//===- FunctionInfo.h -------------------------------------------*- 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_GSYM_FUNCTIONINFO_H #define LLVM_DEBUGINFO_GSYM_FUNCTIONINFO_H #include "llvm/ADT/Optional.h" #include "llvm/DebugInfo/GSYM/InlineInfo.h" #include "llvm/DebugInfo/GSYM/LineTable.h" #include "llvm/DebugInfo/GSYM/LookupResult.h" #include "llvm/DebugInfo/GSYM/Range.h" #include "llvm/DebugInfo/GSYM/StringTable.h" #include #include namespace llvm { class raw_ostream; namespace gsym { class GsymReader; /// Function information in GSYM files encodes information for one contiguous /// address range. If a function has discontiguous address ranges, they will /// need to be encoded using multiple FunctionInfo objects. /// /// ENCODING /// /// The function information gets the function start address as an argument /// to the FunctionInfo::decode(...) function. This information is calculated /// from the GSYM header and an address offset from the GSYM address offsets /// table. The encoded FunctionInfo information must be aligned to a 4 byte /// boundary. /// /// The encoded data for a FunctionInfo starts with fixed data that all /// function info objects have: /// /// ENCODING NAME DESCRIPTION /// ========= =========== ==================================================== /// uint32_t Size The size in bytes of this function. /// uint32_t Name The string table offset of the function name. /// /// The optional data in a FunctionInfo object follows this fixed information /// and consists of a stream of tuples that consist of: /// /// ENCODING NAME DESCRIPTION /// ========= =========== ==================================================== /// uint32_t InfoType An "InfoType" enumeration that describes the type /// of optional data that is encoded. /// uint32_t InfoLength The size in bytes of the encoded data that /// immediately follows this length if this value is /// greater than zero. /// uint8_t[] InfoData Encoded bytes that represent the data for the /// "InfoType". These bytes are only present if /// "InfoLength" is greater than zero. /// /// The "InfoType" is an enumeration: /// /// enum InfoType { /// EndOfList = 0u, /// LineTableInfo = 1u, /// InlineInfo = 2u /// }; /// /// This stream of tuples is terminated by a "InfoType" whose value is /// InfoType::EndOfList and a zero for "InfoLength". This signifies the end of /// the optional information list. This format allows us to add new optional /// information data to a FunctionInfo object over time and allows older /// clients to still parse the format and skip over any data that they don't /// understand or want to parse. /// /// So the function information encoding essientially looks like: /// /// struct { /// uint32_t Size; /// uint32_t Name; /// struct { /// uint32_t InfoType; /// uint32_t InfoLength; /// uint8_t InfoData[InfoLength]; /// }[N]; /// } /// /// Where "N" is the number of tuples. struct FunctionInfo { AddressRange Range; uint32_t Name; ///< String table offset in the string table. llvm::Optional OptLineTable; llvm::Optional Inline; FunctionInfo(uint64_t Addr = 0, uint64_t Size = 0, uint32_t N = 0) : Range(Addr, Addr + Size), Name(N) {} /// Query if a FunctionInfo has rich debug info. /// /// \returns A bool that indicates if this object has something else than /// range and name. When converting information from a symbol table and from /// debug info, we might end up with multiple FunctionInfo objects for the /// same range and we need to be able to tell which one is the better object /// to use. bool hasRichInfo() const { return OptLineTable.hasValue() || Inline.hasValue(); } /// Query if a FunctionInfo object is valid. /// /// Address and size can be zero and there can be no line entries for a /// symbol so the only indication this entry is valid is if the name is /// not zero. This can happen when extracting information from symbol /// tables that do not encode symbol sizes. In that case only the /// address and name will be filled in. /// /// \returns A boolean indicating if this FunctionInfo is valid. bool isValid() const { return Name != 0; } /// Decode an object from a binary data stream. /// /// \param Data The binary stream to read the data from. This object must /// have the data for the object starting at offset zero. The data /// can contain more data than needed. /// /// \param BaseAddr The FunctionInfo's start address and will be used as the /// base address when decoding any contained information like the line table /// and the inline info. /// /// \returns An FunctionInfo or an error describing the issue that was /// encountered during decoding. static llvm::Expected decode(DataExtractor &Data, uint64_t BaseAddr); /// Encode this object into FileWriter stream. /// /// \param O The binary stream to write the data to at the current file /// position. /// /// \returns An error object that indicates failure or the offset of the /// function info that was successfully written into the stream. llvm::Expected encode(FileWriter &O) const; /// Lookup an address within a FunctionInfo object's data stream. /// /// Instead of decoding an entire FunctionInfo object when doing lookups, /// we can decode only the information we need from the FunctionInfo's data /// for the specific address. The lookup result information is returned as /// a LookupResult. /// /// \param Data The binary stream to read the data from. This object must /// have the data for the object starting at offset zero. The data /// can contain more data than needed. /// /// \param GR The GSYM reader that contains the string and file table that /// will be used to fill in information in the returned result. /// /// \param FuncAddr The function start address decoded from the GsymReader. /// /// \param Addr The address to lookup. /// /// \returns An LookupResult or an error describing the issue that was /// encountered during decoding. An error should only be returned if the /// address is not contained in the FunctionInfo or if the data is corrupted. static llvm::Expected lookup(DataExtractor &Data, const GsymReader &GR, uint64_t FuncAddr, uint64_t Addr); uint64_t startAddress() const { return Range.Start; } uint64_t endAddress() const { return Range.End; } uint64_t size() const { return Range.size(); } void setStartAddress(uint64_t Addr) { Range.Start = Addr; } void setEndAddress(uint64_t Addr) { Range.End = Addr; } void setSize(uint64_t Size) { Range.End = Range.Start + Size; } void clear() { Range = {0, 0}; Name = 0; OptLineTable = None; Inline = None; } }; inline bool operator==(const FunctionInfo &LHS, const FunctionInfo &RHS) { return LHS.Range == RHS.Range && LHS.Name == RHS.Name && LHS.OptLineTable == RHS.OptLineTable && LHS.Inline == RHS.Inline; } inline bool operator!=(const FunctionInfo &LHS, const FunctionInfo &RHS) { return !(LHS == RHS); } /// This sorting will order things consistently by address range first, but then /// followed by inlining being valid and line tables. We might end up with a /// FunctionInfo from debug info that will have the same range as one from the /// symbol table, but we want to quickly be able to sort and use the best version /// when creating the final GSYM file. inline bool operator<(const FunctionInfo &LHS, const FunctionInfo &RHS) { // First sort by address range if (LHS.Range != RHS.Range) return LHS.Range < RHS.Range; // Then sort by inline if (LHS.Inline.hasValue() != RHS.Inline.hasValue()) return RHS.Inline.hasValue(); return LHS.OptLineTable < RHS.OptLineTable; } raw_ostream &operator<<(raw_ostream &OS, const FunctionInfo &R); } // namespace gsym } // namespace llvm #endif // #ifndef LLVM_DEBUGINFO_GSYM_FUNCTIONINFO_H