// // Copyright © 2017-2023 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #include "NeonBackend.hpp" #include "NeonBackendId.hpp" #include "NeonBackendModelContext.hpp" #include "NeonWorkloadFactory.hpp" #include "NeonLayerSupport.hpp" #include "NeonTensorHandleFactory.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace armnn { const BackendId& NeonBackend::GetIdStatic() { static const BackendId s_Id{NeonBackendId()}; return s_Id; } IBackendInternal::IMemoryManagerUniquePtr NeonBackend::CreateMemoryManager() const { return std::make_unique(std::make_unique(), BaseMemoryManager::MemoryAffinity::Offset); } IBackendInternal::IWorkloadFactoryPtr NeonBackend::CreateWorkloadFactory( const IBackendInternal::IMemoryManagerSharedPtr& memoryManager) const { return std::make_unique( PolymorphicPointerDowncast(memoryManager)); } IBackendInternal::IWorkloadFactoryPtr NeonBackend::CreateWorkloadFactory( const IBackendInternal::IMemoryManagerSharedPtr& memoryManager, const ModelOptions& modelOptions) const { return std::make_unique( PolymorphicPointerDowncast(memoryManager), CreateBackendSpecificModelContext(modelOptions)); } IBackendInternal::IWorkloadFactoryPtr NeonBackend::CreateWorkloadFactory( class TensorHandleFactoryRegistry& tensorHandleFactoryRegistry) const { auto memoryManager = std::make_shared(std::make_unique(), BaseMemoryManager::MemoryAffinity::Offset); tensorHandleFactoryRegistry.RegisterMemoryManager(memoryManager); auto factory = std::make_unique(memoryManager); // Register copy and import factory pair tensorHandleFactoryRegistry.RegisterCopyAndImportFactoryPair(factory->GetId(), factory->GetId()); // Register the factory tensorHandleFactoryRegistry.RegisterFactory(std::move(factory)); return std::make_unique( PolymorphicPointerDowncast(memoryManager)); } IBackendInternal::IWorkloadFactoryPtr NeonBackend::CreateWorkloadFactory( TensorHandleFactoryRegistry& tensorHandleFactoryRegistry, const ModelOptions& modelOptions) const { auto memoryManager = std::make_shared(std::make_unique(), BaseMemoryManager::MemoryAffinity::Offset); tensorHandleFactoryRegistry.RegisterMemoryManager(memoryManager); auto factory = std::make_unique(memoryManager); // Register copy and import factory pair tensorHandleFactoryRegistry.RegisterCopyAndImportFactoryPair(factory->GetId(), factory->GetId()); // Register the factory tensorHandleFactoryRegistry.RegisterFactory(std::move(factory)); return std::make_unique( PolymorphicPointerDowncast(memoryManager), CreateBackendSpecificModelContext(modelOptions)); } IBackendInternal::IBackendContextPtr NeonBackend::CreateBackendContext(const IRuntime::CreationOptions&) const { return IBackendContextPtr{}; } IBackendInternal::IBackendProfilingContextPtr NeonBackend::CreateBackendProfilingContext( const IRuntime::CreationOptions&, IBackendProfilingPtr&) { return IBackendProfilingContextPtr{}; } IBackendInternal::IBackendSpecificModelContextPtr NeonBackend::CreateBackendSpecificModelContext( const ModelOptions& modelOptions) const { return IBackendSpecificModelContextPtr{new NeonBackendModelContext{modelOptions}}; } IBackendInternal::ILayerSupportSharedPtr NeonBackend::GetLayerSupport() const { static ILayerSupportSharedPtr layerSupport { new NeonLayerSupport(IBackendInternal::IBackendSpecificModelContextPtr{}) }; return layerSupport; } IBackendInternal::ILayerSupportSharedPtr NeonBackend::GetLayerSupport(const ModelOptions& modelOptions) const { static ILayerSupportSharedPtr layerSupport { new NeonLayerSupport(CreateBackendSpecificModelContext(modelOptions)) }; return layerSupport; } OptimizationViews NeonBackend::OptimizeSubgraphView(const SubgraphView& subgraph, const ModelOptions& modelOptions) const { OptimizationViews optimizationViews(modelOptions); auto it = subgraph.endIConnectable(); std::map untouched; while (it != subgraph.beginIConnectable()) { --it; Layer& base = *(PolymorphicDowncast(*it)); untouched.insert({base.GetGuid(), &base}); } it = subgraph.endIConnectable(); while (it != subgraph.beginIConnectable()) { --it; Layer& base = *(PolymorphicDowncast(*it)); // Fuse activation into previous layer if supported by backend if ((base.GetType() == LayerType::DepthwiseConvolution2d || base.GetType() == LayerType::Convolution2d || base.GetType() == LayerType::BatchNormalization || base.GetType() == LayerType::FullyConnected || base.GetType() == LayerType::Addition || base.GetType() == LayerType::Multiplication || base.GetType() == LayerType::Subtraction || base.GetType() == LayerType::Division) && (base.GetAdditionalInformation() == nullptr)) { for (auto output = base.BeginOutputSlots(); output != base.EndOutputSlots(); ++output) { if (output->GetNumConnections() == 1) { for (auto&& childInput : output->GetConnections()) { if ((childInput->GetOwningLayer().GetType() == LayerType::Activation) && (checkDataTypeInputandOutput(childInput->GetOwningLayer()))) { Layer& child = childInput->GetOwningLayer(); auto* activationLayer = PolymorphicDowncast(&child); const std::string name = std::string("fused-") + child.GetName() + std::string("-into-") + base.GetName(); // Get params from activation layer ActivationDescriptor activationDesc = activationLayer->GetParameters(); if (base.GetType() == LayerType::Convolution2d) { Convolution2dLayer* baseLayer = PolymorphicDowncast(&base); Optional biases; if (baseLayer->GetParameters().m_BiasEnabled) { biases = baseLayer->GetInputSlot(2).GetConnectedOutputSlot()->GetTensorInfo(); } arm_compute::Status status = NeonConvolution2dWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetParameters(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), biases, false, &activationDesc); if (status) { FuseConvolution2dLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::DepthwiseConvolution2d) { DepthwiseConvolution2dLayer* baseLayer = PolymorphicDowncast(&base); Optional biases; if (baseLayer->GetParameters().m_BiasEnabled) { biases = baseLayer->GetInputSlot(2).GetConnectedOutputSlot()->GetTensorInfo(); } arm_compute::Status status = NeonDepthwiseConvolutionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetParameters(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), biases, &activationDesc); if (status) { FuseDepthwiseConvolution2dLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::FullyConnected) { FullyConnectedLayer* baseLayer = PolymorphicDowncast(&base); FullyConnectedDescriptor descriptor = baseLayer->GetParameters(); // As bias is optional only try to get TensorInfo from input if bias is enabled. Optional biases; if (descriptor.m_BiasEnabled) { biases = baseLayer->GetInputSlot(2).GetConnectedOutputSlot()->GetTensorInfo(); } arm_compute::Status status = NeonFullyConnectedWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), biases, baseLayer->GetParameters(), &activationDesc); if (status) { FuseFullyConnectedLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::BatchNormalization) { BatchNormalizationLayer* baseLayer = PolymorphicDowncast(&base); arm_compute::Status status = NeonBatchNormalizationValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->m_Mean->GetTensorInfo(), baseLayer->m_Variance->GetTensorInfo(), baseLayer->m_Beta->GetTensorInfo(), baseLayer->m_Gamma->GetTensorInfo(), baseLayer->GetParameters(), &activationDesc); if (status) { BatchNormalizationLayer* replacementLayer = FuseBatchNormalizationLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); replacementLayer->m_Beta = std::move(baseLayer->m_Beta); replacementLayer->m_Gamma = std::move(baseLayer->m_Gamma); replacementLayer->m_Mean = std::move(baseLayer->m_Mean); replacementLayer->m_Variance = std::move(baseLayer->m_Variance); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::Addition) { AdditionLayer* baseLayer = PolymorphicDowncast(&base); arm_compute::Status status = NeonAdditionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseAdditionLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::Division) { DivisionLayer* baseLayer = PolymorphicDowncast(&base); arm_compute::Status status = NeonDivisionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseDivisionLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::Multiplication) { MultiplicationLayer* baseLayer = PolymorphicDowncast(&base); arm_compute::Status status = NeonMultiplicationWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseMultiplicationLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::Subtraction) { SubtractionLayer* baseLayer = PolymorphicDowncast(&base); arm_compute::Status status = NeonSubtractionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseSubtractionLayer(optimizationViews, baseLayer, activationLayer, activationDesc, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (base.GetType() == LayerType::ElementwiseBinary) { ElementwiseBinaryLayer* baseLayer = PolymorphicDowncast(&base); if (baseLayer->GetParameters().m_Operation == BinaryOperation::Add) { arm_compute::Status status = NeonAdditionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseElementwiseBinaryLayer(optimizationViews, baseLayer, activationLayer, activationDesc, BinaryOperation::Add, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (baseLayer->GetParameters().m_Operation == BinaryOperation::Div) { arm_compute::Status status = NeonDivisionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseElementwiseBinaryLayer(optimizationViews, baseLayer, activationLayer, activationDesc, BinaryOperation::Div, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (baseLayer->GetParameters().m_Operation == BinaryOperation::Mul) { arm_compute::Status status = NeonMultiplicationWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseElementwiseBinaryLayer(optimizationViews, baseLayer, activationLayer, activationDesc, BinaryOperation::Mul, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } else if (baseLayer->GetParameters().m_Operation == BinaryOperation::Sub) { arm_compute::Status status = NeonSubtractionWorkloadValidate( baseLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), baseLayer->GetInputSlot(1).GetConnectedOutputSlot()->GetTensorInfo(), activationLayer->GetInputSlot(0).GetConnectedOutputSlot()->GetTensorInfo(), &activationDesc); if (status) { FuseElementwiseBinaryLayer(optimizationViews, baseLayer, activationLayer, activationDesc, BinaryOperation::Sub, name); untouched.erase(baseLayer->GetGuid()); untouched.erase(activationLayer->GetGuid()); } } // No fusion available for other BinaryOperations } } } } } } // Separate reduce layer with multiple axes into multiple reduce layers with 1 axis. if (base.GetType() == LayerType::Reduce) { ReduceLayer* baseLayer = PolymorphicDowncast(&base); ReduceDescriptor reduceDescriptor = baseLayer->GetParameters(); if (!reduceDescriptor.m_vAxis.empty() && reduceDescriptor.m_vAxis.size() > 1) { // Add new layers to the graph and connect them. std::vector layers = ChainReduceLayers(optimizationViews, baseLayer, reduceDescriptor); // Replace existing baselayer with new subgraph. ReplaceLayers(optimizationViews, baseLayer, layers); untouched.erase(baseLayer->GetGuid()); } } } if (optimizationViews.GetSubstitutions().empty()) { optimizationViews.AddUntouchedSubgraph(SubgraphView(subgraph)); } else { ReportUntouchedLayers(optimizationViews, untouched); } return optimizationViews; } std::vector NeonBackend::GetHandleFactoryPreferences() const { return std::vector() = { NeonTensorHandleFactory::GetIdStatic() }; } void NeonBackend::RegisterTensorHandleFactories(class TensorHandleFactoryRegistry& registry) { auto memoryManager = std::make_shared(std::make_unique(), BaseMemoryManager::MemoryAffinity::Offset); registry.RegisterMemoryManager(memoryManager); auto factory = std::make_unique(memoryManager); // Register copy and import factory pair registry.RegisterCopyAndImportFactoryPair(factory->GetId(), factory->GetId()); // Register the factory registry.RegisterFactory(std::move(factory)); } std::unique_ptr NeonBackend::GetDefaultAllocator() const { return std::make_unique(); } } // namespace armnn