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 * and Distribution License("CDDL") (collectively, the "License").  You
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// Portions Copyright [2016] [Payara Foundation] 
//----------------------------------------------------------------------------
//
// Module:      RecoveryManager.java
//
// Description: Process transaction management.
//
// 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 java.util.*;
import java.io.*;
import java.util.concurrent.*;

import org.omg.CORBA.*;
import org.omg.CosTransactions.*;

import com.sun.jts.jtsxa.*;
import com.sun.jts.codegen.jtsxa.*;

import javax.transaction.xa.*;
import com.sun.jts.jta.TransactionManagerImpl;

import com.sun.jts.trace.*;
import java.util.logging.Logger;
import java.util.logging.Level;
import com.sun.logging.LogDomains;
import com.sun.jts.utils.LogFormatter;
import com.sun.enterprise.transaction.jts.api.TransactionRecoveryFence;
/**
 * This class manages information required for recovery, and also general
 * state regarding transactions in a process.
 *
 * @version 0.01
 *
 * @author Simon Holdsworth, IBM Corporation
 *
 * @see
*/

//----------------------------------------------------------------------------
// CHANGE HISTORY
//
// Version By     Change Description
//   0.01  SAJH   Initial implementation.
//-----------------------------------------------------------------------------

public class RecoveryManager {

    /**
     * list of XA Resources to be recovered.
     */
    private static Enumeration uniqueRMSet = null;

    /**
     * This attribute indicates whether initialisation has been started.
     */
    private static boolean initialised = false;

    /**
     * This attribute indicates the number of Coordinator objects which require
     * resync.  This is set to the number of in-doubt transactions recovered
     * from the log, then decreased as transactions are resolved.
     */
    private static int resyncCoords = 0;

    /**
     * This attribute records the thread which is used to perform resync during
     * restart
     */
    private static ResyncThread resyncThread = null;

    /**
     * This attribute is used to block new requests while there are
     * Coordinators which still require resync.
     */
    private static volatile EventSemaphore resyncInProgress = new EventSemaphore();

    /**
     * This attribute is used to block requests against RecoveryCoordinators or
     * CoordinatorResources before recovery has completed.
     */
    private static volatile EventSemaphore recoveryInProgress = new EventSemaphore();

    /**
     * This attribute is used by the Recovery Thread to know if the
     * xaResource list is ready in case manual recovery is attempted.
     */
    private static volatile EventSemaphore uniqueRMSetReady = new EventSemaphore();

    private static Hashtable coordsByGlobalTID = new Hashtable();
    private static Hashtable coordsByLocalTID = new Hashtable();

    /**
     * Mapping between transactionIds and threads. This is used to ensure
     * there is at most one thread doing work in a transaction.
     */
    private static Hashtable transactionIds = new Hashtable();

    /**
     * Mapping between incompleteTxIds and their commit decisions.
     */
    private static Hashtable inCompleteTxMap = new Hashtable();

    // This will start TransactionRecoveryFence service as soon as all resources are available.
    private static TransactionRecoveryFence txRecoveryFence = new TransactionRecoveryFenceSimple();

    
    private static int recoveryResynchTimeout = 120;
    
    /**
     * This is intented to be used as a lock object.
     */
    private static java.lang.Object lockObject = new java.lang.Object();
	/*
		Logger to log transaction messages
	*/  
	    static Logger _logger = LogDomains.getLogger(RecoveryManager.class, LogDomains.TRANSACTION_LOGGER);
    /**
     * Initialises the static state of the RecoveryManager class.
     *
     * @param
     *
     * @return
     *
     * @see
     */
    static void initialise() {

        // If already initialised, return immediately.
        if (initialised) {
            return;
        }
        initialised = true;

        // read the resynch timeout system property
        recoveryResynchTimeout = Integer.getInteger("fish.payara.jts.RecoveryResynchTimeout", recoveryResynchTimeout);
                
        if (recoveryResynchTimeout < 0){
            _logger.log(Level.SEVERE,recoveryResynchTimeout+ " is an invalid value for fish.payara.jts.RecoveryResynchTimeout. Using default value of 120 instead." );
            recoveryResynchTimeout = 120;
        }
        // Perform recovery/resync if necessary.

        if (Configuration.isRecoverable()) {
            resyncThread = new ResyncThread();
	    	if(_logger.isLoggable(Level.FINE))
	    	{
				_logger.logp(Level.FINE,"RecoveryManager","initialise()",
						"Before starting ResyncThread ");
	    	}
            //resyncThread.start();
        } else {

            // If the process is non-recoverable, but there is a valid server
            // name,then check for a log file and issue a warning message
            // if one exists.  Also ensure that restart required is set to no.

            if (!Configuration.isAppClientContainer())  {
                String serverName = Configuration.getServerName();
                if (serverName != null && Log.checkFileExists(serverName)) {
					_logger.log(Level.INFO,"jts.log_file_transient_server",serverName);

                }
            }

            // Modify the restart requirement in the repository, and
            // post the event semaphore as there will be no Coordinators
            // requiring resync.

            try {
                recoveryInProgress.post(); // BUGFIX (Ram Jeyaraman)
                resyncComplete(false, false);
            } catch (Throwable exc) {exc.printStackTrace();}
        }
    }

    /**
     * Sets up the local and global identifier to Coordinator mapping as given.
     * 

* If the global identifier has already got associated information, * the operation returns false. *

* The timeout value, if non-zero, is used to establish a time-out for the * transaction; if the local identifier to Coordinator association * exists after the time-out period, then the TimeoutManager will * attempt to roll the transaction back. * * @param globalTID The global identifier for the transaction. * @param localTID The local identifier for the transaction. * @param coord The Coordinator for the transaction. * @param timeout The timeout for the transaction. * @param log The log object for the transaction. * * @return Indicates success of the operation. * * @see */ static boolean addCoordinator(GlobalTID globalTID, Long localTID, CoordinatorImpl coord, int timeout) { boolean result = true; // Attempt to add the global and local indentifier to // Coordinator associations to the maps. coordsByGlobalTID.put(globalTID,coord); coordsByLocalTID.put(localTID,coord); // Set up the timeout for the transaction. When active, the // timeout thread will periodically examine the map and abort // any active transactions on it that have gone beyond their // allocated time. if (timeout != 0) { TimeoutManager.setTimeout(localTID, TimeoutManager.ACTIVE_TIMEOUT, timeout); } return result; } /** * Removes the Coordinator associations for the given identifiers. *

* If there was no association the operation returns false. *

* Any timeout that was established for the Coordinator is cancelled, * and any active thread associations for the transaction are removed * and the corresponding Control objects destroyed. * * @param globalTID The global identifier for the transaction. * @param localTID The local identifier for the transaction. * @param aborted The transaction aborted indicator. * * @return Indicates success of the operation. * * @see */ static boolean removeCoordinator(GlobalTID globalTID, Long localTID, boolean aborted) { boolean result = false; // Remove the global identifier to Coordinator mapping if possible. CoordinatorImpl coord = null; result = (coordsByGlobalTID.remove(globalTID) != null); // Remove the InternalTid to Coordinator mapping if possible. if (result) { coord = (CoordinatorImpl) coordsByLocalTID.remove(localTID); result = (coord != null); } // If that succeeded, forget the CoordinatorLog object, if the // transaction is not a subtransaction. The following may return // FALSE if there are no log records available // (i.e. non-recoverable OTS). if (coord != null) { try { if (coord.is_top_level_transaction()) { if (inCompleteTxMap.get(coord) == null) { if (Configuration.isDBLoggingEnabled()) LogDBHelper.getInstance().deleteRecord(localTID.longValue()); else CoordinatorLog.removeLog(localTID); } else { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","removeCoordinator()", "Transaction hasn't completed, let it stay in active logs"); } } } } catch(SystemException exc) { result = false; } } // Clear the timeout for the transaction, if any. // Perform the removal under the timer mutex. TimeoutManager.setTimeout(localTID, TimeoutManager.CANCEL_TIMEOUT, 0); // Modify any thread associations there may be for the transaction, to // indicate that the transaction has ended. // COMMENT(Ram J) 09/19/2001 This below line is commented out since in // the J2EE controlled environment, all threads are associated and // dissociated in an orderly fashion, as well as there is no possibility // of concurrent threads active in a given transaction. //CurrentTransaction.endAll(globalTID, aborted); // If the count of resyncing Coordinators is greater than zero, // this means we are still in resync. Decrease the count. if (resyncCoords > 0) { resyncCoords--; // If the number of resyncing Coordinators is now zero, // we may allow new work. if (resyncCoords == 0) { try { resyncComplete(true, true); } catch (Throwable exc) {} } } return result; } /** * Returns a reference to the Coordinator object that corresponds to the * global identifier passed as a parameter. * * @param globalTID The global identifier for the transaction. * * @return The Coordinator for the transaction. * * @see */ static CoordinatorImpl getCoordinator(GlobalTID globalTID) { CoordinatorImpl result = (CoordinatorImpl) coordsByGlobalTID.get(globalTID); return result; } /** * Read and update the transaction ID map atomically with the current * thread, if and only if there is no concurrent activity for the * specified transaction id. * * @param tid transaction id. * * @return true if there is no concurrent activity and the map has been * updated. */ static boolean readAndUpdateTxMap(GlobalTID tid) { synchronized (transactionIds) { Thread thread = (Thread) transactionIds.get(tid); if (thread != null) { // concurrent activity return false; } // register the thread for the transaction id transactionIds.put(tid, Thread.currentThread()); return true; } } /** * Get the value (thread) for the specified transaction id from the * transaction ID map. * * @return the value for the transaction id key from the * transaction ID map. */ static Thread getThreadFromTxMap(GlobalTID tid) { return (Thread) transactionIds.get(tid); } /** * Remove the specified transaction id from the transaction ID map. * * @return the value for the transaction id key from the * transaction ID map. */ static Thread removeFromTxMap(GlobalTID tid) { return (Thread) transactionIds.remove(tid); } /** * Requests that the RecoveryManager proceed with recovery. *

* The log is read and a list of TopCoordinators is reconstructed that * corresponds to those transactions that were in-doubt at the time of the * previous failure. *

* The method returns true if any transactions require resync. * * @param * * @return Indicates that there are Coordinators requiring resync. * * @see */ static boolean recover() { boolean result = false; if (skipRecoveryOnStartup()) { _logger.fine("========== no recovery =========="); // Quickly release all locks // Post the recovery in progress event so that requests // waiting for recovery to complete may proceed. recoveryInProgress.post(); // And finish resync try { resyncComplete(false, false); } catch (Throwable ex) { } return result; } // Check the log for transactions. If there are any outstanding // transactions, recover the Coordinator objects and set up the // OMGtid to Coordinator map. boolean keypointRequired = false; Enumeration logRecords = CoordinatorLog.getLogged(); while (logRecords.hasMoreElements()) { keypointRequired = true; try { new TopCoordinator(). reconstruct((CoordinatorLog) logRecords.nextElement()); } catch(Exception exc) { _logger.log(Level.SEVERE,"jts.recovery_in_doubt_exception",exc); _logger.log(Level.SEVERE,"jts.recovery_in_doubt",exc.toString()); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.recovery_in_doubt", new java.lang.Object[] {exc.toString()}); throw new org.omg.CORBA.INTERNAL(msg); } } // Perform recovery of XA resources. //recoverXA(); if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","recover()", "Before invoking proceedWithXARecovery()"); } proceedWithXARecovery(); // Post the recovery in progress event so that requests // waiting for recovery to complete may proceed. recoveryInProgress.post(); // If resync is not needed, then perform after-resync // tasks immediately. result = coordsByGlobalTID.size() > 0; if (!result) { try { resyncComplete(false,keypointRequired); } catch(Throwable exc) {} } return result; } /** * Performs resync processing. *

* The RecoveryManager gets recovery information from each TopCoordinator * (while holding the transaction lock) and proceeds with resync. *

* Once resync is complete, a keypoint is taken to indicate that the log * information is no longer required. * * @param * * @return * * @see */ static void resync() { // If there are any transactions, proceed with resync. The map of // coordinators by global identifier is created during the // TopCoordinator reconstruct method when the coordinators are added // via addCoordinator. We copy the contents to another map as // Coordinators will remove themselves from the map during resync. // Now that the Coordinators have been reconstructed, record // the number of transactions requiring resync, // and make an event trace point. We must clone the Hashtable // here so that the Enumeration does not get // changed when any subsequent transaction is created (this can happen // when the last Coordinator is removed). resyncCoords = coordsByGlobalTID.size(); Enumeration resyncList = ((Hashtable) coordsByGlobalTID.clone()).elements(); boolean isRoot[] = new boolean[1]; // Go through and resync each transaction. The transaction lock // for each transaction is obtained to avoid deadlocks during recovery. while (resyncList.hasMoreElements()) { TopCoordinator coord = (TopCoordinator)resyncList.nextElement(); try { // Before performing recovery, lock the coordinator. synchronized (coord) { Status state = coord.recover(isRoot); if (state == Status.StatusUnknown) { // If the coordinator can be locked, then perform // recovery on it. If the outcome is not currently // known, we do nothing with the transaction, // as we expect to eventually get an outcome // from the parent. In this case an in-doubt timeout // is established for the // transaction so that it will continue to retry. // For subordinates, the Coordinator will compl-ete the // transaction itself as it will have no // Synchronization objects. TimeoutManager.setTimeout( coord.getLocalTID(), TimeoutManager.IN_DOUBT_TIMEOUT, 60); } else if (state == Status.StatusCommitted) { // For committed or rolled back, proceed with // completion of the transaction, regardless of // whether it is the root or a subordinate. // If the transaction represents a root, it would // normally wait for the CoordinatorTerm object to // call before completing the transaction. As there is // no CoordinatorTerm in recovery, we must do it here. if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","resync()", "Before invoking commit on the reconstructed coordinator"+ "GTID is: "+ ((TopCoordinator)coord).superInfo.globalTID.toString()); } try { coord.commit(); } catch (Throwable exc) { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] {exc.toString(),"commit"}); } if (isRoot[0]) { try { coord.afterCompletion(state); } catch (Throwable exc) { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] {exc.toString(), "after_completion"}); } } } else { // By default, roll the transaction back. try { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","resync()", "Before invoking rollback on the"+ "reconstructed coordinator :"+ "GTID is : "+ ((TopCoordinator)coord).superInfo.globalTID.toString()); } coord.rollback(true); } catch (Throwable exc) { _logger.log(Level.WARNING,"jts.resync_failed", new java.lang.Object [] {exc.toString(),"rollback"}); } if (isRoot[0]) { try { coord.afterCompletion(Status.StatusRolledBack); } catch (Throwable exc) { _logger.log(Level.WARNING,"jts.resync_failed", new java.lang.Object[] { exc.toString(), "after_completion"}); } } } } } catch (Throwable exc) {} } // Note that resyncComplete will be called by the // last TopCoordinator to complete resync (in removeCoordinator) // so we do not need to do it here. } /** * Called to indicate that resync is complete. *

* Indicates that all in-doubt Coordinators recovered from the log have * obtained global outcomes are corresponding transactions are complete. *

* The parameters indicate whether there were Coordinators * requiring resync, and whether a keypoint is required. * * @param resynced Indicates whether any resync was done. * @param keypointRequired Indicates whether the log needs keypointing. * * @return * * @exception LogicErrorException An internal logic error occurred. * * @see */ static void resyncComplete(boolean resynced, boolean keypointRequired) throws LogicErrorException { // Inform JTSXA that resync is complete, and trace the fact // that resync has completed. // COMMENT(Ram J) not needed anymore //JTSXA.resyncComplete(); // Perform a keypoint of the log if required. if (keypointRequired) { CoordinatorLog.keypoint(); } // Post the resync in progress event semaphore. if (resyncInProgress != null) { resyncInProgress.post(); resyncInProgress = null; } } /** * Returns a reference to the Coordinator object that corresponds to the * local identifier passed as a parameter. * * @param localTID The local identifier for the transaction. * * @return The Coordinator object. * * @see */ static CoordinatorImpl getLocalCoordinator(Long localTID) { CoordinatorImpl result = (CoordinatorImpl) coordsByLocalTID.get(localTID); return result; } /** * Determines whether the local transaction identifier represents a valid * transaction. * * @param localTID The local transaction identifier to check. * * @return Indicates the local transaction identifier is valid. * * @see */ static boolean validLocalTID(Long localTID) { boolean result = coordsByLocalTID.containsKey(localTID); return result; } /** * Informs the RecoveryManager that the transaction service is being shut * down. * * For immediate shutdown, * * For quiesce, * * @param immediate Indicates whether to stop immediately. * * @return * * @see */ static void shutdown(boolean immediate) { /** if (immediate) { // If immediate, stop the resync thread if any. if (resyncThread != null) { resyncThread.stop(); } } else { **/ // Otherwise ensure that resync has completed. if (resyncInProgress != null) { try { resyncInProgress.waitEvent(); if (resyncThread != null) { resyncThread.join(); } } catch (InterruptedException exc) {} } /** } **/ // COMMENT(Ram J) not needed anymore. //JTSXA.shutdown(immediate); // If not immediate shutdown, keypoint and close the log. // Only do this if the process is recoverable! if (!immediate && Configuration.isRecoverable()) { CoordinatorLog.keypoint(); CoordinatorLog.finalizeAll(); } //$Continue with shutdown/quiesce. } /** * Reduce the set of XAResource objects into a unique set such that there * is at most one XAResource object per RM. */ private static Enumeration getUniqueRMSet(Enumeration xaResourceList){ Vector uniqueRMList = new Vector(); while (xaResourceList.hasMoreElements()) { XAResource xaRes = (XAResource) xaResourceList.nextElement(); int size = uniqueRMList.size(); boolean match = false; for (int i = 0; i < size; i++) { // compare and eliminate duplicates XAResource uniqueXaRes = (XAResource) uniqueRMList.elementAt(i); try { if (xaRes.isSameRM(uniqueXaRes)) { match = true; break; } } catch (XAException xe) {} } if (!match) { uniqueRMList.add(xaRes); } } return uniqueRMList.elements(); } /** * Recovers the in doubt transactions from the provided list of * XAResource objects. This method is never called by the recovery * thread, and its the application threads which wants to pass in * the XA resources that call this. * * @param xaResources enumerated list of XA Resources to be recovered * */ public static void recoverXAResources(Enumeration xaResources) { /* This method has been newly added - Ram Jeyaraman */ String manualRecovery = Configuration.getPropertyValue(Configuration.MANUAL_RECOVERY); // if ManualRecovery property is not set, do not attempt XA recovery. if (manualRecovery == null || !(manualRecovery.equalsIgnoreCase("true"/*#Frozen*/))) { return; } synchronized (lockObject) { if (uniqueRMSetReady.isPosted() == false) { RecoveryManager.uniqueRMSet = getUniqueRMSet(xaResources); uniqueRMSetReady.post(); waitForResync(); return; } else { RecoveryManager.waitForResync(); RecoveryManager.uniqueRMSet = getUniqueRMSet(xaResources); // the following call is meant to induce recovery. But // currently it will not work as intended, if it is called // during regular TP processing. Currently, this call deals // only with XA recovery. There needs to be some support // from the coordinator to be able to support recovery // during TP processing. proceedWithXARecovery(); } } } /** * This method returns InDoubt Xids for a given XAResource */ static Xid[] getInDoubtXids(XAResource xaResource) { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "getInDoubtXids()", "Before receiving inDoubtXids from xaresource = " + xaResource); } Xid[] inDoubtXids = null; ArrayList inDoubtXidList = null; int flags; String recoveryScanFlags = System.getProperty("RECOVERSCANFLAGS"); if (recoveryScanFlags != null && recoveryScanFlags.equals("TMNOFLAGS")) flags = XAResource.TMSTARTRSCAN; else flags = XAResource.TMSTARTRSCAN | XAResource.TMENDRSCAN; boolean continueLoop = true; while (continueLoop) { try { inDoubtXids = xaResource.recover(flags); if (inDoubtXids == null || inDoubtXids.length == 0) break; if (flags == XAResource.TMSTARTRSCAN || flags == XAResource.TMNOFLAGS) { flags = XAResource.TMNOFLAGS; if (inDoubtXidList == null) { inDoubtXidList = new ArrayList(); } for (int i = 0; i < inDoubtXids.length; i++) inDoubtXidList.add(inDoubtXids[i]); } else { break; } } catch (XAException e) { _logger.log(Level.WARNING,"jts.xaexception_in_recovery", e.errorCode); _logger.log(Level.WARNING, com.sun.jts.trace.TraceUtil.getXAExceptionInfo(e, _logger), e); break; } } if (inDoubtXidList != null) inDoubtXids = inDoubtXidList.toArray(new Xid[]{}); if(_logger.isLoggable(Level.FINE) && (inDoubtXids != null)) { String xidList = LogFormatter.convertXidArrayToString(inDoubtXids); _logger.logp(Level.FINE,"RecoveryManager", "getInDoubtXid()", "InDoubtXids returned from xaresource = "+ xaResource + "are: " +xidList); } return inDoubtXids; } /** * This method is used to recontruct and register the Resource objects * corresponding to in-doubt transactions in the RMs. It is assumed * that the XAResource list has already been provided to the * Recovery Manager. This method can be called by Recovery Thread as * well as any other thread driving recovery of XA Resources. */ private static void proceedWithXARecovery() { /* This method has been newly added - Ram Jeyaraman */ Enumeration xaResources = RecoveryManager.uniqueRMSet; /** if (xaResources == null) { // TODO - check that automatic recovery works in a clustered instance return; } **/ String manualRecovery = Configuration.getPropertyValue(Configuration.MANUAL_RECOVERY); // if ManualRecovery property is not set, do not attempt XA recovery. if (manualRecovery == null || !(manualRecovery.equalsIgnoreCase("true"/*#Frozen*/))) { return; } if (Thread.currentThread().getName().equals("JTS Resync Thread"/*#Frozen*/)) { if (uniqueRMSetReady != null) { try { uniqueRMSetReady.waitEvent(); txRecoveryFence.raiseFence(); xaResources = RecoveryManager.uniqueRMSet; } catch (InterruptedException exc) { _logger.log(Level.SEVERE,"jts.wait_for_resync_complete_interrupted"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.wait_for_resync_complete_interrupted"); throw new org.omg.CORBA.INTERNAL(msg); } } } // sanity check if (xaResources == null) { return; } Vector otsResources = new Vector(); // Map uniqueXids = new Hashtable(); Set uniqueXids = new HashSet(); while (xaResources.hasMoreElements()) { XAResource xaResource = (XAResource) xaResources.nextElement(); // Get the list of XIDs which represent in-doubt transactions // for the database. Xid[] inDoubtXids = getInDoubtXids(xaResource); // uniqueXids.clear(); if (inDoubtXids == null || inDoubtXids.length == 0) { continue; // No in-doubt xids for this resource. } for (int i = 0; i < inDoubtXids.length; i++) { // check to see if the xid belongs to this server. String branchQualifier = new String(inDoubtXids[i].getBranchQualifier()); String serverName = Configuration.getServerName(); if (branchQualifier.startsWith(serverName)) { // check if the xid is a duplicate. i.e., Xids // which have same globalId and branchId are // considered duplicates. Note that the // branchId format is (serverId, rmId). This is // to make sure that at most one OTSResource object // is registered with the coordinator per transaction // per RM. if (!uniqueXids.contains(inDoubtXids[i])) { // unique xid if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "proceedWithXARecovery", " This xid is UNIQUE " + inDoubtXids[i]); } uniqueXids.add(inDoubtXids[i]);// add to uniqueList // Create an OTSResource for the in-doubt // transaction and add it to the list. Each // OTSResource represents a RM per transaction. otsResources.addElement( new OTSResourceImpl(inDoubtXids[i], xaResource, null ).getCORBAObjReference()); } else { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "proceedWithXARecovery", " This xid is NOTUNIQUE " + inDoubtXids[i]); } } } else { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "proceedWithXARecovery", " This xid doesn't belong to me " + inDoubtXids[i]); } } } } // For each OTSResource, determine whether the transaction is known, // and if so, register it, otherwise roll it back. for (int i = 0; i < otsResources.size(); i++) { OTSResource otsResource = (OTSResource) otsResources.elementAt(i); GlobalTID globalTID = new GlobalTID(otsResource.getGlobalTID()); TopCoordinator coord = (TopCoordinator) coordsByGlobalTID.get(globalTID); if (coord == null) { // Roll the OTSResource back if the transaction is not // recognised. This happens when the RM has recorded its // prepare vote, but the JTS has not recorded its prepare vote. if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","proceedWithXARecovery()", "Could not recognize OTSResource: "+otsResource + " with tid: " + LogFormatter.convertToString(globalTID.realTID.tid)+ ";Hence rolling this resource back..."); } boolean infiniteRetry = true; int commitRetries = Configuration.getRetries(); if (commitRetries >= 0) infiniteRetry = false; int commitRetriesLeft = commitRetries; boolean exceptionisThrown = true; while (exceptionisThrown) { try { otsResource.rollback(); exceptionisThrown = false; } catch (Throwable exc) { if ((exc instanceof COMM_FAILURE) || (exc instanceof TRANSIENT)) { if (commitRetriesLeft > 0 || infiniteRetry) { // For TRANSIENT or COMM_FAILURE, wait // for a while, then retry the commit. if (!infiniteRetry) { commitRetriesLeft--; } try { Thread.sleep(Configuration.COMMIT_RETRY_WAIT); } catch( Throwable e ) {} } else { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] {exc.toString(),"OTSResource rollback"}); exceptionisThrown = false; } } else { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] {exc.toString(),"OTSResource rollback"}); exceptionisThrown = false; } } } } else { // NOTE: Currently unimplemented. The coordinator needs to // check if duplicate resources are being registered for the // same RM for the same xid. Also the coordinator should // not go away, until all its resources have been sent // completion notification. The keypointing should not // be done *as is* in the removeCoordinator() method. // waitForResync semaphore needs to be flagged when the // recovery thread goes away. // Register the OTSResource with the Coordinator. // It will be called for commit or rollback during resync. if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "proceedWithXARecovery()", "Recognized OTSResource: " + otsResource + " with tid: " + LogFormatter.convertToString(globalTID.realTID.tid) + ";Hence registering this resource with coordinator..."); } coord.directRegisterResource(otsResource); } } } static void dbXARecovery() { Enumeration xaResources = RecoveryManager.uniqueRMSet; if (skipRecoveryOnStartup()) { _logger.fine("========== no recovery =========="); try { resyncComplete(false, false); } catch (Throwable ex) { } return; } if (Thread.currentThread().getName().equals("JTS Resync Thread"/*#Frozen*/)) { if (uniqueRMSetReady != null) { try { _logger.fine("dbXArecovery()"); uniqueRMSetReady.waitEvent(); xaResources = RecoveryManager.uniqueRMSet; } catch (InterruptedException exc) { _logger.log(Level.SEVERE,"jts.wait_for_resync_complete_interrupted"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.wait_for_resync_complete_interrupted"); throw new org.omg.CORBA.INTERNAL(msg); } } } // sanity check if (xaResources == null) { try { resyncComplete(false, false); } catch (Throwable ex) { } return; } //dbXARecovery(Configuration.getServerName(), xaResources); // Configuration.getServerName() might be not quite right at auto-recovery String sname = LogDBHelper.getInstance().getServerNameForInstanceName(Configuration.getPropertyValue(Configuration.INSTANCE_NAME)); if (sname != null) { dbXARecovery(sname, xaResources); } try { resyncComplete(false, false); } catch (Throwable ex) { ex.printStackTrace(); } } static void dbXARecovery(String serverName, Enumeration xaResources) { // Get global TIDs Map gtidMap = LogDBHelper.getInstance().getGlobalTIDMap(serverName); Set uniqueXids = new HashSet(); if(_logger.isLoggable(Level.INFO)) { _logger.log(Level.INFO, "RecoveryManager.dbXARecovery recovering for serverName: " + serverName); } // if flag is set use commit_one_phase (old style), otherwise use commit boolean one_phase = getCommitOnePhaseDuringRecovery(); while (xaResources.hasMoreElements()) { XAResource xaResource = (XAResource) xaResources.nextElement(); if(_logger.isLoggable(Level.INFO)) { _logger.log(Level.INFO, "RecoveryManager.dbXARecovery processing xaResource: " + xaResource); } // Get the list of XIDs which represent in-doubt transactions // for the database. Xid[] inDoubtXids = getInDoubtXids(xaResource); // uniqueXids.clear(); if (inDoubtXids == null || inDoubtXids.length == 0) { continue; // No in-doubt xids for this resource. } for (int i = 0; i < inDoubtXids.length; i++) { // check to see if the xid belongs to this server. String branchQualifier = new String(inDoubtXids[i].getBranchQualifier()); //String serverName = Configuration.getServerName(); if(_logger.isLoggable(Level.INFO)) { _logger.log(Level.INFO, "RecoveryManager.dbXARecovery inDoubtXid: " + inDoubtXids[i] + " branchQualifier: " + branchQualifier); } if (branchQualifier.startsWith(serverName)) { // check if the xid is a duplicate. i.e., Xids // which have same globalId and branchId are // considered duplicates. Note that the // branchId format is (serverId, rmId). This is // to make sure that at most one OTSResource object // is registered with the coordinator per transaction // per RM. if (!uniqueXids.contains(inDoubtXids[i])) { // unique xid if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "dbXARecovery", " This xid is UNIQUE " + inDoubtXids[i]); } uniqueXids.add(inDoubtXids[i]); // add to uniqueList try { byte[] gtrid = inDoubtXids[i].getGlobalTransactionId(); GlobalTID gtid = GlobalTID.fromTIDBytes(gtrid); Long localTID = (Long)gtidMap.get(gtid); if(_logger.isLoggable(Level.INFO)) { _logger.log(Level.INFO, "RecoveryManager.dbXARecovery completing transaction for localTID: " + localTID); } if (localTID == null) { xaResource.rollback(inDoubtXids[i]); } else { xaResource.commit(inDoubtXids[i], one_phase); LogDBHelper.getInstance().deleteRecord(localTID.longValue(), serverName); } } catch (Exception ex) { ex.printStackTrace(); } } else { if(_logger.isLoggable(Level.INFO)) { _logger.logp(Level.INFO,"RecoveryManager", "dbXARecovery", " This xid is NOTUNIQUE " + inDoubtXids[i]); } } } else { if(_logger.isLoggable(Level.INFO)) { _logger.logp(Level.INFO,"RecoveryManager", "dbXARecovery", " This xid doesn't belong to me " + inDoubtXids[i]); } } } } /** try { resyncComplete(false, false); } catch (Throwable ex) { ex.printStackTrace(); } **/ } /** * Requests that the RecoveryManager proceed with recovery of XA resources * via JTSXA. *

* JTSXA returns a list of OTSResource objects which require * outcomes. These are registered with appropriate Coordinators or rolled * back as appropriate. * /** * Requests that the RecoveryManager proceed with recovery of XA resources * via JTSXA. *

* JTSXA returns a list of OTSResource objects which require * outcomes. These are registered with appropriate Coordinators or rolled * back as appropriate. * * @param * * @return * * @see */ /* * DISCARD(Ram J) - this method is not needed anymore. This has been * replaced by proceedWithXARecovery method. */ /* private static void recoverXA() { boolean result = false; // Get a list of OTSResource objects from JTSXA. Vector resources = new Vector(); JTSXA.recover(resources); Enumeration res = resources.elements(); // For each OTSResource, determine whether the transaction is known, // and if so, register it, otherwise roll it back. while (res.hasMoreElements()) { TxOTSResource xares = (TxOTSResource) res.nextElement(); GlobalTID globalTID = new GlobalTID(xares.getGlobalTID()); TopCoordinator coord = (TopCoordinator) coordsByGlobalTID.get(globalTID); // report(); if (coord == null) { // Roll the OTSResource back if the transaction is not // recognised. This happens when the RM has recorded its // prepare vote, but the JTS has not recorded its prepare vote. try { xares.rollback(); } catch (Throwable exc) { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] { exc.toString(), "xa_rollback"}); } } else { // Register the OTSResource with the Coordinator. // It will be called for commit or rollback during resync. coord.directRegisterResource(xares); } } } */ /** * Returns an array of Coordinator objects currently active. * * @param * * @return The array of Coordinators. * * @see */ static CoordinatorImpl[] getCoordinators() { int size = coordsByGlobalTID.size(); CoordinatorImpl[] result = new CoordinatorImpl[size]; Enumeration coords = coordsByGlobalTID.elements(); for(int pos = 0;pos*/ getCoordsByGlobalTID() { return coordsByGlobalTID; } /** * Gets the restart data for the process. * * @param * * @return The restart data. * * @see */ public static byte[] getRestart() { byte[] result = null; LogFile logFile = Configuration.getLogFile(); if (logFile != null) result = logFile.readRestart(); return result; } /** * Sets the restart data for the process. * * @param bytes The restart data. * * @return * * @see */ public static void setRestart(byte[] bytes) { LogFile logFile = Configuration.getLogFile(); if (logFile != null) { if (!logFile.writeRestart(bytes)) { _logger.log(Level.WARNING,"jts.restart_write_failed"); } } } /** * Waits for recovery to complete. * * @param * * @return * * @see */ public static void waitForRecovery() { if (recoveryInProgress != null) { try { recoveryInProgress.waitEvent(); } catch (InterruptedException exc) { _logger.log(Level.SEVERE,"jts.wait_for_resync_complete_interrupted"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.wait_for_resync_complete_interrupted"); throw new org.omg.CORBA.INTERNAL(msg); } } } /** * Waits for resync to complete. * * @param * * @return * * @see */ public static void waitForResync() { if (resyncInProgress != null) { try { // if (recoveryResynchTimeout == 0) { resyncInProgress.waitEvent(); } else { resyncInProgress.waitTimeoutEvent(recoveryResynchTimeout); } } catch (InterruptedException exc) { _logger.log(Level.SEVERE,"jts.wait_for_resync_complete_interrupted"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.wait_for_resync_complete_interrupted"); throw new org.omg.CORBA.INTERNAL(msg); } } } /** * Waits for resync to complete with timeout. * * @param cmtTimeout Container managed transaction timeout * * @return * * @see */ public static void waitForResync(int cmtTimeOut) { if (resyncInProgress != null) { try { resyncInProgress.waitTimeoutEvent(cmtTimeOut); } catch (InterruptedException exc) { _logger.log(Level.SEVERE,"jts.wait_for_resync_complete_interrupted"); String msg = LogFormatter.getLocalizedMessage(_logger, "jts.wait_for_resync_complete_interrupted"); throw new org.omg.CORBA.INTERNAL(msg); } } } static void addToIncompleTx(CoordinatorImpl coord, boolean commit) { inCompleteTxMap.put(coord, commit); } public static Boolean isIncompleteTxRecoveryRequired() { String logdir = Configuration.getPropertyValue(Configuration.LOG_DIRECTORY); if (inCompleteTxMap.isEmpty() || logdir == null || !(new File(logdir)).exists()) { return Boolean.FALSE; } else { return Boolean.TRUE; } } public static int sizeOfInCompleteTx() { return inCompleteTxMap.size(); } public static void recoverIncompleteTx(XAResource[] xaresArray) { if ((xaresArray == null) || (xaresArray.length == 0)) return; int size = xaresArray.length; Vector v = new Vector(); for (int i=0; i= 0) infiniteRetry = false; int commitRetriesLeft = commitRetries; boolean exceptionisThrown = true; while (exceptionisThrown) { try { if (commit.booleanValue()) { if (commit_one_phase) { otsResource.commit_one_phase(); } else { otsResource.commit(); } if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "recoverIncompleteTx", " committed " + otsResource); } } else { otsResource.rollback(); if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager", "recoverIncompleteTx", " rolled back " + otsResource); } } exceptionisThrown = false; } catch (Throwable exc) { if ((exc instanceof COMM_FAILURE) || (exc instanceof TRANSIENT)) { if (commitRetriesLeft > 0 || infiniteRetry) { // For TRANSIENT or COMM_FAILURE, wait // for a while, then retry the commit. if (!infiniteRetry) { commitRetriesLeft--; } try { Thread.sleep(Configuration.COMMIT_RETRY_WAIT); } catch( Throwable iex ) {} } else { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] {exc.toString(),"OTSResource " + ((commit.booleanValue())? "commit" : "rollback")}); exceptionisThrown = false; } } else { _logger.log(Level.WARNING,"jts.exception_during_resync", new java.lang.Object[] {exc.toString(),"OTSResource " + ((commit.booleanValue())? "commit" : "rollback")}); exceptionisThrown = false; } } } } } } } } static void createRecoveryFile(String serverName) { try { String logPath = LogControl.getLogPath(); if (new File(logPath).exists()) { File recoveryFile = LogControl.recoveryIdentifierFile(serverName,logPath); RandomAccessFile raf = new RandomAccessFile(recoveryFile,"rw"); raf.writeBytes(serverName); raf.setLength(serverName.length()); raf.close(); } } catch (Exception ex) { _logger.log(Level.WARNING,"jts.exception_in_recovery_file_handling",ex); } } /** * Register the implementation of Transaction recovery fence. * This service is started as soon as all the resources are available. */ public static void registerTransactionRecoveryFence(TransactionRecoveryFence fence) { txRecoveryFence = fence; } /** * return the TxRecoveryFence Object */ static TransactionRecoveryFence getTransactionRecoveryFence() { return txRecoveryFence; } /** * Start Transaction recovery fence. */ public static void startTransactionRecoveryFence() { if (txRecoveryFence != null) { // Perform any extra steps (like finish delegated recovery if necessary txRecoveryFence.start(); } else { _logger.log(Level.WARNING,"", new IllegalStateException()); } } /** * return true if commit_one_phase should be used during recovery */ private static boolean getCommitOnePhaseDuringRecovery() { String propValue = Configuration.getPropertyValue(Configuration.COMMIT_ONE_PHASE_DURING_RECOVERY); if (propValue != null && propValue.equalsIgnoreCase("true"/*#Frozen*/)) { return true; } return false; } /** * return true recovery on startup should be skipped */ private static boolean skipRecoveryOnStartup() { // if ManualRecovery property is not set, or the logdir does not exist // do not attempt XA recovery. String logdir = Configuration.getPropertyValue(Configuration.LOG_DIRECTORY); if(_logger.isLoggable(Level.FINE)) { _logger.fine("========== logdir ========== to recover ========= " + logdir); if (logdir != null) _logger.fine("========== logdir ========== exists ========= " + (new File(logdir)).exists()); } String manualRecovery = Configuration.getPropertyValue(Configuration.MANUAL_RECOVERY); return (manualRecovery == null || !(manualRecovery.equalsIgnoreCase("true"/*#Frozen*/)) || logdir == null || !(new File(logdir)).exists()); } /** * Start resync thread */ public static void startResyncThread() { if (resyncThread == null) { initialise(); } if(_logger.isLoggable(Level.FINE)) { _logger.log(Level.FINE,"RecoveryManager.startResyncThread Configuration.isRecoverable? " + Configuration.isRecoverable()); } if (Configuration.isRecoverable()) { resyncThread.start(); } } /** * Reports the contents of the RecoveryManager tables. * $Only required for debug. * * @param immediate Indicates whether to stop immediately. * * @return * * @see */ /* static void report() { // Report on coordsByGlobalTID. if (coordsByGlobalTID.size() > 0) { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","report()", "RecoveryManager.coordsByGlobalTID non-empty"); } Enumeration keys = coordsByGlobalTID.keys(); while (keys.hasMoreElements()) { GlobalTID globalTID = (GlobalTID) keys.nextElement(); CoordinatorImpl coordImpl = (CoordinatorImpl) coordsByGlobalTID.get(globalTID); if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","report()", "GlobalTid :"+globalTID+" -> "+coordImpl); } } } else { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","report()", "RecoveryManager.coordsByGlobalTID empty"); } } // Report on coordsByLocalTID. if (coordsByLocalTID.size() > 0) { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","report()", "RecoveryManager.coordsByLocalTID non-empty"); } Enumeration keys = coordsByLocalTID.keys(); while (keys.hasMoreElements()) { Long localTID = (Long)keys.nextElement(); CoordinatorImpl coordImpl = (CoordinatorImpl) coordsByLocalTID.get(localTID); if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","report()", "LocalTid:"+localTID+" -> " + coordImpl); } } } else { if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"RecoveryManager","report()", "RecoveryManager.coordsByLocalTID empty"); } } } */ /** * A no-op class */ static class TransactionRecoveryFenceSimple implements TransactionRecoveryFence { private final Semaphore semaphore = new Semaphore(1, true); public void start() { } /** * {@inheritDoc} */ public void raiseFence() { try { semaphore.acquire(); } catch(InterruptedException ie) { _logger.log(Level.FINE,"Error in acquireReadLock",ie); } } /** * {@inheritDoc} */ public void lowerFence() { semaphore.release(); } } } /** * This class represents a thread on which the RecoveryManager can perform * resync operations. * * @version 0.01 * * @author Simon Holdsworth, IBM Corporation * * @see */ //---------------------------------------------------------------------------- // CHANGE HISTORY // // Version By Change Description // 0.01 SAJH Initial implementation. //---------------------------------------------------------------------------- class ResyncThread extends Thread { /** * ResyncThread constructor. * * @param * * @return * * @see */ static Logger _logger = LogDomains.getLogger(ResyncThread.class, LogDomains.TRANSACTION_LOGGER); ResyncThread() { setName("JTS Resync Thread"/*#Frozen*/); setDaemon(true); } /** * Performs resync. * * @param * * @return * * @see */ public void run() { yield(); if(_logger.isLoggable(Level.FINE)) { _logger.logp(Level.FINE,"ResyncThread","run()","Before invoking RecoveryManager.recover()"); } try { if (Configuration.isDBLoggingEnabled()) { RecoveryManager.dbXARecovery(); } else { if (RecoveryManager.recover()) { RecoveryManager.resync(); } } } catch (Throwable ex) { _logger.log(Level.SEVERE,"jts.log_exception_at_recovery",ex); } finally { try { RecoveryManager.resyncComplete(false,false); } catch (Throwable tex) {tex.printStackTrace();} // forget any exeception in resyncComplete } if(RecoveryManager.getTransactionRecoveryFence() != null) RecoveryManager.getTransactionRecoveryFence().lowerFence(); } }





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