(* Title: Pure/Isar/args.ML
Author: Markus Wenzel, TU Muenchen
Parsing with implicit value assignment. Concrete argument syntax of
attributes, methods etc.
*)
signature ARGS =
sig
type token = OuterLex.token
type src
val src: (string * token list) * Position.T -> src
val dest_src: src -> (string * token list) * Position.T
val pretty_src: Proof.context -> src -> Pretty.T
val map_name: (string -> string) -> src -> src
val morph_values: morphism -> src -> src
val maxidx_values: src -> int -> int
val assignable: src -> src
val closure: src -> src
val context: Proof.context context_parser
val theory: theory context_parser
val $$$ : string -> string parser
val add: string parser
val del: string parser
val colon: string parser
val query: string parser
val bang: string parser
val query_colon: string parser
val bang_colon: string parser
val parens: ('a parser) -> 'a parser
val bracks: ('a parser) -> 'a parser
val mode: string -> bool context_parser
val maybe: 'a parser -> 'a option parser
val name_source: string parser
val name_source_position: (Symbol_Pos.text * Position.T) parser
val name: string parser
val binding: binding parser
val alt_name: string parser
val symbol: string parser
val liberal_name: string parser
val var: indexname parser
val internal_text: string parser
val internal_typ: typ parser
val internal_term: term parser
val internal_fact: thm list parser
val internal_attribute: (morphism -> attribute) parser
val named_text: (string -> string) -> string parser
val named_typ: (string -> typ) -> typ parser
val named_term: (string -> term) -> term parser
val named_fact: (string -> thm list) -> thm list parser
val named_attribute: (string -> morphism -> attribute) -> (morphism -> attribute) parser
val typ_abbrev: typ context_parser
val typ: typ context_parser
val term: term context_parser
val term_abbrev: term context_parser
val prop: term context_parser
val type_name: bool -> string context_parser
val const: bool -> string context_parser
val const_proper: bool -> string context_parser
val goal_spec: ((int -> tactic) -> tactic) context_parser
val parse: token list parser
val parse1: (string -> bool) -> token list parser
val attribs: (string -> string) -> src list parser
val opt_attribs: (string -> string) -> src list parser
val thm_name: (string -> string) -> string -> (binding * src list) parser
val opt_thm_name: (string -> string) -> string -> (binding * src list) parser
val syntax: string -> 'a context_parser -> src -> Context.generic -> 'a * Context.generic
val context_syntax: string -> 'a context_parser -> src -> Proof.context -> 'a * Proof.context
end;
structure Args: ARGS =
struct
structure T = OuterLex;
structure P = OuterParse;
type token = T.token;
(** datatype src **)
datatype src = Src of (string * token list) * Position.T;
val src = Src;
fun dest_src (Src src) = src;
fun pretty_src ctxt src =
let
val prt_thm = Pretty.backquote o Display.pretty_thm ctxt;
fun prt arg =
(case T.get_value arg of
SOME (T.Text s) => Pretty.str (quote s)
| SOME (T.Typ T) => Syntax.pretty_typ ctxt T
| SOME (T.Term t) => Syntax.pretty_term ctxt t
| SOME (T.Fact ths) => Pretty.enclose "(" ")" (Pretty.breaks (map prt_thm ths))
| _ => Pretty.str (T.unparse arg));
val (s, args) = #1 (dest_src src);
in Pretty.block (Pretty.breaks (Pretty.str s :: map prt args)) end;
fun map_name f (Src ((s, args), pos)) = Src ((f s, args), pos);
fun map_args f (Src ((s, args), pos)) = Src ((s, map f args), pos);
(* values *)
fun morph_values phi = map_args (T.map_value
(fn T.Text s => T.Text s
| T.Typ T => T.Typ (Morphism.typ phi T)
| T.Term t => T.Term (Morphism.term phi t)
| T.Fact ths => T.Fact (Morphism.fact phi ths)
| T.Attribute att => T.Attribute (Morphism.transform phi att)));
fun maxidx_values (Src ((_, args), _)) = args |> fold (fn arg =>
(case T.get_value arg of
SOME (T.Typ T) => Term.maxidx_typ T
| SOME (T.Term t) => Term.maxidx_term t
| SOME (T.Fact ths) => fold Thm.maxidx_thm ths
| _ => I));
val assignable = map_args T.assignable;
val closure = map_args T.closure;
(** argument scanners **)
(* context *)
fun context x = (Scan.state >> Context.proof_of) x;
fun theory x = (Scan.state >> Context.theory_of) x;
(* basic *)
fun token atom = Scan.ahead P.not_eof --| atom;
val ident = token
(P.short_ident || P.long_ident || P.sym_ident || P.term_var ||
P.type_ident || P.type_var || P.number);
val string = token (P.string || P.verbatim);
val alt_string = token P.alt_string;
val symbolic = token P.keyword_ident_or_symbolic;
fun $$$ x = (ident >> T.content_of || P.keyword)
:|-- (fn y => if x = y then Scan.succeed x else Scan.fail);
val named = ident || string;
val add = $$$ "add";
val del = $$$ "del";
val colon = $$$ ":";
val query = $$$ "?";
val bang = $$$ "!";
val query_colon = $$$ "?" ^^ $$$ ":";
val bang_colon = $$$ "!" ^^ $$$ ":";
fun parens scan = $$$ "(" |-- scan --| $$$ ")";
fun bracks scan = $$$ "[" |-- scan --| $$$ "]";
fun mode s = Scan.lift (Scan.optional (parens ($$$ s) >> K true) false);
fun maybe scan = $$$ "_" >> K NONE || scan >> SOME;
val name_source = named >> T.source_of;
val name_source_position = named >> T.source_position_of;
val name = named >> T.content_of;
val binding = P.position name >> Binding.make;
val alt_name = alt_string >> T.content_of;
val symbol = symbolic >> T.content_of;
val liberal_name = symbol || name;
val var = (ident >> T.content_of) :|-- (fn x =>
(case Lexicon.read_variable x of SOME v => Scan.succeed v | NONE => Scan.fail));
(* values *)
fun value dest = Scan.some (fn arg =>
(case T.get_value arg of SOME v => (SOME (dest v) handle Match => NONE) | NONE => NONE));
fun evaluate mk eval arg =
let val x = eval arg in (T.assign (SOME (mk x)) arg; x) end;
val internal_text = value (fn T.Text s => s);
val internal_typ = value (fn T.Typ T => T);
val internal_term = value (fn T.Term t => t);
val internal_fact = value (fn T.Fact ths => ths);
val internal_attribute = value (fn T.Attribute att => att);
fun named_text intern = internal_text || named >> evaluate T.Text (intern o T.content_of);
fun named_typ readT = internal_typ || named >> evaluate T.Typ (readT o T.source_of);
fun named_term read = internal_term || named >> evaluate T.Term (read o T.source_of);
fun named_fact get = internal_fact || named >> evaluate T.Fact (get o T.content_of) ||
alt_string >> evaluate T.Fact (get o T.source_of);
fun named_attribute att = internal_attribute || named >> evaluate T.Attribute (att o T.content_of);
(* terms and types *)
val typ_abbrev = Scan.peek (named_typ o ProofContext.read_typ_abbrev o Context.proof_of);
val typ = Scan.peek (named_typ o Syntax.read_typ o Context.proof_of);
val term = Scan.peek (named_term o Syntax.read_term o Context.proof_of);
val term_abbrev = Scan.peek (named_term o ProofContext.read_term_abbrev o Context.proof_of);
val prop = Scan.peek (named_term o Syntax.read_prop o Context.proof_of);
(* type and constant names *)
fun type_name strict =
Scan.peek (fn ctxt => named_typ (ProofContext.read_type_name (Context.proof_of ctxt) strict))
>> (fn Type (c, _) => c | TFree (a, _) => a | _ => "");
fun const strict =
Scan.peek (fn ctxt => named_term (ProofContext.read_const (Context.proof_of ctxt) strict))
>> (fn Const (c, _) => c | Free (x, _) => x | _ => "");
fun const_proper strict =
Scan.peek (fn ctxt => named_term (ProofContext.read_const_proper (Context.proof_of ctxt) strict))
>> (fn Const (c, _) => c | _ => "");
(* improper method arguments *)
val from_to =
P.nat -- ($$$ "-" |-- P.nat) >> (fn (i, j) => fn tac => Seq.INTERVAL tac i j) ||
P.nat --| $$$ "-" >> (fn i => fn tac => fn st => Seq.INTERVAL tac i (Thm.nprems_of st) st) ||
P.nat >> (fn i => fn tac => tac i) ||
$$$ "!" >> K ALLGOALS;
val goal = $$$ "[" |-- P.!!! (from_to --| $$$ "]");
fun goal_spec x = Scan.lift (Scan.optional goal (fn tac => tac 1)) x;
(* arguments within outer syntax *)
fun parse_args is_symid =
let
val keyword_symid = token (P.keyword_with is_symid);
fun atom blk = P.group "argument"
(ident || keyword_symid || string || alt_string ||
(if blk then token (P.$$$ ",") else Scan.fail));
fun args blk x = Scan.optional (args1 blk) [] x
and args1 blk x =
((Scan.repeat1
(Scan.repeat1 (atom blk) ||
argsp "(" ")" ||
argsp "[" "]")) >> flat) x
and argsp l r x = (token (P.$$$ l) ::: P.!!! (args true @@@ (token (P.$$$ r) >> single))) x;
in (args, args1) end;
val parse = #1 (parse_args T.ident_or_symbolic) false;
fun parse1 is_symid = #2 (parse_args is_symid) false;
(* attributes *)
fun attribs intern =
let
val attrib_name = internal_text || (symbolic || named)
>> evaluate T.Text (intern o T.content_of);
val attrib = P.position (attrib_name -- P.!!! parse) >> src;
in $$$ "[" |-- P.!!! (P.list attrib --| $$$ "]") end;
fun opt_attribs intern = Scan.optional (attribs intern) [];
(* theorem specifications *)
fun thm_name intern s = binding -- opt_attribs intern --| $$$ s;
fun opt_thm_name intern s =
Scan.optional
((binding -- opt_attribs intern || attribs intern >> pair Binding.empty) --| $$$ s)
(Binding.empty, []);
(** syntax wrapper **)
fun syntax kind scan (Src ((s, args), pos)) st =
(case Scan.error (Scan.finite' T.stopper (Scan.option scan)) (st, args) of
(SOME x, (st', [])) => (x, st')
| (_, (_, args')) =>
error (kind ^ " " ^ quote s ^ Position.str_of pos ^ ": bad arguments\n " ^
space_implode " " (map T.unparse args')));
fun context_syntax kind scan src = apsnd Context.the_proof o syntax kind scan src o Context.Proof;
end;