llvm-project/llvm/tools/llvm-objcopy/Object.cpp

1403 lines
49 KiB
C++

//===- Object.cpp ---------------------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "Object.h"
#include "llvm-objcopy.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Twine.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/BinaryFormat/ELF.h"
#include "llvm/Object/ELFObjectFile.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/FileOutputBuffer.h"
#include "llvm/Support/Path.h"
#include <algorithm>
#include <cstddef>
#include <cstdint>
#include <iterator>
#include <utility>
#include <vector>
using namespace llvm;
using namespace llvm::objcopy;
using namespace object;
using namespace ELF;
Buffer::~Buffer() {}
void FileBuffer::allocate(size_t Size) {
Expected<std::unique_ptr<FileOutputBuffer>> BufferOrErr =
FileOutputBuffer::create(getName(), Size, FileOutputBuffer::F_executable);
handleAllErrors(BufferOrErr.takeError(), [this](const ErrorInfoBase &E) {
error("failed to open " + getName() + ": " + E.message());
});
Buf = std::move(*BufferOrErr);
}
Error FileBuffer::commit() { return Buf->commit(); }
uint8_t *FileBuffer::getBufferStart() {
return reinterpret_cast<uint8_t *>(Buf->getBufferStart());
}
void MemBuffer::allocate(size_t Size) {
Buf = WritableMemoryBuffer::getNewMemBuffer(Size, getName());
}
Error MemBuffer::commit() { return Error::success(); }
uint8_t *MemBuffer::getBufferStart() {
return reinterpret_cast<uint8_t *>(Buf->getBufferStart());
}
std::unique_ptr<WritableMemoryBuffer> MemBuffer::releaseMemoryBuffer() {
return std::move(Buf);
}
template <class ELFT> void ELFWriter<ELFT>::writePhdr(const Segment &Seg) {
using Elf_Phdr = typename ELFT::Phdr;
uint8_t *B = Buf.getBufferStart();
B += Obj.ProgramHdrSegment.Offset + Seg.Index * sizeof(Elf_Phdr);
Elf_Phdr &Phdr = *reinterpret_cast<Elf_Phdr *>(B);
Phdr.p_type = Seg.Type;
Phdr.p_flags = Seg.Flags;
Phdr.p_offset = Seg.Offset;
Phdr.p_vaddr = Seg.VAddr;
Phdr.p_paddr = Seg.PAddr;
Phdr.p_filesz = Seg.FileSize;
Phdr.p_memsz = Seg.MemSize;
Phdr.p_align = Seg.Align;
}
void SectionBase::removeSectionReferences(const SectionBase *Sec) {}
void SectionBase::removeSymbols(function_ref<bool(const Symbol &)> ToRemove) {}
void SectionBase::initialize(SectionTableRef SecTable) {}
void SectionBase::finalize() {}
void SectionBase::markSymbols() {}
template <class ELFT> void ELFWriter<ELFT>::writeShdr(const SectionBase &Sec) {
uint8_t *B = Buf.getBufferStart();
B += Sec.HeaderOffset;
typename ELFT::Shdr &Shdr = *reinterpret_cast<typename ELFT::Shdr *>(B);
Shdr.sh_name = Sec.NameIndex;
Shdr.sh_type = Sec.Type;
Shdr.sh_flags = Sec.Flags;
Shdr.sh_addr = Sec.Addr;
Shdr.sh_offset = Sec.Offset;
Shdr.sh_size = Sec.Size;
Shdr.sh_link = Sec.Link;
Shdr.sh_info = Sec.Info;
Shdr.sh_addralign = Sec.Align;
Shdr.sh_entsize = Sec.EntrySize;
}
SectionVisitor::~SectionVisitor() {}
void BinarySectionWriter::visit(const SectionIndexSection &Sec) {
error("Cannot write symbol section index table '" + Sec.Name + "' ");
}
void BinarySectionWriter::visit(const SymbolTableSection &Sec) {
error("Cannot write symbol table '" + Sec.Name + "' out to binary");
}
void BinarySectionWriter::visit(const RelocationSection &Sec) {
error("Cannot write relocation section '" + Sec.Name + "' out to binary");
}
void BinarySectionWriter::visit(const GnuDebugLinkSection &Sec) {
error("Cannot write '" + Sec.Name + "' out to binary");
}
void BinarySectionWriter::visit(const GroupSection &Sec) {
error("Cannot write '" + Sec.Name + "' out to binary");
}
void SectionWriter::visit(const Section &Sec) {
if (Sec.Type == SHT_NOBITS)
return;
uint8_t *Buf = Out.getBufferStart() + Sec.Offset;
std::copy(std::begin(Sec.Contents), std::end(Sec.Contents), Buf);
}
void Section::accept(SectionVisitor &Visitor) const { Visitor.visit(*this); }
void SectionWriter::visit(const OwnedDataSection &Sec) {
uint8_t *Buf = Out.getBufferStart() + Sec.Offset;
std::copy(std::begin(Sec.Data), std::end(Sec.Data), Buf);
}
void OwnedDataSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
void StringTableSection::addString(StringRef Name) {
StrTabBuilder.add(Name);
Size = StrTabBuilder.getSize();
}
uint32_t StringTableSection::findIndex(StringRef Name) const {
return StrTabBuilder.getOffset(Name);
}
void StringTableSection::finalize() { StrTabBuilder.finalize(); }
void SectionWriter::visit(const StringTableSection &Sec) {
Sec.StrTabBuilder.write(Out.getBufferStart() + Sec.Offset);
}
void StringTableSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
template <class ELFT>
void ELFSectionWriter<ELFT>::visit(const SectionIndexSection &Sec) {
uint8_t *Buf = Out.getBufferStart() + Sec.Offset;
auto *IndexesBuffer = reinterpret_cast<typename ELFT::Word *>(Buf);
std::copy(std::begin(Sec.Indexes), std::end(Sec.Indexes), IndexesBuffer);
}
void SectionIndexSection::initialize(SectionTableRef SecTable) {
Size = 0;
setSymTab(SecTable.getSectionOfType<SymbolTableSection>(
Link,
"Link field value " + Twine(Link) + " in section " + Name + " is invalid",
"Link field value " + Twine(Link) + " in section " + Name +
" is not a symbol table"));
Symbols->setShndxTable(this);
}
void SectionIndexSection::finalize() { Link = Symbols->Index; }
void SectionIndexSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
static bool isValidReservedSectionIndex(uint16_t Index, uint16_t Machine) {
switch (Index) {
case SHN_ABS:
case SHN_COMMON:
return true;
}
if (Machine == EM_HEXAGON) {
switch (Index) {
case SHN_HEXAGON_SCOMMON:
case SHN_HEXAGON_SCOMMON_2:
case SHN_HEXAGON_SCOMMON_4:
case SHN_HEXAGON_SCOMMON_8:
return true;
}
}
return false;
}
// Large indexes force us to clarify exactly what this function should do. This
// function should return the value that will appear in st_shndx when written
// out.
uint16_t Symbol::getShndx() const {
if (DefinedIn != nullptr) {
if (DefinedIn->Index >= SHN_LORESERVE)
return SHN_XINDEX;
return DefinedIn->Index;
}
switch (ShndxType) {
// This means that we don't have a defined section but we do need to
// output a legitimate section index.
case SYMBOL_SIMPLE_INDEX:
return SHN_UNDEF;
case SYMBOL_ABS:
case SYMBOL_COMMON:
case SYMBOL_HEXAGON_SCOMMON:
case SYMBOL_HEXAGON_SCOMMON_2:
case SYMBOL_HEXAGON_SCOMMON_4:
case SYMBOL_HEXAGON_SCOMMON_8:
case SYMBOL_XINDEX:
return static_cast<uint16_t>(ShndxType);
}
llvm_unreachable("Symbol with invalid ShndxType encountered");
}
void SymbolTableSection::assignIndices() {
uint32_t Index = 0;
for (auto &Sym : Symbols)
Sym->Index = Index++;
}
void SymbolTableSection::addSymbol(StringRef Name, uint8_t Bind, uint8_t Type,
SectionBase *DefinedIn, uint64_t Value,
uint8_t Visibility, uint16_t Shndx,
uint64_t Sz) {
Symbol Sym;
Sym.Name = Name;
Sym.Binding = Bind;
Sym.Type = Type;
Sym.DefinedIn = DefinedIn;
if (DefinedIn != nullptr)
DefinedIn->HasSymbol = true;
if (DefinedIn == nullptr) {
if (Shndx >= SHN_LORESERVE)
Sym.ShndxType = static_cast<SymbolShndxType>(Shndx);
else
Sym.ShndxType = SYMBOL_SIMPLE_INDEX;
}
Sym.Value = Value;
Sym.Visibility = Visibility;
Sym.Size = Sz;
Sym.Index = Symbols.size();
Symbols.emplace_back(llvm::make_unique<Symbol>(Sym));
Size += this->EntrySize;
}
void SymbolTableSection::removeSectionReferences(const SectionBase *Sec) {
if (SectionIndexTable == Sec)
SectionIndexTable = nullptr;
if (SymbolNames == Sec) {
error("String table " + SymbolNames->Name +
" cannot be removed because it is referenced by the symbol table " +
this->Name);
}
removeSymbols([Sec](const Symbol &Sym) { return Sym.DefinedIn == Sec; });
}
void SymbolTableSection::updateSymbols(function_ref<void(Symbol &)> Callable) {
std::for_each(std::begin(Symbols) + 1, std::end(Symbols),
[Callable](SymPtr &Sym) { Callable(*Sym); });
std::stable_partition(
std::begin(Symbols), std::end(Symbols),
[](const SymPtr &Sym) { return Sym->Binding == STB_LOCAL; });
assignIndices();
}
void SymbolTableSection::removeSymbols(
function_ref<bool(const Symbol &)> ToRemove) {
Symbols.erase(
std::remove_if(std::begin(Symbols) + 1, std::end(Symbols),
[ToRemove](const SymPtr &Sym) { return ToRemove(*Sym); }),
std::end(Symbols));
Size = Symbols.size() * EntrySize;
assignIndices();
}
void SymbolTableSection::initialize(SectionTableRef SecTable) {
Size = 0;
setStrTab(SecTable.getSectionOfType<StringTableSection>(
Link,
"Symbol table has link index of " + Twine(Link) +
" which is not a valid index",
"Symbol table has link index of " + Twine(Link) +
" which is not a string table"));
}
void SymbolTableSection::finalize() {
// Make sure SymbolNames is finalized before getting name indexes.
SymbolNames->finalize();
uint32_t MaxLocalIndex = 0;
for (auto &Sym : Symbols) {
Sym->NameIndex = SymbolNames->findIndex(Sym->Name);
if (Sym->Binding == STB_LOCAL)
MaxLocalIndex = std::max(MaxLocalIndex, Sym->Index);
}
// Now we need to set the Link and Info fields.
Link = SymbolNames->Index;
Info = MaxLocalIndex + 1;
}
void SymbolTableSection::prepareForLayout() {
// Add all potential section indexes before file layout so that the section
// index section has the approprite size.
if (SectionIndexTable != nullptr) {
for (const auto &Sym : Symbols) {
if (Sym->DefinedIn != nullptr && Sym->DefinedIn->Index >= SHN_LORESERVE)
SectionIndexTable->addIndex(Sym->DefinedIn->Index);
else
SectionIndexTable->addIndex(SHN_UNDEF);
}
}
// Add all of our strings to SymbolNames so that SymbolNames has the right
// size before layout is decided.
for (auto &Sym : Symbols)
SymbolNames->addString(Sym->Name);
}
const Symbol *SymbolTableSection::getSymbolByIndex(uint32_t Index) const {
if (Symbols.size() <= Index)
error("Invalid symbol index: " + Twine(Index));
return Symbols[Index].get();
}
Symbol *SymbolTableSection::getSymbolByIndex(uint32_t Index) {
return const_cast<Symbol *>(
static_cast<const SymbolTableSection *>(this)->getSymbolByIndex(Index));
}
template <class ELFT>
void ELFSectionWriter<ELFT>::visit(const SymbolTableSection &Sec) {
uint8_t *Buf = Out.getBufferStart();
Buf += Sec.Offset;
typename ELFT::Sym *Sym = reinterpret_cast<typename ELFT::Sym *>(Buf);
// Loop though symbols setting each entry of the symbol table.
for (auto &Symbol : Sec.Symbols) {
Sym->st_name = Symbol->NameIndex;
Sym->st_value = Symbol->Value;
Sym->st_size = Symbol->Size;
Sym->st_other = Symbol->Visibility;
Sym->setBinding(Symbol->Binding);
Sym->setType(Symbol->Type);
Sym->st_shndx = Symbol->getShndx();
++Sym;
}
}
void SymbolTableSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
template <class SymTabType>
void RelocSectionWithSymtabBase<SymTabType>::removeSectionReferences(
const SectionBase *Sec) {
if (Symbols == Sec) {
error("Symbol table " + Symbols->Name +
" cannot be removed because it is "
"referenced by the relocation "
"section " +
this->Name);
}
}
template <class SymTabType>
void RelocSectionWithSymtabBase<SymTabType>::initialize(
SectionTableRef SecTable) {
setSymTab(SecTable.getSectionOfType<SymTabType>(
Link,
"Link field value " + Twine(Link) + " in section " + Name + " is invalid",
"Link field value " + Twine(Link) + " in section " + Name +
" is not a symbol table"));
if (Info != SHN_UNDEF)
setSection(SecTable.getSection(Info, "Info field value " + Twine(Info) +
" in section " + Name +
" is invalid"));
else
setSection(nullptr);
}
template <class SymTabType>
void RelocSectionWithSymtabBase<SymTabType>::finalize() {
this->Link = Symbols->Index;
if (SecToApplyRel != nullptr)
this->Info = SecToApplyRel->Index;
}
template <class ELFT>
static void setAddend(Elf_Rel_Impl<ELFT, false> &Rel, uint64_t Addend) {}
template <class ELFT>
static void setAddend(Elf_Rel_Impl<ELFT, true> &Rela, uint64_t Addend) {
Rela.r_addend = Addend;
}
template <class RelRange, class T>
static void writeRel(const RelRange &Relocations, T *Buf) {
for (const auto &Reloc : Relocations) {
Buf->r_offset = Reloc.Offset;
setAddend(*Buf, Reloc.Addend);
Buf->setSymbolAndType(Reloc.RelocSymbol->Index, Reloc.Type, false);
++Buf;
}
}
template <class ELFT>
void ELFSectionWriter<ELFT>::visit(const RelocationSection &Sec) {
uint8_t *Buf = Out.getBufferStart() + Sec.Offset;
if (Sec.Type == SHT_REL)
writeRel(Sec.Relocations, reinterpret_cast<Elf_Rel *>(Buf));
else
writeRel(Sec.Relocations, reinterpret_cast<Elf_Rela *>(Buf));
}
void RelocationSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
void RelocationSection::removeSymbols(
function_ref<bool(const Symbol &)> ToRemove) {
for (const Relocation &Reloc : Relocations)
if (ToRemove(*Reloc.RelocSymbol))
error("not stripping symbol `" + Reloc.RelocSymbol->Name +
"' because it is named in a relocation");
}
void RelocationSection::markSymbols() {
for (const Relocation &Reloc : Relocations)
Reloc.RelocSymbol->Referenced = true;
}
void SectionWriter::visit(const DynamicRelocationSection &Sec) {
std::copy(std::begin(Sec.Contents), std::end(Sec.Contents),
Out.getBufferStart() + Sec.Offset);
}
void DynamicRelocationSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
void Section::removeSectionReferences(const SectionBase *Sec) {
if (LinkSection == Sec) {
error("Section " + LinkSection->Name +
" cannot be removed because it is "
"referenced by the section " +
this->Name);
}
}
void GroupSection::finalize() {
this->Info = Sym->Index;
this->Link = SymTab->Index;
}
void GroupSection::removeSymbols(function_ref<bool(const Symbol &)> ToRemove) {
if (ToRemove(*Sym)) {
error("Symbol " + Sym->Name +
" cannot be removed because it is "
"referenced by the section " +
this->Name + "[" + Twine(this->Index) + "]");
}
}
void GroupSection::markSymbols() {
if (Sym)
Sym->Referenced = true;
}
void Section::initialize(SectionTableRef SecTable) {
if (Link != ELF::SHN_UNDEF) {
LinkSection =
SecTable.getSection(Link, "Link field value " + Twine(Link) +
" in section " + Name + " is invalid");
if (LinkSection->Type == ELF::SHT_SYMTAB)
LinkSection = nullptr;
}
}
void Section::finalize() { this->Link = LinkSection ? LinkSection->Index : 0; }
void GnuDebugLinkSection::init(StringRef File, StringRef Data) {
FileName = sys::path::filename(File);
// The format for the .gnu_debuglink starts with the file name and is
// followed by a null terminator and then the CRC32 of the file. The CRC32
// should be 4 byte aligned. So we add the FileName size, a 1 for the null
// byte, and then finally push the size to alignment and add 4.
Size = alignTo(FileName.size() + 1, 4) + 4;
// The CRC32 will only be aligned if we align the whole section.
Align = 4;
Type = ELF::SHT_PROGBITS;
Name = ".gnu_debuglink";
// For sections not found in segments, OriginalOffset is only used to
// establish the order that sections should go in. By using the maximum
// possible offset we cause this section to wind up at the end.
OriginalOffset = std::numeric_limits<uint64_t>::max();
JamCRC crc;
crc.update(ArrayRef<char>(Data.data(), Data.size()));
// The CRC32 value needs to be complemented because the JamCRC dosn't
// finalize the CRC32 value. It also dosn't negate the initial CRC32 value
// but it starts by default at 0xFFFFFFFF which is the complement of zero.
CRC32 = ~crc.getCRC();
}
GnuDebugLinkSection::GnuDebugLinkSection(StringRef File) : FileName(File) {
// Read in the file to compute the CRC of it.
auto DebugOrErr = MemoryBuffer::getFile(File);
if (!DebugOrErr)
error("'" + File + "': " + DebugOrErr.getError().message());
auto Debug = std::move(*DebugOrErr);
init(File, Debug->getBuffer());
}
template <class ELFT>
void ELFSectionWriter<ELFT>::visit(const GnuDebugLinkSection &Sec) {
auto Buf = Out.getBufferStart() + Sec.Offset;
char *File = reinterpret_cast<char *>(Buf);
Elf_Word *CRC =
reinterpret_cast<Elf_Word *>(Buf + Sec.Size - sizeof(Elf_Word));
*CRC = Sec.CRC32;
std::copy(std::begin(Sec.FileName), std::end(Sec.FileName), File);
}
void GnuDebugLinkSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
template <class ELFT>
void ELFSectionWriter<ELFT>::visit(const GroupSection &Sec) {
ELF::Elf32_Word *Buf =
reinterpret_cast<ELF::Elf32_Word *>(Out.getBufferStart() + Sec.Offset);
*Buf++ = Sec.FlagWord;
for (const auto *S : Sec.GroupMembers)
support::endian::write32<ELFT::TargetEndianness>(Buf++, S->Index);
}
void GroupSection::accept(SectionVisitor &Visitor) const {
Visitor.visit(*this);
}
// Returns true IFF a section is wholly inside the range of a segment
static bool sectionWithinSegment(const SectionBase &Section,
const Segment &Segment) {
// If a section is empty it should be treated like it has a size of 1. This is
// to clarify the case when an empty section lies on a boundary between two
// segments and ensures that the section "belongs" to the second segment and
// not the first.
uint64_t SecSize = Section.Size ? Section.Size : 1;
return Segment.Offset <= Section.OriginalOffset &&
Segment.Offset + Segment.FileSize >= Section.OriginalOffset + SecSize;
}
// Returns true IFF a segment's original offset is inside of another segment's
// range.
static bool segmentOverlapsSegment(const Segment &Child,
const Segment &Parent) {
return Parent.OriginalOffset <= Child.OriginalOffset &&
Parent.OriginalOffset + Parent.FileSize > Child.OriginalOffset;
}
static bool compareSegmentsByOffset(const Segment *A, const Segment *B) {
// Any segment without a parent segment should come before a segment
// that has a parent segment.
if (A->OriginalOffset < B->OriginalOffset)
return true;
if (A->OriginalOffset > B->OriginalOffset)
return false;
return A->Index < B->Index;
}
static bool compareSegmentsByPAddr(const Segment *A, const Segment *B) {
if (A->PAddr < B->PAddr)
return true;
if (A->PAddr > B->PAddr)
return false;
return A->Index < B->Index;
}
template <class ELFT> void ELFBuilder<ELFT>::setParentSegment(Segment &Child) {
for (auto &Parent : Obj.segments()) {
// Every segment will overlap with itself but we don't want a segment to
// be it's own parent so we avoid that situation.
if (&Child != &Parent && segmentOverlapsSegment(Child, Parent)) {
// We want a canonical "most parental" segment but this requires
// inspecting the ParentSegment.
if (compareSegmentsByOffset(&Parent, &Child))
if (Child.ParentSegment == nullptr ||
compareSegmentsByOffset(&Parent, Child.ParentSegment)) {
Child.ParentSegment = &Parent;
}
}
}
}
template <class ELFT> void ELFBuilder<ELFT>::readProgramHeaders() {
uint32_t Index = 0;
for (const auto &Phdr : unwrapOrError(ElfFile.program_headers())) {
ArrayRef<uint8_t> Data{ElfFile.base() + Phdr.p_offset,
(size_t)Phdr.p_filesz};
Segment &Seg = Obj.addSegment(Data);
Seg.Type = Phdr.p_type;
Seg.Flags = Phdr.p_flags;
Seg.OriginalOffset = Phdr.p_offset;
Seg.Offset = Phdr.p_offset;
Seg.VAddr = Phdr.p_vaddr;
Seg.PAddr = Phdr.p_paddr;
Seg.FileSize = Phdr.p_filesz;
Seg.MemSize = Phdr.p_memsz;
Seg.Align = Phdr.p_align;
Seg.Index = Index++;
for (auto &Section : Obj.sections()) {
if (sectionWithinSegment(Section, Seg)) {
Seg.addSection(&Section);
if (!Section.ParentSegment ||
Section.ParentSegment->Offset > Seg.Offset) {
Section.ParentSegment = &Seg;
}
}
}
}
auto &ElfHdr = Obj.ElfHdrSegment;
// Creating multiple PT_PHDR segments technically is not valid, but PT_LOAD
// segments must not overlap, and other types fit even less.
ElfHdr.Type = PT_PHDR;
ElfHdr.Flags = 0;
ElfHdr.OriginalOffset = ElfHdr.Offset = 0;
ElfHdr.VAddr = 0;
ElfHdr.PAddr = 0;
ElfHdr.FileSize = ElfHdr.MemSize = sizeof(Elf_Ehdr);
ElfHdr.Align = 0;
ElfHdr.Index = Index++;
const auto &Ehdr = *ElfFile.getHeader();
auto &PrHdr = Obj.ProgramHdrSegment;
PrHdr.Type = PT_PHDR;
PrHdr.Flags = 0;
// The spec requires us to have p_vaddr % p_align == p_offset % p_align.
// Whereas this works automatically for ElfHdr, here OriginalOffset is
// always non-zero and to ensure the equation we assign the same value to
// VAddr as well.
PrHdr.OriginalOffset = PrHdr.Offset = PrHdr.VAddr = Ehdr.e_phoff;
PrHdr.PAddr = 0;
PrHdr.FileSize = PrHdr.MemSize = Ehdr.e_phentsize * Ehdr.e_phnum;
// The spec requires us to naturally align all the fields.
PrHdr.Align = sizeof(Elf_Addr);
PrHdr.Index = Index++;
// Now we do an O(n^2) loop through the segments in order to match up
// segments.
for (auto &Child : Obj.segments())
setParentSegment(Child);
setParentSegment(ElfHdr);
setParentSegment(PrHdr);
}
template <class ELFT>
void ELFBuilder<ELFT>::initGroupSection(GroupSection *GroupSec) {
auto SecTable = Obj.sections();
auto SymTab = SecTable.template getSectionOfType<SymbolTableSection>(
GroupSec->Link,
"Link field value " + Twine(GroupSec->Link) + " in section " +
GroupSec->Name + " is invalid",
"Link field value " + Twine(GroupSec->Link) + " in section " +
GroupSec->Name + " is not a symbol table");
auto Sym = SymTab->getSymbolByIndex(GroupSec->Info);
if (!Sym)
error("Info field value " + Twine(GroupSec->Info) + " in section " +
GroupSec->Name + " is not a valid symbol index");
GroupSec->setSymTab(SymTab);
GroupSec->setSymbol(Sym);
if (GroupSec->Contents.size() % sizeof(ELF::Elf32_Word) ||
GroupSec->Contents.empty())
error("The content of the section " + GroupSec->Name + " is malformed");
const ELF::Elf32_Word *Word =
reinterpret_cast<const ELF::Elf32_Word *>(GroupSec->Contents.data());
const ELF::Elf32_Word *End =
Word + GroupSec->Contents.size() / sizeof(ELF::Elf32_Word);
GroupSec->setFlagWord(*Word++);
for (; Word != End; ++Word) {
uint32_t Index = support::endian::read32<ELFT::TargetEndianness>(Word);
GroupSec->addMember(SecTable.getSection(
Index, "Group member index " + Twine(Index) + " in section " +
GroupSec->Name + " is invalid"));
}
}
template <class ELFT>
void ELFBuilder<ELFT>::initSymbolTable(SymbolTableSection *SymTab) {
const Elf_Shdr &Shdr = *unwrapOrError(ElfFile.getSection(SymTab->Index));
StringRef StrTabData = unwrapOrError(ElfFile.getStringTableForSymtab(Shdr));
ArrayRef<Elf_Word> ShndxData;
auto Symbols = unwrapOrError(ElfFile.symbols(&Shdr));
for (const auto &Sym : Symbols) {
SectionBase *DefSection = nullptr;
StringRef Name = unwrapOrError(Sym.getName(StrTabData));
if (Sym.st_shndx == SHN_XINDEX) {
if (SymTab->getShndxTable() == nullptr)
error("Symbol '" + Name +
"' has index SHN_XINDEX but no SHT_SYMTAB_SHNDX section exists.");
if (ShndxData.data() == nullptr) {
const Elf_Shdr &ShndxSec =
*unwrapOrError(ElfFile.getSection(SymTab->getShndxTable()->Index));
ShndxData = unwrapOrError(
ElfFile.template getSectionContentsAsArray<Elf_Word>(&ShndxSec));
if (ShndxData.size() != Symbols.size())
error("Symbol section index table does not have the same number of "
"entries as the symbol table.");
}
Elf_Word Index = ShndxData[&Sym - Symbols.begin()];
DefSection = Obj.sections().getSection(
Index,
"Symbol '" + Name + "' has invalid section index " + Twine(Index));
} else if (Sym.st_shndx >= SHN_LORESERVE) {
if (!isValidReservedSectionIndex(Sym.st_shndx, Obj.Machine)) {
error(
"Symbol '" + Name +
"' has unsupported value greater than or equal to SHN_LORESERVE: " +
Twine(Sym.st_shndx));
}
} else if (Sym.st_shndx != SHN_UNDEF) {
DefSection = Obj.sections().getSection(
Sym.st_shndx, "Symbol '" + Name +
"' is defined has invalid section index " +
Twine(Sym.st_shndx));
}
SymTab->addSymbol(Name, Sym.getBinding(), Sym.getType(), DefSection,
Sym.getValue(), Sym.st_other, Sym.st_shndx, Sym.st_size);
}
}
template <class ELFT>
static void getAddend(uint64_t &ToSet, const Elf_Rel_Impl<ELFT, false> &Rel) {}
template <class ELFT>
static void getAddend(uint64_t &ToSet, const Elf_Rel_Impl<ELFT, true> &Rela) {
ToSet = Rela.r_addend;
}
template <class T>
static void initRelocations(RelocationSection *Relocs,
SymbolTableSection *SymbolTable, T RelRange) {
for (const auto &Rel : RelRange) {
Relocation ToAdd;
ToAdd.Offset = Rel.r_offset;
getAddend(ToAdd.Addend, Rel);
ToAdd.Type = Rel.getType(false);
ToAdd.RelocSymbol = SymbolTable->getSymbolByIndex(Rel.getSymbol(false));
Relocs->addRelocation(ToAdd);
}
}
SectionBase *SectionTableRef::getSection(uint32_t Index, Twine ErrMsg) {
if (Index == SHN_UNDEF || Index > Sections.size())
error(ErrMsg);
return Sections[Index - 1].get();
}
template <class T>
T *SectionTableRef::getSectionOfType(uint32_t Index, Twine IndexErrMsg,
Twine TypeErrMsg) {
if (T *Sec = dyn_cast<T>(getSection(Index, IndexErrMsg)))
return Sec;
error(TypeErrMsg);
}
template <class ELFT>
SectionBase &ELFBuilder<ELFT>::makeSection(const Elf_Shdr &Shdr) {
ArrayRef<uint8_t> Data;
switch (Shdr.sh_type) {
case SHT_REL:
case SHT_RELA:
if (Shdr.sh_flags & SHF_ALLOC) {
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<DynamicRelocationSection>(Data);
}
return Obj.addSection<RelocationSection>();
case SHT_STRTAB:
// If a string table is allocated we don't want to mess with it. That would
// mean altering the memory image. There are no special link types or
// anything so we can just use a Section.
if (Shdr.sh_flags & SHF_ALLOC) {
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<Section>(Data);
}
return Obj.addSection<StringTableSection>();
case SHT_HASH:
case SHT_GNU_HASH:
// Hash tables should refer to SHT_DYNSYM which we're not going to change.
// Because of this we don't need to mess with the hash tables either.
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<Section>(Data);
case SHT_GROUP:
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<GroupSection>(Data);
case SHT_DYNSYM:
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<DynamicSymbolTableSection>(Data);
case SHT_DYNAMIC:
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<DynamicSection>(Data);
case SHT_SYMTAB: {
auto &SymTab = Obj.addSection<SymbolTableSection>();
Obj.SymbolTable = &SymTab;
return SymTab;
}
case SHT_SYMTAB_SHNDX: {
auto &ShndxSection = Obj.addSection<SectionIndexSection>();
Obj.SectionIndexTable = &ShndxSection;
return ShndxSection;
}
case SHT_NOBITS:
return Obj.addSection<Section>(Data);
default:
Data = unwrapOrError(ElfFile.getSectionContents(&Shdr));
return Obj.addSection<Section>(Data);
}
}
template <class ELFT> void ELFBuilder<ELFT>::readSectionHeaders() {
uint32_t Index = 0;
for (const auto &Shdr : unwrapOrError(ElfFile.sections())) {
if (Index == 0) {
++Index;
continue;
}
auto &Sec = makeSection(Shdr);
Sec.Name = unwrapOrError(ElfFile.getSectionName(&Shdr));
Sec.Type = Shdr.sh_type;
Sec.Flags = Shdr.sh_flags;
Sec.Addr = Shdr.sh_addr;
Sec.Offset = Shdr.sh_offset;
Sec.OriginalOffset = Shdr.sh_offset;
Sec.Size = Shdr.sh_size;
Sec.Link = Shdr.sh_link;
Sec.Info = Shdr.sh_info;
Sec.Align = Shdr.sh_addralign;
Sec.EntrySize = Shdr.sh_entsize;
Sec.Index = Index++;
}
// If a section index table exists we'll need to initialize it before we
// initialize the symbol table because the symbol table might need to
// reference it.
if (Obj.SectionIndexTable)
Obj.SectionIndexTable->initialize(Obj.sections());
// Now that all of the sections have been added we can fill out some extra
// details about symbol tables. We need the symbol table filled out before
// any relocations.
if (Obj.SymbolTable) {
Obj.SymbolTable->initialize(Obj.sections());
initSymbolTable(Obj.SymbolTable);
}
// Now that all sections and symbols have been added we can add
// relocations that reference symbols and set the link and info fields for
// relocation sections.
for (auto &Section : Obj.sections()) {
if (&Section == Obj.SymbolTable)
continue;
Section.initialize(Obj.sections());
if (auto RelSec = dyn_cast<RelocationSection>(&Section)) {
auto Shdr = unwrapOrError(ElfFile.sections()).begin() + RelSec->Index;
if (RelSec->Type == SHT_REL)
initRelocations(RelSec, Obj.SymbolTable,
unwrapOrError(ElfFile.rels(Shdr)));
else
initRelocations(RelSec, Obj.SymbolTable,
unwrapOrError(ElfFile.relas(Shdr)));
} else if (auto GroupSec = dyn_cast<GroupSection>(&Section)) {
initGroupSection(GroupSec);
}
}
}
template <class ELFT> void ELFBuilder<ELFT>::build() {
const auto &Ehdr = *ElfFile.getHeader();
std::copy(Ehdr.e_ident, Ehdr.e_ident + 16, Obj.Ident);
Obj.Type = Ehdr.e_type;
Obj.Machine = Ehdr.e_machine;
Obj.Version = Ehdr.e_version;
Obj.Entry = Ehdr.e_entry;
Obj.Flags = Ehdr.e_flags;
readSectionHeaders();
readProgramHeaders();
uint32_t ShstrIndex = Ehdr.e_shstrndx;
if (ShstrIndex == SHN_XINDEX)
ShstrIndex = unwrapOrError(ElfFile.getSection(0))->sh_link;
Obj.SectionNames =
Obj.sections().template getSectionOfType<StringTableSection>(
ShstrIndex,
"e_shstrndx field value " + Twine(Ehdr.e_shstrndx) +
" in elf header " + " is invalid",
"e_shstrndx field value " + Twine(Ehdr.e_shstrndx) +
" in elf header " + " is not a string table");
}
// A generic size function which computes sizes of any random access range.
template <class R> size_t size(R &&Range) {
return static_cast<size_t>(std::end(Range) - std::begin(Range));
}
Writer::~Writer() {}
Reader::~Reader() {}
ElfType ELFReader::getElfType() const {
if (isa<ELFObjectFile<ELF32LE>>(Bin))
return ELFT_ELF32LE;
if (isa<ELFObjectFile<ELF64LE>>(Bin))
return ELFT_ELF64LE;
if (isa<ELFObjectFile<ELF32BE>>(Bin))
return ELFT_ELF32BE;
if (isa<ELFObjectFile<ELF64BE>>(Bin))
return ELFT_ELF64BE;
llvm_unreachable("Invalid ELFType");
}
std::unique_ptr<Object> ELFReader::create() const {
auto Obj = llvm::make_unique<Object>();
if (auto *o = dyn_cast<ELFObjectFile<ELF32LE>>(Bin)) {
ELFBuilder<ELF32LE> Builder(*o, *Obj);
Builder.build();
return Obj;
} else if (auto *o = dyn_cast<ELFObjectFile<ELF64LE>>(Bin)) {
ELFBuilder<ELF64LE> Builder(*o, *Obj);
Builder.build();
return Obj;
} else if (auto *o = dyn_cast<ELFObjectFile<ELF32BE>>(Bin)) {
ELFBuilder<ELF32BE> Builder(*o, *Obj);
Builder.build();
return Obj;
} else if (auto *o = dyn_cast<ELFObjectFile<ELF64BE>>(Bin)) {
ELFBuilder<ELF64BE> Builder(*o, *Obj);
Builder.build();
return Obj;
}
error("Invalid file type");
}
template <class ELFT> void ELFWriter<ELFT>::writeEhdr() {
uint8_t *B = Buf.getBufferStart();
Elf_Ehdr &Ehdr = *reinterpret_cast<Elf_Ehdr *>(B);
std::copy(Obj.Ident, Obj.Ident + 16, Ehdr.e_ident);
Ehdr.e_type = Obj.Type;
Ehdr.e_machine = Obj.Machine;
Ehdr.e_version = Obj.Version;
Ehdr.e_entry = Obj.Entry;
Ehdr.e_phoff = Obj.ProgramHdrSegment.Offset;
Ehdr.e_flags = Obj.Flags;
Ehdr.e_ehsize = sizeof(Elf_Ehdr);
Ehdr.e_phentsize = sizeof(Elf_Phdr);
Ehdr.e_phnum = size(Obj.segments());
Ehdr.e_shentsize = sizeof(Elf_Shdr);
if (WriteSectionHeaders) {
Ehdr.e_shoff = Obj.SHOffset;
// """
// If the number of sections is greater than or equal to
// SHN_LORESERVE (0xff00), this member has the value zero and the actual
// number of section header table entries is contained in the sh_size field
// of the section header at index 0.
// """
auto Shnum = size(Obj.sections()) + 1;
if (Shnum >= SHN_LORESERVE)
Ehdr.e_shnum = 0;
else
Ehdr.e_shnum = Shnum;
// """
// If the section name string table section index is greater than or equal
// to SHN_LORESERVE (0xff00), this member has the value SHN_XINDEX (0xffff)
// and the actual index of the section name string table section is
// contained in the sh_link field of the section header at index 0.
// """
if (Obj.SectionNames->Index >= SHN_LORESERVE)
Ehdr.e_shstrndx = SHN_XINDEX;
else
Ehdr.e_shstrndx = Obj.SectionNames->Index;
} else {
Ehdr.e_shoff = 0;
Ehdr.e_shnum = 0;
Ehdr.e_shstrndx = 0;
}
}
template <class ELFT> void ELFWriter<ELFT>::writePhdrs() {
for (auto &Seg : Obj.segments())
writePhdr(Seg);
}
template <class ELFT> void ELFWriter<ELFT>::writeShdrs() {
uint8_t *B = Buf.getBufferStart() + Obj.SHOffset;
// This reference serves to write the dummy section header at the begining
// of the file. It is not used for anything else
Elf_Shdr &Shdr = *reinterpret_cast<Elf_Shdr *>(B);
Shdr.sh_name = 0;
Shdr.sh_type = SHT_NULL;
Shdr.sh_flags = 0;
Shdr.sh_addr = 0;
Shdr.sh_offset = 0;
// See writeEhdr for why we do this.
uint64_t Shnum = size(Obj.sections()) + 1;
if (Shnum >= SHN_LORESERVE)
Shdr.sh_size = Shnum;
else
Shdr.sh_size = 0;
// See writeEhdr for why we do this.
if (Obj.SectionNames != nullptr && Obj.SectionNames->Index >= SHN_LORESERVE)
Shdr.sh_link = Obj.SectionNames->Index;
else
Shdr.sh_link = 0;
Shdr.sh_info = 0;
Shdr.sh_addralign = 0;
Shdr.sh_entsize = 0;
for (auto &Sec : Obj.sections())
writeShdr(Sec);
}
template <class ELFT> void ELFWriter<ELFT>::writeSectionData() {
for (auto &Sec : Obj.sections())
Sec.accept(*SecWriter);
}
void Object::removeSections(std::function<bool(const SectionBase &)> ToRemove) {
auto Iter = std::stable_partition(
std::begin(Sections), std::end(Sections), [=](const SecPtr &Sec) {
if (ToRemove(*Sec))
return false;
if (auto RelSec = dyn_cast<RelocationSectionBase>(Sec.get())) {
if (auto ToRelSec = RelSec->getSection())
return !ToRemove(*ToRelSec);
}
return true;
});
if (SymbolTable != nullptr && ToRemove(*SymbolTable))
SymbolTable = nullptr;
if (SectionNames != nullptr && ToRemove(*SectionNames))
SectionNames = nullptr;
if (SectionIndexTable != nullptr && ToRemove(*SectionIndexTable))
SectionIndexTable = nullptr;
// Now make sure there are no remaining references to the sections that will
// be removed. Sometimes it is impossible to remove a reference so we emit
// an error here instead.
for (auto &RemoveSec : make_range(Iter, std::end(Sections))) {
for (auto &Segment : Segments)
Segment->removeSection(RemoveSec.get());
for (auto &KeepSec : make_range(std::begin(Sections), Iter))
KeepSec->removeSectionReferences(RemoveSec.get());
}
// Now finally get rid of them all togethor.
Sections.erase(Iter, std::end(Sections));
}
void Object::removeSymbols(function_ref<bool(const Symbol &)> ToRemove) {
if (!SymbolTable)
return;
for (const SecPtr &Sec : Sections)
Sec->removeSymbols(ToRemove);
}
void Object::sortSections() {
// Put all sections in offset order. Maintain the ordering as closely as
// possible while meeting that demand however.
auto CompareSections = [](const SecPtr &A, const SecPtr &B) {
return A->OriginalOffset < B->OriginalOffset;
};
std::stable_sort(std::begin(this->Sections), std::end(this->Sections),
CompareSections);
}
static uint64_t alignToAddr(uint64_t Offset, uint64_t Addr, uint64_t Align) {
// Calculate Diff such that (Offset + Diff) & -Align == Addr & -Align.
if (Align == 0)
Align = 1;
auto Diff =
static_cast<int64_t>(Addr % Align) - static_cast<int64_t>(Offset % Align);
// We only want to add to Offset, however, so if Diff < 0 we can add Align and
// (Offset + Diff) & -Align == Addr & -Align will still hold.
if (Diff < 0)
Diff += Align;
return Offset + Diff;
}
// Orders segments such that if x = y->ParentSegment then y comes before x.
static void OrderSegments(std::vector<Segment *> &Segments) {
std::stable_sort(std::begin(Segments), std::end(Segments),
compareSegmentsByOffset);
}
// This function finds a consistent layout for a list of segments starting from
// an Offset. It assumes that Segments have been sorted by OrderSegments and
// returns an Offset one past the end of the last segment.
static uint64_t LayoutSegments(std::vector<Segment *> &Segments,
uint64_t Offset) {
assert(std::is_sorted(std::begin(Segments), std::end(Segments),
compareSegmentsByOffset));
// The only way a segment should move is if a section was between two
// segments and that section was removed. If that section isn't in a segment
// then it's acceptable, but not ideal, to simply move it to after the
// segments. So we can simply layout segments one after the other accounting
// for alignment.
for (auto &Segment : Segments) {
// We assume that segments have been ordered by OriginalOffset and Index
// such that a parent segment will always come before a child segment in
// OrderedSegments. This means that the Offset of the ParentSegment should
// already be set and we can set our offset relative to it.
if (Segment->ParentSegment != nullptr) {
auto Parent = Segment->ParentSegment;
Segment->Offset =
Parent->Offset + Segment->OriginalOffset - Parent->OriginalOffset;
} else {
Offset = alignToAddr(Offset, Segment->VAddr, Segment->Align);
Segment->Offset = Offset;
}
Offset = std::max(Offset, Segment->Offset + Segment->FileSize);
}
return Offset;
}
// This function finds a consistent layout for a list of sections. It assumes
// that the ->ParentSegment of each section has already been laid out. The
// supplied starting Offset is used for the starting offset of any section that
// does not have a ParentSegment. It returns either the offset given if all
// sections had a ParentSegment or an offset one past the last section if there
// was a section that didn't have a ParentSegment.
template <class Range>
static uint64_t LayoutSections(Range Sections, uint64_t Offset) {
// Now the offset of every segment has been set we can assign the offsets
// of each section. For sections that are covered by a segment we should use
// the segment's original offset and the section's original offset to compute
// the offset from the start of the segment. Using the offset from the start
// of the segment we can assign a new offset to the section. For sections not
// covered by segments we can just bump Offset to the next valid location.
uint32_t Index = 1;
for (auto &Section : Sections) {
Section.Index = Index++;
if (Section.ParentSegment != nullptr) {
auto Segment = *Section.ParentSegment;
Section.Offset =
Segment.Offset + (Section.OriginalOffset - Segment.OriginalOffset);
} else {
Offset = alignTo(Offset, Section.Align == 0 ? 1 : Section.Align);
Section.Offset = Offset;
if (Section.Type != SHT_NOBITS)
Offset += Section.Size;
}
}
return Offset;
}
template <class ELFT> void ELFWriter<ELFT>::assignOffsets() {
// We need a temporary list of segments that has a special order to it
// so that we know that anytime ->ParentSegment is set that segment has
// already had its offset properly set.
std::vector<Segment *> OrderedSegments;
for (auto &Segment : Obj.segments())
OrderedSegments.push_back(&Segment);
OrderedSegments.push_back(&Obj.ElfHdrSegment);
OrderedSegments.push_back(&Obj.ProgramHdrSegment);
OrderSegments(OrderedSegments);
// Offset is used as the start offset of the first segment to be laid out.
// Since the ELF Header (ElfHdrSegment) must be at the start of the file,
// we start at offset 0.
uint64_t Offset = 0;
Offset = LayoutSegments(OrderedSegments, Offset);
Offset = LayoutSections(Obj.sections(), Offset);
// If we need to write the section header table out then we need to align the
// Offset so that SHOffset is valid.
if (WriteSectionHeaders)
Offset = alignTo(Offset, sizeof(typename ELFT::Addr));
Obj.SHOffset = Offset;
}
template <class ELFT> size_t ELFWriter<ELFT>::totalSize() const {
// We already have the section header offset so we can calculate the total
// size by just adding up the size of each section header.
auto NullSectionSize = WriteSectionHeaders ? sizeof(Elf_Shdr) : 0;
return Obj.SHOffset + size(Obj.sections()) * sizeof(Elf_Shdr) +
NullSectionSize;
}
template <class ELFT> void ELFWriter<ELFT>::write() {
writeEhdr();
writePhdrs();
writeSectionData();
if (WriteSectionHeaders)
writeShdrs();
if (auto E = Buf.commit())
reportError(Buf.getName(), errorToErrorCode(std::move(E)));
}
template <class ELFT> void ELFWriter<ELFT>::finalize() {
// It could happen that SectionNames has been removed and yet the user wants
// a section header table output. We need to throw an error if a user tries
// to do that.
if (Obj.SectionNames == nullptr && WriteSectionHeaders)
error("Cannot write section header table because section header string "
"table was removed.");
Obj.sortSections();
// We need to assign indexes before we perform layout because we need to know
// if we need large indexes or not. We can assign indexes first and check as
// we go to see if we will actully need large indexes.
bool NeedsLargeIndexes = false;
if (size(Obj.sections()) >= SHN_LORESERVE) {
auto Sections = Obj.sections();
NeedsLargeIndexes =
std::any_of(Sections.begin() + SHN_LORESERVE, Sections.end(),
[](const SectionBase &Sec) { return Sec.HasSymbol; });
// TODO: handle case where only one section needs the large index table but
// only needs it because the large index table hasn't been removed yet.
}
if (NeedsLargeIndexes) {
// This means we definitely need to have a section index table but if we
// already have one then we should use it instead of making a new one.
if (Obj.SymbolTable != nullptr && Obj.SectionIndexTable == nullptr) {
// Addition of a section to the end does not invalidate the indexes of
// other sections and assigns the correct index to the new section.
auto &Shndx = Obj.addSection<SectionIndexSection>();
Obj.SymbolTable->setShndxTable(&Shndx);
Shndx.setSymTab(Obj.SymbolTable);
}
} else {
// Since we don't need SectionIndexTable we should remove it and all
// references to it.
if (Obj.SectionIndexTable != nullptr) {
Obj.removeSections([this](const SectionBase &Sec) {
return &Sec == Obj.SectionIndexTable;
});
}
}
// Make sure we add the names of all the sections. Importantly this must be
// done after we decide to add or remove SectionIndexes.
if (Obj.SectionNames != nullptr)
for (const auto &Section : Obj.sections()) {
Obj.SectionNames->addString(Section.Name);
}
// Before we can prepare for layout the indexes need to be finalized.
uint64_t Index = 0;
for (auto &Sec : Obj.sections())
Sec.Index = Index++;
// The symbol table does not update all other sections on update. For
// instance, symbol names are not added as new symbols are added. This means
// that some sections, like .strtab, don't yet have their final size.
if (Obj.SymbolTable != nullptr)
Obj.SymbolTable->prepareForLayout();
assignOffsets();
// Finalize SectionNames first so that we can assign name indexes.
if (Obj.SectionNames != nullptr)
Obj.SectionNames->finalize();
// Finally now that all offsets and indexes have been set we can finalize any
// remaining issues.
uint64_t Offset = Obj.SHOffset + sizeof(Elf_Shdr);
for (auto &Section : Obj.sections()) {
Section.HeaderOffset = Offset;
Offset += sizeof(Elf_Shdr);
if (WriteSectionHeaders)
Section.NameIndex = Obj.SectionNames->findIndex(Section.Name);
Section.finalize();
}
Buf.allocate(totalSize());
SecWriter = llvm::make_unique<ELFSectionWriter<ELFT>>(Buf);
}
void BinaryWriter::write() {
for (auto &Section : Obj.sections()) {
if ((Section.Flags & SHF_ALLOC) == 0)
continue;
Section.accept(*SecWriter);
}
if (auto E = Buf.commit())
reportError(Buf.getName(), errorToErrorCode(std::move(E)));
}
void BinaryWriter::finalize() {
// TODO: Create a filter range to construct OrderedSegments from so that this
// code can be deduped with assignOffsets above. This should also solve the
// todo below for LayoutSections.
// We need a temporary list of segments that has a special order to it
// so that we know that anytime ->ParentSegment is set that segment has
// already had it's offset properly set. We only want to consider the segments
// that will affect layout of allocated sections so we only add those.
std::vector<Segment *> OrderedSegments;
for (auto &Section : Obj.sections()) {
if ((Section.Flags & SHF_ALLOC) != 0 && Section.ParentSegment != nullptr) {
OrderedSegments.push_back(Section.ParentSegment);
}
}
// For binary output, we're going to use physical addresses instead of
// virtual addresses, since a binary output is used for cases like ROM
// loading and physical addresses are intended for ROM loading.
// However, if no segment has a physical address, we'll fallback to using
// virtual addresses for all.
if (std::all_of(std::begin(OrderedSegments), std::end(OrderedSegments),
[](const Segment *Segment) { return Segment->PAddr == 0; }))
for (const auto &Segment : OrderedSegments)
Segment->PAddr = Segment->VAddr;
std::stable_sort(std::begin(OrderedSegments), std::end(OrderedSegments),
compareSegmentsByPAddr);
// Because we add a ParentSegment for each section we might have duplicate
// segments in OrderedSegments. If there were duplicates then LayoutSegments
// would do very strange things.
auto End =
std::unique(std::begin(OrderedSegments), std::end(OrderedSegments));
OrderedSegments.erase(End, std::end(OrderedSegments));
uint64_t Offset = 0;
// Modify the first segment so that there is no gap at the start. This allows
// our layout algorithm to proceed as expected while not out writing out the
// gap at the start.
if (!OrderedSegments.empty()) {
auto Seg = OrderedSegments[0];
auto Sec = Seg->firstSection();
auto Diff = Sec->OriginalOffset - Seg->OriginalOffset;
Seg->OriginalOffset += Diff;
// The size needs to be shrunk as well.
Seg->FileSize -= Diff;
// The PAddr needs to be increased to remove the gap before the first
// section.
Seg->PAddr += Diff;
uint64_t LowestPAddr = Seg->PAddr;
for (auto &Segment : OrderedSegments) {
Segment->Offset = Segment->PAddr - LowestPAddr;
Offset = std::max(Offset, Segment->Offset + Segment->FileSize);
}
}
// TODO: generalize LayoutSections to take a range. Pass a special range
// constructed from an iterator that skips values for which a predicate does
// not hold. Then pass such a range to LayoutSections instead of constructing
// AllocatedSections here.
std::vector<SectionBase *> AllocatedSections;
for (auto &Section : Obj.sections()) {
if ((Section.Flags & SHF_ALLOC) == 0)
continue;
AllocatedSections.push_back(&Section);
}
LayoutSections(make_pointee_range(AllocatedSections), Offset);
// Now that every section has been laid out we just need to compute the total
// file size. This might not be the same as the offset returned by
// LayoutSections, because we want to truncate the last segment to the end of
// its last section, to match GNU objcopy's behaviour.
TotalSize = 0;
for (const auto &Section : AllocatedSections) {
if (Section->Type != SHT_NOBITS)
TotalSize = std::max(TotalSize, Section->Offset + Section->Size);
}
Buf.allocate(TotalSize);
SecWriter = llvm::make_unique<BinarySectionWriter>(Buf);
}
namespace llvm {
namespace objcopy {
template class ELFBuilder<ELF64LE>;
template class ELFBuilder<ELF64BE>;
template class ELFBuilder<ELF32LE>;
template class ELFBuilder<ELF32BE>;
template class ELFWriter<ELF64LE>;
template class ELFWriter<ELF64BE>;
template class ELFWriter<ELF32LE>;
template class ELFWriter<ELF32BE>;
} // end namespace objcopy
} // end namespace llvm