# Partition of a list of integers into K sublists with equal sum

Similar questions are 1 and 2 but the answers didn't help. Assume we have a list of integers. We want to find `K` disjoint lists such that they completely cover the given list and all have the same sum. For example, if `A = [4, 3, 5, 6, 4, 3, 1]` and `K = 2` then the answer should be:

``````[[3, 4, 6], [1, 3, 4, 5]]
or
[[4, 4, 5], [1, 3, 3, 6]]
``````

I have written a code that only works when `K = 2` and it works fine with small lists as input but with very larger lists, because of the code's high complexity, OS terminates the task. My code is:

``````def subarrays_equal_sum(l):
from itertools import combinations

if len(l) < 2 or sum(l) % 2 != 0:
return []
l = sorted(l)
list_sum = sum(l)
all_combinations = []
for i in range(1, len(l)):
all_combinations += (list(combinations(l, i)))

combinations_list = [i for i in all_combinations if sum(i) == list_sum / 2]
if not combinations_list:
return []
final_result = []
for i in range(len(combinations_list)):
for j in range(i + 1, len(combinations_list)):
first = combinations_list[i]
second = combinations_list[j]
concat = sorted(first + second)
if concat == l and [list(first), list(second)] not in final_result:
final_result.append([list(first), list(second)])

return final_result
``````

An answer for any value of `K` is available here. But if we pass the arguments `A = [4, 3, 5, 6, 4, 3, 1]` and `K = 2`, their code only returns `[[5, 4, 3, 1],[4, 3, 6]]` whereas my code returns all possible lists i.e.,

`[[[3, 4, 6], [1, 3, 4, 5]], [[4, 4, 5], [1, 3, 3, 6]]]`

My questions are:

1. How to improve the complexity and cost of my code?
2. How to make my code work with any value of `k`?
• @Ricardo The answers available there, only return True or False. My question is about returning all sublists.
– Bsh
Commented Feb 4, 2023 at 0:23
• @Bsh apologies if I've misunderstood the problem - but it seems to me that the problem offers no guarantees about whether "k" sublists even exist, nor whether the number of compliant sublists that exists is not greater than k. For isntance if the input list of integers is [1, 2], there is no valid answer... does the problem have any conditions/guarantees that I'm missing?
– Vin
Commented Feb 4, 2023 at 0:30
• Note that even finding a single k-partition is an instance of k-way number partitioning which is an NP-hard problem and thus no truly effcient algorithm is known (and, likely, never will be). Commented Feb 4, 2023 at 0:57
• @Vin You mean there is no valid partition. Valid answer is thus `[]` (i.e., that's what the function should return then). Commented Feb 4, 2023 at 1:00
• @Vin You are correct. That is why I have two conditions in my code i.e. `if len(l) < 2 or sum(l) % 2 != 0:`. In your example `[1,2]` the sum of the list (3) is not divisible by 2 so my code returns `[]`.
– Bsh
Commented Feb 4, 2023 at 16:20

Here is a solution that deals with duplicates.

First of all the problem of finding any solution is, as noted, NP-complete. So there are cases where this will churn for a long time to realize that there are none. I've applied reasonable heuristics to limit how often this happens. The heuristics can be improved. But be warned that there will be cases that simply nothing works.

The first step in this solution is to take a list of numbers and turn it into `[(value1, repeat), (value2, repeat), ...]`. One of those heuristics requires that the values be sorted first by descending absolute value, and then by decreasing value. That is because I try to use the first elements first, and we expect a bunch of small leftover numbers to still give us sums.

Next, I'm going to try to split it into a possible maximal subset with the right target sum, and all remaining elements.

Then I'm going to split the remaining into a possible maximal remaining subset that is no bigger than the first, and the ones that result after that.

Do this recursively and we find a solution. Which we yield back up the chain.

But, and here is where it gets tricky, I'm not going to do the split by looking at combinations. Instead I'm going to use dynamic programming like we would for the usual subset-sum pseudo-polynomial algorithm, except I'll use it to construct a data structure from which we can do the split. This data structure will contain the following fields:

1. `value` is the value of this element.
2. `repeat` is how many times we used it in the subset sum.
3. `skip` is how many copies we had and didn't use it in the subset sum.
4. `tail` is the tail of these solutions.
5. `prev` are some other solutions where we did something else.

Here is a class that constructs this data structure, with a method to split elements into a subset and elements still available for further splitting.

``````from collections import namedtuple

class RecursiveSums (
namedtuple('BaseRecursiveSums',
['value', 'repeat', 'skip', 'tail', 'prev'])):

def sum_and_rest(self):
if self.tail is None:
if self.skip:
yield ([self.value] * self.repeat, [(self.value, self.skip)])
else:
yield ([self.value] * self.repeat, [])
else:
for partial_sum, rest in self.tail.sum_and_rest():
for _ in range(self.repeat):
partial_sum.append(self.value)
if self.skip:
rest.append((self.value, self.skip))
yield (partial_sum, rest)
if self.prev is not None:
yield from self.prev.sum_and_rest()
``````

You might have to look at this a few times to see how it works.

Next, remember I said that I used a heuristic to try to use large elements before small ones. Here is some code that we'll need to do that comparison.

``````class AbsComparator(int):
def __lt__ (self, other):
if abs(int(self)) < abs(int(other)):
return True
elif abs(other) < abs(self):
return False
else:
return int(self) < int(other)

def abs_lt (x, y):
return AbsComparator(x) < AbsComparator(y)
``````

We'll need both forms. The function for a direct comparison, the class for Python's `key` argument to the `sort` function. See Using a comparator function to sort for more on the latter.

And now the heart of the method. This finds all ways to split into a subset (that is no larger than `bound` in the comparison metric we are using) and the remaining elements to split more.

The idea is the same as the dynamic programming approach to subset sum https://www.geeksforgeeks.org/count-of-subsets-with-sum-equal-to-x/ except with two major differences. The first is that instead of counting the answers we are building up our data structure. The second is that our keys are `(partial_sum, bound_index)` so we know whether our `bound` is currently satisfied, and if it is not we know what element to compare next to test it.

``````def lexically_maximal_subset_rest (elements, target, bound=None):
"""
elements = [(value, count), (value, count), ...]
with largest absolute values first.
target = target sum
bound = a lexical bound on the maximal subset.
"""
# First let's deal with all of the trivial cases.
if 0 == len(elements):
if 0 == target:
yield []
elif bound is None or 0 == len(bound):
# Set the bound to something that trivially works.
yield from lexically_maximal_subset_rest(elements, target, [abs(elements[0][0]) + 1])
elif abs_lt(bound[0], elements[0][0]):
pass # we automatically use more than the bound.
else:
# The trivial checks are done.

bound_satisfied = (bound[0] != elements[0][0])

# recurse_by_sum will have a key of (partial_sum, bound_index).
# If the bound_index is None, the bound is satisfied.
# Otherwise it will be the last used index in the bound.
recurse_by_sum = {}
# Populate it with all of the ways to use the first element at least once.
(init_value, init_count) = elements[0]
for i in range(init_count):
if not bound_satisfied:
if len(bound) <= i or abs_lt(bound[i], init_value):
# Bound exceeded.
break
elif abs_lt(init_value, bound[i]):
bound_satisfied = True
if bound_satisfied:
key = (init_value * (i+1), None)
else:
key = (init_value * (i+1), i)

recurse_by_sum[key] = RecursiveSums(
init_value, i+1, init_count-i-1, None, recurse_by_sum.get(key))

# And now we do the dynamic programming thing.
for j in range(1, len(elements)):
value, repeat = elements[j]
next_recurse_by_sum = {}
for key, tail in recurse_by_sum.items():
partial_sum, bound_index = key
# Record not using this value at all.
next_recurse_by_sum[key] = RecursiveSums(
value, 0, repeat, tail, next_recurse_by_sum.get(key))
# Now record the rest.
for i in range(1, repeat+1):
if bound_index is not None:
# Bounds check.
if len(bound) <= bound_index + i:
break # bound exceeded.
elif abs_lt(bound[bound_index + i], value):
break # bound exceeded.
elif abs_lt(value, bound[bound_index + i]):
bound_index = None # bound satisfied!
if bound_index is None:
next_key = (partial_sum + value * i, None)
else:
next_key = (partial_sum + value * i, bound_index + i)

next_recurse_by_sum[next_key] = RecursiveSums(
value, i, repeat - i, tail, next_recurse_by_sum.get(next_key))
recurse_by_sum = next_recurse_by_sum

# We now have all of the answers in recurse_by_sum, but in several keys.
# Find all that may have answers.
bound_index = len(bound)
while 0 < bound_index:
bound_index -= 1
if (target, bound_index) in recurse_by_sum:
yield from recurse_by_sum[(target, bound_index)].sum_and_rest()
if (target, None) in recurse_by_sum:
yield from recurse_by_sum[(target, None)].sum_and_rest()
``````

And now we implement the rest.

``````def elements_split (elements, target, k, bound=None):
if 0 == len(elements):
if k == 0:
yield []
elif k == 0:
pass # still have elements left over.
else:
for (subset, rest) in lexically_maximal_subset_rest(elements, target, bound):
for answer in elements_split(rest, target, k-1, subset):

def subset_split (raw_elements, k):
total = sum(raw_elements)
if 0 == (total % k):
target = total // k
counts = {}
for e in sorted(raw_elements, key=AbsComparator, reverse=True):
counts[e] = 1 + counts.get(e, 0)
elements = list(counts.items())
yield from elements_split(elements, target, k)
``````

And here is a demonstration using your list, doubled. Which we split into 4 equal parts. On my laptop it finds all 10 solutions in 0.084 seconds.

``````n = 0
for s in subset_split([4, 3, 5, 6, 4, 3, 1]*2, 4):
n += 1
print(n, s)
``````

So...no performance guarantees. But this should usually be able to find splits pretty quickly per split. Of course there are also usually an exponential number of splits. For example if you take 16 copies of your list and try to split into 32 groups, it takes about 8 minutes on my laptop to find all 224082 solutions.

If I didn't try to deal with negatives, this could be sped up quite a bit. (Use cheaper comparisons, drop all partial sums that have exceeded `target` to avoid calculating most of the dynamic programming table.)

And here is the sped up version. For the case with only nonnegative numbers it is about twice as fast. If there are negative numbers it will produce wrong results.

``````from collections import namedtuple

class RecursiveSums (
namedtuple('BaseRecursiveSums',
['value', 'repeat', 'skip', 'tail', 'prev'])):

def sum_and_rest(self):
if self.tail is None:
if self.skip:
yield ([self.value] * self.repeat, [(self.value, self.skip)])
else:
yield ([self.value] * self.repeat, [])
else:
for partial_sum, rest in self.tail.sum_and_rest():
for _ in range(self.repeat):
partial_sum.append(self.value)
if self.skip:
rest.append((self.value, self.skip))
yield (partial_sum, rest)
if self.prev is not None:
yield from self.prev.sum_and_rest()

def lexically_maximal_subset_rest (elements, target, bound=None):
"""
elements = [(value, count), (value, count), ...]
with largest absolute values first.
target = target sum
bound = a lexical bound on the maximal subset.
"""
# First let's deal with all of the trivial cases.
if 0 == len(elements):
if 0 == target:
yield []
elif bound is None or 0 == len(bound):
# Set the bound to something that trivially works.
yield from lexically_maximal_subset_rest(elements, target, [abs(elements[0][0]) + 1])
elif bound[0] < elements[0][0]:
pass # we automatically use more than the bound.
else:
# The trivial checks are done.

bound_satisfied = (bound[0] != elements[0][0])

# recurse_by_sum will have a key of (partial_sum, bound_index).
# If the bound_index is None, the bound is satisfied.
# Otherwise it will be the last used index in the bound.
recurse_by_sum = {}
# Populate it with all of the ways to use the first element at least once.
(init_value, init_count) = elements[0]
for i in range(init_count):
if not bound_satisfied:
if len(bound) <= i or bound[i] < init_value:
# Bound exceeded.
break
elif init_value < bound[i]:
bound_satisfied = True
if bound_satisfied:
key = (init_value * (i+1), None)
else:
key = (init_value * (i+1), i)

recurse_by_sum[key] = RecursiveSums(
init_value, i+1, init_count-i-1, None, recurse_by_sum.get(key))

# And now we do the dynamic programming thing.
for j in range(1, len(elements)):
value, repeat = elements[j]
next_recurse_by_sum = {}
for key, tail in recurse_by_sum.items():
partial_sum, bound_index = key
# Record not using this value at all.
next_recurse_by_sum[key] = RecursiveSums(
value, 0, repeat, tail, next_recurse_by_sum.get(key))
# Now record the rest.
for i in range(1, repeat+1):
if target < partial_sum + value * i:
break # these are too big.

if bound_index is not None:
# Bounds check.
if len(bound) <= bound_index + i:
break # bound exceeded.
elif bound[bound_index + i] < value:
break # bound exceeded.
elif value < bound[bound_index + i]:
bound_index = None # bound satisfied!
if bound_index is None:
next_key = (partial_sum + value * i, None)
else:
next_key = (partial_sum + value * i, bound_index + i)

next_recurse_by_sum[next_key] = RecursiveSums(
value, i, repeat - i, tail, next_recurse_by_sum.get(next_key))
recurse_by_sum = next_recurse_by_sum

# We now have all of the answers in recurse_by_sum, but in several keys.
# Find all that may have answers.
bound_index = len(bound)
while 0 < bound_index:
bound_index -= 1
if (target, bound_index) in recurse_by_sum:
yield from recurse_by_sum[(target, bound_index)].sum_and_rest()
if (target, None) in recurse_by_sum:
yield from recurse_by_sum[(target, None)].sum_and_rest()

def elements_split (elements, target, k, bound=None):
if 0 == len(elements):
if k == 0:
yield []
elif k == 0:
pass # still have elements left over.
else:
for (subset, rest) in lexically_maximal_subset_rest(elements, target, bound):
for answer in elements_split(rest, target, k-1, subset):

def subset_split (raw_elements, k):
total = sum(raw_elements)
if 0 == (total % k):
target = total // k
counts = {}
for e in sorted(raw_elements, key=AbsComparator, reverse=True):
counts[e] = 1 + counts.get(e, 0)
elements = list(counts.items())
yield from elements_split(elements, target, k)

n = 0
for s in subset_split([4, 3, 5, 6, 4, 3, 1]*16, 32):
n += 1
print(n, s)
``````
• I just ran `subset_split([1, 0, 3, 1, -5], 2)`. Your code that works with all integers returned: `1 [[-5, 3, 1, 1, 0]] and 2 [[0], [-5, 3, 1, 1]]` number 2 is correct but number one shouldn't be among the outputs as it is violating the specification i.e. each output should consist of two lists.
– Bsh
Commented Feb 6, 2023 at 16:19
• @Bsh How annoying. This only happens when `target == 0`. Because only then can you split the set into the wrong number of things of size `target` and have it add up correctly. Still it is only a small fix to `subset_split` and `elements_split` to fix this. And now it is fixed. Commented Feb 6, 2023 at 17:55
• Perfect. It works correctly now. It is indeed a detailed answer. I highly appreciate your generous contribution. Thank you!
– Bsh
Commented Feb 6, 2023 at 18:48
• @ To avoid redundant execution, on the first line inside `def subset_split (raw_elements, k)` there should be `if len(raw_elements) < k: return []`
– Bsh
Commented Jun 8, 2023 at 18:23

This has a large number of potential solutions so, reducing the number of eligible patterns to evaluate will be key to improving performance.

here's an idea: Approach it in two steps:

1. generate a list of indexes groups that add up to the target equal sum.
2. combine the index groups that don't intersect (so indexes are only in one group) so that you get K groups.

The `assemble` function is a recursive generator that will produce lists of `n` index combinations (sets) that don't overlap. given that each group has a sum of total/K, the lists will have full coverage of the original lists elements.

``````def assemble(combos,n):
if not n:
yield []
return
if len(combos)<n: return
for i,idx in enumerate(combos):
others = [c for c in combos if c.isdisjoint(idx)]
for rest in assemble(others,n-1):
yield [idx] + rest

def equalSplit(A,K):
total = sum(A)
if total%K: return       # no equal sum solution
partSum = total//K       # sum of each resulting sub-lists
combos = [ (0,[]) ]      # groups of indices that form sums <= partSum
for i,n in enumerate(A): # build the list of sum,patterns
combos += [ (tot+n,idx+[i]) for tot,idx in combos
if tot+n <= partSum]
# only keep index sets that add up to the target sum
combos = [set(idx) for tot,idx in combos if tot == partSum]
# ouput assembled lists of K sets that don't overlap (full coverage)
seen = set()
for parts in assemble(combos,K):
sol = tuple(sorted(tuple(sorted(A[i] for i in idx)) for idx in parts))
if sol in seen: continue # skip duplicate solutions
yield list(sol)
``````

Output:

``````A = [4, 3, 5, 6, 4, 3, 1]
print(*equalSplit(A,2), sep='\n')
# [(1, 3, 4, 5), (3, 4, 6)]
# [(1, 3, 3, 6), (4, 4, 5)]

A = [21,22,27,14,15,16,17,18,19,10,11,12,13]
print(*equalSplit(A,5), sep='\n')
# [(10, 15, 18), (11, 13, 19), (12, 14, 17), (16, 27), (21, 22)]
# [(10, 14, 19), (11, 15, 17), (12, 13, 18), (16, 27), (21, 22)]
``````

This will still take a long time for large lists that are split in few parts but it should be a bit better than brute force over combinations

• Improving the asymptotic constant of an exponential-time algorithm is a lost battle.
– user1196549
Commented Feb 4, 2023 at 16:04
• Lots battle indeed if you look at it from the perspective of an infinite size problem. It could still be worthwhile for problem domains that have a finite scope that is small enough. A thought to keep in mind in practice to avoid throwing away babies with the purist bath water. Commented Feb 4, 2023 at 16:13