I'm trying to find a way to prove a couple of set theory-based problems in Agda, but I'm having a hard time defining the function range.

I took the definition of Subset from Proving decidability of subset in Agda and built on top of it. This is what I got so far:

```
open import Data.Bool as Bool using (Bool; true; false; T; _∨_; _∧_)
open import Data.Unit using (⊤; tt)
open import Level using (Level; _⊔_; 0ℓ) renaming (suc to lsuc)
open import Data.Product using (_×_) renaming (_,_ to ⟨_,_⟩)
Subset : ∀ {α} (A : Set α) -> Set _
Subset A = A → Bool
_∈_ : ∀ {α} {A : Set α} → A → Subset A → Set
a ∈ p = T (p a)
Relation : ∀ {α β} (A : Set α) (B : Set β) → Set (α ⊔ β)
Relation A B = Subset (A × B)
Range : ∀ {A B : Set} → Relation A B → Subset B
Range = ?
_⊆_ : ∀ {A : Set} → Subset A → Subset A → Set
A ⊆ B = ∀ x → x ∈ A → x ∈ B
wholeSet : ∀ (A : Set) → Subset A
wholeSet _ = λ _ → true
∀subset⊆set : ∀ {A : Set} {sub : Subset A} → sub ⊆ wholeSet A
∀subset⊆set = λ _ _ → tt
_∩_ : ∀ {A : Set} → Subset A → Subset A → Subset A
A ∩ B = λ x → (A x) ∧ (B x)
⊆-range-∩ : ∀ {A B : Set}
(F G : Relation A B)
→ Range (F ∩ G) ⊆ (Range F ∩ Range G)
⊆-range-∩ f g = ?
```

The problem is that `Range`

takes as an input a function of type `A × B → Bool`

and must return a function `B → Bool`

such that a value `B`

is true iff there exists a value `A × B`

which is true in the initial function. Basically, I would need to iterate through all values of `A`

to know whether `B`

is in the range of the relation. Something impossible to do, isn't it?

There must be surely a better way to implement `Range`

, doesn't it?