Library Coq.MSets.MSetFacts


Finite sets library

This functor derives additional facts from MSetInterface.S. These facts are mainly the specifications of MSetInterface.S written using different styles: equivalence and boolean equalities. Moreover, we prove that E.Eq and Equal are setoid equalities.

Require Import DecidableTypeEx.
Require Export MSetInterface.
Set Implicit Arguments.

First, a functor for Weak Sets in functorial version.

Module WFactsOn (Import E : DecidableType)(Import M : WSetsOn E).

Notation eq_dec := E.eq_dec.
Definition eqb x y := if eq_dec x y then true else false.

Specifications written using implications :

this used to be the default interface.

Section ImplSpec.
Variable s s' : t.
Variable x y : elt.

Lemma In_1 : E.eq x y -> In x s -> In y s.

Lemma mem_1 : In x s -> mem x s = true.
Lemma mem_2 : mem x s = true -> In x s.

Lemma equal_1 : Equal s s' -> equal s s' = true.
Lemma equal_2 : equal s s' = true -> Equal s s'.

Lemma subset_1 : Subset s s' -> subset s s' = true.
Lemma subset_2 : subset s s' = true -> Subset s s'.

Lemma is_empty_1 : Empty s -> is_empty s = true.
Lemma is_empty_2 : is_empty s = true -> Empty s.

Lemma add_1 : E.eq x y -> In y (add x s).
Lemma add_2 : In y s -> In y (add x s).
Lemma add_3 : ~ E.eq x y -> In y (add x s) -> In y s.

Lemma remove_1 : E.eq x y -> ~ In y (remove x s).
Lemma remove_2 : ~ E.eq x y -> In y s -> In y (remove x s).
Lemma remove_3 : In y (remove x s) -> In y s.

Lemma singleton_1 : In y (singleton x) -> E.eq x y.
Lemma singleton_2 : E.eq x y -> In y (singleton x).

Lemma union_1 : In x (union s s') -> In x s \/ In x s'.
Lemma union_2 : In x s -> In x (union s s').
Lemma union_3 : In x s' -> In x (union s s').

Lemma inter_1 : In x (inter s s') -> In x s.
Lemma inter_2 : In x (inter s s') -> In x s'.
Lemma inter_3 : In x s -> In x s' -> In x (inter s s').

Lemma diff_1 : In x (diff s s') -> In x s.
Lemma diff_2 : In x (diff s s') -> ~ In x s'.
Lemma diff_3 : In x s -> ~ In x s' -> In x (diff s s').

Variable f : elt -> bool.
Notation compatb := (Proper (E.eq==>Logic.eq)) (only parsing).

Lemma filter_1 : compatb f -> In x (filter f s) -> In x s.
Lemma filter_2 : compatb f -> In x (filter f s) -> f x = true.
Lemma filter_3 : compatb f -> In x s -> f x = true -> In x (filter f s).

Lemma for_all_1 : compatb f ->
      For_all (fun x => f x = true) s -> for_all f s = true.
Lemma for_all_2 : compatb f ->
      for_all f s = true -> For_all (fun x => f x = true) s.

Lemma exists_1 : compatb f ->
      Exists (fun x => f x = true) s -> exists_ f s = true.

Lemma exists_2 : compatb f ->
      exists_ f s = true -> Exists (fun x => f x = true) s.

Lemma elements_1 : In x s -> InA E.eq x (elements s).
Lemma elements_2 : InA E.eq x (elements s) -> In x s.

End ImplSpec.

Notation empty_1 := empty_spec (only parsing).
Notation fold_1 := fold_spec (only parsing).
Notation cardinal_1 := cardinal_spec (only parsing).
Notation partition_1 := partition_spec1 (only parsing).
Notation partition_2 := partition_spec2 (only parsing).
Notation choose_1 := choose_spec1 (only parsing).
Notation choose_2 := choose_spec2 (only parsing).
Notation elements_3w := elements_spec2w (only parsing).

#[global]
Hint Resolve mem_1 equal_1 subset_1 empty_1
    is_empty_1 choose_1 choose_2 add_1 add_2 remove_1
    remove_2 singleton_2 union_1 union_2 union_3
    inter_3 diff_3 fold_1 filter_3 for_all_1 exists_1
    partition_1 partition_2 elements_1 elements_3w
    : set.
#[global]
Hint Immediate In_1 mem_2 equal_2 subset_2 is_empty_2 add_3
    remove_3 singleton_1 inter_1 inter_2 diff_1 diff_2
    filter_1 filter_2 for_all_2 exists_2 elements_2
    : set.

Specifications written using equivalences :

this is now provided by the default interface.

Section IffSpec.
Variable s s' s'' : t.
Variable x y z : elt.

Lemma In_eq_iff : E.eq x y -> (In x s <-> In y s).

Lemma mem_iff : In x s <-> mem x s = true.

Lemma not_mem_iff : ~In x s <-> mem x s = false.

Lemma equal_iff : s[=]s' <-> equal s s' = true.

Lemma subset_iff : s[<=]s' <-> subset s s' = true.

Lemma empty_iff : In x empty <-> False.

Lemma is_empty_iff : Empty s <-> is_empty s = true.

Lemma singleton_iff : In y (singleton x) <-> E.eq x y.

Lemma add_iff : In y (add x s) <-> E.eq x y \/ In y s.

Lemma add_neq_iff : ~ E.eq x y -> (In y (add x s) <-> In y s).

Lemma remove_iff : In y (remove x s) <-> In y s /\ ~E.eq x y.

Lemma remove_neq_iff : ~ E.eq x y -> (In y (remove x s) <-> In y s).

Variable f : elt -> bool.

Lemma for_all_iff : Proper (E.eq==>Logic.eq) f ->
  (For_all (fun x => f x = true) s <-> for_all f s = true).

Lemma exists_iff : Proper (E.eq==>Logic.eq) f ->
  (Exists (fun x => f x = true) s <-> exists_ f s = true).

Lemma elements_iff : In x s <-> InA E.eq x (elements s).

End IffSpec.

Notation union_iff := union_spec (only parsing).
Notation inter_iff := inter_spec (only parsing).
Notation diff_iff := diff_spec (only parsing).
Notation filter_iff := filter_spec (only parsing).

Useful tactic for simplifying expressions like In y (add x (union s s'))

Ltac set_iff :=
 repeat (progress (
  rewrite add_iff || rewrite remove_iff || rewrite singleton_iff
  || rewrite union_iff || rewrite inter_iff || rewrite diff_iff
  || rewrite empty_iff)).

Specifications written using boolean predicates


Section BoolSpec.
Variable s s' s'' : t.
Variable x y z : elt.

Lemma mem_b : E.eq x y -> mem x s = mem y s.

Lemma empty_b : mem y empty = false.

Lemma add_b : mem y (add x s) = eqb x y || mem y s.

Lemma add_neq_b : ~ E.eq x y -> mem y (add x s) = mem y s.

Lemma remove_b : mem y (remove x s) = mem y s && negb (eqb x y).

Lemma remove_neq_b : ~ E.eq x y -> mem y (remove x s) = mem y s.

Lemma singleton_b : mem y (singleton x) = eqb x y.

Lemma union_b : mem x (union s s') = mem x s || mem x s'.

Lemma inter_b : mem x (inter s s') = mem x s && mem x s'.

Lemma diff_b : mem x (diff s s') = mem x s && negb (mem x s').

Lemma elements_b : mem x s = existsb (eqb x) (elements s).

Variable f : elt->bool.

Lemma filter_b : Proper (E.eq==>Logic.eq) f -> mem x (filter f s) = mem x s && f x.

Lemma for_all_b : Proper (E.eq==>Logic.eq) f ->
  for_all f s = forallb f (elements s).

Lemma exists_b : Proper (E.eq==>Logic.eq) f ->
  exists_ f s = existsb f (elements s).

End BoolSpec.

Declarations of morphisms with respects to E.eq and Equal


Instance In_m : Proper (E.eq==>Equal==>iff) In.

Instance Empty_m : Proper (Equal==>iff) Empty.

Instance is_empty_m : Proper (Equal==>Logic.eq) is_empty.

Instance mem_m : Proper (E.eq==>Equal==>Logic.eq) mem.

Instance singleton_m : Proper (E.eq==>Equal) singleton.

Instance add_m : Proper (E.eq==>Equal==>Equal) add.

Instance remove_m : Proper (E.eq==>Equal==>Equal) remove.

Instance union_m : Proper (Equal==>Equal==>Equal) union.

Instance inter_m : Proper (Equal==>Equal==>Equal) inter.

Instance diff_m : Proper (Equal==>Equal==>Equal) diff.

Instance Subset_m : Proper (Equal==>Equal==>iff) Subset.

Instance subset_m : Proper (Equal==>Equal==>Logic.eq) subset.

Instance equal_m : Proper (Equal==>Equal==>Logic.eq) equal.

Instance SubsetSetoid : PreOrder Subset.
Definition Subset_refl := @PreOrder_Reflexive _ _ SubsetSetoid.
Definition Subset_trans := @PreOrder_Transitive _ _ SubsetSetoid.

Instance In_s_m : Morphisms.Proper (E.eq ==> Subset ++> impl) In | 1.

Instance Empty_s_m : Proper (Subset-->impl) Empty.

Instance add_s_m : Proper (E.eq==>Subset++>Subset) add.

Instance remove_s_m : Proper (E.eq==>Subset++>Subset) remove.

Instance union_s_m : Proper (Subset++>Subset++>Subset) union.

Instance inter_s_m : Proper (Subset++>Subset++>Subset) inter.

Instance diff_s_m : Proper (Subset++>Subset-->Subset) diff.



Instance filter_equal : forall `(Proper _ (E.eq==>Logic.eq) f),
 Proper (Equal==>Equal) (filter f).

Instance filter_subset : forall `(Proper _ (E.eq==>Logic.eq) f),
 Proper (Subset==>Subset) (filter f).

Lemma filter_ext : forall f f', Proper (E.eq==>Logic.eq) f -> (forall x, f x = f' x) ->
 forall s s', s[=]s' -> filter f s [=] filter f' s'.



End WFactsOn.

Now comes variants for self-contained weak sets and for full sets. For these variants, only one argument is necessary. Thanks to the subtyping WS<=S, the Facts functor which is meant to be used on modules (M:S) can simply be an alias of WFacts.

Module WFacts (M:WSets) := WFactsOn M.E M.
Module Facts := WFacts.