make use of show_type_emphasis instead of using hack; make sure global configurations don't affect proof script creation
(* Title: HOL/Tools/Sledgehammer/sledgehammer_annotate.ML
Author: Jasmin Blanchette, TU Muenchen
Author: Steffen Juilf Smolka, TU Muenchen
Supplement term with explicit type constraints that show up as
type annotations when printing the term.
*)
signature SLEDGEHAMMER_ANNOTATE =
sig
val annotate_types : Proof.context -> term -> term
end
structure Sledgehammer_Annotate : SLEDGEHAMMER_ANNOTATE =
struct
(* Util *)
fun post_traverse_term_type' f _ (t as Const (_, T)) s = f t T s
| post_traverse_term_type' f _ (t as Free (_, T)) s = f t T s
| post_traverse_term_type' f _ (t as Var (_, T)) s = f t T s
| post_traverse_term_type' f env (t as Bound i) s = f t (nth env i) s
| post_traverse_term_type' f env (Abs (x, T1, b)) s =
let
val ((b', s'), T2) = post_traverse_term_type' f (T1 :: env) b s
in f (Abs (x, T1, b')) (T1 --> T2) s' end
| post_traverse_term_type' f env (u $ v) s =
let
val ((u', s'), Type (_, [_, T])) = post_traverse_term_type' f env u s
val ((v', s''), _) = post_traverse_term_type' f env v s'
in f (u' $ v') T s'' end
fun post_traverse_term_type f s t =
post_traverse_term_type' (fn t => fn T => fn s => (f t T s, T)) [] t s |> fst
fun post_fold_term_type f s t =
post_traverse_term_type (fn t => fn T => fn s => (t, f t T s)) s t |> snd
(* Data structures, orders *)
val cost_ord = prod_ord int_ord (prod_ord int_ord int_ord)
structure Var_Set_Tab = Table(
type key = indexname list
val ord = list_ord Term_Ord.fast_indexname_ord)
(* (1) Generalize types *)
fun generalize_types ctxt t =
t |> map_types (fn _ => dummyT)
|> Syntax.check_term
(Proof_Context.set_mode Proof_Context.mode_pattern ctxt)
(* (2) Typing-spot table *)
local
fun key_of_atype (TVar (z, _)) =
Ord_List.insert Term_Ord.fast_indexname_ord z
| key_of_atype _ = I
fun key_of_type T = fold_atyps key_of_atype T []
fun update_tab t T (tab, pos) =
(case key_of_type T of
[] => tab
| key =>
let val cost = (size_of_typ T, (size_of_term t, pos)) in
case Var_Set_Tab.lookup tab key of
NONE => Var_Set_Tab.update_new (key, cost) tab
| SOME old_cost =>
(case cost_ord (cost, old_cost) of
LESS => Var_Set_Tab.update (key, cost) tab
| _ => tab)
end,
pos + 1)
in
val typing_spot_table =
post_fold_term_type update_tab (Var_Set_Tab.empty, 0) #> fst
end
(* (3) Reverse-greedy *)
fun reverse_greedy typing_spot_tab =
let
fun update_count z =
fold (fn tvar => fn tab =>
let val c = Vartab.lookup tab tvar |> the_default 0 in
Vartab.update (tvar, c + z) tab
end)
fun superfluous tcount =
forall (fn tvar => the (Vartab.lookup tcount tvar) > 1)
fun drop_superfluous (tvars, (_, (_, spot))) (spots, tcount) =
if superfluous tcount tvars then (spots, update_count ~1 tvars tcount)
else (spot :: spots, tcount)
val (typing_spots, tvar_count_tab) =
Var_Set_Tab.fold
(fn kv as (k, _) => apfst (cons kv) #> apsnd (update_count 1 k))
typing_spot_tab ([], Vartab.empty)
|>> sort_distinct (rev_order o cost_ord o pairself snd)
in fold drop_superfluous typing_spots ([], tvar_count_tab) |> fst end
(* (4) Introduce annotations *)
fun introduce_annotations ctxt spots t t' =
let
val thy = Proof_Context.theory_of ctxt
val get_types = post_fold_term_type (K cons) []
fun match_types tp =
fold (Sign.typ_match thy) (op ~~ (pairself get_types tp)) Vartab.empty
fun unica' b x [] = if b then [x] else []
| unica' b x (y :: ys) =
if x = y then unica' false x ys
else unica' true y ys |> b ? cons x
fun unica ord xs =
case sort ord xs of x :: ys => unica' true x ys | [] => []
val add_all_tfree_namesT = fold_atyps (fn TFree (x, _) => cons x | _ => I)
fun erase_unica_tfrees env =
let
val unica =
Vartab.fold (add_all_tfree_namesT o snd o snd) env []
|> filter_out (Variable.is_declared ctxt)
|> unica fast_string_ord
val erase_unica = map_atyps
(fn T as TFree (s, _) =>
if Ord_List.member fast_string_ord unica s then dummyT else T
| T => T)
in Vartab.map (K (apsnd erase_unica)) env end
val env = match_types (t', t) |> erase_unica_tfrees
fun get_annot env (TFree _) = (false, (env, dummyT))
| get_annot env (T as TVar (v, S)) =
let val T' = Envir.subst_type env T in
if T' = dummyT then (false, (env, dummyT))
else (true, (Vartab.update (v, (S, dummyT)) env, T'))
end
| get_annot env (Type (S, Ts)) =
(case fold_rev (fn T => fn (b, (env, Ts)) =>
let
val (b', (env', T)) = get_annot env T
in (b orelse b', (env', T :: Ts)) end)
Ts (false, (env, [])) of
(true, (env', Ts)) => (true, (env', Type (S, Ts)))
| (false, (env', _)) => (false, (env', dummyT)))
fun post1 _ T (env, cp, ps as p :: ps', annots) =
if p <> cp then
(env, cp + 1, ps, annots)
else
let val (annot_necessary, (env', T')) = get_annot env T in
(env', cp + 1, ps', annots |> annot_necessary ? cons (p, T'))
end
| post1 _ _ accum = accum
val (_, _, _, annots) = post_fold_term_type post1 (env, 0, spots, []) t'
fun post2 t _ (cp, annots as (p, T) :: annots') =
if p <> cp then (t, (cp + 1, annots))
else (Type.constraint T t, (cp + 1, annots'))
| post2 t _ x = (t, x)
in
t |> post_traverse_term_type post2 (0, rev annots)
|> fst
end
(* (5) Annotate *)
fun annotate_types ctxt t =
let
val t' = generalize_types ctxt t
val typing_spots =
t' |> typing_spot_table
|> reverse_greedy
|> sort int_ord
in introduce_annotations ctxt typing_spots t t' end
end