hello-algo/en/codes/java/chapter_stack_and_queue/array_deque.java
Yudong Jin 1c0f350ad6
translation: Add Python and Java code for EN version (#1345)
* Add the intial translation of code of all the languages

* test

* revert

* Remove

* Add Python and Java code for EN version
2024-05-06 05:21:51 +08:00

151 lines
4.7 KiB
Java

/**
* File: array_deque.java
* Created Time: 2023-02-16
* Author: krahets (krahets@163.com), FangYuan33 (374072213@qq.com)
*/
package chapter_stack_and_queue;
import java.util.*;
/* Double-ended queue class based on circular array */
class ArrayDeque {
private int[] nums; // Array used to store elements of the double-ended queue
private int front; // Front pointer, pointing to the front element
private int queSize; // Length of the double-ended queue
/* Constructor */
public ArrayDeque(int capacity) {
this.nums = new int[capacity];
front = queSize = 0;
}
/* Get the capacity of the double-ended queue */
public int capacity() {
return nums.length;
}
/* Get the length of the double-ended queue */
public int size() {
return queSize;
}
/* Determine if the double-ended queue is empty */
public boolean isEmpty() {
return queSize == 0;
}
/* Calculate circular array index */
private int index(int i) {
// Implement circular array by modulo operation
// When i exceeds the tail of the array, return to the head
// When i exceeds the head of the array, return to the tail
return (i + capacity()) % capacity();
}
/* Front enqueue */
public void pushFirst(int num) {
if (queSize == capacity()) {
System.out.println("Double-ended queue is full");
return;
}
// Move the front pointer one position to the left
// Implement front crossing the head of the array to return to the tail by modulo operation
front = index(front - 1);
// Add num to the front
nums[front] = num;
queSize++;
}
/* Rear enqueue */
public void pushLast(int num) {
if (queSize == capacity()) {
System.out.println("Double-ended queue is full");
return;
}
// Calculate rear pointer, pointing to rear index + 1
int rear = index(front + queSize);
// Add num to the rear
nums[rear] = num;
queSize++;
}
/* Front dequeue */
public int popFirst() {
int num = peekFirst();
// Move front pointer one position backward
front = index(front + 1);
queSize--;
return num;
}
/* Rear dequeue */
public int popLast() {
int num = peekLast();
queSize--;
return num;
}
/* Access front element */
public int peekFirst() {
if (isEmpty())
throw new IndexOutOfBoundsException();
return nums[front];
}
/* Access rear element */
public int peekLast() {
if (isEmpty())
throw new IndexOutOfBoundsException();
// Calculate rear element index
int last = index(front + queSize - 1);
return nums[last];
}
/* Return array for printing */
public int[] toArray() {
// Only convert elements within valid length range
int[] res = new int[queSize];
for (int i = 0, j = front; i < queSize; i++, j++) {
res[i] = nums[index(j)];
}
return res;
}
}
public class array_deque {
public static void main(String[] args) {
/* Initialize double-ended queue */
ArrayDeque deque = new ArrayDeque(10);
deque.pushLast(3);
deque.pushLast(2);
deque.pushLast(5);
System.out.println("Double-ended queue deque = " + Arrays.toString(deque.toArray()));
/* Access element */
int peekFirst = deque.peekFirst();
System.out.println("Front element peekFirst = " + peekFirst);
int peekLast = deque.peekLast();
System.out.println("Back element peekLast = " + peekLast);
/* Element enqueue */
deque.pushLast(4);
System.out.println("Element 4 enqueued at the tail, deque = " + Arrays.toString(deque.toArray()));
deque.pushFirst(1);
System.out.println("Element 1 enqueued at the head, deque = " + Arrays.toString(deque.toArray()));
/* Element dequeue */
int popLast = deque.popLast();
System.out.println("Deque tail element = " + popLast + ", after dequeuing from the tail" + Arrays.toString(deque.toArray()));
int popFirst = deque.popFirst();
System.out.println("Deque front element = " + popFirst + ", after dequeuing from the front" + Arrays.toString(deque.toArray()));
/* Get the length of the double-ended queue */
int size = deque.size();
System.out.println("Length of the double-ended queue size = " + size);
/* Determine if the double-ended queue is empty */
boolean isEmpty = deque.isEmpty();
System.out.println("Is the double-ended queue empty = " + isEmpty);
}
}