(* Title: Tools/code/code_target.ML
ID: $Id$
Author: Florian Haftmann, TU Muenchen
Serializer from intermediate language ("Thin-gol") to target languages.
*)
signature CODE_TARGET =
sig
include CODE_PRINTER
type serializer
val add_target: string * (serializer * literals) -> theory -> theory
val extend_target: string * (string * (Code_Thingol.program -> Code_Thingol.program))
-> theory -> theory
val assert_target: theory -> string -> string
type destination
type serialization
val parse_args: (OuterLex.token list -> 'a * OuterLex.token list)
-> OuterLex.token list -> 'a
val stmt_names_of_destination: destination -> string list
val code_of_pretty: Pretty.T -> string
val code_writeln: Pretty.T -> unit
val mk_serialization: string -> ('a -> unit) option
-> (Path.T option -> 'a -> unit)
-> ('a -> string * string list)
-> 'a -> serialization
val serialize: theory -> string -> string option -> Args.T list
-> Code_Thingol.program -> string list -> serialization
val serialize_custom: theory -> string * (serializer * literals)
-> Code_Thingol.program -> string list -> string * string list
val compile: serialization -> unit
val export: serialization -> unit
val file: Path.T -> serialization -> unit
val string: string list -> serialization -> string
val code_of: theory -> string -> string -> string list -> string list -> string
val shell_command: string (*theory name*) -> string (*export_code expr*) -> unit
val code_width: int ref
val allow_abort: string -> theory -> theory
val add_syntax_class: string -> class
-> (string * (string * string) list) option -> theory -> theory
val add_syntax_inst: string -> string * class -> bool -> theory -> theory
val add_syntax_tyco: string -> string -> tyco_syntax option -> theory -> theory
val add_syntax_tycoP: string -> string -> OuterParse.token list
-> (theory -> theory) * OuterParse.token list
val add_syntax_const: string -> string -> const_syntax option -> theory -> theory
val add_syntax_constP: string -> string -> OuterParse.token list
-> (theory -> theory) * OuterParse.token list
val add_reserved: string -> string -> theory -> theory
val add_literal_list: string -> string -> string -> theory -> theory
val add_literal_list_string: string -> string -> string
-> string -> string list -> theory -> theory
val add_literal_char: string -> string -> string list -> theory -> theory
val add_literal_numeral: string -> bool -> bool -> string -> string -> string
-> string -> string -> theory -> theory
val add_literal_message: string -> string -> string list -> string
-> string -> string -> theory -> theory
end;
structure Code_Target : CODE_TARGET =
struct
open Basic_Code_Thingol;
open Code_Printer;
(** basics **)
datatype destination = Compile | Export | File of Path.T | String of string list;
type serialization = destination -> (string * string list) option;
val code_width = ref 80; (*FIXME after Pretty module no longer depends on print mode*)
fun code_setmp f = PrintMode.setmp [] (Pretty.setmp_margin (!code_width) f);
fun code_of_pretty p = code_setmp Pretty.string_of p ^ "\n";
fun code_writeln p = Pretty.setmp_margin (!code_width) Pretty.writeln p;
(*FIXME why another code_setmp?*)
fun compile f = (code_setmp f Compile; ());
fun export f = (code_setmp f Export; ());
fun file p f = (code_setmp f (File p); ());
fun string cs f = fst (the (code_setmp f (String cs)));
fun stmt_names_of_destination (String stmts) = stmts
| stmt_names_of_destination _ = [];
fun mk_serialization target (SOME comp) _ _ code Compile = (comp code; NONE)
| mk_serialization target NONE _ _ _ Compile = error (target ^ ": no internal compilation")
| mk_serialization target _ output _ code Export = (output NONE code ; NONE)
| mk_serialization target _ output _ code (File file) = (output (SOME file) code; NONE)
| mk_serialization target _ _ string code (String _) = SOME (string code);
(** pretty syntax **)
(* list, char, string, numeral and monad abstract syntax transformations *)
fun implode_list c_nil c_cons t =
let
fun dest_cons (IConst (c, _) `$ t1 `$ t2) =
if c = c_cons
then SOME (t1, t2)
else NONE
| dest_cons _ = NONE;
val (ts, t') = Code_Thingol.unfoldr dest_cons t;
in case t'
of IConst (c, _) => if c = c_nil then SOME ts else NONE
| _ => NONE
end;
fun decode_char c_nibbles (IConst (c1, _), IConst (c2, _)) =
let
fun idx c = find_index (curry (op =) c) c_nibbles;
fun decode ~1 _ = NONE
| decode _ ~1 = NONE
| decode n m = SOME (chr (n * 16 + m));
in decode (idx c1) (idx c2) end
| decode_char _ _ = NONE;
fun implode_string c_char c_nibbles mk_char mk_string ts =
let
fun implode_char (IConst (c, _) `$ t1 `$ t2) =
if c = c_char then decode_char c_nibbles (t1, t2) else NONE
| implode_char _ = NONE;
val ts' = map implode_char ts;
in if forall is_some ts'
then (SOME o str o mk_string o implode o map_filter I) ts'
else NONE
end;
fun implode_numeral thm negative c_pls c_min c_bit0 c_bit1 =
let
fun dest_bit (IConst (c, _)) = if c = c_bit0 then 0
else if c = c_bit1 then 1
else nerror thm "Illegal numeral expression: illegal bit"
| dest_bit _ = nerror thm "Illegal numeral expression: illegal bit";
fun dest_numeral (IConst (c, _)) = if c = c_pls then SOME 0
else if c = c_min then
if negative then SOME ~1 else NONE
else nerror thm "Illegal numeral expression: illegal leading digit"
| dest_numeral (t1 `$ t2) =
let val (n, b) = (dest_numeral t2, dest_bit t1)
in case n of SOME n => SOME (2 * n + b) | NONE => NONE end
| dest_numeral _ = nerror thm "Illegal numeral expression: illegal term";
in dest_numeral #> the_default 0 end;
(* literal syntax printing *)
fun default_list (target_fxy, target_cons) pr fxy t1 t2 =
brackify_infix (target_fxy, R) fxy [
pr (INFX (target_fxy, X)) t1,
str target_cons,
pr (INFX (target_fxy, R)) t2
];
fun pretty_list c_nil c_cons literals =
let
val mk_list = literal_list literals;
fun pretty pr thm pat vars fxy [(t1, _), (t2, _)] =
case Option.map (cons t1) (implode_list c_nil c_cons t2)
of SOME ts => mk_list (map (pr vars NOBR) ts)
| NONE => default_list (infix_cons literals) (pr vars) fxy t1 t2;
in (2, pretty) end;
fun pretty_list_string c_nil c_cons c_char c_nibbles literals =
let
val mk_list = literal_list literals;
val mk_char = literal_char literals;
val mk_string = literal_string literals;
fun pretty pr thm pat vars fxy [(t1, _), (t2, _)] =
case Option.map (cons t1) (implode_list c_nil c_cons t2)
of SOME ts => (case implode_string c_char c_nibbles mk_char mk_string ts
of SOME p => p
| NONE => mk_list (map (pr vars NOBR) ts))
| NONE => default_list (infix_cons literals) (pr vars) fxy t1 t2;
in (2, pretty) end;
fun pretty_char c_char c_nibbles literals =
let
val mk_char = literal_char literals;
fun pretty _ thm _ _ _ [(t1, _), (t2, _)] =
case decode_char c_nibbles (t1, t2)
of SOME c => (str o mk_char) c
| NONE => nerror thm "Illegal character expression";
in (2, pretty) end;
fun pretty_numeral unbounded negative c_pls c_min c_bit0 c_bit1 literals =
let
val mk_numeral = literal_numeral literals;
fun pretty _ thm _ _ _ [(t, _)] =
(str o mk_numeral unbounded o implode_numeral thm negative c_pls c_min c_bit0 c_bit1) t;
in (1, pretty) end;
fun pretty_message c_char c_nibbles c_nil c_cons literals =
let
val mk_char = literal_char literals;
val mk_string = literal_string literals;
fun pretty _ thm _ _ _ [(t, _)] =
case implode_list c_nil c_cons t
of SOME ts => (case implode_string c_char c_nibbles mk_char mk_string ts
of SOME p => p
| NONE => nerror thm "Illegal message expression")
| NONE => nerror thm "Illegal message expression";
in (1, pretty) end;
(** theory data **)
datatype name_syntax_table = NameSyntaxTable of {
class: class_syntax Symtab.table,
inst: unit Symtab.table,
tyco: tyco_syntax Symtab.table,
const: const_syntax Symtab.table
};
fun mk_name_syntax_table ((class, inst), (tyco, const)) =
NameSyntaxTable { class = class, inst = inst, tyco = tyco, const = const };
fun map_name_syntax_table f (NameSyntaxTable { class, inst, tyco, const }) =
mk_name_syntax_table (f ((class, inst), (tyco, const)));
fun merge_name_syntax_table (NameSyntaxTable { class = class1, inst = inst1, tyco = tyco1, const = const1 },
NameSyntaxTable { class = class2, inst = inst2, tyco = tyco2, const = const2 }) =
mk_name_syntax_table (
(Symtab.join (K snd) (class1, class2),
Symtab.join (K snd) (inst1, inst2)),
(Symtab.join (K snd) (tyco1, tyco2),
Symtab.join (K snd) (const1, const2))
);
type serializer =
string option (*module name*)
-> Args.T list (*arguments*)
-> (string -> string) (*labelled_name*)
-> string list (*reserved symbols*)
-> (string * Pretty.T) list (*includes*)
-> (string -> string option) (*module aliasses*)
-> (string -> class_syntax option)
-> (string -> tyco_syntax option)
-> (string -> const_syntax option)
-> Code_Thingol.program
-> string list (*selected statements*)
-> serialization;
datatype serializer_entry = Serializer of serializer * literals
| Extends of string * (Code_Thingol.program -> Code_Thingol.program);
datatype target = Target of {
serial: serial,
serializer: serializer_entry,
reserved: string list,
includes: Pretty.T Symtab.table,
name_syntax_table: name_syntax_table,
module_alias: string Symtab.table
};
fun mk_target ((serial, serializer), ((reserved, includes), (name_syntax_table, module_alias))) =
Target { serial = serial, serializer = serializer, reserved = reserved,
includes = includes, name_syntax_table = name_syntax_table, module_alias = module_alias };
fun map_target f ( Target { serial, serializer, reserved, includes, name_syntax_table, module_alias } ) =
mk_target (f ((serial, serializer), ((reserved, includes), (name_syntax_table, module_alias))));
fun merge_target strict target (Target { serial = serial1, serializer = serializer,
reserved = reserved1, includes = includes1,
name_syntax_table = name_syntax_table1, module_alias = module_alias1 },
Target { serial = serial2, serializer = _,
reserved = reserved2, includes = includes2,
name_syntax_table = name_syntax_table2, module_alias = module_alias2 }) =
if serial1 = serial2 orelse not strict then
mk_target ((serial1, serializer),
((merge (op =) (reserved1, reserved2), Symtab.merge (op =) (includes1, includes2)),
(merge_name_syntax_table (name_syntax_table1, name_syntax_table2),
Symtab.join (K snd) (module_alias1, module_alias2))
))
else
error ("Incompatible serializers: " ^ quote target);
structure CodeTargetData = TheoryDataFun
(
type T = target Symtab.table * string list;
val empty = (Symtab.empty, []);
val copy = I;
val extend = I;
fun merge _ ((target1, exc1) : T, (target2, exc2)) =
(Symtab.join (merge_target true) (target1, target2), Library.merge (op =) (exc1, exc2));
);
fun the_serializer (Target { serializer, ... }) = serializer;
fun the_reserved (Target { reserved, ... }) = reserved;
fun the_includes (Target { includes, ... }) = includes;
fun the_name_syntax (Target { name_syntax_table = NameSyntaxTable x, ... }) = x;
fun the_module_alias (Target { module_alias , ... }) = module_alias;
val abort_allowed = snd o CodeTargetData.get;
fun assert_target thy target =
case Symtab.lookup (fst (CodeTargetData.get thy)) target
of SOME data => target
| NONE => error ("Unknown code target language: " ^ quote target);
fun put_target (target, seri) thy =
let
val defined_target = is_some o Symtab.lookup (fst (CodeTargetData.get thy));
val _ = case seri
of Extends (super, _) => if defined_target super then ()
else error ("Unknown code target language: " ^ quote super)
| _ => ();
val _ = if defined_target target
then warning ("Overwriting existing target " ^ quote target)
else ();
in
thy
|> (CodeTargetData.map o apfst oo Symtab.map_default)
(target, mk_target ((serial (), seri), (([], Symtab.empty),
(mk_name_syntax_table ((Symtab.empty, Symtab.empty), (Symtab.empty, Symtab.empty)),
Symtab.empty))))
((map_target o apfst o apsnd o K) seri)
end;
fun add_target (target, seri) = put_target (target, Serializer seri);
fun extend_target (target, (super, modify)) =
put_target (target, Extends (super, modify));
fun map_target_data target f thy =
let
val _ = assert_target thy target;
in
thy
|> (CodeTargetData.map o apfst o Symtab.map_entry target o map_target) f
end;
fun map_reserved target =
map_target_data target o apsnd o apfst o apfst;
fun map_includes target =
map_target_data target o apsnd o apfst o apsnd;
fun map_name_syntax target =
map_target_data target o apsnd o apsnd o apfst o map_name_syntax_table;
fun map_module_alias target =
map_target_data target o apsnd o apsnd o apsnd;
(** serializer configuration **)
(* data access *)
local
fun cert_class thy class =
let
val _ = AxClass.get_info thy class;
in class end;
fun read_class thy = cert_class thy o Sign.intern_class thy;
fun cert_tyco thy tyco =
let
val _ = if Sign.declared_tyname thy tyco then ()
else error ("No such type constructor: " ^ quote tyco);
in tyco end;
fun read_tyco thy = cert_tyco thy o Sign.intern_type thy;
fun gen_add_syntax_class prep_class prep_const target raw_class raw_syn thy =
let
val class = prep_class thy raw_class;
val class' = Code_Name.class thy class;
fun mk_classparam c = case AxClass.class_of_param thy c
of SOME class'' => if class = class'' then Code_Name.const thy c
else error ("Not a class operation for class " ^ quote class ^ ": " ^ quote c)
| NONE => error ("Not a class operation: " ^ quote c);
fun mk_syntax_params raw_params = AList.lookup (op =)
((map o apfst) (mk_classparam o prep_const thy) raw_params);
in case raw_syn
of SOME (syntax, raw_params) =>
thy
|> (map_name_syntax target o apfst o apfst)
(Symtab.update (class', (syntax, mk_syntax_params raw_params)))
| NONE =>
thy
|> (map_name_syntax target o apfst o apfst)
(Symtab.delete_safe class')
end;
fun gen_add_syntax_inst prep_class prep_tyco target (raw_tyco, raw_class) add_del thy =
let
val inst = Code_Name.instance thy (prep_class thy raw_class, prep_tyco thy raw_tyco);
in if add_del then
thy
|> (map_name_syntax target o apfst o apsnd)
(Symtab.update (inst, ()))
else
thy
|> (map_name_syntax target o apfst o apsnd)
(Symtab.delete_safe inst)
end;
fun gen_add_syntax_tyco prep_tyco target raw_tyco raw_syn thy =
let
val tyco = prep_tyco thy raw_tyco;
val tyco' = if tyco = "fun" then "fun" else Code_Name.tyco thy tyco;
fun check_args (syntax as (n, _)) = if n <> Sign.arity_number thy tyco
then error ("Number of arguments mismatch in syntax for type constructor " ^ quote tyco)
else syntax
in case raw_syn
of SOME syntax =>
thy
|> (map_name_syntax target o apsnd o apfst)
(Symtab.update (tyco', check_args syntax))
| NONE =>
thy
|> (map_name_syntax target o apsnd o apfst)
(Symtab.delete_safe tyco')
end;
fun gen_add_syntax_const prep_const target raw_c raw_syn thy =
let
val c = prep_const thy raw_c;
val c' = Code_Name.const thy c;
fun check_args (syntax as (n, _)) = if n > Code_Unit.no_args thy c
then error ("Too many arguments in syntax for constant " ^ quote c)
else syntax;
in case raw_syn
of SOME syntax =>
thy
|> (map_name_syntax target o apsnd o apsnd)
(Symtab.update (c', check_args syntax))
| NONE =>
thy
|> (map_name_syntax target o apsnd o apsnd)
(Symtab.delete_safe c')
end;
fun add_reserved target =
let
fun add sym syms = if member (op =) syms sym
then error ("Reserved symbol " ^ quote sym ^ " already declared")
else insert (op =) sym syms
in map_reserved target o add end;
fun add_include target =
let
fun add (name, SOME content) incls =
let
val _ = if Symtab.defined incls name
then warning ("Overwriting existing include " ^ name)
else ();
in Symtab.update (name, str content) incls end
| add (name, NONE) incls =
Symtab.delete name incls;
in map_includes target o add end;
fun add_module_alias target =
map_module_alias target o Symtab.update o apsnd Code_Name.check_modulename;
fun gen_allow_abort prep_cs raw_c thy =
let
val c = prep_cs thy raw_c;
val c' = Code_Name.const thy c;
in thy |> (CodeTargetData.map o apsnd) (insert (op =) c') end;
fun zip_list (x::xs) f g =
f
#-> (fn y =>
fold_map (fn x => g |-- f >> pair x) xs
#-> (fn xys => pair ((x, y) :: xys)));
(* concrete syntax *)
structure P = OuterParse
and K = OuterKeyword
fun parse_multi_syntax parse_thing parse_syntax =
P.and_list1 parse_thing
#-> (fn things => Scan.repeat1 (P.$$$ "(" |-- P.name --
(zip_list things parse_syntax (P.$$$ "and")) --| P.$$$ ")"));
in
val parse_syntax = parse_syntax;
val add_syntax_class = gen_add_syntax_class cert_class (K I);
val add_syntax_inst = gen_add_syntax_inst cert_class cert_tyco;
val add_syntax_tyco = gen_add_syntax_tyco cert_tyco;
val add_syntax_const = gen_add_syntax_const (K I);
val allow_abort = gen_allow_abort (K I);
val add_reserved = add_reserved;
val add_syntax_class_cmd = gen_add_syntax_class read_class Code_Unit.read_const;
val add_syntax_inst_cmd = gen_add_syntax_inst read_class read_tyco;
val add_syntax_tyco_cmd = gen_add_syntax_tyco read_tyco;
val add_syntax_const_cmd = gen_add_syntax_const Code_Unit.read_const;
val allow_abort_cmd = gen_allow_abort Code_Unit.read_const;
fun add_syntax_tycoP target tyco = parse_syntax I
>> add_syntax_tyco_cmd target tyco;
fun add_syntax_constP target c = parse_syntax fst
>> (add_syntax_const_cmd target c o Code_Printer.simple_const_syntax);
fun the_literals thy =
let
val (targets, _) = CodeTargetData.get thy;
fun literals target = case Symtab.lookup targets target
of SOME data => (case the_serializer data
of Serializer (_, literals) => literals
| Extends (super, _) => literals super)
| NONE => error ("Unknown code target language: " ^ quote target);
in literals end;
fun add_literal_list target nill cons thy =
let
val nil' = Code_Name.const thy nill;
val cons' = Code_Name.const thy cons;
val pr = pretty_list nil' cons' (the_literals thy target);
in
thy
|> add_syntax_const target cons (SOME pr)
end;
fun add_literal_list_string target nill cons charr nibbles thy =
let
val nil' = Code_Name.const thy nill;
val cons' = Code_Name.const thy cons;
val charr' = Code_Name.const thy charr;
val nibbles' = map (Code_Name.const thy) nibbles;
val pr = pretty_list_string nil' cons' charr' nibbles' (the_literals thy target);
in
thy
|> add_syntax_const target cons (SOME pr)
end;
fun add_literal_char target charr nibbles thy =
let
val charr' = Code_Name.const thy charr;
val nibbles' = map (Code_Name.const thy) nibbles;
val pr = pretty_char charr' nibbles' (the_literals thy target);
in
thy
|> add_syntax_const target charr (SOME pr)
end;
fun add_literal_numeral target unbounded negative number_of pls min bit0 bit1 thy =
let
val pls' = Code_Name.const thy pls;
val min' = Code_Name.const thy min;
val bit0' = Code_Name.const thy bit0;
val bit1' = Code_Name.const thy bit1;
val pr = pretty_numeral unbounded negative pls' min' bit0' bit1' (the_literals thy target);
in
thy
|> add_syntax_const target number_of (SOME pr)
end;
fun add_literal_message target charr nibbles nill cons str thy =
let
val charr' = Code_Name.const thy charr;
val nibbles' = map (Code_Name.const thy) nibbles;
val nil' = Code_Name.const thy nill;
val cons' = Code_Name.const thy cons;
val pr = pretty_message charr' nibbles' nil' cons' (the_literals thy target);
in
thy
|> add_syntax_const target str (SOME pr)
end;
(** serializer usage **)
(* montage *)
fun invoke_serializer thy modify abortable serializer reserved includes
module_alias class inst tyco const module args program1 cs1 =
let
val program2 = modify program1;
val hidden = Symtab.keys class @ Symtab.keys inst @ Symtab.keys tyco @ Symtab.keys const;
val cs2 = subtract (op =) hidden cs1;
val program3 = Graph.subgraph (not o member (op =) hidden) program2;
val all_cs = Graph.all_succs program2 cs2;
val program4 = Graph.subgraph (member (op =) all_cs) program3;
val empty_funs = filter_out (member (op =) abortable)
(Code_Thingol.empty_funs program3);
val _ = if null empty_funs then () else error ("No defining equations for "
^ commas (map (Code_Name.labelled_name thy) empty_funs));
in
serializer module args (Code_Name.labelled_name thy) reserved includes
(Symtab.lookup module_alias) (Symtab.lookup class)
(Symtab.lookup tyco) (Symtab.lookup const)
program4 cs2
end;
fun mount_serializer thy alt_serializer target =
let
val (targets, abortable) = CodeTargetData.get thy;
fun collapse_hierarchy target =
let
val data = case Symtab.lookup targets target
of SOME data => data
| NONE => error ("Unknown code target language: " ^ quote target);
in case the_serializer data
of Serializer _ => (I, data)
| Extends (super, modify) => let
val (modify', data') = collapse_hierarchy super
in (modify' #> modify, merge_target false target (data', data)) end
end;
val (modify, data) = collapse_hierarchy target;
val (serializer, _) = the_default (case the_serializer data
of Serializer seri => seri) alt_serializer;
val reserved = the_reserved data;
val includes = Symtab.dest (the_includes data);
val module_alias = the_module_alias data;
val { class, inst, tyco, const } = the_name_syntax data;
in
invoke_serializer thy modify abortable serializer reserved
includes module_alias class inst tyco const
end;
fun serialize thy = mount_serializer thy NONE;
fun serialize_custom thy (target_name, seri) program cs =
mount_serializer thy (SOME seri) target_name NONE [] program cs (String [])
|> the;
fun parse_args f args =
case Scan.read OuterLex.stopper f args
of SOME x => x
| NONE => error "Bad serializer arguments";
(* code presentation *)
fun code_of thy target module_name cs stmt_names =
let
val (cs', program) = Code_Thingol.consts_program thy cs;
in
string stmt_names (serialize thy target (SOME module_name) [] program cs')
end;
(* code generation *)
fun read_const_exprs thy cs =
let
val (cs1, cs2) = Code_Name.read_const_exprs thy cs;
val (cs3, program) = Code_Thingol.consts_program thy cs2;
val cs4 = Code_Thingol.transitivly_non_empty_funs program (abort_allowed thy);
val cs5 = map_filter
(fn (c, c') => if member (op =) cs4 c' then SOME c else NONE) (cs2 ~~ cs3);
in fold (insert (op =)) cs5 cs1 end;
fun cached_program thy =
let
val program = Code_Thingol.cached_program thy;
in (Code_Thingol.transitivly_non_empty_funs program (abort_allowed thy), program) end
fun export_code thy cs seris =
let
val (cs', program) = if null cs then cached_program thy
else Code_Thingol.consts_program thy cs;
fun mk_seri_dest dest = case dest
of NONE => compile
| SOME "-" => export
| SOME f => file (Path.explode f)
val _ = map (fn (((target, module), dest), args) =>
(mk_seri_dest dest (serialize thy target module args program cs'))) seris;
in () end;
fun export_code_cmd raw_cs seris thy = export_code thy (read_const_exprs thy raw_cs) seris;
(** Isar setup **)
val (inK, module_nameK, fileK) = ("in", "module_name", "file");
fun code_exprP cmd =
(Scan.repeat P.term_group
-- Scan.repeat (P.$$$ inK |-- P.name
-- Scan.option (P.$$$ module_nameK |-- P.name)
-- Scan.option (P.$$$ fileK |-- P.name)
-- Scan.optional (P.$$$ "(" |-- Args.parse --| P.$$$ ")") []
) >> (fn (raw_cs, seris) => cmd raw_cs seris));
val _ = List.app OuterKeyword.keyword [inK, module_nameK, fileK];
val _ =
OuterSyntax.command "code_class" "define code syntax for class" K.thy_decl (
parse_multi_syntax P.xname
(Scan.option (P.string -- Scan.optional (P.$$$ "where" |-- Scan.repeat1
(P.term_group --| (P.$$$ "\<equiv>" || P.$$$ "==") -- P.string)) []))
>> (Toplevel.theory oo fold) (fn (target, syns) =>
fold (fn (raw_class, syn) => add_syntax_class_cmd target raw_class syn) syns)
);
val _ =
OuterSyntax.command "code_instance" "define code syntax for instance" K.thy_decl (
parse_multi_syntax (P.xname --| P.$$$ "::" -- P.xname)
((P.minus >> K true) || Scan.succeed false)
>> (Toplevel.theory oo fold) (fn (target, syns) =>
fold (fn (raw_inst, add_del) => add_syntax_inst_cmd target raw_inst add_del) syns)
);
val _ =
OuterSyntax.command "code_type" "define code syntax for type constructor" K.thy_decl (
parse_multi_syntax P.xname (parse_syntax I)
>> (Toplevel.theory oo fold) (fn (target, syns) =>
fold (fn (raw_tyco, syn) => add_syntax_tyco_cmd target raw_tyco syn) syns)
);
val _ =
OuterSyntax.command "code_const" "define code syntax for constant" K.thy_decl (
parse_multi_syntax P.term_group (parse_syntax fst)
>> (Toplevel.theory oo fold) (fn (target, syns) =>
fold (fn (raw_const, syn) => add_syntax_const_cmd target raw_const
(Code_Printer.simple_const_syntax syn)) syns)
);
val _ =
OuterSyntax.command "code_reserved" "declare words as reserved for target language" K.thy_decl (
P.name -- Scan.repeat1 P.name
>> (fn (target, reserveds) => (Toplevel.theory o fold (add_reserved target)) reserveds)
);
val _ =
OuterSyntax.command "code_include" "declare piece of code to be included in generated code" K.thy_decl (
P.name -- P.name -- (P.text >> (fn "-" => NONE | s => SOME s))
>> (fn ((target, name), content) => (Toplevel.theory o add_include target)
(name, content))
);
val _ =
OuterSyntax.command "code_modulename" "alias module to other name" K.thy_decl (
P.name -- Scan.repeat1 (P.name -- P.name)
>> (fn (target, modlnames) => (Toplevel.theory o fold (add_module_alias target)) modlnames)
);
val _ =
OuterSyntax.command "code_abort" "permit constant to be implemented as program abort" K.thy_decl (
Scan.repeat1 P.term_group >> (Toplevel.theory o fold allow_abort_cmd)
);
val _ =
OuterSyntax.command "export_code" "generate executable code for constants"
K.diag (P.!!! (code_exprP export_code_cmd) >> (fn f => Toplevel.keep (f o Toplevel.theory_of)));
fun shell_command thyname cmd = Toplevel.program (fn _ =>
(use_thy thyname; case Scan.read OuterLex.stopper (P.!!! (code_exprP export_code_cmd))
((filter OuterLex.is_proper o OuterSyntax.scan Position.none) cmd)
of SOME f => (writeln "Now generating code..."; f (theory thyname))
| NONE => error ("Bad directive " ^ quote cmd)))
handle TOPLEVEL_ERROR => OS.Process.exit OS.Process.failure;
end; (*local*)
end; (*struct*)