OverFlowError while solving “Number of subsets without consecutive numbers”

I'm trying to solve a problem in TalentBuddy using Python

The problem is :

Given a number N. Print to the standard output the total number of subsets that can be formed using the {1,2..N} set, but making sure that none of the subsets contain any two consecutive integers. The final count might be very large, this is why you must print the result modulo 524287.

I've worked the code. All of the tests are OK, except Test 6. I got `OverFlowError` when the test is submitting `10000000` as the argument of my function. I don't know what should I do to resolve this error

My code :

``````import math
def count_subsets(n):
step1 = (1 / math.sqrt(5)) * (((1 + math.sqrt(5)) / 2) ** (n + 2))
step2 = (1 / math.sqrt(5)) * (((1 - math.sqrt(5)) / 2) ** (n + 2))
res = step1 - step2
print int(res) % 524287
``````

I guess this is taking up memory a lot. I wrote this after I found a mathematical formula to the same topic on the Internet.
I guess my code isn't Pythonic at all.

How to do this, the "Pythonic" way? How to resolve the `OverFlowError`?

EDIT: In the problem, I've given the example input `3`, and the result (output) is `5`.

Explanation: The 5 sets are, `{}, {1}, {2}, {3}, {1,3}`.

However, in Test 6, the problem I've given are:

Summary for test #6

Input test:

`[10000000]`

Expected output:

`165366`

``````Traceback (most recent call last):
On line 4, in function count_subsets:
step1 = (1 / math.sqrt(5)) * (((1 + math.sqrt(5)) / 2) ** (n + 2))
OverflowError:
``````
-
Split you step1 and step2 to mini steps, i tried it and i had no errors, the result was 0 so maybe there is some other problem. also try to use Decimal –  Kobi K Oct 15 '13 at 14:45
How precise do you need the solution. What output do you expect from count_subsets() ? –  IntrepidBrit Oct 15 '13 at 16:33
@IntrepidBrit I edited out the question, written the example input/output, and the error test –  Ryo Armanda Oct 15 '13 at 23:23
Next question: Why do you take the integer & modulus? Python is more than capable of handling those large numbers. My local test code is happily chomping though those numbers with ridiculous precision. –  IntrepidBrit Oct 16 '13 at 13:00
@IntrepidBrit First of all, the exact words from the problem : "The final count might be very large, this is why you must print the result modulo 524287" Second, `res` will contain floating number (ex. `5.0`), and the example output is an integer. So in the end I converted `res` into an integer –  Ryo Armanda Oct 16 '13 at 13:41

Let f(N) be the number of subsets that contain no consecutive numbers. There's F(N-2) subsets that contain N, and F(N-1) subsets that don't contain N. This gives:

``````F(N) = F(N-1) + F(N-2).

F(0) = 1 (there's 1 subset of {}, namely {}).
F(1) = 2 (there's 2 subsets of {1}, namely {} and {1}).
``````

This is the fibonacci sequence, albeit with non-standard starting conditions.

There is, as you've found, a formula using the golden ratio to calculate this. The problem is that for large N, you need more and more accuracy in your floating-point calculation.

An exact way to do the calculation is to use iteration:

``````a_0 = 1
b_0 = 2
a_{n+1} = b_n
b_{n+1} = a_n + b_n
``````

The naive version of this is easy but slow.

``````def subsets(n, modulo):
a, b = 1, 2
for _ in xrange(n):
a, b = b, (a + b) % modulo
return a
``````

Instead, a standard trick is to write the repeated application of the recurrences as a matrix power:

``````( a_n ) = | 0 1 |^N  ( 1 )
( b_n ) = | 1 1 |  . ( 2 )
``````

You can compute the matrix power (using modulo-524287 arithmetic) by repeated squaring. See Exponentiation by squaring. Here's complete code:

``````def mul2x2(a, b, modulo):
result = [[0, 0], [0, 0]]
for i in xrange(2):
for j in xrange(2):
for k in xrange(2):
result[i][j] += a[i][k] * b[k][j]
result[i][j] %= modulo
return result

def pow(m, n, modulo):
result = [[1, 0], [0, 1]]
while n:
if n % 2: result = mul2x2(result, m, modulo)
m = mul2x2(m, m, modulo)
n //= 2
return result

def subsets(n):
m = pow([[0, 1], [1, 1]], n, 524287)
return (m[0][0] + 2 * m[0][1]) % 524287

for i in xrange(1, 10):
print i, subsets(i)
for i in xrange(1, 20):
print i, subsets(10 ** i)
``````

This prints solutions for every power of 10 up to 10^19, and it's effectively instant (0.041sec real on my laptop).

-
This code is so good! I didn't even know you can approach this by matrices, and somehow you managed it to run really fast. Big props to you! –  Ryo Armanda Oct 19 '13 at 1:36
–  J.F. Sebastian Oct 19 '13 at 20:42

I've taken the liberty of using numpy and Decimal. This solution takes a trivial amount of time to calculate on my laptop (with a Decimal precision of 1000), so I didn't time it.

``````import math
from decimal import *

def count_subsets(n):
step1 = Decimal(1 / math.sqrt(5)) * ((Decimal(1 + math.sqrt(5)) / 2) ** (n + 2))
step2 = Decimal(1 / math.sqrt(5)) * ((Decimal(1 - math.sqrt(5)) / 2) ** (n + 2))
res = step1 - step2
print "Result : ", res

if __name__ == "__main__":

# Set up Decimal precision
getcontext()
getcontext().prec = 1000

# Actually calculate the subset!
count_subsets(10000000)
``````

EDIT - removed the dependence of numpy. And now my answer has started to look alarmingly like the previous answer ;)

-
This is a great code. But unfortunately, due to I'm working TalentBuddy problems only with its online editor (TalentBuddy doesn't allow uploading scripts), there's no `numpy` module on its system. I'm really sorry for this. Can you do another yet simple approach to this? –  Ryo Armanda Oct 16 '13 at 14:42
Argh. Sorry, my bad. I totally forgot you were using TalentBuddy. Edited the question, you should be able to just use the math module... –  IntrepidBrit Oct 16 '13 at 14:55
@IntrepidBrit stupid of me not to use `getcontext().prec` BTW even modifying the line `print "Result : ", res` to `print int(res) % 524287` the output is `411161` instead of `165366`, Is the precision `1000` not enough? –  K DawG Oct 17 '13 at 10:55
That's because the number you're trying to cast is larger than the maximum representable integer. To prove this, compare sys.maxint and the value returned by my count_subsets. The returned value is > sys.maxint. –  IntrepidBrit Oct 17 '13 at 11:32
@IntrepidBrit Oh noes. The result is the same as the previous answer, which is still not correct. Just a thought, the equation to finding the number of subsets without consecutive integers can be represented by 2 ways. One, using the expression that we worked out until now. And two, using the sigma expression. I don't have any experience of using sigma and combination in Python. Is that approach possible to write? –  Ryo Armanda Oct 17 '13 at 13:39

Okay, I think we've been concentrating on the wrong definition. The problem with the previous answers is that they require too large a number to be calculated in a single step. After you linked me mathematical solution, I used the factorial / n Choose r solution.

The below solution still has its problems (using nCr on a large number makes math.factorial cry and slow to a crawl in Python2.x), but I think it is closer to a solution.

``````import math
from decimal import *

def nCr(n,r):
f = math.factorial
return f(n) / f(r) / f(n-r)

def compute(n):
sum = 0
for m in range(0, int(math.ceil(n/2.)) + 1):
sum += nCr(n - m + 1, m)
sum %= 524287
#print sum
return sum
``````

I'm still working on a solution that'll speed things up.

-
@KDawG - NOW we could use multiple threads to speed up this algorithm :) –  IntrepidBrit Oct 18 '13 at 16:20