Indeed, assuming that `Σprojᵣ`

projects the second element of the pair, `Σprojᵣ (lookup xs proof)`

is correct solution which fits into the hole. The question is, how to write this projection?

If we had ordinary non-dependent pairs, writing both projections is easy:

```
data _×_ (A B : Set) : Set where
_,′_ : A → B → A × B
fst : ∀ {A B} → A × B → A
fst (a ,′ b) = a
snd : ∀ {A B} → A × B → B
snd (a ,′ b) = b
```

What makes it so hard when we use dependent pair? The hint is hidden in the very name: the second component depends on the value of first and we have to somehow capture this in our type.

So, we start with:

```
data Σ (A : Set) (B : A → Set) : Set where
_,_ : (a : A) → B a → Σ A B
```

Writing the projection for the left component is easy (note that I'm calling it `proj₁`

instead of `Σprojₗ`

, that's what the standard library does):

```
proj₁ : {A : Set} {B : A → Set} → Σ A B → A
proj₁ (a , b) = a
```

Now, the second projection should look a bit like this:

```
proj₂ : {A : Set} {B : A → Set} → Σ A B → B ?
proj₂ (a , b) = b
```

But `B`

*what*? Since the type of the second component depends on the value of the first one, we somehow need to smuggle it through `B`

.

We need to be able to refer to our pair, let's do it:

```
proj₂ : {A : Set} {B : A → Set} (pair : Σ A B) → B ?
```

And now, the first component of our pair is `proj₁ pair`

, so let's fill that in:

```
proj₂ : {A : Set} {B : A → Set} (pair : Σ A B) → B (proj₁ pair)
```

And indeed, this typechecks!

There are, however, easier solutions than writing `proj₂`

by hand.

Instead of defining `Σ`

as a `data`

, we can define it as a `record`

. Records are special case of `data`

declarations that have only one constructor. The nice thing is that records give you the projections for free:

```
record Σ (A : Set) (B : A → Set) : Set where
constructor _,_
field
proj₁ : A
proj₂ : B proj₁
open Σ -- opens the implicit record module
```

This (among other useful things) gives you projections `proj₁`

and `proj₂`

.

We can also deconstruct the pair with `with`

statement and avoid this `proj`

bussiness altogether:

```
lookup : ∀ {A} {x : A}(xs : List A) → x ∈ xs → Σ ℕ (λ n → xs ! n ≡ just x)
lookup {x = x} .(x ∷ xs) (first {xs}) = 0 , refl
lookup .(y ∷ xs) (later {y} {xs} p) with lookup xs p
... | n , p′ = suc n , p′
```

`with`

allows you to pattern match not only on the arguments of the function, but also on intermediate expressions. If you are familiar with Haskell, it's something like a `case`

.

Now, this is almost ideal solution, but still can be made a bit better. Notice that we have to bring the implicit `{x}`

, `{xs}`

and `{y}`

into scope just so we can write down the dot pattern. Dot patterns do not participate in pattern matching, they are used as *assertions* that this particular expression is the only one which fits.

For example, in the first equation, the dot pattern tells us that the list must have looked like `x ∷ xs`

- we know this because we pattern matched on the proof. Since we only pattern match on the proof, the list argument is a bit redundant:

```
lookup : ∀ {A} {x : A} (xs : List A) → x ∈ xs → Σ ℕ (λ n → xs ! n ≡ just x)
lookup ._ first = 0 , refl
lookup ._ (later p) with lookup _ p
... | n , p′ = suc n , p′
```

The compiler can even infer the argument to the recursive call! If the compiler can figure this stuff on its own, we can safely mark it implicit:

```
lookup : ∀ {A} {x : A} {xs : List A} → x ∈ xs → Σ ℕ (λ n → xs ! n ≡ just x)
lookup first = 0 , refl
lookup (later p) with lookup p
... | n , p′ = suc n , p′
```

Now, the final step: let's bring in some abstraction. The second equation takes the pair apart, applies some functions (`suc`

) and reconstructs the pair - we *map* functions over the pair!

Now, the fully dependent type for `map`

is quite complicated. Don't be discouraged if you don't understand! When you come back with more knowledge later, you'll find it fascinating.

```
map : {A C : Set} {B : A → Set} {D : C → Set}
(f : A → C) (g : ∀ {a} → B a → D (f a)) →
Σ A B → Σ C D
map f g (a , b) = f a , g b
```

Compare with:

```
map′ : {A B C D : Set}
(f : A → C) (g : B → D) →
A × B → C × D
map′ f g (a ,′ b) = f a ,′ g b
```

And we conclude with the very concise:

```
lookup : ∀ {A} {x : A} {xs : List A} → x ∈ xs → Σ ℕ (λ n → xs ! n ≡ just x)
lookup first = 0 , refl
lookup (later p) = map suc id (lookup p)
```

That is, we map `suc`

over the first component and leave the second one unchanged (`id`

).