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package com.sun.gjc.spi.base;

import com.sun.gjc.common.DataSourceObjectBuilder;
import com.sun.gjc.util.ResultSetClosedEventListener;

import java.io.InputStream;
import java.io.Reader;
import java.math.BigDecimal;
import java.net.URL;
import java.sql.*;
import java.util.Calendar;
import java.util.logging.Level;

/**
 * Abstract class for wrapping PreparedStatement
*/ public abstract class PreparedStatementWrapper extends StatementWrapper implements PreparedStatement, ResultSetClosedEventListener { protected PreparedStatement preparedStatement = null; private boolean busy = false; private boolean cached = false; private int defaultMaxFieldSize; private int defaultMaxRows; private int defaultQueryTimeout; private int defaultFetchDirection; private int defaultFetchSize; private int currentMaxFieldSize; private int currentMaxRows; private int currentQueryTimeout; private int currentFetchDirection; private int currentFetchSize; private boolean valid = true; /** * Abstract class for wrapping PreparedStatement
* * @param con Connection Wrapper
* @param statement PreparedStatement that is to be wrapped.
* @param cachingEnabled boolean that enabled/ disables caching
* @throws SQLException Exception thrown from underlying statement
*/ public PreparedStatementWrapper(Connection con, PreparedStatement statement, boolean cachingEnabled) throws SQLException { super(con, statement); preparedStatement = statement; cached = cachingEnabled; ConnectionHolder wrappedCon = (ConnectionHolder) con; leakDetector = wrappedCon.getManagedConnection().getLeakDetector(); if (cached) { defaultQueryTimeout = preparedStatement.getQueryTimeout(); defaultMaxFieldSize = preparedStatement.getMaxFieldSize(); defaultFetchSize = preparedStatement.getFetchSize(); defaultMaxRows = preparedStatement.getMaxRows(); defaultFetchDirection = preparedStatement.getFetchDirection(); currentQueryTimeout = defaultQueryTimeout; currentMaxFieldSize = defaultMaxFieldSize; currentFetchSize = defaultFetchSize; currentMaxRows = defaultMaxRows; currentFetchDirection = defaultFetchDirection; } else { //Start Statement leak detection if(leakDetector != null) { leakDetector.startStatementLeakTracing(preparedStatement, this); } } } /** * Executes the SQL statement in this PreparedStatement object, * which must be an SQL INSERT, UPDATE or * DELETE statement; or an SQL statement that returns nothing, * such as a DDL statement. * * @return either (1) the row count for INSERT, UPDATE, * or DELETE statements * or (2) 0 for SQL statements that return nothing * @throws java.sql.SQLException if a database access error occurs or the SQL * statement returns a ResultSet object */ public int executeUpdate() throws SQLException { return preparedStatement.executeUpdate(); } /** * Sets the designated parameter to SQL NULL. *

*

Note: You must specify the parameter's SQL type. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param sqlType the SQL type code defined in java.sql.Types * @throws java.sql.SQLException if a database access error occurs */ public void setNull(int parameterIndex, int sqlType) throws SQLException { preparedStatement.setNull(parameterIndex, sqlType); } /** * Sets the designated parameter to the given Java boolean value. * The driver converts this * to an SQL BIT value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setBoolean(int parameterIndex, boolean x) throws SQLException { preparedStatement.setBoolean(parameterIndex, x); } /** * Sets the designated parameter to the given Java byte value. * The driver converts this * to an SQL TINYINT value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setByte(int parameterIndex, byte x) throws SQLException { preparedStatement.setByte(parameterIndex, x); } /** * Sets the designated parameter to the given Java short value. * The driver converts this * to an SQL SMALLINT value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setShort(int parameterIndex, short x) throws SQLException { preparedStatement.setShort(parameterIndex, x); } /** * Sets the designated parameter to the given Java int value. * The driver converts this * to an SQL INTEGER value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setInt(int parameterIndex, int x) throws SQLException { preparedStatement.setInt(parameterIndex, x); } /** * Sets the designated parameter to the given Java long value. * The driver converts this * to an SQL BIGINT value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setLong(int parameterIndex, long x) throws SQLException { preparedStatement.setLong(parameterIndex, x); } /** * Sets the designated parameter to the given Java float value. * The driver converts this * to an SQL FLOAT value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setFloat(int parameterIndex, float x) throws SQLException { preparedStatement.setFloat(parameterIndex, x); } /** * Sets the designated parameter to the given Java double value. * The driver converts this * to an SQL DOUBLE value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setDouble(int parameterIndex, double x) throws SQLException { preparedStatement.setDouble(parameterIndex, x); } /** * Sets the designated parameter to the given java.math.BigDecimal value. * The driver converts this to an SQL NUMERIC value when * it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setBigDecimal(int parameterIndex, BigDecimal x) throws SQLException { preparedStatement.setBigDecimal(parameterIndex, x); } /** * Sets the designated parameter to the given Java String value. * The driver converts this * to an SQL VARCHAR or LONGVARCHAR value * (depending on the argument's * size relative to the driver's limits on VARCHAR values) * when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setString(int parameterIndex, String x) throws SQLException { preparedStatement.setString(parameterIndex, x); } /** * Sets the designated parameter to the given Java array of bytes. The driver converts * this to an SQL VARBINARY or LONGVARBINARY * (depending on the argument's size relative to the driver's limits on * VARBINARY values) when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setBytes(int parameterIndex, byte x[]) throws SQLException { preparedStatement.setBytes(parameterIndex, x); } /** * Sets the designated parameter to the given java.sql.Date value. * The driver converts this * to an SQL DATE value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setDate(int parameterIndex, Date x) throws SQLException { preparedStatement.setDate(parameterIndex, x); } /** * Sets the designated parameter to the given java.sql.Time value. * The driver converts this * to an SQL TIME value when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setTime(int parameterIndex, Time x) throws SQLException { preparedStatement.setTime(parameterIndex, x); } /** * Sets the designated parameter to the given java.sql.Timestamp value. * The driver * converts this to an SQL TIMESTAMP value when it sends it to the * database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @throws java.sql.SQLException if a database access error occurs */ public void setTimestamp(int parameterIndex, Timestamp x) throws SQLException { preparedStatement.setTimestamp(parameterIndex, x); } /** * Sets the designated parameter to the given input stream, which will have * the specified number of bytes. * When a very large ASCII value is input to a LONGVARCHAR * parameter, it may be more practical to send it via a * java.io.InputStream. Data will be read from the stream * as needed until end-of-file is reached. The JDBC driver will * do any necessary conversion from ASCII to the database char format. *

*

Note: This stream object can either be a standard * Java stream object or your own subclass that implements the * standard interface. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the Java input stream that contains the ASCII parameter value * @param length the number of bytes in the stream * @throws java.sql.SQLException if a database access error occurs */ public void setAsciiStream(int parameterIndex, InputStream x, int length) throws SQLException { preparedStatement.setAsciiStream(parameterIndex, x, length); } /** * Sets the designated parameter to the given input stream, which * will have the specified number of bytes. A Unicode character has * two bytes, with the first byte being the high byte, and the second * being the low byte. *

* When a very large Unicode value is input to a LONGVARCHAR * parameter, it may be more practical to send it via a * java.io.InputStream object. The data will be read from the * stream as needed until end-of-file is reached. The JDBC driver will * do any necessary conversion from Unicode to the database char format. *

*

Note: This stream object can either be a standard * Java stream object or your own subclass that implements the * standard interface. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x a java.io.InputStream object that contains the * Unicode parameter value as two-byte Unicode characters * @param length the number of bytes in the stream * @throws java.sql.SQLException if a database access error occurs * @deprecated */ @Deprecated public void setUnicodeStream(int parameterIndex, InputStream x, int length) throws SQLException { preparedStatement.setUnicodeStream(parameterIndex, x, length); } /** * Sets the designated parameter to the given input stream, which will have * the specified number of bytes. * When a very large binary value is input to a LONGVARBINARY * parameter, it may be more practical to send it via a * java.io.InputStream object. The data will be read from the * stream as needed until end-of-file is reached. *

*

Note: This stream object can either be a standard * Java stream object or your own subclass that implements the * standard interface. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the java input stream which contains the binary parameter value * @param length the number of bytes in the stream * @throws java.sql.SQLException if a database access error occurs */ public void setBinaryStream(int parameterIndex, InputStream x, int length) throws SQLException { preparedStatement.setBinaryStream(parameterIndex, x, length); } /** * Clears the current parameter values immediately. *

In general, parameter values remain in force for repeated use of a * statement. Setting a parameter value automatically clears its * previous value. However, in some cases it is useful to immediately * release the resources used by the current parameter values; this can * be done by calling the method clearParameters. * * @throws java.sql.SQLException if a database access error occurs */ public void clearParameters() throws SQLException { preparedStatement.clearParameters(); } /** *

Sets the value of the designated parameter with the given object. The second * argument must be an object type; for integral values, the * java.lang equivalent objects should be used. *

*

The given Java object will be converted to the given targetSqlType * before being sent to the database. *

* If the object has a custom mapping (is of a class implementing the * interface SQLData), * the JDBC driver should call the method SQLData.writeSQL to * write it to the SQL data stream. * If, on the other hand, the object is of a class implementing * Ref, Blob, Clob, Struct, * or Array, the driver should pass it to the database as a * value of the corresponding SQL type. *

*

Note that this method may be used to pass database-specific * abstract data types. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the object containing the input parameter value * @param targetSqlType the SQL type (as defined in java.sql.Types) to be * sent to the database. The scale argument may further qualify this type. * @param scale for java.sql.Types.DECIMAL or java.sql.Types.NUMERIC types, * this is the number of digits after the decimal point. For all other * types, this value will be ignored. * @throws java.sql.SQLException if a database access error occurs * @see java.sql.Types */ public void setObject(int parameterIndex, Object x, int targetSqlType, int scale) throws SQLException { preparedStatement.setObject(parameterIndex, x, targetSqlType, scale); } /** * Sets the value of the designated parameter with the given object. * This method is like the method setObject * above, except that it assumes a scale of zero. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the object containing the input parameter value * @param targetSqlType the SQL type (as defined in java.sql.Types) to be * sent to the database * @throws java.sql.SQLException if a database access error occurs */ public void setObject(int parameterIndex, Object x, int targetSqlType) throws SQLException { preparedStatement.setObject(parameterIndex, x, targetSqlType); } /** *

Sets the value of the designated parameter using the given object. * The second parameter must be of type Object; therefore, the * java.lang equivalent objects should be used for built-in types. *

*

The JDBC specification specifies a standard mapping from * Java Object types to SQL types. The given argument * will be converted to the corresponding SQL type before being * sent to the database. *

*

Note that this method may be used to pass datatabase- * specific abstract data types, by using a driver-specific Java * type. *

* If the object is of a class implementing the interface SQLData, * the JDBC driver should call the method SQLData.writeSQL * to write it to the SQL data stream. * If, on the other hand, the object is of a class implementing * Ref, Blob, Clob, Struct, * or Array, the driver should pass it to the database as a * value of the corresponding SQL type. *

* This method throws an exception if there is an ambiguity, for example, if the * object is of a class implementing more than one of the interfaces named above. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the object containing the input parameter value * @throws java.sql.SQLException if a database access error occurs or the type * of the given object is ambiguous */ public void setObject(int parameterIndex, Object x) throws SQLException { preparedStatement.setObject(parameterIndex, x); } /** * Executes the SQL statement in this PreparedStatement object, * which may be any kind of SQL statement. * Some prepared statements return multiple results; the execute * method handles these complex statements as well as the simpler * form of statements handled by the methods executeQuery * and executeUpdate. *

* The execute method returns a boolean to * indicate the form of the first result. You must call either the method * getResultSet or getUpdateCount * to retrieve the result; you must call getMoreResults to * move to any subsequent result(s). * * @return true if the first result is a ResultSet * object; false if the first result is an update * count or there is no result * @throws java.sql.SQLException if a database access error occurs or an argument * is supplied to this method * @see java.sql.Statement#execute * @see java.sql.Statement#getResultSet * @see java.sql.Statement#getUpdateCount * @see java.sql.Statement#getMoreResults */ public boolean execute() throws SQLException { return preparedStatement.execute(); } /** * Adds a set of parameters to this PreparedStatement * object's batch of commands. * * @throws java.sql.SQLException if a database access error occurs * @see java.sql.Statement#addBatch * @since 1.2 */ public void addBatch() throws SQLException { preparedStatement.addBatch(); } /** * Sets the designated parameter to the given Reader * object, which is the given number of characters long. * When a very large UNICODE value is input to a LONGVARCHAR * parameter, it may be more practical to send it via a * java.io.Reader object. The data will be read from the stream * as needed until end-of-file is reached. The JDBC driver will * do any necessary conversion from UNICODE to the database char format. *

*

Note: This stream object can either be a standard * Java stream object or your own subclass that implements the * standard interface. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param reader the java.io.Reader object that contains the * Unicode data * @param length the number of characters in the stream * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setCharacterStream(int parameterIndex, Reader reader, int length) throws SQLException { preparedStatement.setCharacterStream(parameterIndex, reader, length); } /** * Sets the designated parameter to the given * REF(<structured-type>) value. * The driver converts this to an SQL REF value when it * sends it to the database. * * @param i the first parameter is 1, the second is 2, ... * @param x an SQL REF value * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setRef(int i, Ref x) throws SQLException { preparedStatement.setRef(i, x); } /** * Sets the designated parameter to the given Blob object. * The driver converts this to an SQL BLOB value when it * sends it to the database. * * @param i the first parameter is 1, the second is 2, ... * @param x a Blob object that maps an SQL BLOB value * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setBlob(int i, Blob x) throws SQLException { preparedStatement.setBlob(i, x); } /** * Sets the designated parameter to the given Clob object. * The driver converts this to an SQL CLOB value when it * sends it to the database. * * @param i the first parameter is 1, the second is 2, ... * @param x a Clob object that maps an SQL CLOB value * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setClob(int i, Clob x) throws SQLException { preparedStatement.setClob(i, x); } /** * Sets the designated parameter to the given Array object. * The driver converts this to an SQL ARRAY value when it * sends it to the database. * * @param i the first parameter is 1, the second is 2, ... * @param x an Array object that maps an SQL ARRAY value * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setArray(int i, Array x) throws SQLException { preparedStatement.setArray(i, x); } /** * Retrieves a ResultSetMetaData object that contains * information about the columns of the ResultSet object * that will be returned when this PreparedStatement object * is executed. *

* Because a PreparedStatement object is precompiled, it is * possible to know about the ResultSet object that it will * return without having to execute it. Consequently, it is possible * to invoke the method getMetaData on a * PreparedStatement object rather than waiting to execute * it and then invoking the ResultSet.getMetaData method * on the ResultSet object that is returned. *

* NOTE: Using this method may be expensive for some drivers due * to the lack of underlying DBMS support. * * @return the description of a ResultSet object's columns or * null if the driver cannot return a * ResultSetMetaData object * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public ResultSetMetaData getMetaData() throws SQLException { return preparedStatement.getMetaData(); } /** * Sets the designated parameter to the given java.sql.Date value, * using the given Calendar object. The driver uses * the Calendar object to construct an SQL DATE value, * which the driver then sends to the database. With * a Calendar object, the driver can calculate the date * taking into account a custom timezone. If no * Calendar object is specified, the driver uses the default * timezone, which is that of the virtual machine running the application. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @param cal the Calendar object the driver will use * to construct the date * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setDate(int parameterIndex, Date x, Calendar cal) throws SQLException { preparedStatement.setDate(parameterIndex, x, cal); } /** * Sets the designated parameter to the given java.sql.Time value, * using the given Calendar object. The driver uses * the Calendar object to construct an SQL TIME value, * which the driver then sends to the database. With * a Calendar object, the driver can calculate the time * taking into account a custom timezone. If no * Calendar object is specified, the driver uses the default * timezone, which is that of the virtual machine running the application. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @param cal the Calendar object the driver will use * to construct the time * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setTime(int parameterIndex, Time x, Calendar cal) throws SQLException { preparedStatement.setTime(parameterIndex, x, cal); } /** * Sets the designated parameter to the given java.sql.Timestamp value, * using the given Calendar object. The driver uses * the Calendar object to construct an SQL TIMESTAMP value, * which the driver then sends to the database. With a * Calendar object, the driver can calculate the timestamp * taking into account a custom timezone. If no * Calendar object is specified, the driver uses the default * timezone, which is that of the virtual machine running the application. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the parameter value * @param cal the Calendar object the driver will use * to construct the timestamp * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setTimestamp(int parameterIndex, Timestamp x, Calendar cal) throws SQLException { preparedStatement.setTimestamp(parameterIndex, x, cal); } /** * Sets the designated parameter to SQL NULL. * This version of the method setNull should * be used for user-defined types and REF type parameters. Examples * of user-defined types include: STRUCT, DISTINCT, JAVA_OBJECT, and * named array types. *

*

Note: To be portable, applications must give the * SQL type code and the fully-qualified SQL type name when specifying * a NULL user-defined or REF parameter. In the case of a user-defined type * the name is the type name of the parameter itself. For a REF * parameter, the name is the type name of the referenced type. If * a JDBC driver does not need the type code or type name information, * it may ignore it. *

* Although it is intended for user-defined and Ref parameters, * this method may be used to set a null parameter of any JDBC type. * If the parameter does not have a user-defined or REF type, the given * typeName is ignored. * * @param paramIndex the first parameter is 1, the second is 2, ... * @param sqlType a value from java.sql.Types * @param typeName the fully-qualified name of an SQL user-defined type; * ignored if the parameter is not a user-defined type or REF * @throws java.sql.SQLException if a database access error occurs * @since 1.2 */ public void setNull(int paramIndex, int sqlType, String typeName) throws SQLException { preparedStatement.setNull(paramIndex, sqlType, typeName); } /** * Sets the designated parameter to the given java.net.URL value. * The driver converts this to an SQL DATALINK value * when it sends it to the database. * * @param parameterIndex the first parameter is 1, the second is 2, ... * @param x the java.net.URL object to be set * @throws java.sql.SQLException if a database access error occurs * @since 1.4 */ public void setURL(int parameterIndex, URL x) throws SQLException { preparedStatement.setURL(parameterIndex, x); } /** * Retrieves the number, types and properties of this * PreparedStatement object's parameters. * * @return a ParameterMetaData object that contains information * about the number, types and properties of this * PreparedStatement object's parameters * @throws java.sql.SQLException if a database access error occurs * @see java.sql.ParameterMetaData * @since 1.4 */ public ParameterMetaData getParameterMetaData() throws SQLException { return preparedStatement.getParameterMetaData(); } public boolean isBusy() { return busy; } public void setBusy(boolean busy) { this.busy = busy; if (busy) { if (leakDetector != null) { leakDetector.startStatementLeakTracing(preparedStatement, this); } } else { if (leakDetector != null) { leakDetector.stopStatementLeakTracing(preparedStatement, this); if(cached && isMarkedForReclaim()) { //When caching is on and is marked for reclaim, the statement //would still remain in cache. Hence mark it as invalid and //let the client that uses the statement, detect and purge //it if found as invalid setValid(false); } } } } public boolean getCached() { return cached; } public void close() throws SQLException { if (!cached) { //Stop leak tracing if(leakDetector != null) { leakDetector.stopStatementLeakTracing(preparedStatement, this); } preparedStatement.close(); } else { //TODO-SC what if Exception is thrown in this block, should there be a way to indicate the // con. not to use this statement any more ? clearParameters(); if (defaultQueryTimeout != currentQueryTimeout) { preparedStatement.setQueryTimeout(defaultQueryTimeout); currentQueryTimeout = defaultQueryTimeout; } if (defaultMaxFieldSize != currentMaxFieldSize) { preparedStatement.setMaxFieldSize(defaultMaxFieldSize); currentMaxFieldSize = defaultMaxFieldSize; } if (defaultFetchSize != currentFetchSize) { preparedStatement.setFetchSize(defaultFetchSize); currentFetchSize = defaultFetchSize; } if (defaultMaxRows != currentMaxRows) { preparedStatement.setMaxRows(defaultMaxRows); currentMaxRows = defaultMaxRows; } if (defaultFetchDirection != currentFetchDirection) { preparedStatement.setFetchDirection(defaultFetchDirection); currentFetchDirection = defaultFetchDirection; } setBusy(false); } } public void closeOnCompletion() throws SQLException { if (DataSourceObjectBuilder.isJDBC41()) { if(!cached) { //If statement caching is not turned on, call the driver implementation directly if (leakDetector != null) { _logger.log(Level.INFO, "jdbc.invalid_operation.close_on_completion"); throw new UnsupportedOperationException("Not supported yet."); } actualCloseOnCompletion(); } else { super.closeOnCompletion(); } } } public boolean isCloseOnCompletion() throws SQLException { if (DataSourceObjectBuilder.isJDBC41()) { if(cached) { return getCloseOnCompletion(); } } return super.isCloseOnCompletion(); } public void setMaxFieldSize(int max) throws SQLException { preparedStatement.setMaxFieldSize(max); if (cached) currentMaxFieldSize = max; } public void setMaxRows(int max) throws SQLException { preparedStatement.setMaxRows(max); if (cached) currentMaxRows = max; } public void setQueryTimeout(int seconds) throws SQLException { preparedStatement.setQueryTimeout(seconds); if (cached) currentQueryTimeout = seconds; } public void setFetchDirection(int direction) throws SQLException { preparedStatement.setFetchDirection(direction); if (cached) currentFetchDirection = direction; } public void setFetchSize(int rows) throws SQLException { preparedStatement.setFetchSize(rows); if (cached) currentFetchSize = rows; } public void setCached(boolean cached){ this.cached = cached; } public boolean isValid() { return valid; } public void setValid(boolean valid) { this.valid = valid; } public void incrementResultSetReferenceCount() { //Update resultSetCount to be used in case of jdbc41 closeOnCompletion if (DataSourceObjectBuilder.isJDBC41() && getCached()) { incrementResultSetCount(); } } public void resultSetClosed() throws SQLException { if (DataSourceObjectBuilder.isJDBC41() && getCached()) { decrementResultSetCount(); if (getCloseOnCompletion() && getResultSetCount() == 0) { ConnectionHolder wrappedCon = (ConnectionHolder) getConnection(); wrappedCon.getManagedConnection().purgeStatementFromCache(this); } } } }





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