Files
rocm-systems/rocclr/runtime/platform/program.cpp
T
foreman 50ad4d1a7f P4 to Git Change 2016080 by gandryey@gera-win10 on 2019/10/18 13:08:03
SWDEV-204511 - [NV14 XTM] OpenCL Conformance Test Fails
	- Handle different ABI versions for LC and HSAIL if single context with multiple devices was used. LC changed the locaiton of hidden arguments and HSAIL path requires patching

Affected files ...

... //depot/stg/opencl/drivers/opencl/runtime/device/devkernel.cpp#26 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/pal/palkernel.cpp#83 edit
... //depot/stg/opencl/drivers/opencl/runtime/device/pal/palkernel.hpp#30 edit
... //depot/stg/opencl/drivers/opencl/runtime/platform/kernel.hpp#26 edit
... //depot/stg/opencl/drivers/opencl/runtime/platform/program.cpp#105 edit
2019-10-18 13:20:55 -04:00

655 righe
20 KiB
C++

//
// Copyright (c) 2008 Advanced Micro Devices, Inc. All rights reserved.
//
#include "top.hpp"
#include "device/appprofile.hpp"
#include "platform/program.hpp"
#include "platform/context.hpp"
#include "utils/options.hpp"
#include "utils/libUtils.h"
#include "utils/bif_section_labels.hpp"
#include "acl.h"
#include <cstdlib> // for malloc
#include <cstring> // for strcmp
#include <sstream>
#include <fstream>
#include <iostream>
#include <utility>
namespace amd {
static void remove_g_option(std::string &option)
{
// Remove " -g " option from application.
// People can still add -g in AMD_OCL_BUILD_OPTIONS_APPEND, if it is so desired.
std::string g_str("-g");
std::size_t g_pos = 0;
while ((g_pos = option.find(g_str, g_pos)) != std::string::npos) {
if ((g_pos == 0 || option[g_pos - 1] == ' ') &&
(g_pos + 2 == option.size() || option[g_pos + 2] == ' ')) {
option.erase(g_pos, g_str.size());
} else {
g_pos += g_str.size();
}
}
return;
}
Program::~Program() {
// Destroy all device programs
for (const auto& it : devicePrograms_) {
delete it.second;
}
for (const auto& it : binary_) {
const binary_t& Bin = it.second;
if (Bin.first) {
delete[] Bin.first;
}
}
delete symbolTable_;
//! @todo Make sure we have destroyed all CPU specific objects
}
const Symbol* Program::findSymbol(const char* kernelName) const {
// avoid seg. fault if the program has not built yet
if (symbolTable_ == NULL) {
return NULL;
}
const auto it = symbolTable_->find(kernelName);
return (it == symbolTable_->cend()) ? NULL : &it->second;
}
cl_int Program::addDeviceProgram(Device& device, const void* image, size_t length,
amd::option::Options* options) {
if (image != NULL && !amd::isElfMagic((const char*)image)) {
if (device.settings().useLightning_) {
return CL_INVALID_BINARY;
}
#if defined(WITH_COMPILER_LIB)
else if (!aclValidateBinaryImage(
image, length, language_ == SPIRV ? BINARY_TYPE_SPIRV : BINARY_TYPE_ELF | BINARY_TYPE_LLVM)) {
return CL_INVALID_BINARY;
}
#endif // !defined(WITH_COMPILER_LIB)
}
// Check if the device is already associated with this program
if (deviceList_.find(&device) != deviceList_.end()) {
return CL_INVALID_VALUE;
}
Device& rootDev = device;
// if the rootDev is already associated with a program
if (devicePrograms_[&rootDev] != NULL) {
return CL_SUCCESS;
}
bool emptyOptions = false;
amd::option::Options emptyOpts;
if (options == NULL) {
options = &emptyOpts;
emptyOptions = true;
}
#if defined(WITH_COMPILER_LIB)
if (image != NULL && length != 0 && aclValidateBinaryImage(image, length, BINARY_TYPE_ELF)) {
acl_error errorCode;
aclBinary* binary = aclReadFromMem(image, length, &errorCode);
if (errorCode != ACL_SUCCESS) {
return CL_INVALID_BINARY;
}
const oclBIFSymbolStruct* symbol = findBIF30SymStruct(symOpenclCompilerOptions);
assert(symbol && "symbol not found");
std::string symName = std::string(symbol->str[bif::PRE]) + std::string(symbol->str[bif::POST]);
size_t symSize = 0;
const void* opts = aclExtractSymbol(device.binCompiler(), binary, &symSize, aclCOMMENT,
symName.c_str(), &errorCode);
// if we have options from binary and input options was not specified
if (opts != NULL && emptyOptions) {
std::string sBinOptions = std::string((char*)opts, symSize);
if (!amd::option::parseAllOptions(sBinOptions, *options, false, false)) {
programLog_ = options->optionsLog();
LogError("Parsing compilation options from binary failed.");
return CL_INVALID_COMPILER_OPTIONS;
}
}
options->oVariables->Legacy = !device.settings().useLightning_ ?
isAMDILTarget(*aclutGetTargetInfo(binary)) :
isHSAILTarget(*aclutGetTargetInfo(binary));
aclBinaryFini(binary);
}
#endif // defined(WITH_COMPILER_LIB)
options->oVariables->BinaryIsSpirv = language_ == SPIRV;
device::Program* program = rootDev.createProgram(*this, options);
if (program == NULL) {
return CL_OUT_OF_HOST_MEMORY;
}
if (image != NULL) {
uint8_t* memory = binary(rootDev).first;
// clone 'binary' (it is owned by the host thread).
if (memory == NULL) {
memory = new (std::nothrow) uint8_t[length];
if (memory == NULL) {
delete program;
return CL_OUT_OF_HOST_MEMORY;
}
::memcpy(memory, image, length);
// Save the original image
binary_[&rootDev] = std::make_pair(memory, length);
}
if (!program->setBinary(reinterpret_cast<char*>(memory), length)) {
delete program;
return CL_INVALID_BINARY;
}
#if 0 && defined(WITH_LIGHTNING_COMPILER)
// load the compiler options from the binary if it is not provided
std::string sBinOptions = program->compileOptions();
if (!sBinOptions.empty() && emptyOptions) {
if (!amd::option::parseAllOptions(sBinOptions, *options, false,
device.settings().useLightning_)) {
programLog_ = options->optionsLog();
LogError("Parsing compilation options from binary failed.");
return CL_INVALID_COMPILER_OPTIONS;
}
}
#endif // defined(WITH_LIGHTNING_COMPILER)
}
devicePrograms_[&rootDev] = program;
deviceList_.insert(&device);
return CL_SUCCESS;
}
device::Program* Program::getDeviceProgram(const Device& device) const {
const auto it = devicePrograms_.find(&device);
if (it == devicePrograms_.cend()) {
return NULL;
}
return it->second;
}
Monitor Program::buildLock_("OCL build program", true);
cl_int Program::compile(const std::vector<Device*>& devices, size_t numHeaders,
const std::vector<const Program*>& headerPrograms,
const char** headerIncludeNames, const char* options,
void(CL_CALLBACK* notifyFptr)(cl_program, void*), void* data,
bool optionChangable) {
ScopedLock sl(buildLock_);
cl_int retval = CL_SUCCESS;
// Clear the program object
clear();
// Process build options.
std::string cppstr(options ? options : "");
// if there is a -ignore-env, adjust options.
if (cppstr.size() > 0) {
// Set the options to be the string after -ignore-env
size_t pos = cppstr.find("-ignore-env");
if (pos != std::string::npos) {
cppstr = cppstr.substr(pos + sizeof("-ignore-env"));
optionChangable = false;
}
remove_g_option(cppstr);
}
std::vector<const std::string*> headers(numHeaders);
for (size_t i = 0; i < numHeaders; ++i) {
const std::string& header = headerPrograms[i]->sourceCode();
headers[i] = &header;
}
// Compile the program programs associated with the given devices.
for (const auto& it : devices) {
option::Options parsedOptions;
constexpr bool LinkOptsOnly = false;
if (!ParseAllOptions(cppstr, parsedOptions, optionChangable, LinkOptsOnly,
it->settings().useLightning_)) {
programLog_ = parsedOptions.optionsLog();
LogError("Parsing compile options failed.");
return CL_INVALID_COMPILER_OPTIONS;
}
device::Program* devProgram = getDeviceProgram(*it);
if (devProgram == NULL) {
const binary_t& bin = binary(*it);
retval = addDeviceProgram(*it, bin.first, bin.second, &parsedOptions);
if (retval != CL_SUCCESS) {
return retval;
}
devProgram = getDeviceProgram(*it);
}
if (devProgram->type() == device::Program::TYPE_INTERMEDIATE || language_ == SPIRV) {
continue;
}
// We only build a Device-Program once
if (devProgram->buildStatus() != CL_BUILD_NONE) {
continue;
}
if (sourceCode_.empty()) {
return CL_INVALID_OPERATION;
}
cl_int result =
devProgram->compile(sourceCode_, headers, headerIncludeNames, options, &parsedOptions);
// Check if the previous device failed a build
if ((result != CL_SUCCESS) && (retval != CL_SUCCESS)) {
retval = CL_INVALID_OPERATION;
}
// Update the returned value with a build error
else if (result != CL_SUCCESS) {
retval = result;
}
}
if (notifyFptr != NULL) {
notifyFptr(as_cl(this), data);
}
return retval;
}
cl_int Program::link(const std::vector<Device*>& devices, size_t numInputs,
const std::vector<Program*>& inputPrograms, const char* options,
void(CL_CALLBACK* notifyFptr)(cl_program, void*), void* data,
bool optionChangable) {
ScopedLock sl(buildLock_);
cl_int retval = CL_SUCCESS;
if (symbolTable_ == NULL) {
symbolTable_ = new symbols_t;
if (symbolTable_ == NULL) {
return CL_OUT_OF_HOST_MEMORY;
}
}
// Clear the program object
clear();
// Process build options.
std::string cppstr(options ? options : "");
// if there is a -ignore-env, adjust options.
if (cppstr.size() > 0) {
// Set the options to be the string after -ignore-env
size_t pos = cppstr.find("-ignore-env");
if (pos != std::string::npos) {
cppstr = cppstr.substr(pos + sizeof("-ignore-env"));
optionChangable = false;
}
remove_g_option(cppstr);
}
// Link the program programs associated with the given devices.
for (const auto& it : devices) {
option::Options parsedOptions;
constexpr bool LinkOptsOnly = true;
if (!ParseAllOptions(cppstr, parsedOptions, optionChangable, LinkOptsOnly,
it->settings().useLightning_)) {
programLog_ = parsedOptions.optionsLog();
LogError("Parsing link options failed.");
return CL_INVALID_LINKER_OPTIONS;
}
// find the corresponding device program in each input program
std::vector<device::Program*> inputDevPrograms(numInputs);
bool found = false;
for (size_t i = 0; i < numInputs; ++i) {
Program& inputProgram = *inputPrograms[i];
if (inputProgram.language_ == SPIRV) {
parsedOptions.oVariables->BinaryIsSpirv = true;
}
deviceprograms_t inputDevProgs = inputProgram.devicePrograms();
const auto findIt = inputDevProgs.find(it);
if (findIt == inputDevProgs.cend()) {
if (found) break;
continue;
}
inputDevPrograms[i] = findIt->second;
device::Program::binary_t binary = inputDevPrograms[i]->binary();
// Check the binary's target for the first found device program.
// TODO: Revise these binary's target checks
// and possibly remove them after switching to HSAIL by default.
#if defined(WITH_COMPILER_LIB)
if (!found && binary.first != NULL && binary.second > 0 &&
aclValidateBinaryImage(binary.first, binary.second, BINARY_TYPE_ELF)) {
acl_error errorCode = ACL_SUCCESS;
void* mem = const_cast<void*>(binary.first);
aclBinary* aclBin = aclReadFromMem(mem, binary.second, &errorCode);
if (errorCode != ACL_SUCCESS) {
LogWarning("Error while linking: Could not read from raw binary.");
return CL_INVALID_BINARY;
}
if (isHSAILTarget(*aclutGetTargetInfo(aclBin))) {
parsedOptions.oVariables->Frontend = "clang";
parsedOptions.oVariables->Legacy = it->settings().useLightning_;
} else if (isAMDILTarget(*aclutGetTargetInfo(aclBin))) {
parsedOptions.oVariables->Frontend = "edg";
}
aclBinaryFini(aclBin);
}
#endif // defined(WITH_COMPILER_LIB)
found = true;
}
if (inputDevPrograms.size() == 0) {
continue;
}
if (inputDevPrograms.size() < numInputs) {
return CL_INVALID_VALUE;
}
device::Program* devProgram = getDeviceProgram(*it);
if (devProgram == NULL) {
const binary_t& bin = binary(*it);
retval = addDeviceProgram(*it, bin.first, bin.second, &parsedOptions);
if (retval != CL_SUCCESS) {
return retval;
}
devProgram = getDeviceProgram(*it);
}
// We only build a Device-Program once
if (devProgram->buildStatus() != CL_BUILD_NONE) {
continue;
}
cl_int result = devProgram->link(inputDevPrograms, options, &parsedOptions);
// Check if the previous device failed a build
if ((result != CL_SUCCESS) && (retval != CL_SUCCESS)) {
retval = CL_INVALID_OPERATION;
}
// Update the returned value with a build error
else if (result != CL_SUCCESS) {
retval = result;
}
}
if (retval != CL_SUCCESS) {
return retval;
}
// Rebuild the symbol table
for (const auto& sit : devicePrograms_) {
const Device& device = *(sit.first);
const device::Program& program = *(sit.second);
const device::Program::kernels_t& kernels = program.kernels();
for (const auto& it : kernels) {
const std::string& name = it.first;
const device::Kernel* devKernel = it.second;
Symbol& symbol = (*symbolTable_)[name];
if (!symbol.setDeviceKernel(device, devKernel)) {
retval = CL_LINK_PROGRAM_FAILURE;
}
}
}
// Create a string with all kernel names from the program
if (kernelNames_.length() == 0) {
for (auto it = symbols().cbegin(); it != symbols().cend(); ++it) {
if (it != symbols().cbegin()) {
kernelNames_.append(1, ';');
}
kernelNames_.append(it->first.c_str());
}
}
if (notifyFptr != NULL) {
notifyFptr(as_cl(this), data);
}
return retval;
}
void Program::StubProgramSource(const std::string& app_name) {
static uint program_counter = 0;
std::fstream stub_read;
std::stringstream file_name;
std::string app_name_no_ext;
std::size_t length = app_name.rfind(".exe");
if (length == std::string::npos) {
length = app_name.size();
}
app_name_no_ext.assign(app_name.c_str(), length);
// Construct a unique file name for the CL program
file_name << app_name_no_ext << "_program_" << program_counter << ".cl";
stub_read.open(file_name.str().c_str(), (std::fstream::in | std::fstream::binary));
// Check if we have OpenCL program
if (stub_read.is_open()) {
// Find the stream size
stub_read.seekg(0, std::fstream::end);
size_t size = stub_read.tellg();
stub_read.seekg(0, std::ios::beg);
char* data = new char[size];
stub_read.read(data, size);
stub_read.close();
sourceCode_.assign(data, size);
delete[] data;
} else {
std::fstream stub_write;
stub_write.open(file_name.str().c_str(), (std::fstream::out | std::fstream::binary));
stub_write << sourceCode_;
stub_write.close();
}
program_counter++;
}
cl_int Program::build(const std::vector<Device*>& devices, const char* options,
void(CL_CALLBACK* notifyFptr)(cl_program, void*), void* data,
bool optionChangable) {
ScopedLock sl(buildLock_);
cl_int retval = CL_SUCCESS;
if (symbolTable_ == NULL) {
symbolTable_ = new symbols_t;
if (symbolTable_ == NULL) {
return CL_OUT_OF_HOST_MEMORY;
}
}
if (OCL_STUB_PROGRAMS && !sourceCode_.empty()) {
// The app name should be the samme for all device
StubProgramSource(devices[0]->appProfile()->appFileName());
}
// Clear the program object
clear();
// Process build options.
std::string cppstr(options ? options : "");
// if there is a -ignore-env, adjust options.
if (cppstr.size() > 0) {
// Set the options to be the string after -ignore-env
size_t pos = cppstr.find("-ignore-env");
if (pos != std::string::npos) {
cppstr = cppstr.substr(pos + sizeof("-ignore-env"));
optionChangable = false;
}
remove_g_option(cppstr);
}
// Build the program programs associated with the given devices.
for (const auto& it : devices) {
option::Options parsedOptions;
constexpr bool LinkOptsOnly = false;
if (!ParseAllOptions(cppstr, parsedOptions, optionChangable, LinkOptsOnly,
it->settings().useLightning_)) {
programLog_ = parsedOptions.optionsLog();
LogError("Parsing compile options failed.");
return CL_INVALID_COMPILER_OPTIONS;
}
device::Program* devProgram = getDeviceProgram(*it);
if (devProgram == NULL) {
const binary_t& bin = binary(*it);
if (sourceCode_.empty() && (bin.first == NULL)) {
retval = false;
continue;
}
retval = addDeviceProgram(*it, bin.first, bin.second, &parsedOptions);
if (retval != CL_SUCCESS) {
return retval;
}
devProgram = getDeviceProgram(*it);
}
parsedOptions.oVariables->AssumeAlias = true;
if (language_ == Assembly) {
constexpr char asmLang[] = "asm";
parsedOptions.oVariables->XLang = asmLang;
}
// We only build a Device-Program once
if (devProgram->buildStatus() != CL_BUILD_NONE) {
continue;
}
cl_int result = devProgram->build(sourceCode_, options, &parsedOptions);
// Check if the previous device failed a build
if ((result != CL_SUCCESS) && (retval != CL_SUCCESS)) {
retval = CL_INVALID_OPERATION;
}
// Update the returned value with a build error
else if (result != CL_SUCCESS) {
retval = result;
}
}
if (retval != CL_SUCCESS) {
return retval;
}
// Rebuild the symbol table
for (const auto& it : devicePrograms_) {
const Device& device = *(it.first);
const device::Program& program = *(it.second);
const device::Program::kernels_t& kernels = program.kernels();
for (const auto& kit : kernels) {
const std::string& name = kit.first;
const device::Kernel* devKernel = kit.second;
Symbol& symbol = (*symbolTable_)[name];
if (!symbol.setDeviceKernel(device, devKernel)) {
retval = CL_BUILD_PROGRAM_FAILURE;
}
}
}
// Create a string with all kernel names from the program
if (kernelNames_.length() == 0) {
for (auto it = symbols().cbegin(); it != symbols().cend(); ++it) {
if (it != symbols().cbegin()) {
kernelNames_.append(1, ';');
}
kernelNames_.append(it->first.c_str());
}
}
if (notifyFptr != NULL) {
notifyFptr(as_cl(this), data);
}
return retval;
}
void Program::clear() {
// Destroy old programs if we have any
for (const auto& it : devicePrograms_) {
// Destroy device program
delete it.second;
}
devicePrograms_.clear();
deviceList_.clear();
if (symbolTable_) symbolTable_->clear();
kernelNames_.clear();
}
int Program::GetOclCVersion(const char* clVer) {
// default version
int version = 12;
if (clVer == NULL) {
return version;
}
std::string clStd(clVer);
if (clStd.size() != 5) {
return version;
}
clStd.erase(0, 2);
clStd.erase(1, 1);
return std::stoi(clStd);
}
bool Program::ParseAllOptions(const std::string& options, option::Options& parsedOptions,
bool optionChangable, bool linkOptsOnly, bool isLC) {
std::string allOpts = options;
if (optionChangable) {
if (linkOptsOnly) {
if (AMD_OCL_LINK_OPTIONS != NULL) {
allOpts.append(" ");
allOpts.append(AMD_OCL_LINK_OPTIONS);
}
if (AMD_OCL_LINK_OPTIONS_APPEND != NULL) {
allOpts.append(" ");
allOpts.append(AMD_OCL_LINK_OPTIONS_APPEND);
}
} else {
if (AMD_OCL_BUILD_OPTIONS != NULL) {
allOpts.append(" ");
allOpts.append(AMD_OCL_BUILD_OPTIONS);
}
if (!Device::appProfile()->GetBuildOptsAppend().empty()) {
allOpts.append(" ");
allOpts.append(Device::appProfile()->GetBuildOptsAppend());
}
if (AMD_OCL_BUILD_OPTIONS_APPEND != NULL) {
allOpts.append(" ");
allOpts.append(AMD_OCL_BUILD_OPTIONS_APPEND);
}
}
}
return amd::option::parseAllOptions(allOpts, parsedOptions, linkOptsOnly, isLC);
}
bool Symbol::setDeviceKernel(const Device& device, const device::Kernel* func) {
if (deviceKernels_.size() == 0 ||
// Always pick the most recent version in MGPU case
(func->signature().version() > signature_.version())) {
signature_ = func->signature();
}
deviceKernels_[&device] = func;
return true;
}
const device::Kernel* Symbol::getDeviceKernel(const Device& device) const {
auto it = deviceKernels_.find(&device);
if (it != deviceKernels_.cend()) {
return it->second;
}
return nullptr;
}
} // namespace amd