I went to an interview today and was asked this question:

Suppose you have one billion integers which are unsorted in a disk file. How would you determine the largest hundred numbers?

I'm not even sure where I would start on this question. What is the most efficient process to follow to give the correct result? Do I need to go through the disk file a hundred times grabbing the highest number not yet in my list, or is there a better way?

  • 9
    What was your answer? – Sachin Shanbhag Oct 14 '10 at 8:01
  • 2
    Can you tell a little bit more about the properties of the integers? Are they unique? Are they all in {1, …, 1000000000}? – Gumbo Oct 14 '10 at 8:06
  • This was one of (or very similar to one of) my university interview questions. – Callum Rogers Oct 14 '10 at 8:12
  • @Sachin Shanbhag,currently i still have not got the answer – Tracy Oct 14 '10 at 14:59
  • @Callum: the integers dont have any particular properties,they could be unique or not,and this is not the point.You algorithm should not be based on those 'properties' – Tracy Oct 14 '10 at 15:01

14 Answers 14


Here's my initial algorithm:

create array of size 100 [0..99].
read first 100 numbers and put into array.
sort array in ascending order.
while more numbers in file:
    get next number N.
    if N > array[0]:
        if N > array[99]:
            shift array[1..99] to array[0..98].
            set array[99] to N.
            find, using binary search, first index i where N <= array[i].
            shift array[1..i-1] to array[0..i-2].
            set array[i-1] to N.

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 shift operations like memcpy in C provided you can be sure the overlap isn't a problem.

One other possibility you may want to consider is to maintain three lists (of up to 100 integers each):

read first hundred numbers into array 1 and sort them descending.
while more numbers:
    read up to next hundred numbers into array 2 and sort them descending.
    merge-sort lists 1 and 2 into list 3 (only first (largest) 100 numbers).
    if more numbers:
        read up to next hundred numbers into array 2 and sort them descending.
        merge-sort lists 3 and 2 into list 1 (only first (largest) 100 numbers).
        copy list 3 to list 1.

I'm not sure, but that may end up being more efficient than the continual shuffling.

The merge-sort is a simple selection along the lines of (for merge-sorting lists 1 and 2 into 3):

while list3.size() < 100:
    while list1.peek() >= list2.peek():
    while list2.peek() >= list1.peek():

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.

  • Wouldn't the constant sorting be an unnecessary task? Why bother sorting when all you have to do is a simple comparison. The best case scenario for any sort is O(n) right? Which is when the set is already sorted. But a comparison of each element, remember the lowest value of the highest values, would be O(n-1). – Mike Bethany Oct 14 '10 at 10:03
  • You may be right, @Pickle, that's why I stated I hadn't done a proper analysis - you have to compare the operations rather than the big-O properties, it may be that 10 million of the sort and merge operations is more efficient that a potential 10 million 100-value shuffles involved in my original answer. By the way, if you find an O(n) sort, let me know, I'll buy the rights off you :-) – paxdiablo Oct 14 '10 at 10:06
  • I wrote out some of the logic and it looks like you have to at least do a bubble sort on the 100 (assuming they're sorted) after seeing if a number is larger than your smallest largest number. You pop your buffer of 100 then do a bubble sort to find the appropriate position for the new number. – Mike Bethany Oct 14 '10 at 11:54
  • RE: O(n) sort. A radix sort would work for this problem, but the actual performance might be worse than the other options. @PP: O(n-1)=O(n). Best case isn't always O(n), and an already sorted sequence isn't always the best case. For example, best case for quicksort is O(n log n), and the timing for quicksorting an already sorted sequence is O(n**2). – outis Oct 14 '10 at 22:23
  • @outis "Best case not always O(n)" Yeah, my meaning was the best possible case for the set of all sorts that would do no additional work if the target set is already sorted. I thought that was pretty clear. ;) And yeah also on the O(n-1) thing. I meant O(n) - O(2) if that makes any sense. – Mike Bethany Oct 14 '10 at 23:00

Obviously the interviewers want you to point out two key facts:

  • You cannot read the whole list of integers into memory, since it is too large. So you will have to read it one by one.
  • You need an efficient data structure to hold the 100 largest elements. This data structure must support the following operations:
    • Get-Size: Get the number of values in the container.
    • Find-Min: Get the smallest value.
    • Delete-Min: Remove the smallest value to replace it with a new, larger value.
    • Insert: Insert another element into the container.

By evaluating the requirements for the data structure, a computer science professor would expect you to recommend using a Heap (Min-Heap), since it is designed to support exactly the operations we need here.

For example, for Fibonacci heaps, the operations Get-Size, Find-Min and Insert all are O(1) and Delete-Min is O(log n) (with n <= 100 in this case).

In practice, you could use a priority queue from your favorite language's standard library (e.g. priority_queue from#include <queue> in C++) which is usually implemented using a heap.

  • 1
    Actually, in practice, you could use an array and record the current min value in a separate variable because the time taken to copy numbers around when you want to insert into the array will probably be orders of magnitude less than reading 4 Gb (assuming the file is binary and consists of a packed list of 32 bit integers with no delimiters) off disk. – JeremyP Oct 14 '10 at 8:39
  • @Jeremy what about i read the first 100 ints and sort them out,then i start to read the 101th ints to the end one by one using binary search to insert the read ints to the proper position.Should this be faser? – Tracy Oct 14 '10 at 15:16
  • MY point was, it is not all that important because you have a minimum of 4Gb of disk blocks to get through. That is a lot of IO. – JeremyP Oct 14 '10 at 15:21
  • @Tracy: which is faster in practice depends on (among other things) how fast the blit operation is, since inserting into an array will require shifting all items before it. In terms of timing, deleting-and-inserting into an array is O(n), while deleting-and-inserting into a heap is O(log n) (actually, the delete-and-insert could be combined into a replace-and-sift-down, though that's still O(log n)). – outis Oct 14 '10 at 22:31
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    @Ferdinand Beyer: Agreed if the heap exists in an easy to get hold of library or even natively. By the way, the best solution does not necessarily mean "use the mathematically best algorithm". It might mean "use the algorithm that you can write in the next hour with a reasonable chance of being bug free". – JeremyP Oct 15 '10 at 8:24

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.

  • 1+ for being exactly like mine! – Aliostad Oct 14 '10 at 8:03
  • Very nice. Less memory than a set, but slightly longer time than mine, right? You could probably use a binary search to find the insertion point for the new elements to speed it up a bit. +1 – JoshD Oct 14 '10 at 8:04
  • @Josh: Yeah binary searching your insertion point would definitely be a plan. I'm not entirely sure that it would take more time than yours, though. It is more "complex" but I suspect it'd run at least as fast due to cacheing more nicely :) Would be interesting to try implementing both and see which runs faster. Of course .. the biggest slow down will be the disk reads so optimisation wise you'd be best off loading blocks of integers asynchronously in a double buffered fashion ;) – Goz Oct 14 '10 at 8:06
  • @Goz: yeah I'd get killed with the cacheing issue. But as you said, the I/O would dwarf the computation times. – JoshD Oct 14 '10 at 8:11
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    To use binary search to find 'insertion point', implies keeping the array in order, in which case your insertions require copying (potentially) all the elements in the array (99 operations per item in the file if they are strictly ascending in value). You might be better off with a fixed-size binary heap instead, which has O(lnN) insertion, at least with N=100. ( if N is small enough, arrays are fine, or at least I've never got binary heap code to run as fast as a linear scan for N<=16, but for N=100 it probably will be better ) – Pete Kirkham Oct 14 '10 at 8:21

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)

  • This is not as efficient as mine since everytime you have to check the max of the set. Virtual -1. – Aliostad Oct 14 '10 at 8:05
  • Given a list of 500,450,105 would the number 480 be added in? I think you mean only insert the value if it is greater than the MIN of the set. – Tom Gullen Oct 14 '10 at 8:05
  • @Tom Gullen: quite right. Thanks for catching my meaning :) – JoshD Oct 14 '10 at 8:07
  • -1: you should add a new integer to the set if it is greater than the smallest integer in the set. Suppose that the size of the selected set is 4 and you have [5,7,9,12] and read the number 8 ... – High Performance Mark Oct 14 '10 at 8:08
  • @High Performance Mark: yes, I changed that a minute ago. Thanks. – JoshD Oct 14 '10 at 8:09

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.

  • yeah,you are right,in practice,I/O is the major bottleneck for this question,but now let us just focus on the algorithm.Thanks – Tracy Oct 15 '10 at 1:23
  • @Tracy if the numbers are random, and there are many of them, the top 100 results will conversge rapidly to high values, so that most new values will be lesser than it. At this point the insertion cost of the choosed structure won't matter anymore. All that will matter is the getNextInt(). Sure, it's O(1), but don't forget the hidden constant! I've seen many solutions here that completely ignores it. – ruslik Oct 15 '10 at 10:31

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.

  • Every time you read a new int,your algorithm need to traverse the array,you do quite a lot of comparisons(ranging from 1 to 100) which should cost considerate time when the total numbers here is 1 billion. – Tracy Oct 15 '10 at 1:31
  • @Tracy: There is no other way. You have to compare with the ints in the array starting from the smallest. Someone suggested binary search which I believe will improve. – Aliostad Oct 15 '10 at 7:38

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!

  • i see what you mean,but it costs 536MB mem,plus,the scanning time is definitely unacceptable,right – Tracy Oct 15 '10 at 2:28
  • @Tracy: 536MB is fine for a modern PC. Unless the problem statement constrains the memory you can use then I don't think its an issue. This solution only requires you to scan the file once so no there isn't an issue with scanning time. – Howard May Oct 15 '10 at 8:20
  • 2
    Youch. "536MB is fine for a modern PC" makes me cringe. – Craig McQueen Nov 28 '10 at 10:52

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.

  • 1
    Note that searching for the insertion point is a binary search. As such, this is basically the same as paxdiabolo's answer. – outis Oct 14 '10 at 8:49

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.

  • they did, 2 answers ago – Woot4Moo Oct 14 '10 at 15:50
  • Whoops. Missed the comments before. Thanks for the pointer – The Archetypal Paul Oct 14 '10 at 15:57
  1. Assuming that 1 bill + 100ion numbers fit into memory the best sorting algorithm is heap sort. form a heap and get the first 100 numbers. complexity o(nlogn + 100(for fetching first 100 numbers))

    improving the solution

    divide the implementaion to two heap(so that insertion are less complex) and while fetching the first 100 elements do imperial merge algorithm.


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

import random
import math

class myds:
""" implement a heap to find k greatest numbers out of all that are provided"""
k = 0
getnext = None
heap = []

def __init__(self, k, getnext ):
    """ k is the number of integers to return, getnext is a function that is called to get the next number, it returns a string to signal end of stream """
    assert k>0
    self.k = k
    self.getnext = getnext

def housekeeping_bubbleup(self, index):
    if index == 0:

    parent_index = int(math.floor((index-1)/2))
    if self.heap[parent_index] > self.heap[index]:
        self.heap[index], self.heap[parent_index] = self.heap[parent_index], self.heap[index]

def insertonly_level2(self, n):

def insertonly_level1(self, n):
    """ runs first k times only, can be as slow as i want """
    if len(self.heap) == 0:
    elif n > self.heap[0]:

def housekeeping_bubbledown(self, index, length):
    child_index_l = 2*index+1
    child_index_r = 2*index+2
    child_index = None
    if child_index_l >= length and child_index_r >= length: # No child
    elif child_index_r >= length: #only left child
        if self.heap[child_index_l] < self.heap[index]: # If the child is smaller
            child_index = child_index_l
    else: #both child
        if self.heap[ child_index_r] < self.heap[ child_index_l]:
            child_index = child_index_r
            child_index = child_index_l

    self.heap[index], self.heap[ child_index] = self.heap[child_index], self.heap[index]
    self.housekeeping_bubbledown(child_index, length)

def insertdelete_level1(self, n):
    self.heap[0] = n
    self.housekeeping_bubbledown(0, len(self.heap))

def insert_to_myds(self,  n ):
    if len(self.heap) < self.k:
    elif n > self.heap[0]:

def run(self ):
    for n in self.getnext:
        #            import pdb; pdb.set_trace()

def createinput(n):
    input_arr = range(n)
    f = file('input', 'w')
    for value in input_arr:

input_arr = []
with open('input') as f:
    input_arr = [int(x) for x in f]
myds_object = myds(4, iter(input_arr))
output = myds_object.run()
print output

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)).


Here is another solution (about an eon later, I have no shame sorry!) based on the second one provided by @paxdiablo. The basic idea is that you should read another k numbers only if they're greater than the minimum you already have and that sorting is not really necessary:

// your variables
n = 100
k = a number > n and << 1 billion
create array1[n], array2[k]

read first n numbers into array2
find minimum and maximum of array2 
while more numbers:
  if number > maximum:
    store in array1
    if array1 is full: // I don't need contents of array2 anymore
       array2 = array1
       array1 = []
  else if number > minimum:
    store in array2
    if array2 is full:
       x = n - array1.count()
       find the x largest numbers of array2 and discard the rest
       find minimum and maximum of array2
    discard the number

// Finally
x = n - array1.count()
find the x largest numbers of array2 and discard the rest
return merge array1 and array2 

The critical step is the function for finding the largest x numbers in array2. But you can use the fact, that you know the minimum and maximum to speed up the function for finding the largest x numbers in array2.

Actually, there are lots of possible optimisations since you don't really need to sort it, you just need the x largest numbers.

Furthermore, if k is big enough and you have enough memory, you could even turn it into a recursive algorithm for finding the n largest numbers.

Finally, if the numbers are already sorted (in any order), the algorithm is O(n).

Obviously, this is just theoretically because in practice you would use standard sorting algorithms and the bottleneck would probably be the IO.


There are lots of clever approaches (like the priority queue solutions), but one of the simplest things you can do can also be fast and efficient.

If you want the top k of n, consider:

allocate an array of k ints
while more input
  perform insertion sort of next value into the array

This may sound absurdly simplistic. You might expect this to be O(n^2), but it's actually only O(k*n), and if k is much smaller than n (as is postulated in the problem statement), it approaches O(n).

You might argue that the constant factor is too high because doing an average of k/2 comparisons and moves per input is a lot. But most values will be trivially rejected on the first comparison against the kth largest value seen so far. If you have a billion inputs, only a small fraction are likely to be larger than the 100th so far.

(You could construe a worst-case input where each value is larger than its predecessor, thus requiring k comparisons and moves for every input. But that is essentially a sorted input, and the problem statement said the input is unsorted.)

Even the binary-search improvement (to find the insertion point) only cuts the comparisons to ceil(log_2(k)), and unless you special case an extra comparison against the kth-so-far, you're much less likely to get the trivial rejection of the vast majority of inputs. And it does nothing to reduce the number of moves you need. Given caching schemes and branch prediction, doing 7 non-consecutive comparisons and then 50 consecutive moves doesn't seem likely to be significantly faster than doing 50 consecutive comparisons and moves. It's why many system sorts abandon Quicksort in favor of insertion sort for small sizes.

Also consider that this requires almost no extra memory and that the algorithm is extremely cache friendly (which may or may not be true for a heap or priority queue), and it's trivial to write without errors.

The process of reading the file is probably the major bottleneck, so the real performance gains are likely to be by doing a simple solution for the selection, you can focus your efforts on finding a good buffering strategy for minimizing the i/o.

If k can be arbitrarily large, approaching n, then it makes sense to consider a priority queue or other, smarter, data structure. Another option would be to split the input into multiple chunks, sort each of them in parallel, and then merge.

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