It's a frequently asked question: *How do I extract 'the' value from my monad*, not only in Haskell, but in other languages as well. I have a theory about why this question keeps popping up, so I'll try to answer according to that; I hope it helps.

# Containers of single values

You can think of a *functor* (and therefore also a *monad*) as a **container** of values. This is most palpable with the (redundant) `Identity`

functor:

```
Prelude Control.Monad.Identity> Identity 42
Identity 42
```

This is nothing but a wrapper around a value, in this case `42`

. For this particular container, you *can* extract the value, because it's guaranteed to be there:

```
Prelude Control.Monad.Identity> runIdentity $ Identity 42
42
```

While `Identity`

seems fairly useless, you can find other functors that seem to wrap a single value. In F#, for example, you'll often encounter containers like `Async<'a>`

or `Lazy<'a>`

, which are used to represent asynchronous or lazy computations (Haskell doesn't need the latter, because it's lazy by default).

You'll find lots of other single-value containers in Haskell, such as `Sum`

, `Product`

, `Last`

, `First`

, `Max`

, `Min`

, etc. Common to all of those is that they wrap a single value, which means that you *can* extract the value.

I think that when people first encounter functors and monads, they tend to think of the concept of a *data container* in this way: as a container of a single value.

# Containers of optional values

Unfortunately, some common monads in Haskell seem to support that idea. For example, `Maybe`

is a data container as well, but one that can contain zero or one value. You can, unfortunately, still extract the value if it's there:

```
Prelude Data.Maybe> fromJust $ Just 42
42
```

The problem with this is that `fromJust`

isn't *total*, so it'll crash if you call it with a `Nothing`

value:

```
Prelude Data.Maybe> fromJust Nothing
*** Exception: Maybe.fromJust: Nothing
```

You can see the same sort of problem with `Either`

. Although I'm not aware of a built-in partial function to extract a `Right`

value, you can easily write one with pattern matching (if you ignore the compiler warning):

```
extractRight :: Either l r -> r
extractRight (Right x) = x
```

Again, it works in the 'happy path' scenario, but can just as easily crash:

```
Prelude> extractRight $ Right 42
42
Prelude> extractRight $ Left "foo"
*** Exception: <interactive>:12:1-26: Non-exhaustive patterns in function extractRight
```

Still, since functions like `fromJust`

exists, I suppose it tricks people new to the concept of functors and monads into thinking about them as data containers from which you can extract a value.

When you encounter something like `IO Int`

for the first time, then, I can understand why you'd be tempted to think of it as a container of a single value. In a sense, it is, but in another sense, it isn't.

# Containers of multiple values

Even with lists, you can (attempt to) extract 'the' value from a list:

```
Prelude> head [42..1337]
42
```

Still, it could fail:

```
Prelude> head []
*** Exception: Prelude.head: empty list
```

At this point, however, it should be clear that attempting to extract 'the' value from any arbitrary functor is nonsense. A list is a functor, but it contains an arbitrary number of values, including zero and infinitely many.

What you *can* always do, though, is to write functions that take a 'contained' value as input and returns another value as output. Here's an arbitrary example of such a function:

```
countAndMultiply :: Foldable t => (t a, Int) -> Int
countAndMultiply (xs, factor) = length xs * factor
```

While you can't 'extract *the* value' out of a list, you can apply your function to each of the values in a list:

```
Prelude> fmap countAndMultiply [("foo", 2), ("bar", 3), ("corge", 2)]
[6,9,10]
```

Since `IO`

is a functor, you can do the same with it as well:

```
Prelude> foo = return ("foo", 2) :: IO (String, Int)
Prelude> :t foo
foo :: IO (String, Int)
Prelude> fmap countAndMultiply foo
6
```

The point is that you don't extract a value from a functor, **you step into the functor**.

# Monad

Sometimes, the function you apply to a functor returns a value that's already wrapped in the same data container. As an example, you may have a function that splits a string over a particular character. To keep things simple, let's just look at the built-in function `words`

that splits a string into words:

```
Prelude> words "foo bar"
["foo","bar"]
```

If you have a list of strings, and apply `words`

to each, you'll get a nested list:

```
Prelude> fmap words ["foo bar", "baz qux"]
[["foo","bar"],["baz","qux"]]
```

The result is a nested data container, in this case a list of lists. You can flatten it with `join`

:

```
Prelude Control.Monad> join $ fmap words ["foo bar", "baz qux"]
["foo","bar","baz","qux"]
```

This is the original definition of a monad: it's a functor that you can flatten. In modern Haskell, `Monad`

is defined by *bind* (`>>=`

), from which one can derive `join`

, but it's also possible to derive `>>=`

from `join`

.

# IO as all values

At this point, you may be wondering: *what does that have to do with *`IO`

? Isn't `IO a`

a container of a single value of the type `a`

?

Not really. One *interpretation* of `IO`

is that it's a container that holds an arbitrary value of the type `a`

. According to that interpretation, it's analogous to the *many-worlds* interpretation of quantum mechanics. `IO a`

is the superposition of all possible values of the type `a`

.

In Schrödinger's original thought experiment, the cat in the box is both alive and dead until observed. That's two possible states superimposed. If we think about a variable called `catIsAlive`

, it would be equivalent to the superposition of `True`

and `False`

. So, you can think of `IO Bool`

as a set of possible values `{True, False}`

that will only collapse into a single value when observed.

Likewise, `IO Word8`

can be interpreted as a superposition of the set of all possible `Word8`

values, i.e. `{0, 1, 2,.. 255}`

, `IO Int`

as the superposition of all possible `Int`

values, `IO String`

as all possible `String`

values (i.e. an infinite set), and so on.

So how do you *observe* the value, then?

You don't extract it, you work *within* the data container. You can, as shown above, `fmap`

and `join`

over it. So, you can write your application as pure functions that you then compose with impure values with `fmap`

, `>>=`

, `join`

, and so on.

`a`

, and returns an`IO b`

, and so chain them together with`(>>=)`

. – Willem Van Onsem Jul 31 '18 at 13:30`IO`

monad. Take an RNG for an example why. – Dannyu NDos Jul 31 '18 at 13:55`IO`

,`f`

isn't pure, because you can't predict the return value of, for example,`f getLine`

. – chepner Jul 31 '18 at 14:48