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+(************************************************************************)
+(* v * The Coq Proof Assistant / The Coq Development Team *)
+(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
+(* \VV/ **************************************************************)
+(* // * This file is distributed under the terms of the *)
+(* * GNU Lesser General Public License Version 2.1 *)
+(************************************************************************)
+(*i $Id: Mapcard.v,v 1.5.2.1 2004/07/16 19:31:04 herbelin Exp $ i*)
+
+Require Import Bool.
+Require Import Sumbool.
+Require Import Arith.
+Require Import ZArith.
+Require Import Addr.
+Require Import Adist.
+Require Import Addec.
+Require Import Map.
+Require Import Mapaxioms.
+Require Import Mapiter.
+Require Import Fset.
+Require Import Mapsubset.
+Require Import List.
+Require Import Lsort.
+Require Import Peano_dec.
+
+Section MapCard.
+
+ Variables A B : Set.
+
+ Lemma MapCard_M0 : MapCard A (M0 A) = 0.
+ Proof.
+ trivial.
+ Qed.
+
+ Lemma MapCard_M1 : forall (a:ad) (y:A), MapCard A (M1 A a y) = 1.
+ Proof.
+ trivial.
+ Qed.
+
+ Lemma MapCard_is_O :
+ forall m:Map A, MapCard A m = 0 -> forall a:ad, MapGet A m a = NONE A.
+ Proof.
+ simple induction m. trivial.
+ intros a y H. discriminate H.
+ intros. simpl in H1. elim (plus_is_O _ _ H1). intros. rewrite (MapGet_M2_bit_0_if A m0 m1 a).
+ case (ad_bit_0 a). apply H0. assumption.
+ apply H. assumption.
+ Qed.
+
+ Lemma MapCard_is_not_O :
+ forall (m:Map A) (a:ad) (y:A),
+ MapGet A m a = SOME A y -> {n : nat | MapCard A m = S n}.
+ Proof.
+ simple induction m. intros. discriminate H.
+ intros a y a0 y0 H. simpl in H. elim (sumbool_of_bool (ad_eq a a0)). intro H0. split with 0.
+ reflexivity.
+ intro H0. rewrite H0 in H. discriminate H.
+ intros. elim (sumbool_of_bool (ad_bit_0 a)). intro H2.
+ rewrite (MapGet_M2_bit_0_1 A a H2 m0 m1) in H1. elim (H0 (ad_div_2 a) y H1). intros n H3.
+ simpl in |- *. rewrite H3. split with (MapCard A m0 + n).
+ rewrite <- (plus_Snm_nSm (MapCard A m0) n). reflexivity.
+ intro H2. rewrite (MapGet_M2_bit_0_0 A a H2 m0 m1) in H1. elim (H (ad_div_2 a) y H1).
+ intros n H3. simpl in |- *. rewrite H3. split with (n + MapCard A m1). reflexivity.
+ Qed.
+
+ Lemma MapCard_is_one :
+ forall m:Map A,
+ MapCard A m = 1 -> {a : ad & {y : A | MapGet A m a = SOME A y}}.
+ Proof.
+ simple induction m. intro. discriminate H.
+ intros a y H. split with a. split with y. apply M1_semantics_1.
+ intros. simpl in H1. elim (plus_is_one (MapCard A m0) (MapCard A m1) H1).
+ intro H2. elim H2. intros. elim (H0 H4). intros a H5. split with (ad_double_plus_un a).
+ rewrite (MapGet_M2_bit_0_1 A _ (ad_double_plus_un_bit_0 a) m0 m1).
+ rewrite ad_double_plus_un_div_2. exact H5.
+ intro H2. elim H2. intros. elim (H H3). intros a H5. split with (ad_double a).
+ rewrite (MapGet_M2_bit_0_0 A _ (ad_double_bit_0 a) m0 m1).
+ rewrite ad_double_div_2. exact H5.
+ Qed.
+
+ Lemma MapCard_is_one_unique :
+ forall m:Map A,
+ MapCard A m = 1 ->
+ forall (a a':ad) (y y':A),
+ MapGet A m a = SOME A y ->
+ MapGet A m a' = SOME A y' -> a = a' /\ y = y'.
+ Proof.
+ simple induction m. intro. discriminate H.
+ intros. elim (sumbool_of_bool (ad_eq a a1)). intro H2. rewrite (ad_eq_complete _ _ H2) in H0.
+ rewrite (M1_semantics_1 A a1 a0) in H0. inversion H0. elim (sumbool_of_bool (ad_eq a a')).
+ intro H5. rewrite (ad_eq_complete _ _ H5) in H1. rewrite (M1_semantics_1 A a' a0) in H1.
+ inversion H1. rewrite <- (ad_eq_complete _ _ H2). rewrite <- (ad_eq_complete _ _ H5).
+ rewrite <- H4. rewrite <- H6. split; reflexivity.
+ intro H5. rewrite (M1_semantics_2 A a a' a0 H5) in H1. discriminate H1.
+ intro H2. rewrite (M1_semantics_2 A a a1 a0 H2) in H0. discriminate H0.
+ intros. simpl in H1. elim (plus_is_one _ _ H1). intro H4. elim H4. intros.
+ rewrite (MapGet_M2_bit_0_if A m0 m1 a) in H2. elim (sumbool_of_bool (ad_bit_0 a)).
+ intro H7. rewrite H7 in H2. rewrite (MapGet_M2_bit_0_if A m0 m1 a') in H3.
+ elim (sumbool_of_bool (ad_bit_0 a')). intro H8. rewrite H8 in H3. elim (H0 H6 _ _ _ _ H2 H3).
+ intros. split. rewrite <- (ad_div_2_double_plus_un a H7).
+ rewrite <- (ad_div_2_double_plus_un a' H8). rewrite H9. reflexivity.
+ assumption.
+ intro H8. rewrite H8 in H3. rewrite (MapCard_is_O m0 H5 (ad_div_2 a')) in H3.
+ discriminate H3.
+ intro H7. rewrite H7 in H2. rewrite (MapCard_is_O m0 H5 (ad_div_2 a)) in H2.
+ discriminate H2.
+ intro H4. elim H4. intros. rewrite (MapGet_M2_bit_0_if A m0 m1 a) in H2.
+ elim (sumbool_of_bool (ad_bit_0 a)). intro H7. rewrite H7 in H2.
+ rewrite (MapCard_is_O m1 H6 (ad_div_2 a)) in H2. discriminate H2.
+ intro H7. rewrite H7 in H2. rewrite (MapGet_M2_bit_0_if A m0 m1 a') in H3.
+ elim (sumbool_of_bool (ad_bit_0 a')). intro H8. rewrite H8 in H3.
+ rewrite (MapCard_is_O m1 H6 (ad_div_2 a')) in H3. discriminate H3.
+ intro H8. rewrite H8 in H3. elim (H H5 _ _ _ _ H2 H3). intros. split.
+ rewrite <- (ad_div_2_double a H7). rewrite <- (ad_div_2_double a' H8).
+ rewrite H9. reflexivity.
+ assumption.
+ Qed.
+
+ Lemma length_as_fold :
+ forall (C:Set) (l:list C),
+ length l = fold_right (fun (_:C) (n:nat) => S n) 0 l.
+ Proof.
+ simple induction l. reflexivity.
+ intros. simpl in |- *. rewrite H. reflexivity.
+ Qed.
+
+ Lemma length_as_fold_2 :
+ forall l:alist A,
+ length l =
+ fold_right (fun (r:ad * A) (n:nat) => let (a, y) := r in 1 + n) 0 l.
+ Proof.
+ simple induction l. reflexivity.
+ intros. simpl in |- *. rewrite H. elim a; reflexivity.
+ Qed.
+
+ Lemma MapCard_as_Fold_1 :
+ forall (m:Map A) (pf:ad -> ad),
+ MapCard A m = MapFold1 A nat 0 plus (fun (_:ad) (_:A) => 1) pf m.
+ Proof.
+ simple induction m. trivial.
+ trivial.
+ intros. simpl in |- *. rewrite <- (H (fun a0:ad => pf (ad_double a0))).
+ rewrite <- (H0 (fun a0:ad => pf (ad_double_plus_un a0))). reflexivity.
+ Qed.
+
+ Lemma MapCard_as_Fold :
+ forall m:Map A,
+ MapCard A m = MapFold A nat 0 plus (fun (_:ad) (_:A) => 1) m.
+ Proof.
+ intro. exact (MapCard_as_Fold_1 m (fun a0:ad => a0)).
+ Qed.
+
+ Lemma MapCard_as_length :
+ forall m:Map A, MapCard A m = length (alist_of_Map A m).
+ Proof.
+ intro. rewrite MapCard_as_Fold. rewrite length_as_fold_2.
+ apply MapFold_as_fold with
+ (op := plus) (neutral := 0) (f := fun (_:ad) (_:A) => 1). exact plus_assoc_reverse.
+ trivial.
+ intro. rewrite <- plus_n_O. reflexivity.
+ Qed.
+
+ Lemma MapCard_Put1_equals_2 :
+ forall (p:positive) (a a':ad) (y y':A),
+ MapCard A (MapPut1 A a y a' y' p) = 2.
+ Proof.
+ simple induction p. intros. simpl in |- *. case (ad_bit_0 a); reflexivity.
+ intros. simpl in |- *. case (ad_bit_0 a). exact (H (ad_div_2 a) (ad_div_2 a') y y').
+ simpl in |- *. rewrite <- plus_n_O. exact (H (ad_div_2 a) (ad_div_2 a') y y').
+ intros. simpl in |- *. case (ad_bit_0 a); reflexivity.
+ Qed.
+
+ Lemma MapCard_Put_sum :
+ forall (m m':Map A) (a:ad) (y:A) (n n':nat),
+ m' = MapPut A m a y ->
+ n = MapCard A m -> n' = MapCard A m' -> {n' = n} + {n' = S n}.
+ Proof.
+ simple induction m. simpl in |- *. intros. rewrite H in H1. simpl in H1. right.
+ rewrite H0. rewrite H1. reflexivity.
+ intros a y m' a0 y0 n n' H H0 H1. simpl in H. elim (ad_sum (ad_xor a a0)). intro H2.
+ elim H2. intros p H3. rewrite H3 in H. rewrite H in H1.
+ rewrite (MapCard_Put1_equals_2 p a a0 y y0) in H1. simpl in H0. right.
+ rewrite H0. rewrite H1. reflexivity.
+ intro H2. rewrite H2 in H. rewrite H in H1. simpl in H1. simpl in H0. left.
+ rewrite H0. rewrite H1. reflexivity.
+ intros. simpl in H2. rewrite (MapPut_semantics_3_1 A m0 m1 a y) in H1.
+ elim (sumbool_of_bool (ad_bit_0 a)). intro H4. rewrite H4 in H1.
+ elim
+ (H0 (MapPut A m1 (ad_div_2 a) y) (ad_div_2 a) y (
+ MapCard A m1) (MapCard A (MapPut A m1 (ad_div_2 a) y)) (
+ refl_equal _) (refl_equal _) (refl_equal _)).
+ intro H5. rewrite H1 in H3. simpl in H3. rewrite H5 in H3. rewrite <- H2 in H3. left.
+ assumption.
+ intro H5. rewrite H1 in H3. simpl in H3. rewrite H5 in H3.
+ rewrite <- (plus_Snm_nSm (MapCard A m0) (MapCard A m1)) in H3.
+ simpl in H3. rewrite <- H2 in H3. right. assumption.
+ intro H4. rewrite H4 in H1.
+ elim
+ (H (MapPut A m0 (ad_div_2 a) y) (ad_div_2 a) y (
+ MapCard A m0) (MapCard A (MapPut A m0 (ad_div_2 a) y)) (
+ refl_equal _) (refl_equal _) (refl_equal _)).
+ intro H5. rewrite H1 in H3. simpl in H3. rewrite H5 in H3. rewrite <- H2 in H3.
+ left. assumption.
+ intro H5. rewrite H1 in H3. simpl in H3. rewrite H5 in H3. simpl in H3. rewrite <- H2 in H3.
+ right. assumption.
+ Qed.
+
+ Lemma MapCard_Put_lb :
+ forall (m:Map A) (a:ad) (y:A), MapCard A (MapPut A m a y) >= MapCard A m.
+ Proof.
+ unfold ge in |- *. intros.
+ elim
+ (MapCard_Put_sum m (MapPut A m a y) a y (MapCard A m)
+ (MapCard A (MapPut A m a y)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H. rewrite H. apply le_n.
+ intro H. rewrite H. apply le_n_Sn.
+ Qed.
+
+ Lemma MapCard_Put_ub :
+ forall (m:Map A) (a:ad) (y:A),
+ MapCard A (MapPut A m a y) <= S (MapCard A m).
+ Proof.
+ intros.
+ elim
+ (MapCard_Put_sum m (MapPut A m a y) a y (MapCard A m)
+ (MapCard A (MapPut A m a y)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H. rewrite H. apply le_n_Sn.
+ intro H. rewrite H. apply le_n.
+ Qed.
+
+ Lemma MapCard_Put_1 :
+ forall (m:Map A) (a:ad) (y:A),
+ MapCard A (MapPut A m a y) = MapCard A m ->
+ {y : A | MapGet A m a = SOME A y}.
+ Proof.
+ simple induction m. intros. discriminate H.
+ intros a y a0 y0 H. simpl in H. elim (ad_sum (ad_xor a a0)). intro H0. elim H0.
+ intros p H1. rewrite H1 in H. rewrite (MapCard_Put1_equals_2 p a a0 y y0) in H.
+ discriminate H.
+ intro H0. rewrite H0 in H. rewrite (ad_xor_eq _ _ H0). split with y. apply M1_semantics_1.
+ intros. rewrite (MapPut_semantics_3_1 A m0 m1 a y) in H1. elim (sumbool_of_bool (ad_bit_0 a)).
+ intro H2. rewrite H2 in H1. simpl in H1. elim (H0 (ad_div_2 a) y ((fun n m p:nat => plus_reg_l m p n) _ _ _ H1)).
+ intros y0 H3. split with y0. rewrite <- H3. exact (MapGet_M2_bit_0_1 A a H2 m0 m1).
+ intro H2. rewrite H2 in H1. simpl in H1.
+ rewrite
+ (plus_comm (MapCard A (MapPut A m0 (ad_div_2 a) y)) (MapCard A m1))
+ in H1.
+ rewrite (plus_comm (MapCard A m0) (MapCard A m1)) in H1.
+ elim (H (ad_div_2 a) y ((fun n m p:nat => plus_reg_l m p n) _ _ _ H1)). intros y0 H3. split with y0.
+ rewrite <- H3. exact (MapGet_M2_bit_0_0 A a H2 m0 m1).
+ Qed.
+
+ Lemma MapCard_Put_2 :
+ forall (m:Map A) (a:ad) (y:A),
+ MapCard A (MapPut A m a y) = S (MapCard A m) -> MapGet A m a = NONE A.
+ Proof.
+ simple induction m. trivial.
+ intros. simpl in H. elim (sumbool_of_bool (ad_eq a a1)). intro H0.
+ rewrite (ad_eq_complete _ _ H0) in H. rewrite (ad_xor_nilpotent a1) in H. discriminate H.
+ intro H0. exact (M1_semantics_2 A a a1 a0 H0).
+ intros. elim (sumbool_of_bool (ad_bit_0 a)). intro H2.
+ rewrite (MapGet_M2_bit_0_1 A a H2 m0 m1). apply (H0 (ad_div_2 a) y).
+ apply (fun n m p:nat => plus_reg_l m p n) with (n := MapCard A m0).
+ rewrite <- (plus_Snm_nSm (MapCard A m0) (MapCard A m1)). simpl in H1. simpl in |- *. rewrite <- H1.
+ clear H1.
+ induction a. discriminate H2.
+ induction p. reflexivity.
+ discriminate H2.
+ reflexivity.
+ intro H2. rewrite (MapGet_M2_bit_0_0 A a H2 m0 m1). apply (H (ad_div_2 a) y).
+ cut
+ (MapCard A (MapPut A m0 (ad_div_2 a) y) + MapCard A m1 =
+ S (MapCard A m0) + MapCard A m1).
+ intro. rewrite (plus_comm (MapCard A (MapPut A m0 (ad_div_2 a) y)) (MapCard A m1))
+ in H3.
+ rewrite (plus_comm (S (MapCard A m0)) (MapCard A m1)) in H3. exact ((fun n m p:nat => plus_reg_l m p n) _ _ _ H3).
+ simpl in |- *. simpl in H1. rewrite <- H1. induction a. trivial.
+ induction p. discriminate H2.
+ reflexivity.
+ discriminate H2.
+ Qed.
+
+ Lemma MapCard_Put_1_conv :
+ forall (m:Map A) (a:ad) (y y':A),
+ MapGet A m a = SOME A y -> MapCard A (MapPut A m a y') = MapCard A m.
+ Proof.
+ intros.
+ elim
+ (MapCard_Put_sum m (MapPut A m a y') a y' (MapCard A m)
+ (MapCard A (MapPut A m a y')) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ trivial.
+ intro H0. rewrite (MapCard_Put_2 m a y' H0) in H. discriminate H.
+ Qed.
+
+ Lemma MapCard_Put_2_conv :
+ forall (m:Map A) (a:ad) (y:A),
+ MapGet A m a = NONE A -> MapCard A (MapPut A m a y) = S (MapCard A m).
+ Proof.
+ intros.
+ elim
+ (MapCard_Put_sum m (MapPut A m a y) a y (MapCard A m)
+ (MapCard A (MapPut A m a y)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H0. elim (MapCard_Put_1 m a y H0). intros y' H1. rewrite H1 in H. discriminate H.
+ trivial.
+ Qed.
+
+ Lemma MapCard_ext :
+ forall m m':Map A,
+ eqm A (MapGet A m) (MapGet A m') -> MapCard A m = MapCard A m'.
+ Proof.
+ unfold eqm in |- *. intros. rewrite (MapCard_as_length m). rewrite (MapCard_as_length m').
+ rewrite (alist_canonical A (alist_of_Map A m) (alist_of_Map A m')). reflexivity.
+ unfold eqm in |- *. intro. rewrite (Map_of_alist_semantics A (alist_of_Map A m) a).
+ rewrite (Map_of_alist_semantics A (alist_of_Map A m') a). rewrite (Map_of_alist_of_Map A m' a).
+ rewrite (Map_of_alist_of_Map A m a). exact (H a).
+ apply alist_of_Map_sorts2.
+ apply alist_of_Map_sorts2.
+ Qed.
+
+ Lemma MapCard_Dom : forall m:Map A, MapCard A m = MapCard unit (MapDom A m).
+ Proof.
+ simple induction m; trivial. intros. simpl in |- *. rewrite H. rewrite H0. reflexivity.
+ Qed.
+
+ Lemma MapCard_Dom_Put_behind :
+ forall (m:Map A) (a:ad) (y:A),
+ MapDom A (MapPut_behind A m a y) = MapDom A (MapPut A m a y).
+ Proof.
+ simple induction m. trivial.
+ intros a y a0 y0. simpl in |- *. elim (ad_sum (ad_xor a a0)). intro H. elim H.
+ intros p H0. rewrite H0. reflexivity.
+ intro H. rewrite H. rewrite (ad_xor_eq _ _ H). reflexivity.
+ intros. simpl in |- *. elim (ad_sum a). intro H1. elim H1. intros p H2. rewrite H2. case p.
+ intro p0. simpl in |- *. rewrite H0. reflexivity.
+ intro p0. simpl in |- *. rewrite H. reflexivity.
+ simpl in |- *. rewrite H0. reflexivity.
+ intro H1. rewrite H1. simpl in |- *. rewrite H. reflexivity.
+ Qed.
+
+ Lemma MapCard_Put_behind_Put :
+ forall (m:Map A) (a:ad) (y:A),
+ MapCard A (MapPut_behind A m a y) = MapCard A (MapPut A m a y).
+ Proof.
+ intros. rewrite MapCard_Dom. rewrite MapCard_Dom. rewrite MapCard_Dom_Put_behind.
+ reflexivity.
+ Qed.
+
+ Lemma MapCard_Put_behind_sum :
+ forall (m m':Map A) (a:ad) (y:A) (n n':nat),
+ m' = MapPut_behind A m a y ->
+ n = MapCard A m -> n' = MapCard A m' -> {n' = n} + {n' = S n}.
+ Proof.
+ intros. apply (MapCard_Put_sum m (MapPut A m a y) a y n n'); trivial.
+ rewrite <- MapCard_Put_behind_Put. rewrite <- H. assumption.
+ Qed.
+
+ Lemma MapCard_makeM2 :
+ forall m m':Map A, MapCard A (makeM2 A m m') = MapCard A m + MapCard A m'.
+ Proof.
+ intros. rewrite (MapCard_ext _ _ (makeM2_M2 A m m')). reflexivity.
+ Qed.
+
+ Lemma MapCard_Remove_sum :
+ forall (m m':Map A) (a:ad) (n n':nat),
+ m' = MapRemove A m a ->
+ n = MapCard A m -> n' = MapCard A m' -> {n = n'} + {n = S n'}.
+ Proof.
+ simple induction m. simpl in |- *. intros. rewrite H in H1. simpl in H1. left. rewrite H1. assumption.
+ simpl in |- *. intros. elim (sumbool_of_bool (ad_eq a a1)). intro H2. rewrite H2 in H.
+ rewrite H in H1. simpl in H1. right. rewrite H1. assumption.
+ intro H2. rewrite H2 in H. rewrite H in H1. simpl in H1. left. rewrite H1. assumption.
+ intros. simpl in H1. simpl in H2. elim (sumbool_of_bool (ad_bit_0 a)). intro H4.
+ rewrite H4 in H1. rewrite H1 in H3.
+ rewrite (MapCard_makeM2 m0 (MapRemove A m1 (ad_div_2 a))) in H3.
+ elim
+ (H0 (MapRemove A m1 (ad_div_2 a)) (ad_div_2 a) (
+ MapCard A m1) (MapCard A (MapRemove A m1 (ad_div_2 a)))
+ (refl_equal _) (refl_equal _) (refl_equal _)).
+ intro H5. rewrite H5 in H2. left. rewrite H3. exact H2.
+ intro H5. rewrite H5 in H2.
+ rewrite <-
+ (plus_Snm_nSm (MapCard A m0) (MapCard A (MapRemove A m1 (ad_div_2 a))))
+ in H2.
+ right. rewrite H3. exact H2.
+ intro H4. rewrite H4 in H1. rewrite H1 in H3.
+ rewrite (MapCard_makeM2 (MapRemove A m0 (ad_div_2 a)) m1) in H3.
+ elim
+ (H (MapRemove A m0 (ad_div_2 a)) (ad_div_2 a) (
+ MapCard A m0) (MapCard A (MapRemove A m0 (ad_div_2 a)))
+ (refl_equal _) (refl_equal _) (refl_equal _)).
+ intro H5. rewrite H5 in H2. left. rewrite H3. exact H2.
+ intro H5. rewrite H5 in H2. right. rewrite H3. exact H2.
+ Qed.
+
+ Lemma MapCard_Remove_ub :
+ forall (m:Map A) (a:ad), MapCard A (MapRemove A m a) <= MapCard A m.
+ Proof.
+ intros.
+ elim
+ (MapCard_Remove_sum m (MapRemove A m a) a (MapCard A m)
+ (MapCard A (MapRemove A m a)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H. rewrite H. apply le_n.
+ intro H. rewrite H. apply le_n_Sn.
+ Qed.
+
+ Lemma MapCard_Remove_lb :
+ forall (m:Map A) (a:ad), S (MapCard A (MapRemove A m a)) >= MapCard A m.
+ Proof.
+ unfold ge in |- *. intros.
+ elim
+ (MapCard_Remove_sum m (MapRemove A m a) a (MapCard A m)
+ (MapCard A (MapRemove A m a)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H. rewrite H. apply le_n_Sn.
+ intro H. rewrite H. apply le_n.
+ Qed.
+
+ Lemma MapCard_Remove_1 :
+ forall (m:Map A) (a:ad),
+ MapCard A (MapRemove A m a) = MapCard A m -> MapGet A m a = NONE A.
+ Proof.
+ simple induction m. trivial.
+ simpl in |- *. intros a y a0 H. elim (sumbool_of_bool (ad_eq a a0)). intro H0.
+ rewrite H0 in H. discriminate H.
+ intro H0. rewrite H0. reflexivity.
+ intros. simpl in H1. elim (sumbool_of_bool (ad_bit_0 a)). intro H2. rewrite H2 in H1.
+ rewrite (MapCard_makeM2 m0 (MapRemove A m1 (ad_div_2 a))) in H1.
+ rewrite (MapGet_M2_bit_0_1 A a H2 m0 m1). apply H0. exact ((fun n m p:nat => plus_reg_l m p n) _ _ _ H1).
+ intro H2. rewrite H2 in H1.
+ rewrite (MapCard_makeM2 (MapRemove A m0 (ad_div_2 a)) m1) in H1.
+ rewrite (MapGet_M2_bit_0_0 A a H2 m0 m1). apply H.
+ rewrite
+ (plus_comm (MapCard A (MapRemove A m0 (ad_div_2 a))) (MapCard A m1))
+ in H1.
+ rewrite (plus_comm (MapCard A m0) (MapCard A m1)) in H1. exact ((fun n m p:nat => plus_reg_l m p n) _ _ _ H1).
+ Qed.
+
+ Lemma MapCard_Remove_2 :
+ forall (m:Map A) (a:ad),
+ S (MapCard A (MapRemove A m a)) = MapCard A m ->
+ {y : A | MapGet A m a = SOME A y}.
+ Proof.
+ simple induction m. intros. discriminate H.
+ intros a y a0 H. simpl in H. elim (sumbool_of_bool (ad_eq a a0)). intro H0.
+ rewrite (ad_eq_complete _ _ H0). split with y. exact (M1_semantics_1 A a0 y).
+ intro H0. rewrite H0 in H. discriminate H.
+ intros. simpl in H1. elim (sumbool_of_bool (ad_bit_0 a)). intro H2. rewrite H2 in H1.
+ rewrite (MapCard_makeM2 m0 (MapRemove A m1 (ad_div_2 a))) in H1.
+ rewrite (MapGet_M2_bit_0_1 A a H2 m0 m1). apply H0.
+ change
+ (S (MapCard A m0) + MapCard A (MapRemove A m1 (ad_div_2 a)) =
+ MapCard A m0 + MapCard A m1) in H1.
+ rewrite
+ (plus_Snm_nSm (MapCard A m0) (MapCard A (MapRemove A m1 (ad_div_2 a))))
+ in H1.
+ exact ((fun n m p:nat => plus_reg_l m p n) _ _ _ H1).
+ intro H2. rewrite H2 in H1. rewrite (MapGet_M2_bit_0_0 A a H2 m0 m1). apply H.
+ rewrite (MapCard_makeM2 (MapRemove A m0 (ad_div_2 a)) m1) in H1.
+ change
+ (S (MapCard A (MapRemove A m0 (ad_div_2 a))) + MapCard A m1 =
+ MapCard A m0 + MapCard A m1) in H1.
+ rewrite
+ (plus_comm (S (MapCard A (MapRemove A m0 (ad_div_2 a)))) (MapCard A m1))
+ in H1.
+ rewrite (plus_comm (MapCard A m0) (MapCard A m1)) in H1. exact ((fun n m p:nat => plus_reg_l m p n) _ _ _ H1).
+ Qed.
+
+ Lemma MapCard_Remove_1_conv :
+ forall (m:Map A) (a:ad),
+ MapGet A m a = NONE A -> MapCard A (MapRemove A m a) = MapCard A m.
+ Proof.
+ intros.
+ elim
+ (MapCard_Remove_sum m (MapRemove A m a) a (MapCard A m)
+ (MapCard A (MapRemove A m a)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H0. rewrite H0. reflexivity.
+ intro H0. elim (MapCard_Remove_2 m a (sym_eq H0)). intros y H1. rewrite H1 in H.
+ discriminate H.
+ Qed.
+
+ Lemma MapCard_Remove_2_conv :
+ forall (m:Map A) (a:ad) (y:A),
+ MapGet A m a = SOME A y -> S (MapCard A (MapRemove A m a)) = MapCard A m.
+ Proof.
+ intros.
+ elim
+ (MapCard_Remove_sum m (MapRemove A m a) a (MapCard A m)
+ (MapCard A (MapRemove A m a)) (refl_equal _) (
+ refl_equal _) (refl_equal _)).
+ intro H0. rewrite (MapCard_Remove_1 m a (sym_eq H0)) in H. discriminate H.
+ intro H0. rewrite H0. reflexivity.
+ Qed.
+
+ Lemma MapMerge_Restr_Card :
+ forall m m':Map A,
+ MapCard A m + MapCard A m' =
+ MapCard A (MapMerge A m m') + MapCard A (MapDomRestrTo A A m m').
+ Proof.
+ simple induction m. simpl in |- *. intro. apply plus_n_O.
+ simpl in |- *. intros a y m'. elim (option_sum A (MapGet A m' a)). intro H. elim H. intros y0 H0.
+ rewrite H0. rewrite MapCard_Put_behind_Put. rewrite (MapCard_Put_1_conv m' a y0 y H0).
+ simpl in |- *. rewrite <- plus_Snm_nSm. apply plus_n_O.
+ intro H. rewrite H. rewrite MapCard_Put_behind_Put. rewrite (MapCard_Put_2_conv m' a y H).
+ apply plus_n_O.
+ intros.
+ change
+ (MapCard A m0 + MapCard A m1 + MapCard A m' =
+ MapCard A (MapMerge A (M2 A m0 m1) m') +
+ MapCard A (MapDomRestrTo A A (M2 A m0 m1) m'))
+ in |- *.
+ elim m'. reflexivity.
+ intros a y. unfold MapMerge in |- *. unfold MapDomRestrTo in |- *.
+ elim (option_sum A (MapGet A (M2 A m0 m1) a)). intro H1. elim H1. intros y0 H2. rewrite H2.
+ rewrite (MapCard_Put_1_conv (M2 A m0 m1) a y0 y H2). reflexivity.
+ intro H1. rewrite H1. rewrite (MapCard_Put_2_conv (M2 A m0 m1) a y H1). simpl in |- *.
+ rewrite <- (plus_Snm_nSm (MapCard A m0 + MapCard A m1) 0). reflexivity.
+ intros. simpl in |- *.
+ rewrite
+ (plus_permute_2_in_4 (MapCard A m0) (MapCard A m1) (
+ MapCard A m2) (MapCard A m3)).
+ rewrite (H m2). rewrite (H0 m3).
+ rewrite
+ (MapCard_makeM2 (MapDomRestrTo A A m0 m2) (MapDomRestrTo A A m1 m3))
+ .
+ apply plus_permute_2_in_4.
+ Qed.
+
+ Lemma MapMerge_disjoint_Card :
+ forall m m':Map A,
+ MapDisjoint A A m m' ->
+ MapCard A (MapMerge A m m') = MapCard A m + MapCard A m'.
+ Proof.
+ intros. rewrite (MapMerge_Restr_Card m m').
+ rewrite (MapCard_ext _ _ (MapDisjoint_imp_2 _ _ _ _ H)). apply plus_n_O.
+ Qed.
+
+ Lemma MapSplit_Card :
+ forall (m:Map A) (m':Map B),
+ MapCard A m =
+ MapCard A (MapDomRestrTo A B m m') + MapCard A (MapDomRestrBy A B m m').
+ Proof.
+ intros. rewrite (MapCard_ext _ _ (MapDom_Split_1 A B m m')). apply MapMerge_disjoint_Card.
+ apply MapDisjoint_2_imp. unfold MapDisjoint_2 in |- *. apply MapDom_Split_3.
+ Qed.
+
+ Lemma MapMerge_Card_ub :
+ forall m m':Map A,
+ MapCard A (MapMerge A m m') <= MapCard A m + MapCard A m'.
+ Proof.
+ intros. rewrite MapMerge_Restr_Card. apply le_plus_l.
+ Qed.
+
+ Lemma MapDomRestrTo_Card_ub_l :
+ forall (m:Map A) (m':Map B),
+ MapCard A (MapDomRestrTo A B m m') <= MapCard A m.
+ Proof.
+ intros. rewrite (MapSplit_Card m m'). apply le_plus_l.
+ Qed.
+
+ Lemma MapDomRestrBy_Card_ub_l :
+ forall (m:Map A) (m':Map B),
+ MapCard A (MapDomRestrBy A B m m') <= MapCard A m.
+ Proof.
+ intros. rewrite (MapSplit_Card m m'). apply le_plus_r.
+ Qed.
+
+ Lemma MapMerge_Card_disjoint :
+ forall m m':Map A,
+ MapCard A (MapMerge A m m') = MapCard A m + MapCard A m' ->
+ MapDisjoint A A m m'.
+ Proof.
+ simple induction m. intros. apply Map_M0_disjoint.
+ simpl in |- *. intros. rewrite (MapCard_Put_behind_Put m' a a0) in H. unfold MapDisjoint, in_dom in |- *.
+ simpl in |- *. intros. elim (sumbool_of_bool (ad_eq a a1)). intro H2.
+ rewrite (ad_eq_complete _ _ H2) in H. rewrite (MapCard_Put_2 m' a1 a0 H) in H1.
+ discriminate H1.
+ intro H2. rewrite H2 in H0. discriminate H0.
+ simple induction m'. intros. apply Map_disjoint_M0.
+ intros a y H1. rewrite <- (MapCard_ext _ _ (MapPut_as_Merge A (M2 A m0 m1) a y)) in H1.
+ unfold MapCard at 3 in H1. rewrite <- (plus_Snm_nSm (MapCard A (M2 A m0 m1)) 0) in H1.
+ rewrite <- (plus_n_O (S (MapCard A (M2 A m0 m1)))) in H1. unfold MapDisjoint, in_dom in |- *.
+ unfold MapGet at 2 in |- *. intros. elim (sumbool_of_bool (ad_eq a a0)). intro H4.
+ rewrite <- (ad_eq_complete _ _ H4) in H2. rewrite (MapCard_Put_2 _ _ _ H1) in H2.
+ discriminate H2.
+ intro H4. rewrite H4 in H3. discriminate H3.
+ intros. unfold MapDisjoint in |- *. intros. elim (sumbool_of_bool (ad_bit_0 a)). intro H6.
+ unfold MapDisjoint in H0. apply H0 with (m' := m3) (a := ad_div_2 a). apply le_antisym.
+ apply MapMerge_Card_ub.
+ apply (fun p n m:nat => plus_le_reg_l n m p) with
+ (p := MapCard A m0 + MapCard A m2).
+ rewrite
+ (plus_permute_2_in_4 (MapCard A m0) (MapCard A m2) (
+ MapCard A m1) (MapCard A m3)).
+ change
+ (MapCard A (M2 A (MapMerge A m0 m2) (MapMerge A m1 m3)) =
+ MapCard A m0 + MapCard A m1 + (MapCard A m2 + MapCard A m3))
+ in H3.
+ rewrite <- H3. simpl in |- *. apply plus_le_compat_r. apply MapMerge_Card_ub.
+ elim (in_dom_some _ _ _ H4). intros y H7. rewrite (MapGet_M2_bit_0_1 _ a H6 m0 m1) in H7.
+ unfold in_dom in |- *. rewrite H7. reflexivity.
+ elim (in_dom_some _ _ _ H5). intros y H7. rewrite (MapGet_M2_bit_0_1 _ a H6 m2 m3) in H7.
+ unfold in_dom in |- *. rewrite H7. reflexivity.
+ intro H6. unfold MapDisjoint in H. apply H with (m' := m2) (a := ad_div_2 a). apply le_antisym.
+ apply MapMerge_Card_ub.
+ apply (fun p n m:nat => plus_le_reg_l n m p) with
+ (p := MapCard A m1 + MapCard A m3).
+ rewrite
+ (plus_comm (MapCard A m1 + MapCard A m3) (MapCard A m0 + MapCard A m2))
+ .
+ rewrite
+ (plus_permute_2_in_4 (MapCard A m0) (MapCard A m2) (
+ MapCard A m1) (MapCard A m3)).
+ rewrite
+ (plus_comm (MapCard A m1 + MapCard A m3) (MapCard A (MapMerge A m0 m2)))
+ .
+ change
+ (MapCard A (MapMerge A m0 m2) + MapCard A (MapMerge A m1 m3) =
+ MapCard A m0 + MapCard A m1 + (MapCard A m2 + MapCard A m3))
+ in H3.
+ rewrite <- H3. apply plus_le_compat_l. apply MapMerge_Card_ub.
+ elim (in_dom_some _ _ _ H4). intros y H7. rewrite (MapGet_M2_bit_0_0 _ a H6 m0 m1) in H7.
+ unfold in_dom in |- *. rewrite H7. reflexivity.
+ elim (in_dom_some _ _ _ H5). intros y H7. rewrite (MapGet_M2_bit_0_0 _ a H6 m2 m3) in H7.
+ unfold in_dom in |- *. rewrite H7. reflexivity.
+ Qed.
+
+ Lemma MapCard_is_Sn :
+ forall (m:Map A) (n:nat),
+ MapCard _ m = S n -> {a : ad | in_dom _ a m = true}.
+ Proof.
+ simple induction m. intros. discriminate H.
+ intros a y n H. split with a. unfold in_dom in |- *. rewrite (M1_semantics_1 _ a y). reflexivity.
+ intros. simpl in H1. elim (O_or_S (MapCard _ m0)). intro H2. elim H2. intros m2 H3.
+ elim (H _ (sym_eq H3)). intros a H4. split with (ad_double a). unfold in_dom in |- *.
+ rewrite (MapGet_M2_bit_0_0 A (ad_double a) (ad_double_bit_0 a) m0 m1).
+ rewrite (ad_double_div_2 a). elim (in_dom_some _ _ _ H4). intros y H5. rewrite H5. reflexivity.
+ intro H2. rewrite <- H2 in H1. simpl in H1. elim (H0 _ H1). intros a H3.
+ split with (ad_double_plus_un a). unfold in_dom in |- *.
+ rewrite
+ (MapGet_M2_bit_0_1 A (ad_double_plus_un a) (ad_double_plus_un_bit_0 a)
+ m0 m1).
+ rewrite (ad_double_plus_un_div_2 a). elim (in_dom_some _ _ _ H3). intros y H4. rewrite H4.
+ reflexivity.
+ Qed.
+
+End MapCard.
+
+Section MapCard2.
+
+ Variables A B : Set.
+
+ Lemma MapSubset_card_eq_1 :
+ forall (n:nat) (m:Map A) (m':Map B),
+ MapSubset _ _ m m' ->
+ MapCard _ m = n -> MapCard _ m' = n -> MapSubset _ _ m' m.
+ Proof.
+ simple induction n. intros. unfold MapSubset, in_dom in |- *. intro. rewrite (MapCard_is_O _ m H0 a).
+ rewrite (MapCard_is_O _ m' H1 a). intro H2. discriminate H2.
+ intros. elim (MapCard_is_Sn A m n0 H1). intros a H3. elim (in_dom_some _ _ _ H3).
+ intros y H4. elim (in_dom_some _ _ _ (H0 _ H3)). intros y' H6.
+ cut (eqmap _ (MapPut _ (MapRemove _ m a) a y) m). intro.
+ cut (eqmap _ (MapPut _ (MapRemove _ m' a) a y') m'). intro.
+ apply MapSubset_ext with
+ (m0 := MapPut _ (MapRemove _ m' a) a y')
+ (m2 := MapPut _ (MapRemove _ m a) a y).
+ assumption.
+ assumption.
+ apply MapSubset_Put_mono. apply H. apply MapSubset_Remove_mono. assumption.
+ rewrite <- (MapCard_Remove_2_conv _ m a y H4) in H1. inversion_clear H1. reflexivity.
+ rewrite <- (MapCard_Remove_2_conv _ m' a y' H6) in H2. inversion_clear H2. reflexivity.
+ unfold eqmap, eqm in |- *. intro. rewrite (MapPut_semantics _ (MapRemove B m' a) a y' a0).
+ elim (sumbool_of_bool (ad_eq a a0)). intro H7. rewrite H7. rewrite <- (ad_eq_complete _ _ H7).
+ apply sym_eq. assumption.
+ intro H7. rewrite H7. rewrite (MapRemove_semantics _ m' a a0). rewrite H7. reflexivity.
+ unfold eqmap, eqm in |- *. intro. rewrite (MapPut_semantics _ (MapRemove A m a) a y a0).
+ elim (sumbool_of_bool (ad_eq a a0)). intro H7. rewrite H7. rewrite <- (ad_eq_complete _ _ H7).
+ apply sym_eq. assumption.
+ intro H7. rewrite H7. rewrite (MapRemove_semantics A m a a0). rewrite H7. reflexivity.
+ Qed.
+
+ Lemma MapDomRestrTo_Card_ub_r :
+ forall (m:Map A) (m':Map B),
+ MapCard A (MapDomRestrTo A B m m') <= MapCard B m'.
+ Proof.
+ simple induction m. intro. simpl in |- *. apply le_O_n.
+ intros a y m'. simpl in |- *. elim (option_sum B (MapGet B m' a)). intro H. elim H. intros y0 H0.
+ rewrite H0. elim (MapCard_is_not_O B m' a y0 H0). intros n H1. rewrite H1. simpl in |- *.
+ apply le_n_S. apply le_O_n.
+ intro H. rewrite H. simpl in |- *. apply le_O_n.
+ simple induction m'. simpl in |- *. apply le_O_n.
+
+ intros a y. unfold MapDomRestrTo in |- *. case (MapGet A (M2 A m0 m1) a). simpl in |- *. apply le_O_n.
+ intro. simpl in |- *. apply le_n.
+ intros. simpl in |- *. rewrite
+ (MapCard_makeM2 A (MapDomRestrTo A B m0 m2) (MapDomRestrTo A B m1 m3))
+ .
+ apply plus_le_compat. apply H.
+ apply H0.
+ Qed.
+
+End MapCard2.
+
+Section MapCard3.
+
+ Variables A B : Set.
+
+ Lemma MapMerge_Card_lb_l :
+ forall m m':Map A, MapCard A (MapMerge A m m') >= MapCard A m.
+ Proof.
+ unfold ge in |- *. intros. apply ((fun p n m:nat => plus_le_reg_l n m p) (MapCard A m')).
+ rewrite (plus_comm (MapCard A m') (MapCard A m)).
+ rewrite (plus_comm (MapCard A m') (MapCard A (MapMerge A m m'))).
+ rewrite (MapMerge_Restr_Card A m m'). apply plus_le_compat_l. apply MapDomRestrTo_Card_ub_r.
+ Qed.
+
+ Lemma MapMerge_Card_lb_r :
+ forall m m':Map A, MapCard A (MapMerge A m m') >= MapCard A m'.
+ Proof.
+ unfold ge in |- *. intros. apply ((fun p n m:nat => plus_le_reg_l n m p) (MapCard A m)). rewrite (MapMerge_Restr_Card A m m').
+ rewrite
+ (plus_comm (MapCard A (MapMerge A m m'))
+ (MapCard A (MapDomRestrTo A A m m'))).
+ apply plus_le_compat_r. apply MapDomRestrTo_Card_ub_l.
+ Qed.
+
+ Lemma MapDomRestrBy_Card_lb :
+ forall (m:Map A) (m':Map B),
+ MapCard B m' + MapCard A (MapDomRestrBy A B m m') >= MapCard A m.
+ Proof.
+ unfold ge in |- *. intros. rewrite (MapSplit_Card A B m m'). apply plus_le_compat_r.
+ apply MapDomRestrTo_Card_ub_r.
+ Qed.
+
+ Lemma MapSubset_Card_le :
+ forall (m:Map A) (m':Map B),
+ MapSubset A B m m' -> MapCard A m <= MapCard B m'.
+ Proof.
+ intros. apply le_trans with (m := MapCard B m' + MapCard A (MapDomRestrBy A B m m')).
+ exact (MapDomRestrBy_Card_lb m m').
+ rewrite (MapCard_ext _ _ _ (MapSubset_imp_2 _ _ _ _ H)). simpl in |- *. rewrite <- plus_n_O.
+ apply le_n.
+ Qed.
+
+ Lemma MapSubset_card_eq :
+ forall (m:Map A) (m':Map B),
+ MapSubset _ _ m m' ->
+ MapCard _ m' <= MapCard _ m -> eqmap _ (MapDom _ m) (MapDom _ m').
+ Proof.
+ intros. apply MapSubset_antisym. assumption.
+ cut (MapCard B m' = MapCard A m). intro. apply (MapSubset_card_eq_1 A B (MapCard A m)).
+ assumption.
+ reflexivity.
+ assumption.
+ apply le_antisym. assumption.
+ apply MapSubset_Card_le. assumption.
+ Qed.
+
+End MapCard3. \ No newline at end of file
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