(* Title: Pure/Isar/outer_syntax.ML
ID: $Id$
Author: Markus Wenzel, TU Muenchen
The global Isabelle/Isar outer syntax.
*)
signature BASIC_OUTER_SYNTAX =
sig
val main: unit -> unit
val loop: unit -> unit
val sync_main: unit -> unit
val sync_loop: unit -> unit
val help: unit -> unit
end;
signature OUTER_SYNTAX =
sig
include BASIC_OUTER_SYNTAX
structure Keyword:
sig
val control: string
val diag: string
val thy_begin: string
val thy_switch: string
val thy_end: string
val thy_heading: string
val thy_decl: string
val thy_goal: string
val qed: string
val qed_block: string
val prf_goal: string
val prf_block: string
val prf_chain: string
val prf_decl: string
val prf_asm: string
val prf_asm_goal: string
val prf_script: string
val kinds: string list
end
type token
type parser
val command: string -> string -> string ->
(token list -> (Toplevel.transition -> Toplevel.transition) * token list) -> parser
val improper_command: string -> string -> string ->
(token list -> (Toplevel.transition -> Toplevel.transition) * token list) -> parser
val dest_keywords: unit -> string list
val dest_parsers: unit -> (string * string * string * bool) list
val print_outer_syntax: unit -> unit
val print_help: Toplevel.transition -> Toplevel.transition
val add_keywords: string list -> unit
val add_parsers: parser list -> unit
val theory_header: token list -> (string * string list * (string * bool) list) * token list
val deps_thy: string -> Path.T -> string list * Path.T list
val load_thy: string -> bool -> bool -> Path.T -> unit
val isar: bool -> bool -> Toplevel.isar
end;
structure OuterSyntax: OUTER_SYNTAX =
struct
structure P = OuterParse;
(** outer syntax **)
(* command keyword classification *)
structure Keyword =
struct
val control = "control";
val diag = "diag";
val thy_begin = "theory-begin";
val thy_switch = "theory-switch";
val thy_end = "theory-end";
val thy_heading = "theory-heading";
val thy_decl = "theory-decl";
val thy_goal = "theory-goal";
val qed = "qed";
val qed_block = "qed-block";
val prf_goal = "proof-goal";
val prf_block = "proof-block";
val prf_chain = "proof-chain";
val prf_decl = "proof-decl";
val prf_asm = "proof-asm";
val prf_asm_goal = "proof-asm-goal";
val prf_script = "proof-script";
val kinds = [control, diag, thy_begin, thy_switch, thy_end, thy_heading, thy_decl, thy_goal,
qed, qed_block, prf_goal, prf_block, prf_chain, prf_decl, prf_asm, prf_asm_goal, prf_script];
end;
(* parsers *)
type token = OuterLex.token;
type parser_fn = token list -> (Toplevel.transition -> Toplevel.transition) * token list;
datatype parser =
Parser of string * (string * string) * bool * parser_fn;
fun parser int_only name comment kind parse = Parser (name, (comment, kind), int_only, parse);
(* parse command *)
local
fun command_body cmd (name, _) =
(case cmd name of
Some (int_only, parse) => P.!!! (Scan.prompt (name ^ "# ") (parse >> pair int_only))
| None => sys_error ("no parser for outer syntax command " ^ quote name));
fun terminator false = Scan.succeed ()
| terminator true = P.group "terminator" (Scan.option P.sync -- P.$$$ ";" >> K ());
in
fun command term cmd =
P.$$$ ";" >> K None ||
P.sync >> K None ||
(P.position P.command :-- command_body cmd) --| terminator term
>> (fn ((name, pos), (int_only, f)) =>
Some (Toplevel.empty |> Toplevel.name name |> Toplevel.position pos |>
Toplevel.interactive int_only |> f));
end;
(** global syntax state **)
local
val global_lexicons = ref (Scan.empty_lexicon, Scan.empty_lexicon);
val global_parsers = ref (Symtab.empty: ((string * string) * (bool * parser_fn)) Symtab.table);
fun change_lexicons f =
let val lexs = f (! global_lexicons) in
(case (op inter_string) (pairself Scan.dest_lexicon lexs) of
[] => global_lexicons := lexs
| bads => error ("Clash of outer syntax commands and keywords: " ^ commas_quote bads))
end;
fun change_parsers f = global_parsers := f (! global_parsers);
in
(* get current lexers / parsers *)
(*Note: the syntax for files is statically determined at the very
beginning; for interactive processing it may change dynamically.*)
fun get_lexicons () = ! global_lexicons;
fun get_parsers () = ! global_parsers;
fun get_parser () = apsome snd o curry Symtab.lookup (! global_parsers);
(* augment syntax *)
fun add_keywords keywords = change_lexicons (apfst (fn lex =>
(Scan.extend_lexicon lex (map Symbol.explode keywords))));
fun add_parser (tab, Parser (name, comment, int_only, parse)) =
(if is_none (Symtab.lookup (tab, name)) then ()
else warning ("Redefined outer syntax command " ^ quote name);
Symtab.update ((name, (comment, (int_only, parse))), tab));
fun add_parsers parsers =
(change_parsers (fn tab => foldl add_parser (tab, parsers));
change_lexicons (apsnd (fn lex => Scan.extend_lexicon lex
(map (fn Parser (name, _, _, _) => Symbol.explode name) parsers))));
end;
(* print syntax *)
fun dest_keywords () = Scan.dest_lexicon (#1 (get_lexicons ()));
fun dest_parsers () =
map (fn (name, ((cmt, kind), (int_only, _))) => (name, cmt, kind, int_only))
(Symtab.dest (get_parsers ()));
fun print_outer_syntax () =
let
fun pretty_cmd (name, comment, _, _) =
Pretty.block [Pretty.str (name ^ ":"), Pretty.brk 2, Pretty.str comment];
val (int_cmds, cmds) = partition #4 (dest_parsers ());
in
Pretty.writeln (Pretty.strs ("syntax keywords:" :: map quote (dest_keywords ())));
Pretty.writeln (Pretty.big_list "proper commands:" (map pretty_cmd cmds));
Pretty.writeln (Pretty.big_list "improper commands (interactive-only):"
(map pretty_cmd int_cmds))
end;
val print_help =
Toplevel.keep (fn state =>
let val opt_thy = try Toplevel.theory_of state in
print_outer_syntax ();
Method.help_methods opt_thy;
Attrib.help_attributes opt_thy
end);
(** read theory **)
(* theory keyword *)
val theoryN = "theory";
val theory_keyword = OuterParse.$$$ theoryN;
(* sources *)
local
val no_terminator =
Scan.unless (P.$$$ ";") (Scan.one (OuterLex.not_sync andf OuterLex.not_eof));
val recover = Scan.prompt "recover# " (Scan.repeat no_terminator);
in
fun source term do_recover cmd src =
src
|> Source.source OuterLex.stopper
(Scan.bulk (fn xs => OuterParse.!!! (command term (cmd ())) xs))
(if do_recover then Some recover else None)
|> Source.mapfilter I;
end;
fun token_source (src, pos) =
src
|> Symbol.source false
|> OuterLex.source false (K (get_lexicons ())) pos;
fun filter_proper src =
src
|> Source.filter OuterLex.is_proper;
(* detect header *)
fun scan_header get_lex scan (src, pos) =
src
|> Symbol.source false
|> OuterLex.source false (fn () => (get_lex (), Scan.empty_lexicon)) pos
|> filter_proper
|> Source.source OuterLex.stopper (Scan.single scan) None
|> (fst o the o Source.get_single);
val check_header_lexicon = Scan.make_lexicon [Symbol.explode theoryN];
fun is_old_theory src =
is_none (scan_header (K check_header_lexicon) (Scan.option theory_keyword) src);
(* deps_thy --- inspect theory header *)
val header_lexicon =
Scan.make_lexicon (map Symbol.explode ["(", ")", "+", ":", "=", "files", theoryN]);
local
val file_name =
(P.$$$ "(" |-- P.!!! (P.name --| P.$$$ ")")) >> rpair false || P.name >> rpair true;
val theory_head =
(P.name -- (P.$$$ "=" |-- P.enum1 "+" P.name) --
Scan.optional (P.$$$ "files" |-- P.!!! (Scan.repeat1 file_name)) [])
>> (fn ((A, Bs), files) => (A, Bs, files));
in
val theory_header = theory_head --| (Scan.ahead P.eof || P.$$$ ":");
val only_header = theory_keyword |-- theory_head --| Scan.ahead P.eof;
val new_header = theory_keyword |-- P.!!! theory_header;
val old_header =
P.name -- (P.$$$ "=" |-- P.name -- Scan.repeat (P.$$$ "+" |-- P.name))
>> (fn (A, (B, Bs)) => (A, B :: Bs, []: (string * bool) list));
end;
fun deps_thy name path =
let
val src = Source.of_string (File.read path);
val pos = Path.position path;
val (name', parents, files) =
(*Note: old style headers dynamically depend on the current lexicon :-( *)
if is_old_theory (src, pos) then scan_header ThySyn.get_lexicon (Scan.error old_header) (src, pos)
else scan_header (K header_lexicon) (Scan.error new_header) (src, pos);
val ml_path = ThyLoad.ml_path name;
val ml_file = if is_none (ThyLoad.check_file ml_path) then [] else [ml_path];
in
if name <> name' then
error ("Filename " ^ quote (Path.pack path) ^ " does not match theory name " ^ quote name)
else (parents, map (Path.unpack o #1) files @ ml_file)
end;
(* load_thy --- read text (including header) *)
fun try_ml_file name ml time =
let
val path = ThyLoad.ml_path name;
val tr = Toplevel.imperative (fn () => ThyInfo.may_load_file ml time path);
val tr_name = if time then "time_use" else "use";
in
if is_none (ThyLoad.check_file path) then ()
else Toplevel.excursion_error [Toplevel.empty |> Toplevel.name tr_name |> tr]
end;
fun parse_thy src_pos =
let
val lex_src = filter_proper (token_source src_pos);
val only_head =
lex_src
|> Source.source OuterLex.stopper (Scan.single (Scan.option only_header)) None
|> (fst o the o Source.get_single);
in
(case only_head of
None =>
lex_src
|> source false false (K (get_parser ()))
|> Source.exhaust
| Some spec =>
[Toplevel.empty |> Toplevel.name theoryN |> IsarThy.theory spec,
Toplevel.empty |> Toplevel.name "end" |> Toplevel.exit])
end;
fun run_thy name path =
let
val text = explode (File.read path);
val src = Source.of_list text;
val pos = Path.position path;
fun present_toks () =
Source.exhaust (token_source (Source.of_list (Library.untabify text), pos));
fun present_text () =
Source.exhaust (Symbol.source false (Source.of_list (Library.untabify text)));
in
Present.init_theory name;
if is_old_theory (src, pos) then ThySyn.load_thy name text
else (Toplevel.excursion_error (parse_thy (src, pos)); Present.token_source name present_toks);
Present.verbatim_source name present_text
end;
fun load_thy name ml time path =
(if time then
timeit (fn () =>
(writeln ("\n**** Starting theory " ^ quote name ^ " ****");
setmp Goals.proof_timing true (run_thy name) path;
writeln ("**** Finished theory " ^ quote name ^ " ****\n")))
else run_thy name path;
Context.context (ThyInfo.get_theory name);
try_ml_file name ml time);
(* interactive source of state transformers *)
fun isar term no_pos =
Source.tty
|> Symbol.source true
|> OuterLex.source true get_lexicons
(if no_pos then Position.none else Position.line_name 1 "stdin")
|> filter_proper
|> source term true get_parser;
(** the read-eval-print loop **)
(* main loop *)
fun gen_loop term no_pos =
(Context.reset_context ();
Toplevel.loop (isar term no_pos));
fun gen_main term no_pos =
(Toplevel.set_state Toplevel.toplevel;
ml_prompts "ML> " "ML# ";
writeln (Session.welcome ());
gen_loop term no_pos);
fun main () = gen_main false false;
fun loop () = gen_loop false false;
fun sync_main () = gen_main true true;
fun sync_loop () = gen_loop true true;
(* help *)
fun help () =
writeln ("This is Isabelle's underlying ML system (" ^ ml_system ^ ");\n\
\invoke 'loop();' to enter the Isar loop.");
(*final declarations of this structure!*)
val command = parser false;
val improper_command = parser true;
end;
(*setup theory syntax dependent operations*)
ThyLoad.deps_thy_fn := OuterSyntax.deps_thy;
ThyLoad.load_thy_fn := OuterSyntax.load_thy;
structure ThyLoad: THY_LOAD = ThyLoad;
structure BasicOuterSyntax: BASIC_OUTER_SYNTAX = OuterSyntax;
open BasicOuterSyntax;