xref: /freebsd/contrib/llvm-project/lld/MachO/Writer.cpp (revision a50d73d5782a351ad83e8d1f84d11720a12e70d3)
1 //===- Writer.cpp ---------------------------------------------------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #include "Writer.h"
10 #include "ConcatOutputSection.h"
11 #include "Config.h"
12 #include "InputFiles.h"
13 #include "InputSection.h"
14 #include "MapFile.h"
15 #include "OutputSection.h"
16 #include "OutputSegment.h"
17 #include "SectionPriorities.h"
18 #include "SymbolTable.h"
19 #include "Symbols.h"
20 #include "SyntheticSections.h"
21 #include "Target.h"
22 #include "UnwindInfoSection.h"
23 #include "llvm/Support/Parallel.h"
24 
25 #include "lld/Common/Arrays.h"
26 #include "lld/Common/CommonLinkerContext.h"
27 #include "llvm/BinaryFormat/MachO.h"
28 #include "llvm/Config/llvm-config.h"
29 #include "llvm/Support/LEB128.h"
30 #include "llvm/Support/MathExtras.h"
31 #include "llvm/Support/Parallel.h"
32 #include "llvm/Support/Path.h"
33 #include "llvm/Support/ThreadPool.h"
34 #include "llvm/Support/TimeProfiler.h"
35 #include "llvm/Support/xxhash.h"
36 
37 #include <algorithm>
38 
39 using namespace llvm;
40 using namespace llvm::MachO;
41 using namespace llvm::sys;
42 using namespace lld;
43 using namespace lld::macho;
44 
45 namespace {
46 class LCUuid;
47 
48 class Writer {
49 public:
50   Writer() : buffer(errorHandler().outputBuffer) {}
51 
52   void treatSpecialUndefineds();
53   void scanRelocations();
54   void scanSymbols();
55   template <class LP> void createOutputSections();
56   template <class LP> void createLoadCommands();
57   void finalizeAddresses();
58   void finalizeLinkEditSegment();
59   void assignAddresses(OutputSegment *);
60 
61   void openFile();
62   void writeSections();
63   void writeUuid();
64   void writeCodeSignature();
65   void writeOutputFile();
66 
67   template <class LP> void run();
68 
69   ThreadPool threadPool;
70   std::unique_ptr<FileOutputBuffer> &buffer;
71   uint64_t addr = 0;
72   uint64_t fileOff = 0;
73   MachHeaderSection *header = nullptr;
74   StringTableSection *stringTableSection = nullptr;
75   SymtabSection *symtabSection = nullptr;
76   IndirectSymtabSection *indirectSymtabSection = nullptr;
77   CodeSignatureSection *codeSignatureSection = nullptr;
78   DataInCodeSection *dataInCodeSection = nullptr;
79   FunctionStartsSection *functionStartsSection = nullptr;
80 
81   LCUuid *uuidCommand = nullptr;
82   OutputSegment *linkEditSegment = nullptr;
83 };
84 
85 // LC_DYLD_INFO_ONLY stores the offsets of symbol import/export information.
86 class LCDyldInfo final : public LoadCommand {
87 public:
88   LCDyldInfo(RebaseSection *rebaseSection, BindingSection *bindingSection,
89              WeakBindingSection *weakBindingSection,
90              LazyBindingSection *lazyBindingSection,
91              ExportSection *exportSection)
92       : rebaseSection(rebaseSection), bindingSection(bindingSection),
93         weakBindingSection(weakBindingSection),
94         lazyBindingSection(lazyBindingSection), exportSection(exportSection) {}
95 
96   uint32_t getSize() const override { return sizeof(dyld_info_command); }
97 
98   void writeTo(uint8_t *buf) const override {
99     auto *c = reinterpret_cast<dyld_info_command *>(buf);
100     c->cmd = LC_DYLD_INFO_ONLY;
101     c->cmdsize = getSize();
102     if (rebaseSection->isNeeded()) {
103       c->rebase_off = rebaseSection->fileOff;
104       c->rebase_size = rebaseSection->getFileSize();
105     }
106     if (bindingSection->isNeeded()) {
107       c->bind_off = bindingSection->fileOff;
108       c->bind_size = bindingSection->getFileSize();
109     }
110     if (weakBindingSection->isNeeded()) {
111       c->weak_bind_off = weakBindingSection->fileOff;
112       c->weak_bind_size = weakBindingSection->getFileSize();
113     }
114     if (lazyBindingSection->isNeeded()) {
115       c->lazy_bind_off = lazyBindingSection->fileOff;
116       c->lazy_bind_size = lazyBindingSection->getFileSize();
117     }
118     if (exportSection->isNeeded()) {
119       c->export_off = exportSection->fileOff;
120       c->export_size = exportSection->getFileSize();
121     }
122   }
123 
124   RebaseSection *rebaseSection;
125   BindingSection *bindingSection;
126   WeakBindingSection *weakBindingSection;
127   LazyBindingSection *lazyBindingSection;
128   ExportSection *exportSection;
129 };
130 
131 class LCSubFramework final : public LoadCommand {
132 public:
133   LCSubFramework(StringRef umbrella) : umbrella(umbrella) {}
134 
135   uint32_t getSize() const override {
136     return alignTo(sizeof(sub_framework_command) + umbrella.size() + 1,
137                    target->wordSize);
138   }
139 
140   void writeTo(uint8_t *buf) const override {
141     auto *c = reinterpret_cast<sub_framework_command *>(buf);
142     buf += sizeof(sub_framework_command);
143 
144     c->cmd = LC_SUB_FRAMEWORK;
145     c->cmdsize = getSize();
146     c->umbrella = sizeof(sub_framework_command);
147 
148     memcpy(buf, umbrella.data(), umbrella.size());
149     buf[umbrella.size()] = '\0';
150   }
151 
152 private:
153   const StringRef umbrella;
154 };
155 
156 class LCFunctionStarts final : public LoadCommand {
157 public:
158   explicit LCFunctionStarts(FunctionStartsSection *functionStartsSection)
159       : functionStartsSection(functionStartsSection) {}
160 
161   uint32_t getSize() const override { return sizeof(linkedit_data_command); }
162 
163   void writeTo(uint8_t *buf) const override {
164     auto *c = reinterpret_cast<linkedit_data_command *>(buf);
165     c->cmd = LC_FUNCTION_STARTS;
166     c->cmdsize = getSize();
167     c->dataoff = functionStartsSection->fileOff;
168     c->datasize = functionStartsSection->getFileSize();
169   }
170 
171 private:
172   FunctionStartsSection *functionStartsSection;
173 };
174 
175 class LCDataInCode final : public LoadCommand {
176 public:
177   explicit LCDataInCode(DataInCodeSection *dataInCodeSection)
178       : dataInCodeSection(dataInCodeSection) {}
179 
180   uint32_t getSize() const override { return sizeof(linkedit_data_command); }
181 
182   void writeTo(uint8_t *buf) const override {
183     auto *c = reinterpret_cast<linkedit_data_command *>(buf);
184     c->cmd = LC_DATA_IN_CODE;
185     c->cmdsize = getSize();
186     c->dataoff = dataInCodeSection->fileOff;
187     c->datasize = dataInCodeSection->getFileSize();
188   }
189 
190 private:
191   DataInCodeSection *dataInCodeSection;
192 };
193 
194 class LCDysymtab final : public LoadCommand {
195 public:
196   LCDysymtab(SymtabSection *symtabSection,
197              IndirectSymtabSection *indirectSymtabSection)
198       : symtabSection(symtabSection),
199         indirectSymtabSection(indirectSymtabSection) {}
200 
201   uint32_t getSize() const override { return sizeof(dysymtab_command); }
202 
203   void writeTo(uint8_t *buf) const override {
204     auto *c = reinterpret_cast<dysymtab_command *>(buf);
205     c->cmd = LC_DYSYMTAB;
206     c->cmdsize = getSize();
207 
208     c->ilocalsym = 0;
209     c->iextdefsym = c->nlocalsym = symtabSection->getNumLocalSymbols();
210     c->nextdefsym = symtabSection->getNumExternalSymbols();
211     c->iundefsym = c->iextdefsym + c->nextdefsym;
212     c->nundefsym = symtabSection->getNumUndefinedSymbols();
213 
214     c->indirectsymoff = indirectSymtabSection->fileOff;
215     c->nindirectsyms = indirectSymtabSection->getNumSymbols();
216   }
217 
218   SymtabSection *symtabSection;
219   IndirectSymtabSection *indirectSymtabSection;
220 };
221 
222 template <class LP> class LCSegment final : public LoadCommand {
223 public:
224   LCSegment(StringRef name, OutputSegment *seg) : name(name), seg(seg) {}
225 
226   uint32_t getSize() const override {
227     return sizeof(typename LP::segment_command) +
228            seg->numNonHiddenSections() * sizeof(typename LP::section);
229   }
230 
231   void writeTo(uint8_t *buf) const override {
232     using SegmentCommand = typename LP::segment_command;
233     using SectionHeader = typename LP::section;
234 
235     auto *c = reinterpret_cast<SegmentCommand *>(buf);
236     buf += sizeof(SegmentCommand);
237 
238     c->cmd = LP::segmentLCType;
239     c->cmdsize = getSize();
240     memcpy(c->segname, name.data(), name.size());
241     c->fileoff = seg->fileOff;
242     c->maxprot = seg->maxProt;
243     c->initprot = seg->initProt;
244 
245     c->vmaddr = seg->addr;
246     c->vmsize = seg->vmSize;
247     c->filesize = seg->fileSize;
248     c->nsects = seg->numNonHiddenSections();
249 
250     for (const OutputSection *osec : seg->getSections()) {
251       if (osec->isHidden())
252         continue;
253 
254       auto *sectHdr = reinterpret_cast<SectionHeader *>(buf);
255       buf += sizeof(SectionHeader);
256 
257       memcpy(sectHdr->sectname, osec->name.data(), osec->name.size());
258       memcpy(sectHdr->segname, name.data(), name.size());
259 
260       sectHdr->addr = osec->addr;
261       sectHdr->offset = osec->fileOff;
262       sectHdr->align = Log2_32(osec->align);
263       sectHdr->flags = osec->flags;
264       sectHdr->size = osec->getSize();
265       sectHdr->reserved1 = osec->reserved1;
266       sectHdr->reserved2 = osec->reserved2;
267     }
268   }
269 
270 private:
271   StringRef name;
272   OutputSegment *seg;
273 };
274 
275 class LCMain final : public LoadCommand {
276   uint32_t getSize() const override {
277     return sizeof(structs::entry_point_command);
278   }
279 
280   void writeTo(uint8_t *buf) const override {
281     auto *c = reinterpret_cast<structs::entry_point_command *>(buf);
282     c->cmd = LC_MAIN;
283     c->cmdsize = getSize();
284 
285     if (config->entry->isInStubs())
286       c->entryoff =
287           in.stubs->fileOff + config->entry->stubsIndex * target->stubSize;
288     else
289       c->entryoff = config->entry->getVA() - in.header->addr;
290 
291     c->stacksize = 0;
292   }
293 };
294 
295 class LCSymtab final : public LoadCommand {
296 public:
297   LCSymtab(SymtabSection *symtabSection, StringTableSection *stringTableSection)
298       : symtabSection(symtabSection), stringTableSection(stringTableSection) {}
299 
300   uint32_t getSize() const override { return sizeof(symtab_command); }
301 
302   void writeTo(uint8_t *buf) const override {
303     auto *c = reinterpret_cast<symtab_command *>(buf);
304     c->cmd = LC_SYMTAB;
305     c->cmdsize = getSize();
306     c->symoff = symtabSection->fileOff;
307     c->nsyms = symtabSection->getNumSymbols();
308     c->stroff = stringTableSection->fileOff;
309     c->strsize = stringTableSection->getFileSize();
310   }
311 
312   SymtabSection *symtabSection = nullptr;
313   StringTableSection *stringTableSection = nullptr;
314 };
315 
316 // There are several dylib load commands that share the same structure:
317 //   * LC_LOAD_DYLIB
318 //   * LC_ID_DYLIB
319 //   * LC_REEXPORT_DYLIB
320 class LCDylib final : public LoadCommand {
321 public:
322   LCDylib(LoadCommandType type, StringRef path,
323           uint32_t compatibilityVersion = 0, uint32_t currentVersion = 0)
324       : type(type), path(path), compatibilityVersion(compatibilityVersion),
325         currentVersion(currentVersion) {
326     instanceCount++;
327   }
328 
329   uint32_t getSize() const override {
330     return alignTo(sizeof(dylib_command) + path.size() + 1, 8);
331   }
332 
333   void writeTo(uint8_t *buf) const override {
334     auto *c = reinterpret_cast<dylib_command *>(buf);
335     buf += sizeof(dylib_command);
336 
337     c->cmd = type;
338     c->cmdsize = getSize();
339     c->dylib.name = sizeof(dylib_command);
340     c->dylib.timestamp = 0;
341     c->dylib.compatibility_version = compatibilityVersion;
342     c->dylib.current_version = currentVersion;
343 
344     memcpy(buf, path.data(), path.size());
345     buf[path.size()] = '\0';
346   }
347 
348   static uint32_t getInstanceCount() { return instanceCount; }
349   static void resetInstanceCount() { instanceCount = 0; }
350 
351 private:
352   LoadCommandType type;
353   StringRef path;
354   uint32_t compatibilityVersion;
355   uint32_t currentVersion;
356   static uint32_t instanceCount;
357 };
358 
359 uint32_t LCDylib::instanceCount = 0;
360 
361 class LCLoadDylinker final : public LoadCommand {
362 public:
363   uint32_t getSize() const override {
364     return alignTo(sizeof(dylinker_command) + path.size() + 1, 8);
365   }
366 
367   void writeTo(uint8_t *buf) const override {
368     auto *c = reinterpret_cast<dylinker_command *>(buf);
369     buf += sizeof(dylinker_command);
370 
371     c->cmd = LC_LOAD_DYLINKER;
372     c->cmdsize = getSize();
373     c->name = sizeof(dylinker_command);
374 
375     memcpy(buf, path.data(), path.size());
376     buf[path.size()] = '\0';
377   }
378 
379 private:
380   // Recent versions of Darwin won't run any binary that has dyld at a
381   // different location.
382   const StringRef path = "/usr/lib/dyld";
383 };
384 
385 class LCRPath final : public LoadCommand {
386 public:
387   explicit LCRPath(StringRef path) : path(path) {}
388 
389   uint32_t getSize() const override {
390     return alignTo(sizeof(rpath_command) + path.size() + 1, target->wordSize);
391   }
392 
393   void writeTo(uint8_t *buf) const override {
394     auto *c = reinterpret_cast<rpath_command *>(buf);
395     buf += sizeof(rpath_command);
396 
397     c->cmd = LC_RPATH;
398     c->cmdsize = getSize();
399     c->path = sizeof(rpath_command);
400 
401     memcpy(buf, path.data(), path.size());
402     buf[path.size()] = '\0';
403   }
404 
405 private:
406   StringRef path;
407 };
408 
409 class LCMinVersion final : public LoadCommand {
410 public:
411   explicit LCMinVersion(const PlatformInfo &platformInfo)
412       : platformInfo(platformInfo) {}
413 
414   uint32_t getSize() const override { return sizeof(version_min_command); }
415 
416   void writeTo(uint8_t *buf) const override {
417     auto *c = reinterpret_cast<version_min_command *>(buf);
418     switch (platformInfo.target.Platform) {
419     case PLATFORM_MACOS:
420       c->cmd = LC_VERSION_MIN_MACOSX;
421       break;
422     case PLATFORM_IOS:
423     case PLATFORM_IOSSIMULATOR:
424       c->cmd = LC_VERSION_MIN_IPHONEOS;
425       break;
426     case PLATFORM_TVOS:
427     case PLATFORM_TVOSSIMULATOR:
428       c->cmd = LC_VERSION_MIN_TVOS;
429       break;
430     case PLATFORM_WATCHOS:
431     case PLATFORM_WATCHOSSIMULATOR:
432       c->cmd = LC_VERSION_MIN_WATCHOS;
433       break;
434     default:
435       llvm_unreachable("invalid platform");
436       break;
437     }
438     c->cmdsize = getSize();
439     c->version = encodeVersion(platformInfo.minimum);
440     c->sdk = encodeVersion(platformInfo.sdk);
441   }
442 
443 private:
444   const PlatformInfo &platformInfo;
445 };
446 
447 class LCBuildVersion final : public LoadCommand {
448 public:
449   explicit LCBuildVersion(const PlatformInfo &platformInfo)
450       : platformInfo(platformInfo) {}
451 
452   const int ntools = 1;
453 
454   uint32_t getSize() const override {
455     return sizeof(build_version_command) + ntools * sizeof(build_tool_version);
456   }
457 
458   void writeTo(uint8_t *buf) const override {
459     auto *c = reinterpret_cast<build_version_command *>(buf);
460     c->cmd = LC_BUILD_VERSION;
461     c->cmdsize = getSize();
462 
463     c->platform = static_cast<uint32_t>(platformInfo.target.Platform);
464     c->minos = encodeVersion(platformInfo.minimum);
465     c->sdk = encodeVersion(platformInfo.sdk);
466 
467     c->ntools = ntools;
468     auto *t = reinterpret_cast<build_tool_version *>(&c[1]);
469     t->tool = TOOL_LD;
470     t->version = encodeVersion(VersionTuple(
471         LLVM_VERSION_MAJOR, LLVM_VERSION_MINOR, LLVM_VERSION_PATCH));
472   }
473 
474 private:
475   const PlatformInfo &platformInfo;
476 };
477 
478 // Stores a unique identifier for the output file based on an MD5 hash of its
479 // contents. In order to hash the contents, we must first write them, but
480 // LC_UUID itself must be part of the written contents in order for all the
481 // offsets to be calculated correctly. We resolve this circular paradox by
482 // first writing an LC_UUID with an all-zero UUID, then updating the UUID with
483 // its real value later.
484 class LCUuid final : public LoadCommand {
485 public:
486   uint32_t getSize() const override { return sizeof(uuid_command); }
487 
488   void writeTo(uint8_t *buf) const override {
489     auto *c = reinterpret_cast<uuid_command *>(buf);
490     c->cmd = LC_UUID;
491     c->cmdsize = getSize();
492     uuidBuf = c->uuid;
493   }
494 
495   void writeUuid(uint64_t digest) const {
496     // xxhash only gives us 8 bytes, so put some fixed data in the other half.
497     static_assert(sizeof(uuid_command::uuid) == 16, "unexpected uuid size");
498     memcpy(uuidBuf, "LLD\xa1UU1D", 8);
499     memcpy(uuidBuf + 8, &digest, 8);
500 
501     // RFC 4122 conformance. We need to fix 4 bits in byte 6 and 2 bits in
502     // byte 8. Byte 6 is already fine due to the fixed data we put in. We don't
503     // want to lose bits of the digest in byte 8, so swap that with a byte of
504     // fixed data that happens to have the right bits set.
505     std::swap(uuidBuf[3], uuidBuf[8]);
506 
507     // Claim that this is an MD5-based hash. It isn't, but this signals that
508     // this is not a time-based and not a random hash. MD5 seems like the least
509     // bad lie we can put here.
510     assert((uuidBuf[6] & 0xf0) == 0x30 && "See RFC 4122 Sections 4.2.2, 4.1.3");
511     assert((uuidBuf[8] & 0xc0) == 0x80 && "See RFC 4122 Section 4.2.2");
512   }
513 
514   mutable uint8_t *uuidBuf;
515 };
516 
517 template <class LP> class LCEncryptionInfo final : public LoadCommand {
518 public:
519   uint32_t getSize() const override {
520     return sizeof(typename LP::encryption_info_command);
521   }
522 
523   void writeTo(uint8_t *buf) const override {
524     using EncryptionInfo = typename LP::encryption_info_command;
525     auto *c = reinterpret_cast<EncryptionInfo *>(buf);
526     buf += sizeof(EncryptionInfo);
527     c->cmd = LP::encryptionInfoLCType;
528     c->cmdsize = getSize();
529     c->cryptoff = in.header->getSize();
530     auto it = find_if(outputSegments, [](const OutputSegment *seg) {
531       return seg->name == segment_names::text;
532     });
533     assert(it != outputSegments.end());
534     c->cryptsize = (*it)->fileSize - c->cryptoff;
535   }
536 };
537 
538 class LCCodeSignature final : public LoadCommand {
539 public:
540   LCCodeSignature(CodeSignatureSection *section) : section(section) {}
541 
542   uint32_t getSize() const override { return sizeof(linkedit_data_command); }
543 
544   void writeTo(uint8_t *buf) const override {
545     auto *c = reinterpret_cast<linkedit_data_command *>(buf);
546     c->cmd = LC_CODE_SIGNATURE;
547     c->cmdsize = getSize();
548     c->dataoff = static_cast<uint32_t>(section->fileOff);
549     c->datasize = section->getSize();
550   }
551 
552   CodeSignatureSection *section;
553 };
554 
555 } // namespace
556 
557 void Writer::treatSpecialUndefineds() {
558   if (config->entry)
559     if (auto *undefined = dyn_cast<Undefined>(config->entry))
560       treatUndefinedSymbol(*undefined, "the entry point");
561 
562   // FIXME: This prints symbols that are undefined both in input files and
563   // via -u flag twice.
564   for (const Symbol *sym : config->explicitUndefineds) {
565     if (const auto *undefined = dyn_cast<Undefined>(sym))
566       treatUndefinedSymbol(*undefined, "-u");
567   }
568   // Literal exported-symbol names must be defined, but glob
569   // patterns need not match.
570   for (const CachedHashStringRef &cachedName :
571        config->exportedSymbols.literals) {
572     if (const Symbol *sym = symtab->find(cachedName))
573       if (const auto *undefined = dyn_cast<Undefined>(sym))
574         treatUndefinedSymbol(*undefined, "-exported_symbol(s_list)");
575   }
576 }
577 
578 // Add stubs and bindings where necessary (e.g. if the symbol is a
579 // DylibSymbol.)
580 static void prepareBranchTarget(Symbol *sym) {
581   if (auto *dysym = dyn_cast<DylibSymbol>(sym)) {
582     if (in.stubs->addEntry(dysym)) {
583       if (sym->isWeakDef()) {
584         in.binding->addEntry(dysym, in.lazyPointers->isec,
585                              sym->stubsIndex * target->wordSize);
586         in.weakBinding->addEntry(sym, in.lazyPointers->isec,
587                                  sym->stubsIndex * target->wordSize);
588       } else {
589         in.lazyBinding->addEntry(dysym);
590       }
591     }
592   } else if (auto *defined = dyn_cast<Defined>(sym)) {
593     if (defined->isExternalWeakDef()) {
594       if (in.stubs->addEntry(sym)) {
595         in.rebase->addEntry(in.lazyPointers->isec,
596                             sym->stubsIndex * target->wordSize);
597         in.weakBinding->addEntry(sym, in.lazyPointers->isec,
598                                  sym->stubsIndex * target->wordSize);
599       }
600     } else if (defined->interposable) {
601       if (in.stubs->addEntry(sym))
602         in.lazyBinding->addEntry(sym);
603     }
604   } else {
605     llvm_unreachable("invalid branch target symbol type");
606   }
607 }
608 
609 // Can a symbol's address can only be resolved at runtime?
610 static bool needsBinding(const Symbol *sym) {
611   if (isa<DylibSymbol>(sym))
612     return true;
613   if (const auto *defined = dyn_cast<Defined>(sym))
614     return defined->isExternalWeakDef() || defined->interposable;
615   return false;
616 }
617 
618 static void prepareSymbolRelocation(Symbol *sym, const InputSection *isec,
619                                     const lld::macho::Reloc &r) {
620   assert(sym->isLive());
621   const RelocAttrs &relocAttrs = target->getRelocAttrs(r.type);
622 
623   if (relocAttrs.hasAttr(RelocAttrBits::BRANCH)) {
624     prepareBranchTarget(sym);
625   } else if (relocAttrs.hasAttr(RelocAttrBits::GOT)) {
626     if (relocAttrs.hasAttr(RelocAttrBits::POINTER) || needsBinding(sym))
627       in.got->addEntry(sym);
628   } else if (relocAttrs.hasAttr(RelocAttrBits::TLV)) {
629     if (needsBinding(sym))
630       in.tlvPointers->addEntry(sym);
631   } else if (relocAttrs.hasAttr(RelocAttrBits::UNSIGNED)) {
632     // References from thread-local variable sections are treated as offsets
633     // relative to the start of the referent section, and therefore have no
634     // need of rebase opcodes.
635     if (!(isThreadLocalVariables(isec->getFlags()) && isa<Defined>(sym)))
636       addNonLazyBindingEntries(sym, isec, r.offset, r.addend);
637   }
638 }
639 
640 void Writer::scanRelocations() {
641   TimeTraceScope timeScope("Scan relocations");
642 
643   // This can't use a for-each loop: It calls treatUndefinedSymbol(), which can
644   // add to inputSections, which invalidates inputSections's iterators.
645   for (size_t i = 0; i < inputSections.size(); ++i) {
646     ConcatInputSection *isec = inputSections[i];
647 
648     if (isec->shouldOmitFromOutput())
649       continue;
650 
651     for (auto it = isec->relocs.begin(); it != isec->relocs.end(); ++it) {
652       lld::macho::Reloc &r = *it;
653       if (target->hasAttr(r.type, RelocAttrBits::SUBTRAHEND)) {
654         // Skip over the following UNSIGNED relocation -- it's just there as the
655         // minuend, and doesn't have the usual UNSIGNED semantics. We don't want
656         // to emit rebase opcodes for it.
657         it++;
658         continue;
659       }
660       if (auto *sym = r.referent.dyn_cast<Symbol *>()) {
661         if (auto *undefined = dyn_cast<Undefined>(sym))
662           treatUndefinedSymbol(*undefined, isec, r.offset);
663         // treatUndefinedSymbol() can replace sym with a DylibSymbol; re-check.
664         if (!isa<Undefined>(sym) && validateSymbolRelocation(sym, isec, r))
665           prepareSymbolRelocation(sym, isec, r);
666       } else {
667         // Canonicalize the referent so that later accesses in Writer won't
668         // have to worry about it. Perhaps we should do this for Defined::isec
669         // too...
670         auto *referentIsec = r.referent.get<InputSection *>();
671         r.referent = referentIsec->canonical();
672         if (!r.pcrel)
673           in.rebase->addEntry(isec, r.offset);
674       }
675     }
676   }
677 
678   in.unwindInfo->prepare();
679 }
680 
681 void Writer::scanSymbols() {
682   TimeTraceScope timeScope("Scan symbols");
683   for (Symbol *sym : symtab->getSymbols()) {
684     if (auto *defined = dyn_cast<Defined>(sym)) {
685       if (!defined->isLive())
686         continue;
687       defined->canonicalize();
688       if (defined->overridesWeakDef)
689         in.weakBinding->addNonWeakDefinition(defined);
690       if (!defined->isAbsolute() && isCodeSection(defined->isec))
691         in.unwindInfo->addSymbol(defined);
692     } else if (const auto *dysym = dyn_cast<DylibSymbol>(sym)) {
693       // This branch intentionally doesn't check isLive().
694       if (dysym->isDynamicLookup())
695         continue;
696       dysym->getFile()->refState =
697           std::max(dysym->getFile()->refState, dysym->getRefState());
698     }
699   }
700 
701   for (const InputFile *file : inputFiles) {
702     if (auto *objFile = dyn_cast<ObjFile>(file))
703       for (Symbol *sym : objFile->symbols) {
704         if (auto *defined = dyn_cast_or_null<Defined>(sym)) {
705           if (!defined->isLive())
706             continue;
707           defined->canonicalize();
708           if (!defined->isExternal() && !defined->isAbsolute() &&
709               isCodeSection(defined->isec))
710             in.unwindInfo->addSymbol(defined);
711         }
712       }
713   }
714 }
715 
716 // TODO: ld64 enforces the old load commands in a few other cases.
717 static bool useLCBuildVersion(const PlatformInfo &platformInfo) {
718   static const std::vector<std::pair<PlatformType, VersionTuple>> minVersion = {
719       {PLATFORM_MACOS, VersionTuple(10, 14)},
720       {PLATFORM_IOS, VersionTuple(12, 0)},
721       {PLATFORM_IOSSIMULATOR, VersionTuple(13, 0)},
722       {PLATFORM_TVOS, VersionTuple(12, 0)},
723       {PLATFORM_TVOSSIMULATOR, VersionTuple(13, 0)},
724       {PLATFORM_WATCHOS, VersionTuple(5, 0)},
725       {PLATFORM_WATCHOSSIMULATOR, VersionTuple(6, 0)}};
726   auto it = llvm::find_if(minVersion, [&](const auto &p) {
727     return p.first == platformInfo.target.Platform;
728   });
729   return it == minVersion.end() ? true : platformInfo.minimum >= it->second;
730 }
731 
732 template <class LP> void Writer::createLoadCommands() {
733   uint8_t segIndex = 0;
734   for (OutputSegment *seg : outputSegments) {
735     in.header->addLoadCommand(make<LCSegment<LP>>(seg->name, seg));
736     seg->index = segIndex++;
737   }
738 
739   in.header->addLoadCommand(make<LCDyldInfo>(
740       in.rebase, in.binding, in.weakBinding, in.lazyBinding, in.exports));
741   in.header->addLoadCommand(make<LCSymtab>(symtabSection, stringTableSection));
742   in.header->addLoadCommand(
743       make<LCDysymtab>(symtabSection, indirectSymtabSection));
744   if (!config->umbrella.empty())
745     in.header->addLoadCommand(make<LCSubFramework>(config->umbrella));
746   if (config->emitEncryptionInfo)
747     in.header->addLoadCommand(make<LCEncryptionInfo<LP>>());
748   for (StringRef path : config->runtimePaths)
749     in.header->addLoadCommand(make<LCRPath>(path));
750 
751   switch (config->outputType) {
752   case MH_EXECUTE:
753     in.header->addLoadCommand(make<LCLoadDylinker>());
754     break;
755   case MH_DYLIB:
756     in.header->addLoadCommand(make<LCDylib>(LC_ID_DYLIB, config->installName,
757                                             config->dylibCompatibilityVersion,
758                                             config->dylibCurrentVersion));
759     break;
760   case MH_BUNDLE:
761     break;
762   default:
763     llvm_unreachable("unhandled output file type");
764   }
765 
766   uuidCommand = make<LCUuid>();
767   in.header->addLoadCommand(uuidCommand);
768 
769   if (useLCBuildVersion(config->platformInfo))
770     in.header->addLoadCommand(make<LCBuildVersion>(config->platformInfo));
771   else
772     in.header->addLoadCommand(make<LCMinVersion>(config->platformInfo));
773 
774   if (config->secondaryPlatformInfo) {
775     in.header->addLoadCommand(
776         make<LCBuildVersion>(*config->secondaryPlatformInfo));
777   }
778 
779   // This is down here to match ld64's load command order.
780   if (config->outputType == MH_EXECUTE)
781     in.header->addLoadCommand(make<LCMain>());
782 
783   // See ld64's OutputFile::buildDylibOrdinalMapping for the corresponding
784   // library ordinal computation code in ld64.
785   int64_t dylibOrdinal = 1;
786   DenseMap<StringRef, int64_t> ordinalForInstallName;
787 
788   std::vector<DylibFile *> dylibFiles;
789   for (InputFile *file : inputFiles) {
790     if (auto *dylibFile = dyn_cast<DylibFile>(file))
791       dylibFiles.push_back(dylibFile);
792   }
793   for (size_t i = 0; i < dylibFiles.size(); ++i)
794     dylibFiles.insert(dylibFiles.end(), dylibFiles[i]->extraDylibs.begin(),
795                       dylibFiles[i]->extraDylibs.end());
796 
797   for (DylibFile *dylibFile : dylibFiles) {
798     if (dylibFile->isBundleLoader) {
799       dylibFile->ordinal = BIND_SPECIAL_DYLIB_MAIN_EXECUTABLE;
800       // Shortcut since bundle-loader does not re-export the symbols.
801 
802       dylibFile->reexport = false;
803       continue;
804     }
805 
806     // Don't emit load commands for a dylib that is not referenced if:
807     // - it was added implicitly (via a reexport, an LC_LOAD_DYLINKER --
808     //   if it's on the linker command line, it's explicit)
809     // - or it's marked MH_DEAD_STRIPPABLE_DYLIB
810     // - or the flag -dead_strip_dylibs is used
811     // FIXME: `isReferenced()` is currently computed before dead code
812     // stripping, so references from dead code keep a dylib alive. This
813     // matches ld64, but it's something we should do better.
814     if (!dylibFile->isReferenced() && !dylibFile->forceNeeded &&
815         (!dylibFile->isExplicitlyLinked() || dylibFile->deadStrippable ||
816          config->deadStripDylibs))
817       continue;
818 
819     // Several DylibFiles can have the same installName. Only emit a single
820     // load command for that installName and give all these DylibFiles the
821     // same ordinal.
822     // This can happen in several cases:
823     // - a new framework could change its installName to an older
824     //   framework name via an $ld$ symbol depending on platform_version
825     // - symlinks (for example, libpthread.tbd is a symlink to libSystem.tbd;
826     //   Foo.framework/Foo.tbd is usually a symlink to
827     //   Foo.framework/Versions/Current/Foo.tbd, where
828     //   Foo.framework/Versions/Current is usually a symlink to
829     //   Foo.framework/Versions/A)
830     // - a framework can be linked both explicitly on the linker
831     //   command line and implicitly as a reexport from a different
832     //   framework. The re-export will usually point to the tbd file
833     //   in Foo.framework/Versions/A/Foo.tbd, while the explicit link will
834     //   usually find Foo.framework/Foo.tbd. These are usually symlinks,
835     //   but in a --reproduce archive they will be identical but distinct
836     //   files.
837     // In the first case, *semantically distinct* DylibFiles will have the
838     // same installName.
839     int64_t &ordinal = ordinalForInstallName[dylibFile->installName];
840     if (ordinal) {
841       dylibFile->ordinal = ordinal;
842       continue;
843     }
844 
845     ordinal = dylibFile->ordinal = dylibOrdinal++;
846     LoadCommandType lcType =
847         dylibFile->forceWeakImport || dylibFile->refState == RefState::Weak
848             ? LC_LOAD_WEAK_DYLIB
849             : LC_LOAD_DYLIB;
850     in.header->addLoadCommand(make<LCDylib>(lcType, dylibFile->installName,
851                                             dylibFile->compatibilityVersion,
852                                             dylibFile->currentVersion));
853 
854     if (dylibFile->reexport)
855       in.header->addLoadCommand(
856           make<LCDylib>(LC_REEXPORT_DYLIB, dylibFile->installName));
857   }
858 
859   if (functionStartsSection)
860     in.header->addLoadCommand(make<LCFunctionStarts>(functionStartsSection));
861   if (dataInCodeSection)
862     in.header->addLoadCommand(make<LCDataInCode>(dataInCodeSection));
863   if (codeSignatureSection)
864     in.header->addLoadCommand(make<LCCodeSignature>(codeSignatureSection));
865 
866   const uint32_t MACOS_MAXPATHLEN = 1024;
867   config->headerPad = std::max(
868       config->headerPad, (config->headerPadMaxInstallNames
869                               ? LCDylib::getInstanceCount() * MACOS_MAXPATHLEN
870                               : 0));
871 }
872 
873 // Sorting only can happen once all outputs have been collected. Here we sort
874 // segments, output sections within each segment, and input sections within each
875 // output segment.
876 static void sortSegmentsAndSections() {
877   TimeTraceScope timeScope("Sort segments and sections");
878   sortOutputSegments();
879 
880   DenseMap<const InputSection *, size_t> isecPriorities =
881       priorityBuilder.buildInputSectionPriorities();
882 
883   uint32_t sectionIndex = 0;
884   for (OutputSegment *seg : outputSegments) {
885     seg->sortOutputSections();
886     // References from thread-local variable sections are treated as offsets
887     // relative to the start of the thread-local data memory area, which
888     // is initialized via copying all the TLV data sections (which are all
889     // contiguous). If later data sections require a greater alignment than
890     // earlier ones, the offsets of data within those sections won't be
891     // guaranteed to aligned unless we normalize alignments. We therefore use
892     // the largest alignment for all TLV data sections.
893     uint32_t tlvAlign = 0;
894     for (const OutputSection *osec : seg->getSections())
895       if (isThreadLocalData(osec->flags) && osec->align > tlvAlign)
896         tlvAlign = osec->align;
897 
898     for (OutputSection *osec : seg->getSections()) {
899       // Now that the output sections are sorted, assign the final
900       // output section indices.
901       if (!osec->isHidden())
902         osec->index = ++sectionIndex;
903       if (isThreadLocalData(osec->flags)) {
904         if (!firstTLVDataSection)
905           firstTLVDataSection = osec;
906         osec->align = tlvAlign;
907       }
908 
909       if (!isecPriorities.empty()) {
910         if (auto *merged = dyn_cast<ConcatOutputSection>(osec)) {
911           llvm::stable_sort(merged->inputs,
912                             [&](InputSection *a, InputSection *b) {
913                               return isecPriorities[a] > isecPriorities[b];
914                             });
915         }
916       }
917     }
918   }
919 }
920 
921 template <class LP> void Writer::createOutputSections() {
922   TimeTraceScope timeScope("Create output sections");
923   // First, create hidden sections
924   stringTableSection = make<StringTableSection>();
925   symtabSection = makeSymtabSection<LP>(*stringTableSection);
926   indirectSymtabSection = make<IndirectSymtabSection>();
927   if (config->adhocCodesign)
928     codeSignatureSection = make<CodeSignatureSection>();
929   if (config->emitDataInCodeInfo)
930     dataInCodeSection = make<DataInCodeSection>();
931   if (config->emitFunctionStarts)
932     functionStartsSection = make<FunctionStartsSection>();
933   if (config->emitBitcodeBundle)
934     make<BitcodeBundleSection>();
935 
936   switch (config->outputType) {
937   case MH_EXECUTE:
938     make<PageZeroSection>();
939     break;
940   case MH_DYLIB:
941   case MH_BUNDLE:
942     break;
943   default:
944     llvm_unreachable("unhandled output file type");
945   }
946 
947   // Then add input sections to output sections.
948   for (ConcatInputSection *isec : inputSections) {
949     if (isec->shouldOmitFromOutput())
950       continue;
951     ConcatOutputSection *osec = cast<ConcatOutputSection>(isec->parent);
952     osec->addInput(isec);
953     osec->inputOrder =
954         std::min(osec->inputOrder, static_cast<int>(isec->outSecOff));
955   }
956 
957   // Once all the inputs are added, we can finalize the output section
958   // properties and create the corresponding output segments.
959   for (const auto &it : concatOutputSections) {
960     StringRef segname = it.first.first;
961     ConcatOutputSection *osec = it.second;
962     assert(segname != segment_names::ld);
963     if (osec->isNeeded()) {
964       // See comment in ObjFile::splitEhFrames()
965       if (osec->name == section_names::ehFrame &&
966           segname == segment_names::text)
967         osec->align = target->wordSize;
968 
969       getOrCreateOutputSegment(segname)->addOutputSection(osec);
970     }
971   }
972 
973   for (SyntheticSection *ssec : syntheticSections) {
974     auto it = concatOutputSections.find({ssec->segname, ssec->name});
975     // We add all LinkEdit sections here because we don't know if they are
976     // needed until their finalizeContents() methods get called later. While
977     // this means that we add some redundant sections to __LINKEDIT, there is
978     // is no redundancy in the output, as we do not emit section headers for
979     // any LinkEdit sections.
980     if (ssec->isNeeded() || ssec->segname == segment_names::linkEdit) {
981       if (it == concatOutputSections.end()) {
982         getOrCreateOutputSegment(ssec->segname)->addOutputSection(ssec);
983       } else {
984         fatal("section from " +
985               toString(it->second->firstSection()->getFile()) +
986               " conflicts with synthetic section " + ssec->segname + "," +
987               ssec->name);
988       }
989     }
990   }
991 
992   // dyld requires __LINKEDIT segment to always exist (even if empty).
993   linkEditSegment = getOrCreateOutputSegment(segment_names::linkEdit);
994 }
995 
996 void Writer::finalizeAddresses() {
997   TimeTraceScope timeScope("Finalize addresses");
998   uint64_t pageSize = target->getPageSize();
999 
1000   // We could parallelize this loop, but local benchmarking indicates it is
1001   // faster to do it all in the main thread.
1002   for (OutputSegment *seg : outputSegments) {
1003     if (seg == linkEditSegment)
1004       continue;
1005     for (OutputSection *osec : seg->getSections()) {
1006       if (!osec->isNeeded())
1007         continue;
1008       // Other kinds of OutputSections have already been finalized.
1009       if (auto concatOsec = dyn_cast<ConcatOutputSection>(osec))
1010         concatOsec->finalizeContents();
1011     }
1012   }
1013 
1014   // Ensure that segments (and the sections they contain) are allocated
1015   // addresses in ascending order, which dyld requires.
1016   //
1017   // Note that at this point, __LINKEDIT sections are empty, but we need to
1018   // determine addresses of other segments/sections before generating its
1019   // contents.
1020   for (OutputSegment *seg : outputSegments) {
1021     if (seg == linkEditSegment)
1022       continue;
1023     seg->addr = addr;
1024     assignAddresses(seg);
1025     // codesign / libstuff checks for segment ordering by verifying that
1026     // `fileOff + fileSize == next segment fileOff`. So we call alignTo() before
1027     // (instead of after) computing fileSize to ensure that the segments are
1028     // contiguous. We handle addr / vmSize similarly for the same reason.
1029     fileOff = alignTo(fileOff, pageSize);
1030     addr = alignTo(addr, pageSize);
1031     seg->vmSize = addr - seg->addr;
1032     seg->fileSize = fileOff - seg->fileOff;
1033     seg->assignAddressesToStartEndSymbols();
1034   }
1035 }
1036 
1037 void Writer::finalizeLinkEditSegment() {
1038   TimeTraceScope timeScope("Finalize __LINKEDIT segment");
1039   // Fill __LINKEDIT contents.
1040   std::vector<LinkEditSection *> linkEditSections{
1041       in.rebase,
1042       in.binding,
1043       in.weakBinding,
1044       in.lazyBinding,
1045       in.exports,
1046       symtabSection,
1047       indirectSymtabSection,
1048       dataInCodeSection,
1049       functionStartsSection,
1050   };
1051   SmallVector<std::shared_future<void>> threadFutures;
1052   threadFutures.reserve(linkEditSections.size());
1053   for (LinkEditSection *osec : linkEditSections)
1054     if (osec)
1055       threadFutures.emplace_back(threadPool.async(
1056           [](LinkEditSection *osec) { osec->finalizeContents(); }, osec));
1057   for (std::shared_future<void> &future : threadFutures)
1058     future.wait();
1059 
1060   // Now that __LINKEDIT is filled out, do a proper calculation of its
1061   // addresses and offsets.
1062   linkEditSegment->addr = addr;
1063   assignAddresses(linkEditSegment);
1064   // No need to page-align fileOff / addr here since this is the last segment.
1065   linkEditSegment->vmSize = addr - linkEditSegment->addr;
1066   linkEditSegment->fileSize = fileOff - linkEditSegment->fileOff;
1067 }
1068 
1069 void Writer::assignAddresses(OutputSegment *seg) {
1070   seg->fileOff = fileOff;
1071 
1072   for (OutputSection *osec : seg->getSections()) {
1073     if (!osec->isNeeded())
1074       continue;
1075     addr = alignTo(addr, osec->align);
1076     fileOff = alignTo(fileOff, osec->align);
1077     osec->addr = addr;
1078     osec->fileOff = isZeroFill(osec->flags) ? 0 : fileOff;
1079     osec->finalize();
1080     osec->assignAddressesToStartEndSymbols();
1081 
1082     addr += osec->getSize();
1083     fileOff += osec->getFileSize();
1084   }
1085 }
1086 
1087 void Writer::openFile() {
1088   Expected<std::unique_ptr<FileOutputBuffer>> bufferOrErr =
1089       FileOutputBuffer::create(config->outputFile, fileOff,
1090                                FileOutputBuffer::F_executable);
1091 
1092   if (!bufferOrErr)
1093     fatal("failed to open " + config->outputFile + ": " +
1094           llvm::toString(bufferOrErr.takeError()));
1095   buffer = std::move(*bufferOrErr);
1096   in.bufferStart = buffer->getBufferStart();
1097 }
1098 
1099 void Writer::writeSections() {
1100   uint8_t *buf = buffer->getBufferStart();
1101   std::vector<const OutputSection *> osecs;
1102   for (const OutputSegment *seg : outputSegments)
1103     append_range(osecs, seg->getSections());
1104 
1105   parallelForEach(osecs.begin(), osecs.end(), [&](const OutputSection *osec) {
1106     osec->writeTo(buf + osec->fileOff);
1107   });
1108 }
1109 
1110 // In order to utilize multiple cores, we first split the buffer into chunks,
1111 // compute a hash for each chunk, and then compute a hash value of the hash
1112 // values.
1113 void Writer::writeUuid() {
1114   TimeTraceScope timeScope("Computing UUID");
1115 
1116   ArrayRef<uint8_t> data{buffer->getBufferStart(), buffer->getBufferEnd()};
1117   unsigned chunkCount = parallel::strategy.compute_thread_count() * 10;
1118   // Round-up integer division
1119   size_t chunkSize = (data.size() + chunkCount - 1) / chunkCount;
1120   std::vector<ArrayRef<uint8_t>> chunks = split(data, chunkSize);
1121   // Leave one slot for filename
1122   std::vector<uint64_t> hashes(chunks.size() + 1);
1123   SmallVector<std::shared_future<void>> threadFutures;
1124   threadFutures.reserve(chunks.size());
1125   for (size_t i = 0; i < chunks.size(); ++i)
1126     threadFutures.emplace_back(threadPool.async(
1127         [&](size_t j) { hashes[j] = xxHash64(chunks[j]); }, i));
1128   for (std::shared_future<void> &future : threadFutures)
1129     future.wait();
1130   // Append the output filename so that identical binaries with different names
1131   // don't get the same UUID.
1132   hashes[chunks.size()] = xxHash64(sys::path::filename(config->finalOutput));
1133   uint64_t digest = xxHash64({reinterpret_cast<uint8_t *>(hashes.data()),
1134                               hashes.size() * sizeof(uint64_t)});
1135   uuidCommand->writeUuid(digest);
1136 }
1137 
1138 void Writer::writeCodeSignature() {
1139   if (codeSignatureSection) {
1140     TimeTraceScope timeScope("Write code signature");
1141     codeSignatureSection->writeHashes(buffer->getBufferStart());
1142   }
1143 }
1144 
1145 void Writer::writeOutputFile() {
1146   TimeTraceScope timeScope("Write output file");
1147   openFile();
1148   reportPendingUndefinedSymbols();
1149   if (errorCount())
1150     return;
1151   writeSections();
1152   writeUuid();
1153   writeCodeSignature();
1154 
1155   if (auto e = buffer->commit())
1156     error("failed to write to the output file: " + toString(std::move(e)));
1157 }
1158 
1159 template <class LP> void Writer::run() {
1160   treatSpecialUndefineds();
1161   if (config->entry && !isa<Undefined>(config->entry))
1162     prepareBranchTarget(config->entry);
1163 
1164   // Canonicalization of all pointers to InputSections should be handled by
1165   // these two scan* methods. I.e. from this point onward, for all live
1166   // InputSections, we should have `isec->canonical() == isec`.
1167   scanSymbols();
1168   scanRelocations();
1169 
1170   // Do not proceed if there was an undefined symbol.
1171   reportPendingUndefinedSymbols();
1172   if (errorCount())
1173     return;
1174 
1175   if (in.stubHelper->isNeeded())
1176     in.stubHelper->setup();
1177 
1178   if (in.objCImageInfo->isNeeded())
1179     in.objCImageInfo->finalizeContents();
1180 
1181   // At this point, we should know exactly which output sections are needed,
1182   // courtesy of scanSymbols() and scanRelocations().
1183   createOutputSections<LP>();
1184 
1185   // After this point, we create no new segments; HOWEVER, we might
1186   // yet create branch-range extension thunks for architectures whose
1187   // hardware call instructions have limited range, e.g., ARM(64).
1188   // The thunks are created as InputSections interspersed among
1189   // the ordinary __TEXT,_text InputSections.
1190   sortSegmentsAndSections();
1191   createLoadCommands<LP>();
1192   finalizeAddresses();
1193   threadPool.async([&] {
1194     if (LLVM_ENABLE_THREADS && config->timeTraceEnabled)
1195       timeTraceProfilerInitialize(config->timeTraceGranularity, "writeMapFile");
1196     writeMapFile();
1197     if (LLVM_ENABLE_THREADS && config->timeTraceEnabled)
1198       timeTraceProfilerFinishThread();
1199   });
1200   finalizeLinkEditSegment();
1201   writeOutputFile();
1202 }
1203 
1204 template <class LP> void macho::writeResult() { Writer().run<LP>(); }
1205 
1206 void macho::resetWriter() { LCDylib::resetInstanceCount(); }
1207 
1208 void macho::createSyntheticSections() {
1209   in.header = make<MachHeaderSection>();
1210   if (config->dedupLiterals)
1211     in.cStringSection = make<DeduplicatedCStringSection>();
1212   else
1213     in.cStringSection = make<CStringSection>();
1214   in.wordLiteralSection =
1215       config->dedupLiterals ? make<WordLiteralSection>() : nullptr;
1216   in.rebase = make<RebaseSection>();
1217   in.binding = make<BindingSection>();
1218   in.weakBinding = make<WeakBindingSection>();
1219   in.lazyBinding = make<LazyBindingSection>();
1220   in.exports = make<ExportSection>();
1221   in.got = make<GotSection>();
1222   in.tlvPointers = make<TlvPointerSection>();
1223   in.lazyPointers = make<LazyPointerSection>();
1224   in.stubs = make<StubsSection>();
1225   in.stubHelper = make<StubHelperSection>();
1226   in.unwindInfo = makeUnwindInfoSection();
1227   in.objCImageInfo = make<ObjCImageInfoSection>();
1228 
1229   // This section contains space for just a single word, and will be used by
1230   // dyld to cache an address to the image loader it uses.
1231   uint8_t *arr = bAlloc().Allocate<uint8_t>(target->wordSize);
1232   memset(arr, 0, target->wordSize);
1233   in.imageLoaderCache = makeSyntheticInputSection(
1234       segment_names::data, section_names::data, S_REGULAR,
1235       ArrayRef<uint8_t>{arr, target->wordSize},
1236       /*align=*/target->wordSize);
1237   // References from dyld are not visible to us, so ensure this section is
1238   // always treated as live.
1239   in.imageLoaderCache->live = true;
1240 }
1241 
1242 OutputSection *macho::firstTLVDataSection = nullptr;
1243 
1244 template void macho::writeResult<LP64>();
1245 template void macho::writeResult<ILP32>();
1246