// // Copyright © 2017,2022 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #include "NeonConvolution2dWorkload.hpp" #include #include #include #include #include #include #include #include namespace armnn { using namespace armcomputetensorutils; arm_compute::Status NeonConvolution2dWorkloadValidate(const TensorInfo& input, const TensorInfo& output, const Convolution2dDescriptor& descriptor, const TensorInfo& weights, const Optional& biases, bool isFastMathEnabled, const ActivationDescriptor* activationDescriptor) { const arm_compute::TensorInfo aclInputInfo = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout); const arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout); arm_compute::TensorInfo aclWeightsInfo = BuildArmComputeTensorInfo(weights, descriptor.m_DataLayout); aclWeightsInfo.set_are_values_constant(weights.IsConstant()); const arm_compute::Size2D aclDilationInfo = BuildArmComputeSize2D(descriptor.m_DilationX, descriptor.m_DilationY); arm_compute::TensorInfo aclBiasesInfo; arm_compute::TensorInfo *optionalAclBiasesInfo = nullptr; if (descriptor.m_BiasEnabled) { ARMNN_ASSERT(biases.has_value()); // Same for bias as weights. We don't currently support non const. if (!biases.value().IsConstant()) { return arm_compute::Status{arm_compute::ErrorCode::RUNTIME_ERROR, "ArmNN NeonConvolution2dWorkload does not support non constant bias."}; } aclBiasesInfo = BuildArmComputeTensorInfo(biases.value(), descriptor.m_DataLayout); aclBiasesInfo.set_are_values_constant(biases.value().IsConstant()); optionalAclBiasesInfo = &aclBiasesInfo; } arm_compute::PadStrideInfo layerInfo = BuildArmComputePadStrideInfo(descriptor); const arm_compute::ActivationLayerInfo activationInfo = ConvertActivationDescriptorToAclActivationLayerInfo( activationDescriptor); return arm_compute::NEConvolutionLayer::validate(&aclInputInfo, &aclWeightsInfo, optionalAclBiasesInfo, &aclOutputInfo, layerInfo, arm_compute::WeightsInfo(), aclDilationInfo, activationInfo, isFastMathEnabled); } NeonConvolution2dWorkload::NeonConvolution2dWorkload( const Convolution2dQueueDescriptor& descriptor, const WorkloadInfo& info, std::shared_ptr& memoryManager, const bool isFastMathEnabled) : NeonBaseWorkload(descriptor, info) { using arm_compute::NEConvolutionLayer; uint32_t numInputs = m_Data.m_Parameters.m_BiasEnabled ? 3: 2; m_Data.ValidateInputsOutputs("NeonConvolution2dWorkload", numInputs, 1); arm_compute::ITensor& input = PolymorphicDowncast(m_Data.m_Inputs[0])->GetTensor(); arm_compute::ITensor& output = PolymorphicDowncast(m_Data.m_Outputs[0])->GetTensor(); arm_compute::DataLayout aclDataLayout = ConvertDataLayout(m_Data.m_Parameters.m_DataLayout); input.info()->set_data_layout(aclDataLayout); output.info()->set_data_layout(aclDataLayout); m_KernelTensor = std::make_unique(); BuildArmComputeTensor(*m_KernelTensor, info.m_InputTensorInfos[1], m_Data.m_Parameters.m_DataLayout); if (m_Data.m_Parameters.m_BiasEnabled) { m_BiasTensor = std::make_unique(); BuildArmComputeTensor(*m_BiasTensor, info.m_InputTensorInfos[2], m_Data.m_Parameters.m_DataLayout); } arm_compute::PadStrideInfo padStrideInfo = BuildArmComputePadStrideInfo(m_Data.m_Parameters); const arm_compute::Size2D aclDilationInfo = BuildArmComputeSize2D(m_Data.m_Parameters.m_DilationX, m_Data.m_Parameters.m_DilationY); const arm_compute::ActivationLayerInfo activationInfo = ConvertAdditionalInfoToAclActivationLayerInfo(descriptor); auto convolutionLayer = std::make_unique(memoryManager); convolutionLayer->configure(&input, m_KernelTensor.get(), m_BiasTensor.get(), &output, padStrideInfo, arm_compute::WeightsInfo(), aclDilationInfo, activationInfo, isFastMathEnabled); m_ConvolutionMethod = convolutionLayer->get_convolution_method(input.info(), m_KernelTensor->info(), output.info(), padStrideInfo, arm_compute::WeightsInfo(), aclDilationInfo, activationInfo, isFastMathEnabled); // Add details for profiling output WorkloadInfo detailsInfo; detailsInfo.m_InputTensorInfos = info.m_InputTensorInfos; detailsInfo.m_OutputTensorInfos = info.m_OutputTensorInfos; detailsInfo.m_WeightsTensorInfo = armnn::Optional(info.m_InputTensorInfos[1]); detailsInfo.m_ConvolutionMethod = armnn::Optional(GetConvolutionMethodString(m_ConvolutionMethod)); if (descriptor.m_Parameters.m_BiasEnabled) { detailsInfo.m_BiasTensorInfo = armnn::Optional(info.m_InputTensorInfos[2]); } // Report Profiling Details ARMNN_REPORT_PROFILING_WORKLOAD_DESC("NeonConvolution2dWorkload_Construct", descriptor.m_Parameters, detailsInfo, GetGuid()); m_ConvolutionLayer.reset(convolutionLayer.release()); ARMNN_ASSERT(m_ConvolutionLayer); m_KernelTensorInfo = info.m_InputTensorInfos[1]; if (m_Data.m_Parameters.m_BiasEnabled) { m_BiasTensorInfo = info.m_InputTensorInfos[2]; } } void NeonConvolution2dWorkload::Execute() const { ARMNN_SCOPED_PROFILING_EVENT_NEON_GUID("NeonConvolution2dWorkload_Execute", this->GetGuid()); // The constant tensors may not be fully in place until the workload is Executed if (!prepared) { InitializeArmComputeTensorData(*m_KernelTensor, m_KernelTensorInfo, m_Data.m_Inputs[1]); if (m_Data.m_Parameters.m_BiasEnabled) { InitializeArmComputeTensorData(*m_BiasTensor, m_BiasTensorInfo, m_Data.m_Inputs[2]); } m_ConvolutionLayer->prepare(); FreeTensorIfUnused(m_KernelTensor); FreeTensorIfUnused(m_BiasTensor); prepared = true; } m_ConvolutionLayer->run(); } arm_compute::ConvolutionMethod NeonConvolution2dWorkload::GetConvolutionMethod() const { return m_ConvolutionMethod; } } //namespace armnn