# Largest Prime Factor Ruby using Fermat's factorization method

I have this code that seems to be working for number 6-8 digits, in a normal time period. When I enter bigger values the amount get ridiculously bug. It takes more than 4 hours to complete. Here is my code.

``````#Fermat's factorization method

def get_largest_prime n
t=(Math.sqrt(n)+1).floor
k=0
prime_numbers=[]
while (t+k)<n
element = (t+k)**2-n
if is_integer? Math.sqrt(element)
#store prime numbers
prime_numbers << t+k+Math.sqrt(element)
prime_numbers << t+k-Math.sqrt(element)
#puts "Prime Factors of #{n} are: #{t+k+Math.sqrt(element)} and #{t+k-Math.sqrt(element)}"
end
k+=1
end
puts "Prime Factors: "+prime_numbers.to_s
end

#making sure 450.0 is 450, for example.
def is_integer? number
number.to_i == number ? true : false
end

get_largest_prime 600851475143
``````

Running this will take more than 4 hours.

But running it for value ' 600851' for example or ' 60085167' does not take a lot of time. Any help ?

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1. That's like saying "I want to compress a 5GB file into 5MB 2. You waited 4 hours?! –  Doorknob Apr 5 '13 at 14:19

First note that Fermat factorisation doesn't give you prime factors in general.

Then, you run it until `t+k >= n`, that means you run the `while` loop `n - t` times, since `t` is roughly `sqrt(n)`, that is an `O(n)` algorithm. For a largish `n` like 600851475143 (about 6*10^11), that is bound to take long.

You need to change the algorithm. When you have found a pair of divisors (both larger than 1), factorise them both recursively. If the smaller of the found factors is 1, that is a prime factor.

Doing that (forgive the bad style, I barely know ruby):

``````#Fermat's factorization method

def get_largest_prime n
t=(Math.sqrt(n)+1).floor
k=0
prime_numbers=[]
while (t+k)<n
element = (t+k)**2-n
if is_integer? Math.sqrt(element)
#store prime numbers
a = t+k+Math.sqrt(element)
b = t+k-Math.sqrt(element)
if b == 1
prime_numbers << a
break
end
prime_numbers += get_largest_prime a
prime_numbers += get_largest_prime b
break
#puts "Prime Factors of #{n} are: #{t+k+Math.sqrt(element)} and #{t+k-Math.sqrt(element)}"
end
k+=1
end
return prime_numbers
end

#making sure 450.0 is 450, for example.
def is_integer? number
number.to_i == number ? true : false
end

a = get_largest_prime 600851475143
puts "Prime Factors: "+a.to_s
``````

solves the given problem quickly.

However, it will still take a long time for numbers that have no divisors close to the square root.

The standard factorisation by trial division has much better worst-case behaviour (`O(sqrt(n)` worst case). A mixed approach can be slightly faster than pure trial division, though.

-

Two effects here:

1) When an integer gets larger than 2**31 in Ruby, it uses a different, and slower, representation

2) There are no known factorisation algorithms that don't eventually perform badly once the number gets large enough - technically they all get slower worse than any polynomial of the (number of digits of) the number you want to factorise.

You could speed things up by using

``````Math.sqrt(element)
``````

less. Assign result of it to a variable, before all the tests. Note this will not "fix" your problem. Ultimately it won't run fast enough above a certain number - even if you transferred everything to C (although you might squeeze out a couple of extra digits before C got slow)

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#2 is a very misguided answer. –  Woot4Moo Apr 5 '13 at 14:22
@Woot4Moo: Would it be safer to say they scale badly in general; I thought general case factorisation was NP-complete? –  Neil Slater Apr 5 '13 at 14:26
OK, a look on Wikipedia suggests it might be en.wikipedia.org/wiki/NP-intermediate but there is no proof –  Neil Slater Apr 5 '13 at 14:30
Factorization complexity is not yet known. To say they scale badly in general is also very broad, without evidence to support the claim it is equivalent to "just saying words". I would remove that statement, and perhaps point OP to things such as the general number field sieve. –  Woot4Moo Apr 5 '13 at 14:30
How about "there is no known polynomial-time algorithm"? There may be more efficient approaches, which I think you seem to be in a better position to answer than me. Ultimately you cannot point to OP to something that can cope with any number in reasonable time - if they have an upper bound number they'd like to check, that might be useful to know –  Neil Slater Apr 5 '13 at 14:36