It depends how thorough you want to be. Besides the builtin types (`complex`

, `float`

, and `int`

) there are also other types that are considered numbers in python. For instance: `fractions.Fraction`

, `decimal.Decimal`

, and even `bool`

can act as a number. Then you get external libraries that have their own numeric types. By far the biggest is `numpy`

. With `numpy`

some of its types will succeed `isinstance`

checks, and other will not. For instance: `isinstance(numpy.float64(10), float)`

is true, but `isinstance(numpy.float32(10), float)`

is not.
On top of all this you could even have a user defined class that acts like a number.

Python does provide one way of getting around this -- the `numbers`

module. It provides several abstract types that represent different types of numbers. Any class that implements numeric functionality can register itself as being compatible with the relevant types. `numbers.Number`

is the most basic, and therefore the one you're looking for. All you have to do is use it in your `isinstance`

checks. eg.

```
from numbers import Number
from decimal import Decimal
from fractions import Fraction
import numpy
assert isinstance(1, Number)
assert isinstance(1.5, Number)
assert isinstance(1+5j, Number)
assert isinstance(True, Number)
assert isinstance(Decimal("1.23"), Number)
assert isinstance(Fraction(1, 2), Number)
assert isinstance(numpy.float64(10), Number)
assert isinstance(numpy.float32(10), Number)
assert isinstance(numpy.int32(10), Number)
assert isinstance(numpy.uint32(10), Number)
```

That still leaves us with the problem about whether the object is actually a number, rather than "not a number". The `math.isnan`

function is good for this, but it requires that the number be convertible to a float (which not all numbers are). The big problem here is the `complex`

type. There are a few ways around this: additional `isinstance`

checks (but that comes with its own headaches), using `abs`

, or testing for equality.

`abs`

can be used on every numeric type (that I can think of). For most numbers it returns the positive version of the number, but for complex numbers it returns its magnitude (a float). So now we can do that `isnan`

check. `nan`

is also a special number in that it is the only number that is not equal to itself.

This means your final check might look like:

```
import math
import numbers
def number_is_not_nan(n):
return isinstance(n, numbers.Number) and not math.isnan(abs(n))
def number_is_finite(n):
return isinstance(n, numbers.Number) and not math.isfinite(abs(n))
```

`float('nan') < 1.0e-12`

(for example) does not behave in the way I want. I want it to stop the execution or at least to be evaluated as`False`

. – norio Sep 8 '16 at 17:20