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

 //
 // Copyright © 2020-2023 Arm Ltd and Contributors. All rights reserved.
 // SPDX-License-Identifier: MIT
 //

 #include "NeonBatchToSpaceNdWorkload.hpp"

 #include <armnn/utility/PolymorphicDowncast.hpp>

 namespace armnn
 {

 using namespace armcomputetensorutils;

 arm_compute::Status NeonBatchToSpaceNdWorkloadValidate(const TensorInfo& input,
                                                        const TensorInfo& output,
                                                        const BatchToSpaceNdDescriptor& descriptor)
 {
     arm_compute::TensorInfo aclInputInfo = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
     arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);

     arm_compute::Status statusBatchToSpace  = arm_compute::Status(arm_compute::ErrorCode::OK);
     arm_compute::Status statusReshapeInput  = arm_compute::Status(arm_compute::ErrorCode::OK);
     arm_compute::Status statusReshapeOutput = arm_compute::Status(arm_compute::ErrorCode::OK);

     arm_compute::TensorInfo aclReshapeInputInfo  = aclInputInfo;
     arm_compute::TensorInfo aclReshapeOutputInfo = aclOutputInfo;

     // When a spacial dimension is missing (rank=3) set W to 1
     const unsigned int rank = input.GetNumDimensions();
     if (rank == 3)
     {
         const arm_compute::TensorShape inputShape  = aclInputInfo.tensor_shape();
         const arm_compute::TensorShape outputShape = aclOutputInfo.tensor_shape();

         if (descriptor.m_DataLayout == armnn::DataLayout::NHWC)
         {
             // In ACL dimensions are right to left: C, W, H, N
             aclReshapeInputInfo.set_tensor_shape({inputShape.x(), 1, inputShape.y(), inputShape.z()});
             aclReshapeOutputInfo.set_tensor_shape({outputShape.x(), 1, outputShape.y(), outputShape.z()});
         }
         else if (descriptor.m_DataLayout == armnn::DataLayout::NCHW)
         {
             // In ACL dimensions are right to left: W, H, C, N
             aclReshapeInputInfo.set_tensor_shape({1, inputShape.x(), inputShape.y(), inputShape.z()});
             aclReshapeOutputInfo.set_tensor_shape({1, outputShape.x(), outputShape.y(), outputShape.z()});
         }
         else
         {
             throw InvalidArgumentException("Unsupported or unknown DataLayout", CHECK_LOCATION());
         }

         statusReshapeInput = arm_compute::NEReshapeLayer::validate(&aclInputInfo, &aclReshapeInputInfo);
         statusReshapeOutput = arm_compute::NEReshapeLayer::validate(&aclReshapeOutputInfo, &aclOutputInfo);
     }

     // ArmNN blockShape is [H, W] ACl asks for W, H
     int32_t blockHeight = armnn::numeric_cast<int32_t>(descriptor.m_BlockShape[0]);
     int32_t blockWidth = (rank == 3) ? 1 : armnn::numeric_cast<int32_t>(descriptor.m_BlockShape[1]);

     const arm_compute::CropInfo cropInfo = BuildArmComputeCropInfo(descriptor, rank);

     statusBatchToSpace = arm_compute::NEBatchToSpaceLayer::validate(rank == 3 ? &aclReshapeInputInfo : &aclInputInfo,
                                                                     blockWidth,
                                                                     blockHeight,
                                                                     rank == 3 ? &aclReshapeOutputInfo : &aclOutputInfo,
                                                                     cropInfo);

     if (statusReshapeInput.error_code()  == arm_compute::ErrorCode::OK &&
         statusReshapeOutput.error_code() == arm_compute::ErrorCode::OK &&
         statusBatchToSpace.error_code()  == arm_compute::ErrorCode::OK)
     {
         return arm_compute::Status(arm_compute::ErrorCode::OK,
                                    "All BatchToSpace layers validate status OK.");
     }
     else
     {
         return arm_compute::Status(arm_compute::ErrorCode::RUNTIME_ERROR,
                                    "BatchToSpace layer validate status failed."
                                    + statusBatchToSpace.error_description()
                                    + statusReshapeInput.error_description()
                                    + statusReshapeOutput.error_description());
     }
 }

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

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

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

     arm_compute::TensorInfo aclReshapeInputInfo = BuildArmComputeTensorInfo(info.m_InputTensorInfos[0],
                                                                             m_Data.m_Parameters.m_DataLayout);
     arm_compute::TensorInfo aclReshapeOutputInfo = BuildArmComputeTensorInfo(info.m_OutputTensorInfos[0],
                                                                              m_Data.m_Parameters.m_DataLayout);

     const unsigned int rank = info.m_InputTensorInfos[0].GetNumDimensions();
     if (rank == 3)
     {
         const arm_compute::TensorShape inputShape  = input.info()->tensor_shape();
         const arm_compute::TensorShape outputShape = output.info()->tensor_shape();

         // When a spacial dimension is missing set W to 1
         if (m_Data.m_Parameters.m_DataLayout == armnn::DataLayout::NHWC)
         {
             // In ACL dimensions are right to left: C, W, H, N
             aclReshapeInputInfo.set_tensor_shape({inputShape.x(), 1, inputShape.y(), inputShape.z()});
             aclReshapeOutputInfo.set_tensor_shape({outputShape.x(), 1, outputShape.y(), outputShape.z()});
         }
         else if (m_Data.m_Parameters.m_DataLayout == armnn::DataLayout::NCHW)
         {
             // In ACL dimensions are right to left: W, H, C, N
             aclReshapeInputInfo.set_tensor_shape({1, inputShape.x(), inputShape.y(), inputShape.z()});
             aclReshapeOutputInfo.set_tensor_shape({1, outputShape.x(), outputShape.y(), outputShape.z()});
         }
         else
         {
             throw InvalidArgumentException("Unsupported or unknown DataLayout", CHECK_LOCATION());
         }

         m_ReshapeInputTensor.allocator()->init(aclReshapeInputInfo);
         m_ReshapeOutputTensor.allocator()->init(aclReshapeOutputInfo);

         InitialiseArmComputeTensorEmpty(m_ReshapeInputTensor);
         InitialiseArmComputeTensorEmpty(m_ReshapeOutputTensor);

         m_LayerReshapeInput.reset(new arm_compute::NEReshapeLayer());
         m_LayerReshapeOutput.reset(new arm_compute::NEReshapeLayer());

         m_LayerReshapeInput->configure(&input, &m_ReshapeInputTensor);
         m_LayerReshapeOutput->configure(&m_ReshapeOutputTensor, &output);
     }

     // ArmNN blockShape is [H, W] ACl asks for W, H
     int32_t blockHeight = armnn::numeric_cast<int32_t>(descriptor.m_Parameters.m_BlockShape[0]);
     int32_t blockWidth = (rank == 3) ? 1 : armnn::numeric_cast<int32_t>(descriptor.m_Parameters.m_BlockShape[1]);

     const arm_compute::CropInfo cropInfo = BuildArmComputeCropInfo(descriptor.m_Parameters, rank);

     m_Layer.reset(new arm_compute::NEBatchToSpaceLayer());
     m_Layer->configure(rank == 3 ? &m_ReshapeInputTensor : &input,
                        blockWidth,
                        blockHeight,
                        rank == 3 ? &m_ReshapeOutputTensor : &output,
                        cropInfo);
     m_Layer->prepare();
 }

 void NeonBatchToSpaceNdWorkload::Execute() const
 {
     ARMNN_SCOPED_PROFILING_EVENT_NEON_NAME_GUID("NeonBatchToSpaceNdWorkload_Execute");
     if (m_LayerReshapeInput)
     {
         m_LayerReshapeInput->run();
     }
     if (m_Layer)
     {
         m_Layer->run();
     }
     if (m_LayerReshapeOutput)
     {
         m_LayerReshapeOutput->run();
     }
 }

 } //namespace armnn
	//
	// Copyright © 2020-2023 Arm Ltd and Contributors. All rights reserved.
	// SPDX-License-Identifier: MIT
	//

	#include "NeonBatchToSpaceNdWorkload.hpp"

	#include <armnn/utility/PolymorphicDowncast.hpp>

	namespace armnn
	{

	using namespace armcomputetensorutils;

	arm_compute::Status NeonBatchToSpaceNdWorkloadValidate(const TensorInfo& input,
	const TensorInfo& output,
	const BatchToSpaceNdDescriptor& descriptor)
	{
	arm_compute::TensorInfo aclInputInfo = BuildArmComputeTensorInfo(input, descriptor.m_DataLayout);
	arm_compute::TensorInfo aclOutputInfo = BuildArmComputeTensorInfo(output, descriptor.m_DataLayout);

	arm_compute::Status statusBatchToSpace = arm_compute::Status(arm_compute::ErrorCode::OK);
	arm_compute::Status statusReshapeInput = arm_compute::Status(arm_compute::ErrorCode::OK);
	arm_compute::Status statusReshapeOutput = arm_compute::Status(arm_compute::ErrorCode::OK);

	arm_compute::TensorInfo aclReshapeInputInfo = aclInputInfo;
	arm_compute::TensorInfo aclReshapeOutputInfo = aclOutputInfo;

	// When a spacial dimension is missing (rank=3) set W to 1
	const unsigned int rank = input.GetNumDimensions();
	if (rank == 3)
	{
	const arm_compute::TensorShape inputShape = aclInputInfo.tensor_shape();
	const arm_compute::TensorShape outputShape = aclOutputInfo.tensor_shape();

	if (descriptor.m_DataLayout == armnn::DataLayout::NHWC)
	{
	// In ACL dimensions are right to left: C, W, H, N
	aclReshapeInputInfo.set_tensor_shape({inputShape.x(), 1, inputShape.y(), inputShape.z()});
	aclReshapeOutputInfo.set_tensor_shape({outputShape.x(), 1, outputShape.y(), outputShape.z()});
	}
	else if (descriptor.m_DataLayout == armnn::DataLayout::NCHW)
	{
	// In ACL dimensions are right to left: W, H, C, N
	aclReshapeInputInfo.set_tensor_shape({1, inputShape.x(), inputShape.y(), inputShape.z()});
	aclReshapeOutputInfo.set_tensor_shape({1, outputShape.x(), outputShape.y(), outputShape.z()});
	}
	else
	{
	throw InvalidArgumentException("Unsupported or unknown DataLayout", CHECK_LOCATION());
	}

	statusReshapeInput = arm_compute::NEReshapeLayer::validate(&aclInputInfo, &aclReshapeInputInfo);
	statusReshapeOutput = arm_compute::NEReshapeLayer::validate(&aclReshapeOutputInfo, &aclOutputInfo);
	}

	// ArmNN blockShape is [H, W] ACl asks for W, H
	int32_t blockHeight = armnn::numeric_cast<int32_t>(descriptor.m_BlockShape[0]);
	int32_t blockWidth = (rank == 3) ? 1 : armnn::numeric_cast<int32_t>(descriptor.m_BlockShape[1]);

	const arm_compute::CropInfo cropInfo = BuildArmComputeCropInfo(descriptor, rank);

	statusBatchToSpace = arm_compute::NEBatchToSpaceLayer::validate(rank == 3 ? &aclReshapeInputInfo : &aclInputInfo,
	blockWidth,
	blockHeight,
	rank == 3 ? &aclReshapeOutputInfo : &aclOutputInfo,
	cropInfo);

	if (statusReshapeInput.error_code() == arm_compute::ErrorCode::OK &&
	statusReshapeOutput.error_code() == arm_compute::ErrorCode::OK &&
	statusBatchToSpace.error_code() == arm_compute::ErrorCode::OK)
	{
	return arm_compute::Status(arm_compute::ErrorCode::OK,
	"All BatchToSpace layers validate status OK.");
	}
	else
	{
	return arm_compute::Status(arm_compute::ErrorCode::RUNTIME_ERROR,
	"BatchToSpace layer validate status failed."
	+ statusBatchToSpace.error_description()
	+ statusReshapeInput.error_description()
	+ statusReshapeOutput.error_description());
	}
	}

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

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

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

	arm_compute::TensorInfo aclReshapeInputInfo = BuildArmComputeTensorInfo(info.m_InputTensorInfos[0],
	m_Data.m_Parameters.m_DataLayout);
	arm_compute::TensorInfo aclReshapeOutputInfo = BuildArmComputeTensorInfo(info.m_OutputTensorInfos[0],
	m_Data.m_Parameters.m_DataLayout);

	const unsigned int rank = info.m_InputTensorInfos[0].GetNumDimensions();
	if (rank == 3)
	{
	const arm_compute::TensorShape inputShape = input.info()->tensor_shape();
	const arm_compute::TensorShape outputShape = output.info()->tensor_shape();

	// When a spacial dimension is missing set W to 1
	if (m_Data.m_Parameters.m_DataLayout == armnn::DataLayout::NHWC)
	{
	// In ACL dimensions are right to left: C, W, H, N
	aclReshapeInputInfo.set_tensor_shape({inputShape.x(), 1, inputShape.y(), inputShape.z()});
	aclReshapeOutputInfo.set_tensor_shape({outputShape.x(), 1, outputShape.y(), outputShape.z()});
	}
	else if (m_Data.m_Parameters.m_DataLayout == armnn::DataLayout::NCHW)
	{
	// In ACL dimensions are right to left: W, H, C, N
	aclReshapeInputInfo.set_tensor_shape({1, inputShape.x(), inputShape.y(), inputShape.z()});
	aclReshapeOutputInfo.set_tensor_shape({1, outputShape.x(), outputShape.y(), outputShape.z()});
	}
	else
	{
	throw InvalidArgumentException("Unsupported or unknown DataLayout", CHECK_LOCATION());
	}

	m_ReshapeInputTensor.allocator()->init(aclReshapeInputInfo);
	m_ReshapeOutputTensor.allocator()->init(aclReshapeOutputInfo);

	InitialiseArmComputeTensorEmpty(m_ReshapeInputTensor);
	InitialiseArmComputeTensorEmpty(m_ReshapeOutputTensor);

	m_LayerReshapeInput.reset(new arm_compute::NEReshapeLayer());
	m_LayerReshapeOutput.reset(new arm_compute::NEReshapeLayer());

	m_LayerReshapeInput->configure(&input, &m_ReshapeInputTensor);
	m_LayerReshapeOutput->configure(&m_ReshapeOutputTensor, &output);
	}

	// ArmNN blockShape is [H, W] ACl asks for W, H
	int32_t blockHeight = armnn::numeric_cast<int32_t>(descriptor.m_Parameters.m_BlockShape[0]);
	int32_t blockWidth = (rank == 3) ? 1 : armnn::numeric_cast<int32_t>(descriptor.m_Parameters.m_BlockShape[1]);

	const arm_compute::CropInfo cropInfo = BuildArmComputeCropInfo(descriptor.m_Parameters, rank);

	m_Layer.reset(new arm_compute::NEBatchToSpaceLayer());
	m_Layer->configure(rank == 3 ? &m_ReshapeInputTensor : &input,
	blockWidth,
	blockHeight,
	rank == 3 ? &m_ReshapeOutputTensor : &output,
	cropInfo);
	m_Layer->prepare();
	}

	void NeonBatchToSpaceNdWorkload::Execute() const
	{
	ARMNN_SCOPED_PROFILING_EVENT_NEON_NAME_GUID("NeonBatchToSpaceNdWorkload_Execute");
	if (m_LayerReshapeInput)
	{
	m_LayerReshapeInput->run();
	}
	if (m_Layer)
	{
	m_Layer->run();
	}
	if (m_LayerReshapeOutput)
	{
	m_LayerReshapeOutput->run();
	}
	}

	} //namespace armnn