drd/tests/annotate_smart_pointer.cpp - platform/external/valgrind - Gitiles

 /*
  * Test program that illustrates how to annotate a smart pointer
  * implementation.  In a multithreaded program the following is relevant when
  * working with smart pointers:
  * - whether or not the objects pointed at are shared over threads.
  * - whether or not the methods of the objects pointed at are thread-safe.
  * - whether or not the smart pointer objects are shared over threads.
  * - whether or not the smart pointer object itself is thread-safe.
  *
  * Most smart pointer implemenations are not thread-safe
  * (e.g. boost::shared_ptr<>, tr1::shared_ptr<> and the smart_ptr<>
  * implementation below). This means that it is not safe to modify a shared
  * pointer object that is shared over threads without proper synchronization.
  *
  * Even for non-thread-safe smart pointers it is possible to have different
  * threads access the same object via smart pointers without triggering data
  * races on the smart pointer objects.
  *
  * A smart pointer implementation guarantees that the destructor of the object
  * pointed at is invoked after the last smart pointer that points to that
  * object has been destroyed or reset. Data race detection tools cannot detect
  * this ordering without explicit annotation for smart pointers that track
  * references without invoking synchronization operations recognized by data
  * race detection tools.
  */


 #include <cassert>     // assert()
 #include <climits>     // PTHREAD_STACK_MIN
 #include <iostream>    // std::cerr
 #include <stdlib.h>    // atoi()
 #ifdef _WIN32
 #include <process.h>   // _beginthreadex()
 #include <windows.h>   // CRITICAL_SECTION
 #else
 #include <pthread.h>   // pthread_mutex_t
 #endif
 #include "unified_annotations.h"


 static bool s_enable_annotations = true;


 #ifdef _WIN32

 class AtomicInt32
 {
 public:
   AtomicInt32(const int value = 0) : m_value(value) { }
   ~AtomicInt32() { }
   LONG operator++() { return InterlockedIncrement(&m_value); }
   LONG operator--() { return InterlockedDecrement(&m_value); }

 private:
   volatile LONG m_value;
 };

 class Mutex
 {
 public:
   Mutex() : m_mutex()
   { InitializeCriticalSection(&m_mutex); }
   ~Mutex()
   { DeleteCriticalSection(&m_mutex); }
   void Lock()
   { EnterCriticalSection(&m_mutex); }
   void Unlock()
   { LeaveCriticalSection(&m_mutex); }

 private:
   CRITICAL_SECTION m_mutex;
 };

 class Thread
 {
 public:
   Thread() : m_thread(INVALID_HANDLE_VALUE) { }
   ~Thread() { }
   void Create(void* (*pf)(void*), void* arg)
   {
     WrapperArgs* wrapper_arg_p = new WrapperArgs(pf, arg);
     m_thread = reinterpret_cast<HANDLE>(_beginthreadex(NULL, 0, wrapper,
 						       wrapper_arg_p, 0, NULL));
   }
   void Join()
   { WaitForSingleObject(m_thread, INFINITE); }

 private:
   struct WrapperArgs
   {
     WrapperArgs(void* (*pf)(void*), void* arg) : m_pf(pf), m_arg(arg) { }

     void* (*m_pf)(void*);
     void* m_arg;
   };
   static unsigned int __stdcall wrapper(void* arg)
   {
     WrapperArgs* wrapper_arg_p = reinterpret_cast<WrapperArgs*>(arg);
     WrapperArgs wa = *wrapper_arg_p;
     delete wrapper_arg_p;
     return reinterpret_cast<unsigned>((wa.m_pf)(wa.m_arg));
   }
   HANDLE m_thread;
 };

 #else // _WIN32

 class AtomicInt32
 {
 public:
   AtomicInt32(const int value = 0) : m_value(value) { }
   ~AtomicInt32() { }
   int operator++() { return __sync_add_and_fetch(&m_value, 1); }
   int operator--() { return __sync_sub_and_fetch(&m_value, 1); }
 private:
   volatile int m_value;
 };

 class Mutex
 {
 public:
   Mutex() : m_mutex()
   { pthread_mutex_init(&m_mutex, NULL); }
   ~Mutex()
   { pthread_mutex_destroy(&m_mutex); }
   void Lock()
   { pthread_mutex_lock(&m_mutex); }
   void Unlock()
   { pthread_mutex_unlock(&m_mutex); }

 private:
   pthread_mutex_t m_mutex;
 };

 class Thread
 {
 public:
   Thread() : m_tid() { }
   ~Thread() { }
   void Create(void* (*pf)(void*), void* arg)
   {
     pthread_attr_t attr;
     pthread_attr_init(&attr);
     pthread_attr_setstacksize(&attr, PTHREAD_STACK_MIN + 4096);
     pthread_create(&m_tid, &attr, pf, arg);
     pthread_attr_destroy(&attr);
   }
   void Join()
   { pthread_join(m_tid, NULL); }
 private:
   pthread_t m_tid;
 };

 #endif // !defined(_WIN32)


 template<class T>
 class smart_ptr
 {
 public:
   typedef AtomicInt32 counter_t;

   template <typename Q> friend class smart_ptr;

   explicit smart_ptr()
     : m_ptr(NULL), m_count_ptr(NULL)
   { }

   explicit smart_ptr(T* const pT)
     : m_ptr(NULL), m_count_ptr(NULL)
   {
     set(pT, pT ? new counter_t(0) : NULL);
   }

   template <typename Q>
   explicit smart_ptr(Q* const q)
     : m_ptr(NULL), m_count_ptr(NULL)
   {
     set(q, q ? new counter_t(0) : NULL);
   }

   ~smart_ptr()
   {
     set(NULL, NULL);
   }

   smart_ptr(const smart_ptr<T>& sp)
     : m_ptr(NULL), m_count_ptr(NULL)
   {
     set(sp.m_ptr, sp.m_count_ptr);
   }

   template <typename Q>
   smart_ptr(const smart_ptr<Q>& sp)
     : m_ptr(NULL), m_count_ptr(NULL)
   {
     set(sp.m_ptr, sp.m_count_ptr);
   }

   smart_ptr& operator=(const smart_ptr<T>& sp)
   {
     set(sp.m_ptr, sp.m_count_ptr);
     return *this;
   }

   smart_ptr& operator=(T* const p)
   {
     set(p, p ? new counter_t(0) : NULL);
     return *this;
   }

   template <typename Q>
   smart_ptr& operator=(Q* const q)
   {
     set(q, q ? new counter_t(0) : NULL);
     return *this;
   }

   T* operator->() const
   {
     assert(m_ptr);
     return m_ptr;
   }

   T& operator*() const
   {
     assert(m_ptr);
     return *m_ptr;
   }

 private:
   void set(T* const pT, counter_t* const count_ptr)
   {
     if (m_ptr != pT)
     {
       if (m_count_ptr)
       {
 	if (s_enable_annotations)
 	  U_ANNOTATE_HAPPENS_BEFORE(m_count_ptr);
 	if (--(*m_count_ptr) == 0)
 	{
 	  if (s_enable_annotations)
 	    U_ANNOTATE_HAPPENS_AFTER(m_count_ptr);
 	  delete m_ptr;
 	  m_ptr = NULL;
 	  delete m_count_ptr;
 	  m_count_ptr = NULL;
 	}
       }
       m_ptr = pT;
       m_count_ptr = count_ptr;
       if (count_ptr)
 	++(*m_count_ptr);
     }
   }

   T*         m_ptr;
   counter_t* m_count_ptr;
 };

 class counter
 {
 public:
   counter()
     : m_mutex(), m_count()
   { }
   ~counter()
   {
     // Data race detection tools that do not recognize the
     // ANNOTATE_HAPPENS_BEFORE() / ANNOTATE_HAPPENS_AFTER() annotations in the
     // smart_ptr<> implementation will report that the assignment below
     // triggers a data race.
     m_count = -1;
   }
   int get() const
   {
     int result;
     m_mutex.Lock();
     result = m_count;
     m_mutex.Unlock();
     return result;
   }
   int post_increment()
   {
     int result;
     m_mutex.Lock();
     result = m_count++;
     m_mutex.Unlock();
     return result;
   }

 private:
   mutable Mutex m_mutex;
   int           m_count;
 };

 static void* thread_func(void* arg)
 {
   smart_ptr<counter>* pp = reinterpret_cast<smart_ptr<counter>*>(arg);
   (*pp)->post_increment();
   *pp = NULL;
   delete pp;
   return NULL;
 }

 int main(int argc, char** argv)
 {
   const int nthreads = std::max(argc > 1 ? atoi(argv[1]) : 1, 1);
   const int iterations = std::max(argc > 2 ? atoi(argv[2]) : 1, 1);
   s_enable_annotations = argc > 3 ? !!atoi(argv[3]) : true;

   for (int j = 0; j < iterations; ++j)
   {
     Thread T[nthreads];

     smart_ptr<counter> p(new counter);
     p->post_increment();
     for (int i = 0; i < nthreads; ++i)
       T[i].Create(thread_func, new smart_ptr<counter>(p));
     p = NULL;
     for (int i = 0; i < nthreads; ++i)
       T[i].Join();
   }
   std::cerr << "Done.\n";
   return 0;
 }

 // Local variables:
 // c-basic-offset: 2
 // End:
	/*
	* Test program that illustrates how to annotate a smart pointer
	* implementation. In a multithreaded program the following is relevant when
	* working with smart pointers:
	* - whether or not the objects pointed at are shared over threads.
	* - whether or not the methods of the objects pointed at are thread-safe.
	* - whether or not the smart pointer objects are shared over threads.
	* - whether or not the smart pointer object itself is thread-safe.
	*
	* Most smart pointer implemenations are not thread-safe
	* (e.g. boost::shared_ptr<>, tr1::shared_ptr<> and the smart_ptr<>
	* implementation below). This means that it is not safe to modify a shared
	* pointer object that is shared over threads without proper synchronization.
	*
	* Even for non-thread-safe smart pointers it is possible to have different
	* threads access the same object via smart pointers without triggering data
	* races on the smart pointer objects.
	*
	* A smart pointer implementation guarantees that the destructor of the object
	* pointed at is invoked after the last smart pointer that points to that
	* object has been destroyed or reset. Data race detection tools cannot detect
	* this ordering without explicit annotation for smart pointers that track
	* references without invoking synchronization operations recognized by data
	* race detection tools.
	*/


	#include <cassert> // assert()
	#include <climits> // PTHREAD_STACK_MIN
	#include <iostream> // std::cerr
	#include <stdlib.h> // atoi()
	#ifdef _WIN32
	#include <process.h> // _beginthreadex()
	#include <windows.h> // CRITICAL_SECTION
	#else
	#include <pthread.h> // pthread_mutex_t
	#endif
	#include "unified_annotations.h"


	static bool s_enable_annotations = true;


	#ifdef _WIN32

	class AtomicInt32
	{
	public:
	AtomicInt32(const int value = 0) : m_value(value) { }
	~AtomicInt32() { }
	LONG operator++() { return InterlockedIncrement(&m_value); }
	LONG operator--() { return InterlockedDecrement(&m_value); }

	private:
	volatile LONG m_value;
	};

	class Mutex
	{
	public:
	Mutex() : m_mutex()
	{ InitializeCriticalSection(&m_mutex); }
	~Mutex()
	{ DeleteCriticalSection(&m_mutex); }
	void Lock()
	{ EnterCriticalSection(&m_mutex); }
	void Unlock()
	{ LeaveCriticalSection(&m_mutex); }

	private:
	CRITICAL_SECTION m_mutex;
	};

	class Thread
	{
	public:
	Thread() : m_thread(INVALID_HANDLE_VALUE) { }
	~Thread() { }
	void Create(void* (pf)(void), void* arg)
	{
	WrapperArgs* wrapper_arg_p = new WrapperArgs(pf, arg);
	m_thread = reinterpret_cast<HANDLE>(_beginthreadex(NULL, 0, wrapper,
	wrapper_arg_p, 0, NULL));
	}
	void Join()
	{ WaitForSingleObject(m_thread, INFINITE); }

	private:
	struct WrapperArgs
	{
	WrapperArgs(void* (pf)(void), void* arg) : m_pf(pf), m_arg(arg) { }

	void* (m_pf)(void);
	void* m_arg;
	};
	static unsigned int __stdcall wrapper(void* arg)
	{
	WrapperArgs* wrapper_arg_p = reinterpret_cast<WrapperArgs*>(arg);
	WrapperArgs wa = *wrapper_arg_p;
	delete wrapper_arg_p;
	return reinterpret_cast<unsigned>((wa.m_pf)(wa.m_arg));
	}
	HANDLE m_thread;
	};

	#else // _WIN32

	class AtomicInt32
	{
	public:
	AtomicInt32(const int value = 0) : m_value(value) { }
	~AtomicInt32() { }
	int operator++() { return __sync_add_and_fetch(&m_value, 1); }
	int operator--() { return __sync_sub_and_fetch(&m_value, 1); }
	private:
	volatile int m_value;
	};

	class Mutex
	{
	public:
	Mutex() : m_mutex()
	{ pthread_mutex_init(&m_mutex, NULL); }
	~Mutex()
	{ pthread_mutex_destroy(&m_mutex); }
	void Lock()
	{ pthread_mutex_lock(&m_mutex); }
	void Unlock()
	{ pthread_mutex_unlock(&m_mutex); }

	private:
	pthread_mutex_t m_mutex;
	};

	class Thread
	{
	public:
	Thread() : m_tid() { }
	~Thread() { }
	void Create(void* (pf)(void), void* arg)
	{
	pthread_attr_t attr;
	pthread_attr_init(&attr);
	pthread_attr_setstacksize(&attr, PTHREAD_STACK_MIN + 4096);
	pthread_create(&m_tid, &attr, pf, arg);
	pthread_attr_destroy(&attr);
	}
	void Join()
	{ pthread_join(m_tid, NULL); }
	private:
	pthread_t m_tid;
	};

	#endif // !defined(_WIN32)


	template<class T>
	class smart_ptr
	{
	public:
	typedef AtomicInt32 counter_t;

	template <typename Q> friend class smart_ptr;

	explicit smart_ptr()
	: m_ptr(NULL), m_count_ptr(NULL)
	{ }

	explicit smart_ptr(T* const pT)
	: m_ptr(NULL), m_count_ptr(NULL)
	{
	set(pT, pT ? new counter_t(0) : NULL);
	}

	template <typename Q>
	explicit smart_ptr(Q* const q)
	: m_ptr(NULL), m_count_ptr(NULL)
	{
	set(q, q ? new counter_t(0) : NULL);
	}

	~smart_ptr()
	{
	set(NULL, NULL);
	}

	smart_ptr(const smart_ptr<T>& sp)
	: m_ptr(NULL), m_count_ptr(NULL)
	{
	set(sp.m_ptr, sp.m_count_ptr);
	}

	template <typename Q>
	smart_ptr(const smart_ptr<Q>& sp)
	: m_ptr(NULL), m_count_ptr(NULL)
	{
	set(sp.m_ptr, sp.m_count_ptr);
	}

	smart_ptr& operator=(const smart_ptr<T>& sp)
	{
	set(sp.m_ptr, sp.m_count_ptr);
	return *this;
	}

	smart_ptr& operator=(T* const p)
	{
	set(p, p ? new counter_t(0) : NULL);
	return *this;
	}

	template <typename Q>
	smart_ptr& operator=(Q* const q)
	{
	set(q, q ? new counter_t(0) : NULL);
	return *this;
	}

	T* operator->() const
	{
	assert(m_ptr);
	return m_ptr;
	}

	T& operator*() const
	{
	assert(m_ptr);
	return *m_ptr;
	}

	private:
	void set(T* const pT, counter_t* const count_ptr)
	{
	if (m_ptr != pT)
	{
	if (m_count_ptr)
	{
	if (s_enable_annotations)
	U_ANNOTATE_HAPPENS_BEFORE(m_count_ptr);
	if (--(*m_count_ptr) == 0)
	{
	if (s_enable_annotations)
	U_ANNOTATE_HAPPENS_AFTER(m_count_ptr);
	delete m_ptr;
	m_ptr = NULL;
	delete m_count_ptr;
	m_count_ptr = NULL;
	}
	}
	m_ptr = pT;
	m_count_ptr = count_ptr;
	if (count_ptr)
	++(*m_count_ptr);
	}
	}

	T* m_ptr;
	counter_t* m_count_ptr;
	};

	class counter
	{
	public:
	counter()
	: m_mutex(), m_count()
	{ }
	~counter()
	{
	// Data race detection tools that do not recognize the
	// ANNOTATE_HAPPENS_BEFORE() / ANNOTATE_HAPPENS_AFTER() annotations in the
	// smart_ptr<> implementation will report that the assignment below
	// triggers a data race.
	m_count = -1;
	}
	int get() const
	{
	int result;
	m_mutex.Lock();
	result = m_count;
	m_mutex.Unlock();
	return result;
	}
	int post_increment()
	{
	int result;
	m_mutex.Lock();
	result = m_count++;
	m_mutex.Unlock();
	return result;
	}

	private:
	mutable Mutex m_mutex;
	int m_count;
	};

	static void* thread_func(void* arg)
	{
	smart_ptr<counter>* pp = reinterpret_cast<smart_ptr<counter>*>(arg);
	(*pp)->post_increment();
	*pp = NULL;
	delete pp;
	return NULL;
	}

	int main(int argc, char** argv)
	{
	const int nthreads = std::max(argc > 1 ? atoi(argv[1]) : 1, 1);
	const int iterations = std::max(argc > 2 ? atoi(argv[2]) : 1, 1);
	s_enable_annotations = argc > 3 ? !!atoi(argv[3]) : true;

	for (int j = 0; j < iterations; ++j)
	{
	Thread T[nthreads];

	smart_ptr<counter> p(new counter);
	p->post_increment();
	for (int i = 0; i < nthreads; ++i)
	T[i].Create(thread_func, new smart_ptr<counter>(p));
	p = NULL;
	for (int i = 0; i < nthreads; ++i)
	T[i].Join();
	}
	std::cerr << "Done.\n";
	return 0;
	}

	// Local variables:
	// c-basic-offset: 2
	// End: