llvm-project/lld/ELF/Relocations.cpp

1001 lines
40 KiB
C++

//===- Relocations.cpp ----------------------------------------------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file contains platform-independent functions to process relocations.
// I'll describe the overview of this file here.
//
// Simple relocations are easy to handle for the linker. For example,
// for R_X86_64_PC64 relocs, the linker just has to fix up locations
// with the relative offsets to the target symbols. It would just be
// reading records from relocation sections and applying them to output.
//
// But not all relocations are that easy to handle. For example, for
// R_386_GOTOFF relocs, the linker has to create new GOT entries for
// symbols if they don't exist, and fix up locations with GOT entry
// offsets from the beginning of GOT section. So there is more than
// fixing addresses in relocation processing.
//
// ELF defines a large number of complex relocations.
//
// The functions in this file analyze relocations and do whatever needs
// to be done. It includes, but not limited to, the following.
//
// - create GOT/PLT entries
// - create new relocations in .dynsym to let the dynamic linker resolve
// them at runtime (since ELF supports dynamic linking, not all
// relocations can be resolved at link-time)
// - create COPY relocs and reserve space in .bss
// - replace expensive relocs (in terms of runtime cost) with cheap ones
// - error out infeasible combinations such as PIC and non-relative relocs
//
// Note that the functions in this file don't actually apply relocations
// because it doesn't know about the output file nor the output file buffer.
// It instead stores Relocation objects to InputSection's Relocations
// vector to let it apply later in InputSection::writeTo.
//
//===----------------------------------------------------------------------===//
#include "Relocations.h"
#include "Config.h"
#include "Memory.h"
#include "OutputSections.h"
#include "Strings.h"
#include "SymbolTable.h"
#include "SyntheticSections.h"
#include "Target.h"
#include "Thunks.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
using namespace llvm;
using namespace llvm::ELF;
using namespace llvm::object;
using namespace llvm::support::endian;
namespace lld {
namespace elf {
static bool refersToGotEntry(RelExpr Expr) {
return isRelExprOneOf<R_GOT, R_GOT_OFF, R_MIPS_GOT_LOCAL_PAGE, R_MIPS_GOT_OFF,
R_MIPS_GOT_OFF32, R_MIPS_TLSGD, R_MIPS_TLSLD,
R_GOT_PAGE_PC, R_GOT_PC, R_GOT_FROM_END, R_TLSGD,
R_TLSGD_PC, R_TLSDESC, R_TLSDESC_PAGE>(Expr);
}
static bool isPreemptible(const SymbolBody &Body, uint32_t Type) {
// In case of MIPS GP-relative relocations always resolve to a definition
// in a regular input file, ignoring the one-definition rule. So we,
// for example, should not attempt to create a dynamic relocation even
// if the target symbol is preemptible. There are two two MIPS GP-relative
// relocations R_MIPS_GPREL16 and R_MIPS_GPREL32. But only R_MIPS_GPREL16
// can be against a preemptible symbol.
// To get MIPS relocation type we apply 0xff mask. In case of O32 ABI all
// relocation types occupy eight bit. In case of N64 ABI we extract first
// relocation from 3-in-1 packet because only the first relocation can
// be against a real symbol.
if (Config->EMachine == EM_MIPS && (Type & 0xff) == R_MIPS_GPREL16)
return false;
return Body.isPreemptible();
}
// This function is similar to the `handleTlsRelocation`. ARM and MIPS do not
// support any relaxations for TLS relocations so by factoring out ARM and MIPS
// handling in to the separate function we can simplify the code and do not
// pollute `handleTlsRelocation` by ARM and MIPS `ifs` statements.
template <class ELFT, class GOT>
static unsigned
handleNoRelaxTlsRelocation(GOT *Got, uint32_t Type, SymbolBody &Body,
InputSectionBase &C, typename ELFT::uint Offset,
int64_t Addend, RelExpr Expr) {
typedef typename ELFT::uint uintX_t;
auto addModuleReloc = [](SymbolBody &Body, GOT *Got, uintX_t Off, bool LD) {
// The Dynamic TLS Module Index Relocation can be statically resolved to 1
// if we know that we are linking an executable. For ARM we resolve the
// relocation when writing the Got. MIPS has a custom Got implementation
// that writes the Module index in directly.
if (!Body.isPreemptible() && !Config->pic() && Config->EMachine == EM_ARM)
Got->Relocations.push_back(
{R_ABS, Target->TlsModuleIndexRel, Off, 0, &Body});
else {
SymbolBody *Dest = LD ? nullptr : &Body;
In<ELFT>::RelaDyn->addReloc(
{Target->TlsModuleIndexRel, Got, Off, false, Dest, 0});
}
};
if (isRelExprOneOf<R_MIPS_TLSLD, R_TLSLD_PC>(Expr)) {
if (Got->addTlsIndex() && (Config->pic() || Config->EMachine == EM_ARM))
addModuleReloc(Body, Got, Got->getTlsIndexOff(), true);
C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
return 1;
}
if (Target->isTlsGlobalDynamicRel(Type)) {
if (Got->addDynTlsEntry(Body) &&
(Body.isPreemptible() || Config->EMachine == EM_ARM)) {
uintX_t Off = Got->getGlobalDynOffset(Body);
addModuleReloc(Body, Got, Off, false);
if (Body.isPreemptible())
In<ELFT>::RelaDyn->addReloc({Target->TlsOffsetRel, Got,
Off + (uintX_t)sizeof(uintX_t), false,
&Body, 0});
}
C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
return 1;
}
return 0;
}
// Returns the number of relocations processed.
template <class ELFT>
static unsigned
handleTlsRelocation(uint32_t Type, SymbolBody &Body, InputSectionBase &C,
typename ELFT::uint Offset, int64_t Addend, RelExpr Expr) {
if (!(C.Flags & SHF_ALLOC))
return 0;
if (!Body.isTls())
return 0;
typedef typename ELFT::uint uintX_t;
if (Config->EMachine == EM_ARM)
return handleNoRelaxTlsRelocation<ELFT>(In<ELFT>::Got, Type, Body, C,
Offset, Addend, Expr);
if (Config->EMachine == EM_MIPS)
return handleNoRelaxTlsRelocation<ELFT>(In<ELFT>::MipsGot, Type, Body, C,
Offset, Addend, Expr);
bool IsPreemptible = isPreemptible(Body, Type);
if (isRelExprOneOf<R_TLSDESC, R_TLSDESC_PAGE, R_TLSDESC_CALL>(Expr) &&
Config->Shared) {
if (In<ELFT>::Got->addDynTlsEntry(Body)) {
uintX_t Off = In<ELFT>::Got->getGlobalDynOffset(Body);
In<ELFT>::RelaDyn->addReloc({Target->TlsDescRel, In<ELFT>::Got, Off,
!IsPreemptible, &Body, 0});
}
if (Expr != R_TLSDESC_CALL)
C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
return 1;
}
if (isRelExprOneOf<R_TLSLD_PC, R_TLSLD>(Expr)) {
// Local-Dynamic relocs can be relaxed to Local-Exec.
if (!Config->Shared) {
C.Relocations.push_back(
{R_RELAX_TLS_LD_TO_LE, Type, Offset, Addend, &Body});
return 2;
}
if (In<ELFT>::Got->addTlsIndex())
In<ELFT>::RelaDyn->addReloc({Target->TlsModuleIndexRel, In<ELFT>::Got,
In<ELFT>::Got->getTlsIndexOff(), false,
nullptr, 0});
C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
return 1;
}
// Local-Dynamic relocs can be relaxed to Local-Exec.
if (Target->isTlsLocalDynamicRel(Type) && !Config->Shared) {
C.Relocations.push_back(
{R_RELAX_TLS_LD_TO_LE, Type, Offset, Addend, &Body});
return 1;
}
if (isRelExprOneOf<R_TLSDESC_PAGE, R_TLSDESC, R_TLSDESC_CALL>(Expr) ||
Target->isTlsGlobalDynamicRel(Type)) {
if (Config->Shared) {
if (In<ELFT>::Got->addDynTlsEntry(Body)) {
uintX_t Off = In<ELFT>::Got->getGlobalDynOffset(Body);
In<ELFT>::RelaDyn->addReloc(
{Target->TlsModuleIndexRel, In<ELFT>::Got, Off, false, &Body, 0});
// If the symbol is preemptible we need the dynamic linker to write
// the offset too.
uintX_t OffsetOff = Off + (uintX_t)sizeof(uintX_t);
if (IsPreemptible)
In<ELFT>::RelaDyn->addReloc({Target->TlsOffsetRel, In<ELFT>::Got,
OffsetOff, false, &Body, 0});
else
In<ELFT>::Got->Relocations.push_back(
{R_ABS, Target->TlsOffsetRel, OffsetOff, 0, &Body});
}
C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
return 1;
}
// Global-Dynamic relocs can be relaxed to Initial-Exec or Local-Exec
// depending on the symbol being locally defined or not.
if (IsPreemptible) {
C.Relocations.push_back(
{Target->adjustRelaxExpr(Type, nullptr, R_RELAX_TLS_GD_TO_IE), Type,
Offset, Addend, &Body});
if (!Body.isInGot()) {
In<ELFT>::Got->addEntry(Body);
In<ELFT>::RelaDyn->addReloc({Target->TlsGotRel, In<ELFT>::Got,
Body.getGotOffset<ELFT>(), false, &Body,
0});
}
return Target->TlsGdRelaxSkip;
}
C.Relocations.push_back(
{Target->adjustRelaxExpr(Type, nullptr, R_RELAX_TLS_GD_TO_LE), Type,
Offset, Addend, &Body});
return Target->TlsGdRelaxSkip;
}
// Initial-Exec relocs can be relaxed to Local-Exec if the symbol is locally
// defined.
if (Target->isTlsInitialExecRel(Type) && !Config->Shared && !IsPreemptible) {
C.Relocations.push_back(
{R_RELAX_TLS_IE_TO_LE, Type, Offset, Addend, &Body});
return 1;
}
return 0;
}
template <endianness E> static int16_t readSignedLo16(const uint8_t *Loc) {
return read32<E>(Loc) & 0xffff;
}
template <class RelTy>
static uint32_t getMipsPairType(const RelTy *Rel, const SymbolBody &Sym) {
switch (Rel->getType(Config->isMips64EL())) {
case R_MIPS_HI16:
return R_MIPS_LO16;
case R_MIPS_GOT16:
return Sym.isLocal() ? R_MIPS_LO16 : R_MIPS_NONE;
case R_MIPS_PCHI16:
return R_MIPS_PCLO16;
case R_MICROMIPS_HI16:
return R_MICROMIPS_LO16;
default:
return R_MIPS_NONE;
}
}
template <class ELFT, class RelTy>
static int32_t findMipsPairedAddend(const uint8_t *Buf, const uint8_t *BufLoc,
SymbolBody &Sym, const RelTy *Rel,
const RelTy *End) {
uint32_t SymIndex = Rel->getSymbol(Config->isMips64EL());
uint32_t Type = getMipsPairType(Rel, Sym);
// Some MIPS relocations use addend calculated from addend of the relocation
// itself and addend of paired relocation. ABI requires to compute such
// combined addend in case of REL relocation record format only.
// See p. 4-17 at ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
if (RelTy::IsRela || Type == R_MIPS_NONE)
return 0;
for (const RelTy *RI = Rel; RI != End; ++RI) {
if (RI->getType(Config->isMips64EL()) != Type)
continue;
if (RI->getSymbol(Config->isMips64EL()) != SymIndex)
continue;
const endianness E = ELFT::TargetEndianness;
return ((read32<E>(BufLoc) & 0xffff) << 16) +
readSignedLo16<E>(Buf + RI->r_offset);
}
warn("can't find matching " + toString(Type) + " relocation for " +
toString(Rel->getType(Config->isMips64EL())));
return 0;
}
// True if non-preemptable symbol always has the same value regardless of where
// the DSO is loaded.
template <class ELFT> static bool isAbsolute(const SymbolBody &Body) {
if (Body.isUndefined())
return !Body.isLocal() && Body.symbol()->isWeak();
if (const auto *DR = dyn_cast<DefinedRegular>(&Body))
return DR->Section == nullptr; // Absolute symbol.
return false;
}
template <class ELFT> static bool isAbsoluteValue(const SymbolBody &Body) {
return isAbsolute<ELFT>(Body) || Body.isTls();
}
static bool needsPlt(RelExpr Expr) {
return isRelExprOneOf<R_PLT_PC, R_PPC_PLT_OPD, R_PLT, R_PLT_PAGE_PC>(Expr);
}
// True if this expression is of the form Sym - X, where X is a position in the
// file (PC, or GOT for example).
static bool isRelExpr(RelExpr Expr) {
return isRelExprOneOf<R_PC, R_GOTREL, R_GOTREL_FROM_END, R_MIPS_GOTREL,
R_PAGE_PC, R_RELAX_GOT_PC>(Expr);
}
template <class ELFT>
static bool
isStaticLinkTimeConstant(RelExpr E, uint32_t Type, const SymbolBody &Body,
InputSectionBase &S, typename ELFT::uint RelOff) {
// These expressions always compute a constant
if (isRelExprOneOf<R_SIZE, R_GOT_FROM_END, R_GOT_OFF, R_MIPS_GOT_LOCAL_PAGE,
R_MIPS_GOT_OFF, R_MIPS_GOT_OFF32, R_MIPS_TLSGD,
R_GOT_PAGE_PC, R_GOT_PC, R_PLT_PC, R_TLSGD_PC, R_TLSGD,
R_PPC_PLT_OPD, R_TLSDESC_CALL, R_TLSDESC_PAGE, R_HINT>(E))
return true;
// These never do, except if the entire file is position dependent or if
// only the low bits are used.
if (E == R_GOT || E == R_PLT || E == R_TLSDESC)
return Target->usesOnlyLowPageBits(Type) || !Config->pic();
if (isPreemptible(Body, Type))
return false;
if (!Config->pic())
return true;
bool AbsVal = isAbsoluteValue<ELFT>(Body);
bool RelE = isRelExpr(E);
if (AbsVal && !RelE)
return true;
if (!AbsVal && RelE)
return true;
// Relative relocation to an absolute value. This is normally unrepresentable,
// but if the relocation refers to a weak undefined symbol, we allow it to
// resolve to the image base. This is a little strange, but it allows us to
// link function calls to such symbols. Normally such a call will be guarded
// with a comparison, which will load a zero from the GOT.
// Another special case is MIPS _gp_disp symbol which represents offset
// between start of a function and '_gp' value and defined as absolute just
// to simplify the code.
if (AbsVal && RelE) {
if (Body.isUndefined() && !Body.isLocal() && Body.symbol()->isWeak())
return true;
if (&Body == ElfSym::MipsGpDisp)
return true;
error(S.getLocation<ELFT>(RelOff) + ": relocation " + toString(Type) +
" cannot refer to absolute symbol '" + toString(Body) +
"' defined in " + toString(Body.File));
return true;
}
return Target->usesOnlyLowPageBits(Type);
}
static RelExpr toPlt(RelExpr Expr) {
if (Expr == R_PPC_OPD)
return R_PPC_PLT_OPD;
if (Expr == R_PC)
return R_PLT_PC;
if (Expr == R_PAGE_PC)
return R_PLT_PAGE_PC;
if (Expr == R_ABS)
return R_PLT;
return Expr;
}
static RelExpr fromPlt(RelExpr Expr) {
// We decided not to use a plt. Optimize a reference to the plt to a
// reference to the symbol itself.
if (Expr == R_PLT_PC)
return R_PC;
if (Expr == R_PPC_PLT_OPD)
return R_PPC_OPD;
if (Expr == R_PLT)
return R_ABS;
return Expr;
}
template <class ELFT> static bool isReadOnly(SharedSymbol *SS) {
typedef typename ELFT::Phdr Elf_Phdr;
uint64_t Value = SS->getValue<ELFT>();
// Determine if the symbol is read-only by scanning the DSO's program headers.
auto *File = cast<SharedFile<ELFT>>(SS->File);
for (const Elf_Phdr &Phdr : check(File->getObj().program_headers()))
if ((Phdr.p_type == ELF::PT_LOAD || Phdr.p_type == ELF::PT_GNU_RELRO) &&
!(Phdr.p_flags & ELF::PF_W) && Value >= Phdr.p_vaddr &&
Value < Phdr.p_vaddr + Phdr.p_memsz)
return true;
return false;
}
// Returns symbols at the same offset as a given symbol, including SS itself.
//
// If two or more symbols are at the same offset, and at least one of
// them are copied by a copy relocation, all of them need to be copied.
// Otherwise, they would refer different places at runtime.
template <class ELFT>
static std::vector<SharedSymbol *> getSymbolsAt(SharedSymbol *SS) {
typedef typename ELFT::Sym Elf_Sym;
auto *File = cast<SharedFile<ELFT>>(SS->File);
uint64_t Shndx = SS->getShndx<ELFT>();
uint64_t Value = SS->getValue<ELFT>();
std::vector<SharedSymbol *> Ret;
for (const Elf_Sym &S : File->getGlobalSymbols()) {
if (S.st_shndx != Shndx || S.st_value != Value)
continue;
StringRef Name = check(S.getName(File->getStringTable()));
SymbolBody *Sym = Symtab<ELFT>::X->find(Name);
if (auto *Alias = dyn_cast_or_null<SharedSymbol>(Sym))
Ret.push_back(Alias);
}
return Ret;
}
// Reserve space in .bss or .bss.rel.ro for copy relocation.
//
// The copy relocation is pretty much a hack. If you use a copy relocation
// in your program, not only the symbol name but the symbol's size, RW/RO
// bit and alignment become part of the ABI. In addition to that, if the
// symbol has aliases, the aliases become part of the ABI. That's subtle,
// but if you violate that implicit ABI, that can cause very counter-
// intuitive consequences.
//
// So, what is the copy relocation? It's for linking non-position
// independent code to DSOs. In an ideal world, all references to data
// exported by DSOs should go indirectly through GOT. But if object files
// are compiled as non-PIC, all data references are direct. There is no
// way for the linker to transform the code to use GOT, as machine
// instructions are already set in stone in object files. This is where
// the copy relocation takes a role.
//
// A copy relocation instructs the dynamic linker to copy data from a DSO
// to a specified address (which is usually in .bss) at load-time. If the
// static linker (that's us) finds a direct data reference to a DSO
// symbol, it creates a copy relocation, so that the symbol can be
// resolved as if it were in .bss rather than in a DSO.
//
// As you can see in this function, we create a copy relocation for the
// dynamic linker, and the relocation contains not only symbol name but
// various other informtion about the symbol. So, such attributes become a
// part of the ABI.
//
// Note for application developers: I can give you a piece of advice if
// you are writing a shared library. You probably should export only
// functions from your library. You shouldn't export variables.
//
// As an example what can happen when you export variables without knowing
// the semantics of copy relocations, assume that you have an exported
// variable of type T. It is an ABI-breaking change to add new members at
// end of T even though doing that doesn't change the layout of the
// existing members. That's because the space for the new members are not
// reserved in .bss unless you recompile the main program. That means they
// are likely to overlap with other data that happens to be laid out next
// to the variable in .bss. This kind of issue is sometimes very hard to
// debug. What's a solution? Instead of exporting a varaible V from a DSO,
// define an accessor getV().
template <class ELFT> static void addCopyRelSymbol(SharedSymbol *SS) {
typedef typename ELFT::uint uintX_t;
// Copy relocation against zero-sized symbol doesn't make sense.
uintX_t SymSize = SS->template getSize<ELFT>();
if (SymSize == 0)
fatal("cannot create a copy relocation for symbol " + toString(*SS));
// See if this symbol is in a read-only segment. If so, preserve the symbol's
// memory protection by reserving space in the .bss.rel.ro section.
bool IsReadOnly = isReadOnly<ELFT>(SS);
OutputSection *OSec = IsReadOnly ? Out::BssRelRo : Out::Bss;
// Create a SyntheticSection in Out to hold the .bss and the Copy Reloc.
auto *ISec =
make<CopyRelSection<ELFT>>(IsReadOnly, SS->getAlignment<ELFT>(), SymSize);
OSec->addSection(ISec);
// Look through the DSO's dynamic symbol table for aliases and create a
// dynamic symbol for each one. This causes the copy relocation to correctly
// interpose any aliases.
for (SharedSymbol *Sym : getSymbolsAt<ELFT>(SS)) {
Sym->NeedsCopy = true;
Sym->Section = ISec;
Sym->symbol()->IsUsedInRegularObj = true;
}
In<ELFT>::RelaDyn->addReloc({Target->CopyRel, ISec, 0, false, SS, 0});
}
template <class ELFT>
static RelExpr adjustExpr(const elf::ObjectFile<ELFT> &File, SymbolBody &Body,
bool IsWrite, RelExpr Expr, uint32_t Type,
const uint8_t *Data, InputSectionBase &S,
typename ELFT::uint RelOff) {
bool Preemptible = isPreemptible(Body, Type);
if (Body.isGnuIFunc()) {
Expr = toPlt(Expr);
} else if (!Preemptible) {
if (needsPlt(Expr))
Expr = fromPlt(Expr);
if (Expr == R_GOT_PC && !isAbsoluteValue<ELFT>(Body))
Expr = Target->adjustRelaxExpr(Type, Data, Expr);
}
if (IsWrite || isStaticLinkTimeConstant<ELFT>(Expr, Type, Body, S, RelOff))
return Expr;
// This relocation would require the dynamic linker to write a value to read
// only memory. We can hack around it if we are producing an executable and
// the refered symbol can be preemepted to refer to the executable.
if (Config->Shared || (Config->pic() && !isRelExpr(Expr))) {
error(S.getLocation<ELFT>(RelOff) + ": can't create dynamic relocation " +
toString(Type) + " against " +
(Body.getName().empty() ? "local symbol in readonly segment"
: "symbol '" + toString(Body) + "'") +
" defined in " + toString(Body.File));
return Expr;
}
if (Body.getVisibility() != STV_DEFAULT) {
error(S.getLocation<ELFT>(RelOff) + ": cannot preempt symbol '" +
toString(Body) + "' defined in " + toString(Body.File));
return Expr;
}
if (Body.isObject()) {
// Produce a copy relocation.
auto *B = cast<SharedSymbol>(&Body);
if (!B->NeedsCopy) {
if (Config->ZNocopyreloc)
error(S.getLocation<ELFT>(RelOff) + ": unresolvable relocation " +
toString(Type) + " against symbol '" + toString(*B) +
"'; recompile with -fPIC or remove '-z nocopyreloc'");
addCopyRelSymbol<ELFT>(B);
}
return Expr;
}
if (Body.isFunc()) {
// This handles a non PIC program call to function in a shared library. In
// an ideal world, we could just report an error saying the relocation can
// overflow at runtime. In the real world with glibc, crt1.o has a
// R_X86_64_PC32 pointing to libc.so.
//
// The general idea on how to handle such cases is to create a PLT entry and
// use that as the function value.
//
// For the static linking part, we just return a plt expr and everything
// else will use the the PLT entry as the address.
//
// The remaining problem is making sure pointer equality still works. We
// need the help of the dynamic linker for that. We let it know that we have
// a direct reference to a so symbol by creating an undefined symbol with a
// non zero st_value. Seeing that, the dynamic linker resolves the symbol to
// the value of the symbol we created. This is true even for got entries, so
// pointer equality is maintained. To avoid an infinite loop, the only entry
// that points to the real function is a dedicated got entry used by the
// plt. That is identified by special relocation types (R_X86_64_JUMP_SLOT,
// R_386_JMP_SLOT, etc).
Body.NeedsPltAddr = true;
return toPlt(Expr);
}
error("symbol '" + toString(Body) + "' defined in " + toString(Body.File) +
" is missing type");
return Expr;
}
template <class ELFT, class RelTy>
static int64_t computeAddend(const elf::ObjectFile<ELFT> &File,
const uint8_t *SectionData, const RelTy *End,
const RelTy &RI, RelExpr Expr, SymbolBody &Body) {
uint32_t Type = RI.getType(Config->isMips64EL());
int64_t Addend = getAddend<ELFT>(RI);
const uint8_t *BufLoc = SectionData + RI.r_offset;
if (!RelTy::IsRela)
Addend += Target->getImplicitAddend(BufLoc, Type);
if (Config->EMachine == EM_MIPS) {
Addend += findMipsPairedAddend<ELFT>(SectionData, BufLoc, Body, &RI, End);
if (Type == R_MIPS_LO16 && Expr == R_PC)
// R_MIPS_LO16 expression has R_PC type iif the target is _gp_disp
// symbol. In that case we should use the following formula for
// calculation "AHL + GP - P + 4". Let's add 4 right here.
// For details see p. 4-19 at
// ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
Addend += 4;
if (Expr == R_MIPS_GOTREL && Body.isLocal())
Addend += File.MipsGp0;
}
if (Config->pic() && Config->EMachine == EM_PPC64 && Type == R_PPC64_TOC)
Addend += getPPC64TocBase();
return Addend;
}
template <class ELFT>
static void reportUndefined(SymbolBody &Sym, InputSectionBase &S,
typename ELFT::uint Offset) {
bool CanBeExternal = Sym.symbol()->computeBinding() != STB_LOCAL &&
Sym.getVisibility() == STV_DEFAULT;
if (Config->UnresolvedSymbols == UnresolvedPolicy::IgnoreAll ||
(Config->UnresolvedSymbols == UnresolvedPolicy::Ignore && CanBeExternal))
return;
std::string Msg = S.getLocation<ELFT>(Offset) + ": undefined symbol '" +
toString(Sym) + "'";
if (Config->UnresolvedSymbols == UnresolvedPolicy::WarnAll ||
(Config->UnresolvedSymbols == UnresolvedPolicy::Warn && CanBeExternal))
warn(Msg);
else
error(Msg);
}
template <class RelTy>
static std::pair<uint32_t, uint32_t>
mergeMipsN32RelTypes(uint32_t Type, uint32_t Offset, RelTy *I, RelTy *E) {
// MIPS N32 ABI treats series of successive relocations with the same offset
// as a single relocation. The similar approach used by N64 ABI, but this ABI
// packs all relocations into the single relocation record. Here we emulate
// this for the N32 ABI. Iterate over relocation with the same offset and put
// theirs types into the single bit-set.
uint32_t Processed = 0;
for (; I != E && Offset == I->r_offset; ++I) {
++Processed;
Type |= I->getType(Config->isMips64EL()) << (8 * Processed);
}
return std::make_pair(Type, Processed);
}
// The reason we have to do this early scan is as follows
// * To mmap the output file, we need to know the size
// * For that, we need to know how many dynamic relocs we will have.
// It might be possible to avoid this by outputting the file with write:
// * Write the allocated output sections, computing addresses.
// * Apply relocations, recording which ones require a dynamic reloc.
// * Write the dynamic relocations.
// * Write the rest of the file.
// This would have some drawbacks. For example, we would only know if .rela.dyn
// is needed after applying relocations. If it is, it will go after rw and rx
// sections. Given that it is ro, we will need an extra PT_LOAD. This
// complicates things for the dynamic linker and means we would have to reserve
// space for the extra PT_LOAD even if we end up not using it.
template <class ELFT, class RelTy>
static void scanRelocs(InputSectionBase &C, ArrayRef<RelTy> Rels) {
typedef typename ELFT::uint uintX_t;
bool IsWrite = C.Flags & SHF_WRITE;
if (!Config->ZText)
IsWrite = true;
auto AddDyn = [=](const DynamicReloc<ELFT> &Reloc) {
In<ELFT>::RelaDyn->addReloc(Reloc);
};
const elf::ObjectFile<ELFT> *File = C.getFile<ELFT>();
ArrayRef<uint8_t> SectionData = C.Data;
const uint8_t *Buf = SectionData.begin();
ArrayRef<EhSectionPiece> Pieces;
if (auto *Eh = dyn_cast<EhInputSection>(&C))
Pieces = Eh->Pieces;
ArrayRef<EhSectionPiece>::iterator PieceI = Pieces.begin();
ArrayRef<EhSectionPiece>::iterator PieceE = Pieces.end();
for (auto I = Rels.begin(), E = Rels.end(); I != E; ++I) {
const RelTy &RI = *I;
SymbolBody &Body = File->getRelocTargetSym(RI);
uint32_t Type = RI.getType(Config->isMips64EL());
if (Config->MipsN32Abi) {
uint32_t Processed;
std::tie(Type, Processed) =
mergeMipsN32RelTypes(Type, RI.r_offset, I + 1, E);
I += Processed;
}
// We only report undefined symbols if they are referenced somewhere in the
// code.
if (!Body.isLocal() && Body.isUndefined() && !Body.symbol()->isWeak())
reportUndefined<ELFT>(Body, C, RI.r_offset);
RelExpr Expr = Target->getRelExpr(Type, Body);
// Ignore "hint" relocations because they are only markers for relaxation.
if (isRelExprOneOf<R_HINT, R_NONE>(Expr))
continue;
bool Preemptible = isPreemptible(Body, Type);
Expr = adjustExpr(*File, Body, IsWrite, Expr, Type, Buf + RI.r_offset, C,
RI.r_offset);
if (ErrorCount)
continue;
// Skip a relocation that points to a dead piece
// in a eh_frame section.
while (PieceI != PieceE &&
(PieceI->InputOff + PieceI->size() <= RI.r_offset))
++PieceI;
// Compute the offset of this section in the output section. We do it here
// to try to compute it only once.
uintX_t Offset;
if (PieceI != PieceE) {
assert(PieceI->InputOff <= RI.r_offset && "Relocation not in any piece");
if (PieceI->OutputOff == -1)
continue;
Offset = PieceI->OutputOff + RI.r_offset - PieceI->InputOff;
} else {
Offset = RI.r_offset;
}
// This relocation does not require got entry, but it is relative to got and
// needs it to be created. Here we request for that.
if (isRelExprOneOf<R_GOTONLY_PC, R_GOTONLY_PC_FROM_END, R_GOTREL,
R_GOTREL_FROM_END, R_PPC_TOC>(Expr))
In<ELFT>::Got->HasGotOffRel = true;
int64_t Addend = computeAddend(*File, Buf, E, RI, Expr, Body);
if (unsigned Processed =
handleTlsRelocation<ELFT>(Type, Body, C, Offset, Addend, Expr)) {
I += (Processed - 1);
continue;
}
if (Expr == R_TLSDESC_CALL)
continue;
if (needsPlt(Expr) ||
refersToGotEntry(Expr) || !isPreemptible(Body, Type)) {
// If the relocation points to something in the file, we can process it.
bool Constant =
isStaticLinkTimeConstant<ELFT>(Expr, Type, Body, C, RI.r_offset);
// If the output being produced is position independent, the final value
// is still not known. In that case we still need some help from the
// dynamic linker. We can however do better than just copying the incoming
// relocation. We can process some of it and and just ask the dynamic
// linker to add the load address.
if (!Constant)
AddDyn({Target->RelativeRel, &C, Offset, true, &Body, Addend});
// If the produced value is a constant, we just remember to write it
// when outputting this section. We also have to do it if the format
// uses Elf_Rel, since in that case the written value is the addend.
if (Constant || !RelTy::IsRela)
C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
} else {
// We don't know anything about the finaly symbol. Just ask the dynamic
// linker to handle the relocation for us.
if (!Target->isPicRel(Type))
error(C.getLocation<ELFT>(Offset) + ": relocation " + toString(Type) +
" cannot be used against shared object; recompile with -fPIC.");
AddDyn({Target->getDynRel(Type), &C, Offset, false, &Body, Addend});
// MIPS ABI turns using of GOT and dynamic relocations inside out.
// While regular ABI uses dynamic relocations to fill up GOT entries
// MIPS ABI requires dynamic linker to fills up GOT entries using
// specially sorted dynamic symbol table. This affects even dynamic
// relocations against symbols which do not require GOT entries
// creation explicitly, i.e. do not have any GOT-relocations. So if
// a preemptible symbol has a dynamic relocation we anyway have
// to create a GOT entry for it.
// If a non-preemptible symbol has a dynamic relocation against it,
// dynamic linker takes it st_value, adds offset and writes down
// result of the dynamic relocation. In case of preemptible symbol
// dynamic linker performs symbol resolution, writes the symbol value
// to the GOT entry and reads the GOT entry when it needs to perform
// a dynamic relocation.
// ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf p.4-19
if (Config->EMachine == EM_MIPS)
In<ELFT>::MipsGot->addEntry(Body, Addend, Expr);
continue;
}
// At this point we are done with the relocated position. Some relocations
// also require us to create a got or plt entry.
// If a relocation needs PLT, we create a PLT and a GOT slot for the symbol.
if (needsPlt(Expr)) {
if (Body.isInPlt())
continue;
if (Body.isGnuIFunc() && !Preemptible) {
In<ELFT>::Iplt->addEntry(Body);
In<ELFT>::IgotPlt->addEntry(Body);
In<ELFT>::RelaIplt->addReloc({Target->IRelativeRel, In<ELFT>::IgotPlt,
Body.getGotPltOffset<ELFT>(),
!Preemptible, &Body, 0});
} else {
In<ELFT>::Plt->addEntry(Body);
In<ELFT>::GotPlt->addEntry(Body);
In<ELFT>::RelaPlt->addReloc({Target->PltRel, In<ELFT>::GotPlt,
Body.getGotPltOffset<ELFT>(), !Preemptible,
&Body, 0});
}
continue;
}
if (refersToGotEntry(Expr)) {
if (Config->EMachine == EM_MIPS) {
// MIPS ABI has special rules to process GOT entries and doesn't
// require relocation entries for them. A special case is TLS
// relocations. In that case dynamic loader applies dynamic
// relocations to initialize TLS GOT entries.
// See "Global Offset Table" in Chapter 5 in the following document
// for detailed description:
// ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
In<ELFT>::MipsGot->addEntry(Body, Addend, Expr);
if (Body.isTls() && Body.isPreemptible())
AddDyn({Target->TlsGotRel, In<ELFT>::MipsGot,
Body.getGotOffset<ELFT>(), false, &Body, 0});
continue;
}
if (Body.isInGot())
continue;
In<ELFT>::Got->addEntry(Body);
uintX_t Off = Body.getGotOffset<ELFT>();
uint32_t DynType;
RelExpr GotRE = R_ABS;
if (Body.isTls()) {
DynType = Target->TlsGotRel;
GotRE = R_TLS;
} else if (!Preemptible && Config->pic() && !isAbsolute<ELFT>(Body))
DynType = Target->RelativeRel;
else
DynType = Target->GotRel;
// FIXME: this logic is almost duplicated above.
bool Constant =
!Preemptible && !(Config->pic() && !isAbsolute<ELFT>(Body));
if (!Constant)
AddDyn({DynType, In<ELFT>::Got, Off, !Preemptible, &Body, 0});
if (Constant || (!RelTy::IsRela && !Preemptible))
In<ELFT>::Got->Relocations.push_back({GotRE, DynType, Off, 0, &Body});
continue;
}
}
}
template <class ELFT> void scanRelocations(InputSectionBase &S) {
if (S.AreRelocsRela)
scanRelocs<ELFT>(S, S.relas<ELFT>());
else
scanRelocs<ELFT>(S, S.rels<ELFT>());
}
// Insert the Thunks for OutputSection OS into their designated place
// in the Sections vector, and recalculate the InputSection output section
// offsets.
// This may invalidate any output section offsets stored outside of InputSection
template <class ELFT>
static void mergeThunks(OutputSection *OS,
std::vector<ThunkSection *> &Thunks) {
// Order Thunks in ascending OutSecOff
auto ThunkCmp = [](const ThunkSection *A, const ThunkSection *B) {
return A->OutSecOff < B->OutSecOff;
};
std::stable_sort(Thunks.begin(), Thunks.end(), ThunkCmp);
// Merge sorted vectors of Thunks and InputSections by OutSecOff
std::vector<InputSection *> Tmp;
Tmp.reserve(OS->Sections.size() + Thunks.size());
auto MergeCmp = [](const InputSection *A, const InputSection *B) {
// std::merge requires a strict weak ordering.
if (A->OutSecOff < B->OutSecOff)
return true;
if (A->OutSecOff == B->OutSecOff)
// Check if Thunk is immediately before any specific Target InputSection
// for example Mips LA25 Thunks.
if (auto *TA = dyn_cast<ThunkSection>(A))
if (TA && TA->getTargetInputSection() == B)
return true;
return false;
};
std::merge(OS->Sections.begin(), OS->Sections.end(), Thunks.begin(),
Thunks.end(), std::back_inserter(Tmp), MergeCmp);
OS->Sections = std::move(Tmp);
OS->assignOffsets();
}
// Process all relocations from the InputSections that have been assigned
// to OutputSections and redirect through Thunks if needed.
//
// createThunks must be called after scanRelocs has created the Relocations for
// each InputSection. It must be called before the static symbol table is
// finalized. If any Thunks are added to an OutputSection the output section
// offsets of the InputSections will change.
//
// FIXME: All Thunks are assumed to be in range of the relocation. Range
// extension Thunks are not yet supported.
template <class ELFT>
bool createThunks(ArrayRef<OutputSection *> OutputSections) {
// Track Symbols that already have a Thunk
DenseMap<SymbolBody *, Thunk *> ThunkedSymbols;
// Track InputSections that have a ThunkSection placed in front
DenseMap<InputSection *, ThunkSection *> ThunkedSections;
// Track the ThunksSections that need to be inserted into an OutputSection
std::map<OutputSection *, std::vector<ThunkSection *>> ThunkSections;
// Find or create a Thunk for Body for relocation Type
auto GetThunk = [&](SymbolBody &Body, uint32_t Type) {
auto res = ThunkedSymbols.insert({&Body, nullptr});
if (res.second == true)
res.first->second = addThunk<ELFT>(Type, Body);
return std::make_pair(res.first->second, res.second);
};
// Find or create a ThunkSection to be placed immediately before IS
auto GetISThunkSec = [&](InputSection *IS, OutputSection *OS) {
ThunkSection *TS = ThunkedSections.lookup(IS);
if (TS)
return TS;
auto *TOS = cast<OutputSection>(IS->OutSec);
TS = make<ThunkSection>(TOS, IS->OutSecOff);
ThunkSections[TOS].push_back(TS);
ThunkedSections[IS] = TS;
return TS;
};
// Find or create a ThunkSection to be placed as last executable section in
// OS.
auto GetOSThunkSec = [&](ThunkSection *&TS, OutputSection *OS) {
if (TS == nullptr) {
uint32_t Off = 0;
for (auto *IS : OS->Sections) {
Off = IS->OutSecOff + IS->getSize();
if ((IS->Flags & SHF_EXECINSTR) == 0)
break;
}
TS = make<ThunkSection>(OS, Off);
ThunkSections[OS].push_back(TS);
}
return TS;
};
// Create all the Thunks and insert them into synthetic ThunkSections. The
// ThunkSections are later inserted back into the OutputSection.
// We separate the creation of ThunkSections from the insertion of the
// ThunkSections back into the OutputSection as ThunkSections are not always
// inserted into the same OutputSection as the caller.
for (OutputSection *Base : OutputSections) {
auto *OS = dyn_cast<OutputSection>(Base);
if (OS == nullptr)
continue;
ThunkSection *OSTS = nullptr;
for (InputSection *IS : OS->Sections) {
for (Relocation &Rel : IS->Relocations) {
SymbolBody &Body = *Rel.Sym;
if (Target->needsThunk(Rel.Expr, Rel.Type, IS->template getFile<ELFT>(),
Body)) {
Thunk *T;
bool IsNew;
std::tie(T, IsNew) = GetThunk(Body, Rel.Type);
if (IsNew) {
// Find or create a ThunkSection for the new Thunk
ThunkSection *TS;
if (auto *TIS = T->getTargetInputSection())
TS = GetISThunkSec(TIS, OS);
else
TS = GetOSThunkSec(OSTS, OS);
TS->addThunk(T);
}
// Redirect relocation to Thunk, we never go via the PLT to a Thunk
Rel.Sym = T->ThunkSym;
Rel.Expr = fromPlt(Rel.Expr);
}
}
}
}
// Merge all created synthetic ThunkSections back into OutputSection
for (auto &KV : ThunkSections)
mergeThunks<ELFT>(KV.first, KV.second);
return !ThunkSections.empty();
}
template void scanRelocations<ELF32LE>(InputSectionBase &);
template void scanRelocations<ELF32BE>(InputSectionBase &);
template void scanRelocations<ELF64LE>(InputSectionBase &);
template void scanRelocations<ELF64BE>(InputSectionBase &);
template bool createThunks<ELF32LE>(ArrayRef<OutputSection *>);
template bool createThunks<ELF32BE>(ArrayRef<OutputSection *>);
template bool createThunks<ELF64LE>(ArrayRef<OutputSection *>);
template bool createThunks<ELF64BE>(ArrayRef<OutputSection *>);
}
}