One of my friend been asked with a question, Retrieving the max top 100 numbers from one hundred million of numbers, in a recent job interview. Do you have any idea to come up with an efficient way to solve it?
regards!
One of my friend been asked with a question, Retrieving the max top 100 numbers from one hundred million of numbers, in a recent job interview. Do you have any idea to come up with an efficient way to solve it? regards! 

Run them all through a minheap of size 100: for each input number A search engine like Lucene can use this method, with refinements, to choose the mostrelevant search answers. Edit: I fail the interview  I got the details wrong twice (after having done this before, in production). Here's code to check it; it's almost the same as Python's standard



Ok, here is a really stupid answer, but it is a valid one:
Reasoning:
It is an ok solution for some sort of one time operation. It would suck running it x times per second or something. But then, we need more context  as mclientk also had with his simple SQL statement  assuming 100 million numbersdo not exist in memory is a feasible question, because... they may come from a database and most of the time will, when talking about business relevant numbers. As such, the question is really hard to answer  efficiency first has to be defined. 


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Make sure you tell the interviewer that you assume the table is indexed properly. 


Mergesort in batches of 100, then only keep the top 100. Incidentally, you can scale this in all sorts of directions, including concurrently. 


If the data is already in an array that you can modify, you could use a variant of Hoare's Select algorithm, which is (in turn) a variant of Quicksort. The basic idea is pretty simple. In Quicksort, you partition the array into two pieces, one of items larger than the pivot, and the other of items smaller than the pivot. Then you recursively sort each partition. In the Select algorithm, you do the partitioning step exactly as before  but instead of recursively sorting both partitions, you look at which partition contains the elements you want, and recursively select ONLY in that partition. E.g., assuming your 100 million items partition nearly in half, the first several iterations you're going to look only at the upper partition. Eventually, you're likely to reach a point where the portion you want "bridges" two partitions  e.g., you have a partition of ~150 numbers, and when you partition that you end up with two pieces of ~75 apiece. At that point, only one minor detail changes: instead of rejecting one partition and continuing work only the other, you accept the upper partition of 75 items, and then continue looking for the top 25 in the lower partition. If you were doing this in C++, you could do this with 


There's no reason to sort the whole list. This should be doable in O(n) time. In pseudocode:



@darius can actually be improved !!! Suppose we have a=1000 at the top of the heap



Heapify the array in O(n). Then take out top 100 elements. 


I store first 100 numbers in Max Heap of size 100.






First iteration: Quicksort, take top 100. O(n log n). Simple, easy to code. Very obvious. Better? We are working with numbers, do a radix sort (linear time) take the top 100. I would expect this is what the interviewer is looking for. Any other considerations? Well, a million numbers isn't a lot of memory, but if you want to minimize memory, you keep a max 100 numbers encountered so far and then just scan the numbers. What would be the a best way? Some have mentioned a heap, but a bit better solution might be a doublylinked list, where you keep the pointer to the minimum of the top 100 found so far. If you encounter a number a that is bigger than the current smallest in the listed, compared with the next element, and move the number from next to the current until you find a place for the new number. (This is basically just a specialized heap for the situation). With some tuning (if the number is greater the current minimum, compare with current maximum to see which direction to walk list to find insertion point) this would be relatively effective, and would only take like 1.5k of memory. 


Suppose mylist is a list of hundred million data. so we can sort the list and take the last hundred data from mylist. mylist.sort() mylist[100:] Second way: import heapq heapq.nlargest(100, mylist) 


getpoint()
andless_distance
) – J.F. Sebastian Mar 31 '10 at 18:27