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I want to make a function of natural numbers comparison in coq I declare a Set of invariant contain sup, inf, egal

Inductive invr:Type:=inf | sup | egal.

And I define a function comparaison

Definition comparaison (inv:invr)(a b:nat):bool:=
  match invr with
  |inf => if (a < b) then true else false  
  |sup => if (a > b) then true else false 
  |egal=> if (a = b) then true else false 
  end. 

But it does not work! Thanks for your response.

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1  
"it does not work" is not a proper way to explain your problem. –  Ptival Apr 3 at 15:16

2 Answers 2

You are trying to match type (set) invr with its constructors values instead of variable inv, so you get an error

The term "invr" has type "Set" while it is expected to have type "invr".

You need to do the matching for inv, not invr

Definition comparaison (inv:invr)(a b:nat):bool:=
  match inv with
  |inf => if (a < b) then true else false  
  |sup => if (a > b) then true else false 
  |egal=> if (a = b) then true else false 
  end. 

Also make sure that you have <, >, = notations are defined to return bool, because by default they return Prop, which can't be used in if/else. So you need to use beq_nat, and leb from Arith.

Simplified final version (removed redundant if/else branches).

Require Import Coq.Arith.Arith.

Inductive invr : Type:= inf | sup | egal.

Definition comparaison (inv:invr)(a b:nat):bool:=
  match inv with
  |inf => leb a b
  |sup => leb b a
  |egal=> beq_nat a b
  end. 
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thank you very much , it does working –  NAAS1425 Apr 4 at 8:37
    
@NAAS1425 no problem. In that case please accept the answer and close the question –  romantsegelskyi Apr 4 at 12:27

This is a typical beginner mistake.

< stands for lt, which has type:

lt : nat -> nat -> Prop

That is, a < b is just a proposition, not a procedure that computes whether a is less than b! The same goes for equality.

What you want to use is a function that computes the truth of these propositions, either as a boolean or as a richer type:

In the library Arith:

beq_nat: nat -> nat -> bool
leb: nat -> nat -> bool

(* or the more informative versions which return proofs of what they decide *)
eq_nat_dec: forall n m : nat, {n = m} + {n <> m}
lt_dec: forall n m : nat, {n < m} + {~ n < m}

So the following is a valid expression:

if beq_nat a b then true else false

Also note that the following is a valid expression equivalent to the precedent one (since beq_nat returns a bool):

beq_nat a b
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thank you very much, –  NAAS1425 Apr 4 at 8:38

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