// // Copyright (c) 2017 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. // #ifndef TEST_CONFORMANCE_CLCPP_SUBGROUPS_TEST_SG_SCAN_INCLUSIVE_HPP #define TEST_CONFORMANCE_CLCPP_SUBGROUPS_TEST_SG_SCAN_INCLUSIVE_HPP #include #include // Common for all OpenCL C++ tests #include "../common.hpp" // Common for tests of sub-group functions #include "common.hpp" template std::string generate_sg_scan_inclusive_kernel_code() { return "#include \n" "#include \n" "#include \n" "using namespace cl;\n" "__kernel void test_sg_scan_inclusive(global_ptr<" + type_name() + "[]> input, " "global_ptr<" + type_name() + "[]> output)\n" "{\n" " ulong tid = get_global_id(0);\n" " " + type_name() + " result = sub_group_scan_inclusive(input[tid]);\n" " output[tid] = result;\n" "}\n"; } template int verify_sg_scan_inclusive_add(const std::vector &in, const std::vector &out, size_t wg_size, size_t sg_size) { size_t i, j, k; for (i = 0; i < in.size(); i += wg_size) { for (j = 0; j < ((in.size() - i) > wg_size ? wg_size : (in.size() - i)); j+= sg_size) { CL_INT_TYPE sum = 0; // Check if all work-items in sub-group stored correct value for (k = 0; k < ((wg_size - j) > sg_size ? sg_size : (wg_size - j)); k++) { sum += in[i + j + k]; if (sum != out[i + j + k]) { log_info( "sub_group_scan_exclusive_add %s: Error at %lu: expected = %lu, got = %lu\n", type_name().c_str(), i + j, static_cast(sum), static_cast(out[i + j + k])); return -1; } } } } return CL_SUCCESS; } template int verify_sg_scan_inclusive_min(const std::vector &in, const std::vector &out, size_t wg_size, size_t sg_size) { size_t i, j, k; for (i = 0; i < in.size(); i += wg_size) { for (j = 0; j < ((in.size() - i) > wg_size ? wg_size : (in.size() - i)); j+= sg_size) { CL_INT_TYPE min = (std::numeric_limits::max)(); // Check if all work-items in sub-group stored correct value for (k = 0; k < ((wg_size - j) > sg_size ? sg_size : (wg_size - j)); k++) { min = std::min(min, in[i + j + k]); if (min != out[i + j + k]) { log_info( "sub_group_scan_exclusive_min %s: Error at %lu: expected = %lu, got = %lu\n", type_name().c_str(), i + j, static_cast(min), static_cast(out[i + j + k])); return -1; } } } } return CL_SUCCESS; } template int verify_sg_scan_inclusive_max(const std::vector &in, const std::vector &out, size_t wg_size, size_t sg_size) { size_t i, j, k; for (i = 0; i < in.size(); i += wg_size) { for (j = 0; j < ((in.size() - i) > wg_size ? wg_size : (in.size() - i)); j+= sg_size) { CL_INT_TYPE max = (std::numeric_limits::min)(); // Check if all work-items in sub-group stored correct value for (k = 0; k < ((wg_size - j) > sg_size ? sg_size : (wg_size - j)); k++) { max = std::max(max, in[i + j + k]); if (max != out[i + j + k]) { log_info( "sub_group_scan_exclusive_max %s: Error at %lu: expected = %lu, got = %lu\n", type_name().c_str(), i + j, static_cast(max), static_cast(out[i + j + k])); return -1; } } } } return CL_SUCCESS; } template int verify_sg_scan_inclusive(const std::vector &in, const std::vector &out, size_t wg_size, size_t sg_size) { switch (op) { case work_group_op::add: return verify_sg_scan_inclusive_add(in, out, wg_size, sg_size); case work_group_op::min: return verify_sg_scan_inclusive_min(in, out, wg_size, sg_size); case work_group_op::max: return verify_sg_scan_inclusive_max(in, out, wg_size, sg_size); } return -1; } template int sub_group_scan_inclusive(cl_device_id device, cl_context context, cl_command_queue queue, size_t count) { // don't run test for unsupported types if(!type_supported(device)) { return CL_SUCCESS; } cl_mem buffers[2]; cl_program program; cl_kernel kernel; size_t wg_size; size_t sg_max_size; size_t work_size[1]; int err; std::string code_str = generate_sg_scan_inclusive_kernel_code(); // ----------------------------------------------------------------------------------- // ------------- ONLY FOR OPENCL 22 CONFORMANCE TEST 22 DEVELOPMENT ------------------ // ----------------------------------------------------------------------------------- // Only OpenCL C++ to SPIR-V compilation #if defined(DEVELOPMENT) && defined(ONLY_SPIRV_COMPILATION) err = create_opencl_kernel(context, &program, &kernel, code_str, "test_sg_scan_inclusive"); RETURN_ON_ERROR(err) return err; // Use OpenCL C kernels instead of OpenCL C++ kernels (test C++ host code) #elif defined(DEVELOPMENT) && defined(USE_OPENCLC_KERNELS) log_info("SKIPPED: OpenCL C kernels not provided for this test. Skipping the test.\n"); return CL_SUCCESS; #else err = create_opencl_kernel(context, &program, &kernel, code_str, "test_sg_scan_inclusive"); RETURN_ON_ERROR(err) #endif err = clGetKernelWorkGroupInfo(kernel, device, CL_KERNEL_WORK_GROUP_SIZE, sizeof(size_t), &wg_size, NULL); RETURN_ON_CL_ERROR(err, "clGetKernelWorkGroupInfo") size_t param_value_size = 0; err = clGetKernelSubGroupInfo( kernel, device, CL_KERNEL_MAX_SUB_GROUP_SIZE_FOR_NDRANGE, sizeof(size_t), static_cast(&wg_size), sizeof(size_t), static_cast(&sg_max_size), ¶m_value_size ); RETURN_ON_CL_ERROR(err, "clGetKernelSubGroupInfo") // Verify size of returned param if(param_value_size != sizeof(size_t)) { RETURN_ON_ERROR_MSG(-1, "Returned size of max sub group size not valid! (Expected %lu, got %lu)\n", sizeof(size_t), param_value_size ) } // Calculate global work size size_t flat_work_size; size_t wg_number = static_cast( std::ceil(static_cast(count) / wg_size) ); flat_work_size = wg_number * wg_size; work_size[0] = flat_work_size; std::vector input = generate_input(flat_work_size, wg_size); std::vector output = generate_output(flat_work_size, wg_size); buffers[0] = clCreateBuffer(context, (cl_mem_flags)(CL_MEM_READ_WRITE), sizeof(CL_INT_TYPE) * input.size(), NULL, &err); RETURN_ON_CL_ERROR(err, "clCreateBuffer"); buffers[1] = clCreateBuffer(context, (cl_mem_flags)(CL_MEM_READ_WRITE), sizeof(CL_INT_TYPE) * output.size(), NULL, &err); RETURN_ON_CL_ERROR(err, "clCreateBuffer"); err = clEnqueueWriteBuffer( queue, buffers[0], CL_TRUE, 0, sizeof(CL_INT_TYPE) * input.size(), static_cast(input.data()), 0, NULL, NULL ); RETURN_ON_CL_ERROR(err, "clEnqueueWriteBuffer"); err = clSetKernelArg(kernel, 0, sizeof(buffers[0]), &buffers[0]); err |= clSetKernelArg(kernel, 1, sizeof(buffers[1]), &buffers[1]); RETURN_ON_CL_ERROR(err, "clSetKernelArg"); err = clEnqueueNDRangeKernel(queue, kernel, 1, NULL, work_size, &wg_size, 0, NULL, NULL); RETURN_ON_CL_ERROR(err, "clEnqueueNDRangeKernel"); err = clEnqueueReadBuffer( queue, buffers[1], CL_TRUE, 0, sizeof(CL_INT_TYPE) * output.size(), static_cast(output.data()), 0, NULL, NULL ); RETURN_ON_CL_ERROR(err, "clEnqueueReadBuffer"); if (verify_sg_scan_inclusive(input, output, wg_size, sg_max_size) != CL_SUCCESS) { RETURN_ON_ERROR_MSG(-1, "sub_group_scan_inclusive_%s %s failed", to_string(op).c_str(), type_name().c_str()); } log_info("sub_group_scan_inclusive_%s %s passed\n", to_string(op).c_str(), type_name().c_str()); clReleaseMemObject(buffers[0]); clReleaseMemObject(buffers[1]); clReleaseKernel(kernel); clReleaseProgram(program); return err; } AUTO_TEST_CASE(test_sub_group_scan_inclusive_add) (cl_device_id device, cl_context context, cl_command_queue queue, int n_elems) { int error = CL_SUCCESS; int local_error = CL_SUCCESS; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; if(error != CL_SUCCESS) return -1; return CL_SUCCESS; } AUTO_TEST_CASE(test_sub_group_scan_inclusive_min) (cl_device_id device, cl_context context, cl_command_queue queue, int n_elems) { int error = CL_SUCCESS; int local_error = CL_SUCCESS; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; if(error != CL_SUCCESS) return -1; return CL_SUCCESS; } AUTO_TEST_CASE(test_sub_group_scan_inclusive_max) (cl_device_id device, cl_context context, cl_command_queue queue, int n_elems) { int error = CL_SUCCESS; int local_error = CL_SUCCESS; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; local_error = sub_group_scan_inclusive(device, context, queue, n_elems); CHECK_ERROR(local_error) error |= local_error; if(error != CL_SUCCESS) return -1; return CL_SUCCESS; } #endif // TEST_CONFORMANCE_CLCPP_SUBGROUPS_TEST_SG_SCAN_INCLUSIVE_HPP