Let me answer your second and third questions first. Looking at how `DContT`

is defined:

```
DContT K M r₂ r₁ a = (a → M (K r₁)) → M (K r₂)
```

We can recover the requested definition by specifying `M = id`

and `K = id`

(`M`

also has to be a monad, but we have the `Identity`

monad). `DCont`

already fixes `M`

to be `id`

, so we are left with `K`

.

```
import Category.Monad.Continuation as Cont
open import Function
DCont : Set → Set → Set → Set
DCont = Cont.DCont id
```

Now, we can open the `RawIMonadDCont`

module provided we have an instance of the corresponding record. And luckily, we do: `Category.Monad.Continuation`

has one such record under the name `DContIMonadDCont`

.

```
module ContM {ℓ} =
Cont.RawIMonadDCont (Cont.DContIMonadDCont {f = ℓ} id)
```

And that's it. Let's make sure the required operations are really there:

```
return : ∀ {r a} → a → DCont r r a
return = ContM.return
_>>=_ : ∀ {r i j a b} → DCont r i a → (a → DCont i j b) → DCont r j b
_>>=_ = ContM._>>=_
join : ∀ {r i j a} → DCont r i (DCont i j a) → DCont r j a
join = ContM.join
shift : ∀ {r o i j a} → ((a → DCont i i o) → DCont r j j) → DCont r o a
shift = ContM.shift
reset : ∀ {r i a} → DCont a i i → DCont r r a
reset = ContM.reset
```

And indeed, this typechecks. You can also check if the implementation matches. For example, using `C-c C-n`

(normalize) on `shift`

, we get:

```
λ {.r} {.o} {.i} {.j} {.a} e k → e (λ a f → f (k a)) (λ x → x)
```

Modulo renaming and some implicit parameters, this is exactly implementation of the `shift`

in your question.

Now the first question. The extra parameter is there to allow additional dependency on the indices. I haven't used delimited continuations in this way, so let me reach for an example somewhere else. Consider this indexed writer:

```
open import Data.Product
IWriter : {I : Set} (K : I → I → Set) (i j : I) → Set → Set
IWriter K i j A = A × K i j
```

If we have some sort of indexed monoid, we can write a monad instance for `IWriter`

:

```
record IMonoid {I : Set} (K : I → I → Set) : Set where
field
ε : ∀ {i} → K i i
_∙_ : ∀ {i j k} → K i j → K j k → K i k
module IWriterMonad {I} {K : I → I → Set} (mon : IMonoid K) where
open IMonoid mon
return : ∀ {A} {i : I} →
A → IWriter K i i A
return a = a , ε
_>>=_ : ∀ {A B} {i j k : I} →
IWriter K i j A → (A → IWriter K j k B) → IWriter K i k B
(a , w₁) >>= f with f a
... | (b , w₂) = b , w₁ ∙ w₂
```

Now, how is this useful? Imagine you wanted to use the writer to produce a message log or something of the same ilk. With usual boring lists, this is not a problem; but if you wanted to use vectors, you are stuck. How to express that type of the log can change? With the indexed version, you could do something like this:

```
open import Data.Nat
open import Data.Unit
open import Data.Vec
hiding (_>>=_)
open import Function
K : ℕ → ℕ → Set
K i j = Vec ℕ i → Vec ℕ j
K-m : IMonoid K
K-m = record
{ ε = id
; _∙_ = λ f g → g ∘ f
}
open IWriterMonad K-m
tell : ∀ {i j} → Vec ℕ i → IWriter K j (i + j) ⊤
tell v = _ , _++_ v
test : ∀ {i} → IWriter K i (5 + i) ⊤
test =
tell [] >>= λ _ →
tell (4 ∷ 5 ∷ []) >>= λ _ →
tell (1 ∷ 2 ∷ 3 ∷ [])
```

Well, that was a lot of (ad-hoc) code to make a point. I haven't given it much thought, so I'm fairly sure there's nicer/more principled approach, but it illustrates that such dependency allows your code to be more expressive.

Now, you could apply the same thing to `DCont`

, for example:

```
test : Cont.DCont (Vec ℕ) 2 3 ℕ
test c = tail (c 2)
```

If we apply the definitions, the type reduces to `(ℕ → Vec ℕ 3) → Vec ℕ 2`

. Not very convincing example, I know. But perhaps you can some up with something more useful now that you know what this parameter does.