# Linkedlist keep track of min in constant time?

EDIT:

This isn't as trivial as you think. Consider the fact that each addition of a new number pushes out an old number from the linkedlist.

The solution doesn't seem to be as simple as keeping track of a min number with a variable. What if the minimum gets pushed out of the linkedlist? Then what? How do you know what the new min is?

I heard this interview question:

You have a fixed length linked list.

• At time t=0, the linkedlist is filled with random numbers.

• At each increment in time, one new number is fed into the head of the linkedlist, and one number is pushed out from the tail.

• You are allowed only ONE traversal before the first time interval.

• This means one traversal ever. Not once at every time t.
.
• O(1) storage.

Your task is to be able to return the min of the linkedlist at every time interation.

What is an algorithm that would be able to do this?

Interesting note:

Since there's no information regarding time complexity, you are allowed to use sort operations. The only problem then is: sorting takes more than one iteration.

• Sounds like homework but missing the homework tag – JonH Jun 1 '11 at 17:54
• @Razor Storm - I am not being hasty but I will remove the homework tag. – JonH Jun 1 '11 at 17:56
• This is trickier than it seems. Definitely not a homework. – n.m. Jun 1 '11 at 18:00
• If it makes things clearer, you can simplify "one traversal ever" to "one traversal before the first time interval". Clearly you need a traversal in order to report the minimum the first time - unless the list contains `INT_MIN` or equivalent, you have to look at every value or else you might have missed the minimum. So there's no need to allow any uncertainty about when this permitted traversal occurs... – Steve Jessop Jun 1 '11 at 18:34
• I guess the moral of the story here is we all aren't valid candidates to work at Amazon.com :). – JonH Jun 1 '11 at 18:53

Clarifications before someone misunderstands my post and downvotes it.

First,

O(1) storage is not the same as an a single register. It means constant space usage.

Second,

I am going to call your LL a constant size queue (CSQ).

When initializing your queue, also initialize a min-heap where all elements of the queue keep a reference (pointer) to the heap node corresponding to them.

### 1 op on CSQ

• Pop 1 element out in O(1) time of the CSQ.
• Remove corresponding node from the min-heap in O(lg n) time.
• Add corresponding element to the min-heap in O(lg n) time.
• Push 1 element into the CSQ in O(1) time and mark a reference to the heap node added above.

The above operations guarentee that the heap size will always remain in sync with the queue size --hence O(1). I am taking one traversal limit to mean that it has to be optimal than a simple O(n) search. This is `O(lg n)`.

### Finding min

Clearly O(1). Just return the head of the min heap.

• Alike most of the answers here, this relies on the assumption that "fixed length" refers to N will always be the same. In that case, this is a great solution. – Razor Storm Jun 1 '11 at 18:48
• @Razor, As long as you push one element in the queue and one element comes out of the queue because of the push, that assumption should hold true. These types of queues are common in mainframe job schedulers. – Apoorv Khurasia Jun 1 '11 at 18:50
• why is the smallest element always first? – BlackBear Jun 1 '11 at 18:50
• @BlackBear, Because it is a min-heap. – Apoorv Khurasia Jun 1 '11 at 18:51
• oh thanks for the link :) btw +1, great idea – BlackBear Jun 1 '11 at 18:54

First off, a LL is usually used for dynamic sizes. You would probably want a regular array for fixed-size since, once again usually, it will take up less memory.

Second, you seem to have more of a queue than a list, which means when you push an element in you pop one out. In that case, the minimum can be constantly changing. Naively you can search for the minimum in any 1D list in O(n) time.

Less naively, your LL could also be a pre-sorted (sort-on-insert) heap, in which case finding the minimum element can be O(1) (depending on the structure chosen). However, insert will take O(n) time.

I am aware this does not answer your question, but this really sounds like a homework question. Use this as a guide/reference/help for your problem. :)

Hope everything gets solved, and I hope I helped!

• as mentioned by OP this is not homework, it sounds pretty valid. Second this would not work as first of all you cannot sort it as was mentioned in the post. – JonH Jun 1 '11 at 18:28
• You're right. That'll teach me to answer questions at work :p I'll lrn2read. – Jonathan Pitre Jun 1 '11 at 19:13

I'm surprised no one posted this (so it's probably wrong), but (pseudocode):

``````struct abc                                    // sorry for the name :)
{
int pos
int num
}
initialize
{
struct abc min_array[linked_list_length];   // O(1) space

fill(min_array, linked_list_elements);      // place every element in the array
sort(min_array);                            // sort in ascending order, the sorting
// compares num
}

insert_element
{

for each element in min_array {
element.pos += 1

if element.pos > linked_list.elementCount then   // this was popped out!
element.pos = 1;
element.num = value;
end if
}

sort(min_array);        // as before, sorting compares only num
}

get_min_value
{
return min_array[0];
}
``````
• @BlackBear - you cannot sort it.\ – JonH Jun 1 '11 at 18:29
• I think it's "cheating" to call your array O(1) space. I believe the size of the linked list is intended to be "fixed" in the sense that it doesn't change over the course of the operations described, not "fixed" in the sense of asymptotically constant. The big-O analysis is (I believe) intended to be performed w.r.t the limit as the size of the linked list approaches infinity. – Steve Jessop Jun 1 '11 at 18:30
• @JonH: the OP doesn't say that – BlackBear Jun 1 '11 at 18:30
• @Steve Jessop: see the OP's answer :P – BlackBear Jun 1 '11 at 18:32
• @BlackBear - I assume that if the values are randomized it means you cannot sort them. @Razor Storm if this is sortable you should of mentioned that as sorting this would of made it really easy :). – JonH Jun 1 '11 at 18:32

The only possible solution I can have is through a technicality:

Since the size of the linkedlist is fixed at the time of WRITING, that means N is constant. In that case, we are technically allowed to store an auxiliary structure that is a direct copy of the linkedlist (perhaps in an array). This is O(1) storage since N is constant.

• This feels like exploitation of a loophole, but I don't think the question is solveable in any other way. – Razor Storm Jun 1 '11 at 18:31
• I think in the future if you post stuff like this, give us more details like allowable operations / functions such as sorting or copying. – JonH Jun 1 '11 at 18:34
• @JonH, yeah my bad about the vagueness of the question. I'm not too sure about the specifics myself. I am not saying my answer is right or even valid. Actually it most likely isnt =[ – Razor Storm Jun 1 '11 at 18:36
• Using my test taking skills here :D. Why else would the interviewer say O(1) storage? So I believe your assumption is correct. – Apoorv Khurasia Jun 1 '11 at 18:47

So, basically, this is a queue, implemented as a linked list (correct me if I am wrong). To solve this, I would just change the idea of the node. A typical node will have next pointer and a value. Change this to have three elements, nextPointer, value and minSoFar. If you don't like the idea of changing the queue design, still, read this algo and I have provided another idea at the end.

I think this can be done in O(1) The trick is while traversing the list, keep track of the smallest element encountered until that point in the list and store it in the current node. So, for example you have the following queue

Head at 5 and tail at 13

5 |7 |6 |9 |5 |13 |

My modified queue will contain the nodes like

{5,5}|{7,6}|{6,6}|{9,9}|{13,13}| ({nodeVal, minSoFar})

Now, consider an operation, adding 3 to the queue and removing 13, the queue becomes

{3,3}|{5,5}|{7,6}|{6,6}|{9,9}|

Since 3 is less than the current head element, the min so far for the head element is its value

Consider another case where you need to add 15 to the queue

{15,5}|{5,5}|{7,6}|{6,6}|{9,9}|

Since 15 is greater than the current head element, the current minimum value becomes 5.

So to find the minimum element in the queue/list, all you need to do is check the head element and your time complexity will be O(1)

If you don't want to modify the queue, maintain a parallel queue and keep the minValueSoFar in that queue and mirror the operations in that queue.

• Close, but you need to account for what happens when you push the minimum out of the queue. For example, if your queue is [3,2,1] and you add 4 and extract 1, you get [4,3,2]. The old answer, 1, is invalid; you need to be able to find 2 in constant time. – Ryan Culpepper Jun 1 '11 at 21:47
• @ryanc: Yep, I missed that out... Need to rethink, thanks :) – r00k Jun 2 '11 at 0:04

If node can be defined as follows, then solution is simple:

``````class Node {
int data;
Node next;
Node prevMin;
}
``````