(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* errorlabstrm "AutoRewrite" (str ("Rewriting base "^(bas)^" does not exist.")) let find_rewrites bas = List.rev_map snd (HintDN.find_all (find_base bas)) let find_matches bas pat = let base = find_base bas in let res = HintDN.search_pattern base pat in List.map (fun ((_,rew), esubst, subst) -> rew) res let print_rewrite_hintdb bas = ppnl (str "Database " ++ str bas ++ (Pp.cut ()) ++ prlist_with_sep Pp.cut (fun h -> str (if h.rew_l2r then "rewrite -> " else "rewrite <- ") ++ Printer.pr_lconstr h.rew_lemma ++ str " of type " ++ Printer.pr_lconstr h.rew_type ++ str " then use tactic " ++ Pptactic.pr_glob_tactic (Global.env()) h.rew_tac) (find_rewrites bas)) type raw_rew_rule = loc * constr * bool * raw_tactic_expr (* Applies all the rules of one base *) let one_base general_rewrite_maybe_in tac_main bas = let lrul = find_rewrites bas in let lrul = List.map (fun h -> (h.rew_lemma,h.rew_l2r,Tacinterp.eval_tactic h.rew_tac)) lrul in tclREPEAT_MAIN (tclPROGRESS (List.fold_left (fun tac (csr,dir,tc) -> tclTHEN tac (tclREPEAT_MAIN (tclTHENFIRST (general_rewrite_maybe_in dir csr tc) tac_main))) tclIDTAC lrul)) (* The AutoRewrite tactic *) let autorewrite ?(conds=Naive) tac_main lbas = tclREPEAT_MAIN (tclPROGRESS (List.fold_left (fun tac bas -> tclTHEN tac (one_base (fun dir c tac -> let tac = tac, conds in general_rewrite dir all_occurrences true false ~tac c) tac_main bas)) tclIDTAC lbas)) let autorewrite_multi_in ?(conds=Naive) idl tac_main lbas : tactic = fun gl -> (* let's check at once if id exists (to raise the appropriate error) *) let _ = List.map (Tacmach.pf_get_hyp gl) idl in let general_rewrite_in id = let id = ref id in let to_be_cleared = ref false in fun dir cstr tac gl -> let last_hyp_id = match Tacmach.pf_hyps gl with (last_hyp_id,_,_)::_ -> last_hyp_id | _ -> (* even the hypothesis id is missing *) error ("No such hypothesis: " ^ (string_of_id !id) ^".") in let gl' = general_rewrite_in dir all_occurrences true ~tac:(tac, conds) false !id cstr false gl in let gls = gl'.Evd.it in match gls with g::_ -> (match Environ.named_context_of_val (Goal.V82.hyps gl'.Evd.sigma g) with (lastid,_,_)::_ -> if last_hyp_id <> lastid then begin let gl'' = if !to_be_cleared then tclTHEN (fun _ -> gl') (tclTRY (clear [!id])) gl else gl' in id := lastid ; to_be_cleared := true ; gl'' end else begin to_be_cleared := false ; gl' end | _ -> assert false) (* there must be at least an hypothesis *) | _ -> assert false (* rewriting cannot complete a proof *) in tclMAP (fun id -> tclREPEAT_MAIN (tclPROGRESS (List.fold_left (fun tac bas -> tclTHEN tac (one_base (general_rewrite_in id) tac_main bas)) tclIDTAC lbas))) idl gl let autorewrite_in ?(conds=Naive) id = autorewrite_multi_in ~conds [id] let gen_auto_multi_rewrite conds tac_main lbas cl = let try_do_hyps treat_id l = autorewrite_multi_in ~conds (List.map treat_id l) tac_main lbas in if cl.concl_occs <> all_occurrences_expr & cl.concl_occs <> no_occurrences_expr then error "The \"at\" syntax isn't available yet for the autorewrite tactic." else let compose_tac t1 t2 = match cl.onhyps with | Some [] -> t1 | _ -> tclTHENFIRST t1 t2 in compose_tac (if cl.concl_occs <> no_occurrences_expr then autorewrite ~conds tac_main lbas else tclIDTAC) (match cl.onhyps with | Some l -> try_do_hyps (fun ((_,id),_) -> id) l | None -> fun gl -> (* try to rewrite in all hypothesis (except maybe the rewritten one) *) let ids = Tacmach.pf_ids_of_hyps gl in try_do_hyps (fun id -> id) ids gl) let auto_multi_rewrite ?(conds=Naive) = gen_auto_multi_rewrite conds Refiner.tclIDTAC let auto_multi_rewrite_with ?(conds=Naive) tac_main lbas cl gl = let onconcl = cl.Tacexpr.concl_occs <> no_occurrences_expr in match onconcl,cl.Tacexpr.onhyps with | false,Some [_] | true,Some [] | false,Some [] -> (* autorewrite with .... in clause using tac n'est sur que si clause represente soit le but soit UNE hypothese *) gen_auto_multi_rewrite conds tac_main lbas cl gl | _ -> Util.errorlabstrm "autorewrite" (strbrk "autorewrite .. in .. using can only be used either with a unique hypothesis or on the conclusion.") (* Functions necessary to the library object declaration *) let cache_hintrewrite (_,(rbase,lrl)) = let base = try find_base rbase with e when Errors.noncritical e -> HintDN.empty in let max = try fst (Util.list_last (HintDN.find_all base)) with e when Errors.noncritical e -> 0 in let lrl = HintDN.map (fun (i,h) -> (i + max, h)) lrl in rewtab:=Stringmap.add rbase (HintDN.union lrl base) !rewtab let subst_hintrewrite (subst,(rbase,list as node)) = let list' = HintDN.subst subst list in if list' == list then node else (rbase,list') let classify_hintrewrite x = Libobject.Substitute x (* Declaration of the Hint Rewrite library object *) let inHintRewrite : string * HintDN.t -> Libobject.obj = Libobject.declare_object {(Libobject.default_object "HINT_REWRITE") with Libobject.cache_function = cache_hintrewrite; Libobject.load_function = (fun _ -> cache_hintrewrite); Libobject.subst_function = subst_hintrewrite; Libobject.classify_function = classify_hintrewrite } open Clenv type hypinfo = { hyp_cl : clausenv; hyp_prf : constr; hyp_ty : types; hyp_car : constr; hyp_rel : constr; hyp_l2r : bool; hyp_left : constr; hyp_right : constr; } let evd_convertible env evd x y = try ignore(Unification.w_unify ~flags:Unification.elim_flags env evd Reduction.CONV x y); true (* try ignore(Evarconv.the_conv_x env x y evd); true *) with e when Errors.noncritical e -> false let decompose_applied_relation metas env sigma c ctype left2right = let find_rel ty = let eqclause = Clenv.mk_clenv_from_env env sigma None (c,ty) in let eqclause = if metas then eqclause else clenv_pose_metas_as_evars eqclause (Evd.undefined_metas eqclause.evd) in let (equiv, args) = decompose_app (Clenv.clenv_type eqclause) in let rec split_last_two = function | [c1;c2] -> [],(c1, c2) | x::y::z -> let l,res = split_last_two (y::z) in x::l, res | _ -> raise Not_found in try let others,(c1,c2) = split_last_two args in let ty1, ty2 = Typing.type_of env eqclause.evd c1, Typing.type_of env eqclause.evd c2 in (* if not (evd_convertible env eqclause.evd ty1 ty2) then None *) (* else *) Some { hyp_cl=eqclause; hyp_prf=(Clenv.clenv_value eqclause); hyp_ty = ty; hyp_car=ty1; hyp_rel=mkApp (equiv, Array.of_list others); hyp_l2r=left2right; hyp_left=c1; hyp_right=c2; } with Not_found -> None in match find_rel ctype with | Some c -> Some c | None -> let ctx,t' = Reductionops.splay_prod_assum env sigma ctype in (* Search for underlying eq *) match find_rel (it_mkProd_or_LetIn t' ctx) with | Some c -> Some c | None -> None let find_applied_relation metas loc env sigma c left2right = let ctype = Typing.type_of env sigma c in match decompose_applied_relation metas env sigma c ctype left2right with | Some c -> c | None -> user_err_loc (loc, "decompose_applied_relation", str"The type" ++ spc () ++ Printer.pr_constr_env env ctype ++ spc () ++ str"of this term does not end with an applied relation.") (* To add rewriting rules to a base *) let add_rew_rules base lrul = let counter = ref 0 in let lrul = List.fold_left (fun dn (loc,c,b,t) -> let info = find_applied_relation false loc (Global.env ()) Evd.empty c b in let pat = if b then info.hyp_left else info.hyp_right in let rul = { rew_lemma = c; rew_type = info.hyp_ty; rew_pat = pat; rew_l2r = b; rew_tac = Tacinterp.glob_tactic t} in incr counter; HintDN.add pat (!counter, rul) dn) HintDN.empty lrul in Lib.add_anonymous_leaf (inHintRewrite (base,lrul))