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//
// Copyright © 2017 Arm Ltd. All rights reserved.
// SPDX-License-Identifier: MIT
//
#pragma once
#include <armnn/ArmNN.hpp>
#if defined(ARMNN_TF_LITE_PARSER)
#include <armnnTfLiteParser/ITfLiteParser.hpp>
#endif
#include <HeapProfiling.hpp>
#if defined(ARMNN_ONNX_PARSER)
#include <armnnOnnxParser/IOnnxParser.hpp>
#endif
#include <backends/backendsCommon/BackendRegistry.hpp>
#include <boost/exception/exception.hpp>
#include <boost/exception/diagnostic_information.hpp>
#include <boost/log/trivial.hpp>
#include <boost/format.hpp>
#include <boost/program_options.hpp>
#include <boost/filesystem.hpp>
#include <boost/lexical_cast.hpp>
#include <fstream>
#include <map>
#include <string>
#include <type_traits>
namespace
{
inline bool CheckRequestedBackendsAreValid(const std::vector<armnn::BackendId>& backendIds,
armnn::Optional<std::string&> invalidBackendIds = armnn::EmptyOptional())
{
if (backendIds.empty())
{
return false;
}
armnn::BackendIdSet validBackendIds = armnn::BackendRegistryInstance().GetBackendIds();
bool allValid = true;
for (const auto& backendId : backendIds)
{
if (std::find(validBackendIds.begin(), validBackendIds.end(), backendId) == validBackendIds.end())
{
allValid = false;
if (invalidBackendIds)
{
if (!invalidBackendIds.value().empty())
{
invalidBackendIds.value() += ", ";
}
invalidBackendIds.value() += backendId;
}
}
}
return allValid;
}
} // anonymous namespace
namespace InferenceModelInternal
{
// This needs to go when the armnnCaffeParser, armnnTfParser and armnnTfLiteParser
// definitions of BindingPointInfo gets consolidated.
using BindingPointInfo = std::pair<armnn::LayerBindingId, armnn::TensorInfo>;
using QuantizationParams = std::pair<float,int32_t>;
struct Params
{
std::string m_ModelPath;
std::string m_InputBinding;
std::string m_OutputBinding;
const armnn::TensorShape* m_InputTensorShape;
std::vector<armnn::BackendId> m_ComputeDevice;
bool m_EnableProfiling;
size_t m_SubgraphId;
bool m_IsModelBinary;
bool m_VisualizePostOptimizationModel;
bool m_EnableFp16TurboMode;
Params()
: m_InputTensorShape(nullptr)
, m_ComputeDevice{armnn::Compute::CpuRef}
, m_EnableProfiling(false)
, m_SubgraphId(0)
, m_IsModelBinary(true)
, m_VisualizePostOptimizationModel(false)
, m_EnableFp16TurboMode(false)
{}
};
} // namespace InferenceModelInternal
template <typename IParser>
struct CreateNetworkImpl
{
public:
using Params = InferenceModelInternal::Params;
using BindingPointInfo = InferenceModelInternal::BindingPointInfo;
static armnn::INetworkPtr Create(const Params& params,
BindingPointInfo& inputBindings,
BindingPointInfo& outputBindings)
{
const std::string& modelPath = params.m_ModelPath;
// Create a network from a file on disk
auto parser(IParser::Create());
std::map<std::string, armnn::TensorShape> inputShapes;
if (params.m_InputTensorShape)
{
inputShapes[params.m_InputBinding] = *params.m_InputTensorShape;
}
std::vector<std::string> requestedOutputs{ params.m_OutputBinding };
armnn::INetworkPtr network{nullptr, [](armnn::INetwork *){}};
{
ARMNN_SCOPED_HEAP_PROFILING("Parsing");
// Handle text and binary input differently by calling the corresponding parser function
network = (params.m_IsModelBinary ?
parser->CreateNetworkFromBinaryFile(modelPath.c_str(), inputShapes, requestedOutputs) :
parser->CreateNetworkFromTextFile(modelPath.c_str(), inputShapes, requestedOutputs));
}
inputBindings = parser->GetNetworkInputBindingInfo(params.m_InputBinding);
outputBindings = parser->GetNetworkOutputBindingInfo(params.m_OutputBinding);
return network;
}
};
#if defined(ARMNN_TF_LITE_PARSER)
template <>
struct CreateNetworkImpl<armnnTfLiteParser::ITfLiteParser>
{
public:
using IParser = armnnTfLiteParser::ITfLiteParser;
using Params = InferenceModelInternal::Params;
using BindingPointInfo = InferenceModelInternal::BindingPointInfo;
static armnn::INetworkPtr Create(const Params& params,
BindingPointInfo& inputBindings,
BindingPointInfo& outputBindings)
{
const std::string& modelPath = params.m_ModelPath;
// Create a network from a file on disk
auto parser(IParser::Create());
armnn::INetworkPtr network{nullptr, [](armnn::INetwork *){}};
{
ARMNN_SCOPED_HEAP_PROFILING("Parsing");
network = parser->CreateNetworkFromBinaryFile(modelPath.c_str());
}
inputBindings = parser->GetNetworkInputBindingInfo(params.m_SubgraphId, params.m_InputBinding);
outputBindings = parser->GetNetworkOutputBindingInfo(params.m_SubgraphId, params.m_OutputBinding);
return network;
}
};
#endif
#if defined(ARMNN_ONNX_PARSER)
template <>
struct CreateNetworkImpl<armnnOnnxParser::IOnnxParser>
{
public:
using IParser = armnnOnnxParser::IOnnxParser;
using Params = InferenceModelInternal::Params;
using BindingPointInfo = InferenceModelInternal::BindingPointInfo;
static armnn::INetworkPtr Create(const Params& params,
BindingPointInfo& inputBindings,
BindingPointInfo& outputBindings)
{
const std::string& modelPath = params.m_ModelPath;
// Create a network from a file on disk
auto parser(IParser::Create());
armnn::INetworkPtr network{nullptr, [](armnn::INetwork *){}};
{
ARMNN_SCOPED_HEAP_PROFILING("Parsing");
network = (params.m_IsModelBinary ?
parser->CreateNetworkFromBinaryFile(modelPath.c_str()) :
parser->CreateNetworkFromTextFile(modelPath.c_str()));
}
inputBindings = parser->GetNetworkInputBindingInfo(params.m_InputBinding);
outputBindings = parser->GetNetworkOutputBindingInfo(params.m_OutputBinding);
return network;
}
};
#endif
template<typename TContainer>
inline armnn::InputTensors MakeInputTensors(const InferenceModelInternal::BindingPointInfo& input,
const TContainer& inputTensorData)
{
if (inputTensorData.size() != input.second.GetNumElements())
{
try
{
throw armnn::Exception(boost::str(boost::format("Input tensor has incorrect size. Expected %1% elements "
"but got %2%.") % input.second.GetNumElements() % inputTensorData.size()));
} catch (const boost::exception& e)
{
// Coverity fix: it should not be possible to get here but boost::str and boost::format can both
// throw uncaught exceptions, convert them to armnn exceptions and rethrow.
throw armnn::Exception(diagnostic_information(e));
}
}
return { { input.first, armnn::ConstTensor(input.second, inputTensorData.data()) } };
}
template<typename TContainer>
inline armnn::OutputTensors MakeOutputTensors(const InferenceModelInternal::BindingPointInfo& output,
TContainer& outputTensorData)
{
if (outputTensorData.size() != output.second.GetNumElements())
{
throw armnn::Exception("Output tensor has incorrect size");
}
return { { output.first, armnn::Tensor(output.second, outputTensorData.data()) } };
}
template <typename IParser, typename TDataType>
class InferenceModel
{
public:
using DataType = TDataType;
using Params = InferenceModelInternal::Params;
struct CommandLineOptions
{
std::string m_ModelDir;
std::vector<armnn::BackendId> m_ComputeDevice;
bool m_VisualizePostOptimizationModel;
bool m_EnableFp16TurboMode;
};
static void AddCommandLineOptions(boost::program_options::options_description& desc, CommandLineOptions& options)
{
namespace po = boost::program_options;
std::vector<armnn::BackendId> defaultBackends = {armnn::Compute::CpuAcc, armnn::Compute::CpuRef};
const std::string backendsMessage = "Which device to run layers on by default. Possible choices: "
+ armnn::BackendRegistryInstance().GetBackendIdsAsString();
desc.add_options()
("model-dir,m", po::value<std::string>(&options.m_ModelDir)->required(),
"Path to directory containing model files (.caffemodel/.prototxt/.tflite)")
("compute,c", po::value<std::vector<armnn::BackendId>>(&options.m_ComputeDevice)->default_value
(defaultBackends), backendsMessage.c_str())
("visualize-optimized-model,v",
po::value<bool>(&options.m_VisualizePostOptimizationModel)->default_value(false),
"Produce a dot file useful for visualizing the graph post optimization."
"The file will have the same name as the model with the .dot extention.")
("fp16-turbo-mode", po::value<bool>(&options.m_EnableFp16TurboMode)->default_value(false),
"If this option is enabled FP32 layers, weights and biases will be converted "
"to FP16 where the backend supports it.");
}
InferenceModel(const Params& params, const std::shared_ptr<armnn::IRuntime>& runtime = nullptr)
: m_EnableProfiling(params.m_EnableProfiling)
{
if (runtime)
{
m_Runtime = runtime;
}
else
{
armnn::IRuntime::CreationOptions options;
options.m_EnableGpuProfiling = m_EnableProfiling;
m_Runtime = std::move(armnn::IRuntime::Create(options));
}
std::string invalidBackends;
if (!CheckRequestedBackendsAreValid(params.m_ComputeDevice, armnn::Optional<std::string&>(invalidBackends)))
{
throw armnn::Exception("Some backend IDs are invalid: " + invalidBackends);
}
armnn::INetworkPtr network = CreateNetworkImpl<IParser>::Create(params, m_InputBindingInfo,
m_OutputBindingInfo);
armnn::IOptimizedNetworkPtr optNet{nullptr, [](armnn::IOptimizedNetwork *){}};
{
ARMNN_SCOPED_HEAP_PROFILING("Optimizing");
armnn::OptimizerOptions options;
options.m_ReduceFp32ToFp16 = params.m_EnableFp16TurboMode;
optNet = armnn::Optimize(*network, params.m_ComputeDevice, m_Runtime->GetDeviceSpec(), options);
if (!optNet)
{
throw armnn::Exception("Optimize returned nullptr");
}
}
if (params.m_VisualizePostOptimizationModel)
{
boost::filesystem::path filename = params.m_ModelPath;
filename.replace_extension("dot");
std::fstream file(filename.c_str(),file.out);
optNet->SerializeToDot(file);
}
armnn::Status ret;
{
ARMNN_SCOPED_HEAP_PROFILING("LoadNetwork");
ret = m_Runtime->LoadNetwork(m_NetworkIdentifier, std::move(optNet));
}
if (ret == armnn::Status::Failure)
{
throw armnn::Exception("IRuntime::LoadNetwork failed");
}
}
unsigned int GetOutputSize() const
{
return m_OutputBindingInfo.second.GetNumElements();
}
void Run(const std::vector<TDataType>& input, std::vector<TDataType>& output)
{
BOOST_ASSERT(output.size() == GetOutputSize());
std::shared_ptr<armnn::IProfiler> profiler = m_Runtime->GetProfiler(m_NetworkIdentifier);
if (profiler)
{
profiler->EnableProfiling(m_EnableProfiling);
}
armnn::Status ret = m_Runtime->EnqueueWorkload(m_NetworkIdentifier,
MakeInputTensors(input),
MakeOutputTensors(output));
// if profiling is enabled print out the results
if (profiler && profiler->IsProfilingEnabled())
{
profiler->Print(std::cout);
}
if (ret == armnn::Status::Failure)
{
throw armnn::Exception("IRuntime::EnqueueWorkload failed");
}
}
const InferenceModelInternal::BindingPointInfo & GetInputBindingInfo() const
{
return m_InputBindingInfo;
}
const InferenceModelInternal::BindingPointInfo & GetOutputBindingInfo() const
{
return m_OutputBindingInfo;
}
InferenceModelInternal::QuantizationParams GetQuantizationParams() const
{
return std::make_pair(m_OutputBindingInfo.second.GetQuantizationScale(),
m_OutputBindingInfo.second.GetQuantizationOffset());
}
private:
armnn::NetworkId m_NetworkIdentifier;
std::shared_ptr<armnn::IRuntime> m_Runtime;
InferenceModelInternal::BindingPointInfo m_InputBindingInfo;
InferenceModelInternal::BindingPointInfo m_OutputBindingInfo;
bool m_EnableProfiling;
template<typename TContainer>
armnn::InputTensors MakeInputTensors(const TContainer& inputTensorData)
{
return ::MakeInputTensors(m_InputBindingInfo, inputTensorData);
}
template<typename TContainer>
armnn::OutputTensors MakeOutputTensors(TContainer& outputTensorData)
{
return ::MakeOutputTensors(m_OutputBindingInfo, outputTensorData);
}
};
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