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/*
* Copyright (c) 2021 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.
*/
#ifndef ARM_COMPUTE_TEST_UNIT_TENSOR
#define ARM_COMPUTE_TEST_UNIT_TENSOR
#include "arm_compute/Acl.hpp"
#include "tests/framework/Asserts.h"
#include "tests/framework/Fixture.h"
#include "tests/framework/Macros.h"
#include "tests/validation/Validation.h"
namespace arm_compute
{
namespace test
{
namespace validation
{
/** Test case for AclCreateTensor
*
* Validate that AclCreateTensor behaves as expected with invalid context
*
* Test Steps:
* - Call AclCreateTensor with an invalid context
* - Confirm that AclInvalidArgument is reported
* - Confirm that the tensor is still nullptr
*/
class CreateTensorWithInvalidContextFixture : public framework::Fixture
{
public:
void setup()
{
AclTensor tensor = nullptr;
ARM_COMPUTE_ASSERT(AclCreateTensor(&tensor, nullptr, nullptr, false) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(tensor == nullptr);
};
};
/** Test-case for AclCreateTensor
*
* Validate that AclCreateTensor behaves as expected on invalid descriptor
*
* Test Steps:
* - Call AclCreateTensor with valid context but invalid descriptor
* - Confirm that AclInvalidArgument is reported
* - Confirm that tensor is still nullptr
*/
template <acl::Target Target>
class CreateTensorWithInvalidDescriptorFixture : public framework::Fixture
{
public:
void setup()
{
acl::Context ctx(Target);
AclTensor tensor = nullptr;
ARM_COMPUTE_ASSERT(AclCreateTensor(&tensor, ctx.get(), nullptr, false) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(tensor == nullptr);
// Check invalid data type
AclTensorDescriptor invalid_desc;
invalid_desc.ndims = 4;
invalid_desc.data_type = static_cast<AclDataType>(-1);
ARM_COMPUTE_ASSERT(AclCreateTensor(&tensor, ctx.get(), &invalid_desc, false) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(tensor == nullptr);
// Check invalid number of dimensions
invalid_desc.data_type = AclDataType::AclFloat32;
invalid_desc.ndims = 15;
ARM_COMPUTE_ASSERT(AclCreateTensor(&tensor, ctx.get(), &invalid_desc, false) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(tensor == nullptr);
};
};
/** Test case for AclDestroyTensor
*
* Validate that AclDestroyTensor behaves as expected when an invalid tensor is given
*
* Test Steps:
* - Call AclDestroyTensor with null tensor
* - Confirm that AclInvalidArgument is reported
* - Call AclDestroyTensor on empty array
* - Confirm that AclInvalidArgument is reported
* - Call AclDestroyTensor on an ACL object other than AclTensor
* - Confirm that AclInvalidArgument is reported
* - Confirm that tensor is still nullptr
*/
template <acl::Target Target>
class DestroyInvalidTensorFixture : public framework::Fixture
{
public:
void setup()
{
acl::Context ctx(Target);
std::array<char, 256> empty_array{};
AclTensor tensor = nullptr;
ARM_COMPUTE_ASSERT(AclDestroyTensor(tensor) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(AclDestroyTensor(reinterpret_cast<AclTensor>(ctx.get())) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(AclDestroyTensor(reinterpret_cast<AclTensor>(empty_array.data())) == AclStatus::AclInvalidArgument);
ARM_COMPUTE_ASSERT(tensor == nullptr);
};
};
/** Test case for AclCreateTensor
*
* Validate that a tensor can be created successfully
*
* Test Steps:
* - Create a valid context
* - Create a valid tensor
* - Confirm that AclSuccess is returned
*/
template <acl::Target Target>
class SimpleTensorFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 2, 3 }, acl::DataType::Float32), &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
};
};
/** Test case for AclTensor
*
* Validate that multiple tensors can be created successfully
* Possibly stress the possibility of memory leaks
*
* Test Steps:
* - Create a valid context
* - Create a lot of tensors
* - Confirm that AclSuccess is returned
*/
template <acl::Target Target>
class TensorStressFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
const unsigned int num_tensors = 1024;
for(unsigned int i = 0; i < num_tensors; ++i)
{
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 1024, 1024 }, acl::DataType::Float32), &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
}
};
};
/** Test case for AclMapTensor
*
* Validate that map on an invalid object fails
*
* Test Steps:
* - Create a valid context
* - Pass and invalid object for mapping
* - Confirm that AclInvalidArgument is returned
*/
template <acl::Target Target>
class MapInvalidTensorFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
void *handle = nullptr;
ARM_COMPUTE_ASSERT(AclMapTensor(reinterpret_cast<AclTensor>(ctx.get()), &handle) == AclStatus::AclInvalidArgument);
};
};
/** Test case for AclMapTensor
*
* Validate that map of an unallocated pointer is nullptr
*
* Test Steps:
* - Create a valid context
* - Create a valid tensor without allocating
* - Map tensor
* - Check that mapping is nullptr
*/
template <acl::Target Target>
class MapNotAllocatedTensorFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 8, 8 }, acl::DataType::Float32), false /* allocate */, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
ARM_COMPUTE_ASSERT(tensor.map() == nullptr);
};
};
/** Test case for AclMapTensor
*
* Validate that map of a valid tensor return a non-nullptr value
*
* Test Steps:
* - Create a valid context
* - Create a valid tensor while allocating
* - Map tensor
* - Check that mapping is not nullptr
*/
template <acl::Target Target>
class MapAllocatedTensorFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 8, 8 }, acl::DataType::Float32), &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
void *handle = tensor.map();
ARM_COMPUTE_ASSERT(handle != nullptr);
ARM_COMPUTE_ASSERT(tensor.unmap(handle) == acl::StatusCode::Success);
};
};
/** Test case for AclTensorImport
*
* Validate that an externally memory can be successfully imported
*
* Test Steps:
* - Create a valid context
* - Create a valid tensor without allocating
* - Allocate external memory
* - Import memory to the tensor
* - Check that imported pointer matches
*/
template <acl::Target Target>
class ImportMemoryFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
const int32_t size = 8;
acl::Tensor tensor(ctx, acl::TensorDescriptor({ size }, acl::DataType::Float32), false /* allocate */, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
std::vector<float> data(size);
err = tensor.import(data.data(), acl::ImportType::Host);
void *handle = tensor.map();
ARM_COMPUTE_ASSERT(handle == data.data());
ARM_COMPUTE_ASSERT(tensor.unmap(handle) == acl::StatusCode::Success);
}
};
/** Test case for get_size() interface of Tensor
*
*
* Test Steps:
* - Create a valid context
* - Create a valid tensor
* - Compare the size value returned with the expected value
*/
template <acl::Target Target>
class TensorSizeFixture : public framework::Fixture
{
public:
void setup()
{
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 2, 3 }, acl::DataType::Float32), &err);
// size should be 6 elements (2x3) times 4 bytes (float32) = 24 bytes
constexpr size_t expected_size = 24;
ARM_COMPUTE_ASSERT(tensor.get_size() == expected_size);
};
};
/** Test case for get_size() dealing with invalid arguments
*
* Test Steps:
* - Test nullptr tensor can return a correct error
* - Create a valid tensor
* - Test C interface with null size argument can return a correct error
*/
template <acl::Target Target>
class InvalidTensorSizeFixture : public framework::Fixture
{
public:
void setup()
{
// Null tensor
AclTensor null_tensor = nullptr;
uint64_t size{ 0 };
ARM_COMPUTE_ASSERT(AclGetTensorSize(null_tensor, &size) == AclStatus::AclInvalidArgument);
// Create valid tensor
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 2, 3 }, acl::DataType::Float32), &err);
// Null size argument
ARM_COMPUTE_ASSERT(AclGetTensorSize(tensor.get(), nullptr) == AclStatus::AclInvalidArgument);
};
};
template <acl::Target Target>
class DescriptorConversionFixture : public framework::Fixture
{
bool compare_descriptor(const AclTensorDescriptor &desc_a, const AclTensorDescriptor &desc_b)
{
auto are_descriptors_same = true;
are_descriptors_same &= desc_a.ndims == desc_b.ndims;
are_descriptors_same &= desc_a.data_type == desc_b.data_type;
are_descriptors_same &= desc_a.shape != nullptr && desc_b.shape != nullptr;
for(int32_t d = 0; d < desc_a.ndims; ++d)
{
are_descriptors_same &= desc_a.shape[d] == desc_b.shape[d];
}
// other attributes should be added here
return are_descriptors_same;
}
public:
void setup()
{
auto err{ acl::StatusCode::Success };
auto ctx{ acl::Context(Target, &err) };
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
auto desc{ acl::TensorDescriptor({ 2, 3 }, acl::DataType::Float32) };
acl::Tensor tensor(ctx, desc, &err);
auto desc_from_tensor = tensor.get_descriptor();
ARM_COMPUTE_ASSERT(compare_descriptor(*desc.get(), *desc_from_tensor.get()));
ARM_COMPUTE_ASSERT(desc == desc_from_tensor);
// Test c interface with "prepopulated" descriptor
// Note: When c interface used, there are possibility of memory leak
// if members are not correctly deleted (e.g., shape).
// Since that is considered user's responsibility, we don't test here.
AclTensorDescriptor prepopulated_descriptor
{
3, nullptr, AclDataType::AclBFloat16, nullptr, 0
};
ARM_COMPUTE_ASSERT(AclGetTensorDescriptor(tensor.get(), &prepopulated_descriptor) == AclStatus::AclSuccess);
ARM_COMPUTE_ASSERT(compare_descriptor(*desc.get(), prepopulated_descriptor));
ARM_COMPUTE_ASSERT(desc == acl::TensorDescriptor(prepopulated_descriptor));
};
};
template <acl::Target Target>
class InvalidDescriptorConversionFixture : public framework::Fixture
{
public:
void setup()
{
// Null tensor
AclTensor null_tensor = nullptr;
AclTensorDescriptor desc{};
ARM_COMPUTE_ASSERT(AclGetTensorDescriptor(null_tensor, &desc) == AclStatus::AclInvalidArgument);
// Create valid tensor
acl::StatusCode err = acl::StatusCode::Success;
acl::Context ctx(Target, &err);
ARM_COMPUTE_ASSERT(err == acl::StatusCode::Success);
acl::Tensor tensor(ctx, acl::TensorDescriptor({ 2, 3 }, acl::DataType::Float32), &err);
// Null size argument
ARM_COMPUTE_ASSERT(AclGetTensorDescriptor(tensor.get(), nullptr) == AclStatus::AclInvalidArgument);
};
};
} // namespace validation
} // namespace test
} // namespace arm_compute
#endif /* ARM_COMPUTE_TEST_UNIT_TENSOR */
|
