//===--- ModuleManager.cpp - Module Manager ---------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines the ModuleManager class, which manages a set of loaded // modules for the ASTReader. // //===----------------------------------------------------------------------===// #include "clang/Lex/ModuleMap.h" #include "clang/Serialization/GlobalModuleIndex.h" #include "clang/Serialization/ModuleManager.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Support/system_error.h" #ifndef NDEBUG #include "llvm/Support/GraphWriter.h" #endif using namespace clang; using namespace serialization; ModuleFile *ModuleManager::lookup(StringRef Name) { const FileEntry *Entry = FileMgr.getFile(Name, /*openFile=*/false, /*cacheFailure=*/false); if (Entry) return lookup(Entry); return 0; } ModuleFile *ModuleManager::lookup(const FileEntry *File) { llvm::DenseMap::iterator Known = Modules.find(File); if (Known == Modules.end()) return 0; return Known->second; } llvm::MemoryBuffer *ModuleManager::lookupBuffer(StringRef Name) { const FileEntry *Entry = FileMgr.getFile(Name, /*openFile=*/false, /*cacheFailure=*/false); return InMemoryBuffers[Entry]; } ModuleManager::AddModuleResult ModuleManager::addModule(StringRef FileName, ModuleKind Type, SourceLocation ImportLoc, ModuleFile *ImportedBy, unsigned Generation, off_t ExpectedSize, time_t ExpectedModTime, ModuleFile *&Module, std::string &ErrorStr) { Module = 0; // Look for the file entry. This only fails if the expected size or // modification time differ. const FileEntry *Entry; if (lookupModuleFile(FileName, ExpectedSize, ExpectedModTime, Entry)) { ErrorStr = "module file out of date"; return OutOfDate; } if (!Entry && FileName != "-") { ErrorStr = "module file not found"; return Missing; } // Check whether we already loaded this module, before ModuleFile *&ModuleEntry = Modules[Entry]; bool NewModule = false; if (!ModuleEntry) { // Allocate a new module. ModuleFile *New = new ModuleFile(Type, Generation); New->Index = Chain.size(); New->FileName = FileName.str(); New->File = Entry; New->ImportLoc = ImportLoc; Chain.push_back(New); NewModule = true; ModuleEntry = New; // Load the contents of the module if (llvm::MemoryBuffer *Buffer = lookupBuffer(FileName)) { // The buffer was already provided for us. assert(Buffer && "Passed null buffer"); New->Buffer.reset(Buffer); } else { // Open the AST file. llvm::error_code ec; if (FileName == "-") { ec = llvm::MemoryBuffer::getSTDIN(New->Buffer); if (ec) ErrorStr = ec.message(); } else New->Buffer.reset(FileMgr.getBufferForFile(FileName, &ErrorStr)); if (!New->Buffer) return Missing; } // Initialize the stream New->StreamFile.init((const unsigned char *)New->Buffer->getBufferStart(), (const unsigned char *)New->Buffer->getBufferEnd()); } if (ImportedBy) { ModuleEntry->ImportedBy.insert(ImportedBy); ImportedBy->Imports.insert(ModuleEntry); } else { if (!ModuleEntry->DirectlyImported) ModuleEntry->ImportLoc = ImportLoc; ModuleEntry->DirectlyImported = true; } Module = ModuleEntry; return NewModule? NewlyLoaded : AlreadyLoaded; } namespace { /// \brief Predicate that checks whether a module file occurs within /// the given set. class IsInModuleFileSet : public std::unary_function { llvm::SmallPtrSet &Removed; public: IsInModuleFileSet(llvm::SmallPtrSet &Removed) : Removed(Removed) { } bool operator()(ModuleFile *MF) const { return Removed.count(MF); } }; } void ModuleManager::removeModules(ModuleIterator first, ModuleIterator last, ModuleMap *modMap) { if (first == last) return; // Collect the set of module file pointers that we'll be removing. llvm::SmallPtrSet victimSet(first, last); // Remove any references to the now-destroyed modules. IsInModuleFileSet checkInSet(victimSet); for (unsigned i = 0, n = Chain.size(); i != n; ++i) { Chain[i]->ImportedBy.remove_if(checkInSet); } // Delete the modules and erase them from the various structures. for (ModuleIterator victim = first; victim != last; ++victim) { Modules.erase((*victim)->File); FileMgr.invalidateCache((*victim)->File); if (modMap) { StringRef ModuleName = llvm::sys::path::stem((*victim)->FileName); if (Module *mod = modMap->findModule(ModuleName)) { mod->setASTFile(0); } } delete *victim; } // Remove the modules from the chain. Chain.erase(first, last); } void ModuleManager::addInMemoryBuffer(StringRef FileName, llvm::MemoryBuffer *Buffer) { const FileEntry *Entry = FileMgr.getVirtualFile(FileName, Buffer->getBufferSize(), 0); InMemoryBuffers[Entry] = Buffer; } ModuleManager::VisitState *ModuleManager::allocateVisitState() { // Fast path: if we have a cached state, use it. if (FirstVisitState) { VisitState *Result = FirstVisitState; FirstVisitState = FirstVisitState->NextState; Result->NextState = 0; return Result; } // Allocate and return a new state. return new VisitState(size()); } void ModuleManager::returnVisitState(VisitState *State) { assert(State->NextState == 0 && "Visited state is in list?"); State->NextState = FirstVisitState; FirstVisitState = State; } void ModuleManager::setGlobalIndex(GlobalModuleIndex *Index) { GlobalIndex = Index; if (!GlobalIndex) { ModulesInCommonWithGlobalIndex.clear(); return; } // Notify the global module index about all of the modules we've already // loaded. for (unsigned I = 0, N = Chain.size(); I != N; ++I) { if (!GlobalIndex->loadedModuleFile(Chain[I])) { ModulesInCommonWithGlobalIndex.push_back(Chain[I]); } } } void ModuleManager::moduleFileAccepted(ModuleFile *MF) { if (!GlobalIndex || GlobalIndex->loadedModuleFile(MF)) return; ModulesInCommonWithGlobalIndex.push_back(MF); } ModuleManager::ModuleManager(FileManager &FileMgr) : FileMgr(FileMgr), GlobalIndex(), FirstVisitState(0) { } ModuleManager::~ModuleManager() { for (unsigned i = 0, e = Chain.size(); i != e; ++i) delete Chain[e - i - 1]; delete FirstVisitState; } void ModuleManager::visit(bool (*Visitor)(ModuleFile &M, void *UserData), void *UserData, llvm::SmallPtrSet *ModuleFilesHit) { // If the visitation order vector is the wrong size, recompute the order. if (VisitOrder.size() != Chain.size()) { unsigned N = size(); VisitOrder.clear(); VisitOrder.reserve(N); // Record the number of incoming edges for each module. When we // encounter a module with no incoming edges, push it into the queue // to seed the queue. SmallVector Queue; Queue.reserve(N); llvm::SmallVector UnusedIncomingEdges; UnusedIncomingEdges.reserve(size()); for (ModuleIterator M = begin(), MEnd = end(); M != MEnd; ++M) { if (unsigned Size = (*M)->ImportedBy.size()) UnusedIncomingEdges.push_back(Size); else { UnusedIncomingEdges.push_back(0); Queue.push_back(*M); } } // Traverse the graph, making sure to visit a module before visiting any // of its dependencies. unsigned QueueStart = 0; while (QueueStart < Queue.size()) { ModuleFile *CurrentModule = Queue[QueueStart++]; VisitOrder.push_back(CurrentModule); // For any module that this module depends on, push it on the // stack (if it hasn't already been marked as visited). for (llvm::SetVector::iterator M = CurrentModule->Imports.begin(), MEnd = CurrentModule->Imports.end(); M != MEnd; ++M) { // Remove our current module as an impediment to visiting the // module we depend on. If we were the last unvisited module // that depends on this particular module, push it into the // queue to be visited. unsigned &NumUnusedEdges = UnusedIncomingEdges[(*M)->Index]; if (NumUnusedEdges && (--NumUnusedEdges == 0)) Queue.push_back(*M); } } assert(VisitOrder.size() == N && "Visitation order is wrong?"); delete FirstVisitState; FirstVisitState = 0; } VisitState *State = allocateVisitState(); unsigned VisitNumber = State->NextVisitNumber++; // If the caller has provided us with a hit-set that came from the global // module index, mark every module file in common with the global module // index that is *not* in that set as 'visited'. if (ModuleFilesHit && !ModulesInCommonWithGlobalIndex.empty()) { for (unsigned I = 0, N = ModulesInCommonWithGlobalIndex.size(); I != N; ++I) { ModuleFile *M = ModulesInCommonWithGlobalIndex[I]; if (!ModuleFilesHit->count(M)) State->VisitNumber[M->Index] = VisitNumber; } } for (unsigned I = 0, N = VisitOrder.size(); I != N; ++I) { ModuleFile *CurrentModule = VisitOrder[I]; // Should we skip this module file? if (State->VisitNumber[CurrentModule->Index] == VisitNumber) continue; // Visit the module. assert(State->VisitNumber[CurrentModule->Index] == VisitNumber - 1); State->VisitNumber[CurrentModule->Index] = VisitNumber; if (!Visitor(*CurrentModule, UserData)) continue; // The visitor has requested that cut off visitation of any // module that the current module depends on. To indicate this // behavior, we mark all of the reachable modules as having been visited. ModuleFile *NextModule = CurrentModule; do { // For any module that this module depends on, push it on the // stack (if it hasn't already been marked as visited). for (llvm::SetVector::iterator M = NextModule->Imports.begin(), MEnd = NextModule->Imports.end(); M != MEnd; ++M) { if (State->VisitNumber[(*M)->Index] != VisitNumber) { State->Stack.push_back(*M); State->VisitNumber[(*M)->Index] = VisitNumber; } } if (State->Stack.empty()) break; // Pop the next module off the stack. NextModule = State->Stack.pop_back_val(); } while (true); } returnVisitState(State); } /// \brief Perform a depth-first visit of the current module. static bool visitDepthFirst(ModuleFile &M, bool (*Visitor)(ModuleFile &M, bool Preorder, void *UserData), void *UserData, SmallVectorImpl &Visited) { // Preorder visitation if (Visitor(M, /*Preorder=*/true, UserData)) return true; // Visit children for (llvm::SetVector::iterator IM = M.Imports.begin(), IMEnd = M.Imports.end(); IM != IMEnd; ++IM) { if (Visited[(*IM)->Index]) continue; Visited[(*IM)->Index] = true; if (visitDepthFirst(**IM, Visitor, UserData, Visited)) return true; } // Postorder visitation return Visitor(M, /*Preorder=*/false, UserData); } void ModuleManager::visitDepthFirst(bool (*Visitor)(ModuleFile &M, bool Preorder, void *UserData), void *UserData) { SmallVector Visited(size(), false); for (unsigned I = 0, N = Chain.size(); I != N; ++I) { if (Visited[Chain[I]->Index]) continue; Visited[Chain[I]->Index] = true; if (::visitDepthFirst(*Chain[I], Visitor, UserData, Visited)) return; } } bool ModuleManager::lookupModuleFile(StringRef FileName, off_t ExpectedSize, time_t ExpectedModTime, const FileEntry *&File) { File = FileMgr.getFile(FileName, /*openFile=*/false, /*cacheFailure=*/false); if (!File && FileName != "-") { return false; } if ((ExpectedSize && ExpectedSize != File->getSize()) || (ExpectedModTime && ExpectedModTime != File->getModificationTime())) { return true; } return false; } #ifndef NDEBUG namespace llvm { template<> struct GraphTraits { typedef ModuleFile NodeType; typedef llvm::SetVector::const_iterator ChildIteratorType; typedef ModuleManager::ModuleConstIterator nodes_iterator; static ChildIteratorType child_begin(NodeType *Node) { return Node->Imports.begin(); } static ChildIteratorType child_end(NodeType *Node) { return Node->Imports.end(); } static nodes_iterator nodes_begin(const ModuleManager &Manager) { return Manager.begin(); } static nodes_iterator nodes_end(const ModuleManager &Manager) { return Manager.end(); } }; template<> struct DOTGraphTraits : public DefaultDOTGraphTraits { explicit DOTGraphTraits(bool IsSimple = false) : DefaultDOTGraphTraits(IsSimple) { } static bool renderGraphFromBottomUp() { return true; } std::string getNodeLabel(ModuleFile *M, const ModuleManager&) { return llvm::sys::path::stem(M->FileName); } }; } void ModuleManager::viewGraph() { llvm::ViewGraph(*this, "Modules"); } #endif