module C = Cps
module S = Share
module L = Log
+module Y = Entity
module P = Output
module B = Brg
module O = BrgOutput
module E = BrgEnvironment
-exception TypeError of B.message
-
-type machine = {
- c: B.context;
- s: (B.context * B.term) list;
+type kam = {
+ c: B.lenv;
+ s: (B.lenv * B.term) list;
i: int
}
let level = 5
let log1 s c t =
- let sc, st = s ^ " in the context", "the term" in
- L.log O.specs level (L.ct_items1 sc c st t)
+ let sc, st = s ^ " in the environment", "the term" in
+ L.log O.specs level (L.et_items1 sc c st t)
let log2 s cu u ct t =
- let s1, s2, s3 = s ^ " in the context", "the term", "and in the context" in
- L.log O.specs level (L.ct_items2 s1 cu s2 u s3 ct s2 t)
-
-let error0 i =
- let s = Printf.sprintf "local reference not found %u" i in
- raise (TypeError (L.items1 s))
-
-let error1 st c t =
- let sc = "In the context" in
- raise (TypeError (L.ct_items1 sc c st t))
-
-let error3 c t1 t2 t3 =
- let sc, st1, st2, st3 =
- "In the context", "the term", "is of type", "but must be of type"
- in
- raise (TypeError (L.ct_items3 sc c st1 t1 st2 t2 st3 t3))
+ let s1, s2, s3 = s ^ " in the environment", "the term", "and in the environment" in
+ L.log O.specs level (L.et_items2 s1 cu s2 u ~sc2:s3 ~c2:ct s2 t)
-let are_alpha_convertible f t1 t2 =
+let are_alpha_convertible err f t1 t2 =
let rec aux f = function
| B.Sort (_, p1), B.Sort (_, p2)
- | B.LRef (_, p1), B.LRef (_, p2) -> f (p1 = p2)
- | B.GRef (_, u1), B.GRef (_, u2) -> f (U.eq u1 u2)
+ | B.LRef (_, p1), B.LRef (_, p2) ->
+ if p1 = p2 then f () else err ()
+ | B.GRef (_, u1), B.GRef (_, u2) ->
+ if U.eq u1 u2 then f () else err ()
| B.Cast (_, v1, t1), B.Cast (_, v2, t2)
| B.Appl (_, v1, t1), B.Appl (_, v2, t2) ->
- let f r = if r then aux f (t1, t2) else f r in
+ let f _ = aux f (t1, t2) in
aux f (v1, v2)
- | B.Bind (_, b1, t1), B.Bind (_, b2, t2) ->
- let f r = if r then aux f (t1, t2) else f r in
+ | B.Bind (b1, t1), B.Bind (b2, t2) ->
+ let f _ = aux f (t1, t2) in
aux_bind f (b1, b2)
- | B.Sort _ as t1, B.Bind (_, _, t2) -> aux f (t1, t2)
- | _ -> f false
+ | _ -> err ()
and aux_bind f = function
- | B.Abbr v1, B.Abbr v2
- | B.Abst v1, B.Abst v2 -> aux f (v1, v2)
- | B.Void, B.Void -> f true
- | _ -> f false
+ | B.Abbr (_, v1), B.Abbr (_, v2)
+ | B.Abst (_, v1), B.Abst (_, v2) -> aux f (v1, v2)
+ | B.Void _, B.Void _ -> f ()
+ | _ -> err ()
in
- if S.eq t1 t2 then f true else aux f (t1, t2)
+ if S.eq t1 t2 then f () else aux f (t1, t2)
-let get f m i =
- B.get error0 f m.c i
+let get err f m i =
+ B.get err f m.c i
(* to share *)
let rec step f ?(delta=false) ?(rt=false) m x =
(* L.warn "entering R.step"; *)
match x with
- | B.Sort _ -> f m None x
- | B.GRef (a, uri) ->
+ | B.Sort _ -> f m None x
+ | B.GRef (_, uri) ->
let f = function
- | _, _, B.Abbr v when delta ->
- P.add ~gdelta:1 ();
- step f ~delta ~rt m v
- | _, _, B.Abst w when rt ->
- P.add ~grt:1 ();
- step f ~delta ~rt m w
- | e, _, b ->
- f m (Some (e, b)) x
+ | _, _, Y.Abbr v when delta ->
+ P.add ~gdelta:1 (); step f ~delta ~rt m v
+ | _, _, Y.Abst w when rt ->
+ P.add ~grt:1 (); step f ~delta ~rt m w
+ | a, _, Y.Abbr v ->
+ let f e = f m (Some (e, B.Abbr (a, v))) x in
+ Y.apix C.err f a
+ | a, _, Y.Abst w ->
+ let f e = f m (Some (e, B.Abst (a, w))) x in
+ Y.apix C.err f a
in
- E.get_obj f uri
- | B.LRef (a, i) ->
- let f c a = function
- | B.Abbr v ->
+ E.get_entity C.err f uri
+ | B.LRef (_, i) ->
+ let f c = function
+ | B.Abbr (_, v) ->
P.add ~ldelta:1 ();
step f ~delta ~rt {m with c = c} v
- | B.Abst w when rt ->
+ | B.Abst (_, w) when rt ->
P.add ~lrt:1 ();
step f ~delta ~rt {m with c = c} w
- | B.Void ->
- f {m with c = c} None x
- | b ->
+ | B.Void _ ->
+ assert false
+ | B.Abst (a, _) as b ->
let f e = f {m with c = c} (Some (e, b)) x in
- B.apix C.err f a
+ Y.apix C.err f a
in
- get f m i
- | B.Cast (_, _, t) ->
+ get C.err f m i
+ | B.Cast (_, _, t) ->
P.add ~tau:1 ();
step f ~delta ~rt m t
- | B.Appl (_, v, t) ->
+ | B.Appl (_, v, t) ->
step f ~delta ~rt {m with s = (m.c, v) :: m.s} t
- | B.Bind (a, B.Abst w, t) ->
+ | B.Bind (B.Abst (a, w), t) ->
begin match m.s with
| [] -> f m None x
| (c, v) :: s ->
P.add ~beta:1 ~upsilon:(List.length s) ();
let f c = step f ~delta ~rt {m with c = c; s = s} t in
- B.push f m.c ~c a (B.Abbr v) (* (B.Cast ([], w, v)) *)
+ B.push f m.c ~c (B.abbr a v) (* (B.Cast ([], w, v)) *)
end
- | B.Bind (a, b, t) ->
+ | B.Bind (b, t) ->
P.add ~upsilon:(List.length m.s) ();
let f c = step f ~delta ~rt {m with c = c} t in
- B.push f m.c ~c:m.c a b
-
-let domain f m t =
- let f r = L.unbox level; f r in
- let f m _ = function
- | B.Bind (_, B.Abst w, _) -> f m w
- | _ -> error1 "not a function" m.c t
- in
- L.box level; log1 "Now scanning" m.c t;
- step f ~delta:true ~rt:true m t
+ B.push f m.c ~c:m.c b
-let push f m a b =
+let push f m b =
assert (m.s = []);
- let a, i = match b with
- | B.Abst _ -> B.Apix m.i :: a, succ m.i
- | _ -> a, m.i
+ let b, i = match b with
+ | B.Abst (a, w) -> B.abst (Y.Apix m.i :: a) w, succ m.i
+ | b -> b, m.i
in
let f c = f {m with c = c; i = i} in
- B.push f m.c ~c:m.c a b
+ B.push f m.c ~c:m.c b
-let rec ac_nfs f ~si r m1 a1 u m2 a2 t =
+let rec ac_nfs err f ~si m1 a1 u m2 a2 t =
log2 "Now converting nfs" m1.c u m2.c t;
match a1, u, a2, t with
- | _, B.Sort (_, h1),
- _, B.Sort (_, h2) ->
- if h1 = h2 then f r else f false
- | Some (e1, B.Abst _), _, Some (e2, B.Abst _), _ ->
- if e1 = e2 then ac_stacks f ~si r m1 m2 else f false
- | Some (e1, B.Abbr v1), _, Some (e2, B.Abbr v2), _ ->
+ | _, B.Sort (_, h1), _, B.Sort (_, h2) ->
+ if h1 = h2 then f () else err ()
+ | Some (e1, B.Abst _), _, Some (e2, B.Abst _), _ ->
+ if e1 = e2 then ac_stacks err f m1 m2 else err ()
+ | Some (e1, B.Abbr (_, v1)), _, Some (e2, B.Abbr (_, v2)), _ ->
if e1 = e2 then
- let f r =
- if r then f r
- else begin
- P.add ~gdelta:2 ();
- ac f ~si true m1 v1 m2 v2
- end
- in
- ac_stacks f ~si r m1 m2
+ let err _ = P.add ~gdelta:2 (); ac err f ~si m1 v1 m2 v2 in
+ ac_stacks err f m1 m2
else if e1 < e2 then begin
P.add ~gdelta:1 ();
- step (ac_nfs f ~si r m1 a1 u) m2 v2
+ step (ac_nfs err f ~si m1 a1 u) m2 v2
end else begin
P.add ~gdelta:1 ();
- step (ac_nfs_rev f ~si r m2 a2 t) m1 v1
+ step (ac_nfs_rev err f ~si m2 a2 t) m1 v1
end
- | _, _, Some (_, B.Abbr v2), _ ->
+ | _, _, Some (_, B.Abbr (_, v2)), _ ->
P.add ~gdelta:1 ();
- step (ac_nfs f ~si r m1 a1 u) m2 v2
- | Some (_, B.Abbr v1), _, _, _ ->
+ step (ac_nfs err f ~si m1 a1 u) m2 v2
+ | Some (_, B.Abbr (_, v1)), _, _, _ ->
P.add ~gdelta:1 ();
- step (ac_nfs_rev f ~si r m2 a2 t) m1 v1
- | _, B.Bind (a1, (B.Abst w1 as b1), t1),
- _, B.Bind (a2, (B.Abst w2 as b2), t2) ->
- let g m1 m2 = ac f ~si r m1 t1 m2 t2 in
- let g m1 = push (g m1) m2 a2 b2 in
- let f r = if r then push g m1 a1 b1 else f false in
- ac f ~si r m1 w1 m2 w2
- | _, B.Sort _, _, B.Bind (a, b, t) when si ->
+ step (ac_nfs_rev err f ~si m2 a2 t) m1 v1
+ | _, B.Bind ((B.Abst (_, w1) as b1), t1),
+ _, B.Bind ((B.Abst (_, w2) as b2), t2) ->
+ let f m1 m2 = ac err f ~si m1 t1 m2 t2 in
+ let f m1 = push (f m1) m2 b2 in
+ let f _ = push f m1 b1 in
+ ac err f ~si:false m1 w1 m2 w2
+ | _, B.Sort _, _, B.Bind (b, t) when si ->
P.add ~si:1 ();
- let f m1 m2 = ac f ~si r m1 u m2 t in
- let f m1 = push (f m1) m2 a b in
- push f m1 a b
- | _ -> f false
+ let f m1 m2 = ac err f ~si m1 u m2 t in
+ let f m1 = push (f m1) m2 b in
+ push f m1 b
+ | _ -> err ()
-and ac_nfs_rev f ~si r m2 a2 t m1 a1 u = ac_nfs f ~si r m1 a1 u m2 a2 t
+and ac_nfs_rev err f ~si m2 a2 t m1 a1 u = ac_nfs err f ~si m1 a1 u m2 a2 t
-and ac f ~si r m1 t1 m2 t2 =
+and ac err f ~si m1 t1 m2 t2 =
(* L.warn "entering R.are_convertible"; *)
- let g m1 a1 t1 = step (ac_nfs f ~si r m1 a1 t1) m2 t2 in
- if r = false then f false else step g m1 t1
+ let f m1 a1 t1 = step (ac_nfs err f ~si m1 a1 t1) m2 t2 in
+ step f m1 t1
-and ac_stacks f ~si r m1 m2 =
+and ac_stacks err f m1 m2 =
(* L.warn "entering R.are_convertible_stacks"; *)
- if List.length m1.s <> List.length m2.s then f false else
- let map f r (c1, v1) (c2, v2) =
+ if List.length m1.s <> List.length m2.s then err () else
+ let map f (c1, v1) (c2, v2) =
let m1, m2 = {m1 with c = c1; s = []}, {m2 with c = c2; s = []} in
- ac f ~si r m1 v1 m2 v2
+ ac err f ~si:false m1 v1 m2 v2
in
- C.list_fold_left2 f map r m1.s m2.s
+ C.list_iter2 f map m1.s m2.s
(* Interface functions ******************************************************)
-let empty_machine = {
- c = B.empty_context; s = []; i = 0
+let empty_kam = {
+ c = B.empty_lenv; s = []; i = 0
}
-let get f m i =
+let get err f m i =
assert (m.s = []);
let f c = f in
- get f m i
+ get err f m i
-let assert_conversion f ?(si=false) ?(rt=false) mw u w v =
- let f mu u =
+let xwhd f m t =
+ L.box level; log1 "Now scanning" m.c t;
+ let f m _ t = L.unbox level; f m t in
+ step f ~delta:true ~rt:true m t
+
+let are_convertible err f ?(si=false) mu u mw w =
L.box level; log2 "Now converting" mu.c u mw.c w;
- let f r =
- if r then begin L.unbox level; f () end else error3 mw.c v w u
- in
- let g r = if r then f r else ac f ~si true mu u mw w in
- if S.eq mu mw then are_alpha_convertible g u w else g false
- in
- if rt then domain f mw u else f mw u
+ let f x = L.unbox level; f x in
+ let err _ = ac err f ~si mu u mw w in
+(* if S.eq mu mw then are_alpha_convertible err f u w else *) err ()
-let message1 st m t =
- L.ct_items1 "In the context" m.c st t
+(* error reporting **********************************************************)
+
+let pp_term m frm t = O.specs.L.pp_term m.c frm t
+
+let pp_lenv frm m = O.specs.L.pp_lenv frm m.c
+
+let specs = {
+ L.pp_term = pp_term; L.pp_lenv = pp_lenv
+}