diff options
author | Samuel Mimram <smimram@debian.org> | 2006-04-28 14:59:16 +0000 |
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committer | Samuel Mimram <smimram@debian.org> | 2006-04-28 14:59:16 +0000 |
commit | 3ef7797ef6fc605dfafb32523261fe1b023aeecb (patch) | |
tree | ad89c6bb57ceee608fcba2bb3435b74e0f57919e /theories7/IntMap/Mapcard.v | |
parent | 018ee3b0c2be79eb81b1f65c3f3fa142d24129c8 (diff) |
Imported Upstream version 8.0pl3+8.1alphaupstream/8.0pl3+8.1alpha
Diffstat (limited to 'theories7/IntMap/Mapcard.v')
-rw-r--r-- | theories7/IntMap/Mapcard.v | 670 |
1 files changed, 0 insertions, 670 deletions
diff --git a/theories7/IntMap/Mapcard.v b/theories7/IntMap/Mapcard.v deleted file mode 100644 index 5c5e2a93..00000000 --- a/theories7/IntMap/Mapcard.v +++ /dev/null @@ -1,670 +0,0 @@ -(************************************************************************) -(* 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 1.1.2.1 2004/07/16 19:31:28 herbelin Exp $ i*) - -Require Bool. -Require Sumbool. -Require Arith. -Require ZArith. -Require Addr. -Require Adist. -Require Addec. -Require Map. -Require Mapaxioms. -Require Mapiter. -Require Fset. -Require Mapsubset. -Require PolyList. -Require Lsort. -Require Peano_dec. - -Section MapCard. - - Variable A, B : Set. - - Lemma MapCard_M0 : (MapCard A (M0 A))=O. - Proof. - Trivial. - Qed. - - Lemma MapCard_M1 : (a:ad) (y:A) (MapCard A (M1 A a y))=(1). - Proof. - Trivial. - Qed. - - Lemma MapCard_is_O : (m:(Map A)) (MapCard A m)=O -> - (a:ad) (MapGet A m a)=(NONE A). - Proof. - 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 : (m:(Map A)) (a:ad) (y:A) (MapGet A m a)=(SOME A y) -> - {n:nat | (MapCard A m)=(S n)}. - Proof. - 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 O. - 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. Rewrite H3. Split with (plus (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. Rewrite H3. Split with (plus n (MapCard A m1)). Reflexivity. - Qed. - - Lemma MapCard_is_one : (m:(Map A)) (MapCard A m)=(1) -> - {a:ad & {y:A | (MapGet A m a)=(SOME A y)}}. - Proof. - 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 : (m:(Map A)) (MapCard A m)=(1) -> (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. - 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 : (C:Set) (l:(list C)) - (length l)=(fold_right [_:C][n:nat](S n) O l). - Proof. - Induction l. Reflexivity. - Intros. Simpl. Rewrite H. Reflexivity. - Qed. - - Lemma length_as_fold_2 : (l:(alist A)) - (length l)=(fold_right [r:ad*A][n:nat]let (a,y)=r in (plus (1) n) O l). - Proof. - Induction l. Reflexivity. - Intros. Simpl. Rewrite H. (Elim a; Reflexivity). - Qed. - - Lemma MapCard_as_Fold_1 : (m:(Map A)) (pf:ad->ad) - (MapCard A m)=(MapFold1 A nat O plus [_:ad][_:A](1) pf m). - Proof. - Induction m. Trivial. - Trivial. - Intros. Simpl. Rewrite <- (H [a0:ad](pf (ad_double a0))). - Rewrite <- (H0 [a0:ad](pf (ad_double_plus_un a0))). Reflexivity. - Qed. - - Lemma MapCard_as_Fold : - (m:(Map A)) (MapCard A m)=(MapFold A nat O plus [_:ad][_:A](1) m). - Proof. - Intro. Exact (MapCard_as_Fold_1 m [a0:ad]a0). - Qed. - - Lemma MapCard_as_length : (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:=O f:=[_:ad][_:A](1). Exact plus_assoc_r. - Trivial. - Intro. Rewrite <- plus_n_O. Reflexivity. - Qed. - - Lemma MapCard_Put1_equals_2 : (p:positive) (a,a':ad) (y,y':A) - (MapCard A (MapPut1 A a y a' y' p))=(2). - Proof. - Induction p. Intros. Simpl. (Case (ad_bit_0 a); Reflexivity). - Intros. Simpl. Case (ad_bit_0 a). Exact (H (ad_div_2 a) (ad_div_2 a') y y'). - Simpl. Rewrite <- plus_n_O. Exact (H (ad_div_2 a) (ad_div_2 a') y y'). - Intros. Simpl. (Case (ad_bit_0 a); Reflexivity). - Qed. - - Lemma MapCard_Put_sum : (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. - Induction m. Simpl. 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 : (m:(Map A)) (a:ad) (y:A) - (ge (MapCard A (MapPut A m a y)) (MapCard A m)). - Proof. - Unfold ge. 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 : (m:(Map A)) (a:ad) (y:A) - (le (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 : (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. - 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 (simpl_plus_l ? ? ? 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_sym (MapCard A (MapPut A m0 (ad_div_2 a) y)) (MapCard A m1)) in H1. - Rewrite (plus_sym (MapCard A m0) (MapCard A m1)) in H1. - Elim (H (ad_div_2 a) y (simpl_plus_l ? ? ? 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 : (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. - 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 simpl_plus_l with n:=(MapCard A m0). - Rewrite <- (plus_Snm_nSm (MapCard A m0) (MapCard A m1)). Simpl in H1. Simpl. Rewrite <- H1. - Clear H1. - NewInduction a. Discriminate H2. - NewInduction 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 (plus (MapCard A (MapPut A m0 (ad_div_2 a) y)) (MapCard A m1)) - =(plus (S (MapCard A m0)) (MapCard A m1)). - Intro. Rewrite (plus_sym (MapCard A (MapPut A m0 (ad_div_2 a) y)) (MapCard A m1)) in H3. - Rewrite (plus_sym (S (MapCard A m0)) (MapCard A m1)) in H3. Exact (simpl_plus_l ? ? ? H3). - Simpl. Simpl in H1. Rewrite <- H1. NewInduction a. Trivial. - NewInduction p. Discriminate H2. - Reflexivity. - Discriminate H2. - Qed. - - Lemma MapCard_Put_1_conv : (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 : (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 : (m,m':(Map A)) - (eqm A (MapGet A m) (MapGet A m')) -> (MapCard A m)=(MapCard A m'). - Proof. - Unfold eqm. 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. 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 : (m:(Map A)) (MapCard A m)=(MapCard unit (MapDom A m)). - Proof. - (Induction m; Trivial). Intros. Simpl. Rewrite H. Rewrite H0. Reflexivity. - Qed. - - Lemma MapCard_Dom_Put_behind : (m:(Map A)) (a:ad) (y:A) - (MapDom A (MapPut_behind A m a y))=(MapDom A (MapPut A m a y)). - Proof. - Induction m. Trivial. - Intros a y a0 y0. Simpl. 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. Elim (ad_sum a). Intro H1. Elim H1. Intros p H2. Rewrite H2. Case p. - Intro p0. Simpl. Rewrite H0. Reflexivity. - Intro p0. Simpl. Rewrite H. Reflexivity. - Simpl. Rewrite H0. Reflexivity. - Intro H1. Rewrite H1. Simpl. Rewrite H. Reflexivity. - Qed. - - Lemma MapCard_Put_behind_Put : (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 : (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 : (m,m':(Map A)) - (MapCard A (makeM2 A m m'))=(plus (MapCard A m) (MapCard A m')). - Proof. - Intros. Rewrite (MapCard_ext ? ? (makeM2_M2 A m m')). Reflexivity. - Qed. - - Lemma MapCard_Remove_sum : (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. - Induction m. Simpl. Intros. Rewrite H in H1. Simpl in H1. Left . Rewrite H1. Assumption. - Simpl. 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 : (m:(Map A)) (a:ad) - (le (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 : (m:(Map A)) (a:ad) - (ge (S (MapCard A (MapRemove A m a))) (MapCard A m)). - Proof. - Unfold ge. 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 : (m:(Map A)) (a:ad) - (MapCard A (MapRemove A m a))=(MapCard A m) -> (MapGet A m a)=(NONE A). - Proof. - Induction m. Trivial. - Simpl. 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 (simpl_plus_l ? ? ? 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_sym (MapCard A (MapRemove A m0 (ad_div_2 a))) (MapCard A m1)) in H1. - Rewrite (plus_sym (MapCard A m0) (MapCard A m1)) in H1. Exact (simpl_plus_l ? ? ? H1). - Qed. - - Lemma MapCard_Remove_2 : (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. - 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 (plus (S (MapCard A m0)) (MapCard A (MapRemove A m1 (ad_div_2 a)))) - =(plus (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 (simpl_plus_l ? ? ? 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 (plus (S (MapCard A (MapRemove A m0 (ad_div_2 a)))) (MapCard A m1)) - =(plus (MapCard A m0) (MapCard A m1)) in H1. - Rewrite (plus_sym (S (MapCard A (MapRemove A m0 (ad_div_2 a)))) (MapCard A m1)) in H1. - Rewrite (plus_sym (MapCard A m0) (MapCard A m1)) in H1. Exact (simpl_plus_l ? ? ? H1). - Qed. - - Lemma MapCard_Remove_1_conv : (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 : (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 : (m,m':(Map A)) - (plus (MapCard A m) (MapCard A m'))= - (plus (MapCard A (MapMerge A m m')) (MapCard A (MapDomRestrTo A A m m'))). - Proof. - Induction m. Simpl. Intro. Apply plus_n_O. - Simpl. 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. 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 (plus (plus (MapCard A m0) (MapCard A m1)) (MapCard A m')) - =(plus (MapCard A (MapMerge A (M2 A m0 m1) m')) - (MapCard A (MapDomRestrTo A A (M2 A m0 m1) m'))). - Elim m'. Reflexivity. - Intros a y. Unfold MapMerge. Unfold MapDomRestrTo. - 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. - Rewrite <- (plus_Snm_nSm (plus (MapCard A m0) (MapCard A m1)) O). Reflexivity. - Intros. Simpl. - 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 : (m,m':(Map A)) (MapDisjoint A A m m') -> - (MapCard A (MapMerge A m m'))=(plus (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 : (m:(Map A)) (m':(Map B)) - (MapCard A m)=(plus (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. Apply MapDom_Split_3. - Qed. - - Lemma MapMerge_Card_ub : (m,m':(Map A)) - (le (MapCard A (MapMerge A m m')) (plus (MapCard A m) (MapCard A m'))). - Proof. - Intros. Rewrite MapMerge_Restr_Card. Apply le_plus_l. - Qed. - - Lemma MapDomRestrTo_Card_ub_l : (m:(Map A)) (m':(Map B)) - (le (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 : (m:(Map A)) (m':(Map B)) - (le (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 : (m,m':(Map A)) - (MapCard A (MapMerge A m m'))=(plus (MapCard A m) (MapCard A m')) -> - (MapDisjoint A A m m'). - Proof. - Induction m. Intros. Apply Map_M0_disjoint. - Simpl. Intros. Rewrite (MapCard_Put_behind_Put m' a a0) in H. Unfold MapDisjoint in_dom. - Simpl. 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. - 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 3 MapCard in H1. Rewrite <- (plus_Snm_nSm (MapCard A (M2 A m0 m1)) O) in H1. - Rewrite <- (plus_n_O (S (MapCard A (M2 A m0 m1)))) in H1. Unfold MapDisjoint in_dom. - Unfold 2 MapGet. 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. 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 simpl_le_plus_l with p:=(plus (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))) - =(plus (plus (MapCard A m0) (MapCard A m1)) (plus (MapCard A m2) (MapCard A m3))) in H3. - Rewrite <- H3. Simpl. Apply le_reg_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. 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. 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 simpl_le_plus_l with p:=(plus (MapCard A m1) (MapCard A m3)). - Rewrite (plus_sym (plus (MapCard A m1) (MapCard A m3)) (plus (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_sym (plus (MapCard A m1) (MapCard A m3)) (MapCard A (MapMerge A m0 m2))). - Change (plus (MapCard A (MapMerge A m0 m2)) (MapCard A (MapMerge A m1 m3))) - =(plus (plus (MapCard A m0) (MapCard A m1)) (plus (MapCard A m2) (MapCard A m3))) in H3. - Rewrite <- H3. Apply le_reg_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. 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. Rewrite H7. Reflexivity. - Qed. - - Lemma MapCard_is_Sn : (m:(Map A)) (n:nat) (MapCard ? m)=(S n) -> - {a:ad | (in_dom ? a m)=true}. - Proof. - Induction m. Intros. Discriminate H. - Intros a y n H. Split with a. Unfold in_dom. 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. - 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. - 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. - - Variable A, B : Set. - - Lemma MapSubset_card_eq_1 : (n:nat) (m:(Map A)) (m':(Map B)) - (MapSubset ? ? m m') -> (MapCard ? m)=n -> (MapCard ? m')=n -> - (MapSubset ? ? m' m). - Proof. - Induction n. Intros. Unfold MapSubset in_dom. 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. 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. 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 : (m:(Map A)) (m':(Map B)) - (le (MapCard A (MapDomRestrTo A B m m')) (MapCard B m')). - Proof. - Induction m. Intro. Simpl. Apply le_O_n. - Intros a y m'. Simpl. 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. - Apply le_n_S. Apply le_O_n. - Intro H. Rewrite H. Simpl. Apply le_O_n. - Induction m'. Simpl. Apply le_O_n. - - Intros a y. Unfold MapDomRestrTo. Case (MapGet A (M2 A m0 m1) a). Simpl. Apply le_O_n. - Intro. Simpl. Apply le_n. - Intros. Simpl. Rewrite (MapCard_makeM2 A (MapDomRestrTo A B m0 m2) (MapDomRestrTo A B m1 m3)). - Apply le_plus_plus. Apply H. - Apply H0. - Qed. - -End MapCard2. - -Section MapCard3. - - Variable A, B : Set. - - Lemma MapMerge_Card_lb_l : (m,m':(Map A)) - (ge (MapCard A (MapMerge A m m')) (MapCard A m)). - Proof. - Unfold ge. Intros. Apply (simpl_le_plus_l (MapCard A m')). - Rewrite (plus_sym (MapCard A m') (MapCard A m)). - Rewrite (plus_sym (MapCard A m') (MapCard A (MapMerge A m m'))). - Rewrite (MapMerge_Restr_Card A m m'). Apply le_reg_l. Apply MapDomRestrTo_Card_ub_r. - Qed. - - Lemma MapMerge_Card_lb_r : (m,m':(Map A)) - (ge (MapCard A (MapMerge A m m')) (MapCard A m')). - Proof. - Unfold ge. Intros. Apply (simpl_le_plus_l (MapCard A m)). Rewrite (MapMerge_Restr_Card A m m'). - Rewrite (plus_sym (MapCard A (MapMerge A m m')) (MapCard A (MapDomRestrTo A A m m'))). - Apply le_reg_r. Apply MapDomRestrTo_Card_ub_l. - Qed. - - Lemma MapDomRestrBy_Card_lb : (m:(Map A)) (m':(Map B)) - (ge (plus (MapCard B m') (MapCard A (MapDomRestrBy A B m m'))) (MapCard A m)). - Proof. - Unfold ge. Intros. Rewrite (MapSplit_Card A B m m'). Apply le_reg_r. - Apply MapDomRestrTo_Card_ub_r. - Qed. - - Lemma MapSubset_Card_le : (m:(Map A)) (m':(Map B)) - (MapSubset A B m m') -> (le (MapCard A m) (MapCard B m')). - Proof. - Intros. Apply le_trans with m:=(plus (MapCard B m') (MapCard A (MapDomRestrBy A B m m'))). - Exact (MapDomRestrBy_Card_lb m m'). - Rewrite (MapCard_ext ? ? ? (MapSubset_imp_2 ? ? ? ? H)). Simpl. Rewrite <- plus_n_O. - Apply le_n. - Qed. - - Lemma MapSubset_card_eq : (m:(Map A)) (m':(Map B)) - (MapSubset ? ? m m') -> (le (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. |