Phillip JF's answer only applies to flat domains, but there are `Num`

instances which are not flat, for example the lazy naturals. When you go into this arena, things get quite subtle.

```
data Nat = Zero | Succ Nat
deriving (Show)
instance Num Nat where
x + Zero = x
x + Succ y = Succ (x + y)
x * Zero = Zero
x * Succ y = x + x * y
fromInteger 0 = Zero
fromInteger n = Succ (fromInteger (n-1))
-- we won't need the other definitions
```

It is especially important for lazy naturals that operations be least-strict, since that is the domain of their usage; e.g. we use them to compare lengths of possibly infinite lists, and if its operations are not least-strict, then that will diverge when there is useful information to be found.

As expected, `(+)`

is not commutative:

```
ghci> undefined + Succ undefined
Succ *** Exception: Prelude.undefined
ghci> Succ undefined + undefined
*** Exception: Prelude.undefined
```

So we will apply the standard trick to make it so:

```
laxPlus :: Nat -> Nat -> Nat
laxPlus a b = (a + b) `unamb` (b + a)
```

which seems to work, at first

```
ghci> undefined `laxPlus` Succ undefined
Succ *** Exception: Prelude.undefined
ghci> Succ undefined `laxPlus` undefined
Succ *** Exception: Prelude.undefined
```

but in fact it does not

```
ghci> Succ (Succ undefined) `laxPlus` Succ undefined
Succ (Succ *** Exception: Prelude.undefined
ghci> Succ undefined `laxPlus` Succ (Succ undefined)
Succ *** Exception: Prelude.undefined
```

This is because `Nat`

is not a flat domain, and `unamb`

only applies to flat domains. It is for this reason that I consider `unamb`

a low-level primitive that should not be used except to define higher level concepts -- it should be irrelevant whether a domain is flat. Using `unamb`

will be sensitive to refactors that change the domain structure -- the same reason `seq`

is semantically ugly. We need to generalize `unamb`

the same way `seq`

is generalized to `deeqSeq`

: this is done in the `Data.Lub`

module. We first need to write a `HasLub`

instance for `Nat`

:

```
instance HasLub Nat where
lub a b = unambs [
case a of
Zero -> Zero
Succ _ -> Succ (pa `lub` pb),
case b of
Zero -> Zero
Succ _ -> Succ (pa `lub` pb)
]
where
Succ pa = a
Succ pb = b
```

Assuming this is correct, which is not necessarily the case (it's my third try so far), we can now write `laxPlus'`

:

```
laxPlus' :: Nat -> Nat -> Nat
laxPlus' a b = (a + b) `lub` (b + a)
```

and it actually works:

```
ghci> Succ undefined `laxPlus'` Succ (Succ undefined)
Succ (Succ *** Exception: Prelude.undefined
ghci> Succ (Succ undefined) `laxPlus'` Succ undefined
Succ (Succ *** Exception: Prelude.undefined
```

So we are driven to generalize that the least-strict pattern for commutative binary operators is:

```
leastStrict :: (HasLub a) => (a -> a -> a) -> a -> a -> a
leastStrict f x y = f x y `lub` f y x
```

At the very least, it is guaranteed to be commutative. But, alas, there are further problems:

```
ghci> Succ (Succ undefined) `laxPlus'` Succ (Succ undefined)
Succ (Succ *** Exception: BothBottom
```

We expect the sum of two numbers which are at least 2 to be at least 4, but here we get a number which is only at least 2. I cannot come up with a way to modify `leastStrict`

to give us the result we want, at least not without introducing a new class constraint. To fix this problem, we need to dig into the recursive definition, and simultaneously pattern match on both arguments at every step:

```
laxPlus'' :: Nat -> Nat -> Nat
laxPlus'' a b = lubs [
case a of
Zero -> b
Succ a' -> Succ (a' `laxPlus''` b),
case b of
Zero -> a
Succ b' -> Succ (a `laxPlus''` b')
]
```

And *finally* we get one that gives as much information as possible, I believe:

```
ghci> Succ (Succ undefined) `laxPlus''` Succ (Succ undefined)
Succ (Succ (Succ (Succ *** Exception: BothBottom
```

If we apply the same pattern to times, we get something that seems to work as well:

```
laxMult :: Nat -> Nat -> Nat
laxMult a b = lubs [
case a of
Zero -> Zero
Succ a' -> b `laxPlus''` (a' `laxMult` b),
case b of
Zero -> Zero
Succ b' -> a `laxPlus''` (a `laxMult` b')
]
ghci> Succ (Succ undefined) `laxMult` Succ (Succ (Succ undefined))
Succ (Succ (Succ (Succ (Succ (Succ *** Exception: BothBottom
```

Needless to say, there is some repeated code here, and developing the patterns to express these functions as succinctly (and thus with as few opportunities for error) as possible would be an interesting exercise. However, we have another problem...

```
asLeast :: Nat -> Nat
atLeast Zero = undefined
atLeast (Succ n) = Succ (atLeast n)
ghci> atLeast 7 `laxMult` atLeast 7
Succ (Succ (Succ (Succ (Succ (Succ (Succ (Succ (Succ (Succ ^CInterrupted.
```

It is dreadfully slow. Clearly this is because it is (at least) exponential in the size of its arguments, descending into two branches on each recursion. It will require yet more subtlety to get it to run in reasonable time.

Least-strict programming is relatively unexplored territory, and there is necessity for more research, both in implementation and practical applications. I am excited by it and consider it promising territory.

`error`

. However, being able to recognize any bottom value would amount to solving the halting problem. What should happen if the first argument is a non-terminating computation? – sabauma Feb 16 '13 at 2:29