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android / platform / external / armnn / 81beae3a8 / . / src / backends / reference / test / RefEndToEndTests.cpp
blob: 424df977c87c5064547b7396a393aec89685b734 [file] [log] [blame]
//
// Copyright © 2017 Arm Ltd and Contributors. All rights reserved.
// SPDX-License-Identifier: MIT
//
#include <backendsCommon/test/EndToEndTestImpl.hpp>
#include <backendsCommon/test/ActivationEndToEndTestImpl.hpp>
#include <backendsCommon/test/ArgMinMaxEndToEndTestImpl.hpp>
#include <backendsCommon/test/BatchToSpaceNdEndToEndTestImpl.hpp>
#include <backendsCommon/test/ComparisonEndToEndTestImpl.hpp>
#include <backendsCommon/test/ConcatEndToEndTestImpl.hpp>
#include <backendsCommon/test/DepthToSpaceEndToEndTestImpl.hpp>
#include <backendsCommon/test/DequantizeEndToEndTestImpl.hpp>
#include <backendsCommon/test/DetectionPostProcessEndToEndTestImpl.hpp>
#include <backendsCommon/test/ElementwiseUnaryEndToEndTestImpl.hpp>
#include <backendsCommon/test/FillEndToEndTestImpl.hpp>
#include <backendsCommon/test/FullyConnectedEndToEndTestImpl.hpp>
#include <backendsCommon/test/GatherEndToEndTestImpl.hpp>
#include <backendsCommon/test/InstanceNormalizationEndToEndTestImpl.hpp>
#include <backendsCommon/test/LogSoftmaxEndToEndTestImpl.hpp>
#include <backendsCommon/test/PreluEndToEndTestImpl.hpp>
#include <backendsCommon/test/QLstmEndToEndTestImpl.hpp>
#include <backendsCommon/test/RankEndToEndTestImpl.hpp>
#include <backendsCommon/test/ResizeEndToEndTestImpl.hpp>
#include <backendsCommon/test/SpaceToDepthEndToEndTestImpl.hpp>
#include <backendsCommon/test/SplitterEndToEndTestImpl.hpp>
#include <backendsCommon/test/StridedSliceAsyncEndToEndTest.hpp>
#include <backendsCommon/test/TransposeConvolution2dEndToEndTestImpl.hpp>
#include <doctest/doctest.h>
TEST_SUITE("RefEndToEnd")
{
std::vector<armnn::BackendId> defaultBackends = {armnn::Compute::CpuRef};
// Abs
TEST_CASE("RefAbsEndToEndTestFloat32")
{
std::vector<float> expectedOutput =
{
1.f, 1.f, 1.f, 1.f, 5.f, 5.f, 5.f, 5.f,
3.f, 3.f, 3.f, 3.f, 4.f, 4.f, 4.f, 4.f
};
ElementwiseUnarySimpleEndToEnd<armnn::DataType::Float32>(defaultBackends,
UnaryOperation::Abs,
expectedOutput);
}
TEST_CASE("RefAbsEndToEndTestUint8")
{
// Note the expected output will be implicitly quantized by the below test function
std::vector<float> expectedOutput =
{
1.f, 1.f, 1.f, 1.f, 5.f, 5.f, 5.f, 5.f,
3.f, 3.f, 3.f, 3.f, 4.f, 4.f, 4.f, 4.f
};
ElementwiseUnarySimpleEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends,
UnaryOperation::Abs,
expectedOutput);
}
TEST_CASE("RefAbsEndToEndTestInt16")
{
// Note the expected output will be implicitly quantized by the below test function
std::vector<float> expectedOutput =
{
1.f, 1.f, 1.f, 1.f, 5.f, 5.f, 5.f, 5.f,
3.f, 3.f, 3.f, 3.f, 4.f, 4.f, 4.f, 4.f
};
ElementwiseUnarySimpleEndToEnd<armnn::DataType::QSymmS16>(defaultBackends,
UnaryOperation::Abs,
expectedOutput);
}
// Constant
TEST_CASE("ConstantUsage_Ref_Float32")
{
CHECK(ConstantUsageFloat32Test(defaultBackends));
}
TEST_CASE("ConstantUsage_Ref_Uint8")
{
CHECK(ConstantUsageUint8Test(defaultBackends));
}
TEST_CASE("Unsigned8")
{
using namespace armnn;
// Create runtime in which test will run
armnn::IRuntime::CreationOptions options;
armnn::IRuntimePtr runtime(armnn::IRuntime::Create(options));
// Builds up the structure of the network.
armnn::INetworkPtr net(INetwork::Create());
IConnectableLayer* input = net->AddInputLayer(0, "input");
IConnectableLayer* softmax = net->AddSoftmaxLayer(SoftmaxDescriptor(), "softmax");
IConnectableLayer* output = net->AddOutputLayer(0, "output");
input->GetOutputSlot(0).Connect(softmax->GetInputSlot(0));
softmax->GetOutputSlot(0).Connect(output->GetInputSlot(0));
// Sets the tensors in the network.
TensorInfo inputTensorInfo(TensorShape({1, 5}), DataType::QAsymmU8);
inputTensorInfo.SetQuantizationOffset(100);
inputTensorInfo.SetQuantizationScale(10000.0f);
input->GetOutputSlot(0).SetTensorInfo(inputTensorInfo);
TensorInfo outputTensorInfo(TensorShape({1, 5}), DataType::QAsymmU8);
outputTensorInfo.SetQuantizationOffset(0);
outputTensorInfo.SetQuantizationScale(1.0f/255.0f);
softmax->GetOutputSlot(0).SetTensorInfo(outputTensorInfo);
// optimize the network
IOptimizedNetworkPtr optNet = Optimize(*net, defaultBackends, runtime->GetDeviceSpec());
// Loads it into the runtime.
NetworkId netId;
auto error = runtime->LoadNetwork(netId, std::move(optNet));
CHECK(error == Status::Success);
// Creates structures for input & output.
std::vector<uint8_t> inputData
{
1, 10, 3, 200, 5 // Some inputs - one of which is sufficiently larger than the others to saturate softmax.
};
std::vector<uint8_t> outputData(5);
armnn::InputTensors inputTensors
{
{0, armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), inputData.data())}
};
armnn::OutputTensors outputTensors
{
{0, armnn::Tensor(runtime->GetOutputTensorInfo(netId, 0), outputData.data())}
};
// Does the inference.
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
// Checks the results.
CHECK(outputData[0] == 0);
CHECK(outputData[1] == 0);
CHECK(outputData[2] == 0);
CHECK(outputData[3] == 255); // softmax has been saturated.
CHECK(outputData[4] == 0);
}
TEST_CASE("TrivialAdd")
{
// This test was designed to match "AddTwo" in android nn/runtime/test/TestTrivialModel.cpp.
using namespace armnn;
// Create runtime in which test will run
armnn::IRuntime::CreationOptions options;
armnn::IRuntimePtr runtime(armnn::IRuntime::Create(options));
// Builds up the structure of the network.
armnn::INetworkPtr net(INetwork::Create());
IConnectableLayer* input1 = net->AddInputLayer(0);
IConnectableLayer* input2 = net->AddInputLayer(1);
IConnectableLayer* add = net->AddAdditionLayer();
IConnectableLayer* output = net->AddOutputLayer(0);
input1->GetOutputSlot(0).Connect(add->GetInputSlot(0));
input2->GetOutputSlot(0).Connect(add->GetInputSlot(1));
add->GetOutputSlot(0).Connect(output->GetInputSlot(0));
// Sets the tensors in the network.
TensorInfo tensorInfo(TensorShape({3, 4}), DataType::Float32);
input1->GetOutputSlot(0).SetTensorInfo(tensorInfo);
input2->GetOutputSlot(0).SetTensorInfo(tensorInfo);
add->GetOutputSlot(0).SetTensorInfo(tensorInfo);
// optimize the network
IOptimizedNetworkPtr optNet = Optimize(*net, defaultBackends, runtime->GetDeviceSpec());
// Loads it into the runtime.
NetworkId netId;
runtime->LoadNetwork(netId, std::move(optNet));
// Creates structures for input & output - matching android nn test.
std::vector<float> input1Data
{
1.f, 2.f, 3.f, 4.f, 5.f, 6.f, 7.f, 8.f, 9.f, 10.f, 11.f, 12.f
};
std::vector<float> input2Data
{
100.f, 200.f, 300.f, 400.f, 500.f, 600.f, 700.f, 800.f, 900.f, 1000.f, 1100.f, 1200.f
};
std::vector<float> outputData(12);
InputTensors inputTensors
{
{0,armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), input1Data.data())},
{1,armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), input2Data.data())}
};
OutputTensors outputTensors
{
{0,armnn::Tensor(runtime->GetOutputTensorInfo(netId, 0), outputData.data())}
};
// Does the inference.
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
// Checks the results
CHECK(outputData[0] == 101);
CHECK(outputData[1] == 202);
CHECK(outputData[2] == 303);
CHECK(outputData[3] == 404);
CHECK(outputData[4] == 505);
CHECK(outputData[5] == 606);
CHECK(outputData[6] == 707);
CHECK(outputData[7] == 808);
CHECK(outputData[8] == 909);
CHECK(outputData[9] == 1010);
CHECK(outputData[10] == 1111);
CHECK(outputData[11] == 1212);
}
TEST_CASE("MultipleOutputs")
{
using namespace armnn;
// Create runtime in which test will run
armnn::IRuntime::CreationOptions options;
armnn::IRuntimePtr runtime(armnn::IRuntime::Create(options));
// Builds up the structure of the network.
INetworkPtr net(INetwork::Create());
IConnectableLayer* input = net->AddInputLayer(0);
// ReLu1
ActivationDescriptor activation1Descriptor;
activation1Descriptor.m_Function = ActivationFunction::BoundedReLu;
activation1Descriptor.m_A = 1.f;
activation1Descriptor.m_B = -1.f;
IConnectableLayer* activation1 = net->AddActivationLayer(activation1Descriptor);
// ReLu6
ActivationDescriptor activation2Descriptor;
activation2Descriptor.m_Function = ActivationFunction::BoundedReLu;
activation2Descriptor.m_A = 6.0f;
IConnectableLayer* activation2 = net->AddActivationLayer(activation2Descriptor);
// BoundedReLu(min=2, max=5)
ActivationDescriptor activation3Descriptor;
activation3Descriptor.m_Function = ActivationFunction::BoundedReLu;
activation3Descriptor.m_A = 5.0f;
activation3Descriptor.m_B = 2.0f;
IConnectableLayer* activation3 = net->AddActivationLayer(activation3Descriptor);
IConnectableLayer* output1 = net->AddOutputLayer(0);
IConnectableLayer* output2 = net->AddOutputLayer(1);
IConnectableLayer* output3 = net->AddOutputLayer(2);
input->GetOutputSlot(0).Connect(activation1->GetInputSlot(0));
input->GetOutputSlot(0).Connect(activation2->GetInputSlot(0));
input->GetOutputSlot(0).Connect(activation3->GetInputSlot(0));
activation1->GetOutputSlot(0).Connect(output1->GetInputSlot(0));
activation2->GetOutputSlot(0).Connect(output2->GetInputSlot(0));
activation3->GetOutputSlot(0).Connect(output3->GetInputSlot(0));
// Sets the tensors in the network.
TensorInfo tensorInfo(TensorShape({ 10 }), DataType::Float32);
input->GetOutputSlot(0).SetTensorInfo(tensorInfo);
activation1->GetOutputSlot(0).SetTensorInfo(tensorInfo);
activation2->GetOutputSlot(0).SetTensorInfo(tensorInfo);
activation3->GetOutputSlot(0).SetTensorInfo(tensorInfo);
// optimize the network
IOptimizedNetworkPtr optNet = Optimize(*net, defaultBackends, runtime->GetDeviceSpec());
// Loads it into the runtime.
NetworkId netId;
runtime->LoadNetwork(netId, std::move(optNet));
// Creates structures for input & output.
const std::vector<float> inputData{ 3.f, 5.f, 2.f, 3.f, 7.f, 0.f, -2.f, -1.f, 3.f, 3.f };
std::vector<float> output1Data(inputData.size());
std::vector<float> output2Data(inputData.size());
std::vector<float> output3Data(inputData.size());
InputTensors inputTensors
{
{0,armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), inputData.data())}
};
OutputTensors outputTensors
{
{0,armnn::Tensor(runtime->GetOutputTensorInfo(netId, 0), output1Data.data())},
{1,armnn::Tensor(runtime->GetOutputTensorInfo(netId, 1), output2Data.data())},
{2,armnn::Tensor(runtime->GetOutputTensorInfo(netId, 2), output3Data.data())}
};
// Does the inference.
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
// Checks the results.
CHECK(output1Data == std::vector<float>({ 1.f, 1.f, 1.f, 1.f, 1.f, 0.f, -1.f, -1.f, 1.f, 1.f })); // ReLu1
CHECK(output2Data == std::vector<float>({ 3.f, 5.f, 2.f, 3.f, 6.f, 0.f, 0.f, 0.f, 3.f, 3.f })); // ReLu6
CHECK(output3Data == std::vector<float>({ 3.f, 5.f, 2.f, 3.f, 5.f, 2.f, 2.f, 2.f, 3.f, 3.f })); // [2, 5]
}
TEST_CASE("TrivialMin")
{
using namespace armnn;
// Create runtime in which test will run
armnn::IRuntime::CreationOptions options;
armnn::IRuntimePtr runtime(armnn::IRuntime::Create(options));
// Builds up the structure of the network.
armnn::INetworkPtr net(INetwork::Create());
IConnectableLayer* input1 = net->AddInputLayer(0);
IConnectableLayer* input2 = net->AddInputLayer(1);
IConnectableLayer* min = net->AddMinimumLayer();
IConnectableLayer* output = net->AddOutputLayer(0);
input1->GetOutputSlot(0).Connect(min->GetInputSlot(0));
input2->GetOutputSlot(0).Connect(min->GetInputSlot(1));
min->GetOutputSlot(0).Connect(output->GetInputSlot(0));
// Sets the tensors in the network.
TensorInfo tensorInfo(TensorShape({1, 1, 1, 4}), DataType::Float32);
input1->GetOutputSlot(0).SetTensorInfo(tensorInfo);
input2->GetOutputSlot(0).SetTensorInfo(tensorInfo);
min->GetOutputSlot(0).SetTensorInfo(tensorInfo);
// optimize the network
IOptimizedNetworkPtr optNet = Optimize(*net, defaultBackends, runtime->GetDeviceSpec());
// Loads it into the runtime.
NetworkId netId;
runtime->LoadNetwork(netId, std::move(optNet));
// Creates structures for input & output - matching android nn test.
std::vector<float> input1Data
{
1.0f, 2.0f, 3.0f, 4.0f
};
std::vector<float> input2Data
{
2.0f, 1.0f, 5.0f, 2.0f
};
std::vector<float> outputData(4);
InputTensors inputTensors
{
{0,armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), input1Data.data())},
{1,armnn::ConstTensor(runtime->GetInputTensorInfo(netId, 0), input2Data.data())}
};
OutputTensors outputTensors
{
{0,armnn::Tensor(runtime->GetOutputTensorInfo(netId, 0), outputData.data())}
};
// Does the inference.
runtime->EnqueueWorkload(netId, inputTensors, outputTensors);
// Checks the results
CHECK(outputData[0] == 1);
CHECK(outputData[1] == 1);
CHECK(outputData[2] == 3);
CHECK(outputData[3] == 2);
}
TEST_CASE("RefEqualSimpleEndToEndTest")
{
const std::vector<uint8_t> expectedOutput({ 1, 1, 1, 1, 0, 0, 0, 0,
0, 0, 0, 0, 1, 1, 1, 1 });
ComparisonSimpleEndToEnd<armnn::DataType::Float32>(defaultBackends,
ComparisonOperation::Equal,
expectedOutput);
}
TEST_CASE("RefGreaterSimpleEndToEndTest")
{
const std::vector<uint8_t> expectedOutput({ 0, 0, 0, 0, 1, 1, 1, 1,
0, 0, 0, 0, 0, 0, 0, 0 });
ComparisonSimpleEndToEnd<armnn::DataType::Float32>(defaultBackends,
ComparisonOperation::Greater,
expectedOutput);
}
TEST_CASE("RefEqualSimpleEndToEndUint8Test")
{
const std::vector<uint8_t> expectedOutput({ 1, 1, 1, 1, 0, 0, 0, 0,
0, 0, 0, 0, 1, 1, 1, 1 });
ComparisonSimpleEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends,
ComparisonOperation::Equal,
expectedOutput);
}
TEST_CASE("RefGreaterSimpleEndToEndUint8Test")
{
const std::vector<uint8_t> expectedOutput({ 0, 0, 0, 0, 1, 1, 1, 1,
0, 0, 0, 0, 0, 0, 0, 0 });
ComparisonSimpleEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends,
ComparisonOperation::Greater,
expectedOutput);
}
TEST_CASE("RefEqualBroadcastEndToEndTest")
{
const std::vector<uint8_t> expectedOutput({ 1, 0, 1, 1, 0, 0,
0, 0, 0, 0, 0, 0 });
ComparisonBroadcastEndToEnd<armnn::DataType::Float32>(defaultBackends,
ComparisonOperation::Equal,
expectedOutput);
}
TEST_CASE("RefGreaterBroadcastEndToEndTest")
{
const std::vector<uint8_t> expectedOutput({ 0, 1, 0, 0, 0, 1,
1, 1, 1, 1, 1, 1 });
ComparisonBroadcastEndToEnd<armnn::DataType::Float32>(defaultBackends,
ComparisonOperation::Greater,
expectedOutput);
}
TEST_CASE("RefEqualBroadcastEndToEndUint8Test")
{
const std::vector<uint8_t > expectedOutput({ 1, 0, 1, 1, 0, 0,
0, 0, 0, 0, 0, 0 });
ComparisonBroadcastEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends,
ComparisonOperation::Equal,
expectedOutput);
}
TEST_CASE("RefGreaterBroadcastEndToEndUint8Test")
{
const std::vector<uint8_t> expectedOutput({ 0, 1, 0, 0, 0, 1,
1, 1, 1, 1, 1, 1 });
ComparisonBroadcastEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends,
ComparisonOperation::Greater,
expectedOutput);
}
TEST_CASE("RefBatchToSpaceNdEndToEndFloat32NHWCTest")
{
BatchToSpaceNdEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefBatchToSpaceNdEndToEndUint8NHWCTest")
{
BatchToSpaceNdEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefBatchToSpaceNdEndToEndQSymm16NHWCTest")
{
BatchToSpaceNdEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefBatchToSpaceNdEndToEndFloat32NCHWTest")
{
BatchToSpaceNdEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefBatchToSpaceNdEndToEndUint8NCHWTest")
{
BatchToSpaceNdEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefBatchToSpaceNdEndToEndQSymm16NCHWTest")
{
BatchToSpaceNdEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefBatchToSpaceNdEndToEndComplexFloat32NHWCTest")
{
BatchToSpaceNdComplexEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefBatchToSpaceNdEndToEndComplexUint8NHWCTest")
{
BatchToSpaceNdComplexEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefBatchToSpaceNdEndToEndComplexQSymm16NHWCTest")
{
BatchToSpaceNdComplexEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefBatchToSpaceNdEndToEndComplexFloat32NCHWTest")
{
BatchToSpaceNdComplexEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefBatchToSpaceNdEndToEndComplexUint8NCHWTest")
{
BatchToSpaceNdComplexEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefBatchToSpaceNdEndToEndComplexQSymm16NCHWTest")
{
BatchToSpaceNdComplexEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefConcatEndToEndDim0Test")
{
ConcatDim0EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim0Uint8Test")
{
ConcatDim0EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim1Test")
{
ConcatDim1EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim1Uint8Test")
{
ConcatDim1EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim2Test")
{
ConcatDim2EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim2Uint8Test")
{
ConcatDim2EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim3Test")
{
ConcatDim3EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefConcatEndToEndDim3Uint8Test")
{
ConcatDim3EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefEluEndToEndTestFloat32")
{
EluEndToEndTest<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefEluEndToEndTestFloat16")
{
EluEndToEndTest<armnn::DataType::Float16>(defaultBackends);
}
TEST_CASE("RefEluEndToEndTestBFloat16")
{
EluEndToEndTest<armnn::DataType::BFloat16>(defaultBackends);
}
TEST_CASE("RefEluEndToEndTestQAsymmS8")
{
EluEndToEndTest<armnn::DataType::QAsymmS8>(defaultBackends);
}
TEST_CASE("RefEluEndToEndTestQAsymmU8")
{
EluEndToEndTest<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefEluEndToEndTestQSymmS16")
{
EluEndToEndTest<armnn::DataType::QSymmS16>(defaultBackends);
}
TEST_CASE("RefFillEndToEndTest")
{
FillEndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefFillEndToEndTestFloat16")
{
FillEndToEnd<armnn::DataType::Float16>(defaultBackends);
}
TEST_CASE("RefFillEndToEndTestInt32")
{
FillEndToEnd<armnn::DataType::Signed32>(defaultBackends);
}
TEST_CASE("RefFullyConnectedEndToEndTestFloat32")
{
FullyConnectedWithDynamicWeightsEndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefFullyConnectedEndToEndTestNonConstantWeightsConstantBiasesFloat32")
{
FullyConnectedWithDynamicOrConstantInputsEndToEnd<armnn::DataType::Float32>(defaultBackends, true, true);
}
TEST_CASE("RefFullyConnectedEndToEndTestConstantWeightsNonConstantBiasesFloat32")
{
FullyConnectedWithDynamicOrConstantInputsEndToEnd<armnn::DataType::Float32>(defaultBackends, true, false);
}
TEST_CASE("RefGatherFloatTest")
{
GatherEndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefGatherUint8Test")
{
GatherEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefGatherInt16Test")
{
GatherEndToEnd<armnn::DataType::QSymmS16>(defaultBackends);
}
TEST_CASE("RefGatherMultiDimFloatTest")
{
GatherMultiDimEndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefGatherMultiDimUint8Test")
{
GatherMultiDimEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefGatherMultiDimInt16Test")
{
GatherMultiDimEndToEnd<armnn::DataType::QSymmS16>(defaultBackends);
}
// DepthToSpace
TEST_CASE("DephtToSpaceEndToEndNchwFloat32")
{
DepthToSpaceEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("DephtToSpaceEndToEndNchwFloat16")
{
DepthToSpaceEndToEnd<armnn::DataType::Float16>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("DephtToSpaceEndToEndNchwUint8")
{
DepthToSpaceEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("DephtToSpaceEndToEndNchwInt16")
{
DepthToSpaceEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("DephtToSpaceEndToEndNhwcFloat32")
{
DepthToSpaceEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("DephtToSpaceEndToEndNhwcFloat16")
{
DepthToSpaceEndToEnd<armnn::DataType::Float16>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("DephtToSpaceEndToEndNhwcUint8")
{
DepthToSpaceEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("DephtToSpaceEndToEndNhwcInt16")
{
DepthToSpaceEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NHWC);
}
// Dequantize
TEST_CASE("DequantizeEndToEndSimpleTest")
{
DequantizeEndToEndSimple<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("DequantizeEndToEndOffsetTest")
{
DequantizeEndToEndOffset<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("DequantizeEndToEndSimpleInt16Test")
{
DequantizeEndToEndSimple<armnn::DataType::QSymmS16>(defaultBackends);
}
TEST_CASE("DequantizeEndToEndOffsetInt16Test")
{
DequantizeEndToEndOffset<armnn::DataType::QSymmS16>(defaultBackends);
}
TEST_CASE("RefDetectionPostProcessRegularNmsTest")
{
std::vector<float> boxEncodings({
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, -1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f
});
std::vector<float> scores({
0.0f, 0.9f, 0.8f,
0.0f, 0.75f, 0.72f,
0.0f, 0.6f, 0.5f,
0.0f, 0.93f, 0.95f,
0.0f, 0.5f, 0.4f,
0.0f, 0.3f, 0.2f
});
std::vector<float> anchors({
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 100.5f, 1.0f, 1.0f
});
DetectionPostProcessRegularNmsEndToEnd<armnn::DataType::Float32>(defaultBackends, boxEncodings, scores, anchors);
}
inline void QuantizeData(uint8_t* quant, const float* dequant, const TensorInfo& info)
{
for (size_t i = 0; i < info.GetNumElements(); i++)
{
quant[i] = armnn::Quantize<uint8_t>(dequant[i], info.GetQuantizationScale(), info.GetQuantizationOffset());
}
}
TEST_CASE("RefDetectionPostProcessRegularNmsUint8Test")
{
armnn::TensorInfo boxEncodingsInfo({ 1, 6, 4 }, armnn::DataType::Float32);
armnn::TensorInfo scoresInfo({ 1, 6, 3 }, armnn::DataType::Float32);
armnn::TensorInfo anchorsInfo({ 6, 4 }, armnn::DataType::Float32);
boxEncodingsInfo.SetQuantizationScale(1.0f);
boxEncodingsInfo.SetQuantizationOffset(1);
scoresInfo.SetQuantizationScale(0.01f);
scoresInfo.SetQuantizationOffset(0);
anchorsInfo.SetQuantizationScale(0.5f);
anchorsInfo.SetQuantizationOffset(0);
std::vector<float> boxEncodings({
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, -1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f
});
std::vector<float> scores({
0.0f, 0.9f, 0.8f,
0.0f, 0.75f, 0.72f,
0.0f, 0.6f, 0.5f,
0.0f, 0.93f, 0.95f,
0.0f, 0.5f, 0.4f,
0.0f, 0.3f, 0.2f
});
std::vector<float> anchors({
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 100.5f, 1.0f, 1.0f
});
std::vector<uint8_t> qBoxEncodings(boxEncodings.size(), 0);
std::vector<uint8_t> qScores(scores.size(), 0);
std::vector<uint8_t> qAnchors(anchors.size(), 0);
QuantizeData(qBoxEncodings.data(), boxEncodings.data(), boxEncodingsInfo);
QuantizeData(qScores.data(), scores.data(), scoresInfo);
QuantizeData(qAnchors.data(), anchors.data(), anchorsInfo);
DetectionPostProcessRegularNmsEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, qBoxEncodings,
qScores, qAnchors,
1.0f, 1, 0.01f, 0, 0.5f, 0);
}
TEST_CASE("RefDetectionPostProcessFastNmsTest")
{
std::vector<float> boxEncodings({
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, -1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f
});
std::vector<float> scores({
0.0f, 0.9f, 0.8f,
0.0f, 0.75f, 0.72f,
0.0f, 0.6f, 0.5f,
0.0f, 0.93f, 0.95f,
0.0f, 0.5f, 0.4f,
0.0f, 0.3f, 0.2f
});
std::vector<float> anchors({
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 100.5f, 1.0f, 1.0f
});
DetectionPostProcessFastNmsEndToEnd<armnn::DataType::Float32>(defaultBackends, boxEncodings, scores, anchors);
}
TEST_CASE("RefDetectionPostProcessFastNmsUint8Test")
{
armnn::TensorInfo boxEncodingsInfo({ 1, 6, 4 }, armnn::DataType::Float32);
armnn::TensorInfo scoresInfo({ 1, 6, 3 }, armnn::DataType::Float32);
armnn::TensorInfo anchorsInfo({ 6, 4 }, armnn::DataType::Float32);
boxEncodingsInfo.SetQuantizationScale(1.0f);
boxEncodingsInfo.SetQuantizationOffset(1);
scoresInfo.SetQuantizationScale(0.01f);
scoresInfo.SetQuantizationOffset(0);
anchorsInfo.SetQuantizationScale(0.5f);
anchorsInfo.SetQuantizationOffset(0);
std::vector<float> boxEncodings({
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, -1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f,
0.0f, 1.0f, 0.0f, 0.0f,
0.0f, 0.0f, 0.0f, 0.0f
});
std::vector<float> scores({
0.0f, 0.9f, 0.8f,
0.0f, 0.75f, 0.72f,
0.0f, 0.6f, 0.5f,
0.0f, 0.93f, 0.95f,
0.0f, 0.5f, 0.4f,
0.0f, 0.3f, 0.2f
});
std::vector<float> anchors({
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 0.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 10.5f, 1.0f, 1.0f,
0.5f, 100.5f, 1.0f, 1.0f
});
std::vector<uint8_t> qBoxEncodings(boxEncodings.size(), 0);
std::vector<uint8_t> qScores(scores.size(), 0);
std::vector<uint8_t> qAnchors(anchors.size(), 0);
QuantizeData(qBoxEncodings.data(), boxEncodings.data(), boxEncodingsInfo);
QuantizeData(qScores.data(), scores.data(), scoresInfo);
QuantizeData(qAnchors.data(), anchors.data(), anchorsInfo);
DetectionPostProcessFastNmsEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, qBoxEncodings,
qScores, qAnchors,
1.0f, 1, 0.01f, 0, 0.5f, 0);
}
// HardSwish
TEST_CASE("RefHardSwishEndToEndTestFloat32")
{
HardSwishEndToEndTest<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefHardSwishEndToEndTestFloat16")
{
HardSwishEndToEndTest<armnn::DataType::Float16>(defaultBackends);
}
TEST_CASE("RefHardSwishEndToEndTestBFloat16")
{
HardSwishEndToEndTest<armnn::DataType::BFloat16>(defaultBackends);
}
TEST_CASE("RefHardSwishEndToEndTestQAsymmS8")
{
HardSwishEndToEndTest<armnn::DataType::QAsymmS8>(defaultBackends);
}
TEST_CASE("RefHardSwishEndToEndTestQAsymmU8")
{
HardSwishEndToEndTest<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefHardSwishEndToEndTestQSymmS16")
{
HardSwishEndToEndTest<armnn::DataType::QSymmS16>(defaultBackends);
}
// LogSoftmax
TEST_CASE("RefLogSoftmaxEndToEndTest")
{
LogSoftmaxEndToEndTest(defaultBackends);
}
TEST_CASE("RefPreluEndToEndTestFloat32")
{
PreluEndToEndNegativeTest<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefPreluEndToEndTestUint8")
{
PreluEndToEndPositiveTest<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefPreluEndToEndTestQSymm16")
{
PreluEndToEndPositiveTest<armnn::DataType::QSymmS16>(defaultBackends);
}
TEST_CASE("RefSpaceToDepthNhwcEndToEndTest1")
{
SpaceToDepthNhwcEndToEndTest1(defaultBackends);
}
TEST_CASE("RefSpaceToDepthNchwEndToEndTest1")
{
SpaceToDepthNchwEndToEndTest1(defaultBackends);
}
TEST_CASE("RefSpaceToDepthNhwcEndToEndTest2")
{
SpaceToDepthNhwcEndToEndTest2(defaultBackends);
}
TEST_CASE("RefSpaceToDepthNchwEndToEndTest2")
{
SpaceToDepthNchwEndToEndTest2(defaultBackends);
}
TEST_CASE("RefSplitter1dEndToEndTest")
{
Splitter1dEndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter1dEndToEndUint8Test")
{
Splitter1dEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter2dDim0EndToEndTest")
{
Splitter2dDim0EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter2dDim1EndToEndTest")
{
Splitter2dDim1EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter2dDim0EndToEndUint8Test")
{
Splitter2dDim0EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter2dDim1EndToEndUint8Test")
{
Splitter2dDim1EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter3dDim0EndToEndTest")
{
Splitter3dDim0EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter3dDim1EndToEndTest")
{
Splitter3dDim1EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter3dDim2EndToEndTest")
{
Splitter3dDim2EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter3dDim0EndToEndUint8Test")
{
Splitter3dDim0EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter3dDim1EndToEndUint8Test")
{
Splitter3dDim1EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter3dDim2EndToEndUint8Test")
{
Splitter3dDim2EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim0EndToEndTest")
{
Splitter4dDim0EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim1EndToEndTest")
{
Splitter4dDim1EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim2EndToEndTest")
{
Splitter4dDim2EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim3EndToEndTest")
{
Splitter4dDim3EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim0EndToEndUint8Test")
{
Splitter4dDim0EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim1EndToEndUint8Test")
{
Splitter4dDim1EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim2EndToEndUint8Test")
{
Splitter4dDim2EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefSplitter4dDim3EndToEndUint8Test")
{
Splitter4dDim3EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
// TransposeConvolution2d
TEST_CASE("RefTransposeConvolution2dEndToEndFloatNchwTest")
{
TransposeConvolution2dEndToEnd<armnn::DataType::Float32, armnn::DataType::Float32>(
defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefTransposeConvolution2dEndToEndUint8NchwTest")
{
TransposeConvolution2dEndToEnd<armnn::DataType::QAsymmU8, armnn::DataType::Signed32>(
defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefTransposeConvolution2dEndToEndInt16NchwTest")
{
TransposeConvolution2dEndToEnd<armnn::DataType::QSymmS16, armnn::DataType::Signed32>(
defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefTransposeConvolution2dEndToEndFloatNhwcTest")
{
TransposeConvolution2dEndToEnd<armnn::DataType::Float32, armnn::DataType::Float32>(
defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefTransposeConvolution2dEndToEndUint8NhwcTest")
{
TransposeConvolution2dEndToEnd<armnn::DataType::QAsymmU8, armnn::DataType::Signed32>(
defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefTransposeConvolution2dEndToEndInt16NhwcTest")
{
TransposeConvolution2dEndToEnd<armnn::DataType::QSymmS16, armnn::DataType::Signed32>(
defaultBackends, armnn::DataLayout::NHWC);
}
// Resize Bilinear
TEST_CASE("RefResizeBilinearEndToEndFloatNchwTest")
{
ResizeBilinearEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefResizeBilinearEndToEndUint8NchwTest")
{
ResizeBilinearEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefResizeBilinearEndToEndInt16NchwTest")
{
ResizeBilinearEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefResizeBilinearEndToEndFloatNhwcTest")
{
ResizeBilinearEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefResizeBilinearEndToEndUint8NhwcTest")
{
ResizeBilinearEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefResizeBilinearEndToEndInt16NhwcTest")
{
ResizeBilinearEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NHWC);
}
// Resize NearestNeighbor
TEST_CASE("RefResizeNearestNeighborEndToEndFloatNchwTest")
{
ResizeNearestNeighborEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefResizeNearestNeighborEndToEndUint8NchwTest")
{
ResizeNearestNeighborEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefResizeNearestNeighborEndToEndInt16NchwTest")
{
ResizeNearestNeighborEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NCHW);
}
TEST_CASE("RefResizeNearestNeighborEndToEndFloatNhwcTest")
{
ResizeNearestNeighborEndToEnd<armnn::DataType::Float32>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefResizeNearestNeighborEndToEndUint8NhwcTest")
{
ResizeNearestNeighborEndToEnd<armnn::DataType::QAsymmU8>(defaultBackends, armnn::DataLayout::NHWC);
}
TEST_CASE("RefResizeNearestNeighborEndToEndInt16NhwcTest")
{
ResizeNearestNeighborEndToEnd<armnn::DataType::QSymmS16>(defaultBackends, armnn::DataLayout::NHWC);
}
// InstanceNormalization
TEST_CASE("RefInstanceNormalizationNhwcEndToEndTest1")
{
InstanceNormalizationNhwcEndToEndTest1(defaultBackends);
}
TEST_CASE("RefInstanceNormalizationNchwEndToEndTest1")
{
InstanceNormalizationNchwEndToEndTest1(defaultBackends);
}
TEST_CASE("RefInstanceNormalizationNhwcEndToEndTest2")
{
InstanceNormalizationNhwcEndToEndTest2(defaultBackends);
}
TEST_CASE("RefInstanceNormalizationNchwEndToEndTest2")
{
InstanceNormalizationNchwEndToEndTest2(defaultBackends);
}
// ArgMinMax
TEST_CASE("RefArgMaxSimpleTest")
{
ArgMaxEndToEndSimple<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMaxSimpleUint8Test")
{
ArgMaxEndToEndSimple<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMinSimpleTest")
{
ArgMinEndToEndSimple<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMinSimpleUint8Test")
{
ArgMinEndToEndSimple<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis0Test")
{
ArgMaxAxis0EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis0Uint8Test")
{
ArgMaxAxis0EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMinAxis0Test")
{
ArgMinAxis0EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMinAxis0Uint8Test")
{
ArgMinAxis0EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis1Test")
{
ArgMaxAxis1EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis1Uint8Test")
{
ArgMaxAxis1EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMinAxis1Test")
{
ArgMinAxis1EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMinAxis1Uint8Test")
{
ArgMinAxis1EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis2Test")
{
ArgMaxAxis2EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis2Uint8Test")
{
ArgMaxAxis2EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMinAxis2Test")
{
ArgMinAxis2EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMinAxis2Uint8Test")
{
ArgMinAxis2EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis3Test")
{
ArgMaxAxis3EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMaxAxis3Uint8Test")
{
ArgMaxAxis3EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefArgMinAxis3Test")
{
ArgMinAxis3EndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefArgMinAxis3Uint8Test")
{
ArgMinAxis3EndToEnd<armnn::DataType::QAsymmU8>(defaultBackends);
}
TEST_CASE("RefQLstmEndToEndTest")
{
QLstmEndToEnd(defaultBackends);
}
TEST_CASE("RefRankEndToEndTest")
{
RankEndToEnd<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefRankEndToEndTestFloat16")
{
RankEndToEnd<armnn::DataType::Float16>(defaultBackends);
}
TEST_CASE("RefRankEndToEndTestInt32")
{
RankEndToEnd<armnn::DataType::Signed32>(defaultBackends);
}
TEST_CASE("RefRankEndToEndTestQAsymmS8")
{
RankEndToEnd<armnn::DataType::QAsymmS8>(defaultBackends);
}
TEST_CASE("RefRankEndToEndTestQSymmS16")
{
RankEndToEnd<armnn::DataType::QSymmS16>(defaultBackends);
}
TEST_CASE("RefRankEndToEndTestQSymmS8")
{
RankEndToEnd<armnn::DataType::QSymmS8>(defaultBackends);
}
#if !defined(__ANDROID__)
// Only run these tests on non Android platforms
TEST_CASE("RefImportNonAlignedPointerTest")
{
ImportNonAlignedInputPointerTest(defaultBackends);
}
TEST_CASE("RefExportNonAlignedPointerTest")
{
ExportNonAlignedOutputPointerTest(defaultBackends);
}
TEST_CASE("RefImportAlignedPointerTest")
{
ImportAlignedPointerTest(defaultBackends);
}
TEST_CASE("RefImportOnlyWorkload")
{
ImportOnlyWorkload(defaultBackends);
}
TEST_CASE("RefExportOnlyWorkload")
{
ExportOnlyWorkload(defaultBackends);
}
TEST_CASE("RefImportAndExportWorkload")
{
ImportAndExportWorkload(defaultBackends);
}
TEST_CASE("RefExportOutputWithSeveralOutputSlotConnectionsTest")
{
ExportOutputWithSeveralOutputSlotConnectionsTest(defaultBackends);
}
TEST_CASE("RefStridedSliceInvalidSliceEndToEndTest")
{
StridedSliceInvalidSliceEndToEndTest(defaultBackends);
}
TEST_CASE("RefThreadSafeFP32StridedSlicedEndToEndTest")
{
armnn::experimental::StridedSlicedEndToEndTest<armnn::DataType::Float32>(defaultBackends, 1);
}
TEST_CASE("RefAsyncFP32StridedSlicedMultiThreadedEndToEndTest")
{
armnn::experimental::StridedSlicedMultiThreadedEndToEndTest<armnn::DataType::Float32>(defaultBackends);
}
TEST_CASE("RefAsyncFP32StridedSlicedScheduledMultiThreadedEndToEndTest")
{
armnn::experimental::StridedSlicedEndToEndTest<armnn::DataType::Float32>(defaultBackends, 3);
}
#endif
}