(* *)
(**************************************************************************)
-set "baseuri" "cic:/matita/decidable_kit/fintype/".
-
include "decidable_kit/eqtype.ma".
include "decidable_kit/list_aux.ma".
λbound.filter ? ? (if_p nat_eqType (λx.ltb x bound)) (iota O bound).
lemma iota_ltb : ∀x,p:nat. mem nat_eqType x (iota O p) = ltb x p.
-intros (x p); elim p; simplify; [1:reflexivity]
-rewrite < leb_eqb;
-generalize in match (refl_eq ? (cmp ? x n));
-generalize in match (cmp ? x n) in ⊢ (? ? % ? → %); intros 1 (b);
-cases b; simplify; intros (H1); [1: reflexivity]
-rewrite > H; fold simplify (ltb x n); rewrite > H1; reflexivity;
+intros (x p); elim p; simplify;[reflexivity]
+apply (cmpP nat_eqType x n); intros (E); rewrite > H; clear H; simplify;
+[1: symmetry; apply (p2bT ? ? (lebP ? ?)); rewrite > E; apply le_n;
+|2: rewrite < (leb_eqb x n); rewrite > E; reflexivity;]
qed.
lemma mem_filter :
- ∀d1,d2:eqType.(*∀y:d1.*)∀x:d2.∀l:list d1.∀p:d1 → option d2.
+ ∀d1,d2:eqType.∀x:d2.∀l:list d1.∀p:d1 → option d2.
(∀y.mem d1 y l = true →
match (p y) with [None ⇒ false | (Some q) ⇒ cmp d2 x q] = false) →
mem d2 x (filter d1 d2 p l) = false.
intros 5 (d1 d2 x l p);
-elim l; [1: simplify; auto]
-simplify; fold simplify (filter d1 d2 p l1);
-generalize in match (refl_eq ? (p t));
-generalize in match (p t) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
-[1: simplify; intros (Hpt); apply H; intros (y Hyl);
- apply H1; simplify; fold simplify (orb (cmp ? y t) (mem ? y l1));
- rewrite > Hyl; rewrite > orbC; reflexivity;
-|2:simplify; intros (Hpt);
- generalize in match (refl_eq ? (cmp ? x s));
- generalize in match (cmp ? x s) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- [1: simplify; intros (Exs);
- rewrite < (H1 t); [2: simplify; rewrite > cmp_refl; reflexivity;]
- rewrite > Hpt; simplify; symmetry; assumption;
- |2: intros (Dxs); simplify; apply H; intros;
- apply H1; simplify; fold simplify (orb (cmp ? y t) (mem ? y l1));
- rewrite > H2; rewrite > orbC; reflexivity;]]
+elim l; simplify; [reflexivity]
+generalize in match (refl_eq ? (p a));
+generalize in match (p a) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b; intros (Hpt);
+[1: apply H; intros (y Hyl);
+ apply H1; simplify;
+ rewrite > Hyl; rewrite > orbC; reflexivity;
+|2: simplify; apply (cmpP d2 x s); simplify; intros (E);
+ [1: rewrite < (H1 a); simplify; [rewrite > Hpt; rewrite > E]
+ simplify; rewrite > cmp_refl; reflexivity
+ |2: apply H; intros; apply H1; simplify; rewrite > H2;
+ rewrite > orbC; reflexivity]]
qed.
lemma count_O :
∀d:eqType.∀p:d→bool.∀l:list d.
(∀x:d.mem d x l = true → notb (p x) = true) → count d p l = O.
intros 3 (d p l); elim l; simplify; [1: reflexivity]
-fold simplify (count d p l1); (* XXX simplify troppo *)
-generalize in match (refl_eq ? (p t));
-generalize in match (p t) in ⊢ (? ? ? % → %); intros 1 (b);
+generalize in match (refl_eq ? (p a));
+generalize in match (p a) in ⊢ (? ? ? % → %); intros 1 (b);
cases b; simplify;
[2:intros (Hpt); apply H; intros; apply H1; simplify;
- generalize in match (refl_eq ? (cmp d x t));
- generalize in match (cmp d x t) in ⊢ (? ? ? % → %); intros 1 (b1);
- cases b1; simplify; intros; [2:rewrite > H2] auto.
-|1:intros (H2); lapply (H1 t); [2:simplify; rewrite > cmp_refl; simplify; auto]
+ apply (cmpP d x a); [2: rewrite > H2;]; intros; reflexivity;
+|1:intros (H2); lapply (H1 a); [2:simplify; rewrite > cmp_refl; simplify; autobatch]
rewrite > H2 in Hletin; simplify in Hletin; destruct Hletin]
qed.
[ apply (mk_finType fsort enum Hcut)
| intros (x); cases x (n Hn); simplify in Hn; clear x;
generalize in match Hn; generalize in match Hn; clear Hn;
+ unfold enum;
unfold segment_enum;
generalize in match bound in ⊢ (% → ? → ? ? (? ? ? (? ? ? ? %)) ?);
- intros 1 (m); elim m (Hm Hn p IH Hm Hn);
- [ destruct Hm;
- | simplify; cases (eqP bool_eqType (ltb p bound) true); simplify;
- (* XXX simplify che spacca troppo *)
- fold simplify (filter nat_eqType (sigma nat_eqType (λx.ltb x bound))
- (if_p nat_eqType (λx.ltb x bound)) (iota O p));
- [1:unfold segment in ⊢ (? ? match ? % ? ? with [true⇒ ?|false⇒ ?] ?);
- unfold nat_eqType in ⊢ (? ? match % with [true⇒ ?|false⇒ ?] ?);
- simplify in ⊢ (? ? match % with [true⇒ ?|false⇒ ?] ?);
- generalize in match (refl_eq ? (eqb n p));
- generalize in match (eqb n p) in ⊢ (? ? ? % → %); intros 1(b);
- cases b; simplify;
- [2:intros (Enp); rewrite > IH; [1,3: auto]
- rewrite < ltb_n_Sm in Hm; rewrite > Enp in Hm;
- generalize in match Hm; cases (ltb n p); intros; [1:reflexivity]
- simplify in H1; destruct H1;
- |1:clear IH; intros (Enp);
- fold simplify (count fsort (cmp fsort {n, Hn})
- (filter ? (sigma nat_eqType (λx.ltb x bound))
- (if_p nat_eqType (λx.ltb x bound)) (iota O p)));
- rewrite > (count_O fsort); [1: reflexivity]
- intros 1 (x);
- rewrite < (b2pT ? ? (eqP ? n ?) Enp);
- cases x (y Hy); intros (ABS); clear x;
- unfold segment; unfold notb; simplify;
- generalize in match (refl_eq ? (cmp ? n y));
- generalize in match (cmp ? n y) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- intros (Eny); simplify; [2: auto]
- rewrite < ABS; symmetry; clear ABS;
- generalize in match Hy; clear Hy; rewrite < (b2pT ? ? (eqP nat_eqType ? ?) Eny);
- simplify; intros (Hn); fold simplify (iota O n);
- apply (mem_filter nat_eqType fsort);
- intros (w Hw);
- fold simplify (sort nat_eqType);
- cases (in_sub_eq nat_eqType (λx:nat_eqType.ltb x bound) w);
- simplify; [2: reflexivity]
- generalize in match H1; clear H1; cases s; clear s; intros (H1);
- unfold segment; simplify; simplify in H1; rewrite > H1;
- rewrite > iota_ltb in Hw;
- apply (p2bF ? ? (eqP nat_eqType ? ?));
- unfold Not; intros (Enw);
- rewrite > Enw in Hw; rewrite > ltb_refl in Hw; destruct Hw]
- |2:rewrite > IH; [1:reflexivity|3:assumption]
- rewrite < ltb_n_Sm in Hm;
- cases (b2pT ? ?(orbP ? ?) Hm);[1: assumption]
- rewrite > (b2pT ? ? (eqbP ? ?) H1) in Hn;
- rewrite > Hn in H; cases (H ?); reflexivity;
- ]]]
+ intros 1 (m); elim m (Hm Hn p IH Hm Hn); [ simplify in Hm; destruct Hm ]
+ simplify; cases (eqP bool_eqType (ltb p bound) true); simplify;
+ [1:unfold fsort;
+ unfold segment in ⊢ (? ? match ? % ? ? with [_ ⇒ ?|_ ⇒ ?] ?);
+ unfold nat_eqType in ⊢ (? ? match % with [_ ⇒ ?|_ ⇒ ?] ?);
+ simplify; apply (cmpP nat_eqType n p); intros (Enp); simplify;
+ [2:rewrite > IH; [1,3: autobatch]
+ rewrite < ltb_n_Sm in Hm; rewrite > Enp in Hm;
+ rewrite > orbC in Hm; assumption;
+ |1:clear IH; rewrite > (count_O fsort); [reflexivity]
+ intros 1 (x); rewrite < Enp; cases x (y Hy);
+ intros (ABS); clear x; unfold segment; unfold notb; simplify;
+ apply (cmpP ? n y); intros (Eny); simplify; [2:reflexivity]
+ rewrite < ABS; symmetry; clear ABS;
+ generalize in match Hy; clear Hy;rewrite < Eny;
+ simplify; intros (Hn); apply (mem_filter nat_eqType fsort); intros (w Hw);
+ fold simplify (sort nat_eqType); (* CANONICAL?! *)
+ cases (in_sub_eq nat_eqType (λx:nat_eqType.ltb x bound) w);
+ simplify; [2: reflexivity]
+ generalize in match H1; clear H1; cases s (r Pr); clear s; intros (H1);
+ unfold fsort; unfold segment; simplify; simplify in H1; rewrite > H1;
+ rewrite > iota_ltb in Hw; apply (p2bF ? ? (eqP nat_eqType ? ?));
+ unfold Not; intros (Enw); rewrite > Enw in Hw;
+ rewrite > ltb_refl in Hw; destruct Hw]
+ |2:rewrite > IH; [1:reflexivity|3:assumption]
+ rewrite < ltb_n_Sm in Hm;
+ cases (b2pT ? ?(orbP ? ?) Hm);[1: assumption]
+ rewrite > (b2pT ? ? (eqbP ? ?) H1) in Hn;
+ rewrite > Hn in H; cases (H ?); reflexivity]]
qed.
let rec uniq (d:eqType) (l:list d) on l : bool ≝
match l with
- [ nil⇒ true
+ [ nil ⇒ true
| (cons x tl) ⇒ andb (notb (mem d x tl)) (uniq d tl)].
-lemma uniq_tail_OLD : ∀d:eqType.∀x:d.∀l:list d.uniq d (x::l) = true → uniq d l = true.
-intros (d x l Uxl); simplify in Uxl; cases (b2pT ? ? (andbP ? ?) Uxl); assumption;
-qed.
-
lemma uniq_mem : ∀d:eqType.∀x:d.∀l:list d.uniq d (x::l) = true → mem d x l = false.
intros (d x l H); simplify in H; lapply (b2pT ? ? (andbP ? ?) H) as H1; clear H;
cases H1 (H2 H3); lapply (b2pT ? ?(negbP ?) H2); assumption;
lemma uniq_tail :
∀d:eqType.∀x:d.∀l:list d. uniq d (x::l) = andb (negb (mem d x l)) (uniq d l).
-intros (d x l);
-elim l; [1: simplify; reflexivity]
-generalize in match (refl_eq ? (cmp d x t));
-generalize in match (cmp d x t) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
-intros (E); simplify ; rewrite > E; simplify; [1: reflexivity;]
+intros (d x l); elim l; simplify; [reflexivity]
+apply (cmpP d x a); intros (E); simplify ; try rewrite > E; [reflexivity]
rewrite > andbA; rewrite > andbC in ⊢ (? ? (? % ?) ?); rewrite < andbA;
-rewrite < H; rewrite > andbC in ⊢ (? ? ? (? % ?)); rewrite < andbA;
-reflexivity;
+rewrite < H; rewrite > andbC in ⊢ (? ? ? (? % ?)); rewrite < andbA; reflexivity;
qed.
lemma count_O_mem : ∀d:eqType.∀x:d.∀l:list d.ltb O (count d (cmp d x) l) = mem d x l.
-intros 3 (d x l); elim l [reflexivity]
-simplify; fold simplify (mem d x l1); fold simplify (count d (cmp d x) l1);
-rewrite < H; cases (cmp d x t); simplify; reflexivity;
-qed.
+intros 3 (d x l); elim l [reflexivity] simplify; rewrite < H; cases (cmp d x a);
+reflexivity; qed.
lemma uniqP : ∀d:eqType.∀l:list d.
reflect (∀x:d.mem d x l = true → count d (cmp d x) l = (S O)) (uniq d l).
-intros (d l); apply prove_reflect; elim l; [1: destruct H1 | 3: destruct H]
-[1: generalize in match H2; simplify in H2; fold simplify (orb (cmp d x t) (mem d x l1)) in H2;
- (* lapply (uniq_tail ? ? ? H1) as Ul1; *)
+intros (d l); apply prove_reflect; elim l; [1: simplify in H1; destruct H1 | 3: simplify in H; destruct H]
+[1: generalize in match H2; simplify in H2;
lapply (b2pT ? ? (orbP ? ?) H2) as H3; clear H2;
cases H3; clear H3; intros;
- [2: lapply (uniq_mem ? ? ? H1) as H4;
- generalize in match (refl_eq ? (cmp d x t));
- generalize in match (cmp d x t) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- intros (H5);
- [1: simplify; rewrite > H5; simplify; fold simplify (count d (cmp d x) l1);
- rewrite > count_O; [1:reflexivity]
- intros (y Hy); rewrite > (b2pT ? ? (eqP d ? ?) H5) in H2 H3 H4 ⊢ %;
- clear H5; clear x; rewrite > H2 in H4; destruct H4;
- |2: simplify; rewrite > H5; simplify;
- fold simplify (count d (cmp d x) (l1));
- apply H; rewrite > uniq_tail in H1;
- cases (b2pT ? ? (andbP ? ?) H1);
+ [2: lapply (uniq_mem ? ? ? H1) as H4; simplify; apply (cmpP d x a);
+ intros (H5); simplify;
+ [1: rewrite > count_O; [reflexivity]
+ intros (y Hy); rewrite > H5 in H2 H3 ⊢ %; clear H5; clear x;
+ rewrite > H2 in H4; destruct H4;
+ |2: simplify; apply H;
+ rewrite > uniq_tail in H1; cases (b2pT ? ? (andbP ? ?) H1);
assumption;]
- |1: simplify; rewrite > H2; simplify;
- fold simplify (count d (cmp d x) l1);
- rewrite > count_O; [1:reflexivity]
+ |1: simplify; rewrite > H2; simplify; rewrite > count_O; [reflexivity]
intros (y Hy); rewrite > (b2pT ? ? (eqP d ? ?) H2) in H3 ⊢ %;
- clear H2; clear x;
- lapply (uniq_mem ? ? ? H1) as H4;
- generalize in match (refl_eq ? (cmp d t y));
- generalize in match (cmp d t y) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- [1: intros (E); rewrite > (b2pT ? ? (eqP d ? ?) E) in H4;
- rewrite > H4 in Hy; destruct Hy;
- |2:intros; reflexivity]]
-|2: rewrite > uniq_tail in H1;
+ clear H2; clear x; lapply (uniq_mem ? ? ? H1) as H4;
+ apply (cmpP d a y); intros (E); [2: reflexivity].
+ rewrite > E in H4; rewrite > H4 in Hy; destruct Hy;]
+|2: rewrite > uniq_tail in H1;
generalize in match (refl_eq ? (uniq d l1));
generalize in match (uniq d l1) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
[1: intros (E); rewrite > E in H1; rewrite > andbC in H1; simplify in H1;
- unfold Not; intros (A); lapply (A t) as A';
- [1: simplify in A';
- rewrite > cmp_refl in A'; simplify in A';
- destruct A'; clear A'; fold simplify (count d (cmp d t) l1) in Hcut;
- rewrite < count_O_mem in H1;
- rewrite > Hcut in H1; destruct H1;
- |2: simplify; rewrite > cmp_refl; reflexivity;]
+ unfold Not; intros (A); lapply (A a) as A';
+ [1: simplify in A'; rewrite > cmp_refl in A'; simplify in A';
+ destruct A'; rewrite < count_O_mem in H1;
+ rewrite > Hcut in H1; simplify in H1; destruct H1;
+ |2: simplify; rewrite > cmp_refl; reflexivity;]
|2: intros (Ul1); lapply (H Ul1); unfold Not; intros (A); apply Hletin;
- intros (r Mrl1); lapply (A r); [2: simplify; rewrite > Mrl1; cases (cmp d r t); reflexivity]
- generalize in match (refl_eq ? (cmp d r t));
- generalize in match (cmp d r t) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- [1: intros (E); simplify in Hletin1; rewrite > E in Hletin1;
- simplify in Hletin1; fold simplify (count d (cmp d r) l1) in Hletin1;
- destruct Hletin1;
- rewrite < count_O_mem in Mrl1;
- rewrite > Hcut in Mrl1;
- destruct Mrl1;
- |2: intros; simplify in Hletin1; rewrite > H2 in Hletin1;
- simplify in Hletin1; apply (Hletin1);]]]
+ intros (r Mrl1); lapply (A r);
+ [2: simplify; rewrite > Mrl1; cases (cmp d r a); reflexivity]
+ generalize in match Hletin1; simplify; apply (cmpP d r a);
+ simplify; intros (E Hc); [2: assumption]
+ destruct Hc; rewrite < count_O_mem in Mrl1;
+ rewrite > Hcut in Mrl1; simplify in Mrl1; destruct Mrl1;]]
qed.
lemma mem_finType : ∀d:finType.∀x:d. mem d x (enum d) = true.
intros (d p x); cases x (t Ht); clear x;
generalize in match (mem_finType d t);
generalize in match (uniq_fintype_enum d);
-elim (enum d); [1:destruct H1]
-simplify; fold simplify (filter d (sigma d p) (if_p d p) l);
-cases (in_sub_eq d p t1); simplify in ⊢ (? ? (? ? ? %) ?);
- [simplify; fold simplify (count (sub_eqType d p) (cmp (sub_eqType d p) {t,Ht})
- (filter d (sigma d p) (if_p d p) l));
- generalize in match H3; clear H3; cases s (r Hr); clear s;
- simplify; intros (Ert1); generalize in match Hr; clear Hr;
- rewrite > Ert1; clear Ert1; clear r; intros (Ht1);
- unfold sub_eqType in ⊢ (? ? match ? (% ? ?) ? ? with [true⇒ ?|false⇒ ?] ?);
- simplify; generalize in match (refl_eq ? (cmp d t t1));
- generalize in match (cmp d t t1) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- intros (Ett1); simplify;
- [1: cut (count (sub_eqType d p) (cmp (sub_eqType d p) {t,Ht})
+elim (enum d); [simplify in H1; destruct H1] simplify;
+cases (in_sub_eq d p a); simplify;
+[1:generalize in match H3; clear H3; cases s (r Hr); clear s;
+ simplify; intros (Ert1); generalize in match Hr; clear Hr;
+ rewrite > Ert1; clear Ert1; clear r; intros (Ht1);
+ unfold sub_eqType in ⊢ (? ? match ? (% ? ?) ? ? with [_ ⇒ ?|_ ⇒ ?] ?);
+ simplify; apply (cmpP ? t a); simplify; intros (Ett1);
+ [1: cut (count (sub_eqType d p) (cmp (sub_eqType d p) {t,Ht})
(filter d (sigma d p) (if_p d p) l) = O); [1:rewrite > Hcut; reflexivity]
- lapply (uniq_mem ? ? ? H1);
- generalize in match Ht;
- rewrite > (b2pT ? ? (eqP d ? ?) Ett1); intros (Ht1'); clear Ht1;
- generalize in match Hletin; elim l; [1: reflexivity]
- simplify; cases (in_sub_eq d p t2); simplify;
- [1: generalize in match H5; cases s; simplify; intros; clear H5;
- unfold sub_eqType in ⊢ (? ? match ? (% ? ?) ? ? with [true⇒ ?|false⇒ ?] ?);
- simplify; rewrite > H7; simplify in H4;
- generalize in match H4; clear H4;
- generalize in match (refl_eq ? (cmp d t1 t2));
- generalize in match (cmp d t1 t2) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- simplify; intros; [1: destruct H5] apply H3; assumption
- |2:apply H3;
- generalize in match H4; clear H4; simplify;
- generalize in match (refl_eq ? (cmp d t1 t2));
- generalize in match (cmp d t1 t2) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- simplify; intros; [1: destruct H6] assumption;]
- |2: apply H; [ rewrite > uniq_tail in H1; cases (b2pT ? ? (andbP ? ?) H1); assumption]
- simplify in H2; rewrite > Ett1 in H2; simplify in H2; assumption]
- | rewrite > H; [1:reflexivity|2: rewrite > uniq_tail in H1; cases (b2pT ? ? (andbP ? ?) H1); assumption]
- simplify in H2; generalize in match H2; generalize in match (refl_eq ? (cmp d t t1));
- generalize in match (cmp d t t1) in ⊢ (? ? ? % → %); intros 1 (b); cases b; clear b;
- intros (E);
- [lapply (b2pT ? ? (eqP d ? ?) E); clear H; rewrite > Hletin in Ht;
- rewrite > Ht in H3; destruct H3;
- |assumption]]
+ lapply (uniq_mem ? ? ? H1);
+ generalize in match Ht;
+ rewrite > Ett1; intros (Ht1'); clear Ht1;
+ generalize in match Hletin; elim l; [ reflexivity]
+ simplify; cases (in_sub_eq d p a1); simplify;
+ [1: generalize in match H5; cases s; simplify; intros; clear H5;
+ unfold sub_eqType in ⊢ (? ? match ? (% ? ?) ? ? with [_ ⇒ ?|_ ⇒ ?] ?);
+ simplify; rewrite > H7; simplify in H4;
+ generalize in match H4; clear H4; apply (cmpP ? a a1);
+ simplify; intros; [destruct H5] apply H3; assumption;
+ |2: apply H3;
+ generalize in match H4; clear H4; simplify; apply (cmpP ? a a1);
+ simplify; intros; [destruct H6] assumption;]
+ |2: apply H; [ rewrite > uniq_tail in H1; cases (b2pT ? ? (andbP ? ?) H1); assumption]
+ simplify in H2; rewrite > Ett1 in H2; simplify in H2; assumption]
+|2:rewrite > H; [1:reflexivity|2: rewrite > uniq_tail in H1; cases (b2pT ? ? (andbP ? ?) H1); assumption]
+ simplify in H2; generalize in match H2; apply (cmpP ? t a);
+ intros (E) [2:assumption] clear H; rewrite > E in Ht; rewrite > H3 in Ht;
+ destruct Ht;]
qed.
definition sub_finType : ∀d:finType.∀p:d→bool.finType ≝