forked from OSchip/llvm-project
2044 lines
82 KiB
C++
2044 lines
82 KiB
C++
//===- Relocations.cpp ----------------------------------------------------===//
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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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//
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// This file contains platform-independent functions to process relocations.
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// I'll describe the overview of this file here.
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//
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// Simple relocations are easy to handle for the linker. For example,
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// for R_X86_64_PC64 relocs, the linker just has to fix up locations
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// with the relative offsets to the target symbols. It would just be
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// reading records from relocation sections and applying them to output.
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//
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// But not all relocations are that easy to handle. For example, for
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// R_386_GOTOFF relocs, the linker has to create new GOT entries for
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// symbols if they don't exist, and fix up locations with GOT entry
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// offsets from the beginning of GOT section. So there is more than
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// fixing addresses in relocation processing.
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//
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// ELF defines a large number of complex relocations.
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//
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// The functions in this file analyze relocations and do whatever needs
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// to be done. It includes, but not limited to, the following.
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//
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// - create GOT/PLT entries
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// - create new relocations in .dynsym to let the dynamic linker resolve
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// them at runtime (since ELF supports dynamic linking, not all
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// relocations can be resolved at link-time)
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// - create COPY relocs and reserve space in .bss
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// - replace expensive relocs (in terms of runtime cost) with cheap ones
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// - error out infeasible combinations such as PIC and non-relative relocs
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//
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// Note that the functions in this file don't actually apply relocations
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// because it doesn't know about the output file nor the output file buffer.
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// It instead stores Relocation objects to InputSection's Relocations
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// vector to let it apply later in InputSection::writeTo.
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//
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//===----------------------------------------------------------------------===//
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#include "Relocations.h"
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#include "Config.h"
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#include "LinkerScript.h"
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#include "OutputSections.h"
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#include "SymbolTable.h"
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#include "Symbols.h"
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#include "SyntheticSections.h"
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#include "Target.h"
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#include "Thunks.h"
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#include "lld/Common/ErrorHandler.h"
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#include "lld/Common/Memory.h"
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#include "lld/Common/Strings.h"
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#include "llvm/ADT/SmallSet.h"
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#include "llvm/Demangle/Demangle.h"
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#include "llvm/Support/Endian.h"
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#include "llvm/Support/raw_ostream.h"
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#include <algorithm>
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using namespace llvm;
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using namespace llvm::ELF;
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using namespace llvm::object;
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using namespace llvm::support::endian;
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namespace lld {
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namespace elf {
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static Optional<std::string> getLinkerScriptLocation(const Symbol &sym) {
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for (BaseCommand *base : script->sectionCommands)
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if (auto *cmd = dyn_cast<SymbolAssignment>(base))
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if (cmd->sym == &sym)
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return cmd->location;
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return None;
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}
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static std::string getDefinedLocation(const Symbol &sym) {
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std::string msg = "\n>>> defined in ";
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if (sym.file)
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msg += toString(sym.file);
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else if (Optional<std::string> loc = getLinkerScriptLocation(sym))
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msg += *loc;
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return msg;
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}
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// Construct a message in the following format.
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//
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// >>> defined in /home/alice/src/foo.o
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// >>> referenced by bar.c:12 (/home/alice/src/bar.c:12)
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// >>> /home/alice/src/bar.o:(.text+0x1)
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static std::string getLocation(InputSectionBase &s, const Symbol &sym,
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uint64_t off) {
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std::string msg = getDefinedLocation(sym) + "\n>>> referenced by ";
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std::string src = s.getSrcMsg(sym, off);
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if (!src.empty())
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msg += src + "\n>>> ";
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return msg + s.getObjMsg(off);
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}
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void reportRangeError(uint8_t *loc, const Relocation &rel, const Twine &v,
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int64_t min, uint64_t max) {
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ErrorPlace errPlace = getErrorPlace(loc);
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std::string hint;
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if (rel.sym && !rel.sym->isLocal())
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hint = "; references " + lld::toString(*rel.sym) +
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getDefinedLocation(*rel.sym);
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if (errPlace.isec && errPlace.isec->name.startswith(".debug"))
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hint += "; consider recompiling with -fdebug-types-section to reduce size "
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"of debug sections";
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errorOrWarn(errPlace.loc + "relocation " + lld::toString(rel.type) +
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" out of range: " + v.str() + " is not in [" + Twine(min).str() +
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", " + Twine(max).str() + "]" + hint);
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}
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namespace {
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// Build a bitmask with one bit set for each RelExpr.
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//
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// Constexpr function arguments can't be used in static asserts, so we
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// use template arguments to build the mask.
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// But function template partial specializations don't exist (needed
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// for base case of the recursion), so we need a dummy struct.
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template <RelExpr... Exprs> struct RelExprMaskBuilder {
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static inline uint64_t build() { return 0; }
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};
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// Specialization for recursive case.
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template <RelExpr Head, RelExpr... Tail>
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struct RelExprMaskBuilder<Head, Tail...> {
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static inline uint64_t build() {
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static_assert(0 <= Head && Head < 64,
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"RelExpr is too large for 64-bit mask!");
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return (uint64_t(1) << Head) | RelExprMaskBuilder<Tail...>::build();
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}
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};
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} // namespace
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// Return true if `Expr` is one of `Exprs`.
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// There are fewer than 64 RelExpr's, so we can represent any set of
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// RelExpr's as a constant bit mask and test for membership with a
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// couple cheap bitwise operations.
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template <RelExpr... Exprs> bool oneof(RelExpr expr) {
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assert(0 <= expr && (int)expr < 64 &&
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"RelExpr is too large for 64-bit mask!");
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return (uint64_t(1) << expr) & RelExprMaskBuilder<Exprs...>::build();
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}
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// This function is similar to the `handleTlsRelocation`. MIPS does not
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// support any relaxations for TLS relocations so by factoring out MIPS
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// handling in to the separate function we can simplify the code and do not
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// pollute other `handleTlsRelocation` by MIPS `ifs` statements.
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// Mips has a custom MipsGotSection that handles the writing of GOT entries
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// without dynamic relocations.
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static unsigned handleMipsTlsRelocation(RelType type, Symbol &sym,
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InputSectionBase &c, uint64_t offset,
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int64_t addend, RelExpr expr) {
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if (expr == R_MIPS_TLSLD) {
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in.mipsGot->addTlsIndex(*c.file);
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c.relocations.push_back({expr, type, offset, addend, &sym});
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return 1;
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}
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if (expr == R_MIPS_TLSGD) {
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in.mipsGot->addDynTlsEntry(*c.file, sym);
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c.relocations.push_back({expr, type, offset, addend, &sym});
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return 1;
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}
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return 0;
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}
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// Notes about General Dynamic and Local Dynamic TLS models below. They may
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// require the generation of a pair of GOT entries that have associated dynamic
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// relocations. The pair of GOT entries created are of the form GOT[e0] Module
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// Index (Used to find pointer to TLS block at run-time) GOT[e1] Offset of
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// symbol in TLS block.
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//
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// Returns the number of relocations processed.
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template <class ELFT>
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static unsigned
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handleTlsRelocation(RelType type, Symbol &sym, InputSectionBase &c,
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typename ELFT::uint offset, int64_t addend, RelExpr expr) {
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if (!sym.isTls())
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return 0;
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if (config->emachine == EM_MIPS)
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return handleMipsTlsRelocation(type, sym, c, offset, addend, expr);
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if (oneof<R_AARCH64_TLSDESC_PAGE, R_TLSDESC, R_TLSDESC_CALL, R_TLSDESC_PC>(
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expr) &&
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config->shared) {
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if (in.got->addDynTlsEntry(sym)) {
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uint64_t off = in.got->getGlobalDynOffset(sym);
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mainPart->relaDyn->addReloc(
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{target->tlsDescRel, in.got, off, !sym.isPreemptible, &sym, 0});
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}
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if (expr != R_TLSDESC_CALL)
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c.relocations.push_back({expr, type, offset, addend, &sym});
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return 1;
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}
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bool canRelax = config->emachine != EM_ARM &&
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config->emachine != EM_HEXAGON &&
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config->emachine != EM_RISCV;
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// If we are producing an executable and the symbol is non-preemptable, it
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// must be defined and the code sequence can be relaxed to use Local-Exec.
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//
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// ARM and RISC-V do not support any relaxations for TLS relocations, however,
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// we can omit the DTPMOD dynamic relocations and resolve them at link time
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// because them are always 1. This may be necessary for static linking as
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// DTPMOD may not be expected at load time.
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bool isLocalInExecutable = !sym.isPreemptible && !config->shared;
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// Local Dynamic is for access to module local TLS variables, while still
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// being suitable for being dynamically loaded via dlopen. GOT[e0] is the
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// module index, with a special value of 0 for the current module. GOT[e1] is
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// unused. There only needs to be one module index entry.
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if (oneof<R_TLSLD_GOT, R_TLSLD_GOTPLT, R_TLSLD_PC, R_TLSLD_HINT>(
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expr)) {
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// Local-Dynamic relocs can be relaxed to Local-Exec.
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if (canRelax && !config->shared) {
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c.relocations.push_back(
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{target->adjustRelaxExpr(type, nullptr, R_RELAX_TLS_LD_TO_LE), type,
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offset, addend, &sym});
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return target->getTlsGdRelaxSkip(type);
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}
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if (expr == R_TLSLD_HINT)
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return 1;
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if (in.got->addTlsIndex()) {
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if (isLocalInExecutable)
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in.got->relocations.push_back(
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{R_ADDEND, target->symbolicRel, in.got->getTlsIndexOff(), 1, &sym});
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else
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mainPart->relaDyn->addReloc(target->tlsModuleIndexRel, in.got,
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in.got->getTlsIndexOff(), nullptr);
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}
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c.relocations.push_back({expr, type, offset, addend, &sym});
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return 1;
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}
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// Local-Dynamic relocs can be relaxed to Local-Exec.
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if (expr == R_DTPREL && !config->shared) {
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c.relocations.push_back(
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{target->adjustRelaxExpr(type, nullptr, R_RELAX_TLS_LD_TO_LE), type,
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offset, addend, &sym});
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return 1;
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}
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// Local-Dynamic sequence where offset of tls variable relative to dynamic
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// thread pointer is stored in the got. This cannot be relaxed to Local-Exec.
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if (expr == R_TLSLD_GOT_OFF) {
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if (!sym.isInGot()) {
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in.got->addEntry(sym);
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uint64_t off = sym.getGotOffset();
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in.got->relocations.push_back(
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{R_ABS, target->tlsOffsetRel, off, 0, &sym});
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}
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c.relocations.push_back({expr, type, offset, addend, &sym});
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return 1;
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}
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if (oneof<R_AARCH64_TLSDESC_PAGE, R_TLSDESC, R_TLSDESC_CALL, R_TLSDESC_PC,
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R_TLSGD_GOT, R_TLSGD_GOTPLT, R_TLSGD_PC>(expr)) {
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if (!canRelax || config->shared) {
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if (in.got->addDynTlsEntry(sym)) {
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uint64_t off = in.got->getGlobalDynOffset(sym);
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if (isLocalInExecutable)
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// Write one to the GOT slot.
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in.got->relocations.push_back(
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{R_ADDEND, target->symbolicRel, off, 1, &sym});
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else
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mainPart->relaDyn->addReloc(target->tlsModuleIndexRel, in.got, off, &sym);
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// If the symbol is preemptible we need the dynamic linker to write
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// the offset too.
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uint64_t offsetOff = off + config->wordsize;
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if (sym.isPreemptible)
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mainPart->relaDyn->addReloc(target->tlsOffsetRel, in.got, offsetOff,
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&sym);
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else
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in.got->relocations.push_back(
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{R_ABS, target->tlsOffsetRel, offsetOff, 0, &sym});
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}
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c.relocations.push_back({expr, type, offset, addend, &sym});
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return 1;
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}
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// Global-Dynamic relocs can be relaxed to Initial-Exec or Local-Exec
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// depending on the symbol being locally defined or not.
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if (sym.isPreemptible) {
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c.relocations.push_back(
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{target->adjustRelaxExpr(type, nullptr, R_RELAX_TLS_GD_TO_IE), type,
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offset, addend, &sym});
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if (!sym.isInGot()) {
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in.got->addEntry(sym);
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mainPart->relaDyn->addReloc(target->tlsGotRel, in.got, sym.getGotOffset(),
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&sym);
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}
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} else {
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c.relocations.push_back(
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{target->adjustRelaxExpr(type, nullptr, R_RELAX_TLS_GD_TO_LE), type,
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offset, addend, &sym});
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}
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return target->getTlsGdRelaxSkip(type);
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}
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// Initial-Exec relocs can be relaxed to Local-Exec if the symbol is locally
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// defined.
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if (oneof<R_GOT, R_GOTPLT, R_GOT_PC, R_AARCH64_GOT_PAGE_PC, R_GOT_OFF,
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R_TLSIE_HINT>(expr) &&
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canRelax && isLocalInExecutable) {
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c.relocations.push_back({R_RELAX_TLS_IE_TO_LE, type, offset, addend, &sym});
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return 1;
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}
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if (expr == R_TLSIE_HINT)
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return 1;
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return 0;
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}
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static RelType getMipsPairType(RelType type, bool isLocal) {
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switch (type) {
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case R_MIPS_HI16:
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return R_MIPS_LO16;
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case R_MIPS_GOT16:
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// In case of global symbol, the R_MIPS_GOT16 relocation does not
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// have a pair. Each global symbol has a unique entry in the GOT
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// and a corresponding instruction with help of the R_MIPS_GOT16
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// relocation loads an address of the symbol. In case of local
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// symbol, the R_MIPS_GOT16 relocation creates a GOT entry to hold
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// the high 16 bits of the symbol's value. A paired R_MIPS_LO16
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// relocations handle low 16 bits of the address. That allows
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// to allocate only one GOT entry for every 64 KBytes of local data.
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return isLocal ? R_MIPS_LO16 : R_MIPS_NONE;
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case R_MICROMIPS_GOT16:
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return isLocal ? R_MICROMIPS_LO16 : R_MIPS_NONE;
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case R_MIPS_PCHI16:
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return R_MIPS_PCLO16;
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case R_MICROMIPS_HI16:
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return R_MICROMIPS_LO16;
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default:
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return R_MIPS_NONE;
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}
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}
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// True if non-preemptable symbol always has the same value regardless of where
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// the DSO is loaded.
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static bool isAbsolute(const Symbol &sym) {
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if (sym.isUndefWeak())
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return true;
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if (const auto *dr = dyn_cast<Defined>(&sym))
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return dr->section == nullptr; // Absolute symbol.
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return false;
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}
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static bool isAbsoluteValue(const Symbol &sym) {
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return isAbsolute(sym) || sym.isTls();
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}
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// Returns true if Expr refers a PLT entry.
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static bool needsPlt(RelExpr expr) {
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return oneof<R_PLT_PC, R_PPC32_PLTREL, R_PPC64_CALL_PLT, R_PLT>(expr);
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}
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// Returns true if Expr refers a GOT entry. Note that this function
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// returns false for TLS variables even though they need GOT, because
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// TLS variables uses GOT differently than the regular variables.
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static bool needsGot(RelExpr expr) {
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return oneof<R_GOT, R_GOT_OFF, R_MIPS_GOT_LOCAL_PAGE, R_MIPS_GOT_OFF,
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R_MIPS_GOT_OFF32, R_AARCH64_GOT_PAGE_PC, R_GOT_PC, R_GOTPLT>(
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expr);
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}
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// True if this expression is of the form Sym - X, where X is a position in the
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// file (PC, or GOT for example).
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static bool isRelExpr(RelExpr expr) {
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return oneof<R_PC, R_GOTREL, R_GOTPLTREL, R_MIPS_GOTREL, R_PPC64_CALL,
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R_PPC64_RELAX_TOC, R_AARCH64_PAGE_PC, R_RELAX_GOT_PC,
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R_RISCV_PC_INDIRECT>(expr);
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}
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// Returns true if a given relocation can be computed at link-time.
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//
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// For instance, we know the offset from a relocation to its target at
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// link-time if the relocation is PC-relative and refers a
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// non-interposable function in the same executable. This function
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// will return true for such relocation.
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//
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// If this function returns false, that means we need to emit a
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// dynamic relocation so that the relocation will be fixed at load-time.
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static bool isStaticLinkTimeConstant(RelExpr e, RelType type, const Symbol &sym,
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InputSectionBase &s, uint64_t relOff) {
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// These expressions always compute a constant
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if (oneof<R_DTPREL, R_GOTPLT, R_GOT_OFF, R_TLSLD_GOT_OFF,
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R_MIPS_GOT_LOCAL_PAGE, R_MIPS_GOTREL, R_MIPS_GOT_OFF,
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R_MIPS_GOT_OFF32, R_MIPS_GOT_GP_PC, R_MIPS_TLSGD,
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R_AARCH64_GOT_PAGE_PC, R_GOT_PC, R_GOTONLY_PC, R_GOTPLTONLY_PC,
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R_PLT_PC, R_TLSGD_GOT, R_TLSGD_GOTPLT, R_TLSGD_PC, R_PPC32_PLTREL,
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R_PPC64_CALL_PLT, R_PPC64_RELAX_TOC, R_RISCV_ADD, R_TLSDESC_CALL,
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R_TLSDESC_PC, R_AARCH64_TLSDESC_PAGE, R_TLSLD_HINT, R_TLSIE_HINT>(
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e))
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return true;
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// These never do, except if the entire file is position dependent or if
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// only the low bits are used.
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if (e == R_GOT || e == R_PLT || e == R_TLSDESC)
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return target->usesOnlyLowPageBits(type) || !config->isPic;
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if (sym.isPreemptible)
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return false;
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if (!config->isPic)
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return true;
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// The size of a non preemptible symbol is a constant.
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if (e == R_SIZE)
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return true;
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// For the target and the relocation, we want to know if they are
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// absolute or relative.
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bool absVal = isAbsoluteValue(sym);
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bool relE = isRelExpr(e);
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if (absVal && !relE)
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return true;
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if (!absVal && relE)
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return true;
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if (!absVal && !relE)
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return target->usesOnlyLowPageBits(type);
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assert(absVal && relE);
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// Allow R_PLT_PC (optimized to R_PC here) to a hidden undefined weak symbol
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// in PIC mode. This is a little strange, but it allows us to link function
|
|
// calls to such symbols (e.g. glibc/stdlib/exit.c:__run_exit_handlers).
|
|
// Normally such a call will be guarded with a comparison, which will load a
|
|
// zero from the GOT.
|
|
if (sym.isUndefWeak())
|
|
return true;
|
|
|
|
// We set the final symbols values for linker script defined symbols later.
|
|
// They always can be computed as a link time constant.
|
|
if (sym.scriptDefined)
|
|
return true;
|
|
|
|
error("relocation " + toString(type) + " cannot refer to absolute symbol: " +
|
|
toString(sym) + getLocation(s, sym, relOff));
|
|
return true;
|
|
}
|
|
|
|
static RelExpr toPlt(RelExpr expr) {
|
|
switch (expr) {
|
|
case R_PPC64_CALL:
|
|
return R_PPC64_CALL_PLT;
|
|
case R_PC:
|
|
return R_PLT_PC;
|
|
case R_ABS:
|
|
return R_PLT;
|
|
default:
|
|
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.
|
|
switch (expr) {
|
|
case R_PLT_PC:
|
|
case R_PPC32_PLTREL:
|
|
return R_PC;
|
|
case R_PPC64_CALL_PLT:
|
|
return R_PPC64_CALL;
|
|
case R_PLT:
|
|
return R_ABS;
|
|
default:
|
|
return expr;
|
|
}
|
|
}
|
|
|
|
// Returns true if a given shared symbol is in a read-only segment in a DSO.
|
|
template <class ELFT> static bool isReadOnly(SharedSymbol &ss) {
|
|
using Elf_Phdr = typename ELFT::Phdr;
|
|
|
|
// Determine if the symbol is read-only by scanning the DSO's program headers.
|
|
const SharedFile &file = ss.getFile();
|
|
for (const Elf_Phdr &phdr :
|
|
check(file.template getObj<ELFT>().program_headers()))
|
|
if ((phdr.p_type == ELF::PT_LOAD || phdr.p_type == ELF::PT_GNU_RELRO) &&
|
|
!(phdr.p_flags & ELF::PF_W) && ss.value >= phdr.p_vaddr &&
|
|
ss.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 to different places at runtime.
|
|
template <class ELFT>
|
|
static SmallSet<SharedSymbol *, 4> getSymbolsAt(SharedSymbol &ss) {
|
|
using Elf_Sym = typename ELFT::Sym;
|
|
|
|
SharedFile &file = ss.getFile();
|
|
|
|
SmallSet<SharedSymbol *, 4> ret;
|
|
for (const Elf_Sym &s : file.template getGlobalELFSyms<ELFT>()) {
|
|
if (s.st_shndx == SHN_UNDEF || s.st_shndx == SHN_ABS ||
|
|
s.getType() == STT_TLS || s.st_value != ss.value)
|
|
continue;
|
|
StringRef name = check(s.getName(file.getStringTable()));
|
|
Symbol *sym = symtab->find(name);
|
|
if (auto *alias = dyn_cast_or_null<SharedSymbol>(sym))
|
|
ret.insert(alias);
|
|
}
|
|
return ret;
|
|
}
|
|
|
|
// When a symbol is copy relocated or we create a canonical plt entry, it is
|
|
// effectively a defined symbol. In the case of copy relocation the symbol is
|
|
// in .bss and in the case of a canonical plt entry it is in .plt. This function
|
|
// replaces the existing symbol with a Defined pointing to the appropriate
|
|
// location.
|
|
static void replaceWithDefined(Symbol &sym, SectionBase *sec, uint64_t value,
|
|
uint64_t size) {
|
|
Symbol old = sym;
|
|
|
|
sym.replace(Defined{sym.file, sym.getName(), sym.binding, sym.stOther,
|
|
sym.type, value, size, sec});
|
|
|
|
sym.pltIndex = old.pltIndex;
|
|
sym.gotIndex = old.gotIndex;
|
|
sym.verdefIndex = old.verdefIndex;
|
|
sym.exportDynamic = true;
|
|
sym.isUsedInRegularObj = true;
|
|
}
|
|
|
|
// 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 information 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 variable V from a DSO,
|
|
// define an accessor getV().
|
|
template <class ELFT> static void addCopyRelSymbol(SharedSymbol &ss) {
|
|
// Copy relocation against zero-sized symbol doesn't make sense.
|
|
uint64_t symSize = ss.getSize();
|
|
if (symSize == 0 || ss.alignment == 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 isRO = isReadOnly<ELFT>(ss);
|
|
BssSection *sec =
|
|
make<BssSection>(isRO ? ".bss.rel.ro" : ".bss", symSize, ss.alignment);
|
|
OutputSection *osec = (isRO ? in.bssRelRo : in.bss)->getParent();
|
|
|
|
// At this point, sectionBases has been migrated to sections. Append sec to
|
|
// sections.
|
|
if (osec->sectionCommands.empty() ||
|
|
!isa<InputSectionDescription>(osec->sectionCommands.back()))
|
|
osec->sectionCommands.push_back(make<InputSectionDescription>(""));
|
|
auto *isd = cast<InputSectionDescription>(osec->sectionCommands.back());
|
|
isd->sections.push_back(sec);
|
|
osec->commitSection(sec);
|
|
|
|
// 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))
|
|
replaceWithDefined(*sym, sec, 0, sym->size);
|
|
|
|
mainPart->relaDyn->addReloc(target->copyRel, sec, 0, &ss);
|
|
}
|
|
|
|
// MIPS has an odd notion of "paired" relocations to calculate addends.
|
|
// For example, if a relocation is of R_MIPS_HI16, there must be a
|
|
// R_MIPS_LO16 relocation after that, and an addend is calculated using
|
|
// the two relocations.
|
|
template <class ELFT, class RelTy>
|
|
static int64_t computeMipsAddend(const RelTy &rel, const RelTy *end,
|
|
InputSectionBase &sec, RelExpr expr,
|
|
bool isLocal) {
|
|
if (expr == R_MIPS_GOTREL && isLocal)
|
|
return sec.getFile<ELFT>()->mipsGp0;
|
|
|
|
// The ABI says that the paired relocation is used only for REL.
|
|
// See p. 4-17 at ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
|
|
if (RelTy::IsRela)
|
|
return 0;
|
|
|
|
RelType type = rel.getType(config->isMips64EL);
|
|
uint32_t pairTy = getMipsPairType(type, isLocal);
|
|
if (pairTy == R_MIPS_NONE)
|
|
return 0;
|
|
|
|
const uint8_t *buf = sec.data().data();
|
|
uint32_t symIndex = rel.getSymbol(config->isMips64EL);
|
|
|
|
// To make things worse, paired relocations might not be contiguous in
|
|
// the relocation table, so we need to do linear search. *sigh*
|
|
for (const RelTy *ri = &rel; ri != end; ++ri)
|
|
if (ri->getType(config->isMips64EL) == pairTy &&
|
|
ri->getSymbol(config->isMips64EL) == symIndex)
|
|
return target->getImplicitAddend(buf + ri->r_offset, pairTy);
|
|
|
|
warn("can't find matching " + toString(pairTy) + " relocation for " +
|
|
toString(type));
|
|
return 0;
|
|
}
|
|
|
|
// Returns an addend of a given relocation. If it is RELA, an addend
|
|
// is in a relocation itself. If it is REL, we need to read it from an
|
|
// input section.
|
|
template <class ELFT, class RelTy>
|
|
static int64_t computeAddend(const RelTy &rel, const RelTy *end,
|
|
InputSectionBase &sec, RelExpr expr,
|
|
bool isLocal) {
|
|
int64_t addend;
|
|
RelType type = rel.getType(config->isMips64EL);
|
|
|
|
if (RelTy::IsRela) {
|
|
addend = getAddend<ELFT>(rel);
|
|
} else {
|
|
const uint8_t *buf = sec.data().data();
|
|
addend = target->getImplicitAddend(buf + rel.r_offset, type);
|
|
}
|
|
|
|
if (config->emachine == EM_PPC64 && config->isPic && type == R_PPC64_TOC)
|
|
addend += getPPC64TocBase();
|
|
if (config->emachine == EM_MIPS)
|
|
addend += computeMipsAddend<ELFT>(rel, end, sec, expr, isLocal);
|
|
|
|
return addend;
|
|
}
|
|
|
|
// Custom error message if Sym is defined in a discarded section.
|
|
template <class ELFT>
|
|
static std::string maybeReportDiscarded(Undefined &sym) {
|
|
auto *file = dyn_cast_or_null<ObjFile<ELFT>>(sym.file);
|
|
if (!file || !sym.discardedSecIdx ||
|
|
file->getSections()[sym.discardedSecIdx] != &InputSection::discarded)
|
|
return "";
|
|
ArrayRef<Elf_Shdr_Impl<ELFT>> objSections =
|
|
CHECK(file->getObj().sections(), file);
|
|
|
|
std::string msg;
|
|
if (sym.type == ELF::STT_SECTION) {
|
|
msg = "relocation refers to a discarded section: ";
|
|
msg += CHECK(
|
|
file->getObj().getSectionName(&objSections[sym.discardedSecIdx]), file);
|
|
} else {
|
|
msg = "relocation refers to a symbol in a discarded section: " +
|
|
toString(sym);
|
|
}
|
|
msg += "\n>>> defined in " + toString(file);
|
|
|
|
Elf_Shdr_Impl<ELFT> elfSec = objSections[sym.discardedSecIdx - 1];
|
|
if (elfSec.sh_type != SHT_GROUP)
|
|
return msg;
|
|
|
|
// If the discarded section is a COMDAT.
|
|
StringRef signature = file->getShtGroupSignature(objSections, elfSec);
|
|
if (const InputFile *prevailing =
|
|
symtab->comdatGroups.lookup(CachedHashStringRef(signature)))
|
|
msg += "\n>>> section group signature: " + signature.str() +
|
|
"\n>>> prevailing definition is in " + toString(prevailing);
|
|
return msg;
|
|
}
|
|
|
|
// Undefined diagnostics are collected in a vector and emitted once all of
|
|
// them are known, so that some postprocessing on the list of undefined symbols
|
|
// can happen before lld emits diagnostics.
|
|
struct UndefinedDiag {
|
|
Symbol *sym;
|
|
struct Loc {
|
|
InputSectionBase *sec;
|
|
uint64_t offset;
|
|
};
|
|
std::vector<Loc> locs;
|
|
bool isWarning;
|
|
};
|
|
|
|
static std::vector<UndefinedDiag> undefs;
|
|
|
|
// Check whether the definition name def is a mangled function name that matches
|
|
// the reference name ref.
|
|
static bool canSuggestExternCForCXX(StringRef ref, StringRef def) {
|
|
llvm::ItaniumPartialDemangler d;
|
|
std::string name = def.str();
|
|
if (d.partialDemangle(name.c_str()))
|
|
return false;
|
|
char *buf = d.getFunctionName(nullptr, nullptr);
|
|
if (!buf)
|
|
return false;
|
|
bool ret = ref == buf;
|
|
free(buf);
|
|
return ret;
|
|
}
|
|
|
|
// Suggest an alternative spelling of an "undefined symbol" diagnostic. Returns
|
|
// the suggested symbol, which is either in the symbol table, or in the same
|
|
// file of sym.
|
|
template <class ELFT>
|
|
static const Symbol *getAlternativeSpelling(const Undefined &sym,
|
|
std::string &pre_hint,
|
|
std::string &post_hint) {
|
|
DenseMap<StringRef, const Symbol *> map;
|
|
if (auto *file = dyn_cast_or_null<ObjFile<ELFT>>(sym.file)) {
|
|
// If sym is a symbol defined in a discarded section, maybeReportDiscarded()
|
|
// will give an error. Don't suggest an alternative spelling.
|
|
if (file && sym.discardedSecIdx != 0 &&
|
|
file->getSections()[sym.discardedSecIdx] == &InputSection::discarded)
|
|
return nullptr;
|
|
|
|
// Build a map of local defined symbols.
|
|
for (const Symbol *s : sym.file->getSymbols())
|
|
if (s->isLocal() && s->isDefined())
|
|
map.try_emplace(s->getName(), s);
|
|
}
|
|
|
|
auto suggest = [&](StringRef newName) -> const Symbol * {
|
|
// If defined locally.
|
|
if (const Symbol *s = map.lookup(newName))
|
|
return s;
|
|
|
|
// If in the symbol table and not undefined.
|
|
if (const Symbol *s = symtab->find(newName))
|
|
if (!s->isUndefined())
|
|
return s;
|
|
|
|
return nullptr;
|
|
};
|
|
|
|
// This loop enumerates all strings of Levenshtein distance 1 as typo
|
|
// correction candidates and suggests the one that exists as a non-undefined
|
|
// symbol.
|
|
StringRef name = sym.getName();
|
|
for (size_t i = 0, e = name.size(); i != e + 1; ++i) {
|
|
// Insert a character before name[i].
|
|
std::string newName = (name.substr(0, i) + "0" + name.substr(i)).str();
|
|
for (char c = '0'; c <= 'z'; ++c) {
|
|
newName[i] = c;
|
|
if (const Symbol *s = suggest(newName))
|
|
return s;
|
|
}
|
|
if (i == e)
|
|
break;
|
|
|
|
// Substitute name[i].
|
|
newName = std::string(name);
|
|
for (char c = '0'; c <= 'z'; ++c) {
|
|
newName[i] = c;
|
|
if (const Symbol *s = suggest(newName))
|
|
return s;
|
|
}
|
|
|
|
// Transpose name[i] and name[i+1]. This is of edit distance 2 but it is
|
|
// common.
|
|
if (i + 1 < e) {
|
|
newName[i] = name[i + 1];
|
|
newName[i + 1] = name[i];
|
|
if (const Symbol *s = suggest(newName))
|
|
return s;
|
|
}
|
|
|
|
// Delete name[i].
|
|
newName = (name.substr(0, i) + name.substr(i + 1)).str();
|
|
if (const Symbol *s = suggest(newName))
|
|
return s;
|
|
}
|
|
|
|
// Case mismatch, e.g. Foo vs FOO.
|
|
for (auto &it : map)
|
|
if (name.equals_lower(it.first))
|
|
return it.second;
|
|
for (Symbol *sym : symtab->symbols())
|
|
if (!sym->isUndefined() && name.equals_lower(sym->getName()))
|
|
return sym;
|
|
|
|
// The reference may be a mangled name while the definition is not. Suggest a
|
|
// missing extern "C".
|
|
if (name.startswith("_Z")) {
|
|
std::string buf = name.str();
|
|
llvm::ItaniumPartialDemangler d;
|
|
if (!d.partialDemangle(buf.c_str()))
|
|
if (char *buf = d.getFunctionName(nullptr, nullptr)) {
|
|
const Symbol *s = suggest(buf);
|
|
free(buf);
|
|
if (s) {
|
|
pre_hint = ": extern \"C\" ";
|
|
return s;
|
|
}
|
|
}
|
|
} else {
|
|
const Symbol *s = nullptr;
|
|
for (auto &it : map)
|
|
if (canSuggestExternCForCXX(name, it.first)) {
|
|
s = it.second;
|
|
break;
|
|
}
|
|
if (!s)
|
|
for (Symbol *sym : symtab->symbols())
|
|
if (canSuggestExternCForCXX(name, sym->getName())) {
|
|
s = sym;
|
|
break;
|
|
}
|
|
if (s) {
|
|
pre_hint = " to declare ";
|
|
post_hint = " as extern \"C\"?";
|
|
return s;
|
|
}
|
|
}
|
|
|
|
return nullptr;
|
|
}
|
|
|
|
template <class ELFT>
|
|
static void reportUndefinedSymbol(const UndefinedDiag &undef,
|
|
bool correctSpelling) {
|
|
Symbol &sym = *undef.sym;
|
|
|
|
auto visibility = [&]() -> std::string {
|
|
switch (sym.visibility) {
|
|
case STV_INTERNAL:
|
|
return "internal ";
|
|
case STV_HIDDEN:
|
|
return "hidden ";
|
|
case STV_PROTECTED:
|
|
return "protected ";
|
|
default:
|
|
return "";
|
|
}
|
|
};
|
|
|
|
std::string msg = maybeReportDiscarded<ELFT>(cast<Undefined>(sym));
|
|
if (msg.empty())
|
|
msg = "undefined " + visibility() + "symbol: " + toString(sym);
|
|
|
|
const size_t maxUndefReferences = 3;
|
|
size_t i = 0;
|
|
for (UndefinedDiag::Loc l : undef.locs) {
|
|
if (i >= maxUndefReferences)
|
|
break;
|
|
InputSectionBase &sec = *l.sec;
|
|
uint64_t offset = l.offset;
|
|
|
|
msg += "\n>>> referenced by ";
|
|
std::string src = sec.getSrcMsg(sym, offset);
|
|
if (!src.empty())
|
|
msg += src + "\n>>> ";
|
|
msg += sec.getObjMsg(offset);
|
|
i++;
|
|
}
|
|
|
|
if (i < undef.locs.size())
|
|
msg += ("\n>>> referenced " + Twine(undef.locs.size() - i) + " more times")
|
|
.str();
|
|
|
|
if (correctSpelling) {
|
|
std::string pre_hint = ": ", post_hint;
|
|
if (const Symbol *corrected = getAlternativeSpelling<ELFT>(
|
|
cast<Undefined>(sym), pre_hint, post_hint)) {
|
|
msg += "\n>>> did you mean" + pre_hint + toString(*corrected) + post_hint;
|
|
if (corrected->file)
|
|
msg += "\n>>> defined in: " + toString(corrected->file);
|
|
}
|
|
}
|
|
|
|
if (sym.getName().startswith("_ZTV"))
|
|
msg +=
|
|
"\n>>> the vtable symbol may be undefined because the class is missing "
|
|
"its key function (see https://lld.llvm.org/missingkeyfunction)";
|
|
|
|
if (undef.isWarning)
|
|
warn(msg);
|
|
else
|
|
error(msg);
|
|
}
|
|
|
|
template <class ELFT> void reportUndefinedSymbols() {
|
|
// Find the first "undefined symbol" diagnostic for each diagnostic, and
|
|
// collect all "referenced from" lines at the first diagnostic.
|
|
DenseMap<Symbol *, UndefinedDiag *> firstRef;
|
|
for (UndefinedDiag &undef : undefs) {
|
|
assert(undef.locs.size() == 1);
|
|
if (UndefinedDiag *canon = firstRef.lookup(undef.sym)) {
|
|
canon->locs.push_back(undef.locs[0]);
|
|
undef.locs.clear();
|
|
} else
|
|
firstRef[undef.sym] = &undef;
|
|
}
|
|
|
|
// Enable spell corrector for the first 2 diagnostics.
|
|
for (auto it : enumerate(undefs))
|
|
if (!it.value().locs.empty())
|
|
reportUndefinedSymbol<ELFT>(it.value(), it.index() < 2);
|
|
undefs.clear();
|
|
}
|
|
|
|
// Report an undefined symbol if necessary.
|
|
// Returns true if the undefined symbol will produce an error message.
|
|
static bool maybeReportUndefined(Symbol &sym, InputSectionBase &sec,
|
|
uint64_t offset) {
|
|
if (!sym.isUndefined() || sym.isWeak())
|
|
return false;
|
|
|
|
bool canBeExternal = !sym.isLocal() && sym.visibility == STV_DEFAULT;
|
|
if (config->unresolvedSymbols == UnresolvedPolicy::Ignore && canBeExternal)
|
|
return false;
|
|
|
|
// clang (as of 2019-06-12) / gcc (as of 8.2.1) PPC64 may emit a .rela.toc
|
|
// which references a switch table in a discarded .rodata/.text section. The
|
|
// .toc and the .rela.toc are incorrectly not placed in the comdat. The ELF
|
|
// spec says references from outside the group to a STB_LOCAL symbol are not
|
|
// allowed. Work around the bug.
|
|
//
|
|
// PPC32 .got2 is similar but cannot be fixed. Multiple .got2 is infeasible
|
|
// because .LC0-.LTOC is not representable if the two labels are in different
|
|
// .got2
|
|
if (cast<Undefined>(sym).discardedSecIdx != 0 &&
|
|
(sec.name == ".got2" || sec.name == ".toc"))
|
|
return false;
|
|
|
|
bool isWarning =
|
|
(config->unresolvedSymbols == UnresolvedPolicy::Warn && canBeExternal) ||
|
|
config->noinhibitExec;
|
|
undefs.push_back({&sym, {{&sec, offset}}, isWarning});
|
|
return !isWarning;
|
|
}
|
|
|
|
// 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.
|
|
template <class RelTy> static RelType getMipsN32RelType(RelTy *&rel, RelTy *end) {
|
|
RelType type = 0;
|
|
uint64_t offset = rel->r_offset;
|
|
|
|
int n = 0;
|
|
while (rel != end && rel->r_offset == offset)
|
|
type |= (rel++)->getType(config->isMips64EL) << (8 * n++);
|
|
return type;
|
|
}
|
|
|
|
// .eh_frame sections are mergeable input sections, so their input
|
|
// offsets are not linearly mapped to output section. For each input
|
|
// offset, we need to find a section piece containing the offset and
|
|
// add the piece's base address to the input offset to compute the
|
|
// output offset. That isn't cheap.
|
|
//
|
|
// This class is to speed up the offset computation. When we process
|
|
// relocations, we access offsets in the monotonically increasing
|
|
// order. So we can optimize for that access pattern.
|
|
//
|
|
// For sections other than .eh_frame, this class doesn't do anything.
|
|
namespace {
|
|
class OffsetGetter {
|
|
public:
|
|
explicit OffsetGetter(InputSectionBase &sec) {
|
|
if (auto *eh = dyn_cast<EhInputSection>(&sec))
|
|
pieces = eh->pieces;
|
|
}
|
|
|
|
// Translates offsets in input sections to offsets in output sections.
|
|
// Given offset must increase monotonically. We assume that Piece is
|
|
// sorted by inputOff.
|
|
uint64_t get(uint64_t off) {
|
|
if (pieces.empty())
|
|
return off;
|
|
|
|
while (i != pieces.size() && pieces[i].inputOff + pieces[i].size <= off)
|
|
++i;
|
|
if (i == pieces.size())
|
|
fatal(".eh_frame: relocation is not in any piece");
|
|
|
|
// Pieces must be contiguous, so there must be no holes in between.
|
|
assert(pieces[i].inputOff <= off && "Relocation not in any piece");
|
|
|
|
// Offset -1 means that the piece is dead (i.e. garbage collected).
|
|
if (pieces[i].outputOff == -1)
|
|
return -1;
|
|
return pieces[i].outputOff + off - pieces[i].inputOff;
|
|
}
|
|
|
|
private:
|
|
ArrayRef<EhSectionPiece> pieces;
|
|
size_t i = 0;
|
|
};
|
|
} // namespace
|
|
|
|
static void addRelativeReloc(InputSectionBase *isec, uint64_t offsetInSec,
|
|
Symbol *sym, int64_t addend, RelExpr expr,
|
|
RelType type) {
|
|
Partition &part = isec->getPartition();
|
|
|
|
// Add a relative relocation. If relrDyn section is enabled, and the
|
|
// relocation offset is guaranteed to be even, add the relocation to
|
|
// the relrDyn section, otherwise add it to the relaDyn section.
|
|
// relrDyn sections don't support odd offsets. Also, relrDyn sections
|
|
// don't store the addend values, so we must write it to the relocated
|
|
// address.
|
|
if (part.relrDyn && isec->alignment >= 2 && offsetInSec % 2 == 0) {
|
|
isec->relocations.push_back({expr, type, offsetInSec, addend, sym});
|
|
part.relrDyn->relocs.push_back({isec, offsetInSec});
|
|
return;
|
|
}
|
|
part.relaDyn->addReloc(target->relativeRel, isec, offsetInSec, sym, addend,
|
|
expr, type);
|
|
}
|
|
|
|
template <class PltSection, class GotPltSection>
|
|
static void addPltEntry(PltSection *plt, GotPltSection *gotPlt,
|
|
RelocationBaseSection *rel, RelType type, Symbol &sym) {
|
|
plt->addEntry(sym);
|
|
gotPlt->addEntry(sym);
|
|
rel->addReloc(
|
|
{type, gotPlt, sym.getGotPltOffset(), !sym.isPreemptible, &sym, 0});
|
|
}
|
|
|
|
static void addGotEntry(Symbol &sym) {
|
|
in.got->addEntry(sym);
|
|
|
|
RelExpr expr = sym.isTls() ? R_TLS : R_ABS;
|
|
uint64_t off = sym.getGotOffset();
|
|
|
|
// If a GOT slot value can be calculated at link-time, which is now,
|
|
// we can just fill that out.
|
|
//
|
|
// (We don't actually write a value to a GOT slot right now, but we
|
|
// add a static relocation to a Relocations vector so that
|
|
// InputSection::relocate will do the work for us. We may be able
|
|
// to just write a value now, but it is a TODO.)
|
|
bool isLinkTimeConstant =
|
|
!sym.isPreemptible && (!config->isPic || isAbsolute(sym));
|
|
if (isLinkTimeConstant) {
|
|
in.got->relocations.push_back({expr, target->symbolicRel, off, 0, &sym});
|
|
return;
|
|
}
|
|
|
|
// Otherwise, we emit a dynamic relocation to .rel[a].dyn so that
|
|
// the GOT slot will be fixed at load-time.
|
|
if (!sym.isTls() && !sym.isPreemptible && config->isPic && !isAbsolute(sym)) {
|
|
addRelativeReloc(in.got, off, &sym, 0, R_ABS, target->symbolicRel);
|
|
return;
|
|
}
|
|
mainPart->relaDyn->addReloc(
|
|
sym.isTls() ? target->tlsGotRel : target->gotRel, in.got, off, &sym, 0,
|
|
sym.isPreemptible ? R_ADDEND : R_ABS, target->symbolicRel);
|
|
}
|
|
|
|
// Return true if we can define a symbol in the executable that
|
|
// contains the value/function of a symbol defined in a shared
|
|
// library.
|
|
static bool canDefineSymbolInExecutable(Symbol &sym) {
|
|
// If the symbol has default visibility the symbol defined in the
|
|
// executable will preempt it.
|
|
// Note that we want the visibility of the shared symbol itself, not
|
|
// the visibility of the symbol in the output file we are producing. That is
|
|
// why we use Sym.stOther.
|
|
if ((sym.stOther & 0x3) == STV_DEFAULT)
|
|
return true;
|
|
|
|
// If we are allowed to break address equality of functions, defining
|
|
// a plt entry will allow the program to call the function in the
|
|
// .so, but the .so and the executable will no agree on the address
|
|
// of the function. Similar logic for objects.
|
|
return ((sym.isFunc() && config->ignoreFunctionAddressEquality) ||
|
|
(sym.isObject() && config->ignoreDataAddressEquality));
|
|
}
|
|
|
|
// 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 processRelocAux(InputSectionBase &sec, RelExpr expr, RelType type,
|
|
uint64_t offset, Symbol &sym, const RelTy &rel,
|
|
int64_t addend) {
|
|
// If the relocation is known to be a link-time constant, we know no dynamic
|
|
// relocation will be created, pass the control to relocateAlloc() or
|
|
// relocateNonAlloc() to resolve it.
|
|
//
|
|
// The behavior of an undefined weak reference is implementation defined. If
|
|
// the relocation is to a weak undef, and we are producing an executable, let
|
|
// relocate{,Non}Alloc() resolve it.
|
|
if (isStaticLinkTimeConstant(expr, type, sym, sec, offset) ||
|
|
(!config->shared && sym.isUndefWeak())) {
|
|
sec.relocations.push_back({expr, type, offset, addend, &sym});
|
|
return;
|
|
}
|
|
|
|
bool canWrite = (sec.flags & SHF_WRITE) || !config->zText;
|
|
if (canWrite) {
|
|
RelType rel = target->getDynRel(type);
|
|
if (expr == R_GOT || (rel == target->symbolicRel && !sym.isPreemptible)) {
|
|
addRelativeReloc(&sec, offset, &sym, addend, expr, type);
|
|
return;
|
|
} else if (rel != 0) {
|
|
if (config->emachine == EM_MIPS && rel == target->symbolicRel)
|
|
rel = target->relativeRel;
|
|
sec.getPartition().relaDyn->addReloc(rel, &sec, offset, &sym, addend,
|
|
R_ADDEND, type);
|
|
|
|
// 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.mipsGot->addEntry(*sec.file, sym, addend, expr);
|
|
return;
|
|
}
|
|
}
|
|
|
|
// When producing an executable, we can perform copy relocations (for
|
|
// STT_OBJECT) and canonical PLT (for STT_FUNC).
|
|
if (!config->shared) {
|
|
if (!canDefineSymbolInExecutable(sym)) {
|
|
errorOrWarn("cannot preempt symbol: " + toString(sym) +
|
|
getLocation(sec, sym, offset));
|
|
return;
|
|
}
|
|
|
|
if (sym.isObject()) {
|
|
// Produce a copy relocation.
|
|
if (auto *ss = dyn_cast<SharedSymbol>(&sym)) {
|
|
if (!config->zCopyreloc)
|
|
error("unresolvable relocation " + toString(type) +
|
|
" against symbol '" + toString(*ss) +
|
|
"'; recompile with -fPIC or remove '-z nocopyreloc'" +
|
|
getLocation(sec, sym, offset));
|
|
addCopyRelSymbol<ELFT>(*ss);
|
|
}
|
|
sec.relocations.push_back({expr, type, offset, addend, &sym});
|
|
return;
|
|
}
|
|
|
|
// 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 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).
|
|
|
|
// For position independent executable on i386, the plt entry requires ebx
|
|
// to be set. This causes two problems:
|
|
// * If some code has a direct reference to a function, it was probably
|
|
// compiled without -fPIE/-fPIC and doesn't maintain ebx.
|
|
// * If a library definition gets preempted to the executable, it will have
|
|
// the wrong ebx value.
|
|
if (sym.isFunc()) {
|
|
if (config->pie && config->emachine == EM_386)
|
|
errorOrWarn("symbol '" + toString(sym) +
|
|
"' cannot be preempted; recompile with -fPIE" +
|
|
getLocation(sec, sym, offset));
|
|
if (!sym.isInPlt())
|
|
addPltEntry(in.plt, in.gotPlt, in.relaPlt, target->pltRel, sym);
|
|
if (!sym.isDefined()) {
|
|
replaceWithDefined(
|
|
sym, in.plt,
|
|
target->pltHeaderSize + target->pltEntrySize * sym.pltIndex, 0);
|
|
if (config->emachine == EM_PPC) {
|
|
// PPC32 canonical PLT entries are at the beginning of .glink
|
|
cast<Defined>(sym).value = in.plt->headerSize;
|
|
in.plt->headerSize += 16;
|
|
cast<PPC32GlinkSection>(in.plt)->canonical_plts.push_back(&sym);
|
|
}
|
|
}
|
|
sym.needsPltAddr = true;
|
|
sec.relocations.push_back({expr, type, offset, addend, &sym});
|
|
return;
|
|
}
|
|
}
|
|
|
|
if (config->isPic) {
|
|
if (!canWrite && !isRelExpr(expr))
|
|
errorOrWarn(
|
|
"can't create dynamic relocation " + toString(type) + " against " +
|
|
(sym.getName().empty() ? "local symbol"
|
|
: "symbol: " + toString(sym)) +
|
|
" in readonly segment; recompile object files with -fPIC "
|
|
"or pass '-Wl,-z,notext' to allow text relocations in the output" +
|
|
getLocation(sec, sym, offset));
|
|
else
|
|
errorOrWarn(
|
|
"relocation " + toString(type) + " cannot be used against " +
|
|
(sym.getName().empty() ? "local symbol" : "symbol " + toString(sym)) +
|
|
"; recompile with -fPIC" + getLocation(sec, sym, offset));
|
|
return;
|
|
}
|
|
|
|
errorOrWarn("symbol '" + toString(sym) + "' has no type" +
|
|
getLocation(sec, sym, offset));
|
|
}
|
|
|
|
template <class ELFT, class RelTy>
|
|
static void scanReloc(InputSectionBase &sec, OffsetGetter &getOffset, RelTy *&i,
|
|
RelTy *end) {
|
|
const RelTy &rel = *i;
|
|
uint32_t symIndex = rel.getSymbol(config->isMips64EL);
|
|
Symbol &sym = sec.getFile<ELFT>()->getSymbol(symIndex);
|
|
RelType type;
|
|
|
|
// Deal with MIPS oddity.
|
|
if (config->mipsN32Abi) {
|
|
type = getMipsN32RelType(i, end);
|
|
} else {
|
|
type = rel.getType(config->isMips64EL);
|
|
++i;
|
|
}
|
|
|
|
// Get an offset in an output section this relocation is applied to.
|
|
uint64_t offset = getOffset.get(rel.r_offset);
|
|
if (offset == uint64_t(-1))
|
|
return;
|
|
|
|
// Error if the target symbol is undefined. Symbol index 0 may be used by
|
|
// marker relocations, e.g. R_*_NONE and R_ARM_V4BX. Don't error on them.
|
|
if (symIndex != 0 && maybeReportUndefined(sym, sec, rel.r_offset))
|
|
return;
|
|
|
|
const uint8_t *relocatedAddr = sec.data().begin() + rel.r_offset;
|
|
RelExpr expr = target->getRelExpr(type, sym, relocatedAddr);
|
|
|
|
// Ignore R_*_NONE and other marker relocations.
|
|
if (expr == R_NONE)
|
|
return;
|
|
|
|
if (sym.isGnuIFunc() && !config->zText && config->warnIfuncTextrel) {
|
|
warn("using ifunc symbols when text relocations are allowed may produce "
|
|
"a binary that will segfault, if the object file is linked with "
|
|
"old version of glibc (glibc 2.28 and earlier). If this applies to "
|
|
"you, consider recompiling the object files without -fPIC and "
|
|
"without -Wl,-z,notext option. Use -no-warn-ifunc-textrel to "
|
|
"turn off this warning." +
|
|
getLocation(sec, sym, offset));
|
|
}
|
|
|
|
// Read an addend.
|
|
int64_t addend = computeAddend<ELFT>(rel, end, sec, expr, sym.isLocal());
|
|
|
|
if (config->emachine == EM_PPC64) {
|
|
// We can separate the small code model relocations into 2 categories:
|
|
// 1) Those that access the compiler generated .toc sections.
|
|
// 2) Those that access the linker allocated got entries.
|
|
// lld allocates got entries to symbols on demand. Since we don't try to
|
|
// sort the got entries in any way, we don't have to track which objects
|
|
// have got-based small code model relocs. The .toc sections get placed
|
|
// after the end of the linker allocated .got section and we do sort those
|
|
// so sections addressed with small code model relocations come first.
|
|
if (isPPC64SmallCodeModelTocReloc(type))
|
|
sec.file->ppc64SmallCodeModelTocRelocs = true;
|
|
|
|
// Record the TOC entry (.toc + addend) as not relaxable. See the comment in
|
|
// InputSectionBase::relocateAlloc().
|
|
if (type == R_PPC64_TOC16_LO && sym.isSection() && isa<Defined>(sym) &&
|
|
cast<Defined>(sym).section->name == ".toc")
|
|
ppc64noTocRelax.insert({&sym, addend});
|
|
}
|
|
|
|
// Relax relocations.
|
|
//
|
|
// If we know that a PLT entry will be resolved within the same ELF module, we
|
|
// can skip PLT access and directly jump to the destination function. For
|
|
// example, if we are linking a main executable, all dynamic symbols that can
|
|
// be resolved within the executable will actually be resolved that way at
|
|
// runtime, because the main executable is always at the beginning of a search
|
|
// list. We can leverage that fact.
|
|
if (!sym.isPreemptible && (!sym.isGnuIFunc() || config->zIfuncNoplt)) {
|
|
if (expr == R_GOT_PC && !isAbsoluteValue(sym)) {
|
|
expr = target->adjustRelaxExpr(type, relocatedAddr, expr);
|
|
} else {
|
|
// The 0x8000 bit of r_addend of R_PPC_PLTREL24 is used to choose call
|
|
// stub type. It should be ignored if optimized to R_PC.
|
|
if (config->emachine == EM_PPC && expr == R_PPC32_PLTREL)
|
|
addend &= ~0x8000;
|
|
// R_HEX_GD_PLT_B22_PCREL (call a@GDPLT) is transformed into
|
|
// call __tls_get_addr even if the symbol is non-preemptible.
|
|
if (!(config->emachine == EM_HEXAGON && type == R_HEX_GD_PLT_B22_PCREL))
|
|
expr = fromPlt(expr);
|
|
}
|
|
}
|
|
|
|
// If the relocation does not emit a GOT or GOTPLT entry but its computation
|
|
// uses their addresses, we need GOT or GOTPLT to be created.
|
|
//
|
|
// The 4 types that relative GOTPLT are all x86 and x86-64 specific.
|
|
if (oneof<R_GOTPLTONLY_PC, R_GOTPLTREL, R_GOTPLT, R_TLSGD_GOTPLT>(expr)) {
|
|
in.gotPlt->hasGotPltOffRel = true;
|
|
} else if (oneof<R_GOTONLY_PC, R_GOTREL, R_PPC64_TOCBASE, R_PPC64_RELAX_TOC>(
|
|
expr)) {
|
|
in.got->hasGotOffRel = true;
|
|
}
|
|
|
|
// Process some TLS relocations, including relaxing TLS relocations.
|
|
// Note that this function does not handle all TLS relocations.
|
|
if (unsigned processed =
|
|
handleTlsRelocation<ELFT>(type, sym, sec, offset, addend, expr)) {
|
|
i += (processed - 1);
|
|
return;
|
|
}
|
|
|
|
// We were asked not to generate PLT entries for ifuncs. Instead, pass the
|
|
// direct relocation on through.
|
|
if (sym.isGnuIFunc() && config->zIfuncNoplt) {
|
|
sym.exportDynamic = true;
|
|
mainPart->relaDyn->addReloc(type, &sec, offset, &sym, addend, R_ADDEND, type);
|
|
return;
|
|
}
|
|
|
|
// Non-preemptible ifuncs require special handling. First, handle the usual
|
|
// case where the symbol isn't one of these.
|
|
if (!sym.isGnuIFunc() || sym.isPreemptible) {
|
|
// If a relocation needs PLT, we create PLT and GOTPLT slots for the symbol.
|
|
if (needsPlt(expr) && !sym.isInPlt())
|
|
addPltEntry(in.plt, in.gotPlt, in.relaPlt, target->pltRel, sym);
|
|
|
|
// Create a GOT slot if a relocation needs GOT.
|
|
if (needsGot(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.mipsGot->addEntry(*sec.file, sym, addend, expr);
|
|
} else if (!sym.isInGot()) {
|
|
addGotEntry(sym);
|
|
}
|
|
}
|
|
} else {
|
|
// Handle a reference to a non-preemptible ifunc. These are special in a
|
|
// few ways:
|
|
//
|
|
// - Unlike most non-preemptible symbols, non-preemptible ifuncs do not have
|
|
// a fixed value. But assuming that all references to the ifunc are
|
|
// GOT-generating or PLT-generating, the handling of an ifunc is
|
|
// relatively straightforward. We create a PLT entry in Iplt, which is
|
|
// usually at the end of .plt, which makes an indirect call using a
|
|
// matching GOT entry in igotPlt, which is usually at the end of .got.plt.
|
|
// The GOT entry is relocated using an IRELATIVE relocation in relaIplt,
|
|
// which is usually at the end of .rela.plt. Unlike most relocations in
|
|
// .rela.plt, which may be evaluated lazily without -z now, dynamic
|
|
// loaders evaluate IRELATIVE relocs eagerly, which means that for
|
|
// IRELATIVE relocs only, GOT-generating relocations can point directly to
|
|
// .got.plt without requiring a separate GOT entry.
|
|
//
|
|
// - Despite the fact that an ifunc does not have a fixed value, compilers
|
|
// that are not passed -fPIC will assume that they do, and will emit
|
|
// direct (non-GOT-generating, non-PLT-generating) relocations to the
|
|
// symbol. This means that if a direct relocation to the symbol is
|
|
// seen, the linker must set a value for the symbol, and this value must
|
|
// be consistent no matter what type of reference is made to the symbol.
|
|
// This can be done by creating a PLT entry for the symbol in the way
|
|
// described above and making it canonical, that is, making all references
|
|
// point to the PLT entry instead of the resolver. In lld we also store
|
|
// the address of the PLT entry in the dynamic symbol table, which means
|
|
// that the symbol will also have the same value in other modules.
|
|
// Because the value loaded from the GOT needs to be consistent with
|
|
// the value computed using a direct relocation, a non-preemptible ifunc
|
|
// may end up with two GOT entries, one in .got.plt that points to the
|
|
// address returned by the resolver and is used only by the PLT entry,
|
|
// and another in .got that points to the PLT entry and is used by
|
|
// GOT-generating relocations.
|
|
//
|
|
// - The fact that these symbols do not have a fixed value makes them an
|
|
// exception to the general rule that a statically linked executable does
|
|
// not require any form of dynamic relocation. To handle these relocations
|
|
// correctly, the IRELATIVE relocations are stored in an array which a
|
|
// statically linked executable's startup code must enumerate using the
|
|
// linker-defined symbols __rela?_iplt_{start,end}.
|
|
if (!sym.isInPlt()) {
|
|
// Create PLT and GOTPLT slots for the symbol.
|
|
sym.isInIplt = true;
|
|
|
|
// Create a copy of the symbol to use as the target of the IRELATIVE
|
|
// relocation in the igotPlt. This is in case we make the PLT canonical
|
|
// later, which would overwrite the original symbol.
|
|
//
|
|
// FIXME: Creating a copy of the symbol here is a bit of a hack. All
|
|
// that's really needed to create the IRELATIVE is the section and value,
|
|
// so ideally we should just need to copy those.
|
|
auto *directSym = make<Defined>(cast<Defined>(sym));
|
|
addPltEntry(in.iplt, in.igotPlt, in.relaIplt, target->iRelativeRel,
|
|
*directSym);
|
|
sym.pltIndex = directSym->pltIndex;
|
|
}
|
|
if (needsGot(expr)) {
|
|
// Redirect GOT accesses to point to the Igot.
|
|
//
|
|
// This field is also used to keep track of whether we ever needed a GOT
|
|
// entry. If we did and we make the PLT canonical later, we'll need to
|
|
// create a GOT entry pointing to the PLT entry for Sym.
|
|
sym.gotInIgot = true;
|
|
} else if (!needsPlt(expr)) {
|
|
// Make the ifunc's PLT entry canonical by changing the value of its
|
|
// symbol to redirect all references to point to it.
|
|
auto &d = cast<Defined>(sym);
|
|
d.section = in.iplt;
|
|
d.value = sym.pltIndex * target->ipltEntrySize;
|
|
d.size = 0;
|
|
// It's important to set the symbol type here so that dynamic loaders
|
|
// don't try to call the PLT as if it were an ifunc resolver.
|
|
d.type = STT_FUNC;
|
|
|
|
if (sym.gotInIgot) {
|
|
// We previously encountered a GOT generating reference that we
|
|
// redirected to the Igot. Now that the PLT entry is canonical we must
|
|
// clear the redirection to the Igot and add a GOT entry. As we've
|
|
// changed the symbol type to STT_FUNC future GOT generating references
|
|
// will naturally use this GOT entry.
|
|
//
|
|
// We don't need to worry about creating a MIPS GOT here because ifuncs
|
|
// aren't a thing on MIPS.
|
|
sym.gotInIgot = false;
|
|
addGotEntry(sym);
|
|
}
|
|
}
|
|
}
|
|
|
|
processRelocAux<ELFT>(sec, expr, type, offset, sym, rel, addend);
|
|
}
|
|
|
|
template <class ELFT, class RelTy>
|
|
static void scanRelocs(InputSectionBase &sec, ArrayRef<RelTy> rels) {
|
|
OffsetGetter getOffset(sec);
|
|
|
|
// Not all relocations end up in Sec.Relocations, but a lot do.
|
|
sec.relocations.reserve(rels.size());
|
|
|
|
for (auto i = rels.begin(), end = rels.end(); i != end;)
|
|
scanReloc<ELFT>(sec, getOffset, i, end);
|
|
|
|
// Sort relocations by offset for more efficient searching for
|
|
// R_RISCV_PCREL_HI20 and R_PPC64_ADDR64.
|
|
if (config->emachine == EM_RISCV ||
|
|
(config->emachine == EM_PPC64 && sec.name == ".toc"))
|
|
llvm::stable_sort(sec.relocations,
|
|
[](const Relocation &lhs, const Relocation &rhs) {
|
|
return lhs.offset < rhs.offset;
|
|
});
|
|
}
|
|
|
|
template <class ELFT> void scanRelocations(InputSectionBase &s) {
|
|
if (s.areRelocsRela)
|
|
scanRelocs<ELFT>(s, s.relas<ELFT>());
|
|
else
|
|
scanRelocs<ELFT>(s, s.rels<ELFT>());
|
|
}
|
|
|
|
static bool 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) {
|
|
auto *ta = dyn_cast<ThunkSection>(a);
|
|
auto *tb = dyn_cast<ThunkSection>(b);
|
|
|
|
// Check if Thunk is immediately before any specific Target
|
|
// InputSection for example Mips LA25 Thunks.
|
|
if (ta && ta->getTargetInputSection() == b)
|
|
return true;
|
|
|
|
// Place Thunk Sections without specific targets before
|
|
// non-Thunk Sections.
|
|
if (ta && !tb && !ta->getTargetInputSection())
|
|
return true;
|
|
}
|
|
|
|
return false;
|
|
}
|
|
|
|
// Call Fn on every executable InputSection accessed via the linker script
|
|
// InputSectionDescription::Sections.
|
|
static void forEachInputSectionDescription(
|
|
ArrayRef<OutputSection *> outputSections,
|
|
llvm::function_ref<void(OutputSection *, InputSectionDescription *)> fn) {
|
|
for (OutputSection *os : outputSections) {
|
|
if (!(os->flags & SHF_ALLOC) || !(os->flags & SHF_EXECINSTR))
|
|
continue;
|
|
for (BaseCommand *bc : os->sectionCommands)
|
|
if (auto *isd = dyn_cast<InputSectionDescription>(bc))
|
|
fn(os, isd);
|
|
}
|
|
}
|
|
|
|
// Thunk Implementation
|
|
//
|
|
// Thunks (sometimes called stubs, veneers or branch islands) are small pieces
|
|
// of code that the linker inserts inbetween a caller and a callee. The thunks
|
|
// are added at link time rather than compile time as the decision on whether
|
|
// a thunk is needed, such as the caller and callee being out of range, can only
|
|
// be made at link time.
|
|
//
|
|
// It is straightforward to tell given the current state of the program when a
|
|
// thunk is needed for a particular call. The more difficult part is that
|
|
// the thunk needs to be placed in the program such that the caller can reach
|
|
// the thunk and the thunk can reach the callee; furthermore, adding thunks to
|
|
// the program alters addresses, which can mean more thunks etc.
|
|
//
|
|
// In lld we have a synthetic ThunkSection that can hold many Thunks.
|
|
// The decision to have a ThunkSection act as a container means that we can
|
|
// more easily handle the most common case of a single block of contiguous
|
|
// Thunks by inserting just a single ThunkSection.
|
|
//
|
|
// The implementation of Thunks in lld is split across these areas
|
|
// Relocations.cpp : Framework for creating and placing thunks
|
|
// Thunks.cpp : The code generated for each supported thunk
|
|
// Target.cpp : Target specific hooks that the framework uses to decide when
|
|
// a thunk is used
|
|
// Synthetic.cpp : Implementation of ThunkSection
|
|
// Writer.cpp : Iteratively call framework until no more Thunks added
|
|
//
|
|
// Thunk placement requirements:
|
|
// Mips LA25 thunks. These must be placed immediately before the callee section
|
|
// We can assume that the caller is in range of the Thunk. These are modelled
|
|
// by Thunks that return the section they must precede with
|
|
// getTargetInputSection().
|
|
//
|
|
// ARM interworking and range extension thunks. These thunks must be placed
|
|
// within range of the caller. All implemented ARM thunks can always reach the
|
|
// callee as they use an indirect jump via a register that has no range
|
|
// restrictions.
|
|
//
|
|
// Thunk placement algorithm:
|
|
// For Mips LA25 ThunkSections; the placement is explicit, it has to be before
|
|
// getTargetInputSection().
|
|
//
|
|
// For thunks that must be placed within range of the caller there are many
|
|
// possible choices given that the maximum range from the caller is usually
|
|
// much larger than the average InputSection size. Desirable properties include:
|
|
// - Maximize reuse of thunks by multiple callers
|
|
// - Minimize number of ThunkSections to simplify insertion
|
|
// - Handle impact of already added Thunks on addresses
|
|
// - Simple to understand and implement
|
|
//
|
|
// In lld for the first pass, we pre-create one or more ThunkSections per
|
|
// InputSectionDescription at Target specific intervals. A ThunkSection is
|
|
// placed so that the estimated end of the ThunkSection is within range of the
|
|
// start of the InputSectionDescription or the previous ThunkSection. For
|
|
// example:
|
|
// InputSectionDescription
|
|
// Section 0
|
|
// ...
|
|
// Section N
|
|
// ThunkSection 0
|
|
// Section N + 1
|
|
// ...
|
|
// Section N + K
|
|
// Thunk Section 1
|
|
//
|
|
// The intention is that we can add a Thunk to a ThunkSection that is well
|
|
// spaced enough to service a number of callers without having to do a lot
|
|
// of work. An important principle is that it is not an error if a Thunk cannot
|
|
// be placed in a pre-created ThunkSection; when this happens we create a new
|
|
// ThunkSection placed next to the caller. This allows us to handle the vast
|
|
// majority of thunks simply, but also handle rare cases where the branch range
|
|
// is smaller than the target specific spacing.
|
|
//
|
|
// The algorithm is expected to create all the thunks that are needed in a
|
|
// single pass, with a small number of programs needing a second pass due to
|
|
// the insertion of thunks in the first pass increasing the offset between
|
|
// callers and callees that were only just in range.
|
|
//
|
|
// A consequence of allowing new ThunkSections to be created outside of the
|
|
// pre-created ThunkSections is that in rare cases calls to Thunks that were in
|
|
// range in pass K, are out of range in some pass > K due to the insertion of
|
|
// more Thunks in between the caller and callee. When this happens we retarget
|
|
// the relocation back to the original target and create another Thunk.
|
|
|
|
// Remove ThunkSections that are empty, this should only be the initial set
|
|
// precreated on pass 0.
|
|
|
|
// 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
|
|
void ThunkCreator::mergeThunks(ArrayRef<OutputSection *> outputSections) {
|
|
forEachInputSectionDescription(
|
|
outputSections, [&](OutputSection *os, InputSectionDescription *isd) {
|
|
if (isd->thunkSections.empty())
|
|
return;
|
|
|
|
// Remove any zero sized precreated Thunks.
|
|
llvm::erase_if(isd->thunkSections,
|
|
[](const std::pair<ThunkSection *, uint32_t> &ts) {
|
|
return ts.first->getSize() == 0;
|
|
});
|
|
|
|
// ISD->ThunkSections contains all created ThunkSections, including
|
|
// those inserted in previous passes. Extract the Thunks created this
|
|
// pass and order them in ascending outSecOff.
|
|
std::vector<ThunkSection *> newThunks;
|
|
for (std::pair<ThunkSection *, uint32_t> ts : isd->thunkSections)
|
|
if (ts.second == pass)
|
|
newThunks.push_back(ts.first);
|
|
llvm::stable_sort(newThunks,
|
|
[](const ThunkSection *a, const ThunkSection *b) {
|
|
return a->outSecOff < b->outSecOff;
|
|
});
|
|
|
|
// Merge sorted vectors of Thunks and InputSections by outSecOff
|
|
std::vector<InputSection *> tmp;
|
|
tmp.reserve(isd->sections.size() + newThunks.size());
|
|
|
|
std::merge(isd->sections.begin(), isd->sections.end(),
|
|
newThunks.begin(), newThunks.end(), std::back_inserter(tmp),
|
|
mergeCmp);
|
|
|
|
isd->sections = std::move(tmp);
|
|
});
|
|
}
|
|
|
|
// Find or create a ThunkSection within the InputSectionDescription (ISD) that
|
|
// is in range of Src. An ISD maps to a range of InputSections described by a
|
|
// linker script section pattern such as { .text .text.* }.
|
|
ThunkSection *ThunkCreator::getISDThunkSec(OutputSection *os, InputSection *isec,
|
|
InputSectionDescription *isd,
|
|
uint32_t type, uint64_t src) {
|
|
for (std::pair<ThunkSection *, uint32_t> tp : isd->thunkSections) {
|
|
ThunkSection *ts = tp.first;
|
|
uint64_t tsBase = os->addr + ts->outSecOff;
|
|
uint64_t tsLimit = tsBase + ts->getSize();
|
|
if (target->inBranchRange(type, src, (src > tsLimit) ? tsBase : tsLimit))
|
|
return ts;
|
|
}
|
|
|
|
// No suitable ThunkSection exists. This can happen when there is a branch
|
|
// with lower range than the ThunkSection spacing or when there are too
|
|
// many Thunks. Create a new ThunkSection as close to the InputSection as
|
|
// possible. Error if InputSection is so large we cannot place ThunkSection
|
|
// anywhere in Range.
|
|
uint64_t thunkSecOff = isec->outSecOff;
|
|
if (!target->inBranchRange(type, src, os->addr + thunkSecOff)) {
|
|
thunkSecOff = isec->outSecOff + isec->getSize();
|
|
if (!target->inBranchRange(type, src, os->addr + thunkSecOff))
|
|
fatal("InputSection too large for range extension thunk " +
|
|
isec->getObjMsg(src - (os->addr + isec->outSecOff)));
|
|
}
|
|
return addThunkSection(os, isd, thunkSecOff);
|
|
}
|
|
|
|
// Add a Thunk that needs to be placed in a ThunkSection that immediately
|
|
// precedes its Target.
|
|
ThunkSection *ThunkCreator::getISThunkSec(InputSection *isec) {
|
|
ThunkSection *ts = thunkedSections.lookup(isec);
|
|
if (ts)
|
|
return ts;
|
|
|
|
// Find InputSectionRange within Target Output Section (TOS) that the
|
|
// InputSection (IS) that we need to precede is in.
|
|
OutputSection *tos = isec->getParent();
|
|
for (BaseCommand *bc : tos->sectionCommands) {
|
|
auto *isd = dyn_cast<InputSectionDescription>(bc);
|
|
if (!isd || isd->sections.empty())
|
|
continue;
|
|
|
|
InputSection *first = isd->sections.front();
|
|
InputSection *last = isd->sections.back();
|
|
|
|
if (isec->outSecOff < first->outSecOff || last->outSecOff < isec->outSecOff)
|
|
continue;
|
|
|
|
ts = addThunkSection(tos, isd, isec->outSecOff);
|
|
thunkedSections[isec] = ts;
|
|
return ts;
|
|
}
|
|
|
|
return nullptr;
|
|
}
|
|
|
|
// Create one or more ThunkSections per OS that can be used to place Thunks.
|
|
// We attempt to place the ThunkSections using the following desirable
|
|
// properties:
|
|
// - Within range of the maximum number of callers
|
|
// - Minimise the number of ThunkSections
|
|
//
|
|
// We follow a simple but conservative heuristic to place ThunkSections at
|
|
// offsets that are multiples of a Target specific branch range.
|
|
// For an InputSectionDescription that is smaller than the range, a single
|
|
// ThunkSection at the end of the range will do.
|
|
//
|
|
// For an InputSectionDescription that is more than twice the size of the range,
|
|
// we place the last ThunkSection at range bytes from the end of the
|
|
// InputSectionDescription in order to increase the likelihood that the
|
|
// distance from a thunk to its target will be sufficiently small to
|
|
// allow for the creation of a short thunk.
|
|
void ThunkCreator::createInitialThunkSections(
|
|
ArrayRef<OutputSection *> outputSections) {
|
|
uint32_t thunkSectionSpacing = target->getThunkSectionSpacing();
|
|
|
|
forEachInputSectionDescription(
|
|
outputSections, [&](OutputSection *os, InputSectionDescription *isd) {
|
|
if (isd->sections.empty())
|
|
return;
|
|
|
|
uint32_t isdBegin = isd->sections.front()->outSecOff;
|
|
uint32_t isdEnd =
|
|
isd->sections.back()->outSecOff + isd->sections.back()->getSize();
|
|
uint32_t lastThunkLowerBound = -1;
|
|
if (isdEnd - isdBegin > thunkSectionSpacing * 2)
|
|
lastThunkLowerBound = isdEnd - thunkSectionSpacing;
|
|
|
|
uint32_t isecLimit;
|
|
uint32_t prevIsecLimit = isdBegin;
|
|
uint32_t thunkUpperBound = isdBegin + thunkSectionSpacing;
|
|
|
|
for (const InputSection *isec : isd->sections) {
|
|
isecLimit = isec->outSecOff + isec->getSize();
|
|
if (isecLimit > thunkUpperBound) {
|
|
addThunkSection(os, isd, prevIsecLimit);
|
|
thunkUpperBound = prevIsecLimit + thunkSectionSpacing;
|
|
}
|
|
if (isecLimit > lastThunkLowerBound)
|
|
break;
|
|
prevIsecLimit = isecLimit;
|
|
}
|
|
addThunkSection(os, isd, isecLimit);
|
|
});
|
|
}
|
|
|
|
ThunkSection *ThunkCreator::addThunkSection(OutputSection *os,
|
|
InputSectionDescription *isd,
|
|
uint64_t off) {
|
|
auto *ts = make<ThunkSection>(os, off);
|
|
ts->partition = os->partition;
|
|
if ((config->fixCortexA53Errata843419 || config->fixCortexA8) &&
|
|
!isd->sections.empty()) {
|
|
// The errata fixes are sensitive to addresses modulo 4 KiB. When we add
|
|
// thunks we disturb the base addresses of sections placed after the thunks
|
|
// this makes patches we have generated redundant, and may cause us to
|
|
// generate more patches as different instructions are now in sensitive
|
|
// locations. When we generate more patches we may force more branches to
|
|
// go out of range, causing more thunks to be generated. In pathological
|
|
// cases this can cause the address dependent content pass not to converge.
|
|
// We fix this by rounding up the size of the ThunkSection to 4KiB, this
|
|
// limits the insertion of a ThunkSection on the addresses modulo 4 KiB,
|
|
// which means that adding Thunks to the section does not invalidate
|
|
// errata patches for following code.
|
|
// Rounding up the size to 4KiB has consequences for code-size and can
|
|
// trip up linker script defined assertions. For example the linux kernel
|
|
// has an assertion that what LLD represents as an InputSectionDescription
|
|
// does not exceed 4 KiB even if the overall OutputSection is > 128 Mib.
|
|
// We use the heuristic of rounding up the size when both of the following
|
|
// conditions are true:
|
|
// 1.) The OutputSection is larger than the ThunkSectionSpacing. This
|
|
// accounts for the case where no single InputSectionDescription is
|
|
// larger than the OutputSection size. This is conservative but simple.
|
|
// 2.) The InputSectionDescription is larger than 4 KiB. This will prevent
|
|
// any assertion failures that an InputSectionDescription is < 4 KiB
|
|
// in size.
|
|
uint64_t isdSize = isd->sections.back()->outSecOff +
|
|
isd->sections.back()->getSize() -
|
|
isd->sections.front()->outSecOff;
|
|
if (os->size > target->getThunkSectionSpacing() && isdSize > 4096)
|
|
ts->roundUpSizeForErrata = true;
|
|
}
|
|
isd->thunkSections.push_back({ts, pass});
|
|
return ts;
|
|
}
|
|
|
|
static bool isThunkSectionCompatible(InputSection *source,
|
|
SectionBase *target) {
|
|
// We can't reuse thunks in different loadable partitions because they might
|
|
// not be loaded. But partition 1 (the main partition) will always be loaded.
|
|
if (source->partition != target->partition)
|
|
return target->partition == 1;
|
|
return true;
|
|
}
|
|
|
|
static int64_t getPCBias(RelType type) {
|
|
if (config->emachine != EM_ARM)
|
|
return 0;
|
|
switch (type) {
|
|
case R_ARM_THM_JUMP19:
|
|
case R_ARM_THM_JUMP24:
|
|
case R_ARM_THM_CALL:
|
|
return 4;
|
|
default:
|
|
return 8;
|
|
}
|
|
}
|
|
|
|
std::pair<Thunk *, bool> ThunkCreator::getThunk(InputSection *isec,
|
|
Relocation &rel, uint64_t src) {
|
|
std::vector<Thunk *> *thunkVec = nullptr;
|
|
int64_t addend = rel.addend + getPCBias(rel.type);
|
|
|
|
// We use a ((section, offset), addend) pair to find the thunk position if
|
|
// possible so that we create only one thunk for aliased symbols or ICFed
|
|
// sections. There may be multiple relocations sharing the same (section,
|
|
// offset + addend) pair. We may revert the relocation back to its original
|
|
// non-Thunk target, so we cannot fold offset + addend.
|
|
if (auto *d = dyn_cast<Defined>(rel.sym))
|
|
if (!d->isInPlt() && d->section)
|
|
thunkVec = &thunkedSymbolsBySectionAndAddend[{
|
|
{d->section->repl, d->value}, addend}];
|
|
if (!thunkVec)
|
|
thunkVec = &thunkedSymbols[{rel.sym, addend}];
|
|
|
|
// Check existing Thunks for Sym to see if they can be reused
|
|
for (Thunk *t : *thunkVec)
|
|
if (isThunkSectionCompatible(isec, t->getThunkTargetSym()->section) &&
|
|
t->isCompatibleWith(*isec, rel) &&
|
|
target->inBranchRange(rel.type, src,
|
|
t->getThunkTargetSym()->getVA(rel.addend) +
|
|
getPCBias(rel.type)))
|
|
return std::make_pair(t, false);
|
|
|
|
// No existing compatible Thunk in range, create a new one
|
|
Thunk *t = addThunk(*isec, rel);
|
|
thunkVec->push_back(t);
|
|
return std::make_pair(t, true);
|
|
}
|
|
|
|
// Return true if the relocation target is an in range Thunk.
|
|
// Return false if the relocation is not to a Thunk. If the relocation target
|
|
// was originally to a Thunk, but is no longer in range we revert the
|
|
// relocation back to its original non-Thunk target.
|
|
bool ThunkCreator::normalizeExistingThunk(Relocation &rel, uint64_t src) {
|
|
if (Thunk *t = thunks.lookup(rel.sym)) {
|
|
if (target->inBranchRange(rel.type, src,
|
|
rel.sym->getVA(rel.addend) + getPCBias(rel.type)))
|
|
return true;
|
|
rel.sym = &t->destination;
|
|
rel.addend = t->addend;
|
|
if (rel.sym->isInPlt())
|
|
rel.expr = toPlt(rel.expr);
|
|
}
|
|
return false;
|
|
}
|
|
|
|
// Process all relocations from the InputSections that have been assigned
|
|
// to InputSectionDescriptions and redirect through Thunks if needed. The
|
|
// function should be called iteratively until it returns false.
|
|
//
|
|
// PreConditions:
|
|
// All InputSections that may need a Thunk are reachable from
|
|
// OutputSectionCommands.
|
|
//
|
|
// All OutputSections have an address and all InputSections have an offset
|
|
// within the OutputSection.
|
|
//
|
|
// The offsets between caller (relocation place) and callee
|
|
// (relocation target) will not be modified outside of createThunks().
|
|
//
|
|
// PostConditions:
|
|
// If return value is true then ThunkSections have been inserted into
|
|
// OutputSections. All relocations that needed a Thunk based on the information
|
|
// available to createThunks() on entry have been redirected to a Thunk. Note
|
|
// that adding Thunks changes offsets between caller and callee so more Thunks
|
|
// may be required.
|
|
//
|
|
// If return value is false then no more Thunks are needed, and createThunks has
|
|
// made no changes. If the target requires range extension thunks, currently
|
|
// ARM, then any future change in offset between caller and callee risks a
|
|
// relocation out of range error.
|
|
bool ThunkCreator::createThunks(ArrayRef<OutputSection *> outputSections) {
|
|
bool addressesChanged = false;
|
|
|
|
if (pass == 0 && target->getThunkSectionSpacing())
|
|
createInitialThunkSections(outputSections);
|
|
|
|
// Create all the Thunks and insert them into synthetic ThunkSections. The
|
|
// ThunkSections are later inserted back into InputSectionDescriptions.
|
|
// We separate the creation of ThunkSections from the insertion of the
|
|
// ThunkSections as ThunkSections are not always inserted into the same
|
|
// InputSectionDescription as the caller.
|
|
forEachInputSectionDescription(
|
|
outputSections, [&](OutputSection *os, InputSectionDescription *isd) {
|
|
for (InputSection *isec : isd->sections)
|
|
for (Relocation &rel : isec->relocations) {
|
|
uint64_t src = isec->getVA(rel.offset);
|
|
|
|
// If we are a relocation to an existing Thunk, check if it is
|
|
// still in range. If not then Rel will be altered to point to its
|
|
// original target so another Thunk can be generated.
|
|
if (pass > 0 && normalizeExistingThunk(rel, src))
|
|
continue;
|
|
|
|
if (!target->needsThunk(rel.expr, rel.type, isec->file, src,
|
|
*rel.sym, rel.addend))
|
|
continue;
|
|
|
|
Thunk *t;
|
|
bool isNew;
|
|
std::tie(t, isNew) = getThunk(isec, rel, src);
|
|
|
|
if (isNew) {
|
|
// Find or create a ThunkSection for the new Thunk
|
|
ThunkSection *ts;
|
|
if (auto *tis = t->getTargetInputSection())
|
|
ts = getISThunkSec(tis);
|
|
else
|
|
ts = getISDThunkSec(os, isec, isd, rel.type, src);
|
|
ts->addThunk(t);
|
|
thunks[t->getThunkTargetSym()] = t;
|
|
}
|
|
|
|
// Redirect relocation to Thunk, we never go via the PLT to a Thunk
|
|
rel.sym = t->getThunkTargetSym();
|
|
rel.expr = fromPlt(rel.expr);
|
|
|
|
// On AArch64 and PPC, a jump/call relocation may be encoded as
|
|
// STT_SECTION + non-zero addend, clear the addend after
|
|
// redirection.
|
|
if (config->emachine != EM_MIPS)
|
|
rel.addend = -getPCBias(rel.type);
|
|
}
|
|
|
|
for (auto &p : isd->thunkSections)
|
|
addressesChanged |= p.first->assignOffsets();
|
|
});
|
|
|
|
for (auto &p : thunkedSections)
|
|
addressesChanged |= p.second->assignOffsets();
|
|
|
|
// Merge all created synthetic ThunkSections back into OutputSection
|
|
mergeThunks(outputSections);
|
|
++pass;
|
|
return addressesChanged;
|
|
}
|
|
|
|
// The following aid in the conversion of call x@GDPLT to call __tls_get_addr
|
|
// hexagonNeedsTLSSymbol scans for relocations would require a call to
|
|
// __tls_get_addr.
|
|
// hexagonTLSSymbolUpdate rebinds the relocation to __tls_get_addr.
|
|
bool hexagonNeedsTLSSymbol(ArrayRef<OutputSection *> outputSections) {
|
|
bool needTlsSymbol = false;
|
|
forEachInputSectionDescription(
|
|
outputSections, [&](OutputSection *os, InputSectionDescription *isd) {
|
|
for (InputSection *isec : isd->sections)
|
|
for (Relocation &rel : isec->relocations)
|
|
if (rel.sym->type == llvm::ELF::STT_TLS && rel.expr == R_PLT_PC) {
|
|
needTlsSymbol = true;
|
|
return;
|
|
}
|
|
});
|
|
return needTlsSymbol;
|
|
}
|
|
|
|
void hexagonTLSSymbolUpdate(ArrayRef<OutputSection *> outputSections) {
|
|
Symbol *sym = symtab->find("__tls_get_addr");
|
|
if (!sym)
|
|
return;
|
|
bool needEntry = true;
|
|
forEachInputSectionDescription(
|
|
outputSections, [&](OutputSection *os, InputSectionDescription *isd) {
|
|
for (InputSection *isec : isd->sections)
|
|
for (Relocation &rel : isec->relocations)
|
|
if (rel.sym->type == llvm::ELF::STT_TLS && rel.expr == R_PLT_PC) {
|
|
if (needEntry) {
|
|
addPltEntry(in.plt, in.gotPlt, in.relaPlt, target->pltRel,
|
|
*sym);
|
|
needEntry = false;
|
|
}
|
|
rel.sym = sym;
|
|
}
|
|
});
|
|
}
|
|
|
|
template void scanRelocations<ELF32LE>(InputSectionBase &);
|
|
template void scanRelocations<ELF32BE>(InputSectionBase &);
|
|
template void scanRelocations<ELF64LE>(InputSectionBase &);
|
|
template void scanRelocations<ELF64BE>(InputSectionBase &);
|
|
template void reportUndefinedSymbols<ELF32LE>();
|
|
template void reportUndefinedSymbols<ELF32BE>();
|
|
template void reportUndefinedSymbols<ELF64LE>();
|
|
template void reportUndefinedSymbols<ELF64BE>();
|
|
|
|
} // namespace elf
|
|
} // namespace lld
|