src/backends/cl/workloads/ClUnidirectionalSequenceLstmFloatWorkload.hpp - ml/armnn - Gitiles

 //
 // Copyright © 2022-2023 Arm Ltd and Contributors. All rights reserved.
 // SPDX-License-Identifier: MIT
 //

 #pragma once

 #include <armnn/Descriptors.hpp>
 #include <armnn/LstmParams.hpp>
 #include <armnn/backends/Workload.hpp>
 #include <armnn/backends/WorkloadData.hpp>

 #include <arm_compute/graph/Tensor.h>
 #include <arm_compute/runtime/CL/functions/CLLSTMLayer.h>
 #include <arm_compute/runtime/CL/functions/CLPermute.h>
 #include <arm_compute/runtime/CL/functions/CLSplit.h>
 #include <arm_compute/runtime/CL/functions/CLConcatenateLayer.h>

 namespace armnn
 {

 class ClUnidirectionalSequenceLstmFloatWorkload : public FloatWorkload<UnidirectionalSequenceLstmQueueDescriptor>
 {
 public:
     ClUnidirectionalSequenceLstmFloatWorkload(const UnidirectionalSequenceLstmQueueDescriptor& descriptor,
                                               const WorkloadInfo& info,
                                               const arm_compute::CLCompileContext& clCompileContext);
     virtual void Execute() const override;

 private:

     //
     // ACL layers required to fully form a Unidirectional Sequence LSTM layer.
     //

     // permutation for input (only used when input is batch major)
     mutable std::unique_ptr<arm_compute::CLPermute> m_Permute1;
     mutable std::unique_ptr<arm_compute::IFunction> m_Splitter;
     mutable std::vector<std::unique_ptr<arm_compute::CLLSTMLayer>> m_Layers;
     mutable std::unique_ptr<arm_compute::CLConcatenateLayer> m_Concat;
     // permutation for output (only used when input is batch major)
     mutable std::unique_ptr<arm_compute::CLPermute> m_Permute2;

     //
     // ACL LSTM arm_compute::CLTensors.
     //
     std::unique_ptr<arm_compute::CLTensor> m_InputToInputWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_InputToForgetWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_InputToCellWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_InputToOutputWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_RecurrentToInputWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_RecurrentToForgetWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_RecurrentToCellWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_RecurrentToOutputWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_CellToInputWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_CellToForgetWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_CellToOutputWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_InputGateBiasTensor;
     std::unique_ptr<arm_compute::CLTensor> m_ForgetGateBiasTensor;
     std::unique_ptr<arm_compute::CLTensor> m_CellBiasTensor;
     std::unique_ptr<arm_compute::CLTensor> m_OutputGateBiasTensor;
     std::unique_ptr<arm_compute::CLTensor> m_ProjectionWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_ProjectionBiasTensor;

     std::unique_ptr<arm_compute::CLTensor> m_ScratchBuffer;

     std::unique_ptr<arm_compute::CLTensor> m_InputLayerNormWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_ForgetLayerNormWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_CellLayerNormWeightsTensor;
     std::unique_ptr<arm_compute::CLTensor> m_OutputLayerNormWeightsTensor;

     //
     // Additional ACL arm_compute::CLTensors and std::vector<arm_compute::CLTensor>.
     // Required to perform splitting, concatenation and permutations.
     //
     arm_compute::CLTensor m_PermuteFirstOut;
     std::vector<arm_compute::CLTensor> m_SplitterOutputsTensors;
     std::vector<arm_compute::CLTensor> m_ConcatInputsTensors;
     std::vector<arm_compute::ICLTensor*> m_SplitterOutputs;
     std::vector<const arm_compute::ICLTensor*> m_ConcatInputs;
     arm_compute::CLTensor concat_out;

     void FreeUnusedTensors();
 };

 arm_compute::Status
 ClUnidirectionalSequenceLstmFloatWorkloadValidate(const TensorInfo& input,
                                                   const TensorInfo& outputStateIn,
                                                   const TensorInfo& cellStateIn,
                                                   const TensorInfo& outputStateOut,
                                                   const TensorInfo& cellStateOut,
                                                   const TensorInfo& output,
                                                   const UnidirectionalSequenceLstmDescriptor& descriptor,
                                                   const LstmInputParamsInfo& paramsInfo);

 } //namespace armnn
	//
	// Copyright © 2022-2023 Arm Ltd and Contributors. All rights reserved.
	// SPDX-License-Identifier: MIT
	//

	#pragma once

	#include <armnn/Descriptors.hpp>
	#include <armnn/LstmParams.hpp>
	#include <armnn/backends/Workload.hpp>
	#include <armnn/backends/WorkloadData.hpp>

	#include <arm_compute/graph/Tensor.h>
	#include <arm_compute/runtime/CL/functions/CLLSTMLayer.h>
	#include <arm_compute/runtime/CL/functions/CLPermute.h>
	#include <arm_compute/runtime/CL/functions/CLSplit.h>
	#include <arm_compute/runtime/CL/functions/CLConcatenateLayer.h>

	namespace armnn
	{

	class ClUnidirectionalSequenceLstmFloatWorkload : public FloatWorkload<UnidirectionalSequenceLstmQueueDescriptor>
	{
	public:
	ClUnidirectionalSequenceLstmFloatWorkload(const UnidirectionalSequenceLstmQueueDescriptor& descriptor,
	const WorkloadInfo& info,
	const arm_compute::CLCompileContext& clCompileContext);
	virtual void Execute() const override;

	private:

	//
	// ACL layers required to fully form a Unidirectional Sequence LSTM layer.
	//

	// permutation for input (only used when input is batch major)
	mutable std::unique_ptr<arm_compute::CLPermute> m_Permute1;
	mutable std::unique_ptr<arm_compute::IFunction> m_Splitter;
	mutable std::vector<std::unique_ptr<arm_compute::CLLSTMLayer>> m_Layers;
	mutable std::unique_ptr<arm_compute::CLConcatenateLayer> m_Concat;
	// permutation for output (only used when input is batch major)
	mutable std::unique_ptr<arm_compute::CLPermute> m_Permute2;

	//
	// ACL LSTM arm_compute::CLTensors.
	//
	std::unique_ptr<arm_compute::CLTensor> m_InputToInputWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_InputToForgetWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_InputToCellWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_InputToOutputWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_RecurrentToInputWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_RecurrentToForgetWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_RecurrentToCellWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_RecurrentToOutputWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_CellToInputWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_CellToForgetWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_CellToOutputWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_InputGateBiasTensor;
	std::unique_ptr<arm_compute::CLTensor> m_ForgetGateBiasTensor;
	std::unique_ptr<arm_compute::CLTensor> m_CellBiasTensor;
	std::unique_ptr<arm_compute::CLTensor> m_OutputGateBiasTensor;
	std::unique_ptr<arm_compute::CLTensor> m_ProjectionWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_ProjectionBiasTensor;

	std::unique_ptr<arm_compute::CLTensor> m_ScratchBuffer;

	std::unique_ptr<arm_compute::CLTensor> m_InputLayerNormWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_ForgetLayerNormWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_CellLayerNormWeightsTensor;
	std::unique_ptr<arm_compute::CLTensor> m_OutputLayerNormWeightsTensor;

	//
	// Additional ACL arm_compute::CLTensors and std::vector<arm_compute::CLTensor>.
	// Required to perform splitting, concatenation and permutations.
	//
	arm_compute::CLTensor m_PermuteFirstOut;
	std::vector<arm_compute::CLTensor> m_SplitterOutputsTensors;
	std::vector<arm_compute::CLTensor> m_ConcatInputsTensors;
	std::vector<arm_compute::ICLTensor*> m_SplitterOutputs;
	std::vector<const arm_compute::ICLTensor*> m_ConcatInputs;
	arm_compute::CLTensor concat_out;

	void FreeUnusedTensors();
	};

	arm_compute::Status
	ClUnidirectionalSequenceLstmFloatWorkloadValidate(const TensorInfo& input,
	const TensorInfo& outputStateIn,
	const TensorInfo& cellStateIn,
	const TensorInfo& outputStateOut,
	const TensorInfo& cellStateOut,
	const TensorInfo& output,
	const UnidirectionalSequenceLstmDescriptor& descriptor,
	const LstmInputParamsInfo& paramsInfo);

	} //namespace armnn