# How can Wolfram Alpha compute the divisors of 2305843008139952128 in less than a second?

I am trying to find the divisors of a huge integer I have made a question about that in Haskell but Haskell is not fast enough. I put the above number in Wolfram Alpha and the result was immediate. How this was done?

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Hard to say, without asking them directly but it's possible their implementation is much faster than yours, or they could simply have cached the answer. –  Borgleader Sep 19 '12 at 17:18

That's not actually a difficult factorization, since it's 2^30 * (2^31 - 1). Repeated division by two until the number is odd, then around 20k iterations of a loop attempting to divide 2147483647 by odd numbers greater than 2 but less than sqrt(2147483647)==46340. On modern processors, that's not going to take very long...

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In fact, my laptop, with only a 2GHz processor, and using a pretty naive algorithm similar to what's described above, takes only 58s to determine that 18446744073709551557 (the largest prime that fits in an unsigned 64-bit number) is prime, and less than 0.01s to factor the original number. –  twalberg Sep 19 '12 at 17:54
I did not ask for factorization. I speak for finding the 62(including the number itself) divisors of this number. In my laptop with only 2GB RAM and a 1.8GHz dual core processor took me 16seconds to find all the 62 divisors. Using C++ and the pthread libray. If you try to find if a number is prime you do not have to find all the divisors. If you find one divisor then this number is not prime. By the way the number that I speak of is a perfect number that is produced using Mersenne primes. –  Dragno Sep 21 '12 at 10:39
The number in the title of the question factors in <0.01s on my laptop, producing 2^30 * (2^31 - 1) - the last factor is prime. Finding all possible divisors is then a pretty simple task of recombining. All divisors either have the form 2^n (where 0<=n<=30) or (2^31 - 1)*2^n (same limits on n), giving 62 possible divisors (including 1 and the number itself). Trying to find all the possible divisors without finding the factors first is a bit brute-force-ish, and not particularly efficient, I think. –  twalberg Sep 21 '12 at 14:04
OK. Thanks for the answer –  Dragno Sep 22 '12 at 13:12
``````from random import randint
from fractions import gcd
from math import floor,sqrt
from itertools import combinations
import pdb
def congruent_modulo_n(a,b,n):
return a % n == b % n
def isprimeA(n,k=5):
i=0
while i<k:
a=randint(1,n-1)
if congruent_modulo_n(a**(n-1),1,n) == False:
return False
i=i+1
return True
def powerof2(n):
if n==0: return 1
return 2<<(n-1)
def factoringby2(n):
s=1
d=1
while True:
d=n//powerof2(s)
if isodd(d): break
s=s+1
return (s,d)
def modof2(n):
a0=n>>1
a1=a0<<1
return n-a1
def iseven(m):
return modof2(m)==0
def isodd(m):
return not iseven(m)
class miller_rabin_exception(Exception):
def __init__(self,message,odd=True,lessthan3=False):
self.message=message
self.odd=odd
self.lessthan3=lessthan3
def __str__(self):
return self.message

def miller_rabin_prime_test(n,k=5):
if iseven(n): raise miller_rabin_exception("n must be odd",False)
if n<=3: raise miller_rabin_exception("n must be greater than 3",lessthan3=True)
i=0
s,d=factoringby2(n-1)
z=True
while i<k:
a=randint(2,n-2)
for j in range(0,s):
u=powerof2(j)*d
#x=a**u % n
x=pow(a,u,n)
if x==1 or x==n-1:
z=True
break
else:z=False

i=i+1
return z
def f(x,n):
return pow(x,2,n)+1
def isprime(N):
if N==2 or N==3:
return True
elif N<2:
return False
elif iseven(N):
return False
else:
return miller_rabin_prime_test(N)
def algorithmB(N,outputf):
if N>=2:
#B1
x=5
xx=2
k=1
l=1
n=N
#B2
while(True):
if isprime(n):
outputf(n)
return
while(True):
#B3
g=gcd(xx-x,n)
if g==1:
#B4
k=k-1
if k==0:
xx=x
l=2*l
k=l
x=pow(x,2,n)+1
else:
outputf(g)
if g==n:
return
else:
n=n//g
x=x % n
xx=xx % n
break
def algorithmA(N):
p={}
t=0
k=0
n=N
while(True):
if n==1: return p
for dk in primes_gen():
q,r=divmod(n,dk)
if r!=0:
if q>dk:
continue
else:
t=t+1
p[t]=n
return p
else:
t=t+1
p[t]=dk
n=q
break
def primes_gen():
yield 2
yield 3
yield 5
p=5
while(True):
yield p
else:

def algorithmM(a,m,visit):
n=len(a)
m.insert(0,2)
a.insert(0,0)
j=n
while(j!=0):
visit(a[1:])
j=n
while a[j]==m[j]-1:
a[j]=0
j=j-1
a[j]=a[j]+1

def factorization(N):
s=[]
algorithmB(N,s.append)
s1=filter(lambda x:not isprime(x),s)
d=map(algorithmA,s1)
f=map(lambda x:x.values(),d)
r=reduce(lambda x,y:x+y,f,[])+filter(isprime,s)
distinct_factors=set(r)
m=map(r.count,distinct_factors)
return zip(distinct_factors,m)

def divisors(N):
prime_factors=factorization(N)
a=[0]*len(prime_factors)
m=[]
p=[]
for x,y in prime_factors:
m.append(y+1)
p.append(x)
l=[]
algorithmM(a,m,l.append)
result=[]
for x in l:
result.append(reduce(lambda x,y:x*y,map(lambda x,y:x**y,p,x)))
return result
``````
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