I think this is a very good way to do it. Usually, when you want to create a "subset" of a type, it looks like:

```
postulate
A : Set
P : A → Set
record Subset : Set where
field
value : A
prop : P value
```

However, this might not be a subset in the sense that it can actually contain more elements than the original type. That is because `prop`

might have more propositionally different values. For example:

```
open import Data.Nat
data ℕ-prop : ℕ → Set where
c1 : ∀ n → ℕ-prop n
c2 : ∀ n → ℕ-prop n
record ℕ-Subset : Set where
field
value : ℕ
prop : ℕ-prop value
```

And suddenly, the subset has twice as many elements as the original type. This example is a bit contrived, I agree, but imagine you had a subset relation on sets (sets from set theory). Something like this is actually fairly possible:

```
sub₁ : {1, 2} ⊆ {1, 2, 3, 4}
sub₁ = drop 3 (drop 4 same)
sub₂ : {1, 2} ⊆ {1, 2, 3, 4}
sub₂ = drop 4 (drop 3 same)
```

The usual approach to this problem is to use irrelevant arguments:

```
record Subset : Set where
field
value : A
.prop : P value
```

This means that two values of type `Subset`

are equal if they have the same `value`

, the `prop`

field is *irrelevant* to the equality. And indeed:

```
record Subset : Set where
constructor sub
field
value : A
.prop : P value
prop-irr : ∀ {a b} {p : P a} {q : P b} →
a ≡ b → sub a p ≡ sub b q
prop-irr refl = refl
```

However, this is more of a guideline, because your representation doesn't suffer from this problem. This is because the implementation of pattern matching in Agda implies *axiom K*:

```
K : ∀ {a p} {A : Set a} (x : A) (P : x ≡ x → Set p) (h : x ≡ x) →
P refl → P h
K x P refl p = p
```

Well, this doesn't tell you much. Luckily, there's another property that is equivalent to axiom K:

```
uip : ∀ {a} {A : Set a} {x y : A} (p q : x ≡ y) → p ≡ q
uip refl refl = refl
```

This tells us that there's only one way in which two elements can be equal, namely `refl`

(`uip`

means *uniqueness of identity proofs*).

This means that when you use propositional equality to make a subset, you're getting a true subset.

Let's make this explicit:

```
isSingleton : ∀ {ℓ} → Set ℓ → Set _
isSingleton A = Σ[ x ∈ A ] (∀ y → x ≡ y)
```

`isSingleton A`

expresses the fact that `A`

contains only one element, up to propositonal equality. And indeed, `Singleton x`

is a singleton:

```
Singleton-isSingleton : ∀ {ℓ} {A : Set ℓ} (x : A) →
isSingleton (Singleton x)
Singleton-isSingleton x = (x , refl) , λ {(.x , refl) → refl}
```

Interestingly, this also works without axiom K. If you put `{-# OPTIONS --without-K #-}`

pragma at the top of your file, it will still compile.