## Quick Check

From the signatures, we can tell that they are different:

**pow(x, y[, z])**

**math.pow(x, y)**

Also, trying it in the shell will give you a quick idea:

```
>>> pow is math.pow
False
```

## Testing the differences

Another way to understand the differences in behaviour between the two functions is to test for them:

```
import math
import traceback
import sys
inf = float("inf")
NaN = float("nan")
vals = [inf, NaN, 0.0, 1.0, 2.2, -1.0, -0.0, -2.2, -inf, 1, 0, 2]
tests = set([])
for vala in vals:
for valb in vals:
tests.add( (vala, valb) )
tests.add( (valb, vala) )
for a,b in tests:
print("math.pow(%f,%f)"%(a,b) )
try:
print(" %f "%math.pow(a,b))
except:
traceback.print_exc()
print("__builtins__.pow(%f,%f)"%(a,b) )
try:
print(" %f "%__builtins__.pow(a,b))
except:
traceback.print_exc()
```

We can then notice some subtle differences. For example:

```
math.pow(0.000000,-2.200000)
ValueError: math domain error
__builtins__.pow(0.000000,-2.200000)
ZeroDivisionError: 0.0 cannot be raised to a negative power
```

There are other differences, and the test list above is not complete (no long numbers, no complex, etc...), but this will give us a pragmatic list of how the two functions behave differently. I would also recommend extending the above test to check for the type that each function returns. You could probably write something similar that creates a report of the differences between the two functions.

`math.pow()`

`math.pow()`

handles its arguments very differently from the builtin `**`

or `pow()`

. This comes at the cost of flexibility. Having a look at the source, we can see that the arguments to `math.pow()`

are **cast directly to doubles**:

```
static PyObject *
math_pow(PyObject *self, PyObject *args)
{
PyObject *ox, *oy;
double r, x, y;
int odd_y;
if (! PyArg_UnpackTuple(args, "pow", 2, 2, &ox, &oy))
return NULL;
x = PyFloat_AsDouble(ox);
y = PyFloat_AsDouble(oy);
/*...*/
```

The checks are then carried out against the doubles for validity, and then the result is passed to the underlying C math library.

## builtin `pow()`

The built-in `pow()`

(same as the `**`

operator) on the other hand behaves very differently, it actually uses the Objects's own implementation of the `**`

operator, which can be overridden by the end user if need be by replacing a number's `__pow__()`

, `__rpow__()`

or `__ipow__()`

, method.

For built-in types, it is instructive to study the difference between the power function implemented for two numeric types, for example, floats, long and complex.

## Overriding the default behaviour

Emulating numeric types is described here. essentially, if you are creating a new type for numbers with uncertainty, what you will have to do is provide the `__pow__()`

, `__rpow__()`

and possibly `__ipow__()`

methods for your type. This will allow your numbers to be used with the operator:

```
class Uncertain:
def __init__(self, x, delta=0):
self.delta = delta
self.x = x
def __pow__(self, other):
return Uncertain(
self.x**other.x,
Uncertain._propagate_power(self, other)
)
@staticmethod
def _propagate_power(A, B):
return math.sqrt(
((B.x*(A.x**(B.x-1)))**2)*A.delta*A.delta +
(((A.x**B.x)*math.log(B.x))**2)*B.delta*B.delta
)
```

In order to override `math.pow()`

you will have to monkey patch it to support your new type:

```
def new_pow(a,b):
_a = Uncertain(a)
_b = Uncertain(b)
return _a ** _b
math.pow = new_pow
```

Note that for this to work you'll have to wrangle the `Uncertain`

class to cope with an `Uncertain`

instance as an input to `__init__()`