(***********************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* ] let print_typed_value x = print_typed_value_in_env (Global.env ()) x let pkprinters = function | FW -> (fprterm,fprterm_env) | CCI -> (prterm,prterm_env) | _ -> anomaly "pkprinters" let print_impl_args = function | [] -> [<>] | [i] -> [< 'sTR"Position ["; 'iNT i; 'sTR"] is implicit" >] | l -> [< 'sTR"Positions ["; prlist_with_sep (fun () -> [< 'sTR";" >]) (fun i -> [< 'iNT i >]) l; 'sTR"] are implicit" >] (* To be improved; the type should be used to provide the types in the abstractions. This should be done recursively inside prterm, so that the pretty-print of a proposition (P:(nat->nat)->Prop)(P [u]u) synthesizes the type nat of the abstraction on u *) let print_named_def name body typ = let pbody = prterm body in let ptyp = prtype typ in [< 'sTR "*** ["; 'sTR name ; 'sTR " "; hOV 0 [< 'sTR ":="; 'bRK (1,2); pbody; 'sPC; 'sTR ":"; 'bRK (1,2); ptyp >]; 'sTR "]"; 'fNL >] let print_named_assum name typ = [< 'sTR "*** [" ; 'sTR name ; 'sTR " : "; prtype typ; 'sTR "]"; 'fNL >] let print_named_decl (id,c,typ) = let s = string_of_id id in match c with | Some body -> print_named_def s body typ | None -> print_named_assum s typ let assumptions_for_print lna = List.fold_right (fun na env -> add_name na env) lna empty_names_context let implicit_args_id id l = if l = [] then [<>] else [< 'sTR"For "; pr_id id; 'sTR": "; print_impl_args l ; 'fNL >] let implicit_args_msg sp mipv = [< prvecti (fun i mip -> let imps = inductive_implicits_list (sp,i) in [< (implicit_args_id mip.mind_typename imps); prvecti (fun j idc -> let imps = constructor_implicits_list ((sp,i),succ j) in (implicit_args_id idc imps)) mip.mind_consnames >]) mipv >] let print_params env params = if List.length params = 0 then [<>] else [< 'sTR "["; pr_rel_context env params; 'sTR "]"; 'bRK(1,2) >] let print_constructors envpar names types = let pc = [< prvect_with_sep (fun () -> [<'bRK(1,0); 'sTR "| " >]) (fun (id,c) -> [< pr_id id; 'sTR " : "; prterm_env envpar c >]) (array_map2 (fun n t -> (n,t)) names types) >] in hV 0 [< 'sTR " "; pc >] let build_inductive sp tyi = let ctxt = context_of_global_reference (IndRef (sp,tyi)) in let ctxt = Array.of_list (instance_from_section_context ctxt) in let mis = Global.lookup_mind_specif ((sp,tyi),ctxt) in let params = mis_params_ctxt mis in let args = extended_rel_list 0 params in let indf = make_ind_family (mis,args) in let arity = get_arity_type indf in let cstrtypes = get_constructors_types indf in let cstrnames = mis_consnames mis in (IndRef (sp,tyi), params, arity, cstrnames, cstrtypes) let print_one_inductive sp tyi = let (ref, params, arity, cstrnames, cstrtypes) = build_inductive sp tyi in let env = Global.env () in let envpar = push_rels params env in (hOV 0 [< (hOV 0 [< pr_global (IndRef (sp,tyi)) ; 'bRK(1,2); print_params env params; 'sTR ": "; prterm_env envpar arity; 'sTR " :=" >]); 'bRK(1,2); print_constructors envpar cstrnames cstrtypes >]) let print_mutual sp = let mipv = (Global.lookup_mind sp).mind_packets in if Array.length mipv = 1 then let (ref, params, arity, cstrnames, cstrtypes) = build_inductive sp 0 in let sfinite = if mipv.(0).mind_finite then "Inductive " else "CoInductive " in let env = Global.env () in let envpar = push_rels params env in (hOV 0 [< 'sTR sfinite ; pr_global (IndRef (sp,0)); 'bRK(1,2); print_params env params; 'bRK(1,5); 'sTR": "; prterm_env envpar arity; 'sTR" :="; 'bRK(0,4); print_constructors envpar cstrnames cstrtypes; 'fNL; implicit_args_msg sp mipv >] ) (* Mutual [co]inductive definitions *) else let _,(mipli,miplc) = Array.fold_right (fun mi (n,(li,lc)) -> if mi.mind_finite then (n+1,(n::li,lc)) else (n+1,(li,n::lc))) mipv (0,([],[])) in let strind = if mipli = [] then [<>] else [< 'sTR "Inductive"; 'bRK(1,4); (prlist_with_sep (fun () -> [< 'fNL; 'sTR" with"; 'bRK(1,4) >]) (print_one_inductive sp) mipli); 'fNL >] and strcoind = if miplc = [] then [<>] else [< 'sTR "CoInductive"; 'bRK(1,4); (prlist_with_sep (fun () -> [<'fNL; 'sTR " with"; 'bRK(1,4) >]) (print_one_inductive sp) miplc); 'fNL >] in (hV 0 [< 'sTR"Mutual " ; if mipv.(0).mind_finite then [< strind; strcoind >] else []; implicit_args_msg sp mipv >]) (* let env = Global.env () in let evd = Evd.empty in let {mind_packets=mipv} = mib in (* On suppose que tous les inductifs ont les même paramètres *) let nparams = mipv.(0).mind_nparams in let (lpars,_) = decomp_n_prod env evd nparams (body_of_type (mind_user_arity mipv.(0))) in let arities = Array.map (fun mip -> (Name mip.mind_typename, None, mip.mind_nf_arity)) mipv in let env_ar = push_rels lpars env in let pr_constructor (id,c) = [< pr_id id; 'sTR " : "; prterm_env env_ar c >] in let print_constructors mis = let (_,lC) = mis_type_mconstructs mis in let lidC = array_map2 (fun id c -> (id, snd (decomp_n_prod env evd nparams c))) (mis_consnames mis) lC in let plidC = prvect_with_sep (fun () -> [<'bRK(0,0); 'sTR "| " >]) pr_constructor lidC in hV 0 [< 'sTR " "; plidC >] in let params = if nparams = 0 then [<>] else [< 'sTR "["; pr_rel_context env lpars; 'sTR "]"; 'bRK(1,2) >] in let print_oneind tyi = let mis = build_mis ((sp,tyi), Array.of_list (instance_from_section_context mib.mind_hyps)) mib in let (_,arity) = decomp_n_prod env evd nparams (body_of_type (mis_user_arity mis)) in (hOV 0 [< (hOV 0 [< pr_global (IndRef (sp,tyi)) ; 'bRK(1,2); params; 'sTR ": "; prterm_env env_ar arity; 'sTR " :=" >]); 'bRK(1,2); print_constructors mis >]) in let mis0 = build_mis ((sp,0),Array.of_list (instance_from_section_context mib.mind_hyps)) mib in (* Case one [co]inductive *) if Array.length mipv = 1 then let (_,arity) = decomp_n_prod env evd nparams (body_of_type (mis_user_arity mis0)) in let sfinite = if mis_finite mis0 then "Inductive " else "CoInductive " in (hOV 0 [< 'sTR sfinite ; pr_global (IndRef (sp,0)); if nparams = 0 then [<>] else [< 'sTR" ["; pr_rel_context env lpars; 'sTR "]">]; 'bRK(1,5); 'sTR": "; prterm_env env_ar arity; 'sTR" :="; 'bRK(0,4); print_constructors mis0; 'fNL; implicit_args_msg sp mipv >] ) (* Mutual [co]inductive definitions *) else let _,(mipli,miplc) = List.fold_left (fun (n,(li,lc)) mi -> if mi.mind_finite then (n+1,(n::li,lc)) else (n+1,(li,n::lc))) (0,([],[])) (Array.to_list mipv) in let strind = if mipli = [] then [<>] else [< 'sTR "Inductive"; 'bRK(1,4); (prlist_with_sep (fun () -> [< 'fNL; 'sTR" with"; 'bRK(1,4) >]) print_oneind (List.rev mipli)); 'fNL >] and strcoind = if miplc = [] then [<>] else [< 'sTR "CoInductive"; 'bRK(1,4); (prlist_with_sep (fun () -> [<'fNL; 'sTR " with"; 'bRK(1,4) >]) print_oneind (List.rev miplc)); 'fNL >] in (hV 0 [< 'sTR"Mutual " ; if mis_finite mis0 then [< strind; strcoind >] else []; implicit_args_msg sp mipv >]) *) let print_section_variable sp = let (d,_,_) = get_variable sp in let l = implicits_of_var sp in [< print_named_decl d; print_impl_args l; 'fNL >] let print_body = function | Some c -> prterm c | None -> [< 'sTR"" >] let print_typed_body (val_0,typ) = [< print_body val_0; 'fNL; 'sTR " : "; prtype typ; 'fNL >] let print_constant with_values sep sp = let cb = Global.lookup_constant sp in if kind_of_path sp = CCI then let val_0 = cb.const_body in let typ = cb.const_type in let impls = constant_implicits_list sp in hOV 0 [< (match val_0 with | None -> [< 'sTR"*** [ "; print_basename sp; 'sTR " : "; 'cUT ; prtype typ ; 'sTR" ]"; 'fNL >] | _ -> [< print_basename sp; 'sTR sep; 'cUT ; if with_values then print_typed_body (val_0,typ) else [< prtype typ ; 'fNL >] >]); print_impl_args impls; 'fNL >] else hOV 0 [< 'sTR"Fw constant " ; print_basename sp ; 'fNL>] let print_inductive sp = if kind_of_path sp = CCI then [< print_mutual sp; 'fNL >] else hOV 0 [< 'sTR"Fw inductive definition "; print_basename sp; 'fNL >] let print_syntactic_def sep sp = let id = basename sp in let c = Syntax_def.search_syntactic_definition sp in [< 'sTR" Syntactif Definition "; pr_id id ; 'sTR sep; pr_rawterm c; 'fNL >] let print_leaf_entry with_values sep (sp,lobj) = let tag = object_tag lobj in match (sp,tag) with | (_,"VARIABLE") -> print_section_variable sp | (_,("CONSTANT"|"PARAMETER")) -> print_constant with_values sep sp | (_,"INDUCTIVE") -> print_inductive sp | (_,"AUTOHINT") -> [< 'sTR" Hint Marker"; 'fNL >] | (_,"GRAMMAR") -> [< 'sTR" Grammar Marker"; 'fNL >] | (_,"SYNTAXCONSTANT") -> print_syntactic_def sep sp | (_,"PPSYNTAX") -> [< 'sTR" Syntax Marker"; 'fNL >] | (_,"TOKEN") -> [< 'sTR" Token Marker"; 'fNL >] | (_,"CLASS") -> [< 'sTR" Class Marker"; 'fNL >] | (_,"COERCION") -> [< 'sTR" Coercion Marker"; 'fNL >] | (_,"REQUIRE") -> [< 'sTR" Require Marker"; 'fNL >] | (_,"END-SECTION") -> [< >] | (_,s) -> [< 'sTR(string_of_path sp); 'sTR" : "; 'sTR"Unrecognized object "; 'sTR s; 'fNL >] let rec print_library_entry with_values ent = let sep = if with_values then " = " else " : " in match ent with | (sp,Lib.Leaf lobj) -> [< print_leaf_entry with_values sep (sp,lobj) >] | (_,Lib.OpenedSection (str,_)) -> [< 'sTR(" >>>>>>> Section "^(string_of_id str)); 'fNL >] | (sp,Lib.ClosedSection _) -> [< 'sTR" >>>>>>> Closed Section "; pr_id (basename sp); 'fNL >] | (_,Lib.Module dir) -> [< 'sTR(" >>>>>>> Module " ^ (string_of_dirpath dir)); 'fNL >] | (_,Lib.FrozenState _) -> [< >] and print_context with_values = let rec prec = function | h::rest -> [< prec rest ; print_library_entry with_values h >] | [] -> [< >] in prec let print_full_context () = print_context true (Lib.contents_after None) let print_full_context_typ () = print_context false (Lib.contents_after None) (* For printing an inductive definition with its constructors and elimination, assume that the declaration of constructors and eliminations follows the definition of the inductive type *) let list_filter_vec f vec = let rec frec n lf = if n < 0 then lf else if f vec.(n) then frec (n-1) (vec.(n)::lf) else frec (n-1) lf in frec (Array.length vec -1) [] let read_sec_context qid = let dir = Nametab.locate_section qid in let rec get_cxt in_cxt = function | ((sp,Lib.OpenedSection (_,_)) as hd)::rest -> let dir' = make_dirpath (wd_of_sp sp) in if dir = dir' then (hd::in_cxt) else get_cxt (hd::in_cxt) rest | [] -> [] | hd::rest -> get_cxt (hd::in_cxt) rest in let cxt = (Lib.contents_after None) in List.rev (get_cxt [] cxt) let print_sec_context sec = print_context true (read_sec_context sec) let print_sec_context_typ sec = print_context false (read_sec_context sec) let print_judgment env {uj_val=trm;uj_type=typ} = print_typed_value_in_env env (trm, typ) let print_safe_judgment env j = let trm = Safe_typing.j_val j in let typ = Safe_typing.j_type j in print_typed_value_in_env env (trm, typ) let print_eval red_fun env {uj_val=trm;uj_type=typ} = let ntrm = red_fun env Evd.empty trm in [< 'sTR " = "; print_judgment env {uj_val = ntrm; uj_type = typ} >] let print_name qid = try let sp = Nametab.locate_obj qid in let (sp,lobj) = let (sp,entry) = List.find (fun en -> (fst en) = sp) (Lib.contents_after None) in match entry with | Lib.Leaf obj -> (sp,obj) | _ -> raise Not_found in print_leaf_entry true " = " (sp,lobj) with Not_found -> try match Nametab.locate qid with | ConstRef sp -> print_constant true " = " sp | IndRef (sp,_) -> print_inductive sp | ConstructRef ((sp,_),_) -> print_inductive sp | VarRef sp -> print_section_variable sp with Not_found -> try (* Var locale de but, pas var de section... donc pas d'implicits *) let dir,str = repr_qualid qid in if dir <> [] then raise Not_found; let (c,typ) = Global.lookup_named str in [< print_named_decl (str,c,typ) >] with Not_found -> try let sp = Syntax_def.locate_syntactic_definition qid in print_syntactic_def " = " sp with Not_found -> errorlabstrm "print_name" [< pr_qualid qid; 'sPC; 'sTR "not a defined object" >] let print_opaque_name qid = let sigma = Evd.empty in let env = Global.env () in let sign = Global.named_context () in try let x = global_qualified_reference qid in match kind_of_term x with | IsConst (sp,_ as cst) -> let cb = Global.lookup_constant sp in if is_defined cb then print_constant true " = " sp else error "not a defined constant" | IsMutInd ((sp,_),_) -> print_mutual sp | IsMutConstruct cstr -> let ty = Typeops.type_of_constructor env sigma cstr in print_typed_value (x, ty) | IsVar id -> let (c,ty) = lookup_named id env in print_named_decl (id,c,ty) | _ -> assert false with Not_found -> errorlabstrm "print_opaque" [< pr_qualid qid; 'sPC; 'sTR "not declared" >] let print_local_context () = let env = Lib.contents_after None in let rec print_var_rec = function | [] -> [< >] | (sp,Lib.Leaf lobj)::rest -> if "VARIABLE" = object_tag lobj then let (d,_,_) = get_variable sp in [< print_var_rec rest; print_named_decl d >] else print_var_rec rest | _::rest -> print_var_rec rest and print_last_const = function | (sp,Lib.Leaf lobj)::rest -> (match object_tag lobj with | "CONSTANT" | "PARAMETER" -> let {const_body=val_0;const_type=typ} = Global.lookup_constant sp in [< print_last_const rest; print_basename sp ;'sTR" = "; print_typed_body (val_0,typ) >] | "INDUCTIVE" -> [< print_last_const rest;print_mutual sp; 'fNL >] | "VARIABLE" -> [< >] | _ -> print_last_const rest) | _ -> [< >] in [< print_var_rec env; print_last_const env >] let fprint_var name typ = [< 'sTR ("*** [" ^ name ^ " :"); fprtype typ; 'sTR "]"; 'fNL >] let fprint_judge {uj_val=trm;uj_type=typ} = [< fprterm trm; 'sTR" : " ; fprterm (body_of_type typ) >] let unfold_head_fconst = let rec unfrec k = match kind_of_term k with | IsConst cst -> constant_value (Global.env ()) cst | IsLambda (na,t,b) -> mkLambda (na,t,unfrec b) | IsApp (f,v) -> appvect (unfrec f,v) | _ -> k in unfrec (* for debug *) let inspect depth = let rec inspectrec n res env = if n=0 or env=[] then res else inspectrec (n-1) (List.hd env::res) (List.tl env) in let items = List.rev (inspectrec depth [] (Lib.contents_after None)) in print_context false items (*************************************************************************) (* Pretty-printing functions coming from classops.ml *) open Classops let string_of_strength = function | NotDeclare -> "(temp)" | NeverDischarge -> "(global)" | DischargeAt sp -> "(disch@"^(string_of_dirpath sp) let print_coercion_value v = prterm (get_coercion_value v) let print_index_coercion c = let _,v = coercion_info_from_index c in print_coercion_value v let print_class i = let cl,_ = class_info_from_index i in [< 'sTR (string_of_class cl) >] let print_path ((i,j),p) = [< 'sTR"["; prlist_with_sep (fun () -> [< 'sTR"; " >]) (fun c -> print_index_coercion c) p; 'sTR"] : "; print_class i; 'sTR" >-> "; print_class j >] let _ = Classops.install_path_printer print_path let print_graph () = [< prlist_with_sep pr_fnl print_path (inheritance_graph()) >] let print_classes () = [< prlist_with_sep pr_spc (fun (_,(cl,x)) -> [< 'sTR (string_of_class cl) (*; 'sTR(string_of_strength x.cl_strength) *) >]) (classes()) >] let print_coercions () = [< prlist_with_sep pr_spc (fun (_,(_,v)) -> [< print_coercion_value v >]) (coercions()) >] let cl_of_id id = match string_of_id id with | "FUNCLASS" -> CL_FUN | "SORTCLASS" -> CL_SORT | _ -> let v = Declare.global_reference CCI id in let cl,_ = constructor_at_head v in cl let index_cl_of_id id = try let cl = cl_of_id id in let i,_ = class_info cl in i with _ -> errorlabstrm "index_cl_of_id" [< 'sTR(string_of_id id); 'sTR" is not a defined class" >] let print_path_between ids idt = let i = (index_cl_of_id ids) in let j = (index_cl_of_id idt) in let p = try lookup_path_between (i,j) with _ -> errorlabstrm "index_cl_of_id" [< 'sTR"No path between ";'sTR(string_of_id ids); 'sTR" and ";'sTR(string_of_id ids) >] in print_path ((i,j),p) (*************************************************************************)