/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "mozilla/dom/cache/Manager.h" #include "mozilla/AppShutdown.h" #include "mozilla/AutoRestore.h" #include "mozilla/Mutex.h" #include "mozilla/StaticMutex.h" #include "mozilla/StaticPtr.h" #include "mozilla/Unused.h" #include "mozilla/dom/cache/Context.h" #include "mozilla/dom/cache/DBAction.h" #include "mozilla/dom/cache/DBSchema.h" #include "mozilla/dom/cache/FileUtils.h" #include "mozilla/dom/cache/ManagerId.h" #include "mozilla/dom/cache/CacheTypes.h" #include "mozilla/dom/cache/SavedTypes.h" #include "mozilla/dom/cache/StreamList.h" #include "mozilla/dom/cache/Types.h" #include "mozilla/dom/quota/Client.h" #include "mozilla/dom/quota/ClientImpl.h" #include "mozilla/dom/quota/QuotaManager.h" #include "mozilla/ipc/BackgroundParent.h" #include "mozStorageHelper.h" #include "nsIInputStream.h" #include "nsID.h" #include "nsIFile.h" #include "nsIThread.h" #include "nsThreadUtils.h" #include "nsTObserverArray.h" #include "QuotaClientImpl.h" namespace mozilla::dom::cache { using mozilla::dom::quota::Client; using mozilla::dom::quota::CloneFileAndAppend; using mozilla::dom::quota::DirectoryLock; namespace { /** * Note: The aCommitHook argument will be invoked while a lock is held. Callers * should be careful not to pass a hook that might lock on something else and * trigger a deadlock. */ template nsresult MaybeUpdatePaddingFile(nsIFile* aBaseDir, mozIStorageConnection* aConn, const int64_t aIncreaseSize, const int64_t aDecreaseSize, Callable aCommitHook) { MOZ_ASSERT(!NS_IsMainThread()); MOZ_DIAGNOSTIC_ASSERT(aBaseDir); MOZ_DIAGNOSTIC_ASSERT(aConn); MOZ_DIAGNOSTIC_ASSERT(aIncreaseSize >= 0); MOZ_DIAGNOSTIC_ASSERT(aDecreaseSize >= 0); RefPtr cacheQuotaClient = CacheQuotaClient::Get(); MOZ_DIAGNOSTIC_ASSERT(cacheQuotaClient); QM_TRY(MOZ_TO_RESULT(cacheQuotaClient->MaybeUpdatePaddingFileInternal( *aBaseDir, *aConn, aIncreaseSize, aDecreaseSize, aCommitHook))); return NS_OK; } // An Action that is executed when a Context is first created. It ensures that // the directory and database are setup properly. This lets other actions // not worry about these details. class SetupAction final : public SyncDBAction { public: SetupAction() : SyncDBAction(DBAction::Create) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aDBDir); QM_TRY(MOZ_TO_RESULT(BodyCreateDir(*aDBDir))); // executes in its own transaction QM_TRY(MOZ_TO_RESULT(db::CreateOrMigrateSchema(*aConn))); // If the Context marker file exists, then the last session was // not cleanly shutdown. In these cases sqlite will ensure that // the database is valid, but we might still orphan data. Both // Cache objects and body files can be referenced by DOM objects // after they are "removed" from their parent. So we need to // look and see if any of these late access objects have been // orphaned. // // Note, this must be done after any schema version updates to // ensure our DBSchema methods work correctly. if (MarkerFileExists(aDirectoryMetadata)) { NS_WARNING("Cache not shutdown cleanly! Cleaning up stale data..."); mozStorageTransaction trans(aConn, false, mozIStorageConnection::TRANSACTION_IMMEDIATE); QM_TRY(MOZ_TO_RESULT(trans.Start())); // Clean up orphaned Cache objects QM_TRY_INSPECT(const auto& orphanedCacheIdList, db::FindOrphanedCacheIds(*aConn)); QM_TRY_INSPECT( const CheckedInt64& overallDeletedPaddingSize, Reduce( orphanedCacheIdList, CheckedInt64(0), [aConn, &aDirectoryMetadata, &aDBDir]( CheckedInt64 oldValue, const Maybe& element) -> Result { QM_TRY_INSPECT(const auto& deletionInfo, db::DeleteCacheId(*aConn, *element)); QM_TRY(MOZ_TO_RESULT( BodyDeleteFiles(aDirectoryMetadata, *aDBDir, deletionInfo.mDeletedBodyIdList))); if (deletionInfo.mDeletedPaddingSize > 0) { DecreaseUsageForDirectoryMetadata( aDirectoryMetadata, deletionInfo.mDeletedPaddingSize); } return oldValue + deletionInfo.mDeletedPaddingSize; })); // Clean up orphaned body objects QM_TRY_INSPECT(const auto& knownBodyIdList, db::GetKnownBodyIds(*aConn)); QM_TRY(MOZ_TO_RESULT(BodyDeleteOrphanedFiles(aDirectoryMetadata, *aDBDir, knownBodyIdList))); // Commit() explicitly here, because we want to ensure the padding file // has the correct content. // We'll restore padding file below, so just warn here if failure happens. // // XXX Before, if MaybeUpdatePaddingFile failed but we didn't enter the if // body below, we would have propagated the MaybeUpdatePaddingFile // failure, but if we entered it and RestorePaddingFile succeeded, we // would have returned NS_OK. Now, we will never propagate a // MaybeUpdatePaddingFile failure. QM_WARNONLY_TRY(QM_TO_RESULT( MaybeUpdatePaddingFile(aDBDir, aConn, /* aIncreaceSize */ 0, overallDeletedPaddingSize.value(), [&trans]() { return trans.Commit(); }))); } if (DirectoryPaddingFileExists(*aDBDir, DirPaddingFile::TMP_FILE) || !DirectoryPaddingFileExists(*aDBDir, DirPaddingFile::FILE)) { QM_TRY(MOZ_TO_RESULT(RestorePaddingFile(aDBDir, aConn))); } return NS_OK; } }; // ---------------------------------------------------------------------------- // Action that is executed when we determine that content has stopped using // a body file that has been orphaned. class DeleteOrphanedBodyAction final : public Action { public: using DeletedBodyIdList = AutoTArray; explicit DeleteOrphanedBodyAction(DeletedBodyIdList&& aDeletedBodyIdList) : mDeletedBodyIdList(std::move(aDeletedBodyIdList)) {} explicit DeleteOrphanedBodyAction(const nsID& aBodyId) : mDeletedBodyIdList{aBodyId} {} void RunOnTarget(SafeRefPtr aResolver, const Maybe& aDirectoryMetadata, Data*) override { MOZ_DIAGNOSTIC_ASSERT(aResolver); MOZ_DIAGNOSTIC_ASSERT(aDirectoryMetadata); MOZ_DIAGNOSTIC_ASSERT(aDirectoryMetadata->mDir); // Note that since DeleteOrphanedBodyAction isn't used while the context is // being initialized, we don't need to check for cancellation here. const auto resolve = [&aResolver](const nsresult rv) { aResolver->Resolve(rv); }; QM_TRY_INSPECT(const auto& dbDir, CloneFileAndAppend(*aDirectoryMetadata->mDir, u"cache"_ns), QM_VOID, resolve); QM_TRY(MOZ_TO_RESULT(BodyDeleteFiles(*aDirectoryMetadata, *dbDir, mDeletedBodyIdList)), QM_VOID, resolve); aResolver->Resolve(NS_OK); } private: DeletedBodyIdList mDeletedBodyIdList; }; bool IsHeadRequest(const CacheRequest& aRequest, const CacheQueryParams& aParams) { return !aParams.ignoreMethod() && aRequest.method().LowerCaseEqualsLiteral("head"); } bool IsHeadRequest(const Maybe& aRequest, const CacheQueryParams& aParams) { if (aRequest.isSome()) { return !aParams.ignoreMethod() && aRequest.ref().method().LowerCaseEqualsLiteral("head"); } return false; } auto MatchByCacheId(CacheId aCacheId) { return [aCacheId](const auto& entry) { return entry.mCacheId == aCacheId; }; } auto MatchByBodyId(const nsID& aBodyId) { return [&aBodyId](const auto& entry) { return entry.mBodyId == aBodyId; }; } } // namespace // ---------------------------------------------------------------------------- // Singleton class to track Manager instances and ensure there is only // one for each unique ManagerId. class Manager::Factory { public: friend class StaticAutoPtr; static Result, nsresult> AcquireCreateIfNonExistent( const SafeRefPtr& aManagerId) { mozilla::ipc::AssertIsOnBackgroundThread(); // If we get here during/after quota manager shutdown, we bail out. MOZ_ASSERT(AppShutdown::GetCurrentShutdownPhase() < ShutdownPhase::AppShutdownQM); if (AppShutdown::GetCurrentShutdownPhase() >= ShutdownPhase::AppShutdownQM) { NS_WARNING( "Attempt to AcquireCreateIfNonExistent a Manager during QM " "shutdown."); return Err(NS_ERROR_ILLEGAL_DURING_SHUTDOWN); } // Ensure there is a factory instance. This forces the Acquire() call // below to use the same factory. QM_TRY(MOZ_TO_RESULT(MaybeCreateInstance())); SafeRefPtr ref = Acquire(*aManagerId); if (!ref) { // TODO: replace this with a thread pool (bug 1119864) // XXX Can't use QM_TRY_INSPECT because that causes a clang-plugin // error of the NoNewThreadsChecker. nsCOMPtr ioThread; QM_TRY(MOZ_TO_RESULT( NS_NewNamedThread("DOMCacheThread", getter_AddRefs(ioThread)))); ref = MakeSafeRefPtr(aManagerId.clonePtr(), ioThread, ConstructorGuard{}); // There may be an old manager for this origin in the process of // cleaning up. We need to tell the new manager about this so // that it won't actually start until the old manager is done. const SafeRefPtr oldManager = Acquire(*aManagerId, Closing); ref->Init(oldManager.maybeDeref()); MOZ_ASSERT(!sFactory->mManagerList.Contains(ref)); sFactory->mManagerList.AppendElement( WrapNotNullUnchecked(ref.unsafeGetRawPtr())); } return ref; } static void Remove(Manager& aManager) { mozilla::ipc::AssertIsOnBackgroundThread(); MOZ_DIAGNOSTIC_ASSERT(sFactory); MOZ_ALWAYS_TRUE(sFactory->mManagerList.RemoveElement(&aManager)); // This might both happen in late shutdown such that this event // is executed even after the QuotaManager singleton passed away // or if the QuotaManager has not yet been created. quota::QuotaManager::SafeMaybeRecordQuotaClientShutdownStep( quota::Client::DOMCACHE, "Manager removed"_ns); // clean up the factory singleton if there are no more managers MaybeDestroyInstance(); } static void Abort(const Client::DirectoryLockIdTable& aDirectoryLockIds) { mozilla::ipc::AssertIsOnBackgroundThread(); AbortMatching([&aDirectoryLockIds](const auto& manager) { // Check if the Manager holds an acquired DirectoryLock. Origin clearing // can't be blocked by this Manager if there is no acquired DirectoryLock. // If there is an acquired DirectoryLock, check if the table contains the // lock for the Manager. return Client::IsLockForObjectAcquiredAndContainedInLockTable( manager, aDirectoryLockIds); }); } static void AbortAll() { mozilla::ipc::AssertIsOnBackgroundThread(); AbortMatching([](const auto&) { return true; }); } static void ShutdownAll() { mozilla::ipc::AssertIsOnBackgroundThread(); if (!sFactory) { return; } MOZ_DIAGNOSTIC_ASSERT(!sFactory->mManagerList.IsEmpty()); { // Note that we are synchronously calling shutdown code here. If any // of the shutdown code synchronously decides to delete the Factory // we need to delay that delete until the end of this method. AutoRestore restore(sFactory->mInSyncAbortOrShutdown); sFactory->mInSyncAbortOrShutdown = true; for (const auto& manager : sFactory->mManagerList.ForwardRange()) { auto pinnedManager = SafeRefPtr{manager.get(), AcquireStrongRefFromRawPtr{}}; pinnedManager->Shutdown(); } } MaybeDestroyInstance(); } static bool IsShutdownAllComplete() { mozilla::ipc::AssertIsOnBackgroundThread(); return !sFactory; } #ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED static void RecordMayNotDeleteCSCP(int32_t aCacheStreamControlParentId) { if (sFactory) { sFactory->mPotentiallyUnreleasedCSCP.AppendElement( aCacheStreamControlParentId); } } static void RecordHaveDeletedCSCP(int32_t aCacheStreamControlParentId) { if (sFactory) { sFactory->mPotentiallyUnreleasedCSCP.RemoveElement( aCacheStreamControlParentId); } } #endif static nsCString GetShutdownStatus() { mozilla::ipc::AssertIsOnBackgroundThread(); nsCString data; if (sFactory && !sFactory->mManagerList.IsEmpty()) { data.Append( "Managers: "_ns + IntToCString(static_cast(sFactory->mManagerList.Length())) + " ("_ns); for (const auto& manager : sFactory->mManagerList.NonObservingRange()) { data.Append(quota::AnonymizedOriginString( manager->GetManagerId().QuotaOrigin())); data.AppendLiteral(": "); data.Append(manager->GetState() == State::Open ? "Open"_ns : "Closing"_ns); data.AppendLiteral(", "); } data.AppendLiteral(" ) "); if (sFactory->mPotentiallyUnreleasedCSCP.Length() > 0) { data.Append( "There have been CSCP instances whose" "Send__delete__ might not have freed them."); } } return data; } private: Factory() : mInSyncAbortOrShutdown(false) { MOZ_COUNT_CTOR(cache::Manager::Factory); } ~Factory() { MOZ_COUNT_DTOR(cache::Manager::Factory); MOZ_DIAGNOSTIC_ASSERT(mManagerList.IsEmpty()); MOZ_DIAGNOSTIC_ASSERT(!mInSyncAbortOrShutdown); } static nsresult MaybeCreateInstance() { mozilla::ipc::AssertIsOnBackgroundThread(); if (!sFactory) { // We cannot use ClearOnShutdown() here because we're not on the main // thread. Instead, we delete sFactory in Factory::Remove() after the // last manager is removed. ShutdownObserver ensures this happens // before shutdown. sFactory = new Factory(); } // Never return sFactory to code outside Factory. We need to delete it // out from under ourselves just before we return from Remove(). This // would be (even more) dangerous if other code had a pointer to the // factory itself. return NS_OK; } static void MaybeDestroyInstance() { mozilla::ipc::AssertIsOnBackgroundThread(); MOZ_DIAGNOSTIC_ASSERT(sFactory); // If the factory is is still in use then we cannot delete yet. This // could be due to managers still existing or because we are in the // middle of aborting or shutting down. We need to be careful not to delete // ourself synchronously during shutdown. if (!sFactory->mManagerList.IsEmpty() || sFactory->mInSyncAbortOrShutdown) { return; } sFactory = nullptr; } static SafeRefPtr Acquire(const ManagerId& aManagerId, State aState = Open) { mozilla::ipc::AssertIsOnBackgroundThread(); QM_TRY(MOZ_TO_RESULT(MaybeCreateInstance()), nullptr); // Iterate in reverse to find the most recent, matching Manager. This // is important when looking for a Closing Manager. If a new Manager // chains to an old Manager we want it to be the most recent one. const auto range = Reversed(sFactory->mManagerList.NonObservingRange()); const auto foundIt = std::find_if( range.begin(), range.end(), [aState, &aManagerId](const auto& manager) { return aState == manager->GetState() && *manager->mManagerId == aManagerId; }); return foundIt != range.end() ? SafeRefPtr{foundIt->get(), AcquireStrongRefFromRawPtr{}} : nullptr; } template static void AbortMatching(const Condition& aCondition) { mozilla::ipc::AssertIsOnBackgroundThread(); if (!sFactory) { return; } MOZ_DIAGNOSTIC_ASSERT(!sFactory->mManagerList.IsEmpty()); { // Note that we are synchronously calling abort code here. If any // of the shutdown code synchronously decides to delete the Factory // we need to delay that delete until the end of this method. AutoRestore restore(sFactory->mInSyncAbortOrShutdown); sFactory->mInSyncAbortOrShutdown = true; for (const auto& manager : sFactory->mManagerList.ForwardRange()) { if (aCondition(*manager)) { auto pinnedManager = SafeRefPtr{manager.get(), AcquireStrongRefFromRawPtr{}}; pinnedManager->Abort(); } } } MaybeDestroyInstance(); } // Singleton created on demand and deleted when last Manager is cleared // in Remove(). // PBackground thread only. static StaticAutoPtr sFactory; // Weak references as we don't want to keep Manager objects alive forever. // When a Manager is destroyed it calls Factory::Remove() to clear itself. // PBackground thread only. nsTObserverArray> mManagerList; // This flag is set when we are looping through the list and calling Abort() // or Shutdown() on each Manager. We need to be careful not to synchronously // trigger the deletion of the factory while still executing this loop. bool mInSyncAbortOrShutdown; nsTArray mPotentiallyUnreleasedCSCP; }; // static StaticAutoPtr Manager::Factory::sFactory; // ---------------------------------------------------------------------------- // Abstract class to help implement the various Actions. The vast majority // of Actions are synchronous and need to report back to a Listener on the // Manager. class Manager::BaseAction : public SyncDBAction { protected: BaseAction(SafeRefPtr aManager, ListenerId aListenerId) : SyncDBAction(DBAction::Existing), mManager(std::move(aManager)), mListenerId(aListenerId) {} virtual void Complete(Listener* aListener, ErrorResult&& aRv) = 0; virtual void CompleteOnInitiatingThread(nsresult aRv) override { NS_ASSERT_OWNINGTHREAD(Manager::BaseAction); Listener* listener = mManager->GetListener(mListenerId); if (listener) { Complete(listener, ErrorResult(aRv)); } // ensure we release the manager on the initiating thread mManager = nullptr; } SafeRefPtr mManager; const ListenerId mListenerId; }; // ---------------------------------------------------------------------------- // Action that is executed when we determine that content has stopped using // a Cache object that has been orphaned. class Manager::DeleteOrphanedCacheAction final : public SyncDBAction { public: DeleteOrphanedCacheAction(SafeRefPtr aManager, CacheId aCacheId) : SyncDBAction(DBAction::Existing), mManager(std::move(aManager)), mCacheId(aCacheId) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { mDirectoryMetadata.emplace(aDirectoryMetadata); mozStorageTransaction trans(aConn, false, mozIStorageConnection::TRANSACTION_IMMEDIATE); QM_TRY(MOZ_TO_RESULT(trans.Start())); QM_TRY_UNWRAP(mDeletionInfo, db::DeleteCacheId(*aConn, mCacheId)); QM_TRY(MOZ_TO_RESULT(MaybeUpdatePaddingFile( aDBDir, aConn, /* aIncreaceSize */ 0, mDeletionInfo.mDeletedPaddingSize, [&trans]() mutable { return trans.Commit(); }))); return NS_OK; } virtual void CompleteOnInitiatingThread(nsresult aRv) override { // If the transaction fails, we shouldn't delete the body files and decrease // their padding size. if (NS_FAILED(aRv)) { mDeletionInfo.mDeletedBodyIdList.Clear(); mDeletionInfo.mDeletedPaddingSize = 0; } mManager->NoteOrphanedBodyIdList(mDeletionInfo.mDeletedBodyIdList); if (mDeletionInfo.mDeletedPaddingSize > 0) { DecreaseUsageForDirectoryMetadata(*mDirectoryMetadata, mDeletionInfo.mDeletedPaddingSize); } // ensure we release the manager on the initiating thread mManager = nullptr; } private: SafeRefPtr mManager; const CacheId mCacheId; DeletionInfo mDeletionInfo; Maybe mDirectoryMetadata; }; // ---------------------------------------------------------------------------- class Manager::CacheMatchAction final : public Manager::BaseAction { public: CacheMatchAction(SafeRefPtr aManager, ListenerId aListenerId, CacheId aCacheId, const CacheMatchArgs& aArgs, SafeRefPtr aStreamList) : BaseAction(std::move(aManager), aListenerId), mCacheId(aCacheId), mArgs(aArgs), mStreamList(std::move(aStreamList)), mFoundResponse(false) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aDBDir); QM_TRY_INSPECT( const auto& maybeResponse, db::CacheMatch(*aConn, mCacheId, mArgs.request(), mArgs.params())); mFoundResponse = maybeResponse.isSome(); if (mFoundResponse) { mResponse = std::move(maybeResponse.ref()); } if (!mFoundResponse || !mResponse.mHasBodyId || IsHeadRequest(mArgs.request(), mArgs.params())) { mResponse.mHasBodyId = false; return NS_OK; } nsCOMPtr stream; if (mArgs.openMode() == OpenMode::Eager) { QM_TRY_UNWRAP(stream, BodyOpen(aDirectoryMetadata, *aDBDir, mResponse.mBodyId)); } mStreamList->Add(mResponse.mBodyId, std::move(stream)); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { if (!mFoundResponse) { aListener->OnOpComplete(std::move(aRv), CacheMatchResult(Nothing())); } else { mStreamList->Activate(mCacheId); aListener->OnOpComplete(std::move(aRv), CacheMatchResult(Nothing()), mResponse, *mStreamList); } mStreamList = nullptr; } virtual bool MatchesCacheId(CacheId aCacheId) const override { return aCacheId == mCacheId; } private: const CacheId mCacheId; const CacheMatchArgs mArgs; SafeRefPtr mStreamList; bool mFoundResponse; SavedResponse mResponse; }; // ---------------------------------------------------------------------------- class Manager::CacheMatchAllAction final : public Manager::BaseAction { public: CacheMatchAllAction(SafeRefPtr aManager, ListenerId aListenerId, CacheId aCacheId, const CacheMatchAllArgs& aArgs, SafeRefPtr aStreamList) : BaseAction(std::move(aManager), aListenerId), mCacheId(aCacheId), mArgs(aArgs), mStreamList(std::move(aStreamList)) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aDBDir); QM_TRY_UNWRAP(mSavedResponses, db::CacheMatchAll(*aConn, mCacheId, mArgs.maybeRequest(), mArgs.params())); for (uint32_t i = 0; i < mSavedResponses.Length(); ++i) { if (!mSavedResponses[i].mHasBodyId || IsHeadRequest(mArgs.maybeRequest(), mArgs.params())) { mSavedResponses[i].mHasBodyId = false; continue; } nsCOMPtr stream; if (mArgs.openMode() == OpenMode::Eager) { QM_TRY_UNWRAP(stream, BodyOpen(aDirectoryMetadata, *aDBDir, mSavedResponses[i].mBodyId)); } mStreamList->Add(mSavedResponses[i].mBodyId, std::move(stream)); } return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { mStreamList->Activate(mCacheId); aListener->OnOpComplete(std::move(aRv), CacheMatchAllResult(), mSavedResponses, *mStreamList); mStreamList = nullptr; } virtual bool MatchesCacheId(CacheId aCacheId) const override { return aCacheId == mCacheId; } private: const CacheId mCacheId; const CacheMatchAllArgs mArgs; SafeRefPtr mStreamList; nsTArray mSavedResponses; }; // ---------------------------------------------------------------------------- // This is the most complex Action. It puts a request/response pair into the // Cache. It does not complete until all of the body data has been saved to // disk. This means its an asynchronous Action. class Manager::CachePutAllAction final : public DBAction { public: CachePutAllAction( SafeRefPtr aManager, ListenerId aListenerId, CacheId aCacheId, const nsTArray& aPutList, const nsTArray>& aRequestStreamList, const nsTArray>& aResponseStreamList) : DBAction(DBAction::Existing), mManager(std::move(aManager)), mListenerId(aListenerId), mCacheId(aCacheId), mList(aPutList.Length()), mExpectedAsyncCopyCompletions(1), mAsyncResult(NS_OK), mMutex("cache::Manager::CachePutAllAction"), mUpdatedPaddingSize(0), mDeletedPaddingSize(0) { MOZ_DIAGNOSTIC_ASSERT(!aPutList.IsEmpty()); MOZ_DIAGNOSTIC_ASSERT(aPutList.Length() == aRequestStreamList.Length()); MOZ_DIAGNOSTIC_ASSERT(aPutList.Length() == aResponseStreamList.Length()); for (uint32_t i = 0; i < aPutList.Length(); ++i) { Entry* entry = mList.AppendElement(); entry->mRequest = aPutList[i].request(); entry->mRequestStream = aRequestStreamList[i]; entry->mResponse = aPutList[i].response(); entry->mResponseStream = aResponseStreamList[i]; } } private: ~CachePutAllAction() = default; virtual void RunWithDBOnTarget( SafeRefPtr aResolver, const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aResolver); MOZ_DIAGNOSTIC_ASSERT(aDBDir); MOZ_DIAGNOSTIC_ASSERT(aConn); MOZ_DIAGNOSTIC_ASSERT(!mResolver); MOZ_DIAGNOSTIC_ASSERT(!mDBDir); MOZ_DIAGNOSTIC_ASSERT(!mConn); MOZ_DIAGNOSTIC_ASSERT(!mTarget); mTarget = GetCurrentSerialEventTarget(); MOZ_DIAGNOSTIC_ASSERT(mTarget); // We should be pre-initialized to expect one async completion. This is // the "manual" completion we call at the end of this method in all // cases. MOZ_DIAGNOSTIC_ASSERT(mExpectedAsyncCopyCompletions == 1); mResolver = std::move(aResolver); mDBDir = aDBDir; mConn = aConn; mDirectoryMetadata.emplace(aDirectoryMetadata); // File bodies are streamed to disk via asynchronous copying. Start // this copying now. Each copy will eventually result in a call // to OnAsyncCopyComplete(). const nsresult rv = [this, &aDirectoryMetadata]() -> nsresult { QM_TRY(CollectEachInRange( mList, [this, &aDirectoryMetadata](auto& entry) -> nsresult { QM_TRY(MOZ_TO_RESULT( StartStreamCopy(aDirectoryMetadata, entry, RequestStream, &mExpectedAsyncCopyCompletions))); QM_TRY(MOZ_TO_RESULT( StartStreamCopy(aDirectoryMetadata, entry, ResponseStream, &mExpectedAsyncCopyCompletions))); return NS_OK; })); return NS_OK; }(); // Always call OnAsyncCopyComplete() manually here. This covers the // case where there is no async copying and also reports any startup // errors correctly. If we hit an error, then OnAsyncCopyComplete() // will cancel any async copying. OnAsyncCopyComplete(rv); } // Called once for each asynchronous file copy whether it succeeds or // fails. If a file copy is canceled, it still calls this method with // an error code. void OnAsyncCopyComplete(nsresult aRv) { MOZ_ASSERT(mTarget->IsOnCurrentThread()); MOZ_DIAGNOSTIC_ASSERT(mConn); MOZ_DIAGNOSTIC_ASSERT(mResolver); MOZ_DIAGNOSTIC_ASSERT(mExpectedAsyncCopyCompletions > 0); // Explicitly check for cancellation here to catch a race condition. // Consider: // // 1) NS_AsyncCopy() executes on IO thread, but has not saved its // copy context yet. // 2) CancelAllStreamCopying() occurs on PBackground thread // 3) Copy context from (1) is saved on IO thread. // // Checking for cancellation here catches this condition when we // first call OnAsyncCopyComplete() manually from RunWithDBOnTarget(). // // This explicit cancellation check also handles the case where we // are canceled just after all stream copying completes. We should // abort the synchronous DB operations in this case if we have not // started them yet. if (NS_SUCCEEDED(aRv) && IsCanceled()) { aRv = NS_ERROR_ABORT; } // If any of the async copies fail, we need to still wait for them all to // complete. Cancel any other streams still working and remember the // error. All canceled streams will call OnAsyncCopyComplete(). if (NS_FAILED(aRv) && NS_SUCCEEDED(mAsyncResult)) { CancelAllStreamCopying(); mAsyncResult = aRv; } // Check to see if async copying is still on-going. If so, then simply // return for now. We must wait for a later OnAsyncCopyComplete() call. mExpectedAsyncCopyCompletions -= 1; if (mExpectedAsyncCopyCompletions > 0) { return; } // We have finished with all async copying. Indicate this by clearing all // our copy contexts. { MutexAutoLock lock(mMutex); mCopyContextList.Clear(); } // An error occurred while async copying. Terminate the Action. // DoResolve() will clean up any files we may have written. if (NS_FAILED(mAsyncResult)) { DoResolve(mAsyncResult); return; } mozStorageTransaction trans(mConn, false, mozIStorageConnection::TRANSACTION_IMMEDIATE); QM_TRY(MOZ_TO_RESULT(trans.Start()), QM_VOID); const nsresult rv = [this, &trans]() -> nsresult { QM_TRY(CollectEachInRange(mList, [this](Entry& e) -> nsresult { if (e.mRequestStream) { QM_TRY(MOZ_TO_RESULT(BodyFinalizeWrite(*mDBDir, e.mRequestBodyId))); } if (e.mResponseStream) { // Gerenate padding size for opaque response if needed. if (e.mResponse.type() == ResponseType::Opaque) { // It'll generate padding if we've not set it yet. QM_TRY(MOZ_TO_RESULT(BodyMaybeUpdatePaddingSize( *mDirectoryMetadata, *mDBDir, e.mResponseBodyId, e.mResponse.paddingInfo(), &e.mResponse.paddingSize()))); MOZ_DIAGNOSTIC_ASSERT(INT64_MAX - e.mResponse.paddingSize() >= mUpdatedPaddingSize); mUpdatedPaddingSize += e.mResponse.paddingSize(); } QM_TRY(MOZ_TO_RESULT(BodyFinalizeWrite(*mDBDir, e.mResponseBodyId))); } QM_TRY_UNWRAP( auto deletionInfo, db::CachePut(*mConn, mCacheId, e.mRequest, e.mRequestStream ? &e.mRequestBodyId : nullptr, e.mResponse, e.mResponseStream ? &e.mResponseBodyId : nullptr)); const int64_t deletedPaddingSize = deletionInfo.mDeletedPaddingSize; mDeletedBodyIdList = std::move(deletionInfo.mDeletedBodyIdList); MOZ_DIAGNOSTIC_ASSERT(INT64_MAX - mDeletedPaddingSize >= deletedPaddingSize); mDeletedPaddingSize += deletedPaddingSize; return NS_OK; })); // Update padding file when it's necessary QM_TRY(MOZ_TO_RESULT(MaybeUpdatePaddingFile( mDBDir, mConn, mUpdatedPaddingSize, mDeletedPaddingSize, [&trans]() mutable { return trans.Commit(); }))); return NS_OK; }(); DoResolve(rv); } virtual void CompleteOnInitiatingThread(nsresult aRv) override { NS_ASSERT_OWNINGTHREAD(Action); for (uint32_t i = 0; i < mList.Length(); ++i) { mList[i].mRequestStream = nullptr; mList[i].mResponseStream = nullptr; } // If the transaction fails, we shouldn't delete the body files and decrease // their padding size. if (NS_FAILED(aRv)) { mDeletedBodyIdList.Clear(); mDeletedPaddingSize = 0; } mManager->NoteOrphanedBodyIdList(mDeletedBodyIdList); if (mDeletedPaddingSize > 0) { DecreaseUsageForDirectoryMetadata(*mDirectoryMetadata, mDeletedPaddingSize); } Listener* listener = mManager->GetListener(mListenerId); mManager = nullptr; if (listener) { listener->OnOpComplete(ErrorResult(aRv), CachePutAllResult()); } } virtual void CancelOnInitiatingThread() override { NS_ASSERT_OWNINGTHREAD(Action); Action::CancelOnInitiatingThread(); CancelAllStreamCopying(); } virtual bool MatchesCacheId(CacheId aCacheId) const override { NS_ASSERT_OWNINGTHREAD(Action); return aCacheId == mCacheId; } struct Entry { CacheRequest mRequest; nsCOMPtr mRequestStream; nsID mRequestBodyId; nsCOMPtr mRequestCopyContext; CacheResponse mResponse; nsCOMPtr mResponseStream; nsID mResponseBodyId; nsCOMPtr mResponseCopyContext; }; enum StreamId { RequestStream, ResponseStream }; nsresult StartStreamCopy(const CacheDirectoryMetadata& aDirectoryMetadata, Entry& aEntry, StreamId aStreamId, uint32_t* aCopyCountOut) { MOZ_ASSERT(mTarget->IsOnCurrentThread()); MOZ_DIAGNOSTIC_ASSERT(aCopyCountOut); if (IsCanceled()) { return NS_ERROR_ABORT; } MOZ_DIAGNOSTIC_ASSERT(aStreamId == RequestStream || aStreamId == ResponseStream); const auto& source = aStreamId == RequestStream ? aEntry.mRequestStream : aEntry.mResponseStream; if (!source) { return NS_OK; } QM_TRY_INSPECT((const auto& [bodyId, copyContext]), BodyStartWriteStream(aDirectoryMetadata, *mDBDir, *source, this, AsyncCopyCompleteFunc)); if (aStreamId == RequestStream) { aEntry.mRequestBodyId = bodyId; } else { aEntry.mResponseBodyId = bodyId; } mBodyIdWrittenList.AppendElement(bodyId); if (copyContext) { MutexAutoLock lock(mMutex); mCopyContextList.AppendElement(copyContext); } *aCopyCountOut += 1; return NS_OK; } void CancelAllStreamCopying() { // May occur on either owning thread or target thread MutexAutoLock lock(mMutex); for (uint32_t i = 0; i < mCopyContextList.Length(); ++i) { MOZ_DIAGNOSTIC_ASSERT(mCopyContextList[i]); BodyCancelWrite(*mCopyContextList[i]); } mCopyContextList.Clear(); } static void AsyncCopyCompleteFunc(void* aClosure, nsresult aRv) { // May be on any thread, including STS event target. MOZ_DIAGNOSTIC_ASSERT(aClosure); // Weak ref as we are guaranteed to the action is alive until // CompleteOnInitiatingThread is called. CachePutAllAction* action = static_cast(aClosure); action->CallOnAsyncCopyCompleteOnTargetThread(aRv); } void CallOnAsyncCopyCompleteOnTargetThread(nsresult aRv) { // May be on any thread, including STS event target. Non-owning runnable // here since we are guaranteed the Action will survive until // CompleteOnInitiatingThread is called. nsCOMPtr runnable = NewNonOwningRunnableMethod( "dom::cache::Manager::CachePutAllAction::OnAsyncCopyComplete", this, &CachePutAllAction::OnAsyncCopyComplete, aRv); MOZ_ALWAYS_SUCCEEDS( mTarget->Dispatch(runnable.forget(), nsIThread::DISPATCH_NORMAL)); } void DoResolve(nsresult aRv) { MOZ_ASSERT(mTarget->IsOnCurrentThread()); // DoResolve() must not be called until all async copying has completed. #ifdef DEBUG { MutexAutoLock lock(mMutex); MOZ_ASSERT(mCopyContextList.IsEmpty()); } #endif // Clean up any files we might have written before hitting the error. if (NS_FAILED(aRv)) { BodyDeleteFiles(*mDirectoryMetadata, *mDBDir, mBodyIdWrittenList); if (mUpdatedPaddingSize > 0) { DecreaseUsageForDirectoryMetadata(*mDirectoryMetadata, mUpdatedPaddingSize); } } // Must be released on the target thread where it was opened. mConn = nullptr; // Drop our ref to the target thread as we are done with this thread. // Also makes our thread assertions catch any incorrect method calls // after resolve. mTarget = nullptr; // Make sure to de-ref the resolver per the Action API contract. SafeRefPtr resolver = std::move(mResolver); resolver->Resolve(aRv); } // initiating thread only SafeRefPtr mManager; const ListenerId mListenerId; // Set on initiating thread, read on target thread. State machine guarantees // these are not modified while being read by the target thread. const CacheId mCacheId; nsTArray mList; uint32_t mExpectedAsyncCopyCompletions; // target thread only SafeRefPtr mResolver; nsCOMPtr mDBDir; nsCOMPtr mConn; nsCOMPtr mTarget; nsresult mAsyncResult; nsTArray mBodyIdWrittenList; // Written to on target thread, accessed on initiating thread after target // thread activity is guaranteed complete nsTArray mDeletedBodyIdList; // accessed from any thread while mMutex locked Mutex mMutex MOZ_UNANNOTATED; nsTArray> mCopyContextList; Maybe mDirectoryMetadata; // Track how much pad amount has been added for new entries so that it can be // removed if an error occurs. int64_t mUpdatedPaddingSize; // Track any pad amount associated with overwritten entries. int64_t mDeletedPaddingSize; }; // ---------------------------------------------------------------------------- class Manager::CacheDeleteAction final : public Manager::BaseAction { public: CacheDeleteAction(SafeRefPtr aManager, ListenerId aListenerId, CacheId aCacheId, const CacheDeleteArgs& aArgs) : BaseAction(std::move(aManager), aListenerId), mCacheId(aCacheId), mArgs(aArgs), mSuccess(false) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { mDirectoryMetadata.emplace(aDirectoryMetadata); mozStorageTransaction trans(aConn, false, mozIStorageConnection::TRANSACTION_IMMEDIATE); QM_TRY(MOZ_TO_RESULT(trans.Start())); QM_TRY_UNWRAP( auto maybeDeletionInfo, db::CacheDelete(*aConn, mCacheId, mArgs.request(), mArgs.params())); mSuccess = maybeDeletionInfo.isSome(); if (mSuccess) { mDeletionInfo = std::move(maybeDeletionInfo.ref()); } QM_TRY(MOZ_TO_RESULT(MaybeUpdatePaddingFile( aDBDir, aConn, /* aIncreaceSize */ 0, mDeletionInfo.mDeletedPaddingSize, [&trans]() mutable { return trans.Commit(); })), QM_PROPAGATE, [this](const nsresult) { mSuccess = false; }); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { // If the transaction fails, we shouldn't delete the body files and decrease // their padding size. if (aRv.Failed()) { mDeletionInfo.mDeletedBodyIdList.Clear(); mDeletionInfo.mDeletedPaddingSize = 0; } mManager->NoteOrphanedBodyIdList(mDeletionInfo.mDeletedBodyIdList); if (mDeletionInfo.mDeletedPaddingSize > 0) { DecreaseUsageForDirectoryMetadata(*mDirectoryMetadata, mDeletionInfo.mDeletedPaddingSize); } aListener->OnOpComplete(std::move(aRv), CacheDeleteResult(mSuccess)); } virtual bool MatchesCacheId(CacheId aCacheId) const override { return aCacheId == mCacheId; } private: const CacheId mCacheId; const CacheDeleteArgs mArgs; bool mSuccess; DeletionInfo mDeletionInfo; Maybe mDirectoryMetadata; }; // ---------------------------------------------------------------------------- class Manager::CacheKeysAction final : public Manager::BaseAction { public: CacheKeysAction(SafeRefPtr aManager, ListenerId aListenerId, CacheId aCacheId, const CacheKeysArgs& aArgs, SafeRefPtr aStreamList) : BaseAction(std::move(aManager), aListenerId), mCacheId(aCacheId), mArgs(aArgs), mStreamList(std::move(aStreamList)) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aDBDir); QM_TRY_UNWRAP( mSavedRequests, db::CacheKeys(*aConn, mCacheId, mArgs.maybeRequest(), mArgs.params())); for (uint32_t i = 0; i < mSavedRequests.Length(); ++i) { if (!mSavedRequests[i].mHasBodyId || IsHeadRequest(mArgs.maybeRequest(), mArgs.params())) { mSavedRequests[i].mHasBodyId = false; continue; } nsCOMPtr stream; if (mArgs.openMode() == OpenMode::Eager) { QM_TRY_UNWRAP(stream, BodyOpen(aDirectoryMetadata, *aDBDir, mSavedRequests[i].mBodyId)); } mStreamList->Add(mSavedRequests[i].mBodyId, std::move(stream)); } return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { mStreamList->Activate(mCacheId); aListener->OnOpComplete(std::move(aRv), CacheKeysResult(), mSavedRequests, *mStreamList); mStreamList = nullptr; } virtual bool MatchesCacheId(CacheId aCacheId) const override { return aCacheId == mCacheId; } private: const CacheId mCacheId; const CacheKeysArgs mArgs; SafeRefPtr mStreamList; nsTArray mSavedRequests; }; // ---------------------------------------------------------------------------- class Manager::StorageMatchAction final : public Manager::BaseAction { public: StorageMatchAction(SafeRefPtr aManager, ListenerId aListenerId, Namespace aNamespace, const StorageMatchArgs& aArgs, SafeRefPtr aStreamList) : BaseAction(std::move(aManager), aListenerId), mNamespace(aNamespace), mArgs(aArgs), mStreamList(std::move(aStreamList)), mFoundResponse(false) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aDBDir); auto maybeResponse = db::StorageMatch(*aConn, mNamespace, mArgs.request(), mArgs.params()); if (NS_WARN_IF(maybeResponse.isErr())) { return maybeResponse.unwrapErr(); } mFoundResponse = maybeResponse.inspect().isSome(); if (mFoundResponse) { mSavedResponse = maybeResponse.unwrap().ref(); } if (!mFoundResponse || !mSavedResponse.mHasBodyId || IsHeadRequest(mArgs.request(), mArgs.params())) { mSavedResponse.mHasBodyId = false; return NS_OK; } nsCOMPtr stream; if (mArgs.openMode() == OpenMode::Eager) { QM_TRY_UNWRAP(stream, BodyOpen(aDirectoryMetadata, *aDBDir, mSavedResponse.mBodyId)); } mStreamList->Add(mSavedResponse.mBodyId, std::move(stream)); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { if (!mFoundResponse) { aListener->OnOpComplete(std::move(aRv), StorageMatchResult(Nothing())); } else { mStreamList->Activate(mSavedResponse.mCacheId); aListener->OnOpComplete(std::move(aRv), StorageMatchResult(Nothing()), mSavedResponse, *mStreamList); } mStreamList = nullptr; } private: const Namespace mNamespace; const StorageMatchArgs mArgs; SafeRefPtr mStreamList; bool mFoundResponse; SavedResponse mSavedResponse; }; // ---------------------------------------------------------------------------- class Manager::StorageHasAction final : public Manager::BaseAction { public: StorageHasAction(SafeRefPtr aManager, ListenerId aListenerId, Namespace aNamespace, const StorageHasArgs& aArgs) : BaseAction(std::move(aManager), aListenerId), mNamespace(aNamespace), mArgs(aArgs), mCacheFound(false) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { QM_TRY_INSPECT(const auto& maybeCacheId, db::StorageGetCacheId(*aConn, mNamespace, mArgs.key())); mCacheFound = maybeCacheId.isSome(); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { aListener->OnOpComplete(std::move(aRv), StorageHasResult(mCacheFound)); } private: const Namespace mNamespace; const StorageHasArgs mArgs; bool mCacheFound; }; // ---------------------------------------------------------------------------- class Manager::StorageOpenAction final : public Manager::BaseAction { public: StorageOpenAction(SafeRefPtr aManager, ListenerId aListenerId, Namespace aNamespace, const StorageOpenArgs& aArgs) : BaseAction(std::move(aManager), aListenerId), mNamespace(aNamespace), mArgs(aArgs), mCacheId(INVALID_CACHE_ID) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { // Cache does not exist, create it instead mozStorageTransaction trans(aConn, false, mozIStorageConnection::TRANSACTION_IMMEDIATE); QM_TRY(MOZ_TO_RESULT(trans.Start())); // Look for existing cache QM_TRY_INSPECT(const auto& maybeCacheId, db::StorageGetCacheId(*aConn, mNamespace, mArgs.key())); if (maybeCacheId.isSome()) { mCacheId = maybeCacheId.ref(); MOZ_DIAGNOSTIC_ASSERT(mCacheId != INVALID_CACHE_ID); return NS_OK; } QM_TRY_UNWRAP(mCacheId, db::CreateCacheId(*aConn)); QM_TRY(MOZ_TO_RESULT( db::StoragePutCache(*aConn, mNamespace, mArgs.key(), mCacheId))); QM_TRY(MOZ_TO_RESULT(trans.Commit())); MOZ_DIAGNOSTIC_ASSERT(mCacheId != INVALID_CACHE_ID); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { MOZ_DIAGNOSTIC_ASSERT(aRv.Failed() || mCacheId != INVALID_CACHE_ID); aListener->OnOpComplete(std::move(aRv), StorageOpenResult(nullptr, nullptr, mNamespace), mCacheId); } private: const Namespace mNamespace; const StorageOpenArgs mArgs; CacheId mCacheId; }; // ---------------------------------------------------------------------------- class Manager::StorageDeleteAction final : public Manager::BaseAction { public: StorageDeleteAction(SafeRefPtr aManager, ListenerId aListenerId, Namespace aNamespace, const StorageDeleteArgs& aArgs) : BaseAction(std::move(aManager), aListenerId), mNamespace(aNamespace), mArgs(aArgs), mCacheDeleted(false), mCacheId(INVALID_CACHE_ID) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { mozStorageTransaction trans(aConn, false, mozIStorageConnection::TRANSACTION_IMMEDIATE); QM_TRY(MOZ_TO_RESULT(trans.Start())); QM_TRY_INSPECT(const auto& maybeCacheId, db::StorageGetCacheId(*aConn, mNamespace, mArgs.key())); if (maybeCacheId.isNothing()) { mCacheDeleted = false; return NS_OK; } mCacheId = maybeCacheId.ref(); // Don't delete the removing padding size here, we'll delete it on // DeleteOrphanedCacheAction. QM_TRY( MOZ_TO_RESULT(db::StorageForgetCache(*aConn, mNamespace, mArgs.key()))); QM_TRY(MOZ_TO_RESULT(trans.Commit())); mCacheDeleted = true; return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { if (mCacheDeleted) { // If content is referencing this cache, mark it orphaned to be // deleted later. if (!mManager->SetCacheIdOrphanedIfRefed(mCacheId)) { // no outstanding references, delete immediately const auto pinnedContext = SafeRefPtr{mManager->mContext, AcquireStrongRefFromRawPtr{}}; if (pinnedContext->IsCanceled()) { pinnedContext->NoteOrphanedData(); } else { pinnedContext->CancelForCacheId(mCacheId); pinnedContext->Dispatch(MakeSafeRefPtr( mManager.clonePtr(), mCacheId)); } } } aListener->OnOpComplete(std::move(aRv), StorageDeleteResult(mCacheDeleted)); } private: const Namespace mNamespace; const StorageDeleteArgs mArgs; bool mCacheDeleted; CacheId mCacheId; }; // ---------------------------------------------------------------------------- class Manager::StorageKeysAction final : public Manager::BaseAction { public: StorageKeysAction(SafeRefPtr aManager, ListenerId aListenerId, Namespace aNamespace) : BaseAction(std::move(aManager), aListenerId), mNamespace(aNamespace) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { QM_TRY_UNWRAP(mKeys, db::StorageGetKeys(*aConn, mNamespace)); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { if (aRv.Failed()) { mKeys.Clear(); } aListener->OnOpComplete(std::move(aRv), StorageKeysResult(mKeys)); } private: const Namespace mNamespace; nsTArray mKeys; }; // ---------------------------------------------------------------------------- class Manager::OpenStreamAction final : public Manager::BaseAction { public: OpenStreamAction(SafeRefPtr aManager, ListenerId aListenerId, InputStreamResolver&& aResolver, const nsID& aBodyId) : BaseAction(std::move(aManager), aListenerId), mResolver(std::move(aResolver)), mBodyId(aBodyId) {} virtual nsresult RunSyncWithDBOnTarget( const CacheDirectoryMetadata& aDirectoryMetadata, nsIFile* aDBDir, mozIStorageConnection* aConn) override { MOZ_DIAGNOSTIC_ASSERT(aDBDir); QM_TRY_UNWRAP(mBodyStream, BodyOpen(aDirectoryMetadata, *aDBDir, mBodyId)); return NS_OK; } virtual void Complete(Listener* aListener, ErrorResult&& aRv) override { if (aRv.Failed()) { // Ignore the reason for fail and just pass a null input stream to let it // fail. aRv.SuppressException(); mResolver(nullptr); } else { mResolver(std::move(mBodyStream)); } mResolver = nullptr; } private: InputStreamResolver mResolver; const nsID mBodyId; nsCOMPtr mBodyStream; }; // ---------------------------------------------------------------------------- // static Manager::ListenerId Manager::sNextListenerId = 0; void Manager::Listener::OnOpComplete(ErrorResult&& aRv, const CacheOpResult& aResult) { OnOpComplete(std::move(aRv), aResult, INVALID_CACHE_ID, Nothing()); } void Manager::Listener::OnOpComplete(ErrorResult&& aRv, const CacheOpResult& aResult, CacheId aOpenedCacheId) { OnOpComplete(std::move(aRv), aResult, aOpenedCacheId, Nothing()); } void Manager::Listener::OnOpComplete(ErrorResult&& aRv, const CacheOpResult& aResult, const SavedResponse& aSavedResponse, StreamList& aStreamList) { AutoTArray responseList; responseList.AppendElement(aSavedResponse); OnOpComplete( std::move(aRv), aResult, INVALID_CACHE_ID, Some(StreamInfo{responseList, nsTArray(), aStreamList})); } void Manager::Listener::OnOpComplete( ErrorResult&& aRv, const CacheOpResult& aResult, const nsTArray& aSavedResponseList, StreamList& aStreamList) { OnOpComplete(std::move(aRv), aResult, INVALID_CACHE_ID, Some(StreamInfo{aSavedResponseList, nsTArray(), aStreamList})); } void Manager::Listener::OnOpComplete( ErrorResult&& aRv, const CacheOpResult& aResult, const nsTArray& aSavedRequestList, StreamList& aStreamList) { OnOpComplete(std::move(aRv), aResult, INVALID_CACHE_ID, Some(StreamInfo{nsTArray(), aSavedRequestList, aStreamList})); } // static Result, nsresult> Manager::AcquireCreateIfNonExistent( const SafeRefPtr& aManagerId) { mozilla::ipc::AssertIsOnBackgroundThread(); return Factory::AcquireCreateIfNonExistent(aManagerId); } // static void Manager::InitiateShutdown() { mozilla::ipc::AssertIsOnBackgroundThread(); Factory::AbortAll(); Factory::ShutdownAll(); } // static bool Manager::IsShutdownAllComplete() { mozilla::ipc::AssertIsOnBackgroundThread(); return Factory::IsShutdownAllComplete(); } #ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED void Manager::RecordMayNotDeleteCSCP(int32_t aCacheStreamControlParentId) { Factory::RecordMayNotDeleteCSCP(aCacheStreamControlParentId); } void Manager::RecordHaveDeletedCSCP(int32_t aCacheStreamControlParentId) { Factory::RecordHaveDeletedCSCP(aCacheStreamControlParentId); } #endif // static nsCString Manager::GetShutdownStatus() { mozilla::ipc::AssertIsOnBackgroundThread(); return Factory::GetShutdownStatus(); } // static void Manager::Abort(const Client::DirectoryLockIdTable& aDirectoryLockIds) { mozilla::ipc::AssertIsOnBackgroundThread(); Factory::Abort(aDirectoryLockIds); } // static void Manager::AbortAll() { mozilla::ipc::AssertIsOnBackgroundThread(); Factory::AbortAll(); } void Manager::RemoveListener(Listener* aListener) { NS_ASSERT_OWNINGTHREAD(Manager); // There may not be a listener here in the case where an actor is killed // before it can perform any actual async requests on Manager. mListeners.RemoveElement(aListener, ListenerEntryListenerComparator()); MOZ_ASSERT( !mListeners.Contains(aListener, ListenerEntryListenerComparator())); MaybeAllowContextToClose(); } void Manager::RemoveContext(Context& aContext) { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(mContext); MOZ_DIAGNOSTIC_ASSERT(mContext == &aContext); // Whether the Context destruction was triggered from the Manager going // idle or the underlying storage being invalidated, we should know we // are closing before the Context is destroyed. MOZ_DIAGNOSTIC_ASSERT(mState == Closing); // Before forgetting the Context, check to see if we have any outstanding // cache or body objects waiting for deletion. If so, note that we've // orphaned data so it will be cleaned up on the next open. if (std::any_of( mCacheIdRefs.cbegin(), mCacheIdRefs.cend(), [](const auto& cacheIdRef) { return cacheIdRef.mOrphaned; }) || std::any_of(mBodyIdRefs.cbegin(), mBodyIdRefs.cend(), [](const auto& bodyIdRef) { return bodyIdRef.mOrphaned; })) { aContext.NoteOrphanedData(); } mContext = nullptr; // Once the context is gone, we can immediately remove ourself from the // Factory list. We don't need to block shutdown by staying in the list // any more. Factory::Remove(*this); } void Manager::NoteClosing() { NS_ASSERT_OWNINGTHREAD(Manager); // This can be called more than once legitimately through different paths. mState = Closing; } Manager::State Manager::GetState() const { NS_ASSERT_OWNINGTHREAD(Manager); return mState; } void Manager::AddRefCacheId(CacheId aCacheId) { NS_ASSERT_OWNINGTHREAD(Manager); const auto end = mCacheIdRefs.end(); const auto foundIt = std::find_if(mCacheIdRefs.begin(), end, MatchByCacheId(aCacheId)); if (foundIt != end) { foundIt->mCount += 1; return; } mCacheIdRefs.AppendElement(CacheIdRefCounter{aCacheId, 1, false}); } void Manager::ReleaseCacheId(CacheId aCacheId) { NS_ASSERT_OWNINGTHREAD(Manager); const auto end = mCacheIdRefs.end(); const auto foundIt = std::find_if(mCacheIdRefs.begin(), end, MatchByCacheId(aCacheId)); if (foundIt != end) { #ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED const uint32_t oldRef = foundIt->mCount; #endif foundIt->mCount -= 1; MOZ_DIAGNOSTIC_ASSERT(foundIt->mCount < oldRef); if (foundIt->mCount == 0) { const bool orphaned = foundIt->mOrphaned; mCacheIdRefs.RemoveElementAt(foundIt); const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; // If the context is already gone, then orphan flag should have been // set in RemoveContext(). if (orphaned && pinnedContext) { if (pinnedContext->IsCanceled()) { pinnedContext->NoteOrphanedData(); } else { pinnedContext->CancelForCacheId(aCacheId); pinnedContext->Dispatch(MakeSafeRefPtr( SafeRefPtrFromThis(), aCacheId)); } } } MaybeAllowContextToClose(); return; } MOZ_ASSERT_UNREACHABLE("Attempt to release CacheId that is not referenced!"); } void Manager::AddRefBodyId(const nsID& aBodyId) { NS_ASSERT_OWNINGTHREAD(Manager); const auto end = mBodyIdRefs.end(); const auto foundIt = std::find_if(mBodyIdRefs.begin(), end, MatchByBodyId(aBodyId)); if (foundIt != end) { foundIt->mCount += 1; return; } mBodyIdRefs.AppendElement(BodyIdRefCounter{aBodyId, 1, false}); } void Manager::ReleaseBodyId(const nsID& aBodyId) { NS_ASSERT_OWNINGTHREAD(Manager); const auto end = mBodyIdRefs.end(); const auto foundIt = std::find_if(mBodyIdRefs.begin(), end, MatchByBodyId(aBodyId)); if (foundIt != end) { #ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED const uint32_t oldRef = foundIt->mCount; #endif foundIt->mCount -= 1; MOZ_DIAGNOSTIC_ASSERT(foundIt->mCount < oldRef); if (foundIt->mCount < 1) { const bool orphaned = foundIt->mOrphaned; mBodyIdRefs.RemoveElementAt(foundIt); const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; // If the context is already gone, then orphan flag should have been // set in RemoveContext(). if (orphaned && pinnedContext) { if (pinnedContext->IsCanceled()) { pinnedContext->NoteOrphanedData(); } else { pinnedContext->Dispatch( MakeSafeRefPtr(aBodyId)); } } } MaybeAllowContextToClose(); return; } MOZ_ASSERT_UNREACHABLE("Attempt to release BodyId that is not referenced!"); } const ManagerId& Manager::GetManagerId() const { return *mManagerId; } void Manager::AddStreamList(StreamList& aStreamList) { NS_ASSERT_OWNINGTHREAD(Manager); mStreamLists.AppendElement(WrapNotNullUnchecked(&aStreamList)); } void Manager::RemoveStreamList(StreamList& aStreamList) { NS_ASSERT_OWNINGTHREAD(Manager); mStreamLists.RemoveElement(&aStreamList); } void Manager::ExecuteCacheOp(Listener* aListener, CacheId aCacheId, const CacheOpArgs& aOpArgs) { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(aListener); MOZ_DIAGNOSTIC_ASSERT(aOpArgs.type() != CacheOpArgs::TCachePutAllArgs); if (NS_WARN_IF(mState == Closing)) { aListener->OnOpComplete(ErrorResult(NS_ERROR_FAILURE), void_t()); return; } const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; MOZ_DIAGNOSTIC_ASSERT(!pinnedContext->IsCanceled()); auto action = [this, aListener, aCacheId, &aOpArgs, &pinnedContext]() -> SafeRefPtr { const ListenerId listenerId = SaveListener(aListener); if (CacheOpArgs::TCacheDeleteArgs == aOpArgs.type()) { return MakeSafeRefPtr(SafeRefPtrFromThis(), listenerId, aCacheId, aOpArgs.get_CacheDeleteArgs()); } auto streamList = MakeSafeRefPtr(SafeRefPtrFromThis(), pinnedContext.clonePtr()); switch (aOpArgs.type()) { case CacheOpArgs::TCacheMatchArgs: return MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, aCacheId, aOpArgs.get_CacheMatchArgs(), std::move(streamList)); case CacheOpArgs::TCacheMatchAllArgs: return MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, aCacheId, aOpArgs.get_CacheMatchAllArgs(), std::move(streamList)); case CacheOpArgs::TCacheKeysArgs: return MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, aCacheId, aOpArgs.get_CacheKeysArgs(), std::move(streamList)); default: MOZ_CRASH("Unknown Cache operation!"); } }(); pinnedContext->Dispatch(std::move(action)); } void Manager::ExecuteStorageOp(Listener* aListener, Namespace aNamespace, const CacheOpArgs& aOpArgs) { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(aListener); if (NS_WARN_IF(mState == Closing)) { aListener->OnOpComplete(ErrorResult(NS_ERROR_FAILURE), void_t()); return; } const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; MOZ_DIAGNOSTIC_ASSERT(!pinnedContext->IsCanceled()); auto action = [this, aListener, aNamespace, &aOpArgs, &pinnedContext]() -> SafeRefPtr { const ListenerId listenerId = SaveListener(aListener); switch (aOpArgs.type()) { case CacheOpArgs::TStorageMatchArgs: return MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, aNamespace, aOpArgs.get_StorageMatchArgs(), MakeSafeRefPtr(SafeRefPtrFromThis(), pinnedContext.clonePtr())); case CacheOpArgs::TStorageHasArgs: return MakeSafeRefPtr(SafeRefPtrFromThis(), listenerId, aNamespace, aOpArgs.get_StorageHasArgs()); case CacheOpArgs::TStorageOpenArgs: return MakeSafeRefPtr(SafeRefPtrFromThis(), listenerId, aNamespace, aOpArgs.get_StorageOpenArgs()); case CacheOpArgs::TStorageDeleteArgs: return MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, aNamespace, aOpArgs.get_StorageDeleteArgs()); case CacheOpArgs::TStorageKeysArgs: return MakeSafeRefPtr(SafeRefPtrFromThis(), listenerId, aNamespace); default: MOZ_CRASH("Unknown CacheStorage operation!"); } }(); pinnedContext->Dispatch(std::move(action)); } void Manager::ExecuteOpenStream(Listener* aListener, InputStreamResolver&& aResolver, const nsID& aBodyId) { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(aListener); MOZ_DIAGNOSTIC_ASSERT(aResolver); if (NS_WARN_IF(mState == Closing)) { aResolver(nullptr); return; } const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; MOZ_DIAGNOSTIC_ASSERT(!pinnedContext->IsCanceled()); // We save the listener simply to track the existence of the caller here. // Our returned value will really be passed to the resolver when the // operation completes. In the future we should remove the Listener // mechanism in favor of std::function or MozPromise. ListenerId listenerId = SaveListener(aListener); pinnedContext->Dispatch(MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, std::move(aResolver), aBodyId)); } void Manager::ExecutePutAll( Listener* aListener, CacheId aCacheId, const nsTArray& aPutList, const nsTArray>& aRequestStreamList, const nsTArray>& aResponseStreamList) { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(aListener); if (NS_WARN_IF(mState == Closing)) { aListener->OnOpComplete(ErrorResult(NS_ERROR_FAILURE), CachePutAllResult()); return; } const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; MOZ_DIAGNOSTIC_ASSERT(!pinnedContext->IsCanceled()); ListenerId listenerId = SaveListener(aListener); pinnedContext->Dispatch(MakeSafeRefPtr( SafeRefPtrFromThis(), listenerId, aCacheId, aPutList, aRequestStreamList, aResponseStreamList)); } Manager::Manager(SafeRefPtr aManagerId, nsIThread* aIOThread, const ConstructorGuard&) : mManagerId(std::move(aManagerId)), mIOThread(aIOThread), mContext(nullptr), mShuttingDown(false), mState(Open) { MOZ_DIAGNOSTIC_ASSERT(mManagerId); MOZ_DIAGNOSTIC_ASSERT(mIOThread); } Manager::~Manager() { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(mState == Closing); MOZ_DIAGNOSTIC_ASSERT(!mContext); nsCOMPtr ioThread; mIOThread.swap(ioThread); // Don't spin the event loop in the destructor waiting for the thread to // shutdown. Defer this to the main thread, instead. MOZ_ALWAYS_SUCCEEDS(NS_DispatchToMainThread(NewRunnableMethod( "nsIThread::AsyncShutdown", ioThread, &nsIThread::AsyncShutdown))); } void Manager::Init(Maybe aOldManager) { NS_ASSERT_OWNINGTHREAD(Manager); // Create the context immediately. Since there can at most be one Context // per Manager now, this lets us cleanly call Factory::Remove() once the // Context goes away. SafeRefPtr ref = Context::Create( SafeRefPtrFromThis(), mIOThread->SerialEventTarget(), MakeSafeRefPtr(), aOldManager ? SomeRef(*aOldManager->mContext) : Nothing()); mContext = ref.unsafeGetRawPtr(); } void Manager::Shutdown() { NS_ASSERT_OWNINGTHREAD(Manager); // Ignore duplicate attempts to shutdown. This can occur when we start // a browser initiated shutdown and then run ~Manager() which also // calls Shutdown(). if (mShuttingDown) { return; } mShuttingDown = true; // Note that we are closing to prevent any new requests from coming in and // creating a new Context. We must ensure all Contexts and IO operations are // complete before shutdown proceeds. NoteClosing(); // If there is a context, then cancel and only note that we are done after // its cleaned up. if (mContext) { const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; pinnedContext->CancelAll(); return; } } Maybe Manager::MaybeDirectoryLockRef() const { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(mContext); return mContext->MaybeDirectoryLockRef(); } void Manager::Abort() { NS_ASSERT_OWNINGTHREAD(Manager); MOZ_DIAGNOSTIC_ASSERT(mContext); // Note that we are closing to prevent any new requests from coming in and // creating a new Context. We must ensure all Contexts and IO operations are // complete before origin clear proceeds. NoteClosing(); // Cancel and only note that we are done after the context is cleaned up. const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; pinnedContext->CancelAll(); } Manager::ListenerId Manager::SaveListener(Listener* aListener) { NS_ASSERT_OWNINGTHREAD(Manager); // Once a Listener is added, we keep a reference to it until its // removed. Since the same Listener might make multiple requests, // ensure we only have a single reference in our list. ListenerList::index_type index = mListeners.IndexOf(aListener, 0, ListenerEntryListenerComparator()); if (index != ListenerList::NoIndex) { return mListeners[index].mId; } ListenerId id = sNextListenerId; sNextListenerId += 1; mListeners.AppendElement(ListenerEntry(id, aListener)); return id; } Manager::Listener* Manager::GetListener(ListenerId aListenerId) const { NS_ASSERT_OWNINGTHREAD(Manager); ListenerList::index_type index = mListeners.IndexOf(aListenerId, 0, ListenerEntryIdComparator()); if (index != ListenerList::NoIndex) { return mListeners[index].mListener; } // This can legitimately happen if the actor is deleted while a request is // in process. For example, the child process OOMs. return nullptr; } bool Manager::SetCacheIdOrphanedIfRefed(CacheId aCacheId) { NS_ASSERT_OWNINGTHREAD(Manager); const auto end = mCacheIdRefs.end(); const auto foundIt = std::find_if(mCacheIdRefs.begin(), end, MatchByCacheId(aCacheId)); if (foundIt != end) { MOZ_DIAGNOSTIC_ASSERT(foundIt->mCount > 0); MOZ_DIAGNOSTIC_ASSERT(!foundIt->mOrphaned); foundIt->mOrphaned = true; return true; } return false; } // TODO: provide way to set body non-orphaned if its added back to a cache (bug // 1110479) bool Manager::SetBodyIdOrphanedIfRefed(const nsID& aBodyId) { NS_ASSERT_OWNINGTHREAD(Manager); const auto end = mBodyIdRefs.end(); const auto foundIt = std::find_if(mBodyIdRefs.begin(), end, MatchByBodyId(aBodyId)); if (foundIt != end) { MOZ_DIAGNOSTIC_ASSERT(foundIt->mCount > 0); MOZ_DIAGNOSTIC_ASSERT(!foundIt->mOrphaned); foundIt->mOrphaned = true; return true; } return false; } void Manager::NoteOrphanedBodyIdList(const nsTArray& aDeletedBodyIdList) { NS_ASSERT_OWNINGTHREAD(Manager); // XXX TransformIfIntoNewArray might be generalized to allow specifying the // type of nsTArray to create, so that it can create an AutoTArray as well; an // TransformIf (without AbortOnErr) might be added, which could be used here. DeleteOrphanedBodyAction::DeletedBodyIdList deleteNowList; deleteNowList.SetCapacity(aDeletedBodyIdList.Length()); std::copy_if(aDeletedBodyIdList.cbegin(), aDeletedBodyIdList.cend(), MakeBackInserter(deleteNowList), [this](const auto& deletedBodyId) { return !SetBodyIdOrphanedIfRefed(deletedBodyId); }); // TODO: note that we need to check these bodies for staleness on startup (bug // 1110446) const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; if (!deleteNowList.IsEmpty() && pinnedContext && !pinnedContext->IsCanceled()) { pinnedContext->Dispatch( MakeSafeRefPtr(std::move(deleteNowList))); } } void Manager::MaybeAllowContextToClose() { NS_ASSERT_OWNINGTHREAD(Manager); // If we have an active context, but we have no more users of the Manager, // then let it shut itself down. We must wait for all possible users of // Cache state information to complete before doing this. Once we allow // the Context to close we may not reliably get notified of storage // invalidation. const auto pinnedContext = SafeRefPtr{mContext, AcquireStrongRefFromRawPtr{}}; if (pinnedContext && mListeners.IsEmpty() && mCacheIdRefs.IsEmpty() && mBodyIdRefs.IsEmpty()) { // Mark this Manager as invalid so that it won't get used again. We don't // want to start any new operations once we allow the Context to close since // it may race with the underlying storage getting invalidated. NoteClosing(); pinnedContext->AllowToClose(); } } } // namespace mozilla::dom::cache