Magic-Mirror/llvm-capstone
1
0
Fork 0
mirror of https://github.com/capstone-engine/llvm-capstone.git synced 2025-04-13 11:51:17 +00:00
Code Issues Actions 2 Packages Projects Releases Wiki Activity
llvm-capstone/clang/lib/Frontend/CompilerInstance.cpp
Kevin P. Neal d4ce862f2a Reland "[FPEnv][Clang][Driver] Disable constrained floating point on targets lacking support." 
We currently have strict floating point/constrained floating point enabled
for all targets. Constrained SDAG nodes get converted to the regular ones
before reaching the target layer. In theory this should be fine.

However, the changes are exposed to users through multiple clang options
already in use in the field, and the changes are _completely_ _untested_
on almost all of our targets. Bugs have already been found, like
"https://bugs.llvm.org/show_bug.cgi?id=45274".

This patch disables constrained floating point options in clang everywhere
except X86 and SystemZ. A warning will be printed when this happens.

Use the new -fexperimental-strict-floating-point flag to force allowing
strict floating point on hosts that aren't already marked as supporting
it (X86 and SystemZ).

Differential Revision: https://reviews.llvm.org/D80952
2020-07-10 08:49:45 -04:00

2214 lines
85 KiB
C++
Raw Blame History

//===--- CompilerInstance.cpp ---------------------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "clang/Frontend/CompilerInstance.h"
#include "clang/AST/ASTConsumer.h"
#include "clang/AST/ASTContext.h"
#include "clang/AST/Decl.h"
#include "clang/Basic/CharInfo.h"
#include "clang/Basic/Diagnostic.h"
#include "clang/Basic/FileManager.h"
#include "clang/Basic/LangStandard.h"
#include "clang/Basic/SourceManager.h"
#include "clang/Basic/Stack.h"
#include "clang/Basic/TargetInfo.h"
#include "clang/Basic/Version.h"
#include "clang/Config/config.h"
#include "clang/Frontend/ChainedDiagnosticConsumer.h"
#include "clang/Frontend/FrontendAction.h"
#include "clang/Frontend/FrontendActions.h"
#include "clang/Frontend/FrontendDiagnostic.h"
#include "clang/Frontend/LogDiagnosticPrinter.h"
#include "clang/Frontend/SerializedDiagnosticPrinter.h"
#include "clang/Frontend/TextDiagnosticPrinter.h"
#include "clang/Frontend/Utils.h"
#include "clang/Frontend/VerifyDiagnosticConsumer.h"
#include "clang/Lex/HeaderSearch.h"
#include "clang/Lex/Preprocessor.h"
#include "clang/Lex/PreprocessorOptions.h"
#include "clang/Sema/CodeCompleteConsumer.h"
#include "clang/Sema/Sema.h"
#include "clang/Serialization/ASTReader.h"
#include "clang/Serialization/GlobalModuleIndex.h"
#include "clang/Serialization/InMemoryModuleCache.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/Support/BuryPointer.h"
#include "llvm/Support/CrashRecoveryContext.h"
#include "llvm/Support/Errc.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Host.h"
#include "llvm/Support/LockFileManager.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/Program.h"
#include "llvm/Support/Signals.h"
#include "llvm/Support/TimeProfiler.h"
#include "llvm/Support/Timer.h"
#include "llvm/Support/raw_ostream.h"
#include <time.h>
#include <utility>
using namespace clang;
CompilerInstance::CompilerInstance(
std::shared_ptr<PCHContainerOperations> PCHContainerOps,
InMemoryModuleCache *SharedModuleCache)
: ModuleLoader(/* BuildingModule = */ SharedModuleCache),
Invocation(new CompilerInvocation()),
ModuleCache(SharedModuleCache ? SharedModuleCache
: new InMemoryModuleCache),
ThePCHContainerOperations(std::move(PCHContainerOps)) {}
CompilerInstance::~CompilerInstance() {
assert(OutputFiles.empty() && "Still output files in flight?");
}
void CompilerInstance::setInvocation(
std::shared_ptr<CompilerInvocation> Value) {
Invocation = std::move(Value);
}
bool CompilerInstance::shouldBuildGlobalModuleIndex() const {
return (BuildGlobalModuleIndex ||
(TheASTReader && TheASTReader->isGlobalIndexUnavailable() &&
getFrontendOpts().GenerateGlobalModuleIndex)) &&
!ModuleBuildFailed;
}
void CompilerInstance::setDiagnostics(DiagnosticsEngine *Value) {
Diagnostics = Value;
}
void CompilerInstance::setVerboseOutputStream(raw_ostream &Value) {
OwnedVerboseOutputStream.release();
VerboseOutputStream = &Value;
}
void CompilerInstance::setVerboseOutputStream(std::unique_ptr<raw_ostream> Value) {
OwnedVerboseOutputStream.swap(Value);
VerboseOutputStream = OwnedVerboseOutputStream.get();
}
void CompilerInstance::setTarget(TargetInfo *Value) { Target = Value; }
void CompilerInstance::setAuxTarget(TargetInfo *Value) { AuxTarget = Value; }
llvm::vfs::FileSystem &CompilerInstance::getVirtualFileSystem() const {
return getFileManager().getVirtualFileSystem();
}
void CompilerInstance::setFileManager(FileManager *Value) {
FileMgr = Value;
}
void CompilerInstance::setSourceManager(SourceManager *Value) {
SourceMgr = Value;
}
void CompilerInstance::setPreprocessor(std::shared_ptr<Preprocessor> Value) {
PP = std::move(Value);
}
void CompilerInstance::setASTContext(ASTContext *Value) {
Context = Value;
if (Context && Consumer)
getASTConsumer().Initialize(getASTContext());
}
void CompilerInstance::setSema(Sema *S) {
TheSema.reset(S);
}
void CompilerInstance::setASTConsumer(std::unique_ptr<ASTConsumer> Value) {
Consumer = std::move(Value);
if (Context && Consumer)
getASTConsumer().Initialize(getASTContext());
}
void CompilerInstance::setCodeCompletionConsumer(CodeCompleteConsumer *Value) {
CompletionConsumer.reset(Value);
}
std::unique_ptr<Sema> CompilerInstance::takeSema() {
return std::move(TheSema);
}
IntrusiveRefCntPtr<ASTReader> CompilerInstance::getASTReader() const {
return TheASTReader;
}
void CompilerInstance::setASTReader(IntrusiveRefCntPtr<ASTReader> Reader) {
assert(ModuleCache.get() == &Reader->getModuleManager().getModuleCache() &&
"Expected ASTReader to use the same PCM cache");
TheASTReader = std::move(Reader);
}
std::shared_ptr<ModuleDependencyCollector>
CompilerInstance::getModuleDepCollector() const {
return ModuleDepCollector;
}
void CompilerInstance::setModuleDepCollector(
std::shared_ptr<ModuleDependencyCollector> Collector) {
ModuleDepCollector = std::move(Collector);
}
static void collectHeaderMaps(const HeaderSearch &HS,
std::shared_ptr<ModuleDependencyCollector> MDC) {
SmallVector<std::string, 4> HeaderMapFileNames;
HS.getHeaderMapFileNames(HeaderMapFileNames);
for (auto &Name : HeaderMapFileNames)
MDC->addFile(Name);
}
static void collectIncludePCH(CompilerInstance &CI,
std::shared_ptr<ModuleDependencyCollector> MDC) {
const PreprocessorOptions &PPOpts = CI.getPreprocessorOpts();
if (PPOpts.ImplicitPCHInclude.empty())
return;
StringRef PCHInclude = PPOpts.ImplicitPCHInclude;
FileManager &FileMgr = CI.getFileManager();
auto PCHDir = FileMgr.getDirectory(PCHInclude);
if (!PCHDir) {
MDC->addFile(PCHInclude);
return;
}
std::error_code EC;
SmallString<128> DirNative;
llvm::sys::path::native((*PCHDir)->getName(), DirNative);
llvm::vfs::FileSystem &FS = FileMgr.getVirtualFileSystem();
SimpleASTReaderListener Validator(CI.getPreprocessor());
for (llvm::vfs::directory_iterator Dir = FS.dir_begin(DirNative, EC), DirEnd;
Dir != DirEnd && !EC; Dir.increment(EC)) {
// Check whether this is an AST file. ASTReader::isAcceptableASTFile is not
// used here since we're not interested in validating the PCH at this time,
// but only to check whether this is a file containing an AST.
if (!ASTReader::readASTFileControlBlock(
Dir->path(), FileMgr, CI.getPCHContainerReader(),
/*FindModuleFileExtensions=*/false, Validator,
/*ValidateDiagnosticOptions=*/false))
MDC->addFile(Dir->path());
}
}
static void collectVFSEntries(CompilerInstance &CI,
std::shared_ptr<ModuleDependencyCollector> MDC) {
if (CI.getHeaderSearchOpts().VFSOverlayFiles.empty())
return;
// Collect all VFS found.
SmallVector<llvm::vfs::YAMLVFSEntry, 16> VFSEntries;
for (const std::string &VFSFile : CI.getHeaderSearchOpts().VFSOverlayFiles) {
llvm::ErrorOr<std::unique_ptr<llvm::MemoryBuffer>> Buffer =
llvm::MemoryBuffer::getFile(VFSFile);
if (!Buffer)
return;
llvm::vfs::collectVFSFromYAML(std::move(Buffer.get()),
/*DiagHandler*/ nullptr, VFSFile, VFSEntries);
}
for (auto &E : VFSEntries)
MDC->addFile(E.VPath, E.RPath);
}
// Diagnostics
static void SetUpDiagnosticLog(DiagnosticOptions *DiagOpts,
const CodeGenOptions *CodeGenOpts,
DiagnosticsEngine &Diags) {
std::error_code EC;
std::unique_ptr<raw_ostream> StreamOwner;
raw_ostream *OS = &llvm::errs();
if (DiagOpts->DiagnosticLogFile != "-") {
// Create the output stream.
auto FileOS = std::make_unique<llvm::raw_fd_ostream>(
DiagOpts->DiagnosticLogFile, EC,
llvm::sys::fs::OF_Append | llvm::sys::fs::OF_Text);
if (EC) {
Diags.Report(diag::warn_fe_cc_log_diagnostics_failure)
<< DiagOpts->DiagnosticLogFile << EC.message();
} else {
FileOS->SetUnbuffered();
OS = FileOS.get();
StreamOwner = std::move(FileOS);
}
}
// Chain in the diagnostic client which will log the diagnostics.
auto Logger = std::make_unique<LogDiagnosticPrinter>(*OS, DiagOpts,
std::move(StreamOwner));
if (CodeGenOpts)
Logger->setDwarfDebugFlags(CodeGenOpts->DwarfDebugFlags);
if (Diags.ownsClient()) {
Diags.setClient(
new ChainedDiagnosticConsumer(Diags.takeClient(), std::move(Logger)));
} else {
Diags.setClient(
new ChainedDiagnosticConsumer(Diags.getClient(), std::move(Logger)));
}
}
static void SetupSerializedDiagnostics(DiagnosticOptions *DiagOpts,
DiagnosticsEngine &Diags,
StringRef OutputFile) {
auto SerializedConsumer =
clang::serialized_diags::create(OutputFile, DiagOpts);
if (Diags.ownsClient()) {
Diags.setClient(new ChainedDiagnosticConsumer(
Diags.takeClient(), std::move(SerializedConsumer)));
} else {
Diags.setClient(new ChainedDiagnosticConsumer(
Diags.getClient(), std::move(SerializedConsumer)));
}
}
void CompilerInstance::createDiagnostics(DiagnosticConsumer *Client,
bool ShouldOwnClient) {
Diagnostics = createDiagnostics(&getDiagnosticOpts(), Client,
ShouldOwnClient, &getCodeGenOpts());
}
IntrusiveRefCntPtr<DiagnosticsEngine>
CompilerInstance::createDiagnostics(DiagnosticOptions *Opts,
DiagnosticConsumer *Client,
bool ShouldOwnClient,
const CodeGenOptions *CodeGenOpts) {
IntrusiveRefCntPtr<DiagnosticIDs> DiagID(new DiagnosticIDs());
IntrusiveRefCntPtr<DiagnosticsEngine>
Diags(new DiagnosticsEngine(DiagID, Opts));
// Create the diagnostic client for reporting errors or for
// implementing -verify.
if (Client) {
Diags->setClient(Client, ShouldOwnClient);
} else
Diags->setClient(new TextDiagnosticPrinter(llvm::errs(), Opts));
// Chain in -verify checker, if requested.
if (Opts->VerifyDiagnostics)
Diags->setClient(new VerifyDiagnosticConsumer(*Diags));
// Chain in -diagnostic-log-file dumper, if requested.
if (!Opts->DiagnosticLogFile.empty())
SetUpDiagnosticLog(Opts, CodeGenOpts, *Diags);
if (!Opts->DiagnosticSerializationFile.empty())
SetupSerializedDiagnostics(Opts, *Diags,
Opts->DiagnosticSerializationFile);
// Configure our handling of diagnostics.
ProcessWarningOptions(*Diags, *Opts);
return Diags;
}
// File Manager
FileManager *CompilerInstance::createFileManager(
IntrusiveRefCntPtr<llvm::vfs::FileSystem> VFS) {
if (!VFS)
VFS = FileMgr ? &FileMgr->getVirtualFileSystem()
: createVFSFromCompilerInvocation(getInvocation(),
getDiagnostics());
assert(VFS && "FileManager has no VFS?");
FileMgr = new FileManager(getFileSystemOpts(), std::move(VFS));
return FileMgr.get();
}
// Source Manager
void CompilerInstance::createSourceManager(FileManager &FileMgr) {
SourceMgr = new SourceManager(getDiagnostics(), FileMgr);
}
// Initialize the remapping of files to alternative contents, e.g.,
// those specified through other files.
static void InitializeFileRemapping(DiagnosticsEngine &Diags,
SourceManager &SourceMgr,
FileManager &FileMgr,
const PreprocessorOptions &InitOpts) {
// Remap files in the source manager (with buffers).
for (const auto &RB : InitOpts.RemappedFileBuffers) {
// Create the file entry for the file that we're mapping from.
const FileEntry *FromFile =
FileMgr.getVirtualFile(RB.first, RB.second->getBufferSize(), 0);
if (!FromFile) {
Diags.Report(diag::err_fe_remap_missing_from_file) << RB.first;
if (!InitOpts.RetainRemappedFileBuffers)
delete RB.second;
continue;
}
// Override the contents of the "from" file with the contents of
// the "to" file.
SourceMgr.overrideFileContents(FromFile, RB.second,
InitOpts.RetainRemappedFileBuffers);
}
// Remap files in the source manager (with other files).
for (const auto &RF : InitOpts.RemappedFiles) {
// Find the file that we're mapping to.
auto ToFile = FileMgr.getFile(RF.second);
if (!ToFile) {
Diags.Report(diag::err_fe_remap_missing_to_file) << RF.first << RF.second;
continue;
}
// Create the file entry for the file that we're mapping from.
const FileEntry *FromFile =
FileMgr.getVirtualFile(RF.first, (*ToFile)->getSize(), 0);
if (!FromFile) {
Diags.Report(diag::err_fe_remap_missing_from_file) << RF.first;
continue;
}
// Override the contents of the "from" file with the contents of
// the "to" file.
SourceMgr.overrideFileContents(FromFile, *ToFile);
}
SourceMgr.setOverridenFilesKeepOriginalName(
InitOpts.RemappedFilesKeepOriginalName);
}
// Preprocessor
void CompilerInstance::createPreprocessor(TranslationUnitKind TUKind) {
const PreprocessorOptions &PPOpts = getPreprocessorOpts();
// The AST reader holds a reference to the old preprocessor (if any).
TheASTReader.reset();
// Create the Preprocessor.
HeaderSearch *HeaderInfo =
new HeaderSearch(getHeaderSearchOptsPtr(), getSourceManager(),
getDiagnostics(), getLangOpts(), &getTarget());
PP = std::make_shared<Preprocessor>(Invocation->getPreprocessorOptsPtr(),
getDiagnostics(), getLangOpts(),
getSourceManager(), *HeaderInfo, *this,
/*IdentifierInfoLookup=*/nullptr,
/*OwnsHeaderSearch=*/true, TUKind);
getTarget().adjust(getLangOpts());
PP->Initialize(getTarget(), getAuxTarget());
if (PPOpts.DetailedRecord)
PP->createPreprocessingRecord();
// Apply remappings to the source manager.
InitializeFileRemapping(PP->getDiagnostics(), PP->getSourceManager(),
PP->getFileManager(), PPOpts);
// Predefine macros and configure the preprocessor.
InitializePreprocessor(*PP, PPOpts, getPCHContainerReader(),
getFrontendOpts());
// Initialize the header search object. In CUDA compilations, we use the aux
// triple (the host triple) to initialize our header search, since we need to
// find the host headers in order to compile the CUDA code.
const llvm::Triple *HeaderSearchTriple = &PP->getTargetInfo().getTriple();
if (PP->getTargetInfo().getTriple().getOS() == llvm::Triple::CUDA &&
PP->getAuxTargetInfo())
HeaderSearchTriple = &PP->getAuxTargetInfo()->getTriple();
ApplyHeaderSearchOptions(PP->getHeaderSearchInfo(), getHeaderSearchOpts(),
PP->getLangOpts(), *HeaderSearchTriple);
PP->setPreprocessedOutput(getPreprocessorOutputOpts().ShowCPP);
if (PP->getLangOpts().Modules && PP->getLangOpts().ImplicitModules)
PP->getHeaderSearchInfo().setModuleCachePath(getSpecificModuleCachePath());
// Handle generating dependencies, if requested.
const DependencyOutputOptions &DepOpts = getDependencyOutputOpts();
if (!DepOpts.OutputFile.empty())
addDependencyCollector(std::make_shared<DependencyFileGenerator>(DepOpts));
if (!DepOpts.DOTOutputFile.empty())
AttachDependencyGraphGen(*PP, DepOpts.DOTOutputFile,
getHeaderSearchOpts().Sysroot);
// If we don't have a collector, but we are collecting module dependencies,
// then we're the top level compiler instance and need to create one.
if (!ModuleDepCollector && !DepOpts.ModuleDependencyOutputDir.empty()) {
ModuleDepCollector = std::make_shared<ModuleDependencyCollector>(
DepOpts.ModuleDependencyOutputDir);
}
// If there is a module dep collector, register with other dep collectors
// and also (a) collect header maps and (b) TODO: input vfs overlay files.
if (ModuleDepCollector) {
addDependencyCollector(ModuleDepCollector);
collectHeaderMaps(PP->getHeaderSearchInfo(), ModuleDepCollector);
collectIncludePCH(*this, ModuleDepCollector);
collectVFSEntries(*this, ModuleDepCollector);
}
for (auto &Listener : DependencyCollectors)
Listener->attachToPreprocessor(*PP);
// Handle generating header include information, if requested.
if (DepOpts.ShowHeaderIncludes)
AttachHeaderIncludeGen(*PP, DepOpts);
if (!DepOpts.HeaderIncludeOutputFile.empty()) {
StringRef OutputPath = DepOpts.HeaderIncludeOutputFile;
if (OutputPath == "-")
OutputPath = "";
AttachHeaderIncludeGen(*PP, DepOpts,
/*ShowAllHeaders=*/true, OutputPath,
/*ShowDepth=*/false);
}
if (DepOpts.ShowIncludesDest != ShowIncludesDestination::None) {
AttachHeaderIncludeGen(*PP, DepOpts,
/*ShowAllHeaders=*/true, /*OutputPath=*/"",
/*ShowDepth=*/true, /*MSStyle=*/true);
}
}
std::string CompilerInstance::getSpecificModuleCachePath() {
// Set up the module path, including the hash for the
// module-creation options.
SmallString<256> SpecificModuleCache(getHeaderSearchOpts().ModuleCachePath);
if (!SpecificModuleCache.empty() && !getHeaderSearchOpts().DisableModuleHash)
llvm::sys::path::append(SpecificModuleCache,
getInvocation().getModuleHash());
return std::string(SpecificModuleCache.str());
}
// ASTContext
void CompilerInstance::createASTContext() {
Preprocessor &PP = getPreprocessor();
auto *Context = new ASTContext(getLangOpts(), PP.getSourceManager(),
PP.getIdentifierTable(), PP.getSelectorTable(),
PP.getBuiltinInfo());
Context->InitBuiltinTypes(getTarget(), getAuxTarget());
setASTContext(Context);
}
// ExternalASTSource
void CompilerInstance::createPCHExternalASTSource(
StringRef Path, bool DisablePCHValidation, bool AllowPCHWithCompilerErrors,
void *DeserializationListener, bool OwnDeserializationListener) {
bool Preamble = getPreprocessorOpts().PrecompiledPreambleBytes.first != 0;
TheASTReader = createPCHExternalASTSource(
Path, getHeaderSearchOpts().Sysroot, DisablePCHValidation,
AllowPCHWithCompilerErrors, getPreprocessor(), getModuleCache(),
getASTContext(), getPCHContainerReader(),
getFrontendOpts().ModuleFileExtensions, DependencyCollectors,
DeserializationListener, OwnDeserializationListener, Preamble,
getFrontendOpts().UseGlobalModuleIndex);
}
IntrusiveRefCntPtr<ASTReader> CompilerInstance::createPCHExternalASTSource(
StringRef Path, StringRef Sysroot, bool DisablePCHValidation,
bool AllowPCHWithCompilerErrors, Preprocessor &PP,
InMemoryModuleCache &ModuleCache, ASTContext &Context,
const PCHContainerReader &PCHContainerRdr,
ArrayRef<std::shared_ptr<ModuleFileExtension>> Extensions,
ArrayRef<std::shared_ptr<DependencyCollector>> DependencyCollectors,
void *DeserializationListener, bool OwnDeserializationListener,
bool Preamble, bool UseGlobalModuleIndex) {
HeaderSearchOptions &HSOpts = PP.getHeaderSearchInfo().getHeaderSearchOpts();
IntrusiveRefCntPtr<ASTReader> Reader(new ASTReader(
PP, ModuleCache, &Context, PCHContainerRdr, Extensions,
Sysroot.empty() ? "" : Sysroot.data(), DisablePCHValidation,
AllowPCHWithCompilerErrors, /*AllowConfigurationMismatch*/ false,
HSOpts.ModulesValidateSystemHeaders, HSOpts.ValidateASTInputFilesContent,
UseGlobalModuleIndex));
// We need the external source to be set up before we read the AST, because
// eagerly-deserialized declarations may use it.
Context.setExternalSource(Reader.get());
Reader->setDeserializationListener(
static_cast<ASTDeserializationListener *>(DeserializationListener),
/*TakeOwnership=*/OwnDeserializationListener);
for (auto &Listener : DependencyCollectors)
Listener->attachToASTReader(*Reader);
switch (Reader->ReadAST(Path,
Preamble ? serialization::MK_Preamble
: serialization::MK_PCH,
SourceLocation(),
ASTReader::ARR_None)) {
case ASTReader::Success:
// Set the predefines buffer as suggested by the PCH reader. Typically, the
// predefines buffer will be empty.
PP.setPredefines(Reader->getSuggestedPredefines());
return Reader;
case ASTReader::Failure:
// Unrecoverable failure: don't even try to process the input file.
break;
case ASTReader::Missing:
case ASTReader::OutOfDate:
case ASTReader::VersionMismatch:
case ASTReader::ConfigurationMismatch:
case ASTReader::HadErrors:
// No suitable PCH file could be found. Return an error.
break;
}
Context.setExternalSource(nullptr);
return nullptr;
}
// Code Completion
static bool EnableCodeCompletion(Preprocessor &PP,
StringRef Filename,
unsigned Line,
unsigned Column) {
// Tell the source manager to chop off the given file at a specific
// line and column.
auto Entry = PP.getFileManager().getFile(Filename);
if (!Entry) {
PP.getDiagnostics().Report(diag::err_fe_invalid_code_complete_file)
<< Filename;
return true;
}
// Truncate the named file at the given line/column.
PP.SetCodeCompletionPoint(*Entry, Line, Column);
return false;
}
void CompilerInstance::createCodeCompletionConsumer() {
const ParsedSourceLocation &Loc = getFrontendOpts().CodeCompletionAt;
if (!CompletionConsumer) {
setCodeCompletionConsumer(
createCodeCompletionConsumer(getPreprocessor(),
Loc.FileName, Loc.Line, Loc.Column,
getFrontendOpts().CodeCompleteOpts,
llvm::outs()));
if (!CompletionConsumer)
return;
} else if (EnableCodeCompletion(getPreprocessor(), Loc.FileName,
Loc.Line, Loc.Column)) {
setCodeCompletionConsumer(nullptr);
return;
}
}
void CompilerInstance::createFrontendTimer() {
FrontendTimerGroup.reset(
new llvm::TimerGroup("frontend", "Clang front-end time report"));
FrontendTimer.reset(
new llvm::Timer("frontend", "Clang front-end timer",
*FrontendTimerGroup));
}
CodeCompleteConsumer *
CompilerInstance::createCodeCompletionConsumer(Preprocessor &PP,
StringRef Filename,
unsigned Line,
unsigned Column,
const CodeCompleteOptions &Opts,
raw_ostream &OS) {
if (EnableCodeCompletion(PP, Filename, Line, Column))
return nullptr;
// Set up the creation routine for code-completion.
return new PrintingCodeCompleteConsumer(Opts, OS);
}
void CompilerInstance::createSema(TranslationUnitKind TUKind,
CodeCompleteConsumer *CompletionConsumer) {
TheSema.reset(new Sema(getPreprocessor(), getASTContext(), getASTConsumer(),
TUKind, CompletionConsumer));
// Attach the external sema source if there is any.
if (ExternalSemaSrc) {
TheSema->addExternalSource(ExternalSemaSrc.get());
ExternalSemaSrc->InitializeSema(*TheSema);
}
}
// Output Files
void CompilerInstance::addOutputFile(OutputFile &&OutFile) {
OutputFiles.push_back(std::move(OutFile));
}
void CompilerInstance::clearOutputFiles(bool EraseFiles) {
for (OutputFile &OF : OutputFiles) {
if (!OF.TempFilename.empty()) {
if (EraseFiles) {
llvm::sys::fs::remove(OF.TempFilename);
} else {
SmallString<128> NewOutFile(OF.Filename);
// If '-working-directory' was passed, the output filename should be
// relative to that.
FileMgr->FixupRelativePath(NewOutFile);
if (std::error_code ec =
llvm::sys::fs::rename(OF.TempFilename, NewOutFile)) {
getDiagnostics().Report(diag::err_unable_to_rename_temp)
<< OF.TempFilename << OF.Filename << ec.message();
llvm::sys::fs::remove(OF.TempFilename);
}
}
} else if (!OF.Filename.empty() && EraseFiles)
llvm::sys::fs::remove(OF.Filename);
}
OutputFiles.clear();
if (DeleteBuiltModules) {
for (auto &Module : BuiltModules)
llvm::sys::fs::remove(Module.second);
BuiltModules.clear();
}
NonSeekStream.reset();
}
std::unique_ptr<raw_pwrite_stream>
CompilerInstance::createDefaultOutputFile(bool Binary, StringRef InFile,
StringRef Extension) {
return createOutputFile(getFrontendOpts().OutputFile, Binary,
/*RemoveFileOnSignal=*/true, InFile, Extension,
getFrontendOpts().UseTemporary);
}
std::unique_ptr<raw_pwrite_stream> CompilerInstance::createNullOutputFile() {
return std::make_unique<llvm::raw_null_ostream>();
}
std::unique_ptr<raw_pwrite_stream>
CompilerInstance::createOutputFile(StringRef OutputPath, bool Binary,
bool RemoveFileOnSignal, StringRef InFile,
StringRef Extension, bool UseTemporary,
bool CreateMissingDirectories) {
std::string OutputPathName, TempPathName;
std::error_code EC;
std::unique_ptr<raw_pwrite_stream> OS = createOutputFile(
OutputPath, EC, Binary, RemoveFileOnSignal, InFile, Extension,
UseTemporary, CreateMissingDirectories, &OutputPathName, &TempPathName);
if (!OS) {
getDiagnostics().Report(diag::err_fe_unable_to_open_output) << OutputPath
<< EC.message();
return nullptr;
}
// Add the output file -- but don't try to remove "-", since this means we are
// using stdin.
addOutputFile(
OutputFile((OutputPathName != "-") ? OutputPathName : "", TempPathName));
return OS;
}
std::unique_ptr<llvm::raw_pwrite_stream> CompilerInstance::createOutputFile(
StringRef OutputPath, std::error_code &Error, bool Binary,
bool RemoveFileOnSignal, StringRef InFile, StringRef Extension,
bool UseTemporary, bool CreateMissingDirectories,
std::string *ResultPathName, std::string *TempPathName) {
assert((!CreateMissingDirectories || UseTemporary) &&
"CreateMissingDirectories is only allowed when using temporary files");
std::string OutFile, TempFile;
if (!OutputPath.empty()) {
OutFile = std::string(OutputPath);
} else if (InFile == "-") {
OutFile = "-";
} else if (!Extension.empty()) {
SmallString<128> Path(InFile);
llvm::sys::path::replace_extension(Path, Extension);
OutFile = std::string(Path.str());
} else {
OutFile = "-";
}
std::unique_ptr<llvm::raw_fd_ostream> OS;
std::string OSFile;
if (UseTemporary) {
if (OutFile == "-")
UseTemporary = false;
else {
llvm::sys::fs::file_status Status;
llvm::sys::fs::status(OutputPath, Status);
if (llvm::sys::fs::exists(Status)) {
// Fail early if we can't write to the final destination.
if (!llvm::sys::fs::can_write(OutputPath)) {
Error = make_error_code(llvm::errc::operation_not_permitted);
return nullptr;
}
// Don't use a temporary if the output is a special file. This handles
// things like '-o /dev/null'
if (!llvm::sys::fs::is_regular_file(Status))
UseTemporary = false;
}
}
}
if (UseTemporary) {
// Create a temporary file.
// Insert -%%%%%%%% before the extension (if any), and because some tools
// (noticeable, clang's own GlobalModuleIndex.cpp) glob for build
// artifacts, also append .tmp.
StringRef OutputExtension = llvm::sys::path::extension(OutFile);
SmallString<128> TempPath =
StringRef(OutFile).drop_back(OutputExtension.size());
TempPath += "-%%%%%%%%";
TempPath += OutputExtension;
TempPath += ".tmp";
int fd;
std::error_code EC =
llvm::sys::fs::createUniqueFile(TempPath, fd, TempPath);
if (CreateMissingDirectories &&
EC == llvm::errc::no_such_file_or_directory) {
StringRef Parent = llvm::sys::path::parent_path(OutputPath);
EC = llvm::sys::fs::create_directories(Parent);
if (!EC) {
EC = llvm::sys::fs::createUniqueFile(TempPath, fd, TempPath);
}
}
if (!EC) {
OS.reset(new llvm::raw_fd_ostream(fd, /*shouldClose=*/true));
OSFile = TempFile = std::string(TempPath.str());
}
// If we failed to create the temporary, fallback to writing to the file
// directly. This handles the corner case where we cannot write to the
// directory, but can write to the file.
}
if (!OS) {
OSFile = OutFile;
OS.reset(new llvm::raw_fd_ostream(
OSFile, Error,
(Binary ? llvm::sys::fs::OF_None : llvm::sys::fs::OF_Text)));
if (Error)
return nullptr;
}
// Make sure the out stream file gets removed if we crash.
if (RemoveFileOnSignal)
llvm::sys::RemoveFileOnSignal(OSFile);
if (ResultPathName)
*ResultPathName = OutFile;
if (TempPathName)
*TempPathName = TempFile;
if (!Binary || OS->supportsSeeking())
return std::move(OS);
auto B = std::make_unique<llvm::buffer_ostream>(*OS);
assert(!NonSeekStream);
NonSeekStream = std::move(OS);
return std::move(B);
}
// Initialization Utilities
bool CompilerInstance::InitializeSourceManager(const FrontendInputFile &Input){
return InitializeSourceManager(Input, getDiagnostics(), getFileManager(),
getSourceManager());
}
// static
bool CompilerInstance::InitializeSourceManager(const FrontendInputFile &Input,
DiagnosticsEngine &Diags,
FileManager &FileMgr,
SourceManager &SourceMgr) {
SrcMgr::CharacteristicKind Kind =
Input.getKind().getFormat() == InputKind::ModuleMap
? Input.isSystem() ? SrcMgr::C_System_ModuleMap
: SrcMgr::C_User_ModuleMap
: Input.isSystem() ? SrcMgr::C_System : SrcMgr::C_User;
if (Input.isBuffer()) {
SourceMgr.setMainFileID(SourceMgr.createFileID(SourceManager::Unowned,
Input.getBuffer(), Kind));
assert(SourceMgr.getMainFileID().isValid() &&
"Couldn't establish MainFileID!");
return true;
}
StringRef InputFile = Input.getFile();
// Figure out where to get and map in the main file.
if (InputFile != "-") {
auto FileOrErr = FileMgr.getFileRef(InputFile, /*OpenFile=*/true);
if (!FileOrErr) {
// FIXME: include the error in the diagnostic.
consumeError(FileOrErr.takeError());
Diags.Report(diag::err_fe_error_reading) << InputFile;
return false;
}
FileEntryRef File = *FileOrErr;
// The natural SourceManager infrastructure can't currently handle named
// pipes, but we would at least like to accept them for the main
// file. Detect them here, read them with the volatile flag so FileMgr will
// pick up the correct size, and simply override their contents as we do for
// STDIN.
if (File.getFileEntry().isNamedPipe()) {
auto MB =
FileMgr.getBufferForFile(&File.getFileEntry(), /*isVolatile=*/true);
if (MB) {
// Create a new virtual file that will have the correct size.
const FileEntry *FE =
FileMgr.getVirtualFile(InputFile, (*MB)->getBufferSize(), 0);
SourceMgr.overrideFileContents(FE, std::move(*MB));
SourceMgr.setMainFileID(
SourceMgr.createFileID(FE, SourceLocation(), Kind));
} else {
Diags.Report(diag::err_cannot_open_file) << InputFile
<< MB.getError().message();
return false;
}
} else {
SourceMgr.setMainFileID(
SourceMgr.createFileID(File, SourceLocation(), Kind));
}
} else {
llvm::ErrorOr<std::unique_ptr<llvm::MemoryBuffer>> SBOrErr =
llvm::MemoryBuffer::getSTDIN();
if (std::error_code EC = SBOrErr.getError()) {
Diags.Report(diag::err_fe_error_reading_stdin) << EC.message();
return false;
}
std::unique_ptr<llvm::MemoryBuffer> SB = std::move(SBOrErr.get());
const FileEntry *File = FileMgr.getVirtualFile(SB->getBufferIdentifier(),
SB->getBufferSize(), 0);
SourceMgr.setMainFileID(
SourceMgr.createFileID(File, SourceLocation(), Kind));
SourceMgr.overrideFileContents(File, std::move(SB));
}
assert(SourceMgr.getMainFileID().isValid() &&
"Couldn't establish MainFileID!");
return true;
}
// High-Level Operations
bool CompilerInstance::ExecuteAction(FrontendAction &Act) {
assert(hasDiagnostics() && "Diagnostics engine is not initialized!");
assert(!getFrontendOpts().ShowHelp && "Client must handle '-help'!");
assert(!getFrontendOpts().ShowVersion && "Client must handle '-version'!");
// Mark this point as the bottom of the stack if we don't have somewhere
// better. We generally expect frontend actions to be invoked with (nearly)
// DesiredStackSpace available.
noteBottomOfStack();
raw_ostream &OS = getVerboseOutputStream();
if (!Act.PrepareToExecute(*this))
return false;
// Create the target instance.
setTarget(TargetInfo::CreateTargetInfo(getDiagnostics(),
getInvocation().TargetOpts));
if (!hasTarget())
return false;
// Create TargetInfo for the other side of CUDA/OpenMP/SYCL compilation.
if ((getLangOpts().CUDA || getLangOpts().OpenMPIsDevice ||
getLangOpts().SYCLIsDevice) &&
!getFrontendOpts().AuxTriple.empty()) {
auto TO = std::make_shared<TargetOptions>();
TO->Triple = llvm::Triple::normalize(getFrontendOpts().AuxTriple);
if (getFrontendOpts().AuxTargetCPU)
TO->CPU = getFrontendOpts().AuxTargetCPU.getValue();
if (getFrontendOpts().AuxTargetFeatures)
TO->FeaturesAsWritten = getFrontendOpts().AuxTargetFeatures.getValue();
TO->HostTriple = getTarget().getTriple().str();
setAuxTarget(TargetInfo::CreateTargetInfo(getDiagnostics(), TO));
}
if (!getTarget().hasStrictFP() && !getLangOpts().ExpStrictFP) {
if (getLangOpts().getFPRoundingMode() !=
llvm::RoundingMode::NearestTiesToEven) {
getDiagnostics().Report(diag::warn_fe_backend_unsupported_fp_rounding);
getLangOpts().setFPRoundingMode(llvm::RoundingMode::NearestTiesToEven);
}
if (getLangOpts().getFPExceptionMode() != LangOptions::FPE_Ignore) {
getDiagnostics().Report(diag::warn_fe_backend_unsupported_fp_exceptions);
getLangOpts().setFPExceptionMode(LangOptions::FPE_Ignore);
}
// FIXME: can we disable FEnvAccess?
}
// Inform the target of the language options.
//
// FIXME: We shouldn't need to do this, the target should be immutable once
// created. This complexity should be lifted elsewhere.
getTarget().adjust(getLangOpts());
// Adjust target options based on codegen options.
getTarget().adjustTargetOptions(getCodeGenOpts(), getTargetOpts());
if (auto *Aux = getAuxTarget())
getTarget().setAuxTarget(Aux);
// rewriter project will change target built-in bool type from its default.
if (getFrontendOpts().ProgramAction == frontend::RewriteObjC)
getTarget().noSignedCharForObjCBool();
// Validate/process some options.
if (getHeaderSearchOpts().Verbose)
OS << "clang -cc1 version " CLANG_VERSION_STRING
<< " based upon " << BACKEND_PACKAGE_STRING
<< " default target " << llvm::sys::getDefaultTargetTriple() << "\n";
if (getFrontendOpts().ShowTimers)
createFrontendTimer();
if (getFrontendOpts().ShowStats || !getFrontendOpts().StatsFile.empty())
llvm::EnableStatistics(false);
for (const FrontendInputFile &FIF : getFrontendOpts().Inputs) {
// Reset the ID tables if we are reusing the SourceManager and parsing
// regular files.
if (hasSourceManager() && !Act.isModelParsingAction())
getSourceManager().clearIDTables();
if (Act.BeginSourceFile(*this, FIF)) {
if (llvm::Error Err = Act.Execute()) {
consumeError(std::move(Err)); // FIXME this drops errors on the floor.
}
Act.EndSourceFile();
}
}
// Notify the diagnostic client that all files were processed.
getDiagnostics().getClient()->finish();
if (getDiagnosticOpts().ShowCarets) {
// We can have multiple diagnostics sharing one diagnostic client.
// Get the total number of warnings/errors from the client.
unsigned NumWarnings = getDiagnostics().getClient()->getNumWarnings();
unsigned NumErrors = getDiagnostics().getClient()->getNumErrors();
if (NumWarnings)
OS << NumWarnings << " warning" << (NumWarnings == 1 ? "" : "s");
if (NumWarnings && NumErrors)
OS << " and ";
if (NumErrors)
OS << NumErrors << " error" << (NumErrors == 1 ? "" : "s");
if (NumWarnings || NumErrors) {
OS << " generated";
if (getLangOpts().CUDA) {
if (!getLangOpts().CUDAIsDevice) {
OS << " when compiling for host";
} else {
OS << " when compiling for " << getTargetOpts().CPU;
}
}
OS << ".\n";
}
}
if (getFrontendOpts().ShowStats) {
if (hasFileManager()) {
getFileManager().PrintStats();
OS << '\n';
}
llvm::PrintStatistics(OS);
}
StringRef StatsFile = getFrontendOpts().StatsFile;
if (!StatsFile.empty()) {
std::error_code EC;
auto StatS = std::make_unique<llvm::raw_fd_ostream>(
StatsFile, EC, llvm::sys::fs::OF_Text);
if (EC) {
getDiagnostics().Report(diag::warn_fe_unable_to_open_stats_file)
<< StatsFile << EC.message();
} else {
llvm::PrintStatisticsJSON(*StatS);
}
}
return !getDiagnostics().getClient()->getNumErrors();
}
/// Determine the appropriate source input kind based on language
/// options.
static Language getLanguageFromOptions(const LangOptions &LangOpts) {
if (LangOpts.OpenCL)
return Language::OpenCL;
if (LangOpts.CUDA)
return Language::CUDA;
if (LangOpts.ObjC)
return LangOpts.CPlusPlus ? Language::ObjCXX : Language::ObjC;
return LangOpts.CPlusPlus ? Language::CXX : Language::C;
}
/// Compile a module file for the given module, using the options
/// provided by the importing compiler instance. Returns true if the module
/// was built without errors.
static bool
compileModuleImpl(CompilerInstance &ImportingInstance, SourceLocation ImportLoc,
StringRef ModuleName, FrontendInputFile Input,
StringRef OriginalModuleMapFile, StringRef ModuleFileName,
llvm::function_ref<void(CompilerInstance &)> PreBuildStep =
[](CompilerInstance &) {},
llvm::function_ref<void(CompilerInstance &)> PostBuildStep =
[](CompilerInstance &) {}) {
llvm::TimeTraceScope TimeScope("Module Compile", ModuleName);
// Construct a compiler invocation for creating this module.
auto Invocation =
std::make_shared<CompilerInvocation>(ImportingInstance.getInvocation());
PreprocessorOptions &PPOpts = Invocation->getPreprocessorOpts();
// For any options that aren't intended to affect how a module is built,
// reset them to their default values.
Invocation->getLangOpts()->resetNonModularOptions();
PPOpts.resetNonModularOptions();
// Remove any macro definitions that are explicitly ignored by the module.
// They aren't supposed to affect how the module is built anyway.
HeaderSearchOptions &HSOpts = Invocation->getHeaderSearchOpts();
PPOpts.Macros.erase(
std::remove_if(PPOpts.Macros.begin(), PPOpts.Macros.end(),
[&HSOpts](const std::pair<std::string, bool> &def) {
StringRef MacroDef = def.first;
return HSOpts.ModulesIgnoreMacros.count(
llvm::CachedHashString(MacroDef.split('=').first)) > 0;
}),
PPOpts.Macros.end());
// If the original compiler invocation had -fmodule-name, pass it through.
Invocation->getLangOpts()->ModuleName =
ImportingInstance.getInvocation().getLangOpts()->ModuleName;
// Note the name of the module we're building.
Invocation->getLangOpts()->CurrentModule = std::string(ModuleName);
// Make sure that the failed-module structure has been allocated in
// the importing instance, and propagate the pointer to the newly-created
// instance.
PreprocessorOptions &ImportingPPOpts
= ImportingInstance.getInvocation().getPreprocessorOpts();
if (!ImportingPPOpts.FailedModules)
ImportingPPOpts.FailedModules =
std::make_shared<PreprocessorOptions::FailedModulesSet>();
PPOpts.FailedModules = ImportingPPOpts.FailedModules;
// If there is a module map file, build the module using the module map.
// Set up the inputs/outputs so that we build the module from its umbrella
// header.
FrontendOptions &FrontendOpts = Invocation->getFrontendOpts();
FrontendOpts.OutputFile = ModuleFileName.str();
FrontendOpts.DisableFree = false;
FrontendOpts.GenerateGlobalModuleIndex = false;
FrontendOpts.BuildingImplicitModule = true;
FrontendOpts.OriginalModuleMap = std::string(OriginalModuleMapFile);
// Force implicitly-built modules to hash the content of the module file.
HSOpts.ModulesHashContent = true;
FrontendOpts.Inputs = {Input};
// Don't free the remapped file buffers; they are owned by our caller.
PPOpts.RetainRemappedFileBuffers = true;
Invocation->getDiagnosticOpts().VerifyDiagnostics = 0;
assert(ImportingInstance.getInvocation().getModuleHash() ==
Invocation->getModuleHash() && "Module hash mismatch!");
// Construct a compiler instance that will be used to actually create the
// module. Since we're sharing an in-memory module cache,
// CompilerInstance::CompilerInstance is responsible for finalizing the
// buffers to prevent use-after-frees.
CompilerInstance Instance(ImportingInstance.getPCHContainerOperations(),
&ImportingInstance.getModuleCache());
auto &Inv = *Invocation;
Instance.setInvocation(std::move(Invocation));
Instance.createDiagnostics(new ForwardingDiagnosticConsumer(
ImportingInstance.getDiagnosticClient()),
/*ShouldOwnClient=*/true);
// Note that this module is part of the module build stack, so that we
// can detect cycles in the module graph.
Instance.setFileManager(&ImportingInstance.getFileManager());
Instance.createSourceManager(Instance.getFileManager());
SourceManager &SourceMgr = Instance.getSourceManager();
SourceMgr.setModuleBuildStack(
ImportingInstance.getSourceManager().getModuleBuildStack());
SourceMgr.pushModuleBuildStack(ModuleName,
FullSourceLoc(ImportLoc, ImportingInstance.getSourceManager()));
// If we're collecting module dependencies, we need to share a collector
// between all of the module CompilerInstances. Other than that, we don't
// want to produce any dependency output from the module build.
Instance.setModuleDepCollector(ImportingInstance.getModuleDepCollector());
Inv.getDependencyOutputOpts() = DependencyOutputOptions();
ImportingInstance.getDiagnostics().Report(ImportLoc,
diag::remark_module_build)
<< ModuleName << ModuleFileName;
PreBuildStep(Instance);
// Execute the action to actually build the module in-place. Use a separate
// thread so that we get a stack large enough.
llvm::CrashRecoveryContext CRC;
CRC.RunSafelyOnThread(
[&]() {
GenerateModuleFromModuleMapAction Action;
Instance.ExecuteAction(Action);
},
DesiredStackSize);
PostBuildStep(Instance);
ImportingInstance.getDiagnostics().Report(ImportLoc,
diag::remark_module_build_done)
<< ModuleName;
// Delete the temporary module map file.
// FIXME: Even though we're executing under crash protection, it would still
// be nice to do this with RemoveFileOnSignal when we can. However, that
// doesn't make sense for all clients, so clean this up manually.
Instance.clearOutputFiles(/*EraseFiles=*/true);
return !Instance.getDiagnostics().hasErrorOccurred();
}
static const FileEntry *getPublicModuleMap(const FileEntry *File,
FileManager &FileMgr) {
StringRef Filename = llvm::sys::path::filename(File->getName());
SmallString<128> PublicFilename(File->getDir()->getName());
if (Filename == "module_private.map")
llvm::sys::path::append(PublicFilename, "module.map");
else if (Filename == "module.private.modulemap")
llvm::sys::path::append(PublicFilename, "module.modulemap");
else
return nullptr;
if (auto FE = FileMgr.getFile(PublicFilename))
return *FE;
return nullptr;
}
/// Compile a module file for the given module in a separate compiler instance,
/// using the options provided by the importing compiler instance. Returns true
/// if the module was built without errors.
static bool compileModule(CompilerInstance &ImportingInstance,
SourceLocation ImportLoc, Module *Module,
StringRef ModuleFileName) {
InputKind IK(getLanguageFromOptions(ImportingInstance.getLangOpts()),
InputKind::ModuleMap);
// Get or create the module map that we'll use to build this module.
ModuleMap &ModMap
= ImportingInstance.getPreprocessor().getHeaderSearchInfo().getModuleMap();
bool Result;
if (const FileEntry *ModuleMapFile =
ModMap.getContainingModuleMapFile(Module)) {
// Canonicalize compilation to start with the public module map. This is
// vital for submodules declarations in the private module maps to be
// correctly parsed when depending on a top level module in the public one.
if (const FileEntry *PublicMMFile = getPublicModuleMap(
ModuleMapFile, ImportingInstance.getFileManager()))
ModuleMapFile = PublicMMFile;
// Use the module map where this module resides.
Result = compileModuleImpl(
ImportingInstance, ImportLoc, Module->getTopLevelModuleName(),
FrontendInputFile(ModuleMapFile->getName(), IK, +Module->IsSystem),
ModMap.getModuleMapFileForUniquing(Module)->getName(),
ModuleFileName);
} else {
// FIXME: We only need to fake up an input file here as a way of
// transporting the module's directory to the module map parser. We should
// be able to do that more directly, and parse from a memory buffer without
// inventing this file.
SmallString<128> FakeModuleMapFile(Module->Directory->getName());
llvm::sys::path::append(FakeModuleMapFile, "__inferred_module.map");
std::string InferredModuleMapContent;
llvm::raw_string_ostream OS(InferredModuleMapContent);
Module->print(OS);
OS.flush();
Result = compileModuleImpl(
ImportingInstance, ImportLoc, Module->getTopLevelModuleName(),
FrontendInputFile(FakeModuleMapFile, IK, +Module->IsSystem),
ModMap.getModuleMapFileForUniquing(Module)->getName(),
ModuleFileName,
[&](CompilerInstance &Instance) {
std::unique_ptr<llvm::MemoryBuffer> ModuleMapBuffer =
llvm::MemoryBuffer::getMemBuffer(InferredModuleMapContent);
ModuleMapFile = Instance.getFileManager().getVirtualFile(
FakeModuleMapFile, InferredModuleMapContent.size(), 0);
Instance.getSourceManager().overrideFileContents(
ModuleMapFile, std::move(ModuleMapBuffer));
});
}
// We've rebuilt a module. If we're allowed to generate or update the global
// module index, record that fact in the importing compiler instance.
if (ImportingInstance.getFrontendOpts().GenerateGlobalModuleIndex) {
ImportingInstance.setBuildGlobalModuleIndex(true);
}
return Result;
}
/// Compile a module in a separate compiler instance and read the AST,
/// returning true if the module compiles without errors.
///
/// Uses a lock file manager and exponential backoff to reduce the chances that
/// multiple instances will compete to create the same module. On timeout,
/// deletes the lock file in order to avoid deadlock from crashing processes or
/// bugs in the lock file manager.
static bool compileModuleAndReadAST(CompilerInstance &ImportingInstance,
SourceLocation ImportLoc,
SourceLocation ModuleNameLoc,
Module *Module, StringRef ModuleFileName) {
DiagnosticsEngine &Diags = ImportingInstance.getDiagnostics();
auto diagnoseBuildFailure = [&] {
Diags.Report(ModuleNameLoc, diag::err_module_not_built)
<< Module->Name << SourceRange(ImportLoc, ModuleNameLoc);
};
// FIXME: have LockFileManager return an error_code so that we can
// avoid the mkdir when the directory already exists.
StringRef Dir = llvm::sys::path::parent_path(ModuleFileName);
llvm::sys::fs::create_directories(Dir);
while (1) {
unsigned ModuleLoadCapabilities = ASTReader::ARR_Missing;
llvm::LockFileManager Locked(ModuleFileName);
switch (Locked) {
case llvm::LockFileManager::LFS_Error:
// ModuleCache takes care of correctness and locks are only necessary for
// performance. Fallback to building the module in case of any lock
// related errors.
Diags.Report(ModuleNameLoc, diag::remark_module_lock_failure)
<< Module->Name << Locked.getErrorMessage();
// Clear out any potential leftover.
Locked.unsafeRemoveLockFile();
LLVM_FALLTHROUGH;
case llvm::LockFileManager::LFS_Owned:
// We're responsible for building the module ourselves.
if (!compileModule(ImportingInstance, ModuleNameLoc, Module,
ModuleFileName)) {
diagnoseBuildFailure();
return false;
}
break;
case llvm::LockFileManager::LFS_Shared:
// Someone else is responsible for building the module. Wait for them to
// finish.
switch (Locked.waitForUnlock()) {
case llvm::LockFileManager::Res_Success:
ModuleLoadCapabilities |= ASTReader::ARR_OutOfDate;
break;
case llvm::LockFileManager::Res_OwnerDied:
continue; // try again to get the lock.
case llvm::LockFileManager::Res_Timeout:
// Since ModuleCache takes care of correctness, we try waiting for
// another process to complete the build so clang does not do it done
// twice. If case of timeout, build it ourselves.
Diags.Report(ModuleNameLoc, diag::remark_module_lock_timeout)
<< Module->Name;
// Clear the lock file so that future invocations can make progress.
Locked.unsafeRemoveLockFile();
continue;
}
break;
}
// Try to read the module file, now that we've compiled it.
ASTReader::ASTReadResult ReadResult =
ImportingInstance.getASTReader()->ReadAST(
ModuleFileName, serialization::MK_ImplicitModule, ImportLoc,
ModuleLoadCapabilities);
if (ReadResult == ASTReader::OutOfDate &&
Locked == llvm::LockFileManager::LFS_Shared) {
// The module may be out of date in the presence of file system races,
// or if one of its imports depends on header search paths that are not
// consistent with this ImportingInstance. Try again...
continue;
} else if (ReadResult == ASTReader::Missing) {
diagnoseBuildFailure();
} else if (ReadResult != ASTReader::Success &&
!Diags.hasErrorOccurred()) {
// The ASTReader didn't diagnose the error, so conservatively report it.
diagnoseBuildFailure();
}
return ReadResult == ASTReader::Success;
}
}
/// Diagnose differences between the current definition of the given
/// configuration macro and the definition provided on the command line.
static void checkConfigMacro(Preprocessor &PP, StringRef ConfigMacro,
Module *Mod, SourceLocation ImportLoc) {
IdentifierInfo *Id = PP.getIdentifierInfo(ConfigMacro);
SourceManager &SourceMgr = PP.getSourceManager();
// If this identifier has never had a macro definition, then it could
// not have changed.
if (!Id->hadMacroDefinition())
return;
auto *LatestLocalMD = PP.getLocalMacroDirectiveHistory(Id);
// Find the macro definition from the command line.
MacroInfo *CmdLineDefinition = nullptr;
for (auto *MD = LatestLocalMD; MD; MD = MD->getPrevious()) {
// We only care about the predefines buffer.
FileID FID = SourceMgr.getFileID(MD->getLocation());
if (FID.isInvalid() || FID != PP.getPredefinesFileID())
continue;
if (auto *DMD = dyn_cast<DefMacroDirective>(MD))
CmdLineDefinition = DMD->getMacroInfo();
break;
}
auto *CurrentDefinition = PP.getMacroInfo(Id);
if (CurrentDefinition == CmdLineDefinition) {
// Macro matches. Nothing to do.
} else if (!CurrentDefinition) {
// This macro was defined on the command line, then #undef'd later.
// Complain.
PP.Diag(ImportLoc, diag::warn_module_config_macro_undef)
<< true << ConfigMacro << Mod->getFullModuleName();
auto LatestDef = LatestLocalMD->getDefinition();
assert(LatestDef.isUndefined() &&
"predefined macro went away with no #undef?");
PP.Diag(LatestDef.getUndefLocation(), diag::note_module_def_undef_here)
<< true;
return;
} else if (!CmdLineDefinition) {
// There was no definition for this macro in the predefines buffer,
// but there was a local definition. Complain.
PP.Diag(ImportLoc, diag::warn_module_config_macro_undef)
<< false << ConfigMacro << Mod->getFullModuleName();
PP.Diag(CurrentDefinition->getDefinitionLoc(),
diag::note_module_def_undef_here)
<< false;
} else if (!CurrentDefinition->isIdenticalTo(*CmdLineDefinition, PP,
/*Syntactically=*/true)) {
// The macro definitions differ.
PP.Diag(ImportLoc, diag::warn_module_config_macro_undef)
<< false << ConfigMacro << Mod->getFullModuleName();
PP.Diag(CurrentDefinition->getDefinitionLoc(),
diag::note_module_def_undef_here)
<< false;
}
}
/// Write a new timestamp file with the given path.
static void writeTimestampFile(StringRef TimestampFile) {
std::error_code EC;
llvm::raw_fd_ostream Out(TimestampFile.str(), EC, llvm::sys::fs::OF_None);
}
/// Prune the module cache of modules that haven't been accessed in
/// a long time.
static void pruneModuleCache(const HeaderSearchOptions &HSOpts) {
llvm::sys::fs::file_status StatBuf;
llvm::SmallString<128> TimestampFile;
TimestampFile = HSOpts.ModuleCachePath;
assert(!TimestampFile.empty());
llvm::sys::path::append(TimestampFile, "modules.timestamp");
// Try to stat() the timestamp file.
if (std::error_code EC = llvm::sys::fs::status(TimestampFile, StatBuf)) {
// If the timestamp file wasn't there, create one now.
if (EC == std::errc::no_such_file_or_directory) {
writeTimestampFile(TimestampFile);
}
return;
}
// Check whether the time stamp is older than our pruning interval.
// If not, do nothing.
time_t TimeStampModTime =
llvm::sys::toTimeT(StatBuf.getLastModificationTime());
time_t CurrentTime = time(nullptr);
if (CurrentTime - TimeStampModTime <= time_t(HSOpts.ModuleCachePruneInterval))
return;
// Write a new timestamp file so that nobody else attempts to prune.
// There is a benign race condition here, if two Clang instances happen to
// notice at the same time that the timestamp is out-of-date.
writeTimestampFile(TimestampFile);
// Walk the entire module cache, looking for unused module files and module
// indices.
std::error_code EC;
SmallString<128> ModuleCachePathNative;
llvm::sys::path::native(HSOpts.ModuleCachePath, ModuleCachePathNative);
for (llvm::sys::fs::directory_iterator Dir(ModuleCachePathNative, EC), DirEnd;
Dir != DirEnd && !EC; Dir.increment(EC)) {
// If we don't have a directory, there's nothing to look into.
if (!llvm::sys::fs::is_directory(Dir->path()))
continue;
// Walk all of the files within this directory.
for (llvm::sys::fs::directory_iterator File(Dir->path(), EC), FileEnd;
File != FileEnd && !EC; File.increment(EC)) {
// We only care about module and global module index files.
StringRef Extension = llvm::sys::path::extension(File->path());
if (Extension != ".pcm" && Extension != ".timestamp" &&
llvm::sys::path::filename(File->path()) != "modules.idx")
continue;
// Look at this file. If we can't stat it, there's nothing interesting
// there.
if (llvm::sys::fs::status(File->path(), StatBuf))
continue;
// If the file has been used recently enough, leave it there.
time_t FileAccessTime = llvm::sys::toTimeT(StatBuf.getLastAccessedTime());
if (CurrentTime - FileAccessTime <=
time_t(HSOpts.ModuleCachePruneAfter)) {
continue;
}
// Remove the file.
llvm::sys::fs::remove(File->path());
// Remove the timestamp file.
std::string TimpestampFilename = File->path() + ".timestamp";
llvm::sys::fs::remove(TimpestampFilename);
}
// If we removed all of the files in the directory, remove the directory
// itself.
if (llvm::sys::fs::directory_iterator(Dir->path(), EC) ==
llvm::sys::fs::directory_iterator() && !EC)
llvm::sys::fs::remove(Dir->path());
}
}
void CompilerInstance::createASTReader() {
if (TheASTReader)
return;
if (!hasASTContext())
createASTContext();
// If we're implicitly building modules but not currently recursively
// building a module, check whether we need to prune the module cache.
if (getSourceManager().getModuleBuildStack().empty() &&
!getPreprocessor().getHeaderSearchInfo().getModuleCachePath().empty() &&
getHeaderSearchOpts().ModuleCachePruneInterval > 0 &&
getHeaderSearchOpts().ModuleCachePruneAfter > 0) {
pruneModuleCache(getHeaderSearchOpts());
}
HeaderSearchOptions &HSOpts = getHeaderSearchOpts();
std::string Sysroot = HSOpts.Sysroot;
const PreprocessorOptions &PPOpts = getPreprocessorOpts();
std::unique_ptr<llvm::Timer> ReadTimer;
if (FrontendTimerGroup)
ReadTimer = std::make_unique<llvm::Timer>("reading_modules",
"Reading modules",
*FrontendTimerGroup);
TheASTReader = new ASTReader(
getPreprocessor(), getModuleCache(), &getASTContext(),
getPCHContainerReader(), getFrontendOpts().ModuleFileExtensions,
Sysroot.empty() ? "" : Sysroot.c_str(), PPOpts.DisablePCHValidation,
/*AllowASTWithCompilerErrors=*/false,
/*AllowConfigurationMismatch=*/false, HSOpts.ModulesValidateSystemHeaders,
HSOpts.ValidateASTInputFilesContent,
getFrontendOpts().UseGlobalModuleIndex, std::move(ReadTimer));
if (hasASTConsumer()) {
TheASTReader->setDeserializationListener(
getASTConsumer().GetASTDeserializationListener());
getASTContext().setASTMutationListener(
getASTConsumer().GetASTMutationListener());
}
getASTContext().setExternalSource(TheASTReader);
if (hasSema())
TheASTReader->InitializeSema(getSema());
if (hasASTConsumer())
TheASTReader->StartTranslationUnit(&getASTConsumer());
for (auto &Listener : DependencyCollectors)
Listener->attachToASTReader(*TheASTReader);
}
bool CompilerInstance::loadModuleFile(StringRef FileName) {
llvm::Timer Timer;
if (FrontendTimerGroup)
Timer.init("preloading." + FileName.str(), "Preloading " + FileName.str(),
*FrontendTimerGroup);
llvm::TimeRegion TimeLoading(FrontendTimerGroup ? &Timer : nullptr);
// Helper to recursively read the module names for all modules we're adding.
// We mark these as known and redirect any attempt to load that module to
// the files we were handed.
struct ReadModuleNames : ASTReaderListener {
CompilerInstance &CI;
llvm::SmallVector<IdentifierInfo*, 8> LoadedModules;
ReadModuleNames(CompilerInstance &CI) : CI(CI) {}
void ReadModuleName(StringRef ModuleName) override {
LoadedModules.push_back(
CI.getPreprocessor().getIdentifierInfo(ModuleName));
}
void registerAll() {
ModuleMap &MM = CI.getPreprocessor().getHeaderSearchInfo().getModuleMap();
for (auto *II : LoadedModules)
MM.cacheModuleLoad(*II, MM.findModule(II->getName()));
LoadedModules.clear();
}
void markAllUnavailable() {
for (auto *II : LoadedModules) {
if (Module *M = CI.getPreprocessor()
.getHeaderSearchInfo()
.getModuleMap()
.findModule(II->getName())) {
M->HasIncompatibleModuleFile = true;
// Mark module as available if the only reason it was unavailable
// was missing headers.
SmallVector<Module *, 2> Stack;
Stack.push_back(M);
while (!Stack.empty()) {
Module *Current = Stack.pop_back_val();
if (Current->IsUnimportable) continue;
Current->IsAvailable = true;
Stack.insert(Stack.end(),
Current->submodule_begin(), Current->submodule_end());
}
}
}
LoadedModules.clear();
}
};
// If we don't already have an ASTReader, create one now.
if (!TheASTReader)
createASTReader();
// If -Wmodule-file-config-mismatch is mapped as an error or worse, allow the
// ASTReader to diagnose it, since it can produce better errors that we can.
bool ConfigMismatchIsRecoverable =
getDiagnostics().getDiagnosticLevel(diag::warn_module_config_mismatch,
SourceLocation())
<= DiagnosticsEngine::Warning;
auto Listener = std::make_unique<ReadModuleNames>(*this);
auto &ListenerRef = *Listener;
ASTReader::ListenerScope ReadModuleNamesListener(*TheASTReader,
std::move(Listener));
// Try to load the module file.
switch (TheASTReader->ReadAST(
FileName, serialization::MK_ExplicitModule, SourceLocation(),
ConfigMismatchIsRecoverable ? ASTReader::ARR_ConfigurationMismatch : 0)) {
case ASTReader::Success:
// We successfully loaded the module file; remember the set of provided
// modules so that we don't try to load implicit modules for them.
ListenerRef.registerAll();
return true;
case ASTReader::ConfigurationMismatch:
// Ignore unusable module files.
getDiagnostics().Report(SourceLocation(), diag::warn_module_config_mismatch)
<< FileName;
// All modules provided by any files we tried and failed to load are now
// unavailable; includes of those modules should now be handled textually.
ListenerRef.markAllUnavailable();
return true;
default:
return false;
}
}
namespace {
enum ModuleSource {
MS_ModuleNotFound,
MS_ModuleCache,
MS_PrebuiltModulePath,
MS_ModuleBuildPragma
};
} // end namespace
/// Select a source for loading the named module and compute the filename to
/// load it from.
static ModuleSource selectModuleSource(
Module *M, StringRef ModuleName, std::string &ModuleFilename,
const std::map<std::string, std::string, std::less<>> &BuiltModules,
HeaderSearch &HS) {
assert(ModuleFilename.empty() && "Already has a module source?");
// Check to see if the module has been built as part of this compilation
// via a module build pragma.
auto BuiltModuleIt = BuiltModules.find(ModuleName);
if (BuiltModuleIt != BuiltModules.end()) {
ModuleFilename = BuiltModuleIt->second;
return MS_ModuleBuildPragma;
}
// Try to load the module from the prebuilt module path.
const HeaderSearchOptions &HSOpts = HS.getHeaderSearchOpts();
if (!HSOpts.PrebuiltModuleFiles.empty() ||
!HSOpts.PrebuiltModulePaths.empty()) {
ModuleFilename = HS.getPrebuiltModuleFileName(ModuleName);
if (!ModuleFilename.empty())
return MS_PrebuiltModulePath;
}
// Try to load the module from the module cache.
if (M) {
ModuleFilename = HS.getCachedModuleFileName(M);
return MS_ModuleCache;
}
return MS_ModuleNotFound;
}
ModuleLoadResult CompilerInstance::findOrCompileModuleAndReadAST(
StringRef ModuleName, SourceLocation ImportLoc,
SourceLocation ModuleNameLoc, bool IsInclusionDirective) {
// Search for a module with the given name.
HeaderSearch &HS = PP->getHeaderSearchInfo();
Module *M = HS.lookupModule(ModuleName, true, !IsInclusionDirective);
// Select the source and filename for loading the named module.
std::string ModuleFilename;
ModuleSource Source =
selectModuleSource(M, ModuleName, ModuleFilename, BuiltModules, HS);
if (Source == MS_ModuleNotFound) {
// We can't find a module, error out here.
getDiagnostics().Report(ModuleNameLoc, diag::err_module_not_found)
<< ModuleName << SourceRange(ImportLoc, ModuleNameLoc);
ModuleBuildFailed = true;
// FIXME: Why is this not cached?
return ModuleLoadResult::OtherUncachedFailure;
}
if (ModuleFilename.empty()) {
if (M && M->HasIncompatibleModuleFile) {
// We tried and failed to load a module file for this module. Fall
// back to textual inclusion for its headers.
return ModuleLoadResult::ConfigMismatch;
}
getDiagnostics().Report(ModuleNameLoc, diag::err_module_build_disabled)
<< ModuleName;
ModuleBuildFailed = true;
// FIXME: Why is this not cached?
return ModuleLoadResult::OtherUncachedFailure;
}
// Create an ASTReader on demand.
if (!getASTReader())
createASTReader();
// Time how long it takes to load the module.
llvm::Timer Timer;
if (FrontendTimerGroup)
Timer.init("loading." + ModuleFilename, "Loading " + ModuleFilename,
*FrontendTimerGroup);
llvm::TimeRegion TimeLoading(FrontendTimerGroup ? &Timer : nullptr);
llvm::TimeTraceScope TimeScope("Module Load", ModuleName);
// Try to load the module file. If we are not trying to load from the
// module cache, we don't know how to rebuild modules.
unsigned ARRFlags = Source == MS_ModuleCache
? ASTReader::ARR_OutOfDate | ASTReader::ARR_Missing
: Source == MS_PrebuiltModulePath
? 0
: ASTReader::ARR_ConfigurationMismatch;
switch (getASTReader()->ReadAST(ModuleFilename,
Source == MS_PrebuiltModulePath
? serialization::MK_PrebuiltModule
: Source == MS_ModuleBuildPragma
? serialization::MK_ExplicitModule
: serialization::MK_ImplicitModule,
ImportLoc, ARRFlags)) {
case ASTReader::Success: {
if (M)
return M;
assert(Source != MS_ModuleCache &&
"missing module, but file loaded from cache");
// A prebuilt module is indexed as a ModuleFile; the Module does not exist
// until the first call to ReadAST. Look it up now.
M = HS.lookupModule(ModuleName, true, !IsInclusionDirective);
// Check whether M refers to the file in the prebuilt module path.
if (M && M->getASTFile())
if (auto ModuleFile = FileMgr->getFile(ModuleFilename))
if (*ModuleFile == M->getASTFile())
return M;
ModuleBuildFailed = true;
getDiagnostics().Report(ModuleNameLoc, diag::err_module_prebuilt)
<< ModuleName;
return ModuleLoadResult();
}
case ASTReader::OutOfDate:
case ASTReader::Missing:
// The most interesting case.
break;
case ASTReader::ConfigurationMismatch:
if (Source == MS_PrebuiltModulePath)
// FIXME: We shouldn't be setting HadFatalFailure below if we only
// produce a warning here!
getDiagnostics().Report(SourceLocation(),
diag::warn_module_config_mismatch)
<< ModuleFilename;
// Fall through to error out.
LLVM_FALLTHROUGH;
case ASTReader::VersionMismatch:
case ASTReader::HadErrors:
// FIXME: Should this set ModuleBuildFailed = true?
ModuleLoader::HadFatalFailure = true;
// FIXME: The ASTReader will already have complained, but can we shoehorn
// that diagnostic information into a more useful form?
return ModuleLoadResult();
case ASTReader::Failure:
// FIXME: Should this set ModuleBuildFailed = true?
ModuleLoader::HadFatalFailure = true;
return ModuleLoadResult();
}
// ReadAST returned Missing or OutOfDate.
if (Source != MS_ModuleCache) {
// We don't know the desired configuration for this module and don't
// necessarily even have a module map. Since ReadAST already produces
// diagnostics for these two cases, we simply error out here.
ModuleBuildFailed = true;
return ModuleLoadResult();
}
// The module file is missing or out-of-date. Build it.
assert(M && "missing module, but trying to compile for cache");
// Check whether there is a cycle in the module graph.
ModuleBuildStack ModPath = getSourceManager().getModuleBuildStack();
ModuleBuildStack::iterator Pos = ModPath.begin(), PosEnd = ModPath.end();
for (; Pos != PosEnd; ++Pos) {
if (Pos->first == ModuleName)
break;
}
if (Pos != PosEnd) {
SmallString<256> CyclePath;
for (; Pos != PosEnd; ++Pos) {
CyclePath += Pos->first;
CyclePath += " -> ";
}
CyclePath += ModuleName;
getDiagnostics().Report(ModuleNameLoc, diag::err_module_cycle)
<< ModuleName << CyclePath;
// FIXME: Should this set ModuleBuildFailed = true?
// FIXME: Why is this not cached?
return ModuleLoadResult::OtherUncachedFailure;
}
// Check whether we have already attempted to build this module (but
// failed).
if (getPreprocessorOpts().FailedModules &&
getPreprocessorOpts().FailedModules->hasAlreadyFailed(ModuleName)) {
getDiagnostics().Report(ModuleNameLoc, diag::err_module_not_built)
<< ModuleName << SourceRange(ImportLoc, ModuleNameLoc);
ModuleBuildFailed = true;
// FIXME: Why is this not cached?
return ModuleLoadResult::OtherUncachedFailure;
}
// Try to compile and then read the AST.
if (!compileModuleAndReadAST(*this, ImportLoc, ModuleNameLoc, M,
ModuleFilename)) {
assert(getDiagnostics().hasErrorOccurred() &&
"undiagnosed error in compileModuleAndReadAST");
if (getPreprocessorOpts().FailedModules)
getPreprocessorOpts().FailedModules->addFailed(ModuleName);
ModuleBuildFailed = true;
// FIXME: Why is this not cached?
return ModuleLoadResult::OtherUncachedFailure;
}
// Okay, we've rebuilt and now loaded the module.
return M;
}
ModuleLoadResult
CompilerInstance::loadModule(SourceLocation ImportLoc,
ModuleIdPath Path,
Module::NameVisibilityKind Visibility,
bool IsInclusionDirective) {
// Determine what file we're searching from.
StringRef ModuleName = Path[0].first->getName();
SourceLocation ModuleNameLoc = Path[0].second;
// If we've already handled this import, just return the cached result.
// This one-element cache is important to eliminate redundant diagnostics
// when both the preprocessor and parser see the same import declaration.
if (ImportLoc.isValid() && LastModuleImportLoc == ImportLoc) {
// Make the named module visible.
if (LastModuleImportResult && ModuleName != getLangOpts().CurrentModule)
TheASTReader->makeModuleVisible(LastModuleImportResult, Visibility,
ImportLoc);
return LastModuleImportResult;
}
// If we don't already have information on this module, load the module now.
Module *Module = nullptr;
ModuleMap &MM = getPreprocessor().getHeaderSearchInfo().getModuleMap();
if (auto MaybeModule = MM.getCachedModuleLoad(*Path[0].first)) {
// Use the cached result, which may be nullptr.
Module = *MaybeModule;
} else if (ModuleName == getLangOpts().CurrentModule) {
// This is the module we're building.
Module = PP->getHeaderSearchInfo().lookupModule(
ModuleName, /*AllowSearch*/ true,
/*AllowExtraModuleMapSearch*/ !IsInclusionDirective);
/// FIXME: perhaps we should (a) look for a module using the module name
// to file map (PrebuiltModuleFiles) and (b) diagnose if still not found?
//if (Module == nullptr) {
// getDiagnostics().Report(ModuleNameLoc, diag::err_module_not_found)
// << ModuleName;
// ModuleBuildFailed = true;
// return ModuleLoadResult();
//}
MM.cacheModuleLoad(*Path[0].first, Module);
} else {
ModuleLoadResult Result = findOrCompileModuleAndReadAST(
ModuleName, ImportLoc, ModuleNameLoc, IsInclusionDirective);
// FIXME: Can we pull 'ModuleBuildFailed = true' out of the return
// sequences for findOrCompileModuleAndReadAST and do it here (as long as
// the result is not a config mismatch)? See FIXMEs there.
if (!Result.isNormal())
return Result;
Module = Result;
MM.cacheModuleLoad(*Path[0].first, Module);
if (!Module)
return Module;
}
// If we never found the module, fail. Otherwise, verify the module and link
// it up.
if (!Module)
return ModuleLoadResult();
// Verify that the rest of the module path actually corresponds to
// a submodule.
bool MapPrivateSubModToTopLevel = false;
if (Path.size() > 1) {
for (unsigned I = 1, N = Path.size(); I != N; ++I) {
StringRef Name = Path[I].first->getName();
clang::Module *Sub = Module->findSubmodule(Name);
// If the user is requesting Foo.Private and it doesn't exist, try to
// match Foo_Private and emit a warning asking for the user to write
// @import Foo_Private instead. FIXME: remove this when existing clients
// migrate off of Foo.Private syntax.
if (!Sub && PP->getLangOpts().ImplicitModules && Name == "Private" &&
Module == Module->getTopLevelModule()) {
SmallString<128> PrivateModule(Module->Name);
PrivateModule.append("_Private");
SmallVector<std::pair<IdentifierInfo *, SourceLocation>, 2> PrivPath;
auto &II = PP->getIdentifierTable().get(
PrivateModule, PP->getIdentifierInfo(Module->Name)->getTokenID());
PrivPath.push_back(std::make_pair(&II, Path[0].second));
if (PP->getHeaderSearchInfo().lookupModule(PrivateModule, true,
!IsInclusionDirective))
Sub =
loadModule(ImportLoc, PrivPath, Visibility, IsInclusionDirective);
if (Sub) {
MapPrivateSubModToTopLevel = true;
if (!getDiagnostics().isIgnored(
diag::warn_no_priv_submodule_use_toplevel, ImportLoc)) {
getDiagnostics().Report(Path[I].second,
diag::warn_no_priv_submodule_use_toplevel)
<< Path[I].first << Module->getFullModuleName() << PrivateModule
<< SourceRange(Path[0].second, Path[I].second)
<< FixItHint::CreateReplacement(SourceRange(Path[0].second),
PrivateModule);
getDiagnostics().Report(Sub->DefinitionLoc,
diag::note_private_top_level_defined);
}
}
}
if (!Sub) {
// Attempt to perform typo correction to find a module name that works.
SmallVector<StringRef, 2> Best;
unsigned BestEditDistance = (std::numeric_limits<unsigned>::max)();
for (clang::Module::submodule_iterator J = Module->submodule_begin(),
JEnd = Module->submodule_end();
J != JEnd; ++J) {
unsigned ED = Name.edit_distance((*J)->Name,
/*AllowReplacements=*/true,
BestEditDistance);
if (ED <= BestEditDistance) {
if (ED < BestEditDistance) {
Best.clear();
BestEditDistance = ED;
}
Best.push_back((*J)->Name);
}
}
// If there was a clear winner, user it.
if (Best.size() == 1) {
getDiagnostics().Report(Path[I].second,
diag::err_no_submodule_suggest)
<< Path[I].first << Module->getFullModuleName() << Best[0]
<< SourceRange(Path[0].second, Path[I-1].second)
<< FixItHint::CreateReplacement(SourceRange(Path[I].second),
Best[0]);
Sub = Module->findSubmodule(Best[0]);
}
}
if (!Sub) {
// No submodule by this name. Complain, and don't look for further
// submodules.
getDiagnostics().Report(Path[I].second, diag::err_no_submodule)
<< Path[I].first << Module->getFullModuleName()
<< SourceRange(Path[0].second, Path[I-1].second);
break;
}
Module = Sub;
}
}
// Make the named module visible, if it's not already part of the module
// we are parsing.
if (ModuleName != getLangOpts().CurrentModule) {
if (!Module->IsFromModuleFile && !MapPrivateSubModToTopLevel) {
// We have an umbrella header or directory that doesn't actually include
// all of the headers within the directory it covers. Complain about
// this missing submodule and recover by forgetting that we ever saw
// this submodule.
// FIXME: Should we detect this at module load time? It seems fairly
// expensive (and rare).
getDiagnostics().Report(ImportLoc, diag::warn_missing_submodule)
<< Module->getFullModuleName()
<< SourceRange(Path.front().second, Path.back().second);
return ModuleLoadResult::MissingExpected;
}
// Check whether this module is available.
if (Preprocessor::checkModuleIsAvailable(getLangOpts(), getTarget(),
getDiagnostics(), Module)) {
getDiagnostics().Report(ImportLoc, diag::note_module_import_here)
<< SourceRange(Path.front().second, Path.back().second);
LastModuleImportLoc = ImportLoc;
LastModuleImportResult = ModuleLoadResult();
return ModuleLoadResult();
}
TheASTReader->makeModuleVisible(Module, Visibility, ImportLoc);
}
// Check for any configuration macros that have changed.
clang::Module *TopModule = Module->getTopLevelModule();
for (unsigned I = 0, N = TopModule->ConfigMacros.size(); I != N; ++I) {
checkConfigMacro(getPreprocessor(), TopModule->ConfigMacros[I],
Module, ImportLoc);
}
// Resolve any remaining module using export_as for this one.
getPreprocessor()
.getHeaderSearchInfo()
.getModuleMap()
.resolveLinkAsDependencies(TopModule);
LastModuleImportLoc = ImportLoc;
LastModuleImportResult = ModuleLoadResult(Module);
return LastModuleImportResult;
}
void CompilerInstance::createModuleFromSource(SourceLocation ImportLoc,
StringRef ModuleName,
StringRef Source) {
// Avoid creating filenames with special characters.
SmallString<128> CleanModuleName(ModuleName);
for (auto &C : CleanModuleName)
if (!isAlphanumeric(C))
C = '_';
// FIXME: Using a randomized filename here means that our intermediate .pcm
// output is nondeterministic (as .pcm files refer to each other by name).
// Can this affect the output in any way?
SmallString<128> ModuleFileName;
if (std::error_code EC = llvm::sys::fs::createTemporaryFile(
CleanModuleName, "pcm", ModuleFileName)) {
getDiagnostics().Report(ImportLoc, diag::err_fe_unable_to_open_output)
<< ModuleFileName << EC.message();
return;
}
std::string ModuleMapFileName = (CleanModuleName + ".map").str();
FrontendInputFile Input(
ModuleMapFileName,
InputKind(getLanguageFromOptions(*Invocation->getLangOpts()),
InputKind::ModuleMap, /*Preprocessed*/true));
std::string NullTerminatedSource(Source.str());
auto PreBuildStep = [&](CompilerInstance &Other) {
// Create a virtual file containing our desired source.
// FIXME: We shouldn't need to do this.
const FileEntry *ModuleMapFile = Other.getFileManager().getVirtualFile(
ModuleMapFileName, NullTerminatedSource.size(), 0);
Other.getSourceManager().overrideFileContents(
ModuleMapFile,
llvm::MemoryBuffer::getMemBuffer(NullTerminatedSource.c_str()));
Other.BuiltModules = std::move(BuiltModules);
Other.DeleteBuiltModules = false;
};
auto PostBuildStep = [this](CompilerInstance &Other) {
BuiltModules = std::move(Other.BuiltModules);
};
// Build the module, inheriting any modules that we've built locally.
if (compileModuleImpl(*this, ImportLoc, ModuleName, Input, StringRef(),
ModuleFileName, PreBuildStep, PostBuildStep)) {
BuiltModules[std::string(ModuleName)] = std::string(ModuleFileName.str());
llvm::sys::RemoveFileOnSignal(ModuleFileName);
}
}
void CompilerInstance::makeModuleVisible(Module *Mod,
Module::NameVisibilityKind Visibility,
SourceLocation ImportLoc) {
if (!TheASTReader)
createASTReader();
if (!TheASTReader)
return;
TheASTReader->makeModuleVisible(Mod, Visibility, ImportLoc);
}
GlobalModuleIndex *CompilerInstance::loadGlobalModuleIndex(
SourceLocation TriggerLoc) {
if (getPreprocessor().getHeaderSearchInfo().getModuleCachePath().empty())
return nullptr;
if (!TheASTReader)
createASTReader();
// Can't do anything if we don't have the module manager.
if (!TheASTReader)
return nullptr;
// Get an existing global index. This loads it if not already
// loaded.
TheASTReader->loadGlobalIndex();
GlobalModuleIndex *GlobalIndex = TheASTReader->getGlobalIndex();
// If the global index doesn't exist, create it.
if (!GlobalIndex && shouldBuildGlobalModuleIndex() && hasFileManager() &&
hasPreprocessor()) {
llvm::sys::fs::create_directories(
getPreprocessor().getHeaderSearchInfo().getModuleCachePath());
if (llvm::Error Err = GlobalModuleIndex::writeIndex(
getFileManager(), getPCHContainerReader(),
getPreprocessor().getHeaderSearchInfo().getModuleCachePath())) {
// FIXME this drops the error on the floor. This code is only used for
// typo correction and drops more than just this one source of errors
// (such as the directory creation failure above). It should handle the
// error.
consumeError(std::move(Err));
return nullptr;
}
TheASTReader->resetForReload();
TheASTReader->loadGlobalIndex();
GlobalIndex = TheASTReader->getGlobalIndex();
}
// For finding modules needing to be imported for fixit messages,
// we need to make the global index cover all modules, so we do that here.
if (!HaveFullGlobalModuleIndex && GlobalIndex && !buildingModule()) {
ModuleMap &MMap = getPreprocessor().getHeaderSearchInfo().getModuleMap();
bool RecreateIndex = false;
for (ModuleMap::module_iterator I = MMap.module_begin(),
E = MMap.module_end(); I != E; ++I) {
Module *TheModule = I->second;
const FileEntry *Entry = TheModule->getASTFile();
if (!Entry) {
SmallVector<std::pair<IdentifierInfo *, SourceLocation>, 2> Path;
Path.push_back(std::make_pair(
getPreprocessor().getIdentifierInfo(TheModule->Name), TriggerLoc));
std::reverse(Path.begin(), Path.end());
// Load a module as hidden. This also adds it to the global index.
loadModule(TheModule->DefinitionLoc, Path, Module::Hidden, false);
RecreateIndex = true;
}
}
if (RecreateIndex) {
if (llvm::Error Err = GlobalModuleIndex::writeIndex(
getFileManager(), getPCHContainerReader(),
getPreprocessor().getHeaderSearchInfo().getModuleCachePath())) {
// FIXME As above, this drops the error on the floor.
consumeError(std::move(Err));
return nullptr;
}
TheASTReader->resetForReload();
TheASTReader->loadGlobalIndex();
GlobalIndex = TheASTReader->getGlobalIndex();
}
HaveFullGlobalModuleIndex = true;
}
return GlobalIndex;
}
// Check global module index for missing imports.
bool
CompilerInstance::lookupMissingImports(StringRef Name,
SourceLocation TriggerLoc) {
// Look for the symbol in non-imported modules, but only if an error
// actually occurred.
if (!buildingModule()) {
// Load global module index, or retrieve a previously loaded one.
GlobalModuleIndex *GlobalIndex = loadGlobalModuleIndex(
TriggerLoc);
// Only if we have a global index.
if (GlobalIndex) {
GlobalModuleIndex::HitSet FoundModules;
// Find the modules that reference the identifier.
// Note that this only finds top-level modules.
// We'll let diagnoseTypo find the actual declaration module.
if (GlobalIndex->lookupIdentifier(Name, FoundModules))
return true;
}
}
return false;
}
void CompilerInstance::resetAndLeakSema() { llvm::BuryPointer(takeSema()); }
void CompilerInstance::setExternalSemaSource(
IntrusiveRefCntPtr<ExternalSemaSource> ESS) {
ExternalSemaSrc = std::move(ESS);
}
Reference in New Issue View Git Blame Copy Permalink