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android / platform / external / armnn / 2f2778f3 / . / src / backends / backendsCommon / test / WorkloadDataValidation.cpp
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//
// Copyright © 2017 Arm Ltd. All rights reserved.
// SPDX-License-Identifier: MIT
//
#include "WorkloadTestUtils.hpp"
#include <armnn/Exceptions.hpp>
#include <backendsCommon/CpuTensorHandle.hpp>
#include <backendsCommon/Workload.hpp>
#include <reference/workloads/RefWorkloads.hpp>
#include <reference/RefWorkloadFactory.hpp>
#include <boost/test/unit_test.hpp>
using namespace armnn;
BOOST_AUTO_TEST_SUITE(WorkloadInfoValidation)
BOOST_AUTO_TEST_CASE(QueueDescriptor_Validate_WrongNumOfInputsOutputs)
{
InputQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
//Invalid argument exception is expected, because no inputs and no outputs were defined.
BOOST_CHECK_THROW(RefWorkloadFactory().CreateInput(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(RefPooling2dFloat32Workload_Validate_WrongDimTensor)
{
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int inputShape[] = {2, 3, 4}; // <- Invalid - input tensor has to be 4D.
unsigned int outputShape[] = {2, 3, 4, 5};
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
inputTensorInfo = armnn::TensorInfo(3, inputShape, armnn::DataType::Float32);
Pooling2dQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
// Invalid argument exception is expected, input tensor has to be 4D.
BOOST_CHECK_THROW(RefPooling2dFloat32Workload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(SoftmaxQueueDescriptor_Validate_WrongInputHeight)
{
unsigned int inputHeight = 1;
unsigned int inputWidth = 1;
unsigned int inputChannels = 4;
unsigned int inputNum = 2;
unsigned int outputChannels = inputChannels;
unsigned int outputHeight = inputHeight + 1; //Makes data invalid - Softmax expects height and width to be 1.
unsigned int outputWidth = inputWidth;
unsigned int outputNum = inputNum;
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int inputShape[] = { inputNum, inputChannels, inputHeight, inputWidth };
unsigned int outputShape[] = { outputNum, outputChannels, outputHeight, outputWidth };
inputTensorInfo = armnn::TensorInfo(4, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
SoftmaxQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
//Invalid argument exception is expected, because height != 1.
BOOST_CHECK_THROW(RefSoftmaxFloat32Workload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(FullyConnectedQueueDescriptor_Validate_RequiredDataMissing)
{
unsigned int inputWidth = 1;
unsigned int inputHeight = 1;
unsigned int inputChannels = 5;
unsigned int inputNum = 2;
unsigned int outputWidth = 1;
unsigned int outputHeight = 1;
unsigned int outputChannels = 3;
unsigned int outputNum = 2;
// Define the tensor descriptors.
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
armnn::TensorInfo weightsDesc;
armnn::TensorInfo biasesDesc;
unsigned int inputShape[] = { inputNum, inputChannels, inputHeight, inputWidth };
unsigned int outputShape[] = { outputNum, outputChannels, outputHeight, outputWidth };
unsigned int weightsShape[] = { 1, 1, inputChannels, outputChannels };
unsigned int biasShape[] = { 1, outputChannels, outputHeight, outputWidth };
inputTensorInfo = armnn::TensorInfo(4, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
weightsDesc = armnn::TensorInfo(4, weightsShape, armnn::DataType::Float32);
biasesDesc = armnn::TensorInfo(4, biasShape, armnn::DataType::Float32);
FullyConnectedQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
ScopedCpuTensorHandle weightTensor(weightsDesc);
ScopedCpuTensorHandle biasTensor(biasesDesc);
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
invalidData.m_Weight = &weightTensor;
invalidData.m_Bias = &biasTensor;
invalidData.m_Parameters.m_BiasEnabled = true;
invalidData.m_Parameters.m_TransposeWeightMatrix = false;
//Invalid argument exception is expected, because not all required fields have been provided.
//In particular inputsData[0], outputsData[0] and weightsData can not be null.
BOOST_CHECK_THROW(RefFullyConnectedWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(NormalizationQueueDescriptor_Validate_WrongInputHeight)
{
constexpr unsigned int inputNum = 5;
constexpr unsigned int inputHeight = 32;
constexpr unsigned int inputWidth = 24;
constexpr unsigned int inputChannels = 3;
constexpr unsigned int outputNum = inputNum;
constexpr unsigned int outputChannels = inputChannels;
constexpr unsigned int outputHeight = inputHeight + 1; //Makes data invalid - normalization requires.
//Input and output to have the same dimensions.
constexpr unsigned int outputWidth = inputWidth;
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int inputShape[] = {inputNum, inputChannels, inputHeight, inputWidth};
unsigned int outputShape[] = {outputNum, outputChannels, outputHeight, outputWidth};
inputTensorInfo = armnn::TensorInfo(4, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
armnn::NormalizationAlgorithmMethod normMethod = armnn::NormalizationAlgorithmMethod::LocalBrightness;
armnn::NormalizationAlgorithmChannel normChannel = armnn::NormalizationAlgorithmChannel::Across;
float alpha = 1.f;
float beta = 1.f;
float kappa = 1.f;
uint32_t normSize = 5;
NormalizationQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
invalidData.m_Parameters.m_NormChannelType = normChannel;
invalidData.m_Parameters.m_NormMethodType = normMethod;
invalidData.m_Parameters.m_NormSize = normSize;
invalidData.m_Parameters.m_Alpha = alpha;
invalidData.m_Parameters.m_Beta = beta;
invalidData.m_Parameters.m_K = kappa;
//Invalid argument exception is expected, because input height != output height.
BOOST_CHECK_THROW(RefNormalizationFloat32Workload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(SplitterQueueDescriptor_Validate_WrongWindow)
{
constexpr unsigned int inputNum = 1;
constexpr unsigned int inputHeight = 32;
constexpr unsigned int inputWidth = 24;
constexpr unsigned int inputChannels = 3;
constexpr unsigned int outputNum = inputNum;
constexpr unsigned int outputChannels = inputChannels;
constexpr unsigned int outputHeight = 18;
constexpr unsigned int outputWidth = inputWidth;
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int inputShape[] = {inputNum, inputChannels, inputHeight, inputWidth};
unsigned int outputShape[] = {outputNum, outputChannels, outputHeight, outputWidth};
inputTensorInfo = armnn::TensorInfo(4, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
SplitterQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
// Invalid, since it has only 3 dimensions while the input tensor is 4d.
std::vector<unsigned int> wOrigin = {0, 0, 0};
armnn::SplitterQueueDescriptor::ViewOrigin window(wOrigin);
invalidData.m_ViewOrigins.push_back(window);
BOOST_TEST_INFO("Invalid argument exception is expected, because split window dimensionality does not "
"match input.");
BOOST_CHECK_THROW(RefSplitterFloat32Workload(invalidData, invalidInfo), armnn::InvalidArgumentException);
// Invalid, since window extends past the boundary of input tensor.
std::vector<unsigned int> wOrigin3 = {0, 0, 15, 0};
armnn::SplitterQueueDescriptor::ViewOrigin window3(wOrigin3);
invalidData.m_ViewOrigins[0] = window3;
BOOST_TEST_INFO("Invalid argument exception is expected (wOrigin3[2]+ outputHeight > inputHeight");
BOOST_CHECK_THROW(RefSplitterFloat32Workload(invalidData, invalidInfo), armnn::InvalidArgumentException);
std::vector<unsigned int> wOrigin4 = {0, 0, 0, 0};
armnn::SplitterQueueDescriptor::ViewOrigin window4(wOrigin4);
invalidData.m_ViewOrigins[0] = window4;
std::vector<unsigned int> wOrigin5 = {1, 16, 20, 2};
armnn::SplitterQueueDescriptor::ViewOrigin window5(wOrigin4);
invalidData.m_ViewOrigins.push_back(window5);
BOOST_TEST_INFO("Invalid exception due to number of split windows not matching number of outputs.");
BOOST_CHECK_THROW(RefSplitterFloat32Workload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(MergerQueueDescriptor_Validate_WrongWindow)
{
constexpr unsigned int inputNum = 1;
constexpr unsigned int inputChannels = 3;
constexpr unsigned int inputHeight = 32;
constexpr unsigned int inputWidth = 24;
constexpr unsigned int outputNum = 1;
constexpr unsigned int outputChannels = 3;
constexpr unsigned int outputHeight = 32;
constexpr unsigned int outputWidth = 24;
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int inputShape[] = {inputNum, inputChannels, inputHeight, inputWidth};
unsigned int outputShape[] = {outputNum, outputChannels, outputHeight, outputWidth};
inputTensorInfo = armnn::TensorInfo(4, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
MergerQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
// Invalid, since it has only 3 dimensions while the input tensor is 4d.
std::vector<unsigned int> wOrigin = {0, 0, 0};
armnn::MergerQueueDescriptor::ViewOrigin window(wOrigin);
invalidData.m_ViewOrigins.push_back(window);
BOOST_TEST_INFO("Invalid argument exception is expected, because merge window dimensionality does not "
"match input.");
BOOST_CHECK_THROW(RefConcatWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
// Invalid, since window extends past the boundary of output tensor.
std::vector<unsigned int> wOrigin3 = {0, 0, 15, 0};
armnn::MergerQueueDescriptor::ViewOrigin window3(wOrigin3);
invalidData.m_ViewOrigins[0] = window3;
BOOST_TEST_INFO("Invalid argument exception is expected (wOrigin3[2]+ inputHeight > outputHeight");
BOOST_CHECK_THROW(RefConcatWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
std::vector<unsigned int> wOrigin4 = {0, 0, 0, 0};
armnn::MergerQueueDescriptor::ViewOrigin window4(wOrigin4);
invalidData.m_ViewOrigins[0] = window4;
std::vector<unsigned int> wOrigin5 = {1, 16, 20, 2};
armnn::MergerQueueDescriptor::ViewOrigin window5(wOrigin4);
invalidData.m_ViewOrigins.push_back(window5);
BOOST_TEST_INFO("Invalid exception due to number of merge windows not matching number of inputs.");
BOOST_CHECK_THROW(RefConcatWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(AdditionQueueDescriptor_Validate_InputNumbers)
{
armnn::TensorInfo input1TensorInfo;
armnn::TensorInfo input2TensorInfo;
armnn::TensorInfo input3TensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int shape[] = {1, 1, 1, 1};
input1TensorInfo = armnn::TensorInfo(4, shape, armnn::DataType::Float32);
input2TensorInfo = armnn::TensorInfo(4, shape, armnn::DataType::Float32);
input3TensorInfo = armnn::TensorInfo(4, shape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, shape, armnn::DataType::Float32);
AdditionQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, input1TensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
// Too few inputs.
BOOST_CHECK_THROW(RefAdditionWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
AddInputToWorkload(invalidData, invalidInfo, input2TensorInfo, nullptr);
// Correct.
BOOST_CHECK_NO_THROW(RefAdditionWorkload(invalidData, invalidInfo));
AddInputToWorkload(invalidData, invalidInfo, input3TensorInfo, nullptr);
// Too many inputs.
BOOST_CHECK_THROW(RefAdditionWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(AdditionQueueDescriptor_Validate_InputShapes)
{
armnn::TensorInfo input1TensorInfo;
armnn::TensorInfo input2TensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int shape1[] = {1, 1, 2, 1};
unsigned int shape2[] = {1, 1, 3, 2};
// Incompatible shapes even with broadcasting.
{
input1TensorInfo = armnn::TensorInfo(4, shape1, armnn::DataType::Float32);
input2TensorInfo = armnn::TensorInfo(4, shape2, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, shape1, armnn::DataType::Float32);
AdditionQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, input1TensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, input2TensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
BOOST_CHECK_THROW(RefAdditionWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
// Output size not compatible with input sizes.
{
input1TensorInfo = armnn::TensorInfo(4, shape1, armnn::DataType::Float32);
input2TensorInfo = armnn::TensorInfo(4, shape1, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, shape2, armnn::DataType::Float32);
AdditionQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, input1TensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, input2TensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
// Output differs.
BOOST_CHECK_THROW(RefAdditionWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
}
BOOST_AUTO_TEST_CASE(MultiplicationQueueDescriptor_Validate_InputTensorDimensionMismatch)
{
armnn::TensorInfo input0TensorInfo;
armnn::TensorInfo input1TensorInfo;
armnn::TensorInfo outputTensorInfo;
constexpr unsigned int input0Shape[] = { 2, 2, 4, 4 };
constexpr std::size_t dimensionCount = std::extent<decltype(input0Shape)>::value;
// Checks dimension consistency for input tensors.
for (unsigned int dimIndex = 0; dimIndex < dimensionCount; ++dimIndex)
{
unsigned int input1Shape[dimensionCount];
for (unsigned int i = 0; i < dimensionCount; ++i)
{
input1Shape[i] = input0Shape[i];
}
++input1Shape[dimIndex];
input0TensorInfo = armnn::TensorInfo(dimensionCount, input0Shape, armnn::DataType::Float32);
input1TensorInfo = armnn::TensorInfo(dimensionCount, input1Shape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(dimensionCount, input0Shape, armnn::DataType::Float32);
MultiplicationQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, input0TensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, input1TensorInfo, nullptr);
BOOST_CHECK_THROW(RefMultiplicationWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
// Checks dimension consistency for input and output tensors.
for (unsigned int dimIndex = 0; dimIndex < dimensionCount; ++dimIndex)
{
unsigned int outputShape[dimensionCount];
for (unsigned int i = 0; i < dimensionCount; ++i)
{
outputShape[i] = input0Shape[i];
}
++outputShape[dimIndex];
input0TensorInfo = armnn::TensorInfo(dimensionCount, input0Shape, armnn::DataType::Float32);
input1TensorInfo = armnn::TensorInfo(dimensionCount, input0Shape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(dimensionCount, outputShape, armnn::DataType::Float32);
MultiplicationQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, input0TensorInfo, nullptr);
AddInputToWorkload(invalidData, invalidInfo, input1TensorInfo, nullptr);
BOOST_CHECK_THROW(RefMultiplicationWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
}
BOOST_AUTO_TEST_CASE(ReshapeQueueDescriptor_Validate_MismatchingNumElements)
{
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
// The input and output shapes should have the same number of elements, but these don't.
unsigned int inputShape[] = { 1, 1, 2, 3 };
unsigned int outputShape[] = { 1, 1, 1, 2 };
inputTensorInfo = armnn::TensorInfo(4, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(4, outputShape, armnn::DataType::Float32);
ReshapeQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
// InvalidArgumentException is expected, because the number of elements don't match.
BOOST_CHECK_THROW(RefReshapeWorkload(invalidData, invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_CASE(LstmQueueDescriptor_Validate)
{
armnn::TensorInfo inputTensorInfo;
armnn::TensorInfo outputTensorInfo;
unsigned int inputShape[] = { 1, 2 };
unsigned int outputShape[] = { 1 };
inputTensorInfo = armnn::TensorInfo(2, inputShape, armnn::DataType::Float32);
outputTensorInfo = armnn::TensorInfo(1, outputShape, armnn::DataType::Float32);
LstmQueueDescriptor invalidData;
WorkloadInfo invalidInfo;
AddInputToWorkload(invalidData, invalidInfo, inputTensorInfo, nullptr);
AddOutputToWorkload(invalidData, invalidInfo, outputTensorInfo, nullptr);
BOOST_CHECK_THROW(invalidData.Validate(invalidInfo), armnn::InvalidArgumentException);
}
BOOST_AUTO_TEST_SUITE_END()