%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2012-2013. 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_imm).
-export([per_dec_raw_bitstring/2,
per_dec_boolean/0,per_dec_enumerated/2,per_dec_enumerated/3,
per_dec_extension_map/1,
per_dec_integer/2,per_dec_k_m_string/3,
per_dec_length/3,per_dec_named_integer/3,
per_dec_octet_string/2,per_dec_open_type/1,per_dec_real/1,
per_dec_restricted_string/1]).
-export([per_dec_constrained/3,per_dec_normally_small_number/1]).
-export([per_enc_bit_string/4,per_enc_legacy_bit_string/4,
per_enc_boolean/2,
per_enc_choice/3,per_enc_enumerated/3,
per_enc_integer/3,per_enc_integer/4,
per_enc_null/2,
per_enc_k_m_string/4,per_enc_octet_string/3,
per_enc_legacy_octet_string/3,
per_enc_open_type/2,
per_enc_restricted_string/3,
per_enc_small_number/2]).
-export([per_enc_extension_bit/2,per_enc_extensions/4,per_enc_optional/3]).
-export([per_enc_sof/5]).
-export([enc_absent/3,enc_append/1,enc_element/2]).
-export([enc_cg/2]).
-export([optimize_alignment/1,optimize_alignment/2,
dec_slim_cg/2,dec_code_gen/2]).
-export([effective_constraint/2]).
-import(asn1ct_gen, [emit/1]).
-record(st, {var,
base}).
dec_slim_cg(Imm0, BytesVar) ->
{Imm,_} = optimize_alignment(Imm0),
asn1ct_name:new(v),
[H|T] = atom_to_list(asn1ct_name:curr(v)) ++ "@",
VarBase = [H-($a-$A)|T],
St0 = #st{var=0,base=VarBase},
{Res,Pre,_} = flatten(Imm, BytesVar, St0),
dcg_list_outside(Pre),
Res.
dec_code_gen(Imm, BytesVar) ->
emit(["begin",nl]),
{Dst,DstBuf} = dec_slim_cg(Imm, BytesVar),
emit([",",nl,
"{",Dst,",",DstBuf,"}",nl,
"end"]),
ok.
optimize_alignment(Imm) ->
opt_al(Imm, unknown).
optimize_alignment(Imm, Al) ->
opt_al(Imm, Al).
per_dec_boolean() ->
{map,{get_bits,1,[1]},[{0,false},{1,true}]}.
per_dec_enumerated([{V,_}], _Aligned) ->
{value,V};
per_dec_enumerated(NamedList0, Aligned) ->
Ub = length(NamedList0) - 1,
Constraint = [{'ValueRange',{0,Ub}}],
Int = per_dec_integer(Constraint, Aligned),
EnumTail = case matched_range(Int) of
{0,Ub} ->
%% The error case can never happen.
[];
_ ->
[enum_error]
end,
NamedList = per_dec_enumerated_fix_list(NamedList0, EnumTail, 0),
{map,Int,NamedList}.
per_dec_enumerated(BaseNamedList, NamedListExt0, Aligned) ->
Base = per_dec_enumerated(BaseNamedList, Aligned),
NamedListExt = per_dec_enumerated_fix_list(NamedListExt0,
[enum_default], 0),
Ext = {map,per_dec_normally_small_number(Aligned),NamedListExt},
bit_case(Base, Ext).
per_dec_extension_map(Aligned) ->
Len = per_dec_normally_small_length(Aligned),
{get_bits,Len,[1,bitstring]}.
per_dec_integer(Constraint0, Aligned) ->
Constraint = effective_constraint(integer, Constraint0),
per_dec_integer_1(Constraint, Aligned).
per_dec_length(SingleValue, _, _Aligned) when is_integer(SingleValue) ->
{value,SingleValue};
per_dec_length({{Fixed,Fixed},[]}, AllowZero, Aligned) ->
bit_case(per_dec_length(Fixed, AllowZero, Aligned),
per_dec_length(no, AllowZero, Aligned));
per_dec_length({{_,_}=Constr,[]}, AllowZero, Aligned) ->
bit_case(per_dec_length(Constr, AllowZero, Aligned),
per_dec_length(no, AllowZero, Aligned));
per_dec_length({Lb,Ub}, _AllowZero, Aligned) when is_integer(Lb),
is_integer(Lb) ->
per_dec_constrained(Lb, Ub, Aligned);
per_dec_length(no, AllowZero, Aligned) ->
decode_unconstrained_length(AllowZero, Aligned).
per_dec_named_integer(Constraint, NamedList0, Aligned) ->
Int = per_dec_integer(Constraint, Aligned),
NamedList = [{K,V} || {V,K} <- NamedList0] ++ [integer_default],
{map,Int,NamedList}.
per_dec_k_m_string(StringType, Constraint, Aligned) ->
SzConstr = effective_constraint(bitstring, Constraint),
N = string_num_bits(StringType, Constraint, Aligned),
Imm = dec_string(SzConstr, N, Aligned, k_m_string),
Chars = char_tab(Constraint, StringType, N),
convert_string(N, Chars, Imm).
per_dec_octet_string(Constraint, Aligned) ->
dec_string(Constraint, 8, Aligned, 'OCTET STRING').
per_dec_raw_bitstring(Constraint, Aligned) ->
dec_string(Constraint, 1, Aligned, 'BIT STRING').
per_dec_open_type(Aligned) ->
dec_string(no, 8, Aligned, open_type).
per_dec_real(Aligned) ->
Dec = fun(V, Buf) ->
emit(["{",{call,real_common,decode_real,[V]},
com,Buf,"}"])
end,
{call,Dec,
{get_bits,decode_unconstrained_length(true, Aligned),
[8,binary,{align,Aligned}]}}.
per_dec_restricted_string(Aligned) ->
DecLen = decode_unconstrained_length(true, Aligned),
{get_bits,DecLen,[8,binary]}.
%%%
%%% Encoding.
%%%
per_enc_bit_string(Val, [], Constraint0, Aligned) ->
{B,[[],Bits]} = mk_vars([], [bits]),
Constraint = effective_constraint(bitstring, Constraint0),
B ++ [{call,erlang,bit_size,[Val],Bits}|
per_enc_length(Val, 1, Bits, Constraint, Aligned, 'BIT STRING')];
per_enc_bit_string(Val0, NNL0, Constraint0, Aligned) ->
{B,[Val,Bs,Bits,Positions]} = mk_vars(Val0, [bs,bits,positions]),
NNL = lists:keysort(2, NNL0),
Constraint = effective_constraint(bitstring, Constraint0),
ExtraArgs = case constr_min_size(Constraint) of
no -> [];
Lb -> [Lb]
end,
ToBs = case ExtraArgs of
[] ->
{call,per_common,bs_drop_trailing_zeroes,[Val]};
[0] ->
{call,per_common,bs_drop_trailing_zeroes,[Val]};
[Lower] ->
{call,per_common,adjust_trailing_zeroes,[Val,Lower]}
end,
B ++ [{'try',
[bit_string_name2pos_fun(NNL, Val)],
{Positions,
[{call,per_common,bitstring_from_positions,
[Positions|ExtraArgs]}]},
[ToBs],Bs},
{call,erlang,bit_size,[Bs],Bits}|
per_enc_length(Bs, 1, Bits, Constraint, Aligned, 'BIT STRING')].
per_enc_legacy_bit_string(Val0, [], Constraint0, Aligned) ->
{B,[Val,Bs,Bits]} = mk_vars(Val0, [bs,bits]),
Constraint = effective_constraint(bitstring, Constraint0),
ExtraArgs = case constr_min_size(Constraint) of
no -> [];
Lb -> [Lb]
end,
B ++ [{call,per_common,to_bitstring,[Val|ExtraArgs],Bs},
{call,erlang,bit_size,[Bs],Bits}|
per_enc_length(Bs, 1, Bits, Constraint, Aligned, 'BIT STRING')];
per_enc_legacy_bit_string(Val0, NNL0, Constraint0, Aligned) ->
{B,[Val,Bs,Bits,Positions]} = mk_vars(Val0, [bs,bits,positions]),
NNL = lists:keysort(2, NNL0),
Constraint = effective_constraint(bitstring, Constraint0),
ExtraArgs = case constr_min_size(Constraint) of
no -> [];
0 -> [];
Lb -> [Lb]
end,
B ++ [{'try',
[bit_string_name2pos_fun(NNL, Val)],
{Positions,
[{call,per_common,bitstring_from_positions,
[Positions|ExtraArgs]}]},
[{call,per_common,to_named_bitstring,[Val|ExtraArgs]}],Bs},
{call,erlang,bit_size,[Bs],Bits}|
per_enc_length(Bs, 1, Bits, Constraint, Aligned, 'BIT STRING')].
per_enc_boolean(Val0, _Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
B++build_cond([[{eq,Val,false},{put_bits,0,1,[1]}],
[{eq,Val,true},{put_bits,1,1,[1]}]]).
per_enc_choice(Val0, Cs0, _Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
Cs = [[{eq,Val,Tag}|opt_choice(Imm)] || {Tag,Imm} <- Cs0],
B++build_cond(Cs).
per_enc_enumerated(Val0, {Root,Ext}, Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
Constr = enumerated_constraint(Root),
RootCs = per_enc_enumerated_root(Root, [{put_bits,0,1,[1]}],
Val, Constr, Aligned),
ExtCs = per_enc_enumerated_ext(Ext, Val, Aligned),
B++[{'cond',RootCs++ExtCs++enumerated_error(Val)}];
per_enc_enumerated(Val0, Root, Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
Constr = enumerated_constraint(Root),
Cs = per_enc_enumerated_root(Root, [], Val, Constr, Aligned),
B++[{'cond',Cs++enumerated_error(Val)}].
enumerated_error(Val) ->
[['_',{error,Val}]].
per_enc_integer(Val0, Constraint0, Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
Constraint = effective_constraint(integer, Constraint0),
B ++ per_enc_integer_1(Val, Constraint, Aligned).
per_enc_integer(Val0, NNL, Constraint0, Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
Constraint = effective_constraint(integer, Constraint0),
Cs = [[{eq,Val,N}|per_enc_integer_1(V, Constraint, Aligned)] ||
{N,V} <- NNL],
case per_enc_integer_1(Val, Constraint, Aligned) of
[{'cond',IntCs}] ->
B ++ [{'cond',Cs++IntCs}];
Other ->
B ++ [{'cond',Cs++[['_'|Other]]}]
end.
per_enc_null(_Val, _Aligned) ->
[].
per_enc_k_m_string(Val0, StringType, Constraint, Aligned) ->
{B,[Val,Bin,Len]} = mk_vars(Val0, [bin,len]),
SzConstraint = effective_constraint(bitstring, Constraint),
Unit = string_num_bits(StringType, Constraint, Aligned),
Chars0 = char_tab(Constraint, StringType, Unit),
Enc = case Unit of
16 ->
{call,per_common,encode_chars_16bit,[Val],Bin};
32 ->
{call,per_common,encode_big_chars,[Val],Bin};
8 ->
{call,erlang,list_to_binary,[Val],Bin};
_ ->
case enc_char_tab(Chars0) of
notab ->
{call,per_common,encode_chars,[Val,Unit],Bin};
{tab,Tab} ->
{call,per_common,encode_chars,[Val,Unit,Tab],Bin};
{compact_map,Map} ->
{call,per_common,encode_chars_compact_map,
[Val,Unit,Map],Bin}
end
end,
case Unit of
8 ->
B ++ [Enc,{call,erlang,byte_size,[Bin],Len}];
_ ->
B ++ [{call,erlang,length,[Val],Len},Enc]
end ++ per_enc_length(Bin, Unit, Len, SzConstraint, Aligned, k_m_string).
per_enc_open_type(Imm0, Aligned) ->
Imm = case Aligned of
true ->
%% Temporarily make the implicit 'align' done by
%% complete/1 explicit to facilitate later
%% optimizations: the absence of 'align' can be used
%% as an indication that complete/1 can be replaced
%% with a cheaper operation such as
%% iolist_to_binary/1. The redundant 'align' will be
%% optimized away later.
Imm0 ++ [{put_bits,0,0,[1,align]}];
false ->
Imm0
end,
{[],[[],Val,Len,Bin]} = mk_vars([], [output,len,bin]),
[{list,Imm,Val},
{call,enc_mod(Aligned),complete,[Val],Bin},
{call,erlang,byte_size,[Bin],Len}|
per_enc_length(Bin, 8, Len, Aligned)].
per_enc_octet_string(Bin, Constraint0, Aligned) ->
{B,[[],Len]} = mk_vars([], [len]),
Constraint = effective_constraint(bitstring, Constraint0),
B ++ [{call,erlang,byte_size,[Bin],Len}|
per_enc_length(Bin, 8, Len, Constraint, Aligned, 'OCTET STRING')].
per_enc_legacy_octet_string(Val0, Constraint0, Aligned) ->
{B,[Val,Bin,Len]} = mk_vars(Val0, [bin,len]),
Constraint = effective_constraint(bitstring, Constraint0),
B ++ [{call,erlang,iolist_to_binary,[Val],Bin},
{call,erlang,byte_size,[Bin],Len}|
per_enc_length(Bin, 8, Len, Constraint, Aligned, 'OCTET STRING')].
per_enc_restricted_string(Val0, {M,F}, Aligned) ->
{B,[Val,Bin,Len]} = mk_vars(Val0, [bin,len]),
B ++ [{call,M,F,[Val],Bin},
{call,erlang,byte_size,[Bin],Len}|
per_enc_length(Bin, 8, Len, Aligned)].
per_enc_small_number(Val, Aligned) ->
build_cond([[{lt,Val,64},{put_bits,Val,7,[1]}],
['_',{put_bits,1,1,[1]}|
per_enc_unsigned(Val, Aligned)]]).
per_enc_extension_bit(Val0, _Aligned) ->
{B,[Val]} = mk_vars(Val0, []),
B++build_cond([[{eq,Val,[]},{put_bits,0,1,[1]}],
['_',{put_bits,1,1,[1]}]]).
per_enc_extensions(Val0, Pos0, NumBits, Aligned) when NumBits > 0 ->
Pos = Pos0 + 1,
{B,[Val,Bitmap]} = mk_vars(Val0, [bitmap]),
Length = per_enc_small_length(NumBits, Aligned),
PutBits = case NumBits of
1 -> [{put_bits,1,1,[1]}];
_ -> [{put_bits,Bitmap,NumBits,[1]}]
end,
B++[{call,per_common,extension_bitmap,[Val,Pos,Pos+NumBits],Bitmap},
{list,[{'cond',[[{eq,Bitmap,0}],
['_'|Length ++ PutBits]]}],
{var,"Extensions"}}].
per_enc_optional(Val0, {Pos,DefVals}, _Aligned) when is_integer(Pos),
is_list(DefVals) ->
{B,Val} = enc_element(Pos, Val0),
Zero = {put_bits,0,1,[1]},
One = {put_bits,1,1,[1]},
B++[{'cond',
[[{eq,Val,DefVal},Zero] || DefVal <- DefVals] ++ [['_',One]]}];
per_enc_optional(Val0, {Pos,{call,M,F,A}}, _Aligned) when is_integer(Pos) ->
{B,Val} = enc_element(Pos, Val0),
{[],[[],Tmp]} = mk_vars([], [tmp]),
Zero = {put_bits,0,1,[1]},
One = {put_bits,1,1,[1]},
B++[{call,M,F,[Val|A],Tmp},
{'cond',
[[{eq,Tmp,true},Zero],['_',One]]}];
per_enc_optional(Val0, Pos, _Aligned) when is_integer(Pos) ->
{B,Val} = enc_element(Pos, Val0),
Zero = {put_bits,0,1,[1]},
One = {put_bits,1,1,[1]},
B++[{'cond',[[{eq,Val,asn1_NOVALUE},Zero],
['_',One]]}].
per_enc_sof(Val0, Constraint, ElementVar, ElementImm, Aligned) ->
{B,[Val,Len]} = mk_vars(Val0, [len]),
SzConstraint = effective_constraint(bitstring, Constraint),
LenImm = enc_length(Len, SzConstraint, Aligned),
Lc0 = [{lc,ElementImm,{var,atom_to_list(ElementVar)},Val}],
Lc = opt_lc(Lc0, LenImm),
PreBlock = B ++ [{call,erlang,length,[Val],Len}],
case LenImm of
[{'cond',[[C|Action]]}] ->
PreBlock ++ [{'cond',[[C|Action++Lc]]}];
[{sub,_,_,_}=Sub,{'cond',[[C|Action]]}] ->
PreBlock ++
[Sub,{'cond',[[C|Action++Lc]]}];
EncLen ->
PreBlock ++ EncLen ++ Lc
end.
enc_absent(Val0, {call,M,F,A}, Body) ->
{B,[Var,Tmp]} = mk_vars(Val0, [tmp]),
B++[{call,M,F,[Var|A],Tmp},
{'cond',
[[{eq,Tmp,true}],['_'|Body]]}];
enc_absent(Val0, AbsVals, Body) when is_list(AbsVals) ->
{B,[Var]} = mk_vars(Val0, []),
Cs = [[{eq,Var,Aval}] || Aval <- AbsVals] ++ [['_'|Body]],
B++build_cond(Cs).
enc_append([[]|T]) ->
enc_append(T);
enc_append([[{put_bits,_,_,_}|_]=Pb|[Imm|T]=T0]) ->
case opt_choice(Pb++Imm) of
[{put_bits,_,_,_}|_] ->
[{block,Pb}|enc_append(T0)];
Opt ->
enc_append([Opt|T])
end;
enc_append([Imm0|[Imm1|T]=T0]) ->
try combine_imms(Imm0, Imm1) of
Imm ->
enc_append([Imm|T])
catch
throw:impossible ->
[{block,Imm0}|enc_append(T0)]
end;
enc_append([H|T]) ->
[{block,H}|enc_append(T)];
enc_append([]) -> [].
enc_element(N, Val0) ->
{[],[Val,Dst]} = mk_vars(Val0, [element]),
{[{call,erlang,element,[N,Val],Dst}],Dst}.
enc_cg(Imm0, false) ->
Imm1 = enc_cse(Imm0),
Imm2 = enc_pre_cg(Imm1),
Imm = enc_opt(Imm2),
enc_cg(Imm);
enc_cg(Imm0, true) ->
Imm1 = enc_cse(Imm0),
Imm2 = enc_hoist_align(Imm1),
Imm3 = enc_opt_al(Imm2),
Imm4 = per_fixup(Imm3),
Imm5 = enc_pre_cg(Imm4),
Imm = enc_opt(Imm5),
enc_cg(Imm).
%%%
%%% Local functions.
%%%
%% is_aligned(StringType, LowerBound, UpperBound) -> boolean()
%% StringType = 'OCTET STRING' | 'BIT STRING' | k_m_string
%% LowerBound = UpperBound = number of bits
%% Determine whether a string should be aligned in PER.
is_aligned(T, Lb, Ub) when T =:= 'OCTET STRING'; T =:= 'BIT STRING' ->
%% OCTET STRINGs and BIT STRINGs are aligned to a byte boundary
%% unless the size is fixed and less than or equal to 16 bits.
Lb =/= Ub orelse Lb > 16;
is_aligned(k_m_string, _Lb, Ub) ->
%% X.691 (07/2002) 27.5.7 says if the upper bound times the number
%% of bits is greater than or equal to 16, then the bit field should
%% be aligned.
Ub >= 16.
%%%
%%% Generating the intermediate format format for decoding.
%%%
dec_string(Sv, U, Aligned0, T) when is_integer(Sv) ->
Bits = U*Sv,
Aligned = Aligned0 andalso is_aligned(T, Bits, Bits),
{get_bits,Sv,[U,binary,{align,Aligned}]};
dec_string({{Sv,Sv},[]}, U, Aligned, T) ->
bit_case(dec_string(Sv, U, Aligned, T),
dec_string(no, U, Aligned, T));
dec_string({{_,_}=C,[]}, U, Aligned, T) ->
bit_case(dec_string(C, U, Aligned, T),
dec_string(no, U, Aligned, T));
dec_string({Lb,Ub}, U, Aligned0, T) ->
Len = per_dec_constrained(Lb, Ub, Aligned0),
Aligned = Aligned0 andalso is_aligned(T, Lb*U, Ub*U),
{get_bits,Len,[U,binary,{align,Aligned}]};
dec_string(_, U, Aligned, _T) ->
Al = [{align,Aligned}],
DecRest = fun(V, Buf) ->
asn1ct_func:call(per_common,
decode_fragmented,
[V,Buf,U])
end,
{'case',[{test,{get_bits,1,[1|Al]},0,
{value,{get_bits,
{get_bits,7,[1]},
[U,binary]}}},
{test,{get_bits,1,[1|Al]},1,
{test,{get_bits,1,[1]},0,
{value,{get_bits,
{get_bits,14,[1]},
[U,binary]}}}},
{test,{get_bits,1,[1|Al]},1,
{test,{get_bits,1,[1]},1,
{value,{call,DecRest,{get_bits,6,[1]}}}}}]}.
per_dec_enumerated_fix_list([{V,_}|T], Tail, N) ->
[{N,V}|per_dec_enumerated_fix_list(T, Tail, N+1)];
per_dec_enumerated_fix_list([], Tail, _) -> Tail.
per_dec_integer_1([{'SingleValue',Value}], _Aligned) ->
{value,Value};
per_dec_integer_1([{'ValueRange',{Lb,'MAX'}}], Aligned) when is_integer(Lb) ->
per_decode_semi_constrained(Lb, Aligned);
per_dec_integer_1([{'ValueRange',{Lb,Ub}}], Aligned) when is_integer(Lb),
is_integer(Ub) ->
per_dec_constrained(Lb, Ub, Aligned);
per_dec_integer_1([{{_,_}=Constr0,_}], Aligned) ->
Constr = effective_constraint(integer, [Constr0]),
bit_case(per_dec_integer(Constr, Aligned),
per_dec_unconstrained(Aligned));
per_dec_integer_1([], Aligned) ->
per_dec_unconstrained(Aligned).
per_dec_unconstrained(Aligned) ->
{get_bits,decode_unconstrained_length(false, Aligned),[8,signed]}.
per_dec_constrained(Lb, Ub, false) ->
Range = Ub - Lb + 1,
Get = {get_bits,uper_num_bits(Range),[1]},
add_lb(Lb, Get);
per_dec_constrained(Lb, Ub, true) ->
Range = Ub - Lb + 1,
Get = if
Range =< 255 ->
{get_bits,per_num_bits(Range),[1,unsigned]};
Range == 256 ->
{get_bits,1,[8,unsigned,{align,true}]};
Range =< 65536 ->
{get_bits,2,[8,unsigned,{align,true}]};
true ->
RangeOctLen = byte_size(binary:encode_unsigned(Range - 1)),
{get_bits,per_dec_length({1,RangeOctLen}, false, true),
[8,unsigned,{align,true}]}
end,
add_lb(Lb, Get).
add_lb(0, Get) -> Get;
add_lb(Lb, Get) -> {add,Get,Lb}.
per_dec_normally_small_number(Aligned) ->
Small = {get_bits,6,[1]},
Unlimited = per_decode_semi_constrained(0, Aligned),
bit_case(Small, Unlimited).
per_dec_normally_small_length(Aligned) ->
Small = {add,{get_bits,6,[1]},1},
Unlimited = decode_unconstrained_length(false, Aligned),
bit_case(Small, Unlimited).
per_decode_semi_constrained(Lb, Aligned) ->
add_lb(Lb, {get_bits,decode_unconstrained_length(false, Aligned),[8]}).
bit_case(Base, Ext) ->
{'case',[{test,{get_bits,1,[1]},0,Base},
{test,{get_bits,1,[1]},1,Ext}]}.
decode_unconstrained_length(AllowZero, Aligned) ->
Al = [{align,Aligned}],
Zero = case AllowZero of
false -> [non_zero];
true -> []
end,
{'case',[{test,{get_bits,1,[1|Al]},0,
{value,{get_bits,7,[1|Zero]}}},
{test,{get_bits,1,[1|Al]},1,
{test,{get_bits,1,[1]},0,
{value,{get_bits,14,[1|Zero]}}}}]}.
uper_num_bits(N) ->
uper_num_bits(N, 1, 0).
uper_num_bits(N, T, B) when N =< T -> B;
uper_num_bits(N, T, B) -> uper_num_bits(N, T bsl 1, B+1).
per_num_bits(2) -> 1;
per_num_bits(N) when N =< 4 -> 2;
per_num_bits(N) when N =< 8 -> 3;
per_num_bits(N) when N =< 16 -> 4;
per_num_bits(N) when N =< 32 -> 5;
per_num_bits(N) when N =< 64 -> 6;
per_num_bits(N) when N =< 128 -> 7;
per_num_bits(N) when N =< 255 -> 8.
matched_range({get_bits,Bits0,[U|Flags]}) when is_integer(U) ->
case lists:member(signed, Flags) of
false ->
Bits = U*Bits0,
{0,(1 bsl Bits) - 1};
true ->
unknown
end;
matched_range(_Op) -> unknown.
string_num_bits(StringType, Constraint, Aligned) ->
case get_constraint(Constraint, 'PermittedAlphabet') of
{'SingleValue',Sv} ->
charbits(length(Sv), Aligned);
no ->
case StringType of
'IA5String' ->
charbits(128, Aligned);
'VisibleString' ->
charbits(95, Aligned);
'PrintableString' ->
charbits(74, Aligned);
'NumericString' ->
charbits(11, Aligned);
'UniversalString' ->
32;
'BMPString' ->
16
end
end.
charbits(NumChars, false) ->
uper_num_bits(NumChars);
charbits(NumChars, true) ->
1 bsl uper_num_bits(uper_num_bits(NumChars)).
convert_string(8, notab, Imm) ->
{convert,binary_to_list,Imm};
convert_string(NumBits, notab, Imm) when NumBits < 8 ->
Dec = fun(V, Buf) ->
emit(["{",{call,per_common,decode_chars,
[V,NumBits]},com,Buf,"}"])
end,
{call,Dec,Imm};
convert_string(NumBits, notab, Imm) when NumBits =:= 16 ->
Dec = fun(V, Buf) ->
emit(["{",{call,per_common,decode_chars_16bit,
[V]},com,Buf,"}"])
end,
{call,Dec,Imm};
convert_string(NumBits, notab, Imm) ->
Dec = fun(V, Buf) ->
emit(["{",{call,per_common,decode_big_chars,
[V,NumBits]},com,Buf,"}"])
end,
{call,Dec,Imm};
convert_string(NumBits, Chars, Imm) ->
Dec = fun(V, Buf) ->
emit(["{",{call,per_common,decode_chars,
[V,NumBits,{asis,Chars}]},com,Buf,"}"])
end,
{call,Dec,Imm}.
char_tab(C, StringType, NumBits) ->
case get_constraint(C, 'PermittedAlphabet') of
{'SingleValue',Sv} ->
char_tab_1(Sv, NumBits);
no ->
case StringType of
'IA5String' ->
notab;
'VisibleString' ->
notab;
'PrintableString' ->
Chars = " '()+,-./0123456789:=?"
"ABCDEFGHIJKLMNOPQRSTUVWXYZ"
"abcdefghijklmnopqrstuvwxyz",
char_tab_1(Chars, NumBits);
'NumericString' ->
char_tab_1(" 0123456789", NumBits);
'UniversalString' ->
notab;
'BMPString' ->
notab
end
end.
char_tab_1(Chars, NumBits) ->
Max = lists:max(Chars),
BitValMax = (1 bsl NumBits) - 1,
if
Max =< BitValMax ->
notab;
true ->
list_to_tuple(lists:sort(Chars))
end.
%%%
%%% Remove unnecessary aligning to octet boundaries.
%%%
opt_al({get_bits,E0,Opts0}, A0) ->
{E,A1} = opt_al(E0, A0),
Opts = opt_al_1(A1, Opts0),
A = update_al(A1, E, Opts),
{{get_bits,E,Opts},A};
opt_al({call,Fun,E0}, A0) ->
{E,A} = opt_al(E0, A0),
{{call,Fun,E},A};
opt_al({convert,Op,E0}, A0) ->
{E,A} = opt_al(E0, A0),
{{convert,Op,E},A};
opt_al({value,V}=Term, A) when is_integer(V); is_atom(V) ->
{Term,A};
opt_al({value,E0}, A0) ->
{E,A} = opt_al(E0, A0),
{{value,E},A};
opt_al({add,E0,I}, A0) when is_integer(I) ->
{E,A} = opt_al(E0, A0),
{{add,E,I},A};
opt_al({test,E0,V,B0}, A0) ->
{E,A1} = opt_al(E0, A0),
{B,A2} = opt_al(B0, A1),
{{test,E,V,B},A2};
opt_al({'case',Cs0}, A0) ->
{Cs,A} = opt_al_cs(Cs0, A0),
{{'case',Cs},A};
opt_al({map,E0,Cs}, A0) ->
{E,A} = opt_al(E0, A0),
{{map,E,Cs},A};
opt_al(I, A) when is_integer(I) ->
{I,A}.
opt_al_cs([C0|Cs0], A0) ->
{C,A1} = opt_al(C0, A0),
{Cs,A2} = opt_al_cs(Cs0, A0),
{[C|Cs],merge_al(A1, A2)};
opt_al_cs([], _) -> {[],none}.
merge_al(unknown, _) -> unknown;
merge_al(Other, none) -> Other;
merge_al(_, unknown) -> unknown;
merge_al(I0, I1) ->
case {I0 rem 8,I1 rem 8} of
{I,I} -> I;
{_,_} -> unknown
end.
opt_al_1(unknown, Opts) ->
Opts;
opt_al_1(A, Opts0) ->
case alignment(Opts0) of
none ->
Opts0;
full ->
case A rem 8 of
0 ->
%% Already in alignment.
proplists:delete(align, Opts0);
Bits ->
%% Cheaper alignment with a constant padding.
Opts1 = proplists:delete(align, Opts0),
[{align,8-Bits }|Opts1]
end;
A -> %Assertion.
Opts0
end.
update_al(A0, E, Opts) ->
A = case alignment(Opts) of
none -> A0;
full -> 0;
Bits when is_integer(A0) ->
0 = (A0 + Bits) rem 8; %Assertion.
_ ->
0
end,
[U] = [U || U <- Opts, is_integer(U)],
if
U rem 8 =:= 0 -> A;
is_integer(A), is_integer(E) -> A + U*E;
true -> unknown
end.
%%%
%%% Flatten the intermediate format and assign temporaries.
%%%
flatten({get_bits,I,U}, Buf0, St0) when is_integer(I) ->
{Dst,St} = new_var_pair(St0),
Gb = {get_bits,{I,Buf0},U,Dst},
flatten_align(Gb, [], St);
flatten({get_bits,E0,U}, Buf0, St0) ->
{E,Pre,St1} = flatten(E0, Buf0, St0),
{Dst,St2} = new_var_pair(St1),
Gb = {get_bits,E,U,Dst},
flatten_align(Gb, Pre, St2);
flatten({test,{get_bits,I,U},V,E0}, Buf0, St0) when is_integer(I) ->
{DstBuf0,St1} = new_var("Buf", St0),
Gb = {get_bits,{I,Buf0},U,{V,DstBuf0}},
{{_Dst,DstBuf},Pre0,St2} = flatten_align(Gb, [], St1),
{E,Pre1,St3} = flatten(E0, DstBuf, St2),
{E,Pre0++Pre1,St3};
flatten({add,E0,I}, Buf0, St0) ->
{{Src,Buf},Pre,St1} = flatten(E0, Buf0, St0),
{Dst,St} = new_var("Add", St1),
{{Dst,Buf},Pre++[{add,Src,I,Dst}],St};
flatten({'case',Cs0}, Buf0, St0) ->
{Dst,St1} = new_var_pair(St0),
{Cs1,St} = flatten_cs(Cs0, Buf0, St1),
{Al,Cs2} = flatten_hoist_align(Cs1),
{Dst,Al++[{'case',Buf0,Cs2,Dst}],St};
flatten({map,E0,Cs0}, Buf0, St0) ->
{{E,DstBuf},Pre,St1} = flatten(E0, Buf0, St0),
{Dst,St2} = new_var("Int", St1),
Cs = flatten_map_cs(Cs0, E),
{{Dst,DstBuf},Pre++[{'map',E,Cs,{Dst,DstBuf}}],St2};
flatten({value,V}, Buf0, St0) when is_atom(V) ->
{{"'"++atom_to_list(V)++"'",Buf0},[],St0};
flatten({value,V0}, Buf0, St0) when is_integer(V0) ->
{{V0,Buf0},[],St0};
flatten({value,V0}, Buf0, St0) ->
flatten(V0, Buf0, St0);
flatten({convert,Op,E0}, Buf0, St0) ->
{{E,Buf},Pre,St1} = flatten(E0, Buf0, St0),
{Dst,St2} = new_var("Conv", St1),
{{Dst,Buf},Pre++[{convert,Op,E,Dst}],St2};
flatten({call,Fun,E0}, Buf0, St0) ->
{Src,Pre,St1} = flatten(E0, Buf0, St0),
{Dst,St2} = new_var_pair(St1),
{Dst,Pre++[{call,Fun,Src,Dst}],St2}.
flatten_cs([C0|Cs0], Buf, St0) ->
{C,Pre,St1} = flatten(C0, Buf, St0),
{Cs,St2} = flatten_cs(Cs0, Buf, St0),
St3 = St2#st{var=max(St1#st.var, St2#st.var)},
{[Pre++[{return,C}]|Cs],St3};
flatten_cs([], _, St) -> {[],St}.
flatten_map_cs(Cs, Var) ->
flatten_map_cs_1(Cs, {Var,Cs}).
flatten_map_cs_1([{K,V}|Cs], DefData) ->
[{{asis,K},{asis,V}}|flatten_map_cs_1(Cs, DefData)];
flatten_map_cs_1([integer_default], {Int,_}) ->
[{'_',Int}];
flatten_map_cs_1([enum_default], {Int,_}) ->
[{'_',["{asn1_enum,",Int,"}"]}];
flatten_map_cs_1([enum_error], {Var,Cs}) ->
Vs = [V || {_,V} <- Cs],
[{'_',["exit({error,{asn1,{decode_enumerated,{",Var,",",
{asis,Vs},"}}}})"]}];
flatten_map_cs_1([], _) -> [].
flatten_hoist_align([[{align_bits,_,_}=Ab|T]|Cs]) ->
flatten_hoist_align_1(Cs, Ab, [T]);
flatten_hoist_align(Cs) -> {[],Cs}.
flatten_hoist_align_1([[Ab|T]|Cs], Ab, Acc) ->
flatten_hoist_align_1(Cs, Ab, [T|Acc]);
flatten_hoist_align_1([], Ab, Acc) ->
{[Ab],lists:reverse(Acc)}.
flatten_align({get_bits,{SrcBits,SrcBuf},U,Dst}=Gb0, Pre, St0) ->
case alignment(U) of
none ->
flatten_align_1(U, Dst, Pre++[Gb0], St0);
full ->
{PadBits,St1} = new_var("Pad", St0),
{DstBuf,St2} = new_var("Buf", St1),
Ab = {align_bits,SrcBuf,PadBits},
Agb = {get_bits,{PadBits,SrcBuf},[1],{'_',DstBuf}},
Gb = {get_bits,{SrcBits,DstBuf},U,Dst},
flatten_align_1(U, Dst, Pre++[Ab,Agb,Gb], St2);
PadBits when is_integer(PadBits), PadBits > 0 ->
{DstBuf,St1} = new_var("Buf", St0),
Agb = {get_bits,{PadBits,SrcBuf},[1],{'_',DstBuf}},
Gb = {get_bits,{SrcBits,DstBuf},U,Dst},
flatten_align_1(U, Dst, Pre++[Agb,Gb], St1)
end.
flatten_align_1(U, {D,_}=Dst, Pre, St) ->
case is_non_zero(U) of
false ->
{Dst,Pre,St};
true ->
{Dst,Pre++[{non_zero,D}],St}
end.
new_var_pair(St0) ->
{Var,St1} = new_var("V", St0),
{Buf,St2} = new_var("Buf", St1),
{{Var,Buf},St2}.
new_var(Tag, #st{base=VarBase,var=N}=St) ->
{VarBase++Tag++integer_to_list(N),St#st{var=N+1}}.
alignment([{align,false}|_]) -> none;
alignment([{align,true}|_]) -> full;
alignment([{align,Bits}|_]) -> Bits;
alignment([_|T]) -> alignment(T);
alignment([]) -> none.
is_non_zero(Fl) ->
lists:member(non_zero, Fl).
%%%
%%% Generate Erlang code from the flattened intermediate format.
%%%
dcg_list_outside([{align_bits,Buf,SzVar}|T]) ->
emit([SzVar," = bit_size(",Buf,") band 7"]),
iter_dcg_list_outside(T);
dcg_list_outside([{'case',Buf,Cs,Dst}|T]) ->
dcg_case(Buf, Cs, Dst),
iter_dcg_list_outside(T);
dcg_list_outside([{'map',Val,Cs,Dst}|T]) ->
dcg_map(Val, Cs, Dst),
iter_dcg_list_outside(T);
dcg_list_outside([{add,S1,S2,Dst}|T]) ->
emit([Dst," = ",S1," + ",S2]),
iter_dcg_list_outside(T);
dcg_list_outside([{return,{V,Buf}}|T]) ->
emit(["{",V,",",Buf,"}"]),
iter_dcg_list_outside(T);
dcg_list_outside([{call,Fun,{V,Buf},{Dst,DstBuf}}|T]) ->
emit(["{",Dst,",",DstBuf,"} = "]),
Fun(V, Buf),
iter_dcg_list_outside(T);
dcg_list_outside([{convert,{M,F},V,Dst}|T]) ->
emit([Dst," = ",{asis,M},":",{asis,F},"(",V,")"]),
iter_dcg_list_outside(T);
dcg_list_outside([{convert,Op,V,Dst}|T]) ->
emit([Dst," = ",Op,"(",V,")"]),
iter_dcg_list_outside(T);
dcg_list_outside([{get_bits,{_,Buf0},_,_}|_]=L0) ->
emit("<<"),
{L,Buf} = dcg_list_inside(L0, buf),
emit([Buf,"/bitstring>> = ",Buf0]),
iter_dcg_list_outside(L);
dcg_list_outside([]) ->
emit("ignore"),
ok.
iter_dcg_list_outside([_|_]=T) ->
emit([",",nl]),
dcg_list_outside(T);
iter_dcg_list_outside([]) -> ok.
dcg_case(Buf, Cs, {Dst,DstBuf}) ->
emit(["{",Dst,",",DstBuf,"} = case ",Buf," of",nl]),
dcg_case_cs(Cs),
emit("end").
dcg_case_cs([C|Cs]) ->
emit("<<"),
{T0,DstBuf} = dcg_list_inside(C, buf),
emit([DstBuf,"/bitstring>>"]),
T1 = dcg_guard(T0),
dcg_list_outside(T1),
case Cs of
[] -> emit([nl]);
[_|_] -> emit([";",nl])
end,
dcg_case_cs(Cs);
dcg_case_cs([]) -> ok.
dcg_guard([{non_zero,Src}|T]) ->
emit([" when ",Src," =/= 0 ->",nl]),
T;
dcg_guard(T) ->
emit([" ->",nl]),
T.
dcg_map(Val, Cs, {Dst,_}) ->
emit([Dst," = case ",Val," of",nl]),
dcg_map_cs(Cs),
emit("end").
dcg_map_cs([{K,V}]) ->
emit([K," -> ",V,nl]);
dcg_map_cs([{K,V}|Cs]) ->
emit([K," -> ",V,";",nl]),
dcg_map_cs(Cs).
dcg_list_inside([{get_bits,{Sz,_},Fl0,{Dst,DstBuf}}|T], _) ->
Fl = bit_flags(Fl0, []),
emit([mk_dest(Dst),":",Sz,Fl,","]),
dcg_list_inside(T, DstBuf);
dcg_list_inside(L, Dst) -> {L,Dst}.
bit_flags([{align,_}|T], Acc) ->
bit_flags(T, Acc);
bit_flags([non_zero|T], Acc) ->
bit_flags(T, Acc);
bit_flags([U|T], Acc) when is_integer(U) ->
bit_flags(T, ["unit:"++integer_to_list(U)|Acc]);
bit_flags([H|T], Acc) ->
bit_flags(T, [atom_to_list(H)|Acc]);
bit_flags([], []) ->
"";
bit_flags([], Acc) ->
case "/" ++ bit_flags_1(Acc, "") of
"/unit:1" -> [];
Opts -> Opts
end.
bit_flags_1([H|T], Sep) ->
Sep ++ H ++ bit_flags_1(T, "-");
bit_flags_1([], _) -> [].
mk_dest(I) when is_integer(I) ->
integer_to_list(I);
mk_dest(S) -> S.
%%%
%%% Constructing the intermediate format for encoding.
%%%
split_off_nonbuilding(Imm) ->
lists:splitwith(fun is_nonbuilding/1, Imm).
is_nonbuilding({assign,_,_}) -> true;
is_nonbuilding({call,_,_,_,_}) -> true;
is_nonbuilding({lc,_,_,_,_}) -> true;
is_nonbuilding({set,_,_}) -> true;
is_nonbuilding({list,_,_}) -> true;
is_nonbuilding({sub,_,_,_}) -> true;
is_nonbuilding({'try',_,_,_,_}) -> true;
is_nonbuilding(_) -> false.
mk_vars(Input0, Temps) ->
asn1ct_name:new(enc),
Curr = asn1ct_name:curr(enc),
[H|T] = atom_to_list(Curr),
Base = [H - ($a - $A)|T ++ "@"],
case Input0 of
{var,Name} when is_list(Name) ->
{[],[Input0|mk_vars_1(Base, Temps)]};
[] ->
{[],[Input0|mk_vars_1(Base, Temps)]};
_ when is_integer(Input0) ->
{[],[Input0|mk_vars_1(Base, Temps)]}
end.
mk_vars_1(Base, Vars) ->
[mk_var(Base, V) || V <- Vars].
mk_var(Base, V) ->
{var,Base ++ atom_to_list(V)}.
per_enc_integer_1(Val, [], Aligned) ->
[{'cond',[['_'|per_enc_unconstrained(Val, Aligned)]]}];
per_enc_integer_1(Val, [{{'SingleValue',[_|_]=Svs}=Constr,[]}], Aligned) ->
%% An extensible constraint such as (1|17, ...).
%%
%% A subtle detail is that the extension root as described in the
%% ASN.1 spec should be used to determine whether a particular value
%% belongs to the extension root (as opposed to the effective
%% constraint, which will be used for the actual encoding).
%%
%% So for the example above, only the integers 1 and 17 should be
%% encoded as root values (extension bit = 0).
[{'ValueRange',{Lb,Ub}}] = effective_constraint(integer, [Constr]),
Root = [begin
{[],_,Put} = per_enc_constrained(Sv, Lb, Ub, Aligned),
[{eq,Val,Sv},{put_bits,0,1,[1]}|Put]
end || Sv <- Svs],
Cs = Root ++ [['_',{put_bits,1,1,[1]}|
per_enc_unconstrained(Val, Aligned)]],
build_cond(Cs);
per_enc_integer_1(Val0, [{{_,_}=Constr,[]}], Aligned) ->
{Prefix,Check,Action} = per_enc_integer_2(Val0, Constr, Aligned),
Prefix++build_cond([[Check,{put_bits,0,1,[1]}|Action],
['_',{put_bits,1,1,[1]}|
per_enc_unconstrained(Val0, Aligned)]]);
per_enc_integer_1(Val0, [Constr], Aligned) ->
{Prefix,Check,Action} = per_enc_integer_2(Val0, Constr, Aligned),
Prefix++build_cond([[Check|Action],
['_',{error,Val0}]]).
per_enc_integer_2(Val, {'SingleValue',Sv}, Aligned) when is_integer(Sv) ->
per_enc_constrained(Val, Sv, Sv, Aligned);
per_enc_integer_2(Val0, {'ValueRange',{Lb,'MAX'}}, Aligned)
when is_integer(Lb) ->
{Prefix,Val} = sub_lb(Val0, Lb),
{Prefix,{ge,Val,0},per_enc_unsigned(Val, Aligned)};
per_enc_integer_2(Val, {'ValueRange',{Lb,Ub}}, Aligned)
when is_integer(Lb), is_integer(Ub) ->
per_enc_constrained(Val, Lb, Ub, Aligned).
per_enc_constrained(Val, Sv, Sv, _Aligned) ->
{[],{eq,Val,Sv},[]};
per_enc_constrained(Val0, Lb, Ub, false) ->
{Prefix,Val} = sub_lb(Val0, Lb),
Range = Ub - Lb + 1,
NumBits = uper_num_bits(Range),
Check = {ult,Val,Range},
Put = [{put_bits,Val,NumBits,[1]}],
{Prefix,Check,Put};
per_enc_constrained(Val0, Lb, Ub, true) ->
{Prefix,Val} = sub_lb(Val0, Lb),
Range = Ub - Lb + 1,
if
Range < 256 ->
NumBits = per_num_bits(Range),
Check = {ult,Val,Range},
Put = [{put_bits,Val,NumBits,[1]}],
{Prefix,Check,Put};
Range =:= 256 ->
NumBits = 8,
Check = {ult,Val,Range},
Put = [{put_bits,Val,NumBits,[1,align]}],
{Prefix,Check,Put};
Range =< 65536 ->
Check = {ult,Val,Range},
Put = [{put_bits,Val,16,[1,align]}],
{Prefix,Check,Put};
true ->
{var,VarBase} = Val,
Bin = {var,VarBase++"@bin"},
BinSize0 = {var,VarBase++"@bin_size0"},
BinSize = {var,VarBase++"@bin_size"},
Check = {ult,Val,Range},
RangeOctsLen = byte_size(binary:encode_unsigned(Range - 1)),
BitsNeeded = per_num_bits(RangeOctsLen),
Enc = [{call,binary,encode_unsigned,[Val],Bin},
{call,erlang,byte_size,[Bin],BinSize0},
{sub,BinSize0,1,BinSize},
{'cond',[['_',
{put_bits,BinSize,BitsNeeded,[1]},
{put_bits,Bin,binary,[8,align]}]]}],
{Prefix,Check,Enc}
end.
per_enc_unconstrained(Val, Aligned) ->
case Aligned of
false -> [];
true -> [{put_bits,0,0,[1,align]}]
end ++ [{call,per_common,encode_unconstrained_number,[Val]}].
per_enc_unsigned(Val, Aligned) ->
case is_integer(Val) of
false ->
{var,VarBase} = Val,
Bin = {var,VarBase++"@bin"},
BinSize = {var,VarBase++"@bin_size"},
[{call,binary,encode_unsigned,[Val],Bin},
{call,erlang,byte_size,[Bin],BinSize}|
per_enc_length(Bin, 8, BinSize, Aligned)];
true ->
Bin = binary:encode_unsigned(Val),
Len = byte_size(Bin),
per_enc_length(Bin, 8, Len, Aligned)
end.
%% Encode a length field without any constraint.
per_enc_length(Bin, Unit, Len, Aligned) ->
U = unit(1, Aligned),
PutBits = put_bits_binary(Bin, Unit, Aligned),
EncFragmented = {call,per_common,encode_fragmented,[Bin,Unit]},
Al = case Aligned of
false -> [];
true -> [{put_bits,0,0,[1,align]}]
end,
build_cond([[{lt,Len,128},
{put_bits,Len,8,U},PutBits],
[{lt,Len,16384},
{put_bits,2,2,U},{put_bits,Len,14,[1]},PutBits],
['_'|Al++[EncFragmented]]]).
per_enc_length(Bin, Unit, Len, no, Aligned, _Type) ->
per_enc_length(Bin, Unit, Len, Aligned);
per_enc_length(Bin, Unit, Len, {{Lb,Ub},[]}, Aligned, Type) ->
{Prefix,Check,PutLen} = per_enc_constrained(Len, Lb, Ub, Aligned),
NoExt = {put_bits,0,1,[1]},
U = unit(Unit, Aligned, Type, Lb*Unit, Ub*Unit),
PutBits = [{put_bits,Bin,binary,U}],
[{'cond',ExtConds0}] = per_enc_length(Bin, Unit, Len, Aligned),
Ext = {put_bits,1,1,[1]},
ExtConds = prepend_to_cond(ExtConds0, Ext),
build_length_cond(Prefix, [[Check,NoExt|PutLen++PutBits]|ExtConds]);
per_enc_length(Bin, Unit, Len, {Lb,Ub}, Aligned, Type)
when is_integer(Lb) ->
{Prefix,Check,PutLen} = per_enc_constrained(Len, Lb, Ub, Aligned),
U = unit(Unit, Aligned, Type, Lb*Unit, Ub*Unit),
PutBits = [{put_bits,Bin,binary,U}],
build_length_cond(Prefix, [[Check|PutLen++PutBits]]);
per_enc_length(Bin, Unit0, Len, Sv, Aligned, Type) when is_integer(Sv) ->
NumBits = Sv*Unit0,
Unit = case NumBits rem 8 of
0 ->
%% Help out the alignment optimizer.
8;
_ ->
Unit0
end,
U = unit(Unit, Aligned, Type, NumBits, NumBits),
Pb = {put_bits,Bin,binary,U},
[{'cond',[[{eq,Len,Sv},Pb]]}].
enc_length(Len, no, Aligned) ->
U = unit(1, Aligned),
build_cond([[{lt,Len,128},
{put_bits,Len,8,U}],
[{lt,Len,16384},
{put_bits,2,2,U},{put_bits,Len,14,[1]}]]);
enc_length(Len, {{Lb,Ub},[]}, Aligned) ->
{Prefix,Check,PutLen} = per_enc_constrained(Len, Lb, Ub, Aligned),
NoExt = {put_bits,0,1,[1]},
[{'cond',ExtConds0}] = enc_length(Len, no, Aligned),
Ext = {put_bits,1,1,[1]},
ExtConds = prepend_to_cond(ExtConds0, Ext),
build_length_cond(Prefix, [[Check,NoExt|PutLen]|ExtConds]);
enc_length(Len, {Lb,Ub}, Aligned) when is_integer(Lb) ->
{Prefix,Check,PutLen} = per_enc_constrained(Len, Lb, Ub, Aligned),
build_length_cond(Prefix, [[Check|PutLen]]);
enc_length(Len, Sv, _Aligned) when is_integer(Sv) ->
[{'cond',[[{eq,Len,Sv}]]}].
put_bits_binary(Bin, _Unit, Aligned) when is_binary(Bin) ->
Sz = byte_size(Bin),
<<Int:Sz/unit:8>> = Bin,
{put_bits,Int,8*Sz,unit(1, Aligned)};
put_bits_binary(Bin, Unit, Aligned) ->
{put_bits,Bin,binary,unit(Unit, Aligned)}.
sub_lb(Val, 0) ->
{[],Val};
sub_lb({var,Var}=Val0, Lb) ->
Val = {var,Var++"@sub"},
{[{sub,Val0,Lb,Val}],Val};
sub_lb(Val, Lb) when is_integer(Val) ->
{[],Val-Lb}.
build_length_cond([{sub,Var0,Base,Var}]=Prefix, Cs) ->
%% Non-zero lower bound, such as: SIZE (50..200, ...)
Prefix++[{'cond',opt_length_nzlb(Cs, {Var0,Var,Base}, 0)}];
build_length_cond([], Cs) ->
%% Zero lower bound, such as: SIZE (0..200, ...)
[{'cond',opt_length_zlb(Cs, 0)}].
opt_length_zlb([[{ult,Var,Val}|Actions]|T], Ub) ->
%% Since the SIZE constraint is zero-based, Var
%% must be greater than zero, and we can use
%% the slightly cheaper signed less than operator.
opt_length_zlb([[{lt,Var,Val}|Actions]|T], Ub);
opt_length_zlb([[{lt,_,Val}|_]=H|T], Ub) ->
if
Val =< Ub ->
%% A previous test has already matched.
opt_length_zlb(T, Ub);
true ->
[H|opt_length_zlb(T, max(Ub, Val))]
end;
opt_length_zlb([H|T], Ub) ->
[H|opt_length_zlb(T, Ub)];
opt_length_zlb([], _) -> [].
opt_length_nzlb([[{ult,Var,Val}|_]=H|T], {_,Var,Base}=St, _Ub) ->
[H|opt_length_nzlb(T, St, Base+Val)];
opt_length_nzlb([[{lt,Var0,Val}|_]=H|T], {Var0,_,_}=St, Ub) ->
if
Val =< Ub ->
%% A previous test has already matched.
opt_length_nzlb(T, St, Ub);
true ->
[H|opt_length_nzlb(T, St, Val)]
end;
opt_length_nzlb([H|T], St, Ub) ->
[H|opt_length_nzlb(T, St, Ub)];
opt_length_nzlb([], _, _) -> [].
build_cond(Conds0) ->
case eval_cond(Conds0, gb_sets:empty()) of
[['_'|Actions]] ->
Actions;
Conds ->
[{'cond',Conds}]
end.
eval_cond([['_',{'cond',Cs}]], Seen) ->
eval_cond(Cs, Seen);
eval_cond([[Cond|Actions]=H|T], Seen0) ->
case gb_sets:is_element(Cond, Seen0) of
false ->
Seen = gb_sets:insert(Cond, Seen0),
case eval_cond_1(Cond) of
false ->
eval_cond(T, Seen);
true ->
[['_'|Actions]];
maybe ->
[H|eval_cond(T, Seen)]
end;
true ->
eval_cond(T, Seen0)
end;
eval_cond([], _) -> [].
eval_cond_1({ult,I,N}) when is_integer(I), is_integer(N) ->
0 =< I andalso I < N;
eval_cond_1({eq,[],[]}) ->
true;
eval_cond_1({eq,I,N}) when is_integer(I), is_integer(N) ->
I =:= N;
eval_cond_1({ge,I,N}) when is_integer(I), is_integer(N) ->
I >= N;
eval_cond_1({lt,I,N}) when is_integer(I), is_integer(N) ->
I < N;
eval_cond_1(_) -> maybe.
prepend_to_cond([H|T], Code) ->
[prepend_to_cond_1(H, Code)|prepend_to_cond(T, Code)];
prepend_to_cond([], _) -> [].
prepend_to_cond_1([Check|T], Code) ->
[Check,Code|T].
enc_char_tab(notab) ->
notab;
enc_char_tab(Tab0) ->
Tab1 = tuple_to_list(Tab0),
First = hd(Tab1),
Tab = enc_char_tab_1(Tab1, First, 0),
case lists:member(ill, Tab) of
false ->
{compact_map,{First,tuple_size(Tab0)}};
true ->
{tab,{First-1,list_to_tuple(Tab)}}
end.
enc_char_tab_1([H|T], H, I) ->
[I|enc_char_tab_1(T, H+1, I+1)];
enc_char_tab_1([_|_]=T, H, I) ->
[ill|enc_char_tab_1(T, H+1, I)];
enc_char_tab_1([], _, _) -> [].
enumerated_constraint([_]) ->
[{'SingleValue',0}];
enumerated_constraint(Root) ->
[{'ValueRange',{0,length(Root)-1}}].
per_enc_enumerated_root(NNL, Prefix, Val, Constr, Aligned) ->
per_enc_enumerated_root_1(NNL, Prefix, Val, Constr, Aligned, 0).
per_enc_enumerated_root_1([{H,_}|T], Prefix, Val, Constr, Aligned, N) ->
[[{eq,Val,H}|Prefix++per_enc_integer_1(N, Constr, Aligned)]|
per_enc_enumerated_root_1(T, Prefix, Val, Constr, Aligned, N+1)];
per_enc_enumerated_root_1([], _, _, _, _, _) -> [].
per_enc_enumerated_ext(NNL, Val, Aligned) ->
per_enc_enumerated_ext_1(NNL, Val, Aligned, 0).
per_enc_enumerated_ext_1([{H,_}|T], Val, Aligned, N) ->
[[{eq,Val,H},{put_bits,1,1,[1]}|per_enc_small_number(N, Aligned)]|
per_enc_enumerated_ext_1(T, Val, Aligned, N+1)];
per_enc_enumerated_ext_1([], _, _, _) -> [].
per_enc_small_length(Val0, Aligned) ->
{Sub,Val} = sub_lb(Val0, 1),
U = unit(1, Aligned),
Sub ++ build_cond([[{lt,Val,64},{put_bits,Val,7,[1]}],
[{lt,Val0,128},{put_bits,1,1,[1]},
{put_bits,Val0,8,U}],
['_',{put_bits,1,1,[1]},
{put_bits,2,2,U},{put_bits,Val0,14,[1]}]]).
constr_min_size(no) -> no;
constr_min_size({{Lb,_},[]}) when is_integer(Lb) -> Lb;
constr_min_size({Lb,_}) when is_integer(Lb) -> Lb;
constr_min_size(Sv) when is_integer(Sv) -> Sv.
enc_mod(false) -> uper;
enc_mod(true) -> per.
unit(U, false) -> [U];
unit(U, true) -> [U,align].
unit(U, Aligned, Type, Lb, Ub) ->
case Aligned andalso is_aligned(Type, Lb, Ub) of
true -> [U,align];
false -> [U]
end.
opt_choice(Imm) ->
{Pb,T0} = lists:splitwith(fun({put_bits,V,_,_}) when is_integer(V) ->
true;
(_) ->
false
end, Imm),
try
{Prefix,T} = split_off_nonbuilding(T0),
Prefix ++ opt_choice_1(T, Pb)
catch
throw:impossible ->
Imm
end.
opt_choice_1([{'cond',Cs0}], Pb) ->
case Cs0 of
[[C|Act]] ->
[{'cond',[[C|Pb++Act]]}];
[[C|Act],['_',{error,_}]=Error] ->
[{'cond',[[C|Pb++Act],Error]}];
_ ->
[{'cond',opt_choice_2(Cs0, Pb)}]
end;
opt_choice_1(_, _) -> throw(impossible).
opt_choice_2([[C|[{put_bits,_,_,_}|_]=Act]|T], Pb) ->
[[C|Pb++Act]|opt_choice_2(T, Pb)];
opt_choice_2([[_,{error,_}]=H|T], Pb) ->
[H|opt_choice_2(T, Pb)];
opt_choice_2([_|_], _) ->
throw(impossible);
opt_choice_2([], _) -> [].
%%%
%%% Optimize list comprehensions (SEQUENCE OF/SET OF).
%%%
opt_lc([{lc,[{call,erlang,iolist_to_binary,[Var],Bin},
{call,erlang,byte_size,[Bin],LenVar},
{'cond',[[{eq,LenVar,Len},{put_bits,Bin,_,[_|Align]}]]}],
Var,Val}]=Lc, LenImm) ->
%% Given a sequence of a fixed length string, such as
%% SEQUENCE OF OCTET STRING (SIZE (4)), attempt to rewrite to
%% a list comprehension that just checks the size, followed by
%% a conversion to binary:
%%
%% _ = [if length(Comp) =:= 4; byte_size(Comp) =:= 4 -> [] end ||
%% Comp <- Sof],
%% [align|iolist_to_binary(Sof)]
CheckImm = [{'cond',[[{eq,{expr,"length("++mk_val(Var)++")"},Len}],
[{eq,{expr,"byte_size("++mk_val(Var)++")"},Len}]]}],
Al = case Align of
[] ->
[];
[align] ->
[{put_bits,0,0,[1|Align]}]
end,
case Al =:= [] orelse
is_end_aligned(LenImm) orelse
lb_is_nonzero(LenImm) of
false ->
%% Not possible because an empty SEQUENCE OF would be
%% improperly aligned. Example:
%%
%% SEQUENCE (SIZE (0..3)) OF ...
Lc;
true ->
%% Examples:
%%
%% SEQUENCE (SIZE (1..4)) OF ...
%% (OK because there must be at least one element)
%%
%% SEQUENCE OF ...
%% (OK because the length field will force alignment)
%%
Al ++ [{lc,CheckImm,Var,Val,{var,"_"}},
{call,erlang,iolist_to_binary,[Val]}]
end;
opt_lc([{lc,ElementImm0,V,L}]=Lc, LenImm) ->
%% Attempt to hoist the alignment, putting after the length
%% and before the list comprehension:
%%
%% [Length,
%% align,
%% [Encode(Comp) || Comp <- Sof]]
%%
case enc_opt_al_1(ElementImm0, 0) of
{ElementImm,0} ->
case is_end_aligned(LenImm) orelse
(is_beginning_aligned(ElementImm0) andalso
lb_is_nonzero(LenImm)) of
false ->
%% Examples:
%%
%% SEQUENCE (SIZE (0..3)) OF OCTET STRING
%% (An empty SEQUENCE OF would be improperly aligned)
%%
%% SEQUENCE (SIZE (1..3)) OF OCTET STRING (SIZE (0..4))
%% (There would be an improper alignment before the
%% first element)
Lc;
true ->
%% Examples:
%%
%% SEQUENCE OF INTEGER
%% SEQUENCE (SIZE (1..4)) OF INTEGER
%% SEQUENCE (SIZE (1..4)) OF INTEGER (0..256)
[{put_bits,0,0,[1,align]},{lc,ElementImm,V,L}]
end;
_ ->
%% Unknown alignment, no alignment, or not aligned at the end.
%% Examples:
%%
%% SEQUENCE OF SomeConstructedType
%% SEQUENCE OF INTEGER (0..15)
Lc
end.
is_beginning_aligned([{'cond',Cs}]) ->
lists:all(fun([_|Act]) -> is_beginning_aligned(Act) end, Cs);
is_beginning_aligned([{error,_}|_]) -> true;
is_beginning_aligned([{put_bits,_,_,U}|_]) ->
case U of
[_,align] -> true;
[_] -> false
end;
is_beginning_aligned(Imm0) ->
case split_off_nonbuilding(Imm0) of
{[],_} -> false;
{[_|_],Imm} -> is_beginning_aligned(Imm)
end.
is_end_aligned(Imm) ->
case enc_opt_al_1(Imm, unknown) of
{_,0} -> true;
{_,_} -> false
end.
lb_is_nonzero([{sub,_,_,_}|_]) -> true;
lb_is_nonzero(_) -> false.
%%%
%%% Attempt to combine two chunks of intermediate code.
%%%
combine_imms(ImmA0, ImmB0) ->
{Prefix0,ImmA} = split_off_nonbuilding(ImmA0),
{Prefix1,ImmB} = split_off_nonbuilding(ImmB0),
Prefix = Prefix0 ++ Prefix1,
Combined = do_combine(ImmA ++ ImmB, 3.0),
Prefix ++ Combined.
do_combine([{error,_}=Imm|_], _Budget) ->
[Imm];
do_combine([{'cond',Cs0}|T], Budget0) ->
Budget = debit(Budget0, num_clauses(Cs0, 0)),
Cs = [[C|do_combine(Act++T, Budget)] || [C|Act] <- Cs0],
[{'cond',Cs}];
do_combine([{put_bits,V,_,_}|_]=L, Budget) when is_integer(V) ->
{Pb,T} = collect_put_bits(L),
do_combine_put_bits(Pb, T,Budget);
do_combine(_, _) ->
throw(impossible).
do_combine_put_bits(Pb, [], _Budget) ->
Pb;
do_combine_put_bits(Pb, [{'cond',Cs0}|T], Budget) ->
Cs = [case Act of
[{error,_}] ->
[C|Act];
_ ->
[C|do_combine(Pb++Act, Budget)]
end || [C|Act] <- Cs0],
do_combine([{'cond',Cs}|T], Budget);
do_combine_put_bits(_, _, _) ->
throw(impossible).
debit(Budget0, Alternatives) ->
case Budget0 - log2(Alternatives) of
Budget when Budget > 0.0 ->
Budget;
_ ->
throw(impossible)
end.
num_clauses([[_,{error,_}]|T], N) ->
num_clauses(T, N);
num_clauses([_|T], N) ->
num_clauses(T, N+1);
num_clauses([], N) -> N.
log2(N) ->
math:log(N) / math:log(2.0).
collect_put_bits(Imm) ->
lists:splitwith(fun({put_bits,V,_,_}) when is_integer(V) -> true;
(_) -> false
end, Imm).
%%%
%%% Simple common subexpression elimination to avoid fetching
%%% the same element twice.
%%%
enc_cse([{call,erlang,element,Args,V}=H|T]) ->
[H|enc_cse_1(T, Args, V)];
enc_cse(Imm) -> Imm.
enc_cse_1([{call,erlang,element,Args,Dst}|T], Args, V) ->
[{set,V,Dst}|enc_cse_1(T, Args, V)];
enc_cse_1([{block,Bl}|T], Args, V) ->
[{block,enc_cse_1(Bl, Args, V)}|enc_cse_1(T, Args, V)];
enc_cse_1([H|T], Args, V) ->
[H|enc_cse_1(T, Args, V)];
enc_cse_1([], _, _) -> [].
%%%
%%% Pre-process the intermediate code to simplify code generation.
%%%
enc_pre_cg(Imm) ->
enc_pre_cg_1(Imm, outside_list, in_seq).
enc_pre_cg_1([], _StL, _StB) ->
nil;
enc_pre_cg_1([H], StL, StB) ->
enc_pre_cg_2(H, StL, StB);
enc_pre_cg_1([H0|T0], StL, StB) ->
case is_nonbuilding(H0) of
true ->
H = enc_pre_cg_nonbuilding(H0, StL),
Seq = {seq,H,enc_pre_cg_1(T0, StL, in_seq)},
case StB of
outside_seq -> {block,Seq};
in_seq -> Seq
end;
false ->
H = enc_pre_cg_2(H0, in_head, outside_seq),
T = enc_pre_cg_1(T0, in_tail, outside_seq),
enc_make_cons(H, T)
end.
enc_pre_cg_2(align, StL, _StB) ->
case StL of
in_head -> align;
in_tail -> {cons,align,nil}
end;
enc_pre_cg_2({apply,_,_}=Imm, _, _) ->
Imm;
enc_pre_cg_2({block,Bl0}, StL, StB) ->
enc_pre_cg_1(Bl0, StL, StB);
enc_pre_cg_2({call,_,_,_}=Imm, _, _) ->
Imm;
enc_pre_cg_2({call_gen,_,_,_,_,_}=Imm, _, _) ->
Imm;
enc_pre_cg_2({'cond',Cs0}, StL, _StB) ->
Cs = [{C,enc_pre_cg_1(Act, StL, outside_seq)} || [C|Act] <- Cs0],
{'cond',Cs};
enc_pre_cg_2({error,_}=E, _, _) ->
E;
enc_pre_cg_2({lc,B0,V,L}, StL, _StB) ->
B = enc_pre_cg_1(B0, StL, outside_seq),
{lc,B,V,L};
enc_pre_cg_2({put_bits,V,8,[1]}, StL, _StB) ->
case StL of
in_head -> {integer,V};
in_tail -> {cons,{integer,V},nil};
outside_list -> {cons,{integer,V},nil}
end;
enc_pre_cg_2({put_bits,V,binary,_}, _StL, _StB) ->
V;
enc_pre_cg_2({put_bits,_,_,[_]}=PutBits, _StL, _StB) ->
{binary,[PutBits]};
enc_pre_cg_2({var,_}=Imm, _, _) -> Imm.
enc_make_cons({binary,H}, {binary,T}) ->
{binary,H++T};
enc_make_cons({binary,H0}, {cons,{binary,H1},T}) ->
enc_make_cons({binary,H0++H1}, T);
enc_make_cons({binary,H}, {cons,{integer,Int},T}) ->
enc_make_cons({binary,H++[{put_bits,Int,8,[1]}]}, T);
enc_make_cons({integer,Int}, {binary,T}) ->
{binary,[{put_bits,Int,8,[1]}|T]};
enc_make_cons({integer,Int}, {cons,{binary,H},T}) ->
enc_make_cons({binary,[{put_bits,Int,8,[1]}|H]}, T);
enc_make_cons(H, T) ->
{cons,H,T}.
enc_pre_cg_nonbuilding({lc,B0,Var,List,Dst}, StL) ->
B = enc_pre_cg_1(B0, StL, outside_seq),
{lc,B,Var,List,Dst};
enc_pre_cg_nonbuilding({list,List0,Dst}, _StL) ->
List = enc_pre_cg_1(List0, outside_list, outside_seq),
{list,List,Dst};
enc_pre_cg_nonbuilding({'try',Try0,{P,Succ0},Else0,Dst}, StL) ->
Try = enc_pre_cg_1(Try0, StL, outside_seq),
Succ = enc_pre_cg_1(Succ0, StL, outside_seq),
Else = enc_pre_cg_1(Else0, StL, outside_seq),
{'try',Try,{P,Succ},Else,Dst};
enc_pre_cg_nonbuilding(Imm, _) -> Imm.
%%%
%%% Optimize calls to complete/1 and surrounding code. There are
%%% several opportunities for optimizations.
%%%
%%% It may be possible to replace the call to complete/1 with
%%% something cheaper (most important for the PER back-end which has
%%% an expensive complete/1 implementation). If we can be sure that
%%% complete/1 will be called with an iolist (no 'align' atoms or
%%% bitstrings in the list), we can call iolist_to_binary/1
%%% instead. If the list may include bitstrings, we can can call
%%% list_to_bitstring/1 (note that list_to_bitstring/1 does not accept
%%% a binary or bitstring, so we MUST be sure that we only pass it a
%%% list). If complete/1 is called with a binary, we can omit the
%%% call altogether.
%%%
%%% A call to byte_size/1 that follows complete/1 can be eliminated
%%% if the size of the binary produced by complete/1 can be determined
%%% and is constant.
%%%
%%% The code that encodes the length descriptor (a 'cond' instruction)
%%% for a binary produced by complete/1 can be simplified if the lower
%%% and upper bounds for the size of the binary are known.
%%%
-record(ost,
{sym,
t
}).
enc_opt(Imm0) ->
{Imm,_} = enc_opt(Imm0, #ost{sym=gb_trees:empty()}),
Imm.
enc_opt(align, St) ->
{align,St#ost{t=t_align({0,7})}};
enc_opt({apply,What,As}, St) ->
{{apply,What,subst_list(As, St)},St#ost{t=t_any()}};
enc_opt({assign,_,_}=Imm, St) ->
{Imm,St};
enc_opt({binary,PutBits0}, St) ->
PutBits = [{put_bits,subst(V, St),Sz,F} ||
{put_bits,V,Sz,F} <- PutBits0],
NumBits = lists:foldl(fun({put_bits,_,Bits,_}, Sum) ->
Sum+Bits
end, 0, PutBits),
{{binary,PutBits},St#ost{t=t_bitstring(NumBits)}};
enc_opt({block,Bl0}, St0) ->
{Bl,St} = enc_opt(Bl0, St0),
{{block,Bl},St};
enc_opt({call,binary,encode_unsigned,[Int],Bin}=Imm, St0) ->
Type = get_type(Int, St0),
St = case t_range(Type) of
any ->
set_type(Bin, t_binary(), St0);
{Lb0,Ub0} ->
Lb = bit_size(binary:encode_unsigned(Lb0)),
Ub = bit_size(binary:encode_unsigned(Ub0)),
set_type(Bin, t_binary({Lb,Ub}), St0)
end,
{Imm,St};
enc_opt({call,erlang,bit_size,[Bin],Dst}=Imm0, St0) ->
Type = get_type(Bin, St0),
case t_range(Type) of
any ->
St1 = set_type(Bin, t_bitstring(), St0),
St = propagate(Dst,
fun(T, S) ->
bit_size_propagate(Bin, T, S)
end, St1),
{Imm0,St};
{Lb,Ub}=Range ->
St = set_type(Dst, t_integer(Range), St0),
Imm = case Lb of
Ub -> none;
_ -> Imm0
end,
{Imm,St}
end;
enc_opt({call,erlang,byte_size,[Bin],Dst}=Imm0, St0) ->
Type = get_type(Bin, St0),
case t_range(Type) of
any ->
St1 = set_type(Bin, t_binary(), St0),
St = propagate(Dst,
fun(T, S) ->
byte_size_propagate(Bin, T, S)
end, St1),
{Imm0,St};
{Lb0,Ub0} ->
Lb = (Lb0+7) div 8,
Ub = (Ub0+7) div 8,
St = set_type(Dst, t_integer({Lb,Ub}), St0),
Imm = case Lb of
Ub -> none;
_ -> Imm0
end,
{Imm,St}
end;
enc_opt({call,erlang,iolist_to_binary,_}=Imm, St) ->
{Imm,St#ost{t=t_binary()}};
enc_opt({call,erlang,length,[List],Dst}=Imm0, St0) ->
St1 = propagate(Dst,
fun(T, S) ->
length_propagate(List, T, S)
end, St0),
{Imm0,St1};
enc_opt({call,per,complete,[Data],Dst}, St0) ->
Type = get_type(Data, St0),
St = set_type(Dst, t_binary(t_range(Type)), St0),
case t_type(Type) of
binary ->
{{set,Data,Dst},St};
bitlist ->
%% We KNOW that list_to_bitstring/1 will construct
%% a binary (the number of bits is divisible by 8)
%% because per_enc_open_type/2 added an 'align' atom
%% at the end. If that 'align' atom had not been
%% optimized away, the type would have been 'align'
%% instead of 'bitlist'.
{{call,erlang,list_to_bitstring,[Data],Dst},St};
iolist ->
{{call,erlang,iolist_to_binary,[Data],Dst},St};
nil ->
Imm = {list,{binary,[{put_bits,0,8,[1]}]},Dst},
enc_opt(Imm, St0);
_ ->
{{call,per,complete,[Data],Dst},St}
end;
enc_opt({call,uper,complete,[Data],Dst}, St0) ->
Type = get_type(Data, St0),
St = set_type(Dst, t_binary(t_range(Type)), St0),
case t_type(Type) of
binary ->
{{set,Data,Dst},St0};
iolist ->
{{call,erlang,iolist_to_binary,[Data],Dst},St};
nil ->
Imm = {list,{binary,[{put_bits,0,8,[1]}]},Dst},
enc_opt(Imm, St0);
_ ->
%% 'bitlist' or 'any'.
{{call,uper,complete,[Data],Dst},St}
end;
enc_opt({call,per_common,encode_chars,[List,NumBits|_],Dst}=Imm, St0) ->
%% Note: Never used when NumBits =:= 8 (list_to_binary/1 will
%% be used instead).
St1 = set_type(Dst, t_bitstring(), St0),
St = propagate(List,
fun(T, S) ->
char_propagate(Dst, T, NumBits, S)
end, St1),
{Imm,St};
enc_opt({call,per_common,encode_chars_16bit,[List],Dst}=Imm, St0) ->
St1 = set_type(Dst, t_binary(), St0),
St = propagate(List,
fun(T, S) ->
char_propagate(Dst, T, 16, S)
end, St1),
{Imm,St};
enc_opt({call,per_common,encode_big_chars,[List],Dst}=Imm, St0) ->
St1 = set_type(Dst, t_binary(), St0),
St = propagate(List,
fun(T, S) ->
char_propagate(Dst, T, 32, S)
end, St1),
{Imm,St};
enc_opt({call,per_common,encode_fragmented,[_,Unit]}=Imm, St) ->
T = case Unit rem 8 of
0 -> t_iolist();
_ -> t_bitlist()
end,
{Imm,St#ost{t=T}};
enc_opt({call,per_common,encode_unconstrained_number,_}=Imm, St) ->
{Imm,St#ost{t=t_iolist()}};
enc_opt({call,per_common,bitstring_from_positions,_}=Imm, St) ->
{Imm,St#ost{t=t_bitstring()}};
enc_opt({call,per_common,to_named_bitstring,_}=Imm, St) ->
{Imm,St#ost{t=t_bitstring()}};
enc_opt({call,_,_,_}=Imm, St) ->
{Imm,St#ost{t=t_any()}};
enc_opt({call,_,_,_,_}=Imm, St) ->
{Imm,St#ost{t=undefined}};
enc_opt({call_gen,N,K,F,L,As}, St) ->
{{call_gen,N,K,F,L,subst(As, St)},St#ost{t=t_any()}};
enc_opt({'cond',Cs0}, St0) ->
case enc_opt_cs(Cs0, St0) of
[{'_',Imm,Type}] ->
{Imm,St0#ost{t=Type}};
[{Cond,Imm,Type0}|Cs1] ->
{Cs,Type} = enc_opt_cond_1(Cs1, Type0, [{Cond,Imm}]),
{{'cond',Cs},St0#ost{t=Type}}
end;
enc_opt({cons,H0,T0}, St0) ->
{H,#ost{t=TypeH}=St1} = enc_opt(H0, St0),
{T,#ost{t=TypeT}=St} = enc_opt(T0, St1),
{{cons,H,T},St#ost{t=t_cons(TypeH, TypeT)}};
enc_opt({error,_}=Imm, St) ->
{Imm,St#ost{t=t_any()}};
enc_opt({integer,V}, St) ->
{{integer,subst(V, St)},St#ost{t=t_integer()}};
enc_opt({lc,E0,B,C}, St) ->
{E,_} = enc_opt(E0, St),
{{lc,E,B,C},St#ost{t=t_any()}};
enc_opt({lc,E0,B,C,Dst}, St) ->
{E,_} = enc_opt(E0, St),
{{lc,E,B,C,Dst},St#ost{t=undefined}};
enc_opt({list,Imm0,Dst}, St0) ->
{Imm,#ost{t=Type}=St1} = enc_opt(Imm0, St0),
St = set_type(Dst, Type, St1),
{{list,Imm,Dst},St#ost{t=undefined}};
enc_opt(nil, St) ->
{nil,St#ost{t=t_nil()}};
enc_opt({seq,H0,T0}, St0) ->
{H,St1} = enc_opt(H0, St0),
{T,St} = enc_opt(T0, St1),
case {H,T} of
{none,_} ->
{T,St};
{{list,Imm,Data},
{seq,{call,per,complete,[Data],_},_}} ->
%% Get rid of any explicit 'align' added by per_enc_open_type/2.
{{seq,{list,remove_trailing_align(Imm),Data},T},St};
{_,_} ->
{{seq,H,T},St}
end;
enc_opt({set,_,_}=Imm, St) ->
{Imm,St#ost{t=undefined}};
enc_opt({sub,Src0,Int,Dst}, St0) ->
Src = subst(Src0, St0),
Type = get_type(Src, St0),
St = case t_range(Type) of
any ->
propagate(Dst,
fun(T, S) ->
set_type(Src, t_add(T, Int), S)
end,
St0);
{Lb,Ub} ->
set_type(Dst, t_integer({Lb-Int,Ub-Int}), St0)
end,
{{sub,Src,Int,Dst},St#ost{t=undefined}};
enc_opt({'try',Try0,{P,Succ0},Else0,Dst}, St0) ->
{Try,_} = enc_opt(Try0, St0),
{Succ,_} = enc_opt(Succ0, St0),
{Else,_} = enc_opt(Else0, St0),
{{'try',Try,{P,Succ},Else,Dst},St0#ost{t=undefined}};
enc_opt({var,_}=Imm, St) ->
Type = get_type(Imm, St),
{subst(Imm, St),St#ost{t=Type}}.
remove_trailing_align({block,Bl}) ->
{block,remove_trailing_align(Bl)};
remove_trailing_align({cons,H,{cons,align,nil}}) ->
H;
remove_trailing_align({seq,H,T}) ->
{seq,H,remove_trailing_align(T)};
remove_trailing_align(Imm) -> Imm.
bit_size_propagate(Bin, Type, St) ->
case t_range(Type) of
any ->
St;
{Lb,Ub} ->
set_type(Bin, t_bitstring({Lb,Ub}), St)
end.
byte_size_propagate(Bin, Type, St) ->
case t_range(Type) of
any ->
St;
{Lb,Ub} ->
set_type(Bin, t_binary({Lb*8,Ub*8}), St)
end.
char_propagate(Dst, T, NumBits, St) ->
case t_range(T) of
any ->
St;
{Sz,Sz} when Sz*NumBits rem 8 =:= 0 ->
Bits = Sz*NumBits,
set_type(Dst, t_binary({Bits,Bits}), St);
{Lb,Ub} ->
Range = {Lb*NumBits,Ub*NumBits},
case NumBits rem 8 of
0 ->
set_type(Dst, t_binary(Range), St);
_ ->
set_type(Dst, t_bitstring(Range), St)
end
end.
length_propagate(List, Type, St) ->
set_type(List, t_list(t_range(Type)), St).
enc_opt_cond_1([{Cond,{error,_}=Imm,_}|T], St, Acc) ->
enc_opt_cond_1(T, St, [{Cond,Imm}|Acc]);
enc_opt_cond_1([{Cond,Imm,Curr0}|T], Curr1, Acc) ->
Curr = t_join(Curr0, Curr1),
enc_opt_cond_1(T, Curr, [{Cond,Imm}|Acc]);
enc_opt_cond_1([], St, Acc) ->
{lists:reverse(Acc),St}.
enc_opt_cs([{Cond,Imm0}|T], St0) ->
case eo_eval_cond(Cond, St0) of
false ->
enc_opt_cs(T, St0);
true ->
{Imm,#ost{t=Type}} = enc_opt(Imm0, St0),
[{'_',Imm,Type}];
maybe ->
St = update_type_info(Cond, St0),
{Imm,#ost{t=Type}} = enc_opt(Imm0, St),
[{Cond,Imm,Type}|enc_opt_cs(T, St0)]
end;
enc_opt_cs([], _) -> [].
eo_eval_cond('_', _) ->
true;
eo_eval_cond({Op,{var,_}=Var,Val}, St) ->
Type = get_type(Var, St),
case t_range(Type) of
any -> maybe;
{_,_}=Range -> eval_cond_range(Op, Range, Val)
end;
eo_eval_cond({_Op,{expr,_},_Val}, _St) -> maybe.
eval_cond_range(lt, {Lb,Ub}, Val) ->
if
Ub < Val -> true;
Val =< Lb -> false;
true -> maybe
end;
eval_cond_range(_Op, _Range, _Val) -> maybe.
update_type_info({ult,{var,_}=Var,Val}, St) ->
Int = t_integer({0,Val-1}),
Type = t_meet(get_type(Var, St), Int),
set_type(Var, Type, St);
update_type_info({lt,{var,_}=Var,Val}, St) ->
Int = t_integer({0,Val-1}),
Type = t_meet(get_type(Var, St), Int),
set_type(Var, Type, St);
update_type_info({eq,{var,_}=Var,Val}, St) when is_integer(Val) ->
Int = t_integer(Val),
Type = t_meet(get_type(Var, St), Int),
set_type(Var, Type, St);
update_type_info({eq,_,_}, St) ->
St;
update_type_info({ge,_,_}, St) -> St.
subst_list(As, St) ->
[subst(A, St) || A <- As].
subst({var,_}=Var, St) ->
Type = get_type(Var, St),
case t_type(Type) of
integer ->
case t_range(Type) of
any -> Var;
{Val,Val} -> Val;
{_,_} -> Var
end;
_ ->
Var
end;
subst(V, _St) -> V.
set_type({var,Var}, {_,_}=Type, #ost{sym=Sym0}=St0) ->
Sym1 = gb_trees:enter(Var, Type, Sym0),
case gb_trees:lookup({propagate,Var}, Sym1) of
none ->
St0#ost{sym=Sym1};
{value,Propagate} ->
Sym = gb_trees:delete({propagate,Var}, Sym1),
St = St0#ost{sym=Sym},
Propagate(Type, St)
end.
get_type({var,V}, #ost{sym=Sym}) ->
case gb_trees:lookup(V, Sym) of
none -> t_any();
{value,T} -> T
end.
propagate({var,Var}, Propagate, #ost{sym=Sym0}=St) when is_function(Propagate, 2) ->
Sym = gb_trees:enter({propagate,Var}, Propagate, Sym0),
St#ost{sym=Sym}.
%%%
%%% A simple type system.
%%%
%%% Each type descriptions is a tuple {Type,Range}.
%%% Type is one of the following atoms:
%%%
%%% Type name Description
%%% --------- -----------
%%% any Anything.
%%%
%%% align Basically iodata, but the list may contain bitstrings
%%% and the the atom 'align'. Can be passed to complete/1
%%% to construct a binary. Only used for aligned PER (per).
%%%
%%% bitstring An Erlang bitstring.
%%%
%%% bitlist A list that may be passed to list_to_bitstring/1 to
%%% construct a bitstring.
%%% NOTE: When analysing aligned PER (per), the number
%%% of bits in the bitlist is always divisible by 8 (if
%%% not, the type will be 'align' instead).
%%%
%%% binary An Erlang binary (the number of bits is divisible by 8).
%%%
%%% iolist An Erlang iolist.
%%%
%%% nil []
%%%
%%% integer An integer.
%%%
%%%
%%% Range is one of:
%%%
%%% any
%%% {LowerBound,UpperBound}
%%%
%%%
t_align(Range) ->
{align,t__range(Range)}.
t_any() ->
{any,any}.
t_binary() ->
{binary,any}.
t_binary(Range) ->
{binary,t__range(Range)}.
t_bitlist() ->
{bitlist,any}.
t_bitstring() ->
{bitstring,any}.
t_bitstring(Range0) ->
case t__range(Range0) of
{Bits,Bits}=Range when Bits rem 8 =:= 0 ->
{binary,Range};
Range ->
{bitstring,Range}
end.
t_add({integer,{Lb,Ub}}, N) ->
{integer,{Lb+N,Ub+N}}.
t_cons({_,_}=T1, {_,_}=T2) ->
T = case {t__cons_type(T1),t__cons_type(T2)} of
{_,any} -> any;
{any,_} -> any;
{align,_} -> align;
{_,align} -> align;
{binary,binary} -> iolist;
{binary,bitstring} -> bitlist;
{bitstring,binary} -> bitlist;
{bitstring,bitstring} -> bitlist
end,
{T,t__cons_ranges(t__cons_range(T1), t__cons_range(T2))}.
t_integer() ->
{integer,any}.
t_integer(Range) ->
{integer,t__range(Range)}.
t_iolist() ->
{iolist,any}.
t_list(Range) ->
{list,t__range(Range)}.
t_nil() ->
{nil,{0,0}}.
t_meet({T1,Range1}, {T2,Range2}) ->
{t_meet_types(T1, T2),t_meet_ranges(Range1, Range2)}.
t_meet_types(integer, integer) -> integer;
t_meet_types(any, integer) -> integer.
t_meet_ranges(any, Range) ->
Range;
t_meet_ranges({Lb1,Ub1}, {Lb2,Ub2}) ->
if
Lb1 =< Ub2, Lb2 =< Ub1 ->
{max(Lb1, Lb2),Ub1};
Lb2 =< Ub1, Lb1 =< Ub2 ->
{max(Lb1, Lb2),Ub2}
end.
t_join({T1,Range1}, {T2,Range2}) ->
T = t_join_types(lists:sort([T1,T2])),
Range = t_join_ranges(Range1, Range2),
{T,Range}.
t_join_ranges({Lb1,Ub1}, {Lb2,Ub2}) ->
{min(Lb1, Lb2),max(Ub1, Ub2)};
t_join_ranges(any, _) -> any;
t_join_ranges(_, any) -> any.
t_join_types([T,T]) -> T;
t_join_types([align,any]) -> any;
t_join_types([align,_]) -> align;
t_join_types([any,_]) -> any;
t_join_types([bitlist,bitstring]) -> any;
t_join_types([bitlist,integer]) -> any;
t_join_types([bitlist,iolist]) -> bitlist;
t_join_types([bitlist,nil]) -> bitlist;
t_join_types([binary,bitlist]) -> bitlist;
t_join_types([binary,bitstring]) -> bitstring;
t_join_types([binary,integer]) -> binary;
t_join_types([binary,iolist]) -> iolist;
t_join_types([binary,nil]) -> iolist;
t_join_types([bitstring,integer]) -> any;
t_join_types([bitstring,iolist]) -> any;
t_join_types([bitstring,nil]) -> any;
t_join_types([integer,_]) -> any;
t_join_types([iolist,nil]) -> iolist.
t_type({T,_}) -> T.
t_range({_,Range}) -> Range.
t__cons_type({align,_}) -> align;
t__cons_type({any,_}) -> any;
t__cons_type({binary,_}) -> binary;
t__cons_type({bitstring,_}) -> bitstring;
t__cons_type({bitlist,_}) -> bitstring;
t__cons_type({integer,_}) -> binary;
t__cons_type({iolist,_}) -> binary;
t__cons_type({nil,_}) -> binary.
t__cons_range({integer,_}) -> {8,8};
t__cons_range({_,Range}) -> Range.
t__cons_ranges({Lb1,Ub1}, {Lb2,Ub2}) ->
{Lb1+Lb2,Ub1+Ub2};
t__cons_ranges(any, _) -> any;
t__cons_ranges(_, any) -> any.
t__range({Lb,Ub}=Range) when is_integer(Lb), is_integer(Ub) ->
Range;
t__range(any) ->
any;
t__range(Val) when is_integer(Val) ->
{Val,Val}.
%%%
%%% Code generation for encoding.
%%%
enc_cg({cons,_,_}=Cons) ->
enc_cg_cons(Cons);
enc_cg({block,Imm}) ->
emit(["begin",nl]),
enc_cg(Imm),
emit([nl,
"end"]);
enc_cg({seq,First,Then}) ->
enc_cg(First),
emit([com,nl]),
enc_cg(Then);
enc_cg(align) ->
emit(align);
enc_cg({apply,F0,As0}) ->
As = enc_call_args(As0, ""),
case F0 of
{local,F,_} when is_atom(F) ->
emit([{asis,F},"(",As,")"]);
{M,F,_} ->
emit([{asis,M},":",{asis,F},"(",As,")"])
end;
enc_cg({assign,Dst0,Expr}) ->
Dst = mk_val(Dst0),
emit([Dst," = ",Expr]);
enc_cg({binary,PutBits}) ->
emit(["<<",enc_cg_put_bits(PutBits, ""),">>"]);
enc_cg({call,M,F,As0}) ->
As = [mk_val(A) || A <- As0],
asn1ct_func:call(M, F, As);
enc_cg({call,M,F,As0,Dst}) ->
As = [mk_val(A) || A <- As0],
emit([mk_val(Dst)," = "]),
asn1ct_func:call(M, F, As);
enc_cg({call_gen,Prefix,Key,Gen,_,As0}) ->
As = [mk_val(A) || A <- As0],
asn1ct_func:call_gen(Prefix, Key, Gen, As);
enc_cg({'cond',Cs}) ->
enc_cg_cond(Cs);
enc_cg({error,Error}) when is_function(Error, 0) ->
Error();
enc_cg({error,Var0}) ->
Var = mk_val(Var0),
emit(["exit({error,{asn1,{illegal_value,",Var,"}}})"]);
enc_cg({integer,Int}) ->
emit(mk_val(Int));
enc_cg({lc,Body,Var,List}) ->
emit("["),
enc_cg(Body),
emit([" || ",mk_val(Var)," <- ",mk_val(List),"]"]);
enc_cg({lc,Body,Var,List,Dst}) ->
emit([mk_val(Dst)," = ["]),
enc_cg(Body),
emit([" || ",mk_val(Var)," <- ",mk_val(List),"]"]);
enc_cg({list,List,Dst}) ->
emit([mk_val(Dst)," = "]),
enc_cg(List);
enc_cg(nil) ->
emit("[]");
enc_cg({sub,Src0,Int,Dst0}) ->
Src = mk_val(Src0),
Dst = mk_val(Dst0),
emit([Dst," = ",Src," - ",Int]);
enc_cg({set,{var,Src},{var,Dst}}) ->
emit([Dst," = ",Src]);
enc_cg({'try',Try,{P,Succ},Else,Dst}) ->
emit([mk_val(Dst)," = try "]),
enc_cg(Try),
emit([" of",nl,
mk_val(P)," ->",nl]),
enc_cg(Succ),
emit([nl,
"catch throw:invalid ->",nl]),
enc_cg(Else),
emit([nl,
"end"]);
enc_cg({var,V}) ->
emit(V).
enc_cg_cons(Cons) ->
emit("["),
enc_cg_cons_1(Cons),
emit("]").
enc_cg_cons_1({cons,H,{cons,_,_}=T}) ->
enc_cg(H),
emit([com,nl]),
enc_cg_cons_1(T);
enc_cg_cons_1({cons,H,nil}) ->
enc_cg(H);
enc_cg_cons_1({cons,H,T}) ->
enc_cg(H),
emit("|"),
enc_cg(T).
enc_call_args([A|As], Sep) ->
[Sep,mk_val(A)|enc_call_args(As, ", ")];
enc_call_args([], _) -> [].
enc_cg_cond(Cs) ->
emit("if "),
enc_cg_cond(Cs, ""),
emit([nl,
"end"]).
enc_cg_cond([C|Cs], Sep) ->
emit(Sep),
enc_cg_cond_1(C),
enc_cg_cond(Cs, [";",nl]);
enc_cg_cond([], _) -> ok.
enc_cg_cond_1({Cond,Action}) ->
enc_cond_term(Cond),
emit([" ->",nl]),
enc_cg(Action).
enc_cond_term('_') ->
emit("true");
enc_cond_term({ult,Var0,Int}) ->
Var = mk_val(Var0),
N = uper_num_bits(Int),
case 1 bsl N of
Int ->
emit([Var," bsr ",N," =:= 0"]);
_ ->
emit(["0 =< ",Var,", ",Var," < ",Int])
end;
enc_cond_term({eq,Var0,Term}) ->
Var = mk_val(Var0),
emit([Var," =:= ",{asis,Term}]);
enc_cond_term({ge,Var0,Int}) ->
Var = mk_val(Var0),
emit([Var," >= ",Int]);
enc_cond_term({lt,Var0,Int}) ->
Var = mk_val(Var0),
emit([Var," < ",Int]).
enc_cg_put_bits([{put_bits,Val0,N,[1]}|T], Sep) ->
Val = mk_val(Val0),
[[Sep,Val,":",integer_to_list(N)]|enc_cg_put_bits(T, ",")];
enc_cg_put_bits([], _) -> [].
mk_val({var,Str}) -> Str;
mk_val({expr,Str}) -> Str;
mk_val(Int) when is_integer(Int) -> integer_to_list(Int);
mk_val(Other) -> {asis,Other}.
%%%
%%% Generate a function that maps a name of a bit position
%%% to the bit position.
%%%
bit_string_name2pos_fun(NNL, Src) ->
{call_gen,"bit_string_name2pos_",NNL,
fun(Fd, Name) -> gen_name2pos(Fd, Name, NNL) end,[],[Src]}.
gen_name2pos(Fd, Name, Names) ->
Cs0 = gen_name2pos_cs(Names, Name),
Cs = Cs0 ++ [bit_clause(Name),nil_clause(),invalid_clause()],
F = {function,1,Name,1,Cs},
file:write(Fd, [erl_pp:function(F)]).
gen_name2pos_cs([{K,V}|T], Name) ->
P = [{cons,0,{atom,0,K},{var,0,'T'}}],
B = [{cons,0,{integer,0,V},{call,0,{atom,0,Name},[{var,0,'T'}]}}],
[{clause,0,P,[],B}|gen_name2pos_cs(T, Name)];
gen_name2pos_cs([], _) -> [].
bit_clause(Name) ->
VarT = {var,0,'T'},
VarPos = {var,0,'Pos'},
P = [{cons,0,{tuple,0,[{atom,0,bit},VarPos]},VarT}],
G = [[{call,0,{atom,0,is_integer},[VarPos]}]],
B = [{cons,0,VarPos,{call,0,{atom,0,Name},[VarT]}}],
{clause,0,P,G,B}.
nil_clause() ->
P = B = [{nil,0}],
{clause,0,P,[],B}.
invalid_clause() ->
P = [{var,0,'_'}],
B = [{call,0,{atom,0,throw},[{atom,0,invalid}]}],
{clause,0,P,[],B}.
%%%
%%% Hoist alignment to reduce the number of list elements in
%%% encode. Fewer lists elements means faster traversal in
%%% complete/{2,3}.
%%%
%%% For example, the following data sequence:
%%%
%%% [align,<<1:1,0:1>>,[align,<<Len:16>>|Data]]
%%%
%%% can be rewritten to:
%%%
%%% [align,<<1:1,0:1,0:6>>,[<<Len:16>>|Data]]
%%%
%%% The change from the literal <<1:1,0:1>> to <<1:1,0:1,0:6>>
%%% comes for free, and we have eliminated one element of the
%%% sub list.
%%%
%%% We must be careful not to rewrite:
%%%
%%% [<<1:1,0:1>>,[align,<<Len:16>>|Data]]
%%%
%%% to:
%%%
%%% [[<<1:1,0:1>>,align],[<<Len:16>>|Data]]
%%%
%%% because even though [<<1:0,0:1>>,align] is a literal and does
%%% not add any additional construction cost, there is one more
%%% sub list that needs to be traversed.
%%%
enc_hoist_align(Imm0) ->
Imm = enc_hoist_align_reverse(Imm0, []),
enc_hoist_align(Imm, false, []).
enc_hoist_align_reverse([H|T], Acc) ->
case enc_opt_al_1([H], 0) of
{[H],_} ->
enc_hoist_align_reverse(T, [H|Acc]);
{_,_} ->
lists:reverse(T, [H,stop|Acc])
end;
enc_hoist_align_reverse([], Acc) -> Acc.
enc_hoist_align([stop|T], _Aligned, Acc) ->
lists:reverse(T, Acc);
enc_hoist_align([{block,Bl0}|T], Aligned, Acc) ->
Bl = case Aligned of
false -> Bl0;
true -> enc_hoist_block(Bl0)
end,
case is_beginning_aligned(Bl) of
false ->
enc_hoist_align(T, false, [{block,Bl}|Acc]);
true ->
enc_hoist_align(T, true, [{put_bits,0,0,[1,align]},
{block,Bl}|Acc])
end;
enc_hoist_align([H|T], _, Acc) ->
enc_hoist_align(T, false, [H|Acc]);
enc_hoist_align([], _, Acc) -> Acc.
enc_hoist_block(Bl) ->
try
enc_hoist_block_1(lists:reverse(Bl))
catch
throw:impossible ->
Bl
end.
enc_hoist_block_1([{'cond',Cs0}|T]) ->
Cs = [[C|enc_hoist_block_2(Act)] || [C|Act] <- Cs0],
H = {'cond',Cs},
lists:reverse(T, [H]);
enc_hoist_block_1(_) ->
throw(impossible).
enc_hoist_block_2([{'cond',_}|_]=L) ->
enc_hoist_block(L);
enc_hoist_block_2([{error,_}]=L) ->
L;
enc_hoist_block_2([]) ->
[{put_bits,0,0,[1,align]}];
enc_hoist_block_2(L) ->
case lists:last(L) of
{put_bits,_,_,_} ->
L ++ [{put_bits,0,0,[1,align]}];
_ ->
throw(impossible)
end.
%%%
%%% Optimize alignment for encoding.
%%%
enc_opt_al(Imm0) ->
{Imm,_} = enc_opt_al_1(Imm0, unknown),
Imm.
enc_opt_al_1([H0|T0], Al0) ->
{H,Al1} = enc_opt_al(H0, Al0),
{T,Al} = enc_opt_al_1(T0, Al1),
{H++T,Al};
enc_opt_al_1([], Al) -> {[],Al}.
enc_opt_al({assign,_,_}=Imm, Al) ->
{[Imm],Al};
enc_opt_al({block,Bl0}, Al0) ->
{Bl,Al} = enc_opt_al_1(Bl0, Al0),
{[{block,Bl}],Al};
enc_opt_al({call,erlang,iolist_to_binary,[_]}=Imm, Al) ->
{[Imm],Al};
enc_opt_al({call,per_common,encode_fragmented,[_,U]}=Call, Al) ->
case U rem 8 of
0 -> {[Call],Al};
_ -> {[Call],unknown}
end;
enc_opt_al({call,per_common,encode_unconstrained_number,[_]}=Call, _) ->
{[Call],0};
enc_opt_al({call,_,_,_,_}=Call, Al) ->
{[Call],Al};
enc_opt_al({'cond',Cs0}, Al0) ->
{Cs,Al} = enc_opt_al_cond(Cs0, Al0),
{[{'cond',Cs}],Al};
enc_opt_al({error,_}=Imm, Al) ->
{[Imm],Al};
enc_opt_al({list,Imm0,Dst}, Al) ->
Imm1 = enc_opt_hoist_align(Imm0),
{Imm,_} = enc_opt_al_1(Imm1, 0),
{[{list,Imm,Dst}],Al};
enc_opt_al({put_bits,V,N,[U,align]}, Al0) when Al0 rem 8 =:= 0 ->
Al = if
is_integer(N) -> N*U;
N =:= binary, U rem 8 =:= 0 -> 0;
true -> unknown
end,
{[{put_bits,V,N,[U]}],Al};
enc_opt_al({put_bits,V,binary,[U,align]}, Al0) when is_integer(Al0) ->
N = 8 - (Al0 rem 8),
Al = case U rem 8 of
0 -> 0;
_ -> unknown
end,
{[{put_bits,0,N,[1]},{put_bits,V,binary,[U]}],Al};
enc_opt_al({put_bits,V,N0,[U,align]}, Al0) when is_integer(N0), is_integer(Al0) ->
N = N0 + (8 - Al0 rem 8),
Al = N0*U,
{[{put_bits,V,N,[1]}],Al};
enc_opt_al({put_bits,_,N,[U,align]}=PutBits, _) when is_integer(N) ->
{[PutBits],N*U};
enc_opt_al({put_bits,_,binary,[U,align]}=PutBits, _) when U rem 8 =:= 0 ->
{[PutBits],0};
enc_opt_al({put_bits,_,N,[U]}=PutBits, Al) when is_integer(N), is_integer(Al) ->
{[PutBits],Al+N*U};
enc_opt_al({put_bits,_,binary,[U]}=PutBits, Al) when U rem 8 =:= 0 ->
{[PutBits],Al};
enc_opt_al({set,_,_}=Imm, Al) ->
{[Imm],Al};
enc_opt_al({sub,_,_,_}=Imm, Al) ->
{[Imm],Al};
enc_opt_al({'try',_,_,_,_}=Imm, Al) ->
{[Imm],Al};
enc_opt_al(Imm, _) ->
{[Imm],unknown}.
enc_opt_al_cond(Cs0, Al0) ->
enc_opt_al_cond_1(Cs0, Al0, [], []).
enc_opt_al_cond_1([['_',{error,_}]=C|Cs], Al, CAcc, AAcc) ->
enc_opt_al_cond_1(Cs, Al, [C|CAcc], AAcc);
enc_opt_al_cond_1([[C|Act0]|Cs0], Al0, CAcc, AAcc) ->
{Act,Al1} = enc_opt_al_1(Act0, Al0),
Al = if
Al1 =:= unknown -> Al1;
true -> Al1 rem 8
end,
enc_opt_al_cond_1(Cs0, Al0, [[C|Act]|CAcc], [Al|AAcc]);
enc_opt_al_cond_1([], _, CAcc, AAcc) ->
Al = case lists:usort(AAcc) of
[] -> unknown;
[Al0] -> Al0;
[_|_] -> unknown
end,
{lists:reverse(CAcc),Al}.
enc_opt_hoist_align([{'cond',Cs0},{put_bits,0,0,[1,align]}]=Imm) ->
try
Cs = [insert_align_last(C) || C <- Cs0],
[{'cond',Cs}]
catch
throw:impossible ->
Imm
end;
enc_opt_hoist_align(Imm) -> Imm.
insert_align_last([_,{error,_}]=C) ->
C;
insert_align_last([H|T]) ->
case lists:last(T) of
{put_bits,_,_,_} ->
[H|T ++ [{put_bits,0,0,[1,align]}]];
_ ->
throw(impossible)
end.
%%%
%%% For the aligned PER format, fix up the intermediate format
%%% before code generation. Code generation will be somewhat
%%% easier if 'align' appear as a separate instruction.
%%%
per_fixup([{apply,_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{block,Block}|T]) ->
[{block,per_fixup(Block)}|per_fixup(T)];
per_fixup([{'assign',_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{'cond',Cs0}|T]) ->
Cs = [[C|per_fixup(Act)] || [C|Act] <- Cs0],
[{'cond',Cs}|per_fixup(T)];
per_fixup([{call,_,_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{call,_,_,_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{call_gen,_,_,_,_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{error,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{lc,B,V,L}|T]) ->
[{lc,per_fixup(B),V,L}|per_fixup(T)];
per_fixup([{lc,B,V,L,Dst}|T]) ->
[{lc,per_fixup(B),V,L,Dst}|per_fixup(T)];
per_fixup([{list,Imm,Dst}|T]) ->
[{list,per_fixup(Imm),Dst}|per_fixup(T)];
per_fixup([{set,_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{sub,_,_,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([{'try',Try0,{P,Succ0},Else0,Dst}|T]) ->
Try = per_fixup(Try0),
Succ = per_fixup(Succ0),
Else = per_fixup(Else0),
[{'try',Try,{P,Succ},Else,Dst}|per_fixup(T)];
per_fixup([{put_bits,_,_,_}|_]=L) ->
fixup_put_bits(L);
per_fixup([{var,_}=H|T]) ->
[H|per_fixup(T)];
per_fixup([]) -> [].
fixup_put_bits([{put_bits,0,0,[_,align]}|T]) ->
[align|fixup_put_bits(T)];
fixup_put_bits([{put_bits,0,0,_}|T]) ->
fixup_put_bits(T);
fixup_put_bits([{put_bits,V,N,[U,align]}|T]) ->
[align,{put_bits,V,N,[U]}|fixup_put_bits(T)];
fixup_put_bits([{put_bits,_,_,_}=H|T]) ->
[H|fixup_put_bits(T)];
fixup_put_bits(Other) -> per_fixup(Other).
%% effective_constraint(Type,C)
%% Type = atom()
%% C = [C1,...]
%% C1 = {'SingleValue',SV} | {'ValueRange',VR} | {atom(),term()}
%% SV = integer() | [integer(),...]
%% VR = {Lb,Ub}
%% Lb = 'MIN' | integer()
%% Ub = 'MAX' | integer()
%% Returns a single value if C only has a single value constraint, and no
%% value range constraints, that constrains to a single value, otherwise
%% returns a value range that has the lower bound set to the lowest value
%% of all single values and lower bound values in C and the upper bound to
%% the greatest value.
effective_constraint(integer, [{{_,_}=Root,_}|_Rest]) ->
%% Normalize extension. Note that any range given for the
%% extension should be ignored anyway.
[{Root,[]}];
effective_constraint(integer, C) ->
SVs = get_constraints(C, 'SingleValue'),
SV = effective_constr('SingleValue', SVs),
VRs = get_constraints(C, 'ValueRange'),
VR = effective_constr('ValueRange', VRs),
greatest_common_range(SV, VR);
effective_constraint(bitstring, C) ->
case get_constraint(C, 'SizeConstraint') of
{{Lb,Ub},[]}=Range when is_integer(Lb) ->
if
is_integer(Ub), Ub < 16#10000 ->
Range;
true ->
no
end;
{Lb,Ub}=Range when is_integer(Lb) ->
if
is_integer(Ub), Ub < 16#10000 ->
if
Lb =:= Ub -> Lb;
true -> Range
end;
true ->
no
end;
no ->
no
end.
effective_constr(_, []) -> [];
effective_constr('SingleValue', List) ->
SVList = lists:flatten(lists:map(fun(X) -> element(2, X) end, List)),
%% Sort and remove duplicates before generating SingleValue or ValueRange
%% In case of ValueRange, also check for 'MIN and 'MAX'
case lists:usort(SVList) of
[N] ->
[{'SingleValue',N}];
[_|_]=L ->
[{'ValueRange',{least_Lb(L),greatest_Ub(L)}}]
end;
effective_constr('ValueRange', List) ->
LBs = lists:map(fun({_,{Lb,_}}) -> Lb end, List),
UBs = lists:map(fun({_,{_,Ub}}) -> Ub end, List),
Lb = least_Lb(LBs),
[{'ValueRange',{Lb,lists:max(UBs)}}].
greatest_common_range([], VR) ->
VR;
greatest_common_range(SV, []) ->
SV;
greatest_common_range([{_,Int}], [{_,{'MIN',Ub}}])
when is_integer(Int), Int > Ub ->
[{'ValueRange',{'MIN',Int}}];
greatest_common_range([{_,Int}],[{_,{Lb,Ub}}])
when is_integer(Int), Int < Lb ->
[{'ValueRange',{Int,Ub}}];
greatest_common_range([{_,Int}],VR=[{_,{_Lb,_Ub}}]) when is_integer(Int) ->
VR;
greatest_common_range([{_,L}],[{_,{Lb,Ub}}]) when is_list(L) ->
Min = least_Lb([Lb|L]),
Max = greatest_Ub([Ub|L]),
[{'ValueRange',{Min,Max}}];
greatest_common_range([{_,{Lb1,Ub1}}], [{_,{Lb2,Ub2}}]) ->
Min = least_Lb([Lb1,Lb2]),
Max = greatest_Ub([Ub1,Ub2]),
[{'ValueRange',{Min,Max}}].
least_Lb(L) ->
case lists:member('MIN', L) of
true -> 'MIN';
false -> lists:min(L)
end.
greatest_Ub(L) ->
case lists:member('MAX', L) of
true -> 'MAX';
false -> lists:max(L)
end.
get_constraint(C, Key) ->
case lists:keyfind(Key, 1, C) of
false -> no;
{_,V} -> V
end.
get_constraints([{Key,_}=Pair|T], Key) ->
[Pair|get_constraints(T, Key)];
get_constraints([_|T], Key) ->
get_constraints(T, Key);
get_constraints([], _) -> [].