(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* Thesis n | This c -> This (intern_constr globs c) let add_var id globs= let l1,l2=globs.ltacvars in {globs with ltacvars= (id::l1),(id::l2)} let add_name nam globs= match nam with Anonymous -> globs | Name id -> add_var id globs let intern_hyp iconstr globs = function Hvar (loc,(id,topt)) -> add_var id globs, Hvar (loc,(id,Option.map (intern_constr globs) topt)) | Hprop st -> add_name st.st_label globs, Hprop (intern_statement iconstr globs st) let intern_hyps iconstr globs hyps = snd (list_fold_map (intern_hyp iconstr) globs hyps) let intern_cut intern_it globs cut= let nglobs,nstat=intern_it globs cut.cut_stat in {cut_stat=nstat; cut_by=intern_justification_items nglobs cut.cut_by; cut_using=intern_justification_method nglobs cut.cut_using} let intern_casee globs = function Real c -> Real (intern_constr globs c) | Virtual cut -> Virtual (intern_cut (intern_no_bind (intern_statement intern_constr)) globs cut) let intern_hyp_list args globs = let intern_one globs (loc,(id,opttyp)) = (add_var id globs), (loc,(id,Option.map (intern_constr globs) opttyp)) in list_fold_map intern_one globs args let intern_suffices_clause globs (hyps,c) = let nglobs,nhyps = list_fold_map (intern_hyp intern_constr) globs hyps in nglobs,(nhyps,intern_constr_or_thesis nglobs c) let intern_fundecl args body globs= let nglobs,nargs = intern_hyp_list args globs in nargs,intern_constr nglobs body let rec add_vars_of_simple_pattern globs = function CPatAlias (loc,p,id) -> add_vars_of_simple_pattern (add_var id globs) p (* Loc.raise loc (UserError ("simple_pattern",str "\"as\" is not allowed here"))*) | CPatOr (loc, _)-> Loc.raise loc (UserError ("simple_pattern",str "\"(_ | _)\" is not allowed here")) | CPatDelimiters (_,_,p) -> add_vars_of_simple_pattern globs p | CPatCstr (_,_,pl) | CPatCstrExpl (_,_,pl) -> List.fold_left add_vars_of_simple_pattern globs pl | CPatNotation(_,_,(pl,pll)) -> List.fold_left add_vars_of_simple_pattern globs (List.flatten (pl::pll)) | CPatAtom (_,Some (Libnames.Ident (_,id))) -> add_var id globs | _ -> globs let rec intern_bare_proof_instr globs = function Pthus i -> Pthus (intern_bare_proof_instr globs i) | Pthen i -> Pthen (intern_bare_proof_instr globs i) | Phence i -> Phence (intern_bare_proof_instr globs i) | Pcut c -> Pcut (intern_cut (intern_no_bind (intern_statement intern_constr_or_thesis)) globs c) | Psuffices c -> Psuffices (intern_cut intern_suffices_clause globs c) | Prew (s,c) -> Prew (s,intern_cut (intern_no_bind (intern_statement intern_constr)) globs c) | Psuppose hyps -> Psuppose (intern_hyps intern_constr globs hyps) | Pcase (params,pat,hyps) -> let nglobs,nparams = intern_hyp_list params globs in let nnglobs= add_vars_of_simple_pattern nglobs pat in let nhyps = intern_hyps intern_constr_or_thesis nnglobs hyps in Pcase (nparams,pat,nhyps) | Ptake witl -> Ptake (List.map (intern_constr globs) witl) | Pconsider (c,hyps) -> Pconsider (intern_constr globs c, intern_hyps intern_constr globs hyps) | Pper (et,c) -> Pper (et,intern_casee globs c) | Pend bt -> Pend bt | Pescape -> Pescape | Passume hyps -> Passume (intern_hyps intern_constr globs hyps) | Pgiven hyps -> Pgiven (intern_hyps intern_constr globs hyps) | Plet hyps -> Plet (intern_hyps intern_constr globs hyps) | Pclaim st -> Pclaim (intern_statement intern_constr globs st) | Pfocus st -> Pfocus (intern_statement intern_constr globs st) | Pdefine (id,args,body) -> let nargs,nbody = intern_fundecl args body globs in Pdefine (id,nargs,nbody) | Pcast (id,typ) -> Pcast (id,intern_constr globs typ) let rec intern_proof_instr globs instr= {emph = instr.emph; instr = intern_bare_proof_instr globs instr.instr} (* INTERP *) let interp_justification_items sigma env = Option.map (List.map (fun c ->understand sigma env (fst c))) let interp_constr check_sort sigma env c = if check_sort then understand_type sigma env (fst c) else understand sigma env (fst c) let special_whd env = let infos=Closure.create_clos_infos Closure.betadeltaiota env in (fun t -> Closure.whd_val infos (Closure.inject t)) let _eq = Libnames.constr_of_global (Coqlib.glob_eq) let decompose_eq env id = let typ = Environ.named_type id env in let whd = special_whd env typ in match kind_of_term whd with App (f,args)-> if eq_constr f _eq && (Array.length args)=3 then args.(0) else error "Previous step is not an equality." | _ -> error "Previous step is not an equality." let get_eq_typ info env = let typ = decompose_eq env (get_last env) in typ let interp_constr_in_type typ sigma env c = understand sigma env (fst c) ~expected_type:typ let interp_statement interp_it sigma env st = {st_label=st.st_label; st_it=interp_it sigma env st.st_it} let interp_constr_or_thesis check_sort sigma env = function Thesis n -> Thesis n | This c -> This (interp_constr check_sort sigma env c) let abstract_one_hyp inject h glob = match h with Hvar (loc,(id,None)) -> GProd (dummy_loc,Name id, Explicit, GHole (loc,Evd.BinderType (Name id)), glob) | Hvar (loc,(id,Some typ)) -> GProd (dummy_loc,Name id, Explicit, fst typ, glob) | Hprop st -> GProd (dummy_loc,st.st_label, Explicit, inject st.st_it, glob) let glob_constr_of_hyps inject hyps head = List.fold_right (abstract_one_hyp inject) hyps head let glob_prop = GSort (dummy_loc,GProp Null) let rec match_hyps blend names constr = function [] -> [],substl names constr | hyp::q -> let (name,typ,body)=destProd constr in let st= {st_label=name;st_it=substl names typ} in let qnames= match name with Anonymous -> mkMeta 0 :: names | Name id -> mkVar id :: names in let qhyp = match hyp with Hprop st' -> Hprop (blend st st') | Hvar _ -> Hvar st in let rhyps,head = match_hyps blend qnames body q in qhyp::rhyps,head let interp_hyps_gen inject blend sigma env hyps head = let constr=understand sigma env (glob_constr_of_hyps inject hyps head) in match_hyps blend [] constr hyps let interp_hyps sigma env hyps = fst (interp_hyps_gen fst (fun x _ -> x) sigma env hyps glob_prop) let dummy_prefix= id_of_string "__" let rec deanonymize ids = function PatVar (loc,Anonymous) -> let (found,known) = !ids in let new_id=Namegen.next_ident_away dummy_prefix known in let _= ids:= (loc,new_id) :: found , new_id :: known in PatVar (loc,Name new_id) | PatVar (loc,Name id) as pat -> let (found,known) = !ids in let _= ids:= (loc,id) :: found , known in pat | PatCstr(loc,cstr,lpat,nam) -> PatCstr(loc,cstr,List.map (deanonymize ids) lpat,nam) let rec glob_of_pat = function PatVar (loc,Anonymous) -> anomaly "Anonymous pattern variable" | PatVar (loc,Name id) -> GVar (loc,id) | PatCstr(loc,((ind,_) as cstr),lpat,_) -> let mind= fst (Global.lookup_inductive ind) in let rec add_params n q = if n<=0 then q else add_params (pred n) (GHole(dummy_loc, Evd.TomatchTypeParameter(ind,n))::q) in let args = List.map glob_of_pat lpat in glob_app(loc,GRef(dummy_loc,Libnames.ConstructRef cstr), add_params mind.Declarations.mind_nparams args) let prod_one_hyp = function (loc,(id,None)) -> (fun glob -> GProd (dummy_loc,Name id, Explicit, GHole (loc,Evd.BinderType (Name id)), glob)) | (loc,(id,Some typ)) -> (fun glob -> GProd (dummy_loc,Name id, Explicit, fst typ, glob)) let prod_one_id (loc,id) glob = GProd (dummy_loc,Name id, Explicit, GHole (loc,Evd.BinderType (Name id)), glob) let let_in_one_alias (id,pat) glob = GLetIn (dummy_loc,Name id, glob_of_pat pat, glob) let rec bind_primary_aliases map pat = match pat with PatVar (_,_) -> map | PatCstr(loc,_,lpat,nam) -> let map1 = match nam with Anonymous -> map | Name id -> (id,pat)::map in List.fold_left bind_primary_aliases map1 lpat let bind_secondary_aliases map subst = List.fold_left (fun map (ids,idp) -> (ids,List.assoc idp map)::map) map subst let bind_aliases patvars subst patt = let map = bind_primary_aliases [] patt in let map1 = bind_secondary_aliases map subst in List.rev map1 let interp_pattern env pat_expr = let patvars,pats = Constrintern.intern_pattern env pat_expr in match pats with [] -> anomaly "empty pattern list" | [subst,patt] -> (patvars,bind_aliases patvars subst patt,patt) | _ -> anomaly "undetected disjunctive pattern" let rec match_args dest names constr = function [] -> [],names,substl names constr | _::q -> let (name,typ,body)=dest constr in let st={st_label=name;st_it=substl names typ} in let qnames= match name with Anonymous -> assert false | Name id -> mkVar id :: names in let args,bnames,body = match_args dest qnames body q in st::args,bnames,body let rec match_aliases names constr = function [] -> [],names,substl names constr | _::q -> let (name,c,typ,body)=destLetIn constr in let st={st_label=name;st_it=(substl names c,substl names typ)} in let qnames= match name with Anonymous -> assert false | Name id -> mkVar id :: names in let args,bnames,body = match_aliases qnames body q in st::args,bnames,body let detype_ground c = Detyping.detype false [] [] c let interp_cases info sigma env params (pat:cases_pattern_expr) hyps = let et,pinfo = match info.pm_stack with Per(et,pi,_,_)::_ -> et,pi | _ -> error "No proof per cases/induction/inversion in progress." in let mib,oib=Global.lookup_inductive pinfo.per_ind in let num_params = pinfo.per_nparams in let _ = let expected = mib.Declarations.mind_nparams - num_params in if List.length params <> expected then errorlabstrm "suppose it is" (str "Wrong number of extra arguments: " ++ (if expected = 0 then str "none" else int expected) ++ spc () ++ str "expected.") in let app_ind = let rind = GRef (dummy_loc,Libnames.IndRef pinfo.per_ind) in let rparams = List.map detype_ground pinfo.per_params in let rparams_rec = List.map (fun (loc,(id,_)) -> GVar (loc,id)) params in let dum_args= list_tabulate (fun _ -> GHole (dummy_loc,Evd.QuestionMark (Evd.Define false))) oib.Declarations.mind_nrealargs in glob_app(dummy_loc,rind,rparams@rparams_rec@dum_args) in let pat_vars,aliases,patt = interp_pattern env pat in let inject = function Thesis (Plain) -> Glob_term.GSort(dummy_loc,GProp Null) | Thesis (For rec_occ) -> if not (List.mem rec_occ pat_vars) then errorlabstrm "suppose it is" (str "Variable " ++ Nameops.pr_id rec_occ ++ str " does not occur in pattern."); Glob_term.GSort(dummy_loc,GProp Null) | This (c,_) -> c in let term1 = glob_constr_of_hyps inject hyps glob_prop in let loc_ids,npatt = let rids=ref ([],pat_vars) in let npatt= deanonymize rids patt in List.rev (fst !rids),npatt in let term2 = GLetIn(dummy_loc,Anonymous, GCast(dummy_loc,glob_of_pat npatt, CastConv (DEFAULTcast,app_ind)),term1) in let term3=List.fold_right let_in_one_alias aliases term2 in let term4=List.fold_right prod_one_id loc_ids term3 in let term5=List.fold_right prod_one_hyp params term4 in let constr = understand sigma env term5 in let tparams,nam4,rest4 = match_args destProd [] constr params in let tpatvars,nam3,rest3 = match_args destProd nam4 rest4 loc_ids in let taliases,nam2,rest2 = match_aliases nam3 rest3 aliases in let (_,pat_pat,pat_typ,rest1) = destLetIn rest2 in let blend st st' = match st'.st_it with Thesis nam -> {st_it=Thesis nam;st_label=st'.st_label} | This _ -> {st_it = This st.st_it;st_label=st.st_label} in let thyps = fst (match_hyps blend nam2 (Termops.pop rest1) hyps) in tparams,{pat_vars=tpatvars; pat_aliases=taliases; pat_constr=pat_pat; pat_typ=pat_typ; pat_pat=patt; pat_expr=pat},thyps let interp_cut interp_it sigma env cut= let nenv,nstat = interp_it sigma env cut.cut_stat in {cut with cut_stat=nstat; cut_by=interp_justification_items sigma nenv cut.cut_by} let interp_no_bind interp_it sigma env x = env,interp_it sigma env x let interp_suffices_clause sigma env (hyps,cot)= let (locvars,_) as res = match cot with This (c,_) -> let nhyps,nc = interp_hyps_gen fst (fun x _ -> x) sigma env hyps c in nhyps,This nc | Thesis Plain as th -> interp_hyps sigma env hyps,th | Thesis (For n) -> error "\"thesis for\" is not applicable here." in let push_one hyp env0 = match hyp with (Hprop st | Hvar st) -> match st.st_label with Name id -> Environ.push_named (id,None,st.st_it) env0 | _ -> env in let nenv = List.fold_right push_one locvars env in nenv,res let interp_casee sigma env = function Real c -> Real (understand sigma env (fst c)) | Virtual cut -> Virtual (interp_cut (interp_no_bind (interp_statement (interp_constr true))) sigma env cut) let abstract_one_arg = function (loc,(id,None)) -> (fun glob -> GLambda (dummy_loc,Name id, Explicit, GHole (loc,Evd.BinderType (Name id)), glob)) | (loc,(id,Some typ)) -> (fun glob -> GLambda (dummy_loc,Name id, Explicit, fst typ, glob)) let glob_constr_of_fun args body = List.fold_right abstract_one_arg args (fst body) let interp_fun sigma env args body = let constr=understand sigma env (glob_constr_of_fun args body) in match_args destLambda [] constr args let rec interp_bare_proof_instr info (sigma:Evd.evar_map) (env:Environ.env) = function Pthus i -> Pthus (interp_bare_proof_instr info sigma env i) | Pthen i -> Pthen (interp_bare_proof_instr info sigma env i) | Phence i -> Phence (interp_bare_proof_instr info sigma env i) | Pcut c -> Pcut (interp_cut (interp_no_bind (interp_statement (interp_constr_or_thesis true))) sigma env c) | Psuffices c -> Psuffices (interp_cut interp_suffices_clause sigma env c) | Prew (s,c) -> Prew (s,interp_cut (interp_no_bind (interp_statement (interp_constr_in_type (get_eq_typ info env)))) sigma env c) | Psuppose hyps -> Psuppose (interp_hyps sigma env hyps) | Pcase (params,pat,hyps) -> let tparams,tpat,thyps = interp_cases info sigma env params pat hyps in Pcase (tparams,tpat,thyps) | Ptake witl -> Ptake (List.map (fun c -> understand sigma env (fst c)) witl) | Pconsider (c,hyps) -> Pconsider (interp_constr false sigma env c, interp_hyps sigma env hyps) | Pper (et,c) -> Pper (et,interp_casee sigma env c) | Pend bt -> Pend bt | Pescape -> Pescape | Passume hyps -> Passume (interp_hyps sigma env hyps) | Pgiven hyps -> Pgiven (interp_hyps sigma env hyps) | Plet hyps -> Plet (interp_hyps sigma env hyps) | Pclaim st -> Pclaim (interp_statement (interp_constr true) sigma env st) | Pfocus st -> Pfocus (interp_statement (interp_constr true) sigma env st) | Pdefine (id,args,body) -> let nargs,_,nbody = interp_fun sigma env args body in Pdefine (id,nargs,nbody) | Pcast (id,typ) -> Pcast(id,interp_constr true sigma env typ) let rec interp_proof_instr info sigma env instr= {emph = instr.emph; instr = interp_bare_proof_instr info sigma env instr.instr}