brg: change in the representation of binders

[helm.git] / helm / software / lambda-delta / basic_rg / brgType.ml

diff --git a/helm/software/lambda-delta/basic_rg/brgType.ml b/helm/software/lambda-delta/basic_rg/brgType.ml
index bf067864714dea8c3127c2b4c07bdccd1b75b451..79949a3a745753596a391a32f05f5c07f7ebde4e 100644 (file)
--- a/helm/software/lambda-delta/basic_rg/brgType.ml
+++ b/helm/software/lambda-delta/basic_rg/brgType.ml
@@ -14,89 +14,118 @@ module C = Cps
 module A = Share
 module L = Log
 module H = Hierarchy
+module Y = Entity
 module B = Brg
 module O = BrgOutput
 module E = BrgEnvironment
 module S = BrgSubstitution
 module R = BrgReduction
 
+type message = (R.kam, B.term) Log.message
+
 (* Internal functions *******************************************************)
 
 let level = 4
 
+let message1 st1 m t1 =
+   L.et_items1 "In the environment" m st1 t1
+
 let log1 s m t =
    let s =  s ^ " the term" in
-   L.log O.specs level (R.message1 s m t) 
+   L.log R.specs level (message1 s m t) 
 
-let error1 s m t =
-   raise (R.TypeError (R.message1 s m t))
+let error1 err s m t =
+   err (message1 s m t)
 
-(* Interface functions ******************************************************)
+let message3 m t1 t2 ?mu t3 =    
+   let sm, st1, st2 = "In the environment", "the term", "is of type" in
+   match mu with
+      | Some mu ->
+         let smu, st3 = "but in the environment", "it must be of type" in
+         L.et_items3 sm m st1 t1 st2 t2 ~sc3:smu ~c3:mu st3 t3
+      | None    ->
+         let st3 = "but it must be of type" in
+         L.et_items3 sm m st1 t1 st2 t2 st3 t3
+   
+let error3 err m t1 t2 ?mu t3 =
+   err (message3 m t1 t2 ?mu t3)
+
+let assert_convertibility err f st m u w v =
+   if R.are_convertible st m u m w then f () else
+   error3 err m v w u
+
+let assert_applicability err f st m u w v =
+   match R.xwhd st m u with 
+      | _, B.Sort _                 -> error1 err "not a function type" m u
+      | mu, B.Bind (_, B.Abst u, _) -> 
+         if R.are_convertible st mu u m w then f () else
+        error3 err m v w ~mu u
+      | _                         -> assert false (**)
 
-let rec b_type_of f ~si g m x =
+let rec b_type_of err f st g m x =
    log1 "Now checking" m x;
    match x with
    | B.Sort (a, h)           ->
       let f h = f x (B.Sort (a, h)) in H.apply f g h
    | B.LRef (_, i)           ->
-      let f _ = function
+      begin match R.get m i with
          | B.Abst w                  ->
-           S.lift (f x) (succ i) (0) w
+           f x (S.lift (succ i) (0) w)
         | B.Abbr (B.Cast (_, w, _)) -> 
-           S.lift (f x) (succ i) (0) w
+           f x (S.lift (succ i) (0) w)
         | B.Abbr _                  -> assert false
         | B.Void                    -> 
-           error1 "reference to excluded variable" m x
-      in
-      R.get f m i
+           error1 err "reference to excluded variable" m x
+      end
    | B.GRef (_, uri)         ->
-      let f = function
-         | _, _, B.Abst w                  -> f x w
-        | _, _, B.Abbr (B.Cast (_, w, _)) -> f x w
-        | _, _, B.Abbr _                  -> assert false
-        | _, _, B.Void                    ->
-           error1 "reference to excluded object" m x
-      in
-      E.get_obj f uri   
+      begin match E.get_entity uri with
+         | _, _, Y.Abst w                  -> f x w
+        | _, _, Y.Abbr (B.Cast (_, w, _)) -> f x w
+        | _, _, Y.Abbr _                  -> assert false
+        | _, _, Y.Void                    ->
+            error1 err "reference to unknown entry" m x
+      end
    | B.Bind (a, B.Abbr v, t) ->
       let f xv xt tt =
          f (A.sh2 v xv t xt x (B.bind_abbr a)) (B.bind_abbr a xv tt)
       in
-      let f xv m = b_type_of (f xv) ~si g m t in
-      let f xv = R.push (f xv) m a (B.Abbr xv) in
+      let f xv m = b_type_of err (f xv) st g m t in
+      let f xv = f xv (R.push m a (B.abbr xv)) in
       let f xv vv = match xv with 
         | B.Cast _ -> f xv
          | _        -> f (B.Cast ([], vv, xv))
       in
-      type_of f ~si g m v
+      type_of err f st g m v
    | B.Bind (a, B.Abst u, t) ->
       let f xu xt tt =
         f (A.sh2 u xu t xt x (B.bind_abst a)) (B.bind_abst a xu tt)
       in
-      let f xu m = b_type_of (f xu) ~si g m t in
-      let f xu _ = R.push (f xu) m a (B.Abst xu) in
-      type_of f ~si g m u
+      let f xu m = b_type_of err (f xu) st g m t in
+      let f xu _ = f xu (R.push m a (B.abst xu)) in
+      type_of err f st g m u
    | B.Bind (a, B.Void, t)   ->
       let f xt tt = 
-         f (A.sh1 t xt x (B.bind a B.Void)) (B.bind a B.Void tt)
+         f (A.sh1 t xt x (B.bind_void a)) (B.bind_void a tt)
       in
-      let f m = b_type_of f ~si g m t in
-      R.push f m a B.Void   
+      b_type_of err f st g (R.push m a B.Void) t
+         
    | B.Appl (a, v, t)        ->
       let f xv vv xt tt = 
-         let f () = f (A.sh2 v xv t xt x (B.appl a)) (B.appl a xv tt) in
-         R.assert_conversion f ~si ~rt:true m tt vv xv
+         let f _ = f (A.sh2 v xv t xt x (B.appl a)) (B.appl a xv tt) in
+         assert_applicability err f st m tt vv xv
       in
-      let f xv vv = b_type_of (f xv vv) ~si g m t in
-      type_of f ~si g m v
+      let f xv vv = b_type_of err (f xv vv) st g m t in
+      type_of err f st g m v
    | B.Cast (a, u, t)        ->
       let f xu xt tt =  
-        let f () = f (A.sh2 u xu t xt x (B.cast a)) xu in
-         R.assert_conversion f ~si m xu tt xt
+        let f _ = f (A.sh2 u xu t xt x (B.cast a)) xu in
+         assert_convertibility err f st m xu tt xt
       in
-      let f xu _ = b_type_of (f xu) ~si g m t in
-      type_of f ~si g m u
+      let f xu _ = b_type_of err (f xu) st g m t in
+      type_of err f st g m u
+
+(* Interface functions ******************************************************)
 
-and type_of f ?(si=false) g m x =
+and type_of err f st g m x =
    let f t u = L.unbox level; f t u in
-   L.box level; b_type_of f ~si g m x
+   L.box level; b_type_of err f st g m x