Exemplo n.º 1
0
import time
from primes import divisors, factor, pfactor_gen
START = time.time()
SIZE  = 10**6

factors = pfactor_gen(SIZE)

for i in xrange(2,SIZE,2):
  if sum(divisors(i)) % i == i/2:
    print i, factor(i)

print "Time Taken:", time.time() - START


"""
2: 1,3,7,15,31,65,129
3: 1,4,10,40,121,364
5: 1,6,31,156,781,3906

p(2)    = 3/2 -> 1 1/2
p(24)   = (13 * 4)/8 = 6 1/2
p(4320) = (63 * 40 * 6) = 3 1/2
        -> 2^4 * 3^3 * 5 * 7
  4320  = 2^5 * 3^3 * 5



2 [2]
24 [2, 2, 2, 3]
4320 [2, 2, 2, 2, 2, 3, 3, 3, 5]
4680 [2, 2, 2, 3, 3, 5, 13]
Exemplo n.º 2
0
import time, string
from primes import pfactor_gen, factor_given_pfactor
from itertools import combinations

START = time.time()
SIZE = 10**8
pfactor = pfactor_gen(SIZE)
primes = [2, 3, 5, 7, 11, 13, 17, 19]


def factor(n):
    return factor_given_pfactor(n, pfactor)


def mapToFactorPow(n):
    factors = factor(n)
    powCounts = [factors.count(x) for x in set(factors)]
    return tuple(sorted(powCounts)[::-1])


def getMaxOptions(distro):
    lettersMerged = string.join([str(i) * num for i, num in enumerate(distro)],
                                '')
    return len(set( combinations( \
        lettersMerged, \
        len(lettersMerged)/2 )))


gmo = getMaxOptions

possible = dict()
Exemplo n.º 3
0
#NOTE TODO need to solve it
import time
from primes import pfactor_gen, factor_given_pfactor, get_divisors_given_pfactor
START = time.time()

SIZE = 10**6
pfactor = pfactor_gen(SIZE)

def factor(n):
  return factor_given_pfactor(n, pfactor)

def get_divisors(n):
  return get_divisors_given_pfactor(n, pfactor)

# This function is currently very slow for numbers with lots of factors =/
def practical_check(n):
  divs     = get_divisors(n)
  div_sums = set([0])
  for val in divs:
    div_sums.update(set([ val + num for num in div_sums]))

  div_sums = sorted(div_sums)[:n+1]
  print "On item:", n, "Time up to now:", time.time() - START
  return div_sums == range(n+1)
pc = practical_check


items = []
for i in xrange(21,SIZE-18,2):
  if pfactor[i] == i and pfactor[i+6] == i+6 and \
  pfactor[i+12] == i+12 and pfactor[i+18] == i+18:
Exemplo n.º 4
0
import time, math
from primes import get_primes, factor_given_pfactor, pfactor_gen, get_divisors_given_pfactor
START = time.time()
SIZE = 10**8

primesList = get_primes(SIZE)
pfactorList = pfactor_gen(SIZE)
primeSet = set(primesList)


def factor(n):
    return factor_given_pfactor(n, pfactorList)


def divisors(n):
    return get_divisors_given_pfactor(n, pfactorList)


answers = set()
for p in primesList:
    print p
    divs = divisors(p + 1)
    for div1 in divs:
        for div2 in divs:
            if div1 <= div2:
                continue
            top = ((p + 1) * div1) / div2 - 1
            bottom = ((p + 1) * div2) / div1 - 1
            if top > SIZE:
                continue
            if top in primeSet and bottom in primeSet:
Exemplo n.º 5
0
START = time.time()
SIZE  = 10**6

def get_divisors(n): # returns all divisors of n.
  return get_divisors_given_pfactor(n, pfactors)

def factor(n):
  return sorted(factor_given_pfactor(n, pfactors))

def rep_dig_prime(p):
  potential_pows = get_divisors(p-1)
  for powz in potential_pows:
    if pow(10,powz,p) == 1:
      return powz

pfactors  = pfactor_gen(SIZE)
values    = [0] * SIZE
values[3] = 1
for i in xrange(5,SIZE,2): #Evens are easy to compute, do it later
  if i %1024 == 1:
    print i
  if i %5 == 0: # multiples of 5 add no extra digits from the factor of 5.
    values[i] = values[i/5]
    continue
  if pfactors[i] == i:
    values[i] = rep_dig_prime(i)
  else:
    prime_factors = factor(i)
    values[i]     = 1
    for (index,prime) in enumerate(prime_factors):
      if prime == 3 and index == 1:
Exemplo n.º 6
0
import time, math
from primes import get_primes, factor_given_pfactor, pfactor_gen, get_divisors_given_pfactor
START = time.time()
SIZE  = 10**8

primesList  = get_primes(SIZE)
pfactorList = pfactor_gen(SIZE)
primeSet    = set(primesList)

def factor(n):
  return factor_given_pfactor(n, pfactorList)

def divisors(n):
  return get_divisors_given_pfactor(n, pfactorList)

answers = set()
for p in primesList:
  print p
  divs = divisors(p+1)
  for div1 in divs:
    for div2 in divs:
      if div1 <= div2:
        continue
      top    = ((p+1) * div1) / div2 - 1
      bottom = ((p+1) * div2) / div1 - 1
      if top > SIZE:
        continue
      if top in primeSet and bottom in primeSet:
        answers.add((top, p, bottom))

print sum([x[0] +x[1] + x[2] for x in answers])