org.apache.hadoop.hive.serde2.io.TimestampLocalTZWritable Maven / Gradle / Ivy
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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.io;
import com.google.common.base.Preconditions;
import org.apache.hadoop.hive.common.type.TimestampTZ;
import org.apache.hadoop.hive.serde2.ByteStream;
import org.apache.hadoop.hive.serde2.lazybinary.LazyBinaryUtils;
import org.apache.hadoop.io.WritableComparable;
import org.apache.hadoop.io.WritableUtils;
import java.io.DataInput;
import java.io.DataOutput;
import java.io.IOException;
import java.time.ZoneId;
import java.util.Arrays;
/**
* Writable for TimestampTZ. Copied from TimestampWritableV2.
* After we replace {@link java.sql.Timestamp} with {@link java.time.LocalDateTime} for Timestamp,
* it'll need a new Writable.
* All timestamp with time zone will be serialized as UTC retaining the instant.
* E.g. "2017-04-14 18:00:00 Asia/Shanghai" will be converted to
* "2017-04-14 10:00:00.0 Z".
*/
public class TimestampLocalTZWritable implements WritableComparable {
public static final byte[] nullBytes = {0x0, 0x0, 0x0, 0x0};
private static final int DECIMAL_OR_SECOND_VINT_FLAG = 1 << 31;
private static final long SEVEN_BYTE_LONG_SIGN_FLIP = 0xff80L << 48; // only need flip the MSB?
/**
* The maximum number of bytes required for a TimestampWritableV2
*/
public static final int MAX_BYTES = 13;
public static final int BINARY_SORTABLE_LENGTH = 11;
private TimestampTZ timestampTZ = new TimestampTZ();
private ZoneId timeZone;
/**
* true if data is stored in timestamptz field rather than byte arrays.
* allows for lazy conversion to bytes when necessary
* false otherwise
*/
private boolean bytesEmpty = true;
private boolean timestampTZEmpty = true;
/* Allow use of external byte[] for efficiency */
private byte[] currentBytes;
private final byte[] internalBytes = new byte[MAX_BYTES];
private byte[] externalBytes;
private int offset;
public TimestampLocalTZWritable() {
this.bytesEmpty = false;
this.currentBytes = internalBytes;
this.offset = 0;
}
public TimestampLocalTZWritable(byte[] bytes, int offset, ZoneId timeZone) {
set(bytes, offset, timeZone);
}
public TimestampLocalTZWritable(TimestampLocalTZWritable other) {
this(other.getBytes(), 0, other.getTimestampTZ().getZonedDateTime().getZone());
}
public TimestampLocalTZWritable(TimestampTZ tstz) {
set(tstz);
}
public void set(byte[] bytes, int offset, ZoneId timeZone) {
externalBytes = bytes;
this.offset = offset;
this.timeZone = timeZone;
bytesEmpty = false;
timestampTZEmpty = true;
currentBytes = externalBytes;
}
public void set(TimestampTZ tstz) {
if (tstz == null) {
timestampTZ.setZonedDateTime(null);
return;
}
timestampTZ.setZonedDateTime(tstz.getZonedDateTime());
timeZone = timestampTZ.getZonedDateTime().getZone();
bytesEmpty = true;
timestampTZEmpty = false;
}
public void set(TimestampLocalTZWritable t) {
if (t.bytesEmpty) {
set(t.getTimestampTZ());
} else if (t.currentBytes == t.externalBytes) {
set(t.currentBytes, t.offset, t.timeZone);
} else {
set(t.currentBytes, 0, t.timeZone);
}
}
public void setTimeZone(ZoneId timeZone) {
if (timestampTZ != null) {
timestampTZ.setZonedDateTime(
timestampTZ.getZonedDateTime().withZoneSameInstant(timeZone));
}
this.timeZone = timeZone;
}
public ZoneId getTimeZone() {
return timeZone;
}
public TimestampTZ getTimestampTZ() {
populateTimestampTZ();
return new TimestampTZ(timestampTZ.getZonedDateTime());
}
/**
* Used to create copies of objects
*
* @return a copy of the internal TimestampTZWritable byte[]
*/
public byte[] getBytes() {
checkBytes();
int len = getTotalLength();
byte[] b = new byte[len];
System.arraycopy(currentBytes, offset, b, 0, len);
return b;
}
/**
* @return length of serialized TimestampTZWritable data. As a side effect, populates the internal
* byte array if empty.
*/
private int getTotalLength() {
checkBytes();
return getTotalLength(currentBytes, offset);
}
/**
* The data of TimestampTZWritable can be stored either in a byte[]
* or in a TimestampTZ object. Calling this method ensures that the byte[]
* is populated from the TimestampTZ object if previously empty.
*/
private void checkBytes() {
if (bytesEmpty) {
populateBytes();
offset = 0;
currentBytes = internalBytes;
bytesEmpty = false;
}
}
// Writes the TimestampTZ's serialized value to the internal byte array.
private void populateBytes() {
Arrays.fill(internalBytes, (byte) 0);
long seconds = timestampTZ.getEpochSecond();
int nanos = timestampTZ.getNanos();
boolean hasSecondVInt = seconds < 0 || seconds > Integer.MAX_VALUE;
boolean hasDecimal = setNanosBytes(nanos, internalBytes, offset + 4, hasSecondVInt);
int firstInt = (int) seconds;
if (hasDecimal || hasSecondVInt) {
firstInt |= DECIMAL_OR_SECOND_VINT_FLAG;
}
intToBytes(firstInt, internalBytes, offset);
if (hasSecondVInt) {
LazyBinaryUtils.writeVLongToByteArray(internalBytes,
offset + 4 + WritableUtils.decodeVIntSize(internalBytes[offset + 4]),
seconds >> 31);
}
}
private void populateTimestampTZ() {
if (timestampTZEmpty) {
if (bytesEmpty) {
throw new IllegalStateException("Bytes are empty");
}
long seconds = getSeconds(currentBytes, offset);
int nanos = hasDecimalOrSecondVInt(currentBytes[offset]) ? getNanos(currentBytes, offset + 4) : 0;
timestampTZ.set(seconds, nanos, timeZone);
timestampTZEmpty = false;
}
}
public long getSeconds() {
if (!timestampTZEmpty) {
return timestampTZ.getEpochSecond();
} else if (!bytesEmpty) {
return getSeconds(currentBytes, offset);
}
throw new IllegalStateException("Both timestamp and bytes are empty");
}
public int getNanos() {
if (!timestampTZEmpty) {
return timestampTZ.getNanos();
} else if (!bytesEmpty) {
return hasDecimalOrSecondVInt(currentBytes[offset]) ? getNanos(currentBytes, offset + 4) : 0;
}
throw new IllegalStateException("Both timestamp and bytes are empty");
}
@Override
public int compareTo(TimestampLocalTZWritable o) {
return getTimestampTZ().compareTo(o.getTimestampTZ());
}
@Override
public boolean equals(Object o) {
if (o instanceof TimestampLocalTZWritable) {
return compareTo((TimestampLocalTZWritable) o) == 0;
}
return false;
}
@Override
public int hashCode() {
return getTimestampTZ().hashCode();
}
@Override
public String toString() {
populateTimestampTZ();
return timestampTZ.toString();
}
@Override
public void write(DataOutput dataOutput) throws IOException {
checkBytes();
dataOutput.write(currentBytes, offset, getTotalLength());
}
@Override
public void readFields(DataInput dataInput) throws IOException {
dataInput.readFully(internalBytes, 0, 4);
if (hasDecimalOrSecondVInt(internalBytes[0])) {
dataInput.readFully(internalBytes, 4, 1);
int len = (byte) WritableUtils.decodeVIntSize(internalBytes[4]);
if (len > 1) {
dataInput.readFully(internalBytes, 5, len - 1);
}
long vlong = LazyBinaryUtils.readVLongFromByteArray(internalBytes, 4);
Preconditions.checkState(vlong >= -1000000000 && vlong <= 999999999,
"Invalid nanos value for a TimestampTZWritable: " + vlong +
", expected to be between -1000000000 and 999999999.");
if (vlong < 0) {
// This indicates there is a second VInt containing the additional bits of the seconds
// field.
dataInput.readFully(internalBytes, 4 + len, 1);
int secondVIntLen = (byte) WritableUtils.decodeVIntSize(internalBytes[4 + len]);
if (secondVIntLen > 1) {
dataInput.readFully(internalBytes, 5 + len, secondVIntLen - 1);
}
}
}
currentBytes = internalBytes;
offset = 0;
timestampTZEmpty = true;
bytesEmpty = false;
}
public byte[] toBinarySortable() {
byte[] b = new byte[BINARY_SORTABLE_LENGTH];
int nanos = getNanos();
// We flip the highest-order bit of the seven-byte representation of seconds to make negative
// values come before positive ones.
long seconds = getSeconds() ^ SEVEN_BYTE_LONG_SIGN_FLIP;
sevenByteLongToBytes(seconds, b, 0);
intToBytes(nanos, b, 7);
return b;
}
public void fromBinarySortable(byte[] bytes, int binSortOffset, ZoneId timeZone) {
// Flip the sign bit (and unused bits of the high-order byte) of the seven-byte long back.
long seconds = readSevenByteLong(bytes, binSortOffset) ^ SEVEN_BYTE_LONG_SIGN_FLIP;
int nanos = bytesToInt(bytes, binSortOffset + 7);
timestampTZ.set(seconds, nanos, timeZone);
timestampTZEmpty = false;
bytesEmpty = true;
}
public void writeToByteStream(ByteStream.RandomAccessOutput byteStream) {
checkBytes();
byteStream.write(currentBytes, offset, getTotalLength());
}
/**
* Given an integer representing nanoseconds, write its serialized
* value to the byte array b at offset
*
* @param nanos
* @param b
* @param offset
* @return
*/
private static boolean setNanosBytes(int nanos, byte[] b, int offset, boolean hasSecondVInt) {
int decimal = 0;
if (nanos != 0) {
int counter = 0;
while (counter < 9) {
decimal *= 10;
decimal += nanos % 10;
nanos /= 10;
counter++;
}
}
if (hasSecondVInt || decimal != 0) {
// We use the sign of the reversed-nanoseconds field to indicate that there is a second VInt
// present.
LazyBinaryUtils.writeVLongToByteArray(b, offset, hasSecondVInt ? (-decimal - 1) : decimal);
}
return decimal != 0;
}
public static void setTimestampTZ(TimestampTZ t, byte[] bytes, int offset, ZoneId timeZone) {
long seconds = getSeconds(bytes, offset);
int nanos = hasDecimalOrSecondVInt(bytes[offset]) ? getNanos(bytes, offset + 4) : 0;
t.set(seconds, nanos, timeZone);
}
public static int getTotalLength(byte[] bytes, int offset) {
int len = 4;
if (hasDecimalOrSecondVInt(bytes[offset])) {
int firstVIntLen = WritableUtils.decodeVIntSize(bytes[offset + 4]);
len += firstVIntLen;
if (hasSecondVInt(bytes[offset + 4])) {
len += WritableUtils.decodeVIntSize(bytes[offset + 4 + firstVIntLen]);
}
}
return len;
}
public static long getSeconds(byte[] bytes, int offset) {
int firstVInt = bytesToInt(bytes, offset);
if (firstVInt >= 0 || !hasSecondVInt(bytes[offset + 4])) {
return firstVInt & ~DECIMAL_OR_SECOND_VINT_FLAG;
}
return ((long) (firstVInt & ~DECIMAL_OR_SECOND_VINT_FLAG)) |
(LazyBinaryUtils.readVLongFromByteArray(bytes,
offset + 4 + WritableUtils.decodeVIntSize(bytes[offset + 4])) << 31);
}
public static int getNanos(byte[] bytes, int offset) {
int val = (int) LazyBinaryUtils.readVLongFromByteArray(bytes, offset);
if (val < 0) {
val = -val - 1;
}
int len = (int) Math.floor(Math.log10(val)) + 1;
// Reverse the value
int tmp = 0;
while (val != 0) {
tmp *= 10;
tmp += val % 10;
val /= 10;
}
val = tmp;
if (len < 9) {
val *= Math.pow(10, 9 - len);
}
return val;
}
private static boolean hasDecimalOrSecondVInt(byte b) {
return b < 0;
}
private static boolean hasSecondVInt(byte b) {
return WritableUtils.isNegativeVInt(b);
}
/**
* Writes value into dest at offset
*
* @param value
* @param dest
* @param offset
*/
private static void intToBytes(int value, byte[] dest, int offset) {
dest[offset] = (byte) ((value >> 24) & 0xFF);
dest[offset + 1] = (byte) ((value >> 16) & 0xFF);
dest[offset + 2] = (byte) ((value >> 8) & 0xFF);
dest[offset + 3] = (byte) (value & 0xFF);
}
/**
* Writes value into dest at offset as a seven-byte
* serialized long number.
*/
private static void sevenByteLongToBytes(long value, byte[] dest, int offset) {
dest[offset] = (byte) ((value >> 48) & 0xFF);
dest[offset + 1] = (byte) ((value >> 40) & 0xFF);
dest[offset + 2] = (byte) ((value >> 32) & 0xFF);
dest[offset + 3] = (byte) ((value >> 24) & 0xFF);
dest[offset + 4] = (byte) ((value >> 16) & 0xFF);
dest[offset + 5] = (byte) ((value >> 8) & 0xFF);
dest[offset + 6] = (byte) (value & 0xFF);
}
/**
* @param bytes
* @param offset
* @return integer represented by the four bytes in bytes
* beginning at offset
*/
private static int bytesToInt(byte[] bytes, int offset) {
return ((0xFF & bytes[offset]) << 24)
| ((0xFF & bytes[offset + 1]) << 16)
| ((0xFF & bytes[offset + 2]) << 8)
| (0xFF & bytes[offset + 3]);
}
private static long readSevenByteLong(byte[] bytes, int offset) {
// We need to shift everything 8 bits left and then shift back to populate the sign field.
return (((0xFFL & bytes[offset]) << 56)
| ((0xFFL & bytes[offset + 1]) << 48)
| ((0xFFL & bytes[offset + 2]) << 40)
| ((0xFFL & bytes[offset + 3]) << 32)
| ((0xFFL & bytes[offset + 4]) << 24)
| ((0xFFL & bytes[offset + 5]) << 16)
| ((0xFFL & bytes[offset + 6]) << 8)) >> 8;
}
}