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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2010 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Errors
open Util
open Names
open Nameops
open Term
open Pattern
open Patternops
open Glob_term
open Libnames
open Nametab
(* Discrimination nets of terms.
See the module dn.ml for further explanations.
Eduardo (5/8/97) *)
module Make =
functor (Z : Map.OrderedType) ->
struct
module X = struct
type t = constr_pattern
let compare = Pervasives.compare
end
type term_label =
| GRLabel of global_reference
| ProdLabel
| LambdaLabel
| SortLabel
module Y = struct
type t = term_label
let compare x y =
let make_name n =
match n with
| GRLabel(ConstRef con) ->
GRLabel(ConstRef(constant_of_kn(canonical_con con)))
| GRLabel(IndRef (kn,i)) ->
GRLabel(IndRef(mind_of_kn(canonical_mind kn),i))
| GRLabel(ConstructRef ((kn,i),j ))->
GRLabel(ConstructRef((mind_of_kn(canonical_mind kn),i),j))
| k -> k
in
Pervasives.compare (make_name x) (make_name y)
end
module Dn = Dn.Make(X)(Y)(Z)
type t = Dn.t
type 'a lookup_res = 'a Dn.lookup_res
(*If we have: f a b c ..., decomp gives: (f,[a;b;c;...])*)
let decomp =
let rec decrec acc c = match kind_of_term c with
| App (f,l) -> decrec (Array.fold_right (fun a l -> a::l) l acc) f
| Cast (c1,_,_) -> decrec acc c1
| _ -> (c,acc)
in
decrec []
let decomp_pat =
let rec decrec acc = function
| PApp (f,args) -> decrec (Array.to_list args @ acc) f
| c -> (c,acc)
in
decrec []
let constr_pat_discr t =
if not (occur_meta_pattern t) then
None
else
match decomp_pat t with
| PRef ((IndRef _) as ref), args
| PRef ((ConstructRef _ ) as ref), args -> Some (GRLabel ref,args)
| PRef ((VarRef v) as ref), args -> Some(GRLabel ref,args)
| _ -> None
let constr_pat_discr_st (idpred,cpred) t =
match decomp_pat t with
| PRef ((IndRef _) as ref), args
| PRef ((ConstructRef _ ) as ref), args -> Some (GRLabel ref,args)
| PRef ((VarRef v) as ref), args when not (Idpred.mem v idpred) ->
Some(GRLabel ref,args)
| PVar v, args when not (Idpred.mem v idpred) ->
Some(GRLabel (VarRef v),args)
| PRef ((ConstRef c) as ref), args when not (Cpred.mem c cpred) ->
Some (GRLabel ref, args)
| PProd (_, d, c), [] -> Some (ProdLabel, [d ; c])
| PLambda (_, d, c), l -> Some (LambdaLabel, [d ; c] @ l)
| PSort s, [] -> Some (SortLabel, [])
| _ -> None
open Dn
let constr_val_discr t =
let c, l = decomp t in
match kind_of_term c with
| Ind ind_sp -> Label(GRLabel (IndRef ind_sp),l)
| Construct cstr_sp -> Label(GRLabel (ConstructRef cstr_sp),l)
| Var id -> Label(GRLabel (VarRef id),l)
| Const _ -> Everything
| _ -> Nothing
let constr_val_discr_st (idpred,cpred) t =
let c, l = decomp t in
match kind_of_term c with
| Const c -> if Cpred.mem c cpred then Everything else Label(GRLabel (ConstRef c),l)
| Ind ind_sp -> Label(GRLabel (IndRef ind_sp),l)
| Construct cstr_sp -> Label(GRLabel (ConstructRef cstr_sp),l)
| Var id when not (Idpred.mem id idpred) -> Label(GRLabel (VarRef id),l)
| Prod (n, d, c) -> Label(ProdLabel, [d; c])
| Lambda (n, d, c) -> Label(LambdaLabel, [d; c] @ l)
| Sort _ -> Label (SortLabel, [])
| Evar _ -> Everything
| _ -> Nothing
let create = Dn.create
let add dn st = Dn.add dn (constr_pat_discr_st st)
let rmv dn st = Dn.rmv dn (constr_pat_discr_st st)
let lookup dn st t = Dn.lookup dn (constr_val_discr_st st) t
let app f dn = Dn.app f dn
end
|