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背景

前段时间我们的集群在写入block时有如下报错:

Caused by: org.apache.hadoop.hive.ql.metadata.HiveException: org.apache.hadoop.ipc.RemoteException(java.io.IOException): 
File /tmp/xxxx.tmp could only be replicated to 0 nodes instead of minReplication (=1).  
There are 983 datanode(s) running and 983 node(s) are excluded in this operation.

虽然集群容量确实使用到了百分之九十多,但也不至于近千个节点全部都满了,所以看了一下相关代码,也总结了一下Hadoop的副本存放策略,我们这个集群使用的hadoop版本是2.6

HDFS副本存放策略

  • 1st replica 如果写请求client所在机器是其中一个datanode,则直接存放在本地,否则随机在集群中选择一个datanode.
  • 2nd replica 第二个副本存放于不同第一个副本的所在的机架.
  • 3rd replica 第三个副本存放于第二个副本所在的机架,但是属于不同的节点
  • 4rd replica 第四个副本或更多副本随机选择datanode节点进行存储

在这里插入图片描述

源码分析

BlockManager.java
可以看到以上的报错就是下面这个方法,接下来看chooseTarget方法

/**
   * Choose target datanodes for creating a new block.
   * 
   * @throws IOException
   *           if the number of targets < minimum replication.
   * @see BlockPlacementPolicy#chooseTarget(String, int, Node,
   *      Set, long, List, BlockStoragePolicy)
   */
  public DatanodeStorageInfo[] chooseTarget4NewBlock(final String src,
      final int numOfReplicas, final Node client,
      final Set<Node> excludedNodes,
      final long blocksize,
      final List<String> favoredNodes,
      final byte storagePolicyID) throws IOException {
    List<DatanodeDescriptor> favoredDatanodeDescriptors = 
        getDatanodeDescriptors(favoredNodes);
    final BlockStoragePolicy storagePolicy = storagePolicySuite.getPolicy(storagePolicyID);
    // 调用blockplacement的chooseTarget方法
    final DatanodeStorageInfo[] targets = blockplacement.chooseTarget(src,
        numOfReplicas, client, excludedNodes, blocksize, 
        favoredDatanodeDescriptors, storagePolicy);
    // 选择的目标节点数量不足,则会抛出IO异常
    if (targets.length < minReplication) {
      throw new IOException("File " + src + " could only be replicated to "
          + targets.length + " nodes instead of minReplication (="
          + minReplication + ").  There are "
          + getDatanodeManager().getNetworkTopology().getNumOfLeaves()
          + " datanode(s) running and "
          + (excludedNodes == null? "no": excludedNodes.size())
          + " node(s) are excluded in this operation.");
    }
    return targets;
  }

BlockPlacementPolicyDefault.java

  /** This is the implementation. */
  private DatanodeStorageInfo[] chooseTarget(int numOfReplicas,
                                    Node writer,
                                    List<DatanodeStorageInfo> chosenStorage,
                                    boolean returnChosenNodes,
                                    Set<Node> excludedNodes,
                                    long blocksize,
                                    final BlockStoragePolicy storagePolicy) {
    // 副本数为0或datanode数量为0,返回空数组
    if (numOfReplicas == 0 || clusterMap.getNumOfLeaves()==0) {
      return DatanodeStorageInfo.EMPTY_ARRAY;
    }
    // 初始化排除节点列表
    if (excludedNodes == null) {
      excludedNodes = new HashSet<Node>();
    }
    // 计算每个机架允许分配的最大副本数
    int[] result = getMaxNodesPerRack(chosenStorage.size(), numOfReplicas);
    numOfReplicas = result[0];
    int maxNodesPerRack = result[1];
    // 初始化结果节点列表
    final List<DatanodeStorageInfo> results = new ArrayList<DatanodeStorageInfo>(chosenStorage);
    for (DatanodeStorageInfo storage : chosenStorage) {
      // add localMachine and related nodes to excludedNodes
      addToExcludedNodes(storage.getDatanodeDescriptor(), excludedNodes);
    }

    boolean avoidStaleNodes = (stats != null
        && stats.isAvoidingStaleDataNodesForWrite());
    // 调用chooseTarget方法选择节点
    final Node localNode = chooseTarget(numOfReplicas, writer, excludedNodes,
        blocksize, maxNodesPerRack, results, avoidStaleNodes, storagePolicy,
        EnumSet.noneOf(StorageType.class), results.isEmpty());
    if (!returnChosenNodes) {  
      results.removeAll(chosenStorage);
    }
      
    // sorting nodes to form a pipeline
    return getPipeline(
        (writer != null && writer instanceof DatanodeDescriptor) ? writer
            : localNode,
        results.toArray(new DatanodeStorageInfo[results.size()]));
  }

getMaxNodesPerRack方法(Calculate the maximum number of replicas to allocate per rack.)

  private int[] getMaxNodesPerRack(int numOfChosen, int numOfReplicas) {
    int clusterSize = clusterMap.getNumOfLeaves();
    int totalNumOfReplicas = numOfChosen + numOfReplicas;
    if (totalNumOfReplicas > clusterSize) {
      numOfReplicas -= (totalNumOfReplicas-clusterSize);
      totalNumOfReplicas = clusterSize;
    }
    // No calculation needed when there is only one rack or picking one node.
    int numOfRacks = clusterMap.getNumOfRacks();
    if (numOfRacks == 1 || totalNumOfReplicas <= 1) {
      return new int[] {numOfReplicas, totalNumOfReplicas};
    }

    int maxNodesPerRack = (totalNumOfReplicas-1)/numOfRacks + 2;
    // At this point, there are more than one racks and more than one replicas
    // to store. Avoid all replicas being in the same rack.
    //
    // maxNodesPerRack has the following properties at this stage.
    //   1) maxNodesPerRack >= 2
    //   2) (maxNodesPerRack-1) * numOfRacks > totalNumOfReplicas
    //          when numOfRacks > 1
    //
    // Thus, the following adjustment will still result in a value that forces
    // multi-rack allocation and gives enough number of total nodes.
    if (maxNodesPerRack == totalNumOfReplicas) {
      maxNodesPerRack--;
    }
    return new int[] {numOfReplicas, maxNodesPerRack};
  }

chooseTarget方法,这里就是最主要的选择逻辑

  private Node chooseTarget(int numOfReplicas,
                            Node writer,
                            final Set<Node> excludedNodes,
                            final long blocksize,
                            final int maxNodesPerRack,
                            final List<DatanodeStorageInfo> results,
                            final boolean avoidStaleNodes,
                            final BlockStoragePolicy storagePolicy,
                            final EnumSet<StorageType> unavailableStorages,
                            final boolean newBlock) {
    // 如果额外需要请求副本数为0,或者集群中没有可选节点
    if (numOfReplicas == 0 || clusterMap.getNumOfLeaves()==0) {
      // 如果writer是datanode则直接返回writer,否则返回null
      return (writer instanceof DatanodeDescriptor) ? writer : null;
    }
    // 已经选择完成的节点数
    final int numOfResults = results.size();
    // 期望达到的副本总数
    final int totalReplicasExpected = numOfReplicas + numOfResults;
    // 如果writer为空或不是datanode且不是新的block,则取出已选择节点列表中的第一个,赋值给writer
    if ((writer == null || !(writer instanceof DatanodeDescriptor)) && !newBlock) {
      writer = results.get(0).getDatanodeDescriptor();
    }

    // Keep a copy of original excludedNodes
    final Set<Node> oldExcludedNodes = new HashSet<Node>(excludedNodes);

    // choose storage types; use fallbacks for unavailable storages
    final List<StorageType> requiredStorageTypes = storagePolicy
        .chooseStorageTypes((short) totalReplicasExpected,
            DatanodeStorageInfo.toStorageTypes(results),
            unavailableStorages, newBlock);
    final EnumMap<StorageType, Integer> storageTypes =
        getRequiredStorageTypes(requiredStorageTypes);
    if (LOG.isTraceEnabled()) {
      LOG.trace("storageTypes=" + storageTypes);
    }

    try {
      // 如果请求的存储类型列表为空,则抛出异常
      if ((numOfReplicas = requiredStorageTypes.size()) == 0) {
        throw new NotEnoughReplicasException(
            "All required storage types are unavailable: "
            + " unavailableStorages=" + unavailableStorages
            + ", storagePolicy=" + storagePolicy);
      }
      //如果numOfResults == 0 则表示副本一个都还没开始选,首先从选本地节点开始
      if (numOfResults == 0) {
        // 选择本地存储作为第一个节点
        writer = chooseLocalStorage(writer, excludedNodes, blocksize,
            maxNodesPerRack, results, avoidStaleNodes, storageTypes, true)
                .getDatanodeDescriptor();
        // 如果此时需求的副本数为降为0,代表选择目标完成,返回第一个节点writer
        if (--numOfReplicas == 0) {
          return writer;
        }
      }
      // 取出第一个选好的节点
      final DatanodeDescriptor dn0 = results.get(0).getDatanodeDescriptor();
      if (numOfResults <= 1) {
        // 选择与第一个节点不同机架的节点
        chooseRemoteRack(1, dn0, excludedNodes, blocksize, maxNodesPerRack,
            results, avoidStaleNodes, storageTypes);
        if (--numOfReplicas == 0) {
          return writer;
        }
      }
      if (numOfResults <= 2) {
        // 取出第二个选好的节点
        final DatanodeDescriptor dn1 = results.get(1).getDatanodeDescriptor();
        if (clusterMap.isOnSameRack(dn0, dn1)) {
          // 如果第一个节点和第二个节点在同一个机架,则在另一个机架选第三个节点
          chooseRemoteRack(1, dn0, excludedNodes, blocksize, maxNodesPerRack,
              results, avoidStaleNodes, storageTypes);
        } else if (newBlock){
          // 第一个节点和第二个节点不在一个机架,且是新block,则在第二个节点所在机架选第三个节点
          chooseLocalRack(dn1, excludedNodes, blocksize, maxNodesPerRack,
              results, avoidStaleNodes, storageTypes);
        } else {
          // 在本地机架选节点
          chooseLocalRack(writer, excludedNodes, blocksize, maxNodesPerRack,
              results, avoidStaleNodes, storageTypes);
        }
        if (--numOfReplicas == 0) {
          return writer;
        }
      }
      // 如果副本数超过3个,则剩下的随机选节点
      chooseRandom(numOfReplicas, NodeBase.ROOT, excludedNodes, blocksize,
          maxNodesPerRack, results, avoidStaleNodes, storageTypes);
    } catch (NotEnoughReplicasException e) {
      final String message = "Failed to place enough replicas, still in need of "
          + (totalReplicasExpected - results.size()) + " to reach "
          + totalReplicasExpected
          + " (unavailableStorages=" + unavailableStorages
          + ", storagePolicy=" + storagePolicy
          + ", newBlock=" + newBlock + ")";

      if (LOG.isTraceEnabled()) {
        LOG.trace(message, e);
      } else {
        LOG.warn(message + " " + e.getMessage());
      }

      if (avoidStaleNodes) {
        // Retry chooseTarget again, this time not avoiding stale nodes.

        // excludedNodes contains the initial excludedNodes and nodes that were
        // not chosen because they were stale, decommissioned, etc.
        // We need to additionally exclude the nodes that were added to the 
        // result list in the successful calls to choose*() above.
        for (DatanodeStorageInfo resultStorage : results) {
          addToExcludedNodes(resultStorage.getDatanodeDescriptor(), oldExcludedNodes);
        }
        // Set numOfReplicas, since it can get out of sync with the result list
        // if the NotEnoughReplicasException was thrown in chooseRandom().
        numOfReplicas = totalReplicasExpected - results.size();
        return chooseTarget(numOfReplicas, writer, oldExcludedNodes, blocksize,
            maxNodesPerRack, results, false, storagePolicy, unavailableStorages,
            newBlock);
      }

      boolean retry = false;
      // simply add all the remaining types into unavailableStorages and give
      // another try. No best effort is guaranteed here.
      for (StorageType type : storageTypes.keySet()) {
        if (!unavailableStorages.contains(type)) {
          unavailableStorages.add(type);
          retry = true;
        }
      }
      if (retry) {
        for (DatanodeStorageInfo resultStorage : results) {
          addToExcludedNodes(resultStorage.getDatanodeDescriptor(),
              oldExcludedNodes);
        }
        numOfReplicas = totalReplicasExpected - results.size();
        return chooseTarget(numOfReplicas, writer, oldExcludedNodes, blocksize,
            maxNodesPerRack, results, false, storagePolicy, unavailableStorages,
            newBlock);
      }
    }
    return writer;
  }

副本选择降级处理

首先选择本地存储位置.如果不满足条件,再选择本地机架的其他节点,如果还是没有满足条件的,进一步降级选择不同机架的节点,最后随机选择集群中的节点,关系图如下:

在这里插入图片描述

chooseRandom

无论是在本地机架还是远程机架选择节点,都会调用chooseRandom方法

  protected DatanodeStorageInfo chooseRandom(int numOfReplicas,
                            String scope,
                            Set<Node> excludedNodes,
                            long blocksize,
                            int maxNodesPerRack,
                            List<DatanodeStorageInfo> results,
                            boolean avoidStaleNodes,
                            EnumMap<StorageType, Integer> storageTypes)
                            throws NotEnoughReplicasException {
    // 取出节点数
    int numOfAvailableNodes = clusterMap.countNumOfAvailableNodes(
        scope, excludedNodes);
    StringBuilder builder = null;
    if (LOG.isDebugEnabled()) {
      builder = debugLoggingBuilder.get();
      builder.setLength(0);
      builder.append("[");
    }
    boolean badTarget = false;
    DatanodeStorageInfo firstChosen = null;
    // 开始循环
    while(numOfReplicas > 0 && numOfAvailableNodes > 0) {
      // 随机选择一个节点
      DatanodeDescriptor chosenNode = 
          (DatanodeDescriptor)clusterMap.chooseRandom(scope);
      // 添加进excludedNodes
      if (excludedNodes.add(chosenNode)) { //was not in the excluded list
        if (LOG.isDebugEnabled()) {
          builder.append("\nNode ").append(NodeBase.getPath(chosenNode)).append(" [");
        }
        // 节点数减一
        numOfAvailableNodes--;

        final DatanodeStorageInfo[] storages = DFSUtil.shuffle(
            chosenNode.getStorageInfos());
        int i = 0;
        boolean search = true;
        for (Iterator<Map.Entry<StorageType, Integer>> iter = storageTypes
            .entrySet().iterator(); search && iter.hasNext(); ) {
          Map.Entry<StorageType, Integer> entry = iter.next();
          for (i = 0; i < storages.length; i++) {
            StorageType type = entry.getKey();
            // 判断目标节点是否符合条件
            final int newExcludedNodes = addIfIsGoodTarget(storages[i],
                excludedNodes, blocksize, maxNodesPerRack, considerLoad, results,
                avoidStaleNodes, type);
            // 符合条件
            if (newExcludedNodes >= 0) {
              // 副本数减一
              numOfReplicas--;
              if (firstChosen == null) {
                firstChosen = storages[i];
              }
              numOfAvailableNodes -= newExcludedNodes;
              int num = entry.getValue();
              if (num == 1) {
                iter.remove();
              } else {
                entry.setValue(num - 1);
              }
              search = false;
              break;
            }
          }
        }
        if (LOG.isDebugEnabled()) {
          builder.append("\n]");
        }

        // If no candidate storage was found on this DN then set badTarget.
        badTarget = (i == storages.length);
      }
    }
    // 如果剩余副本数大于0,则抛出NotEnoughReplicasException异常
    if (numOfReplicas>0) {
      String detail = enableDebugLogging;
      if (LOG.isDebugEnabled()) {
        if (badTarget && builder != null) {
          detail = builder.toString();
          builder.setLength(0);
        } else {
          detail = "";
        }
      }
      throw new NotEnoughReplicasException(detail);
    }
    
    return firstChosen;
  }

addIfIsGoodTarget方法(If the given storage is a good target, add it to the result list and update the set of excluded nodes.)

  int addIfIsGoodTarget(DatanodeStorageInfo storage,
      Set<Node> excludedNodes,
      long blockSize,
      int maxNodesPerRack,
      boolean considerLoad,
      List<DatanodeStorageInfo> results,                           
      boolean avoidStaleNodes,
      StorageType storageType) {
    // 调用isGoodTarget方法
    if (isGoodTarget(storage, blockSize, maxNodesPerRack, considerLoad,
        results, avoidStaleNodes, storageType)) {
      // 如果符合条件,则把节点添加进results和excludedNodes
      results.add(storage);
      // add node and related nodes to excludedNode
      return addToExcludedNodes(storage.getDatanodeDescriptor(), excludedNodes);
    } else { 
      return -1;
    }
  }

isGoodTarget方法(Determine if a storage is a good target.)

  private boolean isGoodTarget(DatanodeStorageInfo storage,
                               long blockSize, int maxTargetPerRack,
                               boolean considerLoad,
                               List<DatanodeStorageInfo> results,
                               boolean avoidStaleNodes,
                               StorageType requiredStorageType) {
    // 判断存储类型是否符合
    if (storage.getStorageType() != requiredStorageType) {
      logNodeIsNotChosen(storage, "storage types do not match,"
          + " where the required storage type is " + requiredStorageType);
      return false;
    }
    // storage是否只读
    if (storage.getState() == State.READ_ONLY_SHARED) {
      logNodeIsNotChosen(storage, "storage is read-only");
      return false;
    }
    // storage是否failed
    if (storage.getState() == State.FAILED) {
      logNodeIsNotChosen(storage, "storage has failed");
      return false;
    }

    DatanodeDescriptor node = storage.getDatanodeDescriptor();
    // check if the node is (being) decommissioned
    if (node.isDecommissionInProgress() || node.isDecommissioned()) {
      logNodeIsNotChosen(storage, "the node is (being) decommissioned ");
      return false;
    }
    // 节点是否stale
    if (avoidStaleNodes) {
      if (node.isStale(this.staleInterval)) {
        logNodeIsNotChosen(storage, "the node is stale ");
        return false;
      }
    }
    // 判断容量是否足够
    final long requiredSize = blockSize * HdfsConstants.MIN_BLOCKS_FOR_WRITE;
    final long scheduledSize = blockSize * node.getBlocksScheduled(storage.getStorageType());
    final long remaining =
        node.getRemaining(storage.getStorageType(), requiredSize);
    // 如果remaining < requiredSize+scheduledSize,则不符合条件
    if (requiredSize > remaining - scheduledSize) {
      logNodeIsNotChosen(storage, "the node does not have enough "
          + storage.getStorageType() + " space"
          + " (required=" + requiredSize
          + ", scheduled=" + scheduledSize
          + ", remaining=" + remaining + ")");
      return false;
    }

    // check the communication traffic of the target machine
    if (considerLoad) {
      final double maxLoad = 2.0 * stats.getInServiceXceiverAverage();
      final int nodeLoad = node.getXceiverCount();
      // 如果节点负载大于集群平均负载的2倍,则不符合条件
      if (nodeLoad > maxLoad) {
        logNodeIsNotChosen(storage, "the node is too busy (load: " + nodeLoad
            + " > " + maxLoad + ") ");
        return false;
      }
    }
      
    // check if the target rack has chosen too many nodes
    String rackname = node.getNetworkLocation();
    int counter=1;
    for(DatanodeStorageInfo resultStorage : results) {
      if (rackname.equals(
          resultStorage.getDatanodeDescriptor().getNetworkLocation())) {
        counter++;
      }
    }
    if (counter>maxTargetPerRack) {
      logNodeIsNotChosen(storage, "the rack has too many chosen nodes ");
      return false;
    }
    return true;
  }

副本存储节点需要满足的条件

1、storage type要与请求的storage type相同
2、storage状态不能为read-only
3、storage状态不能为failed
4、节点不能是decommissioned
5、节点不能是stale
6、剩余容量要大于等于requiredSize+scheduledSize
7、节点负载不能大于集群平均负载的2倍
8、不能超过机架最大存放副本数(maxNodesPerRack = (totalNumOfReplicas-1)/numOfRacks + 2)

scheduledSize

scheduledSize = blockSize * node.getBlocksScheduled(storage.getStorageType());

DatanodeDescriptor.java

  /**
   * @return Approximate number of blocks currently scheduled to be written 
   * to the given storage type of this datanode.
   */
  public int getBlocksScheduled(StorageType t) {
    return (int)(currApproxBlocksScheduled.get(t)
        + prevApproxBlocksScheduled.get(t));
  }

返回pipeline

接下来是选择好了副本存放的节点,按最短距离组成pipeline返回

  /**
   * Return a pipeline of nodes.
   * The pipeline is formed finding a shortest path that 
   * starts from the writer and traverses all <i>nodes</i>
   * This is basically a traveling salesman problem.
   */
  private DatanodeStorageInfo[] getPipeline(Node writer,
      DatanodeStorageInfo[] storages) {
    if (storages.length == 0) {
      return storages;
    }

    synchronized(clusterMap) {
      int index=0;
      // 首先如果writer请求方本身不在一个datanode上,则默认选取第一个datanode作为起始节点
      if (writer == null || !clusterMap.contains(writer)) {
        writer = storages[0].getDatanodeDescriptor();
      }
      for(; index < storages.length; index++) {
        // 获取当前index下标所属的Storage为最近距离的目标storage
        DatanodeStorageInfo shortestStorage = storages[index];
        // 计算当前距离
        int shortestDistance = clusterMap.getDistance(writer,
            shortestStorage.getDatanodeDescriptor());
        int shortestIndex = index;
        for(int i = index + 1; i < storages.length; i++) {
          // 遍历计算后面的距离
          int currentDistance = clusterMap.getDistance(writer,
              storages[i].getDatanodeDescriptor());
          if (shortestDistance>currentDistance) {
            shortestDistance = currentDistance;
            shortestStorage = storages[i];
            shortestIndex = i;
          }
        }
        // 找到新的最短距离的storage,并进行下标替换
        if (index != shortestIndex) {
          storages[shortestIndex] = storages[index];
          storages[index] = shortestStorage;
        }
        // 找到当前这一轮的最近的storage,并作为下一轮迭代的源节点
        writer = shortestStorage.getDatanodeDescriptor();
      }
    }
    return storages;
  }

概况就是选出一个源节点,根据这个节点,遍历当前可选的下一个目标节点,找出一个最短距离的节点,作为下一轮选举的源节点,这样每2个节点之间的距离总是最近的,于是整个pipeline节点间的距离和就保证是足够小的了。那要如何定义和计算2个节点直接的距离,如下图:

在这里插入图片描述