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authorMagnus Lång <[email protected]>2017-03-16 16:39:26 +0100
committerMagnus Lång <[email protected]>2017-03-16 20:49:42 +0100
commitd1d26f4bf9da3cc5eab4e918df771d67fe9e6bb5 (patch)
treef1d261bb46fff0908a071de80646859e19cb5809 /lib/hipe/regalloc/hipe_range_split.erl
parentcf047293ecf6ea108a1e5a412743bfb5fe66e26f (diff)
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hipe: Add range splitter range_split
hipe_range_split is a complex live range splitter, more sophisticated thatn hipe_restore_reuse, but still targeted specifically at temporaries forced onto stack by being live over call instructions. hipe_range_split partitions the control flow graph at call instructions, like hipe_regalloc_prepass. Splitting decisions are made on a per partition and per temporary basis. There are three different ways in which hipe_range_split may choose to split a temporary in a program partition: * Mode1: Spill the temp before calls, and restore it after them * Mode2: Spill the temp after definitions, restore it after calls * Mode3: Spill the temp after definitions, restore it before uses To pick which of these should be used for each temp×partiton pair, hipe_range_split uses a cost function. The cost is simply the sum of the cost of all expected stack accesses, and the cost for an individual stack access is based on the probability weight of the basic block that it resides in. This biases the range splitter so that it attempts moving stack accesses from a functions hot path to the cold path. hipe_bb_weights is used to compute the probability weights. mode3 is effectively the same as what hipe_restore_reuse does. Because of this, hipe_restore_reuse reuses the analysis pass of hipe_restore_reuse in order to compute the minimal needed set of spills and restores. The reason mode3 was introduced to hipe_range_split rather than simply composing it with hipe_restore_reuse (by running both) is that such a composition resulted in poor register allocation results due to insufficiently strong move coalescing in the register allocator. The cost function heuristic has a couple of tuning knobs: * {range_split_min_gain, Gain} (default: 1.1, range: [0.0, inf)) The minimum proportional improvement that the cost of all stack accesses to a temp must display in order for that temp to be split. * {range_split_mode1_fudge, Factor} (default: 1.1, range: [0.0, inf)) Costs for mode1 are multiplied by this factor in order to discourage it when it provides marginal benefits. The justification is that mode1 causes temps to be live for longest, thus leading to higher register pressure. * {range_split_weight_power, Factor} (default: 2, range: (0.0, inf)) Adjusts how much effect the basic block weights have on the cost of a stack access. A stack access in a block with weight 1.0 has cost 1.0, a stack access in a block with weight 0.01 has cost 1/Factor. Additionally, the option range_split_weights chooses whether the basic block weights are used at all. In the case that the input is very big, hipe_range_split automatically falls back to hipe_restore_reuse only in order to keep compile times under control. Note that this is not only because of hipe_range_split being slow, but also due to the resulting program being slow to register allocate, and is not as partitionable by hipe_regalloc_prepass. hipe_restore_reuse, on the other hand, does not affect the programs partitionability. The hipe_range_split pass is controlled by a new option ra_range_split. ra_range_split is added to o2, and ra_restore_reuse is disabled in o2.
Diffstat (limited to 'lib/hipe/regalloc/hipe_range_split.erl')
-rw-r--r--lib/hipe/regalloc/hipe_range_split.erl1187
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diff --git a/lib/hipe/regalloc/hipe_range_split.erl b/lib/hipe/regalloc/hipe_range_split.erl
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+%% -*- erlang-indent-level: 2 -*-
+%%
+%% 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.
+%%
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%%@doc
+%% TEMPORARY LIVE RANGE SPLITTING PASS
+%%
+%% Live range splitting is useful to allow a register allocator to allocate a
+%% temporary to register for a part of its lifetime, even if it cannot be for
+%% the entirety. This improves register allocation quality, at the cost of
+%% making the allocation problem more time and memory intensive to solve.
+%%
+%% Optimal allocation can be achieved if all temporaries are split at every
+%% program point (between all instructions), but this makes register allocation
+%% infeasably slow in practice. Instead, this module uses heuristics to choose
+%% which temporaries should have their live ranges split, and at which points.
+%%
+%% The range splitter only considers temps which are live during a call
+%% instruction, since they're known to be spilled. The control-flow graph is
+%% partitioned at call instructions and splitting decisions are made separately
+%% for each partition. The register copy of a temp (if any) gets a separate name
+%% in each partition.
+%%
+%% There are three different ways the range splitter may choose to split a
+%% temporary in a program partition:
+%%
+%% * Mode1: Spill the temp before calls, and restore it after them
+%% * Mode2: Spill the temp after definitions, restore it after calls
+%% * Mode3: Spill the temp after definitions, restore it before uses
+%%
+%% To pick which of these should be used for each temp×partiton pair, the range
+%% splitter uses a cost function. The cost is simply the sum of the cost of all
+%% expected stack accesses, and the cost for an individual stack access is based
+%% on the probability weight of the basic block that it resides in. This biases
+%% the range splitter so that it attempts moving stack accesses from a functions
+%% hot path to the cold path.
+%%
+%% The heuristic has a couple of tuning knobs, adjusting its preference for
+%% different spilling modes, aggressiveness, and how much influence the basic
+%% block probability weights have.
+%%
+%% Edge case not handled: Call instructions directly defining a pseudo. In that
+%% case, if that pseudo has been selected for mode2 spills, no spill is inserted
+%% after the call.
+-module(hipe_range_split).
+
+-export([split/5]).
+
+-compile(inline).
+
+%% -define(DO_ASSERT, 1).
+%% -define(DEBUG, 1).
+-include("../main/hipe.hrl").
+
+%% Heuristic tuning constants
+-define(DEFAULT_MIN_GAIN, 1.1). % option: range_split_min_gain
+-define(DEFAULT_MODE1_FUDGE, 1.1). % option: range_split_mode1_fudge
+-define(DEFAULT_WEIGHT_POWER, 2). % option: range_split_weight_power
+-define(WEIGHT_CONST_FUN(Power), math:log(Power)/math:log(100)).
+-define(WEIGHT_FUN(Wt, Const), math:pow(Wt, Const)).
+-define(HEUR_MAX_TEMPS, 20000).
+
+-type target_cfg() :: any().
+-type target_instr() :: any().
+-type target_temp() :: any().
+-type liveness() :: any().
+-type target_module() :: module().
+-type target_context() :: any().
+-type target() :: {target_module(), target_context()}.
+-type liveset() :: ordsets:ordset(temp()).
+-type temp() :: non_neg_integer().
+-type label() :: non_neg_integer().
+
+-spec split(target_cfg(), liveness(), target_module(), target_context(),
+ comp_options())
+ -> target_cfg().
+split(TCFG0, Liveness, TargetMod, TargetContext, Options) ->
+ Target = {TargetMod, TargetContext},
+ NoTemps = number_of_temporaries(TCFG0, Target),
+ if NoTemps > ?HEUR_MAX_TEMPS ->
+ ?debug_msg("~w: Too many temps (~w), falling back on restore_reuse.~n",
+ [?MODULE, NoTemps]),
+ hipe_restore_reuse:split(TCFG0, Liveness, TargetMod, TargetContext);
+ true ->
+ Wts = compute_weights(TCFG0, TargetMod, TargetContext, Options),
+ {CFG0, Temps} = convert(TCFG0, Target),
+ Avail = avail_analyse(TCFG0, Liveness, Target),
+ Defs = def_analyse(CFG0, TCFG0),
+ RDefs = rdef_analyse(CFG0),
+ PLive = plive_analyse(CFG0),
+ {CFG, DUCounts, Costs, DSets0} =
+ scan(CFG0, Liveness, PLive, Wts, Defs, RDefs, Avail, Target),
+ {DSets, _} = hipe_dsets:to_map(DSets0),
+ Renames = decide(DUCounts, Costs, Target, Options),
+ rewrite(CFG, TCFG0, Target, Liveness, PLive, Defs, Avail, DSets, Renames,
+ Temps)
+ end.
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Internal program representation
+%%
+%% Second pass: Convert cfg to internal representation
+
+-record(cfg, {
+ rpo_labels :: [label()],
+ bbs :: #{label() => bb()}
+ }).
+-type cfg() :: #cfg{}.
+
+cfg_bb(L, #cfg{bbs=BBS}) -> maps:get(L, BBS).
+
+cfg_postorder(#cfg{rpo_labels=RPO}) -> lists:reverse(RPO).
+
+-record(bb, {
+ code :: [code_elem()],
+ %% If the last instruction of code defines all allocatable registers
+ has_call :: boolean(),
+ succ :: [label()]
+ }).
+-type bb() :: #bb{}.
+-type code_elem() :: instr() | mode2_spills() | mode3_restores().
+
+bb_code(#bb{code=Code}) -> Code.
+bb_has_call(#bb{has_call=HasCall}) -> HasCall.
+bb_succ(#bb{succ=Succ}) -> Succ.
+
+bb_butlast(#bb{code=Code}) ->
+ bb_butlast_1(Code).
+
+bb_butlast_1([_Last]) -> [];
+bb_butlast_1([I|Is]) -> [I|bb_butlast_1(Is)].
+
+bb_last(#bb{code=Code}) -> lists:last(Code).
+
+-record(instr, {
+ i :: target_instr(),
+ def :: ordsets:ordset(temp()),
+ use :: ordsets:ordset(temp())
+ }).
+-type instr() :: #instr{}.
+
+-record(mode2_spills, {
+ temps :: ordsets:ordset(temp())
+ }).
+-type mode2_spills() :: #mode2_spills{}.
+
+-record(mode3_restores, {
+ temps :: ordsets:ordset(temp())
+ }).
+-type mode3_restores() :: #mode3_restores{}.
+
+-spec convert(target_cfg(), target()) -> {cfg(), temps()}.
+convert(CFG, Target) ->
+ RPO = reverse_postorder(CFG, Target),
+ {BBsList, Temps} = convert_bbs(RPO, CFG, Target, #{}, []),
+ {#cfg{rpo_labels = RPO,
+ bbs = maps:from_list(BBsList)},
+ Temps}.
+
+convert_bbs([], _CFG, _Target, Temps, Acc) -> {Acc, Temps};
+convert_bbs([L|Ls], CFG, Target, Temps0, Acc) ->
+ Succs = hipe_gen_cfg:succ(CFG, L),
+ TBB = bb(CFG, L, Target),
+ TCode = hipe_bb:code(TBB),
+ {Code, Last, Temps} = convert_code(TCode, Target, Temps0, []),
+ HasCall = defines_all_alloc(Last#instr.i, Target),
+ BB = #bb{code = Code,
+ has_call = HasCall,
+ succ = Succs},
+ convert_bbs(Ls, CFG, Target, Temps, [{L,BB}|Acc]).
+
+convert_code([], _Target, Temps, [Last|_]=Acc) ->
+ {lists:reverse(Acc), Last, Temps};
+convert_code([TI|TIs], Target, Temps0, Acc) ->
+ {TDef, TUse} = def_use(TI, Target),
+ I = #instr{i = TI,
+ def = ordsets:from_list(reg_names(TDef, Target)),
+ use = ordsets:from_list(reg_names(TUse, Target))},
+ Temps = add_temps(TUse, Target, add_temps(TDef, Target, Temps0)),
+ convert_code(TIs, Target, Temps, [I|Acc]).
+
+-type temps() :: #{temp() => target_temp()}.
+add_temps([], _Target, Temps) -> Temps;
+add_temps([T|Ts], Target, Temps) ->
+ add_temps(Ts, Target, Temps#{reg_nr(T, Target) => T}).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Fourth pass: P({DEF}) lattice fwd dataflow (for eliding stores at SPILL
+%% splits)
+-type defsi() :: #{label() => defseti() | {call, defseti(), defseti()}}.
+-type defs() :: #{label() => defsetf()}.
+
+-spec def_analyse(cfg(), target_cfg()) -> defs().
+def_analyse(CFG = #cfg{rpo_labels = RPO}, TCFG) ->
+ Defs0 = def_init(CFG),
+ def_dataf(RPO, TCFG, Defs0).
+
+-spec def_init(cfg()) -> defsi().
+def_init(#cfg{bbs = BBs}) ->
+ maps:from_list(
+ [begin
+ {L, case HasCall of
+ false -> def_init_scan(bb_code(BB), defseti_new());
+ true ->
+ {call, def_init_scan(bb_butlast(BB), defseti_new()),
+ defseti_from_ordset((bb_last(BB))#instr.def)}
+ end}
+ end || {L, BB = #bb{has_call=HasCall}} <- maps:to_list(BBs)]).
+
+def_init_scan([], Defset) -> Defset;
+def_init_scan([#instr{def=Def}|Is], Defset0) ->
+ Defset = defseti_add_ordset(Def, Defset0),
+ def_init_scan(Is, Defset).
+
+-spec def_dataf([label()], target_cfg(), defsi()) -> defs().
+def_dataf(Labels, TCFG, Defs0) ->
+ case def_dataf_once(Labels, TCFG, Defs0, 0) of
+ {Defs, 0} ->
+ def_finalise(Defs);
+ {Defs, _Changed} ->
+ def_dataf(Labels, TCFG, Defs)
+ end.
+
+-spec def_finalise(defsi()) -> defs().
+def_finalise(Defs) ->
+ maps:from_list([{K, defseti_finalise(BL)}
+ || {K, {call, BL, _}} <- maps:to_list(Defs)]).
+
+-spec def_dataf_once([label()], target_cfg(), defsi(), non_neg_integer())
+ -> {defsi(), non_neg_integer()}.
+def_dataf_once([], _TCFG, Defs, Changed) -> {Defs, Changed};
+def_dataf_once([L|Ls], TCFG, Defs0, Changed0) ->
+ AddPreds =
+ fun(Defset1) ->
+ lists:foldl(fun(P, Defset2) ->
+ defseti_union(defout(P, Defs0), Defset2)
+ end, Defset1, hipe_gen_cfg:pred(TCFG, L))
+ end,
+ Defset =
+ case Defset0 = maps:get(L, Defs0) of
+ {call, Butlast, Defout} -> {call, AddPreds(Butlast), Defout};
+ _ -> AddPreds(Defset0)
+ end,
+ Changed = case Defset =:= Defset0 of
+ true -> Changed0;
+ false -> Changed0+1
+ end,
+ def_dataf_once(Ls, TCFG, Defs0#{L := Defset}, Changed).
+
+-spec defout(label(), defsi()) -> defseti().
+defout(L, Defs) ->
+ case maps:get(L, Defs) of
+ {call, _DefButLast, Defout} -> Defout;
+ Defout -> Defout
+ end.
+
+-spec defbutlast(label(), defs()) -> defsetf().
+defbutlast(L, Defs) -> maps:get(L, Defs).
+
+-spec defseti_new() -> defseti().
+-spec defseti_union(defseti(), defseti()) -> defseti().
+-spec defseti_add_ordset(ordset:ordset(temp()), defseti()) -> defseti().
+-spec defseti_from_ordset(ordset:ordset(temp())) -> defseti().
+-spec defseti_finalise(defseti()) -> defsetf().
+-spec defsetf_member(temp(), defsetf()) -> boolean().
+-spec defsetf_intersect_ordset(ordsets:ordset(temp()), defsetf())
+ -> ordsets:ordset(temp()).
+
+-type defseti() :: bitord().
+defseti_new() -> bitord_new().
+defseti_union(A, B) -> bitord_union(A, B).
+defseti_add_ordset(OS, D) -> defseti_union(defseti_from_ordset(OS), D).
+defseti_from_ordset(OS) -> bitord_from_ordset(OS).
+defseti_finalise(D) -> bitarr_from_bitord(D).
+
+-type defsetf() :: bitarr().
+defsetf_member(E, D) -> bitarr_get(E, D).
+
+defsetf_intersect_ordset([], _D) -> [];
+defsetf_intersect_ordset([E|Es], D) ->
+ case bitarr_get(E, D) of
+ true -> [E|defsetf_intersect_ordset(Es,D)];
+ false -> defsetf_intersect_ordset(Es,D)
+ end.
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Fifth pass: P({DEF}) lattice reverse dataflow (for eliding stores at defines
+%% in mode2)
+-type rdefsi() :: #{label() =>
+ {call, rdefseti(), [label()]}
+ | {nocall, rdefseti(), rdefseti(), [label()]}}.
+-type rdefs() :: #{label() => {final, rdefsetf(), [label()]}}.
+
+-spec rdef_analyse(cfg()) -> rdefs().
+rdef_analyse(CFG = #cfg{rpo_labels=RPO}) ->
+ Defs0 = rdef_init(CFG),
+ PO = rdef_postorder(RPO, CFG, []),
+ rdef_dataf(PO, Defs0).
+
+%% Filter out 'call' labels, since they don't change
+-spec rdef_postorder([label()], cfg(), [label()]) -> [label()].
+rdef_postorder([], _CFG, Acc) -> Acc;
+rdef_postorder([L|Ls], CFG, Acc) ->
+ case bb_has_call(cfg_bb(L, CFG)) of
+ true -> rdef_postorder(Ls, CFG, Acc);
+ false -> rdef_postorder(Ls, CFG, [L|Acc])
+ end.
+
+-spec rdef_init(cfg()) -> rdefsi().
+rdef_init(#cfg{bbs = BBs}) ->
+ maps:from_list(
+ [{L, case HasCall of
+ true ->
+ Defin = rdef_init_scan(bb_butlast(BB), rdefseti_empty()),
+ {call, Defin, Succs};
+ false ->
+ Gen = rdef_init_scan(bb_code(BB), rdefseti_empty()),
+ {nocall, Gen, rdefseti_top(), Succs}
+ end}
+ || {L, BB = #bb{has_call=HasCall, succ=Succs}} <- maps:to_list(BBs)]).
+
+-spec rdef_init_scan([instr()], rdefseti()) -> rdefseti().
+rdef_init_scan([], Defset) -> Defset;
+rdef_init_scan([#instr{def=Def}|Is], Defset0) ->
+ Defset = rdefseti_add_ordset(Def, Defset0),
+ rdef_init_scan(Is, Defset).
+
+-spec rdef_dataf([label()], rdefsi()) -> rdefs().
+rdef_dataf(Labels, Defs0) ->
+ case rdef_dataf_once(Labels, Defs0, 0) of
+ {Defs, 0} ->
+ rdef_finalise(Defs);
+ {Defs, _Changed} ->
+ rdef_dataf(Labels, Defs)
+ end.
+
+-spec rdef_finalise(rdefsi()) -> rdefs().
+rdef_finalise(Defs) ->
+ maps:map(fun(L, V) ->
+ Succs = rsuccs_val(V),
+ Defout0 = rdefout_intersect(L, Defs, rdefseti_top()),
+ {final, rdefset_finalise(Defout0), Succs}
+ end, Defs).
+
+-spec rdef_dataf_once([label()], rdefsi(), non_neg_integer())
+ -> {rdefsi(), non_neg_integer()}.
+rdef_dataf_once([], Defs, Changed) -> {Defs, Changed};
+rdef_dataf_once([L|Ls], Defs0, Changed0) ->
+ #{L := {nocall, Gen, Defin0, Succs}} = Defs0,
+ Defin = rdefseti_union(Gen, rdefout_intersect(L, Defs0, Defin0)),
+ Defset = {nocall, Gen, Defin, Succs},
+ Changed = case Defin =:= Defin0 of
+ true -> Changed0;
+ false -> Changed0+1
+ end,
+ rdef_dataf_once(Ls, Defs0#{L := Defset}, Changed).
+
+-spec rdefin(label(), rdefsi()) -> rdefseti().
+rdefin(L, Defs) -> rdefin_val(maps:get(L, Defs)).
+rdefin_val({nocall, _Gen, Defin, _Succs}) -> Defin;
+rdefin_val({call, Defin, _Succs}) -> Defin.
+
+-spec rsuccs(label(), rdefsi()) -> [label()].
+rsuccs(L, Defs) -> rsuccs_val(maps:get(L, Defs)).
+rsuccs_val({nocall, _Gen, _Defin, Succs}) -> Succs;
+rsuccs_val({call, _Defin, Succs}) -> Succs.
+
+-spec rdefout(label(), rdefs()) -> rdefsetf().
+rdefout(L, Defs) ->
+ #{L := {final, Defout, _Succs}} = Defs,
+ Defout.
+
+-spec rdefout_intersect(label(), rdefsi(), rdefseti()) -> rdefseti().
+rdefout_intersect(L, Defs, Init) ->
+ lists:foldl(fun(S, Acc) ->
+ rdefseti_intersect(rdefin(S, Defs), Acc)
+ end, Init, rsuccs(L, Defs)).
+
+-type rdefseti() :: bitord() | top.
+rdefseti_top() -> top.
+rdefseti_empty() -> bitord_new().
+-spec rdefseti_from_ordset(ordsets:ordset(temp())) -> rdefseti().
+rdefseti_from_ordset(OS) -> bitord_from_ordset(OS).
+
+-spec rdefseti_add_ordset(ordsets:ordset(temp()), rdefseti()) -> rdefseti().
+rdefseti_add_ordset(_, top) -> top; % Should never happen in rdef_dataf
+rdefseti_add_ordset(OS, D) -> rdefseti_union(rdefseti_from_ordset(OS), D).
+
+-spec rdefseti_union(rdefseti(), rdefseti()) -> rdefseti().
+rdefseti_union(top, _) -> top;
+rdefseti_union(_, top) -> top;
+rdefseti_union(A, B) -> bitord_union(A, B).
+
+-spec rdefseti_intersect(rdefseti(), rdefseti()) -> rdefseti().
+rdefseti_intersect(top, D) -> D;
+rdefseti_intersect(D, top) -> D;
+rdefseti_intersect(A, B) -> bitord_intersect(A, B).
+
+-type rdefsetf() :: {arr, bitarr()} | top.
+-spec rdefset_finalise(rdefseti()) -> rdefsetf().
+rdefset_finalise(top) -> top;
+rdefset_finalise(Ord) -> {arr, bitarr_from_bitord(Ord)}.
+
+%% rdefsetf_top() -> top.
+rdefsetf_empty() -> {arr, bitarr_new()}.
+
+-spec rdefsetf_add_ordset(ordset:ordset(temp()), rdefsetf()) -> rdefsetf().
+rdefsetf_add_ordset(_, top) -> top;
+rdefsetf_add_ordset(OS, {arr, Arr}) ->
+ {arr, lists:foldl(fun bitarr_set/2, Arr, OS)}.
+
+-spec rdef_step(instr(), rdefsetf()) -> rdefsetf().
+rdef_step(#instr{def=Def}, Defset) ->
+ %% ?ASSERT(not defines_all_alloc(I, Target)),
+ rdefsetf_add_ordset(Def, Defset).
+
+-spec ordset_subtract_rdefsetf(ordsets:ordset(temp()), rdefsetf())
+ -> ordsets:ordset(temp()).
+ordset_subtract_rdefsetf(_, top) -> [];
+ordset_subtract_rdefsetf(OS, {arr, Arr}) ->
+ %% Lazy implementation; could do better if OS can grow
+ lists:filter(fun(E) -> not bitarr_get(E, Arr) end, OS).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Integer sets represented as bit sets
+%%
+%% Two representations; bitord() and bitarr()
+-define(LIMB_IX_BITS, 11).
+-define(LIMB_BITS, (1 bsl ?LIMB_IX_BITS)).
+-define(LIMB_IX(Index), (Index bsr ?LIMB_IX_BITS)).
+-define(BIT_IX(Index), (Index band (?LIMB_BITS - 1))).
+-define(BIT_MASK(Index), (1 bsl ?BIT_IX(Index))).
+
+%% bitord(): fast at union/2 and can be compared for equality with '=:='
+-type bitord() :: orddict:orddict(non_neg_integer(), 0..((1 bsl ?LIMB_BITS)-1)).
+
+-spec bitord_new() -> bitord().
+bitord_new() -> [].
+
+-spec bitord_union(bitord(), bitord()) -> bitord().
+bitord_union(Lhs, Rhs) ->
+ orddict:merge(fun(_, L, R) -> L bor R end, Lhs, Rhs).
+
+-spec bitord_intersect(bitord(), bitord()) -> bitord().
+bitord_intersect([], _) -> [];
+bitord_intersect(_, []) -> [];
+bitord_intersect([{K, L}|Ls], [{K, R}|Rs]) ->
+ [{K, L band R} | bitord_intersect(Ls, Rs)];
+bitord_intersect([{LK, _}|Ls], [{RK, _}|_]=Rs) when LK < RK ->
+ bitord_intersect(Ls, Rs);
+bitord_intersect([{LK, _}|_]=Ls, [{RK, _}|Rs]) when LK > RK ->
+ bitord_intersect(Ls, Rs).
+
+-spec bitord_from_ordset(ordsets:ordset(non_neg_integer())) -> bitord().
+bitord_from_ordset([]) -> [];
+bitord_from_ordset([B|Bs]) ->
+ bitord_from_ordset_1(Bs, ?LIMB_IX(B), ?BIT_MASK(B)).
+
+bitord_from_ordset_1([B|Bs], Key, Val) when Key =:= ?LIMB_IX(B) ->
+ bitord_from_ordset_1(Bs, Key, Val bor ?BIT_MASK(B));
+bitord_from_ordset_1([B|Bs], Key, Val) ->
+ [{Key,Val} | bitord_from_ordset_1(Bs, ?LIMB_IX(B), ?BIT_MASK(B))];
+bitord_from_ordset_1([], Key, Val) -> [{Key, Val}].
+
+%% bitarr(): fast (enough) at get/2
+-type bitarr() :: array:array(0..((1 bsl ?LIMB_BITS)-1)).
+
+-spec bitarr_new() -> bitarr().
+bitarr_new() -> array:new({default, 0}).
+
+-spec bitarr_get(non_neg_integer(), bitarr()) -> boolean().
+bitarr_get(Index, Array) ->
+ Limb = array:get(?LIMB_IX(Index), Array),
+ 0 =/= (Limb band ?BIT_MASK(Index)).
+
+-spec bitarr_set(non_neg_integer(), bitarr()) -> bitarr().
+bitarr_set(Index, Array) ->
+ Limb0 = array:get(?LIMB_IX(Index), Array),
+ Limb = Limb0 bor ?BIT_MASK(Index),
+ array:set(?LIMB_IX(Index), Limb, Array).
+
+-spec bitarr_from_bitord(bitord()) -> bitarr().
+bitarr_from_bitord(Ord) ->
+ array:from_orddict(Ord, 0).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Sixth pass: Partition-local liveness analysis
+%%
+%% As temps are not spilled when exiting a partition in mode2, only
+%% partition-local uses need to be considered when deciding which temps need
+%% restoring at partition entry.
+
+-type plive() :: #{label() =>
+ {call, liveset(), [label()]}
+ | {nocall, {liveset(), liveset()}, liveset(), [label()]}}.
+
+-spec plive_analyse(cfg()) -> plive().
+plive_analyse(CFG) ->
+ Defs0 = plive_init(CFG),
+ PO = cfg_postorder(CFG),
+ plive_dataf(PO, Defs0).
+
+-spec plive_init(cfg()) -> plive().
+plive_init(#cfg{bbs = BBs}) ->
+ maps:from_list(
+ [begin
+ {L, case HasCall of
+ true ->
+ {Gen, _} = plive_init_scan(bb_code(BB)),
+ {call, Gen, Succs};
+ false ->
+ GenKill = plive_init_scan(bb_code(BB)),
+ {nocall, GenKill, liveset_empty(), Succs}
+ end}
+ end || {L, BB = #bb{has_call=HasCall, succ=Succs}} <- maps:to_list(BBs)]).
+
+-spec plive_init_scan([instr()]) -> {liveset(), liveset()}.
+plive_init_scan([]) -> {liveset_empty(), liveset_empty()};
+plive_init_scan([#instr{def=InstrKill, use=InstrGen}|Is]) ->
+ {Gen0, Kill0} = plive_init_scan(Is),
+ Gen1 = liveset_subtract(Gen0, InstrKill),
+ Gen = liveset_union(Gen1, InstrGen),
+ Kill1 = liveset_union(Kill0, InstrKill),
+ Kill = liveset_subtract(Kill1, InstrGen),
+ {Gen, Kill}.
+
+-spec plive_dataf([label()], plive()) -> plive().
+plive_dataf(Labels, PLive0) ->
+ case plive_dataf_once(Labels, PLive0, 0) of
+ {PLive, 0} -> PLive;
+ {PLive, _Changed} ->
+ plive_dataf(Labels, PLive)
+ end.
+
+-spec plive_dataf_once([label()], plive(), non_neg_integer()) ->
+ {plive(), non_neg_integer()}.
+plive_dataf_once([], PLive, Changed) -> {PLive, Changed};
+plive_dataf_once([L|Ls], PLive0, Changed0) ->
+ Liveset =
+ case Liveset0 = maps:get(L, PLive0) of
+ {call, Livein, Succs} ->
+ {call, Livein, Succs};
+ {nocall, {Gen, Kill} = GenKill, _OldLivein, Succs} ->
+ Liveout = pliveout(L, PLive0),
+ Livein = liveset_union(Gen, liveset_subtract(Liveout, Kill)),
+ {nocall, GenKill, Livein, Succs}
+ end,
+ Changed = case Liveset =:= Liveset0 of
+ true -> Changed0;
+ false -> Changed0+1
+ end,
+ plive_dataf_once(Ls, PLive0#{L := Liveset}, Changed).
+
+-spec pliveout(label(), plive()) -> liveset().
+pliveout(L, PLive) ->
+ liveset_union([plivein(S, PLive) || S <- psuccs(L, PLive)]).
+
+-spec psuccs(label(), plive()) -> [label()].
+psuccs(L, PLive) -> psuccs_val(maps:get(L, PLive)).
+psuccs_val({call, _Livein, Succs}) -> Succs;
+psuccs_val({nocall, _GenKill, _Livein, Succs}) -> Succs.
+
+-spec plivein(label(), plive()) -> liveset().
+plivein(L, PLive) -> plivein_val(maps:get(L, PLive)).
+plivein_val({call, Livein, _Succs}) -> Livein;
+plivein_val({nocall, _GenKill, Livein, _Succs}) -> Livein.
+
+liveset_empty() -> ordsets:new().
+liveset_subtract(A, B) -> ordsets:subtract(A, B).
+liveset_union(A, B) -> ordsets:union(A, B).
+liveset_union(LivesetList) -> ordsets:union(LivesetList).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Third pass: Compute dataflow analyses required for placing mode3
+%% spills/restores.
+%% Reuse analysis implementation in hipe_restore_reuse.
+%% XXX: hipe_restore_reuse has it's own "rdef"; we would like to reuse that one
+%% too.
+-type avail() :: hipe_restore_reuse:avail().
+
+-spec avail_analyse(target_cfg(), liveness(), target()) -> avail().
+avail_analyse(CFG, Liveness, Target) ->
+ hipe_restore_reuse:analyse(CFG, Liveness, Target).
+
+-spec mode3_split_in_block(label(), avail()) -> ordsets:ordset(temp()).
+mode3_split_in_block(L, Avail) ->
+ hipe_restore_reuse:split_in_block(L, Avail).
+
+-spec mode3_block_renameset(label(), avail()) -> ordsets:ordset(temp()).
+mode3_block_renameset(L, Avail) ->
+ hipe_restore_reuse:renamed_in_block(L, Avail).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Seventh pass
+%%
+%% Compute program space partitioning, collect information required by the
+%% heuristic.
+-type part_key() :: label().
+-type part_dsets() :: hipe_dsets:dsets(part_key()).
+-type part_dsets_map() :: #{part_key() => part_key()}.
+-type ducounts() :: #{part_key() => ducount()}.
+
+-spec scan(cfg(), liveness(), plive(), weights(), defs(), rdefs(), avail(),
+ target()) -> {cfg(), ducounts(), costs(), part_dsets()}.
+scan(CFG0, Liveness, PLive, Weights, Defs, RDefs, Avail, Target) ->
+ #cfg{rpo_labels = Labels, bbs = BBs0} = CFG0,
+ CFG = CFG0#cfg{bbs=#{}}, % kill reference
+ DSets0 = hipe_dsets:new(Labels),
+ Costs0 = costs_new(),
+ {BBs, DUCounts0, Costs1, DSets1} =
+ scan_bbs(maps:to_list(BBs0), Liveness, PLive, Weights, Defs, RDefs, Avail,
+ Target, #{}, Costs0, DSets0, []),
+ {RLList, DSets2} = hipe_dsets:to_rllist(DSets1),
+ {Costs, DSets} = costs_map_roots(DSets2, Costs1),
+ DUCounts = collect_ducounts(RLList, DUCounts0, #{}),
+ {CFG#cfg{bbs=maps:from_list(BBs)}, DUCounts, Costs, DSets}.
+
+-spec collect_ducounts([{label(), [label()]}], ducounts(), ducounts())
+ -> ducounts().
+collect_ducounts([], _, Acc) -> Acc;
+collect_ducounts([{R,Ls}|RLs], DUCounts, Acc) ->
+ DUCount = lists:foldl(
+ fun(Key, FAcc) ->
+ ducount_merge(maps:get(Key, DUCounts, ducount_new()), FAcc)
+ end, ducount_new(), Ls),
+ collect_ducounts(RLs, DUCounts, Acc#{R => DUCount}).
+
+-spec scan_bbs([{label(), bb()}], liveness(), plive(), weights(), defs(),
+ rdefs(), avail(), target(), ducounts(), costs(), part_dsets(),
+ [{label(), bb()}])
+ -> {[{label(), bb()}], ducounts(), costs(), part_dsets()}.
+scan_bbs([], _Liveness, _PLive, _Weights, _Defs, _RDefs, _Avail, _Target,
+ DUCounts, Costs, DSets, Acc) ->
+ {Acc, DUCounts, Costs, DSets};
+scan_bbs([{L,BB}|BBs], Liveness, PLive, Weights, Defs, RDefs, Avail, Target,
+ DUCounts0, Costs0, DSets0, Acc) ->
+ Wt = weight(L, Weights),
+ {DSets, Costs5, EntryCode, ExitCode, RDefout, Liveout} =
+ case bb_has_call(BB) of
+ false ->
+ DSets1 = lists:foldl(fun(S, DS) -> hipe_dsets:union(L, S, DS) end,
+ DSets0, bb_succ(BB)),
+ {DSets1, Costs0, bb_code(BB), [], rdefout(L, RDefs),
+ liveout(Liveness, L, Target)};
+ true ->
+ LastI = #instr{def=LastDef} = bb_last(BB),
+ LiveBefore = ordsets:subtract(liveout(Liveness, L, Target), LastDef),
+ %% We can omit the spill of a temp that has not been defined since the
+ %% last time it was spilled
+ SpillSet = defsetf_intersect_ordset(LiveBefore, defbutlast(L, Defs)),
+ Costs1 = costs_insert(exit, L, Wt, SpillSet, Costs0),
+ Costs4 = lists:foldl(fun({S, BranchWt}, Costs2) ->
+ SLivein = livein(Liveness, S, Target),
+ SPLivein = plivein(S, PLive),
+ SWt = weight_scaled(L, BranchWt, Weights),
+ Costs3 = costs_insert(entry1, S, SWt, SLivein, Costs2),
+ costs_insert(entry2, S, SWt, SPLivein, Costs3)
+ end, Costs1, branch_preds(LastI#instr.i, Target)),
+ {DSets0, Costs4, bb_butlast(BB), [LastI], rdefsetf_empty(), LiveBefore}
+ end,
+ Mode3Splits = mode3_split_in_block(L, Avail),
+ {RevEntryCode, Restored} = scan_bb_fwd(EntryCode, Mode3Splits, [], []),
+ {Code, DUCount, Mode2Spills} =
+ scan_bb(RevEntryCode, Wt, RDefout, Liveout, ducount_new(), [], ExitCode),
+ DUCounts = DUCounts0#{L => DUCount},
+ M2SpillSet = ordsets:from_list(Mode2Spills),
+ Costs6 = costs_insert(spill, L, Wt, M2SpillSet, Costs5),
+ Mode3Renames = mode3_block_renameset(L, Avail),
+ Costs7 = costs_insert(restore, L, Wt, ordsets:intersection(M2SpillSet, Mode3Renames), Costs6),
+ Costs8 = costs_insert(restore, L, Wt, ordsets:from_list(Restored), Costs7),
+ Costs = add_unsplit_mode3_costs(DUCount, Mode3Renames, L, Costs8),
+ scan_bbs(BBs, Liveness, PLive, Weights, Defs, RDefs, Avail, Target, DUCounts,
+ Costs, DSets, [{L,BB#bb{code=Code}}|Acc]).
+
+-spec add_unsplit_mode3_costs(ducount(), ordsets:ordset(temp()), label(), costs())
+ -> costs().
+add_unsplit_mode3_costs(DUCount, Mode3Renames, L, Costs) ->
+ Unsplit = orddict_without_ordset(Mode3Renames,
+ orddict:from_list(ducount_to_list(DUCount))),
+ add_unsplit_mode3_costs_1(Unsplit, L, Costs).
+
+-spec add_unsplit_mode3_costs_1([{temp(),float()}], label(), costs())
+ -> costs().
+add_unsplit_mode3_costs_1([], _L, Costs) -> Costs;
+add_unsplit_mode3_costs_1([{T,C}|Cs], L, Costs) ->
+ add_unsplit_mode3_costs_1(Cs, L, costs_insert(restore, L, C, [T], Costs)).
+
+%% @doc Returns a new orddict without keys in Set and their associated values.
+-spec orddict_without_ordset(ordsets:ordset(K), orddict:orddict(K, V))
+ -> orddict:orddict(K, V).
+orddict_without_ordset([S|Ss], [{K,_}|_]=Dict) when S < K ->
+ orddict_without_ordset(Ss, Dict);
+orddict_without_ordset([S|_]=Set, [D={K,_}|Ds]) when S > K ->
+ [D|orddict_without_ordset(Set, Ds)];
+orddict_without_ordset([_S|Ss], [{_K,_}|Ds]) -> % _S == _K
+ orddict_without_ordset(Ss, Ds);
+orddict_without_ordset(_, []) -> [];
+orddict_without_ordset([], Dict) -> Dict.
+
+%% Scans the code forward, collecting and inserting mode3 restores
+-spec scan_bb_fwd([instr()], ordsets:ordset(temp()), ordsets:ordset(temp()),
+ [code_elem()])
+ -> {[code_elem()], ordsets:ordset(temp())}.
+scan_bb_fwd([], [], Restored, Acc) -> {Acc, Restored};
+scan_bb_fwd([I|Is], SplitHere0, Restored0, Acc0) ->
+ #instr{def=Def, use=Use} = I,
+ {ToRestore, SplitHere1} =
+ lists:partition(fun(R) -> lists:member(R, Use) end, SplitHere0),
+ SplitHere = lists:filter(fun(R) -> not lists:member(R, Def) end, SplitHere1),
+ Acc =
+ case ToRestore of
+ [] -> [I | Acc0];
+ _ -> [I, #mode3_restores{temps=ToRestore} | Acc0]
+ end,
+ scan_bb_fwd(Is, SplitHere, ToRestore ++ Restored0, Acc).
+
+%% Scans the code backwards, collecting def/use counts and mode2 spills
+-spec scan_bb([code_elem()], float(), rdefsetf(), liveset(), ducount(),
+ [temp()], [code_elem()])
+ -> {[code_elem()], ducount(), [temp()]}.
+scan_bb([], _Wt, _RDefout, _Liveout, DUCount, Spills, Acc) ->
+ {Acc, DUCount, Spills};
+scan_bb([I=#mode3_restores{}|Is], Wt, RDefout, Liveout, DUCount, Spills, Acc) ->
+ scan_bb(Is, Wt, RDefout, Liveout, DUCount, Spills, [I|Acc]);
+scan_bb([I|Is], Wt, RDefout, Liveout, DUCount0, Spills0, Acc0) ->
+ #instr{def=Def,use=Use} = I,
+ DUCount = ducount_add(Use, Wt, ducount_add(Def, Wt, DUCount0)),
+ Livein = liveness_step(I, Liveout),
+ RDefin = rdef_step(I, RDefout),
+ %% The temps that would be spilled after I in mode 2
+ NewSpills = ordset_subtract_rdefsetf(
+ ordsets:intersection(Def, Liveout),
+ RDefout),
+ ?ASSERT(NewSpills =:= (NewSpills -- Spills0)),
+ Spills = NewSpills ++ Spills0,
+ Acc1 = case NewSpills of
+ [] -> Acc0;
+ _ -> [#mode2_spills{temps=NewSpills}|Acc0]
+ end,
+ scan_bb(Is, Wt, RDefin, Livein, DUCount, Spills, [I|Acc1]).
+
+-spec liveness_step(instr(), liveset()) -> liveset().
+liveness_step(#instr{def=Def, use=Use}, Liveout) ->
+ ordsets:union(Use, ordsets:subtract(Liveout, Def)).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% First pass: compute basic-block weighting
+
+-type weights() :: no_bb_weights
+ | {hipe_bb_weights:bb_weights(), float()}.
+
+-spec weight(label(), weights()) -> float().
+weight(L, Weights) -> weight_scaled(L, 1.0, Weights).
+
+-spec compute_weights(target_cfg(), target_module(), target_context(),
+ comp_options()) -> weights().
+compute_weights(CFG, TargetMod, TargetContext, Options) ->
+ case proplists:get_bool(range_split_weights, Options) of
+ false -> no_bb_weights;
+ true ->
+ {hipe_bb_weights:compute(CFG, TargetMod, TargetContext),
+ ?WEIGHT_CONST_FUN(proplists:get_value(range_split_weight_power,
+ Options, ?DEFAULT_WEIGHT_POWER))}
+ end.
+
+-spec weight_scaled(label(), float(), weights()) -> float().
+weight_scaled(_L, _Scale, no_bb_weights) -> 1.0;
+weight_scaled(L, Scale, {Weights, Const}) ->
+ Wt0 = hipe_bb_weights:weight(L, Weights) * Scale,
+ Wt = erlang:min(erlang:max(Wt0, 0.0000000000000000001), 10000.0),
+ ?WEIGHT_FUN(Wt, Const).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Heuristic splitting decision.
+%%
+%% Decide which temps to split, in which parts, and pick new names for them.
+-type spill_mode() :: mode1 % Spill temps at partition exits
+ | mode2 % Spill temps at definitions
+ | mode3.% Spill temps at definitions, restore temps at uses
+-type ren() :: #{temp() => {spill_mode(), temp()}}.
+-type renames() :: #{label() => ren()}.
+
+-record(heur_par, {
+ mode1_fudge :: float(),
+ min_gain :: float()
+ }).
+-type heur_par() :: #heur_par{}.
+
+-spec decide(ducounts(), costs(), target(), comp_options()) -> renames().
+decide(DUCounts, Costs, Target, Options) ->
+ Par = #heur_par{
+ mode1_fudge = proplists:get_value(range_split_mode1_fudge, Options,
+ ?DEFAULT_MODE1_FUDGE),
+ min_gain = proplists:get_value(range_split_min_gain, Options,
+ ?DEFAULT_MIN_GAIN)},
+ decide_parts(maps:to_list(DUCounts), Costs, Target, Par, #{}).
+
+-spec decide_parts([{part_key(), ducount()}], costs(), target(),
+ heur_par(), renames())
+ -> renames().
+decide_parts([], _Costs, _Target, _Par, Acc) -> Acc;
+decide_parts([{Part,DUCount}|Ps], Costs, Target, Par, Acc) ->
+ Spills = decide_temps(ducount_to_list(DUCount), Part, Costs, Target, Par,
+ #{}),
+ decide_parts(Ps, Costs, Target, Par, Acc#{Part => Spills}).
+
+-spec decide_temps([{temp(), float()}], part_key(), costs(), target(),
+ heur_par(), ren())
+ -> ren().
+decide_temps([], _Part, _Costs, _Target, _Par, Acc) -> Acc;
+decide_temps([{Temp, SpillGain}|Ts], Part, Costs, Target, Par, Acc0) ->
+ SpillCost1 = costs_query(Temp, entry1, Part, Costs)
+ + costs_query(Temp, exit, Part, Costs),
+ SpillCost2 = costs_query(Temp, entry2, Part, Costs)
+ + costs_query(Temp, spill, Part, Costs),
+ SpillCost3 = costs_query(Temp, restore, Part, Costs),
+ Acc =
+ %% SpillCost1 =:= 0.0 usually means the temp is local to the partition;
+ %% hence no need to split it
+ case (SpillCost1 =/= 0.0) %% maps:is_key(Temp, S)
+ andalso (not is_precoloured(Temp, Target))
+ andalso ((Par#heur_par.min_gain*SpillCost1 < SpillGain)
+ orelse (Par#heur_par.min_gain*SpillCost2 < SpillGain)
+ orelse (Par#heur_par.min_gain*SpillCost3 < SpillGain))
+ of
+ false -> Acc0;
+ true ->
+ Mode =
+ if Par#heur_par.mode1_fudge*SpillCost1 < SpillCost2,
+ Par#heur_par.mode1_fudge*SpillCost1 < SpillCost3 ->
+ mode1;
+ SpillCost2 < SpillCost3 ->
+ mode2;
+ true ->
+ mode3
+ end,
+ Acc0#{Temp => {Mode, new_reg_nr(Target)}}
+ end,
+ decide_temps(Ts, Part, Costs, Target, Par, Acc).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Eighth pass: Rewrite program performing range splitting.
+
+-spec rewrite(cfg(), target_cfg(), target(), liveness(), plive(), defs(),
+ avail(), part_dsets_map(), renames(), temps())
+ -> target_cfg().
+rewrite(#cfg{bbs=BBs}, TCFG, Target, Liveness, PLive, Defs, Avail, DSets,
+ Renames, Temps) ->
+ rewrite_bbs(maps:to_list(BBs), Target, Liveness, PLive, Defs, Avail, DSets,
+ Renames, Temps, TCFG).
+
+-spec rewrite_bbs([{label(), bb()}], target(), liveness(), plive(), defs(),
+ avail(), part_dsets_map(), renames(), temps(), target_cfg())
+ -> target_cfg().
+rewrite_bbs([], _Target, _Liveness, _PLive, _Defs, _Avail, _DSets, _Renames,
+ _Temps, TCFG) ->
+ TCFG;
+rewrite_bbs([{L,BB}|BBs], Target, Liveness, PLive, Defs, Avail, DSets, Renames,
+ Temps, TCFG0) ->
+ Code0Rev = lists:reverse(bb_code(BB)),
+ EntryRen = maps:get(maps:get(L,DSets), Renames),
+ M3Ren = mode3_block_renameset(L, Avail),
+ SubstFun = rewrite_subst_fun(Target, EntryRen, M3Ren),
+ Fun = fun(I) -> subst_temps(SubstFun, I, Target) end,
+ {Code, TCFG} =
+ case bb_has_call(BB) of
+ false ->
+ Code1 = rewrite_instrs(Code0Rev, Fun, EntryRen, M3Ren, Temps, Target,
+ []),
+ {Code1, TCFG0};
+ true ->
+ CallI0 = hd(Code0Rev),
+ Succ = bb_succ(BB),
+ {CallTI, TCFG1} = inject_restores(Succ, Target, Liveness, PLive, DSets,
+ Renames, Temps, CallI0#instr.i, TCFG0),
+ Liveout1 = liveness_step(CallI0, liveout(Liveness, L, Target)),
+ Defout = defbutlast(L, Defs),
+ SpillMap = mk_spillmap(EntryRen, Liveout1, Defout, Temps, Target),
+ Code1 = rewrite_instrs(tl(Code0Rev), Fun, EntryRen, M3Ren, Temps,
+ Target, []),
+ Code2 = lift_spills(lists:reverse(Code1), Target, SpillMap, [CallTI]),
+ {Code2, TCFG1}
+ end,
+ TBB = hipe_bb:code_update(bb(TCFG, L, Target), Code),
+ rewrite_bbs(BBs, Target, Liveness, PLive, Defs, Avail, DSets, Renames, Temps,
+ update_bb(TCFG, L, TBB, Target)).
+
+-spec rewrite_instrs([code_elem()], rewrite_fun(), ren(),
+ ordsets:ordset(temp()), temps(), target(),
+ [target_instr()])
+ -> [target_instr()].
+rewrite_instrs([], _Fun, _Ren, _M3Ren, _Temps, _Target, Acc) -> Acc;
+rewrite_instrs([I|Is], Fun, Ren, M3Ren, Temps, Target, Acc0) ->
+ Acc =
+ case I of
+ #instr{i=TI} -> [Fun(TI)|Acc0];
+ #mode2_spills{temps=Mode2Spills} ->
+ add_mode2_spills(Mode2Spills, Target, Ren, M3Ren, Temps, Acc0);
+ #mode3_restores{temps=Mode3Restores} ->
+ add_mode3_restores(Mode3Restores, Target, Ren, Temps, Acc0)
+ end,
+ rewrite_instrs(Is, Fun, Ren, M3Ren, Temps, Target, Acc).
+
+-spec add_mode2_spills(ordsets:ordset(temp()), target(), ren(),
+ ordsets:ordset(temp()), temps(), [target_instr()])
+ -> [target_instr()].
+add_mode2_spills([], _Target, _Ren, _M3Ren, _Temps, Acc) -> Acc;
+add_mode2_spills([R|Rs], Target, Ren, M3Ren, Temps, Acc0) ->
+ Acc =
+ case Ren of
+ #{R := {Mode, NewName}} when Mode =:= mode2; Mode =:= mode3 ->
+ case Mode =/= mode3 orelse lists:member(R, M3Ren) of
+ false -> Acc0;
+ true ->
+ #{R := T} = Temps,
+ SpillInstr = mk_move(update_reg_nr(NewName, T, Target), T, Target),
+ [SpillInstr|Acc0]
+ end;
+ #{} ->
+ Acc0
+ end,
+ add_mode2_spills(Rs, Target, Ren, M3Ren, Temps, Acc).
+
+-spec add_mode3_restores(ordsets:ordset(temp()), target(), ren(), temps(),
+ [target_instr()])
+ -> [target_instr()].
+add_mode3_restores([], _Target, _Ren, _Temps, Acc) -> Acc;
+add_mode3_restores([R|Rs], Target, Ren, Temps, Acc) ->
+ case Ren of
+ #{R := {mode3, NewName}} ->
+ #{R := T} = Temps,
+ RestoreInstr = mk_move(T, update_reg_nr(NewName, T, Target), Target),
+ add_mode3_restores(Rs, Target, Ren, Temps, [RestoreInstr|Acc]);
+ #{} ->
+ add_mode3_restores(Rs, Target, Ren, Temps, Acc)
+ end.
+
+-type rewrite_fun() :: fun((target_instr()) -> target_instr()).
+-type subst_fun() :: fun((target_temp()) -> target_temp()).
+-spec rewrite_subst_fun(target(), ren(), ordsets:ordset(temp())) -> subst_fun().
+rewrite_subst_fun(Target, Ren, M3Ren) ->
+ fun(Temp) ->
+ Reg = reg_nr(Temp, Target),
+ case Ren of
+ #{Reg := {Mode, NewName}} ->
+ case Mode =/= mode3 orelse lists:member(Reg, M3Ren) of
+ false -> Temp;
+ true -> update_reg_nr(NewName, Temp, Target)
+ end;
+ #{} -> Temp
+ end
+ end.
+
+-type spillmap() :: [{temp(), target_instr()}].
+-spec mk_spillmap(ren(), liveset(), defsetf(), temps(), target())
+ -> spillmap().
+mk_spillmap(Ren, Livein, Defout, Temps, Target) ->
+ [begin
+ Temp = maps:get(Reg, Temps),
+ {NewName, mk_move(update_reg_nr(NewName, Temp, Target), Temp, Target)}
+ end || {Reg, {mode1, NewName}} <- maps:to_list(Ren),
+ lists:member(Reg, Livein), defsetf_member(Reg, Defout)].
+
+-spec mk_restores(ren(), liveset(), liveset(), temps(), target())
+ -> [target_instr()].
+mk_restores(Ren, Livein, PLivein, Temps, Target) ->
+ [begin
+ Temp = maps:get(Reg, Temps),
+ mk_move(Temp, update_reg_nr(NewName, Temp, Target), Target)
+ end || {Reg, {Mode, NewName}} <- maps:to_list(Ren),
+ ( (Mode =:= mode1 andalso lists:member(Reg, Livein ))
+ orelse (Mode =:= mode2 andalso lists:member(Reg, PLivein)))].
+
+-spec inject_restores([label()], target(), liveness(), plive(),
+ part_dsets_map(), renames(), temps(), target_instr(),
+ target_cfg())
+ -> {target_instr(), target_cfg()}.
+inject_restores([], _Target, _Liveness, _PLive, _DSets, _Renames, _Temps, CFTI,
+ TCFG) ->
+ {CFTI, TCFG};
+inject_restores([L|Ls], Target, Liveness, PLive, DSets, Renames, Temps, CFTI0,
+ TCFG0) ->
+ Ren = maps:get(maps:get(L,DSets), Renames),
+ Livein = livein(Liveness, L, Target),
+ PLivein = plivein(L, PLive),
+ {CFTI, TCFG} =
+ case mk_restores(Ren, Livein, PLivein, Temps, Target) of
+ [] -> {CFTI0, TCFG0}; % optimisation
+ Restores ->
+ RestBBLbl = new_label(Target),
+ Code = Restores ++ [mk_goto(L, Target)],
+ CFTI1 = redirect_jmp(CFTI0, L, RestBBLbl, Target),
+ TCFG1 = update_bb(TCFG0, RestBBLbl, hipe_bb:mk_bb(Code), Target),
+ {CFTI1, TCFG1}
+ end,
+ inject_restores(Ls, Target, Liveness, PLive, DSets, Renames, Temps, CFTI,
+ TCFG).
+
+%% Heuristic. Move spills up until we meet the edge of the BB or a definition of
+%% that temp.
+-spec lift_spills([target_instr()], target(), spillmap(), [target_instr()])
+ -> [target_instr()].
+lift_spills([], _Target, SpillMap, Acc) ->
+ [SpillI || {_, SpillI} <- SpillMap] ++ Acc;
+lift_spills([I|Is], Target, SpillMap0, Acc) ->
+ Def = reg_defines(I, Target),
+ {Spills0, SpillMap} =
+ lists:partition(fun({Reg,_}) -> lists:member(Reg, Def) end, SpillMap0),
+ Spills = [SpillI || {_, SpillI} <- Spills0],
+ lift_spills(Is, Target, SpillMap, [I|Spills ++ Acc]).
+
+reg_defines(I, Target) ->
+ reg_names(defines(I,Target), Target).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Costs ADT
+%%
+%% Keeps track of cumulative cost of spilling temps in particular partitions
+%% using particular spill modes.
+-type cost_map() :: #{[part_key()|temp()] => float()}.
+-type cost_key() :: entry1 | entry2 | exit | spill | restore.
+-record(costs, {entry1 = #{} :: cost_map()
+ ,entry2 = #{} :: cost_map()
+ ,exit = #{} :: cost_map()
+ ,spill = #{} :: cost_map()
+ ,restore = #{} :: cost_map()
+ }).
+-type costs() :: #costs{}.
+
+-spec costs_new() -> costs().
+costs_new() -> #costs{}.
+
+-spec costs_insert(cost_key(), part_key(), float(), liveset(), costs())
+ -> costs().
+costs_insert(entry1, A, Weight, Liveset, Costs=#costs{entry1=Entry1}) ->
+ Costs#costs{entry1=costs_insert_1(A, Weight, Liveset, Entry1)};
+costs_insert(entry2, A, Weight, Liveset, Costs=#costs{entry2=Entry2}) ->
+ Costs#costs{entry2=costs_insert_1(A, Weight, Liveset, Entry2)};
+costs_insert(exit, A, Weight, Liveset, Costs=#costs{exit=Exit}) ->
+ Costs#costs{exit=costs_insert_1(A, Weight, Liveset, Exit)};
+costs_insert(spill, A, Weight, Liveset, Costs=#costs{spill=Spill}) ->
+ Costs#costs{spill=costs_insert_1(A, Weight, Liveset, Spill)};
+costs_insert(restore, A, Weight, Liveset, Costs=#costs{restore=Restore}) ->
+ Costs#costs{restore=costs_insert_1(A, Weight, Liveset, Restore)}.
+
+costs_insert_1(A, Weight, Liveset, CostMap0) when is_float(Weight) ->
+ lists:foldl(fun(Live, CostMap1) ->
+ map_update_counter([A|Live], Weight, CostMap1)
+ end, CostMap0, Liveset).
+
+-spec costs_map_roots(part_dsets(), costs()) -> {costs(), part_dsets()}.
+costs_map_roots(DSets0, Costs) ->
+ {Entry1, DSets1} = costs_map_roots_1(DSets0, Costs#costs.entry1),
+ {Entry2, DSets2} = costs_map_roots_1(DSets1, Costs#costs.entry2),
+ {Exit, DSets3} = costs_map_roots_1(DSets2, Costs#costs.exit),
+ {Spill, DSets4} = costs_map_roots_1(DSets3, Costs#costs.spill),
+ {Restore, DSets} = costs_map_roots_1(DSets4, Costs#costs.restore),
+ {#costs{entry1=Entry1,entry2=Entry2,exit=Exit,spill=Spill,restore=Restore},
+ DSets}.
+
+costs_map_roots_1(DSets0, CostMap) ->
+ {NewEs, DSets} = lists:mapfoldl(fun({[A|T], Wt}, DSets1) ->
+ {AR, DSets2} = hipe_dsets:find(A, DSets1),
+ {{[AR|T], Wt}, DSets2}
+ end, DSets0, maps:to_list(CostMap)),
+ {maps_from_list_merge(NewEs, fun erlang:'+'/2, #{}), DSets}.
+
+maps_from_list_merge([], _MF, Acc) -> Acc;
+maps_from_list_merge([{K,V}|Ps], MF, Acc) ->
+ maps_from_list_merge(Ps, MF, case Acc of
+ #{K := OV} -> Acc#{K := MF(V, OV)};
+ #{} -> Acc#{K => V}
+ end).
+
+-spec costs_query(temp(), cost_key(), part_key(), costs()) -> float().
+costs_query(Temp, entry1, Part, #costs{entry1=Entry1}) ->
+ costs_query_1(Temp, Part, Entry1);
+costs_query(Temp, entry2, Part, #costs{entry2=Entry2}) ->
+ costs_query_1(Temp, Part, Entry2);
+costs_query(Temp, exit, Part, #costs{exit=Exit}) ->
+ costs_query_1(Temp, Part, Exit);
+costs_query(Temp, spill, Part, #costs{spill=Spill}) ->
+ costs_query_1(Temp, Part, Spill);
+costs_query(Temp, restore, Part, #costs{restore=Restore}) ->
+ costs_query_1(Temp, Part, Restore).
+
+costs_query_1(Temp, Part, CostMap) ->
+ Key = [Part|Temp],
+ case CostMap of
+ #{Key := Wt} -> Wt;
+ #{} -> 0.0
+ end.
+
+-spec map_update_counter(Key, number(), #{Key => number(), OK => OV})
+ -> #{Key := number(), OK => OV}.
+map_update_counter(Key, Incr, Map) ->
+ case Map of
+ #{Key := Orig} -> Map#{Key := Orig + Incr};
+ #{} -> Map#{Key => Incr}
+ end.
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Def and use counting ADT
+-type ducount() :: #{temp() => float()}.
+
+-spec ducount_new() -> ducount().
+ducount_new() -> #{}.
+
+-spec ducount_add([temp()], float(), ducount()) -> ducount().
+ducount_add([], _Weight, DUCount) -> DUCount;
+ducount_add([T|Ts], Weight, DUCount0) ->
+ DUCount =
+ case DUCount0 of
+ #{T := Count} -> DUCount0#{T := Count + Weight};
+ #{} -> DUCount0#{T => Weight}
+ end,
+ ducount_add(Ts, Weight, DUCount).
+
+ducount_to_list(DUCount) -> maps:to_list(DUCount).
+
+-spec ducount_merge(ducount(), ducount()) -> ducount().
+ducount_merge(DCA, DCB) when map_size(DCA) < map_size(DCB) ->
+ ducount_merge_1(ducount_to_list(DCA), DCB);
+ducount_merge(DCA, DCB) when map_size(DCA) >= map_size(DCB) ->
+ ducount_merge_1(ducount_to_list(DCB), DCA).
+
+ducount_merge_1([], DUCount) -> DUCount;
+ducount_merge_1([{T,AC}|Ts], DUCount0) ->
+ DUCount =
+ case DUCount0 of
+ #{T := BC} -> DUCount0#{T := AC + BC};
+ #{} -> DUCount0#{T => AC}
+ end,
+ ducount_merge_1(Ts, DUCount).
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%% Target module interface functions
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+-define(TGT_IFACE_0(N), N( {M,C}) -> M:N( C)).
+-define(TGT_IFACE_1(N), N(A1, {M,C}) -> M:N(A1, C)).
+-define(TGT_IFACE_2(N), N(A1,A2, {M,C}) -> M:N(A1,A2, C)).
+-define(TGT_IFACE_3(N), N(A1,A2,A3,{M,C}) -> M:N(A1,A2,A3,C)).
+
+?TGT_IFACE_2(bb).
+?TGT_IFACE_1(def_use).
+?TGT_IFACE_1(defines).
+?TGT_IFACE_1(defines_all_alloc).
+?TGT_IFACE_1(is_precoloured).
+?TGT_IFACE_1(mk_goto).
+?TGT_IFACE_2(mk_move).
+?TGT_IFACE_0(new_label).
+?TGT_IFACE_0(new_reg_nr).
+?TGT_IFACE_1(number_of_temporaries).
+?TGT_IFACE_3(redirect_jmp).
+?TGT_IFACE_1(reg_nr).
+?TGT_IFACE_1(reverse_postorder).
+?TGT_IFACE_2(subst_temps).
+?TGT_IFACE_3(update_bb).
+?TGT_IFACE_2(update_reg_nr).
+
+branch_preds(Instr, {TgtMod,TgtCtx}) ->
+ merge_sorted_preds(lists:keysort(1, TgtMod:branch_preds(Instr, TgtCtx))).
+
+livein(Liveness, L, Target={TgtMod,TgtCtx}) ->
+ ordsets:from_list(reg_names(TgtMod:livein(Liveness, L, TgtCtx), Target)).
+
+liveout(Liveness, L, Target={TgtMod,TgtCtx}) ->
+ ordsets:from_list(reg_names(TgtMod:liveout(Liveness, L, TgtCtx), Target)).
+
+merge_sorted_preds([]) -> [];
+merge_sorted_preds([{L, P1}, {L, P2}|LPs]) ->
+ merge_sorted_preds([{L, P1+P2}|LPs]);
+merge_sorted_preds([LP|LPs]) -> [LP|merge_sorted_preds(LPs)].
+
+reg_names(Regs, {TgtMod,TgtCtx}) ->
+ [TgtMod:reg_nr(X,TgtCtx) || X <- Regs].