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//===- Symbols.h ------------------------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines various types of Symbols.
//
//===----------------------------------------------------------------------===//
#ifndef LLD_ELF_SYMBOLS_H
#define LLD_ELF_SYMBOLS_H
#include "Config.h"
#include "lld/Common/LLVM.h"
#include "lld/Common/Memory.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/Object/ELF.h"
#include "llvm/Support/Compiler.h"
#include <tuple>
namespace lld {
namespace elf {
class Symbol;
}
// Returns a string representation for a symbol for diagnostics.
std::string toString(const elf::Symbol &);
namespace elf {
class CommonSymbol;
class Defined;
class OutputSection;
class SectionBase;
class InputSectionBase;
class SharedSymbol;
class Symbol;
class Undefined;
class LazySymbol;
class InputFile;
void printTraceSymbol(const Symbol &sym, StringRef name);
enum {
NEEDS_GOT = 1 << 0,
NEEDS_PLT = 1 << 1,
HAS_DIRECT_RELOC = 1 << 2,
// True if this symbol needs a canonical PLT entry, or (during
// postScanRelocations) a copy relocation.
NEEDS_COPY = 1 << 3,
NEEDS_TLSDESC = 1 << 4,
NEEDS_TLSGD = 1 << 5,
NEEDS_TLSGD_TO_IE = 1 << 6,
NEEDS_GOT_DTPREL = 1 << 7,
NEEDS_TLSIE = 1 << 8,
};
// The base class for real symbol classes.
class Symbol {
public:
enum Kind {
PlaceholderKind,
DefinedKind,
CommonKind,
SharedKind,
UndefinedKind,
LazyKind,
};
Kind kind() const { return static_cast<Kind>(symbolKind); }
// The file from which this symbol was created.
InputFile *file;
// The default copy constructor is deleted due to atomic flags. Define one for
// places where no atomic is needed.
Symbol(const Symbol &o) { memcpy(this, &o, sizeof(o)); }
protected:
const char *nameData;
// 32-bit size saves space.
uint32_t nameSize;
public:
// The next three fields have the same meaning as the ELF symbol attributes.
// type and binding are placed in this order to optimize generating st_info,
// which is defined as (binding << 4) + (type & 0xf), on a little-endian
// system.
uint8_t type : 4; // symbol type
// Symbol binding. This is not overwritten by replace() to track
// changes during resolution. In particular:
// - An undefined weak is still weak when it resolves to a shared library.
// - An undefined weak will not extract archive members, but we have to
// remember it is weak.
uint8_t binding : 4;
uint8_t stOther; // st_other field value
uint8_t symbolKind;
// The partition whose dynamic symbol table contains this symbol's definition.
uint8_t partition;
// True if this symbol is preemptible at load time.
LLVM_PREFERRED_TYPE(bool)
uint8_t isPreemptible : 1;
// True if the symbol was used for linking and thus need to be added to the
// output file's symbol table. This is true for all symbols except for
// unreferenced DSO symbols, lazy (archive) symbols, and bitcode symbols that
// are unreferenced except by other bitcode objects.
LLVM_PREFERRED_TYPE(bool)
uint8_t isUsedInRegularObj : 1;
// True if an undefined or shared symbol is used from a live section.
//
// NOTE: In Writer.cpp the field is used to mark local defined symbols
// which are referenced by relocations when -r or --emit-relocs is given.
LLVM_PREFERRED_TYPE(bool)
uint8_t used : 1;
// Used by a Defined symbol with protected or default visibility, to record
// whether it is required to be exported into .dynsym. This is set when any of
// the following conditions hold:
//
// - If there is an interposable symbol from a DSO. Note: We also do this for
// STV_PROTECTED symbols which can't be interposed (to match BFD behavior).
// - If -shared or --export-dynamic is specified, any symbol in an object
// file/bitcode sets this property, unless suppressed by LTO
// canBeOmittedFromSymbolTable().
LLVM_PREFERRED_TYPE(bool)
uint8_t exportDynamic : 1;
// True if the symbol is in the --dynamic-list file. A Defined symbol with
// protected or default visibility with this property is required to be
// exported into .dynsym.
LLVM_PREFERRED_TYPE(bool)
uint8_t inDynamicList : 1;
// Used to track if there has been at least one undefined reference to the
// symbol. For Undefined and SharedSymbol, the binding may change to STB_WEAK
// if the first undefined reference from a non-shared object is weak.
LLVM_PREFERRED_TYPE(bool)
uint8_t referenced : 1;
// Used to track if this symbol will be referenced after wrapping is performed
// (i.e. this will be true for foo if __real_foo is referenced, and will be
// true for __wrap_foo if foo is referenced).
LLVM_PREFERRED_TYPE(bool)
uint8_t referencedAfterWrap : 1;
// True if this symbol is specified by --trace-symbol option.
LLVM_PREFERRED_TYPE(bool)
uint8_t traced : 1;
// True if the name contains '@'.
LLVM_PREFERRED_TYPE(bool)
uint8_t hasVersionSuffix : 1;
// Symbol visibility. This is the computed minimum visibility of all
// observed non-DSO symbols.
uint8_t visibility() const { return stOther & 3; }
void setVisibility(uint8_t visibility) {
stOther = (stOther & ~3) | visibility;
}
bool includeInDynsym() const;
uint8_t computeBinding() const;
bool isGlobal() const { return binding == llvm::ELF::STB_GLOBAL; }
bool isWeak() const { return binding == llvm::ELF::STB_WEAK; }
bool isUndefined() const { return symbolKind == UndefinedKind; }
bool isCommon() const { return symbolKind == CommonKind; }
bool isDefined() const { return symbolKind == DefinedKind; }
bool isShared() const { return symbolKind == SharedKind; }
bool isPlaceholder() const { return symbolKind == PlaceholderKind; }
bool isLocal() const { return binding == llvm::ELF::STB_LOCAL; }
bool isLazy() const { return symbolKind == LazyKind; }
// True if this is an undefined weak symbol. This only works once
// all input files have been added.
bool isUndefWeak() const { return isWeak() && isUndefined(); }
StringRef getName() const { return {nameData, nameSize}; }
void setName(StringRef s) {
nameData = s.data();
nameSize = s.size();
}
void parseSymbolVersion();
// Get the NUL-terminated version suffix ("", "@...", or "@@...").
//
// For @@, the name has been truncated by insert(). For @, the name has been
// truncated by Symbol::parseSymbolVersion().
const char *getVersionSuffix() const { return nameData + nameSize; }
uint32_t getGotIdx() const { return ctx.symAux[auxIdx].gotIdx; }
uint32_t getPltIdx() const { return ctx.symAux[auxIdx].pltIdx; }
uint32_t getTlsDescIdx() const { return ctx.symAux[auxIdx].tlsDescIdx; }
uint32_t getTlsGdIdx() const { return ctx.symAux[auxIdx].tlsGdIdx; }
bool isInGot() const { return getGotIdx() != uint32_t(-1); }
bool isInPlt() const { return getPltIdx() != uint32_t(-1); }
uint64_t getVA(int64_t addend = 0) const;
uint64_t getGotOffset() const;
uint64_t getGotVA() const;
uint64_t getGotPltOffset() const;
uint64_t getGotPltVA() const;
uint64_t getPltVA() const;
uint64_t getSize() const;
OutputSection *getOutputSection() const;
// The following two functions are used for symbol resolution.
//
// You are expected to call mergeProperties for all symbols in input
// files so that attributes that are attached to names rather than
// indivisual symbol (such as visibility) are merged together.
//
// Every time you read a new symbol from an input, you are supposed
// to call resolve() with the new symbol. That function replaces
// "this" object as a result of name resolution if the new symbol is
// more appropriate to be included in the output.
//
// For example, if "this" is an undefined symbol and a new symbol is
// a defined symbol, "this" is replaced with the new symbol.
void mergeProperties(const Symbol &other);
void resolve(const Undefined &other);
void resolve(const CommonSymbol &other);
void resolve(const Defined &other);
void resolve(const LazySymbol &other);
void resolve(const SharedSymbol &other);
// If this is a lazy symbol, extract an input file and add the symbol
// in the file to the symbol table. Calling this function on
// non-lazy object causes a runtime error.
void extract() const;
void checkDuplicate(const Defined &other) const;
private:
bool shouldReplace(const Defined &other) const;
protected:
Symbol(Kind k, InputFile *file, StringRef name, uint8_t binding,
uint8_t stOther, uint8_t type)
: file(file), nameData(name.data()), nameSize(name.size()), type(type),
binding(binding), stOther(stOther), symbolKind(k), exportDynamic(false),
archSpecificBit(false) {}
void overwrite(Symbol &sym, Kind k) const {
if (sym.traced)
printTraceSymbol(*this, sym.getName());
sym.file = file;
sym.type = type;
sym.binding = binding;
sym.stOther = (stOther & ~3) | sym.visibility();
sym.symbolKind = k;
}
public:
// True if this symbol is in the Iplt sub-section of the Plt and the Igot
// sub-section of the .got.plt or .got.
LLVM_PREFERRED_TYPE(bool)
uint8_t isInIplt : 1;
// True if this symbol needs a GOT entry and its GOT entry is actually in
// Igot. This will be true only for certain non-preemptible ifuncs.
LLVM_PREFERRED_TYPE(bool)
uint8_t gotInIgot : 1;
// True if defined relative to a section discarded by ICF.
LLVM_PREFERRED_TYPE(bool)
uint8_t folded : 1;
// Allow reuse of a bit between architecture-exclusive symbol flags.
// - needsTocRestore(): On PPC64, true if a call to this symbol needs to be
// followed by a restore of the toc pointer.
// - isTagged(): On AArch64, true if the symbol needs special relocation and
// metadata semantics because it's tagged, under the AArch64 MemtagABI.
LLVM_PREFERRED_TYPE(bool)
uint8_t archSpecificBit : 1;
bool needsTocRestore() const { return archSpecificBit; }
bool isTagged() const { return archSpecificBit; }
void setNeedsTocRestore(bool v) { archSpecificBit = v; }
void setIsTagged(bool v) {
archSpecificBit = v;
}
// True if this symbol is defined by a symbol assignment or wrapped by --wrap.
//
// LTO shouldn't inline the symbol because it doesn't know the final content
// of the symbol.
LLVM_PREFERRED_TYPE(bool)
uint8_t scriptDefined : 1;
// True if defined in a DSO. There may also be a definition in a relocatable
// object file.
LLVM_PREFERRED_TYPE(bool)
uint8_t dsoDefined : 1;
// True if defined in a DSO as protected visibility.
LLVM_PREFERRED_TYPE(bool)
uint8_t dsoProtected : 1;
// Temporary flags used to communicate which symbol entries need PLT and GOT
// entries during postScanRelocations();
std::atomic<uint16_t> flags;
// A ctx.symAux index used to access GOT/PLT entry indexes. This is allocated
// in postScanRelocations().
uint32_t auxIdx;
uint32_t dynsymIndex;
// If `file` is SharedFile (for SharedSymbol or copy-relocated Defined), this
// represents the Verdef index within the input DSO, which will be converted
// to a Verneed index in the output. Otherwise, this represents the Verdef
// index (VER_NDX_LOCAL, VER_NDX_GLOBAL, or a named version).
uint16_t versionId;
LLVM_PREFERRED_TYPE(bool)
uint8_t versionScriptAssigned : 1;
// True if targeted by a range extension thunk.
LLVM_PREFERRED_TYPE(bool)
uint8_t thunkAccessed : 1;
void setFlags(uint16_t bits) {
flags.fetch_or(bits, std::memory_order_relaxed);
}
bool hasFlag(uint16_t bit) const {
assert(bit && (bit & (bit - 1)) == 0 && "bit must be a power of 2");
return flags.load(std::memory_order_relaxed) & bit;
}
bool needsDynReloc() const {
return flags.load(std::memory_order_relaxed) &
(NEEDS_COPY | NEEDS_GOT | NEEDS_PLT | NEEDS_TLSDESC | NEEDS_TLSGD |
NEEDS_TLSGD_TO_IE | NEEDS_GOT_DTPREL | NEEDS_TLSIE);
}
void allocateAux() {
assert(auxIdx == 0);
auxIdx = ctx.symAux.size();
ctx.symAux.emplace_back();
}
bool isSection() const { return type == llvm::ELF::STT_SECTION; }
bool isTls() const { return type == llvm::ELF::STT_TLS; }
bool isFunc() const { return type == llvm::ELF::STT_FUNC; }
bool isGnuIFunc() const { return type == llvm::ELF::STT_GNU_IFUNC; }
bool isObject() const { return type == llvm::ELF::STT_OBJECT; }
bool isFile() const { return type == llvm::ELF::STT_FILE; }
};
// Represents a symbol that is defined in the current output file.
class Defined : public Symbol {
public:
Defined(InputFile *file, StringRef name, uint8_t binding, uint8_t stOther,
uint8_t type, uint64_t value, uint64_t size, SectionBase *section)
: Symbol(DefinedKind, file, name, binding, stOther, type), value(value),
size(size), section(section) {
exportDynamic = config->exportDynamic;
}
void overwrite(Symbol &sym) const;
static bool classof(const Symbol *s) { return s->isDefined(); }
uint64_t value;
uint64_t size;
SectionBase *section;
};
// Represents a common symbol.
//
// On Unix, it is traditionally allowed to write variable definitions
// without initialization expressions (such as "int foo;") to header
// files. Such definition is called "tentative definition".
//
// Using tentative definition is usually considered a bad practice
// because you should write only declarations (such as "extern int
// foo;") to header files. Nevertheless, the linker and the compiler
// have to do something to support bad code by allowing duplicate
// definitions for this particular case.
//
// Common symbols represent variable definitions without initializations.
// The compiler creates common symbols when it sees variable definitions
// without initialization (you can suppress this behavior and let the
// compiler create a regular defined symbol by -fno-common).
//
// The linker allows common symbols to be replaced by regular defined
// symbols. If there are remaining common symbols after name resolution is
// complete, they are converted to regular defined symbols in a .bss
// section. (Therefore, the later passes don't see any CommonSymbols.)
class CommonSymbol : public Symbol {
public:
CommonSymbol(InputFile *file, StringRef name, uint8_t binding,
uint8_t stOther, uint8_t type, uint64_t alignment, uint64_t size)
: Symbol(CommonKind, file, name, binding, stOther, type),
alignment(alignment), size(size) {
exportDynamic = config->exportDynamic;
}
void overwrite(Symbol &sym) const {
Symbol::overwrite(sym, CommonKind);
auto &s = static_cast<CommonSymbol &>(sym);
s.alignment = alignment;
s.size = size;
}
static bool classof(const Symbol *s) { return s->isCommon(); }
uint32_t alignment;
uint64_t size;
};
class Undefined : public Symbol {
public:
Undefined(InputFile *file, StringRef name, uint8_t binding, uint8_t stOther,
uint8_t type, uint32_t discardedSecIdx = 0)
: Symbol(UndefinedKind, file, name, binding, stOther, type),
discardedSecIdx(discardedSecIdx) {}
void overwrite(Symbol &sym) const {
Symbol::overwrite(sym, UndefinedKind);
auto &s = static_cast<Undefined &>(sym);
s.discardedSecIdx = discardedSecIdx;
s.nonPrevailing = nonPrevailing;
}
static bool classof(const Symbol *s) { return s->kind() == UndefinedKind; }
// The section index if in a discarded section, 0 otherwise.
uint32_t discardedSecIdx;
bool nonPrevailing = false;
};
class SharedSymbol : public Symbol {
public:
static bool classof(const Symbol *s) { return s->kind() == SharedKind; }
SharedSymbol(InputFile &file, StringRef name, uint8_t binding,
uint8_t stOther, uint8_t type, uint64_t value, uint64_t size,
uint32_t alignment)
: Symbol(SharedKind, &file, name, binding, stOther, type), value(value),
size(size), alignment(alignment) {
exportDynamic = true;
dsoProtected = visibility() == llvm::ELF::STV_PROTECTED;
// GNU ifunc is a mechanism to allow user-supplied functions to
// resolve PLT slot values at load-time. This is contrary to the
// regular symbol resolution scheme in which symbols are resolved just
// by name. Using this hook, you can program how symbols are solved
// for you program. For example, you can make "memcpy" to be resolved
// to a SSE-enabled version of memcpy only when a machine running the
// program supports the SSE instruction set.
//
// Naturally, such symbols should always be called through their PLT
// slots. What GNU ifunc symbols point to are resolver functions, and
// calling them directly doesn't make sense (unless you are writing a
// loader).
//
// For DSO symbols, we always call them through PLT slots anyway.
// So there's no difference between GNU ifunc and regular function
// symbols if they are in DSOs. So we can handle GNU_IFUNC as FUNC.
if (this->type == llvm::ELF::STT_GNU_IFUNC)
this->type = llvm::ELF::STT_FUNC;
}
void overwrite(Symbol &sym) const {
Symbol::overwrite(sym, SharedKind);
auto &s = static_cast<SharedSymbol &>(sym);
s.dsoProtected = dsoProtected;
s.value = value;
s.size = size;
s.alignment = alignment;
}
uint64_t value; // st_value
uint64_t size; // st_size
uint32_t alignment;
};
// LazySymbol symbols represent symbols in object files between --start-lib and
// --end-lib options. LLD also handles traditional archives as if all the files
// in the archive are surrounded by --start-lib and --end-lib.
//
// A special complication is the handling of weak undefined symbols. They should
// not load a file, but we have to remember we have seen both the weak undefined
// and the lazy. We represent that with a lazy symbol with a weak binding. This
// means that code looking for undefined symbols normally also has to take lazy
// symbols into consideration.
class LazySymbol : public Symbol {
public:
LazySymbol(InputFile &file)
: Symbol(LazyKind, &file, {}, llvm::ELF::STB_GLOBAL,
llvm::ELF::STV_DEFAULT, llvm::ELF::STT_NOTYPE) {}
void overwrite(Symbol &sym) const { Symbol::overwrite(sym, LazyKind); }
static bool classof(const Symbol *s) { return s->kind() == LazyKind; }
};
// A buffer class that is large enough to hold any Symbol-derived
// object. We allocate memory using this class and instantiate a symbol
// using the placement new.
// It is important to keep the size of SymbolUnion small for performance and
// memory usage reasons. 64 bytes is a soft limit based on the size of Defined
// on a 64-bit system. This is enforced by a static_assert in Symbols.cpp.
union SymbolUnion {
alignas(Defined) char a[sizeof(Defined)];
alignas(CommonSymbol) char b[sizeof(CommonSymbol)];
alignas(Undefined) char c[sizeof(Undefined)];
alignas(SharedSymbol) char d[sizeof(SharedSymbol)];
alignas(LazySymbol) char e[sizeof(LazySymbol)];
};
template <typename... T> Defined *makeDefined(T &&...args) {
auto *sym = getSpecificAllocSingleton<SymbolUnion>().Allocate();
memset(sym, 0, sizeof(Symbol));
auto &s = *new (reinterpret_cast<Defined *>(sym)) Defined(std::forward<T>(args)...);
return &s;
}
void reportDuplicate(const Symbol &sym, const InputFile *newFile,
InputSectionBase *errSec, uint64_t errOffset);
void maybeWarnUnorderableSymbol(const Symbol *sym);
bool computeIsPreemptible(const Symbol &sym);
} // namespace elf
} // namespace lld
#endif