//===- Chunks.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 LLD_COFF_CHUNKS_H #define LLD_COFF_CHUNKS_H #include "Config.h" #include "InputFiles.h" #include "lld/Common/LLVM.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/PointerIntPair.h" #include "llvm/ADT/iterator.h" #include "llvm/ADT/iterator_range.h" #include "llvm/MC/StringTableBuilder.h" #include "llvm/Object/COFF.h" #include #include namespace lld { namespace coff { using llvm::COFF::ImportDirectoryTableEntry; using llvm::object::COFFSymbolRef; using llvm::object::SectionRef; using llvm::object::coff_relocation; using llvm::object::coff_section; class Baserel; class Defined; class DefinedImportData; class DefinedRegular; class ObjFile; class OutputSection; class RuntimePseudoReloc; class Symbol; // Mask for permissions (discardable, writable, readable, executable, etc). const uint32_t permMask = 0xFE000000; // Mask for section types (code, data, bss). const uint32_t typeMask = 0x000000E0; // The log base 2 of the largest section alignment, which is log2(8192), or 13. enum : unsigned { Log2MaxSectionAlignment = 13 }; // A Chunk represents a chunk of data that will occupy space in the // output (if the resolver chose that). It may or may not be backed by // a section of an input file. It could be linker-created data, or // doesn't even have actual data (if common or bss). class Chunk { public: enum Kind : uint8_t { SectionKind, OtherKind, ImportThunkKind }; Kind kind() const { return chunkKind; } // Returns the size of this chunk (even if this is a common or BSS.) size_t getSize() const; // Returns chunk alignment in power of two form. Value values are powers of // two from 1 to 8192. uint32_t getAlignment() const { return 1U << p2Align; } // Update the chunk section alignment measured in bytes. Internally alignment // is stored in log2. void setAlignment(uint32_t align) { // Treat zero byte alignment as 1 byte alignment. align = align ? align : 1; assert(llvm::isPowerOf2_32(align) && "alignment is not a power of 2"); p2Align = llvm::Log2_32(align); assert(p2Align <= Log2MaxSectionAlignment && "impossible requested alignment"); } // Write this chunk to a mmap'ed file, assuming Buf is pointing to // beginning of the file. Because this function may use RVA values // of other chunks for relocations, you need to set them properly // before calling this function. void writeTo(uint8_t *buf) const; // The writer sets and uses the addresses. In practice, PE images cannot be // larger than 2GB. Chunks are always laid as part of the image, so Chunk RVAs // can be stored with 32 bits. uint32_t getRVA() const { return rva; } void setRVA(uint64_t v) { // This may truncate. The writer checks for overflow later. rva = (uint32_t)v; } // Returns readable/writable/executable bits. uint32_t getOutputCharacteristics() const; // Returns the section name if this is a section chunk. // It is illegal to call this function on non-section chunks. StringRef getSectionName() const; // An output section has pointers to chunks in the section, and each // chunk has a back pointer to an output section. void setOutputSectionIdx(uint16_t o) { osidx = o; } uint16_t getOutputSectionIdx() const { return osidx; } // Windows-specific. // Collect all locations that contain absolute addresses for base relocations. void getBaserels(std::vector *res); // Returns a human-readable name of this chunk. Chunks are unnamed chunks of // bytes, so this is used only for logging or debugging. StringRef getDebugName() const; // Return true if this file has the hotpatch flag set to true in the // S_COMPILE3 record in codeview debug info. Also returns true for some thunks // synthesized by the linker. bool isHotPatchable() const; protected: Chunk(Kind k = OtherKind) : chunkKind(k), hasData(true), p2Align(0) {} const Kind chunkKind; public: // Returns true if this has non-zero data. BSS chunks return // false. If false is returned, the space occupied by this chunk // will be filled with zeros. Corresponds to the // IMAGE_SCN_CNT_UNINITIALIZED_DATA section characteristic bit. uint8_t hasData : 1; public: // The alignment of this chunk, stored in log2 form. The writer uses the // value. uint8_t p2Align : 7; // The output section index for this chunk. The first valid section number is // one. uint16_t osidx = 0; // The RVA of this chunk in the output. The writer sets a value. uint32_t rva = 0; }; class NonSectionChunk : public Chunk { public: virtual ~NonSectionChunk() = default; // Returns the size of this chunk (even if this is a common or BSS.) virtual size_t getSize() const = 0; virtual uint32_t getOutputCharacteristics() const { return 0; } // Write this chunk to a mmap'ed file, assuming Buf is pointing to // beginning of the file. Because this function may use RVA values // of other chunks for relocations, you need to set them properly // before calling this function. virtual void writeTo(uint8_t *buf) const {} // Returns the section name if this is a section chunk. // It is illegal to call this function on non-section chunks. virtual StringRef getSectionName() const { llvm_unreachable("unimplemented getSectionName"); } // Windows-specific. // Collect all locations that contain absolute addresses for base relocations. virtual void getBaserels(std::vector *res) {} // Returns a human-readable name of this chunk. Chunks are unnamed chunks of // bytes, so this is used only for logging or debugging. virtual StringRef getDebugName() const { return ""; } static bool classof(const Chunk *c) { return c->kind() != SectionKind; } protected: NonSectionChunk(Kind k = OtherKind) : Chunk(k) {} }; // A chunk corresponding a section of an input file. class SectionChunk final : public Chunk { // Identical COMDAT Folding feature accesses section internal data. friend class ICF; public: class symbol_iterator : public llvm::iterator_adaptor_base< symbol_iterator, const coff_relocation *, std::random_access_iterator_tag, Symbol *> { friend SectionChunk; ObjFile *file; symbol_iterator(ObjFile *file, const coff_relocation *i) : symbol_iterator::iterator_adaptor_base(i), file(file) {} public: symbol_iterator() = default; Symbol *operator*() const { return file->getSymbol(I->SymbolTableIndex); } }; SectionChunk(ObjFile *file, const coff_section *header); static bool classof(const Chunk *c) { return c->kind() == SectionKind; } size_t getSize() const { return header->SizeOfRawData; } ArrayRef getContents() const; void writeTo(uint8_t *buf) const; // Defend against unsorted relocations. This may be overly conservative. void sortRelocations(); // Write and relocate a portion of the section. This is intended to be called // in a loop. Relocations must be sorted first. void writeAndRelocateSubsection(ArrayRef sec, ArrayRef subsec, uint32_t &nextRelocIndex, uint8_t *buf) const; uint32_t getOutputCharacteristics() const { return header->Characteristics & (permMask | typeMask); } StringRef getSectionName() const { return StringRef(sectionNameData, sectionNameSize); } void getBaserels(std::vector *res); bool isCOMDAT() const; void applyRelocation(uint8_t *off, const coff_relocation &rel) const; void applyRelX64(uint8_t *off, uint16_t type, OutputSection *os, uint64_t s, uint64_t p) const; void applyRelX86(uint8_t *off, uint16_t type, OutputSection *os, uint64_t s, uint64_t p) const; void applyRelARM(uint8_t *off, uint16_t type, OutputSection *os, uint64_t s, uint64_t p) const; void applyRelARM64(uint8_t *off, uint16_t type, OutputSection *os, uint64_t s, uint64_t p) const; void getRuntimePseudoRelocs(std::vector &res); // Called if the garbage collector decides to not include this chunk // in a final output. It's supposed to print out a log message to stdout. void printDiscardedMessage() const; // Adds COMDAT associative sections to this COMDAT section. A chunk // and its children are treated as a group by the garbage collector. void addAssociative(SectionChunk *child); StringRef getDebugName() const; // True if this is a codeview debug info chunk. These will not be laid out in // the image. Instead they will end up in the PDB, if one is requested. bool isCodeView() const { return getSectionName() == ".debug" || getSectionName().startswith(".debug$"); } // True if this is a DWARF debug info or exception handling chunk. bool isDWARF() const { return getSectionName().startswith(".debug_") || getSectionName() == ".eh_frame"; } // Allow iteration over the bodies of this chunk's relocated symbols. llvm::iterator_range symbols() const { return llvm::make_range(symbol_iterator(file, relocsData), symbol_iterator(file, relocsData + relocsSize)); } ArrayRef getRelocs() const { return llvm::makeArrayRef(relocsData, relocsSize); } // Reloc setter used by ARM range extension thunk insertion. void setRelocs(ArrayRef newRelocs) { relocsData = newRelocs.data(); relocsSize = newRelocs.size(); assert(relocsSize == newRelocs.size() && "reloc size truncation"); } // Single linked list iterator for associated comdat children. class AssociatedIterator : public llvm::iterator_facade_base< AssociatedIterator, std::forward_iterator_tag, SectionChunk> { public: AssociatedIterator() = default; AssociatedIterator(SectionChunk *head) : cur(head) {} bool operator==(const AssociatedIterator &r) const { return cur == r.cur; } // FIXME: Wrong const-ness, but it makes filter ranges work. SectionChunk &operator*() const { return *cur; } SectionChunk &operator*() { return *cur; } AssociatedIterator &operator++() { cur = cur->assocChildren; return *this; } private: SectionChunk *cur = nullptr; }; // Allow iteration over the associated child chunks for this section. llvm::iterator_range children() const { // Associated sections do not have children. The assocChildren field is // part of the parent's list of children. bool isAssoc = selection == llvm::COFF::IMAGE_COMDAT_SELECT_ASSOCIATIVE; return llvm::make_range( AssociatedIterator(isAssoc ? nullptr : assocChildren), AssociatedIterator(nullptr)); } // The section ID this chunk belongs to in its Obj. uint32_t getSectionNumber() const; ArrayRef consumeDebugMagic(); static ArrayRef consumeDebugMagic(ArrayRef data, StringRef sectionName); static SectionChunk *findByName(ArrayRef sections, StringRef name); // The file that this chunk was created from. ObjFile *file; // Pointer to the COFF section header in the input file. const coff_section *header; // The COMDAT leader symbol if this is a COMDAT chunk. DefinedRegular *sym = nullptr; // The CRC of the contents as described in the COFF spec 4.5.5. // Auxiliary Format 5: Section Definitions. Used for ICF. uint32_t checksum = 0; // Used by the garbage collector. bool live; // Whether this section needs to be kept distinct from other sections during // ICF. This is set by the driver using address-significance tables. bool keepUnique = false; // The COMDAT selection if this is a COMDAT chunk. llvm::COFF::COMDATType selection = (llvm::COFF::COMDATType)0; // A pointer pointing to a replacement for this chunk. // Initially it points to "this" object. If this chunk is merged // with other chunk by ICF, it points to another chunk, // and this chunk is considered as dead. SectionChunk *repl; private: SectionChunk *assocChildren = nullptr; // Used for ICF (Identical COMDAT Folding) void replace(SectionChunk *other); uint32_t eqClass[2] = {0, 0}; // Relocations for this section. Size is stored below. const coff_relocation *relocsData; // Section name string. Size is stored below. const char *sectionNameData; uint32_t relocsSize = 0; uint32_t sectionNameSize = 0; }; // Inline methods to implement faux-virtual dispatch for SectionChunk. inline size_t Chunk::getSize() const { if (isa(this)) return static_cast(this)->getSize(); else return static_cast(this)->getSize(); } inline uint32_t Chunk::getOutputCharacteristics() const { if (isa(this)) return static_cast(this)->getOutputCharacteristics(); else return static_cast(this) ->getOutputCharacteristics(); } inline void Chunk::writeTo(uint8_t *buf) const { if (isa(this)) static_cast(this)->writeTo(buf); else static_cast(this)->writeTo(buf); } inline StringRef Chunk::getSectionName() const { if (isa(this)) return static_cast(this)->getSectionName(); else return static_cast(this)->getSectionName(); } inline void Chunk::getBaserels(std::vector *res) { if (isa(this)) static_cast(this)->getBaserels(res); else static_cast(this)->getBaserels(res); } inline StringRef Chunk::getDebugName() const { if (isa(this)) return static_cast(this)->getDebugName(); else return static_cast(this)->getDebugName(); } // This class is used to implement an lld-specific feature (not implemented in // MSVC) that minimizes the output size by finding string literals sharing tail // parts and merging them. // // If string tail merging is enabled and a section is identified as containing a // string literal, it is added to a MergeChunk with an appropriate alignment. // The MergeChunk then tail merges the strings using the StringTableBuilder // class and assigns RVAs and section offsets to each of the member chunks based // on the offsets assigned by the StringTableBuilder. class MergeChunk : public NonSectionChunk { public: MergeChunk(uint32_t alignment); static void addSection(COFFLinkerContext &ctx, SectionChunk *c); void finalizeContents(); void assignSubsectionRVAs(); uint32_t getOutputCharacteristics() const override; StringRef getSectionName() const override { return ".rdata"; } size_t getSize() const override; void writeTo(uint8_t *buf) const override; std::vector sections; private: llvm::StringTableBuilder builder; bool finalized = false; }; // A chunk for common symbols. Common chunks don't have actual data. class CommonChunk : public NonSectionChunk { public: CommonChunk(const COFFSymbolRef sym); size_t getSize() const override { return sym.getValue(); } uint32_t getOutputCharacteristics() const override; StringRef getSectionName() const override { return ".bss"; } private: const COFFSymbolRef sym; }; // A chunk for linker-created strings. class StringChunk : public NonSectionChunk { public: explicit StringChunk(StringRef s) : str(s) {} size_t getSize() const override { return str.size() + 1; } void writeTo(uint8_t *buf) const override; private: StringRef str; }; static const uint8_t importThunkX86[] = { 0xff, 0x25, 0x00, 0x00, 0x00, 0x00, // JMP *0x0 }; static const uint8_t importThunkARM[] = { 0x40, 0xf2, 0x00, 0x0c, // mov.w ip, #0 0xc0, 0xf2, 0x00, 0x0c, // mov.t ip, #0 0xdc, 0xf8, 0x00, 0xf0, // ldr.w pc, [ip] }; static const uint8_t importThunkARM64[] = { 0x10, 0x00, 0x00, 0x90, // adrp x16, #0 0x10, 0x02, 0x40, 0xf9, // ldr x16, [x16] 0x00, 0x02, 0x1f, 0xd6, // br x16 }; // Windows-specific. // A chunk for DLL import jump table entry. In a final output, its // contents will be a JMP instruction to some __imp_ symbol. class ImportThunkChunk : public NonSectionChunk { public: ImportThunkChunk(Defined *s) : NonSectionChunk(ImportThunkKind), impSymbol(s) {} static bool classof(const Chunk *c) { return c->kind() == ImportThunkKind; } protected: Defined *impSymbol; }; class ImportThunkChunkX64 : public ImportThunkChunk { public: explicit ImportThunkChunkX64(Defined *s); size_t getSize() const override { return sizeof(importThunkX86); } void writeTo(uint8_t *buf) const override; }; class ImportThunkChunkX86 : public ImportThunkChunk { public: explicit ImportThunkChunkX86(Defined *s) : ImportThunkChunk(s) {} size_t getSize() const override { return sizeof(importThunkX86); } void getBaserels(std::vector *res) override; void writeTo(uint8_t *buf) const override; }; class ImportThunkChunkARM : public ImportThunkChunk { public: explicit ImportThunkChunkARM(Defined *s) : ImportThunkChunk(s) { setAlignment(2); } size_t getSize() const override { return sizeof(importThunkARM); } void getBaserels(std::vector *res) override; void writeTo(uint8_t *buf) const override; }; class ImportThunkChunkARM64 : public ImportThunkChunk { public: explicit ImportThunkChunkARM64(Defined *s) : ImportThunkChunk(s) { setAlignment(4); } size_t getSize() const override { return sizeof(importThunkARM64); } void writeTo(uint8_t *buf) const override; }; class RangeExtensionThunkARM : public NonSectionChunk { public: explicit RangeExtensionThunkARM(Defined *t) : target(t) { setAlignment(2); } size_t getSize() const override; void writeTo(uint8_t *buf) const override; Defined *target; }; class RangeExtensionThunkARM64 : public NonSectionChunk { public: explicit RangeExtensionThunkARM64(Defined *t) : target(t) { setAlignment(4); } size_t getSize() const override; void writeTo(uint8_t *buf) const override; Defined *target; }; // Windows-specific. // See comments for DefinedLocalImport class. class LocalImportChunk : public NonSectionChunk { public: explicit LocalImportChunk(Defined *s) : sym(s) { setAlignment(config->wordsize); } size_t getSize() const override; void getBaserels(std::vector *res) override; void writeTo(uint8_t *buf) const override; private: Defined *sym; }; // Duplicate RVAs are not allowed in RVA tables, so unique symbols by chunk and // offset into the chunk. Order does not matter as the RVA table will be sorted // later. struct ChunkAndOffset { Chunk *inputChunk; uint32_t offset; struct DenseMapInfo { static ChunkAndOffset getEmptyKey() { return {llvm::DenseMapInfo::getEmptyKey(), 0}; } static ChunkAndOffset getTombstoneKey() { return {llvm::DenseMapInfo::getTombstoneKey(), 0}; } static unsigned getHashValue(const ChunkAndOffset &co) { return llvm::DenseMapInfo>::getHashValue( {co.inputChunk, co.offset}); } static bool isEqual(const ChunkAndOffset &lhs, const ChunkAndOffset &rhs) { return lhs.inputChunk == rhs.inputChunk && lhs.offset == rhs.offset; } }; }; using SymbolRVASet = llvm::DenseSet; // Table which contains symbol RVAs. Used for /safeseh and /guard:cf. class RVATableChunk : public NonSectionChunk { public: explicit RVATableChunk(SymbolRVASet s) : syms(std::move(s)) {} size_t getSize() const override { return syms.size() * 4; } void writeTo(uint8_t *buf) const override; private: SymbolRVASet syms; }; // Table which contains symbol RVAs with flags. Used for /guard:ehcont. class RVAFlagTableChunk : public NonSectionChunk { public: explicit RVAFlagTableChunk(SymbolRVASet s) : syms(std::move(s)) {} size_t getSize() const override { return syms.size() * 5; } void writeTo(uint8_t *buf) const override; private: SymbolRVASet syms; }; // Windows-specific. // This class represents a block in .reloc section. // See the PE/COFF spec 5.6 for details. class BaserelChunk : public NonSectionChunk { public: BaserelChunk(uint32_t page, Baserel *begin, Baserel *end); size_t getSize() const override { return data.size(); } void writeTo(uint8_t *buf) const override; private: std::vector data; }; class Baserel { public: Baserel(uint32_t v, uint8_t ty) : rva(v), type(ty) {} explicit Baserel(uint32_t v) : Baserel(v, getDefaultType()) {} uint8_t getDefaultType(); uint32_t rva; uint8_t type; }; // This is a placeholder Chunk, to allow attaching a DefinedSynthetic to a // specific place in a section, without any data. This is used for the MinGW // specific symbol __RUNTIME_PSEUDO_RELOC_LIST_END__, even though the concept // of an empty chunk isn't MinGW specific. class EmptyChunk : public NonSectionChunk { public: EmptyChunk() {} size_t getSize() const override { return 0; } void writeTo(uint8_t *buf) const override {} }; // MinGW specific, for the "automatic import of variables from DLLs" feature. // This provides the table of runtime pseudo relocations, for variable // references that turned out to need to be imported from a DLL even though // the reference didn't use the dllimport attribute. The MinGW runtime will // process this table after loading, before handling control over to user // code. class PseudoRelocTableChunk : public NonSectionChunk { public: PseudoRelocTableChunk(std::vector &relocs) : relocs(std::move(relocs)) { setAlignment(4); } size_t getSize() const override; void writeTo(uint8_t *buf) const override; private: std::vector relocs; }; // MinGW specific; information about one individual location in the image // that needs to be fixed up at runtime after loading. This represents // one individual element in the PseudoRelocTableChunk table. class RuntimePseudoReloc { public: RuntimePseudoReloc(Defined *sym, SectionChunk *target, uint32_t targetOffset, int flags) : sym(sym), target(target), targetOffset(targetOffset), flags(flags) {} Defined *sym; SectionChunk *target; uint32_t targetOffset; // The Flags field contains the size of the relocation, in bits. No other // flags are currently defined. int flags; }; // MinGW specific. A Chunk that contains one pointer-sized absolute value. class AbsolutePointerChunk : public NonSectionChunk { public: AbsolutePointerChunk(uint64_t value) : value(value) { setAlignment(getSize()); } size_t getSize() const override; void writeTo(uint8_t *buf) const override; private: uint64_t value; }; // Return true if this file has the hotpatch flag set to true in the S_COMPILE3 // record in codeview debug info. Also returns true for some thunks synthesized // by the linker. inline bool Chunk::isHotPatchable() const { if (auto *sc = dyn_cast(this)) return sc->file->hotPatchable; else if (isa(this)) return true; return false; } void applyMOV32T(uint8_t *off, uint32_t v); void applyBranch24T(uint8_t *off, int32_t v); void applyArm64Addr(uint8_t *off, uint64_t s, uint64_t p, int shift); void applyArm64Imm(uint8_t *off, uint64_t imm, uint32_t rangeLimit); void applyArm64Branch26(uint8_t *off, int64_t v); } // namespace coff } // namespace lld namespace llvm { template <> struct DenseMapInfo : lld::coff::ChunkAndOffset::DenseMapInfo {}; } #endif