//===--- extra/modularize/ModularizeUtilities.cpp -------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements a class for loading and validating a module map or // header list by checking that all headers in the corresponding directories // are accounted for. // //===----------------------------------------------------------------------===// #include "clang/Basic/SourceManager.h" #include "clang/Driver/Options.h" #include "clang/Frontend/CompilerInstance.h" #include "clang/Frontend/FrontendActions.h" #include "CoverageChecker.h" #include "llvm/ADT/SmallString.h" #include "llvm/Support/FileUtilities.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/raw_ostream.h" #include "ModularizeUtilities.h" using namespace clang; using namespace llvm; using namespace Modularize; namespace { // Subclass TargetOptions so we can construct it inline with // the minimal option, the triple. class ModuleMapTargetOptions : public clang::TargetOptions { public: ModuleMapTargetOptions() { Triple = llvm::sys::getDefaultTargetTriple(); } }; } // namespace // ModularizeUtilities class implementation. // Constructor. ModularizeUtilities::ModularizeUtilities(std::vector &InputPaths, llvm::StringRef Prefix, llvm::StringRef ProblemFilesListPath) : InputFilePaths(InputPaths), HeaderPrefix(Prefix), ProblemFilesPath(ProblemFilesListPath), HasModuleMap(false), MissingHeaderCount(0), // Init clang stuff needed for loading the module map and preprocessing. LangOpts(new LangOptions()), DiagIDs(new DiagnosticIDs()), DiagnosticOpts(new DiagnosticOptions()), DC(llvm::errs(), DiagnosticOpts.get()), Diagnostics( new DiagnosticsEngine(DiagIDs, DiagnosticOpts.get(), &DC, false)), TargetOpts(new ModuleMapTargetOptions()), Target(TargetInfo::CreateTargetInfo(*Diagnostics, TargetOpts)), FileMgr(new FileManager(FileSystemOpts)), SourceMgr(new SourceManager(*Diagnostics, *FileMgr, false)), HeaderInfo(new HeaderSearch(std::make_shared(), *SourceMgr, *Diagnostics, *LangOpts, Target.get())) {} // Create instance of ModularizeUtilities, to simplify setting up // subordinate objects. ModularizeUtilities *ModularizeUtilities::createModularizeUtilities( std::vector &InputPaths, llvm::StringRef Prefix, llvm::StringRef ProblemFilesListPath) { return new ModularizeUtilities(InputPaths, Prefix, ProblemFilesListPath); } // Load all header lists and dependencies. std::error_code ModularizeUtilities::loadAllHeaderListsAndDependencies() { // For each input file. for (auto I = InputFilePaths.begin(), E = InputFilePaths.end(); I != E; ++I) { llvm::StringRef InputPath = *I; // If it's a module map. if (InputPath.endswith(".modulemap")) { // Load the module map. if (std::error_code EC = loadModuleMap(InputPath)) return EC; } else { // Else we assume it's a header list and load it. if (std::error_code EC = loadSingleHeaderListsAndDependencies(InputPath)) { errs() << "modularize: error: Unable to get header list '" << InputPath << "': " << EC.message() << '\n'; return EC; } } } // If we have a problem files list. if (ProblemFilesPath.size() != 0) { // Load problem files list. if (std::error_code EC = loadProblemHeaderList(ProblemFilesPath)) { errs() << "modularize: error: Unable to get problem header list '" << ProblemFilesPath << "': " << EC.message() << '\n'; return EC; } } return std::error_code(); } // Do coverage checks. // For each loaded module map, do header coverage check. // Starting from the directory of the module.map file, // Find all header files, optionally looking only at files // covered by the include path options, and compare against // the headers referenced by the module.map file. // Display warnings for unaccounted-for header files. // Returns 0 if there were no errors or warnings, 1 if there // were warnings, 2 if any other problem, such as a bad // module map path argument was specified. std::error_code ModularizeUtilities::doCoverageCheck( std::vector &IncludePaths, llvm::ArrayRef CommandLine) { int ModuleMapCount = ModuleMaps.size(); int ModuleMapIndex; std::error_code EC; for (ModuleMapIndex = 0; ModuleMapIndex < ModuleMapCount; ++ModuleMapIndex) { std::unique_ptr &ModMap = ModuleMaps[ModuleMapIndex]; auto Checker = CoverageChecker::createCoverageChecker( InputFilePaths[ModuleMapIndex], IncludePaths, CommandLine, ModMap.get()); std::error_code LocalEC = Checker->doChecks(); if (LocalEC.value() > 0) EC = LocalEC; } return EC; } // Load single header list and dependencies. std::error_code ModularizeUtilities::loadSingleHeaderListsAndDependencies( llvm::StringRef InputPath) { // By default, use the path component of the list file name. SmallString<256> HeaderDirectory(InputPath); llvm::sys::path::remove_filename(HeaderDirectory); SmallString<256> CurrentDirectory; llvm::sys::fs::current_path(CurrentDirectory); // Get the prefix if we have one. if (HeaderPrefix.size() != 0) HeaderDirectory = HeaderPrefix; // Read the header list file into a buffer. ErrorOr> listBuffer = MemoryBuffer::getFile(InputPath); if (std::error_code EC = listBuffer.getError()) return EC; // Parse the header list into strings. SmallVector Strings; listBuffer.get()->getBuffer().split(Strings, "\n", -1, false); // Collect the header file names from the string list. for (SmallVectorImpl::iterator I = Strings.begin(), E = Strings.end(); I != E; ++I) { StringRef Line = I->trim(); // Ignore comments and empty lines. if (Line.empty() || (Line[0] == '#')) continue; std::pair TargetAndDependents = Line.split(':'); SmallString<256> HeaderFileName; // Prepend header file name prefix if it's not absolute. if (llvm::sys::path::is_absolute(TargetAndDependents.first)) llvm::sys::path::native(TargetAndDependents.first, HeaderFileName); else { if (HeaderDirectory.size() != 0) HeaderFileName = HeaderDirectory; else HeaderFileName = CurrentDirectory; llvm::sys::path::append(HeaderFileName, TargetAndDependents.first); llvm::sys::path::native(HeaderFileName); } // Handle optional dependencies. DependentsVector Dependents; SmallVector DependentsList; TargetAndDependents.second.split(DependentsList, " ", -1, false); int Count = DependentsList.size(); for (int Index = 0; Index < Count; ++Index) { SmallString<256> Dependent; if (llvm::sys::path::is_absolute(DependentsList[Index])) Dependent = DependentsList[Index]; else { if (HeaderDirectory.size() != 0) Dependent = HeaderDirectory; else Dependent = CurrentDirectory; llvm::sys::path::append(Dependent, DependentsList[Index]); } llvm::sys::path::native(Dependent); Dependents.push_back(getCanonicalPath(Dependent.str())); } // Get canonical form. HeaderFileName = getCanonicalPath(HeaderFileName); // Save the resulting header file path and dependencies. HeaderFileNames.push_back(HeaderFileName.str()); Dependencies[HeaderFileName.str()] = Dependents; } return std::error_code(); } // Load problem header list. std::error_code ModularizeUtilities::loadProblemHeaderList( llvm::StringRef InputPath) { // By default, use the path component of the list file name. SmallString<256> HeaderDirectory(InputPath); llvm::sys::path::remove_filename(HeaderDirectory); SmallString<256> CurrentDirectory; llvm::sys::fs::current_path(CurrentDirectory); // Get the prefix if we have one. if (HeaderPrefix.size() != 0) HeaderDirectory = HeaderPrefix; // Read the header list file into a buffer. ErrorOr> listBuffer = MemoryBuffer::getFile(InputPath); if (std::error_code EC = listBuffer.getError()) return EC; // Parse the header list into strings. SmallVector Strings; listBuffer.get()->getBuffer().split(Strings, "\n", -1, false); // Collect the header file names from the string list. for (SmallVectorImpl::iterator I = Strings.begin(), E = Strings.end(); I != E; ++I) { StringRef Line = I->trim(); // Ignore comments and empty lines. if (Line.empty() || (Line[0] == '#')) continue; SmallString<256> HeaderFileName; // Prepend header file name prefix if it's not absolute. if (llvm::sys::path::is_absolute(Line)) llvm::sys::path::native(Line, HeaderFileName); else { if (HeaderDirectory.size() != 0) HeaderFileName = HeaderDirectory; else HeaderFileName = CurrentDirectory; llvm::sys::path::append(HeaderFileName, Line); llvm::sys::path::native(HeaderFileName); } // Get canonical form. HeaderFileName = getCanonicalPath(HeaderFileName); // Save the resulting header file path. ProblemFileNames.push_back(HeaderFileName.str()); } return std::error_code(); } // Load single module map and extract header file list. std::error_code ModularizeUtilities::loadModuleMap( llvm::StringRef InputPath) { // Get file entry for module.modulemap file. const FileEntry *ModuleMapEntry = SourceMgr->getFileManager().getFile(InputPath); // return error if not found. if (!ModuleMapEntry) { llvm::errs() << "error: File \"" << InputPath << "\" not found.\n"; return std::error_code(1, std::generic_category()); } // Because the module map parser uses a ForwardingDiagnosticConsumer, // which doesn't forward the BeginSourceFile call, we do it explicitly here. DC.BeginSourceFile(*LangOpts, nullptr); // Figure out the home directory for the module map file. const DirectoryEntry *Dir = ModuleMapEntry->getDir(); StringRef DirName(Dir->getName()); if (llvm::sys::path::filename(DirName) == "Modules") { DirName = llvm::sys::path::parent_path(DirName); if (DirName.endswith(".framework")) Dir = FileMgr->getDirectory(DirName); // 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"); } std::unique_ptr ModMap; ModMap.reset(new ModuleMap(*SourceMgr, *Diagnostics, *LangOpts, Target.get(), *HeaderInfo)); // Parse module.modulemap file into module map. if (ModMap->parseModuleMapFile(ModuleMapEntry, false, Dir)) { return std::error_code(1, std::generic_category()); } // Do matching end call. DC.EndSourceFile(); // Reset missing header count. MissingHeaderCount = 0; if (!collectModuleMapHeaders(ModMap.get())) return std::error_code(1, std::generic_category()); // Save module map. ModuleMaps.push_back(std::move(ModMap)); // Indicate we are using module maps. HasModuleMap = true; // Return code of 1 for missing headers. if (MissingHeaderCount) return std::error_code(1, std::generic_category()); return std::error_code(); } // Collect module map headers. // Walks the modules and collects referenced headers into // HeaderFileNames. bool ModularizeUtilities::collectModuleMapHeaders(clang::ModuleMap *ModMap) { for (ModuleMap::module_iterator I = ModMap->module_begin(), E = ModMap->module_end(); I != E; ++I) { if (!collectModuleHeaders(*I->second)) return false; } return true; } // Collect referenced headers from one module. // Collects the headers referenced in the given module into // HeaderFileNames. bool ModularizeUtilities::collectModuleHeaders(const clang::Module &Mod) { // Ignore explicit modules because they often have dependencies // we can't know. if (Mod.IsExplicit) return true; // Treat headers in umbrella directory as dependencies. DependentsVector UmbrellaDependents; // Recursively do submodules. for (auto MI = Mod.submodule_begin(), MIEnd = Mod.submodule_end(); MI != MIEnd; ++MI) collectModuleHeaders(**MI); if (const FileEntry *UmbrellaHeader = Mod.getUmbrellaHeader().Entry) { std::string HeaderPath = getCanonicalPath(UmbrellaHeader->getName()); // Collect umbrella header. HeaderFileNames.push_back(HeaderPath); // FUTURE: When needed, umbrella header header collection goes here. } else if (const DirectoryEntry *UmbrellaDir = Mod.getUmbrellaDir().Entry) { // If there normal headers, assume these are umbrellas and skip collection. if (Mod.Headers->size() == 0) { // Collect headers in umbrella directory. if (!collectUmbrellaHeaders(UmbrellaDir->getName(), UmbrellaDependents)) return false; } } // We ignore HK_Private, HK_Textual, HK_PrivateTextual, and HK_Excluded, // assuming they are marked as such either because of unsuitability for // modules or because they are meant to be included by another header, // and thus should be ignored by modularize. int NormalHeaderCount = Mod.Headers[clang::Module::HK_Normal].size(); for (int Index = 0; Index < NormalHeaderCount; ++Index) { DependentsVector NormalDependents; // Collect normal header. const clang::Module::Header &Header( Mod.Headers[clang::Module::HK_Normal][Index]); std::string HeaderPath = getCanonicalPath(Header.Entry->getName()); HeaderFileNames.push_back(HeaderPath); } int MissingCountThisModule = Mod.MissingHeaders.size(); for (int Index = 0; Index < MissingCountThisModule; ++Index) { std::string MissingFile = Mod.MissingHeaders[Index].FileName; SourceLocation Loc = Mod.MissingHeaders[Index].FileNameLoc; errs() << Loc.printToString(*SourceMgr) << ": error : Header not found: " << MissingFile << "\n"; } MissingHeaderCount += MissingCountThisModule; return true; } // Collect headers from an umbrella directory. bool ModularizeUtilities::collectUmbrellaHeaders(StringRef UmbrellaDirName, DependentsVector &Dependents) { // Initialize directory name. SmallString<256> Directory(UmbrellaDirName); // Walk the directory. std::error_code EC; for (llvm::sys::fs::directory_iterator I(Directory.str(), EC), E; I != E; I.increment(EC)) { if (EC) return false; std::string File(I->path()); llvm::ErrorOr Status = I->status(); if (!Status) return false; llvm::sys::fs::file_type Type = Status->type(); // If the file is a directory, ignore the name and recurse. if (Type == llvm::sys::fs::file_type::directory_file) { if (!collectUmbrellaHeaders(File, Dependents)) return false; continue; } // If the file does not have a common header extension, ignore it. if (!isHeader(File)) continue; // Save header name. std::string HeaderPath = getCanonicalPath(File); Dependents.push_back(HeaderPath); } return true; } // Replace .. embedded in path for purposes of having // a canonical path. static std::string replaceDotDot(StringRef Path) { SmallString<128> Buffer; llvm::sys::path::const_iterator B = llvm::sys::path::begin(Path), E = llvm::sys::path::end(Path); while (B != E) { if (B->compare(".") == 0) { } else if (B->compare("..") == 0) llvm::sys::path::remove_filename(Buffer); else llvm::sys::path::append(Buffer, *B); ++B; } if (Path.endswith("/") || Path.endswith("\\")) Buffer.append(1, Path.back()); return Buffer.c_str(); } // Convert header path to canonical form. // The canonical form is basically just use forward slashes, and remove "./". // \param FilePath The file path, relative to the module map directory. // \returns The file path in canonical form. std::string ModularizeUtilities::getCanonicalPath(StringRef FilePath) { std::string Tmp(replaceDotDot(FilePath)); std::replace(Tmp.begin(), Tmp.end(), '\\', '/'); StringRef Tmp2(Tmp); if (Tmp2.startswith("./")) Tmp = Tmp2.substr(2); return Tmp; } // Check for header file extension. // If the file extension is .h, .inc, or missing, it's // assumed to be a header. // \param FileName The file name. Must not be a directory. // \returns true if it has a header extension or no extension. bool ModularizeUtilities::isHeader(StringRef FileName) { StringRef Extension = llvm::sys::path::extension(FileName); if (Extension.size() == 0) return true; if (Extension.equals_lower(".h")) return true; if (Extension.equals_lower(".inc")) return true; return false; } // Get directory path component from file path. // \returns the component of the given path, which will be // relative if the given path is relative, absolute if the // given path is absolute, or "." if the path has no leading // path component. std::string ModularizeUtilities::getDirectoryFromPath(StringRef Path) { SmallString<256> Directory(Path); sys::path::remove_filename(Directory); if (Directory.size() == 0) return "."; return Directory.str(); } // Add unique problem file. // Also standardizes the path. void ModularizeUtilities::addUniqueProblemFile(std::string FilePath) { FilePath = getCanonicalPath(FilePath); // Don't add if already present. for(auto &TestFilePath : ProblemFileNames) { if (TestFilePath == FilePath) return; } ProblemFileNames.push_back(FilePath); } // Add file with no compile errors. // Also standardizes the path. void ModularizeUtilities::addNoCompileErrorsFile(std::string FilePath) { FilePath = getCanonicalPath(FilePath); GoodFileNames.push_back(FilePath); } // List problem files. void ModularizeUtilities::displayProblemFiles() { errs() << "\nThese are the files with possible errors:\n\n"; for (auto &ProblemFile : ProblemFileNames) { errs() << ProblemFile << "\n"; } } // List files with no problems. void ModularizeUtilities::displayGoodFiles() { errs() << "\nThese are the files with no detected errors:\n\n"; for (auto &GoodFile : HeaderFileNames) { bool Good = true; for (auto &ProblemFile : ProblemFileNames) { if (ProblemFile == GoodFile) { Good = false; break; } } if (Good) errs() << GoodFile << "\n"; } } // List files with problem files commented out. void ModularizeUtilities::displayCombinedFiles() { errs() << "\nThese are the combined files, with problem files preceded by #:\n\n"; for (auto &File : HeaderFileNames) { bool Good = true; for (auto &ProblemFile : ProblemFileNames) { if (ProblemFile == File) { Good = false; break; } } errs() << (Good ? "" : "#") << File << "\n"; } }