diff options
Diffstat (limited to 'theories/Lists/SetoidList.v')
-rw-r--r-- | theories/Lists/SetoidList.v | 497 |
1 files changed, 322 insertions, 175 deletions
diff --git a/theories/Lists/SetoidList.v b/theories/Lists/SetoidList.v index eb40594b..4edc1581 100644 --- a/theories/Lists/SetoidList.v +++ b/theories/Lists/SetoidList.v @@ -6,7 +6,7 @@ (* * GNU Lesser General Public License Version 2.1 *) (***********************************************************************) -(* $Id: SetoidList.v 8853 2006-05-23 18:17:38Z herbelin $ *) +(* $Id: SetoidList.v 10616 2008-03-04 17:33:35Z letouzey $ *) Require Export List. Require Export Sorting. @@ -21,7 +21,7 @@ Unset Strict Implicit. found in [Sorting]. *) Section Type_with_equality. -Variable A : Set. +Variable A : Type. Variable eqA : A -> A -> Prop. (** Being in a list modulo an equality relation over type [A]. *) @@ -32,6 +32,18 @@ Inductive InA (x : A) : list A -> Prop := Hint Constructors InA. +Lemma InA_cons : forall x y l, InA x (y::l) <-> eqA x y \/ InA x l. +Proof. + intuition. + inversion H; auto. +Qed. + +Lemma InA_nil : forall x, InA x nil <-> False. +Proof. + intuition. + inversion H. +Qed. + (** An alternative definition of [InA]. *) Lemma InA_alt : forall x l, InA x l <-> exists y, eqA x y /\ In y l. @@ -53,7 +65,28 @@ Hint Constructors NoDupA. (** lists with same elements modulo [eqA] *) -Definition eqlistA l l' := forall x, InA x l <-> InA x l'. +Definition equivlistA l l' := forall x, InA x l <-> InA x l'. + +(** lists with same elements modulo [eqA] at the same place *) + +Inductive eqlistA : list A -> list A -> Prop := + | eqlistA_nil : eqlistA nil nil + | eqlistA_cons : forall x x' l l', + eqA x x' -> eqlistA l l' -> eqlistA (x::l) (x'::l'). + +Hint Constructors eqlistA. + +(** Compatibility of a boolean function with respect to an equality. *) + +Definition compat_bool (f : A->bool) := forall x y, eqA x y -> f x = f y. + +(** Compatibility of a function upon natural numbers. *) + +Definition compat_nat (f : A->nat) := forall x y, eqA x y -> f x = f y. + +(** Compatibility of a predicate with respect to an equality. *) + +Definition compat_P (P : A->Prop) := forall x y, eqA x y -> P x -> P y. (** Results concerning lists modulo [eqA] *) @@ -91,6 +124,35 @@ exists (a::l1); exists y; exists l2; auto. split; simpl; f_equal; auto. Qed. +Lemma InA_app : forall l1 l2 x, + InA x (l1 ++ l2) -> InA x l1 \/ InA x l2. +Proof. + induction l1; simpl in *; intuition. + inversion_clear H; auto. + elim (IHl1 l2 x H0); auto. +Qed. + +Lemma InA_app_iff : forall l1 l2 x, + InA x (l1 ++ l2) <-> InA x l1 \/ InA x l2. +Proof. + split. + apply InA_app. + destruct 1; generalize H; do 2 rewrite InA_alt. + destruct 1 as (y,(H1,H2)); exists y; split; auto. + apply in_or_app; auto. + destruct 1 as (y,(H1,H2)); exists y; split; auto. + apply in_or_app; auto. +Qed. + +Lemma InA_rev : forall p m, + InA p (rev m) <-> InA p m. +Proof. + intros; do 2 rewrite InA_alt. + split; intros (y,H); exists y; intuition. + rewrite In_rev; auto. + rewrite <- In_rev; auto. +Qed. + (** Results concerning lists modulo [eqA] and [ltA] *) Variable ltA : A -> A -> Prop. @@ -106,10 +168,12 @@ Hint Immediate ltA_eqA eqA_ltA. Notation InfA:=(lelistA ltA). Notation SortA:=(sort ltA). +Hint Constructors lelistA sort. + Lemma InfA_ltA : forall l x y, ltA x y -> InfA y l -> InfA x l. Proof. - intro s; case s; constructor; inversion_clear H0. + destruct l; constructor; inversion_clear H0; eapply ltA_trans; eauto. Qed. @@ -153,6 +217,26 @@ intros; eapply SortA_InfA_InA; eauto. apply InA_InfA. Qed. +Lemma InfA_app : forall l1 l2 a, InfA a l1 -> InfA a l2 -> InfA a (l1++l2). +Proof. + induction l1; simpl; auto. + inversion_clear 1; auto. +Qed. + +Lemma SortA_app : + forall l1 l2, SortA l1 -> SortA l2 -> + (forall x y, InA x l1 -> InA y l2 -> ltA x y) -> + SortA (l1 ++ l2). +Proof. + induction l1; simpl in *; intuition. + inversion_clear H. + constructor; auto. + apply InfA_app; auto. + destruct l2; auto. +Qed. + +Section NoDupA. + Lemma SortA_NoDupA : forall l, SortA l -> NoDupA l. Proof. simple induction l; auto. @@ -185,7 +269,6 @@ intros. apply (H1 x); auto. Qed. - Lemma NoDupA_rev : forall l, NoDupA l -> NoDupA (rev l). Proof. induction l. @@ -206,33 +289,240 @@ rewrite In_rev; auto. inversion H4. Qed. +Lemma NoDupA_split : forall l l' x, NoDupA (l++x::l') -> NoDupA (l++l'). +Proof. + induction l; simpl in *; inversion_clear 1; auto. + constructor; eauto. + contradict H0. + rewrite InA_app_iff in *; rewrite InA_cons; intuition. +Qed. -Lemma InA_app : forall l1 l2 x, - InA x (l1 ++ l2) -> InA x l1 \/ InA x l2. +Lemma NoDupA_swap : forall l l' x, NoDupA (l++x::l') -> NoDupA (x::l++l'). Proof. - induction l1; simpl in *; intuition. - inversion_clear H; auto. - elim (IHl1 l2 x H0); auto. + induction l; simpl in *; inversion_clear 1; auto. + constructor; eauto. + assert (H2:=IHl _ _ H1). + inversion_clear H2. + rewrite InA_cons. + red; destruct 1. + apply H0. + rewrite InA_app_iff in *; rewrite InA_cons; auto. + apply H; auto. + constructor. + contradict H0. + rewrite InA_app_iff in *; rewrite InA_cons; intuition. + eapply NoDupA_split; eauto. Qed. - Hint Constructors lelistA sort. +End NoDupA. -Lemma InfA_app : forall l1 l2 a, InfA a l1 -> InfA a l2 -> InfA a (l1++l2). +(** Some results about [eqlistA] *) + +Section EqlistA. + +Lemma eqlistA_length : forall l l', eqlistA l l' -> length l = length l'. Proof. - induction l1; simpl; auto. - inversion_clear 1; auto. +induction 1; auto; simpl; congruence. Qed. -Lemma SortA_app : - forall l1 l2, SortA l1 -> SortA l2 -> - (forall x y, InA x l1 -> InA y l2 -> ltA x y) -> - SortA (l1 ++ l2). +Lemma eqlistA_app : forall l1 l1' l2 l2', + eqlistA l1 l1' -> eqlistA l2 l2' -> eqlistA (l1++l2) (l1'++l2'). Proof. - induction l1; simpl in *; intuition. - inversion_clear H. - constructor; auto. - apply InfA_app; auto. - destruct l2; auto. +intros l1 l1' l2 l2' H; revert l2 l2'; induction H; simpl; auto. +Qed. + +Lemma eqlistA_rev_app : forall l1 l1', + eqlistA l1 l1' -> forall l2 l2', eqlistA l2 l2' -> + eqlistA ((rev l1)++l2) ((rev l1')++l2'). +Proof. +induction 1; auto. +simpl; intros. +do 2 rewrite app_ass; simpl; auto. +Qed. + +Lemma eqlistA_rev : forall l1 l1', + eqlistA l1 l1' -> eqlistA (rev l1) (rev l1'). +Proof. +intros. +rewrite (app_nil_end (rev l1)). +rewrite (app_nil_end (rev l1')). +apply eqlistA_rev_app; auto. +Qed. + +Lemma SortA_equivlistA_eqlistA : forall l l', + SortA l -> SortA l' -> equivlistA l l' -> eqlistA l l'. +Proof. +induction l; destruct l'; simpl; intros; auto. +destruct (H1 a); assert (H4 : InA a nil) by auto; inversion H4. +destruct (H1 a); assert (H4 : InA a nil) by auto; inversion H4. +inversion_clear H; inversion_clear H0. +assert (forall y, InA y l -> ltA a y). +intros; eapply SortA_InfA_InA with (l:=l); eauto. +assert (forall y, InA y l' -> ltA a0 y). +intros; eapply SortA_InfA_InA with (l:=l'); eauto. +clear H3 H4. +assert (eqA a a0). + destruct (H1 a). + destruct (H1 a0). + assert (InA a (a0::l')) by auto. + inversion_clear H8; auto. + assert (InA a0 (a::l)) by auto. + inversion_clear H8; auto. + elim (@ltA_not_eqA a a); auto. + apply ltA_trans with a0; auto. +constructor; auto. +apply IHl; auto. +split; intros. +destruct (H1 x). +assert (H8 : InA x (a0::l')) by auto; inversion_clear H8; auto. +elim (@ltA_not_eqA a x); eauto. +destruct (H1 x). +assert (H8 : InA x (a::l)) by auto; inversion_clear H8; auto. +elim (@ltA_not_eqA a0 x); eauto. +Qed. + +End EqlistA. + +(** A few things about [filter] *) + +Section Filter. + +Lemma filter_sort : forall f l, SortA l -> SortA (List.filter f l). +Proof. +induction l; simpl; auto. +inversion_clear 1; auto. +destruct (f a); auto. +constructor; auto. +apply In_InfA; auto. +intros. +rewrite filter_In in H; destruct H. +eapply SortA_InfA_InA; eauto. +Qed. + +Lemma filter_InA : forall f, (compat_bool f) -> + forall l x, InA x (List.filter f l) <-> InA x l /\ f x = true. +Proof. +intros; do 2 rewrite InA_alt; intuition. +destruct H0 as (y,(H0,H1)); rewrite filter_In in H1; exists y; intuition. +destruct H0 as (y,(H0,H1)); rewrite filter_In in H1; intuition. + rewrite (H _ _ H0); auto. +destruct H1 as (y,(H0,H1)); exists y; rewrite filter_In; intuition. + rewrite <- (H _ _ H0); auto. +Qed. + +Lemma filter_split : + forall f, (forall x y, f x = true -> f y = false -> ltA x y) -> + forall l, SortA l -> l = filter f l ++ filter (fun x=>negb (f x)) l. +Proof. +induction l; simpl; intros; auto. +inversion_clear H0. +pattern l at 1; rewrite IHl; auto. +case_eq (f a); simpl; intros; auto. +assert (forall e, In e l -> f e = false). + intros. + assert (H4:=SortA_InfA_InA H1 H2 (In_InA H3)). + case_eq (f e); simpl; intros; auto. + elim (@ltA_not_eqA e e); auto. + apply ltA_trans with a; eauto. +replace (List.filter f l) with (@nil A); auto. +generalize H3; clear; induction l; simpl; auto. +case_eq (f a); auto; intros. +rewrite H3 in H; auto; try discriminate. +Qed. + +End Filter. + +Section Fold. + +Variable B:Type. +Variable eqB:B->B->Prop. + +(** Compatibility of a two-argument function with respect to two equalities. *) +Definition compat_op (f : A -> B -> B) := + forall (x x' : A) (y y' : B), eqA x x' -> eqB y y' -> eqB (f x y) (f x' y'). + +(** Two-argument functions that allow to reorder their arguments. *) +Definition transpose (f : A -> B -> B) := + forall (x y : A) (z : B), eqB (f x (f y z)) (f y (f x z)). + +Variable st:Setoid_Theory _ eqB. +Variable f:A->B->B. +Variable i:B. +Variable Comp:compat_op f. + +Lemma fold_right_eqlistA : + forall s s', eqlistA s s' -> + eqB (fold_right f i s) (fold_right f i s'). +Proof. +induction 1; simpl; auto. +refl_st. +Qed. + +Variable Ass:transpose f. + +Lemma fold_right_commutes : forall s1 s2 x, + eqB (fold_right f i (s1++x::s2)) (f x (fold_right f i (s1++s2))). +Proof. +induction s1; simpl; auto; intros. +refl_st. +trans_st (f a (f x (fold_right f i (s1++s2)))). +Qed. + +Lemma equivlistA_NoDupA_split : forall l l1 l2 x y, eqA x y -> + NoDupA (x::l) -> NoDupA (l1++y::l2) -> + equivlistA (x::l) (l1++y::l2) -> equivlistA l (l1++l2). +Proof. + intros; intro a. + generalize (H2 a). + repeat rewrite InA_app_iff. + do 2 rewrite InA_cons. + inversion_clear H0. + assert (SW:=NoDupA_swap H1). + inversion_clear SW. + rewrite InA_app_iff in H0. + split; intros. + assert (~eqA a x). + contradict H3; apply InA_eqA with a; auto. + assert (~eqA a y). + contradict H8; eauto. + intuition. + assert (eqA a x \/ InA a l) by intuition. + destruct H8; auto. + elim H0. + destruct H7; [left|right]; eapply InA_eqA; eauto. +Qed. + +Lemma fold_right_equivlistA : + forall s s', NoDupA s -> NoDupA s' -> + equivlistA s s' -> eqB (fold_right f i s) (fold_right f i s'). +Proof. + simple induction s. + destruct s'; simpl. + intros; refl_st; auto. + unfold equivlistA; intros. + destruct (H1 a). + assert (X : InA a nil); auto; inversion X. + intros x l Hrec s' N N' E; simpl in *. + assert (InA x s'). + rewrite <- (E x); auto. + destruct (InA_split H) as (s1,(y,(s2,(H1,H2)))). + subst s'. + trans_st (f x (fold_right f i (s1++s2))). + apply Comp; auto. + apply Hrec; auto. + inversion_clear N; auto. + eapply NoDupA_split; eauto. + eapply equivlistA_NoDupA_split; eauto. + trans_st (f y (fold_right f i (s1++s2))). + apply Comp; auto; refl_st. + sym_st; apply fold_right_commutes. +Qed. + +Lemma fold_right_add : + forall s' s x, NoDupA s -> NoDupA s' -> ~ InA x s -> + equivlistA s' (x::s) -> eqB (fold_right f i s') (f x (fold_right f i s)). +Proof. + intros; apply (@fold_right_equivlistA s' (x::s)); auto. Qed. Section Remove. @@ -279,7 +569,7 @@ destruct H0; apply eqA_trans with a; auto. split. inversion_clear 1. split; auto. -swap n. +contradict n. apply eqA_trans with y; auto. rewrite (IHl x y) in H0; destruct H0; auto. destruct 1; inversion_clear H; auto. @@ -298,14 +588,14 @@ rewrite removeA_InA. intuition. Qed. -Lemma removeA_eqlistA : forall l l' x, - ~InA x l -> eqlistA (x :: l) l' -> eqlistA l (removeA x l'). +Lemma removeA_equivlistA : forall l l' x, + ~InA x l -> equivlistA (x :: l) l' -> equivlistA l (removeA x l'). Proof. -unfold eqlistA; intros. +unfold equivlistA; intros. rewrite removeA_InA. split; intros. rewrite <- H0; split; auto. -swap H. +contradict H. apply InA_eqA with x0; auto. rewrite <- (H0 x0) in H1. destruct H1. @@ -313,160 +603,17 @@ inversion_clear H1; auto. elim H2; auto. Qed. -Let addlistA x l l' := forall y, InA y l' <-> eqA x y \/ InA y l. - -Lemma removeA_add : - forall s s' x x', NoDupA s -> NoDupA (x' :: s') -> - ~ eqA x x' -> ~ InA x s -> - addlistA x s (x' :: s') -> addlistA x (removeA x' s) s'. -Proof. -unfold addlistA; intros. -inversion_clear H0. -rewrite removeA_InA; auto. -split; intros. -destruct (eqA_dec x y); auto; intros. -right; split; auto. -destruct (H3 y); clear H3. -destruct H6; intuition. -swap H4; apply InA_eqA with y; auto. -destruct H0. -assert (InA y (x' :: s')) by (rewrite H3; auto). -inversion_clear H6; auto. -elim H1; apply eqA_trans with y; auto. -destruct H0. -assert (InA y (x' :: s')) by (rewrite H3; auto). -inversion_clear H7; auto. -elim H6; auto. -Qed. - -Section Fold. - -Variable B:Set. -Variable eqB:B->B->Prop. - -(** Two-argument functions that allow to reorder its arguments. *) -Definition transpose (f : A -> B -> B) := - forall (x y : A) (z : B), eqB (f x (f y z)) (f y (f x z)). - -(** Compatibility of a two-argument function with respect to two equalities. *) -Definition compat_op (f : A -> B -> B) := - forall (x x' : A) (y y' : B), eqA x x' -> eqB y y' -> eqB (f x y) (f x' y'). - -(** Compatibility of a function upon natural numbers. *) -Definition compat_nat (f : A -> nat) := - forall x x' : A, eqA x x' -> f x = f x'. - -Variable st:Setoid_Theory _ eqB. -Variable f:A->B->B. -Variable Comp:compat_op f. -Variable Ass:transpose f. -Variable i:B. - -Lemma removeA_fold_right_0 : - forall s x, ~InA x s -> - eqB (fold_right f i s) (fold_right f i (removeA x s)). -Proof. - simple induction s; simpl; intros. - refl_st. - destruct (eqA_dec x a); simpl; intros. - absurd_hyp e; auto. - apply Comp; auto. -Qed. - -Lemma removeA_fold_right : - forall s x, NoDupA s -> InA x s -> - eqB (fold_right f i s) (f x (fold_right f i (removeA x s))). -Proof. - simple induction s; simpl. - inversion_clear 2. - intros. - inversion_clear H0. - destruct (eqA_dec x a); simpl; intros. - apply Comp; auto. - apply removeA_fold_right_0; auto. - swap H2; apply InA_eqA with x; auto. - inversion_clear H1. - destruct n; auto. - trans_st (f a (f x (fold_right f i (removeA x l)))). -Qed. - -Lemma fold_right_equal : - forall s s', NoDupA s -> NoDupA s' -> - eqlistA s s' -> eqB (fold_right f i s) (fold_right f i s'). -Proof. - simple induction s. - destruct s'; simpl. - intros; refl_st; auto. - unfold eqlistA; intros. - destruct (H1 a). - assert (X : InA a nil); auto; inversion X. - intros x l Hrec s' N N' E; simpl in *. - trans_st (f x (fold_right f i (removeA x s'))). - apply Comp; auto. - apply Hrec; auto. - inversion N; auto. - apply removeA_NoDupA; auto; apply eqA_trans. - apply removeA_eqlistA; auto. - inversion_clear N; auto. - sym_st. - apply removeA_fold_right; auto. - unfold eqlistA in E. - rewrite <- E; auto. -Qed. - -Lemma fold_right_add : - forall s' s x, NoDupA s -> NoDupA s' -> ~ InA x s -> - addlistA x s s' -> eqB (fold_right f i s') (f x (fold_right f i s)). -Proof. - simple induction s'. - unfold addlistA; intros. - destruct (H2 x); clear H2. - assert (X : InA x nil); auto; inversion X. - intros x' l' Hrec s x N N' IN EQ; simpl. - (* if x=x' *) - destruct (eqA_dec x x'). - apply Comp; auto. - apply fold_right_equal; auto. - inversion_clear N'; trivial. - unfold eqlistA; unfold addlistA in EQ; intros. - destruct (EQ x0); clear EQ. - split; intros. - destruct H; auto. - inversion_clear N'. - destruct H2; apply InA_eqA with x0; auto. - apply eqA_trans with x; auto. - assert (X:InA x0 (x' :: l')); auto; inversion_clear X; auto. - destruct IN; apply InA_eqA with x0; auto. - apply eqA_trans with x'; auto. - (* else x<>x' *) - trans_st (f x' (f x (fold_right f i (removeA x' s)))). - apply Comp; auto. - apply Hrec; auto. - apply removeA_NoDupA; auto; apply eqA_trans. - inversion_clear N'; auto. - rewrite removeA_InA; intuition. - apply removeA_add; auto. - trans_st (f x (f x' (fold_right f i (removeA x' s)))). - apply Comp; auto. - sym_st. - apply removeA_fold_right; auto. - destruct (EQ x'). - destruct H; auto; destruct n; auto. -Qed. +End Remove. End Fold. -End Remove. - End Type_with_equality. -Hint Constructors InA. -Hint Constructors NoDupA. -Hint Constructors sort. -Hint Constructors lelistA. +Hint Unfold compat_bool compat_nat compat_P. +Hint Constructors InA NoDupA sort lelistA eqlistA. Section Find. -Variable A B : Set. +Variable A B : Type. Variable eqA : A -> A -> Prop. Hypothesis eqA_sym : forall x y, eqA x y -> eqA y x. Hypothesis eqA_trans : forall x y z, eqA x y -> eqA y z -> eqA x z. |