1ca7c307dSSotiris Apostolakis //===--- SelectOptimize.cpp - Convert select to branches if profitable ---===//
2ca7c307dSSotiris Apostolakis //
3ca7c307dSSotiris Apostolakis // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4ca7c307dSSotiris Apostolakis // See https://llvm.org/LICENSE.txt for license information.
5ca7c307dSSotiris Apostolakis // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6ca7c307dSSotiris Apostolakis //
7ca7c307dSSotiris Apostolakis //===----------------------------------------------------------------------===//
8ca7c307dSSotiris Apostolakis //
9ca7c307dSSotiris Apostolakis // This pass converts selects to conditional jumps when profitable.
10ca7c307dSSotiris Apostolakis //
11ca7c307dSSotiris Apostolakis //===----------------------------------------------------------------------===//
12ca7c307dSSotiris Apostolakis
13d7ebb746SSotiris Apostolakis #include "llvm/ADT/Optional.h"
1497c3ef5cSSotiris Apostolakis #include "llvm/ADT/SmallVector.h"
1597c3ef5cSSotiris Apostolakis #include "llvm/ADT/Statistic.h"
1697c3ef5cSSotiris Apostolakis #include "llvm/Analysis/BlockFrequencyInfo.h"
1797c3ef5cSSotiris Apostolakis #include "llvm/Analysis/BranchProbabilityInfo.h"
1897c3ef5cSSotiris Apostolakis #include "llvm/Analysis/LoopInfo.h"
198b42bc56SSotiris Apostolakis #include "llvm/Analysis/OptimizationRemarkEmitter.h"
208b42bc56SSotiris Apostolakis #include "llvm/Analysis/ProfileSummaryInfo.h"
218b42bc56SSotiris Apostolakis #include "llvm/Analysis/TargetTransformInfo.h"
22ca7c307dSSotiris Apostolakis #include "llvm/CodeGen/Passes.h"
2397c3ef5cSSotiris Apostolakis #include "llvm/CodeGen/TargetLowering.h"
2497c3ef5cSSotiris Apostolakis #include "llvm/CodeGen/TargetPassConfig.h"
2597c3ef5cSSotiris Apostolakis #include "llvm/CodeGen/TargetSchedule.h"
2697c3ef5cSSotiris Apostolakis #include "llvm/CodeGen/TargetSubtargetInfo.h"
2797c3ef5cSSotiris Apostolakis #include "llvm/IR/BasicBlock.h"
288b42bc56SSotiris Apostolakis #include "llvm/IR/Dominators.h"
29ca7c307dSSotiris Apostolakis #include "llvm/IR/Function.h"
3097c3ef5cSSotiris Apostolakis #include "llvm/IR/IRBuilder.h"
3197c3ef5cSSotiris Apostolakis #include "llvm/IR/Instruction.h"
32ca7c307dSSotiris Apostolakis #include "llvm/InitializePasses.h"
33ca7c307dSSotiris Apostolakis #include "llvm/Pass.h"
34d7ebb746SSotiris Apostolakis #include "llvm/Support/ScaledNumber.h"
3597c3ef5cSSotiris Apostolakis #include "llvm/Target/TargetMachine.h"
368b42bc56SSotiris Apostolakis #include "llvm/Transforms/Utils/SizeOpts.h"
378b42bc56SSotiris Apostolakis #include <algorithm>
388b42bc56SSotiris Apostolakis #include <memory>
398b42bc56SSotiris Apostolakis #include <queue>
408b42bc56SSotiris Apostolakis #include <stack>
418b42bc56SSotiris Apostolakis #include <string>
42ca7c307dSSotiris Apostolakis
43ca7c307dSSotiris Apostolakis using namespace llvm;
44ca7c307dSSotiris Apostolakis
4597c3ef5cSSotiris Apostolakis #define DEBUG_TYPE "select-optimize"
4697c3ef5cSSotiris Apostolakis
478b42bc56SSotiris Apostolakis STATISTIC(NumSelectOptAnalyzed,
488b42bc56SSotiris Apostolakis "Number of select groups considered for conversion to branch");
498b42bc56SSotiris Apostolakis STATISTIC(NumSelectConvertedExpColdOperand,
508b42bc56SSotiris Apostolakis "Number of select groups converted due to expensive cold operand");
518b42bc56SSotiris Apostolakis STATISTIC(NumSelectConvertedHighPred,
528b42bc56SSotiris Apostolakis "Number of select groups converted due to high-predictability");
538b42bc56SSotiris Apostolakis STATISTIC(NumSelectUnPred,
548b42bc56SSotiris Apostolakis "Number of select groups not converted due to unpredictability");
558b42bc56SSotiris Apostolakis STATISTIC(NumSelectColdBB,
568b42bc56SSotiris Apostolakis "Number of select groups not converted due to cold basic block");
57d7ebb746SSotiris Apostolakis STATISTIC(NumSelectConvertedLoop,
58d7ebb746SSotiris Apostolakis "Number of select groups converted due to loop-level analysis");
5997c3ef5cSSotiris Apostolakis STATISTIC(NumSelectsConverted, "Number of selects converted");
6097c3ef5cSSotiris Apostolakis
618b42bc56SSotiris Apostolakis static cl::opt<unsigned> ColdOperandThreshold(
628b42bc56SSotiris Apostolakis "cold-operand-threshold",
638b42bc56SSotiris Apostolakis cl::desc("Maximum frequency of path for an operand to be considered cold."),
648b42bc56SSotiris Apostolakis cl::init(20), cl::Hidden);
658b42bc56SSotiris Apostolakis
668b42bc56SSotiris Apostolakis static cl::opt<unsigned> ColdOperandMaxCostMultiplier(
678b42bc56SSotiris Apostolakis "cold-operand-max-cost-multiplier",
688b42bc56SSotiris Apostolakis cl::desc("Maximum cost multiplier of TCC_expensive for the dependence "
698b42bc56SSotiris Apostolakis "slice of a cold operand to be considered inexpensive."),
708b42bc56SSotiris Apostolakis cl::init(1), cl::Hidden);
718b42bc56SSotiris Apostolakis
72d7ebb746SSotiris Apostolakis static cl::opt<unsigned>
73d7ebb746SSotiris Apostolakis GainGradientThreshold("select-opti-loop-gradient-gain-threshold",
74d7ebb746SSotiris Apostolakis cl::desc("Gradient gain threshold (%)."),
75d7ebb746SSotiris Apostolakis cl::init(25), cl::Hidden);
76d7ebb746SSotiris Apostolakis
77d7ebb746SSotiris Apostolakis static cl::opt<unsigned>
78d7ebb746SSotiris Apostolakis GainCycleThreshold("select-opti-loop-cycle-gain-threshold",
79d7ebb746SSotiris Apostolakis cl::desc("Minimum gain per loop (in cycles) threshold."),
80d7ebb746SSotiris Apostolakis cl::init(4), cl::Hidden);
81d7ebb746SSotiris Apostolakis
82d7ebb746SSotiris Apostolakis static cl::opt<unsigned> GainRelativeThreshold(
83d7ebb746SSotiris Apostolakis "select-opti-loop-relative-gain-threshold",
84d7ebb746SSotiris Apostolakis cl::desc(
85d7ebb746SSotiris Apostolakis "Minimum relative gain per loop threshold (1/X). Defaults to 12.5%"),
86d7ebb746SSotiris Apostolakis cl::init(8), cl::Hidden);
87d7ebb746SSotiris Apostolakis
88d7ebb746SSotiris Apostolakis static cl::opt<unsigned> MispredictDefaultRate(
89d7ebb746SSotiris Apostolakis "mispredict-default-rate", cl::Hidden, cl::init(25),
90d7ebb746SSotiris Apostolakis cl::desc("Default mispredict rate (initialized to 25%)."));
91d7ebb746SSotiris Apostolakis
92d7ebb746SSotiris Apostolakis static cl::opt<bool>
93d7ebb746SSotiris Apostolakis DisableLoopLevelHeuristics("disable-loop-level-heuristics", cl::Hidden,
94d7ebb746SSotiris Apostolakis cl::init(false),
95d7ebb746SSotiris Apostolakis cl::desc("Disable loop-level heuristics."));
96d7ebb746SSotiris Apostolakis
97ca7c307dSSotiris Apostolakis namespace {
98ca7c307dSSotiris Apostolakis
99ca7c307dSSotiris Apostolakis class SelectOptimize : public FunctionPass {
10097c3ef5cSSotiris Apostolakis const TargetMachine *TM = nullptr;
10197c3ef5cSSotiris Apostolakis const TargetSubtargetInfo *TSI;
10297c3ef5cSSotiris Apostolakis const TargetLowering *TLI = nullptr;
1038b42bc56SSotiris Apostolakis const TargetTransformInfo *TTI = nullptr;
10497c3ef5cSSotiris Apostolakis const LoopInfo *LI;
1058b42bc56SSotiris Apostolakis DominatorTree *DT;
10697c3ef5cSSotiris Apostolakis std::unique_ptr<BlockFrequencyInfo> BFI;
10797c3ef5cSSotiris Apostolakis std::unique_ptr<BranchProbabilityInfo> BPI;
1088b42bc56SSotiris Apostolakis ProfileSummaryInfo *PSI;
1098b42bc56SSotiris Apostolakis OptimizationRemarkEmitter *ORE;
110d7ebb746SSotiris Apostolakis TargetSchedModel TSchedModel;
11197c3ef5cSSotiris Apostolakis
112ca7c307dSSotiris Apostolakis public:
113ca7c307dSSotiris Apostolakis static char ID;
1148b42bc56SSotiris Apostolakis
SelectOptimize()115ca7c307dSSotiris Apostolakis SelectOptimize() : FunctionPass(ID) {
116ca7c307dSSotiris Apostolakis initializeSelectOptimizePass(*PassRegistry::getPassRegistry());
117ca7c307dSSotiris Apostolakis }
118ca7c307dSSotiris Apostolakis
119ca7c307dSSotiris Apostolakis bool runOnFunction(Function &F) override;
120ca7c307dSSotiris Apostolakis
getAnalysisUsage(AnalysisUsage & AU) const12197c3ef5cSSotiris Apostolakis void getAnalysisUsage(AnalysisUsage &AU) const override {
1228b42bc56SSotiris Apostolakis AU.addRequired<ProfileSummaryInfoWrapperPass>();
12397c3ef5cSSotiris Apostolakis AU.addRequired<TargetPassConfig>();
1248b42bc56SSotiris Apostolakis AU.addRequired<TargetTransformInfoWrapperPass>();
1258b42bc56SSotiris Apostolakis AU.addRequired<DominatorTreeWrapperPass>();
12697c3ef5cSSotiris Apostolakis AU.addRequired<LoopInfoWrapperPass>();
1278b42bc56SSotiris Apostolakis AU.addRequired<OptimizationRemarkEmitterWrapperPass>();
12897c3ef5cSSotiris Apostolakis }
12997c3ef5cSSotiris Apostolakis
13097c3ef5cSSotiris Apostolakis private:
13197c3ef5cSSotiris Apostolakis // Select groups consist of consecutive select instructions with the same
13297c3ef5cSSotiris Apostolakis // condition.
13397c3ef5cSSotiris Apostolakis using SelectGroup = SmallVector<SelectInst *, 2>;
13497c3ef5cSSotiris Apostolakis using SelectGroups = SmallVector<SelectGroup, 2>;
13597c3ef5cSSotiris Apostolakis
136d7ebb746SSotiris Apostolakis using Scaled64 = ScaledNumber<uint64_t>;
137d7ebb746SSotiris Apostolakis
138d7ebb746SSotiris Apostolakis struct CostInfo {
139d7ebb746SSotiris Apostolakis /// Predicated cost (with selects as conditional moves).
140d7ebb746SSotiris Apostolakis Scaled64 PredCost;
141d7ebb746SSotiris Apostolakis /// Non-predicated cost (with selects converted to branches).
142d7ebb746SSotiris Apostolakis Scaled64 NonPredCost;
143d7ebb746SSotiris Apostolakis };
144d7ebb746SSotiris Apostolakis
1458b42bc56SSotiris Apostolakis // Converts select instructions of a function to conditional jumps when deemed
1468b42bc56SSotiris Apostolakis // profitable. Returns true if at least one select was converted.
14797c3ef5cSSotiris Apostolakis bool optimizeSelects(Function &F);
1488b42bc56SSotiris Apostolakis
1498b42bc56SSotiris Apostolakis // Heuristics for determining which select instructions can be profitably
1508b42bc56SSotiris Apostolakis // conveted to branches. Separate heuristics for selects in inner-most loops
1518b42bc56SSotiris Apostolakis // and the rest of code regions (base heuristics for non-inner-most loop
1528b42bc56SSotiris Apostolakis // regions).
1538b42bc56SSotiris Apostolakis void optimizeSelectsBase(Function &F, SelectGroups &ProfSIGroups);
1548b42bc56SSotiris Apostolakis void optimizeSelectsInnerLoops(Function &F, SelectGroups &ProfSIGroups);
1558b42bc56SSotiris Apostolakis
1568b42bc56SSotiris Apostolakis // Converts to branches the select groups that were deemed
1578b42bc56SSotiris Apostolakis // profitable-to-convert.
15897c3ef5cSSotiris Apostolakis void convertProfitableSIGroups(SelectGroups &ProfSIGroups);
1598b42bc56SSotiris Apostolakis
1608b42bc56SSotiris Apostolakis // Splits selects of a given basic block into select groups.
16197c3ef5cSSotiris Apostolakis void collectSelectGroups(BasicBlock &BB, SelectGroups &SIGroups);
1628b42bc56SSotiris Apostolakis
1638b42bc56SSotiris Apostolakis // Determines for which select groups it is profitable converting to branches
164d7ebb746SSotiris Apostolakis // (base and inner-most-loop heuristics).
1658b42bc56SSotiris Apostolakis void findProfitableSIGroupsBase(SelectGroups &SIGroups,
1668b42bc56SSotiris Apostolakis SelectGroups &ProfSIGroups);
167d7ebb746SSotiris Apostolakis void findProfitableSIGroupsInnerLoops(const Loop *L, SelectGroups &SIGroups,
168d7ebb746SSotiris Apostolakis SelectGroups &ProfSIGroups);
169d7ebb746SSotiris Apostolakis
1708b42bc56SSotiris Apostolakis // Determines if a select group should be converted to a branch (base
1718b42bc56SSotiris Apostolakis // heuristics).
1728b42bc56SSotiris Apostolakis bool isConvertToBranchProfitableBase(const SmallVector<SelectInst *, 2> &ASI);
1738b42bc56SSotiris Apostolakis
1748b42bc56SSotiris Apostolakis // Returns true if there are expensive instructions in the cold value
1758b42bc56SSotiris Apostolakis // operand's (if any) dependence slice of any of the selects of the given
1768b42bc56SSotiris Apostolakis // group.
1778b42bc56SSotiris Apostolakis bool hasExpensiveColdOperand(const SmallVector<SelectInst *, 2> &ASI);
1788b42bc56SSotiris Apostolakis
1798b42bc56SSotiris Apostolakis // For a given source instruction, collect its backwards dependence slice
1808b42bc56SSotiris Apostolakis // consisting of instructions exclusively computed for producing the operands
1818b42bc56SSotiris Apostolakis // of the source instruction.
18267be40dfSSotiris Apostolakis void getExclBackwardsSlice(Instruction *I, std::stack<Instruction *> &Slice,
18367be40dfSSotiris Apostolakis bool ForSinking = false);
1848b42bc56SSotiris Apostolakis
1858b42bc56SSotiris Apostolakis // Returns true if the condition of the select is highly predictable.
1868b42bc56SSotiris Apostolakis bool isSelectHighlyPredictable(const SelectInst *SI);
1878b42bc56SSotiris Apostolakis
188d7ebb746SSotiris Apostolakis // Loop-level checks to determine if a non-predicated version (with branches)
189d7ebb746SSotiris Apostolakis // of the given loop is more profitable than its predicated version.
190d7ebb746SSotiris Apostolakis bool checkLoopHeuristics(const Loop *L, const CostInfo LoopDepth[2]);
191d7ebb746SSotiris Apostolakis
192d7ebb746SSotiris Apostolakis // Computes instruction and loop-critical-path costs for both the predicated
193d7ebb746SSotiris Apostolakis // and non-predicated version of the given loop.
194d7ebb746SSotiris Apostolakis bool computeLoopCosts(const Loop *L, const SelectGroups &SIGroups,
195d7ebb746SSotiris Apostolakis DenseMap<const Instruction *, CostInfo> &InstCostMap,
196d7ebb746SSotiris Apostolakis CostInfo *LoopCost);
197d7ebb746SSotiris Apostolakis
198d7ebb746SSotiris Apostolakis // Returns a set of all the select instructions in the given select groups.
199d7ebb746SSotiris Apostolakis SmallPtrSet<const Instruction *, 2> getSIset(const SelectGroups &SIGroups);
200d7ebb746SSotiris Apostolakis
201d7ebb746SSotiris Apostolakis // Returns the latency cost of a given instruction.
202d7ebb746SSotiris Apostolakis Optional<uint64_t> computeInstCost(const Instruction *I);
203d7ebb746SSotiris Apostolakis
204d7ebb746SSotiris Apostolakis // Returns the misprediction cost of a given select when converted to branch.
205d7ebb746SSotiris Apostolakis Scaled64 getMispredictionCost(const SelectInst *SI, const Scaled64 CondCost);
206d7ebb746SSotiris Apostolakis
207d7ebb746SSotiris Apostolakis // Returns the cost of a branch when the prediction is correct.
208d7ebb746SSotiris Apostolakis Scaled64 getPredictedPathCost(Scaled64 TrueCost, Scaled64 FalseCost,
209d7ebb746SSotiris Apostolakis const SelectInst *SI);
210d7ebb746SSotiris Apostolakis
2118b42bc56SSotiris Apostolakis // Returns true if the target architecture supports lowering a given select.
21297c3ef5cSSotiris Apostolakis bool isSelectKindSupported(SelectInst *SI);
213ca7c307dSSotiris Apostolakis };
214ca7c307dSSotiris Apostolakis } // namespace
215ca7c307dSSotiris Apostolakis
216ca7c307dSSotiris Apostolakis char SelectOptimize::ID = 0;
21797c3ef5cSSotiris Apostolakis
21897c3ef5cSSotiris Apostolakis INITIALIZE_PASS_BEGIN(SelectOptimize, DEBUG_TYPE, "Optimize selects", false,
21997c3ef5cSSotiris Apostolakis false)
INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass)22097c3ef5cSSotiris Apostolakis INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass)
2218b42bc56SSotiris Apostolakis INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass)
2228b42bc56SSotiris Apostolakis INITIALIZE_PASS_DEPENDENCY(ProfileSummaryInfoWrapperPass)
22397c3ef5cSSotiris Apostolakis INITIALIZE_PASS_DEPENDENCY(TargetPassConfig)
2248b42bc56SSotiris Apostolakis INITIALIZE_PASS_DEPENDENCY(TargetTransformInfoWrapperPass)
2258b42bc56SSotiris Apostolakis INITIALIZE_PASS_DEPENDENCY(OptimizationRemarkEmitterWrapperPass)
22697c3ef5cSSotiris Apostolakis INITIALIZE_PASS_END(SelectOptimize, DEBUG_TYPE, "Optimize selects", false,
227ca7c307dSSotiris Apostolakis false)
228ca7c307dSSotiris Apostolakis
229ca7c307dSSotiris Apostolakis FunctionPass *llvm::createSelectOptimizePass() { return new SelectOptimize(); }
230ca7c307dSSotiris Apostolakis
runOnFunction(Function & F)231ca7c307dSSotiris Apostolakis bool SelectOptimize::runOnFunction(Function &F) {
23297c3ef5cSSotiris Apostolakis TM = &getAnalysis<TargetPassConfig>().getTM<TargetMachine>();
23397c3ef5cSSotiris Apostolakis TSI = TM->getSubtargetImpl(F);
23497c3ef5cSSotiris Apostolakis TLI = TSI->getTargetLowering();
2358b42bc56SSotiris Apostolakis
2368b42bc56SSotiris Apostolakis // If none of the select types is supported then skip this pass.
2378b42bc56SSotiris Apostolakis // This is an optimization pass. Legality issues will be handled by
2388b42bc56SSotiris Apostolakis // instruction selection.
2398b42bc56SSotiris Apostolakis if (!TLI->isSelectSupported(TargetLowering::ScalarValSelect) &&
2408b42bc56SSotiris Apostolakis !TLI->isSelectSupported(TargetLowering::ScalarCondVectorVal) &&
2418b42bc56SSotiris Apostolakis !TLI->isSelectSupported(TargetLowering::VectorMaskSelect))
2428b42bc56SSotiris Apostolakis return false;
2438b42bc56SSotiris Apostolakis
2448b42bc56SSotiris Apostolakis TTI = &getAnalysis<TargetTransformInfoWrapperPass>().getTTI(F);
2458b42bc56SSotiris Apostolakis DT = &getAnalysis<DominatorTreeWrapperPass>().getDomTree();
24697c3ef5cSSotiris Apostolakis LI = &getAnalysis<LoopInfoWrapperPass>().getLoopInfo();
24797c3ef5cSSotiris Apostolakis BPI.reset(new BranchProbabilityInfo(F, *LI));
24897c3ef5cSSotiris Apostolakis BFI.reset(new BlockFrequencyInfo(F, *BPI, *LI));
2498b42bc56SSotiris Apostolakis PSI = &getAnalysis<ProfileSummaryInfoWrapperPass>().getPSI();
2508b42bc56SSotiris Apostolakis ORE = &getAnalysis<OptimizationRemarkEmitterWrapperPass>().getORE();
251d7ebb746SSotiris Apostolakis TSchedModel.init(TSI);
2528b42bc56SSotiris Apostolakis
2538b42bc56SSotiris Apostolakis // When optimizing for size, selects are preferable over branches.
2548b42bc56SSotiris Apostolakis if (F.hasOptSize() || llvm::shouldOptimizeForSize(&F, PSI, BFI.get()))
2558b42bc56SSotiris Apostolakis return false;
25697c3ef5cSSotiris Apostolakis
25797c3ef5cSSotiris Apostolakis return optimizeSelects(F);
25897c3ef5cSSotiris Apostolakis }
25997c3ef5cSSotiris Apostolakis
optimizeSelects(Function & F)26097c3ef5cSSotiris Apostolakis bool SelectOptimize::optimizeSelects(Function &F) {
26197c3ef5cSSotiris Apostolakis // Determine for which select groups it is profitable converting to branches.
26297c3ef5cSSotiris Apostolakis SelectGroups ProfSIGroups;
2638b42bc56SSotiris Apostolakis // Base heuristics apply only to non-loops and outer loops.
2648b42bc56SSotiris Apostolakis optimizeSelectsBase(F, ProfSIGroups);
2658b42bc56SSotiris Apostolakis // Separate heuristics for inner-most loops.
2668b42bc56SSotiris Apostolakis optimizeSelectsInnerLoops(F, ProfSIGroups);
26797c3ef5cSSotiris Apostolakis
26897c3ef5cSSotiris Apostolakis // Convert to branches the select groups that were deemed
26997c3ef5cSSotiris Apostolakis // profitable-to-convert.
27097c3ef5cSSotiris Apostolakis convertProfitableSIGroups(ProfSIGroups);
27197c3ef5cSSotiris Apostolakis
27297c3ef5cSSotiris Apostolakis // Code modified if at least one select group was converted.
27397c3ef5cSSotiris Apostolakis return !ProfSIGroups.empty();
27497c3ef5cSSotiris Apostolakis }
27597c3ef5cSSotiris Apostolakis
optimizeSelectsBase(Function & F,SelectGroups & ProfSIGroups)2768b42bc56SSotiris Apostolakis void SelectOptimize::optimizeSelectsBase(Function &F,
2778b42bc56SSotiris Apostolakis SelectGroups &ProfSIGroups) {
2788b42bc56SSotiris Apostolakis // Collect all the select groups.
2798b42bc56SSotiris Apostolakis SelectGroups SIGroups;
2808b42bc56SSotiris Apostolakis for (BasicBlock &BB : F) {
2818b42bc56SSotiris Apostolakis // Base heuristics apply only to non-loops and outer loops.
2828b42bc56SSotiris Apostolakis Loop *L = LI->getLoopFor(&BB);
2838b42bc56SSotiris Apostolakis if (L && L->isInnermost())
2848b42bc56SSotiris Apostolakis continue;
2858b42bc56SSotiris Apostolakis collectSelectGroups(BB, SIGroups);
2868b42bc56SSotiris Apostolakis }
2878b42bc56SSotiris Apostolakis
2888b42bc56SSotiris Apostolakis // Determine for which select groups it is profitable converting to branches.
2898b42bc56SSotiris Apostolakis findProfitableSIGroupsBase(SIGroups, ProfSIGroups);
2908b42bc56SSotiris Apostolakis }
2918b42bc56SSotiris Apostolakis
optimizeSelectsInnerLoops(Function & F,SelectGroups & ProfSIGroups)2928b42bc56SSotiris Apostolakis void SelectOptimize::optimizeSelectsInnerLoops(Function &F,
293d7ebb746SSotiris Apostolakis SelectGroups &ProfSIGroups) {
294d7ebb746SSotiris Apostolakis SmallVector<Loop *, 4> Loops(LI->begin(), LI->end());
295d7ebb746SSotiris Apostolakis // Need to check size on each iteration as we accumulate child loops.
296d7ebb746SSotiris Apostolakis for (unsigned long i = 0; i < Loops.size(); ++i)
297d7ebb746SSotiris Apostolakis for (Loop *ChildL : Loops[i]->getSubLoops())
298d7ebb746SSotiris Apostolakis Loops.push_back(ChildL);
299d7ebb746SSotiris Apostolakis
300d7ebb746SSotiris Apostolakis for (Loop *L : Loops) {
301d7ebb746SSotiris Apostolakis if (!L->isInnermost())
302d7ebb746SSotiris Apostolakis continue;
303d7ebb746SSotiris Apostolakis
304d7ebb746SSotiris Apostolakis SelectGroups SIGroups;
305d7ebb746SSotiris Apostolakis for (BasicBlock *BB : L->getBlocks())
306d7ebb746SSotiris Apostolakis collectSelectGroups(*BB, SIGroups);
307d7ebb746SSotiris Apostolakis
308d7ebb746SSotiris Apostolakis findProfitableSIGroupsInnerLoops(L, SIGroups, ProfSIGroups);
309d7ebb746SSotiris Apostolakis }
310d7ebb746SSotiris Apostolakis }
3118b42bc56SSotiris Apostolakis
31297c3ef5cSSotiris Apostolakis /// If \p isTrue is true, return the true value of \p SI, otherwise return
31397c3ef5cSSotiris Apostolakis /// false value of \p SI. If the true/false value of \p SI is defined by any
31497c3ef5cSSotiris Apostolakis /// select instructions in \p Selects, look through the defining select
31597c3ef5cSSotiris Apostolakis /// instruction until the true/false value is not defined in \p Selects.
31697c3ef5cSSotiris Apostolakis static Value *
getTrueOrFalseValue(SelectInst * SI,bool isTrue,const SmallPtrSet<const Instruction *,2> & Selects)31797c3ef5cSSotiris Apostolakis getTrueOrFalseValue(SelectInst *SI, bool isTrue,
31897c3ef5cSSotiris Apostolakis const SmallPtrSet<const Instruction *, 2> &Selects) {
31997c3ef5cSSotiris Apostolakis Value *V = nullptr;
32097c3ef5cSSotiris Apostolakis for (SelectInst *DefSI = SI; DefSI != nullptr && Selects.count(DefSI);
32197c3ef5cSSotiris Apostolakis DefSI = dyn_cast<SelectInst>(V)) {
32297c3ef5cSSotiris Apostolakis assert(DefSI->getCondition() == SI->getCondition() &&
32397c3ef5cSSotiris Apostolakis "The condition of DefSI does not match with SI");
32497c3ef5cSSotiris Apostolakis V = (isTrue ? DefSI->getTrueValue() : DefSI->getFalseValue());
32597c3ef5cSSotiris Apostolakis }
32697c3ef5cSSotiris Apostolakis assert(V && "Failed to get select true/false value");
32797c3ef5cSSotiris Apostolakis return V;
32897c3ef5cSSotiris Apostolakis }
32997c3ef5cSSotiris Apostolakis
convertProfitableSIGroups(SelectGroups & ProfSIGroups)33097c3ef5cSSotiris Apostolakis void SelectOptimize::convertProfitableSIGroups(SelectGroups &ProfSIGroups) {
33197c3ef5cSSotiris Apostolakis for (SelectGroup &ASI : ProfSIGroups) {
33267be40dfSSotiris Apostolakis // The code transformation here is a modified version of the sinking
33367be40dfSSotiris Apostolakis // transformation in CodeGenPrepare::optimizeSelectInst with a more
33467be40dfSSotiris Apostolakis // aggressive strategy of which instructions to sink.
33567be40dfSSotiris Apostolakis //
33697c3ef5cSSotiris Apostolakis // TODO: eliminate the redundancy of logic transforming selects to branches
33797c3ef5cSSotiris Apostolakis // by removing CodeGenPrepare::optimizeSelectInst and optimizing here
33897c3ef5cSSotiris Apostolakis // selects for all cases (with and without profile information).
33997c3ef5cSSotiris Apostolakis
34097c3ef5cSSotiris Apostolakis // Transform a sequence like this:
34197c3ef5cSSotiris Apostolakis // start:
34297c3ef5cSSotiris Apostolakis // %cmp = cmp uge i32 %a, %b
34397c3ef5cSSotiris Apostolakis // %sel = select i1 %cmp, i32 %c, i32 %d
34497c3ef5cSSotiris Apostolakis //
34597c3ef5cSSotiris Apostolakis // Into:
34697c3ef5cSSotiris Apostolakis // start:
34797c3ef5cSSotiris Apostolakis // %cmp = cmp uge i32 %a, %b
34897c3ef5cSSotiris Apostolakis // %cmp.frozen = freeze %cmp
34967be40dfSSotiris Apostolakis // br i1 %cmp.frozen, label %select.true, label %select.false
35067be40dfSSotiris Apostolakis // select.true:
35167be40dfSSotiris Apostolakis // br label %select.end
35297c3ef5cSSotiris Apostolakis // select.false:
35397c3ef5cSSotiris Apostolakis // br label %select.end
35497c3ef5cSSotiris Apostolakis // select.end:
35567be40dfSSotiris Apostolakis // %sel = phi i32 [ %c, %select.true ], [ %d, %select.false ]
35697c3ef5cSSotiris Apostolakis //
35797c3ef5cSSotiris Apostolakis // %cmp should be frozen, otherwise it may introduce undefined behavior.
35867be40dfSSotiris Apostolakis // In addition, we may sink instructions that produce %c or %d into the
35967be40dfSSotiris Apostolakis // destination(s) of the new branch.
36067be40dfSSotiris Apostolakis // If the true or false blocks do not contain a sunken instruction, that
36167be40dfSSotiris Apostolakis // block and its branch may be optimized away. In that case, one side of the
36267be40dfSSotiris Apostolakis // first branch will point directly to select.end, and the corresponding PHI
36367be40dfSSotiris Apostolakis // predecessor block will be the start block.
36467be40dfSSotiris Apostolakis
36567be40dfSSotiris Apostolakis // Find all the instructions that can be soundly sunk to the true/false
36667be40dfSSotiris Apostolakis // blocks. These are instructions that are computed solely for producing the
36767be40dfSSotiris Apostolakis // operands of the select instructions in the group and can be sunk without
36867be40dfSSotiris Apostolakis // breaking the semantics of the LLVM IR (e.g., cannot sink instructions
36967be40dfSSotiris Apostolakis // with side effects).
37067be40dfSSotiris Apostolakis SmallVector<std::stack<Instruction *>, 2> TrueSlices, FalseSlices;
37167be40dfSSotiris Apostolakis typedef std::stack<Instruction *>::size_type StackSizeType;
37267be40dfSSotiris Apostolakis StackSizeType maxTrueSliceLen = 0, maxFalseSliceLen = 0;
37367be40dfSSotiris Apostolakis for (SelectInst *SI : ASI) {
37467be40dfSSotiris Apostolakis // For each select, compute the sinkable dependence chains of the true and
37567be40dfSSotiris Apostolakis // false operands.
37667be40dfSSotiris Apostolakis if (auto *TI = dyn_cast<Instruction>(SI->getTrueValue())) {
37767be40dfSSotiris Apostolakis std::stack<Instruction *> TrueSlice;
37867be40dfSSotiris Apostolakis getExclBackwardsSlice(TI, TrueSlice, true);
37967be40dfSSotiris Apostolakis maxTrueSliceLen = std::max(maxTrueSliceLen, TrueSlice.size());
38067be40dfSSotiris Apostolakis TrueSlices.push_back(TrueSlice);
38167be40dfSSotiris Apostolakis }
38267be40dfSSotiris Apostolakis if (auto *FI = dyn_cast<Instruction>(SI->getFalseValue())) {
38367be40dfSSotiris Apostolakis std::stack<Instruction *> FalseSlice;
38467be40dfSSotiris Apostolakis getExclBackwardsSlice(FI, FalseSlice, true);
38567be40dfSSotiris Apostolakis maxFalseSliceLen = std::max(maxFalseSliceLen, FalseSlice.size());
38667be40dfSSotiris Apostolakis FalseSlices.push_back(FalseSlice);
38767be40dfSSotiris Apostolakis }
38867be40dfSSotiris Apostolakis }
38967be40dfSSotiris Apostolakis // In the case of multiple select instructions in the same group, the order
39067be40dfSSotiris Apostolakis // of non-dependent instructions (instructions of different dependence
39167be40dfSSotiris Apostolakis // slices) in the true/false blocks appears to affect performance.
39267be40dfSSotiris Apostolakis // Interleaving the slices seems to experimentally be the optimal approach.
39367be40dfSSotiris Apostolakis // This interleaving scheduling allows for more ILP (with a natural downside
39467be40dfSSotiris Apostolakis // of increasing a bit register pressure) compared to a simple ordering of
39567be40dfSSotiris Apostolakis // one whole chain after another. One would expect that this ordering would
39667be40dfSSotiris Apostolakis // not matter since the scheduling in the backend of the compiler would
39767be40dfSSotiris Apostolakis // take care of it, but apparently the scheduler fails to deliver optimal
39867be40dfSSotiris Apostolakis // ILP with a naive ordering here.
39967be40dfSSotiris Apostolakis SmallVector<Instruction *, 2> TrueSlicesInterleaved, FalseSlicesInterleaved;
40067be40dfSSotiris Apostolakis for (StackSizeType IS = 0; IS < maxTrueSliceLen; ++IS) {
40167be40dfSSotiris Apostolakis for (auto &S : TrueSlices) {
40267be40dfSSotiris Apostolakis if (!S.empty()) {
40367be40dfSSotiris Apostolakis TrueSlicesInterleaved.push_back(S.top());
40467be40dfSSotiris Apostolakis S.pop();
40567be40dfSSotiris Apostolakis }
40667be40dfSSotiris Apostolakis }
40767be40dfSSotiris Apostolakis }
40867be40dfSSotiris Apostolakis for (StackSizeType IS = 0; IS < maxFalseSliceLen; ++IS) {
40967be40dfSSotiris Apostolakis for (auto &S : FalseSlices) {
41067be40dfSSotiris Apostolakis if (!S.empty()) {
41167be40dfSSotiris Apostolakis FalseSlicesInterleaved.push_back(S.top());
41267be40dfSSotiris Apostolakis S.pop();
41367be40dfSSotiris Apostolakis }
41467be40dfSSotiris Apostolakis }
41567be40dfSSotiris Apostolakis }
41697c3ef5cSSotiris Apostolakis
41797c3ef5cSSotiris Apostolakis // We split the block containing the select(s) into two blocks.
41897c3ef5cSSotiris Apostolakis SelectInst *SI = ASI.front();
41997c3ef5cSSotiris Apostolakis SelectInst *LastSI = ASI.back();
42097c3ef5cSSotiris Apostolakis BasicBlock *StartBlock = SI->getParent();
42197c3ef5cSSotiris Apostolakis BasicBlock::iterator SplitPt = ++(BasicBlock::iterator(LastSI));
42297c3ef5cSSotiris Apostolakis BasicBlock *EndBlock = StartBlock->splitBasicBlock(SplitPt, "select.end");
42397c3ef5cSSotiris Apostolakis BFI->setBlockFreq(EndBlock, BFI->getBlockFreq(StartBlock).getFrequency());
42497c3ef5cSSotiris Apostolakis // Delete the unconditional branch that was just created by the split.
42597c3ef5cSSotiris Apostolakis StartBlock->getTerminator()->eraseFromParent();
42697c3ef5cSSotiris Apostolakis
42797c3ef5cSSotiris Apostolakis // Move any debug/pseudo instructions that were in-between the select
42897c3ef5cSSotiris Apostolakis // group to the newly-created end block.
42997c3ef5cSSotiris Apostolakis SmallVector<Instruction *, 2> DebugPseudoINS;
43097c3ef5cSSotiris Apostolakis auto DIt = SI->getIterator();
43197c3ef5cSSotiris Apostolakis while (&*DIt != LastSI) {
43297c3ef5cSSotiris Apostolakis if (DIt->isDebugOrPseudoInst())
43397c3ef5cSSotiris Apostolakis DebugPseudoINS.push_back(&*DIt);
43497c3ef5cSSotiris Apostolakis DIt++;
43597c3ef5cSSotiris Apostolakis }
436*9e6d1f4bSKazu Hirata for (auto *DI : DebugPseudoINS) {
43797c3ef5cSSotiris Apostolakis DI->moveBefore(&*EndBlock->getFirstInsertionPt());
43897c3ef5cSSotiris Apostolakis }
43997c3ef5cSSotiris Apostolakis
44097c3ef5cSSotiris Apostolakis // These are the new basic blocks for the conditional branch.
44167be40dfSSotiris Apostolakis // At least one will become an actual new basic block.
44297c3ef5cSSotiris Apostolakis BasicBlock *TrueBlock = nullptr, *FalseBlock = nullptr;
44367be40dfSSotiris Apostolakis BranchInst *TrueBranch = nullptr, *FalseBranch = nullptr;
44467be40dfSSotiris Apostolakis if (!TrueSlicesInterleaved.empty()) {
44567be40dfSSotiris Apostolakis TrueBlock = BasicBlock::Create(LastSI->getContext(), "select.true.sink",
44667be40dfSSotiris Apostolakis EndBlock->getParent(), EndBlock);
44767be40dfSSotiris Apostolakis TrueBranch = BranchInst::Create(EndBlock, TrueBlock);
44867be40dfSSotiris Apostolakis TrueBranch->setDebugLoc(LastSI->getDebugLoc());
44967be40dfSSotiris Apostolakis for (Instruction *TrueInst : TrueSlicesInterleaved)
45067be40dfSSotiris Apostolakis TrueInst->moveBefore(TrueBranch);
45167be40dfSSotiris Apostolakis }
45267be40dfSSotiris Apostolakis if (!FalseSlicesInterleaved.empty()) {
45367be40dfSSotiris Apostolakis FalseBlock = BasicBlock::Create(LastSI->getContext(), "select.false.sink",
45467be40dfSSotiris Apostolakis EndBlock->getParent(), EndBlock);
45567be40dfSSotiris Apostolakis FalseBranch = BranchInst::Create(EndBlock, FalseBlock);
45667be40dfSSotiris Apostolakis FalseBranch->setDebugLoc(LastSI->getDebugLoc());
45767be40dfSSotiris Apostolakis for (Instruction *FalseInst : FalseSlicesInterleaved)
45867be40dfSSotiris Apostolakis FalseInst->moveBefore(FalseBranch);
45967be40dfSSotiris Apostolakis }
46067be40dfSSotiris Apostolakis // If there was nothing to sink, then arbitrarily choose the 'false' side
46167be40dfSSotiris Apostolakis // for a new input value to the PHI.
46267be40dfSSotiris Apostolakis if (TrueBlock == FalseBlock) {
46367be40dfSSotiris Apostolakis assert(TrueBlock == nullptr &&
46467be40dfSSotiris Apostolakis "Unexpected basic block transform while optimizing select");
46597c3ef5cSSotiris Apostolakis
46697c3ef5cSSotiris Apostolakis FalseBlock = BasicBlock::Create(SI->getContext(), "select.false",
46797c3ef5cSSotiris Apostolakis EndBlock->getParent(), EndBlock);
46897c3ef5cSSotiris Apostolakis auto *FalseBranch = BranchInst::Create(EndBlock, FalseBlock);
46997c3ef5cSSotiris Apostolakis FalseBranch->setDebugLoc(SI->getDebugLoc());
47067be40dfSSotiris Apostolakis }
47197c3ef5cSSotiris Apostolakis
47297c3ef5cSSotiris Apostolakis // Insert the real conditional branch based on the original condition.
47367be40dfSSotiris Apostolakis // If we did not create a new block for one of the 'true' or 'false' paths
47467be40dfSSotiris Apostolakis // of the condition, it means that side of the branch goes to the end block
47567be40dfSSotiris Apostolakis // directly and the path originates from the start block from the point of
47667be40dfSSotiris Apostolakis // view of the new PHI.
47797c3ef5cSSotiris Apostolakis BasicBlock *TT, *FT;
47867be40dfSSotiris Apostolakis if (TrueBlock == nullptr) {
47997c3ef5cSSotiris Apostolakis TT = EndBlock;
48097c3ef5cSSotiris Apostolakis FT = FalseBlock;
48167be40dfSSotiris Apostolakis TrueBlock = StartBlock;
48267be40dfSSotiris Apostolakis } else if (FalseBlock == nullptr) {
48367be40dfSSotiris Apostolakis TT = TrueBlock;
48467be40dfSSotiris Apostolakis FT = EndBlock;
48567be40dfSSotiris Apostolakis FalseBlock = StartBlock;
48667be40dfSSotiris Apostolakis } else {
48767be40dfSSotiris Apostolakis TT = TrueBlock;
48867be40dfSSotiris Apostolakis FT = FalseBlock;
48967be40dfSSotiris Apostolakis }
49097c3ef5cSSotiris Apostolakis IRBuilder<> IB(SI);
49197c3ef5cSSotiris Apostolakis auto *CondFr =
49297c3ef5cSSotiris Apostolakis IB.CreateFreeze(SI->getCondition(), SI->getName() + ".frozen");
49397c3ef5cSSotiris Apostolakis IB.CreateCondBr(CondFr, TT, FT, SI);
49497c3ef5cSSotiris Apostolakis
49597c3ef5cSSotiris Apostolakis SmallPtrSet<const Instruction *, 2> INS;
49697c3ef5cSSotiris Apostolakis INS.insert(ASI.begin(), ASI.end());
49797c3ef5cSSotiris Apostolakis // Use reverse iterator because later select may use the value of the
49897c3ef5cSSotiris Apostolakis // earlier select, and we need to propagate value through earlier select
49997c3ef5cSSotiris Apostolakis // to get the PHI operand.
50097c3ef5cSSotiris Apostolakis for (auto It = ASI.rbegin(); It != ASI.rend(); ++It) {
50197c3ef5cSSotiris Apostolakis SelectInst *SI = *It;
50297c3ef5cSSotiris Apostolakis // The select itself is replaced with a PHI Node.
50397c3ef5cSSotiris Apostolakis PHINode *PN = PHINode::Create(SI->getType(), 2, "", &EndBlock->front());
50497c3ef5cSSotiris Apostolakis PN->takeName(SI);
50597c3ef5cSSotiris Apostolakis PN->addIncoming(getTrueOrFalseValue(SI, true, INS), TrueBlock);
50697c3ef5cSSotiris Apostolakis PN->addIncoming(getTrueOrFalseValue(SI, false, INS), FalseBlock);
50797c3ef5cSSotiris Apostolakis PN->setDebugLoc(SI->getDebugLoc());
50897c3ef5cSSotiris Apostolakis
50997c3ef5cSSotiris Apostolakis SI->replaceAllUsesWith(PN);
51097c3ef5cSSotiris Apostolakis SI->eraseFromParent();
51197c3ef5cSSotiris Apostolakis INS.erase(SI);
51297c3ef5cSSotiris Apostolakis ++NumSelectsConverted;
51397c3ef5cSSotiris Apostolakis }
51497c3ef5cSSotiris Apostolakis }
51597c3ef5cSSotiris Apostolakis }
51697c3ef5cSSotiris Apostolakis
collectSelectGroups(BasicBlock & BB,SelectGroups & SIGroups)51797c3ef5cSSotiris Apostolakis void SelectOptimize::collectSelectGroups(BasicBlock &BB,
51897c3ef5cSSotiris Apostolakis SelectGroups &SIGroups) {
51997c3ef5cSSotiris Apostolakis BasicBlock::iterator BBIt = BB.begin();
52097c3ef5cSSotiris Apostolakis while (BBIt != BB.end()) {
52197c3ef5cSSotiris Apostolakis Instruction *I = &*BBIt++;
52297c3ef5cSSotiris Apostolakis if (SelectInst *SI = dyn_cast<SelectInst>(I)) {
52397c3ef5cSSotiris Apostolakis SelectGroup SIGroup;
52497c3ef5cSSotiris Apostolakis SIGroup.push_back(SI);
52597c3ef5cSSotiris Apostolakis while (BBIt != BB.end()) {
52697c3ef5cSSotiris Apostolakis Instruction *NI = &*BBIt;
52797c3ef5cSSotiris Apostolakis SelectInst *NSI = dyn_cast<SelectInst>(NI);
52897c3ef5cSSotiris Apostolakis if (NSI && SI->getCondition() == NSI->getCondition()) {
52997c3ef5cSSotiris Apostolakis SIGroup.push_back(NSI);
53097c3ef5cSSotiris Apostolakis } else if (!NI->isDebugOrPseudoInst()) {
53197c3ef5cSSotiris Apostolakis // Debug/pseudo instructions should be skipped and not prevent the
53297c3ef5cSSotiris Apostolakis // formation of a select group.
53397c3ef5cSSotiris Apostolakis break;
53497c3ef5cSSotiris Apostolakis }
53597c3ef5cSSotiris Apostolakis ++BBIt;
53697c3ef5cSSotiris Apostolakis }
53797c3ef5cSSotiris Apostolakis
53897c3ef5cSSotiris Apostolakis // If the select type is not supported, no point optimizing it.
53997c3ef5cSSotiris Apostolakis // Instruction selection will take care of it.
54097c3ef5cSSotiris Apostolakis if (!isSelectKindSupported(SI))
54197c3ef5cSSotiris Apostolakis continue;
54297c3ef5cSSotiris Apostolakis
54397c3ef5cSSotiris Apostolakis SIGroups.push_back(SIGroup);
54497c3ef5cSSotiris Apostolakis }
54597c3ef5cSSotiris Apostolakis }
54697c3ef5cSSotiris Apostolakis }
54797c3ef5cSSotiris Apostolakis
findProfitableSIGroupsBase(SelectGroups & SIGroups,SelectGroups & ProfSIGroups)5488b42bc56SSotiris Apostolakis void SelectOptimize::findProfitableSIGroupsBase(SelectGroups &SIGroups,
5498b42bc56SSotiris Apostolakis SelectGroups &ProfSIGroups) {
5508b42bc56SSotiris Apostolakis for (SelectGroup &ASI : SIGroups) {
5518b42bc56SSotiris Apostolakis ++NumSelectOptAnalyzed;
5528b42bc56SSotiris Apostolakis if (isConvertToBranchProfitableBase(ASI))
5538b42bc56SSotiris Apostolakis ProfSIGroups.push_back(ASI);
5548b42bc56SSotiris Apostolakis }
5558b42bc56SSotiris Apostolakis }
5568b42bc56SSotiris Apostolakis
findProfitableSIGroupsInnerLoops(const Loop * L,SelectGroups & SIGroups,SelectGroups & ProfSIGroups)557d7ebb746SSotiris Apostolakis void SelectOptimize::findProfitableSIGroupsInnerLoops(
558d7ebb746SSotiris Apostolakis const Loop *L, SelectGroups &SIGroups, SelectGroups &ProfSIGroups) {
559d7ebb746SSotiris Apostolakis NumSelectOptAnalyzed += SIGroups.size();
560d7ebb746SSotiris Apostolakis // For each select group in an inner-most loop,
561d7ebb746SSotiris Apostolakis // a branch is more preferable than a select/conditional-move if:
562d7ebb746SSotiris Apostolakis // i) conversion to branches for all the select groups of the loop satisfies
563d7ebb746SSotiris Apostolakis // loop-level heuristics including reducing the loop's critical path by
564d7ebb746SSotiris Apostolakis // some threshold (see SelectOptimize::checkLoopHeuristics); and
565d7ebb746SSotiris Apostolakis // ii) the total cost of the select group is cheaper with a branch compared
566d7ebb746SSotiris Apostolakis // to its predicated version. The cost is in terms of latency and the cost
567d7ebb746SSotiris Apostolakis // of a select group is the cost of its most expensive select instruction
568d7ebb746SSotiris Apostolakis // (assuming infinite resources and thus fully leveraging available ILP).
569d7ebb746SSotiris Apostolakis
570d7ebb746SSotiris Apostolakis DenseMap<const Instruction *, CostInfo> InstCostMap;
571d7ebb746SSotiris Apostolakis CostInfo LoopCost[2] = {{Scaled64::getZero(), Scaled64::getZero()},
572d7ebb746SSotiris Apostolakis {Scaled64::getZero(), Scaled64::getZero()}};
573d7ebb746SSotiris Apostolakis if (!computeLoopCosts(L, SIGroups, InstCostMap, LoopCost) ||
574d7ebb746SSotiris Apostolakis !checkLoopHeuristics(L, LoopCost)) {
575d7ebb746SSotiris Apostolakis return;
576d7ebb746SSotiris Apostolakis }
577d7ebb746SSotiris Apostolakis
578d7ebb746SSotiris Apostolakis for (SelectGroup &ASI : SIGroups) {
579d7ebb746SSotiris Apostolakis // Assuming infinite resources, the cost of a group of instructions is the
580d7ebb746SSotiris Apostolakis // cost of the most expensive instruction of the group.
581d7ebb746SSotiris Apostolakis Scaled64 SelectCost = Scaled64::getZero(), BranchCost = Scaled64::getZero();
582d7ebb746SSotiris Apostolakis for (SelectInst *SI : ASI) {
583d7ebb746SSotiris Apostolakis SelectCost = std::max(SelectCost, InstCostMap[SI].PredCost);
584d7ebb746SSotiris Apostolakis BranchCost = std::max(BranchCost, InstCostMap[SI].NonPredCost);
585d7ebb746SSotiris Apostolakis }
586d7ebb746SSotiris Apostolakis if (BranchCost < SelectCost) {
587d7ebb746SSotiris Apostolakis OptimizationRemark OR(DEBUG_TYPE, "SelectOpti", ASI.front());
588d7ebb746SSotiris Apostolakis OR << "Profitable to convert to branch (loop analysis). BranchCost="
589d7ebb746SSotiris Apostolakis << BranchCost.toString() << ", SelectCost=" << SelectCost.toString()
590d7ebb746SSotiris Apostolakis << ". ";
591d7ebb746SSotiris Apostolakis ORE->emit(OR);
592d7ebb746SSotiris Apostolakis ++NumSelectConvertedLoop;
593d7ebb746SSotiris Apostolakis ProfSIGroups.push_back(ASI);
594d7ebb746SSotiris Apostolakis } else {
595d7ebb746SSotiris Apostolakis OptimizationRemarkMissed ORmiss(DEBUG_TYPE, "SelectOpti", ASI.front());
596d7ebb746SSotiris Apostolakis ORmiss << "Select is more profitable (loop analysis). BranchCost="
597d7ebb746SSotiris Apostolakis << BranchCost.toString()
598d7ebb746SSotiris Apostolakis << ", SelectCost=" << SelectCost.toString() << ". ";
599d7ebb746SSotiris Apostolakis ORE->emit(ORmiss);
600d7ebb746SSotiris Apostolakis }
601d7ebb746SSotiris Apostolakis }
602d7ebb746SSotiris Apostolakis }
603d7ebb746SSotiris Apostolakis
isConvertToBranchProfitableBase(const SmallVector<SelectInst *,2> & ASI)6048b42bc56SSotiris Apostolakis bool SelectOptimize::isConvertToBranchProfitableBase(
6058b42bc56SSotiris Apostolakis const SmallVector<SelectInst *, 2> &ASI) {
6068b42bc56SSotiris Apostolakis SelectInst *SI = ASI.front();
6078b42bc56SSotiris Apostolakis OptimizationRemark OR(DEBUG_TYPE, "SelectOpti", SI);
6088b42bc56SSotiris Apostolakis OptimizationRemarkMissed ORmiss(DEBUG_TYPE, "SelectOpti", SI);
6098b42bc56SSotiris Apostolakis
6108b42bc56SSotiris Apostolakis // Skip cold basic blocks. Better to optimize for size for cold blocks.
6118b42bc56SSotiris Apostolakis if (PSI->isColdBlock(SI->getParent(), BFI.get())) {
6128b42bc56SSotiris Apostolakis ++NumSelectColdBB;
6138b42bc56SSotiris Apostolakis ORmiss << "Not converted to branch because of cold basic block. ";
6148b42bc56SSotiris Apostolakis ORE->emit(ORmiss);
6158b42bc56SSotiris Apostolakis return false;
6168b42bc56SSotiris Apostolakis }
6178b42bc56SSotiris Apostolakis
6188b42bc56SSotiris Apostolakis // If unpredictable, branch form is less profitable.
6198b42bc56SSotiris Apostolakis if (SI->getMetadata(LLVMContext::MD_unpredictable)) {
6208b42bc56SSotiris Apostolakis ++NumSelectUnPred;
6218b42bc56SSotiris Apostolakis ORmiss << "Not converted to branch because of unpredictable branch. ";
6228b42bc56SSotiris Apostolakis ORE->emit(ORmiss);
6238b42bc56SSotiris Apostolakis return false;
6248b42bc56SSotiris Apostolakis }
6258b42bc56SSotiris Apostolakis
6268b42bc56SSotiris Apostolakis // If highly predictable, branch form is more profitable, unless a
6278b42bc56SSotiris Apostolakis // predictable select is inexpensive in the target architecture.
6288b42bc56SSotiris Apostolakis if (isSelectHighlyPredictable(SI) && TLI->isPredictableSelectExpensive()) {
6298b42bc56SSotiris Apostolakis ++NumSelectConvertedHighPred;
6308b42bc56SSotiris Apostolakis OR << "Converted to branch because of highly predictable branch. ";
6318b42bc56SSotiris Apostolakis ORE->emit(OR);
6328b42bc56SSotiris Apostolakis return true;
6338b42bc56SSotiris Apostolakis }
6348b42bc56SSotiris Apostolakis
6358b42bc56SSotiris Apostolakis // Look for expensive instructions in the cold operand's (if any) dependence
6368b42bc56SSotiris Apostolakis // slice of any of the selects in the group.
6378b42bc56SSotiris Apostolakis if (hasExpensiveColdOperand(ASI)) {
6388b42bc56SSotiris Apostolakis ++NumSelectConvertedExpColdOperand;
6398b42bc56SSotiris Apostolakis OR << "Converted to branch because of expensive cold operand.";
6408b42bc56SSotiris Apostolakis ORE->emit(OR);
6418b42bc56SSotiris Apostolakis return true;
6428b42bc56SSotiris Apostolakis }
6438b42bc56SSotiris Apostolakis
6448b42bc56SSotiris Apostolakis ORmiss << "Not profitable to convert to branch (base heuristic).";
6458b42bc56SSotiris Apostolakis ORE->emit(ORmiss);
6468b42bc56SSotiris Apostolakis return false;
6478b42bc56SSotiris Apostolakis }
6488b42bc56SSotiris Apostolakis
divideNearest(InstructionCost Numerator,uint64_t Denominator)6498b42bc56SSotiris Apostolakis static InstructionCost divideNearest(InstructionCost Numerator,
6508b42bc56SSotiris Apostolakis uint64_t Denominator) {
6518b42bc56SSotiris Apostolakis return (Numerator + (Denominator / 2)) / Denominator;
6528b42bc56SSotiris Apostolakis }
6538b42bc56SSotiris Apostolakis
hasExpensiveColdOperand(const SmallVector<SelectInst *,2> & ASI)6548b42bc56SSotiris Apostolakis bool SelectOptimize::hasExpensiveColdOperand(
6558b42bc56SSotiris Apostolakis const SmallVector<SelectInst *, 2> &ASI) {
6568b42bc56SSotiris Apostolakis bool ColdOperand = false;
6578b42bc56SSotiris Apostolakis uint64_t TrueWeight, FalseWeight, TotalWeight;
6588b42bc56SSotiris Apostolakis if (ASI.front()->extractProfMetadata(TrueWeight, FalseWeight)) {
6598b42bc56SSotiris Apostolakis uint64_t MinWeight = std::min(TrueWeight, FalseWeight);
6608b42bc56SSotiris Apostolakis TotalWeight = TrueWeight + FalseWeight;
6618b42bc56SSotiris Apostolakis // Is there a path with frequency <ColdOperandThreshold% (default:20%) ?
6628b42bc56SSotiris Apostolakis ColdOperand = TotalWeight * ColdOperandThreshold > 100 * MinWeight;
6638b42bc56SSotiris Apostolakis } else if (PSI->hasProfileSummary()) {
6648b42bc56SSotiris Apostolakis OptimizationRemarkMissed ORmiss(DEBUG_TYPE, "SelectOpti", ASI.front());
6658b42bc56SSotiris Apostolakis ORmiss << "Profile data available but missing branch-weights metadata for "
6668b42bc56SSotiris Apostolakis "select instruction. ";
6678b42bc56SSotiris Apostolakis ORE->emit(ORmiss);
6688b42bc56SSotiris Apostolakis }
6698b42bc56SSotiris Apostolakis if (!ColdOperand)
6708b42bc56SSotiris Apostolakis return false;
6718b42bc56SSotiris Apostolakis // Check if the cold path's dependence slice is expensive for any of the
6728b42bc56SSotiris Apostolakis // selects of the group.
6738b42bc56SSotiris Apostolakis for (SelectInst *SI : ASI) {
6748b42bc56SSotiris Apostolakis Instruction *ColdI = nullptr;
6758b42bc56SSotiris Apostolakis uint64_t HotWeight;
6768b42bc56SSotiris Apostolakis if (TrueWeight < FalseWeight) {
6778b42bc56SSotiris Apostolakis ColdI = dyn_cast<Instruction>(SI->getTrueValue());
6788b42bc56SSotiris Apostolakis HotWeight = FalseWeight;
6798b42bc56SSotiris Apostolakis } else {
6808b42bc56SSotiris Apostolakis ColdI = dyn_cast<Instruction>(SI->getFalseValue());
6818b42bc56SSotiris Apostolakis HotWeight = TrueWeight;
6828b42bc56SSotiris Apostolakis }
6838b42bc56SSotiris Apostolakis if (ColdI) {
68467be40dfSSotiris Apostolakis std::stack<Instruction *> ColdSlice;
6858b42bc56SSotiris Apostolakis getExclBackwardsSlice(ColdI, ColdSlice);
6868b42bc56SSotiris Apostolakis InstructionCost SliceCost = 0;
68767be40dfSSotiris Apostolakis while (!ColdSlice.empty()) {
68867be40dfSSotiris Apostolakis SliceCost += TTI->getInstructionCost(ColdSlice.top(),
68967be40dfSSotiris Apostolakis TargetTransformInfo::TCK_Latency);
69067be40dfSSotiris Apostolakis ColdSlice.pop();
6918b42bc56SSotiris Apostolakis }
6928b42bc56SSotiris Apostolakis // The colder the cold value operand of the select is the more expensive
6938b42bc56SSotiris Apostolakis // the cmov becomes for computing the cold value operand every time. Thus,
6948b42bc56SSotiris Apostolakis // the colder the cold operand is the more its cost counts.
6958b42bc56SSotiris Apostolakis // Get nearest integer cost adjusted for coldness.
6968b42bc56SSotiris Apostolakis InstructionCost AdjSliceCost =
6978b42bc56SSotiris Apostolakis divideNearest(SliceCost * HotWeight, TotalWeight);
6988b42bc56SSotiris Apostolakis if (AdjSliceCost >=
6998b42bc56SSotiris Apostolakis ColdOperandMaxCostMultiplier * TargetTransformInfo::TCC_Expensive)
7008b42bc56SSotiris Apostolakis return true;
7018b42bc56SSotiris Apostolakis }
7028b42bc56SSotiris Apostolakis }
7038b42bc56SSotiris Apostolakis return false;
7048b42bc56SSotiris Apostolakis }
7058b42bc56SSotiris Apostolakis
7068b42bc56SSotiris Apostolakis // For a given source instruction, collect its backwards dependence slice
7078b42bc56SSotiris Apostolakis // consisting of instructions exclusively computed for the purpose of producing
7088b42bc56SSotiris Apostolakis // the operands of the source instruction. As an approximation
7098b42bc56SSotiris Apostolakis // (sufficiently-accurate in practice), we populate this set with the
7108b42bc56SSotiris Apostolakis // instructions of the backwards dependence slice that only have one-use and
7118b42bc56SSotiris Apostolakis // form an one-use chain that leads to the source instruction.
getExclBackwardsSlice(Instruction * I,std::stack<Instruction * > & Slice,bool ForSinking)71267be40dfSSotiris Apostolakis void SelectOptimize::getExclBackwardsSlice(Instruction *I,
71367be40dfSSotiris Apostolakis std::stack<Instruction *> &Slice,
71467be40dfSSotiris Apostolakis bool ForSinking) {
7158b42bc56SSotiris Apostolakis SmallPtrSet<Instruction *, 2> Visited;
7168b42bc56SSotiris Apostolakis std::queue<Instruction *> Worklist;
7178b42bc56SSotiris Apostolakis Worklist.push(I);
7188b42bc56SSotiris Apostolakis while (!Worklist.empty()) {
7198b42bc56SSotiris Apostolakis Instruction *II = Worklist.front();
7208b42bc56SSotiris Apostolakis Worklist.pop();
7218b42bc56SSotiris Apostolakis
7228b42bc56SSotiris Apostolakis // Avoid cycles.
723b254d671SKazu Hirata if (!Visited.insert(II).second)
7248b42bc56SSotiris Apostolakis continue;
7258b42bc56SSotiris Apostolakis
7268b42bc56SSotiris Apostolakis if (!II->hasOneUse())
7278b42bc56SSotiris Apostolakis continue;
7288b42bc56SSotiris Apostolakis
72967be40dfSSotiris Apostolakis // Cannot soundly sink instructions with side-effects.
73067be40dfSSotiris Apostolakis // Terminator or phi instructions cannot be sunk.
73167be40dfSSotiris Apostolakis // Avoid sinking other select instructions (should be handled separetely).
73267be40dfSSotiris Apostolakis if (ForSinking && (II->isTerminator() || II->mayHaveSideEffects() ||
73367be40dfSSotiris Apostolakis isa<SelectInst>(II) || isa<PHINode>(II)))
73467be40dfSSotiris Apostolakis continue;
73567be40dfSSotiris Apostolakis
7368b42bc56SSotiris Apostolakis // Avoid considering instructions with less frequency than the source
7378b42bc56SSotiris Apostolakis // instruction (i.e., avoid colder code regions of the dependence slice).
7388b42bc56SSotiris Apostolakis if (BFI->getBlockFreq(II->getParent()) < BFI->getBlockFreq(I->getParent()))
7398b42bc56SSotiris Apostolakis continue;
7408b42bc56SSotiris Apostolakis
7418b42bc56SSotiris Apostolakis // Eligible one-use instruction added to the dependence slice.
74267be40dfSSotiris Apostolakis Slice.push(II);
7438b42bc56SSotiris Apostolakis
7448b42bc56SSotiris Apostolakis // Explore all the operands of the current instruction to expand the slice.
7458b42bc56SSotiris Apostolakis for (unsigned k = 0; k < II->getNumOperands(); ++k)
7468b42bc56SSotiris Apostolakis if (auto *OpI = dyn_cast<Instruction>(II->getOperand(k)))
7478b42bc56SSotiris Apostolakis Worklist.push(OpI);
7488b42bc56SSotiris Apostolakis }
7498b42bc56SSotiris Apostolakis }
7508b42bc56SSotiris Apostolakis
isSelectHighlyPredictable(const SelectInst * SI)7518b42bc56SSotiris Apostolakis bool SelectOptimize::isSelectHighlyPredictable(const SelectInst *SI) {
7528b42bc56SSotiris Apostolakis uint64_t TrueWeight, FalseWeight;
7538b42bc56SSotiris Apostolakis if (SI->extractProfMetadata(TrueWeight, FalseWeight)) {
7548b42bc56SSotiris Apostolakis uint64_t Max = std::max(TrueWeight, FalseWeight);
7558b42bc56SSotiris Apostolakis uint64_t Sum = TrueWeight + FalseWeight;
7568b42bc56SSotiris Apostolakis if (Sum != 0) {
7578b42bc56SSotiris Apostolakis auto Probability = BranchProbability::getBranchProbability(Max, Sum);
7588b42bc56SSotiris Apostolakis if (Probability > TTI->getPredictableBranchThreshold())
7598b42bc56SSotiris Apostolakis return true;
7608b42bc56SSotiris Apostolakis }
7618b42bc56SSotiris Apostolakis }
7628b42bc56SSotiris Apostolakis return false;
7638b42bc56SSotiris Apostolakis }
7648b42bc56SSotiris Apostolakis
checkLoopHeuristics(const Loop * L,const CostInfo LoopCost[2])765d7ebb746SSotiris Apostolakis bool SelectOptimize::checkLoopHeuristics(const Loop *L,
766d7ebb746SSotiris Apostolakis const CostInfo LoopCost[2]) {
767d7ebb746SSotiris Apostolakis // Loop-level checks to determine if a non-predicated version (with branches)
768d7ebb746SSotiris Apostolakis // of the loop is more profitable than its predicated version.
769d7ebb746SSotiris Apostolakis
770d7ebb746SSotiris Apostolakis if (DisableLoopLevelHeuristics)
771d7ebb746SSotiris Apostolakis return true;
772d7ebb746SSotiris Apostolakis
773d7ebb746SSotiris Apostolakis OptimizationRemarkMissed ORmissL(DEBUG_TYPE, "SelectOpti",
774d7ebb746SSotiris Apostolakis L->getHeader()->getFirstNonPHI());
775d7ebb746SSotiris Apostolakis
776d7ebb746SSotiris Apostolakis if (LoopCost[0].NonPredCost > LoopCost[0].PredCost ||
777d7ebb746SSotiris Apostolakis LoopCost[1].NonPredCost >= LoopCost[1].PredCost) {
778d7ebb746SSotiris Apostolakis ORmissL << "No select conversion in the loop due to no reduction of loop's "
779d7ebb746SSotiris Apostolakis "critical path. ";
780d7ebb746SSotiris Apostolakis ORE->emit(ORmissL);
781d7ebb746SSotiris Apostolakis return false;
782d7ebb746SSotiris Apostolakis }
783d7ebb746SSotiris Apostolakis
784d7ebb746SSotiris Apostolakis Scaled64 Gain[2] = {LoopCost[0].PredCost - LoopCost[0].NonPredCost,
785d7ebb746SSotiris Apostolakis LoopCost[1].PredCost - LoopCost[1].NonPredCost};
786d7ebb746SSotiris Apostolakis
787d7ebb746SSotiris Apostolakis // Profitably converting to branches need to reduce the loop's critical path
788d7ebb746SSotiris Apostolakis // by at least some threshold (absolute gain of GainCycleThreshold cycles and
789d7ebb746SSotiris Apostolakis // relative gain of 12.5%).
790d7ebb746SSotiris Apostolakis if (Gain[1] < Scaled64::get(GainCycleThreshold) ||
791d7ebb746SSotiris Apostolakis Gain[1] * Scaled64::get(GainRelativeThreshold) < LoopCost[1].PredCost) {
792d7ebb746SSotiris Apostolakis Scaled64 RelativeGain = Scaled64::get(100) * Gain[1] / LoopCost[1].PredCost;
793d7ebb746SSotiris Apostolakis ORmissL << "No select conversion in the loop due to small reduction of "
794d7ebb746SSotiris Apostolakis "loop's critical path. Gain="
795d7ebb746SSotiris Apostolakis << Gain[1].toString()
796d7ebb746SSotiris Apostolakis << ", RelativeGain=" << RelativeGain.toString() << "%. ";
797d7ebb746SSotiris Apostolakis ORE->emit(ORmissL);
798d7ebb746SSotiris Apostolakis return false;
799d7ebb746SSotiris Apostolakis }
800d7ebb746SSotiris Apostolakis
801d7ebb746SSotiris Apostolakis // If the loop's critical path involves loop-carried dependences, the gradient
802d7ebb746SSotiris Apostolakis // of the gain needs to be at least GainGradientThreshold% (defaults to 25%).
803d7ebb746SSotiris Apostolakis // This check ensures that the latency reduction for the loop's critical path
804d7ebb746SSotiris Apostolakis // keeps decreasing with sufficient rate beyond the two analyzed loop
805d7ebb746SSotiris Apostolakis // iterations.
806d7ebb746SSotiris Apostolakis if (Gain[1] > Gain[0]) {
807d7ebb746SSotiris Apostolakis Scaled64 GradientGain = Scaled64::get(100) * (Gain[1] - Gain[0]) /
808d7ebb746SSotiris Apostolakis (LoopCost[1].PredCost - LoopCost[0].PredCost);
809d7ebb746SSotiris Apostolakis if (GradientGain < Scaled64::get(GainGradientThreshold)) {
810d7ebb746SSotiris Apostolakis ORmissL << "No select conversion in the loop due to small gradient gain. "
811d7ebb746SSotiris Apostolakis "GradientGain="
812d7ebb746SSotiris Apostolakis << GradientGain.toString() << "%. ";
813d7ebb746SSotiris Apostolakis ORE->emit(ORmissL);
814d7ebb746SSotiris Apostolakis return false;
815d7ebb746SSotiris Apostolakis }
816d7ebb746SSotiris Apostolakis }
817d7ebb746SSotiris Apostolakis // If the gain decreases it is not profitable to convert.
818d7ebb746SSotiris Apostolakis else if (Gain[1] < Gain[0]) {
819d7ebb746SSotiris Apostolakis ORmissL
820d7ebb746SSotiris Apostolakis << "No select conversion in the loop due to negative gradient gain. ";
821d7ebb746SSotiris Apostolakis ORE->emit(ORmissL);
822d7ebb746SSotiris Apostolakis return false;
823d7ebb746SSotiris Apostolakis }
824d7ebb746SSotiris Apostolakis
825d7ebb746SSotiris Apostolakis // Non-predicated version of the loop is more profitable than its
826d7ebb746SSotiris Apostolakis // predicated version.
827d7ebb746SSotiris Apostolakis return true;
828d7ebb746SSotiris Apostolakis }
829d7ebb746SSotiris Apostolakis
830d7ebb746SSotiris Apostolakis // Computes instruction and loop-critical-path costs for both the predicated
831d7ebb746SSotiris Apostolakis // and non-predicated version of the given loop.
832d7ebb746SSotiris Apostolakis // Returns false if unable to compute these costs due to invalid cost of loop
833d7ebb746SSotiris Apostolakis // instruction(s).
computeLoopCosts(const Loop * L,const SelectGroups & SIGroups,DenseMap<const Instruction *,CostInfo> & InstCostMap,CostInfo * LoopCost)834d7ebb746SSotiris Apostolakis bool SelectOptimize::computeLoopCosts(
835d7ebb746SSotiris Apostolakis const Loop *L, const SelectGroups &SIGroups,
836d7ebb746SSotiris Apostolakis DenseMap<const Instruction *, CostInfo> &InstCostMap, CostInfo *LoopCost) {
837d7ebb746SSotiris Apostolakis const auto &SIset = getSIset(SIGroups);
838d7ebb746SSotiris Apostolakis // Compute instruction and loop-critical-path costs across two iterations for
839d7ebb746SSotiris Apostolakis // both predicated and non-predicated version.
840d7ebb746SSotiris Apostolakis const unsigned Iterations = 2;
841d7ebb746SSotiris Apostolakis for (unsigned Iter = 0; Iter < Iterations; ++Iter) {
842d7ebb746SSotiris Apostolakis // Cost of the loop's critical path.
843d7ebb746SSotiris Apostolakis CostInfo &MaxCost = LoopCost[Iter];
844d7ebb746SSotiris Apostolakis for (BasicBlock *BB : L->getBlocks()) {
845d7ebb746SSotiris Apostolakis for (const Instruction &I : *BB) {
846d7ebb746SSotiris Apostolakis if (I.isDebugOrPseudoInst())
847d7ebb746SSotiris Apostolakis continue;
848d7ebb746SSotiris Apostolakis // Compute the predicated and non-predicated cost of the instruction.
849d7ebb746SSotiris Apostolakis Scaled64 IPredCost = Scaled64::getZero(),
850d7ebb746SSotiris Apostolakis INonPredCost = Scaled64::getZero();
851d7ebb746SSotiris Apostolakis
852d7ebb746SSotiris Apostolakis // Assume infinite resources that allow to fully exploit the available
853d7ebb746SSotiris Apostolakis // instruction-level parallelism.
854d7ebb746SSotiris Apostolakis // InstCost = InstLatency + max(Op1Cost, Op2Cost, … OpNCost)
855d7ebb746SSotiris Apostolakis for (const Use &U : I.operands()) {
856d7ebb746SSotiris Apostolakis auto UI = dyn_cast<Instruction>(U.get());
857d7ebb746SSotiris Apostolakis if (!UI)
858d7ebb746SSotiris Apostolakis continue;
859d7ebb746SSotiris Apostolakis if (InstCostMap.count(UI)) {
860d7ebb746SSotiris Apostolakis IPredCost = std::max(IPredCost, InstCostMap[UI].PredCost);
861d7ebb746SSotiris Apostolakis INonPredCost = std::max(INonPredCost, InstCostMap[UI].NonPredCost);
862d7ebb746SSotiris Apostolakis }
863d7ebb746SSotiris Apostolakis }
864d7ebb746SSotiris Apostolakis auto ILatency = computeInstCost(&I);
865e0e687a6SKazu Hirata if (!ILatency) {
866d7ebb746SSotiris Apostolakis OptimizationRemarkMissed ORmissL(DEBUG_TYPE, "SelectOpti", &I);
867d7ebb746SSotiris Apostolakis ORmissL << "Invalid instruction cost preventing analysis and "
868d7ebb746SSotiris Apostolakis "optimization of the inner-most loop containing this "
869d7ebb746SSotiris Apostolakis "instruction. ";
870d7ebb746SSotiris Apostolakis ORE->emit(ORmissL);
871d7ebb746SSotiris Apostolakis return false;
872d7ebb746SSotiris Apostolakis }
873611ffcf4SKazu Hirata IPredCost += Scaled64::get(ILatency.value());
874611ffcf4SKazu Hirata INonPredCost += Scaled64::get(ILatency.value());
875d7ebb746SSotiris Apostolakis
876d7ebb746SSotiris Apostolakis // For a select that can be converted to branch,
877d7ebb746SSotiris Apostolakis // compute its cost as a branch (non-predicated cost).
878d7ebb746SSotiris Apostolakis //
879d7ebb746SSotiris Apostolakis // BranchCost = PredictedPathCost + MispredictCost
880d7ebb746SSotiris Apostolakis // PredictedPathCost = TrueOpCost * TrueProb + FalseOpCost * FalseProb
881d7ebb746SSotiris Apostolakis // MispredictCost = max(MispredictPenalty, CondCost) * MispredictRate
882d7ebb746SSotiris Apostolakis if (SIset.contains(&I)) {
883d7ebb746SSotiris Apostolakis auto SI = dyn_cast<SelectInst>(&I);
884d7ebb746SSotiris Apostolakis
885d7ebb746SSotiris Apostolakis Scaled64 TrueOpCost = Scaled64::getZero(),
886d7ebb746SSotiris Apostolakis FalseOpCost = Scaled64::getZero();
887d7ebb746SSotiris Apostolakis if (auto *TI = dyn_cast<Instruction>(SI->getTrueValue()))
888d7ebb746SSotiris Apostolakis if (InstCostMap.count(TI))
889d7ebb746SSotiris Apostolakis TrueOpCost = InstCostMap[TI].NonPredCost;
890d7ebb746SSotiris Apostolakis if (auto *FI = dyn_cast<Instruction>(SI->getFalseValue()))
891d7ebb746SSotiris Apostolakis if (InstCostMap.count(FI))
892d7ebb746SSotiris Apostolakis FalseOpCost = InstCostMap[FI].NonPredCost;
893d7ebb746SSotiris Apostolakis Scaled64 PredictedPathCost =
894d7ebb746SSotiris Apostolakis getPredictedPathCost(TrueOpCost, FalseOpCost, SI);
895d7ebb746SSotiris Apostolakis
896d7ebb746SSotiris Apostolakis Scaled64 CondCost = Scaled64::getZero();
897d7ebb746SSotiris Apostolakis if (auto *CI = dyn_cast<Instruction>(SI->getCondition()))
898d7ebb746SSotiris Apostolakis if (InstCostMap.count(CI))
899d7ebb746SSotiris Apostolakis CondCost = InstCostMap[CI].NonPredCost;
900d7ebb746SSotiris Apostolakis Scaled64 MispredictCost = getMispredictionCost(SI, CondCost);
901d7ebb746SSotiris Apostolakis
902d7ebb746SSotiris Apostolakis INonPredCost = PredictedPathCost + MispredictCost;
903d7ebb746SSotiris Apostolakis }
904d7ebb746SSotiris Apostolakis
905d7ebb746SSotiris Apostolakis InstCostMap[&I] = {IPredCost, INonPredCost};
906d7ebb746SSotiris Apostolakis MaxCost.PredCost = std::max(MaxCost.PredCost, IPredCost);
907d7ebb746SSotiris Apostolakis MaxCost.NonPredCost = std::max(MaxCost.NonPredCost, INonPredCost);
908d7ebb746SSotiris Apostolakis }
909d7ebb746SSotiris Apostolakis }
910d7ebb746SSotiris Apostolakis }
911d7ebb746SSotiris Apostolakis return true;
912d7ebb746SSotiris Apostolakis }
913d7ebb746SSotiris Apostolakis
914d7ebb746SSotiris Apostolakis SmallPtrSet<const Instruction *, 2>
getSIset(const SelectGroups & SIGroups)915d7ebb746SSotiris Apostolakis SelectOptimize::getSIset(const SelectGroups &SIGroups) {
916d7ebb746SSotiris Apostolakis SmallPtrSet<const Instruction *, 2> SIset;
917d7ebb746SSotiris Apostolakis for (const SelectGroup &ASI : SIGroups)
918d7ebb746SSotiris Apostolakis for (const SelectInst *SI : ASI)
919d7ebb746SSotiris Apostolakis SIset.insert(SI);
920d7ebb746SSotiris Apostolakis return SIset;
921d7ebb746SSotiris Apostolakis }
922d7ebb746SSotiris Apostolakis
computeInstCost(const Instruction * I)923d7ebb746SSotiris Apostolakis Optional<uint64_t> SelectOptimize::computeInstCost(const Instruction *I) {
924d7ebb746SSotiris Apostolakis InstructionCost ICost =
925d7ebb746SSotiris Apostolakis TTI->getInstructionCost(I, TargetTransformInfo::TCK_Latency);
926d7ebb746SSotiris Apostolakis if (auto OC = ICost.getValue())
9277a47ee51SKazu Hirata return Optional<uint64_t>(*OC);
928d7ebb746SSotiris Apostolakis return Optional<uint64_t>(None);
929d7ebb746SSotiris Apostolakis }
930d7ebb746SSotiris Apostolakis
931d7ebb746SSotiris Apostolakis ScaledNumber<uint64_t>
getMispredictionCost(const SelectInst * SI,const Scaled64 CondCost)932d7ebb746SSotiris Apostolakis SelectOptimize::getMispredictionCost(const SelectInst *SI,
933d7ebb746SSotiris Apostolakis const Scaled64 CondCost) {
934d7ebb746SSotiris Apostolakis uint64_t MispredictPenalty = TSchedModel.getMCSchedModel()->MispredictPenalty;
935d7ebb746SSotiris Apostolakis
936d7ebb746SSotiris Apostolakis // Account for the default misprediction rate when using a branch
937d7ebb746SSotiris Apostolakis // (conservatively set to 25% by default).
938d7ebb746SSotiris Apostolakis uint64_t MispredictRate = MispredictDefaultRate;
939d7ebb746SSotiris Apostolakis // If the select condition is obviously predictable, then the misprediction
940d7ebb746SSotiris Apostolakis // rate is zero.
941d7ebb746SSotiris Apostolakis if (isSelectHighlyPredictable(SI))
942d7ebb746SSotiris Apostolakis MispredictRate = 0;
943d7ebb746SSotiris Apostolakis
944d7ebb746SSotiris Apostolakis // CondCost is included to account for cases where the computation of the
945d7ebb746SSotiris Apostolakis // condition is part of a long dependence chain (potentially loop-carried)
946d7ebb746SSotiris Apostolakis // that would delay detection of a misprediction and increase its cost.
947d7ebb746SSotiris Apostolakis Scaled64 MispredictCost =
948d7ebb746SSotiris Apostolakis std::max(Scaled64::get(MispredictPenalty), CondCost) *
949d7ebb746SSotiris Apostolakis Scaled64::get(MispredictRate);
950d7ebb746SSotiris Apostolakis MispredictCost /= Scaled64::get(100);
951d7ebb746SSotiris Apostolakis
952d7ebb746SSotiris Apostolakis return MispredictCost;
953d7ebb746SSotiris Apostolakis }
954d7ebb746SSotiris Apostolakis
955d7ebb746SSotiris Apostolakis // Returns the cost of a branch when the prediction is correct.
956d7ebb746SSotiris Apostolakis // TrueCost * TrueProbability + FalseCost * FalseProbability.
957d7ebb746SSotiris Apostolakis ScaledNumber<uint64_t>
getPredictedPathCost(Scaled64 TrueCost,Scaled64 FalseCost,const SelectInst * SI)958d7ebb746SSotiris Apostolakis SelectOptimize::getPredictedPathCost(Scaled64 TrueCost, Scaled64 FalseCost,
959d7ebb746SSotiris Apostolakis const SelectInst *SI) {
960d7ebb746SSotiris Apostolakis Scaled64 PredPathCost;
961d7ebb746SSotiris Apostolakis uint64_t TrueWeight, FalseWeight;
962d7ebb746SSotiris Apostolakis if (SI->extractProfMetadata(TrueWeight, FalseWeight)) {
963d7ebb746SSotiris Apostolakis uint64_t SumWeight = TrueWeight + FalseWeight;
964d7ebb746SSotiris Apostolakis if (SumWeight != 0) {
965d7ebb746SSotiris Apostolakis PredPathCost = TrueCost * Scaled64::get(TrueWeight) +
966d7ebb746SSotiris Apostolakis FalseCost * Scaled64::get(FalseWeight);
967d7ebb746SSotiris Apostolakis PredPathCost /= Scaled64::get(SumWeight);
968d7ebb746SSotiris Apostolakis return PredPathCost;
969d7ebb746SSotiris Apostolakis }
970d7ebb746SSotiris Apostolakis }
971d7ebb746SSotiris Apostolakis // Without branch weight metadata, we assume 75% for the one path and 25% for
972d7ebb746SSotiris Apostolakis // the other, and pick the result with the biggest cost.
973d7ebb746SSotiris Apostolakis PredPathCost = std::max(TrueCost * Scaled64::get(3) + FalseCost,
974d7ebb746SSotiris Apostolakis FalseCost * Scaled64::get(3) + TrueCost);
975d7ebb746SSotiris Apostolakis PredPathCost /= Scaled64::get(4);
976d7ebb746SSotiris Apostolakis return PredPathCost;
977d7ebb746SSotiris Apostolakis }
978d7ebb746SSotiris Apostolakis
isSelectKindSupported(SelectInst * SI)97997c3ef5cSSotiris Apostolakis bool SelectOptimize::isSelectKindSupported(SelectInst *SI) {
98097c3ef5cSSotiris Apostolakis bool VectorCond = !SI->getCondition()->getType()->isIntegerTy(1);
98197c3ef5cSSotiris Apostolakis if (VectorCond)
98297c3ef5cSSotiris Apostolakis return false;
98397c3ef5cSSotiris Apostolakis TargetLowering::SelectSupportKind SelectKind;
98497c3ef5cSSotiris Apostolakis if (SI->getType()->isVectorTy())
98597c3ef5cSSotiris Apostolakis SelectKind = TargetLowering::ScalarCondVectorVal;
98697c3ef5cSSotiris Apostolakis else
98797c3ef5cSSotiris Apostolakis SelectKind = TargetLowering::ScalarValSelect;
98897c3ef5cSSotiris Apostolakis return TLI->isSelectSupported(SelectKind);
989ca7c307dSSotiris Apostolakis }
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