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Open-source constraint solver.
/*
* This file is part of choco-solver, http://choco-solver.org/
*
* Copyright (c) 2020, IMT Atlantique. All rights reserved.
*
* Licensed under the BSD 4-clause license.
*
* See LICENSE file in the project root for full license information.
*/
package org.chocosolver.util.objects;
/**
* A fix sized circular queue optimized for removing first and last elements.
* Some few (essential regarding the usage) methods are implemented.
*
* Be aware of the size computation: the modulo operation is not efficient in java.
* On the other hand, the modulo of powers of 2 can alternatively be expressed as a bitwise AND operation:
*
* x % 2n == x & (2n - 1)
*
* That is why the size of the data is automatically set to the closest greater powers of 2 value.
*
* @author Charles Prud'homme
* @since 29 sept. 2010
*/
public class IntCircularQueue {
private int[] elementData;
// head points to the first logical element in the array, and
// tail points to the element following the last. This means
// that the list is empty when head == tail. It also means
// that the elementData array has to have an extra space in it.
private int head = 0;
private int tail = 0;
// Strictly speaking, we don't need to keep a handle to size,
// as it can be calculated programmatically, but keeping it
// makes the algorithms faster.
private int size = 0;
private int capacity;
/**
* Compute the powers of 2 value immedialty greater to size
*
* @param size the curent number of element
* @return the powers of 2 value immedialty greater to size
*/
private static int closestGreater2n(int size) {
if (size == 0) return 2;
int _size = Integer.highestOneBit(size) << 1;
assert (_size >= size);
return _size;
}
@SuppressWarnings({"unchecked"})
public IntCircularQueue(int size) {
size = closestGreater2n(size);
elementData = new int[size];
capacity = size;
}
// The convert() method takes a logical index (as if head was
// always 0) and calculates the index within elementData
private int convert(int base, int delta) {
return (base + delta) & (capacity - 1);
}
public boolean isEmpty() {
return head == tail;
}
public int size() {
return size;
}
public void clear() {
head = tail = size = 0;
}
public int get(int index) {
return elementData[convert(index, head)];
}
public boolean addFirst(int e) {
// elements[head = (head - 1) & (elements.length - 1)] = e;
// if (head == tail)
// doubleCapacity();
elementData[head = convert(head, -1)] = e;
size++;
if (head == tail)
doubleCapacity();
return true;
}
public boolean addLast(int e) {
// elements[tail] = e;
// if ( (tail = (tail + 1) & (elements.length - 1)) == head)
// doubleCapacity();
elementData[tail] = e;
size++;
if ((tail = convert(tail, 1)) == head)
doubleCapacity();
return true;
}
/**
* {@inheritDoc}
* This method is the main reason we re-wrote the class.
* It is optimized for removing first and last elements
* but also allows you to remove in the middle of the list.
*/
public int pollFirst() {
int pos = convert(head, 0);
// an interesting application of try/finally is to avoid
// having to use local variables
int tmp = elementData[pos];
// optimized for FIFO access, i.e. adding to back and
// removing from front
if (pos == head) {
head = convert(head, 1);
}
size--;
return tmp;
}
/**
* {@inheritDoc}
* This method is the main reason we re-wrote the class.
* It is optimized for removing first and last elements
* but also allows you to remove in the middle of the list.
*/
public int pollLast() {
int pos = convert(tail, -1);
// an interesting application of try/finally is to avoid
// having to use local variables
int tmp = elementData[pos];
// optimized for FIFO access, i.e. adding to back and
// removing from front
tail = pos;
size--;
return tmp;
}
/**
* Double the capacity of this deque. Call only when full, i.e.,
* when head and tail have wrapped around to become equal.
*/
private void doubleCapacity() {
assert head == tail;
int p = head;
int n = capacity;
int r = n - p; // number of elements to the right of p
int newCapacity = n << 1;
if (newCapacity < 0)
throw new IllegalStateException("Sorry, deque too big");
int[] a = new int[newCapacity];
System.arraycopy(elementData, p, a, 0, r);
System.arraycopy(elementData, 0, a, r, p);
elementData = a;
head = 0;
tail = n;
capacity = newCapacity;
}
}