Java tutorial
/* * Copyright (C) 2006 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ // modified from original source see README at the top level of this project /* ** Modified to support SQLite extensions by the SQLite developers: ** sqlite-dev@sqlite.org. */ package io.requery.android.database.sqlite; import android.annotation.SuppressLint; import android.content.ContentValues; import android.database.Cursor; import android.database.SQLException; import android.database.sqlite.SQLiteDatabaseCorruptException; import android.database.sqlite.SQLiteException; import android.database.sqlite.SQLiteTransactionListener; import android.os.Looper; import android.os.ParcelFileDescriptor; import android.support.annotation.IntDef; import android.support.v4.os.CancellationSignal; import android.support.v4.os.OperationCanceledException; import android.text.TextUtils; import android.util.EventLog; import android.util.Log; import android.util.Pair; import android.util.Printer; import io.requery.android.database.DatabaseErrorHandler; import io.requery.android.database.DefaultDatabaseErrorHandler; import java.io.File; import java.io.FileFilter; import java.io.IOException; import java.lang.annotation.Retention; import java.lang.annotation.RetentionPolicy; import java.util.ArrayList; import java.util.List; import java.util.Locale; import java.util.Map; import java.util.WeakHashMap; /** * Exposes methods to manage a SQLite database. * * <p> * SQLiteDatabase has methods to create, delete, execute SQL commands, and * perform other common database management tasks. * </p><p> * See the Notepad sample application in the SDK for an example of creating * and managing a database. * </p><p> * Database names must be unique within an application, not across all applications. * </p> * * <h3>Localized Collation - ORDER BY</h3> * <p> * In addition to SQLite's default <code>BINARY</code> collator, Android supplies * two more, <code>LOCALIZED</code>, which changes with the system's current locale, * and <code>UNICODE</code>, which is the Unicode Collation Algorithm and not tailored * to the current locale. * </p> */ @SuppressWarnings({ "unused", "JavaDoc", "TryFinallyCanBeTryWithResources" }) @SuppressLint("ShiftFlags") // suppressed for readability with native code public final class SQLiteDatabase extends SQLiteClosable { static { System.loadLibrary("sqlite3x"); } private static final String TAG = "SQLiteDatabase"; private static final int EVENT_DB_CORRUPT = 75004; // Stores reference to all databases opened in the current process. // (The referent Object is not used at this time.) // INVARIANT: Guarded by sActiveDatabases. private static final WeakHashMap<SQLiteDatabase, Object> sActiveDatabases = new WeakHashMap<>(); // Thread-local for database sessions that belong to this database. // Each thread has its own database session. // INVARIANT: Immutable. private final ThreadLocal<SQLiteSession> mThreadSession = new ThreadLocal<SQLiteSession>() { @Override protected SQLiteSession initialValue() { return createSession(); } }; // The optional factory to use when creating new Cursors. May be null. // INVARIANT: Immutable. private final CursorFactory mCursorFactory; // Error handler to be used when SQLite returns corruption errors. // INVARIANT: Immutable. private final DatabaseErrorHandler mErrorHandler; // Shared database state lock. // This lock guards all of the shared state of the database, such as its // configuration, whether it is open or closed, and so on. This lock should // be held for as little time as possible. // // The lock MUST NOT be held while attempting to acquire database connections or // while executing SQL statements on behalf of the client as it can lead to deadlock. // // It is ok to hold the lock while reconfiguring the connection pool or dumping // statistics because those operations are non-reentrant and do not try to acquire // connections that might be held by other threads. // // Basic rule: grab the lock, access or modify global state, release the lock, then // do the required SQL work. private final Object mLock = new Object(); // Warns if the database is finalized without being closed properly. // INVARIANT: Guarded by mLock. private final CloseGuard mCloseGuardLocked = CloseGuard.get(); // The database configuration. // INVARIANT: Guarded by mLock. private final SQLiteDatabaseConfiguration mConfigurationLocked; // The connection pool for the database, null when closed. // The pool itself is thread-safe, but the reference to it can only be acquired // when the lock is held. // INVARIANT: Guarded by mLock. private SQLiteConnectionPool mConnectionPoolLocked; /** * When a constraint violation occurs, an immediate ROLLBACK occurs, * thus ending the current transaction, and the command aborts with a * return code of SQLITE_CONSTRAINT. If no transaction is active * (other than the implied transaction that is created on every command) * then this algorithm works the same as ABORT. */ public static final int CONFLICT_ROLLBACK = 1; /** * When a constraint violation occurs,no ROLLBACK is executed * so changes from prior commands within the same transaction * are preserved. This is the default behavior. */ public static final int CONFLICT_ABORT = 2; /** * When a constraint violation occurs, the command aborts with a return * code SQLITE_CONSTRAINT. But any changes to the database that * the command made prior to encountering the constraint violation * are preserved and are not backed out. */ public static final int CONFLICT_FAIL = 3; /** * When a constraint violation occurs, the one row that contains * the constraint violation is not inserted or changed. * But the command continues executing normally. Other rows before and * after the row that contained the constraint violation continue to be * inserted or updated normally. No error is returned. */ public static final int CONFLICT_IGNORE = 4; /** * When a UNIQUE constraint violation occurs, the pre-existing rows that * are causing the constraint violation are removed prior to inserting * or updating the current row. Thus the insert or update always occurs. * The command continues executing normally. No error is returned. * If a NOT NULL constraint violation occurs, the NULL value is replaced * by the default value for that column. If the column has no default * value, then the ABORT algorithm is used. If a CHECK constraint * violation occurs then the IGNORE algorithm is used. When this conflict * resolution strategy deletes rows in order to satisfy a constraint, * it does not invoke delete triggers on those rows. * This behavior might change in a future release. */ public static final int CONFLICT_REPLACE = 5; /** * Use the following when no conflict action is specified. */ public static final int CONFLICT_NONE = 0; /** Conflict options integer enumeration definition */ @IntDef({ CONFLICT_ABORT, CONFLICT_FAIL, CONFLICT_IGNORE, CONFLICT_NONE, CONFLICT_REPLACE, CONFLICT_ROLLBACK }) @Retention(RetentionPolicy.SOURCE) public @interface ConflictAlgorithm { } private static final String[] CONFLICT_VALUES = new String[] { "", " OR ROLLBACK ", " OR ABORT ", " OR FAIL ", " OR IGNORE ", " OR REPLACE " }; /** Open flag to open in the database in read only mode */ public static final int OPEN_READONLY = 0x00000001; /** Open flag to open in the database in read/write mode */ public static final int OPEN_READWRITE = 0x00000002; /** Open flag to create the database if it does not exist */ public static final int OPEN_CREATE = 0x00000004; /** Open flag to support URI filenames */ public static final int OPEN_URI = 0x00000040; /** Open flag opens the database in multi-thread threading mode */ public static final int OPEN_NOMUTEX = 0x00008000; /** Open flag opens the database in serialized threading mode */ public static final int OPEN_FULLMUTEX = 0x00010000; /** Open flag opens the database in shared cache mode */ public static final int OPEN_SHAREDCACHE = 0x00020000; /** Open flag opens the database in private cache mode */ public static final int OPEN_PRIVATECACHE = 0x00040000; /** Open flag equivalent to {@link #OPEN_READWRITE} | {@link #OPEN_CREATE} */ public static final int CREATE_IF_NECESSARY = OPEN_READWRITE | OPEN_CREATE; /** Open flag to enable write-ahead logging */ // custom flag remove for sqlite3_open_v2 public static final int ENABLE_WRITE_AHEAD_LOGGING = 0x20000000; /** Integer flag definition for the database open options */ @SuppressLint("UniqueConstants") // duplicate values provided for compatibility @IntDef(flag = true, value = { OPEN_READONLY, OPEN_READWRITE, OPEN_CREATE, OPEN_URI, OPEN_NOMUTEX, OPEN_FULLMUTEX, OPEN_SHAREDCACHE, OPEN_PRIVATECACHE, CREATE_IF_NECESSARY, ENABLE_WRITE_AHEAD_LOGGING }) @Retention(RetentionPolicy.SOURCE) public @interface OpenFlags { } /** * Absolute max value that can be set by {@link #setMaxSqlCacheSize(int)}. * * Each prepared-statement is between 1K - 6K, depending on the complexity of the * SQL statement & schema. A large SQL cache may use a significant amount of memory. */ public static final int MAX_SQL_CACHE_SIZE = 100; private SQLiteDatabase(SQLiteDatabaseConfiguration configuration, CursorFactory cursorFactory, DatabaseErrorHandler errorHandler) { mCursorFactory = cursorFactory; mErrorHandler = errorHandler != null ? errorHandler : new DefaultDatabaseErrorHandler(); mConfigurationLocked = configuration; } @SuppressWarnings("ThrowFromFinallyBlock") @Override protected void finalize() throws Throwable { try { dispose(true); } finally { super.finalize(); } } @Override protected void onAllReferencesReleased() { dispose(false); } private void dispose(boolean finalized) { final SQLiteConnectionPool pool; synchronized (mLock) { if (mCloseGuardLocked != null) { if (finalized) { mCloseGuardLocked.warnIfOpen(); } mCloseGuardLocked.close(); } pool = mConnectionPoolLocked; mConnectionPoolLocked = null; } if (!finalized) { synchronized (sActiveDatabases) { sActiveDatabases.remove(this); } if (pool != null) { pool.close(); } } } /** * Attempts to release memory that SQLite holds but does not require to * operate properly. Typically this memory will come from the page cache. * * @return the number of bytes actually released */ public static int releaseMemory() { return SQLiteGlobal.releaseMemory(); } /** * Gets a label to use when describing the database in log messages. * @return The label. */ String getLabel() { synchronized (mLock) { return mConfigurationLocked.label; } } /** * Sends a corruption message to the database error handler. */ void onCorruption() { EventLog.writeEvent(EVENT_DB_CORRUPT, getLabel()); mErrorHandler.onCorruption(this); } /** * Gets the {@link SQLiteSession} that belongs to this thread for this database. * Once a thread has obtained a session, it will continue to obtain the same * session even after the database has been closed (although the session will not * be usable). However, a thread that does not already have a session cannot * obtain one after the database has been closed. * * The idea is that threads that have active connections to the database may still * have work to complete even after the call to {@link #close}. Active database * connections are not actually disposed until they are released by the threads * that own them. * * @return The session, never null. * * @throws IllegalStateException if the thread does not yet have a session and * the database is not open. */ SQLiteSession getThreadSession() { return mThreadSession.get(); // initialValue() throws if database closed } SQLiteSession createSession() { final SQLiteConnectionPool pool; synchronized (mLock) { throwIfNotOpenLocked(); pool = mConnectionPoolLocked; } return new SQLiteSession(pool); } /** * Gets default connection flags that are appropriate for this thread, taking into * account whether the thread is acting on behalf of the UI. * * @param readOnly True if the connection should be read-only. * @return The connection flags. */ int getThreadDefaultConnectionFlags(boolean readOnly) { int flags = readOnly ? SQLiteConnectionPool.CONNECTION_FLAG_READ_ONLY : SQLiteConnectionPool.CONNECTION_FLAG_PRIMARY_CONNECTION_AFFINITY; if (isMainThread()) { flags |= SQLiteConnectionPool.CONNECTION_FLAG_INTERACTIVE; } return flags; } private static boolean isMainThread() { // FIXME: There should be a better way to do this. // Would also be nice to have something that would work across Binder calls. Looper looper = Looper.myLooper(); return looper != null && looper == Looper.getMainLooper(); } /** * Begins a transaction in EXCLUSIVE mode. * <p> * Transactions can be nested. * When the outer transaction is ended all of * the work done in that transaction and all of the nested transactions will be committed or * rolled back. The changes will be rolled back if any transaction is ended without being * marked as clean (by calling setTransactionSuccessful). Otherwise they will be committed. * </p> * <p>Here is the standard idiom for transactions: * * <pre> * db.beginTransaction(); * try { * ... * db.setTransactionSuccessful(); * } finally { * db.endTransaction(); * } * </pre> */ public void beginTransaction() { beginTransaction(null, SQLiteSession.TRANSACTION_MODE_EXCLUSIVE); } /** * Begins a transaction in IMMEDIATE mode. Transactions can be nested. When * the outer transaction is ended all of the work done in that transaction * and all of the nested transactions will be committed or rolled back. The * changes will be rolled back if any transaction is ended without being * marked as clean (by calling setTransactionSuccessful). Otherwise they * will be committed. * <p> * Here is the standard idiom for transactions: * * <pre> * db.beginTransactionNonExclusive(); * try { * ... * db.setTransactionSuccessful(); * } finally { * db.endTransaction(); * } * </pre> */ public void beginTransactionNonExclusive() { beginTransaction(null, SQLiteSession.TRANSACTION_MODE_IMMEDIATE); } /** * Begins a transaction in DEFERRED mode. */ public void beginTransactionDeferred() { beginTransaction(null, SQLiteSession.TRANSACTION_MODE_DEFERRED); } /** * Begins a transaction in DEFERRED mode. * * @param transactionListener listener that should be notified when the transaction begins, * commits, or is rolled back, either explicitly or by a call to * {@link #yieldIfContendedSafely}. */ public void beginTransactionWithListenerDeferred(SQLiteTransactionListener transactionListener) { beginTransaction(transactionListener, SQLiteSession.TRANSACTION_MODE_DEFERRED); } /** * Begins a transaction in EXCLUSIVE mode. * <p> * Transactions can be nested. * When the outer transaction is ended all of * the work done in that transaction and all of the nested transactions will be committed or * rolled back. The changes will be rolled back if any transaction is ended without being * marked as clean (by calling setTransactionSuccessful). Otherwise they will be committed. * </p> * <p>Here is the standard idiom for transactions: * * <pre> * db.beginTransactionWithListener(listener); * try { * ... * db.setTransactionSuccessful(); * } finally { * db.endTransaction(); * } * </pre> * * @param transactionListener listener that should be notified when the transaction begins, * commits, or is rolled back, either explicitly or by a call to * {@link #yieldIfContendedSafely}. */ public void beginTransactionWithListener(SQLiteTransactionListener transactionListener) { beginTransaction(transactionListener, SQLiteSession.TRANSACTION_MODE_EXCLUSIVE); } /** * Begins a transaction in IMMEDIATE mode. Transactions can be nested. When * the outer transaction is ended all of the work done in that transaction * and all of the nested transactions will be committed or rolled back. The * changes will be rolled back if any transaction is ended without being * marked as clean (by calling setTransactionSuccessful). Otherwise they * will be committed. * <p> * Here is the standard idiom for transactions: * * <pre> * db.beginTransactionWithListenerNonExclusive(listener); * try { * ... * db.setTransactionSuccessful(); * } finally { * db.endTransaction(); * } * </pre> * * @param transactionListener listener that should be notified when the * transaction begins, commits, or is rolled back, either * explicitly or by a call to {@link #yieldIfContendedSafely}. */ public void beginTransactionWithListenerNonExclusive(SQLiteTransactionListener transactionListener) { beginTransaction(transactionListener, SQLiteSession.TRANSACTION_MODE_IMMEDIATE); } private void beginTransaction(SQLiteTransactionListener transactionListener, int mode) { acquireReference(); try { getThreadSession().beginTransaction(mode, transactionListener, getThreadDefaultConnectionFlags(false /*readOnly*/), null); } finally { releaseReference(); } } /** * End a transaction. See beginTransaction for notes about how to use this and when transactions * are committed and rolled back. */ public void endTransaction() { acquireReference(); try { getThreadSession().endTransaction(null); } finally { releaseReference(); } } /** * Marks the current transaction as successful. Do not do any more database work between * calling this and calling endTransaction. Do as little non-database work as possible in that * situation too. If any errors are encountered between this and endTransaction the transaction * will still be committed. * * @throws IllegalStateException if the current thread is not in a transaction or the * transaction is already marked as successful. */ public void setTransactionSuccessful() { acquireReference(); try { getThreadSession().setTransactionSuccessful(); } finally { releaseReference(); } } /** * Returns true if the current thread has a transaction pending. * * @return True if the current thread is in a transaction. */ public boolean inTransaction() { acquireReference(); try { return getThreadSession().hasTransaction(); } finally { releaseReference(); } } /** * Returns true if the current thread is holding an active connection to the database. * <p> * The name of this method comes from a time when having an active connection * to the database meant that the thread was holding an actual lock on the * database. Nowadays, there is no longer a true "database lock" although threads * may block if they cannot acquire a database connection to perform a * particular operation. * </p> * * @return True if the current thread is holding an active connection to the database. */ public boolean isDbLockedByCurrentThread() { acquireReference(); try { return getThreadSession().hasConnection(); } finally { releaseReference(); } } /** * Temporarily end the transaction to let other threads run. The transaction is assumed to be * successful so far. Do not call setTransactionSuccessful before calling this. When this * returns a new transaction will have been created but not marked as successful. This assumes * that there are no nested transactions (beginTransaction has only been called once) and will * throw an exception if that is not the case. * @return true if the transaction was yielded */ public boolean yieldIfContendedSafely() { return yieldIfContendedHelper(true /* check yielding */, -1 /* sleepAfterYieldDelay*/); } /** * Temporarily end the transaction to let other threads run. The transaction is assumed to be * successful so far. Do not call setTransactionSuccessful before calling this. When this * returns a new transaction will have been created but not marked as successful. This assumes * that there are no nested transactions (beginTransaction has only been called once) and will * throw an exception if that is not the case. * @param sleepAfterYieldDelay if > 0, sleep this long before starting a new transaction if * the lock was actually yielded. This will allow other background threads to make some * more progress than they would if we started the transaction immediately. * @return true if the transaction was yielded */ public boolean yieldIfContendedSafely(long sleepAfterYieldDelay) { return yieldIfContendedHelper(true /* check yielding */, sleepAfterYieldDelay); } private boolean yieldIfContendedHelper(boolean throwIfUnsafe, long sleepAfterYieldDelay) { acquireReference(); try { return getThreadSession().yieldTransaction(sleepAfterYieldDelay, throwIfUnsafe, null); } finally { releaseReference(); } } /** * Open the database according to the flags {@link OpenFlags} * * <p>Sets the locale of the database to the the system's current locale. * Call {@link #setLocale} if you would like something else.</p> * * @param path to database file to open and/or create * @param factory an optional factory class that is called to instantiate a * cursor when query is called, or null for default * @param flags to control database access mode * @return the newly opened database * @throws SQLiteException if the database cannot be opened */ public static SQLiteDatabase openDatabase(String path, CursorFactory factory, @OpenFlags int flags) { return openDatabase(path, factory, flags, null); } /** * Open the database according to the flags {@link OpenFlags} * * <p>Sets the locale of the database to the the system's current locale. * Call {@link #setLocale} if you would like something else.</p> * * <p>Accepts input param: a concrete instance of {@link DatabaseErrorHandler} to be * used to handle corruption when sqlite reports database corruption.</p> * * @param path to database file to open and/or create * @param factory an optional factory class that is called to instantiate a * cursor when query is called, or null for default * @param flags to control database access mode * @param errorHandler the {@link DatabaseErrorHandler} obj to be used to handle corruption * when sqlite reports database corruption * @return the newly opened database * @throws SQLiteException if the database cannot be opened */ public static SQLiteDatabase openDatabase(String path, CursorFactory factory, @OpenFlags int flags, DatabaseErrorHandler errorHandler) { SQLiteDatabaseConfiguration configuration = new SQLiteDatabaseConfiguration(path, flags); SQLiteDatabase db = new SQLiteDatabase(configuration, factory, errorHandler); db.open(); return db; } /** * Open the database according to the given configuration. * * <p>Sets the locale of the database to the the system's current locale. * Call {@link #setLocale} if you would like something else.</p> * * <p>Accepts input param: a concrete instance of {@link DatabaseErrorHandler} to be * used to handle corruption when sqlite reports database corruption.</p> * * @param configuration to database configuration to use * @param factory an optional factory class that is called to instantiate a * cursor when query is called, or null for default * @param errorHandler the {@link DatabaseErrorHandler} obj to be used to handle corruption * when sqlite reports database corruption * @return the newly opened database * @throws SQLiteException if the database cannot be opened */ public static SQLiteDatabase openDatabase(SQLiteDatabaseConfiguration configuration, CursorFactory factory, DatabaseErrorHandler errorHandler) { SQLiteDatabase db = new SQLiteDatabase(configuration, factory, errorHandler); db.open(); return db; } /** * Equivalent to openDatabase(file.getPath(), factory, CREATE_IF_NECESSARY). */ public static SQLiteDatabase openOrCreateDatabase(File file, CursorFactory factory) { return openOrCreateDatabase(file.getPath(), factory); } /** * Equivalent to openDatabase(path, factory, CREATE_IF_NECESSARY). */ public static SQLiteDatabase openOrCreateDatabase(String path, CursorFactory factory) { return openDatabase(path, factory, CREATE_IF_NECESSARY, null); } /** * Equivalent to openDatabase(path, factory, CREATE_IF_NECESSARY, errorHandler). */ public static SQLiteDatabase openOrCreateDatabase(String path, CursorFactory factory, DatabaseErrorHandler errorHandler) { return openDatabase(path, factory, CREATE_IF_NECESSARY, errorHandler); } /** * Deletes a database including its journal file and other auxiliary files * that may have been created by the database engine. * * @param file The database file path. * @return True if the database was successfully deleted. */ public static boolean deleteDatabase(File file) { if (file == null) { throw new IllegalArgumentException("file must not be null"); } boolean deleted; deleted = file.delete(); deleted |= new File(file.getPath() + "-journal").delete(); deleted |= new File(file.getPath() + "-shm").delete(); deleted |= new File(file.getPath() + "-wal").delete(); File dir = file.getParentFile(); if (dir != null) { final String prefix = file.getName() + "-mj"; final FileFilter filter = new FileFilter() { @Override public boolean accept(File candidate) { return candidate.getName().startsWith(prefix); } }; for (File masterJournal : dir.listFiles(filter)) { deleted |= masterJournal.delete(); } } return deleted; } /** * Reopens the database in read-write mode. * If the database is already read-write, does nothing. * * @throws SQLiteException if the database could not be reopened as requested, in which * case it remains open in read only mode. * @throws IllegalStateException if the database is not open. * * @see #isReadOnly() * @hide */ public void reopenReadWrite() { synchronized (mLock) { throwIfNotOpenLocked(); if (!isReadOnlyLocked()) { return; // nothing to do } // Reopen the database in read-write mode. final int oldOpenFlags = mConfigurationLocked.openFlags; mConfigurationLocked.openFlags = (mConfigurationLocked.openFlags & ~OPEN_READONLY); try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.openFlags = oldOpenFlags; throw ex; } } } private void open() { try { if (!mConfigurationLocked.isInMemoryDb()) { ensureFile(mConfigurationLocked.path); } try { openInner(); } catch (SQLiteDatabaseCorruptException ex) { onCorruption(); openInner(); } } catch (SQLiteException ex) { Log.e(TAG, "Failed to open database '" + getLabel() + "'.", ex); close(); throw ex; } } private static void ensureFile(String path) { File file = new File(path); if (!file.exists()) { try { if (!file.getParentFile().mkdirs()) { Log.e(TAG, "Couldn't mkdirs " + file); } if (!file.createNewFile()) { Log.e(TAG, "Couldn't create " + file); } } catch (IOException e) { Log.e(TAG, "Couldn't ensure file " + file, e); } } } private void openInner() { synchronized (mLock) { assert mConnectionPoolLocked == null; mConnectionPoolLocked = SQLiteConnectionPool.open(mConfigurationLocked); mCloseGuardLocked.open("close"); } synchronized (sActiveDatabases) { sActiveDatabases.put(this, null); } } /** * Create a memory backed SQLite database. Its contents will be destroyed * when the database is closed. * * <p>Sets the locale of the database to the the system's current locale. * Call {@link #setLocale} if you would like something else.</p> * * @param factory an optional factory class that is called to instantiate a * cursor when query is called * @return a SQLiteDatabase object, or null if the database can't be created */ public static SQLiteDatabase create(CursorFactory factory) { // This is a magic string with special meaning for SQLite. return openDatabase(SQLiteDatabaseConfiguration.MEMORY_DB_PATH, factory, CREATE_IF_NECESSARY); } /** * Registers a CustomFunction callback as a function that can be called from * SQLite database triggers. * * @param name the name of the sqlite3 function * @param numArgs the number of arguments for the function * @param function callback to call when the function is executed * @hide */ public void addCustomFunction(String name, int numArgs, CustomFunction function) { // Create wrapper (also validates arguments). SQLiteCustomFunction wrapper = new SQLiteCustomFunction(name, numArgs, function); synchronized (mLock) { throwIfNotOpenLocked(); mConfigurationLocked.customFunctions.add(wrapper); try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.customFunctions.remove(wrapper); throw ex; } } } /** * Gets the database version. * * @return the database version */ public int getVersion() { return ((Long) longForQuery("PRAGMA user_version;", null)).intValue(); } /** * Sets the database version. * * @param version the new database version */ public void setVersion(int version) { execSQL("PRAGMA user_version = " + version); } /** * Returns the maximum size the database may grow to. * * @return the new maximum database size */ public long getMaximumSize() { long pageCount = longForQuery("PRAGMA max_page_count;", null); return pageCount * getPageSize(); } /** * Sets the maximum size the database will grow to. The maximum size cannot * be set below the current size. * * @param numBytes the maximum database size, in bytes * @return the new maximum database size */ public long setMaximumSize(long numBytes) { long pageSize = getPageSize(); long numPages = numBytes / pageSize; // If numBytes isn't a multiple of pageSize, bump up a page if ((numBytes % pageSize) != 0) { numPages++; } long newPageCount = longForQuery("PRAGMA max_page_count = " + numPages, null); return newPageCount * pageSize; } /** * Returns the current database page size, in bytes. * * @return the database page size, in bytes */ public long getPageSize() { return longForQuery("PRAGMA page_size;", null); } /** * Sets the database page size. The page size must be a power of two. This * method does not work if any data has been written to the database file, * and must be called right after the database has been created. * * @param numBytes the database page size, in bytes */ public void setPageSize(long numBytes) { execSQL("PRAGMA page_size = " + numBytes); } /** * Finds the name of the first table, which is editable. * * @param tables a list of tables * @return the first table listed */ public static String findEditTable(String tables) { if (!TextUtils.isEmpty(tables)) { // find the first word terminated by either a space or a comma int spacepos = tables.indexOf(' '); int commapos = tables.indexOf(','); if (spacepos > 0 && (spacepos < commapos || commapos < 0)) { return tables.substring(0, spacepos); } else if (commapos > 0 && (commapos < spacepos || spacepos < 0)) { return tables.substring(0, commapos); } return tables; } else { throw new IllegalStateException("Invalid tables"); } } /** * Compiles an SQL statement into a reusable pre-compiled statement object. * The parameters are identical to {@link #execSQL(String)}. You may put ?s in the * statement and fill in those values with {@link SQLiteProgram#bindString} * and {@link SQLiteProgram#bindLong} each time you want to run the * statement. Statements may not return result sets larger than 1x1. *<p> * No two threads should be using the same {@link SQLiteStatement} at the same time. * * @param sql The raw SQL statement, may contain ? for unknown values to be * bound later. * @return A pre-compiled {@link SQLiteStatement} object. Note that * {@link SQLiteStatement}s are not synchronized, see the documentation for more details. */ public SQLiteStatement compileStatement(String sql) throws SQLException { acquireReference(); try { return new SQLiteStatement(this, sql, null); } finally { releaseReference(); } } /** * Query the given URL, returning a {@link Cursor} over the result set. * * @param distinct true if you want each row to be unique, false otherwise. * @param table The table name to compile the query against. * @param columns A list of which columns to return. Passing null will * return all columns, which is discouraged to prevent reading * data from storage that isn't going to be used. * @param selection A filter declaring which rows to return, formatted as an * SQL WHERE clause (excluding the WHERE itself). Passing null * will return all rows for the given table. * @param selectionArgs You may include ?s in selection, which will be * replaced by the values from selectionArgs, in order that they * appear in the selection. * @param groupBy A filter declaring how to group rows, formatted as an SQL * GROUP BY clause (excluding the GROUP BY itself). Passing null * will cause the rows to not be grouped. * @param having A filter declare which row groups to include in the cursor, * if row grouping is being used, formatted as an SQL HAVING * clause (excluding the HAVING itself). Passing null will cause * all row groups to be included, and is required when row * grouping is not being used. * @param orderBy How to order the rows, formatted as an SQL ORDER BY clause * (excluding the ORDER BY itself). Passing null will use the * default sort order, which may be unordered. * @param limit Limits the number of rows returned by the query, * formatted as LIMIT clause. Passing null denotes no LIMIT clause. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. * @see Cursor */ public Cursor query(boolean distinct, String table, String[] columns, String selection, Object[] selectionArgs, String groupBy, String having, String orderBy, String limit) { return queryWithFactory(null, distinct, table, columns, selection, selectionArgs, groupBy, having, orderBy, limit, null); } /** * Query the given URL, returning a {@link Cursor} over the result set. * * @param distinct true if you want each row to be unique, false otherwise. * @param table The table name to compile the query against. * @param columns A list of which columns to return. Passing null will * return all columns, which is discouraged to prevent reading * data from storage that isn't going to be used. * @param selection A filter declaring which rows to return, formatted as an * SQL WHERE clause (excluding the WHERE itself). Passing null * will return all rows for the given table. * @param selectionArgs You may include ?s in selection, which will be * replaced by the values from selectionArgs, in order that they * appear in the selection. * @param groupBy A filter declaring how to group rows, formatted as an SQL * GROUP BY clause (excluding the GROUP BY itself). Passing null * will cause the rows to not be grouped. * @param having A filter declare which row groups to include in the cursor, * if row grouping is being used, formatted as an SQL HAVING * clause (excluding the HAVING itself). Passing null will cause * all row groups to be included, and is required when row * grouping is not being used. * @param orderBy How to order the rows, formatted as an SQL ORDER BY clause * (excluding the ORDER BY itself). Passing null will use the * default sort order, which may be unordered. * @param limit Limits the number of rows returned by the query, * formatted as LIMIT clause. Passing null denotes no LIMIT clause. * @param cancellationSignal A signal to cancel the operation in progress, or null if none. * If the operation is canceled, then {@link OperationCanceledException} will be thrown * when the query is executed. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. * @see Cursor */ public Cursor query(boolean distinct, String table, String[] columns, String selection, Object[] selectionArgs, String groupBy, String having, String orderBy, String limit, CancellationSignal cancellationSignal) { return queryWithFactory(null, distinct, table, columns, selection, selectionArgs, groupBy, having, orderBy, limit, cancellationSignal); } /** * Query the given URL, returning a {@link Cursor} over the result set. * * @param cursorFactory the cursor factory to use, or null for the default factory * @param distinct true if you want each row to be unique, false otherwise. * @param table The table name to compile the query against. * @param columns A list of which columns to return. Passing null will * return all columns, which is discouraged to prevent reading * data from storage that isn't going to be used. * @param selection A filter declaring which rows to return, formatted as an * SQL WHERE clause (excluding the WHERE itself). Passing null * will return all rows for the given table. * @param selectionArgs You may include ?s in selection, which will be * replaced by the values from selectionArgs, in order that they * appear in the selection. * @param groupBy A filter declaring how to group rows, formatted as an SQL * GROUP BY clause (excluding the GROUP BY itself). Passing null * will cause the rows to not be grouped. * @param having A filter declare which row groups to include in the cursor, * if row grouping is being used, formatted as an SQL HAVING * clause (excluding the HAVING itself). Passing null will cause * all row groups to be included, and is required when row * grouping is not being used. * @param orderBy How to order the rows, formatted as an SQL ORDER BY clause * (excluding the ORDER BY itself). Passing null will use the * default sort order, which may be unordered. * @param limit Limits the number of rows returned by the query, * formatted as LIMIT clause. Passing null denotes no LIMIT clause. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. * @see Cursor */ public Cursor queryWithFactory(CursorFactory cursorFactory, boolean distinct, String table, String[] columns, String selection, Object[] selectionArgs, String groupBy, String having, String orderBy, String limit) { return queryWithFactory(cursorFactory, distinct, table, columns, selection, selectionArgs, groupBy, having, orderBy, limit, null); } /** * Query the given URL, returning a {@link Cursor} over the result set. * * @param cursorFactory the cursor factory to use, or null for the default factory * @param distinct true if you want each row to be unique, false otherwise. * @param table The table name to compile the query against. * @param columns A list of which columns to return. Passing null will * return all columns, which is discouraged to prevent reading * data from storage that isn't going to be used. * @param selection A filter declaring which rows to return, formatted as an * SQL WHERE clause (excluding the WHERE itself). Passing null * will return all rows for the given table. * @param selectionArgs You may include ?s in selection, which will be * replaced by the values from selectionArgs, in order that they * appear in the selection. * @param groupBy A filter declaring how to group rows, formatted as an SQL * GROUP BY clause (excluding the GROUP BY itself). Passing null * will cause the rows to not be grouped. * @param having A filter declare which row groups to include in the cursor, * if row grouping is being used, formatted as an SQL HAVING * clause (excluding the HAVING itself). Passing null will cause * all row groups to be included, and is required when row * grouping is not being used. * @param orderBy How to order the rows, formatted as an SQL ORDER BY clause * (excluding the ORDER BY itself). Passing null will use the * default sort order, which may be unordered. * @param limit Limits the number of rows returned by the query, * formatted as LIMIT clause. Passing null denotes no LIMIT clause. * @param cancellationSignal A signal to cancel the operation in progress, or null if none. * If the operation is canceled, then {@link OperationCanceledException} will be thrown * when the query is executed. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. * @see Cursor */ public Cursor queryWithFactory(CursorFactory cursorFactory, boolean distinct, String table, String[] columns, String selection, Object[] selectionArgs, String groupBy, String having, String orderBy, String limit, CancellationSignal cancellationSignal) { acquireReference(); try { String sql = SQLiteQueryBuilder.buildQueryString(distinct, table, columns, selection, groupBy, having, orderBy, limit); return rawQueryWithFactory(cursorFactory, sql, selectionArgs, findEditTable(table), cancellationSignal); } finally { releaseReference(); } } /** * Query the given table, returning a {@link Cursor} over the result set. * * @param table The table name to compile the query against. * @param columns A list of which columns to return. Passing null will * return all columns, which is discouraged to prevent reading * data from storage that isn't going to be used. * @param selection A filter declaring which rows to return, formatted as an * SQL WHERE clause (excluding the WHERE itself). Passing null * will return all rows for the given table. * @param selectionArgs You may include ?s in selection, which will be * replaced by the values from selectionArgs, in order that they * appear in the selection. * @param groupBy A filter declaring how to group rows, formatted as an SQL * GROUP BY clause (excluding the GROUP BY itself). Passing null * will cause the rows to not be grouped. * @param having A filter declare which row groups to include in the cursor, * if row grouping is being used, formatted as an SQL HAVING * clause (excluding the HAVING itself). Passing null will cause * all row groups to be included, and is required when row * grouping is not being used. * @param orderBy How to order the rows, formatted as an SQL ORDER BY clause * (excluding the ORDER BY itself). Passing null will use the * default sort order, which may be unordered. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. * @see Cursor */ public Cursor query(String table, String[] columns, String selection, Object[] selectionArgs, String groupBy, String having, String orderBy) { return query(false, table, columns, selection, selectionArgs, groupBy, having, orderBy, null /* limit */); } /** * Query the given table, returning a {@link Cursor} over the result set. * * @param table The table name to compile the query against. * @param columns A list of which columns to return. Passing null will * return all columns, which is discouraged to prevent reading * data from storage that isn't going to be used. * @param selection A filter declaring which rows to return, formatted as an * SQL WHERE clause (excluding the WHERE itself). Passing null * will return all rows for the given table. * @param selectionArgs You may include ?s in selection, which will be * replaced by the values from selectionArgs, in order that they * appear in the selection. * @param groupBy A filter declaring how to group rows, formatted as an SQL * GROUP BY clause (excluding the GROUP BY itself). Passing null * will cause the rows to not be grouped. * @param having A filter declare which row groups to include in the cursor, * if row grouping is being used, formatted as an SQL HAVING * clause (excluding the HAVING itself). Passing null will cause * all row groups to be included, and is required when row * grouping is not being used. * @param orderBy How to order the rows, formatted as an SQL ORDER BY clause * (excluding the ORDER BY itself). Passing null will use the * default sort order, which may be unordered. * @param limit Limits the number of rows returned by the query, * formatted as LIMIT clause. Passing null denotes no LIMIT clause. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. * @see Cursor */ public Cursor query(String table, String[] columns, String selection, Object[] selectionArgs, String groupBy, String having, String orderBy, String limit) { return query(false, table, columns, selection, selectionArgs, groupBy, having, orderBy, limit); } /** * Runs the provided SQL and returns a {@link Cursor} over the result set. * * @param sql the SQL query. The SQL string must not be ; terminated * @param selectionArgs You may include ?s in where clause in the query, * which will be replaced by the values from selectionArgs. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. */ public Cursor rawQuery(String sql, Object[] selectionArgs) { return rawQueryWithFactory(null, sql, selectionArgs, null, null); } /** * Runs the provided SQL and returns a {@link Cursor} over the result set. * * @param sql the SQL query. The SQL string must not be ; terminated * @param selectionArgs You may include ?s in where clause in the query, * which will be replaced by the values from selectionArgs. * @param cancellationSignal A signal to cancel the operation in progress, or null if none. * If the operation is canceled, then {@link OperationCanceledException} will be thrown * when the query is executed. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. */ public Cursor rawQuery(String sql, Object[] selectionArgs, CancellationSignal cancellationSignal) { return rawQueryWithFactory(null, sql, selectionArgs, null, cancellationSignal); } /** * Runs the provided SQL and returns a cursor over the result set. * * @param cursorFactory the cursor factory to use, or null for the default factory * @param sql the SQL query. The SQL string must not be ; terminated * @param selectionArgs You may include ?s in where clause in the query, * which will be replaced by the values from selectionArgs. * @param editTable the name of the first table, which is editable * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. */ public Cursor rawQueryWithFactory(CursorFactory cursorFactory, String sql, Object[] selectionArgs, String editTable) { return rawQueryWithFactory(cursorFactory, sql, selectionArgs, editTable, null); } /** * Runs the provided SQL and returns a cursor over the result set. * * @param cursorFactory the cursor factory to use, or null for the default factory * @param sql the SQL query. The SQL string must not be ; terminated * @param selectionArgs You may include ?s in where clause in the query, * which will be replaced by the values from selectionArgs. * @param editTable the name of the first table, which is editable * @param cancellationSignal A signal to cancel the operation in progress, or null if none. * If the operation is canceled, then {@link OperationCanceledException} will be thrown * when the query is executed. * @return A {@link Cursor} object, which is positioned before the first entry. Note that * {@link Cursor}s are not synchronized, see the documentation for more details. */ public Cursor rawQueryWithFactory(CursorFactory cursorFactory, String sql, Object[] selectionArgs, String editTable, CancellationSignal cancellationSignal) { acquireReference(); try { SQLiteCursorDriver driver = new SQLiteDirectCursorDriver(this, sql, editTable, cancellationSignal); return driver.query(cursorFactory != null ? cursorFactory : mCursorFactory, selectionArgs); } finally { releaseReference(); } } /** * Convenience method for inserting a row into the database. * * @param table the table to insert the row into * @param nullColumnHack optional; may be <code>null</code>. * SQL doesn't allow inserting a completely empty row without * naming at least one column name. If your provided <code>values</code> is * empty, no column names are known and an empty row can't be inserted. * If not set to null, the <code>nullColumnHack</code> parameter * provides the name of nullable column name to explicitly insert a NULL into * in the case where your <code>values</code> is empty. * @param values this map contains the initial column values for the * row. The keys should be the column names and the values the * column values * @return the row ID of the newly inserted row, or -1 if an error occurred */ public long insert(String table, String nullColumnHack, ContentValues values) { try { return insertWithOnConflict(table, nullColumnHack, values, CONFLICT_NONE); } catch (SQLException e) { Log.e(TAG, "Error inserting " + values, e); return -1; } } /** * Convenience method for inserting a row into the database. * * @param table the table to insert the row into * @param nullColumnHack optional; may be <code>null</code>. * SQL doesn't allow inserting a completely empty row without * naming at least one column name. If your provided <code>values</code> is * empty, no column names are known and an empty row can't be inserted. * If not set to null, the <code>nullColumnHack</code> parameter * provides the name of nullable column name to explicitly insert a NULL into * in the case where your <code>values</code> is empty. * @param values this map contains the initial column values for the * row. The keys should be the column names and the values the * column values * @throws SQLException * @return the row ID of the newly inserted row, or -1 if an error occurred */ public long insertOrThrow(String table, String nullColumnHack, ContentValues values) throws SQLException { return insertWithOnConflict(table, nullColumnHack, values, CONFLICT_NONE); } /** * Convenience method for replacing a row in the database. * * @param table the table in which to replace the row * @param nullColumnHack optional; may be <code>null</code>. * SQL doesn't allow inserting a completely empty row without * naming at least one column name. If your provided <code>initialValues</code> is * empty, no column names are known and an empty row can't be inserted. * If not set to null, the <code>nullColumnHack</code> parameter * provides the name of nullable column name to explicitly insert a NULL into * in the case where your <code>initialValues</code> is empty. * @param initialValues this map contains the initial column values for * the row. * @return the row ID of the newly inserted row, or -1 if an error occurred */ public long replace(String table, String nullColumnHack, ContentValues initialValues) { try { return insertWithOnConflict(table, nullColumnHack, initialValues, CONFLICT_REPLACE); } catch (SQLException e) { Log.e(TAG, "Error inserting " + initialValues, e); return -1; } } /** * Convenience method for replacing a row in the database. * * @param table the table in which to replace the row * @param nullColumnHack optional; may be <code>null</code>. * SQL doesn't allow inserting a completely empty row without * naming at least one column name. If your provided <code>initialValues</code> is * empty, no column names are known and an empty row can't be inserted. * If not set to null, the <code>nullColumnHack</code> parameter * provides the name of nullable column name to explicitly insert a NULL into * in the case where your <code>initialValues</code> is empty. * @param initialValues this map contains the initial column values for * the row. The key * @throws SQLException * @return the row ID of the newly inserted row, or -1 if an error occurred */ public long replaceOrThrow(String table, String nullColumnHack, ContentValues initialValues) throws SQLException { return insertWithOnConflict(table, nullColumnHack, initialValues, CONFLICT_REPLACE); } /** * General method for inserting a row into the database. * * @param table the table to insert the row into * @param nullColumnHack optional; may be <code>null</code>. * SQL doesn't allow inserting a completely empty row without * naming at least one column name. If your provided <code>initialValues</code> is * empty, no column names are known and an empty row can't be inserted. * If not set to null, the <code>nullColumnHack</code> parameter * provides the name of nullable column name to explicitly insert a NULL into * in the case where your <code>initialValues</code> is empty. * @param initialValues this map contains the initial column values for the * row. The keys should be the column names and the values the * column values * @param conflictAlgorithm for insert conflict resolver * @return the row ID of the newly inserted row * OR the primary key of the existing row if the input param 'conflictAlgorithm' = * {@link #CONFLICT_IGNORE} * OR -1 if any error */ @SuppressWarnings("StringConcatenationInsideStringBufferAppend") public long insertWithOnConflict(String table, String nullColumnHack, ContentValues initialValues, @ConflictAlgorithm int conflictAlgorithm) { acquireReference(); try { StringBuilder sql = new StringBuilder(); sql.append("INSERT"); sql.append(CONFLICT_VALUES[conflictAlgorithm]); sql.append(" INTO "); sql.append(table); sql.append('('); Object[] bindArgs = null; int size = (initialValues != null && initialValues.size() > 0) ? initialValues.size() : 0; if (size > 0) { bindArgs = new Object[size]; int i = 0; for (Map.Entry<String, Object> entry : initialValues.valueSet()) { sql.append((i > 0) ? "," : ""); sql.append(entry.getKey()); bindArgs[i++] = entry.getValue(); } sql.append(')'); sql.append(" VALUES ("); for (i = 0; i < size; i++) { sql.append((i > 0) ? ",?" : "?"); } } else { sql.append(nullColumnHack + ") VALUES (NULL"); } sql.append(')'); SQLiteStatement statement = new SQLiteStatement(this, sql.toString(), bindArgs); try { return statement.executeInsert(); } finally { statement.close(); } } finally { releaseReference(); } } /** * Convenience method for deleting rows in the database. * * @param table the table to delete from * @param whereClause the optional WHERE clause to apply when deleting. * Passing null will delete all rows. * @param whereArgs You may include ?s in the where clause, which * will be replaced by the values from whereArgs. The values * will be bound as Strings. * @return the number of rows affected if a whereClause is passed in, 0 * otherwise. To remove all rows and get a count pass "1" as the * whereClause. */ public int delete(String table, String whereClause, String[] whereArgs) { acquireReference(); try { SQLiteStatement statement = new SQLiteStatement(this, "DELETE FROM " + table + (!TextUtils.isEmpty(whereClause) ? " WHERE " + whereClause : ""), whereArgs); try { return statement.executeUpdateDelete(); } finally { statement.close(); } } finally { releaseReference(); } } /** * Convenience method for updating rows in the database. * * @param table the table to update in * @param values a map from column names to new column values. null is a * valid value that will be translated to NULL. * @param whereClause the optional WHERE clause to apply when updating. * Passing null will update all rows. * @param whereArgs You may include ?s in the where clause, which * will be replaced by the values from whereArgs. The values * will be bound as Strings. * @return the number of rows affected */ public int update(String table, ContentValues values, String whereClause, String[] whereArgs) { return updateWithOnConflict(table, values, whereClause, whereArgs, CONFLICT_NONE); } /** * Convenience method for updating rows in the database. * * @param table the table to update in * @param values a map from column names to new column values. null is a * valid value that will be translated to NULL. * @param whereClause the optional WHERE clause to apply when updating. * Passing null will update all rows. * @param whereArgs You may include ?s in the where clause, which * will be replaced by the values from whereArgs. The values * will be bound as Strings. * @param conflictAlgorithm for update conflict resolver * @return the number of rows affected */ public int updateWithOnConflict(String table, ContentValues values, String whereClause, String[] whereArgs, @ConflictAlgorithm int conflictAlgorithm) { if (values == null || values.size() == 0) { throw new IllegalArgumentException("Empty values"); } acquireReference(); try { StringBuilder sql = new StringBuilder(120); sql.append("UPDATE "); sql.append(CONFLICT_VALUES[conflictAlgorithm]); sql.append(table); sql.append(" SET "); // move all bind args to one array int setValuesSize = values.size(); int bindArgsSize = (whereArgs == null) ? setValuesSize : (setValuesSize + whereArgs.length); Object[] bindArgs = new Object[bindArgsSize]; int i = 0; for (Map.Entry<String, Object> entry : values.valueSet()) { sql.append((i > 0) ? "," : ""); sql.append(entry.getKey()); bindArgs[i++] = entry.getValue(); sql.append("=?"); } if (whereArgs != null) { for (i = setValuesSize; i < bindArgsSize; i++) { bindArgs[i] = whereArgs[i - setValuesSize]; } } if (!TextUtils.isEmpty(whereClause)) { sql.append(" WHERE "); sql.append(whereClause); } SQLiteStatement statement = new SQLiteStatement(this, sql.toString(), bindArgs); try { return statement.executeUpdateDelete(); } finally { statement.close(); } } finally { releaseReference(); } } /** * Execute a single SQL statement that is NOT a SELECT * or any other SQL statement that returns data. * <p> * It has no means to return any data (such as the number of affected rows). * Instead, you're encouraged to use {@link #insert(String, String, ContentValues)}, * {@link #update(String, ContentValues, String, String[])}, et al, when possible. * </p> * <p> * When using {@link #enableWriteAheadLogging()}, journal_mode is * automatically managed by this class. So, do not set journal_mode * using "PRAGMA journal_mode'<value>" statement if your app is using * {@link #enableWriteAheadLogging()} * </p> * * @param sql the SQL statement to be executed. Multiple statements separated by semicolons are * not supported. * @throws SQLException if the SQL string is invalid */ public void execSQL(String sql) throws SQLException { executeSql(sql, null); } /** * Execute a single SQL statement that is NOT a SELECT/INSERT/UPDATE/DELETE. * <p> * For INSERT statements, use any of the following instead. * <ul> * <li>{@link #insert(String, String, ContentValues)}</li> * <li>{@link #insertOrThrow(String, String, ContentValues)}</li> * <li>{@link #insertWithOnConflict(String, String, ContentValues, int)}</li> * </ul> * <p> * For UPDATE statements, use any of the following instead. * <ul> * <li>{@link #update(String, ContentValues, String, String[])}</li> * <li>{@link #updateWithOnConflict(String, ContentValues, String, String[], int)}</li> * </ul> * <p> * For DELETE statements, use any of the following instead. * <ul> * <li>{@link #delete(String, String, String[])}</li> * </ul> * <p> * For example, the following are good candidates for using this method: * <ul> * <li>ALTER TABLE</li> * <li>CREATE or DROP table / trigger / view / index / virtual table</li> * <li>REINDEX</li> * <li>RELEASE</li> * <li>SAVEPOINT</li> * <li>PRAGMA that returns no data</li> * </ul> * </p> * <p> * When using {@link #enableWriteAheadLogging()}, journal_mode is * automatically managed by this class. So, do not set journal_mode * using "PRAGMA journal_mode'<value>" statement if your app is using * {@link #enableWriteAheadLogging()} * </p> * * @param sql the SQL statement to be executed. Multiple statements separated by semicolons are * not supported. * @param bindArgs only byte[], String, Long and Double are supported in bindArgs. * @throws SQLException if the SQL string is invalid */ public void execSQL(String sql, Object[] bindArgs) throws SQLException { if (bindArgs == null) { throw new IllegalArgumentException("Empty bindArgs"); } executeSql(sql, bindArgs); } private int executeSql(String sql, Object[] bindArgs) throws SQLException { acquireReference(); try { SQLiteStatement statement = new SQLiteStatement(this, sql, bindArgs); try { return statement.executeUpdateDelete(); } finally { statement.close(); } } finally { releaseReference(); } } /** * Returns true if the database is opened as read only. * * @return True if database is opened as read only. */ public boolean isReadOnly() { synchronized (mLock) { return isReadOnlyLocked(); } } private boolean isReadOnlyLocked() { return (mConfigurationLocked.openFlags & OPEN_READONLY) == OPEN_READONLY; } /** * Returns true if the database is in-memory db. * * @return True if the database is in-memory. * @hide */ public boolean isInMemoryDatabase() { synchronized (mLock) { return mConfigurationLocked.isInMemoryDb(); } } /** * Returns true if the database is currently open. * * @return True if the database is currently open (has not been closed). */ public boolean isOpen() { synchronized (mLock) { return mConnectionPoolLocked != null; } } /** * Returns true if the new version code is greater than the current database version. * * @param newVersion The new version code. * @return True if the new version code is greater than the current database version. */ public boolean needUpgrade(int newVersion) { return newVersion > getVersion(); } /** * Gets the path to the database file. * * @return The path to the database file. */ public final String getPath() { synchronized (mLock) { return mConfigurationLocked.path; } } /** * Sets the locale for this database. * * @param locale The new locale. * * @throws SQLException if the locale could not be set. The most common reason * for this is that there is no collator available for the locale you requested. * In this case the database remains unchanged. */ public void setLocale(Locale locale) { if (locale == null) { throw new IllegalArgumentException("locale must not be null."); } synchronized (mLock) { throwIfNotOpenLocked(); final Locale oldLocale = mConfigurationLocked.locale; mConfigurationLocked.locale = locale; try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.locale = oldLocale; throw ex; } } } /** * Sets the maximum size of the prepared-statement cache for this database. * (size of the cache = number of compiled-sql-statements stored in the cache). *<p> * Maximum cache size can ONLY be increased from its current size (default = 10). * If this method is called with smaller size than the current maximum value, * then IllegalStateException is thrown. *<p> * This method is thread-safe. * * @param cacheSize the size of the cache. can be (0 to {@link #MAX_SQL_CACHE_SIZE}) * @throws IllegalStateException if input cacheSize > {@link #MAX_SQL_CACHE_SIZE}. */ public void setMaxSqlCacheSize(int cacheSize) { if (cacheSize > MAX_SQL_CACHE_SIZE || cacheSize < 0) { throw new IllegalStateException("expected value between 0 and " + MAX_SQL_CACHE_SIZE); } synchronized (mLock) { throwIfNotOpenLocked(); final int oldMaxSqlCacheSize = mConfigurationLocked.maxSqlCacheSize; mConfigurationLocked.maxSqlCacheSize = cacheSize; try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.maxSqlCacheSize = oldMaxSqlCacheSize; throw ex; } } } /** * Sets whether foreign key constraints are enabled for the database. * <p> * By default, foreign key constraints are not enforced by the database. * This method allows an application to enable foreign key constraints. * It must be called each time the database is opened to ensure that foreign * key constraints are enabled for the session. * </p><p> * A good time to call this method is right after calling {@link #openOrCreateDatabase} * or in the {@link SQLiteOpenHelper#onConfigure} callback. * </p><p> * When foreign key constraints are disabled, the database does not check whether * changes to the database will violate foreign key constraints. Likewise, when * foreign key constraints are disabled, the database will not execute cascade * delete or update triggers. As a result, it is possible for the database * state to become inconsistent. To perform a database integrity check, * call {@link #isDatabaseIntegrityOk}. * </p><p> * This method must not be called while a transaction is in progress. * </p><p> * See also <a href="http://sqlite.org/foreignkeys.html">SQLite Foreign Key Constraints</a> * for more details about foreign key constraint support. * </p> * * @param enable True to enable foreign key constraints, false to disable them. * * @throws IllegalStateException if the are transactions is in progress * when this method is called. */ public void setForeignKeyConstraintsEnabled(boolean enable) { synchronized (mLock) { throwIfNotOpenLocked(); if (mConfigurationLocked.foreignKeyConstraintsEnabled == enable) { return; } mConfigurationLocked.foreignKeyConstraintsEnabled = enable; try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.foreignKeyConstraintsEnabled = !enable; throw ex; } } } /** * This method enables parallel execution of queries from multiple threads on the * same database. It does this by opening multiple connections to the database * and using a different database connection for each query. The database * journal mode is also changed to enable writes to proceed concurrently with reads. * <p> * When write-ahead logging is not enabled (the default), it is not possible for * reads and writes to occur on the database at the same time. Before modifying the * database, the writer implicitly acquires an exclusive lock on the database which * prevents readers from accessing the database until the write is completed. * </p><p> * In contrast, when write-ahead logging is enabled (by calling this method), write * operations occur in a separate log file which allows reads to proceed concurrently. * While a write is in progress, readers on other threads will perceive the state * of the database as it was before the write began. When the write completes, readers * on other threads will then perceive the new state of the database. * </p><p> * It is a good idea to enable write-ahead logging whenever a database will be * concurrently accessed and modified by multiple threads at the same time. * However, write-ahead logging uses significantly more memory than ordinary * journaling because there are multiple connections to the same database. * So if a database will only be used by a single thread, or if optimizing * concurrency is not very important, then write-ahead logging should be disabled. * </p><p> * After calling this method, execution of queries in parallel is enabled as long as * the database remains open. To disable execution of queries in parallel, either * call {@link #disableWriteAheadLogging} or close the database and reopen it. * </p><p> * The maximum number of connections used to execute queries in parallel is * dependent upon the device memory and possibly other properties. * </p><p> * If a query is part of a transaction, then it is executed on the same database handle the * transaction was begun. * </p><p> * Writers should use {@link #beginTransactionNonExclusive()} or * {@link #beginTransactionWithListenerNonExclusive(SQLiteTransactionListener)} * to start a transaction. Non-exclusive mode allows database file to be in readable * by other threads executing queries. * </p><p> * If the database has any attached databases, then execution of queries in parallel is NOT * possible. Likewise, write-ahead logging is not supported for read-only databases * or memory databases. In such cases, {@link #enableWriteAheadLogging} returns false. * </p><p> * The best way to enable write-ahead logging is to pass the * {@link #ENABLE_WRITE_AHEAD_LOGGING} flag to {@link #openDatabase}. This is * more efficient than calling {@link #enableWriteAheadLogging}. * <code><pre> * SQLiteDatabase db = SQLiteDatabase.openDatabase("db_filename", cursorFactory, * SQLiteDatabase.CREATE_IF_NECESSARY | SQLiteDatabase.ENABLE_WRITE_AHEAD_LOGGING, * myDatabaseErrorHandler); * db.enableWriteAheadLogging(); * </pre></code> * </p><p> * Another way to enable write-ahead logging is to call {@link #enableWriteAheadLogging} * after opening the database. * <code><pre> * SQLiteDatabase db = SQLiteDatabase.openDatabase("db_filename", cursorFactory, * SQLiteDatabase.CREATE_IF_NECESSARY, myDatabaseErrorHandler); * db.enableWriteAheadLogging(); * </pre></code> * </p><p> * See also <a href="http://sqlite.org/wal.html">SQLite Write-Ahead Logging</a> for * more details about how write-ahead logging works. * </p> * * @return True if write-ahead logging is enabled. * * @throws IllegalStateException if there are transactions in progress at the * time this method is called. WAL mode can only be changed when there are no * transactions in progress. * * @see #ENABLE_WRITE_AHEAD_LOGGING * @see #disableWriteAheadLogging */ public boolean enableWriteAheadLogging() { synchronized (mLock) { throwIfNotOpenLocked(); if ((mConfigurationLocked.openFlags & ENABLE_WRITE_AHEAD_LOGGING) != 0) { return true; } if (isReadOnlyLocked()) { // WAL doesn't make sense for readonly-databases. // TODO: True, but connection pooling does still make sense... return false; } if (mConfigurationLocked.isInMemoryDb()) { Log.i(TAG, "can't enable WAL for memory databases."); return false; } mConfigurationLocked.openFlags |= ENABLE_WRITE_AHEAD_LOGGING; try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.openFlags &= ~ENABLE_WRITE_AHEAD_LOGGING; throw ex; } } return true; } /** * This method disables the features enabled by {@link #enableWriteAheadLogging()}. * * @throws IllegalStateException if there are transactions in progress at the * time this method is called. WAL mode can only be changed when there are no * transactions in progress. * * @see #enableWriteAheadLogging */ public void disableWriteAheadLogging() { synchronized (mLock) { throwIfNotOpenLocked(); if ((mConfigurationLocked.openFlags & ENABLE_WRITE_AHEAD_LOGGING) == 0) { return; } mConfigurationLocked.openFlags &= ~ENABLE_WRITE_AHEAD_LOGGING; try { mConnectionPoolLocked.reconfigure(mConfigurationLocked); } catch (RuntimeException ex) { mConfigurationLocked.openFlags |= ENABLE_WRITE_AHEAD_LOGGING; throw ex; } } } /** * Returns true if write-ahead logging has been enabled for this database. * * @return True if write-ahead logging has been enabled for this database. * * @see #enableWriteAheadLogging * @see #ENABLE_WRITE_AHEAD_LOGGING */ public boolean isWriteAheadLoggingEnabled() { synchronized (mLock) { throwIfNotOpenLocked(); return (mConfigurationLocked.openFlags & ENABLE_WRITE_AHEAD_LOGGING) != 0; } } /** * Collect statistics about all open databases in the current process. * Used by bug report. */ static ArrayList<SQLiteDebug.DbStats> getDbStats() { ArrayList<SQLiteDebug.DbStats> dbStatsList = new ArrayList<>(); for (SQLiteDatabase db : getActiveDatabases()) { db.collectDbStats(dbStatsList); } return dbStatsList; } private void collectDbStats(ArrayList<SQLiteDebug.DbStats> dbStatsList) { synchronized (mLock) { if (mConnectionPoolLocked != null) { mConnectionPoolLocked.collectDbStats(dbStatsList); } } } private static ArrayList<SQLiteDatabase> getActiveDatabases() { ArrayList<SQLiteDatabase> databases = new ArrayList<>(); synchronized (sActiveDatabases) { databases.addAll(sActiveDatabases.keySet()); } return databases; } /** * Dump detailed information about all open databases in the current process. * Used by bug report. */ static void dumpAll(Printer printer, boolean verbose) { for (SQLiteDatabase db : getActiveDatabases()) { db.dump(printer, verbose); } } private void dump(Printer printer, boolean verbose) { synchronized (mLock) { if (mConnectionPoolLocked != null) { printer.println(""); mConnectionPoolLocked.dump(printer, verbose); } } } /** * Returns list of full pathnames of all attached databases including the main database * by executing 'pragma database_list' on the database. * * @return ArrayList of pairs of (database name, database file path) or null if the database * is not open. */ public List<Pair<String, String>> getAttachedDbs() { ArrayList<Pair<String, String>> attachedDbs = new ArrayList<>(); synchronized (mLock) { if (mConnectionPoolLocked == null) { return null; // not open } acquireReference(); } try { // has attached databases. query sqlite to get the list of attached databases. Cursor c = null; try { c = rawQuery("pragma database_list;", null); while (c.moveToNext()) { // sqlite returns a row for each database in the returned list of databases. // in each row, // 1st column is the database name such as main, or the database // name specified on the "ATTACH" command // 2nd column is the database file path. attachedDbs.add(new Pair<>(c.getString(1), c.getString(2))); } } finally { if (c != null) { c.close(); } } return attachedDbs; } finally { releaseReference(); } } /** * Runs 'pragma integrity_check' on the given database (and all the attached databases) * and returns true if the given database (and all its attached databases) pass integrity_check, * false otherwise. *<p> * If the result is false, then this method logs the errors reported by the integrity_check * command execution. *<p> * Note that 'pragma integrity_check' on a database can take a long time. * * @return true if the given database (and all its attached databases) pass integrity_check, * false otherwise. */ public boolean isDatabaseIntegrityOk() { acquireReference(); try { List<Pair<String, String>> attachedDbs; try { attachedDbs = getAttachedDbs(); if (attachedDbs == null) { throw new IllegalStateException("databaselist for: " + getPath() + " couldn't " + "be retrieved. probably because the database is closed"); } } catch (SQLiteException e) { // can't get attachedDb list. do integrity check on the main database attachedDbs = new ArrayList<>(); attachedDbs.add(new Pair<>("main", getPath())); } for (Pair<String, String> p : attachedDbs) { SQLiteStatement prog = null; try { prog = compileStatement("PRAGMA " + p.first + ".integrity_check(1);"); String rslt = prog.simpleQueryForString(); if (!rslt.equalsIgnoreCase("ok")) { // integrity_checker failed on main or attached databases Log.e(TAG, "PRAGMA integrity_check on " + p.second + " returned: " + rslt); return false; } } finally { if (prog != null) prog.close(); } } } finally { releaseReference(); } return true; } @Override public String toString() { return "SQLiteDatabase: " + getPath(); } private void throwIfNotOpenLocked() { if (mConnectionPoolLocked == null) { throw new IllegalStateException("The database '" + mConfigurationLocked.label + "' is not open."); } } /** * Used to allow returning sub-classes of {@link Cursor} when calling query. */ public interface CursorFactory { /** * See {@link SQLiteCursor#SQLiteCursor(SQLiteCursorDriver, String, SQLiteQuery)}. */ Cursor newCursor(SQLiteDatabase db, SQLiteCursorDriver masterQuery, String editTable, SQLiteQuery query); } /** * A callback interface for a custom sqlite3 function. This can be used to create a function * that can be called from sqlite3 database triggers. */ public interface CustomFunction { /** * Invoked whenever the function is called. * @param args function arguments * @return String value of the result or null */ String callback(String[] args); } static boolean hasCodec() { return SQLiteConnection.hasCodec(); } void enableLocalizedCollators() { mConnectionPoolLocked.enableLocalizedCollators(); } /** * Query the table for the number of rows in the table. * @param table the name of the table to query * @return the number of rows in the table */ public long queryNumEntries(String table) { return queryNumEntries(table, null, null); } /** * Query the table for the number of rows in the table. * @param table the name of the table to query * @param selection A filter declaring which rows to return, * formatted as an SQL WHERE clause (excluding the WHERE itself). * Passing null will count all rows for the given table * @return the number of rows in the table filtered by the selection */ public long queryNumEntries(String table, String selection) { return queryNumEntries(table, selection, null); } /** * Query the table for the number of rows in the table. * @param table the name of the table to query * @param selection A filter declaring which rows to return, * formatted as an SQL WHERE clause (excluding the WHERE itself). * Passing null will count all rows for the given table * @param selectionArgs You may include ?s in selection, * which will be replaced by the values from selectionArgs, * in order that they appear in the selection. * The values will be bound as Strings. * @return the number of rows in the table filtered by the selection */ public long queryNumEntries(String table, String selection, String[] selectionArgs) { String s = (!TextUtils.isEmpty(selection)) ? " where " + selection : ""; return longForQuery("select count(*) from " + table + s, selectionArgs); } /** * Utility method to run the query on the db and return the value in the * first column of the first row. */ public long longForQuery(String query, String[] selectionArgs) { SQLiteStatement prog = compileStatement(query); try { return longForQuery(prog, selectionArgs); } finally { prog.close(); } } /** * Utility method to run the pre-compiled query and return the value in the * first column of the first row. */ private static long longForQuery(SQLiteStatement prog, String[] selectionArgs) { prog.bindAllArgsAsStrings(selectionArgs); return prog.simpleQueryForLong(); } /** * Utility method to run the query on the db and return the value in the * first column of the first row. */ public String stringForQuery(String query, String[] selectionArgs) { SQLiteStatement prog = compileStatement(query); try { return stringForQuery(prog, selectionArgs); } finally { prog.close(); } } /** * Utility method to run the pre-compiled query and return the value in the * first column of the first row. */ public static String stringForQuery(SQLiteStatement prog, String[] selectionArgs) { prog.bindAllArgsAsStrings(selectionArgs); return prog.simpleQueryForString(); } /** * Utility method to run the query on the db and return the blob value in the * first column of the first row. * * @return A read-only file descriptor for a copy of the blob value. */ public ParcelFileDescriptor blobFileDescriptorForQuery(String query, String[] selectionArgs) { SQLiteStatement prog = compileStatement(query); try { return blobFileDescriptorForQuery(prog, selectionArgs); } finally { prog.close(); } } /** * Utility method to run the pre-compiled query and return the blob value in the * first column of the first row. * * @return A read-only file descriptor for a copy of the blob value. */ public static ParcelFileDescriptor blobFileDescriptorForQuery(SQLiteStatement prog, String[] selectionArgs) { prog.bindAllArgsAsStrings(selectionArgs); return prog.simpleQueryForBlobFileDescriptor(); } }