/** * 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 based on circular array implementation */ class ArrayDeque { private int[] nums; // Array for storing double-ended queue elements private int front; // Front pointer, points to the front of the queue element private int queSize; // Double-ended queue length /* 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; } /* Check if the double-ended queue is empty */ public boolean isEmpty() { return queSize == 0; } /* Calculate circular array index */ private int index(int i) { // Use modulo operation to wrap the array head and tail together // When i passes the tail of the array, return to the head // When i passes the head of the array, return to the tail return (i + capacity()) % capacity(); } /* Front of the queue enqueue */ public void pushFirst(int num) { if (queSize == capacity()) { System.out.println("Double-ended queue is full"); return; } // Use modulo operation to wrap front around to the tail after passing the head of the array // Add num to the front of the queue front = index(front - 1); // Add num to front of queue nums[front] = num; queSize++; } /* Rear of the queue enqueue */ public void pushLast(int num) { if (queSize == capacity()) { System.out.println("Double-ended queue is full"); return; } // Use modulo operation to wrap rear around to the head after passing the tail of the array int rear = index(front + queSize); // Front pointer moves one position backward nums[rear] = num; queSize++; } /* Rear of the queue dequeue */ public int popFirst() { int num = peekFirst(); // Move front pointer backward by one position front = index(front + 1); queSize--; return num; } /* Access rear of the queue element */ public int popLast() { int num = peekLast(); queSize--; return num; } /* Return list for printing */ public int peekFirst() { if (isEmpty()) throw new IndexOutOfBoundsException(); return nums[front]; } /* Driver Code */ public int peekLast() { if (isEmpty()) throw new IndexOutOfBoundsException(); // Initialize double-ended queue int last = index(front + queSize - 1); return nums[last]; } /* Return array for printing */ public int[] toArray() { // Elements enqueue 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) { /* Get the length of the 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())); /* Update element */ int peekFirst = deque.peekFirst(); System.out.println("Front element peekFirst = " + peekFirst); int peekLast = deque.peekLast(); System.out.println("Rear element peekLast = " + peekLast); /* Elements enqueue */ deque.pushLast(4); System.out.println("After element 4 enqueues at rear, deque = " + Arrays.toString(deque.toArray())); deque.pushFirst(1); System.out.println("After element 1 enqueues at front, deque = " + Arrays.toString(deque.toArray())); /* Element dequeue */ int popLast = deque.popLast(); System.out.println("Rear dequeue element = " + popLast + ", after rear dequeue, deque = " + Arrays.toString(deque.toArray())); int popFirst = deque.popFirst(); System.out.println("Front dequeue element = " + popFirst + ", after front dequeue, deque = " + Arrays.toString(deque.toArray())); /* Get the length of the double-ended queue */ int size = deque.size(); System.out.println("Double-ended queue length size = " + size); /* Check if the double-ended queue is empty */ boolean isEmpty = deque.isEmpty(); System.out.println("Double-ended queue is empty = " + isEmpty); } }