ThreadPoolImpl::ThreadPoolImpl(int numThreads)
: m_ok(false)
, m_referenceCount(1)
, m_firstProvider(NULL)
, m_lastProvider(NULL)
{
if (numThreads == 0)
numThreads = getCpuCount();
m_numSleepMapWords = (numThreads + 63) >> 6;
m_sleepMap = X265_MALLOC(uint64_t, m_numSleepMapWords);
char *buffer = (char*)X265_MALLOC(PoolThread, numThreads);
m_threads = reinterpret_cast<PoolThread*>(buffer);
m_numThreads = numThreads;
if (m_threads && m_sleepMap)
{
for (int i = 0; i < m_numSleepMapWords; i++)
{
m_sleepMap[i] = 0;
}
m_ok = true;
int i;
for (i = 0; i < numThreads; i++)
{
new (buffer)PoolThread(*this, i);
buffer += sizeof(PoolThread);
if (!m_threads[i].start())
{
m_ok = false;
break;
}
}
if (m_ok)
{
waitForAllIdle();
}
else
{
// stop threads that did start up
for (int j = 0; j < i; j++)
{
m_threads[j].poke();
m_threads[j].stop();
}
}
}
}
bool ScalingList::init()
{
bool ok = true;
for (int sizeId = 0; sizeId < NUM_SIZES; sizeId++)
{
for (int listId = 0; listId < NUM_LISTS; listId++)
{
m_scalingListCoef[sizeId][listId] = X265_MALLOC(int32_t, X265_MIN(MAX_MATRIX_COEF_NUM, s_numCoefPerSize[sizeId]));
ok &= !!m_scalingListCoef[sizeId][listId];
for (int rem = 0; rem < NUM_REM; rem++)
{
m_quantCoef[sizeId][listId][rem] = X265_MALLOC(int32_t, s_numCoefPerSize[sizeId]);
m_dequantCoef[sizeId][listId][rem] = X265_MALLOC(int32_t, s_numCoefPerSize[sizeId]);
ok &= m_quantCoef[sizeId][listId][rem] && m_dequantCoef[sizeId][listId][rem];
}
}
}
return ok;
}
bool ThreadPool::create(int numThreads, int maxProviders, int node)
{
X265_CHECK(numThreads <= MAX_POOL_THREADS, "a single thread pool cannot have more than MAX_POOL_THREADS threads\n");
m_numaNode = node;
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;
}
