project-euler/357_prime_generating_integers.py

#!/usr/bin/env python3

from itertools import combinations
from operator import mul

def candidates(sieve):
    n = len(sieve)
    for i in range(4, n, 4):
        sieve[i] = True
    for p in range(3, n, 2):
        if sieve[p]:
            continue
        for i in range(p**2, n, 2*p):
            sieve[i] = p

        for i in range(2*p**2, n, 2*p**2):
            sieve[i] = True
        if not sieve[p-1]:
            yield p-1

def is_prime(n):
    return not sieve[n] and n%2

def factors(n):
    r = []
    while not n%2:
        r.append(2)
        n //= 2
    while sieve[n] != False:
        r.append(sieve[n])
        n //= sieve[n]
    return r + [n]

def test_alt(n):
    fctrs = [f for f in factors(n)]
    for i in range(len(fctrs)//2):
        for c in combinations(fctrs, i+1):
            d = reduce(mul, c)
            if not is_prime(d + n//d):
                return False
    return True

def test(n, fctrs, p=1, i=0, depth=1):
    if depth > len(fctrs) // 2:
        return True
    for j, f in enumerate(fctrs[i:]):
        if not is_prime(p*f + n//(p*f)) or not test(n, fctrs, p*f, j+1, depth+1):
            return False
    return True

N = 10**8 + 2
sieve = [False] * N

print(sum(c for c in candidates(sieve) if test(c, factors(c))) + 1)