I have encountered a very curious case of a massive speed-up in code after changing a seemingly minor detail. I have the following code, which is an implementation of Borwein's algorithm for computing the factorial, implemented in SageMath (but apart from some minor things, like ^
for exponentiation, it should work in pure Python 2.7)
def sieve(n): #My implementation of the sieve of Eratosthenes
T = [1]*n
for i in xrange(2,n):
if T[i]==1:
for j in xrange(2,ceil(n/i)):
T[i*j]=0
return [i for i in xrange(2,n) if T[i]]
def expp(n,p): #Exponent of p in the factorization of n!
k = p
s = 0
while k<=n:
s += n//k
k = k*p
return s
def quick_prod(T): #Computing product of the elements of an array using binary splitting
if len(T)==1:
return T[0]
if len(T)==2:
return T[0]*T[1]
if len(T)>2:
s = len(T)//2
return quick_prod(T[0:s])*quick_prod(T[s:len(T)])
n = 10^6
P = sieve(n) #Array of primes up to n
exps = [expp(n,p) for p in P] #exponents of all primes in P
l = len(bin(abs(n)))-2
nums = [quick_prod([P[j] for j in xrange(len(P)) if (exps[j] >> i)%2])^(2^i) for i in range(l)] #Array of numbers appearing in Borwein's algorithm, whose product is n!
quick_prod(nums)
(Excuse my awful naming conventions (and probably other poor coding practices), I am an amateur and only really code things "quick and dirty")
I did not expect this code to be particularly efficient, so I was not surprised to see it took 10 minutes to run. But when I've started tinkering with the code to try and improve it, I've noticed that replacing the line P = sieve(n)
with P = prime_range(n)
(which produces the same array, except it uses a function which is built-in in SageMath) decreased the run time to 3.5 seconds.
Now, when I saw this, my first thought was that the explanation is obvious - my implementation of the sieve must be so horrible it took ages, and prime_range
does this so much more efficiently. But the results have surprised me - sieve(10^6)
took 4 seconds, while prime_range(10^6)
took 2 seconds. This is not even close to explaining the difference of 10 minutes!
Some of the ideas me and my friends had which could possibly explain it:
- The two arrays may be different, e.g. they may be ordered differently. This is not the case, as
sieve(10^6)==prime_range(10^6)
returnsTrue
- Despite the equality, the arrays may be stored as different types.
type(...)
returnslist
for both. - Intermediate results getting cached. Probably not the case, since the results are approximately the same regardless of compilation order, even after restarting the kernel.
The only way such a massive speed-up (or slow-down, depending how you look at it) could come to be is if the original code somehow returned to the way P was generated after computing it. What could possibly explain this behavior?
[list comprehension expression]
by(list comprehension expression)
and it would stop to spawning a lot of lists in the ramT = [1]*n
forn = 10^6
will spawn10^6
references, or more!?10^6
is 12, not 1000000 I just get couch by this^
by default denotes exponentiation, not bitwise XOR (as I mention in the first paragraph). I will try your suggestion from the first comment when I get a chance.prime_range
docs say that it returns a list of Sage Integers rather than Python ints. What performance do you see if you passpy_ints=True
toprime_range
, which causes it to return a list of Python ints?