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/*
* COPIED FROM APACHE LUCENE 4.7.2
*
* Git URL: [email protected]:apache/lucene.git, tag: releases/lucene-solr/4.7.2, path: lucene/core/src/java
*
* (see https://issues.apache.org/jira/browse/OAK-10786 for details)
*/
package org.apache.lucene.util.packed;
/*
* 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.
*/
import java.io.IOException;
import java.util.Arrays;
import org.apache.lucene.store.DataInput;
import org.apache.lucene.util.RamUsageEstimator;
/**
* Space optimized random access capable array of values with a fixed number of
* bits/value. Values are packed contiguously.
*
* The implementation strives to perform af fast as possible under the
* constraint of contiguous bits, by avoiding expensive operations. This comes
* at the cost of code clarity.
*
* Technical details: This implementation is a refinement of a non-branching
* version. The non-branching get and set methods meant that 2 or 4 atomics in
* the underlying array were always accessed, even for the cases where only
* 1 or 2 were needed. Even with caching, this had a detrimental effect on
* performance.
* Related to this issue, the old implementation used lookup tables for shifts
* and masks, which also proved to be a bit slower than calculating the shifts
* and masks on the fly.
* See https://issues.apache.org/jira/browse/LUCENE-4062 for details.
*
*/
class Packed64 extends PackedInts.MutableImpl {
static final int BLOCK_SIZE = 64; // 32 = int, 64 = long
static final int BLOCK_BITS = 6; // The #bits representing BLOCK_SIZE
static final int MOD_MASK = BLOCK_SIZE - 1; // x % BLOCK_SIZE
/**
* Values are stores contiguously in the blocks array.
*/
private final long[] blocks;
/**
* A right-aligned mask of width BitsPerValue used by {@link #get(int)}.
*/
private final long maskRight;
/**
* Optimization: Saves one lookup in {@link #get(int)}.
*/
private final int bpvMinusBlockSize;
/**
* Creates an array with the internal structures adjusted for the given
* limits and initialized to 0.
* @param valueCount the number of elements.
* @param bitsPerValue the number of bits available for any given value.
*/
public Packed64(int valueCount, int bitsPerValue) {
super(valueCount, bitsPerValue);
final PackedInts.Format format = PackedInts.Format.PACKED;
final int longCount = format.longCount(PackedInts.VERSION_CURRENT, valueCount, bitsPerValue);
this.blocks = new long[longCount];
maskRight = ~0L << (BLOCK_SIZE-bitsPerValue) >>> (BLOCK_SIZE-bitsPerValue);
bpvMinusBlockSize = bitsPerValue - BLOCK_SIZE;
}
/**
* Creates an array with content retrieved from the given DataInput.
* @param in a DataInput, positioned at the start of Packed64-content.
* @param valueCount the number of elements.
* @param bitsPerValue the number of bits available for any given value.
* @throws java.io.IOException if the values for the backing array could not
* be retrieved.
*/
public Packed64(int packedIntsVersion, DataInput in, int valueCount, int bitsPerValue)
throws IOException {
super(valueCount, bitsPerValue);
final PackedInts.Format format = PackedInts.Format.PACKED;
final long byteCount = format.byteCount(packedIntsVersion, valueCount, bitsPerValue); // to know how much to read
final int longCount = format.longCount(PackedInts.VERSION_CURRENT, valueCount, bitsPerValue); // to size the array
blocks = new long[longCount];
// read as many longs as we can
for (int i = 0; i < byteCount / 8; ++i) {
blocks[i] = in.readLong();
}
final int remaining = (int) (byteCount % 8);
if (remaining != 0) {
// read the last bytes
long lastLong = 0;
for (int i = 0; i < remaining; ++i) {
lastLong |= (in.readByte() & 0xFFL) << (56 - i * 8);
}
blocks[blocks.length - 1] = lastLong;
}
maskRight = ~0L << (BLOCK_SIZE-bitsPerValue) >>> (BLOCK_SIZE-bitsPerValue);
bpvMinusBlockSize = bitsPerValue - BLOCK_SIZE;
}
/**
* @param index the position of the value.
* @return the value at the given index.
*/
@Override
public long get(final int index) {
// The abstract index in a bit stream
final long majorBitPos = (long)index * bitsPerValue;
// The index in the backing long-array
final int elementPos = (int)(majorBitPos >>> BLOCK_BITS);
// The number of value-bits in the second long
final long endBits = (majorBitPos & MOD_MASK) + bpvMinusBlockSize;
if (endBits <= 0) { // Single block
return (blocks[elementPos] >>> -endBits) & maskRight;
}
// Two blocks
return ((blocks[elementPos] << endBits)
| (blocks[elementPos+1] >>> (BLOCK_SIZE - endBits)))
& maskRight;
}
@Override
public int get(int index, long[] arr, int off, int len) {
assert len > 0 : "len must be > 0 (got " + len + ")";
assert index >= 0 && index < valueCount;
len = Math.min(len, valueCount - index);
assert off + len <= arr.length;
final int originalIndex = index;
final PackedInts.Decoder decoder = BulkOperation.of(PackedInts.Format.PACKED, bitsPerValue);
// go to the next block where the value does not span across two blocks
final int offsetInBlocks = index % decoder.longValueCount();
if (offsetInBlocks != 0) {
for (int i = offsetInBlocks; i < decoder.longValueCount() && len > 0; ++i) {
arr[off++] = get(index++);
--len;
}
if (len == 0) {
return index - originalIndex;
}
}
// bulk get
assert index % decoder.longValueCount() == 0;
int blockIndex = (int) (((long) index * bitsPerValue) >>> BLOCK_BITS);
assert (((long)index * bitsPerValue) & MOD_MASK) == 0;
final int iterations = len / decoder.longValueCount();
decoder.decode(blocks, blockIndex, arr, off, iterations);
final int gotValues = iterations * decoder.longValueCount();
index += gotValues;
len -= gotValues;
assert len >= 0;
if (index > originalIndex) {
// stay at the block boundary
return index - originalIndex;
} else {
// no progress so far => already at a block boundary but no full block to get
assert index == originalIndex;
return super.get(index, arr, off, len);
}
}
@Override
public void set(final int index, final long value) {
// The abstract index in a contiguous bit stream
final long majorBitPos = (long)index * bitsPerValue;
// The index in the backing long-array
final int elementPos = (int)(majorBitPos >>> BLOCK_BITS); // / BLOCK_SIZE
// The number of value-bits in the second long
final long endBits = (majorBitPos & MOD_MASK) + bpvMinusBlockSize;
if (endBits <= 0) { // Single block
blocks[elementPos] = blocks[elementPos] & ~(maskRight << -endBits)
| (value << -endBits);
return;
}
// Two blocks
blocks[elementPos] = blocks[elementPos] & ~(maskRight >>> endBits)
| (value >>> endBits);
blocks[elementPos+1] = blocks[elementPos+1] & (~0L >>> endBits)
| (value << (BLOCK_SIZE - endBits));
}
@Override
public int set(int index, long[] arr, int off, int len) {
assert len > 0 : "len must be > 0 (got " + len + ")";
assert index >= 0 && index < valueCount;
len = Math.min(len, valueCount - index);
assert off + len <= arr.length;
final int originalIndex = index;
final PackedInts.Encoder encoder = BulkOperation.of(PackedInts.Format.PACKED, bitsPerValue);
// go to the next block where the value does not span across two blocks
final int offsetInBlocks = index % encoder.longValueCount();
if (offsetInBlocks != 0) {
for (int i = offsetInBlocks; i < encoder.longValueCount() && len > 0; ++i) {
set(index++, arr[off++]);
--len;
}
if (len == 0) {
return index - originalIndex;
}
}
// bulk set
assert index % encoder.longValueCount() == 0;
int blockIndex = (int) (((long) index * bitsPerValue) >>> BLOCK_BITS);
assert (((long)index * bitsPerValue) & MOD_MASK) == 0;
final int iterations = len / encoder.longValueCount();
encoder.encode(arr, off, blocks, blockIndex, iterations);
final int setValues = iterations * encoder.longValueCount();
index += setValues;
len -= setValues;
assert len >= 0;
if (index > originalIndex) {
// stay at the block boundary
return index - originalIndex;
} else {
// no progress so far => already at a block boundary but no full block to get
assert index == originalIndex;
return super.set(index, arr, off, len);
}
}
@Override
public String toString() {
return "Packed64(bitsPerValue=" + bitsPerValue + ", size="
+ size() + ", elements.length=" + blocks.length + ")";
}
@Override
public long ramBytesUsed() {
return RamUsageEstimator.alignObjectSize(
RamUsageEstimator.NUM_BYTES_OBJECT_HEADER
+ 3 * RamUsageEstimator.NUM_BYTES_INT // bpvMinusBlockSize,valueCount,bitsPerValue
+ RamUsageEstimator.NUM_BYTES_LONG // maskRight
+ RamUsageEstimator.NUM_BYTES_OBJECT_REF) // blocks ref
+ RamUsageEstimator.sizeOf(blocks);
}
@Override
public void fill(int fromIndex, int toIndex, long val) {
assert PackedInts.bitsRequired(val) <= getBitsPerValue();
assert fromIndex <= toIndex;
// minimum number of values that use an exact number of full blocks
final int nAlignedValues = 64 / gcd(64, bitsPerValue);
final int span = toIndex - fromIndex;
if (span <= 3 * nAlignedValues) {
// there needs be at least 2 * nAlignedValues aligned values for the
// block approach to be worth trying
super.fill(fromIndex, toIndex, val);
return;
}
// fill the first values naively until the next block start
final int fromIndexModNAlignedValues = fromIndex % nAlignedValues;
if (fromIndexModNAlignedValues != 0) {
for (int i = fromIndexModNAlignedValues; i < nAlignedValues; ++i) {
set(fromIndex++, val);
}
}
assert fromIndex % nAlignedValues == 0;
// compute the long[] blocks for nAlignedValues consecutive values and
// use them to set as many values as possible without applying any mask
// or shift
final int nAlignedBlocks = (nAlignedValues * bitsPerValue) >> 6;
final long[] nAlignedValuesBlocks;
{
Packed64 values = new Packed64(nAlignedValues, bitsPerValue);
for (int i = 0; i < nAlignedValues; ++i) {
values.set(i, val);
}
nAlignedValuesBlocks = values.blocks;
assert nAlignedBlocks <= nAlignedValuesBlocks.length;
}
final int startBlock = (int) (((long) fromIndex * bitsPerValue) >>> 6);
final int endBlock = (int) (((long) toIndex * bitsPerValue) >>> 6);
for (int block = startBlock; block < endBlock; ++block) {
final long blockValue = nAlignedValuesBlocks[block % nAlignedBlocks];
blocks[block] = blockValue;
}
// fill the gap
for (int i = (int) (((long) endBlock << 6) / bitsPerValue); i < toIndex; ++i) {
set(i, val);
}
}
private static int gcd(int a, int b) {
if (a < b) {
return gcd(b, a);
} else if (b == 0) {
return a;
} else {
return gcd(b, a % b);
}
}
@Override
public void clear() {
Arrays.fill(blocks, 0L);
}
}