A pure python implementation can be found in the mpmath module (http://code.google.com/p/mpmath/)

From the doc string:

```
>>> from mpmath import *
>>> mp.dps = 15
>>> print erf(0)
0.0
>>> print erf(1)
0.842700792949715
>>> print erf(-1)
-0.842700792949715
>>> print erf(inf)
1.0
>>> print erf(-inf)
-1.0
```

For large real `x`

, `\mathrm{erf}(x)`

approaches 1 very
rapidly::

```
>>> print erf(3)
0.999977909503001
>>> print erf(5)
0.999999999998463
```

The error function is an odd function::

```
>>> nprint(chop(taylor(erf, 0, 5)))
[0.0, 1.12838, 0.0, -0.376126, 0.0, 0.112838]
```

:func:`erf`

implements arbitrary-precision evaluation and
supports complex numbers::

```
>>> mp.dps = 50
>>> print erf(0.5)
0.52049987781304653768274665389196452873645157575796
>>> mp.dps = 25
>>> print erf(1+j)
(1.316151281697947644880271 + 0.1904534692378346862841089j)
```

**Related functions**

See also :func:`erfc`

, which is more accurate for large `x`

,
and :func:`erfi`

which gives the antiderivative of
`\exp(t^2)`

.

The Fresnel integrals :func:`fresnels`

and :func:`fresnelc`

are also related to the error function.