I went to an interview today and was asked this question:
Suppose you have 1 billion integers which are unsorted on one disk file. How would you determine the largest 100 numbers?
Anyone who has ideas, please share!
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Here's my initial algorithm:
This has the (very slight) advantage is that there's no O(n^2) shuffling for the first 100 elements, just an O(n log n) sort and that you very quickly identify and throw away those that are too small. It also uses a binary search (7 comparisons max) to find the correct insertion point rather than 50 (on average) for a simplistic linear search (not that I'm suggesting anyone else proffered such a solution, just that it may impress the interviewer). You may even get bonus points for suggesting the use of optimised One other possibility you may want to consider is to maintain three lists (of up to 100 integers each):
I'm not sure, but that may end up being more efficient than the continual shuffling. The mergesort is a simple selection along the lines of (for mergesorting lists 1 and 2 into 3):
Simply put, pulling the top 100 values out of the combined list by virtue of the fact they're already sorted in descending order. I haven't checked in detail whether that would be more efficient, I'm just offering it as a possibility. I suspect the interviewers would be impressed with the potential for "out of the box" thinking and the fact that you'd stated that it should be evaluated for performance. As with most interviews, technical skill is one of the the things they're looking at. 


Obviously the interviewers want you to point out two key facts:
By evaluating the requirements for the data structure, a computer science professor would expect you to recommend using a Heap (MinHeap), since it is designed to support exactly the operations we need here. For example, for Fibonacci heaps, the operations In practice, you could use a priority queue from your favorite language's standard library (e.g. 


Create an array of 100 numbers all being 2^31. Check if the the first number you read from disk is greater than the first in the list. If it is copy the array down 1 index and update it to the new number. If not check the next in the 100 and so on. When you've finished reading all 1 billion digits you should have the highest 100 in the array. Job done. 


Speed of the processing algorithm is absolutely irrelevant (unless it's completely dumb). The bottleneck here is I/O (it's specified that they are on disk). So make sure that you work with large buffers. 


I'd traverse the list in order. As I go, I add elements to a set (or multiset depending on duplicates). When the set reached 100, I'd only insert if the value was greater than the min in the set (O(log m)). Then delete the min. Calling the number of values in the list n and the number of values to find m: this is O(n * log m) 


Keep a fixed array of 100 integers. Initialise them to a Int.MinValue. When you are reading, from 1 billion integers, compare them with the numbers in the first cell of the array (index 0). If larger, then move up to next. Again if larger, then move up until you hit the end or a smaller value. Then store the value in the index and shift all values in the previous cells one cell down... do this and you will find 100 max integers. 


I believe the quickest way to do this is by using a very large bit map to record which numbers are present. In order to represent a 32 bit integer this would need to be 2^32 / 8 bytes which is about == 536MB. Scan through the integers simply setting the corresponding bit in the bit map. Then look for the highest 100 entries. NOTE: This finds the highest 100 numbers not the highest 100 instances of a number if you see the difference. This kind of approach is discussed in the very good book Programming Pearls which your interviewer may have read! 


You are going to have to check every number, there is no way around that. Just as a slight improvement on solutions offered, Given a list of 100 numbers:
You would check to see if the new found value is > min value of our array, if it is, insert it. However doing a search from bottom to top can be quite expensive, and you may consider taking a divide and conquer approach, by for example evaluating the 50th item in the array and doing a comparison, then you know if the value needs to be inserted in the first 50 items, or the bottom 50. You can repeat this process for a much faster search as we have eliminated 50% of our search space. Also consider the data type of the integers. If they are 32 bit integers and you are on a 64 bit system, you may be able to do some clever memory handling and bitwise operations to deal with two numbers on disk at once if they are continual in memory. 


I think someone should have mentioned a priority queue by now. You just need to keep the current top 100 numbers, know what the lowest is and be able to replace that with a higher number. That's what a priority queue does for you  some implementations may sort the list, but it's not required. 





Here's some python code which implements the algorithm suggested by ferdinand beyer above. essentially it's a heap, the only difference is that deletion has been merged with insertion operation



If you find 100th order statistic using quick sort, it will work in average O(billion). But I doubt that with such numbers and due to random access needed for this approach it will be faster, than O(billion log(100)). 

