//===- DWARFDebugFrame.h - Parsing of .debug_frame --------------*- 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 // //===----------------------------------------------------------------------===// #ifndef LLVM_DEBUGINFO_DWARF_DWARFDEBUGFRAME_H #define LLVM_DEBUGINFO_DWARF_DWARFDEBUGFRAME_H #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/iterator.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/Triple.h" #include "llvm/DebugInfo/DWARF/DWARFDataExtractor.h" #include "llvm/DebugInfo/DWARF/DWARFExpression.h" #include "llvm/Support/Error.h" #include #include namespace llvm { class raw_ostream; namespace dwarf { /// Represent a sequence of Call Frame Information instructions that, when read /// in order, construct a table mapping PC to frame state. This can also be /// referred to as "CFI rules" in DWARF literature to avoid confusion with /// computer programs in the broader sense, and in this context each instruction /// would be a rule to establish the mapping. Refer to pg. 172 in the DWARF5 /// manual, "6.4.1 Structure of Call Frame Information". class CFIProgram { public: typedef SmallVector Operands; /// An instruction consists of a DWARF CFI opcode and an optional sequence of /// operands. If it refers to an expression, then this expression has its own /// sequence of operations and operands handled separately by DWARFExpression. struct Instruction { Instruction(uint8_t Opcode) : Opcode(Opcode) {} uint8_t Opcode; Operands Ops; // Associated DWARF expression in case this instruction refers to one Optional Expression; }; using InstrList = std::vector; using iterator = InstrList::iterator; using const_iterator = InstrList::const_iterator; iterator begin() { return Instructions.begin(); } const_iterator begin() const { return Instructions.begin(); } iterator end() { return Instructions.end(); } const_iterator end() const { return Instructions.end(); } unsigned size() const { return (unsigned)Instructions.size(); } bool empty() const { return Instructions.empty(); } CFIProgram(uint64_t CodeAlignmentFactor, int64_t DataAlignmentFactor, Triple::ArchType Arch) : CodeAlignmentFactor(CodeAlignmentFactor), DataAlignmentFactor(DataAlignmentFactor), Arch(Arch) {} /// Parse and store a sequence of CFI instructions from Data, /// starting at *Offset and ending at EndOffset. *Offset is updated /// to EndOffset upon successful parsing, or indicates the offset /// where a problem occurred in case an error is returned. Error parse(DWARFDataExtractor Data, uint64_t *Offset, uint64_t EndOffset); void dump(raw_ostream &OS, DIDumpOptions DumpOpts, const MCRegisterInfo *MRI, bool IsEH, unsigned IndentLevel = 1) const; private: std::vector Instructions; const uint64_t CodeAlignmentFactor; const int64_t DataAlignmentFactor; Triple::ArchType Arch; /// Convenience method to add a new instruction with the given opcode. void addInstruction(uint8_t Opcode) { Instructions.push_back(Instruction(Opcode)); } /// Add a new single-operand instruction. void addInstruction(uint8_t Opcode, uint64_t Operand1) { Instructions.push_back(Instruction(Opcode)); Instructions.back().Ops.push_back(Operand1); } /// Add a new instruction that has two operands. void addInstruction(uint8_t Opcode, uint64_t Operand1, uint64_t Operand2) { Instructions.push_back(Instruction(Opcode)); Instructions.back().Ops.push_back(Operand1); Instructions.back().Ops.push_back(Operand2); } /// Types of operands to CFI instructions /// In DWARF, this type is implicitly tied to a CFI instruction opcode and /// thus this type doesn't need to be explictly written to the file (this is /// not a DWARF encoding). The relationship of instrs to operand types can /// be obtained from getOperandTypes() and is only used to simplify /// instruction printing. enum OperandType { OT_Unset, OT_None, OT_Address, OT_Offset, OT_FactoredCodeOffset, OT_SignedFactDataOffset, OT_UnsignedFactDataOffset, OT_Register, OT_Expression }; /// Retrieve the array describing the types of operands according to the enum /// above. This is indexed by opcode. static ArrayRef getOperandTypes(); /// Print \p Opcode's operand number \p OperandIdx which has value \p Operand. void printOperand(raw_ostream &OS, DIDumpOptions DumpOpts, const MCRegisterInfo *MRI, bool IsEH, const Instruction &Instr, unsigned OperandIdx, uint64_t Operand) const; }; /// An entry in either debug_frame or eh_frame. This entry can be a CIE or an /// FDE. class FrameEntry { public: enum FrameKind { FK_CIE, FK_FDE }; FrameEntry(FrameKind K, bool IsDWARF64, uint64_t Offset, uint64_t Length, uint64_t CodeAlign, int64_t DataAlign, Triple::ArchType Arch) : Kind(K), IsDWARF64(IsDWARF64), Offset(Offset), Length(Length), CFIs(CodeAlign, DataAlign, Arch) {} virtual ~FrameEntry() {} FrameKind getKind() const { return Kind; } uint64_t getOffset() const { return Offset; } uint64_t getLength() const { return Length; } const CFIProgram &cfis() const { return CFIs; } CFIProgram &cfis() { return CFIs; } /// Dump the instructions in this CFI fragment virtual void dump(raw_ostream &OS, DIDumpOptions DumpOpts, const MCRegisterInfo *MRI, bool IsEH) const = 0; protected: const FrameKind Kind; const bool IsDWARF64; /// Offset of this entry in the section. const uint64_t Offset; /// Entry length as specified in DWARF. const uint64_t Length; CFIProgram CFIs; }; /// DWARF Common Information Entry (CIE) class CIE : public FrameEntry { public: // CIEs (and FDEs) are simply container classes, so the only sensible way to // create them is by providing the full parsed contents in the constructor. CIE(bool IsDWARF64, uint64_t Offset, uint64_t Length, uint8_t Version, SmallString<8> Augmentation, uint8_t AddressSize, uint8_t SegmentDescriptorSize, uint64_t CodeAlignmentFactor, int64_t DataAlignmentFactor, uint64_t ReturnAddressRegister, SmallString<8> AugmentationData, uint32_t FDEPointerEncoding, uint32_t LSDAPointerEncoding, Optional Personality, Optional PersonalityEnc, Triple::ArchType Arch) : FrameEntry(FK_CIE, IsDWARF64, Offset, Length, CodeAlignmentFactor, DataAlignmentFactor, Arch), Version(Version), Augmentation(std::move(Augmentation)), AddressSize(AddressSize), SegmentDescriptorSize(SegmentDescriptorSize), CodeAlignmentFactor(CodeAlignmentFactor), DataAlignmentFactor(DataAlignmentFactor), ReturnAddressRegister(ReturnAddressRegister), AugmentationData(std::move(AugmentationData)), FDEPointerEncoding(FDEPointerEncoding), LSDAPointerEncoding(LSDAPointerEncoding), Personality(Personality), PersonalityEnc(PersonalityEnc) {} static bool classof(const FrameEntry *FE) { return FE->getKind() == FK_CIE; } StringRef getAugmentationString() const { return Augmentation; } uint64_t getCodeAlignmentFactor() const { return CodeAlignmentFactor; } int64_t getDataAlignmentFactor() const { return DataAlignmentFactor; } uint8_t getVersion() const { return Version; } uint64_t getReturnAddressRegister() const { return ReturnAddressRegister; } Optional getPersonalityAddress() const { return Personality; } Optional getPersonalityEncoding() const { return PersonalityEnc; } uint32_t getFDEPointerEncoding() const { return FDEPointerEncoding; } uint32_t getLSDAPointerEncoding() const { return LSDAPointerEncoding; } void dump(raw_ostream &OS, DIDumpOptions DumpOpts, const MCRegisterInfo *MRI, bool IsEH) const override; private: /// The following fields are defined in section 6.4.1 of the DWARF standard v4 const uint8_t Version; const SmallString<8> Augmentation; const uint8_t AddressSize; const uint8_t SegmentDescriptorSize; const uint64_t CodeAlignmentFactor; const int64_t DataAlignmentFactor; const uint64_t ReturnAddressRegister; // The following are used when the CIE represents an EH frame entry. const SmallString<8> AugmentationData; const uint32_t FDEPointerEncoding; const uint32_t LSDAPointerEncoding; const Optional Personality; const Optional PersonalityEnc; }; /// DWARF Frame Description Entry (FDE) class FDE : public FrameEntry { public: FDE(bool IsDWARF64, uint64_t Offset, uint64_t Length, uint64_t CIEPointer, uint64_t InitialLocation, uint64_t AddressRange, CIE *Cie, Optional LSDAAddress, Triple::ArchType Arch) : FrameEntry(FK_FDE, IsDWARF64, Offset, Length, Cie ? Cie->getCodeAlignmentFactor() : 0, Cie ? Cie->getDataAlignmentFactor() : 0, Arch), CIEPointer(CIEPointer), InitialLocation(InitialLocation), AddressRange(AddressRange), LinkedCIE(Cie), LSDAAddress(LSDAAddress) {} ~FDE() override = default; const CIE *getLinkedCIE() const { return LinkedCIE; } uint64_t getInitialLocation() const { return InitialLocation; } uint64_t getAddressRange() const { return AddressRange; } Optional getLSDAAddress() const { return LSDAAddress; } void dump(raw_ostream &OS, DIDumpOptions DumpOpts, const MCRegisterInfo *MRI, bool IsEH) const override; static bool classof(const FrameEntry *FE) { return FE->getKind() == FK_FDE; } private: /// The following fields are defined in section 6.4.1 of the DWARFv3 standard. /// Note that CIE pointers in EH FDEs, unlike DWARF FDEs, contain relative /// offsets to the linked CIEs. See the following link for more info: /// https://refspecs.linuxfoundation.org/LSB_5.0.0/LSB-Core-generic/LSB-Core-generic/ehframechpt.html const uint64_t CIEPointer; const uint64_t InitialLocation; const uint64_t AddressRange; const CIE *LinkedCIE; const Optional LSDAAddress; }; } // end namespace dwarf /// A parsed .debug_frame or .eh_frame section class DWARFDebugFrame { const Triple::ArchType Arch; // True if this is parsing an eh_frame section. const bool IsEH; // Not zero for sane pointer values coming out of eh_frame const uint64_t EHFrameAddress; std::vector> Entries; using iterator = pointee_iterator; /// Return the entry at the given offset or nullptr. dwarf::FrameEntry *getEntryAtOffset(uint64_t Offset) const; public: // If IsEH is true, assume it is a .eh_frame section. Otherwise, // it is a .debug_frame section. EHFrameAddress should be different // than zero for correct parsing of .eh_frame addresses when they // use a PC-relative encoding. DWARFDebugFrame(Triple::ArchType Arch, bool IsEH = false, uint64_t EHFrameAddress = 0); ~DWARFDebugFrame(); /// Dump the section data into the given stream. void dump(raw_ostream &OS, DIDumpOptions DumpOpts, const MCRegisterInfo *MRI, Optional Offset) const; /// Parse the section from raw data. \p Data is assumed to contain the whole /// frame section contents to be parsed. Error parse(DWARFDataExtractor Data); /// Return whether the section has any entries. bool empty() const { return Entries.empty(); } /// DWARF Frame entries accessors iterator begin() const { return Entries.begin(); } iterator end() const { return Entries.end(); } iterator_range entries() const { return iterator_range(Entries.begin(), Entries.end()); } uint64_t getEHFrameAddress() const { return EHFrameAddress; } }; } // end namespace llvm #endif // LLVM_DEBUGINFO_DWARF_DWARFDEBUGFRAME_H