# Does the base for logarithmic calculations in Python influence the speed?

I have to use a lot of logarithmic calculations in one program. In terms of the logarithmic base, the procedure is not specific. I was wondering, if any base `n` (2? 10? e?) is faster in the Python 3.5 `math` module than others, because maybe under the hood all other bases `a` are transformed into `log_a(x) = log_n(x)/log_n(a)`. Or does the choice of the base not influence the speed of the calculation, because all bases are implemented in the same way using a C library?

• Possible duplicate of Where can I inspect Python's math functions? Dec 18 '17 at 16:57
• Are you using `numpy` or another library? Are you functions using vectors/vectorized methods?
– Jon
Dec 18 '17 at 17:00
• You could try to do some benchmarking yourself, but depending on your code it is likely that, even if there is any difference at all, it will be largely eclipsed by other types of overhead. Dec 18 '17 at 17:01
• On x86 the instruction for calculating log has a multiplier built in, so the base doesn't matter at all - at least for compiled code. Since Python is interpreted I'm not sure if that applies. Dec 18 '17 at 17:14
• In this specific case it looks like `math.log` uses C's standard library `log` function, so speed will depend on the platform. Dec 18 '17 at 17:17

In CPython, `math.log` is base independent, but platform dependent. From the C source for the `math` module, on lines 1940-1961, the code for `math.log` is shown.

``````math_log_impl(PyObject *module, PyObject *x, int group_right_1,
PyObject *base)
/*[clinic end generated code: output=7b5a39e526b73fc9 input=0f62d5726cbfebbd]*/

{
PyObject *num, *den;
PyObject *ans;

num = loghelper(x, m_log, "log"); // uses stdlib log
if (num == NULL || base == NULL)
return num;

den = loghelper(base, m_log, "log"); // uses stdlib log
if (den == NULL) {
Py_DECREF(num);
return NULL;
}

ans = PyNumber_TrueDivide(num, den);
Py_DECREF(num);
Py_DECREF(den);
return ans;
}
``````

This, no matter what, calculates the natural log of the number and base, so unless the C `log` function has a special check for `e`, it will run at the same speed.

This source also explains the other answer's `log2` and `log10` being faster than `log`. They are implemented using the standard library `log2` and `log10` functions respectively, which will be faster. These functions, however, are defined differently depending on the platform.

Note: I am not very familiar with C so I may be wrong here.

• I am not in the position to interpret the C code. But I understand from this that `log(x), log2(x), log10(x)` should have the same speed, because they use the same C library strategies. And `log(x, n)` is slower, because it uses the logarithmic formula from my question. Dec 18 '17 at 18:43

Interesting question. I did some "good old" field test (CPython 3.6.2 on Linux, x86_64, i7-3740QM CPU - Python interpreter compiled with all optimizations available for this CPU turned ON).

``````>>> math.log10(3)
0.47712125471966244
>>> math.log(3, 10)
0.47712125471966244
>>> timeit.timeit('math.log(3, 10)', setup = 'import math')
0.2496643289923668
>>> timeit.timeit('math.log10(3)', setup = 'import math')
0.14756392200069968
``````

Log10 is clearly faster than log(n, 10).

``````>>> math.log2(3.0)
1.584962500721156
>>> math.log(3.0, 2.0)
1.5849625007211563
>>> timeit.timeit('math.log2(3.0)', setup = 'import math')
0.16744944200036116
>>> timeit.timeit('math.log(3.0, 2.0)', setup = 'import math')
0.22228705599263776
``````

Log2 is also clearly faster than log(n, 2). Btw, either way, floats and ints are equally fast.

With `numpy`, the picture is different. It kind of does not matter what you do:

``````>>> timeit.timeit('numpy.log(numpy.arange(1, 10))', setup = 'import numpy')
2.725074506000965
>>> timeit.timeit('numpy.log10(numpy.arange(1, 10))', setup = 'import numpy')
2.613872367001022
>>> timeit.timeit('numpy.log2(numpy.arange(1, 10))', setup = 'import numpy')
2.58251854799164
``````