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OpenCL-CTS/test_conformance/api/test_kernel_attributes.cpp
Chetan Mistry 71e2681414 Add Test for CL_KERNEL_ATTRIBUTES (#832) (#1055) 
* Improve Functionality of Harness

In the harness we previously were able to determine whether or
not a device supports the half or double data types, but doing so
required unintuitive function calls and would need to be repeated
per test.
A new pair of functions have been added which clearly state
what they do, and makes it easier to determine whether or not
a device supports the types.

Signed-off-by: Chetankumar Mistry <chetan.mistry@arm.com>

* Add Test for CL_KERNEL_ATTRIBUTES (#832)

This test generates dummy kernels which have any
permutation combining the following attributes:

    * vec_type_hint
    * work_group_size_hint
    * reqd_work_group_size

It then gets the attributes by using clGetKernelInfo
and validates that the attributes returned are correct.
By matching the attributes which were used to generate
the kernel are present in the returned string from
clGetKernelInfo.
This test has been implemented as part of the
test_conformance/api suite.

Signed-off-by: Chetankumar Mistry <chetan.mistry@arm.com>

* [SQUASH] Remove Signed Vector Attribute Hints

As per comments, SPIR-V does not distinguish the signedness
of an argument. This change removes the "signed" types
to ensure that the test passes in all scenarios.

Signed-off-by: Chetankumar Mistry <chetan.mistry@arm.com>

* [SQUASH] Add TODO for Signed Vector Hints

As the current version only tests for unsigned
vector types (uchar/uint/etc), add a TODO in the code
as a reference to future work to introduce signed vector
tests

Signed-off-by: Chetankumar Mistry <chetan.mistry@arm.com>
2021-05-13 09:20:45 +01:00

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//
// Copyright (c) 2020 The Khronos Group Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
#include <iostream>
#include <vector>
#include <string>
#include <algorithm>
#include "procs.h"
#include "harness/errorHelpers.h"
#include "harness/typeWrappers.h"
#include "harness/parseParameters.h"
using KernelAttributes = std::vector<std::string>;
static std::string generate_kernel_source(const KernelAttributes& attributes)
{
std::string kernel;
for (auto attribute : attributes)
{
kernel += "__attribute__((" + attribute + "))\n";
}
kernel += "__kernel void test_kernel(){}";
return kernel;
}
using AttributePermutations = std::vector<KernelAttributes>;
// The following combinations have been chosen as they place each of the
// attribute types in the different orders that they can occur. While distinct
// permutations would provide a complete overview of the API the sheer number of
// combinations increases the runtime of this test by an unreasonable amount
AttributePermutations vect_tests;
AttributePermutations work_tests;
AttributePermutations reqd_tests;
AttributePermutations vect_reqd_tests;
AttributePermutations work_vect_tests;
AttributePermutations reqd_work_tests;
AttributePermutations vect_work_reqd_tests;
AttributePermutations work_reqd_vect_tests;
AttributePermutations reqd_vect_work_tests;
// Generate a vector with vec_type_hint(<data_type>) so that it can be used to
// generate different kernels
static KernelAttributes generate_vec_type_hint_data(cl_device_id deviceID)
{
KernelAttributes vec_type_hint_data;
// TODO Test for signed vectors (char/short/int/etc)
std::vector<std::string> vector_types = { "uchar", "ushort", "uint",
"float" };
if (gHasLong)
{
vector_types.push_back("ulong");
}
if (device_supports_half(deviceID))
{
vector_types.push_back("half");
}
if (device_supports_double(deviceID))
{
vector_types.push_back("double");
}
const auto vector_sizes = { "2", "3", "4", "8", "16" };
for (auto type : vector_types)
{
for (auto size : vector_sizes)
{
vec_type_hint_data.push_back("vec_type_hint(" + type + size + ")");
}
}
return vec_type_hint_data;
}
struct WorkGroupDimensions
{
int x;
int y;
int z;
};
// Generate vectors to store reqd_work_group_size(<dimensions>) and
// work_group_size_hint(<dimensions>) so that they can be used to generate
// different kernels
static KernelAttributes generate_reqd_work_group_size_data(
const std::vector<WorkGroupDimensions>& work_group_dimensions)
{
KernelAttributes reqd_work_group_size_data;
for (auto dimension : work_group_dimensions)
{
reqd_work_group_size_data.push_back(
"reqd_work_group_size(" + std::to_string(dimension.x) + ","
+ std::to_string(dimension.y) + "," + std::to_string(dimension.z)
+ ")");
}
return reqd_work_group_size_data;
}
static KernelAttributes generate_work_group_size_data(
const std::vector<WorkGroupDimensions>& work_group_dimensions)
{
KernelAttributes work_group_size_hint_data;
for (auto dimension : work_group_dimensions)
{
work_group_size_hint_data.push_back(
"work_group_size_hint(" + std::to_string(dimension.x) + ","
+ std::to_string(dimension.y) + "," + std::to_string(dimension.z)
+ ")");
}
return work_group_size_hint_data;
}
// Populate the Global Vectors which store individual Kernel Attributes
static void populate_single_attribute_tests(
// Vectors to store the different data that fill the attributes
const KernelAttributes& vec_type_hint_data,
const KernelAttributes& work_group_size_hint_data,
const KernelAttributes& reqd_work_group_size_data)
{
for (auto vector_test : vec_type_hint_data)
{
// Initialise vec_type_hint attribute tests
vect_tests.push_back({ vector_test });
}
for (auto work_group_test : work_group_size_hint_data)
{
// Initialise work_group_size_hint attribute test
work_tests.push_back({ work_group_test });
}
for (auto reqd_work_group_test : reqd_work_group_size_data)
{
// Initialise reqd_work_group_size attribute tests
reqd_tests.push_back({ reqd_work_group_test });
}
}
// Populate the Global Vectors which store the different permutations of 2
// Kernel Attributes
static void populate_double_attribute_tests(
const KernelAttributes& vec_type_hint_data,
const KernelAttributes& work_group_size_hint_data,
const KernelAttributes& reqd_work_group_size_data)
{
for (auto vector_test : vec_type_hint_data)
{
for (auto work_group_test : work_group_size_hint_data)
{
// Initialise the tests for the permutation of work_group_size_hint
// combined with vec_type_hint
work_vect_tests.push_back({ work_group_test, vector_test });
}
for (auto reqd_work_group_test : reqd_work_group_size_data)
{
// Initialise the tests for the permutation of vec_type_hint and
// reqd_work_group_size
vect_reqd_tests.push_back({ vector_test, reqd_work_group_test });
}
}
for (auto work_group_test : work_group_size_hint_data)
{
for (auto reqd_work_group_test : reqd_work_group_size_data)
{
// Initialse the tests for the permutation of reqd_work_group_size
// and work_group_size_hint
reqd_work_tests.push_back(
{ reqd_work_group_test, work_group_test });
}
}
}
// Populate the Global Vectors which store the different permutations of 3
// Kernel Attributes
static void populate_triple_attribute_tests(
const KernelAttributes& vec_type_hint_data,
const KernelAttributes& work_group_size_hint_data,
const KernelAttributes& reqd_work_group_size_data)
{
for (auto vector_test : vec_type_hint_data)
{
for (auto work_group_test : work_group_size_hint_data)
{
for (auto reqd_work_group_test : reqd_work_group_size_data)
{
// Initialise the chosen permutations of 3 attributes
vect_work_reqd_tests.push_back(
{ vector_test, work_group_test, reqd_work_group_test });
work_reqd_vect_tests.push_back(
{ work_group_test, reqd_work_group_test, vector_test });
reqd_vect_work_tests.push_back(
{ reqd_work_group_test, vector_test, work_group_test });
}
}
}
}
static const std::vector<AttributePermutations*>
generate_attribute_tests(const KernelAttributes& vec_type_hint_data,
const KernelAttributes& work_group_size_hint_data,
const KernelAttributes& reqd_work_group_size_data)
{
populate_single_attribute_tests(vec_type_hint_data,
work_group_size_hint_data,
reqd_work_group_size_data);
populate_double_attribute_tests(vec_type_hint_data,
work_group_size_hint_data,
reqd_work_group_size_data);
populate_triple_attribute_tests(vec_type_hint_data,
work_group_size_hint_data,
reqd_work_group_size_data);
// Store all of the filled vectors in a single structure
const std::vector<AttributePermutations*> all_tests = {
&vect_tests, &work_tests, &reqd_tests,
&work_vect_tests, &vect_reqd_tests, &reqd_work_tests,
&vect_work_reqd_tests, &work_reqd_vect_tests, &reqd_vect_work_tests
};
return all_tests;
}
static const std::vector<AttributePermutations*>
initialise_attribute_data(cl_device_id deviceID)
{
// This vector stores different work group dimensions that can be used by
// the reqd_work_group_size and work_group_size_hint attributes. It
// currently only has a single value to minimise time complexity of the
// overall test but can be easily changed.
static const std::vector<WorkGroupDimensions> work_group_dimensions = {
{ 1, 1, 1 }
};
KernelAttributes vec_type_hint_data = generate_vec_type_hint_data(deviceID);
KernelAttributes work_group_size_hint_data =
generate_work_group_size_data(work_group_dimensions);
KernelAttributes reqd_work_group_size_data =
generate_reqd_work_group_size_data(work_group_dimensions);
// Generate all the permutations of attributes to create different test
// suites
return generate_attribute_tests(vec_type_hint_data,
work_group_size_hint_data,
reqd_work_group_size_data);
}
static bool run_test(cl_context context, cl_device_id deviceID,
const AttributePermutations& permutations)
{
bool success = true;
for (auto attribute_permutation : permutations)
{
std::string kernel_source_string =
generate_kernel_source(attribute_permutation);
const char* kernel_src = kernel_source_string.c_str();
clProgramWrapper program;
clKernelWrapper kernel;
cl_int err = create_single_kernel_helper(context, &program, &kernel, 1,
&kernel_src, "test_kernel");
test_error(err, "create_single_kernel_helper");
// Get the size of the kernel attribute string returned
size_t size = 0;
err = clGetKernelInfo(kernel, CL_KERNEL_ATTRIBUTES, 0, nullptr, &size);
test_error(err, "clGetKernelInfo");
std::vector<char> attributes(size);
err = clGetKernelInfo(kernel, CL_KERNEL_ATTRIBUTES, attributes.size(),
attributes.data(), nullptr);
test_error(err, "clGetKernelInfo");
std::string attribute_string(attributes.data());
attribute_string.erase(
std::remove(attribute_string.begin(), attribute_string.end(), ' '),
attribute_string.end());
if (gCompilationMode != kOnline)
{
if (!attribute_string.empty())
{
success = false;
log_error("Error: Expected an empty string\n");
log_error("Attribute string reported as: %s\n",
attribute_string.c_str());
}
}
else
{
bool permutation_success = true;
for (auto attribute : attribute_permutation)
{
if (attribute_string.find(attribute) == std::string::npos)
{
success = false;
permutation_success = false;
log_error("ERROR: did not find expected attribute: '%s'\n",
attribute.c_str());
}
}
if (!permutation_success)
{
log_error("Attribute string reported as: %s\n",
attribute_string.c_str());
}
}
}
return success;
}
int test_kernel_attributes(cl_device_id deviceID, cl_context context,
cl_command_queue queue, int num_elements)
{
bool success = true;
// Vector to store all of the tests
const std::vector<AttributePermutations*> all_tests =
initialise_attribute_data(deviceID);
for (auto permutations : all_tests)
{
success = success && run_test(context, deviceID, *permutations);
}
return success ? TEST_PASS : TEST_FAIL;
}
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