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/*
* Copyright (c) 2022-2024 Arm Limited.
*
* SPDX-License-Identifier: MIT
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "arm_compute/dynamic_fusion/sketch/gpu/operators/GpuResize.h"
#include "tests/CL/CLAccessor.h"
#include "tests/datasets/ScaleValidationDataset.h"
#include "tests/framework/Asserts.h"
#include "tests/framework/Fixture.h"
#include "tests/framework/Macros.h"
#include "tests/validation/fixtures/dynamic_fusion/operators/ResizeFixture.h"
#include "tests/validation/Validation.h"
using namespace arm_compute::experimental::dynamic_fusion;
namespace arm_compute
{
namespace test
{
namespace validation
{
namespace
{
using datasets::ScaleAlignCornersSamplingPolicySet;
using datasets::ScaleInterpolationPolicySet;
using datasets::ScaleSamplingPolicySet;
using datasets::ScaleShapesBaseDataSet;
/** We consider vector size in byte 16 since the maximum size of
* a vector used by @ref CLScaleKernel is currently 16-byte (float4).
*/
constexpr uint32_t vector_byte = 16;
template <typename T>
constexpr uint32_t num_elements_per_vector()
{
return vector_byte / sizeof(T);
}
/** Quantization information data set */
const auto QuantizationInfoSet = framework::dataset::make("QuantizationInfo",
{
QuantizationInfo(0.5f, -1),
});
/** Tolerance */
constexpr float tolerance_f32_absolute(0.001f);
RelativeTolerance<float> tolerance_f32(0.05);
constexpr float abs_tolerance_f16(0.1f);
RelativeTolerance<half> tolerance_f16(half(0.1));
constexpr float tolerance_num_f32(0.01f);
} // namespace
TEST_SUITE(CL)
TEST_SUITE(DYNAMIC_FUSION)
TEST_SUITE(RESIZE)
TEST_SUITE(Validate)
const auto default_input_shape = TensorShape{2, 3, 3, 2};
const auto default_output_shape = TensorShape{4, 6, 3, 2};
constexpr auto default_data_type = DataType::U8;
constexpr auto default_data_layout = DataLayout::NHWC;
TEST_CASE(NullPtr, framework::DatasetMode::ALL)
{
const TensorInfo input_info = TensorInfo{default_input_shape, 1, default_data_type, default_data_layout};
const TensorInfo output_info = TensorInfo{default_output_shape, 1, default_data_type, default_data_layout};
CLCompileContext cl_compile_ctx = CLKernelLibrary::get().get_compile_context();
GpuWorkloadContext context = GpuWorkloadContext{&cl_compile_ctx};
GpuWorkloadSketch sketch{&context};
// nullptr is given as input
Status status = GpuResize::validate_op(sketch, nullptr, ResizeAttributes());
ARM_COMPUTE_EXPECT(bool(status) == false, framework::LogLevel::ERRORS);
}
TEST_CASE(SupportDataType, framework::DatasetMode::ALL)
{
const std::map<DataType, bool> supported_data_types =
{
{ DataType::U8, false },
{ DataType::S8, false },
{ DataType::QSYMM8, false },
{ DataType::QASYMM8, false },
{ DataType::QASYMM8_SIGNED, false },
{ DataType::QSYMM8_PER_CHANNEL, false },
{ DataType::U16, false },
{ DataType::S16, false },
{ DataType::QSYMM16, false },
{ DataType::QASYMM16, false },
{ DataType::U32, false },
{ DataType::S32, false },
{ DataType::U64, false },
{ DataType::S64, false },
{ DataType::BFLOAT16, false },
{ DataType::F16, true },
{ DataType::F32, true },
{ DataType::F64, false },
{ DataType::SIZET, false },
};
for (auto &kv : supported_data_types)
{
const TensorInfo input_info = TensorInfo{default_input_shape, 1, kv.first, default_data_layout};
CLCompileContext cl_compile_ctx = CLKernelLibrary::get().get_compile_context();
GpuWorkloadContext context = GpuWorkloadContext{&cl_compile_ctx};
GpuWorkloadSketch sketch{&context};
const ITensorInfo *sketch_input_info = context.create_tensor_info(input_info);
ResizeAttributes attributes;
attributes.output_width(default_output_shape[0]); // shape is not important unless it's empty
attributes.output_height(default_output_shape[1]);
Status status = GpuResize::validate_op(sketch, sketch_input_info, attributes);
ARM_COMPUTE_EXPECT(bool(status) == kv.second, framework::LogLevel::ERRORS);
}
}
TEST_CASE(MismatchingDataType, framework::DatasetMode::ALL)
{
constexpr DataType non_default_data_type = DataType::F32;
const TensorInfo input_info = TensorInfo{default_input_shape, 1, default_data_type, default_data_layout};
const TensorInfo output_info = TensorInfo{default_output_shape, 1, non_default_data_type, default_data_layout};
CLCompileContext cl_compile_ctx = CLKernelLibrary::get().get_compile_context();
GpuWorkloadContext context = GpuWorkloadContext{&cl_compile_ctx};
GpuWorkloadSketch sketch{&context};
const ITensorInfo *sketch_input_info = context.create_tensor_info(input_info);
Status status = GpuResize::validate_op(sketch, sketch_input_info, ResizeAttributes());
ARM_COMPUTE_EXPECT(bool(status) == false, framework::LogLevel::ERRORS);
}
TEST_CASE(AlignedCornerNotSupported, framework::DatasetMode::ALL)
{
// Aligned corners require sampling policy to be TOP_LEFT.
constexpr InterpolationPolicy interpolation_policy = InterpolationPolicy::BILINEAR;
constexpr bool align_corners = true;
constexpr SamplingPolicy sampling_policy = SamplingPolicy::CENTER;
const TensorInfo input_info = TensorInfo{default_input_shape, 1, default_data_type, default_data_layout};
const TensorInfo output_info = TensorInfo{default_output_shape, 1, default_data_type, default_data_layout};
CLCompileContext cl_compile_ctx = CLKernelLibrary::get().get_compile_context();
GpuWorkloadContext context = GpuWorkloadContext{&cl_compile_ctx};
GpuWorkloadSketch sketch{&context};
const ITensorInfo *sketch_input_info = context.create_tensor_info(input_info);
ResizeAttributes attributes{};
attributes.interpolation_policy(interpolation_policy).sampling_policy(sampling_policy).align_corners(align_corners);
Status status = GpuResize::validate_op(sketch, sketch_input_info, attributes);
ARM_COMPUTE_EXPECT(bool(status) == false, framework::LogLevel::ERRORS);
}
TEST_CASE(UnsupportedInterpolationPolicy, framework::DatasetMode::ALL)
{
const TensorInfo input_info = TensorInfo{TensorShape(28U, 33U, 2U), 1, DataType::F32, default_data_layout};
const TensorInfo output_info = TensorInfo{TensorShape(26U, 21U, 2U), 1, DataType::F32, default_data_layout};
constexpr auto interpolation_policy = InterpolationPolicy::AREA;
CLCompileContext cl_compile_ctx = CLKernelLibrary::get().get_compile_context();
GpuWorkloadContext context = GpuWorkloadContext{&cl_compile_ctx};
GpuWorkloadSketch sketch{&context};
const ITensorInfo *sketch_input_info = context.create_tensor_info(input_info);
ResizeAttributes attributes{};
attributes.interpolation_policy(interpolation_policy);
Status status = GpuResize::validate_op(sketch, sketch_input_info, attributes);
ARM_COMPUTE_EXPECT(bool(status) == false, framework::LogLevel::ERRORS);
}
TEST_CASE(UnsupportedLayout, framework::DatasetMode::ALL)
{
const TensorInfo input_info = TensorInfo{default_input_shape, 1, default_data_type, DataLayout::NCHW};
const TensorInfo output_info = TensorInfo{default_output_shape, 1, default_data_type, DataLayout::NCHW};
constexpr auto interpolation_policy = InterpolationPolicy::BILINEAR;
CLCompileContext cl_compile_ctx = CLKernelLibrary::get().get_compile_context();
GpuWorkloadContext context = GpuWorkloadContext{&cl_compile_ctx};
GpuWorkloadSketch sketch{&context};
const ITensorInfo *sketch_input_info = context.create_tensor_info(input_info);
ResizeAttributes attributes{};
attributes.interpolation_policy(interpolation_policy);
Status status = GpuResize::validate_op(sketch, sketch_input_info, attributes);
ARM_COMPUTE_EXPECT(bool(status) == false, framework::LogLevel::ERRORS);
}
TEST_SUITE_END() // Validate
template <typename T>
using DynamicFusionResizeFixture = DynamicFusionResizeValidationFixture<CLTensor, CLAccessor, GpuResize, T>;
TEST_SUITE(Float)
TEST_SUITE(FP32)
const auto f32_shape = combine((SCALE_PRECOMMIT_SHAPE_DATASET(num_elements_per_vector<float>())),
framework::dataset::make("DataType", DataType::F32));
FIXTURE_DATA_TEST_CASE(Run,
DynamicFusionResizeFixture<float>,
framework::DatasetMode::ALL,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f32_shape, ScaleSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f32, tolerance_num_f32, tolerance_f32_absolute);
}
FIXTURE_DATA_TEST_CASE(RunAlignCorners,
DynamicFusionResizeFixture<float>,
framework::DatasetMode::ALL,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f32_shape, ScaleAlignCornersSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f32, tolerance_num_f32, tolerance_f32_absolute);
}
const auto f32_nightly_shape = combine((SCALE_NIGHTLY_SHAPE_DATASET(num_elements_per_vector<float>())),
framework::dataset::make("DataType", DataType::F32));
FIXTURE_DATA_TEST_CASE(RunNightly,
DynamicFusionResizeFixture<float>,
framework::DatasetMode::NIGHTLY,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f32_nightly_shape, ScaleSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f32, tolerance_num_f32, tolerance_f32_absolute);
}
FIXTURE_DATA_TEST_CASE(RunNightlyAlignCorners,
DynamicFusionResizeFixture<float>,
framework::DatasetMode::NIGHTLY,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f32_nightly_shape, ScaleAlignCornersSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f32, tolerance_num_f32, tolerance_f32_absolute);
}
TEST_SUITE_END() // FP32
TEST_SUITE(FP16)
const auto f16_shape = combine((SCALE_PRECOMMIT_SHAPE_DATASET(num_elements_per_vector<half>())),
framework::dataset::make("DataType", DataType::F16));
FIXTURE_DATA_TEST_CASE(Run,
DynamicFusionResizeFixture<half>,
framework::DatasetMode::ALL,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f16_shape, ScaleSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f16, 0.0f, abs_tolerance_f16);
}
FIXTURE_DATA_TEST_CASE(RunAlignCorners,
DynamicFusionResizeFixture<half>,
framework::DatasetMode::ALL,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f16_shape, ScaleAlignCornersSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f16, 0.0f, abs_tolerance_f16);
}
const auto f16_nightly_shape = combine((SCALE_NIGHTLY_SHAPE_DATASET(num_elements_per_vector<half>())),
framework::dataset::make("DataType", DataType::F16));
FIXTURE_DATA_TEST_CASE(RunNightly,
DynamicFusionResizeFixture<half>,
framework::DatasetMode::NIGHTLY,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f16_nightly_shape, ScaleSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f16, 0.0f, abs_tolerance_f16);
}
FIXTURE_DATA_TEST_CASE(RunNightlyAlignCorners,
DynamicFusionResizeFixture<half>,
framework::DatasetMode::NIGHTLY,
ASSEMBLE_DATASET_DYNAMIC_FUSION(f16_nightly_shape, ScaleAlignCornersSamplingPolicySet))
{
//Create valid region
TensorInfo src_info(_shape, 1, _data_type);
const ValidRegion valid_region =
calculate_valid_region_scale(src_info, _reference.shape(), _interpolation_policy, _sampling_policy, false);
// Validate output
validate(CLAccessor(_target), _reference, valid_region, tolerance_f16, 0.0f, abs_tolerance_f16);
}
TEST_SUITE_END() // FP16
TEST_SUITE_END() // Float
TEST_SUITE_END() // RESIZE
TEST_SUITE_END() // DYNAMIC_FUSION
TEST_SUITE_END() // CL
} // namespace validation
} // namespace test
} // namespace arm_compute
|
