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PageList.java
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PageList.java
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/*
* Copyright (c) 2002-2016 "Neo Technology,"
* Network Engine for Objects in Lund AB [http://neotechnology.com]
*
* This file is part of Neo4j.
*
* Neo4j 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 3 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, see <http://www.gnu.org/licenses/>.
*/
package org.neo4j.io.pagecache.impl.muninn;
import java.io.IOException;
import org.neo4j.io.pagecache.PageCursor;
import org.neo4j.io.pagecache.PageSwapper;
import org.neo4j.io.pagecache.tracing.PageFaultEvent;
import org.neo4j.unsafe.impl.internal.dragons.MemoryManager;
import org.neo4j.unsafe.impl.internal.dragons.UnsafeUtil;
import static java.lang.String.format;
/**
* The PageList maintains the off-heap meta-data for the individual memory pages.
*
* The meta-data for each page is the following:
*
* <table>
* <tr><th>Bytes</th><th>Use</th></tr>
* <tr><td>8</td><td>Sequence lock word.</td></tr>
* <tr><td>8</td><td>Pointer to the memory page.</td></tr>
* <tr><td>8</td><td>File page id.</td></tr>
* <tr><td>4</td><td>Page swapper id.</td></tr>
* <tr><td>1</td><td>Usage stamp. Optimistically incremented; truncated to a max of 4.</td></tr>
* <tr><td>3</td><td>Padding.</td></tr>
* </table>
*/
class PageList
{
private static final int META_DATA_BYTES_PER_PAGE = 32;
private static final int OFFSET_LOCK_WORD = 0; // 8 bytes
private static final int OFFSET_ADDRESS = 8; // 8 bytes
private static final int OFFSET_FILE_PAGE_ID = 16; // 8 bytes
private static final int OFFSET_SWAPPER_ID = 24; // 4 bytes
private static final int OFFSET_USAGE_COUNTER = 28; // 1 byte
// todo it's possible to reduce the overhead of the individual page to just 24 bytes,
// todo because the file page id can be represented with 5 bytes (enough to address 8-4 PBs),
// todo and then the usage counter can use the high bits of that word, and the swapper id
// todo can use the rest (2 bytes or 20 bits).
// todo we can alternatively also make use of the lower 12 bits of the address field, because
// todo the addresses are page aligned, and we can assume them to be at least 4096 bytes in size.
private final long pageCount;
private final int cachePageSize;
private final MemoryManager memoryManager;
private final SwapperSet swappers;
private final long victimPageAddress;
private final long baseAddress;
PageList( long pageCount, int cachePageSize, MemoryManager memoryManager, SwapperSet swappers, long victimPageAddress )
{
this.pageCount = pageCount;
this.cachePageSize = cachePageSize;
this.memoryManager = memoryManager;
this.swappers = swappers;
this.victimPageAddress = victimPageAddress;
long bytes = pageCount * META_DATA_BYTES_PER_PAGE;
this.baseAddress = memoryManager.allocateAligned( bytes );
clearMemory( baseAddress, pageCount );
}
/**
* This copy-constructor is useful for classes that want to extend the {@code PageList} class to inline its fields.
* All data and state will be shared between this and the given {@code PageList}. This means that changing the page
* list state through one has the same effect as changing it through the other – they are both effectively the same
* object.
* @param pageList The {@code PageList} instance whose state to copy.
*/
PageList( PageList pageList )
{
this.pageCount = pageList.pageCount;
this.cachePageSize = pageList.cachePageSize;
this.memoryManager = pageList.memoryManager;
this.swappers = pageList.swappers;
this.victimPageAddress = pageList.victimPageAddress;
this.baseAddress = pageList.baseAddress;
}
private void clearMemory( long baseAddress, long pageCount )
{
long address = baseAddress - 8;
for ( long i = 0; i < pageCount; i++ )
{
UnsafeUtil.putLong( address += 8, 0 ); // lock word
UnsafeUtil.putLong( address += 8, 0 ); // pointer
UnsafeUtil.putLong( address += 8, PageCursor.UNBOUND_PAGE_ID ); // file page id
UnsafeUtil.putLong( address += 8, 0 ); // rest
}
UnsafeUtil.fullFence(); // Guarantee the visibility of the cleared memory
}
/**
* Turn a {@code pageId} into a {@code pageRef} that can be used for accessing and manipulating the given page
* using the other methods in this class.
* @param pageId The {@code pageId} to turn into a {@code pageRef}.
* @return A {@code pageRef} which is an opaque, internal and direct pointer to the meta-data of the given memory
* page.
*/
public long deref( long pageId )
{
return baseAddress + pageId * META_DATA_BYTES_PER_PAGE;
}
private long offLock( long pageRef )
{
return pageRef + OFFSET_LOCK_WORD;
}
private long offAddress( long pageRef )
{
return pageRef + OFFSET_ADDRESS;
}
private long offUsage( long pageRef )
{
return pageRef + OFFSET_USAGE_COUNTER;
}
private long offFilePageId( long pageRef )
{
return pageRef + OFFSET_FILE_PAGE_ID;
}
private long offSwapperId( long pageRef )
{
return pageRef + OFFSET_SWAPPER_ID;
}
public long tryOptimisticReadLock( long pageRef )
{
return OffHeapPageLock.tryOptimisticReadLock( offLock( pageRef ) );
}
public boolean validateReadLock( long pageRef, long stamp )
{
return OffHeapPageLock.validateReadLock( offLock( pageRef ), stamp );
}
public boolean isModified( long pageRef )
{
return OffHeapPageLock.isModified( offLock( pageRef ) );
}
public boolean isExclusivelyLocked( long pageRef )
{
return OffHeapPageLock.isExclusivelyLocked( offLock( pageRef ) );
}
public boolean tryWriteLock( long pageRef )
{
return OffHeapPageLock.tryWriteLock( offLock( pageRef ) );
}
public void unlockWrite( long pageRef )
{
OffHeapPageLock.unlockWrite( offLock( pageRef ) );
}
public boolean tryExclusiveLock( long pageRef )
{
return OffHeapPageLock.tryExclusiveLock( offLock( pageRef ) );
}
public long unlockExclusive( long pageRef )
{
return OffHeapPageLock.unlockExclusive( offLock( pageRef ) );
}
public void unlockExclusiveAndTakeWriteLock( long pageRef )
{
OffHeapPageLock.unlockExclusiveAndTakeWriteLock( offLock( pageRef ) );
}
public long tryFlushLock( long pageRef )
{
return OffHeapPageLock.tryFlushLock( offLock( pageRef ) );
}
public void unlockFlush( long pageRef, long stamp, boolean success )
{
OffHeapPageLock.unlockFlush( offLock( pageRef ), stamp, success );
}
public void explicitlyMarkPageUnmodifiedUnderExclusiveLock( long pageRef )
{
OffHeapPageLock.explicitlyMarkPageUnmodifiedUnderExclusiveLock( offLock( pageRef ) );
}
public int getCachePageSize()
{
return cachePageSize;
}
public long getAddress( long pageRef )
{
return UnsafeUtil.getLong( offAddress( pageRef ) );
}
public void initBuffer( long pageRef )
{
if ( getAddress( pageRef ) == 0L )
{
long addr = memoryManager.allocateAligned( getCachePageSize() );
UnsafeUtil.putLong( offAddress( pageRef ), addr );
}
}
private byte getUsageCounter( long pageRef )
{
return UnsafeUtil.getByteVolatile( offUsage( pageRef ) );
}
private void setUsageCounter( long pageRef, byte count )
{
UnsafeUtil.putByteVolatile( offUsage( pageRef ), count );
}
/**
* Increment the usage stamp to at most 4.
**/
public void incrementUsage( long pageRef )
{
// This is intentionally left benignly racy for performance.
byte usage = getUsageCounter( pageRef );
if ( usage < 4 ) // avoid cache sloshing by not doing a write if counter is already maxed out
{
usage++;
setUsageCounter( pageRef, usage );
}
}
/**
* Decrement the usage stamp. Returns true if it reaches 0.
**/
public boolean decrementUsage( long pageRef )
{
// This is intentionally left benignly racy for performance.
byte usage = getUsageCounter( pageRef );
if ( usage > 0 )
{
usage--;
setUsageCounter( pageRef, usage );
}
return usage == 0;
}
public long getFilePageId( long pageRef )
{
return UnsafeUtil.getLong( offFilePageId( pageRef ) );
}
private void setFilePageId( long pageRef, long filePageId )
{
UnsafeUtil.putLong( offFilePageId( pageRef ), filePageId );
}
public int getSwapperId( long pageRef )
{
return UnsafeUtil.getInt( offSwapperId( pageRef ) );
}
private void setSwapperId( long pageRef, int swapperId )
{
UnsafeUtil.putInt( offSwapperId( pageRef ), swapperId );
}
public boolean isLoaded( long pageRef )
{
return getFilePageId( pageRef ) != PageCursor.UNBOUND_PAGE_ID;
}
public boolean isBoundTo( long pageRef, int swapperId, long filePageId )
{
return getSwapperId( pageRef ) == swapperId && getFilePageId( pageRef ) == filePageId;
}
public void fault( long pageRef, PageSwapper swapper, int swapperId, long filePageId, PageFaultEvent event )
throws IOException
{
if ( swapper == null )
{
throw swapperCannotBeNull();
}
int currentSwapper = getSwapperId( pageRef );
long currentFilePageId = getFilePageId( pageRef );
if ( filePageId == PageCursor.UNBOUND_PAGE_ID || !isExclusivelyLocked( pageRef )
|| currentSwapper != 0 || currentFilePageId != PageCursor.UNBOUND_PAGE_ID )
{
throw cannotFaultException( pageRef, swapper, swapperId, filePageId, currentSwapper, currentFilePageId );
}
// Note: It is important that we assign the filePageId before we swap
// the page in. If the swapping fails, the page will be considered
// loaded for the purpose of eviction, and will eventually return to
// the freelist. However, because we don't assign the swapper until the
// swapping-in has succeeded, the page will not be considered bound to
// the file page, so any subsequent thread that finds the page in their
// translation table will re-do the page fault.
setFilePageId( pageRef, filePageId ); // Page now considered isLoaded()
long bytesRead = swapper.read( filePageId, getAddress( pageRef ), cachePageSize );
event.addBytesRead( bytesRead );
event.setCachePageId( (int) pageRef );
setSwapperId( pageRef, swapperId ); // Page now considered isBoundTo( swapper, filePageId )
}
private static IllegalArgumentException swapperCannotBeNull()
{
return new IllegalArgumentException( "swapper cannot be null" );
}
private static IllegalStateException cannotFaultException( long pageRef, PageSwapper swapper, int swapperId,
long filePageId, int currentSwapper, long currentFilePageId )
{
String msg = format(
"Cannot fault page {filePageId = %s, swapper = %s (swapper id = %s)} into " +
"cache page %s. Already bound to {filePageId = " +
"%s, swapper id = %s}.",
filePageId, swapper, swapperId, pageRef, currentFilePageId, currentSwapper );
return new IllegalStateException( msg );
}
public boolean tryEvict( long pageRef ) throws IOException
{
if ( tryExclusiveLock( pageRef ) )
{
if ( isLoaded( pageRef ) )
{
int swapperId = getSwapperId( pageRef );
SwapperSet.Allocation allocation = swappers.getAllocation( swapperId );
PageSwapper swapper = allocation.swapper;
long filePageId = getFilePageId( pageRef );
if ( isModified( pageRef ) )
{
long address = getAddress( pageRef );
swapper.write( filePageId, address, allocation.filePageSize );
explicitlyMarkPageUnmodifiedUnderExclusiveLock( pageRef );
}
swapper.evicted( filePageId, null );
clearBinding( pageRef );
return true;
}
else
{
unlockExclusive( pageRef );
}
}
return false;
}
private void clearBinding( long pageRef )
{
setFilePageId( pageRef, PageCursor.UNBOUND_PAGE_ID );
setSwapperId( pageRef, 0 );
}
}