I can naively construct a hierarchy of algebraic structures in Coq using type classes. I'm having some trouble finding resources on Coq's syntax and semantics for type classes. However, I believe the following is a correct implementation of semigroups, monoids and commutative monoids:

```
Class Semigroup {A : Type} (op : A -> A -> A) : Type := {
op_associative : forall x y z : A, op x (op y z) = op (op x y) z
}.
Class Monoid `(M : Semigroup) (id : A) : Type := {
id_ident_left : forall x : A, op id x = x;
id_ident_right : forall x : A, op x id = x
}.
Class AbelianMonoid `(M : Monoid) : Type := {
op_commutative : forall x y : A, op x y = op y x
}.
```

If I understand correctly, additional parameters (e.g., the identity element of a monoid) can be added by first declaring `Monoid`

an instance of `Semigroup`

, then parameterizing on `id : A`

. However, something odd is occurring in the record constructed for `AbelianMonoid`

.

```
< Print Monoid.
Record Monoid (A : Type) (op : A -> A -> A) (M : Semigroup op)
(id : A) : Type := Build_Monoid
{ id_ident_left : forall x : A, op id x = x;
id_ident_right : forall x : A, op x id = x }
< Print AbelianMonoid.
Record AbelianMonoid (A : Type) (op : A -> A -> A)
(M0 : Semigroup op) (id0 : A) (M : Monoid M0 id0) :
Type := Build_AbelianMonoid
{ op_commutative : forall x y : A, op x y = op y x }
```

This occurred when I was trying to build a class for semigroups. I thought that the following syntax was correct:

```
Class Semiring `(P : AbelianMonoid) `(M : Monoid) := {
...
}.
```

However, I couldn't disambigutate the correct operators and identity elements. Printing the records revealed the problems outlined above. So I have two questions: first, how do I correctly declare the class `Monoid`

; second, how do I disambiguate functions in superclasses?

What I'd really like is a good resources that clearly explains Coq's type classes without antiquated syntax. For example, I thought Hutton's book explained type classes in Haskell clearly.