How to use dependent pairs

Suppose I have a function (it really does what the name says):

``````filter : ∀ {A n} → (A → Bool) → Vec A n → ∃ (λ m → Vec A m)
``````

Now, I'd like to somehow work with the dependent pair I return. I wrote simple `head` function:

``````head :: ∀ {A} → ∃ (λ n → Vec A n) → Maybe A
head (zero   , _ )       = nothing
head (succ _ , (x :: _)) = just x
``````

which of course works perfectly. But it made me wonder: is there any way I can make sure, that the function may only be called with `n ≥ 1`?

Ideally, I'd like to make function `head : ∀ {A} → ∃ (λ n → Vec A n) → IsTrue (n ≥ succ zero) → A`; but that fails, because `n` is out of scope when I use it in `IsTrue`.

`IsTrue` is something like:

``````data IsTrue : Bool → Set where
check : IsTrue true
``````
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I think this is a question about uncurrying. The standard library provides uncurrying functions for products, see uncurry. For your situation, it would be more beneficial to have a uncurry function where the first argument is hidden, since a head function would normally take the length index as an implicit argument. We can write an uncurry function like that:

``````uncurryʰ : ∀ {a b c} {A : Set a} {B : A → Set b} {C : (a : A) → B a → Set c} →
({x : A} → (y : B x) → C x y) →
((p : Σ A B) → uncurry C p)
uncurryʰ f (x , y) = f {x} y
``````

The function that returns the head of a vector if there is one does not seem to exist in the standard library, so we write one:

``````maybe-head : ∀ {a n} {A : Set a} → Vec A n → Maybe A
maybe-head (x ∷ xs) = just x
``````

Now your desired function is just a matter of uncurrying the maybe-head function with the first-argument-implicit-uncurrying function defined above:

``````maybe-filter-head : ∀ {A : Set} {n} → (A → Bool) → Vec A n → Maybe A
``````

Conclusion: dependent products gladly curry and uncurry like their non-dependent versions.

Uncurrying aside, the function you want to write with type signature

``````head : ∀ {A} → ∃ (λ n → Vec A n) → IsTrue (n ≥ succ zero) → A
``````

Can be written as:

``````head : ∀ {A} → (p : ∃ (λ n → Vec A n)) → IsTrue (proj₁ p ≥ succ zero) → A
``````
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Excellent, though I think you meant `IsTrue (proj₁ p ≥ succ zero)`. – Vitus Mar 14 '12 at 15:59
Thank you, edited! – danr Mar 14 '12 at 16:01

The best way is probably to destructure the dependent pair first, so that you can just write:

``````head :: ∀ {A n} → Vec A (S n) → A
``````

However, if you really want to keep the dependent pair intact in the function signature, you can write a predicate PosN which inspects the first element of the pair and checks that it is positive:

``````head :: ∀ {A p} → PosN p -> A
``````

or similar. I'll leave the definition of PosN as an exercise to the reader. Essentially this is what Vitus' answer already does, but a simpler predicate can be defined instead.

-

After playing with it for some time, I came up with solution that resembles the function I wanted in first place:

``````data ∃-non-empty (A : Set) : ∃ (λ n → Vec A n) → Set where
∃-non-empty-intro : ∀ {n} → {x : Vec A (succ n)} → ∃-non-empty A (succ n , x)

head : ∀ {A} → (e : ∃ (λ n → Vec A n)) → ∃-non-empty A e → A
head (succ _ , (x :: _)) ∃-non-empty-intro = x
``````

If anyone comes up with better (or more general) solution, I'll gladly accept their answer. Comments are welcome, too.

Here's more general predicate I came up with:

``````data ∃-succ {A : Nat → Set} : ∃ A → Set where
∃-succ-intro : ∀ {n} → {x : A (succ n)} → ∃-succ (succ n , x)

-- or equivalently
data ∃-succ {A : Nat → Set} : ∃ (λ n → A n) → Set where
...
``````
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This is just like the usual `head` function for `Vec`.

``````head' : ∀ {α} {A : Set α} → ∃ (λ n → Vec A (suc n)) → A
head' (_ , x ∷ _) = x
``````
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