Dispatcher::TaskBatchPtr Dispatcher::acquireBatch( const ExecutableNode::Task &task, BatchMap ¤tBatches, TaskToBatchMap &tasksToBatches ) { MurmurHash taskHash = task.hash(); TaskToBatchMap::iterator it = tasksToBatches.find( taskHash ); if ( it != tasksToBatches.end() ) { return it->second; } MurmurHash hash = batchHash( task ); BatchMap::iterator bIt = currentBatches.find( hash ); if ( bIt != currentBatches.end() ) { TaskBatchPtr batch = bIt->second; std::vector<float> &frames = batch->frames(); const CompoundPlug *dispatcherPlug = task.node()->dispatcherPlug(); const IntPlug *batchSizePlug = dispatcherPlug->getChild<const IntPlug>( g_batchSize ); size_t batchSize = ( batchSizePlug ) ? batchSizePlug->getValue() : 1; if ( task.node()->requiresSequenceExecution() || ( frames.size() < batchSize ) ) { if ( task.hash() != MurmurHash() ) { float frame = task.context()->getFrame(); if ( std::find( frames.begin(), frames.end(), frame ) == frames.end() ) { if ( task.node()->requiresSequenceExecution() ) { frames.insert( std::lower_bound( frames.begin(), frames.end(), frame ), frame ); } else { frames.push_back( frame ); } } } if ( taskHash != MurmurHash() ) { tasksToBatches[taskHash] = batch; } return batch; } } TaskBatchPtr batch = new TaskBatch( task ); currentBatches[hash] = batch; if ( taskHash != MurmurHash() ) { tasksToBatches[taskHash] = batch; } return batch; }
TaskBatchPtr acquireBatch( const TaskNode::Task &task ) { // See if we've previously visited this task, and therefore // have placed it in a batch already, which we can return // unchanged. The `taskToBatchMapHash` is used as the unique // identity of a task. MurmurHash taskToBatchMapHash = task.hash(); // Prevent identical tasks from different nodes from being // coalesced. taskToBatchMapHash.append( (uint64_t)task.node() ); if( task.hash() == IECore::MurmurHash() ) { // Prevent no-ops from coalescing into a single batch, as this // would break parallelism - see `DispatcherTest.testNoOpDoesntBreakFrameParallelism()` taskToBatchMapHash.append( contextHash( task.context() ) ); } const TaskToBatchMap::const_iterator it = m_tasksToBatches.find( taskToBatchMapHash ); if( it != m_tasksToBatches.end() ) { return it->second; } // We haven't seen this task before, so we need to find // an appropriate batch to put it in. This may be one of // our current batches, or we may need to make a new one // entirely if the current batch is full. const bool requiresSequenceExecution = task.plug()->requiresSequenceExecution(); TaskBatchPtr batch = nullptr; const MurmurHash batchMapHash = batchHash( task ); BatchMap::iterator bIt = m_currentBatches.find( batchMapHash ); if( bIt != m_currentBatches.end() ) { TaskBatchPtr candidateBatch = bIt->second; // Unfortunately we have to track batch size separately from `batch->frames().size()`, // because no-ops don't update `frames()`, but _do_ count towards batch size. IntDataPtr batchSizeData = candidateBatch->blindData()->member<IntData>( g_sizeBlindDataName ); const IntPlug *batchSizePlug = task.node()->dispatcherPlug()->getChild<const IntPlug>( g_batchSize ); const int batchSizeLimit = ( batchSizePlug ) ? batchSizePlug->getValue() : 1; if( requiresSequenceExecution || ( batchSizeData->readable() < batchSizeLimit ) ) { batch = candidateBatch; batchSizeData->writable()++; } } if( !batch ) { batch = new TaskBatch( task.plug(), task.context() ); batch->blindData()->writable()[g_sizeBlindDataName] = new IntData( 1 ); m_currentBatches[batchMapHash] = batch; } // Now we have an appropriate batch, update it to include // the frame for our task, and any other relevant information. if( task.hash() != MurmurHash() ) { float frame = task.context()->getFrame(); std::vector<float> &frames = batch->frames(); if( requiresSequenceExecution ) { frames.insert( std::lower_bound( frames.begin(), frames.end(), frame ), frame ); } else { frames.push_back( frame ); } } const BoolPlug *immediatePlug = task.node()->dispatcherPlug()->getChild<const BoolPlug>( g_immediatePlugName ); if( immediatePlug && immediatePlug->getValue() ) { /// \todo Should we be scoping a context for this, to allow the plug to /// have expressions on it? If so, should we be doing the same before /// calling requiresSequenceExecution()? Or should we instead require that /// they always be constant? batch->blindData()->writable()[g_immediateBlindDataName] = g_trueBoolData; } // Remember which batch we stored this task in, for // the next time someone asks for it. m_tasksToBatches[taskToBatchMapHash] = batch; return batch; }
TaskBatchPtr acquireBatch( const TaskNode::Task &task ) { // See if we've previously visited this task, and therefore // have placed it in a batch already, which we can return // unchanged. MurmurHash taskToBatchMapHash = task.hash(); taskToBatchMapHash.append( (uint64_t)task.node() ); if( task.hash() == MurmurHash() ) { // Make sure we don't coalesce all no-ops into a single // batch. See comments in batchHash(). taskToBatchMapHash.append( task.context()->getFrame() ); } const TaskToBatchMap::const_iterator it = m_tasksToBatches.find( taskToBatchMapHash ); if( it != m_tasksToBatches.end() ) { return it->second; } // We haven't seen this task before, so we need to find // an appropriate batch to put it in. This may be one of // our current batches, or we may need to make a new one // entirely. TaskBatchPtr batch = NULL; const MurmurHash batchMapHash = batchHash( task ); BatchMap::iterator bIt = m_currentBatches.find( batchMapHash ); if( bIt != m_currentBatches.end() ) { TaskBatchPtr candidateBatch = bIt->second; const IntPlug *batchSizePlug = task.node()->dispatcherPlug()->getChild<const IntPlug>( g_batchSize ); const size_t batchSize = ( batchSizePlug ) ? batchSizePlug->getValue() : 1; if( task.plug()->requiresSequenceExecution() || ( candidateBatch->frames().size() < batchSize ) ) { batch = candidateBatch; } } if( !batch ) { batch = new TaskBatch( task.plug(), task.context() ); m_currentBatches[batchMapHash] = batch; } // Now we have an appropriate batch, update it to include // the frame for our task, and any other relevant information. if( task.hash() != MurmurHash() ) { float frame = task.context()->getFrame(); std::vector<float> &frames = batch->frames(); if( std::find( frames.begin(), frames.end(), frame ) == frames.end() ) { if( task.plug()->requiresSequenceExecution() ) { frames.insert( std::lower_bound( frames.begin(), frames.end(), frame ), frame ); } else { frames.push_back( frame ); } } } const BoolPlug *immediatePlug = task.node()->dispatcherPlug()->getChild<const BoolPlug>( g_immediatePlugName ); if( immediatePlug && immediatePlug->getValue() ) { /// \todo Should we be scoping a context for this, to allow the plug to /// have expressions on it? If so, should we be doing the same before /// calling requiresSequenceExecution()? Or should we instead require that /// they always be constant? batch->blindData()->writable()[g_immediateBlindDataName] = g_trueBoolData; } // Remember which batch we stored this task in, for // the next time someone asks for it. m_tasksToBatches[taskToBatchMapHash] = batch; return batch; }