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diff --git a/theories7/IntMap/Lsort.v b/theories7/IntMap/Lsort.v deleted file mode 100644 index 31b71c62..00000000 --- a/theories7/IntMap/Lsort.v +++ /dev/null @@ -1,537 +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: Lsort.v,v 1.1.2.1 2004/07/16 19:31:27 herbelin Exp $ i*) - -Require Bool. -Require Sumbool. -Require Arith. -Require ZArith. -Require Addr. -Require Adist. -Require Addec. -Require Map. -Require PolyList. -Require Mapiter. - -Section LSort. - - Variable A : Set. - - Fixpoint ad_less_1 [a,a':ad; p:positive] : bool := - Cases p of - (xO p') => (ad_less_1 (ad_div_2 a) (ad_div_2 a') p') - | _ => (andb (negb (ad_bit_0 a)) (ad_bit_0 a')) - end. - - Definition ad_less := [a,a':ad] Cases (ad_xor a a') of - ad_z => false - | (ad_x p) => (ad_less_1 a a' p) - end. - - Lemma ad_bit_0_less : (a,a':ad) (ad_bit_0 a)=false -> (ad_bit_0 a')=true -> - (ad_less a a')=true. - Proof. - Intros. Elim (ad_sum (ad_xor a a')). Intro H1. Elim H1. Intros p H2. Unfold ad_less. - Rewrite H2. Generalize H2. Elim p. Intros. Simpl. Rewrite H. Rewrite H0. Reflexivity. - Intros. Cut (ad_bit_0 (ad_xor a a'))=false. Intro. Rewrite (ad_xor_bit_0 a a') in H5. - Rewrite H in H5. Rewrite H0 in H5. Discriminate H5. - Rewrite H4. Reflexivity. - Intro. Simpl. Rewrite H. Rewrite H0. Reflexivity. - Intro H1. Cut (ad_bit_0 (ad_xor a a'))=false. Intro. Rewrite (ad_xor_bit_0 a a') in H2. - Rewrite H in H2. Rewrite H0 in H2. Discriminate H2. - Rewrite H1. Reflexivity. - Qed. - - Lemma ad_bit_0_gt : (a,a':ad) (ad_bit_0 a)=true -> (ad_bit_0 a')=false -> - (ad_less a a')=false. - Proof. - Intros. Elim (ad_sum (ad_xor a a')). Intro H1. Elim H1. Intros p H2. Unfold ad_less. - Rewrite H2. Generalize H2. Elim p. Intros. Simpl. Rewrite H. Rewrite H0. Reflexivity. - Intros. Cut (ad_bit_0 (ad_xor a a'))=false. Intro. Rewrite (ad_xor_bit_0 a a') in H5. - Rewrite H in H5. Rewrite H0 in H5. Discriminate H5. - Rewrite H4. Reflexivity. - Intro. Simpl. Rewrite H. Rewrite H0. Reflexivity. - Intro H1. Unfold ad_less. Rewrite H1. Reflexivity. - Qed. - - Lemma ad_less_not_refl : (a:ad) (ad_less a a)=false. - Proof. - Intro. Unfold ad_less. Rewrite (ad_xor_nilpotent a). Reflexivity. - Qed. - - Lemma ad_ind_double : - (a:ad)(P:ad->Prop) (P ad_z) -> - ((a:ad) (P a) -> (P (ad_double a))) -> - ((a:ad) (P a) -> (P (ad_double_plus_un a))) -> (P a). - Proof. - Intros; Elim a. Trivial. - Induction p. Intros. - Apply (H1 (ad_x p0)); Trivial. - Intros; Apply (H0 (ad_x p0)); Trivial. - Intros; Apply (H1 ad_z); Assumption. - Qed. - - Lemma ad_rec_double : - (a:ad)(P:ad->Set) (P ad_z) -> - ((a:ad) (P a) -> (P (ad_double a))) -> - ((a:ad) (P a) -> (P (ad_double_plus_un a))) -> (P a). - Proof. - Intros; Elim a. Trivial. - Induction p. Intros. - Apply (H1 (ad_x p0)); Trivial. - Intros; Apply (H0 (ad_x p0)); Trivial. - Intros; Apply (H1 ad_z); Assumption. - Qed. - - Lemma ad_less_def_1 : (a,a':ad) (ad_less (ad_double a) (ad_double a'))=(ad_less a a'). - Proof. - Induction a. Induction a'. Reflexivity. - Trivial. - Induction a'. Unfold ad_less. Simpl. (Elim p; Trivial). - Unfold ad_less. Simpl. Intro. Case (p_xor p p0). Reflexivity. - Trivial. - Qed. - - Lemma ad_less_def_2 : (a,a':ad) - (ad_less (ad_double_plus_un a) (ad_double_plus_un a'))=(ad_less a a'). - Proof. - Induction a. Induction a'. Reflexivity. - Trivial. - Induction a'. Unfold ad_less. Simpl. (Elim p; Trivial). - Unfold ad_less. Simpl. Intro. Case (p_xor p p0). Reflexivity. - Trivial. - Qed. - - Lemma ad_less_def_3 : (a,a':ad) (ad_less (ad_double a) (ad_double_plus_un a'))=true. - Proof. - Intros. Apply ad_bit_0_less. Apply ad_double_bit_0. - Apply ad_double_plus_un_bit_0. - Qed. - - Lemma ad_less_def_4 : (a,a':ad) (ad_less (ad_double_plus_un a) (ad_double a'))=false. - Proof. - Intros. Apply ad_bit_0_gt. Apply ad_double_plus_un_bit_0. - Apply ad_double_bit_0. - Qed. - - Lemma ad_less_z : (a:ad) (ad_less a ad_z)=false. - Proof. - Induction a. Reflexivity. - Unfold ad_less. Intro. Rewrite (ad_xor_neutral_right (ad_x p)). (Elim p; Trivial). - Qed. - - Lemma ad_z_less_1 : (a:ad) (ad_less ad_z a)=true -> {p:positive | a=(ad_x p)}. - Proof. - Induction a. Intro. Discriminate H. - Intros. Split with p. Reflexivity. - Qed. - - Lemma ad_z_less_2 : (a:ad) (ad_less ad_z a)=false -> a=ad_z. - Proof. - Induction a. Trivial. - Unfold ad_less. Simpl. Cut (p:positive)(ad_less_1 ad_z (ad_x p) p)=false->False. - Intros. Elim (H p H0). - Induction p. Intros. Discriminate H0. - Intros. Exact (H H0). - Intro. Discriminate H. - Qed. - - Lemma ad_less_trans : (a,a',a'':ad) - (ad_less a a')=true -> (ad_less a' a'')=true -> (ad_less a a'')=true. - Proof. - Intro a. Apply ad_ind_double with P:=[a:ad] - (a',a'':ad) - (ad_less a a')=true - ->(ad_less a' a'')=true->(ad_less a a'')=true. - Intros. Elim (sumbool_of_bool (ad_less ad_z a'')). Trivial. - Intro H1. Rewrite (ad_z_less_2 a'' H1) in H0. Rewrite (ad_less_z a') in H0. Discriminate H0. - Intros a0 H a'. Apply ad_ind_double with P:=[a':ad] - (a'':ad) - (ad_less (ad_double a0) a')=true - ->(ad_less a' a'')=true->(ad_less (ad_double a0) a'')=true. - Intros. Rewrite (ad_less_z (ad_double a0)) in H0. Discriminate H0. - Intros a1 H0 a'' H1. Rewrite (ad_less_def_1 a0 a1) in H1. - Apply ad_ind_double with P:=[a'':ad] - (ad_less (ad_double a1) a'')=true - ->(ad_less (ad_double a0) a'')=true. - Intro. Rewrite (ad_less_z (ad_double a1)) in H2. Discriminate H2. - Intros. Rewrite (ad_less_def_1 a1 a2) in H3. Rewrite (ad_less_def_1 a0 a2). - Exact (H a1 a2 H1 H3). - Intros. Apply ad_less_def_3. - Intros a1 H0 a'' H1. Apply ad_ind_double with P:=[a'':ad] - (ad_less (ad_double_plus_un a1) a'')=true - ->(ad_less (ad_double a0) a'')=true. - Intro. Rewrite (ad_less_z (ad_double_plus_un a1)) in H2. Discriminate H2. - Intros. Rewrite (ad_less_def_4 a1 a2) in H3. Discriminate H3. - Intros. Apply ad_less_def_3. - Intros a0 H a'. Apply ad_ind_double with P:=[a':ad] - (a'':ad) - (ad_less (ad_double_plus_un a0) a')=true - ->(ad_less a' a'')=true - ->(ad_less (ad_double_plus_un a0) a'')=true. - Intros. Rewrite (ad_less_z (ad_double_plus_un a0)) in H0. Discriminate H0. - Intros. Rewrite (ad_less_def_4 a0 a1) in H1. Discriminate H1. - Intros a1 H0 a'' H1. Apply ad_ind_double with P:=[a'':ad] - (ad_less (ad_double_plus_un a1) a'')=true - ->(ad_less (ad_double_plus_un a0) a'')=true. - Intro. Rewrite (ad_less_z (ad_double_plus_un a1)) in H2. Discriminate H2. - Intros. Rewrite (ad_less_def_4 a1 a2) in H3. Discriminate H3. - Rewrite (ad_less_def_2 a0 a1) in H1. Intros. Rewrite (ad_less_def_2 a1 a2) in H3. - Rewrite (ad_less_def_2 a0 a2). Exact (H a1 a2 H1 H3). - Qed. - - Fixpoint alist_sorted [l:(alist A)] : bool := - Cases l of - nil => true - | (cons (a, _) l') => Cases l' of - nil => true - | (cons (a', y') l'') => (andb (ad_less a a') - (alist_sorted l')) - end - end. - - Fixpoint alist_nth_ad [n:nat; l:(alist A)] : ad := - Cases l of - nil => ad_z (* dummy *) - | (cons (a, y) l') => Cases n of - O => a - | (S n') => (alist_nth_ad n' l') - end - end. - - Definition alist_sorted_1 := [l:(alist A)] - (n:nat) (le (S (S n)) (length l)) -> - (ad_less (alist_nth_ad n l) (alist_nth_ad (S n) l))=true. - - Lemma alist_sorted_imp_1 : (l:(alist A)) (alist_sorted l)=true -> (alist_sorted_1 l). - Proof. - Unfold alist_sorted_1. Induction l. Intros. Elim (le_Sn_O (S n) H0). - Intro r. Elim r. Intros a y. Induction l0. Intros. Simpl in H1. - Elim (le_Sn_O n (le_S_n (S n) O H1)). - Intro r0. Elim r0. Intros a0 y0. Induction n. Intros. Simpl. Simpl in H1. - Exact (proj1 ? ? (andb_prop ? ? H1)). - Intros. Change (ad_less (alist_nth_ad n0 (cons (a0,y0) l1)) - (alist_nth_ad (S n0) (cons (a0,y0) l1)))=true. - Apply H0. Exact (proj2 ? ? (andb_prop ? ? H1)). - Apply le_S_n. Exact H3. - Qed. - - Definition alist_sorted_2 := [l:(alist A)] - (m,n:nat) (lt m n) -> (le (S n) (length l)) -> - (ad_less (alist_nth_ad m l) (alist_nth_ad n l))=true. - - Lemma alist_sorted_1_imp_2 : (l:(alist A)) (alist_sorted_1 l) -> (alist_sorted_2 l). - Proof. - Unfold alist_sorted_1 alist_sorted_2 lt. Intros l H m n H0. Elim H0. Exact (H m). - Intros. Apply ad_less_trans with a':=(alist_nth_ad m0 l). Apply H2. Apply le_trans_S. - Assumption. - Apply H. Assumption. - Qed. - - Lemma alist_sorted_2_imp : (l:(alist A)) (alist_sorted_2 l) -> (alist_sorted l)=true. - Proof. - Unfold alist_sorted_2 lt. Induction l. Trivial. - Intro r. Elim r. Intros a y. Induction l0. Trivial. - Intro r0. Elim r0. Intros a0 y0. Intros. - Change (andb (ad_less a a0) (alist_sorted (cons (a0,y0) l1)))=true. - Apply andb_true_intro. Split. Apply (H1 (0) (1)). Apply le_n. - Simpl. Apply le_n_S. Apply le_n_S. Apply le_O_n. - Apply H0. Intros. Apply (H1 (S m) (S n)). Apply le_n_S. Assumption. - Exact (le_n_S ? ? H3). - Qed. - - Lemma app_length : (C:Set) (l,l':(list C)) (length (app l l'))=(plus (length l) (length l')). - Proof. - Induction l. Trivial. - Intros. Simpl. Rewrite (H l'). Reflexivity. - Qed. - - Lemma aapp_length : (l,l':(alist A)) (length (aapp A l l'))=(plus (length l) (length l')). - Proof. - Exact (app_length ad*A). - Qed. - - Lemma alist_nth_ad_aapp_1 : (l,l':(alist A)) (n:nat) - (le (S n) (length l)) -> (alist_nth_ad n (aapp A l l'))=(alist_nth_ad n l). - Proof. - Induction l. Intros. Elim (le_Sn_O n H). - Intro r. Elim r. Intros a y l' H l''. Induction n. Trivial. - Intros. Simpl. Apply H. Apply le_S_n. Exact H1. - Qed. - - Lemma alist_nth_ad_aapp_2 : (l,l':(alist A)) (n:nat) - (le (S n) (length l')) -> - (alist_nth_ad (plus (length l) n) (aapp A l l'))=(alist_nth_ad n l'). - Proof. - Induction l. Trivial. - Intro r. Elim r. Intros a y l' H l'' n H0. Simpl. Apply H. Exact H0. - Qed. - - Lemma interval_split : (p,q,n:nat) (le (S n) (plus p q)) -> - {n' : nat | (le (S n') q) /\ n=(plus p n')}+{(le (S n) p)}. - Proof. - Induction p. Simpl. Intros. Left . Split with n. (Split; [ Assumption | Reflexivity ]). - Intros p' H q. Induction n. Intros. Right . Apply le_n_S. Apply le_O_n. - Intros. Elim (H ? ? (le_S_n ? ? H1)). Intro H2. Left . Elim H2. Intros n' H3. - Elim H3. Intros H4 H5. Split with n'. (Split; [ Assumption | Rewrite H5; Reflexivity ]). - Intro H2. Right . Apply le_n_S. Assumption. - Qed. - - Lemma alist_conc_sorted : (l,l':(alist A)) (alist_sorted_2 l) -> (alist_sorted_2 l') -> - ((n,n':nat) (le (S n) (length l)) -> (le (S n') (length l')) -> - (ad_less (alist_nth_ad n l) (alist_nth_ad n' l'))=true) -> - (alist_sorted_2 (aapp A l l')). - Proof. - Unfold alist_sorted_2 lt. Intros. Rewrite (aapp_length l l') in H3. - Elim (interval_split (length l) (length l') m - (le_trans ? ? ? (le_n_S ? ? (lt_le_weak m n H2)) H3)). - Intro H4. Elim H4. Intros m' H5. Elim H5. Intros. Rewrite H7. - Rewrite (alist_nth_ad_aapp_2 l l' m' H6). Elim (interval_split (length l) (length l') n H3). - Intro H8. Elim H8. Intros n' H9. Elim H9. Intros. Rewrite H11. - Rewrite (alist_nth_ad_aapp_2 l l' n' H10). Apply H0. Rewrite H7 in H2. Rewrite H11 in H2. - Change (le (plus (S (length l)) m') (plus (length l) n')) in H2. - Rewrite (plus_Snm_nSm (length l) m') in H2. Exact (simpl_le_plus_l (length l) (S m') n' H2). - Exact H10. - Intro H8. Rewrite H7 in H2. Cut (le (S (length l)) (length l)). Intros. Elim (le_Sn_n ? H9). - Apply le_trans with m:=(S n). Apply le_n_S. Apply le_trans with m:=(S (plus (length l) m')). - Apply le_trans with m:=(plus (length l) m'). Apply le_plus_l. - Apply le_n_Sn. - Exact H2. - Exact H8. - Intro H4. Rewrite (alist_nth_ad_aapp_1 l l' m H4). - Elim (interval_split (length l) (length l') n H3). Intro H5. Elim H5. Intros n' H6. Elim H6. - Intros. Rewrite H8. Rewrite (alist_nth_ad_aapp_2 l l' n' H7). Exact (H1 m n' H4 H7). - Intro H5. Rewrite (alist_nth_ad_aapp_1 l l' n H5). Exact (H m n H2 H5). - Qed. - - Lemma alist_nth_ad_semantics : (l:(alist A)) (n:nat) (le (S n) (length l)) -> - {y:A | (alist_semantics A l (alist_nth_ad n l))=(SOME A y)}. - Proof. - Induction l. Intros. Elim (le_Sn_O ? H). - Intro r. Elim r. Intros a y l0 H. Induction n. Simpl. Intro. Split with y. - Rewrite (ad_eq_correct a). Reflexivity. - Intros. Elim (H ? (le_S_n ? ? H1)). Intros y0 H2. - Elim (sumbool_of_bool (ad_eq a (alist_nth_ad n0 l0))). Intro H3. Split with y. - Rewrite (ad_eq_complete ? ? H3). Simpl. Rewrite (ad_eq_correct (alist_nth_ad n0 l0)). - Reflexivity. - Intro H3. Split with y0. Simpl. Rewrite H3. Assumption. - Qed. - - Lemma alist_of_Map_nth_ad : (m:(Map A)) (pf:ad->ad) - (l:(alist A)) l=(MapFold1 A (alist A) (anil A) (aapp A) - [a0:ad][y:A](acons A (a0,y) (anil A)) pf m) -> - (n:nat) (le (S n) (length l)) -> {a':ad | (alist_nth_ad n l)=(pf a')}. - Proof. - Intros. Elim (alist_nth_ad_semantics l n H0). Intros y H1. - Apply (alist_of_Map_semantics_1_1 A m pf (alist_nth_ad n l) y). - Rewrite <- H. Assumption. - Qed. - - Definition ad_monotonic := [pf:ad->ad] (a,a':ad) - (ad_less a a')=true -> (ad_less (pf a) (pf a'))=true. - - Lemma ad_double_monotonic : (ad_monotonic ad_double). - Proof. - Unfold ad_monotonic. Intros. Rewrite ad_less_def_1. Assumption. - Qed. - - Lemma ad_double_plus_un_monotonic : (ad_monotonic ad_double_plus_un). - Proof. - Unfold ad_monotonic. Intros. Rewrite ad_less_def_2. Assumption. - Qed. - - Lemma ad_comp_monotonic : (pf,pf':ad->ad) (ad_monotonic pf) -> (ad_monotonic pf') -> - (ad_monotonic [a0:ad] (pf (pf' a0))). - Proof. - Unfold ad_monotonic. Intros. Apply H. Apply H0. Exact H1. - Qed. - - Lemma ad_comp_double_monotonic : (pf:ad->ad) (ad_monotonic pf) -> - (ad_monotonic [a0:ad] (pf (ad_double a0))). - Proof. - Intros. Apply ad_comp_monotonic. Assumption. - Exact ad_double_monotonic. - Qed. - - Lemma ad_comp_double_plus_un_monotonic : (pf:ad->ad) (ad_monotonic pf) -> - (ad_monotonic [a0:ad] (pf (ad_double_plus_un a0))). - Proof. - Intros. Apply ad_comp_monotonic. Assumption. - Exact ad_double_plus_un_monotonic. - Qed. - - Lemma alist_of_Map_sorts_1 : (m:(Map A)) (pf:ad->ad) (ad_monotonic pf) -> - (alist_sorted_2 (MapFold1 A (alist A) (anil A) (aapp A) - [a:ad][y:A](acons A (a,y) (anil A)) pf m)). - Proof. - Induction m. Simpl. Intros. Apply alist_sorted_1_imp_2. Apply alist_sorted_imp_1. Reflexivity. - Intros. Simpl. Apply alist_sorted_1_imp_2. Apply alist_sorted_imp_1. Reflexivity. - Intros. Simpl. Apply alist_conc_sorted. - Exact (H [a0:ad](pf (ad_double a0)) (ad_comp_double_monotonic pf H1)). - Exact (H0 [a0:ad](pf (ad_double_plus_un a0)) (ad_comp_double_plus_un_monotonic pf H1)). - Intros. Elim (alist_of_Map_nth_ad m0 [a0:ad](pf (ad_double a0)) - (MapFold1 A (alist A) (anil A) (aapp A) - [a0:ad][y:A](acons A (a0,y) (anil A)) - [a0:ad](pf (ad_double a0)) m0) (refl_equal ? ?) n H2). - Intros a H4. Rewrite H4. Elim (alist_of_Map_nth_ad m1 [a0:ad](pf (ad_double_plus_un a0)) - (MapFold1 A (alist A) (anil A) (aapp A) - [a0:ad][y:A](acons A (a0,y) (anil A)) - [a0:ad](pf (ad_double_plus_un a0)) m1) (refl_equal ? ?) n' H3). - Intros a' H5. Rewrite H5. Unfold ad_monotonic in H1. Apply H1. Apply ad_less_def_3. - Qed. - - Lemma alist_of_Map_sorts : (m:(Map A)) (alist_sorted (alist_of_Map A m))=true. - Proof. - Intro. Apply alist_sorted_2_imp. - Exact (alist_of_Map_sorts_1 m [a0:ad]a0 [a,a':ad][p:(ad_less a a')=true]p). - Qed. - - Lemma alist_of_Map_sorts1 : (m:(Map A)) (alist_sorted_1 (alist_of_Map A m)). - Proof. - Intro. Apply alist_sorted_imp_1. Apply alist_of_Map_sorts. - Qed. - - Lemma alist_of_Map_sorts2 : (m:(Map A)) (alist_sorted_2 (alist_of_Map A m)). - Proof. - Intro. Apply alist_sorted_1_imp_2. Apply alist_of_Map_sorts1. - Qed. - - Lemma ad_less_total : (a,a':ad) {(ad_less a a')=true}+{(ad_less a' a)=true}+{a=a'}. - Proof. - Intro a. Refine (ad_rec_double a [a:ad] (a':ad){(ad_less a a')=true}+{(ad_less a' a)=true}+{a=a'} - ? ? ?). - Intro. Elim (sumbool_of_bool (ad_less ad_z a')). Intro H. Left . Left . Assumption. - Intro H. Right . Rewrite (ad_z_less_2 a' H). Reflexivity. - Intros a0 H a'. Refine (ad_rec_double a' [a':ad] {(ad_less (ad_double a0) a')=true} - +{(ad_less a' (ad_double a0))=true}+{(ad_double a0)=a'} ? ? ?). - Elim (sumbool_of_bool (ad_less ad_z (ad_double a0))). Intro H0. Left . Right . Assumption. - Intro H0. Right . Exact (ad_z_less_2 ? H0). - Intros a1 H0. Rewrite ad_less_def_1. Rewrite ad_less_def_1. Elim (H a1). Intro H1. - Left . Assumption. - Intro H1. Right . Rewrite H1. Reflexivity. - Intros a1 H0. Left . Left . Apply ad_less_def_3. - Intros a0 H a'. Refine (ad_rec_double a' [a':ad] {(ad_less (ad_double_plus_un a0) a')=true} - +{(ad_less a' (ad_double_plus_un a0))=true} - +{(ad_double_plus_un a0)=a'} ? ? ?). - Left . Right . (Case a0; Reflexivity). - Intros a1 H0. Left . Right . Apply ad_less_def_3. - Intros a1 H0. Rewrite ad_less_def_2. Rewrite ad_less_def_2. Elim (H a1). Intro H1. - Left . Assumption. - Intro H1. Right . Rewrite H1. Reflexivity. - Qed. - - Lemma alist_too_low : (l:(alist A)) (a,a':ad) (y:A) - (ad_less a a')=true -> (alist_sorted_2 (cons (a',y) l)) -> - (alist_semantics A (cons (a',y) l) a)=(NONE A). - Proof. - Induction l. Intros. Simpl. Elim (sumbool_of_bool (ad_eq a' a)). Intro H1. - Rewrite (ad_eq_complete ? ? H1) in H. Rewrite (ad_less_not_refl a) in H. Discriminate H. - Intro H1. Rewrite H1. Reflexivity. - Intro r. Elim r. Intros a y l0 H a0 a1 y0 H0 H1. - Change (Case (ad_eq a1 a0) of - (SOME A y0) - (alist_semantics A (cons (a,y) l0) a0) - end)=(NONE A). - Elim (sumbool_of_bool (ad_eq a1 a0)). Intro H2. Rewrite (ad_eq_complete ? ? H2) in H0. - Rewrite (ad_less_not_refl a0) in H0. Discriminate H0. - Intro H2. Rewrite H2. Apply H. Apply ad_less_trans with a':=a1. Assumption. - Unfold alist_sorted_2 in H1. Apply (H1 (0) (1)). Apply lt_n_Sn. - Simpl. Apply le_n_S. Apply le_n_S. Apply le_O_n. - Apply alist_sorted_1_imp_2. Apply alist_sorted_imp_1. - Cut (alist_sorted (cons (a1,y0) (cons (a,y) l0)))=true. Intro H3. - Exact (proj2 ? ? (andb_prop ? ? H3)). - Apply alist_sorted_2_imp. Assumption. - Qed. - - Lemma alist_semantics_nth_ad : (l:(alist A)) (a:ad) (y:A) - (alist_semantics A l a)=(SOME A y) -> - {n:nat | (le (S n) (length l)) /\ (alist_nth_ad n l)=a}. - Proof. - Induction l. Intros. Discriminate H. - Intro r. Elim r. Intros a y l0 H a0 y0 H0. Simpl in H0. Elim (sumbool_of_bool (ad_eq a a0)). - Intro H1. Rewrite H1 in H0. Split with O. Split. Simpl. Apply le_n_S. Apply le_O_n. - Simpl. Exact (ad_eq_complete ? ? H1). - Intro H1. Rewrite H1 in H0. Elim (H a0 y0 H0). Intros n' H2. Split with (S n'). Split. - Simpl. Apply le_n_S. Exact (proj1 ? ? H2). - Exact (proj2 ? ? H2). - Qed. - - Lemma alist_semantics_tail : (l:(alist A)) (a:ad) (y:A) - (alist_sorted_2 (cons (a,y) l)) -> - (eqm A (alist_semantics A l) [a0:ad] if (ad_eq a a0) - then (NONE A) - else (alist_semantics A (cons (a,y) l) a0)). - Proof. - Unfold eqm. Intros. Elim (sumbool_of_bool (ad_eq a a0)). Intro H0. Rewrite H0. - Rewrite <- (ad_eq_complete ? ? H0). Unfold alist_sorted_2 in H. - Elim (option_sum A (alist_semantics A l a)). Intro H1. Elim H1. Intros y0 H2. - Elim (alist_semantics_nth_ad l a y0 H2). Intros n H3. Elim H3. Intros. - Cut (ad_less (alist_nth_ad (0) (cons (a,y) l)) (alist_nth_ad (S n) (cons (a,y) l)))=true. - Intro. Simpl in H6. Rewrite H5 in H6. Rewrite (ad_less_not_refl a) in H6. Discriminate H6. - Apply H. Apply lt_O_Sn. - Simpl. Apply le_n_S. Assumption. - Trivial. - Intro H0. Simpl. Rewrite H0. Reflexivity. - Qed. - - Lemma alist_semantics_same_tail : (l,l':(alist A)) (a:ad) (y:A) - (alist_sorted_2 (cons (a,y) l)) -> (alist_sorted_2 (cons (a,y) l')) -> - (eqm A (alist_semantics A (cons (a,y) l)) (alist_semantics A (cons (a,y) l'))) -> - (eqm A (alist_semantics A l) (alist_semantics A l')). - Proof. - Unfold eqm. Intros. Rewrite (alist_semantics_tail ? ? ? H a0). - Rewrite (alist_semantics_tail ? ? ? H0 a0). Case (ad_eq a a0). Reflexivity. - Exact (H1 a0). - Qed. - - Lemma alist_sorted_tail : (l:(alist A)) (a:ad) (y:A) - (alist_sorted_2 (cons (a,y) l)) -> (alist_sorted_2 l). - Proof. - Unfold alist_sorted_2. Intros. Apply (H (S m) (S n)). Apply lt_n_S. Assumption. - Simpl. Apply le_n_S. Assumption. - Qed. - - Lemma alist_canonical : (l,l':(alist A)) - (eqm A (alist_semantics A l) (alist_semantics A l')) -> - (alist_sorted_2 l) -> (alist_sorted_2 l') -> l=l'. - Proof. - Unfold eqm. Induction l. Induction l'. Trivial. - Intro r. Elim r. Intros a y l0 H H0 H1 H2. Simpl in H0. - Cut (NONE A)=(Case (ad_eq a a) of (SOME A y) - (alist_semantics A l0 a) - end). - Rewrite (ad_eq_correct a). Intro. Discriminate H3. - Exact (H0 a). - Intro r. Elim r. Intros a y l0 H. Induction l'. Intros. Simpl in H0. - Cut (Case (ad_eq a a) of (SOME A y) - (alist_semantics A l0 a) - end)=(NONE A). - Rewrite (ad_eq_correct a). Intro. Discriminate H3. - Exact (H0 a). - Intro r'. Elim r'. Intros a' y' l'0 H0 H1 H2 H3. Elim (ad_less_total a a'). Intro H4. - Elim H4. Intro H5. - Cut (alist_semantics A (cons (a,y) l0) a)=(alist_semantics A (cons (a',y') l'0) a). - Intro. Rewrite (alist_too_low l'0 a a' y' H5 H3) in H6. Simpl in H6. - Rewrite (ad_eq_correct a) in H6. Discriminate H6. - Exact (H1 a). - Intro H5. Cut (alist_semantics A (cons (a,y) l0) a')=(alist_semantics A (cons (a',y') l'0) a'). - Intro. Rewrite (alist_too_low l0 a' a y H5 H2) in H6. Simpl in H6. - Rewrite (ad_eq_correct a') in H6. Discriminate H6. - Exact (H1 a'). - Intro H4. Rewrite H4. - Cut (alist_semantics A (cons (a,y) l0) a)=(alist_semantics A (cons (a',y') l'0) a). - Intro. Simpl in H5. Rewrite H4 in H5. Rewrite (ad_eq_correct a') in H5. Inversion H5. - Rewrite H4 in H1. Rewrite H7 in H1. Cut l0=l'0. Intro. Rewrite H6. Reflexivity. - Apply H. Rewrite H4 in H2. Rewrite H7 in H2. - Exact (alist_semantics_same_tail l0 l'0 a' y' H2 H3 H1). - Exact (alist_sorted_tail ? ? ? H2). - Exact (alist_sorted_tail ? ? ? H3). - Exact (H1 a). - Qed. - -End LSort. |