/***************************************************************************** * Copyright (C) 2013 x265 project * * Authors: Steve Borho * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111, USA. * * This program is also available under a commercial proprietary license. * For more information, contact us at license @ x265.com *****************************************************************************/ #include "common.h" #include "threadpool.h" #include "threading.h" #include #if X86_64 #ifdef __GNUC__ #define SLEEPBITMAP_CTZ(id, x) id = (unsigned long)__builtin_ctzll(x) #define SLEEPBITMAP_OR(ptr, mask) __sync_fetch_and_or(ptr, mask) #define SLEEPBITMAP_AND(ptr, mask) __sync_fetch_and_and(ptr, mask) #elif defined(_MSC_VER) #define SLEEPBITMAP_CTZ(id, x) _BitScanForward64(&id, x) #define SLEEPBITMAP_OR(ptr, mask) InterlockedOr64((volatile LONG64*)ptr, (LONG)mask) #define SLEEPBITMAP_AND(ptr, mask) InterlockedAnd64((volatile LONG64*)ptr, (LONG)mask) #endif // ifdef __GNUC__ #else /* use 32-bit primitives defined in threading.h */ #define SLEEPBITMAP_CTZ CTZ #define SLEEPBITMAP_OR ATOMIC_OR #define SLEEPBITMAP_AND ATOMIC_AND #endif #if MACOS #include #include #endif #if HAVE_LIBNUMA #include #endif namespace X265_NS { // x265 private namespace class WorkerThread : public Thread { private: ThreadPool& m_pool; int m_id; Event m_wakeEvent; WorkerThread& operator =(const WorkerThread&); public: JobProvider* m_curJobProvider; BondedTaskGroup* m_bondMaster; WorkerThread(ThreadPool& pool, int id) : m_pool(pool), m_id(id) {} virtual ~WorkerThread() {} void threadMain(); void awaken() { m_wakeEvent.trigger(); } }; void WorkerThread::threadMain() { THREAD_NAME("Worker", m_id); #if _WIN32 SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_BELOW_NORMAL); #else __attribute__((unused)) int val = nice(10); #endif m_pool.setCurrentThreadAffinity(); sleepbitmap_t idBit = (sleepbitmap_t)1 << m_id; m_curJobProvider = m_pool.m_jpTable[0]; m_bondMaster = NULL; SLEEPBITMAP_OR(&m_curJobProvider->m_ownerBitmap, idBit); SLEEPBITMAP_OR(&m_pool.m_sleepBitmap, idBit); m_wakeEvent.wait(); while (m_pool.m_isActive) { if (m_bondMaster) { m_bondMaster->processTasks(m_id); m_bondMaster->m_exitedPeerCount.incr(); m_bondMaster = NULL; } do { /* do pending work for current job provider */ m_curJobProvider->findJob(m_id); /* if the current job provider still wants help, only switch to a * higher priority provider (lower slice type). Else take the first * available job provider with the highest priority */ int curPriority = (m_curJobProvider->m_helpWanted) ? m_curJobProvider->m_sliceType : INVALID_SLICE_PRIORITY + 1; int nextProvider = -1; for (int i = 0; i < m_pool.m_numProviders; i++) { if (m_pool.m_jpTable[i]->m_helpWanted && m_pool.m_jpTable[i]->m_sliceType < curPriority) { nextProvider = i; curPriority = m_pool.m_jpTable[i]->m_sliceType; } } if (nextProvider != -1 && m_curJobProvider != m_pool.m_jpTable[nextProvider]) { SLEEPBITMAP_AND(&m_curJobProvider->m_ownerBitmap, ~idBit); m_curJobProvider = m_pool.m_jpTable[nextProvider]; SLEEPBITMAP_OR(&m_curJobProvider->m_ownerBitmap, idBit); } } while (m_curJobProvider->m_helpWanted); /* While the worker sleeps, a job-provider or bond-group may acquire this * worker's sleep bitmap bit. Once acquired, that thread may modify * m_bondMaster or m_curJobProvider, then waken the thread */ SLEEPBITMAP_OR(&m_pool.m_sleepBitmap, idBit); m_wakeEvent.wait(); } SLEEPBITMAP_OR(&m_pool.m_sleepBitmap, idBit); } void JobProvider::tryWakeOne() { int id = m_pool->tryAcquireSleepingThread(m_ownerBitmap, ALL_POOL_THREADS); if (id < 0) { m_helpWanted = true; return; } WorkerThread& worker = m_pool->m_workers[id]; if (worker.m_curJobProvider != this) /* poaching */ { sleepbitmap_t bit = (sleepbitmap_t)1 << id; SLEEPBITMAP_AND(&worker.m_curJobProvider->m_ownerBitmap, ~bit); worker.m_curJobProvider = this; SLEEPBITMAP_OR(&worker.m_curJobProvider->m_ownerBitmap, bit); } worker.awaken(); } int ThreadPool::tryAcquireSleepingThread(sleepbitmap_t firstTryBitmap, sleepbitmap_t secondTryBitmap) { unsigned long id; sleepbitmap_t masked = m_sleepBitmap & firstTryBitmap; while (masked) { SLEEPBITMAP_CTZ(id, masked); sleepbitmap_t bit = (sleepbitmap_t)1 << id; if (SLEEPBITMAP_AND(&m_sleepBitmap, ~bit) & bit) return (int)id; masked = m_sleepBitmap & firstTryBitmap; } masked = m_sleepBitmap & secondTryBitmap; while (masked) { SLEEPBITMAP_CTZ(id, masked); sleepbitmap_t bit = (sleepbitmap_t)1 << id; if (SLEEPBITMAP_AND(&m_sleepBitmap, ~bit) & bit) return (int)id; masked = m_sleepBitmap & secondTryBitmap; } return -1; } int ThreadPool::tryBondPeers(int maxPeers, sleepbitmap_t peerBitmap, BondedTaskGroup& master) { int bondCount = 0; do { int id = tryAcquireSleepingThread(peerBitmap, 0); if (id < 0) return bondCount; m_workers[id].m_bondMaster = &master; m_workers[id].awaken(); bondCount++; } while (bondCount < maxPeers); return bondCount; } ThreadPool* ThreadPool::allocThreadPools(x265_param* p, int& numPools) { enum { MAX_NODE_NUM = 127 }; int cpusPerNode[MAX_NODE_NUM + 1]; int threadsPerPool[MAX_NODE_NUM + 2]; uint32_t nodeMaskPerPool[MAX_NODE_NUM +2]; memset(cpusPerNode, 0, sizeof(cpusPerNode)); memset(threadsPerPool, 0, sizeof(threadsPerPool)); memset(nodeMaskPerPool, 0, sizeof(nodeMaskPerPool)); int numNumaNodes = X265_MIN(getNumaNodeCount(), MAX_NODE_NUM); int cpuCount = getCpuCount(); bool bNumaSupport = false; #if defined(_WIN32_WINNT) && _WIN32_WINNT >= _WIN32_WINNT_WIN7 bNumaSupport = true; #elif HAVE_LIBNUMA bNumaSupport = numa_available() >= 0; #endif for (int i = 0; i < cpuCount; i++) { #if defined(_WIN32_WINNT) && _WIN32_WINNT >= _WIN32_WINNT_WIN7 UCHAR node; if (GetNumaProcessorNode((UCHAR)i, &node)) cpusPerNode[X265_MIN(node, (UCHAR)MAX_NODE_NUM)]++; else #elif HAVE_LIBNUMA if (bNumaSupport >= 0) cpusPerNode[X265_MIN(numa_node_of_cpu(i), MAX_NODE_NUM)]++; else #endif cpusPerNode[0]++; } if (bNumaSupport && p->logLevel >= X265_LOG_DEBUG) for (int i = 0; i < numNumaNodes; i++) x265_log(p, X265_LOG_DEBUG, "detected NUMA node %d with %d logical cores\n", i, cpusPerNode[i]); /* limit threads based on param->numaPools */ if (p->numaPools && *p->numaPools) { const char *nodeStr = p->numaPools; for (int i = 0; i < numNumaNodes; i++) { if (!*nodeStr) { threadsPerPool[i] = 0; continue; } else if (*nodeStr == '-') threadsPerPool[i] = 0; else if (*nodeStr == '*') { for (int j = i; j < numNumaNodes; j++) { threadsPerPool[numNumaNodes] += cpusPerNode[j]; nodeMaskPerPool[numNumaNodes] |= (1U << j); } break; } else if (*nodeStr == '+') { threadsPerPool[numNumaNodes] += cpusPerNode[i]; nodeMaskPerPool[numNumaNodes] = (1U << i); } else { int count = atoi(nodeStr); threadsPerPool[i] = X265_MIN(count, cpusPerNode[i]); nodeMaskPerPool[i] = (1U << i); } /* consume current node string, comma, and white-space */ while (*nodeStr && *nodeStr != ',') ++nodeStr; if (*nodeStr == ',' || *nodeStr == ' ') ++nodeStr; } } else { for (int i = 0; i < numNumaNodes; i++) { threadsPerPool[numNumaNodes] += cpusPerNode[i]; nodeMaskPerPool[numNumaNodes] |= (1U << i); } } // If the last pool size is > MAX_POOL_THREADS, clip it to spawn thread pools only of size >= 1/2 max (heuristic) if ((threadsPerPool[numNumaNodes] > MAX_POOL_THREADS) && ((threadsPerPool[numNumaNodes] % MAX_POOL_THREADS) < (MAX_POOL_THREADS / 2))) { threadsPerPool[numNumaNodes] -= (threadsPerPool[numNumaNodes] % MAX_POOL_THREADS); x265_log(p, X265_LOG_DEBUG, "Creating only %d worker threads beyond specified numbers with --pools (if specified) to prevent asymmetry in pools; may not use all HW contexts\n", threadsPerPool[numNumaNodes]); } numPools = 0; for (int i = 0; i < numNumaNodes + 1; i++) { if (bNumaSupport) x265_log(p, X265_LOG_DEBUG, "NUMA node %d may use %d logical cores\n", i, cpusPerNode[i]); if (threadsPerPool[i]) numPools += (threadsPerPool[i] + MAX_POOL_THREADS - 1) / MAX_POOL_THREADS; } if (!numPools) return NULL; if (numPools > p->frameNumThreads) { x265_log(p, X265_LOG_DEBUG, "Reducing number of thread pools for frame thread count\n"); numPools = X265_MAX(p->frameNumThreads / 2, 1); } ThreadPool *pools = new ThreadPool[numPools]; if (pools) { int maxProviders = (p->frameNumThreads + numPools - 1) / numPools + 1; /* +1 is Lookahead, always assigned to threadpool 0 */ int node = 0; for (int i = 0; i < numPools; i++) { while (!threadsPerPool[node]) node++; int numThreads = X265_MIN(MAX_POOL_THREADS, threadsPerPool[node]); if (!pools[i].create(numThreads, maxProviders, nodeMaskPerPool[node])) { X265_FREE(pools); numPools = 0; return NULL; } if (numNumaNodes > 1) x265_log(p, X265_LOG_INFO, "Thread pool %d using %d threads with NUMA node mask %lx\n", i, numThreads, nodeMaskPerPool[node]); else x265_log(p, X265_LOG_INFO, "Thread pool created using %d threads\n", numThreads); threadsPerPool[node] -= numThreads; } } else numPools = 0; return pools; } ThreadPool::ThreadPool() { memset(this, 0, sizeof(*this)); } bool ThreadPool::create(int numThreads, int maxProviders, uint32_t nodeMask) { X265_CHECK(numThreads <= MAX_POOL_THREADS, "a single thread pool cannot have more than MAX_POOL_THREADS threads\n"); #if defined(_WIN32_WINNT) && _WIN32_WINNT >= _WIN32_WINNT_WIN7 m_winCpuMask = 0x0; GROUP_AFFINITY groupAffinity; for (int i = 0; i < getNumaNodeCount(); i++) { int numaNode = ((nodeMask >> i) & 0x1U) ? i : -1; if (numaNode != -1) if (GetNumaNodeProcessorMaskEx((USHORT)numaNode, &groupAffinity)) m_winCpuMask |= groupAffinity.Mask; } m_numaMask = &m_winCpuMask; #elif HAVE_LIBNUMA if (numa_available() >= 0) { struct bitmask* nodemask = numa_allocate_nodemask(); if (nodemask) { *(nodemask->maskp) = nodeMask; m_numaMask = nodemask; } else x265_log(NULL, X265_LOG_ERROR, "unable to get NUMA node mask for %lx\n", nodeMask); } #else (void)nodeMask; #endif m_numWorkers = numThreads; m_workers = X265_MALLOC(WorkerThread, numThreads); /* placement new initialization */ if (m_workers) for (int i = 0; i < numThreads; i++) new (m_workers + i)WorkerThread(*this, i); m_jpTable = X265_MALLOC(JobProvider*, maxProviders); m_numProviders = 0; return m_workers && m_jpTable; } bool ThreadPool::start() { m_isActive = true; for (int i = 0; i < m_numWorkers; i++) { if (!m_workers[i].start()) { m_isActive = false; return false; } } return true; } void ThreadPool::stopWorkers() { if (m_workers) { m_isActive = false; for (int i = 0; i < m_numWorkers; i++) { while (!(m_sleepBitmap & ((sleepbitmap_t)1 << i))) GIVE_UP_TIME(); m_workers[i].awaken(); m_workers[i].stop(); } } } ThreadPool::~ThreadPool() { if (m_workers) { for (int i = 0; i < m_numWorkers; i++) m_workers[i].~WorkerThread(); } X265_FREE(m_workers); X265_FREE(m_jpTable); #if HAVE_LIBNUMA if(m_numaMask) numa_free_nodemask((struct bitmask*)m_numaMask); #endif } void ThreadPool::setCurrentThreadAffinity() { setThreadNodeAffinity(m_numaMask); } /* static */ void ThreadPool::setThreadNodeAffinity(void *numaMask) { #if defined(_WIN32_WINNT) && _WIN32_WINNT >= _WIN32_WINNT_WIN7 if (SetThreadAffinityMask(GetCurrentThread(), (DWORD_PTR)(*((DWORD*)numaMask)))) return; else x265_log(NULL, X265_LOG_ERROR, "unable to set thread affinity for NUMA node mask\n"); #elif HAVE_LIBNUMA if (numa_available() >= 0) { numa_run_on_node_mask((struct bitmask*)numaMask); numa_set_interleave_mask((struct bitmask*)numaMask); numa_set_localalloc(); return; } x265_log(NULL, X265_LOG_ERROR, "unable to set thread affinity for NUMA node mask\n"); #else (void)numaMask; #endif return; } /* static */ int ThreadPool::getNumaNodeCount() { #if defined(_WIN32_WINNT) && _WIN32_WINNT >= _WIN32_WINNT_WIN7 ULONG num = 1; if (GetNumaHighestNodeNumber(&num)) num++; return (int)num; #elif HAVE_LIBNUMA if (numa_available() >= 0) return numa_max_node() + 1; else return 1; #else return 1; #endif } /* static */ int ThreadPool::getCpuCount() { #if _WIN32 SYSTEM_INFO sysinfo; GetSystemInfo(&sysinfo); return sysinfo.dwNumberOfProcessors; #elif __unix__ return sysconf(_SC_NPROCESSORS_ONLN); #elif MACOS int nm[2]; size_t len = 4; uint32_t count; nm[0] = CTL_HW; nm[1] = HW_AVAILCPU; sysctl(nm, 2, &count, &len, NULL, 0); if (count < 1) { nm[1] = HW_NCPU; sysctl(nm, 2, &count, &len, NULL, 0); if (count < 1) count = 1; } return count; #else return 2; // default to 2 threads, everywhere else #endif } } // end namespace X265_NS