/* Copyright (c) 2023 - 2024 Advanced Micro Devices, Inc. All rights reserved. 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 "hip_fatbin.hpp" #include #include "hip_code_object.hpp" #include "hip_platform.hpp" #include "comgrctx.hpp" namespace hip { FatBinaryDeviceInfo::~FatBinaryDeviceInfo() { if (program_ != nullptr) { program_->unload(); program_->release(); program_ = nullptr; } } FatBinaryInfo::FatBinaryInfo(const char* fname, const void* image) : fdesc_(amd::Os::FDescInit()), fsize_(0), foffset_(0), image_(image), image_mapped_(false), uri_(std::string()) { if (fname != nullptr) { fname_ = std::string(fname); } else { fname_ = std::string(); } fatbin_dev_info_.resize(g_devices.size(), nullptr); } FatBinaryInfo::~FatBinaryInfo() { // Different devices in the same model have the same binary_image_ std::set toDelete; // Release per device fat bin info. for (auto* fbd : fatbin_dev_info_) { if (fbd != nullptr) { if (fbd->binary_image_ && fbd->binary_offset_ == 0 && fbd->binary_image_ != image_) { toDelete.insert(fbd->binary_image_); } delete fbd; } } for (auto itemData : toDelete) { LogPrintfInfo("~FatBinaryInfo(%p) will delete binary_image_ %p", this, itemData); delete[] reinterpret_cast(itemData); } if (!HIP_USE_RUNTIME_UNBUNDLER) { // Using COMGR Unbundler if (ufd_ && amd::Os::isValidFileDesc(ufd_->fdesc_)) { // Check for ufd_ != nullptr, since sometimes, we never create unique_file_desc. if (ufd_->fsize_ && image_mapped_ && !amd::Os::MemoryUnmapFile(image_, ufd_->fsize_)) { LogPrintfError("Cannot unmap file for fdesc: %d fsize: %d", ufd_->fdesc_, ufd_->fsize_); assert(false); } if (!PlatformState::instance().CloseUniqueFileHandle(ufd_)) { LogPrintfError("Cannot close file for fdesc: %d", ufd_->fdesc_); assert(false); } } fname_ = std::string(); fdesc_ = amd::Os::FDescInit(); fsize_ = 0; image_ = nullptr; uri_ = std::string(); } else { // Using Runtime Unbundler if (amd::Os::isValidFileDesc(fdesc_)) { if (fsize_ && !amd::Os::MemoryUnmapFile(image_, fsize_)) { LogPrintfError("Cannot unmap file for fdesc: %d fsize: %d", fdesc_, fsize_); assert(false); } if (!amd::Os::CloseFileHandle(fdesc_)) { LogPrintfError("Cannot close file for fdesc: %d", fdesc_); assert(false); } } fname_ = std::string(); fdesc_ = amd::Os::FDescInit(); fsize_ = 0; image_ = nullptr; uri_ = std::string(); } } void ListAllDeviceWithNoCOFromBundle( const std::unordered_map>& unique_isa_names) { LogError("Missing CO for these ISAs - "); for (const auto& unique_isa : unique_isa_names) { if (unique_isa.second.first == 0) { LogPrintfError(" %s", unique_isa.first.c_str()); } } } hipError_t FatBinaryInfo::ExtractFatBinaryUsingCOMGR(const std::vector& devices, bool &containGenericTarget) { amd_comgr_data_t data_object {0}; amd_comgr_status_t comgr_status = AMD_COMGR_STATUS_SUCCESS; hipError_t hip_status = hipSuccess; // If image was passed as a pointer to our hipMod* api, we can try to extract the file name // if it was mapped by the app. Otherwise use the COMGR data API. if (fname_.size() == 0) { if (image_ == nullptr) { LogError("Both Filename and image cannot be null"); return hipErrorInvalidValue; } if (!amd::Os::FindFileNameFromAddress(image_, &fname_, &foffset_)) { fname_ = std::string(""); foffset_ = 0; } } // If file name & path are available (or it is passed to you), then get the file desc to use // COMGR file slice APIs. if (fname_.size() > 0) { // Get File Handle & size of the file. ufd_ = PlatformState::instance().GetUniqueFileHandle(fname_.c_str()); if (ufd_ == nullptr) { return hipErrorFileNotFound; } // If the file name exists but the file size is 0, the something wrong with the file or its path if (ufd_->fsize_ == 0) { return hipErrorInvalidValue; } // If image_ is nullptr, then file path is passed via hipMod* APIs, so map the file. if (image_ == nullptr) { if (!amd::Os::MemoryMapFileDesc(ufd_->fdesc_, ufd_->fsize_, foffset_, &image_)) { LogError("Cannot map the file descriptor"); PlatformState::instance().CloseUniqueFileHandle(ufd_); return hipErrorInvalidValue; } image_mapped_ = true; } } // At this line, image should be a valid ptr. guarantee(image_ != nullptr, "Image cannot be nullptr, file:%s did not map for some reason", fname_.c_str()); do { bool isCompressed = false; // If the image ptr is not clang offload bundle then just directly point the image. if (!CodeObject::IsClangOffloadMagicBundle(image_, isCompressed)) { for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { uint64_t elf_size = CodeObject::ElfSize(image_); if (elf_size == 0) { hip_status = hipErrorInvalidImage; break; } fatbin_dev_info_[devices[dev_idx]->deviceId()] = new FatBinaryDeviceInfo(image_, elf_size, 0); fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ = new amd::Program(*devices[dev_idx]->asContext()); if (fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ == nullptr) { hip_status = hipErrorOutOfMemory; break; } } break; } if (!isCompressed) { if (CodeObject::containGenericTarget(image_)) { LogInfo("offload bundle contains generic target code object"); containGenericTarget = true; return hipErrorNoBinaryForGpu; // This path doesn't support generic target } } if (isCompressed || HIP_ALWAYS_USE_NEW_COMGR_UNBUNDLING_ACTION) { size_t major = 0, minor = 0; amd::Comgr::get_version(&major, &minor); if (major >= 2 && minor >= 8) { hip_status = ExtractFatBinaryUsingCOMGR(image_, devices); break; } else if (isCompressed) { LogPrintfError("comgr %zu.%zu cannot support commpressed mode which need comgr 2.8+", major, minor); hip_status = hipErrorNotSupported; break; } else if (HIP_ALWAYS_USE_NEW_COMGR_UNBUNDLING_ACTION) { HIP_ALWAYS_USE_NEW_COMGR_UNBUNDLING_ACTION = false; LogInfo("HIP_ALWAYS_USE_NEW_COMGR_UNBUNDLING_ACTION = true only works on comgr 2.8+"); } } // Create a data object, if it fails return error if ((comgr_status = amd::Comgr::create_data(AMD_COMGR_DATA_KIND_FATBIN, &data_object)) != AMD_COMGR_STATUS_SUCCESS) { LogPrintfError("Creating data object failed with status %d ", comgr_status); hip_status = hipErrorInvalidValue; break; } #if !defined(_WIN32) // Using the file descriptor and file size, map the data object. if (amd::Os::isValidFileDesc(fdesc_)) { guarantee(fsize_ > 0, "Cannot have a file size of 0, fdesc: %d fname: %s", fdesc_, fname_.c_str()); if ((comgr_status = amd::Comgr::set_data_from_file_slice( data_object, fdesc_, foffset_, fsize_)) != AMD_COMGR_STATUS_SUCCESS) { LogPrintfError("Setting data from file slice failed with status %d ", comgr_status); hip_status = hipErrorInvalidValue; break; } } else #endif if (image_ != nullptr) { // Using the image ptr, map the data object. if ((comgr_status = amd::Comgr::set_data(data_object, 4096, reinterpret_cast(image_))) != AMD_COMGR_STATUS_SUCCESS) { LogPrintfError("Setting data from file slice failed with status %d ", comgr_status); hip_status = hipErrorInvalidValue; break; } } else { guarantee(false, "Cannot have both fname_ and image_ as nullptr"); } // Find the unique number of ISAs needed for this COMGR query. std::unordered_map> unique_isa_names; for (auto device : devices) { std::string device_name = device->devices()[0]->isa().isaName(); unique_isa_names.insert({device_name, std::make_pair(0, 0)}); } // Add the spirv target const std::string spirv_isa_name = "spirv64-amd-amdhsa--amdgcnspirv"; unique_isa_names.insert({spirv_isa_name, std::make_pair(0, 0)}); // Create a query list using COMGR info for unique ISAs. std::vector query_list_array; query_list_array.reserve(unique_isa_names.size()); for (const auto& isa_name : unique_isa_names) { auto& item = query_list_array.emplace_back(); item.isa = isa_name.first.c_str(); item.size = 0; item.offset = 0; } // Look up the code object info passing the query list. if ((comgr_status = amd::Comgr::lookup_code_object(data_object, query_list_array.data(), unique_isa_names.size())) != AMD_COMGR_STATUS_SUCCESS) { LogPrintfError("Setting data from file slice failed with status %d ", comgr_status); hip_status = hipErrorInvalidValue; break; } for (const auto& item : query_list_array) { auto unique_it = unique_isa_names.find(item.isa); guarantee(unique_isa_names.cend() != unique_it, "Cannot find unique isa "); unique_it->second = std::pair(static_cast(item.size), static_cast(item.offset)); } // if we have SPIRV isa, we will use Comgr to create isa for all devices. auto spirv_isa_handle = unique_isa_names.find(spirv_isa_name); bool spirv_isa_found = spirv_isa_handle->second.first != 0; if (!spirv_isa_found) { for (auto device : devices) { std::string device_name = device->devices()[0]->isa().isaName(); auto dev_it = unique_isa_names.find(device_name); // If the size is 0, then Comgr API could not find the CO for this GPU device/ISA if (dev_it->second.first == 0) { LogPrintfError("Cannot find CO in the bundle %s for ISA: %s", fname_.c_str(), device_name.c_str()); hip_status = hipErrorNoBinaryForGpu; ListAllDeviceWithNoCOFromBundle(unique_isa_names); break; } guarantee(unique_isa_names.cend() != dev_it, "Cannot find the device name in the unique device name"); fatbin_dev_info_[device->deviceId()] = new FatBinaryDeviceInfo( reinterpret_cast
(const_cast(image_)) + dev_it->second.second, dev_it->second.first, dev_it->second.second); fatbin_dev_info_[device->deviceId()]->program_ = new amd::Program(*(device->asContext())); } } else { LogPrintfDebug("%s", "SPIRV isa found"); amd_comgr_data_set_t spirv_data_set, bc_data_set; amd_comgr_data_t spirv_data; amd_comgr_action_info_t action; if (comgr_status = amd::Comgr::create_data_set(&spirv_data_set); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to create SPIRV Data set"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::create_data(AMD_COMGR_DATA_KIND_SPIRV, &spirv_data); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to create SPIRV Data"); amd::Comgr::destroy_data_set(spirv_data_set); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::set_data(spirv_data, spirv_isa_handle->second.first /* size */, reinterpret_cast(const_cast(image_)) + spirv_isa_handle->second.second /* buffer */); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to assign data in comgr"); (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::set_data_name(spirv_data, "hip_code_object.spv"); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to set data name"); (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::data_set_add(spirv_data_set, spirv_data); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to add spir data"); (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::create_action_info(&action); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to create action"); (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::create_data_set(&bc_data_set); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to create bitcode data set"); (void)amd::Comgr::destroy_action_info(action); (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::do_action(AMD_COMGR_ACTION_TRANSLATE_SPIRV_TO_BC, action, spirv_data_set, bc_data_set); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to compile to ll"); (void)amd::Comgr::destroy_action_info(action); (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); (void)amd::Comgr::destroy_data_set(bc_data_set); return hipErrorInvalidValue; } (void)amd::Comgr::release_data(spirv_data); (void)amd::Comgr::destroy_data_set(spirv_data_set); (void)amd::Comgr::destroy_action_info(action); for (auto device : devices) { LogPrintfInfo("Creating ISA for: %s from spir-v", device->devices()[0]->isa().targetId()); amd_comgr_action_info_t reloc_action; std::string isa = std::string{"amdgcn-amd-amdhsa--"} + device->devices()[0]->isa().targetId(); if (comgr_status = amd::Comgr::create_action_info(&reloc_action); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to create action"); return hipErrorInvalidValue; } // TODO: do this for all devices if (comgr_status = amd::Comgr::action_info_set_isa_name(reloc_action, isa.c_str()); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to set ISA name"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::action_info_set_device_lib_linking(reloc_action, true); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to set device lib linking"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::action_info_set_option_list( reloc_action, nullptr /* options list */, 0 /* options size */); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to set option list"); return hipErrorInvalidValue; } amd_comgr_data_set_t reloc_data; if (comgr_status = amd::Comgr::create_data_set(&reloc_data); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to create reloc data set"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::do_action(AMD_COMGR_ACTION_CODEGEN_BC_TO_RELOCATABLE, reloc_action, bc_data_set, reloc_data); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to compile to reloc"); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to do action: codegen bc ot reloc"); return hipErrorInvalidValue; } amd_comgr_action_info_t exe_action; amd_comgr_data_set_t exe_output; if (comgr_status = amd::Comgr::create_action_info(&exe_action); comgr_status != AMD_COMGR_STATUS_SUCCESS) { LogError("Failed to create action"); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to create exe action"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::action_info_set_isa_name(exe_action, isa.c_str()); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to set exe action isa name"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::create_data_set(&exe_output); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to create exe output"); return hipErrorInvalidValue; } if (comgr_status = amd::Comgr::do_action(AMD_COMGR_ACTION_LINK_RELOCATABLE_TO_EXECUTABLE, exe_action, reloc_data, exe_output); comgr_status != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(exe_output); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to do action: reloc to exe"); return hipErrorInvalidValue; } amd_comgr_data_t exe_data; if (auto res = amd::Comgr::action_data_get_data(exe_output, AMD_COMGR_DATA_KIND_EXECUTABLE, 0, &exe_data); res != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(exe_output); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to action get exe data"); return hipErrorInvalidValue; } size_t co_size; if (auto res = amd::Comgr::get_data(exe_data, &co_size, NULL); res != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(exe_output); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to get exe size"); return hipErrorInvalidValue; } char* co = new char[co_size]; if (auto res = amd::Comgr::get_data(exe_data, &co_size, co); res != AMD_COMGR_STATUS_SUCCESS) { (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(exe_output); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); LogError("Failed to get exe data"); return hipErrorInvalidValue; } fatbin_dev_info_[device->deviceId()] = new FatBinaryDeviceInfo(co, CodeObject::ElfSize(co), 0); fatbin_dev_info_[device->deviceId()]->program_ = new amd::Program(*(device->asContext())); // cleanup (void)amd::Comgr::release_data(exe_data); (void)amd::Comgr::destroy_action_info(exe_action); (void)amd::Comgr::destroy_action_info(reloc_action); (void)amd::Comgr::destroy_data_set(exe_output); (void)amd::Comgr::destroy_data_set(reloc_data); (void)amd::Comgr::destroy_data_set(bc_data_set); } } } while (0); // Clean up file and memory resouces if hip_status failed for some reason. if (hip_status != hipSuccess && hip_status != hipErrorInvalidKernelFile) { if (image_mapped_) { if (!amd::Os::MemoryUnmapFile(image_, ufd_->fsize_)) guarantee(false, "Cannot unmap the file"); image_ = nullptr; image_mapped_ = false; } if (amd::Os::isValidFileDesc(fdesc_)) { guarantee(fsize_ > 0, "Size has to greater than 0 too"); if (!amd::Os::CloseFileHandle(fdesc_)) guarantee(false, "Cannot close the file handle"); fdesc_ = 0; fsize_ = 0; } } if (data_object.handle) { if ((comgr_status = amd::Comgr::release_data(data_object)) != AMD_COMGR_STATUS_SUCCESS) { LogPrintfError("Releasing COMGR data failed with status %d ", comgr_status); return hipErrorInvalidValue; } } return hip_status; } hipError_t FatBinaryInfo::ExtractFatBinary(const std::vector& devices) { amd::ScopedLock lock(FatBinaryLock()); if (!HIP_USE_RUNTIME_UNBUNDLER) { bool containGenericTarget = false; hipError_t status = ExtractFatBinaryUsingCOMGR(devices, containGenericTarget); if (!containGenericTarget) return status; } hipError_t hip_error = hipSuccess; std::vector> code_objs; // Copy device names for Extract Code object File std::vector device_names; device_names.reserve(devices.size()); for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { device_names.push_back(devices[dev_idx]->devices()[0]->isa().isaName()); } if (image_ != nullptr) { // We are directly given image pointer directly, try to extract file desc & file Size hip_error = CodeObject::ExtractCodeObjectFromMemory(image_, device_names, code_objs, uri_); } else if (fname_.size() > 0) { // We are given file name, get the file desc and file size // Get File Handle & size of the file. if (!amd::Os::GetFileHandle(fname_.c_str(), &fdesc_, &fsize_)) { return hipErrorFileNotFound; } if (fsize_ == 0) { return hipErrorInvalidImage; } // Extract the code object from file hip_error = CodeObject::ExtractCodeObjectFromFile(fdesc_, fsize_, &image_, device_names, code_objs, foffset_); } else { return hipErrorInvalidValue; } if (hip_error == hipErrorNoBinaryForGpu) { if (fname_.size() > 0) { LogPrintfError("hipErrorNoBinaryForGpu: Couldn't find binary for file: %s", fname_.c_str()); } else { LogPrintfError("hipErrorNoBinaryForGpu: Couldn't find binary for ptr: 0x%x", image_); } // For the condition: unable to find code object for all devices, // still extract available images to those devices owning them. // This helps users to work with ROCm if there is any supported // GFX on system. for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { if (code_objs[dev_idx].first) { // Calculate the offset wrt binary_image and the original image size_t offset_l = (reinterpret_cast
(const_cast(code_objs[dev_idx].first)) - reinterpret_cast
(const_cast(image_))); fatbin_dev_info_[devices[dev_idx]->deviceId()] = new FatBinaryDeviceInfo(code_objs[dev_idx].first, code_objs[dev_idx].second, offset_l); fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ = new amd::Program(*devices[dev_idx]->asContext()); if (fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ == NULL) { break; } } } return hip_error; } if (hip_error == hipErrorInvalidKernelFile) { for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { // the image type is no CLANG_OFFLOAD_BUNDLER, image for current device directly passed fatbin_dev_info_[devices[dev_idx]->deviceId()] = new FatBinaryDeviceInfo(image_, CodeObject::ElfSize(image_), 0); } } else if (hip_error == hipSuccess) { for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { // Calculate the offset wrt binary_image and the original image size_t offset_l = (reinterpret_cast
(const_cast(code_objs[dev_idx].first)) - reinterpret_cast
(const_cast(image_))); fatbin_dev_info_[devices[dev_idx]->deviceId()] = new FatBinaryDeviceInfo(code_objs[dev_idx].first, code_objs[dev_idx].second, offset_l); } } for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ = new amd::Program(*devices[dev_idx]->asContext()); if (fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ == NULL) { return hipErrorOutOfMemory; } } return hipSuccess; } hipError_t FatBinaryInfo::AddDevProgram(const int device_id) { // Device Id bounds Check DeviceIdCheck(device_id); FatBinaryDeviceInfo* fbd_info = fatbin_dev_info_[device_id]; if (fbd_info == nullptr) { return hipErrorInvalidKernelFile; } // If fat binary was already added, skip this step and return success if (fbd_info->add_dev_prog_ == false) { amd::Context* ctx = g_devices[device_id]->asContext(); if (CL_SUCCESS != fbd_info->program_->addDeviceProgram(*ctx->devices()[0], fbd_info->binary_image_, fbd_info->binary_size_, false, nullptr, nullptr, fdesc_, fbd_info->binary_offset_, uri_)) { return hipErrorInvalidKernelFile; } fbd_info->add_dev_prog_ = true; } return hipSuccess; } hipError_t FatBinaryInfo::BuildProgram(const int device_id) { // Device Id Check and Add DeviceProgram if not added so far DeviceIdCheck(device_id); IHIP_RETURN_ONFAIL(AddDevProgram(device_id)); // If Program was already built skip this step and return success FatBinaryDeviceInfo* fbd_info = fatbin_dev_info_[device_id]; if (fbd_info->prog_built_ == false) { if (CL_SUCCESS != fbd_info->program_->build(g_devices[device_id]->devices(), nullptr, nullptr, nullptr, kOptionChangeable, kNewDevProg)) { return hipErrorNoBinaryForGpu; } fbd_info->prog_built_ = true; } if (!fbd_info->program_->load()) { return hipErrorNoBinaryForGpu; } return hipSuccess; } // ================================================================================================ hipError_t FatBinaryInfo::ExtractFatBinaryUsingCOMGR(const void* data, const std::vector& devices) { hipError_t hip_status = hipSuccess; // At this line, image should be a valid ptr. guarantee(data != nullptr, "Image cannot be nullptr"); do { std::vector> code_objs; // Copy device names std::vector device_names; device_names.reserve(devices.size()); for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { device_names.push_back(devices[dev_idx]->devices()[0]->isa().isaName()); } hip_status = CodeObject::extractCodeObjectFromFatBinaryUsingComgr(data, 0, device_names, code_objs); if (hip_status == hipErrorNoBinaryForGpu || hip_status == hipSuccess) { for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { if (code_objs[dev_idx].first) { fatbin_dev_info_[devices[dev_idx]->deviceId()] = new FatBinaryDeviceInfo(code_objs[dev_idx].first, code_objs[dev_idx].second, 0); fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ = new amd::Program(*devices[dev_idx]->asContext()); if (fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ == NULL) { break; } } else { // This is the case of hipErrorNoBinaryForGpu which will finally fail app on device // without code object LogPrintfError("Cannot find CO in the bundle %s for ISA: %s", fname_.c_str(), device_names[dev_idx].c_str()); } } } else if (hip_status == hipErrorInvalidKernelFile) { hip_status = hipSuccess; // If the image ptr is not clang offload bundle then just directly point the image. for (size_t dev_idx = 0; dev_idx < devices.size(); ++dev_idx) { fatbin_dev_info_[devices[dev_idx]->deviceId()] = new FatBinaryDeviceInfo(data, CodeObject::ElfSize(data), 0); fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ = new amd::Program(*devices[dev_idx]->asContext()); if (fatbin_dev_info_[devices[dev_idx]->deviceId()]->program_ == nullptr) { hip_status = hipErrorOutOfMemory; break; } } } else { LogPrintfError("CodeObject::extractCodeObjectFromFatBinaryUsingComgr failed with status %d\n", hip_status); } } while (0); return hip_status; } } // namespace hip