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I came across this question: Implement a queue in which push_rear(), pop_front() and get_min() are all constant time operations.

I initially thought of using a min-heap data structure which has O(1) complexity for a get_min(). But push_rear() and pop_front() would be O(log(n)).

Does anyone know what would be the best way to implement such a queue which has O(1) push(), pop() and min()?

I googled about this, and wanted to point out this Algorithm Geeks thread. But it seems that none of the solutions follow constant time rule for all 3 methods: push(), pop() and min().

Thanks for all the suggestions.

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Are you okay with amortized O(1) time bounds for all of this, or do these have to be worst-case time bounds? –  templatetypedef Jan 26 '11 at 7:17
I am not sure, its a Google interview question, I saw it initially at careercup.com/question?id=7263132 .... It feels like that the question meant worst-case time bounds. Does it seem impossible? –  bits Jan 26 '11 at 7:23
@bits- No, it definitely seems possible, and I'm cranking away at it right now. :-) I was looking at using Cartesian trees to do this - this gives you O(1) amortized insertion and O(1) lookup, and I almost got O(1) amortized deletion working as well. But, if you're looking for worst-case bounds, I'll change my approach. –  templatetypedef Jan 26 '11 at 7:27
ok, now looking at Kdoto's answer below; I am now certain that worst-case bounds might not be a possible thing. So maybe Googlers must be looking for Amortized O(1). EDIT: ok, as templatetypedef pointer out in comments of Kdoto's answer, the proof isn't correct. Noted. –  bits Jan 26 '11 at 7:30
Don't be so certain, my proof was not correct. However I don't think that O(1) has been found for all of the operations, amortized or not. And I suspect that it is not possible. –  Olhovsky Jan 26 '11 at 7:35

9 Answers 9

up vote 62 down vote accepted

You can implement a stack with O(1) pop(), push() and get_min(): just store the current minimum together with each element. So, for example, the stack [4,2,5,1] (1 on top) becomes [(4,4), (2,2), (5,2), (1,1)].

Then you can use two stacks to implement the queue. Push to one stack, pop from another one; if the second stack is empty during the pop, move all elements from the first stack to the second one.

E.g for a pop request, moving all the elements from first stack [(4,4), (2,2), (5,2), (1,1)], the second stack would be [(1,1), (5,1), (2,1), (4,1)]. and now return top element from second stack.

To find the minimum element of the queue, look at the smallest two elements of the individual min-stacks, then take the minimum of those two values. (Of course, there's some extra logic here is case one of the stacks is empty, but that's not too hard to work around).

It will have O(1) get_min() and push() and amortized O(1) pop().

share|improve this answer
How does using two stacks to implement the queue give you amortized O(1) pop? –  templatetypedef Jan 26 '11 at 7:37
@template Each element can be moved from one stack to another only once. –  adamax Jan 26 '11 at 7:39
If you store the "current minimum together with the elements", and you pop the minimum from the queue, how would you know what the new minimum is, in O(1) time? –  Olhovsky Jan 26 '11 at 7:53
@adamax I can't understand 3rd part. How your minimum is working. As you see there are too many comments here. Why just not provide a little example, with your algorithms steps. It will help understand your algorithm. –  UmmaGumma Jan 26 '11 at 21:01
@Ashot No, you pop the element 2 from the first stack, push it to the second stack, it becomes [(2,2)]. Then you pop element 5, push it to the second stack, it becomes [(2,2), (5,2)]. Etc. –  adamax Jan 26 '11 at 21:34

Okay - I think I have an answer that gives you all of these operations in amortized O(1), meaning that any one operation could take up to O(n), but any sequence of n operations takes O(1) time per operation.

The idea is to store your data as a Cartesian tree. This is a binary tree obeying the min-heap property (each node is no bigger than its children) and is ordered in a way such that an inorder traversal of the nodes gives you back the nodes in the same order in which they were added. For example, here's a Cartesian tree for the sequence 2 1 4 3 5:

     /   \
    2      3
          / \
         4   5

It is possible to insert an element into a Cartesian tree in O(1) amortized time using the following procedure. Look at the right spine of the tree (the path from the root to the rightmost leaf formed by always walking to the right). Starting at rightmost node, scan upward along this path until you find the first node smaller than the node you're inserting.
Change that node so that its right child is this new node, then make that node's former right child the left child of the node you just added. For example, suppose that we want to insert another copy of 2 into the above tree. We walk up the right spine past the 5 and the 3, but stop below the 1 because 1 < 2. We then change the tree to look like this:

     /   \
    2      2
        / \
       4   5

Notice that an inorder traversal gives 2 1 4 3 5 2, which is the sequence in which we added the values.

This runs in amortized O(1) because we can create a potential function equal to the number of nodes in the right spine of the tree. The real time required to insert a node is 1 plus the number of nodes in the spine we consider (call this k). Once we find the place to insert the node, the size of the spine shrinks by length k - 1, since each of the k nodes we visited are no longer on the right spine, and the new node is in its place. This gives an amortized cost of 1 + k + (1 - k) = 2 = O(1), for the amortized O(1) insert. As another way of thinking about this, once a node has been moved off the right spine, it's never part of the right spine again, and so we will never have to move it again. Since each of the n nodes can be moved at most once, this means that n insertions can do at most n moves, so the total runtime is at most O(n) for an amortized O(1) per element.

To do a dequeue step, we simply remove the leftmost node from the Cartesian tree. If this node is a leaf, we're done. Otherwise, the node can only have one child (the right child), and so we replace the node with its right child. Provided that we keep track of where the leftmost node is, this step takes O(1) time. However, after removing the leftmost node and replacing it with its right child, we might not know where the new leftmost node is. To fix this, we simply walk down the left spine of the tree starting at the new node we just moved to the leftmost child. I claim that this still runs in O(1) amortized time. To see this, I claim that a node is visited at most once during any one of these passes to find the leftmost node. To see this, note that once a node has been visited this way, the only way that we could ever need to look at it again would be if it were moved from a child of the leftmost node to the leftmost node. But all the nodes visited are parents of the leftmost node, so this can't happen. Consequently, each node is visited at most once during this process, and the pop runs in O(1).

We can do find-min in O(1) because the Cartesian tree gives us access to the smallest element of the tree for free; it's the root of the tree.

Finally, to see that the nodes come back in the same order in which they were inserted, note that a Cartesian tree always stores its elements so that an inorder traversal visits them in sorted order. Since we always remove the leftmost node at each step, and this is the first element of the inorder traversal, we always get the nodes back in the order in which they were inserted.

In short, we get O(1) amortized push and pop, and O(1) worst-case find-min.

If I can come up with a worst-case O(1) implementation, I'll definitely post it. This was a great problem; thanks for posting it!

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I'm still considering whether your pop is really amortized O(1). I'll be sure to upvote this answer when I confirm this. It would be nice if someone else helped to verify this answer also. –  Olhovsky Jan 26 '11 at 8:14
@Kdoto- Come to think of it, you need each node to store a parent pointer if you want to get the O(1) amortized dequeue, since that way when you remove a leaf you can update the pointer to the leftmost node in the tree in worst-case O(1). –  templatetypedef Jan 26 '11 at 8:15

Ok, here is one solution.

First we need some stuff which provide push_back(),push_front(),pop_back() and pop_front() in 0(1). It's easy to implement with array and 2 iterators. First iterator will point to front, second to back. Let's call such stuff deque.

Here is pseudo-code:

class MyQueue//Our data structure
    deque D;//We need 2 deque objects
    deque Min;

    push(element)//pushing element to MyQueue
        while(Min.is_not_empty() and Min.back()>element)
    pop()//poping MyQueue
         if(Min.front()==D.front() )

         return Min.front();


Example let's push numbers [12,5,10,7,11,19] and to our MyQueue

1)pushing 12

D [12]

2)pushing 5

Min[5] //5>12 so 12 removed

3)pushing 10


4)pushing 7


6)pushing 11


7)pushing 19


Now let's call pop_front()

we got


The minimum is 5

Let's call pop_front() again

Explanation: pop_front will remove 5 from D, but it will pop front element of Min too, because it equals to D's front element (5).


And minimum is 7. :)

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It seems that if you push 2, 3, 1 then get_min returns 2 instead of 1. –  adamax Jan 26 '11 at 22:55
@adamax Oops :). You got me. I corrected push(). Now it's working correct, but not in 0(1). It is working in amortized O(1) like yours :). –  UmmaGumma Jan 26 '11 at 23:09
This should be the correct solution. Thank you. –  Ivan Z. Siu Mar 8 '14 at 23:05
@UmmaGumma,good job! Minor correction though, its 5<12 when 12 is popped off the stack. –  KodeSeeker Oct 20 '14 at 5:18

If you don't mind storing a bit of extra data, it should be trivial to store the minimum value. Push and pop can update the value if the new or removed element is the minimum, and returning the minimum value is as simple as getting the value of the variable.

This is assuming that get_min() does not change the data; if you would rather have something like pop_min() (i.e. remove the minimum element), you can simply store a pointer to the actual element and the element preceding it (if any), and update those accordingly with push_rear() and pop_front() as well.

Edit after comments:

Obviously this leads to O(n) push and pop in the case that the minimum changes on those operations, and so does not strictly satisfy the requirements.

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Doesn't this give you an O(n) pop, since you have to scan all the elements to find the new min? –  templatetypedef Jan 26 '11 at 7:13
I think get_min() doesn't actually pop the data. But pop_front() does pop the data. Lets say the front node is also the min node, so its popped. Now how can we maintain the min property in constant time? –  bits Jan 26 '11 at 7:15
Ah, good call...though you're right, @bits, it's only O(n) in the case that you push a new minimum or pop your current minimum. If it has to be worst-case O(1), I don't know that it's possible, but I would love to see otherwise. –  ajm Jan 26 '11 at 7:27

Use one deque (A) to store the elements and another deque (B) to store the minimums.

When x is enqueued, push_back it to A and keep pop_backing B until the back of B is smaller than x, then push_back x to B.

when dequeuing A, pop_front A as return value, and if it is equal to the front of B, pop_front B as well.

when getting the minimum of A, use the front of B as return value.

dequeue and getmin are obviously O(1). For the enqueue operation, consider the push_back of n elements. There are n push_back to A, n push_back to B and at most n pop_back of B because each element will either stay in B or being popped out once from B. Over all there are O(3n) operations and therefore the amortized cost is O(1) as well for enqueue.

Lastly the reason this algorithm works is that when you enqueue x to A, if there are elements in B that are larger than x, they will never be minimums now because x will stay in the queue A longer than any elements in B (a queue is FIFO). Therefore we need to pop out elements in B (from the back) that are larger than x before we push x into B.

from collections import deque

class MinQueue(deque):
    def __init__(self):
        self.minq = deque()

    def push_rear(self, x):
        while len(self.minq) > 0 and self.minq[-1] > x:

    def pop_front(self):
        x = self.popleft()
        if self.minq[0] == x:

    def get_min(self):
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Solutions to this question, including code, can be found here: http://discuss.joelonsoftware.com/default.asp?interview.11.742223.32

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Links to outside pages are unhelpful. What if the link breaks? Also: the page you link too is just a long discussion. A good answer would capture the important elements of that discussion and leave out the fluff. –  Richard Feb 19 '14 at 15:51

You Can actually use a LinkedList to maintain the Queue.

Each element in LinkedList will be of Type

class LinkedListElement
   LinkedListElement next;
   int currentMin;

You can have two pointers One points to the Start and the other points to the End.

If you add an element to the start of the Queue. Examine the Start pointer and the node to insert. If node to insert currentmin is less than start currentmin node to insert currentmin is the minimum. Else update the currentmin with start currentmin.

Repeat the same for enque.

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We know that push and pop are constant time operations [O(1) to be precise].

But when we think of get_min()[i.e to find the current minimum number in the queue] generally the first thing that comes to mind is searching the whole queue every time the request for the minimum element is made. But this will never give the constant time operation, which is the main aim of the problem.

This is generally asked very frequently in the interviews, so you must know the trick

To do this we have to use two more queues which will keep the track of minimum element and we have to go on modifying these 2 queues as we do push and pop operations on the queue so that minimum element is obtained in O(1) time.

Here is the self-descriptive sudo code based on the above approach mentioned.

    Queue q, minq1, minq2;
    void push(int a)
        if(minq1.empty) minq1.push(a);
          while(!minq1.empty && minq1.top < =a) minq2.push(minq1.pop());
          while(!minq1.empty) minq1.pop();
        //mirror if(isMinq1Current) branch. 

    int pop()
      int a = q.pop();
        if(a==minq1.top) minq1.pop();
        //mirror if(isMinq1Current) branch.    
    return a;

I picked this answer from this site http://www.mycareerstack.com

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#include <iostream>
#include <queue>
#include <deque>
using namespace std;

queue<int> main_queue;
deque<int> min_queue;

void clearQueue(deque<int> &q)
  while(q.empty() == false) q.pop_front();

void PushRear(int elem)

  if(min_queue.empty() == false && elem < min_queue.front())

  while(min_queue.empty() == false && elem < min_queue.back())


void PopFront() 
  int elem = main_queue.front();

  if (elem == min_queue.front())

int GetMin() 
  return min_queue.front(); 

int main()


  return 0;
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It's not good to post code without an accompanying, clearly-stated explanation of why the code is right. –  Richard Feb 19 '14 at 15:49
That code is very self explanatory. If you want explanation, you could ask instead of down voting, please? –  TheMan Apr 30 '14 at 2:58
One of the qualities I like best about StackOverflow is the high quality of the answers here. When I visit other sites it seems like everyone who posts is just throwing up wads of "self-explanatory code", like yours. Inevitably, some of these are wrong and each one takes time to understand and verify. A good answer carries you through the verification process and preemptively answers questions you might have. It's hard to remember to come back and check on these things, so I prefer to down vote and then neutralize or up-vote. –  Richard Apr 30 '14 at 6:53

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