I'm having a bit of trouble understanding the difference between strong and weak specification in Coq. For instance, if I wanted to write the replicate function (given a number n and a value x, it creates a list of length n, with all elements equal to x) using the strong specification way, how would I be able to do that? Apparently I have to write an Inductive "version" of the function but how?

Definition in Haskell:

```
myReplicate :: Int -> a -> [a]
myReplicate 0 _ = []
myReplicate n x | n > 0 = x:myReplicate (n-1) x
| otherwise = []
```

**Definition of weak specification**:

To define these functions with a weak specification and then add companion lemmas.
For instance, we define a function f : A->B and we prove a statement of the form ∀ x:A, *Rx* (*fx*), where R is a relation coding the intended input/output behaviour of the function.

**Definition of strong specification**:

To give a strong specification of the function: the type of this function directly states that the input is a value x of type A and that the output is the combination of a value v of type B and a proof that v satisfies *Rxv*.
This kind of specification usually relies on dependent types.

EDIT: I heard back from my teacher and apparently I have to do something similar to this, but for the replicate case:

"For example, if we want to extract a function that computes the length of a list from its specification, we can define a relation RelLength which establishes a relation between the expected input and output and then prove it. Like this:

```
Inductive RelLength (A:Type) : nat -> list A -> Prop :=
| len_nil : RelLength 0 nil
| len_cons : forall l x n, RelLength n l -> RelLength (S n) (x::l) .
Theorem len_corr : forall (A:Type) (l:list A), {n | RelLength n l}.
Proof.
…
Qed.
Recursive Extraction len_corr.
```

The function used to prove must use the list “recursor” directly (that’s why fixpoint won’t show up - it’s hidden in list_rect).

So you don’t need to write the function itself, only the relation, because the function will be defined by the proof."

Knowing this, how can I apply it to the replicate function case?

`replicate: forall a, nat -> a -> list a`

to something like`replicate: forall a (n: nat) (x: a), {xs: list a | length xs = n /\ all (fun y => y=x) xs }`

where the type contains the correctness property. (I'm not sure if I got the whole Coq syntax right, but that should illustrate the general idea) – chi May 23 at 16:26`fun`

is the Coq syntax for the lambda. I think you need`Fixpoint`

anyway, but I am not fluent enough in Coq to suggest the best way to do it. – chi May 23 at 16:574more comments