ArmnnPreparedModel_1_2.hpp - ml/android-nn-driver - Gitiles

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

 #pragma once

 #include "ArmnnDriver.hpp"
 #include "ArmnnDriverImpl.hpp"
 #include "RequestThread.hpp"
 #include "ModelToINetworkConverter.hpp"

 #include <NeuralNetworks.h>
 #include <armnn/ArmNN.hpp>

 #include <string>
 #include <vector>

 namespace armnn_driver
 {

 using CallbackAsync_1_2 = std::function<
                                 void(V1_0::ErrorStatus errorStatus,
                                      std::vector<::android::hardware::neuralnetworks::V1_2::OutputShape> outputShapes,
                                      const ::android::hardware::neuralnetworks::V1_2::Timing& timing,
                                      std::string callingFunction)>;

 struct ExecutionContext_1_2
 {
     ::android::hardware::neuralnetworks::V1_2::MeasureTiming    measureTimings =
         ::android::hardware::neuralnetworks::V1_2::MeasureTiming::NO;
     TimePoint driverStart;
 };

 using CallbackContext_1_2 = CallbackContext<CallbackAsync_1_2, ExecutionContext_1_2>;

 template <typename HalVersion>
 class ArmnnPreparedModel_1_2 : public V1_2::IPreparedModel
 {
 public:
     using HalModel = typename V1_2::Model;

     ArmnnPreparedModel_1_2(armnn::NetworkId networkId,
                            armnn::IRuntime* runtime,
                            const HalModel& model,
                            const std::string& requestInputsAndOutputsDumpDir,
                            const bool gpuProfilingEnabled,
                            const bool asyncModelExecutionEnabled = false);

     virtual ~ArmnnPreparedModel_1_2();

     virtual Return<V1_0::ErrorStatus> execute(const V1_0::Request& request,
                                               const ::android::sp<V1_0::IExecutionCallback>& callback) override;

     virtual Return<V1_0::ErrorStatus> execute_1_2(const V1_0::Request& request, V1_2::MeasureTiming measure,
                                                   const ::android::sp<V1_2::IExecutionCallback>& callback) override;

     virtual Return<void> executeSynchronously(const V1_0::Request &request,
                                               V1_2::MeasureTiming measure,
                                               V1_2::IPreparedModel::executeSynchronously_cb cb) override;

     virtual Return<void> configureExecutionBurst(
             const ::android::sp<V1_2::IBurstCallback>& callback,
             const android::hardware::MQDescriptorSync<V1_2::FmqRequestDatum>& requestChannel,
             const android::hardware::MQDescriptorSync<V1_2::FmqResultDatum>& resultChannel,
             configureExecutionBurst_cb cb) override;

     /// execute the graph prepared from the request
     template<typename CallbackContext>
     bool ExecuteGraph(std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>>& pMemPools,
                       armnn::InputTensors& inputTensors,
                       armnn::OutputTensors& outputTensors,
                       CallbackContext callback);

     /// Executes this model with dummy inputs (e.g. all zeroes).
     /// \return false on failure, otherwise true
     bool ExecuteWithDummyInputs();

 private:

     template<typename CallbackContext>
     class ArmnnThreadPoolCallback_1_2 : public armnn::IAsyncExecutionCallback
     {
     public:
         ArmnnThreadPoolCallback_1_2(ArmnnPreparedModel_1_2<HalVersion>* model,
                                     std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>>& pMemPools,
                                     std::vector<V1_2::OutputShape> outputShapes,
                                     std::shared_ptr<armnn::InputTensors>& inputTensors,
                                     std::shared_ptr<armnn::OutputTensors>& outputTensors,
                                     CallbackContext callbackContext) :
                 m_Model(model),
                 m_MemPools(pMemPools),
                 m_OutputShapes(outputShapes),
                 m_InputTensors(inputTensors),
                 m_OutputTensors(outputTensors),
                 m_CallbackContext(callbackContext)
         {}

         void Notify(armnn::Status status, armnn::InferenceTimingPair timeTaken) override;

         // Retrieve the Arm NN Status from the AsyncExecutionCallback that has been notified
         virtual armnn::Status GetStatus() const override
         {
             return armnn::Status::Success;
         }

         // Block the calling thread until the AsyncExecutionCallback object allows it to proceed
         virtual void Wait() const override
         {}

         // Retrieve the start time before executing the inference
         virtual armnn::HighResolutionClock GetStartTime() const override
         {
             return std::chrono::high_resolution_clock::now();
         }

         // Retrieve the time after executing the inference
         virtual armnn::HighResolutionClock GetEndTime() const override
         {
             return std::chrono::high_resolution_clock::now();
         }

         ArmnnPreparedModel_1_2<HalVersion>* m_Model;
         std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>> m_MemPools;
         std::vector<V1_2::OutputShape> m_OutputShapes;
         std::shared_ptr<armnn::InputTensors> m_InputTensors;
         std::shared_ptr<armnn::OutputTensors> m_OutputTensors;
         CallbackContext m_CallbackContext;
     };

     Return<V1_0::ErrorStatus> Execute(const V1_0::Request& request,
                                       V1_2::MeasureTiming measureTiming,
                                       CallbackAsync_1_2 callback);

     Return<V1_0::ErrorStatus> PrepareMemoryForInputs(
             armnn::InputTensors& inputs,
             const V1_0::Request& request,
             const std::vector<android::nn::RunTimePoolInfo>& memPools);

     Return<V1_0::ErrorStatus> PrepareMemoryForOutputs(
             armnn::OutputTensors& outputs,
             std::vector<V1_2::OutputShape> &outputShapes,
             const V1_0::Request& request,
             const std::vector<android::nn::RunTimePoolInfo>& memPools);

     Return <V1_0::ErrorStatus> PrepareMemoryForIO(
             armnn::InputTensors& inputs,
             armnn::OutputTensors& outputs,
             std::vector<android::nn::RunTimePoolInfo>& memPools,
             const V1_0::Request& request,
             CallbackAsync_1_2 callback);

     template <typename TensorBindingCollection>
     void DumpTensorsIfRequired(char const* tensorNamePrefix, const TensorBindingCollection& tensorBindings);

     /// schedule the graph prepared from the request for execution
     template<typename CallbackContext>
     void ScheduleGraphForExecution(
             std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>>& pMemPools,
             std::shared_ptr<armnn::InputTensors>& inputTensors,
             std::shared_ptr<armnn::OutputTensors>& outputTensors,
             CallbackContext m_CallbackContext);

     armnn::NetworkId                                                            m_NetworkId;
     armnn::IRuntime*                                                            m_Runtime;
     V1_2::Model                                                                 m_Model;
     // There must be a single RequestThread for all ArmnnPreparedModel objects to ensure serial execution of workloads
     // It is specific to this class, so it is declared as static here
     static RequestThread<ArmnnPreparedModel_1_2,
                          HalVersion,
                          CallbackContext_1_2>                                   m_RequestThread;
     uint32_t                                                                    m_RequestCount;
     const std::string&                                                          m_RequestInputsAndOutputsDumpDir;
     const bool                                                                  m_GpuProfilingEnabled;

     std::unique_ptr<IWorkingMemHandle> m_WorkingMemHandle;
     const bool m_AsyncModelExecutionEnabled;
 };

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

	#pragma once

	#include "ArmnnDriver.hpp"
	#include "ArmnnDriverImpl.hpp"
	#include "RequestThread.hpp"
	#include "ModelToINetworkConverter.hpp"

	#include <NeuralNetworks.h>
	#include <armnn/ArmNN.hpp>

	#include <string>
	#include <vector>

	namespace armnn_driver
	{

	using CallbackAsync_1_2 = std::function<
	void(V1_0::ErrorStatus errorStatus,
	std::vector<::android::hardware::neuralnetworks::V1_2::OutputShape> outputShapes,
	const ::android::hardware::neuralnetworks::V1_2::Timing& timing,
	std::string callingFunction)>;

	struct ExecutionContext_1_2
	{
	::android::hardware::neuralnetworks::V1_2::MeasureTiming measureTimings =
	::android::hardware::neuralnetworks::V1_2::MeasureTiming::NO;
	TimePoint driverStart;
	};

	using CallbackContext_1_2 = CallbackContext<CallbackAsync_1_2, ExecutionContext_1_2>;

	template <typename HalVersion>
	class ArmnnPreparedModel_1_2 : public V1_2::IPreparedModel
	{
	public:
	using HalModel = typename V1_2::Model;

	ArmnnPreparedModel_1_2(armnn::NetworkId networkId,
	armnn::IRuntime* runtime,
	const HalModel& model,
	const std::string& requestInputsAndOutputsDumpDir,
	const bool gpuProfilingEnabled,
	const bool asyncModelExecutionEnabled = false);

	virtual ~ArmnnPreparedModel_1_2();

	virtual Return<V1_0::ErrorStatus> execute(const V1_0::Request& request,
	const ::android::sp<V1_0::IExecutionCallback>& callback) override;

	virtual Return<V1_0::ErrorStatus> execute_1_2(const V1_0::Request& request, V1_2::MeasureTiming measure,
	const ::android::sp<V1_2::IExecutionCallback>& callback) override;

	virtual Return<void> executeSynchronously(const V1_0::Request &request,
	V1_2::MeasureTiming measure,
	V1_2::IPreparedModel::executeSynchronously_cb cb) override;

	virtual Return<void> configureExecutionBurst(
	const ::android::sp<V1_2::IBurstCallback>& callback,
	const android::hardware::MQDescriptorSync<V1_2::FmqRequestDatum>& requestChannel,
	const android::hardware::MQDescriptorSync<V1_2::FmqResultDatum>& resultChannel,
	configureExecutionBurst_cb cb) override;

	/// execute the graph prepared from the request
	template<typename CallbackContext>
	bool ExecuteGraph(std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>>& pMemPools,
	armnn::InputTensors& inputTensors,
	armnn::OutputTensors& outputTensors,
	CallbackContext callback);

	/// Executes this model with dummy inputs (e.g. all zeroes).
	/// \return false on failure, otherwise true
	bool ExecuteWithDummyInputs();

	private:

	template<typename CallbackContext>
	class ArmnnThreadPoolCallback_1_2 : public armnn::IAsyncExecutionCallback
	{
	public:
	ArmnnThreadPoolCallback_1_2(ArmnnPreparedModel_1_2<HalVersion>* model,
	std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>>& pMemPools,
	std::vector<V1_2::OutputShape> outputShapes,
	std::shared_ptr<armnn::InputTensors>& inputTensors,
	std::shared_ptr<armnn::OutputTensors>& outputTensors,
	CallbackContext callbackContext) :
	m_Model(model),
	m_MemPools(pMemPools),
	m_OutputShapes(outputShapes),
	m_InputTensors(inputTensors),
	m_OutputTensors(outputTensors),
	m_CallbackContext(callbackContext)
	{}

	void Notify(armnn::Status status, armnn::InferenceTimingPair timeTaken) override;

	// Retrieve the Arm NN Status from the AsyncExecutionCallback that has been notified
	virtual armnn::Status GetStatus() const override
	{
	return armnn::Status::Success;
	}

	// Block the calling thread until the AsyncExecutionCallback object allows it to proceed
	virtual void Wait() const override
	{}

	// Retrieve the start time before executing the inference
	virtual armnn::HighResolutionClock GetStartTime() const override
	{
	return std::chrono::high_resolution_clock::now();
	}

	// Retrieve the time after executing the inference
	virtual armnn::HighResolutionClock GetEndTime() const override
	{
	return std::chrono::high_resolution_clock::now();
	}

	ArmnnPreparedModel_1_2<HalVersion>* m_Model;
	std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>> m_MemPools;
	std::vector<V1_2::OutputShape> m_OutputShapes;
	std::shared_ptr<armnn::InputTensors> m_InputTensors;
	std::shared_ptr<armnn::OutputTensors> m_OutputTensors;
	CallbackContext m_CallbackContext;
	};

	Return<V1_0::ErrorStatus> Execute(const V1_0::Request& request,
	V1_2::MeasureTiming measureTiming,
	CallbackAsync_1_2 callback);

	Return<V1_0::ErrorStatus> PrepareMemoryForInputs(
	armnn::InputTensors& inputs,
	const V1_0::Request& request,
	const std::vector<android::nn::RunTimePoolInfo>& memPools);

	Return<V1_0::ErrorStatus> PrepareMemoryForOutputs(
	armnn::OutputTensors& outputs,
	std::vector<V1_2::OutputShape> &outputShapes,
	const V1_0::Request& request,
	const std::vector<android::nn::RunTimePoolInfo>& memPools);

	Return <V1_0::ErrorStatus> PrepareMemoryForIO(
	armnn::InputTensors& inputs,
	armnn::OutputTensors& outputs,
	std::vector<android::nn::RunTimePoolInfo>& memPools,
	const V1_0::Request& request,
	CallbackAsync_1_2 callback);

	template <typename TensorBindingCollection>
	void DumpTensorsIfRequired(char const* tensorNamePrefix, const TensorBindingCollection& tensorBindings);

	/// schedule the graph prepared from the request for execution
	template<typename CallbackContext>
	void ScheduleGraphForExecution(
	std::shared_ptr<std::vector<::android::nn::RunTimePoolInfo>>& pMemPools,
	std::shared_ptr<armnn::InputTensors>& inputTensors,
	std::shared_ptr<armnn::OutputTensors>& outputTensors,
	CallbackContext m_CallbackContext);

	armnn::NetworkId m_NetworkId;
	armnn::IRuntime* m_Runtime;
	V1_2::Model m_Model;
	// There must be a single RequestThread for all ArmnnPreparedModel objects to ensure serial execution of workloads
	// It is specific to this class, so it is declared as static here
	static RequestThread<ArmnnPreparedModel_1_2,
	HalVersion,
	CallbackContext_1_2> m_RequestThread;
	uint32_t m_RequestCount;
	const std::string& m_RequestInputsAndOutputsDumpDir;
	const bool m_GpuProfilingEnabled;

	std::unique_ptr<IWorkingMemHandle> m_WorkingMemHandle;
	const bool m_AsyncModelExecutionEnabled;
	};

	}