# “Strictly positive” in Agda

I'm trying to encode some denotational semantics into Agda based on a program I wrote in Haskell.

``````data Value = FunVal (Value -> Value)
| PriVal Int
| ConVal Id [Value]
| Error  String
``````

In Agda, the direct translation would be;

``````data Value : Set where
FunVal : (Value -> Value) -> Value
PriVal : ℕ -> Value
ConVal : String -> List Value -> Value
Error  : String -> Value
``````

but I get an error relating to the FunVal because;

Value is not strictly positive, because it occurs to the left of an arrow in the type of the constructor FunVal in the definition of Value.

What does this mean? Can I encode this in Agda? Am I going about it the wrong way?

Thanks.

• You might be interested in PHOAS, explained by Chlipala here. – danr Feb 9 '12 at 21:22
• Thanks. I've had a little play with that since. – Jason Reich Feb 22 '12 at 11:27

HOAS doesn't work in Agda, because of this:

``````apply : Value -> Value -> Value
apply (FunVal f) x = f x
apply _ x = Error "Applying non-function"

w : Value
w = FunVal (\x -> apply x x)
``````

Now, notice that evaluating `apply w w` gives you `apply w w` back again. The term `apply w w` has no normal form, which is a no-no in agda. Using this idea and the type:

``````data P : Set where
MkP : (P -> Set) -> P
``````

One of the ways out of these paradoxes is only to allow strictly positive recursive types, which is what Agda and Coq choose. That means that if you declare:

``````data X : Set where
MkX : F X -> X
``````

That `F` must be a strictly positive functor, which means that `X` may never occur to the left of any arrow. So these types are strictly positive in `X`:

``````X * X
Nat -> X
X * (Nat -> X)
``````

But these are not:

``````X -> Bool
(X -> Nat) -> Nat  -- this one is "positive", but not strictly
(X * Nat) -> X
``````

So in short, no you can't represent your data type in Agda. You can use de Bruijn encoding to get a term type you can work with, but usually the evaluation function needs some sort of "timeout" (generally called "fuel"), e.g. a maximum number of steps to evaluate, because Agda requires all functions to be total. Here is an example due to @gallais that uses a coinductive partiality type to accomplish this.

• Thanks very much. I had an inkling about something like this but didn't entirely understand. – Jason Reich Apr 6 '10 at 9:59
• "the simply typed lambda calculus [...] has terms without normal forms" Is that true? I thought the simply typed lambda calculus (as opposed to the untyped lambda calculus or the more complexly typed variations of the lambda calculus) always reduces to a normal form (unless you add the fixpoint operator as a built-in), which is why it is not turing-complete. – sepp2k Apr 6 '10 at 12:11
• sepp2k, yes, my mistake. I meant untyped, but braino'd. – luqui Apr 7 '10 at 4:15
• It's worth adding that you can actually embed the untyped lambda calculus into Agda by evaluating it in the partiality monad, which models possible non-termination with a possibly infinite number of discrete steps. – copumpkin Apr 26 '12 at 4:33
• – gallais Jun 6 '18 at 8:21