From e8e18e32e06c0406c12a873a01eb489a35b828c8 Mon Sep 17 00:00:00 2001 From: matitaweb Date: Tue, 13 Dec 2011 11:44:06 +0000 Subject: [PATCH] New chapter 4 --- weblib/tutorial/chapter3.ma | 2 +- weblib/tutorial/chapter4.ma | 826 +++++------------------------------- 2 files changed, 103 insertions(+), 725 deletions(-) diff --git a/weblib/tutorial/chapter3.ma b/weblib/tutorial/chapter3.ma index 45f834a86..f7ad91557 100644 --- a/weblib/tutorial/chapter3.ma +++ b/weblib/tutorial/chapter3.ma @@ -262,7 +262,7 @@ A really convenient tool is the following combination of fold and filter, that essentially allow you to iterate on every subset of a given enumerated (finite) type, represented as a list. *) - let rec fold (A,B:Type[0]) (op:B →B →B) (b:B) (p:A→a href="cic:/matita/basics/bool/bool.ind(1,0,0)" title="null"bool/a) (f:A→B) (l:a href="cic:/matita/tutorial/chapter3/list.ind(1,0,1)"list/a A) on l :B ≝ + let rec fold (A,B:Type[0]) (op:B→B→B) (b:B) (p:A→a href="cic:/matita/basics/bool/bool.ind(1,0,0)" title="null"bool/a) (f:A→B) (l:a href="cic:/matita/tutorial/chapter3/list.ind(1,0,1)"list/a A) on l:B ≝ match l with [ nil ⇒ b | cons a l ⇒ a href="cic:/matita/basics/bool/if_then_else.def(1)"if_then_else/a ? (p a) (op (f a) (fold A B op b p f l)) diff --git a/weblib/tutorial/chapter4.ma b/weblib/tutorial/chapter4.ma index 8649c4469..a0a5a938d 100644 --- a/weblib/tutorial/chapter4.ma +++ b/weblib/tutorial/chapter4.ma @@ -1,748 +1,126 @@ -include "tutorial/chapter3.ma". -(* As a simple application of lists, let us now consider strings of characters -over a given alphabet Alpha. We shall assume to have a decidable equality between -characters, that is a (computable) function eqb associating a boolean value true -or false to each pair of characters; eqb is correct, in the sense that (eqb x y) -if and only if (x = y). The type Alpha of alphabets is hence defined by the -following record *) -interpretation "iff" 'iff a b = (iff a b). +(**************************************************************************) +(* ___ *) +(* ||M|| *) +(* ||A|| A project by Andrea Asperti *) +(* ||T|| *) +(* ||I|| Developers: *) +(* ||T|| The HELM team. *) +(* ||A|| http://helm.cs.unibo.it *) +(* \ / *) +(* \ / This file is distributed under the terms of the *) +(* v GNU General Public License Version 2 *) +(* *) +(**************************************************************************) -record Alpha : Type[1] ≝ { carr :> Type[0]; - eqb: carr → carr → a href="cic:/matita/basics/bool/bool.ind(1,0,0)"bool/a; - eqb_true: ∀x,y. (eqb x y a title="leibnitz's equality" href="cic:/fakeuri.def(1)"=/a a href="cic:/matita/basics/bool/bool.con(0,1,0)"true/a) a title="iff" href="cic:/fakeuri.def(1)"↔/a (x a title="leibnitz's equality" href="cic:/fakeuri.def(1)"=/a y) -}. - -notation "a == b" non associative with precedence 45 for @{ 'eqb $a $b }. -interpretation "eqb" 'eqb a b = (eqb ? a b). +include "arithmetics/nat.ma". +include "basics/lists/list.ma". +include "basics/sets.ma". -definition word ≝ λS: a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a.a href="cic:/matita/tutorial/chapter3/list.ind(1,0,1)"list/a S. - -inductive re (S: a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) : Type[0] ≝ - zero: re S - | epsilon: re S - | char: S → re S - | concat: re S → re S → re S - | or: re S → re S → re S - | star: re S → re S. - -(* notation < "a \sup ⋇" non associative with precedence 90 for @{ 'pk $a}. *) -notation "a ^ *" non associative with precedence 90 for @{ 'kstar $a}. -interpretation "star" 'kstar a = (star ? a). -interpretation "or" 'plus a b = (or ? a b). - -notation "a · b" non associative with precedence 60 for @{ 'concat $a $b}. -interpretation "cat" 'concat a b = (concat ? a b). - -(* to get rid of \middot -coercion c : ∀S:Alpha.∀p:re S. re S → re S ≝ c on _p : re ? to ∀_:?.?. *) - -(* notation < "a" non associative with precedence 90 for @{ 'ps $a}. *) -notation "` term 90 a" non associative with precedence 90 for @{ 'atom $a}. -interpretation "atom" 'atom a = (char ? a). +definition word ≝ λS:DeqSet.list S. notation "ϵ" non associative with precedence 90 for @{ 'epsilon }. -interpretation "epsilon" 'epsilon = (epsilon ?). - -notation "∅" (* slash emptyv *) non associative with precedence 90 for @{ 'empty }. -interpretation "empty" 'empty = (zero ?). - -let rec flatten (S : a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) (l : a href="cic:/matita/tutorial/chapter3/list.ind(1,0,1)"list/a (a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S)) on l : a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S ≝ -match l with [ nil ⇒ a title="nil" href="cic:/fakeuri.def(1)"[/a ] | cons w tl ⇒ w a title="append" href="cic:/fakeuri.def(1)"@/a flatten ? tl ]. - -let rec conjunct (S : a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) (l : a href="cic:/matita/tutorial/chapter3/list.ind(1,0,1)"list/a (a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S)) (L :a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S → Prop) on l: Prop ≝ -match l with [ nil ⇒ a href="cic:/matita/basics/logic/True.ind(1,0,0)"True/a | cons w tl ⇒ L w a title="logical and" href="cic:/fakeuri.def(1)"∧/a conjunct ? tl L ]. - -definition empty_lang ≝ λS.λw:a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S.a href="cic:/matita/basics/logic/False.ind(1,0,0)"False/a. -(* notation "{}" non associative with precedence 90 for @{'empty_lang}. *) -interpretation "empty lang" 'empty = (empty_lang ?). - -definition sing_lang ≝ λS.λx,w:a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S.x a title="leibnitz's equality" href="cic:/fakeuri.def(1)"=/a w. -notation "{: x }" non associative with precedence 90 for @{'sing_lang $x}. -interpretation "sing lang" 'sing_lang x = (sing_lang ? x). - -definition union : ∀S,L1,L2,w.Prop ≝ λS,L1,L2.λw: a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S.L1 w a title="logical or" href="cic:/fakeuri.def(1)"∨/a L2 w. -interpretation "union lang" 'union a b = (union ? a b). +interpretation "epsilon" 'epsilon = (nil ?). +(* concatenation *) definition cat : ∀S,l1,l2,w.Prop ≝ - λS.λl1,l2.λw:a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S.a title="exists" href="cic:/fakeuri.def(1)"∃/aw1,w2.w1 a title="append" href="cic:/fakeuri.def(1)"@/a w2 a title="leibnitz's equality" href="cic:/fakeuri.def(1)"=/a w a title="logical and" href="cic:/fakeuri.def(1)"∧/a l1 w1 a title="logical and" href="cic:/fakeuri.def(1)"∧/a l2 w2. -interpretation "cat lang" 'concat a b = (cat ? a b). - -definition star_lang ≝ λS.λl.λw:a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S.a title="exists" href="cic:/fakeuri.def(1)"∃/alw. a href="cic:/matita/tutorial/chapter4/flatten.fix(0,1,4)"flatten/a ? lw a title="leibnitz's equality" href="cic:/fakeuri.def(1)"=/a w a title="logical and" href="cic:/fakeuri.def(1)"∧/a a href="cic:/matita/tutorial/chapter4/conjunct.fix(0,1,4)"conjunct/a ? lw l. -interpretation "star lang" 'kstar l = (star_lang ? l). - -(* notation "| term 70 E| " non associative with precedence 75 for @{in_l ? $E}. *) - -let rec in_l (S : a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) (r : a href="cic:/matita/tutorial/chapter4/re.ind(1,0,1)"re/a S) on r : a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S → Prop ≝ -match r with - [ zero ⇒ a title="empty lang" href="cic:/fakeuri.def(1)"∅/a - | epsilon ⇒ a title="sing lang" href="cic:/fakeuri.def(1)"{/a: a title="nil" href="cic:/fakeuri.def(1)"[/a] } - | char x ⇒ a title="sing lang" href="cic:/fakeuri.def(1)"{/a: xa title="cons" href="cic:/fakeuri.def(1)":/a:a title="nil" href="cic:/fakeuri.def(1)"[/a] } - | concat r1 r2 ⇒ in_l ? r1 a title="cat lang" href="cic:/fakeuri.def(1)"·/a in_l ? r2 - | or r1 r2 ⇒ in_l ? r1 a title="union lang" href="cic:/fakeuri.def(1)"∪/a in_l ? r2 - | star r1 ⇒ (in_l ? r1)a title="star lang" href="cic:/fakeuri.def(1)"^/a* - ]. - -notation "\sem{E}" non associative with precedence 75 for @{'sem $E}. -interpretation "in_l" 'sem E = (in_l ? E). -interpretation "in_l mem" 'mem w l = (in_l ? l w). - -notation "a ∨ b" left associative with precedence 30 for @{'orb $a $b}. -interpretation "orb" 'orb a b = (orb a b). + λS.λl1,l2.λw:word S.∃w1,w2.w1 @ w2 = w ∧ l1 w1 ∧ l2 w2. +notation "a · b" non associative with precedence 60 for @{ 'middot $a $b}. +interpretation "cat lang" 'middot a b = (cat ? a b). -(* ndefinition if_then_else ≝ λT:Type[0].λe,t,f.match e return λ_.T with [ true ⇒ t | false ⇒ f]. -notation > "'if' term 19 e 'then' term 19 t 'else' term 19 f" non associative with precedence 19 for @{ 'if_then_else $e $t $f }. -notation < "'if' \nbsp term 19 e \nbsp 'then' \nbsp term 19 t \nbsp 'else' \nbsp term 90 f \nbsp" non associative with precedence 19 for @{ 'if_then_else $e $t $f }. -interpretation "if_then_else" 'if_then_else e t f = (if_then_else ? e t f). *) +let rec flatten (S : DeqSet) (l : list (word S)) on l : word S ≝ +match l with [ nil ⇒ [ ] | cons w tl ⇒ w @ flatten ? tl ]. -inductive pitem (S: a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) : Type[0] ≝ - | pzero: pitem S - | pepsilon: pitem S - | pchar: S → pitem S - | ppoint: S → pitem S - | pconcat: pitem S → pitem S → pitem S - | por: pitem S → pitem S → pitem S - | pstar: pitem S → pitem S. - -definition pre ≝ λS.a href="cic:/matita/tutorial/chapter4/pitem.ind(1,0,1)"pitem/a S a title="Product" href="cic:/fakeuri.def(1)"×/a a href="cic:/matita/basics/bool/bool.ind(1,0,0)" title="null"bool/a. +let rec conjunct (S : DeqSet) (l : list (word S)) (r : word S → Prop) on l: Prop ≝ +match l with [ nil ⇒ True | cons w tl ⇒ r w ∧ conjunct ? tl r ]. -interpretation "pstar" 'kstar a = (pstar ? a). -interpretation "por" 'plus a b = (por ? a b). -interpretation "pcat" 'concat a b = (pconcat ? a b). +(* kleene's star *) +definition star ≝ λS.λl.λw:word S.∃lw.flatten ? lw = w ∧ conjunct ? lw l. +notation "a ^ *" non associative with precedence 90 for @{ 'star $a}. +interpretation "star lang" 'star l = (star ? l). -notation "• a" non associative with precedence 90 for @{ 'ppoint $a}. -(* notation > "`. term 90 a" non associative with precedence 90 for @{ 'pp $a}. *) - -interpretation "ppatom" 'ppoint a = (ppoint ? a). -(* to get rid of \middot -ncoercion pc : ∀S.∀p:pitem S. pitem S → pitem S ≝ pc on _p : pitem ? to ∀_:?.?. *) -interpretation "patom" 'pchar a = (pchar ? a). -interpretation "pepsilon" 'epsilon = (pepsilon ?). -interpretation "pempty" 'empty = (pzero ?). - -notation "| e |" non associative with precedence 65 for @{forget ? $e}. - -let rec forget (S: a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) (l : a href="cic:/matita/tutorial/chapter4/pitem.ind(1,0,1)"pitem/a S) on l: a href="cic:/matita/tutorial/chapter4/re.ind(1,0,1)"re/a S ≝ - match l with - [ pzero ⇒ a title="empty" href="cic:/fakeuri.def(1)"∅/a - | pepsilon ⇒ a title="epsilon" href="cic:/fakeuri.def(1)"ϵ/a - | pchar x ⇒ a href="cic:/matita/tutorial/chapter4/re.con(0,3,1)"char/a ? x - | ppoint x ⇒ a href="cic:/matita/tutorial/chapter4/re.con(0,3,1)"char/a ? x - | pconcat e1 e2 ⇒ |e1| a title="cat" href="cic:/fakeuri.def(1)"·/a |e2| - | por e1 e2 ⇒ |e1| a title="or" href="cic:/fakeuri.def(1)"+/a |e2| - | pstar e ⇒ |e|a title="star" href="cic:/fakeuri.def(1)"^/a* - ]. - -notation "| e |" non associative with precedence 65 for @{'fmap $e}. -interpretation "forget" 'fmap a = (forget ? a). +lemma cat_ext_l: ∀S.∀A,B,C:word S →Prop. + A =1 C → A · B =1 C · B. +#S #A #B #C #H #w % * #w1 * #w2 * * #eqw #inw1 #inw2 +cases (H w1) /6/ +qed. -let rec in_pl (S : a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a) (r : a href="cic:/matita/tutorial/chapter4/pitem.ind(1,0,1)"pitem/a S) on r : a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S → Prop ≝ -match r with - [ pzero ⇒ a title="empty lang" href="cic:/fakeuri.def(1)"∅/a - | pepsilon ⇒ a title="empty lang" href="cic:/fakeuri.def(1)"∅/a - | pchar _ ⇒ a title="empty lang" href="cic:/fakeuri.def(1)"∅/a - | ppoint x ⇒ a title="sing lang" href="cic:/fakeuri.def(1)"{/a: xa title="cons" href="cic:/fakeuri.def(1)":/a:a title="nil" href="cic:/fakeuri.def(1)"[/a] } - | pconcat pe1 pe2 ⇒ in_pl ? pe1 a title="cat lang" href="cic:/fakeuri.def(1)"·/a a title="in_l" href="cic:/fakeuri.def(1)"\sem/a{|pe2|} a title="union lang" href="cic:/fakeuri.def(1)"∪/a in_pl ? pe2 - | por pe1 pe2 ⇒ in_pl ? pe1 a title="union lang" href="cic:/fakeuri.def(1)"∪/a in_pl ? pe2 - | pstar pe ⇒ in_pl ? pe a title="cat lang" href="cic:/fakeuri.def(1)"·/a a title="in_l" href="cic:/fakeuri.def(1)"\sem/a{|pe|}a title="star lang" href="cic:/fakeuri.def(1)"^/a* - ]. +lemma cat_ext_r: ∀S.∀A,B,C:word S →Prop. + B =1 C → A · B =1 A · C. +#S #A #B #C #H #w % * #w1 * #w2 * * #eqw #inw1 #inw2 +cases (H w2) /6/ +qed. + +lemma distr_cat_r: ∀S.∀A,B,C:word S →Prop. + (A ∪ B) · C =1 A · C ∪ B · C. +#S #A #B #C #w % + [* #w1 * #w2 * * #eqw * /6/ |* * #w1 * #w2 * * /6/] +qed. -interpretation "in_pl" 'sem E = (in_pl ? E). -interpretation "in_pl mem" 'mem w l = (in_pl ? l w). +lemma espilon_in_star: ∀S.∀A:word S → Prop. + A^* ϵ. +#S #A @(ex_intro … [ ]) normalize /2/ +qed. -definition eps: ∀S:a href="cic:/matita/tutorial/chapter4/Alpha.ind(1,0,0)"Alpha/a.a href="cic:/matita/basics/bool/bool.ind(1,0,0)"bool/a → a href="cic:/matita/tutorial/chapter4/word.def(3)"word/a S → Prop - ≝ λS,b. a href="cic:/matita/basics/bool/if_then_else.def(1)"if_then_else/a ? b a title="sing lang" href="cic:/fakeuri.def(1)"{/a: a title="nil" href="cic:/fakeuri.def(1)"[/a] } a title="empty lang" href="cic:/fakeuri.def(1)"∅/a. +lemma cat_to_star:∀S.∀A:word S → Prop. + ∀w1,w2. A w1 → A^* w2 → A^* (w1@w2). +#S #A #w1 #w2 #Aw * #l * #H #H1 @(ex_intro … (w1::l)) +% normalize /2/ +qed. -notation "ϵ _ b" non associative with precedence 90 for @{'app_epsilon $b}. -interpretation "epsilon lang" 'app_epsilon b = (eps ? b). +lemma fix_star: ∀S.∀A:word S → Prop. + A^* =1 A · A^* ∪ {ϵ}. +#S #A #w % + [* #l generalize in match w; -w cases l [normalize #w * /2/] + #w1 #tl #w * whd in ⊢ ((??%?)→?); #eqw whd in ⊢ (%→?); * + #w1A #cw1 %1 @(ex_intro … w1) @(ex_intro … (flatten S tl)) + % /2/ whd @(ex_intro … tl) /2/ + |* [2: whd in ⊢ (%→?); #eqw H // qed. - -lemma if_epsilon_true : ∀S.∀e:a href="cic:/matita/tutorial/chapter4/pre.def(1)"pre/a S. a title="nil" href="cic:/fakeuri.def(1)"[/a ] a title="in_prl mem" href="cic:/fakeuri.def(1)"∈/a e → a title="pair pi2" href="cic:/fakeuri.def(1)"\snd/a e a title="leibnitz's equality" href="cic:/fakeuri.def(1)"=/a a href="cic:/matita/basics/bool/bool.con(0,1,0)"true/a. -#S * #pi #b * [normalize #abs @a href="cic:/matita/basics/logic/False_ind.fix(0,1,1)"False_ind/a /span class="autotactic"2span class="autotrace" trace a href="cic:/matita/basics/logic/absurd.def(2)"absurd/a/span/span/] cases b normalize // @a href="cic:/matita/basics/logic/False_ind.fix(0,1,1)"False_ind/a +lemma epsilon_cat_l: ∀S.∀A:word S →Prop. + {ϵ} · A =1 A. +#S #A #w % + [* #w1 * #w2 * * #eqw normalize #eqw2 "a ⊙ b" left associative with precedence 60 for @{'lc eclose $a $b}. - -ndefinition lk ≝ λS:Alpha.λbcast:∀S:Alpha.∀E:pitem S.pre S.λa:pre S. - match a with [ mk_pair e1 b1 ⇒ - match b1 with - [ false ⇒ 〈e1^*, false〉 - | true ⇒ 〈(\fst (bcast ? e1))^*, true〉]]. - -notation < "a \sup ⊛" non associative with precedence 90 for @{'lk $op $a}. -interpretation "lk" 'lk op a = (lk ? op a). -notation > "a^⊛" non associative with precedence 90 for @{'lk eclose $a}. - -notation > "•" non associative with precedence 60 for @{eclose ?}. -nlet rec eclose (S: Alpha) (E: pitem S) on E : pre S ≝ - match E with - [ pz ⇒ 〈 ∅, false 〉 - | pe ⇒ 〈 ϵ, true 〉 - | ps x ⇒ 〈 `.x, false 〉 - | pp x ⇒ 〈 `.x, false 〉 - | po E1 E2 ⇒ •E1 ⊕ •E2 - | pc E1 E2 ⇒ •E1 ⊙ 〈 E2, false 〉 - | pk E ⇒ 〈(\fst (•E))^*,true〉]. -notation < "• x" non associative with precedence 60 for @{'eclose $x}. -interpretation "eclose" 'eclose x = (eclose ? x). -notation > "• x" non associative with precedence 60 for @{'eclose $x}. - -ndefinition reclose ≝ λS:Alpha.λp:pre S.let p' ≝ •\fst p in 〈\fst p',\snd p || \snd p'〉. -interpretation "reclose" 'eclose x = (reclose ? x). - -ndefinition eq_f1 ≝ λS.λa,b:word S → Prop.∀w.a w ↔ b w. -notation > "A =1 B" non associative with precedence 45 for @{'eq_f1 $A $B}. -notation "A =\sub 1 B" non associative with precedence 45 for @{'eq_f1 $A $B}. -interpretation "eq f1" 'eq_f1 a b = (eq_f1 ? a b). - -naxiom extP : ∀S.∀p,q:word S → Prop.(p =1 q) → p = q. - -nlemma epsilon_or : ∀S:Alpha.∀b1,b2. ϵ(b1 || b2) = ϵ b1 ∪ ϵ b2. ##[##2: napply S] -#S b1 b2; ncases b1; ncases b2; napply extP; #w; nnormalize; @; /2/; *; //; *; -nqed. - -nlemma cupA : ∀S.∀a,b,c:word S → Prop.a ∪ b ∪ c = a ∪ (b ∪ c). -#S a b c; napply extP; #w; nnormalize; @; *; /3/; *; /3/; nqed. - -nlemma cupC : ∀S. ∀a,b:word S → Prop.a ∪ b = b ∪ a. -#S a b; napply extP; #w; @; *; nnormalize; /2/; nqed. - -(* theorem 16: 2 *) -nlemma oplus_cup : ∀S:Alpha.∀e1,e2:pre S.𝐋\p (e1 ⊕ e2) = 𝐋\p e1 ∪ 𝐋\p e2. -#S r1; ncases r1; #e1 b1 r2; ncases r2; #e2 b2; -nwhd in ⊢ (??(??%)?); -nchange in ⊢(??%?) with (𝐋\p (e1 + e2) ∪ ϵ (b1 || b2)); -nchange in ⊢(??(??%?)?) with (𝐋\p (e1) ∪ 𝐋\p (e2)); -nrewrite > (epsilon_or S …); nrewrite > (cupA S (𝐋\p e1) …); -nrewrite > (cupC ? (ϵ b1) …); nrewrite < (cupA S (𝐋\p e2) …); -nrewrite > (cupC ? ? (ϵ b1) …); nrewrite < (cupA …); //; -nqed. - -nlemma odotEt : - ∀S.∀e1,e2:pitem S.∀b2. 〈e1,true〉 ⊙ 〈e2,b2〉 = 〈e1 · \fst (•e2),b2 || \snd (•e2)〉. -#S e1 e2 b2; nnormalize; ncases (•e2); //; nqed. - -nlemma LcatE : ∀S.∀e1,e2:pitem S.𝐋\p (e1 · e2) = 𝐋\p e1 · 𝐋 |e2| ∪ 𝐋\p e2. //; nqed. - -nlemma cup_dotD : ∀S.∀p,q,r:word S → Prop.(p ∪ q) · r = (p · r) ∪ (q · r). -#S p q r; napply extP; #w; nnormalize; @; -##[ *; #x; *; #y; *; *; #defw; *; /7/ by or_introl, or_intror, ex_intro, conj; -##| *; *; #x; *; #y; *; *; /7/ by or_introl, or_intror, ex_intro, conj; ##] -nqed. - -nlemma cup0 :∀S.∀p:word S → Prop.p ∪ {} = p. -#S p; napply extP; #w; nnormalize; @; /2/; *; //; *; nqed. - -nlemma erase_dot : ∀S.∀e1,e2:pitem S.𝐋 |e1 · e2| = 𝐋 |e1| · 𝐋 |e2|. -#S e1 e2; napply extP; nnormalize; #w; @; *; #w1; *; #w2; *; *; /7/ by ex_intro, conj; -nqed. - -nlemma erase_plus : ∀S.∀e1,e2:pitem S.𝐋 |e1 + e2| = 𝐋 |e1| ∪ 𝐋 |e2|. -#S e1 e2; napply extP; nnormalize; #w; @; *; /4/ by or_introl, or_intror; nqed. - -nlemma erase_star : ∀S.∀e1:pitem S.𝐋 |e1|^* = 𝐋 |e1^*|. //; nqed. - -ndefinition substract := λS.λp,q:word S → Prop.λw.p w ∧ ¬ q w. -interpretation "substract" 'minus a b = (substract ? a b). - -nlemma cup_sub: ∀S.∀a,b:word S → Prop. ¬ (a []) → a ∪ (b - {[]}) = (a ∪ b) - {[]}. -#S a b c; napply extP; #w; nnormalize; @; *; /4/; *; /4/; nqed. - -nlemma sub0 : ∀S.∀a:word S → Prop. a - {} = a. -#S a; napply extP; #w; nnormalize; @; /3/; *; //; nqed. - -nlemma subK : ∀S.∀a:word S → Prop. a - a = {}. -#S a; napply extP; #w; nnormalize; @; *; /2/; nqed. - -nlemma subW : ∀S.∀a,b:word S → Prop.∀w.(a - b) w → a w. -#S a b w; nnormalize; *; //; nqed. - -nlemma erase_bull : ∀S.∀a:pitem S. |\fst (•a)| = |a|. -#S a; nelim a; // by {}; -##[ #e1 e2 IH1 IH2; nchange in ⊢ (???%) with (|e1| · |e2|); - nrewrite < IH1; nrewrite < IH2; - nchange in ⊢ (??(??%)?) with (\fst (•e1 ⊙ 〈e2,false〉)); - ncases (•e1); #e3 b; ncases b; nnormalize; - ##[ ncases (•e2); //; ##| nrewrite > IH2; //] -##| #e1 e2 IH1 IH2; nchange in ⊢ (???%) with (|e1| + |e2|); - nrewrite < IH2; nrewrite < IH1; - nchange in ⊢ (??(??%)?) with (\fst (•e1 ⊕ •e2)); - ncases (•e1); ncases (•e2); //; -##| #e IH; nchange in ⊢ (???%) with (|e|^* ); nrewrite < IH; - nchange in ⊢ (??(??%)?) with (\fst (•e))^*; //; ##] -nqed. - -nlemma eta_lp : ∀S.∀p:pre S.𝐋\p p = 𝐋\p 〈\fst p, \snd p〉. -#S p; ncases p; //; nqed. - -nlemma epsilon_dot: ∀S.∀p:word S → Prop. {[]} · p = p. -#S e; napply extP; #w; nnormalize; @; ##[##2: #Hw; @[]; @w; /3/; ##] -*; #w1; *; #w2; *; *; #defw defw1 Hw2; nrewrite < defw; nrewrite < defw1; -napply Hw2; nqed. - -(* theorem 16: 1 → 3 *) -nlemma odot_dot_aux : ∀S.∀e1,e2: pre S. - 𝐋\p (•(\fst e2)) = 𝐋\p (\fst e2) ∪ 𝐋 |\fst e2| → - 𝐋\p (e1 ⊙ e2) = 𝐋\p e1 · 𝐋 |\fst e2| ∪ 𝐋\p e2. -#S e1 e2 th1; ncases e1; #e1' b1'; ncases b1'; -##[ nwhd in ⊢ (??(??%)?); nletin e2' ≝ (\fst e2); nletin b2' ≝ (\snd e2); - nletin e2'' ≝ (\fst (•(\fst e2))); nletin b2'' ≝ (\snd (•(\fst e2))); - nchange in ⊢ (??%?) with (?∪?); - nchange in ⊢ (??(??%?)?) with (?∪?); - nchange in match (𝐋\p 〈?,?〉) with (?∪?); - nrewrite > (epsilon_or …); nrewrite > (cupC ? (ϵ ?)…); - nrewrite > (cupA …);nrewrite < (cupA ?? (ϵ?)…); - nrewrite > (?: 𝐋\p e2'' ∪ ϵ b2'' = 𝐋\p e2' ∪ 𝐋 |e2'|); ##[##2: - nchange with (𝐋\p 〈e2'',b2''〉 = 𝐋\p e2' ∪ 𝐋 |e2'|); - ngeneralize in match th1; - nrewrite > (eta_lp…); #th1; nrewrite > th1; //;##] - nrewrite > (eta_lp ? e2); - nchange in match (𝐋\p 〈\fst e2,?〉) with (𝐋\p e2'∪ ϵ b2'); - nrewrite > (cup_dotD …); nrewrite > (epsilon_dot…); - nrewrite > (cupC ? (𝐋\p e2')…); nrewrite > (cupA…);nrewrite > (cupA…); - nrewrite < (erase_bull S e2') in ⊢ (???(??%?)); //; -##| ncases e2; #e2' b2'; nchange in match (〈e1',false〉⊙?) with 〈?,?〉; - nchange in match (𝐋\p ?) with (?∪?); - nchange in match (𝐋\p (e1'·?)) with (?∪?); - nchange in match (𝐋\p 〈e1',?〉) with (?∪?); - nrewrite > (cup0…); - nrewrite > (cupA…); //;##] -nqed. - -nlemma sub_dot_star : - ∀S.∀X:word S → Prop.∀b. (X - ϵ b) · X^* ∪ {[]} = X^*. -#S X b; napply extP; #w; @; -##[ *; ##[##2: nnormalize; #defw; nrewrite < defw; @[]; @; //] - *; #w1; *; #w2; *; *; #defw sube; *; #lw; *; #flx cj; - @ (w1 :: lw); nrewrite < defw; nrewrite < flx; @; //; - @; //; napply (subW … sube); -##| *; #wl; *; #defw Pwl; nrewrite < defw; nelim wl in Pwl; ##[ #_; @2; //] - #w' wl' IH; *; #Pw' IHp; nlapply (IH IHp); *; - ##[ *; #w1; *; #w2; *; *; #defwl' H1 H2; - @; ncases b in H1; #H1; - ##[##2: nrewrite > (sub0…); @w'; @(w1@w2); - nrewrite > (associative_append ? w' w1 w2); - nrewrite > defwl'; @; ##[@;//] @(wl'); @; //; - ##| ncases w' in Pw'; - ##[ #ne; @w1; @w2; nrewrite > defwl'; @; //; @; //; - ##| #x xs Px; @(x::xs); @(w1@w2); - nrewrite > (defwl'); @; ##[@; //; @; //; @; nnormalize; #; ndestruct] - @wl'; @; //; ##] ##] - ##| #wlnil; nchange in match (flatten ? (w'::wl')) with (w' @ flatten ? wl'); - nrewrite < (wlnil); nrewrite > (append_nil…); ncases b; - ##[ ncases w' in Pw'; /2/; #x xs Pxs; @; @(x::xs); @([]); - nrewrite > (append_nil…); @; ##[ @; //;@; //; nnormalize; @; #; ndestruct] - @[]; @; //; - ##| @; @w'; @[]; nrewrite > (append_nil…); @; ##[##2: @[]; @; //] - @; //; @; //; @; *;##]##]##] -nqed. - -(* theorem 16: 1 *) -alias symbol "pc" (instance 13) = "cat lang". -alias symbol "in_pl" (instance 23) = "in_pl". -alias symbol "in_pl" (instance 5) = "in_pl". -alias symbol "eclose" (instance 21) = "eclose". -ntheorem bull_cup : ∀S:Alpha. ∀e:pitem S. 𝐋\p (•e) = 𝐋\p e ∪ 𝐋 |e|. -#S e; nelim e; //; - ##[ #a; napply extP; #w; nnormalize; @; *; /3/ by or_introl, or_intror; - ##| #a; napply extP; #w; nnormalize; @; *; /3/ by or_introl; *; - ##| #e1 e2 IH1 IH2; - nchange in ⊢ (??(??(%))?) with (•e1 ⊙ 〈e2,false〉); - nrewrite > (odot_dot_aux S (•e1) 〈e2,false〉 IH2); - nrewrite > (IH1 …); nrewrite > (cup_dotD …); - nrewrite > (cupA …); nrewrite > (cupC ?? (𝐋\p ?) …); - nchange in match (𝐋\p 〈?,?〉) with (𝐋\p e2 ∪ {}); nrewrite > (cup0 …); - nrewrite < (erase_dot …); nrewrite < (cupA …); //; - ##| #e1 e2 IH1 IH2; - nchange in match (•(?+?)) with (•e1 ⊕ •e2); nrewrite > (oplus_cup …); - nrewrite > (IH1 …); nrewrite > (IH2 …); nrewrite > (cupA …); - nrewrite > (cupC ? (𝐋\p e2)…);nrewrite < (cupA ??? (𝐋\p e2)…); - nrewrite > (cupC ?? (𝐋\p e2)…); nrewrite < (cupA …); - nrewrite < (erase_plus …); //. - ##| #e; nletin e' ≝ (\fst (•e)); nletin b' ≝ (\snd (•e)); #IH; - nchange in match (𝐋\p ?) with (𝐋\p 〈e'^*,true〉); - nchange in match (𝐋\p ?) with (𝐋\p (e'^* ) ∪ {[ ]}); - nchange in ⊢ (??(??%?)?) with (𝐋\p e' · 𝐋 |e'|^* ); - nrewrite > (erase_bull…e); - nrewrite > (erase_star …); - nrewrite > (?: 𝐋\p e' = 𝐋\p e ∪ (𝐋 |e| - ϵ b')); ##[##2: - nchange in IH : (??%?) with (𝐋\p e' ∪ ϵ b'); ncases b' in IH; - ##[ #IH; nrewrite > (cup_sub…); //; nrewrite < IH; - nrewrite < (cup_sub…); //; nrewrite > (subK…); nrewrite > (cup0…);//; - ##| nrewrite > (sub0 …); #IH; nrewrite < IH; nrewrite > (cup0 …);//; ##]##] - nrewrite > (cup_dotD…); nrewrite > (cupA…); - nrewrite > (?: ((?·?)∪{[]} = 𝐋 |e^*|)); //; - nchange in match (𝐋 |e^*|) with ((𝐋 |e|)^* ); napply sub_dot_star;##] - nqed. - -(* theorem 16: 3 *) -nlemma odot_dot: - ∀S.∀e1,e2: pre S. 𝐋\p (e1 ⊙ e2) = 𝐋\p e1 · 𝐋 |\fst e2| ∪ 𝐋\p e2. -#S e1 e2; napply odot_dot_aux; napply (bull_cup S (\fst e2)); nqed. - -nlemma dot_star_epsilon : ∀S.∀e:re S.𝐋 e · 𝐋 e^* ∪ {[]} = 𝐋 e^*. -#S e; napply extP; #w; nnormalize; @; -##[ *; ##[##2: #H; nrewrite < H; @[]; /3/] *; #w1; *; #w2; - *; *; #defw Hw1; *; #wl; *; #defw2 Hwl; @(w1 :: wl); - nrewrite < defw; nrewrite < defw2; @; //; @;//; -##| *; #wl; *; #defw Hwl; ncases wl in defw Hwl; ##[#defw; #; @2; nrewrite < defw; //] - #x xs defw; *; #Hx Hxs; @; @x; @(flatten ? xs); nrewrite < defw; - @; /2/; @xs; /2/;##] - nqed. - -nlemma nil_star : ∀S.∀e:re S. [ ] ∈ e^*. -#S e; @[]; /2/; nqed. - -nlemma cupID : ∀S.∀l:word S → Prop.l ∪ l = l. -#S l; napply extP; #w; @; ##[*]//; #; @; //; nqed. - -nlemma cup_star_nil : ∀S.∀l:word S → Prop. l^* ∪ {[]} = l^*. -#S a; napply extP; #w; @; ##[*; //; #H; nrewrite < H; @[]; @; //] #;@; //;nqed. - -nlemma rcanc_sing : ∀S.∀A,C:word S → Prop.∀b:word S . - ¬ (A b) → A ∪ { (b) } = C → A = C - { (b) }. -#S A C b nbA defC; nrewrite < defC; napply extP; #w; @; -##[ #Aw; /3/| *; *; //; #H nH; ncases nH; #abs; nlapply (abs H); *] -nqed. - -(* theorem 16: 4 *) -nlemma star_dot: ∀S.∀e:pre S. 𝐋\p (e^⊛) = 𝐋\p e · (𝐋 |\fst e|)^*. -#S p; ncases p; #e b; ncases b; -##[ nchange in match (〈e,true〉^⊛) with 〈?,?〉; - nletin e' ≝ (\fst (•e)); nletin b' ≝ (\snd (•e)); - nchange in ⊢ (??%?) with (?∪?); - nchange in ⊢ (??(??%?)?) with (𝐋\p e' · 𝐋 |e'|^* ); - nrewrite > (?: 𝐋\p e' = 𝐋\p e ∪ (𝐋 |e| - ϵ b' )); ##[##2: - nlapply (bull_cup ? e); #bc; - nchange in match (𝐋\p (•e)) in bc with (?∪?); - nchange in match b' in bc with b'; - ncases b' in bc; ##[##2: nrewrite > (cup0…); nrewrite > (sub0…); //] - nrewrite > (cup_sub…); ##[napply rcanc_sing] //;##] - nrewrite > (cup_dotD…); nrewrite > (cupA…);nrewrite > (erase_bull…); - nrewrite > (sub_dot_star…); - nchange in match (𝐋\p 〈?,?〉) with (?∪?); - nrewrite > (cup_dotD…); nrewrite > (epsilon_dot…); //; -##| nwhd in match (〈e,false〉^⊛); nchange in match (𝐋\p 〈?,?〉) with (?∪?); - nrewrite > (cup0…); - nchange in ⊢ (??%?) with (𝐋\p e · 𝐋 |e|^* ); - nrewrite < (cup0 ? (𝐋\p e)); //;##] -nqed. - -nlet rec pre_of_re (S : Alpha) (e : re S) on e : pitem S ≝ - match e with - [ z ⇒ pz ? - | e ⇒ pe ? - | s x ⇒ ps ? x - | c e1 e2 ⇒ pc ? (pre_of_re ? e1) (pre_of_re ? e2) - | o e1 e2 ⇒ po ? (pre_of_re ? e1) (pre_of_re ? e2) - | k e1 ⇒ pk ? (pre_of_re ? e1)]. - -nlemma notFalse : ¬False. @; //; nqed. - -nlemma dot0 : ∀S.∀A:word S → Prop. {} · A = {}. -#S A; nnormalize; napply extP; #w; @; ##[##2: *] -*; #w1; *; #w2; *; *; //; nqed. - -nlemma Lp_pre_of_re : ∀S.∀e:re S. 𝐋\p (pre_of_re ? e) = {}. -#S e; nelim e; ##[##1,2,3: //] -##[ #e1 e2 H1 H2; nchange in match (𝐋\p (pre_of_re S (e1 e2))) with (?∪?); - nrewrite > H1; nrewrite > H2; nrewrite > (dot0…); nrewrite > (cupID…);// -##| #e1 e2 H1 H2; nchange in match (𝐋\p (pre_of_re S (e1+e2))) with (?∪?); - nrewrite > H1; nrewrite > H2; nrewrite > (cupID…); // -##| #e1 H1; nchange in match (𝐋\p (pre_of_re S (e1^* ))) with (𝐋\p (pre_of_re ??) · ?); - nrewrite > H1; napply dot0; ##] -nqed. - -nlemma erase_pre_of_reK : ∀S.∀e. 𝐋 |pre_of_re S e| = 𝐋 e. -#S A; nelim A; //; -##[ #e1 e2 H1 H2; nchange in match (𝐋 (e1 · e2)) with (𝐋 e1·?); - nrewrite < H1; nrewrite < H2; // -##| #e1 e2 H1 H2; nchange in match (𝐋 (e1 + e2)) with (𝐋 e1 ∪ ?); - nrewrite < H1; nrewrite < H2; // -##| #e1 H1; nchange in match (𝐋 (e1^* )) with ((𝐋 e1)^* ); - nrewrite < H1; //] -nqed. - -(* corollary 17 *) -nlemma L_Lp_bull : ∀S.∀e:re S.𝐋 e = 𝐋\p (•pre_of_re ? e). -#S e; nrewrite > (bull_cup…); nrewrite > (Lp_pre_of_re…); -nrewrite > (cupC…); nrewrite > (cup0…); nrewrite > (erase_pre_of_reK…); //; -nqed. - -nlemma Pext : ∀S.∀f,g:word S → Prop. f = g → ∀w.f w → g w. -#S f g H; nrewrite > H; //; nqed. - -(* corollary 18 *) -ntheorem bull_true_epsilon : ∀S.∀e:pitem S. \snd (•e) = true ↔ [ ] ∈ |e|. -#S e; @; -##[ #defsnde; nlapply (bull_cup ? e); nchange in match (𝐋\p (•e)) with (?∪?); - nrewrite > defsnde; #H; - nlapply (Pext ??? H [ ] ?); ##[ @2; //] *; //; - -STOP - -notation > "\move term 90 x term 90 E" -non associative with precedence 60 for @{move ? $x $E}. -nlet rec move (S: Alpha) (x:S) (E: pitem S) on E : pre S ≝ - match E with - [ pz ⇒ 〈 ∅, false 〉 - | pe ⇒ 〈 ϵ, false 〉 - | ps y ⇒ 〈 `y, false 〉 - | pp y ⇒ 〈 `y, x == y 〉 - | po e1 e2 ⇒ \move x e1 ⊕ \move x e2 - | pc e1 e2 ⇒ \move x e1 ⊙ \move x e2 - | pk e ⇒ (\move x e)^⊛ ]. -notation < "\move\shy x\shy E" non associative with precedence 60 for @{'move $x $E}. -notation > "\move term 90 x term 90 E" non associative with precedence 60 for @{'move $x $E}. -interpretation "move" 'move x E = (move ? x E). - -ndefinition rmove ≝ λS:Alpha.λx:S.λe:pre S. \move x (\fst e). -interpretation "rmove" 'move x E = (rmove ? x E). - -nlemma XXz : ∀S:Alpha.∀w:word S. w ∈ ∅ → False. -#S w abs; ninversion abs; #; ndestruct; -nqed. - - -nlemma XXe : ∀S:Alpha.∀w:word S. w .∈ ϵ → False. -#S w abs; ninversion abs; #; ndestruct; -nqed. - -nlemma XXze : ∀S:Alpha.∀w:word S. w .∈ (∅ · ϵ) → False. -#S w abs; ninversion abs; #; ndestruct; /2/ by XXz,XXe; -nqed. - - -naxiom in_move_cat: - ∀S.∀w:word S.∀x.∀E1,E2:pitem S. w .∈ \move x (E1 · E2) → - (∃w1.∃w2. w = w1@w2 ∧ w1 .∈ \move x E1 ∧ w2 ∈ .|E2|) ∨ w .∈ \move x E2. -#S w x e1 e2 H; nchange in H with (w .∈ \move x e1 ⊙ \move x e2); -ncases e1 in H; ncases e2; -##[##1: *; ##[*; nnormalize; #; ndestruct] - #H; ninversion H; ##[##1,4,5,6: nnormalize; #; ndestruct] - nnormalize; #; ndestruct; ncases (?:False); /2/ by XXz,XXze; -##|##2: *; ##[*; nnormalize; #; ndestruct] - #H; ninversion H; ##[##1,4,5,6: nnormalize; #; ndestruct] - nnormalize; #; ndestruct; ncases (?:False); /2/ by XXz,XXze; -##| #r; *; ##[ *; nnormalize; #; ndestruct] - #H; ninversion H; ##[##1,4,5,6: nnormalize; #; ndestruct] - ##[##2: nnormalize; #; ndestruct; @2; @2; //.##] - nnormalize; #; ndestruct; ncases (?:False); /2/ by XXz; -##| #y; *; ##[ *; nnormalize; #defw defx; ndestruct; @2; @1; /2/ by conj;##] - #H; ninversion H; nnormalize; #; ndestruct; - ##[ncases (?:False); /2/ by XXz] /3/ by or_intror; -##| #r1 r2; *; ##[ *; #defw] - ... -nqed. - -ntheorem move_ok: - ∀S:Alpha.∀E:pre S.∀a,w.w .∈ \move a E ↔ (a :: w) .∈ E. -#S E; ncases E; #r b; nelim r; -##[##1,2: #a w; @; - ##[##1,3: nnormalize; *; ##[##1,3: *; #; ndestruct; ##| #abs; ncases (XXz … abs); ##] - #H; ninversion H; #; ndestruct; - ##|##*:nnormalize; *; ##[##1,3: *; #; ndestruct; ##| #H1; ncases (XXz … H1); ##] - #H; ninversion H; #; ndestruct;##] -##|#a c w; @; nnormalize; ##[*; ##[*; #; ndestruct; ##] #abs; ninversion abs; #; ndestruct;##] - *; ##[##2: #abs; ninversion abs; #; ndestruct; ##] *; #; ndestruct; -##|#a c w; @; nnormalize; - ##[ *; ##[ *; #defw; nrewrite > defw; #ca; @2; nrewrite > (eqb_t … ca); @; ##] - #H; ninversion H; #; ndestruct; - ##| *; ##[ *; #; ndestruct; ##] #H; ninversion H; ##[##2,3,4,5,6: #; ndestruct] - #d defw defa; ndestruct; @1; @; //; nrewrite > (eqb_true S d d); //. ##] -##|#r1 r2 H1 H2 a w; @; - ##[ #H; ncases (in_move_cat … H); - ##[ *; #w1; *; #w2; *; *; #defw w1m w2m; - ncases (H1 a w1); #H1w1; #_; nlapply (H1w1 w1m); #good; - nrewrite > defw; @2; @2 (a::w1); //; ncases good; ##[ *; #; ndestruct] //. - ##| - ... -##| -##| -##] -nqed. - - -notation > "x ↦* E" non associative with precedence 60 for @{move_star ? $x $E}. -nlet rec move_star (S : decidable) w E on w : bool × (pre S) ≝ - match w with - [ nil ⇒ E - | cons x w' ⇒ w' ↦* (x ↦ \snd E)]. - -ndefinition in_moves ≝ λS:decidable.λw.λE:bool × (pre S). \fst(w ↦* E). - -ncoinductive equiv (S:decidable) : bool × (pre S) → bool × (pre S) → Prop ≝ - mk_equiv: - ∀E1,E2: bool × (pre S). - \fst E1 = \fst E2 → - (∀x. equiv S (x ↦ \snd E1) (x ↦ \snd E2)) → - equiv S E1 E2. - -ndefinition NAT: decidable. - @ nat eqb; /2/. -nqed. - -include "hints_declaration.ma". - -alias symbol "hint_decl" (instance 1) = "hint_decl_Type1". -unification hint 0 ≔ ; X ≟ NAT ⊢ carr X ≡ nat. - -ninductive unit: Type[0] ≝ I: unit. - -nlet corec foo_nop (b: bool): - equiv ? - 〈 b, pc ? (ps ? 0) (pk ? (pc ? (ps ? 1) (ps ? 0))) 〉 - 〈 b, pc ? (pk ? (pc ? (ps ? 0) (ps ? 1))) (ps ? 0) 〉 ≝ ?. - @; //; #x; ncases x - [ nnormalize in ⊢ (??%%); napply (foo_nop false) - | #y; ncases y - [ nnormalize in ⊢ (??%%); napply (foo_nop false) - | #w; nnormalize in ⊢ (??%%); napply (foo_nop false) ]##] -nqed. - -(* -nlet corec foo (a: unit): - equiv NAT - (eclose NAT (pc ? (ps ? 0) (pk ? (pc ? (ps ? 1) (ps ? 0))))) - (eclose NAT (pc ? (pk ? (pc ? (ps ? 0) (ps ? 1))) (ps ? 0))) -≝ ?. - @; - ##[ nnormalize; // - ##| #x; ncases x - [ nnormalize in ⊢ (??%%); - nnormalize in foo: (? → ??%%); - @; //; #y; ncases y - [ nnormalize in ⊢ (??%%); napply foo_nop - | #y; ncases y - [ nnormalize in ⊢ (??%%); - - ##| #z; nnormalize in ⊢ (??%%); napply foo_nop ]##] - ##| #y; nnormalize in ⊢ (??%%); napply foo_nop - ##] -nqed. -*) - -ndefinition test1 : pre ? ≝ ❨ `0 | `1 ❩^* `0. -ndefinition test2 : pre ? ≝ ❨ (`0`1)^* `0 | (`0`1)^* `1 ❩. -ndefinition test3 : pre ? ≝ (`0 (`0`1)^* `1)^*. - - -nlemma foo: in_moves ? [0;0;1;0;1;1] (ɛ test3) = true. - nnormalize in match test3; - nnormalize; -//; -nqed. - -(**********************************************************) - -ninductive der (S: Type[0]) (a: S) : re S → re S → CProp[0] ≝ - der_z: der S a (z S) (z S) - | der_e: der S a (e S) (z S) - | der_s1: der S a (s S a) (e ?) - | der_s2: ∀b. a ≠ b → der S a (s S b) (z S) - | der_c1: ∀e1,e2,e1',e2'. in_l S [] e1 → der S a e1 e1' → der S a e2 e2' → - der S a (c ? e1 e2) (o ? (c ? e1' e2) e2') - | der_c2: ∀e1,e2,e1'. Not (in_l S [] e1) → der S a e1 e1' → - der S a (c ? e1 e2) (c ? e1' e2) - | der_o: ∀e1,e2,e1',e2'. der S a e1 e1' → der S a e2 e2' → - der S a (o ? e1 e2) (o ? e1' e2'). - -nlemma eq_rect_CProp0_r: - ∀A.∀a,x.∀p:eq ? x a.∀P: ∀x:A. eq ? x a → CProp[0]. P a (refl A a) → P x p. - #A; #a; #x; #p; ncases p; #P; #H; nassumption. -nqed. - -nlemma append1: ∀A.∀a:A.∀l. [a] @ l = a::l. //. nqed. - -naxiom in_l1: ∀S,r1,r2,w. in_l S [ ] r1 → in_l S w r2 → in_l S w (c S r1 r2). -(* #S; #r1; #r2; #w; nelim r1 - [ #K; ninversion K - | #H1; #H2; napply (in_c ? []); // - | (* tutti casi assurdi *) *) - -ninductive in_l' (S: Type[0]) : word S → re S → CProp[0] ≝ - in_l_empty1: ∀E.in_l S [] E → in_l' S [] E - | in_l_cons: ∀a,w,e,e'. in_l' S w e' → der S a e e' → in_l' S (a::w) e. - -ncoinductive eq_re (S: Type[0]) : re S → re S → CProp[0] ≝ - mk_eq_re: ∀E1,E2. - (in_l S [] E1 → in_l S [] E2) → - (in_l S [] E2 → in_l S [] E1) → - (∀a,E1',E2'. der S a E1 E1' → der S a E2 E2' → eq_re S E1' E2') → - eq_re S E1 E2. - -(* serve il lemma dopo? *) -ntheorem eq_re_is_eq: ∀S.∀E1,E2. eq_re S E1 E2 → ∀w. in_l ? w E1 → in_l ? w E2. - #S; #E1; #E2; #H1; #w; #H2; nelim H2 in E2 H1 ⊢ % - [ #r; #K (* ok *) - | #a; #w; #R1; #R2; #K1; #K2; #K3; #R3; #K4; @2 R2; //; ncases K4; - -(* IL VICEVERSA NON VALE *) -naxiom in_l_to_in_l: ∀S,w,E. in_l' S w E → in_l S w E. -(* #S; #w; #E; #H; nelim H - [ // - | #a; #w'; #r; #r'; #H1; (* e si cade qua sotto! *) - ] -nqed. *) +lemma distr_cat_r_eps: ∀S.∀A,C:word S →Prop. + (A ∪ {ϵ}) · C =1 A · C ∪ C. +#S #A #C @eqP_trans [|@distr_cat_r |@eqP_union_l @epsilon_cat_l] +qed. -ntheorem der1: ∀S,a,e,e',w. der S a e e' → in_l S w e' → in_l S (a::w) e. - #S; #a; #E; #E'; #w; #H; nelim H - [##1,2: #H1; ninversion H1 - [##1,8: #_; #K; (* non va ndestruct K; *) ncases (?:False); (* perche' due goal?*) /2/ - |##2,9: #X; #Y; #K; ncases (?:False); /2/ - |##3,10: #x; #y; #z; #w; #a; #b; #c; #d; #e; #K; ncases (?:False); /2/ - |##4,11: #x; #y; #z; #w; #a; #b; #K; ncases (?:False); /2/ - |##5,12: #x; #y; #z; #w; #a; #b; #K; ncases (?:False); /2/ - |##6,13: #x; #y; #K; ncases (?:False); /2/ - |##7,14: #x; #y; #z; #w; #a; #b; #c; #d; #K; ncases (?:False); /2/] -##| #H1; ninversion H1 - [ // - | #X; #Y; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #c; #d; #e; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #K; ncases (?:False); /2/ - | #x; #y; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #c; #d; #K; ncases (?:False); /2/ ] -##| #H1; #H2; #H3; ninversion H3 - [ #_; #K; ncases (?:False); /2/ - | #X; #Y; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #c; #d; #e; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #K; ncases (?:False); /2/ - | #x; #y; #K; ncases (?:False); /2/ - | #x; #y; #z; #w; #a; #b; #c; #d; #K; ncases (?:False); /2/ ] -##| #r1; #r2; #r1'; #r2'; #H1; #H2; #H3; #H4; #H5; #H6; \ No newline at end of file -- 2.39.2