src/armnn/backends/RefWorkloadFactory.cpp - platform/external/armnn - Git at Google

 //
 // Copyright © 2017 Arm Ltd. All rights reserved.
 // SPDX-License-Identifier: MIT
 //
 #include "CpuTensorHandle.hpp"
 #include "RefWorkloadFactory.hpp"
 #include "RefWorkloads.hpp"
 #include "Layer.hpp"
 #include "MemCopyWorkload.hpp"
 #include "MakeWorkloadHelper.hpp"

 #include <boost/log/trivial.hpp>

 namespace armnn
 {

 template <typename F32Workload, typename U8Workload, typename QueueDescriptorType>
 std::unique_ptr<IWorkload> RefWorkloadFactory::MakeWorkload(const QueueDescriptorType& descriptor,
     const WorkloadInfo& info) const
 {
     return armnn::MakeWorkload<NullWorkload, F32Workload, U8Workload>(descriptor, info);
 }

 RefWorkloadFactory::RefWorkloadFactory()
 {
 }

 bool RefWorkloadFactory::IsLayerSupported(const Layer& layer, boost::optional<DataType> dataType,
                                           std::string& outReasonIfUnsupported)
 {
     return IWorkloadFactory::IsLayerSupported(Compute::CpuRef, layer, dataType, outReasonIfUnsupported);
 }

 std::unique_ptr<ITensorHandle> RefWorkloadFactory::CreateTensorHandle(const TensorInfo& tensorInfo) const
 {
     return std::make_unique<ScopedCpuTensorHandle>(tensorInfo);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateInput(const InputQueueDescriptor& descriptor,
                                                            const WorkloadInfo& info) const
 {
     if (info.m_InputTensorInfos.empty() )
     {
         throw InvalidArgumentException("RefWorkloadFactory::CreateInput: Input cannot be zero length");
     }
     if (info.m_OutputTensorInfos.empty())
     {
         throw InvalidArgumentException("RefWorkloadFactory::CreateInput: Output cannot be zero length");
     }

     if (info.m_InputTensorInfos[0].GetNumBytes() != info.m_OutputTensorInfos[0].GetNumBytes())
     {
         throw InvalidArgumentException("RefWorkloadFactory::CreateInput: data input and output differ in byte count.");
     }

     return MakeWorkload<CopyMemGenericWorkload, CopyMemGenericWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateOutput(const OutputQueueDescriptor& descriptor,
                                                             const WorkloadInfo& info) const
 {
     if (info.m_InputTensorInfos.empty() )
     {
         throw InvalidArgumentException("RefWorkloadFactory::CreateOutput: Input cannot be zero length");
     }
     if (info.m_OutputTensorInfos.empty())
     {
         throw InvalidArgumentException("RefWorkloadFactory::CreateOutput: Output cannot be zero length");
     }
     if (info.m_InputTensorInfos[0].GetNumBytes() != info.m_OutputTensorInfos[0].GetNumBytes())
     {
         throw InvalidArgumentException("RefWorkloadFactory::CreateOutput: data input and output differ in byte count.");
     }

     return MakeWorkload<CopyMemGenericWorkload, CopyMemGenericWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateActivation(const ActivationQueueDescriptor& descriptor,
                                                                 const WorkloadInfo&              info) const
 {
     return MakeWorkload<RefActivationFloat32Workload, RefActivationUint8Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateSoftmax(const SoftmaxQueueDescriptor& descriptor,
                                                              const WorkloadInfo&           info) const
 {
     return MakeWorkload<RefSoftmaxFloat32Workload, RefSoftmaxUint8Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateSplitter(const SplitterQueueDescriptor& descriptor,
                                                               const WorkloadInfo&            info) const
 {
     return MakeWorkload<RefSplitterFloat32Workload, RefSplitterUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMerger(const MergerQueueDescriptor& descriptor,
                                                                    const WorkloadInfo&          info) const
 {
     return MakeWorkload<RefMergerFloat32Workload, RefMergerUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateFullyConnected(
     const FullyConnectedQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefFullyConnectedFloat32Workload, RefFullyConnectedUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreatePermute(const PermuteQueueDescriptor& descriptor,
                                                                     const WorkloadInfo&           info) const
 {
     return MakeWorkload<RefPermuteFloat32Workload, RefPermuteUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreatePooling2d(const Pooling2dQueueDescriptor& descriptor,
                                                                       const WorkloadInfo&           info) const
 {
     return MakeWorkload<RefPooling2dFloat32Workload, RefPooling2dUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateConvolution2d(
     const Convolution2dQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefConvolution2dFloat32Workload, RefConvolution2dUint8Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateDepthwiseConvolution2d(
     const DepthwiseConvolution2dQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefDepthwiseConvolution2dFloat32Workload,
         RefDepthwiseConvolution2dUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateNormalization(
     const NormalizationQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefNormalizationFloat32Workload, NullWorkload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateAddition(const AdditionQueueDescriptor& descriptor,
                                                                      const WorkloadInfo&            info) const
 {
     return MakeWorkload<RefAdditionFloat32Workload, RefAdditionUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMultiplication(
     const MultiplicationQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefMultiplicationFloat32Workload, RefMultiplicationUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateBatchNormalization(
     const BatchNormalizationQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefBatchNormalizationFloat32Workload, RefBatchNormalizationUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMemCopy(const MemCopyQueueDescriptor& descriptor,
                                                                     const WorkloadInfo&        info) const
 {
     if (descriptor.m_Inputs.empty())
     {
         throw InvalidArgumentException("RefWorkloadFactory: CreateMemCopy() expected an input tensor.");
     }
     return std::make_unique<CopyMemGenericWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateResizeBilinear(const ResizeBilinearQueueDescriptor& descriptor,
                                                                     const WorkloadInfo& info) const
 {
     return MakeWorkload<RefResizeBilinearFloat32Workload, RefResizeBilinearUint8Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateFakeQuantization(
     const FakeQuantizationQueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return MakeWorkload<RefFakeQuantizationFloat32Workload, NullWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateL2Normalization(const L2NormalizationQueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return MakeWorkload<RefL2NormalizationFloat32Workload, NullWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateConstant(const ConstantQueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return MakeWorkload<RefConstantFloat32Workload, RefConstantUint8Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateReshape(const ReshapeQueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return MakeWorkload<RefReshapeFloat32Workload, RefReshapeUint8Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateFloor(const FloorQueueDescriptor& descriptor,
                                                           const WorkloadInfo& info) const
 {
     return MakeWorkload<RefFloorFloat32Workload, NullWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateLstm(const LstmQueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return MakeWorkload<RefLstmFloat32Workload, NullWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateConvertFp16ToFp32(
     const ConvertFp16ToFp32QueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return std::make_unique<RefConvertFp16ToFp32Workload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreateConvertFp32ToFp16(
     const ConvertFp32ToFp16QueueDescriptor& descriptor,
     const WorkloadInfo& info) const
 {
     return std::make_unique<RefConvertFp32ToFp16Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateDivision(
     const DivisionQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefDivisionFloat32Workload, RefDivisionUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateSubtraction(
     const SubtractionQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<RefSubtractionFloat32Workload, RefSubtractionUint8Workload>(descriptor, info);
 }

 std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMean(
     const MeanQueueDescriptor& descriptor, const WorkloadInfo& info) const
 {
     return MakeWorkload<NullWorkload, NullWorkload>(descriptor, info);
 }

 std::unique_ptr<IWorkload> RefWorkloadFactory::CreatePad(const PadQueueDescriptor& descriptor,
                                                  const WorkloadInfo& info) const
 {
     return MakeWorkload<NullWorkload, NullWorkload>(descriptor, info);
 }


 } // namespace armnn
	//
	// Copyright © 2017 Arm Ltd. All rights reserved.
	// SPDX-License-Identifier: MIT
	//
	#include "CpuTensorHandle.hpp"
	#include "RefWorkloadFactory.hpp"
	#include "RefWorkloads.hpp"
	#include "Layer.hpp"
	#include "MemCopyWorkload.hpp"
	#include "MakeWorkloadHelper.hpp"

	#include <boost/log/trivial.hpp>

	namespace armnn
	{

	template <typename F32Workload, typename U8Workload, typename QueueDescriptorType>
	std::unique_ptr<IWorkload> RefWorkloadFactory::MakeWorkload(const QueueDescriptorType& descriptor,
	const WorkloadInfo& info) const
	{
	return armnn::MakeWorkload<NullWorkload, F32Workload, U8Workload>(descriptor, info);
	}

	RefWorkloadFactory::RefWorkloadFactory()
	{
	}

	bool RefWorkloadFactory::IsLayerSupported(const Layer& layer, boost::optional<DataType> dataType,
	std::string& outReasonIfUnsupported)
	{
	return IWorkloadFactory::IsLayerSupported(Compute::CpuRef, layer, dataType, outReasonIfUnsupported);
	}

	std::unique_ptr<ITensorHandle> RefWorkloadFactory::CreateTensorHandle(const TensorInfo& tensorInfo) const
	{
	return std::make_unique<ScopedCpuTensorHandle>(tensorInfo);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateInput(const InputQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	if (info.m_InputTensorInfos.empty() )
	{
	throw InvalidArgumentException("RefWorkloadFactory::CreateInput: Input cannot be zero length");
	}
	if (info.m_OutputTensorInfos.empty())
	{
	throw InvalidArgumentException("RefWorkloadFactory::CreateInput: Output cannot be zero length");
	}

	if (info.m_InputTensorInfos[0].GetNumBytes() != info.m_OutputTensorInfos[0].GetNumBytes())
	{
	throw InvalidArgumentException("RefWorkloadFactory::CreateInput: data input and output differ in byte count.");
	}

	return MakeWorkload<CopyMemGenericWorkload, CopyMemGenericWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateOutput(const OutputQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	if (info.m_InputTensorInfos.empty() )
	{
	throw InvalidArgumentException("RefWorkloadFactory::CreateOutput: Input cannot be zero length");
	}
	if (info.m_OutputTensorInfos.empty())
	{
	throw InvalidArgumentException("RefWorkloadFactory::CreateOutput: Output cannot be zero length");
	}
	if (info.m_InputTensorInfos[0].GetNumBytes() != info.m_OutputTensorInfos[0].GetNumBytes())
	{
	throw InvalidArgumentException("RefWorkloadFactory::CreateOutput: data input and output differ in byte count.");
	}

	return MakeWorkload<CopyMemGenericWorkload, CopyMemGenericWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateActivation(const ActivationQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefActivationFloat32Workload, RefActivationUint8Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateSoftmax(const SoftmaxQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefSoftmaxFloat32Workload, RefSoftmaxUint8Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateSplitter(const SplitterQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefSplitterFloat32Workload, RefSplitterUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMerger(const MergerQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefMergerFloat32Workload, RefMergerUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateFullyConnected(
	const FullyConnectedQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefFullyConnectedFloat32Workload, RefFullyConnectedUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreatePermute(const PermuteQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefPermuteFloat32Workload, RefPermuteUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreatePooling2d(const Pooling2dQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefPooling2dFloat32Workload, RefPooling2dUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateConvolution2d(
	const Convolution2dQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefConvolution2dFloat32Workload, RefConvolution2dUint8Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateDepthwiseConvolution2d(
	const DepthwiseConvolution2dQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefDepthwiseConvolution2dFloat32Workload,
	RefDepthwiseConvolution2dUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateNormalization(
	const NormalizationQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefNormalizationFloat32Workload, NullWorkload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateAddition(const AdditionQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefAdditionFloat32Workload, RefAdditionUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMultiplication(
	const MultiplicationQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefMultiplicationFloat32Workload, RefMultiplicationUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateBatchNormalization(
	const BatchNormalizationQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefBatchNormalizationFloat32Workload, RefBatchNormalizationUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMemCopy(const MemCopyQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	if (descriptor.m_Inputs.empty())
	{
	throw InvalidArgumentException("RefWorkloadFactory: CreateMemCopy() expected an input tensor.");
	}
	return std::make_unique<CopyMemGenericWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateResizeBilinear(const ResizeBilinearQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefResizeBilinearFloat32Workload, RefResizeBilinearUint8Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateFakeQuantization(
	const FakeQuantizationQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefFakeQuantizationFloat32Workload, NullWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateL2Normalization(const L2NormalizationQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefL2NormalizationFloat32Workload, NullWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateConstant(const ConstantQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefConstantFloat32Workload, RefConstantUint8Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateReshape(const ReshapeQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefReshapeFloat32Workload, RefReshapeUint8Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateFloor(const FloorQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefFloorFloat32Workload, NullWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateLstm(const LstmQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<RefLstmFloat32Workload, NullWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateConvertFp16ToFp32(
	const ConvertFp16ToFp32QueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return std::make_unique<RefConvertFp16ToFp32Workload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreateConvertFp32ToFp16(
	const ConvertFp32ToFp16QueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return std::make_unique<RefConvertFp32ToFp16Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateDivision(
	const DivisionQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefDivisionFloat32Workload, RefDivisionUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateSubtraction(
	const SubtractionQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<RefSubtractionFloat32Workload, RefSubtractionUint8Workload>(descriptor, info);
	}

	std::unique_ptr<armnn::IWorkload> RefWorkloadFactory::CreateMean(
	const MeanQueueDescriptor& descriptor, const WorkloadInfo& info) const
	{
	return MakeWorkload<NullWorkload, NullWorkload>(descriptor, info);
	}

	std::unique_ptr<IWorkload> RefWorkloadFactory::CreatePad(const PadQueueDescriptor& descriptor,
	const WorkloadInfo& info) const
	{
	return MakeWorkload<NullWorkload, NullWorkload>(descriptor, info);
	}


	} // namespace armnn