match src,tgt with
| CoercDb.Uri _, CoercDb.Uri _ ->
let c_from_tgt =
- List.filter (fun (f,_,_) -> eq_carr f tgt) coercions
+ List.filter
+ (fun (f,t,_) -> eq_carr f tgt (*&& not (eq_carr t src)*))
+ coercions
in
let c_to_src =
- List.filter (fun (_,t,_) -> eq_carr t src) coercions
+ List.filter
+ (fun (f,t,_) -> eq_carr t src (*&& not (eq_carr f tgt)*))
+ coercions
in
- (List.map (fun (_,t,u) -> src,[uri; u],t) c_from_tgt) @
- (List.map (fun (s,_,u) -> s,[u; uri],tgt) c_to_src) @
- (List.fold_left (
- fun l (s,_,u1) ->
- ((List.map (fun (_,t,u2) ->
- (s,[u1;uri;u2],t)
- )c_from_tgt)@l) )
- [] c_to_src)
+ (HExtlib.flatten_map
+ (fun (_,t,ul) -> List.map (fun u -> src,[uri; u],t) ul) c_from_tgt) @
+ (HExtlib.flatten_map
+ (fun (s,_,ul) -> List.map (fun u -> s,[u; uri],tgt) ul) c_to_src) @
+ (HExtlib.flatten_map
+ (fun (s,_,u1l) ->
+ HExtlib.flatten_map
+ (fun (_,t,u2l) ->
+ HExtlib.flatten_map
+ (fun u1 ->
+ List.map
+ (fun u2 -> (s,[u1;uri;u2],t))
+ u2l)
+ u1l)
+ c_from_tgt)
+ c_to_src)
| _ -> [] (* do not close in case source or target is not an indty ?? *)
;;
-let obj_attrs = [`Class `Coercion; `Generated]
+let obj_attrs n = [`Class (`Coercion n); `Generated]
+
+exception UnableToCompose
(* generate_composite_closure (c2 (c1 s)) in the universe graph univ *)
-let generate_composite_closure c1 c2 univ =
+let generate_composite_closure rt c1 c2 univ arity =
+ let module RT = RefinementTool in
let c1_ty,univ = CicTypeChecker.type_of_aux' [] [] c1 univ in
- let rec mk_rels n =
- match n with
- | 0 -> []
- | _ -> (Cic.Rel n) :: (mk_rels (n-1))
+ let c2_ty,univ = CicTypeChecker.type_of_aux' [] [] c2 univ in
+ let rec mk_implicits = function
+ | 0 -> [] | n -> (Cic.Implicit None) :: mk_implicits (n-1)
in
- let rec compose k =
- function
- | Cic.Prod (name,src,tgt) ->
- let name =
- match name with
- | Cic.Anonymous -> Cic.Name "x"
- | _ -> name
- in
- Cic.Lambda (name,src,compose (k+1) tgt)
- | Cic.Appl (he::tl) ->
- Cic.Appl (c2 :: tl @ [Cic.Appl (c1 :: (mk_rels k)) ])
- | _ -> Cic.Appl (c2 :: [Cic.Appl (c1 :: (mk_rels k)) ])
+ let rec mk_lambda_spline c namer = function
+ | 0 -> c
+ | n ->
+ Cic.Lambda
+ (namer n,
+ (Cic.Implicit None),
+ mk_lambda_spline c namer (n-1))
+ in
+ let count_saturations_needed t arity =
+ let rec aux acc n = function
+ | Cic.Prod (name,src, ((Cic.Prod _) as t)) ->
+ aux (acc@[name]) (n+1) t
+ | _ -> n,acc
+ in
+ let len,names = aux [] 0 t in
+ let len = len - arity in
+ List.fold_left
+ (fun (n,l) x -> if n <= len then n+1,l@[x] else n,l) (0,[])
+ names
+ in
+ let compose c1 nc1 c2 nc2 =
+ Cic.Lambda
+ (Cic.Name "x",
+ (Cic.Implicit None),
+ Cic.Appl ( c2 :: mk_implicits nc2 @
+ [ Cic.Appl ( c1 :: mk_implicits nc1 @ [Cic.Rel 1]) ]))
+ in
+(*
+ let order_metasenv metasenv =
+ let module OT = struct type t = int let compare = Pervasives.compare end in
+ let module S = HTopoSort.Make (OT) in
+ let dep i =
+ let _,_,ty = List.find (fun (j,_,_) -> j=i) metasenv in
+ let metas = List.map fst (CicUtil.metas_of_term ty) in
+ HExtlib.list_uniq (List.sort Pervasives.compare metas)
+ in
+ let om =
+ S.topological_sort (List.map (fun (i,_,_) -> i) metasenv) dep
+ in
+ List.map (fun i -> List.find (fun (j,_,_) -> i=j) metasenv) om
+ in
+*)
+ let rec create_subst_from_metas_to_rels n = function
+ | [] -> []
+ | (metano, ctx, ty)::tl ->
+ (metano,(ctx,Cic.Rel (n+1),ty)) ::
+ create_subst_from_metas_to_rels (n-1) tl
+ in
+ let split_metasenv metasenv n =
+ List.partition (fun (_,ctx,_) -> List.length ctx > n) metasenv
+ in
+ let purge_unused_lambdas metasenv t =
+ let rec aux = function
+ | Cic.Lambda (_, Cic.Meta (i,_), t) when
+ List.exists (fun (j,_,_) -> j = i) metasenv ->
+ aux (CicSubstitution.subst (Cic.Rel ~-100) t)
+ | Cic.Lambda (name, s, t) ->
+ Cic.Lambda (name, s, aux t)
+ | t -> t
+ in
+ aux t
in
- let c = compose 0 c1_ty in
+ let order_body_menv term body_metasenv =
+ let rec purge_lambdas = function
+ | Cic.Lambda (_,_,t) -> purge_lambdas t
+ | t -> t
+ in
+ let skip_appl = function | Cic.Appl l -> List.tl l | _ -> assert false in
+ let metas_that_saturate l =
+ List.fold_left
+ (fun (acc,n) t ->
+ let metas = CicUtil.metas_of_term t in
+ let metas = List.map fst metas in
+ let metas =
+ List.filter
+ (fun i -> List.for_all (fun (j,_) -> j<>i) acc)
+ metas
+ in
+ let metas = List.map (fun i -> i,n) metas in
+ metas @ acc, n+1)
+ ([],0) l
+ in
+ let l_c2 = skip_appl (purge_lambdas term) in
+ let l_c1 =
+ match HExtlib.list_last l_c2 with
+ | Cic.Appl l -> List.tl l
+ | _ -> assert false
+ in
+ (* i should cut off the laet elem of l_c2 *)
+ let meta2no = fst (metas_that_saturate (l_c1 @ l_c2)) in
+ List.sort
+ (fun (i,ctx1,ty1) (j,ctx1,ty1) ->
+ try List.assoc i meta2no - List.assoc j meta2no
+ with Not_found -> assert false)
+ body_metasenv
+ in
+ let namer l n =
+ let l = List.map (function Cic.Name s -> s | _ -> "A") l in
+ let l = List.fold_left
+ (fun acc s ->
+ let rec add' s =
+ if List.exists ((=) s) acc then add' (s^"'") else s
+ in
+ acc@[add' s])
+ [] l
+ in
+ let l = List.rev l in
+ Cic.Name (List.nth l (n-1))
+ in
+ debug_print (lazy ("\nCOMPOSING"));
+ debug_print (lazy (" c1= "^CicPp.ppterm c1 ^" : "^ CicPp.ppterm c1_ty));
+ debug_print (lazy (" c2= "^CicPp.ppterm c2 ^" : "^ CicPp.ppterm c2_ty));
+ let saturations_for_c1, names_c1 = count_saturations_needed c1_ty arity in
+ let saturations_for_c2, names_c2 = count_saturations_needed c2_ty 0 in
+ let c = compose c1 saturations_for_c1 c2 saturations_for_c2 in
+ let spline_len = saturations_for_c1 + saturations_for_c2 in
+ let c = mk_lambda_spline c (namer (names_c1 @ names_c2)) spline_len in
+ debug_print (lazy ("COMPOSTA: " ^ CicPp.ppterm c));
+ let c, univ =
+ match rt.RT.type_of_aux' [] [] c univ with
+ | RT.Success (term, ty, metasenv, ugraph) ->
+ debug_print(lazy("COMPOSED REFINED: "^CicPp.ppterm term));
+(* let metasenv = order_metasenv metasenv in *)
+(* debug_print(lazy("ORDERED MENV: "^rt.RT.ppmetasenv [] metasenv)); *)
+ let body_metasenv, lambdas_metasenv =
+ split_metasenv metasenv spline_len
+ in
+(*
+ debug_print(lazy("B_MENV: "^rt.RT.ppmetasenv [] body_metasenv));
+ debug_print(lazy("L_MENV: "^rt.RT.ppmetasenv [] lambdas_metasenv));
+*)
+ let body_metasenv = order_body_menv term body_metasenv in
+ debug_print(lazy("ORDERED_B_MENV: "^rt.RT.ppmetasenv [] body_metasenv));
+ let subst = create_subst_from_metas_to_rels spline_len body_metasenv in
+ debug_print (lazy("SUBST: "^rt.RT.ppsubst subst));
+ let term = rt.RT.apply_subst subst term in
+ debug_print (lazy ("COMPOSED SUBSTITUTED: " ^ CicPp.ppterm term));
+ (match rt.RT.type_of_aux' metasenv [] term ugraph with
+ | RT.Success (term, ty, metasenv, ugraph) ->
+ let body_metasenv, lambdas_metasenv =
+ split_metasenv metasenv spline_len
+ in
+ let term = purge_unused_lambdas lambdas_metasenv term in
+ debug_print (lazy ("COMPOSED: " ^ CicPp.ppterm term));
+ term, ugraph
+ | RT.Exception s -> debug_print s; raise UnableToCompose)
+ | RT.Exception s -> debug_print s; raise UnableToCompose
+ in
let c_ty,univ =
try
CicTypeChecker.type_of_aux' [] [] c univ
- with CicTypeChecker.TypeCheckerFailure s as exn ->
+ with CicTypeChecker.TypeCheckerFailure s ->
debug_print (lazy (Printf.sprintf "Generated composite coercion:\n%s\n%s"
(CicPp.ppterm c) (Lazy.force s)));
- raise exn
+ raise UnableToCompose
in
let cleaned_ty =
FreshNamesGenerator.clean_dummy_dependent_types c_ty
in
- let obj = Cic.Constant ("xxxx",Some c,cleaned_ty,[],obj_attrs) in
+ let obj = Cic.Constant ("xxxx",Some c,cleaned_ty,[],obj_attrs arity) in
obj,univ
;;
(* removes from l the coercions that are in !coercions *)
let filter_duplicates l coercions =
List.filter (
- fun (src,_,tgt) ->
- not (List.exists (fun (s,t,u) ->
+ fun (src,l1,tgt) ->
+ not (List.exists (fun (s,t,l2) ->
CoercDb.eq_carr s src &&
- CoercDb.eq_carr t tgt)
+ CoercDb.eq_carr t tgt &&
+ try
+ List.for_all2 (fun u1 u2 -> UriManager.eq u1 u2) l1 l2
+ with
+ | Invalid_argument "List.for_all2" -> false)
coercions))
l
+let mangle s t l =
+ (*List.fold_left
+ (fun s x -> s ^ "_" ^ x)
+ (s ^ "_OF_" ^ t ^ "_BY" ^ string_of_int (List.length l)) l*)
+ s ^ "_OF_" ^ t
+;;
+
+exception ManglingFailed of string
+
+let number_if_already_defined buri name l =
+ let err () =
+ raise
+ (ManglingFailed
+ ("Unable to give an altenative name to " ^ buri ^ "/" ^ name ^ ".con"))
+ in
+ let rec aux n =
+ let suffix = if n > 0 then string_of_int n else "" in
+ let suri = buri ^ "/" ^ name ^ suffix ^ ".con" in
+ let uri = UriManager.uri_of_string suri in
+ let retry () =
+ if n < 100 then
+ begin
+ HLog.warn ("Uri " ^ suri ^ " already exists.");
+ aux (n+1)
+ end
+ else
+ err ()
+ in
+ if List.exists (UriManager.eq uri) l then retry ()
+ else
+ try
+ let _ = Http_getter.resolve' ~writable:true uri in
+ if Http_getter.exists' uri then retry () else uri
+ with
+ | Http_getter_types.Key_not_found _ -> uri
+ | Http_getter_types.Unresolvable_URI _ -> assert false
+ in
+ aux 0
+;;
+
(* given a new coercion uri from src to tgt returns
* a list of (new coercion uri, coercion obj, universe graph)
*)
-let close_coercion_graph src tgt uri =
+let close_coercion_graph rt src tgt uri =
(* check if the coercion already exists *)
let coercions = CoercDb.to_list () in
let todo_list = get_closure_coercions src tgt uri coercions in
let todo_list = filter_duplicates todo_list coercions in
- let new_coercions =
- List.map (
- fun (src, l , tgt) ->
- match l with
- | [] -> assert false
- | he :: tl ->
- let first_step =
- Cic.Constant ("",
- Some (CoercDb.term_of_carr (CoercDb.Uri he)),
- Cic.Sort Cic.Prop, [], obj_attrs)
- in
- let o,_ =
- List.fold_left (fun (o,univ) coer ->
- match o with
- | Cic.Constant (_,Some c,_,[],_) ->
- generate_composite_closure c (CoercDb.term_of_carr (CoercDb.Uri
- coer)) univ
- | _ -> assert false
- ) (first_step, CicUniv.empty_ugraph) tl
- in
- let name_src = CoercDb.name_of_carr src in
- let name_tgt = CoercDb.name_of_carr tgt in
- let name = name_tgt ^ "_of_" ^ name_src in
- let buri = UriManager.buri_of_uri uri in
- let c_uri =
- UriManager.uri_of_string (buri ^ "/" ^ name ^ ".con")
- in
- let named_obj =
- match o with
- | Cic.Constant (_,bo,ty,vl,attrs) ->
- Cic.Constant (name,bo,ty,vl,attrs)
- | _ -> assert false
- in
- ((src,tgt,c_uri,named_obj))
- ) todo_list
- in
- new_coercions
+ try
+ let new_coercions =
+ List.fold_left (
+ fun acc (src, l , tgt) ->
+ try
+ (match l with
+ | [] -> assert false
+ | he :: tl ->
+ let arity = match tgt with CoercDb.Fun n -> n | _ -> 0 in
+ let first_step =
+ Cic.Constant ("",
+ Some (CoercDb.term_of_carr (CoercDb.Uri he)),
+ Cic.Sort Cic.Prop, [], obj_attrs arity)
+ in
+ let o,_ =
+ List.fold_left (fun (o,univ) coer ->
+ match o with
+ | Cic.Constant (_,Some c,_,[],_) ->
+ generate_composite_closure rt c
+ (CoercDb.term_of_carr (CoercDb.Uri coer)) univ arity
+ | _ -> assert false
+ ) (first_step, CicUniv.empty_ugraph) tl
+ in
+ let name_src = CoercDb.name_of_carr src in
+ let name_tgt = CoercDb.name_of_carr tgt in
+ let by = List.map UriManager.name_of_uri l in
+ let name = mangle name_tgt name_src by in
+ let buri = UriManager.buri_of_uri uri in
+ let c_uri =
+ number_if_already_defined buri name
+ (List.map (fun (_,_,u,_) -> u) acc)
+ in
+ let named_obj =
+ match o with
+ | Cic.Constant (_,bo,ty,vl,attrs) ->
+ Cic.Constant (name,bo,ty,vl,attrs)
+ | _ -> assert false
+ in
+ (src,tgt,c_uri,named_obj))::acc
+ with UnableToCompose -> acc
+ ) [] todo_list
+ in
+ new_coercions
+ with ManglingFailed s -> HLog.error s; []
;;