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fastutil extends the Java Collections Framework by providing type-specific maps, sets, lists, and queues with a small memory footprint and fast operations; it provides also big (64-bit) arrays, sets, and lists, sorting algorithms, fast, practical I/O classes for binary and text files, and facilities for memory mapping large files. This jar (fastutil-core.jar) contains data structures based on integers, longs, doubles, and objects, only; fastutil.jar contains all classes. If you have both jars in your dependencies, this jar should be excluded.

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/*
 * Copyright (C) 2002-2022 Sebastiano Vigna
 *
 * Licensed 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 PACKAGE;

import static it.unimi.dsi.fastutil.BigArrays.copyFromBig;
import static it.unimi.dsi.fastutil.BigArrays.copyToBig;
import static it.unimi.dsi.fastutil.BigArrays.grow;
import static it.unimi.dsi.fastutil.BigArrays.trim;

import static PACKAGE.ARRAY_FRONT_CODED_LIST.count;
import static PACKAGE.ARRAY_FRONT_CODED_LIST.readInt;
import static PACKAGE.ARRAY_FRONT_CODED_LIST.writeInt;

import it.unimi.dsi.fastutil.BigArrays;
import it.unimi.dsi.fastutil.objects.AbstractObjectBigList;
import it.unimi.dsi.fastutil.objects.ObjectBigListIterator;
#if ! KEY_CLASS_Long
import it.unimi.dsi.fastutil.longs.LongBigArrays;
#endif

import java.io.Serializable;
import java.util.Iterator;
import java.util.Collection;
import java.util.NoSuchElementException;
import java.util.RandomAccess;

/** Compact storage of big lists of arrays using front-coding (also known as prefix-omission) compression.
 *
 * 

This class stores immutably a big list of arrays in a single {@linkplain it.unimi.dsi.fastutil.BigArrays big array} * using front coding (of course, the compression will be reasonable only if * the list is sorted lexicographically—see below). It implements an * immutable type-specific list that returns the i-th array when * calling {@link #get(long) get(i)}. The returned array may be * freely modified. * *

Front-coding (also known as prefix-omission) compression is based on the idea that if the i-th and the * (i+1)-th array have a common prefix, we might store the length * of the common prefix, and then the rest of the second array. * *

This approach, of course, requires that once in a while an array is * stored entirely. The ratio of a front-coded list defines how * often this happens (once every {@link #ratio()} arrays). A higher ratio * means more compression, but means also a longer access time, as more arrays * have to be probed to build the result. Note that we must build an array * every time {@link #get(long)} is called, but this class provides also methods * that extract one of the stored arrays in a given array, reducing garbage * collection. See the documentation of the family of {@code get()} * methods. * *

By setting the ratio to 1 we actually disable front coding: however, we * still have a data structure storing large list of arrays with a reduced * overhead (just one integer per array, plus the space required for lengths). * *

Note that the typical usage of front-coded lists is under the form of * serialized objects; usually, the data that has to be compacted is processed * offline, and the resulting structure is stored permanently. Since the * pointer array is not stored, the serialized format is very small. * *

Implementation Details

* *

All arrays are stored in a {@linkplain it.unimi.dsi.fastutil.BigArrays big array}. A separate array of pointers * indexes arrays whose position is a multiple of the ratio: thus, a higher ratio * means also less pointers. * *

More in detail, an array whose position is a multiple of the ratio is * stored as the array length, followed by the elements of the array. The array * length is coded by a simple variable-length list of k-1 bit * blocks, where k is the number of bits of the underlying primitive * type. All other arrays are stored as follows: let {@code common} the * length of the maximum common prefix between the array and its predecessor. * Then we store the array length decremented by {@code common}, followed * by {@code common}, followed by the array elements whose index is * greater than or equal to {@code common}. For instance, if we store * {@code foo}, {@code foobar}, {@code football} and * {@code fool} in a front-coded character-array list with ratio 3, the * character array will contain * *

 * 3 f o o 3 3 b a r 5 3 t b a l l 4 f o o l
 * 
*/ public class ARRAY_FRONT_CODED_BIG_LIST extends AbstractObjectBigList implements Serializable, Cloneable, RandomAccess { private static final long serialVersionUID = 1L; /** The number of arrays in the list. */ protected final long n; /** The ratio of this front-coded list. */ protected final int ratio; /** The big array containing the compressed arrays. */ protected final KEY_TYPE[][] array; /** The pointers to entire arrays in the list. */ protected transient long[][] p; /** Creates a new front-coded list containing the arrays returned by the given iterator. * * @param arrays an iterator returning arrays. * @param ratio the desired ratio. */ public ARRAY_FRONT_CODED_BIG_LIST(final Iterator arrays, final int ratio) { if (ratio < 1) throw new IllegalArgumentException("Illegal ratio (" + ratio + ")"); KEY_TYPE[][] array = BIG_ARRAYS.EMPTY_BIG_ARRAY; long[][] p = LongBigArrays.EMPTY_BIG_ARRAY; KEY_TYPE[][] a = new KEY_TYPE[2][]; long curSize = 0; long n = 0; int b = 0, length; while(arrays.hasNext()) { a[b] = arrays.next(); length = a[b].length; if (n % ratio == 0) { p = grow(p, n / ratio + 1); BigArrays.set(p, n / ratio, curSize); array = grow(array, curSize + count(length) + length, curSize); curSize += writeInt(array, length, curSize); copyToBig(a[b], 0, array, curSize, length); curSize += length; } else { final int minLength = Math.min(a[1 - b].length, length); int common; for(common = 0; common < minLength; common++) if (a[0][common] != a[1][common]) break; length -= common; array = grow(array, curSize + count(length) + count(common) + length, curSize); curSize += writeInt(array, length, curSize); curSize += writeInt(array, common, curSize); copyToBig(a[b], common, array, curSize, length); curSize += length; } b = 1 - b; n++; } this.n = n; this.ratio = ratio; this.array = trim(array, curSize); this.p = trim(p, (n + ratio - 1) / ratio); } /** Creates a new front-coded list containing the arrays in the given collection. * * @param c a collection containing arrays. * @param ratio the desired ratio. */ public ARRAY_FRONT_CODED_BIG_LIST(final Collection c, final int ratio) { this(c.iterator(), ratio); } public int ratio() { return ratio; } /** Computes the length of the array at the given index. * *

This private version of {@link #arrayLength(long)} does not check its argument. * * @param index an index. * @return the length of the {@code index}-th array. */ private int length(final long index) { final KEY_TYPE[][] array = this.array; final int delta = (int)(index % ratio); // The index into the p array, and the delta inside the block. long pos = BigArrays.get(p, index / ratio); // The position into the array of the first entire word before the index-th. int length = readInt(array, pos); if (delta == 0) return length; // First of all, we recover the array length and the maximum amount of copied elements. int common; pos += count(length) + length; length = readInt(array, pos); common = readInt(array, pos + count(length)); for(int i = 0; i < delta - 1; i++) { pos += count(length) + count(common) + length; length = readInt(array, pos); common = readInt(array, pos + count(length)); } return length + common; } /** Computes the length of the array at the given index. * * @param index an index. * @return the length of the {@code index}-th array. */ public int arrayLength(final long index) { ensureRestrictedIndex(index); return length(index); } /** Extracts the array at the given index. * * @param index an index. * @param a the array that will store the result (we assume that it can hold the result). * @param offset an offset into {@code a} where elements will be store. * @param length a maximum number of elements to store in {@code a}. * @return the length of the extracted array. */ private int extract(final long index, final KEY_TYPE a[], final int offset, final int length) { final int delta = (int)(index % ratio); // The delta inside the block. final long startPos = BigArrays.get(p, index / ratio); // The position into the array of the first entire word before the index-th. long pos, prevArrayPos; int arrayLength = readInt(array, pos = startPos), currLen = 0, actualCommon; if (delta == 0) { pos = BigArrays.get(p, index / ratio) + count(arrayLength); copyFromBig(array, pos, a, offset, Math.min(length, arrayLength)); return arrayLength; } int common = 0; for(int i = 0; i < delta; i++) { prevArrayPos = pos + count(arrayLength) + (i != 0 ? count(common) : 0); pos = prevArrayPos + arrayLength; arrayLength = readInt(array, pos); common = readInt(array, pos + count(arrayLength)); actualCommon = Math.min(common, length); if (actualCommon <= currLen) currLen = actualCommon; else { copyFromBig(array, prevArrayPos, a, currLen + offset, actualCommon - currLen); currLen = actualCommon; } } if (currLen < length) copyFromBig(array, pos + count(arrayLength) + count(common), a, currLen + offset, Math.min(arrayLength, length - currLen)); return arrayLength + common; } /** {@inheritDoc} * @implSpec This implementation delegates to {@link #getArray(long)}. */ @Override public KEY_TYPE[] get(final long index) { return getArray(index); } /** Returns an array stored in this front-coded list. * * @param index an index. * @return the corresponding array stored in this front-coded list. */ public KEY_TYPE[] getArray(final long index) { ensureRestrictedIndex(index); final int length = length(index); final KEY_TYPE a[] = new KEY_TYPE[length]; extract(index, a, 0, length); return a; } /** Stores in the given array elements from an array stored in this front-coded list. * * @param index an index. * @param a the array that will store the result. * @param offset an offset into {@code a} where elements will be store. * @param length a maximum number of elements to store in {@code a}. * @return if {@code a} can hold the extracted elements, the number of extracted elements; * otherwise, the number of remaining elements with the sign changed. */ public int get(final long index, final KEY_TYPE[] a, final int offset, final int length) { ensureRestrictedIndex(index); ARRAYS.ensureOffsetLength(a, offset, length); final int arrayLength = extract(index, a, offset, length); if (length >= arrayLength) return arrayLength; return length - arrayLength; } /** Stores in the given array an array stored in this front-coded list. * * @param index an index. * @param a the array that will store the content of the result (we assume that it can hold the result). * @return if {@code a} can hold the extracted elements, the number of extracted elements; * otherwise, the number of remaining elements with the sign changed. */ public int get(final long index, final KEY_TYPE[] a) { return get(index, a, 0, a.length); } @Override public long size64() { return n; } @Override public ObjectBigListIterator listIterator(final long start) { ensureIndex(start); return new ObjectBigListIterator() { KEY_TYPE s[] = ARRAYS.EMPTY_ARRAY; long i = 0; long pos = 0; boolean inSync; // Whether the current value in a is the string just before the next to be produced. { if (start != 0) { if (start == n) i = start; // If we start at the end, we do nothing. else { pos = BigArrays.get(p, start / ratio); int j = (int)(start % ratio); i = start - j; while(j-- != 0) next(); } } } @Override public boolean hasNext() { return i < n; } @Override public boolean hasPrevious() { return i > 0; } @Override public long previousIndex() { return i - 1; } @Override public long nextIndex() { return i; } @Override public KEY_TYPE[] next() { int length, common; if (! hasNext()) throw new NoSuchElementException(); if (i % ratio == 0) { pos = BigArrays.get(p, i / ratio); length = readInt(array, pos); s = ARRAYS.ensureCapacity(s, length, 0); copyFromBig(array, pos + count(length), s, 0, length); pos += length + count(length); inSync = true; } else { if (inSync) { length = readInt(array, pos); common = readInt(array, pos + count(length)); s = ARRAYS.ensureCapacity(s, length + common, common); copyFromBig(array, pos + count(length) + count (common), s, common, length); pos += count(length) + count(common) + length; length += common; } else { s = ARRAYS.ensureCapacity(s, length = length(i), 0); extract(i, s, 0, length); } } i++; return ARRAYS.copy(s, 0, length); } @Override public KEY_TYPE[] previous() { if (! hasPrevious()) throw new NoSuchElementException(); inSync = false; return getArray(--i); } }; } /** Returns a copy of this list. * * @return a copy of this list. */ @Override public ARRAY_FRONT_CODED_BIG_LIST clone() { return this; } @Override public String toString() { final StringBuffer s = new StringBuffer(); s.append("["); for(long i = 0; i < n; i++) { if (i != 0) s.append(", "); s.append(ARRAY_LIST.wrap(getArray(i)).toString()); } s.append("]"); return s.toString(); } /** Computes the pointer big array using the currently set ratio, number of elements and underlying array. * * @return the computed pointer big array. */ protected long[][] rebuildPointerArray() { final long[][] p = LongBigArrays.newBigArray((n + ratio - 1) / ratio); final KEY_TYPE a[][] = array; int length, count; long pos = 0; int skip = ratio - 1; for(long i = 0, j = 0; i < n; i++) { length = readInt(a, pos); count = count(length); if (++skip == ratio) { skip = 0; BigArrays.set(p, j++, pos); pos += count + length; } else pos += count + count(readInt(a, pos + count)) + length; } return p; } public void dump(java.io.DataOutputStream array, java.io.DataOutputStream pointers) throws java.io.IOException { for(KEY_TYPE[] s: this.array) for(KEY_TYPE e :s) array.WRITE_KEY(e); for(long[] s: p) for(long e: s) pointers.writeLong(e); } private void readObject(java.io.ObjectInputStream s) throws java.io.IOException, ClassNotFoundException { s.defaultReadObject(); // Rebuild pointer array p = rebuildPointerArray(); } }





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