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I'm trying to write an optimal function that given a list of items, returns a reordered list with the top_k items at the start (they don't need to be ordered themselves). I don't have any constraint on the order of the remainder elements but ideally I'd like them in their original ordering.

I tried 3 approaches. First, a trivial solution which runs in O(top_k* N) time. Second, using a priority heap of the largest elements with O(log(top_k)* N) (the slowest) and lastly, by brute force sorting the entire list O(N*logN), which turned out to be the fastest)

def semi_sort_trivial(items, top_k=3):
    for i in range(top_k):
        maximum = items[i]
        pos = i
        for j in range(i+1, len(itemss)):
            if maximum < events[j]:
                pos = j
                maximum = items[j]
        # Swap maximum with the top i'th position under evaluation.
        items[pos], items[i] = items[i], items[pos]
    return items

def semi_heap_sort(items, top_k=3):
    lst = []
    heap_store = items[:top_k]
    for item in items[top_k:]:
        lst.append(heapq.heappushpop(heap_store, item))
    return heap_store + lst

def semi_sort_usingsort(items, top_k=3):
    lst = sorted(items)[-top_k:]
    return lst + [item for item in items if item not in lst]


In [7]: %timeit semi_heap_sort(range(20))
10000 loops, best of 3: 26.3 us per loop

In [8]: %timeit semi_sort_trivial(range(20))
100000 loops, best of 3: 11 us per loop

In [9]: %timeit semi_sort_usingsort(range(20))
100000 loops, best of 3: 5.89 us per loop

I'm surprised the heap performed the worst. My initial guess were the constant factors were too high. But after trying larger ranges, I still had similar performance issues.I expected the heap to perform the best. Any pointers?

It feels like there has to be a better way to do solve this problem. For the general case of N=20 and k=3, N log N is roughly 20 * 5 operations and I believe we should be able to do this in a N log top_k or 20 * 2 operations. It should be possible to do better than the semi_sort_usingsort approach. Any suggestions to make this happen?

Thanks.

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3 Answers 3

up vote 3 down vote accepted

Firstly, you are testing over fairly small problems k = 3, n = 20. With numbers that small the speed of python vs C becomes more significant. As a result, the sort() based method wins because it jumps into C for that logic whereas your other methods have to stay in python.

Secondly, you are doing this with a sorted list. Sorting already sorted items tends to cause unusual behavior in sorting algorithms. Some algorithms exhibit pathological behavior in this case. Python appears to sort the list really quickly as compared to having to actually sort a random list.

Thirdly, there is a function heapq.nlargest which returns the n largest items from an iterable. That would be an option to consider.

Fourthly,

def semi_heap_sort(items, top_k=L):
    lst = []
    heap_store = items[:top_k]

You need to call heapq.heapify() on the heaps to make sure it follows the rules for heaps.

    for item in items[top_k:]:

You are actually producing a new list only slightly shorter then the original. That's gonna take a considerable amount of time.

        lst.append(heapq.heappushpop(heap_store, item))
    return heap_store + lst

Here is an optimized version of the same function:

EDIT Original version was buggy. Sadly, my speed advantage is gone :( Its only better when the problem gets much larger.

def mod_heap_sorta(items, top_k=L):
    heap_store = items[:top_k]
    heapq.heapify(heap_store)
    remaining = itertools.islice(items, top_k, None)
    leftovers = [heapq.heappushpop(heap_store, item) for item in remaining]
    return heap_store + leftovers

I'm guessing that when you tried scaling up the numbers, you increased the size of the list of items but you didn't scale up the value of top_k. All of the algorithms appear to be highly sensitive the size of the list. However, semi_trivial_sort is also highly sensitive to top_k. For small values of k, semi_trivial_sort is faster then semi_heap_sort due to the constant factors.

It seems that the biggest performance benefit in my version was avoiding duplicating the list of items. Use of the list comprehension also helped, but not to the same degree. A small improvement can be had by rewriting the function to use map instead. However, map performs badly on PyPy so I avoid it.

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Thanks! That was very helpful :-) –  GeneralBecos May 24 '11 at 2:38
    
Just noticed your optimized version has a bug, the leftovers array will always be empty. –  GeneralBecos May 24 '11 at 3:51
    
@GeneralBecos, actually its the heap_store that's empty –  Winston Ewert May 24 '11 at 14:00
    
Aah, my bad. I meant the heapstore, don't remember how that happened. Thanks for pointing it out! –  GeneralBecos May 24 '11 at 15:00
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See Selection Algorithm.

If you can stand an approximate method, you could

  1. histogram the data O(N)

  2. Sum the histogram to get a cumulative distribution O(number of histogram buckets)

  3. choose a number X at the k/N part of the distribution O(1)

  4. select all numbers >= X O(N).

So the whole thing is basically O(N). (That doesn't mean it's fast. That only tells how it scales up.)

You can err on the side of choosing too many numbers. Then if you have too many, do it all again on the smaller set, which is O(k)

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Another thing you might try is a quicksort modified to ignore any interval starting at a position greater than top_k.

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