Python/thread_nt.h - platform/external/python/cpython3 - Git at Google

 #include "pycore_interp.h"        // _PyInterpreterState.threads.stacksize
 #include "pycore_time.h"          // _PyTime_AsMicroseconds()

 /* This code implemented by Dag.Gruneau@elsa.preseco.comm.se */
 /* Fast NonRecursiveMutex support by Yakov Markovitch, markovitch@iso.ru */
 /* Eliminated some memory leaks, gsw@agere.com */

 #include <windows.h>
 #include <limits.h>
 #ifdef HAVE_PROCESS_H
 #include <process.h>
 #endif

 /* options */
 #ifndef _PY_USE_CV_LOCKS
 #define _PY_USE_CV_LOCKS 1     /* use locks based on cond vars */
 #endif

 /* Now, define a non-recursive mutex using either condition variables
  * and critical sections (fast) or using operating system mutexes
  * (slow)
  */

 #if _PY_USE_CV_LOCKS

 #include "condvar.h"

 typedef struct _NRMUTEX
 {
     PyMUTEX_T cs;
     PyCOND_T cv;
     int locked;
 } NRMUTEX;
 typedef NRMUTEX *PNRMUTEX;

 static PNRMUTEX
 AllocNonRecursiveMutex(void)
 {
     PNRMUTEX m = (PNRMUTEX)PyMem_RawMalloc(sizeof(NRMUTEX));
     if (!m)
         return NULL;
     if (PyCOND_INIT(&m->cv))
         goto fail;
     if (PyMUTEX_INIT(&m->cs)) {
         PyCOND_FINI(&m->cv);
         goto fail;
     }
     m->locked = 0;
     return m;
 fail:
     PyMem_RawFree(m);
     return NULL;
 }

 static VOID
 FreeNonRecursiveMutex(PNRMUTEX mutex)
 {
     if (mutex) {
         PyCOND_FINI(&mutex->cv);
         PyMUTEX_FINI(&mutex->cs);
         PyMem_RawFree(mutex);
     }
 }

 static DWORD
 EnterNonRecursiveMutex(PNRMUTEX mutex, DWORD milliseconds)
 {
     DWORD result = WAIT_OBJECT_0;
     if (PyMUTEX_LOCK(&mutex->cs))
         return WAIT_FAILED;
     if (milliseconds == INFINITE) {
         while (mutex->locked) {
             if (PyCOND_WAIT(&mutex->cv, &mutex->cs)) {
                 result = WAIT_FAILED;
                 break;
             }
         }
     } else if (milliseconds != 0) {
         /* wait at least until the deadline */
         PyTime_t nanoseconds = _PyTime_FromNanoseconds((PyTime_t)milliseconds * 1000000);
         PyTime_t deadline = _PyTime_Add(_PyTime_GetPerfCounter(), nanoseconds);
         while (mutex->locked) {
             PyTime_t microseconds = _PyTime_AsMicroseconds(nanoseconds,
                                                             _PyTime_ROUND_TIMEOUT);
             if (PyCOND_TIMEDWAIT(&mutex->cv, &mutex->cs, microseconds) < 0) {
                 result = WAIT_FAILED;
                 break;
             }
             nanoseconds = deadline - _PyTime_GetPerfCounter();
             if (nanoseconds <= 0) {
                 break;
             }
         }
     }
     if (!mutex->locked) {
         mutex->locked = 1;
         result = WAIT_OBJECT_0;
     } else if (result == WAIT_OBJECT_0)
         result = WAIT_TIMEOUT;
     /* else, it is WAIT_FAILED */
     PyMUTEX_UNLOCK(&mutex->cs); /* must ignore result here */
     return result;
 }

 static BOOL
 LeaveNonRecursiveMutex(PNRMUTEX mutex)
 {
     BOOL result;
     if (PyMUTEX_LOCK(&mutex->cs))
         return FALSE;
     mutex->locked = 0;
     /* condvar APIs return 0 on success. We need to return TRUE on success. */
     result = !PyCOND_SIGNAL(&mutex->cv);
     PyMUTEX_UNLOCK(&mutex->cs);
     return result;
 }

 #else /* if ! _PY_USE_CV_LOCKS */

 /* NR-locks based on a kernel mutex */
 #define PNRMUTEX HANDLE

 static PNRMUTEX
 AllocNonRecursiveMutex(void)
 {
     return CreateSemaphore(NULL, 1, 1, NULL);
 }

 static VOID
 FreeNonRecursiveMutex(PNRMUTEX mutex)
 {
     /* No in-use check */
     CloseHandle(mutex);
 }

 static DWORD
 EnterNonRecursiveMutex(PNRMUTEX mutex, DWORD milliseconds)
 {
     return WaitForSingleObjectEx(mutex, milliseconds, FALSE);
 }

 static BOOL
 LeaveNonRecursiveMutex(PNRMUTEX mutex)
 {
     return ReleaseSemaphore(mutex, 1, NULL);
 }
 #endif /* _PY_USE_CV_LOCKS */

 unsigned long PyThread_get_thread_ident(void);

 #ifdef PY_HAVE_THREAD_NATIVE_ID
 unsigned long PyThread_get_thread_native_id(void);
 #endif

 /*
  * Initialization for the current runtime.
  */
 static void
 PyThread__init_thread(void)
 {
     // Initialization of the C package should not be needed.
 }

 /*
  * Thread support.
  */

 typedef struct {
     void (*func)(void*);
     void *arg;
 } callobj;

 /* thunker to call adapt between the function type used by the system's
 thread start function and the internally used one. */
 static unsigned __stdcall
 bootstrap(void *call)
 {
     callobj *obj = (callobj*)call;
     void (*func)(void*) = obj->func;
     void *arg = obj->arg;
     HeapFree(GetProcessHeap(), 0, obj);
     func(arg);
     return 0;
 }

 int
 PyThread_start_joinable_thread(void (*func)(void *), void *arg,
                                PyThread_ident_t* ident, PyThread_handle_t* handle) {
     HANDLE hThread;
     unsigned threadID;
     callobj *obj;

     if (!initialized)
         PyThread_init_thread();

     obj = (callobj*)HeapAlloc(GetProcessHeap(), 0, sizeof(*obj));
     if (!obj)
         return -1;
     obj->func = func;
     obj->arg = arg;
     PyThreadState *tstate = _PyThreadState_GET();
     size_t stacksize = tstate ? tstate->interp->threads.stacksize : 0;
     hThread = (HANDLE)_beginthreadex(0,
                       Py_SAFE_DOWNCAST(stacksize, Py_ssize_t, unsigned int),
                       bootstrap, obj,
                       0, &threadID);
     if (hThread == 0) {
         /* I've seen errno == EAGAIN here, which means "there are
          * too many threads".
          */
         HeapFree(GetProcessHeap(), 0, obj);
         return -1;
     }
     *ident = threadID;
     // The cast is safe since HANDLE is pointer-sized
     *handle = (PyThread_handle_t) hThread;
     return 0;
 }

 unsigned long
 PyThread_start_new_thread(void (*func)(void *), void *arg) {
     PyThread_handle_t handle;
     PyThread_ident_t ident;
     if (PyThread_start_joinable_thread(func, arg, &ident, &handle)) {
         return PYTHREAD_INVALID_THREAD_ID;
     }
     CloseHandle((HANDLE) handle);
     // The cast is safe since the ident is really an unsigned int
     return (unsigned long) ident;
 }

 int
 PyThread_join_thread(PyThread_handle_t handle) {
     HANDLE hThread = (HANDLE) handle;
     int errored = (WaitForSingleObject(hThread, INFINITE) != WAIT_OBJECT_0);
     CloseHandle(hThread);
     return errored;
 }

 int
 PyThread_detach_thread(PyThread_handle_t handle) {
     HANDLE hThread = (HANDLE) handle;
     return (CloseHandle(hThread) == 0);
 }

 /*
  * Return the thread Id instead of a handle. The Id is said to uniquely identify the
  * thread in the system
  */
 PyThread_ident_t
 PyThread_get_thread_ident_ex(void)
 {
     if (!initialized)
         PyThread_init_thread();

     return GetCurrentThreadId();
 }

 unsigned long
 PyThread_get_thread_ident(void)
 {
     return (unsigned long) PyThread_get_thread_ident_ex();
 }


 #ifdef PY_HAVE_THREAD_NATIVE_ID
 /*
  * Return the native Thread ID (TID) of the calling thread.
  * The native ID of a thread is valid and guaranteed to be unique system-wide
  * from the time the thread is created until the thread has been terminated.
  */
 unsigned long
 PyThread_get_thread_native_id(void)
 {
     if (!initialized) {
         PyThread_init_thread();
     }

     DWORD native_id;
     native_id = GetCurrentThreadId();
     return (unsigned long) native_id;
 }
 #endif

 void _Py_NO_RETURN
 PyThread_exit_thread(void)
 {
     if (!initialized)
         exit(0);
     _endthreadex(0);
 }

 /*
  * Lock support. It has to be implemented as semaphores.
  * I [Dag] tried to implement it with mutex but I could find a way to
  * tell whether a thread already own the lock or not.
  */
 PyThread_type_lock
 PyThread_allocate_lock(void)
 {
     PNRMUTEX mutex;

     if (!initialized)
         PyThread_init_thread();

     mutex = AllocNonRecursiveMutex() ;

     PyThread_type_lock aLock = (PyThread_type_lock) mutex;
     assert(aLock);

     return aLock;
 }

 void
 PyThread_free_lock(PyThread_type_lock aLock)
 {
     FreeNonRecursiveMutex(aLock) ;
 }

 // WaitForSingleObject() accepts timeout in milliseconds in the range
 // [0; 0xFFFFFFFE] (DWORD type). INFINITE value (0xFFFFFFFF) means no
 // timeout. 0xFFFFFFFE milliseconds is around 49.7 days.
 const DWORD TIMEOUT_MS_MAX = 0xFFFFFFFE;

 /*
  * Return 1 on success if the lock was acquired
  *
  * and 0 if the lock was not acquired. This means a 0 is returned
  * if the lock has already been acquired by this thread!
  */
 PyLockStatus
 PyThread_acquire_lock_timed(PyThread_type_lock aLock,
                             PY_TIMEOUT_T microseconds, int intr_flag)
 {
     assert(aLock);

     /* Fow now, intr_flag does nothing on Windows, and lock acquires are
      * uninterruptible.  */
     PyLockStatus success;
     PY_TIMEOUT_T milliseconds;

     if (microseconds >= 0) {
         milliseconds = microseconds / 1000;
         // Round milliseconds away from zero
         if (microseconds % 1000 > 0) {
             milliseconds++;
         }
         if (milliseconds > (PY_TIMEOUT_T)TIMEOUT_MS_MAX) {
             // bpo-41710: PyThread_acquire_lock_timed() cannot report timeout
             // overflow to the caller, so clamp the timeout to
             // [0, TIMEOUT_MS_MAX] milliseconds.
             //
             // _thread.Lock.acquire() and _thread.RLock.acquire() raise an
             // OverflowError if microseconds is greater than PY_TIMEOUT_MAX.
             milliseconds = TIMEOUT_MS_MAX;
         }
         assert(milliseconds != INFINITE);
     }
     else {
         milliseconds = INFINITE;
     }

     if (EnterNonRecursiveMutex((PNRMUTEX)aLock,
                                (DWORD)milliseconds) == WAIT_OBJECT_0) {
         success = PY_LOCK_ACQUIRED;
     }
     else {
         success = PY_LOCK_FAILURE;
     }

     return success;
 }
 int
 PyThread_acquire_lock(PyThread_type_lock aLock, int waitflag)
 {
     return PyThread_acquire_lock_timed(aLock, waitflag ? -1 : 0, 0);
 }

 void
 PyThread_release_lock(PyThread_type_lock aLock)
 {
     assert(aLock);
     (void)LeaveNonRecursiveMutex((PNRMUTEX) aLock);
 }

 /* minimum/maximum thread stack sizes supported */
 #define THREAD_MIN_STACKSIZE    0x8000          /* 32 KiB */
 #define THREAD_MAX_STACKSIZE    0x10000000      /* 256 MiB */

 /* set the thread stack size.
  * Return 0 if size is valid, -1 otherwise.
  */
 static int
 _pythread_nt_set_stacksize(size_t size)
 {
     /* set to default */
     if (size == 0) {
         _PyInterpreterState_GET()->threads.stacksize = 0;
         return 0;
     }

     /* valid range? */
     if (size >= THREAD_MIN_STACKSIZE && size < THREAD_MAX_STACKSIZE) {
         _PyInterpreterState_GET()->threads.stacksize = size;
         return 0;
     }

     return -1;
 }

 #define THREAD_SET_STACKSIZE(x) _pythread_nt_set_stacksize(x)


 /* Thread Local Storage (TLS) API

    This API is DEPRECATED since Python 3.7.  See PEP 539 for details.
 */

 int
 PyThread_create_key(void)
 {
     DWORD result = TlsAlloc();
     if (result == TLS_OUT_OF_INDEXES)
         return -1;
     return (int)result;
 }

 void
 PyThread_delete_key(int key)
 {
     TlsFree(key);
 }

 int
 PyThread_set_key_value(int key, void *value)
 {
     BOOL ok = TlsSetValue(key, value);
     return ok ? 0 : -1;
 }

 void *
 PyThread_get_key_value(int key)
 {
     return TlsGetValue(key);
 }

 void
 PyThread_delete_key_value(int key)
 {
     /* NULL is used as "key missing", and it is also the default
      * given by TlsGetValue() if nothing has been set yet.
      */
     TlsSetValue(key, NULL);
 }


 /* reinitialization of TLS is not necessary after fork when using
  * the native TLS functions.  And forking isn't supported on Windows either.
  */
 void
 PyThread_ReInitTLS(void)
 {
 }


 /* Thread Specific Storage (TSS) API

    Platform-specific components of TSS API implementation.
 */

 int
 PyThread_tss_create(Py_tss_t *key)
 {
     assert(key != NULL);
     /* If the key has been created, function is silently skipped. */
     if (key->_is_initialized) {
         return 0;
     }

     DWORD result = TlsAlloc();
     if (result == TLS_OUT_OF_INDEXES) {
         return -1;
     }
     /* In Windows, platform-specific key type is DWORD. */
     key->_key = result;
     key->_is_initialized = 1;
     return 0;
 }

 void
 PyThread_tss_delete(Py_tss_t *key)
 {
     assert(key != NULL);
     /* If the key has not been created, function is silently skipped. */
     if (!key->_is_initialized) {
         return;
     }

     TlsFree(key->_key);
     key->_key = TLS_OUT_OF_INDEXES;
     key->_is_initialized = 0;
 }

 int
 PyThread_tss_set(Py_tss_t *key, void *value)
 {
     assert(key != NULL);
     BOOL ok = TlsSetValue(key->_key, value);
     return ok ? 0 : -1;
 }

 void *
 PyThread_tss_get(Py_tss_t *key)
 {
     assert(key != NULL);
     return TlsGetValue(key->_key);
 }
	#include "pycore_interp.h" // _PyInterpreterState.threads.stacksize
	#include "pycore_time.h" // _PyTime_AsMicroseconds()

	/* This code implemented by Dag.Gruneau@elsa.preseco.comm.se */
	/* Fast NonRecursiveMutex support by Yakov Markovitch, markovitch@iso.ru */
	/* Eliminated some memory leaks, gsw@agere.com */

	#include <windows.h>
	#include <limits.h>
	#ifdef HAVE_PROCESS_H
	#include <process.h>
	#endif

	/* options */
	#ifndef _PY_USE_CV_LOCKS
	#define _PY_USE_CV_LOCKS 1 /* use locks based on cond vars */
	#endif

	/* Now, define a non-recursive mutex using either condition variables
	* and critical sections (fast) or using operating system mutexes
	* (slow)
	*/

	#if _PY_USE_CV_LOCKS

	#include "condvar.h"

	typedef struct _NRMUTEX
	{
	PyMUTEX_T cs;
	PyCOND_T cv;
	int locked;
	} NRMUTEX;
	typedef NRMUTEX *PNRMUTEX;

	static PNRMUTEX
	AllocNonRecursiveMutex(void)
	{
	PNRMUTEX m = (PNRMUTEX)PyMem_RawMalloc(sizeof(NRMUTEX));
	if (!m)
	return NULL;
	if (PyCOND_INIT(&m->cv))
	goto fail;
	if (PyMUTEX_INIT(&m->cs)) {
	PyCOND_FINI(&m->cv);
	goto fail;
	}
	m->locked = 0;
	return m;
	fail:
	PyMem_RawFree(m);
	return NULL;
	}

	static VOID
	FreeNonRecursiveMutex(PNRMUTEX mutex)
	{
	if (mutex) {
	PyCOND_FINI(&mutex->cv);
	PyMUTEX_FINI(&mutex->cs);
	PyMem_RawFree(mutex);
	}
	}

	static DWORD
	EnterNonRecursiveMutex(PNRMUTEX mutex, DWORD milliseconds)
	{
	DWORD result = WAIT_OBJECT_0;
	if (PyMUTEX_LOCK(&mutex->cs))
	return WAIT_FAILED;
	if (milliseconds == INFINITE) {
	while (mutex->locked) {
	if (PyCOND_WAIT(&mutex->cv, &mutex->cs)) {
	result = WAIT_FAILED;
	break;
	}
	}
	} else if (milliseconds != 0) {
	/* wait at least until the deadline */
	PyTime_t nanoseconds = _PyTime_FromNanoseconds((PyTime_t)milliseconds * 1000000);
	PyTime_t deadline = _PyTime_Add(_PyTime_GetPerfCounter(), nanoseconds);
	while (mutex->locked) {
	PyTime_t microseconds = _PyTime_AsMicroseconds(nanoseconds,
	_PyTime_ROUND_TIMEOUT);
	if (PyCOND_TIMEDWAIT(&mutex->cv, &mutex->cs, microseconds) < 0) {
	result = WAIT_FAILED;
	break;
	}
	nanoseconds = deadline - _PyTime_GetPerfCounter();
	if (nanoseconds <= 0) {
	break;
	}
	}
	}
	if (!mutex->locked) {
	mutex->locked = 1;
	result = WAIT_OBJECT_0;
	} else if (result == WAIT_OBJECT_0)
	result = WAIT_TIMEOUT;
	/* else, it is WAIT_FAILED */
	PyMUTEX_UNLOCK(&mutex->cs); /* must ignore result here */
	return result;
	}

	static BOOL
	LeaveNonRecursiveMutex(PNRMUTEX mutex)
	{
	BOOL result;
	if (PyMUTEX_LOCK(&mutex->cs))
	return FALSE;
	mutex->locked = 0;
	/* condvar APIs return 0 on success. We need to return TRUE on success. */
	result = !PyCOND_SIGNAL(&mutex->cv);
	PyMUTEX_UNLOCK(&mutex->cs);
	return result;
	}

	#else /* if ! _PY_USE_CV_LOCKS */

	/* NR-locks based on a kernel mutex */
	#define PNRMUTEX HANDLE

	static PNRMUTEX
	AllocNonRecursiveMutex(void)
	{
	return CreateSemaphore(NULL, 1, 1, NULL);
	}

	static VOID
	FreeNonRecursiveMutex(PNRMUTEX mutex)
	{
	/* No in-use check */
	CloseHandle(mutex);
	}

	static DWORD
	EnterNonRecursiveMutex(PNRMUTEX mutex, DWORD milliseconds)
	{
	return WaitForSingleObjectEx(mutex, milliseconds, FALSE);
	}

	static BOOL
	LeaveNonRecursiveMutex(PNRMUTEX mutex)
	{
	return ReleaseSemaphore(mutex, 1, NULL);
	}
	#endif /* _PY_USE_CV_LOCKS */

	unsigned long PyThread_get_thread_ident(void);

	#ifdef PY_HAVE_THREAD_NATIVE_ID
	unsigned long PyThread_get_thread_native_id(void);
	#endif

	/*
	* Initialization for the current runtime.
	*/
	static void
	PyThread__init_thread(void)
	{
	// Initialization of the C package should not be needed.
	}

	/*
	* Thread support.
	*/

	typedef struct {
	void (func)(void);
	void *arg;
	} callobj;

	/* thunker to call adapt between the function type used by the system's
	thread start function and the internally used one. */
	static unsigned __stdcall
	bootstrap(void *call)
	{
	callobj obj = (callobj)call;
	void (func)(void) = obj->func;
	void *arg = obj->arg;
	HeapFree(GetProcessHeap(), 0, obj);
	func(arg);
	return 0;
	}

	int
	PyThread_start_joinable_thread(void (func)(void ), void *arg,
	PyThread_ident_t* ident, PyThread_handle_t* handle) {
	HANDLE hThread;
	unsigned threadID;
	callobj *obj;

	if (!initialized)
	PyThread_init_thread();

	obj = (callobj)HeapAlloc(GetProcessHeap(), 0, sizeof(obj));
	if (!obj)
	return -1;
	obj->func = func;
	obj->arg = arg;
	PyThreadState *tstate = _PyThreadState_GET();
	size_t stacksize = tstate ? tstate->interp->threads.stacksize : 0;
	hThread = (HANDLE)_beginthreadex(0,
	Py_SAFE_DOWNCAST(stacksize, Py_ssize_t, unsigned int),
	bootstrap, obj,
	0, &threadID);
	if (hThread == 0) {
	/* I've seen errno == EAGAIN here, which means "there are
	* too many threads".
	*/
	HeapFree(GetProcessHeap(), 0, obj);
	return -1;
	}
	*ident = threadID;
	// The cast is safe since HANDLE is pointer-sized
	*handle = (PyThread_handle_t) hThread;
	return 0;
	}

	unsigned long
	PyThread_start_new_thread(void (func)(void ), void *arg) {
	PyThread_handle_t handle;
	PyThread_ident_t ident;
	if (PyThread_start_joinable_thread(func, arg, &ident, &handle)) {
	return PYTHREAD_INVALID_THREAD_ID;
	}
	CloseHandle((HANDLE) handle);
	// The cast is safe since the ident is really an unsigned int
	return (unsigned long) ident;
	}

	int
	PyThread_join_thread(PyThread_handle_t handle) {
	HANDLE hThread = (HANDLE) handle;
	int errored = (WaitForSingleObject(hThread, INFINITE) != WAIT_OBJECT_0);
	CloseHandle(hThread);
	return errored;
	}

	int
	PyThread_detach_thread(PyThread_handle_t handle) {
	HANDLE hThread = (HANDLE) handle;
	return (CloseHandle(hThread) == 0);
	}

	/*
	* Return the thread Id instead of a handle. The Id is said to uniquely identify the
	* thread in the system
	*/
	PyThread_ident_t
	PyThread_get_thread_ident_ex(void)
	{
	if (!initialized)
	PyThread_init_thread();

	return GetCurrentThreadId();
	}

	unsigned long
	PyThread_get_thread_ident(void)
	{
	return (unsigned long) PyThread_get_thread_ident_ex();
	}


	#ifdef PY_HAVE_THREAD_NATIVE_ID
	/*
	* Return the native Thread ID (TID) of the calling thread.
	* The native ID of a thread is valid and guaranteed to be unique system-wide
	* from the time the thread is created until the thread has been terminated.
	*/
	unsigned long
	PyThread_get_thread_native_id(void)
	{
	if (!initialized) {
	PyThread_init_thread();
	}

	DWORD native_id;
	native_id = GetCurrentThreadId();
	return (unsigned long) native_id;
	}
	#endif

	void _Py_NO_RETURN
	PyThread_exit_thread(void)
	{
	if (!initialized)
	exit(0);
	_endthreadex(0);
	}

	/*
	* Lock support. It has to be implemented as semaphores.
	* I [Dag] tried to implement it with mutex but I could find a way to
	* tell whether a thread already own the lock or not.
	*/
	PyThread_type_lock
	PyThread_allocate_lock(void)
	{
	PNRMUTEX mutex;

	if (!initialized)
	PyThread_init_thread();

	mutex = AllocNonRecursiveMutex() ;

	PyThread_type_lock aLock = (PyThread_type_lock) mutex;
	assert(aLock);

	return aLock;
	}

	void
	PyThread_free_lock(PyThread_type_lock aLock)
	{
	FreeNonRecursiveMutex(aLock) ;
	}

	// WaitForSingleObject() accepts timeout in milliseconds in the range
	// [0; 0xFFFFFFFE] (DWORD type). INFINITE value (0xFFFFFFFF) means no
	// timeout. 0xFFFFFFFE milliseconds is around 49.7 days.
	const DWORD TIMEOUT_MS_MAX = 0xFFFFFFFE;

	/*
	* Return 1 on success if the lock was acquired
	*
	* and 0 if the lock was not acquired. This means a 0 is returned
	* if the lock has already been acquired by this thread!
	*/
	PyLockStatus
	PyThread_acquire_lock_timed(PyThread_type_lock aLock,
	PY_TIMEOUT_T microseconds, int intr_flag)
	{
	assert(aLock);

	/* Fow now, intr_flag does nothing on Windows, and lock acquires are
	* uninterruptible. */
	PyLockStatus success;
	PY_TIMEOUT_T milliseconds;

	if (microseconds >= 0) {
	milliseconds = microseconds / 1000;
	// Round milliseconds away from zero
	if (microseconds % 1000 > 0) {
	milliseconds++;
	}
	if (milliseconds > (PY_TIMEOUT_T)TIMEOUT_MS_MAX) {
	// bpo-41710: PyThread_acquire_lock_timed() cannot report timeout
	// overflow to the caller, so clamp the timeout to
	// [0, TIMEOUT_MS_MAX] milliseconds.
	//
	// _thread.Lock.acquire() and _thread.RLock.acquire() raise an
	// OverflowError if microseconds is greater than PY_TIMEOUT_MAX.
	milliseconds = TIMEOUT_MS_MAX;
	}
	assert(milliseconds != INFINITE);
	}
	else {
	milliseconds = INFINITE;
	}

	if (EnterNonRecursiveMutex((PNRMUTEX)aLock,
	(DWORD)milliseconds) == WAIT_OBJECT_0) {
	success = PY_LOCK_ACQUIRED;
	}
	else {
	success = PY_LOCK_FAILURE;
	}

	return success;
	}
	int
	PyThread_acquire_lock(PyThread_type_lock aLock, int waitflag)
	{
	return PyThread_acquire_lock_timed(aLock, waitflag ? -1 : 0, 0);
	}

	void
	PyThread_release_lock(PyThread_type_lock aLock)
	{
	assert(aLock);
	(void)LeaveNonRecursiveMutex((PNRMUTEX) aLock);
	}

	/* minimum/maximum thread stack sizes supported */
	#define THREAD_MIN_STACKSIZE 0x8000 /* 32 KiB */
	#define THREAD_MAX_STACKSIZE 0x10000000 /* 256 MiB */

	/* set the thread stack size.
	* Return 0 if size is valid, -1 otherwise.
	*/
	static int
	_pythread_nt_set_stacksize(size_t size)
	{
	/* set to default */
	if (size == 0) {
	_PyInterpreterState_GET()->threads.stacksize = 0;
	return 0;
	}

	/* valid range? */
	if (size >= THREAD_MIN_STACKSIZE && size < THREAD_MAX_STACKSIZE) {
	_PyInterpreterState_GET()->threads.stacksize = size;
	return 0;
	}

	return -1;
	}

	#define THREAD_SET_STACKSIZE(x) _pythread_nt_set_stacksize(x)


	/* Thread Local Storage (TLS) API

	This API is DEPRECATED since Python 3.7. See PEP 539 for details.
	*/

	int
	PyThread_create_key(void)
	{
	DWORD result = TlsAlloc();
	if (result == TLS_OUT_OF_INDEXES)
	return -1;
	return (int)result;
	}

	void
	PyThread_delete_key(int key)
	{
	TlsFree(key);
	}

	int
	PyThread_set_key_value(int key, void *value)
	{
	BOOL ok = TlsSetValue(key, value);
	return ok ? 0 : -1;
	}

	void *
	PyThread_get_key_value(int key)
	{
	return TlsGetValue(key);
	}

	void
	PyThread_delete_key_value(int key)
	{
	/* NULL is used as "key missing", and it is also the default
	* given by TlsGetValue() if nothing has been set yet.
	*/
	TlsSetValue(key, NULL);
	}


	/* reinitialization of TLS is not necessary after fork when using
	* the native TLS functions. And forking isn't supported on Windows either.
	*/
	void
	PyThread_ReInitTLS(void)
	{
	}


	/* Thread Specific Storage (TSS) API

	Platform-specific components of TSS API implementation.
	*/

	int
	PyThread_tss_create(Py_tss_t *key)
	{
	assert(key != NULL);
	/* If the key has been created, function is silently skipped. */
	if (key->_is_initialized) {
	return 0;
	}

	DWORD result = TlsAlloc();
	if (result == TLS_OUT_OF_INDEXES) {
	return -1;
	}
	/* In Windows, platform-specific key type is DWORD. */
	key->_key = result;
	key->_is_initialized = 1;
	return 0;
	}

	void
	PyThread_tss_delete(Py_tss_t *key)
	{
	assert(key != NULL);
	/* If the key has not been created, function is silently skipped. */
	if (!key->_is_initialized) {
	return;
	}

	TlsFree(key->_key);
	key->_key = TLS_OUT_OF_INDEXES;
	key->_is_initialized = 0;
	}

	int
	PyThread_tss_set(Py_tss_t key, void value)
	{
	assert(key != NULL);
	BOOL ok = TlsSetValue(key->_key, value);
	return ok ? 0 : -1;
	}

	void *
	PyThread_tss_get(Py_tss_t *key)
	{
	assert(key != NULL);
	return TlsGetValue(key->_key);
	}