# How to generate exponentially increasing range in Python

I want to test the performance of some code using an exponentially increasing value. So that as an extra digit is added to the numbers_size the increment is multiplied by 10. This is how I'm doing it so far but it looks a bit hacky. Suggestions for improvements without introducing non-standard libraries?

``````numbers_size = 100
increment = 100
numbers_range = 1000000000
while numbers_size < numbers_range:
t = time.time()
test( numbers_size )
taken_t = time.time() - t
print numbers_size, test, taken_t

increment = 10 ** (len(str(numbers_size))-1)
numbers_size += increment
``````
• You've got answers, but can I please ask why? – Jon Clements Jul 12 '12 at 1:39
• To see the difference of searching lists and dictionaries for a talk I'm giving on Python performance tips. – Martlark Jul 20 '12 at 9:54

To produce the same numbers as your code:

``````numbers_sizes = (i*10**exp for exp in range(2, 9) for i in range(1, 10))
for n in numbers_sizes:
test(n)
``````

If you consider numpy as one of the standards ;), you may use numpy.logspace since that is what it exactly what its supposed to do.... (note: 100=10^2, 1000000000=10^9)

``````for n in numpy.logspace(2,9,num=9-2, endpoint=False):
test(n)
``````

example 2 (note: 100=10^2, 1000000000=10^9, want to go at a step 10x, it is 9-2+1 points...):

``````In: np.logspace(2,9,num=9-2+1,base=10,dtype='int')
Out:
array([       100,       1000,      10000,     100000,    1000000,
10000000,  100000000, 1000000000])
``````

example 3:

``````In: np.logspace(2,9,dtype='int')
Out:
array([       100,        138,        193,        268,        372,
517,        719,       1000,       1389,       1930,
2682,       3727,       5179,       7196,      10000,
13894,      19306,      26826,      37275,      51794,
71968,     100000,     138949,     193069,     268269,
372759,     517947,     719685,    1000000,    1389495,
1930697,    2682695,    3727593,    5179474,    7196856,
10000000,   13894954,   19306977,   26826957,   37275937,
51794746,   71968567,  100000000,  138949549,  193069772,
268269579,  372759372,  517947467,  719685673, 1000000000])
``````

on your case, we use `endpoint=False` since you want not to include the endpoint... (e.g. `np.logspace(2,9,num=9-2, endpoint=False)` )

Why not

``````for exponent in range(2, 10):
test(10 ** exponent)
``````

I like Ned Batcheldor's answer, but I would make it a bit more general:

``````def exp_range(start, end, mul):
while start < end:
yield start
start *= mul
``````

``````for sz in exp_range(100, 1000000000, 10):
t = time.time()
test(sz)
print sz, test(sz), time.time()-t
``````

The simplest thing to do is to use a linear sequence of exponents:

``````for e in range(1, 90):
i = int(10**(e/10.0))
test(i)
``````

You can abstract the sequence into its own generator:

``````def exponent_range(max, nsteps):
max_e = math.log10(max)
for e in xrange(1, nsteps+1):
yield int(10**(e*max_e/nsteps))

for i in exponent_range(10**9, nsteps=100):
test(i)
``````

OP wrote "Suggestions for improvements without introducing non-standard libraries?"

Just for completeness, here's a recipe for generating exponential ranges - each element is a fixed factor bigger than the previous:

``````from math import exp
from math import log

def frange(start, stop, numelements):
"""range function for floats"""
incr = (stop - start) / numelements
return (start + x * incr for x in range(numelements))

def exprange(start, stop, numelements):
"""exponential range - each element is a fixed factor bigger than the previous"""
return (exp(x) for x in frange(log(start), log(stop), numelements))
``````

Test:

``````print(", ".join("%.3f" % x for x in exprange(3,81,6)))
``````

Output:

``````3.000, 5.196, 9.000, 15.588, 27.000, 46.765
``````

Using a generator expression:

``````max_exponent = 100
for i in (10**n for n in xrange(1, max_exponent)):
test(i)
``````

example of 'NOT reading the question properly' and 'NOT how to do it'

``````for i in xrange(100, 1000000000, 100):
# timer
test(i)
# whatever
``````

Is about as simple as it gets... adjust `xrange` accordingly

• this was downvoted (though not by me) presumably because your range is linear, not exponential. – msw Jul 12 '12 at 1:14
• @msw Fair point and well made - thank you, I'll stick by my mistake (the read the question properly and not how to do it) though so it stays in the community for reference purposes. – Jon Clements Jul 12 '12 at 1:23
• I serially upvoted some of your older answers that I thought merited it for two reasons: mostly I hate "drive-by" downvoters who don't bother explaining and I appreciate newcomers who contribute. As to why the OP is doing it the really hard way, I share your puzzlement but don't expect we'll hear back on that one. – msw Jul 12 '12 at 3:28
• @msw Much appreciated - although unnecessary of course :) I only discovered SO because I wanted to ask a question on pandas, and there was no mailing list/contact I could find apart from here. Then, kinda got hooked, and it's always a pleasure to share what I know, and great to learn things I didn't know :) And if I get it wrong, fine, I get it wrong -- I'll take it on the chin - I don't take it personally anyway... but thanks :) – Jon Clements Jul 12 '12 at 3:39