(* $Id$ *)
-type aux_comparison = XEQ | XLE | XGE | XLT | XGT | XINCOMPARABLE
+type aux_comparison = XEQ | XLE | XGE | XLT | XGT | XINCOMPARABLE | XINVERTIBLE
-module Orderings (B : Terms.Blob) = struct
+module type Blob =
+ sig
+ include Terms.Blob
- type weight = int * (int * int) list;;
+ (* This order relation should be:
+ * - stable for instantiation
+ * - total on ground terms
+ *
+ *)
+ val compare_terms :
+ t Terms.foterm -> t Terms.foterm -> Terms.comparison
+
+ val compute_unit_clause_weight : 't Terms.unit_clause -> int
+
+ val compute_goal_weight : 't Terms.unit_clause -> int
+
+ val name : string
+
+ end
- let string_of_weight (cw, mw) =
- let s =
- String.concat ", "
- (List.map (function (m, w) -> Printf.sprintf "(%d,%d)" m w) mw)
- in
- Printf.sprintf "[%d; %s]" cw s
- ;;
+type weight = int * (int * int) list;;
+
+let rec eq_foterm f x y =
+ x == y ||
+ match x, y with
+ | Terms.Leaf t1, Terms.Leaf t2 -> f t1 t2
+ | Terms.Var i, Terms.Var j -> i = j
+ | Terms.Node l1, Terms.Node l2 -> List.for_all2 (eq_foterm f) l1 l2
+ | _ -> false
+;;
+
+let string_of_weight (cw, mw) =
+ let s =
+ String.concat ", "
+ (List.map (function (m, w) -> Printf.sprintf "(%d,%d)" m w) mw)
+ in
+ Printf.sprintf "[%d; %s]" cw s
+;;
- let weight_of_term term =
+let weight_of_term term =
let vars_dict = Hashtbl.create 5 in
let rec aux = function
| Terms.Var i ->
| (m1, _), (m2, _) -> m1 - m2
in
(w, List.sort compare l) (* from the smallest meta to the bigest *)
- ;;
+;;
- let compute_unit_clause_weight =
+let compute_unit_clause_weight (_,l, _, _) =
let weight_of_polynomial w m =
let factor = 2 in
w + factor * List.fold_left (fun acc (_,occ) -> acc+occ) 0 m
in
- function
+ match l with
| Terms.Predicate t ->
let w, m = weight_of_term t in
weight_of_polynomial w m
let w, m = weight_of_term x in
weight_of_polynomial w m
| Terms.Equation (l,r,_,Terms.Eq)
- | Terms.Equation (l,r,_,Terms.Incomparable) ->
+ | Terms.Equation (l,r,_,Terms.Incomparable)
+ | Terms.Equation (l,r,_,Terms.Invertible) ->
let wl, ml = weight_of_term l in
let wr, mr = weight_of_term r in
weight_of_polynomial (wl+wr) (ml@mr)
+;;
+
+(* UNUSED for now *)
+let compute_goal_weight (_,l, _, _) =
+ let weight_of_polynomial w m =
+ let factor = 2 in
+ w + factor * List.fold_left (fun acc (_,occ) -> acc+occ) 0 m
+ in
+ match l with
+ | Terms.Predicate t ->
+ let w, m = weight_of_term t in
+ weight_of_polynomial w m
+ | Terms.Equation (l,r,_,_) ->
+ let wl, ml = weight_of_term l in
+ let wr, mr = weight_of_term r in
+ let wl = weight_of_polynomial wl ml in
+ let wr = weight_of_polynomial wr mr in
+ - (abs (wl-wr))
;;
+
+let compute_goal_weight = compute_unit_clause_weight;;
- (* Riazanov: 3.1.5 pag 38 *)
+(* Riazanov: 3.1.5 pag 38 *)
(* Compare weights normalized in a new way :
* Variables should be sorted from the lowest index to the highest
* Variables which do not occur in the term should not be present
* in the normalized polynomial
*)
- let compare_weights (h1, w1) (h2, w2) =
- let rec aux hdiff (lt, gt) diffs w1 w2 =
- match w1, w2 with
- | ((var1, w1)::tl1) as l1, (((var2, w2)::tl2) as l2) ->
- if var1 = var2 then
- let diffs = (w1 - w2) + diffs in
- let r = compare w1 w2 in
- let lt = lt or (r < 0) in
- let gt = gt or (r > 0) in
- if lt && gt then XINCOMPARABLE else
- aux hdiff (lt, gt) diffs tl1 tl2
- else if var1 < var2 then
- if lt then XINCOMPARABLE else
- aux hdiff (false,true) (diffs+w1) tl1 l2
- else
- if gt then XINCOMPARABLE else
- aux hdiff (true,false) (diffs-w2) l1 tl2
- | [], (_,w2)::tl2 ->
- if gt then XINCOMPARABLE else
- aux hdiff (true,false) (diffs-w2) [] tl2
- | (_,w1)::tl1, [] ->
- if lt then XINCOMPARABLE else
- aux hdiff (false,true) (diffs+w1) tl1 []
- | [], [] ->
- if lt then
- if hdiff <= 0 then XLT
- else if (- diffs) >= hdiff then XLE else XINCOMPARABLE
- else if gt then
- if hdiff >= 0 then XGT
- else if diffs >= (- hdiff) then XGE else XINCOMPARABLE
- else
- if hdiff < 0 then XLT
- else if hdiff > 0 then XGT
- else XEQ
- in
- aux (h1-h2) (false,false) 0 w1 w2
- ;;
+let compare_weights (h1, w1) (h2, w2) =
+ let rec aux hdiff (lt, gt) diffs w1 w2 =
+ match w1, w2 with
+ | ((var1, w1)::tl1) as l1, (((var2, w2)::tl2) as l2) ->
+ if var1 = var2 then
+ let diffs = (w1 - w2) + diffs in
+ let r = Pervasives.compare w1 w2 in
+ let lt = lt or (r < 0) in
+ let gt = gt or (r > 0) in
+ if lt && gt then XINCOMPARABLE else
+ aux hdiff (lt, gt) diffs tl1 tl2
+ else if var1 < var2 then
+ if lt then XINCOMPARABLE else
+ aux hdiff (false,true) (diffs+w1) tl1 l2
+ else
+ if gt then XINCOMPARABLE else
+ aux hdiff (true,false) (diffs-w2) l1 tl2
+ | [], (_,w2)::tl2 ->
+ if gt then XINCOMPARABLE else
+ aux hdiff (true,false) (diffs-w2) [] tl2
+ | (_,w1)::tl1, [] ->
+ if lt then XINCOMPARABLE else
+ aux hdiff (false,true) (diffs+w1) tl1 []
+ | [], [] ->
+ if lt then
+ if hdiff <= 0 then XLT
+ else if (- diffs) >= hdiff then XLE else XINCOMPARABLE
+ else if gt then
+ if hdiff >= 0 then XGT
+ else if diffs >= (- hdiff) then XGE else XINCOMPARABLE
+ else
+ if hdiff < 0 then XLT
+ else if hdiff > 0 then XGT
+ else XEQ
+ in
+ aux (h1-h2) (false,false) 0 w1 w2
+;;
+
+(* Riazanov: p. 40, relation >>>
+ * if head_only=true then it is not >>> but helps case 2 of 3.14 p 39 *)
+let rec aux_ordering b_compare ?(head_only=false) t1 t2 =
+ match t1, t2 with
+ (* We want to discard any identity equality. *
+ * If we give back XEQ, no inference rule *
+ * will be applied on this equality *)
+ | Terms.Var i, Terms.Var j when i = j ->
+ XEQ
+ (* 1. *)
+ | Terms.Var _, _
+ | _, Terms.Var _ -> XINCOMPARABLE
+ (* 2.a *)
+ | Terms.Leaf a1, Terms.Leaf a2 ->
+ let cmp = b_compare a1 a2 in
+ if cmp = 0 then XEQ else if cmp < 0 then XLT else XGT
+ | Terms.Leaf _, Terms.Node _ -> XLT
+ | Terms.Node _, Terms.Leaf _ -> XGT
+ (* 2.b *)
+ | Terms.Node l1, Terms.Node l2 ->
+ let rec cmp t1 t2 =
+ match t1, t2 with
+ | [], [] -> XEQ
+ | _, [] -> (* XGT *) assert false (* hd symbols were eq *)
+ | [], _ -> (* XLT *) assert false (* hd symbols were eq *)
+ | hd1::tl1, hd2::tl2 ->
+ let o = aux_ordering b_compare ~head_only hd1 hd2 in
+ if o = XEQ && not head_only then cmp tl1 tl2 else o
+ in
+ cmp l1 l2
+;;
- (* Riazanov: p. 40, relation >>>
- * if head_only=true then it is not >>> but helps case 2 of 3.14 p 39 *)
- let rec aux_ordering ?(head_only=false) t1 t2 =
- match t1, t2 with
- (* We want to discard any identity equality. *
- * If we give back XEQ, no inference rule *
- * will be applied on this equality *)
- | Terms.Var i, Terms.Var j when i = j ->
- XEQ
- (* 1. *)
- | Terms.Var _, _
- | _, Terms.Var _ -> XINCOMPARABLE
- (* 2.a *)
- | Terms.Leaf a1, Terms.Leaf a2 ->
- let cmp = B.compare a1 a2 in
- if cmp = 0 then XEQ else if cmp < 0 then XLT else XGT
- | Terms.Leaf _, Terms.Node _ -> XLT
- | Terms.Node _, Terms.Leaf _ -> XGT
- (* 2.b *)
- | Terms.Node l1, Terms.Node l2 ->
- let rec cmp t1 t2 =
- match t1, t2 with
- | [], [] -> XEQ
- | _, [] -> XGT
- | [], _ -> XLT
- | hd1::tl1, hd2::tl2 ->
- let o = aux_ordering ~head_only hd1 hd2 in
- if o = XEQ && not head_only then cmp tl1 tl2 else o
- in
- cmp l1 l2
+let compare_terms o x y =
+ match o x y with
+ | XINCOMPARABLE -> Terms.Incomparable
+ | XGT -> Terms.Gt
+ | XLT -> Terms.Lt
+ | XEQ -> Terms.Eq
+ | XINVERTIBLE -> Terms.Invertible
+ | _ -> assert false
+;;
+
+module NRKBO (B : Terms.Blob) = struct
+ let name = "nrkbo"
+ include B
+
+ module Pp = Pp.Pp(B)
+
+ let eq_foterm = eq_foterm B.eq;;
+
+exception UnificationFailure of string Lazy.t;;
+
+
+(* DUPLICATE CODE FOR TESTS (see FoUnif) *)
+ let alpha_eq s t =
+ let rec equiv subst s t =
+ let s = match s with Terms.Var i -> FoSubst.lookup i subst | _ -> s
+ and t = match t with Terms.Var i -> FoSubst.lookup i subst | _ -> t
+
+ in
+ match s, t with
+ | s, t when eq_foterm s t -> subst
+ | Terms.Var i, Terms.Var j
+ when (not (List.exists (fun (_,k) -> k=t) subst)) ->
+ let subst = FoSubst.build_subst i t subst in
+ subst
+ | Terms.Node l1, Terms.Node l2 -> (
+ try
+ List.fold_left2
+ (fun subst' s t -> equiv subst' s t)
+ subst l1 l2
+ with Invalid_argument _ ->
+ raise (UnificationFailure (lazy "Inference.unification.unif"))
+ )
+ | _, _ ->
+ raise (UnificationFailure (lazy "Inference.unification.unif"))
+ in
+ equiv FoSubst.id_subst s t
+;;
+
+let relocate maxvar varlist subst =
+ List.fold_right
+ (fun i (maxvar, varlist, s) ->
+ maxvar+1, maxvar::varlist, FoSubst.build_subst i (Terms.Var maxvar) s)
+ varlist (maxvar+1, [], subst)
;;
+
+ let are_invertible l r =
+ let varlist = (Terms.vars_of_term l)@(Terms.vars_of_term r) in
+ let maxvar = List.fold_left max 0 varlist in
+ let _,_,subst = relocate maxvar varlist FoSubst.id_subst in
+ let newl = FoSubst.apply_subst subst l in
+ let newr = FoSubst.apply_subst subst r in
+ try (let subst = alpha_eq l newr in eq_foterm newl (FoSubst.apply_subst subst r)) with
+ UnificationFailure _ -> false
+;;
+
+ let compute_unit_clause_weight = compute_unit_clause_weight;;
+ let compute_goal_weight = compute_goal_weight;;
(* Riazanov: p. 40, relation >_n *)
let nonrec_kbo t1 t2 =
let w2 = weight_of_term t2 in
match compare_weights w1 w2 with
| XLE -> (* this is .> *)
- if aux_ordering t1 t2 = XLT then XLT else XINCOMPARABLE
+ if aux_ordering B.compare t1 t2 = XLT then XLT else XINCOMPARABLE
| XGE ->
- if aux_ordering t1 t2 = XGT then XGT else XINCOMPARABLE
- | XEQ -> aux_ordering t1 t2
+ if aux_ordering B.compare t1 t2 = XGT then XGT else XINCOMPARABLE
+ | XEQ -> let res = aux_ordering B.compare t1 t2 in
+ if res = XINCOMPARABLE && are_invertible t1 t2 then XINVERTIBLE
+ else res
| res -> res
;;
+
+ let compare_terms = compare_terms nonrec_kbo;;
+
+ let profiler = HExtlib.profile ~enable:true "compare_terms(nrkbo)";;
+ let compare_terms x y =
+ profiler.HExtlib.profile (compare_terms x) y
+ ;;
+
+end
+module KBO (B : Terms.Blob) = struct
+ let name = "kbo"
+ include B
+
+ module Pp = Pp.Pp(B)
+
+ let eq_foterm = eq_foterm B.eq;;
+
+ let compute_unit_clause_weight = compute_unit_clause_weight;;
+ let compute_goal_weight = compute_goal_weight;;
+
(* Riazanov: p. 38, relation > *)
let rec kbo t1 t2 =
- let aux = aux_ordering ~head_only:true in
+ let aux = aux_ordering B.compare ~head_only:true in
let rec cmp t1 t2 =
match t1, t2 with
| [], [] -> XEQ
let r = aux t1 t2 in
if r = XEQ then (
match t1, t2 with
+ | Terms.Var i, Terms.Var j when i=j -> XEQ
| Terms.Node (_::tl1), Terms.Node (_::tl2) -> cmp tl1 tl2
| _, _ -> XINCOMPARABLE
) else r
| res -> res
;;
+
+ let compare_terms = compare_terms kbo;;
+
+ let profiler = HExtlib.profile ~enable:true "compare_terms(kbo)";;
+ let compare_terms x y =
+ profiler.HExtlib.profile (compare_terms x) y
+ ;;
+
+end
+
+module LPO (B : Terms.Blob) = struct
+ let name = "lpo"
+ include B
+
+ module Pp = Pp.Pp(B)
+
+ let eq_foterm = eq_foterm B.eq;;
+
+ let compute_unit_clause_weight = compute_unit_clause_weight;;
+ let compute_goal_weight = compute_goal_weight;;
+
+ let rec lpo s t =
+ match s,t with
+ | s, t when eq_foterm s t ->
+ XEQ
+ | Terms.Var _, Terms.Var _ ->
+ XINCOMPARABLE
+ | _, Terms.Var i ->
+ if (List.mem i (Terms.vars_of_term s)) then XGT
+ else XINCOMPARABLE
+ | Terms.Var i,_ ->
+ if (List.mem i (Terms.vars_of_term t)) then XLT
+ else XINCOMPARABLE
+ | Terms.Node (hd1::tl1), Terms.Node (hd2::tl2) ->
+ let rec ge_subterm t ol = function
+ | [] -> (false, ol)
+ | x::tl ->
+ let res = lpo x t in
+ match res with
+ | XGT | XEQ -> (true,res::ol)
+ | o -> ge_subterm t (o::ol) tl
+ in
+ let (res, l_ol) = ge_subterm t [] tl1 in
+ if res then XGT
+ else let (res, r_ol) = ge_subterm s [] tl2 in
+ if res then XLT
+ else begin
+ let rec check_subterms t = function
+ | _,[] -> true
+ | o::ol,_::tl ->
+ if o = XLT then check_subterms t (ol,tl)
+ else false
+ | [], x::tl ->
+ if lpo x t = XLT then check_subterms t ([],tl)
+ else false
+ in
+ match aux_ordering B.compare hd1 hd2 with
+ | XGT -> if check_subterms s (r_ol,tl2) then XGT
+ else XINCOMPARABLE
+ | XLT -> if check_subterms t (l_ol,tl1) then XLT
+ else XINCOMPARABLE
+ | XEQ ->
+ let lex = List.fold_left2
+ (fun acc si ti -> if acc = XEQ then lpo si ti else acc)
+ XEQ tl1 tl2
+ in
+ (match lex with
+ | XGT ->
+ if List.for_all (fun x -> lpo s x = XGT) tl2 then XGT
+ else XINCOMPARABLE
+ | XLT ->
+ if List.for_all (fun x -> lpo x t = XLT) tl1 then XLT
+ else XINCOMPARABLE
+ | o -> o)
+ | XINCOMPARABLE -> XINCOMPARABLE
+ | _ -> assert false
+ end
+ | _,_ -> aux_ordering B.compare s t
- let compare_terms x y =
- match nonrec_kbo x y with
- | XINCOMPARABLE -> Terms.Incomparable
- | XGT -> Terms.Gt
- | XLT -> Terms.Lt
- | XEQ -> Terms.Eq
- | _ -> assert false
- ;;
+ ;;
+
+ let compare_terms = compare_terms lpo;;
+
+ let profiler = HExtlib.profile ~enable:true "compare_terms(lpo)";;
+ let compare_terms x y =
+ profiler.HExtlib.profile (compare_terms x) y
+ ;;
end
+