(* ========================================================================= *) (* Interface to prover9. *) (* ========================================================================= *) (**** NB: this is the "prover9" command invoked by HOL Light. **** If this doesn't work, set an explicit path to the prover9 binary ****) let prover9 = "prover9";; (* ------------------------------------------------------------------------- *) (* Debugging mode (true = keep the Prover9 input and output files) *) (* ------------------------------------------------------------------------- *) let prover9_debugging = ref false;; (* ------------------------------------------------------------------------- *) (* Prover9 options. Set to "" for the Prover9 default. *) (* ------------------------------------------------------------------------- *) let prover9_options = ref ("clear(auto_inference).\n"^ "clear(auto_denials).\n"^ "clear(auto_limits).\n"^ "set(neg_binary_resolution).\n"^ "set(binary_resolution).\n"^ "set(paramodulation).\n");; (* ------------------------------------------------------------------------- *) (* Find the variables, functions, and predicates excluding equality. *) (* ------------------------------------------------------------------------- *) let rec functions fvs tm (vacc,facc,racc as acc) = if is_var tm then if mem tm fvs then (vacc,insert tm facc,racc) else (insert tm vacc,facc,racc) else if is_abs tm then acc else let f,args = strip_comb tm in itlist (functions fvs) args (vacc,insert f facc,racc);; let rec signature fvs tm (vacc,facc,racc as acc) = if is_neg tm then signature fvs (rand tm) acc else if is_conj tm || is_disj tm || is_imp tm || is_iff tm then signature fvs (lhand tm) (signature fvs (rand tm) acc) else if is_forall tm || is_exists tm || is_uexists tm then signature fvs (body(rand tm)) acc else if is_eq tm then functions fvs (lhand tm) (functions fvs (rand tm) acc) else if is_abs tm then acc else let r,args = strip_comb tm in itlist (functions fvs) args (vacc,facc,insert r racc);; (* ------------------------------------------------------------------------- *) (* Shadow first-order syntax. Literal sign is true = positive. *) (* ------------------------------------------------------------------------- *) type folterm = Variable of string | Function of string * folterm list;; type literal = Literal of bool * string * folterm list;; (* ------------------------------------------------------------------------- *) (* Translate clause into shadow syntax. *) (* ------------------------------------------------------------------------- *) let rec translate_term (trans_var,trans_fun,trans_rel as trp) tm = let f,args = strip_comb tm in if defined trans_fun f then Function(apply trans_fun f,map (translate_term trp) args) else if is_var tm then Variable(apply trans_var tm) else failwith("unknown function"^ (try fst(dest_const tm) with Failure _ -> "??"));; let translate_atom (trans_var,trans_fun,trans_rel as trp) tm = if is_eq tm then Literal(true,"=",[translate_term trp (lhand tm); translate_term trp (rand tm)]) else let r,args = strip_comb tm in Literal(true,apply trans_rel r,map (translate_term trp) args);; let rec translate_clause trp tm = if is_disj tm then translate_clause trp (lhand tm) @ translate_clause trp (rand tm) else if is_neg tm then let Literal(s,r,args) = translate_atom trp (rand tm) in [Literal(not s,r,args)] else [translate_atom trp tm];; (* ------------------------------------------------------------------------- *) (* Create Prover9 input file for a set of clauses. *) (* ------------------------------------------------------------------------- *) let rec prover9_of_term tm = match tm with Variable(s) -> s | Function(f,[]) -> f | Function(f,args) -> f^"("^ end_itlist (fun s t -> s^","^t) (map prover9_of_term args) ^ ")";; let prover9_of_literal lit = match lit with Literal(s,r,[]) -> if s then r else "-"^r | Literal(s,"=",[l;r]) -> (if s then "(" else "-(")^ (prover9_of_term l) ^ " = " ^ (prover9_of_term r)^")" | Literal(s,r,args) -> (if s then "" else "-")^r^"("^ end_itlist (fun s t -> s^","^t) (map prover9_of_term args) ^ ")";; let rec prover9_of_clause cls = match cls with [] -> failwith "prover9_of_clause: empty clause" | [l] -> prover9_of_literal l | l::ls -> prover9_of_literal l ^ " | " ^ prover9_of_clause ls;; (* ------------------------------------------------------------------------- *) (* Parse S-expressions. *) (* ------------------------------------------------------------------------- *) type sexp = Atom of string | List of sexp list;; let atom inp = match inp with Resword "("::rst -> raise Noparse | Resword ")"::rst -> raise Noparse | Resword s::rst -> Atom s,rst | Ident s::rst -> Atom s,rst | [] -> raise Noparse;; let rec sexpression inp = ( atom ||| (a (Resword "(") ++ many sexpression ++ a (Resword ")") >> (fun ((_,l),_) -> List l))) inp;; (* ------------------------------------------------------------------------- *) (* Skip to beginning of proof object. *) (* ------------------------------------------------------------------------- *) let rec skipheader i s = if String.sub s i 28 = ";; BEGINNING OF PROOF OBJECT" then String.sub s (i + 28) (String.length s - i - 28) else skipheader (i + 1) s;; (* ------------------------------------------------------------------------- *) (* Parse a proof step. *) (* ------------------------------------------------------------------------- *) let parse_proofstep ps = match ps with List[Atom id; just; formula; Atom "NIL"] -> (id,just,formula) | _ -> failwith "unexpected proofstep";; (* ------------------------------------------------------------------------- *) (* Convert sexp representation of formula to shadow syntax. *) (* ------------------------------------------------------------------------- *) let rec folterm_of_sexp sexp = match sexp with Atom(s) when String.sub s 0 1 = "v" -> Variable s | Atom(s) -> Function(s,[]) | List(Atom f::args) -> Function(f,map folterm_of_sexp args) | _ -> failwith "folterm_of_sexp: malformed sexpression term representation";; let folatom_of_sexp sexp = match sexp with Atom(r) -> Literal(true,r,[]) | List(Atom r::args) -> Literal(true,r,map folterm_of_sexp args) | _ -> failwith "folatom_of_sexp: malformed sexpression atom representation";; let folliteral_of_sexp sexp = match sexp with List[Atom "not";sex] -> let Literal(s,r,args) = folatom_of_sexp sex in Literal(not s,r,args) | _ -> folatom_of_sexp sexp;; let rec folclause_of_sexp sexp = match sexp with List[Atom "or";sex1;sex2] -> folclause_of_sexp sex1 @ folclause_of_sexp sex2 | _ -> [folliteral_of_sexp sexp];; (* ------------------------------------------------------------------------- *) (* Convert shadow syntax back into HOL (sometimes given expected type). *) (* Make a crude type postcorrection for equations between variables based *) (* on their types in other terms, if applicable. *) (* It might be nicer to use preterms to get a systematic use of context, but *) (* this is a pretty simple problem. *) (* ------------------------------------------------------------------------- *) let rec hol_of_folterm (btrans_fun,btrans_rel as trp) ty tm = match tm with Variable(x) -> variant (ran btrans_fun) (mk_var(x,ty)) | Function(fs,args) -> let f = apply btrans_fun fs in let tys,rty = nsplit dest_fun_ty args (type_of f) in list_mk_comb(f,map2 (hol_of_folterm trp) tys args);; let hol_of_folliteral (btrans_fun,btrans_rel as trp) lit = match lit with Literal(s,"false",[]) -> if s then mk_const("F",[]) else mk_neg(mk_const("F",[])) | Literal(s,"=",[l;r]) -> let tml_prov = hol_of_folterm trp aty l and tmr_prov = hol_of_folterm trp aty r in let ty = if type_of tml_prov <> aty then type_of tml_prov else if type_of tmr_prov <> aty then type_of tmr_prov else aty in let ptm = mk_eq(hol_of_folterm trp ty l,hol_of_folterm trp ty r) in if s then ptm else mk_neg ptm | Literal(s,rs,args) -> let r = apply btrans_rel rs in let tys,rty = nsplit dest_fun_ty args (type_of r) in let ptm = list_mk_comb(r,map2 (hol_of_folterm trp) tys args) in if s then ptm else mk_neg ptm;; let is_truevar (bf,_) tm = is_var tm && not(mem tm (ran bf));; let rec hol_of_folclause trp cls = match cls with [] -> mk_const("F",[]) | [c] -> hol_of_folliteral trp c | c::cs -> let rawcls = map (hol_of_folliteral trp) cls in let is_truevar tm = is_var tm && not(mem tm (ran(fst trp))) && not(mem tm (ran(snd trp))) in let und,dec = partition (fun t -> is_eq t && is_truevar(lhs t) && is_truevar(rhs t)) rawcls in if und = [] || dec = [] then list_mk_disj rawcls else let cxt = map dest_var (filter is_truevar (freesl dec)) in let correct t = try let l,r = dest_eq t in let ls = fst(dest_var l) and rs = fst(dest_var r) in let ty = try assoc ls cxt with Failure _ -> assoc rs cxt in mk_eq(mk_var(ls,ty),mk_var(rs,ty)) with Failure _ -> t in list_mk_disj(map correct rawcls);; (* ------------------------------------------------------------------------- *) (* Composed map from sexp to HOL items. *) (* ------------------------------------------------------------------------- *) let hol_of_term trp ty sexp = hol_of_folterm trp ty (folterm_of_sexp sexp);; let hol_of_literal trp sexp = hol_of_folliteral trp (folliteral_of_sexp sexp);; let hol_of_clause trp sexp = hol_of_folclause trp (folclause_of_sexp sexp);; (* ------------------------------------------------------------------------- *) (* Follow paramodulation path *) (* ------------------------------------------------------------------------- *) let rec PARA_SUBS_CONV path eth tm = match path with [] -> if lhs(concl eth) = tm then eth else failwith "PARA_SUBS_CONV" | n::rpt -> let f,args = strip_comb tm in funpow (length args - n) RATOR_CONV (RAND_CONV (PARA_SUBS_CONV rpt eth)) tm;; (* ------------------------------------------------------------------------- *) (* Pull forward disjunct in clause using prover9/Ivy director string. *) (* ------------------------------------------------------------------------- *) let FRONT1_DISJ_CONV = GEN_REWRITE_CONV I [TAUT `a \/ b \/ c <=> b \/ a \/ c`] ORELSEC GEN_REWRITE_CONV I [TAUT `a \/ b <=> b \/ a`];; let rec FRONT_DISJ_CONV l tm = match l with [] | ((Atom "1")::_) -> REFL tm | (Atom "2")::t -> (RAND_CONV (FRONT_DISJ_CONV t) THENC FRONT1_DISJ_CONV) tm | _ -> failwith "unexpected director string in clause";; (* ------------------------------------------------------------------------- *) (* For using paramodulating equation, more convenient to put at the back. *) (* ------------------------------------------------------------------------- *) let AP_IMP = let pp = MATCH_MP(TAUT `(a ==> b) ==> !x. x \/ a ==> x \/ b`) in fun t -> SPEC t o pp;; let rec PARA_BACK_CONV eqdir tm = match eqdir with [Atom "1"] when not(is_disj tm) -> REFL tm | [Atom "2"] when not(is_disj tm) -> SYM_CONV tm | Atom "2"::eqs -> RAND_CONV (PARA_BACK_CONV eqs) tm | [Atom "1"; Atom f] when is_disj tm -> let th1 = if f = "2" then LAND_CONV SYM_CONV tm else REFL tm in let tm' = rand(concl th1) in let djs = disjuncts tm' in let th2 = DISJ_ACI_RULE(mk_eq(tm',list_mk_disj(tl djs @ [hd djs]))) in TRANS th1 th2 | _ -> failwith "PARA_BACK_CONV";; (* ------------------------------------------------------------------------- *) (* Do direct resolution on front clauses. *) (* ------------------------------------------------------------------------- *) let RESOLVE = let resrules = map (MATCH_MP o TAUT) [`a /\ ~a ==> F`; `~a /\ a ==> F`; `a /\ (~a \/ b) ==> b`; `~a /\ (a \/ b) ==> b`; `(a \/ b) /\ ~a ==> b`; `(~a \/ b) /\ a ==> b`; `(a \/ b) /\ (~a \/ c) ==> b \/ c`; `(~a \/ b) /\ (a \/ c) ==> b \/ c`] in fun th1 th2 -> let th = CONJ th1 th2 in tryfind (fun f -> f th) resrules;; (* ------------------------------------------------------------------------- *) (* AC rearrangement of disjunction but maybe correcting proforma types in *) (* the target term for equations between variables. *) (* ------------------------------------------------------------------------- *) let ACI_CORRECT th tm = try EQ_MP (DISJ_ACI_RULE(mk_eq(concl th,tm))) th with Failure _ -> let cxt = map dest_var (frees(concl th)) in let rec correct t = if is_disj t then mk_disj(correct(lhand t),correct(rand t)) else if is_neg t then mk_neg(correct(rand t)) else (try let l,r = dest_eq t in let ls = fst(dest_var l) and rs = fst(dest_var r) in let ty = try assoc ls cxt with Failure _ -> assoc rs cxt in mk_eq(mk_var(ls,ty),mk_var(rs,ty)) with Failure _ -> t) in let tm' = correct tm in EQ_MP (DISJ_ACI_RULE(mk_eq(concl th,tm'))) th;; (* ------------------------------------------------------------------------- *) (* Process proof step. *) (* ------------------------------------------------------------------------- *) let rec PROVER9_PATH_CONV l conv = match l with Atom "2"::t -> RAND_CONV(PROVER9_PATH_CONV t conv) | Atom "1"::t -> LAND_CONV(PROVER9_PATH_CONV t conv) | [] -> conv | _ -> failwith "PROVER9_PATH_CONV:unknown path";; let PROVER9_FLIP_CONV tm = if is_neg tm then RAND_CONV SYM_CONV tm else SYM_CONV tm;; let process_proofstep ths trp asms (lab,just,fm) = let tm = hol_of_clause trp fm in match just with List[Atom "input"] -> if is_eq tm && lhs tm = rhs tm then REFL(rand tm) else tryfind (fun th -> PART_MATCH I th tm) ths | List[Atom "flip"; Atom n; List path] -> let th = apply asms n in let nth = CONV_RULE(PROVER9_PATH_CONV path PROVER9_FLIP_CONV) th in if concl nth = tm then nth else failwith "Inconsistency from flip" | List[Atom "instantiate"; Atom "0"; List[List[x;Atom".";y]]] -> let th = REFL(hol_of_term trp aty y) in if concl th = tm then th else failwith "Inconsistency from instantiation of reflexivity" | List[Atom "instantiate"; Atom n; List i] -> let th = apply asms n and ilist = map (fun (List[Atom x;Atom"."; y]) -> (y,x)) i in let xs = map (fun (y,x) -> find_term (fun v -> is_var v && fst(dest_var v) = x) (concl th)) ilist in let ys = map2 (fun (y,x) v -> hol_of_term trp (type_of v) y) ilist xs in INST (zip ys xs) th | List[Atom "paramod"; Atom eqid; List eqdir; Atom tmid; List dir] -> let eth = CONV_RULE (PARA_BACK_CONV eqdir) (apply asms eqid) and tth = apply asms tmid and path = (map (fun (Atom s) -> int_of_string s) dir) in let etm = concl eth in let th = if is_disj etm then let djs = disjuncts etm in let eq = last djs in let fth = CONV_RULE (PARA_SUBS_CONV path (ASSUME eq)) tth in MP (itlist AP_IMP (butlast djs) (DISCH eq fth)) eth else CONV_RULE(PARA_SUBS_CONV path eth) tth in if concl th = tm then th else failwith "Inconsistency from paramodulation" | List[Atom "resolve"; Atom l1; List path1; Atom l2; List path2] -> let th1 = CONV_RULE (FRONT_DISJ_CONV path1) (apply asms l1) and th2 = CONV_RULE (FRONT_DISJ_CONV path2) (apply asms l2) in let th3 = RESOLVE th1 th2 in ACI_CORRECT th3 tm | List[Atom "propositional"; Atom l] -> let th1 = apply asms l in ACI_CORRECT th1 tm | _ -> failwith "process_proofstep: no translation";; let rec process_proofsteps ths trp asms steps = match steps with [] -> asms,[] | ((lab,_,_) as st)::sts -> (try let th = process_proofstep ths trp asms st in process_proofsteps ths trp ((lab |-> th) asms) sts with _ -> asms,steps);; (* ------------------------------------------------------------------------- *) (* Main refutation procedure for clauses *) (* ------------------------------------------------------------------------- *) let PROVER9_REFUTE ths = let fvs = itlist (fun th -> union (freesl(hyp th))) ths [] in let fovars,functions,relations = signature fvs (end_itlist (curry mk_conj) (map concl ths)) ([],[],[]) in let trans_var = itlist2 (fun f n -> f |-> "x"^string_of_int n) fovars (1--length fovars) undefined and trans_fun = itlist2 (fun f n -> f |-> "f"^string_of_int n) functions (1--length functions) undefined and trans_rel = itlist2 (fun f n -> f |-> "R"^string_of_int n) relations (1--length relations) undefined in let cls = map (translate_clause (trans_var,trans_fun,trans_rel) o concl) ths in let p9cls = map (fun c -> prover9_of_clause c ^".\n") cls in let p9str = "clear(bell).\n"^ !prover9_options ^ "formulas(sos).\n"^ itlist (^) p9cls "end_of_list.\n" in let filename_in = Filename.temp_file "prover9" ".in" and filename_out = Filename.temp_file "prover9" ".out" in let _ = file_of_string filename_in p9str in let retcode = Sys.command (prover9 ^ " -f " ^ filename_in ^ " | prooftrans ivy >" ^ filename_out) in if retcode <> 0 then failwith "Prover9 call apparently failed" else let p9proof = string_of_file filename_out in let _ = if !prover9_debugging then () else (ignore(Sys.remove filename_in); ignore(Sys.remove filename_out)) in let List sexps,unp = sexpression(lex(explode(skipheader 0 p9proof))) in (if unp <> [Ident ";;"; Ident "END"; Ident "OF"; Ident "PROOF"; Ident "OBJECT"] then (Format.print_string "Unexpected proof object tail"; Format.print_newline()) else ()); let btrans_fun = itlist (fun (x,y) -> y |-> x) (graph trans_fun) undefined and btrans_rel = itlist (fun (x,y) -> y |-> x) (graph trans_rel) undefined and proof = map parse_proofstep sexps in let asms,undone = process_proofsteps ths (btrans_fun,btrans_rel) undefined proof in find (fun th -> concl th = mk_const("F",[])) (map snd (graph asms));; (* ------------------------------------------------------------------------- *) (* Hence a prover. *) (* ------------------------------------------------------------------------- *) let PROVER9 = let prule = MATCH_MP(TAUT `(~p ==> F) ==> p`) and false_tm = `F` and true_tm = `T` in let init_conv = TOP_DEPTH_CONV BETA_CONV THENC PRESIMP_CONV THENC CONDS_ELIM_CONV THENC NNFC_CONV THENC CNF_CONV THENC DEPTH_BINOP_CONV `(/\)` (SKOLEM_CONV THENC PRENEX_CONV) THENC GEN_REWRITE_CONV REDEPTH_CONV [RIGHT_AND_EXISTS_THM; LEFT_AND_EXISTS_THM] THENC GEN_REWRITE_CONV TOP_DEPTH_CONV [GSYM DISJ_ASSOC] THENC GEN_REWRITE_CONV TOP_DEPTH_CONV [GSYM CONJ_ASSOC] in fun tm -> let tm' = mk_neg tm in let ith = init_conv tm' in let itm = rand(concl ith) in if itm = true_tm then failwith "PROVER9: formula is trivially false" else if itm = false_tm then prule(fst(EQ_IMP_RULE ith)) else let evs,bod = strip_exists itm in let ths = map SPEC_ALL (CONJUNCTS(ASSUME bod)) in let ths' = end_itlist (@) (map (CONJUNCTS o CONV_RULE CNF_CONV) ths) in let rth = PROVER9_REFUTE ths' in let eth = itlist SIMPLE_CHOOSE evs rth in let sth = PROVE_HYP (UNDISCH(fst(EQ_IMP_RULE ith))) eth in prule(DISCH tm' sth);; (* ------------------------------------------------------------------------- *) (* Examples. *) (* ------------------------------------------------------------------------- *) let FRIEND_0 = time PROVER9 `(!x:P. ~friend(x,x)) /\ ~(a:P = b) /\ (!x y. friend(x,y) ==> friend(y,x)) ==> (!x. ?y z. friend(x,y) /\ ~friend(x,z)) \/ (!x. ?y z. ~(y = z) /\ ~friend(x,y) /\ ~friend(x,z))`;; let FRIEND_1 = time PROVER9 `(!x:P. ~friend(x,x)) /\ a IN s /\ b IN s /\ ~(a:P = b) /\ (!x y. friend(x,y) ==> friend(y,x)) ==> (!x. x IN s ==> ?y z. y IN s /\ z IN s /\ friend(x,y) /\ ~friend(x,z)) \/ (!x. x IN s ==> ?y z. y IN s /\ z IN s /\ ~(y = z) /\ ~friend(x,y) /\ ~friend(x,z))`;; let LOS = time PROVER9 `(!x y z. P(x,y) /\ P(y,z) ==> P(x,z)) /\ (!x y z. Q(x,y) /\ Q(y,z) ==> Q(x,z)) /\ (!x y. Q(x,y) ==> Q(y,x)) /\ (!x y. P(x,y) \/ Q(x,y)) /\ ~P(a,b) /\ ~Q(c,d) ==> F`;; let CONWAY_1 = time PROVER9 `(!x. 0 + x = x) /\ (!x y. x + y = y + x) /\ (!x y z. x + (y + z) = (x + y) + z) /\ (!x. 1 * x = x) /\ (!x. x * 1 = x) /\ (!x y z. x * (y * z) = (x * y) * z) /\ (!x. 0 * x = 0) /\ (!x. x * 0 = 0) /\ (!x y z. x * (y + z) = (x * y) + (x * z)) /\ (!x y z. (x + y) * z = (x * z) + (y * z)) /\ (!x y. star(x * y) = 1 + x * star(y * x) * y) /\ (!x y. star(x + y) = star(star(x) * y) * star(x)) ==> star(star(star(1))) = star(star(1))`;; let CONWAY_2 = time PROVER9 `(!x. 0 + x = x) /\ (!x y. x + y = y + x) /\ (!x y z. x + (y + z) = (x + y) + z) /\ (!x. 1 * x = x) /\ (!x. x * 1 = x) /\ (!x y z. x * (y * z) = (x * y) * z) /\ (!x. 0 * x = 0) /\ (!x. x * 0 = 0) /\ (!x y z. x * (y + z) = (x * y) + (x * z)) /\ (!x y z. (x + y) * z = (x * z) + (y * z)) /\ (!x y. star(x * y) = 1 + x * star(y * x) * y) /\ (!x y. star(x + y) = star(star(x) * y) * star(x)) ==> !a. star(star(star(star(a)))) = star(star(star(a)))`;; let ECKMAN_HILTON_1 = time PROVER9 `(!x. 1 * x = x) /\ (!x. x * 1 = x) /\ (!x. 1 + x = x) /\ (!x. x + 1 = x) /\ (!w x y z. (w * x) + (y * z) = (w + y) * (x + z)) ==> !a b. a * b = a + b`;; let ECKMAN_HILTON_2 = time PROVER9 `(!x. 1 * x = x) /\ (!x. x * 1 = x) /\ (!x. 1 + x = x) /\ (!x. x + 1 = x) /\ (!w x y z. (w * x) + (y * z) = (w + y) * (x + z)) ==> !a b. a * b = b * a`;; let ECKMAN_HILTON_3 = time PROVER9 `(!x. 1 * x = x) /\ (!x. x * 1 = x) /\ (!x. 0 + x = x) /\ (!x. x + 0 = x) /\ (!w x y z. (w * x) + (y * z) = (w + y) * (x + z)) ==> !a b. a * b = b * a`;; let ECKMAN_HILTON_4 = time PROVER9 `(!x. 1 * x = x) /\ (!x. x * 1 = x) /\ (!x. 0 + x = x) /\ (!x. x + 0 = x) /\ (!w x y z. (w * x) + (y * z) = (w + y) * (x + z)) ==> !a b. a + b = a * b`;; let DOUBLE_DISTRIB = time PROVER9 `(!x y z. (x * y) * z = (x * z) * (y * z)) /\ (!x y z. z * (x * y) = (z * x) * (z * y)) ==> !a b c. (a * b) * (c * a) = (a * c) * (b * a)`;; let MOORE_PENROSE_PSEUDOINVERSE_UNIQUE = time PROVER9 `X * A * X = X /\ transpose(A * X) = A * X /\ A * X * A = A /\ transpose(X * A) = X * A /\ Y * A * Y = Y /\ transpose(A * Y) = A * Y /\ A * Y * A = A /\ transpose(Y * A) = Y * A /\ (!x y z. (x * y) * z = x * (y * z)) /\ (!x y. transpose(x * y) = transpose(y) * transpose(x)) ==> X = Y`;;