//===-- DWARFUnit.cpp -------------------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "DWARFUnit.h" #include "lldb/Core/Module.h" #include "lldb/Host/StringConvert.h" #include "lldb/Symbol/CompileUnit.h" #include "lldb/Symbol/LineTable.h" #include "lldb/Symbol/ObjectFile.h" #include "lldb/Utility/LLDBAssert.h" #include "lldb/Utility/StreamString.h" #include "lldb/Utility/Timer.h" #include "DWARFDebugAranges.h" #include "DWARFDebugInfo.h" #include "LogChannelDWARF.h" #include "SymbolFileDWARFDebugMap.h" #include "SymbolFileDWARFDwo.h" using namespace lldb; using namespace lldb_private; using namespace std; extern int g_verbose; DWARFUnit::DWARFUnit(SymbolFileDWARF *dwarf) : m_dwarf(dwarf), m_cancel_scopes(false) {} DWARFUnit::~DWARFUnit() {} // Parses first DIE of a compile unit. void DWARFUnit::ExtractUnitDIEIfNeeded() { { llvm::sys::ScopedReader lock(m_first_die_mutex); if (m_first_die) return; // Already parsed } llvm::sys::ScopedWriter lock(m_first_die_mutex); if (m_first_die) return; // Already parsed static Timer::Category func_cat(LLVM_PRETTY_FUNCTION); Timer scoped_timer( func_cat, "%8.8x: DWARFUnit::ExtractUnitDIEIfNeeded()", m_offset); // Set the offset to that of the first DIE and calculate the start of the // next compilation unit header. lldb::offset_t offset = GetFirstDIEOffset(); // We are in our compile unit, parse starting at the offset we were told to // parse const DWARFDataExtractor &data = GetData(); DWARFFormValue::FixedFormSizes fixed_form_sizes = DWARFFormValue::GetFixedFormSizesForAddressSize(GetAddressByteSize()); if (offset < GetNextCompileUnitOffset() && m_first_die.FastExtract(data, this, fixed_form_sizes, &offset)) { AddUnitDIE(m_first_die); return; } } // Parses a compile unit and indexes its DIEs if it hasn't already been done. // It will leave this compile unit extracted forever. void DWARFUnit::ExtractDIEsIfNeeded() { m_cancel_scopes = true; { llvm::sys::ScopedReader lock(m_die_array_mutex); if (!m_die_array.empty()) return; // Already parsed } llvm::sys::ScopedWriter lock(m_die_array_mutex); if (!m_die_array.empty()) return; // Already parsed ExtractDIEsRWLocked(); } // Parses a compile unit and indexes its DIEs if it hasn't already been done. // It will clear this compile unit after returned instance gets out of scope, // no other ScopedExtractDIEs instance is running for this compile unit // and no ExtractDIEsIfNeeded() has been executed during this ScopedExtractDIEs // lifetime. DWARFUnit::ScopedExtractDIEs DWARFUnit::ExtractDIEsScoped() { ScopedExtractDIEs scoped(this); { llvm::sys::ScopedReader lock(m_die_array_mutex); if (!m_die_array.empty()) return scoped; // Already parsed } llvm::sys::ScopedWriter lock(m_die_array_mutex); if (!m_die_array.empty()) return scoped; // Already parsed // Otherwise m_die_array would be already populated. lldbassert(!m_cancel_scopes); ExtractDIEsRWLocked(); scoped.m_clear_dies = true; return scoped; } DWARFUnit::ScopedExtractDIEs::ScopedExtractDIEs(DWARFUnit *cu) : m_cu(cu) { lldbassert(m_cu); m_cu->m_die_array_scoped_mutex.lock_shared(); } DWARFUnit::ScopedExtractDIEs::~ScopedExtractDIEs() { if (!m_cu) return; m_cu->m_die_array_scoped_mutex.unlock_shared(); if (!m_clear_dies || m_cu->m_cancel_scopes) return; // Be sure no other ScopedExtractDIEs is running anymore. llvm::sys::ScopedWriter lock_scoped(m_cu->m_die_array_scoped_mutex); llvm::sys::ScopedWriter lock(m_cu->m_die_array_mutex); if (m_cu->m_cancel_scopes) return; m_cu->ClearDIEsRWLocked(); } DWARFUnit::ScopedExtractDIEs::ScopedExtractDIEs(ScopedExtractDIEs &&rhs) : m_cu(rhs.m_cu), m_clear_dies(rhs.m_clear_dies) { rhs.m_cu = nullptr; } DWARFUnit::ScopedExtractDIEs &DWARFUnit::ScopedExtractDIEs::operator=( DWARFUnit::ScopedExtractDIEs &&rhs) { m_cu = rhs.m_cu; rhs.m_cu = nullptr; m_clear_dies = rhs.m_clear_dies; return *this; } // Parses a compile unit and indexes its DIEs, m_die_array_mutex must be // held R/W and m_die_array must be empty. void DWARFUnit::ExtractDIEsRWLocked() { llvm::sys::ScopedWriter first_die_lock(m_first_die_mutex); static Timer::Category func_cat(LLVM_PRETTY_FUNCTION); Timer scoped_timer( func_cat, "%8.8x: DWARFUnit::ExtractDIEsIfNeeded()", m_offset); // Set the offset to that of the first DIE and calculate the start of the // next compilation unit header. lldb::offset_t offset = GetFirstDIEOffset(); lldb::offset_t next_cu_offset = GetNextCompileUnitOffset(); DWARFDebugInfoEntry die; uint32_t depth = 0; // We are in our compile unit, parse starting at the offset we were told to // parse const DWARFDataExtractor &data = GetData(); std::vector die_index_stack; die_index_stack.reserve(32); die_index_stack.push_back(0); bool prev_die_had_children = false; DWARFFormValue::FixedFormSizes fixed_form_sizes = DWARFFormValue::GetFixedFormSizesForAddressSize(GetAddressByteSize()); while (offset < next_cu_offset && die.FastExtract(data, this, fixed_form_sizes, &offset)) { const bool null_die = die.IsNULL(); if (depth == 0) { assert(m_die_array.empty() && "Compile unit DIE already added"); // The average bytes per DIE entry has been seen to be around 14-20 so // lets pre-reserve half of that since we are now stripping the NULL // tags. // Only reserve the memory if we are adding children of the main // compile unit DIE. The compile unit DIE is always the first entry, so // if our size is 1, then we are adding the first compile unit child // DIE and should reserve the memory. m_die_array.reserve(GetDebugInfoSize() / 24); m_die_array.push_back(die); if (!m_first_die) AddUnitDIE(m_die_array.front()); } else { if (null_die) { if (prev_die_had_children) { // This will only happen if a DIE says is has children but all it // contains is a NULL tag. Since we are removing the NULL DIEs from // the list (saves up to 25% in C++ code), we need a way to let the // DIE know that it actually doesn't have children. if (!m_die_array.empty()) m_die_array.back().SetHasChildren(false); } } else { die.SetParentIndex(m_die_array.size() - die_index_stack[depth - 1]); if (die_index_stack.back()) m_die_array[die_index_stack.back()].SetSiblingIndex( m_die_array.size() - die_index_stack.back()); // Only push the DIE if it isn't a NULL DIE m_die_array.push_back(die); } } if (null_die) { // NULL DIE. if (!die_index_stack.empty()) die_index_stack.pop_back(); if (depth > 0) --depth; prev_die_had_children = false; } else { die_index_stack.back() = m_die_array.size() - 1; // Normal DIE const bool die_has_children = die.HasChildren(); if (die_has_children) { die_index_stack.push_back(0); ++depth; } prev_die_had_children = die_has_children; } if (depth == 0) break; // We are done with this compile unit! } if (!m_die_array.empty()) { if (m_first_die) { // Only needed for the assertion. m_first_die.SetHasChildren(m_die_array.front().HasChildren()); lldbassert(m_first_die == m_die_array.front()); } m_first_die = m_die_array.front(); } m_die_array.shrink_to_fit(); if (m_dwo_symbol_file) { DWARFUnit *dwo_cu = m_dwo_symbol_file->GetCompileUnit(); dwo_cu->ExtractDIEsIfNeeded(); } } // This is used when a split dwarf is enabled. // A skeleton compilation unit may contain the DW_AT_str_offsets_base attribute // that points to the first string offset of the CU contribution to the // .debug_str_offsets. At the same time, the corresponding split debug unit also // may use DW_FORM_strx* forms pointing to its own .debug_str_offsets.dwo and // for that case, we should find the offset (skip the section header). static void SetDwoStrOffsetsBase(DWARFUnit *dwo_cu) { lldb::offset_t baseOffset = 0; const DWARFDataExtractor &strOffsets = dwo_cu->GetSymbolFileDWARF()->get_debug_str_offsets_data(); uint64_t length = strOffsets.GetU32(&baseOffset); if (length == 0xffffffff) length = strOffsets.GetU64(&baseOffset); // Check version. if (strOffsets.GetU16(&baseOffset) < 5) return; // Skip padding. baseOffset += 2; dwo_cu->SetStrOffsetsBase(baseOffset); } // m_die_array_mutex must be already held as read/write. void DWARFUnit::AddUnitDIE(const DWARFDebugInfoEntry &cu_die) { dw_addr_t addr_base = cu_die.GetAttributeValueAsUnsigned( m_dwarf, this, DW_AT_addr_base, LLDB_INVALID_ADDRESS); if (addr_base != LLDB_INVALID_ADDRESS) SetAddrBase(addr_base); dw_addr_t ranges_base = cu_die.GetAttributeValueAsUnsigned( m_dwarf, this, DW_AT_rnglists_base, LLDB_INVALID_ADDRESS); if (ranges_base != LLDB_INVALID_ADDRESS) SetRangesBase(ranges_base); SetStrOffsetsBase(cu_die.GetAttributeValueAsUnsigned( m_dwarf, this, DW_AT_str_offsets_base, 0)); uint64_t base_addr = cu_die.GetAttributeValueAsAddress( m_dwarf, this, DW_AT_low_pc, LLDB_INVALID_ADDRESS); if (base_addr == LLDB_INVALID_ADDRESS) base_addr = cu_die.GetAttributeValueAsAddress( m_dwarf, this, DW_AT_entry_pc, 0); SetBaseAddress(base_addr); std::unique_ptr dwo_symbol_file = m_dwarf->GetDwoSymbolFileForCompileUnit(*this, cu_die); if (!dwo_symbol_file) return; DWARFUnit *dwo_cu = dwo_symbol_file->GetCompileUnit(); if (!dwo_cu) return; // Can't fetch the compile unit from the dwo file. DWARFBaseDIE dwo_cu_die = dwo_cu->GetUnitDIEOnly(); if (!dwo_cu_die.IsValid()) return; // Can't fetch the compile unit DIE from the dwo file. uint64_t main_dwo_id = cu_die.GetAttributeValueAsUnsigned(m_dwarf, this, DW_AT_GNU_dwo_id, 0); uint64_t sub_dwo_id = dwo_cu_die.GetAttributeValueAsUnsigned(DW_AT_GNU_dwo_id, 0); if (main_dwo_id != sub_dwo_id) return; // The 2 dwo ID isn't match. Don't use the dwo file as it belongs to // a differectn compilation. m_dwo_symbol_file = std::move(dwo_symbol_file); // Here for DWO CU we want to use the address base set in the skeleton unit // (DW_AT_addr_base) if it is available and use the DW_AT_GNU_addr_base // otherwise. We do that because pre-DWARF v5 could use the DW_AT_GNU_* // attributes which were applicable to the DWO units. The corresponding // DW_AT_* attributes standardized in DWARF v5 are also applicable to the main // unit in contrast. if (addr_base == LLDB_INVALID_ADDRESS) addr_base = cu_die.GetAttributeValueAsUnsigned(m_dwarf, this, DW_AT_GNU_addr_base, 0); dwo_cu->SetAddrBase(addr_base); if (ranges_base == LLDB_INVALID_ADDRESS) ranges_base = cu_die.GetAttributeValueAsUnsigned(m_dwarf, this, DW_AT_GNU_ranges_base, 0); dwo_cu->SetRangesBase(ranges_base); dwo_cu->SetBaseObjOffset(m_offset); SetDwoStrOffsetsBase(dwo_cu); } DWARFDIE DWARFUnit::LookupAddress(const dw_addr_t address) { if (DIE()) { const DWARFDebugAranges &func_aranges = GetFunctionAranges(); // Re-check the aranges auto pointer contents in case it was created above if (!func_aranges.IsEmpty()) return GetDIE(func_aranges.FindAddress(address)); } return DWARFDIE(); } size_t DWARFUnit::AppendDIEsWithTag(const dw_tag_t tag, std::vector &dies, uint32_t depth) const { size_t old_size = dies.size(); { llvm::sys::ScopedReader lock(m_die_array_mutex); DWARFDebugInfoEntry::const_iterator pos; DWARFDebugInfoEntry::const_iterator end = m_die_array.end(); for (pos = m_die_array.begin(); pos != end; ++pos) { if (pos->Tag() == tag) dies.emplace_back(this, &(*pos)); } } // Return the number of DIEs added to the collection return dies.size() - old_size; } lldb::user_id_t DWARFUnit::GetID() const { dw_offset_t local_id = m_base_obj_offset != DW_INVALID_OFFSET ? m_base_obj_offset : m_offset; if (m_dwarf) return DIERef(local_id, local_id).GetUID(m_dwarf); else return local_id; } dw_offset_t DWARFUnit::GetNextCompileUnitOffset() const { return m_offset + GetLengthByteSize() + GetLength(); } size_t DWARFUnit::GetDebugInfoSize() const { return GetLengthByteSize() + GetLength() - GetHeaderByteSize(); } const DWARFAbbreviationDeclarationSet *DWARFUnit::GetAbbreviations() const { return m_abbrevs; } dw_offset_t DWARFUnit::GetAbbrevOffset() const { return m_abbrevs ? m_abbrevs->GetOffset() : DW_INVALID_OFFSET; } void DWARFUnit::SetAddrBase(dw_addr_t addr_base) { m_addr_base = addr_base; } void DWARFUnit::SetRangesBase(dw_addr_t ranges_base) { m_ranges_base = ranges_base; } void DWARFUnit::SetBaseObjOffset(dw_offset_t base_obj_offset) { m_base_obj_offset = base_obj_offset; } void DWARFUnit::SetStrOffsetsBase(dw_offset_t str_offsets_base) { m_str_offsets_base = str_offsets_base; } // It may be called only with m_die_array_mutex held R/W. void DWARFUnit::ClearDIEsRWLocked() { m_die_array.clear(); m_die_array.shrink_to_fit(); if (m_dwo_symbol_file) m_dwo_symbol_file->GetCompileUnit()->ClearDIEsRWLocked(); } void DWARFUnit::BuildAddressRangeTable(SymbolFileDWARF *dwarf, DWARFDebugAranges *debug_aranges) { // This function is usually called if there in no .debug_aranges section in // order to produce a compile unit level set of address ranges that is // accurate. size_t num_debug_aranges = debug_aranges->GetNumRanges(); // First get the compile unit DIE only and check if it has a DW_AT_ranges const DWARFDebugInfoEntry *die = GetUnitDIEPtrOnly(); const dw_offset_t cu_offset = GetOffset(); if (die) { DWARFRangeList ranges; const size_t num_ranges = die->GetAttributeAddressRanges(dwarf, this, ranges, false); if (num_ranges > 0) { // This compile unit has DW_AT_ranges, assume this is correct if it is // present since clang no longer makes .debug_aranges by default and it // emits DW_AT_ranges for DW_TAG_compile_units. GCC also does this with // recent GCC builds. for (size_t i = 0; i < num_ranges; ++i) { const DWARFRangeList::Entry &range = ranges.GetEntryRef(i); debug_aranges->AppendRange(cu_offset, range.GetRangeBase(), range.GetRangeEnd()); } return; // We got all of our ranges from the DW_AT_ranges attribute } } // We don't have a DW_AT_ranges attribute, so we need to parse the DWARF // If the DIEs weren't parsed, then we don't want all dies for all compile // units to stay loaded when they weren't needed. So we can end up parsing // the DWARF and then throwing them all away to keep memory usage down. ScopedExtractDIEs clear_dies(ExtractDIEsScoped()); die = DIEPtr(); if (die) die->BuildAddressRangeTable(dwarf, this, debug_aranges); if (debug_aranges->GetNumRanges() == num_debug_aranges) { // We got nothing from the functions, maybe we have a line tables only // situation. Check the line tables and build the arange table from this. SymbolContext sc; sc.comp_unit = dwarf->GetCompUnitForDWARFCompUnit(this); if (sc.comp_unit) { SymbolFileDWARFDebugMap *debug_map_sym_file = m_dwarf->GetDebugMapSymfile(); if (debug_map_sym_file == NULL) { LineTable *line_table = sc.comp_unit->GetLineTable(); if (line_table) { LineTable::FileAddressRanges file_ranges; const bool append = true; const size_t num_ranges = line_table->GetContiguousFileAddressRanges(file_ranges, append); for (uint32_t idx = 0; idx < num_ranges; ++idx) { const LineTable::FileAddressRanges::Entry &range = file_ranges.GetEntryRef(idx); debug_aranges->AppendRange(cu_offset, range.GetRangeBase(), range.GetRangeEnd()); } } } else debug_map_sym_file->AddOSOARanges(dwarf, debug_aranges); } } if (debug_aranges->GetNumRanges() == num_debug_aranges) { // We got nothing from the functions, maybe we have a line tables only // situation. Check the line tables and build the arange table from this. SymbolContext sc; sc.comp_unit = dwarf->GetCompUnitForDWARFCompUnit(this); if (sc.comp_unit) { LineTable *line_table = sc.comp_unit->GetLineTable(); if (line_table) { LineTable::FileAddressRanges file_ranges; const bool append = true; const size_t num_ranges = line_table->GetContiguousFileAddressRanges(file_ranges, append); for (uint32_t idx = 0; idx < num_ranges; ++idx) { const LineTable::FileAddressRanges::Entry &range = file_ranges.GetEntryRef(idx); debug_aranges->AppendRange(GetOffset(), range.GetRangeBase(), range.GetRangeEnd()); } } } } } lldb::ByteOrder DWARFUnit::GetByteOrder() const { return m_dwarf->GetObjectFile()->GetByteOrder(); } TypeSystem *DWARFUnit::GetTypeSystem() { if (m_dwarf) return m_dwarf->GetTypeSystemForLanguage(GetLanguageType()); else return nullptr; } DWARFFormValue::FixedFormSizes DWARFUnit::GetFixedFormSizes() { return DWARFFormValue::GetFixedFormSizesForAddressSize(GetAddressByteSize()); } void DWARFUnit::SetBaseAddress(dw_addr_t base_addr) { m_base_addr = base_addr; } // Compare function DWARFDebugAranges::Range structures static bool CompareDIEOffset(const DWARFDebugInfoEntry &die, const dw_offset_t die_offset) { return die.GetOffset() < die_offset; } // GetDIE() // // Get the DIE (Debug Information Entry) with the specified offset by first // checking if the DIE is contained within this compile unit and grabbing the // DIE from this compile unit. Otherwise we grab the DIE from the DWARF file. DWARFDIE DWARFUnit::GetDIE(dw_offset_t die_offset) { if (die_offset != DW_INVALID_OFFSET) { if (GetDwoSymbolFile()) return GetDwoSymbolFile()->GetCompileUnit()->GetDIE(die_offset); if (ContainsDIEOffset(die_offset)) { ExtractDIEsIfNeeded(); DWARFDebugInfoEntry::const_iterator end = m_die_array.cend(); DWARFDebugInfoEntry::const_iterator pos = lower_bound(m_die_array.cbegin(), end, die_offset, CompareDIEOffset); if (pos != end) { if (die_offset == (*pos).GetOffset()) return DWARFDIE(this, &(*pos)); } } else { // Don't specify the compile unit offset as we don't know it because the // DIE belongs to // a different compile unit in the same symbol file. return m_dwarf->DebugInfo()->GetDIEForDIEOffset(die_offset); } } return DWARFDIE(); // Not found } uint8_t DWARFUnit::GetAddressByteSize(const DWARFUnit *cu) { if (cu) return cu->GetAddressByteSize(); return DWARFUnit::GetDefaultAddressSize(); } uint8_t DWARFUnit::GetDefaultAddressSize() { return 4; } void *DWARFUnit::GetUserData() const { return m_user_data; } void DWARFUnit::SetUserData(void *d) { m_user_data = d; if (m_dwo_symbol_file) m_dwo_symbol_file->GetCompileUnit()->SetUserData(d); } bool DWARFUnit::Supports_DW_AT_APPLE_objc_complete_type() { return GetProducer() != eProducerLLVMGCC; } bool DWARFUnit::DW_AT_decl_file_attributes_are_invalid() { // llvm-gcc makes completely invalid decl file attributes and won't ever be // fixed, so we need to know to ignore these. return GetProducer() == eProducerLLVMGCC; } bool DWARFUnit::Supports_unnamed_objc_bitfields() { if (GetProducer() == eProducerClang) { const uint32_t major_version = GetProducerVersionMajor(); return major_version > 425 || (major_version == 425 && GetProducerVersionUpdate() >= 13); } return true; // Assume all other compilers didn't have incorrect ObjC bitfield // info } SymbolFileDWARF *DWARFUnit::GetSymbolFileDWARF() const { return m_dwarf; } void DWARFUnit::ParseProducerInfo() { m_producer_version_major = UINT32_MAX; m_producer_version_minor = UINT32_MAX; m_producer_version_update = UINT32_MAX; const DWARFDebugInfoEntry *die = GetUnitDIEPtrOnly(); if (die) { const char *producer_cstr = die->GetAttributeValueAsString(m_dwarf, this, DW_AT_producer, NULL); if (producer_cstr) { RegularExpression llvm_gcc_regex( llvm::StringRef("^4\\.[012]\\.[01] \\(Based on Apple " "Inc\\. build [0-9]+\\) \\(LLVM build " "[\\.0-9]+\\)$")); if (llvm_gcc_regex.Execute(llvm::StringRef(producer_cstr))) { m_producer = eProducerLLVMGCC; } else if (strstr(producer_cstr, "clang")) { static RegularExpression g_clang_version_regex( llvm::StringRef("clang-([0-9]+)\\.([0-9]+)\\.([0-9]+)")); RegularExpression::Match regex_match(3); if (g_clang_version_regex.Execute(llvm::StringRef(producer_cstr), ®ex_match)) { std::string str; if (regex_match.GetMatchAtIndex(producer_cstr, 1, str)) m_producer_version_major = StringConvert::ToUInt32(str.c_str(), UINT32_MAX, 10); if (regex_match.GetMatchAtIndex(producer_cstr, 2, str)) m_producer_version_minor = StringConvert::ToUInt32(str.c_str(), UINT32_MAX, 10); if (regex_match.GetMatchAtIndex(producer_cstr, 3, str)) m_producer_version_update = StringConvert::ToUInt32(str.c_str(), UINT32_MAX, 10); } m_producer = eProducerClang; } else if (strstr(producer_cstr, "GNU")) m_producer = eProducerGCC; } } if (m_producer == eProducerInvalid) m_producer = eProcucerOther; } DWARFProducer DWARFUnit::GetProducer() { if (m_producer == eProducerInvalid) ParseProducerInfo(); return m_producer; } uint32_t DWARFUnit::GetProducerVersionMajor() { if (m_producer_version_major == 0) ParseProducerInfo(); return m_producer_version_major; } uint32_t DWARFUnit::GetProducerVersionMinor() { if (m_producer_version_minor == 0) ParseProducerInfo(); return m_producer_version_minor; } uint32_t DWARFUnit::GetProducerVersionUpdate() { if (m_producer_version_update == 0) ParseProducerInfo(); return m_producer_version_update; } LanguageType DWARFUnit::LanguageTypeFromDWARF(uint64_t val) { // Note: user languages between lo_user and hi_user must be handled // explicitly here. switch (val) { case DW_LANG_Mips_Assembler: return eLanguageTypeMipsAssembler; case DW_LANG_GOOGLE_RenderScript: return eLanguageTypeExtRenderScript; default: return static_cast(val); } } LanguageType DWARFUnit::GetLanguageType() { if (m_language_type != eLanguageTypeUnknown) return m_language_type; const DWARFDebugInfoEntry *die = GetUnitDIEPtrOnly(); if (die) m_language_type = LanguageTypeFromDWARF( die->GetAttributeValueAsUnsigned(m_dwarf, this, DW_AT_language, 0)); return m_language_type; } bool DWARFUnit::GetIsOptimized() { if (m_is_optimized == eLazyBoolCalculate) { const DWARFDebugInfoEntry *die = GetUnitDIEPtrOnly(); if (die) { m_is_optimized = eLazyBoolNo; if (die->GetAttributeValueAsUnsigned(m_dwarf, this, DW_AT_APPLE_optimized, 0) == 1) { m_is_optimized = eLazyBoolYes; } } } return m_is_optimized == eLazyBoolYes; } FileSpec::Style DWARFUnit::GetPathStyle() { if (!m_comp_dir) ComputeCompDirAndGuessPathStyle(); return m_comp_dir->GetPathStyle(); } const FileSpec &DWARFUnit::GetCompilationDirectory() { if (!m_comp_dir) ComputeCompDirAndGuessPathStyle(); return *m_comp_dir; } // DWARF2/3 suggests the form hostname:pathname for compilation directory. // Remove the host part if present. static llvm::StringRef removeHostnameFromPathname(llvm::StringRef path_from_dwarf) { llvm::StringRef host, path; std::tie(host, path) = path_from_dwarf.split(':'); if (host.contains('/')) return path_from_dwarf; // check whether we have a windows path, and so the first character is a // drive-letter not a hostname. if (host.size() == 1 && llvm::isAlpha(host[0]) && path.startswith("\\")) return path_from_dwarf; return path; } static FileSpec resolveCompDir(const FileSpec &path) { bool is_symlink = SymbolFileDWARF::GetSymlinkPaths().FindFileIndex( 0, path, /*full*/ true) != UINT32_MAX; if (!is_symlink) return path; namespace fs = llvm::sys::fs; if (fs::get_file_type(path.GetPath(), false) != fs::file_type::symlink_file) return path; FileSpec resolved_symlink; const auto error = FileSystem::Instance().Readlink(path, resolved_symlink); if (error.Success()) return resolved_symlink; return path; } void DWARFUnit::ComputeCompDirAndGuessPathStyle() { m_comp_dir = FileSpec(); const DWARFDebugInfoEntry *die = GetUnitDIEPtrOnly(); if (!die) return; llvm::StringRef comp_dir = removeHostnameFromPathname( die->GetAttributeValueAsString(m_dwarf, this, DW_AT_comp_dir, NULL)); if (!comp_dir.empty()) { FileSpec::Style comp_dir_style = FileSpec::GuessPathStyle(comp_dir).getValueOr(FileSpec::Style::native); m_comp_dir = resolveCompDir(FileSpec(comp_dir, comp_dir_style)); } else { // Try to detect the style based on the DW_AT_name attribute, but just store // the detected style in the m_comp_dir field. const char *name = die->GetAttributeValueAsString(m_dwarf, this, DW_AT_name, NULL); m_comp_dir = FileSpec( "", FileSpec::GuessPathStyle(name).getValueOr(FileSpec::Style::native)); } } SymbolFileDWARFDwo *DWARFUnit::GetDwoSymbolFile() const { return m_dwo_symbol_file.get(); } dw_offset_t DWARFUnit::GetBaseObjOffset() const { return m_base_obj_offset; } const DWARFDebugAranges &DWARFUnit::GetFunctionAranges() { if (m_func_aranges_up == NULL) { m_func_aranges_up.reset(new DWARFDebugAranges()); const DWARFDebugInfoEntry *die = DIEPtr(); if (die) die->BuildFunctionAddressRangeTable(m_dwarf, this, m_func_aranges_up.get()); if (m_dwo_symbol_file) { DWARFUnit *dwo_cu = m_dwo_symbol_file->GetCompileUnit(); const DWARFDebugInfoEntry *dwo_die = dwo_cu->DIEPtr(); if (dwo_die) dwo_die->BuildFunctionAddressRangeTable(m_dwo_symbol_file.get(), dwo_cu, m_func_aranges_up.get()); } const bool minimize = false; m_func_aranges_up->Sort(minimize); } return *m_func_aranges_up; }