The reason that `div`

does not return `Infinity`

is simple--there is no representation for infinity in the `Integer`

type.

`/`

returns `Infinity`

because it follows the IEEE 754 standard (which describes floating point number representations) since the default `Fractional`

type is `Double`

. Other languages with floating point numbers (e.g. JavaScript) also exhibit this behavior.

To make mathematicians cringe even more, you get a different result if you divide by *negative* 0, despite the fact that `-0 == 0`

for floats:

```
Prelude> 1/(-0)
-Infinity
```

This is also behavior from the standard.

If you use a different fractional type like `Rational`

, you will get the behavior you expect:

```
Prelude> 1 / (0 :: Rational)
*** Exception: Ratio.%: zero denominator
```

Coincidentally, if you're wondering about why `Integer`

and `Double`

are the types in question when your actual operation does not reference them, take a look at how Haskell handles defaulting types (especially numeric types) in the report.

The short version is that if you have an ambiguous type from the `Num`

class, Haskell will first try `Integer`

and then `Double`

for that type. You can change this with a `default (Type1, Type2...)`

statement or turn it off with a `default ()`

statement at the module level.

`1 / 0`

be`Infinity`

is completely justified. It is not the only justifiable return value, but the one that makes the most sense. Note that you will also get a`divide by zero`

error if you evaluate`1 / 0 :: Rational`

. – Daniel Fischer Feb 19 '12 at 23:04`NaN`

s! (E.g.`(0/0) /= (0/0)`

. – Tikhon Jelvis Feb 19 '12 at 23:22`1/0`

. But Alexandrov compactification also destroys many useful properties of ℝ - not to mention Čech compactification. – Daniel Fischer Feb 19 '12 at 23:25