from fractions import gcd
from random import randint

def brent(N):
   # brent returns a divisor not guaranteed to be prime, returns n if n prime
   if N%2==0: return 2
   y,c,m = randint(1, N-1),randint(1, N-1),randint(1, N-1)
   g,r,q = 1,1,1
   while g==1:             
       x = y
       for i in range(r):
          y = ((y*y)%N+c)%N
       k = 0
       while (k<r and g==1):
          ys = y
          for i in range(min(m,r-k)):
             y = ((y*y)%N+c)%N
             q = q*(abs(x-y))%N
          g = gcd(q,N)
          k = k + m
       r = r*2
   if g==N:
       while True:
          ys = ((ys*ys)%N+c)%N
          g = gcd(abs(x-ys),N)
          if g>1:  break
   return g

def factorize(n1):
    if n1<=0: return []
    if n1==1: return [1]
    n=n1
    b=[]
    p=0
    mx=1000000
    while n % 2 ==0 : b.append(2);n//=2
    while n % 3 ==0 : b.append(3);n//=3
    i=5
    inc=2
    #use trial division for factors below 1M
    while i <=mx:
       while n % i ==0 : b.append(i); n//=i
       i+=inc
       inc=6-inc
    #use brent for factors >1M   
    while n>mx:
      p1=n
      #iterate until n=brent(n) => n is prime
      while p1!=p:
          p=p1
          p1=brent(p)
      b.append(p1);n//=p1 
    if n!=1:b.append(n)
    b.sort()
    return b


from functools import reduce
from sys import argv
def main():
  if len(argv)==2: 
     n=int(argv[1])
  else:  
     n=int(eval(input(" Integer to factorize? ")))
  li=factorize(n)
  print (n,"= ",li)
  print ("n - product of factors = ",n - reduce(lambda x,y :x*y ,li))

if __name__ == "__main__":
   main()