src/backends/backendsCommon/test/BatchNormTestImpl.hpp - platform/external/armnn - Git at Google

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

 #include <ResolveType.hpp>
 #include "WorkloadTestUtils.hpp"

 #include <armnn/ArmNN.hpp>
 #include <armnn/Tensor.hpp>

 #include <backendsCommon/CpuTensorHandle.hpp>
 #include <backendsCommon/IBackendInternal.hpp>
 #include <backendsCommon/WorkloadFactory.hpp>
 #include <backendsCommon/test/QuantizeHelper.hpp>

 #include <test/TensorHelpers.hpp>

 #include <DataLayoutIndexed.hpp>

 template<armnn::DataType ArmnnType, typename T = armnn::ResolveType<ArmnnType>>
 LayerTestResult<T, 4> BatchNormTestImpl(
     armnn::IWorkloadFactory& workloadFactory,
     const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
     const armnn::TensorShape& inputOutputTensorShape,
     const std::vector<float>& inputValues,
     const std::vector<float>& expectedOutputValues,
     float qScale,
     int32_t qOffset,
     armnn::DataLayout dataLayout)
 {
     armnn::TensorInfo inputTensorInfo(inputOutputTensorShape, ArmnnType);
     armnn::TensorInfo outputTensorInfo(inputOutputTensorShape, ArmnnType);

     armnnUtils::DataLayoutIndexed dataLayoutIndexed(dataLayout);

     armnn::TensorInfo tensorInfo({ inputOutputTensorShape[dataLayoutIndexed.GetChannelsIndex()] },
                                  ArmnnType);

     // Set quantization parameters if the requested type is a quantized type.
     if (armnn::IsQuantizedType<T>())
     {
         inputTensorInfo.SetQuantizationScale(qScale);
         inputTensorInfo.SetQuantizationOffset(qOffset);
         outputTensorInfo.SetQuantizationScale(qScale);
         outputTensorInfo.SetQuantizationOffset(qOffset);
         tensorInfo.SetQuantizationScale(qScale);
         tensorInfo.SetQuantizationOffset(qOffset);
     }

     auto inputTensor = MakeTensor<T, 4>(inputTensorInfo,
                                         QuantizedVector<T>(qScale, qOffset, inputValues));

     // These values are per-channel of the input.
     auto mean     = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, -2}));
     auto variance = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {4,  9}));
     auto beta     = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3,  2}));
     auto gamma    = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {2,  1}));

     LayerTestResult<T, 4> result(outputTensorInfo);

     result.outputExpected = MakeTensor<T, 4>(inputTensorInfo,
                                              QuantizedVector<T>(qScale, qOffset, expectedOutputValues));

     std::unique_ptr<armnn::ITensorHandle> inputHandle = workloadFactory.CreateTensorHandle(inputTensorInfo);
     std::unique_ptr<armnn::ITensorHandle> outputHandle = workloadFactory.CreateTensorHandle(outputTensorInfo);

     armnn::ScopedCpuTensorHandle meanTensor(tensorInfo);
     armnn::ScopedCpuTensorHandle varianceTensor(tensorInfo);
     armnn::ScopedCpuTensorHandle betaTensor(tensorInfo);
     armnn::ScopedCpuTensorHandle gammaTensor(tensorInfo);

     armnn::BatchNormalizationQueueDescriptor descriptor;
     descriptor.m_Mean                    = &meanTensor;
     descriptor.m_Variance                = &varianceTensor;
     descriptor.m_Beta                    = &betaTensor;
     descriptor.m_Gamma                   = &gammaTensor;
     descriptor.m_Parameters.m_Eps        = 0.0f;
     descriptor.m_Parameters.m_DataLayout = dataLayout;
     armnn::WorkloadInfo info;

     AllocateAndCopyDataToITensorHandle(&meanTensor, &mean[0]);
     AllocateAndCopyDataToITensorHandle(&varianceTensor, &variance[0]);
     AllocateAndCopyDataToITensorHandle(&betaTensor, &beta[0]);
     AllocateAndCopyDataToITensorHandle(&gammaTensor, &gamma[0]);

     AddInputToWorkload(descriptor, info, inputTensorInfo, inputHandle.get());
     AddOutputToWorkload(descriptor, info, outputTensorInfo, outputHandle.get());

     std::unique_ptr<armnn::IWorkload> workload = workloadFactory.CreateBatchNormalization(descriptor, info);

     inputHandle->Allocate();
     outputHandle->Allocate();

     CopyDataToITensorHandle(inputHandle.get(), &inputTensor[0][0][0][0]);

     workload->Execute();

     CopyDataFromITensorHandle(&result.output[0][0][0][0], outputHandle.get());

     return result;
 }


 template<armnn::DataType ArmnnType, typename T = armnn::ResolveType<ArmnnType>>
 LayerTestResult<T,4> BatchNormTestNhwcImpl(
     armnn::IWorkloadFactory& workloadFactory,
     const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
     float qScale,
     int32_t qOffset)
 {
     const unsigned int width    = 2;
     const unsigned int height   = 3;
     const unsigned int channels = 2;
     const unsigned int num      = 1;

     armnn::TensorInfo inputTensorInfo({num, height, width, channels}, ArmnnType);
     armnn::TensorInfo outputTensorInfo({num, height, width, channels}, ArmnnType);
     armnn::TensorInfo tensorInfo({channels}, ArmnnType);

     // Set quantization parameters if the requested type is a quantized type.
     if(armnn::IsQuantizedType<T>())
     {
         inputTensorInfo.SetQuantizationScale(qScale);
         inputTensorInfo.SetQuantizationOffset(qOffset);
         outputTensorInfo.SetQuantizationScale(qScale);
         outputTensorInfo.SetQuantizationOffset(qOffset);
         tensorInfo.SetQuantizationScale(qScale);
         tensorInfo.SetQuantizationOffset(qOffset);
     }

     auto input = MakeTensor<T, 4>(inputTensorInfo,
         QuantizedVector<T>(qScale, qOffset,
         {
             1.f, 1.f, 4.f, 1.f,
             4.f, 4.f, 2.f, 1.f,
             1.f, -2.f, 6.f, 4.f
         }));
     // These values are per-channel of the input.
     auto mean     = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, -2}));
     auto variance = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {4, 9}));
     auto beta     = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, 2}));
     auto gamma    = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {2, 1}));
     LayerTestResult<T,4> ret(outputTensorInfo);

     std::unique_ptr<armnn::ITensorHandle> inputHandle = workloadFactory.CreateTensorHandle(inputTensorInfo);
     std::unique_ptr<armnn::ITensorHandle> outputHandle = workloadFactory.CreateTensorHandle(outputTensorInfo);

     armnn::BatchNormalizationQueueDescriptor data;
     armnn::WorkloadInfo info;
     armnn::ScopedCpuTensorHandle meanTensor(tensorInfo);
     armnn::ScopedCpuTensorHandle varianceTensor(tensorInfo);
     armnn::ScopedCpuTensorHandle betaTensor(tensorInfo);
     armnn::ScopedCpuTensorHandle gammaTensor(tensorInfo);

     AllocateAndCopyDataToITensorHandle(&meanTensor, &mean[0]);
     AllocateAndCopyDataToITensorHandle(&varianceTensor, &variance[0]);
     AllocateAndCopyDataToITensorHandle(&betaTensor, &beta[0]);
     AllocateAndCopyDataToITensorHandle(&gammaTensor, &gamma[0]);

     AddInputToWorkload(data, info, inputTensorInfo, inputHandle.get());
     AddOutputToWorkload(data, info, outputTensorInfo, outputHandle.get());
     data.m_Mean             = &meanTensor;
     data.m_Variance         = &varianceTensor;
     data.m_Beta             = &betaTensor;
     data.m_Gamma            = &gammaTensor;
     data.m_Parameters.m_Eps = 0.0f;
     data.m_Parameters.m_DataLayout = armnn::DataLayout::NHWC;

     // For each channel:
     // substract mean, divide by standard deviation (with an epsilon to avoid div by 0),
     // multiply by gamma and add beta
     ret.outputExpected = MakeTensor<T, 4>(outputTensorInfo,
         QuantizedVector<T>(qScale, qOffset,
         {
             1.f, 3.f, 4.f, 3.f,
             4.f, 4.f, 2.f, 3.f,
             1.f, 2.f, 6.f, 4.f
         }));

     std::unique_ptr<armnn::IWorkload> workload = workloadFactory.CreateBatchNormalization(data, info);

     inputHandle->Allocate();
     outputHandle->Allocate();

     CopyDataToITensorHandle(inputHandle.get(), &input[0][0][0][0]);

     workload->Execute();

     CopyDataFromITensorHandle(&ret.output[0][0][0][0], outputHandle.get());

     return ret;
 }
	//
	// Copyright © 2017 Arm Ltd. All rights reserved.
	// SPDX-License-Identifier: MIT
	//
	#pragma once

	#include <ResolveType.hpp>
	#include "WorkloadTestUtils.hpp"

	#include <armnn/ArmNN.hpp>
	#include <armnn/Tensor.hpp>

	#include <backendsCommon/CpuTensorHandle.hpp>
	#include <backendsCommon/IBackendInternal.hpp>
	#include <backendsCommon/WorkloadFactory.hpp>
	#include <backendsCommon/test/QuantizeHelper.hpp>

	#include <test/TensorHelpers.hpp>

	#include <DataLayoutIndexed.hpp>

	template<armnn::DataType ArmnnType, typename T = armnn::ResolveType<ArmnnType>>
	LayerTestResult<T, 4> BatchNormTestImpl(
	armnn::IWorkloadFactory& workloadFactory,
	const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
	const armnn::TensorShape& inputOutputTensorShape,
	const std::vector<float>& inputValues,
	const std::vector<float>& expectedOutputValues,
	float qScale,
	int32_t qOffset,
	armnn::DataLayout dataLayout)
	{
	armnn::TensorInfo inputTensorInfo(inputOutputTensorShape, ArmnnType);
	armnn::TensorInfo outputTensorInfo(inputOutputTensorShape, ArmnnType);

	armnnUtils::DataLayoutIndexed dataLayoutIndexed(dataLayout);

	armnn::TensorInfo tensorInfo({ inputOutputTensorShape[dataLayoutIndexed.GetChannelsIndex()] },
	ArmnnType);

	// Set quantization parameters if the requested type is a quantized type.
	if (armnn::IsQuantizedType<T>())
	{
	inputTensorInfo.SetQuantizationScale(qScale);
	inputTensorInfo.SetQuantizationOffset(qOffset);
	outputTensorInfo.SetQuantizationScale(qScale);
	outputTensorInfo.SetQuantizationOffset(qOffset);
	tensorInfo.SetQuantizationScale(qScale);
	tensorInfo.SetQuantizationOffset(qOffset);
	}

	auto inputTensor = MakeTensor<T, 4>(inputTensorInfo,
	QuantizedVector<T>(qScale, qOffset, inputValues));

	// These values are per-channel of the input.
	auto mean = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, -2}));
	auto variance = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {4, 9}));
	auto beta = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, 2}));
	auto gamma = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {2, 1}));

	LayerTestResult<T, 4> result(outputTensorInfo);

	result.outputExpected = MakeTensor<T, 4>(inputTensorInfo,
	QuantizedVector<T>(qScale, qOffset, expectedOutputValues));

	std::unique_ptr<armnn::ITensorHandle> inputHandle = workloadFactory.CreateTensorHandle(inputTensorInfo);
	std::unique_ptr<armnn::ITensorHandle> outputHandle = workloadFactory.CreateTensorHandle(outputTensorInfo);

	armnn::ScopedCpuTensorHandle meanTensor(tensorInfo);
	armnn::ScopedCpuTensorHandle varianceTensor(tensorInfo);
	armnn::ScopedCpuTensorHandle betaTensor(tensorInfo);
	armnn::ScopedCpuTensorHandle gammaTensor(tensorInfo);

	armnn::BatchNormalizationQueueDescriptor descriptor;
	descriptor.m_Mean = &meanTensor;
	descriptor.m_Variance = &varianceTensor;
	descriptor.m_Beta = &betaTensor;
	descriptor.m_Gamma = &gammaTensor;
	descriptor.m_Parameters.m_Eps = 0.0f;
	descriptor.m_Parameters.m_DataLayout = dataLayout;
	armnn::WorkloadInfo info;

	AllocateAndCopyDataToITensorHandle(&meanTensor, &mean[0]);
	AllocateAndCopyDataToITensorHandle(&varianceTensor, &variance[0]);
	AllocateAndCopyDataToITensorHandle(&betaTensor, &beta[0]);
	AllocateAndCopyDataToITensorHandle(&gammaTensor, &gamma[0]);

	AddInputToWorkload(descriptor, info, inputTensorInfo, inputHandle.get());
	AddOutputToWorkload(descriptor, info, outputTensorInfo, outputHandle.get());

	std::unique_ptr<armnn::IWorkload> workload = workloadFactory.CreateBatchNormalization(descriptor, info);

	inputHandle->Allocate();
	outputHandle->Allocate();

	CopyDataToITensorHandle(inputHandle.get(), &inputTensor[0][0][0][0]);

	workload->Execute();

	CopyDataFromITensorHandle(&result.output[0][0][0][0], outputHandle.get());

	return result;
	}


	template<armnn::DataType ArmnnType, typename T = armnn::ResolveType<ArmnnType>>
	LayerTestResult<T,4> BatchNormTestNhwcImpl(
	armnn::IWorkloadFactory& workloadFactory,
	const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
	float qScale,
	int32_t qOffset)
	{
	const unsigned int width = 2;
	const unsigned int height = 3;
	const unsigned int channels = 2;
	const unsigned int num = 1;

	armnn::TensorInfo inputTensorInfo({num, height, width, channels}, ArmnnType);
	armnn::TensorInfo outputTensorInfo({num, height, width, channels}, ArmnnType);
	armnn::TensorInfo tensorInfo({channels}, ArmnnType);

	// Set quantization parameters if the requested type is a quantized type.
	if(armnn::IsQuantizedType<T>())
	{
	inputTensorInfo.SetQuantizationScale(qScale);
	inputTensorInfo.SetQuantizationOffset(qOffset);
	outputTensorInfo.SetQuantizationScale(qScale);
	outputTensorInfo.SetQuantizationOffset(qOffset);
	tensorInfo.SetQuantizationScale(qScale);
	tensorInfo.SetQuantizationOffset(qOffset);
	}

	auto input = MakeTensor<T, 4>(inputTensorInfo,
	QuantizedVector<T>(qScale, qOffset,
	{
	1.f, 1.f, 4.f, 1.f,
	4.f, 4.f, 2.f, 1.f,
	1.f, -2.f, 6.f, 4.f
	}));
	// These values are per-channel of the input.
	auto mean = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, -2}));
	auto variance = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {4, 9}));
	auto beta = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {3, 2}));
	auto gamma = MakeTensor<T, 1>(tensorInfo, QuantizedVector<T>(qScale, qOffset, {2, 1}));
	LayerTestResult<T,4> ret(outputTensorInfo);

	std::unique_ptr<armnn::ITensorHandle> inputHandle = workloadFactory.CreateTensorHandle(inputTensorInfo);
	std::unique_ptr<armnn::ITensorHandle> outputHandle = workloadFactory.CreateTensorHandle(outputTensorInfo);

	armnn::BatchNormalizationQueueDescriptor data;
	armnn::WorkloadInfo info;
	armnn::ScopedCpuTensorHandle meanTensor(tensorInfo);
	armnn::ScopedCpuTensorHandle varianceTensor(tensorInfo);
	armnn::ScopedCpuTensorHandle betaTensor(tensorInfo);
	armnn::ScopedCpuTensorHandle gammaTensor(tensorInfo);

	AllocateAndCopyDataToITensorHandle(&meanTensor, &mean[0]);
	AllocateAndCopyDataToITensorHandle(&varianceTensor, &variance[0]);
	AllocateAndCopyDataToITensorHandle(&betaTensor, &beta[0]);
	AllocateAndCopyDataToITensorHandle(&gammaTensor, &gamma[0]);

	AddInputToWorkload(data, info, inputTensorInfo, inputHandle.get());
	AddOutputToWorkload(data, info, outputTensorInfo, outputHandle.get());
	data.m_Mean = &meanTensor;
	data.m_Variance = &varianceTensor;
	data.m_Beta = &betaTensor;
	data.m_Gamma = &gammaTensor;
	data.m_Parameters.m_Eps = 0.0f;
	data.m_Parameters.m_DataLayout = armnn::DataLayout::NHWC;

	// For each channel:
	// substract mean, divide by standard deviation (with an epsilon to avoid div by 0),
	// multiply by gamma and add beta
	ret.outputExpected = MakeTensor<T, 4>(outputTensorInfo,
	QuantizedVector<T>(qScale, qOffset,
	{
	1.f, 3.f, 4.f, 3.f,
	4.f, 4.f, 2.f, 3.f,
	1.f, 2.f, 6.f, 4.f
	}));

	std::unique_ptr<armnn::IWorkload> workload = workloadFactory.CreateBatchNormalization(data, info);

	inputHandle->Allocate();
	outputHandle->Allocate();

	CopyDataToITensorHandle(inputHandle.get(), &input[0][0][0][0]);

	workload->Execute();

	CopyDataFromITensorHandle(&ret.output[0][0][0][0], outputHandle.get());

	return ret;
	}