src/armnnTestUtils/CommonTestUtils.hpp - ml/armnn - Gitiles

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

 #pragma once

 #include "TestUtils.hpp"

 #include <Graph.hpp>
 #include <ResolveType.hpp>
 #include <SubgraphViewSelector.hpp>

 #include <armnn/BackendRegistry.hpp>
 #include <armnn/Types.hpp>
 #include <armnn/backends/SubgraphView.hpp>
 #include <armnn/backends/TensorHandle.hpp>

 #include <algorithm>
 #include <random>
 #include <vector>

 // Checks that two collections have the exact same contents (in any order)
 // The given collections do not have to contain duplicates
 // Cannot use std::sort here because std lists have their own std::list::sort method
 template <typename CollectionType>
 bool AreEqual(const CollectionType& lhs, const CollectionType& rhs)
 {
     if (lhs.size() != rhs.size())
     {
         return false;
     }

     auto lhs_it = std::find_if(lhs.begin(), lhs.end(), [&rhs](auto& item)
     {
         return std::find(rhs.begin(), rhs.end(), item) == rhs.end();
     });

     return lhs_it == lhs.end();
 }

 // Checks that the given collection contains the specified item
 template <typename CollectionType>
 bool Contains(const CollectionType& collection, const typename CollectionType::value_type& item)
 {
     return std::find(collection.begin(), collection.end(), item) != collection.end();
 }

 // Checks that the given map contains the specified key
 template <typename MapType>
 bool Contains(const MapType& map, const typename MapType::key_type& key)
 {
     return map.find(key) != map.end();
 }

 // Utility template for comparing tensor elements
 template<armnn::DataType ArmnnType, typename T = armnn::ResolveType<ArmnnType>>
 inline bool Compare(T a, T b, float tolerance = 0.000001f)
 {
     if (ArmnnType == armnn::DataType::Boolean)
     {
         // NOTE: Boolean is represented as uint8_t (with zero equals
         // false and everything else equals true), therefore values
         // need to be casted to bool before comparing them
         return static_cast<bool>(a) == static_cast<bool>(b);
     }

     // NOTE: All other types can be cast to float and compared with
     // a certain level of tolerance
     return std::fabs(static_cast<float>(a) - static_cast<float>(b)) <= tolerance;
 }

 template <typename ConvolutionLayer>
 void SetWeightAndBias(ConvolutionLayer* layer, const armnn::TensorInfo& weightInfo, const armnn::TensorInfo& biasInfo)
 {
     layer->m_Weight = std::make_unique<armnn::ScopedTensorHandle>(weightInfo);
     layer->m_Bias   = std::make_unique<armnn::ScopedTensorHandle>(biasInfo);

     layer->m_Weight->Allocate();
     layer->m_Bias->Allocate();
 }
 armnn::SubgraphView::InputSlots CreateInputsFrom(armnn::Layer* layer,
                                                  std::vector<unsigned int> ignoreSlots = {});

 armnn::SubgraphView::InputSlots CreateInputsFrom(const std::vector<armnn::Layer*>& layers,
                                                  std::vector<unsigned int> ignoreSlots = {});

 armnn::SubgraphView::OutputSlots CreateOutputsFrom(const std::vector<armnn::Layer*>& layers);

 armnn::SubgraphView::SubgraphViewPtr CreateSubgraphViewFrom(armnn::SubgraphView::InputSlots&& inputs,
                                                             armnn::SubgraphView::OutputSlots&& outputs,
                                                             armnn::SubgraphView::Layers&& layers);

 armnn::IBackendInternalUniquePtr CreateBackendObject(const armnn::BackendId& backendId);

 armnn::TensorShape MakeTensorShape(unsigned int batches,
                                    unsigned int channels,
                                    unsigned int height,
                                    unsigned int width,
                                    armnn::DataLayout layout);

 template<typename DataType>
 static std::vector<DataType> GenerateRandomData(size_t size)
 {
     constexpr bool isIntegerType = std::is_integral<DataType>::value;
     using Distribution =
     typename std::conditional<isIntegerType,
             std::uniform_int_distribution<DataType>,
             std::uniform_real_distribution<DataType>>::type;

     static constexpr DataType lowerLimit = std::numeric_limits<DataType>::min();
     static constexpr DataType upperLimit = std::numeric_limits<DataType>::max();

     static Distribution distribution(lowerLimit, upperLimit);
     static std::default_random_engine generator;

     std::vector<DataType> randomData(size);
     generate(randomData.begin(), randomData.end(), []() { return distribution(generator); });

     return randomData;
 }
	//
	// Copyright © 2017 Arm Ltd and Contributors. All rights reserved.
	// SPDX-License-Identifier: MIT
	//

	#pragma once

	#include "TestUtils.hpp"

	#include <Graph.hpp>
	#include <ResolveType.hpp>
	#include <SubgraphViewSelector.hpp>

	#include <armnn/BackendRegistry.hpp>
	#include <armnn/Types.hpp>
	#include <armnn/backends/SubgraphView.hpp>
	#include <armnn/backends/TensorHandle.hpp>

	#include <algorithm>
	#include <random>
	#include <vector>

	// Checks that two collections have the exact same contents (in any order)
	// The given collections do not have to contain duplicates
	// Cannot use std::sort here because std lists have their own std::list::sort method
	template <typename CollectionType>
	bool AreEqual(const CollectionType& lhs, const CollectionType& rhs)
	{
	if (lhs.size() != rhs.size())
	{
	return false;
	}

	auto lhs_it = std::find_if(lhs.begin(), lhs.end(), [&rhs](auto& item)
	{
	return std::find(rhs.begin(), rhs.end(), item) == rhs.end();
	});

	return lhs_it == lhs.end();
	}

	// Checks that the given collection contains the specified item
	template <typename CollectionType>
	bool Contains(const CollectionType& collection, const typename CollectionType::value_type& item)
	{
	return std::find(collection.begin(), collection.end(), item) != collection.end();
	}

	// Checks that the given map contains the specified key
	template <typename MapType>
	bool Contains(const MapType& map, const typename MapType::key_type& key)
	{
	return map.find(key) != map.end();
	}

	// Utility template for comparing tensor elements
	template<armnn::DataType ArmnnType, typename T = armnn::ResolveType<ArmnnType>>
	inline bool Compare(T a, T b, float tolerance = 0.000001f)
	{
	if (ArmnnType == armnn::DataType::Boolean)
	{
	// NOTE: Boolean is represented as uint8_t (with zero equals
	// false and everything else equals true), therefore values
	// need to be casted to bool before comparing them
	return static_cast<bool>(a) == static_cast<bool>(b);
	}

	// NOTE: All other types can be cast to float and compared with
	// a certain level of tolerance
	return std::fabs(static_cast<float>(a) - static_cast<float>(b)) <= tolerance;
	}

	template <typename ConvolutionLayer>
	void SetWeightAndBias(ConvolutionLayer* layer, const armnn::TensorInfo& weightInfo, const armnn::TensorInfo& biasInfo)
	{
	layer->m_Weight = std::make_unique<armnn::ScopedTensorHandle>(weightInfo);
	layer->m_Bias = std::make_unique<armnn::ScopedTensorHandle>(biasInfo);

	layer->m_Weight->Allocate();
	layer->m_Bias->Allocate();
	}
	armnn::SubgraphView::InputSlots CreateInputsFrom(armnn::Layer* layer,
	std::vector<unsigned int> ignoreSlots = {});

	armnn::SubgraphView::InputSlots CreateInputsFrom(const std::vector<armnn::Layer*>& layers,
	std::vector<unsigned int> ignoreSlots = {});

	armnn::SubgraphView::OutputSlots CreateOutputsFrom(const std::vector<armnn::Layer*>& layers);

	armnn::SubgraphView::SubgraphViewPtr CreateSubgraphViewFrom(armnn::SubgraphView::InputSlots&& inputs,
	armnn::SubgraphView::OutputSlots&& outputs,
	armnn::SubgraphView::Layers&& layers);

	armnn::IBackendInternalUniquePtr CreateBackendObject(const armnn::BackendId& backendId);

	armnn::TensorShape MakeTensorShape(unsigned int batches,
	unsigned int channels,
	unsigned int height,
	unsigned int width,
	armnn::DataLayout layout);

	template<typename DataType>
	static std::vector<DataType> GenerateRandomData(size_t size)
	{
	constexpr bool isIntegerType = std::is_integral<DataType>::value;
	using Distribution =
	typename std::conditional<isIntegerType,
	std::uniform_int_distribution<DataType>,
	std::uniform_real_distribution<DataType>>::type;

	static constexpr DataType lowerLimit = std::numeric_limits<DataType>::min();
	static constexpr DataType upperLimit = std::numeric_limits<DataType>::max();

	static Distribution distribution(lowerLimit, upperLimit);
	static std::default_random_engine generator;

	std::vector<DataType> randomData(size);
	generate(randomData.begin(), randomData.end(), []() { return distribution(generator); });

	return randomData;
	}