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/*
 *
 * 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.hbase.io.hfile;

import java.io.ByteArrayOutputStream;
import java.io.DataInput;
import java.io.DataInputStream;
import java.io.DataOutput;
import java.io.DataOutputStream;
import java.io.IOException;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import java.util.concurrent.atomic.AtomicReference;

import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;
import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.fs.FSDataOutputStream;
import org.apache.hadoop.hbase.Cell;
import org.apache.hadoop.hbase.KeyValue;
import org.apache.hadoop.hbase.KeyValue.KVComparator;
import org.apache.hadoop.hbase.KeyValueUtil;
import org.apache.hadoop.hbase.classification.InterfaceAudience;
import org.apache.hadoop.hbase.io.HeapSize;
import org.apache.hadoop.hbase.io.encoding.DataBlockEncoding;
import org.apache.hadoop.hbase.io.hfile.HFile.CachingBlockReader;
import org.apache.hadoop.hbase.regionserver.KeyValueScanner;
import org.apache.hadoop.hbase.util.ByteBufferUtils;
import org.apache.hadoop.hbase.util.Bytes;
import org.apache.hadoop.hbase.util.ClassSize;
import org.apache.hadoop.io.WritableUtils;
import org.apache.hadoop.util.StringUtils;

/**
 * Provides functionality to write ({@link BlockIndexWriter}) and read
 * BlockIndexReader
 * single-level and multi-level block indexes.
 *
 * Examples of how to use the block index writer can be found in
 * {@link org.apache.hadoop.hbase.util.CompoundBloomFilterWriter} and
 *  {@link HFileWriterV2}. Examples of how to use the reader can be
 *  found in {@link HFileReaderV2} and
 *  {@link org.apache.hadoop.hbase.io.hfile.TestHFileBlockIndex}.
 */
@InterfaceAudience.Private
public class HFileBlockIndex {

  private static final Log LOG = LogFactory.getLog(HFileBlockIndex.class);

  static final int DEFAULT_MAX_CHUNK_SIZE = 128 * 1024;

  /**
   * The maximum size guideline for index blocks (both leaf, intermediate, and
   * root). If not specified, DEFAULT_MAX_CHUNK_SIZE is used.
   */
  public static final String MAX_CHUNK_SIZE_KEY = "hfile.index.block.max.size";

  /**
   * Minimum number of entries in a single index block. Even if we are above the
   * hfile.index.block.max.size we will keep writing to the same block unless we have that many
   * entries. We should have at least a few entries so that we don't have too many levels in the
   * multi-level index. This should be at least 2 to make sure there is no infinite recursion.
   */
  public static final String MIN_INDEX_NUM_ENTRIES_KEY = "hfile.index.block.min.entries";

  static final int DEFAULT_MIN_INDEX_NUM_ENTRIES = 16;

  /**
   * The number of bytes stored in each "secondary index" entry in addition to
   * key bytes in the non-root index block format. The first long is the file
   * offset of the deeper-level block the entry points to, and the int that
   * follows is that block's on-disk size without including header.
   */
  static final int SECONDARY_INDEX_ENTRY_OVERHEAD = Bytes.SIZEOF_INT
      + Bytes.SIZEOF_LONG;

  /**
   * Error message when trying to use inline block API in single-level mode.
   */
  private static final String INLINE_BLOCKS_NOT_ALLOWED =
      "Inline blocks are not allowed in the single-level-only mode";

  /**
   * The size of a meta-data record used for finding the mid-key in a
   * multi-level index. Consists of the middle leaf-level index block offset
   * (long), its on-disk size without header included (int), and the mid-key
   * entry's zero-based index in that leaf index block.
   */
  private static final int MID_KEY_METADATA_SIZE = Bytes.SIZEOF_LONG +
      2 * Bytes.SIZEOF_INT;

  /**
   * The reader will always hold the root level index in the memory. Index
   * blocks at all other levels will be cached in the LRU cache in practice,
   * although this API does not enforce that.
   *
   * 

All non-root (leaf and intermediate) index blocks contain what we call a * "secondary index": an array of offsets to the entries within the block. * This allows us to do binary search for the entry corresponding to the * given key without having to deserialize the block. */ public static class BlockIndexReader implements HeapSize { /** Needed doing lookup on blocks. */ private final KVComparator comparator; // Root-level data. private byte[][] blockKeys; private long[] blockOffsets; private int[] blockDataSizes; private int rootCount = 0; // Mid-key metadata. private long midLeafBlockOffset = -1; private int midLeafBlockOnDiskSize = -1; private int midKeyEntry = -1; /** Pre-computed mid-key */ private AtomicReference midKey = new AtomicReference(); /** * The number of levels in the block index tree. One if there is only root * level, two for root and leaf levels, etc. */ private int searchTreeLevel; /** A way to read {@link HFile} blocks at a given offset */ private CachingBlockReader cachingBlockReader; public BlockIndexReader(final KVComparator c, final int treeLevel, final CachingBlockReader cachingBlockReader) { this(c, treeLevel); this.cachingBlockReader = cachingBlockReader; } public BlockIndexReader(final KVComparator c, final int treeLevel) { comparator = c; searchTreeLevel = treeLevel; } /** * @return true if the block index is empty. */ public boolean isEmpty() { return blockKeys.length == 0; } /** * Verifies that the block index is non-empty and throws an * {@link IllegalStateException} otherwise. */ public void ensureNonEmpty() { if (blockKeys.length == 0) { throw new IllegalStateException("Block index is empty or not loaded"); } } /** * Return the data block which contains this key. This function will only * be called when the HFile version is larger than 1. * * @param key the key we are looking for * @param currentBlock the current block, to avoid re-reading the same block * @param cacheBlocks * @param pread * @param isCompaction * @param expectedDataBlockEncoding the data block encoding the caller is * expecting the data block to be in, or null to not perform this * check and return the block irrespective of the encoding * @return reader a basic way to load blocks * @throws IOException */ public HFileBlock seekToDataBlock(final Cell key, HFileBlock currentBlock, boolean cacheBlocks, boolean pread, boolean isCompaction, DataBlockEncoding expectedDataBlockEncoding) throws IOException { BlockWithScanInfo blockWithScanInfo = loadDataBlockWithScanInfo(key, currentBlock, cacheBlocks, pread, isCompaction, expectedDataBlockEncoding); if (blockWithScanInfo == null) { return null; } else { return blockWithScanInfo.getHFileBlock(); } } /** * Return the BlockWithScanInfo, a data structure which contains the Data HFileBlock with * other scan info such as the key that starts the next HFileBlock. This function will only * be called when the HFile version is larger than 1. * * @param key the key we are looking for * @param currentBlock the current block, to avoid re-reading the same block * @param cacheBlocks * @param pread * @param isCompaction * @param expectedDataBlockEncoding the data block encoding the caller is * expecting the data block to be in, or null to not perform this * check and return the block irrespective of the encoding. * @return the BlockWithScanInfo which contains the DataBlock with other * scan info such as nextIndexedKey. * @throws IOException */ public BlockWithScanInfo loadDataBlockWithScanInfo(Cell key, HFileBlock currentBlock, boolean cacheBlocks, boolean pread, boolean isCompaction, DataBlockEncoding expectedDataBlockEncoding) throws IOException { int rootLevelIndex = rootBlockContainingKey(key); if (rootLevelIndex < 0 || rootLevelIndex >= blockOffsets.length) { return null; } // the next indexed key Cell nextIndexedKey = null; // Read the next-level (intermediate or leaf) index block. long currentOffset = blockOffsets[rootLevelIndex]; int currentOnDiskSize = blockDataSizes[rootLevelIndex]; if (rootLevelIndex < blockKeys.length - 1) { nextIndexedKey = new KeyValue.KeyOnlyKeyValue(blockKeys[rootLevelIndex + 1]); } else { nextIndexedKey = KeyValueScanner.NO_NEXT_INDEXED_KEY; } int lookupLevel = 1; // How many levels deep we are in our lookup. int index = -1; HFileBlock block; while (true) { if (currentBlock != null && currentBlock.getOffset() == currentOffset) { // Avoid reading the same block again, even with caching turned off. // This is crucial for compaction-type workload which might have // caching turned off. This is like a one-block cache inside the // scanner. block = currentBlock; } else { // Call HFile's caching block reader API. We always cache index // blocks, otherwise we might get terrible performance. boolean shouldCache = cacheBlocks || (lookupLevel < searchTreeLevel); BlockType expectedBlockType; if (lookupLevel < searchTreeLevel - 1) { expectedBlockType = BlockType.INTERMEDIATE_INDEX; } else if (lookupLevel == searchTreeLevel - 1) { expectedBlockType = BlockType.LEAF_INDEX; } else { // this also accounts for ENCODED_DATA expectedBlockType = BlockType.DATA; } block = cachingBlockReader.readBlock(currentOffset, currentOnDiskSize, shouldCache, pread, isCompaction, true, expectedBlockType, expectedDataBlockEncoding); } if (block == null) { throw new IOException("Failed to read block at offset " + currentOffset + ", onDiskSize=" + currentOnDiskSize); } // Found a data block, break the loop and check our level in the tree. if (block.getBlockType().isData()) { break; } // Not a data block. This must be a leaf-level or intermediate-level // index block. We don't allow going deeper than searchTreeLevel. if (++lookupLevel > searchTreeLevel) { throw new IOException("Search Tree Level overflow: lookupLevel="+ lookupLevel + ", searchTreeLevel=" + searchTreeLevel); } // Locate the entry corresponding to the given key in the non-root // (leaf or intermediate-level) index block. ByteBuffer buffer = block.getBufferWithoutHeader(); index = locateNonRootIndexEntry(buffer, key, comparator); if (index == -1) { // This has to be changed // For now change this to key value KeyValue kv = KeyValueUtil.ensureKeyValue(key); throw new IOException("The key " + Bytes.toStringBinary(kv.getKey(), kv.getKeyOffset(), kv.getKeyLength()) + " is before the" + " first key of the non-root index block " + block); } currentOffset = buffer.getLong(); currentOnDiskSize = buffer.getInt(); // Only update next indexed key if there is a next indexed key in the current level byte[] tmpNextIndexedKey = getNonRootIndexedKey(buffer, index + 1); if (tmpNextIndexedKey != null) { nextIndexedKey = new KeyValue.KeyOnlyKeyValue(tmpNextIndexedKey); } } if (lookupLevel != searchTreeLevel) { throw new IOException("Reached a data block at level " + lookupLevel + " but the number of levels is " + searchTreeLevel); } // set the next indexed key for the current block. BlockWithScanInfo blockWithScanInfo = new BlockWithScanInfo(block, nextIndexedKey); return blockWithScanInfo; } /** * An approximation to the {@link HFile}'s mid-key. Operates on block * boundaries, and does not go inside blocks. In other words, returns the * first key of the middle block of the file. * * @return the first key of the middle block */ public byte[] midkey() throws IOException { if (rootCount == 0) throw new IOException("HFile empty"); byte[] targetMidKey = this.midKey.get(); if (targetMidKey != null) { return targetMidKey; } if (midLeafBlockOffset >= 0) { if (cachingBlockReader == null) { throw new IOException("Have to read the middle leaf block but " + "no block reader available"); } // Caching, using pread, assuming this is not a compaction. HFileBlock midLeafBlock = cachingBlockReader.readBlock( midLeafBlockOffset, midLeafBlockOnDiskSize, true, true, false, true, BlockType.LEAF_INDEX, null); ByteBuffer b = midLeafBlock.getBufferWithoutHeader(); int numDataBlocks = b.getInt(); int keyRelOffset = b.getInt(Bytes.SIZEOF_INT * (midKeyEntry + 1)); int keyLen = b.getInt(Bytes.SIZEOF_INT * (midKeyEntry + 2)) - keyRelOffset - SECONDARY_INDEX_ENTRY_OVERHEAD; int keyOffset = Bytes.SIZEOF_INT * (numDataBlocks + 2) + keyRelOffset + SECONDARY_INDEX_ENTRY_OVERHEAD; targetMidKey = ByteBufferUtils.toBytes(b, keyOffset, keyLen); } else { // The middle of the root-level index. targetMidKey = blockKeys[rootCount / 2]; } this.midKey.set(targetMidKey); return targetMidKey; } /** * @param i from 0 to {@link #getRootBlockCount() - 1} */ public byte[] getRootBlockKey(int i) { return blockKeys[i]; } /** * @param i from 0 to {@link #getRootBlockCount() - 1} */ public long getRootBlockOffset(int i) { return blockOffsets[i]; } /** * @param i zero-based index of a root-level block * @return the on-disk size of the root-level block for version 2, or the * uncompressed size for version 1 */ public int getRootBlockDataSize(int i) { return blockDataSizes[i]; } /** * @return the number of root-level blocks in this block index */ public int getRootBlockCount() { return rootCount; } /** * Finds the root-level index block containing the given key. * * @param key * Key to find * @return Offset of block containing key (between 0 and the * number of blocks - 1) or -1 if this file does not contain the * request. */ public int rootBlockContainingKey(final byte[] key, int offset, int length) { int pos = Bytes.binarySearch(blockKeys, key, offset, length, comparator); // pos is between -(blockKeys.length + 1) to blockKeys.length - 1, see // binarySearch's javadoc. if (pos >= 0) { // This means this is an exact match with an element of blockKeys. assert pos < blockKeys.length; return pos; } // Otherwise, pos = -(i + 1), where blockKeys[i - 1] < key < blockKeys[i], // and i is in [0, blockKeys.length]. We are returning j = i - 1 such that // blockKeys[j] <= key < blockKeys[j + 1]. In particular, j = -1 if // key < blockKeys[0], meaning the file does not contain the given key. int i = -pos - 1; assert 0 <= i && i <= blockKeys.length; return i - 1; } /** * Finds the root-level index block containing the given key. * * @param key * Key to find */ public int rootBlockContainingKey(final Cell key) { int pos = Bytes.binarySearch(blockKeys, key, comparator); // pos is between -(blockKeys.length + 1) to blockKeys.length - 1, see // binarySearch's javadoc. if (pos >= 0) { // This means this is an exact match with an element of blockKeys. assert pos < blockKeys.length; return pos; } // Otherwise, pos = -(i + 1), where blockKeys[i - 1] < key < blockKeys[i], // and i is in [0, blockKeys.length]. We are returning j = i - 1 such that // blockKeys[j] <= key < blockKeys[j + 1]. In particular, j = -1 if // key < blockKeys[0], meaning the file does not contain the given key. int i = -pos - 1; assert 0 <= i && i <= blockKeys.length; return i - 1; } /** * Adds a new entry in the root block index. Only used when reading. * * @param key Last key in the block * @param offset file offset where the block is stored * @param dataSize the uncompressed data size */ private void add(final byte[] key, final long offset, final int dataSize) { blockOffsets[rootCount] = offset; blockKeys[rootCount] = key; blockDataSizes[rootCount] = dataSize; rootCount++; } /** * The indexed key at the ith position in the nonRootIndex. The position starts at 0. * @param nonRootIndex * @param i the ith position * @return The indexed key at the ith position in the nonRootIndex. */ private byte[] getNonRootIndexedKey(ByteBuffer nonRootIndex, int i) { int numEntries = nonRootIndex.getInt(0); if (i < 0 || i >= numEntries) { return null; } // Entries start after the number of entries and the secondary index. // The secondary index takes numEntries + 1 ints. int entriesOffset = Bytes.SIZEOF_INT * (numEntries + 2); // Targetkey's offset relative to the end of secondary index int targetKeyRelOffset = nonRootIndex.getInt( Bytes.SIZEOF_INT * (i + 1)); // The offset of the target key in the blockIndex buffer int targetKeyOffset = entriesOffset // Skip secondary index + targetKeyRelOffset // Skip all entries until mid + SECONDARY_INDEX_ENTRY_OVERHEAD; // Skip offset and on-disk-size // We subtract the two consecutive secondary index elements, which // gives us the size of the whole (offset, onDiskSize, key) tuple. We // then need to subtract the overhead of offset and onDiskSize. int targetKeyLength = nonRootIndex.getInt(Bytes.SIZEOF_INT * (i + 2)) - targetKeyRelOffset - SECONDARY_INDEX_ENTRY_OVERHEAD; return ByteBufferUtils.toBytes(nonRootIndex, targetKeyOffset, targetKeyLength); } /** * Performs a binary search over a non-root level index block. Utilizes the * secondary index, which records the offsets of (offset, onDiskSize, * firstKey) tuples of all entries. * * @param key * the key we are searching for offsets to individual entries in * the blockIndex buffer * @param nonRootIndex * the non-root index block buffer, starting with the secondary * index. The position is ignored. * @return the index i in [0, numEntries - 1] such that keys[i] <= key < * keys[i + 1], if keys is the array of all keys being searched, or * -1 otherwise * @throws IOException */ static int binarySearchNonRootIndex(Cell key, ByteBuffer nonRootIndex, KVComparator comparator) { int numEntries = nonRootIndex.getInt(0); int low = 0; int high = numEntries - 1; int mid = 0; // Entries start after the number of entries and the secondary index. // The secondary index takes numEntries + 1 ints. int entriesOffset = Bytes.SIZEOF_INT * (numEntries + 2); // If we imagine that keys[-1] = -Infinity and // keys[numEntries] = Infinity, then we are maintaining an invariant that // keys[low - 1] < key < keys[high + 1] while narrowing down the range. KeyValue.KeyOnlyKeyValue nonRootIndexKV = new KeyValue.KeyOnlyKeyValue(); while (low <= high) { mid = (low + high) >>> 1; // Midkey's offset relative to the end of secondary index int midKeyRelOffset = nonRootIndex.getInt( Bytes.SIZEOF_INT * (mid + 1)); // The offset of the middle key in the blockIndex buffer int midKeyOffset = entriesOffset // Skip secondary index + midKeyRelOffset // Skip all entries until mid + SECONDARY_INDEX_ENTRY_OVERHEAD; // Skip offset and on-disk-size // We subtract the two consecutive secondary index elements, which // gives us the size of the whole (offset, onDiskSize, key) tuple. We // then need to subtract the overhead of offset and onDiskSize. int midLength = nonRootIndex.getInt(Bytes.SIZEOF_INT * (mid + 2)) - midKeyRelOffset - SECONDARY_INDEX_ENTRY_OVERHEAD; // we have to compare in this order, because the comparator order // has special logic when the 'left side' is a special key. // TODO make KeyOnlyKeyValue to be Buffer backed and avoid array() call. This has to be // done after HBASE-12224 & HBASE-12282 nonRootIndexKV.setKey(nonRootIndex.array(), nonRootIndex.arrayOffset() + midKeyOffset, midLength); int cmp = comparator.compareOnlyKeyPortion(key, nonRootIndexKV); // key lives above the midpoint if (cmp > 0) low = mid + 1; // Maintain the invariant that keys[low - 1] < key // key lives below the midpoint else if (cmp < 0) high = mid - 1; // Maintain the invariant that key < keys[high + 1] else return mid; // exact match } // As per our invariant, keys[low - 1] < key < keys[high + 1], meaning // that low - 1 < high + 1 and (low - high) <= 1. As per the loop break // condition, low >= high + 1. Therefore, low = high + 1. if (low != high + 1) { throw new IllegalStateException("Binary search broken: low=" + low + " " + "instead of " + (high + 1)); } // OK, our invariant says that keys[low - 1] < key < keys[low]. We need to // return i such that keys[i] <= key < keys[i + 1]. Therefore i = low - 1. int i = low - 1; // Some extra validation on the result. if (i < -1 || i >= numEntries) { throw new IllegalStateException("Binary search broken: result is " + i + " but expected to be between -1 and (numEntries - 1) = " + (numEntries - 1)); } return i; } /** * Search for one key using the secondary index in a non-root block. In case * of success, positions the provided buffer at the entry of interest, where * the file offset and the on-disk-size can be read. * * @param nonRootBlock * a non-root block without header. Initial position does not * matter. * @param key * the byte array containing the key * @return the index position where the given key was found, otherwise * return -1 in the case the given key is before the first key. * */ static int locateNonRootIndexEntry(ByteBuffer nonRootBlock, Cell key, KVComparator comparator) { int entryIndex = binarySearchNonRootIndex(key, nonRootBlock, comparator); if (entryIndex != -1) { int numEntries = nonRootBlock.getInt(0); // The end of secondary index and the beginning of entries themselves. int entriesOffset = Bytes.SIZEOF_INT * (numEntries + 2); // The offset of the entry we are interested in relative to the end of // the secondary index. int entryRelOffset = nonRootBlock.getInt(Bytes.SIZEOF_INT * (1 + entryIndex)); nonRootBlock.position(entriesOffset + entryRelOffset); } return entryIndex; } /** * Read in the root-level index from the given input stream. Must match * what was written into the root level by * {@link BlockIndexWriter#writeIndexBlocks(FSDataOutputStream)} at the * offset that function returned. * * @param in the buffered input stream or wrapped byte input stream * @param numEntries the number of root-level index entries * @throws IOException */ public void readRootIndex(DataInput in, final int numEntries) throws IOException { blockOffsets = new long[numEntries]; blockKeys = new byte[numEntries][]; blockDataSizes = new int[numEntries]; // If index size is zero, no index was written. if (numEntries > 0) { for (int i = 0; i < numEntries; ++i) { long offset = in.readLong(); int dataSize = in.readInt(); byte[] key = Bytes.readByteArray(in); add(key, offset, dataSize); } } } /** * Read in the root-level index from the given input stream. Must match * what was written into the root level by * {@link BlockIndexWriter#writeIndexBlocks(FSDataOutputStream)} at the * offset that function returned. * * @param blk the HFile block * @param numEntries the number of root-level index entries * @return the buffered input stream or wrapped byte input stream * @throws IOException */ public DataInputStream readRootIndex(HFileBlock blk, final int numEntries) throws IOException { DataInputStream in = blk.getByteStream(); readRootIndex(in, numEntries); return in; } /** * Read the root-level metadata of a multi-level block index. Based on * {@link #readRootIndex(DataInput, int)}, but also reads metadata * necessary to compute the mid-key in a multi-level index. * * @param blk the HFile block * @param numEntries the number of root-level index entries * @throws IOException */ public void readMultiLevelIndexRoot(HFileBlock blk, final int numEntries) throws IOException { DataInputStream in = readRootIndex(blk, numEntries); // after reading the root index the checksum bytes have to // be subtracted to know if the mid key exists. int checkSumBytes = blk.totalChecksumBytes(); if ((in.available() - checkSumBytes) < MID_KEY_METADATA_SIZE) { // No mid-key metadata available. return; } midLeafBlockOffset = in.readLong(); midLeafBlockOnDiskSize = in.readInt(); midKeyEntry = in.readInt(); } @Override public String toString() { StringBuilder sb = new StringBuilder(); sb.append("size=" + rootCount).append("\n"); for (int i = 0; i < rootCount; i++) { sb.append("key=").append(KeyValue.keyToString(blockKeys[i])) .append("\n offset=").append(blockOffsets[i]) .append(", dataSize=" + blockDataSizes[i]).append("\n"); } return sb.toString(); } @Override public long heapSize() { long heapSize = ClassSize.align(6 * ClassSize.REFERENCE + 2 * Bytes.SIZEOF_INT + ClassSize.OBJECT); // Mid-key metadata. heapSize += MID_KEY_METADATA_SIZE; // Calculating the size of blockKeys if (blockKeys != null) { // Adding array + references overhead heapSize += ClassSize.align(ClassSize.ARRAY + blockKeys.length * ClassSize.REFERENCE); // Adding bytes for (byte[] key : blockKeys) { heapSize += ClassSize.align(ClassSize.ARRAY + key.length); } } if (blockOffsets != null) { heapSize += ClassSize.align(ClassSize.ARRAY + blockOffsets.length * Bytes.SIZEOF_LONG); } if (blockDataSizes != null) { heapSize += ClassSize.align(ClassSize.ARRAY + blockDataSizes.length * Bytes.SIZEOF_INT); } return ClassSize.align(heapSize); } } /** * Writes the block index into the output stream. Generate the tree from * bottom up. The leaf level is written to disk as a sequence of inline * blocks, if it is larger than a certain number of bytes. If the leaf level * is not large enough, we write all entries to the root level instead. * * After all leaf blocks have been written, we end up with an index * referencing the resulting leaf index blocks. If that index is larger than * the allowed root index size, the writer will break it up into * reasonable-size intermediate-level index block chunks write those chunks * out, and create another index referencing those chunks. This will be * repeated until the remaining index is small enough to become the root * index. However, in most practical cases we will only have leaf-level * blocks and the root index, or just the root index. */ public static class BlockIndexWriter implements InlineBlockWriter { /** * While the index is being written, this represents the current block * index referencing all leaf blocks, with one exception. If the file is * being closed and there are not enough blocks to complete even a single * leaf block, no leaf blocks get written and this contains the entire * block index. After all levels of the index were written by * {@link #writeIndexBlocks(FSDataOutputStream)}, this contains the final * root-level index. */ private BlockIndexChunk rootChunk = new BlockIndexChunk(); /** * Current leaf-level chunk. New entries referencing data blocks get added * to this chunk until it grows large enough to be written to disk. */ private BlockIndexChunk curInlineChunk = new BlockIndexChunk(); /** * The number of block index levels. This is one if there is only root * level (even empty), two if there a leaf level and root level, and is * higher if there are intermediate levels. This is only final after * {@link #writeIndexBlocks(FSDataOutputStream)} has been called. The * initial value accounts for the root level, and will be increased to two * as soon as we find out there is a leaf-level in * {@link #blockWritten(long, int, int)}. */ private int numLevels = 1; private HFileBlock.Writer blockWriter; private byte[] firstKey = null; /** * The total number of leaf-level entries, i.e. entries referenced by * leaf-level blocks. For the data block index this is equal to the number * of data blocks. */ private long totalNumEntries; /** Total compressed size of all index blocks. */ private long totalBlockOnDiskSize; /** Total uncompressed size of all index blocks. */ private long totalBlockUncompressedSize; /** The maximum size guideline of all multi-level index blocks. */ private int maxChunkSize; /** The maximum level of multi-level index blocks */ private int minIndexNumEntries; /** Whether we require this block index to always be single-level. */ private boolean singleLevelOnly; /** CacheConfig, or null if cache-on-write is disabled */ private CacheConfig cacheConf; /** Name to use for computing cache keys */ private String nameForCaching; /** Creates a single-level block index writer */ public BlockIndexWriter() { this(null, null, null); singleLevelOnly = true; } /** * Creates a multi-level block index writer. * * @param blockWriter the block writer to use to write index blocks * @param cacheConf used to determine when and how a block should be cached-on-write. */ public BlockIndexWriter(HFileBlock.Writer blockWriter, CacheConfig cacheConf, String nameForCaching) { if ((cacheConf == null) != (nameForCaching == null)) { throw new IllegalArgumentException("Block cache and file name for " + "caching must be both specified or both null"); } this.blockWriter = blockWriter; this.cacheConf = cacheConf; this.nameForCaching = nameForCaching; this.maxChunkSize = HFileBlockIndex.DEFAULT_MAX_CHUNK_SIZE; this.minIndexNumEntries = HFileBlockIndex.DEFAULT_MIN_INDEX_NUM_ENTRIES; } public void setMaxChunkSize(int maxChunkSize) { if (maxChunkSize <= 0) { throw new IllegalArgumentException("Invalid maximum index block size"); } this.maxChunkSize = maxChunkSize; } public void setMinIndexNumEntries(int minIndexNumEntries) { if (minIndexNumEntries <= 1) { throw new IllegalArgumentException("Invalid maximum index level, should be >= 2"); } this.minIndexNumEntries = minIndexNumEntries; } /** * Writes the root level and intermediate levels of the block index into * the output stream, generating the tree from bottom up. Assumes that the * leaf level has been inline-written to the disk if there is enough data * for more than one leaf block. We iterate by breaking the current level * of the block index, starting with the index of all leaf-level blocks, * into chunks small enough to be written to disk, and generate its parent * level, until we end up with a level small enough to become the root * level. * * If the leaf level is not large enough, there is no inline block index * anymore, so we only write that level of block index to disk as the root * level. * * @param out FSDataOutputStream * @return position at which we entered the root-level index. * @throws IOException */ public long writeIndexBlocks(FSDataOutputStream out) throws IOException { if (curInlineChunk != null && curInlineChunk.getNumEntries() != 0) { throw new IOException("Trying to write a multi-level block index, " + "but are " + curInlineChunk.getNumEntries() + " entries in the " + "last inline chunk."); } // We need to get mid-key metadata before we create intermediate // indexes and overwrite the root chunk. byte[] midKeyMetadata = numLevels > 1 ? rootChunk.getMidKeyMetadata() : null; if (curInlineChunk != null) { while (rootChunk.getRootSize() > maxChunkSize // HBASE-16288: if firstKey is larger than maxChunkSize we will loop indefinitely && rootChunk.getNumEntries() > minIndexNumEntries // Sanity check. We will not hit this (minIndexNumEntries ^ 16) blocks can be addressed && numLevels < 16) { rootChunk = writeIntermediateLevel(out, rootChunk); numLevels += 1; } } // write the root level long rootLevelIndexPos = out.getPos(); { DataOutput blockStream = blockWriter.startWriting(BlockType.ROOT_INDEX); rootChunk.writeRoot(blockStream); if (midKeyMetadata != null) blockStream.write(midKeyMetadata); blockWriter.writeHeaderAndData(out); if (cacheConf != null) { HFileBlock blockForCaching = blockWriter.getBlockForCaching(cacheConf); cacheConf.getBlockCache().cacheBlock(new BlockCacheKey(nameForCaching, rootLevelIndexPos, true, blockForCaching.getBlockType()), blockForCaching); } } // Add root index block size totalBlockOnDiskSize += blockWriter.getOnDiskSizeWithoutHeader(); totalBlockUncompressedSize += blockWriter.getUncompressedSizeWithoutHeader(); if (LOG.isTraceEnabled()) { LOG.trace("Wrote a " + numLevels + "-level index with root level at pos " + rootLevelIndexPos + ", " + rootChunk.getNumEntries() + " root-level entries, " + totalNumEntries + " total entries, " + StringUtils.humanReadableInt(this.totalBlockOnDiskSize) + " on-disk size, " + StringUtils.humanReadableInt(totalBlockUncompressedSize) + " total uncompressed size."); } return rootLevelIndexPos; } /** * Writes the block index data as a single level only. Does not do any * block framing. * * @param out the buffered output stream to write the index to. Typically a * stream writing into an {@link HFile} block. * @param description a short description of the index being written. Used * in a log message. * @throws IOException */ public void writeSingleLevelIndex(DataOutput out, String description) throws IOException { expectNumLevels(1); if (!singleLevelOnly) throw new IOException("Single-level mode is turned off"); if (rootChunk.getNumEntries() > 0) throw new IOException("Root-level entries already added in " + "single-level mode"); rootChunk = curInlineChunk; curInlineChunk = new BlockIndexChunk(); if (LOG.isTraceEnabled()) { LOG.trace("Wrote a single-level " + description + " index with " + rootChunk.getNumEntries() + " entries, " + rootChunk.getRootSize() + " bytes"); } rootChunk.writeRoot(out); } /** * Split the current level of the block index into intermediate index * blocks of permitted size and write those blocks to disk. Return the next * level of the block index referencing those intermediate-level blocks. * * @param out * @param currentLevel the current level of the block index, such as the a * chunk referencing all leaf-level index blocks * @return the parent level block index, which becomes the root index after * a few (usually zero) iterations * @throws IOException */ private BlockIndexChunk writeIntermediateLevel(FSDataOutputStream out, BlockIndexChunk currentLevel) throws IOException { // Entries referencing intermediate-level blocks we are about to create. BlockIndexChunk parent = new BlockIndexChunk(); // The current intermediate-level block index chunk. BlockIndexChunk curChunk = new BlockIndexChunk(); for (int i = 0; i < currentLevel.getNumEntries(); ++i) { curChunk.add(currentLevel.getBlockKey(i), currentLevel.getBlockOffset(i), currentLevel.getOnDiskDataSize(i)); // HBASE-16288: We have to have at least minIndexNumEntries(16) items in the index so that // we won't end up with too-many levels for a index with very large rowKeys. Also, if the // first key is larger than maxChunkSize this will cause infinite recursion. if (i >= minIndexNumEntries && curChunk.getRootSize() >= maxChunkSize) { writeIntermediateBlock(out, parent, curChunk); } } if (curChunk.getNumEntries() > 0) { writeIntermediateBlock(out, parent, curChunk); } return parent; } private void writeIntermediateBlock(FSDataOutputStream out, BlockIndexChunk parent, BlockIndexChunk curChunk) throws IOException { long beginOffset = out.getPos(); DataOutputStream dos = blockWriter.startWriting( BlockType.INTERMEDIATE_INDEX); curChunk.writeNonRoot(dos); byte[] curFirstKey = curChunk.getBlockKey(0); blockWriter.writeHeaderAndData(out); if (getCacheOnWrite()) { HFileBlock blockForCaching = blockWriter.getBlockForCaching(cacheConf); cacheConf.getBlockCache().cacheBlock(new BlockCacheKey(nameForCaching, beginOffset, true, blockForCaching.getBlockType()), blockForCaching); } // Add intermediate index block size totalBlockOnDiskSize += blockWriter.getOnDiskSizeWithoutHeader(); totalBlockUncompressedSize += blockWriter.getUncompressedSizeWithoutHeader(); // OFFSET is the beginning offset the chunk of block index entries. // SIZE is the total byte size of the chunk of block index entries // + the secondary index size // FIRST_KEY is the first key in the chunk of block index // entries. parent.add(curFirstKey, beginOffset, blockWriter.getOnDiskSizeWithHeader()); // clear current block index chunk curChunk.clear(); curFirstKey = null; } /** * @return how many block index entries there are in the root level */ public final int getNumRootEntries() { return rootChunk.getNumEntries(); } /** * @return the number of levels in this block index. */ public int getNumLevels() { return numLevels; } private void expectNumLevels(int expectedNumLevels) { if (numLevels != expectedNumLevels) { throw new IllegalStateException("Number of block index levels is " + numLevels + "but is expected to be " + expectedNumLevels); } } /** * Whether there is an inline block ready to be written. In general, we * write an leaf-level index block as an inline block as soon as its size * as serialized in the non-root format reaches a certain threshold. */ @Override public boolean shouldWriteBlock(boolean closing) { if (singleLevelOnly) { throw new UnsupportedOperationException(INLINE_BLOCKS_NOT_ALLOWED); } if (curInlineChunk == null) { throw new IllegalStateException("curInlineChunk is null; has shouldWriteBlock been " + "called with closing=true and then called again?"); } if (curInlineChunk.getNumEntries() == 0) { return false; } // We do have some entries in the current inline chunk. if (closing) { if (rootChunk.getNumEntries() == 0) { // We did not add any leaf-level blocks yet. Instead of creating a // leaf level with one block, move these entries to the root level. expectNumLevels(1); rootChunk = curInlineChunk; curInlineChunk = null; // Disallow adding any more index entries. return false; } return true; } else { return curInlineChunk.getNonRootSize() >= maxChunkSize; } } /** * Write out the current inline index block. Inline blocks are non-root * blocks, so the non-root index format is used. * * @param out */ @Override public void writeInlineBlock(DataOutput out) throws IOException { if (singleLevelOnly) throw new UnsupportedOperationException(INLINE_BLOCKS_NOT_ALLOWED); // Write the inline block index to the output stream in the non-root // index block format. curInlineChunk.writeNonRoot(out); // Save the first key of the inline block so that we can add it to the // parent-level index. firstKey = curInlineChunk.getBlockKey(0); // Start a new inline index block curInlineChunk.clear(); } /** * Called after an inline block has been written so that we can add an * entry referring to that block to the parent-level index. */ @Override public void blockWritten(long offset, int onDiskSize, int uncompressedSize) { // Add leaf index block size totalBlockOnDiskSize += onDiskSize; totalBlockUncompressedSize += uncompressedSize; if (singleLevelOnly) throw new UnsupportedOperationException(INLINE_BLOCKS_NOT_ALLOWED); if (firstKey == null) { throw new IllegalStateException("Trying to add second-level index " + "entry with offset=" + offset + " and onDiskSize=" + onDiskSize + "but the first key was not set in writeInlineBlock"); } if (rootChunk.getNumEntries() == 0) { // We are writing the first leaf block, so increase index level. expectNumLevels(1); numLevels = 2; } // Add another entry to the second-level index. Include the number of // entries in all previous leaf-level chunks for mid-key calculation. rootChunk.add(firstKey, offset, onDiskSize, totalNumEntries); firstKey = null; } @Override public BlockType getInlineBlockType() { return BlockType.LEAF_INDEX; } /** * Add one index entry to the current leaf-level block. When the leaf-level * block gets large enough, it will be flushed to disk as an inline block. * * @param firstKey the first key of the data block * @param blockOffset the offset of the data block * @param blockDataSize the on-disk size of the data block ({@link HFile} * format version 2), or the uncompressed size of the data block ( * {@link HFile} format version 1). */ public void addEntry(byte[] firstKey, long blockOffset, int blockDataSize) { curInlineChunk.add(firstKey, blockOffset, blockDataSize); ++totalNumEntries; } /** * @throws IOException if we happened to write a multi-level index. */ public void ensureSingleLevel() throws IOException { if (numLevels > 1) { throw new IOException ("Wrote a " + numLevels + "-level index with " + rootChunk.getNumEntries() + " root-level entries, but " + "this is expected to be a single-level block index."); } } /** * @return true if we are using cache-on-write. This is configured by the * caller of the constructor by either passing a valid block cache * or null. */ @Override public boolean getCacheOnWrite() { return cacheConf != null && cacheConf.shouldCacheIndexesOnWrite(); } /** * The total uncompressed size of the root index block, intermediate-level * index blocks, and leaf-level index blocks. * * @return the total uncompressed size of all index blocks */ public long getTotalUncompressedSize() { return totalBlockUncompressedSize; } } /** * A single chunk of the block index in the process of writing. The data in * this chunk can become a leaf-level, intermediate-level, or root index * block. */ static class BlockIndexChunk { /** First keys of the key range corresponding to each index entry. */ private final List blockKeys = new ArrayList(); /** Block offset in backing stream. */ private final List blockOffsets = new ArrayList(); /** On-disk data sizes of lower-level data or index blocks. */ private final List onDiskDataSizes = new ArrayList(); /** * The cumulative number of sub-entries, i.e. entries on deeper-level block * index entries. numSubEntriesAt[i] is the number of sub-entries in the * blocks corresponding to this chunk's entries #0 through #i inclusively. */ private final List numSubEntriesAt = new ArrayList(); /** * The offset of the next entry to be added, relative to the end of the * "secondary index" in the "non-root" format representation of this index * chunk. This is the next value to be added to the secondary index. */ private int curTotalNonRootEntrySize = 0; /** * The accumulated size of this chunk if stored in the root index format. */ private int curTotalRootSize = 0; /** * The "secondary index" used for binary search over variable-length * records in a "non-root" format block. These offsets are relative to the * end of this secondary index. */ private final List secondaryIndexOffsetMarks = new ArrayList(); /** * Adds a new entry to this block index chunk. * * @param firstKey the first key in the block pointed to by this entry * @param blockOffset the offset of the next-level block pointed to by this * entry * @param onDiskDataSize the on-disk data of the block pointed to by this * entry, including header size * @param curTotalNumSubEntries if this chunk is the root index chunk under * construction, this specifies the current total number of * sub-entries in all leaf-level chunks, including the one * corresponding to the second-level entry being added. */ void add(byte[] firstKey, long blockOffset, int onDiskDataSize, long curTotalNumSubEntries) { // Record the offset for the secondary index secondaryIndexOffsetMarks.add(curTotalNonRootEntrySize); curTotalNonRootEntrySize += SECONDARY_INDEX_ENTRY_OVERHEAD + firstKey.length; curTotalRootSize += Bytes.SIZEOF_LONG + Bytes.SIZEOF_INT + WritableUtils.getVIntSize(firstKey.length) + firstKey.length; blockKeys.add(firstKey); blockOffsets.add(blockOffset); onDiskDataSizes.add(onDiskDataSize); if (curTotalNumSubEntries != -1) { numSubEntriesAt.add(curTotalNumSubEntries); // Make sure the parallel arrays are in sync. if (numSubEntriesAt.size() != blockKeys.size()) { throw new IllegalStateException("Only have key/value count " + "stats for " + numSubEntriesAt.size() + " block index " + "entries out of " + blockKeys.size()); } } } /** * The same as {@link #add(byte[], long, int, long)} but does not take the * key/value into account. Used for single-level indexes. * * @see {@link #add(byte[], long, int, long)} */ public void add(byte[] firstKey, long blockOffset, int onDiskDataSize) { add(firstKey, blockOffset, onDiskDataSize, -1); } public void clear() { blockKeys.clear(); blockOffsets.clear(); onDiskDataSizes.clear(); secondaryIndexOffsetMarks.clear(); numSubEntriesAt.clear(); curTotalNonRootEntrySize = 0; curTotalRootSize = 0; } /** * Finds the entry corresponding to the deeper-level index block containing * the given deeper-level entry (a "sub-entry"), assuming a global 0-based * ordering of sub-entries. * *

* Implementation note. We are looking for i such that * numSubEntriesAt[i - 1] <= k < numSubEntriesAt[i], because a deeper-level * block #i (0-based) contains sub-entries # numSubEntriesAt[i - 1]'th * through numSubEntriesAt[i] - 1, assuming a global 0-based ordering of * sub-entries. i is by definition the insertion point of k in * numSubEntriesAt. * * @param k sub-entry index, from 0 to the total number sub-entries - 1 * @return the 0-based index of the entry corresponding to the given * sub-entry */ public int getEntryBySubEntry(long k) { // We define mid-key as the key corresponding to k'th sub-entry // (0-based). int i = Collections.binarySearch(numSubEntriesAt, k); // Exact match: cumulativeWeight[i] = k. This means chunks #0 through // #i contain exactly k sub-entries, and the sub-entry #k (0-based) // is in the (i + 1)'th chunk. if (i >= 0) return i + 1; // Inexact match. Return the insertion point. return -i - 1; } /** * Used when writing the root block index of a multi-level block index. * Serializes additional information allowing to efficiently identify the * mid-key. * * @return a few serialized fields for finding the mid-key * @throws IOException if could not create metadata for computing mid-key */ public byte[] getMidKeyMetadata() throws IOException { ByteArrayOutputStream baos = new ByteArrayOutputStream( MID_KEY_METADATA_SIZE); DataOutputStream baosDos = new DataOutputStream(baos); long totalNumSubEntries = numSubEntriesAt.get(blockKeys.size() - 1); if (totalNumSubEntries == 0) { throw new IOException("No leaf-level entries, mid-key unavailable"); } long midKeySubEntry = (totalNumSubEntries - 1) / 2; int midKeyEntry = getEntryBySubEntry(midKeySubEntry); baosDos.writeLong(blockOffsets.get(midKeyEntry)); baosDos.writeInt(onDiskDataSizes.get(midKeyEntry)); long numSubEntriesBefore = midKeyEntry > 0 ? numSubEntriesAt.get(midKeyEntry - 1) : 0; long subEntryWithinEntry = midKeySubEntry - numSubEntriesBefore; if (subEntryWithinEntry < 0 || subEntryWithinEntry > Integer.MAX_VALUE) { throw new IOException("Could not identify mid-key index within the " + "leaf-level block containing mid-key: out of range (" + subEntryWithinEntry + ", numSubEntriesBefore=" + numSubEntriesBefore + ", midKeySubEntry=" + midKeySubEntry + ")"); } baosDos.writeInt((int) subEntryWithinEntry); if (baosDos.size() != MID_KEY_METADATA_SIZE) { throw new IOException("Could not write mid-key metadata: size=" + baosDos.size() + ", correct size: " + MID_KEY_METADATA_SIZE); } // Close just to be good citizens, although this has no effect. baos.close(); return baos.toByteArray(); } /** * Writes the block index chunk in the non-root index block format. This * format contains the number of entries, an index of integer offsets * for quick binary search on variable-length records, and tuples of * block offset, on-disk block size, and the first key for each entry. * * @param out * @throws IOException */ void writeNonRoot(DataOutput out) throws IOException { // The number of entries in the block. out.writeInt(blockKeys.size()); if (secondaryIndexOffsetMarks.size() != blockKeys.size()) { throw new IOException("Corrupted block index chunk writer: " + blockKeys.size() + " entries but " + secondaryIndexOffsetMarks.size() + " secondary index items"); } // For each entry, write a "secondary index" of relative offsets to the // entries from the end of the secondary index. This works, because at // read time we read the number of entries and know where the secondary // index ends. for (int currentSecondaryIndex : secondaryIndexOffsetMarks) out.writeInt(currentSecondaryIndex); // We include one other element in the secondary index to calculate the // size of each entry more easily by subtracting secondary index elements. out.writeInt(curTotalNonRootEntrySize); for (int i = 0; i < blockKeys.size(); ++i) { out.writeLong(blockOffsets.get(i)); out.writeInt(onDiskDataSizes.get(i)); out.write(blockKeys.get(i)); } } /** * @return the size of this chunk if stored in the non-root index block * format */ int getNonRootSize() { return Bytes.SIZEOF_INT // Number of entries + Bytes.SIZEOF_INT * (blockKeys.size() + 1) // Secondary index + curTotalNonRootEntrySize; // All entries } /** * Writes this chunk into the given output stream in the root block index * format. This format is similar to the {@link HFile} version 1 block * index format, except that we store on-disk size of the block instead of * its uncompressed size. * * @param out the data output stream to write the block index to. Typically * a stream writing into an {@link HFile} block. * @throws IOException */ void writeRoot(DataOutput out) throws IOException { for (int i = 0; i < blockKeys.size(); ++i) { out.writeLong(blockOffsets.get(i)); out.writeInt(onDiskDataSizes.get(i)); Bytes.writeByteArray(out, blockKeys.get(i)); } } /** * @return the size of this chunk if stored in the root index block format */ int getRootSize() { return curTotalRootSize; } /** * @return the number of entries in this block index chunk */ public int getNumEntries() { return blockKeys.size(); } public byte[] getBlockKey(int i) { return blockKeys.get(i); } public long getBlockOffset(int i) { return blockOffsets.get(i); } public int getOnDiskDataSize(int i) { return onDiskDataSizes.get(i); } public long getCumulativeNumKV(int i) { if (i < 0) return 0; return numSubEntriesAt.get(i); } } public static int getMaxChunkSize(Configuration conf) { return conf.getInt(MAX_CHUNK_SIZE_KEY, DEFAULT_MAX_CHUNK_SIZE); } public static int getMinIndexNumEntries(Configuration conf) { return conf.getInt(MIN_INDEX_NUM_ENTRIES_KEY, DEFAULT_MIN_INDEX_NUM_ENTRIES); } }





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