(* Title: Pure/Syntax/sextension.ML
ID: $Id$
Author: Tobias Nipkow and Markus Wenzel, TU Muenchen
Syntax extensions (external interface): mixfix declarations, infixes,
binders, translation rules / functions and the Pure syntax.
TODO:
move ast_to_term, pt_to_ast (?)
*)
infix |-> <-| <->;
signature SEXTENSION0 =
sig
structure Parser: PARSER
local open Parser.SynExt.Ast in
datatype mixfix =
Mixfix of string * string * string * int list * int |
Delimfix of string * string * string |
Infixl of string * string * int |
Infixr of string * string * int |
Binder of string * string * string * int * int |
TInfixl of string * string * int |
TInfixr of string * string * int
datatype xrule =
op |-> of (string * string) * (string * string) |
op <-| of (string * string) * (string * string) |
op <-> of (string * string) * (string * string)
datatype sext =
Sext of {
mixfix: mixfix list,
parse_translation: (string * (term list -> term)) list,
print_translation: (string * (term list -> term)) list} |
NewSext of {
mixfix: mixfix list,
xrules: xrule list,
parse_ast_translation: (string * (ast list -> ast)) list,
parse_translation: (string * (term list -> term)) list,
print_translation: (string * (term list -> term)) list,
print_ast_translation: (string * (ast list -> ast)) list}
val eta_contract: bool ref
val mk_binder_tr: string * string -> string * (term list -> term)
val mk_binder_tr': string * string -> string * (term list -> term)
val dependent_tr': string * string -> term list -> term
val max_pri: int
end
end;
signature SEXTENSION1 =
sig
include SEXTENSION0
local open Parser.SynExt.Ast in
val empty_sext: sext
val simple_sext: mixfix list -> sext
val constants: sext -> (string list * string) list
val pure_sext: sext
val syntax_types: string list
val syntax_consts: (string list * string) list
val constrainAbsC: string
val pure_trfuns:
(string * (ast list -> ast)) list *
(string * (term list -> term)) list *
(string * (term list -> term)) list *
(string * (ast list -> ast)) list
end
end;
signature SEXTENSION =
sig
include SEXTENSION1
local open Parser Parser.SynExt Parser.SynExt.Ast in
val xrules_of: sext -> xrule list
val abs_tr': term -> term
val prop_tr': bool -> term -> term
val appl_ast_tr': ast * ast list -> ast
val syn_ext_of_sext: string list -> string list -> string list -> (string -> typ) -> sext -> syn_ext
val pt_to_ast: (string -> (ast list -> ast) option) -> parsetree -> ast
val ast_to_term: (string -> (term list -> term) option) -> ast -> term
end
end;
functor SExtensionFun(structure TypeExt: TYPE_EXT and Parser: PARSER
sharing TypeExt.SynExt = Parser.SynExt): SEXTENSION =
struct
structure Parser = Parser;
open TypeExt Parser.Lexicon Parser.SynExt.Ast Parser.SynExt Parser;
(** datatype sext **) (* FIXME remove *)
datatype mixfix =
Mixfix of string * string * string * int list * int |
Delimfix of string * string * string |
Infixl of string * string * int |
Infixr of string * string * int |
Binder of string * string * string * int * int |
TInfixl of string * string * int |
TInfixr of string * string * int;
(* FIXME -> syntax.ML, BASIC_SYNTAX, SYNTAX *)
datatype xrule =
op |-> of (string * string) * (string * string) |
op <-| of (string * string) * (string * string) |
op <-> of (string * string) * (string * string);
datatype sext =
Sext of {
mixfix: mixfix list,
parse_translation: (string * (term list -> term)) list,
print_translation: (string * (term list -> term)) list} |
NewSext of {
mixfix: mixfix list,
xrules: xrule list,
parse_ast_translation: (string * (ast list -> ast)) list,
parse_translation: (string * (term list -> term)) list,
print_translation: (string * (term list -> term)) list,
print_ast_translation: (string * (ast list -> ast)) list};
(* simple_sext *)
fun simple_sext mixfix =
Sext {mixfix = mixfix, parse_translation = [], print_translation = []};
(* empty_sext *)
val empty_sext = simple_sext [];
(* sext_components *)
fun sext_components (Sext {mixfix, parse_translation, print_translation}) =
{mixfix = mixfix,
xrules = [],
parse_ast_translation = [],
parse_translation = parse_translation,
print_translation = print_translation,
print_ast_translation = []}
| sext_components (NewSext cmps) = cmps;
(* mixfix_of *)
fun mixfix_of (Sext {mixfix, ...}) = mixfix
| mixfix_of (NewSext {mixfix, ...}) = mixfix;
(* xrules_of *)
fun xrules_of (Sext _) = []
| xrules_of (NewSext {xrules, ...}) = xrules;
(*** translation functions ***) (* FIXME -> trans.ML *)
fun const c = Const (c, dummyT);
(** parse (ast) translations **)
(* application *)
fun appl_ast_tr (*"_appl"*) [f, args] = Appl (f :: unfold_ast "_args" args)
| appl_ast_tr (*"_appl"*) asts = raise_ast "appl_ast_tr" asts;
(* abstraction *)
fun idtyp_ast_tr (*"_idtyp"*) [x, ty] = Appl [Constant constrainC, x, ty]
| idtyp_ast_tr (*"_idtyp"*) asts = raise_ast "idtyp_ast_tr" asts;
fun lambda_ast_tr (*"_lambda"*) [idts, body] =
fold_ast_p "_abs" (unfold_ast "_idts" idts, body)
| lambda_ast_tr (*"_lambda"*) asts = raise_ast "lambda_ast_tr" asts;
fun abs_tr (*"_abs"*) [Free (x, T), body] = absfree (x, T, body)
| abs_tr (*"_abs"*) (ts as [Const (c, _) $ Free (x, T) $ tT, body]) =
if c = constrainC then
const "_constrainAbs" $ absfree (x, T, body) $ tT
else raise_term "abs_tr" ts
| abs_tr (*"_abs"*) ts = raise_term "abs_tr" ts;
(* nondependent abstraction *)
fun k_tr (*"_K"*) [t] = Abs ("uu", dummyT, incr_boundvars 1 t)
| k_tr (*"_K"*) ts = raise_term "k_tr" ts;
(* binder *)
fun mk_binder_tr (sy, name) =
let
fun tr (Free (x, T), t) = const name $ absfree (x, T, t)
| tr (Const ("_idts", _) $ idt $ idts, t) = tr (idt, tr (idts, t))
| tr (t1 as Const (c, _) $ Free (x, T) $ tT, t) =
if c = constrainC then
const name $ (const "_constrainAbs" $ absfree (x, T, t) $ tT)
else raise_term "binder_tr" [t1, t]
| tr (t1, t2) = raise_term "binder_tr" [t1, t2];
fun binder_tr (*sy*) [idts, body] = tr (idts, body)
| binder_tr (*sy*) ts = raise_term "binder_tr" ts;
in
(sy, binder_tr)
end;
(* meta propositions *)
fun aprop_tr (*"_aprop"*) [t] = const constrainC $ t $ const "prop"
| aprop_tr (*"_aprop"*) ts = raise_term "aprop_tr" ts;
fun ofclass_tr (*"_ofclass"*) [ty, cls] =
cls $ (const constrainC $ const "TYPE" $ (const "itself" $ ty))
| ofclass_tr (*"_ofclass"*) ts = raise_term "ofclass_tr" ts;
(* meta implication *)
fun bigimpl_ast_tr (*"_bigimpl"*) [asms, concl] =
fold_ast_p "==>" (unfold_ast "_asms" asms, concl)
| bigimpl_ast_tr (*"_bigimpl"*) asts = raise_ast "bigimpl_ast_tr" asts;
(* explode atoms *)
fun explode_tr (*"_explode"*) (ts as [consC, nilC, bit0, bit1, txt]) =
let
fun mk_list [] = nilC
| mk_list (t :: ts) = consC $ t $ mk_list ts;
fun encode_bit 0 = bit0
| encode_bit 1 = bit1
| encode_bit _ = sys_error "encode_bit";
fun encode_char c = (* FIXME leading 0s (?) *)
mk_list (map encode_bit (radixpand (2, (ord c))));
val str =
(case txt of
Free (s, _) => s
| Const (s, _) => s
| _ => raise_term "explode_tr" ts);
in
mk_list (map encode_char (explode str))
end
| explode_tr (*"_explode"*) ts = raise_term "explode_tr" ts;
(** print (ast) translations **)
(* application *)
fun appl_ast_tr' (f, []) = raise_ast "appl_ast_tr'" [f]
| appl_ast_tr' (f, args) = Appl [Constant "_appl", f, fold_ast "_args" args];
(* abstraction *)
fun strip_abss vars_of body_of tm =
let
fun free (x, _) = Free (x, dummyT);
val vars = vars_of tm;
val body = body_of tm;
val rev_new_vars = rename_wrt_term body vars;
in
(map Free (rev rev_new_vars), subst_bounds (map free rev_new_vars, body))
end;
(*do (partial) eta-contraction before printing*)
val eta_contract = ref false;
fun eta_contr tm =
let
fun eta_abs (Abs (a, T, t)) =
(case eta_abs t of
t' as f $ u =>
(case eta_abs u of
Bound 0 =>
if not (0 mem loose_bnos f) then incr_boundvars ~1 f
else Abs (a, T, t')
| _ => Abs (a, T, t'))
| t' => Abs (a, T, t'))
| eta_abs t = t;
in
if ! eta_contract then eta_abs tm else tm
end;
fun abs_tr' tm =
foldr (fn (x, t) => const "_abs" $ x $ t)
(strip_abss strip_abs_vars strip_abs_body (eta_contr tm));
fun abs_ast_tr' (*"_abs"*) asts =
(case unfold_ast_p "_abs" (Appl (Constant "_abs" :: asts)) of
([], _) => raise_ast "abs_ast_tr'" asts
| (xs, body) => Appl [Constant "_lambda", fold_ast "_idts" xs, body]);
(* binder *)
fun mk_binder_tr' (name, sy) =
let
fun mk_idts [] = raise Match (*abort translation*)
| mk_idts [idt] = idt
| mk_idts (idt :: idts) = const "_idts" $ idt $ mk_idts idts;
fun tr' t =
let
val (xs, bd) = strip_abss (strip_qnt_vars name) (strip_qnt_body name) t;
in
const sy $ mk_idts xs $ bd
end;
fun binder_tr' (*name*) (t :: ts) =
list_comb (tr' (const name $ t), ts)
| binder_tr' (*name*) [] = raise Match;
in
(name, binder_tr')
end;
(* idts *)
fun idts_ast_tr' (*"_idts"*) [Appl [Constant c, x, ty], xs] =
if c = constrainC then
Appl [Constant "_idts", Appl [Constant "_idtyp", x, ty], xs]
else raise Match
| idts_ast_tr' (*"_idts"*) _ = raise Match;
(* meta propositions *)
fun prop_tr' show_sorts tm =
let
fun aprop t = const "_aprop" $ t;
fun is_prop tys t =
fastype_of1 (tys, t) = propT handle TERM _ => false;
fun tr' _ (t as Const _) = t
| tr' _ (t as Free (x, ty)) =
if ty = propT then aprop (Free (x, dummyT)) else t
| tr' _ (t as Var (xi, ty)) =
if ty = propT then aprop (Var (xi, dummyT)) else t
| tr' tys (t as Bound _) =
if is_prop tys t then aprop t else t
| tr' tys (Abs (x, ty, t)) = Abs (x, ty, tr' (ty :: tys) t)
| tr' tys (t as t1 $ (t2 as Const ("TYPE", Type ("itself", [ty])))) =
if is_prop tys t then
const "_ofclass" $ term_of_typ show_sorts ty $ tr' tys t1
else tr' tys t1 $ tr' tys t2
| tr' tys (t as t1 $ t2) =
(if is_Const (head_of t) orelse not (is_prop tys t)
then I else aprop) (tr' tys t1 $ tr' tys t2);
in
tr' [] tm
end;
(* meta implication *)
fun impl_ast_tr' (*"==>"*) asts =
(case unfold_ast_p "==>" (Appl (Constant "==>" :: asts)) of
(asms as _ :: _ :: _, concl)
=> Appl [Constant "_bigimpl", fold_ast "_asms" asms, concl]
| _ => raise Match);
(* dependent / nondependent quantifiers *)
fun dependent_tr' (q, r) (A :: Abs (x, T, B) :: ts) =
if 0 mem (loose_bnos B) then
let val (x', B') = variant_abs (x, dummyT, B);
in list_comb (const q $ Free (x', T) $ A $ B', ts) end
else list_comb (const r $ A $ B, ts)
| dependent_tr' _ _ = raise Match;
(* implode atoms *)
fun implode_ast_tr' (*"_implode"*) (asts as [Constant cons_name, nilC,
bit0, bit1, bitss]) =
let
fun err () = raise_ast "implode_ast_tr'" asts;
fun strip_list lst =
let val (xs, y) = unfold_ast_p cons_name lst
in if y = nilC then xs else err ()
end;
fun decode_bit bit =
if bit = bit0 then "0"
else if bit = bit1 then "1"
else err ();
fun decode_char bits =
chr (#1 (scan_radixint (2, map decode_bit (strip_list bits))));
in
Variable (implode (map decode_char (strip_list bitss)))
end
| implode_ast_tr' (*"_implode"*) asts = raise_ast "implode_ast_tr'" asts;
(** syn_ext_of_sext **) (* FIXME remove *)
fun strip_esc str =
let
fun strip ("'" :: c :: cs) = c :: strip cs
| strip ["'"] = []
| strip (c :: cs) = c :: strip cs
| strip [] = [];
in
implode (strip (explode str))
end;
fun infix_name sy = "op " ^ strip_esc sy;
fun syn_ext_of_sext all_roots new_roots xconsts read_typ sext =
let
val {mixfix, parse_ast_translation, parse_translation, print_translation,
print_ast_translation, ...} = sext_components sext;
val tinfixT = [typeT, typeT] ---> typeT;
fun binder (Binder (sy, _, name, _, _)) = Some (sy, name)
| binder _ = None;
fun binder_typ ty =
(case read_typ ty of
Type ("fun", [Type ("fun", [_, T2]), T3]) =>
[Type ("idts", []), T2] ---> T3
| _ => error ("Illegal binder type " ^ quote ty));
fun mk_infix sy ty c p1 p2 p3 =
[Mfix ("(_ " ^ sy ^ "/ _)", ty, c, [p1, p2], p3),
Mfix ("op " ^ sy, ty, c, [], max_pri)];
fun mfix_of (Mixfix (sy, ty, c, ps, p)) = [Mfix (sy, read_typ ty, c, ps, p)]
| mfix_of (Delimfix (sy, ty, c)) = [Mfix (sy, read_typ ty, c, [], max_pri)]
| mfix_of (Infixl (sy, ty, p)) =
mk_infix sy (read_typ ty) (infix_name sy) p (p + 1) p
| mfix_of (Infixr (sy, ty, p)) =
mk_infix sy (read_typ ty) (infix_name sy) (p + 1) p p
| mfix_of (Binder (sy, ty, _, p, q)) =
[Mfix ("(3" ^ sy ^ "_./ _)", binder_typ ty, sy, [0, p], q)]
| mfix_of (TInfixl (s, c, p)) =
[Mfix ("(_ " ^ s ^ "/ _)", tinfixT, c, [p, p + 1], p)]
| mfix_of (TInfixr (s, c, p)) =
[Mfix ("(_ " ^ s ^ "/ _)", tinfixT, c, [p + 1, p], p)];
val mfix = flat (map mfix_of mixfix);
val binders = mapfilter binder mixfix;
val bparses = map mk_binder_tr binders;
val bprints = map (mk_binder_tr' o swap) binders;
in
syn_ext all_roots new_roots mfix (distinct (filter is_xid xconsts))
(parse_ast_translation,
bparses @ parse_translation,
bprints @ print_translation,
print_ast_translation)
([], [])
end;
(** constants **) (* FIXME remove *)
fun constants sext =
let
fun consts (Delimfix (_, ty, c)) = ([c], ty)
| consts (Mixfix (_, ty, c, _, _)) = ([c], ty)
| consts (Infixl (c, ty, _)) = ([infix_name c], ty)
| consts (Infixr (c, ty, _)) = ([infix_name c], ty)
| consts (Binder (_, ty, c, _, _)) = ([c], ty)
| consts _ = ([""], ""); (*is filtered out below*)
in
distinct (filter_out (fn (l, _) => l = [""]) (map consts (mixfix_of sext)))
end;
(** pt_to_ast **)
fun pt_to_ast trf pt =
let
fun trans a args =
(case trf a of
None => mk_appl (Constant a) args
| Some f => f args handle exn
=> (writeln ("Error in parse ast translation for " ^ quote a); raise exn));
fun ast_of (Node (a, pts)) = trans a (map ast_of pts)
| ast_of (Tip tok) = Variable (str_of_token tok);
in
ast_of pt
end;
(** ast_to_term **)
fun ast_to_term trf ast =
let
fun trans a args =
(case trf a of
None => list_comb (const a, args)
| Some f => f args handle exn
=> (writeln ("Error in parse translation for " ^ quote a); raise exn));
fun term_of (Constant a) = trans a []
| term_of (Variable x) = scan_var x
| term_of (Appl (Constant a :: (asts as _ :: _))) =
trans a (map term_of asts)
| term_of (Appl (ast :: (asts as _ :: _))) =
list_comb (term_of ast, map term_of asts)
| term_of (ast as Appl _) = raise_ast "ast_to_term: malformed ast" [ast];
in
term_of ast
end;
(** pure_trfuns **)
val pure_trfuns =
([(applC, appl_ast_tr), ("_lambda", lambda_ast_tr), ("_idtyp", idtyp_ast_tr),
("_bigimpl", bigimpl_ast_tr)],
[("_abs", abs_tr), ("_aprop", aprop_tr), ("_ofclass", ofclass_tr),
("_K", k_tr), ("_explode", explode_tr)],
[],
[("_abs", abs_ast_tr'), ("_idts", idts_ast_tr'), ("==>", impl_ast_tr'),
("_implode", implode_ast_tr')]);
val constrainAbsC = "_constrainAbs";
(** the Pure syntax **) (* FIXME remove *)
val pure_sext =
NewSext {
mixfix = [
Mixfix ("(3%_./ _)", "[idts, 'a] => ('b => 'a)", "_lambda", [0], 0),
Delimfix ("_", "'a => " ^ args, ""),
Delimfix ("_,/ _", "['a, " ^ args ^ "] => " ^ args, "_args"),
Delimfix ("_", "id => idt", ""),
Mixfix ("_::_", "[id, type] => idt", "_idtyp", [0, 0], 0),
Delimfix ("'(_')", "idt => idt", ""),
Delimfix ("_", "idt => idts", ""),
Mixfix ("_/ _", "[idt, idts] => idts", "_idts", [1, 0], 0),
Delimfix ("_", "id => aprop", ""),
Delimfix ("_", "var => aprop", ""),
Mixfix ("(1_/(1'(_')))", "[('b => 'a), " ^ args ^ "] => aprop", applC, [max_pri, 0], max_pri),
Delimfix ("PROP _", "aprop => prop", "_aprop"),
Delimfix ("_", "prop => asms", ""),
Delimfix ("_;/ _", "[prop, asms] => asms", "_asms"),
Mixfix ("((3[| _ |]) ==>/ _)", "[asms, prop] => prop", "_bigimpl", [0, 1], 1),
Mixfix ("(_ ==/ _)", "['a::{}, 'a] => prop", "==", [3, 2], 2),
Mixfix ("(_ =?=/ _)", "['a::{}, 'a] => prop", "=?=", [3, 2], 2),
Mixfix ("(_ ==>/ _)", "[prop, prop] => prop", "==>", [2, 1], 1),
Binder ("!!", "('a::logic => prop) => prop", "all", 0, 0)],
xrules = [],
parse_ast_translation = [(applC, appl_ast_tr), ("_lambda", lambda_ast_tr),
("_idtyp", idtyp_ast_tr), ("_bigimpl", bigimpl_ast_tr)],
parse_translation = [("_abs", abs_tr), ("_aprop", aprop_tr), ("_K", k_tr),
("_explode", explode_tr)],
print_translation = [],
print_ast_translation = [("_abs", abs_ast_tr'), ("_idts", idts_ast_tr'),
("==>", impl_ast_tr'), ("_implode", implode_ast_tr')]};
val syntax_types = terminals @ ["syntax", logic, "type", "types", "sort",
"classes", args, "idt", "idts", "aprop", "asms"];
val syntax_consts = [(["_K", "_explode", "_implode"], "syntax")];
end;