# Any idea how to transform this O(n^2) algo into a O(n)

I have the following algorithm which scan a large circular array (data). At certain point in the array, I need to take a look at the past values (0 = newest data point, n = oldest data point) and determine if there was a value 5% below the current value. I ended up writing a O(n^2) algorithm which works okay, but this doesn't scale.

``````        const int numberOfDataPointsInPast = 1000;
int numberOfDataPoints = 0;
for (int i = numberOfDataPointsInPast; i >= 0; i--)
{
double targetPoint = data[i] * 0.95;
for (int j = i + numberOfDataPointsInPast; j > i; j--)
{
if (data[j] <= targetPoint)
{
numberOfDataPoints++;
break;
}
}
}
``````

Any idea how I could transform this into a O(n) algo? Thanks!

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not sure I understand your algorithm right... how does this work? is your array data from 0 to N or 0 to 2N? (from your code it looks like it has to be 2N) –  Jason S Jun 22 '10 at 13:29
Is this homework? If so, you should consider tagging it accordingly. –  Tomas Lycken Jun 22 '10 at 13:29
The problem description and the code do not seem to describe the same thing to me. –  Svante Jun 22 '10 at 13:30
No, it's not a homework. –  Martin Jun 22 '10 at 13:34
Is `numberOfDataPointsInPast` the size of your array? –  phimuemue Jun 22 '10 at 13:44

While iterating the array store the lowest value. This requires to create a min variable and perform a compare check in every step. Instead of comparing all previous values with the new one, compare it only with the lowest.

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I think you need to elaborate a little more. I don't understand how you create a O(n) algorithm by doing this; it seems that you just defer the search until an insertion is performed. I the worst-case (which is what O measures), you are still O(n^2). –  San Jacinto Jun 22 '10 at 13:31
Depends on whether you can rely on the minimum always being in the window or not. –  Donal Fellows Jun 22 '10 at 13:39
This does not take into account the 'window' of 1500 previous values. –  Adrian Regan Jun 22 '10 at 15:01
He has stated it, in his code example 'numberOfDataPointsInThePast' –  Adrian Regan Jun 22 '10 at 15:18
This is not going to work. It is not taking into consideration the window of 1500 points. –  Martin Jun 22 '10 at 15:47

I think I understand your requirements.... I'm going to restate the problem:

Given: a sliding buffer size K, and a data array of size N > K, indices from 0 to N-1.

Compute: Count the number of points j such K <= j < N-1, and that the set {data[j-1], data[j-2], data[j-3], ... data[j-K]} contains at least one point that has value of <= 0.95 * data[j].

This can be accomplished as follows:

1. Sort the points {data[0], data[1], ... data[K-1]} using a data structure which has at most O(log N) cost for insertion/removal.

2. Initialize a counter R to 0, initialize j to K.

3. Check the sorted array to see if the lowest point is <= data[j] * 0.95; if so, increment R.

4. Remove data[j-K] from the sorted array, and insert data[j] to the sorted array.

5. Increment j

6. If j < N, go back to step 3.

The key here is to choose the proper data structure. I am pretty sure a binary tree would work. If the incremental insertion cost is O(log N) then your total runtime is O(N log N).

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I do not think it is possible to do so in O(n) because by solving it with O(n) you can sort it with O(n) and that is not possible. (minimum, for sort is O(nlogn)).

EDIT - reduce sorting to this problem

Suppose one can tell for each point how many points in the past has value smaller than x% (here x is 5 - but x can also be 0 then the count will be any smaller points in the past).

Now - suppose you want to sort an array of n elements.
If you can get the number of smaller points int the past for all elements in O(n) if point `a` has a greater value than point `b` the count for point `a` will also be greater that the count for point `b` (because the array is circular). So this problem actually yield a function from the values to the count that preserves the order.
Now - the new values are bound between o and n and this can be sorted in time n.

Correct me if I am wrong (It might be that I did not understand the problem in the first place).

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O(n) is possible, IMO. See my answer. –  Aryabhatta Jun 22 '10 at 13:52
Sorry I have to give this a -1: THere is 0.95 involved and O(n) is possible and this has got nothing to do with sorting. You need to find if there is some value <= 0.95*newValue. You don't have to find the exact postition, which sorting requires. –  Aryabhatta Jun 22 '10 at 13:58
I will edit my answer to explain the reduction to sorting. –  Itay Karo Jun 22 '10 at 14:02
@Itay: First, you have to reduce it the other way: Sorting must me reduced to this, not the other way round. Second, O(n) is possible! Did you read my answer? –  Aryabhatta Jun 22 '10 at 14:03
But you are assuming that you must sort the data to accomplish the task. This isn't necessarily the case. –  San Jacinto Jun 22 '10 at 14:14

You could maintain an array `buffArray` for `numberOfDataPointsInPast` elements that will contain current „window” elements sorted in ascending order.

For each iteration:

• Check if current element is lower than `0.95 * buffArray[0]` and perform necessary actions if it is.
• Remove element that goes out of „window” (i.e. `i+numberOfDataPointsInPast`’th) from `buffArray`.
• Add new element (i.e. `i`’th) to `buffArray` maintaining sort order.

This is not O(N) as I understand, but definitely more effective than O(N^2) since adding and removing elements to / from sorted array is O(log N). I suspect that final efficiency is O(N log(W)), where W is `numberOfDataPointsInPast`.

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darn, you finished posting first. –  Jason S Jun 22 '10 at 13:44
Your post is more clean however :) Let it be to choose from :) –  nailxx Jun 22 '10 at 13:50
It is worst case O(NW) if you use an array. O(N logW) is inaccurate. –  Aryabhatta Jun 22 '10 at 21:04
finding elements in a sorted array is O(log N), adding or removing is O(N) –  jk. Jun 23 '10 at 15:13

EDIT:

After thinking about it somemore, an easy O(n) time algorithm is possible, without the need for RMQ or tree (see previous portion of my answer below).

Given an array A[1...n] and and a window width W, you need to find minimum A[i, ...i+W], given i.

For this, you do the following.

Split A[1...n] into contiguous blocks of size W-1. B1, B2, ...B(W-1).

For each block B, maintain two more block called BStart and BEnd.

BStart[i] = minimum of B1, B[2], ..., B[i].

BEnd[i] = minimum of B[W-1], B[W-2], ..., B[W-i].

This can be done in O(W) time for each block, and so O(n) time total.

Now given an i, the sub-array A[i...i+W] will span two consecutive blocks, say B1 and B2.

Find the minimum from i to end of block B1, and start of block B2 to i+w using B1End and B2Start respectively.

This is O(1) time, so total O(n).

For a circular array C[1....n], all you need to do is run the above on

A[1....2n], which is basically two copies of C concatenated together i.e. A[1...n] = C[1...n] and A[n+1 ... 2n] = C[1...n]

Previous writeup.

Ok. Assuming that I have understood your question correctly this time...

It is possible in O(n) time and O(n) space.

In fact it is possible to change your window size to any number you like, have it different for different elements and still have it work!

Given an array A[1...n], it can be preprocessed in O(n) time and O(n) space to answer queries of the form: `What is the position of a minimum element in the sub-array A[i...j]?` in constant time!

This is called the Range Minimum Query Problem.

So theoretically, it is possible to do in O(n) time.

Just using a tree will give you O(nlogW) time, where W is the size of the window and will probably work much better than RMQ, in practice, as I expect the hidden constants might make the RMQ worse.

You can use a tree as follows.

Start backwards and insert W elements. Find the minimum and push onto a stack. Now delete the first element and insert (W+1)th element. Find the minimum, push on the stack.

Continue this way. Total processing time will be O(nlogW).

At the end you have a stack of minimums, which you can just keep popping off as you now walk the array a second time, this time in the correct order, searching for 0.95*target.

Also, your question is not really clear, you say it is a circular buffer, but you don't seem to be doing a modulus operation with the length. And as coded up, your algorithm is O(n), not O(n^2) as your window size is a constant.

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@Martin: Does this answer work for you? I believe it is O(n)... –  Aryabhatta Jun 22 '10 at 13:56
Emmm… and when you stumble upon on a very small element—say zero—it will be linked as a list head and will stay there forever even after it will go out of `numberOfDataPointsInPast`. Am I misunderstand something? –  nailxx Jun 22 '10 at 14:03
@nailxx: You only need to know if there was some previous element <= 0.95*newValue. So having a zero is great! isn't it? In any case, you can create the linkedlist on the fly in O(n) time, just before you start searching, by walking the array backwards (in the reverse order of the order in the question). –  Aryabhatta Jun 22 '10 at 14:08
@nailxx: The size of the linkedlist will be exactly same as the number of elements (i.e. we dupicate values), if that is what is the confusion. –  Aryabhatta Jun 22 '10 at 14:24
@nailxx: I misunderstood the question! –  Aryabhatta Jun 22 '10 at 14:49

You could take the first numberOfDataPointsInPast in the past sort them, which is n*log(n). Then do a binary search, log(n), find the lowest data point that passes the 5% test. That will tell you how many points out of the numberOfDataPointsInPast will pass the test in n*log(n) time I believe.

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The iterations need to start from the bottom and increment (keeping the min of the past). Right now, as posted the algorithm is always looking back, instead of moving forward and remembering the past minimum.

As new points are added, the range of data points can only increase the upper or lower bound. As the lower bound decreases, keeping the lower bound is all that it necessary. Any new points which are more than the lower bound / 0.95 will be acceptable (since the lower bound is always in the past):

``````const int numberOfDataPointsInPast = 1000;
int numberOfDataPoints = 0;
double lb = NAN;
for (int i = 0; i < numberOfDataPointsInPast; i++)
{
if ( lb == NAN || data[i] < lb ) {
lb = data[i];
}
if ( data[i] >= lb / 0.95 ) {
numberOfDataPoints++
}
}
``````
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This is the same solution presented by another poster. –  San Jacinto Jun 22 '10 at 15:11

You have two option:

1. Sort it -- O(n log n)

2. Median of Medians algorithm

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Try this:

Always maintain two pointers to elements within your buffer. One is the minimum value encountered and the other is the next mimumum (that is the next hightest by increment). Remember these are pointers to the buffer.

At each step in your progression through the buffer, determine if the current value is less than or equal to the value pointed to by min1 or min2, if so, update min1 or min2 to point to the current location. Otherwise if by pointer arithmetic, the value of min1 or min2 is 1500 places back in the buffer, you need to determine which one it is and re-adjust min1 or min2 accordingly, that is min1 points to min2 and min2 is set to point at current location, or min2 is simply set to point to current location.

Whether the value pointed to by either min1 or min2 is less than 15% of the current value can then be determined by simple comparison...

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