Suppose we have two stacks and no other temporary variable.
Is to possible to "construct" a queue data structure using only the two stacks?
Let queue to be implemented be q and stacks used to implement q be stack1 and stack2.
q can be implemented in two ways:
Method 1 (By making enQueue operation costly)
This method makes sure that newly entered element is always at the top of stack 1, so that deQueue operation just pops from stack1. To put the element at top of stack1, stack2 is used.
Method 2 (By making deQueue operation costly)
In this method, in en-queue operation, the new element is entered at the top of stack1. In de-queue operation, if stack2 is empty then all the elements are moved to stack2 and finally top of stack2 is returned.
Method 2 is definitely better than method 1. Method 1 moves all the elements twice in enQueue operation, while method 2 (in deQueue operation) moves the elements once and moves elements only if stack2 empty.
Two stacks in the queue are defined as stack1 and stack2.
Enqueue: The euqueued elements are always pushed into stack1
Dequeue: The top of stack2 can be popped out since it is the first element inserted into queue when stack2 is not empty. When stack2 is empty, we pop all elements from stack1 and push them into stack2 one by one. The first element in a queue is pushed into the bottom of stack1. It can be popped out directly after popping and pushing operations since it is on the top of stack2.
The following is same C++ sample code:
This solution is borrowed from my blog. More detailed analysis with step-by-step operation simulations is available in my blog webpage.
Keep 2 stacks, let's call them
Using this method, each element will be in each stack exactly once - meaning each element will be pushed twice and popped twice, giving amortized constant time operations.
Here's an implementation in Java:
For every enqueue operation, we add to the top of the stack1. For every dequeue, we empty the content's of stack1 into stack2, and remove the element at top of the stack.Time complexity is O(n) for dequeue, as we have to copy the stack1 to stack2. time complexity of enqueue is the same as a regular stack
The time complexities would be worse, though. A good queue implementation does everything in constant time.
Not sure why my answer has been downvoted here. If we program, we care about time complexity, and using two standard stacks to make a queue is inefficient. It's a very valid and relevant point. If someone else feels the need to downvote this more, I would be interested to know why.
A little more detail: on why using two stacks is worse than just a queue: if you use two stacks, and someone calls dequeue while the outbox is empty, you need linear time to get to the bottom of the inbox (as you can see in Dave's code).
You can implement a queue as a singly-linked list (each element points to the next-inserted element), keeping an extra pointer to the last-inserted element for pushes (or making it a cyclic list). Implementing queue and dequeue on this data structure is very easy to do in constant time. That's worst-case constant time, not amortized. And, as the comments seem to ask for this clarification, worst-case constant time is strictly better than amortized constant time.
You can even simulate a queue using only one stack. The second (temporary) stack can be simulated by the call stack of recursive calls to the insert method.
The principle stays the same when inserting a new element into the queue:
A Queue class using only one Stack, would be as follows:
You'll have to pop everything off the stack to get the bottom element and then put them all back on for every "dequeue" operation.
Brian's answer is the classically correct one. In fact, this is one of the best ways to implement persistent functional queues with amortized constant time. This is so because in functional programming we have a very nice persistent stack (linked list). By using two lists in the way Brian describes, it is possible to implement a fast queue without requiring an obscene amount of copying.
As a minor aside, it is possible to prove that you can do anything with two stacks. This is because a two-stack operation completely fulfills the definition of a universal Turing machine. However, as Forth demonstrates, it isn't always easy. :-)
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