# 1-0 Knapsack Permutations with Repeatable Items [closed]

I am trying to obtain a list of all permutations of repeatable items using a 1-0 knapsack dynamic programming algorithm. I have written a python program below which find the first set for each item, but I am a little confused about finding the rest.

The program adds each of the first 2 elements in each tuple to a set. The set is then converted into a list and finally sorted in descending order.

#!/usr/bin/python

gMax = 48
dims = [
(40, 24, 10),
(40, 24, 20),
(24, 20, 20),
(24, 20, 30),
(20, 12, 10),
(20, 12, 20),
(20, 12, 30)
]

s = set()
for dim in dims:
for i in range(2):
d = dim[i]
if d not in s:
l = sorted(list(s), reverse=True)
print 'Set:',l,'\nMax:',gMax
i, types, done, lenL = 0, [], False, len(l)
while not done:
lMax, t, j = 0, [], i
while lMax < gMax and j < lenL:
greed = l[j]
if lMax + greed <= gMax:
t.append(greed)
lMax += greed
else:
j+=1
types.append(t)
i+=1
if i >= lenL: done = True
print 'Permutations:',types

Actual Output:

Set: [40, 24, 20, 12]
Max: 48
Permutations: [[40], [24, 24], [20, 20], [12, 12, 12, 12]]

Goal Output:

Set: [40, 24, 20, 12]
Max: 48
Permutations: [
[40],
[24, 24], [24, 20], [24, 12, 12], [24, 12], [24]
[20, 20], [20, 12, 12], [20, 12], [20]
[12, 12, 12, 12], [12, 12, 12], [12, 12, 12], [12, 12], [12]
]

# Edit: Well, I figured it out... (really inefficient though).

Code:

#!/usr/bin/python
# Filename: strips.py

from itertools import chain, combinations
import datetime as dt

def weight(A):
return sum(x for x in A)

def powerset(L):
return chain.from_iterable(combinations(L,r) for r in xrange(len(L)+1))

def uniqueList(L):
s = set()
for i in L:
for j in i:
if j not in s: s.add(j)
return list(s)

def duplicate(L, M):
l = list()
for e in L:
max = 0
while max + e <= M:
l.append(e)
max += e
return sorted(l, reverse=True)

def strips(L, M):
u = uniqueList(L)
d = duplicate(u, M)
return sorted(list(set([x for x in powerset(d) if 0 < weight(x) <= M])), reverse=True)

if __name__ == '__main__':
max = 63
items = [(16, 20), (16, 24), (20, 26), (20, 20), (24, 12)]
timestart = dt.datetime.now()
strips = strips(items, max)
timestop = dt.datetime.now()
print 'Execution Time:',(timestop-timestart)
print 'Number of Results:',len(strips)
for strip in strips:
val = 0
for s in strip:
val += s
print s,
print '=',val

Execution Time: 0:00:00.030264
Number of Results: 51
26 26 = 52
26 24 12 = 62
26 24 = 50
26 20 16 = 62
26 20 12 = 58
26 20 = 46
26 16 16 = 58
26 16 12 = 54
26 16 = 42
26 12 12 12 = 62
26 12 12 = 50
26 12 = 38
26 = 26
24 24 12 = 60
24 24 = 48
24 20 16 = 60
24 20 12 = 56
24 20 = 44
24 16 16 = 56
24 16 12 = 52
24 16 = 40
24 12 12 12 = 60
24 12 12 = 48
24 12 = 36
24 = 24
20 20 20 = 60
20 20 16 = 56
20 20 12 = 52
20 20 = 40
20 16 16 = 52
20 16 12 12 = 60
20 16 12 = 48
20 16 = 36
20 12 12 12 = 56
20 12 12 = 44
20 12 = 32
20 = 20
16 16 16 12 = 60
16 16 16 = 48
16 16 12 12 = 56
16 16 12 = 44
16 16 = 32
16 12 12 12 = 52
16 12 12 = 40
16 12 = 28
16 = 16
12 12 12 12 12 = 60
12 12 12 12 = 48
12 12 12 = 36
12 12 = 24
12 = 12
-
What if you add the extra copies of each value to the set first, then just do a normal knapsack solution on the set? In your example, make Set : [40, 24, 24, 20, 20, 12, 12, 12, 12]. –  mbeckish Mar 28 '13 at 20:11
Sets do not allow duplicates, that's why they are sets :) I know I am using a list, but all I should need is one copy. I am not looking for a hack, I need to make this as clean as possible. –  Mr. Polywhirl Mar 28 '13 at 21:04
I thought it might end up cleaner to precompute the number of copies each value would require, and then just apply a generic algorithm to find the solutions from the *multi*set, rather than having to worry about keeping track of the copies in the guts of your knapsack algorithm. To each his own. –  mbeckish Mar 28 '13 at 22:02
@mbeckish, I considered your suggestion and implemented it. Thanks. –  Mr. Polywhirl Mar 29 '13 at 22:38
Considering you've got a solution and you're now asking to about efficiency, I suggest you post your question on Code Review. –  p.s.w.g Mar 29 '13 at 22:57