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| #!/usr/bin/env python2.7 | |
| """Find the Access Codes | |
| In order to destroy Commander Lambda's LAMBCHOP doomsday device, you'll need | |
| access to it. But the only door leading to the LAMBCHOP chamber is secured with | |
| a unique lock system whose number of passcodes changes daily. Commander Lambda | |
| gets a report every day that includes the locks' access codes, but only she | |
| knows how to figure out which of several lists contains the access codes. You | |
| need to find a way to determine which list contains the access codes once | |
| you're ready to go in. | |
| Fortunately, now that you're Commander Lambda's personal assistant, she's | |
| confided to you that she made all the access codes "lucky triples" in order to | |
| help her better find them in the lists. A "lucky triple" is a tuple (x, y, z) | |
| where x divides y and y divides z, such as (1, 2, 4). With that information, | |
| you can figure out which list contains the number of access codes that matches | |
| the number of locks on the door when you're ready to go in (for example, if | |
| there's 5 passcodes, you'd need to find a list with 5 "lucky triple" access | |
| codes). | |
| Write a function answer(l) that takes a list of positive integers l and counts | |
| the number of "lucky triples" of (lst[i], lst[j], lst[k]) where i < j < k. | |
| The length of l is between 2 and 2000 inclusive. The elements of l are between | |
| 1 and 999999 inclusive. The answer fits within a signed 32-bit integer. Some | |
| of the lists are purposely generated without any access codes to throw off | |
| spies, so if no triples are found, return 0. | |
| For example, [1, 2, 3, 4, 5, 6] has the triples: [1, 2, 4], [1, 2, 6], | |
| [1, 3, 6], making the answer 3 total. | |
| Note | |
| ---- | |
| This solution won't pass the test because deemed too slow. | |
| """ | |
| from bisect import insort_left | |
| from itertools import combinations | |
| def answer(l): | |
| indices = {} | |
| setdefault_ = indices.setdefault | |
| for i, x in enumerate(l): | |
| setdefault_(x, []).append(i) | |
| out = 0 | |
| highest_value = max(l) | |
| for i, x in enumerate(l): | |
| multiples = [] | |
| for m in xrange(1, int(highest_value / x) + 1): | |
| if x * m in indices: | |
| for j in indices[x * m]: | |
| if i < j: | |
| insort_left(multiples, (j, x * m)) | |
| if multiples: | |
| multiples = [m[1] for m in multiples] | |
| for pair in combinations(multiples, 2): | |
| out += pair[1] % pair[0] == 0 | |
| return out | |
| # ----------------------------------------------------------------------------- | |
| _SEED = 1.23 | |
| def benchmark(sample_count): | |
| from random import seed, randint | |
| import timeit | |
| clock = timeit.default_timer | |
| seed(_SEED) | |
| samples = [[randint(1, 999999) for _ in xrange(randint(2, 2000))] | |
| for _ in xrange(sample_count)] | |
| start = clock() | |
| for sample in samples: | |
| answer(sample) | |
| end = clock() | |
| print("%.4f s elapsed for %d samples." % (end - start, sample_count)) | |
| def test(): | |
| # Provided test cases. | |
| assert(answer([1, 1, 1]) == 1) | |
| assert(answer([1, 2, 3, 4, 5, 6]) == 3) | |
| # Custom test cases. | |
| assert(answer([1]) == 0) | |
| assert(answer([1, 2]) == 0) | |
| assert(answer([2, 4]) == 0) | |
| assert(answer([1, 1, 1, 1]) == 4) | |
| assert(answer([1, 1, 1, 1, 1]) == 10) | |
| assert(answer([1, 1, 1, 1, 1, 1]) == 20) | |
| assert(answer([1, 1, 1, 1, 1, 1, 1]) == 35) | |
| assert(answer([1, 1, 2]) == 1) | |
| assert(answer([1, 1, 2, 2]) == 4) | |
| assert(answer([1, 1, 2, 2, 2]) == 10) | |
| assert(answer([1, 1, 2, 2, 2, 3]) == 11) | |
| assert(answer([1, 2, 4, 8, 16]) == 10) | |
| assert(answer([2, 4, 5, 9, 12, 34, 45]) == 1) | |
| assert(answer([2, 2, 2, 2, 4, 4, 5, 6, 8, 8, 8]) == 90) | |
| assert(answer([2, 4, 8]) == 1) | |
| assert(answer([2, 4, 8, 16]) == 4) | |
| assert(answer([3, 4, 2, 7]) == 0) | |
| assert(answer([6, 5, 4, 3, 2, 1]) == 0) | |
| assert(answer([4, 7, 14]) == 0) | |
| assert(answer([4, 21, 7, 14, 8, 56, 56, 42]) == 9) | |
| assert(answer([4, 21, 7, 14, 56, 8, 56, 4, 42]) == 7) | |
| assert(answer([4, 7, 14, 8, 21, 56, 42]) == 4) | |
| assert(answer([4, 8, 4, 16]) == 2) | |
| def main(): | |
| test() | |
| benchmark(100) | |
| if __name__ == '__main__': | |
| main() |
Hi Serguei, thanks for sharing this solution, it's a relief to finally know what I was missing to pass the test!
I was kinda hoping for something else though—it's a bit sad to see that I've been misled all this time thinking that I had to somehow figure out a blazingly fast algorithm, haha. That's my bad anyways—I initially did implement more “naive” solutions but still couldn't think of using such a shortcut like you did to count the triples, nice one!
Anyhow, good job man and keep rockin' these challenges! :)
I eventually got this, which did pass all the tests and run-time requirement by Google. :)
Just as fast as Serguei's on [1] * 2000. Took some ~30s to run 100 samples though. LOL
def answer(l):
col, row = [], []
for i in range(1, len(l)):
col.append(sum([1 if (l[i]%l[q]==0) else 0 for q in range(i)]))
row.append(sum([1 if (l[q]%l[i]==0) else 0 for q in range(i+1, length)]))
return sum([a*b for a,b in zip(col, row)])
Nice one! Also thanks for contributing in making me feel even dumber than what I thought :P
Best wishes for the rest of the challenges, have fun!
Just got passed, figured out a very straightforward method. The key here is to loop through the seconde number in the triple.
def answer(l):
if len(l) < 3:
return 0
cnt = 0
for i in range(1, len(l) - 1):
cnt_x = len([x for x in l[:i] if l[i] % x == 0]) # Count possible x in (x, y, z)
cnt_z = len([z for z in l[i + 1:] if z % l[i] == 0]) # Count possible z in (x, y, z)
cnt += cnt_x * cnt_z # Possible combination should be the product
return cnt
Edding, the solution was absolutely correct.
I eventually got this, which did pass all the tests and run-time requirement by Google. :)
Just as fast as Serguei's on[1] * 2000. Took some ~30s to run 100 samples though. LOLdef answer(l): col, row = [], [] for i in range(1, len(l)): col.append(sum([1 if (l[i]%l[q]==0) else 0 for q in range(i)])) row.append(sum([1 if (l[q]%l[i]==0) else 0 for q in range(i+1, length)])) return sum([a*b for a,b in zip(col, row)])
how did you managed to make 100 test cases??
Why is my Solution not working? It is passing 4/5 tests
def solution(l):
if len(l)<3:
return 0
sols=0
l=np.array(l)
for i in range(len(l)-2):
n1=l[i]
l1=l[i+1:]
l1=l1[l1%n1==0]
for x in range(len(l1)-1):
n2=l1[x]
l2=l1[x+1:]
sols += np.sum(l2%n2==0)
return sols
I'm getting 4/5 as well. I think the longer you find the bug, the sillier it gets.
def solution(l):
possible_ys = []
result = 0
for i in range(len(l)):
for y in possible_ys:
z = l[i]
if z % y == 0:
result += 1
possible_xs = l[:i]
for x in possible_xs:
y = l[i]
if y % x == 0:
possible_ys.append(y)
return result
@DhruvDutta Did you find out why? I have a feeling (like someone mentioned) there is a hidden time constraint.
Hi Christopher,
Here's a solution that passed all 5 tests, it's way slower than yours on average, but solves the worst case in 0.5 seconds.
I think the key is that it's done in a single pass so it stays at O(n^2), where as the pairs approach can have a worse performance if number of pairs is large enough.