#ifdef SYSTEM_WIN32 #pragma warning(push) #pragma warning(disable:4100) // unreferenced formal parameter #endif #ifdef SYSTEM_WIN32 #define WIN32_LEAN_AND_MEAN #include #include #endif #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "cmdlib.h" #include "messages.h" #include "log.h" #include "threads.h" #include "blockmem.h" #ifdef SYSTEM_POSIX #ifdef HAVE_SYS_TIME_H #include #endif #ifdef HAVE_SYS_RESOURCE_H #include #include #endif #ifdef HAVE_PTHREAD_H #include #endif #endif #include "hlassert.h" q_threadpriority g_threadpriority = DEFAULT_THREAD_PRIORITY; #define THREADTIMES_SIZE 100 #define THREADTIMES_SIZEf (float)(THREADTIMES_SIZE) static int dispatch = 0; static int workcount = 0; static int oldf = 0; static bool pacifier = false; static bool threaded = false; static double threadstart = 0; static double threadtimes[THREADTIMES_SIZE]; int GetThreadWork() { int r, f, i; double ct, finish, finish2, finish3; ThreadLock(); if (dispatch == 0) { oldf = 0; } if (dispatch > workcount) { Developer(DEVELOPER_LEVEL_ERROR, "dispatch > workcount!!!\n"); ThreadUnlock(); return -1; } if (dispatch == workcount) { Developer(DEVELOPER_LEVEL_MESSAGE, "dispatch == workcount, work is complete\n"); ThreadUnlock(); return -1; } if (dispatch < 0) { Developer(DEVELOPER_LEVEL_ERROR, "negative dispatch!!!\n"); ThreadUnlock(); return -1; } f = THREADTIMES_SIZE * dispatch / workcount; if (pacifier) { printf("\r%6d /%6d", dispatch, workcount); #ifdef ZHLT_PROGRESSFILE // AJM if (g_progressfile) { } #endif if (f != oldf) { ct = I_FloatTime(); /* Fill in current time for threadtimes record */ for (i = oldf; i <= f; i++) { if (threadtimes[i] < 1) { threadtimes[i] = ct; } } oldf = f; if (f > 10) { finish = (ct - threadtimes[0]) * (THREADTIMES_SIZEf - f) / f; finish2 = 10.0 * (ct - threadtimes[f - 10]) * (THREADTIMES_SIZEf - f) / THREADTIMES_SIZEf; finish3 = THREADTIMES_SIZEf * (ct - threadtimes[f - 1]) * (THREADTIMES_SIZEf - f) / THREADTIMES_SIZEf; if (finish > 1.0) { printf(" (%d%%: est. time to completion %ld/%ld/%ld secs) ", f, (long)(finish), (long)(finish2), (long)(finish3)); #ifdef ZHLT_PROGRESSFILE // AJM if (g_progressfile) { } #endif } else { printf(" (%d%%: est. time to completion <1 sec) ", f); #ifdef ZHLT_PROGRESSFILE // AJM if (g_progressfile) { } #endif } } } } else { if (f != oldf) { oldf = f; switch (f) { case 10: case 20: case 30: case 40: case 50: case 60: case 70: case 80: case 90: case 100: /* case 5: case 15: case 25: case 35: case 45: case 55: case 65: case 75: case 85: case 95: */ printf("%d%%...", f); default: break; } } } r = dispatch; dispatch++; ThreadUnlock(); return r; } q_threadfunction workfunction; static void ThreadWorkerFunction(int unused) { int work; while ((work = GetThreadWork()) != -1) { workfunction(work); } } #ifdef SYSTEM_WIN32 #pragma warning(pop) #endif void RunThreadsOnIndividual(int workcnt, bool showpacifier, q_threadfunction func) { workfunction = func; RunThreadsOn(workcnt, showpacifier, ThreadWorkerFunction); } #ifndef SINGLE_THREADED /*==================== | Begin SYSTEM_WIN32 =*/ #ifdef SYSTEM_WIN32 #define USED #include int g_numthreads = DEFAULT_NUMTHREADS; static CRITICAL_SECTION crit; static int enter; void ThreadSetPriority(q_threadpriority type) { int val; g_threadpriority = type; switch (g_threadpriority) { case eThreadPriorityLow: val = IDLE_PRIORITY_CLASS; break; case eThreadPriorityHigh: val = HIGH_PRIORITY_CLASS; break; case eThreadPriorityNormal: default: val = NORMAL_PRIORITY_CLASS; break; } SetPriorityClass(GetCurrentProcess(), val); } #if 0 static void AdjustPriority(HANDLE hThread) { int val; switch (g_threadpriority) { case eThreadPriorityLow: val = THREAD_PRIORITY_HIGHEST; break; case eThreadPriorityHigh: val = THREAD_PRIORITY_LOWEST; break; case eThreadPriorityNormal: default: val = THREAD_PRIORITY_NORMAL; break; } SetThreadPriority(hThread, val); } #endif void ThreadSetDefault() { SYSTEM_INFO info; if (g_numthreads == -1) // not set manually { GetSystemInfo(&info); g_numthreads = info.dwNumberOfProcessors; if (g_numthreads < 1 || g_numthreads > 32) { g_numthreads = 1; } } } void ThreadLock() { if (!threaded) { return; } EnterCriticalSection(&crit); if (enter) { Warning("Recursive ThreadLock\n"); } enter++; } void ThreadUnlock() { if (!threaded) { return; } if (!enter) { Error("ThreadUnlock without lock\n"); } enter--; LeaveCriticalSection(&crit); } q_threadfunction q_entry; static DWORD WINAPI ThreadEntryStub(LPVOID pParam) { q_entry((int)pParam); return 0; } void threads_InitCrit() { InitializeCriticalSection(&crit); threaded = true; } void threads_UninitCrit() { DeleteCriticalSection(&crit); } void RunThreadsOn(int workcnt, bool showpacifier, q_threadfunction func) { DWORD threadid[MAX_THREADS]; HANDLE threadhandle[MAX_THREADS]; int i; double start, end; threadstart = I_FloatTime(); start = threadstart; for (i = 0; i < THREADTIMES_SIZE; i++) { threadtimes[i] = 0; } dispatch = 0; workcount = workcnt; oldf = -1; pacifier = showpacifier; threaded = true; q_entry = func; if (workcount < dispatch) { Developer(DEVELOPER_LEVEL_ERROR, "RunThreadsOn: Workcount(%i) < dispatch(%i)\n", workcount, dispatch); } hlassume(workcount >= dispatch, assume_BadWorkcount); // // Create all the threads (suspended) // threads_InitCrit(); for (i = 0; i < g_numthreads; i++) { HANDLE hThread = CreateThread(NULL, 0, (LPTHREAD_START_ROUTINE) ThreadEntryStub, (LPVOID) i, CREATE_SUSPENDED, &threadid[i]); if (hThread != NULL) { threadhandle[i] = hThread; } else { LPVOID lpMsgBuf; FormatMessage(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, GetLastError(), MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), // Default language (LPTSTR) & lpMsgBuf, 0, NULL); // Process any inserts in lpMsgBuf. // ... // Display the string. Developer(DEVELOPER_LEVEL_ERROR, "CreateThread #%d [%08X] failed : %s\n", i, threadhandle[i], lpMsgBuf); Fatal(assume_THREAD_ERROR, "Unable to create thread #%d", i); // Free the buffer. LocalFree(lpMsgBuf); } } CheckFatal(); // Start all the threads for (i = 0; i < g_numthreads; i++) { if (ResumeThread(threadhandle[i]) == 0xFFFFFFFF) { LPVOID lpMsgBuf; FormatMessage(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, GetLastError(), MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), // Default language (LPTSTR) & lpMsgBuf, 0, NULL); // Process any inserts in lpMsgBuf. // ... // Display the string. Developer(DEVELOPER_LEVEL_ERROR, "ResumeThread #%d [%08X] failed : %s\n", i, threadhandle[i], lpMsgBuf); Fatal(assume_THREAD_ERROR, "Unable to start thread #%d", i); // Free the buffer. LocalFree(lpMsgBuf); } } CheckFatal(); // Wait for threads to complete for (i = 0; i < g_numthreads; i++) { Developer(DEVELOPER_LEVEL_MESSAGE, "WaitForSingleObject on thread #%d [%08X]\n", i, threadhandle[i]); WaitForSingleObject(threadhandle[i], INFINITE); } threads_UninitCrit(); q_entry = NULL; threaded = false; end = I_FloatTime(); if (pacifier) { printf("\r%60s\r", ""); } Log(" (%.2f seconds)\n", end - start); } #endif /*= | End SYSTEM_WIN32 =====================*/ /*==================== | Begin SYSTEM_POSIX =*/ #ifdef SYSTEM_POSIX #define USED int g_numthreads = DEFAULT_NUMTHREADS; void ThreadSetPriority(q_threadpriority type) { int val; g_threadpriority = type; // Currently in Linux land users are incapable of raising the priority level of their processes // Unless you are root -high is useless . . . switch (g_threadpriority) { case eThreadPriorityLow: val = PRIO_MAX; break; case eThreadPriorityHigh: val = PRIO_MIN; break; case eThreadPriorityNormal: default: val = 0; break; } setpriority(PRIO_PROCESS, 0, val); } void ThreadSetDefault() { if (g_numthreads == -1) { g_numthreads = 1; } } typedef void* pthread_addr_t; pthread_mutex_t* my_mutex; void ThreadLock() { if (my_mutex) { pthread_mutex_lock(my_mutex); } } void ThreadUnlock() { if (my_mutex) { pthread_mutex_unlock(my_mutex); } } q_threadfunction q_entry; static void* CDECL ThreadEntryStub(void* pParam) { q_entry((int)pParam); return NULL; } void threads_InitCrit() { pthread_mutexattr_t mattrib; if (!my_mutex) { my_mutex = (pthread_mutex_t*)Alloc(sizeof(*my_mutex)); if (pthread_mutexattr_init(&mattrib) == -1) { Error("pthread_mutex_attr_init failed"); } if (pthread_mutex_init(my_mutex, &mattrib) == -1) { Error("pthread_mutex_init failed"); } } } void threads_UninitCrit() { Free(my_mutex); my_mutex = NULL; } /* * ============= * RunThreadsOn * ============= */ void RunThreadsOn(int workcnt, bool showpacifier, q_threadfunction func) { int i; pthread_t work_threads[MAX_THREADS]; pthread_addr_t status; pthread_attr_t attrib; double start, end; threadstart = I_FloatTime(); start = threadstart; for (i = 0; i < THREADTIMES_SIZE; i++) { threadtimes[i] = 0; } dispatch = 0; workcount = workcnt; oldf = -1; pacifier = showpacifier; threaded = true; q_entry = func; if (pacifier) { setbuf(stdout, NULL); } threads_InitCrit(); if (pthread_attr_init(&attrib) == -1) { Error("pthread_attr_init failed"); } #ifdef _POSIX_THREAD_ATTR_STACKSIZE if (pthread_attr_setstacksize(&attrib, 0x400000) == -1) { Error("pthread_attr_setstacksize failed"); } #endif for (i = 0; i < g_numthreads; i++) { if (pthread_create(&work_threads[i], &attrib, ThreadEntryStub, (void*)i) == -1) { Error("pthread_create failed"); } } for (i = 0; i < g_numthreads; i++) { if (pthread_join(work_threads[i], &status) == -1) { Error("pthread_join failed"); } } threads_UninitCrit(); q_entry = NULL; threaded = false; end = I_FloatTime(); if (pacifier) { printf("\r%60s\r", ""); } Log(" (%.2f seconds)\n", end - start); } #endif /*SYSTEM_POSIX */ /*= | End SYSTEM_POSIX =====================*/ #endif /*SINGLE_THREADED */ /*==================== | Begin SINGLE_THREADED =*/ #ifdef SINGLE_THREADED int g_numthreads = 1; void ThreadSetPriority(q_threadpriority type) { } void threads_InitCrit() { } void threads_UninitCrit() { } void ThreadSetDefault() { g_numthreads = 1; } void ThreadLock() { } void ThreadUnlock() { } void RunThreadsOn(int workcnt, bool showpacifier, q_threadfunction func) { int i; double start, end; dispatch = 0; workcount = workcnt; oldf = -1; pacifier = showpacifier; threadstart = I_FloatTime(); start = threadstart; for (i = 0; i < THREADTIMES_SIZE; i++) { threadtimes[i] = 0.0; } if (pacifier) { setbuf(stdout, NULL); } func(0); end = I_FloatTime(); if (pacifier) { printf("\r%60s\r", ""); } Log(" (%.2f seconds)\n", end - start); } #endif /*= | End SINGLE_THREADED =====================*/