# Avoiding extensionality postulate when defining non-unary functions over quotient types

I'm trying to define functions with more than one arguments over quotient types. Using currying, I can reduce the problem to defining functions over the pointwise product setoid:

``````module Foo where

open import Quotient
open import Relation.Binary
open import Relation.Binary.PropositionalEquality as P using (proof-irrelevance)

private
open import Relation.Binary.Product.Pointwise
open import Data.Product

_×-quot_ : ∀ {c ℓ} {S : Setoid c ℓ} → Quotient S → Quotient S → Quotient (S ×-setoid S)
_×-quot_ {S = S} = rec S (λ x → rec S (λ y → [ x , y ])
(λ {y} {y′} y≈y′ → [ refl , y≈y′ ]-cong))
(λ {x} {x′} x≈x′ → extensionality (elim _ _ (λ _ → [ x≈x′ , refl ]-cong)
(λ _ → proof-irrelevance _ _)))
where
open Setoid S
postulate extensionality : P.Extensionality _ _
``````

My question is, is there a way to prove the soundness of `×-quot` without postulating extensionality?

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You were needing extensionality because the value of `P` parameter for `rec` you have chosen was a function type. If you avoid that and use a `Quotient` type as `P` instead, you can do it:

``````module Quotients where

open import Quotient
open import Relation.Binary
open import Relation.Binary.PropositionalEquality as P using (proof-irrelevance; _≡_)

private
open import Relation.Binary.Product.Pointwise
open import Data.Product
open import Function.Equality

map-quot : ∀ {c₁ ℓ₁ c₂ ℓ₂} {A : Setoid c₁ ℓ₁} {B : Setoid c₂ ℓ₂} → A ⟶ B → Quotient A → Quotient B
map-quot f = rec _ (λ x → [ f ⟨\$⟩ x ]) (λ x≈y → [ cong f x≈y ]-cong)

map-quot-cong : ∀ {c₁ ℓ₁ c₂ ℓ₂} {A : Setoid c₁ ℓ₁} {B : Setoid c₂ ℓ₂} →
let open Setoid (A ⇨ B) renaming (_≈_ to _≐_) in
(f₁ f₂ : A ⟶ B) → (f₁ ≐ f₂) → (x : Quotient A) → map-quot f₁ x ≡ map-quot f₂ x
map-quot-cong {A = A} {B = B} f₁ f₂ eq x =
elim _
(λ x → map-quot f₁ x ≡ map-quot f₂ x)
(λ x' → [ eq (Setoid.refl A) ]-cong)
(λ x≈y → proof-irrelevance _ _)
x

_×-quot₁_ : ∀ {c ℓ} {A B : Setoid c ℓ} → Quotient A → Quotient B → Quotient (A ×-setoid B)
_×-quot₁_ {A = A} {B = B} qx qy = rec A (λ x → map-quot (f x) qy)
(λ {x} {x′} x≈x′ → map-quot-cong (f x) (f x′) (λ eq → x≈x′ , eq) qy) qx
where
module A = Setoid A
f = λ x → record { _⟨\$⟩_ = _,_ x; cong = λ eq → (A.refl , eq) }
``````

And another way of proving it, going through `_<\$>_` (which I did first and decided not to throw away):

``````  infixl 3 _<\$>_
_<\$>_ : ∀ {c₁ ℓ₁ c₂ ℓ₂} {A : Setoid c₁ ℓ₁} {B : Setoid c₂ ℓ₂} → Quotient (A ⇨ B) → Quotient A → Quotient B
_<\$>_ {A = A} {B = B} qf qa =
rec (A ⇨ B) {P = Quotient B}
(λ x → map-quot x qa)
(λ {f₁} {f₂} f₁≈f₂ → map-quot-cong f₁ f₂ f₁≈f₂ qa) qf

comma0 : ∀ {c ℓ} → ∀ {A B : Setoid c ℓ} → Setoid.Carrier (A ⇨ B ⇨ A ×-setoid B)
comma0 {A = A} {B = B} = record
{ _⟨\$⟩_ = λ x → record
{ _⟨\$⟩_ = λ y → x , y
; cong = λ eq → Setoid.refl A , eq
}
; cong = λ eqa eqb → eqa , eqb
}

comma : ∀ {c ℓ} → ∀ {A B : Setoid c ℓ} → Quotient (A ⇨ B ⇨ A ×-setoid B)
comma = [ comma0 ]

_×-quot₂_ : ∀ {c ℓ} {A B : Setoid c ℓ} → Quotient A → Quotient B → Quotient (A ×-setoid B)
a ×-quot₂ b = comma <\$> a <\$> b
``````

And another version of `_<\$>_`, now using `join`:

``````  map-quot-f : ∀ {c₁ ℓ₁ c₂ ℓ₂} {A : Setoid c₁ ℓ₁} {B : Setoid c₂ ℓ₂}
→ Quotient A → (A ⇨ B) ⟶ (P.setoid (Quotient B))
map-quot-f qa = record { _⟨\$⟩_ = λ f → map-quot f qa; cong = λ eq → map-quot-cong _ _ eq qa }

join : ∀ {c ℓ} → {S : Setoid c ℓ} → Quotient (P.setoid (Quotient S)) → Quotient S
join {S = S} q = rec (P.setoid (Quotient S)) (λ x → x) (λ eq → eq) q

infixl 3 _<\$>_
_<\$>_ : ∀ {c₁ ℓ₁ c₂ ℓ₂} {A : Setoid c₁ ℓ₁} {B : Setoid c₂ ℓ₂} → Quotient (A ⇨ B) → Quotient A → Quotient B
_<\$>_ {A = A} {B = B} qf qa = join (map-quot (map-quot-f qa) qf)
``````

Here it becomes obvious that there is some sort of monad in there. What a nice discovery! :)

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I wonder why I can't inline `comma0`. Is that a bug in Agda? – Rotsor May 13 '12 at 17:14