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1

Here's how I'd write this as a simplified example Consider a simple data type Inductive Foo := | Bar : nat -> Foo | Baz. And now we define a helpful function Definition bar f := match f with | Bar _ => True | Baz => False end. And finally what you want to write: Definition example f := match f return bar f -> nat with ...

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Yes, you are on the right lines. You want: Definition example2 (x:Example) (example_pred x) : nat := and how to proceed further would depend on what you wanted to prove. You might find it helpful to make a definition by proving with tactics, using the Curry-Howard correspondence: Definition example2 (x:Example) (example_pred x) : nat. Proof. some ...

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You can't do case analysis on H0 because {qr : nat * nat | P (S a) b qr} is a Set or Type. Only or_ind is defined for or, so it would need to be a Prop instead. If you use sum you'll have sum_ind, sum_rec, and sum_rect. (snd x < b - 1) + (snd x >= b - 1) Prop is designed that way so that it's consistent with certain axioms.

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No, it is not possible to prove that a nontrivial tool is correct using the tool itself. This was basically stated in Gödel's second incompleteness theorem: For any formal effectively generated theory T including basic arithmetical truths and also certain truths about formal provability, if T includes a statement of its own consistency then T is ...

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First of all, I would repair your definitions. E.g., using your version of is_sorted is too strict in the sense, that [0,0] is not sorted. This is also detected by quick check. fun is_sorted :: "nat list ⇒ bool" where "is_sorted (x1 # x2 # xs) = (x1 <= x2 ∧ is_sorted (x2 # xs))" | "is_sorted x = True" bubble_all has to call itself recursively. ...

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