To take it to C++ (prior to metaclasses, which will eventually give a way to express this properly), the best description of a monad is this:

A *parameterised class* (like the STL container types), i.e. a class of the form

```
template <typename a>
class M;
```

which supports at least the following functions:

“Trivial injection”

```
template <typename a, typename b>
M<a> pure (a x);
```

^{Mathematicians call this η, Haskell has traditionally called it return, other languages often unit.}

Functor^{†} mapping

```
template <typename a, typename b>
M<b> fmap (std::function<b(a)> f, M<a> m);
```

A flattening operation

```
template <typename a, typename b>
M<a> join (M< M<a> > mm);
```

^{Which mathematicians call μ. Many programming languages (including Haskell) don't implemented this by itself but combined with fmap, as such it is then called flatMap or >>=. But join is the simplest form.}

such that the monad laws are fulfilled.

Example for an array type:

```
template <typename a>
struct array {
std::vector<a> contents;
};
template <typename a>
array<a> pure(a x) {
return array<a>{{std::vector<a>({x})}}; // array with only a single element.
}
template <typename a, typename b>
array<b> fmap(std::function<b(a)> f, array<a> m) {
std::vector<b> resultv;
for(auto& x: m) {
resultv.push_back(f(x));
}
return array<b>{{resultv}}; // array with the elements transformed by the given function
}
template <typename a>
array<a> join(array< array<a> > mm) {
std::vector<a> resultv;
for(auto& row: mm.contents) {
for(auto& x: row.contents) {
resultv.push_back(x);
}
}
return array<a>{{resultv}}; // array with all the rows concatenated.
}
```

So, what's the use of this? Well, `fmap`

is pretty useful on its own right, when you quickly want to map a lambda over all the elements of an array (allowing for changing type), without having to fiddle with any iterators (unlike `std::transform`

). But `fmap`

doesn't really require a monad.

What monads really shine at is *generically sequencing actions*. That won't become very clear with that array example, so let me introduce another monad:

```
template <typename a>
struct writer {
std::string logbook;
a result;
};
template <typename a, typename b>
writer<a> pure (a x) {
return writer<a>{{"", x}}; // nothing to log yet
}
template <typename a, typename b>
writer<b> fmap (std::function<b(a)> f, writer<a> m){
return writer<b>{{m.logbook, f(m.result)}};
// simply keep the log as-is
}
template <typename a, typename b>
writer<a> join (writer< writer<a> > mm) {
return writer<a>{{mm.logbook + mm.result.logbook, m.result.result}};
// Concatenate the two logs, and keep the inner value
}
```

`writer`

more resembles the most [in]famous Haskell monad, `IO`

. The `writer`

type allows you to compose arbitrary log-writing functions together, and without ever having to worry about it, gather all the logbook information.

You may wonder at this point: what *is* there to log? None of the operations above actually produce any logbook entries! Indeed they don't – in fact the monad laws would be violated if they did! Monads are not about particular actions, pre-built values. Rather, they just give you an extremely generic *framework* for “glueing together” such actions.

A simple example of such a glueing-compositor is `replicateM`

, which takes a single monadic action and executes it *n* times in sequence, gathering all the results. Unfortunately, this can't be properly typed in C++ in full generality, but here's a specialized version that only works for the writer monad. First, let's quickly implement that combined fmap-join I mentioned earlier, because it's much more handy than `join`

in practice:

```
template<typename a, typename b>
writer<b> flatMap(std::function<writer<b>(a)> f, writer<a> xs) {
return join(fmap(f,xs));
}
template <typename a>
writer<array<a>> replicateM (int n, writer<a> m) {
if (n>0) {
writer<array<a>> resultv = fmap(pure, m);
for (int i=1; i<n; ++i) {
resultv = flatMap( [&](array<a> xs){
return fmap( [&](a x){
return xs.push_back(x);}
, m );}
, resultv);
}
} else {
return pure(std::vector<a>());
}
}
```

Notice that none of the code above actually uses anything specific to `writer`

, so I could copy&paste it and use it for any other monad. (Or, use a language with higher-kinded polymorphism and just write it once and for all.)

What `replicateM`

does in case of `writer`

is frankly quite dumb – it just repeats the same log message `n`

times, and replicates the result value `n`

times as well. However, that's just the simplest example: monads can also have much more functionality, for example, in the IO monad, each invocation might yield a different result (e.g. because it reads from standard input). A generic monad interface allows you to abstract over all kinds of different side-effects, but still keeps clear track of what side-effects can possibly happen in a given context.

^{†}_{Unfortunately, the C++ community misuses the word “functor” simply to describe function objects. Although this is a related concept, a functor is actually more than that.}

any given monadto, say, C++, but that obscures the fundamental idea behind the concept. – leftaroundabout Apr 16 at 12:34