# Fast solution to Subset sum

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Consider this way of solving the Subset sum problem:

def subset_summing_to_zero (activities):
subsets = {0: []}
for (activity, cost) in activities.iteritems():
old_subsets = subsets
subsets = {}
for (prev_sum, subset) in old_subsets.iteritems():
subsets[prev_sum] = subset
new_sum = prev_sum + cost
new_subset = subset + [activity]
if 0 == new_sum:
new_subset.sort()
return new_subset
else:
subsets[new_sum] = new_subset
return []

I have it from here:

http://news.ycombinator.com/item?id=2267392

There is also a comment which says that it is possible to make it "more efficient".

How?

Also, are there any other ways to solve the problem which are at least as fast as the one above?

Edit

I'm interested in any kind of idea which would lead to speed-up. I found:

https://en.wikipedia.org/wiki/Subset_sum_problem#cite_note-Pisinger09-2

which mentions a linear time algorithm. But I don't have the paper, perhaps you, dear people, know how it works? An implementation perhaps? Completely different approach perhaps?

Edit 2

There is now a follow-up:
Fast solution to Subset sum algorithm by Pisinger

-
Is it really the same paper? They have different titles..? – Ecir Hana Mar 21 '12 at 18:44
The abstract claims that "Restricting a dynamic programming algorithm to only consider balanced states, implies that Subset-sub Problem [... is] solvable in linear time, provided that the coefficients are bounded by a constant.", which is what I think you are looking for. – dasblinkenlight Mar 21 '12 at 18:58
There is no linear time algorithm unless P=NP, since subset-sum is NP-complete. Your algorithm, and my answer, is linear time, when weights are bounded - Which means there are only O(activities.size() * 2^bound) possible elements in the subsets array. – maniek Mar 26 '12 at 13:01
@maniek talking to myself - since I can't edit the comment any more. The size is actually O(activities.size() * bound), not O(activities.size() * 2^bound) – maniek Mar 28 '12 at 9:44

While my previous answer describes the polytime approximate algorithm to this problem, a request was specifically made for an implementation of Pisinger's polytime dynamic programming solution when all xi in x are positive:

from bisect import bisect

def balsub(X,c):
""" Simple impl. of Pisinger's generalization of KP for subset sum problems
satisfying xi >= 0, for all xi in X. Returns the state array "st", which may
be used to determine if an optimal solution exists to this subproblem of SSP.
"""
if not X:
return False
X = sorted(X)
n = len(X)
b = bisect(X,c)
r = X[-1]
w_sum = sum(X[:b])
stm1 = {}
st = {}
for u in range(c-r+1,c+1):
stm1[u] = 0
for u in range(c+1,c+r+1):
stm1[u] = 1
stm1[w_sum] = b
for t in range(b,n+1):
for u in range(c-r+1,c+r+1):
st[u] = stm1[u]
for u in range(c-r+1,c+1):
u_tick = u + X[t-1]
st[u_tick] = max(st[u_tick],stm1[u])
for u in reversed(range(c+1,c+X[t-1]+1)):
for j in reversed(range(stm1[u],st[u])):
u_tick = u - X[j-1]
st[u_tick] = max(st[u_tick],j)
return st

Wow, that was headache-inducing. This needs proofreading, because, while it implements balsub, I can't define the right comparator to determine if the optimal solution to this subproblem of SSP exists.

-
As you said, it does not work. I think, if we want to read the paper as close as possible, two line should look different: for t in range(b,n+1): and for j in reversed(range(stm1[u],st[u])):. But then it breaks with "list index out of range" so there might be an off-by-one error(s). Thank you anyway for the help so far! – Ecir Hana Mar 31 '12 at 8:57
@EcirHana balsub is now implemented, and it should be off-by-one free. I can't make sense of the given optimal solution for SSP, z = max{u <= c: sn(u) > 0} because of terseness of description, but you might be able to make headway with this. :) – MrGomez Mar 31 '12 at 19:35
Sorry - what or where is this z = max...? – Ecir Hana Mar 31 '12 at 19:54
@EcirHana Bottom of page four of the paper, second paragraph before the pseudocode for balsub. – MrGomez Mar 31 '12 at 19:55
Even if this doesn't work right now your answers were the most helpful so the eternal fame is yours: Eternal fame. I will post another question specifically about this algorithm. Thank you! – Ecir Hana Apr 1 '12 at 6:44

I respect the alacrity with which you're trying to solve this problem! Unfortunately, you're trying to solve a problem that's NP-complete, meaning that any further improvement that breaks the polynomial time barrier will prove that P = NP.

The implementation you pulled from Hacker News appears to be consistent with the pseudo-polytime dynamic programming solution, where any additional improvements must, by definition, progress the state of current research into this problem and all of its algorithmic isoforms. In other words: while a constant speedup is possible, you're very unlikely to see an algorithmic improvement to this solution to the problem in the context of this thread.

However, you can use an approximate algorithm if you require a polytime solution with a tolerable degree of error. In pseudocode blatantly stolen from Wikipedia, this would be:

initialize a list S to contain one element 0.
for each i from 1 to N do
let T be a list consisting of xi + y, for all y in S
let U be the union of T and S
sort U
make S empty
let y be the smallest element of U
for each element z of U in increasing order do
//trim the list by eliminating numbers close to one another
//and throw out elements greater than s
if y + cs/N < z ≤ s, set y = z and add z to S
if S contains a number between (1 − c)s and s, output yes, otherwise no

Python implementation, preserving the original terms as closely as possible:

from bisect import bisect

def ssum(X,c,s):
""" Simple impl. of the polytime approximate subset sum algorithm
Returns True if the subset exists within our given error; False otherwise
"""
S = [0]
N = len(X)
for xi in X:
T = [xi + y for y in S]
U = set().union(T,S)
U = sorted(U) # Coercion to list
S = []
y = U[0]
S.append(y)
for z in U:
if y + (c*s)/N < z and z <= s:
y = z
S.append(z)
if not c: # For zero error, check equivalence
return S[bisect(S,s)-1] == s
return bisect(S,(1-c)*s) != bisect(S,s)

... where X is your bag of terms, c is your precision (between 0 and 1), and s is the target sum.

For more details, see the Wikipedia article.

-
Thank you! The paper by Pisinger linked above says that there is a dynamic programing algorithm which runs O(nc) - I suppose that's the approach from Hacker News. But they say that if the weight are "bounded" the complexity may be written as O(n^2*r) and they present a algorithm running in O(nr). They even provide pseudo-code for it (page 4) but unfortunately it's a bit over my head. – Ecir Hana Mar 29 '12 at 20:33
However, I think I would be much happier with an exact solution. Btw, just for the reference, if we talk about approximate approach I once found: en.wikipedia.org/wiki/Polynomial-time_approximation_scheme – Ecir Hana Mar 29 '12 at 20:39
@EcirHana Will do! I need to take a rain check for now, but I'll be happy to write up a Python version sometime later today. Thank you for the helpful information on the paper, as well. :) – MrGomez Mar 29 '12 at 20:42
thank you very much for the effort but I'm afraid we misunderstood each other. I would like to have an exact solution, rather than approximate one. I thought your "will do" means that you are going to look into the paper - I would have stopped you earlier - I'm sorry. – Ecir Hana Mar 30 '12 at 7:19
thank you for the spirit! – Ecir Hana Mar 30 '12 at 7:32

I don't know much python, but there is an approach called meet in the middle. Pseudocode:

Divide activities into two subarrays, A1 and A2
for both A1 and A2, calculate subsets hashes, H1 and H2, the way You do it in Your question.
for each (cost, a1) in H1
if(H2.contains(-cost))
return a1 + H2[-cost];

This will allow You to double the number of elements of activities You can handle in reasonable time.

-
 Very clever, thank you! Unfortunately, as you said, it improves the running time "just" by a constant factor (2x). – Ecir Hana Mar 26 '12 at 22:33 Suppose that you have numers 1,2,4,..2^39. You want to check for some number. Without MIM you need 2^40 operations. With it - 2^20 (Assuming that hash works in O(1)) – kilotaras Mar 29 '12 at 15:12

I apologize for "discussing" the problem, but a "Subset Sum" problem where the x values are bounded is not the NP version of the problem. Dynamic programing solutions are known for bounded x value problems. That is done by representing the x values as the sum of unit lengths. The Dynamic programming solutions have a number of fundamental iterations that is linear with that total length of the x's. However, the Subset Sum is in NP when the precision of the numbers equals N. That is, the number or base 2 place values needed to state the x's is = N. For N = 40, the x's have to be in the billions. In the NP problem the unit length of the x's increases exponentially with N.That is why the dynamic programming solutions are not a polynomial time solution to the NP Subset Sum problem. That being the case, there are still practical instances of the Subset Sum problem where the x's are bounded and the dynamic programming solution is valid.

-
 You are totally welcomed to "discuss" the problem, no reason to apologize. You are right about that NP and dynamic programing, I was/am willing to sacrifice some generality (e.g. the weight could be bounded) for speed. That said, the paper above claims to run faster than the classic DP solution from the question (at least that's what I understood). Also, I was hoping to collect a few tricks on the problem from people here. – Ecir Hana Apr 1 '12 at 19:07

Here are three ways to make the code more efficient:

1. The code stores a list of activities for each partial sum. It is more efficient in terms of both memory and time to just store the most recent activity needed to make the sum, and work out the rest by backtracking once a solution is found.

2. For each activity the dictionary is repopulated with the old contents (subsets[prev_sum] = subset). It is faster to simply grow a single dictionary

3. Splitting the values in two and applying a meet in the middle approach.

Applying the first two optimisations results in the following code which is more than 5 times faster:

def subset_summing_to_zero2 (activities):
subsets = {0:-1}
for (activity, cost) in activities.iteritems():
for prev_sum in subsets.keys():
new_sum = prev_sum + cost
if 0 == new_sum:
new_subset = [activity]
while prev_sum:
activity = subsets[prev_sum]
new_subset.append(activity)
prev_sum -= activities[activity]
return sorted(new_subset)
if new_sum in subsets: continue
subsets[new_sum] = activity
return []

Also applying the third optimisation results in something like:

def subset_summing_to_zero3 (activities):
A=activities.items()
mid=len(A)//2
def make_subsets(A):
subsets = {0:-1}
for (activity, cost) in A:
for prev_sum in subsets.keys():
new_sum = prev_sum + cost
if new_sum and new_sum in subsets: continue
subsets[new_sum] = activity
return subsets
subsets = make_subsets(A[:mid])
subsets2 = make_subsets(A[mid:])

def follow_trail(new_subset,subsets,s):
while s:
activity = subsets[s]
new_subset.append(activity)
s -= activities[activity]

new_subset=[]
for s in subsets:
if -s in subsets2:
follow_trail(new_subset,subsets,s)
follow_trail(new_subset,subsets2,-s)
if len(new_subset):
break
return sorted(new_subset)

Define bound to be the largest absolute value of the elements. The algorithmic benefit of the meet in the middle approach depends a lot on bound.

For a low bound (e.g. bound=1000 and n=300) the meet in the middle only gets a factor of about 2 improvement other the first improved method. This is because the dictionary called subsets is densely populated.

However, for a high bound (e.g. bound=100,000 and n=30) the meet in the middle takes 0.03 seconds compared to 2.5 seconds for the first improved method (and 18 seconds for the original code)

For high bounds, the meet in the middle will take about the square root of the number of operations of the normal method.

It may seem surprising that meet in the middle is only twice as fast for low bounds. The reason is that the number of operations in each iteration depends on the number of keys in the dictionary. After adding k activities we might expect there to be 2**k keys, but if bound is small then many of these keys will collide so we will only have O(bound.k) keys instead.

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 I specifically wrote "does not relay on some implementation detail". The difference in #1 is just the fact that Python runs in O(n) for list + [item]. #2 adding to a hash table is O(1). #3 is exactly the kind of trick I'm looking for, see above. – Ecir Hana Mar 30 '12 at 7:31