(* Title: Pure/Syntax/syntax_phases.ML
Author: Makarius
Main phases of inner syntax processing, with standard implementations
of parse/unparse operations.
*)
signature SYNTAX_PHASES =
sig
val decode_sort: term -> sort
val decode_typ: term -> typ
val decode_term: Proof.context ->
Position.report list * term Exn.result -> Position.report list * term Exn.result
val parse_ast_pattern: Proof.context -> string * string -> Ast.ast
val term_of_typ: Proof.context -> typ -> term
val print_checks: Proof.context -> unit
val typ_check: int -> string -> (Proof.context -> typ list -> typ list) ->
Context.generic -> Context.generic
val term_check: int -> string -> (Proof.context -> term list -> term list) ->
Context.generic -> Context.generic
val typ_uncheck: int -> string -> (Proof.context -> typ list -> typ list) ->
Context.generic -> Context.generic
val term_uncheck: int -> string -> (Proof.context -> term list -> term list) ->
Context.generic -> Context.generic
val typ_check': int -> string ->
(typ list -> Proof.context -> (typ list * Proof.context) option) ->
Context.generic -> Context.generic
val term_check': int -> string ->
(term list -> Proof.context -> (term list * Proof.context) option) ->
Context.generic -> Context.generic
val typ_uncheck': int -> string ->
(typ list -> Proof.context -> (typ list * Proof.context) option) ->
Context.generic -> Context.generic
val term_uncheck': int -> string ->
(term list -> Proof.context -> (term list * Proof.context) option) ->
Context.generic -> Context.generic
end
structure Syntax_Phases: SYNTAX_PHASES =
struct
(** markup logical entities **)
fun markup_class ctxt c =
[Name_Space.markup (Type.class_space (Proof_Context.tsig_of ctxt)) c];
fun markup_type ctxt c =
[Name_Space.markup (Type.type_space (Proof_Context.tsig_of ctxt)) c];
fun markup_const ctxt c =
[Name_Space.markup (Consts.space_of (Proof_Context.consts_of ctxt)) c];
fun markup_free ctxt x =
[if can Name.dest_skolem x then Markup.skolem else Markup.free] @
(if Variable.is_body ctxt orelse Variable.is_fixed ctxt x
then [Variable.markup_fixed ctxt x]
else []);
fun markup_var xi = [Markup.name (Term.string_of_vname xi) Markup.var];
fun markup_bound def ps (name, id) =
let val entity = Markup.entity "bound variable" name in
Markup.bound ::
map (fn pos => Markup.properties (Position.entity_properties_of def id pos) entity) ps
end;
fun markup_entity ctxt c =
(case Syntax.lookup_const (Proof_Context.syn_of ctxt) c of
SOME "" => []
| SOME b => markup_entity ctxt b
| NONE => c |> Lexicon.unmark
{case_class = markup_class ctxt,
case_type = markup_type ctxt,
case_const = markup_const ctxt,
case_fixed = markup_free ctxt,
case_default = K []});
(** decode parse trees **)
(* decode_sort *)
fun decode_sort tm =
let
fun err () = raise TERM ("decode_sort: bad encoding of classes", [tm]);
fun class s = Lexicon.unmark_class s handle Fail _ => err ();
fun classes (Const (s, _)) = [class s]
| classes (Const ("_classes", _) $ Const (s, _) $ cs) = class s :: classes cs
| classes _ = err ();
fun sort (Const ("_topsort", _)) = []
| sort (Const (s, _)) = [class s]
| sort (Const ("_sort", _) $ cs) = classes cs
| sort _ = err ();
in sort tm end;
(* decode_typ *)
fun decode_typ tm =
let
fun err () = raise TERM ("decode_typ: bad encoding of type", [tm]);
fun typ (Free (x, _)) = TFree (x, dummyS)
| typ (Var (xi, _)) = TVar (xi, dummyS)
| typ (Const ("_tfree",_) $ (t as Free _)) = typ t
| typ (Const ("_tvar",_) $ (t as Var _)) = typ t
| typ (Const ("_ofsort", _) $ Free (x, _) $ s) = TFree (x, decode_sort s)
| typ (Const ("_ofsort", _) $ (Const ("_tfree",_) $ Free (x, _)) $ s) =
TFree (x, decode_sort s)
| typ (Const ("_ofsort", _) $ Var (xi, _) $ s) = TVar (xi, decode_sort s)
| typ (Const ("_ofsort", _) $ (Const ("_tvar",_) $ Var (xi, _)) $ s) =
TVar (xi, decode_sort s)
| typ (Const ("_dummy_ofsort", _) $ s) = TFree ("'_dummy_", decode_sort s)
| typ t =
let
val (head, args) = Term.strip_comb t;
val a =
(case head of
Const (c, _) => (Lexicon.unmark_type c handle Fail _ => err ())
| _ => err ());
in Type (a, map typ args) end;
in typ tm end;
(* parsetree_to_ast *)
fun parsetree_to_ast ctxt constrain_pos trf parsetree =
let
val reports = Unsynchronized.ref ([]: Position.report list);
fun report pos = Position.store_reports reports [pos];
fun trans a args =
(case trf a of
NONE => Ast.mk_appl (Ast.Constant a) args
| SOME f => f ctxt args);
fun asts_of (Parser.Node ("_class_name", [Parser.Tip tok])) =
let
val pos = Lexicon.pos_of_token tok;
val c = Proof_Context.read_class ctxt (Lexicon.str_of_token tok)
handle ERROR msg => error (msg ^ Position.str_of pos);
val _ = report pos (markup_class ctxt) c;
in [Ast.Constant (Lexicon.mark_class c)] end
| asts_of (Parser.Node ("_type_name", [Parser.Tip tok])) =
let
val pos = Lexicon.pos_of_token tok;
val Type (c, _) =
Proof_Context.read_type_name_proper ctxt false (Lexicon.str_of_token tok)
handle ERROR msg => error (msg ^ Position.str_of pos);
val _ = report pos (markup_type ctxt) c;
in [Ast.Constant (Lexicon.mark_type c)] end
| asts_of (Parser.Node ("_position", [pt as Parser.Tip tok])) =
if constrain_pos then
[Ast.Appl [Ast.Constant "_constrain", ast_of pt,
Ast.Variable (Term_Position.encode (Lexicon.pos_of_token tok))]]
else [ast_of pt]
| asts_of (Parser.Node (a, pts)) =
let
val _ = pts |> List.app
(fn Parser.Node _ => () | Parser.Tip tok =>
if Lexicon.valued_token tok then ()
else report (Lexicon.pos_of_token tok) (markup_entity ctxt) a);
in [trans a (maps asts_of pts)] end
| asts_of (Parser.Tip tok) =
if Lexicon.valued_token tok
then [Ast.Variable (Lexicon.str_of_token tok)]
else []
and ast_of pt =
(case asts_of pt of
[ast] => ast
| asts => raise Ast.AST ("parsetree_to_ast: malformed parsetree", asts));
val ast = Exn.interruptible_capture ast_of parsetree;
in (! reports, ast) end;
(* ast_to_term *)
fun ast_to_term ctxt trf =
let
fun trans a args =
(case trf a of
NONE => Term.list_comb (Syntax.const a, args)
| SOME f => f ctxt args);
fun term_of (Ast.Constant a) = trans a []
| term_of (Ast.Variable x) = Lexicon.read_var x
| term_of (Ast.Appl (Ast.Constant a :: (asts as _ :: _))) =
trans a (map term_of asts)
| term_of (Ast.Appl (ast :: (asts as _ :: _))) =
Term.list_comb (term_of ast, map term_of asts)
| term_of (ast as Ast.Appl _) = raise Ast.AST ("ast_to_term: malformed ast", [ast]);
in term_of end;
(* decode_term -- transform parse tree into raw term *)
fun decode_term _ (result as (_: Position.report list, Exn.Exn _)) = result
| decode_term ctxt (reports0, Exn.Res tm) =
let
fun get_const a =
((true, #1 (Term.dest_Const (Proof_Context.read_const_proper ctxt false a)))
handle ERROR _ => (false, Consts.intern (Proof_Context.consts_of ctxt) a));
val get_free = Proof_Context.intern_skolem ctxt;
val reports = Unsynchronized.ref reports0;
fun report ps = Position.store_reports reports ps;
fun decode ps qs bs (Const ("_constrain", _) $ t $ typ) =
(case Term_Position.decode_position typ of
SOME p => decode (p :: ps) qs bs t
| NONE => Type.constraint (decode_typ typ) (decode ps qs bs t))
| decode ps qs bs (Const ("_constrainAbs", _) $ t $ typ) =
(case Term_Position.decode_position typ of
SOME q => decode ps (q :: qs) bs t
| NONE => Type.constraint (decode_typ typ --> dummyT) (decode ps qs bs t))
| decode _ qs bs (Abs (x, T, t)) =
let
val id = serial ();
val _ = report qs (markup_bound true qs) (x, id);
in Abs (x, T, decode [] [] ((qs, (x, id)) :: bs) t) end
| decode _ _ bs (t $ u) = decode [] [] bs t $ decode [] [] bs u
| decode ps _ _ (Const (a, T)) =
(case try Lexicon.unmark_fixed a of
SOME x => (report ps (markup_free ctxt) x; Free (x, T))
| NONE =>
let
val c =
(case try Lexicon.unmark_const a of
SOME c => c
| NONE => snd (get_const a));
val _ = report ps (markup_const ctxt) c;
in Const (c, T) end)
| decode ps _ _ (Free (a, T)) =
(case (get_free a, get_const a) of
(SOME x, _) => (report ps (markup_free ctxt) x; Free (x, T))
| (_, (true, c)) => (report ps (markup_const ctxt) c; Const (c, T))
| (_, (false, c)) =>
if Long_Name.is_qualified c
then (report ps (markup_const ctxt) c; Const (c, T))
else (report ps (markup_free ctxt) c; Free (c, T)))
| decode ps _ _ (Var (xi, T)) = (report ps markup_var xi; Var (xi, T))
| decode ps _ bs (t as Bound i) =
(case try (nth bs) i of
SOME (qs, (x, id)) => (report ps (markup_bound false qs) (x, id); t)
| NONE => t);
val tm' = Exn.interruptible_capture (fn () => decode [] [] [] tm) ();
in (! reports, tm') end;
(** parse **)
(* results *)
fun ambiguity_msg pos = "Parse error: ambiguous syntax" ^ Position.str_of pos;
fun proper_results results = map_filter (fn (y, Exn.Res x) => SOME (y, x) | _ => NONE) results;
fun failed_results results = map_filter (fn (y, Exn.Exn e) => SOME (y, e) | _ => NONE) results;
fun report_result ctxt pos results =
(case (proper_results results, failed_results results) of
([], (reports, exn) :: _) => (Context_Position.reports ctxt reports; reraise exn)
| ([(reports, x)], _) => (Context_Position.reports ctxt reports; x)
| _ => error (ambiguity_msg pos));
(* parse raw asts *)
fun parse_asts ctxt raw root (syms, pos) =
let
val syn = Proof_Context.syn_of ctxt;
val ast_tr = Syntax.parse_ast_translation syn;
val toks = Syntax.tokenize syn raw syms;
val _ = Context_Position.reports ctxt (map Lexicon.report_of_token toks);
val pts = Syntax.parse ctxt syn root (filter Lexicon.is_proper toks)
handle ERROR msg =>
error (msg ^
implode (map (Markup.markup Markup.report o Lexicon.reported_token_range ctxt) toks));
val len = length pts;
val limit = Config.get ctxt Syntax.ambiguity_limit;
val warnings = Config.get ctxt Syntax.ambiguity_warnings;
val _ =
if len <= Config.get ctxt Syntax.ambiguity_level then ()
else if not (Config.get ctxt Syntax.ambiguity_enabled) then error (ambiguity_msg pos)
else if warnings then
(Context_Position.if_visible ctxt warning (cat_lines
(("Ambiguous input" ^ Position.str_of (Position.reset_range pos) ^
"\nproduces " ^ string_of_int len ^ " parse trees" ^
(if len <= limit then "" else " (" ^ string_of_int limit ^ " displayed)") ^ ":") ::
map (Pretty.string_of o Parser.pretty_parsetree) (take limit pts))))
else ();
val constrain_pos = not raw andalso Config.get ctxt Syntax.positions;
val parsetree_to_ast = parsetree_to_ast ctxt constrain_pos ast_tr;
in map parsetree_to_ast pts end;
fun parse_raw ctxt root input =
let
val syn = Proof_Context.syn_of ctxt;
val tr = Syntax.parse_translation syn;
val parse_rules = Syntax.parse_rules syn;
in
parse_asts ctxt false root input
|> (map o apsnd o Exn.maps_result)
(Ast.normalize ctxt parse_rules #> Exn.interruptible_capture (ast_to_term ctxt tr))
end;
(* parse logical entities *)
fun parse_failed ctxt pos msg kind =
cat_error msg ("Failed to parse " ^ kind ^
Markup.markup Markup.report (Context_Position.reported_text ctxt pos Markup.bad ""));
fun parse_sort ctxt =
Syntax.parse_token ctxt Term_XML.Decode.sort Markup.sort
(fn (syms, pos) =>
parse_raw ctxt "sort" (syms, pos)
|> report_result ctxt pos
|> decode_sort
|> Type.minimize_sort (Proof_Context.tsig_of ctxt)
handle ERROR msg => parse_failed ctxt pos msg "sort");
fun parse_typ ctxt =
Syntax.parse_token ctxt Term_XML.Decode.typ Markup.typ
(fn (syms, pos) =>
parse_raw ctxt "type" (syms, pos)
|> report_result ctxt pos
|> decode_typ
handle ERROR msg => parse_failed ctxt pos msg "type");
fun parse_term is_prop ctxt =
let
val (markup, kind, root, constrain) =
if is_prop
then (Markup.prop, "proposition", "prop", Type.constraint propT)
else (Markup.term, "term", Config.get ctxt Syntax.root, I);
val decode = constrain o Term_XML.Decode.term;
in
Syntax.parse_token ctxt decode markup
(fn (syms, pos) =>
let
val results = parse_raw ctxt root (syms, pos) |> map (decode_term ctxt);
val ambiguity = length (proper_results results);
val level = Config.get ctxt Syntax.ambiguity_level;
val limit = Config.get ctxt Syntax.ambiguity_limit;
val warnings = Config.get ctxt Syntax.ambiguity_warnings;
val ambig_msg =
if ambiguity > 1 andalso ambiguity <= level then
["Got more than one parse tree.\n\
\Retry with smaller syntax_ambiguity_level for more information."]
else [];
(*brute-force disambiguation via type-inference*)
fun check t = (Syntax.check_term ctxt (constrain t); Exn.Res t)
handle exn as ERROR _ => Exn.Exn exn;
val results' =
if ambiguity > 1 then
(Par_List.map_name "Syntax_Phases.parse_term" o apsnd o Exn.maps_result)
check results
else results;
val reports' = fst (hd results');
val errs = map snd (failed_results results');
val checked = map snd (proper_results results');
val len = length checked;
val show_term = Syntax.string_of_term (Config.put Printer.show_brackets true ctxt);
in
if len = 0 then
report_result ctxt pos
[(reports', Exn.Exn (Exn.EXCEPTIONS (map ERROR ambig_msg @ errs)))]
else if len = 1 then
(if ambiguity > level andalso warnings then
Context_Position.if_visible ctxt warning
("Fortunately, only one parse tree is type correct" ^
Position.str_of (Position.reset_range pos) ^
",\nbut you may still want to disambiguate your grammar or your input.")
else (); report_result ctxt pos results')
else
report_result ctxt pos
[(reports', Exn.Exn (ERROR (cat_lines (ambig_msg @
(("Ambiguous input, " ^ string_of_int len ^ " terms are type correct" ^
(if len <= limit then "" else " (" ^ string_of_int limit ^ " displayed)") ^ ":") ::
map show_term (take limit checked))))))]
end handle ERROR msg => parse_failed ctxt pos msg kind)
end;
(* parse_ast_pattern *)
fun parse_ast_pattern ctxt (root, str) =
let
val syn = Proof_Context.syn_of ctxt;
fun constify (ast as Ast.Constant _) = ast
| constify (ast as Ast.Variable x) =
if is_some (Syntax.lookup_const syn x) orelse Long_Name.is_qualified x
then Ast.Constant x
else ast
| constify (Ast.Appl asts) = Ast.Appl (map constify asts);
val (syms, pos) = Syntax.read_token str;
in
parse_asts ctxt true root (syms, pos)
|> report_result ctxt pos
|> constify
end;
(** encode parse trees **)
(* term_of_sort *)
fun term_of_sort S =
let
val class = Syntax.const o Lexicon.mark_class;
fun classes [c] = class c
| classes (c :: cs) = Syntax.const "_classes" $ class c $ classes cs;
in
(case S of
[] => Syntax.const "_topsort"
| [c] => class c
| cs => Syntax.const "_sort" $ classes cs)
end;
(* term_of_typ *)
fun term_of_typ ctxt ty =
let
val show_sorts = Config.get ctxt show_sorts;
fun of_sort t S =
if show_sorts then Syntax.const "_ofsort" $ t $ term_of_sort S
else t;
fun term_of (Type (a, Ts)) =
Term.list_comb (Syntax.const (Lexicon.mark_type a), map term_of Ts)
| term_of (TFree (x, S)) =
if is_some (Term_Position.decode x) then Syntax.free x
else of_sort (Syntax.const "_tfree" $ Syntax.free x) S
| term_of (TVar (xi, S)) = of_sort (Syntax.const "_tvar" $ Syntax.var xi) S;
in term_of ty end;
(* simple_ast_of *)
fun simple_ast_of ctxt =
let
val tune_var = if Config.get ctxt show_question_marks then I else unprefix "?";
fun ast_of (Const (c, _)) = Ast.Constant c
| ast_of (Free (x, _)) = Ast.Variable x
| ast_of (Var (xi, _)) = Ast.Variable (tune_var (Term.string_of_vname xi))
| ast_of (t as _ $ _) =
let val (f, args) = strip_comb t
in Ast.mk_appl (ast_of f) (map ast_of args) end
| ast_of (Bound i) = Ast.Appl [Ast.Constant "_loose", Ast.Variable ("B." ^ string_of_int i)]
| ast_of (Abs _) = raise Fail "simple_ast_of: Abs";
in ast_of end;
(* sort_to_ast and typ_to_ast *)
fun ast_of_termT ctxt trf tm =
let
val ctxt' = Config.put show_sorts false ctxt;
fun ast_of (t as Const ("_tfree", _) $ Free _) = simple_ast_of ctxt t
| ast_of (t as Const ("_tvar", _) $ Var _) = simple_ast_of ctxt t
| ast_of (Const (a, _)) = trans a []
| ast_of (t as _ $ _) =
(case strip_comb t of
(Const (a, _), args) => trans a args
| (f, args) => Ast.Appl (map ast_of (f :: args)))
| ast_of t = simple_ast_of ctxt t
and trans a args = ast_of (trf a ctxt' dummyT args)
handle Match => Ast.mk_appl (Ast.Constant a) (map ast_of args);
in ast_of tm end;
fun sort_to_ast ctxt trf S = ast_of_termT ctxt trf (term_of_sort S);
fun typ_to_ast ctxt trf T = ast_of_termT ctxt trf (term_of_typ ctxt T);
(* term_to_ast *)
fun term_to_ast idents is_syntax_const ctxt trf tm =
let
val show_types =
Config.get ctxt show_types orelse Config.get ctxt show_sorts orelse
Config.get ctxt show_all_types;
val show_structs = Config.get ctxt show_structs;
val show_free_types = Config.get ctxt show_free_types;
val show_all_types = Config.get ctxt show_all_types;
val {structs, fixes} = idents;
fun mark_atoms ((t as Const (c, _)) $ u) =
if member (op =) Syntax.token_markers c
then t $ u else mark_atoms t $ mark_atoms u
| mark_atoms (t $ u) = mark_atoms t $ mark_atoms u
| mark_atoms (Abs (x, T, t)) = Abs (x, T, mark_atoms t)
| mark_atoms (t as Const (c, T)) =
if is_syntax_const c then t
else Const (Lexicon.mark_const c, T)
| mark_atoms (t as Free (x, T)) =
let val i = find_index (fn s => s = x) structs + 1 in
if i = 0 andalso member (op =) fixes x then
Const (Lexicon.mark_fixed x, T)
else if i = 1 andalso not show_structs then
Syntax.const "_struct" $ Syntax.const "_indexdefault"
else Syntax.const "_free" $ t
end
| mark_atoms (t as Var (xi, T)) =
if xi = Syntax_Ext.dddot_indexname then Const ("_DDDOT", T)
else Syntax.const "_var" $ t
| mark_atoms a = a;
fun prune_typs (t_seen as (Const _, _)) = t_seen
| prune_typs (t as Free (x, ty), seen) =
if ty = dummyT then (t, seen)
else if not show_free_types orelse member (op aconv) seen t then (Syntax.free x, seen)
else (t, t :: seen)
| prune_typs (t as Var (xi, ty), seen) =
if ty = dummyT then (t, seen)
else if not show_free_types orelse member (op aconv) seen t then (Syntax.var xi, seen)
else (t, t :: seen)
| prune_typs (t_seen as (Bound _, _)) = t_seen
| prune_typs (Abs (x, ty, t), seen) =
let val (t', seen') = prune_typs (t, seen);
in (Abs (x, ty, t'), seen') end
| prune_typs (t1 $ t2, seen) =
let
val (t1', seen') = prune_typs (t1, seen);
val (t2', seen'') = prune_typs (t2, seen');
in (t1' $ t2', seen'') end;
fun ast_of tm =
(case strip_comb tm of
(t as Abs _, ts) => Ast.mk_appl (ast_of (Syntax_Trans.abs_tr' ctxt t)) (map ast_of ts)
| ((c as Const ("_free", _)), Free (x, T) :: ts) =>
Ast.mk_appl (constrain (c $ Syntax.free x) T) (map ast_of ts)
| ((c as Const ("_var", _)), Var (xi, T) :: ts) =>
Ast.mk_appl (constrain (c $ Syntax.var xi) T) (map ast_of ts)
| ((c as Const ("_bound", _)), Free (x, T) :: ts) =>
Ast.mk_appl (constrain (c $ Syntax.free x) T) (map ast_of ts)
| (Const ("_idtdummy", T), ts) =>
Ast.mk_appl (constrain (Syntax.const "_idtdummy") T) (map ast_of ts)
| (const as Const (c, T), ts) =>
if show_all_types
then Ast.mk_appl (constrain const T) (map ast_of ts)
else trans c T ts
| (t, ts) => Ast.mk_appl (simple_ast_of ctxt t) (map ast_of ts))
and trans a T args = ast_of (trf a ctxt T args)
handle Match => Ast.mk_appl (Ast.Constant a) (map ast_of args)
and constrain t T =
if show_types andalso T <> dummyT then
Ast.Appl [Ast.Constant "_constrain", simple_ast_of ctxt t,
ast_of_termT ctxt trf (term_of_typ ctxt T)]
else simple_ast_of ctxt t;
in
tm
|> Syntax_Trans.prop_tr'
|> show_types ? (#1 o prune_typs o rpair [])
|> mark_atoms
|> ast_of
end;
(** unparse **)
local
fun free_or_skolem ctxt x =
let
val m =
if Variable.is_fixed ctxt x orelse Syntax.is_pretty_global ctxt
then Markup.fixed x
else Markup.hilite;
in
if can Name.dest_skolem x
then ([m, Markup.skolem], Variable.revert_fixed ctxt x)
else ([m, Markup.free], x)
end;
fun var_or_skolem s =
(case Lexicon.read_variable s of
SOME (x, i) =>
(case try Name.dest_skolem x of
NONE => (Markup.var, s)
| SOME x' => (Markup.skolem, Term.string_of_vname (x', i)))
| NONE => (Markup.var, s));
fun unparse_t t_to_ast prt_t markup ctxt t =
let
val syn = Proof_Context.syn_of ctxt;
fun token_trans "_tfree" x = SOME (Pretty.mark_str (Markup.tfree, x))
| token_trans "_tvar" x = SOME (Pretty.mark_str (Markup.tvar, x))
| token_trans "_free" x = SOME (Pretty.marks_str (free_or_skolem ctxt x))
| token_trans "_bound" x = SOME (Pretty.mark_str (Markup.bound, x))
| token_trans "_loose" x = SOME (Pretty.mark_str (Markup.malformed, x))
| token_trans "_var" x = SOME (Pretty.mark_str (var_or_skolem x))
| token_trans "_numeral" x = SOME (Pretty.mark_str (Markup.numeral, x))
| token_trans "_inner_string" x = SOME (Pretty.mark_str (Markup.inner_string, x))
| token_trans _ _ = NONE;
fun markup_extern c =
(case Syntax.lookup_const syn c of
SOME "" => ([], c)
| SOME b => markup_extern b
| NONE => c |> Lexicon.unmark
{case_class = fn x => (markup_class ctxt x, Proof_Context.extern_class ctxt x),
case_type = fn x => (markup_type ctxt x, Proof_Context.extern_type ctxt x),
case_const = fn x => (markup_const ctxt x, Proof_Context.extern_const ctxt x),
case_fixed = fn x => free_or_skolem ctxt x,
case_default = fn x => ([], x)});
in
t_to_ast ctxt (Syntax.print_translation syn) t
|> Ast.normalize ctxt (Syntax.print_rules syn)
|> prt_t ctxt (Syntax.prtabs syn) (Syntax.print_ast_translation syn) token_trans markup_extern
|> Pretty.markup markup
end;
in
val unparse_sort = unparse_t sort_to_ast Printer.pretty_typ_ast Markup.sort;
val unparse_typ = unparse_t typ_to_ast Printer.pretty_typ_ast Markup.typ;
fun unparse_term ctxt =
let
val thy = Proof_Context.theory_of ctxt;
val syn = Proof_Context.syn_of ctxt;
val idents = Local_Syntax.idents_of (Proof_Context.syntax_of ctxt);
in
unparse_t (term_to_ast idents (is_some o Syntax.lookup_const syn))
(Printer.pretty_term_ast (not (Pure_Thy.old_appl_syntax thy)))
Markup.term ctxt
end;
end;
(** translations **)
(* type propositions *)
fun type_prop_tr' ctxt T [Const ("\\<^const>Pure.sort_constraint", _)] =
Syntax.const "_sort_constraint" $ term_of_typ (Config.put show_sorts true ctxt) T
| type_prop_tr' ctxt T [t] =
Syntax.const "_ofclass" $ term_of_typ ctxt T $ t
| type_prop_tr' _ T ts = raise TYPE ("type_prop_tr'", [T], ts);
(* type reflection *)
fun type_tr' ctxt (Type ("itself", [T])) ts =
Term.list_comb (Syntax.const "_TYPE" $ term_of_typ ctxt T, ts)
| type_tr' _ _ _ = raise Match;
(* type constraints *)
fun type_constraint_tr' ctxt (Type ("fun", [T, _])) (t :: ts) =
Term.list_comb (Syntax.const "_constrain" $ t $ term_of_typ ctxt T, ts)
| type_constraint_tr' _ _ _ = raise Match;
(* authentic syntax *)
fun const_ast_tr intern ctxt [Ast.Variable c] =
let
val Const (c', _) = Proof_Context.read_const_proper ctxt false c;
val d = if intern then Lexicon.mark_const c' else c;
in Ast.Constant d end
| const_ast_tr intern ctxt [Ast.Appl [Ast.Constant "_constrain", x, T as Ast.Variable pos]] =
(Ast.Appl [Ast.Constant "_constrain", const_ast_tr intern ctxt [x], T]
handle ERROR msg =>
error (msg ^ Position.str_of (the_default Position.none (Term_Position.decode pos))))
| const_ast_tr _ _ asts = raise Ast.AST ("const_ast_tr", asts);
(* setup translations *)
val _ = Context.>> (Context.map_theory
(Sign.add_advanced_trfuns
([("_context_const", const_ast_tr true),
("_context_xconst", const_ast_tr false)], [], [], []) #>
Sign.add_advanced_trfunsT
[("_type_prop", type_prop_tr'),
("\\<^const>TYPE", type_tr'),
("_type_constraint_", type_constraint_tr')]));
(** check/uncheck **)
(* context-sensitive (un)checking *)
type key = int * bool;
structure Checks = Generic_Data
(
type 'a check = 'a list -> Proof.context -> ('a list * Proof.context) option;
type T =
((key * ((string * typ check) * stamp) list) list *
(key * ((string * term check) * stamp) list) list);
val empty = ([], []);
val extend = I;
fun merge ((typ_checks1, term_checks1), (typ_checks2, term_checks2)) : T =
(AList.join (op =) (K (Library.merge (eq_snd (op =)))) (typ_checks1, typ_checks2),
AList.join (op =) (K (Library.merge (eq_snd (op =)))) (term_checks1, term_checks2));
);
fun print_checks ctxt =
let
fun split_checks checks =
List.partition (fn ((_, un), _) => not un) checks
|> pairself (map (fn ((i, _), fs) => (i, map (fst o fst) fs))
#> sort (int_ord o pairself fst));
fun pretty_checks kind checks =
checks |> map (fn (i, names) => Pretty.block
[Pretty.str (kind ^ " (stage " ^ signed_string_of_int i ^ "):"),
Pretty.brk 1, Pretty.strs names]);
val (typs, terms) = Checks.get (Context.Proof ctxt);
val (typ_checks, typ_unchecks) = split_checks typs;
val (term_checks, term_unchecks) = split_checks terms;
in
pretty_checks "typ_checks" typ_checks @
pretty_checks "term_checks" term_checks @
pretty_checks "typ_unchecks" typ_unchecks @
pretty_checks "term_unchecks" term_unchecks
end |> Pretty.chunks |> Pretty.writeln;
local
fun context_check which (key: key) name f =
Checks.map (which (AList.map_default op = (key, []) (cons ((name, f), stamp ()))));
fun simple_check eq f xs ctxt =
let val xs' = f ctxt xs
in if eq_list eq (xs, xs') then NONE else SOME (xs', ctxt) end;
in
fun typ_check' stage = context_check apfst (stage, false);
fun term_check' stage = context_check apsnd (stage, false);
fun typ_uncheck' stage = context_check apfst (stage, true);
fun term_uncheck' stage = context_check apsnd (stage, true);
fun typ_check key name f = typ_check' key name (simple_check (op =) f);
fun term_check key name f = term_check' key name (simple_check (op aconv) f);
fun typ_uncheck key name f = typ_uncheck' key name (simple_check (op =) f);
fun term_uncheck key name f = term_uncheck' key name (simple_check (op aconv) f);
end;
local
fun check_stage fs = perhaps_loop (perhaps_apply (map uncurry fs));
fun check_all fs = perhaps_apply (map check_stage fs);
fun check which uncheck ctxt0 xs0 =
let
val funs = which (Checks.get (Context.Proof ctxt0))
|> map_filter (fn ((i, u), fs) => if uncheck = u then SOME (i, map (snd o fst) fs) else NONE)
|> Library.sort (int_ord o pairself fst) |> map snd
|> not uncheck ? map rev;
in #1 (perhaps (check_all funs) (xs0, ctxt0)) end;
val apply_typ_check = check fst false;
val apply_term_check = check snd false;
val apply_typ_uncheck = check fst true;
val apply_term_uncheck = check snd true;
fun prepare_types ctxt tys =
let
fun constraint (xi: indexname, S) = S <> dummyS ? insert (op =) (xi, S);
val env =
(fold o fold_atyps)
(fn TFree (x, S) => constraint ((x, ~1), S)
| TVar v => constraint v
| _ => I) tys [];
val get_sort = Proof_Context.get_sort ctxt env;
in
(map o map_atyps)
(fn TFree (x, _) => TFree (x, get_sort (x, ~1))
| TVar (xi, _) => TVar (xi, get_sort xi)
| T => T) tys
end;
in
fun check_typs ctxt =
prepare_types ctxt #>
apply_typ_check ctxt #>
Term_Sharing.typs (Proof_Context.theory_of ctxt);
fun check_terms ctxt =
Term.burrow_types (prepare_types ctxt) #>
apply_term_check ctxt #>
Term_Sharing.terms (Proof_Context.theory_of ctxt);
fun check_props ctxt = map (Type.constraint propT) #> check_terms ctxt;
val uncheck_typs = apply_typ_uncheck;
val uncheck_terms = apply_term_uncheck;
end;
(* standard phases *)
val _ = Context.>>
(typ_check 0 "standard" Proof_Context.standard_typ_check #>
term_check 0 "standard"
(fn ctxt => Type_Infer_Context.infer_types ctxt #> map (Proof_Context.expand_abbrevs ctxt)) #>
term_check 100 "standard_finish" Proof_Context.standard_term_check_finish #>
term_uncheck 0 "standard" Proof_Context.standard_term_uncheck);
(** install operations **)
val _ = Syntax.install_operations
{parse_sort = parse_sort,
parse_typ = parse_typ,
parse_term = parse_term false,
parse_prop = parse_term true,
unparse_sort = unparse_sort,
unparse_typ = unparse_typ,
unparse_term = unparse_term,
check_typs = check_typs,
check_terms = check_terms,
check_props = check_props,
uncheck_typs = uncheck_typs,
uncheck_terms = uncheck_terms};
end;