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diff --git a/theories/IntMap/Map.v b/theories/IntMap/Map.v new file mode 100644 index 00000000..da1fa99e --- /dev/null +++ b/theories/IntMap/Map.v @@ -0,0 +1,865 @@ +(************************************************************************) +(* 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: Map.v,v 1.7.2.1 2004/07/16 19:31:04 herbelin Exp $ i*) + +(** Definition of finite sets as trees indexed by adresses *) + +Require Import Bool. +Require Import Sumbool. +Require Import ZArith. +Require Import Addr. +Require Import Adist. +Require Import Addec. + + +Section MapDefs. + +(** We define maps from ad to A. *) + Variable A : Set. + + Inductive Map : Set := + | M0 : Map + | M1 : ad -> A -> Map + | M2 : Map -> Map -> Map. + + Inductive option : Set := + | NONE : option + | SOME : A -> option. + + Lemma option_sum : forall o:option, {y : A | o = SOME y} + {o = NONE}. + Proof. + simple induction o. right. reflexivity. + left. split with a. reflexivity. + Qed. + + (** The semantics of maps is given by the function [MapGet]. + The semantics of a map [m] is a partial, finite function from + [ad] to [A]: *) + + Fixpoint MapGet (m:Map) : ad -> option := + match m with + | M0 => fun a:ad => NONE + | M1 x y => fun a:ad => if ad_eq x a then SOME y else NONE + | M2 m1 m2 => + fun a:ad => + match a with + | ad_z => MapGet m1 ad_z + | ad_x xH => MapGet m2 ad_z + | ad_x (xO p) => MapGet m1 (ad_x p) + | ad_x (xI p) => MapGet m2 (ad_x p) + end + end. + + Definition newMap := M0. + + Definition MapSingleton := M1. + + Definition eqm (g g':ad -> option) := forall a:ad, g a = g' a. + + Lemma newMap_semantics : eqm (MapGet newMap) (fun a:ad => NONE). + Proof. + simpl in |- *. unfold eqm in |- *. trivial. + Qed. + + Lemma MapSingleton_semantics : + forall (a:ad) (y:A), + eqm (MapGet (MapSingleton a y)) + (fun a':ad => if ad_eq a a' then SOME y else NONE). + Proof. + simpl in |- *. unfold eqm in |- *. trivial. + Qed. + + Lemma M1_semantics_1 : forall (a:ad) (y:A), MapGet (M1 a y) a = SOME y. + Proof. + unfold MapGet in |- *. intros. rewrite (ad_eq_correct a). reflexivity. + Qed. + + Lemma M1_semantics_2 : + forall (a a':ad) (y:A), ad_eq a a' = false -> MapGet (M1 a y) a' = NONE. + Proof. + intros. simpl in |- *. rewrite H. reflexivity. + Qed. + + Lemma Map2_semantics_1 : + forall m m':Map, + eqm (MapGet m) (fun a:ad => MapGet (M2 m m') (ad_double a)). + Proof. + unfold eqm in |- *. simple induction a; trivial. + Qed. + + Lemma Map2_semantics_1_eq : + forall (m m':Map) (f:ad -> option), + eqm (MapGet (M2 m m')) f -> eqm (MapGet m) (fun a:ad => f (ad_double a)). + Proof. + unfold eqm in |- *. + intros. + rewrite <- (H (ad_double a)). + exact (Map2_semantics_1 m m' a). + Qed. + + Lemma Map2_semantics_2 : + forall m m':Map, + eqm (MapGet m') (fun a:ad => MapGet (M2 m m') (ad_double_plus_un a)). + Proof. + unfold eqm in |- *. simple induction a; trivial. + Qed. + + Lemma Map2_semantics_2_eq : + forall (m m':Map) (f:ad -> option), + eqm (MapGet (M2 m m')) f -> + eqm (MapGet m') (fun a:ad => f (ad_double_plus_un a)). + Proof. + unfold eqm in |- *. + intros. + rewrite <- (H (ad_double_plus_un a)). + exact (Map2_semantics_2 m m' a). + Qed. + + Lemma MapGet_M2_bit_0_0 : + forall a:ad, + ad_bit_0 a = false -> + forall m m':Map, MapGet (M2 m m') a = MapGet m (ad_div_2 a). + Proof. + simple induction a; trivial. simple induction p. intros. discriminate H0. + trivial. + intros. discriminate H. + Qed. + + Lemma MapGet_M2_bit_0_1 : + forall a:ad, + ad_bit_0 a = true -> + forall m m':Map, MapGet (M2 m m') a = MapGet m' (ad_div_2 a). + Proof. + simple induction a. intros. discriminate H. + simple induction p. trivial. + intros. discriminate H0. + trivial. + Qed. + + Lemma MapGet_M2_bit_0_if : + forall (m m':Map) (a:ad), + MapGet (M2 m m') a = + (if ad_bit_0 a then MapGet m' (ad_div_2 a) else MapGet m (ad_div_2 a)). + Proof. + intros. elim (sumbool_of_bool (ad_bit_0 a)). intro H. rewrite H. + apply MapGet_M2_bit_0_1; assumption. + intro H. rewrite H. apply MapGet_M2_bit_0_0; assumption. + Qed. + + Lemma MapGet_M2_bit_0 : + forall (m m' m'':Map) (a:ad), + (if ad_bit_0 a then MapGet (M2 m' m) a else MapGet (M2 m m'') a) = + MapGet m (ad_div_2 a). + Proof. + intros. elim (sumbool_of_bool (ad_bit_0 a)). intro H. rewrite H. + apply MapGet_M2_bit_0_1; assumption. + intro H. rewrite H. apply MapGet_M2_bit_0_0; assumption. + Qed. + + Lemma Map2_semantics_3 : + forall m m':Map, + eqm (MapGet (M2 m m')) + (fun a:ad => + match ad_bit_0 a with + | false => MapGet m (ad_div_2 a) + | true => MapGet m' (ad_div_2 a) + end). + Proof. + unfold eqm in |- *. + simple induction a; trivial. + simple induction p; trivial. + Qed. + + Lemma Map2_semantics_3_eq : + forall (m m':Map) (f f':ad -> option), + eqm (MapGet m) f -> + eqm (MapGet m') f' -> + eqm (MapGet (M2 m m')) + (fun a:ad => + match ad_bit_0 a with + | false => f (ad_div_2 a) + | true => f' (ad_div_2 a) + end). + Proof. + unfold eqm in |- *. + intros. + rewrite <- (H (ad_div_2 a)). + rewrite <- (H0 (ad_div_2 a)). + exact (Map2_semantics_3 m m' a). + Qed. + + Fixpoint MapPut1 (a:ad) (y:A) (a':ad) (y':A) (p:positive) {struct p} : + Map := + match p with + | xO p' => + let m := MapPut1 (ad_div_2 a) y (ad_div_2 a') y' p' in + match ad_bit_0 a with + | false => M2 m M0 + | true => M2 M0 m + end + | _ => + match ad_bit_0 a with + | false => M2 (M1 (ad_div_2 a) y) (M1 (ad_div_2 a') y') + | true => M2 (M1 (ad_div_2 a') y') (M1 (ad_div_2 a) y) + end + end. + + Lemma MapGet_if_commute : + forall (b:bool) (m m':Map) (a:ad), + MapGet (if b then m else m') a = (if b then MapGet m a else MapGet m' a). + Proof. + intros. case b; trivial. + Qed. + + (*i + Lemma MapGet_M2_bit_0_1' : (m,m',m'',m''':Map) + (a:ad) (MapGet (if (ad_bit_0 a) then (M2 m m') else (M2 m'' m''')) a)= + (MapGet (if (ad_bit_0 a) then m' else m'') (ad_div_2 a)). + Proof. + Intros. Rewrite (MapGet_if_commute (ad_bit_0 a)). Rewrite (MapGet_if_commute (ad_bit_0 a)). + Cut (ad_bit_0 a)=false\/(ad_bit_0 a)=true. Intros. Elim H. Intros. Rewrite H0. + Apply MapGet_M2_bit_0_0. Assumption. + Intros. Rewrite H0. Apply MapGet_M2_bit_0_1. Assumption. + Case (ad_bit_0 a); Auto. + Qed. + i*) + + Lemma MapGet_if_same : + forall (m:Map) (b:bool) (a:ad), MapGet (if b then m else m) a = MapGet m a. + Proof. + simple induction b; trivial. + Qed. + + Lemma MapGet_M2_bit_0_2 : + forall (m m' m'':Map) (a:ad), + MapGet (if ad_bit_0 a then M2 m m' else M2 m' m'') a = + MapGet m' (ad_div_2 a). + Proof. + intros. rewrite MapGet_if_commute. apply MapGet_M2_bit_0. + Qed. + + Lemma MapPut1_semantics_1 : + forall (p:positive) (a a':ad) (y y':A), + ad_xor a a' = ad_x p -> MapGet (MapPut1 a y a' y' p) a = SOME y. + Proof. + simple induction p. intros. unfold MapPut1 in |- *. rewrite MapGet_M2_bit_0_2. apply M1_semantics_1. + intros. simpl in |- *. rewrite MapGet_M2_bit_0_2. apply H. rewrite <- ad_xor_div_2. rewrite H0. + reflexivity. + intros. unfold MapPut1 in |- *. rewrite MapGet_M2_bit_0_2. apply M1_semantics_1. + Qed. + + Lemma MapPut1_semantics_2 : + forall (p:positive) (a a':ad) (y y':A), + ad_xor a a' = ad_x p -> MapGet (MapPut1 a y a' y' p) a' = SOME y'. + Proof. + simple induction p. intros. unfold MapPut1 in |- *. rewrite (ad_neg_bit_0_2 a a' p0 H0). + rewrite if_negb. rewrite MapGet_M2_bit_0_2. apply M1_semantics_1. + intros. simpl in |- *. rewrite (ad_same_bit_0 a a' p0 H0). rewrite MapGet_M2_bit_0_2. + apply H. rewrite <- ad_xor_div_2. rewrite H0. reflexivity. + intros. unfold MapPut1 in |- *. rewrite (ad_neg_bit_0_1 a a' H). rewrite if_negb. + rewrite MapGet_M2_bit_0_2. apply M1_semantics_1. + Qed. + + Lemma MapGet_M2_both_NONE : + forall (m m':Map) (a:ad), + MapGet m (ad_div_2 a) = NONE -> + MapGet m' (ad_div_2 a) = NONE -> MapGet (M2 m m') a = NONE. + Proof. + intros. rewrite (Map2_semantics_3 m m' a). + case (ad_bit_0 a); assumption. + Qed. + + Lemma MapPut1_semantics_3 : + forall (p:positive) (a a' a0:ad) (y y':A), + ad_xor a a' = ad_x p -> + ad_eq a a0 = false -> + ad_eq a' a0 = false -> MapGet (MapPut1 a y a' y' p) a0 = NONE. + Proof. + simple induction p. intros. unfold MapPut1 in |- *. elim (ad_neq a a0 H1). intro. rewrite H3. rewrite if_negb. + rewrite MapGet_M2_bit_0_2. apply M1_semantics_2. apply ad_div_bit_neq. assumption. + rewrite (ad_neg_bit_0_2 a a' p0 H0) in H3. rewrite (negb_intro (ad_bit_0 a')). + rewrite (negb_intro (ad_bit_0 a0)). rewrite H3. reflexivity. + intro. elim (ad_neq a' a0 H2). intro. rewrite (ad_neg_bit_0_2 a a' p0 H0). rewrite H4. + rewrite (negb_elim (ad_bit_0 a0)). rewrite MapGet_M2_bit_0_2. + apply M1_semantics_2; assumption. + intro; case (ad_bit_0 a); apply MapGet_M2_both_NONE; apply M1_semantics_2; + assumption. + intros. simpl in |- *. elim (ad_neq a a0 H1). intro. rewrite H3. rewrite if_negb. + rewrite MapGet_M2_bit_0_2. reflexivity. + intro. elim (ad_neq a' a0 H2). intro. rewrite (ad_same_bit_0 a a' p0 H0). rewrite H4. + rewrite if_negb. rewrite MapGet_M2_bit_0_2. reflexivity. + intro. cut (ad_xor (ad_div_2 a) (ad_div_2 a') = ad_x p0). intro. + case (ad_bit_0 a); apply MapGet_M2_both_NONE; trivial; apply H; + assumption. + rewrite <- ad_xor_div_2. rewrite H0. reflexivity. + intros. simpl in |- *. elim (ad_neq a a0 H0). intro. rewrite H2. rewrite if_negb. + rewrite MapGet_M2_bit_0_2. apply M1_semantics_2. apply ad_div_bit_neq. assumption. + rewrite (ad_neg_bit_0_1 a a' H) in H2. rewrite (negb_intro (ad_bit_0 a')). + rewrite (negb_intro (ad_bit_0 a0)). rewrite H2. reflexivity. + intro. elim (ad_neq a' a0 H1). intro. rewrite (ad_neg_bit_0_1 a a' H). rewrite H3. + rewrite (negb_elim (ad_bit_0 a0)). rewrite MapGet_M2_bit_0_2. + apply M1_semantics_2; assumption. + intro. case (ad_bit_0 a); apply MapGet_M2_both_NONE; apply M1_semantics_2; + assumption. + Qed. + + Lemma MapPut1_semantics : + forall (p:positive) (a a':ad) (y y':A), + ad_xor a a' = ad_x p -> + eqm (MapGet (MapPut1 a y a' y' p)) + (fun a0:ad => + if ad_eq a a0 + then SOME y + else if ad_eq a' a0 then SOME y' else NONE). + Proof. + unfold eqm in |- *. intros. elim (sumbool_of_bool (ad_eq a a0)). intro H0. rewrite H0. + rewrite <- (ad_eq_complete _ _ H0). exact (MapPut1_semantics_1 p a a' y y' H). + intro H0. rewrite H0. elim (sumbool_of_bool (ad_eq a' a0)). intro H1. + rewrite <- (ad_eq_complete _ _ H1). rewrite (ad_eq_correct a'). + exact (MapPut1_semantics_2 p a a' y y' H). + intro H1. rewrite H1. exact (MapPut1_semantics_3 p a a' a0 y y' H H0 H1). + Qed. + + Lemma MapPut1_semantics' : + forall (p:positive) (a a':ad) (y y':A), + ad_xor a a' = ad_x p -> + eqm (MapGet (MapPut1 a y a' y' p)) + (fun a0:ad => + if ad_eq a' a0 + then SOME y' + else if ad_eq a a0 then SOME y else NONE). + Proof. + unfold eqm in |- *. intros. rewrite (MapPut1_semantics p a a' y y' H a0). + elim (sumbool_of_bool (ad_eq a a0)). intro H0. rewrite H0. + rewrite <- (ad_eq_complete a a0 H0). rewrite (ad_eq_comm a' a). + rewrite (ad_xor_eq_false a a' p H). reflexivity. + intro H0. rewrite H0. reflexivity. + Qed. + + Fixpoint MapPut (m:Map) : ad -> A -> Map := + match m with + | M0 => M1 + | M1 a y => + fun (a':ad) (y':A) => + match ad_xor a a' with + | ad_z => M1 a' y' + | ad_x p => MapPut1 a y a' y' p + end + | M2 m1 m2 => + fun (a:ad) (y:A) => + match a with + | ad_z => M2 (MapPut m1 ad_z y) m2 + | ad_x xH => M2 m1 (MapPut m2 ad_z y) + | ad_x (xO p) => M2 (MapPut m1 (ad_x p) y) m2 + | ad_x (xI p) => M2 m1 (MapPut m2 (ad_x p) y) + end + end. + + Lemma MapPut_semantics_1 : + forall (a:ad) (y:A) (a0:ad), + MapGet (MapPut M0 a y) a0 = MapGet (M1 a y) a0. + Proof. + trivial. + Qed. + + Lemma MapPut_semantics_2_1 : + forall (a:ad) (y y':A) (a0:ad), + MapGet (MapPut (M1 a y) a y') a0 = + (if ad_eq a a0 then SOME y' else NONE). + Proof. + simpl in |- *. intros. rewrite (ad_xor_nilpotent a). trivial. + Qed. + + Lemma MapPut_semantics_2_2 : + forall (a a':ad) (y y':A) (a0 a'':ad), + ad_xor a a' = a'' -> + MapGet (MapPut (M1 a y) a' y') a0 = + (if ad_eq a' a0 then SOME y' else if ad_eq a a0 then SOME y else NONE). + Proof. + simple induction a''. intro. rewrite (ad_xor_eq _ _ H). rewrite MapPut_semantics_2_1. + case (ad_eq a' a0); trivial. + intros. simpl in |- *. rewrite H. rewrite (MapPut1_semantics p a a' y y' H a0). + elim (sumbool_of_bool (ad_eq a a0)). intro H0. rewrite H0. rewrite <- (ad_eq_complete _ _ H0). + rewrite (ad_eq_comm a' a). rewrite (ad_xor_eq_false _ _ _ H). reflexivity. + intro H0. rewrite H0. reflexivity. + Qed. + + Lemma MapPut_semantics_2 : + forall (a a':ad) (y y':A) (a0:ad), + MapGet (MapPut (M1 a y) a' y') a0 = + (if ad_eq a' a0 then SOME y' else if ad_eq a a0 then SOME y else NONE). + Proof. + intros. apply MapPut_semantics_2_2 with (a'' := ad_xor a a'); trivial. + Qed. + + Lemma MapPut_semantics_3_1 : + forall (m m':Map) (a:ad) (y:A), + MapPut (M2 m m') a y = + (if ad_bit_0 a + then M2 m (MapPut m' (ad_div_2 a) y) + else M2 (MapPut m (ad_div_2 a) y) m'). + Proof. + simple induction a. trivial. + simple induction p; trivial. + Qed. + + Lemma MapPut_semantics : + forall (m:Map) (a:ad) (y:A), + eqm (MapGet (MapPut m a y)) + (fun a':ad => if ad_eq a a' then SOME y else MapGet m a'). + Proof. + unfold eqm in |- *. simple induction m. exact MapPut_semantics_1. + intros. unfold MapGet at 2 in |- *. apply MapPut_semantics_2; assumption. + intros. rewrite MapPut_semantics_3_1. rewrite (MapGet_M2_bit_0_if m0 m1 a0). + elim (sumbool_of_bool (ad_bit_0 a)). intro H1. rewrite H1. rewrite MapGet_M2_bit_0_if. + elim (sumbool_of_bool (ad_bit_0 a0)). intro H2. rewrite H2. + rewrite (H0 (ad_div_2 a) y (ad_div_2 a0)). elim (sumbool_of_bool (ad_eq a a0)). + intro H3. rewrite H3. rewrite (ad_div_eq _ _ H3). reflexivity. + intro H3. rewrite H3. rewrite <- H2 in H1. rewrite (ad_div_bit_neq _ _ H3 H1). reflexivity. + intro H2. rewrite H2. rewrite (ad_eq_comm a a0). rewrite (ad_bit_0_neq a0 a H2 H1). + reflexivity. + intro H1. rewrite H1. rewrite MapGet_M2_bit_0_if. elim (sumbool_of_bool (ad_bit_0 a0)). + intro H2. rewrite H2. rewrite (ad_bit_0_neq a a0 H1 H2). reflexivity. + intro H2. rewrite H2. rewrite (H (ad_div_2 a) y (ad_div_2 a0)). + elim (sumbool_of_bool (ad_eq a a0)). intro H3. rewrite H3. + rewrite (ad_div_eq a a0 H3). reflexivity. + intro H3. rewrite H3. rewrite <- H2 in H1. rewrite (ad_div_bit_neq a a0 H3 H1). reflexivity. + Qed. + + Fixpoint MapPut_behind (m:Map) : ad -> A -> Map := + match m with + | M0 => M1 + | M1 a y => + fun (a':ad) (y':A) => + match ad_xor a a' with + | ad_z => m + | ad_x p => MapPut1 a y a' y' p + end + | M2 m1 m2 => + fun (a:ad) (y:A) => + match a with + | ad_z => M2 (MapPut_behind m1 ad_z y) m2 + | ad_x xH => M2 m1 (MapPut_behind m2 ad_z y) + | ad_x (xO p) => M2 (MapPut_behind m1 (ad_x p) y) m2 + | ad_x (xI p) => M2 m1 (MapPut_behind m2 (ad_x p) y) + end + end. + + Lemma MapPut_behind_semantics_3_1 : + forall (m m':Map) (a:ad) (y:A), + MapPut_behind (M2 m m') a y = + (if ad_bit_0 a + then M2 m (MapPut_behind m' (ad_div_2 a) y) + else M2 (MapPut_behind m (ad_div_2 a) y) m'). + Proof. + simple induction a. trivial. + simple induction p; trivial. + Qed. + + Lemma MapPut_behind_as_before_1 : + forall a a' a0:ad, + ad_eq a' a0 = false -> + forall y y':A, + MapGet (MapPut (M1 a y) a' y') a0 = + MapGet (MapPut_behind (M1 a y) a' y') a0. + Proof. + intros a a' a0. simpl in |- *. intros H y y'. elim (ad_sum (ad_xor a a')). intro H0. elim H0. + intros p H1. rewrite H1. reflexivity. + intro H0. rewrite H0. rewrite (ad_xor_eq _ _ H0). rewrite (M1_semantics_2 a' a0 y H). + exact (M1_semantics_2 a' a0 y' H). + Qed. + + Lemma MapPut_behind_as_before : + forall (m:Map) (a:ad) (y:A) (a0:ad), + ad_eq a a0 = false -> + MapGet (MapPut m a y) a0 = MapGet (MapPut_behind m a y) a0. + Proof. + simple induction m. trivial. + intros a y a' y' a0 H. exact (MapPut_behind_as_before_1 a a' a0 H y y'). + intros. rewrite MapPut_semantics_3_1. rewrite MapPut_behind_semantics_3_1. + elim (sumbool_of_bool (ad_bit_0 a)). intro H2. rewrite H2. rewrite MapGet_M2_bit_0_if. + rewrite MapGet_M2_bit_0_if. elim (sumbool_of_bool (ad_bit_0 a0)). intro H3. + rewrite H3. apply H0. rewrite <- H3 in H2. exact (ad_div_bit_neq a a0 H1 H2). + intro H3. rewrite H3. reflexivity. + intro H2. rewrite H2. rewrite MapGet_M2_bit_0_if. rewrite MapGet_M2_bit_0_if. + elim (sumbool_of_bool (ad_bit_0 a0)). intro H3. rewrite H3. reflexivity. + intro H3. rewrite H3. apply H. rewrite <- H3 in H2. exact (ad_div_bit_neq a a0 H1 H2). + Qed. + + Lemma MapPut_behind_new : + forall (m:Map) (a:ad) (y:A), + MapGet (MapPut_behind m a y) a = + match MapGet m a with + | SOME y' => SOME y' + | _ => SOME y + end. + Proof. + simple induction m. simpl in |- *. intros. rewrite (ad_eq_correct a). reflexivity. + intros. elim (ad_sum (ad_xor a a1)). intro H. elim H. intros p H0. simpl in |- *. + rewrite H0. rewrite (ad_xor_eq_false a a1 p). exact (MapPut1_semantics_2 p a a1 a0 y H0). + assumption. + intro H. simpl in |- *. rewrite H. rewrite <- (ad_xor_eq _ _ H). rewrite (ad_eq_correct a). + exact (M1_semantics_1 a a0). + intros. rewrite MapPut_behind_semantics_3_1. rewrite (MapGet_M2_bit_0_if m0 m1 a). + elim (sumbool_of_bool (ad_bit_0 a)). intro H1. rewrite H1. rewrite (MapGet_M2_bit_0_1 a H1). + exact (H0 (ad_div_2 a) y). + intro H1. rewrite H1. rewrite (MapGet_M2_bit_0_0 a H1). exact (H (ad_div_2 a) y). + Qed. + + Lemma MapPut_behind_semantics : + forall (m:Map) (a:ad) (y:A), + eqm (MapGet (MapPut_behind m a y)) + (fun a':ad => + match MapGet m a' with + | SOME y' => SOME y' + | _ => if ad_eq a a' then SOME y else NONE + end). + Proof. + unfold eqm in |- *. intros. elim (sumbool_of_bool (ad_eq a a0)). intro H. rewrite H. + rewrite (ad_eq_complete _ _ H). apply MapPut_behind_new. + intro H. rewrite H. rewrite <- (MapPut_behind_as_before m a y a0 H). + rewrite (MapPut_semantics m a y a0). rewrite H. case (MapGet m a0); trivial. + Qed. + + Definition makeM2 (m m':Map) := + match m, m' with + | M0, M0 => M0 + | M0, M1 a y => M1 (ad_double_plus_un a) y + | M1 a y, M0 => M1 (ad_double a) y + | _, _ => M2 m m' + end. + + Lemma makeM2_M2 : + forall m m':Map, eqm (MapGet (makeM2 m m')) (MapGet (M2 m m')). + Proof. + unfold eqm in |- *. intros. elim (sumbool_of_bool (ad_bit_0 a)). intro H. + rewrite (MapGet_M2_bit_0_1 a H m m'). case m'. case m. reflexivity. + intros a0 y. simpl in |- *. rewrite (ad_bit_0_1_not_double a H a0). reflexivity. + intros m1 m2. unfold makeM2 in |- *. rewrite MapGet_M2_bit_0_1. reflexivity. + assumption. + case m. intros a0 y. simpl in |- *. elim (sumbool_of_bool (ad_eq a0 (ad_div_2 a))). + intro H0. rewrite H0. rewrite (ad_eq_complete _ _ H0). rewrite (ad_div_2_double_plus_un a H). + rewrite (ad_eq_correct a). reflexivity. + intro H0. rewrite H0. rewrite (ad_eq_comm a0 (ad_div_2 a)) in H0. + rewrite (ad_not_div_2_not_double_plus_un a a0 H0). reflexivity. + intros a0 y0 a1 y1. unfold makeM2 in |- *. rewrite MapGet_M2_bit_0_1. reflexivity. + assumption. + intros m1 m2 a0 y. unfold makeM2 in |- *. rewrite MapGet_M2_bit_0_1. reflexivity. + assumption. + intros m1 m2. unfold makeM2 in |- *. + cut (MapGet (M2 m (M2 m1 m2)) a = MapGet (M2 m1 m2) (ad_div_2 a)). + case m; trivial. + exact (MapGet_M2_bit_0_1 a H m (M2 m1 m2)). + intro H. rewrite (MapGet_M2_bit_0_0 a H m m'). case m. case m'. reflexivity. + intros a0 y. simpl in |- *. rewrite (ad_bit_0_0_not_double_plus_un a H a0). reflexivity. + intros m1 m2. unfold makeM2 in |- *. rewrite MapGet_M2_bit_0_0. reflexivity. + assumption. + case m'. intros a0 y. simpl in |- *. elim (sumbool_of_bool (ad_eq a0 (ad_div_2 a))). intro H0. + rewrite H0. rewrite (ad_eq_complete _ _ H0). rewrite (ad_div_2_double a H). + rewrite (ad_eq_correct a). reflexivity. + intro H0. rewrite H0. rewrite (ad_eq_comm (ad_double a0) a). + rewrite (ad_eq_comm a0 (ad_div_2 a)) in H0. rewrite (ad_not_div_2_not_double a a0 H0). + reflexivity. + intros a0 y0 a1 y1. unfold makeM2 in |- *. rewrite MapGet_M2_bit_0_0. reflexivity. + assumption. + intros m1 m2 a0 y. unfold makeM2 in |- *. rewrite MapGet_M2_bit_0_0. reflexivity. + assumption. + intros m1 m2. unfold makeM2 in |- *. exact (MapGet_M2_bit_0_0 a H (M2 m1 m2) m'). + Qed. + + Fixpoint MapRemove (m:Map) : ad -> Map := + match m with + | M0 => fun _:ad => M0 + | M1 a y => + fun a':ad => match ad_eq a a' with + | true => M0 + | false => m + end + | M2 m1 m2 => + fun a:ad => + if ad_bit_0 a + then makeM2 m1 (MapRemove m2 (ad_div_2 a)) + else makeM2 (MapRemove m1 (ad_div_2 a)) m2 + end. + + Lemma MapRemove_semantics : + forall (m:Map) (a:ad), + eqm (MapGet (MapRemove m a)) + (fun a':ad => if ad_eq a a' then NONE else MapGet m a'). + Proof. + unfold eqm in |- *. simple induction m. simpl in |- *. intros. case (ad_eq a a0); trivial. + intros. simpl in |- *. elim (sumbool_of_bool (ad_eq a1 a2)). intro H. rewrite H. + elim (sumbool_of_bool (ad_eq a a1)). intro H0. rewrite H0. reflexivity. + intro H0. rewrite H0. rewrite (ad_eq_complete _ _ H) in H0. exact (M1_semantics_2 a a2 a0 H0). + intro H. elim (sumbool_of_bool (ad_eq a a1)). intro H0. rewrite H0. rewrite H. + rewrite <- (ad_eq_complete _ _ H0) in H. rewrite H. reflexivity. + intro H0. rewrite H0. rewrite H. reflexivity. + intros. change + (MapGet + (if ad_bit_0 a + then makeM2 m0 (MapRemove m1 (ad_div_2 a)) + else makeM2 (MapRemove m0 (ad_div_2 a)) m1) a0 = + (if ad_eq a a0 then NONE else MapGet (M2 m0 m1) a0)) + in |- *. + elim (sumbool_of_bool (ad_bit_0 a)). intro H1. rewrite H1. + rewrite (makeM2_M2 m0 (MapRemove m1 (ad_div_2 a)) a0). elim (sumbool_of_bool (ad_bit_0 a0)). + intro H2. rewrite MapGet_M2_bit_0_1. rewrite (H0 (ad_div_2 a) (ad_div_2 a0)). + elim (sumbool_of_bool (ad_eq a a0)). intro H3. rewrite H3. rewrite (ad_div_eq _ _ H3). + reflexivity. + intro H3. rewrite H3. rewrite <- H2 in H1. rewrite (ad_div_bit_neq _ _ H3 H1). + rewrite (MapGet_M2_bit_0_1 a0 H2 m0 m1). reflexivity. + assumption. + intro H2. rewrite (MapGet_M2_bit_0_0 a0 H2 m0 (MapRemove m1 (ad_div_2 a))). + rewrite (ad_eq_comm a a0). rewrite (ad_bit_0_neq _ _ H2 H1). + rewrite (MapGet_M2_bit_0_0 a0 H2 m0 m1). reflexivity. + intro H1. rewrite H1. rewrite (makeM2_M2 (MapRemove m0 (ad_div_2 a)) m1 a0). + elim (sumbool_of_bool (ad_bit_0 a0)). intro H2. rewrite MapGet_M2_bit_0_1. + rewrite (MapGet_M2_bit_0_1 a0 H2 m0 m1). rewrite (ad_bit_0_neq a a0 H1 H2). reflexivity. + assumption. + intro H2. rewrite MapGet_M2_bit_0_0. rewrite (H (ad_div_2 a) (ad_div_2 a0)). + rewrite (MapGet_M2_bit_0_0 a0 H2 m0 m1). elim (sumbool_of_bool (ad_eq a a0)). intro H3. + rewrite H3. rewrite (ad_div_eq _ _ H3). reflexivity. + intro H3. rewrite H3. rewrite <- H2 in H1. rewrite (ad_div_bit_neq _ _ H3 H1). reflexivity. + assumption. + Qed. + + Fixpoint MapCard (m:Map) : nat := + match m with + | M0 => 0 + | M1 _ _ => 1 + | M2 m m' => MapCard m + MapCard m' + end. + + Fixpoint MapMerge (m:Map) : Map -> Map := + match m with + | M0 => fun m':Map => m' + | M1 a y => fun m':Map => MapPut_behind m' a y + | M2 m1 m2 => + fun m':Map => + match m' with + | M0 => m + | M1 a' y' => MapPut m a' y' + | M2 m'1 m'2 => M2 (MapMerge m1 m'1) (MapMerge m2 m'2) + end + end. + + Lemma MapMerge_semantics : + forall m m':Map, + eqm (MapGet (MapMerge m m')) + (fun a0:ad => + match MapGet m' a0 with + | SOME y' => SOME y' + | NONE => MapGet m a0 + end). + Proof. + unfold eqm in |- *. simple induction m. intros. simpl in |- *. case (MapGet m' a); trivial. + intros. simpl in |- *. rewrite (MapPut_behind_semantics m' a a0 a1). reflexivity. + simple induction m'. trivial. + intros. unfold MapMerge in |- *. rewrite (MapPut_semantics (M2 m0 m1) a a0 a1). + elim (sumbool_of_bool (ad_eq a a1)). intro H1. rewrite H1. rewrite (ad_eq_complete _ _ H1). + rewrite (M1_semantics_1 a1 a0). reflexivity. + intro H1. rewrite H1. rewrite (M1_semantics_2 a a1 a0 H1). reflexivity. + intros. cut (MapMerge (M2 m0 m1) (M2 m2 m3) = M2 (MapMerge m0 m2) (MapMerge m1 m3)). + intro. rewrite H3. rewrite MapGet_M2_bit_0_if. rewrite (H0 m3 (ad_div_2 a)). + rewrite (H m2 (ad_div_2 a)). rewrite (MapGet_M2_bit_0_if m2 m3 a). + rewrite (MapGet_M2_bit_0_if m0 m1 a). case (ad_bit_0 a); trivial. + reflexivity. + Qed. + + (** [MapInter], [MapRngRestrTo], [MapRngRestrBy], [MapInverse] + not implemented: need a decidable equality on [A]. *) + + Fixpoint MapDelta (m:Map) : Map -> Map := + match m with + | M0 => fun m':Map => m' + | M1 a y => + fun m':Map => + match MapGet m' a with + | NONE => MapPut m' a y + | _ => MapRemove m' a + end + | M2 m1 m2 => + fun m':Map => + match m' with + | M0 => m + | M1 a' y' => + match MapGet m a' with + | NONE => MapPut m a' y' + | _ => MapRemove m a' + end + | M2 m'1 m'2 => makeM2 (MapDelta m1 m'1) (MapDelta m2 m'2) + end + end. + + Lemma MapDelta_semantics_comm : + forall m m':Map, eqm (MapGet (MapDelta m m')) (MapGet (MapDelta m' m)). + Proof. + unfold eqm in |- *. simple induction m. simple induction m'; reflexivity. + simple induction m'. reflexivity. + unfold MapDelta in |- *. intros. elim (sumbool_of_bool (ad_eq a a1)). intro H. + rewrite <- (ad_eq_complete _ _ H). rewrite (M1_semantics_1 a a2). + rewrite (M1_semantics_1 a a0). simpl in |- *. rewrite (ad_eq_correct a). reflexivity. + intro H. rewrite (M1_semantics_2 a a1 a0 H). rewrite (ad_eq_comm a a1) in H. + rewrite (M1_semantics_2 a1 a a2 H). rewrite (MapPut_semantics (M1 a a0) a1 a2 a3). + rewrite (MapPut_semantics (M1 a1 a2) a a0 a3). elim (sumbool_of_bool (ad_eq a a3)). + intro H0. rewrite H0. rewrite (ad_eq_complete _ _ H0) in H. rewrite H. + rewrite (ad_eq_complete _ _ H0). rewrite (M1_semantics_1 a3 a0). reflexivity. + intro H0. rewrite H0. rewrite (M1_semantics_2 a a3 a0 H0). + elim (sumbool_of_bool (ad_eq a1 a3)). intro H1. rewrite H1. + rewrite (ad_eq_complete _ _ H1). exact (M1_semantics_1 a3 a2). + intro H1. rewrite H1. exact (M1_semantics_2 a1 a3 a2 H1). + intros. reflexivity. + simple induction m'. reflexivity. + reflexivity. + intros. simpl in |- *. rewrite (makeM2_M2 (MapDelta m0 m2) (MapDelta m1 m3) a). + rewrite (makeM2_M2 (MapDelta m2 m0) (MapDelta m3 m1) a). + rewrite (MapGet_M2_bit_0_if (MapDelta m0 m2) (MapDelta m1 m3) a). + rewrite (MapGet_M2_bit_0_if (MapDelta m2 m0) (MapDelta m3 m1) a). + rewrite (H0 m3 (ad_div_2 a)). rewrite (H m2 (ad_div_2 a)). reflexivity. + Qed. + + Lemma MapDelta_semantics_1_1 : + forall (a:ad) (y:A) (m':Map) (a0:ad), + MapGet (M1 a y) a0 = NONE -> + MapGet m' a0 = NONE -> MapGet (MapDelta (M1 a y) m') a0 = NONE. + Proof. + intros. unfold MapDelta in |- *. elim (sumbool_of_bool (ad_eq a a0)). intro H1. + rewrite (ad_eq_complete _ _ H1) in H. rewrite (M1_semantics_1 a0 y) in H. discriminate H. + intro H1. case (MapGet m' a). rewrite (MapPut_semantics m' a y a0). rewrite H1. assumption. + rewrite (MapRemove_semantics m' a a0). rewrite H1. trivial. + Qed. + + Lemma MapDelta_semantics_1 : + forall (m m':Map) (a:ad), + MapGet m a = NONE -> + MapGet m' a = NONE -> MapGet (MapDelta m m') a = NONE. + Proof. + simple induction m. trivial. + exact MapDelta_semantics_1_1. + simple induction m'. trivial. + intros. rewrite (MapDelta_semantics_comm (M2 m0 m1) (M1 a a0) a1). + apply MapDelta_semantics_1_1; trivial. + intros. simpl in |- *. rewrite (makeM2_M2 (MapDelta m0 m2) (MapDelta m1 m3) a). + rewrite MapGet_M2_bit_0_if. elim (sumbool_of_bool (ad_bit_0 a)). intro H5. rewrite H5. + apply H0. rewrite (MapGet_M2_bit_0_1 a H5 m0 m1) in H3. exact H3. + rewrite (MapGet_M2_bit_0_1 a H5 m2 m3) in H4. exact H4. + intro H5. rewrite H5. apply H. rewrite (MapGet_M2_bit_0_0 a H5 m0 m1) in H3. exact H3. + rewrite (MapGet_M2_bit_0_0 a H5 m2 m3) in H4. exact H4. + Qed. + + Lemma MapDelta_semantics_2_1 : + forall (a:ad) (y:A) (m':Map) (a0:ad) (y0:A), + MapGet (M1 a y) a0 = NONE -> + MapGet m' a0 = SOME y0 -> MapGet (MapDelta (M1 a y) m') a0 = SOME y0. + Proof. + intros. unfold MapDelta in |- *. elim (sumbool_of_bool (ad_eq a a0)). intro H1. + rewrite (ad_eq_complete _ _ H1) in H. rewrite (M1_semantics_1 a0 y) in H. discriminate H. + intro H1. case (MapGet m' a). rewrite (MapPut_semantics m' a y a0). rewrite H1. assumption. + rewrite (MapRemove_semantics m' a a0). rewrite H1. trivial. + Qed. + + Lemma MapDelta_semantics_2_2 : + forall (a:ad) (y:A) (m':Map) (a0:ad) (y0:A), + MapGet (M1 a y) a0 = SOME y0 -> + MapGet m' a0 = NONE -> MapGet (MapDelta (M1 a y) m') a0 = SOME y0. + Proof. + intros. unfold MapDelta in |- *. elim (sumbool_of_bool (ad_eq a a0)). intro H1. + rewrite (ad_eq_complete _ _ H1) in H. rewrite (ad_eq_complete _ _ H1). + rewrite H0. rewrite (MapPut_semantics m' a0 y a0). rewrite (ad_eq_correct a0). + rewrite (M1_semantics_1 a0 y) in H. simple inversion H. assumption. + intro H1. rewrite (M1_semantics_2 a a0 y H1) in H. discriminate H. + Qed. + + Lemma MapDelta_semantics_2 : + forall (m m':Map) (a:ad) (y:A), + MapGet m a = NONE -> + MapGet m' a = SOME y -> MapGet (MapDelta m m') a = SOME y. + Proof. + simple induction m. trivial. + exact MapDelta_semantics_2_1. + simple induction m'. intros. discriminate H2. + intros. rewrite (MapDelta_semantics_comm (M2 m0 m1) (M1 a a0) a1). + apply MapDelta_semantics_2_2; assumption. + intros. simpl in |- *. rewrite (makeM2_M2 (MapDelta m0 m2) (MapDelta m1 m3) a). + rewrite MapGet_M2_bit_0_if. elim (sumbool_of_bool (ad_bit_0 a)). intro H5. rewrite H5. + apply H0. rewrite <- (MapGet_M2_bit_0_1 a H5 m0 m1). assumption. + rewrite <- (MapGet_M2_bit_0_1 a H5 m2 m3). assumption. + intro H5. rewrite H5. apply H. rewrite <- (MapGet_M2_bit_0_0 a H5 m0 m1). assumption. + rewrite <- (MapGet_M2_bit_0_0 a H5 m2 m3). assumption. + Qed. + + Lemma MapDelta_semantics_3_1 : + forall (a0:ad) (y0:A) (m':Map) (a:ad) (y y':A), + MapGet (M1 a0 y0) a = SOME y -> + MapGet m' a = SOME y' -> MapGet (MapDelta (M1 a0 y0) m') a = NONE. + Proof. + intros. unfold MapDelta in |- *. elim (sumbool_of_bool (ad_eq a0 a)). intro H1. + rewrite (ad_eq_complete a0 a H1). rewrite H0. rewrite (MapRemove_semantics m' a a). + rewrite (ad_eq_correct a). reflexivity. + intro H1. rewrite (M1_semantics_2 a0 a y0 H1) in H. discriminate H. + Qed. + + Lemma MapDelta_semantics_3 : + forall (m m':Map) (a:ad) (y y':A), + MapGet m a = SOME y -> + MapGet m' a = SOME y' -> MapGet (MapDelta m m') a = NONE. + Proof. + simple induction m. intros. discriminate H. + exact MapDelta_semantics_3_1. + simple induction m'. intros. discriminate H2. + intros. rewrite (MapDelta_semantics_comm (M2 m0 m1) (M1 a a0) a1). + exact (MapDelta_semantics_3_1 a a0 (M2 m0 m1) a1 y' y H2 H1). + intros. simpl in |- *. rewrite (makeM2_M2 (MapDelta m0 m2) (MapDelta m1 m3) a). + rewrite MapGet_M2_bit_0_if. elim (sumbool_of_bool (ad_bit_0 a)). intro H5. rewrite H5. + apply (H0 m3 (ad_div_2 a) y y'). rewrite <- (MapGet_M2_bit_0_1 a H5 m0 m1). assumption. + rewrite <- (MapGet_M2_bit_0_1 a H5 m2 m3). assumption. + intro H5. rewrite H5. apply (H m2 (ad_div_2 a) y y'). + rewrite <- (MapGet_M2_bit_0_0 a H5 m0 m1). assumption. + rewrite <- (MapGet_M2_bit_0_0 a H5 m2 m3). assumption. + Qed. + + Lemma MapDelta_semantics : + forall m m':Map, + eqm (MapGet (MapDelta m m')) + (fun a0:ad => + match MapGet m a0, MapGet m' a0 with + | NONE, SOME y' => SOME y' + | SOME y, NONE => SOME y + | _, _ => NONE + end). + Proof. + unfold eqm in |- *. intros. elim (option_sum (MapGet m' a)). intro H. elim H. intros a0 H0. + rewrite H0. elim (option_sum (MapGet m a)). intro H1. elim H1. intros a1 H2. rewrite H2. + exact (MapDelta_semantics_3 m m' a a1 a0 H2 H0). + intro H1. rewrite H1. exact (MapDelta_semantics_2 m m' a a0 H1 H0). + intro H. rewrite H. elim (option_sum (MapGet m a)). intro H0. elim H0. intros a0 H1. + rewrite H1. rewrite (MapDelta_semantics_comm m m' a). + exact (MapDelta_semantics_2 m' m a a0 H H1). + intro H0. rewrite H0. exact (MapDelta_semantics_1 m m' a H0 H). + Qed. + + Definition MapEmptyp (m:Map) := match m with + | M0 => true + | _ => false + end. + + Lemma MapEmptyp_correct : MapEmptyp M0 = true. + Proof. + reflexivity. + Qed. + + Lemma MapEmptyp_complete : forall m:Map, MapEmptyp m = true -> m = M0. + Proof. + simple induction m; trivial. intros. discriminate H. + intros. discriminate H1. + Qed. + + (** [MapSplit] not implemented: not the preferred way of recursing over Maps + (use [MapSweep], [MapCollect], or [MapFold] in Mapiter.v. *) + +End MapDefs.
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