Suppose that F is an applicative functor with the additional laws (with Haskell syntax):

`pure (const ()) <*> m`

===`pure ()`

`pure (\a b -> (a, b)) <*> m <*> n`

===`pure (\a b -> (b, a)) <*> n <*> m`

`pure (\a b -> (a, b)) <*> m <*> m`

===`pure (\a -> (a, a)) <*> m`

What is the structure called if we omit (3.)?

Where can I find more info on these laws/structures?

## Comments on comments

Functors which satisfy (2.) are often called commutative.

The question is now, whether (1.) implies (2.) and how these structures can be described. I am especially interested in structures which satisfies (1-2.) but not (3.)

Examples:

- The reader monad satisfies (1-3.)
- The writer monad on a commutative monoid satisfies only (2.)
- The monad
`F`

given below satisfies (1-2.) but not (3.)

Definition of `F`

:

```
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE RankNTypes #-}
import Control.Monad.State
newtype X i = X Integer deriving (Eq)
newtype F i a = F (State Integer a) deriving (Monad)
new :: F i (X i)
new = F $ modify (+1) >> gets X
evalF :: (forall i . F i a) -> a
evalF (F m) = evalState m 0
```

We export only the types `X`

, `F`

, `new`

, `evalF`

, and the instances.

Check that the following holds:

`liftM (const ()) m`

===`return ()`

`liftM2 (\a b -> (a, b)) m n`

===`liftM2 (\a b -> (b, a)) n m`

On the other hand, `liftM2 (,) new new`

cannot be replaced by `liftM (\a -> (a,a)) new`

:

```
test = evalF (liftM (uncurry (==)) $ liftM2 (,) new new)
/= evalF (liftM (uncurry (==)) $ liftM (\a -> (a,a)) new)
```

## Comments on C. A. McCann's answer

I have a sketch of proof that (1.) implies (2.)

```
pure (,) <*> m <*> n
```

=

```
pure (const id) <*> pure () <*> (pure (,) <*> m <*> n)
```

=

```
pure (const id) <*> (pure (const ()) <*> n) <*> (pure (,) <*> m <*> n)
```

=

```
pure (.) <*> pure (const id) <*> pure (const ()) <*> n <*> (pure (,) <*> m <*> n)
```

=

```
pure const <*> n <*> (pure (,) <*> m <*> n)
```

= ... =

```
pure (\_ a b -> (a, b)) <*> n <*> m <*> n
```

= see below =

```
pure (\b a _ -> (a, b)) <*> n <*> m <*> n
```

= ... =

```
pure (\b a -> (a, b)) <*> n <*> m
```

=

```
pure (flip (,)) <*> n <*> m
```

**Observation**

For the missing part first consider

```
pure (\_ _ b -> b) <*> n <*> m <*> n
```

= ... =

```
pure (\_ b -> b) <*> n <*> n
```

= ... =

```
pure (\b -> b) <*> n
```

= ... =

```
pure (\b _ -> b) <*> n <*> n
```

= ... =

```
pure (\b _ _ -> b) <*> n <*> m <*> n
```

**Lemma**

We use the following lemma:

```
pure f1 <*> m === pure g1 <*> m
pure f2 <*> m === pure g2 <*> m
```

implies

```
pure (\x -> (f1 x, f2 x)) m === pure (\x -> (g1 x, g2 x)) m
```

I could prove this lemma only indirectly.

**The missing part**

With this lemma and the first observation we can prove

```
pure (\_ a b -> (a, b)) <*> n <*> m <*> n
```

=

```
pure (\b a _ -> (a, b)) <*> n <*> m <*> n
```

which was the missing part.

**Questions**

Is this proved already somewhere (maybe in a generalized form)?

## Remarks

(1.) implies (2.) but otherwise (1-3.) are independent.

To prove this, we need two more examples:

- The monad
`G`

given below satisfies (3.) but not (1-2.) - The monad
`G'`

given below satisfies (2-3.) but not (1.)

Definition of `G`

:

```
newtype G a = G (State Bool a) deriving (Monad)
putTrue :: G ()
putTrue = G $ put True
getBool :: G Bool
getBool = G get
evalG :: G a -> a
evalG (G m) = evalState m False
```

We export only the type `G`

, `putTrue`

, `getBool`

, `evalG`

, and the `Monad`

instance.

The definition of `G'`

is similar to the definition of `G`

with the following differences:

We define and export `execG`

:

```
execG :: G' a -> Bool
execG (G m) = execState m False
```

We do **not export** `getBool`

.

`IO`

with the only operations`newIORef`

,`readIORef`

and`writeIORef`

satisfies 1-2 but doesn't satisfy 3. The reader monad satisfies all. – Péter Diviánszky Apr 20 '13 at 18:31`pure f <*> m <*> n === pure (flip f) <*> n <*> m`

. Functors which satisfy this are often called commutative. – hammar Apr 20 '13 at 19:05`pure (const ()) <*> writeIORef r x !== pure ()`

? – Niklas B. Apr 20 '13 at 19:20`IO`

with the only operations`newIORef`

,`readIORef`

, and equality on`IORef`

s satisfies 1-2 but not 3. – Péter Diviánszky Apr 20 '13 at 19:25