| Quellcodebibliothek Statistik Leitseite products/Sources/formale Sprachen/Cobol/Test-Suite/SQL M/ Datei vom 4.1.2008 mit Größe 3 kB |
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Quelle tacticals.ml Sprache: SML |
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(* * The Rocq Prover / The Rocq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* <O___,, * (see version control and CREDITS file for authors & dates) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************) open Pp open CErrors open Util open Names open Constr open EConstr open Declarations open Tactypes open Proofview open Proofview.Notations open Tacmach module RelDecl = Context.Rel.Declaration module NamedDecl = Context.Named.Declaration (*********************) (* Tacticals *) (*********************) exception FailError of int * Pp.t Lazy.t let catch_failerror (e, info) = match e with | FailError (lvl,s) when lvl > 0 -> tclZERO ~info (FailError (lvl - 1, s)) | e -> Control.check_for_interrupt (); tclUNIT () (************************************************************************) (* Elimination Tacticals *) (************************************************************************) (* The following tacticals allow to apply a tactic to the branches generated by the application of an elimination tactic. Two auxiliary types --branch_args and branch_assumptions-- are used to keep track of some information about the ``branches'' of the elimination. *) let fix_empty_or_and_pattern nv l = (* 1- The syntax does not distinguish between "[ ]" for one clause with no names and "[ ]" for no clause at all *) (* 2- More generally, we admit "[ ]" for any disjunctive pattern of arbitrary length *) match l with | IntroOrPattern [[]] -> IntroOrPattern (List.make nv []) | _ -> l let check_or_and_pattern_size ?loc check_and names branchsigns = let n = Array.length branchsigns in let msg p1 p2 = strbrk "a conjunctive pattern made of " ++ int p1 ++ (if p1 == p2 then mt () else s let err1 p1 p2 = user_err ?loc (str "Expects " ++ msg p1 p2 ++ str ".") in let errn n = user_err ?loc (str "Expects a disjunctive pattern with " ++ int n ++ str " branches.") in let err1' p1 p2 = user_err ?loc (strbrk "Expects a disjunctive pattern with 1 branch or " ++ msg p1 p2 ++ s let errforthcoming ?loc = user_err ?loc (strbrk "Unexpected non atomic pattern.") in match names with | IntroAndPattern l -> if not (Int.equal n 1) then errn n; let l' = List.filter CAst.(function {v=IntroForthcoming _} -> true | {v=IntroNami if l' != [] then errforthcoming ?loc:(List.hd l').CAst.loc; if check_and then let p1 = List.count (fun x -> x) branchsigns.(0) in let p2 = List.length branchsigns.(0) in let p = List.length l in if not (Int.equal p p1 || Int.equal p p2) then err1 p1 p2; if Int.equal p p1 then IntroAndPattern (List.extend branchsigns.(0) (CAst.make @@ IntroNaming Namegen.IntroAnonymous) l) else names else names | IntroOrPattern ll -> if not (Int.equal n (List.length ll)) then if Int.equal n 1 then let p1 = List.count (fun x -> x) branchsigns.(0) in let p2 = List.length branchsigns.(0) in err1' p1 p2 else errn n; names let get_and_check_or_and_pattern_gen ?loc check_and names branchsigns = let names = check_or_and_pattern_size ?loc check_and names branchsigns in match names with | IntroAndPattern l -> [|l|] | IntroOrPattern l -> Array.of_list l let get_and_check_or_and_pattern ?loc = get_and_check_or_and_pattern_gen ?loc true let compute_induction_names check_and branchletsigns = function | None -> Array.make (Array.length branchletsigns) [] | Some {CAst.loc;v=names} -> let names = fix_empty_or_and_pattern (Array.length branchletsigns) names in get_and_check_or_and_pattern_gen check_and ?loc names branchletsigns let is_recursive_argument env self recarg = match Declareops.dest_recarg recarg with | Norec | Mrec (RecArgPrim _) -> false | Mrec (RecArgInd ind) -> Environ.QInd.equal env self ind (* Compute the let-in signature of case analysis or standard induction scheme *) let compute_constructor_signatures env ~rec_flag ((_,k as ity),u) = let rec analrec c recargs = match c, recargs with | RelDecl.LocalAssum _ :: c, recarg::rest -> let rest = analrec c rest in if rec_flag && is_recursive_argument env ity recarg then true :: true :: rest else true :: rest | RelDecl.LocalDef _ :: c, rest -> false :: analrec c rest | [], [] -> [] | _ -> anomaly (Pp.str "compute_constructor_signatures.") in let (mib,mip) = Inductive.lookup_mind_specif env ity in let map (ctx, _) = List.skipn (Context.Rel.length mib.mind_params_ctxt) (List.rev ctx) in let lc = Array.map map mip.mind_nf_lc in let lrecargs = Declareops.dest_subterms mip.mind_recargs in Array.map2 analrec lc lrecargs let tclIDTAC = tclUNIT () let tclTHEN t1 t2 = t1 <*> t2 let tclFAILn ?info lvl msg = let info = match info with (* If the backtrace points here it means the caller didn't save the backtrace correctly *) | None -> Exninfo.reify () | Some info -> info in tclZERO ~info (FailError (lvl,lazy msg)) let tclFAIL ?info msg = tclFAILn ?info 0 msg let tclZEROMSG ?info ?loc msg = let info = match info with (* If the backtrace points here it means the caller didn't save the backtrace correctly *) | None -> Exninfo.reify () | Some info -> info in let info = match loc with | None -> info | Some loc -> Loc.add_loc info loc in let err = UserError msg in tclZERO ~info err (* spiwack: I chose to give the Ltac + the same semantics as [Proofview.tclOR], however, for consistency with the or-else tactical, we may consider wrapping the first argument with [tclPROGRESS]. It strikes me as a bad idea, but consistency can be considered valuable. *) let tclOR t1 t2 = tclINDEPENDENT begin Proofview.tclOR t1 begin fun e -> catch_failerror e <*> t2 end end let tclORD t1 t2 = tclINDEPENDENT begin Proofview.tclOR t1 begin fun e -> catch_failerror e <*> t2 () end end let tclONCE = Proofview.tclONCE let tclEXACTLY_ONCE t = Proofview.tclEXACTLY_ONCE (FailError(0,lazy (assert false))) t let tclIFCATCH t tt te = tclINDEPENDENT begin Proofview.tclIFCATCH t tt (fun e -> catch_failerror e <*> te ()) end let tclORELSE0 t1 t2 = tclINDEPENDENT begin tclORELSE t1 begin fun e -> catch_failerror e <*> t2 end end let tclORELSE0L t1 t2 = tclINDEPENDENTL begin tclORELSE t1 begin fun e -> catch_failerror e <*> t2 end end let tclORELSE t1 t2 = tclORELSE0 (tclPROGRESS t1) t2 let tclTHENS3PARTS t1 l1 repeat l2 = tclINDEPENDENT begin t1 <*> Proofview.tclORELSE (* converts the [SizeMismatch] error into an ltac error *) begin tclEXTEND (Array.to_list l1) repeat (Array.to_list l2) end begin function (e, info) -> match e with | SizeMismatch (i,_)-> let errmsg = str"Incorrect number of goals" ++ spc() ++ str"(expected "++int i++str(String.plural i " tactic") ++ str")" in tclFAIL errmsg | reraise -> tclZERO ~info reraise end end let tclTHENSFIRSTn t1 l repeat = tclTHENS3PARTS t1 l repeat [||] let tclTHENFIRSTn t1 l = tclTHENSFIRSTn t1 l (tclUNIT()) let tclTHENFIRST t1 t2 = tclTHENFIRSTn t1 [|t2|] let tclBINDFIRST t1 t2 = t1 >>= fun ans -> Proofview.Unsafe.tclGETGOALS >>= fun gls -> match gls with | [] -> tclFAIL (str "Expect at least one goal.") | hd::tl -> Proofview.Unsafe.tclSETGOALS [hd] <*> t2 ans >>= fun ans -> Proofview.Unsafe.tclNEWGOALS tl <*> Proofview.tclUNIT ans let tclTHENSLASTn t1 repeat l = tclTHENS3PARTS t1 [||] repeat l let tclTHENLASTn t1 l = tclTHENS3PARTS t1 [||] (tclUNIT()) l let tclTHENLAST t1 t2 = tclTHENLASTn t1 [|t2|] let option_of_failure f x = try Some (f x) with Failure _ -> None let tclBINDLAST t1 t2 = t1 >>= fun ans -> Proofview.Unsafe.tclGETGOALS >>= fun gls -> match option_of_failure List.sep_last gls with | None -> tclFAIL (str "Expect at least one goal.") | Some (last,firstn) -> Proofview.Unsafe.tclSETGOALS [last] <*> t2 ans >>= fun ans -> Proofview.Unsafe.tclGETGOALS >>= fun newgls -> tclEVARMAP >>= fun sigma -> let firstn = Proofview.Unsafe.undefined sigma firstn in Proofview.Unsafe.tclSETGOALS (firstn@newgls) <*> Proofview.tclUNIT ans let tclTHENS t l = tclINDEPENDENT begin t <*>Proofview.tclORELSE (* converts the [SizeMismatch] error into an ltac error *) begin tclDISPATCH l end begin function (e, info) -> match e with | SizeMismatch (i,_)-> let errmsg = str"Incorrect number of goals" ++ spc() ++ str"(expected "++int i++str(String.plural i " tactic") ++ str")" in tclFAIL errmsg | reraise -> tclZERO ~info reraise end end let tclTHENLIST l = List.fold_left tclTHEN (tclUNIT()) l (* [tclMAP f [x1..xn]] builds [(f x1);(f x2);...(f xn)] *) let tclMAP tacfun l = List.fold_right (fun x -> (tclTHEN (tacfun x))) l (tclUNIT()) let tclTRY t = tclORELSE0 t (tclUNIT ()) let tclTRYb t = tclORELSE0L (t <*> tclUNIT true) (tclUNIT false) let tclIFTHENELSE t1 t2 t3 = tclINDEPENDENT begin Proofview.tclIFCATCH t1 (fun () -> t2) (fun (e, info) -> Proofview.tclORELSE t3 (fun e' -> tclZERO ~info e)) end let tclIFTHENSVELSE t1 a t3 = Proofview.tclIFCATCH t1 (fun () -> tclDISPATCH (Array.to_list a)) (fun _ -> t3) let tclIFTHENFIRSTELSE t1 t2 t3 = Proofview.tclIFCATCH t1 (fun () -> tclEXTEND [t2] (tclUNIT ()) []) (fun _ -> t3) let tclIFTHENTRYELSEMUST t1 t2 = tclIFTHENELSE t1 (tclTRY t2) t2 let tclIFTHENFIRSTTRYELSEMUST t1 t2 = tclIFTHENFIRSTELSE t1 (tclTRY t2) t2 (* Try the first tactic that does not fail in a list of tactics *) let rec tclFIRST = function | [] -> let info = Exninfo.reify () in tclZEROMSG ~info (str"No applicable tactic.") | t::rest -> tclORELSE0 t (tclFIRST rest) let rec tclFIRST_PROGRESS_ON tac = function | [] -> tclFAIL (str "No applicable tactic") | [a] -> tac a (* so that returned failure is the one from last item *) | a::tl -> tclORELSE (tac a) (tclFIRST_PROGRESS_ON tac tl) let rec tclDO n t = if n < 0 then let info = Exninfo.reify () in tclZEROMSG ~info (str"Wrong argument : Do needs a positive integer.") else if n = 0 then tclUNIT () else if n = 1 then t else (* Thunk to avoid stack overflow with large n *) tclTHEN t (tclUNIT () >>= fun () -> (tclDO (n-1) t)) let rec tclREPEAT0 t = tclINDEPENDENT begin Proofview.tclIFCATCH t (fun () -> tclCHECKINTERRUPT <*> tclREPEAT0 t) (fun e -> catch_failerror e <*> tclUNIT ()) end let tclREPEAT t = tclREPEAT0 (tclPROGRESS t) let rec tclREPEAT_MAIN0 t = Proofview.tclIFCATCH t (fun () -> tclTRYFOCUS 1 1 (tclREPEAT_MAIN0 t)) (fun e -> catch_failerror e <*> tclUNIT ()) let tclREPEAT_MAIN t = tclREPEAT_MAIN0 (tclPROGRESS t) let tclCOMPLETE t = t >>= fun res -> (tclINDEPENDENT (let info = Exninfo.reify () in tclZEROMSG ~info (str"Proof is not complete.")) ) <*> tclUNIT res (* Try the first that solves the current goal *) let tclSOLVE tacl = tclFIRST (List.map tclCOMPLETE tacl) let tclPROGRESS t = Proofview.tclINDEPENDENT (Proofview.tclPROGRESS t) (* Check that holes in arguments have been resolved *) let check_evar_list env sigma evars origsigma = (* origsigma ⊆ sigma *) (* evars ⊆ sigma *) let reachable = lazy (Evarutil.reachable_from_evars sigma (Evar.Map.domain (Evd.undefined_map origsigma))) in let rec is_undefined_up_to_restriction sigma evk = if Evd.mem origsigma evk then None else let EvarInfo evi = Evd.find sigma evk in match Evd.evar_body evi with | Evd.Evar_empty -> Some (evk, Evd.EvarInfo evi) | Evd.Evar_defined c -> match Constr.kind (EConstr.Unsafe.to_constr c) with | Evar (evk,l) -> is_undefined_up_to_restriction sigma evk | _ -> (* We make the assumption that there is no way to refine an evar remaining after typing from the initial term given to apply/elim and co tactics, is it correct? *) None in Evar.Set.fold (fun evk acc -> match is_undefined_up_to_restriction sigma evk with | Some (evk',evi) -> (* If [evk'] descends from [evk] which descends itself from an originally undefined evar in [origsigma], it is a not a fresh undefined hole from [sigma]. *) if Evar.Set.mem evk (Lazy.force reachable) then acc else evk'::acc | _ -> acc) evars [] let check_evars env sigma extsigma origsigma = (* origsigma ⊆ extsigma ⊆ sigma *) if Evd.undefined_map extsigma != Evd.undefined_map origsigma then match check_evar_list env sigma (Evar.Map.domain (Evd.undefined_map extsigma)) origsigm | [] -> () | evk :: _ -> let EvarInfo evi = Evd.find sigma evk in let (loc,_) = Evd.evar_source evi in Pretype_errors.error_unsolvable_implicit ?loc env sigma evk None let tclMAPDELAYEDWITHHOLES accept_unresolved_holes l tac = let rec aux = function | [] -> tclUNIT () | x :: l -> Proofview.Goal.enter begin fun gl -> let env = Proofview.Goal.env gl in let sigma_initial = Proofview.Goal.sigma gl in let (sigma, x) = x env sigma_initial in Proofview.Unsafe.tclEVARS sigma <*> tac x >>= fun () -> aux l >>= fun () -> if accept_unresolved_holes then tclUNIT () else tclEVARMAP >>= fun sigma_final -> try let () = check_evars env sigma_final sigma sigma_initial in tclUNIT () with e when CErrors.noncritical e -> let e, info = Exninfo.capture e in tclZERO ~info e end in aux l (* The following is basically tclMAPDELAYEDWITHHOLES accept_unresolved_holes [fun _ _ -> (sigma,())] (fun () -> tac) but with value not necessarily in unit *) let with_holes_check ~sigma_initial ~sigma = tclEVARMAP >>= fun sigma_final -> tclENV >>= fun env -> try let () = check_evars env sigma_final sigma sigma_initial in tclUNIT () with e when CErrors.noncritical e -> let e, info = Exninfo.capture e in tclZERO ~info e let tclRUNWITHHOLES accept_unresolved_holes tac0 tac = if accept_unresolved_holes then tac0 >>= tac else tclEVARMAP >>= fun sigma_initial -> tac0 >>= fun v -> tclEVARMAP >>= fun sigma -> if sigma == sigma_initial then tac v else tac v >>= fun v -> with_holes_check ~sigma_initial ~sigma <*> tclUNIT v let tclWITHHOLES accept_unresolved_holes tac sigma = tclEVARMAP >>= fun sigma_initial -> if sigma == sigma_initial then tac else Proofview.Unsafe.tclEVARS sigma <*> tac >>= fun v -> (if accept_unresolved_holes then tclUNIT () else with_holes_check ~sigma_initial ~sigma) < tclUNIT v let tactic_of_delayed d = Proofview.Goal.enter_one ~__LOC__ @@ fun gl -> let sigma, v = pf_apply d gl in Proofview.Unsafe.tclEVARS sigma <*> tclUNIT v let tclDELAYEDWITHHOLES check x tac = Proofview.Goal.enter begin fun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let (sigma, x) = x env sigma in tclWITHHOLES check (tac x) sigma end let tclTIMEOUT n t = Proofview.tclOR (Proofview.tclTIMEOUT n t) begin function (e, info) -> match e with | Logic_monad.Tac_Timeout as e -> let info = Exninfo.reify () in Proofview.tclZERO ~info (FailError (0,lazy (CErrors.print e))) | e -> Proofview.tclZERO ~info e end let tclTIME s t = Proofview.tclTIME s t let nthDecl m gl = let hyps = Proofview.Goal.hyps gl in try List.nth hyps (m-1) with Failure _ -> CErrors.user_err Pp.(str "No such assumption.") let nLastDecls gl n = try List.firstn n (Proofview.Goal.hyps gl) with Failure _ -> CErrors.user_err Pp.(str "Not enough hypotheses in the goal.") let nthHypId m gl = (* We only use [id] *) nthDecl m gl |> NamedDecl.get_id let nthHyp m gl = mkVar (nthHypId m gl) let onNthHypId m tac = Proofview.Goal.enter begin fun gl -> tac (nthHypId m gl) end let onNthHyp m tac = Proofview.Goal.enter begin fun gl -> tac (nthHyp m gl) end let onLastHypId = onNthHypId 1 let onLastHyp = onNthHyp 1 let onNthDecl m tac = Proofview.Goal.enter begin fun gl -> Proofview.tclUNIT (nthDecl m gl) >>= tac end let onLastDecl = onNthDecl 1 let nLastHypsId gl n = List.map (NamedDecl.get_id) (nLastDecls gl n) let nLastHyps gl n = List.map mkVar (nLastHypsId gl n) let ifOnHyp pred tac1 tac2 id = Proofview.Goal.enter begin fun gl -> let typ = Tacmach.pf_get_hyp_typ id gl in if pf_apply pred gl (id,typ) then tac1 id else tac2 id end let onHyps find tac = Proofview.Goal.enter begin fun gl -> tac (find gl) end let onNLastDecls n tac = onHyps (fun gl -> nLastDecls gl n) tac let onNLastHypsId n tac = onHyps (fun gl -> nLastHypsId gl n) tac let onNLastHyps n tac = onHyps (fun gl -> nLastHyps gl n) tac let afterHyp id tac = Proofview.Goal.enter begin fun gl -> let hyps = Proofview.Goal.hyps gl in let rem, _ = List.split_when (NamedDecl.get_id %> Id.equal id) hyps in tac rem end let fullGoal gl = let hyps = Tacmach.pf_ids_of_hyps gl in None :: List.map Option.make hyps let tryAllHyps tac = Proofview.Goal.enter begin fun gl -> let hyps = Tacmach.pf_ids_of_hyps gl in tclFIRST_PROGRESS_ON tac hyps end let tryAllHypsAndConcl tac = Proofview.Goal.enter begin fun gl -> tclFIRST_PROGRESS_ON tac (fullGoal gl) end let onClause tac cl = Proofview.Goal.enter begin fun gl -> let hyps = Tacmach.pf_ids_of_hyps gl in tclMAP tac (Locusops.simple_clause_of (fun () -> hyps) cl) end let fullGoal gl = None :: List.map Option.make (Tacmach.pf_ids_of_hyps gl) let onAllHyps tac = Proofview.Goal.enter begin fun gl -> tclMAP tac (Tacmach.pf_ids_of_hyps gl) end let onAllHypsAndConcl tac = Proofview.Goal.enter begin fun gl -> tclMAP tac (fullGoal gl) end let elimination_sort_of_goal gl = (* Retyping will expand evars anyway. *) let c = Proofview.Goal.concl gl in pf_apply Retyping.get_sort_quality_of gl c let elimination_sort_of_hyp id gl = (* Retyping will expand evars anyway. *) let c = pf_get_hyp_typ id gl in pf_apply Retyping.get_sort_quality_of gl c let elimination_sort_of_clause id gl = match id with | None -> elimination_sort_of_goal gl | Some id -> elimination_sort_of_hyp id gl let pf_constr_of_global ref = Proofview.tclEVARMAP >>= fun sigma -> Proofview.tclENV >>= fun env -> let (sigma, c) = Evd.fresh_global env sigma ref in Proofview.Unsafe.tclEVARS sigma <*> Proofview.tclUNIT c let tclTYPEOFTHEN ?refresh c tac = Proofview.Goal.enter (fun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let (sigma, t) = Typing.type_of ?refresh env sigma c in Proofview.Unsafe.tclEVARS sigma <*> tac sigma t) let tclSELECT = Goal_select.tclSELECT ¤ Dauer der Verarbeitung: 0.14 Sekunden (vorverarbeitet) ¤*© Formatika GbR, Deutschland |
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2026-03-28