// // Copyright © 2020 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #include "ExecuteNetworkParams.hpp" #include "NetworkExecutionUtils/NetworkExecutionUtils.hpp" #include #include #include 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 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() { // Set to true if it is preferred to throw an exception rather than use ARMNN_LOG bool throwExc = false; try { if (m_DynamicBackendsPath == "") { // Check compute devices are valid unless they are dynamically loaded at runtime std::string invalidBackends; if (!CheckRequestedBackendsAreValid(m_ComputeDevices, armnn::Optional(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) { ARMNN_LOG(fatal) << "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())) { ARMNN_LOG(fatal) << "input-name and input-tensor-shape must have the same amount of elements. "; } if (m_InputTensorDataFilePaths.size() != 0) { if (!ValidatePaths(m_InputTensorDataFilePaths, true)) { ARMNN_LOG(fatal) << "One or more input data file paths are not valid. "; } if (!m_Concurrent && m_InputTensorDataFilePaths.size() != m_InputNames.size()) { ARMNN_LOG(fatal) << "input-name and input-tensor-data must have the same amount of elements. "; } if (m_InputTensorDataFilePaths.size() < m_SimultaneousIterations * m_InputNames.size()) { ARMNN_LOG(fatal) << "There is not enough input data for " << m_SimultaneousIterations << " execution."; } if (m_InputTensorDataFilePaths.size() > m_SimultaneousIterations * m_InputNames.size()) { ARMNN_LOG(fatal) << "There is more input data for " << m_SimultaneousIterations << " execution."; } } if ((m_OutputTensorFiles.size() != 0) && (m_OutputTensorFiles.size() != m_OutputNames.size())) { ARMNN_LOG(fatal) << "output-name and write-outputs-to-file must have the same amount of elements. "; } if ((m_OutputTensorFiles.size() != 0) && m_OutputTensorFiles.size() != m_SimultaneousIterations * m_OutputNames.size()) { ARMNN_LOG(fatal) << "There is not enough output data for " << m_SimultaneousIterations << " execution."; } 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())) { ARMNN_LOG(fatal) << "input-name and input-type must have the same amount of elements."; } 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())) { ARMNN_LOG(fatal) << "output-name and output-type must have the same amount of elements."; } // Check that threshold time is not less than zero if (m_ThresholdTime < 0) { ARMNN_LOG(fatal) << "Threshold time supplied as a command line argument is less than zero."; } } catch (std::string& exc) { if (throwExc) { throw armnn::InvalidArgumentException(exc); } else { std::cout << exc; exit(EXIT_FAILURE); } } // Check turbo modes // 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."; } }