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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) 2010-2022 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.
	*
	* For the sorting code:
	*
	* Copyright (C) 1999 CERN - European Organization for Nuclear Research.
	*
	*   Permission to use, copy, modify, distribute and sell this software and
	*   its documentation for any purpose is hereby granted without fee,
	*   provided that the above copyright notice appear in all copies and that
	*   both that copyright notice and this permission notice appear in
	*   supporting documentation. CERN makes no representations about the
	*   suitability of this software for any purpose. It is provided "as is"
	*   without expressed or implied warranty.
	*/
package it.unimi.dsi.fastutil;
import it.unimi.dsi.fastutil.ints.IntBigArrayBigList;
import it.unimi.dsi.fastutil.longs.LongComparator;
import it.unimi.dsi.fastutil.bytes.ByteBigArrays;
import it.unimi.dsi.fastutil.booleans.BooleanBigArrays;
import it.unimi.dsi.fastutil.chars.CharBigArrays;
import it.unimi.dsi.fastutil.shorts.ShortBigArrays;
import it.unimi.dsi.fastutil.ints.IntBigArrays;
import it.unimi.dsi.fastutil.longs.LongBigArrays;
import it.unimi.dsi.fastutil.floats.FloatBigArrays;
import it.unimi.dsi.fastutil.doubles.DoubleBigArrays;
import it.unimi.dsi.fastutil.objects.ObjectBigArrays;
import it.unimi.dsi.fastutil.booleans.BooleanArrays;
import it.unimi.dsi.fastutil.bytes.ByteArrays;
import it.unimi.dsi.fastutil.chars.CharArrays;
import it.unimi.dsi.fastutil.shorts.ShortArrays;
import it.unimi.dsi.fastutil.ints.IntArrays;
import it.unimi.dsi.fastutil.longs.LongArrays;
import it.unimi.dsi.fastutil.floats.FloatArrays;
import it.unimi.dsi.fastutil.doubles.DoubleArrays;
import it.unimi.dsi.fastutil.objects.ObjectArrays;
import java.util.concurrent.atomic.AtomicIntegerArray;
import java.util.concurrent.atomic.AtomicLongArray;
import java.util.Random;
/**
	* A class providing static methods and objects that do useful things with big
	* arrays.
	*
	* Introducing big arrays
	*
	* 
	* A big array is an array-of-arrays representation of an array. The
	* length of a big array is bounded by {@link #SEGMENT_SIZE} *
	* {@link Integer#MAX_VALUE} = {@value #SEGMENT_SIZE} * (2³¹ −
	* 1) rather than {@link Integer#MAX_VALUE}. The type of a big array is that of
	* an array-of-arrays, so a big array of integers is of type
	* {@code int[][]}. Note that {@link #SEGMENT_SIZE} has been chosen so that
	* a single segment is smaller than 2³¹ bytes independently of the
	* data type. It might be enlarged in the future.
	*
	* 

	* If {@code a} is a big array, {@code a[0]}, {@code a[1]},
	* … are called the segments of the big array. All segments,
	* except possibly for the last one, are of length {@link #SEGMENT_SIZE}. Given
	* an index {@code i} into a big array, there is an associated
	* {@linkplain #segment(long) segment} and an associated
	* {@linkplain #displacement(long)
	* displacement} into that segment. Access to single members happens by
	* means of accessors (see, e.g., {@link #get(int[][], long)} and
	* {@link #set(int[][], long, int)}), but you can also use the
	* methods {@link #segment(long)}/{@link #displacement(long)} to access entries
	* manually.
	*
	* 
The intended usage of most of the methods of this class is that they
	* will be imported statically: for example,
	* 
	* import static it.unimi.dsi.fastutil.BigArrays.copy;
	* import static it.unimi.dsi.fastutil.BigArrays.get;
	* import static it.unimi.dsi.fastutil.BigArrays.length;
	* import static it.unimi.dsi.fastutil.BigArrays.set;
	* 
	*
	* Dynamic binding will take care of selecting the right method depending
	* on the array type.
	*
	* 
Scanning big arrays
	*
	* 
	* You can scan a big array using the following idiomatic form:
	*
	* 
	* for(int s = 0; s < a.length; s++) {
	*     final int[] t = a[s];
	*     final int l = t.length;
	*     for(int d = 0; d < l; d++) {
	*          do something with t[d]
	*     }
	* }
	* 
	*
	* or using the simpler reversed version:
	*
	* 	* for(int s = a.length; s-- != 0;) {
	*     final int[] t = a[s];
	*     for(int d = t.length; d-- != 0;) {
	*         do something with t[d]
	*     }
	* }
	* 
	* 
	* Inside the inner loop, the original index in {@code a} can be retrieved
	* using {@link #index(int, int) index(segment, displacement)}. You can also
	* use an additional long to keep track of the index.
	*
	* 

	* Note that caching is essential in making these loops essentially as fast as
	* those scanning standard arrays (as iterations of the outer loop happen very
	* rarely). Using loops of this kind is extremely faster than using a standard
	* loop and accessors.
	*
	* 

	* In some situations, you might want to iterate over a part of a big array
	* having an offset and a length. In this case, the idiomatic loops are as
	* follows:
	*
	* 
	* for(int s = segment(offset); s < segment(offset + length + SEGMENT_MASK); s++) {
	*     final int[] t = a[s];
	*     final int l = (int)Math.min(t.length, offset + length - start(s));
	*     for(int d = (int)Math.max(0, offset - start(s)); d < l; d++) {
	*         do something with t[d]
	*     }
	* }
	* 
	*
	* or, in a reversed form,
	*
	* 	* for(int s = segment(offset + length + SEGMENT_MASK); s-- != segment(offset);) {
	*     final int[] t = a[s];
	*     final int b = (int)Math.max(0, offset - start(s));
	*     for(int d = (int)Math.min(t.length, offset + length - start(s)); d-- != b ;) {
	*         do something with t[d]
	*     }
	* }
	* 
	*
	* Literal big arrays
	*
	* 
	* A literal big array can be easily created by using the suitable type-specific
	* {@code wrap()} method (e.g., {@link BigArrays#wrap(int[])}) around a
	* standard Java literal array.
	*
	* 
Atomic big arrays
	*
	* Limited support is available for atomic big arrays of integers and longs, with a similar syntax. Atomic big arrays are
	* arrays of instances of {@link java.util.concurrent.atomic.AtomicIntegerArray} or
	* {@link java.util.concurrent.atomic.AtomicLongArray} of length {@link #SEGMENT_SIZE} (or less, for
	* the last segment, as usual) and their size cannot be changed. Some methods from those classes are
	* available in {@link BigArrays} for atomic big arrays (e.g.,
	* {@link BigArrays#incrementAndGet(AtomicIntegerArray[], long)}).
	*
	* 
Big alternatives
	*
	* 
	* If you find the kind of “bare hands” approach to big arrays not
	* enough object-oriented, please use big lists based on big arrays (e.g.,
	* {@link IntBigArrayBigList}). Big arrays follow the Java tradition of
	* considering arrays as a “legal alien”—something in-between
	* an object and a primitive type. This approach lacks the consistency of a full
	* object-oriented approach, but provides some significant performance gains.
	*
	* 
Additional methods
	*
	* In particular, the {@code ensureCapacity()}, {@code grow()},
	* {@code trim()} and {@code setLength()} methods allow to handle
	* arrays much like array lists.
	*
	* 

	* In addition to commodity methods, this class contains {@link BigSwapper}-based 
	* implementations of
	* {@linkplain #quickSort(long, long, LongComparator, BigSwapper) quicksort} and
	* of a stable, in-place
	* {@linkplain #mergeSort(long, long, LongComparator, BigSwapper) mergesort}.
	* These generic sorting methods can be used to sort any kind of list, but they
	* find their natural usage, for instance, in sorting big arrays in parallel.
	*
	* @see it.unimi.dsi.fastutil.Arrays
	*/
public class BigArrays {
	/**
	 * The shift used to compute the segment associated with an index
	 * (equivalently, the logarithm of the segment size).
	 */
	public static final int SEGMENT_SHIFT = 27;
	/**
	 * The current size of a segment (2²⁷) is the largest size that
	 * makes the physical memory allocation for a single segment strictly
	 * smaller than 2³¹ bytes.
	 */
	public static final int SEGMENT_SIZE = 1 << SEGMENT_SHIFT;
	/** The mask used to compute the displacement associated to an index. */
	public static final int SEGMENT_MASK = SEGMENT_SIZE - 1;
	protected BigArrays() {
	}
	/**
	 * Computes the segment associated with a given index.
	 *
	 * @param index
	 *            an index into a big array.
	 * @return the associated segment.
	 */
	public static int segment(final long index) {
	 return (int) (index >>> SEGMENT_SHIFT);
	}
	/**
	 * Computes the displacement associated with a given index.
	 *
	 * @param index
	 *            an index into a big array.
	 * @return the associated displacement (in the associated
	 *         {@linkplain #segment(long) segment}).
	 */
	public static int displacement(final long index) {
	 return (int) (index & SEGMENT_MASK);
	}
	/**
	 * Computes the starting index of a given segment.
	 *
	 * @param segment
	 *            the segment of a big array.
	 * @return the starting index of the segment.
	 */
	public static long start(final int segment) {
	 return (long) segment << SEGMENT_SHIFT;
	}
	/**
	 * Computes the nearest segment starting index of a given index.
	 *
	 * 
This will either be {@code start(segment(index)} or {@code start(segment(index) + 1)},
	 * whichever is closer, given the bounds can be respected. If neither segment start is within
	 * the bounds, then the index is returned unmodified.
	 *
	 * 
This method can be useful for operations that seek to align on the outer array's boundaries
	 * when possible.
	 *
	 * @implSpec The current implementation is branch heavy and is thus not suitable for use in
	 * inner loops. However, it should be fine for the recursive step, where split points are
	 * computed. 
	 *
	 * @param index
	 *            an index into a big array.
	 * @param min
	 *            the minimum (inclusive) valid index of the big array in question
	 * @param max
	 *            the maximum (exclusive) valid index of the big array in question
	 * @return the closest segment starting index to {@code index}
	 * @since 8.5.0
	 */
	public static long nearestSegmentStart(final long index, final long min, final long max) {
	 // There probably is a less branchy, bit twiddly way to do this, but this is fine for now.
	 // This isn't going to be used in inner loops, only the recursive call.
	 final long lower = start(segment(index));
	 final long upper = start(segment(index) + 1);
	 if (upper >= max) {
	     if (lower < min) {
	         return index;
	     }
	     return lower;
	 }
	 if (lower < min) return upper;
	 // Overflow avoiding midpoint computation
	 final long mid = lower + ((upper - lower) >> 1);
	 return index <= mid ? lower : upper;
	}
	/**
	 * Computes the index associated with given segment and displacement.
	 *
	 * @param segment
	 *            the segment of a big array.
	 * @param displacement
	 *            the displacement into the segment.
	 * @return the associated index: that is, {@link #segment(long)
	 *         segment(index(segment, displacement)) == segment} and
	 *         {@link #displacement(long) displacement(index(segment,
	 *         displacement)) == displacement}.
	 */
	public static long index(final int segment, final int displacement) {
	 return start(segment) + displacement;
	}
	/**
	 * Ensures that a range given by its first (inclusive) and last (exclusive)
	 * elements fits a big array of given length.
	 *
	 * 

	 * This method may be used whenever a big array range check is needed.
	 *
	 * @param bigArrayLength
	 *            a big-array length (must be nonnegative).
	 * @param from
	 *            a start index (inclusive).
	 * @param to
	 *            an end index (inclusive).
	 * @throws IllegalArgumentException
	 *             if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException
	 *             if {@code from} or {@code to} are greater than
	 *             {@code bigArrayLength} or negative.
	 *
	 * @implNote An {@code assert} checks whether {@code bigArrayLength} is nonnegative.
	 */
	public static void ensureFromTo(final long bigArrayLength, final long from, final long to) {
	 assert bigArrayLength >= 0;
	 if (from < 0) throw new ArrayIndexOutOfBoundsException("Start index (" + from + ") is negative");
	 if (from > to) throw new IllegalArgumentException("Start index (" + from + ") is greater than end index (" + to + ")");
	 if (to > bigArrayLength) throw new ArrayIndexOutOfBoundsException("End index (" + to + ") is greater than big-array length (" + bigArrayLength + ")");
	}
	/**
	 * Ensures that a range given by an offset and a length fits a big array of
	 * given length.
	 *
	 * 

	 * This method may be used whenever a big array range check is needed.
	 *
	 * @param bigArrayLength
	 *            a big-array length (must be nonnegative).
	 * @param offset
	 *            a start index for the fragment
	 * @param length
	 *            a length (the number of elements in the fragment).
	 * @throws IllegalArgumentException
	 *             if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException
	 *             if {@code offset} is negative or {@code offset} +
	 *             {@code length} is greater than
	 *             {@code bigArrayLength}.
	 *
	 * @implNote An {@code assert} checks whether {@code bigArrayLength} is nonnegative.
	 */
	public static void ensureOffsetLength(final long bigArrayLength, final long offset, final long length) {
	 assert bigArrayLength >= 0;
	 if (offset < 0) throw new ArrayIndexOutOfBoundsException("Offset (" + offset + ") is negative");
	 if (length < 0) throw new IllegalArgumentException("Length (" + length + ") is negative");
	 if (length > bigArrayLength - offset) throw new ArrayIndexOutOfBoundsException("Last index (" + Long.toUnsignedString(offset + length) + ") is greater than big-array length (" + bigArrayLength + ")");
	}
	/**
	 * Ensures that a big-array length is legal.
	 *
	 * @param bigArrayLength
	 *            a big-array length.
	 * @throws IllegalArgumentException
	 *             if {@code length} is negative, or larger than or equal
	 *             to {@link #SEGMENT_SIZE} * {@link Integer#MAX_VALUE}.
	 */
	public static void ensureLength(final long bigArrayLength) {
	 if (bigArrayLength < 0) throw new IllegalArgumentException("Negative big-array size: " + bigArrayLength);
	 if (bigArrayLength >= (long) Integer.MAX_VALUE << SEGMENT_SHIFT) throw new IllegalArgumentException("Big-array size too big: " + bigArrayLength);
	}
	private static final int SMALL = 7;
	private static final int MEDIUM = 40;
	/**
	 * Transforms two consecutive sorted ranges into a single sorted range. The
	 * initial ranges are {@code [first, middle)} and
	 * {@code [middle, last)}, and the resulting range is
	 * {@code [first, last)}. Elements in the first input range will
	 * precede equal elements in the second.
	 */
	private static void inPlaceMerge(final long from, long mid, final long to, final LongComparator comp, final BigSwapper swapper) {
	 if (from >= mid || mid >= to) return;
	 if (to - from == 2) {
	  if (comp.compare(mid, from) < 0) {
	   swapper.swap(from, mid);
	  }
	  return;
	 }
	 long firstCut;
	 long secondCut;
	 if (mid - from > to - mid) {
	  firstCut = from + (mid - from) / 2;
	  secondCut = lowerBound(mid, to, firstCut, comp);
	 } else {
	  secondCut = mid + (to - mid) / 2;
	  firstCut = upperBound(from, mid, secondCut, comp);
	 }
	 long first2 = firstCut;
	 long middle2 = mid;
	 long last2 = secondCut;
	 if (middle2 != first2 && middle2 != last2) {
	  long first1 = first2;
	  long last1 = middle2;
	  while (first1 < --last1)
	   swapper.swap(first1++, last1);
	  first1 = middle2;
	  last1 = last2;
	  while (first1 < --last1)
	   swapper.swap(first1++, last1);
	  first1 = first2;
	  last1 = last2;
	  while (first1 < --last1)
	   swapper.swap(first1++, last1);
	 }
	 mid = firstCut + (secondCut - mid);
	 inPlaceMerge(from, firstCut, mid, comp, swapper);
	 inPlaceMerge(mid, secondCut, to, comp, swapper);
	}
	/**
	 * Performs a binary search on an already sorted range: finds the first
	 * position where an element can be inserted without violating the ordering.
	 * Sorting is by a user-supplied comparison function.
	 *
	 * @param mid
	 *            Beginning of the range.
	 * @param to
	 *            One past the end of the range.
	 * @param firstCut
	 *            Element to be searched for.
	 * @param comp
	 *            Comparison function.
	 * @return The largest index i such that, for every j in the range
	 *         {@code [first, i)}, {@code comp.apply(array[j], x)} is
	 *         {@code true}.
	 */
	private static long lowerBound(long mid, final long to, final long firstCut, final LongComparator comp) {
	 long len = to - mid;
	 while (len > 0) {
	  long half = len / 2;
	  long middle = mid + half;
	  if (comp.compare(middle, firstCut) < 0) {
	   mid = middle + 1;
	   len -= half + 1;
	  } else {
	   len = half;
	  }
	 }
	 return mid;
	}
	/** Returns the index of the median of three elements. */
	private static long med3(final long a, final long b, final long c, final LongComparator comp) {
	 final int ab = comp.compare(a, b);
	 final int ac = comp.compare(a, c);
	 final int bc = comp.compare(b, c);
	 return (ab < 0 ? (bc < 0 ? b : ac < 0 ? c : a) : (bc > 0 ? b : ac > 0 ? c : a));
	}
	/**
	 * Sorts the specified range of elements using the specified big swapper and
	 * according to the order induced by the specified comparator using
	 * mergesort.
	 *
	 * 

	 * This sort is guaranteed to be stable: equal elements will not be
	 * reordered as a result of the sort. The sorting algorithm is an in-place
	 * mergesort that is significantly slower than a standard mergesort, as its
	 * running time is
	 * O(n (log n)²), but it
	 * does not allocate additional memory; as a result, it can be used as a
	 * generic sorting algorithm.
	 *
	 * @param from
	 *            the index of the first element (inclusive) to be sorted.
	 * @param to
	 *            the index of the last element (exclusive) to be sorted.
	 * @param comp
	 *            the comparator to determine the order of the generic data
	 *            (arguments are positions).
	 * @param swapper
	 *            an object that knows how to swap the elements at any two
	 *            positions.
	 */
	public static void mergeSort(final long from, final long to, final LongComparator comp, final BigSwapper swapper) {
	 final long length = to - from;
	 // Insertion sort on smallest arrays
	 if (length < SMALL) {
	  for (long i = from; i < to; i++) {
	   for (long j = i; j > from && (comp.compare(j - 1, j) > 0); j--) {
	    swapper.swap(j, j - 1);
	   }
	  }
	  return;
	 }
	 // Recursively sort halves
	 long mid = (from + to) >>> 1;
	 mergeSort(from, mid, comp, swapper);
	 mergeSort(mid, to, comp, swapper);
	 // If list is already sorted, nothing left to do. This is an
	 // optimization that results in faster sorts for nearly ordered lists.
	 if (comp.compare(mid - 1, mid) <= 0) return;
	 // Merge sorted halves
	 inPlaceMerge(from, mid, to, comp, swapper);
	}
	/**
	 * Sorts the specified range of elements using the specified big swapper and
	 * according to the order induced by the specified comparator using
	 * quicksort.
	 *
	 * 

	 * The sorting algorithm is a tuned quicksort adapted from Jon L. Bentley
	 * and M. Douglas McIlroy, “Engineering a Sort Function”,
	 * Software: Practice and Experience, 23(11), pages 1249−1265,
	 * 1993.
	 *
	 * @param from
	 *            the index of the first element (inclusive) to be sorted.
	 * @param to
	 *            the index of the last element (exclusive) to be sorted.
	 * @param comp
	 *            the comparator to determine the order of the generic data.
	 * @param swapper
	 *            an object that knows how to swap the elements at any two
	 *            positions.
	 */
	public static void quickSort(final long from, final long to, final LongComparator comp, final BigSwapper swapper) {
	 final long len = to - from;
	 // Insertion sort on smallest arrays
	 if (len < SMALL) {
	  for (long i = from; i < to; i++)
	   for (long j = i; j > from && (comp.compare(j - 1, j) > 0); j--) {
	    swapper.swap(j, j - 1);
	   }
	  return;
	 }
	 // Choose a partition element, v
	 long m = from + len / 2; // Small arrays, middle element
	 if (len > SMALL) {
	  long l = from, n = to - 1;
	  if (len > MEDIUM) { // Big arrays, pseudomedian of 9
	   long s = len / 8;
	   l = med3(l, l + s, l + 2 * s, comp);
	   m = med3(m - s, m, m + s, comp);
	   n = med3(n - 2 * s, n - s, n, comp);
	  }
	  m = med3(l, m, n, comp); // Mid-size, med of 3
	 }
	 // long v = x[m];
	 long a = from, b = a, c = to - 1, d = c;
	 // Establish Invariant: v* (v)* v*
	 while (true) {
	  int comparison;
	  while (b <= c && ((comparison = comp.compare(b, m)) <= 0)) {
	   if (comparison == 0) {
	    if (a == m) m = b; // moving target; DELTA to JDK !!!
	    else if (b == m) m = a; // moving target; DELTA to JDK !!!
	    swapper.swap(a++, b);
	   }
	   b++;
	  }
	  while (c >= b && ((comparison = comp.compare(c, m)) >= 0)) {
	   if (comparison == 0) {
	    if (c == m) m = d; // moving target; DELTA to JDK !!!
	    else if (d == m) m = c; // moving target; DELTA to JDK !!!
	    swapper.swap(c, d--);
	   }
	   c--;
	  }
	  if (b > c) break;
	  if (b == m) m = d; // moving target; DELTA to JDK !!!
	  else if (c == m) m = c; // moving target; DELTA to JDK !!!
	  swapper.swap(b++, c--);
	 }
	 // Swap partition elements back to middle
	 long s;
	 long n = from + len;
	 s = Math.min(a - from, b - a);
	 vecSwap(swapper, from, b - s, s);
	 s = Math.min(d - c, n - d - 1);
	 vecSwap(swapper, b, n - s, s);
	 // Recursively sort non-partition-elements
	 if ((s = b - a) > 1) quickSort(from, from + s, comp, swapper);
	 if ((s = d - c) > 1) quickSort(n - s, n, comp, swapper);
	}
	/**
	 * Performs a binary search on an already-sorted range: finds the last
	 * position where an element can be inserted without violating the ordering.
	 * Sorting is by a user-supplied comparison function.
	 *
	 * @param from
	 *            Beginning of the range.
	 * @param mid
	 *            One past the end of the range.
	 * @param secondCut
	 *            Element to be searched for.
	 * @param comp
	 *            Comparison function.
	 * @return The largest index i such that, for every j in the range
	 *         {@code [first, i)}, {@code comp.apply(x, array[j])} is
	 *         {@code false}.
	 */
	private static long upperBound(long from, final long mid, final long secondCut, final LongComparator comp) {
	 long len = mid - from;
	 while (len > 0) {
	  long half = len / 2;
	  long middle = from + half;
	  if (comp.compare(secondCut, middle) < 0) {
	   len = half;
	  } else {
	   from = middle + 1;
	   len -= half + 1;
	  }
	 }
	 return from;
	}
	/** Swaps x[a .. (a+n-1)] with x[b .. (b+n-1)]. */
	private static void vecSwap(final BigSwapper swapper, long from, long l, final long s) {
	 for (int i = 0; i < s; i++, from++, l++)
	  swapper.swap(from, l);
	}
/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static byte get(final byte[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final byte[][] array, final long index, byte value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final byte[][] array, final long first, final long second) {
	 final byte t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static byte[][] reverse(final byte[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final byte[][] array, final long index, byte incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final byte[][] array, final long index, byte factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final byte[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final byte[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final byte[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final byte[][] srcArray, final long srcPos, final byte[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final byte[][] srcArray, final long srcPos, final byte[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final byte[] srcArray, int srcPos, final byte[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static byte[][] wrap(final byte[] array) {
	 if (array.length == 0) return ByteBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new byte[][] { array };
	 final byte[][] bigArray = ByteBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static byte[][] ensureCapacity(final byte[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static byte[][] forceCapacity(final byte[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final byte[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new byte[SEGMENT_SIZE];
	  base[baseLength - 1] = new byte[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new byte[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static byte[][] ensureCapacity(final byte[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static byte[][] grow(final byte[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static byte[][] grow(final byte[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static byte[][] trim(final byte[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final byte[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = ByteArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static byte[][] setLength(final byte[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static byte[][] copy(final byte[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final byte[][] a =
	  ByteBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static byte[][] copy(final byte[][] array) {
	 final byte[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final byte[][] array, final byte value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final byte[][] array, final long from, long to, final byte value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final byte[][] a1, final byte a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 byte[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( (t[j]) == (u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final byte[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final byte[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final byte[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final byte[][] a, final byte[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static byte[][] shuffle(final byte[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final byte t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static byte[][] shuffle(final byte[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final byte t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static int get(final int[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final int[][] array, final long index, int value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Returns the length of the given big atomic array.
	 *
	 * @param array a big atomic array.
	 * @return the length of the given big atomic array.
	 */
	public static long length(final AtomicIntegerArray[] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length();
	}
	/** Returns the element of the given big atomic array of specified index.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the element of the big atomic array at the specified position.
	 */
	public static int get(final AtomicIntegerArray[] array, final long index) {
	 return array[segment(index)].get(displacement(index));
	}
	/** Sets an element of the given big atomic array to a specified value
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a new value for the element of the big atomic array at the specified position.
	 */
	public static void set(final AtomicIntegerArray[] array, final long index, int value) {
	 array[segment(index)].set(displacement(index), value);
	}
	/** Atomically sets an element of the given big atomic array to a specified value, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a new value for the element of the big atomic array at the specified position.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static int getAndSet(final AtomicIntegerArray[] array, final long index, int value) {
	 return array[segment(index)].getAndSet(displacement(index), value);
	}
	/** Atomically adds a value to an element of the given big atomic array, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a value to add to the element of the big atomic array at the specified position.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static int getAndAdd(final AtomicIntegerArray[] array, final long index, int value) {
	 return array[segment(index)].getAndAdd(displacement(index), value);
	}
	/** Atomically adds a value to an element of the given big atomic array, returning the new value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a value to add to the element of the big atomic array at the specified position.
	 * @return the new value of the element of the big atomic array at the specified position.
	 */
	public static int addAndGet(final AtomicIntegerArray[] array, final long index, int value) {
	 return array[segment(index)].addAndGet(displacement(index), value);
	}
	/** Atomically increments an element of the given big atomic array, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static int getAndIncrement(final AtomicIntegerArray[] array, final long index) {
	 return array[segment(index)].getAndDecrement(displacement(index));
	}
	/** Atomically increments an element of the given big atomic array, returning the new value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the new value of the element of the big atomic array at the specified position.
	 */
	public static int incrementAndGet(final AtomicIntegerArray[] array, final long index) {
	 return array[segment(index)].incrementAndGet(displacement(index));
	}
	/** Atomically decrements an element of the given big atomic array, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static int getAndDecrement(final AtomicIntegerArray[] array, final long index) {
	 return array[segment(index)].getAndDecrement(displacement(index));
	}
	/** Atomically decrements an element of the given big atomic array, returning the new value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the new value of the element of the big atomic array at the specified position.
	 */
	public static int decrementAndGet(final AtomicIntegerArray[] array, final long index) {
	 return array[segment(index)].decrementAndGet(displacement(index));
	}
	/** Atomically sets an element of the given big atomic array of specified index to specified value, given 
	 *  the current value is equal to a given expected value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param expected an expected value for the element of the big atomic array at the specified position.
	 * @param value a new value for the element of the big atomic array at the specified position.
	 * @return the element of the big atomic array at the specified position.
	 */
	public static boolean compareAndSet(final AtomicIntegerArray[] array, final long index, int expected, int value) {
	 return array[segment(index)].compareAndSet(displacement(index), expected, value);
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final int[][] array, final long first, final long second) {
	 final int t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static int[][] reverse(final int[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final int[][] array, final long index, int incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final int[][] array, final long index, int factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final int[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final int[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final int[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final int[][] srcArray, final long srcPos, final int[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final int[][] srcArray, final long srcPos, final int[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final int[] srcArray, int srcPos, final int[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static int[][] wrap(final int[] array) {
	 if (array.length == 0) return IntBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new int[][] { array };
	 final int[][] bigArray = IntBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static int[][] ensureCapacity(final int[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static int[][] forceCapacity(final int[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final int[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new int[SEGMENT_SIZE];
	  base[baseLength - 1] = new int[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new int[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static int[][] ensureCapacity(final int[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static int[][] grow(final int[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static int[][] grow(final int[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static int[][] trim(final int[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final int[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = IntArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static int[][] setLength(final int[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static int[][] copy(final int[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final int[][] a =
	  IntBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static int[][] copy(final int[][] array) {
	 final int[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final int[][] array, final int value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final int[][] array, final long from, long to, final int value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final int[][] a1, final int a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 int[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( (t[j]) == (u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final int[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final int[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final int[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final int[][] a, final int[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static int[][] shuffle(final int[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final int t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static int[][] shuffle(final int[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final int t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static long get(final long[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final long[][] array, final long index, long value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Returns the length of the given big atomic array.
	 *
	 * @param array a big atomic array.
	 * @return the length of the given big atomic array.
	 */
	public static long length(final AtomicLongArray[] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length();
	}
	/** Returns the element of the given big atomic array of specified index.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the element of the big atomic array at the specified position.
	 */
	public static long get(final AtomicLongArray[] array, final long index) {
	 return array[segment(index)].get(displacement(index));
	}
	/** Sets an element of the given big atomic array to a specified value
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a new value for the element of the big atomic array at the specified position.
	 */
	public static void set(final AtomicLongArray[] array, final long index, long value) {
	 array[segment(index)].set(displacement(index), value);
	}
	/** Atomically sets an element of the given big atomic array to a specified value, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a new value for the element of the big atomic array at the specified position.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static long getAndSet(final AtomicLongArray[] array, final long index, long value) {
	 return array[segment(index)].getAndSet(displacement(index), value);
	}
	/** Atomically adds a value to an element of the given big atomic array, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a value to add to the element of the big atomic array at the specified position.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static long getAndAdd(final AtomicLongArray[] array, final long index, long value) {
	 return array[segment(index)].getAndAdd(displacement(index), value);
	}
	/** Atomically adds a value to an element of the given big atomic array, returning the new value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param value a value to add to the element of the big atomic array at the specified position.
	 * @return the new value of the element of the big atomic array at the specified position.
	 */
	public static long addAndGet(final AtomicLongArray[] array, final long index, long value) {
	 return array[segment(index)].addAndGet(displacement(index), value);
	}
	/** Atomically increments an element of the given big atomic array, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static long getAndIncrement(final AtomicLongArray[] array, final long index) {
	 return array[segment(index)].getAndDecrement(displacement(index));
	}
	/** Atomically increments an element of the given big atomic array, returning the new value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the new value of the element of the big atomic array at the specified position.
	 */
	public static long incrementAndGet(final AtomicLongArray[] array, final long index) {
	 return array[segment(index)].incrementAndGet(displacement(index));
	}
	/** Atomically decrements an element of the given big atomic array, returning the old value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the old value of the element of the big atomic array at the specified position.
	 */
	public static long getAndDecrement(final AtomicLongArray[] array, final long index) {
	 return array[segment(index)].getAndDecrement(displacement(index));
	}
	/** Atomically decrements an element of the given big atomic array, returning the new value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @return the new value of the element of the big atomic array at the specified position.
	 */
	public static long decrementAndGet(final AtomicLongArray[] array, final long index) {
	 return array[segment(index)].decrementAndGet(displacement(index));
	}
	/** Atomically sets an element of the given big atomic array of specified index to specified value, given 
	 *  the current value is equal to a given expected value.
	 *
	 * @param array a big atomic array.
	 * @param index a position in the big atomic array.
	 * @param expected an expected value for the element of the big atomic array at the specified position.
	 * @param value a new value for the element of the big atomic array at the specified position.
	 * @return the element of the big atomic array at the specified position.
	 */
	public static boolean compareAndSet(final AtomicLongArray[] array, final long index, long expected, long value) {
	 return array[segment(index)].compareAndSet(displacement(index), expected, value);
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final long[][] array, final long first, final long second) {
	 final long t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static long[][] reverse(final long[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final long[][] array, final long index, long incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final long[][] array, final long index, long factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final long[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final long[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final long[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final long[][] srcArray, final long srcPos, final long[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final long[][] srcArray, final long srcPos, final long[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final long[] srcArray, int srcPos, final long[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static long[][] wrap(final long[] array) {
	 if (array.length == 0) return LongBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new long[][] { array };
	 final long[][] bigArray = LongBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static long[][] ensureCapacity(final long[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static long[][] forceCapacity(final long[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final long[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new long[SEGMENT_SIZE];
	  base[baseLength - 1] = new long[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new long[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static long[][] ensureCapacity(final long[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static long[][] grow(final long[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static long[][] grow(final long[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static long[][] trim(final long[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final long[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = LongArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static long[][] setLength(final long[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static long[][] copy(final long[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final long[][] a =
	  LongBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static long[][] copy(final long[][] array) {
	 final long[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final long[][] array, final long value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final long[][] array, final long from, long to, final long value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final long[][] a1, final long a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 long[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( (t[j]) == (u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final long[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final long[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final long[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final long[][] a, final long[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static long[][] shuffle(final long[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final long t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static long[][] shuffle(final long[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final long t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static double get(final double[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final double[][] array, final long index, double value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final double[][] array, final long first, final long second) {
	 final double t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static double[][] reverse(final double[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final double[][] array, final long index, double incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final double[][] array, final long index, double factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final double[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final double[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final double[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final double[][] srcArray, final long srcPos, final double[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final double[][] srcArray, final long srcPos, final double[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final double[] srcArray, int srcPos, final double[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static double[][] wrap(final double[] array) {
	 if (array.length == 0) return DoubleBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new double[][] { array };
	 final double[][] bigArray = DoubleBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static double[][] ensureCapacity(final double[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static double[][] forceCapacity(final double[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final double[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new double[SEGMENT_SIZE];
	  base[baseLength - 1] = new double[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new double[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static double[][] ensureCapacity(final double[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static double[][] grow(final double[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static double[][] grow(final double[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static double[][] trim(final double[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final double[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = DoubleArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static double[][] setLength(final double[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static double[][] copy(final double[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final double[][] a =
	  DoubleBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static double[][] copy(final double[][] array) {
	 final double[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final double[][] array, final double value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final double[][] array, final long from, long to, final double value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final double[][] a1, final double a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 double[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( Double.doubleToLongBits(t[j]) == Double.doubleToLongBits(u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final double[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final double[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final double[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final double[][] a, final double[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static double[][] shuffle(final double[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final double t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static double[][] shuffle(final double[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final double t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static boolean get(final boolean[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final boolean[][] array, final long index, boolean value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final boolean[][] array, final long first, final long second) {
	 final boolean t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static boolean[][] reverse(final boolean[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final boolean[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final boolean[][] srcArray, final long srcPos, final boolean[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final boolean[][] srcArray, final long srcPos, final boolean[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final boolean[] srcArray, int srcPos, final boolean[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static boolean[][] wrap(final boolean[] array) {
	 if (array.length == 0) return BooleanBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new boolean[][] { array };
	 final boolean[][] bigArray = BooleanBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static boolean[][] ensureCapacity(final boolean[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static boolean[][] forceCapacity(final boolean[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final boolean[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new boolean[SEGMENT_SIZE];
	  base[baseLength - 1] = new boolean[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new boolean[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static boolean[][] ensureCapacity(final boolean[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static boolean[][] grow(final boolean[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static boolean[][] grow(final boolean[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static boolean[][] trim(final boolean[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final boolean[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = BooleanArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static boolean[][] setLength(final boolean[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static boolean[][] copy(final boolean[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final boolean[][] a =
	  BooleanBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static boolean[][] copy(final boolean[][] array) {
	 final boolean[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final boolean[][] array, final boolean value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final boolean[][] array, final long from, long to, final boolean value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final boolean[][] a1, final boolean a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 boolean[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( (t[j]) == (u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final boolean[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final boolean[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final boolean[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final boolean[][] a, final boolean[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static boolean[][] shuffle(final boolean[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final boolean t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static boolean[][] shuffle(final boolean[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final boolean t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static short get(final short[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final short[][] array, final long index, short value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final short[][] array, final long first, final long second) {
	 final short t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static short[][] reverse(final short[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final short[][] array, final long index, short incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final short[][] array, final long index, short factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final short[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final short[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final short[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final short[][] srcArray, final long srcPos, final short[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final short[][] srcArray, final long srcPos, final short[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final short[] srcArray, int srcPos, final short[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static short[][] wrap(final short[] array) {
	 if (array.length == 0) return ShortBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new short[][] { array };
	 final short[][] bigArray = ShortBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static short[][] ensureCapacity(final short[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static short[][] forceCapacity(final short[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final short[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new short[SEGMENT_SIZE];
	  base[baseLength - 1] = new short[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new short[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static short[][] ensureCapacity(final short[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static short[][] grow(final short[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static short[][] grow(final short[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static short[][] trim(final short[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final short[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = ShortArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static short[][] setLength(final short[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static short[][] copy(final short[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final short[][] a =
	  ShortBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static short[][] copy(final short[][] array) {
	 final short[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final short[][] array, final short value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final short[][] array, final long from, long to, final short value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final short[][] a1, final short a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 short[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( (t[j]) == (u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final short[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final short[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final short[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final short[][] a, final short[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static short[][] shuffle(final short[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final short t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static short[][] shuffle(final short[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final short t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static char get(final char[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final char[][] array, final long index, char value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final char[][] array, final long first, final long second) {
	 final char t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static char[][] reverse(final char[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final char[][] array, final long index, char incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final char[][] array, final long index, char factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final char[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final char[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final char[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final char[][] srcArray, final long srcPos, final char[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final char[][] srcArray, final long srcPos, final char[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final char[] srcArray, int srcPos, final char[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static char[][] wrap(final char[] array) {
	 if (array.length == 0) return CharBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new char[][] { array };
	 final char[][] bigArray = CharBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static char[][] ensureCapacity(final char[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static char[][] forceCapacity(final char[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final char[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new char[SEGMENT_SIZE];
	  base[baseLength - 1] = new char[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new char[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static char[][] ensureCapacity(final char[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static char[][] grow(final char[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static char[][] grow(final char[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static char[][] trim(final char[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final char[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = CharArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static char[][] setLength(final char[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static char[][] copy(final char[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final char[][] a =
	  CharBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static char[][] copy(final char[][] array) {
	 final char[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final char[][] array, final char value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final char[][] array, final long from, long to, final char value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final char[][] a1, final char a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 char[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( (t[j]) == (u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final char[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final char[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final char[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final char[][] a, final char[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static char[][] shuffle(final char[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final char t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static char[][] shuffle(final char[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final char t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Primitive-type-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static float get(final float[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static void set(final float[][] array, final long index, float value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static void swap(final float[][] array, final long first, final long second) {
	 final float t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static float[][] reverse(final float[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Adds the specified increment the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param incr the increment
	 */
	public static void add(final float[][] array, final long index, float incr) {
	 array[segment(index)][displacement(index)] += incr;
	}
	/** Multiplies by the specified factor the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param factor the factor
	 */
	public static void mul(final float[][] array, final long index, float factor) {
	 array[segment(index)][displacement(index)] *= factor;
	}
	/** Increments the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void incr(final float[][] array, final long index) {
	 array[segment(index)][displacement(index)]++;
	}
	/** Decrements the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 */
	public static void decr(final float[][] array, final long index) {
	 array[segment(index)][displacement(index)]--;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static long length(final float[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copy(final float[][] srcArray, final long srcPos, final float[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyFromBig(final float[][] srcArray, final long srcPos, final float[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static void copyToBig(final float[] srcArray, int srcPos, final float[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	public static float[][] wrap(final float[] array) {
	 if (array.length == 0) return FloatBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) return new float[][] { array };
	 final float[][] bigArray = FloatBigArrays.newBigArray(array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static float[][] ensureCapacity(final float[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static float[][] forceCapacity(final float[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final float[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = new float[SEGMENT_SIZE];
	  base[baseLength - 1] = new float[residual];
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = new float[SEGMENT_SIZE];
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static float[][] ensureCapacity(final float[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static float[][] grow(final float[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static float[][] grow(final float[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static float[][] trim(final float[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final float[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = FloatArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static float[][] setLength(final float[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static float[][] copy(final float[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final float[][] a =
	  FloatBigArrays.newBigArray(length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static float[][] copy(final float[][] array) {
	 final float[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static void fill(final float[][] array, final float value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static void fill(final float[][] array, final long from, long to, final float value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static boolean equals(final float[][] a1, final float a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 float[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! ( Float.floatToIntBits(t[j]) == Float.floatToIntBits(u[j]) )) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static String toString(final float[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static void ensureFromTo(final float[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static void ensureOffsetLength(final float[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static void ensureSameLength(final float[][] a, final float[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static float[][] shuffle(final float[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final float t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static float[][] shuffle(final float[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final float t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}
/* Generic definitions */
/* Assertions (useful to generate conditional code) */
/* Narrowing and widening */
/* Current type and class (and size, if applicable) */
/* Value methods */
/* Interfaces (keys) */
/* Interfaces (values) */
/* Types and methods related to primitive-type support in the JDK */
/* Abstract implementations (keys) */
/* Abstract implementations (values) */
/* Static containers (keys) */
/* Static containers (values) */
/* Implementations */
/* Synchronized wrappers */
/* Unmodifiable wrappers */
/* Other wrappers */
/* Methods (keys) */
/* Methods (values) */
/* Methods (keys/values) */
/* Methods that have special names depending on keys (but the special names depend on values) */
/* Equality */
/* Object/Reference-only definitions (keys) */
/* Object/Reference-only definitions (values) */
/* START_OF_JAVA_SOURCE */
/*
	* Copyright (C) 2004-2022 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.
	*/
	/** Returns the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @return the element of the big array at the specified position.
	 */
	public static  K get(final K[][] array, final long index) {
	 return array[segment(index)][displacement(index)];
	}
	/** Sets the element of the given big array of specified index.
	 *
	 * @param array a big array.
	 * @param index a position in the big array.
	 * @param value the new value for the array element at the specified position.
	 */
	public static  void set(final K[][] array, final long index, K value) {
	 array[segment(index)][displacement(index)] = value;
	}
	/** Swaps the element of the given big array of specified indices.
	 *
	 * @param array a big array.
	 * @param first a position in the big array.
	 * @param second a position in the big array.
	 */
	public static  void swap(final K[][] array, final long first, final long second) {
	 final K t = array[segment(first)][displacement(first)];
	 array[segment(first)][displacement(first)] = array[segment(second)][displacement(second)];
	 array[segment(second)][displacement(second)] = t;
	}
	/** Reverses the order of the elements in the specified big array.
	 *
	 * @param a the big array to be reversed.
	 * @return {@code a}.
	 */
	public static  K[][] reverse(final K[][] a) {
	 final long length = length(a);
	 for(long i = length / 2; i-- != 0;) swap(a, i, length - i- 1);
	 return a;
	}
	/** Returns the length of the given big array.
	 *
	 * @param array a big array.
	 * @return the length of the given big array.
	 */
	public static  long length(final K[][] array) {
	 final int length = array.length;
	 return length == 0 ? 0 : start(length - 1) + array[length - 1].length;
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination big array.
	 * Handles correctly overlapping regions of the same big array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static  void copy(final K[][] srcArray, final long srcPos, final K[][] destArray, final long destPos, long length) {
	 if (destPos <= srcPos) {
	  int srcSegment = segment(srcPos);
	  int destSegment = segment(destPos);
	  int srcDispl = displacement(srcPos);
	  int destDispl = displacement(destPos);
	  while(length > 0) {
	   final int l = (int)Math.min(length, Math.min(srcArray[srcSegment].length - srcDispl, destArray[destSegment].length - destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl, destArray[destSegment], destDispl, l);
	   if ((srcDispl += l) == SEGMENT_SIZE) {
	    srcDispl = 0;
	    srcSegment++;
	   }
	   if ((destDispl += l) == SEGMENT_SIZE) {
	    destDispl = 0;
	    destSegment++;
	   }
	   length -= l;
	  }
	 }
	 else {
	  int srcSegment = segment(srcPos + length);
	  int destSegment = segment(destPos + length);
	  int srcDispl = displacement(srcPos + length);
	  int destDispl = displacement(destPos + length);
	  while(length > 0) {
	   if (srcDispl == 0) {
	    srcDispl = SEGMENT_SIZE;
	    srcSegment--;
	   }
	   if (destDispl == 0) {
	    destDispl = SEGMENT_SIZE;
	    destSegment--;
	   }
	   final int l = (int)Math.min(length, Math.min(srcDispl, destDispl));
	   if (l == 0) throw new ArrayIndexOutOfBoundsException();
	   System.arraycopy(srcArray[srcSegment], srcDispl - l, destArray[destSegment], destDispl - l, l);
	   srcDispl -= l;
	   destDispl -= l;
	   length -= l;
	  }
	 }
	}
	/** Copies a big array from the specified source big array, beginning at the specified position, to the specified position of the destination array.
	 *
	 * @param srcArray the source big array.
	 * @param srcPos the starting position in the source big array.
	 * @param destArray the destination array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static  void copyFromBig(final K[][] srcArray, final long srcPos, final K[] destArray, int destPos, int length) {
	 int srcSegment = segment(srcPos);
	 int srcDispl = displacement(srcPos);
	 while(length > 0) {
	  final int l = Math.min(srcArray[srcSegment].length - srcDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray[srcSegment], srcDispl, destArray, destPos, l);
	  if ((srcDispl += l) == SEGMENT_SIZE) {
	   srcDispl = 0;
	   srcSegment++;
	  }
	  destPos += l;
	  length -= l;
	 }
	}
	/** Copies an array from the specified source array, beginning at the specified position, to the specified position of the destination big array.
	 *
	 * @param srcArray the source array.
	 * @param srcPos the starting position in the source array.
	 * @param destArray the destination big array.
	 * @param destPos the starting position in the destination data.
	 * @param length the number of elements to be copied.
	 */
	public static  void copyToBig(final K[] srcArray, int srcPos, final K[][] destArray, final long destPos, long length) {
	 int destSegment = segment(destPos);
	 int destDispl = displacement(destPos);
	 while(length > 0) {
	  final int l = (int)Math.min(destArray[destSegment].length - destDispl, length);
	  if (l == 0) throw new ArrayIndexOutOfBoundsException();
	  System.arraycopy(srcArray, srcPos, destArray[destSegment], destDispl, l);
	  if ((destDispl += l) == SEGMENT_SIZE) {
	   destDispl = 0;
	   destSegment++;
	  }
	  srcPos += l;
	  length -= l;
	 }
	}
	/** Turns a standard array into a big array.
	 *
	 * 
Note that the returned big array might contain as a segment the original array.
	 *
	 * @param array an array.
	 * @return a new big array with the same length and content of {@code array}.
	 */
	@SuppressWarnings("unchecked")
	public static  K[][] wrap(final K[] array) {
	 if (array.length == 0 && array.getClass() == Object[].class) return (K[][]) ObjectBigArrays.EMPTY_BIG_ARRAY;
	 if (array.length <= SEGMENT_SIZE) {
	  final K[][] bigArray = (K[][])java.lang.reflect.Array.newInstance(array.getClass(), 1);
	  bigArray[0] = array;
	  return bigArray;
	 }
	 final K[][] bigArray = (K[][])ObjectBigArrays.newBigArray(array.getClass(), array.length);
	 for(int i = 0; i < bigArray.length; i++) System.arraycopy(array, (int)start(i), bigArray[i], 0, bigArray[i].length);
	 return bigArray;
	}
	/** Ensures that a big array can contain the given number of entries.
	 *
	 * 
If you cannot foresee whether this big array will need again to be
	 * enlarged, you should probably use {@code grow()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it contains {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code length(array)}
	 * entries are the same as those of {@code array}.
	 */
	public static  K[][] ensureCapacity(final K[][] array, final long length) {
	 return ensureCapacity(array, length, length(array));
	}
	/** Forces a big array to contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
This method returns a new big array of the given length whose element
	 * are of the same class as of those of {@code array}.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	@SuppressWarnings("unchecked")
	public static  K[][] forceCapacity(final K[][] array, final long length, final long preserve) {
	 ensureLength(length);
	 final int valid = array.length - (array.length == 0 || array.length > 0 && array[array.length - 1].length == SEGMENT_SIZE ? 0 : 1);
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final K[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final Class componentType = array.getClass().getComponentType();
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) {
	  for(int i = valid; i < baseLength - 1; i++) base[i] = (K[])java.lang.reflect.Array.newInstance(componentType.getComponentType(), SEGMENT_SIZE);
	  base[baseLength - 1] = (K[])java.lang.reflect.Array.newInstance(componentType.getComponentType(), residual);
	 }
	 else for(int i = valid; i < baseLength; i++) base[i] = (K[])java.lang.reflect.Array.newInstance(componentType.getComponentType(), SEGMENT_SIZE);
	 if (preserve - (valid * (long)SEGMENT_SIZE) > 0) copy(array, valid * (long)SEGMENT_SIZE, base, valid * (long)SEGMENT_SIZE, preserve - (valid * (long)SEGMENT_SIZE));
	 return base;
	}
	/** Ensures that a big array can contain the given number of entries, preserving just a part of the big array.
	 *
	 * 
This method returns a new big array of the given length whose element
	 * are of the same class as of those of {@code array}.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length} entries or more; otherwise,
	 * a big array with {@code length} entries whose first {@code preserve}
	 * entries are the same as those of {@code array}.
	 */
	public static  K[][] ensureCapacity(final K[][] array, final long length, final long preserve) {
	 return length > length(array) ? forceCapacity(array, length, preserve) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code length(array)} entries are the same as those of {@code array}.
	 * */
	public static  K[][] grow(final K[][] array, final long length) {
	 final long oldLength = length(array);
	 return length > oldLength ? grow(array, length, oldLength) : array;
	}
	/** Grows the given big array to the maximum between the given length and
	 * the current length increased by 50%, provided that the given
	 * length is larger than the current length, preserving just a part of the big array.
	 *
	 * 
If you want complete control on the big array growth, you
	 * should probably use {@code ensureCapacity()} instead.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new minimum length for this big array.
	 * @param preserve the number of elements of the big array that must be preserved in case a new allocation is necessary.
	 * @return {@code array}, if it can contain {@code length}
	 * entries; otherwise, a big array with
	 * max({@code length},{@code length(array)}/φ) entries whose first
	 * {@code preserve} entries are the same as those of {@code array}.
	 * */
	public static  K[][] grow(final K[][] array, final long length, final long preserve) {
	 final long oldLength = length(array);
	 return length > oldLength ? ensureCapacity(array, Math.max(oldLength + (oldLength >> 1), length), preserve) : array;
	}
	/** Trims the given big array to the given length.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new maximum length for the big array.
	 * @return {@code array}, if it contains {@code length}
	 * entries or less; otherwise, a big array with
	 * {@code length} entries whose entries are the same as
	 * the first {@code length} entries of {@code array}.
	 *
	 */
	public static  K[][] trim(final K[][] array, final long length) {
	 ensureLength(length);
	 final long oldLength = length(array);
	 if (length >= oldLength) return array;
	 final int baseLength = (int)((length + SEGMENT_MASK) >>> SEGMENT_SHIFT);
	 final K[][] base = java.util.Arrays.copyOf(array, baseLength);
	 final int residual = (int)(length & SEGMENT_MASK);
	 if (residual != 0) base[baseLength - 1] = ObjectArrays.trim(base[baseLength - 1], residual);
	 return base;
	}
	/** Sets the length of the given big array.
	 *
	 * 
Warning: the returned array might use part of the segments of the original
	 * array, which must be considered read-only after calling this method.
	 *
	 * @param array a big array.
	 * @param length the new length for the big array.
	 * @return {@code array}, if it contains exactly {@code length}
	 * entries; otherwise, if it contains more than
	 * {@code length} entries, a big array with {@code length} entries
	 * whose entries are the same as the first {@code length} entries of
	 * {@code array}; otherwise, a big array with {@code length} entries
	 * whose first {@code length(array)} entries are the same as those of
	 * {@code array}.
	 *
	 */
	public static  K[][] setLength(final K[][] array, final long length) {
	 final long oldLength = length(array);
	 if (length == oldLength) return array;
	 if (length < oldLength) return trim(array, length);
	 return ensureCapacity(array, length);
	}
	/** Returns a copy of a portion of a big array.
	 *
	 * @param array a big array.
	 * @param offset the first element to copy.
	 * @param length the number of elements to copy.
	 * @return a new big array containing {@code length} elements of {@code array} starting at {@code offset}.
	 */
	public static  K[][] copy(final K[][] array, final long offset, final long length) {
	 ensureOffsetLength(array, offset, length);
	 final K[][] a =
	  ObjectBigArrays.newBigArray(array, length);
	 copy(array, offset, a, 0, length);
	 return a;
	}
	/** Returns a copy of a big array.
	 *
	 * @param array a big array.
	 * @return a copy of {@code array}.
	 */
	public static  K[][] copy(final K[][] array) {
	 final K[][] base = array.clone();
	 for(int i = base.length; i-- != 0;) base[i] = array[i].clone();
	 return base;
	}
	/** Fills the given big array with the given value.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param value the new value for all elements of the big array.
	 */
	public static  void fill(final K[][] array, final K value) {
	 for(int i = array.length; i-- != 0;) java.util.Arrays.fill(array[i], value);
	}
	/** Fills a portion of the given big array with the given value.
	 *
	 * 
If possible (i.e., {@code from} is 0) this method uses a
	 * backward loop. In this case, it is significantly faster than the
	 * corresponding method in {@link java.util.Arrays}.
	 *
	 * @param array a big array.
	 * @param from the starting index of the portion to fill.
	 * @param to the end index of the portion to fill.
	 * @param value the new value for all elements of the specified portion of the big array.
	 */
	public static  void fill(final K[][] array, final long from, long to, final K value) {
	 final long length = length(array);
	 BigArrays.ensureFromTo(length, from, to);
	 if (length == 0) return; // To avoid addressing array[0]
	 int fromSegment = segment(from);
	 int toSegment = segment(to);
	 int fromDispl = displacement(from);
	 int toDispl = displacement(to);
	 if (fromSegment == toSegment) {
	  java.util.Arrays.fill(array[fromSegment], fromDispl, toDispl, value);
	  return;
	 }
	 if (toDispl != 0) java.util.Arrays.fill(array[toSegment], 0, toDispl, value);
	 while(--toSegment > fromSegment) java.util.Arrays.fill(array[toSegment], value);
	 java.util.Arrays.fill(array[fromSegment], fromDispl, SEGMENT_SIZE, value);
	}
	/** Returns true if the two big arrays are elementwise equal.
	 *
	 * 
This method uses a backward loop. It is significantly faster than the corresponding
	 * method in {@link java.util.Arrays}.
	 *
	 * @param a1 a big array.
	 * @param a2 another big array.
	 * @return true if the two big arrays are of the same length, and their elements are equal.
	 */
	public static  boolean equals(final K[][] a1, final K a2[][]) {
	 if (length(a1) != length(a2)) return false;
	 int i = a1.length, j;
	 K[] t, u;
	 while(i-- != 0) {
	  t = a1[i];
	  u = a2[i];
	  j = t.length;
	  while(j-- != 0) if (! java.util.Objects.equals(t[j], u[j])) return false;
	 }
	 return true;
	}
	/* Returns a string representation of the contents of the specified big array.
	 *
	 * The string representation consists of a list of the big array's elements, enclosed in square brackets ("[]"). Adjacent elements are separated by the characters ", " (a comma followed by a space). Returns "null" if {@code a} is null.
	 * @param a the big array whose string representation to return.
	 * @return the string representation of {@code a}.
	 */
	public static  String toString(final K[][] a) {
	 if (a == null) return "null";
	 final long last = length(a) - 1;
	 if (last == - 1) return "[]";
	 final StringBuilder b = new StringBuilder();
	 b.append('[');
	 for (long i = 0; ; i++) {
	  b.append(String.valueOf(get(a, i)));
	  if (i == last) return b.append(']').toString();
	  b.append(", ");
	 }
	}
	/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits a big array.
	 *
	 * 
This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param from a start index (inclusive).
	 * @param to an end index (inclusive).
	 * @throws IllegalArgumentException if {@code from} is greater than {@code to}.
	 * @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the big array length or negative.
	 */
	public static  void ensureFromTo(final K[][] a, final long from, final long to) {
	 BigArrays.ensureFromTo(length(a), from, to);
	}
	/** Ensures that a range given by an offset and a length fits a big array.
	 *
	 * This method may be used whenever a big array range check is needed.
	 *
	 * @param a a big array.
	 * @param offset a start index.
	 * @param length a length (the number of elements in the range).
	 * @throws IllegalArgumentException if {@code length} is negative.
	 * @throws ArrayIndexOutOfBoundsException if {@code offset} is negative or {@code offset}+{@code length} is greater than the big array length.
	 */
	public static  void ensureOffsetLength(final K[][] a, final long offset, final long length) {
	 BigArrays.ensureOffsetLength(length(a), offset, length);
	}
	/** Ensures that two big arrays are of the same length.
	 *
	 * @param a a big array.
	 * @param b another big array.
	 * @throws IllegalArgumentException if the two argument arrays are not of the same length.
	 */
	public static  void ensureSameLength(final K[][] a, final K[][] b) {
	 if (length(a) != length(b)) throw new IllegalArgumentException("Array size mismatch: " + length(a) + " != " + length(b));
	}
	/** Shuffles the specified big array fragment using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param from the index of the first element (inclusive) to be shuffled.
	 * @param to the index of the last element (exclusive) to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static  K[][] shuffle(final K[][] a, final long from, final long to, final Random random) {
	 for(long i = to - from; i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final K t = BigArrays.get(a, from + i);
	  BigArrays.set(a, from + i, BigArrays.get(a, from + p));
	  BigArrays.set(a, from + p, t);
	 }
	 return a;
	}
	/** Shuffles the specified big array using the specified pseudorandom number generator.
	 *
	 * @param a the big array to be shuffled.
	 * @param random a pseudorandom number generator.
	 * @return {@code a}.
	 */
	public static  K[][] shuffle(final K[][] a, final Random random) {
	 for(long i = length(a); i-- != 0;) {
	  final long p = (random.nextLong() & 0x7FFFFFFFFFFFFFFFL) % (i + 1);
	  final K t = BigArrays.get(a, i);
	  BigArrays.set(a, i, BigArrays.get(a, p));
	  BigArrays.set(a, p, t);
	 }
	 return a;
	}

	public static void main(final String arg[]) {
	 int[][] a = IntBigArrays.newBigArray(1L << Integer.parseInt(arg[0]));
	 long x, y, z, start;
	 for (int k = 10; k-- != 0;) {
	  start = -System.currentTimeMillis();
	  x = 0;
	  for (long i = length(a); i-- != 0;)
	   x ^= i ^ get(a, i);
	  if (x == 0) System.err.println();
	  System.out.println("Single loop: " + (start + System.currentTimeMillis()) + "ms");
	  start = -System.currentTimeMillis();
	  y = 0;
	  for (int i = a.length; i-- != 0;) {
	   final int[] t = a[i];
	   for (int d = t.length; d-- != 0;)
	    y ^= t[d] ^ index(i, d);
	  }
	  if (y == 0) System.err.println();
	  if (x != y) throw new AssertionError();
	  System.out.println("Double loop: " + (start + System.currentTimeMillis()) + "ms");
	  z = 0;
	  long j = length(a);
	  for (int i = a.length; i-- != 0;) {
	   final int[] t = a[i];
	   for (int d = t.length; d-- != 0;)
	    y ^= t[d] ^ --j;
	  }
	  if (z == 0) System.err.println();
	  if (x != z) throw new AssertionError();
	  System.out.println("Double loop (with additional index): " + (start + System.currentTimeMillis()) + "ms");
	 }
	}
}