There's a common notion that one sees in many programming languages of an "infectious function tag" -- some special behavior for a function that must extend to its callers as well.

- Rust functions can be
`unsafe`

, meaning they perform operations that can potentially violate memory unsafety. `unsafe`

functions can call normal functions, but any function that calls an `unsafe`

function must be `unsafe`

as well.
- Python functions can be
`async`

, meaning they return a promise rather than an actual value. `async`

functions can call normal functions, but invocation of an `async`

function (via `await`

) can only be done by another `async`

function.
- Haskell functions can be
*impure*, meaning they return an `IO a`

rather than an `a`

. Impure functions can call pure functions, but impure functions can only be called by other impure functions.
- Mathematical functions can be
*partial*, meaning they don't map every value in their domain to an output. The definitions of partial functions can reference total functions, but if a total function maps some of its domain to a partial function, it becomes partial as well.

While there may be ways to invoke a tagged function from an untagged function, there is no *general* way, and doing so can often be dangerous and threatens to break the abstraction the language tries to provide.

The benefit, then, of having tags is that you can expose a set of special primitives that are given this tag and have any function that uses these primitives make that clear in its signature.

Say you're a language designer and you recognize this pattern, and you decide that you want to allow user-defined tags. Let's say the user defined a tag `Err`

, representing computations that may throw an error. A function using `Err`

might look like this:

```
function div <Err> (n: Int, d: Int): Int
if d == 0
throwError("division by 0")
else
return (n / d)
```

If we wanted to simplify things, we might observe that there's nothing erroneous about taking arguments - it's computing the return value where problems might arise. So we can restrict tags to functions that take no arguments, and have `div`

return a closure rather than the actual value:

```
function div(n: Int, d: Int): <Err> () -> Int
() =>
if d == 0
throwError("division by 0")
else
return (n / d)
```

In a lazy language such as Haskell, we don't need the closure, and can just return a lazy value directly:

```
div :: Int -> Int -> Err Int
div _ 0 = throwError "division by 0"
div n d = return $ n / d
```

It is now apparent that, in Haskell, tags need no special language support - they are ordinary type constructors. Let's make a typeclass for them!

```
class Tag m where
```

We want to be able to call an untagged function from a tagged function, which is equivalent to turning an untagged value (`a`

) into a tagged value (`m a`

).

```
addTag :: a -> m a
```

We also want to be able to take a tagged value (`m a`

) and apply a tagged function (`a -> m b`

) to get a tagged result (`m b`

):

```
embed :: m a -> (a -> m b) -> m b
```

This, of course, is precisely the definition of a monad! `addTag`

corresponds to `return`

, and `embed`

corresponds to `(>>=)`

.

It is now clear that "tagged functions" are merely a type of monad. As such, whenever you spot a place where a "function tag" could apply, chances are you've got a place suitable for a monad.

P.S. Regarding the tags I've mentioned in this answer: Haskell models impurity with the `IO`

monad and partiality with the `Maybe`

monad. Most languages implement async/promises fairly transparently, and there seems to be a Haskell package called promise that mimics this functionality. The `Err`

monad is equivalent to the `Either String`

monad. I'm not aware of any language that models memory unsafety monadically, it could be done.