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//===- HeaderSearch.cpp - Resolve Header File Locations -------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file implements the DirectoryLookup and HeaderSearch interfaces.
//
//===----------------------------------------------------------------------===//
#include "clang/Lex/HeaderSearch.h"
#include "clang/Basic/Diagnostic.h"
#include "clang/Basic/FileManager.h"
#include "clang/Basic/IdentifierTable.h"
#include "clang/Basic/Module.h"
#include "clang/Basic/SourceManager.h"
#include "clang/Lex/DirectoryLookup.h"
#include "clang/Lex/ExternalPreprocessorSource.h"
#include "clang/Lex/HeaderMap.h"
#include "clang/Lex/HeaderSearchOptions.h"
#include "clang/Lex/LexDiagnostic.h"
#include "clang/Lex/ModuleMap.h"
#include "clang/Lex/Preprocessor.h"
#include "llvm/ADT/APInt.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/Allocator.h"
#include "llvm/Support/Capacity.h"
#include "llvm/Support/Errc.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/VirtualFileSystem.h"
#include "llvm/Support/xxhash.h"
#include <algorithm>
#include <cassert>
#include <cstddef>
#include <cstdio>
#include <cstring>
#include <string>
#include <system_error>
#include <utility>
using namespace clang;
#define DEBUG_TYPE "file-search"
ALWAYS_ENABLED_STATISTIC(NumIncluded, "Number of attempted #includes.");
ALWAYS_ENABLED_STATISTIC(
NumMultiIncludeFileOptzn,
"Number of #includes skipped due to the multi-include optimization.");
ALWAYS_ENABLED_STATISTIC(NumFrameworkLookups, "Number of framework lookups.");
ALWAYS_ENABLED_STATISTIC(NumSubFrameworkLookups,
"Number of subframework lookups.");
const IdentifierInfo *
HeaderFileInfo::getControllingMacro(ExternalPreprocessorSource *External) {
if (LazyControllingMacro.isID()) {
if (!External)
return nullptr;
LazyControllingMacro =
External->GetIdentifier(LazyControllingMacro.getID());
return LazyControllingMacro.getPtr();
}
IdentifierInfo *ControllingMacro = LazyControllingMacro.getPtr();
if (ControllingMacro && ControllingMacro->isOutOfDate()) {
assert(External && "We must have an external source if we have a "
"controlling macro that is out of date.");
External->updateOutOfDateIdentifier(*ControllingMacro);
}
return ControllingMacro;
}
ExternalHeaderFileInfoSource::~ExternalHeaderFileInfoSource() = default;
HeaderSearch::HeaderSearch(std::shared_ptr<HeaderSearchOptions> HSOpts,
SourceManager &SourceMgr, DiagnosticsEngine &Diags,
const LangOptions &LangOpts,
const TargetInfo *Target)
: HSOpts(std::move(HSOpts)), Diags(Diags),
FileMgr(SourceMgr.getFileManager()), FrameworkMap(64),
ModMap(SourceMgr, Diags, LangOpts, Target, *this) {}
void HeaderSearch::PrintStats() {
llvm::errs() << "\n*** HeaderSearch Stats:\n"
<< FileInfo.size() << " files tracked.\n";
unsigned NumOnceOnlyFiles = 0;
for (unsigned i = 0, e = FileInfo.size(); i != e; ++i)
NumOnceOnlyFiles += (FileInfo[i].isPragmaOnce || FileInfo[i].isImport);
llvm::errs() << " " << NumOnceOnlyFiles << " #import/#pragma once files.\n";
llvm::errs() << " " << NumIncluded << " #include/#include_next/#import.\n"
<< " " << NumMultiIncludeFileOptzn
<< " #includes skipped due to the multi-include optimization.\n";
llvm::errs() << NumFrameworkLookups << " framework lookups.\n"
<< NumSubFrameworkLookups << " subframework lookups.\n";
}
void HeaderSearch::SetSearchPaths(
std::vector<DirectoryLookup> dirs, unsigned int angledDirIdx,
unsigned int systemDirIdx,
llvm::DenseMap<unsigned int, unsigned int> searchDirToHSEntry) {
assert(angledDirIdx <= systemDirIdx && systemDirIdx <= dirs.size() &&
"Directory indices are unordered");
SearchDirs = std::move(dirs);
SearchDirsUsage.assign(SearchDirs.size(), false);
AngledDirIdx = angledDirIdx;
SystemDirIdx = systemDirIdx;
SearchDirToHSEntry = std::move(searchDirToHSEntry);
//LookupFileCache.clear();
indexInitialHeaderMaps();
}
void HeaderSearch::AddSearchPath(const DirectoryLookup &dir, bool isAngled) {
unsigned idx = isAngled ? SystemDirIdx : AngledDirIdx;
SearchDirs.insert(SearchDirs.begin() + idx, dir);
SearchDirsUsage.insert(SearchDirsUsage.begin() + idx, false);
if (!isAngled)
AngledDirIdx++;
SystemDirIdx++;
}
std::vector<bool> HeaderSearch::computeUserEntryUsage() const {
std::vector<bool> UserEntryUsage(HSOpts->UserEntries.size());
for (unsigned I = 0, E = SearchDirsUsage.size(); I < E; ++I) {
// Check whether this DirectoryLookup has been successfully used.
if (SearchDirsUsage[I]) {
auto UserEntryIdxIt = SearchDirToHSEntry.find(I);
// Check whether this DirectoryLookup maps to a HeaderSearch::UserEntry.
if (UserEntryIdxIt != SearchDirToHSEntry.end())
UserEntryUsage[UserEntryIdxIt->second] = true;
}
}
return UserEntryUsage;
}
std::vector<bool> HeaderSearch::collectVFSUsageAndClear() const {
std::vector<bool> VFSUsage;
if (!getHeaderSearchOpts().ModulesIncludeVFSUsage)
return VFSUsage;
llvm::vfs::FileSystem &RootFS = FileMgr.getVirtualFileSystem();
// TODO: This only works if the `RedirectingFileSystem`s were all created by
// `createVFSFromOverlayFiles`.
RootFS.visit([&](llvm::vfs::FileSystem &FS) {
if (auto *RFS = dyn_cast<llvm::vfs::RedirectingFileSystem>(&FS)) {
VFSUsage.push_back(RFS->hasBeenUsed());
RFS->clearHasBeenUsed();
}
});
assert(VFSUsage.size() == getHeaderSearchOpts().VFSOverlayFiles.size() &&
"A different number of RedirectingFileSystem's were present than "
"-ivfsoverlay options passed to Clang!");
// VFS visit order is the opposite of VFSOverlayFiles order.
std::reverse(VFSUsage.begin(), VFSUsage.end());
return VFSUsage;
}
/// CreateHeaderMap - This method returns a HeaderMap for the specified
/// FileEntry, uniquing them through the 'HeaderMaps' datastructure.
const HeaderMap *HeaderSearch::CreateHeaderMap(FileEntryRef FE) {
// We expect the number of headermaps to be small, and almost always empty.
// If it ever grows, use of a linear search should be re-evaluated.
if (!HeaderMaps.empty()) {
for (unsigned i = 0, e = HeaderMaps.size(); i != e; ++i)
// Pointer equality comparison of FileEntries works because they are
// already uniqued by inode.
if (HeaderMaps[i].first == FE)
return HeaderMaps[i].second.get();
}
if (std::unique_ptr<HeaderMap> HM = HeaderMap::Create(FE, FileMgr)) {
HeaderMaps.emplace_back(FE, std::move(HM));
return HeaderMaps.back().second.get();
}
return nullptr;
}
/// Get filenames for all registered header maps.
void HeaderSearch::getHeaderMapFileNames(
SmallVectorImpl<std::string> &Names) const {
for (auto &HM : HeaderMaps)
Names.push_back(std::string(HM.first.getName()));
}
std::string HeaderSearch::getCachedModuleFileName(Module *Module) {
OptionalFileEntryRef ModuleMap =
getModuleMap().getModuleMapFileForUniquing(Module);
// The ModuleMap maybe a nullptr, when we load a cached C++ module without
// *.modulemap file. In this case, just return an empty string.
if (!ModuleMap)
return {};
return getCachedModuleFileName(Module->Name, ModuleMap->getNameAsRequested());
}
std::string HeaderSearch::getPrebuiltModuleFileName(StringRef ModuleName,
bool FileMapOnly) {
// First check the module name to pcm file map.
auto i(HSOpts->PrebuiltModuleFiles.find(ModuleName));
if (i != HSOpts->PrebuiltModuleFiles.end())
return i->second;
if (FileMapOnly || HSOpts->PrebuiltModulePaths.empty())
return {};
// Then go through each prebuilt module directory and try to find the pcm
// file.
for (const std::string &Dir : HSOpts->PrebuiltModulePaths) {
SmallString<256> Result(Dir);
llvm::sys::fs::make_absolute(Result);
if (ModuleName.contains(':'))
// The separator of C++20 modules partitions (':') is not good for file
// systems, here clang and gcc choose '-' by default since it is not a
// valid character of C++ indentifiers. So we could avoid conflicts.
llvm::sys::path::append(Result, ModuleName.split(':').first + "-" +
ModuleName.split(':').second +
".pcm");
else
llvm::sys::path::append(Result, ModuleName + ".pcm");
if (getFileMgr().getOptionalFileRef(Result))
return std::string(Result);
}
return {};
}
std::string HeaderSearch::getPrebuiltImplicitModuleFileName(Module *Module) {
OptionalFileEntryRef ModuleMap =
getModuleMap().getModuleMapFileForUniquing(Module);
StringRef ModuleName = Module->Name;
StringRef ModuleMapPath = ModuleMap->getName();
StringRef ModuleCacheHash = HSOpts->DisableModuleHash ? "" : getModuleHash();
for (const std::string &Dir : HSOpts->PrebuiltModulePaths) {
SmallString<256> CachePath(Dir);
llvm::sys::fs::make_absolute(CachePath);
llvm::sys::path::append(CachePath, ModuleCacheHash);
std::string FileName =
getCachedModuleFileNameImpl(ModuleName, ModuleMapPath, CachePath);
if (!FileName.empty() && getFileMgr().getOptionalFileRef(FileName))
return FileName;
}
return {};
}
std::string HeaderSearch::getCachedModuleFileName(StringRef ModuleName,
StringRef ModuleMapPath) {
return getCachedModuleFileNameImpl(ModuleName, ModuleMapPath,
getModuleCachePath());
}
std::string HeaderSearch::getCachedModuleFileNameImpl(StringRef ModuleName,
StringRef ModuleMapPath,
StringRef CachePath) {
// If we don't have a module cache path or aren't supposed to use one, we
// can't do anything.
if (CachePath.empty())
return {};
SmallString<256> Result(CachePath);
if (HSOpts->DisableModuleHash) {
llvm::sys::path::append(Result, ModuleName + ".pcm");
} else {
// Construct the name <ModuleName>-<hash of ModuleMapPath>.pcm which should
// ideally be globally unique to this particular module. Name collisions
// in the hash are safe (because any translation unit can only import one
// module with each name), but result in a loss of caching.
//
// To avoid false-negatives, we form as canonical a path as we can, and map
// to lower-case in case we're on a case-insensitive file system.
SmallString<128> CanonicalPath(ModuleMapPath);
if (getModuleMap().canonicalizeModuleMapPath(CanonicalPath))
return {};
auto Hash = llvm::xxh3_64bits(CanonicalPath.str().lower());
SmallString<128> HashStr;
llvm::APInt(64, Hash).toStringUnsigned(HashStr, /*Radix*/36);
llvm::sys::path::append(Result, ModuleName + "-" + HashStr + ".pcm");
}
return Result.str().str();
}
Module *HeaderSearch::lookupModule(StringRef ModuleName,
SourceLocation ImportLoc, bool AllowSearch,
bool AllowExtraModuleMapSearch) {
// Look in the module map to determine if there is a module by this name.
Module *Module = ModMap.findModule(ModuleName);
if (Module || !AllowSearch || !HSOpts->ImplicitModuleMaps)
return Module;
StringRef SearchName = ModuleName;
Module = lookupModule(ModuleName, SearchName, ImportLoc,
AllowExtraModuleMapSearch);
// The facility for "private modules" -- adjacent, optional module maps named
// module.private.modulemap that are supposed to define private submodules --
// may have different flavors of names: FooPrivate, Foo_Private and Foo.Private.
//
// Foo.Private is now deprecated in favor of Foo_Private. Users of FooPrivate
// should also rename to Foo_Private. Representing private as submodules
// could force building unwanted dependencies into the parent module and cause
// dependency cycles.
if (!Module && SearchName.consume_back("_Private"))
Module = lookupModule(ModuleName, SearchName, ImportLoc,
AllowExtraModuleMapSearch);
if (!Module && SearchName.consume_back("Private"))
Module = lookupModule(ModuleName, SearchName, ImportLoc,
AllowExtraModuleMapSearch);
return Module;
}
Module *HeaderSearch::lookupModule(StringRef ModuleName, StringRef SearchName,
SourceLocation ImportLoc,
bool AllowExtraModuleMapSearch) {
Module *Module = nullptr;
// Look through the various header search paths to load any available module
// maps, searching for a module map that describes this module.
for (DirectoryLookup &Dir : search_dir_range()) {
if (Dir.isFramework()) {
// Search for or infer a module map for a framework. Here we use
// SearchName rather than ModuleName, to permit finding private modules
// named FooPrivate in buggy frameworks named Foo.
SmallString<128> FrameworkDirName;
FrameworkDirName += Dir.getFrameworkDirRef()->getName();
llvm::sys::path::append(FrameworkDirName, SearchName + ".framework");
if (auto FrameworkDir =
FileMgr.getOptionalDirectoryRef(FrameworkDirName)) {
bool IsSystem = Dir.getDirCharacteristic() != SrcMgr::C_User;
Module = loadFrameworkModule(ModuleName, *FrameworkDir, IsSystem);
if (Module)
break;
}
}
// FIXME: Figure out how header maps and module maps will work together.
// Only deal with normal search directories.
if (!Dir.isNormalDir())
continue;
bool IsSystem = Dir.isSystemHeaderDirectory();
// Only returns std::nullopt if not a normal directory, which we just
// checked
DirectoryEntryRef NormalDir = *Dir.getDirRef();
// Search for a module map file in this directory.
if (loadModuleMapFile(NormalDir, IsSystem,
/*IsFramework*/false) == LMM_NewlyLoaded) {
// We just loaded a module map file; check whether the module is
// available now.
Module = ModMap.findModule(ModuleName);
if (Module)
break;
}
// Search for a module map in a subdirectory with the same name as the
// module.
SmallString<128> NestedModuleMapDirName;
NestedModuleMapDirName = Dir.getDirRef()->getName();
llvm::sys::path::append(NestedModuleMapDirName, ModuleName);
if (loadModuleMapFile(NestedModuleMapDirName, IsSystem,
/*IsFramework*/false) == LMM_NewlyLoaded){
// If we just loaded a module map file, look for the module again.
Module = ModMap.findModule(ModuleName);
if (Module)
break;
}
if (HSOpts->AllowModuleMapSubdirectorySearch) {
// If we've already performed the exhaustive search for module maps in
// this search directory, don't do it again.
if (Dir.haveSearchedAllModuleMaps())
continue;
// Load all module maps in the immediate subdirectories of this search
// directory if ModuleName was from @import.
if (AllowExtraModuleMapSearch)
loadSubdirectoryModuleMaps(Dir);
// Look again for the module.
Module = ModMap.findModule(ModuleName);
if (Module)
break;
}
}
return Module;
}
void HeaderSearch::indexInitialHeaderMaps() {
llvm::StringMap<unsigned, llvm::BumpPtrAllocator> Index(SearchDirs.size());
// Iterate over all filename keys and associate them with the index i.
for (unsigned i = 0; i != SearchDirs.size(); ++i) {
auto &Dir = SearchDirs[i];
// We're concerned with only the initial contiguous run of header
// maps within SearchDirs, which can be 99% of SearchDirs when
// SearchDirs.size() is ~10000.
if (!Dir.isHeaderMap()) {
SearchDirHeaderMapIndex = std::move(Index);
FirstNonHeaderMapSearchDirIdx = i;
break;
}
// Give earlier keys precedence over identical later keys.
auto Callback = [&](StringRef Filename) {
Index.try_emplace(Filename.lower(), i);
};
Dir.getHeaderMap()->forEachKey(Callback);
}
}
//===----------------------------------------------------------------------===//
// File lookup within a DirectoryLookup scope
//===----------------------------------------------------------------------===//
/// getName - Return the directory or filename corresponding to this lookup
/// object.
StringRef DirectoryLookup::getName() const {
if (isNormalDir())
return getDirRef()->getName();
if (isFramework())
return getFrameworkDirRef()->getName();
assert(isHeaderMap() && "Unknown DirectoryLookup");
return getHeaderMap()->getFileName();
}
OptionalFileEntryRef HeaderSearch::getFileAndSuggestModule(
StringRef FileName, SourceLocation IncludeLoc, const DirectoryEntry *Dir,
bool IsSystemHeaderDir, Module *RequestingModule,
ModuleMap::KnownHeader *SuggestedModule, bool OpenFile /*=true*/,
bool CacheFailures /*=true*/) {
// If we have a module map that might map this header, load it and
// check whether we'll have a suggestion for a module.
auto File = getFileMgr().getFileRef(FileName, OpenFile, CacheFailures);
if (!File) {
// For rare, surprising errors (e.g. "out of file handles"), diag the EC
// message.
std::error_code EC = llvm::errorToErrorCode(File.takeError());
if (EC != llvm::errc::no_such_file_or_directory &&
EC != llvm::errc::invalid_argument &&
EC != llvm::errc::is_a_directory && EC != llvm::errc::not_a_directory) {
Diags.Report(IncludeLoc, diag::err_cannot_open_file)
<< FileName << EC.message();
}
return std::nullopt;
}
// If there is a module that corresponds to this header, suggest it.
if (!findUsableModuleForHeader(
*File, Dir ? Dir : File->getFileEntry().getDir(), RequestingModule,
SuggestedModule, IsSystemHeaderDir))
return std::nullopt;
return *File;
}
/// LookupFile - Lookup the specified file in this search path, returning it
/// if it exists or returning null if not.
OptionalFileEntryRef DirectoryLookup::LookupFile(
StringRef &Filename, HeaderSearch &HS, SourceLocation IncludeLoc,
SmallVectorImpl<char> *SearchPath, SmallVectorImpl<char> *RelativePath,
Module *RequestingModule, ModuleMap::KnownHeader *SuggestedModule,
bool &InUserSpecifiedSystemFramework, bool &IsFrameworkFound,
bool &IsInHeaderMap, SmallVectorImpl<char> &MappedName,
bool OpenFile) const {
InUserSpecifiedSystemFramework = false;
IsInHeaderMap = false;
MappedName.clear();
SmallString<1024> TmpDir;
if (isNormalDir()) {
// Concatenate the requested file onto the directory.
TmpDir = getDirRef()->getName();
llvm::sys::path::append(TmpDir, Filename);
if (SearchPath) {
StringRef SearchPathRef(getDirRef()->getName());
SearchPath->clear();
SearchPath->append(SearchPathRef.begin(), SearchPathRef.end());
}
if (RelativePath) {
RelativePath->clear();
RelativePath->append(Filename.begin(), Filename.end());
}
return HS.getFileAndSuggestModule(
TmpDir, IncludeLoc, getDir(), isSystemHeaderDirectory(),
RequestingModule, SuggestedModule, OpenFile);
}
if (isFramework())
return DoFrameworkLookup(Filename, HS, SearchPath, RelativePath,
RequestingModule, SuggestedModule,
InUserSpecifiedSystemFramework, IsFrameworkFound);
assert(isHeaderMap() && "Unknown directory lookup");
const HeaderMap *HM = getHeaderMap();
SmallString<1024> Path;
StringRef Dest = HM->lookupFilename(Filename, Path);
if (Dest.empty())
return std::nullopt;
IsInHeaderMap = true;
auto FixupSearchPathAndFindUsableModule =
[&](FileEntryRef File) -> OptionalFileEntryRef {
if (SearchPath) {
StringRef SearchPathRef(getName());
SearchPath->clear();
SearchPath->append(SearchPathRef.begin(), SearchPathRef.end());
}
if (RelativePath) {
RelativePath->clear();
RelativePath->append(Filename.begin(), Filename.end());
}
if (!HS.findUsableModuleForHeader(File, File.getFileEntry().getDir(),
RequestingModule, SuggestedModule,
isSystemHeaderDirectory())) {
return std::nullopt;
}
return File;
};
// Check if the headermap maps the filename to a framework include
// ("Foo.h" -> "Foo/Foo.h"), in which case continue header lookup using the
// framework include.
if (llvm::sys::path::is_relative(Dest)) {
MappedName.append(Dest.begin(), Dest.end());
Filename = StringRef(MappedName.begin(), MappedName.size());
Dest = HM->lookupFilename(Filename, Path);
}
if (auto Res = HS.getFileMgr().getOptionalFileRef(Dest, OpenFile)) {
return FixupSearchPathAndFindUsableModule(*Res);
}
// Header maps need to be marked as used whenever the filename matches.
// The case where the target file **exists** is handled by callee of this
// function as part of the regular logic that applies to include search paths.
// The case where the target file **does not exist** is handled here:
HS.noteLookupUsage(HS.searchDirIdx(*this), IncludeLoc);
return std::nullopt;
}
/// Given a framework directory, find the top-most framework directory.
///
/// \param FileMgr The file manager to use for directory lookups.
/// \param DirName The name of the framework directory.
/// \param SubmodulePath Will be populated with the submodule path from the
/// returned top-level module to the originally named framework.
static OptionalDirectoryEntryRef
getTopFrameworkDir(FileManager &FileMgr, StringRef DirName,
SmallVectorImpl<std::string> &SubmodulePath) {
assert(llvm::sys::path::extension(DirName) == ".framework" &&
"Not a framework directory");
// Note: as an egregious but useful hack we use the real path here, because
// frameworks moving between top-level frameworks to embedded frameworks tend
// to be symlinked, and we base the logical structure of modules on the
// physical layout. In particular, we need to deal with crazy includes like
//
// #include <Foo/Frameworks/Bar.framework/Headers/Wibble.h>
//
// where 'Bar' used to be embedded in 'Foo', is now a top-level framework
// which one should access with, e.g.,
//
// #include <Bar/Wibble.h>
//
// Similar issues occur when a top-level framework has moved into an
// embedded framework.
auto TopFrameworkDir = FileMgr.getOptionalDirectoryRef(DirName);
if (TopFrameworkDir)
DirName = FileMgr.getCanonicalName(*TopFrameworkDir);
do {
// Get the parent directory name.
DirName = llvm::sys::path::parent_path(DirName);
if (DirName.empty())
break;
// Determine whether this directory exists.
auto Dir = FileMgr.getOptionalDirectoryRef(DirName);
if (!Dir)
break;
// If this is a framework directory, then we're a subframework of this
// framework.
if (llvm::sys::path::extension(DirName) == ".framework") {
SubmodulePath.push_back(std::string(llvm::sys::path::stem(DirName)));
TopFrameworkDir = *Dir;
}
} while (true);
return TopFrameworkDir;
}
static bool needModuleLookup(Module *RequestingModule,
bool HasSuggestedModule) {
return HasSuggestedModule ||
(RequestingModule && RequestingModule->NoUndeclaredIncludes);
}
/// DoFrameworkLookup - Do a lookup of the specified file in the current
/// DirectoryLookup, which is a framework directory.
OptionalFileEntryRef DirectoryLookup::DoFrameworkLookup(
StringRef Filename, HeaderSearch &HS, SmallVectorImpl<char> *SearchPath,
SmallVectorImpl<char> *RelativePath, Module *RequestingModule,
ModuleMap::KnownHeader *SuggestedModule,
bool &InUserSpecifiedSystemFramework, bool &IsFrameworkFound) const {
FileManager &FileMgr = HS.getFileMgr();
// Framework names must have a '/' in the filename.
size_t SlashPos = Filename.find('/');
if (SlashPos == StringRef::npos)
return std::nullopt;
// Find out if this is the home for the specified framework, by checking
// HeaderSearch. Possible answers are yes/no and unknown.
FrameworkCacheEntry &CacheEntry =
HS.LookupFrameworkCache(Filename.substr(0, SlashPos));
// If it is known and in some other directory, fail.
if (CacheEntry.Directory && CacheEntry.Directory != getFrameworkDirRef())
return std::nullopt;
// Otherwise, construct the path to this framework dir.
// FrameworkName = "/System/Library/Frameworks/"
SmallString<1024> FrameworkName;
FrameworkName += getFrameworkDirRef()->getName();
if (FrameworkName.empty() || FrameworkName.back() != '/')
FrameworkName.push_back('/');
// FrameworkName = "/System/Library/Frameworks/Cocoa"
StringRef ModuleName(Filename.begin(), SlashPos);
FrameworkName += ModuleName;
// FrameworkName = "/System/Library/Frameworks/Cocoa.framework/"
FrameworkName += ".framework/";
// If the cache entry was unresolved, populate it now.
if (!CacheEntry.Directory) {
++NumFrameworkLookups;
// If the framework dir doesn't exist, we fail.
auto Dir = FileMgr.getOptionalDirectoryRef(FrameworkName);
if (!Dir)
return std::nullopt;
// Otherwise, if it does, remember that this is the right direntry for this
// framework.
CacheEntry.Directory = getFrameworkDirRef();
// If this is a user search directory, check if the framework has been
// user-specified as a system framework.
if (getDirCharacteristic() == SrcMgr::C_User) {
SmallString<1024> SystemFrameworkMarker(FrameworkName);
SystemFrameworkMarker += ".system_framework";
if (llvm::sys::fs::exists(SystemFrameworkMarker)) {
CacheEntry.IsUserSpecifiedSystemFramework = true;
}
}
}
// Set out flags.
InUserSpecifiedSystemFramework = CacheEntry.IsUserSpecifiedSystemFramework;
IsFrameworkFound = CacheEntry.Directory.has_value();
if (RelativePath) {
RelativePath->clear();
RelativePath->append(Filename.begin()+SlashPos+1, Filename.end());
}
// Check "/System/Library/Frameworks/Cocoa.framework/Headers/file.h"
unsigned OrigSize = FrameworkName.size();
FrameworkName += "Headers/";
if (SearchPath) {
SearchPath->clear();
// Without trailing '/'.
SearchPath->append(FrameworkName.begin(), FrameworkName.end()-1);
}
FrameworkName.append(Filename.begin()+SlashPos+1, Filename.end());
auto File =
FileMgr.getOptionalFileRef(FrameworkName, /*OpenFile=*/!SuggestedModule);
if (!File) {
// Check "/System/Library/Frameworks/Cocoa.framework/PrivateHeaders/file.h"
const char *Private = "Private";
FrameworkName.insert(FrameworkName.begin()+OrigSize, Private,
Private+strlen(Private));
if (SearchPath)
SearchPath->insert(SearchPath->begin()+OrigSize, Private,
Private+strlen(Private));
File = FileMgr.getOptionalFileRef(FrameworkName,
/*OpenFile=*/!SuggestedModule);
}
// If we found the header and are allowed to suggest a module, do so now.
if (File && needModuleLookup(RequestingModule, SuggestedModule)) {
// Find the framework in which this header occurs.
StringRef FrameworkPath = File->getDir().getName();
bool FoundFramework = false;
do {
// Determine whether this directory exists.
auto Dir = FileMgr.getOptionalDirectoryRef(FrameworkPath);
if (!Dir)
break;
// If this is a framework directory, then we're a subframework of this
// framework.
if (llvm::sys::path::extension(FrameworkPath) == ".framework") {
FoundFramework = true;
break;
}
// Get the parent directory name.
FrameworkPath = llvm::sys::path::parent_path(FrameworkPath);
if (FrameworkPath.empty())
break;
} while (true);
bool IsSystem = getDirCharacteristic() != SrcMgr::C_User;
if (FoundFramework) {
if (!HS.findUsableModuleForFrameworkHeader(*File, FrameworkPath,
RequestingModule,
SuggestedModule, IsSystem))
return std::nullopt;
} else {
if (!HS.findUsableModuleForHeader(*File, getDir(), RequestingModule,
SuggestedModule, IsSystem))
return std::nullopt;
}
}
if (File)
return *File;
return std::nullopt;
}
void HeaderSearch::cacheLookupSuccess(LookupFileCacheInfo &CacheLookup,
ConstSearchDirIterator HitIt,
SourceLocation Loc) {
CacheLookup.HitIt = HitIt;
noteLookupUsage(HitIt.Idx, Loc);
}
void HeaderSearch::noteLookupUsage(unsigned HitIdx, SourceLocation Loc) {
SearchDirsUsage[HitIdx] = true;
auto UserEntryIdxIt = SearchDirToHSEntry.find(HitIdx);
if (UserEntryIdxIt != SearchDirToHSEntry.end())
Diags.Report(Loc, diag::remark_pp_search_path_usage)
<< HSOpts->UserEntries[UserEntryIdxIt->second].Path;
}
void HeaderSearch::setTarget(const TargetInfo &Target) {
ModMap.setTarget(Target);
}
//===----------------------------------------------------------------------===//
// Header File Location.
//===----------------------------------------------------------------------===//
/// Return true with a diagnostic if the file that MSVC would have found
/// fails to match the one that Clang would have found with MSVC header search
/// disabled.
static bool checkMSVCHeaderSearch(DiagnosticsEngine &Diags,
OptionalFileEntryRef MSFE,
const FileEntry *FE,
SourceLocation IncludeLoc) {
if (MSFE && FE != *MSFE) {
Diags.Report(IncludeLoc, diag::ext_pp_include_search_ms) << MSFE->getName();
return true;
}
return false;
}
static const char *copyString(StringRef Str, llvm::BumpPtrAllocator &Alloc) {
assert(!Str.empty());
char *CopyStr = Alloc.Allocate<char>(Str.size()+1);
std::copy(Str.begin(), Str.end(), CopyStr);
CopyStr[Str.size()] = '\0';
return CopyStr;
}
static bool isFrameworkStylePath(StringRef Path, bool &IsPrivateHeader,
SmallVectorImpl<char> &FrameworkName,
SmallVectorImpl<char> &IncludeSpelling) {
using namespace llvm::sys;
path::const_iterator I = path::begin(Path);
path::const_iterator E = path::end(Path);
IsPrivateHeader = false;
// Detect different types of framework style paths:
//
// ...Foo.framework/{Headers,PrivateHeaders}
// ...Foo.framework/Versions/{A,Current}/{Headers,PrivateHeaders}
// ...Foo.framework/Frameworks/Nested.framework/{Headers,PrivateHeaders}
// ...<other variations with 'Versions' like in the above path>
//
// and some other variations among these lines.
int FoundComp = 0;
while (I != E) {
if (*I == "Headers") {
++FoundComp;
} else if (*I == "PrivateHeaders") {
++FoundComp;
IsPrivateHeader = true;
} else if (I->ends_with(".framework")) {
StringRef Name = I->drop_back(10); // Drop .framework
// Need to reset the strings and counter to support nested frameworks.
FrameworkName.clear();
FrameworkName.append(Name.begin(), Name.end());
IncludeSpelling.clear();
IncludeSpelling.append(Name.begin(), Name.end());
FoundComp = 1;
} else if (FoundComp >= 2) {
IncludeSpelling.push_back('/');
IncludeSpelling.append(I->begin(), I->end());
}
++I;
}
return !FrameworkName.empty() && FoundComp >= 2;
}
static void
diagnoseFrameworkInclude(DiagnosticsEngine &Diags, SourceLocation IncludeLoc,
StringRef Includer, StringRef IncludeFilename,
FileEntryRef IncludeFE, bool isAngled = false,
bool FoundByHeaderMap = false) {
bool IsIncluderPrivateHeader = false;
SmallString<128> FromFramework, ToFramework;
SmallString<128> FromIncludeSpelling, ToIncludeSpelling;
if (!isFrameworkStylePath(Includer, IsIncluderPrivateHeader, FromFramework,
FromIncludeSpelling))
return;
bool IsIncludeePrivateHeader = false;
bool IsIncludeeInFramework =
isFrameworkStylePath(IncludeFE.getName(), IsIncludeePrivateHeader,
ToFramework, ToIncludeSpelling);
if (!isAngled && !FoundByHeaderMap) {
SmallString<128> NewInclude("<");
if (IsIncludeeInFramework) {
NewInclude += ToIncludeSpelling;
NewInclude += ">";
} else {
NewInclude += IncludeFilename;
NewInclude += ">";
}
Diags.Report(IncludeLoc, diag::warn_quoted_include_in_framework_header)
<< IncludeFilename
<< FixItHint::CreateReplacement(IncludeLoc, NewInclude);
}
// Headers in Foo.framework/Headers should not include headers
// from Foo.framework/PrivateHeaders, since this violates public/private
// API boundaries and can cause modular dependency cycles.
if (!IsIncluderPrivateHeader && IsIncludeeInFramework &&
IsIncludeePrivateHeader && FromFramework == ToFramework)
Diags.Report(IncludeLoc, diag::warn_framework_include_private_from_public)
<< IncludeFilename;
}
/// LookupFile - Given a "foo" or \<foo> reference, look up the indicated file,
/// return null on failure. isAngled indicates whether the file reference is
/// for system \#include's or not (i.e. using <> instead of ""). Includers, if
/// non-empty, indicates where the \#including file(s) are, in case a relative
/// search is needed. Microsoft mode will pass all \#including files.
OptionalFileEntryRef HeaderSearch::LookupFile(
StringRef Filename, SourceLocation IncludeLoc, bool isAngled,
ConstSearchDirIterator FromDir, ConstSearchDirIterator *CurDirArg,
ArrayRef<std::pair<OptionalFileEntryRef, DirectoryEntryRef>> Includers,
SmallVectorImpl<char> *SearchPath, SmallVectorImpl<char> *RelativePath,
Module *RequestingModule, ModuleMap::KnownHeader *SuggestedModule,
bool *IsMapped, bool *IsFrameworkFound, bool SkipCache,
bool BuildSystemModule, bool OpenFile, bool CacheFailures) {
ConstSearchDirIterator CurDirLocal = nullptr;
ConstSearchDirIterator &CurDir = CurDirArg ? *CurDirArg : CurDirLocal;
if (IsMapped)
*IsMapped = false;
if (IsFrameworkFound)
*IsFrameworkFound = false;
if (SuggestedModule)
*SuggestedModule = ModuleMap::KnownHeader();
// If 'Filename' is absolute, check to see if it exists and no searching.
if (llvm::sys::path::is_absolute(Filename)) {
CurDir = nullptr;
// If this was an #include_next "/absolute/file", fail.
if (FromDir)
return std::nullopt;
if (SearchPath)
SearchPath->clear();
if (RelativePath) {
RelativePath->clear();
RelativePath->append(Filename.begin(), Filename.end());
}
// Otherwise, just return the file.
return getFileAndSuggestModule(Filename, IncludeLoc, nullptr,
/*IsSystemHeaderDir*/ false,
RequestingModule, SuggestedModule, OpenFile,
CacheFailures);
}
// This is the header that MSVC's header search would have found.
ModuleMap::KnownHeader MSSuggestedModule;
OptionalFileEntryRef MSFE;
// Check to see if the file is in the #includer's directory. This cannot be
// based on CurDir, because each includer could be a #include of a
// subdirectory (#include "foo/bar.h") and a subsequent include of "baz.h"
// should resolve to "whatever/foo/baz.h". This search is not done for <>
// headers.
if (!Includers.empty() && !isAngled) {
SmallString<1024> TmpDir;
bool First = true;
for (const auto &IncluderAndDir : Includers) {
OptionalFileEntryRef Includer = IncluderAndDir.first;
// Concatenate the requested file onto the directory.
TmpDir = IncluderAndDir.second.getName();
llvm::sys::path::append(TmpDir, Filename);
// FIXME: We don't cache the result of getFileInfo across the call to
// getFileAndSuggestModule, because it's a reference to an element of
// a container that could be reallocated across this call.
//
// If we have no includer, that means we're processing a #include
// from a module build. We should treat this as a system header if we're
// building a [system] module.
bool IncluderIsSystemHeader = [&]() {
if (!Includer)
return BuildSystemModule;
const HeaderFileInfo *HFI = getExistingFileInfo(*Includer);
assert(HFI && "includer without file info");
return HFI->DirInfo != SrcMgr::C_User;
}();
if (OptionalFileEntryRef FE = getFileAndSuggestModule(
TmpDir, IncludeLoc, IncluderAndDir.second, IncluderIsSystemHeader,
RequestingModule, SuggestedModule)) {
if (!Includer) {
assert(First && "only first includer can have no file");
return FE;
}
// Leave CurDir unset.
// This file is a system header or C++ unfriendly if the old file is.
//
// Note that we only use one of FromHFI/ToHFI at once, due to potential
// reallocation of the underlying vector potentially making the first
// reference binding dangling.
const HeaderFileInfo *FromHFI = getExistingFileInfo(*Includer);
assert(FromHFI && "includer without file info");
unsigned DirInfo = FromHFI->DirInfo;
HeaderFileInfo &ToHFI = getFileInfo(*FE);
ToHFI.DirInfo = DirInfo;
if (SearchPath) {
StringRef SearchPathRef(IncluderAndDir.second.getName());
SearchPath->clear();
SearchPath->append(SearchPathRef.begin(), SearchPathRef.end());
}
if (RelativePath) {
RelativePath->clear();
RelativePath->append(Filename.begin(), Filename.end());
}
if (First) {
diagnoseFrameworkInclude(Diags, IncludeLoc,
IncluderAndDir.second.getName(), Filename,
*FE);
return FE;
}
// Otherwise, we found the path via MSVC header search rules. If
// -Wmsvc-include is enabled, we have to keep searching to see if we
// would've found this header in -I or -isystem directories.
if (Diags.isIgnored(diag::ext_pp_include_search_ms, IncludeLoc)) {
return FE;
} else {
MSFE = FE;
if (SuggestedModule) {
MSSuggestedModule = *SuggestedModule;
*SuggestedModule = ModuleMap::KnownHeader();
}
break;
}
}
First = false;
}
}
CurDir = nullptr;
// If this is a system #include, ignore the user #include locs.
ConstSearchDirIterator It =
isAngled ? angled_dir_begin() : search_dir_begin();
// If this is a #include_next request, start searching after the directory the
// file was found in.
if (FromDir)
It = FromDir;
// Cache all of the lookups performed by this method. Many headers are
// multiply included, and the "pragma once" optimization prevents them from
// being relex/pp'd, but they would still have to search through a
// (potentially huge) series of SearchDirs to find it.
LookupFileCacheInfo &CacheLookup = LookupFileCache[Filename];
ConstSearchDirIterator NextIt = std::next(It);
if (!SkipCache) {
if (CacheLookup.StartIt == NextIt &&
CacheLookup.RequestingModule == RequestingModule) {
// HIT: Skip querying potentially lots of directories for this lookup.
if (CacheLookup.HitIt)
It = CacheLookup.HitIt;
if (CacheLookup.MappedName) {
Filename = CacheLookup.MappedName;
if (IsMapped)
*IsMapped = true;
}
} else {
// MISS: This is the first query, or the previous query didn't match
// our search start. We will fill in our found location below, so prime
// the start point value.
CacheLookup.reset(RequestingModule, /*NewStartIt=*/NextIt);
if (It == search_dir_begin() && FirstNonHeaderMapSearchDirIdx > 0) {
// Handle cold misses of user includes in the presence of many header
// maps. We avoid searching perhaps thousands of header maps by
// jumping directly to the correct one or jumping beyond all of them.
auto Iter = SearchDirHeaderMapIndex.find(Filename.lower());
if (Iter == SearchDirHeaderMapIndex.end())
// Not in index => Skip to first SearchDir after initial header maps
It = search_dir_nth(FirstNonHeaderMapSearchDirIdx);
else
// In index => Start with a specific header map
It = search_dir_nth(Iter->second);
}
}
} else {
CacheLookup.reset(RequestingModule, /*NewStartIt=*/NextIt);
}
SmallString<64> MappedName;
// Check each directory in sequence to see if it contains this file.
for (; It != search_dir_end(); ++It) {
bool InUserSpecifiedSystemFramework = false;
bool IsInHeaderMap = false;
bool IsFrameworkFoundInDir = false;
OptionalFileEntryRef File = It->LookupFile(
Filename, *this, IncludeLoc, SearchPath, RelativePath, RequestingModule,
SuggestedModule, InUserSpecifiedSystemFramework, IsFrameworkFoundInDir,
IsInHeaderMap, MappedName, OpenFile);
if (!MappedName.empty()) {
assert(IsInHeaderMap && "MappedName should come from a header map");
CacheLookup.MappedName =
copyString(MappedName, LookupFileCache.getAllocator());
}
if (IsMapped)
// A filename is mapped when a header map remapped it to a relative path
// used in subsequent header search or to an absolute path pointing to an
// existing file.
*IsMapped |= (!MappedName.empty() || (IsInHeaderMap && File));
if (IsFrameworkFound)
// Because we keep a filename remapped for subsequent search directory
// lookups, ignore IsFrameworkFoundInDir after the first remapping and not
// just for remapping in a current search directory.
*IsFrameworkFound |= (IsFrameworkFoundInDir && !CacheLookup.MappedName);
if (!File)
continue;
CurDir = It;
IncludeNames[*File] = Filename;
// This file is a system header or C++ unfriendly if the dir is.
HeaderFileInfo &HFI = getFileInfo(*File);
HFI.DirInfo = CurDir->getDirCharacteristic();
// If the directory characteristic is User but this framework was
// user-specified to be treated as a system framework, promote the
// characteristic.
if (HFI.DirInfo == SrcMgr::C_User && InUserSpecifiedSystemFramework)
HFI.DirInfo = SrcMgr::C_System;
// If the filename matches a known system header prefix, override
// whether the file is a system header.
for (unsigned j = SystemHeaderPrefixes.size(); j; --j) {
if (Filename.starts_with(SystemHeaderPrefixes[j - 1].first)) {
HFI.DirInfo = SystemHeaderPrefixes[j-1].second ? SrcMgr::C_System
: SrcMgr::C_User;
break;
}
}
if (checkMSVCHeaderSearch(Diags, MSFE, &File->getFileEntry(), IncludeLoc)) {
if (SuggestedModule)
*SuggestedModule = MSSuggestedModule;
return MSFE;
}
bool FoundByHeaderMap = !IsMapped ? false : *IsMapped;
if (!Includers.empty())
diagnoseFrameworkInclude(Diags, IncludeLoc,
Includers.front().second.getName(), Filename,
*File, isAngled, FoundByHeaderMap);
// Remember this location for the next lookup we do.
cacheLookupSuccess(CacheLookup, It, IncludeLoc);
return File;
}
if (checkMSVCHeaderSearch(Diags, MSFE, nullptr, IncludeLoc)) {
if (SuggestedModule)
*SuggestedModule = MSSuggestedModule;
return MSFE;
}
// Otherwise, didn't find it. Remember we didn't find this.
CacheLookup.HitIt = search_dir_end();
return std::nullopt;
}
/// LookupSubframeworkHeader - Look up a subframework for the specified
/// \#include file. For example, if \#include'ing <HIToolbox/HIToolbox.h> from
/// within ".../Carbon.framework/Headers/Carbon.h", check to see if HIToolbox
/// is a subframework within Carbon.framework. If so, return the FileEntry
/// for the designated file, otherwise return null.
OptionalFileEntryRef HeaderSearch::LookupSubframeworkHeader(
StringRef Filename, FileEntryRef ContextFileEnt,
SmallVectorImpl<char> *SearchPath, SmallVectorImpl<char> *RelativePath,
Module *RequestingModule, ModuleMap::KnownHeader *SuggestedModule) {
// Framework names must have a '/' in the filename. Find it.
// FIXME: Should we permit '\' on Windows?
size_t SlashPos = Filename.find('/');
if (SlashPos == StringRef::npos)
return std::nullopt;
// Look up the base framework name of the ContextFileEnt.
StringRef ContextName = ContextFileEnt.getName();
// If the context info wasn't a framework, couldn't be a subframework.
const unsigned DotFrameworkLen = 10;
auto FrameworkPos = ContextName.find(".framework");
if (FrameworkPos == StringRef::npos ||
(ContextName[FrameworkPos + DotFrameworkLen] != '/' &&
ContextName[FrameworkPos + DotFrameworkLen] != '\\'))
return std::nullopt;
SmallString<1024> FrameworkName(ContextName.data(), ContextName.data() +
FrameworkPos +
DotFrameworkLen + 1);
// Append Frameworks/HIToolbox.framework/
FrameworkName += "Frameworks/";
FrameworkName.append(Filename.begin(), Filename.begin()+SlashPos);
FrameworkName += ".framework/";
auto &CacheLookup =
*FrameworkMap.insert(std::make_pair(Filename.substr(0, SlashPos),
FrameworkCacheEntry())).first;
// Some other location?
if (CacheLookup.second.Directory &&
CacheLookup.first().size() == FrameworkName.size() &&
memcmp(CacheLookup.first().data(), &FrameworkName[0],
CacheLookup.first().size()) != 0)
return std::nullopt;
// Cache subframework.
if (!CacheLookup.second.Directory) {
++NumSubFrameworkLookups;
// If the framework dir doesn't exist, we fail.
auto Dir = FileMgr.getOptionalDirectoryRef(FrameworkName);
if (!Dir)
return std::nullopt;
// Otherwise, if it does, remember that this is the right direntry for this
// framework.
CacheLookup.second.Directory = Dir;
}
if (RelativePath) {
RelativePath->clear();
RelativePath->append(Filename.begin()+SlashPos+1, Filename.end());
}
// Check ".../Frameworks/HIToolbox.framework/Headers/HIToolbox.h"
SmallString<1024> HeadersFilename(FrameworkName);
HeadersFilename += "Headers/";
if (SearchPath) {
SearchPath->clear();
// Without trailing '/'.
SearchPath->append(HeadersFilename.begin(), HeadersFilename.end()-1);
}
HeadersFilename.append(Filename.begin()+SlashPos+1, Filename.end());
auto File = FileMgr.getOptionalFileRef(HeadersFilename, /*OpenFile=*/true);
if (!File) {
// Check ".../Frameworks/HIToolbox.framework/PrivateHeaders/HIToolbox.h"
HeadersFilename = FrameworkName;
HeadersFilename += "PrivateHeaders/";
if (SearchPath) {
SearchPath->clear();
// Without trailing '/'.
SearchPath->append(HeadersFilename.begin(), HeadersFilename.end()-1);
}
HeadersFilename.append(Filename.begin()+SlashPos+1, Filename.end());
File = FileMgr.getOptionalFileRef(HeadersFilename, /*OpenFile=*/true);
if (!File)
return std::nullopt;
}
// This file is a system header or C++ unfriendly if the old file is.
const HeaderFileInfo *ContextHFI = getExistingFileInfo(ContextFileEnt);
assert(ContextHFI && "context file without file info");
// Note that the temporary 'DirInfo' is required here, as the call to
// getFileInfo could resize the vector and might invalidate 'ContextHFI'.
unsigned DirInfo = ContextHFI->DirInfo;
getFileInfo(*File).DirInfo = DirInfo;
FrameworkName.pop_back(); // remove the trailing '/'
if (!findUsableModuleForFrameworkHeader(*File, FrameworkName,
RequestingModule, SuggestedModule,
/*IsSystem*/ false))
return std::nullopt;
return *File;
}
//===----------------------------------------------------------------------===//
// File Info Management.
//===----------------------------------------------------------------------===//
static bool moduleMembershipNeedsMerge(const HeaderFileInfo *HFI,
ModuleMap::ModuleHeaderRole Role) {
if (ModuleMap::isModular(Role))
return !HFI->isModuleHeader || HFI->isTextualModuleHeader;
if (!HFI->isModuleHeader && (Role & ModuleMap::TextualHeader))
return !HFI->isTextualModuleHeader;
return false;
}
static void mergeHeaderFileInfoModuleBits(HeaderFileInfo &HFI,
bool isModuleHeader,
bool isTextualModuleHeader) {
HFI.isModuleHeader |= isModuleHeader;
if (HFI.isModuleHeader)
HFI.isTextualModuleHeader = false;
else
HFI.isTextualModuleHeader |= isTextualModuleHeader;
}
void HeaderFileInfo::mergeModuleMembership(ModuleMap::ModuleHeaderRole Role) {
mergeHeaderFileInfoModuleBits(*this, ModuleMap::isModular(Role),
(Role & ModuleMap::TextualHeader));
}
/// Merge the header file info provided by \p OtherHFI into the current
/// header file info (\p HFI)
static void mergeHeaderFileInfo(HeaderFileInfo &HFI,
const HeaderFileInfo &OtherHFI) {
assert(OtherHFI.External && "expected to merge external HFI");
HFI.isImport |= OtherHFI.isImport;
HFI.isPragmaOnce |= OtherHFI.isPragmaOnce;
mergeHeaderFileInfoModuleBits(HFI, OtherHFI.isModuleHeader,
OtherHFI.isTextualModuleHeader);
if (!HFI.LazyControllingMacro.isValid())
HFI.LazyControllingMacro = OtherHFI.LazyControllingMacro;
HFI.DirInfo = OtherHFI.DirInfo;
HFI.External = (!HFI.IsValid || HFI.External);
HFI.IsValid = true;
}
HeaderFileInfo &HeaderSearch::getFileInfo(FileEntryRef FE) {
if (FE.getUID() >= FileInfo.size())
FileInfo.resize(FE.getUID() + 1);
HeaderFileInfo *HFI = &FileInfo[FE.getUID()];
// FIXME: Use a generation count to check whether this is really up to date.
if (ExternalSource && !HFI->Resolved) {
auto ExternalHFI = ExternalSource->GetHeaderFileInfo(FE);
if (ExternalHFI.IsValid) {
HFI->Resolved = true;
if (ExternalHFI.External)
mergeHeaderFileInfo(*HFI, ExternalHFI);
}
}
HFI->IsValid = true;
// We assume the caller has local information about this header file, so it's
// no longer strictly external.
HFI->External = false;
return *HFI;
}
const HeaderFileInfo *HeaderSearch::getExistingFileInfo(FileEntryRef FE) const {
HeaderFileInfo *HFI;
if (ExternalSource) {
if (FE.getUID() >= FileInfo.size())
FileInfo.resize(FE.getUID() + 1);
HFI = &FileInfo[FE.getUID()];
// FIXME: Use a generation count to check whether this is really up to date.
if (!HFI->Resolved) {
auto ExternalHFI = ExternalSource->GetHeaderFileInfo(FE);
if (ExternalHFI.IsValid) {
HFI->Resolved = true;
if (ExternalHFI.External)
mergeHeaderFileInfo(*HFI, ExternalHFI);
}
}
} else if (FE.getUID() < FileInfo.size()) {
HFI = &FileInfo[FE.getUID()];
} else {
HFI = nullptr;
}
return (HFI && HFI->IsValid) ? HFI : nullptr;
}
const HeaderFileInfo *
HeaderSearch::getExistingLocalFileInfo(FileEntryRef FE) const {
HeaderFileInfo *HFI;
if (FE.getUID() < FileInfo.size()) {
HFI = &FileInfo[FE.getUID()];
} else {
HFI = nullptr;
}
return (HFI && HFI->IsValid && !HFI->External) ? HFI : nullptr;
}
bool HeaderSearch::isFileMultipleIncludeGuarded(FileEntryRef File) const {
// Check if we've entered this file and found an include guard or #pragma
// once. Note that we dor't check for #import, because that's not a property
// of the file itself.
if (auto *HFI = getExistingFileInfo(File))
return HFI->isPragmaOnce || HFI->LazyControllingMacro.isValid();
return false;
}
void HeaderSearch::MarkFileModuleHeader(FileEntryRef FE,
ModuleMap::ModuleHeaderRole Role,
bool isCompilingModuleHeader) {
// Don't mark the file info as non-external if there's nothing to change.
if (!isCompilingModuleHeader) {
if ((Role & ModuleMap::ExcludedHeader))
return;
auto *HFI = getExistingFileInfo(FE);
if (HFI && !moduleMembershipNeedsMerge(HFI, Role))
return;
}
auto &HFI = getFileInfo(FE);
HFI.mergeModuleMembership(Role);
HFI.isCompilingModuleHeader |= isCompilingModuleHeader;
}
bool HeaderSearch::ShouldEnterIncludeFile(Preprocessor &PP,
FileEntryRef File, bool isImport,
bool ModulesEnabled, Module *M,
bool &IsFirstIncludeOfFile) {
// An include file should be entered if either:
// 1. This is the first include of the file.
// 2. This file can be included multiple times, that is it's not an
// "include-once" file.
//
// Include-once is controlled by these preprocessor directives.
//
// #pragma once
// This directive is in the include file, and marks it as an include-once
// file.
//
// #import <file>
// This directive is in the includer, and indicates that the include file
// should only be entered if this is the first include.
++NumIncluded;
IsFirstIncludeOfFile = false;
HeaderFileInfo &FileInfo = getFileInfo(File);
auto MaybeReenterImportedFile = [&]() -> bool {
// Modules add a wrinkle though: what's included isn't necessarily visible.
// Consider this module.
// module Example {
// module A { header "a.h" export * }
// module B { header "b.h" export * }
// }
// b.h includes c.h. The main file includes a.h, which will trigger a module
// build of Example, and c.h will be included. However, c.h isn't visible to
// the main file. Normally this is fine, the main file can just include c.h
// if it needs it. If c.h is in a module, the include will translate into a
// module import, this function will be skipped, and everything will work as
// expected. However, if c.h is not in a module (or is `textual`), then this
// function will run. If c.h is include-once, it will not be entered from
// the main file and it will still not be visible.
// If modules aren't enabled then there's no visibility issue. Always
// respect `#pragma once`.
if (!ModulesEnabled || FileInfo.isPragmaOnce)
return false;
// Ensure FileInfo bits are up to date.
ModMap.resolveHeaderDirectives(File);
// This brings up a subtlety of #import - it's not a very good indicator of
// include-once. Developers are often unaware of the difference between
// #include and #import, and tend to use one or the other indiscrimiately.
// In order to support #include on include-once headers that lack macro
// guards and `#pragma once` (which is the vast majority of Objective-C
// headers), if a file is ever included with #import, it's marked as
// isImport in the HeaderFileInfo and treated as include-once. This allows
// #include to work in Objective-C.
// #include <Foundation/Foundation.h>
// #include <Foundation/NSString.h>
// Foundation.h has an #import of NSString.h, and so the second #include is
// skipped even though NSString.h has no `#pragma once` and no macro guard.
//
// However, this helpfulness causes problems with modules. If c.h is not an
// include-once file, but something included it with #import anyway (as is
// typical in Objective-C code), this include will be skipped and c.h will
// not be visible. Consider it not include-once if it is a `textual` header
// in a module.
if (FileInfo.isTextualModuleHeader)
return true;
if (FileInfo.isCompilingModuleHeader) {
// It's safer to re-enter a file whose module is being built because its
// declarations will still be scoped to a single module.
if (FileInfo.isModuleHeader) {
// Headers marked as "builtin" are covered by the system module maps
// rather than the builtin ones. Some versions of the Darwin module fail
// to mark stdarg.h and stddef.h as textual. Attempt to re-enter these
// files while building their module to allow them to function properly.
if (ModMap.isBuiltinHeader(File))
return true;
} else {
// Files that are excluded from their module can potentially be
// re-entered from their own module. This might cause redeclaration
// errors if another module saw this file first, but there's a
// reasonable chance that its module will build first. However if
// there's no controlling macro, then trust the #import and assume this
// really is an include-once file.
if (FileInfo.getControllingMacro(ExternalLookup))
return true;
}
}
// If the include file has a macro guard, then it might still not be
// re-entered if the controlling macro is visibly defined. e.g. another
// header in the module being built included this file and local submodule
// visibility is not enabled.
// It might be tempting to re-enter the include-once file if it's not
// visible in an attempt to make it visible. However this will still cause
// redeclaration errors against the known-but-not-visible declarations. The
// include file not being visible will most likely cause "undefined x"
// errors, but at least there's a slim chance of compilation succeeding.
return false;
};
if (isImport) {
// As discussed above, record that this file was ever `#import`ed, and treat
// it as an include-once file from here out.
FileInfo.isImport = true;
if (PP.alreadyIncluded(File) && !MaybeReenterImportedFile())
return false;
} else {
// isPragmaOnce and isImport are only set after the file has been included
// at least once. If either are set then this is a repeat #include of an
// include-once file.
if (FileInfo.isPragmaOnce ||
(FileInfo.isImport && !MaybeReenterImportedFile()))
return false;
}
// As a final optimization, check for a macro guard and skip entering the file
// if the controlling macro is defined. The macro guard will effectively erase
// the file's contents, and the include would have no effect other than to
// waste time opening and reading a file.
if (const IdentifierInfo *ControllingMacro =
FileInfo.getControllingMacro(ExternalLookup)) {
// If the header corresponds to a module, check whether the macro is already
// defined in that module rather than checking all visible modules. This is
// mainly to cover corner cases where the same controlling macro is used in
// different files in multiple modules.
if (M ? PP.isMacroDefinedInLocalModule(ControllingMacro, M)
: PP.isMacroDefined(ControllingMacro)) {
++NumMultiIncludeFileOptzn;
return false;
}
}
IsFirstIncludeOfFile = PP.markIncluded(File);
return true;
}
size_t HeaderSearch::getTotalMemory() const {
return SearchDirs.capacity()
+ llvm::capacity_in_bytes(FileInfo)
+ llvm::capacity_in_bytes(HeaderMaps)
+ LookupFileCache.getAllocator().getTotalMemory()
+ FrameworkMap.getAllocator().getTotalMemory();
}
unsigned HeaderSearch::searchDirIdx(const DirectoryLookup &DL) const {
return &DL - &*SearchDirs.begin();
}
StringRef HeaderSearch::getUniqueFrameworkName(StringRef Framework) {
return FrameworkNames.insert(Framework).first->first();
}
StringRef HeaderSearch::getIncludeNameForHeader(const FileEntry *File) const {
auto It = IncludeNames.find(File);
if (It == IncludeNames.end())
return {};
return It->second;
}
bool HeaderSearch::hasModuleMap(StringRef FileName,
const DirectoryEntry *Root,
bool IsSystem) {
if (!HSOpts->ImplicitModuleMaps)
return false;
SmallVector<const DirectoryEntry *, 2> FixUpDirectories;
StringRef DirName = FileName;
do {
// Get the parent directory name.
DirName = llvm::sys::path::parent_path(DirName);
if (DirName.empty())
return false;
// Determine whether this directory exists.
auto Dir = FileMgr.getOptionalDirectoryRef(DirName);
if (!Dir)
return false;
// Try to load the module map file in this directory.
switch (loadModuleMapFile(*Dir, IsSystem,
llvm::sys::path::extension(Dir->getName()) ==
".framework")) {
case LMM_NewlyLoaded:
case LMM_AlreadyLoaded:
// Success. All of the directories we stepped through inherit this module
// map file.
for (unsigned I = 0, N = FixUpDirectories.size(); I != N; ++I)
DirectoryHasModuleMap[FixUpDirectories[I]] = true;
return true;
case LMM_NoDirectory:
case LMM_InvalidModuleMap:
break;
}
// If we hit the top of our search, we're done.
if (*Dir == Root)
return false;
// Keep track of all of the directories we checked, so we can mark them as
// having module maps if we eventually do find a module map.
FixUpDirectories.push_back(*Dir);
} while (true);
}
ModuleMap::KnownHeader
HeaderSearch::findModuleForHeader(FileEntryRef File, bool AllowTextual,
bool AllowExcluded) const {
if (ExternalSource) {
// Make sure the external source has handled header info about this file,
// which includes whether the file is part of a module.
(void)getExistingFileInfo(File);
}
return ModMap.findModuleForHeader(File, AllowTextual, AllowExcluded);
}
ArrayRef<ModuleMap::KnownHeader>
HeaderSearch::findAllModulesForHeader(FileEntryRef File) const {
if (ExternalSource) {
// Make sure the external source has handled header info about this file,
// which includes whether the file is part of a module.
(void)getExistingFileInfo(File);
}
return ModMap.findAllModulesForHeader(File);
}
ArrayRef<ModuleMap::KnownHeader>
HeaderSearch::findResolvedModulesForHeader(FileEntryRef File) const {
if (ExternalSource) {
// Make sure the external source has handled header info about this file,
// which includes whether the file is part of a module.
(void)getExistingFileInfo(File);
}
return ModMap.findResolvedModulesForHeader(File);
}
static bool suggestModule(HeaderSearch &HS, FileEntryRef File,
Module *RequestingModule,
ModuleMap::KnownHeader *SuggestedModule) {
ModuleMap::KnownHeader Module =
HS.findModuleForHeader(File, /*AllowTextual*/true);
// If this module specifies [no_undeclared_includes], we cannot find any
// file that's in a non-dependency module.
if (RequestingModule && Module && RequestingModule->NoUndeclaredIncludes) {
HS.getModuleMap().resolveUses(RequestingModule, /*Complain*/ false);
if (!RequestingModule->directlyUses(Module.getModule())) {
// Builtin headers are a special case. Multiple modules can use the same
// builtin as a modular header (see also comment in
// ShouldEnterIncludeFile()), so the builtin header may have been
// "claimed" by an unrelated module. This shouldn't prevent us from
// including the builtin header textually in this module.
if (HS.getModuleMap().isBuiltinHeader(File)) {
if (SuggestedModule)
*SuggestedModule = ModuleMap::KnownHeader();
return true;
}
// TODO: Add this module (or just its module map file) into something like
// `RequestingModule->AffectingClangModules`.
return false;
}
}
if (SuggestedModule)
*SuggestedModule = (Module.getRole() & ModuleMap::TextualHeader)
? ModuleMap::KnownHeader()
: Module;
return true;
}
bool HeaderSearch::findUsableModuleForHeader(
FileEntryRef File, const DirectoryEntry *Root, Module *RequestingModule,
ModuleMap::KnownHeader *SuggestedModule, bool IsSystemHeaderDir) {
if (needModuleLookup(RequestingModule, SuggestedModule)) {
// If there is a module that corresponds to this header, suggest it.
hasModuleMap(File.getNameAsRequested(), Root, IsSystemHeaderDir);
return suggestModule(*this, File, RequestingModule, SuggestedModule);
}
return true;
}
bool HeaderSearch::findUsableModuleForFrameworkHeader(
FileEntryRef File, StringRef FrameworkName, Module *RequestingModule,
ModuleMap::KnownHeader *SuggestedModule, bool IsSystemFramework) {
// If we're supposed to suggest a module, look for one now.
if (needModuleLookup(RequestingModule, SuggestedModule)) {
// Find the top-level framework based on this framework.
SmallVector<std::string, 4> SubmodulePath;
OptionalDirectoryEntryRef TopFrameworkDir =
::getTopFrameworkDir(FileMgr, FrameworkName, SubmodulePath);
assert(TopFrameworkDir && "Could not find the top-most framework dir");
// Determine the name of the top-level framework.
StringRef ModuleName = llvm::sys::path::stem(TopFrameworkDir->getName());
// Load this framework module. If that succeeds, find the suggested module
// for this header, if any.
loadFrameworkModule(ModuleName, *TopFrameworkDir, IsSystemFramework);
// FIXME: This can find a module not part of ModuleName, which is
// important so that we're consistent about whether this header
// corresponds to a module. Possibly we should lock down framework modules
// so that this is not possible.
return suggestModule(*this, File, RequestingModule, SuggestedModule);
}
return true;
}
static OptionalFileEntryRef getPrivateModuleMap(FileEntryRef File,
FileManager &FileMgr,
DiagnosticsEngine &Diags) {
StringRef Filename = llvm::sys::path::filename(File.getName());
SmallString<128> PrivateFilename(File.getDir().getName());
if (Filename == "module.map")
llvm::sys::path::append(PrivateFilename, "module_private.map");
else if (Filename == "module.modulemap")
llvm::sys::path::append(PrivateFilename, "module.private.modulemap");
else
return std::nullopt;
auto PMMFile = FileMgr.getOptionalFileRef(PrivateFilename);
if (PMMFile) {
if (Filename == "module.map")
Diags.Report(diag::warn_deprecated_module_dot_map)
<< PrivateFilename << 1
<< File.getDir().getName().ends_with(".framework");
}
return PMMFile;
}
bool HeaderSearch::loadModuleMapFile(FileEntryRef File, bool IsSystem,
FileID ID, unsigned *Offset,
StringRef OriginalModuleMapFile) {
// Find the directory for the module. For frameworks, that may require going
// up from the 'Modules' directory.
OptionalDirectoryEntryRef Dir;
if (getHeaderSearchOpts().ModuleMapFileHomeIsCwd) {
Dir = FileMgr.getOptionalDirectoryRef(".");
} else {
if (!OriginalModuleMapFile.empty()) {
// We're building a preprocessed module map. Find or invent the directory
// that it originally occupied.
Dir = FileMgr.getOptionalDirectoryRef(
llvm::sys::path::parent_path(OriginalModuleMapFile));
if (!Dir) {
auto FakeFile = FileMgr.getVirtualFileRef(OriginalModuleMapFile, 0, 0);
Dir = FakeFile.getDir();
}
} else {
Dir = File.getDir();
}
assert(Dir && "parent must exist");
StringRef DirName(Dir->getName());
if (llvm::sys::path::filename(DirName) == "Modules") {
DirName = llvm::sys::path::parent_path(DirName);
if (DirName.ends_with(".framework"))
if (auto MaybeDir = FileMgr.getOptionalDirectoryRef(DirName))
Dir = *MaybeDir;
// FIXME: This assert can fail if there's a race between the above check
// and the removal of the directory.
assert(Dir && "parent must exist");
}
}
assert(Dir && "module map home directory must exist");
switch (loadModuleMapFileImpl(File, IsSystem, *Dir, ID, Offset)) {
case LMM_AlreadyLoaded:
case LMM_NewlyLoaded:
return false;
case LMM_NoDirectory:
case LMM_InvalidModuleMap:
return true;
}
llvm_unreachable("Unknown load module map result");
}
HeaderSearch::LoadModuleMapResult
HeaderSearch::loadModuleMapFileImpl(FileEntryRef File, bool IsSystem,
DirectoryEntryRef Dir, FileID ID,
unsigned *Offset) {
// Check whether we've already loaded this module map, and mark it as being
// loaded in case we recursively try to load it from itself.
auto AddResult = LoadedModuleMaps.insert(std::make_pair(File, true));
if (!AddResult.second)
return AddResult.first->second ? LMM_AlreadyLoaded : LMM_InvalidModuleMap;
if (ModMap.parseModuleMapFile(File, IsSystem, Dir, ID, Offset)) {
LoadedModuleMaps[File] = false;
return LMM_InvalidModuleMap;
}
// Try to load a corresponding private module map.
if (OptionalFileEntryRef PMMFile =
getPrivateModuleMap(File, FileMgr, Diags)) {
if (ModMap.parseModuleMapFile(*PMMFile, IsSystem, Dir)) {
LoadedModuleMaps[File] = false;
return LMM_InvalidModuleMap;
}
}
// This directory has a module map.
return LMM_NewlyLoaded;
}
OptionalFileEntryRef
HeaderSearch::lookupModuleMapFile(DirectoryEntryRef Dir, bool IsFramework) {
if (!HSOpts->ImplicitModuleMaps)
return std::nullopt;
// For frameworks, the preferred spelling is Modules/module.modulemap, but
// module.map at the framework root is also accepted.
SmallString<128> ModuleMapFileName(Dir.getName());
if (IsFramework)
llvm::sys::path::append(ModuleMapFileName, "Modules");
llvm::sys::path::append(ModuleMapFileName, "module.modulemap");
if (auto F = FileMgr.getOptionalFileRef(ModuleMapFileName))
return *F;
// Continue to allow module.map, but warn it's deprecated.
ModuleMapFileName = Dir.getName();
llvm::sys::path::append(ModuleMapFileName, "module.map");
if (auto F = FileMgr.getOptionalFileRef(ModuleMapFileName)) {
Diags.Report(diag::warn_deprecated_module_dot_map)
<< ModuleMapFileName << 0 << IsFramework;
return *F;
}
// For frameworks, allow to have a private module map with a preferred
// spelling when a public module map is absent.
if (IsFramework) {
ModuleMapFileName = Dir.getName();
llvm::sys::path::append(ModuleMapFileName, "Modules",
"module.private.modulemap");
if (auto F = FileMgr.getOptionalFileRef(ModuleMapFileName))
return *F;
}
return std::nullopt;
}
Module *HeaderSearch::loadFrameworkModule(StringRef Name, DirectoryEntryRef Dir,
bool IsSystem) {
// Try to load a module map file.
switch (loadModuleMapFile(Dir, IsSystem, /*IsFramework*/true)) {
case LMM_InvalidModuleMap:
// Try to infer a module map from the framework directory.
if (HSOpts->ImplicitModuleMaps)
ModMap.inferFrameworkModule(Dir, IsSystem, /*Parent=*/nullptr);
break;
case LMM_NoDirectory:
return nullptr;
case LMM_AlreadyLoaded:
case LMM_NewlyLoaded:
break;
}
return ModMap.findModule(Name);
}
HeaderSearch::LoadModuleMapResult
HeaderSearch::loadModuleMapFile(StringRef DirName, bool IsSystem,
bool IsFramework) {
if (auto Dir = FileMgr.getOptionalDirectoryRef(DirName))
return loadModuleMapFile(*Dir, IsSystem, IsFramework);
return LMM_NoDirectory;
}
HeaderSearch::LoadModuleMapResult
HeaderSearch::loadModuleMapFile(DirectoryEntryRef Dir, bool IsSystem,
bool IsFramework) {
auto KnownDir = DirectoryHasModuleMap.find(Dir);
if (KnownDir != DirectoryHasModuleMap.end())
return KnownDir->second ? LMM_AlreadyLoaded : LMM_InvalidModuleMap;
if (OptionalFileEntryRef ModuleMapFile =
lookupModuleMapFile(Dir, IsFramework)) {
LoadModuleMapResult Result =
loadModuleMapFileImpl(*ModuleMapFile, IsSystem, Dir);
// Add Dir explicitly in case ModuleMapFile is in a subdirectory.
// E.g. Foo.framework/Modules/module.modulemap
// ^Dir ^ModuleMapFile
if (Result == LMM_NewlyLoaded)
DirectoryHasModuleMap[Dir] = true;
else if (Result == LMM_InvalidModuleMap)
DirectoryHasModuleMap[Dir] = false;
return Result;
}
return LMM_InvalidModuleMap;
}
void HeaderSearch::collectAllModules(SmallVectorImpl<Module *> &Modules) {
Modules.clear();
if (HSOpts->ImplicitModuleMaps) {
// Load module maps for each of the header search directories.
for (DirectoryLookup &DL : search_dir_range()) {
bool IsSystem = DL.isSystemHeaderDirectory();
if (DL.isFramework()) {
std::error_code EC;
SmallString<128> DirNative;
llvm::sys::path::native(DL.getFrameworkDirRef()->getName(), DirNative);
// Search each of the ".framework" directories to load them as modules.
llvm::vfs::FileSystem &FS = FileMgr.getVirtualFileSystem();
for (llvm::vfs::directory_iterator Dir = FS.dir_begin(DirNative, EC),
DirEnd;
Dir != DirEnd && !EC; Dir.increment(EC)) {
if (llvm::sys::path::extension(Dir->path()) != ".framework")
continue;
auto FrameworkDir = FileMgr.getOptionalDirectoryRef(Dir->path());
if (!FrameworkDir)
continue;
// Load this framework module.
loadFrameworkModule(llvm::sys::path::stem(Dir->path()), *FrameworkDir,
IsSystem);
}
continue;
}
// FIXME: Deal with header maps.
if (DL.isHeaderMap())
continue;
// Try to load a module map file for the search directory.
loadModuleMapFile(*DL.getDirRef(), IsSystem, /*IsFramework*/ false);
// Try to load module map files for immediate subdirectories of this
// search directory.
loadSubdirectoryModuleMaps(DL);
}
}
// Populate the list of modules.
llvm::transform(ModMap.modules(), std::back_inserter(Modules),
[](const auto &NameAndMod) { return NameAndMod.second; });
}
void HeaderSearch::loadTopLevelSystemModules() {
if (!HSOpts->ImplicitModuleMaps)
return;
// Load module maps for each of the header search directories.
for (const DirectoryLookup &DL : search_dir_range()) {
// We only care about normal header directories.
if (!DL.isNormalDir())
continue;
// Try to load a module map file for the search directory.
loadModuleMapFile(*DL.getDirRef(), DL.isSystemHeaderDirectory(),
DL.isFramework());
}
}
void HeaderSearch::loadSubdirectoryModuleMaps(DirectoryLookup &SearchDir) {
assert(HSOpts->ImplicitModuleMaps &&
"Should not be loading subdirectory module maps");
if (SearchDir.haveSearchedAllModuleMaps())
return;
std::error_code EC;
SmallString<128> Dir = SearchDir.getDirRef()->getName();
FileMgr.makeAbsolutePath(Dir);
SmallString<128> DirNative;
llvm::sys::path::native(Dir, DirNative);
llvm::vfs::FileSystem &FS = FileMgr.getVirtualFileSystem();
for (llvm::vfs::directory_iterator Dir = FS.dir_begin(DirNative, EC), DirEnd;
Dir != DirEnd && !EC; Dir.increment(EC)) {
if (Dir->type() == llvm::sys::fs::file_type::regular_file)
continue;
bool IsFramework = llvm::sys::path::extension(Dir->path()) == ".framework";
if (IsFramework == SearchDir.isFramework())
loadModuleMapFile(Dir->path(), SearchDir.isSystemHeaderDirectory(),
SearchDir.isFramework());
}
SearchDir.setSearchedAllModuleMaps(true);
}
std::string HeaderSearch::suggestPathToFileForDiagnostics(
FileEntryRef File, llvm::StringRef MainFile, bool *IsAngled) const {
return suggestPathToFileForDiagnostics(File.getName(), /*WorkingDir=*/"",
MainFile, IsAngled);
}
std::string HeaderSearch::suggestPathToFileForDiagnostics(
llvm::StringRef File, llvm::StringRef WorkingDir, llvm::StringRef MainFile,
bool *IsAngled) const {
using namespace llvm::sys;
llvm::SmallString<32> FilePath = File;
if (!WorkingDir.empty() && !path::is_absolute(FilePath))
fs::make_absolute(WorkingDir, FilePath);
// remove_dots switches to backslashes on windows as a side-effect!
// We always want to suggest forward slashes for includes.
// (not remove_dots(..., posix) as that misparses windows paths).
path::remove_dots(FilePath, /*remove_dot_dot=*/true);
path::native(FilePath, path::Style::posix);
File = FilePath;
unsigned BestPrefixLength = 0;
// Checks whether `Dir` is a strict path prefix of `File`. If so and that's
// the longest prefix we've seen so for it, returns true and updates the
// `BestPrefixLength` accordingly.
auto CheckDir = [&](llvm::SmallString<32> Dir) -> bool {
if (!WorkingDir.empty() && !path::is_absolute(Dir))
fs::make_absolute(WorkingDir, Dir);
path::remove_dots(Dir, /*remove_dot_dot=*/true);
for (auto NI = path::begin(File), NE = path::end(File),
DI = path::begin(Dir), DE = path::end(Dir);
NI != NE; ++NI, ++DI) {
if (DI == DE) {
// Dir is a prefix of File, up to choice of path separators.
unsigned PrefixLength = NI - path::begin(File);
if (PrefixLength > BestPrefixLength) {
BestPrefixLength = PrefixLength;
return true;
}
break;
}
// Consider all path separators equal.
if (NI->size() == 1 && DI->size() == 1 &&
path::is_separator(NI->front()) && path::is_separator(DI->front()))
continue;
// Special case Apple .sdk folders since the search path is typically a
// symlink like `iPhoneSimulator14.5.sdk` while the file is instead
// located in `iPhoneSimulator.sdk` (the real folder).
if (NI->ends_with(".sdk") && DI->ends_with(".sdk")) {
StringRef NBasename = path::stem(*NI);
StringRef DBasename = path::stem(*DI);
if (DBasename.starts_with(NBasename))
continue;
}
if (*NI != *DI)
break;
}
return false;
};
bool BestPrefixIsFramework = false;
for (const DirectoryLookup &DL : search_dir_range()) {
if (DL.isNormalDir()) {
StringRef Dir = DL.getDirRef()->getName();
if (CheckDir(Dir)) {
if (IsAngled)
*IsAngled = BestPrefixLength && isSystem(DL.getDirCharacteristic());
BestPrefixIsFramework = false;
}
} else if (DL.isFramework()) {
StringRef Dir = DL.getFrameworkDirRef()->getName();
if (CheckDir(Dir)) {
// Framework includes by convention use <>.
if (IsAngled)
*IsAngled = BestPrefixLength;
BestPrefixIsFramework = true;
}
}
}
// Try to shorten include path using TUs directory, if we couldn't find any
// suitable prefix in include search paths.
if (!BestPrefixLength && CheckDir(path::parent_path(MainFile))) {
if (IsAngled)
*IsAngled = false;
BestPrefixIsFramework = false;
}
// Try resolving resulting filename via reverse search in header maps,
// key from header name is user preferred name for the include file.
StringRef Filename = File.drop_front(BestPrefixLength);
for (const DirectoryLookup &DL : search_dir_range()) {
if (!DL.isHeaderMap())
continue;
StringRef SpelledFilename =
DL.getHeaderMap()->reverseLookupFilename(Filename);
if (!SpelledFilename.empty()) {
Filename = SpelledFilename;
BestPrefixIsFramework = false;
break;
}
}
// If the best prefix is a framework path, we need to compute the proper
// include spelling for the framework header.
bool IsPrivateHeader;
SmallString<128> FrameworkName, IncludeSpelling;
if (BestPrefixIsFramework &&
isFrameworkStylePath(Filename, IsPrivateHeader, FrameworkName,
IncludeSpelling)) {
Filename = IncludeSpelling;
}
return path::convert_to_slash(Filename);
}