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review.mlplatform.org / ml / ComputeLibrary / 7068f9900d136312318ff430aef588b14e0c87ad / . / src / core / GLES_COMPUTE / GCKernelLibrary.cpp
blob: fd362f16650bea874dbb742208eca1ab81ea271c [file] [log] [blame]
/*
* Copyright (c) 2017 ARM Limited.
*
* SPDX-License-Identifier: MIT
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "arm_compute/core/GLES_COMPUTE/GCKernelLibrary.h"
#include "arm_compute/core/Error.h"
#include "arm_compute/core/Utils.h"
#include <fstream>
#include <iomanip>
#include <iostream>
#include <regex>
#include <utility>
#include <vector>
using namespace arm_compute;
GCProgram::GCProgram()
: _name(), _source()
{
}
GCProgram::GCProgram(std::string name, std::string source)
: _name(std::move(name)), _source(std::move(source))
{
}
GLuint GCProgram::link_program(GLuint shader)
{
GLuint program = ARM_COMPUTE_GL_CHECK(glCreateProgram());
GLint rvalue;
GLsizei length;
ARM_COMPUTE_GL_CHECK(glAttachShader(program, shader));
ARM_COMPUTE_GL_CHECK(glLinkProgram(program));
ARM_COMPUTE_GL_CHECK(glDetachShader(program, shader));
ARM_COMPUTE_GL_CHECK(glDeleteShader(shader));
// Check if there were some issues when linking the shader.
ARM_COMPUTE_GL_CHECK(glGetProgramiv(program, GL_LINK_STATUS, &rvalue));
if(rvalue == 0)
{
ARM_COMPUTE_GL_CHECK(glGetProgramiv(program, GL_INFO_LOG_LENGTH, &length));
std::vector<GLchar> log(length);
ARM_COMPUTE_GL_CHECK(glGetProgramInfoLog(program, length, nullptr, log.data()));
ARM_COMPUTE_ERROR("Error: Linker log:\n%s\n", log.data());
return 0;
}
ARM_COMPUTE_GL_CHECK(glUseProgram(program));
return program;
}
GLuint GCProgram::compile_shader(const std::string &build_options)
{
GLuint shader = ARM_COMPUTE_GL_CHECK(glCreateShader(GL_COMPUTE_SHADER));
const char *src[]
{
"#version 310 es\n",
build_options.c_str(),
_source.c_str()
};
ARM_COMPUTE_GL_CHECK(glShaderSource(shader, sizeof(src) / sizeof(src[0]), src, nullptr));
ARM_COMPUTE_GL_CHECK(glCompileShader(shader));
// Check if there were any issues when compiling the shader
GLint rvalue;
GLsizei length;
ARM_COMPUTE_GL_CHECK(glGetShaderiv(shader, GL_COMPILE_STATUS, &rvalue));
if(rvalue == 0)
{
ARM_COMPUTE_GL_CHECK(glGetShaderiv(shader, GL_INFO_LOG_LENGTH, &length));
std::vector<GLchar> log(length);
ARM_COMPUTE_GL_CHECK(glGetShaderInfoLog(shader, length, nullptr, log.data()));
#ifdef ARM_COMPUTE_DEBUG_ENABLED
std::istringstream ss(_source);
std::stringstream output_stream;
std::string line;
size_t line_num = 1;
ARM_COMPUTE_LOG_INFO_MSG_WITH_FORMAT_CORE("GLES Shader build options:\n%s\n", build_options.c_str());
while(std::getline(ss, line, '\n'))
{
output_stream << std::setw(6) << line_num << ": " << line << std::endl;
line_num++;
}
ARM_COMPUTE_LOG_INFO_STREAM_CORE("GLES Shader source code:" << output_stream.rdbuf());
#endif /* ARM_COMPUTE_DEBUG_ENABLED */
ARM_COMPUTE_ERROR("Error: Compiler log:\n%s\n", log.data());
return 0;
}
return shader;
}
GCKernel::GCKernel()
: _name(), _program(), _params(), _shader_params(), _shader_params_binding_point(), _shader_params_index(), _shader_params_size()
{
}
GCKernel::GCKernel(std::string name, GLuint program)
: _name(std::move(name)),
_program(program),
_params(),
_shader_params(0),
_shader_params_binding_point(0),
_shader_params_index(0),
_shader_params_size(0)
{
_params.clear();
ARM_COMPUTE_GL_CHECK(glGenBuffers(1, &_shader_params));
_shader_params_index = ARM_COMPUTE_GL_CHECK(glGetUniformBlockIndex(_program, _shader_params_name));
ARM_COMPUTE_ERROR_ON_MSG((_shader_params_index == GL_INVALID_INDEX), "Failed to get index of %s", _shader_params_name);
ARM_COMPUTE_GL_CHECK(glGetActiveUniformBlockiv(_program, _shader_params_index, GL_UNIFORM_BLOCK_DATA_SIZE, &_shader_params_size));
ARM_COMPUTE_ERROR_ON_MSG((_shader_params_size == 0), "Failed to get size of %s", _shader_params_name);
}
void GCKernel::cleanup()
{
ARM_COMPUTE_GL_CHECK(glDeleteBuffers(1, &_shader_params));
ARM_COMPUTE_GL_CHECK(glBindBuffer(GL_UNIFORM_BUFFER, 0));
ARM_COMPUTE_GL_CHECK(glDeleteProgram(_program));
ARM_COMPUTE_GL_CHECK(glUseProgram(0));
}
void GCKernel::use()
{
ARM_COMPUTE_GL_CHECK(glUseProgram(_program));
}
void GCKernel::unuse()
{
ARM_COMPUTE_GL_CHECK(glUseProgram(0));
}
void GCKernel::update_shader_params()
{
ARM_COMPUTE_ERROR_ON_MSG((_shader_params_size != (int)(_params.size() * sizeof(_params[0]))), "Params size (%d) is not equal to shader params block size (%d)", _params.size() * sizeof(_params[0]),
_shader_params_size);
ARM_COMPUTE_GL_CHECK(glUniformBlockBinding(_program, _shader_params_index, _shader_params_binding_point));
ARM_COMPUTE_GL_CHECK(glBindBufferBase(GL_UNIFORM_BUFFER, _shader_params_binding_point, _shader_params));
ARM_COMPUTE_GL_CHECK(glBindBuffer(GL_UNIFORM_BUFFER, _shader_params));
ARM_COMPUTE_GL_CHECK(glBufferData(GL_UNIFORM_BUFFER, _shader_params_size, _params.data(), GL_DYNAMIC_DRAW));
ARM_COMPUTE_GL_CHECK(glBindBuffer(GL_UNIFORM_BUFFER, 0));
}
const std::map<std::string, std::string> GCKernelLibrary::_shader_program_map =
{
{ "absdiff", "absdiff.cs" },
{ "col2im", "convolution_layer.cs" },
{ "direct_convolution1x1", "direct_convolution1x1.cs" },
{ "direct_convolution3x3", "direct_convolution3x3.cs" },
{ "direct_convolution5x5", "direct_convolution5x5.cs" },
{ "pooling_layer_2", "pooling_layer.cs" },
{ "pooling_layer_3", "pooling_layer.cs" },
{ "pooling_layer_7", "pooling_layer.cs" },
{ "pooling_layer_3_optimized", "pooling_layer.cs" },
{ "pooling_layer_n", "pooling_layer.cs" },
{ "fill_image_borders_replicate", "fill_border.cs" },
{ "fill_image_borders_constant", "fill_border.cs" },
{ "gemm_accumulate_biases", "gemm.cs" },
{ "gemm_interleave4x4", "gemm.cs" },
{ "gemm_ma", "gemm.cs" },
{ "gemm_mm_interleaved_transposed", "gemm.cs" },
{ "gemm_mm_floating_point", "gemm.cs" },
{ "gemm_transpose1x4", "gemm.cs" },
{ "im2col_kernel3x3_padx0_pady0", "convolution_layer.cs" },
{ "im2col_generic", "convolution_layer.cs" },
{ "im2col_reduced", "convolution_layer.cs" },
{ "transpose", "transpose.cs" },
{ "activation_layer", "activation_layer.cs" },
{ "softmax_layer_max", "softmax_layer.cs" },
{ "softmax_layer_shift_exp_sum", "softmax_layer.cs" },
{ "softmax_layer_norm", "softmax_layer.cs" },
{ "pixelwise_mul_float", "pixelwise_mul_float.cs" },
{ "normalization_layer", "normalization_layer.cs" },
{ "batchnormalization_layer", "batchnormalization_layer.cs" },
{ "concatenate_depth", "concatenate.cs" },
{ "dropout", "dropout.cs" },
};
const std::map<std::string, std::string> GCKernelLibrary::_program_source_map =
{
#ifdef EMBEDDED_KERNELS
{
"absdiff.cs",
#include "./cs_shaders/absdiff.csembed"
},
{
"convolution_layer.cs",
#include "./cs_shaders/convolution_layer.csembed"
},
{
"direct_convolution1x1.cs",
#include "./cs_shaders/direct_convolution1x1.csembed"
},
{
"direct_convolution3x3.cs",
#include "./cs_shaders/direct_convolution3x3.csembed"
},
{
"direct_convolution5x5.cs",
#include "./cs_shaders/direct_convolution5x5.csembed"
},
{
"pooling_layer.cs",
#include "./cs_shaders/pooling_layer.csembed"
},
{
"fill_border.cs",
#include "./cs_shaders/fill_border.csembed"
},
{
"gemm.cs",
#include "./cs_shaders/gemm.csembed"
},
{
"transpose.cs",
#include "./cs_shaders/transpose.csembed"
},
{
"activation_layer.cs",
#include "./cs_shaders/activation_layer.csembed"
},
{
"softmax_layer.cs",
#include "./cs_shaders/softmax_layer.csembed"
},
{
"pixelwise_mul_float.cs",
#include "./cs_shaders/pixelwise_mul_float.csembed"
},
{
"normalization_layer.cs",
#include "./cs_shaders/normalization_layer.csembed"
},
{
"batchnormalization_layer.cs",
#include "./cs_shaders/batchnormalization_layer.csembed"
},
{
"concatenate.cs",
#include "./cs_shaders/concatenate.csembed"
},
{
"dropout.cs",
#include "./cs_shaders/dropout.csembed"
},
#endif /* EMBEDDED_KERNELS */
};
GCKernelLibrary::GCKernelLibrary()
: _display(EGL_NO_DISPLAY), _context(EGL_NO_CONTEXT), _frame_buffer(0), _tex_rt(0), _own_context(false), _shader_path("./"), _programs_map(), _built_programs_map()
{
}
GCKernelLibrary &GCKernelLibrary::get()
{
static GCKernelLibrary _kernel_library;
return _kernel_library;
}
GCKernel GCKernelLibrary::create_kernel(const std::string &shader_name, const StringSet &build_options_set) const
{
// Find which program contains the kernel
auto shader_program_it = _shader_program_map.find(shader_name);
if(_shader_program_map.end() == shader_program_it)
{
ARM_COMPUTE_ERROR("Shader %s not found in the GCKernelLibrary", shader_name.c_str());
}
// Check if the program has been built before with same build options.
const std::string program_name = shader_program_it->second;
const std::string build_options = stringify_set(build_options_set);
const std::string built_program_name = program_name + "_" + build_options;
auto built_program_it = _built_programs_map.find(built_program_name);
GCKernel kernel;
if(_built_programs_map.end() != built_program_it)
{
// If program has been built, retrieve to create kernel from it
kernel = built_program_it->second;
kernel.use();
}
else
{
GCProgram program = load_program(program_name);
std::string source_name = _shader_path + shader_program_it->second;
// load shader
GLuint shader = program.compile_shader(build_options);
// Build program
GLuint gles_program = program.link_program(shader);
// Create GCKernel
kernel = GCKernel(shader_name, gles_program);
// Add built program to internal map
_built_programs_map.emplace(built_program_name, kernel);
}
return kernel;
}
const std::string GCKernelLibrary::preprocess_shader(const std::string &shader_source) const
{
enum class ParserStage
{
FIRST,
SKIP_COMMENTS = FIRST,
RESOLVE_INCLUDES,
SKIP_PREPROCESSOR_DIRECTIVES,
SEARCH_MACRO_DEFINITIONS,
EXPAND_MACRO_USES,
LAST
};
struct MacroDefinitionInfo
{
const std::vector<std::string> param_list;
const std::string content;
};
// Found macro definitions so far
std::map<const std::string, const MacroDefinitionInfo> macro_definitions;
// Define a GLES compute shader parser function
std::function<std::string(const std::string &, ParserStage, int)> cs_parser;
cs_parser = [&](const std::string & src, ParserStage stage, int nested_level) -> std::string
{
std::string dst;
if(stage == ParserStage::LAST || std::regex_match(src, std::regex(R"(\s*)")))
{
return src;
}
auto next_stage = static_cast<ParserStage>(static_cast<int>(stage) + 1);
std::string search_pattern;
switch(stage)
{
case ParserStage::SKIP_COMMENTS:
search_pattern = R"((/\*([^*]|\n|(\*+([^*/]|\n)))*\*+/)|(//.*))";
break;
case ParserStage::RESOLVE_INCLUDES:
search_pattern = R"rgx((?:^|\n)[ \t]*#include "(.*)")rgx";
break;
case ParserStage::SKIP_PREPROCESSOR_DIRECTIVES:
search_pattern = R"((^|\n)[ \t]*(#ifdef|#ifndef|#if)[^\n]+)";
break;
case ParserStage::SEARCH_MACRO_DEFINITIONS:
search_pattern = R"((?:^|\n)[ \t]*#define[ \t]+(\w+)(?:\((\w+(?:[ \t]*,[ \t]*\w+)*)\))?(?: |\t|\\\n)*((?:(?:[^\\\n]|\\[^\n])*\\+\n)*(?:[ \t]*[^ \t\n]+)*)[ \t]*)";
break;
case ParserStage::EXPAND_MACRO_USES:
{
if(macro_definitions.empty())
{
// Nothing to expand
return src;
}
int i = 0;
for(auto &def : macro_definitions)
{
if(i == 0)
{
search_pattern = R"((\b)" + def.first;
}
else
{
search_pattern += R"(\b|\b)" + def.first;
}
i++;
}
search_pattern += R"(\b))";
break;
}
default:
break;
}
std::regex search_regex(search_pattern);
std::smatch match;
ptrdiff_t parsed_pos = 0;
if(std::regex_search(src, match, search_regex))
{
// Pass the content before the match to the next stage
dst.append(cs_parser(src.substr(0, match.position()), next_stage, 0));
parsed_pos = match.position() + match.length();
// Deal with the matched content
switch(stage)
{
case ParserStage::RESOLVE_INCLUDES:
{
// Replace with the included file contents
// And parse the content from the first stage
const std::string source_name = _shader_path + match.str(1);
dst.append(cs_parser(read_file(source_name, false), ParserStage::FIRST, 0));
break;
}
case ParserStage::SEARCH_MACRO_DEFINITIONS:
{
std::regex params_regex(R"(\b\w+\b)");
const std::string macro_param_str = match.str(2);
const std::vector<std::string> macro_param_list(
std::sregex_token_iterator(macro_param_str.begin(),
macro_param_str.end(),
params_regex),
std::sregex_token_iterator());
const MacroDefinitionInfo info =
{
macro_param_list,
match.str(3)
};
// Collect the macro definition data and not change the shader source
macro_definitions.insert(std::pair<const std::string, const MacroDefinitionInfo>(match.str(1), info));
dst.append(match.str());
break;
}
case ParserStage::EXPAND_MACRO_USES:
{
ptrdiff_t args_str_length = 0;
std::vector<std::string> args_list;
// Walk through argument list, because the regular expression does NOT support nested parentheses
size_t cur_args_str_pos = match.position() + match.length();
if(src[cur_args_str_pos++] == '(')
{
int nested_parentheses = 0;
ptrdiff_t cur_arg_pos = cur_args_str_pos;
ptrdiff_t cur_arg_length = 0;
args_str_length++;
while(src[cur_args_str_pos] != ')' || nested_parentheses != 0)
{
switch(src[cur_args_str_pos++])
{
case '(':
nested_parentheses++;
cur_arg_length++;
break;
case ',':
if(nested_parentheses == 0)
{
args_list.push_back(src.substr(cur_arg_pos, cur_arg_length));
cur_arg_pos = cur_args_str_pos;
cur_arg_length = 0;
}
else
{
cur_arg_length++;
}
break;
case ' ':
case '\t':
if(cur_arg_length == 0)
{
cur_arg_pos++;
}
else
{
cur_arg_length++;
}
break;
case ')':
nested_parentheses--;
// no break here!
default:
cur_arg_length++;
break;
}
args_str_length++;
}
if(src[cur_args_str_pos] == ')' && nested_parentheses == 0)
{
args_list.push_back(src.substr(cur_arg_pos, cur_arg_length));
}
args_str_length++;
}
std::string expanded_content = match.str();
const std::vector<std::string> macro_param_list = macro_definitions.at(match.str()).param_list;
if((nested_level != 0 || !macro_param_list.empty()) && macro_param_list.size() == args_list.size())
{
parsed_pos += args_str_length;
expanded_content = macro_definitions.at(match.str()).content;
size_t i = 0;
for(auto &param_name : macro_param_list)
{
std::regex params_regex(R"(\b)" + param_name + R"(\b)");
expanded_content.assign(std::regex_replace(expanded_content, params_regex, args_list[i]));
++i;
}
// Expand macro recursively
expanded_content = cs_parser(expanded_content, stage, nested_level + 1);
if(nested_level == 0)
{
const std::regex token_pasting_rgx = std::regex(R"(\b##\b)");
if(std::regex_search(expanded_content, token_pasting_rgx))
{
// Remove token pasting operator "##"
expanded_content.assign(std::regex_replace(expanded_content, std::regex(token_pasting_rgx), ""));
// Trim trailing whitespace
expanded_content.assign(std::regex_replace(expanded_content, std::regex(R"([ \t]*\\\n)"), "\n"));
}
else
{
// Do not expand the macro if the result does not have token pasting operator "##"
expanded_content = src.substr(match.position(), match.length() + args_str_length);
}
}
}
dst.append(expanded_content);
break;
}
case ParserStage::SKIP_COMMENTS:
case ParserStage::SKIP_PREPROCESSOR_DIRECTIVES:
default:
dst.append(match.str());
break;
}
next_stage = stage;
}
dst.append(cs_parser(src.substr(parsed_pos, src.length() - parsed_pos), next_stage, 0));
return dst;
};
return cs_parser(shader_source, ParserStage::FIRST, 0);
}
const GCProgram &GCKernelLibrary::load_program(const std::string &program_name) const
{
const auto program_it = _programs_map.find(program_name);
if(program_it != _programs_map.end())
{
return program_it->second;
}
GCProgram program;
#ifdef EMBEDDED_KERNELS
const auto program_source_it = _program_source_map.find(program_name);
if(_program_source_map.end() == program_source_it)
{
ARM_COMPUTE_ERROR("Embedded program for %s does not exist.", program_name.c_str());
}
// TODO(APPBROWSER-298): Do not call shader preprocessor here
// We should do the preprocess at compile time
// The preprocess_shader function is used for support "#include" directive and token pasting operator "##".
// This job could be done at compile time by using a python script in order to get better performance at runtime.
// BTW: We usually defined EMBEDDED_KERNELS in release build.
program = GCProgram(program_name, preprocess_shader(program_source_it->second));
#else /* EMBEDDED_KERNELS */
// Check for binary
std::string source_name = _shader_path + program_name;
if(std::ifstream(source_name).is_open())
{
program = GCProgram(program_name, preprocess_shader(read_file(source_name, false)));
}
else
{
ARM_COMPUTE_ERROR("Shader file %s does not exist.", source_name.c_str());
}
#endif /* EMBEDDED_KERNELS */
// Insert program to program map
const auto new_program = _programs_map.emplace(program_name, std::move(program));
return new_program.first->second;
}
void GCKernelLibrary::setup_context()
{
EGLBoolean res;
_display = eglGetDisplay(EGL_DEFAULT_DISPLAY);
ARM_COMPUTE_ERROR_ON_MSG(_display == EGL_NO_DISPLAY, "Failed to get display: 0x%x.", eglGetError());
res = eglInitialize(_display, nullptr, nullptr);
ARM_COMPUTE_ERROR_ON_MSG(res == EGL_FALSE, "Failed to initialize egl: 0x%x.", eglGetError());
ARM_COMPUTE_UNUSED(res);
const char *egl_extension_st = eglQueryString(_display, EGL_EXTENSIONS);
ARM_COMPUTE_ERROR_ON_MSG((strstr(egl_extension_st, "EGL_KHR_create_context") == nullptr), "Failed to query EGL_KHR_create_context");
ARM_COMPUTE_ERROR_ON_MSG((strstr(egl_extension_st, "EGL_KHR_surfaceless_context") == nullptr), "Failed to query EGL_KHR_surfaceless_context");
ARM_COMPUTE_UNUSED(egl_extension_st);
const EGLint config_attribs[] =
{
EGL_RENDERABLE_TYPE, EGL_OPENGL_ES3_BIT_KHR,
EGL_NONE
};
EGLConfig cfg;
EGLint count;
res = eglChooseConfig(_display, config_attribs, &cfg, 1, &count);
ARM_COMPUTE_ERROR_ON_MSG(res == EGL_FALSE, "Failed to choose config: 0x%x.", eglGetError());
ARM_COMPUTE_UNUSED(res);
res = eglBindAPI(EGL_OPENGL_ES_API);
ARM_COMPUTE_ERROR_ON_MSG(res == EGL_FALSE, "Failed to bind api: 0x%x.", eglGetError());
const EGLint attribs[] =
{
EGL_CONTEXT_CLIENT_VERSION, 3,
EGL_NONE
};
_context = eglCreateContext(_display,
cfg,
EGL_NO_CONTEXT,
attribs);
ARM_COMPUTE_ERROR_ON_MSG(_context == EGL_NO_CONTEXT, "Failed to create context: 0x%x.", eglGetError());
ARM_COMPUTE_UNUSED(res);
res = eglMakeCurrent(_display, EGL_NO_SURFACE, EGL_NO_SURFACE, _context);
ARM_COMPUTE_ERROR_ON_MSG(res == EGL_FALSE, "Failed to make current: 0x%x.", eglGetError());
ARM_COMPUTE_UNUSED(res);
}
void GCKernelLibrary::setup_dummy_fbo()
{
ARM_COMPUTE_GL_CHECK(glGenFramebuffers(1, &_frame_buffer));
ARM_COMPUTE_GL_CHECK(glBindFramebuffer(GL_FRAMEBUFFER, _frame_buffer));
ARM_COMPUTE_GL_CHECK(glGenTextures(1, &_tex_rt));
ARM_COMPUTE_GL_CHECK(glBindTexture(GL_TEXTURE_2D, _tex_rt));
ARM_COMPUTE_GL_CHECK(glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, 1, 1, 0, GL_RGB, GL_UNSIGNED_BYTE, nullptr));
ARM_COMPUTE_GL_CHECK(glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, _tex_rt, 0));
}
GCKernelLibrary::~GCKernelLibrary()
{
for(auto &program : _built_programs_map)
{
static_cast<GCKernel>(program.second).cleanup();
}
ARM_COMPUTE_GL_CHECK(glBindTexture(GL_TEXTURE_2D, 0));
ARM_COMPUTE_GL_CHECK(glBindFramebuffer(GL_FRAMEBUFFER, 0));
ARM_COMPUTE_GL_CHECK(glDeleteTextures(1, &_tex_rt));
ARM_COMPUTE_GL_CHECK(glDeleteFramebuffers(1, &_frame_buffer));
if(_own_context)
{
eglDestroyContext(_display, _context);
eglTerminate(_display);
_context = EGL_NO_CONTEXT;
_display = EGL_NO_DISPLAY;
}
}
std::string GCKernelLibrary::stringify_set(const StringSet &s) const
{
std::string concat_set;
// Concatenate set
for(const auto &el : s)
{
concat_set += el + "\n";
}
return concat_set;
}