clangd/index/Background.cpp - clang-tools-extra - Git at Google

 //===-- Background.cpp - Build an index in a background thread ------------===//
 //
 // 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 "index/Background.h"
 #include "Compiler.h"
 #include "Context.h"
 #include "FSProvider.h"
 #include "Headers.h"
 #include "Logger.h"
 #include "ParsedAST.h"
 #include "Path.h"
 #include "SourceCode.h"
 #include "Symbol.h"
 #include "Threading.h"
 #include "Trace.h"
 #include "URI.h"
 #include "index/BackgroundIndexLoader.h"
 #include "index/FileIndex.h"
 #include "index/IndexAction.h"
 #include "index/MemIndex.h"
 #include "index/Ref.h"
 #include "index/Relation.h"
 #include "index/Serialization.h"
 #include "index/SymbolCollector.h"
 #include "clang/Basic/SourceLocation.h"
 #include "clang/Basic/SourceManager.h"
 #include "clang/Driver/Types.h"
 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/DenseSet.h"
 #include "llvm/ADT/Hashing.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/ScopeExit.h"
 #include "llvm/ADT/StringMap.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/ADT/StringSet.h"
 #include "llvm/Support/Error.h"
 #include "llvm/Support/Path.h"
 #include "llvm/Support/Threading.h"

 #include <algorithm>
 #include <atomic>
 #include <chrono>
 #include <condition_variable>
 #include <cstddef>
 #include <memory>
 #include <mutex>
 #include <numeric>
 #include <queue>
 #include <random>
 #include <string>
 #include <thread>
 #include <utility>
 #include <vector>

 namespace clang {
 namespace clangd {
 namespace {

 // Resolves URI to file paths with cache.
 class URIToFileCache {
 public:
   URIToFileCache(llvm::StringRef HintPath) : HintPath(HintPath) {}

   llvm::StringRef resolve(llvm::StringRef FileURI) {
     auto I = URIToPathCache.try_emplace(FileURI);
     if (I.second) {
       auto Path = URI::resolve(FileURI, HintPath);
       if (!Path) {
         elog("Failed to resolve URI {0}: {1}", FileURI, Path.takeError());
         assert(false && "Failed to resolve URI");
         return "";
       }
       I.first->second = *Path;
     }
     return I.first->second;
   }

 private:
   std::string HintPath;
   llvm::StringMap<std::string> URIToPathCache;
 };

 // We keep only the node "U" and its edges. Any node other than "U" will be
 // empty in the resultant graph.
 IncludeGraph getSubGraph(const URI &U, const IncludeGraph &FullGraph) {
   IncludeGraph IG;

   std::string FileURI = U.toString();
   auto Entry = IG.try_emplace(FileURI).first;
   auto &Node = Entry->getValue();
   Node = FullGraph.lookup(Entry->getKey());
   Node.URI = Entry->getKey();

   // URIs inside nodes must point into the keys of the same IncludeGraph.
   for (auto &Include : Node.DirectIncludes) {
     auto I = IG.try_emplace(Include).first;
     I->getValue().URI = I->getKey();
     Include = I->getKey();
   }

   return IG;
 }

 // We cannot use vfs->makeAbsolute because Cmd.FileName is either absolute or
 // relative to Cmd.Directory, which might not be the same as current working
 // directory.
 llvm::SmallString<128> getAbsolutePath(const tooling::CompileCommand &Cmd) {
   llvm::SmallString<128> AbsolutePath;
   if (llvm::sys::path::is_absolute(Cmd.Filename)) {
     AbsolutePath = Cmd.Filename;
   } else {
     AbsolutePath = Cmd.Directory;
     llvm::sys::path::append(AbsolutePath, Cmd.Filename);
     llvm::sys::path::remove_dots(AbsolutePath, true);
   }
   return AbsolutePath;
 }

 bool shardIsStale(const LoadedShard &LS, llvm::vfs::FileSystem *FS) {
   auto Buf = FS->getBufferForFile(LS.AbsolutePath);
   if (!Buf) {
     elog("Background-index: Couldn't read {0} to validate stored index: {1}",
          LS.AbsolutePath, Buf.getError().message());
     // There is no point in indexing an unreadable file.
     return false;
   }
   return digest(Buf->get()->getBuffer()) != LS.Digest;
 }

 } // namespace

 BackgroundIndex::BackgroundIndex(
     Context BackgroundContext, const FileSystemProvider &FSProvider,
     const GlobalCompilationDatabase &CDB,
     BackgroundIndexStorage::Factory IndexStorageFactory, size_t ThreadPoolSize)
     : SwapIndex(std::make_unique<MemIndex>()), FSProvider(FSProvider),
       CDB(CDB), BackgroundContext(std::move(BackgroundContext)),
       Rebuilder(this, &IndexedSymbols, ThreadPoolSize),
       IndexStorageFactory(std::move(IndexStorageFactory)),
       CommandsChanged(
           CDB.watch([&](const std::vector<std::string> &ChangedFiles) {
             enqueue(ChangedFiles);
           })) {
   assert(ThreadPoolSize > 0 && "Thread pool size can't be zero.");
   assert(this->IndexStorageFactory && "Storage factory can not be null!");
   for (unsigned I = 0; I < ThreadPoolSize; ++I) {
     ThreadPool.runAsync("background-worker-" + llvm::Twine(I + 1), [this] {
       WithContext Ctx(this->BackgroundContext.clone());
       Queue.work([&] { Rebuilder.idle(); });
     });
   }
 }

 BackgroundIndex::~BackgroundIndex() {
   stop();
   ThreadPool.wait();
 }

 BackgroundQueue::Task BackgroundIndex::changedFilesTask(
     const std::vector<std::string> &ChangedFiles) {
   BackgroundQueue::Task T([this, ChangedFiles] {
     trace::Span Tracer("BackgroundIndexEnqueue");
     // We're doing this asynchronously, because we'll read shards here too.
     log("Enqueueing {0} commands for indexing", ChangedFiles.size());
     SPAN_ATTACH(Tracer, "files", int64_t(ChangedFiles.size()));

     auto NeedsReIndexing = loadProject(std::move(ChangedFiles));
     // Run indexing for files that need to be updated.
     std::shuffle(NeedsReIndexing.begin(), NeedsReIndexing.end(),
                  std::mt19937(std::random_device{}()));
     std::vector<BackgroundQueue::Task> Tasks;
     Tasks.reserve(NeedsReIndexing.size());
     for (auto &Cmd : NeedsReIndexing)
       Tasks.push_back(indexFileTask(std::move(Cmd)));
     Queue.append(std::move(Tasks));
   });

   T.QueuePri = LoadShards;
   T.ThreadPri = llvm::ThreadPriority::Default;
   return T;
 }

 static llvm::StringRef filenameWithoutExtension(llvm::StringRef Path) {
   Path = llvm::sys::path::filename(Path);
   return Path.drop_back(llvm::sys::path::extension(Path).size());
 }

 BackgroundQueue::Task
 BackgroundIndex::indexFileTask(tooling::CompileCommand Cmd) {
   BackgroundQueue::Task T([this, Cmd] {
     // We can't use llvm::StringRef here since we are going to
     // move from Cmd during the call below.
     const std::string FileName = Cmd.Filename;
     if (auto Error = index(std::move(Cmd)))
       elog("Indexing {0} failed: {1}", FileName, std::move(Error));
   });
   T.QueuePri = IndexFile;
   T.Tag = filenameWithoutExtension(Cmd.Filename);
   return T;
 }

 void BackgroundIndex::boostRelated(llvm::StringRef Path) {
   namespace types = clang::driver::types;
   auto Type =
       types::lookupTypeForExtension(llvm::sys::path::extension(Path).substr(1));
   // is this a header?
   if (Type != types::TY_INVALID && types::onlyPrecompileType(Type))
     Queue.boost(filenameWithoutExtension(Path), IndexBoostedFile);
 }

 /// Given index results from a TU, only update symbols coming from files that
 /// are different or missing from than \p ShardVersionsSnapshot. Also stores new
 /// index information on IndexStorage.
 void BackgroundIndex::update(
     llvm::StringRef MainFile, IndexFileIn Index,
     const llvm::StringMap<ShardVersion> &ShardVersionsSnapshot,
     bool HadErrors) {
   // Partition symbols/references into files.
   struct File {
     llvm::DenseSet<const Symbol *> Symbols;
     llvm::DenseSet<const Ref *> Refs;
     llvm::DenseSet<const Relation *> Relations;
     FileDigest Digest;
   };
   llvm::StringMap<File> Files;
   URIToFileCache URICache(MainFile);
   for (const auto &IndexIt : *Index.Sources) {
     const auto &IGN = IndexIt.getValue();
     // Note that sources do not contain any information regarding missing
     // headers, since we don't even know what absolute path they should fall in.
     const auto AbsPath = URICache.resolve(IGN.URI);
     const auto DigestIt = ShardVersionsSnapshot.find(AbsPath);
     // File has different contents, or indexing was successfull this time.
     if (DigestIt == ShardVersionsSnapshot.end() ||
         DigestIt->getValue().Digest != IGN.Digest ||
         (DigestIt->getValue().HadErrors && !HadErrors))
       Files.try_emplace(AbsPath).first->getValue().Digest = IGN.Digest;
   }
   // This map is used to figure out where to store relations.
   llvm::DenseMap<SymbolID, File *> SymbolIDToFile;
   for (const auto &Sym : *Index.Symbols) {
     if (Sym.CanonicalDeclaration) {
       auto DeclPath = URICache.resolve(Sym.CanonicalDeclaration.FileURI);
       const auto FileIt = Files.find(DeclPath);
       if (FileIt != Files.end()) {
         FileIt->second.Symbols.insert(&Sym);
         SymbolIDToFile[Sym.ID] = &FileIt->second;
       }
     }
     // For symbols with different declaration and definition locations, we store
     // the full symbol in both the header file and the implementation file, so
     // that merging can tell the preferred symbols (from canonical headers) from
     // other symbols (e.g. forward declarations).
     if (Sym.Definition &&
         Sym.Definition.FileURI != Sym.CanonicalDeclaration.FileURI) {
       auto DefPath = URICache.resolve(Sym.Definition.FileURI);
       const auto FileIt = Files.find(DefPath);
       if (FileIt != Files.end())
         FileIt->second.Symbols.insert(&Sym);
     }
   }
   llvm::DenseMap<const Ref *, SymbolID> RefToIDs;
   for (const auto &SymRefs : *Index.Refs) {
     for (const auto &R : SymRefs.second) {
       auto Path = URICache.resolve(R.Location.FileURI);
       const auto FileIt = Files.find(Path);
       if (FileIt != Files.end()) {
         auto &F = FileIt->getValue();
         RefToIDs[&R] = SymRefs.first;
         F.Refs.insert(&R);
       }
     }
   }
   for (const auto &Rel : *Index.Relations) {
     const auto FileIt = SymbolIDToFile.find(Rel.Subject);
     if (FileIt != SymbolIDToFile.end())
       FileIt->second->Relations.insert(&Rel);
   }

   // Build and store new slabs for each updated file.
   for (const auto &FileIt : Files) {
     llvm::StringRef Path = FileIt.getKey();
     SymbolSlab::Builder Syms;
     RefSlab::Builder Refs;
     RelationSlab::Builder Relations;
     for (const auto *S : FileIt.second.Symbols)
       Syms.insert(*S);
     for (const auto *R : FileIt.second.Refs)
       Refs.insert(RefToIDs[R], *R);
     for (const auto *Rel : FileIt.second.Relations)
       Relations.insert(*Rel);
     auto SS = std::make_unique<SymbolSlab>(std::move(Syms).build());
     auto RS = std::make_unique<RefSlab>(std::move(Refs).build());
     auto RelS = std::make_unique<RelationSlab>(std::move(Relations).build());
     auto IG = std::make_unique<IncludeGraph>(
         getSubGraph(URI::create(Path), Index.Sources.getValue()));

     // We need to store shards before updating the index, since the latter
     // consumes slabs.
     // FIXME: Also skip serializing the shard if it is already up-to-date.
     BackgroundIndexStorage *IndexStorage = IndexStorageFactory(Path);
     IndexFileOut Shard;
     Shard.Symbols = SS.get();
     Shard.Refs = RS.get();
     Shard.Relations = RelS.get();
     Shard.Sources = IG.get();

     // Only store command line hash for main files of the TU, since our
     // current model keeps only one version of a header file.
     if (Path == MainFile)
       Shard.Cmd = Index.Cmd.getPointer();

     if (auto Error = IndexStorage->storeShard(Path, Shard))
       elog("Failed to write background-index shard for file {0}: {1}", Path,
            std::move(Error));

     {
       std::lock_guard<std::mutex> Lock(ShardVersionsMu);
       auto Hash = FileIt.second.Digest;
       auto DigestIt = ShardVersions.try_emplace(Path);
       ShardVersion &SV = DigestIt.first->second;
       // Skip if file is already up to date, unless previous index was broken
       // and this one is not.
       if (!DigestIt.second && SV.Digest == Hash && SV.HadErrors && !HadErrors)
         continue;
       SV.Digest = Hash;
       SV.HadErrors = HadErrors;

       // This can override a newer version that is added in another thread, if
       // this thread sees the older version but finishes later. This should be
       // rare in practice.
       IndexedSymbols.update(Path, std::move(SS), std::move(RS), std::move(RelS),
                             Path == MainFile);
     }
   }
 }

 llvm::Error BackgroundIndex::index(tooling::CompileCommand Cmd) {
   trace::Span Tracer("BackgroundIndex");
   SPAN_ATTACH(Tracer, "file", Cmd.Filename);
   auto AbsolutePath = getAbsolutePath(Cmd);

   auto FS = FSProvider.getFileSystem();
   auto Buf = FS->getBufferForFile(AbsolutePath);
   if (!Buf)
     return llvm::errorCodeToError(Buf.getError());
   auto Hash = digest(Buf->get()->getBuffer());

   // Take a snapshot of the versions to avoid locking for each file in the TU.
   llvm::StringMap<ShardVersion> ShardVersionsSnapshot;
   {
     std::lock_guard<std::mutex> Lock(ShardVersionsMu);
     ShardVersionsSnapshot = ShardVersions;
   }

   vlog("Indexing {0} (digest:={1})", Cmd.Filename, llvm::toHex(Hash));
   ParseInputs Inputs;
   Inputs.FS = std::move(FS);
   Inputs.FS->setCurrentWorkingDirectory(Cmd.Directory);
   Inputs.CompileCommand = std::move(Cmd);
   IgnoreDiagnostics IgnoreDiags;
   auto CI = buildCompilerInvocation(Inputs, IgnoreDiags);
   if (!CI)
     return llvm::createStringError(llvm::inconvertibleErrorCode(),
                                    "Couldn't build compiler invocation");
   auto Clang = prepareCompilerInstance(std::move(CI), /*Preamble=*/nullptr,
                                        std::move(*Buf), Inputs.FS, IgnoreDiags);
   if (!Clang)
     return llvm::createStringError(llvm::inconvertibleErrorCode(),
                                    "Couldn't build compiler instance");

   SymbolCollector::Options IndexOpts;
   // Creates a filter to not collect index results from files with unchanged
   // digests.
   IndexOpts.FileFilter = [&ShardVersionsSnapshot](const SourceManager &SM,
                                                   FileID FID) {
     const auto *F = SM.getFileEntryForID(FID);
     if (!F)
       return false; // Skip invalid files.
     auto AbsPath = getCanonicalPath(F, SM);
     if (!AbsPath)
       return false; // Skip files without absolute path.
     auto Digest = digestFile(SM, FID);
     if (!Digest)
       return false;
     auto D = ShardVersionsSnapshot.find(*AbsPath);
     if (D != ShardVersionsSnapshot.end() && D->second.Digest == Digest &&
         !D->second.HadErrors)
       return false; // Skip files that haven't changed, without errors.
     return true;
   };

   IndexFileIn Index;
   auto Action = createStaticIndexingAction(
       IndexOpts, [&](SymbolSlab S) { Index.Symbols = std::move(S); },
       [&](RefSlab R) { Index.Refs = std::move(R); },
       [&](RelationSlab R) { Index.Relations = std::move(R); },
       [&](IncludeGraph IG) { Index.Sources = std::move(IG); });

   // We're going to run clang here, and it could potentially crash.
   // We could use CrashRecoveryContext to try to make indexing crashes nonfatal,
   // but the leaky "recovery" is pretty scary too in a long-running process.
   // If crashes are a real problem, maybe we should fork a child process.

   const FrontendInputFile &Input = Clang->getFrontendOpts().Inputs.front();
   if (!Action->BeginSourceFile(*Clang, Input))
     return llvm::createStringError(llvm::inconvertibleErrorCode(),
                                    "BeginSourceFile() failed");
   if (llvm::Error Err = Action->Execute())
     return Err;

   Action->EndSourceFile();

   Index.Cmd = Inputs.CompileCommand;
   assert(Index.Symbols && Index.Refs && Index.Sources &&
          "Symbols, Refs and Sources must be set.");

   log("Indexed {0} ({1} symbols, {2} refs, {3} files)",
       Inputs.CompileCommand.Filename, Index.Symbols->size(),
       Index.Refs->numRefs(), Index.Sources->size());
   SPAN_ATTACH(Tracer, "symbols", int(Index.Symbols->size()));
   SPAN_ATTACH(Tracer, "refs", int(Index.Refs->numRefs()));
   SPAN_ATTACH(Tracer, "sources", int(Index.Sources->size()));

   bool HadErrors = Clang->hasDiagnostics() &&
                    Clang->getDiagnostics().hasUncompilableErrorOccurred();
   if (HadErrors) {
     log("Failed to compile {0}, index may be incomplete", AbsolutePath);
     for (auto &It : *Index.Sources)
       It.second.Flags |= IncludeGraphNode::SourceFlag::HadErrors;
   }
   update(AbsolutePath, std::move(Index), ShardVersionsSnapshot, HadErrors);

   Rebuilder.indexedTU();
   return llvm::Error::success();
 }

 // Restores shards for \p MainFiles from index storage. Then checks staleness of
 // those shards and returns a list of TUs that needs to be indexed to update
 // staleness.
 std::vector<tooling::CompileCommand>
 BackgroundIndex::loadProject(std::vector<std::string> MainFiles) {
   std::vector<tooling::CompileCommand> NeedsReIndexing;

   Rebuilder.startLoading();
   // Load shards for all of the mainfiles.
   const std::vector<LoadedShard> Result =
       loadIndexShards(MainFiles, IndexStorageFactory, CDB);
   size_t LoadedShards = 0;
   {
     // Update in-memory state.
     std::lock_guard<std::mutex> Lock(ShardVersionsMu);
     for (auto &LS : Result) {
       if (!LS.Shard)
         continue;
       auto SS =
           LS.Shard->Symbols
               ? std::make_unique<SymbolSlab>(std::move(*LS.Shard->Symbols))
               : nullptr;
       auto RS = LS.Shard->Refs
                     ? std::make_unique<RefSlab>(std::move(*LS.Shard->Refs))
                     : nullptr;
       auto RelS =
           LS.Shard->Relations
               ? std::make_unique<RelationSlab>(std::move(*LS.Shard->Relations))
               : nullptr;
       ShardVersion &SV = ShardVersions[LS.AbsolutePath];
       SV.Digest = LS.Digest;
       SV.HadErrors = LS.HadErrors;
       ++LoadedShards;

       IndexedSymbols.update(LS.AbsolutePath, std::move(SS), std::move(RS),
                             std::move(RelS), LS.CountReferences);
     }
   }
   Rebuilder.loadedShard(LoadedShards);
   Rebuilder.doneLoading();

   auto FS = FSProvider.getFileSystem();
   llvm::DenseSet<PathRef> TUsToIndex;
   // We'll accept data from stale shards, but ensure the files get reindexed
   // soon.
   for (auto &LS : Result) {
     if (!shardIsStale(LS, FS.get()))
       continue;
     PathRef TUForFile = LS.DependentTU;
     assert(!TUForFile.empty() && "File without a TU!");

     // FIXME: Currently, we simply schedule indexing on a TU whenever any of
     // its dependencies needs re-indexing. We might do it smarter by figuring
     // out a minimal set of TUs that will cover all the stale dependencies.
     // FIXME: Try looking at other TUs if no compile commands are available
     // for this TU, i.e TU was deleted after we performed indexing.
     TUsToIndex.insert(TUForFile);
   }

   for (PathRef TU : TUsToIndex) {
     auto Cmd = CDB.getCompileCommand(TU);
     if (!Cmd)
       continue;
     NeedsReIndexing.emplace_back(std::move(*Cmd));
   }

   return NeedsReIndexing;
 }

 } // namespace clangd
 } // namespace clang
	//===-- Background.cpp - Build an index in a background thread ------------===//
	//
	// 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 "index/Background.h"
	#include "Compiler.h"
	#include "Context.h"
	#include "FSProvider.h"
	#include "Headers.h"
	#include "Logger.h"
	#include "ParsedAST.h"
	#include "Path.h"
	#include "SourceCode.h"
	#include "Symbol.h"
	#include "Threading.h"
	#include "Trace.h"
	#include "URI.h"
	#include "index/BackgroundIndexLoader.h"
	#include "index/FileIndex.h"
	#include "index/IndexAction.h"
	#include "index/MemIndex.h"
	#include "index/Ref.h"
	#include "index/Relation.h"
	#include "index/Serialization.h"
	#include "index/SymbolCollector.h"
	#include "clang/Basic/SourceLocation.h"
	#include "clang/Basic/SourceManager.h"
	#include "clang/Driver/Types.h"
	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/DenseSet.h"
	#include "llvm/ADT/Hashing.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/ScopeExit.h"
	#include "llvm/ADT/StringMap.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/ADT/StringSet.h"
	#include "llvm/Support/Error.h"
	#include "llvm/Support/Path.h"
	#include "llvm/Support/Threading.h"

	#include <algorithm>
	#include <atomic>
	#include <chrono>
	#include <condition_variable>
	#include <cstddef>
	#include <memory>
	#include <mutex>
	#include <numeric>
	#include <queue>
	#include <random>
	#include <string>
	#include <thread>
	#include <utility>
	#include <vector>

	namespace clang {
	namespace clangd {
	namespace {

	// Resolves URI to file paths with cache.
	class URIToFileCache {
	public:
	URIToFileCache(llvm::StringRef HintPath) : HintPath(HintPath) {}

	llvm::StringRef resolve(llvm::StringRef FileURI) {
	auto I = URIToPathCache.try_emplace(FileURI);
	if (I.second) {
	auto Path = URI::resolve(FileURI, HintPath);
	if (!Path) {
	elog("Failed to resolve URI {0}: {1}", FileURI, Path.takeError());
	assert(false && "Failed to resolve URI");
	return "";
	}
	I.first->second = *Path;
	}
	return I.first->second;
	}

	private:
	std::string HintPath;
	llvm::StringMap<std::string> URIToPathCache;
	};

	// We keep only the node "U" and its edges. Any node other than "U" will be
	// empty in the resultant graph.
	IncludeGraph getSubGraph(const URI &U, const IncludeGraph &FullGraph) {
	IncludeGraph IG;

	std::string FileURI = U.toString();
	auto Entry = IG.try_emplace(FileURI).first;
	auto &Node = Entry->getValue();
	Node = FullGraph.lookup(Entry->getKey());
	Node.URI = Entry->getKey();

	// URIs inside nodes must point into the keys of the same IncludeGraph.
	for (auto &Include : Node.DirectIncludes) {
	auto I = IG.try_emplace(Include).first;
	I->getValue().URI = I->getKey();
	Include = I->getKey();
	}

	return IG;
	}

	// We cannot use vfs->makeAbsolute because Cmd.FileName is either absolute or
	// relative to Cmd.Directory, which might not be the same as current working
	// directory.
	llvm::SmallString<128> getAbsolutePath(const tooling::CompileCommand &Cmd) {
	llvm::SmallString<128> AbsolutePath;
	if (llvm::sys::path::is_absolute(Cmd.Filename)) {
	AbsolutePath = Cmd.Filename;
	} else {
	AbsolutePath = Cmd.Directory;
	llvm::sys::path::append(AbsolutePath, Cmd.Filename);
	llvm::sys::path::remove_dots(AbsolutePath, true);
	}
	return AbsolutePath;
	}

	bool shardIsStale(const LoadedShard &LS, llvm::vfs::FileSystem *FS) {
	auto Buf = FS->getBufferForFile(LS.AbsolutePath);
	if (!Buf) {
	elog("Background-index: Couldn't read {0} to validate stored index: {1}",
	LS.AbsolutePath, Buf.getError().message());
	// There is no point in indexing an unreadable file.
	return false;
	}
	return digest(Buf->get()->getBuffer()) != LS.Digest;
	}

	} // namespace

	BackgroundIndex::BackgroundIndex(
	Context BackgroundContext, const FileSystemProvider &FSProvider,
	const GlobalCompilationDatabase &CDB,
	BackgroundIndexStorage::Factory IndexStorageFactory, size_t ThreadPoolSize)
	: SwapIndex(std::make_unique<MemIndex>()), FSProvider(FSProvider),
	CDB(CDB), BackgroundContext(std::move(BackgroundContext)),
	Rebuilder(this, &IndexedSymbols, ThreadPoolSize),
	IndexStorageFactory(std::move(IndexStorageFactory)),
	CommandsChanged(
	CDB.watch([&](const std::vector<std::string> &ChangedFiles) {
	enqueue(ChangedFiles);
	})) {
	assert(ThreadPoolSize > 0 && "Thread pool size can't be zero.");
	assert(this->IndexStorageFactory && "Storage factory can not be null!");
	for (unsigned I = 0; I < ThreadPoolSize; ++I) {
	ThreadPool.runAsync("background-worker-" + llvm::Twine(I + 1), [this] {
	WithContext Ctx(this->BackgroundContext.clone());
	Queue.work([&] { Rebuilder.idle(); });
	});
	}
	}

	BackgroundIndex::~BackgroundIndex() {
	stop();
	ThreadPool.wait();
	}

	BackgroundQueue::Task BackgroundIndex::changedFilesTask(
	const std::vector<std::string> &ChangedFiles) {
	BackgroundQueue::Task T([this, ChangedFiles] {
	trace::Span Tracer("BackgroundIndexEnqueue");
	// We're doing this asynchronously, because we'll read shards here too.
	log("Enqueueing {0} commands for indexing", ChangedFiles.size());
	SPAN_ATTACH(Tracer, "files", int64_t(ChangedFiles.size()));

	auto NeedsReIndexing = loadProject(std::move(ChangedFiles));
	// Run indexing for files that need to be updated.
	std::shuffle(NeedsReIndexing.begin(), NeedsReIndexing.end(),
	std::mt19937(std::random_device{}()));
	std::vector<BackgroundQueue::Task> Tasks;
	Tasks.reserve(NeedsReIndexing.size());
	for (auto &Cmd : NeedsReIndexing)
	Tasks.push_back(indexFileTask(std::move(Cmd)));
	Queue.append(std::move(Tasks));
	});

	T.QueuePri = LoadShards;
	T.ThreadPri = llvm::ThreadPriority::Default;
	return T;
	}

	static llvm::StringRef filenameWithoutExtension(llvm::StringRef Path) {
	Path = llvm::sys::path::filename(Path);
	return Path.drop_back(llvm::sys::path::extension(Path).size());
	}

	BackgroundQueue::Task
	BackgroundIndex::indexFileTask(tooling::CompileCommand Cmd) {
	BackgroundQueue::Task T([this, Cmd] {
	// We can't use llvm::StringRef here since we are going to
	// move from Cmd during the call below.
	const std::string FileName = Cmd.Filename;
	if (auto Error = index(std::move(Cmd)))
	elog("Indexing {0} failed: {1}", FileName, std::move(Error));
	});
	T.QueuePri = IndexFile;
	T.Tag = filenameWithoutExtension(Cmd.Filename);
	return T;
	}

	void BackgroundIndex::boostRelated(llvm::StringRef Path) {
	namespace types = clang::driver::types;
	auto Type =
	types::lookupTypeForExtension(llvm::sys::path::extension(Path).substr(1));
	// is this a header?
	if (Type != types::TY_INVALID && types::onlyPrecompileType(Type))
	Queue.boost(filenameWithoutExtension(Path), IndexBoostedFile);
	}

	/// Given index results from a TU, only update symbols coming from files that
	/// are different or missing from than \p ShardVersionsSnapshot. Also stores new
	/// index information on IndexStorage.
	void BackgroundIndex::update(
	llvm::StringRef MainFile, IndexFileIn Index,
	const llvm::StringMap<ShardVersion> &ShardVersionsSnapshot,
	bool HadErrors) {
	// Partition symbols/references into files.
	struct File {
	llvm::DenseSet<const Symbol *> Symbols;
	llvm::DenseSet<const Ref *> Refs;
	llvm::DenseSet<const Relation *> Relations;
	FileDigest Digest;
	};
	llvm::StringMap<File> Files;
	URIToFileCache URICache(MainFile);
	for (const auto &IndexIt : *Index.Sources) {
	const auto &IGN = IndexIt.getValue();
	// Note that sources do not contain any information regarding missing
	// headers, since we don't even know what absolute path they should fall in.
	const auto AbsPath = URICache.resolve(IGN.URI);
	const auto DigestIt = ShardVersionsSnapshot.find(AbsPath);
	// File has different contents, or indexing was successfull this time.
	if (DigestIt == ShardVersionsSnapshot.end() \|\|
	DigestIt->getValue().Digest != IGN.Digest \|\|
	(DigestIt->getValue().HadErrors && !HadErrors))
	Files.try_emplace(AbsPath).first->getValue().Digest = IGN.Digest;
	}
	// This map is used to figure out where to store relations.
	llvm::DenseMap<SymbolID, File *> SymbolIDToFile;
	for (const auto &Sym : *Index.Symbols) {
	if (Sym.CanonicalDeclaration) {
	auto DeclPath = URICache.resolve(Sym.CanonicalDeclaration.FileURI);
	const auto FileIt = Files.find(DeclPath);
	if (FileIt != Files.end()) {
	FileIt->second.Symbols.insert(&Sym);
	SymbolIDToFile[Sym.ID] = &FileIt->second;
	}
	}
	// For symbols with different declaration and definition locations, we store
	// the full symbol in both the header file and the implementation file, so
	// that merging can tell the preferred symbols (from canonical headers) from
	// other symbols (e.g. forward declarations).
	if (Sym.Definition &&
	Sym.Definition.FileURI != Sym.CanonicalDeclaration.FileURI) {
	auto DefPath = URICache.resolve(Sym.Definition.FileURI);
	const auto FileIt = Files.find(DefPath);
	if (FileIt != Files.end())
	FileIt->second.Symbols.insert(&Sym);
	}
	}
	llvm::DenseMap<const Ref *, SymbolID> RefToIDs;
	for (const auto &SymRefs : *Index.Refs) {
	for (const auto &R : SymRefs.second) {
	auto Path = URICache.resolve(R.Location.FileURI);
	const auto FileIt = Files.find(Path);
	if (FileIt != Files.end()) {
	auto &F = FileIt->getValue();
	RefToIDs[&R] = SymRefs.first;
	F.Refs.insert(&R);
	}
	}
	}
	for (const auto &Rel : *Index.Relations) {
	const auto FileIt = SymbolIDToFile.find(Rel.Subject);
	if (FileIt != SymbolIDToFile.end())
	FileIt->second->Relations.insert(&Rel);
	}

	// Build and store new slabs for each updated file.
	for (const auto &FileIt : Files) {
	llvm::StringRef Path = FileIt.getKey();
	SymbolSlab::Builder Syms;
	RefSlab::Builder Refs;
	RelationSlab::Builder Relations;
	for (const auto *S : FileIt.second.Symbols)
	Syms.insert(*S);
	for (const auto *R : FileIt.second.Refs)
	Refs.insert(RefToIDs[R], *R);
	for (const auto *Rel : FileIt.second.Relations)
	Relations.insert(*Rel);
	auto SS = std::make_unique<SymbolSlab>(std::move(Syms).build());
	auto RS = std::make_unique<RefSlab>(std::move(Refs).build());
	auto RelS = std::make_unique<RelationSlab>(std::move(Relations).build());
	auto IG = std::make_unique<IncludeGraph>(
	getSubGraph(URI::create(Path), Index.Sources.getValue()));

	// We need to store shards before updating the index, since the latter
	// consumes slabs.
	// FIXME: Also skip serializing the shard if it is already up-to-date.
	BackgroundIndexStorage *IndexStorage = IndexStorageFactory(Path);
	IndexFileOut Shard;
	Shard.Symbols = SS.get();
	Shard.Refs = RS.get();
	Shard.Relations = RelS.get();
	Shard.Sources = IG.get();

	// Only store command line hash for main files of the TU, since our
	// current model keeps only one version of a header file.
	if (Path == MainFile)
	Shard.Cmd = Index.Cmd.getPointer();

	if (auto Error = IndexStorage->storeShard(Path, Shard))
	elog("Failed to write background-index shard for file {0}: {1}", Path,
	std::move(Error));

	{
	std::lock_guard<std::mutex> Lock(ShardVersionsMu);
	auto Hash = FileIt.second.Digest;
	auto DigestIt = ShardVersions.try_emplace(Path);
	ShardVersion &SV = DigestIt.first->second;
	// Skip if file is already up to date, unless previous index was broken
	// and this one is not.
	if (!DigestIt.second && SV.Digest == Hash && SV.HadErrors && !HadErrors)
	continue;
	SV.Digest = Hash;
	SV.HadErrors = HadErrors;

	// This can override a newer version that is added in another thread, if
	// this thread sees the older version but finishes later. This should be
	// rare in practice.
	IndexedSymbols.update(Path, std::move(SS), std::move(RS), std::move(RelS),
	Path == MainFile);
	}
	}
	}

	llvm::Error BackgroundIndex::index(tooling::CompileCommand Cmd) {
	trace::Span Tracer("BackgroundIndex");
	SPAN_ATTACH(Tracer, "file", Cmd.Filename);
	auto AbsolutePath = getAbsolutePath(Cmd);

	auto FS = FSProvider.getFileSystem();
	auto Buf = FS->getBufferForFile(AbsolutePath);
	if (!Buf)
	return llvm::errorCodeToError(Buf.getError());
	auto Hash = digest(Buf->get()->getBuffer());

	// Take a snapshot of the versions to avoid locking for each file in the TU.
	llvm::StringMap<ShardVersion> ShardVersionsSnapshot;
	{
	std::lock_guard<std::mutex> Lock(ShardVersionsMu);
	ShardVersionsSnapshot = ShardVersions;
	}

	vlog("Indexing {0} (digest:={1})", Cmd.Filename, llvm::toHex(Hash));
	ParseInputs Inputs;
	Inputs.FS = std::move(FS);
	Inputs.FS->setCurrentWorkingDirectory(Cmd.Directory);
	Inputs.CompileCommand = std::move(Cmd);
	IgnoreDiagnostics IgnoreDiags;
	auto CI = buildCompilerInvocation(Inputs, IgnoreDiags);
	if (!CI)
	return llvm::createStringError(llvm::inconvertibleErrorCode(),
	"Couldn't build compiler invocation");
	auto Clang = prepareCompilerInstance(std::move(CI), /Preamble=/nullptr,
	std::move(*Buf), Inputs.FS, IgnoreDiags);
	if (!Clang)
	return llvm::createStringError(llvm::inconvertibleErrorCode(),
	"Couldn't build compiler instance");

	SymbolCollector::Options IndexOpts;
	// Creates a filter to not collect index results from files with unchanged
	// digests.
	IndexOpts.FileFilter = [&ShardVersionsSnapshot](const SourceManager &SM,
	FileID FID) {
	const auto *F = SM.getFileEntryForID(FID);
	if (!F)
	return false; // Skip invalid files.
	auto AbsPath = getCanonicalPath(F, SM);
	if (!AbsPath)
	return false; // Skip files without absolute path.
	auto Digest = digestFile(SM, FID);
	if (!Digest)
	return false;
	auto D = ShardVersionsSnapshot.find(*AbsPath);
	if (D != ShardVersionsSnapshot.end() && D->second.Digest == Digest &&
	!D->second.HadErrors)
	return false; // Skip files that haven't changed, without errors.
	return true;
	};

	IndexFileIn Index;
	auto Action = createStaticIndexingAction(
	IndexOpts, [&](SymbolSlab S) { Index.Symbols = std::move(S); },
	[&](RefSlab R) { Index.Refs = std::move(R); },
	[&](RelationSlab R) { Index.Relations = std::move(R); },
	[&](IncludeGraph IG) { Index.Sources = std::move(IG); });

	// We're going to run clang here, and it could potentially crash.
	// We could use CrashRecoveryContext to try to make indexing crashes nonfatal,
	// but the leaky "recovery" is pretty scary too in a long-running process.
	// If crashes are a real problem, maybe we should fork a child process.

	const FrontendInputFile &Input = Clang->getFrontendOpts().Inputs.front();
	if (!Action->BeginSourceFile(*Clang, Input))
	return llvm::createStringError(llvm::inconvertibleErrorCode(),
	"BeginSourceFile() failed");
	if (llvm::Error Err = Action->Execute())
	return Err;

	Action->EndSourceFile();

	Index.Cmd = Inputs.CompileCommand;
	assert(Index.Symbols && Index.Refs && Index.Sources &&
	"Symbols, Refs and Sources must be set.");

	log("Indexed {0} ({1} symbols, {2} refs, {3} files)",
	Inputs.CompileCommand.Filename, Index.Symbols->size(),
	Index.Refs->numRefs(), Index.Sources->size());
	SPAN_ATTACH(Tracer, "symbols", int(Index.Symbols->size()));
	SPAN_ATTACH(Tracer, "refs", int(Index.Refs->numRefs()));
	SPAN_ATTACH(Tracer, "sources", int(Index.Sources->size()));

	bool HadErrors = Clang->hasDiagnostics() &&
	Clang->getDiagnostics().hasUncompilableErrorOccurred();
	if (HadErrors) {
	log("Failed to compile {0}, index may be incomplete", AbsolutePath);
	for (auto &It : *Index.Sources)
	It.second.Flags \|= IncludeGraphNode::SourceFlag::HadErrors;
	}
	update(AbsolutePath, std::move(Index), ShardVersionsSnapshot, HadErrors);

	Rebuilder.indexedTU();
	return llvm::Error::success();
	}

	// Restores shards for \p MainFiles from index storage. Then checks staleness of
	// those shards and returns a list of TUs that needs to be indexed to update
	// staleness.
	std::vector<tooling::CompileCommand>
	BackgroundIndex::loadProject(std::vector<std::string> MainFiles) {
	std::vector<tooling::CompileCommand> NeedsReIndexing;

	Rebuilder.startLoading();
	// Load shards for all of the mainfiles.
	const std::vector<LoadedShard> Result =
	loadIndexShards(MainFiles, IndexStorageFactory, CDB);
	size_t LoadedShards = 0;
	{
	// Update in-memory state.
	std::lock_guard<std::mutex> Lock(ShardVersionsMu);
	for (auto &LS : Result) {
	if (!LS.Shard)
	continue;
	auto SS =
	LS.Shard->Symbols
	? std::make_unique<SymbolSlab>(std::move(*LS.Shard->Symbols))
	: nullptr;
	auto RS = LS.Shard->Refs
	? std::make_unique<RefSlab>(std::move(*LS.Shard->Refs))
	: nullptr;
	auto RelS =
	LS.Shard->Relations
	? std::make_unique<RelationSlab>(std::move(*LS.Shard->Relations))
	: nullptr;
	ShardVersion &SV = ShardVersions[LS.AbsolutePath];
	SV.Digest = LS.Digest;
	SV.HadErrors = LS.HadErrors;
	++LoadedShards;

	IndexedSymbols.update(LS.AbsolutePath, std::move(SS), std::move(RS),
	std::move(RelS), LS.CountReferences);
	}
	}
	Rebuilder.loadedShard(LoadedShards);
	Rebuilder.doneLoading();

	auto FS = FSProvider.getFileSystem();
	llvm::DenseSet<PathRef> TUsToIndex;
	// We'll accept data from stale shards, but ensure the files get reindexed
	// soon.
	for (auto &LS : Result) {
	if (!shardIsStale(LS, FS.get()))
	continue;
	PathRef TUForFile = LS.DependentTU;
	assert(!TUForFile.empty() && "File without a TU!");

	// FIXME: Currently, we simply schedule indexing on a TU whenever any of
	// its dependencies needs re-indexing. We might do it smarter by figuring
	// out a minimal set of TUs that will cover all the stale dependencies.
	// FIXME: Try looking at other TUs if no compile commands are available
	// for this TU, i.e TU was deleted after we performed indexing.
	TUsToIndex.insert(TUForFile);
	}

	for (PathRef TU : TUsToIndex) {
	auto Cmd = CDB.getCompileCommand(TU);
	if (!Cmd)
	continue;
	NeedsReIndexing.emplace_back(std::move(*Cmd));
	}

	return NeedsReIndexing;
	}

	} // namespace clangd
	} // namespace clang