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I'm getting confused with this question at what it's trying to ask.

Write function mssl() (minimum sum sublist) that takes as input a list of integers. It then computes and returns the sum of the maximum sum sublist of the input list. The maximum sum sublist is a sublist (slice) of the input list whose sum of entries is largest. The empty sublist is defined to have sum 0. For example, the maximum sum sublist of the list [4, -2, -8, 5, -2, 7, 7, 2, -6, 5] is [5, -2, 7, 7, 2] and the sum of its entries is 19.

If I were to use this function it should return something similar to

>>> l = [4, -2, -8, 5, -2, 7, 7, 2, -6, 5]
>>> mssl(l)
19
>>> mssl([3,4,5])
12
>>> mssl([-2,-3,-5])
0

How can I do it?

Here is my current try, but it doesn't produce the expected result:

def mssl(x):
    ' list ==> int '
    res = 0
    for a in x:
        if a >= 0:
            res = sum(x)
        return res
    else:
        return 0
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5  
If you can't solve a problem in your head, you can't solve it with a computer. Before you write any code, try to solve some examples yourself. When you have a working method, then codify the algorithm. –  Colonel Panic Feb 25 '13 at 8:51
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6 Answers 6

There's actually a very elegant, very efficient solution using dynamic programming. It takes O(1) space, and O(n) time -- this can't be beat!

Define A to be the input array (zero-indexed) and B[i] to be the maximum sum over all sublists ending at, but not including position i (i.e. all sublists A[j:i]). Therefore, B[0] = 0, and B[1] = max(B[0]+A[0], 0), B[2] = max(B[1]+A[1], 0), B[3] = max(B[2]+A[2], 0), and so on. Then, clearly, the solution is given simply by max(B[0], ..., B[n]).

Since every B value depends only on the previous B, we can avoid storing the whole B array, thus giving us our O(1) space guarantee.

With this approach, mssl reduces to a very simple loop:

def mssl(l):
    best = cur = 0
    for i in l:
        cur = max(cur + i, 0)
        best = max(best, cur)
    return best

Demonstration:

>>> mssl([3,4,5])
12
>>> mssl([4, -2, -8, 5, -2, 7, 7, 2, -6, 5])
19
>>> mssl([-2,-3,-5])
0

If you want the start and end slice indices, too, you need to track a few more bits of information (note this is still O(1) space and O(n) time, it's just a bit hairier):

def mssl(l):
    best = cur = 0
    curi = starti = besti = 0
    for ind, i in enumerate(l):
        if cur+i > 0:
            cur += i
        else: # reset start position
            cur, curi = 0, ind+1

        if cur > best:
            starti, besti, best = curi, ind+1, cur
    return starti, besti, best

This returns a tuple (a, b, c) such that sum(l[a:b]) == c and c is maximal:

>>> mssl([4, -2, -8, 5, -2, 7, 7, 2, -6, 5])
(3, 8, 19)
>>> sum([4, -2, -8, 5, -2, 7, 7, 2, -6, 5][3:8])
19
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I doubt anyone is reading this thread anymore, but for the list [-23, 12, 21, -1, -5, 45, 3, -17, 16], this returns the end splice 7, should be 6 –  pg-robban Apr 26 at 12:57
    
@robban: the result is written using Python's slice notation, which excludes the endpoint. –  nneonneo Apr 26 at 15:19
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So if you understand what a sublist is (or a slice, which can be assumed to be the same thing), the slice is defined by the start index and the end index.

So maybe you could try and iterate over all possible start and end indexes and compute the corresponding sum, then return the maximum one.

Hint: the start index can vary from 0 to len(given_list)-1. The end index can be from start_index to len(given_list)-1. You could use a nested for loop to check all possible combinations.

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The simple solution is iterate over the list and just try adding up slices till you find the best one. Here I also included the option to return the actual sublist as well, by default this is False. I used defaultdict for this purpose because it is simpler than lookups.

from collections import defaultdict

def mssl(lst, return_sublist=False):
    d = defaultdict(list)
    for i in range(len(lst)+1):
        for j in range(len(lst)+1):
            d[sum(lst[i:j])].append(lst[i:j])
    key = max(d.keys())
    if return_sublist:
        return (key, d[key])
    return key

print mssl([4, -2, -8, 5, -2, 7, 7, 2, -6, 5])
19
print mssl([4, -2, -8, 5, -2, 7, 7, 2, -6, 5], True)
(19, [[5, -2, 7, 7, 2]])

Bonus: List comprehension method:

def _mssl(lst):
    return max( sum( lst[i:j] ) for i in xrange(len(lst)+1) for j in xrange(i, len(lst)+1) )
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Just noting that this solution is O(n^2) in both time and number of lists stored, so O(n^3) memory. It'd be trivial to modify it to take O(1) memory by only storing the sum of the highest-sum sublist and its start and end indices. –  Dougal Feb 25 '13 at 8:43
    
Correct, this is a lazy, inefficient method. It is here as a simple example of what can be done. I would solve this with a simple list-comprehension. –  Inbar Rose Feb 25 '13 at 8:45
    
The list comprehension still makes a list of length n^2. Kill the brackets to make it a generator expression and it'll be constant memory. Also by the way, these are actually O(n^3) time since each list sum takes O(n). –  Dougal Feb 25 '13 at 8:48
    
@Dougal Thanks, I knew that, just wrote the list comprehension before I wrote the max() and I forgot to remove brackets. –  Inbar Rose Feb 25 '13 at 8:50
    
Also, for practical purposes: j should be in range(i, len(lst)) (or i+1 if you've handled the empty-array case elsewhere), to avoid O(n^2) pointless sums of empty slices. :) –  Dougal Feb 25 '13 at 9:02
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It's asking you to choose a smaller subsection of a list such that the smaller subsection's sum is the largest.

If the list is all positive [1 2 3] then of course the subsection with the largest sum is just the sum of the entire list [1 2 3] which is 6.

If the list is all negative [-1 -2 -3] then the subsection with the largest sum is nothing [] which has sum 0.

However if the list has some positive and some negative the decision is harder

[1 2 3 -100 3 4 5] you should see [3 4 5] and return 12

[1 2 3 -2 3 4 5] you should use all of it and return 16

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This is the maximum sub-array problem. The Kadane's algorithm can solve it in O(n) time and O(1) space, and it goes as follows:

def mssl(x):
    max_ending_here = max_so_far = 0
    for a in x:
        max_ending_here = max(0, max_ending_here + a)
        max_so_far = max(max_so_far, max_ending_here)
    return max_so_far
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This distinction probably isn't important to the OP, who seems to be just trying to understand how to solve the problem at all, but I thought it was worth mentioning:

The other solutions here involve repeatedly summing up all the subparts of the list. We can avoid these repeated sums by using dynamic programming, since of course if we already know the sum from i to j we don't need to do add them up again to get the sum from i to j+1!

That is, make a 2d array of the partial sums, so that partsum[i, j] == sum(lst[i:j]). Something like (using a dictionary because it's easier to index with; a numpy array would be equally easy and more efficient):

import operator

def mssl(lst, return_sublist=False):
    partsum = { (0, 0): 0 }  # to correctly get empty list if all are negative
    for i in xrange(len(lst) - 1):  # or range() in python 3
        last = partsum[i, i+1] = lst[i]
        for j in xrange(i+1, len(lst)):
            last = partsum[i, j+1] = last + lst[j]

    if return_sublist:
        (i, j), sum = max(partsum.iteritems(), key=operator.itemgetter(1))
        return sum, lst[i:j]

    return max(partsum.itervalues())  # or viewvalues() in 2.7 / values() in 3.x

This takes O(n^2) time and memory, as opposed to O(n^3) time and O(1) memory for Lev/Inbar's approach (if not implemented sillily like Inbar's first code example).

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