// plasmaCrawlBalancer.java
// -----------------------
// part of YaCy
// (C) by Michael Peter Christen; mc@yacy.net
// first published on http://www.anomic.de
// Frankfurt, Germany, 2005
// created: 24.09.2005
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
package de.anomic.crawler ;
import java.io.File ;
import java.io.IOException ;
import java.util.ArrayList ;
import java.util.Collections ;
import java.util.HashMap ;
import java.util.HashSet ;
import java.util.Iterator ;
import java.util.LinkedList ;
import java.util.Map ;
import java.util.TreeMap ;
import de.anomic.kelondro.kelondroBase64Order ;
import de.anomic.kelondro.kelondroEcoTable ;
import de.anomic.kelondro.kelondroIndex ;
import de.anomic.kelondro.kelondroRow ;
import de.anomic.kelondro.kelondroStack ;
import de.anomic.plasma.plasmaSwitchboard ;
import de.anomic.server.logging.serverLog ;
import de.anomic.yacy.yacySeedDB ;
public class Balancer {
private static final String stackSuffix = "9.stack" ;
private static final String indexSuffix = "9.db" ;
private static final int EcoFSBufferSize = 200 ;
// a shared domainAccess map for all balancers
private static final Map < String , domaccess > domainAccess = Collections . synchronizedMap ( new HashMap < String , domaccess > ( ) ) ;
// definition of payload for fileStack
private static final kelondroRow stackrow = new kelondroRow ( "byte[] urlhash-" + yacySeedDB . commonHashLength , kelondroBase64Order . enhancedCoder , 0 ) ;
// class variables
private final ArrayList < String > urlRAMStack ; // a list that is flushed first
private kelondroStack urlFileStack ; // a file with url hashes
kelondroIndex urlFileIndex ;
private final HashMap < String , LinkedList < String > > domainStacks ; // a map from domain name part to Lists with url hashs
private final File cacheStacksPath ;
private final String stackname ;
private boolean top ; // to alternate between top and bottom of the file stack
private final boolean fullram ;
public static class domaccess {
long time ;
int count ;
public domaccess ( ) {
this . time = System . currentTimeMillis ( ) ;
this . count = 0 ;
}
public void update ( ) {
this . time = System . currentTimeMillis ( ) ;
this . count + + ;
}
public long time ( ) {
return this . time ;
}
public int count ( ) {
return this . count ;
}
}
public Balancer ( final File cachePath , final String stackname , final boolean fullram ) {
this . cacheStacksPath = cachePath ;
this . stackname = stackname ;
final File stackFile = new File ( cachePath , stackname + stackSuffix ) ;
this . urlFileStack = kelondroStack . open ( stackFile , stackrow ) ;
this . domainStacks = new HashMap < String , LinkedList < String > > ( ) ;
this . urlRAMStack = new ArrayList < String > ( ) ;
this . top = true ;
this . fullram = fullram ;
// create a stack for newly entered entries
if ( ! ( cachePath . exists ( ) ) ) cachePath . mkdir ( ) ; // make the path
openFileIndex ( ) ;
if ( urlFileStack . size ( ) ! = urlFileIndex . size ( ) | | ( urlFileIndex . size ( ) < 10000 & & urlFileIndex . size ( ) > 0 ) ) {
// fix the file stack
serverLog . logInfo ( "Balancer" , "re-creating the " + stackname + " balancer stack, size = " + urlFileIndex . size ( ) + ( ( urlFileStack . size ( ) = = urlFileIndex . size ( ) ) ? "" : " (the old stack size was wrong)" ) ) ;
urlFileStack = kelondroStack . reset ( urlFileStack ) ;
try {
final Iterator < byte [ ] > i = urlFileIndex . keys ( true , null ) ;
byte [ ] hash ;
while ( i . hasNext ( ) ) {
hash = i . next ( ) ;
pushHash ( new String ( hash ) ) ;
}
} catch ( final IOException e ) {
e . printStackTrace ( ) ;
}
}
}
public synchronized void close ( ) {
while ( domainStacksNotEmpty ( ) ) flushOnceDomStacks ( 0 , true ) ; // flush to ram, because the ram flush is optimized
size ( ) ;
try { flushAllRamStack ( ) ; } catch ( final IOException e ) { }
if ( urlFileIndex ! = null ) {
urlFileIndex . close ( ) ;
urlFileIndex = null ;
}
if ( urlFileStack ! = null ) {
urlFileStack . close ( ) ;
urlFileStack = null ;
}
}
public void finalize ( ) {
if ( urlFileStack ! = null ) {
serverLog . logWarning ( "Balancer" , "crawl stack " + stackname + " closed by finalizer" ) ;
close ( ) ;
}
}
public synchronized void clear ( ) {
urlFileStack = kelondroStack . reset ( urlFileStack ) ;
domainStacks . clear ( ) ;
urlRAMStack . clear ( ) ;
resetFileIndex ( ) ;
}
private void openFileIndex ( ) {
cacheStacksPath . mkdirs ( ) ;
urlFileIndex = new kelondroEcoTable ( new File ( cacheStacksPath , stackname + indexSuffix ) , CrawlEntry . rowdef , ( fullram ) ? kelondroEcoTable . tailCacheUsageAuto : kelondroEcoTable . tailCacheDenyUsage , EcoFSBufferSize , 0 ) ;
}
private void resetFileIndex ( ) {
if ( urlFileIndex ! = null ) {
urlFileIndex . close ( ) ;
urlFileIndex = null ;
new File ( cacheStacksPath , stackname + indexSuffix ) . delete ( ) ;
}
openFileIndex ( ) ;
}
public synchronized CrawlEntry get ( final String urlhash ) throws IOException {
assert urlhash ! = null ;
if ( urlFileIndex = = null ) return null ; // case occurs during shutdown
final kelondroRow . Entry entry = urlFileIndex . get ( urlhash . getBytes ( ) ) ;
if ( entry = = null ) return null ;
return new CrawlEntry ( entry ) ;
}
public synchronized int removeAllByProfileHandle ( final String profileHandle , final long timeout ) throws IOException {
// removes all entries with a specific profile hash.
// this may last some time
// returns number of deletions
// first find a list of url hashes that shall be deleted
final Iterator < kelondroRow . Entry > i = urlFileIndex . rows ( true , null ) ;
final HashSet < String > urlHashes = new HashSet < String > ( ) ;
kelondroRow . Entry rowEntry ;
CrawlEntry crawlEntry ;
final long terminate = ( timeout > 0 ) ? System . currentTimeMillis ( ) + timeout : Long . MAX_VALUE ;
while ( i . hasNext ( ) & & ( System . currentTimeMillis ( ) < terminate ) ) {
rowEntry = i . next ( ) ;
crawlEntry = new CrawlEntry ( rowEntry ) ;
if ( crawlEntry . profileHandle ( ) . equals ( profileHandle ) ) {
urlHashes . add ( crawlEntry . url ( ) . hash ( ) ) ;
}
}
// then delete all these urls from the queues and the file index
return this . remove ( urlHashes ) ;
}
/ * *
* this method is only here , because so many import / export methods need it
and it was implemented in the previous architecture
however , usage is not recommended
* @param urlHashes , a list of hashes that shall be removed
* @return number of entries that had been removed
* @throws IOException
* /
public synchronized int remove ( final HashSet < String > urlHashes ) throws IOException {
final int s = urlFileIndex . size ( ) ;
int removedCounter = 0 ;
for ( final String urlhash : urlHashes ) {
final kelondroRow . Entry entry = urlFileIndex . remove ( urlhash . getBytes ( ) ) ;
if ( entry ! = null ) removedCounter + + ;
}
if ( removedCounter = = 0 ) return 0 ;
assert urlFileIndex . size ( ) + removedCounter = = s : "urlFileIndex.size() = " + urlFileIndex . size ( ) + ", s = " + s ;
// now delete these hashes also from the queues
// iterate through the RAM stack
Iterator < String > i = urlRAMStack . iterator ( ) ;
String h ;
while ( i . hasNext ( ) ) {
h = i . next ( ) ;
if ( urlHashes . contains ( h ) ) i . remove ( ) ;
}
// iterate through the file stack
// in general this is a bad idea. But this can only be avoided by avoidance of this method
final Iterator < kelondroRow . Entry > j = urlFileStack . stackIterator ( true ) ;
while ( j . hasNext ( ) ) {
h = new String ( j . next ( ) . getColBytes ( 0 ) ) ;
if ( urlHashes . contains ( h ) ) j . remove ( ) ;
}
// iterate through the domain stacks
final Iterator < Map . Entry < String , LinkedList < String > > > k = domainStacks . entrySet ( ) . iterator ( ) ;
Map . Entry < String , LinkedList < String > > se ;
LinkedList < String > stack ;
while ( k . hasNext ( ) ) {
se = k . next ( ) ;
stack = se . getValue ( ) ;
i = stack . iterator ( ) ;
while ( i . hasNext ( ) ) {
if ( urlHashes . contains ( i . next ( ) ) ) i . remove ( ) ;
}
if ( stack . size ( ) = = 0 ) k . remove ( ) ;
}
return removedCounter ;
}
public synchronized boolean has ( final String urlhash ) {
return urlFileIndex . has ( urlhash . getBytes ( ) ) ;
}
public boolean notEmpty ( ) {
// alternative method to the property size() > 0
// this is better because it may avoid synchronized access to domain stack summarization
return urlRAMStack . size ( ) > 0 | | urlFileStack . size ( ) > 0 | | domainStacksNotEmpty ( ) ;
}
public int size ( ) {
final int componentsize = urlFileIndex . size ( ) ;
/ *
assert componentsize = = urlFileStack . size ( ) + urlRAMStack . size ( ) + sizeDomainStacks ( ) :
"size wrong in " + stackname +
" - urlFileIndex = " + urlFileIndex . size ( ) +
", componentsize = " + urlFileStack . size ( ) + urlRAMStack . size ( ) + sizeDomainStacks ( ) +
" = (urlFileStack = " + urlFileStack . size ( ) +
", urlRAMStack = " + urlRAMStack . size ( ) +
", sizeDomainStacks = " + sizeDomainStacks ( ) + ")" ;
* /
return componentsize ;
}
private boolean domainStacksNotEmpty ( ) {
if ( domainStacks = = null ) return false ;
synchronized ( domainStacks ) {
final Iterator < LinkedList < String > > i = domainStacks . values ( ) . iterator ( ) ;
while ( i . hasNext ( ) ) {
if ( i . next ( ) . size ( ) > 0 ) return true ;
}
}
return false ;
}
private int sizeDomainStacks ( ) {
if ( domainStacks = = null ) return 0 ;
int sum = 0 ;
synchronized ( domainStacks ) {
final Iterator < LinkedList < String > > i = domainStacks . values ( ) . iterator ( ) ;
while ( i . hasNext ( ) ) sum + = i . next ( ) . size ( ) ;
}
return sum ;
}
private void flushOnceDomStacks ( final int minimumleft , final boolean ram ) {
// takes one entry from every domain stack and puts it on the ram or file stack
// the minimumleft value is a limit for the number of entries that should be left
if ( domainStacks . size ( ) = = 0 ) return ;
synchronized ( domainStacks ) {
final Iterator < Map . Entry < String , LinkedList < String > > > i = domainStacks . entrySet ( ) . iterator ( ) ;
Map . Entry < String , LinkedList < String > > entry ;
LinkedList < String > list ;
while ( i . hasNext ( ) ) {
entry = i . next ( ) ;
list = entry . getValue ( ) ;
if ( list . size ( ) > minimumleft ) {
if ( ram ) {
urlRAMStack . add ( list . removeFirst ( ) ) ;
} else try {
urlFileStack . push ( urlFileStack . row ( ) . newEntry ( new byte [ ] [ ] { ( list . removeFirst ( ) ) . getBytes ( ) } ) ) ;
} catch ( final IOException e ) {
e . printStackTrace ( ) ;
}
}
if ( list . size ( ) = = 0 ) i . remove ( ) ;
}
}
}
private void flushAllRamStack ( ) throws IOException {
// this flushes only the ramStack to the fileStack, but does not flush the domainStacks
for ( int i = 0 ; i < urlRAMStack . size ( ) / 2 ; i + + ) {
urlFileStack . push ( urlFileStack . row ( ) . newEntry ( new byte [ ] [ ] { ( urlRAMStack . get ( i ) ) . getBytes ( ) } ) ) ;
urlFileStack . push ( urlFileStack . row ( ) . newEntry ( new byte [ ] [ ] { ( urlRAMStack . get ( urlRAMStack . size ( ) - i - 1 ) ) . getBytes ( ) } ) ) ;
}
if ( urlRAMStack . size ( ) % 2 = = 1 )
urlFileStack . push ( urlFileStack . row ( ) . newEntry ( new byte [ ] [ ] { ( urlRAMStack . get ( urlRAMStack . size ( ) / 2 ) ) . getBytes ( ) } ) ) ;
}
public synchronized void push ( final CrawlEntry entry ) throws IOException {
assert entry ! = null ;
if ( urlFileIndex . has ( entry . url ( ) . hash ( ) . getBytes ( ) ) ) {
serverLog . logWarning ( "PLASMA BALANCER" , "double-check has failed for urlhash " + entry . url ( ) . hash ( ) + " in " + stackname + " - fixed" ) ;
return ;
}
// add to index
urlFileIndex . put ( entry . toRow ( ) ) ;
// add the hash to a queue
pushHash ( entry . url ( ) . hash ( ) ) ;
}
private void pushHash ( final String hash ) {
// extend domain stack
final String dom = hash . substring ( 6 ) ;
LinkedList < String > domainList = domainStacks . get ( dom ) ;
if ( domainList = = null ) {
// create new list
domainList = new LinkedList < String > ( ) ;
synchronized ( domainStacks ) {
domainList . add ( hash ) ;
domainStacks . put ( dom , domainList ) ;
}
} else {
// extend existent domain list
domainList . addLast ( hash ) ;
}
// check size of domainStacks and flush
if ( ( domainStacks . size ( ) > 100 ) | | ( sizeDomainStacks ( ) > 1000 ) ) {
flushOnceDomStacks ( 1 , urlRAMStack . size ( ) < 100 ) ; // when the ram stack is small, flush it there
}
}
public synchronized CrawlEntry pop ( final long minimumLocalDelta , final long minimumGlobalDelta , final long maximumAge ) throws IOException {
// returns an url-hash from the stack and ensures minimum delta times
// we have 3 sources to choose from: the ramStack, the domainStacks and the fileStack
String result = null ; // the result
// 1st: check ramStack
if ( urlRAMStack . size ( ) > 0 ) {
result = urlRAMStack . remove ( 0 ) ;
}
// 2nd-a: check domainStacks for latest arrivals
if ( ( result = = null ) & & ( domainStacks . size ( ) > 0 ) ) synchronized ( domainStacks ) {
// we select specific domains that have not been used for a long time
// i.e. 60 seconds. Latest arrivals that have not yet been crawled
// fit also in that scheme
final Iterator < Map . Entry < String , LinkedList < String > > > i = domainStacks . entrySet ( ) . iterator ( ) ;
Map . Entry < String , LinkedList < String > > entry ;
String domhash ;
long delta , maxdelta = 0 ;
String maxhash = null ;
LinkedList < String > domlist ;
while ( i . hasNext ( ) ) {
entry = i . next ( ) ;
domhash = entry . getKey ( ) ;
delta = lastAccessDelta ( domhash ) ;
if ( delta = = Integer . MAX_VALUE ) {
// a brand new domain - we take it
domlist = entry . getValue ( ) ;
result = domlist . removeFirst ( ) ;
if ( domlist . size ( ) = = 0 ) i . remove ( ) ;
break ;
}
if ( delta > maxdelta ) {
maxdelta = delta ;
maxhash = domhash ;
}
}
if ( maxdelta > maximumAge ) {
// success - we found an entry from a domain that has not been used for a long time
domlist = domainStacks . get ( maxhash ) ;
result = domlist . removeFirst ( ) ;
if ( domlist . size ( ) = = 0 ) domainStacks . remove ( maxhash ) ;
}
}
// 2nd-b: check domainStacks for best match between stack size and retrieval time
if ( ( result = = null ) & & ( domainStacks . size ( ) > 0 ) ) synchronized ( domainStacks ) {
// we order all domains by the number of entries per domain
// then we iterate through these domains in descending entry order
// and that that one, that has a delta > minimumDelta
final Iterator < Map . Entry < String , LinkedList < String > > > i = domainStacks . entrySet ( ) . iterator ( ) ;
Map . Entry < String , LinkedList < String > > entry ;
String domhash ;
LinkedList < String > domlist ;
final TreeMap < Integer , String > hitlist = new TreeMap < Integer , String > ( ) ;
int count = 0 ;
// first collect information about sizes of the domain lists
while ( i . hasNext ( ) ) {
entry = i . next ( ) ;
domhash = entry . getKey ( ) ;
domlist = entry . getValue ( ) ;
hitlist . put ( new Integer ( domlist . size ( ) * 100 + count + + ) , domhash ) ;
}
// now iterate in descending order and fetch that one,
// that is acceptable by the minimumDelta constraint
long delta ;
String maxhash = null ;
while ( hitlist . size ( ) > 0 ) {
domhash = hitlist . remove ( hitlist . lastKey ( ) ) ;
if ( maxhash = = null ) maxhash = domhash ; // remember first entry
delta = lastAccessDelta ( domhash ) ;
if ( delta > minimumGlobalDelta ) {
domlist = domainStacks . get ( domhash ) ;
result = domlist . removeFirst ( ) ;
if ( domlist . size ( ) = = 0 ) domainStacks . remove ( domhash ) ;
break ;
}
}
// if we did yet not choose any entry, we simply take that one with the most entries
if ( ( result = = null ) & & ( maxhash ! = null ) ) {
domlist = domainStacks . get ( maxhash ) ;
result = domlist . removeFirst ( ) ;
if ( domlist . size ( ) = = 0 ) domainStacks . remove ( maxhash ) ;
}
}
// 3rd: take entry from file
if ( ( result = = null ) & & ( urlFileStack . size ( ) > 0 ) ) {
final kelondroRow . Entry nextentry = ( top ) ? urlFileStack . top ( ) : urlFileStack . bot ( ) ;
if ( nextentry = = null ) {
// emergency case: this means that something with the stack organization is wrong
// the file appears to be broken. We kill the file.
kelondroStack . reset ( urlFileStack ) ;
serverLog . logSevere ( "PLASMA BALANCER" , "get() failed to fetch entry from file stack. reset stack file." ) ;
} else {
final String nexthash = new String ( nextentry . getColBytes ( 0 ) ) ;
// check if the time after retrieval of last hash from same
// domain is not shorter than the minimumDelta
long delta = lastAccessDelta ( nexthash ) ;
if ( delta > minimumGlobalDelta ) {
// the entry is fine
result = new String ( ( top ) ? urlFileStack . pop ( ) . getColBytes ( 0 ) : urlFileStack . pot ( ) . getColBytes ( 0 ) ) ;
} else {
// try other entry
result = new String ( ( top ) ? urlFileStack . pot ( ) . getColBytes ( 0 ) : urlFileStack . pop ( ) . getColBytes ( 0 ) ) ;
delta = lastAccessDelta ( result ) ;
}
}
top = ! top ; // alternate top/bottom
}
// check case where we did not found anything
if ( result = = null ) {
serverLog . logSevere ( "PLASMA BALANCER" , "get() was not able to find a valid urlhash - total size = " + size ( ) + ", fileStack.size() = " + urlFileStack . size ( ) + ", ramStack.size() = " + urlRAMStack . size ( ) + ", domainStacks.size() = " + domainStacks . size ( ) ) ;
return null ;
}
// finally: check minimumDelta and if necessary force a sleep
final long delta = lastAccessDelta ( result ) ;
assert delta > = 0 : "delta = " + delta ;
final int s = urlFileIndex . size ( ) ;
final kelondroRow . Entry rowEntry = urlFileIndex . remove ( result . getBytes ( ) ) ;
assert ( rowEntry = = null ) | | ( urlFileIndex . size ( ) + 1 = = s ) : "urlFileIndex.size() = " + urlFileIndex . size ( ) + ", s = " + s + ", result = " + result ;
if ( rowEntry = = null ) {
serverLog . logSevere ( "PLASMA BALANCER" , "get() found a valid urlhash, but failed to fetch the corresponding url entry - total size = " + size ( ) + ", fileStack.size() = " + urlFileStack . size ( ) + ", ramStack.size() = " + urlRAMStack . size ( ) + ", domainStacks.size() = " + domainStacks . size ( ) ) ;
return null ;
}
assert urlFileIndex . size ( ) + 1 = = s : "urlFileIndex.size() = " + urlFileIndex . size ( ) + ", s = " + s + ", result = " + result ;
final CrawlEntry crawlEntry = new CrawlEntry ( rowEntry ) ;
final long genericDelta = Math . min (
15000 ,
Math . max (
( crawlEntry . url ( ) . isLocal ( ) ) ? minimumLocalDelta : minimumGlobalDelta ,
plasmaSwitchboard . getSwitchboard ( ) . robots . crawlDelay ( crawlEntry . url ( ) ) * 1000 )
) ; // prevent that that robots file can stop our indexer completely
if ( delta < genericDelta ) {
// force a busy waiting here
// in best case, this should never happen if the balancer works propertly
// this is only to protect against the worst case, where the crawler could
// behave in a DoS-manner
final long sleeptime = genericDelta - delta ;
try { synchronized ( this ) { this . wait ( sleeptime ) ; } } catch ( final InterruptedException e ) { }
}
// update statistical data
domaccess lastAccess = domainAccess . get ( result . substring ( 6 ) ) ;
if ( lastAccess = = null ) lastAccess = new domaccess ( ) ; else lastAccess . update ( ) ;
domainAccess . put ( result . substring ( 6 ) , lastAccess ) ;
return crawlEntry ;
}
private long lastAccessDelta ( final String hash ) {
assert hash ! = null ;
final domaccess lastAccess = domainAccess . get ( ( hash . length ( ) > 6 ) ? hash . substring ( 6 ) : hash ) ;
if ( lastAccess = = null ) return Long . MAX_VALUE ; // never accessed
return System . currentTimeMillis ( ) - lastAccess . time ( ) ;
}
public synchronized ArrayList < CrawlEntry > top ( int count ) throws IOException {
// if we need to flush anything, then flush the domain stack first,
// to avoid that new urls get hidden by old entries from the file stack
if ( urlRAMStack = = null ) return null ;
while ( ( domainStacksNotEmpty ( ) ) & & ( urlRAMStack . size ( ) < = count ) ) {
// flush only that much as we need to display
flushOnceDomStacks ( 0 , true ) ;
}
while ( ( urlFileStack ! = null ) & & ( urlRAMStack . size ( ) < = count ) & & ( urlFileStack . size ( ) > 0 ) ) {
// flush some entries from disc to ram stack
try {
// one from the top:
kelondroRow . Entry t = urlFileStack . pop ( ) ;
if ( t = = null ) break ;
urlRAMStack . add ( new String ( t . getColBytes ( 0 ) ) ) ;
if ( urlFileStack . size ( ) = = 0 ) break ;
// one from the bottom:
t = urlFileStack . pot ( ) ;
if ( t = = null ) break ;
urlRAMStack . add ( new String ( t . getColBytes ( 0 ) ) ) ;
} catch ( final IOException e ) {
break ;
}
}
count = Math . min ( count , urlRAMStack . size ( ) ) ;
final ArrayList < CrawlEntry > list = new ArrayList < CrawlEntry > ( ) ;
for ( int i = 0 ; i < count ; i + + ) {
final String urlhash = urlRAMStack . get ( i ) ;
final kelondroRow . Entry entry = urlFileIndex . get ( urlhash . getBytes ( ) ) ;
if ( entry = = null ) break ;
list . add ( new CrawlEntry ( entry ) ) ;
}
return list ;
}
public synchronized Iterator < CrawlEntry > iterator ( ) throws IOException {
return new EntryIterator ( ) ;
}
private class EntryIterator implements Iterator < CrawlEntry > {
private Iterator < kelondroRow . Entry > rowIterator ;
public EntryIterator ( ) throws IOException {
rowIterator = urlFileIndex . rows ( true , null ) ;
}
public boolean hasNext ( ) {
return ( rowIterator = = null ) ? false : rowIterator . hasNext ( ) ;
}
public CrawlEntry next ( ) {
final kelondroRow . Entry entry = rowIterator . next ( ) ;
try {
return ( entry = = null ) ? null : new CrawlEntry ( entry ) ;
} catch ( final IOException e ) {
rowIterator = null ;
return null ;
}
}
public void remove ( ) {
if ( rowIterator ! = null ) rowIterator . remove ( ) ;
}
}
}
