Lvc.Constr.CMapJoinSemiLattice

Require Import CSet CMap CMapDomain CMapPartialOrder.
Require Import Infra.PartialOrder Infra.Lattice Infra.OptionR.

Require Import MapNotations.
Set Implicit Arguments.

Definition joinMap X `{OrderedType X} Y `{JoinSemiLattice Y}
           (d d':Map [X, Y]) := @map2 _ H _ Y Y Y join d d'.

Lemma leMap_join X `{OrderedType X} Y `{JoinSemiLattice Y} (x y x' y':Map[X, Y])
  : leMap y x
     leMap y' x'
     leMap (joinMap y y') (joinMap x x').
Proof.
  unfold leMap, joinMap.
  intros LE1 LE2 z.
  repeat rewrite MapFacts.map2_1bis; eauto.
  specialize (LE1 z). specialize (LE2 z).
  revert LE1 LE2.
  case_eq (find z y); case_eq (find z x);
    case_eq (find z y'); case_eq (find z x'); intros; simpl in *;
      clear_trivial_eqs; simpl; repeat cases; try reflexivity;
        eauto using fstNoneOrR, join_struct, join_poLe.
Qed.

Lemma empty_bottom X `{OrderedType X} Y `{PartialOrder Y}
  : a : Map [X, Y], @empty _ _ _ _ a.
Proof.
  intros. econstructor.
Qed.

Lemma joinDom_bound X `{OrderedType X} Y `{JoinSemiLattice Y}
  : a b : Map [X, Y], poLe a b poLe (joinMap a b) b.
Proof.
  unfold joinMap. intros.
  hnf; intros.
  rewrite MapFacts.map2_1bis; eauto.
  rewrite join_bound; eauto.
Qed.

Lemma joinDom_sym X `{OrderedType X} Y `{JoinSemiLattice Y}
  : a b : Map [X, Y], joinMap a b joinMap b a.
Proof.
  unfold joinMap; intros. hnf; intros.
  rewrite !MapFacts.map2_1bis; eauto.
  rewrite join_commutative. reflexivity.
Qed.

Lemma joinDom_assoc X `{OrderedType X} Y `{JoinSemiLattice Y}
  : a b c : Map [X, Y], joinMap (joinMap a b) c joinMap a (joinMap b c).
Proof.
  unfold joinMap; intros. hnf; intros.
  rewrite !MapFacts.map2_1bis; eauto.
  rewrite join_associative. reflexivity.
Qed.

Lemma joinDom_exp X `{OrderedType X} Y `{JoinSemiLattice Y}
  : a b : Map [X, Y], a joinMap a b.
Proof.
  intros. unfold joinMap. hnf; intros.
  rewrite !MapFacts.map2_1bis; eauto.
  eapply join_poLe.
Qed.

Instance joinDom_eq X `{OrderedType X} Y `{JoinSemiLattice Y}
  : Proper (poEq ==> poEq ==> poEq) (@joinMap X _ Y _ _).
Proof.
  unfold Proper, respectful; intros.
  hnf in H, H0.
  unfold joinMap.
  hnf; intros.
  rewrite !MapFacts.map2_1bis; eauto.
  rewrite H2, H3. reflexivity.
Qed.

Instance joinDom_poLe X `{OrderedType X} Y `{JoinSemiLattice Y}
  : Proper (poLe ==> poLe ==> poLe) (@joinMap X _ Y _ _).
Proof.
  unfold Proper, respectful; intros.
  eapply leMap_join; eauto.
Qed.

Instance map_semilattice X `{OrderedType X} Y `{JoinSemiLattice Y}
  : JoinSemiLattice (Map [X, Y]) := {
  join := @joinMap X _ Y _ _
                                                    }.

- eapply joinDom_bound.
- eapply joinDom_sym.
- eapply joinDom_assoc.
- eapply joinDom_exp.
Defined.

Instance map_lower_bounded X `{OrderedType X} Y `{PartialOrder Y}
  : LowerBounded (Map [X, Y]) :=
  {
    bottom := (@empty X _ _ Y)
  }.
Proof.
  - eapply empty_bottom; eauto.
Defined.

Import Terminating.

Lemma leMap_domain X `{OrderedType X} Y `{PartialOrder Y} x y
  : leMap x y domain x domain y.
Proof.
  unfold leMap. intros.
  hnf; intros.
  specialize (H1 a).
  eapply domain_find in H2. dcr.
  rewrite H3 in H1. inv H1.
  eapply find_domain. congruence.
Qed.

Instance ltMap_proper X `{OrderedType X} Y `{PartialOrder Y} (d d':Map [X, Y])
  : Proper (_eq ==> iff) (fun xfind x d find x d').
Proof.
  unfold Proper, respectful; intros.
  split; intros.
  - rewrite <- H1; eauto.
  - rewrite H1; eauto.
Qed.

Lemma domain_join X `{OrderedType X} Y `{JoinSemiLattice Y} (d d':Map[X,Y])
: domain (map2 join d d') [=] domain d domain d'.
Proof.
  split; intros.
  - eapply domain_find in H2; dcr.
    rewrite MapFacts.map2_1bis in H3; eauto.
    revert H3.
    case_eq (find a d); intros.
    + eapply find_domain' in H2. cset_tac.
    + revert H3.
      case_eq (find a d'); intros; simpl in *;
        clear_trivial_eqs.
      × eapply find_domain' in H3. cset_tac.
  - eapply find_domain.
    rewrite MapFacts.map2_1bis; eauto.
    cset_tac'.
    + eapply domain_find in H4. dcr.
      rewrite H2 in H3.
      destruct (find a d'); clear_trivial_eqs.
    + eapply domain_find in H4. dcr.
      rewrite H2 in H3.
      destruct (find a d); clear_trivial_eqs.
Qed.