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version 1.27.4.2, 2003/08/13 19:39:51

version 1.57.2.1, 2006/07/27 23:11:52

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//%/-*-c++-*-////////////////////////////////////////////////////////////////////////////

//%2006////////////////////////////////////////////////////////////////////////

// The Open Group, Tivoli Systems

// Company, L.P.; IBM Corp.; The Open Group; Tivoli Systems.

// IBM Corp.; EMC Corporation, The Open Group.

// IBM Corp.; EMC Corporation; VERITAS Software Corporation; The Open Group.

// EMC Corporation; VERITAS Software Corporation; The Open Group.

// EMC Corporation; Symantec Corporation; The Open Group.

// Permission is hereby granted, free of charge, to any person obtaining a copy

// of this software and associated documentation files (the "Software"), to

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// Author: Mike Day (mdday@us.ibm.com)

// Modified By: Markus Mueller

// Roger Kumpf, Hewlett-Packard Company (roger_kumpf@hp.com)

// Amit K Arora, IBM (amita@in.ibm.com) for PEP#101

// David Dillard, VERITAS Software Corp.

// (david.dillard@veritas.com)

// Sean Keenan, Hewlett-Packard Company (sean.keenan@hp.com)

// Josephine Eskaline Joyce, IBM (jojustin@in.ibm.com) for Bug#2393

//%/////////////////////////////////////////////////////////////////////////////

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#include <cstring>

#include <Pegasus/Common/Config.h>

#include <Pegasus/Common/IPC.h>

#include <Pegasus/Common/AtomicInt.h>

#include <Pegasus/Common/InternalException.h>

#include <Pegasus/Common/DQueue.h>

#include <Pegasus/Common/AcceptLanguageList.h>

#include <Pegasus/Common/AcceptLanguages.h> // l10n

#include <Pegasus/Common/Linkage.h>

#include <Pegasus/Common/AutoPtr.h>

#include <Pegasus/Common/List.h>

#include <Pegasus/Common/Mutex.h>

#include <Pegasus/Common/Semaphore.h>

#include <Pegasus/Common/TSDKey.h>

PEGASUS_NAMESPACE_BEGIN

class PEGASUS_COMMON_LINKAGE cleanup_handler

class PEGASUS_COMMON_LINKAGE cleanup_handler : public Linkable

{

public:

cleanup_handler( void (*routine)(void *), void *arg ) : _routine(routine), _arg(arg) {}

~cleanup_handler() {; }

inline Boolean operator==(const void *key) const

{

if(key == (void *)_routine)

return true;

return false;

}

inline Boolean operator ==(const cleanup_handler & b) const

{

return(operator==((const void *)b._routine));

}

private:

void execute(void) { _routine(_arg); }

void execute() { _routine(_arg); }

cleanup_handler();

void (*_routine)(void *);

void *_arg;

PEGASUS_CLEANUP_HANDLE _cleanup_buffer;

ThreadCleanupType _cleanup_buffer;

friend class DQueue<class cleanup_handler>;

friend class Thread;

};

///////////////////////////////////////////////////////////////////////////////

class PEGASUS_COMMON_LINKAGE thread_data

class PEGASUS_COMMON_LINKAGE thread_data : public Linkable

{

public:

static void default_delete(void *data);

thread_data( const Sint8 *key ) : _delete_func(NULL) , _data(NULL), _size(0)

thread_data( const char *key ) : _delete_func(NULL) , _data(NULL), _size(0)

{

PEGASUS_ASSERT(key != NULL);

size_t keysize = strlen(key);

_key = new Sint8 [keysize + 1];

_key.reset(new char[keysize + 1]);

memcpy(_key, key, keysize);

memcpy(_key.get(), key, keysize);

_key[keysize] = 0x00;

_key.get()[keysize] = 0x00;

}

thread_data(const Sint8 *key, size_t size) : _delete_func(default_delete), _size(size)

thread_data(const char *key, size_t size) : _delete_func(default_delete), _size(size)

{

PEGASUS_ASSERT(key != NULL);

size_t keysize = strlen(key);

_key = new Sint8 [keysize + 1];

_key.reset(new char[keysize + 1]);

memcpy(_key, key, keysize);

memcpy(_key.get(), key, keysize);

_key[keysize] = 0x00;

_key.get()[keysize] = 0x00;

_data = ::operator new(_size) ;

}

thread_data(const Sint8 *key, size_t size, void *data) : _delete_func(default_delete), _size(size)

thread_data(const char *key, size_t size, void *data) : _delete_func(default_delete), _size(size)

{

PEGASUS_ASSERT(key != NULL);

PEGASUS_ASSERT(data != NULL);

size_t keysize = strlen(key);

_key = new Sint8[keysize + 1];

_key.reset(new char[keysize + 1]);

memcpy(_key, key, keysize);

memcpy(_key.get(), key, keysize);

_key[keysize] = 0x00;

_key.get()[keysize] = 0x00;

_data = ::operator new(_size);

memcpy(_data, data, size);

}

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{

_delete_func( _data );

}

if( _key != NULL )

delete [] _key;

}

void put_data(void (*del)(void *), size_t size, void *data ) throw(NullPointer)

/**

* This function is used to put data in thread space.

* Be aware that there is NOTHING in place to stop

* other users of the thread to remove this data.

* Or change the data.

* You, the developer has to make sure that there are

* no situations in which this can arise (ie, have a

* lock for the function which manipulates the TSD.

* @exception NullPointer

void put_data(void (*del)(void *), size_t size, void *data )

{

if(_data != NULL)

if(_delete_func != NULL)

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return ;

}

size_t get_size(void) { return _size; }

size_t get_size() { return _size; }

/**

* This function is used to retrieve data from the

* TSD, the thread specific data.

* Be aware that there is NOTHING in place to stop

* other users of the thread to change the data you

* get from this function.

* You, the developer has to make sure that there are

* no situations in which this can arise (ie, have a

* lock for the function which manipulates the TSD.

void get_data(void **data, size_t *size)

{

if(data == NULL || size == NULL)

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}

void copy_data(void **buf, size_t *size) throw(NullPointer)

// @exception NullPointer

void copy_data(void **buf, size_t *size)

{

if((buf == NULL) || (size == NULL))

throw NullPointer() ;

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inline Boolean operator==(const void *key) const

{

if ( ! strcmp(_key, (Sint8 *)key))

if ( ! strcmp(_key.get(), reinterpret_cast<const char *>(key)))

return(true);

return(false);

}

inline Boolean operator==(const thread_data& b) const

{

return(operator==((const void *)b._key));

return(operator==(b._key.get()));

}

static bool equal(const thread_data* node, const void* key)

{

return ((thread_data*)node)->operator==(key);

}

private:

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thread_data();

void *_data;

size_t _size;

Sint8 *_key;

AutoArrayPtr<char> _key;

friend class DQueue<thread_data>;

friend class Thread;

};

///////////////////////////////////////////////////////////////////////////

enum ThreadStatus {

PEGASUS_THREAD_OK = 1, /* No problems */

PEGASUS_THREAD_INSUFFICIENT_RESOURCES, /* Can't allocate a thread. Not enough

memory. Try again later */

PEGASUS_THREAD_SETUP_FAILURE, /* Could not allocate into the thread specific

data storage. */

PEGASUS_THREAD_UNAVAILABLE /* Service is being destroyed and no new threads can

be provided. */

};

class PEGASUS_COMMON_LINKAGE ThreadPool;

///////////////////////////////////////////////////////////////////////////

class PEGASUS_COMMON_LINKAGE Thread

class PEGASUS_COMMON_LINKAGE Thread : public Linkable

{

public:

Thread( PEGASUS_THREAD_RETURN (PEGASUS_THREAD_CDECL *start )(void *),

Thread( ThreadReturnType (PEGASUS_THREAD_CDECL *start )(void *),

void *parameter, Boolean detached );

~Thread();

void run(void);

/**

Start the thread.

@return PEGASUS_THREAD_OK if the thread is started successfully,

PEGASUS_THREAD_INSUFFICIENT_RESOURCES if the resources necessary

to start the thread are not currently available.

PEGASUS_THREAD_SETUP_FAILURE if the thread could not

be create properly - check the 'errno' value for specific operating

system return code.

ThreadStatus run();

// get the user parameter

inline void *get_parm(void) { return _thread_parm; }

inline void *get_parm() { return _thread_parm; }

// send the thread a signal -- may not be appropriate due to Windows

// void kill(int signum);

// cancellation must be deferred (not asynchronous)

// for user-level threads the thread itself can decide

// when it should die.

void cancel(void);

void cancel();

// cancel if there is a pending cancellation request

void test_cancel(void);

void test_cancel();

Boolean is_cancelled(void);

Boolean is_cancelled();

// for user-level threads - put the calling thread

// to sleep and jump to the thread scheduler.

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// or gnu portable threads will have an existing

// routine that can be mapped to this method

void thread_switch(void);

void thread_switch();

#if defined(PEGASUS_PLATFORM_LINUX_GENERIC_GNU)

// suspend this thread

void suspend(void) ;

void suspend();

// resume this thread

void resume(void) ;

void resume();

#endif

static void sleep(Uint32 msec) ;

// block the calling thread until this thread terminates

void join( void );

void join();

void thread_init(void);

void thread_init();

// thread routine needs to call this function when

// it is ready to exit

void exit_self(PEGASUS_THREAD_RETURN return_code) ;

void exit_self(ThreadReturnType return_code);

// stack of functions to be called when thread terminates

// will be called last in first out (LIFO)

void cleanup_push( void (*routine) (void *), void *parm ) throw(IPCException);

// @exception IPCException

void cleanup_pop(Boolean execute = true) throw(IPCException);

void cleanup_push(void (*routine) (void *), void *parm);

// @exception IPCException

void cleanup_pop(Boolean execute = true);

// create and initialize a tsd

inline void create_tsd(const Sint8 *key, int size, void *buffer) throw(IPCException)

// @exception IPCException

inline void create_tsd(const char *key, int size, void *buffer)

{

thread_data *tsd = new thread_data(key, size, buffer);

AutoPtr<thread_data> tsd(new thread_data(key, size, buffer));

try { _tsd.insert_first(tsd); }

_tsd.insert_front(tsd.get());

catch(IPCException& e) { e = e; delete tsd; throw; }

tsd.release();

}

// get the buffer associated with the key

// NOTE: this call leaves the tsd LOCKED !!!!

inline void *reference_tsd(const Sint8 *key) throw(IPCException)

// @exception IPCException

inline void *reference_tsd(const char *key)

{

_tsd.lock();

thread_data *tsd = _tsd.reference((const void *)key);

thread_data *tsd = _tsd.find(thread_data::equal, key);

if(tsd != NULL)

return( (void *)(tsd->_data) );

else

return(NULL);

}

inline void *try_reference_tsd(const Sint8 *key) throw(IPCException)

// @exception IPCException

inline void *try_reference_tsd(const char *key)

{

_tsd.try_lock();

thread_data *tsd = _tsd.reference((const void *)key);

thread_data *tsd = _tsd.find(thread_data::equal, key);

if(tsd != NULL)

return((void *)(tsd->_data) );

else

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// release the lock held on the tsd

// NOTE: assumes a corresponding and prior call to reference_tsd() !!!

inline void dereference_tsd(void) throw(IPCException)

// @exception IPCException

inline void dereference_tsd()

{

_tsd.unlock();

}

// delete the tsd associated with the key

inline void delete_tsd(const Sint8 *key) throw(IPCException)

// @exception IPCException

inline void delete_tsd(const char *key)

{

thread_data *tsd = _tsd.remove((const void *)key);

AutoPtr<thread_data> tsd(_tsd.remove(thread_data::equal, key));

if(tsd != NULL)

delete tsd;

}

// Note: Caller must delete the thread_data object returned (if not null)

// @exception IPCException

inline void *remove_tsd(const Sint8 *key) throw(IPCException)

inline void empty_tsd()

{

return(_tsd.remove((const void *)key));

_tsd.clear();

}

inline void empty_tsd(void) throw(IPCException)

{

thread_data* tsd;

while (0 != (tsd = _tsd.remove_first()))

{

delete tsd;

}

//_tsd.empty_list();

}

// create or re-initialize tsd associated with the key

// if the tsd already exists, delete the existing buffer

void put_tsd(const Sint8 *key, void (*delete_func)(void *), Uint32 size, void *value)

// @exception IPCException

throw(IPCException)

void put_tsd(const char *key, void (*delete_func)(void *), Uint32 size, void *value)

{

PEGASUS_ASSERT(key != NULL);

thread_data *tsd ;

AutoPtr<thread_data> tsd;

tsd = _tsd.remove((const void *)key); // may throw an IPC exception

tsd.reset(_tsd.remove(thread_data::equal, key)); // may throw an IPC exception

delete tsd;

tsd.reset();

thread_data *ntsd = new thread_data(key);

AutoPtr<thread_data> ntsd(new thread_data(key));

ntsd->put_data(delete_func, size, value);

try { _tsd.insert_first(ntsd); }

try { _tsd.insert_front(ntsd.get()); }

catch(IPCException& e) { e = e; delete ntsd; throw; }

catch(IPCException& e) { e = e; throw; }

ntsd.release();

}

inline PEGASUS_THREAD_RETURN get_exit(void) { return _exit_code; }

inline ThreadReturnType get_exit() { return _exit_code; }

inline PEGASUS_THREAD_TYPE self(void) {return pegasus_thread_self(); }

inline ThreadType self() {return Threads::self(); }

PEGASUS_THREAD_HANDLE getThreadHandle() {return _handle;}

ThreadHandle getThreadHandle() {return _handle;}

inline Boolean operator==(const void *key) const

void detach();

{

if ( (void *)this == key)

return(true);

return(false);

}

inline Boolean operator==(const Thread & b) const

{

return(operator==((const void *)&b ));

}

void detach(void);

// Gets the Thread object associated with the caller's thread.

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static void setCurrent(Thread * thrd); // l10n

// Gets the AcceptLanguages object associated with the caller's

// Gets the AcceptLanguageList object associated with the caller's

// Thread.

// Note: this may return NULL if no Thread object, or no

// AcceptLanguages object, is associated with the caller's thread.

// AcceptLanguageList object, is associated with the caller's thread.

static AcceptLanguages * getLanguages(); //l10n

static AcceptLanguageList * getLanguages(); //l10n

// Sets the AcceptLanguages object associated with the caller's

// Sets the AcceptLanguageList object associated with the caller's

// Thread.

// Note: a Thread object must have been previously associated with

// the caller's thread.

// Note: the AcceptLanguages object must be placed on the heap.

// Note: the AcceptLanguageList object must be placed on the heap.

static void setLanguages(AcceptLanguages *langs); //l10n

static void setLanguages(AcceptLanguageList *langs); //l10n

// Removes the AcceptLanguages object associated with the caller's

// Removes the AcceptLanguageList object associated with the caller's

// Thread.

static void clearLanguages(); //l10n

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static Sint8 initializeKey(); // l10n

inline void create_tsd(const Sint8 *key ) throw(IPCException)

// @exception IPCException

inline void create_tsd(const char *key )

{

thread_data *tsd = new thread_data(key);

AutoPtr<thread_data> tsd(new thread_data(key));

try { _tsd.insert_first(tsd); }

_tsd.insert_front(tsd.get());

catch(IPCException& e) { e = e; delete tsd; throw; }

tsd.release();

}

PEGASUS_THREAD_HANDLE _handle;

ThreadHandle _handle;

Boolean _is_detached;

Boolean _cancel_enabled;

Boolean _cancelled;

PEGASUS_SEM_HANDLE _suspend_count;

// always pass this * as the void * parameter to the thread

// store the user parameter in _thread_parm

PEGASUS_THREAD_RETURN ( PEGASUS_THREAD_CDECL *_start)(void *) ;

ThreadReturnType ( PEGASUS_THREAD_CDECL *_start)(void *);

DQueue<class cleanup_handler> _cleanup;

List<cleanup_handler, Mutex> _cleanup;

DQueue<class thread_data> _tsd;

List<thread_data, Mutex> _tsd;

void *_thread_parm;

PEGASUS_THREAD_RETURN _exit_code;

ThreadReturnType _exit_code;

static Boolean _signals_blocked;

static PEGASUS_THREAD_KEY_TYPE _platform_thread_key; //l10n

static TSDKeyType _platform_thread_key; //l10n

static Boolean _key_initialized; // l10n

static Boolean _key_error; // l10n

friend class ThreadPool;

} ;

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{

public:

ThreadPool(Sint16 initial_size,

/**

const Sint8 *key,

Constructs a new ThreadPool object.

Sint16 min,

@param initialSize The number of threads that are initially added to

Sint16 max,

the thread pool.

struct timeval & alloc_wait,

@param key A name for this thread pool that can be used to determine

struct timeval & dealloc_wait,

equality of two thread pool objects. Only the first 16 characters

struct timeval & deadlock_detect);

of this value are used.

@param minThreads The minimum number of threads that should be

~ThreadPool(void);

contained in this thread pool at any given time.

@param maxThreads The maximum number of threads that should be

void allocate_and_awaken(void *parm,

contained in this thread pool at any given time.

PEGASUS_THREAD_RETURN (PEGASUS_THREAD_CDECL *work)(void *),

@param deallocateWait The minimum time that a thread should be idle

Semaphore *blocking = 0)

before it is removed from the pool and cleaned up.

throw(IPCException);

ThreadPool(

Sint16 initialSize,

Uint32 kill_dead_threads( void )

const char* key,

throw(IPCException);

Sint16 minThreads,

Sint16 maxThreads,

struct timeval& deallocateWait);

/**

Destructs the ThreadPool object.

~ThreadPool();

/**

Allocate and start a thread to do a unit of work.

@param parm A generic parameter to pass to the thread

@param work A pointer to the function that is to be executed by

the thread

@param blocking A pointer to an optional semaphore which, if

specified, is signaled after the thread finishes

executing the work function

@return PEGASUS_THREAD_OK if the thread is started successfully,

PEGASUS_THREAD_INSUFFICIENT_RESOURCES if the

resources necessary to start the thread are not currently

available. PEGASUS_THREAD_SETUP_FAILURE if the thread

could not be setup properly. PEGASUS_THREAD_UNAVAILABLE

if this service is shutting down and no more threads can

be allocated.

@exception IPCException

ThreadStatus allocate_and_awaken(

void* parm,

ThreadReturnType (PEGASUS_THREAD_CDECL* work)(void *),

Semaphore* blocking = 0);

/**

Cleans up idle threads if they have been running longer than the

deallocate_wait configuration and more than the configured

minimum number of threads is running.

@return The number of threads that were cleaned up.

@exception IPCException

Uint32 cleanupIdleThreads();

void get_key(Sint8 *buf, int bufsize);

inline Boolean operator==(const void *key) const

inline void setMinThreads(Sint16 min)

{

if ( ! strncmp( reinterpret_cast<Sint8 *>(const_cast<void *>(key)), _key, 16 ))

return(true);

return(false);

}

inline Boolean operator==(const ThreadPool & b) const

{

return(operator==((const void *) b._key ));

}

inline void set_min_threads(Sint16 min)

{

_min_threads = min;

}

inline Sint16 get_min_threads(void) const

{

return _min_threads;

}

inline void set_max_threads(Sint16 max)

{

_max_threads = max;

}

inline Sint16 get_max_threads(void) const

{

return _max_threads;

}

inline void set_allocate_wait(const struct timeval & alloc_wait)

{

_allocate_wait.tv_sec = alloc_wait.tv_sec;

_minThreads = min;

_allocate_wait.tv_usec = alloc_wait.tv_usec;

}

inline struct timeval *get_allocate_wait(struct timeval *buffer) const

inline Sint16 getMinThreads() const

{

if(buffer == 0)

return _minThreads;

throw NullPointer();

buffer->tv_sec = _allocate_wait.tv_sec;

buffer->tv_usec = _allocate_wait.tv_usec;

return buffer;

}

inline void set_deallocate_wait(const struct timeval & dealloc_wait)

inline void setMaxThreads(Sint16 max)

{

_deallocate_wait.tv_sec = dealloc_wait.tv_sec;

_maxThreads = max;

_deallocate_wait.tv_usec = dealloc_wait.tv_usec;

}

inline struct timeval *get_deallocate_wait(struct timeval *buffer) const

inline Sint16 getMaxThreads() const

{

if(buffer == 0)

return _maxThreads;

throw NullPointer();

buffer->tv_sec = _deallocate_wait.tv_sec;

buffer->tv_usec = _deallocate_wait.tv_usec;

return buffer;

}

inline void set_deadlock_detect(const struct timeval & deadlock)

inline Uint32 runningCount()

{

_deadlock_detect.tv_sec = deadlock.tv_sec;

return _runningThreads.size();

_deadlock_detect.tv_usec = deadlock.tv_usec;

}

inline struct timeval * get_deadlock_detect(struct timeval *buffer) const

inline Uint32 idleCount()

{

if(buffer == 0)

return _idleThreads.size();

throw NullPointer();

buffer->tv_sec = _deadlock_detect.tv_sec;

buffer->tv_usec = _deadlock_detect.tv_usec;

return buffer;

}

inline Uint32 running_count(void)

{

return _running.count();

}

inline Uint32 pool_count(void)

{

return _pool.count();

}

inline Uint32 dead_count(void)

{

return _dead.count();

}

static Boolean check_time(struct timeval *start, struct timeval *interval);

Boolean operator ==(const ThreadPool & p)

{

return operator==((const void *)&p);

}

Boolean operator ==(const void *p)

{

if((void *)this == p)

return true;

return false;

}

static void kill_idle_threads(void);

private:

ThreadPool(void);

Sint16 _max_threads;

Sint16 _min_threads;

AtomicInt _current_threads;

struct timeval _allocate_wait;

struct timeval _deallocate_wait;

struct timeval _deadlock_detect;

static PEGASUS_THREAD_RETURN PEGASUS_THREAD_CDECL _loop(void *);

Sint8 _key[17];

DQueue<Thread> _pool;

DQueue<Thread> _running;

DQueue<Thread> _dead;

AtomicInt _dying;

static void _sleep_sem_del(void *p);

void _check_deadlock(struct timeval *start) throw(Deadlock);

ThreadPool(); // Unimplemented

Boolean _check_deadlock_no_throw(struct timeval *start);

ThreadPool(const ThreadPool&); // Unimplemented

Boolean _check_dealloc(struct timeval *start);

ThreadPool& operator=(const ThreadPool&); // Unimplemented

Thread *_init_thread(void) throw(IPCException);

void _link_pool(Thread *th) throw(IPCException);

static ThreadReturnType PEGASUS_THREAD_CDECL _loop(void *);

static PEGASUS_THREAD_RETURN _undertaker(void *);

static DQueue<ThreadPool> _pools;

static Boolean _timeIntervalExpired(

struct timeval* start,

struct timeval* interval);

static void _deleteSemaphore(void* p);

void _cleanupThread(Thread* thread);

Thread* _initializeThread();

void _addToIdleThreadsQueue(Thread* th);

Sint16 _maxThreads;

Sint16 _minThreads;

AtomicInt _currentThreads;

struct timeval _deallocateWait;

char _key[17];

List<Thread, Mutex> _idleThreads;

List<Thread, Mutex> _runningThreads;

AtomicInt _dying;

};

#if defined(PEGASUS_OS_TYPE_WINDOWS)

# include "ThreadWindows_inline.h"

#elif defined(PEGASUS_PLATFORM_ZOS_ZSERIES_IBM)

# include "ThreadzOS_inline.h"

#elif defined(PEGASUS_OS_TYPE_UNIX)

# include "ThreadUnix_inline.h"

#elif defined(PEGASUS_OS_VMS)

# include "ThreadVms_inline.h"

#endif

PEGASUS_NAMESPACE_END

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