66466ff151
When enabled, input sections that would otherwise overflow a memory region are instead spilled to the next matching output section. This feature parallels the one in GNU LD, but there are some differences from its documented behavior: - /DISCARD/ only matches previously-unmatched sections (i.e., the flag does not affect it). - If a section fails to fit at any of its matches, the link fails instead of discarding the section. - The flag --enable-non-contiguous-regions-warnings is not implemented, as it exists to warn about such occurrences. The implementation places stubs at possible spill locations, and replaces them with the original input section when effecting spills. Spilling decisions occur after address assignment. Sections are spilled in reverse order of assignment, with each spill naively decreasing the size of the affected memory regions. This continues until the memory regions are brought back under size. Spilling anything causes another pass of address assignment, and this continues to fixed point. Spilling after rather than during assignment allows the algorithm to consider the size effects of unspillable input sections that appear later in the assignment. Otherwise, such sections (e.g. thunks) may force an overflow, even if spilling something earlier could have avoided it. A few notable feature interactions occur: - Stubs affect alignment, ONLY_IF_RO, etc, broadly as if a copy of the input section were actually placed there. - SHF_MERGE synthetic sections use the spill list of their first contained input section (the one that gives the section its name). - ICF occurs oblivious to spill sections; spill lists for merged-away sections become inert and are removed after assignment. - SHF_LINK_ORDER and .ARM.exidx are ordered according to the final section ordering, after all spilling has completed. - INSERT BEFORE/AFTER and OVERWRITE_SECTIONS are explicitly disallowed.
492 lines
17 KiB
C++
492 lines
17 KiB
C++
//===- InputSection.h -------------------------------------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLD_ELF_INPUT_SECTION_H
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#define LLD_ELF_INPUT_SECTION_H
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#include "Config.h"
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#include "Relocations.h"
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#include "lld/Common/CommonLinkerContext.h"
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#include "lld/Common/LLVM.h"
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#include "lld/Common/Memory.h"
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#include "llvm/ADT/CachedHashString.h"
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#include "llvm/ADT/DenseSet.h"
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#include "llvm/ADT/StringExtras.h"
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#include "llvm/ADT/TinyPtrVector.h"
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#include "llvm/Object/ELF.h"
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#include "llvm/Support/Compiler.h"
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namespace lld {
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namespace elf {
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class InputFile;
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class Symbol;
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class Defined;
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struct Partition;
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class SyntheticSection;
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template <class ELFT> class ObjFile;
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class OutputSection;
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LLVM_LIBRARY_VISIBILITY extern std::vector<Partition> partitions;
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// Returned by InputSectionBase::relsOrRelas. At least one member is empty.
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template <class ELFT> struct RelsOrRelas {
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ArrayRef<typename ELFT::Rel> rels;
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ArrayRef<typename ELFT::Rela> relas;
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bool areRelocsRel() const { return rels.size(); }
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};
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// This is the base class of all sections that lld handles. Some are sections in
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// input files, some are sections in the produced output file and some exist
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// just as a convenience for implementing special ways of combining some
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// sections.
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class SectionBase {
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public:
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enum Kind { Regular, Synthetic, Spill, EHFrame, Merge, Output };
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Kind kind() const { return (Kind)sectionKind; }
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uint8_t sectionKind : 3;
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// The next two bit fields are only used by InputSectionBase, but we
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// put them here so the struct packs better.
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uint8_t bss : 1;
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// Set for sections that should not be folded by ICF.
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uint8_t keepUnique : 1;
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uint8_t partition = 1;
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uint32_t type;
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StringRef name;
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// The 1-indexed partition that this section is assigned to by the garbage
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// collector, or 0 if this section is dead. Normally there is only one
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// partition, so this will either be 0 or 1.
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elf::Partition &getPartition() const;
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// These corresponds to the fields in Elf_Shdr.
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uint64_t flags;
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uint32_t addralign;
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uint32_t entsize;
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uint32_t link;
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uint32_t info;
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OutputSection *getOutputSection();
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const OutputSection *getOutputSection() const {
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return const_cast<SectionBase *>(this)->getOutputSection();
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}
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// Translate an offset in the input section to an offset in the output
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// section.
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uint64_t getOffset(uint64_t offset) const;
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uint64_t getVA(uint64_t offset = 0) const;
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bool isLive() const { return partition != 0; }
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void markLive() { partition = 1; }
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void markDead() { partition = 0; }
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protected:
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constexpr SectionBase(Kind sectionKind, StringRef name, uint64_t flags,
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uint32_t entsize, uint32_t addralign, uint32_t type,
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uint32_t info, uint32_t link)
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: sectionKind(sectionKind), bss(false), keepUnique(false), type(type),
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name(name), flags(flags), addralign(addralign), entsize(entsize),
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link(link), info(info) {}
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};
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struct SymbolAnchor {
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uint64_t offset;
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Defined *d;
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bool end; // true for the anchor of st_value+st_size
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};
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struct RelaxAux {
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// This records symbol start and end offsets which will be adjusted according
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// to the nearest relocDeltas element.
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SmallVector<SymbolAnchor, 0> anchors;
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// For relocations[i], the actual offset is
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// r_offset - (i ? relocDeltas[i-1] : 0).
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std::unique_ptr<uint32_t[]> relocDeltas;
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// For relocations[i], the actual type is relocTypes[i].
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std::unique_ptr<RelType[]> relocTypes;
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SmallVector<uint32_t, 0> writes;
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};
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// This corresponds to a section of an input file.
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class InputSectionBase : public SectionBase {
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public:
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template <class ELFT>
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InputSectionBase(ObjFile<ELFT> &file, const typename ELFT::Shdr &header,
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StringRef name, Kind sectionKind);
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InputSectionBase(InputFile *file, uint64_t flags, uint32_t type,
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uint64_t entsize, uint32_t link, uint32_t info,
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uint32_t addralign, ArrayRef<uint8_t> data, StringRef name,
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Kind sectionKind);
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static bool classof(const SectionBase *s) { return s->kind() != Output; }
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// The file which contains this section. Its dynamic type is usually
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// ObjFile<ELFT>, but may be an InputFile of InternalKind (for a synthetic
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// section).
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InputFile *file;
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// Input sections are part of an output section. Special sections
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// like .eh_frame and merge sections are first combined into a
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// synthetic section that is then added to an output section. In all
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// cases this points one level up.
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SectionBase *parent = nullptr;
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// Section index of the relocation section if exists.
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uint32_t relSecIdx = 0;
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// Getter when the dynamic type is ObjFile<ELFT>.
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template <class ELFT> ObjFile<ELFT> *getFile() const {
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return cast<ObjFile<ELFT>>(file);
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}
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// Used by --optimize-bb-jumps and RISC-V linker relaxation temporarily to
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// indicate the number of bytes which is not counted in the size. This should
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// be reset to zero after uses.
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uint32_t bytesDropped = 0;
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mutable bool compressed = false;
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// Whether the section needs to be padded with a NOP filler due to
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// deleteFallThruJmpInsn.
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bool nopFiller = false;
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void drop_back(unsigned num) {
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assert(bytesDropped + num < 256);
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bytesDropped += num;
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}
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void push_back(uint64_t num) {
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assert(bytesDropped >= num);
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bytesDropped -= num;
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}
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mutable const uint8_t *content_;
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uint64_t size;
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void trim() {
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if (bytesDropped) {
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size -= bytesDropped;
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bytesDropped = 0;
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}
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}
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ArrayRef<uint8_t> content() const {
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return ArrayRef<uint8_t>(content_, size);
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}
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ArrayRef<uint8_t> contentMaybeDecompress() const {
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if (compressed)
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decompress();
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return content();
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}
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// The next member in the section group if this section is in a group. This is
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// used by --gc-sections.
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InputSectionBase *nextInSectionGroup = nullptr;
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template <class ELFT> RelsOrRelas<ELFT> relsOrRelas() const;
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// InputSections that are dependent on us (reverse dependency for GC)
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llvm::TinyPtrVector<InputSection *> dependentSections;
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// Returns the size of this section (even if this is a common or BSS.)
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size_t getSize() const;
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InputSection *getLinkOrderDep() const;
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// Get a symbol that encloses this offset from within the section. If type is
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// not zero, return a symbol with the specified type.
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Defined *getEnclosingSymbol(uint64_t offset, uint8_t type = 0) const;
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Defined *getEnclosingFunction(uint64_t offset) const {
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return getEnclosingSymbol(offset, llvm::ELF::STT_FUNC);
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}
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// Returns a source location string. Used to construct an error message.
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std::string getLocation(uint64_t offset) const;
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std::string getSrcMsg(const Symbol &sym, uint64_t offset) const;
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std::string getObjMsg(uint64_t offset) const;
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// Each section knows how to relocate itself. These functions apply
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// relocations, assuming that Buf points to this section's copy in
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// the mmap'ed output buffer.
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template <class ELFT> void relocate(uint8_t *buf, uint8_t *bufEnd);
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static uint64_t getRelocTargetVA(const InputFile *File, RelType Type,
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int64_t A, uint64_t P, const Symbol &Sym,
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RelExpr Expr);
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// The native ELF reloc data type is not very convenient to handle.
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// So we convert ELF reloc records to our own records in Relocations.cpp.
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// This vector contains such "cooked" relocations.
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SmallVector<Relocation, 0> relocations;
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void addReloc(const Relocation &r) { relocations.push_back(r); }
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MutableArrayRef<Relocation> relocs() { return relocations; }
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ArrayRef<Relocation> relocs() const { return relocations; }
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union {
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// These are modifiers to jump instructions that are necessary when basic
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// block sections are enabled. Basic block sections creates opportunities
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// to relax jump instructions at basic block boundaries after reordering the
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// basic blocks.
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JumpInstrMod *jumpInstrMod = nullptr;
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// Auxiliary information for RISC-V and LoongArch linker relaxation.
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// They do not use jumpInstrMod.
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RelaxAux *relaxAux;
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// The compressed content size when `compressed` is true.
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size_t compressedSize;
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};
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// A function compiled with -fsplit-stack calling a function
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// compiled without -fsplit-stack needs its prologue adjusted. Find
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// such functions and adjust their prologues. This is very similar
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// to relocation. See https://gcc.gnu.org/wiki/SplitStacks for more
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// information.
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template <typename ELFT>
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void adjustSplitStackFunctionPrologues(uint8_t *buf, uint8_t *end);
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template <typename T> llvm::ArrayRef<T> getDataAs() const {
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size_t s = content().size();
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assert(s % sizeof(T) == 0);
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return llvm::ArrayRef<T>((const T *)content().data(), s / sizeof(T));
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}
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protected:
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template <typename ELFT>
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void parseCompressedHeader();
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void decompress() const;
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};
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// SectionPiece represents a piece of splittable section contents.
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// We allocate a lot of these and binary search on them. This means that they
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// have to be as compact as possible, which is why we don't store the size (can
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// be found by looking at the next one).
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struct SectionPiece {
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SectionPiece() = default;
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SectionPiece(size_t off, uint32_t hash, bool live)
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: inputOff(off), live(live), hash(hash >> 1) {}
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uint32_t inputOff;
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uint32_t live : 1;
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uint32_t hash : 31;
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uint64_t outputOff = 0;
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};
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static_assert(sizeof(SectionPiece) == 16, "SectionPiece is too big");
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// This corresponds to a SHF_MERGE section of an input file.
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class MergeInputSection : public InputSectionBase {
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public:
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template <class ELFT>
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MergeInputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
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StringRef name);
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MergeInputSection(uint64_t flags, uint32_t type, uint64_t entsize,
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ArrayRef<uint8_t> data, StringRef name);
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static bool classof(const SectionBase *s) { return s->kind() == Merge; }
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void splitIntoPieces();
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// Translate an offset in the input section to an offset in the parent
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// MergeSyntheticSection.
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uint64_t getParentOffset(uint64_t offset) const;
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// Splittable sections are handled as a sequence of data
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// rather than a single large blob of data.
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SmallVector<SectionPiece, 0> pieces;
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// Returns I'th piece's data. This function is very hot when
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// string merging is enabled, so we want to inline.
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LLVM_ATTRIBUTE_ALWAYS_INLINE
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llvm::CachedHashStringRef getData(size_t i) const {
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size_t begin = pieces[i].inputOff;
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size_t end =
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(pieces.size() - 1 == i) ? content().size() : pieces[i + 1].inputOff;
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return {toStringRef(content().slice(begin, end - begin)), pieces[i].hash};
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}
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// Returns the SectionPiece at a given input section offset.
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SectionPiece &getSectionPiece(uint64_t offset);
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const SectionPiece &getSectionPiece(uint64_t offset) const {
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return const_cast<MergeInputSection *>(this)->getSectionPiece(offset);
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}
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SyntheticSection *getParent() const {
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return cast_or_null<SyntheticSection>(parent);
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}
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private:
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void splitStrings(StringRef s, size_t size);
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void splitNonStrings(ArrayRef<uint8_t> a, size_t size);
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};
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struct EhSectionPiece {
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EhSectionPiece(size_t off, InputSectionBase *sec, uint32_t size,
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unsigned firstRelocation)
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: inputOff(off), sec(sec), size(size), firstRelocation(firstRelocation) {}
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ArrayRef<uint8_t> data() const {
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return {sec->content().data() + this->inputOff, size};
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}
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size_t inputOff;
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ssize_t outputOff = -1;
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InputSectionBase *sec;
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uint32_t size;
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unsigned firstRelocation;
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};
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// This corresponds to a .eh_frame section of an input file.
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class EhInputSection : public InputSectionBase {
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public:
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template <class ELFT>
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EhInputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
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StringRef name);
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static bool classof(const SectionBase *s) { return s->kind() == EHFrame; }
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template <class ELFT> void split();
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template <class ELFT, class RelTy> void split(ArrayRef<RelTy> rels);
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// Splittable sections are handled as a sequence of data
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// rather than a single large blob of data.
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SmallVector<EhSectionPiece, 0> cies, fdes;
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SyntheticSection *getParent() const;
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uint64_t getParentOffset(uint64_t offset) const;
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};
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// This is a section that is added directly to an output section
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// instead of needing special combination via a synthetic section. This
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// includes all input sections with the exceptions of SHF_MERGE and
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// .eh_frame. It also includes the synthetic sections themselves.
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class InputSection : public InputSectionBase {
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public:
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InputSection(InputFile *f, uint64_t flags, uint32_t type, uint32_t addralign,
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ArrayRef<uint8_t> data, StringRef name, Kind k = Regular);
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template <class ELFT>
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InputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
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StringRef name);
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static bool classof(const SectionBase *s) {
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return s->kind() == SectionBase::Regular ||
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s->kind() == SectionBase::Synthetic ||
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s->kind() == SectionBase::Spill;
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}
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// Write this section to a mmap'ed file, assuming Buf is pointing to
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// beginning of the output section.
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template <class ELFT> void writeTo(uint8_t *buf);
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OutputSection *getParent() const {
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return reinterpret_cast<OutputSection *>(parent);
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}
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// This variable has two usages. Initially, it represents an index in the
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// OutputSection's InputSection list, and is used when ordering SHF_LINK_ORDER
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// sections. After assignAddresses is called, it represents the offset from
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// the beginning of the output section this section was assigned to.
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uint64_t outSecOff = 0;
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InputSectionBase *getRelocatedSection() const;
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template <class ELFT, class RelTy>
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void relocateNonAlloc(uint8_t *buf, llvm::ArrayRef<RelTy> rels);
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// Points to the canonical section. If ICF folds two sections, repl pointer of
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// one section points to the other.
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InputSection *repl = this;
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// Used by ICF.
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uint32_t eqClass[2] = {0, 0};
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// Called by ICF to merge two input sections.
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void replace(InputSection *other);
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static InputSection discarded;
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private:
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template <class ELFT, class RelTy> void copyRelocations(uint8_t *buf);
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template <class ELFT, class RelTy, class RelIt>
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void copyRelocations(uint8_t *buf, llvm::iterator_range<RelIt> rels);
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template <class ELFT> void copyShtGroup(uint8_t *buf);
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};
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// A marker for a potential spill location for another input section. This
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// broadly acts as if it were the original section until address assignment.
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// Then it is either replaced with the real input section or removed.
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class PotentialSpillSection : public InputSection {
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public:
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// The containing input section description; used to quickly replace this stub
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// with the actual section.
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InputSectionDescription *isd;
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// Next potential spill location for the same source input section.
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PotentialSpillSection *next = nullptr;
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PotentialSpillSection(const InputSectionBase &source,
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InputSectionDescription &isd);
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static bool classof(const SectionBase *sec) {
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return sec->kind() == InputSectionBase::Spill;
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}
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};
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static_assert(sizeof(InputSection) <= 160, "InputSection is too big");
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class SyntheticSection : public InputSection {
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public:
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SyntheticSection(uint64_t flags, uint32_t type, uint32_t addralign,
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StringRef name)
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: InputSection(ctx.internalFile, flags, type, addralign, {}, name,
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InputSectionBase::Synthetic) {}
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virtual ~SyntheticSection() = default;
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virtual size_t getSize() const = 0;
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virtual bool updateAllocSize() { return false; }
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// If the section has the SHF_ALLOC flag and the size may be changed if
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// thunks are added, update the section size.
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virtual bool isNeeded() const { return true; }
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virtual void finalizeContents() {}
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virtual void writeTo(uint8_t *buf) = 0;
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static bool classof(const SectionBase *sec) {
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return sec->kind() == InputSectionBase::Synthetic;
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}
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};
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inline bool isStaticRelSecType(uint32_t type) {
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|
return type == llvm::ELF::SHT_RELA || type == llvm::ELF::SHT_REL;
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|
}
|
|
|
|
inline bool isDebugSection(const InputSectionBase &sec) {
|
|
return (sec.flags & llvm::ELF::SHF_ALLOC) == 0 &&
|
|
sec.name.starts_with(".debug");
|
|
}
|
|
|
|
// The set of TOC entries (.toc + addend) for which we should not apply
|
|
// toc-indirect to toc-relative relaxation. const Symbol * refers to the
|
|
// STT_SECTION symbol associated to the .toc input section.
|
|
extern llvm::DenseSet<std::pair<const Symbol *, uint64_t>> ppc64noTocRelax;
|
|
|
|
} // namespace elf
|
|
|
|
std::string toString(const elf::InputSectionBase *);
|
|
} // namespace lld
|
|
|
|
#endif
|