xref: /freebsd/contrib/llvm-project/clang/lib/Lex/ModuleMap.cpp (revision 1db9f3b21e39176dd5b67cf8ac378633b172463e)
1 //===- ModuleMap.cpp - Describe the layout of modules ---------------------===//
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 // This file defines the ModuleMap implementation, which describes the layout
10 // of a module as it relates to headers.
11 //
12 //===----------------------------------------------------------------------===//
13 
14 #include "clang/Lex/ModuleMap.h"
15 #include "clang/Basic/CharInfo.h"
16 #include "clang/Basic/Diagnostic.h"
17 #include "clang/Basic/FileManager.h"
18 #include "clang/Basic/LLVM.h"
19 #include "clang/Basic/LangOptions.h"
20 #include "clang/Basic/Module.h"
21 #include "clang/Basic/SourceLocation.h"
22 #include "clang/Basic/SourceManager.h"
23 #include "clang/Basic/TargetInfo.h"
24 #include "clang/Lex/HeaderSearch.h"
25 #include "clang/Lex/HeaderSearchOptions.h"
26 #include "clang/Lex/LexDiagnostic.h"
27 #include "clang/Lex/Lexer.h"
28 #include "clang/Lex/LiteralSupport.h"
29 #include "clang/Lex/Token.h"
30 #include "llvm/ADT/DenseMap.h"
31 #include "llvm/ADT/STLExtras.h"
32 #include "llvm/ADT/SmallPtrSet.h"
33 #include "llvm/ADT/SmallString.h"
34 #include "llvm/ADT/SmallVector.h"
35 #include "llvm/ADT/StringMap.h"
36 #include "llvm/ADT/StringRef.h"
37 #include "llvm/ADT/StringSwitch.h"
38 #include "llvm/Support/Allocator.h"
39 #include "llvm/Support/Compiler.h"
40 #include "llvm/Support/ErrorHandling.h"
41 #include "llvm/Support/MemoryBuffer.h"
42 #include "llvm/Support/Path.h"
43 #include "llvm/Support/VirtualFileSystem.h"
44 #include "llvm/Support/raw_ostream.h"
45 #include <algorithm>
46 #include <cassert>
47 #include <cstdint>
48 #include <cstring>
49 #include <optional>
50 #include <string>
51 #include <system_error>
52 #include <utility>
53 
54 using namespace clang;
55 
56 void ModuleMapCallbacks::anchor() {}
57 
58 void ModuleMap::resolveLinkAsDependencies(Module *Mod) {
59   auto PendingLinkAs = PendingLinkAsModule.find(Mod->Name);
60   if (PendingLinkAs != PendingLinkAsModule.end()) {
61     for (auto &Name : PendingLinkAs->second) {
62       auto *M = findModule(Name.getKey());
63       if (M)
64         M->UseExportAsModuleLinkName = true;
65     }
66   }
67 }
68 
69 void ModuleMap::addLinkAsDependency(Module *Mod) {
70   if (findModule(Mod->ExportAsModule))
71     Mod->UseExportAsModuleLinkName = true;
72   else
73     PendingLinkAsModule[Mod->ExportAsModule].insert(Mod->Name);
74 }
75 
76 Module::HeaderKind ModuleMap::headerRoleToKind(ModuleHeaderRole Role) {
77   switch ((int)Role) {
78   case NormalHeader:
79     return Module::HK_Normal;
80   case PrivateHeader:
81     return Module::HK_Private;
82   case TextualHeader:
83     return Module::HK_Textual;
84   case PrivateHeader | TextualHeader:
85     return Module::HK_PrivateTextual;
86   case ExcludedHeader:
87     return Module::HK_Excluded;
88   }
89   llvm_unreachable("unknown header role");
90 }
91 
92 ModuleMap::ModuleHeaderRole
93 ModuleMap::headerKindToRole(Module::HeaderKind Kind) {
94   switch ((int)Kind) {
95   case Module::HK_Normal:
96     return NormalHeader;
97   case Module::HK_Private:
98     return PrivateHeader;
99   case Module::HK_Textual:
100     return TextualHeader;
101   case Module::HK_PrivateTextual:
102     return ModuleHeaderRole(PrivateHeader | TextualHeader);
103   case Module::HK_Excluded:
104     return ExcludedHeader;
105   }
106   llvm_unreachable("unknown header kind");
107 }
108 
109 bool ModuleMap::isModular(ModuleHeaderRole Role) {
110   return !(Role & (ModuleMap::TextualHeader | ModuleMap::ExcludedHeader));
111 }
112 
113 Module::ExportDecl
114 ModuleMap::resolveExport(Module *Mod,
115                          const Module::UnresolvedExportDecl &Unresolved,
116                          bool Complain) const {
117   // We may have just a wildcard.
118   if (Unresolved.Id.empty()) {
119     assert(Unresolved.Wildcard && "Invalid unresolved export");
120     return Module::ExportDecl(nullptr, true);
121   }
122 
123   // Resolve the module-id.
124   Module *Context = resolveModuleId(Unresolved.Id, Mod, Complain);
125   if (!Context)
126     return {};
127 
128   return Module::ExportDecl(Context, Unresolved.Wildcard);
129 }
130 
131 Module *ModuleMap::resolveModuleId(const ModuleId &Id, Module *Mod,
132                                    bool Complain) const {
133   // Find the starting module.
134   Module *Context = lookupModuleUnqualified(Id[0].first, Mod);
135   if (!Context) {
136     if (Complain)
137       Diags.Report(Id[0].second, diag::err_mmap_missing_module_unqualified)
138       << Id[0].first << Mod->getFullModuleName();
139 
140     return nullptr;
141   }
142 
143   // Dig into the module path.
144   for (unsigned I = 1, N = Id.size(); I != N; ++I) {
145     Module *Sub = lookupModuleQualified(Id[I].first, Context);
146     if (!Sub) {
147       if (Complain)
148         Diags.Report(Id[I].second, diag::err_mmap_missing_module_qualified)
149         << Id[I].first << Context->getFullModuleName()
150         << SourceRange(Id[0].second, Id[I-1].second);
151 
152       return nullptr;
153     }
154 
155     Context = Sub;
156   }
157 
158   return Context;
159 }
160 
161 /// Append to \p Paths the set of paths needed to get to the
162 /// subframework in which the given module lives.
163 static void appendSubframeworkPaths(Module *Mod,
164                                     SmallVectorImpl<char> &Path) {
165   // Collect the framework names from the given module to the top-level module.
166   SmallVector<StringRef, 2> Paths;
167   for (; Mod; Mod = Mod->Parent) {
168     if (Mod->IsFramework)
169       Paths.push_back(Mod->Name);
170   }
171 
172   if (Paths.empty())
173     return;
174 
175   // Add Frameworks/Name.framework for each subframework.
176   for (StringRef Framework : llvm::drop_begin(llvm::reverse(Paths)))
177     llvm::sys::path::append(Path, "Frameworks", Framework + ".framework");
178 }
179 
180 OptionalFileEntryRef ModuleMap::findHeader(
181     Module *M, const Module::UnresolvedHeaderDirective &Header,
182     SmallVectorImpl<char> &RelativePathName, bool &NeedsFramework) {
183   // Search for the header file within the module's home directory.
184   auto Directory = M->Directory;
185   SmallString<128> FullPathName(Directory->getName());
186 
187   auto GetFile = [&](StringRef Filename) -> OptionalFileEntryRef {
188     auto File =
189         expectedToOptional(SourceMgr.getFileManager().getFileRef(Filename));
190     if (!File || (Header.Size && File->getSize() != *Header.Size) ||
191         (Header.ModTime && File->getModificationTime() != *Header.ModTime))
192       return std::nullopt;
193     return *File;
194   };
195 
196   auto GetFrameworkFile = [&]() -> OptionalFileEntryRef {
197     unsigned FullPathLength = FullPathName.size();
198     appendSubframeworkPaths(M, RelativePathName);
199     unsigned RelativePathLength = RelativePathName.size();
200 
201     // Check whether this file is in the public headers.
202     llvm::sys::path::append(RelativePathName, "Headers", Header.FileName);
203     llvm::sys::path::append(FullPathName, RelativePathName);
204     if (auto File = GetFile(FullPathName))
205       return File;
206 
207     // Check whether this file is in the private headers.
208     // Ideally, private modules in the form 'FrameworkName.Private' should
209     // be defined as 'module FrameworkName.Private', and not as
210     // 'framework module FrameworkName.Private', since a 'Private.Framework'
211     // does not usually exist. However, since both are currently widely used
212     // for private modules, make sure we find the right path in both cases.
213     if (M->IsFramework && M->Name == "Private")
214       RelativePathName.clear();
215     else
216       RelativePathName.resize(RelativePathLength);
217     FullPathName.resize(FullPathLength);
218     llvm::sys::path::append(RelativePathName, "PrivateHeaders",
219                             Header.FileName);
220     llvm::sys::path::append(FullPathName, RelativePathName);
221     return GetFile(FullPathName);
222   };
223 
224   if (llvm::sys::path::is_absolute(Header.FileName)) {
225     RelativePathName.clear();
226     RelativePathName.append(Header.FileName.begin(), Header.FileName.end());
227     return GetFile(Header.FileName);
228   }
229 
230   if (M->isPartOfFramework())
231     return GetFrameworkFile();
232 
233   // Lookup for normal headers.
234   llvm::sys::path::append(RelativePathName, Header.FileName);
235   llvm::sys::path::append(FullPathName, RelativePathName);
236   auto NormalHdrFile = GetFile(FullPathName);
237 
238   if (!NormalHdrFile && Directory->getName().ends_with(".framework")) {
239     // The lack of 'framework' keyword in a module declaration it's a simple
240     // mistake we can diagnose when the header exists within the proper
241     // framework style path.
242     FullPathName.assign(Directory->getName());
243     RelativePathName.clear();
244     if (GetFrameworkFile()) {
245       Diags.Report(Header.FileNameLoc,
246                    diag::warn_mmap_incomplete_framework_module_declaration)
247           << Header.FileName << M->getFullModuleName();
248       NeedsFramework = true;
249     }
250     return std::nullopt;
251   }
252 
253   return NormalHdrFile;
254 }
255 
256 /// Determine whether the given file name is the name of a builtin
257 /// header, supplied by Clang to replace, override, or augment existing system
258 /// headers.
259 static bool isBuiltinHeaderName(StringRef FileName) {
260   return llvm::StringSwitch<bool>(FileName)
261            .Case("float.h", true)
262            .Case("iso646.h", true)
263            .Case("limits.h", true)
264            .Case("stdalign.h", true)
265            .Case("stdarg.h", true)
266            .Case("stdatomic.h", true)
267            .Case("stdbool.h", true)
268            .Case("stddef.h", true)
269            .Case("stdint.h", true)
270            .Case("tgmath.h", true)
271            .Case("unwind.h", true)
272            .Default(false);
273 }
274 
275 /// Determine whether the given module name is the name of a builtin
276 /// module that is cyclic with a system module  on some platforms.
277 static bool isBuiltInModuleName(StringRef ModuleName) {
278   return llvm::StringSwitch<bool>(ModuleName)
279            .Case("_Builtin_float", true)
280            .Case("_Builtin_inttypes", true)
281            .Case("_Builtin_iso646", true)
282            .Case("_Builtin_limits", true)
283            .Case("_Builtin_stdalign", true)
284            .Case("_Builtin_stdarg", true)
285            .Case("_Builtin_stdatomic", true)
286            .Case("_Builtin_stdbool", true)
287            .Case("_Builtin_stddef", true)
288            .Case("_Builtin_stdint", true)
289            .Case("_Builtin_stdnoreturn", true)
290            .Case("_Builtin_tgmath", true)
291            .Case("_Builtin_unwind", true)
292            .Default(false);
293 }
294 
295 void ModuleMap::resolveHeader(Module *Mod,
296                               const Module::UnresolvedHeaderDirective &Header,
297                               bool &NeedsFramework) {
298   SmallString<128> RelativePathName;
299   if (OptionalFileEntryRef File =
300           findHeader(Mod, Header, RelativePathName, NeedsFramework)) {
301     if (Header.IsUmbrella) {
302       const DirectoryEntry *UmbrellaDir = &File->getDir().getDirEntry();
303       if (Module *UmbrellaMod = UmbrellaDirs[UmbrellaDir])
304         Diags.Report(Header.FileNameLoc, diag::err_mmap_umbrella_clash)
305           << UmbrellaMod->getFullModuleName();
306       else
307         // Record this umbrella header.
308         setUmbrellaHeaderAsWritten(Mod, *File, Header.FileName,
309                                    RelativePathName.str());
310     } else {
311       Module::Header H = {Header.FileName, std::string(RelativePathName.str()),
312                           *File};
313       addHeader(Mod, H, headerKindToRole(Header.Kind));
314     }
315   } else if (Header.HasBuiltinHeader && !Header.Size && !Header.ModTime) {
316     // There's a builtin header but no corresponding on-disk header. Assume
317     // this was supposed to modularize the builtin header alone.
318   } else if (Header.Kind == Module::HK_Excluded) {
319     // Ignore missing excluded header files. They're optional anyway.
320   } else {
321     // If we find a module that has a missing header, we mark this module as
322     // unavailable and store the header directive for displaying diagnostics.
323     Mod->MissingHeaders.push_back(Header);
324     // A missing header with stat information doesn't make the module
325     // unavailable; this keeps our behavior consistent as headers are lazily
326     // resolved. (Such a module still can't be built though, except from
327     // preprocessed source.)
328     if (!Header.Size && !Header.ModTime)
329       Mod->markUnavailable(/*Unimportable=*/false);
330   }
331 }
332 
333 bool ModuleMap::resolveAsBuiltinHeader(
334     Module *Mod, const Module::UnresolvedHeaderDirective &Header) {
335   if (Header.Kind == Module::HK_Excluded ||
336       llvm::sys::path::is_absolute(Header.FileName) ||
337       Mod->isPartOfFramework() || !Mod->IsSystem || Header.IsUmbrella ||
338       !BuiltinIncludeDir || BuiltinIncludeDir == Mod->Directory ||
339       !LangOpts.BuiltinHeadersInSystemModules || !isBuiltinHeaderName(Header.FileName))
340     return false;
341 
342   // This is a system module with a top-level header. This header
343   // may have a counterpart (or replacement) in the set of headers
344   // supplied by Clang. Find that builtin header.
345   SmallString<128> Path;
346   llvm::sys::path::append(Path, BuiltinIncludeDir->getName(), Header.FileName);
347   auto File = SourceMgr.getFileManager().getOptionalFileRef(Path);
348   if (!File)
349     return false;
350 
351   Module::Header H = {Header.FileName, Header.FileName, *File};
352   auto Role = headerKindToRole(Header.Kind);
353   addHeader(Mod, H, Role);
354   return true;
355 }
356 
357 ModuleMap::ModuleMap(SourceManager &SourceMgr, DiagnosticsEngine &Diags,
358                      const LangOptions &LangOpts, const TargetInfo *Target,
359                      HeaderSearch &HeaderInfo)
360     : SourceMgr(SourceMgr), Diags(Diags), LangOpts(LangOpts), Target(Target),
361       HeaderInfo(HeaderInfo) {
362   MMapLangOpts.LineComment = true;
363 }
364 
365 ModuleMap::~ModuleMap() {
366   for (auto &M : Modules)
367     delete M.getValue();
368   for (auto *M : ShadowModules)
369     delete M;
370 }
371 
372 void ModuleMap::setTarget(const TargetInfo &Target) {
373   assert((!this->Target || this->Target == &Target) &&
374          "Improper target override");
375   this->Target = &Target;
376 }
377 
378 /// "Sanitize" a filename so that it can be used as an identifier.
379 static StringRef sanitizeFilenameAsIdentifier(StringRef Name,
380                                               SmallVectorImpl<char> &Buffer) {
381   if (Name.empty())
382     return Name;
383 
384   if (!isValidAsciiIdentifier(Name)) {
385     // If we don't already have something with the form of an identifier,
386     // create a buffer with the sanitized name.
387     Buffer.clear();
388     if (isDigit(Name[0]))
389       Buffer.push_back('_');
390     Buffer.reserve(Buffer.size() + Name.size());
391     for (unsigned I = 0, N = Name.size(); I != N; ++I) {
392       if (isAsciiIdentifierContinue(Name[I]))
393         Buffer.push_back(Name[I]);
394       else
395         Buffer.push_back('_');
396     }
397 
398     Name = StringRef(Buffer.data(), Buffer.size());
399   }
400 
401   while (llvm::StringSwitch<bool>(Name)
402 #define KEYWORD(Keyword,Conditions) .Case(#Keyword, true)
403 #define ALIAS(Keyword, AliasOf, Conditions) .Case(Keyword, true)
404 #include "clang/Basic/TokenKinds.def"
405            .Default(false)) {
406     if (Name.data() != Buffer.data())
407       Buffer.append(Name.begin(), Name.end());
408     Buffer.push_back('_');
409     Name = StringRef(Buffer.data(), Buffer.size());
410   }
411 
412   return Name;
413 }
414 
415 bool ModuleMap::isBuiltinHeader(FileEntryRef File) {
416   return File.getDir() == BuiltinIncludeDir && LangOpts.BuiltinHeadersInSystemModules &&
417          isBuiltinHeaderName(llvm::sys::path::filename(File.getName()));
418 }
419 
420 bool ModuleMap::shouldImportRelativeToBuiltinIncludeDir(StringRef FileName,
421                                                         Module *Module) const {
422   return LangOpts.BuiltinHeadersInSystemModules && BuiltinIncludeDir &&
423          Module->IsSystem && !Module->isPartOfFramework() &&
424          isBuiltinHeaderName(FileName);
425 }
426 
427 ModuleMap::HeadersMap::iterator ModuleMap::findKnownHeader(FileEntryRef File) {
428   resolveHeaderDirectives(File);
429   HeadersMap::iterator Known = Headers.find(File);
430   if (HeaderInfo.getHeaderSearchOpts().ImplicitModuleMaps &&
431       Known == Headers.end() && ModuleMap::isBuiltinHeader(File)) {
432     HeaderInfo.loadTopLevelSystemModules();
433     return Headers.find(File);
434   }
435   return Known;
436 }
437 
438 ModuleMap::KnownHeader ModuleMap::findHeaderInUmbrellaDirs(
439     FileEntryRef File, SmallVectorImpl<DirectoryEntryRef> &IntermediateDirs) {
440   if (UmbrellaDirs.empty())
441     return {};
442 
443   OptionalDirectoryEntryRef Dir = File.getDir();
444 
445   // Note: as an egregious but useful hack we use the real path here, because
446   // frameworks moving from top-level frameworks to embedded frameworks tend
447   // to be symlinked from the top-level location to the embedded location,
448   // and we need to resolve lookups as if we had found the embedded location.
449   StringRef DirName = SourceMgr.getFileManager().getCanonicalName(*Dir);
450 
451   // Keep walking up the directory hierarchy, looking for a directory with
452   // an umbrella header.
453   do {
454     auto KnownDir = UmbrellaDirs.find(*Dir);
455     if (KnownDir != UmbrellaDirs.end())
456       return KnownHeader(KnownDir->second, NormalHeader);
457 
458     IntermediateDirs.push_back(*Dir);
459 
460     // Retrieve our parent path.
461     DirName = llvm::sys::path::parent_path(DirName);
462     if (DirName.empty())
463       break;
464 
465     // Resolve the parent path to a directory entry.
466     Dir = SourceMgr.getFileManager().getOptionalDirectoryRef(DirName);
467   } while (Dir);
468   return {};
469 }
470 
471 static bool violatesPrivateInclude(Module *RequestingModule,
472                                    const FileEntry *IncFileEnt,
473                                    ModuleMap::KnownHeader Header) {
474 #ifndef NDEBUG
475   if (Header.getRole() & ModuleMap::PrivateHeader) {
476     // Check for consistency between the module header role
477     // as obtained from the lookup and as obtained from the module.
478     // This check is not cheap, so enable it only for debugging.
479     bool IsPrivate = false;
480     SmallVectorImpl<Module::Header> *HeaderList[] = {
481         &Header.getModule()->Headers[Module::HK_Private],
482         &Header.getModule()->Headers[Module::HK_PrivateTextual]};
483     for (auto *Hs : HeaderList)
484       IsPrivate |= llvm::any_of(
485           *Hs, [&](const Module::Header &H) { return H.Entry == IncFileEnt; });
486     assert(IsPrivate && "inconsistent headers and roles");
487   }
488 #endif
489   return !Header.isAccessibleFrom(RequestingModule);
490 }
491 
492 static Module *getTopLevelOrNull(Module *M) {
493   return M ? M->getTopLevelModule() : nullptr;
494 }
495 
496 void ModuleMap::diagnoseHeaderInclusion(Module *RequestingModule,
497                                         bool RequestingModuleIsModuleInterface,
498                                         SourceLocation FilenameLoc,
499                                         StringRef Filename, FileEntryRef File) {
500   // No errors for indirect modules. This may be a bit of a problem for modules
501   // with no source files.
502   if (getTopLevelOrNull(RequestingModule) != getTopLevelOrNull(SourceModule))
503     return;
504 
505   if (RequestingModule) {
506     resolveUses(RequestingModule, /*Complain=*/false);
507     resolveHeaderDirectives(RequestingModule, /*File=*/std::nullopt);
508   }
509 
510   bool Excluded = false;
511   Module *Private = nullptr;
512   Module *NotUsed = nullptr;
513 
514   HeadersMap::iterator Known = findKnownHeader(File);
515   if (Known != Headers.end()) {
516     for (const KnownHeader &Header : Known->second) {
517       // Excluded headers don't really belong to a module.
518       if (Header.getRole() == ModuleMap::ExcludedHeader) {
519         Excluded = true;
520         continue;
521       }
522 
523       // Remember private headers for later printing of a diagnostic.
524       if (violatesPrivateInclude(RequestingModule, File, Header)) {
525         Private = Header.getModule();
526         continue;
527       }
528 
529       // If uses need to be specified explicitly, we are only allowed to return
530       // modules that are explicitly used by the requesting module.
531       if (RequestingModule && LangOpts.ModulesDeclUse &&
532           !RequestingModule->directlyUses(Header.getModule())) {
533         NotUsed = Header.getModule();
534         continue;
535       }
536 
537       // We have found a module that we can happily use.
538       return;
539     }
540 
541     Excluded = true;
542   }
543 
544   // We have found a header, but it is private.
545   if (Private) {
546     Diags.Report(FilenameLoc, diag::warn_use_of_private_header_outside_module)
547         << Filename;
548     return;
549   }
550 
551   // We have found a module, but we don't use it.
552   if (NotUsed) {
553     Diags.Report(FilenameLoc, diag::err_undeclared_use_of_module_indirect)
554         << RequestingModule->getTopLevelModule()->Name << Filename
555         << NotUsed->Name;
556     return;
557   }
558 
559   if (Excluded || isHeaderInUmbrellaDirs(File))
560     return;
561 
562   // At this point, only non-modular includes remain.
563 
564   if (RequestingModule && LangOpts.ModulesStrictDeclUse) {
565     Diags.Report(FilenameLoc, diag::err_undeclared_use_of_module)
566         << RequestingModule->getTopLevelModule()->Name << Filename;
567   } else if (RequestingModule && RequestingModuleIsModuleInterface &&
568              LangOpts.isCompilingModule()) {
569     // Do not diagnose when we are not compiling a module.
570     diag::kind DiagID = RequestingModule->getTopLevelModule()->IsFramework ?
571         diag::warn_non_modular_include_in_framework_module :
572         diag::warn_non_modular_include_in_module;
573     Diags.Report(FilenameLoc, DiagID) << RequestingModule->getFullModuleName()
574         << File.getName();
575   }
576 }
577 
578 static bool isBetterKnownHeader(const ModuleMap::KnownHeader &New,
579                                 const ModuleMap::KnownHeader &Old) {
580   // Prefer available modules.
581   // FIXME: Considering whether the module is available rather than merely
582   // importable is non-hermetic and can result in surprising behavior for
583   // prebuilt modules. Consider only checking for importability here.
584   if (New.getModule()->isAvailable() && !Old.getModule()->isAvailable())
585     return true;
586 
587   // Prefer a public header over a private header.
588   if ((New.getRole() & ModuleMap::PrivateHeader) !=
589       (Old.getRole() & ModuleMap::PrivateHeader))
590     return !(New.getRole() & ModuleMap::PrivateHeader);
591 
592   // Prefer a non-textual header over a textual header.
593   if ((New.getRole() & ModuleMap::TextualHeader) !=
594       (Old.getRole() & ModuleMap::TextualHeader))
595     return !(New.getRole() & ModuleMap::TextualHeader);
596 
597   // Prefer a non-excluded header over an excluded header.
598   if ((New.getRole() == ModuleMap::ExcludedHeader) !=
599       (Old.getRole() == ModuleMap::ExcludedHeader))
600     return New.getRole() != ModuleMap::ExcludedHeader;
601 
602   // Don't have a reason to choose between these. Just keep the first one.
603   return false;
604 }
605 
606 ModuleMap::KnownHeader ModuleMap::findModuleForHeader(FileEntryRef File,
607                                                       bool AllowTextual,
608                                                       bool AllowExcluded) {
609   auto MakeResult = [&](ModuleMap::KnownHeader R) -> ModuleMap::KnownHeader {
610     if (!AllowTextual && R.getRole() & ModuleMap::TextualHeader)
611       return {};
612     return R;
613   };
614 
615   HeadersMap::iterator Known = findKnownHeader(File);
616   if (Known != Headers.end()) {
617     ModuleMap::KnownHeader Result;
618     // Iterate over all modules that 'File' is part of to find the best fit.
619     for (KnownHeader &H : Known->second) {
620       // Cannot use a module if the header is excluded in it.
621       if (!AllowExcluded && H.getRole() == ModuleMap::ExcludedHeader)
622         continue;
623       // Prefer a header from the source module over all others.
624       if (H.getModule()->getTopLevelModule() == SourceModule)
625         return MakeResult(H);
626       if (!Result || isBetterKnownHeader(H, Result))
627         Result = H;
628     }
629     return MakeResult(Result);
630   }
631 
632   return MakeResult(findOrCreateModuleForHeaderInUmbrellaDir(File));
633 }
634 
635 ModuleMap::KnownHeader
636 ModuleMap::findOrCreateModuleForHeaderInUmbrellaDir(FileEntryRef File) {
637   assert(!Headers.count(File) && "already have a module for this header");
638 
639   SmallVector<DirectoryEntryRef, 2> SkippedDirs;
640   KnownHeader H = findHeaderInUmbrellaDirs(File, SkippedDirs);
641   if (H) {
642     Module *Result = H.getModule();
643 
644     // Search up the module stack until we find a module with an umbrella
645     // directory.
646     Module *UmbrellaModule = Result;
647     while (!UmbrellaModule->getEffectiveUmbrellaDir() && UmbrellaModule->Parent)
648       UmbrellaModule = UmbrellaModule->Parent;
649 
650     if (UmbrellaModule->InferSubmodules) {
651       OptionalFileEntryRef UmbrellaModuleMap =
652           getModuleMapFileForUniquing(UmbrellaModule);
653 
654       // Infer submodules for each of the directories we found between
655       // the directory of the umbrella header and the directory where
656       // the actual header is located.
657       bool Explicit = UmbrellaModule->InferExplicitSubmodules;
658 
659       for (DirectoryEntryRef SkippedDir : llvm::reverse(SkippedDirs)) {
660         // Find or create the module that corresponds to this directory name.
661         SmallString<32> NameBuf;
662         StringRef Name = sanitizeFilenameAsIdentifier(
663             llvm::sys::path::stem(SkippedDir.getName()), NameBuf);
664         Result = findOrCreateModule(Name, Result, /*IsFramework=*/false,
665                                     Explicit).first;
666         InferredModuleAllowedBy[Result] = UmbrellaModuleMap;
667         Result->IsInferred = true;
668 
669         // Associate the module and the directory.
670         UmbrellaDirs[SkippedDir] = Result;
671 
672         // If inferred submodules export everything they import, add a
673         // wildcard to the set of exports.
674         if (UmbrellaModule->InferExportWildcard && Result->Exports.empty())
675           Result->Exports.push_back(Module::ExportDecl(nullptr, true));
676       }
677 
678       // Infer a submodule with the same name as this header file.
679       SmallString<32> NameBuf;
680       StringRef Name = sanitizeFilenameAsIdentifier(
681                          llvm::sys::path::stem(File.getName()), NameBuf);
682       Result = findOrCreateModule(Name, Result, /*IsFramework=*/false,
683                                   Explicit).first;
684       InferredModuleAllowedBy[Result] = UmbrellaModuleMap;
685       Result->IsInferred = true;
686       Result->addTopHeader(File);
687 
688       // If inferred submodules export everything they import, add a
689       // wildcard to the set of exports.
690       if (UmbrellaModule->InferExportWildcard && Result->Exports.empty())
691         Result->Exports.push_back(Module::ExportDecl(nullptr, true));
692     } else {
693       // Record each of the directories we stepped through as being part of
694       // the module we found, since the umbrella header covers them all.
695       for (unsigned I = 0, N = SkippedDirs.size(); I != N; ++I)
696         UmbrellaDirs[SkippedDirs[I]] = Result;
697     }
698 
699     KnownHeader Header(Result, NormalHeader);
700     Headers[File].push_back(Header);
701     return Header;
702   }
703 
704   return {};
705 }
706 
707 ArrayRef<ModuleMap::KnownHeader>
708 ModuleMap::findAllModulesForHeader(FileEntryRef File) {
709   HeadersMap::iterator Known = findKnownHeader(File);
710   if (Known != Headers.end())
711     return Known->second;
712 
713   if (findOrCreateModuleForHeaderInUmbrellaDir(File))
714     return Headers.find(File)->second;
715 
716   return std::nullopt;
717 }
718 
719 ArrayRef<ModuleMap::KnownHeader>
720 ModuleMap::findResolvedModulesForHeader(FileEntryRef File) const {
721   // FIXME: Is this necessary?
722   resolveHeaderDirectives(File);
723   auto It = Headers.find(File);
724   if (It == Headers.end())
725     return std::nullopt;
726   return It->second;
727 }
728 
729 bool ModuleMap::isHeaderInUnavailableModule(FileEntryRef Header) const {
730   return isHeaderUnavailableInModule(Header, nullptr);
731 }
732 
733 bool ModuleMap::isHeaderUnavailableInModule(
734     FileEntryRef Header, const Module *RequestingModule) const {
735   resolveHeaderDirectives(Header);
736   HeadersMap::const_iterator Known = Headers.find(Header);
737   if (Known != Headers.end()) {
738     for (SmallVectorImpl<KnownHeader>::const_iterator
739              I = Known->second.begin(),
740              E = Known->second.end();
741          I != E; ++I) {
742 
743       if (I->getRole() == ModuleMap::ExcludedHeader)
744         continue;
745 
746       if (I->isAvailable() &&
747           (!RequestingModule ||
748            I->getModule()->isSubModuleOf(RequestingModule))) {
749         // When no requesting module is available, the caller is looking if a
750         // header is part a module by only looking into the module map. This is
751         // done by warn_uncovered_module_header checks; don't consider textual
752         // headers part of it in this mode, otherwise we get misleading warnings
753         // that a umbrella header is not including a textual header.
754         if (!RequestingModule && I->getRole() == ModuleMap::TextualHeader)
755           continue;
756         return false;
757       }
758     }
759     return true;
760   }
761 
762   OptionalDirectoryEntryRef Dir = Header.getDir();
763   SmallVector<DirectoryEntryRef, 2> SkippedDirs;
764   StringRef DirName = Dir->getName();
765 
766   auto IsUnavailable = [&](const Module *M) {
767     return !M->isAvailable() && (!RequestingModule ||
768                                  M->isSubModuleOf(RequestingModule));
769   };
770 
771   // Keep walking up the directory hierarchy, looking for a directory with
772   // an umbrella header.
773   do {
774     auto KnownDir = UmbrellaDirs.find(*Dir);
775     if (KnownDir != UmbrellaDirs.end()) {
776       Module *Found = KnownDir->second;
777       if (IsUnavailable(Found))
778         return true;
779 
780       // Search up the module stack until we find a module with an umbrella
781       // directory.
782       Module *UmbrellaModule = Found;
783       while (!UmbrellaModule->getEffectiveUmbrellaDir() &&
784              UmbrellaModule->Parent)
785         UmbrellaModule = UmbrellaModule->Parent;
786 
787       if (UmbrellaModule->InferSubmodules) {
788         for (DirectoryEntryRef SkippedDir : llvm::reverse(SkippedDirs)) {
789           // Find or create the module that corresponds to this directory name.
790           SmallString<32> NameBuf;
791           StringRef Name = sanitizeFilenameAsIdentifier(
792               llvm::sys::path::stem(SkippedDir.getName()), NameBuf);
793           Found = lookupModuleQualified(Name, Found);
794           if (!Found)
795             return false;
796           if (IsUnavailable(Found))
797             return true;
798         }
799 
800         // Infer a submodule with the same name as this header file.
801         SmallString<32> NameBuf;
802         StringRef Name = sanitizeFilenameAsIdentifier(
803                            llvm::sys::path::stem(Header.getName()),
804                            NameBuf);
805         Found = lookupModuleQualified(Name, Found);
806         if (!Found)
807           return false;
808       }
809 
810       return IsUnavailable(Found);
811     }
812 
813     SkippedDirs.push_back(*Dir);
814 
815     // Retrieve our parent path.
816     DirName = llvm::sys::path::parent_path(DirName);
817     if (DirName.empty())
818       break;
819 
820     // Resolve the parent path to a directory entry.
821     Dir = SourceMgr.getFileManager().getOptionalDirectoryRef(DirName);
822   } while (Dir);
823 
824   return false;
825 }
826 
827 Module *ModuleMap::findModule(StringRef Name) const {
828   llvm::StringMap<Module *>::const_iterator Known = Modules.find(Name);
829   if (Known != Modules.end())
830     return Known->getValue();
831 
832   return nullptr;
833 }
834 
835 Module *ModuleMap::lookupModuleUnqualified(StringRef Name,
836                                            Module *Context) const {
837   for(; Context; Context = Context->Parent) {
838     if (Module *Sub = lookupModuleQualified(Name, Context))
839       return Sub;
840   }
841 
842   return findModule(Name);
843 }
844 
845 Module *ModuleMap::lookupModuleQualified(StringRef Name, Module *Context) const{
846   if (!Context)
847     return findModule(Name);
848 
849   return Context->findSubmodule(Name);
850 }
851 
852 std::pair<Module *, bool> ModuleMap::findOrCreateModule(StringRef Name,
853                                                         Module *Parent,
854                                                         bool IsFramework,
855                                                         bool IsExplicit) {
856   // Try to find an existing module with this name.
857   if (Module *Sub = lookupModuleQualified(Name, Parent))
858     return std::make_pair(Sub, false);
859 
860   // Create a new module with this name.
861   Module *Result = new Module(Name, SourceLocation(), Parent, IsFramework,
862                               IsExplicit, NumCreatedModules++);
863   if (!Parent) {
864     if (LangOpts.CurrentModule == Name)
865       SourceModule = Result;
866     Modules[Name] = Result;
867     ModuleScopeIDs[Result] = CurrentModuleScopeID;
868   }
869   return std::make_pair(Result, true);
870 }
871 
872 Module *ModuleMap::createGlobalModuleFragmentForModuleUnit(SourceLocation Loc,
873                                                            Module *Parent) {
874   auto *Result = new Module("<global>", Loc, Parent, /*IsFramework*/ false,
875                             /*IsExplicit*/ true, NumCreatedModules++);
876   Result->Kind = Module::ExplicitGlobalModuleFragment;
877   // If the created module isn't owned by a parent, send it to PendingSubmodules
878   // to wait for its parent.
879   if (!Result->Parent)
880     PendingSubmodules.emplace_back(Result);
881   return Result;
882 }
883 
884 Module *
885 ModuleMap::createImplicitGlobalModuleFragmentForModuleUnit(SourceLocation Loc,
886                                                            Module *Parent) {
887   assert(Parent && "We should only create an implicit global module fragment "
888                    "in a module purview");
889   // Note: Here the `IsExplicit` parameter refers to the semantics in clang
890   // modules. All the non-explicit submodules in clang modules will be exported
891   // too. Here we simplify the implementation by using the concept.
892   auto *Result =
893       new Module("<implicit global>", Loc, Parent, /*IsFramework=*/false,
894                  /*IsExplicit=*/false, NumCreatedModules++);
895   Result->Kind = Module::ImplicitGlobalModuleFragment;
896   return Result;
897 }
898 
899 Module *
900 ModuleMap::createPrivateModuleFragmentForInterfaceUnit(Module *Parent,
901                                                        SourceLocation Loc) {
902   auto *Result =
903       new Module("<private>", Loc, Parent, /*IsFramework*/ false,
904                  /*IsExplicit*/ true, NumCreatedModules++);
905   Result->Kind = Module::PrivateModuleFragment;
906   return Result;
907 }
908 
909 Module *ModuleMap::createModuleUnitWithKind(SourceLocation Loc, StringRef Name,
910                                             Module::ModuleKind Kind) {
911   auto *Result =
912       new Module(Name, Loc, nullptr, /*IsFramework*/ false,
913                  /*IsExplicit*/ false, NumCreatedModules++);
914   Result->Kind = Kind;
915 
916   // Reparent any current global module fragment as a submodule of this module.
917   for (auto &Submodule : PendingSubmodules) {
918     Submodule->setParent(Result);
919     Submodule.release(); // now owned by parent
920   }
921   PendingSubmodules.clear();
922   return Result;
923 }
924 
925 Module *ModuleMap::createModuleForInterfaceUnit(SourceLocation Loc,
926                                                 StringRef Name) {
927   assert(LangOpts.CurrentModule == Name && "module name mismatch");
928   assert(!Modules[Name] && "redefining existing module");
929 
930   auto *Result =
931       createModuleUnitWithKind(Loc, Name, Module::ModuleInterfaceUnit);
932   Modules[Name] = SourceModule = Result;
933 
934   // Mark the main source file as being within the newly-created module so that
935   // declarations and macros are properly visibility-restricted to it.
936   auto MainFile = SourceMgr.getFileEntryRefForID(SourceMgr.getMainFileID());
937   assert(MainFile && "no input file for module interface");
938   Headers[*MainFile].push_back(KnownHeader(Result, PrivateHeader));
939 
940   return Result;
941 }
942 
943 Module *ModuleMap::createModuleForImplementationUnit(SourceLocation Loc,
944                                                      StringRef Name) {
945   assert(LangOpts.CurrentModule == Name && "module name mismatch");
946   // The interface for this implementation must exist and be loaded.
947   assert(Modules[Name] && Modules[Name]->Kind == Module::ModuleInterfaceUnit &&
948          "creating implementation module without an interface");
949 
950   // Create an entry in the modules map to own the implementation unit module.
951   // User module names must not start with a period (so that this cannot clash
952   // with any legal user-defined module name).
953   StringRef IName = ".ImplementationUnit";
954   assert(!Modules[IName] && "multiple implementation units?");
955 
956   auto *Result =
957       createModuleUnitWithKind(Loc, Name, Module::ModuleImplementationUnit);
958   Modules[IName] = SourceModule = Result;
959 
960   // Check that the main file is present.
961   assert(SourceMgr.getFileEntryForID(SourceMgr.getMainFileID()) &&
962          "no input file for module implementation");
963 
964   return Result;
965 }
966 
967 Module *ModuleMap::createHeaderUnit(SourceLocation Loc, StringRef Name,
968                                     Module::Header H) {
969   assert(LangOpts.CurrentModule == Name && "module name mismatch");
970   assert(!Modules[Name] && "redefining existing module");
971 
972   auto *Result = new Module(Name, Loc, nullptr, /*IsFramework*/ false,
973                             /*IsExplicit*/ false, NumCreatedModules++);
974   Result->Kind = Module::ModuleHeaderUnit;
975   Modules[Name] = SourceModule = Result;
976   addHeader(Result, H, NormalHeader);
977   return Result;
978 }
979 
980 /// For a framework module, infer the framework against which we
981 /// should link.
982 static void inferFrameworkLink(Module *Mod) {
983   assert(Mod->IsFramework && "Can only infer linking for framework modules");
984   assert(!Mod->isSubFramework() &&
985          "Can only infer linking for top-level frameworks");
986 
987   StringRef FrameworkName(Mod->Name);
988   FrameworkName.consume_back("_Private");
989   Mod->LinkLibraries.push_back(Module::LinkLibrary(FrameworkName.str(),
990                                                    /*IsFramework=*/true));
991 }
992 
993 Module *ModuleMap::inferFrameworkModule(DirectoryEntryRef FrameworkDir,
994                                         bool IsSystem, Module *Parent) {
995   Attributes Attrs;
996   Attrs.IsSystem = IsSystem;
997   return inferFrameworkModule(FrameworkDir, Attrs, Parent);
998 }
999 
1000 Module *ModuleMap::inferFrameworkModule(DirectoryEntryRef FrameworkDir,
1001                                         Attributes Attrs, Module *Parent) {
1002   // Note: as an egregious but useful hack we use the real path here, because
1003   // we might be looking at an embedded framework that symlinks out to a
1004   // top-level framework, and we need to infer as if we were naming the
1005   // top-level framework.
1006   StringRef FrameworkDirName =
1007       SourceMgr.getFileManager().getCanonicalName(FrameworkDir);
1008 
1009   // In case this is a case-insensitive filesystem, use the canonical
1010   // directory name as the ModuleName, since modules are case-sensitive.
1011   // FIXME: we should be able to give a fix-it hint for the correct spelling.
1012   SmallString<32> ModuleNameStorage;
1013   StringRef ModuleName = sanitizeFilenameAsIdentifier(
1014       llvm::sys::path::stem(FrameworkDirName), ModuleNameStorage);
1015 
1016   // Check whether we've already found this module.
1017   if (Module *Mod = lookupModuleQualified(ModuleName, Parent))
1018     return Mod;
1019 
1020   FileManager &FileMgr = SourceMgr.getFileManager();
1021 
1022   // If the framework has a parent path from which we're allowed to infer
1023   // a framework module, do so.
1024   OptionalFileEntryRef ModuleMapFile;
1025   if (!Parent) {
1026     // Determine whether we're allowed to infer a module map.
1027     bool canInfer = false;
1028     if (llvm::sys::path::has_parent_path(FrameworkDirName)) {
1029       // Figure out the parent path.
1030       StringRef Parent = llvm::sys::path::parent_path(FrameworkDirName);
1031       if (auto ParentDir = FileMgr.getOptionalDirectoryRef(Parent)) {
1032         // Check whether we have already looked into the parent directory
1033         // for a module map.
1034         llvm::DenseMap<const DirectoryEntry *, InferredDirectory>::const_iterator
1035           inferred = InferredDirectories.find(*ParentDir);
1036         if (inferred == InferredDirectories.end()) {
1037           // We haven't looked here before. Load a module map, if there is
1038           // one.
1039           bool IsFrameworkDir = Parent.ends_with(".framework");
1040           if (OptionalFileEntryRef ModMapFile =
1041                   HeaderInfo.lookupModuleMapFile(*ParentDir, IsFrameworkDir)) {
1042             parseModuleMapFile(*ModMapFile, Attrs.IsSystem, *ParentDir);
1043             inferred = InferredDirectories.find(*ParentDir);
1044           }
1045 
1046           if (inferred == InferredDirectories.end())
1047             inferred = InferredDirectories.insert(
1048                          std::make_pair(*ParentDir, InferredDirectory())).first;
1049         }
1050 
1051         if (inferred->second.InferModules) {
1052           // We're allowed to infer for this directory, but make sure it's okay
1053           // to infer this particular module.
1054           StringRef Name = llvm::sys::path::stem(FrameworkDirName);
1055           canInfer =
1056               !llvm::is_contained(inferred->second.ExcludedModules, Name);
1057 
1058           Attrs.IsSystem |= inferred->second.Attrs.IsSystem;
1059           Attrs.IsExternC |= inferred->second.Attrs.IsExternC;
1060           Attrs.IsExhaustive |= inferred->second.Attrs.IsExhaustive;
1061           Attrs.NoUndeclaredIncludes |=
1062               inferred->second.Attrs.NoUndeclaredIncludes;
1063           ModuleMapFile = inferred->second.ModuleMapFile;
1064         }
1065       }
1066     }
1067 
1068     // If we're not allowed to infer a framework module, don't.
1069     if (!canInfer)
1070       return nullptr;
1071   } else {
1072     ModuleMapFile = getModuleMapFileForUniquing(Parent);
1073   }
1074 
1075   // Look for an umbrella header.
1076   SmallString<128> UmbrellaName = FrameworkDir.getName();
1077   llvm::sys::path::append(UmbrellaName, "Headers", ModuleName + ".h");
1078   auto UmbrellaHeader = FileMgr.getOptionalFileRef(UmbrellaName);
1079 
1080   // FIXME: If there's no umbrella header, we could probably scan the
1081   // framework to load *everything*. But, it's not clear that this is a good
1082   // idea.
1083   if (!UmbrellaHeader)
1084     return nullptr;
1085 
1086   Module *Result = new Module(ModuleName, SourceLocation(), Parent,
1087                               /*IsFramework=*/true, /*IsExplicit=*/false,
1088                               NumCreatedModules++);
1089   InferredModuleAllowedBy[Result] = ModuleMapFile;
1090   Result->IsInferred = true;
1091   if (!Parent) {
1092     if (LangOpts.CurrentModule == ModuleName)
1093       SourceModule = Result;
1094     Modules[ModuleName] = Result;
1095     ModuleScopeIDs[Result] = CurrentModuleScopeID;
1096   }
1097 
1098   Result->IsSystem |= Attrs.IsSystem;
1099   Result->IsExternC |= Attrs.IsExternC;
1100   Result->ConfigMacrosExhaustive |= Attrs.IsExhaustive;
1101   Result->NoUndeclaredIncludes |= Attrs.NoUndeclaredIncludes;
1102   Result->Directory = FrameworkDir;
1103 
1104   // Chop off the first framework bit, as that is implied.
1105   StringRef RelativePath = UmbrellaName.str().substr(
1106       Result->getTopLevelModule()->Directory->getName().size());
1107   RelativePath = llvm::sys::path::relative_path(RelativePath);
1108 
1109   // umbrella header "umbrella-header-name"
1110   setUmbrellaHeaderAsWritten(Result, *UmbrellaHeader, ModuleName + ".h",
1111                              RelativePath);
1112 
1113   // export *
1114   Result->Exports.push_back(Module::ExportDecl(nullptr, true));
1115 
1116   // module * { export * }
1117   Result->InferSubmodules = true;
1118   Result->InferExportWildcard = true;
1119 
1120   // Look for subframeworks.
1121   std::error_code EC;
1122   SmallString<128> SubframeworksDirName = FrameworkDir.getName();
1123   llvm::sys::path::append(SubframeworksDirName, "Frameworks");
1124   llvm::sys::path::native(SubframeworksDirName);
1125   llvm::vfs::FileSystem &FS = FileMgr.getVirtualFileSystem();
1126   for (llvm::vfs::directory_iterator
1127            Dir = FS.dir_begin(SubframeworksDirName, EC),
1128            DirEnd;
1129        Dir != DirEnd && !EC; Dir.increment(EC)) {
1130     if (!StringRef(Dir->path()).ends_with(".framework"))
1131       continue;
1132 
1133     if (auto SubframeworkDir = FileMgr.getOptionalDirectoryRef(Dir->path())) {
1134       // Note: as an egregious but useful hack, we use the real path here and
1135       // check whether it is actually a subdirectory of the parent directory.
1136       // This will not be the case if the 'subframework' is actually a symlink
1137       // out to a top-level framework.
1138       StringRef SubframeworkDirName =
1139           FileMgr.getCanonicalName(*SubframeworkDir);
1140       bool FoundParent = false;
1141       do {
1142         // Get the parent directory name.
1143         SubframeworkDirName
1144           = llvm::sys::path::parent_path(SubframeworkDirName);
1145         if (SubframeworkDirName.empty())
1146           break;
1147 
1148         if (auto SubDir = FileMgr.getDirectory(SubframeworkDirName)) {
1149           if (*SubDir == FrameworkDir) {
1150             FoundParent = true;
1151             break;
1152           }
1153         }
1154       } while (true);
1155 
1156       if (!FoundParent)
1157         continue;
1158 
1159       // FIXME: Do we want to warn about subframeworks without umbrella headers?
1160       inferFrameworkModule(*SubframeworkDir, Attrs, Result);
1161     }
1162   }
1163 
1164   // If the module is a top-level framework, automatically link against the
1165   // framework.
1166   if (!Result->isSubFramework())
1167     inferFrameworkLink(Result);
1168 
1169   return Result;
1170 }
1171 
1172 Module *ModuleMap::createShadowedModule(StringRef Name, bool IsFramework,
1173                                         Module *ShadowingModule) {
1174 
1175   // Create a new module with this name.
1176   Module *Result =
1177       new Module(Name, SourceLocation(), /*Parent=*/nullptr, IsFramework,
1178                  /*IsExplicit=*/false, NumCreatedModules++);
1179   Result->ShadowingModule = ShadowingModule;
1180   Result->markUnavailable(/*Unimportable*/true);
1181   ModuleScopeIDs[Result] = CurrentModuleScopeID;
1182   ShadowModules.push_back(Result);
1183 
1184   return Result;
1185 }
1186 
1187 void ModuleMap::setUmbrellaHeaderAsWritten(
1188     Module *Mod, FileEntryRef UmbrellaHeader, const Twine &NameAsWritten,
1189     const Twine &PathRelativeToRootModuleDirectory) {
1190   Headers[UmbrellaHeader].push_back(KnownHeader(Mod, NormalHeader));
1191   Mod->Umbrella = UmbrellaHeader;
1192   Mod->UmbrellaAsWritten = NameAsWritten.str();
1193   Mod->UmbrellaRelativeToRootModuleDirectory =
1194       PathRelativeToRootModuleDirectory.str();
1195   UmbrellaDirs[UmbrellaHeader.getDir()] = Mod;
1196 
1197   // Notify callbacks that we just added a new header.
1198   for (const auto &Cb : Callbacks)
1199     Cb->moduleMapAddUmbrellaHeader(UmbrellaHeader);
1200 }
1201 
1202 void ModuleMap::setUmbrellaDirAsWritten(
1203     Module *Mod, DirectoryEntryRef UmbrellaDir, const Twine &NameAsWritten,
1204     const Twine &PathRelativeToRootModuleDirectory) {
1205   Mod->Umbrella = UmbrellaDir;
1206   Mod->UmbrellaAsWritten = NameAsWritten.str();
1207   Mod->UmbrellaRelativeToRootModuleDirectory =
1208       PathRelativeToRootModuleDirectory.str();
1209   UmbrellaDirs[UmbrellaDir] = Mod;
1210 }
1211 
1212 void ModuleMap::addUnresolvedHeader(Module *Mod,
1213                                     Module::UnresolvedHeaderDirective Header,
1214                                     bool &NeedsFramework) {
1215   // If there is a builtin counterpart to this file, add it now so it can
1216   // wrap the system header.
1217   if (resolveAsBuiltinHeader(Mod, Header)) {
1218     // If we have both a builtin and system version of the file, the
1219     // builtin version may want to inject macros into the system header, so
1220     // force the system header to be treated as a textual header in this
1221     // case.
1222     Header.Kind = headerRoleToKind(ModuleMap::ModuleHeaderRole(
1223         headerKindToRole(Header.Kind) | ModuleMap::TextualHeader));
1224     Header.HasBuiltinHeader = true;
1225   }
1226 
1227   // If possible, don't stat the header until we need to. This requires the
1228   // user to have provided us with some stat information about the file.
1229   // FIXME: Add support for lazily stat'ing umbrella headers and excluded
1230   // headers.
1231   if ((Header.Size || Header.ModTime) && !Header.IsUmbrella &&
1232       Header.Kind != Module::HK_Excluded) {
1233     // We expect more variation in mtime than size, so if we're given both,
1234     // use the mtime as the key.
1235     if (Header.ModTime)
1236       LazyHeadersByModTime[*Header.ModTime].push_back(Mod);
1237     else
1238       LazyHeadersBySize[*Header.Size].push_back(Mod);
1239     Mod->UnresolvedHeaders.push_back(Header);
1240     return;
1241   }
1242 
1243   // We don't have stat information or can't defer looking this file up.
1244   // Perform the lookup now.
1245   resolveHeader(Mod, Header, NeedsFramework);
1246 }
1247 
1248 void ModuleMap::resolveHeaderDirectives(const FileEntry *File) const {
1249   auto BySize = LazyHeadersBySize.find(File->getSize());
1250   if (BySize != LazyHeadersBySize.end()) {
1251     for (auto *M : BySize->second)
1252       resolveHeaderDirectives(M, File);
1253     LazyHeadersBySize.erase(BySize);
1254   }
1255 
1256   auto ByModTime = LazyHeadersByModTime.find(File->getModificationTime());
1257   if (ByModTime != LazyHeadersByModTime.end()) {
1258     for (auto *M : ByModTime->second)
1259       resolveHeaderDirectives(M, File);
1260     LazyHeadersByModTime.erase(ByModTime);
1261   }
1262 }
1263 
1264 void ModuleMap::resolveHeaderDirectives(
1265     Module *Mod, std::optional<const FileEntry *> File) const {
1266   bool NeedsFramework = false;
1267   SmallVector<Module::UnresolvedHeaderDirective, 1> NewHeaders;
1268   const auto Size = File ? (*File)->getSize() : 0;
1269   const auto ModTime = File ? (*File)->getModificationTime() : 0;
1270 
1271   for (auto &Header : Mod->UnresolvedHeaders) {
1272     if (File && ((Header.ModTime && Header.ModTime != ModTime) ||
1273                  (Header.Size && Header.Size != Size)))
1274       NewHeaders.push_back(Header);
1275     else
1276       // This operation is logically const; we're just changing how we represent
1277       // the header information for this file.
1278       const_cast<ModuleMap *>(this)->resolveHeader(Mod, Header, NeedsFramework);
1279   }
1280   Mod->UnresolvedHeaders.swap(NewHeaders);
1281 }
1282 
1283 void ModuleMap::addHeader(Module *Mod, Module::Header Header,
1284                           ModuleHeaderRole Role, bool Imported) {
1285   KnownHeader KH(Mod, Role);
1286 
1287   // Only add each header to the headers list once.
1288   // FIXME: Should we diagnose if a header is listed twice in the
1289   // same module definition?
1290   auto &HeaderList = Headers[Header.Entry];
1291   if (llvm::is_contained(HeaderList, KH))
1292     return;
1293 
1294   HeaderList.push_back(KH);
1295   Mod->Headers[headerRoleToKind(Role)].push_back(Header);
1296 
1297   bool isCompilingModuleHeader = Mod->isForBuilding(LangOpts);
1298   if (!Imported || isCompilingModuleHeader) {
1299     // When we import HeaderFileInfo, the external source is expected to
1300     // set the isModuleHeader flag itself.
1301     HeaderInfo.MarkFileModuleHeader(Header.Entry, Role,
1302                                     isCompilingModuleHeader);
1303   }
1304 
1305   // Notify callbacks that we just added a new header.
1306   for (const auto &Cb : Callbacks)
1307     Cb->moduleMapAddHeader(Header.Entry.getName());
1308 }
1309 
1310 OptionalFileEntryRef
1311 ModuleMap::getContainingModuleMapFile(const Module *Module) const {
1312   if (Module->DefinitionLoc.isInvalid())
1313     return std::nullopt;
1314 
1315   return SourceMgr.getFileEntryRefForID(
1316       SourceMgr.getFileID(Module->DefinitionLoc));
1317 }
1318 
1319 OptionalFileEntryRef
1320 ModuleMap::getModuleMapFileForUniquing(const Module *M) const {
1321   if (M->IsInferred) {
1322     assert(InferredModuleAllowedBy.count(M) && "missing inferred module map");
1323     return InferredModuleAllowedBy.find(M)->second;
1324   }
1325   return getContainingModuleMapFile(M);
1326 }
1327 
1328 void ModuleMap::setInferredModuleAllowedBy(Module *M,
1329                                            OptionalFileEntryRef ModMap) {
1330   assert(M->IsInferred && "module not inferred");
1331   InferredModuleAllowedBy[M] = ModMap;
1332 }
1333 
1334 std::error_code
1335 ModuleMap::canonicalizeModuleMapPath(SmallVectorImpl<char> &Path) {
1336   StringRef Dir = llvm::sys::path::parent_path({Path.data(), Path.size()});
1337 
1338   // Do not canonicalize within the framework; the module map parser expects
1339   // Modules/ not Versions/A/Modules.
1340   if (llvm::sys::path::filename(Dir) == "Modules") {
1341     StringRef Parent = llvm::sys::path::parent_path(Dir);
1342     if (Parent.ends_with(".framework"))
1343       Dir = Parent;
1344   }
1345 
1346   FileManager &FM = SourceMgr.getFileManager();
1347   auto DirEntry = FM.getDirectoryRef(Dir.empty() ? "." : Dir);
1348   if (!DirEntry)
1349     return llvm::errorToErrorCode(DirEntry.takeError());
1350 
1351   // Canonicalize the directory.
1352   StringRef CanonicalDir = FM.getCanonicalName(*DirEntry);
1353   if (CanonicalDir != Dir)
1354     llvm::sys::path::replace_path_prefix(Path, Dir, CanonicalDir);
1355 
1356   // In theory, the filename component should also be canonicalized if it
1357   // on a case-insensitive filesystem. However, the extra canonicalization is
1358   // expensive and if clang looked up the filename it will always be lowercase.
1359 
1360   // Remove ., remove redundant separators, and switch to native separators.
1361   // This is needed for separators between CanonicalDir and the filename.
1362   llvm::sys::path::remove_dots(Path);
1363 
1364   return std::error_code();
1365 }
1366 
1367 void ModuleMap::addAdditionalModuleMapFile(const Module *M,
1368                                            FileEntryRef ModuleMap) {
1369   AdditionalModMaps[M].insert(ModuleMap);
1370 }
1371 
1372 LLVM_DUMP_METHOD void ModuleMap::dump() {
1373   llvm::errs() << "Modules:";
1374   for (llvm::StringMap<Module *>::iterator M = Modules.begin(),
1375                                         MEnd = Modules.end();
1376        M != MEnd; ++M)
1377     M->getValue()->print(llvm::errs(), 2);
1378 
1379   llvm::errs() << "Headers:";
1380   for (HeadersMap::iterator H = Headers.begin(), HEnd = Headers.end();
1381        H != HEnd; ++H) {
1382     llvm::errs() << "  \"" << H->first.getName() << "\" -> ";
1383     for (SmallVectorImpl<KnownHeader>::const_iterator I = H->second.begin(),
1384                                                       E = H->second.end();
1385          I != E; ++I) {
1386       if (I != H->second.begin())
1387         llvm::errs() << ",";
1388       llvm::errs() << I->getModule()->getFullModuleName();
1389     }
1390     llvm::errs() << "\n";
1391   }
1392 }
1393 
1394 bool ModuleMap::resolveExports(Module *Mod, bool Complain) {
1395   auto Unresolved = std::move(Mod->UnresolvedExports);
1396   Mod->UnresolvedExports.clear();
1397   for (auto &UE : Unresolved) {
1398     Module::ExportDecl Export = resolveExport(Mod, UE, Complain);
1399     if (Export.getPointer() || Export.getInt())
1400       Mod->Exports.push_back(Export);
1401     else
1402       Mod->UnresolvedExports.push_back(UE);
1403   }
1404   return !Mod->UnresolvedExports.empty();
1405 }
1406 
1407 bool ModuleMap::resolveUses(Module *Mod, bool Complain) {
1408   auto *Top = Mod->getTopLevelModule();
1409   auto Unresolved = std::move(Top->UnresolvedDirectUses);
1410   Top->UnresolvedDirectUses.clear();
1411   for (auto &UDU : Unresolved) {
1412     Module *DirectUse = resolveModuleId(UDU, Top, Complain);
1413     if (DirectUse)
1414       Top->DirectUses.push_back(DirectUse);
1415     else
1416       Top->UnresolvedDirectUses.push_back(UDU);
1417   }
1418   return !Top->UnresolvedDirectUses.empty();
1419 }
1420 
1421 bool ModuleMap::resolveConflicts(Module *Mod, bool Complain) {
1422   auto Unresolved = std::move(Mod->UnresolvedConflicts);
1423   Mod->UnresolvedConflicts.clear();
1424   for (auto &UC : Unresolved) {
1425     if (Module *OtherMod = resolveModuleId(UC.Id, Mod, Complain)) {
1426       Module::Conflict Conflict;
1427       Conflict.Other = OtherMod;
1428       Conflict.Message = UC.Message;
1429       Mod->Conflicts.push_back(Conflict);
1430     } else
1431       Mod->UnresolvedConflicts.push_back(UC);
1432   }
1433   return !Mod->UnresolvedConflicts.empty();
1434 }
1435 
1436 //----------------------------------------------------------------------------//
1437 // Module map file parser
1438 //----------------------------------------------------------------------------//
1439 
1440 namespace clang {
1441 
1442   /// A token in a module map file.
1443   struct MMToken {
1444     enum TokenKind {
1445       Comma,
1446       ConfigMacros,
1447       Conflict,
1448       EndOfFile,
1449       HeaderKeyword,
1450       Identifier,
1451       Exclaim,
1452       ExcludeKeyword,
1453       ExplicitKeyword,
1454       ExportKeyword,
1455       ExportAsKeyword,
1456       ExternKeyword,
1457       FrameworkKeyword,
1458       LinkKeyword,
1459       ModuleKeyword,
1460       Period,
1461       PrivateKeyword,
1462       UmbrellaKeyword,
1463       UseKeyword,
1464       RequiresKeyword,
1465       Star,
1466       StringLiteral,
1467       IntegerLiteral,
1468       TextualKeyword,
1469       LBrace,
1470       RBrace,
1471       LSquare,
1472       RSquare
1473     } Kind;
1474 
1475     SourceLocation::UIntTy Location;
1476     unsigned StringLength;
1477     union {
1478       // If Kind != IntegerLiteral.
1479       const char *StringData;
1480 
1481       // If Kind == IntegerLiteral.
1482       uint64_t IntegerValue;
1483     };
1484 
1485     void clear() {
1486       Kind = EndOfFile;
1487       Location = 0;
1488       StringLength = 0;
1489       StringData = nullptr;
1490     }
1491 
1492     bool is(TokenKind K) const { return Kind == K; }
1493 
1494     SourceLocation getLocation() const {
1495       return SourceLocation::getFromRawEncoding(Location);
1496     }
1497 
1498     uint64_t getInteger() const {
1499       return Kind == IntegerLiteral ? IntegerValue : 0;
1500     }
1501 
1502     StringRef getString() const {
1503       return Kind == IntegerLiteral ? StringRef()
1504                                     : StringRef(StringData, StringLength);
1505     }
1506   };
1507 
1508   class ModuleMapParser {
1509     Lexer &L;
1510     SourceManager &SourceMgr;
1511 
1512     /// Default target information, used only for string literal
1513     /// parsing.
1514     const TargetInfo *Target;
1515 
1516     DiagnosticsEngine &Diags;
1517     ModuleMap &Map;
1518 
1519     /// The current module map file.
1520     FileEntryRef ModuleMapFile;
1521 
1522     /// Source location of most recent parsed module declaration
1523     SourceLocation CurrModuleDeclLoc;
1524 
1525     /// The directory that file names in this module map file should
1526     /// be resolved relative to.
1527     DirectoryEntryRef Directory;
1528 
1529     /// Whether this module map is in a system header directory.
1530     bool IsSystem;
1531 
1532     /// Whether an error occurred.
1533     bool HadError = false;
1534 
1535     /// Stores string data for the various string literals referenced
1536     /// during parsing.
1537     llvm::BumpPtrAllocator StringData;
1538 
1539     /// The current token.
1540     MMToken Tok;
1541 
1542     /// The active module.
1543     Module *ActiveModule = nullptr;
1544 
1545     /// Whether a module uses the 'requires excluded' hack to mark its
1546     /// contents as 'textual'.
1547     ///
1548     /// On older Darwin SDK versions, 'requires excluded' is used to mark the
1549     /// contents of the Darwin.C.excluded (assert.h) and Tcl.Private modules as
1550     /// non-modular headers.  For backwards compatibility, we continue to
1551     /// support this idiom for just these modules, and map the headers to
1552     /// 'textual' to match the original intent.
1553     llvm::SmallPtrSet<Module *, 2> UsesRequiresExcludedHack;
1554 
1555     /// Consume the current token and return its location.
1556     SourceLocation consumeToken();
1557 
1558     /// Skip tokens until we reach the a token with the given kind
1559     /// (or the end of the file).
1560     void skipUntil(MMToken::TokenKind K);
1561 
1562     bool parseModuleId(ModuleId &Id);
1563     void parseModuleDecl();
1564     void parseExternModuleDecl();
1565     void parseRequiresDecl();
1566     void parseHeaderDecl(MMToken::TokenKind, SourceLocation LeadingLoc);
1567     void parseUmbrellaDirDecl(SourceLocation UmbrellaLoc);
1568     void parseExportDecl();
1569     void parseExportAsDecl();
1570     void parseUseDecl();
1571     void parseLinkDecl();
1572     void parseConfigMacros();
1573     void parseConflict();
1574     void parseInferredModuleDecl(bool Framework, bool Explicit);
1575 
1576     /// Private modules are canonicalized as Foo_Private. Clang provides extra
1577     /// module map search logic to find the appropriate private module when PCH
1578     /// is used with implicit module maps. Warn when private modules are written
1579     /// in other ways (FooPrivate and Foo.Private), providing notes and fixits.
1580     void diagnosePrivateModules(SourceLocation ExplicitLoc,
1581                                 SourceLocation FrameworkLoc);
1582 
1583     using Attributes = ModuleMap::Attributes;
1584 
1585     bool parseOptionalAttributes(Attributes &Attrs);
1586 
1587   public:
1588     explicit ModuleMapParser(Lexer &L, SourceManager &SourceMgr,
1589                              const TargetInfo *Target, DiagnosticsEngine &Diags,
1590                              ModuleMap &Map, FileEntryRef ModuleMapFile,
1591                              DirectoryEntryRef Directory, bool IsSystem)
1592         : L(L), SourceMgr(SourceMgr), Target(Target), Diags(Diags), Map(Map),
1593           ModuleMapFile(ModuleMapFile), Directory(Directory),
1594           IsSystem(IsSystem) {
1595       Tok.clear();
1596       consumeToken();
1597     }
1598 
1599     bool parseModuleMapFile();
1600 
1601     bool terminatedByDirective() { return false; }
1602     SourceLocation getLocation() { return Tok.getLocation(); }
1603   };
1604 
1605 } // namespace clang
1606 
1607 SourceLocation ModuleMapParser::consumeToken() {
1608   SourceLocation Result = Tok.getLocation();
1609 
1610 retry:
1611   Tok.clear();
1612   Token LToken;
1613   L.LexFromRawLexer(LToken);
1614   Tok.Location = LToken.getLocation().getRawEncoding();
1615   switch (LToken.getKind()) {
1616   case tok::raw_identifier: {
1617     StringRef RI = LToken.getRawIdentifier();
1618     Tok.StringData = RI.data();
1619     Tok.StringLength = RI.size();
1620     Tok.Kind = llvm::StringSwitch<MMToken::TokenKind>(RI)
1621                  .Case("config_macros", MMToken::ConfigMacros)
1622                  .Case("conflict", MMToken::Conflict)
1623                  .Case("exclude", MMToken::ExcludeKeyword)
1624                  .Case("explicit", MMToken::ExplicitKeyword)
1625                  .Case("export", MMToken::ExportKeyword)
1626                  .Case("export_as", MMToken::ExportAsKeyword)
1627                  .Case("extern", MMToken::ExternKeyword)
1628                  .Case("framework", MMToken::FrameworkKeyword)
1629                  .Case("header", MMToken::HeaderKeyword)
1630                  .Case("link", MMToken::LinkKeyword)
1631                  .Case("module", MMToken::ModuleKeyword)
1632                  .Case("private", MMToken::PrivateKeyword)
1633                  .Case("requires", MMToken::RequiresKeyword)
1634                  .Case("textual", MMToken::TextualKeyword)
1635                  .Case("umbrella", MMToken::UmbrellaKeyword)
1636                  .Case("use", MMToken::UseKeyword)
1637                  .Default(MMToken::Identifier);
1638     break;
1639   }
1640 
1641   case tok::comma:
1642     Tok.Kind = MMToken::Comma;
1643     break;
1644 
1645   case tok::eof:
1646     Tok.Kind = MMToken::EndOfFile;
1647     break;
1648 
1649   case tok::l_brace:
1650     Tok.Kind = MMToken::LBrace;
1651     break;
1652 
1653   case tok::l_square:
1654     Tok.Kind = MMToken::LSquare;
1655     break;
1656 
1657   case tok::period:
1658     Tok.Kind = MMToken::Period;
1659     break;
1660 
1661   case tok::r_brace:
1662     Tok.Kind = MMToken::RBrace;
1663     break;
1664 
1665   case tok::r_square:
1666     Tok.Kind = MMToken::RSquare;
1667     break;
1668 
1669   case tok::star:
1670     Tok.Kind = MMToken::Star;
1671     break;
1672 
1673   case tok::exclaim:
1674     Tok.Kind = MMToken::Exclaim;
1675     break;
1676 
1677   case tok::string_literal: {
1678     if (LToken.hasUDSuffix()) {
1679       Diags.Report(LToken.getLocation(), diag::err_invalid_string_udl);
1680       HadError = true;
1681       goto retry;
1682     }
1683 
1684     // Parse the string literal.
1685     LangOptions LangOpts;
1686     StringLiteralParser StringLiteral(LToken, SourceMgr, LangOpts, *Target);
1687     if (StringLiteral.hadError)
1688       goto retry;
1689 
1690     // Copy the string literal into our string data allocator.
1691     unsigned Length = StringLiteral.GetStringLength();
1692     char *Saved = StringData.Allocate<char>(Length + 1);
1693     memcpy(Saved, StringLiteral.GetString().data(), Length);
1694     Saved[Length] = 0;
1695 
1696     // Form the token.
1697     Tok.Kind = MMToken::StringLiteral;
1698     Tok.StringData = Saved;
1699     Tok.StringLength = Length;
1700     break;
1701   }
1702 
1703   case tok::numeric_constant: {
1704     // We don't support any suffixes or other complications.
1705     SmallString<32> SpellingBuffer;
1706     SpellingBuffer.resize(LToken.getLength() + 1);
1707     const char *Start = SpellingBuffer.data();
1708     unsigned Length =
1709         Lexer::getSpelling(LToken, Start, SourceMgr, Map.LangOpts);
1710     uint64_t Value;
1711     if (StringRef(Start, Length).getAsInteger(0, Value)) {
1712       Diags.Report(Tok.getLocation(), diag::err_mmap_unknown_token);
1713       HadError = true;
1714       goto retry;
1715     }
1716 
1717     Tok.Kind = MMToken::IntegerLiteral;
1718     Tok.IntegerValue = Value;
1719     break;
1720   }
1721 
1722   case tok::comment:
1723     goto retry;
1724 
1725   case tok::hash:
1726     // A module map can be terminated prematurely by
1727     //   #pragma clang module contents
1728     // When building the module, we'll treat the rest of the file as the
1729     // contents of the module.
1730     {
1731       auto NextIsIdent = [&](StringRef Str) -> bool {
1732         L.LexFromRawLexer(LToken);
1733         return !LToken.isAtStartOfLine() && LToken.is(tok::raw_identifier) &&
1734                LToken.getRawIdentifier() == Str;
1735       };
1736       if (NextIsIdent("pragma") && NextIsIdent("clang") &&
1737           NextIsIdent("module") && NextIsIdent("contents")) {
1738         Tok.Kind = MMToken::EndOfFile;
1739         break;
1740       }
1741     }
1742     [[fallthrough]];
1743 
1744   default:
1745     Diags.Report(Tok.getLocation(), diag::err_mmap_unknown_token);
1746     HadError = true;
1747     goto retry;
1748   }
1749 
1750   return Result;
1751 }
1752 
1753 void ModuleMapParser::skipUntil(MMToken::TokenKind K) {
1754   unsigned braceDepth = 0;
1755   unsigned squareDepth = 0;
1756   do {
1757     switch (Tok.Kind) {
1758     case MMToken::EndOfFile:
1759       return;
1760 
1761     case MMToken::LBrace:
1762       if (Tok.is(K) && braceDepth == 0 && squareDepth == 0)
1763         return;
1764 
1765       ++braceDepth;
1766       break;
1767 
1768     case MMToken::LSquare:
1769       if (Tok.is(K) && braceDepth == 0 && squareDepth == 0)
1770         return;
1771 
1772       ++squareDepth;
1773       break;
1774 
1775     case MMToken::RBrace:
1776       if (braceDepth > 0)
1777         --braceDepth;
1778       else if (Tok.is(K))
1779         return;
1780       break;
1781 
1782     case MMToken::RSquare:
1783       if (squareDepth > 0)
1784         --squareDepth;
1785       else if (Tok.is(K))
1786         return;
1787       break;
1788 
1789     default:
1790       if (braceDepth == 0 && squareDepth == 0 && Tok.is(K))
1791         return;
1792       break;
1793     }
1794 
1795    consumeToken();
1796   } while (true);
1797 }
1798 
1799 /// Parse a module-id.
1800 ///
1801 ///   module-id:
1802 ///     identifier
1803 ///     identifier '.' module-id
1804 ///
1805 /// \returns true if an error occurred, false otherwise.
1806 bool ModuleMapParser::parseModuleId(ModuleId &Id) {
1807   Id.clear();
1808   do {
1809     if (Tok.is(MMToken::Identifier) || Tok.is(MMToken::StringLiteral)) {
1810       Id.push_back(
1811           std::make_pair(std::string(Tok.getString()), Tok.getLocation()));
1812       consumeToken();
1813     } else {
1814       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_module_name);
1815       return true;
1816     }
1817 
1818     if (!Tok.is(MMToken::Period))
1819       break;
1820 
1821     consumeToken();
1822   } while (true);
1823 
1824   return false;
1825 }
1826 
1827 namespace {
1828 
1829   /// Enumerates the known attributes.
1830   enum AttributeKind {
1831     /// An unknown attribute.
1832     AT_unknown,
1833 
1834     /// The 'system' attribute.
1835     AT_system,
1836 
1837     /// The 'extern_c' attribute.
1838     AT_extern_c,
1839 
1840     /// The 'exhaustive' attribute.
1841     AT_exhaustive,
1842 
1843     /// The 'no_undeclared_includes' attribute.
1844     AT_no_undeclared_includes
1845   };
1846 
1847 } // namespace
1848 
1849 /// Private modules are canonicalized as Foo_Private. Clang provides extra
1850 /// module map search logic to find the appropriate private module when PCH
1851 /// is used with implicit module maps. Warn when private modules are written
1852 /// in other ways (FooPrivate and Foo.Private), providing notes and fixits.
1853 void ModuleMapParser::diagnosePrivateModules(SourceLocation ExplicitLoc,
1854                                              SourceLocation FrameworkLoc) {
1855   auto GenNoteAndFixIt = [&](StringRef BadName, StringRef Canonical,
1856                              const Module *M, SourceRange ReplLoc) {
1857     auto D = Diags.Report(ActiveModule->DefinitionLoc,
1858                           diag::note_mmap_rename_top_level_private_module);
1859     D << BadName << M->Name;
1860     D << FixItHint::CreateReplacement(ReplLoc, Canonical);
1861   };
1862 
1863   for (auto E = Map.module_begin(); E != Map.module_end(); ++E) {
1864     auto const *M = E->getValue();
1865     if (M->Directory != ActiveModule->Directory)
1866       continue;
1867 
1868     SmallString<128> FullName(ActiveModule->getFullModuleName());
1869     if (!FullName.starts_with(M->Name) && !FullName.ends_with("Private"))
1870       continue;
1871     SmallString<128> FixedPrivModDecl;
1872     SmallString<128> Canonical(M->Name);
1873     Canonical.append("_Private");
1874 
1875     // Foo.Private -> Foo_Private
1876     if (ActiveModule->Parent && ActiveModule->Name == "Private" && !M->Parent &&
1877         M->Name == ActiveModule->Parent->Name) {
1878       Diags.Report(ActiveModule->DefinitionLoc,
1879                    diag::warn_mmap_mismatched_private_submodule)
1880           << FullName;
1881 
1882       SourceLocation FixItInitBegin = CurrModuleDeclLoc;
1883       if (FrameworkLoc.isValid())
1884         FixItInitBegin = FrameworkLoc;
1885       if (ExplicitLoc.isValid())
1886         FixItInitBegin = ExplicitLoc;
1887 
1888       if (FrameworkLoc.isValid() || ActiveModule->Parent->IsFramework)
1889         FixedPrivModDecl.append("framework ");
1890       FixedPrivModDecl.append("module ");
1891       FixedPrivModDecl.append(Canonical);
1892 
1893       GenNoteAndFixIt(FullName, FixedPrivModDecl, M,
1894                       SourceRange(FixItInitBegin, ActiveModule->DefinitionLoc));
1895       continue;
1896     }
1897 
1898     // FooPrivate and whatnots -> Foo_Private
1899     if (!ActiveModule->Parent && !M->Parent && M->Name != ActiveModule->Name &&
1900         ActiveModule->Name != Canonical) {
1901       Diags.Report(ActiveModule->DefinitionLoc,
1902                    diag::warn_mmap_mismatched_private_module_name)
1903           << ActiveModule->Name;
1904       GenNoteAndFixIt(ActiveModule->Name, Canonical, M,
1905                       SourceRange(ActiveModule->DefinitionLoc));
1906     }
1907   }
1908 }
1909 
1910 /// Parse a module declaration.
1911 ///
1912 ///   module-declaration:
1913 ///     'extern' 'module' module-id string-literal
1914 ///     'explicit'[opt] 'framework'[opt] 'module' module-id attributes[opt]
1915 ///       { module-member* }
1916 ///
1917 ///   module-member:
1918 ///     requires-declaration
1919 ///     header-declaration
1920 ///     submodule-declaration
1921 ///     export-declaration
1922 ///     export-as-declaration
1923 ///     link-declaration
1924 ///
1925 ///   submodule-declaration:
1926 ///     module-declaration
1927 ///     inferred-submodule-declaration
1928 void ModuleMapParser::parseModuleDecl() {
1929   assert(Tok.is(MMToken::ExplicitKeyword) || Tok.is(MMToken::ModuleKeyword) ||
1930          Tok.is(MMToken::FrameworkKeyword) || Tok.is(MMToken::ExternKeyword));
1931   if (Tok.is(MMToken::ExternKeyword)) {
1932     parseExternModuleDecl();
1933     return;
1934   }
1935 
1936   // Parse 'explicit' or 'framework' keyword, if present.
1937   SourceLocation ExplicitLoc;
1938   SourceLocation FrameworkLoc;
1939   bool Explicit = false;
1940   bool Framework = false;
1941 
1942   // Parse 'explicit' keyword, if present.
1943   if (Tok.is(MMToken::ExplicitKeyword)) {
1944     ExplicitLoc = consumeToken();
1945     Explicit = true;
1946   }
1947 
1948   // Parse 'framework' keyword, if present.
1949   if (Tok.is(MMToken::FrameworkKeyword)) {
1950     FrameworkLoc = consumeToken();
1951     Framework = true;
1952   }
1953 
1954   // Parse 'module' keyword.
1955   if (!Tok.is(MMToken::ModuleKeyword)) {
1956     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_module);
1957     consumeToken();
1958     HadError = true;
1959     return;
1960   }
1961   CurrModuleDeclLoc = consumeToken(); // 'module' keyword
1962 
1963   // If we have a wildcard for the module name, this is an inferred submodule.
1964   // Parse it.
1965   if (Tok.is(MMToken::Star))
1966     return parseInferredModuleDecl(Framework, Explicit);
1967 
1968   // Parse the module name.
1969   ModuleId Id;
1970   if (parseModuleId(Id)) {
1971     HadError = true;
1972     return;
1973   }
1974 
1975   if (ActiveModule) {
1976     if (Id.size() > 1) {
1977       Diags.Report(Id.front().second, diag::err_mmap_nested_submodule_id)
1978         << SourceRange(Id.front().second, Id.back().second);
1979 
1980       HadError = true;
1981       return;
1982     }
1983   } else if (Id.size() == 1 && Explicit) {
1984     // Top-level modules can't be explicit.
1985     Diags.Report(ExplicitLoc, diag::err_mmap_explicit_top_level);
1986     Explicit = false;
1987     ExplicitLoc = SourceLocation();
1988     HadError = true;
1989   }
1990 
1991   Module *PreviousActiveModule = ActiveModule;
1992   if (Id.size() > 1) {
1993     // This module map defines a submodule. Go find the module of which it
1994     // is a submodule.
1995     ActiveModule = nullptr;
1996     const Module *TopLevelModule = nullptr;
1997     for (unsigned I = 0, N = Id.size() - 1; I != N; ++I) {
1998       if (Module *Next = Map.lookupModuleQualified(Id[I].first, ActiveModule)) {
1999         if (I == 0)
2000           TopLevelModule = Next;
2001         ActiveModule = Next;
2002         continue;
2003       }
2004 
2005       Diags.Report(Id[I].second, diag::err_mmap_missing_parent_module)
2006           << Id[I].first << (ActiveModule != nullptr)
2007           << (ActiveModule
2008                   ? ActiveModule->getTopLevelModule()->getFullModuleName()
2009                   : "");
2010       HadError = true;
2011     }
2012 
2013     if (TopLevelModule &&
2014         ModuleMapFile != Map.getContainingModuleMapFile(TopLevelModule)) {
2015       assert(ModuleMapFile != Map.getModuleMapFileForUniquing(TopLevelModule) &&
2016              "submodule defined in same file as 'module *' that allowed its "
2017              "top-level module");
2018       Map.addAdditionalModuleMapFile(TopLevelModule, ModuleMapFile);
2019     }
2020   }
2021 
2022   StringRef ModuleName = Id.back().first;
2023   SourceLocation ModuleNameLoc = Id.back().second;
2024 
2025   // Parse the optional attribute list.
2026   Attributes Attrs;
2027   if (parseOptionalAttributes(Attrs))
2028     return;
2029 
2030   // Parse the opening brace.
2031   if (!Tok.is(MMToken::LBrace)) {
2032     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_lbrace)
2033       << ModuleName;
2034     HadError = true;
2035     return;
2036   }
2037   SourceLocation LBraceLoc = consumeToken();
2038 
2039   // Determine whether this (sub)module has already been defined.
2040   Module *ShadowingModule = nullptr;
2041   if (Module *Existing = Map.lookupModuleQualified(ModuleName, ActiveModule)) {
2042     // We might see a (re)definition of a module that we already have a
2043     // definition for in four cases:
2044     //  - If we loaded one definition from an AST file and we've just found a
2045     //    corresponding definition in a module map file, or
2046     bool LoadedFromASTFile = Existing->IsFromModuleFile;
2047     //  - If we previously inferred this module from different module map file.
2048     bool Inferred = Existing->IsInferred;
2049     //  - If we're building a framework that vends a module map, we might've
2050     //    previously seen the one in intermediate products and now the system
2051     //    one.
2052     // FIXME: If we're parsing module map file that looks like this:
2053     //          framework module FW { ... }
2054     //          module FW.Sub { ... }
2055     //        We can't check the framework qualifier, since it's not attached to
2056     //        the definition of Sub. Checking that qualifier on \c Existing is
2057     //        not correct either, since we might've previously seen:
2058     //          module FW { ... }
2059     //          module FW.Sub { ... }
2060     //        We should enforce consistency of redefinitions so that we can rely
2061     //        that \c Existing is part of a framework iff the redefinition of FW
2062     //        we have just skipped had it too. Once we do that, stop checking
2063     //        the local framework qualifier and only rely on \c Existing.
2064     bool PartOfFramework = Framework || Existing->isPartOfFramework();
2065     //  - If we're building a (preprocessed) module and we've just loaded the
2066     //    module map file from which it was created.
2067     bool ParsedAsMainInput =
2068         Map.LangOpts.getCompilingModule() == LangOptions::CMK_ModuleMap &&
2069         Map.LangOpts.CurrentModule == ModuleName &&
2070         SourceMgr.getDecomposedLoc(ModuleNameLoc).first !=
2071             SourceMgr.getDecomposedLoc(Existing->DefinitionLoc).first;
2072     if (LoadedFromASTFile || Inferred || PartOfFramework || ParsedAsMainInput) {
2073       ActiveModule = PreviousActiveModule;
2074       // Skip the module definition.
2075       skipUntil(MMToken::RBrace);
2076       if (Tok.is(MMToken::RBrace))
2077         consumeToken();
2078       else {
2079         Diags.Report(Tok.getLocation(), diag::err_mmap_expected_rbrace);
2080         Diags.Report(LBraceLoc, diag::note_mmap_lbrace_match);
2081         HadError = true;
2082       }
2083       return;
2084     }
2085 
2086     if (!Existing->Parent && Map.mayShadowNewModule(Existing)) {
2087       ShadowingModule = Existing;
2088     } else {
2089       // This is not a shawdowed module decl, it is an illegal redefinition.
2090       Diags.Report(ModuleNameLoc, diag::err_mmap_module_redefinition)
2091           << ModuleName;
2092       Diags.Report(Existing->DefinitionLoc, diag::note_mmap_prev_definition);
2093 
2094       // Skip the module definition.
2095       skipUntil(MMToken::RBrace);
2096       if (Tok.is(MMToken::RBrace))
2097         consumeToken();
2098 
2099       HadError = true;
2100       return;
2101     }
2102   }
2103 
2104   // Start defining this module.
2105   if (ShadowingModule) {
2106     ActiveModule =
2107         Map.createShadowedModule(ModuleName, Framework, ShadowingModule);
2108   } else {
2109     ActiveModule =
2110         Map.findOrCreateModule(ModuleName, ActiveModule, Framework, Explicit)
2111             .first;
2112   }
2113 
2114   ActiveModule->DefinitionLoc = ModuleNameLoc;
2115   if (Attrs.IsSystem || IsSystem)
2116     ActiveModule->IsSystem = true;
2117   if (Attrs.IsExternC)
2118     ActiveModule->IsExternC = true;
2119   if (Attrs.NoUndeclaredIncludes)
2120     ActiveModule->NoUndeclaredIncludes = true;
2121   ActiveModule->Directory = Directory;
2122 
2123   StringRef MapFileName(ModuleMapFile.getName());
2124   if (MapFileName.ends_with("module.private.modulemap") ||
2125       MapFileName.ends_with("module_private.map")) {
2126     ActiveModule->ModuleMapIsPrivate = true;
2127   }
2128 
2129   // Private modules named as FooPrivate, Foo.Private or similar are likely a
2130   // user error; provide warnings, notes and fixits to direct users to use
2131   // Foo_Private instead.
2132   SourceLocation StartLoc =
2133       SourceMgr.getLocForStartOfFile(SourceMgr.getMainFileID());
2134   if (Map.HeaderInfo.getHeaderSearchOpts().ImplicitModuleMaps &&
2135       !Diags.isIgnored(diag::warn_mmap_mismatched_private_submodule,
2136                        StartLoc) &&
2137       !Diags.isIgnored(diag::warn_mmap_mismatched_private_module_name,
2138                        StartLoc) &&
2139       ActiveModule->ModuleMapIsPrivate)
2140     diagnosePrivateModules(ExplicitLoc, FrameworkLoc);
2141 
2142   bool Done = false;
2143   do {
2144     switch (Tok.Kind) {
2145     case MMToken::EndOfFile:
2146     case MMToken::RBrace:
2147       Done = true;
2148       break;
2149 
2150     case MMToken::ConfigMacros:
2151       parseConfigMacros();
2152       break;
2153 
2154     case MMToken::Conflict:
2155       parseConflict();
2156       break;
2157 
2158     case MMToken::ExplicitKeyword:
2159     case MMToken::ExternKeyword:
2160     case MMToken::FrameworkKeyword:
2161     case MMToken::ModuleKeyword:
2162       parseModuleDecl();
2163       break;
2164 
2165     case MMToken::ExportKeyword:
2166       parseExportDecl();
2167       break;
2168 
2169     case MMToken::ExportAsKeyword:
2170       parseExportAsDecl();
2171       break;
2172 
2173     case MMToken::UseKeyword:
2174       parseUseDecl();
2175       break;
2176 
2177     case MMToken::RequiresKeyword:
2178       parseRequiresDecl();
2179       break;
2180 
2181     case MMToken::TextualKeyword:
2182       parseHeaderDecl(MMToken::TextualKeyword, consumeToken());
2183       break;
2184 
2185     case MMToken::UmbrellaKeyword: {
2186       SourceLocation UmbrellaLoc = consumeToken();
2187       if (Tok.is(MMToken::HeaderKeyword))
2188         parseHeaderDecl(MMToken::UmbrellaKeyword, UmbrellaLoc);
2189       else
2190         parseUmbrellaDirDecl(UmbrellaLoc);
2191       break;
2192     }
2193 
2194     case MMToken::ExcludeKeyword:
2195       parseHeaderDecl(MMToken::ExcludeKeyword, consumeToken());
2196       break;
2197 
2198     case MMToken::PrivateKeyword:
2199       parseHeaderDecl(MMToken::PrivateKeyword, consumeToken());
2200       break;
2201 
2202     case MMToken::HeaderKeyword:
2203       parseHeaderDecl(MMToken::HeaderKeyword, consumeToken());
2204       break;
2205 
2206     case MMToken::LinkKeyword:
2207       parseLinkDecl();
2208       break;
2209 
2210     default:
2211       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_member);
2212       consumeToken();
2213       break;
2214     }
2215   } while (!Done);
2216 
2217   if (Tok.is(MMToken::RBrace))
2218     consumeToken();
2219   else {
2220     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_rbrace);
2221     Diags.Report(LBraceLoc, diag::note_mmap_lbrace_match);
2222     HadError = true;
2223   }
2224 
2225   // If the active module is a top-level framework, and there are no link
2226   // libraries, automatically link against the framework.
2227   if (ActiveModule->IsFramework && !ActiveModule->isSubFramework() &&
2228       ActiveModule->LinkLibraries.empty())
2229     inferFrameworkLink(ActiveModule);
2230 
2231   // If the module meets all requirements but is still unavailable, mark the
2232   // whole tree as unavailable to prevent it from building.
2233   if (!ActiveModule->IsAvailable && !ActiveModule->IsUnimportable &&
2234       ActiveModule->Parent) {
2235     ActiveModule->getTopLevelModule()->markUnavailable(/*Unimportable=*/false);
2236     ActiveModule->getTopLevelModule()->MissingHeaders.append(
2237       ActiveModule->MissingHeaders.begin(), ActiveModule->MissingHeaders.end());
2238   }
2239 
2240   // We're done parsing this module. Pop back to the previous module.
2241   ActiveModule = PreviousActiveModule;
2242 }
2243 
2244 /// Parse an extern module declaration.
2245 ///
2246 ///   extern module-declaration:
2247 ///     'extern' 'module' module-id string-literal
2248 void ModuleMapParser::parseExternModuleDecl() {
2249   assert(Tok.is(MMToken::ExternKeyword));
2250   SourceLocation ExternLoc = consumeToken(); // 'extern' keyword
2251 
2252   // Parse 'module' keyword.
2253   if (!Tok.is(MMToken::ModuleKeyword)) {
2254     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_module);
2255     consumeToken();
2256     HadError = true;
2257     return;
2258   }
2259   consumeToken(); // 'module' keyword
2260 
2261   // Parse the module name.
2262   ModuleId Id;
2263   if (parseModuleId(Id)) {
2264     HadError = true;
2265     return;
2266   }
2267 
2268   // Parse the referenced module map file name.
2269   if (!Tok.is(MMToken::StringLiteral)) {
2270     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_mmap_file);
2271     HadError = true;
2272     return;
2273   }
2274   std::string FileName = std::string(Tok.getString());
2275   consumeToken(); // filename
2276 
2277   StringRef FileNameRef = FileName;
2278   SmallString<128> ModuleMapFileName;
2279   if (llvm::sys::path::is_relative(FileNameRef)) {
2280     ModuleMapFileName += Directory.getName();
2281     llvm::sys::path::append(ModuleMapFileName, FileName);
2282     FileNameRef = ModuleMapFileName;
2283   }
2284   if (auto File = SourceMgr.getFileManager().getOptionalFileRef(FileNameRef))
2285     Map.parseModuleMapFile(
2286         *File, IsSystem,
2287         Map.HeaderInfo.getHeaderSearchOpts().ModuleMapFileHomeIsCwd
2288             ? Directory
2289             : File->getDir(),
2290         FileID(), nullptr, ExternLoc);
2291 }
2292 
2293 /// Whether to add the requirement \p Feature to the module \p M.
2294 ///
2295 /// This preserves backwards compatibility for two hacks in the Darwin system
2296 /// module map files:
2297 ///
2298 /// 1. The use of 'requires excluded' to make headers non-modular, which
2299 ///    should really be mapped to 'textual' now that we have this feature.  We
2300 ///    drop the 'excluded' requirement, and set \p IsRequiresExcludedHack to
2301 ///    true.  Later, this bit will be used to map all the headers inside this
2302 ///    module to 'textual'.
2303 ///
2304 ///    This affects Darwin.C.excluded (for assert.h) and Tcl.Private.
2305 ///
2306 /// 2. Removes a bogus cplusplus requirement from IOKit.avc.  This requirement
2307 ///    was never correct and causes issues now that we check it, so drop it.
2308 static bool shouldAddRequirement(Module *M, StringRef Feature,
2309                                  bool &IsRequiresExcludedHack) {
2310   if (Feature == "excluded" &&
2311       (M->fullModuleNameIs({"Darwin", "C", "excluded"}) ||
2312        M->fullModuleNameIs({"Tcl", "Private"}))) {
2313     IsRequiresExcludedHack = true;
2314     return false;
2315   } else if (Feature == "cplusplus" && M->fullModuleNameIs({"IOKit", "avc"})) {
2316     return false;
2317   }
2318 
2319   return true;
2320 }
2321 
2322 /// Parse a requires declaration.
2323 ///
2324 ///   requires-declaration:
2325 ///     'requires' feature-list
2326 ///
2327 ///   feature-list:
2328 ///     feature ',' feature-list
2329 ///     feature
2330 ///
2331 ///   feature:
2332 ///     '!'[opt] identifier
2333 void ModuleMapParser::parseRequiresDecl() {
2334   assert(Tok.is(MMToken::RequiresKeyword));
2335 
2336   // Parse 'requires' keyword.
2337   consumeToken();
2338 
2339   // Parse the feature-list.
2340   do {
2341     bool RequiredState = true;
2342     if (Tok.is(MMToken::Exclaim)) {
2343       RequiredState = false;
2344       consumeToken();
2345     }
2346 
2347     if (!Tok.is(MMToken::Identifier)) {
2348       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_feature);
2349       HadError = true;
2350       return;
2351     }
2352 
2353     // Consume the feature name.
2354     std::string Feature = std::string(Tok.getString());
2355     consumeToken();
2356 
2357     bool IsRequiresExcludedHack = false;
2358     bool ShouldAddRequirement =
2359         shouldAddRequirement(ActiveModule, Feature, IsRequiresExcludedHack);
2360 
2361     if (IsRequiresExcludedHack)
2362       UsesRequiresExcludedHack.insert(ActiveModule);
2363 
2364     if (ShouldAddRequirement) {
2365       // Add this feature.
2366       ActiveModule->addRequirement(Feature, RequiredState, Map.LangOpts,
2367                                    *Map.Target);
2368     }
2369 
2370     if (!Tok.is(MMToken::Comma))
2371       break;
2372 
2373     // Consume the comma.
2374     consumeToken();
2375   } while (true);
2376 }
2377 
2378 /// Parse a header declaration.
2379 ///
2380 ///   header-declaration:
2381 ///     'textual'[opt] 'header' string-literal
2382 ///     'private' 'textual'[opt] 'header' string-literal
2383 ///     'exclude' 'header' string-literal
2384 ///     'umbrella' 'header' string-literal
2385 ///
2386 /// FIXME: Support 'private textual header'.
2387 void ModuleMapParser::parseHeaderDecl(MMToken::TokenKind LeadingToken,
2388                                       SourceLocation LeadingLoc) {
2389   // We've already consumed the first token.
2390   ModuleMap::ModuleHeaderRole Role = ModuleMap::NormalHeader;
2391 
2392   if (LeadingToken == MMToken::PrivateKeyword) {
2393     Role = ModuleMap::PrivateHeader;
2394     // 'private' may optionally be followed by 'textual'.
2395     if (Tok.is(MMToken::TextualKeyword)) {
2396       LeadingToken = Tok.Kind;
2397       consumeToken();
2398     }
2399   } else if (LeadingToken == MMToken::ExcludeKeyword) {
2400     Role = ModuleMap::ExcludedHeader;
2401   }
2402 
2403   if (LeadingToken == MMToken::TextualKeyword)
2404     Role = ModuleMap::ModuleHeaderRole(Role | ModuleMap::TextualHeader);
2405 
2406   if (UsesRequiresExcludedHack.count(ActiveModule)) {
2407     // Mark this header 'textual' (see doc comment for
2408     // Module::UsesRequiresExcludedHack).
2409     Role = ModuleMap::ModuleHeaderRole(Role | ModuleMap::TextualHeader);
2410   }
2411 
2412   if (LeadingToken != MMToken::HeaderKeyword) {
2413     if (!Tok.is(MMToken::HeaderKeyword)) {
2414       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_header)
2415           << (LeadingToken == MMToken::PrivateKeyword ? "private" :
2416               LeadingToken == MMToken::ExcludeKeyword ? "exclude" :
2417               LeadingToken == MMToken::TextualKeyword ? "textual" : "umbrella");
2418       return;
2419     }
2420     consumeToken();
2421   }
2422 
2423   // Parse the header name.
2424   if (!Tok.is(MMToken::StringLiteral)) {
2425     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_header)
2426       << "header";
2427     HadError = true;
2428     return;
2429   }
2430   Module::UnresolvedHeaderDirective Header;
2431   Header.FileName = std::string(Tok.getString());
2432   Header.FileNameLoc = consumeToken();
2433   Header.IsUmbrella = LeadingToken == MMToken::UmbrellaKeyword;
2434   Header.Kind = Map.headerRoleToKind(Role);
2435 
2436   // Check whether we already have an umbrella.
2437   if (Header.IsUmbrella &&
2438       !std::holds_alternative<std::monostate>(ActiveModule->Umbrella)) {
2439     Diags.Report(Header.FileNameLoc, diag::err_mmap_umbrella_clash)
2440       << ActiveModule->getFullModuleName();
2441     HadError = true;
2442     return;
2443   }
2444 
2445   // If we were given stat information, parse it so we can skip looking for
2446   // the file.
2447   if (Tok.is(MMToken::LBrace)) {
2448     SourceLocation LBraceLoc = consumeToken();
2449 
2450     while (!Tok.is(MMToken::RBrace) && !Tok.is(MMToken::EndOfFile)) {
2451       enum Attribute { Size, ModTime, Unknown };
2452       StringRef Str = Tok.getString();
2453       SourceLocation Loc = consumeToken();
2454       switch (llvm::StringSwitch<Attribute>(Str)
2455                   .Case("size", Size)
2456                   .Case("mtime", ModTime)
2457                   .Default(Unknown)) {
2458       case Size:
2459         if (Header.Size)
2460           Diags.Report(Loc, diag::err_mmap_duplicate_header_attribute) << Str;
2461         if (!Tok.is(MMToken::IntegerLiteral)) {
2462           Diags.Report(Tok.getLocation(),
2463                        diag::err_mmap_invalid_header_attribute_value) << Str;
2464           skipUntil(MMToken::RBrace);
2465           break;
2466         }
2467         Header.Size = Tok.getInteger();
2468         consumeToken();
2469         break;
2470 
2471       case ModTime:
2472         if (Header.ModTime)
2473           Diags.Report(Loc, diag::err_mmap_duplicate_header_attribute) << Str;
2474         if (!Tok.is(MMToken::IntegerLiteral)) {
2475           Diags.Report(Tok.getLocation(),
2476                        diag::err_mmap_invalid_header_attribute_value) << Str;
2477           skipUntil(MMToken::RBrace);
2478           break;
2479         }
2480         Header.ModTime = Tok.getInteger();
2481         consumeToken();
2482         break;
2483 
2484       case Unknown:
2485         Diags.Report(Loc, diag::err_mmap_expected_header_attribute);
2486         skipUntil(MMToken::RBrace);
2487         break;
2488       }
2489     }
2490 
2491     if (Tok.is(MMToken::RBrace))
2492       consumeToken();
2493     else {
2494       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_rbrace);
2495       Diags.Report(LBraceLoc, diag::note_mmap_lbrace_match);
2496       HadError = true;
2497     }
2498   }
2499 
2500   bool NeedsFramework = false;
2501   // Don't add the top level headers to the builtin modules if the builtin headers
2502   // belong to the system modules.
2503   if (!Map.LangOpts.BuiltinHeadersInSystemModules || ActiveModule->isSubModule() || !isBuiltInModuleName(ActiveModule->Name))
2504     Map.addUnresolvedHeader(ActiveModule, std::move(Header), NeedsFramework);
2505 
2506   if (NeedsFramework)
2507     Diags.Report(CurrModuleDeclLoc, diag::note_mmap_add_framework_keyword)
2508       << ActiveModule->getFullModuleName()
2509       << FixItHint::CreateReplacement(CurrModuleDeclLoc, "framework module");
2510 }
2511 
2512 static bool compareModuleHeaders(const Module::Header &A,
2513                                  const Module::Header &B) {
2514   return A.NameAsWritten < B.NameAsWritten;
2515 }
2516 
2517 /// Parse an umbrella directory declaration.
2518 ///
2519 ///   umbrella-dir-declaration:
2520 ///     umbrella string-literal
2521 void ModuleMapParser::parseUmbrellaDirDecl(SourceLocation UmbrellaLoc) {
2522   // Parse the directory name.
2523   if (!Tok.is(MMToken::StringLiteral)) {
2524     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_header)
2525       << "umbrella";
2526     HadError = true;
2527     return;
2528   }
2529 
2530   std::string DirName = std::string(Tok.getString());
2531   std::string DirNameAsWritten = DirName;
2532   SourceLocation DirNameLoc = consumeToken();
2533 
2534   // Check whether we already have an umbrella.
2535   if (!std::holds_alternative<std::monostate>(ActiveModule->Umbrella)) {
2536     Diags.Report(DirNameLoc, diag::err_mmap_umbrella_clash)
2537       << ActiveModule->getFullModuleName();
2538     HadError = true;
2539     return;
2540   }
2541 
2542   // Look for this file.
2543   OptionalDirectoryEntryRef Dir;
2544   if (llvm::sys::path::is_absolute(DirName)) {
2545     Dir = SourceMgr.getFileManager().getOptionalDirectoryRef(DirName);
2546   } else {
2547     SmallString<128> PathName;
2548     PathName = Directory.getName();
2549     llvm::sys::path::append(PathName, DirName);
2550     Dir = SourceMgr.getFileManager().getOptionalDirectoryRef(PathName);
2551   }
2552 
2553   if (!Dir) {
2554     Diags.Report(DirNameLoc, diag::warn_mmap_umbrella_dir_not_found)
2555       << DirName;
2556     return;
2557   }
2558 
2559   if (UsesRequiresExcludedHack.count(ActiveModule)) {
2560     // Mark this header 'textual' (see doc comment for
2561     // ModuleMapParser::UsesRequiresExcludedHack). Although iterating over the
2562     // directory is relatively expensive, in practice this only applies to the
2563     // uncommonly used Tcl module on Darwin platforms.
2564     std::error_code EC;
2565     SmallVector<Module::Header, 6> Headers;
2566     llvm::vfs::FileSystem &FS =
2567         SourceMgr.getFileManager().getVirtualFileSystem();
2568     for (llvm::vfs::recursive_directory_iterator I(FS, Dir->getName(), EC), E;
2569          I != E && !EC; I.increment(EC)) {
2570       if (auto FE = SourceMgr.getFileManager().getOptionalFileRef(I->path())) {
2571         Module::Header Header = {"", std::string(I->path()), *FE};
2572         Headers.push_back(std::move(Header));
2573       }
2574     }
2575 
2576     // Sort header paths so that the pcm doesn't depend on iteration order.
2577     std::stable_sort(Headers.begin(), Headers.end(), compareModuleHeaders);
2578 
2579     for (auto &Header : Headers)
2580       Map.addHeader(ActiveModule, std::move(Header), ModuleMap::TextualHeader);
2581     return;
2582   }
2583 
2584   if (Module *OwningModule = Map.UmbrellaDirs[*Dir]) {
2585     Diags.Report(UmbrellaLoc, diag::err_mmap_umbrella_clash)
2586       << OwningModule->getFullModuleName();
2587     HadError = true;
2588     return;
2589   }
2590 
2591   // Record this umbrella directory.
2592   Map.setUmbrellaDirAsWritten(ActiveModule, *Dir, DirNameAsWritten, DirName);
2593 }
2594 
2595 /// Parse a module export declaration.
2596 ///
2597 ///   export-declaration:
2598 ///     'export' wildcard-module-id
2599 ///
2600 ///   wildcard-module-id:
2601 ///     identifier
2602 ///     '*'
2603 ///     identifier '.' wildcard-module-id
2604 void ModuleMapParser::parseExportDecl() {
2605   assert(Tok.is(MMToken::ExportKeyword));
2606   SourceLocation ExportLoc = consumeToken();
2607 
2608   // Parse the module-id with an optional wildcard at the end.
2609   ModuleId ParsedModuleId;
2610   bool Wildcard = false;
2611   do {
2612     // FIXME: Support string-literal module names here.
2613     if (Tok.is(MMToken::Identifier)) {
2614       ParsedModuleId.push_back(
2615           std::make_pair(std::string(Tok.getString()), Tok.getLocation()));
2616       consumeToken();
2617 
2618       if (Tok.is(MMToken::Period)) {
2619         consumeToken();
2620         continue;
2621       }
2622 
2623       break;
2624     }
2625 
2626     if(Tok.is(MMToken::Star)) {
2627       Wildcard = true;
2628       consumeToken();
2629       break;
2630     }
2631 
2632     Diags.Report(Tok.getLocation(), diag::err_mmap_module_id);
2633     HadError = true;
2634     return;
2635   } while (true);
2636 
2637   Module::UnresolvedExportDecl Unresolved = {
2638     ExportLoc, ParsedModuleId, Wildcard
2639   };
2640   ActiveModule->UnresolvedExports.push_back(Unresolved);
2641 }
2642 
2643 /// Parse a module export_as declaration.
2644 ///
2645 ///   export-as-declaration:
2646 ///     'export_as' identifier
2647 void ModuleMapParser::parseExportAsDecl() {
2648   assert(Tok.is(MMToken::ExportAsKeyword));
2649   consumeToken();
2650 
2651   if (!Tok.is(MMToken::Identifier)) {
2652     Diags.Report(Tok.getLocation(), diag::err_mmap_module_id);
2653     HadError = true;
2654     return;
2655   }
2656 
2657   if (ActiveModule->Parent) {
2658     Diags.Report(Tok.getLocation(), diag::err_mmap_submodule_export_as);
2659     consumeToken();
2660     return;
2661   }
2662 
2663   if (!ActiveModule->ExportAsModule.empty()) {
2664     if (ActiveModule->ExportAsModule == Tok.getString()) {
2665       Diags.Report(Tok.getLocation(), diag::warn_mmap_redundant_export_as)
2666         << ActiveModule->Name << Tok.getString();
2667     } else {
2668       Diags.Report(Tok.getLocation(), diag::err_mmap_conflicting_export_as)
2669         << ActiveModule->Name << ActiveModule->ExportAsModule
2670         << Tok.getString();
2671     }
2672   }
2673 
2674   ActiveModule->ExportAsModule = std::string(Tok.getString());
2675   Map.addLinkAsDependency(ActiveModule);
2676 
2677   consumeToken();
2678 }
2679 
2680 /// Parse a module use declaration.
2681 ///
2682 ///   use-declaration:
2683 ///     'use' wildcard-module-id
2684 void ModuleMapParser::parseUseDecl() {
2685   assert(Tok.is(MMToken::UseKeyword));
2686   auto KWLoc = consumeToken();
2687   // Parse the module-id.
2688   ModuleId ParsedModuleId;
2689   parseModuleId(ParsedModuleId);
2690 
2691   if (ActiveModule->Parent)
2692     Diags.Report(KWLoc, diag::err_mmap_use_decl_submodule);
2693   else
2694     ActiveModule->UnresolvedDirectUses.push_back(ParsedModuleId);
2695 }
2696 
2697 /// Parse a link declaration.
2698 ///
2699 ///   module-declaration:
2700 ///     'link' 'framework'[opt] string-literal
2701 void ModuleMapParser::parseLinkDecl() {
2702   assert(Tok.is(MMToken::LinkKeyword));
2703   SourceLocation LinkLoc = consumeToken();
2704 
2705   // Parse the optional 'framework' keyword.
2706   bool IsFramework = false;
2707   if (Tok.is(MMToken::FrameworkKeyword)) {
2708     consumeToken();
2709     IsFramework = true;
2710   }
2711 
2712   // Parse the library name
2713   if (!Tok.is(MMToken::StringLiteral)) {
2714     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_library_name)
2715       << IsFramework << SourceRange(LinkLoc);
2716     HadError = true;
2717     return;
2718   }
2719 
2720   std::string LibraryName = std::string(Tok.getString());
2721   consumeToken();
2722   ActiveModule->LinkLibraries.push_back(Module::LinkLibrary(LibraryName,
2723                                                             IsFramework));
2724 }
2725 
2726 /// Parse a configuration macro declaration.
2727 ///
2728 ///   module-declaration:
2729 ///     'config_macros' attributes[opt] config-macro-list?
2730 ///
2731 ///   config-macro-list:
2732 ///     identifier (',' identifier)?
2733 void ModuleMapParser::parseConfigMacros() {
2734   assert(Tok.is(MMToken::ConfigMacros));
2735   SourceLocation ConfigMacrosLoc = consumeToken();
2736 
2737   // Only top-level modules can have configuration macros.
2738   if (ActiveModule->Parent) {
2739     Diags.Report(ConfigMacrosLoc, diag::err_mmap_config_macro_submodule);
2740   }
2741 
2742   // Parse the optional attributes.
2743   Attributes Attrs;
2744   if (parseOptionalAttributes(Attrs))
2745     return;
2746 
2747   if (Attrs.IsExhaustive && !ActiveModule->Parent) {
2748     ActiveModule->ConfigMacrosExhaustive = true;
2749   }
2750 
2751   // If we don't have an identifier, we're done.
2752   // FIXME: Support macros with the same name as a keyword here.
2753   if (!Tok.is(MMToken::Identifier))
2754     return;
2755 
2756   // Consume the first identifier.
2757   if (!ActiveModule->Parent) {
2758     ActiveModule->ConfigMacros.push_back(Tok.getString().str());
2759   }
2760   consumeToken();
2761 
2762   do {
2763     // If there's a comma, consume it.
2764     if (!Tok.is(MMToken::Comma))
2765       break;
2766     consumeToken();
2767 
2768     // We expect to see a macro name here.
2769     // FIXME: Support macros with the same name as a keyword here.
2770     if (!Tok.is(MMToken::Identifier)) {
2771       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_config_macro);
2772       break;
2773     }
2774 
2775     // Consume the macro name.
2776     if (!ActiveModule->Parent) {
2777       ActiveModule->ConfigMacros.push_back(Tok.getString().str());
2778     }
2779     consumeToken();
2780   } while (true);
2781 }
2782 
2783 /// Format a module-id into a string.
2784 static std::string formatModuleId(const ModuleId &Id) {
2785   std::string result;
2786   {
2787     llvm::raw_string_ostream OS(result);
2788 
2789     for (unsigned I = 0, N = Id.size(); I != N; ++I) {
2790       if (I)
2791         OS << ".";
2792       OS << Id[I].first;
2793     }
2794   }
2795 
2796   return result;
2797 }
2798 
2799 /// Parse a conflict declaration.
2800 ///
2801 ///   module-declaration:
2802 ///     'conflict' module-id ',' string-literal
2803 void ModuleMapParser::parseConflict() {
2804   assert(Tok.is(MMToken::Conflict));
2805   SourceLocation ConflictLoc = consumeToken();
2806   Module::UnresolvedConflict Conflict;
2807 
2808   // Parse the module-id.
2809   if (parseModuleId(Conflict.Id))
2810     return;
2811 
2812   // Parse the ','.
2813   if (!Tok.is(MMToken::Comma)) {
2814     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_conflicts_comma)
2815       << SourceRange(ConflictLoc);
2816     return;
2817   }
2818   consumeToken();
2819 
2820   // Parse the message.
2821   if (!Tok.is(MMToken::StringLiteral)) {
2822     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_conflicts_message)
2823       << formatModuleId(Conflict.Id);
2824     return;
2825   }
2826   Conflict.Message = Tok.getString().str();
2827   consumeToken();
2828 
2829   // Add this unresolved conflict.
2830   ActiveModule->UnresolvedConflicts.push_back(Conflict);
2831 }
2832 
2833 /// Parse an inferred module declaration (wildcard modules).
2834 ///
2835 ///   module-declaration:
2836 ///     'explicit'[opt] 'framework'[opt] 'module' * attributes[opt]
2837 ///       { inferred-module-member* }
2838 ///
2839 ///   inferred-module-member:
2840 ///     'export' '*'
2841 ///     'exclude' identifier
2842 void ModuleMapParser::parseInferredModuleDecl(bool Framework, bool Explicit) {
2843   assert(Tok.is(MMToken::Star));
2844   SourceLocation StarLoc = consumeToken();
2845   bool Failed = false;
2846 
2847   // Inferred modules must be submodules.
2848   if (!ActiveModule && !Framework) {
2849     Diags.Report(StarLoc, diag::err_mmap_top_level_inferred_submodule);
2850     Failed = true;
2851   }
2852 
2853   if (ActiveModule) {
2854     // Inferred modules must have umbrella directories.
2855     if (!Failed && ActiveModule->IsAvailable &&
2856         !ActiveModule->getEffectiveUmbrellaDir()) {
2857       Diags.Report(StarLoc, diag::err_mmap_inferred_no_umbrella);
2858       Failed = true;
2859     }
2860 
2861     // Check for redefinition of an inferred module.
2862     if (!Failed && ActiveModule->InferSubmodules) {
2863       Diags.Report(StarLoc, diag::err_mmap_inferred_redef);
2864       if (ActiveModule->InferredSubmoduleLoc.isValid())
2865         Diags.Report(ActiveModule->InferredSubmoduleLoc,
2866                      diag::note_mmap_prev_definition);
2867       Failed = true;
2868     }
2869 
2870     // Check for the 'framework' keyword, which is not permitted here.
2871     if (Framework) {
2872       Diags.Report(StarLoc, diag::err_mmap_inferred_framework_submodule);
2873       Framework = false;
2874     }
2875   } else if (Explicit) {
2876     Diags.Report(StarLoc, diag::err_mmap_explicit_inferred_framework);
2877     Explicit = false;
2878   }
2879 
2880   // If there were any problems with this inferred submodule, skip its body.
2881   if (Failed) {
2882     if (Tok.is(MMToken::LBrace)) {
2883       consumeToken();
2884       skipUntil(MMToken::RBrace);
2885       if (Tok.is(MMToken::RBrace))
2886         consumeToken();
2887     }
2888     HadError = true;
2889     return;
2890   }
2891 
2892   // Parse optional attributes.
2893   Attributes Attrs;
2894   if (parseOptionalAttributes(Attrs))
2895     return;
2896 
2897   if (ActiveModule) {
2898     // Note that we have an inferred submodule.
2899     ActiveModule->InferSubmodules = true;
2900     ActiveModule->InferredSubmoduleLoc = StarLoc;
2901     ActiveModule->InferExplicitSubmodules = Explicit;
2902   } else {
2903     // We'll be inferring framework modules for this directory.
2904     Map.InferredDirectories[Directory].InferModules = true;
2905     Map.InferredDirectories[Directory].Attrs = Attrs;
2906     Map.InferredDirectories[Directory].ModuleMapFile = ModuleMapFile;
2907     // FIXME: Handle the 'framework' keyword.
2908   }
2909 
2910   // Parse the opening brace.
2911   if (!Tok.is(MMToken::LBrace)) {
2912     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_lbrace_wildcard);
2913     HadError = true;
2914     return;
2915   }
2916   SourceLocation LBraceLoc = consumeToken();
2917 
2918   // Parse the body of the inferred submodule.
2919   bool Done = false;
2920   do {
2921     switch (Tok.Kind) {
2922     case MMToken::EndOfFile:
2923     case MMToken::RBrace:
2924       Done = true;
2925       break;
2926 
2927     case MMToken::ExcludeKeyword:
2928       if (ActiveModule) {
2929         Diags.Report(Tok.getLocation(), diag::err_mmap_expected_inferred_member)
2930           << (ActiveModule != nullptr);
2931         consumeToken();
2932         break;
2933       }
2934 
2935       consumeToken();
2936       // FIXME: Support string-literal module names here.
2937       if (!Tok.is(MMToken::Identifier)) {
2938         Diags.Report(Tok.getLocation(), diag::err_mmap_missing_exclude_name);
2939         break;
2940       }
2941 
2942       Map.InferredDirectories[Directory].ExcludedModules.push_back(
2943           std::string(Tok.getString()));
2944       consumeToken();
2945       break;
2946 
2947     case MMToken::ExportKeyword:
2948       if (!ActiveModule) {
2949         Diags.Report(Tok.getLocation(), diag::err_mmap_expected_inferred_member)
2950           << (ActiveModule != nullptr);
2951         consumeToken();
2952         break;
2953       }
2954 
2955       consumeToken();
2956       if (Tok.is(MMToken::Star))
2957         ActiveModule->InferExportWildcard = true;
2958       else
2959         Diags.Report(Tok.getLocation(),
2960                      diag::err_mmap_expected_export_wildcard);
2961       consumeToken();
2962       break;
2963 
2964     case MMToken::ExplicitKeyword:
2965     case MMToken::ModuleKeyword:
2966     case MMToken::HeaderKeyword:
2967     case MMToken::PrivateKeyword:
2968     case MMToken::UmbrellaKeyword:
2969     default:
2970       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_inferred_member)
2971           << (ActiveModule != nullptr);
2972       consumeToken();
2973       break;
2974     }
2975   } while (!Done);
2976 
2977   if (Tok.is(MMToken::RBrace))
2978     consumeToken();
2979   else {
2980     Diags.Report(Tok.getLocation(), diag::err_mmap_expected_rbrace);
2981     Diags.Report(LBraceLoc, diag::note_mmap_lbrace_match);
2982     HadError = true;
2983   }
2984 }
2985 
2986 /// Parse optional attributes.
2987 ///
2988 ///   attributes:
2989 ///     attribute attributes
2990 ///     attribute
2991 ///
2992 ///   attribute:
2993 ///     [ identifier ]
2994 ///
2995 /// \param Attrs Will be filled in with the parsed attributes.
2996 ///
2997 /// \returns true if an error occurred, false otherwise.
2998 bool ModuleMapParser::parseOptionalAttributes(Attributes &Attrs) {
2999   bool HadError = false;
3000 
3001   while (Tok.is(MMToken::LSquare)) {
3002     // Consume the '['.
3003     SourceLocation LSquareLoc = consumeToken();
3004 
3005     // Check whether we have an attribute name here.
3006     if (!Tok.is(MMToken::Identifier)) {
3007       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_attribute);
3008       skipUntil(MMToken::RSquare);
3009       if (Tok.is(MMToken::RSquare))
3010         consumeToken();
3011       HadError = true;
3012     }
3013 
3014     // Decode the attribute name.
3015     AttributeKind Attribute
3016       = llvm::StringSwitch<AttributeKind>(Tok.getString())
3017           .Case("exhaustive", AT_exhaustive)
3018           .Case("extern_c", AT_extern_c)
3019           .Case("no_undeclared_includes", AT_no_undeclared_includes)
3020           .Case("system", AT_system)
3021           .Default(AT_unknown);
3022     switch (Attribute) {
3023     case AT_unknown:
3024       Diags.Report(Tok.getLocation(), diag::warn_mmap_unknown_attribute)
3025         << Tok.getString();
3026       break;
3027 
3028     case AT_system:
3029       Attrs.IsSystem = true;
3030       break;
3031 
3032     case AT_extern_c:
3033       Attrs.IsExternC = true;
3034       break;
3035 
3036     case AT_exhaustive:
3037       Attrs.IsExhaustive = true;
3038       break;
3039 
3040     case AT_no_undeclared_includes:
3041       Attrs.NoUndeclaredIncludes = true;
3042       break;
3043     }
3044     consumeToken();
3045 
3046     // Consume the ']'.
3047     if (!Tok.is(MMToken::RSquare)) {
3048       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_rsquare);
3049       Diags.Report(LSquareLoc, diag::note_mmap_lsquare_match);
3050       skipUntil(MMToken::RSquare);
3051       HadError = true;
3052     }
3053 
3054     if (Tok.is(MMToken::RSquare))
3055       consumeToken();
3056   }
3057 
3058   return HadError;
3059 }
3060 
3061 /// Parse a module map file.
3062 ///
3063 ///   module-map-file:
3064 ///     module-declaration*
3065 bool ModuleMapParser::parseModuleMapFile() {
3066   do {
3067     switch (Tok.Kind) {
3068     case MMToken::EndOfFile:
3069       return HadError;
3070 
3071     case MMToken::ExplicitKeyword:
3072     case MMToken::ExternKeyword:
3073     case MMToken::ModuleKeyword:
3074     case MMToken::FrameworkKeyword:
3075       parseModuleDecl();
3076       break;
3077 
3078     case MMToken::Comma:
3079     case MMToken::ConfigMacros:
3080     case MMToken::Conflict:
3081     case MMToken::Exclaim:
3082     case MMToken::ExcludeKeyword:
3083     case MMToken::ExportKeyword:
3084     case MMToken::ExportAsKeyword:
3085     case MMToken::HeaderKeyword:
3086     case MMToken::Identifier:
3087     case MMToken::LBrace:
3088     case MMToken::LinkKeyword:
3089     case MMToken::LSquare:
3090     case MMToken::Period:
3091     case MMToken::PrivateKeyword:
3092     case MMToken::RBrace:
3093     case MMToken::RSquare:
3094     case MMToken::RequiresKeyword:
3095     case MMToken::Star:
3096     case MMToken::StringLiteral:
3097     case MMToken::IntegerLiteral:
3098     case MMToken::TextualKeyword:
3099     case MMToken::UmbrellaKeyword:
3100     case MMToken::UseKeyword:
3101       Diags.Report(Tok.getLocation(), diag::err_mmap_expected_module);
3102       HadError = true;
3103       consumeToken();
3104       break;
3105     }
3106   } while (true);
3107 }
3108 
3109 bool ModuleMap::parseModuleMapFile(FileEntryRef File, bool IsSystem,
3110                                    DirectoryEntryRef Dir, FileID ID,
3111                                    unsigned *Offset,
3112                                    SourceLocation ExternModuleLoc) {
3113   assert(Target && "Missing target information");
3114   llvm::DenseMap<const FileEntry *, bool>::iterator Known
3115     = ParsedModuleMap.find(File);
3116   if (Known != ParsedModuleMap.end())
3117     return Known->second;
3118 
3119   // If the module map file wasn't already entered, do so now.
3120   if (ID.isInvalid()) {
3121     auto FileCharacter =
3122         IsSystem ? SrcMgr::C_System_ModuleMap : SrcMgr::C_User_ModuleMap;
3123     ID = SourceMgr.createFileID(File, ExternModuleLoc, FileCharacter);
3124   }
3125 
3126   assert(Target && "Missing target information");
3127   std::optional<llvm::MemoryBufferRef> Buffer = SourceMgr.getBufferOrNone(ID);
3128   if (!Buffer)
3129     return ParsedModuleMap[File] = true;
3130   assert((!Offset || *Offset <= Buffer->getBufferSize()) &&
3131          "invalid buffer offset");
3132 
3133   // Parse this module map file.
3134   Lexer L(SourceMgr.getLocForStartOfFile(ID), MMapLangOpts,
3135           Buffer->getBufferStart(),
3136           Buffer->getBufferStart() + (Offset ? *Offset : 0),
3137           Buffer->getBufferEnd());
3138   SourceLocation Start = L.getSourceLocation();
3139   ModuleMapParser Parser(L, SourceMgr, Target, Diags, *this, File, Dir,
3140                          IsSystem);
3141   bool Result = Parser.parseModuleMapFile();
3142   ParsedModuleMap[File] = Result;
3143 
3144   if (Offset) {
3145     auto Loc = SourceMgr.getDecomposedLoc(Parser.getLocation());
3146     assert(Loc.first == ID && "stopped in a different file?");
3147     *Offset = Loc.second;
3148   }
3149 
3150   // Notify callbacks that we parsed it.
3151   for (const auto &Cb : Callbacks)
3152     Cb->moduleMapFileRead(Start, File, IsSystem);
3153 
3154   return Result;
3155 }
3156