%% %% %CopyrightBegin% %% %% Copyright Ericsson AB 1997-2013. All Rights Reserved. %% %% The contents of this file are subject to the Erlang Public License, %% Version 1.1, (the "License"); you may not use this file except in %% compliance with the License. You should have received a copy of the %% Erlang Public License along with this software. If not, it can be %% retrieved online at http://www.erlang.org/. %% %% Software distributed under the License is distributed on an "AS IS" %% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See %% the License for the specific language governing rights and limitations %% under the License. %% %% %CopyrightEnd% %% %% -module(asn1ct_gen_per). %% Generate erlang module which handles (PER) encode and decode for %% all types in an ASN.1 module -include("asn1_records.hrl"). %-compile(export_all). -export([gen_dec_imm/2]). -export([gen_dec_prim/3,gen_encode_prim/4]). -export([gen_obj_code/3,gen_objectset_code/2]). -export([gen_decode/2, gen_decode/3]). -export([gen_encode/2, gen_encode/3]). -export([extaddgroup2sequence/1]). -import(asn1ct_gen, [emit/1,demit/1]). -import(asn1ct_func, [call/3]). %% Generate ENCODING ****************************** %%****************************************x gen_encode(Erules,Type) when is_record(Type,typedef) -> gen_encode_user(Erules,Type). %% case Type#typedef.typespec of %% Def when is_record(Def,type) -> %% gen_encode_user(Erules,Type); %% Def when is_tuple(Def),(element(1,Def) == 'Object') -> %% gen_encode_object(Erules,Type); %% Other -> %% exit({error,{asn1,{unknown,Other}}}) %% end. gen_encode(Erules,Typename,#'ComponentType'{name=Cname,typespec=Type}) -> NewTypename = [Cname|Typename], gen_encode(Erules,NewTypename,Type); gen_encode(Erules,Typename,Type) when is_record(Type,type) -> InnerType = asn1ct_gen:get_inner(Type#type.def), ObjFun = case lists:keysearch(objfun,1,Type#type.tablecinf) of {value,{_,_Name}} -> %% lists:concat([", ObjFun",Name]); ", ObjFun"; false -> "" end, case asn1ct_gen:type(InnerType) of {constructed,bif} -> emit({"'enc_",asn1ct_gen:list2name(Typename),"'(Val",ObjFun, ") ->",nl}), asn1ct_gen:gen_encode_constructed(Erules,Typename,InnerType,Type); _ -> true end. gen_encode_user(Erules,D) when is_record(D,typedef) -> CurrMod = get(currmod), Typename = [D#typedef.name], Def = D#typedef.typespec, InnerType = asn1ct_gen:get_inner(Def#type.def), emit({"'enc_",asn1ct_gen:list2name(Typename),"'(Val) ->",nl}), case asn1ct_gen:type(InnerType) of {primitive,bif} -> gen_encode_prim(Erules,Def,"false"), emit({".",nl}); 'ASN1_OPEN_TYPE' -> gen_encode_prim(Erules,Def#type{def='ASN1_OPEN_TYPE'},"false"), emit({".",nl}); {constructed,bif} -> asn1ct_gen:gen_encode_constructed(Erules,Typename,InnerType,D); #'Externaltypereference'{module=CurrMod,type=Etype} -> emit({"'enc_",Etype,"'(Val).",nl,nl}); #'Externaltypereference'{module=Emod,type=Etype} -> emit({"'",Emod,"':'enc_",Etype,"'(Val).",nl,nl}); #typereference{val=Ename} -> emit({"'enc_",Ename,"'(Val).",nl,nl}); {notype,_} -> emit({"'enc_",InnerType,"'(Val).",nl,nl}) end. gen_encode_prim(Erules,D,DoTag) -> Value = asn1ct_gen:mk_var(asn1ct_name:curr(val)), gen_encode_prim(Erules,D,DoTag,Value). gen_encode_prim(Erules, #type{def={'ENUMERATED',{N1,N2}}}, _, Value) -> NewList = [{0,X} || {X,_} <- N1] ++ ['EXT_MARK'] ++ [{1,X} || {X,_} <- N2], NewC = {0,length(N1)-1}, emit(["case ",Value," of",nl]), emit_enc_enumerated_cases(Erules, NewC, NewList, 0); gen_encode_prim(Erules, #type{def={'ENUMERATED',NNL}}, _, Value) -> NewList = [X || {X,_} <- NNL], NewC = {0,length(NewList)-1}, emit(["case ",Value," of",nl]), emit_enc_enumerated_cases(Erules, NewC, NewList, 0); gen_encode_prim(per=Erules, D, DoTag, Value) -> asn1ct_gen_per_rt2ct:gen_encode_prim(Erules, D, DoTag, Value); gen_encode_prim(Erules,D,DoTag,Value) when is_record(D,type) -> Constraint = D#type.constraint, asn1ct_name:new(enumval), case D#type.def of 'INTEGER' -> Args = [{asis,asn1ct_imm:effective_constraint(integer,Constraint)}, Value], call(Erules, encode_integer, Args); {'INTEGER',NamedNumberList} -> Args = [{asis,asn1ct_imm:effective_constraint(integer,Constraint)}, Value,{asis,NamedNumberList}], call(Erules, encode_integer, Args); 'REAL' -> emit_enc_real(Erules, Value); {'BIT STRING',NamedNumberList} -> SizeConstr = get_constraint(Constraint, 'SizeConstraint'), call(Erules, encode_bit_string, [{asis,SizeConstr},Value, {asis,NamedNumberList}]); 'NULL' -> emit("[]"); 'OBJECT IDENTIFIER' -> call(Erules, encode_object_identifier, [Value]); 'RELATIVE-OID' -> call(Erules, encode_relative_oid, [Value]); 'ObjectDescriptor' -> call(Erules, encode_ObjectDescriptor, [{asis,Constraint},Value]); 'BOOLEAN' -> call(Erules, encode_boolean, [Value]); 'OCTET STRING' -> case get_constraint(Constraint, 'SizeConstraint') of 0 -> emit("[]"); no -> call(Erules, encode_octet_string, [Value]); C -> call(Erules, encode_octet_string, [{asis,C},Value]) end; 'NumericString' -> call(Erules, encode_NumericString, [{asis,Constraint},Value]); TString when TString == 'TeletexString'; TString == 'T61String' -> call(Erules, encode_TeletexString, [{asis,Constraint},Value]); 'VideotexString' -> call(Erules, encode_VideotexString, [{asis,Constraint},Value]); 'UTCTime' -> call(Erules, encode_VisibleString, [{asis,Constraint},Value]); 'GeneralizedTime' -> call(Erules, encode_VisibleString, [{asis,Constraint},Value]); 'GraphicString' -> call(Erules, encode_GraphicString, [{asis,Constraint},Value]); 'VisibleString' -> call(Erules, encode_VisibleString, [{asis,Constraint},Value]); 'GeneralString' -> call(Erules, encode_GeneralString, [{asis,Constraint},Value]); 'PrintableString' -> call(Erules, encode_PrintableString, [{asis,Constraint},Value]); 'IA5String' -> call(Erules, encode_IA5String, [{asis,Constraint},Value]); 'BMPString' -> call(Erules, encode_BMPString, [{asis,Constraint},Value]); 'UniversalString' -> call(Erules, encode_UniversalString, [{asis,Constraint},Value]); 'UTF8String' -> call(Erules, encode_UTF8String, [Value]); 'ANY' -> call(Erules, encode_open_type, [Value]); 'ASN1_OPEN_TYPE' -> NewValue = case Constraint of [#'Externaltypereference'{type=Tname}] -> asn1ct_func:need({Erules,complete,1}), io_lib:format( "complete(enc_~s(~s))",[Tname,Value]); [#type{def=#'Externaltypereference'{type=Tname}}] -> asn1ct_func:need({Erules,complete,1}), io_lib:format( "complete(enc_~s(~s))", [Tname,Value]); _ -> Value end, call(Erules, encode_open_type, [NewValue]); #'ObjectClassFieldType'{} -> case asn1ct_gen:get_inner(D#type.def) of {fixedtypevaluefield,_,InnerType} -> gen_encode_prim(Erules,InnerType,DoTag,Value); T -> %% 'ASN1_OPEN_TYPE' gen_encode_prim(Erules,D#type{def=T},DoTag,Value) end; XX -> exit({asn1_error,nyi,XX}) end. emit_enc_real(Erules, Real) -> asn1ct_name:new(tmpval), asn1ct_name:new(tmplen), emit(["begin",nl, "{",{curr,tmpval},com,{curr,tmplen},"} = ", {call,real_common,encode_real,[Real]},com,nl, "[",{call,Erules,encode_length,[{curr,tmplen}]},",", {curr,tmpval},"]",nl, "end"]). emit_enc_enumerated_cases(Erules, C, ['EXT_MARK'|T], _Count) -> %% Reset enumeration counter. emit_enc_enumerated_cases(Erules, C, T, 0); emit_enc_enumerated_cases(Erules, C, [H|T], Count) -> emit_enc_enumerated_case(Erules, C, H, Count), emit([";",nl]), emit_enc_enumerated_cases(Erules, C, T, Count+1); emit_enc_enumerated_cases(_Erules, _, [], _Count) -> emit(["EnumVal -> " "exit({error,{asn1,{enumerated_not_in_range, EnumVal}}})",nl, "end"]). emit_enc_enumerated_case(Erules, C, {0,EnumName}, Count) -> %% ENUMERATED with extensionmark; the value lies within then extension root Enc = enc_ext_and_val(Erules, 0, encode_constrained_number, [C,Count]), emit(["'",EnumName,"' -> ",{asis,Enc}]); emit_enc_enumerated_case(Erules, _C, {1,EnumName}, Count) -> %% ENUMERATED with extensionmark; the value is higher than extension root Enc = enc_ext_and_val(Erules, 1, encode_small_number, [Count]), emit(["'",EnumName,"' -> ",{asis,Enc}]); emit_enc_enumerated_case(Erules, C, EnumName, Count) -> %% ENUMERATED without extension EvalMod = eval_module(Erules), emit(["'",EnumName,"' -> ", {asis,EvalMod:encode_constrained_number(C, Count)}]). enc_ext_and_val(per, E, F, Args) -> [E|apply(asn1ct_eval_per, F, Args)]; enc_ext_and_val(uper, E, F, Args) -> <>. get_constraint([{Key,V}], Key) -> V; get_constraint([], _) -> no; get_constraint(C, Key) -> case lists:keyfind(Key, 1, C) of false -> no; {Key,V} -> V end. %% Object code generating for encoding and decoding %% ------------------------------------------------ gen_obj_code(Erules,_Module,Obj) when is_record(Obj,typedef) -> ObjName = Obj#typedef.name, Def = Obj#typedef.typespec, #'Externaltypereference'{module=Mod,type=ClassName} = Def#'Object'.classname, Class = asn1_db:dbget(Mod,ClassName), {object,_,Fields} = Def#'Object'.def, emit({nl,nl,nl,"%%================================"}), emit({nl,"%% ",ObjName}), emit({nl,"%%================================",nl}), EncConstructed = gen_encode_objectfields(Erules, ClassName,get_class_fields(Class), ObjName,Fields,[]), emit(nl), gen_encode_constr_type(Erules,EncConstructed), emit(nl), DecConstructed = gen_decode_objectfields(Erules, ClassName, get_class_fields(Class), ObjName, Fields, []), emit(nl), gen_decode_constr_type(Erules,DecConstructed), emit(nl); gen_obj_code(_,_,Obj) when is_record(Obj,pobjectdef) -> ok. gen_encode_objectfields(Erule, ClassName, [{typefield,Name,OptOrMand}|Rest], ObjName, ObjectFields, ConstrAcc) -> EmitFuncClause = fun(V) -> emit(["'enc_",ObjName,"'(",{asis,Name}, ",",V,",_RestPrimFieldName) ->",nl]) end, % emit(["'enc_",ObjName,"'(",{asis,Name}, % ", Val, _RestPrimFieldName) ->",nl]), MaybeConstr = case {get_object_field(Name,ObjectFields),OptOrMand} of {false,'MANDATORY'} -> %% this case is illegal exit({error,{asn1,{"missing mandatory field in object", ObjName}}}); {false,'OPTIONAL'} -> EmitFuncClause("Val"), case Erule of uper -> emit(" Val"); per -> emit([" if",nl, " is_list(Val) ->",nl, " NewVal = list_to_binary(Val),",nl, " [20,byte_size(NewVal),NewVal];",nl, " is_binary(Val) ->",nl, " [20,byte_size(Val),Val]",nl, " end"]) end, []; {false,{'DEFAULT',DefaultType}} -> EmitFuncClause("Val"), gen_encode_default_call(Erule, ClassName, Name, DefaultType); {{Name,TypeSpec},_} -> %% A specified field owerwrites any 'DEFAULT' or %% 'OPTIONAL' field in the class EmitFuncClause("Val"), gen_encode_field_call(Erule, ObjName, Name, TypeSpec) end, case more_genfields(Rest) of true -> emit([";",nl]); false -> emit([".",nl]) end, gen_encode_objectfields(Erule,ClassName,Rest,ObjName,ObjectFields, MaybeConstr++ConstrAcc); gen_encode_objectfields(Erule,ClassName,[{objectfield,Name,_,_,OptOrMand}|Rest], ObjName,ObjectFields,ConstrAcc) -> CurrentMod = get(currmod), EmitFuncClause = fun(Attrs) -> emit(["'enc_",ObjName,"'(",{asis,Name}, ",",Attrs,") ->",nl]) end, % emit(["'enc_",ObjName,"'(",{asis,Name}, % ", Val,[H|T]) ->",nl]), case {get_object_field(Name,ObjectFields),OptOrMand} of {false,'MANDATORY'} -> exit({error,{asn1,{"missing mandatory field in object", ObjName}}}); {false,'OPTIONAL'} -> EmitFuncClause("_,_"), emit([" exit({error,{'use of missing field in object', ",{asis,Name}, "}})"]); {false,{'DEFAULT',_DefaultObject}} -> exit({error,{asn1,{"not implemented yet",Name}}}); {{Name,#'Externalvaluereference'{module=CurrentMod, value=TypeName}},_} -> EmitFuncClause(" Val, [H|T]"), emit({indent(3),"'enc_",TypeName,"'(H, Val, T)"}); {{Name,#'Externalvaluereference'{module=M,value=TypeName}},_} -> EmitFuncClause(" Val, [H|T]"), emit({indent(3),"'",M,"':'enc_",TypeName,"'(H, Val, T)"}); {{Name,TypeSpec},_} -> EmitFuncClause("Val,[H|T]"), case TypeSpec#typedef.name of {ExtMod,TypeName} -> emit({indent(3),"'",ExtMod,"':'enc_",TypeName, "'(H, Val, T)"}); TypeName -> emit({indent(3),"'enc_",TypeName,"'(H, Val, T)"}) end end, case more_genfields(Rest) of true -> emit([";",nl]); false -> emit([".",nl]) end, gen_encode_objectfields(Erule,ClassName,Rest,ObjName,ObjectFields,ConstrAcc); gen_encode_objectfields(Erule,ClassName,[_C|Cs],O,OF,Acc) -> gen_encode_objectfields(Erule,ClassName,Cs,O,OF,Acc); gen_encode_objectfields(_, _,[],_,_,Acc) -> Acc. gen_encode_constr_type(Erules,[TypeDef|Rest]) when is_record(TypeDef,typedef) -> case is_already_generated(enc,TypeDef#typedef.name) of true -> ok; _ -> %% FuncName = list_to_atom(lists:concat(["enc_",TypeDef#typedef.name])), FuncName = asn1ct_gen:list2rname(TypeDef#typedef.name ++ [enc]), emit(["'",FuncName,"'(Val) ->",nl]), Def = TypeDef#typedef.typespec, InnerType = asn1ct_gen:get_inner(Def#type.def), asn1ct_gen:gen_encode_constructed(Erules,TypeDef#typedef.name, InnerType,Def), gen_encode_constr_type(Erules,Rest) end; gen_encode_constr_type(_,[]) -> ok. gen_encode_field_call(_Erules, _ObjName, _FieldName, #'Externaltypereference'{module=M,type=T}) -> CurrentMod = get(currmod), if M == CurrentMod -> emit({" 'enc_",T,"'(Val)"}), []; true -> emit({" '",M,"':'enc_",T,"'(Val)"}), [] end; gen_encode_field_call(Erules, ObjName, FieldName, Type) -> Def = Type#typedef.typespec, case Type#typedef.name of {primitive,bif} -> gen_encode_prim(Erules, Def, "false", "Val"), []; {constructed,bif} -> emit({" 'enc_",ObjName,'_',FieldName, "'(Val)"}), %% [Type#typedef{name=list_to_atom(lists:concat([ObjName,'_',FieldName]))}]; [Type#typedef{name=[FieldName,ObjName]}]; {ExtMod,TypeName} -> emit({" '",ExtMod,"':'enc_",TypeName, "'(Val)"}), []; TypeName -> emit({" 'enc_",TypeName,"'(Val)"}), [] end. gen_encode_default_call(Erules, ClassName, FieldName, Type) -> CurrentMod = get(currmod), InnerType = asn1ct_gen:get_inner(Type#type.def), case asn1ct_gen:type(InnerType) of {constructed,bif} -> %% asn1ct_gen:gen_encode_constructed(Erules,Typename,InnerType,Type); emit([" 'enc_",ClassName,'_',FieldName,"'(Val)"]), %% [#typedef{name=list_to_atom(lists:concat([ClassName,'_',FieldName])), [#typedef{name=[FieldName,ClassName], typespec=Type}]; {primitive,bif} -> gen_encode_prim(Erules, Type, "false", "Val"), []; #'Externaltypereference'{module=CurrentMod,type=Etype} -> emit([" 'enc_",Etype,"'(Val)",nl]), []; #'Externaltypereference'{module=Emod,type=Etype} -> emit([" '",Emod,"':'enc_",Etype,"'(Val)",nl]), [] end. gen_decode_objectfields(Erules, ClassName, [{typefield,Name,OptOrMand}|Rest], ObjName, ObjectFields, ConstrAcc) -> EmitFuncClause = fun(Bytes) -> emit(["'dec_",ObjName,"'(",{asis,Name},",",Bytes, ",_,_RestPrimFieldName) ->",nl]) end, MaybeConstr= case {get_object_field(Name,ObjectFields),OptOrMand} of {false,'MANDATORY'} -> %% this case is illegal exit({error,{asn1,{"missing mandatory field in object", ObjName}}}); {false,'OPTIONAL'} -> EmitFuncClause("Bytes"), emit([" {Bytes,[]}"]), []; {false,{'DEFAULT',DefaultType}} -> EmitFuncClause("Bytes"), gen_decode_default_call(Erules, ClassName, Name, "Bytes", DefaultType); {{Name,TypeSpec},_} -> %% A specified field owerwrites any 'DEFAULT' or %% 'OPTIONAL' field in the class EmitFuncClause("Bytes"), gen_decode_field_call(Erules, ObjName, Name, "Bytes", TypeSpec) end, case more_genfields(Rest) of true -> emit([";",nl]); false -> emit([".",nl]) end, gen_decode_objectfields(Erules, ClassName, Rest, ObjName, ObjectFields, MaybeConstr++ConstrAcc); gen_decode_objectfields(Erules, ClassName, [{objectfield,Name,_,_,OptOrMand}|Rest], ObjName, ObjectFields, ConstrAcc) -> CurrentMod = get(currmod), EmitFuncClause = fun(Attrs) -> emit(["'dec_",ObjName,"'(",{asis,Name}, ",",Attrs,") ->",nl]) end, % emit(["'dec_",ObjName,"'(",{asis,Name}, % ", Bytes,_,[H|T]) ->",nl]), case {get_object_field(Name,ObjectFields),OptOrMand} of {false,'MANDATORY'} -> exit({error,{asn1,{"missing mandatory field in object", ObjName}}}); {false,'OPTIONAL'} -> EmitFuncClause("_,_,_"), emit([" exit({error,{'illegal use of missing field in object', ",{asis,Name}, "}})"]); {false,{'DEFAULT',_DefaultObject}} -> exit({error,{asn1,{"not implemented yet",Name}}}); {{Name,#'Externalvaluereference'{module=CurrentMod, value=TypeName}},_} -> EmitFuncClause("Bytes,_,[H|T]"), emit({indent(3),"'dec_",TypeName,"'(H, Bytes, telltype, T)"}); {{Name,#'Externalvaluereference'{module=M,value=TypeName}},_} -> EmitFuncClause("Bytes,_,[H|T]"), emit({indent(3),"'",M,"':'dec_",TypeName, "'(H, Bytes, telltype, T)"}); {{Name,TypeSpec},_} -> EmitFuncClause("Bytes,_,[H|T]"), case TypeSpec#typedef.name of {ExtMod,TypeName} -> emit({indent(3),"'",ExtMod,"':'dec_",TypeName, "'(H, Bytes, telltype, T)"}); TypeName -> emit({indent(3),"'dec_",TypeName,"'(H, Bytes, telltype, T)"}) end end, case more_genfields(Rest) of true -> emit([";",nl]); false -> emit([".",nl]) end, gen_decode_objectfields(Erules, ClassName, Rest, ObjName, ObjectFields, ConstrAcc); gen_decode_objectfields(Erules, CN, [_C|Cs], O, OF, CAcc) -> gen_decode_objectfields(Erules, CN, Cs, O, OF, CAcc); gen_decode_objectfields(_, _, [], _, _, CAcc) -> CAcc. gen_decode_field_call(_Erules, _ObjName, _FieldName, Bytes, #'Externaltypereference'{module=M,type=T}) -> CurrentMod = get(currmod), if M == CurrentMod -> emit([" 'dec_",T,"'(",Bytes,", telltype)"]), []; true -> emit([" '",M,"':'dec_",T,"'(",Bytes,", telltype)"]), [] end; gen_decode_field_call(Erules, ObjName, FieldName, Bytes, Type) -> Def = Type#typedef.typespec, case Type#typedef.name of {primitive,bif} -> gen_dec_prim(Erules, Def, Bytes), []; {constructed,bif} -> emit({" 'dec_",ObjName,'_',FieldName, "'(",Bytes,",telltype)"}), %% [Type#typedef{name=list_to_atom(lists:concat([ObjName,'_',FieldName]))}]; [Type#typedef{name=[FieldName,ObjName]}]; {ExtMod,TypeName} -> emit({" '",ExtMod,"':'dec_",TypeName, "'(",Bytes,", telltype)"}), []; TypeName -> emit({" 'dec_",TypeName,"'(",Bytes,", telltype)"}), [] end. gen_decode_default_call(Erules, ClassName, FieldName, Bytes, Type) -> CurrentMod = get(currmod), InnerType = asn1ct_gen:get_inner(Type#type.def), case asn1ct_gen:type(InnerType) of {constructed,bif} -> emit([" 'dec_",ClassName,'_',FieldName,"'(",Bytes,", telltype)"]), %% [#typedef{name=list_to_atom(lists:concat([ClassName,'_',FieldName])), [#typedef{name=[FieldName,ClassName], typespec=Type}]; {primitive,bif} -> gen_dec_prim(Erules, Type, Bytes), []; #'Externaltypereference'{module=CurrentMod,type=Etype} -> emit([" 'dec_",Etype,"'(",Bytes,", telltype)",nl]), []; #'Externaltypereference'{module=Emod,type=Etype} -> emit([" '",Emod,"':'dec_",Etype,"'(",Bytes,", telltype)",nl]), [] end. gen_decode_constr_type(Erules,[TypeDef|Rest]) when is_record(TypeDef,typedef) -> case is_already_generated(dec,TypeDef#typedef.name) of true -> ok; _ -> gen_decode(Erules,TypeDef#typedef{name=asn1ct_gen:list2rname(TypeDef#typedef.name)}) end, gen_decode_constr_type(Erules,Rest); gen_decode_constr_type(_,[]) -> ok. more_genfields([]) -> false; more_genfields([Field|Fields]) -> case element(1,Field) of typefield -> true; objectfield -> true; _ -> more_genfields(Fields) end. %% Object Set code generating for encoding and decoding %% ---------------------------------------------------- gen_objectset_code(Erules,ObjSet) -> ObjSetName = ObjSet#typedef.name, Def = ObjSet#typedef.typespec, %% {ClassName,ClassDef} = Def#'ObjectSet'.class, #'Externaltypereference'{module=ClassModule, type=ClassName} = Def#'ObjectSet'.class, ClassDef = asn1_db:dbget(ClassModule,ClassName), UniqueFName = Def#'ObjectSet'.uniquefname, Set = Def#'ObjectSet'.set, emit({nl,nl,nl,"%%================================"}), emit({nl,"%% ",ObjSetName}), emit({nl,"%%================================",nl}), case ClassName of {_Module,ExtClassName} -> gen_objset_code(Erules,ObjSetName,UniqueFName,Set, ExtClassName,ClassDef); _ -> gen_objset_code(Erules,ObjSetName,UniqueFName,Set, ClassName,ClassDef) end, emit(nl). gen_objset_code(Erules,ObjSetName,UniqueFName,Set,ClassName,ClassDef)-> ClassFields = (ClassDef#classdef.typespec)#objectclass.fields, InternalFuncs= gen_objset_enc(Erules,ObjSetName,UniqueFName,Set,ClassName,ClassFields,1,[]), gen_objset_dec(Erules, ObjSetName,UniqueFName,Set,ClassName,ClassFields,1), gen_internal_funcs(Erules,InternalFuncs). %% gen_objset_enc iterates over the objects of the object set gen_objset_enc(_,_,{unique,undefined},_,_,_,_,_) -> %% There is no unique field in the class of this object set %% don't bother about the constraint []; gen_objset_enc(Erule, ObjSetName, UniqueName, [{ObjName,Val,Fields}|T], ClName, ClFields, NthObj, Acc)-> emit(["'getenc_",ObjSetName,"'(",{asis,UniqueName},",",{asis,Val}, ") ->",nl]), CurrMod = get(currmod), {InternalFunc,NewNthObj}= case ObjName of {no_mod,no_name} -> gen_inlined_enc_funs(Erule, Fields, ClFields, ObjSetName, NthObj); {CurrMod,Name} -> emit({" fun 'enc_",Name,"'/3"}), {[],0}; {ModName,Name} -> emit_ext_encfun(ModName,Name), {[],0}; _Other -> emit({" fun 'enc_",ObjName,"'/3"}), {[],0} end, emit({";",nl}), gen_objset_enc(Erule, ObjSetName, UniqueName, T, ClName, ClFields, NewNthObj, InternalFunc ++ Acc); gen_objset_enc(uper, ObjSetName, _UniqueName, ['EXTENSIONMARK'], _ClName, _ClFields, _NthObj, Acc) -> emit({"'getenc_",ObjSetName,"'(_, _) ->",nl}), emit({indent(3),"fun(_, Val, _) ->",nl}), emit([indent(6),"Val",nl, indent(3),"end.",nl,nl]), Acc; gen_objset_enc(per, ObjSetName, _UniqueName, ['EXTENSIONMARK'], _ClName, _ClFields, _NthObj, Acc) -> emit(["'getenc_",ObjSetName,"'(_, _) ->",nl, indent(3),"fun(_, Val, _) ->",nl, indent(6),"BinVal = if",nl, indent(9),"is_list(Val) -> list_to_binary(Val);",nl, indent(9),"true -> Val",nl, indent(6),"end,",nl, indent(6),"Size = byte_size(BinVal),",nl, indent(6),"if",nl, indent(9),"Size < 256 ->",nl, indent(12),"[20,Size,BinVal];",nl, indent(9),"true ->",nl, indent(12),"[21,<>,Val]",nl, indent(6),"end",nl, indent(3),"end.",nl,nl]), Acc; gen_objset_enc(_, ObjSetName, UniqueName, [], _, _, _, Acc) -> emit_default_getenc(ObjSetName, UniqueName), emit([".",nl,nl]), Acc. emit_ext_encfun(ModuleName,Name) -> emit([indent(4),"fun(T,V,O) -> '",ModuleName,"':'enc_", Name,"'(T,V,O) end"]). emit_default_getenc(ObjSetName,UniqueName) -> emit(["'getenc_",ObjSetName,"'(",{asis,UniqueName},", ErrV) ->",nl]), emit([indent(4),"fun(C,V,_) -> exit({'Type not compatible with table constraint',{component,C},{value,V},{unique_name_and_value,",{asis,UniqueName},",ErrV}}) end"]). %% gen_inlined_enc_funs for each object iterates over all fields of a %% class, and for each typefield it checks if the object has that %% field and emits the proper code. gen_inlined_enc_funs(Erule, Fields, [{typefield,_,_}|_]=T, ObjSetName, NthObj) -> emit([indent(3),"fun(Type, Val, _) ->",nl, indent(6),"case Type of",nl]), gen_inlined_enc_funs1(Erule, Fields, T, ObjSetName, [], NthObj, []); gen_inlined_enc_funs(Erule,Fields,[_H|Rest],ObjSetName,NthObj) -> gen_inlined_enc_funs(Erule,Fields,Rest,ObjSetName,NthObj); gen_inlined_enc_funs(_,_,[],_,NthObj) -> {[],NthObj}. gen_inlined_enc_funs1(Erule, Fields, [{typefield,Name,_}|Rest], ObjSetName, Sep0, NthObj, Acc0) -> emit(Sep0), Sep = [";",nl], CurrentMod = get(currmod), InternalDefFunName = asn1ct_gen:list2name([NthObj,Name,ObjSetName]), {Acc,NAdd} = case lists:keyfind(Name, 1, Fields) of {_,#type{}=Type} -> {Ret,N} = emit_inner_of_fun(Erule, Type, InternalDefFunName), {Ret++Acc0,N}; {_,#typedef{}=Type} -> emit([indent(9),{asis,Name}," ->",nl]), {Ret,N} = emit_inner_of_fun(Erule, Type, InternalDefFunName), {Ret++Acc0,N}; {_,#'Externaltypereference'{module=CurrentMod,type=T}} -> emit([indent(9),{asis,Name}," ->",nl, indent(12),"'enc_",T,"'(Val)"]), {Acc0,0}; {_,#'Externaltypereference'{module=M,type=T}} -> emit([indent(9),{asis,Name}," ->",nl, indent(12),"'",M,"'",":'enc_",T,"'(Val)"]), {Acc0,0}; false when Erule =:= uper -> emit([indent(9),{asis,Name}," ->",nl, indent(12),"Val",nl]), {Acc0,0}; false when Erule =:= per -> emit([indent(9),{asis,Name}," ->",nl, indent(12),"Size = case Val of",nl, indent(15),"B when is_binary(B) -> size(B);",nl, indent(15),"_ -> length(Val)",nl, indent(12),"end,",nl, indent(12),"if",nl, indent(15),"Size < 256 -> [20,Size,Val];",nl, indent(15),"true -> [21,<>,Val]",nl, indent(12),"end"]), {Acc0,0} end, gen_inlined_enc_funs1(Erule, Fields, Rest, ObjSetName, Sep, NthObj+NAdd, Acc); gen_inlined_enc_funs1(Erule, Fields, [_|T], ObjSetName, Sep, NthObj, Acc)-> gen_inlined_enc_funs1(Erule, Fields, T, ObjSetName, Sep, NthObj, Acc); gen_inlined_enc_funs1(_, _, [], _, _, NthObj, Acc) -> emit([nl,indent(6),"end",nl, indent(3),"end"]), {Acc,NthObj}. emit_inner_of_fun(Erule, #typedef{name={ExtMod,Name},typespec=Type}=TDef, InternalDefFunName) -> case {ExtMod,Name} of {primitive,bif} -> emit(indent(12)), gen_encode_prim(Erule, Type, dotag, "Val"), {[],0}; {constructed,bif} -> emit([indent(12),"'enc_", InternalDefFunName,"'(Val)"]), {[TDef#typedef{name=InternalDefFunName}],1}; _ -> emit({indent(12),"'",ExtMod,"':'enc_",Name,"'(Val)"}), {[],0} end; emit_inner_of_fun(_Erule, #typedef{name=Name}, _) -> emit({indent(12),"'enc_",Name,"'(Val)"}), {[],0}; emit_inner_of_fun(Erule, #type{}=Type, _) -> CurrMod = get(currmod), case Type#type.def of Def when is_atom(Def) -> emit({indent(9),Def," ->",nl,indent(12)}), gen_encode_prim(Erule, Type, dotag, "Val"); TRef when is_record(TRef,typereference) -> T = TRef#typereference.val, emit({indent(9),T," ->",nl,indent(12),"'enc_",T,"'(Val)"}); #'Externaltypereference'{module=CurrMod,type=T} -> emit({indent(9),T," ->",nl,indent(12),"'enc_",T,"'(Val)"}); #'Externaltypereference'{module=ExtMod,type=T} -> emit({indent(9),T," ->",nl,indent(12),ExtMod,":'enc_", T,"'(Val)"}) end, {[],0}. indent(N) -> lists:duplicate(N,32). % 32 = space gen_objset_dec(_, _, {unique,undefined}, _, _, _, _) -> %% There is no unique field in the class of this object set %% don't bother about the constraint ok; gen_objset_dec(Erule, ObjSName, UniqueName, [{ObjName,Val,Fields}|T], ClName, ClFields, NthObj)-> emit({"'getdec_",ObjSName,"'(",{asis,UniqueName},",",{asis,Val}, ") ->",nl}), CurrMod = get(currmod), NewNthObj= case ObjName of {no_mod,no_name} -> gen_inlined_dec_funs(Erule, Fields, ClFields, ObjSName, NthObj); {CurrMod,Name} -> emit([" fun 'dec_",Name,"'/4"]), NthObj; {ModName,Name} -> emit_ext_decfun(ModName,Name), NthObj; _Other -> emit({" fun 'dec_",ObjName,"'/4"}), NthObj end, emit({";",nl}), gen_objset_dec(Erule, ObjSName, UniqueName, T, ClName, ClFields, NewNthObj); gen_objset_dec(_Erule, ObjSetName, _UniqueName, ['EXTENSIONMARK'], _ClName, _ClFields, _NthObj) -> emit({"'getdec_",ObjSetName,"'(_, _) ->",nl}), emit({indent(3),"fun(Attr1, Bytes, _,_) ->",nl}), emit({indent(6),"{Bytes,Attr1}",nl}), emit({indent(3),"end.",nl,nl}), ok; gen_objset_dec(_Erule, ObjSetName, UniqueName, [], _, _, _) -> emit_default_getdec(ObjSetName, UniqueName), emit([".",nl,nl]), ok. emit_ext_decfun(ModuleName,Name) -> emit([indent(3),"fun(T,V,O1,O2) -> '",ModuleName,"':'dec_", Name,"'(T,V,O1,O2) end"]). emit_default_getdec(ObjSetName,UniqueName) -> emit(["'getdec_",ObjSetName,"'(",{asis,UniqueName},", ErrV) ->",nl]), emit([indent(2), "fun(C,V,_,_) -> exit({{component,C},{value,V},{unique_name_and_value,",{asis,UniqueName},",ErrV}}) end"]). gen_inlined_dec_funs(Erule, Fields, List, ObjSetName, NthObj0) -> emit([indent(3),"fun(Type, Val, _, _) ->",nl, indent(6),"case Type of",nl]), NthObj = gen_inlined_dec_funs1(Erule, Fields, List, ObjSetName, "", NthObj0), emit([nl,indent(6),"end",nl, indent(3),"end"]), NthObj. gen_inlined_dec_funs1(Erule, Fields, [{typefield,Name,_}|Rest], ObjSetName, Sep0, NthObj) -> CurrentMod = get(currmod), InternalDefFunName = [NthObj,Name,ObjSetName], emit(Sep0), Sep = [";",nl], N = case lists:keyfind(Name, 1, Fields) of {_,#type{}=Type} -> emit_inner_of_decfun(Erule, Type, InternalDefFunName); {_,#typedef{}=Type} -> emit([indent(9),{asis,Name}," ->",nl]), emit_inner_of_decfun(Erule, Type, InternalDefFunName); {_,#'Externaltypereference'{module=CurrentMod,type=T}} -> emit([indent(9),{asis,Name}," ->",nl, indent(12),"'dec_",T,"'(Val,telltype)"]), 0; {_,#'Externaltypereference'{module=M,type=T}} -> emit([indent(9),{asis,Name}," ->",nl, indent(12),"'",M,"':'dec_",T,"'(Val,telltype)"]), 0; false -> emit([indent(9),{asis,Name}," -> {Val,Type}"]), 0 end, gen_inlined_dec_funs1(Erule, Fields, Rest, ObjSetName, Sep, NthObj+N); gen_inlined_dec_funs1(Erule, Fields, [_|Rest], ObjSetName, Sep, NthObj) -> gen_inlined_dec_funs1(Erule, Fields, Rest, ObjSetName, Sep, NthObj); gen_inlined_dec_funs1(_, _, [], _, _, NthObj) -> NthObj. emit_inner_of_decfun(Erule, #typedef{name={ExtName,Name},typespec=Type}, InternalDefFunName) -> case {ExtName,Name} of {primitive,bif} -> emit(indent(12)), gen_dec_prim(Erule, Type, "Val"), 0; {constructed,bif} -> emit({indent(12),"'dec_", asn1ct_gen:list2name(InternalDefFunName),"'(Val)"}), 1; _ -> emit({indent(12),"'",ExtName,"':'dec_",Name,"'(Val, telltype)"}), 0 end; emit_inner_of_decfun(_Erule, #typedef{name=Name}, _) -> emit({indent(12),"'dec_",Name,"'(Val, telltype)"}), 0; emit_inner_of_decfun(Erule, #type{}=Type, _) -> CurrMod = get(currmod), case Type#type.def of Def when is_atom(Def) -> emit({indent(9),Def," ->",nl,indent(12)}), gen_dec_prim(Erule, Type, "Val"); TRef when is_record(TRef,typereference) -> T = TRef#typereference.val, emit({indent(9),T," ->",nl,indent(12),"'dec_",T,"'(Val)"}); #'Externaltypereference'{module=CurrMod,type=T} -> emit({indent(9),T," ->",nl,indent(12),"'dec_",T,"'(Val)"}); #'Externaltypereference'{module=ExtMod,type=T} -> emit({indent(9),T," ->",nl,indent(12),ExtMod,":'dec_", T,"'(Val)"}) end, 0. gen_internal_funcs(_,[]) -> ok; gen_internal_funcs(Erules,[TypeDef|Rest]) -> gen_encode_user(Erules,TypeDef), emit([nl,nl,"'dec_",TypeDef#typedef.name,"'(Bytes) ->",nl]), gen_decode_user(Erules,TypeDef), gen_internal_funcs(Erules,Rest). %% DECODING ***************************** %%*************************************** gen_decode(Erules,Type) when is_record(Type,typedef) -> D = Type, emit({nl,nl}), emit({"'dec_",Type#typedef.name,"'(Bytes,_) ->",nl}), dbdec(Type#typedef.name), gen_decode_user(Erules,D). gen_decode(Erules,Tname,#'ComponentType'{name=Cname,typespec=Type}) -> NewTname = [Cname|Tname], gen_decode(Erules,NewTname,Type); gen_decode(Erules,Typename,Type) when is_record(Type,type) -> InnerType = asn1ct_gen:get_inner(Type#type.def), case asn1ct_gen:type(InnerType) of {constructed,bif} -> ObjFun = case Type#type.tablecinf of [{objfun,_}|_R] -> ", ObjFun"; _ -> "" end, emit({nl,"'dec_",asn1ct_gen:list2name(Typename), "'(Bytes,_",ObjFun,") ->",nl}), dbdec(Typename), asn1ct_gen:gen_decode_constructed(Erules,Typename,InnerType,Type); _ -> true end. dbdec(Type) when is_list(Type)-> demit({"io:format(\"decoding: ",asn1ct_gen:list2name(Type),"~w~n\",[Bytes]),",nl}); dbdec(Type) -> demit({"io:format(\"decoding: ",{asis,Type},"~w~n\",[Bytes]),",nl}). gen_decode_user(Erules,D) when is_record(D,typedef) -> CurrMod = get(currmod), Typename = [D#typedef.name], Def = D#typedef.typespec, InnerType = asn1ct_gen:get_inner(Def#type.def), case asn1ct_gen:type(InnerType) of {primitive,bif} -> gen_dec_prim(Erules,Def,"Bytes"), emit({".",nl,nl}); 'ASN1_OPEN_TYPE' -> gen_dec_prim(Erules,Def#type{def='ASN1_OPEN_TYPE'},"Bytes"), emit({".",nl,nl}); {constructed,bif} -> asn1ct_gen:gen_decode_constructed(Erules,Typename,InnerType,D); #typereference{val=Dname} -> emit({"'dec_",Dname,"'(Bytes,telltype)"}), emit({".",nl,nl}); #'Externaltypereference'{module=CurrMod,type=Etype} -> emit({"'dec_",Etype,"'(Bytes,telltype).",nl,nl}); #'Externaltypereference'{module=Emod,type=Etype} -> emit({"'",Emod,"':'dec_",Etype,"'(Bytes,telltype).",nl,nl}); Other -> exit({error,{asn1,{unknown,Other}}}) end. gen_dec_imm(Erule, #type{def=Name,constraint=C}) -> Aligned = case Erule of uper -> false; per -> true end, gen_dec_imm_1(Name, C, Aligned). gen_dec_imm_1('ASN1_OPEN_TYPE', Constraint, Aligned) -> imm_decode_open_type(Constraint, Aligned); gen_dec_imm_1('ANY', _Constraint, Aligned) -> imm_decode_open_type([], Aligned); gen_dec_imm_1({'BIT STRING',NNL}, Constr0, Aligned) -> Constr = get_constraint(Constr0, 'SizeConstraint'), Imm = asn1ct_imm:per_dec_raw_bitstring(Constr, Aligned), case NNL of [] -> case asn1ct:get_bit_string_format() of compact -> gen_dec_bit_string(decode_compact_bit_string, Imm); legacy -> gen_dec_bit_string(decode_legacy_bit_string, Imm); bitstring -> gen_dec_copy_bitstring(Imm) end; [_|_] -> D = fun(V, Buf) -> As = [V,{asis,NNL}], Call = {call,per_common,decode_named_bit_string,As}, emit(["{",Call,com,Buf,"}"]) end, {call,D,Imm} end; gen_dec_imm_1('NULL', _Constr, _Aligned) -> {value,'NULL'}; gen_dec_imm_1('BOOLEAN', _Constr, _Aligned) -> asn1ct_imm:per_dec_boolean(); gen_dec_imm_1({'ENUMERATED',{Base,Ext}}, _Constr, Aligned) -> asn1ct_imm:per_dec_enumerated(Base, Ext, Aligned); gen_dec_imm_1({'ENUMERATED',NamedNumberList}, _Constr, Aligned) -> asn1ct_imm:per_dec_enumerated(NamedNumberList, Aligned); gen_dec_imm_1('INTEGER', Constr, Aligned) -> asn1ct_imm:per_dec_integer(Constr, Aligned); gen_dec_imm_1({'INTEGER',NamedNumberList}, Constraint, Aligned) -> asn1ct_imm:per_dec_named_integer(Constraint, NamedNumberList, Aligned); gen_dec_imm_1('BMPString'=Type, Constraint, Aligned) -> gen_dec_k_m_string(Type, Constraint, Aligned); gen_dec_imm_1('NumericString'=Type, Constraint, Aligned) -> gen_dec_k_m_string(Type, Constraint, Aligned); gen_dec_imm_1('PrintableString'=Type, Constraint, Aligned) -> gen_dec_k_m_string(Type, Constraint, Aligned); gen_dec_imm_1('VisibleString'=Type, Constraint, Aligned) -> gen_dec_k_m_string(Type, Constraint, Aligned); gen_dec_imm_1('IA5String'=Type, Constraint, Aligned) -> gen_dec_k_m_string(Type, Constraint, Aligned); gen_dec_imm_1('UniversalString'=Type, Constraint, Aligned) -> gen_dec_k_m_string(Type, Constraint, Aligned); gen_dec_imm_1('UTCTime', Constraint, Aligned) -> gen_dec_k_m_string('VisibleString', Constraint, Aligned); gen_dec_imm_1('GeneralizedTime', Constraint, Aligned) -> gen_dec_k_m_string('VisibleString', Constraint, Aligned); gen_dec_imm_1('OCTET STRING', Constraint, Aligned) -> SzConstr = get_constraint(Constraint, 'SizeConstraint'), Imm = asn1ct_imm:per_dec_octet_string(SzConstr, Aligned), {convert,binary_to_list,Imm}; gen_dec_imm_1('TeletexString', _Constraint, Aligned) -> gen_dec_restricted_string(Aligned); gen_dec_imm_1('T61String', _Constraint, Aligned) -> gen_dec_restricted_string(Aligned); gen_dec_imm_1('VideotexString', _Constraint, Aligned) -> gen_dec_restricted_string(Aligned); gen_dec_imm_1('GraphicString', _Constraint, Aligned) -> gen_dec_restricted_string(Aligned); gen_dec_imm_1('GeneralString', _Constraint, Aligned) -> gen_dec_restricted_string(Aligned); gen_dec_imm_1('ObjectDescriptor', _Constraint, Aligned) -> gen_dec_restricted_string(Aligned); gen_dec_imm_1('OBJECT IDENTIFIER', _Constraint, Aligned) -> Dec = fun(V, Buf) -> emit(["{",{call,per_common,decode_oid,[V]},com, Buf,"}"]) end, {call,Dec,gen_dec_restricted_string(Aligned)}; gen_dec_imm_1('RELATIVE-OID', _Constraint, Aligned) -> Dec = fun(V, Buf) -> emit(["{",{call,per_common,decode_relative_oid,[V]},com, Buf,"}"]) end, {call,Dec,gen_dec_restricted_string(Aligned)}; gen_dec_imm_1('UTF8String', _Constraint, Aligned) -> asn1ct_imm:per_dec_restricted_string(Aligned); gen_dec_imm_1('REAL', _Constraint, Aligned) -> asn1ct_imm:per_dec_real(Aligned); gen_dec_imm_1(#'ObjectClassFieldType'{}=TypeName, _Constraint, Aligned) -> case asn1ct_gen:get_inner(TypeName) of {fixedtypevaluefield,_,#type{def=InnerType,constraint=C}} -> gen_dec_imm_1(InnerType, C, Aligned); #type{def=T,constraint=C} -> gen_dec_imm_1(T, C, Aligned) end. gen_dec_bit_string(F, Imm) -> D = fun(V, Buf) -> emit(["{",{call,per_common,F,[V]},com,Buf,"}"]) end, {call,D,Imm}. gen_dec_copy_bitstring(Imm) -> D = fun(V, Buf) -> emit(["{list_to_bitstring([",V,"]),",Buf,"}"]) end, {call,D,Imm}. gen_dec_k_m_string(Type, Constraint, Aligned) -> asn1ct_imm:per_dec_k_m_string(Type, Constraint, Aligned). gen_dec_restricted_string(Aligned) -> Imm = asn1ct_imm:per_dec_restricted_string(Aligned), {convert,binary_to_list,Imm}. gen_dec_prim(Erule, Type, BytesVar) -> Imm = gen_dec_imm(Erule, Type), asn1ct_imm:dec_code_gen(Imm, BytesVar). is_already_generated(Operation,Name) -> case get(class_default_type) of undefined -> put(class_default_type,[{Operation,Name}]), false; GeneratedList -> case lists:member({Operation,Name},GeneratedList) of true -> true; false -> put(class_default_type,[{Operation,Name}|GeneratedList]), false end end. get_class_fields(#classdef{typespec=ObjClass}) -> ObjClass#objectclass.fields; get_class_fields(#objectclass{fields=Fields}) -> Fields; get_class_fields(_) -> []. get_object_field(Name,ObjectFields) -> case lists:keysearch(Name,1,ObjectFields) of {value,Field} -> Field; false -> false end. %% For PER the ExtensionAdditionGroup notation has significance for the encoding and decoding %% the components within the ExtensionAdditionGroup is treated in a similar way as if they %% have been specified within a SEQUENCE, therefore we construct a fake sequence type here %% so that we can generate code for it extaddgroup2sequence(ExtList) -> extaddgroup2sequence(ExtList,0,[]). extaddgroup2sequence([{'ExtensionAdditionGroup',Number0}|T],ExtNum,Acc) -> Number = case Number0 of undefined -> 1; _ -> Number0 end, {ExtGroupComps,['ExtensionAdditionGroupEnd'|T2]} = lists:splitwith(fun(Elem) -> is_record(Elem,'ComponentType') end,T), extaddgroup2sequence(T2,ExtNum+1, [#'ComponentType'{ name=list_to_atom("ExtAddGroup"++ integer_to_list(ExtNum+1)), typespec=#type{def=#'SEQUENCE'{ extaddgroup=Number, components=ExtGroupComps}}, prop='OPTIONAL'}|Acc]); extaddgroup2sequence([C|T],ExtNum,Acc) -> extaddgroup2sequence(T,ExtNum,[C|Acc]); extaddgroup2sequence([],_,Acc) -> lists:reverse(Acc). imm_decode_open_type([#'Externaltypereference'{type=Tname}], Aligned) -> imm_dec_open_type_1(Tname, Aligned); imm_decode_open_type([#type{def=#'Externaltypereference'{type=Tname}}], Aligned) -> imm_dec_open_type_1(Tname, Aligned); imm_decode_open_type(_, Aligned) -> asn1ct_imm:per_dec_open_type(Aligned). imm_dec_open_type_1(Type, Aligned) -> D = fun(OpenType, Buf) -> asn1ct_name:new(tmpval), emit(["begin",nl, "{",{curr,tmpval},",_} = ", "dec_",Type,"(",OpenType,", mandatory),",nl, "{",{curr,tmpval},com,Buf,"}",nl, "end"]) end, {call,D,asn1ct_imm:per_dec_open_type(Aligned)}. eval_module(per) -> asn1ct_eval_per; eval_module(uper) -> asn1ct_eval_uper.