//===-- ProcessElfCore.cpp --------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include #include #include "lldb/Core/Module.h" #include "lldb/Core/ModuleSpec.h" #include "lldb/Core/PluginManager.h" #include "lldb/Core/Section.h" #include "lldb/Target/DynamicLoader.h" #include "lldb/Target/MemoryRegionInfo.h" #include "lldb/Target/Target.h" #include "lldb/Target/UnixSignals.h" #include "lldb/Utility/DataBufferHeap.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/State.h" #include "llvm/BinaryFormat/ELF.h" #include "llvm/Support/Threading.h" #include "Plugins/DynamicLoader/POSIX-DYLD/DynamicLoaderPOSIXDYLD.h" #include "Plugins/ObjectFile/ELF/ObjectFileELF.h" #include "Plugins/Process/elf-core/RegisterUtilities.h" #include "ProcessElfCore.h" #include "ThreadElfCore.h" using namespace lldb_private; ConstString ProcessElfCore::GetPluginNameStatic() { static ConstString g_name("elf-core"); return g_name; } const char *ProcessElfCore::GetPluginDescriptionStatic() { return "ELF core dump plug-in."; } void ProcessElfCore::Terminate() { PluginManager::UnregisterPlugin(ProcessElfCore::CreateInstance); } lldb::ProcessSP ProcessElfCore::CreateInstance(lldb::TargetSP target_sp, lldb::ListenerSP listener_sp, const FileSpec *crash_file) { lldb::ProcessSP process_sp; if (crash_file) { // Read enough data for a ELF32 header or ELF64 header Note: Here we care // about e_type field only, so it is safe to ignore possible presence of // the header extension. const size_t header_size = sizeof(llvm::ELF::Elf64_Ehdr); auto data_sp = FileSystem::Instance().CreateDataBuffer( crash_file->GetPath(), header_size, 0); if (data_sp && data_sp->GetByteSize() == header_size && elf::ELFHeader::MagicBytesMatch(data_sp->GetBytes())) { elf::ELFHeader elf_header; DataExtractor data(data_sp, lldb::eByteOrderLittle, 4); lldb::offset_t data_offset = 0; if (elf_header.Parse(data, &data_offset)) { if (elf_header.e_type == llvm::ELF::ET_CORE) process_sp.reset( new ProcessElfCore(target_sp, listener_sp, *crash_file)); } } } return process_sp; } bool ProcessElfCore::CanDebug(lldb::TargetSP target_sp, bool plugin_specified_by_name) { // For now we are just making sure the file exists for a given module if (!m_core_module_sp && FileSystem::Instance().Exists(m_core_file)) { ModuleSpec core_module_spec(m_core_file, target_sp->GetArchitecture()); Status error(ModuleList::GetSharedModule(core_module_spec, m_core_module_sp, NULL, NULL, NULL)); if (m_core_module_sp) { ObjectFile *core_objfile = m_core_module_sp->GetObjectFile(); if (core_objfile && core_objfile->GetType() == ObjectFile::eTypeCoreFile) return true; } } return false; } //---------------------------------------------------------------------- // ProcessElfCore constructor //---------------------------------------------------------------------- ProcessElfCore::ProcessElfCore(lldb::TargetSP target_sp, lldb::ListenerSP listener_sp, const FileSpec &core_file) : Process(target_sp, listener_sp), m_core_file(core_file) {} //---------------------------------------------------------------------- // Destructor //---------------------------------------------------------------------- ProcessElfCore::~ProcessElfCore() { Clear(); // We need to call finalize on the process before destroying ourselves to // make sure all of the broadcaster cleanup goes as planned. If we destruct // this class, then Process::~Process() might have problems trying to fully // destroy the broadcaster. Finalize(); } //---------------------------------------------------------------------- // PluginInterface //---------------------------------------------------------------------- ConstString ProcessElfCore::GetPluginName() { return GetPluginNameStatic(); } uint32_t ProcessElfCore::GetPluginVersion() { return 1; } lldb::addr_t ProcessElfCore::AddAddressRangeFromLoadSegment( const elf::ELFProgramHeader *header) { const lldb::addr_t addr = header->p_vaddr; FileRange file_range(header->p_offset, header->p_filesz); VMRangeToFileOffset::Entry range_entry(addr, header->p_memsz, file_range); VMRangeToFileOffset::Entry *last_entry = m_core_aranges.Back(); if (last_entry && last_entry->GetRangeEnd() == range_entry.GetRangeBase() && last_entry->data.GetRangeEnd() == range_entry.data.GetRangeBase() && last_entry->GetByteSize() == last_entry->data.GetByteSize()) { last_entry->SetRangeEnd(range_entry.GetRangeEnd()); last_entry->data.SetRangeEnd(range_entry.data.GetRangeEnd()); } else { m_core_aranges.Append(range_entry); } // Keep a separate map of permissions that that isn't coalesced so all ranges // are maintained. const uint32_t permissions = ((header->p_flags & llvm::ELF::PF_R) ? lldb::ePermissionsReadable : 0u) | ((header->p_flags & llvm::ELF::PF_W) ? lldb::ePermissionsWritable : 0u) | ((header->p_flags & llvm::ELF::PF_X) ? lldb::ePermissionsExecutable : 0u); m_core_range_infos.Append( VMRangeToPermissions::Entry(addr, header->p_memsz, permissions)); return addr; } //---------------------------------------------------------------------- // Process Control //---------------------------------------------------------------------- Status ProcessElfCore::DoLoadCore() { Status error; if (!m_core_module_sp) { error.SetErrorString("invalid core module"); return error; } ObjectFileELF *core = (ObjectFileELF *)(m_core_module_sp->GetObjectFile()); if (core == NULL) { error.SetErrorString("invalid core object file"); return error; } const uint32_t num_segments = core->GetProgramHeaderCount(); if (num_segments == 0) { error.SetErrorString("core file has no segments"); return error; } SetCanJIT(false); m_thread_data_valid = true; bool ranges_are_sorted = true; lldb::addr_t vm_addr = 0; /// Walk through segments and Thread and Address Map information. /// PT_NOTE - Contains Thread and Register information /// PT_LOAD - Contains a contiguous range of Process Address Space for (uint32_t i = 1; i <= num_segments; i++) { const elf::ELFProgramHeader *header = core->GetProgramHeaderByIndex(i); assert(header != NULL); DataExtractor data = core->GetSegmentDataByIndex(i); // Parse thread contexts and auxv structure if (header->p_type == llvm::ELF::PT_NOTE) { if (llvm::Error error = ParseThreadContextsFromNoteSegment(header, data)) return Status(std::move(error)); } // PT_LOAD segments contains address map if (header->p_type == llvm::ELF::PT_LOAD) { lldb::addr_t last_addr = AddAddressRangeFromLoadSegment(header); if (vm_addr > last_addr) ranges_are_sorted = false; vm_addr = last_addr; } } if (!ranges_are_sorted) { m_core_aranges.Sort(); m_core_range_infos.Sort(); } // Even if the architecture is set in the target, we need to override it to // match the core file which is always single arch. ArchSpec arch(m_core_module_sp->GetArchitecture()); ArchSpec target_arch = GetTarget().GetArchitecture(); ArchSpec core_arch(m_core_module_sp->GetArchitecture()); target_arch.MergeFrom(core_arch); GetTarget().SetArchitecture(target_arch); SetUnixSignals(UnixSignals::Create(GetArchitecture())); // Ensure we found at least one thread that was stopped on a signal. bool siginfo_signal_found = false; bool prstatus_signal_found = false; // Check we found a signal in a SIGINFO note. for (const auto &thread_data : m_thread_data) { if (thread_data.signo != 0) siginfo_signal_found = true; if (thread_data.prstatus_sig != 0) prstatus_signal_found = true; } if (!siginfo_signal_found) { // If we don't have signal from SIGINFO use the signal from each threads // PRSTATUS note. if (prstatus_signal_found) { for (auto &thread_data : m_thread_data) thread_data.signo = thread_data.prstatus_sig; } else if (m_thread_data.size() > 0) { // If all else fails force the first thread to be SIGSTOP m_thread_data.begin()->signo = GetUnixSignals()->GetSignalNumberFromName("SIGSTOP"); } } // Core files are useless without the main executable. See if we can locate // the main executable using data we found in the core file notes. lldb::ModuleSP exe_module_sp = GetTarget().GetExecutableModule(); if (!exe_module_sp) { // The first entry in the NT_FILE might be our executable if (!m_nt_file_entries.empty()) { ModuleSpec exe_module_spec; exe_module_spec.GetArchitecture() = arch; exe_module_spec.GetFileSpec().SetFile( m_nt_file_entries[0].path.GetCString(), FileSpec::Style::native); if (exe_module_spec.GetFileSpec()) { exe_module_sp = GetTarget().GetSharedModule(exe_module_spec); if (exe_module_sp) GetTarget().SetExecutableModule(exe_module_sp, eLoadDependentsNo); } } } return error; } lldb_private::DynamicLoader *ProcessElfCore::GetDynamicLoader() { if (m_dyld_ap.get() == NULL) m_dyld_ap.reset(DynamicLoader::FindPlugin( this, DynamicLoaderPOSIXDYLD::GetPluginNameStatic().GetCString())); return m_dyld_ap.get(); } bool ProcessElfCore::UpdateThreadList(ThreadList &old_thread_list, ThreadList &new_thread_list) { const uint32_t num_threads = GetNumThreadContexts(); if (!m_thread_data_valid) return false; for (lldb::tid_t tid = 0; tid < num_threads; ++tid) { const ThreadData &td = m_thread_data[tid]; lldb::ThreadSP thread_sp(new ThreadElfCore(*this, td)); new_thread_list.AddThread(thread_sp); } return new_thread_list.GetSize(false) > 0; } void ProcessElfCore::RefreshStateAfterStop() {} Status ProcessElfCore::DoDestroy() { return Status(); } //------------------------------------------------------------------ // Process Queries //------------------------------------------------------------------ bool ProcessElfCore::IsAlive() { return true; } //------------------------------------------------------------------ // Process Memory //------------------------------------------------------------------ size_t ProcessElfCore::ReadMemory(lldb::addr_t addr, void *buf, size_t size, Status &error) { // Don't allow the caching that lldb_private::Process::ReadMemory does since // in core files we have it all cached our our core file anyway. return DoReadMemory(addr, buf, size, error); } Status ProcessElfCore::GetMemoryRegionInfo(lldb::addr_t load_addr, MemoryRegionInfo ®ion_info) { region_info.Clear(); const VMRangeToPermissions::Entry *permission_entry = m_core_range_infos.FindEntryThatContainsOrFollows(load_addr); if (permission_entry) { if (permission_entry->Contains(load_addr)) { region_info.GetRange().SetRangeBase(permission_entry->GetRangeBase()); region_info.GetRange().SetRangeEnd(permission_entry->GetRangeEnd()); const Flags permissions(permission_entry->data); region_info.SetReadable(permissions.Test(lldb::ePermissionsReadable) ? MemoryRegionInfo::eYes : MemoryRegionInfo::eNo); region_info.SetWritable(permissions.Test(lldb::ePermissionsWritable) ? MemoryRegionInfo::eYes : MemoryRegionInfo::eNo); region_info.SetExecutable(permissions.Test(lldb::ePermissionsExecutable) ? MemoryRegionInfo::eYes : MemoryRegionInfo::eNo); region_info.SetMapped(MemoryRegionInfo::eYes); } else if (load_addr < permission_entry->GetRangeBase()) { region_info.GetRange().SetRangeBase(load_addr); region_info.GetRange().SetRangeEnd(permission_entry->GetRangeBase()); region_info.SetReadable(MemoryRegionInfo::eNo); region_info.SetWritable(MemoryRegionInfo::eNo); region_info.SetExecutable(MemoryRegionInfo::eNo); region_info.SetMapped(MemoryRegionInfo::eNo); } return Status(); } region_info.GetRange().SetRangeBase(load_addr); region_info.GetRange().SetRangeEnd(LLDB_INVALID_ADDRESS); region_info.SetReadable(MemoryRegionInfo::eNo); region_info.SetWritable(MemoryRegionInfo::eNo); region_info.SetExecutable(MemoryRegionInfo::eNo); region_info.SetMapped(MemoryRegionInfo::eNo); return Status(); } size_t ProcessElfCore::DoReadMemory(lldb::addr_t addr, void *buf, size_t size, Status &error) { ObjectFile *core_objfile = m_core_module_sp->GetObjectFile(); if (core_objfile == NULL) return 0; // Get the address range const VMRangeToFileOffset::Entry *address_range = m_core_aranges.FindEntryThatContains(addr); if (address_range == NULL || address_range->GetRangeEnd() < addr) { error.SetErrorStringWithFormat("core file does not contain 0x%" PRIx64, addr); return 0; } // Convert the address into core file offset const lldb::addr_t offset = addr - address_range->GetRangeBase(); const lldb::addr_t file_start = address_range->data.GetRangeBase(); const lldb::addr_t file_end = address_range->data.GetRangeEnd(); size_t bytes_to_read = size; // Number of bytes to read from the core file size_t bytes_copied = 0; // Number of bytes actually read from the core file size_t zero_fill_size = 0; // Padding lldb::addr_t bytes_left = 0; // Number of bytes available in the core file from the given address // Don't proceed if core file doesn't contain the actual data for this // address range. if (file_start == file_end) return 0; // Figure out how many on-disk bytes remain in this segment starting at the // given offset if (file_end > file_start + offset) bytes_left = file_end - (file_start + offset); // Figure out how many bytes we need to zero-fill if we are reading more // bytes than available in the on-disk segment if (bytes_to_read > bytes_left) { zero_fill_size = bytes_to_read - bytes_left; bytes_to_read = bytes_left; } // If there is data available on the core file read it if (bytes_to_read) bytes_copied = core_objfile->CopyData(offset + file_start, bytes_to_read, buf); assert(zero_fill_size <= size); // Pad remaining bytes if (zero_fill_size) memset(((char *)buf) + bytes_copied, 0, zero_fill_size); return bytes_copied + zero_fill_size; } void ProcessElfCore::Clear() { m_thread_list.Clear(); SetUnixSignals(std::make_shared()); } void ProcessElfCore::Initialize() { static llvm::once_flag g_once_flag; llvm::call_once(g_once_flag, []() { PluginManager::RegisterPlugin(GetPluginNameStatic(), GetPluginDescriptionStatic(), CreateInstance); }); } lldb::addr_t ProcessElfCore::GetImageInfoAddress() { ObjectFile *obj_file = GetTarget().GetExecutableModule()->GetObjectFile(); Address addr = obj_file->GetImageInfoAddress(&GetTarget()); if (addr.IsValid()) return addr.GetLoadAddress(&GetTarget()); return LLDB_INVALID_ADDRESS; } // Parse a FreeBSD NT_PRSTATUS note - see FreeBSD sys/procfs.h for details. static void ParseFreeBSDPrStatus(ThreadData &thread_data, const DataExtractor &data, const ArchSpec &arch) { lldb::offset_t offset = 0; bool lp64 = (arch.GetMachine() == llvm::Triple::aarch64 || arch.GetMachine() == llvm::Triple::mips64 || arch.GetMachine() == llvm::Triple::ppc64 || arch.GetMachine() == llvm::Triple::x86_64); int pr_version = data.GetU32(&offset); Log *log(GetLogIfAllCategoriesSet(LIBLLDB_LOG_PROCESS)); if (log) { if (pr_version > 1) log->Printf("FreeBSD PRSTATUS unexpected version %d", pr_version); } // Skip padding, pr_statussz, pr_gregsetsz, pr_fpregsetsz, pr_osreldate if (lp64) offset += 32; else offset += 16; thread_data.signo = data.GetU32(&offset); // pr_cursig thread_data.tid = data.GetU32(&offset); // pr_pid if (lp64) offset += 4; size_t len = data.GetByteSize() - offset; thread_data.gpregset = DataExtractor(data, offset, len); } static void ParseNetBSDProcInfo(ThreadData &thread_data, const DataExtractor &data) { lldb::offset_t offset = 0; int version = data.GetU32(&offset); if (version != 1) return; offset += 4; thread_data.signo = data.GetU32(&offset); } static void ParseOpenBSDProcInfo(ThreadData &thread_data, const DataExtractor &data) { lldb::offset_t offset = 0; int version = data.GetU32(&offset); if (version != 1) return; offset += 4; thread_data.signo = data.GetU32(&offset); } llvm::Expected> ProcessElfCore::parseSegment(const DataExtractor &segment) { lldb::offset_t offset = 0; std::vector result; while (offset < segment.GetByteSize()) { ELFNote note = ELFNote(); if (!note.Parse(segment, &offset)) return llvm::make_error( "Unable to parse note segment", llvm::inconvertibleErrorCode()); size_t note_start = offset; size_t note_size = llvm::alignTo(note.n_descsz, 4); DataExtractor note_data(segment, note_start, note_size); result.push_back({note, note_data}); offset += note_size; } return std::move(result); } llvm::Error ProcessElfCore::parseFreeBSDNotes(llvm::ArrayRef notes) { bool have_prstatus = false; bool have_prpsinfo = false; ThreadData thread_data; for (const auto ¬e : notes) { if (note.info.n_name != "FreeBSD") continue; if ((note.info.n_type == FREEBSD::NT_PRSTATUS && have_prstatus) || (note.info.n_type == FREEBSD::NT_PRPSINFO && have_prpsinfo)) { assert(thread_data.gpregset.GetByteSize() > 0); // Add the new thread to thread list m_thread_data.push_back(thread_data); thread_data = ThreadData(); have_prstatus = false; have_prpsinfo = false; } switch (note.info.n_type) { case FREEBSD::NT_PRSTATUS: have_prstatus = true; ParseFreeBSDPrStatus(thread_data, note.data, GetArchitecture()); break; case FREEBSD::NT_PRPSINFO: have_prpsinfo = true; break; case FREEBSD::NT_THRMISC: { lldb::offset_t offset = 0; thread_data.name = note.data.GetCStr(&offset, 20); break; } case FREEBSD::NT_PROCSTAT_AUXV: // FIXME: FreeBSD sticks an int at the beginning of the note m_auxv = DataExtractor(note.data, 4, note.data.GetByteSize() - 4); break; default: thread_data.notes.push_back(note); break; } } if (!have_prstatus) { return llvm::make_error( "Could not find NT_PRSTATUS note in core file.", llvm::inconvertibleErrorCode()); } m_thread_data.push_back(thread_data); return llvm::Error::success(); } llvm::Error ProcessElfCore::parseNetBSDNotes(llvm::ArrayRef notes) { ThreadData thread_data; for (const auto ¬e : notes) { // NetBSD per-thread information is stored in notes named "NetBSD-CORE@nnn" // so match on the initial part of the string. if (!llvm::StringRef(note.info.n_name).startswith("NetBSD-CORE")) continue; switch (note.info.n_type) { case NETBSD::NT_PROCINFO: ParseNetBSDProcInfo(thread_data, note.data); break; case NETBSD::NT_AUXV: m_auxv = note.data; break; case NETBSD::NT_AMD64_REGS: if (GetArchitecture().GetMachine() == llvm::Triple::x86_64) thread_data.gpregset = note.data; break; default: thread_data.notes.push_back(note); break; } } if (thread_data.gpregset.GetByteSize() == 0) { return llvm::make_error( "Could not find general purpose registers note in core file.", llvm::inconvertibleErrorCode()); } m_thread_data.push_back(thread_data); return llvm::Error::success(); } llvm::Error ProcessElfCore::parseOpenBSDNotes(llvm::ArrayRef notes) { ThreadData thread_data; for (const auto ¬e : notes) { // OpenBSD per-thread information is stored in notes named "OpenBSD@nnn" so // match on the initial part of the string. if (!llvm::StringRef(note.info.n_name).startswith("OpenBSD")) continue; switch (note.info.n_type) { case OPENBSD::NT_PROCINFO: ParseOpenBSDProcInfo(thread_data, note.data); break; case OPENBSD::NT_AUXV: m_auxv = note.data; break; case OPENBSD::NT_REGS: thread_data.gpregset = note.data; break; default: thread_data.notes.push_back(note); break; } } if (thread_data.gpregset.GetByteSize() == 0) { return llvm::make_error( "Could not find general purpose registers note in core file.", llvm::inconvertibleErrorCode()); } m_thread_data.push_back(thread_data); return llvm::Error::success(); } /// A description of a linux process usually contains the following NOTE /// entries: /// - NT_PRPSINFO - General process information like pid, uid, name, ... /// - NT_SIGINFO - Information about the signal that terminated the process /// - NT_AUXV - Process auxiliary vector /// - NT_FILE - Files mapped into memory /// /// Additionally, for each thread in the process the core file will contain at /// least the NT_PRSTATUS note, containing the thread id and general purpose /// registers. It may include additional notes for other register sets (floating /// point and vector registers, ...). The tricky part here is that some of these /// notes have "CORE" in their owner fields, while other set it to "LINUX". llvm::Error ProcessElfCore::parseLinuxNotes(llvm::ArrayRef notes) { const ArchSpec &arch = GetArchitecture(); bool have_prstatus = false; bool have_prpsinfo = false; ThreadData thread_data; for (const auto ¬e : notes) { if (note.info.n_name != "CORE" && note.info.n_name != "LINUX") continue; if ((note.info.n_type == LINUX::NT_PRSTATUS && have_prstatus) || (note.info.n_type == LINUX::NT_PRPSINFO && have_prpsinfo)) { assert(thread_data.gpregset.GetByteSize() > 0); // Add the new thread to thread list m_thread_data.push_back(thread_data); thread_data = ThreadData(); have_prstatus = false; have_prpsinfo = false; } switch (note.info.n_type) { case LINUX::NT_PRSTATUS: { have_prstatus = true; ELFLinuxPrStatus prstatus; Status status = prstatus.Parse(note.data, arch); if (status.Fail()) return status.ToError(); thread_data.prstatus_sig = prstatus.pr_cursig; thread_data.tid = prstatus.pr_pid; uint32_t header_size = ELFLinuxPrStatus::GetSize(arch); size_t len = note.data.GetByteSize() - header_size; thread_data.gpregset = DataExtractor(note.data, header_size, len); break; } case LINUX::NT_PRPSINFO: { have_prpsinfo = true; ELFLinuxPrPsInfo prpsinfo; Status status = prpsinfo.Parse(note.data, arch); if (status.Fail()) return status.ToError(); thread_data.name.assign (prpsinfo.pr_fname, strnlen (prpsinfo.pr_fname, sizeof (prpsinfo.pr_fname))); SetID(prpsinfo.pr_pid); break; } case LINUX::NT_SIGINFO: { ELFLinuxSigInfo siginfo; Status status = siginfo.Parse(note.data, arch); if (status.Fail()) return status.ToError(); thread_data.signo = siginfo.si_signo; break; } case LINUX::NT_FILE: { m_nt_file_entries.clear(); lldb::offset_t offset = 0; const uint64_t count = note.data.GetAddress(&offset); note.data.GetAddress(&offset); // Skip page size for (uint64_t i = 0; i < count; ++i) { NT_FILE_Entry entry; entry.start = note.data.GetAddress(&offset); entry.end = note.data.GetAddress(&offset); entry.file_ofs = note.data.GetAddress(&offset); m_nt_file_entries.push_back(entry); } for (uint64_t i = 0; i < count; ++i) { const char *path = note.data.GetCStr(&offset); if (path && path[0]) m_nt_file_entries[i].path.SetCString(path); } break; } case LINUX::NT_AUXV: m_auxv = note.data; break; default: thread_data.notes.push_back(note); break; } } // Add last entry in the note section if (have_prstatus) m_thread_data.push_back(thread_data); return llvm::Error::success(); } /// Parse Thread context from PT_NOTE segment and store it in the thread list /// A note segment consists of one or more NOTE entries, but their types and /// meaning differ depending on the OS. llvm::Error ProcessElfCore::ParseThreadContextsFromNoteSegment( const elf::ELFProgramHeader *segment_header, DataExtractor segment_data) { assert(segment_header && segment_header->p_type == llvm::ELF::PT_NOTE); auto notes_or_error = parseSegment(segment_data); if(!notes_or_error) return notes_or_error.takeError(); switch (GetArchitecture().GetTriple().getOS()) { case llvm::Triple::FreeBSD: return parseFreeBSDNotes(*notes_or_error); case llvm::Triple::Linux: return parseLinuxNotes(*notes_or_error); case llvm::Triple::NetBSD: return parseNetBSDNotes(*notes_or_error); case llvm::Triple::OpenBSD: return parseOpenBSDNotes(*notes_or_error); default: return llvm::make_error( "Don't know how to parse core file. Unsupported OS.", llvm::inconvertibleErrorCode()); } } uint32_t ProcessElfCore::GetNumThreadContexts() { if (!m_thread_data_valid) DoLoadCore(); return m_thread_data.size(); } ArchSpec ProcessElfCore::GetArchitecture() { ArchSpec arch; m_core_module_sp->GetObjectFile()->GetArchitecture(arch); ArchSpec target_arch = GetTarget().GetArchitecture(); arch.MergeFrom(target_arch); // On MIPS there is no way to differentiate betwenn 32bit and 64bit core // files and this information can't be merged in from the target arch so we // fail back to unconditionally returning the target arch in this config. if (target_arch.IsMIPS()) { return target_arch; } return arch; } const lldb::DataBufferSP ProcessElfCore::GetAuxvData() { const uint8_t *start = m_auxv.GetDataStart(); size_t len = m_auxv.GetByteSize(); lldb::DataBufferSP buffer(new lldb_private::DataBufferHeap(start, len)); return buffer; } bool ProcessElfCore::GetProcessInfo(ProcessInstanceInfo &info) { info.Clear(); info.SetProcessID(GetID()); info.SetArchitecture(GetArchitecture()); lldb::ModuleSP module_sp = GetTarget().GetExecutableModule(); if (module_sp) { const bool add_exe_file_as_first_arg = false; info.SetExecutableFile(GetTarget().GetExecutableModule()->GetFileSpec(), add_exe_file_as_first_arg); } return true; }