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OpenCL-CTS/test_conformance/math_brute_force/common.cpp
Sven van Haastregt b23268acf5 math_brute_force: don't get build log after clCreateKernel (#1722) 
The OpenCL specification states that the build log is only for
clBuildProgram, clCompileProgram or clLinkProgram.  Calling it after
clCreateKernel should not give any additional information, so this is
effectively dead code.  In case building failed, any logs would
already have been printed by create_single_kernel_helper.

Signed-off-by: Sven van Haastregt <sven.vanhaastregt@arm.com>
2023-05-13 10:21:13 +01:00

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//
// Copyright (c) 2022 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 "common.h"
#include "utility.h" // for sizeNames and sizeValues.
#include <sstream>
#include <string>
namespace {
const char *GetTypeName(ParameterType type)
{
switch (type)
{
case ParameterType::Float: return "float";
case ParameterType::Double: return "double";
case ParameterType::Int: return "int";
case ParameterType::UInt: return "uint";
case ParameterType::Long: return "long";
case ParameterType::ULong: return "ulong";
}
return nullptr;
}
const char *GetUndefValue(ParameterType type)
{
switch (type)
{
case ParameterType::Float:
case ParameterType::Double: return "NAN";
case ParameterType::Int:
case ParameterType::UInt: return "0x12345678";
case ParameterType::Long:
case ParameterType::ULong: return "0x0ddf00dbadc0ffee";
}
return nullptr;
}
void EmitDefineType(std::ostringstream &kernel, const char *name,
ParameterType type, int vector_size_index)
{
kernel << "#define " << name << " " << GetTypeName(type)
<< sizeNames[vector_size_index] << '\n';
kernel << "#define " << name << "_SCALAR " << GetTypeName(type) << '\n';
}
void EmitDefineUndef(std::ostringstream &kernel, const char *name,
ParameterType type)
{
kernel << "#define " << name << " " << GetUndefValue(type) << '\n';
}
void EmitEnableExtension(std::ostringstream &kernel,
const std::initializer_list<ParameterType> &types)
{
bool needsFp64 = false;
for (const auto &type : types)
{
switch (type)
{
case ParameterType::Double: needsFp64 = true; break;
case ParameterType::Float:
case ParameterType::Int:
case ParameterType::UInt:
case ParameterType::Long:
case ParameterType::ULong:
// No extension required.
break;
}
}
if (needsFp64) kernel << "#pragma OPENCL EXTENSION cl_khr_fp64 : enable\n";
}
std::string GetBuildOptions(bool relaxed_mode)
{
std::ostringstream options;
if (gForceFTZ)
{
options << " -cl-denorms-are-zero";
}
if (gFloatCapabilities & CL_FP_CORRECTLY_ROUNDED_DIVIDE_SQRT)
{
options << " -cl-fp32-correctly-rounded-divide-sqrt";
}
if (relaxed_mode)
{
options << " -cl-fast-relaxed-math";
}
return options.str();
}
} // anonymous namespace
std::string GetKernelName(int vector_size_index)
{
return std::string("math_kernel") + sizeNames[vector_size_index];
}
std::string GetUnaryKernel(const std::string &kernel_name, const char *builtin,
ParameterType retType, ParameterType type1,
int vector_size_index)
{
// To keep the kernel code readable, use macros for types and undef values.
std::ostringstream kernel;
EmitDefineType(kernel, "RETTYPE", retType, vector_size_index);
EmitDefineType(kernel, "TYPE1", type1, vector_size_index);
EmitDefineUndef(kernel, "UNDEF1", type1);
EmitEnableExtension(kernel, { retType, type1 });
// clang-format off
const char *kernel_nonvec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE* out,
__global TYPE1* in1)
{
size_t i = get_global_id(0);
out[i] = )", builtin, R"((in1[i]);
}
)" };
const char *kernel_vec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE_SCALAR* out,
__global TYPE1_SCALAR* in1)
{
size_t i = get_global_id(0);
if (i + 1 < get_global_size(0))
{
TYPE1 a = vload3(0, in1 + 3 * i);
RETTYPE res = )", builtin, R"((a);
vstore3(res, 0, out + 3 * i);
}
else
{
// Figure out how many elements are left over after
// BUFFER_SIZE % (3 * sizeof(type)).
// Assume power of two buffer size.
size_t parity = i & 1;
TYPE1 a = (TYPE1)(UNDEF1, UNDEF1, UNDEF1);
switch (parity)
{
case 0:
a.y = in1[3 * i + 1];
// fall through
case 1:
a.x = in1[3 * i];
break;
}
RETTYPE res = )", builtin, R"((a);
switch (parity)
{
case 0:
out[3 * i + 1] = res.y;
// fall through
case 1:
out[3 * i] = res.x;
break;
}
}
}
)" };
// clang-format on
if (sizeValues[vector_size_index] != 3)
for (const auto &chunk : kernel_nonvec3) kernel << chunk;
else
for (const auto &chunk : kernel_vec3) kernel << chunk;
return kernel.str();
}
std::string GetUnaryKernel(const std::string &kernel_name, const char *builtin,
ParameterType retType1, ParameterType retType2,
ParameterType type1, int vector_size_index)
{
// To keep the kernel code readable, use macros for types and undef values.
std::ostringstream kernel;
EmitDefineType(kernel, "RETTYPE1", retType1, vector_size_index);
EmitDefineType(kernel, "RETTYPE2", retType2, vector_size_index);
EmitDefineType(kernel, "TYPE1", type1, vector_size_index);
EmitDefineUndef(kernel, "UNDEF1", type1);
EmitDefineUndef(kernel, "UNDEFR2", retType2);
EmitEnableExtension(kernel, { retType1, retType2, type1 });
// clang-format off
const char *kernel_nonvec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE1* out1,
__global RETTYPE2* out2,
__global TYPE1* in1)
{
size_t i = get_global_id(0);
out1[i] = )", builtin, R"((in1[i], out2 + i);
}
)" };
const char *kernel_vec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE1_SCALAR* out1,
__global RETTYPE2_SCALAR* out2,
__global TYPE1_SCALAR* in1)
{
size_t i = get_global_id(0);
if (i + 1 < get_global_size(0))
{
TYPE1 a = vload3(0, in1 + 3 * i);
RETTYPE2 res2 = UNDEFR2;
RETTYPE1 res1 = )", builtin, R"((a, &res2);
vstore3(res1, 0, out1 + 3 * i);
vstore3(res2, 0, out2 + 3 * i);
}
else
{
// Figure out how many elements are left over after
// BUFFER_SIZE % (3 * sizeof(type)).
// Assume power of two buffer size.
size_t parity = i & 1;
TYPE1 a = (TYPE1)(UNDEF1, UNDEF1, UNDEF1);
switch (parity)
{
case 0:
a.y = in1[3 * i + 1];
// fall through
case 1:
a.x = in1[3 * i];
break;
}
RETTYPE2 res2 = UNDEFR2;
RETTYPE1 res1 = )", builtin, R"((a, &res2);
switch (parity)
{
case 0:
out1[3 * i + 1] = res1.y;
out2[3 * i + 1] = res2.y;
// fall through
case 1:
out1[3 * i] = res1.x;
out2[3 * i] = res2.x;
break;
}
}
}
)" };
// clang-format on
if (sizeValues[vector_size_index] != 3)
for (const auto &chunk : kernel_nonvec3) kernel << chunk;
else
for (const auto &chunk : kernel_vec3) kernel << chunk;
return kernel.str();
}
std::string GetBinaryKernel(const std::string &kernel_name, const char *builtin,
ParameterType retType, ParameterType type1,
ParameterType type2, int vector_size_index)
{
// To keep the kernel code readable, use macros for types and undef values.
std::ostringstream kernel;
EmitDefineType(kernel, "RETTYPE", retType, vector_size_index);
EmitDefineType(kernel, "TYPE1", type1, vector_size_index);
EmitDefineType(kernel, "TYPE2", type2, vector_size_index);
EmitDefineUndef(kernel, "UNDEF1", type1);
EmitDefineUndef(kernel, "UNDEF2", type2);
EmitEnableExtension(kernel, { retType, type1, type2 });
const bool is_vec3 = sizeValues[vector_size_index] == 3;
std::string invocation;
if (strlen(builtin) == 1)
{
// Assume a single-character builtin is an operator (e.g., +, *, ...).
invocation = is_vec3 ? "a" : "in1[i] ";
invocation += builtin;
invocation += is_vec3 ? "b" : " in2[i]";
}
else
{
// Otherwise call the builtin as a function with two arguments.
invocation = builtin;
invocation += is_vec3 ? "(a, b)" : "(in1[i], in2[i])";
}
// clang-format off
const char *kernel_nonvec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE* out,
__global TYPE1* in1,
__global TYPE2* in2)
{
size_t i = get_global_id(0);
out[i] = )", invocation.c_str(), R"(;
}
)" };
const char *kernel_vec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE_SCALAR* out,
__global TYPE1_SCALAR* in1,
__global TYPE2_SCALAR* in2)
{
size_t i = get_global_id(0);
if (i + 1 < get_global_size(0))
{
TYPE1 a = vload3(0, in1 + 3 * i);
TYPE2 b = vload3(0, in2 + 3 * i);
RETTYPE res = )", invocation.c_str(), R"(;
vstore3(res, 0, out + 3 * i);
}
else
{
// Figure out how many elements are left over after
// BUFFER_SIZE % (3 * sizeof(type)).
// Assume power of two buffer size.
size_t parity = i & 1;
TYPE1 a = (TYPE1)(UNDEF1, UNDEF1, UNDEF1);
TYPE2 b = (TYPE2)(UNDEF2, UNDEF2, UNDEF2);
switch (parity)
{
case 0:
a.y = in1[3 * i + 1];
b.y = in2[3 * i + 1];
// fall through
case 1:
a.x = in1[3 * i];
b.x = in2[3 * i];
break;
}
RETTYPE res = )", invocation.c_str(), R"(;
switch (parity)
{
case 0:
out[3 * i + 1] = res.y;
// fall through
case 1:
out[3 * i] = res.x;
break;
}
}
}
)" };
// clang-format on
if (!is_vec3)
for (const auto &chunk : kernel_nonvec3) kernel << chunk;
else
for (const auto &chunk : kernel_vec3) kernel << chunk;
return kernel.str();
}
std::string GetBinaryKernel(const std::string &kernel_name, const char *builtin,
ParameterType retType1, ParameterType retType2,
ParameterType type1, ParameterType type2,
int vector_size_index)
{
// To keep the kernel code readable, use macros for types and undef values.
std::ostringstream kernel;
EmitDefineType(kernel, "RETTYPE1", retType1, vector_size_index);
EmitDefineType(kernel, "RETTYPE2", retType2, vector_size_index);
EmitDefineType(kernel, "TYPE1", type1, vector_size_index);
EmitDefineType(kernel, "TYPE2", type2, vector_size_index);
EmitDefineUndef(kernel, "UNDEF1", type1);
EmitDefineUndef(kernel, "UNDEF2", type2);
EmitDefineUndef(kernel, "UNDEFR2", retType2);
EmitEnableExtension(kernel, { retType1, retType2, type1, type2 });
// clang-format off
const char *kernel_nonvec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE1* out1,
__global RETTYPE2* out2,
__global TYPE1* in1,
__global TYPE2* in2)
{
size_t i = get_global_id(0);
out1[i] = )", builtin, R"((in1[i], in2[i], out2 + i);
}
)" };
const char *kernel_vec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE1_SCALAR* out1,
__global RETTYPE2_SCALAR* out2,
__global TYPE1_SCALAR* in1,
__global TYPE2_SCALAR* in2)
{
size_t i = get_global_id(0);
if (i + 1 < get_global_size(0))
{
TYPE1 a = vload3(0, in1 + 3 * i);
TYPE2 b = vload3(0, in2 + 3 * i);
RETTYPE2 res2 = UNDEFR2;
RETTYPE1 res1 = )", builtin, R"((a, b, &res2);
vstore3(res1, 0, out1 + 3 * i);
vstore3(res2, 0, out2 + 3 * i);
}
else
{
// Figure out how many elements are left over after
// BUFFER_SIZE % (3 * sizeof(type)).
// Assume power of two buffer size.
size_t parity = i & 1;
TYPE1 a = (TYPE1)(UNDEF1, UNDEF1, UNDEF1);
TYPE2 b = (TYPE2)(UNDEF2, UNDEF2, UNDEF2);
switch (parity)
{
case 0:
a.y = in1[3 * i + 1];
b.y = in2[3 * i + 1];
// fall through
case 1:
a.x = in1[3 * i];
b.x = in2[3 * i];
break;
}
RETTYPE2 res2 = UNDEFR2;
RETTYPE1 res1 = )", builtin, R"((a, b, &res2);
switch (parity)
{
case 0:
out1[3 * i + 1] = res1.y;
out2[3 * i + 1] = res2.y;
// fall through
case 1:
out1[3 * i] = res1.x;
out2[3 * i] = res2.x;
break;
}
}
}
)" };
// clang-format on
if (sizeValues[vector_size_index] != 3)
for (const auto &chunk : kernel_nonvec3) kernel << chunk;
else
for (const auto &chunk : kernel_vec3) kernel << chunk;
return kernel.str();
}
std::string GetTernaryKernel(const std::string &kernel_name,
const char *builtin, ParameterType retType,
ParameterType type1, ParameterType type2,
ParameterType type3, int vector_size_index)
{
// To keep the kernel code readable, use macros for types and undef values.
std::ostringstream kernel;
EmitDefineType(kernel, "RETTYPE", retType, vector_size_index);
EmitDefineType(kernel, "TYPE1", type1, vector_size_index);
EmitDefineType(kernel, "TYPE2", type2, vector_size_index);
EmitDefineType(kernel, "TYPE3", type3, vector_size_index);
EmitDefineUndef(kernel, "UNDEF1", type1);
EmitDefineUndef(kernel, "UNDEF2", type2);
EmitDefineUndef(kernel, "UNDEF3", type3);
EmitEnableExtension(kernel, { retType, type1, type2, type3 });
// clang-format off
const char *kernel_nonvec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE* out,
__global TYPE1* in1,
__global TYPE2* in2,
__global TYPE3* in3)
{
size_t i = get_global_id(0);
out[i] = )", builtin, R"((in1[i], in2[i], in3[i]);
}
)" };
const char *kernel_vec3[] = { R"(
__kernel void )", kernel_name.c_str(), R"((__global RETTYPE_SCALAR* out,
__global TYPE1_SCALAR* in1,
__global TYPE2_SCALAR* in2,
__global TYPE3_SCALAR* in3)
{
size_t i = get_global_id(0);
if (i + 1 < get_global_size(0))
{
TYPE1 a = vload3(0, in1 + 3 * i);
TYPE2 b = vload3(0, in2 + 3 * i);
TYPE3 c = vload3(0, in3 + 3 * i);
RETTYPE res = )", builtin, R"((a, b, c);
vstore3(res, 0, out + 3 * i);
}
else
{
// Figure out how many elements are left over after
// BUFFER_SIZE % (3 * sizeof(type)).
// Assume power of two buffer size.
size_t parity = i & 1;
TYPE1 a = (TYPE1)(UNDEF1, UNDEF1, UNDEF1);
TYPE2 b = (TYPE2)(UNDEF2, UNDEF2, UNDEF2);
TYPE3 c = (TYPE3)(UNDEF3, UNDEF3, UNDEF3);
switch (parity)
{
case 0:
a.y = in1[3 * i + 1];
b.y = in2[3 * i + 1];
c.y = in3[3 * i + 1];
// fall through
case 1:
a.x = in1[3 * i];
b.x = in2[3 * i];
c.x = in3[3 * i];
break;
}
RETTYPE res = )", builtin, R"((a, b, c);
switch (parity)
{
case 0:
out[3 * i + 1] = res.y;
// fall through
case 1:
out[3 * i] = res.x;
break;
}
}
}
)" };
// clang-format on
if (sizeValues[vector_size_index] != 3)
for (const auto &chunk : kernel_nonvec3) kernel << chunk;
else
for (const auto &chunk : kernel_vec3) kernel << chunk;
return kernel.str();
}
cl_int BuildKernels(BuildKernelInfo &info, cl_uint job_id,
SourceGenerator generator)
{
// Generate the kernel code.
cl_uint vector_size_index = gMinVectorSizeIndex + job_id;
auto kernel_name = GetKernelName(vector_size_index);
auto source = generator(kernel_name, info.nameInCode, vector_size_index);
std::array<const char *, 1> sources{ source.c_str() };
// Create the program.
clProgramWrapper &program = info.programs[vector_size_index];
auto options = GetBuildOptions(info.relaxedMode);
int error =
create_single_kernel_helper(gContext, &program, nullptr, sources.size(),
sources.data(), nullptr, options.c_str());
if (error != CL_SUCCESS)
{
vlog_error("\t\tFAILED -- Failed to create program. (%d)\n", error);
return error;
}
// Create a kernel for each thread. cl_kernels aren't thread safe, so make
// one for every thread
auto &kernels = info.kernels[vector_size_index];
assert(kernels.empty() && "Dirty BuildKernelInfo");
kernels.resize(info.threadCount);
for (auto &kernel : kernels)
{
kernel = clCreateKernel(program, kernel_name.c_str(), &error);
if (!kernel || error != CL_SUCCESS)
{
vlog_error("\t\tFAILED -- clCreateKernel() failed: (%d)\n", error);
return error;
}
}
return CL_SUCCESS;
}
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