profiling/instrumentation.h - platform/external/gemmlowp - Git at Google

 // Copyright 2015 The Gemmlowp Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 // instrumentation.h: contains the definitions needed to
 // instrument code for profiling:
 //   ScopedProfilingLabel, RegisterCurrentThreadForProfiling.
 //
 // profiler.h is only needed to drive the profiler:
 //   StartProfiling, FinishProfiling.
 //
 // See the usage example in profiler.h.

 #ifndef GEMMLOWP_PROFILING_INSTRUMENTATION_H_
 #define GEMMLOWP_PROFILING_INSTRUMENTATION_H_

 #include <cstdio>

 #ifndef GEMMLOWP_USE_STLPORT
 #include <cstdint>
 #else
 #include <stdint.h>
 namespace std {
 using ::int16_t;
 using ::int32_t;
 using ::int8_t;
 using ::size_t;
 using ::uint16_t;
 using ::uint32_t;
 using ::uint8_t;
 using ::uintptr_t;
 }  // namespace std
 #endif

 #include <algorithm>
 #include <cassert>
 #include <cstdlib>

 #ifdef GEMMLOWP_PROFILING
 #include <cstring>
 #include <set>
 #endif

 #include "./pthread_everywhere.h"

 namespace gemmlowp {

 inline void ReleaseBuildAssertion(bool condition, const char* msg) {
   if (!condition) {
     fprintf(stderr, "gemmlowp error: %s\n", msg);
     abort();
   }
 }

 class Mutex {
  public:
   Mutex(const Mutex&) = delete;
   Mutex& operator=(const Mutex&) = delete;

   Mutex() { pthread_mutex_init(&m, NULL); }
   ~Mutex() { pthread_mutex_destroy(&m); }

   void Lock() { pthread_mutex_lock(&m); }
   void Unlock() { pthread_mutex_unlock(&m); }

  private:
   pthread_mutex_t m;
 };

 class GlobalMutexes {
  public:
   static Mutex* Profiler() {
     static Mutex m;
     return &m;
   }

   static Mutex* EightBitIntGemm() {
     static Mutex m;
     return &m;
   }
 };

 // A very simple RAII helper to lock and unlock a Mutex
 struct ScopedLock {
   ScopedLock(Mutex* m) : _m(m) { _m->Lock(); }
   ~ScopedLock() { _m->Unlock(); }

  private:
   Mutex* _m;
 };

 // Profiling definitions. Two paths: when profiling is enabled,
 // and when profiling is disabled.
 #ifdef GEMMLOWP_PROFILING
 // This code path is when profiling is enabled.

 // A pseudo-call-stack. Contrary to a real call-stack, this only
 // contains pointers to literal strings that were manually entered
 // in the instrumented code (see ScopedProfilingLabel).
 struct ProfilingStack {
   static const std::size_t kMaxSize = 30;
   typedef const char* LabelsArrayType[kMaxSize];
   LabelsArrayType labels;
   std::size_t size;
   Mutex* lock;

   ProfilingStack() { memset(this, 0, sizeof(ProfilingStack)); }
   ~ProfilingStack() { delete lock; }

   void Push(const char* label) {
     ScopedLock sl(lock);
     ReleaseBuildAssertion(size < kMaxSize, "ProfilingStack overflow");
     labels[size] = label;
     size++;
   }

   void Pop() {
     ScopedLock sl(lock);
     ReleaseBuildAssertion(size > 0, "ProfilingStack underflow");
     size--;
   }

   void UpdateTop(const char* new_label) {
     ScopedLock sl(lock);
     assert(size);
     labels[size - 1] = new_label;
   }

   ProfilingStack& operator=(const ProfilingStack& other) {
     memcpy(this, &other, sizeof(ProfilingStack));
     return *this;
   }

   bool operator==(const ProfilingStack& other) const {
     return !memcmp(this, &other, sizeof(ProfilingStack));
   }
 };

 static_assert(
     !(sizeof(ProfilingStack) & (sizeof(ProfilingStack) - 1)),
     "ProfilingStack should have power-of-two size to fit in cache lines");

 struct ThreadInfo;

 // The global set of threads being profiled.
 inline std::set<ThreadInfo*>& ThreadsUnderProfiling() {
   static std::set<ThreadInfo*> v;
   return v;
 }

 struct ThreadInfo {
   pthread_key_t key;  // used only to get a callback at thread exit.
   ProfilingStack stack;

   ThreadInfo() {
     pthread_key_create(&key, ThreadExitCallback);
     pthread_setspecific(key, this);
     stack.lock = new Mutex();
   }

   static void ThreadExitCallback(void* ptr) {
     ScopedLock sl(GlobalMutexes::Profiler());
     ThreadInfo* self = static_cast<ThreadInfo*>(ptr);
     ThreadsUnderProfiling().erase(self);
   }
 };

 inline ThreadInfo& ThreadLocalThreadInfo() {
   static pthread_key_t key;
   static auto DeleteThreadInfo = [](void* threadInfoPtr) {
     ThreadInfo* threadInfo = static_cast<ThreadInfo*>(threadInfoPtr);
     if (threadInfo) {
       delete threadInfo;
     }
   };

   // key_result is unused. The purpose of this 'static' local object is
   // to have its initializer (the pthread_key_create call) performed exactly
   // once, in a way that is guaranteed (since C++11) to be reentrant.
   static const int key_result = pthread_key_create(&key, DeleteThreadInfo);
   (void)key_result;

   ThreadInfo* threadInfo = static_cast<ThreadInfo*>(pthread_getspecific(key));
   if (!threadInfo) {
     threadInfo = new ThreadInfo();
     pthread_setspecific(key, threadInfo);
   }
   return *threadInfo;
 }

 // ScopedProfilingLabel is how one instruments code for profiling
 // with this profiler. Construct local ScopedProfilingLabel variables,
 // passing a literal string describing the local code. Profile
 // samples will then be annotated with this label, while it is in scope
 // (whence the name --- also known as RAII).
 // See the example in profiler.h.
 class ScopedProfilingLabel {
   ProfilingStack* profiling_stack_;

  public:
   explicit ScopedProfilingLabel(const char* label)
       : profiling_stack_(&ThreadLocalThreadInfo().stack) {
     profiling_stack_->Push(label);
   }

   ~ScopedProfilingLabel() { profiling_stack_->Pop(); }

   void Update(const char* new_label) { profiling_stack_->UpdateTop(new_label); }
 };

 // To be called once on each thread to be profiled.
 inline void RegisterCurrentThreadForProfiling() {
   ScopedLock sl(GlobalMutexes::Profiler());
   ThreadsUnderProfiling().insert(&ThreadLocalThreadInfo());
 }

 #else  // not GEMMLOWP_PROFILING
 // This code path is when profiling is disabled.

 // This empty definition of ScopedProfilingLabel ensures that
 // it has zero runtime overhead when profiling is disabled.
 struct ScopedProfilingLabel {
   explicit ScopedProfilingLabel(const char*) {}
   void Update(const char*) {}
 };

 inline void RegisterCurrentThreadForProfiling() {}

 #endif

 }  // end namespace gemmlowp

 #endif  // GEMMLOWP_PROFILING_INSTRUMENTATION_H_
	// Copyright 2015 The Gemmlowp Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	// instrumentation.h: contains the definitions needed to
	// instrument code for profiling:
	// ScopedProfilingLabel, RegisterCurrentThreadForProfiling.
	//
	// profiler.h is only needed to drive the profiler:
	// StartProfiling, FinishProfiling.
	//
	// See the usage example in profiler.h.

	#ifndef GEMMLOWP_PROFILING_INSTRUMENTATION_H_
	#define GEMMLOWP_PROFILING_INSTRUMENTATION_H_

	#include <cstdio>

	#ifndef GEMMLOWP_USE_STLPORT
	#include <cstdint>
	#else
	#include <stdint.h>
	namespace std {
	using ::int16_t;
	using ::int32_t;
	using ::int8_t;
	using ::size_t;
	using ::uint16_t;
	using ::uint32_t;
	using ::uint8_t;
	using ::uintptr_t;
	} // namespace std
	#endif

	#include <algorithm>
	#include <cassert>
	#include <cstdlib>

	#ifdef GEMMLOWP_PROFILING
	#include <cstring>
	#include <set>
	#endif

	#include "./pthread_everywhere.h"

	namespace gemmlowp {

	inline void ReleaseBuildAssertion(bool condition, const char* msg) {
	if (!condition) {
	fprintf(stderr, "gemmlowp error: %s\n", msg);
	abort();
	}
	}

	class Mutex {
	public:
	Mutex(const Mutex&) = delete;
	Mutex& operator=(const Mutex&) = delete;

	Mutex() { pthread_mutex_init(&m, NULL); }
	~Mutex() { pthread_mutex_destroy(&m); }

	void Lock() { pthread_mutex_lock(&m); }
	void Unlock() { pthread_mutex_unlock(&m); }

	private:
	pthread_mutex_t m;
	};

	class GlobalMutexes {
	public:
	static Mutex* Profiler() {
	static Mutex m;
	return &m;
	}

	static Mutex* EightBitIntGemm() {
	static Mutex m;
	return &m;
	}
	};

	// A very simple RAII helper to lock and unlock a Mutex
	struct ScopedLock {
	ScopedLock(Mutex* m) : _m(m) { _m->Lock(); }
	~ScopedLock() { _m->Unlock(); }

	private:
	Mutex* _m;
	};

	// Profiling definitions. Two paths: when profiling is enabled,
	// and when profiling is disabled.
	#ifdef GEMMLOWP_PROFILING
	// This code path is when profiling is enabled.

	// A pseudo-call-stack. Contrary to a real call-stack, this only
	// contains pointers to literal strings that were manually entered
	// in the instrumented code (see ScopedProfilingLabel).
	struct ProfilingStack {
	static const std::size_t kMaxSize = 30;
	typedef const char* LabelsArrayType[kMaxSize];
	LabelsArrayType labels;
	std::size_t size;
	Mutex* lock;

	ProfilingStack() { memset(this, 0, sizeof(ProfilingStack)); }
	~ProfilingStack() { delete lock; }

	void Push(const char* label) {
	ScopedLock sl(lock);
	ReleaseBuildAssertion(size < kMaxSize, "ProfilingStack overflow");
	labels[size] = label;
	size++;
	}

	void Pop() {
	ScopedLock sl(lock);
	ReleaseBuildAssertion(size > 0, "ProfilingStack underflow");
	size--;
	}

	void UpdateTop(const char* new_label) {
	ScopedLock sl(lock);
	assert(size);
	labels[size - 1] = new_label;
	}

	ProfilingStack& operator=(const ProfilingStack& other) {
	memcpy(this, &other, sizeof(ProfilingStack));
	return *this;
	}

	bool operator==(const ProfilingStack& other) const {
	return !memcmp(this, &other, sizeof(ProfilingStack));
	}
	};

	static_assert(
	!(sizeof(ProfilingStack) & (sizeof(ProfilingStack) - 1)),
	"ProfilingStack should have power-of-two size to fit in cache lines");

	struct ThreadInfo;

	// The global set of threads being profiled.
	inline std::set<ThreadInfo*>& ThreadsUnderProfiling() {
	static std::set<ThreadInfo*> v;
	return v;
	}

	struct ThreadInfo {
	pthread_key_t key; // used only to get a callback at thread exit.
	ProfilingStack stack;

	ThreadInfo() {
	pthread_key_create(&key, ThreadExitCallback);
	pthread_setspecific(key, this);
	stack.lock = new Mutex();
	}

	static void ThreadExitCallback(void* ptr) {
	ScopedLock sl(GlobalMutexes::Profiler());
	ThreadInfo* self = static_cast<ThreadInfo*>(ptr);
	ThreadsUnderProfiling().erase(self);
	}
	};

	inline ThreadInfo& ThreadLocalThreadInfo() {
	static pthread_key_t key;
	static auto DeleteThreadInfo = [](void* threadInfoPtr) {
	ThreadInfo* threadInfo = static_cast<ThreadInfo*>(threadInfoPtr);
	if (threadInfo) {
	delete threadInfo;
	}
	};

	// key_result is unused. The purpose of this 'static' local object is
	// to have its initializer (the pthread_key_create call) performed exactly
	// once, in a way that is guaranteed (since C++11) to be reentrant.
	static const int key_result = pthread_key_create(&key, DeleteThreadInfo);
	(void)key_result;

	ThreadInfo* threadInfo = static_cast<ThreadInfo*>(pthread_getspecific(key));
	if (!threadInfo) {
	threadInfo = new ThreadInfo();
	pthread_setspecific(key, threadInfo);
	}
	return *threadInfo;
	}

	// ScopedProfilingLabel is how one instruments code for profiling
	// with this profiler. Construct local ScopedProfilingLabel variables,
	// passing a literal string describing the local code. Profile
	// samples will then be annotated with this label, while it is in scope
	// (whence the name --- also known as RAII).
	// See the example in profiler.h.
	class ScopedProfilingLabel {
	ProfilingStack* profiling_stack_;

	public:
	explicit ScopedProfilingLabel(const char* label)
	: profiling_stack_(&ThreadLocalThreadInfo().stack) {
	profiling_stack_->Push(label);
	}

	~ScopedProfilingLabel() { profiling_stack_->Pop(); }

	void Update(const char* new_label) { profiling_stack_->UpdateTop(new_label); }
	};

	// To be called once on each thread to be profiled.
	inline void RegisterCurrentThreadForProfiling() {
	ScopedLock sl(GlobalMutexes::Profiler());
	ThreadsUnderProfiling().insert(&ThreadLocalThreadInfo());
	}

	#else // not GEMMLOWP_PROFILING
	// This code path is when profiling is disabled.

	// This empty definition of ScopedProfilingLabel ensures that
	// it has zero runtime overhead when profiling is disabled.
	struct ScopedProfilingLabel {
	explicit ScopedProfilingLabel(const char*) {}
	void Update(const char*) {}
	};

	inline void RegisterCurrentThreadForProfiling() {}

	#endif

	} // end namespace gemmlowp

	#endif // GEMMLOWP_PROFILING_INSTRUMENTATION_H_