That's because `_ =? _`

is defined by structural recursion on both arguments.

```
Require Import Arith.
Locate "_ =? _".
(* Notation "x =? y" := (Nat.eqb x y) : nat_scope (default interpretation) *)
Print Nat.eqb.
(*
Nat.eqb =
fix eqb (n m : nat) {struct n} : bool :=
match n with
| 0 => match m with
| 0 => true
| S _ => false
end
| S n' => match m with
| 0 => false
| S m' => eqb n' m'
end
end
: nat -> nat -> bool
*)
```

When you use `simpl`

, you're computing `_ =? _`

, same as you're computing every other function that simplifies.

Note that there are two equalities for natural numbers: `_ = _`

lives in `Prop`

and checks whether two terms are exactly the same, "character for character", so to say. `_ =? _`

is defined as above. They behave exactly the same [*], as the following theorem states:

```
Nat.eqb_eq: forall n m : nat, (n =? m) = true <-> n = m
```

However, they aren't defined in the same way (they don't even have the same type signature).

[*] This wasn't predetermined. You can define equivalence relations on types that don't behave like `_ = _`

. For example, rational numbers can be represented as pairs of a natural number and a positive natural number. Thus, `<1,2>`

can represent `1/2`

and yet `<2,4>`

also represents `1/2`

. So we can define a relation on these pairs where `(1,2) =? (2,4) = true`

, and yet `(1,2) <> (2,4)`

.