new lemmas for Ntree recursor example; more simprules; more lemmas borrowed
from directory AC
(* Title: ZF/thy_syntax.ML
ID: $Id$
Author: Lawrence C Paulson
Copyright 1994 University of Cambridge
Additional theory file sections for ZF.
*)
local
open ThyParse;
(*ML identifiers for introduction rules.*)
fun mk_intr_name suffix s =
if ThmDatabase.is_ml_identifier s then
"op " ^ s ^ suffix (*the "op" cancels any infix status*)
else "_"; (*bad name, don't try to bind*)
(*For lists of theorems. Either a string (an ML list expression) or else
a list of identifiers.*)
fun optlist s =
optional (s $$--
(string >> unenclose
|| list1 (name>>unenclose) >> mk_list))
"[]";
(*(Co)Inductive definitions theory section."*)
fun inductive_decl coind =
let
fun mk_params ((((((recs, sdom_sum), ipairs),
monos), con_defs), type_intrs), type_elims) =
let val big_rec_name = space_implode "_"
(map (scan_to_id o unenclose) recs)
and srec_tms = mk_list recs
and sintrs = mk_big_list (map snd ipairs)
and inames = mk_list (map (mk_intr_name "" o fst) ipairs)
in
";\n\n\
\local\n\
\val (thy, {defs, intrs, elim, mk_cases, \
\bnd_mono, dom_subset, induct, mutual_induct, ...}) =\n\
\ " ^
(if coind then "Co" else "") ^
"Ind_Package.add_inductive (" ^ srec_tms ^ ", " ^ sdom_sum ^ ", " ^
sintrs ^ ", " ^ monos ^ ", " ^ con_defs ^ ", " ^
type_intrs ^ ", " ^ type_elims ^ ") thy;\n\
\in\n\
\structure " ^ big_rec_name ^ " =\n\
\struct\n\
\ val defs = defs\n\
\ val bnd_mono = bnd_mono\n\
\ val dom_subset = dom_subset\n\
\ val intrs = intrs\n\
\ val elim = elim\n\
\ val " ^ (if coind then "co" else "") ^ "induct = induct\n\
\ val mutual_induct = mutual_induct\n\
\ val mk_cases = mk_cases\n\
\ val " ^ inames ^ " = intrs\n\
\end;\n\
\val thy = thy;\nend;\n\
\val thy = thy\n"
end
val domains = "domains" $$-- enum1 "+" string --$$ "<=" -- !! string
val ipairs = "intrs" $$-- repeat1 (ident -- !! string)
in domains -- ipairs -- optlist "monos" -- optlist "con_defs"
-- optlist "type_intrs" -- optlist "type_elims"
>> mk_params
end;
(*Datatype definitions theory section. co is true for codatatypes*)
fun datatype_decl coind =
let
(*generate strings*)
fun mk_const ((x, y), z) = mk_triple (x, mk_list y, z);
val mk_data = mk_list o map mk_const o snd
val mk_scons = mk_big_list o map mk_data
fun mk_params ((((sdom, rec_pairs), monos), type_intrs), type_elims) =
let val rec_names = map (scan_to_id o unenclose o fst) rec_pairs
val big_rec_name = space_implode "_" rec_names
and srec_tms = mk_list (map fst rec_pairs)
and scons = mk_scons rec_pairs
val con_names = flat (map (map (unenclose o #1 o #1) o snd)
rec_pairs)
val inames = mk_list (map (mk_intr_name "_I") con_names)
in
";\n\n\
\local\n\
\val (thy,\n\
\ {defs, intrs, elim, mk_cases, \
\bnd_mono, dom_subset, induct, mutual_induct, ...},\n\
\ {con_defs, case_eqns, recursor_eqns, free_iffs, free_SEs, mk_free, ...}) =\n\
\ " ^
(if coind then "Co" else "") ^
"Data_Package.add_datatype (" ^ sdom ^ ", " ^ srec_tms ^ ", " ^
scons ^ ", " ^ monos ^ ", " ^
type_intrs ^ ", " ^ type_elims ^ ") thy;\n\
\in\n\
\structure " ^ big_rec_name ^ " =\n\
\struct\n\
\ val defs = defs\n\
\ val bnd_mono = bnd_mono\n\
\ val dom_subset = dom_subset\n\
\ val intrs = intrs\n\
\ val elim = elim\n\
\ val " ^ (if coind then "co" else "") ^ "induct = induct\n\
\ val mutual_induct = mutual_induct\n\
\ val mk_cases = mk_cases\n\
\ val con_defs = con_defs\n\
\ val case_eqns = case_eqns\n\
\ val recursor_eqns = recursor_eqns\n\
\ val free_iffs = free_iffs\n\
\ val free_SEs = free_SEs\n\
\ val mk_free = mk_free\n\
\ val " ^ inames ^ " = intrs;\n\
\end;\n\
\val thy = thy;\nend;\n\
\val thy = thy\n"
end
val string_list = "(" $$-- list1 string --$$ ")" || ThyParse.empty;
val construct = name -- string_list -- opt_mixfix;
in optional ("<=" $$-- string) "\"\"" --
enum1 "and" (name --$$ "=" -- enum1 "|" construct) --
optlist "monos" -- optlist "type_intrs" -- optlist "type_elims"
>> mk_params
end;
(** rep_datatype **)
fun mk_rep_dt_string (((elim, induct), case_eqns), recursor_eqns) =
"|> DatatypeTactics.rep_datatype_i " ^ elim ^ " " ^ induct ^ "\n " ^
mk_list case_eqns ^ " " ^ mk_list recursor_eqns;
val rep_datatype_decl =
(("elim" $$-- ident) --
("induct" $$-- ident) --
("case_eqns" $$-- list1 ident) --
optional ("recursor_eqns" $$-- list1 ident) []) >> mk_rep_dt_string;
(** primrec **)
fun mk_primrec_decl eqns =
let val names = map fst eqns
in
";\nval (thy, " ^ mk_list names ^
") = PrimrecPackage.add_primrec " ^
mk_list (map mk_pair (map (apfst quote) eqns)) ^ " " ^ " thy;\n\
\val thy = thy\n"
end;
(* either names and axioms or just axioms *)
val primrec_decl =
((repeat1 ((ident -- string) || (string >> pair "_")))) >> mk_primrec_decl;
(** augment thy syntax **)
in
val _ = ThySyn.add_syntax
["inductive", "coinductive", "datatype", "codatatype", "and", "|",
"<=", "domains", "intrs", "monos", "con_defs", "type_intrs", "type_elims",
(*rep_datatype*)
"elim", "induct", "case_eqns", "recursor_eqns"]
[section "inductive" "" (inductive_decl false),
section "coinductive" "" (inductive_decl true),
section "datatype" "" (datatype_decl false),
section "codatatype" "" (datatype_decl true),
section "rep_datatype" "" rep_datatype_decl,
section "primrec" "" primrec_decl];
end;