You need to simplify `(nx * dy + dx * ny) / (dx * dy)`

to ensure its numerator and denominator are coprimes.

The following code shows you the core of the solution by simplifying a pair of natural numbers `x`

and `suc y-1`

(i.e. a non-zero `y`

). Extending it to handle the signs of the numerator should be an easy exercise. The heavy lifting is done by `Data.Nat.Coprimality.Bézout-coprime`

.

```
open import Data.Nat
open import Data.Nat.GCD
open import Data.Nat.Coprimality hiding (sym)
open import Relation.Binary.PropositionalEquality
open import Data.Product
open import Data.Nat.Divisibility
open import Data.Empty
record Simp (x : ℕ) (y : ℕ) : Set where
constructor MkSimp
field
x′ y′ : ℕ
eq-prf : x * y′ ≡ x′ * y
coprime-prf : Coprime x′ y′
1+≢*0 : ∀ x y → suc x ≢ y * 0
1+≢*0 x zero ()
1+≢*0 x (suc y) = 1+≢*0 x y
simp : ∀ x y-1 → Simp x (suc y-1)
simp x y-1 with Bézout.lemma x (suc y-1)
simp x y-1 | Bézout.result 0 (GCD.is (_ , divides y′ y-eq) _) _ = ⊥-elim (1+≢*0 y-1 y′ y-eq)
simp x y-1 | Bézout.result (suc d-1) (GCD.is (divides x′ x-eq , divides y′ y-eq) _) bézout = MkSimp x′ y′ eq-prf (Bézout-coprime bézout′)
where
y = suc y-1
d = suc d-1
bézout′ : Bézout.Identity d (x′ * d) (y′ * d)
bézout′ = subst₂ (Bézout.Identity d) x-eq y-eq bézout
open Relation.Binary.PropositionalEquality.≡-Reasoning
open import Data.Nat.Properties.Simple
eq-prf : x * y′ ≡ x′ * y
eq-prf = begin
x * y′ ≡⟨ cong (λ z → z * y′) x-eq ⟩
x′ * d * y′ ≡⟨ *-assoc x′ d y′ ⟩
x′ * (d * y′) ≡⟨ sym (cong (_*_ x′) (*-comm y′ d)) ⟩
x′ * (y′ * d) ≡⟨ sym (cong (_*_ x′) y-eq) ⟩
x′ * y ∎
```