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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.commons.codec.digest;

import org.apache.commons.codec.binary.StringUtils;

/**
 * Implementation of the MurmurHash3 32-bit and 128-bit hash functions.
 *
 * 

* MurmurHash is a non-cryptographic hash function suitable for general hash-based lookup. The name comes from two basic * operations, multiply (MU) and rotate (R), used in its inner loop. Unlike cryptographic hash functions, it is not * specifically designed to be difficult to reverse by an adversary, making it unsuitable for cryptographic purposes. *

* *

* This contains a Java port of the 32-bit hash function {@code MurmurHash3_x86_32} and the 128-bit hash function * {@code MurmurHash3_x64_128} from Austin Applyby's original {@code c++} code in SMHasher. *

* *

* This is public domain code with no copyrights. From home page of * SMHasher: *

* *
"All MurmurHash versions are public domain software, and the author disclaims all copyright to their * code."
* *

* Original adaption from Apache Hive. That adaption contains a {@code hash64} method that is not part of the original * MurmurHash3 code. It is not recommended to use these methods. They will be removed in a future release. To obtain a * 64-bit hash use half of the bits from the {@code hash128x64} methods using the input data converted to bytes. *

* * @see MurmurHash * @see Original MurmurHash3 c++ * code * @see * Apache Hive Murmer3 * @since 1.13 */ public final class MurmurHash3 { /** * A random number to use for a hash code. * * @deprecated This is not used internally and will be removed in a future release. */ @Deprecated public static final long NULL_HASHCODE = 2862933555777941757L; /** * A default seed to use for the murmur hash algorithm. * Has the value {@code 104729}. */ public static final int DEFAULT_SEED = 104729; /** TODO Replace on Java 8 with Long.BYTES. */ static final int LONG_BYTES = Long.SIZE / Byte.SIZE; /** TODO Replace on Java 8 with Integer.BYTES. */ static final int INTEGER_BYTES = Integer.SIZE / Byte.SIZE; /** TODO Replace on Java 8 with Short.BYTES. */ static final int SHORT_BYTES = Short.SIZE / Byte.SIZE; // Constants for 32-bit variant private static final int C1_32 = 0xcc9e2d51; private static final int C2_32 = 0x1b873593; private static final int R1_32 = 15; private static final int R2_32 = 13; private static final int M_32 = 5; private static final int N_32 = 0xe6546b64; // Constants for 128-bit variant private static final long C1 = 0x87c37b91114253d5L; private static final long C2 = 0x4cf5ad432745937fL; private static final int R1 = 31; private static final int R2 = 27; private static final int R3 = 33; private static final int M = 5; private static final int N1 = 0x52dce729; private static final int N2 = 0x38495ab5; /** No instance methods. */ private MurmurHash3() { } /** * Generates 32-bit hash from two longs with a default seed value. * This is a helper method that will produce the same result as: * *

     * int offset = 0;
     * int seed = 104729;
     * int hash = MurmurHash3.hash32x86(ByteBuffer.allocate(16)
     *                                            .putLong(data1)
     *                                            .putLong(data2)
     *                                            .array(), offset, 16, seed);
     * 
* * @param data1 The first long to hash * @param data2 The second long to hash * @return The 32-bit hash * @see #hash32x86(byte[], int, int, int) */ public static int hash32(final long data1, final long data2) { return hash32(data1, data2, DEFAULT_SEED); } /** * Generates 32-bit hash from two longs with the given seed. * This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int hash = MurmurHash3.hash32x86(ByteBuffer.allocate(16)
     *                                            .putLong(data1)
     *                                            .putLong(data2)
     *                                            .array(), offset, 16, seed);
     * 
* * @param data1 The first long to hash * @param data2 The second long to hash * @param seed The initial seed value * @return The 32-bit hash * @see #hash32x86(byte[], int, int, int) */ public static int hash32(final long data1, final long data2, final int seed) { int hash = seed; final long r0 = Long.reverseBytes(data1); final long r1 = Long.reverseBytes(data2); hash = mix32((int) r0, hash); hash = mix32((int) (r0 >>> 32), hash); hash = mix32((int) (r1), hash); hash = mix32((int) (r1 >>> 32), hash); hash ^= LONG_BYTES * 2; return fmix32(hash); } /** * Generates 32-bit hash from a long with a default seed value. * This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int seed = 104729;
     * int hash = MurmurHash3.hash32x86(ByteBuffer.allocate(8)
     *                                            .putLong(data)
     *                                            .array(), offset, 8, seed);
     * 
* * @param data The long to hash * @return The 32-bit hash * @see #hash32x86(byte[], int, int, int) */ public static int hash32(final long data) { return hash32(data, DEFAULT_SEED); } /** * Generates 32-bit hash from a long with the given seed. * This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int hash = MurmurHash3.hash32x86(ByteBuffer.allocate(8)
     *                                            .putLong(data)
     *                                            .array(), offset, 8, seed);
     * 
* * @param data The long to hash * @param seed The initial seed value * @return The 32-bit hash * @see #hash32x86(byte[], int, int, int) */ public static int hash32(final long data, final int seed) { int hash = seed; final long r0 = Long.reverseBytes(data); hash = mix32((int) r0, hash); hash = mix32((int) (r0 >>> 32), hash); hash ^= LONG_BYTES; return fmix32(hash); } /** * Generates 32-bit hash from the byte array with a default seed. * This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int seed = 104729;
     * int hash = MurmurHash3.hash32(data, offset, data.length, seed);
     * 
* *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @param data The input byte array * @return The 32-bit hash * @see #hash32(byte[], int, int, int) * @deprecated Use {@link #hash32x86(byte[], int, int, int)}. This corrects the processing of trailing bytes. */ @Deprecated public static int hash32(final byte[] data) { return hash32(data, 0, data.length, DEFAULT_SEED); } /** * Generates 32-bit hash from a string with a default seed. *

* Before 1.14 the string was converted using default encoding. * Since 1.14 the string is converted to bytes using UTF-8 encoding. *

* This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int seed = 104729;
     * byte[] bytes = data.getBytes(StandardCharsets.UTF_8);
     * int hash = MurmurHash3.hash32(bytes, offset, bytes.length, seed);
     * 
* *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @param data The input string * @return The 32-bit hash * @see #hash32(byte[], int, int, int) * @deprecated Use {@link #hash32x86(byte[], int, int, int)} with the bytes returned from * {@link String#getBytes(java.nio.charset.Charset)}. This corrects the processing of trailing bytes. */ @Deprecated public static int hash32(final String data) { final byte[] bytes = StringUtils.getBytesUtf8(data); return hash32(bytes, 0, bytes.length, DEFAULT_SEED); } /** * Generates 32-bit hash from the byte array with the given length and a default seed. * This is a helper method that will produce the same result as: * *

     * int offset = 0;
     * int seed = 104729;
     * int hash = MurmurHash3.hash32(data, offset, length, seed);
     * 
* *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @param data The input byte array * @param length The length of array * @return The 32-bit hash * @see #hash32(byte[], int, int, int) * @deprecated Use {@link #hash32x86(byte[], int, int, int)}. This corrects the processing of trailing bytes. */ @Deprecated public static int hash32(final byte[] data, final int length) { return hash32(data, length, DEFAULT_SEED); } /** * Generates 32-bit hash from the byte array with the given length and seed. This is a * helper method that will produce the same result as: * *

     * int offset = 0;
     * int hash = MurmurHash3.hash32(data, offset, length, seed);
     * 
* *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @param data The input byte array * @param length The length of array * @param seed The initial seed value * @return The 32-bit hash * @see #hash32(byte[], int, int, int) * @deprecated Use {@link #hash32x86(byte[], int, int, int)}. This corrects the processing of trailing bytes. */ @Deprecated public static int hash32(final byte[] data, final int length, final int seed) { return hash32(data, 0, length, seed); } /** * Generates 32-bit hash from the byte array with the given offset, length and seed. * *

This is an implementation of the 32-bit hash function {@code MurmurHash3_x86_32} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @param data The input byte array * @param offset The offset of data * @param length The length of array * @param seed The initial seed value * @return The 32-bit hash * @deprecated Use {@link #hash32x86(byte[], int, int, int)}. This corrects the processing of trailing bytes. */ @Deprecated public static int hash32(final byte[] data, final int offset, final int length, final int seed) { int hash = seed; final int nblocks = length >> 2; // body for (int i = 0; i < nblocks; i++) { final int index = offset + (i << 2); final int k = getLittleEndianInt(data, index); hash = mix32(k, hash); } // tail // ************ // Note: This fails to apply masking using 0xff to the 3 remaining bytes. // ************ final int index = offset + (nblocks << 2); int k1 = 0; switch (offset + length - index) { case 3: k1 ^= data[index + 2] << 16; case 2: k1 ^= data[index + 1] << 8; case 1: k1 ^= data[index]; // mix functions k1 *= C1_32; k1 = Integer.rotateLeft(k1, R1_32); k1 *= C2_32; hash ^= k1; } hash ^= length; return fmix32(hash); } /** * Generates 32-bit hash from the byte array with a seed of zero. * This is a helper method that will produce the same result as: * *

     * int offset = 0;
     * int seed = 0;
     * int hash = MurmurHash3.hash32x86(data, offset, data.length, seed);
     * 
* * @param data The input byte array * @return The 32-bit hash * @see #hash32x86(byte[], int, int, int) * @since 1.14 */ public static int hash32x86(final byte[] data) { return hash32x86(data, 0, data.length, 0); } /** * Generates 32-bit hash from the byte array with the given offset, length and seed. * *

This is an implementation of the 32-bit hash function {@code MurmurHash3_x86_32} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* * @param data The input byte array * @param offset The offset of data * @param length The length of array * @param seed The initial seed value * @return The 32-bit hash * @since 1.14 */ public static int hash32x86(final byte[] data, final int offset, final int length, final int seed) { int hash = seed; final int nblocks = length >> 2; // body for (int i = 0; i < nblocks; i++) { final int index = offset + (i << 2); final int k = getLittleEndianInt(data, index); hash = mix32(k, hash); } // tail final int index = offset + (nblocks << 2); int k1 = 0; switch (offset + length - index) { case 3: k1 ^= (data[index + 2] & 0xff) << 16; case 2: k1 ^= (data[index + 1] & 0xff) << 8; case 1: k1 ^= (data[index] & 0xff); // mix functions k1 *= C1_32; k1 = Integer.rotateLeft(k1, R1_32); k1 *= C2_32; hash ^= k1; } hash ^= length; return fmix32(hash); } /** * Generates 64-bit hash from a long with a default seed. * *

This is not part of the original MurmurHash3 {@code c++} implementation.

* *

This is a Murmur3-like 64-bit variant. * The method does not produce the same result as either half of the hash bytes from * {@linkplain #hash128x64(byte[])} with the same byte data from the {@code long}. * This method will be removed in a future release.

* *

Note: The sign extension bug in {@link #hash64(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* *

This is a helper method that will produce the same result as:

* *
     * int offset = 0;
     * int seed = 104729;
     * long hash = MurmurHash3.hash64(ByteBuffer.allocate(8)
     *                                          .putLong(data)
     *                                          .array(), offset, 8, seed);
     * 
* * @param data The long to hash * @return The 64-bit hash * @see #hash64(byte[], int, int, int) * @deprecated Not part of the MurmurHash3 implementation. * Use half of the hash bytes from {@link #hash128x64(byte[])} with the bytes from the {@code long}. */ @Deprecated public static long hash64(final long data) { long hash = DEFAULT_SEED; long k = Long.reverseBytes(data); final int length = LONG_BYTES; // mix functions k *= C1; k = Long.rotateLeft(k, R1); k *= C2; hash ^= k; hash = Long.rotateLeft(hash, R2) * M + N1; // finalization hash ^= length; hash = fmix64(hash); return hash; } /** * Generates 64-bit hash from an int with a default seed. * *

This is not part of the original MurmurHash3 {@code c++} implementation.

* *

This is a Murmur3-like 64-bit variant. * The method does not produce the same result as either half of the hash bytes from * {@linkplain #hash128x64(byte[])} with the same byte data from the {@code int}. * This method will be removed in a future release.

* *

Note: The sign extension bug in {@link #hash64(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* *

This is a helper method that will produce the same result as:

* *
     * int offset = 0;
     * int seed = 104729;
     * long hash = MurmurHash3.hash64(ByteBuffer.allocate(4)
     *                                          .putInt(data)
     *                                          .array(), offset, 4, seed);
     * 
* * @param data The int to hash * @return The 64-bit hash * @see #hash64(byte[], int, int, int) * @deprecated Not part of the MurmurHash3 implementation. * Use half of the hash bytes from {@link #hash128x64(byte[])} with the bytes from the {@code int}. */ @Deprecated public static long hash64(final int data) { long k1 = Integer.reverseBytes(data) & (-1L >>> 32); final int length = INTEGER_BYTES; long hash = DEFAULT_SEED; k1 *= C1; k1 = Long.rotateLeft(k1, R1); k1 *= C2; hash ^= k1; // finalization hash ^= length; hash = fmix64(hash); return hash; } /** * Generates 64-bit hash from a short with a default seed. * *

This is not part of the original MurmurHash3 {@code c++} implementation.

* *

This is a Murmur3-like 64-bit variant. * The method does not produce the same result as either half of the hash bytes from * {@linkplain #hash128x64(byte[])} with the same byte data from the {@code short}. * This method will be removed in a future release.

* *

Note: The sign extension bug in {@link #hash64(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* *

This is a helper method that will produce the same result as:

* *
     * int offset = 0;
     * int seed = 104729;
     * long hash = MurmurHash3.hash64(ByteBuffer.allocate(2)
     *                                          .putShort(data)
     *                                          .array(), offset, 2, seed);
     * 
* * @param data The short to hash * @return The 64-bit hash * @see #hash64(byte[], int, int, int) * @deprecated Not part of the MurmurHash3 implementation. * Use half of the hash bytes from {@link #hash128x64(byte[])} with the bytes from the {@code short}. */ @Deprecated public static long hash64(final short data) { long hash = DEFAULT_SEED; long k1 = 0; k1 ^= ((long) data & 0xff) << 8; k1 ^= ((long) ((data & 0xFF00) >> 8) & 0xff); k1 *= C1; k1 = Long.rotateLeft(k1, R1); k1 *= C2; hash ^= k1; // finalization hash ^= SHORT_BYTES; hash = fmix64(hash); return hash; } /** * Generates 64-bit hash from a byte array with a default seed. * *

This is not part of the original MurmurHash3 {@code c++} implementation.

* *

This is a Murmur3-like 64-bit variant. * The method does not produce the same result as either half of the hash bytes from * {@linkplain #hash128x64(byte[])} with the same byte data. * This method will be removed in a future release.

* *

Note: The sign extension bug in {@link #hash64(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* *

This is a helper method that will produce the same result as:

* *
     * int offset = 0;
     * int seed = 104729;
     * long hash = MurmurHash3.hash64(data, offset, data.length, seed);
     * 
* * @param data The input byte array * @return The 64-bit hash * @see #hash64(byte[], int, int, int) * @deprecated Not part of the MurmurHash3 implementation. * Use half of the hash bytes from {@link #hash128x64(byte[])}. */ @Deprecated public static long hash64(final byte[] data) { return hash64(data, 0, data.length, DEFAULT_SEED); } /** * Generates 64-bit hash from a byte array with the given offset and length and a default seed. * *

This is not part of the original MurmurHash3 {@code c++} implementation.

* *

This is a Murmur3-like 64-bit variant. * The method does not produce the same result as either half of the hash bytes from * {@linkplain #hash128x64(byte[])} with the same byte data. * This method will be removed in a future release.

* *

Note: The sign extension bug in {@link #hash64(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* *

This is a helper method that will produce the same result as:

* *
     * int seed = 104729;
     * long hash = MurmurHash3.hash64(data, offset, length, seed);
     * 
* * @param data The input byte array * @param offset The offset of data * @param length The length of array * @return The 64-bit hash * @see #hash64(byte[], int, int, int) * @deprecated Not part of the MurmurHash3 implementation. * Use half of the hash bytes from {@link #hash128x64(byte[], int, int, int)}. */ @Deprecated public static long hash64(final byte[] data, final int offset, final int length) { return hash64(data, offset, length, DEFAULT_SEED); } /** * Generates 64-bit hash from a byte array with the given offset, length and seed. * *

This is not part of the original MurmurHash3 {@code c++} implementation.

* *

This is a Murmur3-like 64-bit variant. * This method will be removed in a future release.

* *

This implementation contains a sign-extension bug in the seed initialization. * This manifests if the seed is negative.

* *

This algorithm processes 8 bytes chunks of data in a manner similar to the 16 byte chunks * of data processed in the MurmurHash3 {@code MurmurHash3_x64_128} method. However the hash * is not mixed with a hash chunk from the next 8 bytes of data. The method will not return * the same value as the first or second 64-bits of the function * {@link #hash128(byte[], int, int, int)}.

* *

Use of this method is not advised. Use the first long returned from * {@link #hash128x64(byte[], int, int, int)}.

* * @param data The input byte array * @param offset The offset of data * @param length The length of array * @param seed The initial seed value * @return The 64-bit hash * @deprecated Not part of the MurmurHash3 implementation. * Use half of the hash bytes from {@link #hash128x64(byte[], int, int, int)}. */ @Deprecated public static long hash64(final byte[] data, final int offset, final int length, final int seed) { // ************ // Note: This fails to apply masking using 0xffffffffL to the seed. // ************ long hash = seed; final int nblocks = length >> 3; // body for (int i = 0; i < nblocks; i++) { final int index = offset + (i << 3); long k = getLittleEndianLong(data, index); // mix functions k *= C1; k = Long.rotateLeft(k, R1); k *= C2; hash ^= k; hash = Long.rotateLeft(hash, R2) * M + N1; } // tail long k1 = 0; final int index = offset + (nblocks << 3); switch (offset + length - index) { case 7: k1 ^= ((long) data[index + 6] & 0xff) << 48; case 6: k1 ^= ((long) data[index + 5] & 0xff) << 40; case 5: k1 ^= ((long) data[index + 4] & 0xff) << 32; case 4: k1 ^= ((long) data[index + 3] & 0xff) << 24; case 3: k1 ^= ((long) data[index + 2] & 0xff) << 16; case 2: k1 ^= ((long) data[index + 1] & 0xff) << 8; case 1: k1 ^= ((long) data[index] & 0xff); k1 *= C1; k1 = Long.rotateLeft(k1, R1); k1 *= C2; hash ^= k1; } // finalization hash ^= length; hash = fmix64(hash); return hash; } /** * Generates 128-bit hash from the byte array with a default seed. * This is a helper method that will produce the same result as: * *

     * int offset = 0;
     * int seed = 104729;
     * int hash = MurmurHash3.hash128(data, offset, data.length, seed);
     * 
* *

Note: The sign extension bug in {@link #hash128(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* * @param data The input byte array * @return The 128-bit hash (2 longs) * @see #hash128(byte[], int, int, int) */ public static long[] hash128(final byte[] data) { return hash128(data, 0, data.length, DEFAULT_SEED); } /** * Generates 128-bit hash from the byte array with a seed of zero. * This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int seed = 0;
     * int hash = MurmurHash3.hash128x64(data, offset, data.length, seed);
     * 
* * @param data The input byte array * @return The 128-bit hash (2 longs) * @see #hash128x64(byte[], int, int, int) * @since 1.14 */ public static long[] hash128x64(final byte[] data) { return hash128x64(data, 0, data.length, 0); } /** * Generates 128-bit hash from a string with a default seed. *

* Before 1.14 the string was converted using default encoding. * Since 1.14 the string is converted to bytes using UTF-8 encoding. *

* This is a helper method that will produce the same result as: * *
     * int offset = 0;
     * int seed = 104729;
     * byte[] bytes = data.getBytes(StandardCharsets.UTF_8);
     * int hash = MurmurHash3.hash128(bytes, offset, bytes.length, seed);
     * 
* *

Note: The sign extension bug in {@link #hash128(byte[], int, int, int)} does not effect * this result as the default seed is positive.

* * @param data The input String * @return The 128-bit hash (2 longs) * @see #hash128(byte[], int, int, int) * @deprecated Use {@link #hash128x64(byte[])} using the bytes returned from * {@link String#getBytes(java.nio.charset.Charset)}. */ @Deprecated public static long[] hash128(final String data) { final byte[] bytes = StringUtils.getBytesUtf8(data); return hash128(bytes, 0, bytes.length, DEFAULT_SEED); } /** * Generates 128-bit hash from the byte array with the given offset, length and seed. * *

This is an implementation of the 128-bit hash function {@code MurmurHash3_x64_128} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* *

This implementation contains a sign-extension bug in the seed initialization. * This manifests if the seed is negative.

* * @param data The input byte array * @param offset The first element of array * @param length The length of array * @param seed The initial seed value * @return The 128-bit hash (2 longs) * @deprecated Use {@link #hash128x64(byte[], int, int, int)}. This corrects the seed initialization. */ @Deprecated public static long[] hash128(final byte[] data, final int offset, final int length, final int seed) { // ************ // Note: This deliberately fails to apply masking using 0xffffffffL to the seed // to maintain behavioral compatibility with the original version. // The implicit conversion to a long will extend a negative sign // bit through the upper 32-bits of the long seed. These should be zero. // ************ return hash128x64Internal(data, offset, length, seed); } /** * Generates 128-bit hash from the byte array with the given offset, length and seed. * *

This is an implementation of the 128-bit hash function {@code MurmurHash3_x64_128} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* * @param data The input byte array * @param offset The first element of array * @param length The length of array * @param seed The initial seed value * @return The 128-bit hash (2 longs) * @since 1.14 */ public static long[] hash128x64(final byte[] data, final int offset, final int length, final int seed) { // Use an unsigned 32-bit integer as the seed return hash128x64Internal(data, offset, length, seed & 0xffffffffL); } /** * Generates 128-bit hash from the byte array with the given offset, length and seed. * *

This is an implementation of the 128-bit hash function {@code MurmurHash3_x64_128} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* * @param data The input byte array * @param offset The first element of array * @param length The length of array * @param seed The initial seed value * @return The 128-bit hash (2 longs) */ private static long[] hash128x64Internal(final byte[] data, final int offset, final int length, final long seed) { long h1 = seed; long h2 = seed; final int nblocks = length >> 4; // body for (int i = 0; i < nblocks; i++) { final int index = offset + (i << 4); long k1 = getLittleEndianLong(data, index); long k2 = getLittleEndianLong(data, index + 8); // mix functions for k1 k1 *= C1; k1 = Long.rotateLeft(k1, R1); k1 *= C2; h1 ^= k1; h1 = Long.rotateLeft(h1, R2); h1 += h2; h1 = h1 * M + N1; // mix functions for k2 k2 *= C2; k2 = Long.rotateLeft(k2, R3); k2 *= C1; h2 ^= k2; h2 = Long.rotateLeft(h2, R1); h2 += h1; h2 = h2 * M + N2; } // tail long k1 = 0; long k2 = 0; final int index = offset + (nblocks << 4); switch (offset + length - index) { case 15: k2 ^= ((long) data[index + 14] & 0xff) << 48; case 14: k2 ^= ((long) data[index + 13] & 0xff) << 40; case 13: k2 ^= ((long) data[index + 12] & 0xff) << 32; case 12: k2 ^= ((long) data[index + 11] & 0xff) << 24; case 11: k2 ^= ((long) data[index + 10] & 0xff) << 16; case 10: k2 ^= ((long) data[index + 9] & 0xff) << 8; case 9: k2 ^= data[index + 8] & 0xff; k2 *= C2; k2 = Long.rotateLeft(k2, R3); k2 *= C1; h2 ^= k2; case 8: k1 ^= ((long) data[index + 7] & 0xff) << 56; case 7: k1 ^= ((long) data[index + 6] & 0xff) << 48; case 6: k1 ^= ((long) data[index + 5] & 0xff) << 40; case 5: k1 ^= ((long) data[index + 4] & 0xff) << 32; case 4: k1 ^= ((long) data[index + 3] & 0xff) << 24; case 3: k1 ^= ((long) data[index + 2] & 0xff) << 16; case 2: k1 ^= ((long) data[index + 1] & 0xff) << 8; case 1: k1 ^= data[index] & 0xff; k1 *= C1; k1 = Long.rotateLeft(k1, R1); k1 *= C2; h1 ^= k1; } // finalization h1 ^= length; h2 ^= length; h1 += h2; h2 += h1; h1 = fmix64(h1); h2 = fmix64(h2); h1 += h2; h2 += h1; return new long[] { h1, h2 }; } /** * Gets the little-endian long from 8 bytes starting at the specified index. * * @param data The data * @param index The index * @return The little-endian long */ private static long getLittleEndianLong(final byte[] data, final int index) { return (((long) data[index ] & 0xff) ) | (((long) data[index + 1] & 0xff) << 8) | (((long) data[index + 2] & 0xff) << 16) | (((long) data[index + 3] & 0xff) << 24) | (((long) data[index + 4] & 0xff) << 32) | (((long) data[index + 5] & 0xff) << 40) | (((long) data[index + 6] & 0xff) << 48) | (((long) data[index + 7] & 0xff) << 56); } /** * Gets the little-endian int from 4 bytes starting at the specified index. * * @param data The data * @param index The index * @return The little-endian int */ private static int getLittleEndianInt(final byte[] data, final int index) { return ((data[index ] & 0xff) ) | ((data[index + 1] & 0xff) << 8) | ((data[index + 2] & 0xff) << 16) | ((data[index + 3] & 0xff) << 24); } /** * Performs the intermediate mix step of the 32-bit hash function {@code MurmurHash3_x86_32}. * * @param k The data to add to the hash * @param hash The current hash * @return The new hash */ private static int mix32(int k, int hash) { k *= C1_32; k = Integer.rotateLeft(k, R1_32); k *= C2_32; hash ^= k; return Integer.rotateLeft(hash, R2_32) * M_32 + N_32; } /** * Performs the final avalanche mix step of the 32-bit hash function {@code MurmurHash3_x86_32}. * * @param hash The current hash * @return The final hash */ private static int fmix32(int hash) { hash ^= (hash >>> 16); hash *= 0x85ebca6b; hash ^= (hash >>> 13); hash *= 0xc2b2ae35; hash ^= (hash >>> 16); return hash; } /** * Performs the final avalanche mix step of the 64-bit hash function {@code MurmurHash3_x64_128}. * * @param hash The current hash * @return The final hash */ private static long fmix64(long hash) { hash ^= (hash >>> 33); hash *= 0xff51afd7ed558ccdL; hash ^= (hash >>> 33); hash *= 0xc4ceb9fe1a85ec53L; hash ^= (hash >>> 33); return hash; } /** * Generates 32-bit hash from input bytes. Bytes can be added incrementally and the new * hash computed. * *

This is an implementation of the 32-bit hash function {@code MurmurHash3_x86_32} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* * @since 1.14 */ public static class IncrementalHash32x86 { /** The size of byte blocks that are processed together. */ private static final int BLOCK_SIZE = 4; /** Up to 3 unprocessed bytes from input data. */ private final byte[] unprocessed = new byte[3]; /** The number of unprocessed bytes in the tail data. */ private int unprocessedLength; /** The total number of input bytes added since the start. */ private int totalLen; /** * The current running hash. * This must be finalised to generate the 32-bit hash value. */ private int hash; /** * Starts a new incremental hash. * * @param seed The initial seed value */ public final void start(final int seed) { // Reset unprocessedLength = totalLen = 0; this.hash = seed; } /** * Adds the byte array to the current incremental hash. * * @param data The input byte array * @param offset The offset of data * @param length The length of array */ public final void add(final byte[] data, final int offset, final int length) { if (length <= 0) { // Nothing to add return; } totalLen += length; // Process the bytes in blocks of 4. // New bytes must be added to any current unprocessed bytes, // then processed in blocks of 4 and the remaining bytes saved: // // |--|---------------------------|--| // unprocessed // main block // remaining // Check if the unprocessed bytes and new bytes can fill a block of 4. // Make this overflow safe in the event that length is Integer.MAX_VALUE. // Equivalent to: (unprocessedLength + length < BLOCK_SIZE) if (unprocessedLength + length - BLOCK_SIZE < 0) { // Not enough so add to the unprocessed bytes System.arraycopy(data, offset, unprocessed, unprocessedLength, length); unprocessedLength += length; return; } // Combine unprocessed bytes with new bytes. int newOffset; int newLength; if (unprocessedLength > 0) { int k = -1; switch (unprocessedLength) { case 1: k = orBytes(unprocessed[0], data[offset], data[offset + 1], data[offset + 2]); break; case 2: k = orBytes(unprocessed[0], unprocessed[1], data[offset], data[offset + 1]); break; case 3: k = orBytes(unprocessed[0], unprocessed[1], unprocessed[2], data[offset]); break; default: throw new IllegalStateException("Unprocessed length should be 1, 2, or 3: " + unprocessedLength); } hash = mix32(k, hash); // Update the offset and length final int consumed = BLOCK_SIZE - unprocessedLength; newOffset = offset + consumed; newLength = length - consumed; } else { newOffset = offset; newLength = length; } // Main processing of blocks of 4 bytes final int nblocks = newLength >> 2; for (int i = 0; i < nblocks; i++) { final int index = newOffset + (i << 2); final int k = getLittleEndianInt(data, index); hash = mix32(k, hash); } // Save left-over unprocessed bytes final int consumed = (nblocks << 2); unprocessedLength = newLength - consumed; if (unprocessedLength != 0) { System.arraycopy(data, newOffset + consumed, unprocessed, 0, unprocessedLength); } } /** * Generate the 32-bit hash value. Repeat calls to this method with no additional data * will generate the same hash value. * * @return The 32-bit hash */ public final int end() { // Allow calling end() again after adding no data to return the same result. return finalise(hash, unprocessedLength, unprocessed, totalLen); } /** * Finalize the running hash to the output 32-bit hash by processing remaining bytes * and performing final mixing. * * @param hash The running hash * @param unprocessedLength The number of unprocessed bytes in the tail data. * @param unprocessed Up to 3 unprocessed bytes from input data. * @param totalLen The total number of input bytes added since the start. * @return The 32-bit hash */ int finalise(final int hash, final int unprocessedLength, final byte[] unprocessed, final int totalLen) { int result = hash; int k1 = 0; switch (unprocessedLength) { case 3: k1 ^= (unprocessed[2] & 0xff) << 16; case 2: k1 ^= (unprocessed[1] & 0xff) << 8; case 1: k1 ^= (unprocessed[0] & 0xff); // mix functions k1 *= C1_32; k1 = Integer.rotateLeft(k1, R1_32); k1 *= C2_32; result ^= k1; } // finalization result ^= totalLen; return fmix32(result); } /** * Combines the bytes using an Or operation ({@code | } in a little-endian representation * of a 32-bit integer; byte 1 will be the least significant byte, byte 4 the most * significant. * * @param b1 The first byte * @param b2 The second byte * @param b3 The third byte * @param b4 The fourth byte * @return The 32-bit integer */ private static int orBytes(final byte b1, final byte b2, final byte b3, final byte b4) { return (b1 & 0xff) | ((b2 & 0xff) << 8) | ((b3 & 0xff) << 16) | ((b4 & 0xff) << 24); } } /** * Generates 32-bit hash from input bytes. Bytes can be added incrementally and the new * hash computed. * *

This is an implementation of the 32-bit hash function {@code MurmurHash3_x86_32} * from from Austin Applyby's original MurmurHash3 {@code c++} code in SMHasher.

* *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @deprecated Use IncrementalHash32x86. This corrects the processing of trailing bytes. */ @Deprecated public static class IncrementalHash32 extends IncrementalHash32x86 { /** * {@inheritDoc} * *

This implementation contains a sign-extension bug in the finalization step of * any bytes left over from dividing the length by 4. This manifests if any of these * bytes are negative.

* * @deprecated Use IncrementalHash32x86. This corrects the processing of trailing bytes. */ @Override @Deprecated int finalise(final int hash, final int unprocessedLength, final byte[] unprocessed, final int totalLen) { int result = hash; // ************ // Note: This fails to apply masking using 0xff to the 3 remaining bytes. // ************ int k1 = 0; switch (unprocessedLength) { case 3: k1 ^= unprocessed[2] << 16; case 2: k1 ^= unprocessed[1] << 8; case 1: k1 ^= unprocessed[0]; // mix functions k1 *= C1_32; k1 = Integer.rotateLeft(k1, R1_32); k1 *= C2_32; result ^= k1; } // finalization result ^= totalLen; return fmix32(result); } } }





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