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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.io.file.tfile;
import java.io.DataInput;
import java.io.DataOutput;
import java.io.IOException;
import java.util.Comparator;
import java.util.List;
import org.apache.hadoop.classification.InterfaceAudience;
import org.apache.hadoop.classification.InterfaceStability;
import org.apache.hadoop.io.Text;
/**
* Supporting Utility classes used by TFile, and shared by users of TFile.
*/
@InterfaceAudience.Public
@InterfaceStability.Evolving
public final class Utils {
/**
* Prevent the instantiation of Utils.
*/
private Utils() {
// nothing
}
/**
* Encoding an integer into a variable-length encoding format. Synonymous to
* Utils#writeVLong(out, n)
.
*
* @param out
* output stream
* @param n
* The integer to be encoded
* @throws IOException
* @see Utils#writeVLong(DataOutput, long)
*/
public static void writeVInt(DataOutput out, int n) throws IOException {
writeVLong(out, n);
}
/**
* Encoding a Long integer into a variable-length encoding format.
*
* - if n in [-32, 127): encode in one byte with the actual value.
* Otherwise,
*
- if n in [-20*2^8, 20*2^8): encode in two bytes: byte[0] = n/256 - 52;
* byte[1]=n&0xff. Otherwise,
*
- if n IN [-16*2^16, 16*2^16): encode in three bytes: byte[0]=n/2^16 -
* 88; byte[1]=(n>>8)&0xff; byte[2]=n&0xff. Otherwise,
*
- if n in [-8*2^24, 8*2^24): encode in four bytes: byte[0]=n/2^24 - 112;
* byte[1] = (n>>16)&0xff; byte[2] = (n>>8)&0xff; byte[3]=n&0xff. Otherwise:
*
- if n in [-2^31, 2^31): encode in five bytes: byte[0]=-125; byte[1] =
* (n>>24)&0xff; byte[2]=(n>>16)&0xff; byte[3]=(n>>8)&0xff; byte[4]=n&0xff;
*
- if n in [-2^39, 2^39): encode in six bytes: byte[0]=-124; byte[1] =
* (n>>32)&0xff; byte[2]=(n>>24)&0xff; byte[3]=(n>>16)&0xff;
* byte[4]=(n>>8)&0xff; byte[5]=n&0xff
*
- if n in [-2^47, 2^47): encode in seven bytes: byte[0]=-123; byte[1] =
* (n>>40)&0xff; byte[2]=(n>>32)&0xff; byte[3]=(n>>24)&0xff;
* byte[4]=(n>>16)&0xff; byte[5]=(n>>8)&0xff; byte[6]=n&0xff;
*
- if n in [-2^55, 2^55): encode in eight bytes: byte[0]=-122; byte[1] =
* (n>>48)&0xff; byte[2] = (n>>40)&0xff; byte[3]=(n>>32)&0xff;
* byte[4]=(n>>24)&0xff; byte[5]=(n>>16)&0xff; byte[6]=(n>>8)&0xff;
* byte[7]=n&0xff;
*
- if n in [-2^63, 2^63): encode in nine bytes: byte[0]=-121; byte[1] =
* (n>>54)&0xff; byte[2] = (n>>48)&0xff; byte[3] = (n>>40)&0xff;
* byte[4]=(n>>32)&0xff; byte[5]=(n>>24)&0xff; byte[6]=(n>>16)&0xff;
* byte[7]=(n>>8)&0xff; byte[8]=n&0xff;
*
*
* @param out
* output stream
* @param n
* the integer number
* @throws IOException
*/
@SuppressWarnings("fallthrough")
public static void writeVLong(DataOutput out, long n) throws IOException {
if ((n < 128) && (n >= -32)) {
out.writeByte((int) n);
return;
}
long un = (n < 0) ? ~n : n;
// how many bytes do we need to represent the number with sign bit?
int len = (Long.SIZE - Long.numberOfLeadingZeros(un)) / 8 + 1;
int firstByte = (int) (n >> ((len - 1) * 8));
switch (len) {
case 1:
// fall it through to firstByte==-1, len=2.
firstByte >>= 8;
case 2:
if ((firstByte < 20) && (firstByte >= -20)) {
out.writeByte(firstByte - 52);
out.writeByte((int) n);
return;
}
// fall it through to firstByte==0/-1, len=3.
firstByte >>= 8;
case 3:
if ((firstByte < 16) && (firstByte >= -16)) {
out.writeByte(firstByte - 88);
out.writeShort((int) n);
return;
}
// fall it through to firstByte==0/-1, len=4.
firstByte >>= 8;
case 4:
if ((firstByte < 8) && (firstByte >= -8)) {
out.writeByte(firstByte - 112);
out.writeShort(((int) n) >>> 8);
out.writeByte((int) n);
return;
}
out.writeByte(len - 129);
out.writeInt((int) n);
return;
case 5:
out.writeByte(len - 129);
out.writeInt((int) (n >>> 8));
out.writeByte((int) n);
return;
case 6:
out.writeByte(len - 129);
out.writeInt((int) (n >>> 16));
out.writeShort((int) n);
return;
case 7:
out.writeByte(len - 129);
out.writeInt((int) (n >>> 24));
out.writeShort((int) (n >>> 8));
out.writeByte((int) n);
return;
case 8:
out.writeByte(len - 129);
out.writeLong(n);
return;
default:
throw new RuntimeException("Internel error");
}
}
/**
* Decoding the variable-length integer. Synonymous to
* (int)Utils#readVLong(in)
.
*
* @param in
* input stream
* @return the decoded integer
* @throws IOException
*
* @see Utils#readVLong(DataInput)
*/
public static int readVInt(DataInput in) throws IOException {
long ret = readVLong(in);
if ((ret > Integer.MAX_VALUE) || (ret < Integer.MIN_VALUE)) {
throw new RuntimeException(
"Number too large to be represented as Integer");
}
return (int) ret;
}
/**
* Decoding the variable-length integer. Suppose the value of the first byte
* is FB, and the following bytes are NB[*].
*
* - if (FB >= -32), return (long)FB;
*
- if (FB in [-72, -33]), return (FB+52)<<8 + NB[0]&0xff;
*
- if (FB in [-104, -73]), return (FB+88)<<16 + (NB[0]&0xff)<<8 +
* NB[1]&0xff;
*
- if (FB in [-120, -105]), return (FB+112)<<24 + (NB[0]&0xff)<<16 +
* (NB[1]&0xff)<<8 + NB[2]&0xff;
*
- if (FB in [-128, -121]), return interpret NB[FB+129] as a signed
* big-endian integer.
*
* @param in
* input stream
* @return the decoded long integer.
* @throws IOException
*/
public static long readVLong(DataInput in) throws IOException {
int firstByte = in.readByte();
if (firstByte >= -32) {
return firstByte;
}
switch ((firstByte + 128) / 8) {
case 11:
case 10:
case 9:
case 8:
case 7:
return ((firstByte + 52) << 8) | in.readUnsignedByte();
case 6:
case 5:
case 4:
case 3:
return ((firstByte + 88) << 16) | in.readUnsignedShort();
case 2:
case 1:
return ((firstByte + 112) << 24) | (in.readUnsignedShort() << 8)
| in.readUnsignedByte();
case 0:
int len = firstByte + 129;
switch (len) {
case 4:
return in.readInt();
case 5:
return ((long) in.readInt()) << 8 | in.readUnsignedByte();
case 6:
return ((long) in.readInt()) << 16 | in.readUnsignedShort();
case 7:
return ((long) in.readInt()) << 24 | (in.readUnsignedShort() << 8)
| in.readUnsignedByte();
case 8:
return in.readLong();
default:
throw new IOException("Corrupted VLong encoding");
}
default:
throw new RuntimeException("Internal error");
}
}
/**
* Write a String as a VInt n, followed by n Bytes as in Text format.
*
* @param out
* @param s
* @throws IOException
*/
public static void writeString(DataOutput out, String s) throws IOException {
if (s != null) {
Text text = new Text(s);
byte[] buffer = text.getBytes();
int len = text.getLength();
writeVInt(out, len);
out.write(buffer, 0, len);
} else {
writeVInt(out, -1);
}
}
/**
* Read a String as a VInt n, followed by n Bytes in Text format.
*
* @param in
* The input stream.
* @return The string
* @throws IOException
*/
public static String readString(DataInput in) throws IOException {
int length = readVInt(in);
if (length == -1) return null;
byte[] buffer = new byte[length];
in.readFully(buffer);
return Text.decode(buffer);
}
/**
* A generic Version class. We suggest applications built on top of TFile use
* this class to maintain version information in their meta blocks.
*
* A version number consists of a major version and a minor version. The
* suggested usage of major and minor version number is to increment major
* version number when the new storage format is not backward compatible, and
* increment the minor version otherwise.
*/
public static final class Version implements Comparable
{
private final short major;
private final short minor;
/**
* Construct the Version object by reading from the input stream.
*
* @param in
* input stream
* @throws IOException
*/
public Version(DataInput in) throws IOException {
major = in.readShort();
minor = in.readShort();
}
/**
* Constructor.
*
* @param major
* major version.
* @param minor
* minor version.
*/
public Version(short major, short minor) {
this.major = major;
this.minor = minor;
}
/**
* Write the objec to a DataOutput. The serialized format of the Version is
* major version followed by minor version, both as big-endian short
* integers.
*
* @param out
* The DataOutput object.
* @throws IOException
*/
public void write(DataOutput out) throws IOException {
out.writeShort(major);
out.writeShort(minor);
}
/**
* Get the major version.
*
* @return Major version.
*/
public int getMajor() {
return major;
}
/**
* Get the minor version.
*
* @return The minor version.
*/
public int getMinor() {
return minor;
}
/**
* Get the size of the serialized Version object.
*
* @return serialized size of the version object.
*/
public static int size() {
return (Short.SIZE + Short.SIZE) / Byte.SIZE;
}
/**
* Return a string representation of the version.
*/
@Override
public String toString() {
return new StringBuilder("v").append(major).append(".").append(minor)
.toString();
}
/**
* Test compatibility.
*
* @param other
* The Version object to test compatibility with.
* @return true if both versions have the same major version number; false
* otherwise.
*/
public boolean compatibleWith(Version other) {
return major == other.major;
}
/**
* Compare this version with another version.
*/
@Override
public int compareTo(Version that) {
if (major != that.major) {
return major - that.major;
}
return minor - that.minor;
}
@Override
public boolean equals(Object other) {
if (this == other) return true;
if (!(other instanceof Version)) return false;
return compareTo((Version) other) == 0;
}
@Override
public int hashCode() {
return (major << 16 + minor);
}
}
/**
* Lower bound binary search. Find the index to the first element in the list
* that compares greater than or equal to key.
*
* @param
* Type of the input key.
* @param list
* The list
* @param key
* The input key.
* @param cmp
* Comparator for the key.
* @return The index to the desired element if it exists; or list.size()
* otherwise.
*/
public static int lowerBound(List extends T> list, T key,
Comparator super T> cmp) {
int low = 0;
int high = list.size();
while (low < high) {
int mid = (low + high) >>> 1;
T midVal = list.get(mid);
int ret = cmp.compare(midVal, key);
if (ret < 0)
low = mid + 1;
else high = mid;
}
return low;
}
/**
* Upper bound binary search. Find the index to the first element in the list
* that compares greater than the input key.
*
* @param
* Type of the input key.
* @param list
* The list
* @param key
* The input key.
* @param cmp
* Comparator for the key.
* @return The index to the desired element if it exists; or list.size()
* otherwise.
*/
public static int upperBound(List extends T> list, T key,
Comparator super T> cmp) {
int low = 0;
int high = list.size();
while (low < high) {
int mid = (low + high) >>> 1;
T midVal = list.get(mid);
int ret = cmp.compare(midVal, key);
if (ret <= 0)
low = mid + 1;
else high = mid;
}
return low;
}
/**
* Lower bound binary search. Find the index to the first element in the list
* that compares greater than or equal to key.
*
* @param
* Type of the input key.
* @param list
* The list
* @param key
* The input key.
* @return The index to the desired element if it exists; or list.size()
* otherwise.
*/
public static int lowerBound(List extends Comparable super T>> list,
T key) {
int low = 0;
int high = list.size();
while (low < high) {
int mid = (low + high) >>> 1;
Comparable super T> midVal = list.get(mid);
int ret = midVal.compareTo(key);
if (ret < 0)
low = mid + 1;
else high = mid;
}
return low;
}
/**
* Upper bound binary search. Find the index to the first element in the list
* that compares greater than the input key.
*
* @param
* Type of the input key.
* @param list
* The list
* @param key
* The input key.
* @return The index to the desired element if it exists; or list.size()
* otherwise.
*/
public static int upperBound(List extends Comparable super T>> list,
T key) {
int low = 0;
int high = list.size();
while (low < high) {
int mid = (low + high) >>> 1;
Comparable super T> midVal = list.get(mid);
int ret = midVal.compareTo(key);
if (ret <= 0)
low = mid + 1;
else high = mid;
}
return low;
}
}