I wrote two codes with almost same structure,
def prime_gen1(Limit = 10000):
List = [2,]
for x in range(3,Limit):
for y in List:
if not x%y:
break
if not x%y:
continue
else:
List.append(x)
yield x
def prime_gen2(Limit = 10000):
from math import floor
for x in range(3,Limit):
for y in range(2, floor(x**0.5)+2):
if not x%y:
break
if not x%y:
continue
else:
yield x
>>> list(prime_gen1(20000)) == list(prime_gen2(20000))
True
>>> def time1(number):
st = time()
list(prime_gen1(number))
end = time()
return end - st
>>> def time2(number):
st = time()
list(prime_gen2(number))
end = time()
return end - st
One does same work as other, but the latter actually works much faster. I'm wondering why this happens.
Logically - or nonlogically, I thought checking with primes will outdo the other way, in this case- checking by numers between 3 and root of number.But time-checking showed vice versa, checking with all the numers works much faster - about 5 times. Its performance increasingly differs,
>>> time1(200000)
8.185129404067993
>>> time2(200000)
0.4998643398284912
Second method is outdoing it. What makes this different?
List = {2}
rather thanList = [2,]
and let us know.int()
to get the floor of a positive float number. Also, testing up toint(x ** 0.5) + 1
is enough, no need to go toint(x ** 0.5) + 2
.set
does change nothing.n^2
is much worse than(n log n)^1.5
(inn
primes produced). You can detect this by measuring empirical orders of growth (aslog(n2/n1) / log(t2/t1)
), or drawing a log-log plot of run times vs problem sizes.