Make leak counters thread-safe and turn them on by default for Debug
Make leak counters implemented with SK_DECLARE_INST_COUNT thread-safe.
Enable the leak counting for Debug builds.
Protect the instance counter initialization step (initStep) by
using SkOnce.
Makes SkOnce.h part of the public API, since SkInstCnt is public.
Protect the per-class child list shared variable with a per-class mutex.
Changes the behavior in the way that if the child list has been
"cleaned up", it will still try to create subsequent child lists.
BUG=skia:1219
R=robertphillips@google.com, mtklein@google.com, bungeman@gmail.com, bsalomon@google.com, bungeman@google.com
Author: kkinnunen@nvidia.com
Review URL: https://codereview.chromium.org/99483003
git-svn-id: http://skia.googlecode.com/svn/trunk/src@12635 2bbb7eff-a529-9590-31e7-b0007b416f81
diff --git a/core/SkOnce.h b/core/SkOnce.h
deleted file mode 100644
index 89de112..0000000
--- a/core/SkOnce.h
+++ /dev/null
@@ -1,155 +0,0 @@
-/*
- * Copyright 2013 Google Inc.
- *
- * Use of this source code is governed by a BSD-style license that can be
- * found in the LICENSE file.
- */
-
-#ifndef SkOnce_DEFINED
-#define SkOnce_DEFINED
-
-// SkOnce.h defines SK_DECLARE_STATIC_ONCE and SkOnce(), which you can use
-// together to create a threadsafe way to call a function just once. This
-// is particularly useful for lazy singleton initialization. E.g.
-//
-// static void set_up_my_singleton(Singleton** singleton) {
-// *singleton = new Singleton(...);
-// }
-// ...
-// const Singleton& GetSingleton() {
-// static Singleton* singleton = NULL;
-// SK_DECLARE_STATIC_ONCE(once);
-// SkOnce(&once, set_up_my_singleton, &singleton);
-// SkASSERT(NULL != singleton);
-// return *singleton;
-// }
-//
-// OnceTest.cpp also should serve as a few other simple examples.
-
-#include "SkThread.h"
-#include "SkTypes.h"
-
-#ifdef SK_USE_POSIX_THREADS
-# define SK_ONCE_INIT { false, { PTHREAD_MUTEX_INITIALIZER } }
-#else
-# define SK_ONCE_INIT { false, SkBaseMutex() }
-#endif
-
-#define SK_DECLARE_STATIC_ONCE(name) static SkOnceFlag name = SK_ONCE_INIT
-
-struct SkOnceFlag; // If manually created, initialize with SkOnceFlag once = SK_ONCE_INIT
-
-template <typename Func, typename Arg>
-inline void SkOnce(SkOnceFlag* once, Func f, Arg arg);
-
-// ---------------------- Implementation details below here. -----------------------------
-
-struct SkOnceFlag {
- bool done;
- SkBaseMutex mutex;
-};
-
-// TODO(bungeman, mtklein): move all these *barrier* functions to SkThread when refactoring lands.
-
-#ifdef SK_BUILD_FOR_WIN
-#include <intrin.h>
-inline static void compiler_barrier() {
- _ReadWriteBarrier();
-}
-#else
-inline static void compiler_barrier() {
- asm volatile("" : : : "memory");
-}
-#endif
-
-inline static void full_barrier_on_arm() {
-#ifdef SK_CPU_ARM
-#if SK_ARM_ARCH >= 7
- asm volatile("dmb" : : : "memory");
-#else
- asm volatile("mcr p15, 0, %0, c7, c10, 5" : : "r" (0) : "memory");
-#endif
-#endif
-}
-
-// On every platform, we issue a compiler barrier to prevent it from reordering
-// code. That's enough for platforms like x86 where release and acquire
-// barriers are no-ops. On other platforms we may need to be more careful;
-// ARM, in particular, needs real code for both acquire and release. We use a
-// full barrier, which acts as both, because that the finest precision ARM
-// provides.
-
-inline static void release_barrier() {
- compiler_barrier();
- full_barrier_on_arm();
-}
-
-inline static void acquire_barrier() {
- compiler_barrier();
- full_barrier_on_arm();
-}
-
-// We've pulled a pretty standard double-checked locking implementation apart
-// into its main fast path and a slow path that's called when we suspect the
-// one-time code hasn't run yet.
-
-// This is the guts of the code, called when we suspect the one-time code hasn't been run yet.
-// This should be rarely called, so we separate it from SkOnce and don't mark it as inline.
-// (We don't mind if this is an actual function call, but odds are it'll be inlined anyway.)
-template <typename Func, typename Arg>
-static void sk_once_slow(SkOnceFlag* once, Func f, Arg arg) {
- const SkAutoMutexAcquire lock(once->mutex);
- if (!once->done) {
- f(arg);
- // Also known as a store-store/load-store barrier, this makes sure that the writes
- // done before here---in particular, those done by calling f(arg)---are observable
- // before the writes after the line, *done = true.
- //
- // In version control terms this is like saying, "check in the work up
- // to and including f(arg), then check in *done=true as a subsequent change".
- //
- // We'll use this in the fast path to make sure f(arg)'s effects are
- // observable whenever we observe *done == true.
- release_barrier();
- once->done = true;
- }
-}
-
-// We nabbed this code from the dynamic_annotations library, and in their honor
-// we check the same define. If you find yourself wanting more than just
-// ANNOTATE_BENIGN_RACE, it might make sense to pull that in as a dependency
-// rather than continue to reproduce it here.
-
-#if DYNAMIC_ANNOTATIONS_ENABLED
-// TSAN provides this hook to supress a known-safe apparent race.
-extern "C" {
-void AnnotateBenignRace(const char* file, int line, const volatile void* mem, const char* desc);
-}
-#define ANNOTATE_BENIGN_RACE(mem, desc) AnnotateBenignRace(__FILE__, __LINE__, mem, desc)
-#else
-#define ANNOTATE_BENIGN_RACE(mem, desc)
-#endif
-
-// This is our fast path, called all the time. We do really want it to be inlined.
-template <typename Func, typename Arg>
-inline void SkOnce(SkOnceFlag* once, Func f, Arg arg) {
- ANNOTATE_BENIGN_RACE(&(once->done), "Don't worry TSAN, we're sure this is safe.");
- if (!once->done) {
- sk_once_slow(once, f, arg);
- }
- // Also known as a load-load/load-store barrier, this acquire barrier makes
- // sure that anything we read from memory---in particular, memory written by
- // calling f(arg)---is at least as current as the value we read from once->done.
- //
- // In version control terms, this is a lot like saying "sync up to the
- // commit where we wrote once->done = true".
- //
- // The release barrier in sk_once_slow guaranteed that once->done = true
- // happens after f(arg), so by syncing to once->done = true here we're
- // forcing ourselves to also wait until the effects of f(arg) are readble.
- acquire_barrier();
-}
-
-#undef ANNOTATE_BENIGN_RACE
-
-#endif // SkOnce_DEFINED
