Java tutorial
/** * * 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 com.alibaba.wasp.zookeeper; import org.apache.commons.logging.Log; import org.apache.commons.logging.LogFactory; import org.apache.hadoop.hbase.util.Bytes; import org.apache.hadoop.hbase.util.RetryCounter; import org.apache.hadoop.hbase.util.RetryCounterFactory; import org.apache.zookeeper.AsyncCallback; import org.apache.zookeeper.CreateMode; import org.apache.zookeeper.KeeperException; import org.apache.zookeeper.Watcher; import org.apache.zookeeper.ZooKeeper; import org.apache.zookeeper.ZooKeeper.States; import org.apache.zookeeper.data.ACL; import org.apache.zookeeper.data.Stat; import java.io.IOException; import java.lang.management.ManagementFactory; import java.security.SecureRandom; import java.util.ArrayList; import java.util.List; import java.util.Random; /** * A zookeeper that can handle 'recoverable' errors. To handle recoverable * errors, developers need to realize that there are two classes of requests: * idempotent and non-idempotent requests. Read requests and unconditional sets * and deletes are examples of idempotent requests, they can be reissued with * the same results. (Although, the delete may throw a NoNodeException on * reissue its effect on the ZooKeeper state is the same.) Non-idempotent * requests need special handling, application and library writers need to keep * in mind that they may need to encode information in the data or name of * znodes to detect retries. A simple example is a create that uses a sequence * flag. If a process issues a create("/x-", ..., SEQUENCE) and gets a * connection loss exception, that process will reissue another create("/x-", * ..., SEQUENCE) and get back x-111. When the process does a getChildren("/"), * it sees x-1,x-30,x-109,x-110,x-111, now it could be that x-109 was the result * of the previous create, so the process actually owns both x-109 and x-111. An * easy way around this is to use "x-process id-" when doing the create. If the * process is using an id of 352, before reissuing the create it will do a * getChildren("/") and see "x-222-1", "x-542-30", "x-352-109", x-333-110". The * process will know that the original create succeeded an the znode it created * is "x-352-109". * @see "http://wiki.apache.org/hadoop/ZooKeeper/ErrorHandling" */ public class RecoverableZooKeeper { private static final Log LOG = LogFactory.getLog(RecoverableZooKeeper.class); // the actual ZooKeeper client instance private ZooKeeper zk; private final RetryCounterFactory retryCounterFactory; // An identifier of this process in the cluster private final String identifier; private final byte[] id; private Watcher watcher; private int sessionTimeout; private String quorumServers; private final Random salter; // The metadata attached to each piece of data has the // format: // <magic> 1-byte constant // <id length> 4-byte big-endian integer (length of next field) // <id> identifier corresponding uniquely to this process // It is prepended to the data supplied by the user. // the magic number is to be backward compatible private static final byte MAGIC = (byte) 0XFF; private static final int MAGIC_SIZE = Bytes.SIZEOF_BYTE; private static final int ID_LENGTH_OFFSET = MAGIC_SIZE; private static final int ID_LENGTH_SIZE = Bytes.SIZEOF_INT; public RecoverableZooKeeper(String quorumServers, int sessionTimeout, Watcher watcher, int maxRetries, int retryIntervalMillis) throws IOException { this.zk = new ZooKeeper(quorumServers, sessionTimeout, watcher); this.retryCounterFactory = new RetryCounterFactory(maxRetries, retryIntervalMillis); // the identifier = processID@hostName this.identifier = ManagementFactory.getRuntimeMXBean().getName(); LOG.info("The identifier of this process is " + identifier); this.id = Bytes.toBytes(identifier); this.watcher = watcher; this.sessionTimeout = sessionTimeout; this.quorumServers = quorumServers; salter = new SecureRandom(); } public void reconnectAfterExpiration() throws IOException, InterruptedException { LOG.info("Closing dead ZooKeeper connection, session" + " was: 0x" + Long.toHexString(zk.getSessionId())); zk.close(); this.zk = new ZooKeeper(this.quorumServers, this.sessionTimeout, this.watcher); LOG.info("Recreated a ZooKeeper, session" + " is: 0x" + Long.toHexString(zk.getSessionId())); } /** * delete is an idempotent operation. Retry before throwing exception. This * function will not throw NoNodeException if the path does not exist. */ public void delete(String path, int version) throws InterruptedException, KeeperException { RetryCounter retryCounter = retryCounterFactory.create(); boolean isRetry = false; // False for first attempt, true for all retries. while (true) { try { zk.delete(path, version); return; } catch (KeeperException e) { switch (e.code()) { case NONODE: if (isRetry) { LOG.info("Node " + path + " already deleted. Assuming a " + "previous attempt succeeded."); return; } LOG.warn("Node " + path + " already deleted, retry=" + isRetry); throw e; case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "delete"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); isRetry = true; } } /** * exists is an idempotent operation. Retry before throwing exception * @return A Stat instance */ public Stat exists(String path, Watcher watcher) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); while (true) { try { return zk.exists(path, watcher); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "exists"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } /** * exists is an idempotent operation. Retry before throwing exception * @return A Stat instance */ public Stat exists(String path, boolean watch) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); while (true) { try { return zk.exists(path, watch); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "exists"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } private void retryOrThrow(RetryCounter retryCounter, KeeperException e, String opName) throws KeeperException { LOG.warn("Possibly transient ZooKeeper exception: " + e); if (!retryCounter.shouldRetry()) { LOG.error("ZooKeeper " + opName + " failed after " + retryCounter.getMaxRetries() + " retries"); throw e; } } /** * getChildren is an idempotent operation. Retry before throwing exception * @return List of children znodes */ public List<String> getChildren(String path, Watcher watcher) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); while (true) { try { return zk.getChildren(path, watcher); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "getChildren"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } /** * getChildren is an idempotent operation. Retry before throwing exception * @return List of children znodes */ public List<String> getChildren(String path, boolean watch) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); while (true) { try { return zk.getChildren(path, watch); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "getChildren"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } /** * getData is an idempotent operation. Retry before throwing exception * @return Data */ public byte[] getData(String path, Watcher watcher, Stat stat) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); while (true) { try { byte[] revData = zk.getData(path, watcher, stat); return this.removeMetaData(revData); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "getData"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } /** * getData is an idemnpotent operation. Retry before throwing exception * @return Data */ public byte[] getData(String path, boolean watch, Stat stat) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); while (true) { try { byte[] revData = zk.getData(path, watch, stat); return this.removeMetaData(revData); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "getData"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } /** * setData is NOT an idempotent operation. Retry may cause BadVersion * Exception Adding an identifier field into the data to check whether * badversion is caused by the result of previous correctly setData * @return Stat instance */ public Stat setData(String path, byte[] data, int version) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); byte[] newData = appendMetaData(data); boolean isRetry = false; while (true) { try { return zk.setData(path, newData, version); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "setData"); break; case BADVERSION: if (isRetry) { // try to verify whether the previous setData success or not try { Stat stat = new Stat(); byte[] revData = zk.getData(path, false, stat); if (Bytes.compareTo(revData, newData) == 0) { // the bad version is caused by previous successful setData return stat; } } catch (KeeperException keeperException) { // the ZK is not reliable at this moment. just throwing // exception throw keeperException; } } // throw other exceptions and verified bad version exceptions default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); isRetry = true; } } /** * <p> * NONSEQUENTIAL create is idempotent operation. Retry before throwing * exceptions. But this function will not throw the NodeExist exception back * to the application. * </p> * <p> * But SEQUENTIAL is NOT idempotent operation. It is necessary to add * identifier to the path to verify, whether the previous one is successful or * not. * </p> * * @return Path */ public String create(String path, byte[] data, List<ACL> acl, CreateMode createMode) throws KeeperException, InterruptedException { byte[] newData = appendMetaData(data); switch (createMode) { case EPHEMERAL: case PERSISTENT: return createNonSequential(path, newData, acl, createMode); case EPHEMERAL_SEQUENTIAL: case PERSISTENT_SEQUENTIAL: return createSequential(path, newData, acl, createMode); default: throw new IllegalArgumentException("Unrecognized CreateMode: " + createMode); } } private String createNonSequential(String path, byte[] data, List<ACL> acl, CreateMode createMode) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); boolean isRetry = false; // False for first attempt, true for all retries. while (true) { try { return zk.create(path, data, acl, createMode); } catch (KeeperException e) { switch (e.code()) { case NODEEXISTS: if (isRetry) { // If the connection was lost, there is still a possibility that // we have successfully created the node at our previous attempt, // so we read the node and compare. byte[] currentData = zk.getData(path, false, null); if (currentData != null && Bytes.compareTo(currentData, data) == 0) { // We successfully created a non-sequential node return path; } LOG.error("Node " + path + " already exists with " + Bytes.toStringBinary(currentData) + ", could not write " + Bytes.toStringBinary(data)); throw e; } LOG.error("Node " + path + " already exists and this is not a " + "retry"); throw e; case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "create"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); isRetry = true; } } private String createSequential(String path, byte[] data, List<ACL> acl, CreateMode createMode) throws KeeperException, InterruptedException { RetryCounter retryCounter = retryCounterFactory.create(); boolean first = true; String newPath = path + this.identifier; while (true) { try { if (!first) { // Check if we succeeded on a previous attempt String previousResult = findPreviousSequentialNode(newPath); if (previousResult != null) { return previousResult; } } first = false; return zk.create(newPath, data, acl, createMode); } catch (KeeperException e) { switch (e.code()) { case CONNECTIONLOSS: case SESSIONEXPIRED: case OPERATIONTIMEOUT: retryOrThrow(retryCounter, e, "create"); break; default: throw e; } } retryCounter.sleepUntilNextRetry(); retryCounter.useRetry(); } } private String findPreviousSequentialNode(String path) throws KeeperException, InterruptedException { int lastSlashIdx = path.lastIndexOf('/'); assert (lastSlashIdx != -1); String parent = path.substring(0, lastSlashIdx); String nodePrefix = path.substring(lastSlashIdx + 1); List<String> nodes = zk.getChildren(parent, false); List<String> matching = filterByPrefix(nodes, nodePrefix); for (String node : matching) { String nodePath = parent + "/" + node; Stat stat = zk.exists(nodePath, false); if (stat != null) { return nodePath; } } return null; } public byte[] removeMetaData(byte[] data) { if (data == null || data.length == 0) { return data; } // check the magic data; to be backward compatible byte magic = data[0]; if (magic != MAGIC) { return data; } int idLength = Bytes.toInt(data, ID_LENGTH_OFFSET); int dataLength = data.length - MAGIC_SIZE - ID_LENGTH_SIZE - idLength; int dataOffset = MAGIC_SIZE + ID_LENGTH_SIZE + idLength; byte[] newData = new byte[dataLength]; System.arraycopy(data, dataOffset, newData, 0, dataLength); return newData; } private byte[] appendMetaData(byte[] data) { if (data == null || data.length == 0) { return data; } byte[] salt = Bytes.toBytes(salter.nextLong()); int idLength = id.length + salt.length; byte[] newData = new byte[MAGIC_SIZE + ID_LENGTH_SIZE + idLength + data.length]; int pos = 0; pos = Bytes.putByte(newData, pos, MAGIC); pos = Bytes.putInt(newData, pos, idLength); pos = Bytes.putBytes(newData, pos, id, 0, id.length); pos = Bytes.putBytes(newData, pos, salt, 0, salt.length); pos = Bytes.putBytes(newData, pos, data, 0, data.length); return newData; } public long getSessionId() { return zk.getSessionId(); } public void close() throws InterruptedException { zk.close(); } public States getState() { return zk.getState(); } public ZooKeeper getZooKeeper() { return zk; } public byte[] getSessionPasswd() { return zk.getSessionPasswd(); } public void sync(String path, AsyncCallback.VoidCallback cb, Object ctx) { this.zk.sync(path, null, null); } /** * Filters the given node list by the given prefixes. This method is * all-inclusive--if any element in the node list starts with any of the given * prefixes, then it is included in the result. * * @param nodes the nodes to filter * @param prefixes the prefixes to include in the result * @return list of every element that starts with one of the prefixes */ private static List<String> filterByPrefix(List<String> nodes, String... prefixes) { List<String> lockChildren = new ArrayList<String>(); for (String child : nodes) { for (String prefix : prefixes) { if (child.startsWith(prefix)) { lockChildren.add(child); break; } } } return lockChildren; } }