(* Title: Sequents/Sequents.thy
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1993 University of Cambridge
*)
section {* Parsing and pretty-printing of sequences *}
theory Sequents
imports Pure
keywords "print_pack" :: diag
begin
setup Pure_Thy.old_appl_syntax_setup
declare [[unify_trace_bound = 20, unify_search_bound = 40]]
typedecl o
subsection {* Sequences *}
typedecl
seq'
consts
SeqO' :: "[o,seq']=>seq'"
Seq1' :: "o=>seq'"
subsection {* Concrete syntax *}
nonterminal seq and seqobj and seqcont
syntax
"_SeqEmp" :: seq ("")
"_SeqApp" :: "[seqobj,seqcont] => seq" ("__")
"_SeqContEmp" :: seqcont ("")
"_SeqContApp" :: "[seqobj,seqcont] => seqcont" (",/ __")
"_SeqO" :: "o => seqobj" ("_")
"_SeqId" :: "'a => seqobj" ("$_")
type_synonym single_seqe = "[seq,seqobj] => prop"
type_synonym single_seqi = "[seq'=>seq',seq'=>seq'] => prop"
type_synonym two_seqi = "[seq'=>seq', seq'=>seq'] => prop"
type_synonym two_seqe = "[seq, seq] => prop"
type_synonym three_seqi = "[seq'=>seq', seq'=>seq', seq'=>seq'] => prop"
type_synonym three_seqe = "[seq, seq, seq] => prop"
type_synonym four_seqi = "[seq'=>seq', seq'=>seq', seq'=>seq', seq'=>seq'] => prop"
type_synonym four_seqe = "[seq, seq, seq, seq] => prop"
type_synonym sequence_name = "seq'=>seq'"
syntax
(*Constant to allow definitions of SEQUENCES of formulas*)
"_Side" :: "seq=>(seq'=>seq')" ("<<(_)>>")
ML {*
(* parse translation for sequences *)
fun abs_seq' t = Abs ("s", Type (@{type_name seq'}, []), t);
fun seqobj_tr (Const (@{syntax_const "_SeqO"}, _) $ f) =
Const (@{const_syntax SeqO'}, dummyT) $ f
| seqobj_tr (_ $ i) = i;
fun seqcont_tr (Const (@{syntax_const "_SeqContEmp"}, _)) = Bound 0
| seqcont_tr (Const (@{syntax_const "_SeqContApp"}, _) $ so $ sc) =
seqobj_tr so $ seqcont_tr sc;
fun seq_tr (Const (@{syntax_const "_SeqEmp"}, _)) = abs_seq' (Bound 0)
| seq_tr (Const (@{syntax_const "_SeqApp"}, _) $ so $ sc) =
abs_seq'(seqobj_tr so $ seqcont_tr sc);
fun singlobj_tr (Const (@{syntax_const "_SeqO"},_) $ f) =
abs_seq' ((Const (@{const_syntax SeqO'}, dummyT) $ f) $ Bound 0);
(* print translation for sequences *)
fun seqcont_tr' (Bound 0) =
Const (@{syntax_const "_SeqContEmp"}, dummyT)
| seqcont_tr' (Const (@{const_syntax SeqO'}, _) $ f $ s) =
Const (@{syntax_const "_SeqContApp"}, dummyT) $
(Const (@{syntax_const "_SeqO"}, dummyT) $ f) $ seqcont_tr' s
| seqcont_tr' (i $ s) =
Const (@{syntax_const "_SeqContApp"}, dummyT) $
(Const (@{syntax_const "_SeqId"}, dummyT) $ i) $ seqcont_tr' s;
fun seq_tr' s =
let
fun seq_itr' (Bound 0) = Const (@{syntax_const "_SeqEmp"}, dummyT)
| seq_itr' (Const (@{const_syntax SeqO'}, _) $ f $ s) =
Const (@{syntax_const "_SeqApp"}, dummyT) $
(Const (@{syntax_const "_SeqO"}, dummyT) $ f) $ seqcont_tr' s
| seq_itr' (i $ s) =
Const (@{syntax_const "_SeqApp"}, dummyT) $
(Const (@{syntax_const "_SeqId"}, dummyT) $ i) $ seqcont_tr' s
in
case s of
Abs (_, _, t) => seq_itr' t
| _ => s $ Bound 0
end;
fun single_tr c [s1, s2] =
Const (c, dummyT) $ seq_tr s1 $ singlobj_tr s2;
fun two_seq_tr c [s1, s2] =
Const (c, dummyT) $ seq_tr s1 $ seq_tr s2;
fun three_seq_tr c [s1, s2, s3] =
Const (c, dummyT) $ seq_tr s1 $ seq_tr s2 $ seq_tr s3;
fun four_seq_tr c [s1, s2, s3, s4] =
Const (c, dummyT) $ seq_tr s1 $ seq_tr s2 $ seq_tr s3 $ seq_tr s4;
fun singlobj_tr' (Const (@{const_syntax SeqO'},_) $ fm) = fm
| singlobj_tr' id = Const (@{syntax_const "_SeqId"}, dummyT) $ id;
fun single_tr' c [s1, s2] =
Const (c, dummyT) $ seq_tr' s1 $ seq_tr' s2;
fun two_seq_tr' c [s1, s2] =
Const (c, dummyT) $ seq_tr' s1 $ seq_tr' s2;
fun three_seq_tr' c [s1, s2, s3] =
Const (c, dummyT) $ seq_tr' s1 $ seq_tr' s2 $ seq_tr' s3;
fun four_seq_tr' c [s1, s2, s3, s4] =
Const (c, dummyT) $ seq_tr' s1 $ seq_tr' s2 $ seq_tr' s3 $ seq_tr' s4;
(** for the <<...>> notation **)
fun side_tr [s1] = seq_tr s1;
*}
parse_translation {* [(@{syntax_const "_Side"}, K side_tr)] *}
subsection {* Proof tools *}
ML_file "prover.ML"
end