diff -r 000000000000 -r a5a9c433f639 src/LK/LK.thy --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/src/LK/LK.thy Thu Sep 16 12:20:38 1993 +0200 @@ -0,0 +1,124 @@ +(* Title: LK/lk.thy + ID: $Id$ + Author: Lawrence C Paulson, Cambridge University Computer Laboratory + Copyright 1993 University of Cambridge + +Classical First-Order Sequent Calculus +*) + +LK = Pure + +classes term < logic +default term +types o 0 + sequence,seqobj,seqcont,sequ,sobj 0 +arities o :: logic +consts + True,False :: "o" + "=" :: "['a,'a] => o" (infixl 50) + "Not" :: "o => o" ("~ _" [40] 40) + "&" :: "[o,o] => o" (infixr 35) + "|" :: "[o,o] => o" (infixr 30) + "-->","<->" :: "[o,o] => o" (infixr 25) + The :: "('a => o) => 'a" (binder "THE " 10) + All :: "('a => o) => o" (binder "ALL " 10) + Ex :: "('a => o) => o" (binder "EX " 10) + + (*Representation of sequents*) + Trueprop :: "[sobj=>sobj,sobj=>sobj] => prop" + Seqof :: "o => sobj=>sobj" + "@Trueprop" :: "[sequence,sequence] => prop" ("((_)/ |- (_))" [6,6] 5) + "@MtSeq" :: "sequence" ("" [] 1000) + "@NmtSeq" :: "[seqobj,seqcont] => sequence" ("__" [] 1000) + "@MtSeqCont" :: "seqcont" ("" [] 1000) + "@SeqCont" :: "[seqobj,seqcont] => seqcont" (",/ __" [] 1000) + "" :: "o => seqobj" ("_" [] 1000) + "@SeqId" :: "id => seqobj" ("$_" [] 1000) + "@SeqVar" :: "var => seqobj" ("$_") + +rules + (*Structural rules*) + + basic "$H, P, $G |- $E, P, $F" + + thinR "$H |- $E, $F ==> $H |- $E, P, $F" + thinL "$H, $G |- $E ==> $H, P, $G |- $E" + + cut "[| $H |- $E, P; $H, P |- $E |] ==> $H |- $E" + + (*Propositional rules*) + + conjR "[| $H|- $E, P, $F; $H|- $E, Q, $F |] ==> $H|- $E, P&Q, $F" + conjL "$H, P, Q, $G |- $E ==> $H, P & Q, $G |- $E" + + disjR "$H |- $E, P, Q, $F ==> $H |- $E, P|Q, $F" + disjL "[| $H, P, $G |- $E; $H, Q, $G |- $E |] ==> $H, P|Q, $G |- $E" + + impR "$H, P |- $E, Q, $F ==> $H |- $E, P-->Q, $F" + impL "[| $H,$G |- $E,P; $H, Q, $G |- $E |] ==> $H, P-->Q, $G |- $E" + + notR "$H, P |- $E, $F ==> $H |- $E, ~P, $F" + notL "$H, $G |- $E, P ==> $H, ~P, $G |- $E" + + FalseL "$H, False, $G |- $E" + + True_def "True == False-->False" + iff_def "P<->Q == (P-->Q) & (Q-->P)" + + (*Quantifiers*) + + allR "(!!x.$H |- $E, P(x), $F) ==> $H |- $E, ALL x.P(x), $F" + allL "$H, P(x), $G, ALL x.P(x) |- $E ==> $H, ALL x.P(x), $G |- $E" + + exR "$H |- $E, P(x), $F, EX x.P(x) ==> $H |- $E, EX x.P(x), $F" + exL "(!!x.$H, P(x), $G |- $E) ==> $H, EX x.P(x), $G |- $E" + + (*Equality*) + + refl "$H |- $E, a=a, $F" + sym "$H |- $E, a=b, $F ==> $H |- $E, b=a, $F" + trans "[| $H|- $E, a=b, $F; $H|- $E, b=c, $F |] ==> $H|- $E, a=c, $F" + + + (*Descriptions*) + + The "[| $H |- $E, P(a), $F; !!x.$H, P(x) |- $E, x=a, $F |] ==> \ +\ $H |- $E, P(THE x.P(x)), $F" +end + +ML + +(*Abstract over "sobj" -- representation of a sequence of formulae *) +fun abs_sobj t = Abs("sobj", Type("sobj",[]), t); + +(*Representation of empty sequence*) +val Sempty = abs_sobj (Bound 0); + +fun seq_obj_tr(Const("@SeqId",_)$id) = id | + seq_obj_tr(Const("@SeqVar",_)$id) = id | + seq_obj_tr(fm) = Const("Seqof",dummyT)$fm; + +fun seq_tr(_$obj$seq) = seq_obj_tr(obj)$seq_tr(seq) | + seq_tr(_) = Bound 0; + +fun seq_tr1(Const("@MtSeq",_)) = Sempty | + seq_tr1(seq) = abs_sobj(seq_tr seq); + +fun true_tr[s1,s2] = Const("Trueprop",dummyT)$seq_tr1 s1$seq_tr1 s2; + +fun seq_obj_tr'(Const("Seqof",_)$fm) = fm | + seq_obj_tr'(id) = Const("@SeqId",dummyT)$id; + +fun seq_tr'(obj$sq,C) = + let val sq' = case sq of + Bound 0 => Const("@MtSeqCont",dummyT) | + _ => seq_tr'(sq,Const("@SeqCont",dummyT)) + in C $ seq_obj_tr' obj $ sq' end; + +fun seq_tr1'(Bound 0) = Const("@MtSeq",dummyT) | + seq_tr1' s = seq_tr'(s,Const("@NmtSeq",dummyT)); + +fun true_tr'[Abs(_,_,s1),Abs(_,_,s2)] = + Const("@Trueprop",dummyT)$seq_tr1' s1$seq_tr1' s2; + +val parse_translation = [("@Trueprop",true_tr)]; +val print_translation = [("Trueprop",true_tr')];