(* Title: Pure/Thy/thy_output.ML
Author: Markus Wenzel, TU Muenchen
Theory document output with antiquotations.
*)
signature THY_OUTPUT =
sig
val display: bool Config.T
val quotes: bool Config.T
val indent: int Config.T
val source: bool Config.T
val break: bool Config.T
val modes: string Config.T
val add_wrapper: ((unit -> string) -> unit -> string) -> Proof.context -> Proof.context
val add_option: binding -> (string -> Proof.context -> Proof.context) -> theory -> theory
val check_command: Proof.context -> xstring * Position.T -> string
val check_option: Proof.context -> xstring * Position.T -> string
val print_antiquotations: Proof.context -> unit
val antiquotation: binding -> 'a context_parser ->
({source: Token.src, state: Toplevel.state, context: Proof.context} -> 'a -> string) ->
theory -> theory
val boolean: string -> bool
val integer: string -> int
val eval_antiq: Toplevel.state -> Antiquote.antiq -> string
val check_text: Input.source -> Toplevel.state -> unit
val present_thy: theory -> (Toplevel.transition * Toplevel.state) list -> Token.T list -> Buffer.T
val pretty_text: Proof.context -> string -> Pretty.T
val pretty_term: Proof.context -> term -> Pretty.T
val pretty_thm: Proof.context -> thm -> Pretty.T
val str_of_source: Token.src -> string
val maybe_pretty_source: (Proof.context -> 'a -> Pretty.T) -> Proof.context ->
Token.src -> 'a list -> Pretty.T list
val output: Proof.context -> Pretty.T list -> string
val verbatim_text: Proof.context -> string -> string
val old_header_command: Input.source -> Toplevel.transition -> Toplevel.transition
val document_command: (xstring * Position.T) option * Input.source ->
Toplevel.transition -> Toplevel.transition
end;
structure Thy_Output: THY_OUTPUT =
struct
(** options **)
val display = Attrib.setup_option_bool ("thy_output_display", @{here});
val break = Attrib.setup_option_bool ("thy_output_break", @{here});
val quotes = Attrib.setup_option_bool ("thy_output_quotes", @{here});
val indent = Attrib.setup_option_int ("thy_output_indent", @{here});
val source = Attrib.setup_option_bool ("thy_output_source", @{here});
val modes = Attrib.setup_option_string ("thy_output_modes", @{here});
structure Wrappers = Proof_Data
(
type T = ((unit -> string) -> unit -> string) list;
fun init _ = [];
);
fun add_wrapper wrapper = Wrappers.map (cons wrapper);
val wrap = Wrappers.get #> fold (fn wrapper => fn f => wrapper f);
(** maintain global antiquotations **)
structure Antiquotations = Theory_Data
(
type T =
(Token.src -> Toplevel.state -> Proof.context -> string) Name_Space.table *
(string -> Proof.context -> Proof.context) Name_Space.table;
val empty : T =
(Name_Space.empty_table Markup.document_antiquotationN,
Name_Space.empty_table Markup.document_antiquotation_optionN);
val extend = I;
fun merge ((commands1, options1), (commands2, options2)) : T =
(Name_Space.merge_tables (commands1, commands2),
Name_Space.merge_tables (options1, options2));
);
val get_antiquotations = Antiquotations.get o Proof_Context.theory_of;
fun add_command name cmd thy = thy
|> Antiquotations.map (apfst (Name_Space.define (Context.Theory thy) true (name, cmd) #> snd));
fun add_option name opt thy = thy
|> Antiquotations.map (apsnd (Name_Space.define (Context.Theory thy) true (name, opt) #> snd));
fun check_command ctxt = #1 o Name_Space.check (Context.Proof ctxt) (#1 (get_antiquotations ctxt));
fun check_option ctxt = #1 o Name_Space.check (Context.Proof ctxt) (#2 (get_antiquotations ctxt));
fun command src state ctxt =
let val (src', f) = Token.check_src ctxt (#1 (get_antiquotations ctxt)) src
in f src' state ctxt end;
fun option ((xname, pos), s) ctxt =
let
val (_, opt) =
Name_Space.check (Context.Proof ctxt) (#2 (get_antiquotations ctxt)) (xname, pos);
in opt s ctxt end;
fun print_antiquotations ctxt =
let
val (commands, options) = get_antiquotations ctxt;
val command_names = map #1 (Name_Space.markup_table ctxt commands);
val option_names = map #1 (Name_Space.markup_table ctxt options);
in
[Pretty.big_list "document antiquotations:" (map Pretty.mark_str command_names),
Pretty.big_list "document antiquotation options:" (map Pretty.mark_str option_names)]
|> Pretty.writeln_chunks
end;
fun antiquotation name scan body =
add_command name
(fn src => fn state => fn ctxt =>
let val (x, ctxt') = Token.syntax scan src ctxt
in body {source = src, state = state, context = ctxt'} x end);
(** syntax of antiquotations **)
(* option values *)
fun boolean "" = true
| boolean "true" = true
| boolean "false" = false
| boolean s = error ("Bad boolean value: " ^ quote s);
fun integer s =
let
fun int ss =
(case Library.read_int ss of (i, []) => i
| _ => error ("Bad integer value: " ^ quote s));
in (case Symbol.explode s of "-" :: ss => ~ (int ss) | ss => int ss) end;
(* outer syntax *)
local
val property =
Parse.position Parse.xname -- Scan.optional (Parse.$$$ "=" |-- Parse.!!! Parse.xname) "";
val properties =
Scan.optional (Parse.$$$ "[" |-- Parse.!!! (Parse.enum "," property --| Parse.$$$ "]")) [];
in
val antiq =
Parse.!!!
(Parse.position Parse.liberal_name -- properties -- Parse.args --| Scan.ahead Parse.eof)
>> (fn ((name, props), args) => (props, Token.src name args));
end;
(* eval_antiq *)
fun eval_antiq state ((ss, {range = (pos, _), ...}): Antiquote.antiq) =
let
val keywords =
(case try Toplevel.presentation_context_of state of
SOME ctxt => Thy_Header.get_keywords' ctxt
| NONE =>
error ("Unknown context -- cannot expand document antiquotations" ^
Position.here pos));
val (opts, src) = Token.read_antiq keywords antiq (ss, pos);
fun cmd ctxt = wrap ctxt (fn () => command src state ctxt) ();
val preview_ctxt = fold option opts (Toplevel.presentation_context_of state);
val print_ctxt = Context_Position.set_visible false preview_ctxt;
val _ = cmd preview_ctxt;
val print_modes = space_explode "," (Config.get print_ctxt modes) @ Latex.modes;
in Print_Mode.with_modes print_modes (fn () => cmd print_ctxt) () end;
(* check_text *)
fun eval_antiquote state source =
let
fun words (Antiquote.Text ss) = [(#1 (Symbol_Pos.range ss), Markup.words)]
| words (Antiquote.Antiq _) = [];
fun expand (Antiquote.Text ss) = Symbol_Pos.content ss
| expand (Antiquote.Antiq antiq) = eval_antiq state antiq;
val ants = Antiquote.read source;
val _ = Position.reports (maps words ants);
in implode (map expand ants) end;
fun check_text source state =
(Position.report (Input.pos_of source) (Markup.language_document (Input.is_delimited source));
if Toplevel.is_skipped_proof state then ()
else ignore (eval_antiquote state source));
(** present theory source **)
(*NB: arranging white space around command spans is a black art.*)
(* presentation tokens *)
datatype token =
No_Token
| Basic_Token of Token.T
| Markup_Token of string * Input.source
| Markup_Env_Token of string * Input.source
| Verbatim_Token of Input.source;
fun output_token state =
let val eval = eval_antiquote state in
fn No_Token => ""
| Basic_Token tok => Latex.output_basic tok
| Markup_Token (cmd, source) => Latex.output_markup cmd (eval source)
| Markup_Env_Token (cmd, source) => Latex.output_markup_env cmd (eval source)
| Verbatim_Token source => Latex.output_verbatim (eval source)
end;
fun basic_token pred (Basic_Token tok) = pred tok
| basic_token _ _ = false;
val improper_token = basic_token Token.is_improper;
val comment_token = basic_token Token.is_comment;
val blank_token = basic_token Token.is_blank;
val newline_token = basic_token Token.is_newline;
(* command spans *)
type command = string * Position.T * string list; (*name, position, tags*)
type source = (token * (string * int)) list; (*token, markup flag, meta-comment depth*)
datatype span = Span of command * (source * source * source * source) * bool;
fun make_span cmd src =
let
fun take_newline (tok :: toks) =
if newline_token (fst tok) then ([tok], toks, true)
else ([], tok :: toks, false)
| take_newline [] = ([], [], false);
val (((src_prefix, src_main), src_suffix1), (src_suffix2, src_appendix, newline)) =
src
|> take_prefix (improper_token o fst)
||>> take_suffix (improper_token o fst)
||>> take_prefix (comment_token o fst)
||> take_newline;
in Span (cmd, (src_prefix, src_main, src_suffix1 @ src_suffix2, src_appendix), newline) end;
(* present spans *)
local
fun err_bad_nesting pos =
error ("Bad nesting of commands in presentation" ^ pos);
fun edge which f (x: string option, y) =
if x = y then I
else (case which (x, y) of NONE => I | SOME txt => Buffer.add (f txt));
val begin_tag = edge #2 Latex.begin_tag;
val end_tag = edge #1 Latex.end_tag;
fun open_delim delim e = edge #2 Latex.begin_delim e #> delim #> edge #2 Latex.end_delim e;
fun close_delim delim e = edge #1 Latex.begin_delim e #> delim #> edge #1 Latex.end_delim e;
in
fun present_span keywords span state state' (tag_stack, active_tag, newline, buffer, present_cont) =
let
val present = fold (fn (tok, (flag, 0)) =>
Buffer.add (output_token state' tok)
#> Buffer.add flag
| _ => I);
val Span ((cmd_name, cmd_pos, cmd_tags), srcs, span_newline) = span;
val (tag, tags) = tag_stack;
val tag' = try hd (fold (update (op =)) cmd_tags (the_list tag));
val nesting = Toplevel.level state' - Toplevel.level state;
val active_tag' =
if is_some tag' then tag'
else if cmd_name = "end" andalso not (Toplevel.is_toplevel state') then NONE
else
(case Keyword.command_tags keywords cmd_name of
default_tag :: _ => SOME default_tag
| [] =>
if Keyword.is_vacuous keywords cmd_name andalso Toplevel.is_proof state
then active_tag
else NONE);
val edge = (active_tag, active_tag');
val newline' =
if is_none active_tag' then span_newline else newline;
val tag_stack' =
if nesting = 0 andalso not (Toplevel.is_proof state) then tag_stack
else if nesting >= 0 then (tag', replicate nesting tag @ tags)
else
(case drop (~ nesting - 1) tags of
tg :: tgs => (tg, tgs)
| [] => err_bad_nesting (Position.here cmd_pos));
val buffer' =
buffer
|> end_tag edge
|> close_delim (fst present_cont) edge
|> snd present_cont
|> open_delim (present (#1 srcs)) edge
|> begin_tag edge
|> present (#2 srcs);
val present_cont' =
if newline then (present (#3 srcs), present (#4 srcs))
else (I, present (#3 srcs) #> present (#4 srcs));
in (tag_stack', active_tag', newline', buffer', present_cont') end;
fun present_trailer ((_, tags), active_tag, _, buffer, present_cont) =
if not (null tags) then err_bad_nesting " at end of theory"
else
buffer
|> end_tag (active_tag, NONE)
|> close_delim (fst present_cont) (active_tag, NONE)
|> snd present_cont;
end;
(* present_thy *)
local
val space_proper =
Scan.one Token.is_blank -- Scan.many Token.is_comment -- Scan.one Token.is_proper;
val is_improper = not o (Token.is_proper orf Token.is_begin_ignore orf Token.is_end_ignore);
val improper = Scan.many is_improper;
val improper_end = Scan.repeat (Scan.unless space_proper (Scan.one is_improper));
val blank_end = Scan.repeat (Scan.unless space_proper (Scan.one Token.is_blank));
val opt_newline = Scan.option (Scan.one Token.is_newline);
val ignore =
Scan.depend (fn d => opt_newline |-- Scan.one Token.is_begin_ignore
>> pair (d + 1)) ||
Scan.depend (fn d => Scan.one Token.is_end_ignore --|
(if d = 0 then Scan.fail_with (K (fn () => "Bad nesting of meta-comments")) else opt_newline)
>> pair (d - 1));
val tag = (improper -- Parse.$$$ "%" -- improper) |-- Parse.!!! (Parse.tag_name --| blank_end);
val locale =
Scan.option ((Parse.$$$ "(" -- improper -- Parse.$$$ "in") |--
Parse.!!! (improper |-- Parse.xname --| (improper -- Parse.$$$ ")")));
in
fun present_thy thy command_results toks =
let
val keywords = Thy_Header.get_keywords thy;
(* tokens *)
val ignored = Scan.state --| ignore
>> (fn d => (NONE, (No_Token, ("", d))));
fun markup pred mk flag = Scan.peek (fn d =>
improper |--
Parse.position (Scan.one (fn tok =>
Token.is_command tok andalso pred keywords (Token.content_of tok))) --
Scan.repeat tag --
Parse.!!!! ((improper -- locale -- improper) |-- Parse.document_source --| improper_end)
>> (fn (((tok, pos'), tags), source) =>
let val name = Token.content_of tok
in (SOME (name, pos', tags), (mk (name, source), (flag, d))) end));
val command = Scan.peek (fn d =>
Parse.position (Scan.one (Token.is_command)) --
Scan.repeat tag
>> (fn ((tok, pos), tags) =>
let val name = Token.content_of tok
in (SOME (name, pos, tags), (Basic_Token tok, (Latex.markup_false, d))) end));
val cmt = Scan.peek (fn d =>
Parse.$$$ "--" |-- Parse.!!!! (improper |-- Parse.document_source) >>
(fn source => (NONE, (Markup_Token ("cmt", source), ("", d)))));
val other = Scan.peek (fn d =>
Parse.not_eof >> (fn tok => (NONE, (Basic_Token tok, ("", d)))));
val token =
ignored ||
markup Keyword.is_document_heading Markup_Token Latex.markup_true ||
markup Keyword.is_document_body Markup_Env_Token Latex.markup_true ||
markup Keyword.is_document_raw (Verbatim_Token o #2) "" ||
command || cmt || other;
(* spans *)
val is_eof = fn (_, (Basic_Token x, _)) => Token.is_eof x | _ => false;
val stopper = Scan.stopper (K (NONE, (Basic_Token Token.eof, ("", 0)))) is_eof;
val cmd = Scan.one (is_some o fst);
val non_cmd = Scan.one (is_none o fst andf not o is_eof) >> #2;
val comments = Scan.many (comment_token o fst o snd);
val blank = Scan.one (blank_token o fst o snd);
val newline = Scan.one (newline_token o fst o snd);
val before_cmd =
Scan.option (newline -- comments) --
Scan.option (newline -- comments) --
Scan.option (blank -- comments) -- cmd;
val span =
Scan.repeat non_cmd -- cmd --
Scan.repeat (Scan.unless before_cmd non_cmd) --
Scan.option (newline >> (single o snd))
>> (fn (((toks1, (cmd, tok2)), toks3), tok4) =>
make_span (the cmd) (toks1 @ (tok2 :: (toks3 @ the_default [] tok4))));
val spans = toks
|> take_suffix Token.is_space |> #1
|> Source.of_list
|> Source.source' 0 Token.stopper (Scan.error (Scan.bulk token))
|> Source.source stopper (Scan.error (Scan.bulk span))
|> Source.exhaust;
(* present commands *)
fun present_command tr span st st' =
Toplevel.setmp_thread_position tr (present_span keywords span st st');
fun present _ [] = I
| present st (((tr, st'), span) :: rest) = present_command tr span st st' #> present st' rest;
in
if length command_results = length spans then
((NONE, []), NONE, true, Buffer.empty, (I, I))
|> present Toplevel.toplevel (command_results ~~ spans)
|> present_trailer
else error "Messed-up outer syntax for presentation"
end;
end;
(** setup default output **)
(* options *)
val _ = Theory.setup
(add_option @{binding show_types} (Config.put show_types o boolean) #>
add_option @{binding show_sorts} (Config.put show_sorts o boolean) #>
add_option @{binding show_structs} (Config.put show_structs o boolean) #>
add_option @{binding show_question_marks} (Config.put show_question_marks o boolean) #>
add_option @{binding show_abbrevs} (Config.put show_abbrevs o boolean) #>
add_option @{binding names_long} (Config.put Name_Space.names_long o boolean) #>
add_option @{binding names_short} (Config.put Name_Space.names_short o boolean) #>
add_option @{binding names_unique} (Config.put Name_Space.names_unique o boolean) #>
add_option @{binding eta_contract} (Config.put Syntax_Trans.eta_contract o boolean) #>
add_option @{binding display} (Config.put display o boolean) #>
add_option @{binding break} (Config.put break o boolean) #>
add_option @{binding quotes} (Config.put quotes o boolean) #>
add_option @{binding mode} (add_wrapper o Print_Mode.with_modes o single) #>
add_option @{binding margin} (add_wrapper o setmp_CRITICAL Pretty.margin_default o integer) #>
add_option @{binding indent} (Config.put indent o integer) #>
add_option @{binding source} (Config.put source o boolean) #>
add_option @{binding goals_limit} (Config.put Goal_Display.goals_limit o integer));
(* basic pretty printing *)
fun tweak_line ctxt s =
if Config.get ctxt display then s else Symbol.strip_blanks s;
fun pretty_text ctxt =
Pretty.chunks o map Pretty.str o map (tweak_line ctxt) o split_lines;
fun pretty_text_report ctxt source =
(Context_Position.report ctxt (Input.pos_of source)
(Markup.language_text (Input.is_delimited source));
pretty_text ctxt (Input.source_content source));
fun pretty_term ctxt t = Syntax.pretty_term (Variable.auto_fixes t ctxt) t;
fun pretty_thm ctxt = pretty_term ctxt o Thm.full_prop_of;
fun pretty_term_style ctxt (style, t) =
pretty_term ctxt (style t);
fun pretty_thm_style ctxt (style, th) =
pretty_term ctxt (style (Thm.full_prop_of th));
fun pretty_term_typ ctxt (style, t) =
let val t' = style t
in pretty_term ctxt (Type.constraint (Term.fastype_of t') t') end;
fun pretty_term_typeof ctxt (style, t) =
Syntax.pretty_typ ctxt (Term.fastype_of (style t));
fun pretty_const ctxt c =
let
val t = Const (c, Consts.type_scheme (Proof_Context.consts_of ctxt) c)
handle TYPE (msg, _, _) => error msg;
val ([t'], _) = Variable.import_terms true [t] ctxt;
in pretty_term ctxt t' end;
fun pretty_abbrev ctxt s =
let
val t = Syntax.read_term (Proof_Context.set_mode Proof_Context.mode_abbrev ctxt) s;
fun err () = error ("Abbreviated constant expected: " ^ Syntax.string_of_term ctxt t);
val (head, args) = Term.strip_comb t;
val (c, T) = Term.dest_Const head handle TERM _ => err ();
val (U, u) = Consts.the_abbreviation (Proof_Context.consts_of ctxt) c
handle TYPE _ => err ();
val t' = Term.betapplys (Envir.expand_atom T (U, u), args);
val eq = Logic.mk_equals (t, t');
val ctxt' = Variable.auto_fixes eq ctxt;
in Proof_Context.pretty_term_abbrev ctxt' eq end;
fun pretty_class ctxt =
Pretty.str o Proof_Context.extern_class ctxt o Proof_Context.read_class ctxt;
fun pretty_type ctxt s =
let val Type (name, _) = Proof_Context.read_type_name {proper = true, strict = false} ctxt s
in Pretty.str (Proof_Context.extern_type ctxt name) end;
fun pretty_prf full ctxt = Proof_Syntax.pretty_proof_of ctxt full;
fun pretty_theory ctxt (name, pos) =
(case find_first (fn thy => Context.theory_name thy = name)
(Theory.nodes_of (Proof_Context.theory_of ctxt)) of
NONE => error ("No ancestor theory " ^ quote name ^ Position.here pos)
| SOME thy => (Context_Position.report ctxt pos (Theory.get_markup thy); Pretty.str name));
(* default output *)
val str_of_source = space_implode " " o Token.unparse_src;
fun maybe_pretty_source pretty ctxt src xs =
map (pretty ctxt) xs (*always pretty in order to exhibit errors!*)
|> (if Config.get ctxt source then K [pretty_text ctxt (str_of_source src)] else I);
fun output ctxt prts =
prts
|> Config.get ctxt quotes ? map Pretty.quote
|> (if Config.get ctxt display then
map (Output.output o Pretty.string_of o Pretty.indent (Config.get ctxt indent))
#> space_implode "\\isasep\\isanewline%\n"
#> enclose "\\begin{isabelle}%\n" "%\n\\end{isabelle}"
else
map (Output.output o (if Config.get ctxt break then Pretty.string_of else Pretty.str_of))
#> space_implode "\\isasep\\isanewline%\n"
#> enclose "\\isa{" "}");
(** concrete antiquotations **)
(* basic entities *)
local
fun basic_entities name scan pretty = antiquotation name scan
(fn {source, context, ...} => output context o maybe_pretty_source pretty context source);
fun basic_entities_style name scan pretty = antiquotation name scan
(fn {source, context, ...} => fn (style, xs) =>
output context
(maybe_pretty_source (fn ctxt => fn x => pretty ctxt (style, x)) context source xs));
fun basic_entity name scan = basic_entities name (scan >> single);
in
val _ = Theory.setup
(basic_entities_style @{binding thm} (Term_Style.parse -- Attrib.thms) pretty_thm_style #>
basic_entity @{binding prop} (Term_Style.parse -- Args.prop) pretty_term_style #>
basic_entity @{binding term} (Term_Style.parse -- Args.term) pretty_term_style #>
basic_entity @{binding term_type} (Term_Style.parse -- Args.term) pretty_term_typ #>
basic_entity @{binding typeof} (Term_Style.parse -- Args.term) pretty_term_typeof #>
basic_entity @{binding const} (Args.const {proper = true, strict = false}) pretty_const #>
basic_entity @{binding abbrev} (Scan.lift Args.name_inner_syntax) pretty_abbrev #>
basic_entity @{binding typ} Args.typ_abbrev Syntax.pretty_typ #>
basic_entity @{binding class} (Scan.lift Args.name_inner_syntax) pretty_class #>
basic_entity @{binding type} (Scan.lift Args.name) pretty_type #>
basic_entity @{binding text} (Scan.lift Args.text_source_position) pretty_text_report #>
basic_entities @{binding prf} Attrib.thms (pretty_prf false) #>
basic_entities @{binding full_prf} Attrib.thms (pretty_prf true) #>
basic_entity @{binding theory} (Scan.lift (Parse.position Args.name)) pretty_theory);
end;
(* goal state *)
local
fun proof_state state =
(case try (Proof.goal o Toplevel.proof_of) state of
SOME {goal, ...} => goal
| _ => error "No proof state");
fun goal_state name main = antiquotation name (Scan.succeed ())
(fn {state, context = ctxt, ...} => fn () => output ctxt
[Goal_Display.pretty_goal
(Config.put Goal_Display.show_main_goal main ctxt) (proof_state state)]);
in
val _ = Theory.setup
(goal_state @{binding goals} true #>
goal_state @{binding subgoals} false);
end;
(* embedded lemma *)
val _ = Theory.setup
(antiquotation @{binding lemma}
(Scan.lift (Scan.ahead Parse.not_eof) -- Args.prop --
Scan.lift (Parse.position (Parse.reserved "by") -- Method.parse -- Scan.option Method.parse))
(fn {source, context = ctxt, ...} => fn ((prop_token, prop), (((_, by_pos), m1), m2)) =>
let
val prop_src = Token.src (Token.name_of_src source) [prop_token];
val reports = (by_pos, Markup.keyword1) :: maps Method.reports_of (m1 :: the_list m2);
val _ = Context_Position.reports ctxt reports;
(* FIXME check proof!? *)
val _ = ctxt
|> Proof.theorem NONE (K I) [[(prop, [])]]
|> Proof.global_terminal_proof (m1, m2);
in output ctxt (maybe_pretty_source pretty_term ctxt prop_src [prop]) end));
(* verbatim text *)
fun verbatim_text ctxt =
if Config.get ctxt display then
Latex.output_ascii #>
enclose "\\begin{isabellett}%\n" "%\n\\end{isabellett}"
else
split_lines #>
map (Latex.output_ascii #> enclose "\\isatt{" "}") #>
space_implode "\\isasep\\isanewline%\n";
val _ =
Theory.setup
(antiquotation @{binding verbatim} (Scan.lift Args.text) (verbatim_text o #context));
(* ML text *)
local
fun ml_text name ml = antiquotation name (Scan.lift Args.text_source_position)
(fn {context = ctxt, ...} => fn source =>
(ML_Context.eval_in (SOME ctxt) ML_Compiler.flags (Input.pos_of source) (ml source);
verbatim_text ctxt (Input.source_content source)));
fun ml_enclose bg en source =
ML_Lex.read bg @ ML_Lex.read_source false source @ ML_Lex.read en;
in
val _ = Theory.setup
(ml_text @{binding ML} (ml_enclose "fn _ => (" ");") #>
ml_text @{binding ML_op} (ml_enclose "fn _ => (op " ");") #>
ml_text @{binding ML_type} (ml_enclose "val _ = NONE : (" ") option;") #>
ml_text @{binding ML_structure}
(ml_enclose "functor XXX() = struct structure XX = " " end;") #>
ml_text @{binding ML_functor} (* FIXME formal treatment of functor name (!?) *)
(fn source =>
ML_Lex.read ("ML_Env.check_functor " ^
ML_Syntax.print_string (Input.source_content source))) #>
ml_text @{binding ML_text} (K []));
end;
(* URLs *)
val _ = Theory.setup
(antiquotation @{binding url} (Scan.lift (Parse.position Parse.name))
(fn {context = ctxt, ...} => fn (name, pos) =>
(Context_Position.reports ctxt [(pos, Markup.language_path), (pos, Markup.url name)];
enclose "\\url{" "}" name)));
(** document commands **)
fun old_header_command txt =
Toplevel.keep (fn state =>
if Toplevel.is_toplevel state then
(legacy_feature "Obsolete 'header' command -- use 'chapter', 'section' etc. instead";
check_text txt state)
else raise Toplevel.UNDEF);
fun document_command (loc, txt) =
Toplevel.keep (fn state =>
(case loc of
NONE => check_text txt state
| SOME (_, pos) =>
error ("Illegal target specification -- not a theory context" ^ Position.here pos))) o
Toplevel.present_local_theory loc (check_text txt);
end;