hello-algo/en/codes/cpp/chapter_stack_and_queue/array_deque.cpp

/**
 * File: array_deque.cpp
 * Created Time: 2023-03-02
 * Author: krahets (krahets@163.com)
 */

#include "../utils/common.hpp"

/* Double-ended queue class based on circular array */
class ArrayDeque {
  private:
    vector<int> nums; // Array used to store elements of the double-ended queue
    int front;        // Front pointer, pointing to the front element
    int queSize;      // Length of the double-ended queue

  public:
    /* Constructor */
    ArrayDeque(int capacity) {
        nums.resize(capacity);
        front = queSize = 0;
    }

    /* Get the capacity of the double-ended queue */
    int capacity() {
        return nums.size();
    }

    /* Get the length of the double-ended queue */
    int size() {
        return queSize;
    }

    /* Determine if the double-ended queue is empty */
    bool isEmpty() {
        return queSize == 0;
    }

    /* Calculate circular array index */
    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 */
    void pushFirst(int num) {
        if (queSize == capacity()) {
            cout << "Double-ended queue is full" << endl;
            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 */
    void pushLast(int num) {
        if (queSize == capacity()) {
            cout << "Double-ended queue is full" << endl;
            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 */
    int popFirst() {
        int num = peekFirst();
        // Move front pointer one position backward
        front = index(front + 1);
        queSize--;
        return num;
    }

    /* Rear dequeue */
    int popLast() {
        int num = peekLast();
        queSize--;
        return num;
    }

    /* Access front element */
    int peekFirst() {
        if (isEmpty())
            throw out_of_range("Double-ended queue is empty");
        return nums[front];
    }

    /* Access rear element */
    int peekLast() {
        if (isEmpty())
            throw out_of_range("Double-ended queue is empty");
        // Calculate rear element index
        int last = index(front + queSize - 1);
        return nums[last];
    }

    /* Return array for printing */
    vector<int> toVector() {
        // Only convert elements within valid length range
        vector<int> res(queSize);
        for (int i = 0, j = front; i < queSize; i++, j++) {
            res[i] = nums[index(j)];
        }
        return res;
    }
};

/* Driver Code */
int main() {
    /* Initialize double-ended queue */
    ArrayDeque *deque = new ArrayDeque(10);
    deque->pushLast(3);
    deque->pushLast(2);
    deque->pushLast(5);
    cout << "Double-ended queue deque = ";
    printVector(deque->toVector());

    /* Access element */
    int peekFirst = deque->peekFirst();
    cout << "Front element peekFirst = " << peekFirst << endl;
    int peekLast = deque->peekLast();
    cout << "Back element peekLast = " << peekLast << endl;

    /* Element enqueue */
    deque->pushLast(4);
    cout << "Element 4 enqueued at the tail, deque = ";
    printVector(deque->toVector());
    deque->pushFirst(1);
    cout << "Element 1 enqueued at the head, deque = ";
    printVector(deque->toVector());

    /* Element dequeue */
    int popLast = deque->popLast();
    cout << "Deque tail element = " << popLast << ", after dequeuing from the tail";
    printVector(deque->toVector());
    int popFirst = deque->popFirst();
    cout << "Deque front element = " << popFirst << ", after dequeuing from the front";
    printVector(deque->toVector());

    /* Get the length of the double-ended queue */
    int size = deque->size();
    cout << "Length of the double-ended queue size = " << size << endl;

    /* Determine if the double-ended queue is empty */
    bool isEmpty = deque->isEmpty();
    cout << "Is the double-ended queue empty = " << boolalpha << isEmpty << endl;
    return 0;
}
Add the initial EN translation for C++ code (#1346) 6 months ago			`/**`
			`* File: array_deque.cpp`
			`* Created Time: 2023-03-02`
			`* Author: krahets (krahets@163.com)`
			`*/`

			`#include "../utils/common.hpp"`

			`/* Double-ended queue class based on circular array */`
			`class ArrayDeque {`
			`private:`
			`vector<int> nums; // Array used to store elements of the double-ended queue`
			`int front; // Front pointer, pointing to the front element`
			`int queSize; // Length of the double-ended queue`

			`public:`
			`/* Constructor */`
			`ArrayDeque(int capacity) {`
			`nums.resize(capacity);`
			`front = queSize = 0;`
			`}`

			`/* Get the capacity of the double-ended queue */`
			`int capacity() {`
			`return nums.size();`
			`}`

			`/* Get the length of the double-ended queue */`
			`int size() {`
			`return queSize;`
			`}`

			`/* Determine if the double-ended queue is empty */`
			`bool isEmpty() {`
			`return queSize == 0;`
			`}`

			`/* Calculate circular array index */`
			`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 */`
			`void pushFirst(int num) {`
			`if (queSize == capacity()) {`
			`cout << "Double-ended queue is full" << endl;`
			`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 */`
			`void pushLast(int num) {`
			`if (queSize == capacity()) {`
			`cout << "Double-ended queue is full" << endl;`
			`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 */`
			`int popFirst() {`
			`int num = peekFirst();`
			`// Move front pointer one position backward`
			`front = index(front + 1);`
			`queSize--;`
			`return num;`
			`}`

			`/* Rear dequeue */`
			`int popLast() {`
			`int num = peekLast();`
			`queSize--;`
			`return num;`
			`}`

			`/* Access front element */`
			`int peekFirst() {`
			`if (isEmpty())`
			`throw out_of_range("Double-ended queue is empty");`
			`return nums[front];`
			`}`

			`/* Access rear element */`
			`int peekLast() {`
			`if (isEmpty())`
			`throw out_of_range("Double-ended queue is empty");`
			`// Calculate rear element index`
			`int last = index(front + queSize - 1);`
			`return nums[last];`
			`}`

			`/* Return array for printing */`
			`vector<int> toVector() {`
			`// Only convert elements within valid length range`
			`vector<int> res(queSize);`
			`for (int i = 0, j = front; i < queSize; i++, j++) {`
			`res[i] = nums[index(j)];`
			`}`
			`return res;`
			`}`
			`};`

			`/* Driver Code */`
			`int main() {`
			`/* Initialize double-ended queue */`
			`ArrayDeque *deque = new ArrayDeque(10);`
			`deque->pushLast(3);`
			`deque->pushLast(2);`
			`deque->pushLast(5);`
			`cout << "Double-ended queue deque = ";`
			`printVector(deque->toVector());`

			`/* Access element */`
			`int peekFirst = deque->peekFirst();`
			`cout << "Front element peekFirst = " << peekFirst << endl;`
			`int peekLast = deque->peekLast();`
			`cout << "Back element peekLast = " << peekLast << endl;`

			`/* Element enqueue */`
			`deque->pushLast(4);`
			`cout << "Element 4 enqueued at the tail, deque = ";`
			`printVector(deque->toVector());`
			`deque->pushFirst(1);`
			`cout << "Element 1 enqueued at the head, deque = ";`
			`printVector(deque->toVector());`

			`/* Element dequeue */`
			`int popLast = deque->popLast();`
			`cout << "Deque tail element = " << popLast << ", after dequeuing from the tail";`
			`printVector(deque->toVector());`
			`int popFirst = deque->popFirst();`
			`cout << "Deque front element = " << popFirst << ", after dequeuing from the front";`
			`printVector(deque->toVector());`

			`/* Get the length of the double-ended queue */`
			`int size = deque->size();`
			`cout << "Length of the double-ended queue size = " << size << endl;`

			`/* Determine if the double-ended queue is empty */`
			`bool isEmpty = deque->isEmpty();`
			`cout << "Is the double-ended queue empty = " << boolalpha << isEmpty << endl;`
			`return 0;`
			`}`