diff options
author | Samuel Mimram <smimram@debian.org> | 2006-06-16 14:41:51 +0000 |
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committer | Samuel Mimram <smimram@debian.org> | 2006-06-16 14:41:51 +0000 |
commit | e978da8c41d8a3c19a29036d9c569fbe2a4616b0 (patch) | |
tree | 0de2a907ee93c795978f3c843155bee91c11ed60 /theories/IntMap/Mapcard.v | |
parent | 3ef7797ef6fc605dfafb32523261fe1b023aeecb (diff) |
Imported Upstream version 8.0pl3+8.1betaupstream/8.0pl3+8.1beta
Diffstat (limited to 'theories/IntMap/Mapcard.v')
-rw-r--r-- | theories/IntMap/Mapcard.v | 222 |
1 files changed, 111 insertions, 111 deletions
diff --git a/theories/IntMap/Mapcard.v b/theories/IntMap/Mapcard.v index 35efac47..36be9bf9 100644 --- a/theories/IntMap/Mapcard.v +++ b/theories/IntMap/Mapcard.v @@ -5,15 +5,14 @@ (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (************************************************************************) -(*i $Id: Mapcard.v 5920 2004-07-16 20:01:26Z herbelin $ i*) +(*i $Id: Mapcard.v 8733 2006-04-25 22:52:18Z letouzey $ i*) Require Import Bool. Require Import Sumbool. Require Import Arith. -Require Import ZArith. -Require Import Addr. -Require Import Adist. -Require Import Addec. +Require Import NArith. +Require Import Ndigits. +Require Import Ndec. Require Import Map. Require Import Mapaxioms. Require Import Mapiter. @@ -38,80 +37,80 @@ Section MapCard. Qed. Lemma MapCard_is_O : - forall m:Map A, MapCard A m = 0 -> forall a:ad, MapGet A m a = NONE A. + forall m:Map A, MapCard A m = 0 -> forall a:ad, MapGet A m a = None. 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. + case (Nbit0 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}. + MapGet A m a = Some 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. + intros a y a0 y0 H. simpl in H. elim (sumbool_of_bool (Neqb 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. + intros. elim (sumbool_of_bool (Nbit0 a)). intro H2. + rewrite (MapGet_M2_bit_0_1 A a H2 m0 m1) in H1. elim (H0 (Ndiv2 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). + intro H2. rewrite (MapGet_M2_bit_0_0 A a H2 m0 m1) in H1. elim (H (Ndiv2 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}}. + MapCard A m = 1 -> {a : ad & {y : A | MapGet A m a = Some 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. + intro H2. elim H2. intros. elim (H0 H4). intros a H5. split with (Ndouble_plus_one a). + rewrite (MapGet_M2_bit_0_1 A _ (Ndouble_plus_one_bit0 a) m0 m1). + rewrite Ndouble_plus_one_div2. exact H5. + intro H2. elim H2. intros. elim (H H3). intros a H5. split with (Ndouble a). + rewrite (MapGet_M2_bit_0_0 A _ (Ndouble_bit0 a) m0 m1). + rewrite Ndouble_div2. 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'. + MapGet A m a = Some y -> + MapGet A m a' = Some 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). + intros. elim (sumbool_of_bool (Neqb a a1)). intro H2. rewrite (Neqb_complete _ _ H2) in H0. + rewrite (M1_semantics_1 A a1 a0) in H0. inversion H0. elim (sumbool_of_bool (Neqb a a')). + intro H5. rewrite (Neqb_complete _ _ H5) in H1. rewrite (M1_semantics_1 A a' a0) in H1. + inversion H1. rewrite <- (Neqb_complete _ _ H2). rewrite <- (Neqb_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)). + rewrite (MapGet_M2_bit_0_if A m0 m1 a) in H2. elim (sumbool_of_bool (Nbit0 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. + elim (sumbool_of_bool (Nbit0 a')). intro H8. rewrite H8 in H3. elim (H0 H6 _ _ _ _ H2 H3). + intros. split. rewrite <- (Ndiv2_double_plus_one a H7). + rewrite <- (Ndiv2_double_plus_one a' H8). rewrite H9. reflexivity. assumption. - intro H8. rewrite H8 in H3. rewrite (MapCard_is_O m0 H5 (ad_div_2 a')) in H3. + intro H8. rewrite H8 in H3. rewrite (MapCard_is_O m0 H5 (Ndiv2 a')) in H3. discriminate H3. - intro H7. rewrite H7 in H2. rewrite (MapCard_is_O m0 H5 (ad_div_2 a)) in H2. + intro H7. rewrite H7 in H2. rewrite (MapCard_is_O m0 H5 (Ndiv2 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. + elim (sumbool_of_bool (Nbit0 a)). intro H7. rewrite H7 in H2. + rewrite (MapCard_is_O m1 H6 (Ndiv2 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. + elim (sumbool_of_bool (Nbit0 a')). intro H8. rewrite H8 in H3. + rewrite (MapCard_is_O m1 H6 (Ndiv2 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 <- (Ndiv2_double a H7). rewrite <- (Ndiv2_double a' H8). rewrite H9. reflexivity. assumption. Qed. @@ -139,8 +138,8 @@ Section MapCard. 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. + intros. simpl in |- *. rewrite <- (H (fun a0:ad => pf (Ndouble a0))). + rewrite <- (H0 (fun a0:ad => pf (Ndouble_plus_one a0))). reflexivity. Qed. Lemma MapCard_as_Fold : @@ -164,10 +163,10 @@ Section MapCard. 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. + simple induction p. intros. simpl in |- *. case (Nbit0 a); reflexivity. + intros. simpl in |- *. case (Nbit0 a). exact (H (Ndiv2 a) (Ndiv2 a') y y'). + simpl in |- *. rewrite <- plus_n_O. exact (H (Ndiv2 a) (Ndiv2 a') y y'). + intros. simpl in |- *. case (Nbit0 a); reflexivity. Qed. Lemma MapCard_Put_sum : @@ -177,17 +176,17 @@ Section MapCard. 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. + intros a y m' a0 y0 n n' H H0 H1. simpl in H. elim (Ndiscr (Nxor 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 (sumbool_of_bool (Nbit0 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)) ( + (H0 (MapPut A m1 (Ndiv2 a) y) (Ndiv2 a) y ( + MapCard A m1) (MapCard A (MapPut A m1 (Ndiv2 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. @@ -196,8 +195,8 @@ Section MapCard. 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)) ( + (H (MapPut A m0 (Ndiv2 a) y) (Ndiv2 a) y ( + MapCard A m0) (MapCard A (MapPut A m0 (Ndiv2 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. @@ -233,35 +232,35 @@ Section MapCard. 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}. + {y : A | MapGet A m a = Some 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 a y a0 y0 H. simpl in H. elim (Ndiscr (Nxor 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)). + intro H0. rewrite H0 in H. rewrite (Nxor_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 (Nbit0 a)). + intro H2. rewrite H2 in H1. simpl in H1. elim (H0 (Ndiv2 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)) + (plus_comm (MapCard A (MapPut A m0 (Ndiv2 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. + elim (H (Ndiv2 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. + MapCard A (MapPut A m a y) = S (MapCard A m) -> MapGet A m a = None. 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. + intros. simpl in H. elim (sumbool_of_bool (Neqb a a1)). intro H0. + rewrite (Neqb_complete _ _ H0) in H. rewrite (Nxor_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). + intros. elim (sumbool_of_bool (Nbit0 a)). intro H2. + rewrite (MapGet_M2_bit_0_1 A a H2 m0 m1). apply (H0 (Ndiv2 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. @@ -269,11 +268,11 @@ Section MapCard. 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). + intro H2. rewrite (MapGet_M2_bit_0_0 A a H2 m0 m1). apply (H (Ndiv2 a) y). cut - (MapCard A (MapPut A m0 (ad_div_2 a) y) + MapCard A m1 = + (MapCard A (MapPut A m0 (Ndiv2 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)) + intro. rewrite (plus_comm (MapCard A (MapPut A m0 (Ndiv2 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. @@ -284,7 +283,7 @@ Section MapCard. 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. + MapGet A m a = Some y -> MapCard A (MapPut A m a y') = MapCard A m. Proof. intros. elim @@ -297,7 +296,7 @@ Section MapCard. 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). + MapGet A m a = None -> MapCard A (MapPut A m a y) = S (MapCard A m). Proof. intros. elim @@ -331,10 +330,10 @@ Section MapCard. 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 a y a0 y0. simpl in |- *. elim (Ndiscr (Nxor 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 H. rewrite H. rewrite (Nxor_eq _ _ H). reflexivity. + intros. simpl in |- *. elim (Ndiscr 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. @@ -370,27 +369,27 @@ Section MapCard. 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. + simpl in |- *. intros. elim (sumbool_of_bool (Neqb 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. + intros. simpl in H1. simpl in H2. elim (sumbool_of_bool (Nbit0 a)). intro H4. rewrite H4 in H1. rewrite H1 in H3. - rewrite (MapCard_makeM2 m0 (MapRemove A m1 (ad_div_2 a))) in H3. + rewrite (MapCard_makeM2 m0 (MapRemove A m1 (Ndiv2 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))) + (H0 (MapRemove A m1 (Ndiv2 a)) (Ndiv2 a) ( + MapCard A m1) (MapCard A (MapRemove A m1 (Ndiv2 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)))) + (plus_Snm_nSm (MapCard A m0) (MapCard A (MapRemove A m1 (Ndiv2 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. + rewrite (MapCard_makeM2 (MapRemove A m0 (Ndiv2 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))) + (H (MapRemove A m0 (Ndiv2 a)) (Ndiv2 a) ( + MapCard A m0) (MapCard A (MapRemove A m0 (Ndiv2 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. @@ -422,20 +421,20 @@ Section MapCard. 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. + MapCard A (MapRemove A m a) = MapCard A m -> MapGet A m a = None. Proof. simple induction m. trivial. - simpl in |- *. intros a y a0 H. elim (sumbool_of_bool (ad_eq a a0)). intro H0. + simpl in |- *. intros a y a0 H. elim (sumbool_of_bool (Neqb 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. + intros. simpl in H1. elim (sumbool_of_bool (Nbit0 a)). intro H2. rewrite H2 in H1. + rewrite (MapCard_makeM2 m0 (MapRemove A m1 (Ndiv2 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 (MapCard_makeM2 (MapRemove A m0 (Ndiv2 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)) + (plus_comm (MapCard A (MapRemove A m0 (Ndiv2 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. @@ -443,36 +442,36 @@ Section MapCard. 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}. + {y : A | MapGet A m a = Some 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). + intros a y a0 H. simpl in H. elim (sumbool_of_bool (Neqb a a0)). intro H0. + rewrite (Neqb_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. + intros. simpl in H1. elim (sumbool_of_bool (Nbit0 a)). intro H2. rewrite H2 in H1. + rewrite (MapCard_makeM2 m0 (MapRemove A m1 (Ndiv2 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)) = + (S (MapCard A m0) + MapCard A (MapRemove A m1 (Ndiv2 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)))) + (plus_Snm_nSm (MapCard A m0) (MapCard A (MapRemove A m1 (Ndiv2 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. + rewrite (MapCard_makeM2 (MapRemove A m0 (Ndiv2 a)) m1) in H1. change - (S (MapCard A (MapRemove A m0 (ad_div_2 a))) + MapCard A m1 = + (S (MapCard A (MapRemove A m0 (Ndiv2 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)) + (plus_comm (S (MapCard A (MapRemove A m0 (Ndiv2 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. + MapGet A m a = None -> MapCard A (MapRemove A m a) = MapCard A m. Proof. intros. elim @@ -486,7 +485,7 @@ Section MapCard. 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. + MapGet A m a = Some y -> S (MapCard A (MapRemove A m a)) = MapCard A m. Proof. intros. elim @@ -577,20 +576,20 @@ Section MapCard. 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. + simpl in |- *. intros. elim (sumbool_of_bool (Neqb a a1)). intro H2. + rewrite (Neqb_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. + unfold MapGet at 2 in |- *. intros. elim (sumbool_of_bool (Neqb a a0)). intro H4. + rewrite <- (Neqb_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. + intros. unfold MapDisjoint in |- *. intros. elim (sumbool_of_bool (Nbit0 a)). intro H6. + unfold MapDisjoint in H0. apply H0 with (m' := m3) (a := Ndiv2 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). @@ -606,7 +605,7 @@ Section MapCard. 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. + intro H6. unfold MapDisjoint in H. apply H with (m' := m2) (a := Ndiv2 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). @@ -637,15 +636,15 @@ Section MapCard. 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. + elim (H _ (sym_eq H3)). intros a H4. split with (Ndouble a). unfold in_dom in |- *. + rewrite (MapGet_M2_bit_0_0 A (Ndouble a) (Ndouble_bit0 a) m0 m1). + rewrite (Ndouble_div2 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 |- *. + split with (Ndouble_plus_one a). unfold in_dom in |- *. rewrite - (MapGet_M2_bit_0_1 A (ad_double_plus_un a) (ad_double_plus_un_bit_0 a) + (MapGet_M2_bit_0_1 A (Ndouble_plus_one a) (Ndouble_plus_one_bit0 a) m0 m1). - rewrite (ad_double_plus_un_div_2 a). elim (in_dom_some _ _ _ H3). intros y H4. rewrite H4. + rewrite (Ndouble_plus_one_div2 a). elim (in_dom_some _ _ _ H3). intros y H4. rewrite H4. reflexivity. Qed. @@ -675,11 +674,11 @@ Section MapCard2. 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). + elim (sumbool_of_bool (Neqb a a0)). intro H7. rewrite H7. rewrite <- (Neqb_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). + elim (sumbool_of_bool (Neqb a a0)). intro H7. rewrite H7. rewrite <- (Neqb_complete _ _ H7). apply sym_eq. assumption. intro H7. rewrite H7. rewrite (MapRemove_semantics A m a a0). rewrite H7. reflexivity. Qed. @@ -695,8 +694,9 @@ Section MapCard2. 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. + intros a y. unfold MapDomRestrTo in |- *. case (MapGet A (M2 A m0 m1) a). simpl in |- *. intro. simpl in |- *. apply le_n. + apply le_O_n. intros. simpl in |- *. rewrite (MapCard_makeM2 A (MapDomRestrTo A B m0 m2) (MapDomRestrTo A B m1 m3)) . |