tests/ExecuteNetwork/ExecuteNetworkParams.cpp - ml/armnn - Gitiles

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

 #include "ExecuteNetworkParams.hpp"

 #include "NetworkExecutionUtils/NetworkExecutionUtils.hpp"
 #include <InferenceModel.hpp>
 #include <armnn/Logging.hpp>

 #include <fmt/format.h>

 bool IsModelBinary(const std::string& modelFormat)
 {
     // Parse model binary flag from the model-format string we got from the command-line
     if (modelFormat.find("binary") != std::string::npos)
     {
         return true;
     }
     else if (modelFormat.find("txt") != std::string::npos || modelFormat.find("text") != std::string::npos)
     {
         return false;
     }
     else
     {
         throw armnn::InvalidArgumentException(fmt::format("Unknown model format: '{}'. "
                                                           "Please include 'binary' or 'text'",
                                                           modelFormat));
     }
 }

 void CheckModelFormat(const std::string& modelFormat)
 {
     // Forward to implementation based on the parser type
     if (modelFormat.find("armnn") != std::string::npos)
     {
 #if defined(ARMNN_SERIALIZER)
 #else
         throw armnn::InvalidArgumentException("Can't run model in armnn format without a "
                                               "built with serialization support.");
 #endif
     }
     else if (modelFormat.find("onnx") != std::string::npos)
     {
 #if defined(ARMNN_ONNX_PARSER)
 #else
         throw armnn::InvalidArgumentException("Can't run model in onnx format without a "
                                               "built with Onnx parser support.");
 #endif
     }
     else if (modelFormat.find("tflite") != std::string::npos)
     {
 #if defined(ARMNN_TF_LITE_PARSER)
         if (!IsModelBinary(modelFormat))
         {
             throw armnn::InvalidArgumentException(fmt::format("Unknown model format: '{}'. Only 'binary' "
                                                               "format supported for tflite files",
                                                               modelFormat));
         }
 #elif defined(ARMNN_TFLITE_DELEGATE)
 #else
         throw armnn::InvalidArgumentException("Can't run model in tflite format without a "
                                               "built with Tensorflow Lite parser support.");
 #endif
     }
     else
     {
         throw armnn::InvalidArgumentException(fmt::format("Unknown model format: '{}'. "
                                                           "Please include 'tflite' or 'onnx'",
                                                           modelFormat));
     }
 }

 void CheckClTuningParameter(const int& tuningLevel,
                             const std::string& tuningPath,
                             const std::vector<armnn::BackendId> computeDevices)
 {
     if (!tuningPath.empty())
     {
         if (tuningLevel == 0)
         {
             ARMNN_LOG(info) << "Using cl tuning file: " << tuningPath << "\n";
             if (!ValidatePath(tuningPath, true))
             {
                 throw armnn::InvalidArgumentException("The tuning path is not valid");
             }
         }
         else if ((1 <= tuningLevel) && (tuningLevel <= 3))
         {
             ARMNN_LOG(info) << "Starting execution to generate a cl tuning file: " << tuningPath << "\n"
                             << "Tuning level in use: " << tuningLevel << "\n";
         }
         else if ((0 < tuningLevel) || (tuningLevel > 3))
         {
             throw armnn::InvalidArgumentException(fmt::format("The tuning level {} is not valid.",
                                                               tuningLevel));
         }

         // Ensure that a GpuAcc is enabled. Otherwise no tuning data are used or genereted
         // Only warn if it's not enabled
         auto it = std::find(computeDevices.begin(), computeDevices.end(), "GpuAcc");
         if (it == computeDevices.end())
         {
             ARMNN_LOG(warning) << "To use Cl Tuning the compute device GpuAcc needs to be active.";
         }
     }

 }

 void ExecuteNetworkParams::ValidateParams()
 {
     if (m_DynamicBackendsPath == "")
     {
         // Check compute devices are valid unless they are dynamically loaded at runtime
         std::string invalidBackends;
         if (!CheckRequestedBackendsAreValid(m_ComputeDevices, armnn::Optional<std::string&>(invalidBackends)))
         {
             ARMNN_LOG(fatal) << "The list of preferred devices contains invalid backend IDs: "
                              << invalidBackends;
         }
     }

     CheckClTuningParameter(m_TuningLevel, m_TuningPath, m_ComputeDevices);

     if (m_EnableBf16TurboMode && m_EnableFp16TurboMode)
     {
         throw armnn::InvalidArgumentException("BFloat16 and Float16 turbo mode cannot be "
                                               "enabled at the same time.");
     }

     m_IsModelBinary = IsModelBinary(m_ModelFormat);

     CheckModelFormat(m_ModelFormat);

     // Check input tensor shapes
     if ((m_InputTensorShapes.size() != 0) &&
         (m_InputTensorShapes.size() != m_InputNames.size()))
     {
         throw armnn::InvalidArgumentException("input-name and input-tensor-shape must have "
                                               "the same amount of elements. ");
     }

     if (m_InputTensorDataFilePaths.size() != 0)
     {
         if (!ValidatePaths(m_InputTensorDataFilePaths, true))
         {
             throw armnn::InvalidArgumentException("One or more input data file paths are not valid.");
         }

         if (m_InputTensorDataFilePaths.size() < m_InputNames.size())
         {
             throw armnn::InvalidArgumentException(
                     fmt::format("According to the number of input names the user provided the network has {} "
                                 "inputs. But only {} input-tensor-data file paths were provided. Each input of the "
                                 "model is expected to be stored in it's own file.",
                                 m_InputNames.size(),
                                 m_InputTensorDataFilePaths.size()));
         }
         else if (m_InputTensorDataFilePaths.size() % m_InputNames.size() != 0)
         {
             throw armnn::InvalidArgumentException(
                     fmt::format("According to the number of input names the user provided the network has {} "
                                 "inputs. The user specified {} input-tensor-data file paths which is not "
                                 "divisible by the number of inputs.",
                                 m_InputNames.size(),
                                 m_InputTensorDataFilePaths.size()));
         }
     }

     if (m_InputTypes.size() == 0)
     {
         //Defaults the value of all inputs to "float"
         m_InputTypes.assign(m_InputNames.size(), "float");
     }
     else if ((m_InputTypes.size() != 0) &&
              (m_InputTypes.size() != m_InputNames.size()))
     {
         throw armnn::InvalidArgumentException("input-name and input-type must have the same amount of elements.");
     }

     // Make sure that the number of input files given is divisible by the number of inputs of the model
     if (!(m_InputTensorDataFilePaths.size() % m_InputNames.size() == 0))
     {
         throw armnn::InvalidArgumentException(
                 fmt::format("The number of input-tensor-data files ({0}) is not divisible by the "
                             "number of inputs ({1} according to the number of input names).",
                             m_InputTensorDataFilePaths.size(),
                             m_InputNames.size()));
     }

     if (m_OutputTypes.size() == 0)
     {
         //Defaults the value of all outputs to "float"
         m_OutputTypes.assign(m_OutputNames.size(), "float");
     }
     else if ((m_OutputTypes.size() != 0) &&
              (m_OutputTypes.size() != m_OutputNames.size()))
     {
         throw armnn::InvalidArgumentException("output-name and output-type must have the same amount of elements.");
     }

     // Make sure that the number of output files given is equal to the number of outputs of the model
     // or equal to the number of outputs of the model multiplied with the number of iterations
     if (!m_OutputTensorFiles.empty())
     {
         if ((m_OutputTensorFiles.size() != m_OutputNames.size()) &&
             (m_OutputTensorFiles.size() != m_OutputNames.size() * m_Iterations))
         {
             std::stringstream errmsg;
             auto numOutputs = m_OutputNames.size();
             throw armnn::InvalidArgumentException(
                     fmt::format("The user provided {0} output-tensor files. The only allowed number of output-tensor "
                                 "files is the number of outputs of the network ({1} according to the number of "
                                 "output names) or the number of outputs multiplied with the number of times the "
                                 "network should be executed (NumOutputs * NumIterations = {1} * {2} = {3}).",
                                 m_OutputTensorFiles.size(),
                                 numOutputs,
                                 m_Iterations,
                                 numOutputs*m_Iterations));
         }
     }

     // Check that threshold time is not less than zero
     if (m_ThresholdTime < 0)
     {
         throw armnn::InvalidArgumentException("Threshold time supplied as a command line argument is less than zero.");
     }

     // Warn if ExecuteNetwork will generate dummy input data
     if (m_GenerateTensorData)
     {
         ARMNN_LOG(warning) << "No input files provided, input tensors will be filled with 0s.";
     }
 }

 #if defined(ARMNN_TFLITE_DELEGATE)
 /**
  * A utility method that populates a DelegateOptions object from this ExecuteNetworkParams.
  *
  * @return a populated armnnDelegate::DelegateOptions object.
  */
 armnnDelegate::DelegateOptions ExecuteNetworkParams::ToDelegateOptions() const
 {
     armnnDelegate::DelegateOptions delegateOptions(m_ComputeDevices);
     delegateOptions.SetDynamicBackendsPath(m_DynamicBackendsPath);
     delegateOptions.SetGpuProfilingState(m_EnableProfiling);

     armnn::OptimizerOptions options;
     options.m_ReduceFp32ToFp16 = m_EnableFp16TurboMode;
     options.m_ReduceFp32ToBf16 = m_EnableBf16TurboMode;
     options.m_Debug = m_PrintIntermediate;
     options.m_ProfilingEnabled = m_EnableProfiling;
     delegateOptions.SetInternalProfilingParams(m_EnableProfiling, armnn::ProfilingDetailsMethod::DetailsWithEvents);
     options.m_shapeInferenceMethod = armnn::ShapeInferenceMethod::ValidateOnly;
     if (m_InferOutputShape)
     {
         options.m_shapeInferenceMethod = armnn::ShapeInferenceMethod::InferAndValidate;
     }

     armnn::BackendOptions gpuAcc("GpuAcc",
                                  {
         { "FastMathEnabled", m_EnableFastMath },
         { "SaveCachedNetwork", m_SaveCachedNetwork },
         { "CachedNetworkFilePath", m_CachedNetworkFilePath },
         { "TuningLevel", m_TuningLevel},
         { "TuningFile", m_TuningPath.c_str()},
         { "KernelProfilingEnabled", m_EnableProfiling},
         { "MLGOTuningFilePath", m_MLGOTuningFilePath}
                                  });

     armnn::BackendOptions cpuAcc("CpuAcc",
                                  {
         { "FastMathEnabled", m_EnableFastMath },
         { "NumberOfThreads", m_NumberOfThreads }
                                  });
     options.m_ModelOptions.push_back(gpuAcc);
     options.m_ModelOptions.push_back(cpuAcc);

     delegateOptions.SetOptimizerOptions(options);

     // If v,visualize-optimized-model is enabled then construct a file name for the dot file.
     if (m_EnableLayerDetails)
     {
         fs::path filename = m_ModelPath;
         filename.replace_extension("dot");
         delegateOptions.SetSerializeToDot(filename);
     }

     return delegateOptions;
 }
 #endif
	//
	// Copyright © 2020 Arm Ltd and Contributors. All rights reserved.
	// SPDX-License-Identifier: MIT
	//

	#include "ExecuteNetworkParams.hpp"

	#include "NetworkExecutionUtils/NetworkExecutionUtils.hpp"
	#include <InferenceModel.hpp>
	#include <armnn/Logging.hpp>

	#include <fmt/format.h>

	bool IsModelBinary(const std::string& modelFormat)
	{
	// Parse model binary flag from the model-format string we got from the command-line
	if (modelFormat.find("binary") != std::string::npos)
	{
	return true;
	}
	else if (modelFormat.find("txt") != std::string::npos \|\| modelFormat.find("text") != std::string::npos)
	{
	return false;
	}
	else
	{
	throw armnn::InvalidArgumentException(fmt::format("Unknown model format: '{}'. "
	"Please include 'binary' or 'text'",
	modelFormat));
	}
	}

	void CheckModelFormat(const std::string& modelFormat)
	{
	// Forward to implementation based on the parser type
	if (modelFormat.find("armnn") != std::string::npos)
	{
	#if defined(ARMNN_SERIALIZER)
	#else
	throw armnn::InvalidArgumentException("Can't run model in armnn format without a "
	"built with serialization support.");
	#endif
	}
	else if (modelFormat.find("onnx") != std::string::npos)
	{
	#if defined(ARMNN_ONNX_PARSER)
	#else
	throw armnn::InvalidArgumentException("Can't run model in onnx format without a "
	"built with Onnx parser support.");
	#endif
	}
	else if (modelFormat.find("tflite") != std::string::npos)
	{
	#if defined(ARMNN_TF_LITE_PARSER)
	if (!IsModelBinary(modelFormat))
	{
	throw armnn::InvalidArgumentException(fmt::format("Unknown model format: '{}'. Only 'binary' "
	"format supported for tflite files",
	modelFormat));
	}
	#elif defined(ARMNN_TFLITE_DELEGATE)
	#else
	throw armnn::InvalidArgumentException("Can't run model in tflite format without a "
	"built with Tensorflow Lite parser support.");
	#endif
	}
	else
	{
	throw armnn::InvalidArgumentException(fmt::format("Unknown model format: '{}'. "
	"Please include 'tflite' or 'onnx'",
	modelFormat));
	}
	}

	void CheckClTuningParameter(const int& tuningLevel,
	const std::string& tuningPath,
	const std::vector<armnn::BackendId> computeDevices)
	{
	if (!tuningPath.empty())
	{
	if (tuningLevel == 0)
	{
	ARMNN_LOG(info) << "Using cl tuning file: " << tuningPath << "\n";
	if (!ValidatePath(tuningPath, true))
	{
	throw armnn::InvalidArgumentException("The tuning path is not valid");
	}
	}
	else if ((1 <= tuningLevel) && (tuningLevel <= 3))
	{
	ARMNN_LOG(info) << "Starting execution to generate a cl tuning file: " << tuningPath << "\n"
	<< "Tuning level in use: " << tuningLevel << "\n";
	}
	else if ((0 < tuningLevel) \|\| (tuningLevel > 3))
	{
	throw armnn::InvalidArgumentException(fmt::format("The tuning level {} is not valid.",
	tuningLevel));
	}

	// Ensure that a GpuAcc is enabled. Otherwise no tuning data are used or genereted
	// Only warn if it's not enabled
	auto it = std::find(computeDevices.begin(), computeDevices.end(), "GpuAcc");
	if (it == computeDevices.end())
	{
	ARMNN_LOG(warning) << "To use Cl Tuning the compute device GpuAcc needs to be active.";
	}
	}

	}

	void ExecuteNetworkParams::ValidateParams()
	{
	if (m_DynamicBackendsPath == "")
	{
	// Check compute devices are valid unless they are dynamically loaded at runtime
	std::string invalidBackends;
	if (!CheckRequestedBackendsAreValid(m_ComputeDevices, armnn::Optional<std::string&>(invalidBackends)))
	{
	ARMNN_LOG(fatal) << "The list of preferred devices contains invalid backend IDs: "
	<< invalidBackends;
	}
	}

	CheckClTuningParameter(m_TuningLevel, m_TuningPath, m_ComputeDevices);

	if (m_EnableBf16TurboMode && m_EnableFp16TurboMode)
	{
	throw armnn::InvalidArgumentException("BFloat16 and Float16 turbo mode cannot be "
	"enabled at the same time.");
	}

	m_IsModelBinary = IsModelBinary(m_ModelFormat);

	CheckModelFormat(m_ModelFormat);

	// Check input tensor shapes
	if ((m_InputTensorShapes.size() != 0) &&
	(m_InputTensorShapes.size() != m_InputNames.size()))
	{
	throw armnn::InvalidArgumentException("input-name and input-tensor-shape must have "
	"the same amount of elements. ");
	}

	if (m_InputTensorDataFilePaths.size() != 0)
	{
	if (!ValidatePaths(m_InputTensorDataFilePaths, true))
	{
	throw armnn::InvalidArgumentException("One or more input data file paths are not valid.");
	}

	if (m_InputTensorDataFilePaths.size() < m_InputNames.size())
	{
	throw armnn::InvalidArgumentException(
	fmt::format("According to the number of input names the user provided the network has {} "
	"inputs. But only {} input-tensor-data file paths were provided. Each input of the "
	"model is expected to be stored in it's own file.",
	m_InputNames.size(),
	m_InputTensorDataFilePaths.size()));
	}
	else if (m_InputTensorDataFilePaths.size() % m_InputNames.size() != 0)
	{
	throw armnn::InvalidArgumentException(
	fmt::format("According to the number of input names the user provided the network has {} "
	"inputs. The user specified {} input-tensor-data file paths which is not "
	"divisible by the number of inputs.",
	m_InputNames.size(),
	m_InputTensorDataFilePaths.size()));
	}
	}

	if (m_InputTypes.size() == 0)
	{
	//Defaults the value of all inputs to "float"
	m_InputTypes.assign(m_InputNames.size(), "float");
	}
	else if ((m_InputTypes.size() != 0) &&
	(m_InputTypes.size() != m_InputNames.size()))
	{
	throw armnn::InvalidArgumentException("input-name and input-type must have the same amount of elements.");
	}

	// Make sure that the number of input files given is divisible by the number of inputs of the model
	if (!(m_InputTensorDataFilePaths.size() % m_InputNames.size() == 0))
	{
	throw armnn::InvalidArgumentException(
	fmt::format("The number of input-tensor-data files ({0}) is not divisible by the "
	"number of inputs ({1} according to the number of input names).",
	m_InputTensorDataFilePaths.size(),
	m_InputNames.size()));
	}

	if (m_OutputTypes.size() == 0)
	{
	//Defaults the value of all outputs to "float"
	m_OutputTypes.assign(m_OutputNames.size(), "float");
	}
	else if ((m_OutputTypes.size() != 0) &&
	(m_OutputTypes.size() != m_OutputNames.size()))
	{
	throw armnn::InvalidArgumentException("output-name and output-type must have the same amount of elements.");
	}

	// Make sure that the number of output files given is equal to the number of outputs of the model
	// or equal to the number of outputs of the model multiplied with the number of iterations
	if (!m_OutputTensorFiles.empty())
	{
	if ((m_OutputTensorFiles.size() != m_OutputNames.size()) &&
	(m_OutputTensorFiles.size() != m_OutputNames.size() * m_Iterations))
	{
	std::stringstream errmsg;
	auto numOutputs = m_OutputNames.size();
	throw armnn::InvalidArgumentException(
	fmt::format("The user provided {0} output-tensor files. The only allowed number of output-tensor "
	"files is the number of outputs of the network ({1} according to the number of "
	"output names) or the number of outputs multiplied with the number of times the "
	"network should be executed (NumOutputs * NumIterations = {1} * {2} = {3}).",
	m_OutputTensorFiles.size(),
	numOutputs,
	m_Iterations,
	numOutputs*m_Iterations));
	}
	}

	// Check that threshold time is not less than zero
	if (m_ThresholdTime < 0)
	{
	throw armnn::InvalidArgumentException("Threshold time supplied as a command line argument is less than zero.");
	}

	// Warn if ExecuteNetwork will generate dummy input data
	if (m_GenerateTensorData)
	{
	ARMNN_LOG(warning) << "No input files provided, input tensors will be filled with 0s.";
	}
	}

	#if defined(ARMNN_TFLITE_DELEGATE)
	/**
	* A utility method that populates a DelegateOptions object from this ExecuteNetworkParams.
	*
	* @return a populated armnnDelegate::DelegateOptions object.
	*/
	armnnDelegate::DelegateOptions ExecuteNetworkParams::ToDelegateOptions() const
	{
	armnnDelegate::DelegateOptions delegateOptions(m_ComputeDevices);
	delegateOptions.SetDynamicBackendsPath(m_DynamicBackendsPath);
	delegateOptions.SetGpuProfilingState(m_EnableProfiling);

	armnn::OptimizerOptions options;
	options.m_ReduceFp32ToFp16 = m_EnableFp16TurboMode;
	options.m_ReduceFp32ToBf16 = m_EnableBf16TurboMode;
	options.m_Debug = m_PrintIntermediate;
	options.m_ProfilingEnabled = m_EnableProfiling;
	delegateOptions.SetInternalProfilingParams(m_EnableProfiling, armnn::ProfilingDetailsMethod::DetailsWithEvents);
	options.m_shapeInferenceMethod = armnn::ShapeInferenceMethod::ValidateOnly;
	if (m_InferOutputShape)
	{
	options.m_shapeInferenceMethod = armnn::ShapeInferenceMethod::InferAndValidate;
	}

	armnn::BackendOptions gpuAcc("GpuAcc",
	{
	{ "FastMathEnabled", m_EnableFastMath },
	{ "SaveCachedNetwork", m_SaveCachedNetwork },
	{ "CachedNetworkFilePath", m_CachedNetworkFilePath },
	{ "TuningLevel", m_TuningLevel},
	{ "TuningFile", m_TuningPath.c_str()},
	{ "KernelProfilingEnabled", m_EnableProfiling},
	{ "MLGOTuningFilePath", m_MLGOTuningFilePath}
	});

	armnn::BackendOptions cpuAcc("CpuAcc",
	{
	{ "FastMathEnabled", m_EnableFastMath },
	{ "NumberOfThreads", m_NumberOfThreads }
	});
	options.m_ModelOptions.push_back(gpuAcc);
	options.m_ModelOptions.push_back(cpuAcc);

	delegateOptions.SetOptimizerOptions(options);

	// If v,visualize-optimized-model is enabled then construct a file name for the dot file.
	if (m_EnableLayerDetails)
	{
	fs::path filename = m_ModelPath;
	filename.replace_extension("dot");
	delegateOptions.SetSerializeToDot(filename);
	}

	return delegateOptions;
	}
	#endif