A group extends the idea of a monoid to allow for inverses. This allows for:

```
gremove :: (Group a) => a -> a -> a
gremove x y = x `mappend` (invert y)
```

But what about structures like natural numbers, where there is no inverse? I'm thinking about:

```
class (Monoid a) => MRemove a where
mremove :: a -> a -> a
```

with laws:

```
x `mremove` x = mempty
x `mremove` mempty = x
(x `mappend` y) `mremove` y = x
```

And additionally:

```
class (MRemove a) => Group a where
invert :: a -> a
invert x = mempty `mremove` x
-- | For defining MRemove in terms of Group
defaultMRemove :: (Group a) => a -> a -> a
defaultMRemove x y = x `mappend` (invert y)
```

So, my question is: what is `MRemove`

?

anywayneed to define an extension of a given data type to allow for the`mremove`

to be total (to work always). If we allow for`mremove`

to diverge sometimes, we can allow for`invert`

to diverge always just the same, no? And if we perform extension and`mremove`

becomes total, so will`invert`

then. – Will Ness Feb 16 '13 at 19:16`mempty`

? A pseudo-subtraction on naturals that clips to zero is sensible and would seem to fit the requirements. – C. A. McCann Feb 16 '13 at 19:20`mremove`

would be set differencing and`mappend`

would be a union operation. That definition makes sense and is total without the need for the objects to form a group. – sabauma Feb 16 '13 at 19:24