drd/drd_mutex.c - fp2-dev/platform/external/valgrind - Gitiles

 /*
   This file is part of drd, a thread error detector.

   Copyright (C) 2006-2011 Bart Van Assche <bvanassche@acm.org>.

   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.
 */


 #include "drd_basics.h"
 #include "drd_clientobj.h"
 #include "drd_error.h"
 #include "drd_mutex.h"
 #include "pub_tool_vki.h"
 #include "pub_tool_errormgr.h"    /* VG_(maybe_record_error)()     */
 #include "pub_tool_libcassert.h"  /* tl_assert()                   */
 #include "pub_tool_libcbase.h"    /* VG_(strlen)                   */
 #include "pub_tool_libcprint.h"   /* VG_(message)()                */
 #include "pub_tool_libcproc.h"    /* VG_(read_millisecond_timer)() */
 #include "pub_tool_machine.h"     /* VG_(get_IP)()                 */
 #include "pub_tool_threadstate.h" /* VG_(get_running_tid)()        */


 /* Local functions. */

 static void mutex_cleanup(struct mutex_info* p);
 static Bool mutex_is_locked(struct mutex_info* const p);
 static void mutex_delete_thread(struct mutex_info* p, const DrdThreadId tid);


 /* Local variables. */

 static Bool s_trace_mutex;
 static ULong s_mutex_lock_count;
 static ULong s_mutex_segment_creation_count;
 static UInt s_mutex_lock_threshold_ms;


 /* Function definitions. */

 void DRD_(mutex_set_trace)(const Bool trace_mutex)
 {
    tl_assert(!! trace_mutex == trace_mutex);
    s_trace_mutex = trace_mutex;
 }

 void DRD_(mutex_set_lock_threshold)(const UInt lock_threshold_ms)
 {
    s_mutex_lock_threshold_ms = lock_threshold_ms;
 }

 static
 void DRD_(mutex_initialize)(struct mutex_info* const p,
                             const Addr mutex, const MutexT mutex_type)
 {
    tl_assert(mutex);
    tl_assert(p->a1 == mutex);

    p->cleanup             = (void(*)(DrdClientobj*))mutex_cleanup;
    p->delete_thread
       = (void(*)(DrdClientobj*, DrdThreadId))mutex_delete_thread;
    p->mutex_type          = mutex_type;
    p->recursion_count     = 0;
    p->owner               = DRD_INVALID_THREADID;
    p->last_locked_segment = 0;
    p->acquiry_time_ms     = 0;
    p->acquired_at         = 0;
 }

 /** Deallocate the memory that was allocated by mutex_initialize(). */
 static void mutex_cleanup(struct mutex_info* p)
 {
    tl_assert(p);

    if (s_trace_mutex)
       DRD_(trace_msg)("[%d] mutex_destroy   %s 0x%lx rc %d owner %d",
                       DRD_(thread_get_running_tid)(),
                       DRD_(mutex_get_typename)(p), p->a1,
                       p ? p->recursion_count : -1,
                       p ? p->owner : DRD_INVALID_THREADID);

    if (mutex_is_locked(p))
    {
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(VG_(get_running_tid)(),
                               MutexErr,
                               VG_(get_IP)(VG_(get_running_tid)()),
                               "Destroying locked mutex",
                               &MEI);
    }

    DRD_(sg_put)(p->last_locked_segment);
    p->last_locked_segment = 0;
 }

 /** Report that address 'mutex' is not the address of a mutex object. */
 void DRD_(not_a_mutex)(const Addr mutex)
 {
    MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                         mutex, -1, DRD_INVALID_THREADID };
    VG_(maybe_record_error)(VG_(get_running_tid)(),
                            MutexErr,
                            VG_(get_IP)(VG_(get_running_tid)()),
                            "Not a mutex",
                            &MEI);
 }

 /**
  * Report that address 'mutex' is not the address of a mutex object of the
  * expected type.
  */
 static void wrong_mutex_type(const Addr mutex)
 {
    MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                         mutex, -1, DRD_INVALID_THREADID };
    VG_(maybe_record_error)(VG_(get_running_tid)(),
                            MutexErr,
                            VG_(get_IP)(VG_(get_running_tid)()),
                            "Mutex type mismatch",
                            &MEI);
 }

 static
 struct mutex_info*
 DRD_(mutex_get_or_allocate)(const Addr mutex, const MutexT mutex_type)
 {
    struct mutex_info* p;

    tl_assert(offsetof(DrdClientobj, mutex) == 0);
    p = &(DRD_(clientobj_get)(mutex, ClientMutex)->mutex);
    if (p)
    {
       if (mutex_type == mutex_type_unknown || p->mutex_type == mutex_type)
 	 return p;
       else
       {
 	 wrong_mutex_type(mutex);
 	 return 0;
       }
    }

    if (DRD_(clientobj_present)(mutex, mutex + 1))
    {
       DRD_(not_a_mutex)(mutex);
       return 0;
    }

    p = &(DRD_(clientobj_add)(mutex, ClientMutex)->mutex);
    DRD_(mutex_initialize)(p, mutex, mutex_type);
    return p;
 }

 struct mutex_info* DRD_(mutex_get)(const Addr mutex)
 {
    tl_assert(offsetof(DrdClientobj, mutex) == 0);
    return &(DRD_(clientobj_get)(mutex, ClientMutex)->mutex);
 }

 /** Called before pthread_mutex_init(). */
 struct mutex_info*
 DRD_(mutex_init)(const Addr mutex, const MutexT mutex_type)
 {
    struct mutex_info* p;

    if (s_trace_mutex)
       DRD_(trace_msg)("[%d] mutex_init      %s 0x%lx",
                       DRD_(thread_get_running_tid)(),
                       DRD_(mutex_type_name)(mutex_type),
                       mutex);

    if (mutex_type == mutex_type_invalid_mutex)
    {
       DRD_(not_a_mutex)(mutex);
       return 0;
    }

    p = DRD_(mutex_get)(mutex);
    if (p)
    {
       const ThreadId vg_tid = VG_(get_running_tid)();
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(vg_tid,
                               MutexErr,
                               VG_(get_IP)(vg_tid),
                               "Mutex reinitialization",
                               &MEI);
       p->mutex_type = mutex_type;
       return p;
    }
    p = DRD_(mutex_get_or_allocate)(mutex, mutex_type);

    return p;
 }

 /** Called after pthread_mutex_destroy(). */
 void DRD_(mutex_post_destroy)(const Addr mutex)
 {
    struct mutex_info* p;

    p = DRD_(mutex_get)(mutex);
    if (p == 0)
    {
       DRD_(not_a_mutex)(mutex);
       return;
    }

    DRD_(clientobj_remove)(mutex, ClientMutex);
 }

 /**
  * Called before pthread_mutex_lock() is invoked. If a data structure for the
  * client-side object was not yet created, do this now. Also check whether an
  * attempt is made to lock recursively a synchronization object that must not
  * be locked recursively.
  */
 void DRD_(mutex_pre_lock)(const Addr mutex, MutexT mutex_type,
                           const Bool trylock)
 {
    struct mutex_info* p;

    p = DRD_(mutex_get_or_allocate)(mutex, mutex_type);
    if (p && mutex_type == mutex_type_unknown)
       mutex_type = p->mutex_type;

    if (s_trace_mutex)
       DRD_(trace_msg)("[%d] %s %s 0x%lx rc %d owner %d",
                       DRD_(thread_get_running_tid)(),
                       trylock ? "pre_mutex_lock " : "mutex_trylock  ",
                       p ? DRD_(mutex_get_typename)(p) : "(?)",
                       mutex, p ? p->recursion_count : -1,
                       p ? p->owner : DRD_INVALID_THREADID);

    if (p == 0)
    {
       DRD_(not_a_mutex)(mutex);
       return;
    }

    tl_assert(p);

    if (mutex_type == mutex_type_invalid_mutex)
    {
       DRD_(not_a_mutex)(mutex);
       return;
    }

    if (! trylock
        && p->owner == DRD_(thread_get_running_tid)()
        && p->recursion_count >= 1
        && mutex_type != mutex_type_recursive_mutex)
    {
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(VG_(get_running_tid)(),
                               MutexErr,
                               VG_(get_IP)(VG_(get_running_tid)()),
                               "Recursive locking not allowed",
                               &MEI);
    }
 }

 /**
  * Update mutex_info state when locking the pthread_mutex_t mutex.
  * Note: this function must be called after pthread_mutex_lock() has been
  * called, or a race condition is triggered !
  */
 void DRD_(mutex_post_lock)(const Addr mutex, const Bool took_lock,
                            const Bool post_cond_wait)
 {
    const DrdThreadId drd_tid = DRD_(thread_get_running_tid)();
    struct mutex_info* p;

    p = DRD_(mutex_get)(mutex);

    if (s_trace_mutex)
       DRD_(trace_msg)("[%d] %s %s 0x%lx rc %d owner %d%s",
                       drd_tid,
                       post_cond_wait ? "cond_post_wait " : "post_mutex_lock",
                       p ? DRD_(mutex_get_typename)(p) : "(?)",
                       mutex, p ? p->recursion_count : 0,
                       p ? p->owner : VG_INVALID_THREADID,
                       took_lock ? "" : " (locking failed)");

    if (! p || ! took_lock)
       return;

    if (p->recursion_count == 0) {
       if (p->owner != drd_tid && p->owner != DRD_INVALID_THREADID)
       {
          tl_assert(p->last_locked_segment);

          DRD_(thread_new_segment_and_combine_vc)(drd_tid,
                                                  p->last_locked_segment);
       }
       else
          DRD_(thread_new_segment)(drd_tid);

       s_mutex_segment_creation_count++;

       p->owner           = drd_tid;
       p->acquiry_time_ms = VG_(read_millisecond_timer)();
       p->acquired_at     = VG_(record_ExeContext)(VG_(get_running_tid)(), 0);
       s_mutex_lock_count++;
    } else if (p->owner != drd_tid) {
       const ThreadId vg_tid = VG_(get_running_tid)();
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(vg_tid,
                               MutexErr,
                               VG_(get_IP)(vg_tid),
                               "The impossible happened: mutex is locked"
                               " simultaneously by two threads",
                               &MEI);
       p->owner = drd_tid;
    }
    p->recursion_count++;
 }

 /**
  * Update mutex_info state when unlocking the pthread_mutex_t mutex.
  *
  * @param[in] mutex      Address of the client mutex.
  * @param[in] mutex_type Mutex type.
  *
  * @return New value of the mutex recursion count.
  *
  * @note This function must be called before pthread_mutex_unlock() is called,
  *       or a race condition is triggered !
  */
 void DRD_(mutex_unlock)(const Addr mutex, MutexT mutex_type)
 {
    const DrdThreadId drd_tid = DRD_(thread_get_running_tid)();
    const ThreadId vg_tid = VG_(get_running_tid)();
    struct mutex_info* p;

    p = DRD_(mutex_get)(mutex);
    if (p && mutex_type == mutex_type_unknown)
       mutex_type = p->mutex_type;

    if (s_trace_mutex) {
       DRD_(trace_msg)("[%d] mutex_unlock    %s 0x%lx rc %d",
                       drd_tid, p ? DRD_(mutex_get_typename)(p) : "(?)",
                       mutex, p ? p->recursion_count : 0);
    }

    if (p == 0 || mutex_type == mutex_type_invalid_mutex)
    {
       DRD_(not_a_mutex)(mutex);
       return;
    }

    if (p->owner == DRD_INVALID_THREADID)
    {
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(vg_tid,
                               MutexErr,
                               VG_(get_IP)(vg_tid),
                               "Mutex not locked",
                               &MEI);
       return;
    }

    tl_assert(p);
    if (p->mutex_type != mutex_type) {
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(vg_tid, MutexErr, VG_(get_IP)(vg_tid),
                               "Mutex type changed", &MEI);
    }
    tl_assert(p->mutex_type == mutex_type);
    tl_assert(p->owner != DRD_INVALID_THREADID);

    if (p->owner != drd_tid || p->recursion_count <= 0)
    {
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(vg_tid,
                               MutexErr,
                               VG_(get_IP)(vg_tid),
                               "Mutex not locked by calling thread",
                               &MEI);
       return;
    }
    tl_assert(p->recursion_count > 0);
    p->recursion_count--;
    tl_assert(p->recursion_count >= 0);

    if (p->recursion_count == 0)
    {
       if (s_mutex_lock_threshold_ms > 0)
       {
          Long held = VG_(read_millisecond_timer)() - p->acquiry_time_ms;
          if (held > s_mutex_lock_threshold_ms)
          {
             HoldtimeErrInfo HEI
                = { DRD_(thread_get_running_tid)(),
                    mutex, p->acquired_at, held, s_mutex_lock_threshold_ms };
             VG_(maybe_record_error)(vg_tid,
                                     HoldtimeErr,
                                     VG_(get_IP)(vg_tid),
                                     "mutex",
                                     &HEI);
          }
       }

       /* This pthread_mutex_unlock() call really unlocks the mutex. Save the */
       /* current vector clock of the thread such that it is available when  */
       /* this mutex is locked again.                                        */

       DRD_(thread_get_latest_segment)(&p->last_locked_segment, drd_tid);
       DRD_(thread_new_segment)(drd_tid);
       p->acquired_at = 0;
       s_mutex_segment_creation_count++;
    }
 }

 void DRD_(spinlock_init_or_unlock)(const Addr spinlock)
 {
    struct mutex_info* mutex_p = DRD_(mutex_get)(spinlock);
    if (mutex_p)
    {
       DRD_(mutex_unlock)(spinlock, mutex_type_spinlock);
    }
    else
    {
       DRD_(mutex_init)(spinlock, mutex_type_spinlock);
    }
 }

 const char* DRD_(mutex_get_typename)(struct mutex_info* const p)
 {
    tl_assert(p);

    return DRD_(mutex_type_name)(p->mutex_type);
 }

 const char* DRD_(mutex_type_name)(const MutexT mt)
 {
    switch (mt)
    {
    case mutex_type_unknown:
       return "mutex";
    case mutex_type_invalid_mutex:
       return "invalid mutex";
    case mutex_type_recursive_mutex:
       return "recursive mutex";
    case mutex_type_errorcheck_mutex:
       return "error checking mutex";
    case mutex_type_default_mutex:
       return "mutex";
    case mutex_type_spinlock:
       return "spinlock";
    }
    tl_assert(0);
    return "?";
 }

 /** Return true if the specified mutex is locked by any thread. */
 static Bool mutex_is_locked(struct mutex_info* const p)
 {
    tl_assert(p);
    return (p->recursion_count > 0);
 }

 Bool DRD_(mutex_is_locked_by)(const Addr mutex, const DrdThreadId tid)
 {
    struct mutex_info* const p = DRD_(mutex_get)(mutex);
    if (p)
    {
       return (p->recursion_count > 0 && p->owner == tid);
    }
    return False;
 }

 int DRD_(mutex_get_recursion_count)(const Addr mutex)
 {
    struct mutex_info* const p = DRD_(mutex_get)(mutex);
    tl_assert(p);
    return p->recursion_count;
 }

 /**
  * Call this function when thread tid stops to exist, such that the
  * "last owner" field can be cleared if it still refers to that thread.
  */
 static void mutex_delete_thread(struct mutex_info* p, const DrdThreadId tid)
 {
    tl_assert(p);

    if (p->owner == tid && p->recursion_count > 0)
    {
       MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
                            p->a1, p->recursion_count, p->owner };
       VG_(maybe_record_error)(VG_(get_running_tid)(),
                               MutexErr,
                               VG_(get_IP)(VG_(get_running_tid)()),
                               "Mutex still locked at thread exit",
                               &MEI);
       p->owner = VG_INVALID_THREADID;
    }
 }

 ULong DRD_(get_mutex_lock_count)(void)
 {
    return s_mutex_lock_count;
 }

 ULong DRD_(get_mutex_segment_creation_count)(void)
 {
    return s_mutex_segment_creation_count;
 }
	/*
	This file is part of drd, a thread error detector.

	Copyright (C) 2006-2011 Bart Van Assche <bvanassche@acm.org>.

	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.
	*/


	#include "drd_basics.h"
	#include "drd_clientobj.h"
	#include "drd_error.h"
	#include "drd_mutex.h"
	#include "pub_tool_vki.h"
	#include "pub_tool_errormgr.h" /* VG_(maybe_record_error)() */
	#include "pub_tool_libcassert.h" /* tl_assert() */
	#include "pub_tool_libcbase.h" /* VG_(strlen) */
	#include "pub_tool_libcprint.h" /* VG_(message)() */
	#include "pub_tool_libcproc.h" /* VG_(read_millisecond_timer)() */
	#include "pub_tool_machine.h" /* VG_(get_IP)() */
	#include "pub_tool_threadstate.h" /* VG_(get_running_tid)() */


	/* Local functions. */

	static void mutex_cleanup(struct mutex_info* p);
	static Bool mutex_is_locked(struct mutex_info* const p);
	static void mutex_delete_thread(struct mutex_info* p, const DrdThreadId tid);


	/* Local variables. */

	static Bool s_trace_mutex;
	static ULong s_mutex_lock_count;
	static ULong s_mutex_segment_creation_count;
	static UInt s_mutex_lock_threshold_ms;


	/* Function definitions. */

	void DRD_(mutex_set_trace)(const Bool trace_mutex)
	{
	tl_assert(!! trace_mutex == trace_mutex);
	s_trace_mutex = trace_mutex;
	}

	void DRD_(mutex_set_lock_threshold)(const UInt lock_threshold_ms)
	{
	s_mutex_lock_threshold_ms = lock_threshold_ms;
	}

	static
	void DRD_(mutex_initialize)(struct mutex_info* const p,
	const Addr mutex, const MutexT mutex_type)
	{
	tl_assert(mutex);
	tl_assert(p->a1 == mutex);

	p->cleanup = (void()(DrdClientobj))mutex_cleanup;
	p->delete_thread
	= (void()(DrdClientobj, DrdThreadId))mutex_delete_thread;
	p->mutex_type = mutex_type;
	p->recursion_count = 0;
	p->owner = DRD_INVALID_THREADID;
	p->last_locked_segment = 0;
	p->acquiry_time_ms = 0;
	p->acquired_at = 0;
	}

	/** Deallocate the memory that was allocated by mutex_initialize(). */
	static void mutex_cleanup(struct mutex_info* p)
	{
	tl_assert(p);

	if (s_trace_mutex)
	DRD_(trace_msg)("[%d] mutex_destroy %s 0x%lx rc %d owner %d",
	DRD_(thread_get_running_tid)(),
	DRD_(mutex_get_typename)(p), p->a1,
	p ? p->recursion_count : -1,
	p ? p->owner : DRD_INVALID_THREADID);

	if (mutex_is_locked(p))
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(VG_(get_running_tid)(),
	MutexErr,
	VG_(get_IP)(VG_(get_running_tid)()),
	"Destroying locked mutex",
	&MEI);
	}

	DRD_(sg_put)(p->last_locked_segment);
	p->last_locked_segment = 0;
	}

	/** Report that address 'mutex' is not the address of a mutex object. */
	void DRD_(not_a_mutex)(const Addr mutex)
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	mutex, -1, DRD_INVALID_THREADID };
	VG_(maybe_record_error)(VG_(get_running_tid)(),
	MutexErr,
	VG_(get_IP)(VG_(get_running_tid)()),
	"Not a mutex",
	&MEI);
	}

	/**
	* Report that address 'mutex' is not the address of a mutex object of the
	* expected type.
	*/
	static void wrong_mutex_type(const Addr mutex)
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	mutex, -1, DRD_INVALID_THREADID };
	VG_(maybe_record_error)(VG_(get_running_tid)(),
	MutexErr,
	VG_(get_IP)(VG_(get_running_tid)()),
	"Mutex type mismatch",
	&MEI);
	}

	static
	struct mutex_info*
	DRD_(mutex_get_or_allocate)(const Addr mutex, const MutexT mutex_type)
	{
	struct mutex_info* p;

	tl_assert(offsetof(DrdClientobj, mutex) == 0);
	p = &(DRD_(clientobj_get)(mutex, ClientMutex)->mutex);
	if (p)
	{
	if (mutex_type == mutex_type_unknown \|\| p->mutex_type == mutex_type)
	return p;
	else
	{
	wrong_mutex_type(mutex);
	return 0;
	}
	}

	if (DRD_(clientobj_present)(mutex, mutex + 1))
	{
	DRD_(not_a_mutex)(mutex);
	return 0;
	}

	p = &(DRD_(clientobj_add)(mutex, ClientMutex)->mutex);
	DRD_(mutex_initialize)(p, mutex, mutex_type);
	return p;
	}

	struct mutex_info* DRD_(mutex_get)(const Addr mutex)
	{
	tl_assert(offsetof(DrdClientobj, mutex) == 0);
	return &(DRD_(clientobj_get)(mutex, ClientMutex)->mutex);
	}

	/** Called before pthread_mutex_init(). */
	struct mutex_info*
	DRD_(mutex_init)(const Addr mutex, const MutexT mutex_type)
	{
	struct mutex_info* p;

	if (s_trace_mutex)
	DRD_(trace_msg)("[%d] mutex_init %s 0x%lx",
	DRD_(thread_get_running_tid)(),
	DRD_(mutex_type_name)(mutex_type),
	mutex);

	if (mutex_type == mutex_type_invalid_mutex)
	{
	DRD_(not_a_mutex)(mutex);
	return 0;
	}

	p = DRD_(mutex_get)(mutex);
	if (p)
	{
	const ThreadId vg_tid = VG_(get_running_tid)();
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(vg_tid,
	MutexErr,
	VG_(get_IP)(vg_tid),
	"Mutex reinitialization",
	&MEI);
	p->mutex_type = mutex_type;
	return p;
	}
	p = DRD_(mutex_get_or_allocate)(mutex, mutex_type);

	return p;
	}

	/** Called after pthread_mutex_destroy(). */
	void DRD_(mutex_post_destroy)(const Addr mutex)
	{
	struct mutex_info* p;

	p = DRD_(mutex_get)(mutex);
	if (p == 0)
	{
	DRD_(not_a_mutex)(mutex);
	return;
	}

	DRD_(clientobj_remove)(mutex, ClientMutex);
	}

	/**
	* Called before pthread_mutex_lock() is invoked. If a data structure for the
	* client-side object was not yet created, do this now. Also check whether an
	* attempt is made to lock recursively a synchronization object that must not
	* be locked recursively.
	*/
	void DRD_(mutex_pre_lock)(const Addr mutex, MutexT mutex_type,
	const Bool trylock)
	{
	struct mutex_info* p;

	p = DRD_(mutex_get_or_allocate)(mutex, mutex_type);
	if (p && mutex_type == mutex_type_unknown)
	mutex_type = p->mutex_type;

	if (s_trace_mutex)
	DRD_(trace_msg)("[%d] %s %s 0x%lx rc %d owner %d",
	DRD_(thread_get_running_tid)(),
	trylock ? "pre_mutex_lock " : "mutex_trylock ",
	p ? DRD_(mutex_get_typename)(p) : "(?)",
	mutex, p ? p->recursion_count : -1,
	p ? p->owner : DRD_INVALID_THREADID);

	if (p == 0)
	{
	DRD_(not_a_mutex)(mutex);
	return;
	}

	tl_assert(p);

	if (mutex_type == mutex_type_invalid_mutex)
	{
	DRD_(not_a_mutex)(mutex);
	return;
	}

	if (! trylock
	&& p->owner == DRD_(thread_get_running_tid)()
	&& p->recursion_count >= 1
	&& mutex_type != mutex_type_recursive_mutex)
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(VG_(get_running_tid)(),
	MutexErr,
	VG_(get_IP)(VG_(get_running_tid)()),
	"Recursive locking not allowed",
	&MEI);
	}
	}

	/**
	* Update mutex_info state when locking the pthread_mutex_t mutex.
	* Note: this function must be called after pthread_mutex_lock() has been
	* called, or a race condition is triggered !
	*/
	void DRD_(mutex_post_lock)(const Addr mutex, const Bool took_lock,
	const Bool post_cond_wait)
	{
	const DrdThreadId drd_tid = DRD_(thread_get_running_tid)();
	struct mutex_info* p;

	p = DRD_(mutex_get)(mutex);

	if (s_trace_mutex)
	DRD_(trace_msg)("[%d] %s %s 0x%lx rc %d owner %d%s",
	drd_tid,
	post_cond_wait ? "cond_post_wait " : "post_mutex_lock",
	p ? DRD_(mutex_get_typename)(p) : "(?)",
	mutex, p ? p->recursion_count : 0,
	p ? p->owner : VG_INVALID_THREADID,
	took_lock ? "" : " (locking failed)");

	if (! p \|\| ! took_lock)
	return;

	if (p->recursion_count == 0) {
	if (p->owner != drd_tid && p->owner != DRD_INVALID_THREADID)
	{
	tl_assert(p->last_locked_segment);

	DRD_(thread_new_segment_and_combine_vc)(drd_tid,
	p->last_locked_segment);
	}
	else
	DRD_(thread_new_segment)(drd_tid);

	s_mutex_segment_creation_count++;

	p->owner = drd_tid;
	p->acquiry_time_ms = VG_(read_millisecond_timer)();
	p->acquired_at = VG_(record_ExeContext)(VG_(get_running_tid)(), 0);
	s_mutex_lock_count++;
	} else if (p->owner != drd_tid) {
	const ThreadId vg_tid = VG_(get_running_tid)();
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(vg_tid,
	MutexErr,
	VG_(get_IP)(vg_tid),
	"The impossible happened: mutex is locked"
	" simultaneously by two threads",
	&MEI);
	p->owner = drd_tid;
	}
	p->recursion_count++;
	}

	/**
	* Update mutex_info state when unlocking the pthread_mutex_t mutex.
	*
	* @param[in] mutex Address of the client mutex.
	* @param[in] mutex_type Mutex type.
	*
	* @return New value of the mutex recursion count.
	*
	* @note This function must be called before pthread_mutex_unlock() is called,
	* or a race condition is triggered !
	*/
	void DRD_(mutex_unlock)(const Addr mutex, MutexT mutex_type)
	{
	const DrdThreadId drd_tid = DRD_(thread_get_running_tid)();
	const ThreadId vg_tid = VG_(get_running_tid)();
	struct mutex_info* p;

	p = DRD_(mutex_get)(mutex);
	if (p && mutex_type == mutex_type_unknown)
	mutex_type = p->mutex_type;

	if (s_trace_mutex) {
	DRD_(trace_msg)("[%d] mutex_unlock %s 0x%lx rc %d",
	drd_tid, p ? DRD_(mutex_get_typename)(p) : "(?)",
	mutex, p ? p->recursion_count : 0);
	}

	if (p == 0 \|\| mutex_type == mutex_type_invalid_mutex)
	{
	DRD_(not_a_mutex)(mutex);
	return;
	}

	if (p->owner == DRD_INVALID_THREADID)
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(vg_tid,
	MutexErr,
	VG_(get_IP)(vg_tid),
	"Mutex not locked",
	&MEI);
	return;
	}

	tl_assert(p);
	if (p->mutex_type != mutex_type) {
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(vg_tid, MutexErr, VG_(get_IP)(vg_tid),
	"Mutex type changed", &MEI);
	}
	tl_assert(p->mutex_type == mutex_type);
	tl_assert(p->owner != DRD_INVALID_THREADID);

	if (p->owner != drd_tid \|\| p->recursion_count <= 0)
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(vg_tid,
	MutexErr,
	VG_(get_IP)(vg_tid),
	"Mutex not locked by calling thread",
	&MEI);
	return;
	}
	tl_assert(p->recursion_count > 0);
	p->recursion_count--;
	tl_assert(p->recursion_count >= 0);

	if (p->recursion_count == 0)
	{
	if (s_mutex_lock_threshold_ms > 0)
	{
	Long held = VG_(read_millisecond_timer)() - p->acquiry_time_ms;
	if (held > s_mutex_lock_threshold_ms)
	{
	HoldtimeErrInfo HEI
	= { DRD_(thread_get_running_tid)(),
	mutex, p->acquired_at, held, s_mutex_lock_threshold_ms };
	VG_(maybe_record_error)(vg_tid,
	HoldtimeErr,
	VG_(get_IP)(vg_tid),
	"mutex",
	&HEI);
	}
	}

	/* This pthread_mutex_unlock() call really unlocks the mutex. Save the */
	/* current vector clock of the thread such that it is available when */
	/* this mutex is locked again. */

	DRD_(thread_get_latest_segment)(&p->last_locked_segment, drd_tid);
	DRD_(thread_new_segment)(drd_tid);
	p->acquired_at = 0;
	s_mutex_segment_creation_count++;
	}
	}

	void DRD_(spinlock_init_or_unlock)(const Addr spinlock)
	{
	struct mutex_info* mutex_p = DRD_(mutex_get)(spinlock);
	if (mutex_p)
	{
	DRD_(mutex_unlock)(spinlock, mutex_type_spinlock);
	}
	else
	{
	DRD_(mutex_init)(spinlock, mutex_type_spinlock);
	}
	}

	const char* DRD_(mutex_get_typename)(struct mutex_info* const p)
	{
	tl_assert(p);

	return DRD_(mutex_type_name)(p->mutex_type);
	}

	const char* DRD_(mutex_type_name)(const MutexT mt)
	{
	switch (mt)
	{
	case mutex_type_unknown:
	return "mutex";
	case mutex_type_invalid_mutex:
	return "invalid mutex";
	case mutex_type_recursive_mutex:
	return "recursive mutex";
	case mutex_type_errorcheck_mutex:
	return "error checking mutex";
	case mutex_type_default_mutex:
	return "mutex";
	case mutex_type_spinlock:
	return "spinlock";
	}
	tl_assert(0);
	return "?";
	}

	/** Return true if the specified mutex is locked by any thread. */
	static Bool mutex_is_locked(struct mutex_info* const p)
	{
	tl_assert(p);
	return (p->recursion_count > 0);
	}

	Bool DRD_(mutex_is_locked_by)(const Addr mutex, const DrdThreadId tid)
	{
	struct mutex_info* const p = DRD_(mutex_get)(mutex);
	if (p)
	{
	return (p->recursion_count > 0 && p->owner == tid);
	}
	return False;
	}

	int DRD_(mutex_get_recursion_count)(const Addr mutex)
	{
	struct mutex_info* const p = DRD_(mutex_get)(mutex);
	tl_assert(p);
	return p->recursion_count;
	}

	/**
	* Call this function when thread tid stops to exist, such that the
	* "last owner" field can be cleared if it still refers to that thread.
	*/
	static void mutex_delete_thread(struct mutex_info* p, const DrdThreadId tid)
	{
	tl_assert(p);

	if (p->owner == tid && p->recursion_count > 0)
	{
	MutexErrInfo MEI = { DRD_(thread_get_running_tid)(),
	p->a1, p->recursion_count, p->owner };
	VG_(maybe_record_error)(VG_(get_running_tid)(),
	MutexErr,
	VG_(get_IP)(VG_(get_running_tid)()),
	"Mutex still locked at thread exit",
	&MEI);
	p->owner = VG_INVALID_THREADID;
	}
	}

	ULong DRD_(get_mutex_lock_count)(void)
	{
	return s_mutex_lock_count;
	}

	ULong DRD_(get_mutex_segment_creation_count)(void)
	{
	return s_mutex_segment_creation_count;
	}