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//----------------------------------------------------------------------------
//
// Module:      CoordinatorLog.java
//
// Description: Coordinator state logging.
//
// Product:     com.sun.jts.CosTransactions
//
// Author:      Simon Holdsworth
//
// Date:        March, 1997
//
// Copyright (c):   1995-1997 IBM Corp.
//
//   The source code for this program is not published or otherwise divested
//   of its trade secrets, irrespective of what has been deposited with the
//   U.S. Copyright Office.
//
//   This software contains confidential and proprietary information of
//   IBM Corp.
//----------------------------------------------------------------------------

package com.sun.jts.CosTransactions;

// Import required classes.

import java.util.*;
import java.io.*;

import org.omg.CORBA.*;

import java.io.DataOutputStream;
import java.io.DataInputStream;
import java.util.logging.Logger;
import java.util.logging.Level;
import com.sun.logging.LogDomains;
import com.sun.jts.utils.LogFormatter;

/**The CoordinatorLog interface provides operations to record transaction-
 * specific information that needs to be persistently stored at a particular
 * point in time, and subsequently restored.
 * 

* The CoordinatorLog contains an attribute value which is the local transaction * identifier associated with the transaction operating on the log. The * CoordinatorLog maintains the LSN of the last log record written for the * transaction, and a flag indicating whether rewrite is required for a * keypoint. *

* As an instance of this class may be accessed from multiple threads within * a process, serialisation for thread-safety and locking during keypoint is * necessary. * * @version 0.01 * * @author Simon Holdsworth, IBM Corporation * * @see */ //---------------------------------------------------------------------------- // CHANGE HISTORY // // Version By Change Description // 0.01 SAJH Initial implementation. //------------------------------------------------------------------------------ class CoordinatorLog extends java.lang.Object implements LogUpcallTarget { private static final int LOG_DEF_KEY_TRIGGER = 100; private static final int LOG_THRESHOLD = 10000; private static final int STRING_TO_REF_RETRIES = 20; private static final String defaultstring = "DEFAULT_LOG"; /** // Since muliple logs have to coexist as part of delegated recovery // support, static data can not be maintained. Now this data is stored // per log location private static LogFile logFile = null; private static Log log = null; private static Hashtable activeLogs = new Hashtable(); private static Hashtable keypointLogs = new Hashtable(); private static int tranCount = 0; private static int keypointTrigger = 100; private static boolean keypointInProgress = false; private static java.lang.Object keypointLock = new java.lang.Object(); private static java.lang.Object keypointStateLock = new java.lang.Object(); **/ private static int keypointTrigger = 100; private static Hashtable logStateHoldertable = new Hashtable(); private static final java.lang.Object NULL_ENTRY = new java.lang.Object(); private Hashtable sectionMapping = null; private boolean rewriteRequired = false; private boolean writeDone = false; private String logPath = null; /* Logger to log transaction messages */ static Logger _logger = LogDomains.getLogger(CoordinatorLog.class, LogDomains.TRANSACTION_LOGGER); /**The local transaction identifier for the transaction this object is logging. */ Long localTID = null; CoordinatorLogStateHolder logStateHolder = null; private static CoordinatorLogStateHolder defaultLogStateHolder = getStateHolder(defaultstring); // Static variables to handle byte array formatting. private ByteArrayOutputStream byteOutput = new ByteArrayOutputStream(2000); private DataOutputStream dataOutput = new DataOutputStream(byteOutput); // All the methods which take "String logPath" as parameter are same as the // ones with out that parameter. These methods are added for delegated // recovery support /** * Get the state for the given log location. * If the state does not exists, creates the state and retuns, otherwise existing * state is returned. * * @param str log location. * * @return state for the given log location. * * @see */ static private CoordinatorLogStateHolder getStateHolder(String str) { synchronized (logStateHoldertable) { CoordinatorLogStateHolder logStateHolder = (CoordinatorLogStateHolder)logStateHoldertable.get(str); if (logStateHolder == null) { logStateHolder = new CoordinatorLogStateHolder(); logStateHolder.logFile = null; logStateHolder.log = null; logStateHolder.activeLogs = new Hashtable(); logStateHolder.keypointLogs = new Hashtable(); logStateHolder.tranCount = 0; logStateHolder.keypointInProgress = false; // logStateHolder.keypointLock = new java.lang.Object(); logStateHolder.keypointLock = new RWLock(); logStateHolder.keypointStateLock = new java.lang.Object(); logStateHoldertable.put(str,logStateHolder); } return logStateHolder; } } /**Default CoordinatorLog constructor. * * @param * * @return * * @see */ CoordinatorLog() { sectionMapping = new Hashtable(); logStateHolder = defaultLogStateHolder; // Do not inform the metaclass about the existence of this object yet, as it // does not have a transaction identifier. } CoordinatorLog(String logPath) { sectionMapping = new Hashtable(); logStateHolder = getStateHolder(logPath); this.logPath = logPath; // Do not inform the metaclass about the existence of this object yet, as it // does not have a transaction identifier. } /**Default CoordinatorLog destructor. * * @param * * @return * * @see */ synchronized public void doFinalize() { // Clear up the section mapping. if( sectionMapping != null ) { Enumeration sections = sectionMapping.elements(); // the traditional way of iterating through the enumeration // using sections.hasMoreElements was showing up as a // hot spot during performance tests. Arun 9/27/99 int sz = sectionMapping.size(); while (sz-- > 0) { CoordinatorLogSection section = (CoordinatorLogSection)sections.nextElement(); section.reUse(); } sectionMapping.clear(); sectionMapping = null; } } /** * reUse method is called explicitly to clean up * and return this instance to the pool * * Note: the implementation of the cache does not ensure * that when an object is re-used there are no * outstanding references to that object. However, the * risk involved is minimal since reUse() replaces the * existing call to finalize(). The existing call to * finalize also does not ensure that there are no * outstanding references to the object being finalized. * * * @param * * @return * * @see */ synchronized private void reUse() { // Arun 9/27/99 // Clear up the section mapping. if( sectionMapping != null ) { Enumeration sections = sectionMapping.elements(); int sz = sectionMapping.size(); while (sz-- > 0) { CoordinatorLogSection section = (CoordinatorLogSection)sections.nextElement(); section.reUse(); } sectionMapping.clear(); } rewriteRequired = false; writeDone = false; localTID = null; byteOutput.reset(); // cache the coordinator log in the coordinator log pool CoordinatorLogPool.putCoordinatorLog(this); } synchronized private void reUse(String logPath) { // Clear up the section mapping. if( sectionMapping != null ) { Enumeration sections = sectionMapping.elements(); int sz = sectionMapping.size(); while (sz-- > 0) { CoordinatorLogSection section = (CoordinatorLogSection)sections.nextElement(); section.reUse(); } sectionMapping.clear(); } rewriteRequired = false; writeDone = false; localTID = null; byteOutput.reset(); // cache the coordinator log in the coordinator log pool CoordinatorLogPool.putCoordinatorLog(this, logPath); } /**Creates and initialises a new CoordinatorLog object, with the given local * transaction identifier. *

* If the local transaction identifier is non-NULL, * the CoordinatorLog adds itself to the static list of instances. * * @param localTID The local transaction identifier. * * @return * * @see */ CoordinatorLog( Long localTID ) { // Set up the local transaction identifier; if it is not NULL, inform the // metaclass of the object's existence. this.localTID = localTID; if( localTID.longValue() != 0 ) addLog(localTID,this); } /** * Creates a subsection in the CoordinatorLog in which to store related * objects and data. *

* The object that is returned is used to identify the section on subsequent * calls. *

* If the section has already been created, the object for the existing * section is returned. * * @param sectionName The name of the section. * * @return An object representing the section. * * @see */ synchronized java.lang.Object createSection( String sectionName ) { CoordinatorLogSection result = null; // Check whether the given name already has a corresponding section. result = (CoordinatorLogSection) sectionMapping.get(sectionName); if (result == null) { // Create a new section. // If a section info structure cannot be allocated, return. // Note that the section name is added to the end of the section // info structure to reduce the number of SOMMalloc calls. // get a new section object from the cache Arun 9/27/99 result = SectionPool.getCoordinatorLogSection(sectionName); if( result == null ) { } // Copy in the name and set initial values of the other variables. else { // Add the new section information to the map. sectionMapping.put(sectionName,result); } } return result; } /**Adds the given object to the sequence of those in the given section. *

* The objects are stored in the order that they are added to the sequence. * No checking is done for duplicates. * * @param sectionObj The object representing the section. * @param obj The object to be added. * * @return Indicates success of the operation. * * @see */ synchronized boolean addObject( java.lang.Object sectionObj, org.omg.CORBA.Object obj ) { boolean result = true; // Determine if section is valid if( sectionObj != null ) { CoordinatorLogSection section = (CoordinatorLogSection)sectionObj; // Add header length to unwritten data length if section has currently has no // unwritten information. section.unwrittenEmpty = false; // Arun 9/27/99 if( section.unwrittenObjects == null ) section.unwrittenObjects = new Vector(10,10); // Convert the object reference to string value String objRefStr = null; try { objRefStr = Configuration.getORB().object_to_string(obj); // Add object reference to section and update counts section.unwrittenObjects.addElement(objRefStr); //$Write logrecord if threshold is exceeded //$ //$ if( unwrittenLength >= LOG_THRESHOLD ) //$ try //$ { formatLogRecords(false); } //$ catch( IOException exc ) //$ { //$ if( trc != null ) trc.error(ERR_WRITE).data(exc).write(); //$ result = false; //$ } } catch( Throwable exc ) { result = false; } } else { result = false; } return result; } /**Adds the given opaque data structure to the sequence of those in the * given section. *

* The data structures are stored in the order that they are added to the * sequence. No checking is done for duplicates. * * @param sectionObj The object representing the section. * @param data The data to be added. * * @return Indicates success of the operation. * * @see */ synchronized boolean addData( java.lang.Object sectionObj, byte[] data ) { boolean result = true; byte[] dataCopy; // Determine if section is valid if( sectionObj != null ) { CoordinatorLogSection section = (CoordinatorLogSection)sectionObj; // Add header length to unwritten data length if section has currently has no // unwritten information. section.unwrittenEmpty = false; // Arun 9/27/99 if( section.unwrittenData == null ) section.unwrittenData = new Vector(4,4); // Make a copy of the data to add to the unwritten data queue. dataCopy = new byte[data.length]; System.arraycopy(data,0,dataCopy,0,data.length); // Add data item (sequence of octets) to section and update counts section.unwrittenData.addElement(dataCopy); //$Write logrecord if threshold is exceeded //$ if( unwrittenLength >= LOG_THRESHOLD ) //$ try //$ { formatLogRecords(false); } //$ catch( IOException exc ) //$ { //$ if( trc != null ) trc.error(ERR_WRITE).data(exc).write(); //$ result = false; //$ } } else { result = false; } return result; } /**Write the contents of the CoordinatorLog to persistent storage. *

* If the force parameter is set, this requires that all information defined * to the CoordinatorLog that has not already been written be recorded before * the operation returns. *

* If rewrite is required, all information whether previously written or not * is recorded. *

* The log record should include the LSN of the previous record * written for the same transaction, if any, otherwise it is NULL. Further * information may be added to the CoordinatorLog after it has been forced, * and will be separately written in a subsequent log record, whose LSN will * point to the current one. *

* This operation discharges the CoordinatorLog's requirement to rewrite. The * keypoint lock must be obtained from the metaclass before checking whether * a rewrite is required, and released after the write is complete. * * @param force Indicates whether the log data should be forced before this * method returns. * * @return Indicates success of the operation. * * @see */ boolean write( boolean force ) { // Format the log records with a forced write. boolean result = true; try { result = formatLogRecords(force); } catch( IOException exc ) { result = false; } return result; } /**Informs the CoordinatorLog object that it must rewrite its entire state * the next time it writes a log record. *

* If the CoordinatorLog has state that has previously been written, it records * the requirement to rewrite, otherwise it does not record the requirement. * * @param * * @return Indicates success of the operation. * * @see */ private synchronized boolean requireRewrite() { boolean result = true; // Record the fact that a rewrite is required if a write has been done. if( writeDone ) rewriteRequired = true; return result; } /**Rewrites the contents of the CoordinatorLog to persistent storage. *

* This requires that all information defined to the CoordinatorLog that has * already been written be re-written (unforced) to the log. *

* The CoordinatorLog also writes any unwritten state at this point. *

* The log record will contain a NULL LSN to indicate that no previous records * for this transaction should be used for recovery. If no state has previously * been written, the CoordinatorLog does nothing at this point and waits for * a subsequent force operation. *

* This operation discharges the CoordinatorLog's requirement to rewrite. * * @param * * @return Indicates success of the operation. * * @see */ private boolean rewrite() { boolean result = true; // If a rewrite is required, format a log record with all the CoordinatorLog // data, with a non-forced write. if( rewriteRequired ) try { result = formatLogRecords(false); } catch( IOException exc ) { result = false; } return result; } /** * Requests that the object reconstructs its state from the given stream. *

* There may be more than one if the CoordinatorLog elects to write to the * log before it is asked to force the transaction state. *

* This operation is invoked when there are log records that need to * be recovered. The CoordinatorLog should reconstruct the sequences of * objects and data from each of the sections so that they can be queried by * the callers that set them up. * * @param data The data to be used to create the CoordinatorLog object. * * @return Indicates success of the operation. * * @see */ private boolean reconstruct( DataInputStream dataInput ) throws IOException { boolean result = true; // Read in the number of sections. int numSections = dataInput.readUnsignedShort(); // Reconstruct each of the sections in the log record while( --numSections >= 0 ) { // Get the section name, number of objects and number of data items from the // log record passed in. int length = dataInput.readUnsignedShort(); // If the section name length is zero, then it contains no data, so skip it. if( length > 0 ) { int numObjects = dataInput.readUnsignedShort(); int numData = dataInput.readUnsignedShort(); // Make a copy of the section name. byte[] stringData = new byte[length]; dataInput.read(stringData); String sectionName = new String(stringData); // Create a section in the CoordinatorLog CoordinatorLogSection section = (CoordinatorLogSection) createSection(sectionName); // Add each object reference from the log record to the section. // BUGFIX(Ram J) added (writtenObject == null) check, so that // the previously collected objects are not discarded. if (numObjects > 0 && section.writtenObjects == null) { section.writtenObjects = new Vector(numObjects, 10); } for( int i = 0; i < numObjects; i++ ) { // Get the size of the object reference and allocate a buffer to make a copy // of it. length = dataInput.readUnsignedShort(); stringData = new byte[length]; dataInput.read(stringData); String objRefStr = new String(stringData); // Add the object reference to the list of written objects. section.writtenObjects.addElement(objRefStr); } // Add each data item from the log record to the section. // BUGFIX(Ram J) added (writtenData == null) check, so that // the previously collected data are not discarded. if (numData > 0 && section.writtenData == null) { section.writtenData = new Vector(numData, 4); } for( int i = 0; i < numData; i++ ) { // Get the size of the data item and allocate a buffer to make a copy of it. length = dataInput.readUnsignedShort(); byte[] dataItem = new byte[length]; // Copy the data item into the storage allocated, and add that to the list // of written data items. dataInput.read(dataItem); section.writtenData.addElement(dataItem); } } } return result; } /**Returns a sequence containing all of the objects in the given section. * * @param sectionObj The object representing the section. * * @return The objects. * * @see */ java.lang.Object[] getObjects( java.lang.Object sectionObj ) { java.lang.Object[] result = null; // Check that the section identifier is valid. // Browse through the Queue of stringified object references, converting each // to an actual object reference and adding it to the sequence returned from // this method. if( sectionObj != null ) { CoordinatorLogSection section = (CoordinatorLogSection)sectionObj; int unwrittenSize = 0; if( section.unwrittenObjects != null ) unwrittenSize = section.unwrittenObjects.size(); int writtenSize = 0; if( section.writtenObjects != null ) writtenSize = section.writtenObjects.size(); result = new java.lang.Object[unwrittenSize + writtenSize]; int currObject = 0; // Obtain the reference of the ORB. ORB orb = Configuration.getORB(); // Go through the written objects. for( int i = 0; i < writtenSize; i++ ) { org.omg.CORBA.Object obj = null; String refStr = (String)section.writtenObjects.elementAt(i); // Try ten times to convert the reference to a string. int retries = STRING_TO_REF_RETRIES; boolean discard = false; while( obj == null && retries-- > 0 && !discard ) { try { obj = orb.string_to_object(refStr); } catch( MARSHAL exc ) { // The MARSHAL exception indicates that the ImplHelper for the object has not been // started, so try again after two seconds. try { Thread.sleep(2000); } catch( InterruptedException ex2 ) { _logger.log(Level.WARNING, "jts.wait_for_resync_complete_interrupted"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.wait_for_resync_complete_interrupted"); throw new org.omg.CORBA.INTERNAL(msg); } } catch( Throwable exc ) { // Any other exception indicates that the reference is invalid, so just discard it. discard = true; } } // Add the valid object to the list. if( !discard ){ if( obj != null ){ result[currObject++] = obj; } else { _logger.log(Level.SEVERE, "jts.unable_to_convert_object_reference_to_string_in_recovery"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.unable_to_convert_object_reference_to_string_in_recovery"); throw new org.omg.CORBA.INTERNAL(msg); } } } // Now get the unwritten objects. We do not need to do all the above error // checking as these objects have not been recovered from the log. for( int i = 0; i < unwrittenSize; i++ ) { try { // Add the valid object to the list. org.omg.CORBA.Object obj = orb.string_to_object((String)section.unwrittenObjects.elementAt(i)); result[currObject++] = obj; } catch( Throwable exc ) { // If the object resulting from the string is invalid, then don't add it to // the list. } } } return result; } /**Returns a sequence containing all of the opaque data in the given section. * * @param sectionObj The object representing the section. * * @return The data. * * @see */ byte[][] getData( java.lang.Object sectionObj ) { byte[][] result = null; // Check that the section identifier is valid. // Browse through the Queues of data items, adding each to the sequence // returned from this method. if( sectionObj != null ) { CoordinatorLogSection section = (CoordinatorLogSection)sectionObj; int unwrittenSize = 0; if( section.unwrittenData != null ) unwrittenSize = section.unwrittenData.size(); int writtenSize = 0; if( section.writtenData != null ) writtenSize = section.writtenData.size(); result = new byte[unwrittenSize+writtenSize][]; if( unwrittenSize > 0 ) section.unwrittenData.copyInto(result); for( int i = 0; i < writtenSize; i++ ) result[unwrittenSize++] = (byte[])section.writtenData.elementAt(i); } return result; } /**Sets the local identifier for the CoordinatorLog object. *

* If the local identifier was previously 0, the CoordinatorLog object is * added to the static list. * * @param localTID The new local identifier. * * @return * * @see */ synchronized void setLocalTID( Long localTID ) { // Check whether the local identifier is currently NULL. boolean addToMetaclass = (localTID.longValue() != 0 && (this.localTID == null || this.localTID.longValue() == 0)); // Set the local identifier, and add the object to the metaclass if required. this.localTID = localTID; if( addToMetaclass ) addLog(localTID,this); } synchronized void setLocalTID( Long localTID, String logPath ) { // Check whether the local identifier is currently NULL. boolean addToMetaclass = (localTID.longValue() != 0 && (this.localTID == null || this.localTID.longValue() == 0)); // Set the local identifier, and add the object to the metaclass if required. this.localTID = localTID; if( addToMetaclass ) addLog(localTID,this, logPath); } /**Formats the information in a single section of the Coordinatorlog into a * stream. *

* This internal method does not need to be synchronized. * If the rewrite flag is not set, only information that has not already been * written is formatted, otherwise all information is formatted. * * @param section The section. * @param rewrite Indicates if the record is being rewritten. * @param dataOutput The stream to which to data is output. * * @return * * @exception IOException The format failed. * * @see */ private void formatSection( CoordinatorLogSection section, boolean rewrite, DataOutputStream dataOutput ) throws IOException { // No formatting is done if the section is empty, and if rewrite is required, // the written section is also empty. // Note that we still need to write something out to satisfy the number of // sections originally written, so we write out a name length of zero. if( section.unwrittenEmpty && (!rewrite || section.writtenEmpty) ) { dataOutput.writeShort(0); return; } // Place length of section name into buffer. dataOutput.writeShort(section.sectionName.length()); // Place count of number of object references into buffer, including written // object references if rewrite is required. int unwrittenObjectsSize = 0; int writtenObjectsSize = 0; if( section.unwrittenObjects != null ) unwrittenObjectsSize = section.unwrittenObjects.size(); if( rewrite && section.writtenObjects != null ) writtenObjectsSize = section.writtenObjects.size(); dataOutput.writeShort(unwrittenObjectsSize + writtenObjectsSize); // Place count of number of data items into buffer, including written data // items if rewrite is required. int unwrittenDataSize = 0; int writtenDataSize = 0; if( section.unwrittenData != null ) unwrittenDataSize = section.unwrittenData.size(); if( rewrite && section.writtenData != null ) writtenDataSize = section.writtenData.size(); dataOutput.writeShort(unwrittenDataSize + writtenDataSize); // Copy the section name into the buffer. dataOutput.writeBytes(section.sectionName); // If rewrite is required, first write the already-written object references for( int i = 0; i < writtenObjectsSize; i++ ) { String objRefStr = (String)section.writtenObjects.elementAt(i); dataOutput.writeShort(objRefStr.length()); dataOutput.writeBytes(objRefStr); } // Next place length of each stringified object reference and the stringified // object reference into the buffer. Move each from unwritten to written queue for( int i = 0; i < unwrittenObjectsSize; i++ ) { String objRefStr = (String)section.unwrittenObjects.elementAt(i); dataOutput.writeShort(objRefStr.length()); dataOutput.writeBytes(objRefStr); if( section.writtenObjects == null ) section.writtenObjects = new Vector(unwrittenObjectsSize,10); section.writtenObjects.addElement(objRefStr); } if( unwrittenObjectsSize > 0 ) section.unwrittenObjects.removeAllElements(); // Now we process the data items. // If rewrite is required, first write the already-written data items. for( int i = 0; i < writtenDataSize; i++ ) { byte[] dataItem = (byte[])section.writtenData.elementAt(i); dataOutput.writeShort(dataItem.length); dataOutput.write(dataItem); } // Next place length of each stringified object reference and the stringified // object reference into the buffer. Move each from unwritten to written queue for( int i = 0; i < unwrittenDataSize; i++ ) { byte[] dataItem = (byte[])section.unwrittenData.elementAt(i); dataOutput.writeShort(dataItem.length); dataOutput.write(dataItem); if( section.writtenData == null ) section.writtenData = new Vector(unwrittenDataSize,4); section.writtenData.addElement(dataItem); } if( unwrittenDataSize > 0 ) section.unwrittenData.removeAllElements(); // Set unwritten_empty to TRUE and written_empty to FALSE since everything // // has moved from the unwritten to the written queues. // section.unwrittenEmpty = true; section.writtenEmpty = false; } /**Formats the information in all sections of the CoordinatorLog. *

* The formatted information is written to the log. *

* This internal method does not need to be synchronized. * If the rewrite flag is not set, only information that has not already been * written is formatted, otherwise all information is formatted. * * @param forced Forced/unforced write indicator. * * @return Indicates success of the operation. * * @exception IOException The format failed. * * @see */ private boolean formatLogRecords( boolean forced ) throws IOException { // If there is no LogFile for this transaction, and one cannot be obtained // from the metaclass, then no formatting can be done. if (logPath == null) openLog(); else openLog(logPath); if( logStateHolder.logFile == null ) { return false; } // In order to check whether rewrite is required, we must first obtain the // keypoint lock to ensure that the metaclass is not in the process of // informing us that a rewrite is required. //$We must not wait for the keypoint lock while holding our own lock so //$release it now. boolean result = false; try { logStateHolder.keypointLock.acquireReadLock(); // Once we have the keypoint lock, it is OK to obtain our own. synchronized( this ) { // Place the tid in the buffer. byteOutput.reset(); dataOutput.writeLong(localTID.longValue()); // Write out the number of sections. dataOutput.writeShort(sectionMapping.size()); // Format log section within map and add the information to buffer. Browse // through the CoordinatorLog filling in the buffer for each entry. Enumeration sections = sectionMapping.elements(); int sz = sectionMapping.size(); // Arun 9/27/99 while (sz-- > 0) { // Arun 9/27/99 formatSection((CoordinatorLogSection)sections.nextElement(), rewriteRequired,dataOutput); } // Write the buffer to the LogFile. result = logStateHolder.logFile.write( forced ? LogFile.FORCED : LogFile.UNFORCED, byteOutput.toByteArray(), rewriteRequired ? LogFile.REWRITE : LogFile.NORMAL, null ); rewriteRequired = false; writeDone = true; } } finally { logStateHolder.keypointLock.releaseReadLock(); } return result; } /**Provides static initialisation of the CoordinatorLog class. * * @param * * @return * * @see */ static { // Get the value of the keypoint trigger from the environment. String keypointCountEnv = Configuration.getPropertyValue(Configuration.KEYPOINT_COUNT); keypointTrigger = LOG_DEF_KEY_TRIGGER; if( keypointCountEnv != null ) try { keypointTrigger = Integer.parseInt(keypointCountEnv); } catch( Throwable e ) {} } /**Opens the log file for all CoordinatorLogs in this process. *

* If the log has already been opened, the operation uses the opened LogFile. * * @param * * @return Indicates success of the operation. * * @see */ private static boolean openLog() { boolean result = false; String logName; CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; // If the log has been opened, there is nothing to do. if( logStateHolder.log == null ) { logStateHolder.log = new Log(); if( !logStateHolder.log.initialise() ) { logStateHolder.log = null; _logger.log(Level.SEVERE,"jts.cannot_initialise_log"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.cannot_initialise_log"); throw new org.omg.CORBA.INTERNAL(msg); } } // Open the Log and set the logfile object reference. If there is no // ImplementationDef object available, then we cannot determine the log file // name, so the log cannot be opened. // Note that this does not preclude the log file being opened at some later // time. String serverName = null; if( logStateHolder.log != null && logStateHolder.logFile == null && (serverName = Configuration.getServerName()) != null ) { // get a coordinator log object from cache instead // of instantiating a new one Arun 9/27/99 logStateHolder.logFile = logStateHolder.log.open(serverName, CoordinatorLogPool.getCoordinatorLog()); if( logStateHolder.logFile == null ) { _logger.log(Level.SEVERE,"jts.cannot_open_log_file",serverName); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.cannot_open_log_file"); throw new org.omg.CORBA.INTERNAL(msg); } else Configuration.setLogFile(logStateHolder.logFile); } result = (logStateHolder.logFile != null); return result; } /**Opens the log file for all CoordinatorLogs in this process. *

* If the log has already been opened, the operation uses the opened LogFile. * * @param * * @return Indicates success of the operation. * * @see */ private static boolean openLog(String logPath) { boolean result = false; String logName; CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); // If the log has been opened, there is nothing to do. if( logStateHolder.log == null ) { logStateHolder.log = new Log(logPath); if( !logStateHolder.log.initialise() ) { logStateHolder.log = null; _logger.log(Level.SEVERE,"jts.cannot_initialise_log"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.cannot_initialise_log"); throw new org.omg.CORBA.INTERNAL(msg); } } // Open the Log and set the logfile object reference. If there is no // ImplementationDef object available, then we cannot determine the log file // name, so the log cannot be opened. // Note that this does not preclude the log file being opened at some later // time. String serverName = null; // Always reopen logFile for a delegated recovery: do not check for logStateHolder.logFile == null if( logStateHolder.log != null && (serverName = Configuration.getServerName(logPath)) != null ) { // get a coordinator log object from cache instead // of instantiating a new one Arun 9/27/99 logStateHolder.logFile = logStateHolder.log.open(serverName, CoordinatorLogPool.getCoordinatorLog(logPath)); if( logStateHolder.logFile == null ) { _logger.log(Level.SEVERE,"jts.cannot_open_log_file",serverName); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.cannot_open_log_file"); throw new org.omg.CORBA.INTERNAL(msg); } else Configuration.setLogFile(logPath,logStateHolder.logFile); } result = (logStateHolder.logFile != null); return result; } /**Process the log to build a sequence of CoordinatorLog objects which * represent all logged transactions. * * @param * * @return The CoordinatorLog objects, or null if there are none. * * @see */ synchronized static Enumeration getLogged() { Vector logRecords = null; Enumeration coordLogs = null; // Initialise the Log. If the log cannot be opened, return an empty // sequence, with whatever exception the open returned. if( openLog() ) { CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; // Get the log records returned from the log and browse through them. Take // Take the sequence of log records returned from the LogFile and convert // them into the sequence of CoordinatorLog objects that are returned from // this method. logRecords = logStateHolder.logFile.getLogRecords(); for( int i = 0; i < logRecords.size(); i++ ) { // Get tid value from the log record. Get the CoordinatorLog reference if // it exists in map, else create a new CoordinatorLog object; it will // added to the map when we set the transaction id. byte[] buffer = (byte[])logRecords.elementAt(i); ByteArrayInputStream byteInput = new ByteArrayInputStream(buffer); DataInputStream dataInput = new DataInputStream(byteInput); try { Long localTID = dataInput.readLong(); CoordinatorLog coordLog = (CoordinatorLog)logStateHolder.activeLogs.get(localTID); if( coordLog == null ) { // get a coordinator log object from cache instead // of instantiating a new one Arun 9/27/99 coordLog = CoordinatorLogPool.getCoordinatorLog(); coordLog.setLocalTID(localTID); } // Reconstruct the CoordinatorLog information from the log record. coordLog.reconstruct(dataInput); } catch( IOException exc ) { } } // Return a copy of the list of active CoordinatorLog objects. coordLogs = logStateHolder.activeLogs.elements(); } // If the log could not be opened, return an empty Enumeration. else coordLogs = new Hashtable().elements(); return coordLogs; } /**Process the log to build a sequence of CoordinatorLog objects which * represent all logged transactions. * * @param * * @return The CoordinatorLog objects, or null if there are none. * * @see */ synchronized static Enumeration getLogged(String logPath) { Vector logRecords = null; Enumeration coordLogs = null; // Initialise the Log. If the log cannot be opened, return an empty // sequence, with whatever exception the open returned. if( openLog(logPath) ) { CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); // Get the log records returned from the log and browse through them. Take // Take the sequence of log records returned from the LogFile and convert // them into the sequence of CoordinatorLog objects that are returned from // this method. logRecords = logStateHolder.logFile.getLogRecords(); for( int i = 0; i < logRecords.size(); i++ ) { // Get tid value from the log record. Get the CoordinatorLog reference if // it exists in map, else create a new CoordinatorLog object; it will // added to the map when we set the transaction id. byte[] buffer = (byte[])logRecords.elementAt(i); ByteArrayInputStream byteInput = new ByteArrayInputStream(buffer); DataInputStream dataInput = new DataInputStream(byteInput); try { Long localTID = dataInput.readLong(); CoordinatorLog coordLog = (CoordinatorLog)logStateHolder.activeLogs.get(localTID); if( coordLog == null ) { // get a coordinator log object from cache instead // of instantiating a new one Arun 9/27/99 coordLog = CoordinatorLogPool.getCoordinatorLog(logPath); coordLog.setLocalTID(localTID, logPath); } // Reconstruct the CoordinatorLog information from the log record. coordLog.reconstruct(dataInput); } catch( IOException exc ) { } } // Return a copy of the list of active CoordinatorLog objects. coordLogs = logStateHolder.activeLogs.elements(); } // If the log could not be opened, return an empty Enumeration. else coordLogs = new Hashtable().elements(); return coordLogs; } /**Remembers the mapping between the local transaction identifier and the * CoordinatorLog object. * * @param localTID The local transaction identifier. * @param clog The CoordinatorLog object. * * @return Indicates success of the operation. * * @see */ private static boolean addLog(Long localTID, CoordinatorLog clog ) { CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; boolean result = true; logStateHolder.activeLogs.put(localTID,clog); return result; } private static boolean addLog(Long localTID, CoordinatorLog clog, String logPath ) { CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); boolean result = true; logStateHolder.activeLogs.put(localTID,clog); return result; } /**Removes the CoordinatorLog object from the map, and destroys it. * * @param localTID The local transaction identifier. * * @return Indicates success of the operation. * * @see */ synchronized static boolean removeLog( Long localTID ) { boolean result = true; CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; // Remove the given CoordinatorLog and local identifier from the map. // If the CoordinatorLog could be removed, we need to check whether a // keypoint is in progress, and if so, prevent the CoordinatorLog from being // called during the keypoint. CoordinatorLog clog = (CoordinatorLog)logStateHolder.activeLogs.remove(localTID); if( clog != null ) { // Obtaining the keypoint state lock prevents us from doing this while the // keypoint method is using the map. synchronized( logStateHolder.keypointStateLock ) { // If a keypoint is in progress, look up the entry for the transaction in the // map and replace the value with a NULL entry. if( logStateHolder.keypointInProgress && logStateHolder.keypointLogs != null ) logStateHolder.keypointLogs.put(localTID,NULL_ENTRY); } // If the transaction is read-only, then do not increment the transaction count. if( clog.writeDone ) logStateHolder.tranCount++; // return the CoordinatorLog object to the pool to be reused. // Arun 9/27/99 clog.reUse(); // Check whether a keypoint is required. This is based solely on the number // of (non-readonly) transactions since the last keypoint. if( logStateHolder.tranCount >= keypointTrigger ) { logStateHolder.tranCount = 0; keypoint(); } } return result; } synchronized static boolean removeLog( Long localTID , String logPath) { boolean result = true; CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); // Remove the given CoordinatorLog and local identifier from the map. // If the CoordinatorLog could be removed, we need to check whether a // keypoint is in progress, and if so, prevent the CoordinatorLog from being // called during the keypoint. CoordinatorLog clog = (CoordinatorLog)logStateHolder.activeLogs.remove(localTID); if( clog != null ) { // Obtaining the keypoint state lock prevents us from doing this while the // keypoint method is using the map. synchronized( logStateHolder.keypointStateLock ) { // If a keypoint is in progress, look up the entry for the transaction in the // map and replace the value with a NULL entry. if( logStateHolder.keypointInProgress && logStateHolder.keypointLogs != null ) logStateHolder.keypointLogs.put(localTID,NULL_ENTRY); } // If the transaction is read-only, then do not increment the transaction count. if( clog.writeDone ) logStateHolder.tranCount++; // return the CoordinatorLog object to the pool to be reused. // Arun 9/27/99 clog.reUse(logPath); // Check whether a keypoint is required. This is based solely on the number // of (non-readonly) transactions since the last keypoint. if( logStateHolder.tranCount >= keypointTrigger ) { logStateHolder.tranCount = 0; keypoint(logPath); } } return result; } /**Performs a keypoint operation to allow old information in the log to be * discarded. *

* This operation is not synchronized as we do not want the latter part of the * operation to block other logging operations. The start of the keypoint is * in a separate method which is synchronized. * * @param * * @return * * @see */ static void keypoint() { CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; byte[] keypointEndRecord = { (byte) 'K', (byte) 'E', (byte) 'Y', (byte) 'E', (byte) 'N', (byte) 'D'}; LogLSN previousLSN = new LogLSN(); LogLSN keypointStartLSN = new LogLSN(); boolean keypointRequired = false; // Obtain the global keypoint lock to prevent any activity until the keypoint // start has been recorded. // Once the keypoint start has been completed, we can release the // keypoint lock. This will allow waiting CoordinatorLog writes to complete. try { logStateHolder.keypointLock.acquireWriteLock(); keypointRequired = startKeypoint(keypointStartLSN); } finally { logStateHolder.keypointLock.releaseWriteLock(); } // If no keypoint start record was written, then just return. if( keypointStartLSN.isNULL() ) { return; } // Once all of the CoordinatorLog objects have been unlocked, we must make // sure each of them has been rewritten before the keypoint end record is // written. Note that it is possible that one or more of the CoordinatorLog // objects in this list has already been deleted. We must be careful // to make sure that we do not invoke a method on a deleted object. if( keypointRequired ) { Enumeration keypointLocalTIDs = logStateHolder.keypointLogs.keys(); while( keypointLocalTIDs.hasMoreElements() ) // Obtain the keypoint state lock before obtaining the value from the map, as the // remove operation might be changing the value to NULL. Note that the // remove operation only changes the value of an entry in this map, it does // not change the number of entries in the map, so we do not need to hold the // mutex for the browse. synchronized( logStateHolder.keypointStateLock ) { CoordinatorLog currentLog = (CoordinatorLog)logStateHolder.keypointLogs.get(keypointLocalTIDs.nextElement()); // Get the value out of the map, and if not NULL entry, tell it to rewrite itself. if( currentLog != NULL_ENTRY ) currentLog.rewrite(); } } // Now we know all CoordinatorLog objects have either independently rewritten // themselves, or we have done it explicitly. A keypoint end record is // written to indicate that the keypoint is complete. logStateHolder.logFile.write(LogFile.UNFORCED, keypointEndRecord, LogFile.KEYPOINT_END, previousLSN); // All that is left to do is to inform the LogFile that the records before // the keypoint start record are no longer required. // Checkpoint the log. This allows the log to discard previous entries that // are no longer required. logStateHolder.logFile.checkpoint(keypointStartLSN); // Clear the keypoint in progress flag, empty the map of CoordinatorLog // objects being keypointed, release muteces and return. logStateHolder.keypointInProgress = false; logStateHolder.keypointLogs.clear(); } static void keypoint(String logPath) { CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); byte[] keypointEndRecord = { (byte) 'K', (byte) 'E', (byte) 'Y', (byte) 'E', (byte) 'N', (byte) 'D'}; LogLSN previousLSN = new LogLSN(); LogLSN keypointStartLSN = new LogLSN(); boolean keypointRequired = false; // Obtain the global keypoint lock to prevent any activity until the keypoint // start has been recorded. // Once the keypoint start has been completed, we can release the // keypoint lock. This will allow waiting CoordinatorLog writes to complete. try { logStateHolder.keypointLock.acquireWriteLock(); keypointRequired = startKeypoint(keypointStartLSN, logPath); } finally { logStateHolder.keypointLock.releaseWriteLock(); } // If no keypoint start record was written, then just return. if( keypointStartLSN.isNULL() ) { return; } // Once all of the CoordinatorLog objects have been unlocked, we must make // sure each of them has been rewritten before the keypoint end record is // written. Note that it is possible that one or more of the CoordinatorLog // objects in this list has already been deleted. We must be careful // to make sure that we do not invoke a method on a deleted object. if( keypointRequired ) { Enumeration keypointLocalTIDs = logStateHolder.keypointLogs.keys(); while( keypointLocalTIDs.hasMoreElements() ) // Obtain the keypoint state lock before obtaining the value from the map, as the // remove operation might be changing the value to NULL. Note that the // remove operation only changes the value of an entry in this map, it does // not change the number of entries in the map, so we do not need to hold the // mutex for the browse. synchronized( logStateHolder.keypointStateLock ) { CoordinatorLog currentLog = (CoordinatorLog)logStateHolder.keypointLogs.get(keypointLocalTIDs.nextElement()); // Get the value out of the map, and if not NULL entry, tell it to rewrite itself. if( currentLog != NULL_ENTRY ) currentLog.rewrite(); } } // Now we know all CoordinatorLog objects have either independently rewritten // themselves, or we have done it explicitly. A keypoint end record is // written to indicate that the keypoint is complete. logStateHolder.logFile.write(LogFile.UNFORCED, keypointEndRecord, LogFile.KEYPOINT_END, previousLSN); // All that is left to do is to inform the LogFile that the records before // the keypoint start record are no longer required. // Checkpoint the log. This allows the log to discard previous entries that // are no longer required. logStateHolder.logFile.checkpoint(keypointStartLSN); // Clear the keypoint in progress flag, empty the map of CoordinatorLog // objects being keypointed, release muteces and return. logStateHolder.keypointInProgress = false; logStateHolder.keypointLogs.clear(); } /**Handles a short-on-storage situation in the log by taking a keypoint. /**Handles a short-on-storage situation in the log by taking a keypoint. * * @param reason The reason for the upcall. * * @return * * @see */ public void upcall( int reason ){ // Just perform a keypoint. if (logPath == null) CoordinatorLog.keypoint(); else CoordinatorLog.keypoint(logPath); } /**Destroys the state of the CoordinatorLog class. * * @param * * @return * * @see */ synchronized static void finalizeAll(){ CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; boolean deleteFile = false; // Obtain the keypoint state lock for this operation. synchronized( logStateHolder.keypointStateLock ) { // Close the LogFile. if( logStateHolder.activeLogs != null ) { // If there are no active log records sete delete_file to TRUE so that // LogFile_close will cause the logfile to be deleted if( logStateHolder.activeLogs.size() == 0 ) deleteFile = true; logStateHolder.activeLogs.clear(); logStateHolder.activeLogs = null; } if( logStateHolder.logFile != null ) logStateHolder.logFile.close(deleteFile); logStateHolder.logFile = null; // Discard the CoordinatorLog mappings. if( logStateHolder.keypointLogs != null ) logStateHolder.keypointLogs.clear(); logStateHolder.keypointLogs = null; } // Discard the locks. logStateHolder.keypointStateLock = null; logStateHolder.keypointLock = null; } synchronized static void finalizeAll(String logPath){ CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); boolean deleteFile = false; // Obtain the keypoint state lock for this operation. synchronized( logStateHolder.keypointStateLock ) { // Close the LogFile. if( logStateHolder.activeLogs != null ) { // If there are no active log records sete delete_file to TRUE so that // LogFile_close will cause the logfile to be deleted if( logStateHolder.activeLogs.size() == 0 ) deleteFile = true; logStateHolder.activeLogs.clear(); logStateHolder.activeLogs = null; } if( logStateHolder.logFile != null ) logStateHolder.logFile.close(deleteFile); logStateHolder.logFile = null; // Discard the CoordinatorLog mappings. if( logStateHolder.keypointLogs != null ) logStateHolder.keypointLogs.clear(); logStateHolder.keypointLogs = null; } // Discard the locks. logStateHolder.keypointStateLock = null; logStateHolder.keypointLock = null; } /**Starts a keypoint. * * @param keypointStartLSN The LSN to hold the keypoint start LSN. * * @return Indicates whether keypoint is required. * * @see */ synchronized static boolean startKeypoint( LogLSN keypointStartLSN ) { CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; boolean keypointRequired = false; // If a keypoint is in progress, return and do nothing. if( logStateHolder.keypointInProgress ) { return false; } logStateHolder.keypointInProgress = true; // Initialise the Log. If this fails, then return whatever exception the // open raised. if( !openLog() ) { logStateHolder.keypointInProgress = false; return false; } // If there are no known CoordinatorLog objects, then all that the keypoint // operation does is checkpoint the log at the head. if( logStateHolder.activeLogs.size() == 0 ) keypointRequired = false; // Else go round all currently known CoordinatorLog objects and build a list // of them. New CoordinatorLog objects that are created during this time // will be suspended when they try to do an CoordinatorLog.addLog operation as // this thread has the lock. else { // Go through all current CoordinatorLog objects, telling them that they // must rewrite their state if necessary. // Each CoordinatorLog that exists at this time is copied to a separate list. Enumeration clogs = logStateHolder.activeLogs.elements(); while( clogs.hasMoreElements() ) { CoordinatorLog currentLog = (CoordinatorLog)clogs.nextElement(); Long localTID = currentLog.localTID; currentLog.requireRewrite(); logStateHolder.keypointLogs.put(localTID,currentLog); } keypointRequired = logStateHolder.keypointLogs.size() > 0; } // Write a keypoint start record now that we know no logging activity is // taking place. byte[] keypointStartRecord = {(byte) 'K', (byte) 'E', (byte) 'Y', (byte) 'S', (byte) 'T', (byte) 'A', (byte) 'R', (byte) 'T'}; logStateHolder.logFile.write(LogFile.UNFORCED, keypointStartRecord, LogFile.KEYPOINT_START, keypointStartLSN); return keypointRequired; } synchronized static boolean startKeypoint( LogLSN keypointStartLSN, String logPath ) { CoordinatorLogStateHolder logStateHolder = getStateHolder(logPath); boolean keypointRequired = false; // If a keypoint is in progress, return and do nothing. if( logStateHolder.keypointInProgress ) { return false; } logStateHolder.keypointInProgress = true; // Initialise the Log. If this fails, then return whatever exception the // open raised. if( !openLog(logPath) ) { logStateHolder.keypointInProgress = false; return false; } // If there are no known CoordinatorLog objects, then all that the keypoint // operation does is checkpoint the log at the head. if( logStateHolder.activeLogs.size() == 0 ) keypointRequired = false; // Else go round all currently known CoordinatorLog objects and build a list // of them. New CoordinatorLog objects that are created during this time // will be suspended when they try to do an CoordinatorLog.addLog operation as // this thread has the lock. else { // Go through all current CoordinatorLog objects, telling them that they // must rewrite their state if necessary. // Each CoordinatorLog that exists at this time is copied to a separate list. Enumeration clogs = logStateHolder.activeLogs.elements(); while( clogs.hasMoreElements() ) { CoordinatorLog currentLog = (CoordinatorLog)clogs.nextElement(); Long localTID = currentLog.localTID; currentLog.requireRewrite(); logStateHolder.keypointLogs.put(localTID,currentLog); } keypointRequired = logStateHolder.keypointLogs.size() > 0; } // Write a keypoint start record now that we know no logging activity is // taking place. byte[] keypointStartRecord = {(byte) 'K', (byte) 'E', (byte) 'Y', (byte) 'S', (byte) 'T', (byte) 'A', (byte) 'R', (byte) 'T'}; logStateHolder.logFile.write(LogFile.UNFORCED, keypointStartRecord, LogFile.KEYPOINT_START, keypointStartLSN); return keypointRequired; } /**Dumps the state of the class. * * @param * * @return * * @see */ static void dumpClass() { // Dump the contained objects. CoordinatorLogStateHolder logStateHolder = defaultLogStateHolder; logStateHolder.log.dump(); logStateHolder.logFile.dump(); } // START IASRI 4662745 public static void setKeypointTrigger(int keypoint) { keypointTrigger = keypoint; } // END IASRI 4662745 } /**The CoordinatorLogSection class stores information relevant to a section. * * @version 0.1 * * @author Simon Holdsworth, IBM Corporation * * @see */ // CHANGE HISTORY // // Version By Change Description // 0.1 SAJH Initial implementation. //------------------------------------------------------------------------------ class CoordinatorLogSection extends java.lang.Object { String sectionName = null; boolean unwrittenEmpty = true; boolean writtenEmpty = true; Vector unwrittenObjects = null; Vector unwrittenData = null; Vector writtenObjects = null; Vector writtenData = null; /**Creates a CoordinatorLogSection with the given name. * * @param sectionName The name of the section. * * @return * * @see */ CoordinatorLogSection( String sectionName ) { this.sectionName = sectionName; } /**Destroys the contents of a CoordinatorLogSection. * * @param * * @return * * @see */ public void doFinalize() { if( unwrittenObjects != null ) unwrittenObjects.removeAllElements(); if( unwrittenData != null ) unwrittenData.removeAllElements(); if( writtenObjects != null ) writtenObjects.removeAllElements(); if( writtenData != null ) writtenData.removeAllElements(); sectionName = null; unwrittenObjects = null; unwrittenData = null; writtenObjects = null; writtenData = null; } /**Cleans up the CoordinatorLogSection and * returns it to the pool for re-use * * Note: the implementation of the cache does not ensure * that when an object is re-used there are no * outstanding references to that object. However, the * risk involved is minimal since reUse() replaces the * existing call to finalize(). The existing call to * finalize also does not ensure that there are no * outstanding references to the object being finalized. * * @param * * @return * * @see */ synchronized void reUse() { // Arun 9/27/99 if( unwrittenObjects != null ) unwrittenObjects.removeAllElements(); if( unwrittenData != null ) unwrittenData.removeAllElements(); if( writtenObjects != null ) writtenObjects.removeAllElements(); if( writtenData != null ) writtenData.removeAllElements(); sectionName = null; unwrittenEmpty = true; writtenEmpty = true; SectionPool.putCoordinatorLogSection(this); } } /** * The SectionPool is used as a cache for CoordinatorLogSection objects. * This pool allows the re-use of these objects which are very expensive * to instantiate. * * The pool was added to improve performance of trnasaction logging * * @version 0.01 * * @author Arun Krishnan * * @see */ class SectionPool { private Stack pool; private static final int MAXSTACKSIZE = 15; static SectionPool SPool = new SectionPool(); public SectionPool() { pool = new Stack(); } /** * Fetch a CoordinatorLogSection object from the cache. This method * should be called instead of "new CoordinatorLogSection()". If the * cache is empty this method will instantiate a new * CoordinatorLogSection object. * * @param String name the section name * * @return CoordinatorLogSection * */ public static synchronized CoordinatorLogSection getCoordinatorLogSection(String name) { CoordinatorLogSection cls; if (SPool.pool.empty()) { return new CoordinatorLogSection(name); } else { cls = (CoordinatorLogSection) SPool.pool.pop(); cls.sectionName = name; return cls; } } /** * Return a CoordinatorLogSection object to cache. Cache size is * limited to MAXSTACKSIZE by discarding objects when the cache * is already at max size. * * @param CoordinatorLogSection object to be returned to cache * */ public static void putCoordinatorLogSection(CoordinatorLogSection cls) { if (SPool.pool.size() <= MAXSTACKSIZE) { SPool.pool.push(cls); } } } class CoordinatorLogStateHolder { LogFile logFile = null; Log log = null; Hashtable activeLogs = null; Hashtable keypointLogs = null; int tranCount = 0; boolean keypointInProgress = false; // java.lang.Object keypointLock = new java.lang.Object(); RWLock keypointLock = null; java.lang.Object keypointStateLock = null; }





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