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review.mlplatform.org / ml / armnn / 5488cfaaa1a411cb5a18c81a98b90c6e3011abdc / . / src / backends / backendsCommon / test / TransposeConvolution2dTestImpl.hpp
blob: 3bbd5d67700caf5d41de9886684a19d33d413986 [file] [log] [blame]
//
// Copyright © 2017 Arm Ltd. All rights reserved.
// SPDX-License-Identifier: MIT
//
#pragma once
#include "QuantizeHelper.hpp"
#include <armnn/ArmNN.hpp>
#include <ResolveType.hpp>
#include <backendsCommon/CpuTensorHandle.hpp>
#include <backendsCommon/test/CommonTestUtils.hpp>
#include <backendsCommon/test/TensorCopyUtils.hpp>
#include <backendsCommon/test/WorkloadTestUtils.hpp>
#include <reference/RefWorkloadFactory.hpp>
#include <boost/test/unit_test.hpp>
#include <string>
#include <utility>
#include <vector>
namespace
{
template<typename T>
using TensorData = std::pair<armnn::TensorInfo, std::vector<T>>;
template<typename T>
void VerifyInputTensorData(const TensorData<T>& data, const std::string& tensorName)
{
if (data.first.GetNumElements() > data.second.size())
{
throw armnn::InvalidArgumentException("Size of data too small for " + tensorName + ": expected " +
std::to_string(data.first.GetNumElements()) + "but got " + std::to_string(data.second.size()));
}
}
template<typename T, typename BT>
void TransposeConvolution2dTestImpl(armnn::IWorkloadFactory& workloadFactory,
const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
const armnn::TransposeConvolution2dDescriptor& descriptor,
const TensorData<T>& input,
TensorData<T>& output,
const TensorData<T>& weights,
const armnn::Optional<TensorData<BT>>& biases)
{
using namespace armnn;
VerifyInputTensorData(input, "input");
VerifyInputTensorData(weights, "biases");
if (descriptor.m_BiasEnabled)
{
if (!biases.has_value())
{
throw InvalidArgumentException("Bias enabled but no bias data provided");
}
VerifyInputTensorData(biases.value(), "biases");
}
// set up weights
ScopedCpuTensorHandle weightsTensor(weights.first);
TransposeConvolution2dQueueDescriptor queueDescriptor;
queueDescriptor.m_Parameters = descriptor;
queueDescriptor.m_Weight = &weightsTensor;
AllocateAndCopyDataToITensorHandle(&weightsTensor, weights.second.data());
std::unique_ptr<ScopedCpuTensorHandle> biasesTensor;
if (descriptor.m_BiasEnabled)
{
// set up biases
biasesTensor = std::make_unique<ScopedCpuTensorHandle>(biases.value().first);
queueDescriptor.m_Bias = biasesTensor.get();
AllocateAndCopyDataToITensorHandle(biasesTensor.get(), biases.value().second.data());
}
// set up input and output handles
std::unique_ptr<ITensorHandle> inputHandle = workloadFactory.CreateTensorHandle(input.first);
std::unique_ptr<ITensorHandle> outputHandle = workloadFactory.CreateTensorHandle(output.first);
// set up workload
armnn::WorkloadInfo workloadInfo;
AddInputToWorkload(queueDescriptor, workloadInfo, input.first, inputHandle.get());
AddOutputToWorkload(queueDescriptor, workloadInfo, output.first, outputHandle.get());
std::unique_ptr<armnn::IWorkload> workload =
workloadFactory.CreateTransposeConvolution2d(queueDescriptor, workloadInfo);
inputHandle->Allocate();
outputHandle->Allocate();
CopyDataToITensorHandle(inputHandle.get(), input.second.data());
ExecuteWorkload(*workload, nullptr);
// copy output
output.second = std::vector<T>(output.first.GetNumElements(), 0.0f);
CopyDataFromITensorHandle(output.second.data(), outputHandle.get());
}
template<armnn::DataType ArmnnType, armnn::DataType ArmnnBType, typename T = armnn::ResolveType<ArmnnType>>
LayerTestResult<T, 4> TransposeConvolution2dTestImpl(
armnn::IWorkloadFactory& workloadFactory,
const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
const armnn::TransposeConvolution2dDescriptor& descriptor,
armnn::TensorInfo& inputInfo,
const std::vector<float>& inputData,
armnn::TensorInfo& outputInfo,
const std::vector<float>& expectedOutputData,
armnn::TensorInfo& weightsInfo,
const std::vector<float>& weightsData,
armnn::TensorInfo& biasesInfo,
const std::vector<float>& biasesData)
{
using namespace armnn;
// set up quantization parameters
if (armnn::IsQuantizedType<T>())
{
constexpr float qScale = 0.25f;
constexpr int32_t qOffset = 50;
inputInfo.SetQuantizationScale(qScale);
inputInfo.SetQuantizationOffset(qOffset);
outputInfo.SetQuantizationScale(qScale);
outputInfo.SetQuantizationOffset(qOffset);
weightsInfo.SetQuantizationScale(qScale);
weightsInfo.SetQuantizationOffset(qOffset);
biasesInfo.SetQuantizationScale(qScale * qScale);
biasesInfo.SetQuantizationOffset(0);
}
// set up input
TensorData<T> input =
{
inputInfo,
QuantizedVector<T>(inputInfo.GetQuantizationScale(), inputInfo.GetQuantizationOffset(), inputData)
};
// set up weights
TensorData<T> weights =
{
weightsInfo,
QuantizedVector<T>(weightsInfo.GetQuantizationScale(), weightsInfo.GetQuantizationOffset(), weightsData)
};
// set up biases
using BT = armnn::ResolveType<ArmnnBType>;
Optional<TensorData<BT>> optionalBiases;
if (descriptor.m_BiasEnabled)
{
TensorData<BT> biases =
{
biasesInfo,
QuantizedVector<BT>(biasesInfo.GetQuantizationScale(), biasesInfo.GetQuantizationOffset(), biasesData)
};
optionalBiases = Optional<TensorData<BT>>(biases);
}
// set up output
TensorData<T> output = { outputInfo, {} };
// execute test
TransposeConvolution2dTestImpl(workloadFactory,
memoryManager,
descriptor,
input,
output,
weights,
optionalBiases);
// construct result object
LayerTestResult<T, 4> testResult(outputInfo);
testResult.output = MakeTensor<T, 4>(outputInfo, output.second);
testResult.outputExpected = MakeTensor<T, 4>(outputInfo,
QuantizedVector<T>(outputInfo.GetQuantizationScale(),
outputInfo.GetQuantizationOffset(),
expectedOutputData));
return testResult;
}
} // anonymous namespace
template<armnn::DataType ArmnnType, armnn::DataType ArmnnBType, typename T = armnn::ResolveType<ArmnnType>>
LayerTestResult<T, 4> SimpleTransposeConvolution2dTestImpl(
armnn::IWorkloadFactory& workloadFactory,
const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
bool biasEnabled,
const armnn::DataLayout layout)
{
using namespace armnn;
constexpr unsigned int batches = 1u;
constexpr unsigned int channels = 1u;
constexpr unsigned int wInput = 3u;
constexpr unsigned int hInput = wInput;
constexpr unsigned int wOutput = 5u;
constexpr unsigned int hOutput = wOutput;
constexpr unsigned int wWeights = 3u;
constexpr unsigned int hWeights = wWeights;
TensorShape inputShape = MakeTensorShape(batches, channels, hInput, wInput, layout);
TensorShape outputShape = MakeTensorShape(batches, channels, hOutput, wOutput, layout);
TensorShape weightsShape = MakeTensorShape(batches, channels, hWeights, wWeights, layout);
TensorInfo inputInfo(inputShape, ArmnnType);
TensorInfo outputInfo(outputShape, ArmnnType);
TensorInfo weightsInfo(weightsShape, ArmnnType);
TensorInfo biasesInfo({ channels }, ArmnnBType);
std::vector<float> inputData =
{
1.f, 1.f, 1.f,
1.f, 1.f, 1.f,
1.f, 1.f, 1.f
};
std::vector<float> weightsData =
{
1.f, 2.f, 3.f,
4.f, 5.f, 6.f,
7.f, 8.f, 9.f
};
std::vector<float> biasesData = { 1.f };
std::vector<float> expectedOutputData =
{
1.f, 3.f, 6.f, 5.f, 3.f,
5.f, 12.f, 21.f, 16.f, 9.f,
12.f, 27.f, 45.f, 33.f, 18.f,
11.f, 24.f, 39.f, 28.f, 15.f,
7.f, 15.f, 24.f, 17.f, 9.f
};
if (biasEnabled)
{
// apply bias to expected output data
std::transform(expectedOutputData.begin(), expectedOutputData.end(), expectedOutputData.begin(),
[&](float f) -> float { return f + biasesData[0]; });
}
TransposeConvolution2dDescriptor descriptor;
descriptor.m_StrideX = 1;
descriptor.m_StrideY = 1;
descriptor.m_BiasEnabled = biasEnabled;
descriptor.m_DataLayout = layout;
// swizzle data if needed
if (layout == armnn::DataLayout::NHWC)
{
constexpr size_t dataTypeSize = sizeof(float);
const armnn::PermutationVector nchwToNhwc = { 0, 3, 1, 2 };
std::vector<float> tmp(inputData.size());
armnnUtils::Permute(inputInfo.GetShape(), nchwToNhwc, inputData.data(), tmp.data(), dataTypeSize);
inputData = tmp;
tmp.resize(weightsData.size());
armnnUtils::Permute(weightsInfo.GetShape(), nchwToNhwc, weightsData.data(), tmp.data(), dataTypeSize);
weightsData = tmp;
tmp.resize(expectedOutputData.size());
armnnUtils::Permute(outputInfo.GetShape(), nchwToNhwc, expectedOutputData.data(), tmp.data(), dataTypeSize);
expectedOutputData = tmp;
}
return TransposeConvolution2dTestImpl<ArmnnType, ArmnnBType>(workloadFactory,
memoryManager,
descriptor,
inputInfo,
inputData,
outputInfo,
expectedOutputData,
weightsInfo,
weightsData,
biasesInfo,
biasesData);
}
template<armnn::DataType ArmnnType, armnn::DataType ArmnnBType, typename T = armnn::ResolveType<ArmnnType>>
LayerTestResult<T, 4> PaddedTransposeConvolution2dTestImpl(
armnn::IWorkloadFactory& workloadFactory,
const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
bool biasEnabled,
const armnn::DataLayout layout)
{
using namespace armnn;
constexpr unsigned int batches = 1u;
constexpr unsigned int channels = 1u;
constexpr unsigned int wInput = 4u;
constexpr unsigned int hInput = wInput;
constexpr unsigned int wOutput = 2u;
constexpr unsigned int hOutput = wOutput;
constexpr unsigned int wWeights = 3u;
constexpr unsigned int hWeights = wWeights;
TensorShape inputShape = MakeTensorShape(batches, channels, hInput, wInput, layout);
TensorShape outputShape = MakeTensorShape(batches, channels, hOutput, wOutput, layout);
TensorShape weightsShape = MakeTensorShape(batches, channels, hWeights, wWeights, layout);
TensorInfo inputInfo(inputShape, ArmnnType);
TensorInfo outputInfo(outputShape, ArmnnType);
TensorInfo weightsInfo(weightsShape, ArmnnType);
TensorInfo biasesInfo({ channels }, ArmnnBType);
std::vector<float> inputData =
{
1.f, 3.f, 2.f, 1.f,
1.f, 3.f, 3.f, 1.f,
2.f, 1.f, 1.f, 3.f,
3.f, 2.f, 3.f, 3.f
};
std::vector<float> weightsData =
{
1.f, 2.f, 3.f,
0.f, 1.f, 0.f,
2.f, 1.f, 2.f
};
std::vector<float> biasesData = { 1.f };
std::vector<float> expectedOutputData =
{
21.f, 21.f,
28.f, 27.f
};
if (biasEnabled)
{
// apply bias to expected output data
std::transform(expectedOutputData.begin(), expectedOutputData.end(), expectedOutputData.begin(),
[&](float f) -> float { return f + biasesData[0]; });
}
TransposeConvolution2dDescriptor descriptor;
descriptor.m_PadLeft = 2;
descriptor.m_PadRight = 2;
descriptor.m_PadTop = 2;
descriptor.m_PadBottom = 2;
descriptor.m_StrideX = 1;
descriptor.m_StrideY = 1;
descriptor.m_BiasEnabled = biasEnabled;
descriptor.m_DataLayout = layout;
// swizzle data if needed
if (layout == armnn::DataLayout::NHWC)
{
constexpr size_t dataTypeSize = sizeof(float);
const armnn::PermutationVector nchwToNhwc = { 0, 3, 1, 2 };
std::vector<float> tmp(inputData.size());
armnnUtils::Permute(inputInfo.GetShape(), nchwToNhwc, inputData.data(), tmp.data(), dataTypeSize);
inputData = tmp;
tmp.resize(weightsData.size());
armnnUtils::Permute(weightsInfo.GetShape(), nchwToNhwc, weightsData.data(), tmp.data(), dataTypeSize);
weightsData = tmp;
tmp.resize(expectedOutputData.size());
armnnUtils::Permute(outputInfo.GetShape(), nchwToNhwc, expectedOutputData.data(), tmp.data(), dataTypeSize);
expectedOutputData = tmp;
}
return TransposeConvolution2dTestImpl<ArmnnType, ArmnnBType>(workloadFactory,
memoryManager,
descriptor,
inputInfo,
inputData,
outputInfo,
expectedOutputData,
weightsInfo,
weightsData,
biasesInfo,
biasesData);
}
template<armnn::DataType ArmnnType, armnn::DataType ArmnnBType, typename T = armnn::ResolveType<ArmnnType>>
LayerTestResult<T, 4> StridedTransposeConvolution2dTestImpl(
armnn::IWorkloadFactory& workloadFactory,
const armnn::IBackendInternal::IMemoryManagerSharedPtr& memoryManager,
bool biasEnabled,
const armnn::DataLayout layout)
{
using namespace armnn;
constexpr unsigned int batches = 1u;
constexpr unsigned int channels = 1u;
constexpr unsigned int wInput = 3u;
constexpr unsigned int hInput = wInput;
constexpr unsigned int wOutput = 7u;
constexpr unsigned int hOutput = wOutput;
constexpr unsigned int wWeights = 3u;
constexpr unsigned int hWeights = wWeights;
TensorShape inputShape = MakeTensorShape(batches, channels, hInput, wInput, layout);
TensorShape outputShape = MakeTensorShape(batches, channels, hOutput, wOutput, layout);
TensorShape weightsShape = MakeTensorShape(batches, channels, hWeights, wWeights, layout);
TensorInfo inputInfo(inputShape, ArmnnType);
TensorInfo outputInfo(outputShape, ArmnnType);
TensorInfo weightsInfo(weightsShape, ArmnnType);
TensorInfo biasesInfo({ channels }, ArmnnBType);
std::vector<float> inputData =
{
1.f, 1.f, 1.f,
1.f, 1.f, 1.f,
1.f, 1.f, 1.f
};
std::vector<float> weightsData =
{
1.f, 2.f, 3.f,
4.f, 5.f, 6.f,
7.f, 8.f, 9.f
};
std::vector<float> biasesData = { 1.f };
std::vector<float> expectedOutputData =
{
1.f, 2.f, 4.f, 2.f, 4.f, 2.f, 3.f,
4.f, 5.f, 10.f, 5.f, 10.f, 5.f, 6.f,
8.f, 10.f, 20.f, 10.f, 20.f, 10.f, 12.f,
4.f, 5.f, 10.f, 5.f, 10.f, 5.f, 6.f,
8.f, 10.f, 20.f, 10.f, 20.f, 10.f, 12.f,
4.f, 5.f, 10.f, 5.f, 10.f, 5.f, 6.f,
7.f, 8.f, 16.f, 8.f, 16.f, 8.f, 9.f
};
if (biasEnabled)
{
// apply bias to expected output data
std::transform(expectedOutputData.begin(), expectedOutputData.end(), expectedOutputData.begin(),
[&](float f) -> float { return f + biasesData[0]; });
}
TransposeConvolution2dDescriptor descriptor;
descriptor.m_StrideX = 2;
descriptor.m_StrideY = 2;
descriptor.m_BiasEnabled = biasEnabled;
descriptor.m_DataLayout = layout;
// swizzle data if needed
if (layout == armnn::DataLayout::NHWC)
{
constexpr size_t dataTypeSize = sizeof(float);
const armnn::PermutationVector nchwToNhwc = { 0, 3, 1, 2 };
std::vector<float> tmp(inputData.size());
armnnUtils::Permute(inputInfo.GetShape(), nchwToNhwc, inputData.data(), tmp.data(), dataTypeSize);
inputData = tmp;
tmp.resize(weightsData.size());
armnnUtils::Permute(weightsInfo.GetShape(), nchwToNhwc, weightsData.data(), tmp.data(), dataTypeSize);
weightsData = tmp;
tmp.resize(expectedOutputData.size());
armnnUtils::Permute(outputInfo.GetShape(), nchwToNhwc, expectedOutputData.data(), tmp.data(), dataTypeSize);
expectedOutputData = tmp;
}
return TransposeConvolution2dTestImpl<ArmnnType, ArmnnBType>(workloadFactory,
memoryManager,
descriptor,
inputInfo,
inputData,
outputInfo,
expectedOutputData,
weightsInfo,
weightsData,
biasesInfo,
biasesData);
}