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authorBjörn Gustavsson <[email protected]>2018-03-01 06:42:57 +0100
committerBjörn Gustavsson <[email protected]>2018-08-17 09:50:59 +0200
commit3fc40fd57fa01b097b4c363860c4d4762e13db8b (patch)
tree8988da71d06fb0104b82aaee8b9ca645756e715d /lib/compiler/src/beam_utils.erl
parent6065d9f8540cd4621cbace0cd4d485956a720fd6 (diff)
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Don't run unsafe compiler passes
As a preparation for replacing v3_codegen with a new code generator, remove unsafe optimization passes. Especially the older compiler passes have implicit assumptions about how the code is generated. Remove the optimizations in beam_block (keep the code that creates blocks) because they are unsafe. beam_block also calls beam_utils:live_opt/1, which is unsafe. Remove beam_type because it calls beam_utils:live_opt/1, and also because it recalculates the number of heaps words and number of live registers in allocation instructions, thus potentially hiding bugs in other passes. Remove beam_receive because it is unsafe. Remove beam_record because it is the only remaining user of beam_utils:anno_defs/1. Remove beam_reorder because it makes much more sense to run it as an early SSA-based optimization pass. Remove the now unused functions in beam_utils: anno_def/1 delete_annos/1 is_killed_block/2 live_opt/1 usage/3 Note that the following test cases will fail because of the removed optimizations: compile_SUITE:optimized_guards/1 compile_SUITE:bc_options/1 receive_SUITE:ref_opt/1
Diffstat (limited to 'lib/compiler/src/beam_utils.erl')
-rw-r--r--lib/compiler/src/beam_utils.erl561
1 files changed, 3 insertions, 558 deletions
diff --git a/lib/compiler/src/beam_utils.erl b/lib/compiler/src/beam_utils.erl
index 317252e87a..af1e719206 100644
--- a/lib/compiler/src/beam_utils.erl
+++ b/lib/compiler/src/beam_utils.erl
@@ -21,18 +21,16 @@
%%
-module(beam_utils).
--export([is_killed_block/2,is_killed/3,is_killed_at/3,
- is_not_used/3,usage/3,
+-export([is_killed/3,is_killed_at/3,is_not_used/3,
empty_label_index/0,index_label/3,index_labels/1,replace_labels/4,
code_at/2,bif_to_test/3,is_pure_test/1,
- live_opt/1,delete_annos/1,combine_heap_needs/2,
- anno_defs/1,
+ combine_heap_needs/2,
split_even/1
]).
-export_type([code_index/0,module_code/0,instruction/0]).
--import(lists, [flatmap/2,map/2,member/2,sort/1,reverse/1,splitwith/2]).
+-import(lists, [flatmap/2,map/2,member/2,sort/1,reverse/1]).
-define(is_const(Val), (Val =:= nil orelse
element(1, Val) =:= integer orelse
@@ -62,46 +60,6 @@
{lbl :: code_index(), %Label to code index.
res :: result_cache()}). %Result cache for each label.
-%% usage(Register, [Instruction], State) -> killed|not_used|used.
-%% Determine the usage of Register in the instruction sequence.
-%% The return value is one of:
-%%
-%% killed - The register is not used in any way.
-%% not_used - The register is referenced only by an allocating instruction
-%% (the actual value does not matter).
-%% used - The register is used (its value do matter).
-
--spec usage(beam_asm:reg(), [instruction()], code_index()) ->
- 'killed' | 'not_used' | 'used'.
-
-usage(R, Is, D) ->
- St = #live{lbl=D,res=gb_trees:empty()},
- {Usage,_} = check_liveness(R, Is, St),
- Usage.
-
-
-%% is_killed_block(Register, [Instruction]) -> true|false
-%% Determine whether a register is killed by the instruction sequence inside
-%% a block.
-%%
-%% If true is returned, it means that the register will not be
-%% referenced in ANY way (not even indirectly by an allocate instruction);
-%% i.e. it is OK to enter the instruction sequence with Register
-%% containing garbage.
-
--spec is_killed_block(beam_asm:reg(), [instruction()]) -> boolean().
-
-is_killed_block({x,X}, [{set,_,_,{alloc,Live,_}}|_]) ->
- X >= Live;
-is_killed_block(R, [{set,Ds,Ss,_Op}|Is]) ->
- not member(R, Ss) andalso (member(R, Ds) orelse is_killed_block(R, Is));
-is_killed_block(R, [{'%anno',{used,Regs}}|Is]) ->
- case R of
- {x,X} when (Regs bsr X) band 1 =:= 0 -> true;
- _ -> is_killed_block(R, Is)
- end;
-is_killed_block(_, []) -> false.
-
%% is_killed(Register, [Instruction], State) -> true|false
%% Determine whether a register is killed by the instruction sequence.
%% If true is returned, it means that the register will not be
@@ -261,42 +219,6 @@ is_pure_test({test,is_function2,_,[_,_]}) -> true;
is_pure_test({test,Op,_,Ops}) ->
erl_internal:new_type_test(Op, length(Ops)).
-
-%% live_opt([Instruction]) -> [Instruction].
-%% Go through the instruction sequence in reverse execution
-%% order, keep track of liveness and remove 'move' instructions
-%% whose destination is a register that will not be used.
-%% Also insert {used,Regs} annotations at the beginning
-%% and end of each block.
-
--spec live_opt([instruction()]) -> [instruction()].
-
-live_opt(Is0) ->
- {[{label,Fail}|_]=Bef,[Fi|Is]} =
- splitwith(fun({func_info,_,_,_}) -> false;
- (_) -> true
- end, Is0),
- {func_info,_,_,Live} = Fi,
- D = gb_trees:insert(Fail, live_call(Live), gb_trees:empty()),
- Bef ++ [Fi|live_opt(reverse(Is), 0, D, [])].
-
-
-%% delete_annos([Instruction]) -> [Instruction].
-%% Delete all annotations.
-
--spec delete_annos([instruction()]) -> [instruction()].
-
-delete_annos([{block,Bl0}|Is]) ->
- case delete_annos(Bl0) of
- [] -> delete_annos(Is);
- [_|_]=Bl -> [{block,Bl}|delete_annos(Is)]
- end;
-delete_annos([{'%anno',_}|Is]) ->
- delete_annos(Is);
-delete_annos([I|Is]) ->
- [I|delete_annos(Is)];
-delete_annos([]) -> [].
-
%% combine_heap_needs(HeapNeed1, HeapNeed2) -> HeapNeed
%% Combine the heap need for two allocation instructions.
@@ -310,24 +232,6 @@ combine_heap_needs(H1, H2) when is_integer(H1), is_integer(H2) ->
combine_heap_needs(H1, H2) ->
{alloc,combine_alloc_lists([H1,H2])}.
-
-%% anno_defs(Instructions) -> Instructions'
-%% Add {def,RegisterBitmap} annotations to the beginning of
-%% each block. Iff bit X is set in the the bitmap, it means
-%% that {x,X} is defined when the block is entered.
-
--spec anno_defs([instruction()]) -> [instruction()].
-
-anno_defs(Is0) ->
- {Bef,[Fi|Is1]} =
- splitwith(fun({func_info,_,_,_}) -> false;
- (_) -> true
- end, Is0),
- {func_info,_,_,Arity} = Fi,
- Regs = init_def_regs(Arity),
- Is = defs(Is1, Regs, #{}),
- Bef ++ [Fi|Is].
-
%% split_even/1
%% [1,2,3,4,5,6] -> {[1,3,5],[2,4,6]}
@@ -846,466 +750,7 @@ combine_alloc_lists(Al0) ->
%% live_opt/4.
-%% Bit syntax instructions.
-live_opt([{bs_context_to_binary,Src}=I|Is], Regs0, D, Acc) ->
- Regs = x_live([Src], Regs0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{bs_init,Fail,_,none,Ss,Dst}=I|Is], Regs0, D, Acc) ->
- Regs1 = x_live(Ss, x_dead([Dst], Regs0)),
- Regs = live_join_label(Fail, D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{bs_init,Fail,Info,Live0,Ss,Dst}|Is], Regs0, D, Acc) ->
- Regs1 = x_dead([Dst], Regs0),
- Live = live_regs(Regs1),
- true = Live =< Live0, %Assertion.
- Regs2 = live_call(Live),
- Regs3 = x_live(Ss, Regs2),
- Regs = live_join_label(Fail, D, Regs3),
- I = {bs_init,Fail,Info,Live,Ss,Dst},
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{bs_put,Fail,_,Ss}=I|Is], Regs0, D, Acc) ->
- Regs1 = x_live(Ss, Regs0),
- Regs = live_join_label(Fail, D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{bs_restore2,Src,_}=I|Is], Regs0, D, Acc) ->
- Regs = x_live([Src], Regs0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{bs_save2,Src,_}=I|Is], Regs0, D, Acc) ->
- Regs = x_live([Src], Regs0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{test,bs_start_match2,Fail,Live,[Src,_],_}=I|Is], _, D, Acc) ->
- Regs0 = live_call(Live),
- Regs1 = x_live([Src], Regs0),
- Regs = live_join_label(Fail, D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-
-%% Other instructions.
-live_opt([{block,Bl0}|Is], Regs0, D, Acc) ->
- Live0 = make_anno({used,Regs0}),
- {Bl,Regs} = live_opt_block(reverse(Bl0), Regs0, D, [Live0]),
- Live = make_anno({used,Regs}),
- live_opt(Is, Regs, D, [{block,[Live|Bl]}|Acc]);
-live_opt([build_stacktrace=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(1), D, [I|Acc]);
-live_opt([raw_raise=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(3), D, [I|Acc]);
-live_opt([{label,L}=I|Is], Regs, D0, Acc) ->
- D = gb_trees:insert(L, Regs, D0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{jump,{f,L}}=I|Is], _, D, Acc) ->
- Regs = gb_trees:get(L, D),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([return=I|Is], _, D, Acc) ->
- live_opt(Is, 1, D, [I|Acc]);
-live_opt([{catch_end,_}=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(1), D, [I|Acc]);
-live_opt([{badmatch,Src}=I|Is], _, D, Acc) ->
- Regs = x_live([Src], 0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{case_end,Src}=I|Is], _, D, Acc) ->
- Regs = x_live([Src], 0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{try_case_end,Src}=I|Is], _, D, Acc) ->
- Regs = x_live([Src], 0),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([if_end=I|Is], _, D, Acc) ->
- Regs = 0,
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{call,Arity,_}=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(Arity), D, [I|Acc]);
-live_opt([{call_ext,Arity,_}=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(Arity), D, [I|Acc]);
-live_opt([{call_fun,Arity}=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(Arity+1), D, [I|Acc]);
-live_opt([{apply,Arity}=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(Arity+2), D, [I|Acc]);
-live_opt([{make_fun2,_,_,_,Arity}=I|Is], _, D, Acc) ->
- live_opt(Is, live_call(Arity), D, [I|Acc]);
-live_opt([{test,_,Fail,Ss}=I|Is], Regs0, D, Acc) ->
- Regs1 = x_live(Ss, Regs0),
- Regs = live_join_label(Fail, D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{test,_,Fail,Live,Ss,_}=I|Is], _, D, Acc) ->
- Regs0 = live_call(Live),
- Regs1 = x_live(Ss, Regs0),
- Regs = live_join_label(Fail, D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{select,_,Src,Fail,List}=I|Is], _, D, Acc) ->
- Regs0 = 0,
- Regs1 = x_live([Src], Regs0),
- Regs = live_join_labels([Fail|List], D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{try_case,Y}=I|Is], Regs0, D, Acc) ->
- Regs = live_call(1),
- case Regs0 of
- 0 ->
- live_opt(Is, Regs, D, [{try_end,Y}|Acc]);
- _ ->
- live_opt(Is, live_call(1), D, [I|Acc])
- end;
-live_opt([{loop_rec,_Fail,_Dst}=I|Is], _, D, Acc) ->
- live_opt(Is, 0, D, [I|Acc]);
-live_opt([timeout=I|Is], _, D, Acc) ->
- live_opt(Is, 0, D, [I|Acc]);
-live_opt([{wait,_}=I|Is], _, D, Acc) ->
- live_opt(Is, 0, D, [I|Acc]);
-live_opt([{get_map_elements,Fail,Src,{list,List}}=I|Is], Regs0, D, Acc) ->
- {Ss,Ds} = split_even(List),
- Regs1 = x_live([Src|Ss], x_dead(Ds, Regs0)),
- Regs = live_join_label(Fail, D, Regs1),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{gc_bif,N,F,R,As,Dst}=I|Is], Regs0, D, Acc) ->
- Bl = [{set,[Dst],As,{alloc,R,{gc_bif,N,F}}}],
- {_,Regs} = live_opt_block(Bl, Regs0, D, []),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{bif,N,F,As,Dst}=I|Is], Regs0, D, Acc) ->
- Bl = [{set,[Dst],As,{bif,N,F}}],
- {_,Regs} = live_opt_block(Bl, Regs0, D, []),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{get_tuple_element,Src,Idx,Dst}=I|Is], Regs0, D, Acc) ->
- Bl = [{set,[Dst],[Src],{get_tuple_element,Idx}}],
- {_,Regs} = live_opt_block(Bl, Regs0, D, []),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{move,Src,Dst}=I|Is], Regs0, D, Acc) ->
- Regs = x_live([Src], x_dead([Dst], Regs0)),
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{put_map,F,Op,S,Dst,R,{list,Puts}}=I|Is], Regs0, D, Acc) ->
- Bl = [{set,[Dst],[S|Puts],{alloc,R,{put_map,Op,F}}}],
- {_,Regs} = live_opt_block(Bl, Regs0, D, []),
- live_opt(Is, Regs, D, [I|Acc]);
-
-%% Transparent instructions - they neither use nor modify x registers.
-live_opt([{deallocate,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{kill,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{try_end,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{loop_rec_end,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{wait_timeout,_,nil}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{wait_timeout,_,{Tag,_}}=I|Is], Regs, D, Acc) when Tag =/= x ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{line,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{'catch',_,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{'try',_,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-
-%% The following instructions can occur if the "compilation" has been
-%% started from a .S file using the 'from_asm' option.
-live_opt([{trim,_,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{'%',_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{recv_set,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-live_opt([{recv_mark,_}=I|Is], Regs, D, Acc) ->
- live_opt(Is, Regs, D, [I|Acc]);
-
-live_opt([], _, _, Acc) -> Acc.
-
-live_opt_block([{set,[{x,X}]=Ds,Ss,move}=I|Is], Regs0, D, Acc) ->
- Regs = x_live(Ss, x_dead(Ds, Regs0)),
- case is_live(X, Regs0) of
- true ->
- live_opt_block(Is, Regs, D, [I|Acc]);
- false ->
- %% Useless move, will never be used.
- live_opt_block(Is, Regs, D, Acc)
- end;
-live_opt_block([{set,Ds,Ss,{alloc,Live0,AllocOp}}|Is], Regs0, D, Acc) ->
- %% Calculate liveness from the point of view of the GC.
- %% There will never be a GC if the instruction fails, so we should
- %% ignore the failure branch.
- GcRegs1 = x_dead(Ds, Regs0),
- GcRegs = x_live(Ss, GcRegs1),
- Live = live_regs(GcRegs),
-
- %% The life-time analysis used by the code generator is sometimes too
- %% conservative, so it may be possible to lower the number of live
- %% registers based on the exact liveness information. The main benefit is
- %% that more optimizations that depend on liveness information (such as the
- %% beam_dead pass) may be applied.
- true = Live =< Live0, %Assertion.
- I = {set,Ds,Ss,{alloc,Live,AllocOp}},
-
- %% Calculate liveness from the point of view of the preceding instruction.
- %% The liveness is the union of live registers in the GC and the live
- %% registers at the failure label.
- Regs1 = live_call(Live),
- Regs = live_join_alloc(AllocOp, D, Regs1),
- live_opt_block(Is, Regs, D, [I|Acc]);
-live_opt_block([{set,Ds,Ss,{bif,_,Fail}}=I|Is], Regs0, D, Acc) ->
- Regs1 = x_dead(Ds, Regs0),
- Regs2 = x_live(Ss, Regs1),
- Regs = live_join_label(Fail, D, Regs2),
- live_opt_block(Is, Regs, D, [I|Acc]);
-live_opt_block([{set,Ds,Ss,_}=I|Is], Regs0, D, Acc) ->
- Regs = x_live(Ss, x_dead(Ds, Regs0)),
- live_opt_block(Is, Regs, D, [I|Acc]);
-live_opt_block([{'%anno',_}|Is], Regs, D, Acc) ->
- live_opt_block(Is, Regs, D, Acc);
-live_opt_block([], Regs, _, Acc) -> {Acc,Regs}.
-
-live_join_alloc({Kind,_Name,Fail}, D, Regs) when Kind =:= gc_bif; Kind =:= put_map ->
- live_join_label(Fail, D, Regs);
-live_join_alloc(_, _, Regs) -> Regs.
-
-live_join_labels([{f,L}|T], D, Regs0) when L =/= 0 ->
- Regs = gb_trees:get(L, D) bor Regs0,
- live_join_labels(T, D, Regs);
-live_join_labels([_|T], D, Regs) ->
- live_join_labels(T, D, Regs);
-live_join_labels([], _, Regs) -> Regs.
-
-live_join_label({f,0}, _, Regs) ->
- Regs;
-live_join_label({f,L}, D, Regs) ->
- gb_trees:get(L, D) bor Regs.
-
-live_call(Live) -> (1 bsl Live) - 1.
-
-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.
-
-is_live(X, Regs) -> ((Regs bsr X) band 1) =:= 1.
-
split_even([], Ss, Ds) ->
{reverse(Ss),reverse(Ds)};
split_even([S,D|Rs], Ss, Ds) ->
split_even(Rs, [S|Ss], [D|Ds]).
-
-%%%
-%%% Add annotations for defined registers.
-%%%
-%%% This analysis is done by scanning the instructions in
-%%% execution order.
-%%%
-
-defs([{apply,_}=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([{bif,_,{f,Fail},_Src,Dst}=I|Is], Regs0, D) ->
- Regs = def_regs([Dst], Regs0),
- [I|defs(Is, Regs, update_regs(Fail, Regs0, D))];
-defs([{block,Block0}|Is], Regs0, D0) ->
- {Block,Regs,D} = defs_list(Block0, Regs0, D0),
- [{block,[make_anno({def,Regs0})|Block]}|defs(Is, Regs, D)];
-defs([{bs_init,{f,L},_,Live,_,Dst}=I|Is], Regs0, D) ->
- Regs1 = case Live of
- none -> Regs0;
- _ -> init_def_regs(Live)
- end,
- Regs = def_regs([Dst], Regs1),
- [I|defs(Is, Regs, update_regs(L, Regs, D))];
-defs([{bs_put,{f,L},_,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, update_regs(L, Regs, D))];
-defs([build_stacktrace=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([{call,_,_}=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([{call_ext,_,{extfunc,M,F,A}}=I|Is], _Regs, D) ->
- case erl_bifs:is_exit_bif(M, F, A) of
- false ->
- [I|defs(Is, 1, D)];
- true ->
- [I|defs_unreachable(Is, D)]
- end;
-defs([{call_ext,_,_}=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([{call_fun,_}=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([{'catch',_,{f,L}}=I|Is], Regs, D) ->
- RegsAtLabel = init_def_regs(1),
- [I|defs(Is, Regs, update_regs(L, RegsAtLabel, D))];
-defs([{catch_end,_}=I|Is], _Regs, D) ->
- Regs = init_def_regs(1),
- [I|defs(Is, Regs, D)];
-defs([{gc_bif,_,{f,Fail},Live,_Src,Dst}=I|Is], Regs0, D) ->
- true = all_defined(Live, Regs0), %Assertion.
- Regs = def_regs([Dst], init_def_regs(Live)),
- [I|defs(Is, Regs, update_regs(Fail, Regs0, D))];
-defs([{get_map_elements,{f,L},_Src,{list,DstList}}=I|Is], Regs0, D) ->
- {_,Ds} = beam_utils:split_even(DstList),
- Regs = def_regs(Ds, Regs0),
- [I|defs(Is, Regs, update_regs(L, Regs0, D))];
-defs([{get_tuple_element,_,_,Dst}=I|Is], Regs0, D) ->
- Regs = def_regs([Dst], Regs0),
- [I|defs(Is, Regs, D)];
-defs([{jump,{f,L}}=I|Is], Regs, D) ->
- [I|defs_unreachable(Is, update_regs(L, Regs, D))];
-defs([{label,L}=I|Is], Regs0, D) ->
- case D of
- #{L:=Regs1} ->
- Regs = Regs0 band Regs1,
- [I|defs(Is, Regs, D)];
- #{} ->
- [I|defs(Is, Regs0, D)]
- end;
-defs([{loop_rec,{f,L},{x,0}}=I|Is], _Regs, D0) ->
- RegsAtLabel = init_def_regs(0),
- D = update_regs(L, RegsAtLabel, D0),
- [I|defs(Is, init_def_regs(1), D)];
-defs([{loop_rec_end,_}=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-defs([{make_fun2,_,_,_,_}=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([{move,_,Dst}=I|Is], Regs0, D) ->
- Regs = def_regs([Dst], Regs0),
- [I|defs(Is, Regs, D)];
-defs([{put_map,{f,Fail},_,_,Dst,_,_}=I|Is], Regs0, D) ->
- Regs = def_regs([Dst], Regs0),
- [I|defs(Is, Regs, update_regs(Fail, Regs0, D))];
-defs([raw_raise=I|Is], _Regs, D) ->
- [I|defs(Is, 1, D)];
-defs([return=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-defs([{select,_,_Src,Fail,List}=I|Is], Regs, D0) ->
- D = update_list([Fail|List], Regs, D0),
- [I|defs_unreachable(Is, D)];
-defs([{test,_,{f,L},_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, update_regs(L, Regs, D))];
-defs([{test,_,{f,L},Live,_,Dst}=I|Is], Regs0, D) ->
- true = all_defined(Live, Regs0), %Assertion.
- Regs = def_regs([Dst], init_def_regs(Live)),
- [I|defs(Is, Regs, update_regs(L, Regs0, D))];
-defs([{'try',_,{f,L}}=I|Is], Regs, D) ->
- RegsAtLabel = init_def_regs(3),
- [I|defs(Is, Regs, update_regs(L, RegsAtLabel, D))];
-defs([{try_case,_}=I|Is], _Regs, D) ->
- [I|defs(Is, init_def_regs(3), D)];
-defs([{wait,_}=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-defs([{wait_timeout,_,_}=I|Is], _Regs, D) ->
- [I|defs(Is, 0, D)];
-
-%% Exceptions.
-defs([{badmatch,_}=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-defs([{case_end,_}=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-defs([if_end=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-defs([{try_case_end,_}=I|Is], _Regs, D) ->
- [I|defs_unreachable(Is, D)];
-
-%% Neutral instructions
-defs([{bs_context_to_binary,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{bs_restore2,_,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{bs_save2,_,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{deallocate,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{kill,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{line,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{recv_mark,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{recv_set,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([timeout=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{trim,_,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{try_end,_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([{'%',_}=I|Is], Regs, D) ->
- [I|defs(Is, Regs, D)];
-defs([], _, _) -> [].
-
-defs_unreachable([{label,L}=I|Is], D) ->
- case D of
- #{L:=Regs} ->
- [I|defs(Is, Regs, D)];
- #{} ->
- defs_unreachable(Is, D)
- end;
-defs_unreachable([_|Is], D) ->
- defs_unreachable(Is, D);
-defs_unreachable([], _D) -> [].
-
-defs_list(Is, Regs, D) ->
- defs_list(Is, Regs, D, []).
-
-defs_list([{set,Ds,_,{alloc,Live,Info}}=I|Is], Regs0, D0, Acc) ->
- true = all_defined(Live, Regs0), %Assertion.
- D = case Info of
- {gc_bif,_,{f,Fail}} ->
- update_regs(Fail, Regs0, D0);
- {put_map,_,{f,Fail}} ->
- update_regs(Fail, Regs0, D0);
- _ ->
- D0
- end,
- Regs = def_regs(Ds, init_def_regs(Live)),
- defs_list(Is, Regs, D, [I|Acc]);
-defs_list([{set,Ds,_,Info}=I|Is], Regs0, D0, Acc) ->
- D = case Info of
- {bif,_,{f,Fail}} ->
- update_regs(Fail, Regs0, D0);
- {try_catch,'catch',{f,Fail}} ->
- update_regs(Fail, init_def_regs(1), D0);
- {try_catch,'try',{f,Fail}} ->
- update_regs(Fail, init_def_regs(3), D0);
- _ ->
- D0
- end,
- Regs = def_regs(Ds, Regs0),
- defs_list(Is, Regs, D, [I|Acc]);
-defs_list([], Regs, D, Acc) ->
- {reverse(Acc),Regs,D}.
-
-init_def_regs(Arity) ->
- (1 bsl Arity) - 1.
-
-def_regs([{x,X}|T], Regs) ->
- def_regs(T, Regs bor (1 bsl X));
-def_regs([_|T], Regs) ->
- def_regs(T, Regs);
-def_regs([], Regs) -> Regs.
-
-update_list([{f,L}|T], Regs, D0) ->
- D = update_regs(L, Regs, D0),
- update_list(T, Regs, D);
-update_list([_|T], Regs, D) ->
- update_list(T, Regs, D);
-update_list([], _Regs, D) -> D.
-
-update_regs(L, Regs0, D) ->
- case D of
- #{L:=Regs1} ->
- Regs = Regs0 band Regs1,
- D#{L:=Regs};
- #{} ->
- D#{L=>Regs0}
- end.
-
-all_defined(Live, Regs) ->
- All = (1 bsl Live) - 1,
- Regs band All =:= All.
-
-%%%
-%%% Utilities.
-%%%
-
-%% make_anno(Anno) -> WrappedAnno.
-%% Wrap an annotation term.
-
-make_anno(Anno) ->
- {'%anno',Anno}.