // Issues acquire memory barrier on failure, release on success.
 template <typename P, void (*Destroy)(P)>
 static P try_cas(P* dst, P ptr) {
     P prev = NULL;
     if (sk_atomic_compare_exchange(dst, &prev, ptr,
                                    sk_memory_order_release/*on success*/,
                                    sk_memory_order_acquire/*on failure*/)) {
         // We need a release barrier before returning ptr.  The compare_exchange provides it.
         SkASSERT(!prev);
         return ptr;
     } else {
         Destroy(ptr);
         // We need an acquire barrier before returning prev.  The compare_exchange provided it.
         SkASSERT(prev);
         return prev;
     }
 }

 template <typename T> T* sk_new() { return SkNEW(T); }
 template <typename T> void sk_delete(T* ptr) { SkDELETE(ptr); }

 // We're basing these implementations here on this article:
 //   http://preshing.com/20140709/the-purpose-of-memory_order_consume-in-cpp11/
 //
 // Because the users of SkLazyPtr and SkLazyPtrArray will read the pointers
 // _through_ our atomically set pointer, there is a data dependency between our
 // atomic and the guarded data, and so we only need writer-releases /
 // reader-consumes memory pairing rather than the more general write-releases /
 // reader-acquires convention.
 //
 // This is nice, because a consume load is free on all our platforms: x86,
 // ARM, MIPS.  In contrast, an acquire load issues a memory barrier on non-x86.

 template <typename T>
 T consume_load(T* ptr) {
 #if defined(THREAD_SANITIZER)
     // TSAN gets anxious if we don't tell it what we're actually doing, a consume load.
     return sk_atomic_load(ptr, sk_memory_order_consume);
 #else
     // All current compilers blindly upgrade consume memory order to acquire memory order.
     // For our purposes, though, no memory barrier is required, so we lie and use relaxed.
     return sk_atomic_load(ptr, sk_memory_order_relaxed);
 #endif
 }

 // This has no constructor and must be zero-initalized (the macro above does this).
 template <typename T, T* (*Create)() = sk_new<T>, void (*Destroy)(T*) = sk_delete<T> >
 class SkStaticLazyPtr {
 public:
     T* get() {
         // If fPtr has already been filled, we need a consume barrier when loading it.
         // If not, we need a release barrier when setting it.  try_cas will do that.
         T* ptr = consume_load(&fPtr);
         return ptr ? ptr : try_cas<T*, Destroy>(&fPtr, Create());
     }

 private:
     T* fPtr;
 };

 template <typename T> T* sk_new_arg(int i) { return SkNEW_ARGS(T, (i)); }

 // This has no constructor and must be zero-initalized (the macro above does this).
 template <typename T, int N, T* (*Create)(int) = sk_new_arg<T>, void (*Destroy)(T*) = sk_delete<T> >
 class SkStaticLazyPtrArray {
 public:
     T* operator[](int i) {
         SkASSERT(i >= 0 && i < N);
         // If fPtr has already been filled, we need an consume barrier when loading it.
         // If not, we need a release barrier when setting it.  try_cas will do that.
         T* ptr = consume_load(&fArray[i]);
         return ptr ? ptr : try_cas<T*, Destroy>(&fArray[i], Create(i));
     }

 private:
     T* fArray[N];
 };

 }  // namespace Private

 // This version is suitable for use as a class member.
 // It's much the same as above except:
 //   - it has a constructor to zero itself;
 //   - it has a destructor to clean up;
 //   - get() calls SkNew(T) to create the pointer;
 //   - get(functor) calls functor to create the pointer.
 template <typename T, void (*Destroy)(T*) = Private::sk_delete<T> >
 class SkLazyPtr : SkNoncopyable {
 public:
     SkLazyPtr() : fPtr(NULL) {}
     ~SkLazyPtr() { if (fPtr) { Destroy((T*)fPtr); } }

     T* get() const {
         T* ptr = Private::consume_load(&fPtr);
         return ptr ? ptr : Private::try_cas<T*, Destroy>(&fPtr, SkNEW(T));
     }

     template <typename Create>
     T* get(const Create& create) const {
         T* ptr = Private::consume_load(&fPtr);
         return ptr ? ptr : Private::try_cas<T*, Destroy>(&fPtr, create());
     }

 private:
     mutable T* fPtr;
 };


 #endif//SkLazyPtr_DEFINED
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkLazyPtr_DEFINED
	#define SkLazyPtr_DEFINED

	/** Declare a lazily-chosen static pointer (or array of pointers) of type T.
	*
	* Example usage:
	*
	* Foo* GetSingletonFoo() {
	* SK_DECLARE_STATIC_LAZY_PTR(Foo, singleton); // Created with SkNEW, destroyed with SkDELETE.
	* return singleton.get();
	* }
	*
	* These macros take an optional T* (Create)() and void (Destroy)(T*) at the end.
	* If not given, we'll use SkNEW and SkDELETE.
	* These options are most useful when T doesn't have a public constructor or destructor.
	* Create comes first, so you may use a custom Create with a default Destroy, but not vice versa.
	*
	* Foo* CustomCreate() { return ...; }
	* void CustomDestroy(Foo* ptr) { ... }
	* Foo* GetSingletonFooWithCustomCleanup() {
	* SK_DECLARE_STATIC_LAZY_PTR(Foo, singleton, CustomCreate, CustomDestroy);
	* return singleton.get();
	* }
	*
	* If you have a bunch of related static pointers of the same type, you can
	* declare an array of lazy pointers together, and we'll pass the index to Create().
	*
	* Foo* CreateFoo(int i) { return ...; }
	* Foo* GetCachedFoo(Foo::Enum enumVal) {
	* SK_DECLARE_STATIC_LAZY_PTR_ARRAY(Foo, Foo::kEnumCount, cachedFoos, CreateFoo);
	* return cachedFoos[enumVal];
	* }
	*
	*
	* You can think of SK_DECLARE_STATIC_LAZY_PTR as a cheaper specialization of
	* SkOnce. There is no mutex or extra storage used past the pointer itself.
	*
	* We may call Create more than once, but all threads will see the same pointer
	* returned from get(). Any extra calls to Create will be cleaned up.
	*
	* These macros must be used in a global scope, not in function scope or as a class member.
	*/

	#define SK_DECLARE_STATIC_LAZY_PTR(T, name, ...) \
	namespace {} static Private::SkStaticLazyPtr<T, ##__VA_ARGS__> name

	#define SK_DECLARE_STATIC_LAZY_PTR_ARRAY(T, name, N, ...) \
	namespace {} static Private::SkStaticLazyPtrArray<T, N, ##__VA_ARGS__> name

	// namespace {} forces these macros to only be legal in global scopes. Chrome has thread-safety
	// problems with them in function-local statics because it uses -fno-threadsafe-statics, and even
	// in builds with threadsafe statics, those threadsafe statics are just unnecessary overhead.

	// Everything below here is private implementation details. Don't touch, don't even look.

	#include "SkAtomics.h"

	// See FIXME below.
	class SkFontConfigInterfaceDirect;

	namespace Private {

	// Set dst to ptr if dst is NULL. Returns value of *dst, destroying ptr if not swapped in.
	// Issues acquire memory barrier on failure, release on success.
	template <typename P, void (*Destroy)(P)>
	static P try_cas(P* dst, P ptr) {
	P prev = NULL;
	if (sk_atomic_compare_exchange(dst, &prev, ptr,
	sk_memory_order_release/on success/,
	sk_memory_order_acquire/on failure/)) {
	// We need a release barrier before returning ptr. The compare_exchange provides it.
	SkASSERT(!prev);
	return ptr;
	} else {
	Destroy(ptr);
	// We need an acquire barrier before returning prev. The compare_exchange provided it.
	SkASSERT(prev);
	return prev;
	}
	}

	template <typename T> T* sk_new() { return SkNEW(T); }
	template <typename T> void sk_delete(T* ptr) { SkDELETE(ptr); }

	// We're basing these implementations here on this article:
	// http://preshing.com/20140709/the-purpose-of-memory_order_consume-in-cpp11/
	//
	// Because the users of SkLazyPtr and SkLazyPtrArray will read the pointers
	// _through_ our atomically set pointer, there is a data dependency between our
	// atomic and the guarded data, and so we only need writer-releases /
	// reader-consumes memory pairing rather than the more general write-releases /
	// reader-acquires convention.
	//
	// This is nice, because a consume load is free on all our platforms: x86,
	// ARM, MIPS. In contrast, an acquire load issues a memory barrier on non-x86.

	template <typename T>
	T consume_load(T* ptr) {
	#if defined(THREAD_SANITIZER)
	// TSAN gets anxious if we don't tell it what we're actually doing, a consume load.
	return sk_atomic_load(ptr, sk_memory_order_consume);
	#else
	// All current compilers blindly upgrade consume memory order to acquire memory order.
	// For our purposes, though, no memory barrier is required, so we lie and use relaxed.
	return sk_atomic_load(ptr, sk_memory_order_relaxed);
	#endif
	}

	// This has no constructor and must be zero-initalized (the macro above does this).
	template <typename T, T* (Create)() = sk_new<T>, void (Destroy)(T*) = sk_delete<T> >
	class SkStaticLazyPtr {
	public:
	T* get() {
	// If fPtr has already been filled, we need a consume barrier when loading it.
	// If not, we need a release barrier when setting it. try_cas will do that.
	T* ptr = consume_load(&fPtr);
	return ptr ? ptr : try_cas<T*, Destroy>(&fPtr, Create());
	}

	private:
	T* fPtr;
	};

	template <typename T> T* sk_new_arg(int i) { return SkNEW_ARGS(T, (i)); }

	// This has no constructor and must be zero-initalized (the macro above does this).
	template <typename T, int N, T* (Create)(int) = sk_new_arg<T>, void (Destroy)(T*) = sk_delete<T> >
	class SkStaticLazyPtrArray {
	public:
	T* operator[](int i) {
	SkASSERT(i >= 0 && i < N);
	// If fPtr has already been filled, we need an consume barrier when loading it.
	// If not, we need a release barrier when setting it. try_cas will do that.
	T* ptr = consume_load(&fArray[i]);
	return ptr ? ptr : try_cas<T*, Destroy>(&fArray[i], Create(i));
	}

	private:
	T* fArray[N];
	};

	} // namespace Private

	// This version is suitable for use as a class member.
	// It's much the same as above except:
	// - it has a constructor to zero itself;
	// - it has a destructor to clean up;
	// - get() calls SkNew(T) to create the pointer;
	// - get(functor) calls functor to create the pointer.
	template <typename T, void (Destroy)(T) = Private::sk_delete<T> >
	class SkLazyPtr : SkNoncopyable {
	public:
	SkLazyPtr() : fPtr(NULL) {}
	~SkLazyPtr() { if (fPtr) { Destroy((T*)fPtr); } }

	T* get() const {
	T* ptr = Private::consume_load(&fPtr);
	return ptr ? ptr : Private::try_cas<T*, Destroy>(&fPtr, SkNEW(T));
	}

	template <typename Create>
	T* get(const Create& create) const {
	T* ptr = Private::consume_load(&fPtr);
	return ptr ? ptr : Private::try_cas<T*, Destroy>(&fPtr, create());
	}

	private:
	mutable T* fPtr;
	};


	#endif//SkLazyPtr_DEFINED