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Design your implementation of the circular queue. The circular queue is a linear data structure in which the operations are performed based on FIFO (First In First Out) principle and the last position is connected back to the first position to make a circle. It is also called "Ring Buffer".
One of the benefits of the circular queue is that we can make use of the spaces in front of the queue. In a normal queue, once the queue becomes full, we cannot insert the next element even if there is a space in front of the queue. But using the circular queue, we can use the space to store new values.
Your implementation should support following operations:
MyCircularQueue(k): Constructor, set the size of the queue to be k.
Front: Get the front item from the queue. If the queue is empty, return -1.
Rear: Get the last item from the queue. If the queue is empty, return -1.
enQueue(value): Insert an element into the circular queue. Return true if the operation is successful.
deQueue(): Delete an element from the circular queue. Return true if the operation is successful.
isEmpty(): Checks whether the circular queue is empty or not.
isFull(): Checks whether the circular queue is full or not.
Example:
MyCircularQueue circularQueue = new MyCircularQueue(3); // set the size to be 3
circularQueue.enQueue(1); // return true
circularQueue.enQueue(2); // return true
circularQueue.enQueue(3); // return true
circularQueue.enQueue(4); // return false, the queue is full
circularQueue.Rear(); // return 3
circularQueue.isFull(); // return true
circularQueue.deQueue(); // return true
circularQueue.enQueue(4); // return true
circularQueue.Rear(); // return 4
Note:
All values will be in the range of [0, 1000].
The number of operations will be in the range of [1, 1000].
Please do not use the built-in Queue library.
这道题让我们设计一个环形的队列,说是不能使用内置的 queue 类,并且让我们实现一系列的成员函数,如进队,出队,取首尾元素,以及判空,判满等等。那么博主最先想到的就是用一个数组 data 来实现,并且用一个变量 size 来保存我们的环形队列的大小。先来实现最简单的判空和判满函数吧,判空就是判断 data 数组是否为空,判满就是看 data 数组的大小是否等于 size。然后是取首尾元素,需要先对数组判空,然后取首尾元素即可。进队列函数先要判满,然后加入 data 数组,出队列函数,先要判空,然后去掉数组的首元素即可,参见代码如下:
解法一:
class MyCircularQueue {
public:
MyCircularQueue(int k) {
size = k;
}
bool enQueue(int value) {
if (isFull()) return false;
data.push_back(value);
return true;
}
bool deQueue() {
if (isEmpty()) return false;
data.erase(data.begin());
return true;
}
int Front() {
if (isEmpty()) return -1;
return data.front();
}
int Rear() {
if (isEmpty()) return -1;
return data.back();
}
bool isEmpty() {
return data.empty();
}
bool isFull() {
return data.size() >= size;
}
private:
vector<int> data;
int size;
};
Design your implementation of the circular queue. The circular queue is a linear data structure in which the operations are performed based on FIFO (First In First Out) principle and the last position is connected back to the first position to make a circle. It is also called "Ring Buffer".
One of the benefits of the circular queue is that we can make use of the spaces in front of the queue. In a normal queue, once the queue becomes full, we cannot insert the next element even if there is a space in front of the queue. But using the circular queue, we can use the space to store new values.
Your implementation should support following operations:
MyCircularQueue(k): Constructor, set the size of the queue to be k.Front: Get the front item from the queue. If the queue is empty, return -1.Rear: Get the last item from the queue. If the queue is empty, return -1.enQueue(value): Insert an element into the circular queue. Return true if the operation is successful.deQueue(): Delete an element from the circular queue. Return true if the operation is successful.isEmpty(): Checks whether the circular queue is empty or not.isFull(): Checks whether the circular queue is full or not.Example:
Note:
这道题让我们设计一个环形的队列,说是不能使用内置的 queue 类,并且让我们实现一系列的成员函数,如进队,出队,取首尾元素,以及判空,判满等等。那么博主最先想到的就是用一个数组 data 来实现,并且用一个变量 size 来保存我们的环形队列的大小。先来实现最简单的判空和判满函数吧,判空就是判断 data 数组是否为空,判满就是看 data 数组的大小是否等于 size。然后是取首尾元素,需要先对数组判空,然后取首尾元素即可。进队列函数先要判满,然后加入 data 数组,出队列函数,先要判空,然后去掉数组的首元素即可,参见代码如下:
解法一:
做完上面的方法有没有一种感觉,这跟环形 Circular 有毛线关系,还有题目要求中的第二段话里的“我们可以使用队列前面的空间”,完全没有用到啊。其实上面的解法并不是本题真正想要考察的内容,我们要用上环形 Circular 的性质,之前我们貌似应该做过环形数组的题目吧,提到环形数组,博主最先想到的就是坐标加1,再对数组长度取余。这是数组能够环形的关键,那么这里也一样,我们除了使用 size 来记录环形队列的最大长度之外,还要使用三个变量,head,tail,cnt,分别来记录队首位置,队尾位置,和当前队列中数字的个数,这里我们将head初始化为 0,tail初始化为 k-1,head 是指向数组范围内的起始位置,tail 指向数组范围内的结束位置。那么在 Front() 函数,由于我们要返回起始位置的数字,为了不越界,进行环形走位,还要对 size 取余,于是就变成了 head % size,同理,对于 Rear() 函数,我们要返回结束位置的数字,为了不越界,并且环形走位,tail 要先加上size,再对 size 取余,于是就变成了 (tail+size) % size。
还是从简单的做起,判空就看当前个数 cnt 是否为0,判满就看当前个数 cnt 是否等于 size。接下来取首尾元素,先进行判空,然后根据 head 和tail 取即可,记得使用上循环数组的性质,要对 size 取余。再来看进队列函数,先进行判满,tail 要移动到下一位,为了避免越界,我们使用环形数组的经典操作,加1之后对长度取余,然后将新的数字加到当前的tail位置,cnt 再自增1即可。同样,出队列函数先进行判空,队首位置 head 要向后移动一位,同样进行加1之后对长度取余的操作,到这里就可以了,不用真正的去删除数字,因为 head 和 tail 限定了我们的当前队列的范围,然后 cnt 自减1,参见代码如下:
解法二:
论坛上还见到了使用链表来做的解法,由于博主比较抵触在解法中新建class,所以这里就不贴了,可以参见这个帖子。
类似题目:
Design Circular Deque
参考资料:
https://leetcode.com/problems/design-circular-queue/
https://leetcode.com/problems/design-circular-queue/discuss/149420/Concise-Java-using-array
https://leetcode.com/problems/design-circular-queue/discuss/162759/JAVA-Pass-All-Test-Cases-100-O(1)
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