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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.fs;

import java.io.EOFException;
import java.io.IOException;
import java.io.InputStream;
import java.util.zip.Checksum;

import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;
import org.apache.hadoop.classification.InterfaceAudience;
import org.apache.hadoop.classification.InterfaceStability;
import org.apache.hadoop.util.StringUtils;
import java.nio.ByteBuffer;
import java.nio.IntBuffer;

/**
 * This is a generic input stream for verifying checksums for
 * data before it is read by a user.
 */
@InterfaceAudience.LimitedPrivate({"HDFS"})
@InterfaceStability.Unstable
abstract public class FSInputChecker extends FSInputStream {
  public static final Log LOG 
  = LogFactory.getLog(FSInputChecker.class);
  
  /** The file name from which data is read from */
  protected Path file;
  private Checksum sum;
  private boolean verifyChecksum = true;
  private int maxChunkSize; // data bytes for checksum (eg 512)
  private byte[] buf; // buffer for non-chunk-aligned reading
  private byte[] checksum;
  private IntBuffer checksumInts; // wrapper on checksum buffer
  private int pos; // the position of the reader inside buf
  private int count; // the number of bytes currently in buf
  
  private int numOfRetries;
  
  // cached file position
  // this should always be a multiple of maxChunkSize
  private long chunkPos = 0;

  // Number of checksum chunks that can be read at once into a user
  // buffer. Chosen by benchmarks - higher values do not reduce
  // CPU usage. The size of the data reads made to the underlying stream
  // will be CHUNKS_PER_READ * maxChunkSize.
  private static final int CHUNKS_PER_READ = 32;
  protected static final int CHECKSUM_SIZE = 4; // 32-bit checksum

  /** Constructor
   * 
   * @param file The name of the file to be read
   * @param numOfRetries Number of read retries when ChecksumError occurs
   */
  protected FSInputChecker( Path file, int numOfRetries) {
    this.file = file;
    this.numOfRetries = numOfRetries;
  }
  
  /** Constructor
   * 
   * @param file The name of the file to be read
   * @param numOfRetries Number of read retries when ChecksumError occurs
   * @param sum the type of Checksum engine
   * @param chunkSize maximun chunk size
   * @param checksumSize the number byte of each checksum
   */
  protected FSInputChecker( Path file, int numOfRetries, 
      boolean verifyChecksum, Checksum sum, int chunkSize, int checksumSize ) {
    this(file, numOfRetries);
    set(verifyChecksum, sum, chunkSize, checksumSize);
  }
  
  /**
   * Reads in checksum chunks into buf at offset
   * and checksum into checksum.
   * Since checksums can be disabled, there are two cases implementors need
   * to worry about:
   *
   *  (a) needChecksum() will return false:
   *     - len can be any positive value
   *     - checksum will be null
   *     Implementors should simply pass through to the underlying data stream.
   * or
   *  (b) needChecksum() will return true:
   *    - len >= maxChunkSize
   *    - checksum.length is a multiple of CHECKSUM_SIZE
   *    Implementors should read an integer number of data chunks into
   *    buf. The amount read should be bounded by len or by 
   *    checksum.length / CHECKSUM_SIZE * maxChunkSize. Note that len may
   *    be a value that is not a multiple of maxChunkSize, in which case
   *    the implementation may return less than len.
   *
   * The method is used for implementing read, therefore, it should be optimized
   * for sequential reading.
   *
   * @param pos chunkPos
   * @param buf desitination buffer
   * @param offset offset in buf at which to store data
   * @param len maximum number of bytes to read
   * @param checksum the data buffer into which to write checksums
   * @return number of bytes read
   */
  abstract protected int readChunk(long pos, byte[] buf, int offset, int len,
      byte[] checksum) throws IOException;

  /** Return position of beginning of chunk containing pos. 
   *
   * @param pos a postion in the file
   * @return the starting position of the chunk which contains the byte
   */
  abstract protected long getChunkPosition(long pos);

  /** Return true if there is a need for checksum verification */
  protected synchronized boolean needChecksum() {
    return verifyChecksum && sum != null;
  }

  /**
   * Read one checksum-verified byte
   * 
   * @return     the next byte of data, or -1 if the end of the
   *             stream is reached.
   * @exception  IOException  if an I/O error occurs.
   */

  @Override
  public synchronized int read() throws IOException {
    if (pos >= count) {
      fill();
      if (pos >= count) {
        return -1;
      }
    }
    return buf[pos++] & 0xff;
  }
  
  /**
   * Read checksum verified bytes from this byte-input stream into 
   * the specified byte array, starting at the given offset.
   *
   * 

This method implements the general contract of the corresponding * {@link InputStream#read(byte[], int, int) read} method of * the {@link InputStream} class. As an additional * convenience, it attempts to read as many bytes as possible by repeatedly * invoking the read method of the underlying stream. This * iterated read continues until one of the following * conditions becomes true:

    * *
  • The specified number of bytes have been read, * *
  • The read method of the underlying stream returns * -1, indicating end-of-file. * *
If the first read on the underlying stream returns * -1 to indicate end-of-file then this method returns * -1. Otherwise this method returns the number of bytes * actually read. * * @param b destination buffer. * @param off offset at which to start storing bytes. * @param len maximum number of bytes to read. * @return the number of bytes read, or -1 if the end of * the stream has been reached. * @exception IOException if an I/O error occurs. * ChecksumException if any checksum error occurs */ @Override public synchronized int read(byte[] b, int off, int len) throws IOException { // parameter check if ((off | len | (off + len) | (b.length - (off + len))) < 0) { throw new IndexOutOfBoundsException(); } else if (len == 0) { return 0; } int n = 0; for (;;) { int nread = read1(b, off + n, len - n); if (nread <= 0) return (n == 0) ? nread : n; n += nread; if (n >= len) return n; } } /** * Fills the buffer with a chunk data. * No mark is supported. * This method assumes that all data in the buffer has already been read in, * hence pos > count. */ private void fill( ) throws IOException { assert(pos>=count); // fill internal buffer count = readChecksumChunk(buf, 0, maxChunkSize); if (count < 0) count = 0; } /* * Read characters into a portion of an array, reading from the underlying * stream at most once if necessary. */ private int read1(byte b[], int off, int len) throws IOException { int avail = count-pos; if( avail <= 0 ) { if(len >= maxChunkSize) { // read a chunk to user buffer directly; avoid one copy int nread = readChecksumChunk(b, off, len); return nread; } else { // read a chunk into the local buffer fill(); if( count <= 0 ) { return -1; } else { avail = count; } } } // copy content of the local buffer to the user buffer int cnt = (avail < len) ? avail : len; System.arraycopy(buf, pos, b, off, cnt); pos += cnt; return cnt; } /* Read up one or more checksum chunk to array b at pos off * It requires at least one checksum chunk boundary * in between * and it stops reading at the last boundary or at the end of the stream; * Otherwise an IllegalArgumentException is thrown. * This makes sure that all data read are checksum verified. * * @param b the buffer into which the data is read. * @param off the start offset in array b * at which the data is written. * @param len the maximum number of bytes to read. * @return the total number of bytes read into the buffer, or * -1 if there is no more data because the end of * the stream has been reached. * @throws IOException if an I/O error occurs. */ private int readChecksumChunk(byte b[], final int off, final int len) throws IOException { // invalidate buffer count = pos = 0; int read = 0; boolean retry = true; int retriesLeft = numOfRetries; do { retriesLeft--; try { read = readChunk(chunkPos, b, off, len, checksum); if( read > 0) { if( needChecksum() ) { verifySums(b, off, read); } chunkPos += read; } retry = false; } catch (ChecksumException ce) { LOG.info("Found checksum error: b[" + off + ", " + (off+read) + "]=" + StringUtils.byteToHexString(b, off, off + read), ce); if (retriesLeft == 0) { throw ce; } // try a new replica if (seekToNewSource(chunkPos)) { // Since at least one of the sources is different, // the read might succeed, so we'll retry. seek(chunkPos); } else { // Neither the data stream nor the checksum stream are being read // from different sources, meaning we'll still get a checksum error // if we try to do the read again. We throw an exception instead. throw ce; } } } while (retry); return read; } private void verifySums(final byte b[], final int off, int read) throws ChecksumException { int leftToVerify = read; int verifyOff = 0; checksumInts.rewind(); checksumInts.limit((read - 1)/maxChunkSize + 1); while (leftToVerify > 0) { sum.update(b, off + verifyOff, Math.min(leftToVerify, maxChunkSize)); int expected = checksumInts.get(); int calculated = (int)sum.getValue(); sum.reset(); if (expected != calculated) { long errPos = chunkPos + verifyOff; throw new ChecksumException( "Checksum error: "+file+" at "+ errPos + " exp: " + expected + " got: " + calculated, errPos); } leftToVerify -= maxChunkSize; verifyOff += maxChunkSize; } } /** * Convert a checksum byte array to a long * This is deprecated since 0.22 since it is no longer in use * by this class. */ @Deprecated static public long checksum2long(byte[] checksum) { long crc = 0L; for(int i=0; in
bytes of data from the * input stream. * *

This method may skip more bytes than are remaining in the backing * file. This produces no exception and the number of bytes skipped * may include some number of bytes that were beyond the EOF of the * backing file. Attempting to read from the stream after skipping past * the end will result in -1 indicating the end of the file. * *

If n is negative, no bytes are skipped. * * @param n the number of bytes to be skipped. * @return the actual number of bytes skipped. * @exception IOException if an I/O error occurs. * ChecksumException if the chunk to skip to is corrupted */ @Override public synchronized long skip(long n) throws IOException { if (n <= 0) { return 0; } seek(getPos()+n); return n; } /** * Seek to the given position in the stream. * The next read() will be from that position. * *

This method may seek past the end of the file. * This produces no exception and an attempt to read from * the stream will result in -1 indicating the end of the file. * * @param pos the postion to seek to. * @exception IOException if an I/O error occurs. * ChecksumException if the chunk to seek to is corrupted */ @Override public synchronized void seek(long pos) throws IOException { if( pos < 0 ) { throw new EOFException(FSExceptionMessages.NEGATIVE_SEEK); } // optimize: check if the pos is in the buffer long start = chunkPos - this.count; if( pos>=start && pos 0) { readFully(this, new byte[delta], 0, delta); } } /** * A utility function that tries to read up to len bytes from * stm * * @param stm an input stream * @param buf destiniation buffer * @param offset offset at which to store data * @param len number of bytes to read * @return actual number of bytes read * @throws IOException if there is any IO error */ protected static int readFully(InputStream stm, byte[] buf, int offset, int len) throws IOException { int n = 0; for (;;) { int nread = stm.read(buf, offset + n, len - n); if (nread <= 0) return (n == 0) ? nread : n; n += nread; if (n >= len) return n; } } /** * Set the checksum related parameters * @param verifyChecksum whether to verify checksum * @param sum which type of checksum to use * @param maxChunkSize maximun chunk size * @param checksumSize checksum size */ final protected synchronized void set(boolean verifyChecksum, Checksum sum, int maxChunkSize, int checksumSize) { // The code makes assumptions that checksums are always 32-bit. assert !verifyChecksum || sum == null || checksumSize == CHECKSUM_SIZE; this.maxChunkSize = maxChunkSize; this.verifyChecksum = verifyChecksum; this.sum = sum; this.buf = new byte[maxChunkSize]; // The size of the checksum array here determines how much we can // read in a single call to readChunk this.checksum = new byte[CHUNKS_PER_READ * checksumSize]; this.checksumInts = ByteBuffer.wrap(checksum).asIntBuffer(); this.count = 0; this.pos = 0; } @Override final public boolean markSupported() { return false; } @Override final public void mark(int readlimit) { } @Override final public void reset() throws IOException { throw new IOException("mark/reset not supported"); } /* reset this FSInputChecker's state */ private void resetState() { // invalidate buffer count = 0; pos = 0; // reset Checksum if (sum != null) { sum.reset(); } } }





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