3

Here is a sample function:

fun divide :: "enat option ⇒ enat option ⇒ real option" where
  "divide (Some ∞) _ = None"
| "divide _ (Some ∞) = None"
| "divide _ (Some 0) = None"
| "divide (Some a) (Some b) = Some (a / b)"
| "divide _ _ = None"

Isabelle HOL shows me the following error:

Malformed definition:
Non-constructor pattern not allowed in sequential mode.
⋀uw_. divide uw_ (Some 0) = None

Why pattern-matching works fine for Some ∞ and doesn't work for Some 0? is a constant for class infinity and 0 is a constant for class zero. What is the difference between these constants?

5

Pattern matching with fun only works for constructors, which are typically generated using datatype and codatatype commands. (In fact, it suffices if they are registered as free constructors using free_constructors.) The extended naturals enat as defined in ~~/src/HOL/Library/Extended_Nat have two such constructors registered: and enat :: nat ⇒ enat. So 0 is not a constructor of enat, but of the ordinary naturals nat. So if you write

| "divide _ (Some (enat 0)) = None"

instead, it will work because there are only registered constructors in the patterns.

Conversely, if your theory imports Coinductive_Nat from the APF entry Coinductive, then enat is registered to have the constructors 0 and eSuc, i.e., as if it were a codatatype. Then you can pattern-match on 0, but you can no longer pattern match on .

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.