(* Title: Pure/ML/ml_antiquote.ML
Author: Makarius
Common ML antiquotations.
*)
signature ML_ANTIQUOTE =
sig
val variant: string -> Proof.context -> string * Proof.context
val macro: binding -> Proof.context context_parser -> theory -> theory
val inline: binding -> string context_parser -> theory -> theory
val declaration: string -> binding -> string context_parser -> theory -> theory
val value: binding -> string context_parser -> theory -> theory
end;
structure ML_Antiquote: ML_ANTIQUOTE =
struct
(** generic tools **)
(* ML names *)
val init_context = ML_Syntax.reserved |> Name.declare "ML_context";
structure Names = Proof_Data
(
type T = Name.context;
fun init _ = init_context;
);
fun variant a ctxt =
let
val names = Names.get ctxt;
val (b, names') = Name.variant a names;
val ctxt' = Names.put names' ctxt;
in (b, ctxt') end;
(* specific antiquotations *)
fun macro name scan = ML_Context.add_antiq name
(fn _ => scan :|-- (fn ctxt => Scan.depend (fn _ => Scan.succeed
(Context.Proof ctxt, fn background => (K ("", ""), background)))));
fun inline name scan = ML_Context.add_antiq name
(fn _ => scan >> (fn s => fn background => (K ("", s), background)));
fun declaration kind name scan = ML_Context.add_antiq name
(fn _ => scan >> (fn s => fn background =>
let
val (a, background') =
variant (translate_string (fn "." => "_" | c => c) (Binding.name_of name)) background;
val env = kind ^ " " ^ a ^ " = " ^ s ^ ";\n";
val body = "Isabelle." ^ a;
in (K (env, body), background') end));
val value = declaration "val";
(** misc antiquotations **)
val _ = Context.>> (Context.map_theory
(inline (Binding.name "assert")
(Scan.succeed "(fn b => if b then () else raise General.Fail \"Assertion failed\")") #>
inline (Binding.name "make_string") (Scan.succeed ml_make_string) #>
value (Binding.name "option_default") (Scan.lift Args.name >> (fn name =>
let val typ = Options.typ (Options.default ()) name
in "fn () => Options.default_" ^ typ ^ " " ^ ML_Syntax.print_string name end)) #>
value (Binding.name "binding")
(Scan.lift (Parse.position Args.name) >> ML_Syntax.make_binding) #>
value (Binding.name "theory")
(Args.theory -- Scan.lift (Parse.position Args.name) >> (fn (thy, (name, pos)) =>
(Position.report pos (Theory.get_markup (Context.get_theory thy name));
"Context.get_theory (Proof_Context.theory_of ML_context) " ^ ML_Syntax.print_string name))
|| Scan.succeed "Proof_Context.theory_of ML_context") #>
value (Binding.name "theory_context")
(Args.theory -- Scan.lift (Parse.position Args.name) >> (fn (thy, (name, pos)) =>
(Position.report pos (Theory.get_markup (Context.get_theory thy name));
"Proof_Context.get_global (Proof_Context.theory_of ML_context) " ^
ML_Syntax.print_string name))) #>
inline (Binding.name "context") (Scan.succeed "Isabelle.ML_context") #>
inline (Binding.name "typ") (Args.typ >> (ML_Syntax.atomic o ML_Syntax.print_typ)) #>
inline (Binding.name "term") (Args.term >> (ML_Syntax.atomic o ML_Syntax.print_term)) #>
inline (Binding.name "prop") (Args.prop >> (ML_Syntax.atomic o ML_Syntax.print_term)) #>
macro (Binding.name "let")
(Args.context --
Scan.lift
(Parse.and_list1 (Parse.and_list1 Args.name_source -- (Args.$$$ "=" |-- Args.name_source)))
>> (fn (ctxt, args) => #2 (Proof_Context.match_bind true args ctxt))) #>
macro (Binding.name "note")
(Args.context :|-- (fn ctxt =>
Parse.and_list1' (Scan.lift (Args.opt_thm_name I "=") -- Attrib.thms
>> (fn ((a, srcs), ths) => ((a, map (Attrib.attribute_cmd ctxt) srcs), [(ths, [])])))
>> (fn args => #2 (Proof_Context.note_thmss "" args ctxt)))) #>
value (Binding.name "ctyp") (Args.typ >> (fn T =>
"Thm.ctyp_of (Proof_Context.theory_of ML_context) " ^
ML_Syntax.atomic (ML_Syntax.print_typ T))) #>
value (Binding.name "cterm") (Args.term >> (fn t =>
"Thm.cterm_of (Proof_Context.theory_of ML_context) " ^
ML_Syntax.atomic (ML_Syntax.print_term t))) #>
value (Binding.name "cprop") (Args.prop >> (fn t =>
"Thm.cterm_of (Proof_Context.theory_of ML_context) " ^
ML_Syntax.atomic (ML_Syntax.print_term t))) #>
value (Binding.name "cpat")
(Args.context --
Scan.lift Args.name_source >> uncurry Proof_Context.read_term_pattern >> (fn t =>
"Thm.cterm_of (Proof_Context.theory_of ML_context) " ^
ML_Syntax.atomic (ML_Syntax.print_term t)))));
(* type classes *)
fun class syn = Args.context -- Scan.lift Args.name_source >> (fn (ctxt, s) =>
Proof_Context.read_class ctxt s
|> syn ? Lexicon.mark_class
|> ML_Syntax.print_string);
val _ = Context.>> (Context.map_theory
(inline (Binding.name "class") (class false) #>
inline (Binding.name "class_syntax") (class true) #>
inline (Binding.name "sort")
(Args.context -- Scan.lift Args.name_source >> (fn (ctxt, s) =>
ML_Syntax.atomic (ML_Syntax.print_sort (Syntax.read_sort ctxt s))))));
(* type constructors *)
fun type_name kind check = Args.context -- Scan.lift (Parse.position Args.name_source)
>> (fn (ctxt, (s, pos)) =>
let
val Type (c, _) = Proof_Context.read_type_name_proper ctxt false s;
val decl = Type.the_decl (Proof_Context.tsig_of ctxt) (c, pos);
val res =
(case try check (c, decl) of
SOME res => res
| NONE => error ("Not a " ^ kind ^ ": " ^ quote c ^ Position.here pos));
in ML_Syntax.print_string res end);
val _ = Context.>> (Context.map_theory
(inline (Binding.name "type_name")
(type_name "logical type" (fn (c, Type.LogicalType _) => c)) #>
inline (Binding.name "type_abbrev")
(type_name "type abbreviation" (fn (c, Type.Abbreviation _) => c)) #>
inline (Binding.name "nonterminal")
(type_name "nonterminal" (fn (c, Type.Nonterminal) => c)) #>
inline (Binding.name "type_syntax")
(type_name "type" (fn (c, _) => Lexicon.mark_type c))));
(* constants *)
fun const_name check = Args.context -- Scan.lift (Parse.position Args.name_source)
>> (fn (ctxt, (s, pos)) =>
let
val Const (c, _) = Proof_Context.read_const_proper ctxt false s;
val res = check (Proof_Context.consts_of ctxt, c)
handle TYPE (msg, _, _) => error (msg ^ Position.here pos);
in ML_Syntax.print_string res end);
val _ = Context.>> (Context.map_theory
(inline (Binding.name "const_name")
(const_name (fn (consts, c) => (Consts.the_const consts c; c))) #>
inline (Binding.name "const_abbrev")
(const_name (fn (consts, c) => (Consts.the_abbreviation consts c; c))) #>
inline (Binding.name "const_syntax")
(const_name (fn (_, c) => Lexicon.mark_const c)) #>
inline (Binding.name "syntax_const")
(Args.context -- Scan.lift (Parse.position Args.name) >> (fn (ctxt, (c, pos)) =>
if is_some (Syntax.lookup_const (Proof_Context.syn_of ctxt) c)
then ML_Syntax.print_string c
else error ("Unknown syntax const: " ^ quote c ^ Position.here pos))) #>
inline (Binding.name "const")
(Args.context -- Scan.lift Args.name_source -- Scan.optional
(Scan.lift (Args.$$$ "(") |-- Parse.enum1' "," Args.typ --| Scan.lift (Args.$$$ ")")) []
>> (fn ((ctxt, raw_c), Ts) =>
let
val Const (c, _) = Proof_Context.read_const_proper ctxt true raw_c;
val consts = Proof_Context.consts_of ctxt;
val n = length (Consts.typargs consts (c, Consts.type_scheme consts c));
val _ = length Ts <> n andalso
error ("Constant requires " ^ string_of_int n ^ " type argument(s): " ^
quote c ^ enclose "(" ")" (commas (replicate n "_")));
val const = Const (c, Consts.instance consts (c, Ts));
in ML_Syntax.atomic (ML_Syntax.print_term const) end))));
(* outer syntax *)
fun with_keyword f =
Args.theory -- Scan.lift (Parse.position Parse.string) >> (fn (thy, (name, pos)) =>
(f ((name, Thy_Header.the_keyword thy name), pos)
handle ERROR msg => error (msg ^ Position.here pos)));
val _ = Context.>> (Context.map_theory
(value (Binding.name "keyword")
(with_keyword
(fn ((name, NONE), _) => "Parse.$$$ " ^ ML_Syntax.print_string name
| ((name, SOME _), pos) =>
error ("Expected minor keyword " ^ quote name ^ Position.here pos))) #>
value (Binding.name "command_spec")
(with_keyword
(fn ((name, SOME kind), pos) =>
"Keyword.command_spec " ^ ML_Syntax.atomic
((ML_Syntax.print_pair
(ML_Syntax.print_pair ML_Syntax.print_string
(ML_Syntax.print_pair
(ML_Syntax.print_pair ML_Syntax.print_string
(ML_Syntax.print_list ML_Syntax.print_string))
(ML_Syntax.print_list ML_Syntax.print_string)))
ML_Syntax.print_position) ((name, kind), pos))
| ((name, NONE), pos) =>
error ("Expected command keyword " ^ quote name ^ Position.here pos)))));
end;