src/backends/neon/workloads/NeonDepthwiseConvolutionWorkload.cpp - ml/armnn - Gitiles

 //
 // Copyright © 2017 Arm Ltd. All rights reserved.
 // SPDX-License-Identifier: MIT
 //

 #include "NeonDepthwiseConvolutionWorkload.hpp"

 #include "NeonWorkloadUtils.hpp"

 #include <DataLayoutIndexed.hpp>
 #include <aclCommon/ArmComputeTensorUtils.hpp>
 #include <neon/NeonLayerSupport.hpp>
 #include <backendsCommon/CpuTensorHandle.hpp>
 #include <backendsCommon/WorkloadUtils.hpp>

 #include <arm_compute/runtime/NEON/functions/NEDepthwiseConvolutionLayer.h>

 using namespace armnnUtils;

 namespace armnn
 {

 using namespace armcomputetensorutils;

 arm_compute::Status NeonDepthwiseConvolutionWorkloadValidate(const TensorInfo& input,
                                                              const TensorInfo& output,
                                                              const DepthwiseConvolution2dDescriptor& descriptor,
                                                              const TensorInfo& weights,
                                                              const Optional<TensorInfo>& biases)
 {
     const arm_compute::TensorInfo aclInputInfo  = BuildArmComputeTensorInfo(input,  descriptor.m_DataLayout);
     const arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);

     // ArmNN's weight format is [ M, I, H, W ]
     const unsigned int aclDepthMultiplier = weights.GetShape()[0];

     // Convert the weight format from ArmNN's [ M, I, H, W ] (does NOT depend on the data layout) to either
     // [ 1, H, W, I * M ] (if NHWC) or [ 1, I * M, H, W ] (if NCHW), as required by the compute library
     TensorInfo weightsPermuted = ConvertWeightTensorInfoFromArmnnToAcl(weights, descriptor.m_DataLayout);

     // Convert the weights into the compute library format
     const arm_compute::TensorInfo aclWeightsInfo = BuildArmComputeTensorInfo(weightsPermuted, descriptor.m_DataLayout);

     arm_compute::TensorInfo aclBiasesInfo;
     arm_compute::TensorInfo *optionalAclBiasesInfo = nullptr;

     if (descriptor.m_BiasEnabled)
     {
         BOOST_ASSERT(biases.has_value());

         aclBiasesInfo = BuildArmComputeTensorInfo(biases.value(), descriptor.m_DataLayout);
         optionalAclBiasesInfo = &aclBiasesInfo;
     }

     arm_compute::PadStrideInfo aclPadStrideInfo = BuildArmComputePadStrideInfo(descriptor);
     const arm_compute::Size2D aclDilationInfo = BuildArmComputeSize2D(
             descriptor.m_DilationX,descriptor.m_DilationY);

     return arm_compute::NEDepthwiseConvolutionLayer::validate(&aclInputInfo,
                                                               &aclWeightsInfo,
                                                               optionalAclBiasesInfo,
                                                               &aclOutputInfo,
                                                               aclPadStrideInfo,
                                                               aclDepthMultiplier,
                                                               arm_compute::ActivationLayerInfo(),
                                                               aclDilationInfo);
 }

 NeonDepthwiseConvolutionWorkload::NeonDepthwiseConvolutionWorkload(
     const DepthwiseConvolution2dQueueDescriptor& descriptor,
     const WorkloadInfo& info)
     : BaseWorkload<DepthwiseConvolution2dQueueDescriptor>(descriptor, info)
 {
     // ArmNN's weight format is [ M, I, H, W ]
     auto& weightInfo = m_Data.m_Weight->GetTensorInfo();

     // Allocate a buffer for the swizzling of the weight tensor
     std::unique_ptr<unsigned char[]> permuteBuffer(new unsigned char[m_Data.m_Weight->GetTensorInfo().GetNumBytes()]);

     // Convert the weight format from ArmNN's [ M, I, H, W ] (does NOT depend on the data layout) to either
     // [ 1, H, W, I * M ] (if NHWC) or [ 1, I * M, H, W ] (if NCHW), as required by the compute library
     ConstTensor weightPermuted = ConvertWeightTensorFromArmnnToAcl(m_Data.m_Weight,
                                                                    m_Data.m_Parameters.m_DataLayout,
                                                                    permuteBuffer.get());

     // Convert the weights into the compute library format
     m_KernelTensor = std::make_unique<arm_compute::Tensor>();
     BuildArmComputeTensor(*m_KernelTensor, weightPermuted.GetInfo(), m_Data.m_Parameters.m_DataLayout);

     if (m_Data.m_Parameters.m_BiasEnabled)
     {
         m_BiasTensor = std::make_unique<arm_compute::Tensor>();
         BuildArmComputeTensor(*m_BiasTensor, m_Data.m_Bias->GetTensorInfo(), m_Data.m_Parameters.m_DataLayout);
     }

     arm_compute::PadStrideInfo padStrideInfo(m_Data.m_Parameters.m_StrideX,
                                              m_Data.m_Parameters.m_StrideY,
                                              m_Data.m_Parameters.m_PadLeft,
                                              m_Data.m_Parameters.m_PadRight,
                                              m_Data.m_Parameters.m_PadTop,
                                              m_Data.m_Parameters.m_PadBottom,
                                              arm_compute::DimensionRoundingType::FLOOR);


     const arm_compute::Size2D aclDilationInfo = BuildArmComputeSize2D(
                 m_Data.m_Parameters.m_DilationX, m_Data.m_Parameters.m_DilationY);

     m_Data.ValidateInputsOutputs("NeonDepthwiseConvolutionWorkload", 1, 1);

     INeonTensorHandle* inputTensorHandle  = static_cast<INeonTensorHandle*>(m_Data.m_Inputs[0]);
     INeonTensorHandle* outputTensorHandle = static_cast<INeonTensorHandle*>(m_Data.m_Outputs[0]);

     arm_compute::ITensor& input  = inputTensorHandle->GetTensor();
     arm_compute::ITensor& output = outputTensorHandle->GetTensor();

     arm_compute::DataLayout aclDataLayout = ConvertDataLayout(m_Data.m_Parameters.m_DataLayout);
     input.info()->set_data_layout(aclDataLayout);
     output.info()->set_data_layout(aclDataLayout);

     // Get the depth multiplier
     const unsigned int depthMultiplier = weightInfo.GetShape()[0];

     // Check for optimisation opportunities.
     bool use3x3Optimisation = (weightInfo.GetShape()[2] == 3) && (weightInfo.GetShape()[3] == 3);
     if (use3x3Optimisation)
     {
         m_pDepthwiseConvolutionLayer = std::make_unique<arm_compute::NEDepthwiseConvolutionLayer3x3>();
         static_cast<arm_compute::NEDepthwiseConvolutionLayer3x3*>(
             m_pDepthwiseConvolutionLayer.get())->configure(&input,
                                                            m_KernelTensor.get(),
                                                            m_BiasTensor.get(),
                                                            &output,
                                                            padStrideInfo,
                                                            depthMultiplier,
                                                            arm_compute::ActivationLayerInfo(),
                                                            aclDilationInfo);
     }
     else
     {
         m_pDepthwiseConvolutionLayer = std::make_unique<arm_compute::NEDepthwiseConvolutionLayer>();
         static_cast<arm_compute::NEDepthwiseConvolutionLayer*>(
             m_pDepthwiseConvolutionLayer.get())->configure(&input,
                                                            m_KernelTensor.get(),
                                                            m_BiasTensor.get(),
                                                            &output,
                                                            padStrideInfo,
                                                            depthMultiplier,
                                                            arm_compute::ActivationLayerInfo(),
                                                            aclDilationInfo);
     }

     BOOST_ASSERT(m_pDepthwiseConvolutionLayer);

     ScopedCpuTensorHandle weightsPermutedHandle(weightPermuted);
     InitializeArmComputeTensorData(*m_KernelTensor, &weightsPermutedHandle);

     if (m_Data.m_Parameters.m_BiasEnabled)
     {
         InitializeArmComputeTensorData(*m_BiasTensor, m_Data.m_Bias);
     }

     m_pDepthwiseConvolutionLayer->prepare();
     FreeUnusedTensors();
 }

 void NeonDepthwiseConvolutionWorkload::Execute() const
 {
     ARMNN_SCOPED_PROFILING_EVENT_NEON("NeonDepthwiseConvolutionWorkload_Execute");
     BOOST_ASSERT(m_pDepthwiseConvolutionLayer);

     m_pDepthwiseConvolutionLayer->run();
 }

 void NeonDepthwiseConvolutionWorkload::FreeUnusedTensors()
 {
     FreeTensorIfUnused(m_KernelTensor);
     FreeTensorIfUnused(m_BiasTensor);
 }

 } //namespace armnn
	//
	// Copyright © 2017 Arm Ltd. All rights reserved.
	// SPDX-License-Identifier: MIT
	//

	#include "NeonDepthwiseConvolutionWorkload.hpp"

	#include "NeonWorkloadUtils.hpp"

	#include <DataLayoutIndexed.hpp>
	#include <aclCommon/ArmComputeTensorUtils.hpp>
	#include <neon/NeonLayerSupport.hpp>
	#include <backendsCommon/CpuTensorHandle.hpp>
	#include <backendsCommon/WorkloadUtils.hpp>

	#include <arm_compute/runtime/NEON/functions/NEDepthwiseConvolutionLayer.h>

	using namespace armnnUtils;

	namespace armnn
	{

	using namespace armcomputetensorutils;

	arm_compute::Status NeonDepthwiseConvolutionWorkloadValidate(const TensorInfo& input,
	const TensorInfo& output,
	const DepthwiseConvolution2dDescriptor& descriptor,
	const TensorInfo& weights,
	const Optional<TensorInfo>& biases)
	{
	const arm_compute::TensorInfo aclInputInfo = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
	const arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);

	// ArmNN's weight format is [ M, I, H, W ]
	const unsigned int aclDepthMultiplier = weights.GetShape()[0];

	// Convert the weight format from ArmNN's [ M, I, H, W ] (does NOT depend on the data layout) to either
	// [ 1, H, W, I * M ] (if NHWC) or [ 1, I * M, H, W ] (if NCHW), as required by the compute library
	TensorInfo weightsPermuted = ConvertWeightTensorInfoFromArmnnToAcl(weights, descriptor.m_DataLayout);

	// Convert the weights into the compute library format
	const arm_compute::TensorInfo aclWeightsInfo = BuildArmComputeTensorInfo(weightsPermuted, descriptor.m_DataLayout);

	arm_compute::TensorInfo aclBiasesInfo;
	arm_compute::TensorInfo *optionalAclBiasesInfo = nullptr;

	if (descriptor.m_BiasEnabled)
	{
	BOOST_ASSERT(biases.has_value());

	aclBiasesInfo = BuildArmComputeTensorInfo(biases.value(), descriptor.m_DataLayout);
	optionalAclBiasesInfo = &aclBiasesInfo;
	}

	arm_compute::PadStrideInfo aclPadStrideInfo = BuildArmComputePadStrideInfo(descriptor);
	const arm_compute::Size2D aclDilationInfo = BuildArmComputeSize2D(
	descriptor.m_DilationX,descriptor.m_DilationY);

	return arm_compute::NEDepthwiseConvolutionLayer::validate(&aclInputInfo,
	&aclWeightsInfo,
	optionalAclBiasesInfo,
	&aclOutputInfo,
	aclPadStrideInfo,
	aclDepthMultiplier,
	arm_compute::ActivationLayerInfo(),
	aclDilationInfo);
	}

	NeonDepthwiseConvolutionWorkload::NeonDepthwiseConvolutionWorkload(
	const DepthwiseConvolution2dQueueDescriptor& descriptor,
	const WorkloadInfo& info)
	: BaseWorkload<DepthwiseConvolution2dQueueDescriptor>(descriptor, info)
	{
	// ArmNN's weight format is [ M, I, H, W ]
	auto& weightInfo = m_Data.m_Weight->GetTensorInfo();

	// Allocate a buffer for the swizzling of the weight tensor
	std::unique_ptr<unsigned char[]> permuteBuffer(new unsigned char[m_Data.m_Weight->GetTensorInfo().GetNumBytes()]);

	// Convert the weight format from ArmNN's [ M, I, H, W ] (does NOT depend on the data layout) to either
	// [ 1, H, W, I * M ] (if NHWC) or [ 1, I * M, H, W ] (if NCHW), as required by the compute library
	ConstTensor weightPermuted = ConvertWeightTensorFromArmnnToAcl(m_Data.m_Weight,
	m_Data.m_Parameters.m_DataLayout,
	permuteBuffer.get());

	// Convert the weights into the compute library format
	m_KernelTensor = std::make_unique<arm_compute::Tensor>();
	BuildArmComputeTensor(*m_KernelTensor, weightPermuted.GetInfo(), m_Data.m_Parameters.m_DataLayout);

	if (m_Data.m_Parameters.m_BiasEnabled)
	{
	m_BiasTensor = std::make_unique<arm_compute::Tensor>();
	BuildArmComputeTensor(*m_BiasTensor, m_Data.m_Bias->GetTensorInfo(), m_Data.m_Parameters.m_DataLayout);
	}

	arm_compute::PadStrideInfo padStrideInfo(m_Data.m_Parameters.m_StrideX,
	m_Data.m_Parameters.m_StrideY,
	m_Data.m_Parameters.m_PadLeft,
	m_Data.m_Parameters.m_PadRight,
	m_Data.m_Parameters.m_PadTop,
	m_Data.m_Parameters.m_PadBottom,
	arm_compute::DimensionRoundingType::FLOOR);


	const arm_compute::Size2D aclDilationInfo = BuildArmComputeSize2D(
	m_Data.m_Parameters.m_DilationX, m_Data.m_Parameters.m_DilationY);

	m_Data.ValidateInputsOutputs("NeonDepthwiseConvolutionWorkload", 1, 1);

	INeonTensorHandle* inputTensorHandle = static_cast<INeonTensorHandle*>(m_Data.m_Inputs[0]);
	INeonTensorHandle* outputTensorHandle = static_cast<INeonTensorHandle*>(m_Data.m_Outputs[0]);

	arm_compute::ITensor& input = inputTensorHandle->GetTensor();
	arm_compute::ITensor& output = outputTensorHandle->GetTensor();

	arm_compute::DataLayout aclDataLayout = ConvertDataLayout(m_Data.m_Parameters.m_DataLayout);
	input.info()->set_data_layout(aclDataLayout);
	output.info()->set_data_layout(aclDataLayout);

	// Get the depth multiplier
	const unsigned int depthMultiplier = weightInfo.GetShape()[0];

	// Check for optimisation opportunities.
	bool use3x3Optimisation = (weightInfo.GetShape()[2] == 3) && (weightInfo.GetShape()[3] == 3);
	if (use3x3Optimisation)
	{
	m_pDepthwiseConvolutionLayer = std::make_unique<arm_compute::NEDepthwiseConvolutionLayer3x3>();
	static_cast<arm_compute::NEDepthwiseConvolutionLayer3x3*>(
	m_pDepthwiseConvolutionLayer.get())->configure(&input,
	m_KernelTensor.get(),
	m_BiasTensor.get(),
	&output,
	padStrideInfo,
	depthMultiplier,
	arm_compute::ActivationLayerInfo(),
	aclDilationInfo);
	}
	else
	{
	m_pDepthwiseConvolutionLayer = std::make_unique<arm_compute::NEDepthwiseConvolutionLayer>();
	static_cast<arm_compute::NEDepthwiseConvolutionLayer*>(
	m_pDepthwiseConvolutionLayer.get())->configure(&input,
	m_KernelTensor.get(),
	m_BiasTensor.get(),
	&output,
	padStrideInfo,
	depthMultiplier,
	arm_compute::ActivationLayerInfo(),
	aclDilationInfo);
	}

	BOOST_ASSERT(m_pDepthwiseConvolutionLayer);

	ScopedCpuTensorHandle weightsPermutedHandle(weightPermuted);
	InitializeArmComputeTensorData(*m_KernelTensor, &weightsPermutedHandle);

	if (m_Data.m_Parameters.m_BiasEnabled)
	{
	InitializeArmComputeTensorData(*m_BiasTensor, m_Data.m_Bias);
	}

	m_pDepthwiseConvolutionLayer->prepare();
	FreeUnusedTensors();
	}

	void NeonDepthwiseConvolutionWorkload::Execute() const
	{
	ARMNN_SCOPED_PROFILING_EVENT_NEON("NeonDepthwiseConvolutionWorkload_Execute");
	BOOST_ASSERT(m_pDepthwiseConvolutionLayer);

	m_pDepthwiseConvolutionLayer->run();
	}

	void NeonDepthwiseConvolutionWorkload::FreeUnusedTensors()
	{
	FreeTensorIfUnused(m_KernelTensor);
	FreeTensorIfUnused(m_BiasTensor);
	}

	} //namespace armnn