test_conformance/commonfns/test_clamp.cpp - external/github.com/KhronosGroup/OpenCL-CTS - Git at Google

 //
 // 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.
 //
 #include "harness/compat.h"

 #include <stdio.h>
 #include <string.h>
 #include <sys/types.h>
 #include <sys/stat.h>

 #include "procs.h"

 #ifndef M_PI
 #define M_PI    3.14159265358979323846264338327950288
 #endif

 #define CLAMP_KERNEL( type )                        \
     const char *clamp_##type##_kernel_code =                \
     EMIT_PRAGMA_DIRECTIVE                        \
     "__kernel void test_clamp(__global " #type " *x, __global " #type " *minval, __global " #type " *maxval, __global " #type " *dst)\n" \
     "{\n"                                \
     "    int  tid = get_global_id(0);\n"                \
     "\n"                                \
     "    dst[tid] = clamp(x[tid], minval[tid], maxval[tid]);\n"    \
     "}\n";

 #define CLAMP_KERNEL_V( type, size)                    \
     const char *clamp_##type##size##_kernel_code =            \
     EMIT_PRAGMA_DIRECTIVE                        \
     "__kernel void test_clamp(__global " #type #size " *x, __global " #type #size " *minval, __global " #type #size " *maxval, __global " #type #size " *dst)\n" \
     "{\n"                                \
     "    int  tid = get_global_id(0);\n"                \
     "\n"                                \
     "    dst[tid] = clamp(x[tid], minval[tid], maxval[tid]);\n"    \
     "}\n";

 #define CLAMP_KERNEL_V3( type, size)                    \
     const char *clamp_##type##size##_kernel_code =            \
     EMIT_PRAGMA_DIRECTIVE                        \
     "__kernel void test_clamp(__global " #type " *x, __global " #type " *minval, __global " #type " *maxval, __global " #type " *dst)\n" \
     "{\n"                                \
     "    int  tid = get_global_id(0);\n"                \
     "\n"                                \
     "    vstore3(clamp(vload3(tid, x), vload3(tid,minval), vload3(tid,maxval)), tid, dst);\n"    \
     "}\n";

 #define EMIT_PRAGMA_DIRECTIVE " "
 CLAMP_KERNEL( float )
 CLAMP_KERNEL_V( float, 2 )
 CLAMP_KERNEL_V( float, 4 )
 CLAMP_KERNEL_V( float, 8 )
 CLAMP_KERNEL_V( float, 16 )
 CLAMP_KERNEL_V3( float, 3)
 #undef EMIT_PRAGMA_DIRECTIVE

 #define EMIT_PRAGMA_DIRECTIVE "#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
 CLAMP_KERNEL( double )
 CLAMP_KERNEL_V( double, 2 )
 CLAMP_KERNEL_V( double, 4 )
 CLAMP_KERNEL_V( double, 8 )
 CLAMP_KERNEL_V( double, 16 )
 CLAMP_KERNEL_V3( double, 3 )
 #undef EMIT_PRAGMA_DIRECTIVE

 const char *clamp_float_codes[] = { clamp_float_kernel_code, clamp_float2_kernel_code, clamp_float4_kernel_code, clamp_float8_kernel_code, clamp_float16_kernel_code, clamp_float3_kernel_code };
 const char *clamp_double_codes[] = { clamp_double_kernel_code, clamp_double2_kernel_code, clamp_double4_kernel_code, clamp_double8_kernel_code, clamp_double16_kernel_code, clamp_double3_kernel_code };

 static int verify_clamp(float *x, float *minval, float *maxval, float *outptr, int n)
 {
     float       t;
     int         i;

     for (i=0; i<n; i++)
     {
         t = fminf( fmaxf( x[ i ], minval[ i ] ), maxval[ i ] );
         if (t != outptr[i])
         {
             log_error( "%d) verification error: clamp( %a, %a, %a) = *%a vs. %a\n", i, x[i], minval[i], maxval[i], t, outptr[i] );
             return -1;
         }
     }

     return 0;
 }

 static int verify_clamp_double(double *x, double *minval, double *maxval, double *outptr, int n)
 {
     double       t;
     int         i;

     for (i=0; i<n; i++)
     {
         t = fmin( fmax( x[ i ], minval[ i ] ), maxval[ i ] );
         if (t != outptr[i])
         {
             log_error( "%d) verification error: clamp( %a, %a, %a) = *%a vs. %a\n", i, x[i], minval[i], maxval[i], t, outptr[i] );
             return -1;
         }
     }

     return 0;
 }

 int
 test_clamp(cl_device_id device, cl_context context, cl_command_queue queue, int n_elems)
 {
     cl_mem      streams[8];
     cl_float      *input_ptr[3], *output_ptr;
     cl_double     *input_ptr_double[3], *output_ptr_double = NULL;
     cl_program  *program;
     cl_kernel   *kernel;
     size_t threads[1];
     int num_elements;
     int err;
     int i, j;
     MTdata d;

     program = (cl_program*)malloc(sizeof(cl_program)*kTotalVecCount*2);
     kernel = (cl_kernel*)malloc(sizeof(cl_kernel)*kTotalVecCount*2);

     num_elements = n_elems * (1 << (kVectorSizeCount-1));

     int test_double = 0;
     if(is_extension_available( device, "cl_khr_fp64" )) {
     log_info("Testing doubles.\n");
       test_double = 1;
     }


     // why does this go from 0 to 2?? -- Oh, I see, there are four function
     // arguments to the function, and 3 of them are inputs?
     for( i = 0; i < 3; i++ )
     {
         input_ptr[i] = (cl_float*)malloc(sizeof(cl_float) * num_elements);
         if (test_double) input_ptr_double[i] = (cl_double*)malloc(sizeof(cl_double) * num_elements);
     }
     output_ptr = (cl_float*)malloc(sizeof(cl_float) * num_elements);
     if (test_double) output_ptr_double = (cl_double*)malloc(sizeof(cl_double) * num_elements);

     // why does this go from 0 to 3?
     for( i = 0; i < 4; i++ )
     {
         streams[i] =
             clCreateBuffer(context, CL_MEM_READ_WRITE,
                            sizeof(cl_float) * num_elements, NULL, NULL);
         if (!streams[0])
         {
             log_error("clCreateBuffer failed\n");
             return -1;
         }
     }
     if (test_double)
     for( i = 4; i < 8; i++ )
         {
             streams[i] =
                 clCreateBuffer(context, CL_MEM_READ_WRITE,
                                sizeof(cl_double) * num_elements, NULL, NULL);
             if (!streams[0])
             {
             log_error("clCreateBuffer failed\n");
             return -1;
             }
         }

     d = init_genrand( gRandomSeed );
     for( j = 0; j < num_elements; j++ )
     {
         input_ptr[0][j] = get_random_float(-0x20000000, 0x20000000, d);
         input_ptr[1][j] = get_random_float(-0x20000000, 0x20000000, d);
         input_ptr[2][j] = get_random_float(input_ptr[1][j], 0x20000000, d);

         if (test_double) {
         input_ptr_double[0][j] = get_random_double(-0x20000000, 0x20000000, d);
         input_ptr_double[1][j] = get_random_double(-0x20000000, 0x20000000, d);
         input_ptr_double[2][j] = get_random_double(input_ptr_double[1][j], 0x20000000, d);
         }
     }
     free_mtdata(d); d = NULL;

     for( i = 0; i < 3; i++ )
     {
         err = clEnqueueWriteBuffer( queue, streams[ i ], CL_TRUE, 0, sizeof( cl_float ) * num_elements, input_ptr[ i ], 0, NULL, NULL );
         test_error( err, "Unable to write input buffer" );

         if (test_double) {
         err = clEnqueueWriteBuffer( queue, streams[ 4 + i ], CL_TRUE, 0, sizeof( cl_double ) * num_elements, input_ptr_double[ i ], 0, NULL, NULL );
         test_error( err, "Unable to write input buffer" );
         }
     }

     for( i = 0; i < kTotalVecCount; i++ )
     {
         err = create_single_kernel_helper( context, &program[ i ], &kernel[ i ], 1, &clamp_float_codes[ i ], "test_clamp" );
         test_error( err, "Unable to create kernel" );

         log_info("Just made a program for float, i=%d, size=%d, in slot %d\n", i, g_arrVecSizes[i], i);
         fflush(stdout);

         if (test_double) {
         err = create_single_kernel_helper( context, &program[ kTotalVecCount + i ], &kernel[ kTotalVecCount + i ], 1, &clamp_double_codes[ i ], "test_clamp" );
         log_info("Just made a program for double, i=%d, size=%d, in slot %d\n", i, g_arrVecSizes[i], kTotalVecCount+i);
         fflush(stdout);
         test_error( err, "Unable to create kernel" );
         }
     }

     for( i = 0; i < kTotalVecCount; i++ )
     {
         for( j = 0; j < 4; j++ )
         {
             err = clSetKernelArg( kernel[ i ], j, sizeof( streams[ j ] ), &streams[ j ] );
             test_error( err, "Unable to set kernel argument" );
         }

         threads[0] = (size_t)n_elems;

         err = clEnqueueNDRangeKernel( queue, kernel[i], 1, NULL, threads, NULL, 0, NULL, NULL );
         test_error( err, "Unable to execute kernel" );

         err = clEnqueueReadBuffer( queue, streams[3], true, 0, sizeof(cl_float)*num_elements, (void *)output_ptr, 0, NULL, NULL );
         test_error( err, "Unable to read results" );

         if (verify_clamp(input_ptr[0], input_ptr[1], input_ptr[2], output_ptr, n_elems*((g_arrVecSizes[i]))))
         {
             log_error("CLAMP float%d test failed\n", ((g_arrVecSizes[i])));
             err = -1;
         }
         else
         {
             log_info("CLAMP float%d test passed\n", ((g_arrVecSizes[i])));
             err = 0;
         }


         if (err)
         break;
     }

     // If the device supports double precision then test that
     if (test_double)
     {
         for( ; i < 2*kTotalVecCount; i++ )
         {

             log_info("Start of test_double loop, i is %d\n", i);
             for( j = 0; j < 4; j++ )
             {
                 err = clSetKernelArg( kernel[i], j, sizeof( streams[j+4] ), &streams[j+4] );
                 test_error( err, "Unable to set kernel argument" );
             }

             threads[0] = (size_t)n_elems;

             err = clEnqueueNDRangeKernel( queue, kernel[i], 1, NULL, threads, NULL, 0, NULL, NULL );
             test_error( err, "Unable to execute kernel" );

             err = clEnqueueReadBuffer( queue, streams[7], CL_TRUE, 0, sizeof(cl_double)*num_elements, (void *)output_ptr_double, 0, NULL, NULL );
             test_error( err, "Unable to read results" );

             if (verify_clamp_double(input_ptr_double[0], input_ptr_double[1], input_ptr_double[2], output_ptr_double, n_elems*g_arrVecSizes[(i-kTotalVecCount)]))
             {
                 log_error("CLAMP double%d test failed\n", g_arrVecSizes[(i-kTotalVecCount)]);
                 err = -1;
             }
             else
             {
                 log_info("CLAMP double%d test passed\n", g_arrVecSizes[(i-kTotalVecCount)]);
                 err = 0;
             }

             if (err)
             break;
         }
     }


     for( i = 0; i < ((test_double) ? 8 : 4); i++ )
     {
         clReleaseMemObject(streams[i]);
     }
     for (i=0; i < ((test_double) ? kTotalVecCount * 2-1 : kTotalVecCount); i++)
     {
         clReleaseKernel(kernel[i]);
         clReleaseProgram(program[i]);
     }
     free(input_ptr[0]);
     free(input_ptr[1]);
     free(input_ptr[2]);
     free(output_ptr);
     free(program);
     free(kernel);
     if (test_double) {
         free(input_ptr_double[0]);
         free(input_ptr_double[1]);
         free(input_ptr_double[2]);
         free(output_ptr_double);
     }

     return err;
 }
	//
	// 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.
	//
	#include "harness/compat.h"

	#include <stdio.h>
	#include <string.h>
	#include <sys/types.h>
	#include <sys/stat.h>

	#include "procs.h"

	#ifndef M_PI
	#define M_PI 3.14159265358979323846264338327950288
	#endif

	#define CLAMP_KERNEL( type ) \
	const char *clamp_##type##_kernel_code = \
	EMIT_PRAGMA_DIRECTIVE \
	"__kernel void test_clamp(__global " #type " x, __global " #type " minval, __global " #type " maxval, __global " #type " dst)\n" \
	"{\n" \
	" int tid = get_global_id(0);\n" \
	"\n" \
	" dst[tid] = clamp(x[tid], minval[tid], maxval[tid]);\n" \
	"}\n";

	#define CLAMP_KERNEL_V( type, size) \
	const char *clamp_##type##size##_kernel_code = \
	EMIT_PRAGMA_DIRECTIVE \
	"__kernel void test_clamp(__global " #type #size " x, __global " #type #size " minval, __global " #type #size " maxval, __global " #type #size " dst)\n" \
	"{\n" \
	" int tid = get_global_id(0);\n" \
	"\n" \
	" dst[tid] = clamp(x[tid], minval[tid], maxval[tid]);\n" \
	"}\n";

	#define CLAMP_KERNEL_V3( type, size) \
	const char *clamp_##type##size##_kernel_code = \
	EMIT_PRAGMA_DIRECTIVE \
	"__kernel void test_clamp(__global " #type " x, __global " #type " minval, __global " #type " maxval, __global " #type " dst)\n" \
	"{\n" \
	" int tid = get_global_id(0);\n" \
	"\n" \
	" vstore3(clamp(vload3(tid, x), vload3(tid,minval), vload3(tid,maxval)), tid, dst);\n" \
	"}\n";

	#define EMIT_PRAGMA_DIRECTIVE " "
	CLAMP_KERNEL( float )
	CLAMP_KERNEL_V( float, 2 )
	CLAMP_KERNEL_V( float, 4 )
	CLAMP_KERNEL_V( float, 8 )
	CLAMP_KERNEL_V( float, 16 )
	CLAMP_KERNEL_V3( float, 3)
	#undef EMIT_PRAGMA_DIRECTIVE

	#define EMIT_PRAGMA_DIRECTIVE "#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
	CLAMP_KERNEL( double )
	CLAMP_KERNEL_V( double, 2 )
	CLAMP_KERNEL_V( double, 4 )
	CLAMP_KERNEL_V( double, 8 )
	CLAMP_KERNEL_V( double, 16 )
	CLAMP_KERNEL_V3( double, 3 )
	#undef EMIT_PRAGMA_DIRECTIVE

	const char *clamp_float_codes[] = { clamp_float_kernel_code, clamp_float2_kernel_code, clamp_float4_kernel_code, clamp_float8_kernel_code, clamp_float16_kernel_code, clamp_float3_kernel_code };
	const char *clamp_double_codes[] = { clamp_double_kernel_code, clamp_double2_kernel_code, clamp_double4_kernel_code, clamp_double8_kernel_code, clamp_double16_kernel_code, clamp_double3_kernel_code };

	static int verify_clamp(float x, float minval, float maxval, float outptr, int n)
	{
	float t;
	int i;

	for (i=0; i<n; i++)
	{
	t = fminf( fmaxf( x[ i ], minval[ i ] ), maxval[ i ] );
	if (t != outptr[i])
	{
	log_error( "%d) verification error: clamp( %a, %a, %a) = *%a vs. %a\n", i, x[i], minval[i], maxval[i], t, outptr[i] );
	return -1;
	}
	}

	return 0;
	}

	static int verify_clamp_double(double x, double minval, double maxval, double outptr, int n)
	{
	double t;
	int i;

	for (i=0; i<n; i++)
	{
	t = fmin( fmax( x[ i ], minval[ i ] ), maxval[ i ] );
	if (t != outptr[i])
	{
	log_error( "%d) verification error: clamp( %a, %a, %a) = *%a vs. %a\n", i, x[i], minval[i], maxval[i], t, outptr[i] );
	return -1;
	}
	}

	return 0;
	}

	int
	test_clamp(cl_device_id device, cl_context context, cl_command_queue queue, int n_elems)
	{
	cl_mem streams[8];
	cl_float input_ptr[3], output_ptr;
	cl_double input_ptr_double[3], output_ptr_double = NULL;
	cl_program *program;
	cl_kernel *kernel;
	size_t threads[1];
	int num_elements;
	int err;
	int i, j;
	MTdata d;

	program = (cl_program)malloc(sizeof(cl_program)kTotalVecCount*2);
	kernel = (cl_kernel)malloc(sizeof(cl_kernel)kTotalVecCount*2);

	num_elements = n_elems * (1 << (kVectorSizeCount-1));

	int test_double = 0;
	if(is_extension_available( device, "cl_khr_fp64" )) {
	log_info("Testing doubles.\n");
	test_double = 1;
	}


	// why does this go from 0 to 2?? -- Oh, I see, there are four function
	// arguments to the function, and 3 of them are inputs?
	for( i = 0; i < 3; i++ )
	{
	input_ptr[i] = (cl_float)malloc(sizeof(cl_float) num_elements);
	if (test_double) input_ptr_double[i] = (cl_double)malloc(sizeof(cl_double) num_elements);
	}
	output_ptr = (cl_float)malloc(sizeof(cl_float) num_elements);
	if (test_double) output_ptr_double = (cl_double)malloc(sizeof(cl_double) num_elements);

	// why does this go from 0 to 3?
	for( i = 0; i < 4; i++ )
	{
	streams[i] =
	clCreateBuffer(context, CL_MEM_READ_WRITE,
	sizeof(cl_float) * num_elements, NULL, NULL);
	if (!streams[0])
	{
	log_error("clCreateBuffer failed\n");
	return -1;
	}
	}
	if (test_double)
	for( i = 4; i < 8; i++ )
	{
	streams[i] =
	clCreateBuffer(context, CL_MEM_READ_WRITE,
	sizeof(cl_double) * num_elements, NULL, NULL);
	if (!streams[0])
	{
	log_error("clCreateBuffer failed\n");
	return -1;
	}
	}

	d = init_genrand( gRandomSeed );
	for( j = 0; j < num_elements; j++ )
	{
	input_ptr[0][j] = get_random_float(-0x20000000, 0x20000000, d);
	input_ptr[1][j] = get_random_float(-0x20000000, 0x20000000, d);
	input_ptr[2][j] = get_random_float(input_ptr[1][j], 0x20000000, d);

	if (test_double) {
	input_ptr_double[0][j] = get_random_double(-0x20000000, 0x20000000, d);
	input_ptr_double[1][j] = get_random_double(-0x20000000, 0x20000000, d);
	input_ptr_double[2][j] = get_random_double(input_ptr_double[1][j], 0x20000000, d);
	}
	}
	free_mtdata(d); d = NULL;

	for( i = 0; i < 3; i++ )
	{
	err = clEnqueueWriteBuffer( queue, streams[ i ], CL_TRUE, 0, sizeof( cl_float ) * num_elements, input_ptr[ i ], 0, NULL, NULL );
	test_error( err, "Unable to write input buffer" );

	if (test_double) {
	err = clEnqueueWriteBuffer( queue, streams[ 4 + i ], CL_TRUE, 0, sizeof( cl_double ) * num_elements, input_ptr_double[ i ], 0, NULL, NULL );
	test_error( err, "Unable to write input buffer" );
	}
	}

	for( i = 0; i < kTotalVecCount; i++ )
	{
	err = create_single_kernel_helper( context, &program[ i ], &kernel[ i ], 1, &clamp_float_codes[ i ], "test_clamp" );
	test_error( err, "Unable to create kernel" );

	log_info("Just made a program for float, i=%d, size=%d, in slot %d\n", i, g_arrVecSizes[i], i);
	fflush(stdout);

	if (test_double) {
	err = create_single_kernel_helper( context, &program[ kTotalVecCount + i ], &kernel[ kTotalVecCount + i ], 1, &clamp_double_codes[ i ], "test_clamp" );
	log_info("Just made a program for double, i=%d, size=%d, in slot %d\n", i, g_arrVecSizes[i], kTotalVecCount+i);
	fflush(stdout);
	test_error( err, "Unable to create kernel" );
	}
	}

	for( i = 0; i < kTotalVecCount; i++ )
	{
	for( j = 0; j < 4; j++ )
	{
	err = clSetKernelArg( kernel[ i ], j, sizeof( streams[ j ] ), &streams[ j ] );
	test_error( err, "Unable to set kernel argument" );
	}

	threads[0] = (size_t)n_elems;

	err = clEnqueueNDRangeKernel( queue, kernel[i], 1, NULL, threads, NULL, 0, NULL, NULL );
	test_error( err, "Unable to execute kernel" );

	err = clEnqueueReadBuffer( queue, streams[3], true, 0, sizeof(cl_float)num_elements, (void )output_ptr, 0, NULL, NULL );
	test_error( err, "Unable to read results" );

	if (verify_clamp(input_ptr[0], input_ptr[1], input_ptr[2], output_ptr, n_elems*((g_arrVecSizes[i]))))
	{
	log_error("CLAMP float%d test failed\n", ((g_arrVecSizes[i])));
	err = -1;
	}
	else
	{
	log_info("CLAMP float%d test passed\n", ((g_arrVecSizes[i])));
	err = 0;
	}



	if (err)
	break;
	}

	// If the device supports double precision then test that
	if (test_double)
	{
	for( ; i < 2*kTotalVecCount; i++ )
	{

	log_info("Start of test_double loop, i is %d\n", i);
	for( j = 0; j < 4; j++ )
	{
	err = clSetKernelArg( kernel[i], j, sizeof( streams[j+4] ), &streams[j+4] );
	test_error( err, "Unable to set kernel argument" );
	}

	threads[0] = (size_t)n_elems;

	err = clEnqueueNDRangeKernel( queue, kernel[i], 1, NULL, threads, NULL, 0, NULL, NULL );
	test_error( err, "Unable to execute kernel" );

	err = clEnqueueReadBuffer( queue, streams[7], CL_TRUE, 0, sizeof(cl_double)num_elements, (void )output_ptr_double, 0, NULL, NULL );
	test_error( err, "Unable to read results" );

	if (verify_clamp_double(input_ptr_double[0], input_ptr_double[1], input_ptr_double[2], output_ptr_double, n_elems*g_arrVecSizes[(i-kTotalVecCount)]))
	{
	log_error("CLAMP double%d test failed\n", g_arrVecSizes[(i-kTotalVecCount)]);
	err = -1;
	}
	else
	{
	log_info("CLAMP double%d test passed\n", g_arrVecSizes[(i-kTotalVecCount)]);
	err = 0;
	}

	if (err)
	break;
	}
	}


	for( i = 0; i < ((test_double) ? 8 : 4); i++ )
	{
	clReleaseMemObject(streams[i]);
	}
	for (i=0; i < ((test_double) ? kTotalVecCount * 2-1 : kTotalVecCount); i++)
	{
	clReleaseKernel(kernel[i]);
	clReleaseProgram(program[i]);
	}
	free(input_ptr[0]);
	free(input_ptr[1]);
	free(input_ptr[2]);
	free(output_ptr);
	free(program);
	free(kernel);
	if (test_double) {
	free(input_ptr_double[0]);
	free(input_ptr_double[1]);
	free(input_ptr_double[2]);
	free(output_ptr_double);
	}

	return err;
	}