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rk35xx-android12/external/OpenCL-CTS/test_conformance/half/Test_vStoreHalf.cpp

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//
// 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 "harness/kernelHelpers.h"
#include "harness/testHarness.h"
#include <string.h>
#include "cl_utils.h"
#include "tests.h"
#include <CL/cl_half.h>
typedef struct ComputeReferenceInfoF_
{
float *x;
cl_ushort *r;
f2h f;
cl_ulong i;
cl_uint lim;
cl_uint count;
} ComputeReferenceInfoF;
typedef struct ComputeReferenceInfoD_
{
double *x;
cl_ushort *r;
d2h f;
cl_ulong i;
cl_uint lim;
cl_uint count;
} ComputeReferenceInfoD;
typedef struct CheckResultInfoF_
{
const float *x;
const cl_ushort *r;
const cl_ushort *s;
f2h f;
const char *aspace;
cl_uint lim;
cl_uint count;
int vsz;
} CheckResultInfoF;
typedef struct CheckResultInfoD_
{
const double *x;
const cl_ushort *r;
const cl_ushort *s;
d2h f;
const char *aspace;
cl_uint lim;
cl_uint count;
int vsz;
} CheckResultInfoD;
static cl_int
ReferenceF(cl_uint jid, cl_uint tid, void *userInfo)
{
ComputeReferenceInfoF *cri = (ComputeReferenceInfoF *)userInfo;
cl_uint lim = cri->lim;
cl_uint count = cri->count;
cl_uint off = jid * count;
float *x = cri->x + off;
cl_ushort *r = cri->r + off;
f2h f = cri->f;
cl_ulong i = cri->i + off;
cl_uint j, rr;
if (off + count > lim)
count = lim - off;
for (j = 0; j < count; ++j) {
x[j] = as_float((cl_uint)(i + j));
r[j] = f(x[j]);
}
return 0;
}
static cl_int
CheckF(cl_uint jid, cl_uint tid, void *userInfo)
{
CheckResultInfoF *cri = (CheckResultInfoF *)userInfo;
cl_uint lim = cri->lim;
cl_uint count = cri->count;
cl_uint off = jid * count;
const float *x = cri->x + off;
const cl_ushort *r = cri->r + off;
const cl_ushort *s = cri->s + off;
f2h f = cri->f;
cl_uint j;
cl_ushort correct2 = f( 0.0f);
cl_ushort correct3 = f(-0.0f);
cl_int ret = 0;
if (off + count > lim)
count = lim - off;
if (!memcmp(r, s, count*sizeof(cl_ushort)))
return 0;
for (j = 0; j < count; j++) {
if (s[j] == r[j])
continue;
// Pass any NaNs
if ((s[j] & 0x7fff) > 0x7c00 && (r[j] & 0x7fff) > 0x7c00 )
continue;
// retry per section 6.5.3.3
if (IsFloatSubnormal(x[j]) && (s[j] == correct2 || s[j] == correct3))
continue;
// if reference result is subnormal, pass any zero
if (gIsEmbedded && IsHalfSubnormal(r[j]) && (s[j] == 0x0000 || s[j] == 0x8000))
continue;
vlog_error("\nFailure at [%u] with %.6a: *0x%04x vs 0x%04x, vector_size = %d, address_space = %s\n",
j+off, x[j], r[j], s[j], cri->vsz, cri->aspace);
ret = 1;
break;
}
return ret;
}
static cl_int
ReferenceD(cl_uint jid, cl_uint tid, void *userInfo)
{
ComputeReferenceInfoD *cri = (ComputeReferenceInfoD *)userInfo;
cl_uint lim = cri->lim;
cl_uint count = cri->count;
cl_uint off = jid * count;
double *x = cri->x + off;
cl_ushort *r = cri->r + off;
d2h f = cri->f;
cl_uint j;
cl_ulong i = cri->i + off;
if (off + count > lim)
count = lim - off;
for (j = 0; j < count; ++j) {
x[j] = as_double(DoubleFromUInt((cl_uint)(i + j)));
r[j] = f(x[j]);
}
return 0;
}
static cl_int
CheckD(cl_uint jid, cl_uint tid, void *userInfo)
{
CheckResultInfoD *cri = (CheckResultInfoD *)userInfo;
cl_uint lim = cri->lim;
cl_uint count = cri->count;
cl_uint off = jid * count;
const double *x = cri->x + off;
const cl_ushort *r = cri->r + off;
const cl_ushort *s = cri->s + off;
d2h f = cri->f;
cl_uint j;
cl_ushort correct2 = f( 0.0);
cl_ushort correct3 = f(-0.0);
cl_int ret = 0;
if (off + count > lim)
count = lim - off;
if (!memcmp(r, s, count*sizeof(cl_ushort)))
return 0;
for (j = 0; j < count; j++) {
if (s[j] == r[j])
continue;
// Pass any NaNs
if ((s[j] & 0x7fff) > 0x7c00 && (r[j] & 0x7fff) > 0x7c00)
continue;
if (IsDoubleSubnormal(x[j]) && (s[j] == correct2 || s[j] == correct3))
continue;
// if reference result is subnormal, pass any zero result
if (gIsEmbedded && IsHalfSubnormal(r[j]) && (s[j] == 0x0000 || s[j] == 0x8000))
continue;
vlog_error("\nFailure at [%u] with %.13la: *0x%04x vs 0x%04x, vector_size = %d, address space = %s (double precision)\n",
j+off, x[j], r[j], s[j], cri->vsz, cri->aspace);
ret = 1;
break;
}
return ret;
}
static cl_half float2half_rte(float f)
{
return cl_half_from_float(f, CL_HALF_RTE);
}
static cl_half float2half_rtz(float f)
{
return cl_half_from_float(f, CL_HALF_RTZ);
}
static cl_half float2half_rtp(float f)
{
return cl_half_from_float(f, CL_HALF_RTP);
}
static cl_half float2half_rtn(float f)
{
return cl_half_from_float(f, CL_HALF_RTN);
}
static cl_half double2half_rte(double f)
{
return cl_half_from_double(f, CL_HALF_RTE);
}
static cl_half double2half_rtz(double f)
{
return cl_half_from_double(f, CL_HALF_RTZ);
}
static cl_half double2half_rtp(double f)
{
return cl_half_from_double(f, CL_HALF_RTP);
}
static cl_half double2half_rtn(double f)
{
return cl_half_from_double(f, CL_HALF_RTN);
}
int test_vstore_half( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
switch (get_default_rounding_mode(deviceID))
{
case CL_FP_ROUND_TO_ZERO:
return Test_vStoreHalf_private(deviceID, float2half_rtz, double2half_rte, "");
case 0:
return -1;
default:
return Test_vStoreHalf_private(deviceID, float2half_rte, double2half_rte, "");
}
}
int test_vstore_half_rte( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreHalf_private(deviceID, float2half_rte, double2half_rte, "_rte");
}
int test_vstore_half_rtz( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreHalf_private(deviceID, float2half_rtz, double2half_rtz, "_rtz");
}
int test_vstore_half_rtp( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreHalf_private(deviceID, float2half_rtp, double2half_rtp, "_rtp");
}
int test_vstore_half_rtn( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreHalf_private(deviceID, float2half_rtn, double2half_rtn, "_rtn");
}
int test_vstorea_half( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
switch (get_default_rounding_mode(deviceID))
{
case CL_FP_ROUND_TO_ZERO:
return Test_vStoreaHalf_private(deviceID,float2half_rtz, double2half_rte, "");
case 0:
return -1;
default:
return Test_vStoreaHalf_private(deviceID, float2half_rte, double2half_rte, "");
}
}
int test_vstorea_half_rte( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreaHalf_private(deviceID, float2half_rte, double2half_rte, "_rte");
}
int test_vstorea_half_rtz( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreaHalf_private(deviceID, float2half_rtz, double2half_rtz, "_rtz");
}
int test_vstorea_half_rtp( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreaHalf_private(deviceID, float2half_rtp, double2half_rtp, "_rtp");
}
int test_vstorea_half_rtn( cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements )
{
return Test_vStoreaHalf_private(deviceID, float2half_rtn, double2half_rtn, "_rtn");
}
#pragma mark -
int Test_vStoreHalf_private( cl_device_id device, f2h referenceFunc, d2h doubleReferenceFunc, const char *roundName )
{
int vectorSize, error;
cl_program programs[kVectorSizeCount+kStrangeVectorSizeCount][3];
cl_kernel kernels[kVectorSizeCount+kStrangeVectorSizeCount][3];
uint64_t time[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
uint64_t min_time[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
memset( min_time, -1, sizeof( min_time ) );
cl_program doublePrograms[kVectorSizeCount+kStrangeVectorSizeCount][3];
cl_kernel doubleKernels[kVectorSizeCount+kStrangeVectorSizeCount][3];
uint64_t doubleTime[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
uint64_t min_double_time[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
memset( min_double_time, -1, sizeof( min_double_time ) );
bool aligned= false;
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
{
const char *source[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" size_t i = get_global_id(0);\n"
" vstore_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], i, f );\n"
"}\n"
};
const char *source_v3[] = {
"__kernel void test( __global float *p, __global half *f,\n"
" uint extra_last_thread)\n"
"{\n"
" size_t i = get_global_id(0);\n"
" size_t last_i = get_global_size(0)-1;\n"
" size_t adjust = 0;\n"
" if(last_i == i && extra_last_thread != 0) {\n"
" adjust = 3-extra_last_thread;\n"
" } "
" vstore_half3",roundName,"( vload3(i, p-adjust), i, f-adjust );\n"
"}\n"
};
const char *source_private_store[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __private ushort data[16];\n"
" size_t i = get_global_id(0);\n"
" size_t offset = 0;\n"
" size_t vecsize = vec_step(p[i]);\n"
" vstore_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], 0, (__private half *)(&data[0]) );\n"
" for(offset = 0; offset < vecsize; offset++)\n"
" {\n"
" vstore_half(vload_half(offset, (__private half *)data), 0, &f[vecsize*i+offset]);\n"
" }\n"
"}\n"
};
const char *source_private_store_v3[] = {
"__kernel void test( __global float *p, __global half *f,\n"
" uint extra_last_thread )\n"
"{\n"
" __private ushort data[4];\n"
" size_t i = get_global_id(0);\n"
" size_t last_i = get_global_size(0)-1;\n"
" size_t adjust = 0;\n"
" size_t offset = 0;\n"
" if(last_i == i && extra_last_thread != 0) {\n"
" adjust = 3-extra_last_thread;\n"
" } "
" vstore_half3",roundName,"( vload3(i, p-adjust), 0, (__private half *)(&data[0]) );\n"
" for(offset = 0; offset < 3; offset++)\n"
" {\n"
" vstore_half(vload_half(offset, (__private half *) data), 0, &f[3*i+offset-adjust]);\n"
" }\n"
"}\n"
};
char local_buf_size[10];
sprintf(local_buf_size, "%lld", (uint64_t)gWorkGroupSize);
const char *source_local_store[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __local ushort data[16*", local_buf_size, "];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" size_t lsize = get_local_size(0);\n"
" size_t vecsize = vec_step(p[0]);\n"
" event_t async_event;\n"
" vstore_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], lid, (__local half *)(&data[0]) );\n"
" barrier( CLK_LOCAL_MEM_FENCE ); \n"
" async_event = async_work_group_copy((__global ushort *)f+vecsize*(i-lid), (__local ushort *)(&data[0]), vecsize*lsize, 0);\n" // investigate later
" wait_group_events(1, &async_event);\n"
"}\n"
};
const char *source_local_store_v3[] = {
"__kernel void test( __global float *p, __global half *f,\n"
" uint extra_last_thread )\n"
"{\n"
" __local ushort data[3*(", local_buf_size, "+1)];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" size_t last_i = get_global_size(0)-1;\n"
" size_t adjust = 0;\n"
" size_t lsize = get_local_size(0);\n"
" event_t async_event;\n"
" if(last_i == i && extra_last_thread != 0) {\n"
" adjust = 3-extra_last_thread;\n"
" } "
" vstore_half3",roundName,"( vload3(i,p-adjust), lid, (__local half *)(&data[0]) );\n"
" barrier( CLK_LOCAL_MEM_FENCE ); \n"
" async_event = async_work_group_copy((__global ushort *)(f+3*(i-lid)), (__local ushort *)(&data[adjust]), lsize*3-adjust, 0);\n" // investigate later
" wait_group_events(1, &async_event);\n"
"}\n"
};
const char *double_source[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" size_t i = get_global_id(0);\n"
" vstore_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], i, f );\n"
"}\n"
};
const char *double_source_private_store[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __private ushort data[16];\n"
" size_t i = get_global_id(0);\n"
" size_t offset = 0;\n"
" size_t vecsize = vec_step(p[i]);\n"
" vstore_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], 0, (__private half *)(&data[0]) );\n"
" for(offset = 0; offset < vecsize; offset++)\n"
" {\n"
" vstore_half(vload_half(offset, (__private half *)data), 0, &f[vecsize*i+offset]);\n"
" }\n"
"}\n"
};
const char *double_source_local_store[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __local ushort data[16*", local_buf_size, "];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" size_t vecsize = vec_step(p[0]);\n"
" size_t lsize = get_local_size(0);\n"
" event_t async_event;\n"
" vstore_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], lid, (__local half *)(&data[0]) );\n"
" barrier( CLK_LOCAL_MEM_FENCE ); \n"
" async_event = async_work_group_copy((__global ushort *)(f+vecsize*(i-lid)), (__local ushort *)(&data[0]), vecsize*lsize, 0);\n" // investigate later
" wait_group_events(1, &async_event);\n"
"}\n"
};
const char *double_source_v3[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double *p, __global half *f ,\n"
" uint extra_last_thread)\n"
"{\n"
" size_t i = get_global_id(0);\n"
" size_t last_i = get_global_size(0)-1;\n"
" size_t adjust = 0;\n"
" if(last_i == i && extra_last_thread != 0) {\n"
" adjust = 3-extra_last_thread;\n"
" } "
" vstore_half3",roundName,"( vload3(i,p-adjust), i, f -adjust);\n"
"}\n"
};
const char *double_source_private_store_v3[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double *p, __global half *f,\n"
" uint extra_last_thread )\n"
"{\n"
" __private ushort data[4];\n"
" size_t i = get_global_id(0);\n"
" size_t last_i = get_global_size(0)-1;\n"
" size_t adjust = 0;\n"
" size_t offset = 0;\n"
" if(last_i == i && extra_last_thread != 0) {\n"
" adjust = 3-extra_last_thread;\n"
" } "
" vstore_half3",roundName,"( vload3(i, p-adjust), 0, (__private half *)(&data[0]) );\n"
" for(offset = 0; offset < 3; offset++)\n"
" {\n"
" vstore_half(vload_half(offset, (__private half *)data), 0, &f[3*i+offset-adjust]);\n"
" }\n"
"}\n"
};
const char *double_source_local_store_v3[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double *p, __global half *f,\n"
" uint extra_last_thread )\n"
"{\n"
" __local ushort data[3*(", local_buf_size, "+1)];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" size_t last_i = get_global_size(0)-1;\n"
" size_t adjust = 0;\n"
" size_t lsize = get_local_size(0);\n"
" event_t async_event;\n"
" if(last_i == i && extra_last_thread != 0) {\n"
" adjust = 3-extra_last_thread;\n"
" }\n "
" vstore_half3",roundName,"( vload3(i,p-adjust), lid, (__local half *)(&data[0]) );\n"
" barrier( CLK_LOCAL_MEM_FENCE ); \n"
" async_event = async_work_group_copy((__global ushort *)(f+3*(i-lid)), (__local ushort *)(&data[adjust]), lsize*3-adjust, 0);\n" // investigate later
" wait_group_events(1, &async_event);\n"
"}\n"
};
if(g_arrVecSizes[vectorSize] == 3) {
programs[vectorSize][0] = MakeProgram( device, source_v3, sizeof(source_v3) / sizeof( source_v3[0]) );
} else {
programs[vectorSize][0] = MakeProgram( device, source, sizeof(source) / sizeof( source[0]) );
}
if( NULL == programs[ vectorSize ][0] )
{
gFailCount++;
return -1;
}
kernels[ vectorSize ][0] = clCreateKernel( programs[ vectorSize ][0], "test", &error );
if( NULL == kernels[vectorSize][0] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
programs[vectorSize][1] = MakeProgram( device, source_private_store_v3, sizeof(source_private_store_v3) / sizeof( source_private_store_v3[0]) );
} else {
programs[vectorSize][1] = MakeProgram( device, source_private_store, sizeof(source_private_store) / sizeof( source_private_store[0]) );
}
if( NULL == programs[ vectorSize ][1] )
{
gFailCount++;
return -1;
}
kernels[ vectorSize ][1] = clCreateKernel( programs[ vectorSize ][1], "test", &error );
if( NULL == kernels[vectorSize][1] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create private kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
programs[vectorSize][2] = MakeProgram( device, source_local_store_v3, sizeof(source_local_store_v3) / sizeof( source_local_store_v3[0]) );
if( NULL == programs[ vectorSize ][2] )
{
unsigned q;
for ( q= 0; q < sizeof( source_local_store_v3) / sizeof( source_local_store_v3[0]); q++)
vlog_error("%s", source_local_store_v3[q]);
gFailCount++;
return -1;
}
} else {
programs[vectorSize][2] = MakeProgram( device, source_local_store, sizeof(source_local_store) / sizeof( source_local_store[0]) );
if( NULL == programs[ vectorSize ][2] )
{
unsigned q;
for ( q= 0; q < sizeof( source_local_store) / sizeof( source_local_store[0]); q++)
vlog_error("%s", source_local_store[q]);
gFailCount++;
return -1;
}
}
kernels[ vectorSize ][2] = clCreateKernel( programs[ vectorSize ][2], "test", &error );
if( NULL == kernels[vectorSize][2] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create local kernel. (%d)\n", error );
return error;
}
if( gTestDouble )
{
if(g_arrVecSizes[vectorSize] == 3) {
doublePrograms[vectorSize][0] = MakeProgram( device, double_source_v3, sizeof(double_source_v3) / sizeof( double_source_v3[0]) );
} else {
doublePrograms[vectorSize][0] = MakeProgram( device, double_source, sizeof(double_source) / sizeof( double_source[0]) );
}
if( NULL == doublePrograms[ vectorSize ][0] )
{
gFailCount++;
return -1;
}
doubleKernels[ vectorSize ][0] = clCreateKernel( doublePrograms[ vectorSize ][0], "test", &error );
if( NULL == kernels[vectorSize][0] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create double kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3)
doublePrograms[vectorSize][1] = MakeProgram( device, double_source_private_store_v3, sizeof(double_source_private_store_v3) / sizeof( double_source_private_store_v3[0]) );
else
doublePrograms[vectorSize][1] = MakeProgram( device, double_source_private_store, sizeof(double_source_private_store) / sizeof( double_source_private_store[0]) );
if( NULL == doublePrograms[ vectorSize ][1] )
{
gFailCount++;
return -1;
}
doubleKernels[ vectorSize ][1] = clCreateKernel( doublePrograms[ vectorSize ][1], "test", &error );
if( NULL == kernels[vectorSize][1] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create double private kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
doublePrograms[vectorSize][2] = MakeProgram( device, double_source_local_store_v3, sizeof(double_source_local_store_v3) / sizeof( double_source_local_store_v3[0]) );
} else {
doublePrograms[vectorSize][2] = MakeProgram( device, double_source_local_store, sizeof(double_source_local_store) / sizeof( double_source_local_store[0]) );
}
if( NULL == doublePrograms[ vectorSize ][2] )
{
gFailCount++;
return -1;
}
doubleKernels[ vectorSize ][2] = clCreateKernel( doublePrograms[ vectorSize ][2], "test", &error );
if( NULL == kernels[vectorSize][2] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create double local kernel. (%d)\n", error );
return error;
}
}
} // end for vector size
// Figure out how many elements are in a work block
size_t elementSize = MAX( sizeof(cl_ushort), sizeof(float));
size_t blockCount = BUFFER_SIZE / elementSize; // elementSize is power of 2
uint64_t lastCase = 1ULL << (8*sizeof(float)); // number of floats.
size_t stride = blockCount;
if (gWimpyMode)
stride = (uint64_t)blockCount * (uint64_t)gWimpyReductionFactor;
// we handle 64-bit types a bit differently.
if( lastCase == 0 )
lastCase = 0x100000000ULL;
uint64_t i, j;
error = 0;
uint64_t printMask = (lastCase >> 4) - 1;
cl_uint count = 0;
int addressSpace;
size_t loopCount;
cl_uint threadCount = GetThreadCount();
ComputeReferenceInfoF fref;
fref.x = (float *)gIn_single;
fref.r = (cl_half *)gOut_half_reference;
fref.f = referenceFunc;
fref.lim = blockCount;
fref.count = (blockCount + threadCount - 1) / threadCount;
CheckResultInfoF fchk;
fchk.x = (const float *)gIn_single;
fchk.r = (const cl_half *)gOut_half_reference;
fchk.s = (const cl_half *)gOut_half;
fchk.f = referenceFunc;
fchk.lim = blockCount;
fchk.count = (blockCount + threadCount - 1) / threadCount;
ComputeReferenceInfoD dref;
dref.x = (double *)gIn_double;
dref.r = (cl_half *)gOut_half_reference_double;
dref.f = doubleReferenceFunc;
dref.lim = blockCount;
dref.count = (blockCount + threadCount - 1) / threadCount;
CheckResultInfoD dchk;
dchk.x = (const double *)gIn_double;
dchk.r = (const cl_half *)gOut_half_reference_double;
dchk.s = (const cl_half *)gOut_half;
dchk.f = doubleReferenceFunc;
dchk.lim = blockCount;
dchk.count = (blockCount + threadCount - 1) / threadCount;
for( i = 0; i < lastCase; i += stride )
{
count = (cl_uint) MIN( blockCount, lastCase - i );
fref.i = i;
dref.i = i;
// Compute the input and reference
ThreadPool_Do(ReferenceF, threadCount, &fref);
error = clEnqueueWriteBuffer(gQueue, gInBuffer_single, CL_FALSE, 0, count * sizeof(float ), gIn_single, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteBuffer\n" );
gFailCount++;
goto exit;
}
if (gTestDouble) {
ThreadPool_Do(ReferenceD, threadCount, &dref);
error = clEnqueueWriteBuffer(gQueue, gInBuffer_double, CL_FALSE, 0, count * sizeof(double ), gIn_double, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteBuffer\n" );
gFailCount++;
goto exit;
}
}
for (vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++) {
// Loop through vector sizes
fchk.vsz = g_arrVecSizes[vectorSize];
dchk.vsz = g_arrVecSizes[vectorSize];
for ( addressSpace = 0; addressSpace < 3; addressSpace++) {
// Loop over address spaces
fchk.aspace = addressSpaceNames[addressSpace];
dchk.aspace = addressSpaceNames[addressSpace];
cl_uint pattern = 0xdeaddead;
memset_pattern4( gOut_half, &pattern, BUFFER_SIZE/2);
error = clEnqueueWriteBuffer(gQueue, gOutBuffer_half, CL_FALSE,
0, count * sizeof(cl_half),
gOut_half, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
error = RunKernel(device, kernels[vectorSize][addressSpace], gInBuffer_single, gOutBuffer_half,
numVecs(count, vectorSize, aligned) ,
runsOverBy(count, vectorSize, aligned));
if (error) {
gFailCount++;
goto exit;
}
error = clEnqueueReadBuffer(gQueue, gOutBuffer_half, CL_TRUE, 0,
count * sizeof(cl_half), gOut_half,
0, NULL, NULL);
if (error) {
vlog_error( "Failure in clReadArray\n" );
gFailCount++;
goto exit;
}
error = ThreadPool_Do(CheckF, threadCount, &fchk);
if (error) {
gFailCount++;
goto exit;
}
if (gTestDouble) {
memset_pattern4( gOut_half, &pattern, BUFFER_SIZE/2);
error = clEnqueueWriteBuffer(
gQueue, gOutBuffer_half, CL_FALSE, 0,
count * sizeof(cl_half), gOut_half, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
error = RunKernel(device, doubleKernels[vectorSize][addressSpace], gInBuffer_double, gOutBuffer_half,
numVecs(count, vectorSize, aligned),
runsOverBy(count, vectorSize, aligned));
if (error) {
gFailCount++;
goto exit;
}
error = clEnqueueReadBuffer(
gQueue, gOutBuffer_half, CL_TRUE, 0,
count * sizeof(cl_half), gOut_half, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clReadArray\n" );
gFailCount++;
goto exit;
}
error = ThreadPool_Do(CheckD, threadCount, &dchk);
if (error) {
gFailCount++;
goto exit;
}
}
}
}
if( ((i+blockCount) & ~printMask) == (i+blockCount) )
{
vlog( "." );
fflush( stdout );
}
} // end last case
loopCount = count == blockCount ? 1 : 100;
if( gReportTimes )
{
//Init the input stream
cl_float *p = (cl_float *)gIn_single;
for( j = 0; j < count; j++ )
p[j] = (float)((double) (rand() - RAND_MAX/2) / (RAND_MAX/2));
if( (error = clEnqueueWriteBuffer(gQueue, gInBuffer_single, CL_TRUE, 0, count * sizeof( float ), gIn_single, 0, NULL, NULL)) )
{
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
if( gTestDouble )
{
//Init the input stream
cl_double *q = (cl_double *)gIn_double;
for( j = 0; j < count; j++ )
q[j] = ((double) (rand() - RAND_MAX/2) / (RAND_MAX/2));
if( (error = clEnqueueWriteBuffer(gQueue, gInBuffer_double, CL_TRUE, 0, count * sizeof( double ), gIn_double, 0, NULL, NULL)) )
{
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
}
//Run again for timing
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
{
uint64_t bestTime = -1ULL;
for( j = 0; j < loopCount; j++ )
{
uint64_t startTime = ReadTime();
if( (error = RunKernel(device, kernels[vectorSize][0], gInBuffer_single, gOutBuffer_half, numVecs(count, vectorSize, aligned) ,
runsOverBy(count, vectorSize, aligned)) ) )
{
gFailCount++;
goto exit;
}
if( (error = clFinish(gQueue)) )
{
vlog_error( "Failure in clFinish\n" );
gFailCount++;
goto exit;
}
uint64_t currentTime = ReadTime() - startTime;
if( currentTime < bestTime )
bestTime = currentTime;
time[ vectorSize ] += currentTime;
}
if( bestTime < min_time[ vectorSize ] )
min_time[ vectorSize ] = bestTime ;
if( gTestDouble )
{
bestTime = -1ULL;
for( j = 0; j < loopCount; j++ )
{
uint64_t startTime = ReadTime();
if( (error = RunKernel(device, doubleKernels[vectorSize][0], gInBuffer_double, gOutBuffer_half, numVecs(count, vectorSize, aligned) ,
runsOverBy(count, vectorSize, aligned)) ) )
{
gFailCount++;
goto exit;
}
if( (error = clFinish(gQueue)) )
{
vlog_error( "Failure in clFinish\n" );
gFailCount++;
goto exit;
}
uint64_t currentTime = ReadTime() - startTime;
if( currentTime < bestTime )
bestTime = currentTime;
doubleTime[ vectorSize ] += currentTime;
}
if( bestTime < min_double_time[ vectorSize ] )
min_double_time[ vectorSize ] = bestTime;
}
}
}
if( gReportTimes )
{
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( time[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) (count * loopCount), 0,
"average us/elem", "vStoreHalf%s avg. (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( min_time[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) count, 0,
"best us/elem", "vStoreHalf%s best (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
if( gTestDouble )
{
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( doubleTime[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) (count * loopCount), 0,
"average us/elem (double)", "vStoreHalf%s avg. d (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( min_double_time[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) count, 0,
"best us/elem (double)", "vStoreHalf%s best d (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
}
}
exit:
//clean up
for( vectorSize = kMinVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
{
for ( addressSpace = 0; addressSpace < 3; addressSpace++) {
clReleaseKernel( kernels[ vectorSize ][ addressSpace ] );
clReleaseProgram( programs[ vectorSize ][ addressSpace ] );
if( gTestDouble )
{
clReleaseKernel( doubleKernels[ vectorSize ][addressSpace] );
clReleaseProgram( doublePrograms[ vectorSize ][addressSpace] );
}
}
}
return error;
}
int Test_vStoreaHalf_private( cl_device_id device, f2h referenceFunc, d2h doubleReferenceFunc, const char *roundName )
{
int vectorSize, error;
cl_program programs[kVectorSizeCount+kStrangeVectorSizeCount][3];
cl_kernel kernels[kVectorSizeCount+kStrangeVectorSizeCount][3];
uint64_t time[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
uint64_t min_time[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
memset( min_time, -1, sizeof( min_time ) );
cl_program doublePrograms[kVectorSizeCount+kStrangeVectorSizeCount][3];
cl_kernel doubleKernels[kVectorSizeCount+kStrangeVectorSizeCount][3];
uint64_t doubleTime[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
uint64_t min_double_time[kVectorSizeCount+kStrangeVectorSizeCount] = {0};
memset( min_double_time, -1, sizeof( min_double_time ) );
bool aligned = true;
int minVectorSize = kMinVectorSize;
// There is no aligned scalar vstorea_half
if( 0 == minVectorSize )
minVectorSize = 1;
//Loop over vector sizes
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
{
const char *source[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" size_t i = get_global_id(0);\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], i, f );\n"
"}\n"
};
const char *source_v3[] = {
"__kernel void test( __global float3 *p, __global half *f )\n"
"{\n"
" size_t i = get_global_id(0);\n"
" vstorea_half3",roundName,"( p[i], i, f );\n"
" vstore_half",roundName,"( ((__global float *)p)[4*i+3], 4*i+3, f);\n"
"}\n"
};
const char *source_private[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __private float", vector_size_name_extensions[vectorSize], " data;\n"
" size_t i = get_global_id(0);\n"
" data = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data, i, f );\n"
"}\n"
};
const char *source_private_v3[] = {
"__kernel void test( __global float3 *p, __global half *f )\n"
"{\n"
" __private float", vector_size_name_extensions[vectorSize], " data;\n"
" size_t i = get_global_id(0);\n"
" data = p[i];\n"
" vstorea_half3",roundName,"( data, i, f );\n"
" vstore_half",roundName,"( ((__global float *)p)[4*i+3], 4*i+3, f);\n"
"}\n"
};
char local_buf_size[10];
sprintf(local_buf_size, "%lld", (uint64_t)gWorkGroupSize);
const char *source_local[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __local float", vector_size_name_extensions[vectorSize], " data[", local_buf_size, "];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" data[lid] = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data[lid], i, f );\n"
"}\n"
};
const char *source_local_v3[] = {
"__kernel void test( __global float", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __local float", vector_size_name_extensions[vectorSize], " data[", local_buf_size, "];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" data[lid] = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data[lid], i, f );\n"
" vstore_half",roundName,"( ((__global float *)p)[4*i+3], 4*i+3, f);\n"
"}\n"
};
const char *double_source[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" size_t i = get_global_id(0);\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], i, f );\n"
"}\n"
};
const char *double_source_v3[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" size_t i = get_global_id(0);\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( p[i], i, f );\n"
" vstore_half",roundName,"( ((__global double *)p)[4*i+3], 4*i+3, f);\n"
"}\n"
};
const char *double_source_private[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __private double", vector_size_name_extensions[vectorSize], " data;\n"
" size_t i = get_global_id(0);\n"
" data = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data, i, f );\n"
"}\n"
};
const char *double_source_private_v3[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __private double", vector_size_name_extensions[vectorSize], " data;\n"
" size_t i = get_global_id(0);\n"
" data = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data, i, f );\n"
" vstore_half",roundName,"( ((__global double *)p)[4*i+3], 4*i+3, f);\n"
"}\n"
};
const char *double_source_local[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __local double", vector_size_name_extensions[vectorSize], " data[", local_buf_size, "];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" data[lid] = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data[lid], i, f );\n"
"}\n"
};
const char *double_source_local_v3[] = {
"#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n"
"__kernel void test( __global double", vector_size_name_extensions[vectorSize]," *p, __global half *f )\n"
"{\n"
" __local double", vector_size_name_extensions[vectorSize], " data[", local_buf_size, "];\n"
" size_t i = get_global_id(0);\n"
" size_t lid = get_local_id(0);\n"
" data[lid] = p[i];\n"
" vstorea_half",vector_size_name_extensions[vectorSize],roundName,"( data[lid], i, f );\n"
" vstore_half",roundName,"( ((__global double *)p)[4*i+3], 4*i+3, f);\n"
"}\n"
};
if(g_arrVecSizes[vectorSize] == 3) {
programs[vectorSize][0] = MakeProgram( device, source_v3, sizeof(source_v3) / sizeof( source_v3[0]) );
if( NULL == programs[ vectorSize ][0] )
{
gFailCount++;
return -1;
}
} else {
programs[vectorSize][0] = MakeProgram( device, source, sizeof(source) / sizeof( source[0]) );
if( NULL == programs[ vectorSize ][0] )
{
gFailCount++;
return -1;
}
}
kernels[ vectorSize ][0] = clCreateKernel( programs[ vectorSize ][0], "test", &error );
if( NULL == kernels[vectorSize][0] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
programs[vectorSize][1] = MakeProgram( device, source_private_v3, sizeof(source_private_v3) / sizeof( source_private_v3[0]) );
if( NULL == programs[ vectorSize ][1] )
{
gFailCount++;
return -1;
}
} else {
programs[vectorSize][1] = MakeProgram( device, source_private, sizeof(source_private) / sizeof( source_private[0]) );
if( NULL == programs[ vectorSize ][1] )
{
gFailCount++;
return -1;
}
}
kernels[ vectorSize ][1] = clCreateKernel( programs[ vectorSize ][1], "test", &error );
if( NULL == kernels[vectorSize][1] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create private kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
programs[vectorSize][2] = MakeProgram( device, source_local_v3, sizeof(source_local_v3) / sizeof( source_local_v3[0]) );
if( NULL == programs[ vectorSize ][2] )
{
gFailCount++;
return -1;
}
} else {
programs[vectorSize][2] = MakeProgram( device, source_local, sizeof(source_local) / sizeof( source_local[0]) );
if( NULL == programs[ vectorSize ][2] )
{
gFailCount++;
return -1;
}
}
kernels[ vectorSize ][2] = clCreateKernel( programs[ vectorSize ][2], "test", &error );
if( NULL == kernels[vectorSize][2] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create local kernel. (%d)\n", error );
return error;
}
if( gTestDouble )
{
if(g_arrVecSizes[vectorSize] == 3) {
doublePrograms[vectorSize][0] = MakeProgram( device, double_source_v3, sizeof(double_source_v3) / sizeof( double_source_v3[0]) );
if( NULL == doublePrograms[ vectorSize ][0] )
{
gFailCount++;
return -1;
}
} else {
doublePrograms[vectorSize][0] = MakeProgram( device, double_source, sizeof(double_source) / sizeof( double_source[0]) );
if( NULL == doublePrograms[ vectorSize ][0] )
{
gFailCount++;
return -1;
}
}
doubleKernels[ vectorSize ][0] = clCreateKernel( doublePrograms[ vectorSize ][0], "test", &error );
if( NULL == kernels[vectorSize][0] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create double kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
doublePrograms[vectorSize][1] = MakeProgram( device, double_source_private_v3, sizeof(double_source_private_v3) / sizeof( double_source_private_v3[0]) );
if( NULL == doublePrograms[ vectorSize ][1] )
{
gFailCount++;
return -1;
}
} else {
doublePrograms[vectorSize][1] = MakeProgram( device, double_source_private, sizeof(double_source_private) / sizeof( double_source_private[0]) );
if( NULL == doublePrograms[ vectorSize ][1] )
{
gFailCount++;
return -1;
}
}
doubleKernels[ vectorSize ][1] = clCreateKernel( doublePrograms[ vectorSize ][1], "test", &error );
if( NULL == kernels[vectorSize][1] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create double private kernel. (%d)\n", error );
return error;
}
if(g_arrVecSizes[vectorSize] == 3) {
doublePrograms[vectorSize][2] = MakeProgram( device, double_source_local_v3, sizeof(double_source_local_v3) / sizeof( double_source_local_v3[0]) );
if( NULL == doublePrograms[ vectorSize ][2] )
{
gFailCount++;
return -1;
}
} else {
doublePrograms[vectorSize][2] = MakeProgram( device, double_source_local, sizeof(double_source_local) / sizeof( double_source_local[0]) );
if( NULL == doublePrograms[ vectorSize ][2] )
{
gFailCount++;
return -1;
}
}
doubleKernels[ vectorSize ][2] = clCreateKernel( doublePrograms[ vectorSize ][2], "test", &error );
if( NULL == kernels[vectorSize][2] )
{
gFailCount++;
vlog_error( "\t\tFAILED -- Failed to create double local kernel. (%d)\n", error );
return error;
}
}
}
// Figure out how many elements are in a work block
size_t elementSize = MAX( sizeof(cl_ushort), sizeof(float));
size_t blockCount = BUFFER_SIZE / elementSize;
uint64_t lastCase = 1ULL << (8*sizeof(float));
size_t stride = blockCount;
if (gWimpyMode)
stride = (uint64_t)blockCount * (uint64_t)gWimpyReductionFactor;
// we handle 64-bit types a bit differently.
if( lastCase == 0 )
lastCase = 0x100000000ULL;
uint64_t i, j;
error = 0;
uint64_t printMask = (lastCase >> 4) - 1;
cl_uint count = 0;
int addressSpace;
size_t loopCount;
cl_uint threadCount = GetThreadCount();
ComputeReferenceInfoF fref;
fref.x = (float *)gIn_single;
fref.r = (cl_half *)gOut_half_reference;
fref.f = referenceFunc;
fref.lim = blockCount;
fref.count = (blockCount + threadCount - 1) / threadCount;
CheckResultInfoF fchk;
fchk.x = (const float *)gIn_single;
fchk.r = (const cl_half *)gOut_half_reference;
fchk.s = (const cl_half *)gOut_half;
fchk.f = referenceFunc;
fchk.lim = blockCount;
fchk.count = (blockCount + threadCount - 1) / threadCount;
ComputeReferenceInfoD dref;
dref.x = (double *)gIn_double;
dref.r = (cl_half *)gOut_half_reference_double;
dref.f = doubleReferenceFunc;
dref.lim = blockCount;
dref.count = (blockCount + threadCount - 1) / threadCount;
CheckResultInfoD dchk;
dchk.x = (const double *)gIn_double;
dchk.r = (const cl_half *)gOut_half_reference_double;
dchk.s = (const cl_half *)gOut_half;
dchk.f = doubleReferenceFunc;
dchk.lim = blockCount;
dchk.count = (blockCount + threadCount - 1) / threadCount;
for( i = 0; i < (uint64_t)lastCase; i += stride )
{
count = (cl_uint) MIN( blockCount, lastCase - i );
fref.i = i;
dref.i = i;
// Create the input and reference
ThreadPool_Do(ReferenceF, threadCount, &fref);
error = clEnqueueWriteBuffer(gQueue, gInBuffer_single, CL_FALSE, 0, count * sizeof(float ), gIn_single, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
if (gTestDouble) {
ThreadPool_Do(ReferenceD, threadCount, &dref);
error = clEnqueueWriteBuffer(gQueue, gInBuffer_double, CL_FALSE, 0, count * sizeof(double ), gIn_double, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
}
for (vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++) {
// Loop over vector legths
fchk.vsz = g_arrVecSizes[vectorSize];
dchk.vsz = g_arrVecSizes[vectorSize];
for ( addressSpace = 0; addressSpace < 3; addressSpace++) {
// Loop over address spaces
fchk.aspace = addressSpaceNames[addressSpace];
dchk.aspace = addressSpaceNames[addressSpace];
cl_uint pattern = 0xdeaddead;
memset_pattern4(gOut_half, &pattern, BUFFER_SIZE/2);
error = clEnqueueWriteBuffer(gQueue, gOutBuffer_half, CL_FALSE,
0, count * sizeof(cl_half),
gOut_half, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
error = RunKernel(device, kernels[vectorSize][addressSpace], gInBuffer_single, gOutBuffer_half,
numVecs(count, vectorSize, aligned),
runsOverBy(count, vectorSize, aligned));
if (error) {
gFailCount++;
goto exit;
}
error = clEnqueueReadBuffer(gQueue, gOutBuffer_half, CL_TRUE, 0,
count * sizeof(cl_half), gOut_half,
0, NULL, NULL);
if (error) {
vlog_error( "Failure in clReadArray\n" );
gFailCount++;
goto exit;
}
error = ThreadPool_Do(CheckF, threadCount, &fchk);
if (error) {
gFailCount++;
goto exit;
}
if (gTestDouble) {
memset_pattern4(gOut_half, &pattern, BUFFER_SIZE/2);
error = clEnqueueWriteBuffer(
gQueue, gOutBuffer_half, CL_FALSE, 0,
count * sizeof(cl_half), gOut_half, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
error = RunKernel(device, doubleKernels[vectorSize][addressSpace], gInBuffer_double, gOutBuffer_half,
numVecs(count, vectorSize, aligned),
runsOverBy(count, vectorSize, aligned));
if (error) {
gFailCount++;
goto exit;
}
error = clEnqueueReadBuffer(
gQueue, gOutBuffer_half, CL_TRUE, 0,
count * sizeof(cl_half), gOut_half, 0, NULL, NULL);
if (error) {
vlog_error( "Failure in clReadArray\n" );
gFailCount++;
goto exit;
}
error = ThreadPool_Do(CheckD, threadCount, &dchk);
if (error) {
gFailCount++;
goto exit;
}
}
}
} // end for vector size
if( ((i+blockCount) & ~printMask) == (i+blockCount) ) {
vlog( "." );
fflush( stdout );
}
} // for end lastcase
loopCount = count == blockCount ? 1 : 100;
if( gReportTimes )
{
//Init the input stream
cl_float *p = (cl_float *)gIn_single;
for( j = 0; j < count; j++ )
p[j] = (float)((double) (rand() - RAND_MAX/2) / (RAND_MAX/2));
if( (error = clEnqueueWriteBuffer(gQueue, gInBuffer_single, CL_TRUE, 0, count * sizeof( float ), gIn_single, 0, NULL, NULL)) )
{
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
if( gTestDouble )
{
//Init the input stream
cl_double *q = (cl_double *)gIn_double;
for( j = 0; j < count; j++ )
q[j] = ((double) (rand() - RAND_MAX/2) / (RAND_MAX/2));
if( (error = clEnqueueWriteBuffer(gQueue, gInBuffer_double, CL_TRUE, 0, count * sizeof( double ), gIn_double, 0, NULL, NULL)) )
{
vlog_error( "Failure in clWriteArray\n" );
gFailCount++;
goto exit;
}
}
//Run again for timing
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
{
uint64_t bestTime = -1ULL;
for( j = 0; j < loopCount; j++ )
{
uint64_t startTime = ReadTime();
if( (error = RunKernel(device, kernels[vectorSize][0], gInBuffer_single, gOutBuffer_half, numVecs(count, vectorSize, aligned) ,
runsOverBy(count, vectorSize, aligned)) ) )
{
gFailCount++;
goto exit;
}
if( (error = clFinish(gQueue)) )
{
vlog_error( "Failure in clFinish\n" );
gFailCount++;
goto exit;
}
uint64_t currentTime = ReadTime() - startTime;
if( currentTime < bestTime )
bestTime = currentTime;
time[ vectorSize ] += currentTime;
}
if( bestTime < min_time[ vectorSize ] )
min_time[ vectorSize ] = bestTime ;
if( gTestDouble )
{
bestTime = -1ULL;
for( j = 0; j < loopCount; j++ )
{
uint64_t startTime = ReadTime();
if( (error = RunKernel(device, doubleKernels[vectorSize][0], gInBuffer_double, gOutBuffer_half, numVecs(count, vectorSize, aligned) ,
runsOverBy(count, vectorSize, aligned)) ) )
{
gFailCount++;
goto exit;
}
if( (error = clFinish(gQueue)) )
{
vlog_error( "Failure in clFinish\n" );
gFailCount++;
goto exit;
}
uint64_t currentTime = ReadTime() - startTime;
if( currentTime < bestTime )
bestTime = currentTime;
doubleTime[ vectorSize ] += currentTime;
}
if( bestTime < min_double_time[ vectorSize ] )
min_double_time[ vectorSize ] = bestTime;
}
}
}
if( gReportTimes )
{
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( time[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) (count * loopCount), 0,
"average us/elem", "vStoreaHalf%s avg. (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( min_time[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) count, 0,
"best us/elem", "vStoreaHalf%s best (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
if( gTestDouble )
{
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( doubleTime[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) (count * loopCount), 0,
"average us/elem (double)", "vStoreaHalf%s avg. d (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
vlog_perf( SubtractTime( min_double_time[ vectorSize ], 0 ) * 1e6 * gDeviceFrequency * gComputeDevices / (double) count, 0,
"best us/elem (double)", "vStoreaHalf%s best d (%s vector size: %d)", roundName, addressSpaceNames[0], (g_arrVecSizes[vectorSize]) );
}
}
exit:
//clean up
for( vectorSize = minVectorSize; vectorSize < kLastVectorSizeToTest; vectorSize++)
{
for ( addressSpace = 0; addressSpace < 3; addressSpace++) {
clReleaseKernel( kernels[ vectorSize ][addressSpace] );
clReleaseProgram( programs[ vectorSize ][addressSpace] );
if( gTestDouble )
{
clReleaseKernel( doubleKernels[ vectorSize ][addressSpace] );
clReleaseProgram( doublePrograms[ vectorSize ][addressSpace] );
}
}
}
return error;
}
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