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/*
* Copyright (C) 2002-2022 Sebastiano Vigna
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*
*
* For the sorting and binary search 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.floats;
import it.unimi.dsi.fastutil.Arrays;
import it.unimi.dsi.fastutil.Hash;
import java.util.Random;
import java.util.concurrent.ForkJoinPool;
import java.util.concurrent.ForkJoinTask;
import java.util.concurrent.RecursiveAction;
import it.unimi.dsi.fastutil.ints.IntArrays;
import java.util.concurrent.ExecutorCompletionService;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.atomic.AtomicInteger;
/** A class providing static methods and objects that do useful things with type-specific arrays.
*
* In particular, the {@code forceCapacity()}, {@code ensureCapacity()}, {@code grow()},
* {@code trim()} and {@code setLength()} methods allow to handle
* arrays much like array lists. This can be very useful when efficiency (or
* syntactic simplicity) reasons make array lists unsuitable.
*
*
Note that {@link it.unimi.dsi.fastutil.io.BinIO} and {@link it.unimi.dsi.fastutil.io.TextIO}
* contain several methods make it possible to load and save arrays of primitive types as sequences
* of elements in {@link java.io.DataInput} format (i.e., not as objects) or as sequences of lines of text.
*
*
Sorting
*
* There are several sorting methods available. The main theme is that of letting you choose
* the sorting algorithm you prefer (i.e., trading stability of mergesort for no memory allocation in quicksort).
*
*
Parallel operations
* Some algorithms provide a parallel version that will by default use the
* {@linkplain ForkJoinPool#commonPool() common pool}, but this can be overridden by calling the
* function in a task already in the {@link ForkJoinPool} that the operation should run in. For example,
* something along the lines of "{@code poolToParallelSortIn.invoke(() -> parallelQuickSort(arrayToSort))}"
* will run the parallel sort in {@code poolToParallelSortIn} instead of the default pool.
*
* Some algorithms also provide an explicit indirect sorting facility, which makes it possible
* to sort an array using the values in another array as comparator.
*
* However, if you wish to let the implementation choose an algorithm for you, both
* {@link #stableSort} and {@link #unstableSort} methods are available, which dynamically
* chooses an algorithm based on unspecified criteria (but most likely stability, array size, and array element type).
*
*
All comparison-based algorithm have an implementation based on a type-specific comparator.
*
*
As a general rule, sequential radix sort is significantly faster than quicksort or mergesort, in particular
* on random-looking data. In
* the parallel case, up to a few cores parallel radix sort is still the fastest, but at some point quicksort
* exploits parallelism better.
*
*
If you are fine with not knowing exactly which algorithm will be run (in particular, not knowing exactly whether a support array will be allocated),
* the dual-pivot parallel sorts in {@link java.util.Arrays}
* are about 50% faster than the classical single-pivot implementation used here.
*
*
In any case, if sorting time is important I suggest that you benchmark your sorting load
* with your data distribution and on your architecture.
*
* @see java.util.Arrays
*/
public final class FloatArrays {
private FloatArrays() {}
/** A static, final, empty array. */
public static final float[] EMPTY_ARRAY = {};
/** A static, final, empty array to be used as default array in allocations. An
* object distinct from {@link #EMPTY_ARRAY} makes it possible to have different
* behaviors depending on whether the user required an empty allocation, or we are
* just lazily delaying allocation.
*
* @see java.util.ArrayList
*/
public static final float[] DEFAULT_EMPTY_ARRAY = {};
/** Forces an array to contain the given number of entries, preserving just a part of the array.
*
* @param array an array.
* @param length the new minimum length for this array.
* @param preserve the number of elements of the array that must be preserved in case a new allocation is necessary.
* @return an 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 int length, final int preserve) {
final float t[] =
new float[length];
System.arraycopy(array, 0, t, 0, preserve);
return t;
}
/** Ensures that an array can contain the given number of entries.
*
*
If you cannot foresee whether this array will need again to be
* enlarged, you should probably use {@code grow()} instead.
*
* @param array an array.
* @param length the new minimum length for this array.
* @return {@code array}, if it contains {@code length} entries or more; otherwise,
* an array with {@code length} entries whose first {@code array.length}
* entries are the same as those of {@code array}.
*/
public static float[] ensureCapacity(final float[] array, final int length) {
return ensureCapacity(array, length, array.length);
}
/** Ensures that an array can contain the given number of entries, preserving just a part of the array.
*
* @param array an array.
* @param length the new minimum length for this array.
* @param preserve the number of elements of the 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,
* an 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 int length, final int preserve) {
return length > array.length ? forceCapacity(array, length, preserve) : array;
}
/** Grows the given 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 array growth, you
* should probably use {@code ensureCapacity()} instead.
*
* @param array an array.
* @param length the new minimum length for this array.
* @return {@code array}, if it can contain {@code length}
* entries; otherwise, an array with
* max({@code length},{@code array.length}/φ) entries whose first
* {@code array.length} entries are the same as those of {@code array}.
* */
public static float[] grow(final float[] array, final int length) {
return grow(array, length, array.length);
}
/** Grows the given 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 array.
*
*
If you want complete control on the array growth, you
* should probably use {@code ensureCapacity()} instead.
*
* @param array an array.
* @param length the new minimum length for this array.
* @param preserve the number of elements of the array that must be preserved in case a new allocation is necessary.
* @return {@code array}, if it can contain {@code length}
* entries; otherwise, an array with
* max({@code length},{@code array.length}/φ) entries whose first
* {@code preserve} entries are the same as those of {@code array}.
* */
public static float[] grow(final float[] array, final int length, final int preserve) {
if (length > array.length) {
final int newLength = (int)Math.max(Math.min((long)array.length + (array.length >> 1), Arrays.MAX_ARRAY_SIZE), length);
final float t[] =
new float[newLength];
System.arraycopy(array, 0, t, 0, preserve);
return t;
}
return array;
}
/** Trims the given array to the given length.
*
* @param array an array.
* @param length the new maximum length for the array.
* @return {@code array}, if it contains {@code length}
* entries or less; otherwise, an 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 int length) {
if (length >= array.length) return array;
final float t[] =
length == 0 ? EMPTY_ARRAY : new float[length];
System.arraycopy(array, 0, t, 0, length);
return t;
}
/** Sets the length of the given array.
*
* @param array an array.
* @param length the new length for the array.
* @return {@code array}, if it contains exactly {@code length}
* entries; otherwise, if it contains more than
* {@code length} entries, an array with {@code length} entries
* whose entries are the same as the first {@code length} entries of
* {@code array}; otherwise, an array with {@code length} entries
* whose first {@code array.length} entries are the same as those of
* {@code array}.
*
*/
public static float[] setLength(final float[] array, final int length) {
if (length == array.length) return array;
if (length < array.length) return trim(array, length);
return ensureCapacity(array, length);
}
/** Returns a copy of a portion of an array.
*
* @param array an array.
* @param offset the first element to copy.
* @param length the number of elements to copy.
* @return a new array containing {@code length} elements of {@code array} starting at {@code offset}.
*/
public static float[] copy(final float[] array, final int offset, final int length) {
ensureOffsetLength(array, offset, length);
final float[] a =
length == 0 ? EMPTY_ARRAY : new float[length];
System.arraycopy(array, offset, a, 0, length);
return a;
}
/** Returns a copy of an array.
*
* @param array an array.
* @return a copy of {@code array}.
*/
public static float[] copy(final float[] array) {
return array.clone();
}
/** Fills the given array with the given value.
*
* @param array an array.
* @param value the new value for all elements of the array.
* @deprecated Please use the corresponding {@link java.util.Arrays} method.
*/
@Deprecated
public static void fill(final float[] array, final float value) {
int i = array.length;
while(i-- != 0) array[i] = value;
}
/** Fills a portion of the given array with the given value.
*
* @param array an array.
* @param from the starting index of the portion to fill (inclusive).
* @param to the end index of the portion to fill (exclusive).
* @param value the new value for all elements of the specified portion of the array.
* @deprecated Please use the corresponding {@link java.util.Arrays} method.
*/
@Deprecated
public static void fill(final float[] array, final int from, int to, final float value) {
ensureFromTo(array, from, to);
if (from == 0) while(to-- != 0) array[to] = value;
else for(int i = from; i < to; i++) array[i] = value;
}
/** Returns true if the two arrays are elementwise equal.
*
* @param a1 an array.
* @param a2 another array.
* @return true if the two arrays are of the same length, and their elements are equal.
* @deprecated Please use the corresponding {@link java.util.Arrays} method, which is intrinsified in recent JVMs.
*/
@Deprecated
public static boolean equals(final float[] a1, final float a2[]) {
int i = a1.length;
if (i != a2.length) return false;
while(i-- != 0) if (! ( Float.floatToIntBits(a1[i]) == Float.floatToIntBits(a2[i]) )) return false;
return true;
}
/** Ensures that a range given by its first (inclusive) and last (exclusive) elements fits an array.
*
*
This method may be used whenever an array range check is needed.
*
*
In Java 9 and up, this method should be considered deprecated in favor of the
* {@link java.util.Objects#checkFromToIndex(int, int, int)} method, which may be intrinsified in recent JVMs.
*
* @param a an array.
* @param from a start index (inclusive).
* @param to an end index (exclusive).
* @throws IllegalArgumentException if {@code from} is greater than {@code to}.
* @throws ArrayIndexOutOfBoundsException if {@code from} or {@code to} are greater than the array length or negative.
*/
public static void ensureFromTo(final float[] a, final int from, final int to) {
Arrays.ensureFromTo(a.length, from, to);
}
/** Ensures that a range given by an offset and a length fits an array.
*
*
This method may be used whenever an array range check is needed.
*
*
In Java 9 and up, this method should be considered deprecated in favor of the
* {@link java.util.Objects#checkFromIndexSize(int, int, int)} method, which may be intrinsified in recent JVMs.
*
* @param a an 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 array length.
*/
public static void ensureOffsetLength(final float[] a, final int offset, final int length) {
Arrays.ensureOffsetLength(a.length, offset, length);
}
/** Ensures that two arrays are of the same length.
*
* @param a an array.
* @param b another 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 (a.length != b.length) throw new IllegalArgumentException("Array size mismatch: " + a.length + " != " + b.length);
}
private static final int QUICKSORT_NO_REC = 16;
private static final int PARALLEL_QUICKSORT_NO_FORK = 8192;
private static final int QUICKSORT_MEDIAN_OF_9 = 128;
private static final int MERGESORT_NO_REC = 16;
private static ForkJoinPool getPool() {
// Make sure to update Arrays.drv, BigArrays.drv, and src/it/unimi/dsi/fastutil/Arrays.java as well
ForkJoinPool current = ForkJoinTask.getPool();
return current == null ? ForkJoinPool.commonPool() : current;
}
/** Swaps two elements of an anrray.
*
* @param x an array.
* @param a a position in {@code x}.
* @param b another position in {@code x}.
*/
public static void swap(final float x[], final int a, final int b) {
final float t = x[a];
x[a] = x[b];
x[b] = t;
}
/** Swaps two sequences of elements of an array.
*
* @param x an array.
* @param a a position in {@code x}.
* @param b another position in {@code x}.
* @param n the number of elements to exchange starting at {@code a} and {@code b}.
*/
public static void swap(final float[] x, int a, int b, final int n) {
for(int i = 0; i < n; i++, a++, b++) swap(x, a, b);
}
private static int med3(final float x[], final int a, final int b, final int c, FloatComparator comp) {
final int ab = comp.compare(x[a], x[b]);
final int ac = comp.compare(x[a], x[c]);
final int bc = comp.compare(x[b], x[c]);
return (ab < 0 ?
(bc < 0 ? b : ac < 0 ? c : a) :
(bc > 0 ? b : ac > 0 ? c : a));
}
private static void selectionSort(final float[] a, final int from, final int to, final FloatComparator comp) {
for(int i = from; i < to - 1; i++) {
int m = i;
for(int j = i + 1; j < to; j++) if (comp.compare(a[j], a[m]) < 0) m = j;
if (m != i) {
final float u = a[i];
a[i] = a[m];
a[m] = u;
}
}
}
private static void insertionSort(final float[] a, final int from, final int to, final FloatComparator comp) {
for (int i = from; ++i < to;) {
float t = a[i];
int j = i;
for (float u = a[j - 1]; comp.compare(t, u) < 0; u = a[--j - 1]) {
a[j] = u;
if (from == j - 1) {
--j;
break;
}
}
a[j] = t;
}
}
/** Sorts the specified range of elements 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.
*
*
Note that this implementation does not allocate any object, contrarily to the implementation
* used to sort primitive types in {@link java.util.Arrays}, which switches to mergesort on large inputs.
*
* @param x the array to be sorted.
* @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 sorting order.
*
*/
public static void quickSort(final float[] x, final int from, final int to, final FloatComparator comp) {
final int len = to - from;
// Selection sort on smallest arrays
if (len < QUICKSORT_NO_REC) {
selectionSort(x, from, to, comp);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
if (len > QUICKSORT_MEDIAN_OF_9) { // Big arrays, pseudomedian of 9
int s = len / 8;
l = med3(x, l, l + s, l + 2 * s, comp);
m = med3(x, m - s, m, m + s, comp);
n = med3(x, n - 2 * s, n - s, n, comp);
}
m = med3(x, l, m, n, comp); // Mid-size, med of 3
final float v = x[m];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while(true) {
int comparison;
while (b <= c && (comparison = comp.compare(x[b], v)) <= 0) {
if (comparison == 0) swap(x, a++, b);
b++;
}
while (c >= b && (comparison = comp.compare(x[c], v)) >=0) {
if (comparison == 0) swap(x, c, d--);
c--;
}
if (b > c) break;
swap(x, b++, c--);
}
// Swap partition elements back to middle
int s;
s = Math.min(a - from, b - a);
swap(x, from, b - s, s);
s = Math.min(d - c, to - d - 1);
swap(x, b, to - s, s);
// Recursively sort non-partition-elements
if ((s = b - a) > 1) quickSort(x, from, from + s, comp);
if ((s = d - c) > 1) quickSort(x, to - s, to, comp);
}
/** Sorts an array 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.
*
*
Note that this implementation does not allocate any object, contrarily to the implementation
* used to sort primitive types in {@link java.util.Arrays}, which switches to mergesort on large inputs.
*
* @param x the array to be sorted.
* @param comp the comparator to determine the sorting order.
*
*/
public static void quickSort(final float[] x, final FloatComparator comp) {
quickSort(x, 0, x.length, comp);
}
protected static class ForkJoinQuickSortComp extends RecursiveAction {
private static final long serialVersionUID = 1L;
private final int from;
private final int to;
private final float[] x;
private final FloatComparator comp;
public ForkJoinQuickSortComp(final float[] x , final int from , final int to, final FloatComparator comp) {
this.from = from;
this.to = to;
this.x = x;
this.comp = comp;
}
@Override
protected void compute() {
final float[] x = this.x;
final int len = to - from;
if (len < PARALLEL_QUICKSORT_NO_FORK) {
quickSort(x, from, to, comp);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
int s = len / 8;
l = med3(x, l, l + s, l + 2 * s, comp);
m = med3(x, m - s, m, m + s, comp);
n = med3(x, n - 2 * s, n - s, n, comp);
m = med3(x, l, m, n, comp);
final float v = x[m];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while (true) {
int comparison;
while (b <= c && (comparison = comp.compare(x[b], v)) <= 0) {
if (comparison == 0) swap(x, a++, b);
b++;
}
while (c >= b && (comparison = comp.compare(x[c], v)) >= 0) {
if (comparison == 0) swap(x, c, d--);
c--;
}
if (b > c) break;
swap(x, b++, c--);
}
// Swap partition elements back to middle
int t;
s = Math.min(a - from, b - a);
swap(x, from, b - s, s);
s = Math.min(d - c, to - d - 1);
swap(x, b, to - s, s);
// Recursively sort non-partition-elements
s = b - a;
t = d - c;
if (s > 1 && t > 1) invokeAll(new ForkJoinQuickSortComp (x, from, from + s, comp), new ForkJoinQuickSortComp (x, to - t, to, comp));
else if (s > 1) invokeAll(new ForkJoinQuickSortComp (x, from, from + s, comp));
else invokeAll(new ForkJoinQuickSortComp (x, to - t, to, comp));
}
}
/** Sorts the specified range of elements according to the order induced by the specified
* comparator using a parallel 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 x the array to be sorted.
* @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 sorting order.
*/
public static void parallelQuickSort(final float[] x, final int from, final int to, final FloatComparator comp) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_QUICKSORT_NO_FORK || pool.getParallelism() == 1) quickSort(x, from, to, comp);
else {
pool.invoke(new ForkJoinQuickSortComp (x, from, to, comp));
}
}
/** Sorts an array according to the order induced by the specified
* comparator using a parallel 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 x the array to be sorted.
* @param comp the comparator to determine the sorting order.
*/
public static void parallelQuickSort(final float[] x, final FloatComparator comp) {
parallelQuickSort(x, 0, x.length, comp);
}
private static int med3(final float x[], final int a, final int b, final int c) {
final int ab = ( Float.compare((x[a]),(x[b])) );
final int ac = ( Float.compare((x[a]),(x[c])) );
final int bc = ( Float.compare((x[b]),(x[c])) );
return (ab < 0 ?
(bc < 0 ? b : ac < 0 ? c : a) :
(bc > 0 ? b : ac > 0 ? c : a));
}
private static void selectionSort(final float[] a, final int from, final int to) {
for(int i = from; i < to - 1; i++) {
int m = i;
for(int j = i + 1; j < to; j++) if (( Float.compare((a[j]),(a[m])) < 0 )) m = j;
if (m != i) {
final float u = a[i];
a[i] = a[m];
a[m] = u;
}
}
}
private static void insertionSort(final float[] a, final int from, final int to) {
for (int i = from; ++i < to;) {
float t = a[i];
int j = i;
for (float u = a[j - 1]; ( Float.compare((t),(u)) < 0 ); u = a[--j - 1]) {
a[j] = u;
if (from == j - 1) {
--j;
break;
}
}
a[j] = t;
}
}
/** Sorts the specified range of elements according to the natural ascending order 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.
*
*
Note that this implementation does not allocate any object, contrarily to the implementation
* used to sort primitive types in {@link java.util.Arrays}, which switches to mergesort on large inputs.
*
* @param x the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void quickSort(final float[] x, final int from, final int to) {
final int len = to - from;
// Selection sort on smallest arrays
if (len < QUICKSORT_NO_REC) {
selectionSort(x, from, to);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
if (len > QUICKSORT_MEDIAN_OF_9) { // Big arrays, pseudomedian of 9
int s = len / 8;
l = med3(x, l, l + s, l + 2 * s);
m = med3(x, m - s, m, m + s);
n = med3(x, n - 2 * s, n - s, n);
}
m = med3(x, l, m, n); // Mid-size, med of 3
final float v = x[m];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while(true) {
int comparison;
while (b <= c && (comparison = ( Float.compare((x[b]),(v)) )) <= 0) {
if (comparison == 0) swap(x, a++, b);
b++;
}
while (c >= b && (comparison = ( Float.compare((x[c]),(v)) )) >=0) {
if (comparison == 0) swap(x, c, d--);
c--;
}
if (b > c) break;
swap(x, b++, c--);
}
// Swap partition elements back to middle
int s;
s = Math.min(a - from, b - a);
swap(x, from, b - s, s);
s = Math.min(d - c, to - d - 1);
swap(x, b, to - s, s);
// Recursively sort non-partition-elements
if ((s = b - a) > 1) quickSort(x, from, from + s);
if ((s = d - c) > 1) quickSort(x, to - s, to);
}
/** Sorts an array according to the natural ascending order 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.
*
*
Note that this implementation does not allocate any object, contrarily to the implementation
* used to sort primitive types in {@link java.util.Arrays}, which switches to mergesort on large inputs.
*
* @param x the array to be sorted.
*
*/
public static void quickSort(final float[] x) {
quickSort(x, 0, x.length);
}
protected static class ForkJoinQuickSort extends RecursiveAction {
private static final long serialVersionUID = 1L;
private final int from;
private final int to;
private final float[] x;
public ForkJoinQuickSort(final float[] x , final int from , final int to) {
this.from = from;
this.to = to;
this.x = x;
}
@Override
protected void compute() {
final float[] x = this.x;
final int len = to - from;
if (len < PARALLEL_QUICKSORT_NO_FORK) {
quickSort(x, from, to);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
int s = len / 8;
l = med3(x, l, l + s, l + 2 * s);
m = med3(x, m - s, m, m + s);
n = med3(x, n - 2 * s, n - s, n);
m = med3(x, l, m, n);
final float v = x[m];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while (true) {
int comparison;
while (b <= c && (comparison = ( Float.compare((x[b]),(v)) )) <= 0) {
if (comparison == 0) swap(x, a++, b);
b++;
}
while (c >= b && (comparison = ( Float.compare((x[c]),(v)) )) >= 0) {
if (comparison == 0) swap(x, c, d--);
c--;
}
if (b > c) break;
swap(x, b++, c--);
}
// Swap partition elements back to middle
int t;
s = Math.min(a - from, b - a);
swap(x, from, b - s, s);
s = Math.min(d - c, to - d - 1);
swap(x, b, to - s, s);
// Recursively sort non-partition-elements
s = b - a;
t = d - c;
if (s > 1 && t > 1) invokeAll(new ForkJoinQuickSort (x, from, from + s), new ForkJoinQuickSort (x, to - t, to));
else if (s > 1) invokeAll(new ForkJoinQuickSort (x, from, from + s));
else invokeAll(new ForkJoinQuickSort (x, to - t, to));
}
}
/** Sorts the specified range of elements according to the natural ascending order using a parallel 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 x the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void parallelQuickSort(final float[] x, final int from, final int to) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_QUICKSORT_NO_FORK || pool.getParallelism() == 1) quickSort(x, from, to);
else {
pool.invoke(new ForkJoinQuickSort (x, from, to));
}
}
/** Sorts an array according to the natural ascending order using a parallel 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 x the array to be sorted.
*
*/
public static void parallelQuickSort(final float[] x) {
parallelQuickSort(x, 0, x.length);
}
private static int med3Indirect(final int perm[], final float x[], final int a, final int b, final int c) {
final float aa = x[perm[a]];
final float bb = x[perm[b]];
final float cc = x[perm[c]];
final int ab = ( Float.compare((aa),(bb)) );
final int ac = ( Float.compare((aa),(cc)) );
final int bc = ( Float.compare((bb),(cc)) );
return (ab < 0 ?
(bc < 0 ? b : ac < 0 ? c : a) :
(bc > 0 ? b : ac > 0 ? c : a));
}
private static void insertionSortIndirect(final int[] perm, final float[] a, final int from, final int to) {
for (int i = from; ++i < to;) {
int t = perm[i];
int j = i;
for (int u = perm[j - 1]; ( Float.compare((a[t]),(a[u])) < 0 ); u = perm[--j - 1]) {
perm[j] = u;
if (from == j - 1) {
--j;
break;
}
}
perm[j] = t;
}
}
/** Sorts the specified range of elements according to the natural ascending order using indirect 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.
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code x[perm[i]] ≤ x[perm[i + 1]]}.
*
*
Note that this implementation does not allocate any object, contrarily to the implementation
* used to sort primitive types in {@link java.util.Arrays}, which switches to mergesort on large inputs.
*
* @param perm a permutation array indexing {@code x}.
* @param x the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void quickSortIndirect(final int[] perm, final float[] x, final int from, final int to) {
final int len = to - from;
// Selection sort on smallest arrays
if (len < QUICKSORT_NO_REC) {
insertionSortIndirect(perm, x, from, to);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
if (len > QUICKSORT_MEDIAN_OF_9) { // Big arrays, pseudomedian of 9
int s = len / 8;
l = med3Indirect(perm, x, l, l + s, l + 2 * s);
m = med3Indirect(perm, x, m - s, m, m + s);
n = med3Indirect(perm, x, n - 2 * s, n - s, n);
}
m = med3Indirect(perm, x, l, m, n); // Mid-size, med of 3
final float v = x[perm[m]];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while(true) {
int comparison;
while (b <= c && (comparison = ( Float.compare((x[perm[b]]),(v)) )) <= 0) {
if (comparison == 0) IntArrays.swap(perm, a++, b);
b++;
}
while (c >= b && (comparison = ( Float.compare((x[perm[c]]),(v)) )) >=0) {
if (comparison == 0) IntArrays.swap(perm, c, d--);
c--;
}
if (b > c) break;
IntArrays.swap(perm, b++, c--);
}
// Swap partition elements back to middle
int s;
s = Math.min(a - from, b - a);
IntArrays.swap(perm, from, b - s, s);
s = Math.min(d - c, to - d - 1);
IntArrays.swap(perm, b, to - s, s);
// Recursively sort non-partition-elements
if ((s = b - a) > 1) quickSortIndirect(perm, x, from, from + s);
if ((s = d - c) > 1) quickSortIndirect(perm, x, to - s, to);
}
/** Sorts an array according to the natural ascending order using indirect 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.
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code x[perm[i]] ≤ x[perm[i + 1]]}.
*
*
Note that this implementation does not allocate any object, contrarily to the implementation
* used to sort primitive types in {@link java.util.Arrays}, which switches to mergesort on large inputs.
*
* @param perm a permutation array indexing {@code x}.
* @param x the array to be sorted.
*/
public static void quickSortIndirect(final int perm[], final float[] x) {
quickSortIndirect(perm, x, 0, x.length);
}
protected static class ForkJoinQuickSortIndirect extends RecursiveAction {
private static final long serialVersionUID = 1L;
private final int from;
private final int to;
private final int[] perm;
private final float[] x;
public ForkJoinQuickSortIndirect(final int perm[], final float[] x , final int from , final int to) {
this.from = from;
this.to = to;
this.x = x;
this.perm = perm;
}
@Override
protected void compute() {
final float[] x = this.x;
final int len = to - from;
if (len < PARALLEL_QUICKSORT_NO_FORK) {
quickSortIndirect(perm, x, from, to);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
int s = len / 8;
l = med3Indirect(perm, x, l, l + s, l + 2 * s);
m = med3Indirect(perm, x, m - s, m, m + s);
n = med3Indirect(perm, x, n - 2 * s, n - s, n);
m = med3Indirect(perm, x, l, m, n);
final float v = x[perm[m]];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while (true) {
int comparison;
while (b <= c && (comparison = ( Float.compare((x[perm[b]]),(v)) )) <= 0) {
if (comparison == 0) IntArrays.swap(perm, a++, b);
b++;
}
while (c >= b && (comparison = ( Float.compare((x[perm[c]]),(v)) )) >= 0) {
if (comparison == 0) IntArrays.swap(perm, c, d--);
c--;
}
if (b > c) break;
IntArrays.swap(perm, b++, c--);
}
// Swap partition elements back to middle
int t;
s = Math.min(a - from, b - a);
IntArrays.swap(perm, from, b - s, s);
s = Math.min(d - c, to - d - 1);
IntArrays.swap(perm, b, to - s, s);
// Recursively sort non-partition-elements
s = b - a;
t = d - c;
if (s > 1 && t > 1) invokeAll(new ForkJoinQuickSortIndirect (perm, x, from, from + s), new ForkJoinQuickSortIndirect (perm, x, to - t, to));
else if (s > 1) invokeAll(new ForkJoinQuickSortIndirect (perm, x, from, from + s));
else invokeAll(new ForkJoinQuickSortIndirect (perm, x, to - t, to));
}
}
/** Sorts the specified range of elements according to the natural ascending order using a parallel indirect 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.
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code x[perm[i]] ≤ x[perm[i + 1]]}.
*
* @param perm a permutation array indexing {@code x}.
* @param x the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void parallelQuickSortIndirect(final int[] perm, final float[] x, final int from, final int to) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_QUICKSORT_NO_FORK || pool.getParallelism() == 1) quickSortIndirect(perm, x, from, to);
else {
pool.invoke(new ForkJoinQuickSortIndirect (perm, x, from, to));
}
}
/** Sorts an array according to the natural ascending order using a parallel indirect 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.
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code x[perm[i]] ≤ x[perm[i + 1]]}.
*
* @param perm a permutation array indexing {@code x}.
* @param x the array to be sorted.
*
*/
public static void parallelQuickSortIndirect(final int perm[], final float[] x) {
parallelQuickSortIndirect(perm, x, 0, x.length);
}
/** Stabilizes a permutation.
*
*
This method can be used to stabilize the permutation generated by an indirect sorting, assuming that
* initially the permutation array was in ascending order (e.g., the identity, as usually happens). This method
* scans the permutation, and for each non-singleton block of elements with the same associated values in {@code x},
* permutes them in ascending order. The resulting permutation corresponds to a stable sort.
*
*
Usually combining an unstable indirect sort and this method is more efficient than using a stable sort,
* as most stable sort algorithms require a support array.
*
*
More precisely, assuming that {@code x[perm[i]] ≤ x[perm[i + 1]]}, after
* stabilization we will also have that {@code x[perm[i]] = x[perm[i + 1]]} implies
* {@code perm[i] ≤ perm[i + 1]}.
*
* @param perm a permutation array indexing {@code x} so that it is sorted.
* @param x the sorted array to be stabilized.
* @param from the index of the first element (inclusive) to be stabilized.
* @param to the index of the last element (exclusive) to be stabilized.
*/
public static void stabilize(final int perm[], final float[] x, final int from, final int to) {
int curr = from;
for(int i = from + 1; i < to; i++) {
if (x[perm[i]] != x[perm[curr]]) {
if (i - curr > 1) IntArrays.parallelQuickSort(perm, curr, i);
curr = i;
}
}
if (to - curr > 1) IntArrays.parallelQuickSort(perm, curr, to);
}
/** Stabilizes a permutation.
*
*
This method can be used to stabilize the permutation generated by an indirect sorting, assuming that
* initially the permutation array was in ascending order (e.g., the identity, as usually happens). This method
* scans the permutation, and for each non-singleton block of elements with the same associated values in {@code x},
* permutes them in ascending order. The resulting permutation corresponds to a stable sort.
*
*
Usually combining an unstable indirect sort and this method is more efficient than using a stable sort,
* as most stable sort algorithms require a support array.
*
*
More precisely, assuming that {@code x[perm[i]] ≤ x[perm[i + 1]]}, after
* stabilization we will also have that {@code x[perm[i]] = x[perm[i + 1]]} implies
* {@code perm[i] ≤ perm[i + 1]}.
*
* @param perm a permutation array indexing {@code x} so that it is sorted.
* @param x the sorted array to be stabilized.
*/
public static void stabilize(final int perm[], final float[] x) {
stabilize(perm, x, 0, perm.length);
}
private static int med3(final float x[], final float[] y, final int a, final int b, final int c) {
int t;
final int ab = (t = ( Float.compare((x[a]),(x[b])) )) == 0 ? ( Float.compare((y[a]),(y[b])) ) : t;
final int ac = (t = ( Float.compare((x[a]),(x[c])) )) == 0 ? ( Float.compare((y[a]),(y[c])) ) : t;
final int bc = (t = ( Float.compare((x[b]),(x[c])) )) == 0 ? ( Float.compare((y[b]),(y[c])) ) : t;
return (ab < 0 ?
(bc < 0 ? b : ac < 0 ? c : a) :
(bc > 0 ? b : ac > 0 ? c : a));
}
private static void swap(final float x[], final float[] y, final int a, final int b) {
final float t = x[a];
final float u = y[a];
x[a] = x[b];
y[a] = y[b];
x[b] = t;
y[b] = u;
}
private static void swap(final float[] x, final float[] y, int a, int b, final int n) {
for (int i = 0; i < n; i++, a++, b++) swap(x, y, a, b);
}
private static void selectionSort(final float[] a, final float[] b, final int from, final int to) {
for(int i = from; i < to - 1; i++) {
int m = i, u;
for(int j = i + 1; j < to; j++)
if ((u = ( Float.compare((a[j]),(a[m])) )) < 0 || u == 0 && ( Float.compare((b[j]),(b[m])) < 0 )) m = j;
if (m != i) {
float t = a[i];
a[i] = a[m];
a[m] = t;
t = b[i];
b[i] = b[m];
b[m] = t;
}
}
}
/** Sorts the specified range of elements of two arrays according to the natural lexicographical
* ascending order 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.
*
*
This method implements a lexicographical sorting of the arguments. Pairs of
* elements in the same position in the two provided arrays will be considered a single key, and
* permuted accordingly. In the end, either {@code x[i] < x[i + 1]} or {@code x[i]
* == x[i + 1]} and {@code y[i] ≤ y[i + 1]}.
*
* @param x the first array to be sorted.
* @param y the second array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void quickSort(final float[] x, final float[] y, final int from, final int to) {
final int len = to - from;
if (len < QUICKSORT_NO_REC) {
selectionSort(x, y, from, to);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
if (len > QUICKSORT_MEDIAN_OF_9) { // Big arrays, pseudomedian of 9
int s = len / 8;
l = med3(x, y, l, l + s, l + 2 * s);
m = med3(x, y, m - s, m, m + s);
n = med3(x, y, n - 2 * s, n - s, n);
}
m = med3(x, y, l, m, n); // Mid-size, med of 3
final float v = x[m], w = y[m];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while (true) {
int comparison, t;
while (b <= c && (comparison = (t = ( Float.compare((x[b]),(v)) )) == 0 ? ( Float.compare((y[b]),(w)) ) : t) <= 0) {
if (comparison == 0) swap(x, y, a++, b);
b++;
}
while (c >= b && (comparison = (t = ( Float.compare((x[c]),(v)) )) == 0 ? ( Float.compare((y[c]),(w)) ) : t) >= 0) {
if (comparison == 0) swap(x, y, c, d--);
c--;
}
if (b > c) break;
swap(x, y, b++, c--);
}
// Swap partition elements back to middle
int s;
s = Math.min(a - from, b - a);
swap(x, y, from, b - s, s);
s = Math.min(d - c, to - d - 1);
swap(x, y, b, to - s, s);
// Recursively sort non-partition-elements
if ((s = b - a) > 1) quickSort(x, y, from, from + s);
if ((s = d - c) > 1) quickSort(x, y, to - s, to);
}
/** Sorts two arrays according to the natural lexicographical ascending order 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.
*
*
This method implements a lexicographical sorting of the arguments. Pairs of
* elements in the same position in the two provided arrays will be considered a single key, and
* permuted accordingly. In the end, either {@code x[i] < x[i + 1]} or {@code x[i]
* == x[i + 1]} and {@code y[i] ≤ y[i + 1]}.
*
* @param x the first array to be sorted.
* @param y the second array to be sorted.
*/
public static void quickSort(final float[] x, final float[] y) {
ensureSameLength(x, y);
quickSort(x, y, 0, x.length);
}
protected static class ForkJoinQuickSort2 extends RecursiveAction {
private static final long serialVersionUID = 1L;
private final int from;
private final int to;
private final float[] x, y;
public ForkJoinQuickSort2(final float[] x, final float[] y, final int from , final int to) {
this.from = from;
this.to = to;
this.x = x;
this.y = y;
}
@Override
protected void compute() {
final float[] x = this.x;
final float[] y = this.y;
final int len = to - from;
if (len < PARALLEL_QUICKSORT_NO_FORK) {
quickSort(x, y, from, to);
return;
}
// Choose a partition element, v
int m = from + len / 2;
int l = from;
int n = to - 1;
int s = len / 8;
l = med3(x, y, l, l + s, l + 2 * s);
m = med3(x, y, m - s, m, m + s);
n = med3(x, y, n - 2 * s, n - s, n);
m = med3(x, y, l, m, n);
final float v = x[m], w = y[m];
// Establish Invariant: v* (v)* v*
int a = from, b = a, c = to - 1, d = c;
while (true) {
int comparison, t;
while (b <= c && (comparison = (t = ( Float.compare((x[b]),(v)) )) == 0 ? ( Float.compare((y[b]),(w)) ) : t) <= 0) {
if (comparison == 0) swap(x, y, a++, b);
b++;
}
while (c >= b && (comparison = (t = ( Float.compare((x[c]),(v)) )) == 0 ? ( Float.compare((y[c]),(w)) ) : t) >= 0) {
if (comparison == 0) swap(x, y, c, d--);
c--;
}
if (b > c) break;
swap(x, y, b++, c--);
}
// Swap partition elements back to middle
int t;
s = Math.min(a - from, b - a);
swap(x, y, from, b - s, s);
s = Math.min(d - c, to - d - 1);
swap(x, y, b, to - s, s);
s = b - a;
t = d - c;
// Recursively sort non-partition-elements
if (s > 1 && t > 1) invokeAll(new ForkJoinQuickSort2 (x, y, from, from + s), new ForkJoinQuickSort2 (x, y, to - t, to));
else if (s > 1) invokeAll(new ForkJoinQuickSort2 (x, y, from, from + s));
else invokeAll(new ForkJoinQuickSort2 (x, y, to - t, to));
}
}
/** Sorts the specified range of elements of two arrays according to the natural lexicographical
* ascending order using a parallel 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.
*
*
This method implements a lexicographical sorting of the arguments. Pairs of
* elements in the same position in the two provided arrays will be considered a single key, and
* permuted accordingly. In the end, either {@code x[i] < x[i + 1]} or {@code x[i]
* == x[i + 1]} and {@code y[i] ≤ y[i + 1]}.
*
* @param x the first array to be sorted.
* @param y the second array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void parallelQuickSort(final float[] x, final float[] y, final int from, final int to) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_QUICKSORT_NO_FORK || pool.getParallelism() == 1) quickSort(x, y, from, to);
else {
pool.invoke(new ForkJoinQuickSort2 (x, y, from, to));
}
}
/** Sorts two arrays according to the natural lexicographical
* ascending order using a parallel 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.
*
*
This method implements a lexicographical sorting of the arguments. Pairs of
* elements in the same position in the two provided arrays will be considered a single key, and
* permuted accordingly. In the end, either {@code x[i] < x[i + 1]} or {@code x[i]
* == x[i + 1]} and {@code y[i] ≤ y[i + 1]}.
*
* @param x the first array to be sorted.
* @param y the second array to be sorted.
*/
public static void parallelQuickSort(final float[] x, final float[] y) {
ensureSameLength(x, y);
parallelQuickSort(x, y, 0, x.length);
}
/** Sorts an array according to the natural ascending order,
* potentially dynamically choosing an appropriate algorithm given the type and size of the array. The
* sort will be stable unless it is provable that it would be impossible for there to be any difference
* between a stable and unstable sort for the given type, in which case stability is meaningless and thus
* unspecified.
*
* @param a the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
* @since 8.3.0
*/
public static void unstableSort(final float a[], final int from, final int to) {
// TODO For some TBD threshold, delegate to java.util.Arrays.sort if under it.
if (to - from >= RADIX_SORT_MIN_THRESHOLD) {
radixSort(a, from, to);
} else {
quickSort(a, from, to);
}
}
/** Sorts the specified range of elements according to the natural ascending order
* potentially dynamically choosing an appropriate algorithm given the type and size of the array.
* No assurance is made of the stability of the sort.
*
* @param a the array to be sorted.
* @since 8.3.0
*/
public static void unstableSort(final float a[]) {
unstableSort(a, 0, a.length);
}
/** Sorts the specified range of elements according to the order induced by the specified comparator,
* potentially dynamically choosing an appropriate algorithm given the type and size of the array.
* No assurance is made of the stability of the sort.
*
* @param a the array to be sorted.
* @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 sorting order.
* @since 8.3.0
*/
public static void unstableSort(final float a[], final int from, final int to, FloatComparator comp) {
quickSort(a, from, to, comp);
}
/** Sorts an array according to the order induced by the specified comparator,
* potentially dynamically choosing an appropriate algorithm given the type and size of the array.
* No assurance is made of the stability of the sort.
*
* @param a the array to be sorted.
* @param comp the comparator to determine the sorting order.
* @since 8.3.0
*/
public static void unstableSort(final float a[], FloatComparator comp) {
unstableSort(a, 0, a.length, comp);
}
/** Sorts the specified range of elements according to the natural ascending order using mergesort, using a given pre-filled support array.
*
*
This sort is guaranteed to be stable: equal elements will not be reordered as a result
* of the sort. Moreover, no support arrays will be allocated.
*
* @param a the array to be sorted.
* @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 supp a support array containing at least {@code to} elements, and whose entries are identical to those
* of {@code a} in the specified range. It can be {@code null}, in which case {@code a} will be cloned.
*/
public static void mergeSort(final float a[], final int from, final int to, float supp[]) {
int len = to - from;
// Insertion sort on smallest arrays
if (len < MERGESORT_NO_REC) {
insertionSort(a, from, to);
return;
}
if (supp == null) supp = java.util.Arrays.copyOf(a, to);
// Recursively sort halves of a into supp
final int mid = (from + to) >>> 1;
mergeSort(supp, from, mid, a);
mergeSort(supp, mid, to, a);
// If list is already sorted, just copy from supp to a. This is an
// optimization that results in faster sorts for nearly ordered lists.
if (( Float.compare((supp[mid - 1]),(supp[mid])) <= 0 )) {
System.arraycopy(supp, from, a, from, len);
return;
}
// Merge sorted halves (now in supp) into a
for(int i = from, p = from, q = mid; i < to; i++) {
if (q >= to || p < mid && ( Float.compare((supp[p]),(supp[q])) <= 0 )) a[i] = supp[p++];
else a[i] = supp[q++];
}
}
/** Sorts the specified range of elements according to the natural ascending order using mergesort.
*
*
This sort is guaranteed to be stable: equal elements will not be reordered as a result
* of the sort. An array as large as {@code a} will be allocated by this method.
* @param a the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void mergeSort(final float a[], final int from, final int to) {
mergeSort(a, from, to, (float[])null);
}
/** Sorts an array according to the natural ascending order using mergesort.
*
*
This sort is guaranteed to be stable: equal elements will not be reordered as a result
* of the sort. An array as large as {@code a} will be allocated by this method.
* @param a the array to be sorted.
*/
public static void mergeSort(final float a[]) {
mergeSort(a, 0, a.length);
}
/** Sorts the specified range of elements according to the order induced by the specified
* comparator using mergesort, using a given pre-filled support array.
*
*
This sort is guaranteed to be stable: equal elements will not be reordered as a result
* of the sort. Moreover, no support arrays will be allocated.
* @param a the array to be sorted.
* @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 sorting order.
* @param supp a support array containing at least {@code to} elements, and whose entries are identical to those
* of {@code a} in the specified range. It can be {@code null}, in which case {@code a} will be cloned.
*/
public static void mergeSort(final float a[], final int from, final int to, FloatComparator comp, float supp[]) {
int len = to - from;
// Insertion sort on smallest arrays
if (len < MERGESORT_NO_REC) {
insertionSort(a, from, to, comp);
return;
}
if (supp == null) supp = java.util.Arrays.copyOf(a, to);
// Recursively sort halves of a into supp
final int mid = (from + to) >>> 1;
mergeSort(supp, from, mid, comp, a);
mergeSort(supp, mid, to, comp, a);
// If list is already sorted, just copy from supp to a. This is an
// optimization that results in faster sorts for nearly ordered lists.
if (comp.compare(supp[mid - 1], supp[mid]) <= 0) {
System.arraycopy(supp, from, a, from, len);
return;
}
// Merge sorted halves (now in supp) into a
for(int i = from, p = from, q = mid; i < to; i++) {
if (q >= to || p < mid && comp.compare(supp[p], supp[q]) <= 0) a[i] = supp[p++];
else a[i] = supp[q++];
}
}
/** Sorts the specified range of elements 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. An array as large as {@code a} will be allocated by this method.
*
* @param a the array to be sorted.
* @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 sorting order.
*/
public static void mergeSort(final float a[], final int from, final int to, FloatComparator comp) {
mergeSort(a, from, to, comp, (float[])null);
}
/** Sorts an array 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. An array as large as {@code a} will be allocated by this method.
* @param a the array to be sorted.
* @param comp the comparator to determine the sorting order.
*/
public static void mergeSort(final float a[], FloatComparator comp) {
mergeSort(a, 0, a.length, comp);
}
/** Sorts an array according to the natural ascending order,
* potentially dynamically choosing an appropriate algorithm given the type and size of the array. The
* sort will be stable unless it is provable that it would be impossible for there to be any difference
* between a stable and unstable sort for the given type, in which case stability is meaningless and thus
* unspecified.
*
*
An array as large as {@code a} may be allocated by this method.
*
* @param a the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
* @since 8.3.0
*/
public static void stableSort(final float a[], final int from, final int to) {
// Due to subtle differences between Float/Double.compare and operator compare, it is
// not safe to delegate this to java.util.Arrays.sort(double[], int, int)
mergeSort(a, from, to);
}
/** Sorts the specified range of elements according to the natural ascending order
* potentially dynamically choosing an appropriate algorithm given the type and size of the array. The
* sort will be stable unless it is provable that it would be impossible for there to be any difference
* between a stable and unstable sort for the given type, in which case stability is meaningless and thus
* unspecified.
*
*
An array as large as {@code a} may be allocated by this method.
*
* @param a the array to be sorted.
* @since 8.3.0
*/
public static void stableSort(final float a[]) {
stableSort(a, 0, a.length);
}
/** Sorts the specified range of elements according to the order induced by the specified comparator,
* potentially dynamically choosing an appropriate algorithm given the type and size of the array. The
* sort will be stable unless it is provable that it would be impossible for there to be any difference
* between a stable and unstable sort for the given type, in which case stability is meaningless and thus
* unspecified.
*
*
An array as large as {@code a} may be allocated by this method.
*
* @param a the array to be sorted.
* @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 sorting order.
* @since 8.3.0
*/
public static void stableSort(final float a[], final int from, final int to, FloatComparator comp) {
mergeSort(a, from, to, comp);
}
/** Sorts an array according to the order induced by the specified comparator,
* potentially dynamically choosing an appropriate algorithm given the type and size of the array. The
* sort will be stable unless it is provable that it would be impossible for there to be any difference
* between a stable and unstable sort for the given type, in which case stability is meaningless and thus
* unspecified.
*
*
An array as large as {@code a} may be allocated by this method.
*
* @param a the array to be sorted.
* @param comp the comparator to determine the sorting order.
* @since 8.3.0
*/
public static void stableSort(final float a[], FloatComparator comp) {
stableSort(a, 0, a.length, comp);
}
/**
* Searches a range of the specified array for the specified value using
* the binary search algorithm. The range must be sorted prior to making this call.
* If it is not sorted, the results are undefined. If the range contains multiple elements with
* the specified value, there is no guarantee which one will be found.
*
* @param a the array to be searched.
* @param from the index of the first element (inclusive) to be searched.
* @param to the index of the last element (exclusive) to be searched.
* @param key the value to be searched for.
* @return index of the search key, if it is contained in the array;
* otherwise, {@code (-(insertion point) - 1)}. The insertion
* point is defined as the the point at which the value would
* be inserted into the array: the index of the first
* element greater than the key, or the length of the array, if all
* elements in the array are less than the specified key. Note
* that this guarantees that the return value will be ≥ 0 if
* and only if the key is found.
* @see java.util.Arrays
*/
public static int binarySearch(final float[] a, int from, int to, final float key) {
float midVal;
to--;
while (from <= to) {
final int mid = (from + to) >>> 1;
midVal = a[mid];
if (midVal < key) from = mid + 1;
else if (midVal > key) to = mid - 1;
else return mid;
}
return -(from + 1);
}
/**
* Searches an array for the specified value using
* the binary search algorithm. The range must be sorted prior to making this call.
* If it is not sorted, the results are undefined. If the range contains multiple elements with
* the specified value, there is no guarantee which one will be found.
*
* @param a the array to be searched.
* @param key the value to be searched for.
* @return index of the search key, if it is contained in the array;
* otherwise, {@code (-(insertion point) - 1)}. The insertion
* point is defined as the the point at which the value would
* be inserted into the array: the index of the first
* element greater than the key, or the length of the array, if all
* elements in the array are less than the specified key. Note
* that this guarantees that the return value will be ≥ 0 if
* and only if the key is found.
* @see java.util.Arrays
*/
public static int binarySearch(final float[] a, final float key) {
return binarySearch(a, 0, a.length, key);
}
/**
* Searches a range of the specified array for the specified value using
* the binary search algorithm and a specified comparator. The range must be sorted following the comparator prior to making this call.
* If it is not sorted, the results are undefined. If the range contains multiple elements with
* the specified value, there is no guarantee which one will be found.
*
* @param a the array to be searched.
* @param from the index of the first element (inclusive) to be searched.
* @param to the index of the last element (exclusive) to be searched.
* @param key the value to be searched for.
* @param c a comparator.
* @return index of the search key, if it is contained in the array;
* otherwise, {@code (-(insertion point) - 1)}. The insertion
* point is defined as the the point at which the value would
* be inserted into the array: the index of the first
* element greater than the key, or the length of the array, if all
* elements in the array are less than the specified key. Note
* that this guarantees that the return value will be ≥ 0 if
* and only if the key is found.
* @see java.util.Arrays
*/
public static int binarySearch(final float[] a, int from, int to, final float key, final FloatComparator c) {
float midVal;
to--;
while (from <= to) {
final int mid = (from + to) >>> 1;
midVal = a[mid];
final int cmp = c.compare(midVal, key);
if (cmp < 0) from = mid + 1;
else if (cmp > 0) to = mid - 1;
else return mid; // key found
}
return -(from + 1);
}
/**
* Searches an array for the specified value using
* the binary search algorithm and a specified comparator. The range must be sorted following the comparator prior to making this call.
* If it is not sorted, the results are undefined. If the range contains multiple elements with
* the specified value, there is no guarantee which one will be found.
*
* @param a the array to be searched.
* @param key the value to be searched for.
* @param c a comparator.
* @return index of the search key, if it is contained in the array;
* otherwise, {@code (-(insertion point) - 1)}. The insertion
* point is defined as the the point at which the value would
* be inserted into the array: the index of the first
* element greater than the key, or the length of the array, if all
* elements in the array are less than the specified key. Note
* that this guarantees that the return value will be ≥ 0 if
* and only if the key is found.
* @see java.util.Arrays
*/
public static int binarySearch(final float[] a, final float key, final FloatComparator c) {
return binarySearch(a, 0, a.length, key, c);
}
/** The size of a digit used during radix sort (must be a power of 2). */
private static final int DIGIT_BITS = 8;
/** The mask to extract a digit of {@link #DIGIT_BITS} bits. */
private static final int DIGIT_MASK = (1 << DIGIT_BITS) - 1;
/** The number of digits per element. */
private static final int DIGITS_PER_ELEMENT = Float.SIZE / DIGIT_BITS;
private static final int RADIXSORT_NO_REC = 1024;
private static final int RADIXSORT_NO_REC_SMALL = 64;
private static final int PARALLEL_RADIXSORT_NO_FORK = 1024;
// The thresholds were determined on an Intel i7 8700K.
/** Threshold hint for using a radix sort vs a comparison based sort. */
static final int RADIX_SORT_MIN_THRESHOLD = 2000;
/** This method fixes negative numbers so that the combination exponent/significand is lexicographically sorted. */
private static final int fixFloat(final float f) {
final int i = Float.floatToIntBits(f);
return i >= 0 ? i : i ^ 0x7FFFFFFF;
}
/** Sorts the specified array using radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
* @implSpec This implementation is significantly faster than quicksort
* already at small sizes (say, more than 5000 elements), but it can only
* sort in ascending order.
*
* @param a the array to be sorted.
*/
public static void radixSort(final float[] a) {
radixSort(a, 0, a.length);
}
/** Sorts the specified range of an array using radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
* @implSpec This implementation is significantly faster than quicksort
* already at small sizes (say, more than 5000 elements), but it can only
* sort in ascending order.
*
* @param a the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void radixSort(final float[] a, final int from, final int to) {
if (to - from < RADIXSORT_NO_REC) {
quickSort(a, from, to);
return;
}
final int maxLevel = DIGITS_PER_ELEMENT - 1;
final int stackSize = ((1 << DIGIT_BITS) - 1) * (DIGITS_PER_ELEMENT - 1) + 1;
int stackPos = 0;
final int[] offsetStack = new int[stackSize];
final int[] lengthStack = new int[stackSize];
final int[] levelStack = new int[stackSize];
offsetStack[stackPos] = from;
lengthStack[stackPos] = to - from;
levelStack[stackPos++] = 0;
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
while(stackPos > 0) {
final int first = offsetStack[--stackPos];
final int length = lengthStack[stackPos];
final int level = levelStack[stackPos];
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(a[i]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
float t = a[i];
c = (fixFloat(t) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while ((d = --pos[c]) > i) {
final float z = t;
t = a[d];
a[d] = z;
c = (fixFloat(t) >>> shift & DIGIT_MASK ^ signMask);
}
a[i] = t;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < RADIXSORT_NO_REC) quickSort(a, i, i + count[c]);
else {
offsetStack[stackPos] = i;
lengthStack[stackPos] = count[c];
levelStack[stackPos++] = level + 1;
}
}
}
}
}
protected static final class Segment {
protected final int offset, length, level;
protected Segment(final int offset, final int length, final int level) {
this.offset = offset;
this.length = length;
this.level = level;
}
@Override
public String toString() { return "Segment [offset=" + offset + ", length=" + length + ", level=" + level + "]"; }
}
protected static final Segment POISON_PILL = new Segment(-1, -1, -1);
/** Sorts the specified range of an array using parallel radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
* @param a the array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void parallelRadixSort(final float[] a, final int from, final int to) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_RADIXSORT_NO_FORK || pool.getParallelism() == 1) {
quickSort(a, from, to);
return;
}
final int maxLevel = DIGITS_PER_ELEMENT - 1;
final LinkedBlockingQueue queue = new LinkedBlockingQueue<>();
queue.add(new Segment(from, to - from, 0));
final AtomicInteger queueSize = new AtomicInteger(1);
final int numberOfThreads = pool.getParallelism();
final ExecutorCompletionService executorCompletionService = new ExecutorCompletionService<>(pool);
for(int j = numberOfThreads; j-- != 0;) executorCompletionService.submit(() -> {
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
for(;;) {
if (queueSize.get() == 0) for(int i = numberOfThreads; i-- != 0;) queue.add(POISON_PILL);
final Segment segment = queue.take();
if (segment == POISON_PILL) return null;
final int first = segment.offset;
final int length = segment.length;
final int level = segment.level;
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(a[i]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for(int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
float t = a[i];
c = (fixFloat(t) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) {
while((d = --pos[c]) > i) {
final float z = t;
t = a[d];
a[d] = z;
c = (fixFloat(t) >>> shift & DIGIT_MASK ^ signMask);
}
a[i] = t;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < PARALLEL_RADIXSORT_NO_FORK) quickSort(a, i, i + count[c]);
else {
queueSize.incrementAndGet();
queue.add(new Segment(i, count[c], level + 1));
}
}
}
queueSize.decrementAndGet();
}
});
Throwable problem = null;
for(int i = numberOfThreads; i-- != 0;)
try {
executorCompletionService.take().get();
}
catch(Exception e) {
problem = e.getCause(); // We keep only the last one. They will be logged anyway.
}
if (problem != null) throw (problem instanceof RuntimeException) ? (RuntimeException)problem : new RuntimeException(problem);
}
/** Sorts the specified array using parallel radix sort.
*
* The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
* @param a the array to be sorted.
*/
public static void parallelRadixSort(final float[] a) {
parallelRadixSort(a, 0, a.length);
}
/** Sorts the specified array using indirect radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code a[perm[i]] ≤ a[perm[i + 1]]}.
*
* @implSpec This implementation will allocate, in the stable case, a support array as large as {@code perm} (note that the stable
* version is slightly faster).
*
* @param perm a permutation array indexing {@code a}.
* @param a the array to be sorted.
* @param stable whether the sorting algorithm should be stable.
*/
public static void radixSortIndirect(final int[] perm, final float[] a, final boolean stable) {
radixSortIndirect(perm, a, 0, perm.length, stable);
}
/** Sorts the specified array using indirect radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code a[perm[i]] ≤ a[perm[i + 1]]}.
*
* @implSpec This implementation will allocate, in the stable case, a support array as large as {@code perm} (note that the stable
* version is slightly faster).
*
* @param perm a permutation array indexing {@code a}.
* @param a the array to be sorted.
* @param from the index of the first element of {@code perm} (inclusive) to be permuted.
* @param to the index of the last element of {@code perm} (exclusive) to be permuted.
* @param stable whether the sorting algorithm should be stable.
*/
public static void radixSortIndirect(final int[] perm, final float[] a, final int from, final int to, final boolean stable) {
if (to - from < RADIXSORT_NO_REC) {
quickSortIndirect(perm, a, from, to);
if (stable) stabilize(perm, a, from, to);
return;
}
final int maxLevel = DIGITS_PER_ELEMENT - 1;
final int stackSize = ((1 << DIGIT_BITS) - 1) * (DIGITS_PER_ELEMENT - 1) + 1;
int stackPos = 0;
final int[] offsetStack = new int[stackSize];
final int[] lengthStack = new int[stackSize];
final int[] levelStack = new int[stackSize];
offsetStack[stackPos] = from;
lengthStack[stackPos] = to - from;
levelStack[stackPos++] = 0;
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
final int[] support = stable ? new int[perm.length] : null;
while(stackPos > 0) {
final int first = offsetStack[--stackPos];
final int length = lengthStack[stackPos];
final int level = levelStack[stackPos];
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(a[perm[i]]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = stable ? 0 : first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
if (stable) {
for(int i = first + length; i-- != first;) support[--pos[(fixFloat(a[perm[i]]) >>> shift & DIGIT_MASK ^ signMask)]] = perm[i];
System.arraycopy(support, 0, perm, first, length);
for(int i = 0, p = first; i <= lastUsed; i++) {
if (level < maxLevel && count[i] > 1) {
if (count[i] < RADIXSORT_NO_REC) {
quickSortIndirect(perm, a, p, p + count[i]);
if (stable) stabilize(perm, a, p, p + count[i]);
}
else {
offsetStack[stackPos] = p;
lengthStack[stackPos] = count[i];
levelStack[stackPos++] = level + 1;
}
}
p += count[i];
}
java.util.Arrays.fill(count, 0);
}
else {
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
int t = perm[i];
c = (fixFloat(a[t]) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while((d = --pos[c]) > i) {
final int z = t;
t = perm[d];
perm[d] = z;
c = (fixFloat(a[t]) >>> shift & DIGIT_MASK ^ signMask);
}
perm[i] = t;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < RADIXSORT_NO_REC) {
quickSortIndirect(perm, a, i, i + count[c]);
if (stable) stabilize(perm, a, i, i + count[c]);
}
else {
offsetStack[stackPos] = i;
lengthStack[stackPos] = count[c];
levelStack[stackPos++] = level + 1;
}
}
}
}
}
}
/** Sorts the specified range of an array using parallel indirect radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code a[perm[i]] ≤ a[perm[i + 1]]}.
*
* @param perm a permutation array indexing {@code a}.
* @param a the array to be sorted.
* @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 stable whether the sorting algorithm should be stable.
*/
public static void parallelRadixSortIndirect(final int perm[], final float[] a, final int from, final int to, final boolean stable) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_RADIXSORT_NO_FORK || pool.getParallelism() == 1) {
radixSortIndirect(perm, a, from, to, stable);
return;
}
final int maxLevel = DIGITS_PER_ELEMENT - 1;
final LinkedBlockingQueue queue = new LinkedBlockingQueue<>();
queue.add(new Segment(from, to - from, 0));
final AtomicInteger queueSize = new AtomicInteger(1);
final int numberOfThreads = pool.getParallelism();
final ExecutorCompletionService executorCompletionService = new ExecutorCompletionService<>(pool);
final int[] support = stable ? new int[perm.length] : null;
for(int j = numberOfThreads; j-- != 0;) executorCompletionService.submit(() -> {
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
for(;;) {
if (queueSize.get() == 0) for(int i = numberOfThreads; i-- != 0;) queue.add(POISON_PILL);
final Segment segment = queue.take();
if (segment == POISON_PILL) return null;
final int first = segment.offset;
final int length = segment.length;
final int level = segment.level;
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(a[perm[i]]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
if (stable) {
for(int i = first + length; i-- != first;) support[--pos[(fixFloat(a[perm[i]]) >>> shift & DIGIT_MASK ^ signMask)]] = perm[i];
System.arraycopy(support, first, perm, first, length);
for(int i = 0, p = first; i <= lastUsed; i++) {
if (level < maxLevel && count[i] > 1) {
if (count[i] < PARALLEL_RADIXSORT_NO_FORK) radixSortIndirect(perm, a, p, p + count[i], stable);
else {
queueSize.incrementAndGet();
queue.add(new Segment(p, count[i], level + 1));
}
}
p += count[i];
}
java.util.Arrays.fill(count, 0);
}
else {
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
int t = perm[i];
c = (fixFloat(a[t]) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while((d = --pos[c]) > i) {
final int z = t;
t = perm[d];
perm[d] = z;
c = (fixFloat(a[t]) >>> shift & DIGIT_MASK ^ signMask);
}
perm[i] = t;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < PARALLEL_RADIXSORT_NO_FORK) radixSortIndirect(perm, a, i, i + count[c], stable);
else {
queueSize.incrementAndGet();
queue.add(new Segment(i, count[c], level + 1));
}
}
}
}
queueSize.decrementAndGet();
}
});
Throwable problem = null;
for(int i = numberOfThreads; i-- != 0;)
try {
executorCompletionService.take().get();
}
catch(Exception e) {
problem = e.getCause(); // We keep only the last one. They will be logged anyway.
}
if (problem != null) throw (problem instanceof RuntimeException) ? (RuntimeException)problem : new RuntimeException(problem);
}
/** Sorts the specified array using parallel indirect radix sort.
*
* The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code a[perm[i]] ≤ a[perm[i + 1]]}.
*
* @param perm a permutation array indexing {@code a}.
* @param a the array to be sorted.
* @param stable whether the sorting algorithm should be stable.
*/
public static void parallelRadixSortIndirect(final int perm[], final float[] a, final boolean stable) {
parallelRadixSortIndirect(perm, a, 0, a.length, stable);
}
/** Sorts the specified pair of arrays lexicographically using radix sort.
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implements a lexicographical sorting of the arguments. Pairs of elements
* in the same position in the two provided arrays will be considered a single key, and permuted
* accordingly. In the end, either {@code a[i] < a[i + 1]} or {@code a[i] == a[i + 1]} and {@code b[i] ≤ b[i + 1]}.
*
* @param a the first array to be sorted.
* @param b the second array to be sorted.
*/
public static void radixSort(final float[] a, final float[] b) {
ensureSameLength(a, b);
radixSort(a, b, 0, a.length);
}
/** Sorts the specified range of elements of two arrays using radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implements a lexicographical sorting of the arguments. Pairs of elements
* in the same position in the two provided arrays will be considered a single key, and permuted
* accordingly. In the end, either {@code a[i] < a[i + 1]} or {@code a[i] == a[i + 1]} and {@code b[i] ≤ b[i + 1]}.
*
* @param a the first array to be sorted.
* @param b the second array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void radixSort(final float[] a, final float[] b, final int from, final int to) {
if (to - from < RADIXSORT_NO_REC) {
quickSort(a, b, from, to);
return;
}
final int layers = 2;
final int maxLevel = DIGITS_PER_ELEMENT * layers - 1;
final int stackSize = ((1 << DIGIT_BITS) - 1) * (layers * DIGITS_PER_ELEMENT - 1) + 1;
int stackPos = 0;
final int[] offsetStack = new int[stackSize];
final int[] lengthStack = new int[stackSize];
final int[] levelStack = new int[stackSize];
offsetStack[stackPos] = from;
lengthStack[stackPos] = to - from;
levelStack[stackPos++] = 0;
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
while(stackPos > 0) {
final int first = offsetStack[--stackPos];
final int length = lengthStack[stackPos];
final int level = levelStack[stackPos];
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final float[] k = level < DIGITS_PER_ELEMENT ? a : b; // This is the key array
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(k[i]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
float t = a[i];
float u = b[i];
c = (fixFloat(k[i]) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while((d = --pos[c]) > i) {
c = (fixFloat(k[d]) >>> shift & DIGIT_MASK ^ signMask);
float z = t;
t = a[d];
a[d] = z;
z = u;
u = b[d];
b[d] = z;
}
a[i] = t;
b[i] = u;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < RADIXSORT_NO_REC) quickSort(a, b, i, i + count[c]);
else {
offsetStack[stackPos] = i;
lengthStack[stackPos] = count[c];
levelStack[stackPos++] = level + 1;
}
}
}
}
}
/** Sorts the specified range of elements of two arrays using a parallel radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implements a lexicographical sorting of the arguments. Pairs of elements
* in the same position in the two provided arrays will be considered a single key, and permuted
* accordingly. In the end, either {@code a[i] < a[i + 1]} or {@code a[i] == a[i + 1]} and {@code b[i] ≤ b[i + 1]}.
*
* @param a the first array to be sorted.
* @param b the second array to be sorted.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void parallelRadixSort(final float[] a, final float[] b, final int from, final int to) {
ForkJoinPool pool = getPool();
if (to - from < PARALLEL_RADIXSORT_NO_FORK || pool.getParallelism() == 1) {
quickSort(a, b, from, to);
return;
}
final int layers = 2;
if (a.length != b.length) throw new IllegalArgumentException("Array size mismatch.");
final int maxLevel = DIGITS_PER_ELEMENT * layers - 1;
final LinkedBlockingQueue queue = new LinkedBlockingQueue<>();
queue.add(new Segment(from, to - from, 0));
final AtomicInteger queueSize = new AtomicInteger(1);
final int numberOfThreads = pool.getParallelism();
final ExecutorCompletionService executorCompletionService = new ExecutorCompletionService<>(pool);
for (int j = numberOfThreads; j-- != 0;) executorCompletionService.submit(() -> {
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
for (;;) {
if (queueSize.get() == 0) for (int i = numberOfThreads; i-- != 0;)
queue.add(POISON_PILL);
final Segment segment = queue.take();
if (segment == POISON_PILL) return null;
final int first = segment.offset;
final int length = segment.length;
final int level = segment.level;
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final float[] k = level < DIGITS_PER_ELEMENT ? a : b; // This is the key array
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS;
// Count keys.
for (int i = first + length; i-- != first;)
count[(fixFloat(k[i]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
final int end = first + length - count[lastUsed];
for (int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
float t = a[i];
float u = b[i];
c = (fixFloat(k[i]) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while ((d = --pos[c]) > i) {
c = (fixFloat(k[d]) >>> shift & DIGIT_MASK ^ signMask);
final float z = t;
final float w = u;
t = a[d];
u = b[d];
a[d] = z;
b[d] = w;
}
a[i] = t;
b[i] = u;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < PARALLEL_RADIXSORT_NO_FORK) quickSort(a, b, i, i + count[c]);
else {
queueSize.incrementAndGet();
queue.add(new Segment(i, count[c], level + 1));
}
}
}
queueSize.decrementAndGet();
}
});
Throwable problem = null;
for (int i = numberOfThreads; i-- != 0;)
try {
executorCompletionService.take().get();
}
catch (Exception e) {
problem = e.getCause(); // We keep only the last one. They will be logged anyway.
}
if (problem != null) throw (problem instanceof RuntimeException) ? (RuntimeException)problem : new RuntimeException(problem);
}
/** Sorts two arrays using a parallel radix sort.
*
* The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implements a lexicographical sorting of the arguments. Pairs of elements
* in the same position in the two provided arrays will be considered a single key, and permuted
* accordingly. In the end, either {@code a[i] < a[i + 1]} or {@code a[i] == a[i + 1]} and {@code b[i] ≤ b[i + 1]}.
*
* @param a the first array to be sorted.
* @param b the second array to be sorted.
*/
public static void parallelRadixSort(final float[] a, final float[] b) {
ensureSameLength(a, b);
parallelRadixSort(a, b, 0, a.length);
}
private static void insertionSortIndirect(final int[] perm, final float[] a, final float[] b, final int from, final int to) {
for (int i = from; ++i < to;) {
int t = perm[i];
int j = i;
for (int u = perm[j - 1]; ( Float.compare((a[t]),(a[u])) < 0 ) || ( Float.compare((a[t]),(a[u])) == 0 ) && ( Float.compare((b[t]),(b[u])) < 0 ); u = perm[--j - 1]) {
perm[j] = u;
if (from == j - 1) {
--j;
break;
}
}
perm[j] = t;
}
}
/** Sorts the specified pair of arrays lexicographically using indirect radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code a[perm[i]] ≤ a[perm[i + 1]]} or {@code a[perm[i]] == a[perm[i + 1]]} and {@code b[perm[i]] ≤ b[perm[i + 1]]}.
*
* @implSpec This implementation will allocate, in the stable case, a further support array as large as {@code perm} (note that the stable
* version is slightly faster).
*
* @param perm a permutation array indexing {@code a}.
* @param a the array to be sorted.
* @param b the second array to be sorted.
* @param stable whether the sorting algorithm should be stable.
*/
public static void radixSortIndirect(final int[] perm, final float[] a, final float[] b, final boolean stable) {
ensureSameLength(a, b);
radixSortIndirect(perm, a, b, 0, a.length, stable);
}
/** Sorts the specified pair of arrays lexicographically using indirect radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implement an indirect sort. The elements of {@code perm} (which must
* be exactly the numbers in the interval {@code [0..perm.length)}) will be permuted so that
* {@code a[perm[i]] ≤ a[perm[i + 1]]} or {@code a[perm[i]] == a[perm[i + 1]]} and {@code b[perm[i]] ≤ b[perm[i + 1]]}.
*
* @implSpec This implementation will allocate, in the stable case, a further support array as large as {@code perm} (note that the stable
* version is slightly faster).
*
* @param perm a permutation array indexing {@code a}.
* @param a the array to be sorted.
* @param b the second array to be sorted.
* @param from the index of the first element of {@code perm} (inclusive) to be permuted.
* @param to the index of the last element of {@code perm} (exclusive) to be permuted.
* @param stable whether the sorting algorithm should be stable.
*/
public static void radixSortIndirect(final int[] perm, final float[] a, final float[] b, final int from, final int to, final boolean stable) {
if (to - from < RADIXSORT_NO_REC_SMALL) {
insertionSortIndirect(perm, a, b, from, to);
return;
}
final int layers = 2;
final int maxLevel = DIGITS_PER_ELEMENT * layers - 1;
final int stackSize = ((1 << DIGIT_BITS) - 1) * (layers * DIGITS_PER_ELEMENT - 1) + 1;
int stackPos = 0;
final int[] offsetStack = new int[stackSize];
final int[] lengthStack = new int[stackSize];
final int[] levelStack = new int[stackSize];
offsetStack[stackPos] = from;
lengthStack[stackPos] = to - from;
levelStack[stackPos++] = 0;
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
final int[] support = stable ? new int[perm.length] : null;
while(stackPos > 0) {
final int first = offsetStack[--stackPos];
final int length = lengthStack[stackPos];
final int level = levelStack[stackPos];
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final float[] k = level < DIGITS_PER_ELEMENT ? a : b; // This is the key array
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(k[perm[i]]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = stable ? 0 : first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
if (stable) {
for(int i = first + length; i-- != first;) support[--pos[(fixFloat(k[perm[i]]) >>> shift & DIGIT_MASK ^ signMask)]] = perm[i];
System.arraycopy(support, 0, perm, first, length);
for(int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (level < maxLevel && count[i] > 1) {
if (count[i] < RADIXSORT_NO_REC_SMALL) insertionSortIndirect(perm, a, b, p, p + count[i]);
else {
offsetStack[stackPos] = p;
lengthStack[stackPos] = count[i];
levelStack[stackPos++] = level + 1;
}
}
p += count[i];
}
java.util.Arrays.fill(count, 0);
}
else {
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
int t = perm[i];
c = (fixFloat(k[t]) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while((d = --pos[c]) > i) {
final int z = t;
t = perm[d];
perm[d] = z;
c = (fixFloat(k[t]) >>> shift & DIGIT_MASK ^ signMask);
}
perm[i] = t;
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < RADIXSORT_NO_REC_SMALL) insertionSortIndirect(perm, a, b, i, i + count[c]);
else {
offsetStack[stackPos] = i;
lengthStack[stackPos] = count[c];
levelStack[stackPos++] = level + 1;
}
}
}
}
}
}
private static void selectionSort(final float[][] a, final int from, final int to, final int level) {
final int layers = a.length;
final int firstLayer = level / DIGITS_PER_ELEMENT;
for(int i = from; i < to - 1; i++) {
int m = i;
for(int j = i + 1; j < to; j++) {
for(int p = firstLayer; p < layers; p++) {
if (a[p][j] < a[p][m]) {
m = j;
break;
}
else if (a[p][j] > a[p][m]) break;
}
}
if (m != i) {
for(int p = layers; p-- != 0;) {
final float u = a[p][i];
a[p][i] = a[p][m];
a[p][m] = u;
}
}
}
}
/** Sorts the specified array of arrays lexicographically using radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implements a lexicographical sorting of the provided arrays. Tuples of elements
* in the same position will be considered a single key, and permuted
* accordingly.
*
* @param a an array containing arrays of equal length to be sorted lexicographically in parallel.
*/
public static void radixSort(final float[][] a) {
radixSort(a, 0, a[0].length);
}
/** Sorts the specified array of arrays lexicographically using radix sort.
*
*
The sorting algorithm is a tuned radix sort adapted from Peter M. McIlroy, Keith Bostic and M. Douglas
* McIlroy, “Engineering radix sort”, Computing Systems, 6(1), pages 5−27 (1993).
*
*
This method implements a lexicographical sorting of the provided arrays. Tuples of elements
* in the same position will be considered a single key, and permuted
* accordingly.
*
* @param a an array containing arrays of equal length to be sorted lexicographically in parallel.
* @param from the index of the first element (inclusive) to be sorted.
* @param to the index of the last element (exclusive) to be sorted.
*/
public static void radixSort(final float[][] a, final int from, final int to) {
if (to - from < RADIXSORT_NO_REC_SMALL) {
selectionSort(a, from, to, 0);
return;
}
final int layers = a.length;
final int maxLevel = DIGITS_PER_ELEMENT * layers - 1;
for(int p = layers, l = a[0].length; p-- != 0;) if (a[p].length != l) throw new IllegalArgumentException("The array of index " + p + " has not the same length of the array of index 0.");
final int stackSize = ((1 << DIGIT_BITS) - 1) * (layers * DIGITS_PER_ELEMENT - 1) + 1;
int stackPos = 0;
final int[] offsetStack = new int[stackSize];
final int[] lengthStack = new int[stackSize];
final int[] levelStack = new int[stackSize];
offsetStack[stackPos] = from;
lengthStack[stackPos] = to - from;
levelStack[stackPos++] = 0;
final int[] count = new int[1 << DIGIT_BITS];
final int[] pos = new int[1 << DIGIT_BITS];
final float[] t = new float[layers];
while(stackPos > 0) {
final int first = offsetStack[--stackPos];
final int length = lengthStack[stackPos];
final int level = levelStack[stackPos];
final int signMask = level % DIGITS_PER_ELEMENT == 0 ? 1 << DIGIT_BITS - 1 : 0;
final float[] k = a[level / DIGITS_PER_ELEMENT]; // This is the key array
final int shift = (DIGITS_PER_ELEMENT - 1 - level % DIGITS_PER_ELEMENT) * DIGIT_BITS; // This is the shift that extract the right byte from a key
// Count keys.
for(int i = first + length; i-- != first;) count[(fixFloat(k[i]) >>> shift & DIGIT_MASK ^ signMask)]++;
// Compute cumulative distribution
int lastUsed = -1;
for (int i = 0, p = first; i < 1 << DIGIT_BITS; i++) {
if (count[i] != 0) lastUsed = i;
pos[i] = (p += count[i]);
}
final int end = first + length - count[lastUsed];
// i moves through the start of each block
for(int i = first, c = -1, d; i <= end; i += count[c], count[c] = 0) {
for(int p = layers; p-- != 0;) t[p] = a[p][i];
c = (fixFloat(k[i]) >>> shift & DIGIT_MASK ^ signMask);
if (i < end) { // When all slots are OK, the last slot is necessarily OK.
while((d = --pos[c]) > i) {
c = (fixFloat(k[d]) >>> shift & DIGIT_MASK ^ signMask);
for(int p = layers; p-- != 0;) {
final float u = t[p];
t[p] = a[p][d];
a[p][d] = u;
}
}
for(int p = layers; p-- != 0;) a[p][i] = t[p];
}
if (level < maxLevel && count[c] > 1) {
if (count[c] < RADIXSORT_NO_REC_SMALL) selectionSort(a, i, i + count[c], level + 1);
else {
offsetStack[stackPos] = i;
lengthStack[stackPos] = count[c];
levelStack[stackPos++] = level + 1;
}
}
}
}
}
/** Shuffles the specified array fragment using the specified pseudorandom number generator.
*
* @param a the 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 int from, final int to, final Random random) {
for(int i = to - from; i-- != 0;) {
final int p = random.nextInt(i + 1);
final float t = a[from + i];
a[from + i] = a[from + p];
a[from + p] = t;
}
return a;
}
/** Shuffles the specified array using the specified pseudorandom number generator.
*
* @param a the array to be shuffled.
* @param random a pseudorandom number generator.
* @return {@code a}.
*/
public static float[] shuffle(final float[] a, final Random random) {
for(int i = a.length; i-- != 0;) {
final int p = random.nextInt(i + 1);
final float t = a[i];
a[i] = a[p];
a[p] = t;
}
return a;
}
/** Reverses the order of the elements in the specified array.
*
* @param a the array to be reversed.
* @return {@code a}.
*/
public static float[] reverse(final float[] a) {
final int length = a.length;
for(int i = length / 2; i-- != 0;) {
final float t = a[length - i - 1];
a[length - i - 1] = a[i];
a[i] = t;
}
return a;
}
/** Reverses the order of the elements in the specified array fragment.
*
* @param a the array to be reversed.
* @param from the index of the first element (inclusive) to be reversed.
* @param to the index of the last element (exclusive) to be reversed.
* @return {@code a}.
*/
public static float[] reverse(final float[] a, final int from, final int to) {
final int length = to - from;
for(int i = length / 2; i-- != 0;) {
final float t = a[from + length - i - 1];
a[from + length - i - 1] = a[from + i];
a[from + i] = t;
}
return a;
}
/** A type-specific content-based hash strategy for arrays. */
private static final class ArrayHashStrategy implements Hash.Strategy, java.io.Serializable {
private static final long serialVersionUID = -7046029254386353129L;
@Override
public int hashCode(final float[] o) { return java.util.Arrays.hashCode(o); }
@Override
public boolean equals(final float[] a, final float[] b) { return java.util.Arrays.equals(a, b); }
}
/** A type-specific content-based hash strategy for arrays.
*
* This hash strategy may be used in custom hash collections whenever keys are
* arrays, and they must be considered equal by content. This strategy
* will handle {@code null} correctly, and it is serializable.
*/
public static final Hash.Strategy HASH_STRATEGY = new ArrayHashStrategy();
}