Library Coq.Classes.SetoidClass
Typeclass-based setoids, tactics and standard instances.
Set Implicit Arguments.
Require Import Coq.Program.Program.
Require Import Relation_Definitions.
Require Export Coq.Classes.RelationClasses.
Require Export Coq.Classes.Morphisms.
A setoid wraps an equivalence.
Shortcuts to make proof search easier.
Definition setoid_refl `(sa : Setoid A) : Reflexive equiv.
Definition setoid_sym `(sa : Setoid A) : Symmetric equiv.
Definition setoid_trans `(sa : Setoid A) : Transitive equiv.
Standard setoids.
Overloaded notations for setoid equivalence and inequivalence. Not to be confused with eq and =.
Subset objects should be first coerced to their underlying type, but that notation doesn't work in the standard case then.
Notation " x == y " := (equiv x y) (at level 70, no associativity) : type_scope.
Notation " x =/= y " := (complement equiv x y) (at level 70, no associativity) : type_scope.
Use the clsubstitute command which substitutes an equality in every hypothesis.
Ltac clsubst H :=
lazymatch type of H with
?x == ?y => substitute H ; clear H x
end.
Ltac clsubst_nofail :=
match goal with
| [ H : ?x == ?y |- _ ] => clsubst H ; clsubst_nofail
| _ => idtac
end.
subst* will try its best at substituting every equality in the goal.
Tactic Notation "clsubst" "*" := clsubst_nofail.
Lemma nequiv_equiv_trans : forall `{Setoid A} (x y z : A), x =/= y -> y == z -> x =/= z.
Lemma equiv_nequiv_trans : forall `{Setoid A} (x y z : A), x == y -> y =/= z -> x =/= z.
Ltac setoid_simplify_one :=
match goal with
| [ H : (?x == ?x)%type |- _ ] => clear H
| [ H : (?x == ?y)%type |- _ ] => clsubst H
| [ |- (?x =/= ?y)%type ] => let name:=fresh "Hneq" in intro name
end.
Ltac setoid_simplify := repeat setoid_simplify_one.
Ltac setoidify_tac :=
match goal with
| [ s : Setoid ?A, H : ?R ?x ?y |- _ ] => change R with (@equiv A R s) in H
| [ s : Setoid ?A |- context C [ ?R ?x ?y ] ] => change (R x y) with (@equiv A R s x y)
end.
Ltac setoidify := repeat setoidify_tac.
Every setoid relation gives rise to a morphism, in fact every partial setoid does.
Program Instance setoid_morphism `(sa : Setoid A) : Proper (equiv ++> equiv ++> iff) equiv :=
proper_prf.
Program Instance setoid_partial_app_morphism `(sa : Setoid A) (x : A) : Proper (equiv ++> iff) (equiv x) :=
proper_prf.
Partial setoids don't require reflexivity so we can build a partial setoid on the function space.
Overloaded notation for partial setoid equivalence.
Reset the default Program tactic.
Obligation Tactic := program_simpl.