(* Title: Tools/code/code_package.ML
ID: $Id$
Author: Florian Haftmann, TU Muenchen
Code generator translation kernel. Code generator Isar setup.
*)
signature CODE_PACKAGE =
sig
val eval_conv: theory
-> (CodeThingol.code -> CodeThingol.typscheme * CodeThingol.iterm
-> string list -> cterm -> thm)
-> cterm -> thm;
val eval_term: theory
-> (CodeThingol.code -> CodeThingol.typscheme * CodeThingol.iterm
-> string list -> term -> 'a)
-> term -> 'a;
val satisfies_ref: (unit -> bool) option ref;
val satisfies: theory -> term -> string list -> bool;
val eval_invoke: theory -> (string * (unit -> 'a) option ref) -> CodeThingol.code
-> CodeThingol.iterm * CodeThingol.itype -> string list -> 'a;
val codegen_command: theory -> string -> unit;
type appgen;
val add_appconst: string * appgen -> theory -> theory;
val appgen_let: appgen;
val appgen_if: appgen;
val appgen_case: (theory -> term
-> ((string * typ) list * ((term * typ) * (term * term) list)) option)
-> appgen;
end;
structure CodePackage : CODE_PACKAGE =
struct
open BasicCodeThingol;
(** code translation **)
(* theory data *)
type appgen = theory -> ((sort -> sort) * Sorts.algebra) * Consts.T
-> CodeFuncgr.T
-> (string * typ) * term list -> CodeThingol.transact -> iterm * CodeThingol.transact;
structure Appgens = TheoryDataFun
(
type T = (int * (appgen * stamp)) Symtab.table;
val empty = Symtab.empty;
val copy = I;
val extend = I;
fun merge _ = Symtab.merge (fn ((bounds1, (_, stamp1)), (bounds2, (_, stamp2))) =>
bounds1 = bounds2 andalso stamp1 = stamp2);
);
fun code_depgr thy [] = CodeFuncgr.make thy []
| code_depgr thy consts =
let
val gr = CodeFuncgr.make thy consts;
val select = Graph.all_succs gr consts;
in
gr
|> Graph.subgraph (member (op =) select)
|> Graph.map_nodes ((apsnd o map) (Conv.fconv_rule (Class.overload thy)))
end;
fun code_thms thy =
Pretty.writeln o CodeFuncgr.pretty thy o code_depgr thy;
fun code_deps thy consts =
let
val gr = code_depgr thy consts;
fun mk_entry (const, (_, (_, parents))) =
let
val name = CodeUnit.string_of_const thy const;
val nameparents = map (CodeUnit.string_of_const thy) parents;
in { name = name, ID = name, dir = "", unfold = true,
path = "", parents = nameparents }
end;
val prgr = Graph.fold ((fn x => fn xs => xs @ [x]) o mk_entry) gr [];
in Present.display_graph prgr end;
structure Program = CodeDataFun
(
type T = CodeThingol.code;
val empty = CodeThingol.empty_code;
fun merge _ = CodeThingol.merge_code;
fun purge _ NONE _ = CodeThingol.empty_code
| purge NONE _ _ = CodeThingol.empty_code
| purge (SOME thy) (SOME cs) code =
let
val cs_exisiting =
map_filter (CodeName.const_rev thy) (Graph.keys code);
val dels = (Graph.all_preds code
o map (CodeName.const thy)
o filter (member (op =) cs_exisiting)
) cs;
in Graph.del_nodes dels code end;
);
(* translation kernel *)
val value_name = "Isabelle_Eval.EVAL.EVAL";
fun ensure_def thy = CodeThingol.ensure_def
(fn s => if s = value_name then "<term>" else CodeName.labelled_name thy s);
exception CONSTRAIN of (string * typ) * typ;
fun ensure_def_class thy (algbr as ((_, algebra), _)) funcgr class =
let
val superclasses = (Sorts.certify_sort algebra o Sorts.super_classes algebra) class;
val (v, cs) = AxClass.params_of_class thy class;
val class' = CodeName.class thy class;
val defgen_class =
fold_map (fn superclass => ensure_def_class thy algbr funcgr superclass
##>> ensure_def_classrel thy algbr funcgr (class, superclass)) superclasses
##>> fold_map (fn (c, ty) => ensure_def_const thy algbr funcgr c
##>> exprgen_typ thy algbr funcgr ty) cs
#>> (fn info => CodeThingol.Class (unprefix "'" v, info))
in
ensure_def thy defgen_class class'
#> pair class'
end
and ensure_def_classrel thy algbr funcgr (subclass, superclass) =
let
val classrel' = CodeName.classrel thy (subclass, superclass);
val defgen_classrel =
ensure_def_class thy algbr funcgr subclass
##>> ensure_def_class thy algbr funcgr superclass
#>> CodeThingol.Classrel;
in
ensure_def thy defgen_classrel classrel'
#> pair classrel'
end
and ensure_def_tyco thy algbr funcgr "fun" =
pair "fun"
| ensure_def_tyco thy algbr funcgr tyco =
let
val defgen_datatype =
let
val (vs, cos) = Code.get_datatype thy tyco;
in
fold_map (exprgen_tyvar_sort thy algbr funcgr) vs
##>> fold_map (fn (c, tys) =>
ensure_def_const thy algbr funcgr c
##>> fold_map (exprgen_typ thy algbr funcgr) tys) cos
#>> CodeThingol.Datatype
end;
val tyco' = CodeName.tyco thy tyco;
in
ensure_def thy defgen_datatype tyco'
#> pair tyco'
end
and exprgen_tyvar_sort thy (algbr as ((proj_sort, _), _)) funcgr (v, sort) =
fold_map (ensure_def_class thy algbr funcgr) (proj_sort sort)
#>> (fn sort => (unprefix "'" v, sort))
and exprgen_typ thy algbr funcgr (TFree vs) =
exprgen_tyvar_sort thy algbr funcgr vs
#>> (fn (v, sort) => ITyVar v)
| exprgen_typ thy algbr funcgr (Type (tyco, tys)) =
ensure_def_tyco thy algbr funcgr tyco
##>> fold_map (exprgen_typ thy algbr funcgr) tys
#>> (fn (tyco, tys) => tyco `%% tys)
and exprgen_dicts thy (algbr as ((proj_sort, algebra), consts)) funcgr (ty_ctxt, sort_decl) =
let
val pp = Sign.pp thy;
datatype typarg =
Global of (class * string) * typarg list list
| Local of (class * class) list * (string * (int * sort));
fun class_relation (Global ((_, tyco), yss), _) class =
Global ((class, tyco), yss)
| class_relation (Local (classrels, v), subclass) superclass =
Local ((subclass, superclass) :: classrels, v);
fun type_constructor tyco yss class =
Global ((class, tyco), (map o map) fst yss);
fun type_variable (TFree (v, sort)) =
let
val sort' = proj_sort sort;
in map_index (fn (n, class) => (Local ([], (v, (n, sort'))), class)) sort' end;
val typargs = Sorts.of_sort_derivation pp algebra
{class_relation = class_relation, type_constructor = type_constructor,
type_variable = type_variable}
(ty_ctxt, proj_sort sort_decl);
fun mk_dict (Global (inst, yss)) =
ensure_def_inst thy algbr funcgr inst
##>> (fold_map o fold_map) mk_dict yss
#>> (fn (inst, dss) => DictConst (inst, dss))
| mk_dict (Local (classrels, (v, (k, sort)))) =
fold_map (ensure_def_classrel thy algbr funcgr) classrels
#>> (fn classrels => DictVar (classrels, (unprefix "'" v, (k, length sort))))
in
fold_map mk_dict typargs
end
and exprgen_dict_parms thy (algbr as (_, consts)) funcgr (c, ty_ctxt) =
let
val ty_decl = Consts.the_declaration consts c;
val (tys, tys_decl) = pairself (curry (Consts.typargs consts) c) (ty_ctxt, ty_decl);
val sorts = map (snd o dest_TVar) tys_decl;
in
fold_map (exprgen_dicts thy algbr funcgr) (tys ~~ sorts)
end
and exprgen_eq thy algbr funcgr thm =
let
val (args, rhs) = (apfst (snd o strip_comb) o Logic.dest_equals
o Logic.unvarify o prop_of) thm;
in
fold_map (exprgen_term thy algbr funcgr) args
##>> exprgen_term thy algbr funcgr rhs
#>> rpair thm
end
and ensure_def_inst thy (algbr as ((_, algebra), _)) funcgr (class, tyco) =
let
val superclasses = (Sorts.certify_sort algebra o Sorts.super_classes algebra) class;
val (var, classparams) = try (AxClass.params_of_class thy) class |> the_default ("'a", [])
val vs = Name.names Name.context "'a" (Sorts.mg_domain algebra tyco [class]);
val sorts' = Sorts.mg_domain (Sign.classes_of thy) tyco [class];
val vs' = map2 (fn (v, sort1) => fn sort2 => (v,
Sorts.inter_sort (Sign.classes_of thy) (sort1, sort2))) vs sorts';
val arity_typ = Type (tyco, map TFree vs);
val arity_typ' = Type (tyco, map (fn (v, sort) => TVar ((v, 0), sort)) vs');
fun exprgen_superarity superclass =
ensure_def_class thy algbr funcgr superclass
##>> ensure_def_classrel thy algbr funcgr (class, superclass)
##>> exprgen_dicts thy algbr funcgr (arity_typ, [superclass])
#>> (fn ((superclass, classrel), [DictConst (inst, dss)]) =>
(superclass, (classrel, (inst, dss))));
fun exprgen_classparam_inst (c, ty) =
let
val c_inst = Const (c, map_type_tfree (K arity_typ') ty);
val thm = Class.unoverload thy (Thm.cterm_of thy c_inst);
val c_ty = (apsnd Logic.unvarifyT o dest_Const o snd
o Logic.dest_equals o Thm.prop_of) thm;
in
ensure_def_const thy algbr funcgr c
##>> exprgen_const thy algbr funcgr c_ty
#>> (fn (c, IConst c_inst) => ((c, c_inst), thm))
end;
val defgen_inst =
ensure_def_class thy algbr funcgr class
##>> ensure_def_tyco thy algbr funcgr tyco
##>> fold_map (exprgen_tyvar_sort thy algbr funcgr) vs
##>> fold_map exprgen_superarity superclasses
##>> fold_map exprgen_classparam_inst classparams
#>> (fn ((((class, tyco), arity), superarities), classparams) =>
CodeThingol.Classinst ((class, (tyco, arity)), (superarities, classparams)));
val inst = CodeName.instance thy (class, tyco);
in
ensure_def thy defgen_inst inst
#> pair inst
end
and ensure_def_const thy (algbr as (_, consts)) funcgr c =
let
val c' = CodeName.const thy c;
fun defgen_datatypecons tyco =
ensure_def_tyco thy algbr funcgr tyco
#>> K (CodeThingol.Datatypecons c');
fun defgen_classparam class =
ensure_def_class thy algbr funcgr class
#>> K (CodeThingol.Classparam c');
fun defgen_fun trns =
let
val raw_thms = CodeFuncgr.funcs funcgr c;
val ty = (Logic.unvarifyT o CodeFuncgr.typ funcgr) c;
val vs = (map dest_TFree o Consts.typargs consts) (c, ty);
val thms = if (null o Term.typ_tfrees) ty orelse (null o fst o strip_type) ty
then raw_thms
else map (CodeUnit.expand_eta 1) raw_thms;
in
trns
|> fold_map (exprgen_tyvar_sort thy algbr funcgr) vs
||>> exprgen_typ thy algbr funcgr ty
||>> fold_map (exprgen_eq thy algbr funcgr) thms
|>> (fn ((vs, ty), eqs) => CodeThingol.Fun ((vs, ty), eqs))
end;
val defgen = case Code.get_datatype_of_constr thy c
of SOME tyco => defgen_datatypecons tyco
| NONE => (case AxClass.class_of_param thy c
of SOME class => defgen_classparam class
| NONE => defgen_fun)
in
ensure_def thy defgen c'
#> pair c'
end
and exprgen_term thy algbr funcgr (Const (c, ty)) =
exprgen_app thy algbr funcgr ((c, ty), [])
| exprgen_term thy algbr funcgr (Free (v, _)) =
pair (IVar v)
| exprgen_term thy algbr funcgr (Abs (abs as (_, ty, _))) =
let
val (v, t) = Syntax.variant_abs abs;
in
exprgen_typ thy algbr funcgr ty
##>> exprgen_term thy algbr funcgr t
#>> (fn (ty, t) => (v, ty) `|-> t)
end
| exprgen_term thy algbr funcgr (t as _ $ _) =
case strip_comb t
of (Const (c, ty), ts) =>
exprgen_app thy algbr funcgr ((c, ty), ts)
| (t', ts) =>
exprgen_term thy algbr funcgr t'
##>> fold_map (exprgen_term thy algbr funcgr) ts
#>> (fn (t, ts) => t `$$ ts)
and exprgen_const thy algbr funcgr (c, ty) =
ensure_def_const thy algbr funcgr c
##>> exprgen_dict_parms thy algbr funcgr (c, ty)
##>> fold_map (exprgen_typ thy algbr funcgr) ((fst o Term.strip_type) ty)
(*##>> exprgen_typ thy algbr funcgr ((snd o Term.strip_type) ty)*)
#>> (fn ((c, iss), tys) => IConst (c, (iss, tys)))
and exprgen_app_default thy algbr funcgr (c_ty, ts) =
exprgen_const thy algbr funcgr c_ty
##>> fold_map (exprgen_term thy algbr funcgr) ts
#>> (fn (t, ts) => t `$$ ts)
and exprgen_app thy algbr funcgr ((c, ty), ts) =
case Symtab.lookup (Appgens.get thy) c
of SOME (i, (appgen, _)) =>
if length ts < i then
let
val k = length ts;
val tys = (curry Library.take (i - k) o curry Library.drop k o fst o strip_type) ty;
val ctxt = (fold o fold_aterms)
(fn Free (v, _) => Name.declare v | _ => I) ts Name.context;
val vs = Name.names ctxt "a" tys;
in
fold_map (exprgen_typ thy algbr funcgr) tys
##>> appgen thy algbr funcgr ((c, ty), ts @ map Free vs)
#>> (fn (tys, t) => map2 (fn (v, _) => pair v) vs tys `|--> t)
end
else if length ts > i then
appgen thy algbr funcgr ((c, ty), Library.take (i, ts))
##>> fold_map (exprgen_term thy algbr funcgr) (Library.drop (i, ts))
#>> (fn (t, ts) => t `$$ ts)
else
appgen thy algbr funcgr ((c, ty), ts)
| NONE =>
exprgen_app_default thy algbr funcgr ((c, ty), ts);
(* entrance points into translation kernel *)
fun ensure_def_const' thy algbr funcgr c trns =
ensure_def_const thy algbr funcgr c trns
handle CONSTRAIN ((c, ty), ty_decl) => error (
"Constant " ^ c ^ " with most general type\n"
^ CodeUnit.string_of_typ thy ty
^ "\noccurs with type\n"
^ CodeUnit.string_of_typ thy ty_decl);
fun perhaps_def_const thy algbr funcgr c trns =
case try (ensure_def_const thy algbr funcgr c) trns
of SOME (c, trns) => (SOME c, trns)
| NONE => (NONE, trns);
fun exprgen_term' thy algbr funcgr t trns =
exprgen_term thy algbr funcgr t trns
handle CONSTRAIN ((c, ty), ty_decl) => error ("In term " ^ (quote o Sign.string_of_term thy) t
^ ",\nconstant " ^ c ^ " with most general type\n"
^ CodeUnit.string_of_typ thy ty
^ "\noccurs with type\n"
^ CodeUnit.string_of_typ thy ty_decl);
(* parametrized application generators, for instantiation in object logic *)
(* (axiomatic extensions of translation kernel) *)
fun appgen_case dest_case_expr thy algbr funcgr (app as (c_ty, ts)) =
let
val SOME ([], ((st, sty), ds)) = dest_case_expr thy (list_comb (Const c_ty, ts));
fun clause_gen (dt, bt) =
exprgen_term thy algbr funcgr
(map_aterms (fn Const (c_ty as (c, ty)) => Const
(Class.unoverload_const thy c_ty, ty) | t => t) dt)
##>> exprgen_term thy algbr funcgr bt;
in
exprgen_term thy algbr funcgr st
##>> exprgen_typ thy algbr funcgr sty
##>> fold_map clause_gen ds
##>> exprgen_app_default thy algbr funcgr app
#>> (fn (((se, sty), ds), t0) => ICase (((se, sty), ds), t0))
end;
fun appgen_let thy algbr funcgr (app as (_, [st, ct])) =
exprgen_term thy algbr funcgr ct
##>> exprgen_term thy algbr funcgr st
##>> exprgen_app_default thy algbr funcgr app
#>> (fn (((v, ty) `|-> be, se), t0) =>
ICase (CodeThingol.collapse_let (((v, ty), se), be), t0)
| (_, t0) => t0);
fun appgen_if thy algbr funcgr (app as (_, [tb, tt, tf])) =
exprgen_term thy algbr funcgr tb
##>> exprgen_typ thy algbr funcgr (Type ("bool", []))
##>> exprgen_term thy algbr funcgr (Const ("True", Type ("bool", [])))
##>> exprgen_term thy algbr funcgr tt
##>> exprgen_term thy algbr funcgr (Const ("False", Type ("bool", [])))
##>> exprgen_term thy algbr funcgr tf
##>> exprgen_app_default thy algbr funcgr app
#>> (fn ((((((tb, B), T), tt), F), tf), t0) => ICase (((tb, B), [(T, tt), (F, tf)]), t0));
fun add_appconst (c, appgen) thy =
let
val i = (length o fst o strip_type o Sign.the_const_type thy) c;
val _ = Program.change thy (K CodeThingol.empty_code);
in
Appgens.map (Symtab.update (c, (i, (appgen, stamp ())))) thy
end;
(** code generation interfaces **)
(* generic generation combinators *)
fun generate thy funcgr gen it =
let
val naming = NameSpace.qualified_names NameSpace.default_naming;
val consttab = Consts.empty
|> fold (fn c => Consts.declare true naming [] (c, CodeFuncgr.typ funcgr c))
(CodeFuncgr.all funcgr);
val algbr = (Code.operational_algebra thy, consttab);
in
Program.change_yield thy
(CodeThingol.start_transact (gen thy algbr funcgr it))
|> fst
end;
fun code thy permissive cs seris =
let
val code = Program.get thy;
val seris' = map (fn (((target, module), file), args) =>
CodeTarget.get_serializer thy target permissive module file args
CodeName.labelled_name cs) seris;
in (map (fn f => f code) seris' : unit list; ()) end;
fun raw_eval evaluate term_of thy g =
let
val value_name = "Isabelle_Eval.EVAL.EVAL";
fun ensure_eval thy algbr funcgr t =
let
val ty = fastype_of t;
val vs = fold_term_types (K (fold_atyps (insert (eq_fst op =)
o dest_TFree))) t [];
val defgen_eval =
fold_map (exprgen_tyvar_sort thy algbr funcgr) vs
##>> exprgen_typ thy algbr funcgr ty
##>> exprgen_term' thy algbr funcgr t
#>> (fn ((vs, ty), t) => CodeThingol.Fun ((vs, ty), [(([], t), Drule.dummy_thm)]));
fun result (dep, code) =
let
val CodeThingol.Fun ((vs, ty), [(([], t), _)]) = Graph.get_node code value_name;
val deps = Graph.imm_succs code value_name;
val code' = Graph.del_nodes [value_name] code;
val code'' = CodeThingol.project_code false [] (SOME deps) code';
in ((code'', ((vs, ty), t), deps), (dep, code')) end;
in
ensure_def thy defgen_eval value_name
#> result
end;
fun h funcgr ct =
let
val (code, vs_ty_t, deps) = generate thy funcgr ensure_eval (term_of ct);
in g code vs_ty_t deps ct end;
in evaluate thy h end;
fun eval_conv thy = raw_eval CodeFuncgr.eval_conv Thm.term_of thy;
fun eval_term thy = raw_eval CodeFuncgr.eval_term I thy;
fun eval_invoke thy = CodeTarget.eval_invoke thy CodeName.labelled_name;
val satisfies_ref : (unit -> bool) option ref = ref NONE;
fun satisfies thy t witnesses =
let
fun evl code ((vs, ty), t) deps ct =
eval_invoke thy ("CodePackage.satisfies_ref", satisfies_ref)
code (t, ty) witnesses;
in eval_term thy evl t end;
fun filter_generatable thy consts =
let
val (consts', funcgr) = CodeFuncgr.make_consts thy consts;
val consts'' = generate thy funcgr (fold_map ooo perhaps_def_const) consts';
val consts''' = map_filter (fn (const, SOME _) => SOME const | (_, NONE) => NONE)
(consts' ~~ consts'');
in consts''' end;
fun generate_const_exprs thy raw_cs =
let
val (perm1, cs) = CodeUnit.read_const_exprs thy
(filter_generatable thy) raw_cs;
val (perm2, cs') = case generate thy (CodeFuncgr.make thy cs)
(fold_map ooo ensure_def_const') cs
of [] => (true, NONE)
| cs => (false, SOME cs);
in (perm1 orelse perm2, cs') end;
(** code properties **)
fun mk_codeprops thy all_cs sel_cs =
let
fun select (thmref, thm) = case try (Drule.unvarify o Drule.zero_var_indexes) thm
of NONE => NONE
| SOME thm => let
val t = (ObjectLogic.drop_judgment thy o Thm.prop_of) thm;
val cs = fold_aterms (fn Const (c, ty) =>
cons (Class.unoverload_const thy (c, ty)) | _ => I) t [];
in if exists (member (op =) sel_cs) cs
andalso forall (member (op =) all_cs) cs
then SOME (thmref, thm) else NONE end;
fun mk_codeprop (thmref, thm) =
let
val t = ObjectLogic.drop_judgment thy (Thm.prop_of thm);
val ty_judg = fastype_of t;
val tfrees1 = fold_aterms (fn Const (c, ty) =>
Term.add_tfreesT ty | _ => I) t [];
val vars = Term.add_frees t [];
val tfrees2 = fold (Term.add_tfreesT o snd) vars [];
val tfrees' = subtract (op =) tfrees2 tfrees1 |> map TFree;
val ty = map Term.itselfT tfrees' @ map snd vars ---> ty_judg;
val tfree_vars = map Logic.mk_type tfrees';
val c = PureThy.string_of_thmref thmref
|> NameSpace.explode
|> (fn [x] => [x] | (x::xs) => xs)
|> space_implode "_"
val propdef = (((c, ty), tfree_vars @ map Free vars), t);
in if c = "" then NONE else SOME (thmref, propdef) end;
in
PureThy.thms_containing thy ([], [])
|> maps PureThy.selections
|> map_filter select
|> map_filter mk_codeprop
end;
fun add_codeprops all_cs sel_cs thy =
let
val codeprops = mk_codeprops thy all_cs sel_cs;
fun lift_name_yield f x = (Name.context, x) |> f ||> snd;
fun add (thmref, (((raw_c, ty), ts), t)) (names, thy) =
let
val _ = warning ("Adding theorem " ^ quote (PureThy.string_of_thmref thmref)
^ " as code property " ^ quote raw_c);
val ([raw_c'], names') = Name.variants [raw_c] names;
in
thy
|> PureThy.simple_def ("", []) (((raw_c', ty, Syntax.NoSyn), ts), t)
||> pair names'
end;
in
thy
|> Sign.sticky_prefix "codeprop"
|> lift_name_yield (fold_map add codeprops)
||> Sign.restore_naming thy
|-> (fn c_thms => fold (Code.add_func o snd) c_thms #> pair c_thms)
end;
(** toplevel interface and setup **)
local
structure P = OuterParse
and K = OuterKeyword
fun code_cmd raw_cs seris thy =
let
val (permissive, cs) = generate_const_exprs thy raw_cs;
val _ = code thy permissive cs seris;
in () end;
fun code_thms_cmd thy =
code_thms thy o snd o CodeUnit.read_const_exprs thy (fst o CodeFuncgr.make_consts thy);
fun code_deps_cmd thy =
code_deps thy o snd o CodeUnit.read_const_exprs thy (fst o CodeFuncgr.make_consts thy);
fun code_props_cmd raw_cs seris thy =
let
val (_, all_cs) = generate_const_exprs thy ["*"];
val (permissive, cs) = generate_const_exprs thy raw_cs;
val (c_thms, thy') = add_codeprops (map (the o CodeName.const_rev thy) (these all_cs))
(map (the o CodeName.const_rev thy) (these cs)) thy;
val prop_cs = (filter_generatable thy' o map fst) c_thms;
val _ = if null seris then [] else generate thy' (CodeFuncgr.make thy' prop_cs)
(fold_map ooo ensure_def_const') prop_cs;
val _ = if null seris then () else code thy' permissive
(SOME (map (CodeName.const thy') prop_cs)) seris;
in thy' end;
val (inK, module_nameK, fileK) = ("in", "module_name", "file");
fun code_exprP cmd =
(Scan.repeat P.term
-- Scan.repeat (P.$$$ inK |-- P.name
-- Scan.option (P.$$$ module_nameK |-- P.name)
-- Scan.option (P.$$$ fileK |-- P.name)
-- Scan.optional (P.$$$ "(" |-- P.arguments --| P.$$$ ")") []
) >> (fn (raw_cs, seris) => cmd raw_cs seris));
val _ = OuterSyntax.add_keywords [inK, module_nameK, fileK];
val (codeK, code_thmsK, code_depsK, code_propsK) =
("export_code", "code_thms", "code_deps", "code_props");
in
val codeP =
OuterSyntax.improper_command codeK "generate executable code for constants"
K.diag (P.!!! (code_exprP code_cmd) >> (fn f => Toplevel.keep (f o Toplevel.theory_of)));
fun codegen_command thy cmd =
case Scan.read OuterLex.stopper (P.!!! (code_exprP code_cmd)) ((filter OuterLex.is_proper o OuterSyntax.scan) cmd)
of SOME f => (writeln "Now generating code..."; f thy)
| NONE => error ("Bad directive " ^ quote cmd);
val code_thmsP =
OuterSyntax.improper_command code_thmsK "print system of defining equations for code" OuterKeyword.diag
(Scan.repeat P.term
>> (fn cs => Toplevel.no_timing o Toplevel.unknown_theory
o Toplevel.keep ((fn thy => code_thms_cmd thy cs) o Toplevel.theory_of)));
val code_depsP =
OuterSyntax.improper_command code_depsK "visualize dependencies of defining equations for code" OuterKeyword.diag
(Scan.repeat P.term
>> (fn cs => Toplevel.no_timing o Toplevel.unknown_theory
o Toplevel.keep ((fn thy => code_deps_cmd thy cs) o Toplevel.theory_of)));
val code_propsP =
OuterSyntax.command code_propsK "generate characteristic properties for executable constants"
K.thy_decl (P.!!! (code_exprP code_props_cmd) >> Toplevel.theory);
val _ = OuterSyntax.add_parsers [codeP, code_thmsP, code_depsP, code_propsP];
end; (*local*)
end; (*struct*)