%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 1999-2013. 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%
%%
%% Purpose : Partitions assembly instructions into basic blocks and
%% optimizes them.
-module(beam_block).
-export([module/2]).
-import(lists, [mapfoldl/3,reverse/1,reverse/2,foldl/3,member/2]).
-define(MAXREG, 1024).
module({Mod,Exp,Attr,Fs0,Lc0}, _Opt) ->
{Fs,Lc} = mapfoldl(fun function/2, Lc0, Fs0),
{ok,{Mod,Exp,Attr,Fs,Lc}}.
function({function,Name,Arity,CLabel,Is0}, Lc0) ->
try
%% Collect basic blocks and optimize them.
Is1 = blockify(Is0),
Is2 = embed_lines(Is1),
Is3 = move_allocates(Is2),
Is4 = beam_utils:live_opt(Is3),
Is5 = opt_blocks(Is4),
Is6 = beam_utils:delete_live_annos(Is5),
%% Optimize bit syntax.
{Is,Lc} = bsm_opt(Is6, Lc0),
%% Done.
{{function,Name,Arity,CLabel,Is},Lc}
catch
Class:Error ->
Stack = erlang:get_stacktrace(),
io:fwrite("Function: ~w/~w\n", [Name,Arity]),
erlang:raise(Class, Error, Stack)
end.
%% blockify(Instructions0) -> Instructions
%% Collect sequences of instructions to basic blocks.
%% Also do some simple optimations on instructions outside the blocks.
blockify(Is) ->
blockify(Is, []).
blockify([{loop_rec,{f,Fail},{x,0}},{loop_rec_end,_Lbl},{label,Fail}|Is], Acc) ->
%% Useless instruction sequence.
blockify(Is, Acc);
%% New bit syntax matching.
blockify([{bs_save2,R,Point}=I,{bs_restore2,R,Point}|Is], Acc) ->
blockify([I|Is], Acc);
blockify([{bs_save2,R,Point}=I,{test,is_eq_exact,_,_}=Test,
{bs_restore2,R,Point}|Is], Acc) ->
blockify([I,Test|Is], Acc);
%% Do other peep-hole optimizations.
blockify([{test,is_atom,{f,Fail},[Reg]}=I|
[{select,select_val,Reg,{f,Fail},
[{atom,false},{f,_}=BrFalse,
{atom,true}=AtomTrue,{f,_}=BrTrue]}|Is]=Is0],
[{block,Bl}|_]=Acc) ->
case is_last_bool(Bl, Reg) of
false ->
blockify(Is0, [I|Acc]);
true ->
%% The last instruction is a boolean operator/guard BIF that can't fail.
%% We can convert the three-way branch to a two-way branch (eliminating
%% the reference to the failure label).
blockify(Is, [{jump,BrTrue},
{test,is_eq_exact,BrFalse,[Reg,AtomTrue]}|Acc])
end;
blockify([{test,is_atom,{f,Fail},[Reg]}=I|
[{select,select_val,Reg,{f,Fail},
[{atom,true}=AtomTrue,{f,_}=BrTrue,
{atom,false},{f,_}=BrFalse]}|Is]=Is0],
[{block,Bl}|_]=Acc) ->
case is_last_bool(Bl, Reg) of
false ->
blockify(Is0, [I|Acc]);
true ->
blockify(Is, [{jump,BrTrue},
{test,is_eq_exact,BrFalse,[Reg,AtomTrue]}|Acc])
end;
blockify([I|Is0]=IsAll, Acc) ->
case is_bs_put(I) of
true ->
{BsPuts0,Is} = collect_bs_puts(IsAll),
BsPuts = opt_bs_puts(BsPuts0),
blockify(Is, reverse(BsPuts, Acc));
false ->
case collect(I) of
error -> blockify(Is0, [I|Acc]);
Instr when is_tuple(Instr) ->
{Block,Is} = collect_block(IsAll),
blockify(Is, [{block,Block}|Acc])
end
end;
blockify([], Acc) -> reverse(Acc).
is_last_bool([{set,[Reg],As,{bif,N,_}}], Reg) ->
Ar = length(As),
erl_internal:new_type_test(N, Ar) orelse erl_internal:comp_op(N, Ar)
orelse erl_internal:bool_op(N, Ar);
is_last_bool([_|Is], Reg) -> is_last_bool(Is, Reg);
is_last_bool([], _) -> false.
collect_block(Is) ->
collect_block(Is, []).
collect_block([{allocate,N,R}|Is0], Acc) ->
{Inits,Is} = lists:splitwith(fun ({init,{y,_}}) -> true;
(_) -> false
end, Is0),
collect_block(Is, [{set,[],[],{alloc,R,{nozero,N,0,Inits}}}|Acc]);
collect_block([{allocate_zero,Ns,R},{test_heap,Nh,R}|Is], Acc) ->
collect_block(Is, [{set,[],[],{alloc,R,{zero,Ns,Nh,[]}}}|Acc]);
collect_block([I|Is]=Is0, Acc) ->
case collect(I) of
error -> {reverse(Acc),Is0};
Instr -> collect_block(Is, [Instr|Acc])
end.
collect({allocate,N,R}) -> {set,[],[],{alloc,R,{nozero,N,0,[]}}};
collect({allocate_zero,N,R}) -> {set,[],[],{alloc,R,{zero,N,0,[]}}};
collect({allocate_heap,Ns,Nh,R}) -> {set,[],[],{alloc,R,{nozero,Ns,Nh,[]}}};
collect({allocate_heap_zero,Ns,Nh,R}) -> {set,[],[],{alloc,R,{zero,Ns,Nh,[]}}};
collect({init,D}) -> {set,[D],[],init};
collect({test_heap,N,R}) -> {set,[],[],{alloc,R,{nozero,nostack,N,[]}}};
collect({bif,N,F,As,D}) -> {set,[D],As,{bif,N,F}};
collect({gc_bif,N,F,R,As,D}) -> {set,[D],As,{alloc,R,{gc_bif,N,F}}};
collect({move,S,D}) -> {set,[D],[S],move};
collect({put_list,S1,S2,D}) -> {set,[D],[S1,S2],put_list};
collect({put_tuple,A,D}) -> {set,[D],[],{put_tuple,A}};
collect({put,S}) -> {set,[],[S],put};
collect({get_tuple_element,S,I,D}) -> {set,[D],[S],{get_tuple_element,I}};
collect({set_tuple_element,S,D,I}) -> {set,[],[S,D],{set_tuple_element,I}};
collect({get_list,S,D1,D2}) -> {set,[D1,D2],[S],get_list};
collect(remove_message) -> {set,[],[],remove_message};
collect({put_map,F,Op,S,D,R,{list,Puts}}) ->
{set,[D],[S|Puts],{alloc,R,{put_map,Op,F}}};
collect({get_map_elements,F,S,{list,Gets}}) ->
{set,Gets,[S],{get_map_elements,F}};
collect({'catch',R,L}) -> {set,[R],[],{'catch',L}};
collect(fclearerror) -> {set,[],[],fclearerror};
collect({fcheckerror,{f,0}}) -> {set,[],[],fcheckerror};
collect({fmove,S,D}) -> {set,[D],[S],fmove};
collect({fconv,S,D}) -> {set,[D],[S],fconv};
collect(_) -> error.
%% embed_lines([Instruction]) -> [Instruction]
%% Combine blocks that would be split by line/1 instructions.
%% Also move a line instruction before a block into the block,
%% but leave the line/1 instruction after a block outside.
embed_lines(Is) ->
embed_lines(reverse(Is), []).
embed_lines([{block,B2},{line,_}=Line,{block,B1}|T], Acc) ->
B = {block,B1++[{set,[],[],Line}]++B2},
embed_lines([B|T], Acc);
embed_lines([{block,B1},{line,_}=Line|T], Acc) ->
B = {block,[{set,[],[],Line}|B1]},
embed_lines([B|T], Acc);
embed_lines([I|Is], Acc) ->
embed_lines(Is, [I|Acc]);
embed_lines([], Acc) -> Acc.
opt_blocks([{block,Bl0}|Is]) ->
%% The live annotation at the beginning is not useful.
[{'%live',_}|Bl] = Bl0,
[{block,opt_block(Bl)}|opt_blocks(Is)];
opt_blocks([I|Is]) ->
[I|opt_blocks(Is)];
opt_blocks([]) -> [].
opt_block(Is0) ->
Is = find_fixpoint(fun opt/1, Is0),
opt_alloc(Is).
find_fixpoint(OptFun, Is0) ->
case OptFun(Is0) of
Is0 -> Is0;
Is1 -> find_fixpoint(OptFun, Is1)
end.
%% move_allocates(Is0) -> Is
%% Move allocate instructions upwards in the instruction stream, in the
%% hope of getting more possibilities for optimizing away moves later.
%%
%% NOTE: Moving allocation instructions is only safe because it is done
%% immediately after code generation so that we KNOW that if {x,X} is
%% initialized, all x registers with lower numbers are also initialized.
%% That assumption may not be true after other optimizations, such as
%% the beam_utils:live_opt/1 optimization.
move_allocates([{block,Bl0}|Is]) ->
Bl = move_allocates_1(reverse(Bl0), []),
[{block,Bl}|move_allocates(Is)];
move_allocates([I|Is]) ->
[I|move_allocates(Is)];
move_allocates([]) -> [].
move_allocates_1([{set,[],[],{alloc,_,_}=Alloc}|Is0], Acc0) ->
{Is,Acc} = move_allocates_2(Alloc, Is0, Acc0),
move_allocates_1(Is, Acc);
move_allocates_1([I|Is], Acc) ->
move_allocates_1(Is, [I|Acc]);
move_allocates_1([], Is) -> Is.
move_allocates_2({alloc,Live,Info}, [{set,[],[],{alloc,Live0,Info0}}|Is], Acc) ->
Live = Live0, % Assertion.
Alloc = {alloc,Live,combine_alloc(Info0, Info)},
move_allocates_2(Alloc, Is, Acc);
move_allocates_2({alloc,Live,Info}=Alloc0, [I|Is]=Is0, Acc) ->
case alloc_may_pass(I) of
false ->
{Is0,[{set,[],[],Alloc0}|Acc]};
true ->
Alloc = {alloc,alloc_live_regs(I, Live),Info},
move_allocates_2(Alloc, Is, [I|Acc])
end;
move_allocates_2(Alloc, [], Acc) ->
{[],[{set,[],[],Alloc}|Acc]}.
alloc_may_pass({set,_,_,{alloc,_,_}}) -> false;
alloc_may_pass({set,_,_,{set_tuple_element,_}}) -> false;
alloc_may_pass({set,_,_,{get_map_elements,_}}) -> false;
alloc_may_pass({set,_,_,put_list}) -> false;
alloc_may_pass({set,_,_,put}) -> false;
alloc_may_pass({set,_,_,_}) -> true.
combine_alloc({_,Ns,Nh1,Init}, {_,nostack,Nh2,[]}) ->
{zero,Ns,beam_utils:combine_heap_needs(Nh1, Nh2),Init}.
%% opt([Instruction]) -> [Instruction]
%% Optimize the instruction stream inside a basic block.
opt([{set,[Dst],As,{bif,Bif,Fail}}=I1,
{set,[Dst],[Dst],{bif,'not',Fail}}=I2|Is]) ->
%% Get rid of the 'not' if the operation can be inverted.
case inverse_comp_op(Bif) of
none -> [I1,I2|opt(Is)];
RevBif -> [{set,[Dst],As,{bif,RevBif,Fail}}|opt(Is)]
end;
opt([{set,[X],[X],move}|Is]) -> opt(Is);
opt([{set,_,_,{line,_}}=Line1,
{set,[D1],[{integer,Idx1},Reg],{bif,element,{f,0}}}=I1,
{set,_,_,{line,_}}=Line2,
{set,[D2],[{integer,Idx2},Reg],{bif,element,{f,0}}}=I2|Is])
when Idx1 < Idx2, D1 =/= D2, D1 =/= Reg, D2 =/= Reg ->
opt([Line2,I2,Line1,I1|Is]);
opt([{set,Ds0,Ss,Op}|Is0]) ->
{Ds,Is} = opt_moves(Ds0, Is0),
[{set,Ds,Ss,Op}|opt(Is)];
opt([{'%live',_}=I|Is]) ->
[I|opt(Is)];
opt([]) -> [].
%% opt_moves([Dest], [Instruction]) -> {[Dest],[Instruction]}
%% For each Dest, does the optimization described in opt_move/2.
opt_moves([], Is0) -> {[],Is0};
opt_moves([D0]=Ds, Is0) ->
case opt_move(D0, Is0) of
not_possible -> {Ds,Is0};
{D1,Is} -> {[D1],Is}
end;
opt_moves([X0,Y0], Is0) ->
{X,Is2} = case opt_move(X0, Is0) of
not_possible -> {X0,Is0};
{Y0,_} -> {X0,Is0};
{_X1,_Is1} = XIs1 -> XIs1
end,
case opt_move(Y0, Is2) of
not_possible -> {[X,Y0],Is2};
{X,_} -> {[X,Y0],Is2};
{Y,Is} -> {[X,Y],Is}
end;
opt_moves(Ds, Is) ->
%% multiple destinations -> pass through
{Ds,Is}.
%% opt_move(Dest, [Instruction]) -> {UpdatedDest,[Instruction]} | not_possible
%% If there is a {move,Dest,FinalDest} instruction
%% in the instruction stream, remove the move instruction
%% and let FinalDest be the destination.
%%
%% For this optimization to be safe, we must be sure that
%% Dest will not be referenced in any other by other instructions
%% in the rest of the instruction stream. Not even the indirect
%% reference by an instruction that may allocate (such as
%% test_heap/2 or a GC Bif) is allowed.
opt_move(Dest, Is) ->
opt_move_1(Dest, Is, ?MAXREG, []).
opt_move_1(R, [{set,_,_,{alloc,Live,_}}|_]=Is, SafeRegs, Acc) when Live < SafeRegs ->
%% Downgrade number of safe regs and rescan the instruction, as it most probably
%% is a gc_bif instruction.
opt_move_1(R, Is, Live, Acc);
opt_move_1(R, [{set,[{x,X}=D],[R],move}|Is], SafeRegs, Acc) ->
case X < SafeRegs andalso beam_utils:is_killed_block(R, Is) of
true -> opt_move_2(D, Acc, Is);
false -> not_possible
end;
opt_move_1(R, [{set,[D],[R],move}|Is], _SafeRegs, Acc) ->
case beam_utils:is_killed_block(R, Is) of
true -> opt_move_2(D, Acc, Is);
false -> not_possible
end;
opt_move_1(R, [I|Is], SafeRegs, Acc) ->
case is_transparent(R, I) of
false -> not_possible;
true -> opt_move_1(R, Is, SafeRegs, [I|Acc])
end.
%% Reverse the instructions, while checking that there are no instructions that
%% would interfere with using the new destination register chosen.
opt_move_2(D, [I|Is], Acc) ->
case is_transparent(D, I) of
false -> not_possible;
true -> opt_move_2(D, Is, [I|Acc])
end;
opt_move_2(D, [], Acc) -> {D,Acc}.
%% is_transparent(Register, Instruction) -> true | false
%% Returns true if Instruction does not in any way references Register
%% (even indirectly by an allocation instruction).
%% Returns false if Instruction does reference Register, or we are
%% not sure.
is_transparent({x,X}, {set,_,_,{alloc,Live,_}}) when X < Live ->
false;
is_transparent(R, {set,Ds,Ss,_Op}) ->
case member(R, Ds) of
true -> false;
false -> not member(R, Ss)
end;
is_transparent(_, _) -> false.
%% opt_alloc(Instructions) -> Instructions'
%% Optimises all allocate instructions.
opt_alloc([{set,[],[],{alloc,R,{_,Ns,Nh,[]}}}|Is]) ->
[{set,[],[],opt_alloc(Is, Ns, Nh, R)}|opt(Is)];
opt_alloc([I|Is]) -> [I|opt_alloc(Is)];
opt_alloc([]) -> [].
%% opt_alloc(Instructions, FrameSize, HeapNeed, LivingRegs) -> [Instr]
%% Generates the optimal sequence of instructions for
%% allocating and initalizing the stack frame and needed heap.
opt_alloc(_Is, nostack, Nh, LivingRegs) ->
{alloc,LivingRegs,{nozero,nostack,Nh,[]}};
opt_alloc(Is, Ns, Nh, LivingRegs) ->
InitRegs = init_yreg(Is, 0),
case count_ones(InitRegs) of
N when N*2 > Ns ->
{alloc,LivingRegs,{nozero,Ns,Nh,gen_init(Ns, InitRegs)}};
_ ->
{alloc,LivingRegs,{zero,Ns,Nh,[]}}
end.
gen_init(Fs, Regs) -> gen_init(Fs, Regs, 0, []).
gen_init(SameFs, _Regs, SameFs, Acc) -> reverse(Acc);
gen_init(Fs, Regs, Y, Acc) when Regs band 1 =:= 0 ->
gen_init(Fs, Regs bsr 1, Y+1, [{init,{y,Y}}|Acc]);
gen_init(Fs, Regs, Y, Acc) ->
gen_init(Fs, Regs bsr 1, Y+1, Acc).
%% init_yreg(Instructions, RegSet) -> RegSetInitialized
%% Calculate the set of initialized y registers.
init_yreg([{set,_,_,{bif,_,_}}|_], Reg) -> Reg;
init_yreg([{set,_,_,{alloc,_,{gc_bif,_,_}}}|_], Reg) -> Reg;
init_yreg([{set,_,_,{alloc,_,{put_map,_,_}}}|_], Reg) -> Reg;
init_yreg([{set,Ds,_,_}|Is], Reg) -> init_yreg(Is, add_yregs(Ds, Reg));
init_yreg(_Is, Reg) -> Reg.
add_yregs(Ys, Reg) -> foldl(fun(Y, R0) -> add_yreg(Y, R0) end, Reg, Ys).
add_yreg({y,Y}, Reg) -> Reg bor (1 bsl Y);
add_yreg(_, Reg) -> Reg.
count_ones(Bits) -> count_ones(Bits, 0).
count_ones(0, Acc) -> Acc;
count_ones(Bits, Acc) ->
count_ones(Bits bsr 1, Acc + (Bits band 1)).
%% Calculate the new number of live registers when we move an allocate
%% instruction upwards, passing a 'set' instruction.
alloc_live_regs({set,Ds,Ss,_}, Regs0) ->
Rset = x_live(Ss, x_dead(Ds, (1 bsl Regs0)-1)),
live_regs(Rset).
live_regs(Regs) ->
live_regs_1(0, Regs).
live_regs_1(N, 0) -> N;
live_regs_1(N, Regs) -> live_regs_1(N+1, Regs bsr 1).
x_dead([{x,N}|Rs], Regs) -> x_dead(Rs, Regs band (bnot (1 bsl N)));
x_dead([_|Rs], Regs) -> x_dead(Rs, Regs);
x_dead([], Regs) -> Regs.
x_live([{x,N}|Rs], Regs) -> x_live(Rs, Regs bor (1 bsl N));
x_live([_|Rs], Regs) -> x_live(Rs, Regs);
x_live([], Regs) -> Regs.
%% inverse_comp_op(Op) -> none|RevOp
inverse_comp_op('=:=') -> '=/=';
inverse_comp_op('=/=') -> '=:=';
inverse_comp_op('==') -> '/=';
inverse_comp_op('/=') -> '==';
inverse_comp_op('>') -> '=<';
inverse_comp_op('<') -> '>=';
inverse_comp_op('>=') -> '<';
inverse_comp_op('=<') -> '>';
inverse_comp_op(_) -> none.
%%%
%%% Evaluation of constant bit fields.
%%%
is_bs_put({bs_put,_,{bs_put_integer,_,_},_}) -> true;
is_bs_put({bs_put,_,{bs_put_float,_,_},_}) -> true;
is_bs_put(_) -> false.
collect_bs_puts(Is) ->
collect_bs_puts_1(Is, []).
collect_bs_puts_1([I|Is]=Is0, Acc) ->
case is_bs_put(I) of
false -> {reverse(Acc),Is0};
true -> collect_bs_puts_1(Is, [I|Acc])
end.
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
<<Int:Sz>> ->
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.
<<Int:Sz>> = <<N:Sz/little>>,
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 -> <<Val:Sz/little-float-unit:1>>;
big -> <<Val:Sz/big-float-unit:1>>
%% 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.
%%%
%%% Optimization of new bit syntax matching: get rid
%%% of redundant bs_restore2/2 instructions across select_val
%%% instructions, as well as a few other simple peep-hole optimizations.
%%%
bsm_opt(Is0, Lc0) ->
{Is1,D0,Lc} = bsm_scan(Is0, [], Lc0, []),
Is2 = case D0 of
[] ->
Is1;
_ ->
D = gb_trees:from_orddict(orddict:from_list(D0)),
bsm_reroute(Is1, D, none, [])
end,
Is = beam_clean:bs_clean_saves(Is2),
{bsm_opt_2(Is, []),Lc}.
bsm_scan([{label,L}=Lbl,{bs_restore2,_,Save}=R|Is], D0, Lc, Acc0) ->
D = [{{L,Save},Lc}|D0],
Acc = [{label,Lc},R,Lbl|Acc0],
bsm_scan(Is, D, Lc+1, Acc);
bsm_scan([I|Is], D, Lc, Acc) ->
bsm_scan(Is, D, Lc, [I|Acc]);
bsm_scan([], D, Lc, Acc) ->
{reverse(Acc),D,Lc}.
bsm_reroute([{bs_save2,Reg,Save}=I|Is], D, _, Acc) ->
bsm_reroute(Is, D, {Reg,Save}, [I|Acc]);
bsm_reroute([{bs_restore2,Reg,Save}=I|Is], D, _, Acc) ->
bsm_reroute(Is, D, {Reg,Save}, [I|Acc]);
bsm_reroute([{label,_}=I|Is], D, S, Acc) ->
bsm_reroute(Is, D, S, [I|Acc]);
bsm_reroute([{select,select_val,Reg,F0,Lbls0}|Is], D, {_,Save}=S, Acc0) ->
[F|Lbls] = bsm_subst_labels([F0|Lbls0], Save, D),
Acc = [{select,select_val,Reg,F,Lbls}|Acc0],
bsm_reroute(Is, D, S, Acc);
bsm_reroute([{test,TestOp,F0,TestArgs}=I|Is], D, {_,Save}=S, Acc0) ->
F = bsm_subst_label(F0, Save, D),
Acc = [{test,TestOp,F,TestArgs}|Acc0],
case bsm_not_bs_test(I) of
true ->
%% The test instruction will not update the bit offset for the
%% binary being matched. Therefore the save position can be kept.
bsm_reroute(Is, D, S, Acc);
false ->
%% The test instruction might update the bit offset. Kill our
%% remembered Save position.
bsm_reroute(Is, D, none, Acc)
end;
bsm_reroute([{test,TestOp,F0,Live,TestArgs,Dst}|Is], D, {_,Save}, Acc0) ->
F = bsm_subst_label(F0, Save, D),
Acc = [{test,TestOp,F,Live,TestArgs,Dst}|Acc0],
%% The test instruction will update the bit offset. Kill our
%% remembered Save position.
bsm_reroute(Is, D, none, Acc);
bsm_reroute([{block,[{set,[],[],{alloc,_,_}}]}=Bl,
{bs_context_to_binary,_}=I|Is], D, S, Acc) ->
%% To help further bit syntax optimizations.
bsm_reroute([I,Bl|Is], D, S, Acc);
bsm_reroute([I|Is], D, _, Acc) ->
bsm_reroute(Is, D, none, [I|Acc]);
bsm_reroute([], _, _, Acc) -> reverse(Acc).
bsm_opt_2([{test,bs_test_tail2,F,[Ctx,Bits]}|Is],
[{test,bs_skip_bits2,F,[Ctx,{integer,I},Unit,_Flags]}|Acc]) ->
bsm_opt_2(Is, [{test,bs_test_tail2,F,[Ctx,Bits+I*Unit]}|Acc]);
bsm_opt_2([{test,bs_skip_bits2,F,[Ctx,{integer,I1},Unit1,_]}|Is],
[{test,bs_skip_bits2,F,[Ctx,{integer,I2},Unit2,Flags]}|Acc]) ->
bsm_opt_2(Is, [{test,bs_skip_bits2,F,
[Ctx,{integer,I1*Unit1+I2*Unit2},1,Flags]}|Acc]);
bsm_opt_2([I|Is], Acc) ->
bsm_opt_2(Is, [I|Acc]);
bsm_opt_2([], Acc) -> reverse(Acc).
%% bsm_not_bs_test({test,Name,_,Operands}) -> true|false.
%% Test whether is the test is a "safe", i.e. does not move the
%% bit offset for a binary.
%%
%% 'true' means that the test is safe, 'false' that we don't know or
%% that the test moves the offset (e.g. bs_get_integer2).
bsm_not_bs_test({test,bs_test_tail2,_,[_,_]}) -> true;
bsm_not_bs_test(Test) -> beam_utils:is_pure_test(Test).
bsm_subst_labels(Fs, Save, D) ->
bsm_subst_labels_1(Fs, Save, D, []).
bsm_subst_labels_1([F|Fs], Save, D, Acc) ->
bsm_subst_labels_1(Fs, Save, D, [bsm_subst_label(F, Save, D)|Acc]);
bsm_subst_labels_1([], _, _, Acc) ->
reverse(Acc).
bsm_subst_label({f,Lbl0}=F, Save, D) ->
case gb_trees:lookup({Lbl0,Save}, D) of
{value,Lbl} -> {f,Lbl};
none -> F
end;
bsm_subst_label(Other, _, _) -> Other.
