/**************************************************************************** * Copyright (C) 2018-2020 Maschell * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . ****************************************************************************/ #include "PluginInformationFactory.h" #include "../utils/ElfUtils.h" #include "../utils/utils.h" #include "utils/HeapMemoryFixedSize.h" #include "utils/wiiu_zlib.hpp" #include #include #include #include #include using namespace ELFIO; std::unique_ptr PluginInformationFactory::load(const PluginData &pluginData, std::vector &trampolineData, uint8_t trampolineId) { auto buffer = pluginData.getBuffer(); if (buffer.empty()) { DEBUG_FUNCTION_LINE_ERR("Buffer was empty"); return nullptr; } elfio reader(new wiiu_zlib); if (!reader.load(reinterpret_cast(buffer.data()), buffer.size())) { DEBUG_FUNCTION_LINE_ERR("Can't process PluginData in elfio"); return nullptr; } auto pluginInfo = make_unique_nothrow(); if (!pluginInfo) { DEBUG_FUNCTION_LINE_ERR("Failed to allocate PluginInformation"); return nullptr; } uint32_t sec_num = reader.sections.size(); auto destinationsData = make_unique_nothrow(sec_num); if (!destinationsData) { DEBUG_FUNCTION_LINE_ERR("Failed alloc memory for destinations array"); return nullptr; } std::span destinations(destinationsData.get(), sec_num); uint32_t totalSize = 0; uint32_t text_size = 0; uint32_t data_size = 0; for (uint32_t i = 0; i < sec_num; ++i) { section *psec = reader.sections[i]; if (psec->get_type() == 0x80000002) { continue; } if ((psec->get_type() == SHT_PROGBITS || psec->get_type() == SHT_NOBITS) && (psec->get_flags() & SHF_ALLOC)) { uint32_t sectionSize = psec->get_size(); auto address = (uint32_t) psec->get_address(); if ((address >= 0x02000000) && address < 0x10000000) { text_size += sectionSize; } else if ((address >= 0x10000000) && address < 0xC0000000) { data_size += sectionSize; } if (psec->get_name().starts_with(".wups.")) { data_size += sectionSize; } } } HeapMemoryFixedSize text_data(text_size); if (!text_data) { DEBUG_FUNCTION_LINE_ERR("Failed to alloc memory for the .text section (%d bytes)", text_size); return nullptr; } HeapMemoryFixedSize data_data(data_size); if (!data_data) { DEBUG_FUNCTION_LINE_ERR("Failed to alloc memory for the .data section (%d bytes)", data_size); return nullptr; } for (uint32_t i = 0; i < sec_num; ++i) { section *psec = reader.sections[i]; if (psec->get_type() == 0x80000002 || psec->get_name() == ".wut_load_bounds") { continue; } if ((psec->get_type() == SHT_PROGBITS || psec->get_type() == SHT_NOBITS) && (psec->get_flags() & SHF_ALLOC)) { uint32_t sectionSize = psec->get_size(); auto address = (uint32_t) psec->get_address(); uint32_t destination = address; if ((address >= 0x02000000) && address < 0x10000000) { destination += (uint32_t) text_data.data(); destination -= 0x02000000; destinations[psec->get_index()] = (uint8_t *) text_data.data(); if (destination + sectionSize > (uint32_t) text_data.data() + text_size) { DEBUG_FUNCTION_LINE_ERR("Tried to overflow .text buffer. %08X > %08X", destination + sectionSize, (uint32_t) text_data.data() + text_data.size()); OSFatal("WUPSLoader: Tried to overflow buffer"); } } else if ((address >= 0x10000000) && address < 0xC0000000) { destination += (uint32_t) data_data.data(); destination -= 0x10000000; destinations[psec->get_index()] = (uint8_t *) data_data.data(); if (destination + sectionSize > (uint32_t) data_data.data() + data_data.size()) { DEBUG_FUNCTION_LINE_ERR("Tried to overflow .data buffer. %08X > %08X", destination + sectionSize, (uint32_t) text_data.data() + text_data.size()); OSFatal("WUPSLoader: Tried to overflow buffer"); } } else if (address >= 0xC0000000) { DEBUG_FUNCTION_LINE_ERR("Loading section from 0xC0000000 is NOT supported"); return nullptr; } else { DEBUG_FUNCTION_LINE_ERR("Unhandled case"); return nullptr; } const char *p = psec->get_data(); if (psec->get_type() == SHT_NOBITS) { DEBUG_FUNCTION_LINE_VERBOSE("memset section %s %08X to 0 (%d bytes)", psec->get_name().c_str(), destination, sectionSize); memset((void *) destination, 0, sectionSize); } else if (psec->get_type() == SHT_PROGBITS) { DEBUG_FUNCTION_LINE_VERBOSE("Copy section %s %08X -> %08X (%d bytes)", psec->get_name().c_str(), p, destination, sectionSize); memcpy((void *) destination, p, sectionSize); } auto sectionInfo = make_unique_nothrow(psec->get_name(), destination, sectionSize); if (!sectionInfo) { DEBUG_FUNCTION_LINE_ERR("Failed to allocat SectionInfo"); return nullptr; } pluginInfo->addSectionInfo(std::move(sectionInfo)); DEBUG_FUNCTION_LINE_VERBOSE("Saved %s section info. Location: %08X size: %08X", psec->get_name().c_str(), destination, sectionSize); totalSize += sectionSize; DCFlushRange((void *) destination, sectionSize); ICInvalidateRange((void *) destination, sectionSize); } } for (uint32_t i = 0; i < sec_num; ++i) { section *psec = reader.sections[i]; if ((psec->get_type() == SHT_PROGBITS || psec->get_type() == SHT_NOBITS) && (psec->get_flags() & SHF_ALLOC)) { DEBUG_FUNCTION_LINE_VERBOSE("Linking (%d)... %s at %08X", i, psec->get_name().c_str(), destinations[psec->get_index()]); if (!linkSection(reader, psec->get_index(), (uint32_t) destinations[psec->get_index()], (uint32_t) text_data.data(), (uint32_t) data_data.data(), trampolineData, trampolineId)) { DEBUG_FUNCTION_LINE_ERR("linkSection failed"); return nullptr; } } } if (!PluginInformationFactory::addImportRelocationData(*pluginInfo, reader, destinations)) { DEBUG_FUNCTION_LINE_ERR("addImportRelocationData failed"); return nullptr; } DCFlushRange((void *) text_data.data(), text_data.size()); ICInvalidateRange((void *) text_data.data(), text_data.size()); DCFlushRange((void *) data_data.data(), data_data.size()); ICInvalidateRange((void *) data_data.data(), data_data.size()); pluginInfo->setTrampolineId(trampolineId); auto secInfo = pluginInfo->getSectionInfo(".wups.hooks"); if (secInfo && secInfo->getSize() > 0) { size_t entries_count = secInfo->getSize() / sizeof(wups_loader_hook_t); auto *entries = (wups_loader_hook_t *) secInfo->getAddress(); if (entries != nullptr) { for (size_t j = 0; j < entries_count; j++) { wups_loader_hook_t *hook = &entries[j]; DEBUG_FUNCTION_LINE_VERBOSE("Saving hook of plugin Type: %08X, target: %08X", hook->type, (void *) hook->target); auto hookData = make_unique_nothrow((void *) hook->target, hook->type); if (!hookData) { DEBUG_FUNCTION_LINE_ERR("Failed to allocate HookData"); return nullptr; } pluginInfo->addHookData(std::move(hookData)); } } } secInfo = pluginInfo->getSectionInfo(".wups.load"); if (secInfo && secInfo->getSize() > 0) { size_t entries_count = secInfo->getSize() / sizeof(wups_loader_entry_t); auto *entries = (wups_loader_entry_t *) secInfo->getAddress(); if (entries != nullptr) { for (size_t j = 0; j < entries_count; j++) { wups_loader_entry_t *cur_function = &entries[j]; DEBUG_FUNCTION_LINE_VERBOSE("Saving function \"%s\" of plugin . PA:%08X VA:%08X Library: %08X, target: %08X, call_addr: %08X", cur_function->_function.name /*,mPluginData->getPluginInformation()->getName().c_str()*/, cur_function->_function.physical_address, cur_function->_function.virtual_address, cur_function->_function.library, cur_function->_function.target, (void *) cur_function->_function.call_addr); auto functionData = make_unique_nothrow((void *) cur_function->_function.physical_address, (void *) cur_function->_function.virtual_address, cur_function->_function.name, (function_replacement_library_type_t) cur_function->_function.library, (void *) cur_function->_function.target, (void *) cur_function->_function.call_addr, (FunctionPatcherTargetProcess) cur_function->_function.targetProcess); if (!functionData) { DEBUG_FUNCTION_LINE_ERR("Failed to allocate FunctionData"); return nullptr; } pluginInfo->addFunctionData(std::move(functionData)); } } } // Get the symbol for functions. Elf_Half n = reader.sections.size(); for (Elf_Half i = 0; i < n; ++i) { section *sec = reader.sections[i]; if (SHT_SYMTAB == sec->get_type()) { symbol_section_accessor symbols(reader, sec); auto sym_no = (uint32_t) symbols.get_symbols_num(); if (sym_no > 0) { for (Elf_Half j = 0; j < sym_no; ++j) { std::string name; Elf64_Addr value = 0; Elf_Xword size = 0; unsigned char bind = 0; unsigned char type = 0; Elf_Half section = 0; unsigned char other = 0; if (symbols.get_symbol(j, name, value, size, bind, type, section, other)) { if (type == STT_FUNC) { // We only care about functions. auto sectionVal = reader.sections[section]; auto offsetVal = value - sectionVal->get_address(); auto sectionInfo = pluginInfo->getSectionInfo(sectionVal->get_name()); if (!sectionInfo) { continue; } auto finalAddress = offsetVal + sectionInfo->getAddress(); auto functionSymbolData = make_unique_nothrow(name, (void *) finalAddress, (uint32_t) size); if (!functionSymbolData) { DEBUG_FUNCTION_LINE_ERR("Failed to allocate FunctionSymbolData"); return nullptr; } pluginInfo->addFunctionSymbolData(std::move(functionSymbolData)); } } } break; } } } if (totalSize > text_size + data_size) { DEBUG_FUNCTION_LINE_ERR("We didn't allocate enough memory!!"); return nullptr; } // Save the addresses for the allocated memory. This way we can free it again :) pluginInfo->mAllocatedDataMemoryAddress = std::move(data_data); pluginInfo->mAllocatedTextMemoryAddress = std::move(text_data); return pluginInfo; } bool PluginInformationFactory::addImportRelocationData(PluginInformation &pluginInfo, const elfio &reader, std::span destinations) { std::map> infoMap; uint32_t sec_num = reader.sections.size(); for (uint32_t i = 0; i < sec_num; ++i) { auto *psec = reader.sections[i]; if (psec->get_type() == 0x80000002) { auto info = make_shared_nothrow(psec->get_name()); if (!info) { return false; } infoMap[i] = std::move(info); } } for (uint32_t i = 0; i < sec_num; ++i) { section *psec = reader.sections[i]; if (psec->get_type() == SHT_RELA || psec->get_type() == SHT_REL) { DEBUG_FUNCTION_LINE_VERBOSE("Found relocation section %s", psec->get_name().c_str()); relocation_section_accessor rel(reader, psec); for (uint32_t j = 0; j < (uint32_t) rel.get_entries_num(); ++j) { Elf_Word symbol = 0; Elf64_Addr offset; Elf_Word type; Elf_Sxword addend; std::string sym_name; Elf64_Addr sym_value; if (!rel.get_entry(j, offset, symbol, type, addend)) { DEBUG_FUNCTION_LINE_ERR("Failed to get relocation"); return false; } symbol_section_accessor symbols(reader, reader.sections[(Elf_Half) psec->get_link()]); // Find the symbol Elf_Xword size; unsigned char bind; unsigned char symbolType; Elf_Half sym_section_index; unsigned char other; if (!symbols.get_symbol(symbol, sym_name, sym_value, size, bind, symbolType, sym_section_index, other)) { DEBUG_FUNCTION_LINE_ERR("Failed to get symbol"); return false; } auto adjusted_sym_value = (uint32_t) sym_value; if (adjusted_sym_value < 0xC0000000) { continue; } uint32_t section_index = psec->get_info(); if (!infoMap.contains(sym_section_index)) { DEBUG_FUNCTION_LINE_ERR("Relocation is referencing a unknown section. %d destination: %08X sym_name %s", section_index, destinations[section_index], sym_name.c_str()); return false; } auto relocationData = make_unique_nothrow(type, offset - 0x02000000, addend, (void *) (destinations[section_index]), sym_name, infoMap[sym_section_index]); if (!relocationData) { DEBUG_FUNCTION_LINE_ERR("Failed to allocate RelocationData"); return false; } pluginInfo.addRelocationData(std::move(relocationData)); } } } return true; } bool PluginInformationFactory::linkSection(const elfio &reader, uint32_t section_index, uint32_t destination, uint32_t base_text, uint32_t base_data, std::vector &trampolineData, uint8_t trampolineId) { uint32_t sec_num = reader.sections.size(); for (uint32_t i = 0; i < sec_num; ++i) { section *psec = reader.sections[i]; if (psec->get_info() == section_index) { DEBUG_FUNCTION_LINE_VERBOSE("Found relocation section %s", psec->get_name().c_str()); relocation_section_accessor rel(reader, psec); for (uint32_t j = 0; j < (uint32_t) rel.get_entries_num(); ++j) { Elf_Word symbol = 0; Elf64_Addr offset; Elf_Word type; Elf_Sxword addend; std::string sym_name; Elf64_Addr sym_value; if (!rel.get_entry(j, offset, symbol, type, addend)) { DEBUG_FUNCTION_LINE_ERR("Failed to get relocation"); return false; } symbol_section_accessor symbols(reader, reader.sections[(Elf_Half) psec->get_link()]); // Find the symbol Elf_Xword size; unsigned char bind; unsigned char symbolType; Elf_Half sym_section_index; unsigned char other; if (!symbols.get_symbol(symbol, sym_name, sym_value, size, bind, symbolType, sym_section_index, other)) { DEBUG_FUNCTION_LINE_ERR("Failed to get symbol"); return false; } auto adjusted_sym_value = (uint32_t) sym_value; if ((adjusted_sym_value >= 0x02000000) && adjusted_sym_value < 0x10000000) { adjusted_sym_value -= 0x02000000; adjusted_sym_value += base_text; } else if ((adjusted_sym_value >= 0x10000000) && adjusted_sym_value < 0xC0000000) { adjusted_sym_value -= 0x10000000; adjusted_sym_value += base_data; } else if (adjusted_sym_value >= 0xC0000000) { //DEBUG_FUNCTION_LINE("Skip imports"); // Skip imports continue; } else if (adjusted_sym_value == 0x0) { // } else { DEBUG_FUNCTION_LINE_ERR("Unhandled case %08X", adjusted_sym_value); return false; } auto adjusted_offset = (uint32_t) offset; if ((offset >= 0x02000000) && offset < 0x10000000) { adjusted_offset -= 0x02000000; } else if ((adjusted_offset >= 0x10000000) && adjusted_offset < 0xC0000000) { adjusted_offset -= 0x10000000; } else if (adjusted_offset >= 0xC0000000) { adjusted_offset -= 0xC0000000; } if (sym_section_index == SHN_ABS) { // } else if (sym_section_index > SHN_LORESERVE) { DEBUG_FUNCTION_LINE_ERR("NOT IMPLEMENTED: %04X", sym_section_index); return false; } // DEBUG_FUNCTION_LINE_VERBOSE("sym_value %08X adjusted_sym_value %08X offset %08X adjusted_offset %08X", (uint32_t) sym_value, adjusted_sym_value, (uint32_t) offset, adjusted_offset); if (!ElfUtils::elfLinkOne(type, adjusted_offset, addend, destination, adjusted_sym_value, trampolineData, RELOC_TYPE_FIXED, trampolineId)) { DEBUG_FUNCTION_LINE_ERR("Link failed"); return false; } } DEBUG_FUNCTION_LINE_VERBOSE("done"); return true; } } return true; }