/* * 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 F. * * Example usage: * * Foo* CreateFoo() { return SkNEW(Foo); } * Foo* GetSingletonFoo() { * SK_DECLARE_STATIC_LAZY_PTR(Foo, singleton, CreateFoo); // Clean up with SkDELETE. * return singleton.get(); * } * * These macros take an optional void (*Destroy)(T*) at the end. If not given, we'll use SkDELETE. * This option is most useful when T doesn't have a public destructor. * * void CustomCleanup(Foo* ptr) { ... } * Foo* GetSingletonFooWithCustomCleanup() { * SK_DECLARE_STATIC_LAZY_PTR(Foo, singleton, CreateFoo, CustomCleanup); * 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: * * 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. * In debug mode, each lazy pointer will be cleaned up at process exit so we * can check that we've not leaked or freed them early. * * 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 or function scope, not as a class member. */ #define SK_DECLARE_STATIC_LAZY_PTR(T, name, Create, ...) \ static Private::SkLazyPtr name #define SK_DECLARE_STATIC_LAZY_PTR_ARRAY(T, name, N, Create, ...) \ static Private::SkLazyPtrArray name // Everything below here is private implementation details. Don't touch, don't even look. #include "SkDynamicAnnotations.h" #include "SkThread.h" #include "SkThreadPriv.h" // See FIXME below. class SkFontConfigInterface; namespace Private { template void sk_delete(T* ptr) { SkDELETE(ptr); } // Set *dst to ptr if *dst is NULL. Returns value of *dst, destroying ptr if not swapped in. // Issues the same memory barriers as sk_atomic_cas: acquire on failure, release on success. template static P try_cas(void** dst, P ptr) { P prev = (P)sk_atomic_cas(dst, NULL, ptr); if (prev) { // We need an acquire barrier before returning prev, which sk_atomic_cas provided. Destroy(ptr); return prev; } else { // We need a release barrier before returning ptr, which sk_atomic_cas provided. return ptr; } } // This has no constructor and must be zero-initalized (the macro above does this). template > class SkLazyPtr { public: T* get() { // If fPtr has already been filled, we need an acquire barrier when loading it. // If not, we need a release barrier when setting it. try_cas will do that. T* ptr = (T*)sk_acquire_load(&fPtr); return ptr ? ptr : try_cas(&fPtr, Create()); } #ifdef SK_DEVELOPER // FIXME: We know we leak refs on some classes. For now, let them leak. void cleanup(SkFontConfigInterface*) {} template void cleanup(U* ptr) { Destroy(ptr); } ~SkLazyPtr() { this->cleanup((T*)fPtr); fPtr = NULL; } #endif private: void* fPtr; }; // This has no constructor and must be zero-initalized (the macro above does this). template > class SkLazyPtrArray { public: T* operator[](int i) { SkASSERT(i >= 0 && i < N); // If fPtr has already been filled, we need an acquire barrier when loading it. // If not, we need a release barrier when setting it. try_cas will do that. T* ptr = (T*)sk_acquire_load(&fArray[i]); return ptr ? ptr : try_cas(&fArray[i], Create(i)); } #ifdef SK_DEVELOPER ~SkLazyPtrArray() { for (int i = 0; i < N; i++) { Destroy((T*)fArray[i]); fArray[i] = NULL; } } #endif private: void* fArray[N]; }; } // namespace Private #endif//SkLazyPtr_DEFINED