HDFS-11419. HDFS specific network topology classes with storage type info included. Contributed by Chen Liang.

This commit is contained in:
Arpit Agarwal 2017-03-02 09:21:27 -08:00
parent 4e14eaded2
commit eeca8b0c4e
10 changed files with 602 additions and 22 deletions

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@ -61,7 +61,7 @@ public interface InnerNode extends Node {
* *
* @param leafIndex an indexed leaf of the node * @param leafIndex an indexed leaf of the node
* @param excludedNode an excluded node (can be null) * @param excludedNode an excluded node (can be null)
* @return * @return the leaf node corresponding to the given index.
*/ */
Node getLeaf(int leafIndex, Node excludedNode); Node getLeaf(int leafIndex, Node excludedNode);
} }

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@ -25,9 +25,9 @@ import java.util.Map;
/** InnerNode represents a switch/router of a data center or rack. /** InnerNode represents a switch/router of a data center or rack.
* Different from a leaf node, it has non-null children. * Different from a leaf node, it has non-null children.
*/ */
class InnerNodeImpl extends NodeBase implements InnerNode { public class InnerNodeImpl extends NodeBase implements InnerNode {
static class Factory implements InnerNode.Factory<InnerNodeImpl> { protected static class Factory implements InnerNode.Factory<InnerNodeImpl> {
private Factory() {} protected Factory() {}
@Override @Override
public InnerNodeImpl newInnerNode(String path) { public InnerNodeImpl newInnerNode(String path) {
@ -37,18 +37,18 @@ class InnerNodeImpl extends NodeBase implements InnerNode {
static final Factory FACTORY = new Factory(); static final Factory FACTORY = new Factory();
private final List<Node> children = new ArrayList<>(); protected final List<Node> children = new ArrayList<>();
private final Map<String, Node> childrenMap = new HashMap<>(); protected final Map<String, Node> childrenMap = new HashMap<>();
private int numOfLeaves; protected int numOfLeaves;
/** Construct an InnerNode from a path-like string */ /** Construct an InnerNode from a path-like string */
InnerNodeImpl(String path) { protected InnerNodeImpl(String path) {
super(path); super(path);
} }
/** Construct an InnerNode /** Construct an InnerNode
* from its name, its network location, its parent, and its level */ * from its name, its network location, its parent, and its level */
InnerNodeImpl(String name, String location, InnerNode parent, int level) { protected InnerNodeImpl(String name, String location, InnerNode parent, int level) {
super(name, location, parent, level); super(name, location, parent, level);
} }
@ -81,7 +81,7 @@ class InnerNodeImpl extends NodeBase implements InnerNode {
* @param n a node * @param n a node
* @return true if this node is an ancestor of <i>n</i> * @return true if this node is an ancestor of <i>n</i>
*/ */
boolean isAncestor(Node n) { protected boolean isAncestor(Node n) {
return getPath(this).equals(NodeBase.PATH_SEPARATOR_STR) || return getPath(this).equals(NodeBase.PATH_SEPARATOR_STR) ||
(n.getNetworkLocation()+NodeBase.PATH_SEPARATOR_STR). (n.getNetworkLocation()+NodeBase.PATH_SEPARATOR_STR).
startsWith(getPath(this)+NodeBase.PATH_SEPARATOR_STR); startsWith(getPath(this)+NodeBase.PATH_SEPARATOR_STR);
@ -92,12 +92,12 @@ class InnerNodeImpl extends NodeBase implements InnerNode {
* @param n a node * @param n a node
* @return true if this node is the parent of <i>n</i> * @return true if this node is the parent of <i>n</i>
*/ */
boolean isParent(Node n) { protected boolean isParent(Node n) {
return n.getNetworkLocation().equals(getPath(this)); return n.getNetworkLocation().equals(getPath(this));
} }
/* Return a child name of this node who is an ancestor of node <i>n</i> */ /* Return a child name of this node who is an ancestor of node <i>n</i> */
private String getNextAncestorName(Node n) { protected String getNextAncestorName(Node n) {
if (!isAncestor(n)) { if (!isAncestor(n)) {
throw new IllegalArgumentException( throw new IllegalArgumentException(
this + "is not an ancestor of " + n); this + "is not an ancestor of " + n);

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@ -68,16 +68,32 @@ public class NetworkTopology {
* @return an instance of NetworkTopology * @return an instance of NetworkTopology
*/ */
public static NetworkTopology getInstance(Configuration conf){ public static NetworkTopology getInstance(Configuration conf){
return ReflectionUtils.newInstance( return getInstance(conf, InnerNodeImpl.FACTORY);
conf.getClass(CommonConfigurationKeysPublic.NET_TOPOLOGY_IMPL_KEY,
NetworkTopology.class, NetworkTopology.class), conf);
} }
InnerNode.Factory factory = InnerNodeImpl.FACTORY; public static NetworkTopology getInstance(Configuration conf,
InnerNode.Factory factory) {
NetworkTopology nt = ReflectionUtils.newInstance(
conf.getClass(CommonConfigurationKeysPublic.NET_TOPOLOGY_IMPL_KEY,
NetworkTopology.class, NetworkTopology.class), conf);
return nt.init(factory);
}
protected NetworkTopology init(InnerNode.Factory factory) {
if (!factory.equals(this.factory)) {
// the constructor has initialized the factory to default. So only init
// again if another factory is specified.
this.factory = factory;
this.clusterMap = factory.newInnerNode(NodeBase.ROOT);
}
return this;
}
InnerNode.Factory factory;
/** /**
* the root cluster map * the root cluster map
*/ */
InnerNode clusterMap = factory.newInnerNode(NodeBase.ROOT); InnerNode clusterMap;
/** Depth of all leaf nodes */ /** Depth of all leaf nodes */
private int depthOfAllLeaves = -1; private int depthOfAllLeaves = -1;
/** rack counter */ /** rack counter */
@ -92,7 +108,10 @@ public class NetworkTopology {
/** the lock used to manage access */ /** the lock used to manage access */
protected ReadWriteLock netlock = new ReentrantReadWriteLock(); protected ReadWriteLock netlock = new ReentrantReadWriteLock();
// keeping the constructor because other components like MR still uses this.
public NetworkTopology() { public NetworkTopology() {
this.factory = InnerNodeImpl.FACTORY;
this.clusterMap = factory.newInnerNode(NodeBase.ROOT);
} }
/** Add a leaf node /** Add a leaf node

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@ -22,6 +22,7 @@ import java.util.HashMap;
import java.util.List; import java.util.List;
import org.apache.commons.math3.stat.inference.ChiSquareTest; import org.apache.commons.math3.stat.inference.ChiSquareTest;
import org.apache.hadoop.conf.Configuration;
import org.junit.Assert; import org.junit.Assert;
import org.junit.Test; import org.junit.Test;
@ -80,7 +81,7 @@ public class TestClusterTopology extends Assert {
@Test @Test
public void testCountNumNodes() throws Exception { public void testCountNumNodes() throws Exception {
// create the topology // create the topology
NetworkTopology cluster = new NetworkTopology(); NetworkTopology cluster = NetworkTopology.getInstance(new Configuration());
NodeElement node1 = getNewNode("node1", "/d1/r1"); NodeElement node1 = getNewNode("node1", "/d1/r1");
cluster.add(node1); cluster.add(node1);
NodeElement node2 = getNewNode("node2", "/d1/r2"); NodeElement node2 = getNewNode("node2", "/d1/r2");
@ -128,7 +129,7 @@ public class TestClusterTopology extends Assert {
@Test @Test
public void testChooseRandom() { public void testChooseRandom() {
// create the topology // create the topology
NetworkTopology cluster = new NetworkTopology(); NetworkTopology cluster = NetworkTopology.getInstance(new Configuration());
NodeElement node1 = getNewNode("node1", "/d1/r1"); NodeElement node1 = getNewNode("node1", "/d1/r1");
cluster.add(node1); cluster.add(node1);
NodeElement node2 = getNewNode("node2", "/d1/r2"); NodeElement node2 = getNewNode("node2", "/d1/r2");

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@ -20,6 +20,7 @@ package org.apache.hadoop.hdfs.server.blockmanagement;
import java.util.ArrayList; import java.util.ArrayList;
import java.util.Collection; import java.util.Collection;
import java.util.Collections; import java.util.Collections;
import java.util.EnumSet;
import java.util.HashMap; import java.util.HashMap;
import java.util.HashSet; import java.util.HashSet;
import java.util.Iterator; import java.util.Iterator;
@ -300,6 +301,14 @@ public class DatanodeDescriptor extends DatanodeInfo {
} }
} }
public EnumSet<StorageType> getStorageTypes() {
EnumSet<StorageType> storageTypes = EnumSet.noneOf(StorageType.class);
for (DatanodeStorageInfo dsi : getStorageInfos()) {
storageTypes.add(dsi.getStorageType());
}
return storageTypes;
}
public StorageReport[] getStorageReports() { public StorageReport[] getStorageReports() {
final DatanodeStorageInfo[] infos = getStorageInfos(); final DatanodeStorageInfo[] infos = getStorageInfos();
final StorageReport[] reports = new StorageReport[infos.length]; final StorageReport[] reports = new StorageReport[infos.length];

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@ -0,0 +1,36 @@
/**
* 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;
import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.net.NetworkTopology;
/**
* The HDFS specific network topology class. The main purpose of doing this
* subclassing is to add storage-type-aware chooseRandom method. All the
* remaining parts should be the same.
*
* Currently a placeholder to test storage type info.
* TODO : add "chooseRandom with storageType info" function.
*/
public class DFSNetworkTopology extends NetworkTopology {
public static DFSNetworkTopology getInstance(Configuration conf) {
DFSNetworkTopology nt = new DFSNetworkTopology();
return (DFSNetworkTopology)nt.init(DFSTopologyNodeImpl.FACTORY);
}
}

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@ -0,0 +1,253 @@
/**
* 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;
import com.google.common.annotations.VisibleForTesting;
import org.apache.hadoop.fs.StorageType;
import org.apache.hadoop.hdfs.server.blockmanagement.DatanodeDescriptor;
import org.apache.hadoop.net.InnerNode;
import org.apache.hadoop.net.InnerNodeImpl;
import org.apache.hadoop.net.Node;
import java.util.EnumMap;
import java.util.EnumSet;
import java.util.HashMap;
/**
* The HDFS-specific representation of a network topology inner node. The
* difference is this class includes the information about the storage type
* info of this subtree. This info will be used when selecting subtrees
* in block placement.
*/
public class DFSTopologyNodeImpl extends InnerNodeImpl {
static final InnerNodeImpl.Factory FACTORY
= new DFSTopologyNodeImpl.Factory();
static final class Factory extends InnerNodeImpl.Factory {
private Factory() {}
@Override
public InnerNodeImpl newInnerNode(String path) {
return new DFSTopologyNodeImpl(path);
}
}
/**
* The core data structure of this class. The information about what storage
* types this subtree has. Basically, a map whose key is a child
* id, value is a enum map including the counts of each storage type. e.g.
* DISK type has count 5 means there are 5 leaf datanodes with DISK type
* available. This value is set/updated upon datanode joining and leaving.
*
* NOTE : It might be sufficient to keep only a map from storage type
* to count, omitting the child node id. But this might make it hard to keep
* consistency when there are updates from children.
*
* For example, if currently R has two children A and B with storage X, Y, and
* A : X=1 Y=1
* B : X=2 Y=2
* so we store X=3 Y=3 as total on R.
*
* Now say A has a new X plugged in and becomes X=2 Y=1.
*
* If we know that "A adds one X", it is easy to update R by +1 on X. However,
* if we don't know "A adds one X", but instead got "A now has X=2 Y=1",
* (which seems to be the case in current heartbeat) we will not know how to
* update R. While if we store on R "A has X=1 and Y=1" then we can simply
* update R by completely replacing the A entry and all will be good.
*/
private final HashMap
<String, EnumMap<StorageType, Integer>> childrenStorageInfo;
DFSTopologyNodeImpl(String path) {
super(path);
childrenStorageInfo = new HashMap<>();
}
DFSTopologyNodeImpl(
String name, String location, InnerNode parent, int level) {
super(name, location, parent, level);
childrenStorageInfo = new HashMap<>();
}
int getNumOfChildren() {
return children.size();
}
@Override
public boolean add(Node n) {
if (!isAncestor(n)) {
throw new IllegalArgumentException(n.getName()
+ ", which is located at " + n.getNetworkLocation()
+ ", is not a descendant of " + getPath(this));
}
// In HDFS topology, the leaf node should always be DatanodeDescriptor
if (!(n instanceof DatanodeDescriptor)) {
throw new IllegalArgumentException("Unexpected node type "
+ n.getClass().getName());
}
DatanodeDescriptor dnDescriptor = (DatanodeDescriptor) n;
if (isParent(n)) {
// this node is the parent of n; add n directly
n.setParent(this);
n.setLevel(this.level + 1);
Node prev = childrenMap.put(n.getName(), n);
if (prev != null) {
for(int i=0; i<children.size(); i++) {
if (children.get(i).getName().equals(n.getName())) {
children.set(i, n);
return false;
}
}
}
children.add(n);
numOfLeaves++;
synchronized (childrenStorageInfo) {
if (!childrenStorageInfo.containsKey(dnDescriptor.getName())) {
childrenStorageInfo.put(
dnDescriptor.getName(), new EnumMap<>(StorageType.class));
}
for (StorageType st : dnDescriptor.getStorageTypes()) {
childrenStorageInfo.get(dnDescriptor.getName()).put(st, 1);
}
}
return true;
} else {
// find the next ancestor node
String parentName = getNextAncestorName(n);
InnerNode parentNode = (InnerNode)childrenMap.get(parentName);
if (parentNode == null) {
// create a new InnerNode
parentNode = createParentNode(parentName);
children.add(parentNode);
childrenMap.put(parentNode.getName(), parentNode);
}
// add n to the subtree of the next ancestor node
if (parentNode.add(n)) {
numOfLeaves++;
synchronized (childrenStorageInfo) {
if (!childrenStorageInfo.containsKey(parentNode.getName())) {
childrenStorageInfo.put(
parentNode.getName(), new EnumMap<>(StorageType.class));
for (StorageType st : dnDescriptor.getStorageTypes()) {
childrenStorageInfo.get(parentNode.getName()).put(st, 1);
}
} else {
EnumMap<StorageType, Integer> currentCount =
childrenStorageInfo.get(parentNode.getName());
for (StorageType st : dnDescriptor.getStorageTypes()) {
if (currentCount.containsKey(st)) {
currentCount.put(st, currentCount.get(st) + 1);
} else {
currentCount.put(st, 1);
}
}
}
}
return true;
} else {
return false;
}
}
}
@VisibleForTesting
HashMap <String, EnumMap<StorageType, Integer>> getChildrenStorageInfo() {
return childrenStorageInfo;
}
private DFSTopologyNodeImpl createParentNode(String parentName) {
return new DFSTopologyNodeImpl(
parentName, getPath(this), this, this.getLevel() + 1);
}
@Override
public boolean remove(Node n) {
if (!isAncestor(n)) {
throw new IllegalArgumentException(n.getName()
+ ", which is located at " + n.getNetworkLocation()
+ ", is not a descendant of " + getPath(this));
}
// In HDFS topology, the leaf node should always be DatanodeDescriptor
if (!(n instanceof DatanodeDescriptor)) {
throw new IllegalArgumentException("Unexpected node type "
+ n.getClass().getName());
}
DatanodeDescriptor dnDescriptor = (DatanodeDescriptor) n;
if (isParent(n)) {
// this node is the parent of n; remove n directly
if (childrenMap.containsKey(n.getName())) {
for (int i=0; i<children.size(); i++) {
if (children.get(i).getName().equals(n.getName())) {
children.remove(i);
childrenMap.remove(n.getName());
synchronized (childrenStorageInfo) {
childrenStorageInfo.remove(dnDescriptor.getName());
}
numOfLeaves--;
n.setParent(null);
return true;
}
}
}
return false;
} else {
// find the next ancestor node: the parent node
String parentName = getNextAncestorName(n);
DFSTopologyNodeImpl parentNode =
(DFSTopologyNodeImpl)childrenMap.get(parentName);
if (parentNode == null) {
return false;
}
// remove n from the parent node
boolean isRemoved = parentNode.remove(n);
if (isRemoved) {
// if the parent node has no children, remove the parent node too
synchronized (childrenStorageInfo) {
EnumMap<StorageType, Integer> currentCount =
childrenStorageInfo.get(parentNode.getName());
EnumSet<StorageType> toRemove = EnumSet.noneOf(StorageType.class);
for (StorageType st : dnDescriptor.getStorageTypes()) {
int newCount = currentCount.get(st) - 1;
if (newCount == 0) {
toRemove.add(st);
}
currentCount.put(st, newCount);
}
for (StorageType st : toRemove) {
currentCount.remove(st);
}
}
if (parentNode.getNumOfChildren() == 0) {
for(int i=0; i < children.size(); i++) {
if (children.get(i).getName().equals(parentName)) {
children.remove(i);
childrenMap.remove(parentName);
childrenStorageInfo.remove(parentNode.getName());
break;
}
}
}
numOfLeaves--;
}
return isRemoved;
}
}
}

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@ -1268,7 +1268,7 @@ public class TestBlockStoragePolicy {
} }
FileSystem.setDefaultUri(conf, "hdfs://localhost:0"); FileSystem.setDefaultUri(conf, "hdfs://localhost:0");
conf.set(DFSConfigKeys.DFS_NAMENODE_HTTP_ADDRESS_KEY, "0.0.0.0:0"); conf.set(DFSConfigKeys.DFS_NAMENODE_HTTP_ADDRESS_KEY, "0.0.0.0:0");
File baseDir = PathUtils.getTestDir(TestReplicationPolicy.class); File baseDir = PathUtils.getTestDir(TestReplicationPolicy.class);
conf.set(DFSConfigKeys.DFS_NAMENODE_NAME_DIR_KEY, conf.set(DFSConfigKeys.DFS_NAMENODE_NAME_DIR_KEY,
new File(baseDir, "name").getPath()); new File(baseDir, "name").getPath());

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@ -0,0 +1,260 @@
/**
* 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;
import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;
import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.fs.StorageType;
import org.apache.hadoop.hdfs.server.blockmanagement.DatanodeDescriptor;
import org.apache.hadoop.hdfs.server.blockmanagement.DatanodeStorageInfo;
import org.junit.Before;
import org.junit.Rule;
import org.junit.Test;
import org.junit.rules.Timeout;
import java.util.EnumMap;
import java.util.HashMap;
import static org.junit.Assert.assertEquals;
import static org.junit.Assert.assertNull;
import static org.junit.Assert.assertTrue;
/**
* This class tests the correctness of storage type info stored in
* DFSNetworkTopology.
*/
public class TestDFSNetworkTopology {
private static final Log LOG =
LogFactory.getLog(TestDFSNetworkTopology.class);
private final static DFSNetworkTopology CLUSTER =
DFSNetworkTopology.getInstance(new Configuration());
private DatanodeDescriptor[] dataNodes;
@Rule
public Timeout testTimeout = new Timeout(30000);
@Before
public void setupDatanodes() {
final String[] racks = {
"/l1/d1/r1", "/l1/d1/r1", "/l1/d1/r2", "/l1/d1/r2", "/l1/d1/r2",
"/l1/d2/r3", "/l1/d2/r3", "/l1/d2/r3",
"/l2/d3/r1", "/l2/d3/r2", "/l2/d3/r3", "/l2/d3/r4", "/l2/d3/r5",
"/l2/d4/r1", "/l2/d4/r1", "/l2/d4/r1", "/l2/d4/r1", "/l2/d4/r1",
"/l2/d4/r1", "/l2/d4/r1"};
final String[] hosts = {
"host1", "host2", "host3", "host4", "host5",
"host6", "host7", "host8", "host9", "host10",
"host11", "host12", "host13", "host14", "host15",
"host16", "host17", "host18", "host19", "host20"};
final StorageType[] types = {
StorageType.ARCHIVE, StorageType.DISK, StorageType.ARCHIVE,
StorageType.DISK, StorageType.DISK,
StorageType.DISK, StorageType.RAM_DISK, StorageType.SSD,
StorageType.DISK, StorageType.RAM_DISK, StorageType.DISK,
StorageType.ARCHIVE, StorageType.ARCHIVE,
StorageType.DISK, StorageType.DISK, StorageType.RAM_DISK,
StorageType.RAM_DISK, StorageType.ARCHIVE, StorageType.ARCHIVE,
StorageType.SSD};
final DatanodeStorageInfo[] storages =
DFSTestUtil.createDatanodeStorageInfos(20, racks, hosts, types);
dataNodes = DFSTestUtil.toDatanodeDescriptor(storages);
for (int i = 0; i < dataNodes.length; i++) {
CLUSTER.add(dataNodes[i]);
}
dataNodes[9].setDecommissioned();
dataNodes[10].setDecommissioned();
}
/**
* Test getting the storage type info of subtree.
* @throws Exception
*/
@Test
public void testGetStorageTypeInfo() throws Exception {
// checking level = 2 nodes
DFSTopologyNodeImpl d1 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1/d1");
HashMap<String, EnumMap<StorageType, Integer>> d1info =
d1.getChildrenStorageInfo();
assertEquals(2, d1info.keySet().size());
assertTrue(d1info.get("r1").size() == 2 && d1info.get("r2").size() == 2);
assertEquals(1, (int)d1info.get("r1").get(StorageType.DISK));
assertEquals(1, (int)d1info.get("r1").get(StorageType.ARCHIVE));
assertEquals(2, (int)d1info.get("r2").get(StorageType.DISK));
assertEquals(1, (int)d1info.get("r2").get(StorageType.ARCHIVE));
DFSTopologyNodeImpl d2 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1/d2");
HashMap<String, EnumMap<StorageType, Integer>> d2info =
d2.getChildrenStorageInfo();
assertEquals(1, d2info.keySet().size());
assertTrue(d2info.get("r3").size() == 3);
assertEquals(1, (int)d2info.get("r3").get(StorageType.DISK));
assertEquals(1, (int)d2info.get("r3").get(StorageType.RAM_DISK));
assertEquals(1, (int)d2info.get("r3").get(StorageType.SSD));
DFSTopologyNodeImpl d3 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l2/d3");
HashMap<String, EnumMap<StorageType, Integer>> d3info =
d3.getChildrenStorageInfo();
assertEquals(5, d3info.keySet().size());
assertEquals(1, (int)d3info.get("r1").get(StorageType.DISK));
assertEquals(1, (int)d3info.get("r2").get(StorageType.RAM_DISK));
assertEquals(1, (int)d3info.get("r3").get(StorageType.DISK));
assertEquals(1, (int)d3info.get("r4").get(StorageType.ARCHIVE));
assertEquals(1, (int)d3info.get("r5").get(StorageType.ARCHIVE));
DFSTopologyNodeImpl d4 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l2/d4");
HashMap<String, EnumMap<StorageType, Integer>> d4info =
d4.getChildrenStorageInfo();
assertEquals(1, d4info.keySet().size());
assertEquals(2, (int)d4info.get("r1").get(StorageType.DISK));
assertEquals(2, (int)d4info.get("r1").get(StorageType.RAM_DISK));
assertEquals(2, (int)d4info.get("r1").get(StorageType.ARCHIVE));
assertEquals(1, (int)d4info.get("r1").get(StorageType.SSD));
DFSTopologyNodeImpl l1 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1");
HashMap<String, EnumMap<StorageType, Integer>> l1info =
l1.getChildrenStorageInfo();
assertEquals(2, l1info.keySet().size());
assertTrue(l1info.get("d1").size() == 2
&& l1info.get("d2").size() == 3);
assertEquals(2, (int)l1info.get("d1").get(StorageType.ARCHIVE));
assertEquals(3, (int)l1info.get("d1").get(StorageType.DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.RAM_DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.SSD));
// checking level = 1 nodes
DFSTopologyNodeImpl l2 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l2");
HashMap<String, EnumMap<StorageType, Integer>> l2info =
l2.getChildrenStorageInfo();
assertTrue(l2info.get("d3").size() == 3
&& l2info.get("d4").size() == 4);
assertEquals(2, l2info.keySet().size());
assertEquals(2, (int)l2info.get("d3").get(StorageType.DISK));
assertEquals(2, (int)l2info.get("d3").get(StorageType.ARCHIVE));
assertEquals(1, (int)l2info.get("d3").get(StorageType.RAM_DISK));
assertEquals(2, (int)l2info.get("d4").get(StorageType.DISK));
assertEquals(2, (int)l2info.get("d4").get(StorageType.ARCHIVE));
assertEquals(2, (int)l2info.get("d4").get(StorageType.RAM_DISK));
assertEquals(1, (int)l2info.get("d4").get(StorageType.SSD));
}
/**
* Test the correctness of storage type info when nodes are added and removed.
* @throws Exception
*/
@Test
public void testAddAndRemoveTopology() throws Exception {
String[] newRack = {"/l1/d1/r1", "/l1/d1/r3", "/l1/d3/r3", "/l1/d3/r3"};
String[] newHost = {"nhost1", "nhost2", "nhost3", "nhost4"};
String[] newips = {"30.30.30.30", "31.31.31.31", "32.32.32.32",
"33.33.33.33"};
StorageType[] newTypes = {StorageType.DISK, StorageType.SSD,
StorageType.SSD, StorageType.SSD};
DatanodeDescriptor[] newDD = new DatanodeDescriptor[4];
for (int i = 0; i<4; i++) {
DatanodeStorageInfo dsi = DFSTestUtil.createDatanodeStorageInfo(
"s" + newHost[i], newips[i], newRack[i], newHost[i],
newTypes[i], null);
newDD[i] = dsi.getDatanodeDescriptor();
CLUSTER.add(newDD[i]);
}
DFSTopologyNodeImpl d1 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1/d1");
HashMap<String, EnumMap<StorageType, Integer>> d1info =
d1.getChildrenStorageInfo();
assertEquals(3, d1info.keySet().size());
assertTrue(d1info.get("r1").size() == 2 && d1info.get("r2").size() == 2
&& d1info.get("r3").size() == 1);
assertEquals(2, (int)d1info.get("r1").get(StorageType.DISK));
assertEquals(1, (int)d1info.get("r1").get(StorageType.ARCHIVE));
assertEquals(2, (int)d1info.get("r2").get(StorageType.DISK));
assertEquals(1, (int)d1info.get("r2").get(StorageType.ARCHIVE));
assertEquals(1, (int)d1info.get("r3").get(StorageType.SSD));
DFSTopologyNodeImpl d3 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1/d3");
HashMap<String, EnumMap<StorageType, Integer>> d3info =
d3.getChildrenStorageInfo();
assertEquals(1, d3info.keySet().size());
assertTrue(d3info.get("r3").size() == 1);
assertEquals(2, (int)d3info.get("r3").get(StorageType.SSD));
DFSTopologyNodeImpl l1 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1");
HashMap<String, EnumMap<StorageType, Integer>> l1info =
l1.getChildrenStorageInfo();
assertEquals(3, l1info.keySet().size());
assertTrue(l1info.get("d1").size() == 3 &&
l1info.get("d2").size() == 3 && l1info.get("d3").size() == 1);
assertEquals(4, (int)l1info.get("d1").get(StorageType.DISK));
assertEquals(2, (int)l1info.get("d1").get(StorageType.ARCHIVE));
assertEquals(1, (int)l1info.get("d1").get(StorageType.SSD));
assertEquals(1, (int)l1info.get("d2").get(StorageType.SSD));
assertEquals(1, (int)l1info.get("d2").get(StorageType.RAM_DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.DISK));
assertEquals(2, (int)l1info.get("d3").get(StorageType.SSD));
for (int i = 0; i<4; i++) {
CLUSTER.remove(newDD[i]);
}
// /d1/r3 should've been out, /d1/r1 should've been resumed
DFSTopologyNodeImpl nd1 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1/d1");
HashMap<String, EnumMap<StorageType, Integer>> nd1info =
nd1.getChildrenStorageInfo();
assertEquals(2, nd1info.keySet().size());
assertTrue(nd1info.get("r1").size() == 2 && nd1info.get("r2").size() == 2);
assertEquals(1, (int)nd1info.get("r1").get(StorageType.DISK));
assertEquals(1, (int)nd1info.get("r1").get(StorageType.ARCHIVE));
assertEquals(2, (int)nd1info.get("r2").get(StorageType.DISK));
assertEquals(1, (int)nd1info.get("r2").get(StorageType.ARCHIVE));
// /l1/d3 should've been out, and /l1/d1 should've been resumed
DFSTopologyNodeImpl nl1 =
(DFSTopologyNodeImpl) CLUSTER.getNode("/l1");
HashMap<String, EnumMap<StorageType, Integer>> nl1info =
nl1.getChildrenStorageInfo();
assertEquals(2, nl1info.keySet().size());
assertTrue(l1info.get("d1").size() == 2
&& l1info.get("d2").size() == 3);
assertEquals(2, (int)nl1info.get("d1").get(StorageType.ARCHIVE));
assertEquals(3, (int)nl1info.get("d1").get(StorageType.DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.RAM_DISK));
assertEquals(1, (int)l1info.get("d2").get(StorageType.SSD));
assertNull(CLUSTER.getNode("/l1/d3"));
}
}

View File

@ -47,7 +47,8 @@ import org.junit.rules.Timeout;
public class TestNetworkTopology { public class TestNetworkTopology {
private static final Log LOG = LogFactory.getLog(TestNetworkTopology.class); private static final Log LOG = LogFactory.getLog(TestNetworkTopology.class);
private final static NetworkTopology cluster = new NetworkTopology(); private final static NetworkTopology cluster =
NetworkTopology.getInstance(new Configuration());
private DatanodeDescriptor dataNodes[]; private DatanodeDescriptor dataNodes[];
@Rule @Rule
@ -101,7 +102,8 @@ public class TestNetworkTopology {
@Test @Test
public void testCreateInvalidTopology() throws Exception { public void testCreateInvalidTopology() throws Exception {
NetworkTopology invalCluster = new NetworkTopology(); NetworkTopology invalCluster =
NetworkTopology.getInstance(new Configuration());
DatanodeDescriptor invalDataNodes[] = new DatanodeDescriptor[] { DatanodeDescriptor invalDataNodes[] = new DatanodeDescriptor[] {
DFSTestUtil.getDatanodeDescriptor("1.1.1.1", "/d1/r1"), DFSTestUtil.getDatanodeDescriptor("1.1.1.1", "/d1/r1"),
DFSTestUtil.getDatanodeDescriptor("2.2.2.2", "/d1/r1"), DFSTestUtil.getDatanodeDescriptor("2.2.2.2", "/d1/r1"),