From 6b649aba925b6f7462da07599fe67ebb12a3460e Mon Sep 17 00:00:00 2001 From: Samuel Mimram Date: Wed, 28 Jul 2004 21:54:47 +0000 Subject: Imported Upstream version 8.0pl1 --- tactics/tacinterp.ml | 2236 ++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2236 insertions(+) create mode 100644 tactics/tacinterp.ml (limited to 'tactics/tacinterp.ml') diff --git a/tactics/tacinterp.ml b/tactics/tacinterp.ml new file mode 100644 index 00000000..2080b5dc --- /dev/null +++ b/tactics/tacinterp.ml @@ -0,0 +1,2236 @@ +(************************************************************************) +(* v * The Coq Proof Assistant / The Coq Development Team *) +(* x + | MetaId (loc,_) -> error_syntactic_metavariables_not_allowed loc + +type ltac_type = + | LtacFun of ltac_type + | LtacBasic + | LtacTactic + +(* Values for interpretation *) +type value = + | VTactic of loc * tactic (* For mixed ML/Ltac tactics (e.g. Tauto) *) + | VRTactic of (goal list sigma * validation) (* For Match results *) + (* Not a true value *) + | VFun of (identifier*value) list * identifier option list * glob_tactic_expr + | VVoid + | VInteger of int + | VIntroPattern of intro_pattern_expr (* includes idents which are not *) + (* bound as in "Intro H" but which may be bound *) + (* later, as in "tac" in "Intro H; tac" *) + | VConstr of constr (* includes idents known bound and references *) + | VConstr_context of constr + | VRec of value ref + +let locate_tactic_call loc = function + | VTactic (_,t) -> VTactic (loc,t) + | v -> v + +let locate_error_in_file dir = function + | Stdpp.Exc_located (loc,e) -> Error_in_file ("",(true,dir,loc),e) + | e -> Error_in_file ("",(true,dir,dummy_loc),e) + +let catch_error loc tac g = + try tac g + with e when loc <> dummy_loc -> + match e with + | Stdpp.Exc_located (_,e) -> raise (Stdpp.Exc_located (loc,e)) + | e -> raise (Stdpp.Exc_located (loc,e)) + +(* Signature for interpretation: val_interp and interpretation functions *) +type interp_sign = + { lfun : (identifier * value) list; + debug : debug_info } + +let check_is_value = function + | VRTactic _ -> (* These are goals produced by Match *) + error "Immediate match producing tactics not allowed in local definitions" + | _ -> () + +(* For tactic_of_value *) +exception NotTactic + +(* Gives the constr corresponding to a Constr_context tactic_arg *) +let constr_of_VConstr_context = function + | VConstr_context c -> c + | _ -> + errorlabstrm "constr_of_VConstr_context" (str "not a context variable") + +(* Displays a value *) +let pr_value env = function + | VVoid -> str "()" + | VInteger n -> int n + | VIntroPattern ipat -> pr_intro_pattern ipat + | VConstr c -> Printer.prterm_env env c + | VConstr_context c -> Printer.prterm_env env c + | (VTactic _ | VRTactic _ | VFun _ | VRec _) -> str "" + +(* Transforms a named_context into a (string * constr) list *) +let make_hyps = List.map (fun (id,_,typ) -> (id, typ)) + +(* Transforms an id into a constr if possible, or fails *) +let constr_of_id env id = + construct_reference (Environ.named_context env) id + +(* To embed several objects in Coqast.t *) +let ((tactic_in : (interp_sign -> raw_tactic_expr) -> Dyn.t), + (tactic_out : Dyn.t -> (interp_sign -> raw_tactic_expr))) = + create "tactic" + +let ((value_in : value -> Dyn.t), + (value_out : Dyn.t -> value)) = create "value" + +let tacticIn t = TacArg (TacDynamic (dummy_loc,tactic_in t)) +let tacticOut = function + | TacArg (TacDynamic (_,d)) -> + if (tag d) = "tactic" then + tactic_out d + else + anomalylabstrm "tacticOut" (str "Dynamic tag should be tactic") + | ast -> + anomalylabstrm "tacticOut" + (str "Not a Dynamic ast: " (* ++ print_ast ast*) ) + +let valueIn t = TacDynamic (dummy_loc,value_in t) +let valueOut = function + | TacDynamic (_,d) -> + if (tag d) = "value" then + value_out d + else + anomalylabstrm "valueOut" (str "Dynamic tag should be value") + | ast -> + anomalylabstrm "valueOut" (str "Not a Dynamic ast: ") + +(* To embed constr in Coqast.t *) +let constrIn t = CDynamic (dummy_loc,Pretyping.constr_in t) +let constrOut = function + | CDynamic (_,d) -> + if (Dyn.tag d) = "constr" then + Pretyping.constr_out d + else + anomalylabstrm "constrOut" (str "Dynamic tag should be constr") + | ast -> + anomalylabstrm "constrOut" (str "Not a Dynamic ast") +let loc = dummy_loc + +(* Table of interpretation functions *) +let interp_tab = + (Hashtbl.create 17 : (string , interp_sign -> Coqast.t -> value) Hashtbl.t) + +(* Adds an interpretation function *) +let interp_add (ast_typ,interp_fun) = + try + Hashtbl.add interp_tab ast_typ interp_fun + with + Failure _ -> + errorlabstrm "interp_add" + (str "Cannot add the interpretation function for " ++ str ast_typ ++ str " twice") + +(* Adds a possible existing interpretation function *) +let overwriting_interp_add (ast_typ,interp_fun) = + if Hashtbl.mem interp_tab ast_typ then + begin + Hashtbl.remove interp_tab ast_typ; + warning ("Overwriting definition of tactic interpreter command " ^ ast_typ) + end; + Hashtbl.add interp_tab ast_typ interp_fun + +(* Finds the interpretation function corresponding to a given ast type *) +let look_for_interp = Hashtbl.find interp_tab + +(* Globalizes the identifier *) + +let find_reference env qid = + (* We first look for a variable of the current proof *) + match repr_qualid qid with + | (d,id) when repr_dirpath d = [] & List.mem id (ids_of_context env) + -> VarRef id + | _ -> Nametab.locate qid + +let coerce_to_reference env = function + | VConstr c -> + (try reference_of_constr c + with Not_found -> invalid_arg_loc (loc, "Not a reference")) + | v -> errorlabstrm "coerce_to_reference" + (str "The value" ++ spc () ++ pr_value env v ++ + str "cannot be coerced to a reference") + +(* turns a value into an evaluable reference *) +let error_not_evaluable s = + errorlabstrm "evalref_of_ref" + (str "Cannot coerce" ++ spc () ++ s ++ spc () ++ + str "to an evaluable reference") + +let coerce_to_evaluable_ref env c = + let ev = match c with + | VConstr c when isConst c -> EvalConstRef (destConst c) + | VConstr c when isVar c -> EvalVarRef (destVar c) + | VIntroPattern (IntroIdentifier id) + when Environ.evaluable_named id env -> EvalVarRef id + | _ -> error_not_evaluable (pr_value env c) + in + if not (Tacred.is_evaluable env ev) then + error_not_evaluable (pr_value env c); + ev + +let coerce_to_inductive = function + | VConstr c when isInd c -> destInd c + | x -> + try + let r = match x with + | VConstr c -> reference_of_constr c + | _ -> failwith "" in + errorlabstrm "coerce_to_inductive" + (Printer.pr_global r ++ str " is not an inductive type") + with _ -> + errorlabstrm "coerce_to_inductive" + (str "Found an argument which should be an inductive type") + + +(* Table of "pervasives" macros tactics (e.g. auto, simpl, etc.) *) +let atomic_mactab = ref Idmap.empty +let add_primitive_tactic s tac = + (if not !Options.v7 then + let id = id_of_string s in + atomic_mactab := Idmap.add id tac !atomic_mactab) + +let _ = + if not !Options.v7 then + (let nocl = {onhyps=Some[];onconcl=true; concl_occs=[]} in + List.iter + (fun (s,t) -> add_primitive_tactic s (TacAtom(dummy_loc,t))) + [ "red", TacReduce(Red false,nocl); + "hnf", TacReduce(Hnf,nocl); + "simpl", TacReduce(Simpl None,nocl); + "compute", TacReduce(Cbv all_flags,nocl); + "intro", TacIntroMove(None,None); + "intros", TacIntroPattern []; + "assumption", TacAssumption; + "cofix", TacCofix None; + "trivial", TacTrivial None; + "auto", TacAuto(None,None); + "left", TacLeft NoBindings; + "right", TacRight NoBindings; + "split", TacSplit(false,NoBindings); + "constructor", TacAnyConstructor None; + "reflexivity", TacReflexivity; + "symmetry", TacSymmetry nocl + ]; + List.iter + (fun (s,t) -> add_primitive_tactic s t) + [ "idtac",TacId ""; + "fail", TacFail(ArgArg 0,""); + "fresh", TacArg(TacFreshId None) + ]) + +let lookup_atomic id = Idmap.find id !atomic_mactab +let is_atomic id = Idmap.mem id !atomic_mactab +let is_atomic_kn kn = + let (_,_,l) = repr_kn kn in + is_atomic (id_of_label l) + +(* Summary and Object declaration *) +let mactab = ref Gmap.empty + +let lookup r = Gmap.find r !mactab + +let _ = + let init () = mactab := Gmap.empty in + let freeze () = !mactab in + let unfreeze fs = mactab := fs in + Summary.declare_summary "tactic-definition" + { Summary.freeze_function = freeze; + Summary.unfreeze_function = unfreeze; + Summary.init_function = init; + Summary.survive_module = false; + Summary.survive_section = false } + +(* Interpretation of extra generic arguments *) +type glob_sign = { + ltacvars : identifier list * identifier list; + (* ltac variables and the subset of vars introduced by Intro/Let/... *) + ltacrecvars : (identifier * ltac_constant) list; + (* ltac recursive names *) + gsigma : Evd.evar_map; + genv : Environ.env } + +type interp_genarg_type = + (glob_sign -> raw_generic_argument -> glob_generic_argument) * + (interp_sign -> goal sigma -> glob_generic_argument -> + closed_generic_argument) * + (Names.substitution -> glob_generic_argument -> glob_generic_argument) + +let extragenargtab = + ref (Gmap.empty : (string,interp_genarg_type) Gmap.t) +let add_interp_genarg id f = + extragenargtab := Gmap.add id f !extragenargtab +let lookup_genarg id = + try Gmap.find id !extragenargtab + with Not_found -> failwith ("No interpretation function found for entry "^id) + +let lookup_genarg_glob id = let (f,_,_) = lookup_genarg id in f +let lookup_interp_genarg id = let (_,f,_) = lookup_genarg id in f +let lookup_genarg_subst id = let (_,_,f) = lookup_genarg id in f + +(* Unboxes VRec *) +let unrec = function + | VRec v -> !v + | a -> a + +(*****************) +(* Globalization *) +(*****************) + +(* We have identifier <| global_reference <| constr *) + +let find_ident id sign = + List.mem id (fst sign.ltacvars) or + List.mem id (ids_of_named_context (Environ.named_context sign.genv)) + +let find_recvar qid sign = List.assoc qid sign.ltacrecvars + +(* a "var" is a ltac var or a var introduced by an intro tactic *) +let find_var id sign = List.mem id (fst sign.ltacvars) + +(* a "ctxvar" is a var introduced by an intro tactic (Intro/LetTac/...) *) +let find_ctxvar id sign = List.mem id (snd sign.ltacvars) + +(* a "ltacvar" is an ltac var (Let-In/Fun/...) *) +let find_ltacvar id sign = find_var id sign & not (find_ctxvar id sign) + +let find_hyp id sign = + List.mem id (ids_of_named_context (Environ.named_context sign.genv)) + +(* Globalize a name introduced by Intro/LetTac/... ; it is allowed to *) +(* be fresh in which case it is binding later on *) +let intern_ident l ist id = + (* We use identifier both for variables and new names; thus nothing to do *) + if not (find_ident id ist) then l:=(id::fst !l,id::snd !l); + id + +let intern_name l ist = function + | Anonymous -> Anonymous + | Name id -> Name (intern_ident l ist id) + +let vars_of_ist (lfun,_,_,env) = + List.fold_left (fun s id -> Idset.add id s) + (vars_of_env env) lfun + +let get_current_context () = + try Pfedit.get_current_goal_context () + with e when Logic.catchable_exception e -> + (Evd.empty, Global.env()) + +let strict_check = ref false + +let adjust_loc loc = if !strict_check then dummy_loc else loc + +(* Globalize a name which must be bound -- actually just check it is bound *) +let intern_hyp ist (loc,id as locid) = + let (_,env) = get_current_context () in + if not !strict_check then + locid + else if find_ident id ist then + (dummy_loc,id) + else + Pretype_errors.error_var_not_found_loc loc id + +let intern_hyp_or_metaid ist id = intern_hyp ist (skip_metaid id) + +let intern_int_or_var ist = function + | ArgVar locid as x -> ArgVar (intern_hyp ist locid) + | ArgArg n as x -> x + +let intern_inductive ist = function + | Ident (loc,id) when find_var id ist -> ArgVar (loc,id) + | r -> ArgArg (Nametab.global_inductive r) + +exception NotSyntacticRef + +let locate_reference qid = + match Nametab.extended_locate qid with + | TrueGlobal ref -> ref + | SyntacticDef kn -> + match Syntax_def.search_syntactic_definition loc kn with + | Rawterm.RRef (_,ref) -> ref + | _ -> raise NotSyntacticRef + +let intern_global_reference ist = function + | Ident (loc,id) as r when find_var id ist -> ArgVar (loc,id) + | r -> + let loc,qid = qualid_of_reference r in + try ArgArg (loc,locate_reference qid) + with _ -> + error_global_not_found_loc loc qid + +let intern_tac_ref ist = function + | Ident (loc,id) when find_ltacvar id ist -> ArgVar (loc,id) + | Ident (loc,id) -> + ArgArg (loc, + try find_recvar id ist + with Not_found -> locate_tactic (make_short_qualid id)) + | r -> + let (loc,qid) = qualid_of_reference r in + ArgArg (loc,locate_tactic qid) + +let intern_tactic_reference ist r = + try intern_tac_ref ist r + with Not_found -> + let (loc,qid) = qualid_of_reference r in + error_global_not_found_loc loc qid + +let intern_constr_reference strict ist = function + | Ident (_,id) when (not strict & find_hyp id ist) or find_ctxvar id ist -> + RVar (loc,id), None + | r -> + let loc,qid = qualid_of_reference r in + RRef (loc,locate_reference qid), if strict then None else Some (CRef r) + +let intern_reference strict ist = function + | Ident (loc,id) when is_atomic id -> Tacexp (lookup_atomic id) + | r -> + (try Reference (intern_tac_ref ist r) + with Not_found -> + (try + ConstrMayEval (ConstrTerm (intern_constr_reference strict ist r)) + with Not_found -> + (match r with + | Ident (loc,id) when not strict -> + IntroPattern (IntroIdentifier id) + | _ -> + let (loc,qid) = qualid_of_reference r in + error_global_not_found_loc loc qid))) + +let rec intern_intro_pattern lf ist = function + | IntroOrAndPattern l -> + IntroOrAndPattern (intern_case_intro_pattern lf ist l) + | IntroWildcard -> + IntroWildcard + | IntroIdentifier id -> + IntroIdentifier (intern_ident lf ist id) + +and intern_case_intro_pattern lf ist = + List.map (List.map (intern_intro_pattern lf ist)) + +let intern_quantified_hypothesis ist x = + (* We use identifier both for variables and quantified hyps (no way to + statically check the existence of a quantified hyp); thus nothing to do *) + x + +let intern_constr {ltacvars=lfun; gsigma=sigma; genv=env} c = + let warn = if !strict_check then fun x -> x else Constrintern.for_grammar in + let c' = + warn (Constrintern.interp_rawconstr_gen false sigma env + false (fst lfun,[])) c in + begin if Options.do_translate () then try + (* Try to infer old case and type annotations *) + let _ = Pretyping.understand_gen_tcc sigma env [] None c' in + (* msgerrnl (str "Typage tactique OK");*) + () + with e -> (*msgerrnl (str "Warning: can't type tactic");*) () end; + (c',if !strict_check then None else Some c) + +(* Globalize bindings *) +let intern_binding ist (loc,b,c) = + (loc,intern_quantified_hypothesis ist b,intern_constr ist c) + +let intern_bindings ist = function + | NoBindings -> NoBindings + | ImplicitBindings l -> ImplicitBindings (List.map (intern_constr ist) l) + | ExplicitBindings l -> ExplicitBindings (List.map (intern_binding ist) l) + +let intern_constr_with_bindings ist (c,bl) = + (intern_constr ist c, intern_bindings ist bl) + +let intern_clause_pattern ist (l,occl) = + let rec check = function + | (hyp,l) :: rest -> (intern_hyp ist (skip_metaid hyp),l)::(check rest) + | [] -> [] + in (l,check occl) + + (* TODO: catch ltac vars *) +let intern_induction_arg ist = function + | ElimOnConstr c -> ElimOnConstr (intern_constr ist c) + | ElimOnAnonHyp n as x -> x + | ElimOnIdent (loc,id) as x -> + if !strict_check then + (* If in a defined tactic, no intros-until *) + ElimOnConstr (intern_constr ist (CRef (Ident (dummy_loc,id)))) + else + ElimOnIdent (loc,id) + +(* Globalizes a reduction expression *) +let intern_evaluable ist = function + | Ident (loc,id) as r when find_ltacvar id ist -> ArgVar (loc,id) + | Ident (_,id) when + (not !strict_check & find_hyp id ist) or find_ctxvar id ist -> + ArgArg (EvalVarRef id, None) + | r -> + let loc,qid = qualid_of_reference r in + try + let e = match locate_reference qid with + | ConstRef c -> EvalConstRef c + | VarRef c -> EvalVarRef c + | _ -> error_not_evaluable (pr_reference r) in + let short_name = match r with + | Ident (loc,id) when not !strict_check -> Some (loc,id) + | _ -> None in + ArgArg (e,short_name) + with + | NotSyntacticRef -> error_not_evaluable (pr_reference r) + | Not_found -> + match r with + | Ident (loc,id) when not !strict_check -> + ArgArg (EvalVarRef id, Some (loc,id)) + | _ -> error_global_not_found_loc loc qid + +let intern_unfold ist (l,qid) = (l,intern_evaluable ist qid) + +let intern_flag ist red = + { red with rConst = List.map (intern_evaluable ist) red.rConst } + +let intern_constr_occurrence ist (l,c) = (l,intern_constr ist c) + +let intern_redexp ist = function + | Unfold l -> Unfold (List.map (intern_unfold ist) l) + | Fold l -> Fold (List.map (intern_constr ist) l) + | Cbv f -> Cbv (intern_flag ist f) + | Lazy f -> Lazy (intern_flag ist f) + | Pattern l -> Pattern (List.map (intern_constr_occurrence ist) l) + | Simpl o -> Simpl (option_app (intern_constr_occurrence ist) o) + | (Red _ | Hnf as r) -> r + | ExtraRedExpr (s,c) -> ExtraRedExpr (s, intern_constr ist c) + +let intern_inversion_strength lf ist = function + | NonDepInversion (k,idl,ids) -> + NonDepInversion (k,List.map (intern_hyp_or_metaid ist) idl, + option_app (intern_intro_pattern lf ist) ids) + | DepInversion (k,copt,ids) -> + DepInversion (k, option_app (intern_constr ist) copt, + option_app (intern_intro_pattern lf ist) ids) + | InversionUsing (c,idl) -> + InversionUsing (intern_constr ist c, List.map (intern_hyp_or_metaid ist) idl) + +(* Interprets an hypothesis name *) +let intern_hyp_location ist (id,occs,hl) = + (intern_hyp ist (skip_metaid id), occs, hl) + +(* Reads a pattern *) +let intern_pattern evc env lfun = function + | Subterm (ido,pc) -> + let (metas,pat) = interp_constrpattern_gen evc env lfun pc in + ido, metas, Subterm (ido,pat) + | Term pc -> + let (metas,pat) = interp_constrpattern_gen evc env lfun pc in + None, metas, Term pat + +let intern_constr_may_eval ist = function + | ConstrEval (r,c) -> ConstrEval (intern_redexp ist r,intern_constr ist c) + | ConstrContext (locid,c) -> + ConstrContext (intern_hyp ist locid,intern_constr ist c) + | ConstrTypeOf c -> ConstrTypeOf (intern_constr ist c) + | ConstrTerm c -> ConstrTerm (intern_constr ist c) + +(* Reads the hypotheses of a Match Context rule *) +let rec intern_match_context_hyps evc env lfun = function + | (Hyp ((_,na) as locna,mp))::tl -> + let ido, metas1, pat = intern_pattern evc env lfun mp in + let lfun, metas2, hyps = intern_match_context_hyps evc env lfun tl in + let lfun' = name_cons na (option_cons ido lfun) in + lfun', metas1@metas2, Hyp (locna,pat)::hyps + | [] -> lfun, [], [] + +(* Utilities *) +let rec filter_some = function + | None :: l -> filter_some l + | Some a :: l -> a :: filter_some l + | [] -> [] + +let extract_names lrc = + List.fold_right + (fun ((loc,name),_) l -> + if List.mem name l then + user_err_loc + (loc, "intern_tactic", str "This variable is bound several times"); + name::l) + lrc [] + +let extract_let_names lrc = + List.fold_right + (fun ((loc,name),_,_) l -> + if List.mem name l then + user_err_loc + (loc, "glob_tactic", str "This variable is bound several times"); + name::l) + lrc [] + + +let clause_app f = function + { onhyps=None; onconcl=b;concl_occs=nl } -> + { onhyps=None; onconcl=b; concl_occs=nl } + | { onhyps=Some l; onconcl=b;concl_occs=nl } -> + { onhyps=Some(List.map f l); onconcl=b;concl_occs=nl} + +(* Globalizes tactics : raw_tactic_expr -> glob_tactic_expr *) +let rec intern_atomic lf ist x = + match (x:raw_atomic_tactic_expr) with + (* Basic tactics *) + | TacIntroPattern l -> + TacIntroPattern (List.map (intern_intro_pattern lf ist) l) + | TacIntrosUntil hyp -> TacIntrosUntil (intern_quantified_hypothesis ist hyp) + | TacIntroMove (ido,ido') -> + TacIntroMove (option_app (intern_ident lf ist) ido, + option_app (intern_hyp ist) ido') + | TacAssumption -> TacAssumption + | TacExact c -> TacExact (intern_constr ist c) + | TacApply cb -> TacApply (intern_constr_with_bindings ist cb) + | TacElim (cb,cbo) -> + TacElim (intern_constr_with_bindings ist cb, + option_app (intern_constr_with_bindings ist) cbo) + | TacElimType c -> TacElimType (intern_constr ist c) + | TacCase cb -> TacCase (intern_constr_with_bindings ist cb) + | TacCaseType c -> TacCaseType (intern_constr ist c) + | TacFix (idopt,n) -> TacFix (option_app (intern_ident lf ist) idopt,n) + | TacMutualFix (id,n,l) -> + let f (id,n,c) = (intern_ident lf ist id,n,intern_constr ist c) in + TacMutualFix (intern_ident lf ist id, n, List.map f l) + | TacCofix idopt -> TacCofix (option_app (intern_ident lf ist) idopt) + | TacMutualCofix (id,l) -> + let f (id,c) = (intern_ident lf ist id,intern_constr ist c) in + TacMutualCofix (intern_ident lf ist id, List.map f l) + | TacCut c -> TacCut (intern_constr ist c) + | TacTrueCut (na,c) -> + TacTrueCut (intern_name lf ist na, intern_constr ist c) + | TacForward (b,na,c) -> + TacForward (b,intern_name lf ist na,intern_constr ist c) + | TacGeneralize cl -> TacGeneralize (List.map (intern_constr ist) cl) + | TacGeneralizeDep c -> TacGeneralizeDep (intern_constr ist c) + | TacLetTac (na,c,cls) -> + let na = intern_name lf ist na in + TacLetTac (na,intern_constr ist c, + (clause_app (intern_hyp_location ist) cls)) + | TacInstantiate (n,c,cls) -> + TacInstantiate (n,intern_constr ist c, + (clause_app (intern_hyp_location ist) cls)) + + (* Automation tactics *) + | TacTrivial l -> TacTrivial l + | TacAuto (n,l) -> TacAuto (n,l) + | TacAutoTDB n -> TacAutoTDB n + | TacDestructHyp (b,id) -> TacDestructHyp(b,intern_hyp ist id) + | TacDestructConcl -> TacDestructConcl + | TacSuperAuto (n,l,b1,b2) -> TacSuperAuto (n,l,b1,b2) + | TacDAuto (n,p) -> TacDAuto (n,p) + + (* Derived basic tactics *) + | TacSimpleInduction (h,ids) -> + TacSimpleInduction (intern_quantified_hypothesis ist h,ids) + | TacNewInduction (c,cbo,(ids,ids')) -> + TacNewInduction (intern_induction_arg ist c, + option_app (intern_constr_with_bindings ist) cbo, + (option_app (intern_intro_pattern lf ist) ids,ids')) + | TacSimpleDestruct h -> + TacSimpleDestruct (intern_quantified_hypothesis ist h) + | TacNewDestruct (c,cbo,(ids,ids')) -> + TacNewDestruct (intern_induction_arg ist c, + option_app (intern_constr_with_bindings ist) cbo, + (option_app (intern_intro_pattern lf ist) ids,ids')) + | TacDoubleInduction (h1,h2) -> + let h1 = intern_quantified_hypothesis ist h1 in + let h2 = intern_quantified_hypothesis ist h2 in + TacDoubleInduction (h1,h2) + | TacDecomposeAnd c -> TacDecomposeAnd (intern_constr ist c) + | TacDecomposeOr c -> TacDecomposeOr (intern_constr ist c) + | TacDecompose (l,c) -> let l = List.map (intern_inductive ist) l in + TacDecompose (l,intern_constr ist c) + | TacSpecialize (n,l) -> TacSpecialize (n,intern_constr_with_bindings ist l) + | TacLApply c -> TacLApply (intern_constr ist c) + + (* Context management *) + | TacClear l -> TacClear (List.map (intern_hyp_or_metaid ist) l) + | TacClearBody l -> TacClearBody (List.map (intern_hyp_or_metaid ist) l) + | TacMove (dep,id1,id2) -> + TacMove (dep,intern_hyp_or_metaid ist id1,intern_hyp_or_metaid ist id2) + | TacRename (id1,id2) -> TacRename (intern_hyp_or_metaid ist id1, intern_hyp_or_metaid ist id2) + + (* Constructors *) + | TacLeft bl -> TacLeft (intern_bindings ist bl) + | TacRight bl -> TacRight (intern_bindings ist bl) + | TacSplit (b,bl) -> TacSplit (b,intern_bindings ist bl) + | TacAnyConstructor t -> TacAnyConstructor (option_app (intern_tactic ist) t) + | TacConstructor (n,bl) -> TacConstructor (n, intern_bindings ist bl) + + (* Conversion *) + | TacReduce (r,cl) -> + TacReduce (intern_redexp ist r, clause_app (intern_hyp_location ist) cl) + | TacChange (occl,c,cl) -> + TacChange (option_app (intern_constr_occurrence ist) occl, + intern_constr ist c, clause_app (intern_hyp_location ist) cl) + + (* Equivalence relations *) + | TacReflexivity -> TacReflexivity + | TacSymmetry idopt -> + TacSymmetry (clause_app (intern_hyp_location ist) idopt) + | TacTransitivity c -> TacTransitivity (intern_constr ist c) + + (* Equality and inversion *) + | TacInversion (inv,hyp) -> + TacInversion (intern_inversion_strength lf ist inv, + intern_quantified_hypothesis ist hyp) + + (* For extensions *) + | TacExtend (loc,opn,l) -> + let _ = lookup_tactic opn in + TacExtend (adjust_loc loc,opn,List.map (intern_genarg ist) l) + | TacAlias (loc,s,l,(dir,body)) -> + let (l1,l2) = ist.ltacvars in + let ist' = { ist with ltacvars = ((List.map fst l)@l1,l2) } in + let l = List.map (fun (id,a) -> (strip_meta id,intern_genarg ist a)) l in + try TacAlias (loc,s,l,(dir,intern_tactic ist' body)) + with e -> raise (locate_error_in_file (string_of_dirpath dir) e) + +and intern_tactic ist tac = (snd (intern_tactic_seq ist tac) : glob_tactic_expr) + +and intern_tactic_seq ist = function + (* Traducteur v7->v8 *) + | TacAtom (_,TacReduce (Unfold [_,Ident (_,id)],_)) + when string_of_id id = "INZ" & !Options.translate_syntax + -> ist.ltacvars, (TacId "") + (* Fin traducteur v7->v8 *) + + | TacAtom (loc,t) -> + let lf = ref ist.ltacvars in + let t = intern_atomic lf ist t in + !lf, TacAtom (adjust_loc loc, t) + | TacFun tacfun -> ist.ltacvars, TacFun (intern_tactic_fun ist tacfun) + | TacLetRecIn (lrc,u) -> + let names = extract_names lrc in + let (l1,l2) = ist.ltacvars in + let ist = { ist with ltacvars = (names@l1,l2) } in + let lrc = List.map (fun (n,b) -> (n,intern_tactic_fun ist b)) lrc in + ist.ltacvars, TacLetRecIn (lrc,intern_tactic ist u) + | TacLetIn (l,u) -> + let l = List.map + (fun (n,c,b) -> + (n,option_app (intern_tactic ist) c, intern_tacarg !strict_check ist b)) l in + let (l1,l2) = ist.ltacvars in + let ist' = { ist with ltacvars = ((extract_let_names l)@l1,l2) } in + ist.ltacvars, TacLetIn (l,intern_tactic ist' u) + | TacMatchContext (lr,lmr) -> + ist.ltacvars, TacMatchContext(lr, intern_match_rule ist lmr) + | TacMatch (c,lmr) -> + ist.ltacvars, TacMatch (intern_tactic ist c,intern_match_rule ist lmr) + | TacId _ as x -> ist.ltacvars, x + | TacFail (n,x) -> ist.ltacvars, TacFail (intern_int_or_var ist n,x) + | TacProgress tac -> ist.ltacvars, TacProgress (intern_tactic ist tac) + | TacAbstract (tac,s) -> ist.ltacvars, TacAbstract (intern_tactic ist tac,s) + | TacThen (t1,t2) -> + let lfun', t1 = intern_tactic_seq ist t1 in + let lfun'', t2 = intern_tactic_seq { ist with ltacvars = lfun' } t2 in + lfun'', TacThen (t1,t2) + | TacThens (t,tl) -> + let lfun', t = intern_tactic_seq ist t in + (* Que faire en cas de (tac complexe avec Match et Thens; tac2) ?? *) + lfun', + TacThens (t, List.map (intern_tactic { ist with ltacvars = lfun' }) tl) + | TacDo (n,tac) -> + ist.ltacvars, TacDo (intern_int_or_var ist n,intern_tactic ist tac) + | TacTry tac -> ist.ltacvars, TacTry (intern_tactic ist tac) + | TacInfo tac -> ist.ltacvars, TacInfo (intern_tactic ist tac) + | TacRepeat tac -> ist.ltacvars, TacRepeat (intern_tactic ist tac) + | TacOrelse (tac1,tac2) -> + ist.ltacvars, TacOrelse (intern_tactic ist tac1,intern_tactic ist tac2) + | TacFirst l -> ist.ltacvars, TacFirst (List.map (intern_tactic ist) l) + | TacSolve l -> ist.ltacvars, TacSolve (List.map (intern_tactic ist) l) + | TacArg a -> ist.ltacvars, TacArg (intern_tacarg true ist a) + +and intern_tactic_fun ist (var,body) = + let (l1,l2) = ist.ltacvars in + let lfun' = List.rev_append (filter_some var) l1 in + (var,intern_tactic { ist with ltacvars = (lfun',l2) } body) + +and intern_tacarg strict ist = function + | TacVoid -> TacVoid + | Reference r -> intern_reference strict ist r + | IntroPattern ipat -> + let lf = ref([],[]) in (*How to know what names the intropattern binds?*) + IntroPattern (intern_intro_pattern lf ist ipat) + | Integer n -> Integer n + | ConstrMayEval c -> ConstrMayEval (intern_constr_may_eval ist c) + | MetaIdArg (loc,s) -> + (* $id can occur in Grammar tactic... *) + let id = id_of_string s in + if find_ltacvar id ist or Options.do_translate() + then Reference (ArgVar (adjust_loc loc,strip_meta id)) + else error_syntactic_metavariables_not_allowed loc + | TacCall (loc,f,l) -> + TacCall (loc, + intern_tactic_reference ist f, + List.map (intern_tacarg !strict_check ist) l) + | TacFreshId _ as x -> x + | Tacexp t -> Tacexp (intern_tactic ist t) + | TacDynamic(loc,t) as x -> + (match tag t with + | "tactic" | "value" | "constr" -> x + | s -> anomaly_loc (loc, "", + str "Unknown dynamic: <" ++ str s ++ str ">")) + +(* Reads the rules of a Match Context or a Match *) +and intern_match_rule ist = function + | (All tc)::tl -> + All (intern_tactic ist tc) :: (intern_match_rule ist tl) + | (Pat (rl,mp,tc))::tl -> + let {ltacvars=(lfun,l2); gsigma=sigma; genv=env} = ist in + let lfun',metas1,hyps = intern_match_context_hyps sigma env lfun rl in + let ido,metas2,pat = intern_pattern sigma env lfun mp in + let metas = list_uniquize (metas1@metas2) in + let ist' = { ist with ltacvars = (metas@(option_cons ido lfun'),l2) } in + Pat (hyps,pat,intern_tactic ist' tc) :: (intern_match_rule ist tl) + | [] -> [] + +and intern_genarg ist x = + match genarg_tag x with + | BoolArgType -> in_gen globwit_bool (out_gen rawwit_bool x) + | IntArgType -> in_gen globwit_int (out_gen rawwit_int x) + | IntOrVarArgType -> + in_gen globwit_int_or_var + (intern_int_or_var ist (out_gen rawwit_int_or_var x)) + | StringArgType -> + in_gen globwit_string (out_gen rawwit_string x) + | PreIdentArgType -> + in_gen globwit_pre_ident (out_gen rawwit_pre_ident x) + | IntroPatternArgType -> + let lf = ref ([],[]) in + (* how to know which names are bound by the intropattern *) + in_gen globwit_intro_pattern + (intern_intro_pattern lf ist (out_gen rawwit_intro_pattern x)) + | IdentArgType -> + let lf = ref ([],[]) in + in_gen globwit_ident(intern_ident lf ist (out_gen rawwit_ident x)) + | HypArgType -> + in_gen globwit_var (intern_hyp ist (out_gen rawwit_var x)) + | RefArgType -> + in_gen globwit_ref (intern_global_reference ist (out_gen rawwit_ref x)) + | SortArgType -> + in_gen globwit_sort (out_gen rawwit_sort x) + | ConstrArgType -> + in_gen globwit_constr (intern_constr ist (out_gen rawwit_constr x)) + | ConstrMayEvalArgType -> + in_gen globwit_constr_may_eval + (intern_constr_may_eval ist (out_gen rawwit_constr_may_eval x)) + | QuantHypArgType -> + in_gen globwit_quant_hyp + (intern_quantified_hypothesis ist (out_gen rawwit_quant_hyp x)) + | RedExprArgType -> + in_gen globwit_red_expr (intern_redexp ist (out_gen rawwit_red_expr x)) + | TacticArgType -> + in_gen globwit_tactic (intern_tactic ist (out_gen rawwit_tactic x)) + | CastedOpenConstrArgType -> + in_gen globwit_casted_open_constr + (intern_constr ist (out_gen rawwit_casted_open_constr x)) + | ConstrWithBindingsArgType -> + in_gen globwit_constr_with_bindings + (intern_constr_with_bindings ist (out_gen rawwit_constr_with_bindings x)) + | BindingsArgType -> + in_gen globwit_bindings + (intern_bindings ist (out_gen rawwit_bindings x)) + | List0ArgType _ -> app_list0 (intern_genarg ist) x + | List1ArgType _ -> app_list1 (intern_genarg ist) x + | OptArgType _ -> app_opt (intern_genarg ist) x + | PairArgType _ -> app_pair (intern_genarg ist) (intern_genarg ist) x + | ExtraArgType s -> lookup_genarg_glob s ist x + +(************* End globalization ************) + +(***************************************************************************) +(* Evaluation/interpretation *) + +(* Associates variables with values and gives the remaining variables and + values *) +let head_with_value (lvar,lval) = + let rec head_with_value_rec lacc = function + | ([],[]) -> (lacc,[],[]) + | (vr::tvr,ve::tve) -> + (match vr with + | None -> head_with_value_rec lacc (tvr,tve) + | Some v -> head_with_value_rec ((v,ve)::lacc) (tvr,tve)) + | (vr,[]) -> (lacc,vr,[]) + | ([],ve) -> (lacc,[],ve) + in + head_with_value_rec [] (lvar,lval) + +(* Gives a context couple if there is a context identifier *) +let give_context ctxt = function + | None -> [] + | Some id -> [id,VConstr_context ctxt] + +(* Reads a pattern by substituing vars of lfun *) +let eval_pattern lfun c = + let lvar = List.map (fun (id,c) -> (id,pattern_of_constr c)) lfun in + instantiate_pattern lvar c + +let read_pattern evc env lfun = function + | Subterm (ido,pc) -> Subterm (ido,eval_pattern lfun pc) + | Term pc -> Term (eval_pattern lfun pc) + +(* Reads the hypotheses of a Match Context rule *) +let cons_and_check_name id l = + if List.mem id l then + user_err_loc (loc,"read_match_context_hyps", + str ("Hypothesis pattern-matching variable "^(string_of_id id)^ + " used twice in the same pattern")) + else id::l + +let rec read_match_context_hyps evc env lfun lidh = function + | (Hyp ((loc,na) as locna,mp))::tl -> + let lidh' = name_fold cons_and_check_name na lidh in + Hyp (locna,read_pattern evc env lfun mp):: + (read_match_context_hyps evc env lfun lidh' tl) + | [] -> [] + +(* Reads the rules of a Match Context or a Match *) +let rec read_match_rule evc env lfun = function + | (All tc)::tl -> (All tc)::(read_match_rule evc env lfun tl) + | (Pat (rl,mp,tc))::tl -> + Pat (read_match_context_hyps evc env lfun [] rl, + read_pattern evc env lfun mp,tc) + ::(read_match_rule evc env lfun tl) + | [] -> [] + +(* For Match Context and Match *) +exception No_match +exception Not_coherent_metas +exception Eval_fail of string + +let is_failure = function + | FailError _ | Stdpp.Exc_located (_,FailError _) -> true + | _ -> false + +let is_match_catchable = function + | No_match | Eval_fail _ -> true + | e -> is_failure e or Logic.catchable_exception e + +(* Verifies if the matched list is coherent with respect to lcm *) +let rec verify_metas_coherence gl lcm = function + | (num,csr)::tl -> + if (List.for_all (fun (a,b) -> a<>num or pf_conv_x gl b csr) lcm) then + (num,csr)::(verify_metas_coherence gl lcm tl) + else + raise Not_coherent_metas + | [] -> [] + +(* Tries to match a pattern and a constr *) +let apply_matching pat csr = + try + (matches pat csr) + with + PatternMatchingFailure -> raise No_match + +(* Tries to match one hypothesis pattern with a list of hypotheses *) +let apply_one_mhyp_context ist env gl lmatch (hypname,pat) (lhyps,nocc) = + let get_id_couple id = function +(* | Name idpat -> [idpat,VIdentifier id]*) + | Name idpat -> [idpat,VConstr (mkVar id)] + | Anonymous -> [] in + let rec apply_one_mhyp_context_rec nocc = function + | (id,hyp)::tl as hyps -> + (match pat with + | Term t -> + (try + let lmeta = verify_metas_coherence gl lmatch (matches t hyp) in + (get_id_couple id hypname,lmeta,(id,hyp),(tl,0)) + with + | PatternMatchingFailure | Not_coherent_metas -> + apply_one_mhyp_context_rec 0 tl) + | Subterm (ic,t) -> + (try + let (lm,ctxt) = sub_match nocc t hyp in + let lmeta = verify_metas_coherence gl lmatch lm in + ((get_id_couple id hypname)@(give_context ctxt ic), + lmeta,(id,hyp),(hyps,nocc + 1)) + with + | NextOccurrence _ -> + apply_one_mhyp_context_rec 0 tl + | Not_coherent_metas -> + apply_one_mhyp_context_rec (nocc + 1) hyps)) + | [] -> + db_hyp_pattern_failure ist.debug env (hypname,pat); + raise No_match + in + apply_one_mhyp_context_rec nocc lhyps + +let constr_to_id loc = function + | VConstr c when isVar c -> destVar c + | _ -> invalid_arg_loc (loc, "Not an identifier") + +let constr_to_qid loc c = + try shortest_qualid_of_global Idset.empty (reference_of_constr c) + with _ -> invalid_arg_loc (loc, "Not a global reference") + +(* Debug reference *) +let debug = ref DebugOff + +(* Sets the debugger mode *) +let set_debug pos = debug := pos + +(* Gives the state of debug *) +let get_debug () = !debug + +(* Interprets an identifier which must be fresh *) +let interp_ident ist id = + try match List.assoc id ist.lfun with + | VIntroPattern (IntroIdentifier id) -> id + | VConstr c as v when isVar c -> + (* This happends e.g. in definitions like "Tac H = Clear H; Intro H" *) + (* c is then expected not to belong to the proof context *) + (* would be checkable if env were known from interp_ident *) + destVar c + | _ -> user_err_loc(loc,"interp_ident", str "An ltac name (" ++ pr_id id ++ + str ") should have been bound to an identifier") + with Not_found -> id + +let interp_intro_pattern_var ist id = + try match List.assoc id ist.lfun with + | VIntroPattern ipat -> ipat + | VConstr c as v when isVar c -> + (* This happends e.g. in definitions like "Tac H = Clear H; Intro H" *) + (* c is then expected not to belong to the proof context *) + (* would be checkable if env were known from interp_ident *) + IntroIdentifier (destVar c) + | _ -> user_err_loc(loc,"interp_ident", str "An ltac name (" ++ pr_id id ++ + str ") should have been bound to an introduction pattern") + with Not_found -> IntroIdentifier id + +let interp_int lfun (loc,id) = + try match List.assoc id lfun with + | VInteger n -> n + | _ -> user_err_loc(loc,"interp_int",str "should be bound to an integer") + with Not_found -> user_err_loc (loc,"interp_int",str "Unbound variable") + +let interp_int_or_var ist = function + | ArgVar locid -> interp_int ist.lfun locid + | ArgArg n -> n + +let constr_of_value env = function + | VConstr csr -> csr + | VIntroPattern (IntroIdentifier id) -> constr_of_id env id + | _ -> raise Not_found + +let is_variable env id = + List.mem id (ids_of_named_context (Environ.named_context env)) + +let variable_of_value env = function + | VConstr c as v when isVar c -> destVar c + | VIntroPattern (IntroIdentifier id) when is_variable env id -> id + | _ -> raise Not_found + +(* Extract a variable from a value, if any *) +let id_of_Identifier = variable_of_value + +(* Extract a constr from a value, if any *) +let constr_of_VConstr = constr_of_value + +(* Interprets an variable *) +let interp_var ist gl (loc,id) = + (* Look first in lfun for a value coercible to a variable *) + try + let v = List.assoc id ist.lfun in + try variable_of_value (pf_env gl) v + with Not_found -> + errorlabstrm "coerce_to_variable" + (str "Cannot coerce" ++ spc () ++ pr_value (pf_env gl) v ++ spc () ++ + str "to a variable") + with Not_found -> + (* Then look if bound in the proof context at calling time *) + if is_variable (pf_env gl) id then id + else + user_err_loc (loc,"eval_variable",pr_id id ++ str " not found") + +(* Interprets an existing hypothesis (i.e. a declared variable) *) +let interp_hyp = interp_var + +let interp_name ist = function + | Anonymous -> Anonymous + | Name id -> Name (interp_ident ist id) + +let interp_clause_pattern ist gl (l,occl) = + let rec check acc = function + | (hyp,l) :: rest -> + let hyp = interp_hyp ist gl hyp in + if List.mem hyp acc then + error ("Hypothesis "^(string_of_id hyp)^" occurs twice"); + (hyp,l)::(check (hyp::acc) rest) + | [] -> [] + in (l,check [] occl) + +(* Interprets a qualified name *) +let interp_reference ist env = function + | ArgArg (_,r) -> r + | ArgVar (loc,id) -> coerce_to_reference env (unrec (List.assoc id ist.lfun)) + +let pf_interp_reference ist gl = interp_reference ist (pf_env gl) + +let interp_inductive ist = function + | ArgArg r -> r + | ArgVar (_,id) -> coerce_to_inductive (unrec (List.assoc id ist.lfun)) + +let interp_evaluable ist env = function + | ArgArg (r,Some (loc,id)) -> + (* Maybe [id] has been introduced by Intro-like tactics *) + (try match Environ.lookup_named id env with + | (_,Some _,_) -> EvalVarRef id + | _ -> error_not_evaluable (pr_id id) + with Not_found -> + match r with + | EvalConstRef _ -> r + | _ -> Pretype_errors.error_var_not_found_loc loc id) + | ArgArg (r,None) -> r + | ArgVar (_,id) -> + coerce_to_evaluable_ref env (unrec (List.assoc id ist.lfun)) + +(* Interprets an hypothesis name *) +let interp_hyp_location ist gl (id,occs,hl) = (interp_hyp ist gl id,occs,hl) + +let interp_clause ist gl { onhyps=ol; onconcl=b; concl_occs=occs } = + { onhyps=option_app(List.map (interp_hyp_location ist gl)) ol; + onconcl=b; + concl_occs=occs } + +(* Interpretation of constructions *) + +(* Extract the constr list from lfun *) +let rec constr_list_aux env = function + | (id,v)::tl -> + let (l1,l2) = constr_list_aux env tl in + (try ((id,constr_of_value env v)::l1,l2) + with Not_found -> + let ido = match v with + | VIntroPattern (IntroIdentifier id0) -> Some id0 + | _ -> None in + (l1,(id,ido)::l2)) + | [] -> ([],[]) + +let constr_list ist env = constr_list_aux env ist.lfun + +(*Extract the identifier list from lfun: join all branches (what to do else?)*) +let rec intropattern_ids = function + | IntroIdentifier id -> [id] + | IntroOrAndPattern ll -> + List.flatten (List.map intropattern_ids (List.flatten ll)) + | IntroWildcard -> [] + +let rec extract_ids = function + | (id,VIntroPattern ipat)::tl -> intropattern_ids ipat @ extract_ids tl + | _::tl -> extract_ids tl + | [] -> [] + +let retype_list sigma env lst = + List.fold_right (fun (x,csr) a -> + try (x,Retyping.get_judgment_of env sigma csr)::a with + | Anomaly _ -> a) lst [] + +let interp_casted_constr ocl ist sigma env (c,ce) = + let (l1,l2) = constr_list ist env in + let tl1 = retype_list sigma env l1 in + let csr = + match ce with + | None -> + Pretyping.understand_gen_ltac sigma env (tl1,l2) ocl c + (* If at toplevel (ce<>None), the error can be due to an incorrect + context at globalization time: we retype with the now known + intros/lettac/inversion hypothesis names *) + | Some c -> interp_constr_gen sigma env (l1,l2) c ocl + in + db_constr ist.debug env csr; + csr + +let interp_constr ist sigma env c = + interp_casted_constr None ist sigma env c + +(* Interprets an open constr expression casted by the current goal *) +let pf_interp_casted_openconstr ist gl (c,ce) = + let sigma = project gl in + let env = pf_env gl in + let (ltacvars,l) = constr_list ist env in + let typs = retype_list sigma env ltacvars in + let ocl = Some (pf_concl gl) in + match ce with + | None -> + Pretyping.understand_gen_tcc sigma env typs ocl c + (* If at toplevel (ce<>None), the error can be due to an incorrect + context at globalization time: we retype with the now known + intros/lettac/inversion hypothesis names *) + | Some c -> interp_openconstr_gen sigma env (ltacvars,l) c ocl + +(* Interprets a constr expression *) +let pf_interp_constr ist gl = + interp_constr ist (project gl) (pf_env gl) + +(* Interprets a constr expression casted by the current goal *) +let pf_interp_casted_constr ist gl c = + interp_casted_constr (Some(pf_concl gl)) ist (project gl) (pf_env gl) c + +(* Interprets a reduction expression *) +let interp_unfold ist env (l,qid) = + (l,interp_evaluable ist env qid) + +let interp_flag ist env red = + { red with rConst = List.map (interp_evaluable ist env) red.rConst } + +let interp_pattern ist sigma env (l,c) = (l,interp_constr ist sigma env c) + +let pf_interp_pattern ist gl = interp_pattern ist (project gl) (pf_env gl) + +let redexp_interp ist sigma env = function + | Unfold l -> Unfold (List.map (interp_unfold ist env) l) + | Fold l -> Fold (List.map (interp_constr ist sigma env) l) + | Cbv f -> Cbv (interp_flag ist env f) + | Lazy f -> Lazy (interp_flag ist env f) + | Pattern l -> Pattern (List.map (interp_pattern ist sigma env) l) + | Simpl o -> Simpl (option_app (interp_pattern ist sigma env) o) + | (Red _ | Hnf as r) -> r + | ExtraRedExpr (s,c) -> ExtraRedExpr (s,interp_constr ist sigma env c) + +let pf_redexp_interp ist gl = redexp_interp ist (project gl) (pf_env gl) + +let interp_may_eval f ist gl = function + | ConstrEval (r,c) -> + let redexp = pf_redexp_interp ist gl r in + pf_reduction_of_redexp gl redexp (f ist gl c) + | ConstrContext ((loc,s),c) -> + (try + let ic = f ist gl c + and ctxt = constr_of_VConstr_context (List.assoc s ist.lfun) in + subst_meta [special_meta,ic] ctxt + with + | Not_found -> + user_err_loc (loc, "interp_may_eval", + str "Unbound context identifier" ++ pr_id s)) + | ConstrTypeOf c -> pf_type_of gl (f ist gl c) + | ConstrTerm c -> f ist gl c + +(* Interprets a constr expression possibly to first evaluate *) +let interp_constr_may_eval ist gl c = + let csr = interp_may_eval pf_interp_constr ist gl c in + begin + db_constr ist.debug (pf_env gl) csr; + csr + end + +let rec interp_intro_pattern ist = function + | IntroOrAndPattern l -> IntroOrAndPattern (interp_case_intro_pattern ist l) + | IntroWildcard -> IntroWildcard + | IntroIdentifier id -> interp_intro_pattern_var ist id + +and interp_case_intro_pattern ist = + List.map (List.map (interp_intro_pattern ist)) + +(* Quantified named or numbered hypothesis or hypothesis in context *) +(* (as in Inversion) *) +let interp_quantified_hypothesis ist = function + | AnonHyp n -> AnonHyp n + | NamedHyp id -> + try match List.assoc id ist.lfun with + | VInteger n -> AnonHyp n + | VIntroPattern (IntroIdentifier id) -> NamedHyp id + | _ -> raise Not_found + with Not_found -> NamedHyp id + +(* Quantified named or numbered hypothesis or hypothesis in context *) +(* (as in Inversion) *) +let interp_declared_or_quantified_hypothesis ist gl = function + | AnonHyp n -> AnonHyp n + | NamedHyp id -> + try match List.assoc id ist.lfun with + | VInteger n -> AnonHyp n + | v -> NamedHyp (variable_of_value (pf_env gl) v) + with Not_found -> NamedHyp id + +let interp_induction_arg ist gl = function + | ElimOnConstr c -> ElimOnConstr (pf_interp_constr ist gl c) + | ElimOnAnonHyp n as x -> x + | ElimOnIdent (loc,id) -> + if Tactics.is_quantified_hypothesis id gl then ElimOnIdent (loc,id) + else ElimOnConstr + (pf_interp_constr ist gl (RVar (loc,id),Some (CRef (Ident (loc,id))))) + +let interp_binding ist gl (loc,b,c) = + (loc,interp_quantified_hypothesis ist b,pf_interp_constr ist gl c) + +let interp_bindings ist gl = function +| NoBindings -> NoBindings +| ImplicitBindings l -> ImplicitBindings (List.map (pf_interp_constr ist gl) l) +| ExplicitBindings l -> ExplicitBindings (List.map (interp_binding ist gl) l) + +let interp_constr_with_bindings ist gl (c,bl) = + (pf_interp_constr ist gl c, interp_bindings ist gl bl) + +(* Interprets an l-tac expression into a value *) +let rec val_interp ist gl (tac:glob_tactic_expr) = + + let value_interp ist = match tac with + (* Immediate evaluation *) + | TacFun (it,body) -> VFun (ist.lfun,it,body) + | TacLetRecIn (lrc,u) -> letrec_interp ist gl lrc u + | TacLetIn (l,u) -> + let addlfun = interp_letin ist gl l in + val_interp { ist with lfun=addlfun@ist.lfun } gl u + | TacMatchContext (lr,lmr) -> interp_match_context ist gl lr lmr + | TacMatch (c,lmr) -> interp_match ist gl c lmr + | TacArg a -> interp_tacarg ist gl a + (* Delayed evaluation *) + | t -> VTactic (dummy_loc,eval_tactic ist t) + + in check_for_interrupt (); + match ist.debug with + | DebugOn lev -> + debug_prompt lev gl tac (fun v -> value_interp {ist with debug=v}) + | _ -> value_interp ist + +and eval_tactic ist = function + | TacAtom (loc,t) -> fun gl -> catch_error loc (interp_atomic ist gl t) gl + | TacFun (it,body) -> assert false + | TacLetRecIn (lrc,u) -> assert false + | TacLetIn (l,u) -> assert false + | TacMatchContext _ -> assert false + | TacMatch (c,lmr) -> assert false + | TacId s -> tclIDTAC_MESSAGE s + | TacFail (n,s) -> tclFAIL (interp_int_or_var ist n) s + | TacProgress tac -> tclPROGRESS (interp_tactic ist tac) + | TacAbstract (tac,s) -> Tactics.tclABSTRACT s (interp_tactic ist tac) + | TacThen (t1,t2) -> tclTHEN (interp_tactic ist t1) (interp_tactic ist t2) + | TacThens (t,tl) -> + tclTHENS (interp_tactic ist t) (List.map (interp_tactic ist) tl) + | TacDo (n,tac) -> tclDO (interp_int_or_var ist n) (interp_tactic ist tac) + | TacTry tac -> tclTRY (interp_tactic ist tac) + | TacInfo tac -> tclINFO (interp_tactic ist tac) + | TacRepeat tac -> tclREPEAT (interp_tactic ist tac) + | TacOrelse (tac1,tac2) -> + tclORELSE (interp_tactic ist tac1) (interp_tactic ist tac2) + | TacFirst l -> tclFIRST (List.map (interp_tactic ist) l) + | TacSolve l -> tclSOLVE (List.map (interp_tactic ist) l) + | TacArg a -> assert false + +and interp_ltac_reference isapplied ist gl = function + | ArgVar (loc,id) -> unrec (List.assoc id ist.lfun) + | ArgArg (loc,r) -> + let v = val_interp {lfun=[];debug=ist.debug} gl (lookup r) in + if isapplied then v else locate_tactic_call loc v + +and interp_tacarg ist gl = function + | TacVoid -> VVoid + | Reference r -> interp_ltac_reference false ist gl r + | Integer n -> VInteger n + | IntroPattern ipat -> VIntroPattern ipat + | ConstrMayEval c -> VConstr (interp_constr_may_eval ist gl c) + | MetaIdArg (loc,id) -> assert false + | TacCall (loc,f,l) -> + let fv = interp_ltac_reference true ist gl f + and largs = List.map (interp_tacarg ist gl) l in + List.iter check_is_value largs; + interp_app ist gl fv largs loc + | TacFreshId idopt -> + let s = match idopt with None -> "H" | Some s -> s in + let id = Tactics.fresh_id (extract_ids ist.lfun) (id_of_string s) gl in + VIntroPattern (IntroIdentifier id) + | Tacexp t -> val_interp ist gl t + | TacDynamic(_,t) -> + let tg = (tag t) in + if tg = "tactic" then + let f = (tactic_out t) in + val_interp ist gl + (intern_tactic { + ltacvars = (List.map fst ist.lfun,[]); ltacrecvars = []; + gsigma = project gl; genv = pf_env gl } + (f ist)) + else if tg = "value" then + value_out t + else if tg = "constr" then + VConstr (Pretyping.constr_out t) + else + anomaly_loc (loc, "Tacinterp.val_interp", + (str "Unknown dynamic: <" ++ str (Dyn.tag t) ++ str ">")) + +(* Interprets an application node *) +and interp_app ist gl fv largs loc = + match fv with + | VFun(olfun,var,body) -> + let (newlfun,lvar,lval)=head_with_value (var,largs) in + if lvar=[] then + let v = val_interp { ist with lfun=newlfun@olfun } gl body in + if lval=[] then locate_tactic_call loc v + else interp_app ist gl v lval loc + else + VFun(newlfun@olfun,lvar,body) + | _ -> + user_err_loc (loc, "Tacinterp.interp_app", + (str"Illegal tactic application")) + +(* Gives the tactic corresponding to the tactic value *) +and tactic_of_value vle g = + match vle with + | VRTactic res -> res + | VTactic (loc,tac) -> catch_error loc tac g + | VFun _ -> error "A fully applied tactic is expected" + | _ -> raise NotTactic + +(* Evaluation with FailError catching *) +and eval_with_fail ist tac goal = + try + (match val_interp ist goal tac with + | VTactic (loc,tac) -> VRTactic (catch_error loc tac goal) + | a -> a) + with + | Stdpp.Exc_located (_,FailError (0,s)) | FailError (0,s) -> + raise (Eval_fail s) + | Stdpp.Exc_located (s',FailError (lvl,s)) -> + raise (Stdpp.Exc_located (s',FailError (lvl - 1, s))) + | FailError (lvl,s) -> + raise (FailError (lvl - 1, s)) + +(* Interprets recursive expressions *) +and letrec_interp ist gl lrc u = + let lref = Array.to_list (Array.make (List.length lrc) (ref VVoid)) in + let lenv = + List.fold_right2 (fun ((loc,name),_) vref l -> (name,VRec vref)::l) + lrc lref [] in + let lve = List.map (fun ((loc,name),(var,body)) -> + (name,VFun(lenv@ist.lfun,var,body))) lrc in + begin + List.iter2 (fun vref (_,ve) -> vref:=ve) lref lve; + val_interp { ist with lfun=lve@ist.lfun } gl u + end + +(* Interprets the clauses of a LetIn *) +and interp_letin ist gl = function + | [] -> [] + | ((loc,id),None,t)::tl -> + let v = interp_tacarg ist gl t in + check_is_value v; + (id,v):: (interp_letin ist gl tl) + | ((loc,id),Some com,tce)::tl -> + let env = pf_env gl in + let typ = constr_of_value env (val_interp ist gl com) + and v = interp_tacarg ist gl tce in + let csr = + try + constr_of_value env v + with Not_found -> + try + let t = tactic_of_value v in + let ndc = Environ.named_context env in + start_proof id IsLocal ndc typ (fun _ _ -> ()); + by t; + let (_,({const_entry_body = pft},_,_)) = cook_proof () in + delete_proof (dummy_loc,id); + pft + with | NotTactic -> + delete_proof (dummy_loc,id); + errorlabstrm "Tacinterp.interp_letin" + (str "Term or fully applied tactic expected in Let") + in (id,VConstr (mkCast (csr,typ)))::(interp_letin ist gl tl) + +(* Interprets the Match Context expressions *) +and interp_match_context ist g lr lmr = + let rec apply_goal_sub ist env goal nocc (id,c) csr mt mhyps hyps = + try + let (lgoal,ctxt) = sub_match nocc c csr in + let lctxt = give_context ctxt id in + if mhyps = [] then + let lgoal = List.map (fun (id,c) -> (id,VConstr c)) lgoal in + eval_with_fail { ist with lfun=lgoal@lctxt@ist.lfun } mt goal + else + apply_hyps_context ist env goal mt lgoal mhyps hyps + with + | e when is_failure e -> raise e + | NextOccurrence _ -> raise No_match + | e when is_match_catchable e -> + apply_goal_sub ist env goal (nocc + 1) (id,c) csr mt mhyps hyps in + let rec apply_match_context ist env goal nrs lex lpt = + begin + if lex<>[] then db_pattern_rule ist.debug nrs (List.hd lex); + match lpt with + | (All t)::tl -> + begin + db_mc_pattern_success ist.debug; + try eval_with_fail ist t goal + with e when is_match_catchable e -> + apply_match_context ist env goal (nrs+1) (List.tl lex) tl + end + | (Pat (mhyps,mgoal,mt))::tl -> + let hyps = make_hyps (pf_hyps goal) in + let hyps = if lr then List.rev hyps else hyps in + let mhyps = List.rev mhyps (* Sens naturel *) in + let concl = pf_concl goal in + (match mgoal with + | Term mg -> + (try + (let lgoal = apply_matching mg concl in + begin + db_matched_concl ist.debug (pf_env goal) concl; + if mhyps = [] then + begin + db_mc_pattern_success ist.debug; + let lgoal = List.map (fun (id,c) -> (id,VConstr c)) lgoal in + eval_with_fail {ist with lfun=lgoal@ist.lfun} mt goal + end + else + apply_hyps_context ist env goal mt lgoal mhyps hyps + end) + with + | e when is_match_catchable e -> + begin + (match e with + | No_match -> db_matching_failure ist.debug + | Eval_fail s -> db_eval_failure ist.debug s + | _ -> db_logic_failure ist.debug e); + apply_match_context ist env goal (nrs+1) (List.tl lex) tl + end) + | Subterm (id,mg) -> + (try apply_goal_sub ist env goal 0 (id,mg) concl mt mhyps hyps + with e when is_match_catchable e -> + apply_match_context ist env goal (nrs+1) (List.tl lex) tl)) + | _ -> + errorlabstrm "Tacinterp.apply_match_context" (str + "No matching clauses for match goal") + (v 0 (str "No matching clauses for match goal" ++ + (if ist.debug=DebugOff then + fnl() ++ str "(use \"Debug On\" for more info)" + else mt()))) + end in + let env = pf_env g in + apply_match_context ist env g 0 lmr + (read_match_rule (project g) env (fst (constr_list ist env)) lmr) + +(* Tries to match the hypotheses in a Match Context *) +and apply_hyps_context ist env goal mt lgmatch mhyps hyps = + let rec apply_hyps_context_rec lfun lmatch lhyps_rest current = function + | Hyp ((_,hypname),mhyp)::tl as mhyps -> + let (lids,lm,hyp_match,next) = + apply_one_mhyp_context ist env goal lmatch (hypname,mhyp) current in + db_matched_hyp ist.debug (pf_env goal) hyp_match hypname; + begin + try + let nextlhyps = list_except hyp_match lhyps_rest in + apply_hyps_context_rec (lfun@lids) (lmatch@lm) nextlhyps + (nextlhyps,0) tl + with + | e when is_failure e -> raise e + | e when is_match_catchable e -> + apply_hyps_context_rec lfun lmatch lhyps_rest next mhyps + end + | [] -> + let lmatch = List.map (fun (id,c) -> (id,VConstr c)) lmatch in + db_mc_pattern_success ist.debug; + eval_with_fail {ist with lfun=lmatch@lfun@ist.lfun} mt goal + in + apply_hyps_context_rec [] lgmatch hyps (hyps,0) mhyps + + (* Interprets extended tactic generic arguments *) +and interp_genarg ist goal x = + match genarg_tag x with + | BoolArgType -> in_gen wit_bool (out_gen globwit_bool x) + | IntArgType -> in_gen wit_int (out_gen globwit_int x) + | IntOrVarArgType -> + in_gen wit_int_or_var + (ArgArg (interp_int_or_var ist (out_gen globwit_int_or_var x))) + | StringArgType -> + in_gen wit_string (out_gen globwit_string x) + | PreIdentArgType -> + in_gen wit_pre_ident (out_gen globwit_pre_ident x) + | IntroPatternArgType -> + in_gen wit_intro_pattern + (interp_intro_pattern ist (out_gen globwit_intro_pattern x)) + | IdentArgType -> + in_gen wit_ident (interp_ident ist (out_gen globwit_ident x)) + | HypArgType -> + in_gen wit_var (mkVar (interp_hyp ist goal (out_gen globwit_var x))) + | RefArgType -> + in_gen wit_ref (pf_interp_reference ist goal (out_gen globwit_ref x)) + | SortArgType -> + in_gen wit_sort + (destSort + (pf_interp_constr ist goal + (RSort (dummy_loc,out_gen globwit_sort x), None))) + | ConstrArgType -> + in_gen wit_constr (pf_interp_constr ist goal (out_gen globwit_constr x)) + | ConstrMayEvalArgType -> + in_gen wit_constr_may_eval (interp_constr_may_eval ist goal (out_gen globwit_constr_may_eval x)) + | QuantHypArgType -> + in_gen wit_quant_hyp + (interp_declared_or_quantified_hypothesis ist goal + (out_gen globwit_quant_hyp x)) + | RedExprArgType -> + in_gen wit_red_expr (pf_redexp_interp ist goal (out_gen globwit_red_expr x)) + | TacticArgType -> in_gen wit_tactic (out_gen globwit_tactic x) + | CastedOpenConstrArgType -> + in_gen wit_casted_open_constr + (pf_interp_casted_openconstr ist goal (out_gen globwit_casted_open_constr x)) + | ConstrWithBindingsArgType -> + in_gen wit_constr_with_bindings + (interp_constr_with_bindings ist goal (out_gen globwit_constr_with_bindings x)) + | BindingsArgType -> + in_gen wit_bindings + (interp_bindings ist goal (out_gen globwit_bindings x)) + | List0ArgType _ -> app_list0 (interp_genarg ist goal) x + | List1ArgType _ -> app_list1 (interp_genarg ist goal) x + | OptArgType _ -> app_opt (interp_genarg ist goal) x + | PairArgType _ -> app_pair (interp_genarg ist goal) (interp_genarg ist goal) x + | ExtraArgType s -> lookup_interp_genarg s ist goal x + +(* Interprets the Match expressions *) +and interp_match ist g constr lmr = + let rec apply_sub_match ist nocc (id,c) csr mt = + try + let (lm,ctxt) = sub_match nocc c csr in + let lctxt = give_context ctxt id in + let lm = List.map (fun (id,c) -> (id,VConstr c)) lm in + val_interp {ist with lfun=lm@lctxt@ist.lfun} g mt + with | NextOccurrence _ -> raise No_match + in + let rec apply_match ist csr = function + | (All t)::_ -> + (try val_interp ist g t + with e when is_match_catchable e -> apply_match ist csr []) + | (Pat ([],Term c,mt))::tl -> + (try + let lm = apply_matching c csr in + let lm = List.map (fun (id,c) -> (id,VConstr c)) lm in + val_interp + { ist with lfun=lm@ist.lfun } g mt + with e when is_match_catchable e -> apply_match ist csr tl) + | (Pat ([],Subterm (id,c),mt))::tl -> + (try + apply_sub_match ist 0 (id,c) csr mt + with | No_match -> + apply_match ist csr tl) + | _ -> + errorlabstrm "Tacinterp.apply_match" (str + "No matching clauses for match") in + let env = pf_env g in + let csr = + try constr_of_value env (val_interp ist g constr) + with Not_found -> + errorlabstrm "Tacinterp.apply_match" + (str "Argument of match does not evaluate to a term") in + let ilr = read_match_rule (project g) env (fst (constr_list ist env)) lmr in + apply_match ist csr ilr + +(* Interprets tactic expressions : returns a "tactic" *) +and interp_tactic ist tac gl = + try tactic_of_value (val_interp ist gl tac) gl + with | NotTactic -> + errorlabstrm "Tacinterp.interp_tactic" (str + "Must be a command or must give a tactic value") + +(* Interprets a primitive tactic *) +and interp_atomic ist gl = function + (* Basic tactics *) + | TacIntroPattern l -> + h_intro_patterns (List.map (interp_intro_pattern ist) l) + | TacIntrosUntil hyp -> + h_intros_until (interp_quantified_hypothesis ist hyp) + | TacIntroMove (ido,ido') -> + h_intro_move (option_app (interp_ident ist) ido) + (option_app (interp_hyp ist gl) ido') + | TacAssumption -> h_assumption + | TacExact c -> h_exact (pf_interp_casted_constr ist gl c) + | TacApply cb -> h_apply (interp_constr_with_bindings ist gl cb) + | TacElim (cb,cbo) -> + h_elim (interp_constr_with_bindings ist gl cb) + (option_app (interp_constr_with_bindings ist gl) cbo) + | TacElimType c -> h_elim_type (pf_interp_constr ist gl c) + | TacCase cb -> h_case (interp_constr_with_bindings ist gl cb) + | TacCaseType c -> h_case_type (pf_interp_constr ist gl c) + | TacFix (idopt,n) -> h_fix (option_app (interp_ident ist) idopt) n + | TacMutualFix (id,n,l) -> + let f (id,n,c) = (interp_ident ist id,n,pf_interp_constr ist gl c) in + h_mutual_fix (interp_ident ist id) n (List.map f l) + | TacCofix idopt -> h_cofix (option_app (interp_ident ist) idopt) + | TacMutualCofix (id,l) -> + let f (id,c) = (interp_ident ist id,pf_interp_constr ist gl c) in + h_mutual_cofix (interp_ident ist id) (List.map f l) + | TacCut c -> h_cut (pf_interp_constr ist gl c) + | TacTrueCut (na,c) -> + h_true_cut (interp_name ist na) (pf_interp_constr ist gl c) + | TacForward (b,na,c) -> + h_forward b (interp_name ist na) (pf_interp_constr ist gl c) + | TacGeneralize cl -> h_generalize (List.map (pf_interp_constr ist gl) cl) + | TacGeneralizeDep c -> h_generalize_dep (pf_interp_constr ist gl c) + | TacLetTac (na,c,clp) -> + let clp = interp_clause ist gl clp in + h_let_tac (interp_name ist na) (pf_interp_constr ist gl c) clp + | TacInstantiate (n,c,ido) -> h_instantiate n (pf_interp_constr ist gl c) + (clause_app (interp_hyp_location ist gl) ido) + + (* Automation tactics *) + | TacTrivial l -> Auto.h_trivial l + | TacAuto (n, l) -> Auto.h_auto n l + | TacAutoTDB n -> Dhyp.h_auto_tdb n + | TacDestructHyp (b,id) -> Dhyp.h_destructHyp b (interp_hyp ist gl id) + | TacDestructConcl -> Dhyp.h_destructConcl + | TacSuperAuto (n,l,b1,b2) -> Auto.h_superauto n l b1 b2 + | TacDAuto (n,p) -> Auto.h_dauto (n,p) + + (* Derived basic tactics *) + | TacSimpleInduction (h,ids) -> + let h = + if !Options.v7 then interp_declared_or_quantified_hypothesis ist gl h + else interp_quantified_hypothesis ist h in + h_simple_induction (h,ids) + | TacNewInduction (c,cbo,(ids,ids')) -> + h_new_induction (interp_induction_arg ist gl c) + (option_app (interp_constr_with_bindings ist gl) cbo) + (option_app (interp_intro_pattern ist) ids,ids') + | TacSimpleDestruct h -> + h_simple_destruct (interp_quantified_hypothesis ist h) + | TacNewDestruct (c,cbo,(ids,ids')) -> + h_new_destruct (interp_induction_arg ist gl c) + (option_app (interp_constr_with_bindings ist gl) cbo) + (option_app (interp_intro_pattern ist) ids,ids') + | TacDoubleInduction (h1,h2) -> + let h1 = interp_quantified_hypothesis ist h1 in + let h2 = interp_quantified_hypothesis ist h2 in + Elim.h_double_induction h1 h2 + | TacDecomposeAnd c -> Elim.h_decompose_and (pf_interp_constr ist gl c) + | TacDecomposeOr c -> Elim.h_decompose_or (pf_interp_constr ist gl c) + | TacDecompose (l,c) -> + let l = List.map (interp_inductive ist) l in + Elim.h_decompose l (pf_interp_constr ist gl c) + | TacSpecialize (n,l) -> + h_specialize n (interp_constr_with_bindings ist gl l) + | TacLApply c -> h_lapply (pf_interp_constr ist gl c) + + (* Context management *) + | TacClear l -> h_clear (List.map (interp_hyp ist gl) l) + | TacClearBody l -> h_clear_body (List.map (interp_hyp ist gl) l) + | TacMove (dep,id1,id2) -> + h_move dep (interp_hyp ist gl id1) (interp_hyp ist gl id2) + | TacRename (id1,id2) -> + h_rename (interp_hyp ist gl id1) (interp_ident ist (snd id2)) + + (* Constructors *) + | TacLeft bl -> h_left (interp_bindings ist gl bl) + | TacRight bl -> h_right (interp_bindings ist gl bl) + | TacSplit (_,bl) -> h_split (interp_bindings ist gl bl) + | TacAnyConstructor t -> + abstract_tactic (TacAnyConstructor t) + (Tactics.any_constructor (option_app (interp_tactic ist) t)) + | TacConstructor (n,bl) -> + h_constructor (skip_metaid n) (interp_bindings ist gl bl) + + (* Conversion *) + | TacReduce (r,cl) -> + h_reduce (pf_redexp_interp ist gl r) (interp_clause ist gl cl) + | TacChange (occl,c,cl) -> + h_change (option_app (pf_interp_pattern ist gl) occl) + (pf_interp_constr ist gl c) (interp_clause ist gl cl) + + (* Equivalence relations *) + | TacReflexivity -> h_reflexivity + | TacSymmetry c -> h_symmetry (interp_clause ist gl c) + | TacTransitivity c -> h_transitivity (pf_interp_constr ist gl c) + + (* Equality and inversion *) + | TacInversion (DepInversion (k,c,ids),hyp) -> + Inv.dinv k (option_app (pf_interp_constr ist gl) c) + (option_app (interp_intro_pattern ist) ids) + (interp_declared_or_quantified_hypothesis ist gl hyp) + | TacInversion (NonDepInversion (k,idl,ids),hyp) -> + Inv.inv_clause k + (option_app (interp_intro_pattern ist) ids) + (List.map (interp_hyp ist gl) idl) + (interp_declared_or_quantified_hypothesis ist gl hyp) + | TacInversion (InversionUsing (c,idl),hyp) -> + Leminv.lemInv_clause (interp_declared_or_quantified_hypothesis ist gl hyp) + (pf_interp_constr ist gl c) + (List.map (interp_hyp ist gl) idl) + + (* For extensions *) + | TacExtend (loc,opn,l) -> + fun gl -> vernac_tactic (opn,List.map (interp_genarg ist gl) l) gl + | TacAlias (loc,_,l,(_,body)) -> fun gl -> + let rec f x = match genarg_tag x with + | IntArgType -> VInteger (out_gen globwit_int x) + | IntOrVarArgType -> + VInteger (interp_int_or_var ist (out_gen globwit_int_or_var x)) + | PreIdentArgType -> + failwith "pre-identifiers cannot be bound" + | IntroPatternArgType -> + VIntroPattern (out_gen globwit_intro_pattern x) + | IdentArgType -> + VIntroPattern (IntroIdentifier (out_gen globwit_ident x)) + | HypArgType -> + VConstr (mkVar (interp_var ist gl (out_gen globwit_var x))) + | RefArgType -> + VConstr (constr_of_reference + (pf_interp_reference ist gl (out_gen globwit_ref x))) + | SortArgType -> + VConstr (mkSort (Pretyping.interp_sort (out_gen globwit_sort x))) + | ConstrArgType -> + VConstr (pf_interp_constr ist gl (out_gen globwit_constr x)) + | ConstrMayEvalArgType -> + VConstr + (interp_constr_may_eval ist gl (out_gen globwit_constr_may_eval x)) + | TacticArgType -> + val_interp ist gl (out_gen globwit_tactic x) + | StringArgType | BoolArgType + | QuantHypArgType | RedExprArgType + | CastedOpenConstrArgType | ConstrWithBindingsArgType | BindingsArgType + | ExtraArgType _ | List0ArgType _ | List1ArgType _ | OptArgType _ | PairArgType _ + -> error "This generic type is not supported in alias" + in + let lfun = (List.map (fun (x,c) -> (x,f c)) l)@ist.lfun in + let v = locate_tactic_call loc (val_interp { ist with lfun=lfun } gl body) + in tactic_of_value v gl + +(* Initial call for interpretation *) +let interp_tac_gen lfun debug t gl = + interp_tactic { lfun=lfun; debug=debug } + (intern_tactic { + ltacvars = (List.map fst lfun, []); ltacrecvars = []; + gsigma = project gl; genv = pf_env gl } t) gl + +let eval_tactic t = interp_tactic { lfun=[]; debug=get_debug() } t + +let interp t = interp_tac_gen [] (get_debug()) t + +(* Hides interpretation for pretty-print *) +let hide_interp t ot gl = + let ist = { ltacvars = ([],[]); ltacrecvars = []; + gsigma = project gl; genv = pf_env gl } in + let te = intern_tactic ist t in + let t = eval_tactic te in + match ot with + | None -> abstract_tactic_expr (TacArg (Tacexp te)) t gl + | Some t' -> abstract_tactic_expr (TacArg (Tacexp te)) (tclTHEN t t') gl + +(***************************************************************************) +(* Substitution at module closing time *) + +let subst_quantified_hypothesis _ x = x + +let subst_declared_or_quantified_hypothesis _ x = x + +let subst_inductive subst (kn,i) = (subst_kn subst kn,i) + +let subst_rawconstr subst (c,e) = + assert (e=None); (* e<>None only for toplevel tactics *) + (subst_raw subst c,None) + +let subst_binding subst (loc,b,c) = + (loc,subst_quantified_hypothesis subst b,subst_rawconstr subst c) + +let subst_bindings subst = function + | NoBindings -> NoBindings + | ImplicitBindings l -> ImplicitBindings (List.map (subst_rawconstr subst) l) + | ExplicitBindings l -> ExplicitBindings (List.map (subst_binding subst) l) + +let subst_raw_with_bindings subst (c,bl) = + (subst_rawconstr subst c, subst_bindings subst bl) + +let subst_induction_arg subst = function + | ElimOnConstr c -> ElimOnConstr (subst_rawconstr subst c) + | ElimOnAnonHyp n as x -> x + | ElimOnIdent id as x -> x + +let subst_evaluable_reference subst = function + | EvalVarRef id -> EvalVarRef id + | EvalConstRef kn -> EvalConstRef (subst_kn subst kn) + +let subst_and_short_name f (c,n) = + assert (n=None); (* since tacdef are strictly globalized *) + (f c,None) + +let subst_or_var f = function + | ArgVar _ as x -> x + | ArgArg (x) -> ArgArg (f x) + +let subst_located f (_loc,id) = (loc,f id) + +let subst_reference subst = + subst_or_var (subst_located (subst_kn subst)) + +let subst_global_reference subst = + subst_or_var (subst_located (subst_global subst)) + +let subst_evaluable subst = + subst_or_var (subst_and_short_name (subst_evaluable_reference subst)) + +let subst_unfold subst (l,e) = + (l,subst_evaluable subst e) + +let subst_flag subst red = + { red with rConst = List.map (subst_evaluable subst) red.rConst } + +let subst_constr_occurrence subst (l,c) = (l,subst_rawconstr subst c) + +let subst_redexp subst = function + | Unfold l -> Unfold (List.map (subst_unfold subst) l) + | Fold l -> Fold (List.map (subst_rawconstr subst) l) + | Cbv f -> Cbv (subst_flag subst f) + | Lazy f -> Lazy (subst_flag subst f) + | Pattern l -> Pattern (List.map (subst_constr_occurrence subst) l) + | Simpl o -> Simpl (option_app (subst_constr_occurrence subst) o) + | (Red _ | Hnf as r) -> r + | ExtraRedExpr (s,c) -> ExtraRedExpr (s, subst_rawconstr subst c) + +let subst_raw_may_eval subst = function + | ConstrEval (r,c) -> ConstrEval (subst_redexp subst r,subst_rawconstr subst c) + | ConstrContext (locid,c) -> ConstrContext (locid,subst_rawconstr subst c) + | ConstrTypeOf c -> ConstrTypeOf (subst_rawconstr subst c) + | ConstrTerm c -> ConstrTerm (subst_rawconstr subst c) + +let subst_match_pattern subst = function + | Subterm (ido,pc) -> Subterm (ido,subst_pattern subst pc) + | Term pc -> Term (subst_pattern subst pc) + +let rec subst_match_context_hyps subst = function + | Hyp (locs,mp) :: tl -> + Hyp (locs,subst_match_pattern subst mp) + :: subst_match_context_hyps subst tl + | [] -> [] + +let rec subst_atomic subst (t:glob_atomic_tactic_expr) = match t with + (* Basic tactics *) + | TacIntroPattern _ | TacIntrosUntil _ | TacIntroMove _ as x -> x + | TacAssumption as x -> x + | TacExact c -> TacExact (subst_rawconstr subst c) + | TacApply cb -> TacApply (subst_raw_with_bindings subst cb) + | TacElim (cb,cbo) -> + TacElim (subst_raw_with_bindings subst cb, + option_app (subst_raw_with_bindings subst) cbo) + | TacElimType c -> TacElimType (subst_rawconstr subst c) + | TacCase cb -> TacCase (subst_raw_with_bindings subst cb) + | TacCaseType c -> TacCaseType (subst_rawconstr subst c) + | TacFix (idopt,n) as x -> x + | TacMutualFix (id,n,l) -> + TacMutualFix(id,n,List.map (fun (id,n,c) -> (id,n,subst_rawconstr subst c)) l) + | TacCofix idopt as x -> x + | TacMutualCofix (id,l) -> + TacMutualCofix (id, List.map (fun (id,c) -> (id,subst_rawconstr subst c)) l) + | TacCut c -> TacCut (subst_rawconstr subst c) + | TacTrueCut (ido,c) -> TacTrueCut (ido, subst_rawconstr subst c) + | TacForward (b,na,c) -> TacForward (b,na,subst_rawconstr subst c) + | TacGeneralize cl -> TacGeneralize (List.map (subst_rawconstr subst) cl) + | TacGeneralizeDep c -> TacGeneralizeDep (subst_rawconstr subst c) + | TacLetTac (id,c,clp) -> TacLetTac (id,subst_rawconstr subst c,clp) + | TacInstantiate (n,c,ido) -> TacInstantiate (n,subst_rawconstr subst c,ido) + + (* Automation tactics *) + | TacTrivial l -> TacTrivial l + | TacAuto (n,l) -> TacAuto (n,l) + | TacAutoTDB n -> TacAutoTDB n + | TacDestructHyp (b,id) -> TacDestructHyp(b,id) + | TacDestructConcl -> TacDestructConcl + | TacSuperAuto (n,l,b1,b2) -> TacSuperAuto (n,l,b1,b2) + | TacDAuto (n,p) -> TacDAuto (n,p) + + (* Derived basic tactics *) + | TacSimpleInduction h as x -> x + | TacNewInduction (c,cbo,ids) -> + TacNewInduction (subst_induction_arg subst c, + option_app (subst_raw_with_bindings subst) cbo, ids) + | TacSimpleDestruct h as x -> x + | TacNewDestruct (c,cbo,ids) -> + TacNewDestruct (subst_induction_arg subst c, + option_app (subst_raw_with_bindings subst) cbo, ids) + | TacDoubleInduction (h1,h2) as x -> x + | TacDecomposeAnd c -> TacDecomposeAnd (subst_rawconstr subst c) + | TacDecomposeOr c -> TacDecomposeOr (subst_rawconstr subst c) + | TacDecompose (l,c) -> + let l = List.map (subst_or_var (subst_inductive subst)) l in + TacDecompose (l,subst_rawconstr subst c) + | TacSpecialize (n,l) -> TacSpecialize (n,subst_raw_with_bindings subst l) + | TacLApply c -> TacLApply (subst_rawconstr subst c) + + (* Context management *) + | TacClear l as x -> x + | TacClearBody l as x -> x + | TacMove (dep,id1,id2) as x -> x + | TacRename (id1,id2) as x -> x + + (* Constructors *) + | TacLeft bl -> TacLeft (subst_bindings subst bl) + | TacRight bl -> TacRight (subst_bindings subst bl) + | TacSplit (b,bl) -> TacSplit (b,subst_bindings subst bl) + | TacAnyConstructor t -> TacAnyConstructor (option_app (subst_tactic subst) t) + | TacConstructor (n,bl) -> TacConstructor (n, subst_bindings subst bl) + + (* Conversion *) + | TacReduce (r,cl) -> TacReduce (subst_redexp subst r, cl) + | TacChange (occl,c,cl) -> + TacChange (option_app (subst_constr_occurrence subst) occl, + subst_rawconstr subst c, cl) + + (* Equivalence relations *) + | TacReflexivity | TacSymmetry _ as x -> x + | TacTransitivity c -> TacTransitivity (subst_rawconstr subst c) + + (* Equality and inversion *) + | TacInversion (DepInversion (k,c,l),hyp) -> + TacInversion (DepInversion (k,option_app (subst_rawconstr subst) c,l),hyp) + | TacInversion (NonDepInversion _,_) as x -> x + | TacInversion (InversionUsing (c,cl),hyp) -> + TacInversion (InversionUsing (subst_rawconstr subst c,cl),hyp) + + (* For extensions *) + | TacExtend (_loc,opn,l) -> + TacExtend (loc,opn,List.map (subst_genarg subst) l) + | TacAlias (_,s,l,(dir,body)) -> + TacAlias (loc,s,List.map (fun (id,a) -> (id,subst_genarg subst a)) l, + (dir,subst_tactic subst body)) + +and subst_tactic subst (t:glob_tactic_expr) = match t with + | TacAtom (_loc,t) -> TacAtom (loc, subst_atomic subst t) + | TacFun tacfun -> TacFun (subst_tactic_fun subst tacfun) + | TacLetRecIn (lrc,u) -> + let lrc = List.map (fun (n,b) -> (n,subst_tactic_fun subst b)) lrc in + TacLetRecIn (lrc,(subst_tactic subst u:glob_tactic_expr)) + | TacLetIn (l,u) -> + let l = List.map (fun (n,c,b) -> (n,option_app (subst_tactic subst) c,subst_tacarg subst b)) l in + TacLetIn (l,subst_tactic subst u) + | TacMatchContext (lr,lmr) -> + TacMatchContext(lr, subst_match_rule subst lmr) + | TacMatch (c,lmr) -> + TacMatch (subst_tactic subst c,subst_match_rule subst lmr) + | TacId _ | TacFail _ as x -> x + | TacProgress tac -> TacProgress (subst_tactic subst tac:glob_tactic_expr) + | TacAbstract (tac,s) -> TacAbstract (subst_tactic subst tac,s) + | TacThen (t1,t2) -> + TacThen (subst_tactic subst t1,subst_tactic subst t2) + | TacThens (t,tl) -> + TacThens (subst_tactic subst t, List.map (subst_tactic subst) tl) + | TacDo (n,tac) -> TacDo (n,subst_tactic subst tac) + | TacTry tac -> TacTry (subst_tactic subst tac) + | TacInfo tac -> TacInfo (subst_tactic subst tac) + | TacRepeat tac -> TacRepeat (subst_tactic subst tac) + | TacOrelse (tac1,tac2) -> + TacOrelse (subst_tactic subst tac1,subst_tactic subst tac2) + | TacFirst l -> TacFirst (List.map (subst_tactic subst) l) + | TacSolve l -> TacSolve (List.map (subst_tactic subst) l) + | TacArg a -> TacArg (subst_tacarg subst a) + +and subst_tactic_fun subst (var,body) = (var,subst_tactic subst body) + +and subst_tacarg subst = function + | Reference r -> Reference (subst_reference subst r) + | ConstrMayEval c -> ConstrMayEval (subst_raw_may_eval subst c) + | MetaIdArg (_loc,_) -> assert false + | TacCall (_loc,f,l) -> + TacCall (_loc, subst_reference subst f, List.map (subst_tacarg subst) l) + | (TacVoid | IntroPattern _ | Integer _ | TacFreshId _) as x -> x + | Tacexp t -> Tacexp (subst_tactic subst t) + | TacDynamic(_,t) as x -> + (match tag t with + | "tactic" | "value" | "constr" -> x + | s -> anomaly_loc (loc, "Tacinterp.val_interp", + str "Unknown dynamic: <" ++ str s ++ str ">")) + +(* Reads the rules of a Match Context or a Match *) +and subst_match_rule subst = function + | (All tc)::tl -> + (All (subst_tactic subst tc))::(subst_match_rule subst tl) + | (Pat (rl,mp,tc))::tl -> + let hyps = subst_match_context_hyps subst rl in + let pat = subst_match_pattern subst mp in + Pat (hyps,pat,subst_tactic subst tc) + ::(subst_match_rule subst tl) + | [] -> [] + +and subst_genarg subst (x:glob_generic_argument) = + match genarg_tag x with + | BoolArgType -> in_gen globwit_bool (out_gen globwit_bool x) + | IntArgType -> in_gen globwit_int (out_gen globwit_int x) + | IntOrVarArgType -> in_gen globwit_int_or_var (out_gen globwit_int_or_var x) + | StringArgType -> in_gen globwit_string (out_gen globwit_string x) + | PreIdentArgType -> in_gen globwit_pre_ident (out_gen globwit_pre_ident x) + | IntroPatternArgType -> + in_gen globwit_intro_pattern (out_gen globwit_intro_pattern x) + | IdentArgType -> in_gen globwit_ident (out_gen globwit_ident x) + | HypArgType -> in_gen globwit_var (out_gen globwit_var x) + | RefArgType -> + in_gen globwit_ref (subst_global_reference subst + (out_gen globwit_ref x)) + | SortArgType -> + in_gen globwit_sort (out_gen globwit_sort x) + | ConstrArgType -> + in_gen globwit_constr (subst_rawconstr subst (out_gen globwit_constr x)) + | ConstrMayEvalArgType -> + in_gen globwit_constr_may_eval (subst_raw_may_eval subst (out_gen globwit_constr_may_eval x)) + | QuantHypArgType -> + in_gen globwit_quant_hyp + (subst_declared_or_quantified_hypothesis subst + (out_gen globwit_quant_hyp x)) + | RedExprArgType -> + in_gen globwit_red_expr (subst_redexp subst (out_gen globwit_red_expr x)) + | TacticArgType -> + in_gen globwit_tactic (subst_tactic subst (out_gen globwit_tactic x)) + | CastedOpenConstrArgType -> + in_gen globwit_casted_open_constr + (subst_rawconstr subst (out_gen globwit_casted_open_constr x)) + | ConstrWithBindingsArgType -> + in_gen globwit_constr_with_bindings + (subst_raw_with_bindings subst (out_gen globwit_constr_with_bindings x)) + | BindingsArgType -> + in_gen globwit_bindings + (subst_bindings subst (out_gen globwit_bindings x)) + | List0ArgType _ -> app_list0 (subst_genarg subst) x + | List1ArgType _ -> app_list1 (subst_genarg subst) x + | OptArgType _ -> app_opt (subst_genarg subst) x + | PairArgType _ -> app_pair (subst_genarg subst) (subst_genarg subst) x + | ExtraArgType s -> lookup_genarg_subst s subst x + +(***************************************************************************) +(* Tactic registration *) + +(* For bad tactic calls *) +let bad_tactic_args s = + anomalylabstrm s + (str "Tactic " ++ str s ++ str " called with bad arguments") + +(* Declaration of the TAC-DEFINITION object *) +let add (kn,td) = mactab := Gmap.add kn td !mactab + +let load_md i ((sp,kn),defs) = + let dp,_ = repr_path sp in + let mp,dir,_ = repr_kn kn in + List.iter (fun (id,t) -> + let sp = Libnames.make_path dp id in + let kn = Names.make_kn mp dir (label_of_id id) in + Nametab.push_tactic (Until i) sp kn; + add (kn,t)) defs + +let open_md i((sp,kn),defs) = + let dp,_ = repr_path sp in + let mp,dir,_ = repr_kn kn in + List.iter (fun (id,t) -> + let sp = Libnames.make_path dp id in + let kn = Names.make_kn mp dir (label_of_id id) in + Nametab.push_tactic (Exactly i) sp kn) defs + +let cache_md x = load_md 1 x + +let subst_md (_,subst,defs) = + List.map (fun (id,t) -> (id,subst_tactic subst t)) defs + +let (inMD,outMD) = + declare_object {(default_object "TAC-DEFINITION") with + cache_function = cache_md; + load_function = load_md; + open_function = open_md; + subst_function = subst_md; + classify_function = (fun (_,o) -> Substitute o); + export_function = (fun x -> Some x)} + +(* Adds a definition for tactics in the table *) +let make_absolute_name (loc,id) = + let kn = Lib.make_kn id in + if Gmap.mem kn !mactab or is_atomic_kn kn then + user_err_loc (loc,"Tacinterp.add_tacdef", + str "There is already an Ltac named " ++ pr_id id); + kn + +let make_empty_glob_sign () = + { ltacvars = ([],[]); ltacrecvars = []; + gsigma = Evd.empty; genv = Global.env() } + +let add_tacdef isrec tacl = +(* let isrec = if !Options.p1 then isrec else true in*) + let rfun = List.map (fun ((loc,id as locid),_) -> (id,make_absolute_name locid)) tacl in + let ist = + {(make_empty_glob_sign()) with ltacrecvars = if isrec then rfun else []} in + let gtacl = + List.map (fun ((_,id),def) -> + (id,Options.with_option strict_check (intern_tactic ist) def)) + tacl in + let id0 = fst (List.hd rfun) in + let _ = Lib.add_leaf id0 (inMD gtacl) in + List.iter + (fun (id,_) -> Options.if_verbose msgnl (pr_id id ++ str " is defined")) + rfun + +(***************************************************************************) +(* Other entry points *) + +let glob_tactic x = intern_tactic (make_empty_glob_sign ()) x + +let glob_tactic_env l env x = + intern_tactic + { ltacvars = (l,[]); ltacrecvars = []; gsigma = Evd.empty; genv = env } + x + +let interp_redexp env evc r = + let ist = { lfun=[]; debug=get_debug () } in + let gist = {(make_empty_glob_sign ()) with genv = env; gsigma = evc } in + redexp_interp ist evc env (intern_redexp gist r) + +(***************************************************************************) +(* Backwarding recursive needs of tactic glob/interp/eval functions *) + +let _ = Auto.set_extern_interp + (fun l -> + let l = List.map (fun (id,c) -> (id,VConstr c)) l in + interp_tactic {lfun=l;debug=get_debug()}) +let _ = Auto.set_extern_intern_tac + (fun l -> + Options.with_option strict_check + (intern_tactic {(make_empty_glob_sign()) with ltacvars=(l,[])})) +let _ = Auto.set_extern_subst_tactic subst_tactic +let _ = Dhyp.set_extern_interp eval_tactic +let _ = Dhyp.set_extern_intern_tac + (fun t -> intern_tactic (make_empty_glob_sign()) t) -- cgit v1.2.3