/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: sw=2 ts=2 et lcs=trail\:.,tab\:>~ : * 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 #include "nsError.h" #include "nsIMutableArray.h" #include "nsAutoPtr.h" #include "nsIMemoryReporter.h" #include "nsThreadUtils.h" #include "nsIFile.h" #include "nsIFileURL.h" #include "mozilla/Telemetry.h" #include "mozilla/Mutex.h" #include "mozilla/CondVar.h" #include "mozilla/Attributes.h" #include "mozilla/ErrorNames.h" #include "mozilla/Unused.h" #include "mozilla/dom/quota/QuotaObject.h" #include "mozIStorageAggregateFunction.h" #include "mozIStorageCompletionCallback.h" #include "mozIStorageFunction.h" #include "mozStorageAsyncStatementExecution.h" #include "mozStorageSQLFunctions.h" #include "mozStorageConnection.h" #include "mozStorageService.h" #include "mozStorageStatement.h" #include "mozStorageAsyncStatement.h" #include "mozStorageArgValueArray.h" #include "mozStoragePrivateHelpers.h" #include "mozStorageStatementData.h" #include "StorageBaseStatementInternal.h" #include "SQLCollations.h" #include "FileSystemModule.h" #include "mozStorageHelper.h" #include "GeckoProfiler.h" #include "mozilla/Logging.h" #include "prprf.h" #include "nsProxyRelease.h" #include #define MIN_AVAILABLE_BYTES_PER_CHUNKED_GROWTH 524288000 // 500 MiB // Maximum size of the pages cache per connection. #define MAX_CACHE_SIZE_KIBIBYTES 2048 // 2 MiB mozilla::LazyLogModule gStorageLog("mozStorage"); // Checks that the protected code is running on the main-thread only if the // connection was also opened on it. #ifdef DEBUG #define CHECK_MAINTHREAD_ABUSE() \ do { \ nsCOMPtr mainThread = do_GetMainThread(); \ NS_WARNING_ASSERTION( \ threadOpenedOn == mainThread || !NS_IsMainThread(), \ "Using Storage synchronous API on main-thread, but the connection was " \ "opened on another thread."); \ } while(0) #else #define CHECK_MAINTHREAD_ABUSE() do { /* Nothing */ } while(0) #endif namespace mozilla { namespace storage { using mozilla::dom::quota::QuotaObject; namespace { int nsresultToSQLiteResult(nsresult aXPCOMResultCode) { if (NS_SUCCEEDED(aXPCOMResultCode)) { return SQLITE_OK; } switch (aXPCOMResultCode) { case NS_ERROR_FILE_CORRUPTED: return SQLITE_CORRUPT; case NS_ERROR_FILE_ACCESS_DENIED: return SQLITE_CANTOPEN; case NS_ERROR_STORAGE_BUSY: return SQLITE_BUSY; case NS_ERROR_FILE_IS_LOCKED: return SQLITE_LOCKED; case NS_ERROR_FILE_READ_ONLY: return SQLITE_READONLY; case NS_ERROR_STORAGE_IOERR: return SQLITE_IOERR; case NS_ERROR_FILE_NO_DEVICE_SPACE: return SQLITE_FULL; case NS_ERROR_OUT_OF_MEMORY: return SQLITE_NOMEM; case NS_ERROR_UNEXPECTED: return SQLITE_MISUSE; case NS_ERROR_ABORT: return SQLITE_ABORT; case NS_ERROR_STORAGE_CONSTRAINT: return SQLITE_CONSTRAINT; default: return SQLITE_ERROR; } MOZ_MAKE_COMPILER_ASSUME_IS_UNREACHABLE("Must return in switch above!"); } //////////////////////////////////////////////////////////////////////////////// //// Variant Specialization Functions (variantToSQLiteT) int sqlite3_T_int(sqlite3_context *aCtx, int aValue) { ::sqlite3_result_int(aCtx, aValue); return SQLITE_OK; } int sqlite3_T_int64(sqlite3_context *aCtx, sqlite3_int64 aValue) { ::sqlite3_result_int64(aCtx, aValue); return SQLITE_OK; } int sqlite3_T_double(sqlite3_context *aCtx, double aValue) { ::sqlite3_result_double(aCtx, aValue); return SQLITE_OK; } int sqlite3_T_text(sqlite3_context *aCtx, const nsCString &aValue) { ::sqlite3_result_text(aCtx, aValue.get(), aValue.Length(), SQLITE_TRANSIENT); return SQLITE_OK; } int sqlite3_T_text16(sqlite3_context *aCtx, const nsString &aValue) { ::sqlite3_result_text16(aCtx, aValue.get(), aValue.Length() * 2, // Number of bytes. SQLITE_TRANSIENT); return SQLITE_OK; } int sqlite3_T_null(sqlite3_context *aCtx) { ::sqlite3_result_null(aCtx); return SQLITE_OK; } int sqlite3_T_blob(sqlite3_context *aCtx, const void *aData, int aSize) { ::sqlite3_result_blob(aCtx, aData, aSize, free); return SQLITE_OK; } #include "variantToSQLiteT_impl.h" //////////////////////////////////////////////////////////////////////////////// //// Modules struct Module { const char* name; int (*registerFunc)(sqlite3*, const char*); }; Module gModules[] = { { "filesystem", RegisterFileSystemModule } }; //////////////////////////////////////////////////////////////////////////////// //// Local Functions int tracefunc (unsigned aReason, void *aClosure, void *aP, void *aX) { switch (aReason) { case SQLITE_TRACE_STMT: { // aP is a pointer to the prepared statement. sqlite3_stmt* stmt = static_cast(aP); // aX is a pointer to a string containing the unexpanded SQL or a comment, // starting with "--"" in case of a trigger. char* expanded = static_cast(aX); // Simulate what sqlite_trace was doing. if (!::strncmp(expanded, "--", 2)) { MOZ_LOG(gStorageLog, LogLevel::Debug, ("TRACE_STMT on %p: '%s'", aClosure, expanded)); } else { char* sql = ::sqlite3_expanded_sql(stmt); MOZ_LOG(gStorageLog, LogLevel::Debug, ("TRACE_STMT on %p: '%s'", aClosure, sql)); ::sqlite3_free(sql); } break; } case SQLITE_TRACE_PROFILE: { // aX is pointer to a 64bit integer containing nanoseconds it took to // execute the last command. sqlite_int64 time = *(static_cast(aX)) / 1000000; if (time > 0) { MOZ_LOG(gStorageLog, LogLevel::Debug, ("TRACE_TIME on %p: %dms", aClosure, time)); } break; } } return 0; } void basicFunctionHelper(sqlite3_context *aCtx, int aArgc, sqlite3_value **aArgv) { void *userData = ::sqlite3_user_data(aCtx); mozIStorageFunction *func = static_cast(userData); RefPtr arguments(new ArgValueArray(aArgc, aArgv)); if (!arguments) return; nsCOMPtr result; nsresult rv = func->OnFunctionCall(arguments, getter_AddRefs(result)); if (NS_FAILED(rv)) { nsAutoCString errorMessage; GetErrorName(rv, errorMessage); errorMessage.InsertLiteral("User function returned ", 0); errorMessage.Append('!'); NS_WARNING(errorMessage.get()); ::sqlite3_result_error(aCtx, errorMessage.get(), -1); ::sqlite3_result_error_code(aCtx, nsresultToSQLiteResult(rv)); return; } int retcode = variantToSQLiteT(aCtx, result); if (retcode == SQLITE_IGNORE) { ::sqlite3_result_int(aCtx, SQLITE_IGNORE); } else if (retcode != SQLITE_OK) { NS_WARNING("User function returned invalid data type!"); ::sqlite3_result_error(aCtx, "User function returned invalid data type", -1); } } void aggregateFunctionStepHelper(sqlite3_context *aCtx, int aArgc, sqlite3_value **aArgv) { void *userData = ::sqlite3_user_data(aCtx); mozIStorageAggregateFunction *func = static_cast(userData); RefPtr arguments(new ArgValueArray(aArgc, aArgv)); if (!arguments) return; if (NS_FAILED(func->OnStep(arguments))) NS_WARNING("User aggregate step function returned error code!"); } void aggregateFunctionFinalHelper(sqlite3_context *aCtx) { void *userData = ::sqlite3_user_data(aCtx); mozIStorageAggregateFunction *func = static_cast(userData); RefPtr result; if (NS_FAILED(func->OnFinal(getter_AddRefs(result)))) { NS_WARNING("User aggregate final function returned error code!"); ::sqlite3_result_error(aCtx, "User aggregate final function returned error code", -1); return; } if (variantToSQLiteT(aCtx, result) != SQLITE_OK) { NS_WARNING("User aggregate final function returned invalid data type!"); ::sqlite3_result_error(aCtx, "User aggregate final function returned invalid data type", -1); } } /** * This code is heavily based on the sample at: * http://www.sqlite.org/unlock_notify.html */ class UnlockNotification { public: UnlockNotification() : mMutex("UnlockNotification mMutex") , mCondVar(mMutex, "UnlockNotification condVar") , mSignaled(false) { } void Wait() { MutexAutoLock lock(mMutex); while (!mSignaled) { (void)mCondVar.Wait(); } } void Signal() { MutexAutoLock lock(mMutex); mSignaled = true; (void)mCondVar.Notify(); } private: Mutex mMutex; CondVar mCondVar; bool mSignaled; }; void UnlockNotifyCallback(void **aArgs, int aArgsSize) { for (int i = 0; i < aArgsSize; i++) { UnlockNotification *notification = static_cast(aArgs[i]); notification->Signal(); } } int WaitForUnlockNotify(sqlite3* aDatabase) { UnlockNotification notification; int srv = ::sqlite3_unlock_notify(aDatabase, UnlockNotifyCallback, ¬ification); MOZ_ASSERT(srv == SQLITE_LOCKED || srv == SQLITE_OK); if (srv == SQLITE_OK) { notification.Wait(); } return srv; } } // namespace //////////////////////////////////////////////////////////////////////////////// //// Local Classes namespace { class AsyncCloseConnection final: public Runnable { public: AsyncCloseConnection(Connection *aConnection, sqlite3 *aNativeConnection, nsIRunnable *aCallbackEvent, already_AddRefed aAsyncExecutionThread) : mConnection(aConnection) , mNativeConnection(aNativeConnection) , mCallbackEvent(aCallbackEvent) , mAsyncExecutionThread(aAsyncExecutionThread) { } NS_IMETHOD Run() override { #ifdef DEBUG // This code is executed on the background thread bool onAsyncThread = false; (void)mAsyncExecutionThread->IsOnCurrentThread(&onAsyncThread); MOZ_ASSERT(onAsyncThread); #endif // DEBUG nsCOMPtr event = NewRunnableMethod> (mConnection, &Connection::shutdownAsyncThread, mAsyncExecutionThread); (void)NS_DispatchToMainThread(event); // Internal close. (void)mConnection->internalClose(mNativeConnection); // Callback if (mCallbackEvent) { nsCOMPtr thread; (void)NS_GetMainThread(getter_AddRefs(thread)); (void)thread->Dispatch(mCallbackEvent, NS_DISPATCH_NORMAL); } return NS_OK; } ~AsyncCloseConnection() { NS_ReleaseOnMainThread(mConnection.forget()); NS_ReleaseOnMainThread(mCallbackEvent.forget()); } private: RefPtr mConnection; sqlite3 *mNativeConnection; nsCOMPtr mCallbackEvent; nsCOMPtr mAsyncExecutionThread; }; /** * An event used to initialize the clone of a connection. * * Must be executed on the clone's async execution thread. */ class AsyncInitializeClone final: public Runnable { public: /** * @param aConnection The connection being cloned. * @param aClone The clone. * @param aReadOnly If |true|, the clone is read only. * @param aCallback A callback to trigger once initialization * is complete. This event will be called on * aClone->threadOpenedOn. */ AsyncInitializeClone(Connection* aConnection, Connection* aClone, const bool aReadOnly, mozIStorageCompletionCallback* aCallback) : mConnection(aConnection) , mClone(aClone) , mReadOnly(aReadOnly) , mCallback(aCallback) { MOZ_ASSERT(NS_IsMainThread()); } NS_IMETHOD Run() override { MOZ_ASSERT (NS_GetCurrentThread() == mConnection->getAsyncExecutionTarget()); nsresult rv = mConnection->initializeClone(mClone, mReadOnly); if (NS_FAILED(rv)) { return Dispatch(rv, nullptr); } return Dispatch(NS_OK, NS_ISUPPORTS_CAST(mozIStorageAsyncConnection*, mClone)); } private: nsresult Dispatch(nsresult aResult, nsISupports* aValue) { RefPtr event = new CallbackComplete(aResult, aValue, mCallback.forget()); return mClone->threadOpenedOn->Dispatch(event, NS_DISPATCH_NORMAL); } ~AsyncInitializeClone() { nsCOMPtr thread; DebugOnly rv = NS_GetMainThread(getter_AddRefs(thread)); MOZ_ASSERT(NS_SUCCEEDED(rv)); // Handle ambiguous nsISupports inheritance. NS_ProxyRelease(thread, mConnection.forget()); NS_ProxyRelease(thread, mClone.forget()); // Generally, the callback will be released by CallbackComplete. // However, if for some reason Run() is not executed, we still // need to ensure that it is released here. NS_ProxyRelease(thread, mCallback.forget()); } RefPtr mConnection; RefPtr mClone; const bool mReadOnly; nsCOMPtr mCallback; }; } // namespace //////////////////////////////////////////////////////////////////////////////// //// Connection Connection::Connection(Service *aService, int aFlags, bool aAsyncOnly, bool aIgnoreLockingMode) : sharedAsyncExecutionMutex("Connection::sharedAsyncExecutionMutex") , sharedDBMutex("Connection::sharedDBMutex") , threadOpenedOn(do_GetCurrentThread()) , mDBConn(nullptr) , mAsyncExecutionThreadShuttingDown(false) #ifdef DEBUG , mAsyncExecutionThreadIsAlive(false) #endif , mConnectionClosed(false) , mTransactionInProgress(false) , mProgressHandler(nullptr) , mFlags(aFlags) , mIgnoreLockingMode(aIgnoreLockingMode) , mStorageService(aService) , mAsyncOnly(aAsyncOnly) { MOZ_ASSERT(!mIgnoreLockingMode || mFlags & SQLITE_OPEN_READONLY, "Can't ignore locking for a non-readonly connection!"); mStorageService->registerConnection(this); } Connection::~Connection() { (void)Close(); MOZ_ASSERT(!mAsyncExecutionThread, "AsyncClose has not been invoked on this connection!"); MOZ_ASSERT(!mAsyncExecutionThreadIsAlive, "The async execution thread should have been shutdown!"); } NS_IMPL_ADDREF(Connection) NS_INTERFACE_MAP_BEGIN(Connection) NS_INTERFACE_MAP_ENTRY(mozIStorageAsyncConnection) NS_INTERFACE_MAP_ENTRY(nsIInterfaceRequestor) NS_INTERFACE_MAP_ENTRY_CONDITIONAL(mozIStorageConnection, !mAsyncOnly) NS_INTERFACE_MAP_ENTRY_AMBIGUOUS(nsISupports, mozIStorageConnection) NS_INTERFACE_MAP_END // This is identical to what NS_IMPL_RELEASE provides, but with the // extra |1 == count| case. NS_IMETHODIMP_(MozExternalRefCountType) Connection::Release(void) { NS_PRECONDITION(0 != mRefCnt, "dup release"); nsrefcnt count = --mRefCnt; NS_LOG_RELEASE(this, count, "Connection"); if (1 == count) { // If the refcount is 1, the single reference must be from // gService->mConnections (in class |Service|). Which means we can // unregister it safely. mStorageService->unregisterConnection(this); } else if (0 == count) { mRefCnt = 1; /* stabilize */ #if 0 /* enable this to find non-threadsafe destructors: */ NS_ASSERT_OWNINGTHREAD(Connection); #endif delete (this); return 0; } return count; } int32_t Connection::getSqliteRuntimeStatus(int32_t aStatusOption, int32_t* aMaxValue) { MOZ_ASSERT(mDBConn, "A connection must exist at this point"); int curr = 0, max = 0; DebugOnly rc = ::sqlite3_db_status(mDBConn, aStatusOption, &curr, &max, 0); MOZ_ASSERT(NS_SUCCEEDED(convertResultCode(rc))); if (aMaxValue) *aMaxValue = max; return curr; } nsIEventTarget * Connection::getAsyncExecutionTarget() { MutexAutoLock lockedScope(sharedAsyncExecutionMutex); // If we are shutting down the asynchronous thread, don't hand out any more // references to the thread. if (mAsyncExecutionThreadShuttingDown) return nullptr; if (!mAsyncExecutionThread) { nsresult rv = ::NS_NewThread(getter_AddRefs(mAsyncExecutionThread)); if (NS_FAILED(rv)) { NS_WARNING("Failed to create async thread."); return nullptr; } static nsThreadPoolNaming naming; naming.SetThreadPoolName(NS_LITERAL_CSTRING("mozStorage"), mAsyncExecutionThread); } #ifdef DEBUG mAsyncExecutionThreadIsAlive = true; #endif return mAsyncExecutionThread; } nsresult Connection::initialize() { NS_ASSERTION (!mDBConn, "Initialize called on already opened database!"); MOZ_ASSERT(!mIgnoreLockingMode, "Can't ignore locking on an in-memory db."); PROFILER_LABEL("mozStorageConnection", "initialize", js::ProfileEntry::Category::STORAGE); // in memory database requested, sqlite uses a magic file name int srv = ::sqlite3_open_v2(":memory:", &mDBConn, mFlags, nullptr); if (srv != SQLITE_OK) { mDBConn = nullptr; return convertResultCode(srv); } // Do not set mDatabaseFile or mFileURL here since this is a "memory" // database. nsresult rv = initializeInternal(); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult Connection::initialize(nsIFile *aDatabaseFile) { NS_ASSERTION (aDatabaseFile, "Passed null file!"); NS_ASSERTION (!mDBConn, "Initialize called on already opened database!"); PROFILER_LABEL("mozStorageConnection", "initialize", js::ProfileEntry::Category::STORAGE); mDatabaseFile = aDatabaseFile; nsAutoString path; nsresult rv = aDatabaseFile->GetPath(path); NS_ENSURE_SUCCESS(rv, rv); #ifdef XP_WIN static const char* sIgnoreLockingVFS = "win32-none"; #else static const char* sIgnoreLockingVFS = "unix-none"; #endif const char* vfs = mIgnoreLockingMode ? sIgnoreLockingVFS : nullptr; int srv = ::sqlite3_open_v2(NS_ConvertUTF16toUTF8(path).get(), &mDBConn, mFlags, vfs); if (srv != SQLITE_OK) { mDBConn = nullptr; return convertResultCode(srv); } // Do not set mFileURL here since this is database does not have an associated // URL. mDatabaseFile = aDatabaseFile; rv = initializeInternal(); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult Connection::initialize(nsIFileURL *aFileURL) { NS_ASSERTION (aFileURL, "Passed null file URL!"); NS_ASSERTION (!mDBConn, "Initialize called on already opened database!"); PROFILER_LABEL("mozStorageConnection", "initialize", js::ProfileEntry::Category::STORAGE); nsCOMPtr databaseFile; nsresult rv = aFileURL->GetFile(getter_AddRefs(databaseFile)); NS_ENSURE_SUCCESS(rv, rv); nsAutoCString spec; rv = aFileURL->GetSpec(spec); NS_ENSURE_SUCCESS(rv, rv); int srv = ::sqlite3_open_v2(spec.get(), &mDBConn, mFlags, nullptr); if (srv != SQLITE_OK) { mDBConn = nullptr; return convertResultCode(srv); } // Set both mDatabaseFile and mFileURL here. mFileURL = aFileURL; mDatabaseFile = databaseFile; rv = initializeInternal(); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } nsresult Connection::initializeInternal() { MOZ_ASSERT(mDBConn); if (mFileURL) { const char* dbPath = ::sqlite3_db_filename(mDBConn, "main"); MOZ_ASSERT(dbPath); const char* telemetryFilename = ::sqlite3_uri_parameter(dbPath, "telemetryFilename"); if (telemetryFilename) { if (NS_WARN_IF(*telemetryFilename == '\0')) { return NS_ERROR_INVALID_ARG; } mTelemetryFilename = telemetryFilename; } } if (mTelemetryFilename.IsEmpty()) { mTelemetryFilename = getFilename(); MOZ_ASSERT(!mTelemetryFilename.IsEmpty()); } // Properly wrap the database handle's mutex. sharedDBMutex.initWithMutex(sqlite3_db_mutex(mDBConn)); // SQLite tracing can slow down queries (especially long queries) // significantly. Don't trace unless the user is actively monitoring SQLite. if (MOZ_LOG_TEST(gStorageLog, LogLevel::Debug)) { ::sqlite3_trace_v2(mDBConn, SQLITE_TRACE_STMT | SQLITE_TRACE_PROFILE, tracefunc, this); MOZ_LOG(gStorageLog, LogLevel::Debug, ("Opening connection to '%s' (%p)", mTelemetryFilename.get(), this)); } int64_t pageSize = Service::getDefaultPageSize(); // Set page_size to the preferred default value. This is effective only if // the database has just been created, otherwise, if the database does not // use WAL journal mode, a VACUUM operation will updated its page_size. nsAutoCString pageSizeQuery(MOZ_STORAGE_UNIQUIFY_QUERY_STR "PRAGMA page_size = "); pageSizeQuery.AppendInt(pageSize); nsresult rv = ExecuteSimpleSQL(pageSizeQuery); NS_ENSURE_SUCCESS(rv, rv); // Setting the cache_size forces the database open, verifying if it is valid // or corrupt. So this is executed regardless it being actually needed. // The cache_size is calculated from the actual page_size, to save memory. nsAutoCString cacheSizeQuery(MOZ_STORAGE_UNIQUIFY_QUERY_STR "PRAGMA cache_size = "); cacheSizeQuery.AppendInt(-MAX_CACHE_SIZE_KIBIBYTES); int srv = executeSql(mDBConn, cacheSizeQuery.get()); if (srv != SQLITE_OK) { ::sqlite3_close(mDBConn); mDBConn = nullptr; return convertResultCode(srv); } #if defined(MOZ_MEMORY_TEMP_STORE_PRAGMA) (void)ExecuteSimpleSQL(NS_LITERAL_CSTRING("PRAGMA temp_store = 2;")); #endif // Register our built-in SQL functions. srv = registerFunctions(mDBConn); if (srv != SQLITE_OK) { ::sqlite3_close(mDBConn); mDBConn = nullptr; return convertResultCode(srv); } // Register our built-in SQL collating sequences. srv = registerCollations(mDBConn, mStorageService); if (srv != SQLITE_OK) { ::sqlite3_close(mDBConn); mDBConn = nullptr; return convertResultCode(srv); } // Set the synchronous PRAGMA, according to the preference. switch (Service::getSynchronousPref()) { case 2: (void)ExecuteSimpleSQL(NS_LITERAL_CSTRING( "PRAGMA synchronous = FULL;")); break; case 0: (void)ExecuteSimpleSQL(NS_LITERAL_CSTRING( "PRAGMA synchronous = OFF;")); break; case 1: default: (void)ExecuteSimpleSQL(NS_LITERAL_CSTRING( "PRAGMA synchronous = NORMAL;")); break; } return NS_OK; } nsresult Connection::databaseElementExists(enum DatabaseElementType aElementType, const nsACString &aElementName, bool *_exists) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; // When constructing the query, make sure to SELECT the correct db's sqlite_master // if the user is prefixing the element with a specific db. ex: sample.test nsCString query("SELECT name FROM (SELECT * FROM "); nsDependentCSubstring element; int32_t ind = aElementName.FindChar('.'); if (ind == kNotFound) { element.Assign(aElementName); } else { nsDependentCSubstring db(Substring(aElementName, 0, ind + 1)); element.Assign(Substring(aElementName, ind + 1, aElementName.Length())); query.Append(db); } query.AppendLiteral("sqlite_master UNION ALL SELECT * FROM sqlite_temp_master) WHERE type = '"); switch (aElementType) { case INDEX: query.AppendLiteral("index"); break; case TABLE: query.AppendLiteral("table"); break; } query.AppendLiteral("' AND name ='"); query.Append(element); query.Append('\''); sqlite3_stmt *stmt; int srv = prepareStatement(mDBConn, query, &stmt); if (srv != SQLITE_OK) return convertResultCode(srv); srv = stepStatement(mDBConn, stmt); // we just care about the return value from step (void)::sqlite3_finalize(stmt); if (srv == SQLITE_ROW) { *_exists = true; return NS_OK; } if (srv == SQLITE_DONE) { *_exists = false; return NS_OK; } return convertResultCode(srv); } bool Connection::findFunctionByInstance(nsISupports *aInstance) { sharedDBMutex.assertCurrentThreadOwns(); for (auto iter = mFunctions.Iter(); !iter.Done(); iter.Next()) { if (iter.UserData().function == aInstance) { return true; } } return false; } /* static */ int Connection::sProgressHelper(void *aArg) { Connection *_this = static_cast(aArg); return _this->progressHandler(); } int Connection::progressHandler() { sharedDBMutex.assertCurrentThreadOwns(); if (mProgressHandler) { bool result; nsresult rv = mProgressHandler->OnProgress(this, &result); if (NS_FAILED(rv)) return 0; // Don't break request return result ? 1 : 0; } return 0; } nsresult Connection::setClosedState() { // Ensure that we are on the correct thread to close the database. bool onOpenedThread; nsresult rv = threadOpenedOn->IsOnCurrentThread(&onOpenedThread); NS_ENSURE_SUCCESS(rv, rv); if (!onOpenedThread) { NS_ERROR("Must close the database on the thread that you opened it with!"); return NS_ERROR_UNEXPECTED; } // Flag that we are shutting down the async thread, so that // getAsyncExecutionTarget knows not to expose/create the async thread. { MutexAutoLock lockedScope(sharedAsyncExecutionMutex); NS_ENSURE_FALSE(mAsyncExecutionThreadShuttingDown, NS_ERROR_UNEXPECTED); mAsyncExecutionThreadShuttingDown = true; } // Set the property to null before closing the connection, otherwise the other // functions in the module may try to use the connection after it is closed. mDBConn = nullptr; return NS_OK; } bool Connection::connectionReady() { return mDBConn != nullptr; } bool Connection::isClosing() { bool shuttingDown = false; { MutexAutoLock lockedScope(sharedAsyncExecutionMutex); shuttingDown = mAsyncExecutionThreadShuttingDown; } return shuttingDown && !isClosed(); } bool Connection::isClosed() { MutexAutoLock lockedScope(sharedAsyncExecutionMutex); return mConnectionClosed; } void Connection::shutdownAsyncThread(nsIThread *aThread) { MOZ_ASSERT(!mAsyncExecutionThread); MOZ_ASSERT(mAsyncExecutionThreadIsAlive); MOZ_ASSERT(mAsyncExecutionThreadShuttingDown); DebugOnly rv = aThread->Shutdown(); MOZ_ASSERT(NS_SUCCEEDED(rv)); #ifdef DEBUG mAsyncExecutionThreadIsAlive = false; #endif } nsresult Connection::internalClose(sqlite3 *aNativeConnection) { // Sanity checks to make sure we are in the proper state before calling this. // aNativeConnection can be null if OpenAsyncDatabase failed and is now just // cleaning up the async thread. MOZ_ASSERT(!isClosed()); #ifdef DEBUG { // Make sure we have marked our async thread as shutting down. MutexAutoLock lockedScope(sharedAsyncExecutionMutex); NS_ASSERTION(mAsyncExecutionThreadShuttingDown, "Did not call setClosedState!"); } #endif // DEBUG if (MOZ_LOG_TEST(gStorageLog, LogLevel::Debug)) { nsAutoCString leafName(":memory"); if (mDatabaseFile) (void)mDatabaseFile->GetNativeLeafName(leafName); MOZ_LOG(gStorageLog, LogLevel::Debug, ("Closing connection to '%s'", leafName.get())); } // At this stage, we may still have statements that need to be // finalized. Attempt to close the database connection. This will // always disconnect any virtual tables and cleanly finalize their // internal statements. Once this is done, closing may fail due to // unfinalized client statements, in which case we need to finalize // these statements and close again. { MutexAutoLock lockedScope(sharedAsyncExecutionMutex); mConnectionClosed = true; } // Nothing else needs to be done if we don't have a connection here. if (!aNativeConnection) return NS_OK; int srv = sqlite3_close(aNativeConnection); if (srv == SQLITE_BUSY) { // We still have non-finalized statements. Finalize them. sqlite3_stmt *stmt = nullptr; while ((stmt = ::sqlite3_next_stmt(aNativeConnection, stmt))) { MOZ_LOG(gStorageLog, LogLevel::Debug, ("Auto-finalizing SQL statement '%s' (%x)", ::sqlite3_sql(stmt), stmt)); #ifdef DEBUG char *msg = ::PR_smprintf("SQL statement '%s' (%x) should have been finalized before closing the connection", ::sqlite3_sql(stmt), stmt); NS_WARNING(msg); ::PR_smprintf_free(msg); msg = nullptr; #endif // DEBUG srv = ::sqlite3_finalize(stmt); #ifdef DEBUG if (srv != SQLITE_OK) { msg = ::PR_smprintf("Could not finalize SQL statement '%s' (%x)", ::sqlite3_sql(stmt), stmt); NS_WARNING(msg); ::PR_smprintf_free(msg); msg = nullptr; } #endif // DEBUG // Ensure that the loop continues properly, whether closing has succeeded // or not. if (srv == SQLITE_OK) { stmt = nullptr; } } // Now that all statements have been finalized, we // should be able to close. srv = ::sqlite3_close(aNativeConnection); } if (srv != SQLITE_OK) { MOZ_ASSERT(srv == SQLITE_OK, "sqlite3_close failed. There are probably outstanding statements that are listed above!"); } return convertResultCode(srv); } nsCString Connection::getFilename() { nsCString leafname(":memory:"); if (mDatabaseFile) { (void)mDatabaseFile->GetNativeLeafName(leafname); } return leafname; } int Connection::stepStatement(sqlite3 *aNativeConnection, sqlite3_stmt *aStatement) { MOZ_ASSERT(aStatement); bool checkedMainThread = false; TimeStamp startTime = TimeStamp::Now(); // The connection may have been closed if the executing statement has been // created and cached after a call to asyncClose() but before the actual // sqlite3_close(). This usually happens when other tasks using cached // statements are asynchronously scheduled for execution and any of them ends // up after asyncClose. See bug 728653 for details. if (isClosed()) return SQLITE_MISUSE; (void)::sqlite3_extended_result_codes(aNativeConnection, 1); int srv; while ((srv = ::sqlite3_step(aStatement)) == SQLITE_LOCKED_SHAREDCACHE) { if (!checkedMainThread) { checkedMainThread = true; if (::NS_IsMainThread()) { NS_WARNING("We won't allow blocking on the main thread!"); break; } } srv = WaitForUnlockNotify(aNativeConnection); if (srv != SQLITE_OK) { break; } ::sqlite3_reset(aStatement); } // Report very slow SQL statements to Telemetry TimeDuration duration = TimeStamp::Now() - startTime; const uint32_t threshold = NS_IsMainThread() ? Telemetry::kSlowSQLThresholdForMainThread : Telemetry::kSlowSQLThresholdForHelperThreads; if (duration.ToMilliseconds() >= threshold) { nsDependentCString statementString(::sqlite3_sql(aStatement)); Telemetry::RecordSlowSQLStatement(statementString, mTelemetryFilename, duration.ToMilliseconds()); } (void)::sqlite3_extended_result_codes(aNativeConnection, 0); // Drop off the extended result bits of the result code. return srv & 0xFF; } int Connection::prepareStatement(sqlite3 *aNativeConnection, const nsCString &aSQL, sqlite3_stmt **_stmt) { // We should not even try to prepare statements after the connection has // been closed. if (isClosed()) return SQLITE_MISUSE; bool checkedMainThread = false; (void)::sqlite3_extended_result_codes(aNativeConnection, 1); int srv; while((srv = ::sqlite3_prepare_v2(aNativeConnection, aSQL.get(), -1, _stmt, nullptr)) == SQLITE_LOCKED_SHAREDCACHE) { if (!checkedMainThread) { checkedMainThread = true; if (::NS_IsMainThread()) { NS_WARNING("We won't allow blocking on the main thread!"); break; } } srv = WaitForUnlockNotify(aNativeConnection); if (srv != SQLITE_OK) { break; } } if (srv != SQLITE_OK) { nsCString warnMsg; warnMsg.AppendLiteral("The SQL statement '"); warnMsg.Append(aSQL); warnMsg.AppendLiteral("' could not be compiled due to an error: "); warnMsg.Append(::sqlite3_errmsg(aNativeConnection)); #ifdef DEBUG NS_WARNING(warnMsg.get()); #endif MOZ_LOG(gStorageLog, LogLevel::Error, ("%s", warnMsg.get())); } (void)::sqlite3_extended_result_codes(aNativeConnection, 0); // Drop off the extended result bits of the result code. int rc = srv & 0xFF; // sqlite will return OK on a comment only string and set _stmt to nullptr. // The callers of this function are used to only checking the return value, // so it is safer to return an error code. if (rc == SQLITE_OK && *_stmt == nullptr) { return SQLITE_MISUSE; } return rc; } int Connection::executeSql(sqlite3 *aNativeConnection, const char *aSqlString) { if (isClosed()) return SQLITE_MISUSE; TimeStamp startTime = TimeStamp::Now(); int srv = ::sqlite3_exec(aNativeConnection, aSqlString, nullptr, nullptr, nullptr); // Report very slow SQL statements to Telemetry TimeDuration duration = TimeStamp::Now() - startTime; const uint32_t threshold = NS_IsMainThread() ? Telemetry::kSlowSQLThresholdForMainThread : Telemetry::kSlowSQLThresholdForHelperThreads; if (duration.ToMilliseconds() >= threshold) { nsDependentCString statementString(aSqlString); Telemetry::RecordSlowSQLStatement(statementString, mTelemetryFilename, duration.ToMilliseconds()); } return srv; } //////////////////////////////////////////////////////////////////////////////// //// nsIInterfaceRequestor NS_IMETHODIMP Connection::GetInterface(const nsIID &aIID, void **_result) { if (aIID.Equals(NS_GET_IID(nsIEventTarget))) { nsIEventTarget *background = getAsyncExecutionTarget(); NS_IF_ADDREF(background); *_result = background; return NS_OK; } return NS_ERROR_NO_INTERFACE; } //////////////////////////////////////////////////////////////////////////////// //// mozIStorageConnection NS_IMETHODIMP Connection::Close() { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; { // Make sure we have not executed any asynchronous statements. // If this fails, the mDBConn will be left open, resulting in a leak. // Ideally we'd schedule some code to destroy the mDBConn once all its // async statements have finished executing; see bug 704030. MutexAutoLock lockedScope(sharedAsyncExecutionMutex); bool asyncCloseWasCalled = !mAsyncExecutionThread; NS_ENSURE_TRUE(asyncCloseWasCalled, NS_ERROR_UNEXPECTED); } // setClosedState nullifies our connection pointer, so we take a raw pointer // off it, to pass it through the close procedure. sqlite3 *nativeConn = mDBConn; nsresult rv = setClosedState(); NS_ENSURE_SUCCESS(rv, rv); return internalClose(nativeConn); } NS_IMETHODIMP Connection::AsyncClose(mozIStorageCompletionCallback *aCallback) { if (!NS_IsMainThread()) { return NS_ERROR_NOT_SAME_THREAD; } // The two relevant factors at this point are whether we have a database // connection and whether we have an async execution thread. Here's what the // states mean and how we handle them: // // - (mDBConn && asyncThread): The expected case where we are either an // async connection or a sync connection that has been used asynchronously. // Either way the caller must call us and not Close(). Nothing surprising // about this. We'll dispatch AsyncCloseConnection to the already-existing // async thread. // // - (mDBConn && !asyncThread): A somewhat unusual case where the caller // opened the connection synchronously and was planning to use it // asynchronously, but never got around to using it asynchronously before // needing to shutdown. This has been observed to happen for the cookie // service in a case where Firefox shuts itself down almost immediately // after startup (for unknown reasons). In the Firefox shutdown case, // we may also fail to create a new async execution thread if one does not // already exist. (nsThreadManager will refuse to create new threads when // it has already been told to shutdown.) As such, we need to handle a // failure to create the async execution thread by falling back to // synchronous Close() and also dispatching the completion callback because // at least Places likes to spin a nested event loop that depends on the // callback being invoked. // // Note that we have considered not trying to spin up the async execution // thread in this case if it does not already exist, but the overhead of // thread startup (if successful) is significantly less expensive than the // worst-case potential I/O hit of synchronously closing a database when we // could close it asynchronously. // // - (!mDBConn && asyncThread): This happens in some but not all cases where // OpenAsyncDatabase encountered a problem opening the database. If it // happened in all cases AsyncInitDatabase would just shut down the thread // directly and we would avoid this case. But it doesn't, so for simplicity // and consistency AsyncCloseConnection knows how to handle this and we // act like this was the (mDBConn && asyncThread) case in this method. // // - (!mDBConn && !asyncThread): The database was never successfully opened or // Close() or AsyncClose() has already been called (at least) once. This is // undeniably a misuse case by the caller. We could optimize for this // case by adding an additional check of mAsyncExecutionThread without using // getAsyncExecutionTarget() to avoid wastefully creating a thread just to // shut it down. But this complicates the method for broken caller code // whereas we're still correct and safe without the special-case. nsIEventTarget *asyncThread = getAsyncExecutionTarget(); // Create our callback event if we were given a callback. This will // eventually be dispatched in all cases, even if we fall back to Close() and // the database wasn't open and we return an error. The rationale is that // no existing consumer checks our return value and several of them like to // spin nested event loops until the callback fires. Given that, it seems // preferable for us to dispatch the callback in all cases. (Except the // wrong thread misuse case we bailed on up above. But that's okay because // that is statically wrong whereas these edge cases are dynamic.) nsCOMPtr completeEvent; if (aCallback) { completeEvent = newCompletionEvent(aCallback); } if (!asyncThread) { // We were unable to create an async thread, so we need to fall back to // using normal Close(). Since there is no async thread, Close() will // not complain about that. (Close() may, however, complain if the // connection is closed, but that's okay.) if (completeEvent) { // Closing the database is more important than returning an error code // about a failure to dispatch, especially because all existing native // callers ignore our return value. Unused << NS_DispatchToMainThread(completeEvent.forget()); } return Close(); } // setClosedState nullifies our connection pointer, so we take a raw pointer // off it, to pass it through the close procedure. sqlite3 *nativeConn = mDBConn; nsresult rv = setClosedState(); NS_ENSURE_SUCCESS(rv, rv); // Create and dispatch our close event to the background thread. nsCOMPtr closeEvent; { // We need to lock because we're modifying mAsyncExecutionThread MutexAutoLock lockedScope(sharedAsyncExecutionMutex); closeEvent = new AsyncCloseConnection(this, nativeConn, completeEvent, mAsyncExecutionThread.forget()); } rv = asyncThread->Dispatch(closeEvent, NS_DISPATCH_NORMAL); NS_ENSURE_SUCCESS(rv, rv); return NS_OK; } NS_IMETHODIMP Connection::AsyncClone(bool aReadOnly, mozIStorageCompletionCallback *aCallback) { PROFILER_LABEL("mozStorageConnection", "AsyncClone", js::ProfileEntry::Category::STORAGE); if (!NS_IsMainThread()) { return NS_ERROR_NOT_SAME_THREAD; } if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; if (!mDatabaseFile) return NS_ERROR_UNEXPECTED; int flags = mFlags; if (aReadOnly) { // Turn off SQLITE_OPEN_READWRITE, and set SQLITE_OPEN_READONLY. flags = (~SQLITE_OPEN_READWRITE & flags) | SQLITE_OPEN_READONLY; // Turn off SQLITE_OPEN_CREATE. flags = (~SQLITE_OPEN_CREATE & flags); } RefPtr clone = new Connection(mStorageService, flags, mAsyncOnly); RefPtr initEvent = new AsyncInitializeClone(this, clone, aReadOnly, aCallback); // Dispatch to our async thread, since the originating connection must remain // valid and open for the whole cloning process. This also ensures we are // properly serialized with a `close` operation, rather than race with it. nsCOMPtr target = getAsyncExecutionTarget(); if (!target) { return NS_ERROR_UNEXPECTED; } return target->Dispatch(initEvent, NS_DISPATCH_NORMAL); } nsresult Connection::initializeClone(Connection* aClone, bool aReadOnly) { nsresult rv = mFileURL ? aClone->initialize(mFileURL) : aClone->initialize(mDatabaseFile); if (NS_FAILED(rv)) { return rv; } // Re-attach on-disk databases that were attached to the original connection. { nsCOMPtr stmt; rv = CreateStatement(NS_LITERAL_CSTRING("PRAGMA database_list"), getter_AddRefs(stmt)); MOZ_ASSERT(NS_SUCCEEDED(rv)); bool hasResult = false; while (stmt && NS_SUCCEEDED(stmt->ExecuteStep(&hasResult)) && hasResult) { nsAutoCString name; rv = stmt->GetUTF8String(1, name); if (NS_SUCCEEDED(rv) && !name.Equals(NS_LITERAL_CSTRING("main")) && !name.Equals(NS_LITERAL_CSTRING("temp"))) { nsCString path; rv = stmt->GetUTF8String(2, path); if (NS_SUCCEEDED(rv) && !path.IsEmpty()) { rv = aClone->ExecuteSimpleSQL(NS_LITERAL_CSTRING("ATTACH DATABASE '") + path + NS_LITERAL_CSTRING("' AS ") + name); MOZ_ASSERT(NS_SUCCEEDED(rv), "couldn't re-attach database to cloned connection"); } } } } // Copy over pragmas from the original connection. static const char * pragmas[] = { "cache_size", "temp_store", "foreign_keys", "journal_size_limit", "synchronous", "wal_autocheckpoint", "busy_timeout" }; for (uint32_t i = 0; i < ArrayLength(pragmas); ++i) { // Read-only connections just need cache_size and temp_store pragmas. if (aReadOnly && ::strcmp(pragmas[i], "cache_size") != 0 && ::strcmp(pragmas[i], "temp_store") != 0) { continue; } nsAutoCString pragmaQuery("PRAGMA "); pragmaQuery.Append(pragmas[i]); nsCOMPtr stmt; rv = CreateStatement(pragmaQuery, getter_AddRefs(stmt)); MOZ_ASSERT(NS_SUCCEEDED(rv)); bool hasResult = false; if (stmt && NS_SUCCEEDED(stmt->ExecuteStep(&hasResult)) && hasResult) { pragmaQuery.AppendLiteral(" = "); pragmaQuery.AppendInt(stmt->AsInt32(0)); rv = aClone->ExecuteSimpleSQL(pragmaQuery); MOZ_ASSERT(NS_SUCCEEDED(rv)); } } // Copy any functions that have been added to this connection. SQLiteMutexAutoLock lockedScope(sharedDBMutex); for (auto iter = mFunctions.Iter(); !iter.Done(); iter.Next()) { const nsACString &key = iter.Key(); Connection::FunctionInfo data = iter.UserData(); MOZ_ASSERT(data.type == Connection::FunctionInfo::SIMPLE || data.type == Connection::FunctionInfo::AGGREGATE, "Invalid function type!"); if (data.type == Connection::FunctionInfo::SIMPLE) { mozIStorageFunction *function = static_cast(data.function.get()); rv = aClone->CreateFunction(key, data.numArgs, function); if (NS_FAILED(rv)) { NS_WARNING("Failed to copy function to cloned connection"); } } else { mozIStorageAggregateFunction *function = static_cast(data.function.get()); rv = aClone->CreateAggregateFunction(key, data.numArgs, function); if (NS_FAILED(rv)) { NS_WARNING("Failed to copy aggregate function to cloned connection"); } } } return NS_OK; } NS_IMETHODIMP Connection::Clone(bool aReadOnly, mozIStorageConnection **_connection) { MOZ_ASSERT(threadOpenedOn == NS_GetCurrentThread()); PROFILER_LABEL("mozStorageConnection", "Clone", js::ProfileEntry::Category::STORAGE); if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; if (!mDatabaseFile) return NS_ERROR_UNEXPECTED; int flags = mFlags; if (aReadOnly) { // Turn off SQLITE_OPEN_READWRITE, and set SQLITE_OPEN_READONLY. flags = (~SQLITE_OPEN_READWRITE & flags) | SQLITE_OPEN_READONLY; // Turn off SQLITE_OPEN_CREATE. flags = (~SQLITE_OPEN_CREATE & flags); } RefPtr clone = new Connection(mStorageService, flags, mAsyncOnly); nsresult rv = initializeClone(clone, aReadOnly); if (NS_FAILED(rv)) { return rv; } NS_IF_ADDREF(*_connection = clone); return NS_OK; } NS_IMETHODIMP Connection::GetDefaultPageSize(int32_t *_defaultPageSize) { *_defaultPageSize = Service::getDefaultPageSize(); return NS_OK; } NS_IMETHODIMP Connection::GetConnectionReady(bool *_ready) { *_ready = connectionReady(); return NS_OK; } NS_IMETHODIMP Connection::GetDatabaseFile(nsIFile **_dbFile) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; NS_IF_ADDREF(*_dbFile = mDatabaseFile); return NS_OK; } NS_IMETHODIMP Connection::GetLastInsertRowID(int64_t *_id) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; sqlite_int64 id = ::sqlite3_last_insert_rowid(mDBConn); *_id = id; return NS_OK; } NS_IMETHODIMP Connection::GetAffectedRows(int32_t *_rows) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; *_rows = ::sqlite3_changes(mDBConn); return NS_OK; } NS_IMETHODIMP Connection::GetLastError(int32_t *_error) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; *_error = ::sqlite3_errcode(mDBConn); return NS_OK; } NS_IMETHODIMP Connection::GetLastErrorString(nsACString &_errorString) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; const char *serr = ::sqlite3_errmsg(mDBConn); _errorString.Assign(serr); return NS_OK; } NS_IMETHODIMP Connection::GetSchemaVersion(int32_t *_version) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; nsCOMPtr stmt; (void)CreateStatement(NS_LITERAL_CSTRING("PRAGMA user_version"), getter_AddRefs(stmt)); NS_ENSURE_TRUE(stmt, NS_ERROR_OUT_OF_MEMORY); *_version = 0; bool hasResult; if (NS_SUCCEEDED(stmt->ExecuteStep(&hasResult)) && hasResult) *_version = stmt->AsInt32(0); return NS_OK; } NS_IMETHODIMP Connection::SetSchemaVersion(int32_t aVersion) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; nsAutoCString stmt(NS_LITERAL_CSTRING("PRAGMA user_version = ")); stmt.AppendInt(aVersion); return ExecuteSimpleSQL(stmt); } NS_IMETHODIMP Connection::CreateStatement(const nsACString &aSQLStatement, mozIStorageStatement **_stmt) { NS_ENSURE_ARG_POINTER(_stmt); if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; RefPtr statement(new Statement()); NS_ENSURE_TRUE(statement, NS_ERROR_OUT_OF_MEMORY); nsresult rv = statement->initialize(this, mDBConn, aSQLStatement); NS_ENSURE_SUCCESS(rv, rv); Statement *rawPtr; statement.forget(&rawPtr); *_stmt = rawPtr; return NS_OK; } NS_IMETHODIMP Connection::CreateAsyncStatement(const nsACString &aSQLStatement, mozIStorageAsyncStatement **_stmt) { NS_ENSURE_ARG_POINTER(_stmt); if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; RefPtr statement(new AsyncStatement()); NS_ENSURE_TRUE(statement, NS_ERROR_OUT_OF_MEMORY); nsresult rv = statement->initialize(this, mDBConn, aSQLStatement); NS_ENSURE_SUCCESS(rv, rv); AsyncStatement *rawPtr; statement.forget(&rawPtr); *_stmt = rawPtr; return NS_OK; } NS_IMETHODIMP Connection::ExecuteSimpleSQL(const nsACString &aSQLStatement) { CHECK_MAINTHREAD_ABUSE(); if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; int srv = executeSql(mDBConn, PromiseFlatCString(aSQLStatement).get()); return convertResultCode(srv); } NS_IMETHODIMP Connection::ExecuteAsync(mozIStorageBaseStatement **aStatements, uint32_t aNumStatements, mozIStorageStatementCallback *aCallback, mozIStoragePendingStatement **_handle) { nsTArray stmts(aNumStatements); for (uint32_t i = 0; i < aNumStatements; i++) { nsCOMPtr stmt = do_QueryInterface(aStatements[i]); // Obtain our StatementData. StatementData data; nsresult rv = stmt->getAsynchronousStatementData(data); NS_ENSURE_SUCCESS(rv, rv); NS_ASSERTION(stmt->getOwner() == this, "Statement must be from this database connection!"); // Now append it to our array. NS_ENSURE_TRUE(stmts.AppendElement(data), NS_ERROR_OUT_OF_MEMORY); } // Dispatch to the background return AsyncExecuteStatements::execute(stmts, this, mDBConn, aCallback, _handle); } NS_IMETHODIMP Connection::ExecuteSimpleSQLAsync(const nsACString &aSQLStatement, mozIStorageStatementCallback *aCallback, mozIStoragePendingStatement **_handle) { if (!NS_IsMainThread()) { return NS_ERROR_NOT_SAME_THREAD; } nsCOMPtr stmt; nsresult rv = CreateAsyncStatement(aSQLStatement, getter_AddRefs(stmt)); if (NS_FAILED(rv)) { return rv; } nsCOMPtr pendingStatement; rv = stmt->ExecuteAsync(aCallback, getter_AddRefs(pendingStatement)); if (NS_FAILED(rv)) { return rv; } pendingStatement.forget(_handle); return rv; } NS_IMETHODIMP Connection::TableExists(const nsACString &aTableName, bool *_exists) { return databaseElementExists(TABLE, aTableName, _exists); } NS_IMETHODIMP Connection::IndexExists(const nsACString &aIndexName, bool* _exists) { return databaseElementExists(INDEX, aIndexName, _exists); } NS_IMETHODIMP Connection::GetTransactionInProgress(bool *_inProgress) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; SQLiteMutexAutoLock lockedScope(sharedDBMutex); *_inProgress = mTransactionInProgress; return NS_OK; } NS_IMETHODIMP Connection::BeginTransaction() { return BeginTransactionAs(mozIStorageConnection::TRANSACTION_DEFERRED); } NS_IMETHODIMP Connection::BeginTransactionAs(int32_t aTransactionType) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; return beginTransactionInternal(mDBConn, aTransactionType); } nsresult Connection::beginTransactionInternal(sqlite3 *aNativeConnection, int32_t aTransactionType) { SQLiteMutexAutoLock lockedScope(sharedDBMutex); if (mTransactionInProgress) return NS_ERROR_FAILURE; nsresult rv; switch(aTransactionType) { case TRANSACTION_DEFERRED: rv = convertResultCode(executeSql(aNativeConnection, "BEGIN DEFERRED")); break; case TRANSACTION_IMMEDIATE: rv = convertResultCode(executeSql(aNativeConnection, "BEGIN IMMEDIATE")); break; case TRANSACTION_EXCLUSIVE: rv = convertResultCode(executeSql(aNativeConnection, "BEGIN EXCLUSIVE")); break; default: return NS_ERROR_ILLEGAL_VALUE; } if (NS_SUCCEEDED(rv)) mTransactionInProgress = true; return rv; } NS_IMETHODIMP Connection::CommitTransaction() { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; return commitTransactionInternal(mDBConn); } nsresult Connection::commitTransactionInternal(sqlite3 *aNativeConnection) { SQLiteMutexAutoLock lockedScope(sharedDBMutex); if (!mTransactionInProgress) return NS_ERROR_UNEXPECTED; nsresult rv = convertResultCode(executeSql(aNativeConnection, "COMMIT TRANSACTION")); if (NS_SUCCEEDED(rv)) mTransactionInProgress = false; return rv; } NS_IMETHODIMP Connection::RollbackTransaction() { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; return rollbackTransactionInternal(mDBConn); } nsresult Connection::rollbackTransactionInternal(sqlite3 *aNativeConnection) { SQLiteMutexAutoLock lockedScope(sharedDBMutex); if (!mTransactionInProgress) return NS_ERROR_UNEXPECTED; nsresult rv = convertResultCode(executeSql(aNativeConnection, "ROLLBACK TRANSACTION")); if (NS_SUCCEEDED(rv)) mTransactionInProgress = false; return rv; } NS_IMETHODIMP Connection::CreateTable(const char *aTableName, const char *aTableSchema) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; char *buf = ::PR_smprintf("CREATE TABLE %s (%s)", aTableName, aTableSchema); if (!buf) return NS_ERROR_OUT_OF_MEMORY; int srv = executeSql(mDBConn, buf); ::PR_smprintf_free(buf); return convertResultCode(srv); } NS_IMETHODIMP Connection::CreateFunction(const nsACString &aFunctionName, int32_t aNumArguments, mozIStorageFunction *aFunction) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; // Check to see if this function is already defined. We only check the name // because a function can be defined with the same body but different names. SQLiteMutexAutoLock lockedScope(sharedDBMutex); NS_ENSURE_FALSE(mFunctions.Get(aFunctionName, nullptr), NS_ERROR_FAILURE); int srv = ::sqlite3_create_function(mDBConn, nsPromiseFlatCString(aFunctionName).get(), aNumArguments, SQLITE_ANY, aFunction, basicFunctionHelper, nullptr, nullptr); if (srv != SQLITE_OK) return convertResultCode(srv); FunctionInfo info = { aFunction, Connection::FunctionInfo::SIMPLE, aNumArguments }; mFunctions.Put(aFunctionName, info); return NS_OK; } NS_IMETHODIMP Connection::CreateAggregateFunction(const nsACString &aFunctionName, int32_t aNumArguments, mozIStorageAggregateFunction *aFunction) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; // Check to see if this function name is already defined. SQLiteMutexAutoLock lockedScope(sharedDBMutex); NS_ENSURE_FALSE(mFunctions.Get(aFunctionName, nullptr), NS_ERROR_FAILURE); // Because aggregate functions depend on state across calls, you cannot have // the same instance use the same name. We want to enumerate all functions // and make sure this instance is not already registered. NS_ENSURE_FALSE(findFunctionByInstance(aFunction), NS_ERROR_FAILURE); int srv = ::sqlite3_create_function(mDBConn, nsPromiseFlatCString(aFunctionName).get(), aNumArguments, SQLITE_ANY, aFunction, nullptr, aggregateFunctionStepHelper, aggregateFunctionFinalHelper); if (srv != SQLITE_OK) return convertResultCode(srv); FunctionInfo info = { aFunction, Connection::FunctionInfo::AGGREGATE, aNumArguments }; mFunctions.Put(aFunctionName, info); return NS_OK; } NS_IMETHODIMP Connection::RemoveFunction(const nsACString &aFunctionName) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; SQLiteMutexAutoLock lockedScope(sharedDBMutex); NS_ENSURE_TRUE(mFunctions.Get(aFunctionName, nullptr), NS_ERROR_FAILURE); int srv = ::sqlite3_create_function(mDBConn, nsPromiseFlatCString(aFunctionName).get(), 0, SQLITE_ANY, nullptr, nullptr, nullptr, nullptr); if (srv != SQLITE_OK) return convertResultCode(srv); mFunctions.Remove(aFunctionName); return NS_OK; } NS_IMETHODIMP Connection::SetProgressHandler(int32_t aGranularity, mozIStorageProgressHandler *aHandler, mozIStorageProgressHandler **_oldHandler) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; // Return previous one SQLiteMutexAutoLock lockedScope(sharedDBMutex); NS_IF_ADDREF(*_oldHandler = mProgressHandler); if (!aHandler || aGranularity <= 0) { aHandler = nullptr; aGranularity = 0; } mProgressHandler = aHandler; ::sqlite3_progress_handler(mDBConn, aGranularity, sProgressHelper, this); return NS_OK; } NS_IMETHODIMP Connection::RemoveProgressHandler(mozIStorageProgressHandler **_oldHandler) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; // Return previous one SQLiteMutexAutoLock lockedScope(sharedDBMutex); NS_IF_ADDREF(*_oldHandler = mProgressHandler); mProgressHandler = nullptr; ::sqlite3_progress_handler(mDBConn, 0, nullptr, nullptr); return NS_OK; } NS_IMETHODIMP Connection::SetGrowthIncrement(int32_t aChunkSize, const nsACString &aDatabaseName) { // Bug 597215: Disk space is extremely limited on Android // so don't preallocate space. This is also not effective // on log structured file systems used by Android devices #if !defined(ANDROID) && !defined(MOZ_PLATFORM_MAEMO) // Don't preallocate if less than 500MiB is available. int64_t bytesAvailable; nsresult rv = mDatabaseFile->GetDiskSpaceAvailable(&bytesAvailable); NS_ENSURE_SUCCESS(rv, rv); if (bytesAvailable < MIN_AVAILABLE_BYTES_PER_CHUNKED_GROWTH) { return NS_ERROR_FILE_TOO_BIG; } (void)::sqlite3_file_control(mDBConn, aDatabaseName.Length() ? nsPromiseFlatCString(aDatabaseName).get() : nullptr, SQLITE_FCNTL_CHUNK_SIZE, &aChunkSize); #endif return NS_OK; } NS_IMETHODIMP Connection::EnableModule(const nsACString& aModuleName) { if (!mDBConn) return NS_ERROR_NOT_INITIALIZED; for (size_t i = 0; i < ArrayLength(gModules); i++) { struct Module* m = &gModules[i]; if (aModuleName.Equals(m->name)) { int srv = m->registerFunc(mDBConn, m->name); if (srv != SQLITE_OK) return convertResultCode(srv); return NS_OK; } } return NS_ERROR_FAILURE; } NS_IMETHODIMP Connection::GetQuotaObjects(QuotaObject** aDatabaseQuotaObject, QuotaObject** aJournalQuotaObject) { MOZ_ASSERT(aDatabaseQuotaObject); MOZ_ASSERT(aJournalQuotaObject); if (!mDBConn) { return NS_ERROR_NOT_INITIALIZED; } sqlite3_file* file; int srv = ::sqlite3_file_control(mDBConn, nullptr, SQLITE_FCNTL_FILE_POINTER, &file); if (srv != SQLITE_OK) { return convertResultCode(srv); } srv = ::sqlite3_file_control(mDBConn, nullptr, SQLITE_FCNTL_JOURNAL_POINTER, &file); if (srv != SQLITE_OK) { return convertResultCode(srv); } return NS_OK; } } // namespace storage } // namespace mozilla