Using the power operator `**`

will be faster as it won’t have the overhead of a function call. You can see this if you disassemble the Python code:

```
>>> dis.dis('7. ** i')
1 0 LOAD_CONST 0 (7.0)
3 LOAD_NAME 0 (i)
6 BINARY_POWER
7 RETURN_VALUE
>>> dis.dis('pow(7., i)')
1 0 LOAD_NAME 0 (pow)
3 LOAD_CONST 0 (7.0)
6 LOAD_NAME 1 (i)
9 CALL_FUNCTION 2 (2 positional, 0 keyword pair)
12 RETURN_VALUE
>>> dis.dis('math.pow(7, i)')
1 0 LOAD_NAME 0 (math)
3 LOAD_ATTR 1 (pow)
6 LOAD_CONST 0 (7)
9 LOAD_NAME 2 (i)
12 CALL_FUNCTION 2 (2 positional, 0 keyword pair)
15 RETURN_VALUE
```

Note that I’m using a variable `i`

as the exponent here because constant expressions like `7. ** 5`

are actually evaluated at compile time.

Now, in practice, this difference does not matter that much, as you can see when timing it:

```
>>> from timeit import timeit
>>> timeit('7. ** i', setup='i = 5')
0.2894785532627111
>>> timeit('pow(7., i)', setup='i = 5')
0.41218495570683444
>>> timeit('math.pow(7, i)', setup='import math; i = 5')
0.5655053168791255
```

So, while `pow`

and `math.pow`

are about twice as slow, they are still fast enough to not care much. Unless you can actually identify the exponentiation as a bottleneck, there won’t be a reason to choose one method over the other if clarity decreases. This especially applies since `pow`

offers an integrated modulo operation for example.

Alfe asked a good question in the comments above:

`timeit`

shows that `math.pow`

is slower than `**`

in all cases. What is `math.pow()`

good for anyway? Has anybody an idea where it can be of any advantage then?

The big difference of `math.pow`

to both the builtin `pow`

and the power operator `**`

is that it *always* uses float semantics. So if you, for some reason, want to make sure you get a float as a result back, then `math.pow`

will ensure this property.

Let’s think of an example: We have two numbers, `i`

and `j`

, and have no idea if they are floats or integers. But we want to have a float result of `i^j`

. So what options do we have?

- We can convert at least one of the arguments to a float and then do
`i ** j`

.
- We can do
`i ** j`

and convert the result to a float (float exponentation is automatically used when either `i`

or `j`

are floats, so the result is the same).
- We can use
`math.pow`

.

So, let’s test this:

```
>>> timeit('float(i) ** j', setup='i, j = 7, 5')
0.7610865891750791
>>> timeit('i ** float(j)', setup='i, j = 7, 5')
0.7930400942188385
>>> timeit('float(i ** j)', setup='i, j = 7, 5')
0.8946636625872202
>>> timeit('math.pow(i, j)', setup='import math; i, j = 7, 5')
0.5699394063529439
```

As you can see, `math.pow`

is actually faster! And if you think about it, the overhead from the function call is also gone now, because in all the other alternatives we have to call `float()`

.

In addition, it might be worth to note that the behavior of `**`

and `pow`

can be overridden by implementing the special `__pow__`

(and `__rpow__`

) method for custom types. So if you don’t want that (for whatever reason), using `math.pow`

won’t do that.

`timeit`

to find out?`timeit`

shows that`math.pow`

is slower than`**`

in all cases. What is`math.pow()`

good for anyway? Has anybody an idea where it can be of any advantage then?`in all cases`

? I see cases where`math.pow`

is much faster.`pow`

with`math.pow`

, but I'm talking about a comparison of`math.pow`

with the`**`

operator. Your comparison there can be completed by adding that third version, then`**`

again beats every other option:`import timeit; print timeit.timeit("math.pow(2, 100)",setup='import math'), timeit.timeit("pow(2, 100)"), timeit.timeit("2 ** 100")`

→`0.170357942581 1.00546097755 0.013473033905`

.`math.pow`

alwaysreturns a`float`

(also for`int`

input) while`**`

returns the type of its input (well, mixed input results in`float`

). But that's still no good reason to use`math.pow`

, IMHO.4more comments