To respect fast readers, I start with precise definition first,
continue with quick more "plain English" explanation, and then move to examples.

Here is a both concise and precise definition slightly reworded:

A **monad** (in computer science) is formally a map that:

sends every type `X`

of some given programming language to a new type `T(X)`

(called the "type of `T`

-computations with values in `X`

");

equipped with a rule for composing two functions of the form
`f:X->T(Y)`

and `g:Y->T(Z)`

to a function `g∘f:X->T(Z)`

;

in a way that is associative in the evident sense and unital with respect to a given unit function called `pure_X:X->T(X)`

, to be thought of as taking a value to the pure computation that simply returns that value.

So in simple words, a **monad** is a *rule to pass from any type *`X`

to another type `T(X)`

, and a *rule to pass from two functions *`f:X->T(Y)`

and `g:Y->T(Z)`

(that you would like to compose but can't) to a new function `h:X->T(Z)`

. Which, however, **is not the composition** in strict mathematical sense. We are basically "bending" function's composition or re-defining how functions are composed.

Plus, we require the monad's rule of composing to satisfy the "obvious" mathematical axioms:

**Associativity**: Composing `f`

with `g`

and then with `h`

(from outside) should be the same as composing `g`

with `h`

and then with `f`

(from inside).
**Unital property**: Composing `f`

with the *identity* function on either side should yield `f`

.

Again, in simple words, we can't just go crazy re-defining our function composition as we like:

- We first need the associativity to be able to compose several functions in a row e.g.
`f(g(h(k(x)))`

, and not to worry about specifying the order composing function pairs. As the monad rule only prescribes how to compose a *pair of functions*, without that axiom, we would need to know which pair is composed first and so on. (Note that is different from the commutativity property that `f`

composed with `g`

were the same as `g`

composed with `f`

, which is not required).
- And second, we need the unital property, which is simply to say that identities compose trivially the way we expect them. So we can safely refactor functions whenever those identities can be extracted.

*So again in brief: A monad is the rule of type extension and composing functions satisfying the two axioms -- associativity and unital property.*

In practical terms, you want the monad to be implemented for you by the language, compiler or framework that would take care of composing functions for you. So you can focus on writing your function's logic rather than worrying how their execution is implemented.

**That is essentially it, in a nutshell.**

Being professional mathematician, I prefer to avoid calling `h`

the "composition" of `f`

and `g`

. Because mathematically, it isn't. Calling it the "composition" incorrectly presumes that `h`

is the true mathematical composition, which it isn't. It is not even uniquely determined by `f`

and `g`

. Instead, it is the result of our monad's new "rule of composing" the functions. Which can be totally different from the actual mathematical composition even if the latter exists!

Monad is *not a functor*! A functor is a rule to go from types to types and functions between them to other functions (sending objects to objects and their morphisms to morphisms in category theory). Instead a monad sends a **pair** of functions `f`

and `g`

to a new one `h`

.

To make it less dry, let me try to illustrate it by example
that I am annotating with small sections, so you can skip right to the point.

## Exception throwing as Monad examples

Suppose we want to compose two functions:

```
f: x -> 1 / x
g: y -> 2 * y
```

But `f(0)`

is not defined, so an exception `e`

is thrown. Then how can you define the compositional value `g(f(0))`

? Throw an exception again, of course! Maybe the same `e`

. Maybe a new updated exception `e1`

.

What precisely happens here? First, we need new exception value(s) (different or same). You can call them `nothing`

or `null`

or whatever but the essence remains the same -- they should be new values, e.g. it should not be a `number`

in our example here. I prefer not to call them `null`

to avoid confusion with how `null`

can be implemented in any specific language. Equally I prefer to avoid `nothing`

because it is often associated with `null`

, which, in principle, is what `null`

should do, however, that principle often gets bended for whatever practical reasons.

## What is exception exactly?

This is a trivial matter for any experienced programmer but I'd like to drop few words just to extinguish any worm of confusion:

*Exception is an object encapsulating information about how the invalid result of execution occurred.*

This can range from throwing away any details and returning a single global value (like `NaN`

or `null`

) or generating a long log list or what exactly happened, send it to a database and replicating all over the distributed data storage layer ;)

The important difference between these two extreme examples of exception is that in the first case there are **no side-effects**. In the second there are. Which brings us to the (thousand-dollar) question:

## Are exceptions allowed in pure functions?

*Shorter answer*: Yes, but only when they don't lead to side-effects.

*Longer answer.* To be pure, your function's output must be uniquely determined by its input. So we amend our function `f`

by sending `0`

to the new abstract value `e`

that we call exception. We make sure that value `e`

contains no outside information that is not uniquely determined by our input, which is `x`

. So here is an example of exception without side-effect:

```
e = {
type: error,
message: 'I got error trying to divide 1 by 0'
}
```

And here is one with side-effect:

```
e = {
type: error,
message: 'Our committee to decide what is 1/0 is currently away'
}
```

Actually, it only has side-effects if that message can possibly change in the future. But if it is guaranteed to never change, that value becomes uniquely predictable, and so there is no side-effect.

To make it even sillier. A function returning `42`

ever is clearly pure. But if someone crazy decides to make `42`

a variable that value might change, the very same function stops being pure under the new conditions.

Note that I am using the object literal notation for simplicity to demonstrate the essence. Unfortunately things are messed-up in languages like JavaScript, where `error`

is not a type that behaves the way we want here with respect to function composition, whereas actual types like `null`

or `NaN`

do not behave this way but rather go through the some artificial and not always intuitive type conversions.

## Type extension

As we want to vary the message inside our exception, we are really declaring a new type `E`

for the whole exception object and then
That is what the `maybe number`

does, apart from its confusing name, which is to be either of type `number`

or of the new exception type `E`

, so it is really the union `number | E`

of `number`

and `E`

. In particular, it depends on how we want to construct `E`

, which is neither suggested nor reflected in the name `maybe number`

.

## What is functional composition?

It is the mathematical operation taking functions
`f: X -> Y`

and `g: Y -> Z`

and constructing
their composition as function `h: X -> Z`

satisfying `h(x) = g(f(x))`

.
The problem with this definition occurs when the result `f(x)`

is not allowed as argument of `g`

.

In mathematics those functions cannot be composed without extra work.
The strictly mathematical solution for our above example of `f`

and `g`

is to remove `0`

from the set of definition of `f`

. With that new set of definition (new more restrictive type of `x`

), `f`

becomes composable with `g`

.

However, it is not very practical in programming to restrict the set of definition of `f`

like that. Instead, exceptions can be used.

Or as another approach, artificial values are created like `NaN`

, `undefined`

, `null`

, `Infinity`

etc. So you evaluate `1/0`

to `Infinity`

and `1/-0`

to `-Infinity`

. And then force the new value back into your expression instead of throwing exception. Leading to results you may or may not find predictable:

```
1/0 // => Infinity
parseInt(Infinity) // => NaN
NaN < 0 // => false
false + 1 // => 1
```

And we are back to regular numbers ready to move on ;)

JavaScript allows us to keep executing numerical expressions at any costs without throwing errors as in the above example. That means, it also allows to compose functions. Which is exactly what monad is about - it is a rule to compose functions satisfying the axioms as defined at the beginning of this answer.

*But is the rule of composing function, arising from JavaScript's implementation for dealing with numerical errors, a monad?*

To answer this question, all you need is to check the axioms (left as exercise as not part of the question here;).

## Can throwing exception be used to construct a monad?

Indeed, a more useful monad would instead be the rule prescribing
that if `f`

throws exception for some `x`

, so does its composition with any `g`

. Plus make the exception `E`

globally unique with only one possible value ever (terminal object in category theory). Now the two axioms are instantly checkable and we get a very useful monad. And the result is what is well-known as the **maybe monad**.

muchbetter than the ones in those other suggested Q's for people with an OO background (as opposed to a FP background). – Donal Fellows Apr 24 '10 at 14:43