/**
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.apache.hadoop.hdfs.server.datanode;
import java.io.BufferedInputStream;
import java.io.DataInputStream;
import java.io.DataOutputStream;
import java.io.FileDescriptor;
import java.io.FileInputStream;
import java.io.FileNotFoundException;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.net.SocketException;
import java.net.SocketTimeoutException;
import java.nio.ByteBuffer;
import java.nio.channels.FileChannel;
import java.util.Arrays;
import org.apache.commons.logging.Log;
import org.apache.hadoop.fs.ChecksumException;
import org.apache.hadoop.hdfs.protocol.ExtendedBlock;
import org.apache.hadoop.hdfs.protocol.HdfsConstants;
import org.apache.hadoop.hdfs.protocol.datatransfer.PacketHeader;
import org.apache.hadoop.hdfs.server.datanode.fsdataset.FsVolumeReference;
import org.apache.hadoop.hdfs.server.datanode.fsdataset.LengthInputStream;
import org.apache.hadoop.hdfs.util.DataTransferThrottler;
import org.apache.hadoop.io.IOUtils;
import org.apache.hadoop.io.LongWritable;
import org.apache.hadoop.io.ReadaheadPool.ReadaheadRequest;
import org.apache.hadoop.io.nativeio.NativeIO;
import org.apache.hadoop.net.SocketOutputStream;
import org.apache.hadoop.util.DataChecksum;
import org.apache.htrace.Sampler;
import org.apache.htrace.Trace;
import org.apache.htrace.TraceScope;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Preconditions;
/**
* Reads a block from the disk and sends it to a recipient.
*
* Data sent from the BlockeSender in the following format:
* <br><b>Data format:</b> <pre>
* +--------------------------------------------------+
* | ChecksumHeader | Sequence of data PACKETS... |
* +--------------------------------------------------+
* </pre>
* <b>ChecksumHeader format:</b> <pre>
* +--------------------------------------------------+
* | 1 byte CHECKSUM_TYPE | 4 byte BYTES_PER_CHECKSUM |
* +--------------------------------------------------+
* </pre>
* An empty packet is sent to mark the end of block and read completion.
*
* PACKET Contains a packet header, checksum and data. Amount of data
* carried is set by BUFFER_SIZE.
* <pre>
* +-----------------------------------------------------+
* | Variable length header. See {@link PacketHeader} |
* +-----------------------------------------------------+
* | x byte checksum data. x is defined below |
* +-----------------------------------------------------+
* | actual data ...... |
* +-----------------------------------------------------+
*
* Data is made of Chunks. Each chunk is of length <= BYTES_PER_CHECKSUM.
* A checksum is calculated for each chunk.
*
* x = (length of data + BYTE_PER_CHECKSUM - 1)/BYTES_PER_CHECKSUM *
* CHECKSUM_SIZE
*
* CHECKSUM_SIZE depends on CHECKSUM_TYPE (usually, 4 for CRC32)
* </pre>
*
* The client reads data until it receives a packet with
* "LastPacketInBlock" set to true or with a zero length. If there is
* no checksum error, it replies to DataNode with OP_STATUS_CHECKSUM_OK.
*/
class BlockSender implements java.io.Closeable {
static final Log LOG = DataNode.LOG;
static final Log ClientTraceLog = DataNode.ClientTraceLog;
private static final boolean is32Bit =
System.getProperty("sun.arch.data.model").equals("32");
/**
* Minimum buffer used while sending data to clients. Used only if
* transferTo() is enabled. 64KB is not that large. It could be larger, but
* not sure if there will be much more improvement.
*/
private static final int MIN_BUFFER_WITH_TRANSFERTO = 64*1024;
private static final int TRANSFERTO_BUFFER_SIZE = Math.max(
HdfsConstants.IO_FILE_BUFFER_SIZE, MIN_BUFFER_WITH_TRANSFERTO);
/** the block to read from */
private final ExtendedBlock block;
/** Stream to read block data from */
private InputStream blockIn;
/** updated while using transferTo() */
private long blockInPosition = -1;
/** Stream to read checksum */
private DataInputStream checksumIn;
/** Checksum utility */
private final DataChecksum checksum;
/** Initial position to read */
private long initialOffset;
/** Current position of read */
private long offset;
/** Position of last byte to read from block file */
private final long endOffset;
/** Number of bytes in chunk used for computing checksum */
private final int chunkSize;
/** Number bytes of checksum computed for a chunk */
private final int checksumSize;
/** If true, failure to read checksum is ignored */
private final boolean corruptChecksumOk;
/** Sequence number of packet being sent */
private long seqno;
/** Set to true if transferTo is allowed for sending data to the client */
private final boolean transferToAllowed;
/** Set to true once entire requested byte range has been sent to the client */
private boolean sentEntireByteRange;
/** When true, verify checksum while reading from checksum file */
private final boolean verifyChecksum;
/** Format used to print client trace log messages */
private final String clientTraceFmt;
private volatile ChunkChecksum lastChunkChecksum = null;
private DataNode datanode;
/** The file descriptor of the block being sent */
private FileDescriptor blockInFd;
/** The reference to the volume where the block is located */
private FsVolumeReference volumeRef;
// Cache-management related fields
private final long readaheadLength;
private ReadaheadRequest curReadahead;
private final boolean alwaysReadahead;
private final boolean dropCacheBehindLargeReads;
private final boolean dropCacheBehindAllReads;
private long lastCacheDropOffset;
@VisibleForTesting
static long CACHE_DROP_INTERVAL_BYTES = 1024 * 1024; // 1MB
/**
* See {{@link BlockSender#isLongRead()}
*/
private static final long LONG_READ_THRESHOLD_BYTES = 256 * 1024;
/**
* Constructor
*
* @param block Block that is being read
* @param startOffset starting offset to read from
* @param length length of data to read
* @param corruptChecksumOk if true, corrupt checksum is okay
* @param verifyChecksum verify checksum while reading the data
* @param sendChecksum send checksum to client.
* @param datanode datanode from which the block is being read
* @param clientTraceFmt format string used to print client trace logs
* @throws IOException
*/
BlockSender(ExtendedBlock block, long startOffset, long length,
boolean corruptChecksumOk, boolean verifyChecksum,
boolean sendChecksum, DataNode datanode, String clientTraceFmt,
CachingStrategy cachingStrategy)
throws IOException {
try {
this.block = block;
this.corruptChecksumOk = corruptChecksumOk;
this.verifyChecksum = verifyChecksum;
this.clientTraceFmt = clientTraceFmt;
/*
* If the client asked for the cache to be dropped behind all reads,
* we honor that. Otherwise, we use the DataNode defaults.
* When using DataNode defaults, we use a heuristic where we only
* drop the cache for large reads.
*/
if (cachingStrategy.getDropBehind() == null) {
this.dropCacheBehindAllReads = false;
this.dropCacheBehindLargeReads =
datanode.getDnConf().dropCacheBehindReads;
} else {
this.dropCacheBehindAllReads =
this.dropCacheBehindLargeReads =
cachingStrategy.getDropBehind().booleanValue();
}
/*
* Similarly, if readahead was explicitly requested, we always do it.
* Otherwise, we read ahead based on the DataNode settings, and only
* when the reads are large.
*/
if (cachingStrategy.getReadahead() == null) {
this.alwaysReadahead = false;
this.readaheadLength = datanode.getDnConf().readaheadLength;
} else {
this.alwaysReadahead = true;
this.readaheadLength = cachingStrategy.getReadahead().longValue();
}
this.datanode = datanode;
if (verifyChecksum) {
// To simplify implementation, callers may not specify verification
// without sending.
Preconditions.checkArgument(sendChecksum,
"If verifying checksum, currently must also send it.");
}
final Replica replica;
final long replicaVisibleLength;
synchronized(datanode.data) {
replica = getReplica(block, datanode);
replicaVisibleLength = replica.getVisibleLength();
}
// if there is a write in progress
ChunkChecksum chunkChecksum = null;
if (replica instanceof ReplicaBeingWritten) {
final ReplicaBeingWritten rbw = (ReplicaBeingWritten)replica;
waitForMinLength(rbw, startOffset + length);
chunkChecksum = rbw.getLastChecksumAndDataLen();
}
if (replica.getGenerationStamp() < block.getGenerationStamp()) {
throw new IOException("Replica gen stamp < block genstamp, block="
+ block + ", replica=" + replica);
} else if (replica.getGenerationStamp() > block.getGenerationStamp()) {
if (DataNode.LOG.isDebugEnabled()) {
DataNode.LOG.debug("Bumping up the client provided"
+ " block's genstamp to latest " + replica.getGenerationStamp()
+ " for block " + block);
}
block.setGenerationStamp(replica.getGenerationStamp());
}
if (replicaVisibleLength < 0) {
throw new IOException("Replica is not readable, block="
+ block + ", replica=" + replica);
}
if (DataNode.LOG.isDebugEnabled()) {
DataNode.LOG.debug("block=" + block + ", replica=" + replica);
}
// transferToFully() fails on 32 bit platforms for block sizes >= 2GB,
// use normal transfer in those cases
this.transferToAllowed = datanode.getDnConf().transferToAllowed &&
(!is32Bit || length <= Integer.MAX_VALUE);
// Obtain a reference before reading data
this.volumeRef = datanode.data.getVolume(block).obtainReference();
/*
* (corruptChecksumOK, meta_file_exist): operation
* True, True: will verify checksum
* True, False: No verify, e.g., need to read data from a corrupted file
* False, True: will verify checksum
* False, False: throws IOException file not found
*/
DataChecksum csum = null;
if (verifyChecksum || sendChecksum) {
LengthInputStream metaIn = null;
boolean keepMetaInOpen = false;
try {
metaIn = datanode.data.getMetaDataInputStream(block);
if (!corruptChecksumOk || metaIn != null) {
if (metaIn == null) {
//need checksum but meta-data not found
throw new FileNotFoundException("Meta-data not found for " +
block);
}
// The meta file will contain only the header if the NULL checksum
// type was used, or if the replica was written to transient storage.
// Checksum verification is not performed for replicas on transient
// storage. The header is important for determining the checksum
// type later when lazy persistence copies the block to non-transient
// storage and computes the checksum.
if (metaIn.getLength() > BlockMetadataHeader.getHeaderSize()) {
checksumIn = new DataInputStream(new BufferedInputStream(
metaIn, HdfsConstants.IO_FILE_BUFFER_SIZE));
csum = BlockMetadataHeader.readDataChecksum(checksumIn, block);
keepMetaInOpen = true;
}
} else {
LOG.warn("Could not find metadata file for " + block);
}
} finally {
if (!keepMetaInOpen) {
IOUtils.closeStream(metaIn);
}
}
}
if (csum == null) {
// The number of bytes per checksum here determines the alignment
// of reads: we always start reading at a checksum chunk boundary,
// even if the checksum type is NULL. So, choosing too big of a value
// would risk sending too much unnecessary data. 512 (1 disk sector)
// is likely to result in minimal extra IO.
csum = DataChecksum.newDataChecksum(DataChecksum.Type.NULL, 512);
}
/*
* If chunkSize is very large, then the metadata file is mostly
* corrupted. For now just truncate bytesPerchecksum to blockLength.
*/
int size = csum.getBytesPerChecksum();
if (size > 10*1024*1024 && size > replicaVisibleLength) {
csum = DataChecksum.newDataChecksum(csum.getChecksumType(),
Math.max((int)replicaVisibleLength, 10*1024*1024));
size = csum.getBytesPerChecksum();
}
chunkSize = size;
checksum = csum;
checksumSize = checksum.getChecksumSize();
length = length < 0 ? replicaVisibleLength : length;
// end is either last byte on disk or the length for which we have a
// checksum
long end = chunkChecksum != null ? chunkChecksum.getDataLength()
: replica.getBytesOnDisk();
if (startOffset < 0 || startOffset > end
|| (length + startOffset) > end) {
String msg = " Offset " + startOffset + " and length " + length
+ " don't match block " + block + " ( blockLen " + end + " )";
LOG.warn(datanode.getDNRegistrationForBP(block.getBlockPoolId()) +
":sendBlock() : " + msg);
throw new IOException(msg);
}
// Ensure read offset is position at the beginning of chunk
offset = startOffset - (startOffset % chunkSize);
if (length >= 0) {
// Ensure endOffset points to end of chunk.
long tmpLen = startOffset + length;
if (tmpLen % chunkSize != 0) {
tmpLen += (chunkSize - tmpLen % chunkSize);
}
if (tmpLen < end) {
// will use on-disk checksum here since the end is a stable chunk
end = tmpLen;
} else if (chunkChecksum != null) {
// last chunk is changing. flag that we need to use in-memory checksum
this.lastChunkChecksum = chunkChecksum;
}
}
endOffset = end;
// seek to the right offsets
if (offset > 0 && checksumIn != null) {
long checksumSkip = (offset / chunkSize) * checksumSize;
// note blockInStream is seeked when created below
if (checksumSkip > 0) {
// Should we use seek() for checksum file as well?
IOUtils.skipFully(checksumIn, checksumSkip);
}
}
seqno = 0;
if (DataNode.LOG.isDebugEnabled()) {
DataNode.LOG.debug("replica=" + replica);
}
blockIn = datanode.data.getBlockInputStream(block, offset); // seek to offset
if (blockIn instanceof FileInputStream) {
blockInFd = ((FileInputStream)blockIn).getFD();
} else {
blockInFd = null;
}
} catch (IOException ioe) {
IOUtils.closeStream(this);
IOUtils.closeStream(blockIn);
throw ioe;
}
}
/**
* close opened files.
*/
@Override
public void close() throws IOException {
if (blockInFd != null &&
((dropCacheBehindAllReads) ||
(dropCacheBehindLargeReads && isLongRead()))) {
try {
NativeIO.POSIX.getCacheManipulator().posixFadviseIfPossible(
block.getBlockName(), blockInFd, lastCacheDropOffset,
offset - lastCacheDropOffset,
NativeIO.POSIX.POSIX_FADV_DONTNEED);
} catch (Exception e) {
LOG.warn("Unable to drop cache on file close", e);
}
}
if (curReadahead != null) {
curReadahead.cancel();
}
IOException ioe = null;
if(checksumIn!=null) {
try {
checksumIn.close(); // close checksum file
} catch (IOException e) {
ioe = e;
}
checksumIn = null;
}
if(blockIn!=null) {
try {
blockIn.close(); // close data file
} catch (IOException e) {
ioe = e;
}
blockIn = null;
blockInFd = null;
}
if (volumeRef != null) {
IOUtils.cleanup(null, volumeRef);
volumeRef = null;
}
// throw IOException if there is any
if(ioe!= null) {
throw ioe;
}
}
private static Replica getReplica(ExtendedBlock block, DataNode datanode)
throws ReplicaNotFoundException {
Replica replica = datanode.data.getReplica(block.getBlockPoolId(),
block.getBlockId());
if (replica == null) {
throw new ReplicaNotFoundException(block);
}
return replica;
}
/**
* Wait for rbw replica to reach the length
* @param rbw replica that is being written to
* @param len minimum length to reach
* @throws IOException on failing to reach the len in given wait time
*/
private static void waitForMinLength(ReplicaBeingWritten rbw, long len)
throws IOException {
// Wait for 3 seconds for rbw replica to reach the minimum length
for (int i = 0; i < 30 && rbw.getBytesOnDisk() < len; i++) {
try {
Thread.sleep(100);
} catch (InterruptedException ie) {
throw new IOException(ie);
}
}
long bytesOnDisk = rbw.getBytesOnDisk();
if (bytesOnDisk < len) {
throw new IOException(
String.format("Need %d bytes, but only %d bytes available", len,
bytesOnDisk));
}
}
/**
* Converts an IOExcpetion (not subclasses) to SocketException.
* This is typically done to indicate to upper layers that the error
* was a socket error rather than often more serious exceptions like
* disk errors.
*/
private static IOException ioeToSocketException(IOException ioe) {
if (ioe.getClass().equals(IOException.class)) {
// "se" could be a new class in stead of SocketException.
IOException se = new SocketException("Original Exception : " + ioe);
se.initCause(ioe);
/* Change the stacktrace so that original trace is not truncated
* when printed.*/
se.setStackTrace(ioe.getStackTrace());
return se;
}
// otherwise just return the same exception.
return ioe;
}
/**
* @param datalen Length of data
* @return number of chunks for data of given size
*/
private int numberOfChunks(long datalen) {
return (int) ((datalen + chunkSize - 1)/chunkSize);
}
/**
* Sends a packet with up to maxChunks chunks of data.
*
* @param pkt buffer used for writing packet data
* @param maxChunks maximum number of chunks to send
* @param out stream to send data to
* @param transferTo use transferTo to send data
* @param throttler used for throttling data transfer bandwidth
*/
private int sendPacket(ByteBuffer pkt, int maxChunks, OutputStream out,
boolean transferTo, DataTransferThrottler throttler) throws IOException {
int dataLen = (int) Math.min(endOffset - offset,
(chunkSize * (long) maxChunks));
int numChunks = numberOfChunks(dataLen); // Number of chunks be sent in the packet
int checksumDataLen = numChunks * checksumSize;
int packetLen = dataLen + checksumDataLen + 4;
boolean lastDataPacket = offset + dataLen == endOffset && dataLen > 0;
// The packet buffer is organized as follows:
// _______HHHHCCCCD?D?D?D?
// ^ ^
// | \ checksumOff
// \ headerOff
// _ padding, since the header is variable-length
// H = header and length prefixes
// C = checksums
// D? = data, if transferTo is false.
int headerLen = writePacketHeader(pkt, dataLen, packetLen);
// Per above, the header doesn't start at the beginning of the
// buffer
int headerOff = pkt.position() - headerLen;
int checksumOff = pkt.position();
byte[] buf = pkt.array();
if (checksumSize > 0 && checksumIn != null) {
readChecksum(buf, checksumOff, checksumDataLen);
// write in progress that we need to use to get last checksum
if (lastDataPacket && lastChunkChecksum != null) {
int start = checksumOff + checksumDataLen - checksumSize;
byte[] updatedChecksum = lastChunkChecksum.getChecksum();
if (updatedChecksum != null) {
System.arraycopy(updatedChecksum, 0, buf, start, checksumSize);
}
}
}
int dataOff = checksumOff + checksumDataLen;
if (!transferTo) { // normal transfer
IOUtils.readFully(blockIn, buf, dataOff, dataLen);
if (verifyChecksum) {
verifyChecksum(buf, dataOff, dataLen, numChunks, checksumOff);
}
}
try {
if (transferTo) {
SocketOutputStream sockOut = (SocketOutputStream)out;
// First write header and checksums
sockOut.write(buf, headerOff, dataOff - headerOff);
// no need to flush since we know out is not a buffered stream
FileChannel fileCh = ((FileInputStream)blockIn).getChannel();
LongWritable waitTime = new LongWritable();
LongWritable transferTime = new LongWritable();
sockOut.transferToFully(fileCh, blockInPosition, dataLen,
waitTime, transferTime);
datanode.metrics.addSendDataPacketBlockedOnNetworkNanos(waitTime.get());
datanode.metrics.addSendDataPacketTransferNanos(transferTime.get());
blockInPosition += dataLen;
} else {
// normal transfer
out.write(buf, headerOff, dataOff + dataLen - headerOff);
}
} catch (IOException e) {
if (e instanceof SocketTimeoutException) {
/*
* writing to client timed out. This happens if the client reads
* part of a block and then decides not to read the rest (but leaves
* the socket open).
*
* Reporting of this case is done in DataXceiver#run
*/
} else {
/* Exception while writing to the client. Connection closure from
* the other end is mostly the case and we do not care much about
* it. But other things can go wrong, especially in transferTo(),
* which we do not want to ignore.
*
* The message parsing below should not be considered as a good
* coding example. NEVER do it to drive a program logic. NEVER.
* It was done here because the NIO throws an IOException for EPIPE.
*/
String ioem = e.getMessage();
if (!ioem.startsWith("Broken pipe") && !ioem.startsWith("Connection reset")) {
LOG.error("BlockSender.sendChunks() exception: ", e);
}
datanode.getBlockScanner().markSuspectBlock(
volumeRef.getVolume().getStorageID(),
block);
}
throw ioeToSocketException(e);
}
if (throttler != null) { // rebalancing so throttle
throttler.throttle(packetLen);
}
return dataLen;
}
/**
* Read checksum into given buffer
* @param buf buffer to read the checksum into
* @param checksumOffset offset at which to write the checksum into buf
* @param checksumLen length of checksum to write
* @throws IOException on error
*/
private void readChecksum(byte[] buf, final int checksumOffset,
final int checksumLen) throws IOException {
if (checksumSize <= 0 && checksumIn == null) {
return;
}
try {
checksumIn.readFully(buf, checksumOffset, checksumLen);
} catch (IOException e) {
LOG.warn(" Could not read or failed to veirfy checksum for data"
+ " at offset " + offset + " for block " + block, e);
IOUtils.closeStream(checksumIn);
checksumIn = null;
if (corruptChecksumOk) {
if (checksumOffset < checksumLen) {
// Just fill the array with zeros.
Arrays.fill(buf, checksumOffset, checksumLen, (byte) 0);
}
} else {
throw e;
}
}
}
/**
* Compute checksum for chunks and verify the checksum that is read from
* the metadata file is correct.
*
* @param buf buffer that has checksum and data
* @param dataOffset position where data is written in the buf
* @param datalen length of data
* @param numChunks number of chunks corresponding to data
* @param checksumOffset offset where checksum is written in the buf
* @throws ChecksumException on failed checksum verification
*/
public void verifyChecksum(final byte[] buf, final int dataOffset,
final int datalen, final int numChunks, final int checksumOffset)
throws ChecksumException {
int dOff = dataOffset;
int cOff = checksumOffset;
int dLeft = datalen;
for (int i = 0; i < numChunks; i++) {
checksum.reset();
int dLen = Math.min(dLeft, chunkSize);
checksum.update(buf, dOff, dLen);
if (!checksum.compare(buf, cOff)) {
long failedPos = offset + datalen - dLeft;
throw new ChecksumException("Checksum failed at " + failedPos,
failedPos);
}
dLeft -= dLen;
dOff += dLen;
cOff += checksumSize;
}
}
/**
* sendBlock() is used to read block and its metadata and stream the data to
* either a client or to another datanode.
*
* @param out stream to which the block is written to
* @param baseStream optional. if non-null, <code>out</code> is assumed to
* be a wrapper over this stream. This enables optimizations for
* sending the data, e.g.
* {@link SocketOutputStream#transferToFully(FileChannel,
* long, int)}.
* @param throttler for sending data.
* @return total bytes read, including checksum data.
*/
long sendBlock(DataOutputStream out, OutputStream baseStream,
DataTransferThrottler throttler) throws IOException {
TraceScope scope =
Trace.startSpan("sendBlock_" + block.getBlockId(), Sampler.NEVER);
try {
return doSendBlock(out, baseStream, throttler);
} finally {
scope.close();
}
}
private long doSendBlock(DataOutputStream out, OutputStream baseStream,
DataTransferThrottler throttler) throws IOException {
if (out == null) {
throw new IOException( "out stream is null" );
}
initialOffset = offset;
long totalRead = 0;
OutputStream streamForSendChunks = out;
lastCacheDropOffset = initialOffset;
if (isLongRead() && blockInFd != null) {
// Advise that this file descriptor will be accessed sequentially.
NativeIO.POSIX.getCacheManipulator().posixFadviseIfPossible(
block.getBlockName(), blockInFd, 0, 0,
NativeIO.POSIX.POSIX_FADV_SEQUENTIAL);
}
// Trigger readahead of beginning of file if configured.
manageOsCache();
final long startTime = ClientTraceLog.isDebugEnabled() ? System.nanoTime() : 0;
try {
int maxChunksPerPacket;
int pktBufSize = PacketHeader.PKT_MAX_HEADER_LEN;
boolean transferTo = transferToAllowed && !verifyChecksum
&& baseStream instanceof SocketOutputStream
&& blockIn instanceof FileInputStream;
if (transferTo) {
FileChannel fileChannel = ((FileInputStream)blockIn).getChannel();
blockInPosition = fileChannel.position();
streamForSendChunks = baseStream;
maxChunksPerPacket = numberOfChunks(TRANSFERTO_BUFFER_SIZE);
// Smaller packet size to only hold checksum when doing transferTo
pktBufSize += checksumSize * maxChunksPerPacket;
} else {
maxChunksPerPacket = Math.max(1,
numberOfChunks(HdfsConstants.IO_FILE_BUFFER_SIZE));
// Packet size includes both checksum and data
pktBufSize += (chunkSize + checksumSize) * maxChunksPerPacket;
}
ByteBuffer pktBuf = ByteBuffer.allocate(pktBufSize);
while (endOffset > offset && !Thread.currentThread().isInterrupted()) {
manageOsCache();
long len = sendPacket(pktBuf, maxChunksPerPacket, streamForSendChunks,
transferTo, throttler);
offset += len;
totalRead += len + (numberOfChunks(len) * checksumSize);
seqno++;
}
// If this thread was interrupted, then it did not send the full block.
if (!Thread.currentThread().isInterrupted()) {
try {
// send an empty packet to mark the end of the block
sendPacket(pktBuf, maxChunksPerPacket, streamForSendChunks, transferTo,
throttler);
out.flush();
} catch (IOException e) { //socket error
throw ioeToSocketException(e);
}
sentEntireByteRange = true;
}
} finally {
if ((clientTraceFmt != null) && ClientTraceLog.isDebugEnabled()) {
final long endTime = System.nanoTime();
ClientTraceLog.debug(String.format(clientTraceFmt, totalRead,
initialOffset, endTime - startTime));
}
close();
}
return totalRead;
}
/**
* Manage the OS buffer cache by performing read-ahead
* and drop-behind.
*/
private void manageOsCache() throws IOException {
// We can't manage the cache for this block if we don't have a file
// descriptor to work with.
if (blockInFd == null) return;
// Perform readahead if necessary
if ((readaheadLength > 0) && (datanode.readaheadPool != null) &&
(alwaysReadahead || isLongRead())) {
curReadahead = datanode.readaheadPool.readaheadStream(
clientTraceFmt, blockInFd, offset, readaheadLength, Long.MAX_VALUE,
curReadahead);
}
// Drop what we've just read from cache, since we aren't
// likely to need it again
if (dropCacheBehindAllReads ||
(dropCacheBehindLargeReads && isLongRead())) {
long nextCacheDropOffset = lastCacheDropOffset + CACHE_DROP_INTERVAL_BYTES;
if (offset >= nextCacheDropOffset) {
long dropLength = offset - lastCacheDropOffset;
NativeIO.POSIX.getCacheManipulator().posixFadviseIfPossible(
block.getBlockName(), blockInFd, lastCacheDropOffset,
dropLength, NativeIO.POSIX.POSIX_FADV_DONTNEED);
lastCacheDropOffset = offset;
}
}
}
/**
* Returns true if we have done a long enough read for this block to qualify
* for the DataNode-wide cache management defaults. We avoid applying the
* cache management defaults to smaller reads because the overhead would be
* too high.
*
* Note that if the client explicitly asked for dropBehind, we will do it
* even on short reads.
*
* This is also used to determine when to invoke
* posix_fadvise(POSIX_FADV_SEQUENTIAL).
*/
private boolean isLongRead() {
return (endOffset - initialOffset) > LONG_READ_THRESHOLD_BYTES;
}
/**
* Write packet header into {@code pkt},
* return the length of the header written.
*/
private int writePacketHeader(ByteBuffer pkt, int dataLen, int packetLen) {
pkt.clear();
// both syncBlock and syncPacket are false
PacketHeader header = new PacketHeader(packetLen, offset, seqno,
(dataLen == 0), dataLen, false);
int size = header.getSerializedSize();
pkt.position(PacketHeader.PKT_MAX_HEADER_LEN - size);
header.putInBuffer(pkt);
return size;
}
boolean didSendEntireByteRange() {
return sentEntireByteRange;
}
/**
* @return the checksum type that will be used with this block transfer.
*/
DataChecksum getChecksum() {
return checksum;
}
/**
* @return the offset into the block file where the sender is currently
* reading.
*/
long getOffset() {
return offset;
}
}
