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|
/*
* tclUnixThrd.c --
*
* This file implements the UNIX-specific thread support.
*
* Copyright (c) 1991-1994 The Regents of the University of California.
* Copyright (c) 1994-1997 Sun Microsystems, Inc.
*
* See the file "license.terms" for information on usage and redistribution
* of this file, and for a DISCLAIMER OF ALL WARRANTIES.
*
* SCCS: @(#) tclUnixThrd.c 1.18 98/02/19 14:24:12
*/
#include "tclInt.h"
#ifdef TCL_THREADS
#include "pthread.h"
typedef struct ThreadSpecificData {
char nabuf[16];
struct {
Tcl_DirEntry ent;
char name[MAXNAMLEN+1];
} rdbuf;
} ThreadSpecificData;
static Tcl_ThreadDataKey dataKey;
/*
* masterLock is used to serialize creation of mutexes, condition
* variables, and thread local storage.
* This is the only place that can count on the ability to statically
* initialize the mutex.
*/
static pthread_mutex_t masterLock = PTHREAD_MUTEX_INITIALIZER;
/*
* initLock is used to serialize initialization and finalization
* of Tcl. It cannot use any dyamically allocated storage.
*/
static pthread_mutex_t initLock = PTHREAD_MUTEX_INITIALIZER;
/*
* allocLock is used by Tcl's version of malloc for synchronization.
* For obvious reasons, cannot use any dyamically allocated storage.
*/
static pthread_mutex_t allocLock = PTHREAD_MUTEX_INITIALIZER;
static pthread_mutex_t *allocLockPtr = &allocLock;
/*
* These are for the critical sections inside this file.
*/
#define MASTER_LOCK pthread_mutex_lock(&masterLock)
#define MASTER_UNLOCK pthread_mutex_unlock(&masterLock)
#endif /* TCL_THREADS */
/*
*----------------------------------------------------------------------
*
* TclpThreadCreaet --
*
* This procedure creates a new thread.
*
* Results:
* TCL_OK if the thread could be created. The thread ID is
* returned in a parameter.
*
* Side effects:
* A new thread is created.
*
*----------------------------------------------------------------------
*/
int
TclpThreadCreate(idPtr, proc, clientData, stackSize, flags)
Tcl_ThreadId *idPtr; /* Return, the ID of the thread */
Tcl_ThreadCreateProc proc; /* Main() function of the thread */
ClientData clientData; /* The one argument to Main() */
int stackSize; /* Size of stack for the new thread */
int flags; /* Flags controlling behaviour of
* the new thread */
{
#ifdef TCL_THREADS
pthread_attr_t attr;
pthread_t theThread;
int result;
pthread_attr_init(&attr);
pthread_attr_setscope(&attr, PTHREAD_SCOPE_SYSTEM);
#ifdef HAVE_PTHREAD_ATTR_SETSTACKSIZE
if (stackSize != TCL_THREAD_STACK_DEFAULT) {
pthread_attr_setstacksize(&attr, (size_t) stackSize);
#ifdef TCL_THREAD_STACK_MIN
} else {
/*
* Certain systems define a thread stack size that by default is
* too small for many operations. The user has the option of
* defining TCL_THREAD_STACK_MIN to a value large enough to work
* for their needs. This would look like (for 128K min stack):
* make MEM_DEBUG_FLAGS=-DTCL_THREAD_STACK_MIN=131072L
*
* This solution is not optimal, as we should allow the user to
* specify a size at runtime, but we don't want to slow this function
* down, and that would still leave the main thread at the default.
*/
size_t size;
result = pthread_attr_getstacksize(&attr, &size);
if (!result && (size < TCL_THREAD_STACK_MIN)) {
pthread_attr_setstacksize(&attr, (size_t) TCL_THREAD_STACK_MIN);
}
#endif
}
#endif
if (! (flags & TCL_THREAD_JOINABLE)) {
pthread_attr_setdetachstate (&attr, PTHREAD_CREATE_DETACHED);
}
if (pthread_create(&theThread, &attr,
(void * (*)(void *))proc, (void *)clientData) &&
pthread_create(&theThread, NULL,
(void * (*)(void *))proc, (void *)clientData)) {
result = TCL_ERROR;
} else {
*idPtr = (Tcl_ThreadId)theThread;
result = TCL_OK;
}
pthread_attr_destroy(&attr);
return result;
#else
return TCL_ERROR;
#endif /* TCL_THREADS */
}
/*
*----------------------------------------------------------------------
*
* Tcl_JoinThread --
*
* This procedure waits upon the exit of the specified thread.
*
* Results:
* TCL_OK if the wait was successful, TCL_ERROR else.
*
* Side effects:
* The result area is set to the exit code of the thread we
* waited upon.
*
*----------------------------------------------------------------------
*/
int
Tcl_JoinThread(threadId, state)
Tcl_ThreadId threadId; /* Id of the thread to wait upon */
int* state; /* Reference to the storage the result
* of the thread we wait upon will be
* written into. */
{
#ifdef TCL_THREADS
int result;
result = pthread_join ((pthread_t) threadId, (VOID**) state);
return (result == 0) ? TCL_OK : TCL_ERROR;
#else
return TCL_ERROR;
#endif
}
#ifdef TCL_THREADS
/*
*----------------------------------------------------------------------
*
* TclpThreadExit --
*
* This procedure terminates the current thread.
*
* Results:
* None.
*
* Side effects:
* This procedure terminates the current thread.
*
*----------------------------------------------------------------------
*/
void
TclpThreadExit(status)
int status;
{
pthread_exit((VOID *)status);
}
#endif /* TCL_THREADS */
#ifdef TCL_THREADS
/*
*----------------------------------------------------------------------
*
* TclpThreadGetStackSize --
*
* This procedure returns the size of the current thread's stack.
*
* Results:
* Stack size (in bytes?) or -1 for error or 0 for undeterminable.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
int
TclpThreadGetStackSize()
{
#if defined(HAVE_PTHREAD_SETSTACKSIZE) && defined(TclpPthreadGetAttrs)
pthread_attr_t threadAttr; /* This will hold the thread attributes for
* the current thread. */
size_t stackSize;
if (pthread_attr_init(&threadAttr) != 0) {
return -1;
}
if (TclpPthreadGetAttrs(pthread_self(), &threadAttr) != 0) {
pthread_attr_destroy(&threadAttr);
return -1;
}
if (pthread_attr_getstacksize(&threadAttr, &stackSize) != 0) {
pthread_attr_destroy(&threadAttr);
return -1;
}
pthread_attr_destroy(&threadAttr);
return (int) stackSize;
#else
/*
* Cannot determine the real stack size of this thread. The
* caller might want to try looking at the process accounting
* limits instead.
*/
return 0;
#endif
}
#endif /* TCL_THREADS */
/*
*----------------------------------------------------------------------
*
* Tcl_GetCurrentThread --
*
* This procedure returns the ID of the currently running thread.
*
* Results:
* A thread ID.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
Tcl_ThreadId
Tcl_GetCurrentThread()
{
#ifdef TCL_THREADS
return (Tcl_ThreadId) pthread_self();
#else
return (Tcl_ThreadId) 0;
#endif
}
/*
*----------------------------------------------------------------------
*
* TclpInitLock
*
* This procedure is used to grab a lock that serializes initialization
* and finalization of Tcl. On some platforms this may also initialize
* the mutex used to serialize creation of more mutexes and thread
* local storage keys.
*
* Results:
* None.
*
* Side effects:
* Acquire the initialization mutex.
*
*----------------------------------------------------------------------
*/
void
TclpInitLock()
{
#ifdef TCL_THREADS
pthread_mutex_lock(&initLock);
#endif
}
/*
*----------------------------------------------------------------------
*
* TclpFinalizeLock
*
* This procedure is used to destroy all private resources used in
* this file.
*
* Results:
* None.
*
* Side effects:
* Destroys everything private. TclpInitLock must be held
* entering this function.
*
*----------------------------------------------------------------------
*/
void
TclFinalizeLock ()
{
#ifdef TCL_THREADS
/*
* You do not need to destroy mutexes that were created with the
* PTHREAD_MUTEX_INITIALIZER macro. These mutexes do not need
* any destruction: masterLock, allocLock, and initLock.
*/
pthread_mutex_unlock(&initLock);
#endif
}
/*
*----------------------------------------------------------------------
*
* TclpInitUnlock
*
* This procedure is used to release a lock that serializes initialization
* and finalization of Tcl.
*
* Results:
* None.
*
* Side effects:
* Release the initialization mutex.
*
*----------------------------------------------------------------------
*/
void
TclpInitUnlock()
{
#ifdef TCL_THREADS
pthread_mutex_unlock(&initLock);
#endif
}
/*
*----------------------------------------------------------------------
*
* TclpMasterLock
*
* This procedure is used to grab a lock that serializes creation
* and finalization of serialization objects. This interface is
* only needed in finalization; it is hidden during
* creation of the objects.
*
* This lock must be different than the initLock because the
* initLock is held during creation of syncronization objects.
*
* Results:
* None.
*
* Side effects:
* Acquire the master mutex.
*
*----------------------------------------------------------------------
*/
void
TclpMasterLock()
{
#ifdef TCL_THREADS
pthread_mutex_lock(&masterLock);
#endif
}
/*
*----------------------------------------------------------------------
*
* TclpMasterUnlock
*
* This procedure is used to release a lock that serializes creation
* and finalization of synchronization objects.
*
* Results:
* None.
*
* Side effects:
* Release the master mutex.
*
*----------------------------------------------------------------------
*/
void
TclpMasterUnlock()
{
#ifdef TCL_THREADS
pthread_mutex_unlock(&masterLock);
#endif
}
/*
*----------------------------------------------------------------------
*
* Tcl_GetAllocMutex
*
* This procedure returns a pointer to a statically initialized
* mutex for use by the memory allocator. The alloctor must
* use this lock, because all other locks are allocated...
*
* Results:
* A pointer to a mutex that is suitable for passing to
* Tcl_MutexLock and Tcl_MutexUnlock.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
Tcl_Mutex *
Tcl_GetAllocMutex()
{
#ifdef TCL_THREADS
return (Tcl_Mutex *)&allocLockPtr;
#else
return NULL;
#endif
}
#ifdef TCL_THREADS
/*
*----------------------------------------------------------------------
*
* Tcl_MutexLock --
*
* This procedure is invoked to lock a mutex. This procedure
* handles initializing the mutex, if necessary. The caller
* can rely on the fact that Tcl_Mutex is an opaque pointer.
* This routine will change that pointer from NULL after first use.
*
* Results:
* None.
*
* Side effects:
* May block the current thread. The mutex is aquired when
* this returns. Will allocate memory for a pthread_mutex_t
* and initialize this the first time this Tcl_Mutex is used.
*
*----------------------------------------------------------------------
*/
void
Tcl_MutexLock(mutexPtr)
Tcl_Mutex *mutexPtr; /* Really (pthread_mutex_t **) */
{
pthread_mutex_t *pmutexPtr;
if (*mutexPtr == NULL) {
MASTER_LOCK;
if (*mutexPtr == NULL) {
/*
* Double inside master lock check to avoid a race condition.
*/
pmutexPtr = (pthread_mutex_t *)ckalloc(sizeof(pthread_mutex_t));
pthread_mutex_init(pmutexPtr, NULL);
*mutexPtr = (Tcl_Mutex)pmutexPtr;
TclRememberMutex(mutexPtr);
}
MASTER_UNLOCK;
}
pmutexPtr = *((pthread_mutex_t **)mutexPtr);
pthread_mutex_lock(pmutexPtr);
}
/*
*----------------------------------------------------------------------
*
* Tcl_MutexUnlock --
*
* This procedure is invoked to unlock a mutex. The mutex must
* have been locked by Tcl_MutexLock.
*
* Results:
* None.
*
* Side effects:
* The mutex is released when this returns.
*
*----------------------------------------------------------------------
*/
void
Tcl_MutexUnlock(mutexPtr)
Tcl_Mutex *mutexPtr; /* Really (pthread_mutex_t **) */
{
pthread_mutex_t *pmutexPtr = *(pthread_mutex_t **)mutexPtr;
pthread_mutex_unlock(pmutexPtr);
}
/*
*----------------------------------------------------------------------
*
* TclpFinalizeMutex --
*
* This procedure is invoked to clean up one mutex. This is only
* safe to call at the end of time.
*
* This assumes the Master Lock is held.
*
* Results:
* None.
*
* Side effects:
* The mutex list is deallocated.
*
*----------------------------------------------------------------------
*/
void
TclpFinalizeMutex(mutexPtr)
Tcl_Mutex *mutexPtr;
{
pthread_mutex_t *pmutexPtr = *(pthread_mutex_t **)mutexPtr;
if (pmutexPtr != NULL) {
pthread_mutex_destroy(pmutexPtr);
ckfree((char *)pmutexPtr);
*mutexPtr = NULL;
}
}
/*
*----------------------------------------------------------------------
*
* TclpThreadDataKeyInit --
*
* This procedure initializes a thread specific data block key.
* Each thread has table of pointers to thread specific data.
* all threads agree on which table entry is used by each module.
* this is remembered in a "data key", that is just an index into
* this table. To allow self initialization, the interface
* passes a pointer to this key and the first thread to use
* the key fills in the pointer to the key. The key should be
* a process-wide static.
*
* Results:
* None.
*
* Side effects:
* Will allocate memory the first time this process calls for
* this key. In this case it modifies its argument
* to hold the pointer to information about the key.
*
*----------------------------------------------------------------------
*/
void
TclpThreadDataKeyInit(keyPtr)
Tcl_ThreadDataKey *keyPtr; /* Identifier for the data chunk,
* really (pthread_key_t **) */
{
pthread_key_t *pkeyPtr;
MASTER_LOCK;
if (*keyPtr == NULL) {
pkeyPtr = (pthread_key_t *)ckalloc(sizeof(pthread_key_t));
pthread_key_create(pkeyPtr, NULL);
*keyPtr = (Tcl_ThreadDataKey)pkeyPtr;
TclRememberDataKey(keyPtr);
}
MASTER_UNLOCK;
}
/*
*----------------------------------------------------------------------
*
* TclpThreadDataKeyGet --
*
* This procedure returns a pointer to a block of thread local storage.
*
* Results:
* A thread-specific pointer to the data structure, or NULL
* if the memory has not been assigned to this key for this thread.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
VOID *
TclpThreadDataKeyGet(keyPtr)
Tcl_ThreadDataKey *keyPtr; /* Identifier for the data chunk,
* really (pthread_key_t **) */
{
pthread_key_t *pkeyPtr = *(pthread_key_t **)keyPtr;
if (pkeyPtr == NULL) {
return NULL;
} else {
return (VOID *)pthread_getspecific(*pkeyPtr);
}
}
/*
*----------------------------------------------------------------------
*
* TclpThreadDataKeySet --
*
* This procedure sets the pointer to a block of thread local storage.
*
* Results:
* None.
*
* Side effects:
* Sets up the thread so future calls to TclpThreadDataKeyGet with
* this key will return the data pointer.
*
*----------------------------------------------------------------------
*/
void
TclpThreadDataKeySet(keyPtr, data)
Tcl_ThreadDataKey *keyPtr; /* Identifier for the data chunk,
* really (pthread_key_t **) */
VOID *data; /* Thread local storage */
{
pthread_key_t *pkeyPtr = *(pthread_key_t **)keyPtr;
pthread_setspecific(*pkeyPtr, data);
}
/*
*----------------------------------------------------------------------
*
* TclpFinalizeThreadData --
*
* This procedure cleans up the thread-local storage. This is
* called once for each thread.
*
* Results:
* None.
*
* Side effects:
* Frees up all thread local storage.
*
*----------------------------------------------------------------------
*/
void
TclpFinalizeThreadData(keyPtr)
Tcl_ThreadDataKey *keyPtr;
{
VOID *result;
pthread_key_t *pkeyPtr;
if (*keyPtr != NULL) {
pkeyPtr = *(pthread_key_t **)keyPtr;
result = (VOID *)pthread_getspecific(*pkeyPtr);
if (result != NULL) {
ckfree((char *)result);
pthread_setspecific(*pkeyPtr, (void *)NULL);
}
}
}
/*
*----------------------------------------------------------------------
*
* TclpFinalizeThreadDataKey --
*
* This procedure is invoked to clean up one key. This is a
* process-wide storage identifier. The thread finalization code
* cleans up the thread local storage itself.
*
* This assumes the master lock is held.
*
* Results:
* None.
*
* Side effects:
* The key is deallocated.
*
*----------------------------------------------------------------------
*/
void
TclpFinalizeThreadDataKey(keyPtr)
Tcl_ThreadDataKey *keyPtr;
{
pthread_key_t *pkeyPtr;
if (*keyPtr != NULL) {
pkeyPtr = *(pthread_key_t **)keyPtr;
pthread_key_delete(*pkeyPtr);
ckfree((char *)pkeyPtr);
*keyPtr = NULL;
}
}
/*
*----------------------------------------------------------------------
*
* Tcl_ConditionWait --
*
* This procedure is invoked to wait on a condition variable.
* The mutex is automically released as part of the wait, and
* automatically grabbed when the condition is signaled.
*
* The mutex must be held when this procedure is called.
*
* Results:
* None.
*
* Side effects:
* May block the current thread. The mutex is aquired when
* this returns. Will allocate memory for a pthread_mutex_t
* and initialize this the first time this Tcl_Mutex is used.
*
*----------------------------------------------------------------------
*/
void
Tcl_ConditionWait(condPtr, mutexPtr, timePtr)
Tcl_Condition *condPtr; /* Really (pthread_cond_t **) */
Tcl_Mutex *mutexPtr; /* Really (pthread_mutex_t **) */
Tcl_Time *timePtr; /* Timeout on waiting period */
{
pthread_cond_t *pcondPtr;
pthread_mutex_t *pmutexPtr;
struct timespec ptime;
if (*condPtr == NULL) {
MASTER_LOCK;
/*
* Double check inside mutex to avoid race,
* then initialize condition variable if necessary.
*/
if (*condPtr == NULL) {
pcondPtr = (pthread_cond_t *)ckalloc(sizeof(pthread_cond_t));
pthread_cond_init(pcondPtr, NULL);
*condPtr = (Tcl_Condition)pcondPtr;
TclRememberCondition(condPtr);
}
MASTER_UNLOCK;
}
pmutexPtr = *((pthread_mutex_t **)mutexPtr);
pcondPtr = *((pthread_cond_t **)condPtr);
if (timePtr == NULL) {
pthread_cond_wait(pcondPtr, pmutexPtr);
} else {
Tcl_Time now;
/*
* Make sure to take into account the microsecond component of the
* current time, including possible overflow situations. [Bug #411603]
*/
Tcl_GetTime(&now);
ptime.tv_sec = timePtr->sec + now.sec +
(timePtr->usec + now.usec) / 1000000;
ptime.tv_nsec = 1000 * ((timePtr->usec + now.usec) % 1000000);
pthread_cond_timedwait(pcondPtr, pmutexPtr, &ptime);
}
}
/*
*----------------------------------------------------------------------
*
* Tcl_ConditionNotify --
*
* This procedure is invoked to signal a condition variable.
*
* The mutex must be held during this call to avoid races,
* but this interface does not enforce that.
*
* Results:
* None.
*
* Side effects:
* May unblock another thread.
*
*----------------------------------------------------------------------
*/
void
Tcl_ConditionNotify(condPtr)
Tcl_Condition *condPtr;
{
pthread_cond_t *pcondPtr = *((pthread_cond_t **)condPtr);
if (pcondPtr != NULL) {
pthread_cond_broadcast(pcondPtr);
} else {
/*
* Noone has used the condition variable, so there are no waiters.
*/
}
}
/*
*----------------------------------------------------------------------
*
* TclpFinalizeCondition --
*
* This procedure is invoked to clean up a condition variable.
* This is only safe to call at the end of time.
*
* This assumes the Master Lock is held.
*
* Results:
* None.
*
* Side effects:
* The condition variable is deallocated.
*
*----------------------------------------------------------------------
*/
void
TclpFinalizeCondition(condPtr)
Tcl_Condition *condPtr;
{
pthread_cond_t *pcondPtr = *(pthread_cond_t **)condPtr;
if (pcondPtr != NULL) {
pthread_cond_destroy(pcondPtr);
ckfree((char *)pcondPtr);
*condPtr = NULL;
}
}
#endif /* TCL_THREADS */
/*
*----------------------------------------------------------------------
*
* TclpReaddir, TclpLocaltime, TclpGmtime, TclpInetNtoa --
*
* These procedures replace core C versions to be used in a
* threaded environment.
*
* Results:
* See documentation of C functions.
*
* Side effects:
* See documentation of C functions.
*
*----------------------------------------------------------------------
*/
#if defined(TCL_THREADS) && !defined(HAVE_READDIR_R)
TCL_DECLARE_MUTEX( rdMutex )
#undef readdir
#endif
Tcl_DirEntry *
TclpReaddir(DIR * dir)
{
Tcl_DirEntry *ent;
#ifdef TCL_THREADS
ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey);
#ifdef HAVE_READDIR_R
ent = &tsdPtr->rdbuf.ent;
# ifdef HAVE_TWO_ARG_READDIR_R
if (TclOSreaddir_r(dir, ent) != 0) {
# else /* HAVE_THREE_ARG_READDIR_R */
if (TclOSreaddir_r(dir, ent, &ent) != 0) {
# endif /* HAVE_TWO_ARG_READDIR_R */
ent = NULL;
}
#else /* !HAVE_READDIR_R */
Tcl_MutexLock(&rdMutex);
# ifdef HAVE_STRUCT_DIRENT64
ent = readdir64(dir);
# else /* !HAVE_STRUCT_DIRENT64 */
ent = readdir(dir);
# endif /* HAVE_STRUCT_DIRENT64 */
if (ent != NULL) {
memcpy((VOID *) &tsdPtr->rdbuf.ent, (VOID *) ent,
sizeof(tsdPtr->rdbuf));
ent = &tsdPtr->rdbuf.ent;
}
Tcl_MutexUnlock(&rdMutex);
#endif /* HAVE_READDIR_R */
#else
# ifdef HAVE_STRUCT_DIRENT64
ent = readdir64(dir);
# else /* !HAVE_STRUCT_DIRENT64 */
ent = readdir(dir);
# endif /* HAVE_STRUCT_DIRENT64 */
#endif
return ent;
}
char *
TclpInetNtoa(struct in_addr addr)
{
#ifdef TCL_THREADS
ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey);
union {
unsigned long l;
unsigned char b[4];
} u;
u.l = (unsigned long) addr.s_addr;
sprintf(tsdPtr->nabuf, "%u.%u.%u.%u", u.b[0], u.b[1], u.b[2], u.b[3]);
return tsdPtr->nabuf;
#else
return inet_ntoa(addr);
#endif
}
#ifdef TCL_THREADS
/*
* Additions by AOL for specialized thread memory allocator.
*/
#ifdef USE_THREAD_ALLOC
static volatile int initialized = 0;
static pthread_key_t key;
typedef struct allocMutex {
Tcl_Mutex tlock;
pthread_mutex_t plock;
} allocMutex;
Tcl_Mutex *
TclpNewAllocMutex(void)
{
struct allocMutex *lockPtr;
lockPtr = malloc(sizeof(struct allocMutex));
if (lockPtr == NULL) {
Tcl_Panic("could not allocate lock");
}
lockPtr->tlock = (Tcl_Mutex) &lockPtr->plock;
pthread_mutex_init(&lockPtr->plock, NULL);
return &lockPtr->tlock;
}
void
TclpFreeAllocMutex(mutex)
Tcl_Mutex *mutex; /* The alloc mutex to free. */
{
allocMutex* lockPtr = (allocMutex*) mutex;
if (!lockPtr) return;
pthread_mutex_destroy(&lockPtr->plock);
free(lockPtr);
}
void TclpFreeAllocCache(ptr)
void *ptr;
{
extern void TclFreeAllocCache(void *);
TclFreeAllocCache(ptr);
/*
* Perform proper cleanup of things done in TclpGetAllocCache.
*/
if (initialized) {
pthread_key_delete(key);
initialized = 0;
}
}
void *
TclpGetAllocCache(void)
{
if (!initialized) {
pthread_mutex_lock(allocLockPtr);
if (!initialized) {
pthread_key_create(&key, TclpFreeAllocCache);
initialized = 1;
}
pthread_mutex_unlock(allocLockPtr);
}
return pthread_getspecific(key);
}
void
TclpSetAllocCache(void *arg)
{
pthread_setspecific(key, arg);
}
#endif /* USE_THREAD_ALLOC */
#endif /* TCL_THREADS */
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