(* Title: Tools/Code/code_target.ML
Author: Florian Haftmann, TU Muenchen
Generic infrastructure for target language data.
*)
signature CODE_TARGET =
sig
val cert_tyco: theory -> string -> string
val read_tyco: theory -> string -> string
val read_const_exprs: theory -> string list -> string list
val export_code_for: theory -> Path.T option -> string -> int option -> string -> Token.T list
-> Code_Thingol.naming -> Code_Thingol.program -> string list -> unit
val produce_code_for: theory -> string -> int option -> string -> Token.T list
-> Code_Thingol.naming -> Code_Thingol.program -> string list -> (string * string) list * string option list
val present_code_for: theory -> string -> int option -> string -> Token.T list
-> Code_Thingol.naming -> Code_Thingol.program -> string list * string list -> string
val check_code_for: theory -> string -> bool -> Token.T list
-> Code_Thingol.naming -> Code_Thingol.program -> string list -> unit
val export_code: theory -> string list
-> (((string * string) * Path.T option) * Token.T list) list -> unit
val produce_code: theory -> string list
-> string -> int option -> string -> Token.T list -> (string * string) list * string option list
val present_code: theory -> string list -> (Code_Thingol.naming -> string list)
-> string -> int option -> string -> Token.T list -> string
val check_code: theory -> string list
-> ((string * bool) * Token.T list) list -> unit
val generatedN: string
val evaluator: theory -> string -> Code_Thingol.naming -> Code_Thingol.program
-> string list -> ((string * class list) list * Code_Thingol.itype) * Code_Thingol.iterm
-> (string * string) list * string
type serializer
type literals = Code_Printer.literals
val add_target: string * { serializer: serializer, literals: literals,
check: { env_var: string, make_destination: Path.T -> Path.T, make_command: string -> string } }
-> theory -> theory
val extend_target: string *
(string * (Code_Thingol.naming -> Code_Thingol.program -> Code_Thingol.program))
-> theory -> theory
val assert_target: theory -> string -> string
val the_literals: theory -> string -> literals
type serialization
val parse_args: 'a parser -> Token.T list -> 'a
val serialization: (int -> Path.T option -> 'a -> unit)
-> (string list -> int -> 'a -> (string * string) list * (string -> string option))
-> 'a -> serialization
val set_default_code_width: int -> theory -> theory
type ('a, 'b, 'c, 'd, 'e, 'f) symbol_attr_decl
type identifier_data
val set_identifiers: (string, string, string, string, string, string) symbol_attr_decl
-> theory -> theory
type const_syntax = Code_Printer.const_syntax
type tyco_syntax = Code_Printer.tyco_syntax
val set_printings: (const_syntax, tyco_syntax, string, unit, unit, (string * string list)) symbol_attr_decl
-> theory -> theory
val add_const_syntax: string -> string -> const_syntax option -> theory -> theory
val add_tyco_syntax: string -> string -> tyco_syntax option -> theory -> theory
val add_class_syntax: string -> class -> string option -> theory -> theory
val add_instance_syntax: string -> class * string -> unit option -> theory -> theory
val add_reserved: string -> string -> theory -> theory
val add_include: string -> string * (string * string list) option -> theory -> theory
val allow_abort: string -> theory -> theory
val codegen_tool: string (*theory name*) -> string (*export_code expr*) -> unit
val setup: theory -> theory
end;
structure Code_Target : CODE_TARGET =
struct
open Basic_Code_Thingol;
type literals = Code_Printer.literals;
type ('a, 'b, 'c, 'd, 'e, 'f) symbol_attr_decl =
(string * (string * 'a option) list, string * (string * 'b option) list,
class * (string * 'c option) list, (class * class) * (string * 'd option) list,
(class * string) * (string * 'e option) list,
string * (string * 'f option) list) Code_Symbol.attr;
type identifier_data = (string, string, string, string, string, string) Code_Symbol.data;
type tyco_syntax = Code_Printer.tyco_syntax;
type const_syntax = Code_Printer.const_syntax;
(** checking and parsing of symbols **)
fun cert_const thy const =
let
val _ = if Sign.declared_const thy const then ()
else error ("No such constant: " ^ quote const);
in const end;
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 = #1 o dest_Type
o Proof_Context.read_type_name_proper (Proof_Context.init_global thy) true;
fun cert_class thy class =
let
val _ = Axclass.get_info thy class;
in class end;
fun read_class thy = Proof_Context.read_class (Proof_Context.init_global thy);
val parse_classrel_ident = Parse.class --| @{keyword "<"} -- Parse.class;
fun cert_inst thy (class, tyco) =
(cert_class thy class, cert_tyco thy tyco);
fun read_inst thy (raw_tyco, raw_class) =
(read_class thy raw_class, read_tyco thy raw_tyco);
val parse_inst_ident = Parse.xname --| @{keyword "::"} -- Parse.class;
fun cert_syms thy =
Code_Symbol.map_attr (apfst (cert_const thy)) (apfst (cert_tyco thy))
(apfst (cert_class thy)) ((apfst o pairself) (cert_class thy)) (apfst (cert_inst thy)) I;
fun read_syms thy =
Code_Symbol.map_attr (apfst (Code.read_const thy)) (apfst (read_tyco thy))
(apfst (read_class thy)) ((apfst o pairself) (read_class thy)) (apfst (read_inst thy)) I;
fun check_name is_module s =
let
val _ = if s = "" then error "Bad empty code name" else ();
val xs = Long_Name.explode s;
val xs' = if is_module
then map (Name.desymbolize true) xs
else if length xs < 2
then error ("Bad code name without module component: " ^ quote s)
else
let
val (ys, y) = split_last xs;
val ys' = map (Name.desymbolize true) ys;
val y' = Name.desymbolize false y;
in ys' @ [y'] end;
in if xs' = xs
then s
else error ("Invalid code name: " ^ quote s ^ "\n"
^ "better try " ^ quote (Long_Name.implode xs'))
end;
(** serializations and serializer **)
(* serialization: abstract nonsense to cover different destinies for generated code *)
datatype destination = Export of Path.T option | Produce | Present of string list;
type serialization = int -> destination -> ((string * string) list * (string -> string option)) option;
fun serialization output _ content width (Export some_path) =
(output width some_path content; NONE)
| serialization _ string content width Produce =
string [] width content |> SOME
| serialization _ string content width (Present stmt_names) =
string stmt_names width content
|> (apfst o map o apsnd) (Pretty.output (SOME width) o Pretty.str)
|> SOME;
fun export some_path f = (f (Export some_path); ());
fun produce f = the (f Produce);
fun present stmt_names f = space_implode "\n\n" (map snd (fst (the (f (Present stmt_names)))));
(* serializers: functions producing serializations *)
type serializer = Token.T list
-> Proof.context
-> {
symbol_of: string -> Code_Symbol.symbol,
module_name: string,
reserved_syms: string list,
identifiers: identifier_data,
includes: (string * Pretty.T) list,
class_syntax: string -> string option,
tyco_syntax: string -> Code_Printer.tyco_syntax option,
const_syntax: string -> Code_Printer.activated_const_syntax option }
-> Code_Thingol.program
-> serialization;
datatype description =
Fundamental of { serializer: serializer,
literals: literals,
check: { env_var: string, make_destination: Path.T -> Path.T,
make_command: string -> string } }
| Extension of string *
(Code_Thingol.naming -> Code_Thingol.program -> Code_Thingol.program);
(** theory data **)
datatype target = Target of {
serial: serial,
description: description,
reserved: string list,
identifiers: identifier_data,
printings: (Code_Printer.const_syntax, Code_Printer.tyco_syntax, string, unit, unit,
(Pretty.T * string list)) Code_Symbol.data
};
fun make_target ((serial, description), (reserved, (identifiers, printings))) =
Target { serial = serial, description = description, reserved = reserved,
identifiers = identifiers, printings = printings };
fun map_target f (Target { serial, description, reserved, identifiers, printings }) =
make_target (f ((serial, description), (reserved, (identifiers, printings))));
fun merge_target strict target (Target { serial = serial1, description = description,
reserved = reserved1, identifiers = identifiers1, printings = printings1 },
Target { serial = serial2, description = _,
reserved = reserved2, identifiers = identifiers2, printings = printings2 }) =
if serial1 = serial2 orelse not strict then
make_target ((serial1, description), (merge (op =) (reserved1, reserved2),
(Code_Symbol.merge_data (identifiers1, identifiers2),
Code_Symbol.merge_data (printings1, printings2))))
else
error ("Incompatible targets: " ^ quote target);
fun the_description (Target { description, ... }) = description;
fun the_reserved (Target { reserved, ... }) = reserved;
fun the_identifiers (Target { identifiers , ... }) = identifiers;
fun the_printings (Target { printings, ... }) = printings;
structure Targets = Theory_Data
(
type T = (target Symtab.table * string list) * int;
val empty = ((Symtab.empty, []), 80);
val extend = I;
fun merge (((target1, exc1), width1), ((target2, exc2), width2)) : T =
((Symtab.join (merge_target true) (target1, target2),
Library.merge (op =) (exc1, exc2)), Int.max (width1, width2));
);
val abort_allowed = snd o fst o Targets.get;
fun assert_target thy target = if Symtab.defined ((fst o fst) (Targets.get thy)) target
then target
else error ("Unknown code target language: " ^ quote target);
fun put_target (target, seri) thy =
let
val lookup_target = Symtab.lookup ((fst o fst) (Targets.get thy));
val _ = case seri
of Extension (super, _) => if is_some (lookup_target super) then ()
else error ("Unknown code target language: " ^ quote super)
| _ => ();
val overwriting = case (Option.map the_description o lookup_target) target
of NONE => false
| SOME (Extension _) => true
| SOME (Fundamental _) => (case seri
of Extension _ => error ("Will not overwrite existing target " ^ quote target)
| _ => true);
val _ = if overwriting
then warning ("Overwriting existing target " ^ quote target)
else ();
in
thy
|> (Targets.map o apfst o apfst o Symtab.update)
(target, make_target ((serial (), seri),
([], (Code_Symbol.empty_data, Code_Symbol.empty_data))))
end;
fun add_target (target, seri) = put_target (target, Fundamental seri);
fun extend_target (target, (super, modify)) =
put_target (target, Extension (super, modify));
fun map_target_data target f thy =
let
val _ = assert_target thy target;
in
thy
|> (Targets.map o apfst o apfst o Symtab.map_entry target o map_target o apsnd) f
end;
fun map_reserved target =
map_target_data target o apfst;
fun map_identifiers target =
map_target_data target o apsnd o apfst;
fun map_printings target =
map_target_data target o apsnd o apsnd;
fun set_default_code_width k = (Targets.map o apsnd) (K k);
(** serializer usage **)
(* montage *)
fun the_fundamental thy =
let
val ((targets, _), _) = Targets.get thy;
fun fundamental target = case Symtab.lookup targets target
of SOME data => (case the_description data
of Fundamental data => data
| Extension (super, _) => fundamental super)
| NONE => error ("Unknown code target language: " ^ quote target);
in fundamental end;
fun the_literals thy = #literals o the_fundamental thy;
fun collapse_hierarchy thy =
let
val ((targets, _), _) = Targets.get thy;
fun collapse target =
let
val data = case Symtab.lookup targets target
of SOME data => data
| NONE => error ("Unknown code target language: " ^ quote target);
in case the_description data
of Fundamental _ => (K I, data)
| Extension (super, modify) => let
val (modify', data') = collapse super
in (fn naming => modify' naming #> modify naming, merge_target false target (data', data)) end
end;
in collapse end;
local
fun activate_target thy target =
let
val ((_, abortable), default_width) = Targets.get thy;
val (modify, data) = collapse_hierarchy thy target;
in (default_width, abortable, data, modify) end;
fun activate_const_syntax thy literals cs_data naming =
(Symtab.empty, naming)
|> fold_map (fn (c, data) => fn (tab, naming) =>
case Code_Thingol.lookup_const naming c
of SOME name => let
val (syn, naming') =
Code_Printer.activate_const_syntax thy literals c data naming
in (SOME name, (Symtab.update_new (name, syn) tab, naming')) end
| NONE => (NONE, (tab, naming))) cs_data
|>> map_filter I;
fun activate_syntax lookup_name things =
Symtab.empty
|> fold_map (fn (thing_identifier, data) => fn tab => case lookup_name thing_identifier
of SOME name => (SOME name, Symtab.update_new (name, data) tab)
| NONE => (NONE, tab)) things
|>> map_filter I;
fun activate_symbol_syntax thy literals naming printings =
let
val (names_const, (const_syntax, _)) =
activate_const_syntax thy literals (Code_Symbol.dest_constant_data printings) naming;
val (names_tyco, tyco_syntax) =
activate_syntax (Code_Thingol.lookup_tyco naming) (Code_Symbol.dest_type_constructor_data printings);
val (names_class, class_syntax) =
activate_syntax (Code_Thingol.lookup_class naming) (Code_Symbol.dest_type_class_data printings);
val names_inst = map_filter (Code_Thingol.lookup_instance naming o fst)
(Code_Symbol.dest_class_instance_data printings);
in
(names_const @ names_tyco @ names_class @ names_inst,
(const_syntax, tyco_syntax, class_syntax))
end;
fun project_program thy abortable names_hidden names1 program2 =
let
val ctxt = Proof_Context.init_global thy;
val names2 = subtract (op =) names_hidden names1;
val program3 = Graph.restrict (not o member (op =) names_hidden) program2;
val names4 = Graph.all_succs program3 names2;
val empty_funs = filter_out (member (op =) abortable)
(Code_Thingol.empty_funs program3);
val _ =
if null empty_funs then ()
else error ("No code equations for " ^
commas (map (Proof_Context.extern_const ctxt) empty_funs));
val program4 = Graph.restrict (member (op =) names4) program3;
in (names4, program4) end;
fun prepare_serializer thy abortable (serializer : serializer) literals reserved identifiers
printings module_name args naming proto_program names =
let
val (names_hidden, (const_syntax, tyco_syntax, class_syntax)) =
activate_symbol_syntax thy literals naming printings;
val (names_all, program) = project_program thy abortable names_hidden names proto_program;
fun select_include (name, (content, cs)) =
if null cs orelse exists (fn c => case Code_Thingol.lookup_const naming c
of SOME name => member (op =) names_all name
| NONE => false) cs
then SOME (name, content) else NONE;
val includes = map_filter select_include (Code_Symbol.dest_module_data printings);
in
(serializer args (Proof_Context.init_global thy) {
symbol_of = Code_Thingol.symbol_of proto_program,
module_name = module_name,
reserved_syms = reserved,
identifiers = identifiers,
includes = includes,
const_syntax = Symtab.lookup const_syntax,
tyco_syntax = Symtab.lookup tyco_syntax,
class_syntax = Symtab.lookup class_syntax },
program)
end;
fun mount_serializer thy target some_width module_name args naming program names =
let
val (default_width, abortable, data, modify) = activate_target thy target;
val serializer = case the_description data
of Fundamental seri => #serializer seri;
val (prepared_serializer, prepared_program) =
prepare_serializer thy abortable serializer (the_literals thy target)
(the_reserved data) (the_identifiers data) (the_printings data)
module_name args naming (modify naming program) names
val width = the_default default_width some_width;
in (fn program => prepared_serializer program width, prepared_program) end;
fun invoke_serializer thy target some_width module_name args naming program names =
let
val (mounted_serializer, prepared_program) = mount_serializer thy
target some_width module_name args naming program names;
in mounted_serializer prepared_program end;
fun assert_module_name "" = error "Empty module name not allowed here"
| assert_module_name module_name = module_name;
fun using_master_directory thy =
Option.map (Path.append (File.pwd ()) o Path.append (Thy_Load.master_directory thy));
in
val generatedN = "Generated_Code";
fun export_code_for thy some_path target some_width module_name args =
export (using_master_directory thy some_path)
ooo invoke_serializer thy target some_width module_name args;
fun produce_code_for thy target some_width module_name args =
let
val serializer = invoke_serializer thy target some_width (assert_module_name module_name) args;
in fn naming => fn program => fn names =>
produce (serializer naming program names) |> apsnd (fn deresolve => map deresolve names)
end;
fun present_code_for thy target some_width module_name args =
let
val serializer = invoke_serializer thy target some_width (assert_module_name module_name) args;
in fn naming => fn program => fn (names, selects) =>
present selects (serializer naming program names)
end;
fun check_code_for thy target strict args naming program names_cs =
let
val { env_var, make_destination, make_command } =
(#check o the_fundamental thy) target;
fun ext_check p =
let
val destination = make_destination p;
val _ = export (SOME destination) (invoke_serializer thy target (SOME 80)
generatedN args naming program names_cs);
val cmd = make_command generatedN;
in
if Isabelle_System.bash ("cd " ^ File.shell_path p ^ " && " ^ cmd ^ " 2>&1") <> 0
then error ("Code check failed for " ^ target ^ ": " ^ cmd)
else ()
end;
in
if getenv env_var = ""
then if strict
then error (env_var ^ " not set; cannot check code for " ^ target)
else warning (env_var ^ " not set; skipped checking code for " ^ target)
else Isabelle_System.with_tmp_dir "Code_Test" ext_check
end;
fun evaluation mounted_serializer prepared_program consts ((vs, ty), t) =
let
val _ = if Code_Thingol.contains_dict_var t then
error "Term to be evaluated contains free dictionaries" else ();
val v' = singleton (Name.variant_list (map fst vs)) "a";
val vs' = (v', []) :: vs;
val ty' = Code_Thingol.fun_tyco `%% [ITyVar v', ty];
val value_name = "Value.value.value"
val program = prepared_program
|> Graph.new_node (value_name,
Code_Thingol.Fun (@{const_name dummy_pattern}, (((vs', ty'), [(([IVar NONE], t), (NONE, true))]), NONE)))
|> fold (curry (perhaps o try o Graph.add_edge) value_name) consts;
val (program_code, deresolve) = produce (mounted_serializer program);
val value_name' = the (deresolve value_name);
in (program_code, value_name') end;
fun evaluator thy target naming program consts =
let
val (mounted_serializer, prepared_program) = mount_serializer thy
target NONE generatedN [] naming program consts;
in evaluation mounted_serializer prepared_program consts end;
end; (* local *)
(* code generation *)
fun transitivly_non_empty_funs thy naming program =
let
val cs = subtract (op =) (abort_allowed thy) (Code_Thingol.empty_funs program);
val names = map_filter (Code_Thingol.lookup_const naming) cs;
in subtract (op =) (Graph.all_preds program names) (Graph.keys program) end;
fun read_const_exprs thy cs =
let
val (cs1, cs2) = Code_Thingol.read_const_exprs thy cs;
val (names2, (naming, program)) = Code_Thingol.consts_program thy true cs2;
val names3 = transitivly_non_empty_funs thy naming program;
val cs3 = map_filter (fn (c, name) =>
if member (op =) names3 name then SOME c else NONE) (cs2 ~~ names2);
in union (op =) cs3 cs1 end;
fun prep_destination "" = NONE
| prep_destination "-" = NONE
| prep_destination s = SOME (Path.explode s);
fun export_code thy cs seris =
let
val (names_cs, (naming, program)) = Code_Thingol.consts_program thy false cs;
val _ = map (fn (((target, module_name), some_path), args) =>
export_code_for thy some_path target NONE module_name args naming program names_cs) seris;
in () end;
fun export_code_cmd raw_cs seris thy = export_code thy (read_const_exprs thy raw_cs)
((map o apfst o apsnd) prep_destination seris);
fun produce_code thy cs target some_width some_module_name args =
let
val (names_cs, (naming, program)) = Code_Thingol.consts_program thy false cs;
in produce_code_for thy target some_width some_module_name args naming program names_cs end;
fun present_code thy cs names_stmt target some_width some_module_name args =
let
val (names_cs, (naming, program)) = Code_Thingol.consts_program thy false cs;
in present_code_for thy target some_width some_module_name args naming program (names_cs, names_stmt naming) end;
fun check_code thy cs seris =
let
val (names_cs, (naming, program)) = Code_Thingol.consts_program thy false cs;
val _ = map (fn ((target, strict), args) =>
check_code_for thy target strict args naming program names_cs) seris;
in () end;
fun check_code_cmd raw_cs seris thy = check_code thy (read_const_exprs thy raw_cs) seris;
local
val parse_const_terms = Scan.repeat1 Args.term
>> (fn ts => fn thy => map (Code.check_const thy) ts);
fun parse_names category parse internalize lookup =
Scan.lift (Args.parens (Args.$$$ category)) |-- Scan.repeat1 parse
>> (fn xs => fn thy => fn naming => map_filter (lookup naming o internalize thy) xs);
val parse_consts = parse_names "consts" Args.term
Code.check_const Code_Thingol.lookup_const;
val parse_types = parse_names "types" (Scan.lift Args.name)
Sign.intern_type Code_Thingol.lookup_tyco;
val parse_classes = parse_names "classes" (Scan.lift Args.name)
Sign.intern_class Code_Thingol.lookup_class;
val parse_instances = parse_names "instances" (Scan.lift (Args.name --| Args.$$$ "::" -- Args.name))
(fn thy => fn (raw_tyco, raw_class) => (Sign.intern_class thy raw_class, Sign.intern_type thy raw_tyco))
Code_Thingol.lookup_instance;
in
val antiq_setup =
Thy_Output.antiquotation @{binding code_stmts}
(parse_const_terms --
Scan.repeat (parse_consts || parse_types || parse_classes || parse_instances)
-- Scan.lift (Args.parens (Args.name -- Scan.option Parse.int)))
(fn {context = ctxt, ...} => fn ((mk_cs, mk_stmtss), (target, some_width)) =>
let val thy = Proof_Context.theory_of ctxt in
present_code thy (mk_cs thy)
(fn naming => maps (fn f => f thy naming) mk_stmtss)
target some_width "Example" []
end);
end;
(** serializer configuration **)
(* reserved symbol names *)
fun add_reserved target sym thy =
let
val (_, data) = collapse_hierarchy thy target;
val _ = if member (op =) (the_reserved data) sym
then error ("Reserved symbol " ^ quote sym ^ " already declared")
else ();
in
thy
|> map_reserved target (insert (op =) sym)
end;
(* checking of syntax *)
fun check_const_syntax thy c syn =
if Code_Printer.requires_args syn > Code.args_number thy c
then error ("Too many arguments in syntax for constant " ^ quote c)
else syn;
fun check_tyco_syntax thy tyco syn =
if fst syn <> Sign.arity_number thy tyco
then error ("Number of arguments mismatch in syntax for type constructor " ^ quote tyco)
else syn;
(* custom symbol names *)
fun arrange_name_decls x =
let
fun arrange is_module (sym, target_names) = map (fn (target, some_name) =>
(target, (sym, Option.map (check_name is_module) some_name))) target_names;
in
Code_Symbol.maps_attr' (arrange false) (arrange false) (arrange false)
(arrange false) (arrange false) (arrange true) x
end;
fun cert_name_decls thy = cert_syms thy #> arrange_name_decls;
fun read_name_decls thy = read_syms thy #> arrange_name_decls;
fun set_identifier (target, sym_name) = map_identifiers target (Code_Symbol.set_data sym_name);
fun gen_set_identifiers prep_name_decl raw_name_decls thy =
fold set_identifier (prep_name_decl thy raw_name_decls) thy;
val set_identifiers = gen_set_identifiers cert_name_decls;
val set_identifiers_cmd = gen_set_identifiers read_name_decls;
fun add_module_alias_cmd target = fold (fn (sym, name) =>
set_identifier (target, Code_Symbol.Module (sym, if name = "" then NONE else SOME (check_name true name))));
(* custom printings *)
fun arrange_printings prep_const thy =
let
fun arrange check (sym, target_syns) =
map (fn (target, some_syn) => (target, (sym, Option.map (check thy sym) some_syn))) target_syns;
in
Code_Symbol.maps_attr'
(arrange check_const_syntax) (arrange check_tyco_syntax)
(arrange ((K o K) I)) (arrange ((K o K) I)) (arrange ((K o K) I))
(arrange (fn thy => fn _ => fn (raw_content, raw_cs) =>
(Code_Printer.str raw_content, map (prep_const thy) raw_cs)))
end;
fun cert_printings thy = cert_syms thy #> arrange_printings cert_const thy;
fun read_printings thy = read_syms thy #> arrange_printings Code.read_const thy;
fun set_printing (target, sym_syn) = map_printings target (Code_Symbol.set_data sym_syn);
fun gen_set_printings prep_print_decl raw_print_decls thy =
fold set_printing (prep_print_decl thy raw_print_decls) thy;
val set_printings = gen_set_printings cert_printings;
val set_printings_cmd = gen_set_printings read_printings;
fun gen_add_syntax Symbol prep_x prep_syn target raw_x some_raw_syn thy =
let
val x = prep_x thy raw_x;
in set_printing (target, Symbol (x, Option.map (prep_syn thy x) some_raw_syn)) thy end;
fun gen_add_const_syntax prep_const =
gen_add_syntax Code_Symbol.Constant prep_const check_const_syntax;
fun gen_add_tyco_syntax prep_tyco =
gen_add_syntax Code_Symbol.Type_Constructor prep_tyco check_tyco_syntax;
fun gen_add_class_syntax prep_class =
gen_add_syntax Code_Symbol.Type_Class prep_class ((K o K) I);
fun gen_add_instance_syntax prep_inst =
gen_add_syntax Code_Symbol.Class_Instance prep_inst ((K o K) I);
fun gen_add_include prep_const target (name, some_content) thy =
gen_add_syntax Code_Symbol.Module (K I)
(fn thy => fn _ => fn (raw_content, raw_cs) => (Code_Printer.str raw_content, map (prep_const thy) raw_cs))
target name some_content thy;
(* abortable constants *)
fun gen_allow_abort prep_const raw_c thy =
let
val c = prep_const thy raw_c;
in thy |> (Targets.map o apfst o apsnd) (insert (op =) c) end;
(* concrete syntax *)
local
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)));
fun process_multi_syntax parse_thing parse_syntax change =
(Parse.and_list1 parse_thing
:|-- (fn things => Scan.repeat1 (@{keyword "("} |-- Parse.name --
(zip_list things (Scan.option parse_syntax) @{keyword "and"}) --| @{keyword ")"})))
>> (Toplevel.theory oo fold)
(fn (target, syns) => fold (fn (raw_x, syn) => change target raw_x syn) syns);
in
val add_reserved = add_reserved;
val add_const_syntax = gen_add_const_syntax (K I);
val add_tyco_syntax = gen_add_tyco_syntax cert_tyco;
val add_class_syntax = gen_add_class_syntax cert_class;
val add_instance_syntax = gen_add_instance_syntax cert_inst;
val add_include = gen_add_include (K I);
val allow_abort = gen_allow_abort (K I);
val add_const_syntax_cmd = gen_add_const_syntax Code.read_const;
val add_tyco_syntax_cmd = gen_add_tyco_syntax read_tyco;
val add_class_syntax_cmd = gen_add_class_syntax read_class;
val add_instance_syntax_cmd = gen_add_instance_syntax read_inst;
val add_include_cmd = gen_add_include Code.read_const;
val allow_abort_cmd = gen_allow_abort Code.read_const;
fun parse_args f args =
case Scan.read Token.stopper f args
of SOME x => x
| NONE => error "Bad serializer arguments";
(** Isar setup **)
fun parse_single_symbol_pragma parse_keyword parse_isa parse_target =
parse_keyword |-- Parse.!!! parse_isa --| (@{keyword "\<rightharpoonup>"} || @{keyword "=>"})
-- Parse.and_list1 (@{keyword "("} |-- (Parse.name --| @{keyword ")"} -- Scan.option parse_target));
fun parse_symbol_pragma parse_const parse_tyco parse_class parse_classrel parse_inst parse_module =
parse_single_symbol_pragma @{keyword "constant"} Parse.term_group parse_const
>> Code_Symbol.Constant
|| parse_single_symbol_pragma @{keyword "type_constructor"} Parse.type_const parse_tyco
>> Code_Symbol.Type_Constructor
|| parse_single_symbol_pragma @{keyword "type_class"} Parse.class parse_class
>> Code_Symbol.Type_Class
|| parse_single_symbol_pragma @{keyword "class_relation"} parse_classrel_ident parse_classrel
>> Code_Symbol.Class_Relation
|| parse_single_symbol_pragma @{keyword "class_instance"} parse_inst_ident parse_inst
>> Code_Symbol.Class_Instance
|| parse_single_symbol_pragma @{keyword "code_module"} Parse.name parse_module
>> Code_Symbol.Module;
fun parse_symbol_pragmas parse_const parse_tyco parse_class parse_classrel parse_inst parse_module =
Parse.enum1 "|" (Parse.group (fn () => "code symbol pragma")
(parse_symbol_pragma parse_const parse_tyco parse_class parse_classrel parse_inst parse_module));
val code_expr_argsP = Scan.optional (@{keyword "("} |-- Args.parse --| @{keyword ")"}) [];
val code_exprP =
Scan.repeat1 Parse.term_group :|-- (fn raw_cs =>
((@{keyword "checking"} |-- Scan.repeat (Parse.name
-- ((@{keyword "?"} |-- Scan.succeed false) || Scan.succeed true) -- code_expr_argsP))
>> (fn seris => check_code_cmd raw_cs seris)
|| Scan.repeat (@{keyword "in"} |-- Parse.name
-- Scan.optional (@{keyword "module_name"} |-- Parse.name) ""
-- Scan.optional (@{keyword "file"} |-- Parse.name) ""
-- code_expr_argsP) >> (fn seris => export_code_cmd raw_cs seris)));
val _ =
Outer_Syntax.command @{command_spec "code_reserved"}
"declare words as reserved for target language"
(Parse.name -- Scan.repeat1 Parse.name
>> (fn (target, reserveds) => (Toplevel.theory o fold (add_reserved target)) reserveds));
val _ =
Outer_Syntax.command @{command_spec "code_identifier"} "declare mandatory names for code symbols"
(parse_symbol_pragmas Parse.name Parse.name Parse.name Parse.name Parse.name Parse.name
>> (Toplevel.theory o fold set_identifiers_cmd));
val _ =
Outer_Syntax.command @{command_spec "code_modulename"} "alias module to other name"
(Parse.name -- Scan.repeat1 (Parse.name -- Parse.name)
>> (fn (target, modlnames) => (Toplevel.theory o add_module_alias_cmd target) modlnames));
val _ =
Outer_Syntax.command @{command_spec "code_printing"} "declare dedicated printing for code symbols"
(parse_symbol_pragmas (Code_Printer.parse_const_syntax) (Code_Printer.parse_tyco_syntax)
Parse.string (Parse.minus >> K ()) (Parse.minus >> K ())
(Parse.text -- Scan.optional (@{keyword "attach"} |-- Scan.repeat1 Parse.term) [])
>> (Toplevel.theory o fold set_printings_cmd));
val _ =
Outer_Syntax.command @{command_spec "code_const"} "define code syntax for constant"
(process_multi_syntax Parse.term_group Code_Printer.parse_const_syntax
add_const_syntax_cmd);
val _ =
Outer_Syntax.command @{command_spec "code_type"} "define code syntax for type constructor"
(process_multi_syntax Parse.type_const Code_Printer.parse_tyco_syntax
add_tyco_syntax_cmd);
val _ =
Outer_Syntax.command @{command_spec "code_class"} "define code syntax for class"
(process_multi_syntax Parse.class Parse.string
add_class_syntax_cmd);
val _ =
Outer_Syntax.command @{command_spec "code_instance"} "define code syntax for instance"
(process_multi_syntax parse_inst_ident (Parse.minus >> K ())
add_instance_syntax_cmd);
val _ =
Outer_Syntax.command @{command_spec "code_include"}
"declare piece of code to be included in generated code"
(Parse.name -- Parse.name -- (Parse.text :|--
(fn "-" => Scan.succeed NONE
| s => Scan.optional (@{keyword "attach"} |-- Scan.repeat1 Parse.term) [] >> pair s >> SOME))
>> (fn ((target, name), content_consts) =>
(Toplevel.theory o add_include_cmd target) (name, content_consts)));
val _ =
Outer_Syntax.command @{command_spec "code_abort"}
"permit constant to be implemented as program abort"
(Scan.repeat1 Parse.term_group >> (Toplevel.theory o fold allow_abort_cmd));
val _ =
Outer_Syntax.command @{command_spec "export_code"} "generate executable code for constants"
(Parse.!!! code_exprP >> (fn f => Toplevel.keep (f o Toplevel.theory_of)));
end; (*local*)
(** external entrance point -- for codegen tool **)
fun codegen_tool thyname cmd_expr =
let
val thy = Thy_Info.get_theory thyname;
val parse = Scan.read Token.stopper (Parse.!!! code_exprP) o
(filter Token.is_proper o Outer_Syntax.scan Position.none);
in case parse cmd_expr
of SOME f => (writeln "Now generating code..."; f thy)
| NONE => error ("Bad directive " ^ quote cmd_expr)
end;
(** theory setup **)
val setup = antiq_setup;
end; (*struct*)