X-Git-Url: http://matita.cs.unibo.it/gitweb/?a=blobdiff_plain;f=matita%2Fmatita%2Flib%2Fturing%2Funiversal%2Fmove_char_l.ma;h=bed0ba5960e6654ca999cf67f5defd9d35e12c75;hb=bc02962ed23518a09e7f4ed875d7d967a33de135;hp=bc6e5c4aafa02dd4746a4cca646cf892f5f3a144;hpb=9a7e0697f0b305e4ba26b67c37681c434709509a;p=helm.git diff --git a/matita/matita/lib/turing/universal/move_char_l.ma b/matita/matita/lib/turing/universal/move_char_l.ma index bc6e5c4aa..bed0ba596 100644 --- a/matita/matita/lib/turing/universal/move_char_l.ma +++ b/matita/matita/lib/turing/universal/move_char_l.ma @@ -12,7 +12,8 @@ (* MOVE_CHAR (left) MACHINE -Sposta il carattere binario su cui si trova la testina appena prima del primo # alla sua destra. +Sposta il carattere binario su cui si trova la testina appena prima del primo # +alla sua sinistra. Input: (ls,cs,rs can be empty; # is a parameter) @@ -31,77 +32,13 @@ Final state = 〈4,#〉 *) -include "turing/while_machine.ma". - -definition mcl_states : FinSet → FinSet ≝ λalpha:FinSet.FinProd (initN 5) alpha. - -definition mcl0 : initN 5 ≝ mk_Sig ?? 0 (leb_true_to_le 1 5 (refl …)). -definition mcl1 : initN 5 ≝ mk_Sig ?? 1 (leb_true_to_le 2 5 (refl …)). -definition mcl2 : initN 5 ≝ mk_Sig ?? 2 (leb_true_to_le 3 5 (refl …)). -definition mcl3 : initN 5 ≝ mk_Sig ?? 3 (leb_true_to_le 4 5 (refl …)). -definition mcl4 : initN 5 ≝ mk_Sig ?? 4 (leb_true_to_le 5 5 (refl …)). - -definition mcl_step ≝ - λalpha:FinSet.λsep:alpha. - mk_TM alpha (mcl_states alpha) - (λp.let 〈q,a〉 ≝ p in - let 〈q',b〉 ≝ q in - let q' ≝ pi1 nat (λi.i<5) q' in (* perche' devo passare il predicato ??? *) - match a with - [ None ⇒ 〈〈mcl4,sep〉,None ?〉 - | Some a' ⇒ - match q' with - [ O ⇒ (* qinit *) - match a' == sep with - [ true ⇒ 〈〈mcl4,sep〉,None ?〉 - | false ⇒ 〈〈mcl1,a'〉,Some ? 〈a',R〉〉 ] - | S q' ⇒ match q' with - [ O ⇒ (* q1 *) - 〈〈mcl2,a'〉,Some ? 〈b,L〉〉 - | S q' ⇒ match q' with - [ O ⇒ (* q2 *) - 〈〈mcl3,sep〉,Some ? 〈b,L〉〉 - | S q' ⇒ match q' with - [ O ⇒ (* qacc *) - 〈〈mcl3,sep〉,None ?〉 - | S q' ⇒ (* qfail *) - 〈〈mcl4,sep〉,None ?〉 ] ] ] ] ]) - 〈mcl0,sep〉 - (λq.let 〈q',a〉 ≝ q in q' == mcl3 ∨ q' == mcl4). - -lemma mcl_q0_q1 : - ∀alpha:FinSet.∀sep,a,ls,a0,rs. - a0 == sep = false → - step alpha (mcl_step alpha sep) - (mk_config ?? 〈mcl0,a〉 (mk_tape … ls (Some ? a0) rs)) = - mk_config alpha (states ? (mcl_step alpha sep)) 〈mcl1,a0〉 - (tape_move_right alpha ls a0 rs). -#alpha #sep #a * -[ #a0 #rs #Ha0 whd in ⊢ (??%?); - normalize in match (trans ???); >Ha0 % -| #a1 #ls #a0 #rs #Ha0 whd in ⊢ (??%?); - normalize in match (trans ???); >Ha0 % -] -qed. - -lemma mcl_q1_q2 : - ∀alpha:FinSet.∀sep,a,ls,a0,rs. - step alpha (mcl_step alpha sep) - (mk_config ?? 〈mcl1,a〉 (mk_tape … ls (Some ? a0) rs)) = - mk_config alpha (states ? (mcl_step alpha sep)) 〈mcl2,a0〉 - (tape_move_left alpha ls a rs). -#alpha #sep #a #ls #a0 * // -qed. - -lemma mcl_q2_q3 : - ∀alpha:FinSet.∀sep,a,ls,a0,rs. - step alpha (mcl_step alpha sep) - (mk_config ?? 〈mcl2,a〉 (mk_tape … ls (Some ? a0) rs)) = - mk_config alpha (states ? (mcl_step alpha sep)) 〈mcl3,sep〉 - (tape_move_left alpha ls a rs). -#alpha #sep #a #ls #a0 * // -qed. +include "turing/basic_machines.ma". +include "turing/if_machine.ma". +definition mcl_step ≝ λalpha:FinSet.λsep:alpha. + ifTM alpha (test_char ? (λc.¬c==sep)) + (single_finalTM … (seq … (swap alpha sep) (move_l ?))) (nop ?) tc_true. + definition Rmcl_step_true ≝ λalpha,sep,t1,t2. ∀a,b,ls,rs. @@ -113,67 +50,32 @@ definition Rmcl_step_false ≝ λalpha,sep,t1,t2. right ? t1 ≠ [] → current alpha t1 ≠ None alpha → current alpha t1 = Some alpha sep ∧ t2 = t1. - -lemma mcl_trans_init_sep: - ∀alpha,sep,x. - trans ? (mcl_step alpha sep) 〈〈mcl0,x〉,Some ? sep〉 = 〈〈mcl4,sep〉,None ?〉. -#alpha #sep #x normalize >(\b ?) // -qed. - -lemma mcl_trans_init_not_sep: - ∀alpha,sep,x,y.y == sep = false → - trans ? (mcl_step alpha sep) 〈〈mcl0,x〉,Some ? y〉 = 〈〈mcl1,y〉,Some ? 〈y,R〉〉. -#alpha #sep #x #y #H1 normalize >H1 // -qed. lemma sem_mcl_step : ∀alpha,sep. - accRealize alpha (mcl_step alpha sep) - 〈mcl3,sep〉 (Rmcl_step_true alpha sep) (Rmcl_step_false alpha sep). -#alpha #sep cut (∀P:Prop.〈mcl4,sep〉=〈mcl3,sep〉→P) - [#P whd in ⊢ ((??(???%?)(???%?))→?); #Hfalse destruct] #Hfalse -* -[@(ex_intro ?? 2) - @(ex_intro … (mk_config ?? 〈mcl4,sep〉 (niltape ?))) - % [% [whd in ⊢ (??%?);% |@Hfalse] |#H1 #H2 @False_ind @(absurd ?? H2) %] -|#l0 #lt0 @(ex_intro ?? 2) - @(ex_intro … (mk_config ?? 〈mcl4,sep〉 (leftof ? l0 lt0))) - % [% [whd in ⊢ (??%?);% |@Hfalse] |#H1 #H2 #H3 @False_ind @(absurd ?? H3) %] -|#r0 #rt0 @(ex_intro ?? 2) - @(ex_intro … (mk_config ?? 〈mcl4,sep〉 (rightof ? r0 rt0))) - % [% [whd in ⊢ (??%?);% |@Hfalse] |#H1 #H2 #H3 @False_ind @(absurd ?? H3) %] -| #lt #c #rt cases (true_or_false (c == sep)) #Hc - [ @(ex_intro ?? 2) - @(ex_intro ?? (mk_config ?? 〈mcl4,sep〉 (midtape ? lt c rt))) - % [ % - [ >(\P Hc) >loop_S_false // >loop_S_true - [ @eq_f whd in ⊢ (??%?); >mcl_trans_init_sep % - |>(\P Hc) whd in ⊢(??(???(???%))?); >mcl_trans_init_sep % ] - |@Hfalse] - |#_ #H1 #H2 % // normalize >(\P Hc) % ] - |@(ex_intro ?? 4) cases rt - [ @ex_intro - [|% [ % - [ >loop_S_false // >mcl_q0_q1 // - | normalize in ⊢ (%→?); @Hfalse] - | normalize in ⊢ (%→?); #_ #H1 @False_ind @(absurd ?? H1) % ] ] - | #r0 #rt0 @ex_intro - [| % [ % - [ >loop_S_false // >mcl_q0_q1 // - | #_ #a #b #ls #rs #Hb destruct (Hb) % - [ @(\Pf Hc) - | >mcl_q1_q2 >mcl_q2_q3 cases ls normalize // ] ] - | normalize in ⊢ (% → ?); * #Hfalse - @False_ind /2/ ] - ] - ] - ] -] + mcl_step alpha sep ⊨ + [inr … (inl … (inr … start_nop)): Rmcl_step_true alpha sep, Rmcl_step_false alpha sep]. +#alpha #sep + @(acc_sem_if_app … + (sem_test_char …) (sem_seq …(sem_swap …) (sem_move_l …)) (sem_nop …)) + [#intape #outtape #tapea whd in ⊢ (%→%→%); + #Htapea * #tapeb * whd in ⊢ (%→%→?); + #Htapeb #Houttape #a #b #ls #rs #Hintape + >Hintape in Htapea; #Htapea cases (Htapea ? (refl …)) -Htapea + #Hbsep #Htapea % [@(\Pf (injective_notb ? false Hbsep))] + @Houttape @Htapeb // + |#intape #outtape #tapea whd in ⊢ (%→%→%); + cases (current alpha intape) + [#_ #_ #_ * #Hfalse @False_ind @Hfalse % + |#c #H #Htapea #_ #_ cases (H c (refl …)) #csep #Hintape % // + lapply (injective_notb ? true csep) -csep #csep >(\P csep) // + ] + ] qed. - -(* the move_char (variant c) machine *) + +(* the move_char (variant left) machine *) definition move_char_l ≝ - λalpha,sep.whileTM alpha (mcl_step alpha sep) 〈mcl3,sep〉. + λalpha,sep.whileTM alpha (mcl_step alpha sep) (inr … (inl … (inr … start_nop))). definition R_move_char_l ≝ λalpha,sep,t1,t2. @@ -248,4 +150,17 @@ lemma terminate_move_char_l : [#Hb @False_ind /2/ | #Hmemb cases (orb_true_l … Hmemb) [#eqsep %1 >(\P eqsep) // | #H %2 //] ] -qed. \ No newline at end of file +qed. + +(* NO GOOD: we must stop if current = None too!!! +lemma ssem_move_char_l : + ∀alpha,sep. + Realize alpha (move_char_l alpha sep) (R_move_char_l alpha sep). +#alpha #sep * +[ %{5} % [| % [whd in ⊢ (??%?); + @WRealize_to_Realize // @terminate_move_char_l +*) + +axiom ssem_move_char_l : + ∀alpha,sep. + Realize alpha (move_char_l alpha sep) (R_move_char_l alpha sep).