%%
%% %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_imm/3]).
-export([gen_obj_code/3,gen_objectset_code/2]).
-export([gen_decode/2, gen_decode/3]).
-export([gen_encode/2, gen_encode/3]).
-export([gen_dec_external/2]).
-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),
emit({".",nl});
'ASN1_OPEN_TYPE' ->
gen_encode_prim(Erules, Def#type{def='ASN1_OPEN_TYPE'}),
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})
end.
gen_encode_prim(Erules, D) ->
Value = {var,atom_to_list(asn1ct_gen:mk_var(asn1ct_name:curr(val)))},
gen_encode_prim(Erules, D, Value).
gen_encode_prim(Erules, #type{}=D, Value) ->
Aligned = case Erules of
uper -> false;
per -> true
end,
Imm = gen_encode_prim_imm(Value, D, Aligned),
asn1ct_imm:enc_cg(Imm, Aligned).
gen_encode_prim_imm(Val, #type{def=Type0,constraint=Constraint}, Aligned) ->
case simplify_type(Type0) of
k_m_string ->
Type = case Type0 of
'GeneralizedTime' -> 'VisibleString';
'UTCTime' -> 'VisibleString';
_ -> Type0
end,
asn1ct_imm:per_enc_k_m_string(Val, Type, Constraint, Aligned);
restricted_string ->
ToBinary = {erlang,iolist_to_binary},
asn1ct_imm:per_enc_restricted_string(Val, ToBinary, Aligned);
{'ENUMERATED',NNL} ->
asn1ct_imm:per_enc_enumerated(Val, NNL, Aligned);
'INTEGER' ->
asn1ct_imm:per_enc_integer(Val, Constraint, Aligned);
{'INTEGER',NNL} ->
asn1ct_imm:per_enc_integer(Val, NNL, Constraint, Aligned);
'REAL' ->
ToBinary = {real_common,encode_real},
asn1ct_imm:per_enc_restricted_string(Val, ToBinary, Aligned);
{'BIT STRING',NNL} ->
case asn1ct:use_legacy_types() of
false ->
asn1ct_imm:per_enc_bit_string(Val, NNL,
Constraint, Aligned);
true ->
asn1ct_imm:per_enc_legacy_bit_string(Val, NNL,
Constraint, Aligned)
end;
'NULL' ->
asn1ct_imm:per_enc_null(Val, Aligned);
'OBJECT IDENTIFIER' ->
ToBinary = {per_common,encode_oid},
asn1ct_imm:per_enc_restricted_string(Val, ToBinary, Aligned);
'RELATIVE-OID' ->
ToBinary = {per_common,encode_relative_oid},
asn1ct_imm:per_enc_restricted_string(Val, ToBinary, Aligned);
'BOOLEAN' ->
asn1ct_imm:per_enc_boolean(Val, Aligned);
'OCTET STRING' ->
asn1ct_imm:per_enc_octet_string(Val, Constraint, Aligned);
'ASN1_OPEN_TYPE' ->
case Constraint of
[#'Externaltypereference'{type=Tname}] ->
EncFunc = enc_func(Tname),
Imm = [{apply,{local,EncFunc,[]},[Val]}],
asn1ct_imm:per_enc_open_type(Imm, Aligned);
[] ->
Imm = [{call,erlang,iolist_to_binary,[Val]}],
asn1ct_imm:per_enc_open_type(Imm, Aligned)
end
end.
dec_func(Tname) ->
list_to_atom(lists:concat(["dec_",Tname])).
enc_func(Tname) ->
list_to_atom(lists:concat(["enc_",Tname])).
simplify_type(Type) ->
case Type of
'BMPString' -> k_m_string;
'IA5String' -> k_m_string;
'NumericString' -> k_m_string;
'PrintableString' -> k_m_string;
'VisibleString' -> k_m_string;
'UniversalString' -> k_m_string;
'GeneralizedTime' -> k_m_string;
'UTCTime' -> k_m_string;
'TeletexString' -> restricted_string;
'T61String' -> restricted_string;
'VideotexString' -> restricted_string;
'GraphicString' -> restricted_string;
'GeneralString' -> restricted_string;
'UTF8String' -> restricted_string;
'ObjectDescriptor' -> restricted_string;
Other -> Other
end.
%% Object code generating for encoding and decoding
%% ------------------------------------------------
gen_obj_code(_Erules, _Module, #typedef{}) ->
ok.
%% Object Set code generating for encoding and decoding
%% ----------------------------------------------------
gen_objectset_code(_Erules, _ObjSet) ->
ok.
%% DECODING *****************************
%%***************************************
gen_decode(Erules, #typedef{}=Type) ->
DecFunc = dec_func(Type#typedef.name),
emit([nl,nl,{asis,DecFunc},"(Bytes) ->",nl]),
dbdec(Type#typedef.name),
gen_decode_user(Erules, Type).
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,
{asis,dec_func(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) ->
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);
#'Externaltypereference'{}=Etype ->
gen_dec_external(Etype, "Bytes"),
emit([".",nl,nl]);
Other ->
exit({error,{asn1,{unknown,Other}}})
end.
gen_dec_external(Ext, BytesVar) ->
CurrMod = get(currmod),
#'Externaltypereference'{module=Mod,type=Type} = Ext,
emit([case CurrMod of
Mod -> [];
_ -> [{asis,Mod},":"]
end,{asis,dec_func(Type)},"(",BytesVar,")"]).
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({'BIT STRING',NNL}, Constr0, Aligned) ->
Constr = asn1ct_imm:effective_constraint(bitstring, Constr0),
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 = asn1ct_imm:effective_constraint(bitstring, Constraint),
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_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).
%% 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},",_} = ",
{asis,dec_func(Type)},"(",OpenType,"),",nl,
"{",{curr,tmpval},com,Buf,"}",nl,
"end"])
end,
{call,D,asn1ct_imm:per_dec_open_type(Aligned)}.