//===- DIContext.h ----------------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines DIContext, an abstract data structure that holds // debug information data. // //===----------------------------------------------------------------------===// #ifndef LLVM_DEBUGINFO_DICONTEXT_H #define LLVM_DEBUGINFO_DICONTEXT_H #include "llvm/ADT/SmallVector.h" #include "llvm/Object/ObjectFile.h" #include <cassert> #include <cstdint> #include <memory> #include <string> #include <tuple> #include <utility> namespace llvm { class raw_ostream; /// A format-neutral container for source line information. struct DILineInfo { std::string FileName; std::string FunctionName; uint32_t Line = 0; uint32_t Column = 0; uint32_t StartLine = 0; // DWARF-specific. uint32_t Discriminator = 0; DILineInfo() : FileName("<invalid>"), FunctionName("<invalid>") {} bool operator==(const DILineInfo &RHS) const { return Line == RHS.Line && Column == RHS.Column && FileName == RHS.FileName && FunctionName == RHS.FunctionName && StartLine == RHS.StartLine && Discriminator == RHS.Discriminator; } bool operator!=(const DILineInfo &RHS) const { return !(*this == RHS); } bool operator<(const DILineInfo &RHS) const { return std::tie(FileName, FunctionName, Line, Column, StartLine, Discriminator) < std::tie(RHS.FileName, RHS.FunctionName, RHS.Line, RHS.Column, RHS.StartLine, RHS.Discriminator); } }; using DILineInfoTable = SmallVector<std::pair<uint64_t, DILineInfo>, 16>; /// A format-neutral container for inlined code description. class DIInliningInfo { SmallVector<DILineInfo, 4> Frames; public: DIInliningInfo() = default; DILineInfo getFrame(unsigned Index) const { assert(Index < Frames.size()); return Frames[Index]; } DILineInfo *getMutableFrame(unsigned Index) { assert(Index < Frames.size()); return &Frames[Index]; } uint32_t getNumberOfFrames() const { return Frames.size(); } void addFrame(const DILineInfo &Frame) { Frames.push_back(Frame); } }; /// Container for description of a global variable. struct DIGlobal { std::string Name; uint64_t Start = 0; uint64_t Size = 0; DIGlobal() : Name("<invalid>") {} }; /// A DINameKind is passed to name search methods to specify a /// preference regarding the type of name resolution the caller wants. enum class DINameKind { None, ShortName, LinkageName }; /// Controls which fields of DILineInfo container should be filled /// with data. struct DILineInfoSpecifier { enum class FileLineInfoKind { None, Default, AbsoluteFilePath }; using FunctionNameKind = DINameKind; FileLineInfoKind FLIKind; FunctionNameKind FNKind; DILineInfoSpecifier(FileLineInfoKind FLIKind = FileLineInfoKind::Default, FunctionNameKind FNKind = FunctionNameKind::None) : FLIKind(FLIKind), FNKind(FNKind) {} }; /// This is just a helper to programmatically construct DIDumpType. enum DIDumpTypeCounter { #define HANDLE_DWARF_SECTION(ENUM_NAME, ELF_NAME, CMDLINE_NAME) \ DIDT_ID_##ENUM_NAME, #include "llvm/BinaryFormat/Dwarf.def" #undef HANDLE_DWARF_SECTION DIDT_ID_UUID, DIDT_ID_Count }; static_assert(DIDT_ID_Count <= 32, "section types overflow storage"); /// Selects which debug sections get dumped. enum DIDumpType : unsigned { DIDT_Null, DIDT_All = ~0U, #define HANDLE_DWARF_SECTION(ENUM_NAME, ELF_NAME, CMDLINE_NAME) \ DIDT_##ENUM_NAME = 1U << DIDT_ID_##ENUM_NAME, #include "llvm/BinaryFormat/Dwarf.def" #undef HANDLE_DWARF_SECTION DIDT_UUID = 1 << DIDT_ID_UUID, }; /// Container for dump options that control which debug information will be /// dumped. struct DIDumpOptions { unsigned DumpType = DIDT_All; unsigned RecurseDepth = -1U; bool ShowChildren = false; bool ShowParents = false; bool ShowForm = false; bool SummarizeTypes = false; bool Verbose = false; /// Return default option set for printing a single DIE without children. static DIDumpOptions getForSingleDIE() { DIDumpOptions Opts; Opts.RecurseDepth = 0; return Opts; } /// Return the options with RecurseDepth set to 0 unless explicitly required. DIDumpOptions noImplicitRecursion() const { DIDumpOptions Opts = *this; if (RecurseDepth == -1U && !ShowChildren) Opts.RecurseDepth = 0; return Opts; } }; class DIContext { public: enum DIContextKind { CK_DWARF, CK_PDB }; DIContext(DIContextKind K) : Kind(K) {} virtual ~DIContext() = default; DIContextKind getKind() const { return Kind; } virtual void dump(raw_ostream &OS, DIDumpOptions DumpOpts) = 0; virtual bool verify(raw_ostream &OS, DIDumpOptions DumpOpts = {}) { // No verifier? Just say things went well. return true; } virtual DILineInfo getLineInfoForAddress(uint64_t Address, DILineInfoSpecifier Specifier = DILineInfoSpecifier()) = 0; virtual DILineInfoTable getLineInfoForAddressRange(uint64_t Address, uint64_t Size, DILineInfoSpecifier Specifier = DILineInfoSpecifier()) = 0; virtual DIInliningInfo getInliningInfoForAddress(uint64_t Address, DILineInfoSpecifier Specifier = DILineInfoSpecifier()) = 0; private: const DIContextKind Kind; }; /// An inferface for inquiring the load address of a loaded object file /// to be used by the DIContext implementations when applying relocations /// on the fly. class LoadedObjectInfo { protected: LoadedObjectInfo() = default; LoadedObjectInfo(const LoadedObjectInfo &) = default; public: virtual ~LoadedObjectInfo() = default; /// Obtain the Load Address of a section by SectionRef. /// /// Calculate the address of the given section. /// The section need not be present in the local address space. The addresses /// need to be consistent with the addresses used to query the DIContext and /// the output of this function should be deterministic, i.e. repeated calls /// with the same Sec should give the same address. virtual uint64_t getSectionLoadAddress(const object::SectionRef &Sec) const { return 0; } /// If conveniently available, return the content of the given Section. /// /// When the section is available in the local address space, in relocated /// (loaded) form, e.g. because it was relocated by a JIT for execution, this /// function should provide the contents of said section in `Data`. If the /// loaded section is not available, or the cost of retrieving it would be /// prohibitive, this function should return false. In that case, relocations /// will be read from the local (unrelocated) object file and applied on the /// fly. Note that this method is used purely for optimzation purposes in the /// common case of JITting in the local address space, so returning false /// should always be correct. virtual bool getLoadedSectionContents(const object::SectionRef &Sec, StringRef &Data) const { return false; } // FIXME: This is untested and unused anywhere in the LLVM project, it's // used/needed by Julia (an external project). It should have some coverage // (at least tests, but ideally example functionality). /// Obtain a copy of this LoadedObjectInfo. virtual std::unique_ptr<LoadedObjectInfo> clone() const = 0; }; template <typename Derived, typename Base = LoadedObjectInfo> struct LoadedObjectInfoHelper : Base { protected: LoadedObjectInfoHelper(const LoadedObjectInfoHelper &) = default; LoadedObjectInfoHelper() = default; public: template <typename... Ts> LoadedObjectInfoHelper(Ts &&... Args) : Base(std::forward<Ts>(Args)...) {} std::unique_ptr<llvm::LoadedObjectInfo> clone() const override { return llvm::make_unique<Derived>(static_cast<const Derived &>(*this)); } }; } // end namespace llvm #endif // LLVM_DEBUGINFO_DICONTEXT_H