def consecutive_prime_sum():
sieve = eulerlib.prime_sieve(1000000) # takes ~0.5 sec to load
primes = [i for i, v in enumerate(sieve) if v]
max_s = 0
max_len = 0
max_i = 0
# 551 = number of primes needed when the sum >1 M
# 551 = len([i for i, v in enumerate(eulerlib.prime_sieve(1000000//50//5)) if v])
number_of_primes_till_sum_1m = 551
for i in range(0, number_of_primes_till_sum_1m):
for k in range(i, number_of_primes_till_sum_1m, 2):
if k * primes[i] > 1000000:
break
s = sum(primes[i:k + 1])
if s > 1000000:
break
if sieve[s] and k - i > max_len:
max_s = s
max_len = k - i
max_i = i
print('Number of terms: {}'.format(max_len))
print('Sum starts at n: {}'.format(max_i))
print('Sum starts at P: {}'.format(primes[max_i]))
return max_s
def find_contradiction():
N = 10000
primes = eulerlib.prime_sieve(N)
# For all odd composite numbers
for i in range(3, N, 2):
if primes[i]:
continue
# Factor into a prime plus a square
p, a = factor_goldbach(i, primes)
# Not factorized?
if not p:
# Return solution
return i
print('{} = {} + 2^{}'.format(i, p, a))
def circular_primes():
sieve = eulerlib.prime_sieve(1000000)
primes = [i for i, v in enumerate(sieve) if v]
result = 0
for p in primes:
is_circular_prime = True
prime_c = eulerlib.digits(p)
for _ in range(len(prime_c) - 1):
prime_c = eulerlib.shift(prime_c)
if not sieve[eulerlib.digits_to_int(prime_c)]:
is_circular_prime = False
break
if is_circular_prime:
print(p)
result += 1
return result
def prime_permutations():
N = 10000
S = eulerlib.prime_sieve(N)
P = [p for p in eulerlib.sieve_to_list(S) if 1000 < p < 9999]
print('p1 p2 p3 d')
print('------------------------')
for p1 in P:
d = 1
while p1 + 2 * d < N:
p2 = p1 + d
p3 = p2 + d
if S[p1] and S[p2] and S[p3] and is_permutation3(
eulerlib.digits(p1), eulerlib.digits(p2),
eulerlib.digits(p3)):
print(p1, p2, p3, d)
break
d += 1
def reciprocal_cycles_primes():
denominator_with_largest_cycle = 0
largest_cycle = 0
longest_decimal = ""
primes = [i for i, v in enumerate(eulerlib.prime_sieve(1000)) if v]
for d in primes:
decimal, is_cyclic, cycle_length = fraction_to_decimal(1, d)
if is_cyclic and cycle_length > largest_cycle:
denominator_with_largest_cycle = d
largest_cycle = cycle_length
longest_decimal = decimal
print('Denominator with largest cycle: {}'.format(
denominator_with_largest_cycle))
print('Cycle length: {}'.format(largest_cycle))
print('Decimal as string: {}'.format(longest_decimal))
print('Decimal as float: {}'.format(1 / denominator_with_largest_cycle))
return denominator_with_largest_cycle
def prime_pair_sets():
sieve = euler.prime_sieve(10000000)
primes = euler.sieve_to_list(sieve)
for prime in primes:
n = len(str(prime))
if 4 <= n <= 5:
groups_that_are_prime = 0
sub_primes = []
for i in range(1, n):
left = int(str(prime)[:i])
right = int(str(prime)[i:])
if sieve[left]:
groups_that_are_prime += 1
sub_primes.append(left)
if sieve[right]:
groups_that_are_prime += 1
sub_primes.append(right)
sub_primes = list(set(sub_primes))
m = len(sub_primes)
if m >= n:
all_orders_are_prime = True
print(sub_primes)
for i in range(m):
for j in range(m):
if i == j:
continue
test_prime = int(
str(sub_primes[i]) + str(sub_primes[j]))
if test_prime >= 1000000 and not euler.is_prime(
test_prime, 32
) or test_prime < 1000000 and not sieve[test_prime]:
all_orders_are_prime = False
print(' {} is not prime.'.format(test_prime))
break
if not all_orders_are_prime:
break
if all_orders_are_prime:
print(sub_primes)
return sum(sub_primes)
"""
import eulerlib
LIMIT = 10**8
primes = eulerlib.prime_sieve(LIMIT + 1)
print("Primes generated")
total = 0
for num in range(LIMIT + 1):
# PGI (prime generating integer) will always be 1 less than a prime number
if primes[num + 1] == False:
continue
# if num is divisible by 4, it is not a PGI
if num % 4 == 0:
continue
isPGI = True
for d in range(2, int(num**0.5) + 1):
# if d is a divisor
if num % d == 0:
# p is the prime number we are looking for
p = d + int(num / d)
if primes[p] == False:
isPGI = False
break
if isPGI == True:
def test_prime_sieve_997(self):
assert eulerlib.prime_sieve(1000)[997]
def test_prime_sieve_12345(self):
assert eulerlib.prime_sieve(5) == [
False, False, True, True, False, True
]
import eulerlib as lib
sieve = lib.prime_sieve(1000000)
def perm(k, n, res = [], memo = {}):
if n == 1:
return
for i in range(len(k)):
if k[i] == '*':
continue
temp = k[i]
k[i] = '*'
pstr = ''.join(map(str, k))
if pstr not in memo.keys():
res.append(pstr)
memo[pstr] = True
perm(k, n-1, res, memo)
k[i] = temp
if len(k) == n:
return res
def pdr(max_n):
result = {}
memo = {}
for i in range(13, max_n):
if not sieve[i] and i % 11 != 0:
continue
print('Testing: {}'.format(i))
istr = str(i)
