In get's type signature: MonadState s m => m s, how does [1,2,3] have
a type of MonadState s m? It's not clear to me what the types of s and
m are.

```
ghci> runState get [1,2,3]
```

The function `runState`

takes two arguments: the first is the `State`

action to run, and the second is the initial state. So, since the initial state is `[1,2,3]`

which is a list of integers (*), the state type `s`

is just `[Integer]`

.

(*) Actually, `[1,2,3] :: Num a => [a]`

before GHCi defaults it, but for simplicity's sake let's use `[Integer]`

as GHCi does.

Hence, we see that `runState`

is specialized to

```
runState :: State [Integer] a -> [Integer] -> (a, [Integer])
```

Now, about the first argument:

```
get :: MonadState s m => m s
```

We must have `m s = State s a`

because we are passing it to `runState`

which requires such type. Hence:

```
runState :: State [Integer] a -> [Integer] -> (a, [Integer])
get :: MonadState s m => m s
with m s = State [Integer] a
```

The latter equation can be simplified as follows:

```
runState :: State [Integer] a -> [Integer] -> (a, [Integer])
get :: MonadState s m => m s
with m = State [Integer]
and s = a
```

Substituting `s`

:

```
runState :: State [Integer] a -> [Integer] -> (a, [Integer])
get :: MonadState a m => m a
with m = State [Integer]
```

Substituting `m`

:

```
runState :: State [Integer] a -> [Integer] -> (a, [Integer])
get :: MonadState a (State [Integer]) => State [Integer] a
```

Now, the constraint `MonadState a (State [Integer])`

is satisfied only when `a = [Integer]`

. This is tricky to see, since the `MonasState`

type class exploits a functional dependency to enforce that every monad in that class has only one related state type. This is also made more complex from `State`

being a wrapper around `StateT`

. Anyway, we get:

```
runState :: State [Integer] a -> [Integer] -> (a, [Integer])
get :: MonadState a (State [Integer]) => State [Integer] a
with a = [Integer]
```

So,

```
runState :: State [Integer] [Integer] -> [Integer] -> ([Integer], [Integer])
get :: MonadState [Integer] (State [Integer]) => State [Integer] [Integer]
```

And since the constraint is satisfied:

```
runState :: State [Integer] [Integer] -> [Integer] -> ([Integer], [Integer])
get :: State [Integer] [Integer]
```

And now we can see the involved ground types.

`MonadState`

is a type class. No value has type`MonadState s m`

.`MonadState s m`

means the monad`m`

supports state operations with state of type`s`

. So`MonadState s m => s -> m ()`

is a function that takes a value of type`s`

and returns apolymorphicvalue representingany monadwhich supports state operations over a state of type`s`

.`get`

reads approximatley as "for all m which supports state operations over state of type s, we have a value of type`m s`

- that is, the monad operation which yields the current state". – user2407038 Aug 22 '14 at 2:14