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llvm-capstone/lld/MachO/Symbols.h
Jez Ng 002eda7056 [lld-macho] Associate compact unwind entries with function symbols 
Compact unwind entries (CUEs) contain pointers to their respective
function symbols. However, during the link process, it's far more useful
to have pointers from the function symbol to the CUE than vice versa.
This diff adds that pointer in the form of `Defined::compactUnwind`.

In particular, when doing dead-stripping, we want to mark CUEs live when
their function symbol is live; and when doing ICF, we want to dedup
sections iff the symbols in that section have identical CUEs. In both
cases, we want to be able to locate the symbols within a given section,
as well as locate the CUEs belonging to those symbols. So this diff also
adds `InputSection::symbols`.

The ultimate goal of this refactor is to have ICF support dedup'ing
functions with unwind info, but that will be handled in subsequent
diffs. This diff focuses on simplifying `-dead_strip` --
`findFunctionsWithUnwindInfo` is no longer necessary, and
`Defined::isLive()` is now a lot simpler. Moreover, UnwindInfoSection no
longer has to check for dead CUEs -- we simply avoid adding them in the
first place.

Additionally, we now support stripping of dead LSDAs, which follows
quite naturally since `markLive()` can now reach them via the CUEs.

Reviewed By: #lld-macho, gkm

Differential Revision: https://reviews.llvm.org/D109944
2021-10-26 16:04:15 -04:00

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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
//
//===----------------------------------------------------------------------===//
#ifndef LLD_MACHO_SYMBOLS_H
#define LLD_MACHO_SYMBOLS_H
#include "Config.h"
#include "InputFiles.h"
#include "Target.h"
#include "lld/Common/ErrorHandler.h"
#include "lld/Common/Strings.h"
#include "llvm/Object/Archive.h"
#include "llvm/Support/MathExtras.h"
namespace lld {
namespace macho {
class MachHeaderSection;
struct StringRefZ {
StringRefZ(const char *s) : data(s), size(-1) {}
StringRefZ(StringRef s) : data(s.data()), size(s.size()) {}
const char *data;
const uint32_t size;
};
class Symbol {
public:
enum Kind {
DefinedKind,
UndefinedKind,
CommonKind,
DylibKind,
LazyKind,
};
virtual ~Symbol() {}
Kind kind() const { return symbolKind; }
StringRef getName() const {
if (nameSize == (uint32_t)-1)
nameSize = strlen(nameData);
return {nameData, nameSize};
}
bool isLive() const { return used; }
virtual uint64_t getVA() const { return 0; }
virtual bool isWeakDef() const { llvm_unreachable("cannot be weak def"); }
// Only undefined or dylib symbols can be weak references. A weak reference
// need not be satisfied at runtime, e.g. due to the symbol not being
// available on a given target platform.
virtual bool isWeakRef() const { llvm_unreachable("cannot be a weak ref"); }
virtual bool isTlv() const { llvm_unreachable("cannot be TLV"); }
// Whether this symbol is in the GOT or TLVPointer sections.
bool isInGot() const { return gotIndex != UINT32_MAX; }
// Whether this symbol is in the StubsSection.
bool isInStubs() const { return stubsIndex != UINT32_MAX; }
uint64_t getStubVA() const;
uint64_t getGotVA() const;
uint64_t getTlvVA() const;
uint64_t resolveBranchVA() const {
assert(isa<Defined>(this) || isa<DylibSymbol>(this));
return isInStubs() ? getStubVA() : getVA();
}
uint64_t resolveGotVA() const { return isInGot() ? getGotVA() : getVA(); }
uint64_t resolveTlvVA() const { return isInGot() ? getTlvVA() : getVA(); }
// The index of this symbol in the GOT or the TLVPointer section, depending
// on whether it is a thread-local. A given symbol cannot be referenced by
// both these sections at once.
uint32_t gotIndex = UINT32_MAX;
uint32_t stubsIndex = UINT32_MAX;
uint32_t symtabIndex = UINT32_MAX;
InputFile *getFile() const { return file; }
protected:
Symbol(Kind k, StringRefZ name, InputFile *file)
: symbolKind(k), nameData(name.data), nameSize(name.size), file(file),
isUsedInRegularObj(!file || isa<ObjFile>(file)),
used(!config->deadStrip) {}
Kind symbolKind;
const char *nameData;
mutable uint32_t nameSize;
InputFile *file;
public:
// True if this symbol was referenced by a regular (non-bitcode) object.
bool isUsedInRegularObj : 1;
// True if an undefined or dylib symbol is used from a live section.
bool used : 1;
};
class Defined : public Symbol {
public:
Defined(StringRefZ name, InputFile *file, InputSection *isec, uint64_t value,
uint64_t size, bool isWeakDef, bool isExternal, bool isPrivateExtern,
bool isThumb, bool isReferencedDynamically, bool noDeadStrip);
bool isWeakDef() const override { return weakDef; }
bool isExternalWeakDef() const {
return isWeakDef() && isExternal() && !privateExtern;
}
bool isTlv() const override;
bool isExternal() const { return external; }
bool isAbsolute() const { return isec == nullptr; }
uint64_t getVA() const override;
static bool classof(const Symbol *s) { return s->kind() == DefinedKind; }
InputSection *isec;
// Contains the offset from the containing subsection. Note that this is
// different from nlist::n_value, which is the absolute address of the symbol.
uint64_t value;
// size is only calculated for regular (non-bitcode) symbols.
uint64_t size;
ConcatInputSection *compactUnwind = nullptr;
bool overridesWeakDef : 1;
// Whether this symbol should appear in the output binary's export trie.
bool privateExtern : 1;
// Whether this symbol should appear in the output symbol table.
bool includeInSymtab : 1;
// Only relevant when compiling for Thumb-supporting arm32 archs.
bool thumb : 1;
// Symbols marked referencedDynamically won't be removed from the output's
// symbol table by tools like strip. In theory, this could be set on arbitrary
// symbols in input object files. In practice, it's used solely for the
// synthetic __mh_execute_header symbol.
// This is information for the static linker, and it's also written to the
// output file's symbol table for tools running later (such as `strip`).
bool referencedDynamically : 1;
// Set on symbols that should not be removed by dead code stripping.
// Set for example on `__attribute__((used))` globals, or on some Objective-C
// metadata. This is information only for the static linker and not written
// to the output.
bool noDeadStrip : 1;
private:
const bool weakDef : 1;
const bool external : 1;
};
// This enum does double-duty: as a symbol property, it indicates whether & how
// a dylib symbol is referenced. As a DylibFile property, it indicates the kind
// of referenced symbols contained within the file. If there are both weak
// and strong references to the same file, we will count the file as
// strongly-referenced.
enum class RefState : uint8_t { Unreferenced = 0, Weak = 1, Strong = 2 };
class Undefined : public Symbol {
public:
Undefined(StringRefZ name, InputFile *file, RefState refState)
: Symbol(UndefinedKind, name, file), refState(refState) {
assert(refState != RefState::Unreferenced);
}
bool isWeakRef() const override { return refState == RefState::Weak; }
static bool classof(const Symbol *s) { return s->kind() == UndefinedKind; }
RefState refState : 2;
};
// On Unix, it is traditionally allowed to write variable definitions without
// initialization expressions (such as "int foo;") to header files. These are
// called tentative definitions.
//
// Using tentative definitions is usually considered a bad practice; 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.
//
// The compiler creates common symbols when it sees tentative definitions.
// (You can suppress this behavior and let the compiler create a regular
// defined symbol by passing -fno-common. -fno-common is the default in clang
// as of LLVM 11.0.) When linking the final binary, if there are remaining
// common symbols after name resolution is complete, the linker converts them
// to regular defined symbols in a __common section.
class CommonSymbol : public Symbol {
public:
CommonSymbol(StringRefZ name, InputFile *file, uint64_t size, uint32_t align,
bool isPrivateExtern)
: Symbol(CommonKind, name, file), size(size),
align(align != 1 ? align : llvm::PowerOf2Ceil(size)),
privateExtern(isPrivateExtern) {
// TODO: cap maximum alignment
}
static bool classof(const Symbol *s) { return s->kind() == CommonKind; }
const uint64_t size;
const uint32_t align;
const bool privateExtern;
};
class DylibSymbol : public Symbol {
public:
DylibSymbol(DylibFile *file, StringRefZ name, bool isWeakDef,
RefState refState, bool isTlv)
: Symbol(DylibKind, name, file), refState(refState), weakDef(isWeakDef),
tlv(isTlv) {
if (file && refState > RefState::Unreferenced)
file->numReferencedSymbols++;
}
uint64_t getVA() const override;
bool isWeakDef() const override { return weakDef; }
bool isWeakRef() const override { return refState == RefState::Weak; }
bool isReferenced() const { return refState != RefState::Unreferenced; }
bool isTlv() const override { return tlv; }
bool isDynamicLookup() const { return file == nullptr; }
bool hasStubsHelper() const { return stubsHelperIndex != UINT32_MAX; }
DylibFile *getFile() const {
assert(!isDynamicLookup());
return cast<DylibFile>(file);
}
static bool classof(const Symbol *s) { return s->kind() == DylibKind; }
uint32_t stubsHelperIndex = UINT32_MAX;
uint32_t lazyBindOffset = UINT32_MAX;
RefState getRefState() const { return refState; }
void reference(RefState newState) {
assert(newState > RefState::Unreferenced);
if (refState == RefState::Unreferenced && file)
getFile()->numReferencedSymbols++;
refState = std::max(refState, newState);
}
void unreference() {
// dynamic_lookup symbols have no file.
if (refState > RefState::Unreferenced && file) {
assert(getFile()->numReferencedSymbols > 0);
getFile()->numReferencedSymbols--;
}
}
private:
RefState refState : 2;
const bool weakDef : 1;
const bool tlv : 1;
};
class LazySymbol : public Symbol {
public:
LazySymbol(ArchiveFile *file, const llvm::object::Archive::Symbol &sym)
: Symbol(LazyKind, sym.getName(), file), sym(sym) {}
ArchiveFile *getFile() const { return cast<ArchiveFile>(file); }
void fetchArchiveMember();
static bool classof(const Symbol *s) { return s->kind() == LazyKind; }
private:
const llvm::object::Archive::Symbol sym;
};
union SymbolUnion {
alignas(Defined) char a[sizeof(Defined)];
alignas(Undefined) char b[sizeof(Undefined)];
alignas(CommonSymbol) char c[sizeof(CommonSymbol)];
alignas(DylibSymbol) char d[sizeof(DylibSymbol)];
alignas(LazySymbol) char e[sizeof(LazySymbol)];
};
template <typename T, typename... ArgT>
T *replaceSymbol(Symbol *s, ArgT &&...arg) {
static_assert(sizeof(T) <= sizeof(SymbolUnion), "SymbolUnion too small");
static_assert(alignof(T) <= alignof(SymbolUnion),
"SymbolUnion not aligned enough");
assert(static_cast<Symbol *>(static_cast<T *>(nullptr)) == nullptr &&
"Not a Symbol");
bool isUsedInRegularObj = s->isUsedInRegularObj;
bool used = s->used;
T *sym = new (s) T(std::forward<ArgT>(arg)...);
sym->isUsedInRegularObj |= isUsedInRegularObj;
sym->used |= used;
return sym;
}
} // namespace macho
std::string toString(const macho::Symbol &);
std::string toMachOString(const llvm::object::Archive::Symbol &);
} // namespace lld
#endif
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