/**
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.apache.hadoop.hdfs.server.namenode;
import java.io.DataInput;
import java.io.IOException;
import java.util.*;
import org.apache.hadoop.hdfs.protocol.Block;
import org.apache.hadoop.hdfs.protocol.BlockListAsLongs;
import org.apache.hadoop.hdfs.protocol.DatanodeID;
import org.apache.hadoop.hdfs.protocol.DatanodeInfo;
import org.apache.hadoop.hdfs.server.common.GenerationStamp;
import org.apache.hadoop.hdfs.server.namenode.BlocksMap.BlockInfo;
import org.apache.hadoop.hdfs.server.protocol.BlockCommand;
import org.apache.hadoop.hdfs.server.protocol.DatanodeProtocol;
import org.apache.hadoop.io.Text;
import org.apache.hadoop.io.UTF8;
import org.apache.hadoop.io.WritableUtils;
/**************************************************
* DatanodeDescriptor tracks stats on a given DataNode,
* such as available storage capacity, last update time, etc.,
* and maintains a set of blocks stored on the datanode.
*
* This data structure is a data structure that is internal
* to the namenode. It is *not* sent over-the-wire to the Client
* or the Datnodes. Neither is it stored persistently in the
* fsImage.
**************************************************/
public class DatanodeDescriptor extends DatanodeInfo {
// Stores status of decommissioning.
// If node is not decommissioning, do not use this object for anything.
DecommissioningStatus decommissioningStatus = new DecommissioningStatus();
/** Block and targets pair */
public static class BlockTargetPair {
public final Block block;
public final DatanodeDescriptor[] targets;
BlockTargetPair(Block block, DatanodeDescriptor[] targets) {
this.block = block;
this.targets = targets;
}
}
/** A BlockTargetPair queue. */
private static class BlockQueue {
private final Queue<BlockTargetPair> blockq = new LinkedList<BlockTargetPair>();
/** Size of the queue */
synchronized int size() {return blockq.size();}
/** Enqueue */
synchronized boolean offer(Block block, DatanodeDescriptor[] targets) {
return blockq.offer(new BlockTargetPair(block, targets));
}
/** Dequeue */
synchronized List<BlockTargetPair> poll(int numBlocks) {
if (numBlocks <= 0 || blockq.isEmpty()) {
return null;
}
List<BlockTargetPair> results = new ArrayList<BlockTargetPair>();
for(; !blockq.isEmpty() && numBlocks > 0; numBlocks--) {
results.add(blockq.poll());
}
return results;
}
}
private volatile BlockInfo blockList = null;
// isAlive == heartbeats.contains(this)
// This is an optimization, because contains takes O(n) time on Arraylist
protected boolean isAlive = false;
protected boolean needKeyUpdate = false;
// A system administrator can tune the balancer bandwidth parameter
// (dfs.balance.bandwidthPerSec) dynamically by calling
// "dfsadmin -setBalanacerBandwidth <newbandwidth>", at which point the
// following 'bandwidth' variable gets updated with the new value for each
// node. Once the heartbeat command is issued to update the value on the
// specified datanode, this value will be set back to 0.
private long bandwidth;
/** A queue of blocks to be replicated by this datanode */
private BlockQueue replicateBlocks = new BlockQueue();
/** A queue of blocks to be recovered by this datanode */
private BlockQueue recoverBlocks = new BlockQueue();
/** A set of blocks to be invalidated by this datanode */
private Set<Block> invalidateBlocks = new TreeSet<Block>();
/* Variables for maintaning number of blocks scheduled to be written to
* this datanode. This count is approximate and might be slightly higger
* in case of errors (e.g. datanode does not report if an error occurs
* while writing the block).
*/
private int currApproxBlocksScheduled = 0;
private int prevApproxBlocksScheduled = 0;
private long lastBlocksScheduledRollTime = 0;
private static final int BLOCKS_SCHEDULED_ROLL_INTERVAL = 600*1000; //10min
// Set to false after processing first block report
private boolean firstBlockReport = true;
/** Default constructor */
public DatanodeDescriptor() {}
/** DatanodeDescriptor constructor
* @param nodeID id of the data node
*/
public DatanodeDescriptor(DatanodeID nodeID) {
this(nodeID, 0L, 0L, 0L, 0);
}
/** DatanodeDescriptor constructor
*
* @param nodeID id of the data node
* @param networkLocation location of the data node in network
*/
public DatanodeDescriptor(DatanodeID nodeID,
String networkLocation) {
this(nodeID, networkLocation, null);
}
/** DatanodeDescriptor constructor
*
* @param nodeID id of the data node
* @param networkLocation location of the data node in network
* @param hostName it could be different from host specified for DatanodeID
*/
public DatanodeDescriptor(DatanodeID nodeID,
String networkLocation,
String hostName) {
this(nodeID, networkLocation, hostName, 0L, 0L, 0L, 0);
}
/** DatanodeDescriptor constructor
*
* @param nodeID id of the data node
* @param capacity capacity of the data node
* @param dfsUsed space used by the data node
* @param remaining remaing capacity of the data node
* @param xceiverCount # of data transfers at the data node
*/
public DatanodeDescriptor(DatanodeID nodeID,
long capacity,
long dfsUsed,
long remaining,
int xceiverCount) {
super(nodeID);
updateHeartbeat(capacity, dfsUsed, remaining, xceiverCount);
}
/** DatanodeDescriptor constructor
*
* @param nodeID id of the data node
* @param networkLocation location of the data node in network
* @param capacity capacity of the data node, including space used by non-dfs
* @param dfsUsed the used space by dfs datanode
* @param remaining remaing capacity of the data node
* @param xceiverCount # of data transfers at the data node
*/
public DatanodeDescriptor(DatanodeID nodeID,
String networkLocation,
String hostName,
long capacity,
long dfsUsed,
long remaining,
int xceiverCount) {
super(nodeID, networkLocation, hostName);
updateHeartbeat(capacity, dfsUsed, remaining, xceiverCount);
}
/**
* Add data-node to the block.
* Add block to the head of the list of blocks belonging to the data-node.
*/
boolean addBlock(BlockInfo b) {
if(!b.addNode(this))
return false;
// add to the head of the data-node list
blockList = b.listInsert(blockList, this);
return true;
}
/**
* Remove block from the list of blocks belonging to the data-node.
* Remove data-node from the block.
*/
boolean removeBlock(BlockInfo b) {
blockList = b.listRemove(blockList, this);
return b.removeNode(this);
}
/**
* Move block to the head of the list of blocks belonging to the data-node.
*/
void moveBlockToHead(BlockInfo b) {
blockList = b.listRemove(blockList, this);
blockList = b.listInsert(blockList, this);
}
void resetBlocks() {
this.capacity = 0;
this.remaining = 0;
this.dfsUsed = 0;
this.xceiverCount = 0;
this.blockList = null;
this.invalidateBlocks.clear();
}
public int numBlocks() {
return blockList == null ? 0 : blockList.listCount(this);
}
/**
*/
void updateHeartbeat(long capacity, long dfsUsed, long remaining,
int xceiverCount) {
this.capacity = capacity;
this.dfsUsed = dfsUsed;
this.remaining = remaining;
this.lastUpdate = System.currentTimeMillis();
this.xceiverCount = xceiverCount;
rollBlocksScheduled(lastUpdate);
}
/**
* Iterates over the list of blocks belonging to the data-node.
*/
static private class BlockIterator implements Iterator<Block> {
private BlockInfo current;
private DatanodeDescriptor node;
BlockIterator(BlockInfo head, DatanodeDescriptor dn) {
this.current = head;
this.node = dn;
}
public boolean hasNext() {
return current != null;
}
public BlockInfo next() {
BlockInfo res = current;
current = current.getNext(current.findDatanode(node));
return res;
}
public void remove() {
throw new UnsupportedOperationException("Sorry. can't remove.");
}
}
Iterator<Block> getBlockIterator() {
return new BlockIterator(this.blockList, this);
}
/**
* Store block replication work.
*/
void addBlockToBeReplicated(Block block, DatanodeDescriptor[] targets) {
assert(block != null && targets != null && targets.length > 0);
replicateBlocks.offer(block, targets);
}
/**
* Store block recovery work.
*/
void addBlockToBeRecovered(Block block, DatanodeDescriptor[] targets) {
assert(block != null && targets != null && targets.length > 0);
recoverBlocks.offer(block, targets);
}
/**
* Store block invalidation work.
*/
void addBlocksToBeInvalidated(List<Block> blocklist) {
assert(blocklist != null && blocklist.size() > 0);
synchronized (invalidateBlocks) {
for(Block blk : blocklist) {
invalidateBlocks.add(blk);
}
}
}
/**
* The number of work items that are pending to be replicated
*/
int getNumberOfBlocksToBeReplicated() {
return replicateBlocks.size();
}
/**
* The number of block invalidation items that are pending to
* be sent to the datanode
*/
int getNumberOfBlocksToBeInvalidated() {
synchronized (invalidateBlocks) {
return invalidateBlocks.size();
}
}
BlockCommand getReplicationCommand(int maxTransfers) {
List<BlockTargetPair> blocktargetlist = replicateBlocks.poll(maxTransfers);
return blocktargetlist == null? null:
new BlockCommand(DatanodeProtocol.DNA_TRANSFER, blocktargetlist);
}
BlockCommand getLeaseRecoveryCommand(int maxTransfers) {
List<BlockTargetPair> blocktargetlist = recoverBlocks.poll(maxTransfers);
return blocktargetlist == null? null:
new BlockCommand(DatanodeProtocol.DNA_RECOVERBLOCK, blocktargetlist);
}
/**
* Remove the specified number of blocks to be invalidated
*/
BlockCommand getInvalidateBlocks(int maxblocks) {
Block[] deleteList = getBlockArray(invalidateBlocks, maxblocks);
return deleteList == null?
null: new BlockCommand(DatanodeProtocol.DNA_INVALIDATE, deleteList);
}
static private Block[] getBlockArray(Collection<Block> blocks, int max) {
Block[] blockarray = null;
synchronized(blocks) {
int available = blocks.size();
int n = available;
if (max > 0 && n > 0) {
if (max < n) {
n = max;
}
// allocate the properly sized block array ...
blockarray = new Block[n];
// iterate tree collecting n blocks...
Iterator<Block> e = blocks.iterator();
int blockCount = 0;
while (blockCount < n && e.hasNext()) {
// insert into array ...
blockarray[blockCount++] = e.next();
// remove from tree via iterator, if we are removing
// less than total available blocks
if (n < available){
e.remove();
}
}
assert(blockarray.length == n);
// now if the number of blocks removed equals available blocks,
// them remove all blocks in one fell swoop via clear
if (n == available) {
blocks.clear();
}
}
}
return blockarray;
}
void reportDiff(BlocksMap blocksMap,
BlockListAsLongs newReport,
Collection<Block> toAdd,
Collection<Block> toRemove,
Collection<Block> toInvalidate) {
// place a deilimiter in the list which separates blocks
// that have been reported from those that have not
BlockInfo delimiter = new BlockInfo(new Block(), 1);
boolean added = this.addBlock(delimiter);
assert added : "Delimiting block cannot be present in the node";
if(newReport == null)
newReport = new BlockListAsLongs( new long[0]);
// scan the report and collect newly reported blocks
// Note we are taking special precaution to limit tmp blocks allocated
// as part this block report - which why block list is stored as longs
Block iblk = new Block(); // a fixed new'ed block to be reused with index i
Block oblk = new Block(); // for fixing genstamps
for (int i = 0; i < newReport.getNumberOfBlocks(); ++i) {
iblk.set(newReport.getBlockId(i), newReport.getBlockLen(i),
newReport.getBlockGenStamp(i));
BlockInfo storedBlock = blocksMap.getStoredBlock(iblk);
if(storedBlock == null) {
// if the block with a WILDCARD generation stamp matches
// then accept this block.
// This block has a diferent generation stamp on the datanode
// because of a lease-recovery-attempt.
oblk.set(newReport.getBlockId(i), newReport.getBlockLen(i),
GenerationStamp.WILDCARD_STAMP);
storedBlock = blocksMap.getStoredBlock(oblk);
if (storedBlock != null && storedBlock.getINode() != null &&
(storedBlock.getGenerationStamp() <= iblk.getGenerationStamp() ||
storedBlock.getINode().isUnderConstruction())) {
// accept block. It wil be cleaned up on cluster restart.
} else {
storedBlock = null;
}
}
if(storedBlock == null) {
// If block is not in blocksMap it does not belong to any file
toInvalidate.add(new Block(iblk));
continue;
}
if(storedBlock.findDatanode(this) < 0) {// Known block, but not on the DN
// if the size differs from what is in the blockmap, then return
// the new block. addStoredBlock will then pick up the right size of this
// block and will update the block object in the BlocksMap
if (storedBlock.getNumBytes() != iblk.getNumBytes()) {
toAdd.add(new Block(iblk));
} else {
toAdd.add(storedBlock);
}
continue;
}
// move block to the head of the list
this.moveBlockToHead(storedBlock);
}
// collect blocks that have not been reported
// all of them are next to the delimiter
Iterator<Block> it = new BlockIterator(delimiter.getNext(0), this);
while(it.hasNext()) {
BlockInfo storedBlock = (BlockInfo)it.next();
INodeFile file = storedBlock.getINode();
if (file == null || !file.isUnderConstruction()) {
toRemove.add(storedBlock);
}
}
this.removeBlock(delimiter);
}
/** Serialization for FSEditLog */
void readFieldsFromFSEditLog(DataInput in) throws IOException {
this.name = UTF8.readString(in);
this.storageID = UTF8.readString(in);
this.infoPort = in.readShort() & 0x0000ffff;
this.capacity = in.readLong();
this.dfsUsed = in.readLong();
this.remaining = in.readLong();
this.lastUpdate = in.readLong();
this.xceiverCount = in.readInt();
this.location = Text.readString(in);
this.hostName = Text.readString(in);
setAdminState(WritableUtils.readEnum(in, AdminStates.class));
}
/**
* @return Approximate number of blocks currently scheduled to be written
* to this datanode.
*/
public int getBlocksScheduled() {
return currApproxBlocksScheduled + prevApproxBlocksScheduled;
}
/**
* Increments counter for number of blocks scheduled.
*/
void incBlocksScheduled() {
currApproxBlocksScheduled++;
}
/**
* Decrements counter for number of blocks scheduled.
*/
void decBlocksScheduled() {
if (prevApproxBlocksScheduled > 0) {
prevApproxBlocksScheduled--;
} else if (currApproxBlocksScheduled > 0) {
currApproxBlocksScheduled--;
}
// its ok if both counters are zero.
}
/**
* Adjusts curr and prev number of blocks scheduled every few minutes.
*/
private void rollBlocksScheduled(long now) {
if ((now - lastBlocksScheduledRollTime) >
BLOCKS_SCHEDULED_ROLL_INTERVAL) {
prevApproxBlocksScheduled = currApproxBlocksScheduled;
currApproxBlocksScheduled = 0;
lastBlocksScheduledRollTime = now;
}
}
class DecommissioningStatus {
int underReplicatedBlocks;
int decommissionOnlyReplicas;
int underReplicatedInOpenFiles;
long startTime;
synchronized void set(int underRep, int onlyRep, int underConstruction) {
if (isDecommissionInProgress() == false) {
return;
}
underReplicatedBlocks = underRep;
decommissionOnlyReplicas = onlyRep;
underReplicatedInOpenFiles = underConstruction;
}
synchronized int getUnderReplicatedBlocks() {
if (isDecommissionInProgress() == false) {
return 0;
}
return underReplicatedBlocks;
}
synchronized int getDecommissionOnlyReplicas() {
if (isDecommissionInProgress() == false) {
return 0;
}
return decommissionOnlyReplicas;
}
synchronized int getUnderReplicatedInOpenFiles() {
if (isDecommissionInProgress() == false) {
return 0;
}
return underReplicatedInOpenFiles;
}
synchronized void setStartTime(long time) {
startTime = time;
}
synchronized long getStartTime() {
if (isDecommissionInProgress() == false) {
return 0;
}
return startTime;
}
} // End of class DecommissioningStatus
/**
* @return Blanacer bandwidth in bytes per second for this datanode.
*/
public long getBalancerBandwidth() {
return this.bandwidth;
}
/**
* @param bandwidth Blanacer bandwidth in bytes per second for this datanode.
*/
public void setBalancerBandwidth(long bandwidth) {
this.bandwidth = bandwidth;
}
boolean firstBlockReport() {
return firstBlockReport;
}
void processedBlockReport() {
firstBlockReport = false;
}
}