/* * 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. */ package android.database.sqlite; import android.database.Cursor; import android.database.DatabaseUtils; import android.provider.BaseColumns; import android.text.TextUtils; import android.util.Log; import java.util.Iterator; import java.util.Map; import java.util.Map.Entry; import java.util.Set; import java.util.regex.Pattern; /** * This is a convience class that helps build SQL queries to be sent to * {@link SQLiteDatabase} objects. */ public class SQLiteQueryBuilder { private static final String TAG = "SQLiteQueryBuilder"; private static final Pattern sLimitPattern = Pattern.compile("\\s*\\d+\\s*(,\\s*\\d+\\s*)?"); private Map mProjectionMap = null; private String mTables = ""; private StringBuilder mWhereClause = null; // lazily created private boolean mDistinct; private SQLiteDatabase.CursorFactory mFactory; private boolean mStrict; public SQLiteQueryBuilder() { mDistinct = false; mFactory = null; } /** * Mark the query as DISTINCT. * * @param distinct if true the query is DISTINCT, otherwise it isn't */ public void setDistinct(boolean distinct) { mDistinct = distinct; } /** * Returns the list of tables being queried * * @return the list of tables being queried */ public String getTables() { return mTables; } /** * Sets the list of tables to query. Multiple tables can be specified to perform a join. * For example: * setTables("foo, bar") * setTables("foo LEFT OUTER JOIN bar ON (foo.id = bar.foo_id)") * * @param inTables the list of tables to query on */ public void setTables(String inTables) { mTables = inTables; } /** * Append a chunk to the WHERE clause of the query. All chunks appended are surrounded * by parenthesis and ANDed with the selection passed to {@link #query}. The final * WHERE clause looks like: * * WHERE (<append chunk 1><append chunk2>) AND (<query() selection parameter>) * * @param inWhere the chunk of text to append to the WHERE clause. */ public void appendWhere(CharSequence inWhere) { if (mWhereClause == null) { mWhereClause = new StringBuilder(inWhere.length() + 16); } if (mWhereClause.length() == 0) { mWhereClause.append('('); } mWhereClause.append(inWhere); } /** * Append a chunk to the WHERE clause of the query. All chunks appended are surrounded * by parenthesis and ANDed with the selection passed to {@link #query}. The final * WHERE clause looks like: * * WHERE (<append chunk 1><append chunk2>) AND (<query() selection parameter>) * * @param inWhere the chunk of text to append to the WHERE clause. it will be escaped * to avoid SQL injection attacks */ public void appendWhereEscapeString(String inWhere) { if (mWhereClause == null) { mWhereClause = new StringBuilder(inWhere.length() + 16); } if (mWhereClause.length() == 0) { mWhereClause.append('('); } DatabaseUtils.appendEscapedSQLString(mWhereClause, inWhere); } /** * Sets the projection map for the query. The projection map maps * from column names that the caller passes into query to database * column names. This is useful for renaming columns as well as * disambiguating column names when doing joins. For example you * could map "name" to "people.name". If a projection map is set * it must contain all column names the user may request, even if * the key and value are the same. * * @param columnMap maps from the user column names to the database column names */ public void setProjectionMap(Map columnMap) { mProjectionMap = columnMap; } /** * Sets the cursor factory to be used for the query. You can use * one factory for all queries on a database but it is normally * easier to specify the factory when doing this query. @param * factory the factor to use */ public void setCursorFactory(SQLiteDatabase.CursorFactory factory) { mFactory = factory; } /** * When set, the selection is verified against malicious arguments. * When using this class to create a statement using * {@link #buildQueryString(boolean, String, String[], String, String, String, String, String)}, * non-numeric limits will raise an exception. If a projection map is specified, fields * not in that map will be ignored. * If this class is used to execute the statement directly using * {@link #query(SQLiteDatabase, String[], String, String[], String, String, String)} * or * {@link #query(SQLiteDatabase, String[], String, String[], String, String, String, String)}, * additionally also parenthesis escaping selection are caught. * * To summarize: To get maximum protection against malicious third party apps (for example * content provider consumers), make sure to do the following: * * By default, this value is false. */ public void setStrict(boolean flag) { mStrict = flag; } /** * Build an SQL query string from the given clauses. * * @param distinct true if you want each row to be unique, false otherwise. * @param tables The table names 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 where 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 URL. * @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 the SQL query string */ public static String buildQueryString( boolean distinct, String tables, String[] columns, String where, String groupBy, String having, String orderBy, String limit) { if (TextUtils.isEmpty(groupBy) && !TextUtils.isEmpty(having)) { throw new IllegalArgumentException( "HAVING clauses are only permitted when using a groupBy clause"); } if (!TextUtils.isEmpty(limit) && !sLimitPattern.matcher(limit).matches()) { throw new IllegalArgumentException("invalid LIMIT clauses:" + limit); } StringBuilder query = new StringBuilder(120); query.append("SELECT "); if (distinct) { query.append("DISTINCT "); } if (columns != null && columns.length != 0) { appendColumns(query, columns); } else { query.append("* "); } query.append("FROM "); query.append(tables); appendClause(query, " WHERE ", where); appendClause(query, " GROUP BY ", groupBy); appendClause(query, " HAVING ", having); appendClause(query, " ORDER BY ", orderBy); appendClause(query, " LIMIT ", limit); return query.toString(); } private static void appendClause(StringBuilder s, String name, String clause) { if (!TextUtils.isEmpty(clause)) { s.append(name); s.append(clause); } } /** * Add the names that are non-null in columns to s, separating * them with commas. */ public static void appendColumns(StringBuilder s, String[] columns) { int n = columns.length; for (int i = 0; i < n; i++) { String column = columns[i]; if (column != null) { if (i > 0) { s.append(", "); } s.append(column); } } s.append(' '); } /** * Perform a query by combining all current settings and the * information passed into this method. * * @param db the database to query on * @param projectionIn 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 URL. * @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. * @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 sortOrder 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 cursor over the result set * @see android.content.ContentResolver#query(android.net.Uri, String[], * String, String[], String) */ public Cursor query(SQLiteDatabase db, String[] projectionIn, String selection, String[] selectionArgs, String groupBy, String having, String sortOrder) { return query(db, projectionIn, selection, selectionArgs, groupBy, having, sortOrder, null /* limit */); } /** * Perform a query by combining all current settings and the * information passed into this method. * * @param db the database to query on * @param projectionIn 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 URL. * @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. * @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 sortOrder 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 cursor over the result set * @see android.content.ContentResolver#query(android.net.Uri, String[], * String, String[], String) */ public Cursor query(SQLiteDatabase db, String[] projectionIn, String selection, String[] selectionArgs, String groupBy, String having, String sortOrder, String limit) { if (mTables == null) { return null; } if (mStrict && selection != null && selection.length() > 0) { // Validate the user-supplied selection to detect syntactic anomalies // in the selection string that could indicate a SQL injection attempt. // The idea is to ensure that the selection clause is a valid SQL expression // by compiling it twice: once wrapped in parentheses and once as // originally specified. An attacker cannot create an expression that // would escape the SQL expression while maintaining balanced parentheses // in both the wrapped and original forms. String sqlForValidation = buildQuery(projectionIn, "(" + selection + ")", groupBy, having, sortOrder, limit); validateSql(db, sqlForValidation); // will throw if query is invalid } String sql = buildQuery( projectionIn, selection, groupBy, having, sortOrder, limit); if (Log.isLoggable(TAG, Log.DEBUG)) { Log.d(TAG, "Performing query: " + sql); } return db.rawQueryWithFactory( mFactory, sql, selectionArgs, SQLiteDatabase.findEditTable(mTables)); // will throw if query is invalid } /** * Verifies that a SQL statement is valid by compiling it. * If the SQL statement is not valid, this method will throw a {@link SQLiteException}. */ private void validateSql(SQLiteDatabase db, String sql) { db.lock(sql); try { new SQLiteCompiledSql(db, sql).releaseSqlStatement(); } finally { db.unlock(); } } /** * Construct a SELECT statement suitable for use in a group of * SELECT statements that will be joined through UNION operators * in buildUnionQuery. * * @param projectionIn 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 * URL. * @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 sortOrder 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 the resulting SQL SELECT statement */ public String buildQuery( String[] projectionIn, String selection, String groupBy, String having, String sortOrder, String limit) { String[] projection = computeProjection(projectionIn); StringBuilder where = new StringBuilder(); boolean hasBaseWhereClause = mWhereClause != null && mWhereClause.length() > 0; if (hasBaseWhereClause) { where.append(mWhereClause.toString()); where.append(')'); } // Tack on the user's selection, if present. if (selection != null && selection.length() > 0) { if (hasBaseWhereClause) { where.append(" AND "); } where.append('('); where.append(selection); where.append(')'); } return buildQueryString( mDistinct, mTables, projection, where.toString(), groupBy, having, sortOrder, limit); } /** * @deprecated This method's signature is misleading since no SQL parameter * substitution is carried out. The selection arguments parameter does not get * used at all. To avoid confusion, call * {@link #buildQuery(String[], String, String, String, String, String)} instead. */ @Deprecated public String buildQuery( String[] projectionIn, String selection, String[] selectionArgs, String groupBy, String having, String sortOrder, String limit) { return buildQuery(projectionIn, selection, groupBy, having, sortOrder, limit); } /** * Construct a SELECT statement suitable for use in a group of * SELECT statements that will be joined through UNION operators * in buildUnionQuery. * * @param typeDiscriminatorColumn the name of the result column * whose cells will contain the name of the table from which * each row was drawn. * @param unionColumns the names of the columns to appear in the * result. This may include columns that do not appear in the * table this SELECT is querying (i.e. mTables), but that do * appear in one of the other tables in the UNION query that we * are constructing. * @param columnsPresentInTable a Set of the names of the columns * that appear in this table (i.e. in the table whose name is * mTables). Since columns in unionColumns include columns that * appear only in other tables, we use this array to distinguish * which ones actually are present. Other columns will have * NULL values for results from this subquery. * @param computedColumnsOffset all columns in unionColumns before * this index are included under the assumption that they're * computed and therefore won't appear in columnsPresentInTable, * e.g. "date * 1000 as normalized_date" * @param typeDiscriminatorValue the value used for the * type-discriminator column in this subquery * @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 * URL. * @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. * @return the resulting SQL SELECT statement */ public String buildUnionSubQuery( String typeDiscriminatorColumn, String[] unionColumns, Set columnsPresentInTable, int computedColumnsOffset, String typeDiscriminatorValue, String selection, String groupBy, String having) { int unionColumnsCount = unionColumns.length; String[] projectionIn = new String[unionColumnsCount]; for (int i = 0; i < unionColumnsCount; i++) { String unionColumn = unionColumns[i]; if (unionColumn.equals(typeDiscriminatorColumn)) { projectionIn[i] = "'" + typeDiscriminatorValue + "' AS " + typeDiscriminatorColumn; } else if (i <= computedColumnsOffset || columnsPresentInTable.contains(unionColumn)) { projectionIn[i] = unionColumn; } else { projectionIn[i] = "NULL AS " + unionColumn; } } return buildQuery( projectionIn, selection, groupBy, having, null /* sortOrder */, null /* limit */); } /** * @deprecated This method's signature is misleading since no SQL parameter * substitution is carried out. The selection arguments parameter does not get * used at all. To avoid confusion, call * {@link #buildUnionSubQuery} * instead. */ @Deprecated public String buildUnionSubQuery( String typeDiscriminatorColumn, String[] unionColumns, Set columnsPresentInTable, int computedColumnsOffset, String typeDiscriminatorValue, String selection, String[] selectionArgs, String groupBy, String having) { return buildUnionSubQuery( typeDiscriminatorColumn, unionColumns, columnsPresentInTable, computedColumnsOffset, typeDiscriminatorValue, selection, groupBy, having); } /** * Given a set of subqueries, all of which are SELECT statements, * construct a query that returns the union of what those * subqueries return. * @param subQueries an array of SQL SELECT statements, all of * which must have the same columns as the same positions in * their results * @param sortOrder 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 The limit clause, which applies to the entire union result set * * @return the resulting SQL SELECT statement */ public String buildUnionQuery(String[] subQueries, String sortOrder, String limit) { StringBuilder query = new StringBuilder(128); int subQueryCount = subQueries.length; String unionOperator = mDistinct ? " UNION " : " UNION ALL "; for (int i = 0; i < subQueryCount; i++) { if (i > 0) { query.append(unionOperator); } query.append(subQueries[i]); } appendClause(query, " ORDER BY ", sortOrder); appendClause(query, " LIMIT ", limit); return query.toString(); } private String[] computeProjection(String[] projectionIn) { if (projectionIn != null && projectionIn.length > 0) { if (mProjectionMap != null) { String[] projection = new String[projectionIn.length]; int length = projectionIn.length; for (int i = 0; i < length; i++) { String userColumn = projectionIn[i]; String column = mProjectionMap.get(userColumn); if (column != null) { projection[i] = column; continue; } if (!mStrict && ( userColumn.contains(" AS ") || userColumn.contains(" as "))) { /* A column alias already exist */ projection[i] = userColumn; continue; } throw new IllegalArgumentException("Invalid column " + projectionIn[i]); } return projection; } else { return projectionIn; } } else if (mProjectionMap != null) { // Return all columns in projection map. Set> entrySet = mProjectionMap.entrySet(); String[] projection = new String[entrySet.size()]; Iterator> entryIter = entrySet.iterator(); int i = 0; while (entryIter.hasNext()) { Entry entry = entryIter.next(); // Don't include the _count column when people ask for no projection. if (entry.getKey().equals(BaseColumns._COUNT)) { continue; } projection[i++] = entry.getValue(); } return projection; } return null; } }