src/backends/neon/workloads/NeonPooling3dWorkload.cpp - ml/armnn - Gitiles

 //
 // Copyright © 2022-2023 Arm Ltd and Contributors. All rights reserved.
 // SPDX-License-Identifier: MIT
 //
 #include "NeonPooling3dWorkload.hpp"
 #include "NeonWorkloadUtils.hpp"
 #include <neon/NeonLayerSupport.hpp>
 #include <neon/NeonTensorHandle.hpp>
 #include <aclCommon/ArmComputeUtils.hpp>
 #include <aclCommon/ArmComputeTensorUtils.hpp>

 namespace armnn
 {
     using namespace armcomputetensorutils;
     arm_compute::Status NeonPooling3dWorkloadValidate(const TensorInfo& input,
                                                       const TensorInfo& output,
                                                       const Pooling3dDescriptor& descriptor)
     {
         const arm_compute::TensorInfo aclInputInfo = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
         const arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);
         arm_compute::Pooling3dLayerInfo layerInfo = BuildArmComputePooling3dLayerInfo(descriptor);
         return arm_compute::NEPooling3dLayer::validate(&aclInputInfo, &aclOutputInfo, layerInfo);
     }

     NeonPooling3dWorkload::NeonPooling3dWorkload( const Pooling3dQueueDescriptor& descriptor,
                                                   const WorkloadInfo& info)
             : NeonBaseWorkload<Pooling3dQueueDescriptor>(descriptor, info)
     {
         // Report Profiling Details
         ARMNN_REPORT_PROFILING_WORKLOAD_DESC("NeonPooling3dWorkload_Construct",
                                              descriptor.m_Parameters,
                                              info,
                                              this->GetGuid());

         m_Data.ValidateInputsOutputs("NeonPooling3dWorkload", 1, 1);

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

         // flag to use wider accumulators (32 bit instead of 16 for FP16) to improve accuracy
         // enable fp_mixed_precision for the the FP16 cases that
         // accumulation reaches a limit beyond which there is no more increment of the value
         bool fpMixedPrecision = false;

         arm_compute::Pooling3dLayerInfo layerInfo = BuildArmComputePooling3dLayerInfo(m_Data.m_Parameters,
                                                                                       fpMixedPrecision);
         {
             ARMNN_SCOPED_PROFILING_EVENT(Compute::Undefined, "NeonPooling3dWorkload_configure");

             auto layer = std::make_unique<arm_compute::NEPooling3dLayer>();
             layer->configure(&input, &output, layerInfo);
             m_PoolingLayer.reset(layer.release());
         }
     }
     void NeonPooling3dWorkload::Execute() const
     {
         ARMNN_SCOPED_PROFILING_EVENT_NEON_NAME_GUID("NeonPooling3dWorkload_Execute");
         m_PoolingLayer->run();
     }
 }
	//
	// Copyright © 2022-2023 Arm Ltd and Contributors. All rights reserved.
	// SPDX-License-Identifier: MIT
	//
	#include "NeonPooling3dWorkload.hpp"
	#include "NeonWorkloadUtils.hpp"
	#include <neon/NeonLayerSupport.hpp>
	#include <neon/NeonTensorHandle.hpp>
	#include <aclCommon/ArmComputeUtils.hpp>
	#include <aclCommon/ArmComputeTensorUtils.hpp>

	namespace armnn
	{
	using namespace armcomputetensorutils;
	arm_compute::Status NeonPooling3dWorkloadValidate(const TensorInfo& input,
	const TensorInfo& output,
	const Pooling3dDescriptor& descriptor)
	{
	const arm_compute::TensorInfo aclInputInfo = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
	const arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);
	arm_compute::Pooling3dLayerInfo layerInfo = BuildArmComputePooling3dLayerInfo(descriptor);
	return arm_compute::NEPooling3dLayer::validate(&aclInputInfo, &aclOutputInfo, layerInfo);
	}

	NeonPooling3dWorkload::NeonPooling3dWorkload( const Pooling3dQueueDescriptor& descriptor,
	const WorkloadInfo& info)
	: NeonBaseWorkload<Pooling3dQueueDescriptor>(descriptor, info)
	{
	// Report Profiling Details
	ARMNN_REPORT_PROFILING_WORKLOAD_DESC("NeonPooling3dWorkload_Construct",
	descriptor.m_Parameters,
	info,
	this->GetGuid());

	m_Data.ValidateInputsOutputs("NeonPooling3dWorkload", 1, 1);

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

	// flag to use wider accumulators (32 bit instead of 16 for FP16) to improve accuracy
	// enable fp_mixed_precision for the the FP16 cases that
	// accumulation reaches a limit beyond which there is no more increment of the value
	bool fpMixedPrecision = false;

	arm_compute::Pooling3dLayerInfo layerInfo = BuildArmComputePooling3dLayerInfo(m_Data.m_Parameters,
	fpMixedPrecision);
	{
	ARMNN_SCOPED_PROFILING_EVENT(Compute::Undefined, "NeonPooling3dWorkload_configure");

	auto layer = std::make_unique<arm_compute::NEPooling3dLayer>();
	layer->configure(&input, &output, layerInfo);
	m_PoolingLayer.reset(layer.release());
	}
	}
	void NeonPooling3dWorkload::Execute() const
	{
	ARMNN_SCOPED_PROFILING_EVENT_NEON_NAME_GUID("NeonPooling3dWorkload_Execute");
	m_PoolingLayer->run();
	}
	}