%% %% %CopyrightBegin% %% %% Copyright Ericsson AB 1999-2018. All Rights Reserved. %% %% 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. %% %% %CopyrightEnd% %% %% Purpose: Peephole optimization of binary syntax instructions. -module(beam_bs). -export([module/2]). -import(lists, [reverse/1]). -spec module(beam_utils:module_code(), [compile:option()]) -> {'ok',beam_utils:module_code()}. module({Mod,Exp,Attr,Fs0,Lc}, _Opt) -> Fs = [function(F) || F <- Fs0], {ok,{Mod,Exp,Attr,Fs,Lc}}. function({function,Name,Arity,CLabel,Is0}) -> try Is = bs_opt(Is0), {function,Name,Arity,CLabel,Is} catch Class:Error:Stack -> io:fwrite("Function: ~w/~w\n", [Name,Arity]), erlang:raise(Class, Error, Stack) end. %%% %%% Evaluate construction of constant bit fields. %%% bs_opt([{bs_put,_,_,_}=I|Is0]) -> {BsPuts0,Is} = collect_bs_puts(Is0, [I]), BsPuts = opt_bs_puts(BsPuts0), BsPuts ++ bs_opt(Is); bs_opt([I|Is]) -> [I|bs_opt(Is)]; bs_opt([]) -> []. collect_bs_puts([{bs_put,_,_,_}=I|Is], Acc) -> collect_bs_puts(Is, [I|Acc]); collect_bs_puts([_|_]=Is, Acc) -> {reverse(Acc),Is}. opt_bs_puts(Is) -> opt_bs_1(Is, []). opt_bs_1([{bs_put,Fail, {bs_put_float,1,Flags0},[{integer,Sz},Src]}=I0|Is], Acc) -> try eval_put_float(Src, Sz, Flags0) of <> -> Flags = force_big(Flags0), I = {bs_put,Fail,{bs_put_integer,1,Flags}, [{integer,Sz},{integer,Int}]}, opt_bs_1([I|Is], Acc) catch error:_ -> opt_bs_1(Is, [I0|Acc]) end; opt_bs_1([{bs_put,_,{bs_put_integer,1,_},[{integer,8},{integer,_}]}|_]=IsAll, Acc0) -> {Is,Acc} = bs_collect_string(IsAll, Acc0), opt_bs_1(Is, Acc); opt_bs_1([{bs_put,Fail,{bs_put_integer,1,F},[{integer,Sz},{integer,N}]}=I|Is0], Acc) when Sz > 8 -> case field_endian(F) of big -> %% We can do this optimization for any field size without %% risk for code explosion. case bs_split_int(N, Sz, Fail, Is0) of no_split -> opt_bs_1(Is0, [I|Acc]); Is -> opt_bs_1(Is, Acc) end; little when Sz < 128 -> %% We only try to optimize relatively small fields, to %% avoid an explosion in code size. <> = <>, Flags = force_big(F), Is = [{bs_put,Fail,{bs_put_integer,1,Flags}, [{integer,Sz},{integer,Int}]}|Is0], opt_bs_1(Is, Acc); _ -> %native or too wide little field opt_bs_1(Is0, [I|Acc]) end; opt_bs_1([{bs_put,Fail,{Op,U,F},[{integer,Sz},Src]}|Is], Acc) when U > 1 -> opt_bs_1([{bs_put,Fail,{Op,1,F},[{integer,U*Sz},Src]}|Is], Acc); opt_bs_1([I|Is], Acc) -> opt_bs_1(Is, [I|Acc]); opt_bs_1([], Acc) -> reverse(Acc). eval_put_float(Src, Sz, Flags) when Sz =< 256 -> %%Only evaluate if Sz is reasonable. Val = value(Src), case field_endian(Flags) of little -> <>; big -> <> %% native intentionally not handled here - we can't optimize %% it. end. value({integer,I}) -> I; value({float,F}) -> F. bs_collect_string(Is, [{bs_put,_,{bs_put_string,Len,{string,Str}},[]}|Acc]) -> bs_coll_str_1(Is, Len, reverse(Str), Acc); bs_collect_string(Is, Acc) -> bs_coll_str_1(Is, 0, [], Acc). bs_coll_str_1([{bs_put,_,{bs_put_integer,U,_},[{integer,Sz},{integer,V}]}|Is], Len, StrAcc, IsAcc) when U*Sz =:= 8 -> Byte = V band 16#FF, bs_coll_str_1(Is, Len+1, [Byte|StrAcc], IsAcc); bs_coll_str_1(Is, Len, StrAcc, IsAcc) -> {Is,[{bs_put,{f,0},{bs_put_string,Len,{string,reverse(StrAcc)}},[]}|IsAcc]}. field_endian({field_flags,F}) -> field_endian_1(F). field_endian_1([big=E|_]) -> E; field_endian_1([little=E|_]) -> E; field_endian_1([native=E|_]) -> E; field_endian_1([_|Fs]) -> field_endian_1(Fs). force_big({field_flags,F}) -> {field_flags,force_big_1(F)}. force_big_1([big|_]=Fs) -> Fs; force_big_1([little|Fs]) -> [big|Fs]; force_big_1([F|Fs]) -> [F|force_big_1(Fs)]. bs_split_int(0, Sz, _, _) when Sz > 64 -> %% We don't want to split in this case because the %% string will consist of only zeroes. no_split; bs_split_int(-1, Sz, _, _) when Sz > 64 -> %% We don't want to split in this case because the %% string will consist of only 255 bytes. no_split; bs_split_int(N, Sz, Fail, Acc) -> FirstByteSz = case Sz rem 8 of 0 -> 8; Rem -> Rem end, bs_split_int_1(N, FirstByteSz, Sz, Fail, Acc). bs_split_int_1(-1, _, Sz, Fail, Acc) when Sz > 64 -> I = {bs_put,Fail,{bs_put_integer,1,{field_flags,[big]}}, [{integer,Sz},{integer,-1}]}, [I|Acc]; bs_split_int_1(0, _, Sz, Fail, Acc) when Sz > 64 -> I = {bs_put,Fail,{bs_put_integer,1,{field_flags,[big]}}, [{integer,Sz},{integer,0}]}, [I|Acc]; bs_split_int_1(N, ByteSz, Sz, Fail, Acc) when Sz > 0 -> Mask = (1 bsl ByteSz) - 1, I = {bs_put,Fail,{bs_put_integer,1,{field_flags,[big]}}, [{integer,ByteSz},{integer,N band Mask}]}, bs_split_int_1(N bsr ByteSz, 8, Sz-ByteSz, Fail, [I|Acc]); bs_split_int_1(_, _, _, _, Acc) -> Acc.