/** * OpenAL cross platform audio library * Copyright (C) 1999-2007 by authors. * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include "threads.h" #include #include #include #include "uintmap.h" extern inline althrd_t althrd_current(void); extern inline int althrd_equal(althrd_t thr0, althrd_t thr1); extern inline void althrd_exit(int res); extern inline void althrd_yield(void); extern inline int almtx_lock(almtx_t *mtx); extern inline int almtx_unlock(almtx_t *mtx); extern inline int almtx_trylock(almtx_t *mtx); extern inline void *altss_get(altss_t tss_id); extern inline int altss_set(altss_t tss_id, void *val); #ifndef UNUSED #if defined(__cplusplus) #define UNUSED(x) #elif defined(__GNUC__) #define UNUSED(x) UNUSED_##x __attribute__((unused)) #elif defined(__LCLINT__) #define UNUSED(x) /*@unused@*/ x #else #define UNUSED(x) x #endif #endif #define THREAD_STACK_SIZE (2*1024*1024) /* 2MB */ #ifdef _WIN32 #define WIN32_LEAN_AND_MEAN #include #include /* An associative map of uint:void* pairs. The key is the unique Thread ID and * the value is the thread HANDLE. The thread ID is passed around as the * althrd_t since there is only one ID per thread, whereas a thread may be * referenced by multiple different HANDLEs. This map allows retrieving the * original handle which is needed to join the thread and get its return value. */ static UIntMap ThrdIdHandle = UINTMAP_STATIC_INITIALIZE; /* An associative map of uint:void* pairs. The key is the TLS index (given by * TlsAlloc), and the value is the altss_dtor_t callback. When a thread exits, * we iterate over the TLS indices for their thread-local value and call the * destructor function with it if they're both not NULL. */ static UIntMap TlsDestructors = UINTMAP_STATIC_INITIALIZE; void althrd_setname(althrd_t thr, const char *name) { #if defined(_MSC_VER) #define MS_VC_EXCEPTION 0x406D1388 #pragma pack(push,8) struct { DWORD dwType; // Must be 0x1000. LPCSTR szName; // Pointer to name (in user addr space). DWORD dwThreadID; // Thread ID (-1=caller thread). DWORD dwFlags; // Reserved for future use, must be zero. } info; #pragma pack(pop) info.dwType = 0x1000; info.szName = name; info.dwThreadID = thr; info.dwFlags = 0; __try { RaiseException(MS_VC_EXCEPTION, 0, sizeof(info)/sizeof(ULONG_PTR), (ULONG_PTR*)&info); } __except(EXCEPTION_CONTINUE_EXECUTION) { } #undef MS_VC_EXCEPTION #else (void)thr; (void)name; #endif } typedef struct thread_cntr { althrd_start_t func; void *arg; } thread_cntr; static DWORD WINAPI althrd_starter(void *arg) { thread_cntr cntr; memcpy(&cntr, arg, sizeof(cntr)); free(arg); return (DWORD)((*cntr.func)(cntr.arg)); } int althrd_create(althrd_t *thr, althrd_start_t func, void *arg) { thread_cntr *cntr; DWORD thrid; HANDLE hdl; cntr = malloc(sizeof(*cntr)); if(!cntr) return althrd_nomem; cntr->func = func; cntr->arg = arg; hdl = CreateThread(NULL, THREAD_STACK_SIZE, althrd_starter, cntr, 0, &thrid); if(!hdl) { free(cntr); return althrd_error; } InsertUIntMapEntry(&ThrdIdHandle, thrid, hdl); *thr = thrid; return althrd_success; } int althrd_detach(althrd_t thr) { HANDLE hdl = RemoveUIntMapKey(&ThrdIdHandle, thr); if(!hdl) return althrd_error; CloseHandle(hdl); return althrd_success; } int althrd_join(althrd_t thr, int *res) { DWORD code; HANDLE hdl = RemoveUIntMapKey(&ThrdIdHandle, thr); if(!hdl) return althrd_error; WaitForSingleObject(hdl, INFINITE); GetExitCodeThread(hdl, &code); CloseHandle(hdl); if(res != NULL) *res = (int)code; return althrd_success; } int althrd_sleep(const struct timespec *ts, struct timespec* UNUSED(rem)) { DWORD msec; if(ts->tv_sec < 0 || ts->tv_sec >= (0x7fffffff / 1000) || ts->tv_nsec < 0 || ts->tv_nsec >= 1000000000) return -2; msec = (DWORD)(ts->tv_sec * 1000); msec += (DWORD)((ts->tv_nsec+999999) / 1000000); Sleep(msec); return 0; } int almtx_init(almtx_t *mtx, int type) { if(!mtx) return althrd_error; type &= ~almtx_recursive; if(type != almtx_plain) return althrd_error; InitializeCriticalSection(mtx); return althrd_success; } void almtx_destroy(almtx_t *mtx) { DeleteCriticalSection(mtx); } #if defined(_WIN32_WINNT) && _WIN32_WINNT >= 0x0600 int alcnd_init(alcnd_t *cond) { InitializeConditionVariable(cond); return althrd_success; } int alcnd_signal(alcnd_t *cond) { WakeConditionVariable(cond); return althrd_success; } int alcnd_broadcast(alcnd_t *cond) { WakeAllConditionVariable(cond); return althrd_success; } int alcnd_wait(alcnd_t *cond, almtx_t *mtx) { if(SleepConditionVariableCS(cond, mtx, INFINITE) != 0) return althrd_success; return althrd_error; } void alcnd_destroy(alcnd_t* UNUSED(cond)) { /* Nothing to delete? */ } #else /* WARNING: This is a rather poor implementation of condition variables, with * known problems. However, it's simple, efficient, and good enough for now to * not require Vista. Based on "Strategies for Implementing POSIX Condition * Variables" by Douglas C. Schmidt and Irfan Pyarali: * http://www.cs.wustl.edu/~schmidt/win32-cv-1.html */ /* A better solution may be using Wine's implementation. It requires internals * (NtCreateKeyedEvent, NtReleaseKeyedEvent, and NtWaitForKeyedEvent) from * ntdll, and implemention of exchange and compare-exchange for RefCounts. */ typedef struct { RefCount wait_count; HANDLE events[2]; } _int_alcnd_t; enum { SIGNAL = 0, BROADCAST = 1 }; int alcnd_init(alcnd_t *cond) { _int_alcnd_t *icond = calloc(1, sizeof(*icond)); if(!icond) return althrd_nomem; InitRef(&icond->wait_count, 0); icond->events[SIGNAL] = CreateEventW(NULL, FALSE, FALSE, NULL); icond->events[BROADCAST] = CreateEventW(NULL, TRUE, FALSE, NULL); if(!icond->events[SIGNAL] || !icond->events[BROADCAST]) { if(icond->events[SIGNAL]) CloseHandle(icond->events[SIGNAL]); if(icond->events[BROADCAST]) CloseHandle(icond->events[BROADCAST]); free(icond); return althrd_error; } cond->Ptr = icond; return althrd_success; } int alcnd_signal(alcnd_t *cond) { _int_alcnd_t *icond = cond->Ptr; if(ReadRef(&icond->wait_count) > 0) SetEvent(icond->events[SIGNAL]); return althrd_success; } int alcnd_broadcast(alcnd_t *cond) { _int_alcnd_t *icond = cond->Ptr; if(ReadRef(&icond->wait_count) > 0) SetEvent(icond->events[BROADCAST]); return althrd_success; } int alcnd_wait(alcnd_t *cond, almtx_t *mtx) { _int_alcnd_t *icond = cond->Ptr; int res; IncrementRef(&icond->wait_count); LeaveCriticalSection(mtx); res = WaitForMultipleObjects(2, icond->events, FALSE, INFINITE); if(DecrementRef(&icond->wait_count) == 0 && res == WAIT_OBJECT_0+BROADCAST) ResetEvent(icond->events[BROADCAST]); EnterCriticalSection(mtx); return althrd_success; } void alcnd_destroy(alcnd_t *cond) { _int_alcnd_t *icond = cond->Ptr; CloseHandle(icond->events[SIGNAL]); CloseHandle(icond->events[BROADCAST]); free(icond); } #endif /* defined(_WIN32_WINNT) && _WIN32_WINNT >= 0x0600 */ int alsem_init(alsem_t *sem, unsigned int initial) { *sem = CreateSemaphore(NULL, initial, INT_MAX, NULL); if(*sem != NULL) return althrd_success; return althrd_error; } void alsem_destroy(alsem_t *sem) { CloseHandle(*sem); } int alsem_post(alsem_t *sem) { DWORD ret = ReleaseSemaphore(*sem, 1, NULL); if(ret) return althrd_success; return althrd_error; } int alsem_wait(alsem_t *sem) { DWORD ret = WaitForSingleObject(*sem, INFINITE); if(ret == WAIT_OBJECT_0) return althrd_success; return althrd_error; } int alsem_trywait(alsem_t *sem) { DWORD ret = WaitForSingleObject(*sem, 0); if(ret == WAIT_OBJECT_0) return althrd_success; if(ret == WAIT_TIMEOUT) return althrd_busy; return althrd_error; } int altss_create(altss_t *tss_id, altss_dtor_t callback) { DWORD key = TlsAlloc(); if(key == TLS_OUT_OF_INDEXES) return althrd_error; *tss_id = key; if(callback != NULL) InsertUIntMapEntry(&TlsDestructors, key, callback); return althrd_success; } void altss_delete(altss_t tss_id) { RemoveUIntMapKey(&TlsDestructors, tss_id); TlsFree(tss_id); } int altimespec_get(struct timespec *ts, int base) { static_assert(sizeof(FILETIME) == sizeof(ULARGE_INTEGER), "Size of FILETIME does not match ULARGE_INTEGER"); if(base == AL_TIME_UTC) { union { FILETIME ftime; ULARGE_INTEGER ulint; } systime; GetSystemTimeAsFileTime(&systime.ftime); /* FILETIME is in 100-nanosecond units, or 1/10th of a microsecond. */ ts->tv_sec = systime.ulint.QuadPart/10000000; ts->tv_nsec = (systime.ulint.QuadPart%10000000) * 100; return base; } return 0; } void alcall_once(alonce_flag *once, void (*callback)(void)) { LONG ret; while((ret=InterlockedExchange(once, 1)) == 1) althrd_yield(); if(ret == 0) (*callback)(); InterlockedExchange(once, 2); } void althrd_deinit(void) { ResetUIntMap(&ThrdIdHandle); ResetUIntMap(&TlsDestructors); } void althrd_thread_detach(void) { ALsizei i; LockUIntMapRead(&TlsDestructors); for(i = 0;i < TlsDestructors.size;i++) { void *ptr = altss_get(TlsDestructors.keys[i]); altss_dtor_t callback = (altss_dtor_t)TlsDestructors.values[i]; if(ptr) { if(callback) callback(ptr); altss_set(TlsDestructors.keys[i], NULL); } } UnlockUIntMapRead(&TlsDestructors); } #else #include #include #include #ifdef HAVE_PTHREAD_NP_H #include #endif extern inline int althrd_sleep(const struct timespec *ts, struct timespec *rem); extern inline void alcall_once(alonce_flag *once, void (*callback)(void)); extern inline void althrd_deinit(void); extern inline void althrd_thread_detach(void); void althrd_setname(althrd_t thr, const char *name) { #if defined(HAVE_PTHREAD_SETNAME_NP) #if defined(PTHREAD_SETNAME_NP_ONE_PARAM) if(althrd_equal(thr, althrd_current())) pthread_setname_np(name); #elif defined(PTHREAD_SETNAME_NP_THREE_PARAMS) pthread_setname_np(thr, "%s", (void*)name); #else pthread_setname_np(thr, name); #endif #elif defined(HAVE_PTHREAD_SET_NAME_NP) pthread_set_name_np(thr, name); #else (void)thr; (void)name; #endif } typedef struct thread_cntr { althrd_start_t func; void *arg; } thread_cntr; static void *althrd_starter(void *arg) { thread_cntr cntr; memcpy(&cntr, arg, sizeof(cntr)); free(arg); return (void*)(intptr_t)((*cntr.func)(cntr.arg)); } int althrd_create(althrd_t *thr, althrd_start_t func, void *arg) { thread_cntr *cntr; pthread_attr_t attr; size_t stackmult = 1; int err; cntr = malloc(sizeof(*cntr)); if(!cntr) return althrd_nomem; if(pthread_attr_init(&attr) != 0) { free(cntr); return althrd_error; } retry_stacksize: if(pthread_attr_setstacksize(&attr, THREAD_STACK_SIZE*stackmult) != 0) { pthread_attr_destroy(&attr); free(cntr); return althrd_error; } cntr->func = func; cntr->arg = arg; if((err=pthread_create(thr, &attr, althrd_starter, cntr)) == 0) { pthread_attr_destroy(&attr); return althrd_success; } if(err == EINVAL) { /* If an invalid stack size, try increasing it (limit x4, 8MB). */ if(stackmult < 4) { stackmult *= 2; goto retry_stacksize; } /* If still nothing, try defaults and hope they're good enough. */ if(pthread_create(thr, NULL, althrd_starter, cntr) == 0) { pthread_attr_destroy(&attr); return althrd_success; } } pthread_attr_destroy(&attr); free(cntr); return althrd_error; } int althrd_detach(althrd_t thr) { if(pthread_detach(thr) != 0) return althrd_error; return althrd_success; } int althrd_join(althrd_t thr, int *res) { void *code; if(pthread_join(thr, &code) != 0) return althrd_error; if(res != NULL) *res = (int)(intptr_t)code; return althrd_success; } int almtx_init(almtx_t *mtx, int type) { int ret; if(!mtx) return althrd_error; if((type&~almtx_recursive) != 0) return althrd_error; if(type == almtx_plain) ret = pthread_mutex_init(mtx, NULL); else { pthread_mutexattr_t attr; ret = pthread_mutexattr_init(&attr); if(ret) return althrd_error; if(type == almtx_recursive) { ret = pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE); #ifdef HAVE_PTHREAD_MUTEXATTR_SETKIND_NP if(ret != 0) ret = pthread_mutexattr_setkind_np(&attr, PTHREAD_MUTEX_RECURSIVE); #endif } else ret = 1; if(ret == 0) ret = pthread_mutex_init(mtx, &attr); pthread_mutexattr_destroy(&attr); } return ret ? althrd_error : althrd_success; } void almtx_destroy(almtx_t *mtx) { pthread_mutex_destroy(mtx); } int alcnd_init(alcnd_t *cond) { if(pthread_cond_init(cond, NULL) == 0) return althrd_success; return althrd_error; } int alcnd_signal(alcnd_t *cond) { if(pthread_cond_signal(cond) == 0) return althrd_success; return althrd_error; } int alcnd_broadcast(alcnd_t *cond) { if(pthread_cond_broadcast(cond) == 0) return althrd_success; return althrd_error; } int alcnd_wait(alcnd_t *cond, almtx_t *mtx) { if(pthread_cond_wait(cond, mtx) == 0) return althrd_success; return althrd_error; } void alcnd_destroy(alcnd_t *cond) { pthread_cond_destroy(cond); } int alsem_init(alsem_t *sem, unsigned int initial) { if(sem_init(sem, 0, initial) == 0) return althrd_success; return althrd_error; } void alsem_destroy(alsem_t *sem) { sem_destroy(sem); } int alsem_post(alsem_t *sem) { if(sem_post(sem) == 0) return althrd_success; return althrd_error; } int alsem_wait(alsem_t *sem) { if(sem_wait(sem) == 0) return althrd_success; if(errno == EINTR) return -2; return althrd_error; } int alsem_trywait(alsem_t *sem) { if(sem_trywait(sem) == 0) return althrd_success; if(errno == EWOULDBLOCK) return althrd_busy; if(errno == EINTR) return -2; return althrd_error; } int altss_create(altss_t *tss_id, altss_dtor_t callback) { if(pthread_key_create(tss_id, callback) != 0) return althrd_error; return althrd_success; } void altss_delete(altss_t tss_id) { pthread_key_delete(tss_id); } int altimespec_get(struct timespec *ts, int base) { if(base == AL_TIME_UTC) { int ret; #if _POSIX_TIMERS > 0 ret = clock_gettime(CLOCK_REALTIME, ts); if(ret == 0) return base; #else /* _POSIX_TIMERS > 0 */ struct timeval tv; ret = gettimeofday(&tv, NULL); if(ret == 0) { ts->tv_sec = tv.tv_sec; ts->tv_nsec = tv.tv_usec * 1000; return base; } #endif } return 0; } #endif void al_nssleep(unsigned long nsec) { struct timespec ts, rem; ts.tv_sec = nsec / 1000000000ul; ts.tv_nsec = nsec % 1000000000ul; while(althrd_sleep(&ts, &rem) == -1) ts = rem; }