//===- DWARFEmitter - Convert YAML to DWARF binary data -------------------===// // // 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 // //===----------------------------------------------------------------------===// /// /// \file /// The DWARF component of yaml2obj. Provided as library code for tests. /// //===----------------------------------------------------------------------===// #include "llvm/ObjectYAML/DWARFEmitter.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/StringSwitch.h" #include "llvm/BinaryFormat/Dwarf.h" #include "llvm/ObjectYAML/DWARFYAML.h" #include "llvm/Support/Errc.h" #include "llvm/Support/Error.h" #include "llvm/Support/LEB128.h" #include "llvm/Support/MathExtras.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Support/SwapByteOrder.h" #include "llvm/Support/YAMLTraits.h" #include "llvm/Support/raw_ostream.h" #include "llvm/TargetParser/Host.h" #include #include #include #include #include #include #include #include using namespace llvm; template static void writeInteger(T Integer, raw_ostream &OS, bool IsLittleEndian) { if (IsLittleEndian != sys::IsLittleEndianHost) sys::swapByteOrder(Integer); OS.write(reinterpret_cast(&Integer), sizeof(T)); } static Error writeVariableSizedInteger(uint64_t Integer, size_t Size, raw_ostream &OS, bool IsLittleEndian) { if (8 == Size) writeInteger((uint64_t)Integer, OS, IsLittleEndian); else if (4 == Size) writeInteger((uint32_t)Integer, OS, IsLittleEndian); else if (2 == Size) writeInteger((uint16_t)Integer, OS, IsLittleEndian); else if (1 == Size) writeInteger((uint8_t)Integer, OS, IsLittleEndian); else return createStringError(errc::not_supported, "invalid integer write size: %zu", Size); return Error::success(); } static void ZeroFillBytes(raw_ostream &OS, size_t Size) { std::vector FillData(Size, 0); OS.write(reinterpret_cast(FillData.data()), Size); } static void writeInitialLength(const dwarf::DwarfFormat Format, const uint64_t Length, raw_ostream &OS, bool IsLittleEndian) { bool IsDWARF64 = Format == dwarf::DWARF64; if (IsDWARF64) cantFail(writeVariableSizedInteger(dwarf::DW_LENGTH_DWARF64, 4, OS, IsLittleEndian)); cantFail( writeVariableSizedInteger(Length, IsDWARF64 ? 8 : 4, OS, IsLittleEndian)); } static void writeDWARFOffset(uint64_t Offset, dwarf::DwarfFormat Format, raw_ostream &OS, bool IsLittleEndian) { cantFail(writeVariableSizedInteger(Offset, Format == dwarf::DWARF64 ? 8 : 4, OS, IsLittleEndian)); } Error DWARFYAML::emitDebugStr(raw_ostream &OS, const DWARFYAML::Data &DI) { for (StringRef Str : *DI.DebugStrings) { OS.write(Str.data(), Str.size()); OS.write('\0'); } return Error::success(); } StringRef DWARFYAML::Data::getAbbrevTableContentByIndex(uint64_t Index) const { assert(Index < DebugAbbrev.size() && "Index should be less than the size of DebugAbbrev array"); auto It = AbbrevTableContents.find(Index); if (It != AbbrevTableContents.cend()) return It->second; std::string AbbrevTableBuffer; raw_string_ostream OS(AbbrevTableBuffer); uint64_t AbbrevCode = 0; for (const DWARFYAML::Abbrev &AbbrevDecl : DebugAbbrev[Index].Table) { AbbrevCode = AbbrevDecl.Code ? (uint64_t)*AbbrevDecl.Code : AbbrevCode + 1; encodeULEB128(AbbrevCode, OS); encodeULEB128(AbbrevDecl.Tag, OS); OS.write(AbbrevDecl.Children); for (const auto &Attr : AbbrevDecl.Attributes) { encodeULEB128(Attr.Attribute, OS); encodeULEB128(Attr.Form, OS); if (Attr.Form == dwarf::DW_FORM_implicit_const) encodeSLEB128(Attr.Value, OS); } encodeULEB128(0, OS); encodeULEB128(0, OS); } // The abbreviations for a given compilation unit end with an entry // consisting of a 0 byte for the abbreviation code. OS.write_zeros(1); AbbrevTableContents.insert({Index, AbbrevTableBuffer}); return AbbrevTableContents[Index]; } Error DWARFYAML::emitDebugAbbrev(raw_ostream &OS, const DWARFYAML::Data &DI) { for (uint64_t I = 0; I < DI.DebugAbbrev.size(); ++I) { StringRef AbbrevTableContent = DI.getAbbrevTableContentByIndex(I); OS.write(AbbrevTableContent.data(), AbbrevTableContent.size()); } return Error::success(); } Error DWARFYAML::emitDebugAranges(raw_ostream &OS, const DWARFYAML::Data &DI) { assert(DI.DebugAranges && "unexpected emitDebugAranges() call"); for (const auto &Range : *DI.DebugAranges) { uint8_t AddrSize; if (Range.AddrSize) AddrSize = *Range.AddrSize; else AddrSize = DI.Is64BitAddrSize ? 8 : 4; uint64_t Length = 4; // sizeof(version) 2 + sizeof(address_size) 1 + // sizeof(segment_selector_size) 1 Length += Range.Format == dwarf::DWARF64 ? 8 : 4; // sizeof(debug_info_offset) const uint64_t HeaderLength = Length + (Range.Format == dwarf::DWARF64 ? 12 : 4); // sizeof(unit_header) = 12 (DWARF64) or 4 (DWARF32) const uint64_t PaddedHeaderLength = alignTo(HeaderLength, AddrSize * 2); if (Range.Length) { Length = *Range.Length; } else { Length += PaddedHeaderLength - HeaderLength; Length += AddrSize * 2 * (Range.Descriptors.size() + 1); } writeInitialLength(Range.Format, Length, OS, DI.IsLittleEndian); writeInteger((uint16_t)Range.Version, OS, DI.IsLittleEndian); writeDWARFOffset(Range.CuOffset, Range.Format, OS, DI.IsLittleEndian); writeInteger((uint8_t)AddrSize, OS, DI.IsLittleEndian); writeInteger((uint8_t)Range.SegSize, OS, DI.IsLittleEndian); ZeroFillBytes(OS, PaddedHeaderLength - HeaderLength); for (const auto &Descriptor : Range.Descriptors) { if (Error Err = writeVariableSizedInteger(Descriptor.Address, AddrSize, OS, DI.IsLittleEndian)) return createStringError(errc::not_supported, "unable to write debug_aranges address: %s", toString(std::move(Err)).c_str()); cantFail(writeVariableSizedInteger(Descriptor.Length, AddrSize, OS, DI.IsLittleEndian)); } ZeroFillBytes(OS, AddrSize * 2); } return Error::success(); } Error DWARFYAML::emitDebugRanges(raw_ostream &OS, const DWARFYAML::Data &DI) { const size_t RangesOffset = OS.tell(); uint64_t EntryIndex = 0; for (const auto &DebugRanges : *DI.DebugRanges) { const size_t CurrOffset = OS.tell() - RangesOffset; if (DebugRanges.Offset && (uint64_t)*DebugRanges.Offset < CurrOffset) return createStringError(errc::invalid_argument, "'Offset' for 'debug_ranges' with index " + Twine(EntryIndex) + " must be greater than or equal to the " "number of bytes written already (0x" + Twine::utohexstr(CurrOffset) + ")"); if (DebugRanges.Offset) ZeroFillBytes(OS, *DebugRanges.Offset - CurrOffset); uint8_t AddrSize; if (DebugRanges.AddrSize) AddrSize = *DebugRanges.AddrSize; else AddrSize = DI.Is64BitAddrSize ? 8 : 4; for (const auto &Entry : DebugRanges.Entries) { if (Error Err = writeVariableSizedInteger(Entry.LowOffset, AddrSize, OS, DI.IsLittleEndian)) return createStringError( errc::not_supported, "unable to write debug_ranges address offset: %s", toString(std::move(Err)).c_str()); cantFail(writeVariableSizedInteger(Entry.HighOffset, AddrSize, OS, DI.IsLittleEndian)); } ZeroFillBytes(OS, AddrSize * 2); ++EntryIndex; } return Error::success(); } static Error emitPubSection(raw_ostream &OS, const DWARFYAML::PubSection &Sect, bool IsLittleEndian, bool IsGNUPubSec = false) { writeInitialLength(Sect.Format, Sect.Length, OS, IsLittleEndian); writeInteger((uint16_t)Sect.Version, OS, IsLittleEndian); writeInteger((uint32_t)Sect.UnitOffset, OS, IsLittleEndian); writeInteger((uint32_t)Sect.UnitSize, OS, IsLittleEndian); for (const auto &Entry : Sect.Entries) { writeInteger((uint32_t)Entry.DieOffset, OS, IsLittleEndian); if (IsGNUPubSec) writeInteger((uint8_t)Entry.Descriptor, OS, IsLittleEndian); OS.write(Entry.Name.data(), Entry.Name.size()); OS.write('\0'); } return Error::success(); } Error DWARFYAML::emitDebugPubnames(raw_ostream &OS, const Data &DI) { assert(DI.PubNames && "unexpected emitDebugPubnames() call"); return emitPubSection(OS, *DI.PubNames, DI.IsLittleEndian); } Error DWARFYAML::emitDebugPubtypes(raw_ostream &OS, const Data &DI) { assert(DI.PubTypes && "unexpected emitDebugPubtypes() call"); return emitPubSection(OS, *DI.PubTypes, DI.IsLittleEndian); } Error DWARFYAML::emitDebugGNUPubnames(raw_ostream &OS, const Data &DI) { assert(DI.GNUPubNames && "unexpected emitDebugGNUPubnames() call"); return emitPubSection(OS, *DI.GNUPubNames, DI.IsLittleEndian, /*IsGNUStyle=*/true); } Error DWARFYAML::emitDebugGNUPubtypes(raw_ostream &OS, const Data &DI) { assert(DI.GNUPubTypes && "unexpected emitDebugGNUPubtypes() call"); return emitPubSection(OS, *DI.GNUPubTypes, DI.IsLittleEndian, /*IsGNUStyle=*/true); } static Expected writeDIE(const DWARFYAML::Data &DI, uint64_t CUIndex, uint64_t AbbrevTableID, const dwarf::FormParams &Params, const DWARFYAML::Entry &Entry, raw_ostream &OS, bool IsLittleEndian) { uint64_t EntryBegin = OS.tell(); encodeULEB128(Entry.AbbrCode, OS); uint32_t AbbrCode = Entry.AbbrCode; if (AbbrCode == 0 || Entry.Values.empty()) return OS.tell() - EntryBegin; Expected AbbrevTableInfoOrErr = DI.getAbbrevTableInfoByID(AbbrevTableID); if (!AbbrevTableInfoOrErr) return createStringError(errc::invalid_argument, toString(AbbrevTableInfoOrErr.takeError()) + " for compilation unit with index " + utostr(CUIndex)); ArrayRef AbbrevDecls( DI.DebugAbbrev[AbbrevTableInfoOrErr->Index].Table); if (AbbrCode > AbbrevDecls.size()) return createStringError( errc::invalid_argument, "abbrev code must be less than or equal to the number of " "entries in abbreviation table"); const DWARFYAML::Abbrev &Abbrev = AbbrevDecls[AbbrCode - 1]; auto FormVal = Entry.Values.begin(); auto AbbrForm = Abbrev.Attributes.begin(); for (; FormVal != Entry.Values.end() && AbbrForm != Abbrev.Attributes.end(); ++FormVal, ++AbbrForm) { dwarf::Form Form = AbbrForm->Form; bool Indirect; do { Indirect = false; switch (Form) { case dwarf::DW_FORM_addr: // TODO: Test this error. if (Error Err = writeVariableSizedInteger( FormVal->Value, Params.AddrSize, OS, IsLittleEndian)) return std::move(Err); break; case dwarf::DW_FORM_ref_addr: // TODO: Test this error. if (Error Err = writeVariableSizedInteger(FormVal->Value, Params.getRefAddrByteSize(), OS, IsLittleEndian)) return std::move(Err); break; case dwarf::DW_FORM_exprloc: case dwarf::DW_FORM_block: encodeULEB128(FormVal->BlockData.size(), OS); OS.write((const char *)FormVal->BlockData.data(), FormVal->BlockData.size()); break; case dwarf::DW_FORM_block1: { writeInteger((uint8_t)FormVal->BlockData.size(), OS, IsLittleEndian); OS.write((const char *)FormVal->BlockData.data(), FormVal->BlockData.size()); break; } case dwarf::DW_FORM_block2: { writeInteger((uint16_t)FormVal->BlockData.size(), OS, IsLittleEndian); OS.write((const char *)FormVal->BlockData.data(), FormVal->BlockData.size()); break; } case dwarf::DW_FORM_block4: { writeInteger((uint32_t)FormVal->BlockData.size(), OS, IsLittleEndian); OS.write((const char *)FormVal->BlockData.data(), FormVal->BlockData.size()); break; } case dwarf::DW_FORM_strx: case dwarf::DW_FORM_addrx: case dwarf::DW_FORM_rnglistx: case dwarf::DW_FORM_loclistx: case dwarf::DW_FORM_udata: case dwarf::DW_FORM_ref_udata: case dwarf::DW_FORM_GNU_addr_index: case dwarf::DW_FORM_GNU_str_index: encodeULEB128(FormVal->Value, OS); break; case dwarf::DW_FORM_data1: case dwarf::DW_FORM_ref1: case dwarf::DW_FORM_flag: case dwarf::DW_FORM_strx1: case dwarf::DW_FORM_addrx1: writeInteger((uint8_t)FormVal->Value, OS, IsLittleEndian); break; case dwarf::DW_FORM_data2: case dwarf::DW_FORM_ref2: case dwarf::DW_FORM_strx2: case dwarf::DW_FORM_addrx2: writeInteger((uint16_t)FormVal->Value, OS, IsLittleEndian); break; case dwarf::DW_FORM_data4: case dwarf::DW_FORM_ref4: case dwarf::DW_FORM_ref_sup4: case dwarf::DW_FORM_strx4: case dwarf::DW_FORM_addrx4: writeInteger((uint32_t)FormVal->Value, OS, IsLittleEndian); break; case dwarf::DW_FORM_data8: case dwarf::DW_FORM_ref8: case dwarf::DW_FORM_ref_sup8: case dwarf::DW_FORM_ref_sig8: writeInteger((uint64_t)FormVal->Value, OS, IsLittleEndian); break; case dwarf::DW_FORM_sdata: encodeSLEB128(FormVal->Value, OS); break; case dwarf::DW_FORM_string: OS.write(FormVal->CStr.data(), FormVal->CStr.size()); OS.write('\0'); break; case dwarf::DW_FORM_indirect: encodeULEB128(FormVal->Value, OS); Indirect = true; Form = static_cast((uint64_t)FormVal->Value); ++FormVal; break; case dwarf::DW_FORM_strp: case dwarf::DW_FORM_sec_offset: case dwarf::DW_FORM_GNU_ref_alt: case dwarf::DW_FORM_GNU_strp_alt: case dwarf::DW_FORM_line_strp: case dwarf::DW_FORM_strp_sup: cantFail(writeVariableSizedInteger(FormVal->Value, Params.getDwarfOffsetByteSize(), OS, IsLittleEndian)); break; default: break; } } while (Indirect); } return OS.tell() - EntryBegin; } Error DWARFYAML::emitDebugInfo(raw_ostream &OS, const DWARFYAML::Data &DI) { for (uint64_t I = 0; I < DI.CompileUnits.size(); ++I) { const DWARFYAML::Unit &Unit = DI.CompileUnits[I]; uint8_t AddrSize; if (Unit.AddrSize) AddrSize = *Unit.AddrSize; else AddrSize = DI.Is64BitAddrSize ? 8 : 4; dwarf::FormParams Params = {Unit.Version, AddrSize, Unit.Format}; uint64_t Length = 3; // sizeof(version) + sizeof(address_size) Length += Unit.Version >= 5 ? 1 : 0; // sizeof(unit_type) Length += Params.getDwarfOffsetByteSize(); // sizeof(debug_abbrev_offset) // Since the length of the current compilation unit is undetermined yet, we // firstly write the content of the compilation unit to a buffer to // calculate it and then serialize the buffer content to the actual output // stream. std::string EntryBuffer; raw_string_ostream EntryBufferOS(EntryBuffer); uint64_t AbbrevTableID = Unit.AbbrevTableID.value_or(I); for (const DWARFYAML::Entry &Entry : Unit.Entries) { if (Expected EntryLength = writeDIE(DI, I, AbbrevTableID, Params, Entry, EntryBufferOS, DI.IsLittleEndian)) Length += *EntryLength; else return EntryLength.takeError(); } // If the length is specified in the YAML description, we use it instead of // the actual length. if (Unit.Length) Length = *Unit.Length; writeInitialLength(Unit.Format, Length, OS, DI.IsLittleEndian); writeInteger((uint16_t)Unit.Version, OS, DI.IsLittleEndian); uint64_t AbbrevTableOffset = 0; if (Unit.AbbrOffset) { AbbrevTableOffset = *Unit.AbbrOffset; } else { if (Expected AbbrevTableInfoOrErr = DI.getAbbrevTableInfoByID(AbbrevTableID)) { AbbrevTableOffset = AbbrevTableInfoOrErr->Offset; } else { // The current compilation unit may not have DIEs and it will not be // able to find the associated abbrev table. We consume the error and // assign 0 to the debug_abbrev_offset in such circumstances. consumeError(AbbrevTableInfoOrErr.takeError()); } } if (Unit.Version >= 5) { writeInteger((uint8_t)Unit.Type, OS, DI.IsLittleEndian); writeInteger((uint8_t)AddrSize, OS, DI.IsLittleEndian); writeDWARFOffset(AbbrevTableOffset, Unit.Format, OS, DI.IsLittleEndian); } else { writeDWARFOffset(AbbrevTableOffset, Unit.Format, OS, DI.IsLittleEndian); writeInteger((uint8_t)AddrSize, OS, DI.IsLittleEndian); } OS.write(EntryBuffer.data(), EntryBuffer.size()); } return Error::success(); } static void emitFileEntry(raw_ostream &OS, const DWARFYAML::File &File) { OS.write(File.Name.data(), File.Name.size()); OS.write('\0'); encodeULEB128(File.DirIdx, OS); encodeULEB128(File.ModTime, OS); encodeULEB128(File.Length, OS); } static void writeExtendedOpcode(const DWARFYAML::LineTableOpcode &Op, uint8_t AddrSize, bool IsLittleEndian, raw_ostream &OS) { // The first byte of extended opcodes is a zero byte. The next bytes are an // ULEB128 integer giving the number of bytes in the instruction itself (does // not include the first zero byte or the size). We serialize the instruction // itself into the OpBuffer and then write the size of the buffer and the // buffer to the real output stream. std::string OpBuffer; raw_string_ostream OpBufferOS(OpBuffer); writeInteger((uint8_t)Op.SubOpcode, OpBufferOS, IsLittleEndian); switch (Op.SubOpcode) { case dwarf::DW_LNE_set_address: cantFail(writeVariableSizedInteger(Op.Data, AddrSize, OpBufferOS, IsLittleEndian)); break; case dwarf::DW_LNE_define_file: emitFileEntry(OpBufferOS, Op.FileEntry); break; case dwarf::DW_LNE_set_discriminator: encodeULEB128(Op.Data, OpBufferOS); break; case dwarf::DW_LNE_end_sequence: break; default: for (auto OpByte : Op.UnknownOpcodeData) writeInteger((uint8_t)OpByte, OpBufferOS, IsLittleEndian); } uint64_t ExtLen = Op.ExtLen.value_or(OpBuffer.size()); encodeULEB128(ExtLen, OS); OS.write(OpBuffer.data(), OpBuffer.size()); } static void writeLineTableOpcode(const DWARFYAML::LineTableOpcode &Op, uint8_t OpcodeBase, uint8_t AddrSize, raw_ostream &OS, bool IsLittleEndian) { writeInteger((uint8_t)Op.Opcode, OS, IsLittleEndian); if (Op.Opcode == 0) { writeExtendedOpcode(Op, AddrSize, IsLittleEndian, OS); } else if (Op.Opcode < OpcodeBase) { switch (Op.Opcode) { case dwarf::DW_LNS_copy: case dwarf::DW_LNS_negate_stmt: case dwarf::DW_LNS_set_basic_block: case dwarf::DW_LNS_const_add_pc: case dwarf::DW_LNS_set_prologue_end: case dwarf::DW_LNS_set_epilogue_begin: break; case dwarf::DW_LNS_advance_pc: case dwarf::DW_LNS_set_file: case dwarf::DW_LNS_set_column: case dwarf::DW_LNS_set_isa: encodeULEB128(Op.Data, OS); break; case dwarf::DW_LNS_advance_line: encodeSLEB128(Op.SData, OS); break; case dwarf::DW_LNS_fixed_advance_pc: writeInteger((uint16_t)Op.Data, OS, IsLittleEndian); break; default: for (auto OpData : Op.StandardOpcodeData) { encodeULEB128(OpData, OS); } } } } static std::vector getStandardOpcodeLengths(uint16_t Version, std::optional OpcodeBase) { // If the opcode_base field isn't specified, we returns the // standard_opcode_lengths array according to the version by default. std::vector StandardOpcodeLengths{0, 1, 1, 1, 1, 0, 0, 0, 1, 0, 0, 1}; if (Version == 2) { // DWARF v2 uses the same first 9 standard opcodes as v3-5. StandardOpcodeLengths.resize(9); } else if (OpcodeBase) { StandardOpcodeLengths.resize(*OpcodeBase > 0 ? *OpcodeBase - 1 : 0, 0); } return StandardOpcodeLengths; } Error DWARFYAML::emitDebugLine(raw_ostream &OS, const DWARFYAML::Data &DI) { for (const DWARFYAML::LineTable &LineTable : DI.DebugLines) { // Buffer holds the bytes following the header_length (or prologue_length in // DWARFv2) field to the end of the line number program itself. std::string Buffer; raw_string_ostream BufferOS(Buffer); writeInteger(LineTable.MinInstLength, BufferOS, DI.IsLittleEndian); // TODO: Add support for emitting DWARFv5 line table. if (LineTable.Version >= 4) writeInteger(LineTable.MaxOpsPerInst, BufferOS, DI.IsLittleEndian); writeInteger(LineTable.DefaultIsStmt, BufferOS, DI.IsLittleEndian); writeInteger(LineTable.LineBase, BufferOS, DI.IsLittleEndian); writeInteger(LineTable.LineRange, BufferOS, DI.IsLittleEndian); std::vector StandardOpcodeLengths = LineTable.StandardOpcodeLengths.value_or( getStandardOpcodeLengths(LineTable.Version, LineTable.OpcodeBase)); uint8_t OpcodeBase = LineTable.OpcodeBase ? *LineTable.OpcodeBase : StandardOpcodeLengths.size() + 1; writeInteger(OpcodeBase, BufferOS, DI.IsLittleEndian); for (uint8_t OpcodeLength : StandardOpcodeLengths) writeInteger(OpcodeLength, BufferOS, DI.IsLittleEndian); for (StringRef IncludeDir : LineTable.IncludeDirs) { BufferOS.write(IncludeDir.data(), IncludeDir.size()); BufferOS.write('\0'); } BufferOS.write('\0'); for (const DWARFYAML::File &File : LineTable.Files) emitFileEntry(BufferOS, File); BufferOS.write('\0'); uint64_t HeaderLength = LineTable.PrologueLength ? *LineTable.PrologueLength : Buffer.size(); for (const DWARFYAML::LineTableOpcode &Op : LineTable.Opcodes) writeLineTableOpcode(Op, OpcodeBase, DI.Is64BitAddrSize ? 8 : 4, BufferOS, DI.IsLittleEndian); uint64_t Length; if (LineTable.Length) { Length = *LineTable.Length; } else { Length = 2; // sizeof(version) Length += (LineTable.Format == dwarf::DWARF64 ? 8 : 4); // sizeof(header_length) Length += Buffer.size(); } writeInitialLength(LineTable.Format, Length, OS, DI.IsLittleEndian); writeInteger(LineTable.Version, OS, DI.IsLittleEndian); writeDWARFOffset(HeaderLength, LineTable.Format, OS, DI.IsLittleEndian); OS.write(Buffer.data(), Buffer.size()); } return Error::success(); } Error DWARFYAML::emitDebugAddr(raw_ostream &OS, const Data &DI) { for (const AddrTableEntry &TableEntry : *DI.DebugAddr) { uint8_t AddrSize; if (TableEntry.AddrSize) AddrSize = *TableEntry.AddrSize; else AddrSize = DI.Is64BitAddrSize ? 8 : 4; uint64_t Length; if (TableEntry.Length) Length = (uint64_t)*TableEntry.Length; else // 2 (version) + 1 (address_size) + 1 (segment_selector_size) = 4 Length = 4 + (AddrSize + TableEntry.SegSelectorSize) * TableEntry.SegAddrPairs.size(); writeInitialLength(TableEntry.Format, Length, OS, DI.IsLittleEndian); writeInteger((uint16_t)TableEntry.Version, OS, DI.IsLittleEndian); writeInteger((uint8_t)AddrSize, OS, DI.IsLittleEndian); writeInteger((uint8_t)TableEntry.SegSelectorSize, OS, DI.IsLittleEndian); for (const SegAddrPair &Pair : TableEntry.SegAddrPairs) { if (TableEntry.SegSelectorSize != yaml::Hex8{0}) if (Error Err = writeVariableSizedInteger(Pair.Segment, TableEntry.SegSelectorSize, OS, DI.IsLittleEndian)) return createStringError(errc::not_supported, "unable to write debug_addr segment: %s", toString(std::move(Err)).c_str()); if (AddrSize != 0) if (Error Err = writeVariableSizedInteger(Pair.Address, AddrSize, OS, DI.IsLittleEndian)) return createStringError(errc::not_supported, "unable to write debug_addr address: %s", toString(std::move(Err)).c_str()); } } return Error::success(); } Error DWARFYAML::emitDebugStrOffsets(raw_ostream &OS, const Data &DI) { assert(DI.DebugStrOffsets && "unexpected emitDebugStrOffsets() call"); for (const DWARFYAML::StringOffsetsTable &Table : *DI.DebugStrOffsets) { uint64_t Length; if (Table.Length) Length = *Table.Length; else // sizeof(version) + sizeof(padding) = 4 Length = 4 + Table.Offsets.size() * (Table.Format == dwarf::DWARF64 ? 8 : 4); writeInitialLength(Table.Format, Length, OS, DI.IsLittleEndian); writeInteger((uint16_t)Table.Version, OS, DI.IsLittleEndian); writeInteger((uint16_t)Table.Padding, OS, DI.IsLittleEndian); for (uint64_t Offset : Table.Offsets) writeDWARFOffset(Offset, Table.Format, OS, DI.IsLittleEndian); } return Error::success(); } static Error checkOperandCount(StringRef EncodingString, ArrayRef Values, uint64_t ExpectedOperands) { if (Values.size() != ExpectedOperands) return createStringError( errc::invalid_argument, "invalid number (%zu) of operands for the operator: %s, %" PRIu64 " expected", Values.size(), EncodingString.str().c_str(), ExpectedOperands); return Error::success(); } static Error writeListEntryAddress(StringRef EncodingName, raw_ostream &OS, uint64_t Addr, uint8_t AddrSize, bool IsLittleEndian) { if (Error Err = writeVariableSizedInteger(Addr, AddrSize, OS, IsLittleEndian)) return createStringError(errc::invalid_argument, "unable to write address for the operator %s: %s", EncodingName.str().c_str(), toString(std::move(Err)).c_str()); return Error::success(); } static Expected writeDWARFExpression(raw_ostream &OS, const DWARFYAML::DWARFOperation &Operation, uint8_t AddrSize, bool IsLittleEndian) { auto CheckOperands = [&](uint64_t ExpectedOperands) -> Error { return checkOperandCount(dwarf::OperationEncodingString(Operation.Operator), Operation.Values, ExpectedOperands); }; uint64_t ExpressionBegin = OS.tell(); writeInteger((uint8_t)Operation.Operator, OS, IsLittleEndian); switch (Operation.Operator) { case dwarf::DW_OP_consts: if (Error Err = CheckOperands(1)) return std::move(Err); encodeSLEB128(Operation.Values[0], OS); break; case dwarf::DW_OP_stack_value: if (Error Err = CheckOperands(0)) return std::move(Err); break; default: StringRef EncodingStr = dwarf::OperationEncodingString(Operation.Operator); return createStringError(errc::not_supported, "DWARF expression: " + (EncodingStr.empty() ? "0x" + utohexstr(Operation.Operator) : EncodingStr) + " is not supported"); } return OS.tell() - ExpressionBegin; } static Expected writeListEntry(raw_ostream &OS, const DWARFYAML::RnglistEntry &Entry, uint8_t AddrSize, bool IsLittleEndian) { uint64_t BeginOffset = OS.tell(); writeInteger((uint8_t)Entry.Operator, OS, IsLittleEndian); StringRef EncodingName = dwarf::RangeListEncodingString(Entry.Operator); auto CheckOperands = [&](uint64_t ExpectedOperands) -> Error { return checkOperandCount(EncodingName, Entry.Values, ExpectedOperands); }; auto WriteAddress = [&](uint64_t Addr) -> Error { return writeListEntryAddress(EncodingName, OS, Addr, AddrSize, IsLittleEndian); }; switch (Entry.Operator) { case dwarf::DW_RLE_end_of_list: if (Error Err = CheckOperands(0)) return std::move(Err); break; case dwarf::DW_RLE_base_addressx: if (Error Err = CheckOperands(1)) return std::move(Err); encodeULEB128(Entry.Values[0], OS); break; case dwarf::DW_RLE_startx_endx: case dwarf::DW_RLE_startx_length: case dwarf::DW_RLE_offset_pair: if (Error Err = CheckOperands(2)) return std::move(Err); encodeULEB128(Entry.Values[0], OS); encodeULEB128(Entry.Values[1], OS); break; case dwarf::DW_RLE_base_address: if (Error Err = CheckOperands(1)) return std::move(Err); if (Error Err = WriteAddress(Entry.Values[0])) return std::move(Err); break; case dwarf::DW_RLE_start_end: if (Error Err = CheckOperands(2)) return std::move(Err); if (Error Err = WriteAddress(Entry.Values[0])) return std::move(Err); cantFail(WriteAddress(Entry.Values[1])); break; case dwarf::DW_RLE_start_length: if (Error Err = CheckOperands(2)) return std::move(Err); if (Error Err = WriteAddress(Entry.Values[0])) return std::move(Err); encodeULEB128(Entry.Values[1], OS); break; } return OS.tell() - BeginOffset; } static Expected writeListEntry(raw_ostream &OS, const DWARFYAML::LoclistEntry &Entry, uint8_t AddrSize, bool IsLittleEndian) { uint64_t BeginOffset = OS.tell(); writeInteger((uint8_t)Entry.Operator, OS, IsLittleEndian); StringRef EncodingName = dwarf::LocListEncodingString(Entry.Operator); auto CheckOperands = [&](uint64_t ExpectedOperands) -> Error { return checkOperandCount(EncodingName, Entry.Values, ExpectedOperands); }; auto WriteAddress = [&](uint64_t Addr) -> Error { return writeListEntryAddress(EncodingName, OS, Addr, AddrSize, IsLittleEndian); }; auto WriteDWARFOperations = [&]() -> Error { std::string OpBuffer; raw_string_ostream OpBufferOS(OpBuffer); uint64_t DescriptionsLength = 0; for (const DWARFYAML::DWARFOperation &Op : Entry.Descriptions) { if (Expected OpSize = writeDWARFExpression(OpBufferOS, Op, AddrSize, IsLittleEndian)) DescriptionsLength += *OpSize; else return OpSize.takeError(); } if (Entry.DescriptionsLength) DescriptionsLength = *Entry.DescriptionsLength; else DescriptionsLength = OpBuffer.size(); encodeULEB128(DescriptionsLength, OS); OS.write(OpBuffer.data(), OpBuffer.size()); return Error::success(); }; switch (Entry.Operator) { case dwarf::DW_LLE_end_of_list: if (Error Err = CheckOperands(0)) return std::move(Err); break; case dwarf::DW_LLE_base_addressx: if (Error Err = CheckOperands(1)) return std::move(Err); encodeULEB128(Entry.Values[0], OS); break; case dwarf::DW_LLE_startx_endx: case dwarf::DW_LLE_startx_length: case dwarf::DW_LLE_offset_pair: if (Error Err = CheckOperands(2)) return std::move(Err); encodeULEB128(Entry.Values[0], OS); encodeULEB128(Entry.Values[1], OS); if (Error Err = WriteDWARFOperations()) return std::move(Err); break; case dwarf::DW_LLE_default_location: if (Error Err = CheckOperands(0)) return std::move(Err); if (Error Err = WriteDWARFOperations()) return std::move(Err); break; case dwarf::DW_LLE_base_address: if (Error Err = CheckOperands(1)) return std::move(Err); if (Error Err = WriteAddress(Entry.Values[0])) return std::move(Err); break; case dwarf::DW_LLE_start_end: if (Error Err = CheckOperands(2)) return std::move(Err); if (Error Err = WriteAddress(Entry.Values[0])) return std::move(Err); cantFail(WriteAddress(Entry.Values[1])); if (Error Err = WriteDWARFOperations()) return std::move(Err); break; case dwarf::DW_LLE_start_length: if (Error Err = CheckOperands(2)) return std::move(Err); if (Error Err = WriteAddress(Entry.Values[0])) return std::move(Err); encodeULEB128(Entry.Values[1], OS); if (Error Err = WriteDWARFOperations()) return std::move(Err); break; } return OS.tell() - BeginOffset; } template static Error writeDWARFLists(raw_ostream &OS, ArrayRef> Tables, bool IsLittleEndian, bool Is64BitAddrSize) { for (const DWARFYAML::ListTable &Table : Tables) { // sizeof(version) + sizeof(address_size) + sizeof(segment_selector_size) + // sizeof(offset_entry_count) = 8 uint64_t Length = 8; uint8_t AddrSize; if (Table.AddrSize) AddrSize = *Table.AddrSize; else AddrSize = Is64BitAddrSize ? 8 : 4; // Since the length of the current range/location lists entry is // undetermined yet, we firstly write the content of the range/location // lists to a buffer to calculate the length and then serialize the buffer // content to the actual output stream. std::string ListBuffer; raw_string_ostream ListBufferOS(ListBuffer); // Offsets holds offsets for each range/location list. The i-th element is // the offset from the beginning of the first range/location list to the // location of the i-th range list. std::vector Offsets; for (const DWARFYAML::ListEntries &List : Table.Lists) { Offsets.push_back(ListBufferOS.tell()); if (List.Content) { List.Content->writeAsBinary(ListBufferOS, UINT64_MAX); Length += List.Content->binary_size(); } else if (List.Entries) { for (const EntryType &Entry : *List.Entries) { Expected EntrySize = writeListEntry(ListBufferOS, Entry, AddrSize, IsLittleEndian); if (!EntrySize) return EntrySize.takeError(); Length += *EntrySize; } } } // If the offset_entry_count field isn't specified, yaml2obj will infer it // from the 'Offsets' field in the YAML description. If the 'Offsets' field // isn't specified either, yaml2obj will infer it from the auto-generated // offsets. uint32_t OffsetEntryCount; if (Table.OffsetEntryCount) OffsetEntryCount = *Table.OffsetEntryCount; else OffsetEntryCount = Table.Offsets ? Table.Offsets->size() : Offsets.size(); uint64_t OffsetsSize = OffsetEntryCount * (Table.Format == dwarf::DWARF64 ? 8 : 4); Length += OffsetsSize; // If the length is specified in the YAML description, we use it instead of // the actual length. if (Table.Length) Length = *Table.Length; writeInitialLength(Table.Format, Length, OS, IsLittleEndian); writeInteger((uint16_t)Table.Version, OS, IsLittleEndian); writeInteger((uint8_t)AddrSize, OS, IsLittleEndian); writeInteger((uint8_t)Table.SegSelectorSize, OS, IsLittleEndian); writeInteger((uint32_t)OffsetEntryCount, OS, IsLittleEndian); auto EmitOffsets = [&](ArrayRef Offsets, uint64_t OffsetsSize) { for (uint64_t Offset : Offsets) writeDWARFOffset(OffsetsSize + Offset, Table.Format, OS, IsLittleEndian); }; if (Table.Offsets) EmitOffsets(ArrayRef((const uint64_t *)Table.Offsets->data(), Table.Offsets->size()), 0); else if (OffsetEntryCount != 0) EmitOffsets(Offsets, OffsetsSize); OS.write(ListBuffer.data(), ListBuffer.size()); } return Error::success(); } Error DWARFYAML::emitDebugRnglists(raw_ostream &OS, const Data &DI) { assert(DI.DebugRnglists && "unexpected emitDebugRnglists() call"); return writeDWARFLists( OS, *DI.DebugRnglists, DI.IsLittleEndian, DI.Is64BitAddrSize); } Error DWARFYAML::emitDebugLoclists(raw_ostream &OS, const Data &DI) { assert(DI.DebugLoclists && "unexpected emitDebugRnglists() call"); return writeDWARFLists( OS, *DI.DebugLoclists, DI.IsLittleEndian, DI.Is64BitAddrSize); } std::function DWARFYAML::getDWARFEmitterByName(StringRef SecName) { auto EmitFunc = StringSwitch< std::function>(SecName) .Case("debug_abbrev", DWARFYAML::emitDebugAbbrev) .Case("debug_addr", DWARFYAML::emitDebugAddr) .Case("debug_aranges", DWARFYAML::emitDebugAranges) .Case("debug_gnu_pubnames", DWARFYAML::emitDebugGNUPubnames) .Case("debug_gnu_pubtypes", DWARFYAML::emitDebugGNUPubtypes) .Case("debug_info", DWARFYAML::emitDebugInfo) .Case("debug_line", DWARFYAML::emitDebugLine) .Case("debug_loclists", DWARFYAML::emitDebugLoclists) .Case("debug_pubnames", DWARFYAML::emitDebugPubnames) .Case("debug_pubtypes", DWARFYAML::emitDebugPubtypes) .Case("debug_ranges", DWARFYAML::emitDebugRanges) .Case("debug_rnglists", DWARFYAML::emitDebugRnglists) .Case("debug_str", DWARFYAML::emitDebugStr) .Case("debug_str_offsets", DWARFYAML::emitDebugStrOffsets) .Default([&](raw_ostream &, const DWARFYAML::Data &) { return createStringError(errc::not_supported, SecName + " is not supported"); }); return EmitFunc; } static Error emitDebugSectionImpl(const DWARFYAML::Data &DI, StringRef Sec, StringMap> &OutputBuffers) { std::string Data; raw_string_ostream DebugInfoStream(Data); auto EmitFunc = DWARFYAML::getDWARFEmitterByName(Sec); if (Error Err = EmitFunc(DebugInfoStream, DI)) return Err; DebugInfoStream.flush(); if (!Data.empty()) OutputBuffers[Sec] = MemoryBuffer::getMemBufferCopy(Data); return Error::success(); } Expected>> DWARFYAML::emitDebugSections(StringRef YAMLString, bool IsLittleEndian, bool Is64BitAddrSize) { auto CollectDiagnostic = [](const SMDiagnostic &Diag, void *DiagContext) { *static_cast(DiagContext) = Diag; }; SMDiagnostic GeneratedDiag; yaml::Input YIn(YAMLString, /*Ctxt=*/nullptr, CollectDiagnostic, &GeneratedDiag); DWARFYAML::Data DI; DI.IsLittleEndian = IsLittleEndian; DI.Is64BitAddrSize = Is64BitAddrSize; YIn >> DI; if (YIn.error()) return createStringError(YIn.error(), GeneratedDiag.getMessage()); StringMap> DebugSections; Error Err = Error::success(); for (StringRef SecName : DI.getNonEmptySectionNames()) Err = joinErrors(std::move(Err), emitDebugSectionImpl(DI, SecName, DebugSections)); if (Err) return std::move(Err); return std::move(DebugSections); }