There are lots of implementations of monads in dynamically typed languages:

In general, the Church-Turing-Thesis tells us that everything that can be done in *one* language can also be done in *every other* language.

As you can probably tell from the selection of examples above, I am (mostly) a Ruby programmer. So, just as a joke, I took one of the examples above and re-implemented it in a language that I know *absolutely nothing* about, that is usually thought of as a not very powerful language, and that seems to be the only programming language on the planet for which I was not able to find a Monad tutorial. May I present to you … the Identity Monad in PHP:

```
<?php
class Identity {
protected $val;
public function __construct($val) { $this->val = $val; }
public static function m_return($a) { return new Identity($a); }
public static function m_bind($id_a, $f) { return $f($id_a->val); }
}
var_dump(Identity::m_bind(
Identity::m_return(1), function ($x) {
return Identity::m_return($x+1);
}
));
?>
```

No static types, no generics, no closures necessary.

Now, if you actually want to statically check monads, then you need a static type system. But that is more or less a tautology: if you want to statically check types, you need a static type checker. Duh.

With regards to your question:

In my understanding, the language implementing monad should be type-checked statically. Otherwise, type errors cannot be found during compilation and "Complexity" is not controlled. Is my understanding correct?

You are right, but this has nothing to do with monads. This is just about static type checking in general, and applies equally well to arrays, lists or even plain boring integers.

There is also a red herring here: if you look for example at monad implementations in C#, Java or C, they are much longer and much more complex than, say, the PHP example above. In particular, there's *tons* of types everywhere, so it certainly *looks* impressive. But the ugly truth is: C#'s, Java's and C's type systems aren't actually powerful enough to express the type of `Monad`

. In particular, `Monad`

is a rank-2 polymorphic type, but C# and Java only support rank-1 polymorphism (they call it "generics", but it's the same thing) and C doesn't support even that.

So, monads are in fact *not* statically type-checked in C#, Java and C. (That's for example the reason why the LINQ monad comprehensions are defined as a pattern and not as a type: because you simply cannot *express* the type in C#.) All the static type system does, is make the implementation much more complex, without actually helping. It requires a much more sophisticated type system such as Haskell's, to get actual type-safety for monads.

Note: what I wrote above *only* applies to the generic `monad`

type itself, as @Porges points out. You can certainly express the type of any *specific* monad, like `List`

or `Maybe`

, but you cannot express the type of `Monad`

itself. And this means that you cannot type-check the fact that "`List`

IS-A `Monad`

", and you cannot type-check generic operations that work on all instances of `Monad`

.

(Note that checking that `Monad`

also obeys the monad *laws* in addition to conforming to the monad *type* is probably too much even for Haskell's type system. You'd probably need dependent types and maybe even a full-blown automatic theorem prover for that.)