drd/tests/tsan_thread_wrappers_pthread.h - platform/external/valgrind - Git at Google

 /*
   This file is part of Valgrind, a dynamic binary instrumentation
   framework.

   Copyright (C) 2008-2008 Google Inc
      opensource@google.com

   This program is free software; you can redistribute it and/or
   modify it under the terms of the GNU General Public License as
   published by the Free Software Foundation; either version 2 of the
   License, or (at your option) any later version.

   This program is distributed in the hope that it will be useful, but
   WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
   02111-1307, USA.

   The GNU General Public License is contained in the file COPYING.
 */

 // Author: Konstantin Serebryany <opensource@google.com>
 //
 // Here we define few simple classes that wrap pthread primitives.
 //
 // We need this to create unit tests for helgrind (or similar tool)
 // that will work with different threading frameworks.
 //
 // If one needs to test helgrind's support for another threading library,
 // he/she can create a copy of this file and replace pthread_ calls
 // with appropriate calls to his/her library.
 //
 // Note, that some of the methods defined here are annotated with
 // ANNOTATE_* macros defined in dynamic_annotations.h.
 //
 // DISCLAIMER: the classes defined in this header file
 // are NOT intended for general use -- only for unit tests.
 //

 #ifndef THREAD_WRAPPERS_PTHREAD_H
 #define THREAD_WRAPPERS_PTHREAD_H

 #include <pthread.h>
 #include <semaphore.h>
 #include <unistd.h>
 #include <queue>
 #include <stdio.h>
 #include <limits.h>   // INT_MAX

 #ifdef VGO_darwin
 #include <libkern/OSAtomic.h>
 #define NO_BARRIER
 #define NO_TLS
 #endif

 #include <string>
 using namespace std;

 #include <sys/time.h>
 #include <time.h>

 #include "../../drd/drd.h"
 #define ANNOTATE_NO_OP(arg) do { } while(0)
 #define ANNOTATE_EXPECT_RACE(addr, descr)                \
     ANNOTATE_BENIGN_RACE_SIZED(addr, 4, "expected race")
 static inline bool RunningOnValgrind() { return RUNNING_ON_VALGRIND; }

 #include <assert.h>
 #ifdef NDEBUG
 # error "Pleeease, do not define NDEBUG"
 #endif
 #define CHECK assert

 /// Set this to true if malloc() uses mutex on your platform as this may
 /// introduce a happens-before arc for a pure happens-before race detector.
 const bool kMallocUsesMutex = false;

 /// Current time in milliseconds.
 static inline int64_t GetCurrentTimeMillis() {
   struct timeval now;
   gettimeofday(&now, NULL);
   return now.tv_sec * 1000 + now.tv_usec / 1000;
 }

 /// Copy tv to ts adding offset in milliseconds.
 static inline void timeval2timespec(timeval *const tv,
                                      timespec *ts,
                                      int64_t offset_milli) {
   const int64_t ten_9 = 1000000000LL;
   const int64_t ten_6 = 1000000LL;
   const int64_t ten_3 = 1000LL;
   int64_t now_nsec = (int64_t)tv->tv_sec * ten_9;
   now_nsec += (int64_t)tv->tv_usec * ten_3;
   int64_t then_nsec = now_nsec + offset_milli * ten_6;
   ts->tv_sec  = then_nsec / ten_9;
   ts->tv_nsec = then_nsec % ten_9;
 }


 class CondVar;

 #ifndef NO_SPINLOCK
 /// helgrind does not (yet) support spin locks, so we annotate them.

 #ifndef VGO_darwin
 class SpinLock {
  public:
   SpinLock() {
     CHECK(0 == pthread_spin_init(&mu_, 0));
     ANNOTATE_RWLOCK_CREATE((void*)&mu_);
   }
   ~SpinLock() {
     ANNOTATE_RWLOCK_DESTROY((void*)&mu_);
     CHECK(0 == pthread_spin_destroy(&mu_));
   }
   void Lock() {
     CHECK(0 == pthread_spin_lock(&mu_));
     ANNOTATE_RWLOCK_ACQUIRED((void*)&mu_, 1);
   }
   void Unlock() {
     ANNOTATE_RWLOCK_RELEASED((void*)&mu_, 1);
     CHECK(0 == pthread_spin_unlock(&mu_));
   }
  private:
   pthread_spinlock_t mu_;
 };

 #else

 class SpinLock {
  public:
   // Mac OS X version.
   SpinLock() : mu_(OS_SPINLOCK_INIT) {
     ANNOTATE_RWLOCK_CREATE((void*)&mu_);
   }
   ~SpinLock() {
     ANNOTATE_RWLOCK_DESTROY((void*)&mu_);
   }
   void Lock() {
     OSSpinLockLock(&mu_);
     ANNOTATE_RWLOCK_ACQUIRED((void*)&mu_, 1);
   }
   void Unlock() {
     ANNOTATE_RWLOCK_RELEASED((void*)&mu_, 1);
     OSSpinLockUnlock(&mu_);
   }
  private:
   OSSpinLock mu_;
 };
 #endif // VGO_darwin

 #endif // NO_SPINLOCK

 /// Just a boolean condition. Used by Mutex::LockWhen and similar.
 class Condition {
  public:
   typedef bool (*func_t)(void*);

   template <typename T>
   Condition(bool (*func)(T*), T* arg)
   : func_(reinterpret_cast<func_t>(func)), arg_(arg) {}

   Condition(bool (*func)())
   : func_(reinterpret_cast<func_t>(func)), arg_(NULL) {}

   bool Eval() { return func_(arg_); }
  private:
   func_t func_;
   void *arg_;

 };


 /// Wrapper for pthread_mutex_t.
 ///
 /// pthread_mutex_t is *not* a reader-writer lock,
 /// so the methods like ReaderLock() aren't really reader locks.
 /// We can not use pthread_rwlock_t because it
 /// does not work with pthread_cond_t.
 ///
 /// TODO: We still need to test reader locks with this class.
 /// Implement a mode where pthread_rwlock_t will be used
 /// instead of pthread_mutex_t (only when not used with CondVar or LockWhen).
 ///
 class Mutex {
   friend class CondVar;
  public:
   Mutex() {
     CHECK(0 == pthread_mutex_init(&mu_, NULL));
     CHECK(0 == pthread_cond_init(&cv_, NULL));
     signal_at_unlock_ = true;  // Always signal at Unlock to make
                                // Mutex more friendly to hybrid detectors.
   }
   ~Mutex() {
     CHECK(0 == pthread_cond_destroy(&cv_));
     CHECK(0 == pthread_mutex_destroy(&mu_));
   }
   void Lock()          { CHECK(0 == pthread_mutex_lock(&mu_));}
   bool TryLock()       { return (0 == pthread_mutex_trylock(&mu_));}
   void Unlock() {
     if (signal_at_unlock_) {
       CHECK(0 == pthread_cond_signal(&cv_));
     }
     CHECK(0 == pthread_mutex_unlock(&mu_));
   }
   void ReaderLock()    { Lock(); }
   bool ReaderTryLock() { return TryLock();}
   void ReaderUnlock()  { Unlock(); }

   void LockWhen(Condition cond)            { Lock(); WaitLoop(cond); }
   void ReaderLockWhen(Condition cond)      { Lock(); WaitLoop(cond); }
   void Await(Condition cond)               { WaitLoop(cond); }

   bool ReaderLockWhenWithTimeout(Condition cond, int millis)
     { Lock(); return WaitLoopWithTimeout(cond, millis); }
   bool LockWhenWithTimeout(Condition cond, int millis)
     { Lock(); return WaitLoopWithTimeout(cond, millis); }
   bool AwaitWithTimeout(Condition cond, int millis)
     { return WaitLoopWithTimeout(cond, millis); }

  private:

   void WaitLoop(Condition cond) {
     signal_at_unlock_ = true;
     while(cond.Eval() == false) {
       pthread_cond_wait(&cv_, &mu_);
     }
     ANNOTATE_CONDVAR_LOCK_WAIT(&cv_, &mu_);
   }

   bool WaitLoopWithTimeout(Condition cond, int millis) {
     struct timeval now;
     struct timespec timeout;
     int retcode = 0;
     gettimeofday(&now, NULL);
     timeval2timespec(&now, &timeout, millis);

     signal_at_unlock_ = true;
     while (cond.Eval() == false && retcode == 0) {
       retcode = pthread_cond_timedwait(&cv_, &mu_, &timeout);
     }
     if(retcode == 0) {
       ANNOTATE_CONDVAR_LOCK_WAIT(&cv_, &mu_);
     }
     return cond.Eval();
   }

   // A hack. cv_ should be the first data member so that
   // ANNOTATE_CONDVAR_WAIT(&MU, &MU) and ANNOTATE_CONDVAR_SIGNAL(&MU) works.
   // (See also racecheck_unittest.cc)
   pthread_cond_t  cv_;
   pthread_mutex_t mu_;
   bool            signal_at_unlock_;  // Set to true if Wait was called.
 };


 class MutexLock {  // Scoped Mutex Locker/Unlocker
  public:
   MutexLock(Mutex *mu)
     : mu_(mu) {
     mu_->Lock();
   }
   ~MutexLock() {
     mu_->Unlock();
   }
  private:
   Mutex *mu_;
 };


 /// Wrapper for pthread_cond_t.
 class CondVar {
  public:
   CondVar()   { CHECK(0 == pthread_cond_init(&cv_, NULL)); }
   ~CondVar()  { CHECK(0 == pthread_cond_destroy(&cv_)); }
   void Wait(Mutex *mu) { CHECK(0 == pthread_cond_wait(&cv_, &mu->mu_)); }
   bool WaitWithTimeout(Mutex *mu, int millis) {
     struct timeval now;
     struct timespec timeout;
     gettimeofday(&now, NULL);
     timeval2timespec(&now, &timeout, millis);
     return 0 != pthread_cond_timedwait(&cv_, &mu->mu_, &timeout);
   }
   void Signal() { CHECK(0 == pthread_cond_signal(&cv_)); }
   void SignalAll() { CHECK(0 == pthread_cond_broadcast(&cv_)); }
  private:
   pthread_cond_t cv_;
 };


 // pthreads do not allow to use condvar with rwlock so we can't make
 // ReaderLock method of Mutex to be the real rw-lock.
 // So, we need a special lock class to test reader locks.
 #define NEEDS_SEPERATE_RW_LOCK
 class RWLock {
  public:
   RWLock() { CHECK(0 == pthread_rwlock_init(&mu_, NULL)); }
   ~RWLock() { CHECK(0 == pthread_rwlock_destroy(&mu_)); }
   void Lock() { CHECK(0 == pthread_rwlock_wrlock(&mu_)); }
   void ReaderLock() { CHECK(0 == pthread_rwlock_rdlock(&mu_)); }
   void Unlock() { CHECK(0 == pthread_rwlock_unlock(&mu_)); }
   void ReaderUnlock() { CHECK(0 == pthread_rwlock_unlock(&mu_)); }
  private:
   pthread_cond_t dummy; // Damn, this requires some redesign...
   pthread_rwlock_t mu_;
 };

 class ReaderLockScoped {  // Scoped RWLock Locker/Unlocker
  public:
   ReaderLockScoped(RWLock *mu)
     : mu_(mu) {
     mu_->ReaderLock();
   }
   ~ReaderLockScoped() {
     mu_->ReaderUnlock();
   }
  private:
   RWLock *mu_;
 };

 class WriterLockScoped {  // Scoped RWLock Locker/Unlocker
  public:
   WriterLockScoped(RWLock *mu)
     : mu_(mu) {
     mu_->Lock();
   }
   ~WriterLockScoped() {
     mu_->Unlock();
   }
  private:
   RWLock *mu_;
 };


 /// Wrapper for pthread_create()/pthread_join().
 class MyThread {
  public:
   typedef void *(*worker_t)(void*);

   MyThread(worker_t worker, void *arg = NULL, const char *name = NULL)
       :w_(worker), arg_(arg), name_(name) {}
   MyThread(void (*worker)(void), void *arg = NULL, const char *name = NULL)
       :w_(reinterpret_cast<worker_t>(worker)), arg_(arg), name_(name) {}
   MyThread(void (*worker)(void *), void *arg = NULL, const char *name = NULL)
       :w_(reinterpret_cast<worker_t>(worker)), arg_(arg), name_(name) {}

   ~MyThread(){ w_ = NULL; arg_ = NULL;}
   void Start() { CHECK(0 == pthread_create(&t_, NULL, (worker_t)ThreadBody, this));}
   void Join()  { CHECK(0 == pthread_join(t_, NULL));}
   pthread_t tid() const { return t_; }
  private:
   static void ThreadBody(MyThread *my_thread) {
     if (my_thread->name_) {
       ANNOTATE_THREAD_NAME(my_thread->name_);
     }
     my_thread->w_(my_thread->arg_);
   }
   pthread_t t_;
   worker_t  w_;
   void     *arg_;
   const char *name_;
 };


 /// Just a message queue.
 class ProducerConsumerQueue {
  public:
   ProducerConsumerQueue(int unused) {
     //ANNOTATE_PCQ_CREATE(this);
   }
   ~ProducerConsumerQueue() {
     CHECK(q_.empty());
     //ANNOTATE_PCQ_DESTROY(this);
   }

   // Put.
   void Put(void *item) {
     mu_.Lock();
       q_.push(item);
       ANNOTATE_CONDVAR_SIGNAL(&mu_); // LockWhen in Get()
       //ANNOTATE_PCQ_PUT(this);
     mu_.Unlock();
   }

   // Get.
   // Blocks if the queue is empty.
   void *Get() {
     mu_.LockWhen(Condition(IsQueueNotEmpty, &q_));
       void * item = NULL;
       bool ok = TryGetInternal(&item);
       CHECK(ok);
     mu_.Unlock();
     return item;
   }

   // If queue is not empty,
   // remove an element from queue, put it into *res and return true.
   // Otherwise return false.
   bool TryGet(void **res) {
     mu_.Lock();
       bool ok = TryGetInternal(res);
     mu_.Unlock();
     return ok;
   }

  private:
   Mutex mu_;
   std::queue<void*> q_; // protected by mu_

   // Requires mu_
   bool TryGetInternal(void ** item_ptr) {
     if (q_.empty())
       return false;
     *item_ptr = q_.front();
     q_.pop();
     //ANNOTATE_PCQ_GET(this);
     return true;
   }

   static bool IsQueueNotEmpty(std::queue<void*> * queue) {
      return !queue->empty();
   }
 };


 /// Function pointer with zero, one or two parameters.
 struct Closure {
   typedef void (*F0)();
   typedef void (*F1)(void *arg1);
   typedef void (*F2)(void *arg1, void *arg2);
   int  n_params;
   void *f;
   void *param1;
   void *param2;

   void Execute() {
     if (n_params == 0) {
       (F0(f))();
     } else if (n_params == 1) {
       (F1(f))(param1);
     } else {
       CHECK(n_params == 2);
       (F2(f))(param1, param2);
     }
     delete this;
   }
 };

 Closure *NewCallback(void (*f)()) {
   Closure *res = new Closure;
   res->n_params = 0;
   res->f = (void*)(f);
   res->param1 = NULL;
   res->param2 = NULL;
   return res;
 }

 template <class P1>
 Closure *NewCallback(void (*f)(P1), P1 p1) {
   CHECK(sizeof(P1) <= sizeof(void*));
   Closure *res = new Closure;
   res->n_params = 1;
   res->f = (void*)(f);
   res->param1 = (void*)p1;
   res->param2 = NULL;
   return res;
 }

 template <class T, class P1, class P2>
 Closure *NewCallback(void (*f)(P1, P2), P1 p1, P2 p2) {
   CHECK(sizeof(P1) <= sizeof(void*));
   Closure *res = new Closure;
   res->n_params = 2;
   res->f = (void*)(f);
   res->param1 = (void*)p1;
   res->param2 = (void*)p2;
   return res;
 }

 /*! A thread pool that uses ProducerConsumerQueue.
   Usage:
   {
     ThreadPool pool(n_workers);
     pool.StartWorkers();
     pool.Add(NewCallback(func_with_no_args));
     pool.Add(NewCallback(func_with_one_arg, arg));
     pool.Add(NewCallback(func_with_two_args, arg1, arg2));
     ... // more calls to pool.Add()

     // the ~ThreadPool() is called: we wait workers to finish
     // and then join all threads in the pool.
   }
 */
 class ThreadPool {
  public:
   //! Create n_threads threads, but do not start.
   explicit ThreadPool(int n_threads)
     : queue_(INT_MAX) {
     for (int i = 0; i < n_threads; i++) {
       MyThread *thread = new MyThread(&ThreadPool::Worker, this);
       workers_.push_back(thread);
     }
   }

   //! Start all threads.
   void StartWorkers() {
     for (size_t i = 0; i < workers_.size(); i++) {
       workers_[i]->Start();
     }
   }

   //! Add a closure.
   void Add(Closure *closure) {
     queue_.Put(closure);
   }

   int num_threads() { return workers_.size();}

   //! Wait workers to finish, then join all threads.
   ~ThreadPool() {
     for (size_t i = 0; i < workers_.size(); i++) {
       Add(NULL);
     }
     for (size_t i = 0; i < workers_.size(); i++) {
       workers_[i]->Join();
       delete workers_[i];
     }
   }
  private:
   std::vector<MyThread*>   workers_;
   ProducerConsumerQueue  queue_;

   static void *Worker(void *p) {
     ThreadPool *pool = reinterpret_cast<ThreadPool*>(p);
     while (true) {
       Closure *closure = reinterpret_cast<Closure*>(pool->queue_.Get());
       if(closure == NULL) {
         return NULL;
       }
       closure->Execute();
     }
   }
 };

 #ifndef NO_BARRIER
 /// Wrapper for pthread_barrier_t.
 class Barrier{
  public:
   explicit Barrier(int n_threads) {CHECK(0 == pthread_barrier_init(&b_, 0, n_threads));}
   ~Barrier()                      {CHECK(0 == pthread_barrier_destroy(&b_));}
   void Block() {
     // helgrind 3.3.0 does not have an interceptor for barrier.
     // but our current local version does.
     // ANNOTATE_CONDVAR_SIGNAL(this);
     pthread_barrier_wait(&b_);
     // ANNOTATE_CONDVAR_WAIT(this, this);
   }
  private:
   pthread_barrier_t b_;
 };

 #endif // NO_BARRIER

 class BlockingCounter {
  public:
   explicit BlockingCounter(int initial_count) :
     count_(initial_count) {}
   bool DecrementCount() {
     MutexLock lock(&mu_);
     count_--;
     return count_ == 0;
   }
   void Wait() {
     mu_.LockWhen(Condition(&IsZero, &count_));
     mu_.Unlock();
   }
  private:
   static bool IsZero(int *arg) { return *arg == 0; }
   Mutex mu_;
   int count_;
 };

 int AtomicIncrement(volatile int *value, int increment);

 #ifndef VGO_darwin
 inline int AtomicIncrement(volatile int *value, int increment) {
   return __sync_add_and_fetch(value, increment);
 }

 #else
 // Mac OS X version.
 inline int AtomicIncrement(volatile int *value, int increment) {
   return OSAtomicAdd32(increment, value);
 }

 // TODO(timurrrr) this is a hack
 #define memalign(A,B) malloc(B)

 // TODO(timurrrr) this is a hack
 int posix_memalign(void **out, size_t al, size_t size) {
   *out = memalign(al, size);
   return (*out == 0);
 }
 #endif // VGO_darwin

 #endif // THREAD_WRAPPERS_PTHREAD_H
 // vim:shiftwidth=2:softtabstop=2:expandtab:foldmethod=marker
	/*
	This file is part of Valgrind, a dynamic binary instrumentation
	framework.

	Copyright (C) 2008-2008 Google Inc
	opensource@google.com

	This program is free software; you can redistribute it and/or
	modify it under the terms of the GNU General Public License as
	published by the Free Software Foundation; either version 2 of the
	License, or (at your option) any later version.

	This program is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program; if not, write to the Free Software
	Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
	02111-1307, USA.

	The GNU General Public License is contained in the file COPYING.
	*/

	// Author: Konstantin Serebryany <opensource@google.com>
	//
	// Here we define few simple classes that wrap pthread primitives.
	//
	// We need this to create unit tests for helgrind (or similar tool)
	// that will work with different threading frameworks.
	//
	// If one needs to test helgrind's support for another threading library,
	// he/she can create a copy of this file and replace pthread_ calls
	// with appropriate calls to his/her library.
	//
	// Note, that some of the methods defined here are annotated with
	// ANNOTATE_* macros defined in dynamic_annotations.h.
	//
	// DISCLAIMER: the classes defined in this header file
	// are NOT intended for general use -- only for unit tests.
	//

	#ifndef THREAD_WRAPPERS_PTHREAD_H
	#define THREAD_WRAPPERS_PTHREAD_H

	#include <pthread.h>
	#include <semaphore.h>
	#include <unistd.h>
	#include <queue>
	#include <stdio.h>
	#include <limits.h> // INT_MAX

	#ifdef VGO_darwin
	#include <libkern/OSAtomic.h>
	#define NO_BARRIER
	#define NO_TLS
	#endif

	#include <string>
	using namespace std;

	#include <sys/time.h>
	#include <time.h>

	#include "../../drd/drd.h"
	#define ANNOTATE_NO_OP(arg) do { } while(0)
	#define ANNOTATE_EXPECT_RACE(addr, descr) \
	ANNOTATE_BENIGN_RACE_SIZED(addr, 4, "expected race")
	static inline bool RunningOnValgrind() { return RUNNING_ON_VALGRIND; }

	#include <assert.h>
	#ifdef NDEBUG
	# error "Pleeease, do not define NDEBUG"
	#endif
	#define CHECK assert

	/// Set this to true if malloc() uses mutex on your platform as this may
	/// introduce a happens-before arc for a pure happens-before race detector.
	const bool kMallocUsesMutex = false;

	/// Current time in milliseconds.
	static inline int64_t GetCurrentTimeMillis() {
	struct timeval now;
	gettimeofday(&now, NULL);
	return now.tv_sec * 1000 + now.tv_usec / 1000;
	}

	/// Copy tv to ts adding offset in milliseconds.
	static inline void timeval2timespec(timeval *const tv,
	timespec *ts,
	int64_t offset_milli) {
	const int64_t ten_9 = 1000000000LL;
	const int64_t ten_6 = 1000000LL;
	const int64_t ten_3 = 1000LL;
	int64_t now_nsec = (int64_t)tv->tv_sec * ten_9;
	now_nsec += (int64_t)tv->tv_usec * ten_3;
	int64_t then_nsec = now_nsec + offset_milli * ten_6;
	ts->tv_sec = then_nsec / ten_9;
	ts->tv_nsec = then_nsec % ten_9;
	}


	class CondVar;

	#ifndef NO_SPINLOCK
	/// helgrind does not (yet) support spin locks, so we annotate them.

	#ifndef VGO_darwin
	class SpinLock {
	public:
	SpinLock() {
	CHECK(0 == pthread_spin_init(&mu_, 0));
	ANNOTATE_RWLOCK_CREATE((void*)&mu_);
	}
	~SpinLock() {
	ANNOTATE_RWLOCK_DESTROY((void*)&mu_);
	CHECK(0 == pthread_spin_destroy(&mu_));
	}
	void Lock() {
	CHECK(0 == pthread_spin_lock(&mu_));
	ANNOTATE_RWLOCK_ACQUIRED((void*)&mu_, 1);
	}
	void Unlock() {
	ANNOTATE_RWLOCK_RELEASED((void*)&mu_, 1);
	CHECK(0 == pthread_spin_unlock(&mu_));
	}
	private:
	pthread_spinlock_t mu_;
	};

	#else

	class SpinLock {
	public:
	// Mac OS X version.
	SpinLock() : mu_(OS_SPINLOCK_INIT) {
	ANNOTATE_RWLOCK_CREATE((void*)&mu_);
	}
	~SpinLock() {
	ANNOTATE_RWLOCK_DESTROY((void*)&mu_);
	}
	void Lock() {
	OSSpinLockLock(&mu_);
	ANNOTATE_RWLOCK_ACQUIRED((void*)&mu_, 1);
	}
	void Unlock() {
	ANNOTATE_RWLOCK_RELEASED((void*)&mu_, 1);
	OSSpinLockUnlock(&mu_);
	}
	private:
	OSSpinLock mu_;
	};
	#endif // VGO_darwin

	#endif // NO_SPINLOCK

	/// Just a boolean condition. Used by Mutex::LockWhen and similar.
	class Condition {
	public:
	typedef bool (func_t)(void);

	template <typename T>
	Condition(bool (func)(T), T* arg)
	: func_(reinterpret_cast<func_t>(func)), arg_(arg) {}

	Condition(bool (*func)())
	: func_(reinterpret_cast<func_t>(func)), arg_(NULL) {}

	bool Eval() { return func_(arg_); }
	private:
	func_t func_;
	void *arg_;

	};


	/// Wrapper for pthread_mutex_t.
	///
	/// pthread_mutex_t is not a reader-writer lock,
	/// so the methods like ReaderLock() aren't really reader locks.
	/// We can not use pthread_rwlock_t because it
	/// does not work with pthread_cond_t.
	///
	/// TODO: We still need to test reader locks with this class.
	/// Implement a mode where pthread_rwlock_t will be used
	/// instead of pthread_mutex_t (only when not used with CondVar or LockWhen).
	///
	class Mutex {
	friend class CondVar;
	public:
	Mutex() {
	CHECK(0 == pthread_mutex_init(&mu_, NULL));
	CHECK(0 == pthread_cond_init(&cv_, NULL));
	signal_at_unlock_ = true; // Always signal at Unlock to make
	// Mutex more friendly to hybrid detectors.
	}
	~Mutex() {
	CHECK(0 == pthread_cond_destroy(&cv_));
	CHECK(0 == pthread_mutex_destroy(&mu_));
	}
	void Lock() { CHECK(0 == pthread_mutex_lock(&mu_));}
	bool TryLock() { return (0 == pthread_mutex_trylock(&mu_));}
	void Unlock() {
	if (signal_at_unlock_) {
	CHECK(0 == pthread_cond_signal(&cv_));
	}
	CHECK(0 == pthread_mutex_unlock(&mu_));
	}
	void ReaderLock() { Lock(); }
	bool ReaderTryLock() { return TryLock();}
	void ReaderUnlock() { Unlock(); }

	void LockWhen(Condition cond) { Lock(); WaitLoop(cond); }
	void ReaderLockWhen(Condition cond) { Lock(); WaitLoop(cond); }
	void Await(Condition cond) { WaitLoop(cond); }

	bool ReaderLockWhenWithTimeout(Condition cond, int millis)
	{ Lock(); return WaitLoopWithTimeout(cond, millis); }
	bool LockWhenWithTimeout(Condition cond, int millis)
	{ Lock(); return WaitLoopWithTimeout(cond, millis); }
	bool AwaitWithTimeout(Condition cond, int millis)
	{ return WaitLoopWithTimeout(cond, millis); }

	private:

	void WaitLoop(Condition cond) {
	signal_at_unlock_ = true;
	while(cond.Eval() == false) {
	pthread_cond_wait(&cv_, &mu_);
	}
	ANNOTATE_CONDVAR_LOCK_WAIT(&cv_, &mu_);
	}

	bool WaitLoopWithTimeout(Condition cond, int millis) {
	struct timeval now;
	struct timespec timeout;
	int retcode = 0;
	gettimeofday(&now, NULL);
	timeval2timespec(&now, &timeout, millis);

	signal_at_unlock_ = true;
	while (cond.Eval() == false && retcode == 0) {
	retcode = pthread_cond_timedwait(&cv_, &mu_, &timeout);
	}
	if(retcode == 0) {
	ANNOTATE_CONDVAR_LOCK_WAIT(&cv_, &mu_);
	}
	return cond.Eval();
	}

	// A hack. cv_ should be the first data member so that
	// ANNOTATE_CONDVAR_WAIT(&MU, &MU) and ANNOTATE_CONDVAR_SIGNAL(&MU) works.
	// (See also racecheck_unittest.cc)
	pthread_cond_t cv_;
	pthread_mutex_t mu_;
	bool signal_at_unlock_; // Set to true if Wait was called.
	};


	class MutexLock { // Scoped Mutex Locker/Unlocker
	public:
	MutexLock(Mutex *mu)
	: mu_(mu) {
	mu_->Lock();
	}
	~MutexLock() {
	mu_->Unlock();
	}
	private:
	Mutex *mu_;
	};


	/// Wrapper for pthread_cond_t.
	class CondVar {
	public:
	CondVar() { CHECK(0 == pthread_cond_init(&cv_, NULL)); }
	~CondVar() { CHECK(0 == pthread_cond_destroy(&cv_)); }
	void Wait(Mutex *mu) { CHECK(0 == pthread_cond_wait(&cv_, &mu->mu_)); }
	bool WaitWithTimeout(Mutex *mu, int millis) {
	struct timeval now;
	struct timespec timeout;
	gettimeofday(&now, NULL);
	timeval2timespec(&now, &timeout, millis);
	return 0 != pthread_cond_timedwait(&cv_, &mu->mu_, &timeout);
	}
	void Signal() { CHECK(0 == pthread_cond_signal(&cv_)); }
	void SignalAll() { CHECK(0 == pthread_cond_broadcast(&cv_)); }
	private:
	pthread_cond_t cv_;
	};


	// pthreads do not allow to use condvar with rwlock so we can't make
	// ReaderLock method of Mutex to be the real rw-lock.
	// So, we need a special lock class to test reader locks.
	#define NEEDS_SEPERATE_RW_LOCK
	class RWLock {
	public:
	RWLock() { CHECK(0 == pthread_rwlock_init(&mu_, NULL)); }
	~RWLock() { CHECK(0 == pthread_rwlock_destroy(&mu_)); }
	void Lock() { CHECK(0 == pthread_rwlock_wrlock(&mu_)); }
	void ReaderLock() { CHECK(0 == pthread_rwlock_rdlock(&mu_)); }
	void Unlock() { CHECK(0 == pthread_rwlock_unlock(&mu_)); }
	void ReaderUnlock() { CHECK(0 == pthread_rwlock_unlock(&mu_)); }
	private:
	pthread_cond_t dummy; // Damn, this requires some redesign...
	pthread_rwlock_t mu_;
	};

	class ReaderLockScoped { // Scoped RWLock Locker/Unlocker
	public:
	ReaderLockScoped(RWLock *mu)
	: mu_(mu) {
	mu_->ReaderLock();
	}
	~ReaderLockScoped() {
	mu_->ReaderUnlock();
	}
	private:
	RWLock *mu_;
	};

	class WriterLockScoped { // Scoped RWLock Locker/Unlocker
	public:
	WriterLockScoped(RWLock *mu)
	: mu_(mu) {
	mu_->Lock();
	}
	~WriterLockScoped() {
	mu_->Unlock();
	}
	private:
	RWLock *mu_;
	};




	/// Wrapper for pthread_create()/pthread_join().
	class MyThread {
	public:
	typedef void (worker_t)(void*);

	MyThread(worker_t worker, void arg = NULL, const char name = NULL)
	:w_(worker), arg_(arg), name_(name) {}
	MyThread(void (worker)(void), void arg = NULL, const char *name = NULL)
	:w_(reinterpret_cast<worker_t>(worker)), arg_(arg), name_(name) {}
	MyThread(void (worker)(void ), void arg = NULL, const char name = NULL)
	:w_(reinterpret_cast<worker_t>(worker)), arg_(arg), name_(name) {}

	~MyThread(){ w_ = NULL; arg_ = NULL;}
	void Start() { CHECK(0 == pthread_create(&t_, NULL, (worker_t)ThreadBody, this));}
	void Join() { CHECK(0 == pthread_join(t_, NULL));}
	pthread_t tid() const { return t_; }
	private:
	static void ThreadBody(MyThread *my_thread) {
	if (my_thread->name_) {
	ANNOTATE_THREAD_NAME(my_thread->name_);
	}
	my_thread->w_(my_thread->arg_);
	}
	pthread_t t_;
	worker_t w_;
	void *arg_;
	const char *name_;
	};


	/// Just a message queue.
	class ProducerConsumerQueue {
	public:
	ProducerConsumerQueue(int unused) {
	//ANNOTATE_PCQ_CREATE(this);
	}
	~ProducerConsumerQueue() {
	CHECK(q_.empty());
	//ANNOTATE_PCQ_DESTROY(this);
	}

	// Put.
	void Put(void *item) {
	mu_.Lock();
	q_.push(item);
	ANNOTATE_CONDVAR_SIGNAL(&mu_); // LockWhen in Get()
	//ANNOTATE_PCQ_PUT(this);
	mu_.Unlock();
	}

	// Get.
	// Blocks if the queue is empty.
	void *Get() {
	mu_.LockWhen(Condition(IsQueueNotEmpty, &q_));
	void * item = NULL;
	bool ok = TryGetInternal(&item);
	CHECK(ok);
	mu_.Unlock();
	return item;
	}

	// If queue is not empty,
	// remove an element from queue, put it into *res and return true.
	// Otherwise return false.
	bool TryGet(void **res) {
	mu_.Lock();
	bool ok = TryGetInternal(res);
	mu_.Unlock();
	return ok;
	}

	private:
	Mutex mu_;
	std::queue<void*> q_; // protected by mu_

	// Requires mu_
	bool TryGetInternal(void ** item_ptr) {
	if (q_.empty())
	return false;
	*item_ptr = q_.front();
	q_.pop();
	//ANNOTATE_PCQ_GET(this);
	return true;
	}

	static bool IsQueueNotEmpty(std::queue<void> queue) {
	return !queue->empty();
	}
	};



	/// Function pointer with zero, one or two parameters.
	struct Closure {
	typedef void (*F0)();
	typedef void (F1)(void arg1);
	typedef void (F2)(void arg1, void *arg2);
	int n_params;
	void *f;
	void *param1;
	void *param2;

	void Execute() {
	if (n_params == 0) {
	(F0(f))();
	} else if (n_params == 1) {
	(F1(f))(param1);
	} else {
	CHECK(n_params == 2);
	(F2(f))(param1, param2);
	}
	delete this;
	}
	};

	Closure NewCallback(void (f)()) {
	Closure *res = new Closure;
	res->n_params = 0;
	res->f = (void*)(f);
	res->param1 = NULL;
	res->param2 = NULL;
	return res;
	}

	template <class P1>
	Closure NewCallback(void (f)(P1), P1 p1) {
	CHECK(sizeof(P1) <= sizeof(void*));
	Closure *res = new Closure;
	res->n_params = 1;
	res->f = (void*)(f);
	res->param1 = (void*)p1;
	res->param2 = NULL;
	return res;
	}

	template <class T, class P1, class P2>
	Closure NewCallback(void (f)(P1, P2), P1 p1, P2 p2) {
	CHECK(sizeof(P1) <= sizeof(void*));
	Closure *res = new Closure;
	res->n_params = 2;
	res->f = (void*)(f);
	res->param1 = (void*)p1;
	res->param2 = (void*)p2;
	return res;
	}

	/*! A thread pool that uses ProducerConsumerQueue.
	Usage:
	{
	ThreadPool pool(n_workers);
	pool.StartWorkers();
	pool.Add(NewCallback(func_with_no_args));
	pool.Add(NewCallback(func_with_one_arg, arg));
	pool.Add(NewCallback(func_with_two_args, arg1, arg2));
	... // more calls to pool.Add()

	// the ~ThreadPool() is called: we wait workers to finish
	// and then join all threads in the pool.
	}
	*/
	class ThreadPool {
	public:
	//! Create n_threads threads, but do not start.
	explicit ThreadPool(int n_threads)
	: queue_(INT_MAX) {
	for (int i = 0; i < n_threads; i++) {
	MyThread *thread = new MyThread(&ThreadPool::Worker, this);
	workers_.push_back(thread);
	}
	}

	//! Start all threads.
	void StartWorkers() {
	for (size_t i = 0; i < workers_.size(); i++) {
	workers_[i]->Start();
	}
	}

	//! Add a closure.
	void Add(Closure *closure) {
	queue_.Put(closure);
	}

	int num_threads() { return workers_.size();}

	//! Wait workers to finish, then join all threads.
	~ThreadPool() {
	for (size_t i = 0; i < workers_.size(); i++) {
	Add(NULL);
	}
	for (size_t i = 0; i < workers_.size(); i++) {
	workers_[i]->Join();
	delete workers_[i];
	}
	}
	private:
	std::vector<MyThread*> workers_;
	ProducerConsumerQueue queue_;

	static void Worker(void p) {
	ThreadPool pool = reinterpret_cast<ThreadPool>(p);
	while (true) {
	Closure closure = reinterpret_cast<Closure>(pool->queue_.Get());
	if(closure == NULL) {
	return NULL;
	}
	closure->Execute();
	}
	}
	};

	#ifndef NO_BARRIER
	/// Wrapper for pthread_barrier_t.
	class Barrier{
	public:
	explicit Barrier(int n_threads) {CHECK(0 == pthread_barrier_init(&b_, 0, n_threads));}
	~Barrier() {CHECK(0 == pthread_barrier_destroy(&b_));}
	void Block() {
	// helgrind 3.3.0 does not have an interceptor for barrier.
	// but our current local version does.
	// ANNOTATE_CONDVAR_SIGNAL(this);
	pthread_barrier_wait(&b_);
	// ANNOTATE_CONDVAR_WAIT(this, this);
	}
	private:
	pthread_barrier_t b_;
	};

	#endif // NO_BARRIER

	class BlockingCounter {
	public:
	explicit BlockingCounter(int initial_count) :
	count_(initial_count) {}
	bool DecrementCount() {
	MutexLock lock(&mu_);
	count_--;
	return count_ == 0;
	}
	void Wait() {
	mu_.LockWhen(Condition(&IsZero, &count_));
	mu_.Unlock();
	}
	private:
	static bool IsZero(int arg) { return arg == 0; }
	Mutex mu_;
	int count_;
	};

	int AtomicIncrement(volatile int *value, int increment);

	#ifndef VGO_darwin
	inline int AtomicIncrement(volatile int *value, int increment) {
	return __sync_add_and_fetch(value, increment);
	}

	#else
	// Mac OS X version.
	inline int AtomicIncrement(volatile int *value, int increment) {
	return OSAtomicAdd32(increment, value);
	}

	// TODO(timurrrr) this is a hack
	#define memalign(A,B) malloc(B)

	// TODO(timurrrr) this is a hack
	int posix_memalign(void **out, size_t al, size_t size) {
	*out = memalign(al, size);
	return (*out == 0);
	}
	#endif // VGO_darwin

	#endif // THREAD_WRAPPERS_PTHREAD_H
	// vim:shiftwidth=2:softtabstop=2:expandtab:foldmethod=marker