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llvm-project/lld/lib/ReaderWriter/MachO/MachONormalizedFileToAtoms.cpp

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//===- lib/ReaderWriter/MachO/MachONormalizedFileToAtoms.cpp --------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file Converts from in-memory normalized mach-o to in-memory Atoms.
///
/// +------------+
/// | normalized |
/// +------------+
/// |
/// |
/// v
/// +-------+
/// | Atoms |
/// +-------+
#include "ArchHandler.h"
#include "Atoms.h"
#include "File.h"
#include "MachONormalizedFile.h"
#include "MachONormalizedFileBinaryUtils.h"
#include "lld/Common/LLVM.h"
#include "lld/Core/Error.h"
#include "llvm/BinaryFormat/Dwarf.h"
#include "llvm/BinaryFormat/MachO.h"
#include "llvm/DebugInfo/DWARF/DWARFFormValue.h"
#include "llvm/Support/DataExtractor.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/Error.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/LEB128.h"
#include "llvm/Support/raw_ostream.h"
using namespace llvm::MachO;
using namespace lld::mach_o::normalized;
#define DEBUG_TYPE "normalized-file-to-atoms"
namespace lld {
namespace mach_o {
namespace { // anonymous
#define ENTRY(seg, sect, type, atomType) \
{seg, sect, type, DefinedAtom::atomType }
struct MachORelocatableSectionToAtomType {
StringRef segmentName;
StringRef sectionName;
SectionType sectionType;
DefinedAtom::ContentType atomType;
};
const MachORelocatableSectionToAtomType sectsToAtomType[] = {
ENTRY("__TEXT", "__text", S_REGULAR, typeCode),
ENTRY("__TEXT", "__text", S_REGULAR, typeResolver),
ENTRY("__TEXT", "__cstring", S_CSTRING_LITERALS, typeCString),
ENTRY("", "", S_CSTRING_LITERALS, typeCString),
ENTRY("__TEXT", "__ustring", S_REGULAR, typeUTF16String),
ENTRY("__TEXT", "__const", S_REGULAR, typeConstant),
ENTRY("__TEXT", "__const_coal", S_COALESCED, typeConstant),
ENTRY("__TEXT", "__eh_frame", S_COALESCED, typeCFI),
ENTRY("__TEXT", "__eh_frame", S_REGULAR, typeCFI),
ENTRY("__TEXT", "__literal4", S_4BYTE_LITERALS, typeLiteral4),
ENTRY("__TEXT", "__literal8", S_8BYTE_LITERALS, typeLiteral8),
ENTRY("__TEXT", "__literal16", S_16BYTE_LITERALS, typeLiteral16),
ENTRY("__TEXT", "__gcc_except_tab", S_REGULAR, typeLSDA),
ENTRY("__DATA", "__data", S_REGULAR, typeData),
ENTRY("__DATA", "__datacoal_nt", S_COALESCED, typeData),
ENTRY("__DATA", "__const", S_REGULAR, typeConstData),
ENTRY("__DATA", "__cfstring", S_REGULAR, typeCFString),
ENTRY("__DATA", "__mod_init_func", S_MOD_INIT_FUNC_POINTERS,
typeInitializerPtr),
ENTRY("__DATA", "__mod_term_func", S_MOD_TERM_FUNC_POINTERS,
typeTerminatorPtr),
ENTRY("__DATA", "__got", S_NON_LAZY_SYMBOL_POINTERS,
typeGOT),
ENTRY("__DATA", "__bss", S_ZEROFILL, typeZeroFill),
ENTRY("", "", S_NON_LAZY_SYMBOL_POINTERS,
typeGOT),
ENTRY("__DATA", "__interposing", S_INTERPOSING, typeInterposingTuples),
ENTRY("__DATA", "__thread_vars", S_THREAD_LOCAL_VARIABLES,
typeThunkTLV),
ENTRY("__DATA", "__thread_data", S_THREAD_LOCAL_REGULAR, typeTLVInitialData),
ENTRY("__DATA", "__thread_bss", S_THREAD_LOCAL_ZEROFILL,
typeTLVInitialZeroFill),
ENTRY("__DATA", "__objc_imageinfo", S_REGULAR, typeObjCImageInfo),
ENTRY("__DATA", "__objc_catlist", S_REGULAR, typeObjC2CategoryList),
ENTRY("", "", S_INTERPOSING, typeInterposingTuples),
ENTRY("__LD", "__compact_unwind", S_REGULAR,
typeCompactUnwindInfo),
ENTRY("", "", S_REGULAR, typeUnknown)
};
#undef ENTRY
/// Figures out ContentType of a mach-o section.
DefinedAtom::ContentType atomTypeFromSection(const Section &section,
bool &customSectionName) {
// First look for match of name and type. Empty names in table are wildcards.
customSectionName = false;
for (const MachORelocatableSectionToAtomType *p = sectsToAtomType ;
p->atomType != DefinedAtom::typeUnknown; ++p) {
if (p->sectionType != section.type)
continue;
if (!p->segmentName.equals(section.segmentName) && !p->segmentName.empty())
continue;
if (!p->sectionName.equals(section.sectionName) && !p->sectionName.empty())
continue;
customSectionName = p->segmentName.empty() && p->sectionName.empty();
return p->atomType;
}
// Look for code denoted by section attributes
if (section.attributes & S_ATTR_PURE_INSTRUCTIONS)
return DefinedAtom::typeCode;
return DefinedAtom::typeUnknown;
}
enum AtomizeModel {
atomizeAtSymbols,
atomizeFixedSize,
atomizePointerSize,
atomizeUTF8,
atomizeUTF16,
atomizeCFI,
atomizeCU,
atomizeCFString
};
/// Returns info on how to atomize a section of the specified ContentType.
void sectionParseInfo(DefinedAtom::ContentType atomType,
unsigned int &sizeMultiple,
DefinedAtom::Scope &scope,
DefinedAtom::Merge &merge,
AtomizeModel &atomizeModel) {
struct ParseInfo {
DefinedAtom::ContentType atomType;
unsigned int sizeMultiple;
DefinedAtom::Scope scope;
DefinedAtom::Merge merge;
AtomizeModel atomizeModel;
};
#define ENTRY(type, size, scope, merge, model) \
{DefinedAtom::type, size, DefinedAtom::scope, DefinedAtom::merge, model }
static const ParseInfo parseInfo[] = {
ENTRY(typeCode, 1, scopeGlobal, mergeNo,
atomizeAtSymbols),
ENTRY(typeData, 1, scopeGlobal, mergeNo,
atomizeAtSymbols),
ENTRY(typeConstData, 1, scopeGlobal, mergeNo,
atomizeAtSymbols),
ENTRY(typeZeroFill, 1, scopeGlobal, mergeNo,
atomizeAtSymbols),
ENTRY(typeConstant, 1, scopeGlobal, mergeNo,
atomizeAtSymbols),
ENTRY(typeCString, 1, scopeLinkageUnit, mergeByContent,
atomizeUTF8),
ENTRY(typeUTF16String, 1, scopeLinkageUnit, mergeByContent,
atomizeUTF16),
ENTRY(typeCFI, 4, scopeTranslationUnit, mergeNo,
atomizeCFI),
ENTRY(typeLiteral4, 4, scopeLinkageUnit, mergeByContent,
atomizeFixedSize),
ENTRY(typeLiteral8, 8, scopeLinkageUnit, mergeByContent,
atomizeFixedSize),
ENTRY(typeLiteral16, 16, scopeLinkageUnit, mergeByContent,
atomizeFixedSize),
ENTRY(typeCFString, 4, scopeLinkageUnit, mergeByContent,
atomizeCFString),
ENTRY(typeInitializerPtr, 4, scopeTranslationUnit, mergeNo,
atomizePointerSize),
ENTRY(typeTerminatorPtr, 4, scopeTranslationUnit, mergeNo,
atomizePointerSize),
ENTRY(typeCompactUnwindInfo, 4, scopeTranslationUnit, mergeNo,
atomizeCU),
ENTRY(typeGOT, 4, scopeLinkageUnit, mergeByContent,
atomizePointerSize),
ENTRY(typeObjC2CategoryList, 4, scopeTranslationUnit, mergeByContent,
atomizePointerSize),
ENTRY(typeUnknown, 1, scopeGlobal, mergeNo,
atomizeAtSymbols)
};
#undef ENTRY
const int tableLen = sizeof(parseInfo) / sizeof(ParseInfo);
for (int i=0; i < tableLen; ++i) {
if (parseInfo[i].atomType == atomType) {
sizeMultiple = parseInfo[i].sizeMultiple;
scope = parseInfo[i].scope;
merge = parseInfo[i].merge;
atomizeModel = parseInfo[i].atomizeModel;
return;
}
}
// Unknown type is atomized by symbols.
sizeMultiple = 1;
scope = DefinedAtom::scopeGlobal;
merge = DefinedAtom::mergeNo;
atomizeModel = atomizeAtSymbols;
}
Atom::Scope atomScope(uint8_t scope) {
switch (scope) {
case N_EXT:
return Atom::scopeGlobal;
case N_PEXT:
case N_PEXT | N_EXT:
return Atom::scopeLinkageUnit;
case 0:
return Atom::scopeTranslationUnit;
}
llvm_unreachable("unknown scope value!");
}
void appendSymbolsInSection(const std::vector<Symbol> &inSymbols,
uint32_t sectionIndex,
SmallVector<const Symbol *, 64> &outSyms) {
for (const Symbol &sym : inSymbols) {
// Only look at definition symbols.
if ((sym.type & N_TYPE) != N_SECT)
continue;
if (sym.sect != sectionIndex)
continue;
outSyms.push_back(&sym);
}
}
void atomFromSymbol(DefinedAtom::ContentType atomType, const Section &section,
MachOFile &file, uint64_t symbolAddr, StringRef symbolName,
uint16_t symbolDescFlags, Atom::Scope symbolScope,
uint64_t nextSymbolAddr, bool scatterable, bool copyRefs) {
// Mach-O symbol table does have size in it. Instead the size is the
// difference between this and the next symbol.
uint64_t size = nextSymbolAddr - symbolAddr;
uint64_t offset = symbolAddr - section.address;
bool noDeadStrip = (symbolDescFlags & N_NO_DEAD_STRIP) || !scatterable;
if (isZeroFillSection(section.type)) {
file.addZeroFillDefinedAtom(symbolName, symbolScope, offset, size,
noDeadStrip, copyRefs, &section);
} else {
DefinedAtom::Merge merge = (symbolDescFlags & N_WEAK_DEF)
? DefinedAtom::mergeAsWeak : DefinedAtom::mergeNo;
bool thumb = (symbolDescFlags & N_ARM_THUMB_DEF);
if (atomType == DefinedAtom::typeUnknown) {
// Mach-O needs a segment and section name. Concatentate those two
// with a / separator (e.g. "seg/sect") to fit into the lld model
// of just a section name.
std::string segSectName = section.segmentName.str()
+ "/" + section.sectionName.str();
file.addDefinedAtomInCustomSection(symbolName, symbolScope, atomType,
merge, thumb, noDeadStrip, offset,
size, segSectName, true, &section);
} else {
if ((atomType == lld::DefinedAtom::typeCode) &&
(symbolDescFlags & N_SYMBOL_RESOLVER)) {
atomType = lld::DefinedAtom::typeResolver;
}
file.addDefinedAtom(symbolName, symbolScope, atomType, merge,
offset, size, thumb, noDeadStrip, copyRefs, &section);
}
}
}
llvm::Error processSymboledSection(DefinedAtom::ContentType atomType,
const Section &section,
const NormalizedFile &normalizedFile,
MachOFile &file, bool scatterable,
bool copyRefs) {
// Find section's index.
uint32_t sectIndex = 1;
for (auto &sect : normalizedFile.sections) {
if (&sect == &section)
break;
++sectIndex;
}
// Find all symbols in this section.
SmallVector<const Symbol *, 64> symbols;
appendSymbolsInSection(normalizedFile.globalSymbols, sectIndex, symbols);
appendSymbolsInSection(normalizedFile.localSymbols, sectIndex, symbols);
// Sort symbols.
std::sort(symbols.begin(), symbols.end(),
[](const Symbol *lhs, const Symbol *rhs) -> bool {
if (lhs == rhs)
return false;
// First by address.
uint64_t lhsAddr = lhs->value;
uint64_t rhsAddr = rhs->value;
if (lhsAddr != rhsAddr)
return lhsAddr < rhsAddr;
// If same address, one is an alias so sort by scope.
Atom::Scope lScope = atomScope(lhs->scope);
Atom::Scope rScope = atomScope(rhs->scope);
if (lScope != rScope)
return lScope < rScope;
// If same address and scope, see if one might be better as
// the alias.
bool lPrivate = (lhs->name.front() == 'l');
bool rPrivate = (rhs->name.front() == 'l');
if (lPrivate != rPrivate)
return lPrivate;
// If same address and scope, sort by name.
return lhs->name < rhs->name;
});
// Debug logging of symbols.
//for (const Symbol *sym : symbols)
// llvm::errs() << " sym: "
// << llvm::format("0x%08llx ", (uint64_t)sym->value)
// << ", " << sym->name << "\n";
// If section has no symbols and no content, there are no atoms.
if (symbols.empty() && section.content.empty())
return llvm::Error::success();
if (symbols.empty()) {
// Section has no symbols, put all content in one anoymous atom.
atomFromSymbol(atomType, section, file, section.address, StringRef(),
0, Atom::scopeTranslationUnit,
section.address + section.content.size(),
scatterable, copyRefs);
}
else if (symbols.front()->value != section.address) {
// Section has anonymous content before first symbol.
atomFromSymbol(atomType, section, file, section.address, StringRef(),
0, Atom::scopeTranslationUnit, symbols.front()->value,
scatterable, copyRefs);
}
const Symbol *lastSym = nullptr;
for (const Symbol *sym : symbols) {
if (lastSym != nullptr) {
// Ignore any assembler added "ltmpNNN" symbol at start of section
// if there is another symbol at the start.
if ((lastSym->value != sym->value)
|| lastSym->value != section.address
|| !lastSym->name.startswith("ltmp")) {
atomFromSymbol(atomType, section, file, lastSym->value, lastSym->name,
lastSym->desc, atomScope(lastSym->scope), sym->value,
scatterable, copyRefs);
}
}
lastSym = sym;
}
if (lastSym != nullptr) {
atomFromSymbol(atomType, section, file, lastSym->value, lastSym->name,
lastSym->desc, atomScope(lastSym->scope),
section.address + section.content.size(),
scatterable, copyRefs);
}
// If object built without .subsections_via_symbols, add reference chain.
if (!scatterable) {
MachODefinedAtom *prevAtom = nullptr;
file.eachAtomInSection(section,
[&](MachODefinedAtom *atom, uint64_t offset)->void {
if (prevAtom)
prevAtom->addReference(Reference::KindNamespace::all,
Reference::KindArch::all,
Reference::kindLayoutAfter, 0, atom, 0);
prevAtom = atom;
});
}
return llvm::Error::success();
}
llvm::Error processSection(DefinedAtom::ContentType atomType,
const Section &section,
bool customSectionName,
const NormalizedFile &normalizedFile,
MachOFile &file, bool scatterable,
bool copyRefs) {
const bool is64 = MachOLinkingContext::is64Bit(normalizedFile.arch);
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
// Get info on how to atomize section.
unsigned int sizeMultiple;
DefinedAtom::Scope scope;
DefinedAtom::Merge merge;
AtomizeModel atomizeModel;
sectionParseInfo(atomType, sizeMultiple, scope, merge, atomizeModel);
// Validate section size.
if ((section.content.size() % sizeMultiple) != 0)
return llvm::make_error<GenericError>(Twine("Section ")
+ section.segmentName
+ "/" + section.sectionName
+ " has size ("
+ Twine(section.content.size())
+ ") which is not a multiple of "
+ Twine(sizeMultiple));
if (atomizeModel == atomizeAtSymbols) {
// Break section up into atoms each with a fixed size.
return processSymboledSection(atomType, section, normalizedFile, file,
scatterable, copyRefs);
} else {
unsigned int size;
for (unsigned int offset = 0, e = section.content.size(); offset != e;) {
switch (atomizeModel) {
case atomizeFixedSize:
// Break section up into atoms each with a fixed size.
size = sizeMultiple;
break;
case atomizePointerSize:
// Break section up into atoms each the size of a pointer.
size = is64 ? 8 : 4;
break;
case atomizeUTF8:
// Break section up into zero terminated c-strings.
size = 0;
for (unsigned int i = offset; i < e; ++i) {
if (section.content[i] == 0) {
size = i + 1 - offset;
break;
}
}
break;
case atomizeUTF16:
// Break section up into zero terminated UTF16 strings.
size = 0;
for (unsigned int i = offset; i < e; i += 2) {
if ((section.content[i] == 0) && (section.content[i + 1] == 0)) {
size = i + 2 - offset;
break;
}
}
break;
case atomizeCFI:
// Break section up into dwarf unwind CFIs (FDE or CIE).
size = read32(&section.content[offset], isBig) + 4;
if (offset+size > section.content.size()) {
return llvm::make_error<GenericError>(Twine("Section ")
+ section.segmentName
+ "/" + section.sectionName
+ " is malformed. Size of CFI "
"starting at offset ("
+ Twine(offset)
+ ") is past end of section.");
}
break;
case atomizeCU:
// Break section up into compact unwind entries.
size = is64 ? 32 : 20;
break;
case atomizeCFString:
// Break section up into NS/CFString objects.
size = is64 ? 32 : 16;
break;
case atomizeAtSymbols:
break;
}
if (size == 0) {
return llvm::make_error<GenericError>(Twine("Section ")
+ section.segmentName
+ "/" + section.sectionName
+ " is malformed. The last atom "
"is not zero terminated.");
}
if (customSectionName) {
// Mach-O needs a segment and section name. Concatentate those two
// with a / separator (e.g. "seg/sect") to fit into the lld model
// of just a section name.
std::string segSectName = section.segmentName.str()
+ "/" + section.sectionName.str();
file.addDefinedAtomInCustomSection(StringRef(), scope, atomType,
merge, false, false, offset,
size, segSectName, true, &section);
} else {
file.addDefinedAtom(StringRef(), scope, atomType, merge, offset, size,
false, false, copyRefs, &section);
}
offset += size;
}
}
return llvm::Error::success();
}
const Section* findSectionCoveringAddress(const NormalizedFile &normalizedFile,
uint64_t address) {
for (const Section &s : normalizedFile.sections) {
uint64_t sAddr = s.address;
if ((sAddr <= address) && (address < sAddr+s.content.size())) {
return &s;
}
}
return nullptr;
}
const MachODefinedAtom *
findAtomCoveringAddress(const NormalizedFile &normalizedFile, MachOFile &file,
uint64_t addr, Reference::Addend &addend) {
const Section *sect = nullptr;
sect = findSectionCoveringAddress(normalizedFile, addr);
if (!sect)
return nullptr;
uint32_t offsetInTarget;
uint64_t offsetInSect = addr - sect->address;
auto atom =
file.findAtomCoveringAddress(*sect, offsetInSect, &offsetInTarget);
addend = offsetInTarget;
return atom;
}
// Walks all relocations for a section in a normalized .o file and
// creates corresponding lld::Reference objects.
llvm::Error convertRelocs(const Section &section,
const NormalizedFile &normalizedFile,
bool scatterable,
MachOFile &file,
ArchHandler &handler) {
// Utility function for ArchHandler to find atom by its address.
auto atomByAddr = [&] (uint32_t sectIndex, uint64_t addr,
const lld::Atom **atom, Reference::Addend *addend)
-> llvm::Error {
if (sectIndex > normalizedFile.sections.size())
return llvm::make_error<GenericError>(Twine("out of range section "
"index (") + Twine(sectIndex) + ")");
const Section *sect = nullptr;
if (sectIndex == 0) {
sect = findSectionCoveringAddress(normalizedFile, addr);
if (!sect)
return llvm::make_error<GenericError>(Twine("address (" + Twine(addr)
+ ") is not in any section"));
} else {
sect = &normalizedFile.sections[sectIndex-1];
}
uint32_t offsetInTarget;
uint64_t offsetInSect = addr - sect->address;
*atom = file.findAtomCoveringAddress(*sect, offsetInSect, &offsetInTarget);
*addend = offsetInTarget;
return llvm::Error::success();
};
// Utility function for ArchHandler to find atom by its symbol index.
auto atomBySymbol = [&] (uint32_t symbolIndex, const lld::Atom **result)
-> llvm::Error {
// Find symbol from index.
const Symbol *sym = nullptr;
uint32_t numStabs = normalizedFile.stabsSymbols.size();
uint32_t numLocal = normalizedFile.localSymbols.size();
uint32_t numGlobal = normalizedFile.globalSymbols.size();
uint32_t numUndef = normalizedFile.undefinedSymbols.size();
assert(symbolIndex >= numStabs && "Searched for stab via atomBySymbol?");
if (symbolIndex < numStabs+numLocal) {
sym = &normalizedFile.localSymbols[symbolIndex-numStabs];
} else if (symbolIndex < numStabs+numLocal+numGlobal) {
sym = &normalizedFile.globalSymbols[symbolIndex-numStabs-numLocal];
} else if (symbolIndex < numStabs+numLocal+numGlobal+numUndef) {
sym = &normalizedFile.undefinedSymbols[symbolIndex-numStabs-numLocal-
numGlobal];
} else {
return llvm::make_error<GenericError>(Twine("symbol index (")
+ Twine(symbolIndex) + ") out of range");
}
// Find atom from symbol.
if ((sym->type & N_TYPE) == N_SECT) {
if (sym->sect > normalizedFile.sections.size())
return llvm::make_error<GenericError>(Twine("symbol section index (")
+ Twine(sym->sect) + ") out of range ");
const Section &symSection = normalizedFile.sections[sym->sect-1];
uint64_t targetOffsetInSect = sym->value - symSection.address;
MachODefinedAtom *target = file.findAtomCoveringAddress(symSection,
targetOffsetInSect);
if (target) {
*result = target;
return llvm::Error::success();
}
return llvm::make_error<GenericError>("no atom found for defined symbol");
} else if ((sym->type & N_TYPE) == N_UNDF) {
const lld::Atom *target = file.findUndefAtom(sym->name);
if (target) {
*result = target;
return llvm::Error::success();
}
return llvm::make_error<GenericError>("no undefined atom found for sym");
} else {
// Search undefs
return llvm::make_error<GenericError>("no atom found for symbol");
}
};
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
// Use old-school iterator so that paired relocations can be grouped.
for (auto it=section.relocations.begin(), e=section.relocations.end();
it != e; ++it) {
const Relocation &reloc = *it;
// Find atom this relocation is in.
if (reloc.offset > section.content.size())
return llvm::make_error<GenericError>(
Twine("r_address (") + Twine(reloc.offset)
+ ") is larger than section size ("
+ Twine(section.content.size()) + ")");
uint32_t offsetInAtom;
MachODefinedAtom *inAtom = file.findAtomCoveringAddress(section,
reloc.offset,
&offsetInAtom);
assert(inAtom && "r_address in range, should have found atom");
uint64_t fixupAddress = section.address + reloc.offset;
const lld::Atom *target = nullptr;
Reference::Addend addend = 0;
Reference::KindValue kind;
if (handler.isPairedReloc(reloc)) {
// Handle paired relocations together.
const Relocation &reloc2 = *++it;
auto relocErr = handler.getPairReferenceInfo(
reloc, reloc2, inAtom, offsetInAtom, fixupAddress, isBig, scatterable,
atomByAddr, atomBySymbol, &kind, &target, &addend);
if (relocErr) {
return handleErrors(std::move(relocErr),
[&](std::unique_ptr<GenericError> GE) {
return llvm::make_error<GenericError>(
Twine("bad relocation (") + GE->getMessage()
+ ") in section "
+ section.segmentName + "/" + section.sectionName
+ " (r1_address=" + Twine::utohexstr(reloc.offset)
+ ", r1_type=" + Twine(reloc.type)
+ ", r1_extern=" + Twine(reloc.isExtern)
+ ", r1_length=" + Twine((int)reloc.length)
+ ", r1_pcrel=" + Twine(reloc.pcRel)
+ (!reloc.scattered ? (Twine(", r1_symbolnum=")
+ Twine(reloc.symbol))
: (Twine(", r1_scattered=1, r1_value=")
+ Twine(reloc.value)))
+ ")"
+ ", (r2_address=" + Twine::utohexstr(reloc2.offset)
+ ", r2_type=" + Twine(reloc2.type)
+ ", r2_extern=" + Twine(reloc2.isExtern)
+ ", r2_length=" + Twine((int)reloc2.length)
+ ", r2_pcrel=" + Twine(reloc2.pcRel)
+ (!reloc2.scattered ? (Twine(", r2_symbolnum=")
+ Twine(reloc2.symbol))
: (Twine(", r2_scattered=1, r2_value=")
+ Twine(reloc2.value)))
+ ")" );
});
}
}
else {
// Use ArchHandler to convert relocation record into information
// needed to instantiate an lld::Reference object.
auto relocErr = handler.getReferenceInfo(
reloc, inAtom, offsetInAtom, fixupAddress, isBig, atomByAddr,
atomBySymbol, &kind, &target, &addend);
if (relocErr) {
return handleErrors(std::move(relocErr),
[&](std::unique_ptr<GenericError> GE) {
return llvm::make_error<GenericError>(
Twine("bad relocation (") + GE->getMessage()
+ ") in section "
+ section.segmentName + "/" + section.sectionName
+ " (r_address=" + Twine::utohexstr(reloc.offset)
+ ", r_type=" + Twine(reloc.type)
+ ", r_extern=" + Twine(reloc.isExtern)
+ ", r_length=" + Twine((int)reloc.length)
+ ", r_pcrel=" + Twine(reloc.pcRel)
+ (!reloc.scattered ? (Twine(", r_symbolnum=") + Twine(reloc.symbol))
: (Twine(", r_scattered=1, r_value=")
+ Twine(reloc.value)))
+ ")" );
});
}
}
// Instantiate an lld::Reference object and add to its atom.
inAtom->addReference(Reference::KindNamespace::mach_o,
handler.kindArch(),
kind, offsetInAtom, target, addend);
}
return llvm::Error::success();
}
bool isDebugInfoSection(const Section &section) {
if ((section.attributes & S_ATTR_DEBUG) == 0)
return false;
return section.segmentName.equals("__DWARF");
}
static const Atom* findDefinedAtomByName(MachOFile &file, Twine name) {
std::string strName = name.str();
for (auto *atom : file.defined())
if (atom->name() == strName)
return atom;
return nullptr;
}
static StringRef copyDebugString(StringRef str, BumpPtrAllocator &alloc) {
char *strCopy = alloc.Allocate<char>(str.size() + 1);
memcpy(strCopy, str.data(), str.size());
strCopy[str.size()] = '\0';
return strCopy;
}
llvm::Error parseStabs(MachOFile &file,
const NormalizedFile &normalizedFile,
bool copyRefs) {
if (normalizedFile.stabsSymbols.empty())
return llvm::Error::success();
// FIXME: Kill this off when we can move to sane yaml parsing.
std::unique_ptr<BumpPtrAllocator> allocator;
if (copyRefs)
allocator = llvm::make_unique<BumpPtrAllocator>();
enum { start, inBeginEnd } state = start;
const Atom *currentAtom = nullptr;
uint64_t currentAtomAddress = 0;
StabsDebugInfo::StabsList stabsList;
for (const auto &stabSym : normalizedFile.stabsSymbols) {
Stab stab(nullptr, stabSym.type, stabSym.sect, stabSym.desc,
stabSym.value, stabSym.name);
switch (state) {
case start:
switch (static_cast<StabType>(stabSym.type)) {
case N_BNSYM:
state = inBeginEnd;
currentAtomAddress = stabSym.value;
Reference::Addend addend;
currentAtom = findAtomCoveringAddress(normalizedFile, file,
currentAtomAddress, addend);
if (addend != 0)
return llvm::make_error<GenericError>(
"Non-zero addend for BNSYM '" + stabSym.name + "' in " +
file.path());
if (currentAtom)
stab.atom = currentAtom;
else {
// FIXME: ld64 just issues a warning here - should we match that?
return llvm::make_error<GenericError>(
"can't find atom for stabs BNSYM at " +
Twine::utohexstr(stabSym.value) + " in " + file.path());
}
break;
case N_SO:
case N_OSO:
// Not associated with an atom, just copy.
if (copyRefs)
stab.str = copyDebugString(stabSym.name, *allocator);
else
stab.str = stabSym.name;
break;
case N_GSYM: {
auto colonIdx = stabSym.name.find(':');
if (colonIdx != StringRef::npos) {
StringRef name = stabSym.name.substr(0, colonIdx);
currentAtom = findDefinedAtomByName(file, "_" + name);
stab.atom = currentAtom;
if (copyRefs)
stab.str = copyDebugString(stabSym.name, *allocator);
else
stab.str = stabSym.name;
} else {
currentAtom = findDefinedAtomByName(file, stabSym.name);
stab.atom = currentAtom;
if (copyRefs)
stab.str = copyDebugString(stabSym.name, *allocator);
else
stab.str = stabSym.name;
}
if (stab.atom == nullptr)
return llvm::make_error<GenericError>(
"can't find atom for N_GSYM stabs" + stabSym.name +
" in " + file.path());
break;
}
case N_FUN:
return llvm::make_error<GenericError>(
"old-style N_FUN stab '" + stabSym.name + "' unsupported");
default:
return llvm::make_error<GenericError>(
"unrecognized stab symbol '" + stabSym.name + "'");
}
break;
case inBeginEnd:
stab.atom = currentAtom;
switch (static_cast<StabType>(stabSym.type)) {
case N_ENSYM:
state = start;
currentAtom = nullptr;
break;
case N_FUN:
// Just copy the string.
if (copyRefs)
stab.str = copyDebugString(stabSym.name, *allocator);
else
stab.str = stabSym.name;
break;
default:
return llvm::make_error<GenericError>(
"unrecognized stab symbol '" + stabSym.name + "'");
}
}
llvm::dbgs() << "Adding to stabsList: " << stab << "\n";
stabsList.push_back(stab);
}
file.setDebugInfo(llvm::make_unique<StabsDebugInfo>(std::move(stabsList)));
// FIXME: Kill this off when we fix YAML memory ownership.
file.debugInfo()->setAllocator(std::move(allocator));
return llvm::Error::success();
}
static llvm::DataExtractor
dataExtractorFromSection(const NormalizedFile &normalizedFile,
const Section &S) {
const bool is64 = MachOLinkingContext::is64Bit(normalizedFile.arch);
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
StringRef SecData(reinterpret_cast<const char*>(S.content.data()),
S.content.size());
return llvm::DataExtractor(SecData, !isBig, is64 ? 8 : 4);
}
// FIXME: Cribbed from llvm-dwp -- should share "lightweight CU DIE
// inspection" code if possible.
static uint32_t getCUAbbrevOffset(llvm::DataExtractor abbrevData,
uint64_t abbrCode) {
uint64_t curCode;
uint32_t offset = 0;
while ((curCode = abbrevData.getULEB128(&offset)) != abbrCode) {
// Tag
abbrevData.getULEB128(&offset);
// DW_CHILDREN
abbrevData.getU8(&offset);
// Attributes
while (abbrevData.getULEB128(&offset) | abbrevData.getULEB128(&offset))
;
}
return offset;
}
// FIXME: Cribbed from llvm-dwp -- should share "lightweight CU DIE
// inspection" code if possible.
static Expected<const char *>
getIndexedString(const NormalizedFile &normalizedFile,
llvm::dwarf::Form form, llvm::DataExtractor infoData,
uint32_t &infoOffset, const Section &stringsSection) {
if (form == llvm::dwarf::DW_FORM_string)
return infoData.getCStr(&infoOffset);
if (form != llvm::dwarf::DW_FORM_strp)
return llvm::make_error<GenericError>(
"string field encoded without DW_FORM_strp");
uint32_t stringOffset = infoData.getU32(&infoOffset);
llvm::DataExtractor stringsData =
dataExtractorFromSection(normalizedFile, stringsSection);
return stringsData.getCStr(&stringOffset);
}
// FIXME: Cribbed from llvm-dwp -- should share "lightweight CU DIE
// inspection" code if possible.
static llvm::Expected<TranslationUnitSource>
readCompUnit(const NormalizedFile &normalizedFile,
const Section &info,
const Section &abbrev,
const Section &strings,
StringRef path) {
// FIXME: Cribbed from llvm-dwp -- should share "lightweight CU DIE
// inspection" code if possible.
uint32_t offset = 0;
llvm::dwarf::DwarfFormat Format = llvm::dwarf::DwarfFormat::DWARF32;
auto infoData = dataExtractorFromSection(normalizedFile, info);
uint32_t length = infoData.getU32(&offset);
if (length == 0xffffffff) {
Format = llvm::dwarf::DwarfFormat::DWARF64;
infoData.getU64(&offset);
}
else if (length > 0xffffff00)
return llvm::make_error<GenericError>("Malformed DWARF in " + path);
uint16_t version = infoData.getU16(&offset);
if (version < 2 || version > 4)
return llvm::make_error<GenericError>("Unsupported DWARF version in " +
path);
infoData.getU32(&offset); // Abbrev offset (should be zero)
uint8_t addrSize = infoData.getU8(&offset);
uint32_t abbrCode = infoData.getULEB128(&offset);
auto abbrevData = dataExtractorFromSection(normalizedFile, abbrev);
uint32_t abbrevOffset = getCUAbbrevOffset(abbrevData, abbrCode);
uint64_t tag = abbrevData.getULEB128(&abbrevOffset);
if (tag != llvm::dwarf::DW_TAG_compile_unit)
return llvm::make_error<GenericError>("top level DIE is not a compile unit");
// DW_CHILDREN
abbrevData.getU8(&abbrevOffset);
uint32_t name;
llvm::dwarf::Form form;
llvm::DWARFFormParams formParams = {version, addrSize, Format};
TranslationUnitSource tu;
while ((name = abbrevData.getULEB128(&abbrevOffset)) |
(form = static_cast<llvm::dwarf::Form>(
abbrevData.getULEB128(&abbrevOffset))) &&
(name != 0 || form != 0)) {
switch (name) {
case llvm::dwarf::DW_AT_name: {
if (auto eName = getIndexedString(normalizedFile, form, infoData, offset,
strings))
tu.name = *eName;
else
return eName.takeError();
break;
}
case llvm::dwarf::DW_AT_comp_dir: {
if (auto eName = getIndexedString(normalizedFile, form, infoData, offset,
strings))
tu.path = *eName;
else
return eName.takeError();
break;
}
default:
llvm::DWARFFormValue::skipValue(form, infoData, &offset, formParams);
}
}
return tu;
}
llvm::Error parseDebugInfo(MachOFile &file,
const NormalizedFile &normalizedFile, bool copyRefs) {
// Find the interesting debug info sections.
const Section *debugInfo = nullptr;
const Section *debugAbbrev = nullptr;
const Section *debugStrings = nullptr;
for (auto &s : normalizedFile.sections) {
if (s.segmentName == "__DWARF") {
if (s.sectionName == "__debug_info")
debugInfo = &s;
else if (s.sectionName == "__debug_abbrev")
debugAbbrev = &s;
else if (s.sectionName == "__debug_str")
debugStrings = &s;
}
}
if (!debugInfo)
return parseStabs(file, normalizedFile, copyRefs);
if (debugInfo->content.size() == 0)
return llvm::Error::success();
if (debugInfo->content.size() < 12)
return llvm::make_error<GenericError>("Malformed __debug_info section in " +
file.path() + ": too small");
if (!debugAbbrev)
return llvm::make_error<GenericError>("Missing __dwarf_abbrev section in " +
file.path());
if (auto tuOrErr = readCompUnit(normalizedFile, *debugInfo, *debugAbbrev,
*debugStrings, file.path())) {
// FIXME: Kill of allocator and code under 'copyRefs' when we fix YAML
// memory ownership.
std::unique_ptr<BumpPtrAllocator> allocator;
if (copyRefs) {
allocator = llvm::make_unique<BumpPtrAllocator>();
tuOrErr->name = copyDebugString(tuOrErr->name, *allocator);
tuOrErr->path = copyDebugString(tuOrErr->path, *allocator);
}
file.setDebugInfo(llvm::make_unique<DwarfDebugInfo>(std::move(*tuOrErr)));
if (copyRefs)
file.debugInfo()->setAllocator(std::move(allocator));
} else
return tuOrErr.takeError();
return llvm::Error::success();
}
static int64_t readSPtr(bool is64, bool isBig, const uint8_t *addr) {
if (is64)
return read64(addr, isBig);
int32_t res = read32(addr, isBig);
return res;
}
/// --- Augmentation String Processing ---
struct CIEInfo {
bool _augmentationDataPresent = false;
bool _mayHaveEH = false;
uint32_t _offsetOfLSDA = ~0U;
uint32_t _offsetOfPersonality = ~0U;
uint32_t _offsetOfFDEPointerEncoding = ~0U;
uint32_t _augmentationDataLength = ~0U;
};
typedef llvm::DenseMap<const MachODefinedAtom*, CIEInfo> CIEInfoMap;
static llvm::Error processAugmentationString(const uint8_t *augStr,
CIEInfo &cieInfo,
unsigned &len) {
if (augStr[0] == '\0') {
len = 1;
return llvm::Error::success();
}
if (augStr[0] != 'z')
return llvm::make_error<GenericError>("expected 'z' at start of "
"augmentation string");
cieInfo._augmentationDataPresent = true;
uint64_t idx = 1;
uint32_t offsetInAugmentationData = 0;
while (augStr[idx] != '\0') {
if (augStr[idx] == 'L') {
cieInfo._offsetOfLSDA = offsetInAugmentationData;
// This adds a single byte to the augmentation data.
++offsetInAugmentationData;
++idx;
continue;
}
if (augStr[idx] == 'P') {
cieInfo._offsetOfPersonality = offsetInAugmentationData;
// This adds a single byte to the augmentation data for the encoding,
// then a number of bytes for the pointer data.
// FIXME: We are assuming 4 is correct here for the pointer size as we
// always currently use delta32ToGOT.
offsetInAugmentationData += 5;
++idx;
continue;
}
if (augStr[idx] == 'R') {
cieInfo._offsetOfFDEPointerEncoding = offsetInAugmentationData;
// This adds a single byte to the augmentation data.
++offsetInAugmentationData;
++idx;
continue;
}
if (augStr[idx] == 'e') {
if (augStr[idx + 1] != 'h')
return llvm::make_error<GenericError>("expected 'eh' in "
"augmentation string");
cieInfo._mayHaveEH = true;
idx += 2;
continue;
}
++idx;
}
cieInfo._augmentationDataLength = offsetInAugmentationData;
len = idx + 1;
return llvm::Error::success();
}
static llvm::Error processCIE(const NormalizedFile &normalizedFile,
MachOFile &file,
mach_o::ArchHandler &handler,
const Section *ehFrameSection,
MachODefinedAtom *atom,
uint64_t offset,
CIEInfoMap &cieInfos) {
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
const uint8_t *frameData = atom->rawContent().data();
CIEInfo cieInfo;
uint32_t size = read32(frameData, isBig);
uint64_t cieIDField = size == 0xffffffffU
? sizeof(uint32_t) + sizeof(uint64_t)
: sizeof(uint32_t);
uint64_t versionField = cieIDField + sizeof(uint32_t);
uint64_t augmentationStringField = versionField + sizeof(uint8_t);
unsigned augmentationStringLength = 0;
if (auto err = processAugmentationString(frameData + augmentationStringField,
cieInfo, augmentationStringLength))
return err;
if (cieInfo._offsetOfPersonality != ~0U) {
// If we have augmentation data for the personality function, then we may
// need to implicitly generate its relocation.
// Parse the EH Data field which is pointer sized.
uint64_t EHDataField = augmentationStringField + augmentationStringLength;
const bool is64 = MachOLinkingContext::is64Bit(normalizedFile.arch);
unsigned EHDataFieldSize = (cieInfo._mayHaveEH ? (is64 ? 8 : 4) : 0);
// Parse Code Align Factor which is a ULEB128.
uint64_t CodeAlignField = EHDataField + EHDataFieldSize;
unsigned lengthFieldSize = 0;
llvm::decodeULEB128(frameData + CodeAlignField, &lengthFieldSize);
// Parse Data Align Factor which is a SLEB128.
uint64_t DataAlignField = CodeAlignField + lengthFieldSize;
llvm::decodeSLEB128(frameData + DataAlignField, &lengthFieldSize);
// Parse Return Address Register which is a byte.
uint64_t ReturnAddressField = DataAlignField + lengthFieldSize;
// Parse the augmentation length which is a ULEB128.
uint64_t AugmentationLengthField = ReturnAddressField + 1;
uint64_t AugmentationLength =
llvm::decodeULEB128(frameData + AugmentationLengthField,
&lengthFieldSize);
if (AugmentationLength != cieInfo._augmentationDataLength)
return llvm::make_error<GenericError>("CIE augmentation data length "
"mismatch");
// Get the start address of the augmentation data.
uint64_t AugmentationDataField = AugmentationLengthField + lengthFieldSize;
// Parse the personality function from the augmentation data.
uint64_t PersonalityField =
AugmentationDataField + cieInfo._offsetOfPersonality;
// Parse the personality encoding.
// FIXME: Verify that this is a 32-bit pcrel offset.
uint64_t PersonalityFunctionField = PersonalityField + 1;
if (atom->begin() != atom->end()) {
// If we have an explicit relocation, then make sure it matches this
// offset as this is where we'd expect it to be applied to.
DefinedAtom::reference_iterator CurrentRef = atom->begin();
if (CurrentRef->offsetInAtom() != PersonalityFunctionField)
return llvm::make_error<GenericError>("CIE personality reloc at "
"wrong offset");
if (++CurrentRef != atom->end())
return llvm::make_error<GenericError>("CIE contains too many relocs");
} else {
// Implicitly generate the personality function reloc. It's assumed to
// be a delta32 offset to a GOT entry.
// FIXME: Parse the encoding and check this.
int32_t funcDelta = read32(frameData + PersonalityFunctionField, isBig);
uint64_t funcAddress = ehFrameSection->address + offset +
PersonalityFunctionField;
funcAddress += funcDelta;
const MachODefinedAtom *func = nullptr;
Reference::Addend addend;
func = findAtomCoveringAddress(normalizedFile, file, funcAddress,
addend);
atom->addReference(Reference::KindNamespace::mach_o, handler.kindArch(),
handler.unwindRefToPersonalityFunctionKind(),
PersonalityFunctionField, func, addend);
}
} else if (atom->begin() != atom->end()) {
// Otherwise, we expect there to be no relocations in this atom as the only
// relocation would have been to the personality function.
return llvm::make_error<GenericError>("unexpected relocation in CIE");
}
cieInfos[atom] = std::move(cieInfo);
return llvm::Error::success();
}
static llvm::Error processFDE(const NormalizedFile &normalizedFile,
MachOFile &file,
mach_o::ArchHandler &handler,
const Section *ehFrameSection,
MachODefinedAtom *atom,
uint64_t offset,
const CIEInfoMap &cieInfos) {
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
const bool is64 = MachOLinkingContext::is64Bit(normalizedFile.arch);
// Compiler wasn't lazy and actually told us what it meant.
// Unfortunately, the compiler may not have generated references for all of
// [cie, func, lsda] and so we still need to parse the FDE and add references
// for any the compiler didn't generate.
if (atom->begin() != atom->end())
atom->sortReferences();
DefinedAtom::reference_iterator CurrentRef = atom->begin();
// This helper returns the reference (if one exists) at the offset we are
// currently processing. It automatically increments the ref iterator if we
// do return a ref, and throws an error if we pass over a ref without
// comsuming it.
auto currentRefGetter = [&CurrentRef,
&atom](uint64_t Offset)->const Reference* {
// If there are no more refs found, then we are done.
if (CurrentRef == atom->end())
return nullptr;
const Reference *Ref = *CurrentRef;
// If we haven't reached the offset for this reference, then return that
// we don't yet have a reference to process.
if (Offset < Ref->offsetInAtom())
return nullptr;
// If the offset is equal, then we want to process this ref.
if (Offset == Ref->offsetInAtom()) {
++CurrentRef;
return Ref;
}
// The current ref is at an offset which is earlier than the current
// offset, then we failed to consume it when we should have. In this case
// throw an error.
llvm::report_fatal_error("Skipped reference when processing FDE");
};
// Helper to either get the reference at this current location, and verify
// that it is of the expected type, or add a reference of that type.
// Returns the reference target.
auto verifyOrAddReference = [&](uint64_t targetAddress,
Reference::KindValue refKind,
uint64_t refAddress,
bool allowsAddend)->const Atom* {
if (auto *ref = currentRefGetter(refAddress)) {
// The compiler already emitted a relocation for the CIE ref. This should
// have been converted to the correct type of reference in
// get[Pair]ReferenceInfo().
assert(ref->kindValue() == refKind &&
"Incorrect EHFrame reference kind");
return ref->target();
}
Reference::Addend addend;
auto *target = findAtomCoveringAddress(normalizedFile, file,
targetAddress, addend);
atom->addReference(Reference::KindNamespace::mach_o, handler.kindArch(),
refKind, refAddress, target, addend);
if (!allowsAddend)
assert(!addend && "EHFrame reference cannot have addend");
return target;
};
const uint8_t *startFrameData = atom->rawContent().data();
const uint8_t *frameData = startFrameData;
uint32_t size = read32(frameData, isBig);
uint64_t cieFieldInFDE = size == 0xffffffffU
? sizeof(uint32_t) + sizeof(uint64_t)
: sizeof(uint32_t);
// Linker needs to fixup a reference from the FDE to its parent CIE (a
// 32-bit byte offset backwards in the __eh_frame section).
uint32_t cieDelta = read32(frameData + cieFieldInFDE, isBig);
uint64_t cieAddress = ehFrameSection->address + offset + cieFieldInFDE;
cieAddress -= cieDelta;
auto *cieRefTarget = verifyOrAddReference(cieAddress,
handler.unwindRefToCIEKind(),
cieFieldInFDE, false);
const MachODefinedAtom *cie = dyn_cast<MachODefinedAtom>(cieRefTarget);
assert(cie && cie->contentType() == DefinedAtom::typeCFI &&
"FDE's CIE field does not point at the start of a CIE.");
const CIEInfo &cieInfo = cieInfos.find(cie)->second;
// Linker needs to fixup reference from the FDE to the function it's
// describing. FIXME: there are actually different ways to do this, and the
// particular method used is specified in the CIE's augmentation fields
// (hopefully)
uint64_t rangeFieldInFDE = cieFieldInFDE + sizeof(uint32_t);
int64_t functionFromFDE = readSPtr(is64, isBig,
frameData + rangeFieldInFDE);
uint64_t rangeStart = ehFrameSection->address + offset + rangeFieldInFDE;
rangeStart += functionFromFDE;
verifyOrAddReference(rangeStart,
handler.unwindRefToFunctionKind(),
rangeFieldInFDE, true);
// Handle the augmentation data if there is any.
if (cieInfo._augmentationDataPresent) {
// First process the augmentation data length field.
uint64_t augmentationDataLengthFieldInFDE =
rangeFieldInFDE + 2 * (is64 ? sizeof(uint64_t) : sizeof(uint32_t));
unsigned lengthFieldSize = 0;
uint64_t augmentationDataLength =
llvm::decodeULEB128(frameData + augmentationDataLengthFieldInFDE,
&lengthFieldSize);
if (cieInfo._offsetOfLSDA != ~0U && augmentationDataLength > 0) {
// Look at the augmentation data field.
uint64_t augmentationDataFieldInFDE =
augmentationDataLengthFieldInFDE + lengthFieldSize;
int64_t lsdaFromFDE = readSPtr(is64, isBig,
frameData + augmentationDataFieldInFDE);
uint64_t lsdaStart =
ehFrameSection->address + offset + augmentationDataFieldInFDE +
lsdaFromFDE;
verifyOrAddReference(lsdaStart,
handler.unwindRefToFunctionKind(),
augmentationDataFieldInFDE, true);
}
}
return llvm::Error::success();
}
llvm::Error addEHFrameReferences(const NormalizedFile &normalizedFile,
MachOFile &file,
mach_o::ArchHandler &handler) {
const Section *ehFrameSection = nullptr;
for (auto &section : normalizedFile.sections)
if (section.segmentName == "__TEXT" &&
section.sectionName == "__eh_frame") {
ehFrameSection = &section;
break;
}
// No __eh_frame so nothing to do.
if (!ehFrameSection)
return llvm::Error::success();
llvm::Error ehFrameErr = llvm::Error::success();
CIEInfoMap cieInfos;
file.eachAtomInSection(*ehFrameSection,
[&](MachODefinedAtom *atom, uint64_t offset) -> void {
assert(atom->contentType() == DefinedAtom::typeCFI);
// Bail out if we've encountered an error.
if (ehFrameErr)
return;
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
if (ArchHandler::isDwarfCIE(isBig, atom))
ehFrameErr = processCIE(normalizedFile, file, handler, ehFrameSection,
atom, offset, cieInfos);
else
ehFrameErr = processFDE(normalizedFile, file, handler, ehFrameSection,
atom, offset, cieInfos);
});
return ehFrameErr;
}
llvm::Error parseObjCImageInfo(const Section &sect,
const NormalizedFile &normalizedFile,
MachOFile &file) {
// struct objc_image_info {
// uint32_t version; // initially 0
// uint32_t flags;
// };
ArrayRef<uint8_t> content = sect.content;
if (content.size() != 8)
return llvm::make_error<GenericError>(sect.segmentName + "/" +
sect.sectionName +
" in file " + file.path() +
" should be 8 bytes in size");
const bool isBig = MachOLinkingContext::isBigEndian(normalizedFile.arch);
uint32_t version = read32(content.data(), isBig);
if (version)
return llvm::make_error<GenericError>(sect.segmentName + "/" +
sect.sectionName +
" in file " + file.path() +
" should have version=0");
uint32_t flags = read32(content.data() + 4, isBig);
if (flags & (MachOLinkingContext::objc_supports_gc |
MachOLinkingContext::objc_gc_only))
return llvm::make_error<GenericError>(sect.segmentName + "/" +
sect.sectionName +
" in file " + file.path() +
" uses GC. This is not supported");
if (flags & MachOLinkingContext::objc_retainReleaseForSimulator)
file.setObjcConstraint(MachOLinkingContext::objc_retainReleaseForSimulator);
else
file.setObjcConstraint(MachOLinkingContext::objc_retainRelease);
file.setSwiftVersion((flags >> 8) & 0xFF);
return llvm::Error::success();
}
/// Converts normalized mach-o file into an lld::File and lld::Atoms.
llvm::Expected<std::unique_ptr<lld::File>>
objectToAtoms(const NormalizedFile &normalizedFile, StringRef path,
bool copyRefs) {
std::unique_ptr<MachOFile> file(new MachOFile(path));
if (auto ec = normalizedObjectToAtoms(file.get(), normalizedFile, copyRefs))
return std::move(ec);
return std::unique_ptr<File>(std::move(file));
}
llvm::Expected<std::unique_ptr<lld::File>>
dylibToAtoms(const NormalizedFile &normalizedFile, StringRef path,
bool copyRefs) {
// Instantiate SharedLibraryFile object.
std::unique_ptr<MachODylibFile> file(new MachODylibFile(path));
if (auto ec = normalizedDylibToAtoms(file.get(), normalizedFile, copyRefs))
return std::move(ec);
return std::unique_ptr<File>(std::move(file));
}
} // anonymous namespace
namespace normalized {
static bool isObjCImageInfo(const Section &sect) {
return (sect.segmentName == "__OBJC" && sect.sectionName == "__image_info") ||
(sect.segmentName == "__DATA" && sect.sectionName == "__objc_imageinfo");
}
llvm::Error
normalizedObjectToAtoms(MachOFile *file,
const NormalizedFile &normalizedFile,
bool copyRefs) {
DEBUG(llvm::dbgs() << "******** Normalizing file to atoms: "
<< file->path() << "\n");
bool scatterable = ((normalizedFile.flags & MH_SUBSECTIONS_VIA_SYMBOLS) != 0);
// Create atoms from each section.
for (auto &sect : normalizedFile.sections) {
// If this is a debug-info section parse it specially.
if (isDebugInfoSection(sect))
continue;
// If the file contains an objc_image_info struct, then we should parse the
// ObjC flags and Swift version.
if (isObjCImageInfo(sect)) {
if (auto ec = parseObjCImageInfo(sect, normalizedFile, *file))
return ec;
// We then skip adding atoms for this section as we use the ObjCPass to
// re-emit this data after it has been aggregated for all files.
continue;
}
bool customSectionName;
DefinedAtom::ContentType atomType = atomTypeFromSection(sect,
customSectionName);
if (auto ec = processSection(atomType, sect, customSectionName,
normalizedFile, *file, scatterable, copyRefs))
return ec;
}
// Create atoms from undefined symbols.
for (auto &sym : normalizedFile.undefinedSymbols) {
// Undefinded symbols with n_value != 0 are actually tentative definitions.
if (sym.value == Hex64(0)) {
file->addUndefinedAtom(sym.name, copyRefs);
} else {
file->addTentativeDefAtom(sym.name, atomScope(sym.scope), sym.value,
DefinedAtom::Alignment(1 << (sym.desc >> 8)),
copyRefs);
}
}
// Convert mach-o relocations to References
std::unique_ptr<mach_o::ArchHandler> handler
= ArchHandler::create(normalizedFile.arch);
for (auto &sect : normalizedFile.sections) {
if (isDebugInfoSection(sect))
continue;
if (llvm::Error ec = convertRelocs(sect, normalizedFile, scatterable,
*file, *handler))
return ec;
}
// Add additional arch-specific References
file->eachDefinedAtom([&](MachODefinedAtom* atom) -> void {
handler->addAdditionalReferences(*atom);
});
// Each __eh_frame section needs references to both __text (the function we're
// providing unwind info for) and itself (FDE -> CIE). These aren't
// represented in the relocations on some architectures, so we have to add
// them back in manually there.
if (auto ec = addEHFrameReferences(normalizedFile, *file, *handler))
return ec;
// Process mach-o data-in-code regions array. That information is encoded in
// atoms as References at each transition point.
unsigned nextIndex = 0;
for (const DataInCode &entry : normalizedFile.dataInCode) {
++nextIndex;
const Section* s = findSectionCoveringAddress(normalizedFile, entry.offset);
if (!s) {
return llvm::make_error<GenericError>(Twine("LC_DATA_IN_CODE address ("
+ Twine(entry.offset)
+ ") is not in any section"));
}
uint64_t offsetInSect = entry.offset - s->address;
uint32_t offsetInAtom;
MachODefinedAtom *atom = file->findAtomCoveringAddress(*s, offsetInSect,
&offsetInAtom);
if (offsetInAtom + entry.length > atom->size()) {
return llvm::make_error<GenericError>(Twine("LC_DATA_IN_CODE entry "
"(offset="
+ Twine(entry.offset)
+ ", length="
+ Twine(entry.length)
+ ") crosses atom boundary."));
}
// Add reference that marks start of data-in-code.
atom->addReference(Reference::KindNamespace::mach_o, handler->kindArch(),
handler->dataInCodeTransitionStart(*atom),
offsetInAtom, atom, entry.kind);
// Peek at next entry, if it starts where this one ends, skip ending ref.
if (nextIndex < normalizedFile.dataInCode.size()) {
const DataInCode &nextEntry = normalizedFile.dataInCode[nextIndex];
if (nextEntry.offset == (entry.offset + entry.length))
continue;
}
// If data goes to end of function, skip ending ref.
if ((offsetInAtom + entry.length) == atom->size())
continue;
// Add reference that marks end of data-in-code.
atom->addReference(Reference::KindNamespace::mach_o, handler->kindArch(),
handler->dataInCodeTransitionEnd(*atom),
offsetInAtom+entry.length, atom, 0);
}
// Cache some attributes on the file for use later.
file->setFlags(normalizedFile.flags);
file->setArch(normalizedFile.arch);
file->setOS(normalizedFile.os);
file->setMinVersion(normalizedFile.minOSverson);
file->setMinVersionLoadCommandKind(normalizedFile.minOSVersionKind);
// Sort references in each atom to their canonical order.
for (const DefinedAtom* defAtom : file->defined()) {
reinterpret_cast<const SimpleDefinedAtom*>(defAtom)->sortReferences();
}
if (auto err = parseDebugInfo(*file, normalizedFile, copyRefs))
return err;
return llvm::Error::success();
}
llvm::Error
normalizedDylibToAtoms(MachODylibFile *file,
const NormalizedFile &normalizedFile,
bool copyRefs) {
file->setInstallName(normalizedFile.installName);
file->setCompatVersion(normalizedFile.compatVersion);
file->setCurrentVersion(normalizedFile.currentVersion);
// Tell MachODylibFile object about all symbols it exports.
if (!normalizedFile.exportInfo.empty()) {
// If exports trie exists, use it instead of traditional symbol table.
for (const Export &exp : normalizedFile.exportInfo) {
bool weakDef = (exp.flags & EXPORT_SYMBOL_FLAGS_WEAK_DEFINITION);
// StringRefs from export iterator are ephemeral, so force copy.
file->addExportedSymbol(exp.name, weakDef, true);
}
} else {
for (auto &sym : normalizedFile.globalSymbols) {
assert((sym.scope & N_EXT) && "only expect external symbols here");
bool weakDef = (sym.desc & N_WEAK_DEF);
file->addExportedSymbol(sym.name, weakDef, copyRefs);
}
}
// Tell MachODylibFile object about all dylibs it re-exports.
for (const DependentDylib &dep : normalizedFile.dependentDylibs) {
if (dep.kind == llvm::MachO::LC_REEXPORT_DYLIB)
file->addReExportedDylib(dep.path);
}
return llvm::Error::success();
}
void relocatableSectionInfoForContentType(DefinedAtom::ContentType atomType,
StringRef &segmentName,
StringRef &sectionName,
SectionType &sectionType,
SectionAttr &sectionAttrs,
bool &relocsToDefinedCanBeImplicit) {
for (const MachORelocatableSectionToAtomType *p = sectsToAtomType ;
p->atomType != DefinedAtom::typeUnknown; ++p) {
if (p->atomType != atomType)
continue;
// Wild carded entries are ignored for reverse lookups.
if (p->segmentName.empty() || p->sectionName.empty())
continue;
segmentName = p->segmentName;
sectionName = p->sectionName;
sectionType = p->sectionType;
sectionAttrs = 0;
relocsToDefinedCanBeImplicit = false;
if (atomType == DefinedAtom::typeCode)
sectionAttrs = S_ATTR_PURE_INSTRUCTIONS;
if (atomType == DefinedAtom::typeCFI)
relocsToDefinedCanBeImplicit = true;
return;
}
llvm_unreachable("content type not yet supported");
}
llvm::Expected<std::unique_ptr<lld::File>>
normalizedToAtoms(const NormalizedFile &normalizedFile, StringRef path,
bool copyRefs) {
switch (normalizedFile.fileType) {
case MH_DYLIB:
case MH_DYLIB_STUB:
return dylibToAtoms(normalizedFile, path, copyRefs);
case MH_OBJECT:
return objectToAtoms(normalizedFile, path, copyRefs);
default:
llvm_unreachable("unhandled MachO file type!");
}
}
} // namespace normalized
} // namespace mach_o
} // namespace lld
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