So while learning Coq I did a simple example with the game paper, scissor, rock. I defined a data type.

```
Inductive PSR : Set := paper | scissor | rock.
```

And three functions:

```
Definition me (elem: PSR) : PSR := elem.
Definition beats (elem: PSR) : PSR :=
match elem with
| paper => scissor
| rock => paper
| scissor => rock
end.
Definition beatenBy (elem: PSR) : PSR :=
match elem with
| paper => rock
| rock => scissor
| scissor => paper
end.
```

I also define composition (although this should be somewhere in the standard library)

```
Definition compose {A B C} (g : B -> C) (f : A -> B) : (A -> C) :=
fun x : A => g (f x).
```

I implement the class monoid as described here

```
Class Monoid {A : Type} (dot : A -> A -> A) (unit : A) : Type := {
dot_assoc : forall x y z:A,
dot x (dot y z)= dot (dot x y) z;
unit_left : forall x,
dot unit x = x;
unit_right : forall x,
dot x unit = x
}.
```

I finally managed to prove that you can `PSR`

forms a monoid under `compose`

as `+`

and `me`

as `1`

```
Instance MSPR : Monoid compose me.
split.
intros. reflexivity.
intros. reflexivity.
intros. reflexivity.
Qed.
```

## Question

Why does the proof of `Instance MSPR : Monoid compose me.`

work just by applying `intros`

and `reflexivity`

? Honestly, I did `split`

and `intros`

knowing what I was doing, but after `intros`

I got something like

```
3 subgoal
x : PSR -> PSR
y : PSR -> PSR
z : PSR -> PSR
______________________________________(1/3)
compose x (compose y z) = compose (compose x y) z
```

tried `apply compose.`

but it didn't work. Magically `reflexivity.`

solved it but I don't know why.

## Side Note

This worked wonderfully, if you define power like this

```
Fixpoint power {A dot one} {M : @Monoid A dot one}(a:A)(n:nat) :=
match n with 0 % nat => one
| S p => dot a (power a p)
end.
```

then `Compute (power beats 2) paper.`

yields

```
= rock
: PSR
```

which did this `beats (beats paper) = beats scissor = rock`

!!!

`me`

is the identity function; what you've proven is that the function space`PSR -> PSR`

is a monoid with`compose`

as binary op and`id`

as unit. It is true of any set of endomorphisms. Your proofs work by reflexivity because function composition is associative (try using`unfold compose`

and see what happens). – gallais Jun 26 '14 at 8:08