%%
%% %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).
-include("asn1_records.hrl").
-export([demit/1,
emit/1,
get_inner/1,type/1,def_to_tag/1,prim_bif/1,
list2name/1,
list2rname/1,
constructed_suffix/2,
unify_if_string/1,
gen_check_call/7,
get_constraint/2,
insert_once/2,
ct_gen_module/1,
index2suffix/1,
get_record_name_prefix/0]).
-export([pgen/5,
mk_var/1,
un_hyphen_var/1]).
-export([gen_encode_constructed/4,
gen_decode_constructed/4]).
%% pgen(Outfile, Erules, Module, TypeOrVal, Options)
%% Generate Erlang module (.erl) and (.hrl) file corresponding to an ASN.1 module
%% .hrl file is only generated if necessary
%% Erules = per | ber
%% Module = atom()
%% TypeOrVal = {TypeList,ValueList}
%% TypeList = ValueList = [atom()]
%% Options = [Options] from asn1ct:compile()
pgen(OutFile,Erules,Module,TypeOrVal,Options) ->
pgen_module(OutFile,Erules,Module,TypeOrVal,Options,true).
pgen_module(OutFile,Erules,Module,
TypeOrVal = {Types,_Values,_Ptypes,_Classes,_Objects,_ObjectSets},
Options,Indent) ->
N2nConvEnums = [CName|| {n2n,CName} <- get(encoding_options)],
case N2nConvEnums -- Types of
[] ->
ok;
UnmatchedTypes ->
exit({"Non existing ENUMERATION types used in n2n option",
UnmatchedTypes})
end,
put(outfile,OutFile),
HrlGenerated = pgen_hrl(Erules,Module,TypeOrVal,Options,Indent),
asn1ct_name:start(),
ErlFile = lists:concat([OutFile,".erl"]),
Fid = fopen(ErlFile),
put(gen_file_out,Fid),
asn1ct_func:start_link(),
gen_head(Erules,Module,HrlGenerated),
pgen_exports(Erules,Module,TypeOrVal),
pgen_dispatcher(Erules,Module,TypeOrVal),
pgen_info(),
pgen_typeorval(Erules,Module,N2nConvEnums,TypeOrVal),
pgen_partial_incomplete_decode(Erules),
% gen_vars(asn1_db:mod_to_vars(Module)),
% gen_tag_table(AllTypes),
emit([nl,
"%%%",nl,
"%%% Run-time functions.",nl,
"%%%",nl]),
asn1ct_func:generate(Fid),
file:close(Fid),
asn1ct:verbose("--~p--~n",[{generated,ErlFile}],Options).
pgen_typeorval(Erules,Module,N2nConvEnums,{Types,Values,_Ptypes,_Classes,Objects,ObjectSets}) ->
Rtmod = ct_gen_module(Erules),
pgen_types(Rtmod,Erules,N2nConvEnums,Module,Types),
pgen_values(Erules,Module,Values),
pgen_objects(Rtmod,Erules,Module,Objects),
pgen_objectsets(Rtmod,Erules,Module,ObjectSets),
case catch lists:member(der,get(encoding_options)) of
true ->
pgen_check_defaultval(Erules,Module);
_ -> ok
end,
pgen_partial_decode(Rtmod,Erules,Module).
pgen_values(_,_,[]) ->
true;
pgen_values(Erules,Module,[H|T]) ->
Valuedef = asn1_db:dbget(Module,H),
gen_value(Valuedef),
pgen_values(Erules,Module,T).
pgen_types(_, _, _, _, []) ->
true;
pgen_types(Rtmod,Erules,N2nConvEnums,Module,[H|T]) ->
asn1ct_name:clear(),
Typedef = asn1_db:dbget(Module,H),
Rtmod:gen_encode(Erules,Typedef),
asn1ct_name:clear(),
Rtmod:gen_decode(Erules,Typedef),
case lists:member(H,N2nConvEnums) of
true ->
pgen_n2nconversion(Erules,Typedef);
_ ->
true
end,
pgen_types(Rtmod,Erules,N2nConvEnums,Module,T).
%% Enumerated type with extension marker
pgen_n2nconversion(_Erules,#typedef{name=TypeName,typespec=#type{def={'ENUMERATED',{NN1,NN2}}}}) ->
NN = NN1 ++ NN2,
pgen_name2numfunc(TypeName,NN, extension_marker),
pgen_num2namefunc(TypeName,NN, extension_marker);
%% Without extension marker
pgen_n2nconversion(_Erules,#typedef{name=TypeName,typespec=#type{def={'ENUMERATED',NN}}}) ->
pgen_name2numfunc(TypeName,NN, no_extension_marker),
pgen_num2namefunc(TypeName,NN, no_extension_marker);
pgen_n2nconversion(_Erules,_) ->
true.
pgen_name2numfunc(_TypeName,[], _) ->
true;
pgen_name2numfunc(TypeName,[{Atom,Number}], extension_marker) ->
emit(["name2num_",TypeName,"(",{asis,Atom},") ->",Number,";",nl]),
emit(["name2num_",TypeName,"({asn1_enum, Num}) -> Num.",nl,nl]);
pgen_name2numfunc(TypeName,[{Atom,Number}], _) ->
emit(["name2num_",TypeName,"(",{asis,Atom},") ->",Number,".",nl,nl]);
pgen_name2numfunc(TypeName,[{Atom,Number}|NNRest], EM) ->
emit(["name2num_",TypeName,"(",{asis,Atom},") ->",Number,";",nl]),
pgen_name2numfunc(TypeName,NNRest, EM).
pgen_num2namefunc(_TypeName,[], _) ->
true;
pgen_num2namefunc(TypeName,[{Atom,Number}], extension_marker) ->
emit(["num2name_",TypeName,"(",Number,") ->",{asis,Atom},";",nl]),
emit(["num2name_",TypeName,"(ExtensionNum) -> {asn1_enum, ExtensionNum}.",nl,nl]);
pgen_num2namefunc(TypeName,[{Atom,Number}], _) ->
emit(["num2name_",TypeName,"(",Number,") ->",{asis,Atom},".",nl,nl]);
pgen_num2namefunc(TypeName,[{Atom,Number}|NNRest], EM) ->
emit(["num2name_",TypeName,"(",Number,") ->",{asis,Atom},";",nl]),
pgen_num2namefunc(TypeName,NNRest, EM).
pgen_objects(_,_,_,[]) ->
true;
pgen_objects(Rtmod,Erules,Module,[H|T]) ->
asn1ct_name:clear(),
Typedef = asn1_db:dbget(Module,H),
Rtmod:gen_obj_code(Erules,Module,Typedef),
pgen_objects(Rtmod,Erules,Module,T).
pgen_objectsets(_,_,_,[]) ->
true;
pgen_objectsets(Rtmod,Erules,Module,[H|T]) ->
asn1ct_name:clear(),
TypeDef = asn1_db:dbget(Module,H),
Rtmod:gen_objectset_code(Erules,TypeDef),
pgen_objectsets(Rtmod,Erules,Module,T).
pgen_check_defaultval(Erules,Module) ->
CheckObjects = asn1ct_table:to_list(check_functions),
case get(asndebug) of
true ->
FileName = lists:concat([Module,".table"]),
{ok,IoDevice} = file:open(FileName,[write]),
Fun =
fun(X)->
io:format(IoDevice,"~n~n************~n~n~p~n~n*****"
"********~n~n",[X])
end,
lists:foreach(Fun,CheckObjects),
file:close(IoDevice);
_ -> ok
end,
gen_check_defaultval(Erules,Module,CheckObjects).
pgen_partial_decode(Rtmod,Erule,Module) when Erule == ber ->
pgen_partial_inc_dec(Rtmod,Erule,Module),
pgen_partial_dec(Rtmod,Erule,Module);
pgen_partial_decode(_,_,_) ->
ok.
pgen_partial_inc_dec(Rtmod,Erules,Module) ->
% io:format("Start partial incomplete decode gen?~n"),
case asn1ct:get_gen_state_field(inc_type_pattern) of
undefined ->
% io:format("Partial incomplete decode gen not started: ~w~n",[asn1ct:get_gen_state_field(active)]),
ok;
% [] ->
% ok;
ConfList ->
PatternLists=lists:map(fun({_,P}) -> P end,ConfList),
pgen_partial_inc_dec1(Rtmod,Erules,Module,PatternLists),
gen_partial_inc_dec_refed_funcs(Rtmod,Erules)
end.
%% pgen_partial_inc_dec1 generates a function of the toptype in each
%% of the partial incomplete decoded types.
pgen_partial_inc_dec1(Rtmod,Erules,Module,[P|Ps]) ->
TopTypeName = asn1ct:partial_inc_dec_toptype(P),
TypeDef=asn1_db:dbget(Module,TopTypeName),
asn1ct_name:clear(),
asn1ct:update_gen_state(namelist,P),
asn1ct:update_gen_state(active,true),
asn1ct:update_gen_state(prefix,"dec-inc-"),
case asn1ct:maybe_saved_sindex(TopTypeName,P) of
I when is_integer(I),I > 0 ->
% io:format("Index:~p~n",[I]),
asn1ct:set_current_sindex(I);
_I ->
asn1ct:set_current_sindex(0),
% io:format("Index=~p~n",[_I]),
ok
end,
Rtmod:gen_decode(Erules,TypeDef),
gen_dec_part_inner_constr(Rtmod,Erules,TypeDef,[TopTypeName]),
pgen_partial_inc_dec1(Rtmod,Erules,Module,Ps);
pgen_partial_inc_dec1(_,_,_,[]) ->
ok.
gen_partial_inc_dec_refed_funcs(Rtmod,Erule) when Erule == ber ->
case asn1ct:next_refed_func() of
[] ->
ok;
{#'Externaltypereference'{module=M,type=Name},Sindex,Pattern} ->
TypeDef = asn1_db:dbget(M,Name),
asn1ct:update_gen_state(namelist,Pattern),
asn1ct:set_current_sindex(Sindex),
Rtmod:gen_inc_decode(Erule,TypeDef),
gen_dec_part_inner_constr(Rtmod,Erule,TypeDef,[Name]),
gen_partial_inc_dec_refed_funcs(Rtmod,Erule);
{Name,Sindex,Pattern,Type} ->
TypeDef=#typedef{name=asn1ct_gen:list2name(Name),typespec=Type},
asn1ct:update_gen_state(namelist,Pattern),
asn1ct:set_current_sindex(Sindex),
Rtmod:gen_inc_decode(Erule,TypeDef),
gen_dec_part_inner_constr(Rtmod,Erule,TypeDef,Name),
gen_partial_inc_dec_refed_funcs(Rtmod,Erule)
end;
gen_partial_inc_dec_refed_funcs(_,_) ->
ok.
pgen_partial_dec(_Rtmod,Erules,_Module) ->
Type_pattern = asn1ct:get_gen_state_field(type_pattern),
% io:format("Type_pattern: ~w~n",[Type_pattern]),
%% Get the typedef of the top type and follow into the choosen components until the last type/component.
pgen_partial_types(Erules,Type_pattern),
ok.
pgen_partial_types(Erules,Type_pattern) ->
% until this functionality works on all back-ends
Options = get(encoding_options),
case lists:member(asn1config,Options) of
true ->
pgen_partial_types1(Erules,Type_pattern);
_ -> ok
end.
pgen_partial_types1(Erules,[{FuncName,[TopType|RestTypes]}|Rest]) ->
% emit([FuncName,"(Bytes) ->",nl]),
CurrMod = get(currmod),
TypeDef = asn1_db:dbget(CurrMod,TopType),
traverse_type_structure(Erules,TypeDef,RestTypes,FuncName,
TypeDef#typedef.name),
pgen_partial_types1(Erules,Rest);
pgen_partial_types1(_,[]) ->
ok;
pgen_partial_types1(_,undefined) ->
ok.
%% traverse_type_structure searches the structure of TypeDef for next
%% type/component in TypeList until the last one. For the last type in
%% TypeList a decode function will be generated.
traverse_type_structure(Erules,Type,[],FuncName,TopTypeName) ->
%% this is the selected type
Ctmod = ct_gen_module(Erules),
TypeDef =
case Type of
#type{} ->
#typedef{name=TopTypeName,typespec=Type};
#typedef{} -> Type
end,
Ctmod:gen_decode_selected(Erules,TypeDef,FuncName); % what if Type is #type{}
traverse_type_structure(Erules,#type{def=Def},[[N]],FuncName,TopTypeName)
when is_integer(N) -> % this case a decode of one of the elements in
% the SEQUENCE OF is required.
InnerType = asn1ct_gen:get_inner(Def),
case InnerType of
'SEQUENCE OF' ->
{_,Type} = Def,
traverse_type_structure(Erules,Type,[],FuncName,TopTypeName);
WrongType ->
exit({error,{configuration_file_error,[N],"only for SEQUENCE OF components",WrongType}})
end;
traverse_type_structure(Erules,Type,[[N]|Ts],FuncName,TopTypeName)
when is_integer(N) ->
traverse_type_structure(Erules,Type,Ts,FuncName,TopTypeName);
traverse_type_structure(Erules,#type{def=Def},[T|Ts],FuncName,TopTypeName) ->
InnerType = asn1ct_gen:get_inner(Def),
case InnerType of
'SET' ->
#'SET'{components=Components} = Def,
C = get_component(T,Components),
traverse_type_structure(Erules,C#'ComponentType'.typespec,Ts,
FuncName,[T|TopTypeName]);
'SEQUENCE' ->
#'SEQUENCE'{components=Components} = Def,
C = get_component(T,Components),
traverse_type_structure(Erules,C#'ComponentType'.typespec,Ts,
FuncName,[T|TopTypeName]);
'CHOICE' ->
{_,Components} = Def,
C = get_component(T,Components),
traverse_type_structure(Erules,C#'ComponentType'.typespec,Ts,
FuncName,[T|TopTypeName]);
'SEQUENCE OF' ->
{_,Type} = Def,
traverse_SO_type_structure(Erules,Type,[T|Ts],FuncName,
TopTypeName);
'SET OF' ->
{_,Type} = Def,
traverse_SO_type_structure(Erules,Type,[T|Ts],FuncName,
TopTypeName);
#'Externaltypereference'{module=M,type=TName} ->
TypeDef = asn1_db:dbget(M,TName),
traverse_type_structure(Erules,TypeDef,[T|Ts],FuncName,
[TypeDef#typedef.name]);
_ ->
traverse_type_structure(Erules,Def,Ts,FuncName,[T|TopTypeName])
end;
traverse_type_structure(Erules,#typedef{typespec=Def},[T|Ts],FuncName,
TopTypeName) ->
InnerType = asn1ct_gen:get_inner(Def#type.def),
case InnerType of
'SET' ->
#'SET'{components=Components} = Def#type.def,
C = get_component(T,Components),
traverse_type_structure(Erules,C#'ComponentType'.typespec,Ts,
FuncName,[T|TopTypeName]);
'SEQUENCE' ->
#'SEQUENCE'{components=Components} = Def#type.def,
C = get_component(T,Components),
traverse_type_structure(Erules,C#'ComponentType'.typespec,Ts,
FuncName,[T|TopTypeName]);
'CHOICE' ->
{_,Components} = Def#type.def,
C = get_component(T,Components),
traverse_type_structure(Erules,C#'ComponentType'.typespec,Ts,
FuncName,[T|TopTypeName]);
'SEQUENCE OF' ->
{_,Type} = Def#type.def,
traverse_SO_type_structure(Erules,Type,[T|Ts],FuncName,
TopTypeName);
'SET OF' ->
{_,Type} = Def#type.def,
traverse_SO_type_structure(Erules,Type,[T|Ts],FuncName,
TopTypeName);
#'Externaltypereference'{module=M,type=TName} ->
TypeDef = asn1_db:dbget(M,TName),
traverse_type_structure(Erules,TypeDef,[T|Ts],FuncName,
[TypeDef#typedef.name]);
_ -> %this may be a referenced type that shall be traversed or
%the selected type
traverse_type_structure(Erules,Def,Ts,FuncName,[T|TopTypeName])
end.
traverse_SO_type_structure(Erules,Type,[N|Rest],FuncName,TopTypeName)
when is_integer(N) ->
traverse_type_structure(Erules,Type,Rest,FuncName,TopTypeName);
traverse_SO_type_structure(Erules,Type,TypeList,FuncName,TopTypeName) ->
traverse_type_structure(Erules,Type,TypeList,FuncName,TopTypeName).
get_component(Name,{C1,C2}) when is_list(C1),is_list(C2) ->
get_component(Name,C1++C2);
get_component(Name,[C=#'ComponentType'{name=Name}|_Cs]) ->
C;
get_component(Name,[_C|Cs]) ->
get_component(Name,Cs);
get_component(Name,_) ->
throw({error,{asn1,{internal_error,Name}}}).
%% generate code for all inner types that are called from the top type
%% of the partial incomplete decode and are defined within the top
%% type.Constructed subtypes deeper in the structure will be generated
%% in turn after all top types have been generated.
gen_dec_part_inner_constr(Rtmod,Erules,TypeDef,TypeName) ->
Def = TypeDef#typedef.typespec,
InnerType = asn1ct_gen:get_inner(Def#type.def),
case InnerType of
'SET' ->
#'SET'{components=Components} = Def#type.def,
gen_dec_part_inner_types(Rtmod,Erules,Components,TypeName);
%% Continue generate the inner of each component
'SEQUENCE' ->
#'SEQUENCE'{components=Components} = Def#type.def,
gen_dec_part_inner_types(Rtmod,Erules,Components,TypeName);
'CHOICE' ->
{_,Components} = Def#type.def,
gen_dec_part_inner_types(Rtmod,Erules,Components,TypeName);
'SEQUENCE OF' ->
%% this and next case must be the last component in the
%% partial decode chain here. Not likely that this occur.
{_,Type} = Def#type.def,
NameSuffix = constructed_suffix(InnerType,Type#type.def),
asn1ct_name:clear(),
Rtmod:gen_decode(Erules,[NameSuffix|TypeName],Type);
%% gen_types(Erules,[NameSuffix|Typename],Type);
'SET OF' ->
{_,Type} = Def#type.def,
NameSuffix = constructed_suffix(InnerType,Type#type.def),
asn1ct_name:clear(),
Rtmod:gen_decode(Erules,[NameSuffix|TypeName],Type);
_ ->
ok
end.
gen_dec_part_inner_types(Rtmod,Erules,[ComponentType|Rest],TypeName) ->
asn1ct_name:clear(),
Rtmod:gen_decode(Erules,TypeName,ComponentType),
gen_dec_part_inner_types(Rtmod,Erules,Rest,TypeName);
gen_dec_part_inner_types(Rtmod,Erules,{Comps1,Comps2},TypeName)
when is_list(Comps1),is_list(Comps2) ->
gen_dec_part_inner_types(Rtmod,Erules,Comps1 ++ Comps2,TypeName);
gen_dec_part_inner_types(_,_,[],_) ->
ok.
pgen_partial_incomplete_decode(Erule) ->
case asn1ct:get_gen_state_field(active) of
true ->
pgen_partial_incomplete_decode1(Erule),
asn1ct:reset_gen_state();
_ ->
ok
end.
pgen_partial_incomplete_decode1(ber) ->
case asn1ct:read_config_data(partial_incomplete_decode) of
undefined ->
ok;
Data ->
lists:foreach(fun emit_partial_incomplete_decode/1,Data)
end,
GeneratedFs= asn1ct:get_gen_state_field(gen_refed_funcs),
% io:format("GeneratedFs :~n~p~n",[GeneratedFs]),
gen_part_decode_funcs(GeneratedFs,0);
pgen_partial_incomplete_decode1(_) -> ok.
emit_partial_incomplete_decode({FuncName,TopType,Pattern}) ->
TypePattern = asn1ct:get_gen_state_field(inc_type_pattern),
TPattern =
case lists:keysearch(FuncName,1,TypePattern) of
{value,{_,TP}} -> TP;
_ -> exit({error,{asn1_internal_error,exclusive_decode}})
end,
TopTypeName =
case asn1ct:maybe_saved_sindex(TopType,TPattern) of
I when is_integer(I),I>0 ->
lists:concat([TopType,"_",I]);
_ ->
atom_to_list(TopType)
end,
emit([{asis,FuncName},"(Bytes) ->",nl,
" decode_partial_incomplete('",TopTypeName,"',Bytes,",{asis,Pattern},").",nl]);
emit_partial_incomplete_decode(D) ->
throw({error,{asn1,{"bad data in asn1config file",D}}}).
gen_part_decode_funcs([Data={Name,_,_,Type}|GeneratedFs],N) ->
InnerType =
case Type#type.def of
#'ObjectClassFieldType'{type=OCFTType} ->
OCFTType;
_ ->
get_inner(Type#type.def)
end,
WhatKind = type(InnerType),
TypeName=list2name(Name),
if
N > 0 -> emit([";",nl]);
true -> ok
end,
emit(["decode_inc_disp('",TypeName,"',Data) ->",nl]),
gen_part_decode_funcs(WhatKind,TypeName,Data),
gen_part_decode_funcs(GeneratedFs,N+1);
gen_part_decode_funcs([_H|T],N) ->
gen_part_decode_funcs(T,N);
gen_part_decode_funcs([],N) ->
if
N > 0 ->
emit([".",nl]);
true ->
ok
end.
gen_part_decode_funcs(#'Externaltypereference'{module=M,type=T},
_TypeName,Data) ->
#typedef{typespec=TS} = asn1_db:dbget(M,T),
InnerType =
case TS#type.def of
#'ObjectClassFieldType'{type=OCFTType} ->
OCFTType;
_ ->
get_inner(TS#type.def)
end,
WhatKind = type(InnerType),
gen_part_decode_funcs(WhatKind,[T],Data);
gen_part_decode_funcs({constructed,bif},TypeName,
{_Name,parts,Tag,_Type}) ->
emit([" case Data of",nl,
" L when is_list(L) ->",nl,
" 'dec_",TypeName,"'(lists:map(fun(X) -> element(1, ",
{call,ber,ber_decode_erlang,["X"]},") end, L),",{asis,Tag},");",nl,
" _ ->",nl,
" [Res] = 'dec_",TypeName,"'([Data],",{asis,Tag},"),",nl,
" Res",nl,
" end"]);
gen_part_decode_funcs(WhatKind,_TypeName,{_Name,parts,_Tag,_Type}) ->
throw({error,{asn1,{"only SEQUENCE OF/SET OF may have the partial incomplete directive 'parts'.",WhatKind}}});
gen_part_decode_funcs({constructed,bif},TypeName,
{_Name,undecoded,Tag,_Type}) ->
emit([" 'dec_",TypeName,"'(Data,",{asis,Tag},")"]);
gen_part_decode_funcs({primitive,bif},_TypeName,
{_Name,undecoded,Tag,Type}) ->
% Argument no 6 is 0, i.e. bit 6 for primitive encoding.
asn1ct_gen_ber_bin_v2:gen_dec_prim(ber_bin_v2,Type,"Data",Tag,[],0,", mandatory, ");
gen_part_decode_funcs(WhatKind,_TypeName,{_,Directive,_,_}) ->
throw({error,{asn1,{"Not implemented yet",WhatKind," partial incomplete directive:",Directive}}}).
gen_types(Erules,Tname,{RootL1,ExtList,RootL2})
when is_list(RootL1), is_list(RootL2) ->
gen_types(Erules,Tname,RootL1),
Rtmod = ct_gen_module(Erules),
gen_types(Erules,Tname,Rtmod:extaddgroup2sequence(ExtList)),
gen_types(Erules,Tname,RootL2);
gen_types(Erules,Tname,{RootList,ExtList}) when is_list(RootList) ->
gen_types(Erules,Tname,RootList),
Rtmod = ct_gen_module(Erules),
gen_types(Erules,Tname,Rtmod:extaddgroup2sequence(ExtList));
gen_types(Erules,Tname,[{'EXTENSIONMARK',_,_}|Rest]) ->
gen_types(Erules,Tname,Rest);
gen_types(Erules,Tname,[ComponentType|Rest]) ->
Rtmod = ct_gen_module(Erules),
asn1ct_name:clear(),
Rtmod:gen_encode(Erules,Tname,ComponentType),
asn1ct_name:clear(),
Rtmod:gen_decode(Erules,Tname,ComponentType),
gen_types(Erules,Tname,Rest);
gen_types(_,_,[]) ->
true;
gen_types(Erules,Tname,Type) when is_record(Type,type) ->
Rtmod = ct_gen_module(Erules),
asn1ct_name:clear(),
Rtmod:gen_encode(Erules,Tname,Type),
asn1ct_name:clear(),
Rtmod:gen_decode(Erules,Tname,Type).
gen_check_defaultval(Erules,Module,[{Name,Type}|Rest]) ->
gen_check_func(Name,Type),
gen_check_defaultval(Erules,Module,Rest);
gen_check_defaultval(_,_,[]) ->
ok.
gen_check_func(Name,FType = #type{def=Def}) ->
EncName = ensure_atom(Name),
emit({{asis,EncName},"(_V,asn1_DEFAULT) ->",nl," true;",nl}),
emit({{asis,EncName},"(V,V) ->",nl," true;",nl}),
emit({{asis,EncName},"(V,{_,V}) ->",nl," true;",nl}),
case Def of
{'SEQUENCE OF',Type} ->
gen_check_sof(Name,'SEQOF',Type);
{'SET OF',Type} ->
gen_check_sof(Name,'SETOF',Type);
#'SEQUENCE'{components=Components} ->
gen_check_sequence(Name,Components);
#'SET'{components=Components} ->
gen_check_sequence(Name,Components);
{'CHOICE',Components} ->
gen_check_choice(Name,Components);
#'Externaltypereference'{type=T} ->
emit({{asis,EncName},"(DefaultValue,Value) ->",nl}),
emit({" '",list2name([T,check]),"'(DefaultValue,Value).",nl});
MaybePrim ->
InnerType = get_inner(MaybePrim),
case type(InnerType) of
{primitive,bif} ->
emit({{asis,EncName},"(DefaultValue,Value) ->",nl," "}),
gen_prim_check_call(get_inner(InnerType),"DefaultValue","Value",
FType),
emit({".",nl,nl});
_ ->
throw({asn1_error,{unknown,type,MaybePrim}})
end
end.
gen_check_sof(Name,SOF,Type) ->
EncName = ensure_atom(Name),
NewName = ensure_atom(list2name([sorted,Name])),
emit({{asis,EncName},"(V1,V2) ->",nl}),
emit({" ",{asis,NewName},"(lists:sort(V1),lists:sort(V2)).",nl,nl}),
emit({{asis,NewName},"([],[]) ->",nl," true;",nl}),
emit({{asis,NewName},"([DV|DVs],[V|Vs]) ->",nl," "}),
InnerType = get_inner(Type#type.def),
case type(InnerType) of
{primitive,bif} ->
gen_prim_check_call(get_inner(InnerType),"DV","V",Type),
emit({",",nl});
{constructed,bif} ->
emit([{asis,ensure_atom(list2name([SOF,Name]))},"(DV, V),",nl]);
#'Externaltypereference'{type=T} ->
emit([{asis,ensure_atom(list2name([T,check]))},"(DV,V),",nl]);
'ASN1_OPEN_TYPE' ->
emit(["DV = V,",nl]);
_ ->
emit(["DV = V,",nl])
end,
emit({" ",{asis,NewName},"(DVs,Vs).",nl,nl}).
gen_check_sequence(Name, []) ->
emit([{asis,ensure_atom(Name)},"(_,_) ->",nl,
" throw(badval).",nl,nl]);
gen_check_sequence(Name,Components) ->
emit([{asis,ensure_atom(Name)},"(DefaultValue,Value) ->",nl]),
gen_check_sequence(Name,Components,1).
gen_check_sequence(Name,[#'ComponentType'{name=N,typespec=Type}|Cs],Num) ->
InnerType = get_inner(Type#type.def),
NthDefV = ["element(",Num+1,",DefaultValue)"],
NthV = ["element(",Num+1,",Value)"],
gen_check_func_call(Name,Type,InnerType,NthDefV,NthV,N),
case Cs of
[] ->
emit({".",nl,nl});
_ ->
emit({",",nl}),
gen_check_sequence(Name,Cs,Num+1)
end.
gen_check_choice(Name,CList=[#'ComponentType'{}|_Cs]) ->
emit([{asis,ensure_atom(Name)},"({Id,DefaultValue},{Id,Value}) ->",nl]),
emit([" case Id of",nl]),
gen_check_choice_components(Name,CList,1).
gen_check_choice_components(_,[],_)->
ok;
gen_check_choice_components(Name,[#'ComponentType'{name=N,typespec=Type}|
Cs],Num) ->
Ind6 = " ",
InnerType = get_inner(Type#type.def),
emit({Ind6,"'",N,"' ->",nl,Ind6}),
gen_check_func_call(Name,Type,InnerType,{var,"defaultValue"},
{var,"value"},N),
case Cs of
[] ->
emit({nl," end.",nl,nl});
_ ->
emit({";",nl}),
gen_check_choice_components(Name,Cs,Num+1)
end.
gen_check_func_call(Name,Type,InnerType,DefVal,Val,N) ->
case type(InnerType) of
{primitive,bif} ->
emit(" "),
gen_prim_check_call(get_inner(InnerType),DefVal,Val,Type);
#'Externaltypereference'{type=T} ->
emit({" ",{asis,ensure_atom(list2name([T,check]))},"(",DefVal,",",Val,")"});
'ASN1_OPEN_TYPE' ->
emit([" if",nl,
" ",DefVal," == ",Val," -> true;",nl,
" true -> throw({error,{asn1_open_type}})",nl,
" end",nl]);
{constructed,bif} ->
emit([" ",{asis,ensure_atom(list2name([N,Name]))},"(",DefVal,",",Val,")"]);
_ ->
emit([" if",nl,
" ",DefVal," == ",Val," -> true;",nl,
" true -> throw({error,{asn1_open_type}})",nl,
" end",nl])
end.
%% VARIOUS GENERATOR STUFF
%% *************************************************
%%**************************************************
mk_var(X) when is_atom(X) ->
list_to_atom(mk_var(atom_to_list(X)));
mk_var([H|T]) ->
[H-32|T].
%% Since hyphens are allowed in ASN.1 names, it may occur in a
%% variable to. Turn a hyphen into a under-score sign.
un_hyphen_var(X) when is_atom(X) ->
list_to_atom(un_hyphen_var(atom_to_list(X)));
un_hyphen_var([45|T]) ->
[95|un_hyphen_var(T)];
un_hyphen_var([H|T]) ->
[H|un_hyphen_var(T)];
un_hyphen_var([]) ->
[].
%% Generate value functions ***************
%% ****************************************
%% Generates a function 'V'/0 for each Value V defined in the ASN.1 module
%% the function returns the value in an Erlang representation which can be
%% used as input to the runtime encode functions
gen_value(Value) when is_record(Value,valuedef) ->
%% io:format(" ~w ",[Value#valuedef.name]),
emit({"'",Value#valuedef.name,"'() ->",nl}),
V = Value#valuedef.value,
emit([{asis,V},".",nl,nl]).
gen_encode_constructed(Erules,Typename,InnerType,D) when is_record(D,type) ->
Rtmod = ct_constructed_module(Erules),
case InnerType of
'SET' ->
Rtmod:gen_encode_set(Erules,Typename,D),
#'SET'{components=Components} = D#type.def,
gen_types(Erules,Typename,Components);
'SEQUENCE' ->
Rtmod:gen_encode_sequence(Erules,Typename,D),
#'SEQUENCE'{components=Components} = D#type.def,
gen_types(Erules,Typename,Components);
'CHOICE' ->
Rtmod:gen_encode_choice(Erules,Typename,D),
{_,Components} = D#type.def,
gen_types(Erules,Typename,Components);
'SEQUENCE OF' ->
Rtmod:gen_encode_sof(Erules,Typename,InnerType,D),
{_,Type} = D#type.def,
NameSuffix = asn1ct_gen:constructed_suffix(InnerType,Type#type.def),
gen_types(Erules,[NameSuffix|Typename],Type);
'SET OF' ->
Rtmod:gen_encode_sof(Erules,Typename,InnerType,D),
{_,Type} = D#type.def,
NameSuffix = asn1ct_gen:constructed_suffix(InnerType,Type#type.def),
gen_types(Erules,[NameSuffix|Typename],Type);
_ ->
exit({nyi,InnerType})
end;
gen_encode_constructed(Erules,Typename,InnerType,D)
when is_record(D,typedef) ->
gen_encode_constructed(Erules,Typename,InnerType,D#typedef.typespec).
gen_decode_constructed(Erules,Typename,InnerType,D) when is_record(D,type) ->
Rtmod = ct_constructed_module(Erules),
asn1ct:step_in_constructed(), %% updates namelist for exclusive decode
case InnerType of
'SET' ->
Rtmod:gen_decode_set(Erules,Typename,D);
'SEQUENCE' ->
Rtmod:gen_decode_sequence(Erules,Typename,D);
'CHOICE' ->
Rtmod:gen_decode_choice(Erules,Typename,D);
'SEQUENCE OF' ->
Rtmod:gen_decode_sof(Erules,Typename,InnerType,D);
'SET OF' ->
Rtmod:gen_decode_sof(Erules,Typename,InnerType,D);
_ ->
exit({nyi,InnerType})
end;
gen_decode_constructed(Erules,Typename,InnerType,D) when is_record(D,typedef) ->
gen_decode_constructed(Erules,Typename,InnerType,D#typedef.typespec).
pgen_exports(Erules,_Module,{Types,Values,_,_,Objects,ObjectSets}) ->
emit(["-export([encoding_rule/0,bit_string_format/0]).",nl]),
case Types of
[] -> ok;
_ ->
emit({"-export([",nl}),
case Erules of
ber ->
gen_exports1(Types,"enc_",2);
_ ->
gen_exports1(Types,"enc_",1)
end,
emit({"-export([",nl}),
gen_exports1(Types,"dec_",2)
end,
case [X || {n2n,X} <- get(encoding_options)] of
[] -> ok;
A2nNames ->
emit({"-export([",nl}),
gen_exports1(A2nNames,"name2num_",1),
emit({"-export([",nl}),
gen_exports1(A2nNames,"num2name_",1)
end,
case Values of
[] -> ok;
_ ->
emit({"-export([",nl}),
gen_exports1(Values,"",0)
end,
case Objects of
[] -> ok;
_ ->
case erule(Erules) of
per ->
emit({"-export([",nl}),
gen_exports1(Objects,"enc_",3),
emit({"-export([",nl}),
gen_exports1(Objects,"dec_",4);
ber ->
emit({"-export([",nl}),
gen_exports1(Objects,"enc_",3),
emit({"-export([",nl}),
gen_exports1(Objects,"dec_",3)
end
end,
case ObjectSets of
[] -> ok;
_ ->
emit({"-export([",nl}),
gen_exports1(ObjectSets,"getenc_",2),
emit({"-export([",nl}),
gen_exports1(ObjectSets,"getdec_",2)
end,
emit({"-export([info/0]).",nl}),
gen_partial_inc_decode_exports(),
gen_selected_decode_exports(),
emit({nl,nl}).
gen_exports1([F1,F2|T],Prefix,Arity) ->
emit({"'",Prefix,F1,"'/",Arity,com,nl}),
gen_exports1([F2|T],Prefix,Arity);
gen_exports1([Flast|_T],Prefix,Arity) ->
emit({"'",Prefix,Flast,"'/",Arity,nl,"]).",nl,nl}).
gen_partial_inc_decode_exports() ->
case {asn1ct:read_config_data(partial_incomplete_decode),
asn1ct:get_gen_state_field(inc_type_pattern)} of
{undefined,_} ->
ok;
{_,undefined} ->
ok;
{Data,_} ->
gen_partial_inc_decode_exports(Data),
emit(["-export([decode_part/2]).",nl])
end.
gen_partial_inc_decode_exports([]) ->
ok;
gen_partial_inc_decode_exports([{Name,_,_}|Rest]) ->
emit(["-export([",Name,"/1"]),
gen_partial_inc_decode_exports1(Rest);
gen_partial_inc_decode_exports([_|Rest]) ->
gen_partial_inc_decode_exports(Rest).
gen_partial_inc_decode_exports1([]) ->
emit(["]).",nl]);
gen_partial_inc_decode_exports1([{Name,_,_}|Rest]) ->
emit([", ",Name,"/1"]),
gen_partial_inc_decode_exports1(Rest);
gen_partial_inc_decode_exports1([_|Rest]) ->
gen_partial_inc_decode_exports1(Rest).
gen_selected_decode_exports() ->
case asn1ct:get_gen_state_field(type_pattern) of
undefined ->
ok;
L ->
gen_selected_decode_exports(L)
end.
gen_selected_decode_exports([]) ->
ok;
gen_selected_decode_exports([{FuncName,_}|Rest]) ->
emit(["-export([",FuncName,"/1"]),
gen_selected_decode_exports1(Rest).
gen_selected_decode_exports1([]) ->
emit(["]).",nl,nl]);
gen_selected_decode_exports1([{FuncName,_}|Rest]) ->
emit([",",nl," ",FuncName,"/1"]),
gen_selected_decode_exports1(Rest).
pgen_dispatcher(Erules,_Module,{[],_Values,_,_,_Objects,_ObjectSets}) ->
gen_info_functions(Erules);
pgen_dispatcher(Erules,_Module,{Types,_Values,_,_,_Objects,_ObjectSets}) ->
emit(["-export([encode/2,decode/2]).",nl,nl]),
gen_info_functions(Erules),
NoFinalPadding = lists:member(no_final_padding,get(encoding_options)),
{Call,BytesAsBinary} =
case Erules of
per ->
asn1ct_func:need({Erules,complete,1}),
{["complete(encode_disp(Type, Data))"],"Bytes"};
ber ->
{"encode_disp(Type,Data)","iolist_to_binary(Bytes)"};
uper when NoFinalPadding == true ->
asn1ct_func:need({Erules,complete_NFP,1}),
{"complete_NFP(encode_disp(Type, Data))","Bytes"};
uper ->
asn1ct_func:need({Erules,complete,1}),
{["complete(encode_disp(Type, Data))"],"Bytes"}
end,
emit(["encode(Type,Data) ->",nl,
"case catch ",Call," of",nl,
" {'EXIT',{error,Reason}} ->",nl,
" {error,Reason};",nl,
" {'EXIT',Reason} ->",nl,
" {error,{asn1,Reason}};",nl,
" {Bytes,_Len} ->",nl,
" {ok,",BytesAsBinary,"};",nl,
" Bytes ->",nl,
" {ok,",BytesAsBinary,"}",nl,
"end.",nl,nl]),
Return_rest = lists:member(undec_rest,get(encoding_options)),
Data = case {Erules,Return_rest} of
{ber,true} -> "Data0";
_ -> "Data"
end,
emit(["decode(Type,",Data,") ->",nl]),
DecAnonymous =
case {Erules,Return_rest} of
{ber,false} ->
asn1ct_func:need({ber,ber_decode_nif,1}),
"element(1, ber_decode_nif(Data))";
{ber,true} ->
asn1ct_func:need({ber,ber_decode_nif,1}),
emit(["{Data,Rest} = ber_decode_nif(Data0),",nl]),
"Data";
_ ->
"Data"
end,
DecWrap = case Erules of
ber ->
DecAnonymous;
_ -> "Data"
end,
emit(["case catch decode_disp(Type,",DecWrap,") of",nl,
" {'EXIT',{error,Reason}} ->",nl,
" {error,Reason};",nl,
" {'EXIT',Reason} ->",nl,
" {error,{asn1,Reason}};",nl]),
case {Erules,Return_rest} of
{ber,false} ->
emit([" Result ->",nl,
" {ok,Result}",nl]);
{ber,true} ->
emit([" Result ->",nl,
" {ok,Result,Rest}",nl]);
{_,false} ->
emit([" {X,_Rest} ->",nl,
" {ok,X};",nl,
" {X,_Rest,_Len} ->",nl,
" {ok,X}",nl]);
{per,true} ->
emit([" {X,{_,Rest}} ->",nl,
" {ok,X,Rest};",nl,
" {X,{_,Rest},_Len} ->",nl,
" {ok,X,Rest};",nl,
" {X,Rest} ->",nl,
" {ok,X,Rest};",nl,
" {X,Rest,_Len} ->",nl,
" {ok,X,Rest}",nl]);
{uper,true} ->
emit([" {X,{_,Rest}} ->",nl,
" {ok,X,Rest};",nl,
" {X,{_,Rest},_Len} ->",nl,
" {ok,X,Rest};",nl,
" {X,Rest} ->",nl,
" {ok,X,Rest};",nl,
" {X,Rest,_Len} ->",nl,
" {ok,X,Rest}",nl])
end,
emit(["end.",nl,nl]),
gen_decode_partial_incomplete(Erules),
case Erules of
ber ->
gen_dispatcher(Types,"encode_disp","enc_",""),
gen_dispatcher(Types,"decode_disp","dec_",""),
gen_partial_inc_dispatcher();
_PerOrPer_bin ->
gen_dispatcher(Types,"encode_disp","enc_",""),
gen_dispatcher(Types,"decode_disp","dec_",",mandatory")
end,
emit([nl]),
emit({nl,nl}).
gen_info_functions(Erules) ->
emit(["encoding_rule() -> ",
{asis,Erules},".",nl,nl,
"bit_string_format() -> ",
{asis,asn1ct:get_bit_string_format()},".",nl,nl]).
gen_decode_partial_incomplete(ber) ->
case {asn1ct:read_config_data(partial_incomplete_decode),
asn1ct:get_gen_state_field(inc_type_pattern)} of
{undefined,_} ->
ok;
{_,undefined} ->
ok;
_ ->
EmitCaseClauses =
fun() ->
emit([" {'EXIT',{error,Reason}} ->",nl,
" {error,Reason};",nl,
" {'EXIT',Reason} ->",nl,
" {error,{asn1,Reason}};",nl,
" Result ->",nl,
" {ok,Result}",nl,
" end"])
end,
emit(["decode_partial_incomplete(Type,Data0,",
"Pattern) ->",nl]),
emit([" {Data,_RestBin} =",nl,
" ",{call,ber,decode_primitive_incomplete,
["Pattern","Data0"]},com,nl,
" case catch decode_partial_inc_disp(Type,",
"Data) of",nl]),
EmitCaseClauses(),
emit([".",nl,nl]),
emit(["decode_part(Type, Data0) "
"when is_binary(Data0) ->",nl]),
emit([" case catch decode_inc_disp(Type,element(1, ",
{call,ber,ber_decode_nif,["Data0"]},")) of",nl]),
EmitCaseClauses(),
emit([";",nl]),
emit(["decode_part(Type, Data0) ->",nl]),
emit([" case catch decode_inc_disp(Type, Data0) of",nl]),
EmitCaseClauses(),
emit([".",nl,nl])
end;
gen_decode_partial_incomplete(_Erule) ->
ok.
gen_partial_inc_dispatcher() ->
case {asn1ct:read_config_data(partial_incomplete_decode),
asn1ct:get_gen_state_field(inc_type_pattern)} of
{undefined,_} ->
ok;
{_,undefined} ->
ok;
{Data1,Data2} ->
% io:format("partial_incomplete_decode: ~p~ninc_type_pattern: ~p~n",[Data,Data2]),
gen_partial_inc_dispatcher(Data1,Data2)
end.
gen_partial_inc_dispatcher([{FuncName,TopType,_Pattern}|Rest],TypePattern) ->
TPattern =
case lists:keysearch(FuncName,1,TypePattern) of
{value,{_,TP}} -> TP;
_ -> exit({error,{asn1_internal_error,exclusive_decode}})
end,
FuncName2=asn1ct:maybe_rename_function(inc_disp,TopType,TPattern),
TopTypeName =
case asn1ct:maybe_saved_sindex(TopType,TPattern) of
I when is_integer(I),I>0 ->
lists:concat([TopType,"_",I]);
_ ->
atom_to_list(TopType)
end,
emit(["decode_partial_inc_disp('",TopTypeName,"',Data) ->",nl,
" ",{asis,list_to_atom(lists:concat(["dec-inc-",FuncName2]))},
"(Data);",nl]),
gen_partial_inc_dispatcher(Rest,TypePattern);
gen_partial_inc_dispatcher([],_) ->
emit(["decode_partial_inc_disp(Type,_Data) ->",nl,
" exit({error,{asn1,{undefined_type,Type}}}).",nl]).
gen_dispatcher([F1,F2|T],FuncName,Prefix,ExtraArg) ->
emit([FuncName,"('",F1,"',Data) -> '",Prefix,F1,"'(Data",ExtraArg,")",";",nl]),
gen_dispatcher([F2|T],FuncName,Prefix,ExtraArg);
gen_dispatcher([Flast|_T],FuncName,Prefix,ExtraArg) ->
emit([FuncName,"('",Flast,"',Data) -> '",Prefix,Flast,"'(Data",ExtraArg,")",";",nl]),
emit([FuncName,"(","Type",",_Data) -> exit({error,{asn1,{undefined_type,Type}}}).",nl,nl,nl]).
pgen_info() ->
emit(["info() ->",nl,
" case ?MODULE:module_info(attributes) of",nl,
" Attributes when is_list(Attributes) ->",nl,
" case lists:keyfind(asn1_info, 1, Attributes) of",nl,
" {_,Info} when is_list(Info) ->",nl,
" Info;",nl,
" _ ->",nl,
" []",nl,
" end;",nl,
" _ ->",nl,
" []",nl,
" end.",nl]).
open_hrl(OutFile,Module) ->
File = lists:concat([OutFile,".hrl"]),
Fid = fopen(File),
put(gen_file_out,Fid),
gen_hrlhead(Module).
%% EMIT functions ************************
%% ***************************************
% debug generation
demit(Term) ->
case get(asndebug) of
true -> emit(Term);
_ ->true
end.
% always generation
emit(Term) ->
ok = file:write(get(gen_file_out), do_emit(Term)).
do_emit({external,_M,T}) ->
do_emit(T);
do_emit({prev,Variable}) when is_atom(Variable) ->
do_emit({var,asn1ct_name:prev(Variable)});
do_emit({next,Variable}) when is_atom(Variable) ->
do_emit({var,asn1ct_name:next(Variable)});
do_emit({curr,Variable}) when is_atom(Variable) ->
do_emit({var,asn1ct_name:curr(Variable)});
do_emit({var,Variable}) when is_atom(Variable) ->
[Head|V] = atom_to_list(Variable),
[Head-32|V];
do_emit({var,Variable}) ->
[Head|V] = Variable,
[Head-32|V];
do_emit({asis,What}) ->
io_lib:format("~w", [What]);
do_emit({call,M,F,A}) ->
MFA = {M,F,length(A)},
asn1ct_func:need(MFA),
[atom_to_list(F),"(",call_args(A, "")|")"];
do_emit(nl) ->
"\n";
do_emit(com) ->
",";
do_emit(tab) ->
" ";
do_emit(What) when is_integer(What) ->
integer_to_list(What);
do_emit(What) when is_list(What), is_integer(hd(What)) ->
What;
do_emit(What) when is_atom(What) ->
atom_to_list(What);
do_emit(What) when is_tuple(What) ->
[do_emit(E) || E <- tuple_to_list(What)];
do_emit(What) when is_list(What) ->
[do_emit(E) || E <- What].
call_args([A|As], Sep) ->
[Sep,do_emit(A)|call_args(As, ", ")];
call_args([], _) -> [].
fopen(F) ->
case file:open(F, [write,raw,delayed_write]) of
{ok, Fd} ->
Fd;
{error, Reason} ->
io:format("** Can't open file ~p ~n", [F]),
exit({error,Reason})
end.
pgen_hrl(Erules,Module,TypeOrVal,Options,_Indent) ->
put(currmod,Module),
{Types,Values,Ptypes,_,_,_} = TypeOrVal,
Ret =
case pgen_hrltypes(Erules,Module,Ptypes++Types,0) of
0 ->
case Values of
[] ->
0;
_ ->
open_hrl(get(outfile),get(currmod)),
pgen_macros(Erules,Module,Values),
1
end;
X ->
pgen_macros(Erules,Module,Values),
X
end,
case Ret of
0 ->
0;
Y ->
Fid = get(gen_file_out),
file:close(Fid),
asn1ct:verbose("--~p--~n",
[{generated,lists:concat([get(outfile),".hrl"])}],
Options),
Y
end.
pgen_macros(_,_,[]) ->
true;
pgen_macros(Erules,Module,[H|T]) ->
Valuedef = asn1_db:dbget(Module,H),
gen_macro(Valuedef),
pgen_macros(Erules,Module,T).
pgen_hrltypes(_,_,[],NumRecords) ->
NumRecords;
pgen_hrltypes(Erules,Module,[H|T],NumRecords) ->
% io:format("records = ~p~n",NumRecords),
Typedef = asn1_db:dbget(Module,H),
AddNumRecords = gen_record(Typedef,NumRecords),
pgen_hrltypes(Erules,Module,T,NumRecords+AddNumRecords).
%% Generates a macro for value Value defined in the ASN.1 module
gen_macro(Value) when is_record(Value,valuedef) ->
Prefix = get_macro_name_prefix(),
emit({"-define('",Prefix,Value#valuedef.name,"', ",
{asis,Value#valuedef.value},").",nl}).
%% Generate record functions **************
%% Generates an Erlang record for each named and unnamed SEQUENCE and SET in the ASN.1
%% module. If no SEQUENCE or SET is found there is no .hrl file generated
gen_record(Tdef,NumRecords) when is_record(Tdef,typedef) ->
Name = [Tdef#typedef.name],
Type = Tdef#typedef.typespec,
gen_record(type,Name,Type,NumRecords);
gen_record(Tdef,NumRecords) when is_record(Tdef,ptypedef) ->
Name = [Tdef#ptypedef.name],
Type = Tdef#ptypedef.typespec,
gen_record(ptype,Name,Type,NumRecords).
gen_record(TorPtype,Name,[#'ComponentType'{name=Cname,typespec=Type}|T],Num) ->
Num2 = gen_record(TorPtype,[Cname|Name],Type,Num),
gen_record(TorPtype,Name,T,Num2);
gen_record(TorPtype,Name,{Clist1,Clist2},Num)
when is_list(Clist1), is_list(Clist2) ->
gen_record(TorPtype,Name,Clist1++Clist2,Num);
gen_record(TorPtype,Name,{Clist1,EClist,Clist2},Num)
when is_list(Clist1), is_list(EClist), is_list(Clist2) ->
gen_record(TorPtype,Name,Clist1++EClist++Clist2,Num);
gen_record(TorPtype,Name,[_|T],Num) -> % skip EXTENSIONMARK
gen_record(TorPtype,Name,T,Num);
gen_record(_TorPtype,_Name,[],Num) ->
Num;
gen_record(TorPtype,Name,Type,Num) when is_record(Type,type) ->
Def = Type#type.def,
Rec = case Def of
Seq when is_record(Seq,'SEQUENCE') ->
case Seq#'SEQUENCE'.pname of
false ->
{record,Seq#'SEQUENCE'.components};
%% _Pname when TorPtype == type ->
%% false;
_ ->
{record,Seq#'SEQUENCE'.components}
end;
Set when is_record(Set,'SET') ->
case Set#'SET'.pname of
false ->
{record,to_textual_order(Set#'SET'.components)};
_Pname when TorPtype == type ->
false;
_ ->
{record,to_textual_order(Set#'SET'.components)}
end;
% {'SET',{_,_CompList}} ->
% {record,_CompList};
{'CHOICE',_CompList} -> {inner,Def};
{'SEQUENCE OF',_CompList} -> {['SEQOF'|Name],Def};
{'SET OF',_CompList} -> {['SETOF'|Name],Def};
_ -> false
end,
case Rec of
false -> Num;
{record,CompList} ->
case Num of
0 -> open_hrl(get(outfile),get(currmod));
_ -> true
end,
Prefix = get_record_name_prefix(),
emit({"-record('",Prefix,list2name(Name),"',{",nl}),
RootList = case CompList of
_ when is_list(CompList) ->
CompList;
{Rl,_} -> Rl;
{Rl1,_Ext,_Rl2} -> Rl1
end,
gen_record2(Name,'SEQUENCE',RootList),
NewCompList =
case CompList of
{CompList1,[]} ->
emit({"}). % with extension mark",nl,nl}),
CompList1;
{Tr,ExtensionList2} ->
case Tr of
[] -> true;
_ -> emit({",",nl})
end,
emit({"%% with extensions",nl}),
gen_record2(Name, 'SEQUENCE', ExtensionList2,
"", ext),
emit({"}).",nl,nl}),
Tr ++ ExtensionList2;
{Rootl1,Extl,Rootl2} ->
case Rootl1 of
[] -> true;
_ -> emit([",",nl])
end,
emit(["%% with extensions",nl]),
gen_record2(Name,'SEQUENCE',Extl,"",ext),
case Extl of
[_H|_] when Rootl2 /= [] -> emit([",",nl]);
_ -> ok
end,
emit(["%% end of extensions",nl]),
gen_record2(Name,'SEQUENCE',Rootl2,"",noext),
emit(["}).",nl,nl]),
Rootl1++Extl++Rootl2;
_ ->
emit({"}).",nl,nl}),
CompList
end,
gen_record(TorPtype,Name,NewCompList,Num+1);
{inner,{'CHOICE', CompList}} ->
gen_record(TorPtype,Name,CompList,Num);
{NewName,{_, CompList}} ->
gen_record(TorPtype,NewName,CompList,Num)
end;
gen_record(_,_,_,NumRecords) -> % skip CLASS etc for now.
NumRecords.
gen_head(Erules,Mod,Hrl) ->
Options = get(encoding_options),
case Erules of
per ->
emit(["%% Generated by the Erlang ASN.1 PER-"
"compiler version, utilizing bit-syntax:",
asn1ct:vsn(),nl]);
ber ->
emit(["%% Generated by the Erlang ASN.1 BER_V2-"
"compiler version, utilizing bit-syntax:",
asn1ct:vsn(),nl]);
uper ->
emit(["%% Generated by the Erlang ASN.1 UNALIGNED"
" PER-compiler version, utilizing bit-syntax:",
asn1ct:vsn(),nl])
end,
emit({"%% Purpose: encoder and decoder to the types in mod ",Mod,nl,nl}),
emit({"-module('",Mod,"').",nl}),
put(currmod,Mod),
emit({"-compile(nowarn_unused_vars).",nl}),
case Hrl of
0 -> ok;
_ -> emit({"-include(\"",Mod,".hrl\").",nl})
end,
emit(["-asn1_info([{vsn,'",asn1ct:vsn(),"'},",nl,
" {module,'",Mod,"'},",nl,
" {options,",io_lib:format("~p",[Options]),"}]).",nl,nl]).
gen_hrlhead(Mod) ->
emit({"%% Generated by the Erlang ASN.1 compiler version:",asn1ct:vsn(),nl}),
emit({"%% Purpose: Erlang record definitions for each named and unnamed",nl}),
emit({"%% SEQUENCE and SET, and macro definitions for each value",nl}),
emit({"%% definition,in module ",Mod,nl,nl}),
emit({nl,nl}).
gen_record2(Name,SeqOrSet,Comps) ->
gen_record2(Name,SeqOrSet,Comps,"",noext).
gen_record2(_Name,_SeqOrSet,[],_Com,_Extension) ->
true;
gen_record2(_Name,_SeqOrSet,[H = #'ComponentType'{name=Cname}],Com,Extension) ->
emit(Com),
emit({asis,Cname}),
gen_record_default(H, Extension);
gen_record2(Name,SeqOrSet,[H = #'ComponentType'{name=Cname}|T],Com, Extension) ->
emit(Com),
emit({asis,Cname}),
gen_record_default(H, Extension),
gen_record2(Name,SeqOrSet,T,", ", Extension);
gen_record2(Name,SeqOrSet,[_|T],Com,Extension) ->
%% skip EXTENSIONMARK, ExtensionAdditionGroup and other markers
gen_record2(Name,SeqOrSet,T,Com,Extension).
gen_record_default(#'ComponentType'{prop='OPTIONAL'}, _)->
emit(" = asn1_NOVALUE");
gen_record_default(#'ComponentType'{prop={'DEFAULT',_}}, _)->
emit(" = asn1_DEFAULT");
gen_record_default(_, _) ->
true.
%% May only be a list or a two-tuple.
to_textual_order({Root,Ext}) ->
{to_textual_order(Root),Ext};
to_textual_order(Cs={_R1,_Ext,_R2}) ->
Cs;
to_textual_order(Cs=[#'ComponentType'{textual_order=undefined}|_]) ->
Cs;
to_textual_order(Cs) when is_list(Cs) ->
lists:keysort(#'ComponentType'.textual_order,Cs).
gen_check_call(TopType,Cname,Type,InnerType,WhatKind,DefaultValue,Element) ->
case WhatKind of
{primitive,bif} ->
gen_prim_check_call(InnerType,DefaultValue,Element,Type);
#'Externaltypereference'{module=M,type=T} ->
%% generate function call
Name = list2name([T,check]),
emit({"'",Name,"'(",DefaultValue,", ",Element,")"}),
%% insert in ets table and do look ahead check
Typedef = asn1_db:dbget(M,T),
RefType = Typedef#typedef.typespec,
InType = asn1ct_gen:get_inner(RefType#type.def),
case insert_once(check_functions,{Name,RefType}) of
true ->
lookahead_innertype([T],InType,RefType);
_ ->
ok
end;
{constructed,bif} ->
NameList = [Cname|TopType],
Name = list2name(NameList ++ [check]),
emit({"'",Name,"'(",DefaultValue,", ",Element,")"}),
asn1ct_table:insert(check_functions, {Name, Type}),
%% Must look for check functions in InnerType,
%% that may be referenced or internal defined
%% constructed types not used elsewhere.
lookahead_innertype(NameList,InnerType,Type);
_ ->
%% Generate Dummy function call i.e. anything is accepted
emit(["fun() -> true end ()"])
end.
gen_prim_check_call(PrimType, Default, Element, Type) ->
case unify_if_string(PrimType) of
'BOOLEAN' ->
check_call(check_bool, [Default,Element]);
'INTEGER' ->
NNL = case Type#type.def of
{_,NamedNumberList} -> NamedNumberList;
_ -> []
end,
check_call(check_int, [Default,Element,{asis,NNL}]);
'BIT STRING' ->
{_,NBL} = Type#type.def,
check_call(check_bitstring, [Default,Element,{asis,NBL}]);
'OCTET STRING' ->
check_call(check_octetstring, [Default,Element]);
'NULL' ->
check_call(check_null, [Default,Element]);
'OBJECT IDENTIFIER' ->
check_call(check_objectidentifier, [Default,Element]);
'RELATIVE-OID' ->
check_call(check_objectidentifier, [Default,Element]);
'ObjectDescriptor' ->
check_call(check_objectdescriptor, [Default,Element]);
'REAL' ->
check_call(check_real, [Default,Element]);
'ENUMERATED' ->
{_,Enumerations} = Type#type.def,
check_call(check_enum, [Default,Element,{asis,Enumerations}]);
restrictedstring ->
check_call(check_restrictedstring, [Default,Element])
end.
check_call(F, Args) ->
asn1ct_func:call(check, F, Args).
%% lokahead_innertype/3 traverses Type and checks if check functions
%% have to be generated, i.e. for all constructed or referenced types.
lookahead_innertype(Name,'SEQUENCE',Type) ->
Components = (Type#type.def)#'SEQUENCE'.components,
lookahead_components(Name,Components);
lookahead_innertype(Name,'SET',Type) ->
Components = (Type#type.def)#'SET'.components,
lookahead_components(Name,Components);
lookahead_innertype(Name,'CHOICE',Type) ->
{_,Components} = Type#type.def,
lookahead_components(Name,Components);
lookahead_innertype(Name,'SEQUENCE OF',SeqOf) ->
lookahead_sof(Name,'SEQOF',SeqOf);
lookahead_innertype(Name,'SET OF',SeqOf) ->
lookahead_sof(Name,'SETOF',SeqOf);
lookahead_innertype(_Name,#'Externaltypereference'{module=M,type=T},_) ->
Typedef = asn1_db:dbget(M,T),
RefType = Typedef#typedef.typespec,
insert_once(check_functions,{list2name([T,check]),RefType}),
InType = asn1ct_gen:get_inner(RefType#type.def),
case type(InType) of
{constructed,bif} ->
lookahead_innertype([T],InType,RefType);
Ref = #'Externaltypereference'{} ->
lookahead_reference(Ref);
_ ->
ok
end;
lookahead_innertype(_,_,_) ->
ok.
lookahead_components(_,[]) -> ok;
lookahead_components(Name,[C|Cs]) ->
#'ComponentType'{name=Cname,typespec=Type} = C,
InType = asn1ct_gen:get_inner(Type#type.def),
case asn1ct_gen:type(InType) of
{constructed,bif} ->
case insert_once(check_functions,
{list2name([Cname|Name] ++ [check]),Type}) of
true ->
lookahead_innertype([Cname|Name],InType,Type);
_ ->
ok
end;
#'Externaltypereference'{module=RefMod,type=RefName} ->
Typedef = asn1_db:dbget(RefMod,RefName),
RefType = Typedef#typedef.typespec,
case insert_once(check_functions,{list2name([RefName,check]),
RefType}) of
true ->
lookahead_innertype([RefName],InType,RefType);
_ ->
ok
end;
_ ->
ok
end,
lookahead_components(Name,Cs).
lookahead_sof(Name,SOF,SOFType) ->
Type = case SOFType#type.def of
{_,_Type} -> _Type;
_Type -> _Type
end,
InnerType = asn1ct_gen:get_inner(Type#type.def),
case asn1ct_gen:type(InnerType) of
{constructed,bif} ->
%% this is if a constructed type is defined in
%% the SEQUENCE OF type
NameList = [SOF|Name],
insert_once(check_functions,
{list2name(NameList ++ [check]),Type}),
lookahead_innertype(NameList,InnerType,Type);
Ref = #'Externaltypereference'{} ->
lookahead_reference(Ref);
_ ->
ok
end.
lookahead_reference(#'Externaltypereference'{module=M,type=T}) ->
Typedef = asn1_db:dbget(M,T),
RefType = Typedef#typedef.typespec,
InType = get_inner(RefType#type.def),
case insert_once(check_functions,
{list2name([T,check]),RefType}) of
true ->
lookahead_innertype([T],InType,RefType);
_ ->
ok
end.
insert_once(Table,Object) ->
case asn1ct_table:lookup(Table, element(1, Object)) of
[] ->
asn1ct_table:insert(Table, Object); %returns true
_ -> false
end.
unify_if_string(PrimType) ->
case PrimType of
'NumericString' ->
restrictedstring;
'PrintableString' ->
restrictedstring;
'TeletexString' ->
restrictedstring;
'T61String' ->
restrictedstring;
'VideotexString' ->
restrictedstring;
'IA5String' ->
restrictedstring;
'UTCTime' ->
restrictedstring;
'GeneralizedTime' ->
restrictedstring;
'GraphicString' ->
restrictedstring;
'VisibleString' ->
restrictedstring;
'GeneralString' ->
restrictedstring;
'UniversalString' ->
restrictedstring;
'BMPString' ->
restrictedstring;
'UTF8String' ->
restrictedstring;
Other -> Other
end.
get_inner(A) when is_atom(A) -> A;
get_inner(Ext) when is_record(Ext,'Externaltypereference') -> Ext;
get_inner({fixedtypevaluefield,_,Type}) ->
if
is_record(Type,type) ->
get_inner(Type#type.def);
true ->
get_inner(Type)
end;
get_inner({typefield,TypeName}) ->
TypeName;
get_inner(#'ObjectClassFieldType'{type=Type}) ->
% get_inner(Type);
Type;
get_inner(T) when is_tuple(T) ->
case element(1,T) of
Tuple when is_tuple(Tuple),element(1,Tuple) == objectclass ->
case catch(lists:last(element(2,T))) of
{valuefieldreference,FieldName} ->
get_fieldtype(element(2,Tuple),FieldName);
{typefieldreference,FieldName} ->
get_fieldtype(element(2,Tuple),FieldName);
{'EXIT',Reason} ->
throw({asn1,{'internal error in get_inner/1',Reason}})
end;
_ -> element(1,T)
end.
type(X) when is_record(X,'Externaltypereference') ->
X;
type('ASN1_OPEN_TYPE') ->
'ASN1_OPEN_TYPE';
type({fixedtypevaluefield,_Name,Type}) when is_record(Type,type) ->
type(get_inner(Type#type.def));
type({typefield,_}) ->
'ASN1_OPEN_TYPE';
type(X) ->
case prim_bif(X) of
true ->
{primitive,bif};
false ->
case construct_bif(X) of
true ->
{constructed,bif};
false ->
{undefined,user}
end
end.
prim_bif(X) ->
lists:member(X,['INTEGER' ,
'ENUMERATED',
'REAL',
'OBJECT IDENTIFIER',
'RELATIVE-OID',
'NULL',
'BIT STRING' ,
'OCTET STRING' ,
'ObjectDescriptor',
'NumericString',
'TeletexString',
'T61String',
'VideotexString',
'UTCTime',
'GeneralizedTime',
'GraphicString',
'VisibleString',
'GeneralString',
'PrintableString',
'IA5String',
'UniversalString',
'UTF8String',
'BMPString',
'ENUMERATED',
'BOOLEAN']).
construct_bif(T) ->
lists:member(T,['SEQUENCE' ,
'SEQUENCE OF' ,
'CHOICE' ,
'SET' ,
'SET OF']).
def_to_tag(#tag{class=Class,number=Number}) ->
{Class,Number};
def_to_tag(#'ObjectClassFieldType'{type=Type}) ->
case Type of
T when is_tuple(T),element(1,T)==fixedtypevaluefield ->
{'UNIVERSAL',get_inner(Type)};
_ ->
[]
end;
def_to_tag(Def) ->
{'UNIVERSAL',get_inner(Def)}.
%% Information Object Class
get_fieldtype([],_FieldName)->
{no_type,no_name};
get_fieldtype([Field|Rest],FieldName) ->
case element(2,Field) of
FieldName ->
case element(1,Field) of
fixedtypevaluefield ->
{element(1,Field),FieldName,element(3,Field)};
_ ->
{element(1,Field),FieldName}
end;
_ ->
get_fieldtype(Rest,FieldName)
end.
%% Information Object Class
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Convert a list of name parts to something that can be output by emit
%%
%% used to output function names in generated code.
list2name(L) ->
NewL = list2name1(L),
lists:concat(lists:reverse(NewL)).
list2name1([{ptype,H1},H2|T]) ->
[H1,"_",list2name([H2|T])];
list2name1([H1,H2|T]) ->
[H1,"_",list2name([H2|T])];
list2name1([{ptype,H}|_T]) ->
[H];
list2name1([H|_T]) ->
[H];
list2name1([]) ->
[].
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Convert a list of name parts to something that can be output by emit
%% stops at {ptype,Pname} i.e Pname whill be the first part of the name
%% used to output record names in generated code.
list2rname(L) ->
NewL = list2rname1(L),
lists:concat(lists:reverse(NewL)).
list2rname1([{ptype,H1},_H2|_T]) ->
[H1];
list2rname1([H1,H2|T]) ->
[H1,"_",list2name([H2|T])];
list2rname1([{ptype,H}|_T]) ->
[H];
list2rname1([H|_T]) ->
[H];
list2rname1([]) ->
[].
constructed_suffix(_,#'SEQUENCE'{pname=Ptypename}) when Ptypename =/= false ->
{ptype, Ptypename};
constructed_suffix(_,#'SET'{pname=Ptypename}) when Ptypename =/= false ->
{ptype,Ptypename};
constructed_suffix('SEQUENCE OF',_) ->
'SEQOF';
constructed_suffix('SET OF',_) ->
'SETOF'.
erule(ber) -> ber;
erule(per) -> per;
erule(uper) -> per.
index2suffix(0) ->
"";
index2suffix(N) ->
lists:concat(["_",N]).
ct_gen_module(ber) ->
asn1ct_gen_ber_bin_v2;
ct_gen_module(per) ->
asn1ct_gen_per;
ct_gen_module(uper) ->
asn1ct_gen_per.
ct_constructed_module(ber) ->
asn1ct_constructed_ber_bin_v2;
ct_constructed_module(per) ->
asn1ct_constructed_per;
ct_constructed_module(uper) ->
asn1ct_constructed_per.
get_constraint(C,Key) ->
case lists:keysearch(Key,1,C) of
false ->
no;
{value,{_,V}} ->
V;
{value,Cnstr} ->
Cnstr
end.
ensure_atom(Atom) when is_atom(Atom) ->
Atom;
ensure_atom(List) when is_list(List) ->
list_to_atom(List).
get_record_name_prefix() ->
case lists:keysearch(record_name_prefix,1,get(encoding_options)) of
false ->
"";
{value,{_,Prefix}} ->
Prefix
end.
get_macro_name_prefix() ->
case lists:keysearch(macro_name_prefix,1,get(encoding_options)) of
false ->
"";
{value,{_,Prefix}} ->
Prefix
end.