* http://cs.unibo.it/helm/.
*)
-module C = Cic
-module R = CicReduction
-module D = Deannotate
-module Int = struct
- type t = int
- let compare = compare
-end
-module S = Set.Make (Int)
+module UM = UriManager
+module C = Cic
+module D = Deannotate
+module I = CicInspect
+module PEH = ProofEngineHelpers
-type conclusion = (int * int) option
+module H = ProceduralHelpers
+
+type dependence = I.S.t * bool
+
+type conclusion = (int * int * UM.uri * int) option
(* debugging ****************************************************************)
-let string_of_entry inverse =
- if S.mem 0 inverse then "C" else
- if S.is_empty inverse then "I" else "P"
+let string_of_entry (inverse, b) =
+ if I.S.mem 0 inverse then begin if b then "CF" else "C" end else
+ if I.S.is_empty inverse then "I" else "P"
let to_string (classes, rc) =
let linearize = String.concat " " (List.map string_of_entry classes) in
match rc with
- | None -> linearize
- | Some (i, j) -> Printf.sprintf "%s %u %u" linearize i j
+ | None -> linearize
+ | Some (i, j, _, _) -> Printf.sprintf "%s %u %u" linearize i j
let out_table b =
let map i (_, inverse) =
let map i tl = Printf.sprintf "%2u" i :: tl in
- let iset = String.concat " " (S.fold map inverse []) in
+ let iset = String.concat " " (I.S.fold map inverse []) in
Printf.eprintf "%2u|%s\n" i iset
in
Array.iteri map b;
prerr_newline ()
-
-(****************************************************************************)
-let id x = x
+(* classification ***********************************************************)
-let rec list_fold_left g map = function
- | [] -> g
- | hd :: tl -> map (list_fold_left g map tl) hd
-
-let get_rels h t =
- let rec aux d g = function
- | C.Sort _
- | C.Implicit _ -> g
- | C.Rel i ->
- if i < d then g else fun a -> g (S.add (i - d + h + 1) a)
- | C.Appl ss -> list_fold_left g (aux d) ss
- | C.Const (_, ss)
- | C.MutInd (_, _, ss)
- | C.MutConstruct (_, _, _, ss)
- | C.Var (_, ss) ->
- let map g (_, t) = aux d g t in
- list_fold_left g map ss
- | C.Meta (_, ss) ->
- let map g = function
- | None -> g
- | Some t -> aux d g t
- in
- list_fold_left g map ss
- | C.Cast (t1, t2) -> aux d (aux d g t2) t1
- | C.LetIn (_, t1, t2)
- | C.Lambda (_, t1, t2)
- | C.Prod (_, t1, t2) -> aux d (aux (succ d) g t2) t1
- | C.MutCase (_, _, t1, t2, ss) ->
- aux d (aux d (list_fold_left g (aux d) ss) t2) t1
- | C.Fix (_, ss) ->
- let k = List.length ss in
- let map g (_, _, t1, t2) = aux d (aux (d + k) g t2) t1 in
- list_fold_left g map ss
- | C.CoFix (_, ss) ->
- let k = List.length ss in
- let map g (_, t1, t2) = aux d (aux (d + k) g t2) t1 in
- list_fold_left g map ss
+let classify_conclusion vs =
+ let rec get_argsno = function
+ | c, C.Appl (t :: vs) ->
+ let hd, argsno = get_argsno (c, t) in
+ hd, argsno + List.length vs
+ | _, t -> t, 0
in
- let g a = a in
- aux 1 g t S.empty
-
-let split c t =
- let add s v c = Some (s, C.Decl v) :: c in
- let rec aux whd a n c = function
- | C.Prod (s, v, t) -> aux false (v :: a) (succ n) (add s v c) t
- | v when whd -> v :: a, n
- | v -> aux true a n c (R.whd ~delta:true c v)
- in
- aux false [] 0 c t
-
-let classify_conclusion = function
- | C.Rel i -> Some (i, 0)
- | C.Appl (C.Rel i :: tl) -> Some (i, List.length tl)
- | _ -> None
-
+ let inside i = i > 1 && i <= List.length vs in
+ match vs with
+ | v0 :: v1 :: _ ->
+ let hd0, a0 = get_argsno v0 in
+ let hd1, a1 = get_argsno v1 in
+ begin match hd0, hd1 with
+ | C.Rel i, C.MutInd (u, n, _) when inside i -> Some (i, a0, u, n)
+ | _ -> None
+ end
+ | _ -> None
+
let classify c t =
try
- let vs, h = split c t in
- let rc = classify_conclusion (List.hd vs) in
- let map (b, h) v = (get_rels h v, S.empty) :: b, succ h in
+ let vs, h = PEH.split_with_normalize (c, t) in
+ let rc = classify_conclusion vs in
+ let map (b, h) (c, v) =
+ let _, argsno = PEH.split_with_whd (c, v) in
+ let isf = argsno > 0 || H.is_sort v in
+ let iu = H.is_unsafe h (List.hd vs) in
+ (I.get_rels_from_premise h v, I.S.empty, isf && iu) :: b, succ h
+ in
let l, h = List.fold_left map ([], 0) vs in
let b = Array.of_list (List.rev l) in
let mk_closure b h =
- let map j = if j < h then S.union (fst b.(j)) else id in
+ let map j = if j < h then I.S.union (H.fst3 b.(j)) else H.identity in
for i = pred h downto 0 do
- let direct, unused = b.(i) in
- b.(i) <- S.fold map direct direct, unused
+ let direct, unused, fa = b.(i) in
+ b.(i) <- I.S.fold map direct direct, unused, fa
done; b
in
let b = mk_closure b h in
let rec mk_inverse i direct =
- if S.is_empty direct then () else
- let j = S.choose direct in
+ if I.S.is_empty direct then () else
+ let j = I.S.choose direct in
if j < h then
- let unused, inverse = b.(j) in
- b.(j) <- unused, S.add i inverse
+ let unused, inverse, fa = b.(j) in
+ b.(j) <- unused, I.S.add i inverse, fa
else ();
- mk_inverse i (S.remove j direct)
+ mk_inverse i (I.S.remove j direct)
in
- let map i (direct, _) = mk_inverse i direct in
+ let map i (direct, _, _) = mk_inverse i direct in
Array.iteri map b;
(* out_table b; *)
- List.rev_map snd (List.tl (Array.to_list b)), rc
+ let extract (x, y, z) = y, z in
+ List.rev_map extract (List.tl (Array.to_list b)), rc
with Invalid_argument _ -> failwith "Classify.classify"
-
-let overlaps s1 s2 =
- let predicate x = S.mem x s1 in
- S.exists predicate s2