axiom binary_to_bin_char :∀sig,csl,csr,a.
csl@true::csr=bin_char sig a → FS_nth ? (length ? csr) = Some ? a.
-lemma binaryTM_phase1_midtape_aux :
+lemma binaryTM_phase0_midtape_aux :
∀sig,M,q,ls,a,rs,k.
halt sig M q=false →
∀csr,csl,t,ch.length ? csr < S (2*FS_crd sig) →
t = mk_tape ? (reverse ? csl@ls) (option_hd ? (csr@rs)) (tail ? (csr@rs)) →
csl@csr = bin_char sig a →
+ |csl@csr| = FS_crd sig →
+ (index_of_FS ? a < |csl| → ch = Some ? a) →
loopM ? (mk_binaryTM sig M) (S (length ? csr) + k)
(mk_config ?? (〈q,bin0,ch,length ? csr〉) t)
= loopM ? (mk_binaryTM sig M) k
(mk_config ?? (〈q,bin1,Some ? a,FS_crd sig〉)
- (mk_tape ? (reverse ? (bin_char ? a)@ls) (option_hd ? rs) (tail ? rs))). [2,3://]
+ (mk_tape ? (reverse ? (bin_char ? a)@ls) (option_hd ? rs) (tail ? rs))). [2,3:/2 by O/]
#sig #M #q #ls #a #rs #k #Hhalt #csr elim csr
-[ #csl #t #ch #Hlen #Ht >append_nil #Hcsl >loopM_unfold >loop_S_false [|normalize //]
+[ #csl #t #ch #Hlen #Ht >append_nil #Hcsl #Hlencsl #Hch >loopM_unfold >loop_S_false [|normalize //]
+ >Hch [| >Hlencsl (* lemmatize *) @daemon]
<loopM_unfold @eq_f >binaryTM_bin0_bin1 @eq_f >Ht
whd in match (step ???); whd in match (trans ???); <Hcsl %
| #c cases c
- [ #csr0 #IH #csl #t #ch #Hlen #Ht #Heq >loopM_unfold >loop_S_false [|normalize //]
+ [ #csr0 #IH #csl #t #ch #Hlen #Ht #Heq #Hcrd #Hch >loopM_unfold >loop_S_false [|normalize //]
<loopM_unfold lapply (binary_to_bin_char … Heq) #Ha >binaryTM_bin0_true
[| >Ht % ]
- lapply (IH (csl@[true]) (tape_move FinBool t R) ????)
+ lapply (IH (csl@[true]) (tape_move FinBool t R) ??????)
[ //
+ | >associative_append @Hcrd
+ | >associative_append @Heq
| >Ht whd in match (option_hd ??) in ⊢ (??%?); whd in match (tail ??) in ⊢ (??%?);
cases csr0
[ cases rs
[ normalize >rev_append_def >rev_append_def >reverse_append %
| #r1 #rs1 normalize >rev_append_def >rev_append_def >reverse_append % ]
| #c1 #csr1 normalize >rev_append_def >rev_append_def >reverse_append % ]
- | /2/
- | @(Some ? a) ]
- #H whd in match (plus ??); >Ha >H @eq_f @eq_f2 //
-
+ | /2 by lt_S_to_lt/
+ |]
+ #H whd in match (plus ??); >H @eq_f @eq_f2 %
+ | #csr0 #IH #csl #t #ch #Hlen #Ht #Heq #Hcrd #Hch >loopM_unfold >loop_S_false [|normalize //]
+ <loopM_unfold >binaryTM_bin0_false [| >Ht % ]
+ lapply (IH (csl@[false]) (tape_move FinBool t R) ??????)
+ [6: @ch
+ | (* by cases: if index < |csl|, then Hch, else False *)
+ @daemon
+ | >associative_append @Hcrd
+ | >associative_append @Heq
+ | >Ht whd in match (option_hd ??) in ⊢ (??%?); whd in match (tail ??) in ⊢ (??%?);
+ cases csr0
+ [ cases rs
+ [ normalize >rev_append_def >rev_append_def >reverse_append %
+ | #r1 #rs1 normalize >rev_append_def >rev_append_def >reverse_append % ]
+ | #c1 #csr1 normalize >rev_append_def >rev_append_def >reverse_append % ]
+ | /2 by lt_S_to_lt/
+ |]
+ #H whd in match (plus ??); >H @eq_f @eq_f2 %
+ ]
+]
qed.
-
-lemma binaryTM_phase1_midtape :
- ∀sig,M,t,q,ls,a,rs,ch.
+lemma binaryTM_phase0_midtape :
+ ∀sig,M,t,q,ls,a,rs,ch,k.
+ halt sig M q=false →
t = mk_tape ? ls (option_hd ? (bin_char ? a)) (tail ? (bin_char sig a@rs)) →
- step ? (mk_binaryTM sig M) (mk_config ?? (〈q,bin0,ch,FS_crd sig〉) t)
- = mk_config ?? (〈q,bin1,ch,to_initN (FS_crd sig) ??〉)
- (mk_tape ? (reverse ? (bin_char ? a)@ls) (option_hd ? rs) (tail ? rs)). [2,3://]
-#sig #M #t #q #ls #a #rs #ch #Ht
-whd in match (step ???); whd in match (trans ???);
->Hcur %
+ loopM ? (mk_binaryTM sig M) (S (length ? (bin_char ? a)) + k)
+ (mk_config ?? (〈q,bin0,ch,length ? (bin_char ? a)〉) t)
+ = loopM ? (mk_binaryTM sig M) k
+ (mk_config ?? (〈q,bin1,Some ? a,FS_crd sig〉)
+ (mk_tape ? (reverse ? (bin_char ? a)@ls) (option_hd ? rs) (tail ? rs))). [|@daemon|//]
+#sig #M #t #q #ls #a #rs #ch #k #Hhalt #Ht
+cut (∃c,cl.bin_char sig a = c::cl) [@daemon] * #c * #cl #Ha >Ha
+>(binaryTM_phase0_midtape_aux ? M q ls a rs ? ? (c::cl) [ ] t ch) //
+[| normalize #Hfalse @False_ind cases (not_le_Sn_O ?) /2/
+| <Ha (* |bin_char sig ?| = FS_crd sig *) @daemon
+| >Ha %
+| >Ht >Ha % ]
+<Ha %
+qed.
+
+lemma binaryTM_phase0_None :
+ ∀sig,M,t,q,ch,k,n.
+ n < 2*FS_crd sig →
+ halt sig M q=false →
+ current ? t = None ? →
+ loopM ? (mk_binaryTM sig M) (S k) (mk_config ?? (〈q,bin0,ch,S n〉) t)
+ = loopM ? (mk_binaryTM sig M) k
+ (mk_config ?? (〈q,bin4,None ?,to_initN O ??〉) (tape_move ? t R)). [2,3: /2 by le_to_lt_to_lt/ ]
+#sig #M #t #q #ch #k #n #Hn #Hhalt cases t
+[ >loopM_unfold >loop_S_false [|@Hhalt] //
+| #r0 #rs0 >loopM_unfold >loop_S_false [|@Hhalt] //
+| #l0 #ls0 >loopM_unfold >loop_S_false [|@Hhalt] //
+| #ls #cur #rs normalize in ⊢ (%→?); #H destruct (H) ]
+qed.
+
+lemma binaryTM_bin1_O :
+ ∀sig,M,t,q,ch.
+ step ? (mk_binaryTM sig M) (mk_config ?? (〈q,bin1,ch,O〉) t)
+ = mk_config ?? (〈q,bin2,ch,to_initN (FS_crd sig) ??〉) t. [2,3://]
+#sig #M #t #q #ch %
+qed.
+
+lemma binaryTM_bin1_S :
+ ∀sig,M,t,q,ch,k. S k <S (2*FS_crd sig) →
+ step ? (mk_binaryTM sig M) (mk_config ?? (〈q,bin1,ch,S k〉) t)
+ = mk_config ?? (〈q,bin1,ch,to_initN k ??〉) (tape_move ? t L). [2,3:/2 by lt_S_to_lt/]
+#sig #M #t #q #ch #k #HSk %
+qed.
+
+lemma binaryTM_phase1 :
+ ∀sig,M,q,ls1,ls2,cur,rs,ch,k.
+ |ls1| = FS_crd sig → (cur = None ? → rs = [ ]) →
+ loopM ? (mk_binaryTM sig M) (S (FS_crd sig) + k)
+ (mk_config ?? (〈q,bin1,ch,FS_crd sig〉) (mk_tape ? (ls1@ls2) cur rs))
+ = loopM ? (mk_binaryTM sig M) k
+ (mk_config ?? (〈q,bin2,ch,FS_crd sig〉)
+ (mk_tape ? ls2 (option_hd ? (reverse ? ls1@option_cons ? cur rs))
+ (tail ? (reverse ? ls1@option_cons ? cur rs)))). [2,3:/2 by O/]
+cut (∀sig,M,q,ls1,ls2,ch,k,n,cur,rs.
+ |ls1| = n → n<S (2*FS_crd sig) → (cur = None ? → rs = [ ]) →
+ loopM ? (mk_binaryTM sig M) (S n + k)
+ (mk_config ?? (〈q,bin1,ch,n〉) (mk_tape ? (ls1@ls2) cur rs))
+ = loopM ? (mk_binaryTM sig M) k
+ (mk_config ?? (〈q,bin2,ch,FS_crd sig〉)
+ (mk_tape ? ls2 (option_hd ? (reverse ? ls1@option_cons ? cur rs))
+ (tail ? (reverse ? ls1@option_cons ? cur rs))))) [1,2://]
+[ #sig #M #q #ls1 #ls2 #ch #k elim ls1
+ [ #n normalize in ⊢ (%→?); #cur #rs #Hn <Hn #Hcrd #Hcur >loopM_unfold >loop_S_false [| % ]
+ >binaryTM_bin1_O cases cur in Hcur;
+ [ #H >(H (refl ??)) -H %
+ | #cur' #_ % ]
+ | #l0 #ls0 #IH * [ #cur #rs normalize in ⊢ (%→?); #H destruct (H) ]
+ #n #cur #rs normalize in ⊢ (%→?); #H destruct (H) #Hlt #Hcur
+ >loopM_unfold >loop_S_false [|%] >binaryTM_bin1_S
+ <(?:mk_tape ? (ls0@ls2) (Some ? l0) (option_cons ? cur rs) =
+ tape_move FinBool (mk_tape FinBool ((l0::ls0)@ls2) cur rs) L)
+ [| cases cur in Hcur; [ #H >(H ?) // | #cur' #_ % ] ]
+ >(?:loop (config FinBool (states FinBool (mk_binaryTM sig M))) (S (|ls0|)+k)
+ (step FinBool (mk_binaryTM sig M))
+ (λc:config FinBool (states FinBool (mk_binaryTM sig M))
+ .halt FinBool (mk_binaryTM sig M)
+ (cstate FinBool (states FinBool (mk_binaryTM sig M)) c))
+ (mk_config FinBool (states FinBool (mk_binaryTM sig M))
+ 〈q,bin1,ch,to_initN (|ls0|) (S (2*FS_crd sig))
+ (lt_S_to_lt (|ls0|) (S (2*FS_crd sig)) Hlt)〉
+ (mk_tape FinBool (ls0@ls2) (Some FinBool l0) (option_cons FinBool cur rs)))
+ = loopM FinBool (mk_binaryTM sig M) k
+ (mk_config FinBool (states FinBool (mk_binaryTM sig M))
+ 〈q,bin2,〈ch,FS_crd sig〉〉
+ (mk_tape FinBool ls2
+ (option_hd FinBool (reverse FinBool ls0@l0::option_cons FinBool cur rs))
+ (tail FinBool (reverse FinBool ls0@l0::option_cons FinBool cur rs)))))
+ [| /2/
+ | >(?: l0::option_cons ? cur rs = option_cons ? (Some ? l0) (option_cons ? cur rs)) [| % ]
+ @trans_eq [|| @(IH ??? (refl ??)) [ /2 by lt_S_to_lt/ | #H destruct (H) ] ]
+ %
+ ]
+ >reverse_cons >associative_append %
+ ]
+| #Hcut #sig #M #q #ls1 #ls2 #cur #rs #ch #k #Hlen @Hcut // ]
+qed.
+
+lemma binaryTM_bin3_O :
+ ∀sig,M,t,q,ch.
+ step ? (mk_binaryTM sig M) (mk_config ?? (〈q,bin3,ch,O〉) t)
+ = mk_config ?? (〈q,bin0,None ?,to_initN (FS_crd sig) ??〉) t. [2,3://]
+#sig #M #t #q #ch %
+qed.
+
+lemma binaryTM_bin3_S :
+ ∀sig,M,t,q,ch,k. S k <S (2*FS_crd sig) →
+ step ? (mk_binaryTM sig M) (mk_config ?? (〈q,bin3,ch,S k〉) t)
+ = mk_config ?? (〈q,bin3,ch,to_initN k ??〉) (tape_move ? t L). [2,3:/2 by lt_S_to_lt/]
+#sig #M #t #q #ch #k #HSk %
+qed.
+
+lemma binaryTM_phase3 :∀sig,M,q,ls1,ls2,ch,k,n,cur,rs.
+ |ls1| = n → n<S (2*FS_crd sig) → (cur = None ? → rs = [ ]) →
+ loopM ? (mk_binaryTM sig M) (S n + k)
+ (mk_config ?? (〈q,bin3,ch,n〉) (mk_tape ? (ls1@ls2) cur rs))
+ = loopM ? (mk_binaryTM sig M) k
+ (mk_config ?? (〈q,bin0,None ?,FS_crd sig〉)
+ (mk_tape ? ls2 (option_hd ? (reverse ? ls1@option_cons ? cur rs))
+ (tail ? (reverse ? ls1@option_cons ? cur rs)))). [2,3://]
+#sig #M #q #ls1 #ls2 #ch #k elim ls1
+[ #n normalize in ⊢ (%→?); #cur #rs #Hn <Hn #Hcrd #Hcur >loopM_unfold >loop_S_false [| % ]
+ >binaryTM_bin3_O cases cur in Hcur;
+ [ #H >(H (refl ??)) -H %
+ | #cur' #_ % ]
+| #l0 #ls0 #IH * [ #cur #rs normalize in ⊢ (%→?); #H destruct (H) ]
+ #n #cur #rs normalize in ⊢ (%→?); #H destruct (H) #Hlt #Hcur
+ >loopM_unfold >loop_S_false [|%] >binaryTM_bin3_S
+ <(?:mk_tape ? (ls0@ls2) (Some ? l0) (option_cons ? cur rs) =
+ tape_move FinBool (mk_tape FinBool ((l0::ls0)@ls2) cur rs) L)
+ [| cases cur in Hcur; [ #H >(H ?) // | #cur' #_ % ] ]
+ >(?:loop (config FinBool (states FinBool (mk_binaryTM sig M))) (S (|ls0|)+k)
+ (step FinBool (mk_binaryTM sig M))
+ (λc:config FinBool (states FinBool (mk_binaryTM sig M))
+ .halt FinBool (mk_binaryTM sig M)
+ (cstate FinBool (states FinBool (mk_binaryTM sig M)) c))
+ (mk_config FinBool (states FinBool (mk_binaryTM sig M))
+ 〈q,bin3,ch,to_initN (|ls0|) (S (2*FS_crd sig))
+ (lt_S_to_lt (|ls0|) (S (2*FS_crd sig)) Hlt)〉
+ (mk_tape FinBool (ls0@ls2) (Some FinBool l0) (option_cons FinBool cur rs)))
+ = loopM FinBool (mk_binaryTM sig M) k
+ (mk_config FinBool (states FinBool (mk_binaryTM sig M))
+ 〈q,bin0,〈None ?,FS_crd sig〉〉
+ (mk_tape FinBool ls2
+ (option_hd FinBool (reverse FinBool ls0@l0::option_cons FinBool cur rs))
+ (tail FinBool (reverse FinBool ls0@l0::option_cons FinBool cur rs)))))
+ [| /2/
+ | >(?: l0::option_cons ? cur rs = option_cons ? (Some ? l0) (option_cons ? cur rs)) [| % ]
+ @trans_eq [|| @(IH ??? (refl ??)) [ /2 by lt_S_to_lt/ | #H destruct (H) ] ]
+ %
+ ]
+ >reverse_cons >associative_append %
+]
qed.
+STOP
lemma binaryTM_loop :
∀sig,M,i,t,q,tf,qf.
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