# python - 2 lists, and finding maximum product from 2 lists

I have two lists made of numbers(integers); both have 2 million unique elements.

I want to find number a from list 1 and b from list 2, that -

``````1)a*b should be maximized.
2)a*b has to be smaller than certain limit.
``````

here's what I came up with:

``````maxpq = 0
nums = sorted(nums, reverse=True)
nums2 = sorted(nums2, reverse=True)
for p in nums:
n = p*dropwhile(lambda q: p*q>sqr, nums2).next()
if n>maxpq:
maxpq=n
print maxpq
``````

any suggestions? edit : my method is too slow. It would take more than one day.

-
Does what you have work? if it doesn't, what's wrong with it? – Aesthete Nov 17 '12 at 2:56
It is too slow. :D list 1 has 2000000 elements, which means from my code 2000000 comparisons has to be done - the speed of comparison on my ivy bridge is around 1~2 comparison(s) / sec. this won't go well.. – thkang Nov 17 '12 at 2:58
You should probably mentions that in your question, because it's pretty vague at the moment. – Aesthete Nov 17 '12 at 3:00
Why not just do `max(nums) * max(nums2)`? – Joel Cornett Nov 17 '12 at 3:00
@JoelCornett `a*b has to be smaller than certain limit.` – irrelephant Nov 17 '12 at 3:00

Here's a linear-time solution (after sorting):

``````def maximize(a, b, lim):
a.sort(reverse=True)
b.sort()
found = False
best = 0
j = 0
for i in xrange(len(a)):
while j < len(b) and a[i] * b[j] < lim:
found = True
if a[i]*b[j] > best:
best, n1, n2 = a[i] * b[j], a[i], b[j]
j += 1
return found and (best, n1, n2)
``````

Simply put:

• start from the highest and lowest from each list
• while their product is less than the target, advance the small-item
• once the product becomes bigger than your goal, advance the big-item until it goes below again

This way, you're guaranteed to go through each list only once. It'll return `False` if it couldn't find anything small enough, otherwise it'll return the product and the pair that produced it.

Sample output:

``````a = [2, 5, 4, 3, 6]
b = [8, 1, 5, 4]
maximize(a, b, 2)   # False
maximize(a, b, 3)   # (2, 2, 1)
maximize(a, b, 10)  # (8, 2, 4)
maximize(a, b, 100) # (48, 6, 8)
``````
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Just tried this one. This does not yield correct maximum output... – thkang Nov 17 '12 at 3:49
oops, I forgot a condition. try now. – tzaman Nov 17 '12 at 3:52
thanks. it returns correct value and faster than bisect module. `11564.4234058 ms` for my bisect, `5679.87929394 ms` for yours. :D – thkang Nov 17 '12 at 3:56

Thanks for everyone's advices and ideas. I finally came up with useful solution. Mr inspectorG4dget shone a light on this one.

It uses `bisect` module from python's standard library.

edit : bisect module does binary search in order to find insert position of a value in a sorted list. therefore It reduces number of compares, unlike my previous solution.

http://www.sparknotes.com/cs/searching/binarysearch/section1.rhtml

``````import bisect

def bisect_find(num1, num2, limit):
num1.sort()
max_ab = 0

for a in num2:
complement = limit / float(a)
b = num1[bisect.bisect(num1, complement)-1]

if limit > a*b > max_ab:
max_ab=b*a

return max_ab
``````
-
bisect does binary search, the first paragraph on this page is a good explanation - it's fast because it only has to look at a small number of items in the list (it's first step is to look at the middle value, and see if the target is before-or-after that point, then one half of the list can be ignored) – dbr Nov 17 '12 at 3:49

This might be faster.

``````def doer(L1, L2, ceil):
max_c = ceil - 1
L1.sort(reverse=True)
L2.sort(reverse=True)
big_a = big_b = big_c = 0

for a in L1:
for b in L2:
c = a * b
if c == max_c:
return a, b
elif max_c > c > big_c:
big_a = a
big_b = b
big_c = c

return big_a, big_b

print doer([1, 3, 5, 10], [8, 7, 3, 6], 60)
``````

Note that it sorts the lists in-place; this is faster, but may or may not be appropriate in your scenario.

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Thanks for your help but unfortunately I don't see any significant speed-up. – thkang Nov 17 '12 at 3:17
I imagine there's some great algorithm out there, just waiting for us :P – pydsigner Nov 17 '12 at 3:21
Ah, the binary search might be the best – pydsigner Nov 17 '12 at 3:25
Ack, I go write a binary search algorithm, then come back and find the problem solved :P – pydsigner Nov 18 '12 at 0:26