// Copyright 2014 The Crashpad Authors // // 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 "snapshot/mac/mach_o_image_reader.h" #include #include #include #include #include #include #include "base/check_op.h" #include "base/logging.h" #include "base/strings/stringprintf.h" #include "client/crashpad_info.h" #include "snapshot/mac/mach_o_image_segment_reader.h" #include "snapshot/mac/mach_o_image_symbol_table_reader.h" #include "snapshot/mac/process_reader_mac.h" #include "util/mac/checked_mach_address_range.h" #include "util/misc/implicit_cast.h" namespace { constexpr uint32_t kInvalidSegmentIndex = std::numeric_limits::max(); } // namespace namespace crashpad { MachOImageReader::MachOImageReader() : segments_(), segment_map_(), module_name_(), module_info_(), dylinker_name_(), uuid_(), address_(0), size_(0), slide_(0), source_version_(0), symtab_command_(), dysymtab_command_(), symbol_table_(), id_dylib_command_(), process_reader_(nullptr), file_type_(0), initialized_(), symbol_table_initialized_() { } MachOImageReader::~MachOImageReader() { } bool MachOImageReader::Initialize(ProcessReaderMac* process_reader, mach_vm_address_t address, const std::string& name) { INITIALIZATION_STATE_SET_INITIALIZING(initialized_); process_reader_ = process_reader; address_ = address; module_name_ = name; module_info_ = base::StringPrintf(", module %s, address 0x%llx", name.c_str(), address); process_types::mach_header mach_header; if (!mach_header.Read(process_reader, address)) { LOG(WARNING) << "could not read mach_header" << module_info_; return false; } const bool is_64_bit = process_reader->Is64Bit(); const uint32_t kExpectedMagic = is_64_bit ? MH_MAGIC_64 : MH_MAGIC; if (mach_header.magic != kExpectedMagic) { LOG(WARNING) << base::StringPrintf("unexpected mach_header::magic 0x%08x", mach_header.magic) << module_info_; return false; } switch (mach_header.filetype) { case MH_EXECUTE: case MH_DYLIB: case MH_DYLINKER: case MH_BUNDLE: file_type_ = mach_header.filetype; break; default: LOG(WARNING) << base::StringPrintf( "unexpected mach_header::filetype 0x%08x", mach_header.filetype) << module_info_; return false; } const uint32_t kExpectedSegmentCommand = is_64_bit ? LC_SEGMENT_64 : LC_SEGMENT; const uint32_t kUnexpectedSegmentCommand = is_64_bit ? LC_SEGMENT : LC_SEGMENT_64; const struct { // Which method to call when encountering a load command matching |command|. bool (MachOImageReader::*function)(mach_vm_address_t, const std::string&); // The minimum size that may be allotted to store the load command. size_t size; // The load command to match. uint32_t command; // True if the load command must not appear more than one time. bool singleton; } kLoadCommandReaders[] = { { &MachOImageReader::ReadSegmentCommand, process_types::segment_command::ExpectedSize(process_reader), kExpectedSegmentCommand, false, }, { &MachOImageReader::ReadSymTabCommand, process_types::symtab_command::ExpectedSize(process_reader), LC_SYMTAB, true, }, { &MachOImageReader::ReadDySymTabCommand, process_types::symtab_command::ExpectedSize(process_reader), LC_DYSYMTAB, true, }, { &MachOImageReader::ReadIdDylibCommand, process_types::dylib_command::ExpectedSize(process_reader), LC_ID_DYLIB, true, }, { &MachOImageReader::ReadDylinkerCommand, process_types::dylinker_command::ExpectedSize(process_reader), LC_LOAD_DYLINKER, true, }, { &MachOImageReader::ReadDylinkerCommand, process_types::dylinker_command::ExpectedSize(process_reader), LC_ID_DYLINKER, true, }, { &MachOImageReader::ReadUUIDCommand, process_types::uuid_command::ExpectedSize(process_reader), LC_UUID, true, }, { &MachOImageReader::ReadSourceVersionCommand, process_types::source_version_command::ExpectedSize(process_reader), LC_SOURCE_VERSION, true, }, // When reading a 64-bit process, no 32-bit segment commands should be // present, and vice-versa. { &MachOImageReader::ReadUnexpectedCommand, process_types::load_command::ExpectedSize(process_reader), kUnexpectedSegmentCommand, false, }, }; // This vector is parallel to the kLoadCommandReaders array, and tracks // whether a singleton load command matching the |command| field has been // found yet. std::vector singleton_indices(std::size(kLoadCommandReaders), kInvalidSegmentIndex); size_t offset = mach_header.Size(); const mach_vm_address_t kLoadCommandAddressLimit = address + offset + mach_header.sizeofcmds; for (uint32_t load_command_index = 0; load_command_index < mach_header.ncmds; ++load_command_index) { mach_vm_address_t load_command_address = address + offset; std::string load_command_info = base::StringPrintf(", load command %u/%u%s", load_command_index, mach_header.ncmds, module_info_.c_str()); process_types::load_command load_command; // Make sure that the basic load command structure doesn’t overflow the // space allotted for load commands. if (load_command_address + load_command.ExpectedSize(process_reader) > kLoadCommandAddressLimit) { LOG(WARNING) << base::StringPrintf( "load_command at 0x%llx exceeds sizeofcmds 0x%x", load_command_address, mach_header.sizeofcmds) << load_command_info; return false; } if (!load_command.Read(process_reader, load_command_address)) { LOG(WARNING) << "could not read load_command" << load_command_info; return false; } load_command_info = base::StringPrintf(", load command 0x%x %u/%u%s", load_command.cmd, load_command_index, mach_header.ncmds, module_info_.c_str()); // Now that the load command’s stated size is known, make sure that it // doesn’t overflow the space allotted for load commands. if (load_command_address + load_command.cmdsize > kLoadCommandAddressLimit) { LOG(WARNING) << base::StringPrintf( "load_command at 0x%llx cmdsize 0x%x exceeds sizeofcmds 0x%x", load_command_address, load_command.cmdsize, mach_header.sizeofcmds) << load_command_info; return false; } for (size_t reader_index = 0; reader_index < std::size(kLoadCommandReaders); ++reader_index) { if (load_command.cmd != kLoadCommandReaders[reader_index].command) { continue; } if (load_command.cmdsize < kLoadCommandReaders[reader_index].size) { LOG(WARNING) << base::StringPrintf( "load command cmdsize 0x%x insufficient for 0x%zx", load_command.cmdsize, kLoadCommandReaders[reader_index].size) << load_command_info; return false; } if (kLoadCommandReaders[reader_index].singleton) { if (singleton_indices[reader_index] != kInvalidSegmentIndex) { LOG(WARNING) << "duplicate load command at " << singleton_indices[reader_index] << load_command_info; return false; } singleton_indices[reader_index] = load_command_index; } if (!((this)->*(kLoadCommandReaders[reader_index].function))( load_command_address, load_command_info)) { return false; } break; } offset += load_command.cmdsize; } // Now that the slide is known, push it into the segments. for (const auto& segment : segments_) { segment->SetSlide(slide_); // This was already checked for the unslid values while the segments were // read, but now it’s possible to check the slid values too. The individual // sections don’t need to be checked because they were verified to be // contained within their respective segments when the segments were read. mach_vm_address_t slid_segment_address = segment->Address(); mach_vm_size_t slid_segment_size = segment->Size(); CheckedMachAddressRange slid_segment_range( process_reader_->Is64Bit(), slid_segment_address, slid_segment_size); if (!slid_segment_range.IsValid()) { LOG(WARNING) << base::StringPrintf( "invalid slid segment range 0x%llx + 0x%llx, " "segment ", slid_segment_address, slid_segment_size) << segment->Name() << module_info_; return false; } } if (!segment_map_.count(SEG_TEXT)) { // The __TEXT segment is required. Even a module with no executable code // will have a __TEXT segment encompassing the Mach-O header and load // commands. Without a __TEXT segment, |size_| will not have been computed. LOG(WARNING) << "no " SEG_TEXT " segment" << module_info_; return false; } if (mach_header.filetype == MH_DYLIB && !id_dylib_command_) { // This doesn’t render a module unusable, it’s just weird and worth noting. LOG(INFO) << "no LC_ID_DYLIB" << module_info_; } INITIALIZATION_STATE_SET_VALID(initialized_); return true; } const MachOImageSegmentReader* MachOImageReader::GetSegmentByName( const std::string& segment_name) const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); const auto& iterator = segment_map_.find(segment_name); if (iterator == segment_map_.end()) { return nullptr; } return segments_[iterator->second].get(); } const process_types::section* MachOImageReader::GetSectionByName( const std::string& segment_name, const std::string& section_name, mach_vm_address_t* address) const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); const MachOImageSegmentReader* segment = GetSegmentByName(segment_name); if (!segment) { return nullptr; } return segment->GetSectionByName(section_name, address); } const process_types::section* MachOImageReader::GetSectionAtIndex( size_t index, const MachOImageSegmentReader** containing_segment, mach_vm_address_t* address) const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); static_assert(NO_SECT == 0, "NO_SECT must be zero"); if (index == NO_SECT) { LOG(WARNING) << "section index " << index << " out of range"; return nullptr; } // Switch to a more comfortable 0-based index. size_t local_index = index - 1; for (const auto& segment : segments_) { size_t nsects = segment->nsects(); if (local_index < nsects) { const process_types::section* section = segment->GetSectionAtIndex(local_index, address); if (containing_segment) { *containing_segment = segment.get(); } return section; } local_index -= nsects; } LOG(WARNING) << "section index " << index << " out of range"; return nullptr; } bool MachOImageReader::LookUpExternalDefinedSymbol( const std::string& name, mach_vm_address_t* value) const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); if (symbol_table_initialized_.is_uninitialized()) { InitializeSymbolTable(); } if (!symbol_table_initialized_.is_valid() || !symbol_table_) { return false; } const MachOImageSymbolTableReader::SymbolInformation* symbol_info = symbol_table_->LookUpExternalDefinedSymbol(name); if (!symbol_info) { return false; } if (symbol_info->section == NO_SECT) { // This is an absolute (N_ABS) symbol, which requires no further validation // or processing. *value = symbol_info->value; return true; } // This is a symbol defined in a particular section, so make sure that it’s // valid for that section and fix it up for any “slide” as needed. mach_vm_address_t section_address; const MachOImageSegmentReader* segment; const process_types::section* section = GetSectionAtIndex(symbol_info->section, &segment, §ion_address); if (!section) { return false; } mach_vm_address_t slid_value = symbol_info->value + (segment->SegmentSlides() ? slide_ : 0); // The __mh_execute_header (_MH_EXECUTE_SYM) symbol is weird. In // position-independent executables, it shows up in the symbol table as a // symbol in section 1, although it’s not really in that section. It points to // the mach_header[_64], which is the beginning of the __TEXT segment, and the // __text section normally begins after the load commands in the __TEXT // segment. The range check below will fail for this symbol, because it’s not // really in the section it claims to be in. See Xcode 5.1 // ld64-236.3/src/ld/OutputFile.cpp ld::tool::OutputFile::buildSymbolTable(). // There, ld takes symbols that refer to anything in the mach_header[_64] and // marks them as being in section 1. Here, section 1 is treated in this same // special way as long as it’s in the __TEXT segment that begins at the start // of the image, which is normally the case, and as long as the symbol’s value // is the base of the image. // // This only happens for PIE executables, because __mh_execute_header needs // to slide. In non-PIE executables, __mh_execute_header is an absolute // symbol. CheckedMachAddressRange section_range( process_reader_->Is64Bit(), section_address, section->size); if (!section_range.ContainsValue(slid_value) && !(symbol_info->section == 1 && segment->Name() == SEG_TEXT && slid_value == Address())) { std::string section_name_full = MachOImageSegmentReader::SegmentAndSectionNameString(section->segname, section->sectname); LOG(WARNING) << base::StringPrintf( "symbol %s (0x%llx) outside of section %s (0x%llx + " "0x%llx)", name.c_str(), slid_value, section_name_full.c_str(), section_address, section->size) << module_info_; return false; } *value = slid_value; return true; } uint32_t MachOImageReader::DylibVersion() const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); DCHECK_EQ(FileType(), implicit_cast(MH_DYLIB)); if (id_dylib_command_) { return id_dylib_command_->dylib_current_version; } // In case this was a weird dylib without an LC_ID_DYLIB command. return 0; } void MachOImageReader::UUID(crashpad::UUID* uuid) const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); memcpy(uuid, &uuid_, sizeof(uuid_)); } bool MachOImageReader::GetCrashpadInfo( process_types::CrashpadInfo* crashpad_info) const { INITIALIZATION_STATE_DCHECK_VALID(initialized_); mach_vm_address_t crashpad_info_address; const process_types::section* crashpad_info_section = GetSectionByName(SEG_DATA, "crashpad_info", &crashpad_info_address); if (!crashpad_info_section) { return false; } if (crashpad_info_section->size < crashpad_info->MinimumSize(process_reader_)) { LOG(WARNING) << "small crashpad info section size " << crashpad_info_section->size << module_info_; return false; } // This Read() will zero out anything beyond the structure’s declared size. if (!crashpad_info->Read(process_reader_, crashpad_info_address)) { LOG(WARNING) << "could not read crashpad info" << module_info_; return false; } if (crashpad_info->signature != CrashpadInfo::kSignature || crashpad_info->version != 1) { LOG(WARNING) << base::StringPrintf( "unexpected crashpad info signature 0x%x, version %u%s", crashpad_info->signature, crashpad_info->version, module_info_.c_str()); return false; } // Don’t require strict equality, to leave wiggle room for sloppy linkers. if (crashpad_info->size > crashpad_info_section->size) { LOG(WARNING) << "crashpad info struct size " << crashpad_info->size << " large for section size " << crashpad_info_section->size << module_info_; return false; } if (crashpad_info->size > crashpad_info->ExpectedSize(process_reader_)) { // This isn’t strictly a problem, because unknown fields will simply be // ignored, but it may be of diagnostic interest. LOG(INFO) << "large crashpad info size " << crashpad_info->size << module_info_; } return true; } template bool MachOImageReader::ReadLoadCommand(mach_vm_address_t load_command_address, const std::string& load_command_info, uint32_t expected_load_command_id, T* load_command) { if (!load_command->Read(process_reader_, load_command_address)) { LOG(WARNING) << "could not read load command" << load_command_info; return false; } DCHECK_GE(load_command->cmdsize, load_command->Size()); DCHECK_EQ(load_command->cmd, expected_load_command_id); return true; } bool MachOImageReader::ReadSegmentCommand( mach_vm_address_t load_command_address, const std::string& load_command_info) { size_t segment_index = segments_.size(); segments_.push_back(std::make_unique()); MachOImageSegmentReader* segment = segments_.back().get(); if (!segment->Initialize(process_reader_, load_command_address, load_command_info, module_name_, file_type_)) { segments_.pop_back(); return false; } // At this point, the segment itself is considered valid, but if one of the // next checks fails, it will render the module invalid. If any of the next // checks fail, this method should return false, but it doesn’t need to bother // removing the segment from segments_. The segment will be properly released // when the image is destroyed, and the image won’t be usable because // initialization won’t have completed. Most importantly, leaving the segment // in segments_ means that no other structures (such as perhaps segment_map_) // become inconsistent or require cleanup. const std::string segment_name = segment->Name(); const auto insert_result = segment_map_.insert(std::make_pair(segment_name, segment_index)); if (!insert_result.second) { LOG(WARNING) << base::StringPrintf("duplicate %s segment at %zu and %zu", segment_name.c_str(), insert_result.first->second, segment_index) << load_command_info; return false; } if (segment_name == SEG_TEXT) { mach_vm_size_t vmsize = segment->vmsize(); if (vmsize == 0) { LOG(WARNING) << "zero-sized " SEG_TEXT " segment" << load_command_info; return false; } size_ = vmsize; // The slide is computed as the difference between the __TEXT segment’s // preferred and actual load addresses. This is the same way that dyld // computes slide. See 10.9.2 dyld-239.4/src/dyldInitialization.cpp // slideOfMainExecutable(). slide_ = address_ - segment->vmaddr(); } return true; } bool MachOImageReader::ReadSymTabCommand(mach_vm_address_t load_command_address, const std::string& load_command_info) { symtab_command_.reset(new process_types::symtab_command()); return ReadLoadCommand(load_command_address, load_command_info, LC_SYMTAB, symtab_command_.get()); } bool MachOImageReader::ReadDySymTabCommand( mach_vm_address_t load_command_address, const std::string& load_command_info) { dysymtab_command_.reset(new process_types::dysymtab_command()); return ReadLoadCommand(load_command_address, load_command_info, LC_DYSYMTAB, dysymtab_command_.get()); } bool MachOImageReader::ReadIdDylibCommand( mach_vm_address_t load_command_address, const std::string& load_command_info) { if (file_type_ != MH_DYLIB) { LOG(WARNING) << base::StringPrintf( "LC_ID_DYLIB inappropriate in non-dylib file type 0x%x", file_type_) << load_command_info; return false; } DCHECK(!id_dylib_command_); id_dylib_command_.reset(new process_types::dylib_command()); return ReadLoadCommand(load_command_address, load_command_info, LC_ID_DYLIB, id_dylib_command_.get()); } bool MachOImageReader::ReadDylinkerCommand( mach_vm_address_t load_command_address, const std::string& load_command_info) { if (file_type_ != MH_EXECUTE && file_type_ != MH_DYLINKER) { LOG(WARNING) << base::StringPrintf( "LC_LOAD_DYLINKER/LC_ID_DYLINKER inappropriate in file " "type 0x%x", file_type_) << load_command_info; return false; } const uint32_t kExpectedCommand = file_type_ == MH_DYLINKER ? LC_ID_DYLINKER : LC_LOAD_DYLINKER; process_types::dylinker_command dylinker_command; if (!ReadLoadCommand(load_command_address, load_command_info, kExpectedCommand, &dylinker_command)) { return false; } if (!process_reader_->Memory()->ReadCStringSizeLimited( load_command_address + dylinker_command.name, dylinker_command.cmdsize - dylinker_command.name, &dylinker_name_)) { LOG(WARNING) << "could not read dylinker_command name" << load_command_info; return false; } return true; } bool MachOImageReader::ReadUUIDCommand(mach_vm_address_t load_command_address, const std::string& load_command_info) { process_types::uuid_command uuid_command; if (!ReadLoadCommand( load_command_address, load_command_info, LC_UUID, &uuid_command)) { return false; } uuid_.InitializeFromBytes(uuid_command.uuid); return true; } bool MachOImageReader::ReadSourceVersionCommand( mach_vm_address_t load_command_address, const std::string& load_command_info) { process_types::source_version_command source_version_command; if (!ReadLoadCommand(load_command_address, load_command_info, LC_SOURCE_VERSION, &source_version_command)) { return false; } source_version_ = source_version_command.version; return true; } bool MachOImageReader::ReadUnexpectedCommand( mach_vm_address_t load_command_address, const std::string& load_command_info) { LOG(WARNING) << "unexpected load command" << load_command_info; return false; } void MachOImageReader::InitializeSymbolTable() const { DCHECK(symbol_table_initialized_.is_uninitialized()); symbol_table_initialized_.set_invalid(); if (!symtab_command_) { // It’s technically valid for there to be no LC_SYMTAB, and in that case, // any symbol lookups should fail. Mark the symbol table as valid, and // LookUpExternalDefinedSymbol() will understand what it means when this is // valid but symbol_table_ is not present. symbol_table_initialized_.set_valid(); return; } // Find the __LINKEDIT segment. Technically, the symbol table can be in any // mapped segment, but by convention, it’s in the one named __LINKEDIT. const MachOImageSegmentReader* linkedit_segment = GetSegmentByName(SEG_LINKEDIT); if (!linkedit_segment) { LOG(WARNING) << "no " SEG_LINKEDIT " segment"; return; } symbol_table_.reset(new MachOImageSymbolTableReader()); if (!symbol_table_->Initialize(process_reader_, symtab_command_.get(), dysymtab_command_.get(), linkedit_segment, module_info_)) { symbol_table_.reset(); return; } symbol_table_initialized_.set_valid(); } } // namespace crashpad