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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.hive.serde2.lazybinary;
import java.util.ArrayList;
import java.util.List;
import java.util.concurrent.ConcurrentHashMap;
import org.apache.hadoop.hive.serde2.ByteStream.RandomAccessOutput;
import org.apache.hadoop.hive.serde2.io.TimestampLocalTZWritable;
import org.apache.hadoop.hive.serde2.io.TimestampWritable;
import org.apache.hadoop.hive.serde2.lazybinary.objectinspector.LazyBinaryObjectInspectorFactory;
import org.apache.hadoop.hive.serde2.objectinspector.ObjectInspector;
import org.apache.hadoop.hive.serde2.objectinspector.ObjectInspector.Category;
import org.apache.hadoop.hive.serde2.objectinspector.PrimitiveObjectInspector;
import org.apache.hadoop.hive.serde2.objectinspector.PrimitiveObjectInspector.PrimitiveCategory;
import org.apache.hadoop.hive.serde2.objectinspector.primitive.PrimitiveObjectInspectorFactory;
import org.apache.hadoop.hive.serde2.typeinfo.ListTypeInfo;
import org.apache.hadoop.hive.serde2.typeinfo.MapTypeInfo;
import org.apache.hadoop.hive.serde2.typeinfo.PrimitiveTypeInfo;
import org.apache.hadoop.hive.serde2.typeinfo.StructTypeInfo;
import org.apache.hadoop.hive.serde2.typeinfo.TypeInfo;
import org.apache.hadoop.hive.serde2.typeinfo.UnionTypeInfo;
import org.apache.hadoop.io.WritableUtils;
/**
* LazyBinaryUtils.
*
*/
public final class LazyBinaryUtils {
/**
* Convert the byte array to an int starting from the given offset. Refer to
* code by aeden on DZone Snippets:
*
* @param b
* the byte array
* @param offset
* the array offset
* @return the integer
*/
public static int byteArrayToInt(byte[] b, int offset) {
int value = 0;
for (int i = 0; i < 4; i++) {
int shift = (4 - 1 - i) * 8;
value += (b[i + offset] & 0x000000FF) << shift;
}
return value;
}
/**
* Convert the byte array to a long starting from the given offset.
*
* @param b
* the byte array
* @param offset
* the array offset
* @return the long
*/
public static long byteArrayToLong(byte[] b, int offset) {
long value = 0;
for (int i = 0; i < 8; i++) {
int shift = (8 - 1 - i) * 8;
value += ((long) (b[i + offset] & 0x00000000000000FF)) << shift;
}
return value;
}
/**
* Convert the byte array to a short starting from the given offset.
*
* @param b
* the byte array
* @param offset
* the array offset
* @return the short
*/
public static short byteArrayToShort(byte[] b, int offset) {
short value = 0;
value += (b[offset] & 0x000000FF) << 8;
value += (b[offset + 1] & 0x000000FF);
return value;
}
/**
* Record is the unit that data is serialized in. A record includes two parts.
* The first part stores the size of the element and the second part stores
* the real element. size element record -> |----|-------------------------|
*
* A RecordInfo stores two information of a record, the size of the "size"
* part which is the element offset and the size of the element part which is
* element size.
*/
public static class RecordInfo {
public RecordInfo() {
elementOffset = 0;
elementSize = 0;
}
public byte elementOffset;
public int elementSize;
@Override
public String toString() {
return "(" + elementOffset + ", " + elementSize + ")";
}
}
/**
* Check a particular field and set its size and offset in bytes based on the
* field type and the bytes arrays.
*
* For void, boolean, byte, short, int, long, float and double, there is no
* offset and the size is fixed. For string, map, list, struct, the first four
* bytes are used to store the size. So the offset is 4 and the size is
* computed by concating the first four bytes together. The first four bytes
* are defined with respect to the offset in the bytes arrays.
* For timestamp, if the first bit is 0, the record length is 4, otherwise
* a VInt begins at the 5th byte and its length is added to 4.
*
* @param objectInspector
* object inspector of the field
* @param bytes
* bytes arrays store the table row
* @param offset
* offset of this field
* @param recordInfo
* modify this byteinfo object and return it
*/
public static void checkObjectByteInfo(ObjectInspector objectInspector,
byte[] bytes, int offset, RecordInfo recordInfo, VInt vInt) {
Category category = objectInspector.getCategory();
switch (category) {
case PRIMITIVE:
PrimitiveCategory primitiveCategory = ((PrimitiveObjectInspector) objectInspector)
.getPrimitiveCategory();
switch (primitiveCategory) {
case VOID:
recordInfo.elementOffset = 0;
recordInfo.elementSize = 0;
break;
case BOOLEAN:
case BYTE:
recordInfo.elementOffset = 0;
recordInfo.elementSize = 1;
break;
case SHORT:
recordInfo.elementOffset = 0;
recordInfo.elementSize = 2;
break;
case FLOAT:
recordInfo.elementOffset = 0;
recordInfo.elementSize = 4;
break;
case DOUBLE:
recordInfo.elementOffset = 0;
recordInfo.elementSize = 8;
break;
case INT:
recordInfo.elementOffset = 0;
recordInfo.elementSize = WritableUtils.decodeVIntSize(bytes[offset]);
break;
case LONG:
recordInfo.elementOffset = 0;
recordInfo.elementSize = WritableUtils.decodeVIntSize(bytes[offset]);
break;
case STRING:
// using vint instead of 4 bytes
LazyBinaryUtils.readVInt(bytes, offset, vInt);
recordInfo.elementOffset = vInt.length;
recordInfo.elementSize = vInt.value;
break;
case CHAR:
case VARCHAR:
LazyBinaryUtils.readVInt(bytes, offset, vInt);
recordInfo.elementOffset = vInt.length;
recordInfo.elementSize = vInt.value;
break;
case BINARY:
// using vint instead of 4 bytes
LazyBinaryUtils.readVInt(bytes, offset, vInt);
recordInfo.elementOffset = vInt.length;
recordInfo.elementSize = vInt.value;
break;
case DATE:
recordInfo.elementOffset = 0;
recordInfo.elementSize = WritableUtils.decodeVIntSize(bytes[offset]);
break;
case TIMESTAMP:
recordInfo.elementOffset = 0;
recordInfo.elementSize = TimestampWritable.getTotalLength(bytes, offset);
break;
case TIMESTAMPLOCALTZ:
recordInfo.elementOffset = 0;
recordInfo.elementSize = TimestampLocalTZWritable.getTotalLength(bytes, offset);
break;
case INTERVAL_YEAR_MONTH:
recordInfo.elementOffset = 0;
recordInfo.elementSize = WritableUtils.decodeVIntSize(bytes[offset]);
break;
case INTERVAL_DAY_TIME:
recordInfo.elementOffset = 0;
int secondsSize = WritableUtils.decodeVIntSize(bytes[offset]);
int nanosSize = WritableUtils.decodeVIntSize(bytes[offset + secondsSize]);
recordInfo.elementSize = secondsSize + nanosSize;
break;
case DECIMAL:
// using vint instead of 4 bytes
LazyBinaryUtils.readVInt(bytes, offset, vInt);
recordInfo.elementOffset = 0;
recordInfo.elementSize = vInt.length;
LazyBinaryUtils.readVInt(bytes, offset + vInt.length, vInt);
recordInfo.elementSize += vInt.length + vInt.value;
break;
default: {
throw new RuntimeException("Unrecognized primitive type: "
+ primitiveCategory);
}
}
break;
case LIST:
case MAP:
case STRUCT:
case UNION:
recordInfo.elementOffset = 4;
recordInfo.elementSize = LazyBinaryUtils.byteArrayToInt(bytes, offset);
break;
default: {
throw new RuntimeException("Unrecognized non-primitive type: " + category);
}
}
}
/**
* A zero-compressed encoded long.
*/
public static class VLong {
public VLong() {
value = 0;
length = 0;
}
public long value;
public byte length;
};
/**
* Reads a zero-compressed encoded long from a byte array and returns it.
*
* @param bytes
* the byte array
* @param offset
* offset of the array to read from
* @param vlong
* storing the deserialized long and its size in byte
*/
public static void readVLong(byte[] bytes, int offset, VLong vlong) {
byte firstByte = bytes[offset];
vlong.length = (byte) WritableUtils.decodeVIntSize(firstByte);
if (vlong.length == 1) {
vlong.value = firstByte;
return;
}
long i = 0;
for (int idx = 0; idx < vlong.length - 1; idx++) {
byte b = bytes[offset + 1 + idx];
i = i << 8;
i = i | (b & 0xFF);
}
vlong.value = (WritableUtils.isNegativeVInt(firstByte) ? (i ^ -1L) : i);
}
/**
* A zero-compressed encoded integer.
*/
public static class VInt {
public VInt() {
value = 0;
length = 0;
}
public int value;
public byte length;
};
public static final ThreadLocal threadLocalVInt = new ThreadLocal() {
@Override
protected VInt initialValue() {
return new VInt();
}
};
/**
* Reads a zero-compressed encoded int from a byte array and returns it.
*
* @param bytes
* the byte array
* @param offset
* offset of the array to read from
* @param vInt
* storing the deserialized int and its size in byte
*/
public static void readVInt(byte[] bytes, int offset, VInt vInt) {
byte firstByte = bytes[offset];
vInt.length = (byte) WritableUtils.decodeVIntSize(firstByte);
if (vInt.length == 1) {
vInt.value = firstByte;
return;
}
int i = 0;
for (int idx = 0; idx < vInt.length - 1; idx++) {
byte b = bytes[offset + 1 + idx];
i = i << 8;
i = i | (b & 0xFF);
}
vInt.value = (WritableUtils.isNegativeVInt(firstByte) ? (i ^ -1) : i);
}
/**
* Writes a zero-compressed encoded int to a byte array.
*
* @param byteStream
* the byte array/stream
* @param i
* the int
*/
public static void writeVInt(RandomAccessOutput byteStream, int i) {
writeVLong(byteStream, i);
}
/**
* Read a zero-compressed encoded long from a byte array.
*
* @param bytes the byte array
* @param offset the offset in the byte array where the VLong is stored
* @return the long
*/
public static long readVLongFromByteArray(final byte[] bytes, int offset) {
byte firstByte = bytes[offset++];
int len = WritableUtils.decodeVIntSize(firstByte);
if (len == 1) {
return firstByte;
}
long i = 0;
for (int idx = 0; idx < len-1; idx++) {
byte b = bytes[offset++];
i = i << 8;
i = i | (b & 0xFF);
}
return (WritableUtils.isNegativeVInt(firstByte) ? ~i : i);
}
/**
* Write a zero-compressed encoded long to a byte array.
*
* @param bytes
* the byte array/stream
* @param l
* the long
*/
public static int writeVLongToByteArray(byte[] bytes, long l) {
return LazyBinaryUtils.writeVLongToByteArray(bytes, 0, l);
}
public static int writeVLongToByteArray(byte[] bytes, int offset, long l) {
if (l >= -112 && l <= 127) {
bytes[offset] = (byte) l;
return 1;
}
int len = -112;
if (l < 0) {
l ^= -1L; // take one's complement'
len = -120;
}
long tmp = l;
while (tmp != 0) {
tmp = tmp >> 8;
len--;
}
bytes[offset] = (byte) len;
len = (len < -120) ? -(len + 120) : -(len + 112);
for (int idx = len; idx != 0; idx--) {
int shiftbits = (idx - 1) * 8;
long mask = 0xFFL << shiftbits;
bytes[offset+1-(idx - len)] = (byte) ((l & mask) >> shiftbits);
}
return 1 + len;
}
public static final int VLONG_BYTES_LEN = 9;
private static ThreadLocal vLongBytesThreadLocal = new ThreadLocal() {
@Override
public byte[] initialValue() {
return new byte[VLONG_BYTES_LEN];
}
};
public static void writeVLong(RandomAccessOutput byteStream, long l) {
byte[] vLongBytes = vLongBytesThreadLocal.get();
int len = LazyBinaryUtils.writeVLongToByteArray(vLongBytes, l);
byteStream.write(vLongBytes, 0, len);
}
public static void writeDouble(RandomAccessOutput byteStream, double d) {
long v = Double.doubleToLongBits(d);
byteStream.write((byte) (v >> 56));
byteStream.write((byte) (v >> 48));
byteStream.write((byte) (v >> 40));
byteStream.write((byte) (v >> 32));
byteStream.write((byte) (v >> 24));
byteStream.write((byte) (v >> 16));
byteStream.write((byte) (v >> 8));
byteStream.write((byte) (v));
}
static ConcurrentHashMap cachedLazyBinaryObjectInspector =
new ConcurrentHashMap();
/**
* Returns the lazy binary object inspector that can be used to inspect an
* lazy binary object of that typeInfo
*
* For primitive types, we use the standard writable object inspector.
*/
public static ObjectInspector getLazyBinaryObjectInspectorFromTypeInfo(
TypeInfo typeInfo) {
ObjectInspector result = cachedLazyBinaryObjectInspector.get(typeInfo);
if (result == null) {
switch (typeInfo.getCategory()) {
case PRIMITIVE: {
result = PrimitiveObjectInspectorFactory
.getPrimitiveWritableObjectInspector(((PrimitiveTypeInfo) typeInfo));
break;
}
case LIST: {
ObjectInspector elementObjectInspector = getLazyBinaryObjectInspectorFromTypeInfo(((ListTypeInfo) typeInfo)
.getListElementTypeInfo());
result = LazyBinaryObjectInspectorFactory
.getLazyBinaryListObjectInspector(elementObjectInspector);
break;
}
case MAP: {
MapTypeInfo mapTypeInfo = (MapTypeInfo) typeInfo;
ObjectInspector keyObjectInspector = getLazyBinaryObjectInspectorFromTypeInfo(mapTypeInfo
.getMapKeyTypeInfo());
ObjectInspector valueObjectInspector = getLazyBinaryObjectInspectorFromTypeInfo(mapTypeInfo
.getMapValueTypeInfo());
result = LazyBinaryObjectInspectorFactory
.getLazyBinaryMapObjectInspector(keyObjectInspector,
valueObjectInspector);
break;
}
case STRUCT: {
StructTypeInfo structTypeInfo = (StructTypeInfo) typeInfo;
List fieldNames = structTypeInfo.getAllStructFieldNames();
List fieldTypeInfos = structTypeInfo
.getAllStructFieldTypeInfos();
List fieldObjectInspectors = new ArrayList(
fieldTypeInfos.size());
for (int i = 0; i < fieldTypeInfos.size(); i++) {
fieldObjectInspectors
.add(getLazyBinaryObjectInspectorFromTypeInfo(fieldTypeInfos
.get(i)));
}
result = LazyBinaryObjectInspectorFactory
.getLazyBinaryStructObjectInspector(fieldNames,
fieldObjectInspectors);
break;
}
case UNION: {
UnionTypeInfo unionTypeInfo = (UnionTypeInfo) typeInfo;
final List fieldTypeInfos = unionTypeInfo.getAllUnionObjectTypeInfos();
List fieldObjectInspectors = new ArrayList(
fieldTypeInfos.size());
for (int i = 0; i < fieldTypeInfos.size(); i++) {
fieldObjectInspectors
.add(getLazyBinaryObjectInspectorFromTypeInfo(fieldTypeInfos
.get(i)));
}
result = LazyBinaryObjectInspectorFactory
.getLazyBinaryUnionObjectInspector(fieldObjectInspectors);
break;
}
default: {
result = null;
}
}
ObjectInspector prev =
cachedLazyBinaryObjectInspector.putIfAbsent(typeInfo, result);
if (prev != null) {
result = prev;
}
}
return result;
}
private LazyBinaryUtils() {
// prevent instantiation
}
}