\ / This software is distributed as is, NO WARRANTY.
V_______________________________________________________________ *)
+module KF = Filename
module KP = Printf
module U = NUri
uris = []; nodes = 0; xnodes = 0
}
+IFDEF SUMMARY THEN
+
let rec count_term_binder f c e = function
| B.Abst (_, _, w) ->
let c = {c with tabsts = succ c.tabsts; nodes = succ c.nodes} in
f c
and count_term f c e = function
- | B.Sort _ ->
+ | B.Sort _ ->
f {c with tsorts = succ c.tsorts; nodes = succ c.nodes}
- | B.LRef (_, i) ->
+ | B.LRef (_, i) ->
begin match B.get e i with
- | _, _, _, B.Abst _
- | _, _, _, B.Void ->
+ | _, _, _, _, B.Abst _
+ | _, _, _, _, B.Void ->
f {c with tlrefs = succ c.tlrefs; nodes = succ c.nodes}
- | _, _, _, B.Abbr _ ->
+ | _, _, _, _, B.Abbr _ ->
f {c with tlrefs = succ c.tlrefs; xnodes = succ c.xnodes}
end
| B.GRef (_, u) ->
else {c with xnodes = succ c.xnodes}
in
f {c with tgrefs = succ c.tgrefs}
- | B.Cast (_, v, t) ->
+ | B.Cast (v, t) ->
let c = {c with tcasts = succ c.tcasts} in
let f c = count_term f c e t in
count_term f c e v
let c = {c with tappls = succ c.tappls; nodes = succ c.nodes} in
let f c = count_term f c e t in
count_term f c e v
- | B.Bind (a, b, t) ->
- let f c = count_term f c (B.push e B.empty a b) t in
+ | B.Bind (y, b, t) ->
+ let f c = count_term f c (B.push e B.empty E.empty_node y b) t in
count_term_binder f c e b
let count_entity f c = function
- | _, _, u, E.Abst w ->
+ | _, _, u, E.Abst (_, w) ->
let c = {c with
eabsts = succ c.eabsts; nodes = succ c.nodes; uris = u :: c.uris
} in
count_term f c B.empty w
- | _, _, _, E.Abbr v ->
+ | _, _, _, E.Abbr (_, v) ->
let c = {c with eabbrs = succ c.eabbrs; xnodes = succ c.xnodes} in
count_term f c B.empty v
- | _, _, _, E.Void -> assert false
+ | _, _, _, E.Void -> assert false
let print_counters f c =
let terms =
- c.tsorts + c.tgrefs + c.tgrefs + c.tcasts + c.tappls + c.tabsts +
+ c.tsorts + c.tlrefs + c.tgrefs + c.tcasts + c.tappls + c.tabsts +
c.tabbrs
in
let items = c.eabsts + c.eabbrs in
L.warn level (KP.sprintf " + Abbreviation nodes: %7u" nodes);
f ()
+END
+
(* lenv/term pretty printing ************************************************)
let name err och a =
KP.fprintf och "%s" (N.to_string st n)
let rec pp_term st e och = function
- | B.Sort (_, h) ->
- let err _ = KP.fprintf och "*%u" h in
+ | B.Sort k ->
+ let err _ = KP.fprintf och "*%u" k in
let f s = KP.fprintf och "%s" s in
- H.string_of_sort err f h
+ H.string_of_sort err f k
| B.LRef (_, i) ->
let err _ = KP.fprintf och "#%u" i in
if !G.indexes then err () else
- let _, _, a, b = B.get e i in
- KP.fprintf och "%a" (name err) a
+ let _, _, _, y, b = B.get e i in
+ KP.fprintf och "%a" (name err) y
| B.GRef (_, s) ->
- KP.fprintf och "$%s" (U.string_of_uri s)
- | B.Cast (_, u, t) ->
- KP.fprintf och "{%a}.%a" (pp_term st e) u (pp_term st e) t
+ let u = U.string_of_uri s in
+ KP.fprintf och "$%s" (if !G.short then KF.basename u else u)
+ | B.Cast (u, t) ->
+ KP.fprintf och "<%a>.%a" (pp_term st e) u (pp_term st e) t
| B.Appl (_, v, t) ->
KP.fprintf och "(%a).%a" (pp_term st e) v (pp_term st e) t
- | B.Bind (a, B.Abst (x, n, w), t) ->
- let a = R.alpha B.mem e a in
- let ee = B.push e B.empty a (B.abst x n w) in
- KP.fprintf och "%a%a[%a:%a].%a" (pp_level st) n pp_reduced x (name C.start) a (pp_term st e) w (pp_term st ee) t
- | B.Bind (a, B.Abbr v, t) ->
- let a = R.alpha B.mem e a in
- let ee = B.push e B.empty a (B.abbr v) in
- KP.fprintf och "[%a=%a].%a" (name C.start) a (pp_term st e) v (pp_term st ee) t
- | B.Bind (a, B.Void, t) ->
- let a = R.alpha B.mem e a in
- let ee = B.push e B.empty a B.Void in
- KP.fprintf och "[%a].%a" (name C.start) a (pp_term st ee) t
+ | B.Bind (y, B.Abst (r, n, w), t) ->
+ let y = R.alpha B.mem e y in
+ let ee = B.push e B.empty E.empty_node y (B.abst r n w) in
+ KP.fprintf och "%a%a[%a:%a].%a" (pp_level st) n pp_reduced r (name C.start) y (pp_term st e) w (pp_term st ee) t
+ | B.Bind (y, B.Abbr v, t) ->
+ let y = R.alpha B.mem e y in
+ let ee = B.push e B.empty E.empty_node y (B.abbr v) in
+ KP.fprintf och "[%a=%a].%a" (name C.start) y (pp_term st e) v (pp_term st ee) t
+ | B.Bind (y, B.Void, t) ->
+ let y = R.alpha B.mem e y in
+ let ee = B.push e B.empty E.empty_node y B.Void in
+ KP.fprintf och "[%a].%a" (name C.start) y (pp_term st ee) t
let pp_lenv st och e =
- let pp_entry f e c a b x = f x (* match b with
- | B.Abst (a, w) ->
- let a = R.alpha B.mem e a in
- KP.fprintf och "%a : %a\n" (name C.start) a (pp_term st e) w; f a
- | B.Abbr (a, v) ->
- let a = R.alpha B.mem e a in
- KP.fprintf och "%a = %a\n" (name C.start) a (pp_term st e) v; f a
- | B.Void a ->
- let a = R.alpha B.mem e a in
- KP.fprintf och "%a\n" (name C.start) a; f a
-*) in
- let e = B.empty in
- if e = B.empty then KP.fprintf och "%s\n" "not shown" else
+ let pp_entry f c a y b x =
+ let y = R.alpha B.mem e y in
+ let x = B.push x c a y b in
+ match b with
+ | B.Abst (_, _, w) ->
+ KP.fprintf och "[%a : %a] " (name C.start) y (pp_term st c) w; f x
+ | B.Abbr v ->
+ KP.fprintf och "[%a = %a] " (name C.start) y (pp_term st c) v; f x
+ | B.Void ->
+ KP.fprintf och "[%a]" (name C.start) y; f x
+ in
+ if e = B.empty then KP.fprintf och "%s" "empty" else
B.fold_right ignore pp_entry e B.empty
let specs = {
L.pp_term = pp_term; L.pp_lenv = pp_lenv
}
+IFDEF OBJECTS THEN
+
(* term xml printing ********************************************************)
let export_term st =
BD.crg_of_brg (XD.export_term st)
+
+END