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

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

 #include "NeonNormalizationFloatWorkload.hpp"

 #include "NeonWorkloadUtils.hpp"
 #include <aclCommon/ArmComputeUtils.hpp>
 #include <aclCommon/ArmComputeTensorUtils.hpp>
 #include <armnn/utility/PolymorphicDowncast.hpp>

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

 using namespace armnn::armcomputetensorutils;

 namespace armnn
 {

 namespace
 {

 bool IsNeonNormalizationDescriptorSupported(const NormalizationDescriptor& parameters,
                                             Optional<std::string&> reasonIfUnsupported)
 {
     if (parameters.m_NormMethodType != NormalizationAlgorithmMethod::LocalBrightness)
     {
         if (reasonIfUnsupported)
         {
             reasonIfUnsupported.value() = "Unsupported normalisation method type, only LocalBrightness is supported";
         }
         return false;
     }
     if (parameters.m_NormSize % 2 == 0)
     {
         if (reasonIfUnsupported)
         {
             reasonIfUnsupported.value() = "Normalization size must be an odd number.";
         }
         return false;
     }

     return true;
 }

 } // anonymous namespace

 arm_compute::Status NeonNormalizationWorkloadValidate(const TensorInfo& input,
                                                       const TensorInfo& output,
                                                       const NormalizationDescriptor& descriptor)
 {
     const arm_compute::TensorInfo aclInput = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
     const arm_compute::TensorInfo aclOutput = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);

     arm_compute::NormalizationLayerInfo normalizationInfo = BuildArmComputeNormalizationLayerInfo(descriptor);

     return arm_compute::NENormalizationLayer::validate(&aclInput, &aclOutput, normalizationInfo);
 }

 NeonNormalizationFloatWorkload::NeonNormalizationFloatWorkload(const NormalizationQueueDescriptor& descriptor,
                                                    const WorkloadInfo& info,
                                                    std::shared_ptr<arm_compute::MemoryManagerOnDemand>& memoryManager)
     : FloatWorkload<NormalizationQueueDescriptor>(descriptor, info)
 {
     m_Data.ValidateInputsOutputs("NeonNormalizationFloatWorkload", 1, 1);
     std::string reasonIfUnsupported;
     if (!IsNeonNormalizationDescriptorSupported(m_Data.m_Parameters, Optional<std::string&>(reasonIfUnsupported)))
     {
         throw UnimplementedException(reasonIfUnsupported);
     }

     // Input and output tensors have to have the same dimensionality.
     if (info.m_InputTensorInfos[0].GetShape()[1] != info.m_OutputTensorInfos[0].GetShape()[1]
         || info.m_InputTensorInfos[0].GetShape()[0] != info.m_OutputTensorInfos[0].GetShape()[0]
         || info.m_InputTensorInfos[0].GetShape()[3] != info.m_OutputTensorInfos[0].GetShape()[3]
         || info.m_InputTensorInfos[0].GetShape()[2] != info.m_OutputTensorInfos[0].GetShape()[2])
     {
         throw InvalidArgumentException("Normalization requires input and output tensors to have equal dimensionality.");
     }

     arm_compute::ITensor& input = PolymorphicDowncast<IAclTensorHandle*>(m_Data.m_Inputs[0])->GetTensor();
     arm_compute::ITensor& output = PolymorphicDowncast<IAclTensorHandle*>(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);

     const arm_compute::NormType normType =
         ConvertNormalizationAlgorithmChannelToAclNormType(m_Data.m_Parameters.m_NormChannelType);
     arm_compute::NormalizationLayerInfo normalizationInfo(normType,
                                                           m_Data.m_Parameters.m_NormSize,
                                                           m_Data.m_Parameters.m_Alpha,
                                                           m_Data.m_Parameters.m_Beta,
                                                           m_Data.m_Parameters.m_K,
                                                           false);
     auto layer = std::make_unique<arm_compute::NENormalizationLayer>(memoryManager);
     layer->configure(&input, &output, normalizationInfo);
     m_NormalizationLayer.reset(layer.release());
 }

 void NeonNormalizationFloatWorkload::Execute() const
 {
     ARMNN_SCOPED_PROFILING_EVENT_NEON("NeonNormalizationFloatWorkload_Execute");
     m_NormalizationLayer->run();
 }

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

	#include "NeonNormalizationFloatWorkload.hpp"

	#include "NeonWorkloadUtils.hpp"
	#include <aclCommon/ArmComputeUtils.hpp>
	#include <aclCommon/ArmComputeTensorUtils.hpp>
	#include <armnn/utility/PolymorphicDowncast.hpp>

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

	using namespace armnn::armcomputetensorutils;

	namespace armnn
	{

	namespace
	{

	bool IsNeonNormalizationDescriptorSupported(const NormalizationDescriptor& parameters,
	Optional<std::string&> reasonIfUnsupported)
	{
	if (parameters.m_NormMethodType != NormalizationAlgorithmMethod::LocalBrightness)
	{
	if (reasonIfUnsupported)
	{
	reasonIfUnsupported.value() = "Unsupported normalisation method type, only LocalBrightness is supported";
	}
	return false;
	}
	if (parameters.m_NormSize % 2 == 0)
	{
	if (reasonIfUnsupported)
	{
	reasonIfUnsupported.value() = "Normalization size must be an odd number.";
	}
	return false;
	}

	return true;
	}

	} // anonymous namespace

	arm_compute::Status NeonNormalizationWorkloadValidate(const TensorInfo& input,
	const TensorInfo& output,
	const NormalizationDescriptor& descriptor)
	{
	const arm_compute::TensorInfo aclInput = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
	const arm_compute::TensorInfo aclOutput = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);

	arm_compute::NormalizationLayerInfo normalizationInfo = BuildArmComputeNormalizationLayerInfo(descriptor);

	return arm_compute::NENormalizationLayer::validate(&aclInput, &aclOutput, normalizationInfo);
	}

	NeonNormalizationFloatWorkload::NeonNormalizationFloatWorkload(const NormalizationQueueDescriptor& descriptor,
	const WorkloadInfo& info,
	std::shared_ptr<arm_compute::MemoryManagerOnDemand>& memoryManager)
	: FloatWorkload<NormalizationQueueDescriptor>(descriptor, info)
	{
	m_Data.ValidateInputsOutputs("NeonNormalizationFloatWorkload", 1, 1);
	std::string reasonIfUnsupported;
	if (!IsNeonNormalizationDescriptorSupported(m_Data.m_Parameters, Optional<std::string&>(reasonIfUnsupported)))
	{
	throw UnimplementedException(reasonIfUnsupported);
	}

	// Input and output tensors have to have the same dimensionality.
	if (info.m_InputTensorInfos[0].GetShape()[1] != info.m_OutputTensorInfos[0].GetShape()[1]
	\|\| info.m_InputTensorInfos[0].GetShape()[0] != info.m_OutputTensorInfos[0].GetShape()[0]
	\|\| info.m_InputTensorInfos[0].GetShape()[3] != info.m_OutputTensorInfos[0].GetShape()[3]
	\|\| info.m_InputTensorInfos[0].GetShape()[2] != info.m_OutputTensorInfos[0].GetShape()[2])
	{
	throw InvalidArgumentException("Normalization requires input and output tensors to have equal dimensionality.");
	}

	arm_compute::ITensor& input = PolymorphicDowncast<IAclTensorHandle*>(m_Data.m_Inputs[0])->GetTensor();
	arm_compute::ITensor& output = PolymorphicDowncast<IAclTensorHandle*>(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);

	const arm_compute::NormType normType =
	ConvertNormalizationAlgorithmChannelToAclNormType(m_Data.m_Parameters.m_NormChannelType);
	arm_compute::NormalizationLayerInfo normalizationInfo(normType,
	m_Data.m_Parameters.m_NormSize,
	m_Data.m_Parameters.m_Alpha,
	m_Data.m_Parameters.m_Beta,
	m_Data.m_Parameters.m_K,
	false);
	auto layer = std::make_unique<arm_compute::NENormalizationLayer>(memoryManager);
	layer->configure(&input, &output, normalizationInfo);
	m_NormalizationLayer.reset(layer.release());
	}

	void NeonNormalizationFloatWorkload::Execute() const
	{
	ARMNN_SCOPED_PROFILING_EVENT_NEON("NeonNormalizationFloatWorkload_Execute");
	m_NormalizationLayer->run();
	}

	} //namespace armnn