(**
   - Get types of existentials ;
   - Flatten dependency tree (prefix order) ;
   - Replace existentials by De Bruijn indices in term, applied to the right arguments ;
   - Apply term prefixed by quantification on "existentials".
*)

open Term
open Names
open Evd
open List
open Pp
open Util

let reverse_array arr = 
  Array.of_list (List.rev (Array.to_list arr))
    
let trace s = 
  if !Options.debug then (msgnl s; msgerr s)
  else ()

(** Utilities to find indices in lists *)
let list_index x l =
  let rec aux i = function
      k :: tl -> if k = x then i else aux (succ i) tl
    | [] -> raise Not_found
  in aux 0 l

let list_assoc_index x l =
  let rec aux i = function
      (k, _, v) :: tl -> if k = x then i else aux (succ i) tl
    | [] -> raise Not_found
  in aux 0 l


(** Substitute evar references in t using De Bruijn indices, 
  where n binders were passed through. *)
let subst_evar_constr evs n t = 
  let seen = ref Intset.empty in
  let evar_info id = 
    let rec aux i = function
	(k, x) :: tl -> 
	  if k = id then x else aux (succ i) tl
      | [] -> raise Not_found
    in aux 0 evs
  in
  let rec substrec depth c = match kind_of_term c with
    | Evar (k, args) ->
	let (id, idstr), hyps, _, _ = 
	  try evar_info k
	  with Not_found -> 
	    anomaly ("eterm: existential variable " ^ string_of_int k ^ " not found")
	in
        seen := Intset.add id !seen;
(* 	  (try trace (str "Evar " ++ int k ++ str " found, applied to " ++ int (Array.length args) ++ str "arguments," ++ *)
(* 			int (List.length hyps) ++ str " hypotheses"); 	      with _ -> () ); *)
	  (* Evar arguments are created in inverse order, 
	     and we must not apply to defined ones (i.e. LetIn's)
	  *)
	let args =
	  let rec aux hyps args acc =
	     match hyps, args with
		 ((_, None, _) :: tlh), (c :: tla) -> 
		   aux tlh tla ((map_constr_with_binders succ substrec depth c) :: acc)
	       | ((_, Some _, _) :: tlh), (_ :: tla) ->
		   aux tlh tla acc
	       | [], [] -> acc
	       | _, _ -> acc (*failwith "subst_evars: invalid argument"*)
	   in aux hyps (Array.to_list args) [] 
	 in
	   mkApp (mkVar idstr, Array.of_list args)
    | _ -> map_constr_with_binders succ substrec depth c
  in 
  let t' = substrec 0 t in
    t', !seen

      
(** Substitute variable references in t using De Bruijn indices, 
  where n binders were passed through. *)
let subst_vars acc n t = 
  let var_index id = 
    let idx = list_index id acc in
      idx + 1
  in
  let rec substrec depth c = match kind_of_term c with
    | Var v -> (try mkRel (depth + (var_index v)) with Not_found -> c)
    | _ -> map_constr_with_binders succ substrec depth c
  in 
    substrec 0 t

(** Rewrite type of an evar ([ H1 : t1, ... Hn : tn |- concl ])
  to a product : forall H1 : t1, ..., forall Hn : tn, concl.
    Changes evars and hypothesis references to variable references.
*)
let etype_of_evar evs ev hyps =
  let rec aux acc n = function
      (id, copt, t) :: tl ->
	let t', s = subst_evar_constr evs n t in
	let t'' = subst_vars acc 0 t' in
	let copt', s = 
	  match copt with
	      Some c -> 
		let c', s' = subst_evar_constr evs n c in
		  Some c', Intset.union s s'
	    | None -> None, s
	in
	let copt' = option_map (subst_vars acc 0) copt' in
 	let rest, s' = aux (id :: acc) (succ n) tl in
	  mkNamedProd_or_LetIn (id, copt', t'') rest, Intset.union s' s
    | [] ->
	let t', s = subst_evar_constr evs n ev.evar_concl in
	  subst_vars acc 0 t', s
  in aux [] 0 (rev hyps)


open Tacticals
    
let rec take n l = 
  if n = 0 then [] else List.hd l :: take (pred n) (List.tl l)    

let trunc_named_context n ctx = 
  let len = List.length ctx in
    take (len - n) ctx
  
let eterm_obligations name nclen evm t tycon = 
  (* 'Serialize' the evars, we assume that the types of the existentials
     refer to previous existentials in the list only *)
  let evl = List.rev (to_list evm) in
  let evn = 
    let i = ref (-1) in
      List.rev_map (fun (id, ev) -> incr i; 
		  (id, (!i, id_of_string (string_of_id name ^ "_obligation_" ^ string_of_int (succ !i))), ev)) evl
  in
  let evts = 
    (* Remove existential variables in types and build the corresponding products *)
    fold_right 
      (fun (id, (n, nstr), ev) l ->
	 let hyps = Environ.named_context_of_val ev.evar_hyps in
	 let hyps = trunc_named_context nclen hyps in
	 let evtyp, deps = etype_of_evar l ev hyps in
	 let y' = (id, ((n, nstr), hyps, evtyp, deps)) in
	   y' :: l) 
      evn []
  in 
  let t', _ = (* Substitute evar refs in the term by variables *)
    subst_evar_constr evts 0 t 
  in
  let evars = 
    List.map (fun (_, ((_, name), _, typ, deps)) -> name, typ, deps) evts
  in
(*     (try  *)
(*        trace (str "Term given to eterm" ++ spc () ++ *)
(* 		Termops.print_constr_env (Global.env ()) t); *)
(*        trace (str "Term constructed in eterm" ++ spc () ++ *)
(* 		Termops.print_constr_env (Global.env ()) t'); *)
(*        ignore(iter *)
(* 		(fun (name, typ, deps) -> *)
(* 		   trace (str "Evar :" ++ spc () ++ str (string_of_id name) ++ *)
(* 			    Termops.print_constr_env (Global.env ()) typ)) *)
(* 		evars); *)
(*      with _ -> ()); *)
    Array.of_list (List.rev evars), t'

let mkMetas n = 
  let rec aux i acc = 
    if i > 0 then aux (pred i) (Evarutil.mk_new_meta () :: acc)
    else acc
  in aux n []

(* let eterm evm t (tycon : types option) =  *)
(*   let t, tycon, evs = eterm_term evm t tycon in *)
(*     match tycon with *)
(* 	Some typ -> Tactics.apply_term (mkCast (t, DEFAULTcast, typ)) [] *)
(*       | None -> Tactics.apply_term t (mkMetas (List.length evs)) *)
     
(* open Tacmach *)

let etermtac (evm, t) = assert(false) (*eterm evm t None *)