%% ``Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%
%% The Initial Developer of the Original Code is Ericsson Utvecklings AB.
%% Portions created by Ericsson are Copyright 1999, Ericsson Utvecklings
%% AB. All Rights Reserved.''
%%
%% $Id: asn1rt_per_bin_rt2ct.erl,v 1.1 2008/12/17 09:53:31 mikpe Exp $
-module(asn1rt_per_bin_rt2ct).
%% encoding / decoding of PER aligned
-include("asn1_records.hrl").
-export([dec_fixup/3, cindex/3, list_to_record/2]).
-export([setchoiceext/1, setext/1, fixoptionals/3, fixextensions/2,
getext/1, getextension/2, skipextensions/3, getbit/1, getchoice/3 ]).
-export([getoptionals/2, getoptionals2/2,
set_choice/3, encode_integer/2, encode_integer/3 ]).
-export([decode_integer/2, decode_integer/3, encode_small_number/1,
decode_boolean/1, encode_length/2, decode_length/1, decode_length/2,
encode_small_length/1, decode_small_length/1,
decode_compact_bit_string/3]).
-export([decode_enumerated/3,
encode_bit_string/3, decode_bit_string/3 ]).
-export([encode_octet_string/2, decode_octet_string/2,
encode_null/1, decode_null/1,
encode_object_identifier/1, decode_object_identifier/1,
complete/1]).
-export([encode_open_type/2, decode_open_type/2]).
-export([%encode_UniversalString/2, decode_UniversalString/2,
%encode_PrintableString/2, decode_PrintableString/2,
encode_GeneralString/2, decode_GeneralString/2,
encode_GraphicString/2, decode_GraphicString/2,
encode_TeletexString/2, decode_TeletexString/2,
encode_VideotexString/2, decode_VideotexString/2,
%encode_VisibleString/2, decode_VisibleString/2,
%encode_BMPString/2, decode_BMPString/2,
%encode_IA5String/2, decode_IA5String/2,
%encode_NumericString/2, decode_NumericString/2,
encode_ObjectDescriptor/2, decode_ObjectDescriptor/1
]).
-export([decode_constrained_number/2,
decode_constrained_number/3,
decode_unconstrained_number/1,
decode_semi_constrained_number/2,
encode_unconstrained_number/1,
decode_constrained_number/4,
encode_octet_string/3,
decode_octet_string/3,
encode_known_multiplier_string/5,
decode_known_multiplier_string/5,
getoctets/2, getbits/2
% start_drv/1,start_drv2/1,init_drv/1
]).
-export([eint_positive/1]).
-export([pre_complete_bits/2]).
-define('16K',16384).
-define('32K',32768).
-define('64K',65536).
%%-define(nodriver,true).
dec_fixup(Terms,Cnames,RemBytes) ->
dec_fixup(Terms,Cnames,RemBytes,[]).
dec_fixup([novalue|T],[_Hc|Tc],RemBytes,Acc) ->
dec_fixup(T,Tc,RemBytes,Acc);
dec_fixup([{_Name,novalue}|T],[_Hc|Tc],RemBytes,Acc) ->
dec_fixup(T,Tc,RemBytes,Acc);
dec_fixup([H|T],[Hc|Tc],RemBytes,Acc) ->
dec_fixup(T,Tc,RemBytes,[{Hc,H}|Acc]);
dec_fixup([],_Cnames,RemBytes,Acc) ->
{lists:reverse(Acc),RemBytes}.
cindex(Ix,Val,Cname) ->
case element(Ix,Val) of
{Cname,Val2} -> Val2;
X -> X
end.
%% converts a list to a record if necessary
list_to_record(_,Tuple) when tuple(Tuple) ->
Tuple;
list_to_record(Name,List) when list(List) ->
list_to_tuple([Name|List]).
%%--------------------------------------------------------
%% setchoiceext(InRootSet) -> [{bit,X}]
%% X is set to 1 when InRootSet==false
%% X is set to 0 when InRootSet==true
%%
setchoiceext(true) ->
% [{debug,choiceext},{bits,1,0}];
[0];
setchoiceext(false) ->
% [{debug,choiceext},{bits,1,1}].
[1].
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% setext(true|false) -> CompleteList
%%
setext(false) ->
% [{debug,ext},{bits,1,0}];
[0];
setext(true) ->
% [{debug,ext},{bits,1,1}];
[1].
fixoptionals(OptList,_OptLength,Val) when tuple(Val) ->
% Bits = fixoptionals(OptList,Val,0),
% {Val,{bits,OptLength,Bits}};
% {Val,[10,OptLength,Bits]};
{Val,fixoptionals(OptList,Val,[])};
fixoptionals([],_,Acc) ->
%% Optbits
lists:reverse(Acc);
fixoptionals([Pos|Ot],Val,Acc) ->
case element(Pos,Val) of
% asn1_NOVALUE -> fixoptionals(Ot,Val,Acc bsl 1);
% asn1_DEFAULT -> fixoptionals(Ot,Val,Acc bsl 1);
% _ -> fixoptionals(Ot,Val,(Acc bsl 1) + 1)
asn1_NOVALUE -> fixoptionals(Ot,Val,[0|Acc]);
asn1_DEFAULT -> fixoptionals(Ot,Val,[0|Acc]);
_ -> fixoptionals(Ot,Val,[1|Acc])
end.
getext(Bytes) when tuple(Bytes) ->
getbit(Bytes);
getext(Bytes) when binary(Bytes) ->
getbit({0,Bytes});
getext(Bytes) when list(Bytes) ->
getbit({0,Bytes}).
getextension(0, Bytes) ->
{{},Bytes};
getextension(1, Bytes) ->
{Len,Bytes2} = decode_small_length(Bytes),
{Blist, Bytes3} = getbits_as_list(Len,Bytes2),
{list_to_tuple(Blist),Bytes3}.
fixextensions({ext,ExtPos,ExtNum},Val) ->
case fixextensions(ExtPos,ExtNum+ExtPos,Val,0) of
0 -> [];
ExtBits ->
% [encode_small_length(ExtNum),{bits,ExtNum,ExtBits}]
% [encode_small_length(ExtNum),[10,ExtNum,ExtBits]]
[encode_small_length(ExtNum),pre_complete_bits(ExtNum,ExtBits)]
end.
fixextensions(Pos,MaxPos,_,Acc) when Pos >= MaxPos ->
Acc;
fixextensions(Pos,ExtPos,Val,Acc) ->
Bit = case catch(element(Pos+1,Val)) of
asn1_NOVALUE ->
0;
asn1_NOEXTVALUE ->
0;
{'EXIT',_} ->
0;
_ ->
1
end,
fixextensions(Pos+1,ExtPos,Val,(Acc bsl 1)+Bit).
skipextensions(Bytes,Nr,ExtensionBitPattern) ->
case (catch element(Nr,ExtensionBitPattern)) of
1 ->
{_,Bytes2} = decode_open_type(Bytes,[]),
skipextensions(Bytes2, Nr+1, ExtensionBitPattern);
0 ->
skipextensions(Bytes, Nr+1, ExtensionBitPattern);
{'EXIT',_} -> % badarg, no more extensions
Bytes
end.
getchoice(Bytes,1,0) -> % only 1 alternative is not encoded
{0,Bytes};
getchoice(Bytes,_,1) ->
decode_small_number(Bytes);
getchoice(Bytes,NumChoices,0) ->
decode_constrained_number(Bytes,{0,NumChoices-1}).
%% old version kept for backward compatibility with generates from R7B01
getoptionals(Bytes,NumOpt) ->
{Blist,Bytes1} = getbits_as_list(NumOpt,Bytes),
{list_to_tuple(Blist),Bytes1}.
%% new version used in generates from r8b_patch/3 and later
getoptionals2(Bytes,NumOpt) ->
{_,_} = getbits(Bytes,NumOpt).
%% getbits_as_binary(Num,Bytes) -> {{Unused,BinBits},RestBytes},
%% Num = integer(),
%% Bytes = list() | tuple(),
%% Unused = integer(),
%% BinBits = binary(),
%% RestBytes = tuple()
getbits_as_binary(Num,Bytes) when binary(Bytes) ->
getbits_as_binary(Num,{0,Bytes});
getbits_as_binary(0,Buffer) ->
{{0,<<>>},Buffer};
getbits_as_binary(Num,{0,Bin}) when Num > 16 ->
Used = Num rem 8,
Pad = (8 - Used) rem 8,
%% Nbytes = Num div 8,
<<Bits:Num,_:Pad,RestBin/binary>> = Bin,
{{Pad,<<Bits:Num,0:Pad>>},RestBin};
getbits_as_binary(Num,Buffer={_Used,_Bin}) -> % Unaligned buffer
%% Num =< 16,
{Bits2,Buffer2} = getbits(Buffer,Num),
Pad = (8 - (Num rem 8)) rem 8,
{{Pad,<<Bits2:Num,0:Pad>>},Buffer2}.
% integer_from_list(Int,[],BigInt) ->
% BigInt;
% integer_from_list(Int,[H|T],BigInt) when Int < 8 ->
% (BigInt bsl Int) bor (H bsr (8-Int));
% integer_from_list(Int,[H|T],BigInt) ->
% integer_from_list(Int-8,T,(BigInt bsl 8) bor H).
getbits_as_list(Num,Bytes) when binary(Bytes) ->
getbits_as_list(Num,{0,Bytes},[]);
getbits_as_list(Num,Bytes) ->
getbits_as_list(Num,Bytes,[]).
%% If buffer is empty and nothing more will be picked.
getbits_as_list(0, B, Acc) ->
{lists:reverse(Acc),B};
%% If first byte in buffer is full and at least one byte will be picked,
%% then pick one byte.
getbits_as_list(N,{0,Bin},Acc) when N >= 8 ->
<<B7:1,B6:1,B5:1,B4:1,B3:1,B2:1,B1:1,B0:1,Rest/binary>> = Bin,
getbits_as_list(N-8,{0,Rest},[B0,B1,B2,B3,B4,B5,B6,B7|Acc]);
getbits_as_list(N,{Used,Bin},Acc) when N >= 4, Used =< 4 ->
NewUsed = Used + 4,
Rem = 8 - NewUsed,
<<_:Used,B3:1,B2:1,B1:1,B0:1,_:Rem, Rest/binary>> = Bin,
NewRest = case Rem of 0 -> Rest; _ -> Bin end,
getbits_as_list(N-4,{NewUsed rem 8,NewRest},[B0,B1,B2,B3|Acc]);
getbits_as_list(N,{Used,Bin},Acc) when N >= 2, Used =< 6 ->
NewUsed = Used + 2,
Rem = 8 - NewUsed,
<<_:Used,B1:1,B0:1,_:Rem, Rest/binary>> = Bin,
NewRest = case Rem of 0 -> Rest; _ -> Bin end,
getbits_as_list(N-2,{NewUsed rem 8,NewRest},[B0,B1|Acc]);
getbits_as_list(N,{Used,Bin},Acc) when Used =< 7 ->
NewUsed = Used + 1,
Rem = 8 - NewUsed,
<<_:Used,B0:1,_:Rem, Rest/binary>> = Bin,
NewRest = case Rem of 0 -> Rest; _ -> Bin end,
getbits_as_list(N-1,{NewUsed rem 8,NewRest},[B0|Acc]).
getbit({7,<<_:7,B:1,Rest/binary>>}) ->
{B,{0,Rest}};
getbit({0,Buffer = <<B:1,_:7,_/binary>>}) ->
{B,{1,Buffer}};
getbit({Used,Buffer}) ->
Unused = (8 - Used) - 1,
<<_:Used,B:1,_:Unused,_/binary>> = Buffer,
{B,{Used+1,Buffer}};
getbit(Buffer) when binary(Buffer) ->
getbit({0,Buffer}).
getbits({0,Buffer},Num) when (Num rem 8) == 0 ->
<<Bits:Num,Rest/binary>> = Buffer,
{Bits,{0,Rest}};
getbits({Used,Bin},Num) ->
NumPlusUsed = Num + Used,
NewUsed = NumPlusUsed rem 8,
Unused = (8-NewUsed) rem 8,
case Unused of
0 ->
<<_:Used,Bits:Num,Rest/binary>> = Bin,
{Bits,{0,Rest}};
_ ->
Bytes = NumPlusUsed div 8,
<<_:Used,Bits:Num,_:Unused,_/binary>> = Bin,
<<_:Bytes/binary,Rest/binary>> = Bin,
{Bits,{NewUsed,Rest}}
end;
getbits(Bin,Num) when binary(Bin) ->
getbits({0,Bin},Num).
% getoctet(Bytes) when list(Bytes) ->
% getoctet({0,Bytes});
% getoctet(Bytes) ->
% %% io:format("getoctet:Buffer = ~p~n",[Bytes]),
% getoctet1(Bytes).
% getoctet1({0,[H|T]}) ->
% {H,{0,T}};
% getoctet1({Pos,[_,H|T]}) ->
% {H,{0,T}}.
align({0,L}) ->
{0,L};
align({_Pos,<<_H,T/binary>>}) ->
{0,T};
align(Bytes) ->
{0,Bytes}.
%% First align buffer, then pick the first Num octets.
%% Returns octets as an integer with bit significance as in buffer.
getoctets({0,Buffer},Num) ->
<<Val:Num/integer-unit:8,RestBin/binary>> = Buffer,
{Val,{0,RestBin}};
getoctets({U,<<_Padding,Rest/binary>>},Num) when U /= 0 ->
getoctets({0,Rest},Num);
getoctets(Buffer,Num) when binary(Buffer) ->
getoctets({0,Buffer},Num).
% getoctets(Buffer,Num) ->
% %% io:format("getoctets:Buffer = ~p~nNum = ~p~n",[Buffer,Num]),
% getoctets(Buffer,Num,0).
% getoctets(Buffer,0,Acc) ->
% {Acc,Buffer};
% getoctets(Buffer,Num,Acc) ->
% {Oct,NewBuffer} = getoctet(Buffer),
% getoctets(NewBuffer,Num-1,(Acc bsl 8)+Oct).
% getoctets_as_list(Buffer,Num) ->
% getoctets_as_list(Buffer,Num,[]).
% getoctets_as_list(Buffer,0,Acc) ->
% {lists:reverse(Acc),Buffer};
% getoctets_as_list(Buffer,Num,Acc) ->
% {Oct,NewBuffer} = getoctet(Buffer),
% getoctets_as_list(NewBuffer,Num-1,[Oct|Acc]).
%% First align buffer, then pick the first Num octets.
%% Returns octets as a binary
getoctets_as_bin({0,Bin},Num)->
<<Octets:Num/binary,RestBin/binary>> = Bin,
{Octets,{0,RestBin}};
getoctets_as_bin({_U,Bin},Num) ->
<<_Padding,Octets:Num/binary,RestBin/binary>> = Bin,
{Octets,{0,RestBin}};
getoctets_as_bin(Bin,Num) when binary(Bin) ->
getoctets_as_bin({0,Bin},Num).
%% same as above but returns octets as a List
getoctets_as_list(Buffer,Num) ->
{Bin,Buffer2} = getoctets_as_bin(Buffer,Num),
{binary_to_list(Bin),Buffer2}.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% set_choice(Alt,Choices,Altnum) -> ListofBitSettings
%% Alt = atom()
%% Altnum = integer() | {integer(),integer()}% number of alternatives
%% Choices = [atom()] | {[atom()],[atom()]}
%% When Choices is a tuple the first list is the Rootset and the
%% second is the Extensions and then Altnum must also be a tuple with the
%% lengths of the 2 lists
%%
set_choice(Alt,{L1,L2},{Len1,_Len2}) ->
case set_choice_tag(Alt,L1) of
N when integer(N), Len1 > 1 ->
% [{bits,1,0}, % the value is in the root set
% encode_constrained_number({0,Len1-1},N)];
[0, % the value is in the root set
encode_constrained_number({0,Len1-1},N)];
N when integer(N) ->
% [{bits,1,0}]; % no encoding if only 0 or 1 alternative
[0]; % no encoding if only 0 or 1 alternative
false ->
% [{bits,1,1}, % extension value
[1, % extension value
case set_choice_tag(Alt,L2) of
N2 when integer(N2) ->
encode_small_number(N2);
false ->
unknown_choice_alt
end]
end;
set_choice(Alt,L,Len) ->
case set_choice_tag(Alt,L) of
N when integer(N), Len > 1 ->
encode_constrained_number({0,Len-1},N);
N when integer(N) ->
[]; % no encoding if only 0 or 1 alternative
false ->
[unknown_choice_alt]
end.
set_choice_tag(Alt,Choices) ->
set_choice_tag(Alt,Choices,0).
set_choice_tag(Alt,[Alt|_Rest],Tag) ->
Tag;
set_choice_tag(Alt,[_H|Rest],Tag) ->
set_choice_tag(Alt,Rest,Tag+1);
set_choice_tag(_Alt,[],_Tag) ->
false.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% decode_fragmented_XXX; decode of values encoded fragmented according
%% to ITU-T X.691 clause 10.9.3.8. The unit (XXX) is either bits, octets,
%% characters or number of components (in a choice,sequence or similar).
%% Buffer is a buffer {Used, Bin}.
%% C is the constrained length.
%% If the buffer is not aligned, this function does that.
decode_fragmented_bits({0,Buffer},C) ->
decode_fragmented_bits(Buffer,C,[]);
decode_fragmented_bits({_N,<<_B,Bs/binary>>},C) ->
decode_fragmented_bits(Bs,C,[]).
decode_fragmented_bits(<<3:2,Len:6,Bin/binary>>,C,Acc) ->
{Value,Bin2} = split_binary(Bin, Len * ?'16K'),
decode_fragmented_bits(Bin2,C,[Value,Acc]);
decode_fragmented_bits(<<0:1,0:7,Bin/binary>>,C,Acc) ->
BinBits = list_to_binary(lists:reverse(Acc)),
case C of
Int when integer(Int),C == size(BinBits) ->
{BinBits,{0,Bin}};
Int when integer(Int) ->
exit({error,{asn1,{illegal_value,C,BinBits}}});
_ ->
{BinBits,{0,Bin}}
end;
decode_fragmented_bits(<<0:1,Len:7,Bin/binary>>,C,Acc) ->
Result = {BinBits,{Used,_Rest}} =
case (Len rem 8) of
0 ->
<<Value:Len/binary-unit:1,Bin2/binary>> = Bin,
{list_to_binary(lists:reverse([Value|Acc])),{0,Bin2}};
Rem ->
Bytes = Len div 8,
U = 8 - Rem,
<<Value:Bytes/binary-unit:8,Bits1:Rem,Bits2:U,Bin2/binary>> = Bin,
{list_to_binary(lists:reverse([Bits1 bsl U,Value|Acc])),
{Rem,<<Bits2,Bin2/binary>>}}
end,
case C of
Int when integer(Int),C == (size(BinBits) - ((8 - Used) rem 8)) ->
Result;
Int when integer(Int) ->
exit({error,{asn1,{illegal_value,C,BinBits}}});
_ ->
Result
end.
decode_fragmented_octets({0,Bin},C) ->
decode_fragmented_octets(Bin,C,[]);
decode_fragmented_octets({_N,<<_B,Bs/binary>>},C) ->
decode_fragmented_octets(Bs,C,[]).
decode_fragmented_octets(<<3:2,Len:6,Bin/binary>>,C,Acc) ->
{Value,Bin2} = split_binary(Bin,Len * ?'16K'),
decode_fragmented_octets(Bin2,C,[Value,Acc]);
decode_fragmented_octets(<<0:1,0:7,Bin/binary>>,C,Acc) ->
Octets = list_to_binary(lists:reverse(Acc)),
case C of
Int when integer(Int), C == size(Octets) ->
{Octets,{0,Bin}};
Int when integer(Int) ->
exit({error,{asn1,{illegal_value,C,Octets}}});
_ ->
{Octets,{0,Bin}}
end;
decode_fragmented_octets(<<0:1,Len:7,Bin/binary>>,C,Acc) ->
<<Value:Len/binary-unit:8,Bin2/binary>> = Bin,
BinOctets = list_to_binary(lists:reverse([Value|Acc])),
case C of
Int when integer(Int),size(BinOctets) == Int ->
{BinOctets,Bin2};
Int when integer(Int) ->
exit({error,{asn1,{illegal_value,C,BinOctets}}});
_ ->
{BinOctets,Bin2}
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% encode_open_type(Constraint, Value) -> CompleteList
%% Value = list of bytes of an already encoded value (the list must be flat)
%% | binary
%% Contraint = not used in this version
%%
encode_open_type(_Constraint, Val) when list(Val) ->
Bin = list_to_binary(Val),
case size(Bin) of
Size when Size>255 ->
[encode_length(undefined,Size),[21,<<Size:16>>,Bin]];
Size ->
[encode_length(undefined,Size),[20,Size,Bin]]
end;
% [encode_length(undefined,size(Bin)),{octets,Bin}]; % octets implies align
encode_open_type(_Constraint, Val) when binary(Val) ->
% [encode_length(undefined,size(Val)),{octets,Val}]. % octets implies align
case size(Val) of
Size when Size>255 ->
[encode_length(undefined,size(Val)),[21,<<Size:16>>,Val]]; % octets implies align
Size ->
[encode_length(undefined,Size),[20,Size,Val]]
end.
%% the binary_to_list is not optimal but compatible with the current solution
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% decode_open_type(Buffer,Constraint) -> Value
%% Constraint is not used in this version
%% Buffer = [byte] with PER encoded data
%% Value = [byte] with decoded data (which must be decoded again as some type)
%%
decode_open_type(Bytes, _Constraint) ->
{Len,Bytes2} = decode_length(Bytes,undefined),
getoctets_as_bin(Bytes2,Len).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% encode_integer(Constraint,Value,NamedNumberList) -> CompleteList
%% encode_integer(Constraint,Value) -> CompleteList
%% encode_integer(Constraint,{Name,Value}) -> CompleteList
%%
%%
encode_integer(C,V,NamedNumberList) when atom(V) ->
case lists:keysearch(V,1,NamedNumberList) of
{value,{_,NewV}} ->
encode_integer(C,NewV);
_ ->
exit({error,{asn1,{namednumber,V}}})
end;
encode_integer(C,V,_NamedNumberList) when integer(V) ->
encode_integer(C,V);
encode_integer(C,{Name,V},NamedNumberList) when atom(Name) ->
encode_integer(C,V,NamedNumberList).
encode_integer(C,{Name,Val}) when atom(Name) ->
encode_integer(C,Val);
encode_integer([{Rc,_Ec}],Val) when tuple(Rc) -> % XXX when is this invoked? First argument most often a list,...Ok this is the extension case...but it doesn't work.
case (catch encode_integer([Rc],Val)) of
{'EXIT',{error,{asn1,_}}} ->
% [{bits,1,1},encode_unconstrained_number(Val)];
[1,encode_unconstrained_number(Val)];
Encoded ->
% [{bits,1,0},Encoded]
[0,Encoded]
end;
encode_integer([],Val) ->
encode_unconstrained_number(Val);
%% The constraint is the effective constraint, and in this case is a number
encode_integer([{'SingleValue',V}],V) ->
[];
encode_integer([{'ValueRange',VR={Lb,Ub},Range,PreEnc}],Val) when Val >= Lb,
Ub >= Val ->
%% this case when NamedNumberList
encode_constrained_number(VR,Range,PreEnc,Val);
encode_integer([{'ValueRange',{Lb,'MAX'}}],Val) ->
encode_semi_constrained_number(Lb,Val);
encode_integer([{'ValueRange',{'MIN',_}}],Val) ->
encode_unconstrained_number(Val);
encode_integer([{'ValueRange',VR={_Lb,_Ub}}],Val) ->
encode_constrained_number(VR,Val);
encode_integer(_,Val) ->
exit({error,{asn1,{illegal_value,Val}}}).
decode_integer(Buffer,Range,NamedNumberList) ->
{Val,Buffer2} = decode_integer(Buffer,Range),
case lists:keysearch(Val,2,NamedNumberList) of
{value,{NewVal,_}} -> {NewVal,Buffer2};
_ -> {Val,Buffer2}
end.
decode_integer(Buffer,[{Rc,_Ec}]) when tuple(Rc) ->
{Ext,Buffer2} = getext(Buffer),
case Ext of
0 -> decode_integer(Buffer2,[Rc]);
1 -> decode_unconstrained_number(Buffer2)
end;
decode_integer(Buffer,undefined) ->
decode_unconstrained_number(Buffer);
decode_integer(Buffer,C) ->
case get_constraint(C,'SingleValue') of
V when integer(V) ->
{V,Buffer};
_ ->
decode_integer1(Buffer,C)
end.
decode_integer1(Buffer,C) ->
case VR = get_constraint(C,'ValueRange') of
no ->
decode_unconstrained_number(Buffer);
{Lb, 'MAX'} ->
decode_semi_constrained_number(Buffer,Lb);
{_Lb,_Ub} ->
decode_constrained_number(Buffer,VR)
end.
%% X.691:10.6 Encoding of a normally small non-negative whole number
%% Use this for encoding of CHOICE index if there is an extension marker in
%% the CHOICE
encode_small_number({Name,Val}) when atom(Name) ->
encode_small_number(Val);
encode_small_number(Val) when Val =< 63 ->
% [{bits,1,0},{bits,6,Val}];
% [{bits,7,Val}]; % same as above but more efficient
[10,7,Val]; % same as above but more efficient
encode_small_number(Val) ->
% [{bits,1,1},encode_semi_constrained_number(0,Val)].
[1,encode_semi_constrained_number(0,Val)].
decode_small_number(Bytes) ->
{Bit,Bytes2} = getbit(Bytes),
case Bit of
0 ->
getbits(Bytes2,6);
1 ->
decode_semi_constrained_number(Bytes2,0)
end.
%% X.691:10.7 Encoding of a semi-constrained whole number
%% might be an optimization encode_semi_constrained_number(0,Val) ->
encode_semi_constrained_number(C,{Name,Val}) when atom(Name) ->
encode_semi_constrained_number(C,Val);
encode_semi_constrained_number({Lb,'MAX'},Val) ->
encode_semi_constrained_number(Lb,Val);
encode_semi_constrained_number(Lb,Val) ->
Val2 = Val - Lb,
Oct = eint_positive(Val2),
Len = length(Oct),
if
Len < 128 ->
%{octets,[Len|Oct]}; % equiv with encode_length(undefined,Len) but faster
[20,Len+1,[Len|Oct]];
Len < 256 ->
[encode_length(undefined,Len),[20,Len,Oct]];
true ->
[encode_length(undefined,Len),[21,<<Len:16>>,Oct]]
end.
decode_semi_constrained_number(Bytes,{Lb,_}) ->
decode_semi_constrained_number(Bytes,Lb);
decode_semi_constrained_number(Bytes,Lb) ->
{Len,Bytes2} = decode_length(Bytes,undefined),
{V,Bytes3} = getoctets(Bytes2,Len),
{V+Lb,Bytes3}.
encode_constrained_number({Lb,_Ub},_Range,{bits,N},Val) ->
Val2 = Val-Lb,
% {bits,N,Val2};
[10,N,Val2];
encode_constrained_number({Lb,_Ub},_Range,{octets,N},Val) when N < 256->
%% N is 8 or 16 (1 or 2 octets)
Val2 = Val-Lb,
% {octets,<<Val2:N/unit:8>>};
[20,N,Val2];
encode_constrained_number({Lb,_Ub},_Range,{octets,N},Val) -> % N>255
%% N is 8 or 16 (1 or 2 octets)
Val2 = Val-Lb,
% {octets,<<Val2:N/unit:8>>};
[21,<<N:16>>,Val2];
encode_constrained_number({Lb,_Ub},Range,_,Val) ->
Val2 = Val-Lb,
if
Range =< 16#1000000 -> % max 3 octets
Octs = eint_positive(Val2),
% [encode_length({1,3},size(Octs)),{octets,Octs}];
L = length(Octs),
[encode_length({1,3},L),[20,L,Octs]];
Range =< 16#100000000 -> % max 4 octets
Octs = eint_positive(Val2),
% [encode_length({1,4},size(Octs)),{octets,Octs}];
L = length(Octs),
[encode_length({1,4},L),[20,L,Octs]];
Range =< 16#10000000000 -> % max 5 octets
Octs = eint_positive(Val2),
% [encode_length({1,5},size(Octs)),{octets,Octs}];
L = length(Octs),
[encode_length({1,5},L),[20,L,Octs]];
true ->
exit({not_supported,{integer_range,Range}})
end.
encode_constrained_number(Range,{Name,Val}) when atom(Name) ->
encode_constrained_number(Range,Val);
encode_constrained_number({Lb,Ub},Val) when Val >= Lb, Ub >= Val ->
Range = Ub - Lb + 1,
Val2 = Val - Lb,
if
Range == 2 ->
% Size = {bits,1,Val2};
[Val2];
Range =< 4 ->
% Size = {bits,2,Val2};
[10,2,Val2];
Range =< 8 ->
[10,3,Val2];
Range =< 16 ->
[10,4,Val2];
Range =< 32 ->
[10,5,Val2];
Range =< 64 ->
[10,6,Val2];
Range =< 128 ->
[10,7,Val2];
Range =< 255 ->
[10,8,Val2];
Range =< 256 ->
% Size = {octets,[Val2]};
[20,1,Val2];
Range =< 65536 ->
% Size = {octets,<<Val2:16>>};
[20,2,<<Val2:16>>];
Range =< 16#1000000 ->
Octs = eint_positive(Val2),
% [{bits,2,length(Octs)-1},{octets,Octs}];
Len = length(Octs),
[10,2,Len-1,20,Len,Octs];
Range =< 16#100000000 ->
Octs = eint_positive(Val2),
Len = length(Octs),
[10,2,Len-1,20,Len,Octs];
Range =< 16#10000000000 ->
Octs = eint_positive(Val2),
Len = length(Octs),
[10,3,Len-1,20,Len,Octs];
true ->
exit({not_supported,{integer_range,Range}})
end;
encode_constrained_number({_,_},Val) ->
exit({error,{asn1,{illegal_value,Val}}}).
decode_constrained_number(Buffer,VR={Lb,Ub}) ->
Range = Ub - Lb + 1,
decode_constrained_number(Buffer,VR,Range).
decode_constrained_number(Buffer,{Lb,_Ub},_Range,{bits,N}) ->
{Val,Remain} = getbits(Buffer,N),
{Val+Lb,Remain};
decode_constrained_number(Buffer,{Lb,_Ub},_Range,{octets,N}) ->
{Val,Remain} = getoctets(Buffer,N),
{Val+Lb,Remain}.
decode_constrained_number(Buffer,{Lb,_Ub},Range) ->
% Val2 = Val - Lb,
{Val,Remain} =
if
Range == 2 ->
getbits(Buffer,1);
Range =< 4 ->
getbits(Buffer,2);
Range =< 8 ->
getbits(Buffer,3);
Range =< 16 ->
getbits(Buffer,4);
Range =< 32 ->
getbits(Buffer,5);
Range =< 64 ->
getbits(Buffer,6);
Range =< 128 ->
getbits(Buffer,7);
Range =< 255 ->
getbits(Buffer,8);
Range =< 256 ->
getoctets(Buffer,1);
Range =< 65536 ->
getoctets(Buffer,2);
Range =< 16#1000000 ->
{Len,Bytes2} = decode_length(Buffer,{1,3}),
{Octs,Bytes3} = getoctets_as_list(Bytes2,Len),
{dec_pos_integer(Octs),Bytes3};
Range =< 16#100000000 ->
{Len,Bytes2} = decode_length(Buffer,{1,4}),
{Octs,Bytes3} = getoctets_as_list(Bytes2,Len),
{dec_pos_integer(Octs),Bytes3};
Range =< 16#10000000000 ->
{Len,Bytes2} = decode_length(Buffer,{1,5}),
{Octs,Bytes3} = getoctets_as_list(Bytes2,Len),
{dec_pos_integer(Octs),Bytes3};
true ->
exit({not_supported,{integer_range,Range}})
end,
{Val+Lb,Remain}.
%% X.691:10.8 Encoding of an unconstrained whole number
encode_unconstrained_number(Val) when Val >= 0 ->
Oct = eint(Val,[]),
Len = length(Oct),
if
Len < 128 ->
%{octets,[Len|Oct]}; % equiv with encode_length(undefined,Len) but faster
[20,Len+1,[Len|Oct]];
Len < 256 ->
% [encode_length(undefined,Len),20,Len,Oct];
[20,Len+2,<<2:2,Len:14>>,Oct];% equiv with encode_length(undefined,Len) but faster
true ->
% [encode_length(undefined,Len),{octets,Oct}]
[encode_length(undefined,Len),[21,<<Len:16>>,Oct]]
end;
encode_unconstrained_number(Val) -> % negative
Oct = enint(Val,[]),
Len = length(Oct),
if
Len < 128 ->
% {octets,[Len|Oct]}; % equiv with encode_length(undefined,Len) but faster
[20,Len+1,[Len|Oct]];% equiv with encode_length(undefined,Len) but faster
Len < 256 ->
% [encode_length(undefined,Len),20,Len,Oct];
[20,Len+2,<<2:2,Len:14>>,Oct];% equiv with encode_length(undefined,Len) but faster
true ->
%[encode_length(undefined,Len),{octets,Oct}]
[encode_length(undefined,Len),[21,<<Len:16>>,Oct]]
end.
%% used for positive Values which don't need a sign bit
%% returns a list
eint_positive(Val) ->
case eint(Val,[]) of
[0,B1|T] ->
[B1|T];
T ->
T
end.
eint(0, [B|Acc]) when B < 128 ->
[B|Acc];
eint(N, Acc) ->
eint(N bsr 8, [N band 16#ff| Acc]).
enint(-1, [B1|T]) when B1 > 127 ->
[B1|T];
enint(N, Acc) ->
enint(N bsr 8, [N band 16#ff|Acc]).
decode_unconstrained_number(Bytes) ->
{Len,Bytes2} = decode_length(Bytes,undefined),
{Ints,Bytes3} = getoctets_as_list(Bytes2,Len),
{dec_integer(Ints),Bytes3}.
dec_pos_integer(Ints) ->
decpint(Ints, 8 * (length(Ints) - 1)).
dec_integer(Ints) when hd(Ints) band 255 =< 127 -> %% Positive number
decpint(Ints, 8 * (length(Ints) - 1));
dec_integer(Ints) -> %% Negative
decnint(Ints, 8 * (length(Ints) - 1)).
decpint([Byte|Tail], Shift) ->
(Byte bsl Shift) bor decpint(Tail, Shift-8);
decpint([], _) -> 0.
decnint([Byte|Tail], Shift) ->
(-128 + (Byte band 127) bsl Shift) bor decpint(Tail, Shift-8).
% minimum_octets(Val) ->
% minimum_octets(Val,[]).
% minimum_octets(Val,Acc) when Val > 0 ->
% minimum_octets((Val bsr 8),[Val band 16#FF|Acc]);
% minimum_octets(0,Acc) ->
% Acc.
%% X.691:10.9 Encoding of a length determinant
%%encode_small_length(undefined,Len) -> % null means no UpperBound
%% encode_small_number(Len).
%% X.691:10.9.3.5
%% X.691:10.9.3.7
encode_length(undefined,Len) -> % un-constrained
if
Len < 128 ->
% {octets,[Len]};
[20,1,Len];
Len < 16384 ->
%{octets,<<2:2,Len:14>>};
[20,2,<<2:2,Len:14>>];
true -> % should be able to endode length >= 16384 i.e. fragmented length
exit({error,{asn1,{encode_length,{nyi,above_16k}}}})
end;
encode_length({0,'MAX'},Len) ->
encode_length(undefined,Len);
encode_length(Vr={Lb,Ub},Len) when Ub =< 65535 ,Lb >= 0 -> % constrained
encode_constrained_number(Vr,Len);
encode_length({Lb,_Ub},Len) when integer(Lb), Lb >= 0 -> % Ub > 65535
encode_length(undefined,Len);
encode_length({Vr={Lb,Ub},[]},Len) when Ub =< 65535 ,Lb >= 0,Len=<Ub ->
%% constrained extensible
% [{bits,1,0},encode_constrained_number(Vr,Len)];
[0,encode_constrained_number(Vr,Len)];
encode_length({{Lb,_},[]},Len) ->
[1,encode_semi_constrained_number(Lb,Len)];
encode_length(SingleValue,_Len) when integer(SingleValue) ->
[].
%% X.691 10.9.3.4 (only used for length of bitmap that prefixes extension
%% additions in a sequence or set
encode_small_length(Len) when Len =< 64 ->
%% [{bits,1,0},{bits,6,Len-1}];
% {bits,7,Len-1}; % the same as above but more efficient
[10,7,Len-1];
encode_small_length(Len) ->
% [{bits,1,1},encode_length(undefined,Len)].
[1,encode_length(undefined,Len)].
% decode_small_length({Used,<<_:Used,0:1,Num:6,_:((8-Used+1) rem 8),Rest/binary>>}) ->
% case Buffer of
% <<_:Used,0:1,Num:6,_:((8-Used+1) rem 8),Rest/binary>> ->
% {Num,
% case getbit(Buffer) of
% {0,Remain} ->
% {Bits,Remain2} = getbits(Remain,6),
% {Bits+1,Remain2};
% {1,Remain} ->
% decode_length(Remain,undefined)
% end.
decode_small_length(Buffer) ->
case getbit(Buffer) of
{0,Remain} ->
{Bits,Remain2} = getbits(Remain,6),
{Bits+1,Remain2};
{1,Remain} ->
decode_length(Remain,undefined)
end.
decode_length(Buffer) ->
decode_length(Buffer,undefined).
decode_length(Buffer,undefined) -> % un-constrained
{0,Buffer2} = align(Buffer),
case Buffer2 of
<<0:1,Oct:7,Rest/binary>> ->
{Oct,{0,Rest}};
<<2:2,Val:14,Rest/binary>> ->
{Val,{0,Rest}};
<<3:2,_Val:14,_Rest/binary>> ->
%% this case should be fixed
exit({error,{asn1,{decode_length,{nyi,above_16k}}}})
end;
%% {Bits,_} = getbits(Buffer2,2),
% case Bits of
% 2 ->
% {Val,Bytes3} = getoctets(Buffer2,2),
% {(Val band 16#3FFF),Bytes3};
% 3 ->
% exit({error,{asn1,{decode_length,{nyi,above_16k}}}});
% _ ->
% {Val,Bytes3} = getoctet(Buffer2),
% {Val band 16#7F,Bytes3}
% end;
decode_length(Buffer,{Lb,Ub}) when Ub =< 65535 ,Lb >= 0 -> % constrained
decode_constrained_number(Buffer,{Lb,Ub});
decode_length(_Buffer,{Lb,_Ub}) when integer(Lb), Lb >= 0 -> % Ub > 65535
exit({error,{asn1,{decode_length,{nyi,above_64K}}}});
decode_length(Buffer,{{Lb,Ub},[]}) ->
case getbit(Buffer) of
{0,Buffer2} ->
decode_length(Buffer2, {Lb,Ub})
end;
%When does this case occur with {_,_Lb,Ub} ??
% X.691:10.9.3.5
decode_length({Used,Bin},{_,_Lb,_Ub}) -> %when Len =< 127 -> % Unconstrained or large Ub NOTE! this case does not cover case when Ub > 65535
Unused = (8-Used) rem 8,
case Bin of
<<_:Used,0:1,Val:7,R:Unused,Rest/binary>> ->
{Val,{Used,<<R,Rest/binary>>}};
<<_:Used,_:Unused,2:2,Val:14,Rest/binary>> ->
{Val, {0,Rest}};
<<_:Used,_:Unused,3:2,_:14,_Rest/binary>> ->
exit({error,{asn1,{decode_length,{nyi,length_above_64K}}}})
end;
% decode_length(Buffer,{_,_Lb,Ub}) -> %when Len =< 127 -> % Unconstrained or large Ub
% case getbit(Buffer) of
% {0,Remain} ->
% getbits(Remain,7);
% {1,Remain} ->
% {Val,Remain2} = getoctets(Buffer,2),
% {Val band 2#0111111111111111, Remain2}
% end;
decode_length(Buffer,SingleValue) when integer(SingleValue) ->
{SingleValue,Buffer}.
% X.691:11
decode_boolean(Buffer) -> %when record(Buffer,buffer)
case getbit(Buffer) of
{1,Remain} -> {true,Remain};
{0,Remain} -> {false,Remain}
end.
%% ENUMERATED with extension marker
decode_enumerated(Buffer,C,{Ntup1,Ntup2}) when tuple(Ntup1), tuple(Ntup2) ->
{Ext,Buffer2} = getext(Buffer),
case Ext of
0 -> % not an extension value
{Val,Buffer3} = decode_integer(Buffer2,C),
case catch (element(Val+1,Ntup1)) of
NewVal when atom(NewVal) -> {NewVal,Buffer3};
_Error -> exit({error,{asn1,{decode_enumerated,{Val,[Ntup1,Ntup2]}}}})
end;
1 -> % this an extension value
{Val,Buffer3} = decode_small_number(Buffer2),
case catch (element(Val+1,Ntup2)) of
NewVal when atom(NewVal) -> {NewVal,Buffer3};
_ -> {{asn1_enum,Val},Buffer3}
end
end;
decode_enumerated(Buffer,C,NamedNumberTup) when tuple(NamedNumberTup) ->
{Val,Buffer2} = decode_integer(Buffer,C),
case catch (element(Val+1,NamedNumberTup)) of
NewVal when atom(NewVal) -> {NewVal,Buffer2};
_Error -> exit({error,{asn1,{decode_enumerated,{Val,NamedNumberTup}}}})
end.
%%===============================================================================
%%===============================================================================
%%===============================================================================
%% Bitstring value, ITU_T X.690 Chapter 8.5
%%===============================================================================
%%===============================================================================
%%===============================================================================
%%===============================================================================
%% encode bitstring value
%%===============================================================================
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% bitstring NamedBitList
%% Val can be of:
%% - [identifiers] where only named identifers are set to one,
%% the Constraint must then have some information of the
%% bitlength.
%% - [list of ones and zeroes] all bits
%% - integer value representing the bitlist
%% C is constraint Len, only valid when identifiers
%% when the value is a list of {Unused,BinBits}, where
%% Unused = integer(),
%% BinBits = binary().
encode_bit_string(C,Bin={Unused,BinBits},NamedBitList) when integer(Unused),
binary(BinBits) ->
encode_bin_bit_string(C,Bin,NamedBitList);
%% when the value is a list of named bits
encode_bit_string(C, LoNB=[FirstVal | _RestVal], NamedBitList) when atom(FirstVal) ->
ToSetPos = get_all_bitposes(LoNB, NamedBitList, []),
BitList = make_and_set_list(ToSetPos,0),
encode_bit_string(C,BitList,NamedBitList);% consider the constraint
encode_bit_string(C, BL=[{bit,_} | _RestVal], NamedBitList) ->
ToSetPos = get_all_bitposes(BL, NamedBitList, []),
BitList = make_and_set_list(ToSetPos,0),
encode_bit_string(C,BitList,NamedBitList);
%% when the value is a list of ones and zeroes
encode_bit_string(Int, BitListValue, _)
when list(BitListValue),integer(Int) ->
%% The type is constrained by a single value size constraint
[40,Int,length(BitListValue),BitListValue];
% encode_bit_string(C, BitListValue,NamedBitList)
% when list(BitListValue) ->
% [encode_bit_str_length(C,BitListValue),
% 2,45,BitListValue];
encode_bit_string(no, BitListValue,[])
when list(BitListValue) ->
[encode_length(undefined,length(BitListValue)),
2,BitListValue];
encode_bit_string(C, BitListValue,[])
when list(BitListValue) ->
[encode_length(C,length(BitListValue)),
2,BitListValue];
encode_bit_string(no, BitListValue,_NamedBitList)
when list(BitListValue) ->
%% this case with an unconstrained BIT STRING can be made more efficient
%% if the complete driver can take a special code so the length field
%% is encoded there.
NewBitLVal = lists:reverse(lists:dropwhile(fun(0)->true;(1)->false end,
lists:reverse(BitListValue))),
[encode_length(undefined,length(NewBitLVal)),
2,NewBitLVal];
encode_bit_string(C,BitListValue,_NamedBitList)
when list(BitListValue) ->% C = {_,'MAX'}
% NewBitLVal = lists:reverse(lists:dropwhile(fun(0)->true;(1)->false end,
% lists:reverse(BitListValue))),
NewBitLVal = bit_string_trailing_zeros(BitListValue,C),
[encode_length(C,length(NewBitLVal)),
2,NewBitLVal];
% encode_bit_string(C, BitListValue, NamedBitList) when list(BitListValue) ->
% BitListToBinary =
% %% fun that transforms a list of 1 and 0 to a tuple:
% %% {UnusedBitsInLastByte, Binary}
% fun([H|T],Acc,N,Fun) ->
% Fun(T,(Acc bsl 1)+H,N+1,Fun);
% ([],Acc,N,_) -> % length fits in one byte
% Unused = (8 - (N rem 8)) rem 8,
% % case N/8 of
% % _Len =< 255 ->
% % [30,Unused,(Unused+N)/8,<<Acc:N,0:Unused>>];
% % _Len ->
% % Len = (Unused+N)/8,
% % [31,Unused,<<Len:16>>,<<Acc:N,0:Unused>>]
% % end
% {Unused,<<Acc:N,0:Unused>>}
% end,
% UnusedAndBin =
% case NamedBitList of
% [] -> % dont remove trailing zeroes
% BitListToBinary(BitListValue,0,0,BitListToBinary);
% _ ->
% BitListToBinary(lists:reverse(
% lists:dropwhile(fun(0)->true;(1)->false end,
% lists:reverse(BitListValue))),
% 0,0,BitListToBinary)
% end,
% encode_bin_bit_string(C,UnusedAndBin,NamedBitList);
%% when the value is an integer
encode_bit_string(C, IntegerVal, NamedBitList) when integer(IntegerVal)->
BitList = int_to_bitlist(IntegerVal),
encode_bit_string(C,BitList,NamedBitList);
%% when the value is a tuple
encode_bit_string(C,{Name,Val}, NamedBitList) when atom(Name) ->
encode_bit_string(C,Val,NamedBitList).
bit_string_trailing_zeros(BitList,C) when integer(C) ->
bit_string_trailing_zeros1(BitList,C,C);
bit_string_trailing_zeros(BitList,{Lb,Ub}) when integer(Lb) ->
bit_string_trailing_zeros1(BitList,Lb,Ub);
bit_string_trailing_zeros(BitList,{{Lb,Ub},_}) when integer(Lb) ->
bit_string_trailing_zeros1(BitList,Lb,Ub);
bit_string_trailing_zeros(BitList,_) ->
BitList.
bit_string_trailing_zeros1(BitList,Lb,Ub) ->
case length(BitList) of
Lb -> BitList;
B when B<Lb -> BitList++lists:duplicate(Lb-B,0);
D -> F = fun(L,LB,LB,_,_)->lists:reverse(L);
([0|R],L1,LB,UB,Fun)->Fun(R,L1-1,LB,UB,Fun);
(L,L1,_,UB,_)when L1 =< UB -> lists:reverse(L);
(_,_L1,_,_,_) ->exit({error,{list_length_BIT_STRING,
BitList}}) end,
F(lists:reverse(BitList),D,Lb,Ub,F)
end.
%% encode_bin_bit_string/3, when value is a tuple of Unused and BinBits.
%% Unused = integer(),i.e. number unused bits in least sign. byte of
%% BinBits = binary().
encode_bin_bit_string(C,{_,BinBits},_NamedBitList)
when integer(C),C=<16 ->
[45,C,size(BinBits),BinBits];
encode_bin_bit_string(C,{_Unused,BinBits},_NamedBitList)
when integer(C) ->
[2,45,C,size(BinBits),BinBits];
encode_bin_bit_string(C,UnusedAndBin={_,_},NamedBitList) ->
% UnusedAndBin1 = {Unused1,Bin1} =
{Unused1,Bin1} =
%% removes all trailing bits if NamedBitList is not empty
remove_trailing_bin(NamedBitList,UnusedAndBin),
case C of
% case get_constraint(C,'SizeConstraint') of
% 0 ->
% []; % should be dont in compile time
% V when integer(V),V=<16 ->
% {Unused2,Bin2} = pad_list(V,UnusedAndBin1),
% <<BitVal:V,_:Unused2>> = Bin2,
% % {bits,V,BitVal};
% [10,V,BitVal];
% V when integer(V) ->
% %[align, pad_list(V, UnusedAndBin1)];
% {Unused2,Bin2} = pad_list(V, UnusedAndBin1),
% <<BitVal:V,_:Unused2>> = Bin2,
% [2,octets_unused_to_complete(Unused2,size(Bin2),Bin2)];
{Lb,Ub} when integer(Lb),integer(Ub) ->
% [encode_length({Lb,Ub},size(Bin1)*8 - Unused1),
% align,UnusedAndBin1];
Size=size(Bin1),
[encode_length({Lb,Ub},Size*8 - Unused1),
2,octets_unused_to_complete(Unused1,Size,Bin1)];
no ->
Size=size(Bin1),
[encode_length(undefined,Size*8 - Unused1),
2,octets_unused_to_complete(Unused1,Size,Bin1)];
Sc ->
Size=size(Bin1),
[encode_length(Sc,Size*8 - Unused1),
2,octets_unused_to_complete(Unused1,Size,Bin1)]
end.
remove_trailing_bin([], {Unused,Bin}) ->
{Unused,Bin};
remove_trailing_bin(NamedNumberList, {_Unused,Bin}) ->
Size = size(Bin)-1,
<<Bfront:Size/binary, LastByte:8>> = Bin,
%% clear the Unused bits to be sure
% LastByte1 = LastByte band (((1 bsl Unused) -1) bxor 255),% why this???
Unused1 = trailingZeroesInNibble(LastByte band 15),
Unused2 =
case Unused1 of
4 ->
4 + trailingZeroesInNibble(LastByte bsr 4);
_ -> Unused1
end,
case Unused2 of
8 ->
remove_trailing_bin(NamedNumberList,{0,Bfront});
_ ->
{Unused2,Bin}
end.
trailingZeroesInNibble(0) ->
4;
trailingZeroesInNibble(1) ->
0;
trailingZeroesInNibble(2) ->
1;
trailingZeroesInNibble(3) ->
0;
trailingZeroesInNibble(4) ->
2;
trailingZeroesInNibble(5) ->
0;
trailingZeroesInNibble(6) ->
1;
trailingZeroesInNibble(7) ->
0;
trailingZeroesInNibble(8) ->
3;
trailingZeroesInNibble(9) ->
0;
trailingZeroesInNibble(10) ->
1;
trailingZeroesInNibble(11) ->
0;
trailingZeroesInNibble(12) -> %#1100
2;
trailingZeroesInNibble(13) ->
0;
trailingZeroesInNibble(14) ->
1;
trailingZeroesInNibble(15) ->
0.
%%%%%%%%%%%%%%%
%% The result is presented as a list of named bits (if possible)
%% else as a tuple {Unused,Bits}. Unused is the number of unused
%% bits, least significant bits in the last byte of Bits. Bits is
%% the BIT STRING represented as a binary.
%%
decode_compact_bit_string(Buffer, C, NamedNumberList) ->
case get_constraint(C,'SizeConstraint') of
0 -> % fixed length
{{8,0},Buffer};
V when integer(V),V=<16 -> %fixed length 16 bits or less
compact_bit_string(Buffer,V,NamedNumberList);
V when integer(V),V=<65536 -> %fixed length > 16 bits
Bytes2 = align(Buffer),
compact_bit_string(Bytes2,V,NamedNumberList);
V when integer(V) -> % V > 65536 => fragmented value
{Bin,Buffer2} = decode_fragmented_bits(Buffer,V),
case Buffer2 of
{0,_} -> {{0,Bin},Buffer2};
{U,_} -> {{8-U,Bin},Buffer2}
end;
{Lb,Ub} when integer(Lb),integer(Ub) ->
%% This case may demand decoding of fragmented length/value
{Len,Bytes2} = decode_length(Buffer,{Lb,Ub}),
Bytes3 = align(Bytes2),
compact_bit_string(Bytes3,Len,NamedNumberList);
no ->
%% This case may demand decoding of fragmented length/value
{Len,Bytes2} = decode_length(Buffer,undefined),
Bytes3 = align(Bytes2),
compact_bit_string(Bytes3,Len,NamedNumberList);
Sc ->
{Len,Bytes2} = decode_length(Buffer,Sc),
Bytes3 = align(Bytes2),
compact_bit_string(Bytes3,Len,NamedNumberList)
end.
%%%%%%%%%%%%%%%
%% The result is presented as a list of named bits (if possible)
%% else as a list of 0 and 1.
%%
decode_bit_string(Buffer, C, NamedNumberList) ->
case get_constraint(C,'SizeConstraint') of
{Lb,Ub} when integer(Lb),integer(Ub) ->
{Len,Bytes2} = decode_length(Buffer,{Lb,Ub}),
Bytes3 = align(Bytes2),
bit_list_or_named(Bytes3,Len,NamedNumberList);
no ->
{Len,Bytes2} = decode_length(Buffer,undefined),
Bytes3 = align(Bytes2),
bit_list_or_named(Bytes3,Len,NamedNumberList);
0 -> % fixed length
{[],Buffer}; % nothing to encode
V when integer(V),V=<16 -> % fixed length 16 bits or less
bit_list_or_named(Buffer,V,NamedNumberList);
V when integer(V),V=<65536 ->
Bytes2 = align(Buffer),
bit_list_or_named(Bytes2,V,NamedNumberList);
V when integer(V) ->
Bytes2 = align(Buffer),
{BinBits,_Bytes3} = decode_fragmented_bits(Bytes2,V),
bit_list_or_named(BinBits,V,NamedNumberList);
Sc -> % extension marker
{Len,Bytes2} = decode_length(Buffer,Sc),
Bytes3 = align(Bytes2),
bit_list_or_named(Bytes3,Len,NamedNumberList)
end.
%% if no named bits are declared we will return a
%% {Unused,Bits}. Unused = integer(),
%% Bits = binary().
compact_bit_string(Buffer,Len,[]) ->
getbits_as_binary(Len,Buffer); % {{Unused,BinBits},NewBuffer}
compact_bit_string(Buffer,Len,NamedNumberList) ->
bit_list_or_named(Buffer,Len,NamedNumberList).
%% if no named bits are declared we will return a
%% BitList = [0 | 1]
bit_list_or_named(Buffer,Len,[]) ->
getbits_as_list(Len,Buffer);
%% if there are named bits declared we will return a named
%% BitList where the names are atoms and unnamed bits represented
%% as {bit,Pos}
%% BitList = [atom() | {bit,Pos}]
%% Pos = integer()
bit_list_or_named(Buffer,Len,NamedNumberList) ->
{BitList,Rest} = getbits_as_list(Len,Buffer),
{bit_list_or_named1(0,BitList,NamedNumberList,[]), Rest}.
bit_list_or_named1(Pos,[0|Bt],Names,Acc) ->
bit_list_or_named1(Pos+1,Bt,Names,Acc);
bit_list_or_named1(Pos,[1|Bt],Names,Acc) ->
case lists:keysearch(Pos,2,Names) of
{value,{Name,_}} ->
bit_list_or_named1(Pos+1,Bt,Names,[Name|Acc]);
_ ->
bit_list_or_named1(Pos+1,Bt,Names,[{bit,Pos}|Acc])
end;
bit_list_or_named1(_Pos,[],_Names,Acc) ->
lists:reverse(Acc).
%%%%%%%%%%%%%%%
%%
int_to_bitlist(Int) when integer(Int), Int > 0 ->
[Int band 1 | int_to_bitlist(Int bsr 1)];
int_to_bitlist(0) ->
[].
%%%%%%%%%%%%%%%%%%
%% get_all_bitposes([list of named bits to set], named_bit_db, []) ->
%% [sorted_list_of_bitpositions_to_set]
get_all_bitposes([{bit,ValPos}|Rest], NamedBitList, Ack) ->
get_all_bitposes(Rest, NamedBitList, [ValPos | Ack ]);
get_all_bitposes([Val | Rest], NamedBitList, Ack) ->
case lists:keysearch(Val, 1, NamedBitList) of
{value, {_ValName, ValPos}} ->
get_all_bitposes(Rest, NamedBitList, [ValPos | Ack]);
_ ->
exit({error,{asn1, {bitstring_namedbit, Val}}})
end;
get_all_bitposes([], _NamedBitList, Ack) ->
lists:sort(Ack).
%%%%%%%%%%%%%%%%%%
%% make_and_set_list([list of positions to set to 1])->
%% returns list with all in SetPos set.
%% in positioning in list the first element is 0, the second 1 etc.., but
%%
make_and_set_list([XPos|SetPos], XPos) ->
[1 | make_and_set_list(SetPos, XPos + 1)];
make_and_set_list([Pos|SetPos], XPos) ->
[0 | make_and_set_list([Pos | SetPos], XPos + 1)];
make_and_set_list([], _) ->
[].
%%%%%%%%%%%%%%%%%
%% pad_list(N,BitList) -> PaddedList
%% returns a padded (with trailing {bit,0} elements) list of length N
%% if Bitlist contains more than N significant bits set an exit asn1_error
%% is generated
% pad_list(N,In={Unused,Bin}) ->
% pad_list(N, size(Bin)*8 - Unused, In).
% pad_list(N,Size,In={Unused,Bin}) when N < Size ->
% exit({error,{asn1,{range_error,{bit_string,In}}}});
% pad_list(N,Size,{Unused,Bin}) when N > Size, Unused > 0 ->
% pad_list(N,Size+1,{Unused-1,Bin});
% pad_list(N,Size,{Unused,Bin}) when N > Size ->
% pad_list(N,Size+1,{7,<<Bin/binary,0>>});
% pad_list(N,N,In={Unused,Bin}) ->
% In.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% X.691:16
%% encode_octet_string(Constraint,ExtensionMarker,Val)
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
encode_octet_string(C,Val) ->
encode_octet_string(C,false,Val).
encode_octet_string(C,Bool,{_Name,Val}) ->
encode_octet_string(C,Bool,Val);
encode_octet_string(_C,true,_Val) ->
exit({error,{asn1,{'not_supported',extensionmarker}}});
encode_octet_string(SZ={_,_},false,Val) ->
% [encode_length(SZ,length(Val)),align,
% {octets,Val}];
Len = length(Val),
[encode_length(SZ,Len),2,
octets_to_complete(Len,Val)];
encode_octet_string(SZ,false,Val) when list(SZ) ->
Len = length(Val),
[encode_length({hd(SZ),lists:max(SZ)},Len),2,
octets_to_complete(Len,Val)];
encode_octet_string(no,false,Val) ->
Len = length(Val),
[encode_length(undefined,Len),2,
octets_to_complete(Len,Val)];
encode_octet_string(C,_,_) ->
exit({error,{not_implemented,C}}).
decode_octet_string(Bytes,Range) ->
decode_octet_string(Bytes,Range,false).
decode_octet_string(Bytes,1,false) ->
{B1,Bytes2} = getbits(Bytes,8),
{[B1],Bytes2};
decode_octet_string(Bytes,2,false) ->
{Bs,Bytes2}= getbits(Bytes,16),
{binary_to_list(<<Bs:16>>),Bytes2};
decode_octet_string(Bytes,Sv,false) when integer(Sv),Sv=<65535 ->
Bytes2 = align(Bytes),
getoctets_as_list(Bytes2,Sv);
decode_octet_string(Bytes,Sv,false) when integer(Sv) ->
Bytes2 = align(Bytes),
decode_fragmented_octets(Bytes2,Sv);
decode_octet_string(Bytes,{Lb,Ub},false) ->
{Len,Bytes2} = decode_length(Bytes,{Lb,Ub}),
Bytes3 = align(Bytes2),
getoctets_as_list(Bytes3,Len);
decode_octet_string(Bytes,Sv,false) when list(Sv) ->
{Len,Bytes2} = decode_length(Bytes,{hd(Sv),lists:max(Sv)}),
Bytes3 = align(Bytes2),
getoctets_as_list(Bytes3,Len);
decode_octet_string(Bytes,no,false) ->
{Len,Bytes2} = decode_length(Bytes,undefined),
Bytes3 = align(Bytes2),
getoctets_as_list(Bytes3,Len).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Restricted char string types
%% (NumericString, PrintableString,VisibleString,IA5String,BMPString,UniversalString)
%% X.691:26 and X.680:34-36
%%encode_restricted_string(aligned,'BMPString',Constraints,Extension,Val)
encode_restricted_string(aligned,{Name,Val}) when atom(Name) ->
encode_restricted_string(aligned,Val);
encode_restricted_string(aligned,Val) when list(Val)->
Len = length(Val),
% [encode_length(undefined,length(Val)),{octets,Val}].
[encode_length(undefined,Len),octets_to_complete(Len,Val)].
encode_known_multiplier_string(StringType,SizeC,NumBits,CharOutTab,{Name,Val}) when atom(Name) ->
encode_known_multiplier_string(StringType,SizeC,NumBits,CharOutTab,Val);
encode_known_multiplier_string(StringType,SizeC,NumBits,CharOutTab,Val) ->
Result = chars_encode2(Val,NumBits,CharOutTab),
case SizeC of
Ub when integer(Ub), Ub*NumBits =< 16 ->
case {StringType,Result} of
{'BMPString',{octets,Ol}} -> %% this case cannot happen !!??
[{bits,8,Oct}||Oct <- Ol];
_ ->
Result
end;
Ub when integer(Ub),Ub =<65535 -> % fixed length
%% [align,Result];
[2,Result];
{Ub,Lb} ->
% [encode_length({Ub,Lb},length(Val)),align,Result];
[encode_length({Ub,Lb},length(Val)),2,Result];
no ->
% [encode_length(undefined,length(Val)),align,Result]
[encode_length(undefined,length(Val)),2,Result]
end.
decode_restricted_string(Bytes,aligned) ->
{Len,Bytes2} = decode_length(Bytes,undefined),
getoctets_as_list(Bytes2,Len).
decode_known_multiplier_string(StringType,SizeC,NumBits,CharInTab,Bytes) ->
case SizeC of
Ub when integer(Ub), Ub*NumBits =< 16 ->
chars_decode(Bytes,NumBits,StringType,CharInTab,Ub);
Ub when integer(Ub),Ub =<65535 -> % fixed length
Bytes1 = align(Bytes),
chars_decode(Bytes1,NumBits,StringType,CharInTab,Ub);
Vl when list(Vl) ->
{Len,Bytes1} = decode_length(Bytes,{hd(Vl),lists:max(Vl)}),
Bytes2 = align(Bytes1),
chars_decode(Bytes2,NumBits,StringType,CharInTab,Len);
no ->
{Len,Bytes1} = decode_length(Bytes,undefined),
Bytes2 = align(Bytes1),
chars_decode(Bytes2,NumBits,StringType,CharInTab,Len);
{Lb,Ub}->
{Len,Bytes1} = decode_length(Bytes,{Lb,Ub}),
Bytes2 = align(Bytes1),
chars_decode(Bytes2,NumBits,StringType,CharInTab,Len)
end.
encode_GeneralString(_C,Val) ->
encode_restricted_string(aligned,Val).
decode_GeneralString(Bytes,_C) ->
decode_restricted_string(Bytes,aligned).
encode_GraphicString(_C,Val) ->
encode_restricted_string(aligned,Val).
decode_GraphicString(Bytes,_C) ->
decode_restricted_string(Bytes,aligned).
encode_ObjectDescriptor(_C,Val) ->
encode_restricted_string(aligned,Val).
decode_ObjectDescriptor(Bytes) ->
decode_restricted_string(Bytes,aligned).
encode_TeletexString(_C,Val) -> % equivalent with T61String
encode_restricted_string(aligned,Val).
decode_TeletexString(Bytes,_C) ->
decode_restricted_string(Bytes,aligned).
encode_VideotexString(_C,Val) ->
encode_restricted_string(aligned,Val).
decode_VideotexString(Bytes,_C) ->
decode_restricted_string(Bytes,aligned).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% getBMPChars(Bytes,Len) ->{BMPcharList,RemainingBytes}
%%
getBMPChars(Bytes,1) ->
{O1,Bytes2} = getbits(Bytes,8),
{O2,Bytes3} = getbits(Bytes2,8),
if
O1 == 0 ->
{[O2],Bytes3};
true ->
{[{0,0,O1,O2}],Bytes3}
end;
getBMPChars(Bytes,Len) ->
getBMPChars(Bytes,Len,[]).
getBMPChars(Bytes,0,Acc) ->
{lists:reverse(Acc),Bytes};
getBMPChars(Bytes,Len,Acc) ->
{Octs,Bytes1} = getoctets_as_list(Bytes,2),
case Octs of
[0,O2] ->
getBMPChars(Bytes1,Len-1,[O2|Acc]);
[O1,O2]->
getBMPChars(Bytes1,Len-1,[{0,0,O1,O2}|Acc])
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% chars_encode(C,StringType,Value) -> ValueList
%%
%% encodes chars according to the per rules taking the constraint PermittedAlphabet
%% into account.
%% This function does only encode the value part and NOT the length
% chars_encode(C,StringType,Value) ->
% case {StringType,get_constraint(C,'PermittedAlphabet')} of
% {'UniversalString',{_,Sv}} ->
% exit({error,{asn1,{'not implemented',"UniversalString with PermittedAlphabet constraint"}}});
% {'BMPString',{_,Sv}} ->
% exit({error,{asn1,{'not implemented',"BMPString with PermittedAlphabet constraint"}}});
% _ ->
% {NumBits,CharOutTab} = {get_NumBits(C,StringType),get_CharOutTab(C,StringType)},
% chars_encode2(Value,NumBits,CharOutTab)
% end.
chars_encode2([H|T],NumBits,T1={Min,Max,notab}) when H =< Max, H >= Min ->
% [[10,NumBits,H-Min]|chars_encode2(T,NumBits,T1)];
[pre_complete_bits(NumBits,H-Min)|chars_encode2(T,NumBits,T1)];
chars_encode2([H|T],NumBits,T1={Min,Max,Tab}) when H =< Max, H >= Min ->
% [[10,NumBits,element(H-Min+1,Tab)]|chars_encode2(T,NumBits,T1)];
[pre_complete_bits(NumBits,exit_if_false(H,element(H-Min+1,Tab)))|
chars_encode2(T,NumBits,T1)];
chars_encode2([{A,B,C,D}|T],NumBits,T1={Min,_Max,notab}) ->
%% no value range check here (ought to be, but very expensive)
% [{bits,NumBits,(A*B*C*D)-Min}|chars_encode2(T,NumBits,{Min,Max,notab})];
% [[10,NumBits,((((((A bsl 8)+B) bsl 8)+C) bsl 8)+D)-Min]|chars_encode2(T,NumBits,T1)];
[pre_complete_bits(NumBits,
((((((A bsl 8)+B) bsl 8)+C) bsl 8)+D)-Min)|
chars_encode2(T,NumBits,T1)];
chars_encode2([H={A,B,C,D}|T],NumBits,{Min,Max,Tab}) ->
%% no value range check here (ought to be, but very expensive)
[pre_complete_bits(NumBits,exit_if_false(H,element(((((((A bsl 8)+B) bsl 8)+C) bsl 8)+D)-Min,Tab)))|chars_encode2(T,NumBits,{Min,Max,notab})];
chars_encode2([H|_T],_NumBits,{_Min,_Max,_Tab}) ->
exit({error,{asn1,{illegal_char_value,H}}});
chars_encode2([],_,_) ->
[].
exit_if_false(V,false)->
exit({error,{asn1,{"illegal value according to Permitted alphabet constraint",V}}});
exit_if_false(_,V) ->V.
pre_complete_bits(NumBits,Val) when NumBits =< 8 ->
[10,NumBits,Val];
pre_complete_bits(NumBits,Val) when NumBits =< 16 ->
[10,NumBits-8,Val bsr 8,10,8,(Val band 255)];
pre_complete_bits(NumBits,Val) when NumBits =< 2040 -> % 255 * 8
% LBUsed = NumBits rem 8,
% {Unused,Len} = case (8 - LBUsed) of
% 8 -> {0,NumBits div 8};
% U -> {U,(NumBits div 8) + 1}
% end,
% NewVal = Val bsr LBUsed,
% [30,Unused,Len,<<NewVal:Len/unit:8,Val:LBUsed,0:Unused>>].
Unused = (8 - (NumBits rem 8)) rem 8,
Len = NumBits + Unused,
[30,Unused,Len div 8,<<(Val bsl Unused):Len>>].
% get_NumBits(C,StringType) ->
% case get_constraint(C,'PermittedAlphabet') of
% {'SingleValue',Sv} ->
% charbits(length(Sv),aligned);
% no ->
% case StringType of
% 'IA5String' ->
% charbits(128,aligned); % 16#00..16#7F
% 'VisibleString' ->
% charbits(95,aligned); % 16#20..16#7E
% 'PrintableString' ->
% charbits(74,aligned); % [$\s,$',$(,$),$+,$,,$-,$.,$/,"0123456789",$:,$=,$?,$A..$Z,$a..$z
% 'NumericString' ->
% charbits(11,aligned); % $ ,"0123456789"
% 'UniversalString' ->
% 32;
% 'BMPString' ->
% 16
% end
% end.
%%Maybe used later
%%get_MaxChar(C,StringType) ->
%% case get_constraint(C,'PermittedAlphabet') of
%% {'SingleValue',Sv} ->
%% lists:nth(length(Sv),Sv);
%% no ->
%% case StringType of
%% 'IA5String' ->
%% 16#7F; % 16#00..16#7F
%% 'VisibleString' ->
%% 16#7E; % 16#20..16#7E
%% 'PrintableString' ->
%% $z; % [$\s,$',$(,$),$+,$,,$-,$.,$/,"0123456789",$:,$=,$?,$A..$Z,$a..$z
%% 'NumericString' ->
%% $9; % $ ,"0123456789"
%% 'UniversalString' ->
%% 16#ffffffff;
%% 'BMPString' ->
%% 16#ffff
%% end
%% end.
%%Maybe used later
%%get_MinChar(C,StringType) ->
%% case get_constraint(C,'PermittedAlphabet') of
%% {'SingleValue',Sv} ->
%% hd(Sv);
%% no ->
%% case StringType of
%% 'IA5String' ->
%% 16#00; % 16#00..16#7F
%% 'VisibleString' ->
%% 16#20; % 16#20..16#7E
%% 'PrintableString' ->
%% $\s; % [$\s,$',$(,$),$+,$,,$-,$.,$/,"0123456789",$:,$=,$?,$A..$Z,$a..$z
%% 'NumericString' ->
%% $\s; % $ ,"0123456789"
%% 'UniversalString' ->
%% 16#00;
%% 'BMPString' ->
%% 16#00
%% end
%% end.
% get_CharOutTab(C,StringType) ->
% get_CharTab(C,StringType,out).
% get_CharInTab(C,StringType) ->
% get_CharTab(C,StringType,in).
% get_CharTab(C,StringType,InOut) ->
% case get_constraint(C,'PermittedAlphabet') of
% {'SingleValue',Sv} ->
% get_CharTab2(C,StringType,hd(Sv),lists:max(Sv),Sv,InOut);
% no ->
% case StringType of
% 'IA5String' ->
% {0,16#7F,notab};
% 'VisibleString' ->
% get_CharTab2(C,StringType,16#20,16#7F,notab,InOut);
% 'PrintableString' ->
% Chars = lists:sort(
% " '()+,-./0123456789:=?ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz"),
% get_CharTab2(C,StringType,hd(Chars),lists:max(Chars),Chars,InOut);
% 'NumericString' ->
% get_CharTab2(C,StringType,16#20,$9," 0123456789",InOut);
% 'UniversalString' ->
% {0,16#FFFFFFFF,notab};
% 'BMPString' ->
% {0,16#FFFF,notab}
% end
% end.
% get_CharTab2(C,StringType,Min,Max,Chars,InOut) ->
% BitValMax = (1 bsl get_NumBits(C,StringType))-1,
% if
% Max =< BitValMax ->
% {0,Max,notab};
% true ->
% case InOut of
% out ->
% {Min,Max,create_char_tab(Min,Chars)};
% in ->
% {Min,Max,list_to_tuple(Chars)}
% end
% end.
% create_char_tab(Min,L) ->
% list_to_tuple(create_char_tab(Min,L,0)).
% create_char_tab(Min,[Min|T],V) ->
% [V|create_char_tab(Min+1,T,V+1)];
% create_char_tab(_Min,[],_V) ->
% [];
% create_char_tab(Min,L,V) ->
% [false|create_char_tab(Min+1,L,V)].
%% This very inefficient and should be moved to compiletime
% charbits(NumOfChars,aligned) ->
% case charbits(NumOfChars) of
% 1 -> 1;
% 2 -> 2;
% B when B =< 4 -> 4;
% B when B =< 8 -> 8;
% B when B =< 16 -> 16;
% B when B =< 32 -> 32
% end.
% charbits(NumOfChars) when NumOfChars =< 2 -> 1;
% charbits(NumOfChars) when NumOfChars =< 4 -> 2;
% charbits(NumOfChars) when NumOfChars =< 8 -> 3;
% charbits(NumOfChars) when NumOfChars =< 16 -> 4;
% charbits(NumOfChars) when NumOfChars =< 32 -> 5;
% charbits(NumOfChars) when NumOfChars =< 64 -> 6;
% charbits(NumOfChars) when NumOfChars =< 128 -> 7;
% charbits(NumOfChars) when NumOfChars =< 256 -> 8;
% charbits(NumOfChars) when NumOfChars =< 512 -> 9;
% charbits(NumOfChars) when NumOfChars =< 1024 -> 10;
% charbits(NumOfChars) when NumOfChars =< 2048 -> 11;
% charbits(NumOfChars) when NumOfChars =< 4096 -> 12;
% charbits(NumOfChars) when NumOfChars =< 8192 -> 13;
% charbits(NumOfChars) when NumOfChars =< 16384 -> 14;
% charbits(NumOfChars) when NumOfChars =< 32768 -> 15;
% charbits(NumOfChars) when NumOfChars =< 65536 -> 16;
% charbits(NumOfChars) when integer(NumOfChars) ->
% 16 + charbits1(NumOfChars bsr 16).
% charbits1(0) ->
% 0;
% charbits1(NumOfChars) ->
% 1 + charbits1(NumOfChars bsr 1).
chars_decode(Bytes,_,'BMPString',_,Len) ->
getBMPChars(Bytes,Len);
chars_decode(Bytes,NumBits,_StringType,CharInTab,Len) ->
chars_decode2(Bytes,CharInTab,NumBits,Len).
chars_decode2(Bytes,CharInTab,NumBits,Len) ->
chars_decode2(Bytes,CharInTab,NumBits,Len,[]).
chars_decode2(Bytes,_CharInTab,_NumBits,0,Acc) ->
{lists:reverse(Acc),Bytes};
chars_decode2(Bytes,{Min,Max,notab},NumBits,Len,Acc) when NumBits > 8 ->
{Char,Bytes2} = getbits(Bytes,NumBits),
Result =
if
Char < 256 -> Char;
true ->
list_to_tuple(binary_to_list(<<Char:32>>))
end,
chars_decode2(Bytes2,{Min,Max,notab},NumBits,Len -1,[Result|Acc]);
chars_decode2(Bytes,{Min,Max,notab},NumBits,Len,Acc) ->
{Char,Bytes2} = getbits(Bytes,NumBits),
chars_decode2(Bytes2,{Min,Max,notab},NumBits,Len -1,[Char+Min|Acc]);
%% BMPString and UniversalString with PermittedAlphabet is currently not supported
chars_decode2(Bytes,{Min,Max,CharInTab},NumBits,Len,Acc) ->
{Char,Bytes2} = getbits(Bytes,NumBits),
chars_decode2(Bytes2,{Min,Max,CharInTab},NumBits,Len -1,[element(Char+1,CharInTab)|Acc]).
% X.691:17
encode_null(_Val) -> []; % encodes to nothing
encode_null({Name,Val}) when atom(Name) ->
encode_null(Val).
decode_null(Bytes) ->
{'NULL',Bytes}.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% encode_object_identifier(Val) -> CompleteList
%% encode_object_identifier({Name,Val}) -> CompleteList
%% Val -> {Int1,Int2,...,IntN} % N >= 2
%% Name -> atom()
%% Int1 -> integer(0..2)
%% Int2 -> integer(0..39) when Int1 (0..1) else integer()
%% Int3-N -> integer()
%% CompleteList -> [{bits,8,Val}|{octets,Ol}|align|...]
%%
encode_object_identifier({Name,Val}) when atom(Name) ->
encode_object_identifier(Val);
encode_object_identifier(Val) ->
OctetList = e_object_identifier(Val),
Octets = list_to_binary(OctetList), % performs a flatten at the same time
% [{debug,object_identifier},encode_length(undefined,size(Octets)),{octets,Octets}].
[encode_length(undefined,size(Octets)),
octets_to_complete(size(Octets),Octets)].
%% This code is copied from asn1_encode.erl (BER) and corrected and modified
e_object_identifier({'OBJECT IDENTIFIER',V}) ->
e_object_identifier(V);
e_object_identifier({Cname,V}) when atom(Cname),tuple(V) ->
e_object_identifier(tuple_to_list(V));
e_object_identifier({Cname,V}) when atom(Cname),list(V) ->
e_object_identifier(V);
e_object_identifier(V) when tuple(V) ->
e_object_identifier(tuple_to_list(V));
%% E1 = 0|1|2 and (E2 < 40 when E1 = 0|1)
e_object_identifier([E1,E2|Tail]) when E1 >= 0, E1 < 2, E2 < 40 ; E1==2 ->
Head = 40*E1 + E2, % weird
e_object_elements([Head|Tail],[]);
e_object_identifier(Oid=[_,_|_Tail]) ->
exit({error,{asn1,{'illegal_value',Oid}}}).
e_object_elements([],Acc) ->
lists:reverse(Acc);
e_object_elements([H|T],Acc) ->
e_object_elements(T,[e_object_element(H)|Acc]).
e_object_element(Num) when Num < 128 ->
Num;
%% must be changed to handle more than 2 octets
e_object_element(Num) -> %% when Num < ???
Left = ((Num band 2#11111110000000) bsr 7) bor 2#10000000,
Right = Num band 2#1111111 ,
[Left,Right].
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% decode_object_identifier(Bytes) -> {ObjId,RemainingBytes}
%% ObjId -> {integer(),integer(),...} % at least 2 integers
%% RemainingBytes -> [integer()] when integer() (0..255)
decode_object_identifier(Bytes) ->
{Len,Bytes2} = decode_length(Bytes,undefined),
{Octs,Bytes3} = getoctets_as_list(Bytes2,Len),
[First|Rest] = dec_subidentifiers(Octs,0,[]),
Idlist = if
First < 40 ->
[0,First|Rest];
First < 80 ->
[1,First - 40|Rest];
true ->
[2,First - 80|Rest]
end,
{list_to_tuple(Idlist),Bytes3}.
dec_subidentifiers([H|T],Av,Al) when H >=16#80 ->
dec_subidentifiers(T,(Av bsl 7) + (H band 16#7F),Al);
dec_subidentifiers([H|T],Av,Al) ->
dec_subidentifiers(T,0,[(Av bsl 7) + H |Al]);
dec_subidentifiers([],_Av,Al) ->
lists:reverse(Al).
get_constraint([{Key,V}],Key) ->
V;
get_constraint([],_) ->
no;
get_constraint(C,Key) ->
case lists:keysearch(Key,1,C) of
false ->
no;
{value,{_,V}} ->
V
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% complete(InList) -> ByteList
%% Takes a coded list with bits and bytes and converts it to a list of bytes
%% Should be applied as the last step at encode of a complete ASN.1 type
%%
-ifdef(nodriver).
complete(L) ->
case complete1(L) of
{[],[]} ->
<<0>>;
{Acc,[]} ->
Acc;
{Acc,Bacc} ->
[Acc|complete_bytes(Bacc)]
end.
% this function builds the ugly form of lists [E1|E2] to avoid having to reverse it at the end.
% this is done because it is efficient and that the result always will be sent on a port or
% converted by means of list_to_binary/1
complete1(InList) when list(InList) ->
complete1(InList,[],[]);
complete1(InList) ->
complete1([InList],[],[]).
complete1([],Acc,Bacc) ->
{Acc,Bacc};
complete1([H|T],Acc,Bacc) when list(H) ->
{NewH,NewBacc} = complete1(H,Acc,Bacc),
complete1(T,NewH,NewBacc);
complete1([{octets,Bin}|T],Acc,[]) ->
complete1(T,[Acc|Bin],[]);
complete1([{octets,Bin}|T],Acc,Bacc) ->
complete1(T,[Acc|[complete_bytes(Bacc),Bin]],[]);
complete1([{debug,_}|T], Acc,Bacc) ->
complete1(T,Acc,Bacc);
complete1([{bits,N,Val}|T],Acc,Bacc) ->
complete1(T,Acc,complete_update_byte(Bacc,Val,N));
complete1([{bit,Val}|T],Acc,Bacc) ->
complete1(T,Acc,complete_update_byte(Bacc,Val,1));
complete1([align|T],Acc,[]) ->
complete1(T,Acc,[]);
complete1([align|T],Acc,Bacc) ->
complete1(T,[Acc|complete_bytes(Bacc)],[]);
complete1([{0,Bin}|T],Acc,[]) when binary(Bin) ->
complete1(T,[Acc|Bin],[]);
complete1([{Unused,Bin}|T],Acc,[]) when integer(Unused),binary(Bin) ->
Size = size(Bin)-1,
<<Bs:Size/binary,B>> = Bin,
NumBits = 8-Unused,
complete1(T,[Acc|Bs],[[B bsr Unused]|NumBits]);
complete1([{Unused,Bin}|T],Acc,Bacc) when integer(Unused),binary(Bin) ->
Size = size(Bin)-1,
<<Bs:Size/binary,B>> = Bin,
NumBits = 8 - Unused,
Bf = complete_bytes(Bacc),
complete1(T,[Acc|[Bf,Bs]],[[B bsr Unused]|NumBits]).
complete_update_byte([],Val,Len) ->
complete_update_byte([[0]|0],Val,Len);
complete_update_byte([[Byte|Bacc]|NumBits],Val,Len) when NumBits + Len == 8 ->
[[0,((Byte bsl Len) + Val) band 255|Bacc]|0];
complete_update_byte([[Byte|Bacc]|NumBits],Val,Len) when NumBits + Len > 8 ->
Rem = 8 - NumBits,
Rest = Len - Rem,
complete_update_byte([[0,((Byte bsl Rem) + (Val bsr Rest)) band 255 |Bacc]|0],Val,Rest);
complete_update_byte([[Byte|Bacc]|NumBits],Val,Len) ->
[[((Byte bsl Len) + Val) band 255|Bacc]|NumBits+Len].
complete_bytes([[Byte|Bacc]|0]) ->
lists:reverse(Bacc);
complete_bytes([[Byte|Bacc]|NumBytes]) ->
lists:reverse([(Byte bsl (8-NumBytes)) band 255|Bacc]);
complete_bytes([]) ->
[].
-else.
complete(L) ->
case catch port_control(drv_complete,1,L) of
Bin when binary(Bin) ->
Bin;
List when list(List) -> handle_error(List,L);
{'EXIT',{badarg,Reason}} ->
asn1rt_driver_handler:load_driver(),
receive
driver_ready ->
case catch port_control(drv_complete,1,L) of
Bin2 when binary(Bin2) -> Bin2;
List when list(List) -> handle_error(List,L);
Error -> exit(Error)
end;
{error,Error} -> % error when loading driver
%% the driver could not be loaded
exit(Error);
Error={port_error,Reason} ->
exit(Error)
end;
{'EXIT',Reason} ->
exit(Reason)
end.
handle_error([],_)->
exit({error,{"memory allocation problem"}});
handle_error("1",L) -> % error in complete in driver
exit({error,{asn1_error,L}});
handle_error(ErrL,L) ->
exit({error,{unknown_error,ErrL,L}}).
-endif.
octets_to_complete(Len,Val) when Len < 256 ->
[20,Len,Val];
octets_to_complete(Len,Val) ->
[21,<<Len:16>>,Val].
octets_unused_to_complete(Unused,Len,Val) when Len < 256 ->
[30,Unused,Len,Val];
octets_unused_to_complete(Unused,Len,Val) ->
[31,Unused,<<Len:16>>,Val].