1 //===- LoopVectorize.cpp - A Loop Vectorizer ------------------------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 // This is the LLVM loop vectorizer. This pass modifies 'vectorizable' loops
10 // and generates target-independent LLVM-IR.
11 // The vectorizer uses the TargetTransformInfo analysis to estimate the costs
12 // of instructions in order to estimate the profitability of vectorization.
13 //
14 // The loop vectorizer combines consecutive loop iterations into a single
15 // 'wide' iteration. After this transformation the index is incremented
16 // by the SIMD vector width, and not by one.
17 //
18 // This pass has three parts:
19 // 1. The main loop pass that drives the different parts.
20 // 2. LoopVectorizationLegality - A unit that checks for the legality
21 // of the vectorization.
22 // 3. InnerLoopVectorizer - A unit that performs the actual
23 // widening of instructions.
24 // 4. LoopVectorizationCostModel - A unit that checks for the profitability
25 // of vectorization. It decides on the optimal vector width, which
26 // can be one, if vectorization is not profitable.
27 //
28 // There is a development effort going on to migrate loop vectorizer to the
29 // VPlan infrastructure and to introduce outer loop vectorization support (see
30 // docs/Proposal/VectorizationPlan.rst and
31 // http://lists.llvm.org/pipermail/llvm-dev/2017-December/119523.html). For this
32 // purpose, we temporarily introduced the VPlan-native vectorization path: an
33 // alternative vectorization path that is natively implemented on top of the
34 // VPlan infrastructure. See EnableVPlanNativePath for enabling.
35 //
36 //===----------------------------------------------------------------------===//
37 //
38 // The reduction-variable vectorization is based on the paper:
39 // D. Nuzman and R. Henderson. Multi-platform Auto-vectorization.
40 //
41 // Variable uniformity checks are inspired by:
42 // Karrenberg, R. and Hack, S. Whole Function Vectorization.
43 //
44 // The interleaved access vectorization is based on the paper:
45 // Dorit Nuzman, Ira Rosen and Ayal Zaks. Auto-Vectorization of Interleaved
46 // Data for SIMD
47 //
48 // Other ideas/concepts are from:
49 // A. Zaks and D. Nuzman. Autovectorization in GCC-two years later.
50 //
51 // S. Maleki, Y. Gao, M. Garzaran, T. Wong and D. Padua. An Evaluation of
52 // Vectorizing Compilers.
53 //
54 //===----------------------------------------------------------------------===//
55
56 #include "llvm/Transforms/Vectorize/LoopVectorize.h"
57 #include "LoopVectorizationPlanner.h"
58 #include "VPRecipeBuilder.h"
59 #include "VPlan.h"
60 #include "VPlanHCFGBuilder.h"
61 #include "VPlanPredicator.h"
62 #include "VPlanTransforms.h"
63 #include "llvm/ADT/APInt.h"
64 #include "llvm/ADT/ArrayRef.h"
65 #include "llvm/ADT/DenseMap.h"
66 #include "llvm/ADT/DenseMapInfo.h"
67 #include "llvm/ADT/Hashing.h"
68 #include "llvm/ADT/MapVector.h"
69 #include "llvm/ADT/None.h"
70 #include "llvm/ADT/Optional.h"
71 #include "llvm/ADT/STLExtras.h"
72 #include "llvm/ADT/SmallPtrSet.h"
73 #include "llvm/ADT/SmallSet.h"
74 #include "llvm/ADT/SmallVector.h"
75 #include "llvm/ADT/Statistic.h"
76 #include "llvm/ADT/StringRef.h"
77 #include "llvm/ADT/Twine.h"
78 #include "llvm/ADT/iterator_range.h"
79 #include "llvm/Analysis/AssumptionCache.h"
80 #include "llvm/Analysis/BasicAliasAnalysis.h"
81 #include "llvm/Analysis/BlockFrequencyInfo.h"
82 #include "llvm/Analysis/CFG.h"
83 #include "llvm/Analysis/CodeMetrics.h"
84 #include "llvm/Analysis/DemandedBits.h"
85 #include "llvm/Analysis/GlobalsModRef.h"
86 #include "llvm/Analysis/LoopAccessAnalysis.h"
87 #include "llvm/Analysis/LoopAnalysisManager.h"
88 #include "llvm/Analysis/LoopInfo.h"
89 #include "llvm/Analysis/LoopIterator.h"
90 #include "llvm/Analysis/MemorySSA.h"
91 #include "llvm/Analysis/OptimizationRemarkEmitter.h"
92 #include "llvm/Analysis/ProfileSummaryInfo.h"
93 #include "llvm/Analysis/ScalarEvolution.h"
94 #include "llvm/Analysis/ScalarEvolutionExpressions.h"
95 #include "llvm/Analysis/TargetLibraryInfo.h"
96 #include "llvm/Analysis/TargetTransformInfo.h"
97 #include "llvm/Analysis/VectorUtils.h"
98 #include "llvm/IR/Attributes.h"
99 #include "llvm/IR/BasicBlock.h"
100 #include "llvm/IR/CFG.h"
101 #include "llvm/IR/Constant.h"
102 #include "llvm/IR/Constants.h"
103 #include "llvm/IR/DataLayout.h"
104 #include "llvm/IR/DebugInfoMetadata.h"
105 #include "llvm/IR/DebugLoc.h"
106 #include "llvm/IR/DerivedTypes.h"
107 #include "llvm/IR/DiagnosticInfo.h"
108 #include "llvm/IR/Dominators.h"
109 #include "llvm/IR/Function.h"
110 #include "llvm/IR/IRBuilder.h"
111 #include "llvm/IR/InstrTypes.h"
112 #include "llvm/IR/Instruction.h"
113 #include "llvm/IR/Instructions.h"
114 #include "llvm/IR/IntrinsicInst.h"
115 #include "llvm/IR/Intrinsics.h"
116 #include "llvm/IR/LLVMContext.h"
117 #include "llvm/IR/Metadata.h"
118 #include "llvm/IR/Module.h"
119 #include "llvm/IR/Operator.h"
120 #include "llvm/IR/PatternMatch.h"
121 #include "llvm/IR/Type.h"
122 #include "llvm/IR/Use.h"
123 #include "llvm/IR/User.h"
124 #include "llvm/IR/Value.h"
125 #include "llvm/IR/ValueHandle.h"
126 #include "llvm/IR/Verifier.h"
127 #include "llvm/InitializePasses.h"
128 #include "llvm/Pass.h"
129 #include "llvm/Support/Casting.h"
130 #include "llvm/Support/CommandLine.h"
131 #include "llvm/Support/Compiler.h"
132 #include "llvm/Support/Debug.h"
133 #include "llvm/Support/ErrorHandling.h"
134 #include "llvm/Support/InstructionCost.h"
135 #include "llvm/Support/MathExtras.h"
136 #include "llvm/Support/raw_ostream.h"
137 #include "llvm/Transforms/Utils/BasicBlockUtils.h"
138 #include "llvm/Transforms/Utils/InjectTLIMappings.h"
139 #include "llvm/Transforms/Utils/LoopSimplify.h"
140 #include "llvm/Transforms/Utils/LoopUtils.h"
141 #include "llvm/Transforms/Utils/LoopVersioning.h"
142 #include "llvm/Transforms/Utils/ScalarEvolutionExpander.h"
143 #include "llvm/Transforms/Utils/SizeOpts.h"
144 #include "llvm/Transforms/Vectorize/LoopVectorizationLegality.h"
145 #include <algorithm>
146 #include <cassert>
147 #include <cstdint>
148 #include <cstdlib>
149 #include <functional>
150 #include <iterator>
151 #include <limits>
152 #include <memory>
153 #include <string>
154 #include <tuple>
155 #include <utility>
156
157 using namespace llvm;
158
159 #define LV_NAME "loop-vectorize"
160 #define DEBUG_TYPE LV_NAME
161
162 #ifndef NDEBUG
163 const char VerboseDebug[] = DEBUG_TYPE "-verbose";
164 #endif
165
166 /// @{
167 /// Metadata attribute names
168 const char LLVMLoopVectorizeFollowupAll[] = "llvm.loop.vectorize.followup_all";
169 const char LLVMLoopVectorizeFollowupVectorized[] =
170 "llvm.loop.vectorize.followup_vectorized";
171 const char LLVMLoopVectorizeFollowupEpilogue[] =
172 "llvm.loop.vectorize.followup_epilogue";
173 /// @}
174
175 STATISTIC(LoopsVectorized, "Number of loops vectorized");
176 STATISTIC(LoopsAnalyzed, "Number of loops analyzed for vectorization");
177 STATISTIC(LoopsEpilogueVectorized, "Number of epilogues vectorized");
178
179 static cl::opt<bool> EnableEpilogueVectorization(
180 "enable-epilogue-vectorization", cl::init(true), cl::Hidden,
181 cl::desc("Enable vectorization of epilogue loops."));
182
183 static cl::opt<unsigned> EpilogueVectorizationForceVF(
184 "epilogue-vectorization-force-VF", cl::init(1), cl::Hidden,
185 cl::desc("When epilogue vectorization is enabled, and a value greater than "
186 "1 is specified, forces the given VF for all applicable epilogue "
187 "loops."));
188
189 static cl::opt<unsigned> EpilogueVectorizationMinVF(
190 "epilogue-vectorization-minimum-VF", cl::init(16), cl::Hidden,
191 cl::desc("Only loops with vectorization factor equal to or larger than "
192 "the specified value are considered for epilogue vectorization."));
193
194 /// Loops with a known constant trip count below this number are vectorized only
195 /// if no scalar iteration overheads are incurred.
196 static cl::opt<unsigned> TinyTripCountVectorThreshold(
197 "vectorizer-min-trip-count", cl::init(16), cl::Hidden,
198 cl::desc("Loops with a constant trip count that is smaller than this "
199 "value are vectorized only if no scalar iteration overheads "
200 "are incurred."));
201
202 static cl::opt<unsigned> PragmaVectorizeMemoryCheckThreshold(
203 "pragma-vectorize-memory-check-threshold", cl::init(128), cl::Hidden,
204 cl::desc("The maximum allowed number of runtime memory checks with a "
205 "vectorize(enable) pragma."));
206
207 // Option prefer-predicate-over-epilogue indicates that an epilogue is undesired,
208 // that predication is preferred, and this lists all options. I.e., the
209 // vectorizer will try to fold the tail-loop (epilogue) into the vector body
210 // and predicate the instructions accordingly. If tail-folding fails, there are
211 // different fallback strategies depending on these values:
212 namespace PreferPredicateTy {
213 enum Option {
214 ScalarEpilogue = 0,
215 PredicateElseScalarEpilogue,
216 PredicateOrDontVectorize
217 };
218 } // namespace PreferPredicateTy
219
220 static cl::opt<PreferPredicateTy::Option> PreferPredicateOverEpilogue(
221 "prefer-predicate-over-epilogue",
222 cl::init(PreferPredicateTy::ScalarEpilogue),
223 cl::Hidden,
224 cl::desc("Tail-folding and predication preferences over creating a scalar "
225 "epilogue loop."),
226 cl::values(clEnumValN(PreferPredicateTy::ScalarEpilogue,
227 "scalar-epilogue",
228 "Don't tail-predicate loops, create scalar epilogue"),
229 clEnumValN(PreferPredicateTy::PredicateElseScalarEpilogue,
230 "predicate-else-scalar-epilogue",
231 "prefer tail-folding, create scalar epilogue if tail "
232 "folding fails."),
233 clEnumValN(PreferPredicateTy::PredicateOrDontVectorize,
234 "predicate-dont-vectorize",
235 "prefers tail-folding, don't attempt vectorization if "
236 "tail-folding fails.")));
237
238 static cl::opt<bool> MaximizeBandwidth(
239 "vectorizer-maximize-bandwidth", cl::init(false), cl::Hidden,
240 cl::desc("Maximize bandwidth when selecting vectorization factor which "
241 "will be determined by the smallest type in loop."));
242
243 static cl::opt<bool> EnableInterleavedMemAccesses(
244 "enable-interleaved-mem-accesses", cl::init(false), cl::Hidden,
245 cl::desc("Enable vectorization on interleaved memory accesses in a loop"));
246
247 /// An interleave-group may need masking if it resides in a block that needs
248 /// predication, or in order to mask away gaps.
249 static cl::opt<bool> EnableMaskedInterleavedMemAccesses(
250 "enable-masked-interleaved-mem-accesses", cl::init(false), cl::Hidden,
251 cl::desc("Enable vectorization on masked interleaved memory accesses in a loop"));
252
253 static cl::opt<unsigned> TinyTripCountInterleaveThreshold(
254 "tiny-trip-count-interleave-threshold", cl::init(128), cl::Hidden,
255 cl::desc("We don't interleave loops with a estimated constant trip count "
256 "below this number"));
257
258 static cl::opt<unsigned> ForceTargetNumScalarRegs(
259 "force-target-num-scalar-regs", cl::init(0), cl::Hidden,
260 cl::desc("A flag that overrides the target's number of scalar registers."));
261
262 static cl::opt<unsigned> ForceTargetNumVectorRegs(
263 "force-target-num-vector-regs", cl::init(0), cl::Hidden,
264 cl::desc("A flag that overrides the target's number of vector registers."));
265
266 static cl::opt<unsigned> ForceTargetMaxScalarInterleaveFactor(
267 "force-target-max-scalar-interleave", cl::init(0), cl::Hidden,
268 cl::desc("A flag that overrides the target's max interleave factor for "
269 "scalar loops."));
270
271 static cl::opt<unsigned> ForceTargetMaxVectorInterleaveFactor(
272 "force-target-max-vector-interleave", cl::init(0), cl::Hidden,
273 cl::desc("A flag that overrides the target's max interleave factor for "
274 "vectorized loops."));
275
276 static cl::opt<unsigned> ForceTargetInstructionCost(
277 "force-target-instruction-cost", cl::init(0), cl::Hidden,
278 cl::desc("A flag that overrides the target's expected cost for "
279 "an instruction to a single constant value. Mostly "
280 "useful for getting consistent testing."));
281
282 static cl::opt<bool> ForceTargetSupportsScalableVectors(
283 "force-target-supports-scalable-vectors", cl::init(false), cl::Hidden,
284 cl::desc(
285 "Pretend that scalable vectors are supported, even if the target does "
286 "not support them. This flag should only be used for testing."));
287
288 static cl::opt<unsigned> SmallLoopCost(
289 "small-loop-cost", cl::init(20), cl::Hidden,
290 cl::desc(
291 "The cost of a loop that is considered 'small' by the interleaver."));
292
293 static cl::opt<bool> LoopVectorizeWithBlockFrequency(
294 "loop-vectorize-with-block-frequency", cl::init(true), cl::Hidden,
295 cl::desc("Enable the use of the block frequency analysis to access PGO "
296 "heuristics minimizing code growth in cold regions and being more "
297 "aggressive in hot regions."));
298
299 // Runtime interleave loops for load/store throughput.
300 static cl::opt<bool> EnableLoadStoreRuntimeInterleave(
301 "enable-loadstore-runtime-interleave", cl::init(true), cl::Hidden,
302 cl::desc(
303 "Enable runtime interleaving until load/store ports are saturated"));
304
305 /// Interleave small loops with scalar reductions.
306 static cl::opt<bool> InterleaveSmallLoopScalarReduction(
307 "interleave-small-loop-scalar-reduction", cl::init(false), cl::Hidden,
308 cl::desc("Enable interleaving for loops with small iteration counts that "
309 "contain scalar reductions to expose ILP."));
310
311 /// The number of stores in a loop that are allowed to need predication.
312 static cl::opt<unsigned> NumberOfStoresToPredicate(
313 "vectorize-num-stores-pred", cl::init(1), cl::Hidden,
314 cl::desc("Max number of stores to be predicated behind an if."));
315
316 static cl::opt<bool> EnableIndVarRegisterHeur(
317 "enable-ind-var-reg-heur", cl::init(true), cl::Hidden,
318 cl::desc("Count the induction variable only once when interleaving"));
319
320 static cl::opt<bool> EnableCondStoresVectorization(
321 "enable-cond-stores-vec", cl::init(true), cl::Hidden,
322 cl::desc("Enable if predication of stores during vectorization."));
323
324 static cl::opt<unsigned> MaxNestedScalarReductionIC(
325 "max-nested-scalar-reduction-interleave", cl::init(2), cl::Hidden,
326 cl::desc("The maximum interleave count to use when interleaving a scalar "
327 "reduction in a nested loop."));
328
329 static cl::opt<bool>
330 PreferInLoopReductions("prefer-inloop-reductions", cl::init(false),
331 cl::Hidden,
332 cl::desc("Prefer in-loop vector reductions, "
333 "overriding the targets preference."));
334
335 cl::opt<bool> EnableStrictReductions(
336 "enable-strict-reductions", cl::init(false), cl::Hidden,
337 cl::desc("Enable the vectorisation of loops with in-order (strict) "
338 "FP reductions"));
339
340 static cl::opt<bool> PreferPredicatedReductionSelect(
341 "prefer-predicated-reduction-select", cl::init(false), cl::Hidden,
342 cl::desc(
343 "Prefer predicating a reduction operation over an after loop select."));
344
345 cl::opt<bool> EnableVPlanNativePath(
346 "enable-vplan-native-path", cl::init(false), cl::Hidden,
347 cl::desc("Enable VPlan-native vectorization path with "
348 "support for outer loop vectorization."));
349
350 // FIXME: Remove this switch once we have divergence analysis. Currently we
351 // assume divergent non-backedge branches when this switch is true.
352 cl::opt<bool> EnableVPlanPredication(
353 "enable-vplan-predication", cl::init(false), cl::Hidden,
354 cl::desc("Enable VPlan-native vectorization path predicator with "
355 "support for outer loop vectorization."));
356
357 // This flag enables the stress testing of the VPlan H-CFG construction in the
358 // VPlan-native vectorization path. It must be used in conjuction with
359 // -enable-vplan-native-path. -vplan-verify-hcfg can also be used to enable the
360 // verification of the H-CFGs built.
361 static cl::opt<bool> VPlanBuildStressTest(
362 "vplan-build-stress-test", cl::init(false), cl::Hidden,
363 cl::desc(
364 "Build VPlan for every supported loop nest in the function and bail "
365 "out right after the build (stress test the VPlan H-CFG construction "
366 "in the VPlan-native vectorization path)."));
367
368 cl::opt<bool> llvm::EnableLoopInterleaving(
369 "interleave-loops", cl::init(true), cl::Hidden,
370 cl::desc("Enable loop interleaving in Loop vectorization passes"));
371 cl::opt<bool> llvm::EnableLoopVectorization(
372 "vectorize-loops", cl::init(true), cl::Hidden,
373 cl::desc("Run the Loop vectorization passes"));
374
375 cl::opt<bool> PrintVPlansInDotFormat(
376 "vplan-print-in-dot-format", cl::init(false), cl::Hidden,
377 cl::desc("Use dot format instead of plain text when dumping VPlans"));
378
379 /// A helper function that returns true if the given type is irregular. The
380 /// type is irregular if its allocated size doesn't equal the store size of an
381 /// element of the corresponding vector type.
hasIrregularType(Type * Ty,const DataLayout & DL)382 static bool hasIrregularType(Type *Ty, const DataLayout &DL) {
383 // Determine if an array of N elements of type Ty is "bitcast compatible"
384 // with a <N x Ty> vector.
385 // This is only true if there is no padding between the array elements.
386 return DL.getTypeAllocSizeInBits(Ty) != DL.getTypeSizeInBits(Ty);
387 }
388
389 /// A helper function that returns the reciprocal of the block probability of
390 /// predicated blocks. If we return X, we are assuming the predicated block
391 /// will execute once for every X iterations of the loop header.
392 ///
393 /// TODO: We should use actual block probability here, if available. Currently,
394 /// we always assume predicated blocks have a 50% chance of executing.
getReciprocalPredBlockProb()395 static unsigned getReciprocalPredBlockProb() { return 2; }
396
397 /// A helper function that returns an integer or floating-point constant with
398 /// value C.
getSignedIntOrFpConstant(Type * Ty,int64_t C)399 static Constant *getSignedIntOrFpConstant(Type *Ty, int64_t C) {
400 return Ty->isIntegerTy() ? ConstantInt::getSigned(Ty, C)
401 : ConstantFP::get(Ty, C);
402 }
403
404 /// Returns "best known" trip count for the specified loop \p L as defined by
405 /// the following procedure:
406 /// 1) Returns exact trip count if it is known.
407 /// 2) Returns expected trip count according to profile data if any.
408 /// 3) Returns upper bound estimate if it is known.
409 /// 4) Returns None if all of the above failed.
getSmallBestKnownTC(ScalarEvolution & SE,Loop * L)410 static Optional<unsigned> getSmallBestKnownTC(ScalarEvolution &SE, Loop *L) {
411 // Check if exact trip count is known.
412 if (unsigned ExpectedTC = SE.getSmallConstantTripCount(L))
413 return ExpectedTC;
414
415 // Check if there is an expected trip count available from profile data.
416 if (LoopVectorizeWithBlockFrequency)
417 if (auto EstimatedTC = getLoopEstimatedTripCount(L))
418 return EstimatedTC;
419
420 // Check if upper bound estimate is known.
421 if (unsigned ExpectedTC = SE.getSmallConstantMaxTripCount(L))
422 return ExpectedTC;
423
424 return None;
425 }
426
427 // Forward declare GeneratedRTChecks.
428 class GeneratedRTChecks;
429
430 namespace llvm {
431
432 /// InnerLoopVectorizer vectorizes loops which contain only one basic
433 /// block to a specified vectorization factor (VF).
434 /// This class performs the widening of scalars into vectors, or multiple
435 /// scalars. This class also implements the following features:
436 /// * It inserts an epilogue loop for handling loops that don't have iteration
437 /// counts that are known to be a multiple of the vectorization factor.
438 /// * It handles the code generation for reduction variables.
439 /// * Scalarization (implementation using scalars) of un-vectorizable
440 /// instructions.
441 /// InnerLoopVectorizer does not perform any vectorization-legality
442 /// checks, and relies on the caller to check for the different legality
443 /// aspects. The InnerLoopVectorizer relies on the
444 /// LoopVectorizationLegality class to provide information about the induction
445 /// and reduction variables that were found to a given vectorization factor.
446 class InnerLoopVectorizer {
447 public:
InnerLoopVectorizer(Loop * OrigLoop,PredicatedScalarEvolution & PSE,LoopInfo * LI,DominatorTree * DT,const TargetLibraryInfo * TLI,const TargetTransformInfo * TTI,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,ElementCount VecWidth,unsigned UnrollFactor,LoopVectorizationLegality * LVL,LoopVectorizationCostModel * CM,BlockFrequencyInfo * BFI,ProfileSummaryInfo * PSI,GeneratedRTChecks & RTChecks)448 InnerLoopVectorizer(Loop *OrigLoop, PredicatedScalarEvolution &PSE,
449 LoopInfo *LI, DominatorTree *DT,
450 const TargetLibraryInfo *TLI,
451 const TargetTransformInfo *TTI, AssumptionCache *AC,
452 OptimizationRemarkEmitter *ORE, ElementCount VecWidth,
453 unsigned UnrollFactor, LoopVectorizationLegality *LVL,
454 LoopVectorizationCostModel *CM, BlockFrequencyInfo *BFI,
455 ProfileSummaryInfo *PSI, GeneratedRTChecks &RTChecks)
456 : OrigLoop(OrigLoop), PSE(PSE), LI(LI), DT(DT), TLI(TLI), TTI(TTI),
457 AC(AC), ORE(ORE), VF(VecWidth), UF(UnrollFactor),
458 Builder(PSE.getSE()->getContext()), Legal(LVL), Cost(CM), BFI(BFI),
459 PSI(PSI), RTChecks(RTChecks) {
460 // Query this against the original loop and save it here because the profile
461 // of the original loop header may change as the transformation happens.
462 OptForSizeBasedOnProfile = llvm::shouldOptimizeForSize(
463 OrigLoop->getHeader(), PSI, BFI, PGSOQueryType::IRPass);
464 }
465
466 virtual ~InnerLoopVectorizer() = default;
467
468 /// Create a new empty loop that will contain vectorized instructions later
469 /// on, while the old loop will be used as the scalar remainder. Control flow
470 /// is generated around the vectorized (and scalar epilogue) loops consisting
471 /// of various checks and bypasses. Return the pre-header block of the new
472 /// loop.
473 /// In the case of epilogue vectorization, this function is overriden to
474 /// handle the more complex control flow around the loops.
475 virtual BasicBlock *createVectorizedLoopSkeleton();
476
477 /// Widen a single instruction within the innermost loop.
478 void widenInstruction(Instruction &I, VPValue *Def, VPUser &Operands,
479 VPTransformState &State);
480
481 /// Widen a single call instruction within the innermost loop.
482 void widenCallInstruction(CallInst &I, VPValue *Def, VPUser &ArgOperands,
483 VPTransformState &State);
484
485 /// Widen a single select instruction within the innermost loop.
486 void widenSelectInstruction(SelectInst &I, VPValue *VPDef, VPUser &Operands,
487 bool InvariantCond, VPTransformState &State);
488
489 /// Fix the vectorized code, taking care of header phi's, live-outs, and more.
490 void fixVectorizedLoop(VPTransformState &State);
491
492 // Return true if any runtime check is added.
areSafetyChecksAdded()493 bool areSafetyChecksAdded() { return AddedSafetyChecks; }
494
495 /// A type for vectorized values in the new loop. Each value from the
496 /// original loop, when vectorized, is represented by UF vector values in the
497 /// new unrolled loop, where UF is the unroll factor.
498 using VectorParts = SmallVector<Value *, 2>;
499
500 /// Vectorize a single GetElementPtrInst based on information gathered and
501 /// decisions taken during planning.
502 void widenGEP(GetElementPtrInst *GEP, VPValue *VPDef, VPUser &Indices,
503 unsigned UF, ElementCount VF, bool IsPtrLoopInvariant,
504 SmallBitVector &IsIndexLoopInvariant, VPTransformState &State);
505
506 /// Vectorize a single first-order recurrence or pointer induction PHINode in
507 /// a block. This method handles the induction variable canonicalization. It
508 /// supports both VF = 1 for unrolled loops and arbitrary length vectors.
509 void widenPHIInstruction(Instruction *PN, VPWidenPHIRecipe *PhiR,
510 VPTransformState &State);
511
512 /// A helper function to scalarize a single Instruction in the innermost loop.
513 /// Generates a sequence of scalar instances for each lane between \p MinLane
514 /// and \p MaxLane, times each part between \p MinPart and \p MaxPart,
515 /// inclusive. Uses the VPValue operands from \p Operands instead of \p
516 /// Instr's operands.
517 void scalarizeInstruction(Instruction *Instr, VPValue *Def, VPUser &Operands,
518 const VPIteration &Instance, bool IfPredicateInstr,
519 VPTransformState &State);
520
521 /// Widen an integer or floating-point induction variable \p IV. If \p Trunc
522 /// is provided, the integer induction variable will first be truncated to
523 /// the corresponding type.
524 void widenIntOrFpInduction(PHINode *IV, Value *Start, TruncInst *Trunc,
525 VPValue *Def, VPValue *CastDef,
526 VPTransformState &State);
527
528 /// Construct the vector value of a scalarized value \p V one lane at a time.
529 void packScalarIntoVectorValue(VPValue *Def, const VPIteration &Instance,
530 VPTransformState &State);
531
532 /// Try to vectorize interleaved access group \p Group with the base address
533 /// given in \p Addr, optionally masking the vector operations if \p
534 /// BlockInMask is non-null. Use \p State to translate given VPValues to IR
535 /// values in the vectorized loop.
536 void vectorizeInterleaveGroup(const InterleaveGroup<Instruction> *Group,
537 ArrayRef<VPValue *> VPDefs,
538 VPTransformState &State, VPValue *Addr,
539 ArrayRef<VPValue *> StoredValues,
540 VPValue *BlockInMask = nullptr);
541
542 /// Vectorize Load and Store instructions with the base address given in \p
543 /// Addr, optionally masking the vector operations if \p BlockInMask is
544 /// non-null. Use \p State to translate given VPValues to IR values in the
545 /// vectorized loop.
546 void vectorizeMemoryInstruction(Instruction *Instr, VPTransformState &State,
547 VPValue *Def, VPValue *Addr,
548 VPValue *StoredValue, VPValue *BlockInMask);
549
550 /// Set the debug location in the builder \p Ptr using the debug location in
551 /// \p V. If \p Ptr is None then it uses the class member's Builder.
552 void setDebugLocFromInst(const Value *V,
553 Optional<IRBuilder<> *> CustomBuilder = None);
554
555 /// Fix the non-induction PHIs in the OrigPHIsToFix vector.
556 void fixNonInductionPHIs(VPTransformState &State);
557
558 /// Returns true if the reordering of FP operations is not allowed, but we are
559 /// able to vectorize with strict in-order reductions for the given RdxDesc.
560 bool useOrderedReductions(RecurrenceDescriptor &RdxDesc);
561
562 /// Create a broadcast instruction. This method generates a broadcast
563 /// instruction (shuffle) for loop invariant values and for the induction
564 /// value. If this is the induction variable then we extend it to N, N+1, ...
565 /// this is needed because each iteration in the loop corresponds to a SIMD
566 /// element.
567 virtual Value *getBroadcastInstrs(Value *V);
568
569 protected:
570 friend class LoopVectorizationPlanner;
571
572 /// A small list of PHINodes.
573 using PhiVector = SmallVector<PHINode *, 4>;
574
575 /// A type for scalarized values in the new loop. Each value from the
576 /// original loop, when scalarized, is represented by UF x VF scalar values
577 /// in the new unrolled loop, where UF is the unroll factor and VF is the
578 /// vectorization factor.
579 using ScalarParts = SmallVector<SmallVector<Value *, 4>, 2>;
580
581 /// Set up the values of the IVs correctly when exiting the vector loop.
582 void fixupIVUsers(PHINode *OrigPhi, const InductionDescriptor &II,
583 Value *CountRoundDown, Value *EndValue,
584 BasicBlock *MiddleBlock);
585
586 /// Create a new induction variable inside L.
587 PHINode *createInductionVariable(Loop *L, Value *Start, Value *End,
588 Value *Step, Instruction *DL);
589
590 /// Handle all cross-iteration phis in the header.
591 void fixCrossIterationPHIs(VPTransformState &State);
592
593 /// Fix a first-order recurrence. This is the second phase of vectorizing
594 /// this phi node.
595 void fixFirstOrderRecurrence(VPWidenPHIRecipe *PhiR, VPTransformState &State);
596
597 /// Fix a reduction cross-iteration phi. This is the second phase of
598 /// vectorizing this phi node.
599 void fixReduction(VPReductionPHIRecipe *Phi, VPTransformState &State);
600
601 /// Clear NSW/NUW flags from reduction instructions if necessary.
602 void clearReductionWrapFlags(const RecurrenceDescriptor &RdxDesc,
603 VPTransformState &State);
604
605 /// Fixup the LCSSA phi nodes in the unique exit block. This simply
606 /// means we need to add the appropriate incoming value from the middle
607 /// block as exiting edges from the scalar epilogue loop (if present) are
608 /// already in place, and we exit the vector loop exclusively to the middle
609 /// block.
610 void fixLCSSAPHIs(VPTransformState &State);
611
612 /// Iteratively sink the scalarized operands of a predicated instruction into
613 /// the block that was created for it.
614 void sinkScalarOperands(Instruction *PredInst);
615
616 /// Shrinks vector element sizes to the smallest bitwidth they can be legally
617 /// represented as.
618 void truncateToMinimalBitwidths(VPTransformState &State);
619
620 /// This function adds
621 /// (StartIdx * Step, (StartIdx + 1) * Step, (StartIdx + 2) * Step, ...)
622 /// to each vector element of Val. The sequence starts at StartIndex.
623 /// \p Opcode is relevant for FP induction variable.
624 virtual Value *getStepVector(Value *Val, int StartIdx, Value *Step,
625 Instruction::BinaryOps Opcode =
626 Instruction::BinaryOpsEnd);
627
628 /// Compute scalar induction steps. \p ScalarIV is the scalar induction
629 /// variable on which to base the steps, \p Step is the size of the step, and
630 /// \p EntryVal is the value from the original loop that maps to the steps.
631 /// Note that \p EntryVal doesn't have to be an induction variable - it
632 /// can also be a truncate instruction.
633 void buildScalarSteps(Value *ScalarIV, Value *Step, Instruction *EntryVal,
634 const InductionDescriptor &ID, VPValue *Def,
635 VPValue *CastDef, VPTransformState &State);
636
637 /// Create a vector induction phi node based on an existing scalar one. \p
638 /// EntryVal is the value from the original loop that maps to the vector phi
639 /// node, and \p Step is the loop-invariant step. If \p EntryVal is a
640 /// truncate instruction, instead of widening the original IV, we widen a
641 /// version of the IV truncated to \p EntryVal's type.
642 void createVectorIntOrFpInductionPHI(const InductionDescriptor &II,
643 Value *Step, Value *Start,
644 Instruction *EntryVal, VPValue *Def,
645 VPValue *CastDef,
646 VPTransformState &State);
647
648 /// Returns true if an instruction \p I should be scalarized instead of
649 /// vectorized for the chosen vectorization factor.
650 bool shouldScalarizeInstruction(Instruction *I) const;
651
652 /// Returns true if we should generate a scalar version of \p IV.
653 bool needsScalarInduction(Instruction *IV) const;
654
655 /// If there is a cast involved in the induction variable \p ID, which should
656 /// be ignored in the vectorized loop body, this function records the
657 /// VectorLoopValue of the respective Phi also as the VectorLoopValue of the
658 /// cast. We had already proved that the casted Phi is equal to the uncasted
659 /// Phi in the vectorized loop (under a runtime guard), and therefore
660 /// there is no need to vectorize the cast - the same value can be used in the
661 /// vector loop for both the Phi and the cast.
662 /// If \p VectorLoopValue is a scalarized value, \p Lane is also specified,
663 /// Otherwise, \p VectorLoopValue is a widened/vectorized value.
664 ///
665 /// \p EntryVal is the value from the original loop that maps to the vector
666 /// phi node and is used to distinguish what is the IV currently being
667 /// processed - original one (if \p EntryVal is a phi corresponding to the
668 /// original IV) or the "newly-created" one based on the proof mentioned above
669 /// (see also buildScalarSteps() and createVectorIntOrFPInductionPHI()). In the
670 /// latter case \p EntryVal is a TruncInst and we must not record anything for
671 /// that IV, but it's error-prone to expect callers of this routine to care
672 /// about that, hence this explicit parameter.
673 void recordVectorLoopValueForInductionCast(
674 const InductionDescriptor &ID, const Instruction *EntryVal,
675 Value *VectorLoopValue, VPValue *CastDef, VPTransformState &State,
676 unsigned Part, unsigned Lane = UINT_MAX);
677
678 /// Generate a shuffle sequence that will reverse the vector Vec.
679 virtual Value *reverseVector(Value *Vec);
680
681 /// Returns (and creates if needed) the original loop trip count.
682 Value *getOrCreateTripCount(Loop *NewLoop);
683
684 /// Returns (and creates if needed) the trip count of the widened loop.
685 Value *getOrCreateVectorTripCount(Loop *NewLoop);
686
687 /// Returns a bitcasted value to the requested vector type.
688 /// Also handles bitcasts of vector<float> <-> vector<pointer> types.
689 Value *createBitOrPointerCast(Value *V, VectorType *DstVTy,
690 const DataLayout &DL);
691
692 /// Emit a bypass check to see if the vector trip count is zero, including if
693 /// it overflows.
694 void emitMinimumIterationCountCheck(Loop *L, BasicBlock *Bypass);
695
696 /// Emit a bypass check to see if all of the SCEV assumptions we've
697 /// had to make are correct. Returns the block containing the checks or
698 /// nullptr if no checks have been added.
699 BasicBlock *emitSCEVChecks(Loop *L, BasicBlock *Bypass);
700
701 /// Emit bypass checks to check any memory assumptions we may have made.
702 /// Returns the block containing the checks or nullptr if no checks have been
703 /// added.
704 BasicBlock *emitMemRuntimeChecks(Loop *L, BasicBlock *Bypass);
705
706 /// Compute the transformed value of Index at offset StartValue using step
707 /// StepValue.
708 /// For integer induction, returns StartValue + Index * StepValue.
709 /// For pointer induction, returns StartValue[Index * StepValue].
710 /// FIXME: The newly created binary instructions should contain nsw/nuw
711 /// flags, which can be found from the original scalar operations.
712 Value *emitTransformedIndex(IRBuilder<> &B, Value *Index, ScalarEvolution *SE,
713 const DataLayout &DL,
714 const InductionDescriptor &ID) const;
715
716 /// Emit basic blocks (prefixed with \p Prefix) for the iteration check,
717 /// vector loop preheader, middle block and scalar preheader. Also
718 /// allocate a loop object for the new vector loop and return it.
719 Loop *createVectorLoopSkeleton(StringRef Prefix);
720
721 /// Create new phi nodes for the induction variables to resume iteration count
722 /// in the scalar epilogue, from where the vectorized loop left off (given by
723 /// \p VectorTripCount).
724 /// In cases where the loop skeleton is more complicated (eg. epilogue
725 /// vectorization) and the resume values can come from an additional bypass
726 /// block, the \p AdditionalBypass pair provides information about the bypass
727 /// block and the end value on the edge from bypass to this loop.
728 void createInductionResumeValues(
729 Loop *L, Value *VectorTripCount,
730 std::pair<BasicBlock *, Value *> AdditionalBypass = {nullptr, nullptr});
731
732 /// Complete the loop skeleton by adding debug MDs, creating appropriate
733 /// conditional branches in the middle block, preparing the builder and
734 /// running the verifier. Take in the vector loop \p L as argument, and return
735 /// the preheader of the completed vector loop.
736 BasicBlock *completeLoopSkeleton(Loop *L, MDNode *OrigLoopID);
737
738 /// Add additional metadata to \p To that was not present on \p Orig.
739 ///
740 /// Currently this is used to add the noalias annotations based on the
741 /// inserted memchecks. Use this for instructions that are *cloned* into the
742 /// vector loop.
743 void addNewMetadata(Instruction *To, const Instruction *Orig);
744
745 /// Add metadata from one instruction to another.
746 ///
747 /// This includes both the original MDs from \p From and additional ones (\see
748 /// addNewMetadata). Use this for *newly created* instructions in the vector
749 /// loop.
750 void addMetadata(Instruction *To, Instruction *From);
751
752 /// Similar to the previous function but it adds the metadata to a
753 /// vector of instructions.
754 void addMetadata(ArrayRef<Value *> To, Instruction *From);
755
756 /// Allow subclasses to override and print debug traces before/after vplan
757 /// execution, when trace information is requested.
printDebugTracesAtStart()758 virtual void printDebugTracesAtStart(){};
printDebugTracesAtEnd()759 virtual void printDebugTracesAtEnd(){};
760
761 /// The original loop.
762 Loop *OrigLoop;
763
764 /// A wrapper around ScalarEvolution used to add runtime SCEV checks. Applies
765 /// dynamic knowledge to simplify SCEV expressions and converts them to a
766 /// more usable form.
767 PredicatedScalarEvolution &PSE;
768
769 /// Loop Info.
770 LoopInfo *LI;
771
772 /// Dominator Tree.
773 DominatorTree *DT;
774
775 /// Alias Analysis.
776 AAResults *AA;
777
778 /// Target Library Info.
779 const TargetLibraryInfo *TLI;
780
781 /// Target Transform Info.
782 const TargetTransformInfo *TTI;
783
784 /// Assumption Cache.
785 AssumptionCache *AC;
786
787 /// Interface to emit optimization remarks.
788 OptimizationRemarkEmitter *ORE;
789
790 /// LoopVersioning. It's only set up (non-null) if memchecks were
791 /// used.
792 ///
793 /// This is currently only used to add no-alias metadata based on the
794 /// memchecks. The actually versioning is performed manually.
795 std::unique_ptr<LoopVersioning> LVer;
796
797 /// The vectorization SIMD factor to use. Each vector will have this many
798 /// vector elements.
799 ElementCount VF;
800
801 /// The vectorization unroll factor to use. Each scalar is vectorized to this
802 /// many different vector instructions.
803 unsigned UF;
804
805 /// The builder that we use
806 IRBuilder<> Builder;
807
808 // --- Vectorization state ---
809
810 /// The vector-loop preheader.
811 BasicBlock *LoopVectorPreHeader;
812
813 /// The scalar-loop preheader.
814 BasicBlock *LoopScalarPreHeader;
815
816 /// Middle Block between the vector and the scalar.
817 BasicBlock *LoopMiddleBlock;
818
819 /// The unique ExitBlock of the scalar loop if one exists. Note that
820 /// there can be multiple exiting edges reaching this block.
821 BasicBlock *LoopExitBlock;
822
823 /// The vector loop body.
824 BasicBlock *LoopVectorBody;
825
826 /// The scalar loop body.
827 BasicBlock *LoopScalarBody;
828
829 /// A list of all bypass blocks. The first block is the entry of the loop.
830 SmallVector<BasicBlock *, 4> LoopBypassBlocks;
831
832 /// The new Induction variable which was added to the new block.
833 PHINode *Induction = nullptr;
834
835 /// The induction variable of the old basic block.
836 PHINode *OldInduction = nullptr;
837
838 /// Store instructions that were predicated.
839 SmallVector<Instruction *, 4> PredicatedInstructions;
840
841 /// Trip count of the original loop.
842 Value *TripCount = nullptr;
843
844 /// Trip count of the widened loop (TripCount - TripCount % (VF*UF))
845 Value *VectorTripCount = nullptr;
846
847 /// The legality analysis.
848 LoopVectorizationLegality *Legal;
849
850 /// The profitablity analysis.
851 LoopVectorizationCostModel *Cost;
852
853 // Record whether runtime checks are added.
854 bool AddedSafetyChecks = false;
855
856 // Holds the end values for each induction variable. We save the end values
857 // so we can later fix-up the external users of the induction variables.
858 DenseMap<PHINode *, Value *> IVEndValues;
859
860 // Vector of original scalar PHIs whose corresponding widened PHIs need to be
861 // fixed up at the end of vector code generation.
862 SmallVector<PHINode *, 8> OrigPHIsToFix;
863
864 /// BFI and PSI are used to check for profile guided size optimizations.
865 BlockFrequencyInfo *BFI;
866 ProfileSummaryInfo *PSI;
867
868 // Whether this loop should be optimized for size based on profile guided size
869 // optimizatios.
870 bool OptForSizeBasedOnProfile;
871
872 /// Structure to hold information about generated runtime checks, responsible
873 /// for cleaning the checks, if vectorization turns out unprofitable.
874 GeneratedRTChecks &RTChecks;
875 };
876
877 class InnerLoopUnroller : public InnerLoopVectorizer {
878 public:
InnerLoopUnroller(Loop * OrigLoop,PredicatedScalarEvolution & PSE,LoopInfo * LI,DominatorTree * DT,const TargetLibraryInfo * TLI,const TargetTransformInfo * TTI,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,unsigned UnrollFactor,LoopVectorizationLegality * LVL,LoopVectorizationCostModel * CM,BlockFrequencyInfo * BFI,ProfileSummaryInfo * PSI,GeneratedRTChecks & Check)879 InnerLoopUnroller(Loop *OrigLoop, PredicatedScalarEvolution &PSE,
880 LoopInfo *LI, DominatorTree *DT,
881 const TargetLibraryInfo *TLI,
882 const TargetTransformInfo *TTI, AssumptionCache *AC,
883 OptimizationRemarkEmitter *ORE, unsigned UnrollFactor,
884 LoopVectorizationLegality *LVL,
885 LoopVectorizationCostModel *CM, BlockFrequencyInfo *BFI,
886 ProfileSummaryInfo *PSI, GeneratedRTChecks &Check)
887 : InnerLoopVectorizer(OrigLoop, PSE, LI, DT, TLI, TTI, AC, ORE,
888 ElementCount::getFixed(1), UnrollFactor, LVL, CM,
889 BFI, PSI, Check) {}
890
891 private:
892 Value *getBroadcastInstrs(Value *V) override;
893 Value *getStepVector(Value *Val, int StartIdx, Value *Step,
894 Instruction::BinaryOps Opcode =
895 Instruction::BinaryOpsEnd) override;
896 Value *reverseVector(Value *Vec) override;
897 };
898
899 /// Encapsulate information regarding vectorization of a loop and its epilogue.
900 /// This information is meant to be updated and used across two stages of
901 /// epilogue vectorization.
902 struct EpilogueLoopVectorizationInfo {
903 ElementCount MainLoopVF = ElementCount::getFixed(0);
904 unsigned MainLoopUF = 0;
905 ElementCount EpilogueVF = ElementCount::getFixed(0);
906 unsigned EpilogueUF = 0;
907 BasicBlock *MainLoopIterationCountCheck = nullptr;
908 BasicBlock *EpilogueIterationCountCheck = nullptr;
909 BasicBlock *SCEVSafetyCheck = nullptr;
910 BasicBlock *MemSafetyCheck = nullptr;
911 Value *TripCount = nullptr;
912 Value *VectorTripCount = nullptr;
913
EpilogueLoopVectorizationInfollvm::EpilogueLoopVectorizationInfo914 EpilogueLoopVectorizationInfo(unsigned MVF, unsigned MUF, unsigned EVF,
915 unsigned EUF)
916 : MainLoopVF(ElementCount::getFixed(MVF)), MainLoopUF(MUF),
917 EpilogueVF(ElementCount::getFixed(EVF)), EpilogueUF(EUF) {
918 assert(EUF == 1 &&
919 "A high UF for the epilogue loop is likely not beneficial.");
920 }
921 };
922
923 /// An extension of the inner loop vectorizer that creates a skeleton for a
924 /// vectorized loop that has its epilogue (residual) also vectorized.
925 /// The idea is to run the vplan on a given loop twice, firstly to setup the
926 /// skeleton and vectorize the main loop, and secondly to complete the skeleton
927 /// from the first step and vectorize the epilogue. This is achieved by
928 /// deriving two concrete strategy classes from this base class and invoking
929 /// them in succession from the loop vectorizer planner.
930 class InnerLoopAndEpilogueVectorizer : public InnerLoopVectorizer {
931 public:
InnerLoopAndEpilogueVectorizer(Loop * OrigLoop,PredicatedScalarEvolution & PSE,LoopInfo * LI,DominatorTree * DT,const TargetLibraryInfo * TLI,const TargetTransformInfo * TTI,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,EpilogueLoopVectorizationInfo & EPI,LoopVectorizationLegality * LVL,llvm::LoopVectorizationCostModel * CM,BlockFrequencyInfo * BFI,ProfileSummaryInfo * PSI,GeneratedRTChecks & Checks)932 InnerLoopAndEpilogueVectorizer(
933 Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI,
934 DominatorTree *DT, const TargetLibraryInfo *TLI,
935 const TargetTransformInfo *TTI, AssumptionCache *AC,
936 OptimizationRemarkEmitter *ORE, EpilogueLoopVectorizationInfo &EPI,
937 LoopVectorizationLegality *LVL, llvm::LoopVectorizationCostModel *CM,
938 BlockFrequencyInfo *BFI, ProfileSummaryInfo *PSI,
939 GeneratedRTChecks &Checks)
940 : InnerLoopVectorizer(OrigLoop, PSE, LI, DT, TLI, TTI, AC, ORE,
941 EPI.MainLoopVF, EPI.MainLoopUF, LVL, CM, BFI, PSI,
942 Checks),
943 EPI(EPI) {}
944
945 // Override this function to handle the more complex control flow around the
946 // three loops.
createVectorizedLoopSkeleton()947 BasicBlock *createVectorizedLoopSkeleton() final override {
948 return createEpilogueVectorizedLoopSkeleton();
949 }
950
951 /// The interface for creating a vectorized skeleton using one of two
952 /// different strategies, each corresponding to one execution of the vplan
953 /// as described above.
954 virtual BasicBlock *createEpilogueVectorizedLoopSkeleton() = 0;
955
956 /// Holds and updates state information required to vectorize the main loop
957 /// and its epilogue in two separate passes. This setup helps us avoid
958 /// regenerating and recomputing runtime safety checks. It also helps us to
959 /// shorten the iteration-count-check path length for the cases where the
960 /// iteration count of the loop is so small that the main vector loop is
961 /// completely skipped.
962 EpilogueLoopVectorizationInfo &EPI;
963 };
964
965 /// A specialized derived class of inner loop vectorizer that performs
966 /// vectorization of *main* loops in the process of vectorizing loops and their
967 /// epilogues.
968 class EpilogueVectorizerMainLoop : public InnerLoopAndEpilogueVectorizer {
969 public:
EpilogueVectorizerMainLoop(Loop * OrigLoop,PredicatedScalarEvolution & PSE,LoopInfo * LI,DominatorTree * DT,const TargetLibraryInfo * TLI,const TargetTransformInfo * TTI,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,EpilogueLoopVectorizationInfo & EPI,LoopVectorizationLegality * LVL,llvm::LoopVectorizationCostModel * CM,BlockFrequencyInfo * BFI,ProfileSummaryInfo * PSI,GeneratedRTChecks & Check)970 EpilogueVectorizerMainLoop(
971 Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI,
972 DominatorTree *DT, const TargetLibraryInfo *TLI,
973 const TargetTransformInfo *TTI, AssumptionCache *AC,
974 OptimizationRemarkEmitter *ORE, EpilogueLoopVectorizationInfo &EPI,
975 LoopVectorizationLegality *LVL, llvm::LoopVectorizationCostModel *CM,
976 BlockFrequencyInfo *BFI, ProfileSummaryInfo *PSI,
977 GeneratedRTChecks &Check)
978 : InnerLoopAndEpilogueVectorizer(OrigLoop, PSE, LI, DT, TLI, TTI, AC, ORE,
979 EPI, LVL, CM, BFI, PSI, Check) {}
980 /// Implements the interface for creating a vectorized skeleton using the
981 /// *main loop* strategy (ie the first pass of vplan execution).
982 BasicBlock *createEpilogueVectorizedLoopSkeleton() final override;
983
984 protected:
985 /// Emits an iteration count bypass check once for the main loop (when \p
986 /// ForEpilogue is false) and once for the epilogue loop (when \p
987 /// ForEpilogue is true).
988 BasicBlock *emitMinimumIterationCountCheck(Loop *L, BasicBlock *Bypass,
989 bool ForEpilogue);
990 void printDebugTracesAtStart() override;
991 void printDebugTracesAtEnd() override;
992 };
993
994 // A specialized derived class of inner loop vectorizer that performs
995 // vectorization of *epilogue* loops in the process of vectorizing loops and
996 // their epilogues.
997 class EpilogueVectorizerEpilogueLoop : public InnerLoopAndEpilogueVectorizer {
998 public:
EpilogueVectorizerEpilogueLoop(Loop * OrigLoop,PredicatedScalarEvolution & PSE,LoopInfo * LI,DominatorTree * DT,const TargetLibraryInfo * TLI,const TargetTransformInfo * TTI,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,EpilogueLoopVectorizationInfo & EPI,LoopVectorizationLegality * LVL,llvm::LoopVectorizationCostModel * CM,BlockFrequencyInfo * BFI,ProfileSummaryInfo * PSI,GeneratedRTChecks & Checks)999 EpilogueVectorizerEpilogueLoop(
1000 Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI,
1001 DominatorTree *DT, const TargetLibraryInfo *TLI,
1002 const TargetTransformInfo *TTI, AssumptionCache *AC,
1003 OptimizationRemarkEmitter *ORE, EpilogueLoopVectorizationInfo &EPI,
1004 LoopVectorizationLegality *LVL, llvm::LoopVectorizationCostModel *CM,
1005 BlockFrequencyInfo *BFI, ProfileSummaryInfo *PSI,
1006 GeneratedRTChecks &Checks)
1007 : InnerLoopAndEpilogueVectorizer(OrigLoop, PSE, LI, DT, TLI, TTI, AC, ORE,
1008 EPI, LVL, CM, BFI, PSI, Checks) {}
1009 /// Implements the interface for creating a vectorized skeleton using the
1010 /// *epilogue loop* strategy (ie the second pass of vplan execution).
1011 BasicBlock *createEpilogueVectorizedLoopSkeleton() final override;
1012
1013 protected:
1014 /// Emits an iteration count bypass check after the main vector loop has
1015 /// finished to see if there are any iterations left to execute by either
1016 /// the vector epilogue or the scalar epilogue.
1017 BasicBlock *emitMinimumVectorEpilogueIterCountCheck(Loop *L,
1018 BasicBlock *Bypass,
1019 BasicBlock *Insert);
1020 void printDebugTracesAtStart() override;
1021 void printDebugTracesAtEnd() override;
1022 };
1023 } // end namespace llvm
1024
1025 /// Look for a meaningful debug location on the instruction or it's
1026 /// operands.
getDebugLocFromInstOrOperands(Instruction * I)1027 static Instruction *getDebugLocFromInstOrOperands(Instruction *I) {
1028 if (!I)
1029 return I;
1030
1031 DebugLoc Empty;
1032 if (I->getDebugLoc() != Empty)
1033 return I;
1034
1035 for (Use &Op : I->operands()) {
1036 if (Instruction *OpInst = dyn_cast<Instruction>(Op))
1037 if (OpInst->getDebugLoc() != Empty)
1038 return OpInst;
1039 }
1040
1041 return I;
1042 }
1043
setDebugLocFromInst(const Value * V,Optional<IRBuilder<> * > CustomBuilder)1044 void InnerLoopVectorizer::setDebugLocFromInst(
1045 const Value *V, Optional<IRBuilder<> *> CustomBuilder) {
1046 IRBuilder<> *B = (CustomBuilder == None) ? &Builder : *CustomBuilder;
1047 if (const Instruction *Inst = dyn_cast_or_null<Instruction>(V)) {
1048 const DILocation *DIL = Inst->getDebugLoc();
1049
1050 // When a FSDiscriminator is enabled, we don't need to add the multiply
1051 // factors to the discriminators.
1052 if (DIL && Inst->getFunction()->isDebugInfoForProfiling() &&
1053 !isa<DbgInfoIntrinsic>(Inst) && !EnableFSDiscriminator) {
1054 // FIXME: For scalable vectors, assume vscale=1.
1055 auto NewDIL =
1056 DIL->cloneByMultiplyingDuplicationFactor(UF * VF.getKnownMinValue());
1057 if (NewDIL)
1058 B->SetCurrentDebugLocation(NewDIL.getValue());
1059 else
1060 LLVM_DEBUG(dbgs()
1061 << "Failed to create new discriminator: "
1062 << DIL->getFilename() << " Line: " << DIL->getLine());
1063 } else
1064 B->SetCurrentDebugLocation(DIL);
1065 } else
1066 B->SetCurrentDebugLocation(DebugLoc());
1067 }
1068
1069 /// Write a \p DebugMsg about vectorization to the debug output stream. If \p I
1070 /// is passed, the message relates to that particular instruction.
1071 #ifndef NDEBUG
debugVectorizationMessage(const StringRef Prefix,const StringRef DebugMsg,Instruction * I)1072 static void debugVectorizationMessage(const StringRef Prefix,
1073 const StringRef DebugMsg,
1074 Instruction *I) {
1075 dbgs() << "LV: " << Prefix << DebugMsg;
1076 if (I != nullptr)
1077 dbgs() << " " << *I;
1078 else
1079 dbgs() << '.';
1080 dbgs() << '\n';
1081 }
1082 #endif
1083
1084 /// Create an analysis remark that explains why vectorization failed
1085 ///
1086 /// \p PassName is the name of the pass (e.g. can be AlwaysPrint). \p
1087 /// RemarkName is the identifier for the remark. If \p I is passed it is an
1088 /// instruction that prevents vectorization. Otherwise \p TheLoop is used for
1089 /// the location of the remark. \return the remark object that can be
1090 /// streamed to.
createLVAnalysis(const char * PassName,StringRef RemarkName,Loop * TheLoop,Instruction * I)1091 static OptimizationRemarkAnalysis createLVAnalysis(const char *PassName,
1092 StringRef RemarkName, Loop *TheLoop, Instruction *I) {
1093 Value *CodeRegion = TheLoop->getHeader();
1094 DebugLoc DL = TheLoop->getStartLoc();
1095
1096 if (I) {
1097 CodeRegion = I->getParent();
1098 // If there is no debug location attached to the instruction, revert back to
1099 // using the loop's.
1100 if (I->getDebugLoc())
1101 DL = I->getDebugLoc();
1102 }
1103
1104 return OptimizationRemarkAnalysis(PassName, RemarkName, DL, CodeRegion);
1105 }
1106
1107 /// Return a value for Step multiplied by VF.
createStepForVF(IRBuilder<> & B,Constant * Step,ElementCount VF)1108 static Value *createStepForVF(IRBuilder<> &B, Constant *Step, ElementCount VF) {
1109 assert(isa<ConstantInt>(Step) && "Expected an integer step");
1110 Constant *StepVal = ConstantInt::get(
1111 Step->getType(),
1112 cast<ConstantInt>(Step)->getSExtValue() * VF.getKnownMinValue());
1113 return VF.isScalable() ? B.CreateVScale(StepVal) : StepVal;
1114 }
1115
1116 namespace llvm {
1117
1118 /// Return the runtime value for VF.
getRuntimeVF(IRBuilder<> & B,Type * Ty,ElementCount VF)1119 Value *getRuntimeVF(IRBuilder<> &B, Type *Ty, ElementCount VF) {
1120 Constant *EC = ConstantInt::get(Ty, VF.getKnownMinValue());
1121 return VF.isScalable() ? B.CreateVScale(EC) : EC;
1122 }
1123
reportVectorizationFailure(const StringRef DebugMsg,const StringRef OREMsg,const StringRef ORETag,OptimizationRemarkEmitter * ORE,Loop * TheLoop,Instruction * I)1124 void reportVectorizationFailure(const StringRef DebugMsg,
1125 const StringRef OREMsg, const StringRef ORETag,
1126 OptimizationRemarkEmitter *ORE, Loop *TheLoop,
1127 Instruction *I) {
1128 LLVM_DEBUG(debugVectorizationMessage("Not vectorizing: ", DebugMsg, I));
1129 LoopVectorizeHints Hints(TheLoop, true /* doesn't matter */, *ORE);
1130 ORE->emit(
1131 createLVAnalysis(Hints.vectorizeAnalysisPassName(), ORETag, TheLoop, I)
1132 << "loop not vectorized: " << OREMsg);
1133 }
1134
reportVectorizationInfo(const StringRef Msg,const StringRef ORETag,OptimizationRemarkEmitter * ORE,Loop * TheLoop,Instruction * I)1135 void reportVectorizationInfo(const StringRef Msg, const StringRef ORETag,
1136 OptimizationRemarkEmitter *ORE, Loop *TheLoop,
1137 Instruction *I) {
1138 LLVM_DEBUG(debugVectorizationMessage("", Msg, I));
1139 LoopVectorizeHints Hints(TheLoop, true /* doesn't matter */, *ORE);
1140 ORE->emit(
1141 createLVAnalysis(Hints.vectorizeAnalysisPassName(), ORETag, TheLoop, I)
1142 << Msg);
1143 }
1144
1145 } // end namespace llvm
1146
1147 #ifndef NDEBUG
1148 /// \return string containing a file name and a line # for the given loop.
getDebugLocString(const Loop * L)1149 static std::string getDebugLocString(const Loop *L) {
1150 std::string Result;
1151 if (L) {
1152 raw_string_ostream OS(Result);
1153 if (const DebugLoc LoopDbgLoc = L->getStartLoc())
1154 LoopDbgLoc.print(OS);
1155 else
1156 // Just print the module name.
1157 OS << L->getHeader()->getParent()->getParent()->getModuleIdentifier();
1158 OS.flush();
1159 }
1160 return Result;
1161 }
1162 #endif
1163
addNewMetadata(Instruction * To,const Instruction * Orig)1164 void InnerLoopVectorizer::addNewMetadata(Instruction *To,
1165 const Instruction *Orig) {
1166 // If the loop was versioned with memchecks, add the corresponding no-alias
1167 // metadata.
1168 if (LVer && (isa<LoadInst>(Orig) || isa<StoreInst>(Orig)))
1169 LVer->annotateInstWithNoAlias(To, Orig);
1170 }
1171
addMetadata(Instruction * To,Instruction * From)1172 void InnerLoopVectorizer::addMetadata(Instruction *To,
1173 Instruction *From) {
1174 propagateMetadata(To, From);
1175 addNewMetadata(To, From);
1176 }
1177
addMetadata(ArrayRef<Value * > To,Instruction * From)1178 void InnerLoopVectorizer::addMetadata(ArrayRef<Value *> To,
1179 Instruction *From) {
1180 for (Value *V : To) {
1181 if (Instruction *I = dyn_cast<Instruction>(V))
1182 addMetadata(I, From);
1183 }
1184 }
1185
1186 namespace llvm {
1187
1188 // Loop vectorization cost-model hints how the scalar epilogue loop should be
1189 // lowered.
1190 enum ScalarEpilogueLowering {
1191
1192 // The default: allowing scalar epilogues.
1193 CM_ScalarEpilogueAllowed,
1194
1195 // Vectorization with OptForSize: don't allow epilogues.
1196 CM_ScalarEpilogueNotAllowedOptSize,
1197
1198 // A special case of vectorisation with OptForSize: loops with a very small
1199 // trip count are considered for vectorization under OptForSize, thereby
1200 // making sure the cost of their loop body is dominant, free of runtime
1201 // guards and scalar iteration overheads.
1202 CM_ScalarEpilogueNotAllowedLowTripLoop,
1203
1204 // Loop hint predicate indicating an epilogue is undesired.
1205 CM_ScalarEpilogueNotNeededUsePredicate,
1206
1207 // Directive indicating we must either tail fold or not vectorize
1208 CM_ScalarEpilogueNotAllowedUsePredicate
1209 };
1210
1211 /// ElementCountComparator creates a total ordering for ElementCount
1212 /// for the purposes of using it in a set structure.
1213 struct ElementCountComparator {
operator ()llvm::ElementCountComparator1214 bool operator()(const ElementCount &LHS, const ElementCount &RHS) const {
1215 return std::make_tuple(LHS.isScalable(), LHS.getKnownMinValue()) <
1216 std::make_tuple(RHS.isScalable(), RHS.getKnownMinValue());
1217 }
1218 };
1219 using ElementCountSet = SmallSet<ElementCount, 16, ElementCountComparator>;
1220
1221 /// LoopVectorizationCostModel - estimates the expected speedups due to
1222 /// vectorization.
1223 /// In many cases vectorization is not profitable. This can happen because of
1224 /// a number of reasons. In this class we mainly attempt to predict the
1225 /// expected speedup/slowdowns due to the supported instruction set. We use the
1226 /// TargetTransformInfo to query the different backends for the cost of
1227 /// different operations.
1228 class LoopVectorizationCostModel {
1229 public:
LoopVectorizationCostModel(ScalarEpilogueLowering SEL,Loop * L,PredicatedScalarEvolution & PSE,LoopInfo * LI,LoopVectorizationLegality * Legal,const TargetTransformInfo & TTI,const TargetLibraryInfo * TLI,DemandedBits * DB,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,const Function * F,const LoopVectorizeHints * Hints,InterleavedAccessInfo & IAI)1230 LoopVectorizationCostModel(ScalarEpilogueLowering SEL, Loop *L,
1231 PredicatedScalarEvolution &PSE, LoopInfo *LI,
1232 LoopVectorizationLegality *Legal,
1233 const TargetTransformInfo &TTI,
1234 const TargetLibraryInfo *TLI, DemandedBits *DB,
1235 AssumptionCache *AC,
1236 OptimizationRemarkEmitter *ORE, const Function *F,
1237 const LoopVectorizeHints *Hints,
1238 InterleavedAccessInfo &IAI)
1239 : ScalarEpilogueStatus(SEL), TheLoop(L), PSE(PSE), LI(LI), Legal(Legal),
1240 TTI(TTI), TLI(TLI), DB(DB), AC(AC), ORE(ORE), TheFunction(F),
1241 Hints(Hints), InterleaveInfo(IAI) {}
1242
1243 /// \return An upper bound for the vectorization factors (both fixed and
1244 /// scalable). If the factors are 0, vectorization and interleaving should be
1245 /// avoided up front.
1246 FixedScalableVFPair computeMaxVF(ElementCount UserVF, unsigned UserIC);
1247
1248 /// \return True if runtime checks are required for vectorization, and false
1249 /// otherwise.
1250 bool runtimeChecksRequired();
1251
1252 /// \return The most profitable vectorization factor and the cost of that VF.
1253 /// This method checks every VF in \p CandidateVFs. If UserVF is not ZERO
1254 /// then this vectorization factor will be selected if vectorization is
1255 /// possible.
1256 VectorizationFactor
1257 selectVectorizationFactor(const ElementCountSet &CandidateVFs);
1258
1259 VectorizationFactor
1260 selectEpilogueVectorizationFactor(const ElementCount MaxVF,
1261 const LoopVectorizationPlanner &LVP);
1262
1263 /// Setup cost-based decisions for user vectorization factor.
1264 /// \return true if the UserVF is a feasible VF to be chosen.
selectUserVectorizationFactor(ElementCount UserVF)1265 bool selectUserVectorizationFactor(ElementCount UserVF) {
1266 collectUniformsAndScalars(UserVF);
1267 collectInstsToScalarize(UserVF);
1268 return expectedCost(UserVF).first.isValid();
1269 }
1270
1271 /// \return The size (in bits) of the smallest and widest types in the code
1272 /// that needs to be vectorized. We ignore values that remain scalar such as
1273 /// 64 bit loop indices.
1274 std::pair<unsigned, unsigned> getSmallestAndWidestTypes();
1275
1276 /// \return The desired interleave count.
1277 /// If interleave count has been specified by metadata it will be returned.
1278 /// Otherwise, the interleave count is computed and returned. VF and LoopCost
1279 /// are the selected vectorization factor and the cost of the selected VF.
1280 unsigned selectInterleaveCount(ElementCount VF, unsigned LoopCost);
1281
1282 /// Memory access instruction may be vectorized in more than one way.
1283 /// Form of instruction after vectorization depends on cost.
1284 /// This function takes cost-based decisions for Load/Store instructions
1285 /// and collects them in a map. This decisions map is used for building
1286 /// the lists of loop-uniform and loop-scalar instructions.
1287 /// The calculated cost is saved with widening decision in order to
1288 /// avoid redundant calculations.
1289 void setCostBasedWideningDecision(ElementCount VF);
1290
1291 /// A struct that represents some properties of the register usage
1292 /// of a loop.
1293 struct RegisterUsage {
1294 /// Holds the number of loop invariant values that are used in the loop.
1295 /// The key is ClassID of target-provided register class.
1296 SmallMapVector<unsigned, unsigned, 4> LoopInvariantRegs;
1297 /// Holds the maximum number of concurrent live intervals in the loop.
1298 /// The key is ClassID of target-provided register class.
1299 SmallMapVector<unsigned, unsigned, 4> MaxLocalUsers;
1300 };
1301
1302 /// \return Returns information about the register usages of the loop for the
1303 /// given vectorization factors.
1304 SmallVector<RegisterUsage, 8>
1305 calculateRegisterUsage(ArrayRef<ElementCount> VFs);
1306
1307 /// Collect values we want to ignore in the cost model.
1308 void collectValuesToIgnore();
1309
1310 /// Collect all element types in the loop for which widening is needed.
1311 void collectElementTypesForWidening();
1312
1313 /// Split reductions into those that happen in the loop, and those that happen
1314 /// outside. In loop reductions are collected into InLoopReductionChains.
1315 void collectInLoopReductions();
1316
1317 /// Returns true if we should use strict in-order reductions for the given
1318 /// RdxDesc. This is true if the -enable-strict-reductions flag is passed,
1319 /// the IsOrdered flag of RdxDesc is set and we do not allow reordering
1320 /// of FP operations.
useOrderedReductions(const RecurrenceDescriptor & RdxDesc)1321 bool useOrderedReductions(const RecurrenceDescriptor &RdxDesc) {
1322 return EnableStrictReductions && !Hints->allowReordering() &&
1323 RdxDesc.isOrdered();
1324 }
1325
1326 /// \returns The smallest bitwidth each instruction can be represented with.
1327 /// The vector equivalents of these instructions should be truncated to this
1328 /// type.
getMinimalBitwidths() const1329 const MapVector<Instruction *, uint64_t> &getMinimalBitwidths() const {
1330 return MinBWs;
1331 }
1332
1333 /// \returns True if it is more profitable to scalarize instruction \p I for
1334 /// vectorization factor \p VF.
isProfitableToScalarize(Instruction * I,ElementCount VF) const1335 bool isProfitableToScalarize(Instruction *I, ElementCount VF) const {
1336 assert(VF.isVector() &&
1337 "Profitable to scalarize relevant only for VF > 1.");
1338
1339 // Cost model is not run in the VPlan-native path - return conservative
1340 // result until this changes.
1341 if (EnableVPlanNativePath)
1342 return false;
1343
1344 auto Scalars = InstsToScalarize.find(VF);
1345 assert(Scalars != InstsToScalarize.end() &&
1346 "VF not yet analyzed for scalarization profitability");
1347 return Scalars->second.find(I) != Scalars->second.end();
1348 }
1349
1350 /// Returns true if \p I is known to be uniform after vectorization.
isUniformAfterVectorization(Instruction * I,ElementCount VF) const1351 bool isUniformAfterVectorization(Instruction *I, ElementCount VF) const {
1352 if (VF.isScalar())
1353 return true;
1354
1355 // Cost model is not run in the VPlan-native path - return conservative
1356 // result until this changes.
1357 if (EnableVPlanNativePath)
1358 return false;
1359
1360 auto UniformsPerVF = Uniforms.find(VF);
1361 assert(UniformsPerVF != Uniforms.end() &&
1362 "VF not yet analyzed for uniformity");
1363 return UniformsPerVF->second.count(I);
1364 }
1365
1366 /// Returns true if \p I is known to be scalar after vectorization.
isScalarAfterVectorization(Instruction * I,ElementCount VF) const1367 bool isScalarAfterVectorization(Instruction *I, ElementCount VF) const {
1368 if (VF.isScalar())
1369 return true;
1370
1371 // Cost model is not run in the VPlan-native path - return conservative
1372 // result until this changes.
1373 if (EnableVPlanNativePath)
1374 return false;
1375
1376 auto ScalarsPerVF = Scalars.find(VF);
1377 assert(ScalarsPerVF != Scalars.end() &&
1378 "Scalar values are not calculated for VF");
1379 return ScalarsPerVF->second.count(I);
1380 }
1381
1382 /// \returns True if instruction \p I can be truncated to a smaller bitwidth
1383 /// for vectorization factor \p VF.
canTruncateToMinimalBitwidth(Instruction * I,ElementCount VF) const1384 bool canTruncateToMinimalBitwidth(Instruction *I, ElementCount VF) const {
1385 return VF.isVector() && MinBWs.find(I) != MinBWs.end() &&
1386 !isProfitableToScalarize(I, VF) &&
1387 !isScalarAfterVectorization(I, VF);
1388 }
1389
1390 /// Decision that was taken during cost calculation for memory instruction.
1391 enum InstWidening {
1392 CM_Unknown,
1393 CM_Widen, // For consecutive accesses with stride +1.
1394 CM_Widen_Reverse, // For consecutive accesses with stride -1.
1395 CM_Interleave,
1396 CM_GatherScatter,
1397 CM_Scalarize
1398 };
1399
1400 /// Save vectorization decision \p W and \p Cost taken by the cost model for
1401 /// instruction \p I and vector width \p VF.
setWideningDecision(Instruction * I,ElementCount VF,InstWidening W,InstructionCost Cost)1402 void setWideningDecision(Instruction *I, ElementCount VF, InstWidening W,
1403 InstructionCost Cost) {
1404 assert(VF.isVector() && "Expected VF >=2");
1405 WideningDecisions[std::make_pair(I, VF)] = std::make_pair(W, Cost);
1406 }
1407
1408 /// Save vectorization decision \p W and \p Cost taken by the cost model for
1409 /// interleaving group \p Grp and vector width \p VF.
setWideningDecision(const InterleaveGroup<Instruction> * Grp,ElementCount VF,InstWidening W,InstructionCost Cost)1410 void setWideningDecision(const InterleaveGroup<Instruction> *Grp,
1411 ElementCount VF, InstWidening W,
1412 InstructionCost Cost) {
1413 assert(VF.isVector() && "Expected VF >=2");
1414 /// Broadcast this decicion to all instructions inside the group.
1415 /// But the cost will be assigned to one instruction only.
1416 for (unsigned i = 0; i < Grp->getFactor(); ++i) {
1417 if (auto *I = Grp->getMember(i)) {
1418 if (Grp->getInsertPos() == I)
1419 WideningDecisions[std::make_pair(I, VF)] = std::make_pair(W, Cost);
1420 else
1421 WideningDecisions[std::make_pair(I, VF)] = std::make_pair(W, 0);
1422 }
1423 }
1424 }
1425
1426 /// Return the cost model decision for the given instruction \p I and vector
1427 /// width \p VF. Return CM_Unknown if this instruction did not pass
1428 /// through the cost modeling.
getWideningDecision(Instruction * I,ElementCount VF) const1429 InstWidening getWideningDecision(Instruction *I, ElementCount VF) const {
1430 assert(VF.isVector() && "Expected VF to be a vector VF");
1431 // Cost model is not run in the VPlan-native path - return conservative
1432 // result until this changes.
1433 if (EnableVPlanNativePath)
1434 return CM_GatherScatter;
1435
1436 std::pair<Instruction *, ElementCount> InstOnVF = std::make_pair(I, VF);
1437 auto Itr = WideningDecisions.find(InstOnVF);
1438 if (Itr == WideningDecisions.end())
1439 return CM_Unknown;
1440 return Itr->second.first;
1441 }
1442
1443 /// Return the vectorization cost for the given instruction \p I and vector
1444 /// width \p VF.
getWideningCost(Instruction * I,ElementCount VF)1445 InstructionCost getWideningCost(Instruction *I, ElementCount VF) {
1446 assert(VF.isVector() && "Expected VF >=2");
1447 std::pair<Instruction *, ElementCount> InstOnVF = std::make_pair(I, VF);
1448 assert(WideningDecisions.find(InstOnVF) != WideningDecisions.end() &&
1449 "The cost is not calculated");
1450 return WideningDecisions[InstOnVF].second;
1451 }
1452
1453 /// Return True if instruction \p I is an optimizable truncate whose operand
1454 /// is an induction variable. Such a truncate will be removed by adding a new
1455 /// induction variable with the destination type.
isOptimizableIVTruncate(Instruction * I,ElementCount VF)1456 bool isOptimizableIVTruncate(Instruction *I, ElementCount VF) {
1457 // If the instruction is not a truncate, return false.
1458 auto *Trunc = dyn_cast<TruncInst>(I);
1459 if (!Trunc)
1460 return false;
1461
1462 // Get the source and destination types of the truncate.
1463 Type *SrcTy = ToVectorTy(cast<CastInst>(I)->getSrcTy(), VF);
1464 Type *DestTy = ToVectorTy(cast<CastInst>(I)->getDestTy(), VF);
1465
1466 // If the truncate is free for the given types, return false. Replacing a
1467 // free truncate with an induction variable would add an induction variable
1468 // update instruction to each iteration of the loop. We exclude from this
1469 // check the primary induction variable since it will need an update
1470 // instruction regardless.
1471 Value *Op = Trunc->getOperand(0);
1472 if (Op != Legal->getPrimaryInduction() && TTI.isTruncateFree(SrcTy, DestTy))
1473 return false;
1474
1475 // If the truncated value is not an induction variable, return false.
1476 return Legal->isInductionPhi(Op);
1477 }
1478
1479 /// Collects the instructions to scalarize for each predicated instruction in
1480 /// the loop.
1481 void collectInstsToScalarize(ElementCount VF);
1482
1483 /// Collect Uniform and Scalar values for the given \p VF.
1484 /// The sets depend on CM decision for Load/Store instructions
1485 /// that may be vectorized as interleave, gather-scatter or scalarized.
collectUniformsAndScalars(ElementCount VF)1486 void collectUniformsAndScalars(ElementCount VF) {
1487 // Do the analysis once.
1488 if (VF.isScalar() || Uniforms.find(VF) != Uniforms.end())
1489 return;
1490 setCostBasedWideningDecision(VF);
1491 collectLoopUniforms(VF);
1492 collectLoopScalars(VF);
1493 }
1494
1495 /// Returns true if the target machine supports masked store operation
1496 /// for the given \p DataType and kind of access to \p Ptr.
isLegalMaskedStore(Type * DataType,Value * Ptr,Align Alignment) const1497 bool isLegalMaskedStore(Type *DataType, Value *Ptr, Align Alignment) const {
1498 return Legal->isConsecutivePtr(Ptr) &&
1499 TTI.isLegalMaskedStore(DataType, Alignment);
1500 }
1501
1502 /// Returns true if the target machine supports masked load operation
1503 /// for the given \p DataType and kind of access to \p Ptr.
isLegalMaskedLoad(Type * DataType,Value * Ptr,Align Alignment) const1504 bool isLegalMaskedLoad(Type *DataType, Value *Ptr, Align Alignment) const {
1505 return Legal->isConsecutivePtr(Ptr) &&
1506 TTI.isLegalMaskedLoad(DataType, Alignment);
1507 }
1508
1509 /// Returns true if the target machine can represent \p V as a masked gather
1510 /// or scatter operation.
isLegalGatherOrScatter(Value * V)1511 bool isLegalGatherOrScatter(Value *V) {
1512 bool LI = isa<LoadInst>(V);
1513 bool SI = isa<StoreInst>(V);
1514 if (!LI && !SI)
1515 return false;
1516 auto *Ty = getLoadStoreType(V);
1517 Align Align = getLoadStoreAlignment(V);
1518 return (LI && TTI.isLegalMaskedGather(Ty, Align)) ||
1519 (SI && TTI.isLegalMaskedScatter(Ty, Align));
1520 }
1521
1522 /// Returns true if the target machine supports all of the reduction
1523 /// variables found for the given VF.
canVectorizeReductions(ElementCount VF) const1524 bool canVectorizeReductions(ElementCount VF) const {
1525 return (all_of(Legal->getReductionVars(), [&](auto &Reduction) -> bool {
1526 const RecurrenceDescriptor &RdxDesc = Reduction.second;
1527 return TTI.isLegalToVectorizeReduction(RdxDesc, VF);
1528 }));
1529 }
1530
1531 /// Returns true if \p I is an instruction that will be scalarized with
1532 /// predication. Such instructions include conditional stores and
1533 /// instructions that may divide by zero.
1534 /// If a non-zero VF has been calculated, we check if I will be scalarized
1535 /// predication for that VF.
1536 bool isScalarWithPredication(Instruction *I) const;
1537
1538 // Returns true if \p I is an instruction that will be predicated either
1539 // through scalar predication or masked load/store or masked gather/scatter.
1540 // Superset of instructions that return true for isScalarWithPredication.
isPredicatedInst(Instruction * I)1541 bool isPredicatedInst(Instruction *I) {
1542 if (!blockNeedsPredication(I->getParent()))
1543 return false;
1544 // Loads and stores that need some form of masked operation are predicated
1545 // instructions.
1546 if (isa<LoadInst>(I) || isa<StoreInst>(I))
1547 return Legal->isMaskRequired(I);
1548 return isScalarWithPredication(I);
1549 }
1550
1551 /// Returns true if \p I is a memory instruction with consecutive memory
1552 /// access that can be widened.
1553 bool
1554 memoryInstructionCanBeWidened(Instruction *I,
1555 ElementCount VF = ElementCount::getFixed(1));
1556
1557 /// Returns true if \p I is a memory instruction in an interleaved-group
1558 /// of memory accesses that can be vectorized with wide vector loads/stores
1559 /// and shuffles.
1560 bool
1561 interleavedAccessCanBeWidened(Instruction *I,
1562 ElementCount VF = ElementCount::getFixed(1));
1563
1564 /// Check if \p Instr belongs to any interleaved access group.
isAccessInterleaved(Instruction * Instr)1565 bool isAccessInterleaved(Instruction *Instr) {
1566 return InterleaveInfo.isInterleaved(Instr);
1567 }
1568
1569 /// Get the interleaved access group that \p Instr belongs to.
1570 const InterleaveGroup<Instruction> *
getInterleavedAccessGroup(Instruction * Instr)1571 getInterleavedAccessGroup(Instruction *Instr) {
1572 return InterleaveInfo.getInterleaveGroup(Instr);
1573 }
1574
1575 /// Returns true if we're required to use a scalar epilogue for at least
1576 /// the final iteration of the original loop.
requiresScalarEpilogue(ElementCount VF) const1577 bool requiresScalarEpilogue(ElementCount VF) const {
1578 if (!isScalarEpilogueAllowed())
1579 return false;
1580 // If we might exit from anywhere but the latch, must run the exiting
1581 // iteration in scalar form.
1582 if (TheLoop->getExitingBlock() != TheLoop->getLoopLatch())
1583 return true;
1584 return VF.isVector() && InterleaveInfo.requiresScalarEpilogue();
1585 }
1586
1587 /// Returns true if a scalar epilogue is not allowed due to optsize or a
1588 /// loop hint annotation.
isScalarEpilogueAllowed() const1589 bool isScalarEpilogueAllowed() const {
1590 return ScalarEpilogueStatus == CM_ScalarEpilogueAllowed;
1591 }
1592
1593 /// Returns true if all loop blocks should be masked to fold tail loop.
foldTailByMasking() const1594 bool foldTailByMasking() const { return FoldTailByMasking; }
1595
blockNeedsPredication(BasicBlock * BB) const1596 bool blockNeedsPredication(BasicBlock *BB) const {
1597 return foldTailByMasking() || Legal->blockNeedsPredication(BB);
1598 }
1599
1600 /// A SmallMapVector to store the InLoop reduction op chains, mapping phi
1601 /// nodes to the chain of instructions representing the reductions. Uses a
1602 /// MapVector to ensure deterministic iteration order.
1603 using ReductionChainMap =
1604 SmallMapVector<PHINode *, SmallVector<Instruction *, 4>, 4>;
1605
1606 /// Return the chain of instructions representing an inloop reduction.
getInLoopReductionChains() const1607 const ReductionChainMap &getInLoopReductionChains() const {
1608 return InLoopReductionChains;
1609 }
1610
1611 /// Returns true if the Phi is part of an inloop reduction.
isInLoopReduction(PHINode * Phi) const1612 bool isInLoopReduction(PHINode *Phi) const {
1613 return InLoopReductionChains.count(Phi);
1614 }
1615
1616 /// Estimate cost of an intrinsic call instruction CI if it were vectorized
1617 /// with factor VF. Return the cost of the instruction, including
1618 /// scalarization overhead if it's needed.
1619 InstructionCost getVectorIntrinsicCost(CallInst *CI, ElementCount VF) const;
1620
1621 /// Estimate cost of a call instruction CI if it were vectorized with factor
1622 /// VF. Return the cost of the instruction, including scalarization overhead
1623 /// if it's needed. The flag NeedToScalarize shows if the call needs to be
1624 /// scalarized -
1625 /// i.e. either vector version isn't available, or is too expensive.
1626 InstructionCost getVectorCallCost(CallInst *CI, ElementCount VF,
1627 bool &NeedToScalarize) const;
1628
1629 /// Returns true if the per-lane cost of VectorizationFactor A is lower than
1630 /// that of B.
1631 bool isMoreProfitable(const VectorizationFactor &A,
1632 const VectorizationFactor &B) const;
1633
1634 /// Invalidates decisions already taken by the cost model.
invalidateCostModelingDecisions()1635 void invalidateCostModelingDecisions() {
1636 WideningDecisions.clear();
1637 Uniforms.clear();
1638 Scalars.clear();
1639 }
1640
1641 private:
1642 unsigned NumPredStores = 0;
1643
1644 /// \return An upper bound for the vectorization factors for both
1645 /// fixed and scalable vectorization, where the minimum-known number of
1646 /// elements is a power-of-2 larger than zero. If scalable vectorization is
1647 /// disabled or unsupported, then the scalable part will be equal to
1648 /// ElementCount::getScalable(0).
1649 FixedScalableVFPair computeFeasibleMaxVF(unsigned ConstTripCount,
1650 ElementCount UserVF);
1651
1652 /// \return the maximized element count based on the targets vector
1653 /// registers and the loop trip-count, but limited to a maximum safe VF.
1654 /// This is a helper function of computeFeasibleMaxVF.
1655 /// FIXME: MaxSafeVF is currently passed by reference to avoid some obscure
1656 /// issue that occurred on one of the buildbots which cannot be reproduced
1657 /// without having access to the properietary compiler (see comments on
1658 /// D98509). The issue is currently under investigation and this workaround
1659 /// will be removed as soon as possible.
1660 ElementCount getMaximizedVFForTarget(unsigned ConstTripCount,
1661 unsigned SmallestType,
1662 unsigned WidestType,
1663 const ElementCount &MaxSafeVF);
1664
1665 /// \return the maximum legal scalable VF, based on the safe max number
1666 /// of elements.
1667 ElementCount getMaxLegalScalableVF(unsigned MaxSafeElements);
1668
1669 /// The vectorization cost is a combination of the cost itself and a boolean
1670 /// indicating whether any of the contributing operations will actually
1671 /// operate on vector values after type legalization in the backend. If this
1672 /// latter value is false, then all operations will be scalarized (i.e. no
1673 /// vectorization has actually taken place).
1674 using VectorizationCostTy = std::pair<InstructionCost, bool>;
1675
1676 /// Returns the expected execution cost. The unit of the cost does
1677 /// not matter because we use the 'cost' units to compare different
1678 /// vector widths. The cost that is returned is *not* normalized by
1679 /// the factor width. If \p Invalid is not nullptr, this function
1680 /// will add a pair(Instruction*, ElementCount) to \p Invalid for
1681 /// each instruction that has an Invalid cost for the given VF.
1682 using InstructionVFPair = std::pair<Instruction *, ElementCount>;
1683 VectorizationCostTy
1684 expectedCost(ElementCount VF,
1685 SmallVectorImpl<InstructionVFPair> *Invalid = nullptr);
1686
1687 /// Returns the execution time cost of an instruction for a given vector
1688 /// width. Vector width of one means scalar.
1689 VectorizationCostTy getInstructionCost(Instruction *I, ElementCount VF);
1690
1691 /// The cost-computation logic from getInstructionCost which provides
1692 /// the vector type as an output parameter.
1693 InstructionCost getInstructionCost(Instruction *I, ElementCount VF,
1694 Type *&VectorTy);
1695
1696 /// Return the cost of instructions in an inloop reduction pattern, if I is
1697 /// part of that pattern.
1698 Optional<InstructionCost>
1699 getReductionPatternCost(Instruction *I, ElementCount VF, Type *VectorTy,
1700 TTI::TargetCostKind CostKind);
1701
1702 /// Calculate vectorization cost of memory instruction \p I.
1703 InstructionCost getMemoryInstructionCost(Instruction *I, ElementCount VF);
1704
1705 /// The cost computation for scalarized memory instruction.
1706 InstructionCost getMemInstScalarizationCost(Instruction *I, ElementCount VF);
1707
1708 /// The cost computation for interleaving group of memory instructions.
1709 InstructionCost getInterleaveGroupCost(Instruction *I, ElementCount VF);
1710
1711 /// The cost computation for Gather/Scatter instruction.
1712 InstructionCost getGatherScatterCost(Instruction *I, ElementCount VF);
1713
1714 /// The cost computation for widening instruction \p I with consecutive
1715 /// memory access.
1716 InstructionCost getConsecutiveMemOpCost(Instruction *I, ElementCount VF);
1717
1718 /// The cost calculation for Load/Store instruction \p I with uniform pointer -
1719 /// Load: scalar load + broadcast.
1720 /// Store: scalar store + (loop invariant value stored? 0 : extract of last
1721 /// element)
1722 InstructionCost getUniformMemOpCost(Instruction *I, ElementCount VF);
1723
1724 /// Estimate the overhead of scalarizing an instruction. This is a
1725 /// convenience wrapper for the type-based getScalarizationOverhead API.
1726 InstructionCost getScalarizationOverhead(Instruction *I,
1727 ElementCount VF) const;
1728
1729 /// Returns whether the instruction is a load or store and will be a emitted
1730 /// as a vector operation.
1731 bool isConsecutiveLoadOrStore(Instruction *I);
1732
1733 /// Returns true if an artificially high cost for emulated masked memrefs
1734 /// should be used.
1735 bool useEmulatedMaskMemRefHack(Instruction *I);
1736
1737 /// Map of scalar integer values to the smallest bitwidth they can be legally
1738 /// represented as. The vector equivalents of these values should be truncated
1739 /// to this type.
1740 MapVector<Instruction *, uint64_t> MinBWs;
1741
1742 /// A type representing the costs for instructions if they were to be
1743 /// scalarized rather than vectorized. The entries are Instruction-Cost
1744 /// pairs.
1745 using ScalarCostsTy = DenseMap<Instruction *, InstructionCost>;
1746
1747 /// A set containing all BasicBlocks that are known to present after
1748 /// vectorization as a predicated block.
1749 SmallPtrSet<BasicBlock *, 4> PredicatedBBsAfterVectorization;
1750
1751 /// Records whether it is allowed to have the original scalar loop execute at
1752 /// least once. This may be needed as a fallback loop in case runtime
1753 /// aliasing/dependence checks fail, or to handle the tail/remainder
1754 /// iterations when the trip count is unknown or doesn't divide by the VF,
1755 /// or as a peel-loop to handle gaps in interleave-groups.
1756 /// Under optsize and when the trip count is very small we don't allow any
1757 /// iterations to execute in the scalar loop.
1758 ScalarEpilogueLowering ScalarEpilogueStatus = CM_ScalarEpilogueAllowed;
1759
1760 /// All blocks of loop are to be masked to fold tail of scalar iterations.
1761 bool FoldTailByMasking = false;
1762
1763 /// A map holding scalar costs for different vectorization factors. The
1764 /// presence of a cost for an instruction in the mapping indicates that the
1765 /// instruction will be scalarized when vectorizing with the associated
1766 /// vectorization factor. The entries are VF-ScalarCostTy pairs.
1767 DenseMap<ElementCount, ScalarCostsTy> InstsToScalarize;
1768
1769 /// Holds the instructions known to be uniform after vectorization.
1770 /// The data is collected per VF.
1771 DenseMap<ElementCount, SmallPtrSet<Instruction *, 4>> Uniforms;
1772
1773 /// Holds the instructions known to be scalar after vectorization.
1774 /// The data is collected per VF.
1775 DenseMap<ElementCount, SmallPtrSet<Instruction *, 4>> Scalars;
1776
1777 /// Holds the instructions (address computations) that are forced to be
1778 /// scalarized.
1779 DenseMap<ElementCount, SmallPtrSet<Instruction *, 4>> ForcedScalars;
1780
1781 /// PHINodes of the reductions that should be expanded in-loop along with
1782 /// their associated chains of reduction operations, in program order from top
1783 /// (PHI) to bottom
1784 ReductionChainMap InLoopReductionChains;
1785
1786 /// A Map of inloop reduction operations and their immediate chain operand.
1787 /// FIXME: This can be removed once reductions can be costed correctly in
1788 /// vplan. This was added to allow quick lookup to the inloop operations,
1789 /// without having to loop through InLoopReductionChains.
1790 DenseMap<Instruction *, Instruction *> InLoopReductionImmediateChains;
1791
1792 /// Returns the expected difference in cost from scalarizing the expression
1793 /// feeding a predicated instruction \p PredInst. The instructions to
1794 /// scalarize and their scalar costs are collected in \p ScalarCosts. A
1795 /// non-negative return value implies the expression will be scalarized.
1796 /// Currently, only single-use chains are considered for scalarization.
1797 int computePredInstDiscount(Instruction *PredInst, ScalarCostsTy &ScalarCosts,
1798 ElementCount VF);
1799
1800 /// Collect the instructions that are uniform after vectorization. An
1801 /// instruction is uniform if we represent it with a single scalar value in
1802 /// the vectorized loop corresponding to each vector iteration. Examples of
1803 /// uniform instructions include pointer operands of consecutive or
1804 /// interleaved memory accesses. Note that although uniformity implies an
1805 /// instruction will be scalar, the reverse is not true. In general, a
1806 /// scalarized instruction will be represented by VF scalar values in the
1807 /// vectorized loop, each corresponding to an iteration of the original
1808 /// scalar loop.
1809 void collectLoopUniforms(ElementCount VF);
1810
1811 /// Collect the instructions that are scalar after vectorization. An
1812 /// instruction is scalar if it is known to be uniform or will be scalarized
1813 /// during vectorization. Non-uniform scalarized instructions will be
1814 /// represented by VF values in the vectorized loop, each corresponding to an
1815 /// iteration of the original scalar loop.
1816 void collectLoopScalars(ElementCount VF);
1817
1818 /// Keeps cost model vectorization decision and cost for instructions.
1819 /// Right now it is used for memory instructions only.
1820 using DecisionList = DenseMap<std::pair<Instruction *, ElementCount>,
1821 std::pair<InstWidening, InstructionCost>>;
1822
1823 DecisionList WideningDecisions;
1824
1825 /// Returns true if \p V is expected to be vectorized and it needs to be
1826 /// extracted.
needsExtract(Value * V,ElementCount VF) const1827 bool needsExtract(Value *V, ElementCount VF) const {
1828 Instruction *I = dyn_cast<Instruction>(V);
1829 if (VF.isScalar() || !I || !TheLoop->contains(I) ||
1830 TheLoop->isLoopInvariant(I))
1831 return false;
1832
1833 // Assume we can vectorize V (and hence we need extraction) if the
1834 // scalars are not computed yet. This can happen, because it is called
1835 // via getScalarizationOverhead from setCostBasedWideningDecision, before
1836 // the scalars are collected. That should be a safe assumption in most
1837 // cases, because we check if the operands have vectorizable types
1838 // beforehand in LoopVectorizationLegality.
1839 return Scalars.find(VF) == Scalars.end() ||
1840 !isScalarAfterVectorization(I, VF);
1841 };
1842
1843 /// Returns a range containing only operands needing to be extracted.
filterExtractingOperands(Instruction::op_range Ops,ElementCount VF) const1844 SmallVector<Value *, 4> filterExtractingOperands(Instruction::op_range Ops,
1845 ElementCount VF) const {
1846 return SmallVector<Value *, 4>(make_filter_range(
1847 Ops, [this, VF](Value *V) { return this->needsExtract(V, VF); }));
1848 }
1849
1850 /// Determines if we have the infrastructure to vectorize loop \p L and its
1851 /// epilogue, assuming the main loop is vectorized by \p VF.
1852 bool isCandidateForEpilogueVectorization(const Loop &L,
1853 const ElementCount VF) const;
1854
1855 /// Returns true if epilogue vectorization is considered profitable, and
1856 /// false otherwise.
1857 /// \p VF is the vectorization factor chosen for the original loop.
1858 bool isEpilogueVectorizationProfitable(const ElementCount VF) const;
1859
1860 public:
1861 /// The loop that we evaluate.
1862 Loop *TheLoop;
1863
1864 /// Predicated scalar evolution analysis.
1865 PredicatedScalarEvolution &PSE;
1866
1867 /// Loop Info analysis.
1868 LoopInfo *LI;
1869
1870 /// Vectorization legality.
1871 LoopVectorizationLegality *Legal;
1872
1873 /// Vector target information.
1874 const TargetTransformInfo &TTI;
1875
1876 /// Target Library Info.
1877 const TargetLibraryInfo *TLI;
1878
1879 /// Demanded bits analysis.
1880 DemandedBits *DB;
1881
1882 /// Assumption cache.
1883 AssumptionCache *AC;
1884
1885 /// Interface to emit optimization remarks.
1886 OptimizationRemarkEmitter *ORE;
1887
1888 const Function *TheFunction;
1889
1890 /// Loop Vectorize Hint.
1891 const LoopVectorizeHints *Hints;
1892
1893 /// The interleave access information contains groups of interleaved accesses
1894 /// with the same stride and close to each other.
1895 InterleavedAccessInfo &InterleaveInfo;
1896
1897 /// Values to ignore in the cost model.
1898 SmallPtrSet<const Value *, 16> ValuesToIgnore;
1899
1900 /// Values to ignore in the cost model when VF > 1.
1901 SmallPtrSet<const Value *, 16> VecValuesToIgnore;
1902
1903 /// All element types found in the loop.
1904 SmallPtrSet<Type *, 16> ElementTypesInLoop;
1905
1906 /// Profitable vector factors.
1907 SmallVector<VectorizationFactor, 8> ProfitableVFs;
1908 };
1909 } // end namespace llvm
1910
1911 /// Helper struct to manage generating runtime checks for vectorization.
1912 ///
1913 /// The runtime checks are created up-front in temporary blocks to allow better
1914 /// estimating the cost and un-linked from the existing IR. After deciding to
1915 /// vectorize, the checks are moved back. If deciding not to vectorize, the
1916 /// temporary blocks are completely removed.
1917 class GeneratedRTChecks {
1918 /// Basic block which contains the generated SCEV checks, if any.
1919 BasicBlock *SCEVCheckBlock = nullptr;
1920
1921 /// The value representing the result of the generated SCEV checks. If it is
1922 /// nullptr, either no SCEV checks have been generated or they have been used.
1923 Value *SCEVCheckCond = nullptr;
1924
1925 /// Basic block which contains the generated memory runtime checks, if any.
1926 BasicBlock *MemCheckBlock = nullptr;
1927
1928 /// The value representing the result of the generated memory runtime checks.
1929 /// If it is nullptr, either no memory runtime checks have been generated or
1930 /// they have been used.
1931 Instruction *MemRuntimeCheckCond = nullptr;
1932
1933 DominatorTree *DT;
1934 LoopInfo *LI;
1935
1936 SCEVExpander SCEVExp;
1937 SCEVExpander MemCheckExp;
1938
1939 public:
GeneratedRTChecks(ScalarEvolution & SE,DominatorTree * DT,LoopInfo * LI,const DataLayout & DL)1940 GeneratedRTChecks(ScalarEvolution &SE, DominatorTree *DT, LoopInfo *LI,
1941 const DataLayout &DL)
1942 : DT(DT), LI(LI), SCEVExp(SE, DL, "scev.check"),
1943 MemCheckExp(SE, DL, "scev.check") {}
1944
1945 /// Generate runtime checks in SCEVCheckBlock and MemCheckBlock, so we can
1946 /// accurately estimate the cost of the runtime checks. The blocks are
1947 /// un-linked from the IR and is added back during vector code generation. If
1948 /// there is no vector code generation, the check blocks are removed
1949 /// completely.
Create(Loop * L,const LoopAccessInfo & LAI,const SCEVUnionPredicate & UnionPred)1950 void Create(Loop *L, const LoopAccessInfo &LAI,
1951 const SCEVUnionPredicate &UnionPred) {
1952
1953 BasicBlock *LoopHeader = L->getHeader();
1954 BasicBlock *Preheader = L->getLoopPreheader();
1955
1956 // Use SplitBlock to create blocks for SCEV & memory runtime checks to
1957 // ensure the blocks are properly added to LoopInfo & DominatorTree. Those
1958 // may be used by SCEVExpander. The blocks will be un-linked from their
1959 // predecessors and removed from LI & DT at the end of the function.
1960 if (!UnionPred.isAlwaysTrue()) {
1961 SCEVCheckBlock = SplitBlock(Preheader, Preheader->getTerminator(), DT, LI,
1962 nullptr, "vector.scevcheck");
1963
1964 SCEVCheckCond = SCEVExp.expandCodeForPredicate(
1965 &UnionPred, SCEVCheckBlock->getTerminator());
1966 }
1967
1968 const auto &RtPtrChecking = *LAI.getRuntimePointerChecking();
1969 if (RtPtrChecking.Need) {
1970 auto *Pred = SCEVCheckBlock ? SCEVCheckBlock : Preheader;
1971 MemCheckBlock = SplitBlock(Pred, Pred->getTerminator(), DT, LI, nullptr,
1972 "vector.memcheck");
1973
1974 std::tie(std::ignore, MemRuntimeCheckCond) =
1975 addRuntimeChecks(MemCheckBlock->getTerminator(), L,
1976 RtPtrChecking.getChecks(), MemCheckExp);
1977 assert(MemRuntimeCheckCond &&
1978 "no RT checks generated although RtPtrChecking "
1979 "claimed checks are required");
1980 }
1981
1982 if (!MemCheckBlock && !SCEVCheckBlock)
1983 return;
1984
1985 // Unhook the temporary block with the checks, update various places
1986 // accordingly.
1987 if (SCEVCheckBlock)
1988 SCEVCheckBlock->replaceAllUsesWith(Preheader);
1989 if (MemCheckBlock)
1990 MemCheckBlock->replaceAllUsesWith(Preheader);
1991
1992 if (SCEVCheckBlock) {
1993 SCEVCheckBlock->getTerminator()->moveBefore(Preheader->getTerminator());
1994 new UnreachableInst(Preheader->getContext(), SCEVCheckBlock);
1995 Preheader->getTerminator()->eraseFromParent();
1996 }
1997 if (MemCheckBlock) {
1998 MemCheckBlock->getTerminator()->moveBefore(Preheader->getTerminator());
1999 new UnreachableInst(Preheader->getContext(), MemCheckBlock);
2000 Preheader->getTerminator()->eraseFromParent();
2001 }
2002
2003 DT->changeImmediateDominator(LoopHeader, Preheader);
2004 if (MemCheckBlock) {
2005 DT->eraseNode(MemCheckBlock);
2006 LI->removeBlock(MemCheckBlock);
2007 }
2008 if (SCEVCheckBlock) {
2009 DT->eraseNode(SCEVCheckBlock);
2010 LI->removeBlock(SCEVCheckBlock);
2011 }
2012 }
2013
2014 /// Remove the created SCEV & memory runtime check blocks & instructions, if
2015 /// unused.
~GeneratedRTChecks()2016 ~GeneratedRTChecks() {
2017 SCEVExpanderCleaner SCEVCleaner(SCEVExp, *DT);
2018 SCEVExpanderCleaner MemCheckCleaner(MemCheckExp, *DT);
2019 if (!SCEVCheckCond)
2020 SCEVCleaner.markResultUsed();
2021
2022 if (!MemRuntimeCheckCond)
2023 MemCheckCleaner.markResultUsed();
2024
2025 if (MemRuntimeCheckCond) {
2026 auto &SE = *MemCheckExp.getSE();
2027 // Memory runtime check generation creates compares that use expanded
2028 // values. Remove them before running the SCEVExpanderCleaners.
2029 for (auto &I : make_early_inc_range(reverse(*MemCheckBlock))) {
2030 if (MemCheckExp.isInsertedInstruction(&I))
2031 continue;
2032 SE.forgetValue(&I);
2033 SE.eraseValueFromMap(&I);
2034 I.eraseFromParent();
2035 }
2036 }
2037 MemCheckCleaner.cleanup();
2038 SCEVCleaner.cleanup();
2039
2040 if (SCEVCheckCond)
2041 SCEVCheckBlock->eraseFromParent();
2042 if (MemRuntimeCheckCond)
2043 MemCheckBlock->eraseFromParent();
2044 }
2045
2046 /// Adds the generated SCEVCheckBlock before \p LoopVectorPreHeader and
2047 /// adjusts the branches to branch to the vector preheader or \p Bypass,
2048 /// depending on the generated condition.
emitSCEVChecks(Loop * L,BasicBlock * Bypass,BasicBlock * LoopVectorPreHeader,BasicBlock * LoopExitBlock)2049 BasicBlock *emitSCEVChecks(Loop *L, BasicBlock *Bypass,
2050 BasicBlock *LoopVectorPreHeader,
2051 BasicBlock *LoopExitBlock) {
2052 if (!SCEVCheckCond)
2053 return nullptr;
2054 if (auto *C = dyn_cast<ConstantInt>(SCEVCheckCond))
2055 if (C->isZero())
2056 return nullptr;
2057
2058 auto *Pred = LoopVectorPreHeader->getSinglePredecessor();
2059
2060 BranchInst::Create(LoopVectorPreHeader, SCEVCheckBlock);
2061 // Create new preheader for vector loop.
2062 if (auto *PL = LI->getLoopFor(LoopVectorPreHeader))
2063 PL->addBasicBlockToLoop(SCEVCheckBlock, *LI);
2064
2065 SCEVCheckBlock->getTerminator()->eraseFromParent();
2066 SCEVCheckBlock->moveBefore(LoopVectorPreHeader);
2067 Pred->getTerminator()->replaceSuccessorWith(LoopVectorPreHeader,
2068 SCEVCheckBlock);
2069
2070 DT->addNewBlock(SCEVCheckBlock, Pred);
2071 DT->changeImmediateDominator(LoopVectorPreHeader, SCEVCheckBlock);
2072
2073 ReplaceInstWithInst(
2074 SCEVCheckBlock->getTerminator(),
2075 BranchInst::Create(Bypass, LoopVectorPreHeader, SCEVCheckCond));
2076 // Mark the check as used, to prevent it from being removed during cleanup.
2077 SCEVCheckCond = nullptr;
2078 return SCEVCheckBlock;
2079 }
2080
2081 /// Adds the generated MemCheckBlock before \p LoopVectorPreHeader and adjusts
2082 /// the branches to branch to the vector preheader or \p Bypass, depending on
2083 /// the generated condition.
emitMemRuntimeChecks(Loop * L,BasicBlock * Bypass,BasicBlock * LoopVectorPreHeader)2084 BasicBlock *emitMemRuntimeChecks(Loop *L, BasicBlock *Bypass,
2085 BasicBlock *LoopVectorPreHeader) {
2086 // Check if we generated code that checks in runtime if arrays overlap.
2087 if (!MemRuntimeCheckCond)
2088 return nullptr;
2089
2090 auto *Pred = LoopVectorPreHeader->getSinglePredecessor();
2091 Pred->getTerminator()->replaceSuccessorWith(LoopVectorPreHeader,
2092 MemCheckBlock);
2093
2094 DT->addNewBlock(MemCheckBlock, Pred);
2095 DT->changeImmediateDominator(LoopVectorPreHeader, MemCheckBlock);
2096 MemCheckBlock->moveBefore(LoopVectorPreHeader);
2097
2098 if (auto *PL = LI->getLoopFor(LoopVectorPreHeader))
2099 PL->addBasicBlockToLoop(MemCheckBlock, *LI);
2100
2101 ReplaceInstWithInst(
2102 MemCheckBlock->getTerminator(),
2103 BranchInst::Create(Bypass, LoopVectorPreHeader, MemRuntimeCheckCond));
2104 MemCheckBlock->getTerminator()->setDebugLoc(
2105 Pred->getTerminator()->getDebugLoc());
2106
2107 // Mark the check as used, to prevent it from being removed during cleanup.
2108 MemRuntimeCheckCond = nullptr;
2109 return MemCheckBlock;
2110 }
2111 };
2112
2113 // Return true if \p OuterLp is an outer loop annotated with hints for explicit
2114 // vectorization. The loop needs to be annotated with #pragma omp simd
2115 // simdlen(#) or #pragma clang vectorize(enable) vectorize_width(#). If the
2116 // vector length information is not provided, vectorization is not considered
2117 // explicit. Interleave hints are not allowed either. These limitations will be
2118 // relaxed in the future.
2119 // Please, note that we are currently forced to abuse the pragma 'clang
2120 // vectorize' semantics. This pragma provides *auto-vectorization hints*
2121 // (i.e., LV must check that vectorization is legal) whereas pragma 'omp simd'
2122 // provides *explicit vectorization hints* (LV can bypass legal checks and
2123 // assume that vectorization is legal). However, both hints are implemented
2124 // using the same metadata (llvm.loop.vectorize, processed by
2125 // LoopVectorizeHints). This will be fixed in the future when the native IR
2126 // representation for pragma 'omp simd' is introduced.
isExplicitVecOuterLoop(Loop * OuterLp,OptimizationRemarkEmitter * ORE)2127 static bool isExplicitVecOuterLoop(Loop *OuterLp,
2128 OptimizationRemarkEmitter *ORE) {
2129 assert(!OuterLp->isInnermost() && "This is not an outer loop");
2130 LoopVectorizeHints Hints(OuterLp, true /*DisableInterleaving*/, *ORE);
2131
2132 // Only outer loops with an explicit vectorization hint are supported.
2133 // Unannotated outer loops are ignored.
2134 if (Hints.getForce() == LoopVectorizeHints::FK_Undefined)
2135 return false;
2136
2137 Function *Fn = OuterLp->getHeader()->getParent();
2138 if (!Hints.allowVectorization(Fn, OuterLp,
2139 true /*VectorizeOnlyWhenForced*/)) {
2140 LLVM_DEBUG(dbgs() << "LV: Loop hints prevent outer loop vectorization.\n");
2141 return false;
2142 }
2143
2144 if (Hints.getInterleave() > 1) {
2145 // TODO: Interleave support is future work.
2146 LLVM_DEBUG(dbgs() << "LV: Not vectorizing: Interleave is not supported for "
2147 "outer loops.\n");
2148 Hints.emitRemarkWithHints();
2149 return false;
2150 }
2151
2152 return true;
2153 }
2154
collectSupportedLoops(Loop & L,LoopInfo * LI,OptimizationRemarkEmitter * ORE,SmallVectorImpl<Loop * > & V)2155 static void collectSupportedLoops(Loop &L, LoopInfo *LI,
2156 OptimizationRemarkEmitter *ORE,
2157 SmallVectorImpl<Loop *> &V) {
2158 // Collect inner loops and outer loops without irreducible control flow. For
2159 // now, only collect outer loops that have explicit vectorization hints. If we
2160 // are stress testing the VPlan H-CFG construction, we collect the outermost
2161 // loop of every loop nest.
2162 if (L.isInnermost() || VPlanBuildStressTest ||
2163 (EnableVPlanNativePath && isExplicitVecOuterLoop(&L, ORE))) {
2164 LoopBlocksRPO RPOT(&L);
2165 RPOT.perform(LI);
2166 if (!containsIrreducibleCFG<const BasicBlock *>(RPOT, *LI)) {
2167 V.push_back(&L);
2168 // TODO: Collect inner loops inside marked outer loops in case
2169 // vectorization fails for the outer loop. Do not invoke
2170 // 'containsIrreducibleCFG' again for inner loops when the outer loop is
2171 // already known to be reducible. We can use an inherited attribute for
2172 // that.
2173 return;
2174 }
2175 }
2176 for (Loop *InnerL : L)
2177 collectSupportedLoops(*InnerL, LI, ORE, V);
2178 }
2179
2180 namespace {
2181
2182 /// The LoopVectorize Pass.
2183 struct LoopVectorize : public FunctionPass {
2184 /// Pass identification, replacement for typeid
2185 static char ID;
2186
2187 LoopVectorizePass Impl;
2188
LoopVectorize__anonae0bb1450311::LoopVectorize2189 explicit LoopVectorize(bool InterleaveOnlyWhenForced = false,
2190 bool VectorizeOnlyWhenForced = false)
2191 : FunctionPass(ID),
2192 Impl({InterleaveOnlyWhenForced, VectorizeOnlyWhenForced}) {
2193 initializeLoopVectorizePass(*PassRegistry::getPassRegistry());
2194 }
2195
runOnFunction__anonae0bb1450311::LoopVectorize2196 bool runOnFunction(Function &F) override {
2197 if (skipFunction(F))
2198 return false;
2199
2200 auto *SE = &getAnalysis<ScalarEvolutionWrapperPass>().getSE();
2201 auto *LI = &getAnalysis<LoopInfoWrapperPass>().getLoopInfo();
2202 auto *TTI = &getAnalysis<TargetTransformInfoWrapperPass>().getTTI(F);
2203 auto *DT = &getAnalysis<DominatorTreeWrapperPass>().getDomTree();
2204 auto *BFI = &getAnalysis<BlockFrequencyInfoWrapperPass>().getBFI();
2205 auto *TLIP = getAnalysisIfAvailable<TargetLibraryInfoWrapperPass>();
2206 auto *TLI = TLIP ? &TLIP->getTLI(F) : nullptr;
2207 auto *AA = &getAnalysis<AAResultsWrapperPass>().getAAResults();
2208 auto *AC = &getAnalysis<AssumptionCacheTracker>().getAssumptionCache(F);
2209 auto *LAA = &getAnalysis<LoopAccessLegacyAnalysis>();
2210 auto *DB = &getAnalysis<DemandedBitsWrapperPass>().getDemandedBits();
2211 auto *ORE = &getAnalysis<OptimizationRemarkEmitterWrapperPass>().getORE();
2212 auto *PSI = &getAnalysis<ProfileSummaryInfoWrapperPass>().getPSI();
2213
2214 std::function<const LoopAccessInfo &(Loop &)> GetLAA =
2215 [&](Loop &L) -> const LoopAccessInfo & { return LAA->getInfo(&L); };
2216
2217 return Impl.runImpl(F, *SE, *LI, *TTI, *DT, *BFI, TLI, *DB, *AA, *AC,
2218 GetLAA, *ORE, PSI).MadeAnyChange;
2219 }
2220
getAnalysisUsage__anonae0bb1450311::LoopVectorize2221 void getAnalysisUsage(AnalysisUsage &AU) const override {
2222 AU.addRequired<AssumptionCacheTracker>();
2223 AU.addRequired<BlockFrequencyInfoWrapperPass>();
2224 AU.addRequired<DominatorTreeWrapperPass>();
2225 AU.addRequired<LoopInfoWrapperPass>();
2226 AU.addRequired<ScalarEvolutionWrapperPass>();
2227 AU.addRequired<TargetTransformInfoWrapperPass>();
2228 AU.addRequired<AAResultsWrapperPass>();
2229 AU.addRequired<LoopAccessLegacyAnalysis>();
2230 AU.addRequired<DemandedBitsWrapperPass>();
2231 AU.addRequired<OptimizationRemarkEmitterWrapperPass>();
2232 AU.addRequired<InjectTLIMappingsLegacy>();
2233
2234 // We currently do not preserve loopinfo/dominator analyses with outer loop
2235 // vectorization. Until this is addressed, mark these analyses as preserved
2236 // only for non-VPlan-native path.
2237 // TODO: Preserve Loop and Dominator analyses for VPlan-native path.
2238 if (!EnableVPlanNativePath) {
2239 AU.addPreserved<LoopInfoWrapperPass>();
2240 AU.addPreserved<DominatorTreeWrapperPass>();
2241 }
2242
2243 AU.addPreserved<BasicAAWrapperPass>();
2244 AU.addPreserved<GlobalsAAWrapperPass>();
2245 AU.addRequired<ProfileSummaryInfoWrapperPass>();
2246 }
2247 };
2248
2249 } // end anonymous namespace
2250
2251 //===----------------------------------------------------------------------===//
2252 // Implementation of LoopVectorizationLegality, InnerLoopVectorizer and
2253 // LoopVectorizationCostModel and LoopVectorizationPlanner.
2254 //===----------------------------------------------------------------------===//
2255
getBroadcastInstrs(Value * V)2256 Value *InnerLoopVectorizer::getBroadcastInstrs(Value *V) {
2257 // We need to place the broadcast of invariant variables outside the loop,
2258 // but only if it's proven safe to do so. Else, broadcast will be inside
2259 // vector loop body.
2260 Instruction *Instr = dyn_cast<Instruction>(V);
2261 bool SafeToHoist = OrigLoop->isLoopInvariant(V) &&
2262 (!Instr ||
2263 DT->dominates(Instr->getParent(), LoopVectorPreHeader));
2264 // Place the code for broadcasting invariant variables in the new preheader.
2265 IRBuilder<>::InsertPointGuard Guard(Builder);
2266 if (SafeToHoist)
2267 Builder.SetInsertPoint(LoopVectorPreHeader->getTerminator());
2268
2269 // Broadcast the scalar into all locations in the vector.
2270 Value *Shuf = Builder.CreateVectorSplat(VF, V, "broadcast");
2271
2272 return Shuf;
2273 }
2274
createVectorIntOrFpInductionPHI(const InductionDescriptor & II,Value * Step,Value * Start,Instruction * EntryVal,VPValue * Def,VPValue * CastDef,VPTransformState & State)2275 void InnerLoopVectorizer::createVectorIntOrFpInductionPHI(
2276 const InductionDescriptor &II, Value *Step, Value *Start,
2277 Instruction *EntryVal, VPValue *Def, VPValue *CastDef,
2278 VPTransformState &State) {
2279 assert((isa<PHINode>(EntryVal) || isa<TruncInst>(EntryVal)) &&
2280 "Expected either an induction phi-node or a truncate of it!");
2281
2282 // Construct the initial value of the vector IV in the vector loop preheader
2283 auto CurrIP = Builder.saveIP();
2284 Builder.SetInsertPoint(LoopVectorPreHeader->getTerminator());
2285 if (isa<TruncInst>(EntryVal)) {
2286 assert(Start->getType()->isIntegerTy() &&
2287 "Truncation requires an integer type");
2288 auto *TruncType = cast<IntegerType>(EntryVal->getType());
2289 Step = Builder.CreateTrunc(Step, TruncType);
2290 Start = Builder.CreateCast(Instruction::Trunc, Start, TruncType);
2291 }
2292 Value *SplatStart = Builder.CreateVectorSplat(VF, Start);
2293 Value *SteppedStart =
2294 getStepVector(SplatStart, 0, Step, II.getInductionOpcode());
2295
2296 // We create vector phi nodes for both integer and floating-point induction
2297 // variables. Here, we determine the kind of arithmetic we will perform.
2298 Instruction::BinaryOps AddOp;
2299 Instruction::BinaryOps MulOp;
2300 if (Step->getType()->isIntegerTy()) {
2301 AddOp = Instruction::Add;
2302 MulOp = Instruction::Mul;
2303 } else {
2304 AddOp = II.getInductionOpcode();
2305 MulOp = Instruction::FMul;
2306 }
2307
2308 // Multiply the vectorization factor by the step using integer or
2309 // floating-point arithmetic as appropriate.
2310 Type *StepType = Step->getType();
2311 if (Step->getType()->isFloatingPointTy())
2312 StepType = IntegerType::get(StepType->getContext(),
2313 StepType->getScalarSizeInBits());
2314 Value *RuntimeVF = getRuntimeVF(Builder, StepType, VF);
2315 if (Step->getType()->isFloatingPointTy())
2316 RuntimeVF = Builder.CreateSIToFP(RuntimeVF, Step->getType());
2317 Value *Mul = Builder.CreateBinOp(MulOp, Step, RuntimeVF);
2318
2319 // Create a vector splat to use in the induction update.
2320 //
2321 // FIXME: If the step is non-constant, we create the vector splat with
2322 // IRBuilder. IRBuilder can constant-fold the multiply, but it doesn't
2323 // handle a constant vector splat.
2324 Value *SplatVF = isa<Constant>(Mul)
2325 ? ConstantVector::getSplat(VF, cast<Constant>(Mul))
2326 : Builder.CreateVectorSplat(VF, Mul);
2327 Builder.restoreIP(CurrIP);
2328
2329 // We may need to add the step a number of times, depending on the unroll
2330 // factor. The last of those goes into the PHI.
2331 PHINode *VecInd = PHINode::Create(SteppedStart->getType(), 2, "vec.ind",
2332 &*LoopVectorBody->getFirstInsertionPt());
2333 VecInd->setDebugLoc(EntryVal->getDebugLoc());
2334 Instruction *LastInduction = VecInd;
2335 for (unsigned Part = 0; Part < UF; ++Part) {
2336 State.set(Def, LastInduction, Part);
2337
2338 if (isa<TruncInst>(EntryVal))
2339 addMetadata(LastInduction, EntryVal);
2340 recordVectorLoopValueForInductionCast(II, EntryVal, LastInduction, CastDef,
2341 State, Part);
2342
2343 LastInduction = cast<Instruction>(
2344 Builder.CreateBinOp(AddOp, LastInduction, SplatVF, "step.add"));
2345 LastInduction->setDebugLoc(EntryVal->getDebugLoc());
2346 }
2347
2348 // Move the last step to the end of the latch block. This ensures consistent
2349 // placement of all induction updates.
2350 auto *LoopVectorLatch = LI->getLoopFor(LoopVectorBody)->getLoopLatch();
2351 auto *Br = cast<BranchInst>(LoopVectorLatch->getTerminator());
2352 auto *ICmp = cast<Instruction>(Br->getCondition());
2353 LastInduction->moveBefore(ICmp);
2354 LastInduction->setName("vec.ind.next");
2355
2356 VecInd->addIncoming(SteppedStart, LoopVectorPreHeader);
2357 VecInd->addIncoming(LastInduction, LoopVectorLatch);
2358 }
2359
shouldScalarizeInstruction(Instruction * I) const2360 bool InnerLoopVectorizer::shouldScalarizeInstruction(Instruction *I) const {
2361 return Cost->isScalarAfterVectorization(I, VF) ||
2362 Cost->isProfitableToScalarize(I, VF);
2363 }
2364
needsScalarInduction(Instruction * IV) const2365 bool InnerLoopVectorizer::needsScalarInduction(Instruction *IV) const {
2366 if (shouldScalarizeInstruction(IV))
2367 return true;
2368 auto isScalarInst = [&](User *U) -> bool {
2369 auto *I = cast<Instruction>(U);
2370 return (OrigLoop->contains(I) && shouldScalarizeInstruction(I));
2371 };
2372 return llvm::any_of(IV->users(), isScalarInst);
2373 }
2374
recordVectorLoopValueForInductionCast(const InductionDescriptor & ID,const Instruction * EntryVal,Value * VectorLoopVal,VPValue * CastDef,VPTransformState & State,unsigned Part,unsigned Lane)2375 void InnerLoopVectorizer::recordVectorLoopValueForInductionCast(
2376 const InductionDescriptor &ID, const Instruction *EntryVal,
2377 Value *VectorLoopVal, VPValue *CastDef, VPTransformState &State,
2378 unsigned Part, unsigned Lane) {
2379 assert((isa<PHINode>(EntryVal) || isa<TruncInst>(EntryVal)) &&
2380 "Expected either an induction phi-node or a truncate of it!");
2381
2382 // This induction variable is not the phi from the original loop but the
2383 // newly-created IV based on the proof that casted Phi is equal to the
2384 // uncasted Phi in the vectorized loop (under a runtime guard possibly). It
2385 // re-uses the same InductionDescriptor that original IV uses but we don't
2386 // have to do any recording in this case - that is done when original IV is
2387 // processed.
2388 if (isa<TruncInst>(EntryVal))
2389 return;
2390
2391 const SmallVectorImpl<Instruction *> &Casts = ID.getCastInsts();
2392 if (Casts.empty())
2393 return;
2394 // Only the first Cast instruction in the Casts vector is of interest.
2395 // The rest of the Casts (if exist) have no uses outside the
2396 // induction update chain itself.
2397 if (Lane < UINT_MAX)
2398 State.set(CastDef, VectorLoopVal, VPIteration(Part, Lane));
2399 else
2400 State.set(CastDef, VectorLoopVal, Part);
2401 }
2402
widenIntOrFpInduction(PHINode * IV,Value * Start,TruncInst * Trunc,VPValue * Def,VPValue * CastDef,VPTransformState & State)2403 void InnerLoopVectorizer::widenIntOrFpInduction(PHINode *IV, Value *Start,
2404 TruncInst *Trunc, VPValue *Def,
2405 VPValue *CastDef,
2406 VPTransformState &State) {
2407 assert((IV->getType()->isIntegerTy() || IV != OldInduction) &&
2408 "Primary induction variable must have an integer type");
2409
2410 auto II = Legal->getInductionVars().find(IV);
2411 assert(II != Legal->getInductionVars().end() && "IV is not an induction");
2412
2413 auto ID = II->second;
2414 assert(IV->getType() == ID.getStartValue()->getType() && "Types must match");
2415
2416 // The value from the original loop to which we are mapping the new induction
2417 // variable.
2418 Instruction *EntryVal = Trunc ? cast<Instruction>(Trunc) : IV;
2419
2420 auto &DL = OrigLoop->getHeader()->getModule()->getDataLayout();
2421
2422 // Generate code for the induction step. Note that induction steps are
2423 // required to be loop-invariant
2424 auto CreateStepValue = [&](const SCEV *Step) -> Value * {
2425 assert(PSE.getSE()->isLoopInvariant(Step, OrigLoop) &&
2426 "Induction step should be loop invariant");
2427 if (PSE.getSE()->isSCEVable(IV->getType())) {
2428 SCEVExpander Exp(*PSE.getSE(), DL, "induction");
2429 return Exp.expandCodeFor(Step, Step->getType(),
2430 LoopVectorPreHeader->getTerminator());
2431 }
2432 return cast<SCEVUnknown>(Step)->getValue();
2433 };
2434
2435 // The scalar value to broadcast. This is derived from the canonical
2436 // induction variable. If a truncation type is given, truncate the canonical
2437 // induction variable and step. Otherwise, derive these values from the
2438 // induction descriptor.
2439 auto CreateScalarIV = [&](Value *&Step) -> Value * {
2440 Value *ScalarIV = Induction;
2441 if (IV != OldInduction) {
2442 ScalarIV = IV->getType()->isIntegerTy()
2443 ? Builder.CreateSExtOrTrunc(Induction, IV->getType())
2444 : Builder.CreateCast(Instruction::SIToFP, Induction,
2445 IV->getType());
2446 ScalarIV = emitTransformedIndex(Builder, ScalarIV, PSE.getSE(), DL, ID);
2447 ScalarIV->setName("offset.idx");
2448 }
2449 if (Trunc) {
2450 auto *TruncType = cast<IntegerType>(Trunc->getType());
2451 assert(Step->getType()->isIntegerTy() &&
2452 "Truncation requires an integer step");
2453 ScalarIV = Builder.CreateTrunc(ScalarIV, TruncType);
2454 Step = Builder.CreateTrunc(Step, TruncType);
2455 }
2456 return ScalarIV;
2457 };
2458
2459 // Create the vector values from the scalar IV, in the absence of creating a
2460 // vector IV.
2461 auto CreateSplatIV = [&](Value *ScalarIV, Value *Step) {
2462 Value *Broadcasted = getBroadcastInstrs(ScalarIV);
2463 for (unsigned Part = 0; Part < UF; ++Part) {
2464 assert(!VF.isScalable() && "scalable vectors not yet supported.");
2465 Value *EntryPart =
2466 getStepVector(Broadcasted, VF.getKnownMinValue() * Part, Step,
2467 ID.getInductionOpcode());
2468 State.set(Def, EntryPart, Part);
2469 if (Trunc)
2470 addMetadata(EntryPart, Trunc);
2471 recordVectorLoopValueForInductionCast(ID, EntryVal, EntryPart, CastDef,
2472 State, Part);
2473 }
2474 };
2475
2476 // Fast-math-flags propagate from the original induction instruction.
2477 IRBuilder<>::FastMathFlagGuard FMFG(Builder);
2478 if (ID.getInductionBinOp() && isa<FPMathOperator>(ID.getInductionBinOp()))
2479 Builder.setFastMathFlags(ID.getInductionBinOp()->getFastMathFlags());
2480
2481 // Now do the actual transformations, and start with creating the step value.
2482 Value *Step = CreateStepValue(ID.getStep());
2483 if (VF.isZero() || VF.isScalar()) {
2484 Value *ScalarIV = CreateScalarIV(Step);
2485 CreateSplatIV(ScalarIV, Step);
2486 return;
2487 }
2488
2489 // Determine if we want a scalar version of the induction variable. This is
2490 // true if the induction variable itself is not widened, or if it has at
2491 // least one user in the loop that is not widened.
2492 auto NeedsScalarIV = needsScalarInduction(EntryVal);
2493 if (!NeedsScalarIV) {
2494 createVectorIntOrFpInductionPHI(ID, Step, Start, EntryVal, Def, CastDef,
2495 State);
2496 return;
2497 }
2498
2499 // Try to create a new independent vector induction variable. If we can't
2500 // create the phi node, we will splat the scalar induction variable in each
2501 // loop iteration.
2502 if (!shouldScalarizeInstruction(EntryVal)) {
2503 createVectorIntOrFpInductionPHI(ID, Step, Start, EntryVal, Def, CastDef,
2504 State);
2505 Value *ScalarIV = CreateScalarIV(Step);
2506 // Create scalar steps that can be used by instructions we will later
2507 // scalarize. Note that the addition of the scalar steps will not increase
2508 // the number of instructions in the loop in the common case prior to
2509 // InstCombine. We will be trading one vector extract for each scalar step.
2510 buildScalarSteps(ScalarIV, Step, EntryVal, ID, Def, CastDef, State);
2511 return;
2512 }
2513
2514 // All IV users are scalar instructions, so only emit a scalar IV, not a
2515 // vectorised IV. Except when we tail-fold, then the splat IV feeds the
2516 // predicate used by the masked loads/stores.
2517 Value *ScalarIV = CreateScalarIV(Step);
2518 if (!Cost->isScalarEpilogueAllowed())
2519 CreateSplatIV(ScalarIV, Step);
2520 buildScalarSteps(ScalarIV, Step, EntryVal, ID, Def, CastDef, State);
2521 }
2522
getStepVector(Value * Val,int StartIdx,Value * Step,Instruction::BinaryOps BinOp)2523 Value *InnerLoopVectorizer::getStepVector(Value *Val, int StartIdx, Value *Step,
2524 Instruction::BinaryOps BinOp) {
2525 // Create and check the types.
2526 auto *ValVTy = cast<VectorType>(Val->getType());
2527 ElementCount VLen = ValVTy->getElementCount();
2528
2529 Type *STy = Val->getType()->getScalarType();
2530 assert((STy->isIntegerTy() || STy->isFloatingPointTy()) &&
2531 "Induction Step must be an integer or FP");
2532 assert(Step->getType() == STy && "Step has wrong type");
2533
2534 SmallVector<Constant *, 8> Indices;
2535
2536 // Create a vector of consecutive numbers from zero to VF.
2537 VectorType *InitVecValVTy = ValVTy;
2538 Type *InitVecValSTy = STy;
2539 if (STy->isFloatingPointTy()) {
2540 InitVecValSTy =
2541 IntegerType::get(STy->getContext(), STy->getScalarSizeInBits());
2542 InitVecValVTy = VectorType::get(InitVecValSTy, VLen);
2543 }
2544 Value *InitVec = Builder.CreateStepVector(InitVecValVTy);
2545
2546 // Add on StartIdx
2547 Value *StartIdxSplat = Builder.CreateVectorSplat(
2548 VLen, ConstantInt::get(InitVecValSTy, StartIdx));
2549 InitVec = Builder.CreateAdd(InitVec, StartIdxSplat);
2550
2551 if (STy->isIntegerTy()) {
2552 Step = Builder.CreateVectorSplat(VLen, Step);
2553 assert(Step->getType() == Val->getType() && "Invalid step vec");
2554 // FIXME: The newly created binary instructions should contain nsw/nuw flags,
2555 // which can be found from the original scalar operations.
2556 Step = Builder.CreateMul(InitVec, Step);
2557 return Builder.CreateAdd(Val, Step, "induction");
2558 }
2559
2560 // Floating point induction.
2561 assert((BinOp == Instruction::FAdd || BinOp == Instruction::FSub) &&
2562 "Binary Opcode should be specified for FP induction");
2563 InitVec = Builder.CreateUIToFP(InitVec, ValVTy);
2564 Step = Builder.CreateVectorSplat(VLen, Step);
2565 Value *MulOp = Builder.CreateFMul(InitVec, Step);
2566 return Builder.CreateBinOp(BinOp, Val, MulOp, "induction");
2567 }
2568
buildScalarSteps(Value * ScalarIV,Value * Step,Instruction * EntryVal,const InductionDescriptor & ID,VPValue * Def,VPValue * CastDef,VPTransformState & State)2569 void InnerLoopVectorizer::buildScalarSteps(Value *ScalarIV, Value *Step,
2570 Instruction *EntryVal,
2571 const InductionDescriptor &ID,
2572 VPValue *Def, VPValue *CastDef,
2573 VPTransformState &State) {
2574 // We shouldn't have to build scalar steps if we aren't vectorizing.
2575 assert(VF.isVector() && "VF should be greater than one");
2576 // Get the value type and ensure it and the step have the same integer type.
2577 Type *ScalarIVTy = ScalarIV->getType()->getScalarType();
2578 assert(ScalarIVTy == Step->getType() &&
2579 "Val and Step should have the same type");
2580
2581 // We build scalar steps for both integer and floating-point induction
2582 // variables. Here, we determine the kind of arithmetic we will perform.
2583 Instruction::BinaryOps AddOp;
2584 Instruction::BinaryOps MulOp;
2585 if (ScalarIVTy->isIntegerTy()) {
2586 AddOp = Instruction::Add;
2587 MulOp = Instruction::Mul;
2588 } else {
2589 AddOp = ID.getInductionOpcode();
2590 MulOp = Instruction::FMul;
2591 }
2592
2593 // Determine the number of scalars we need to generate for each unroll
2594 // iteration. If EntryVal is uniform, we only need to generate the first
2595 // lane. Otherwise, we generate all VF values.
2596 bool IsUniform =
2597 Cost->isUniformAfterVectorization(cast<Instruction>(EntryVal), VF);
2598 unsigned Lanes = IsUniform ? 1 : VF.getKnownMinValue();
2599 // Compute the scalar steps and save the results in State.
2600 Type *IntStepTy = IntegerType::get(ScalarIVTy->getContext(),
2601 ScalarIVTy->getScalarSizeInBits());
2602 Type *VecIVTy = nullptr;
2603 Value *UnitStepVec = nullptr, *SplatStep = nullptr, *SplatIV = nullptr;
2604 if (!IsUniform && VF.isScalable()) {
2605 VecIVTy = VectorType::get(ScalarIVTy, VF);
2606 UnitStepVec = Builder.CreateStepVector(VectorType::get(IntStepTy, VF));
2607 SplatStep = Builder.CreateVectorSplat(VF, Step);
2608 SplatIV = Builder.CreateVectorSplat(VF, ScalarIV);
2609 }
2610
2611 for (unsigned Part = 0; Part < UF; ++Part) {
2612 Value *StartIdx0 =
2613 createStepForVF(Builder, ConstantInt::get(IntStepTy, Part), VF);
2614
2615 if (!IsUniform && VF.isScalable()) {
2616 auto *SplatStartIdx = Builder.CreateVectorSplat(VF, StartIdx0);
2617 auto *InitVec = Builder.CreateAdd(SplatStartIdx, UnitStepVec);
2618 if (ScalarIVTy->isFloatingPointTy())
2619 InitVec = Builder.CreateSIToFP(InitVec, VecIVTy);
2620 auto *Mul = Builder.CreateBinOp(MulOp, InitVec, SplatStep);
2621 auto *Add = Builder.CreateBinOp(AddOp, SplatIV, Mul);
2622 State.set(Def, Add, Part);
2623 recordVectorLoopValueForInductionCast(ID, EntryVal, Add, CastDef, State,
2624 Part);
2625 // It's useful to record the lane values too for the known minimum number
2626 // of elements so we do those below. This improves the code quality when
2627 // trying to extract the first element, for example.
2628 }
2629
2630 if (ScalarIVTy->isFloatingPointTy())
2631 StartIdx0 = Builder.CreateSIToFP(StartIdx0, ScalarIVTy);
2632
2633 for (unsigned Lane = 0; Lane < Lanes; ++Lane) {
2634 Value *StartIdx = Builder.CreateBinOp(
2635 AddOp, StartIdx0, getSignedIntOrFpConstant(ScalarIVTy, Lane));
2636 // The step returned by `createStepForVF` is a runtime-evaluated value
2637 // when VF is scalable. Otherwise, it should be folded into a Constant.
2638 assert((VF.isScalable() || isa<Constant>(StartIdx)) &&
2639 "Expected StartIdx to be folded to a constant when VF is not "
2640 "scalable");
2641 auto *Mul = Builder.CreateBinOp(MulOp, StartIdx, Step);
2642 auto *Add = Builder.CreateBinOp(AddOp, ScalarIV, Mul);
2643 State.set(Def, Add, VPIteration(Part, Lane));
2644 recordVectorLoopValueForInductionCast(ID, EntryVal, Add, CastDef, State,
2645 Part, Lane);
2646 }
2647 }
2648 }
2649
packScalarIntoVectorValue(VPValue * Def,const VPIteration & Instance,VPTransformState & State)2650 void InnerLoopVectorizer::packScalarIntoVectorValue(VPValue *Def,
2651 const VPIteration &Instance,
2652 VPTransformState &State) {
2653 Value *ScalarInst = State.get(Def, Instance);
2654 Value *VectorValue = State.get(Def, Instance.Part);
2655 VectorValue = Builder.CreateInsertElement(
2656 VectorValue, ScalarInst,
2657 Instance.Lane.getAsRuntimeExpr(State.Builder, VF));
2658 State.set(Def, VectorValue, Instance.Part);
2659 }
2660
reverseVector(Value * Vec)2661 Value *InnerLoopVectorizer::reverseVector(Value *Vec) {
2662 assert(Vec->getType()->isVectorTy() && "Invalid type");
2663 return Builder.CreateVectorReverse(Vec, "reverse");
2664 }
2665
2666 // Return whether we allow using masked interleave-groups (for dealing with
2667 // strided loads/stores that reside in predicated blocks, or for dealing
2668 // with gaps).
useMaskedInterleavedAccesses(const TargetTransformInfo & TTI)2669 static bool useMaskedInterleavedAccesses(const TargetTransformInfo &TTI) {
2670 // If an override option has been passed in for interleaved accesses, use it.
2671 if (EnableMaskedInterleavedMemAccesses.getNumOccurrences() > 0)
2672 return EnableMaskedInterleavedMemAccesses;
2673
2674 return TTI.enableMaskedInterleavedAccessVectorization();
2675 }
2676
2677 // Try to vectorize the interleave group that \p Instr belongs to.
2678 //
2679 // E.g. Translate following interleaved load group (factor = 3):
2680 // for (i = 0; i < N; i+=3) {
2681 // R = Pic[i]; // Member of index 0
2682 // G = Pic[i+1]; // Member of index 1
2683 // B = Pic[i+2]; // Member of index 2
2684 // ... // do something to R, G, B
2685 // }
2686 // To:
2687 // %wide.vec = load <12 x i32> ; Read 4 tuples of R,G,B
2688 // %R.vec = shuffle %wide.vec, poison, <0, 3, 6, 9> ; R elements
2689 // %G.vec = shuffle %wide.vec, poison, <1, 4, 7, 10> ; G elements
2690 // %B.vec = shuffle %wide.vec, poison, <2, 5, 8, 11> ; B elements
2691 //
2692 // Or translate following interleaved store group (factor = 3):
2693 // for (i = 0; i < N; i+=3) {
2694 // ... do something to R, G, B
2695 // Pic[i] = R; // Member of index 0
2696 // Pic[i+1] = G; // Member of index 1
2697 // Pic[i+2] = B; // Member of index 2
2698 // }
2699 // To:
2700 // %R_G.vec = shuffle %R.vec, %G.vec, <0, 1, 2, ..., 7>
2701 // %B_U.vec = shuffle %B.vec, poison, <0, 1, 2, 3, u, u, u, u>
2702 // %interleaved.vec = shuffle %R_G.vec, %B_U.vec,
2703 // <0, 4, 8, 1, 5, 9, 2, 6, 10, 3, 7, 11> ; Interleave R,G,B elements
2704 // store <12 x i32> %interleaved.vec ; Write 4 tuples of R,G,B
vectorizeInterleaveGroup(const InterleaveGroup<Instruction> * Group,ArrayRef<VPValue * > VPDefs,VPTransformState & State,VPValue * Addr,ArrayRef<VPValue * > StoredValues,VPValue * BlockInMask)2705 void InnerLoopVectorizer::vectorizeInterleaveGroup(
2706 const InterleaveGroup<Instruction> *Group, ArrayRef<VPValue *> VPDefs,
2707 VPTransformState &State, VPValue *Addr, ArrayRef<VPValue *> StoredValues,
2708 VPValue *BlockInMask) {
2709 Instruction *Instr = Group->getInsertPos();
2710 const DataLayout &DL = Instr->getModule()->getDataLayout();
2711
2712 // Prepare for the vector type of the interleaved load/store.
2713 Type *ScalarTy = getLoadStoreType(Instr);
2714 unsigned InterleaveFactor = Group->getFactor();
2715 assert(!VF.isScalable() && "scalable vectors not yet supported.");
2716 auto *VecTy = VectorType::get(ScalarTy, VF * InterleaveFactor);
2717
2718 // Prepare for the new pointers.
2719 SmallVector<Value *, 2> AddrParts;
2720 unsigned Index = Group->getIndex(Instr);
2721
2722 // TODO: extend the masked interleaved-group support to reversed access.
2723 assert((!BlockInMask || !Group->isReverse()) &&
2724 "Reversed masked interleave-group not supported.");
2725
2726 // If the group is reverse, adjust the index to refer to the last vector lane
2727 // instead of the first. We adjust the index from the first vector lane,
2728 // rather than directly getting the pointer for lane VF - 1, because the
2729 // pointer operand of the interleaved access is supposed to be uniform. For
2730 // uniform instructions, we're only required to generate a value for the
2731 // first vector lane in each unroll iteration.
2732 if (Group->isReverse())
2733 Index += (VF.getKnownMinValue() - 1) * Group->getFactor();
2734
2735 for (unsigned Part = 0; Part < UF; Part++) {
2736 Value *AddrPart = State.get(Addr, VPIteration(Part, 0));
2737 setDebugLocFromInst(AddrPart);
2738
2739 // Notice current instruction could be any index. Need to adjust the address
2740 // to the member of index 0.
2741 //
2742 // E.g. a = A[i+1]; // Member of index 1 (Current instruction)
2743 // b = A[i]; // Member of index 0
2744 // Current pointer is pointed to A[i+1], adjust it to A[i].
2745 //
2746 // E.g. A[i+1] = a; // Member of index 1
2747 // A[i] = b; // Member of index 0
2748 // A[i+2] = c; // Member of index 2 (Current instruction)
2749 // Current pointer is pointed to A[i+2], adjust it to A[i].
2750
2751 bool InBounds = false;
2752 if (auto *gep = dyn_cast<GetElementPtrInst>(AddrPart->stripPointerCasts()))
2753 InBounds = gep->isInBounds();
2754 AddrPart = Builder.CreateGEP(ScalarTy, AddrPart, Builder.getInt32(-Index));
2755 cast<GetElementPtrInst>(AddrPart)->setIsInBounds(InBounds);
2756
2757 // Cast to the vector pointer type.
2758 unsigned AddressSpace = AddrPart->getType()->getPointerAddressSpace();
2759 Type *PtrTy = VecTy->getPointerTo(AddressSpace);
2760 AddrParts.push_back(Builder.CreateBitCast(AddrPart, PtrTy));
2761 }
2762
2763 setDebugLocFromInst(Instr);
2764 Value *PoisonVec = PoisonValue::get(VecTy);
2765
2766 Value *MaskForGaps = nullptr;
2767 if (Group->requiresScalarEpilogue() && !Cost->isScalarEpilogueAllowed()) {
2768 MaskForGaps = createBitMaskForGaps(Builder, VF.getKnownMinValue(), *Group);
2769 assert(MaskForGaps && "Mask for Gaps is required but it is null");
2770 }
2771
2772 // Vectorize the interleaved load group.
2773 if (isa<LoadInst>(Instr)) {
2774 // For each unroll part, create a wide load for the group.
2775 SmallVector<Value *, 2> NewLoads;
2776 for (unsigned Part = 0; Part < UF; Part++) {
2777 Instruction *NewLoad;
2778 if (BlockInMask || MaskForGaps) {
2779 assert(useMaskedInterleavedAccesses(*TTI) &&
2780 "masked interleaved groups are not allowed.");
2781 Value *GroupMask = MaskForGaps;
2782 if (BlockInMask) {
2783 Value *BlockInMaskPart = State.get(BlockInMask, Part);
2784 Value *ShuffledMask = Builder.CreateShuffleVector(
2785 BlockInMaskPart,
2786 createReplicatedMask(InterleaveFactor, VF.getKnownMinValue()),
2787 "interleaved.mask");
2788 GroupMask = MaskForGaps
2789 ? Builder.CreateBinOp(Instruction::And, ShuffledMask,
2790 MaskForGaps)
2791 : ShuffledMask;
2792 }
2793 NewLoad =
2794 Builder.CreateMaskedLoad(VecTy, AddrParts[Part], Group->getAlign(),
2795 GroupMask, PoisonVec, "wide.masked.vec");
2796 }
2797 else
2798 NewLoad = Builder.CreateAlignedLoad(VecTy, AddrParts[Part],
2799 Group->getAlign(), "wide.vec");
2800 Group->addMetadata(NewLoad);
2801 NewLoads.push_back(NewLoad);
2802 }
2803
2804 // For each member in the group, shuffle out the appropriate data from the
2805 // wide loads.
2806 unsigned J = 0;
2807 for (unsigned I = 0; I < InterleaveFactor; ++I) {
2808 Instruction *Member = Group->getMember(I);
2809
2810 // Skip the gaps in the group.
2811 if (!Member)
2812 continue;
2813
2814 auto StrideMask =
2815 createStrideMask(I, InterleaveFactor, VF.getKnownMinValue());
2816 for (unsigned Part = 0; Part < UF; Part++) {
2817 Value *StridedVec = Builder.CreateShuffleVector(
2818 NewLoads[Part], StrideMask, "strided.vec");
2819
2820 // If this member has different type, cast the result type.
2821 if (Member->getType() != ScalarTy) {
2822 assert(!VF.isScalable() && "VF is assumed to be non scalable.");
2823 VectorType *OtherVTy = VectorType::get(Member->getType(), VF);
2824 StridedVec = createBitOrPointerCast(StridedVec, OtherVTy, DL);
2825 }
2826
2827 if (Group->isReverse())
2828 StridedVec = reverseVector(StridedVec);
2829
2830 State.set(VPDefs[J], StridedVec, Part);
2831 }
2832 ++J;
2833 }
2834 return;
2835 }
2836
2837 // The sub vector type for current instruction.
2838 auto *SubVT = VectorType::get(ScalarTy, VF);
2839
2840 // Vectorize the interleaved store group.
2841 for (unsigned Part = 0; Part < UF; Part++) {
2842 // Collect the stored vector from each member.
2843 SmallVector<Value *, 4> StoredVecs;
2844 for (unsigned i = 0; i < InterleaveFactor; i++) {
2845 // Interleaved store group doesn't allow a gap, so each index has a member
2846 assert(Group->getMember(i) && "Fail to get a member from an interleaved store group");
2847
2848 Value *StoredVec = State.get(StoredValues[i], Part);
2849
2850 if (Group->isReverse())
2851 StoredVec = reverseVector(StoredVec);
2852
2853 // If this member has different type, cast it to a unified type.
2854
2855 if (StoredVec->getType() != SubVT)
2856 StoredVec = createBitOrPointerCast(StoredVec, SubVT, DL);
2857
2858 StoredVecs.push_back(StoredVec);
2859 }
2860
2861 // Concatenate all vectors into a wide vector.
2862 Value *WideVec = concatenateVectors(Builder, StoredVecs);
2863
2864 // Interleave the elements in the wide vector.
2865 Value *IVec = Builder.CreateShuffleVector(
2866 WideVec, createInterleaveMask(VF.getKnownMinValue(), InterleaveFactor),
2867 "interleaved.vec");
2868
2869 Instruction *NewStoreInstr;
2870 if (BlockInMask) {
2871 Value *BlockInMaskPart = State.get(BlockInMask, Part);
2872 Value *ShuffledMask = Builder.CreateShuffleVector(
2873 BlockInMaskPart,
2874 createReplicatedMask(InterleaveFactor, VF.getKnownMinValue()),
2875 "interleaved.mask");
2876 NewStoreInstr = Builder.CreateMaskedStore(
2877 IVec, AddrParts[Part], Group->getAlign(), ShuffledMask);
2878 }
2879 else
2880 NewStoreInstr =
2881 Builder.CreateAlignedStore(IVec, AddrParts[Part], Group->getAlign());
2882
2883 Group->addMetadata(NewStoreInstr);
2884 }
2885 }
2886
vectorizeMemoryInstruction(Instruction * Instr,VPTransformState & State,VPValue * Def,VPValue * Addr,VPValue * StoredValue,VPValue * BlockInMask)2887 void InnerLoopVectorizer::vectorizeMemoryInstruction(
2888 Instruction *Instr, VPTransformState &State, VPValue *Def, VPValue *Addr,
2889 VPValue *StoredValue, VPValue *BlockInMask) {
2890 // Attempt to issue a wide load.
2891 LoadInst *LI = dyn_cast<LoadInst>(Instr);
2892 StoreInst *SI = dyn_cast<StoreInst>(Instr);
2893
2894 assert((LI || SI) && "Invalid Load/Store instruction");
2895 assert((!SI || StoredValue) && "No stored value provided for widened store");
2896 assert((!LI || !StoredValue) && "Stored value provided for widened load");
2897
2898 LoopVectorizationCostModel::InstWidening Decision =
2899 Cost->getWideningDecision(Instr, VF);
2900 assert((Decision == LoopVectorizationCostModel::CM_Widen ||
2901 Decision == LoopVectorizationCostModel::CM_Widen_Reverse ||
2902 Decision == LoopVectorizationCostModel::CM_GatherScatter) &&
2903 "CM decision is not to widen the memory instruction");
2904
2905 Type *ScalarDataTy = getLoadStoreType(Instr);
2906
2907 auto *DataTy = VectorType::get(ScalarDataTy, VF);
2908 const Align Alignment = getLoadStoreAlignment(Instr);
2909
2910 // Determine if the pointer operand of the access is either consecutive or
2911 // reverse consecutive.
2912 bool Reverse = (Decision == LoopVectorizationCostModel::CM_Widen_Reverse);
2913 bool ConsecutiveStride =
2914 Reverse || (Decision == LoopVectorizationCostModel::CM_Widen);
2915 bool CreateGatherScatter =
2916 (Decision == LoopVectorizationCostModel::CM_GatherScatter);
2917
2918 // Either Ptr feeds a vector load/store, or a vector GEP should feed a vector
2919 // gather/scatter. Otherwise Decision should have been to Scalarize.
2920 assert((ConsecutiveStride || CreateGatherScatter) &&
2921 "The instruction should be scalarized");
2922 (void)ConsecutiveStride;
2923
2924 VectorParts BlockInMaskParts(UF);
2925 bool isMaskRequired = BlockInMask;
2926 if (isMaskRequired)
2927 for (unsigned Part = 0; Part < UF; ++Part)
2928 BlockInMaskParts[Part] = State.get(BlockInMask, Part);
2929
2930 const auto CreateVecPtr = [&](unsigned Part, Value *Ptr) -> Value * {
2931 // Calculate the pointer for the specific unroll-part.
2932 GetElementPtrInst *PartPtr = nullptr;
2933
2934 bool InBounds = false;
2935 if (auto *gep = dyn_cast<GetElementPtrInst>(Ptr->stripPointerCasts()))
2936 InBounds = gep->isInBounds();
2937 if (Reverse) {
2938 // If the address is consecutive but reversed, then the
2939 // wide store needs to start at the last vector element.
2940 // RunTimeVF = VScale * VF.getKnownMinValue()
2941 // For fixed-width VScale is 1, then RunTimeVF = VF.getKnownMinValue()
2942 Value *RunTimeVF = getRuntimeVF(Builder, Builder.getInt32Ty(), VF);
2943 // NumElt = -Part * RunTimeVF
2944 Value *NumElt = Builder.CreateMul(Builder.getInt32(-Part), RunTimeVF);
2945 // LastLane = 1 - RunTimeVF
2946 Value *LastLane = Builder.CreateSub(Builder.getInt32(1), RunTimeVF);
2947 PartPtr =
2948 cast<GetElementPtrInst>(Builder.CreateGEP(ScalarDataTy, Ptr, NumElt));
2949 PartPtr->setIsInBounds(InBounds);
2950 PartPtr = cast<GetElementPtrInst>(
2951 Builder.CreateGEP(ScalarDataTy, PartPtr, LastLane));
2952 PartPtr->setIsInBounds(InBounds);
2953 if (isMaskRequired) // Reverse of a null all-one mask is a null mask.
2954 BlockInMaskParts[Part] = reverseVector(BlockInMaskParts[Part]);
2955 } else {
2956 Value *Increment = createStepForVF(Builder, Builder.getInt32(Part), VF);
2957 PartPtr = cast<GetElementPtrInst>(
2958 Builder.CreateGEP(ScalarDataTy, Ptr, Increment));
2959 PartPtr->setIsInBounds(InBounds);
2960 }
2961
2962 unsigned AddressSpace = Ptr->getType()->getPointerAddressSpace();
2963 return Builder.CreateBitCast(PartPtr, DataTy->getPointerTo(AddressSpace));
2964 };
2965
2966 // Handle Stores:
2967 if (SI) {
2968 setDebugLocFromInst(SI);
2969
2970 for (unsigned Part = 0; Part < UF; ++Part) {
2971 Instruction *NewSI = nullptr;
2972 Value *StoredVal = State.get(StoredValue, Part);
2973 if (CreateGatherScatter) {
2974 Value *MaskPart = isMaskRequired ? BlockInMaskParts[Part] : nullptr;
2975 Value *VectorGep = State.get(Addr, Part);
2976 NewSI = Builder.CreateMaskedScatter(StoredVal, VectorGep, Alignment,
2977 MaskPart);
2978 } else {
2979 if (Reverse) {
2980 // If we store to reverse consecutive memory locations, then we need
2981 // to reverse the order of elements in the stored value.
2982 StoredVal = reverseVector(StoredVal);
2983 // We don't want to update the value in the map as it might be used in
2984 // another expression. So don't call resetVectorValue(StoredVal).
2985 }
2986 auto *VecPtr = CreateVecPtr(Part, State.get(Addr, VPIteration(0, 0)));
2987 if (isMaskRequired)
2988 NewSI = Builder.CreateMaskedStore(StoredVal, VecPtr, Alignment,
2989 BlockInMaskParts[Part]);
2990 else
2991 NewSI = Builder.CreateAlignedStore(StoredVal, VecPtr, Alignment);
2992 }
2993 addMetadata(NewSI, SI);
2994 }
2995 return;
2996 }
2997
2998 // Handle loads.
2999 assert(LI && "Must have a load instruction");
3000 setDebugLocFromInst(LI);
3001 for (unsigned Part = 0; Part < UF; ++Part) {
3002 Value *NewLI;
3003 if (CreateGatherScatter) {
3004 Value *MaskPart = isMaskRequired ? BlockInMaskParts[Part] : nullptr;
3005 Value *VectorGep = State.get(Addr, Part);
3006 NewLI = Builder.CreateMaskedGather(DataTy, VectorGep, Alignment, MaskPart,
3007 nullptr, "wide.masked.gather");
3008 addMetadata(NewLI, LI);
3009 } else {
3010 auto *VecPtr = CreateVecPtr(Part, State.get(Addr, VPIteration(0, 0)));
3011 if (isMaskRequired)
3012 NewLI = Builder.CreateMaskedLoad(
3013 DataTy, VecPtr, Alignment, BlockInMaskParts[Part],
3014 PoisonValue::get(DataTy), "wide.masked.load");
3015 else
3016 NewLI =
3017 Builder.CreateAlignedLoad(DataTy, VecPtr, Alignment, "wide.load");
3018
3019 // Add metadata to the load, but setVectorValue to the reverse shuffle.
3020 addMetadata(NewLI, LI);
3021 if (Reverse)
3022 NewLI = reverseVector(NewLI);
3023 }
3024
3025 State.set(Def, NewLI, Part);
3026 }
3027 }
3028
scalarizeInstruction(Instruction * Instr,VPValue * Def,VPUser & User,const VPIteration & Instance,bool IfPredicateInstr,VPTransformState & State)3029 void InnerLoopVectorizer::scalarizeInstruction(Instruction *Instr, VPValue *Def,
3030 VPUser &User,
3031 const VPIteration &Instance,
3032 bool IfPredicateInstr,
3033 VPTransformState &State) {
3034 assert(!Instr->getType()->isAggregateType() && "Can't handle vectors");
3035
3036 // llvm.experimental.noalias.scope.decl intrinsics must only be duplicated for
3037 // the first lane and part.
3038 if (isa<NoAliasScopeDeclInst>(Instr))
3039 if (!Instance.isFirstIteration())
3040 return;
3041
3042 setDebugLocFromInst(Instr);
3043
3044 // Does this instruction return a value ?
3045 bool IsVoidRetTy = Instr->getType()->isVoidTy();
3046
3047 Instruction *Cloned = Instr->clone();
3048 if (!IsVoidRetTy)
3049 Cloned->setName(Instr->getName() + ".cloned");
3050
3051 State.Builder.SetInsertPoint(Builder.GetInsertBlock(),
3052 Builder.GetInsertPoint());
3053 // Replace the operands of the cloned instructions with their scalar
3054 // equivalents in the new loop.
3055 for (unsigned op = 0, e = User.getNumOperands(); op != e; ++op) {
3056 auto *Operand = dyn_cast<Instruction>(Instr->getOperand(op));
3057 auto InputInstance = Instance;
3058 if (!Operand || !OrigLoop->contains(Operand) ||
3059 (Cost->isUniformAfterVectorization(Operand, State.VF)))
3060 InputInstance.Lane = VPLane::getFirstLane();
3061 auto *NewOp = State.get(User.getOperand(op), InputInstance);
3062 Cloned->setOperand(op, NewOp);
3063 }
3064 addNewMetadata(Cloned, Instr);
3065
3066 // Place the cloned scalar in the new loop.
3067 Builder.Insert(Cloned);
3068
3069 State.set(Def, Cloned, Instance);
3070
3071 // If we just cloned a new assumption, add it the assumption cache.
3072 if (auto *II = dyn_cast<AssumeInst>(Cloned))
3073 AC->registerAssumption(II);
3074
3075 // End if-block.
3076 if (IfPredicateInstr)
3077 PredicatedInstructions.push_back(Cloned);
3078 }
3079
createInductionVariable(Loop * L,Value * Start,Value * End,Value * Step,Instruction * DL)3080 PHINode *InnerLoopVectorizer::createInductionVariable(Loop *L, Value *Start,
3081 Value *End, Value *Step,
3082 Instruction *DL) {
3083 BasicBlock *Header = L->getHeader();
3084 BasicBlock *Latch = L->getLoopLatch();
3085 // As we're just creating this loop, it's possible no latch exists
3086 // yet. If so, use the header as this will be a single block loop.
3087 if (!Latch)
3088 Latch = Header;
3089
3090 IRBuilder<> B(&*Header->getFirstInsertionPt());
3091 Instruction *OldInst = getDebugLocFromInstOrOperands(OldInduction);
3092 setDebugLocFromInst(OldInst, &B);
3093 auto *Induction = B.CreatePHI(Start->getType(), 2, "index");
3094
3095 B.SetInsertPoint(Latch->getTerminator());
3096 setDebugLocFromInst(OldInst, &B);
3097
3098 // Create i+1 and fill the PHINode.
3099 //
3100 // If the tail is not folded, we know that End - Start >= Step (either
3101 // statically or through the minimum iteration checks). We also know that both
3102 // Start % Step == 0 and End % Step == 0. We exit the vector loop if %IV +
3103 // %Step == %End. Hence we must exit the loop before %IV + %Step unsigned
3104 // overflows and we can mark the induction increment as NUW.
3105 Value *Next = B.CreateAdd(Induction, Step, "index.next",
3106 /*NUW=*/!Cost->foldTailByMasking(), /*NSW=*/false);
3107 Induction->addIncoming(Start, L->getLoopPreheader());
3108 Induction->addIncoming(Next, Latch);
3109 // Create the compare.
3110 Value *ICmp = B.CreateICmpEQ(Next, End);
3111 B.CreateCondBr(ICmp, L->getUniqueExitBlock(), Header);
3112
3113 // Now we have two terminators. Remove the old one from the block.
3114 Latch->getTerminator()->eraseFromParent();
3115
3116 return Induction;
3117 }
3118
getOrCreateTripCount(Loop * L)3119 Value *InnerLoopVectorizer::getOrCreateTripCount(Loop *L) {
3120 if (TripCount)
3121 return TripCount;
3122
3123 assert(L && "Create Trip Count for null loop.");
3124 IRBuilder<> Builder(L->getLoopPreheader()->getTerminator());
3125 // Find the loop boundaries.
3126 ScalarEvolution *SE = PSE.getSE();
3127 const SCEV *BackedgeTakenCount = PSE.getBackedgeTakenCount();
3128 assert(!isa<SCEVCouldNotCompute>(BackedgeTakenCount) &&
3129 "Invalid loop count");
3130
3131 Type *IdxTy = Legal->getWidestInductionType();
3132 assert(IdxTy && "No type for induction");
3133
3134 // The exit count might have the type of i64 while the phi is i32. This can
3135 // happen if we have an induction variable that is sign extended before the
3136 // compare. The only way that we get a backedge taken count is that the
3137 // induction variable was signed and as such will not overflow. In such a case
3138 // truncation is legal.
3139 if (SE->getTypeSizeInBits(BackedgeTakenCount->getType()) >
3140 IdxTy->getPrimitiveSizeInBits())
3141 BackedgeTakenCount = SE->getTruncateOrNoop(BackedgeTakenCount, IdxTy);
3142 BackedgeTakenCount = SE->getNoopOrZeroExtend(BackedgeTakenCount, IdxTy);
3143
3144 // Get the total trip count from the count by adding 1.
3145 const SCEV *ExitCount = SE->getAddExpr(
3146 BackedgeTakenCount, SE->getOne(BackedgeTakenCount->getType()));
3147
3148 const DataLayout &DL = L->getHeader()->getModule()->getDataLayout();
3149
3150 // Expand the trip count and place the new instructions in the preheader.
3151 // Notice that the pre-header does not change, only the loop body.
3152 SCEVExpander Exp(*SE, DL, "induction");
3153
3154 // Count holds the overall loop count (N).
3155 TripCount = Exp.expandCodeFor(ExitCount, ExitCount->getType(),
3156 L->getLoopPreheader()->getTerminator());
3157
3158 if (TripCount->getType()->isPointerTy())
3159 TripCount =
3160 CastInst::CreatePointerCast(TripCount, IdxTy, "exitcount.ptrcnt.to.int",
3161 L->getLoopPreheader()->getTerminator());
3162
3163 return TripCount;
3164 }
3165
getOrCreateVectorTripCount(Loop * L)3166 Value *InnerLoopVectorizer::getOrCreateVectorTripCount(Loop *L) {
3167 if (VectorTripCount)
3168 return VectorTripCount;
3169
3170 Value *TC = getOrCreateTripCount(L);
3171 IRBuilder<> Builder(L->getLoopPreheader()->getTerminator());
3172
3173 Type *Ty = TC->getType();
3174 // This is where we can make the step a runtime constant.
3175 Value *Step = createStepForVF(Builder, ConstantInt::get(Ty, UF), VF);
3176
3177 // If the tail is to be folded by masking, round the number of iterations N
3178 // up to a multiple of Step instead of rounding down. This is done by first
3179 // adding Step-1 and then rounding down. Note that it's ok if this addition
3180 // overflows: the vector induction variable will eventually wrap to zero given
3181 // that it starts at zero and its Step is a power of two; the loop will then
3182 // exit, with the last early-exit vector comparison also producing all-true.
3183 if (Cost->foldTailByMasking()) {
3184 assert(isPowerOf2_32(VF.getKnownMinValue() * UF) &&
3185 "VF*UF must be a power of 2 when folding tail by masking");
3186 assert(!VF.isScalable() &&
3187 "Tail folding not yet supported for scalable vectors");
3188 TC = Builder.CreateAdd(
3189 TC, ConstantInt::get(Ty, VF.getKnownMinValue() * UF - 1), "n.rnd.up");
3190 }
3191
3192 // Now we need to generate the expression for the part of the loop that the
3193 // vectorized body will execute. This is equal to N - (N % Step) if scalar
3194 // iterations are not required for correctness, or N - Step, otherwise. Step
3195 // is equal to the vectorization factor (number of SIMD elements) times the
3196 // unroll factor (number of SIMD instructions).
3197 Value *R = Builder.CreateURem(TC, Step, "n.mod.vf");
3198
3199 // There are cases where we *must* run at least one iteration in the remainder
3200 // loop. See the cost model for when this can happen. If the step evenly
3201 // divides the trip count, we set the remainder to be equal to the step. If
3202 // the step does not evenly divide the trip count, no adjustment is necessary
3203 // since there will already be scalar iterations. Note that the minimum
3204 // iterations check ensures that N >= Step.
3205 if (Cost->requiresScalarEpilogue(VF)) {
3206 auto *IsZero = Builder.CreateICmpEQ(R, ConstantInt::get(R->getType(), 0));
3207 R = Builder.CreateSelect(IsZero, Step, R);
3208 }
3209
3210 VectorTripCount = Builder.CreateSub(TC, R, "n.vec");
3211
3212 return VectorTripCount;
3213 }
3214
createBitOrPointerCast(Value * V,VectorType * DstVTy,const DataLayout & DL)3215 Value *InnerLoopVectorizer::createBitOrPointerCast(Value *V, VectorType *DstVTy,
3216 const DataLayout &DL) {
3217 // Verify that V is a vector type with same number of elements as DstVTy.
3218 auto *DstFVTy = cast<FixedVectorType>(DstVTy);
3219 unsigned VF = DstFVTy->getNumElements();
3220 auto *SrcVecTy = cast<FixedVectorType>(V->getType());
3221 assert((VF == SrcVecTy->getNumElements()) && "Vector dimensions do not match");
3222 Type *SrcElemTy = SrcVecTy->getElementType();
3223 Type *DstElemTy = DstFVTy->getElementType();
3224 assert((DL.getTypeSizeInBits(SrcElemTy) == DL.getTypeSizeInBits(DstElemTy)) &&
3225 "Vector elements must have same size");
3226
3227 // Do a direct cast if element types are castable.
3228 if (CastInst::isBitOrNoopPointerCastable(SrcElemTy, DstElemTy, DL)) {
3229 return Builder.CreateBitOrPointerCast(V, DstFVTy);
3230 }
3231 // V cannot be directly casted to desired vector type.
3232 // May happen when V is a floating point vector but DstVTy is a vector of
3233 // pointers or vice-versa. Handle this using a two-step bitcast using an
3234 // intermediate Integer type for the bitcast i.e. Ptr <-> Int <-> Float.
3235 assert((DstElemTy->isPointerTy() != SrcElemTy->isPointerTy()) &&
3236 "Only one type should be a pointer type");
3237 assert((DstElemTy->isFloatingPointTy() != SrcElemTy->isFloatingPointTy()) &&
3238 "Only one type should be a floating point type");
3239 Type *IntTy =
3240 IntegerType::getIntNTy(V->getContext(), DL.getTypeSizeInBits(SrcElemTy));
3241 auto *VecIntTy = FixedVectorType::get(IntTy, VF);
3242 Value *CastVal = Builder.CreateBitOrPointerCast(V, VecIntTy);
3243 return Builder.CreateBitOrPointerCast(CastVal, DstFVTy);
3244 }
3245
emitMinimumIterationCountCheck(Loop * L,BasicBlock * Bypass)3246 void InnerLoopVectorizer::emitMinimumIterationCountCheck(Loop *L,
3247 BasicBlock *Bypass) {
3248 Value *Count = getOrCreateTripCount(L);
3249 // Reuse existing vector loop preheader for TC checks.
3250 // Note that new preheader block is generated for vector loop.
3251 BasicBlock *const TCCheckBlock = LoopVectorPreHeader;
3252 IRBuilder<> Builder(TCCheckBlock->getTerminator());
3253
3254 // Generate code to check if the loop's trip count is less than VF * UF, or
3255 // equal to it in case a scalar epilogue is required; this implies that the
3256 // vector trip count is zero. This check also covers the case where adding one
3257 // to the backedge-taken count overflowed leading to an incorrect trip count
3258 // of zero. In this case we will also jump to the scalar loop.
3259 auto P = Cost->requiresScalarEpilogue(VF) ? ICmpInst::ICMP_ULE
3260 : ICmpInst::ICMP_ULT;
3261
3262 // If tail is to be folded, vector loop takes care of all iterations.
3263 Value *CheckMinIters = Builder.getFalse();
3264 if (!Cost->foldTailByMasking()) {
3265 Value *Step =
3266 createStepForVF(Builder, ConstantInt::get(Count->getType(), UF), VF);
3267 CheckMinIters = Builder.CreateICmp(P, Count, Step, "min.iters.check");
3268 }
3269 // Create new preheader for vector loop.
3270 LoopVectorPreHeader =
3271 SplitBlock(TCCheckBlock, TCCheckBlock->getTerminator(), DT, LI, nullptr,
3272 "vector.ph");
3273
3274 assert(DT->properlyDominates(DT->getNode(TCCheckBlock),
3275 DT->getNode(Bypass)->getIDom()) &&
3276 "TC check is expected to dominate Bypass");
3277
3278 // Update dominator for Bypass & LoopExit (if needed).
3279 DT->changeImmediateDominator(Bypass, TCCheckBlock);
3280 if (!Cost->requiresScalarEpilogue(VF))
3281 // If there is an epilogue which must run, there's no edge from the
3282 // middle block to exit blocks and thus no need to update the immediate
3283 // dominator of the exit blocks.
3284 DT->changeImmediateDominator(LoopExitBlock, TCCheckBlock);
3285
3286 ReplaceInstWithInst(
3287 TCCheckBlock->getTerminator(),
3288 BranchInst::Create(Bypass, LoopVectorPreHeader, CheckMinIters));
3289 LoopBypassBlocks.push_back(TCCheckBlock);
3290 }
3291
emitSCEVChecks(Loop * L,BasicBlock * Bypass)3292 BasicBlock *InnerLoopVectorizer::emitSCEVChecks(Loop *L, BasicBlock *Bypass) {
3293
3294 BasicBlock *const SCEVCheckBlock =
3295 RTChecks.emitSCEVChecks(L, Bypass, LoopVectorPreHeader, LoopExitBlock);
3296 if (!SCEVCheckBlock)
3297 return nullptr;
3298
3299 assert(!(SCEVCheckBlock->getParent()->hasOptSize() ||
3300 (OptForSizeBasedOnProfile &&
3301 Cost->Hints->getForce() != LoopVectorizeHints::FK_Enabled)) &&
3302 "Cannot SCEV check stride or overflow when optimizing for size");
3303
3304
3305 // Update dominator only if this is first RT check.
3306 if (LoopBypassBlocks.empty()) {
3307 DT->changeImmediateDominator(Bypass, SCEVCheckBlock);
3308 if (!Cost->requiresScalarEpilogue(VF))
3309 // If there is an epilogue which must run, there's no edge from the
3310 // middle block to exit blocks and thus no need to update the immediate
3311 // dominator of the exit blocks.
3312 DT->changeImmediateDominator(LoopExitBlock, SCEVCheckBlock);
3313 }
3314
3315 LoopBypassBlocks.push_back(SCEVCheckBlock);
3316 AddedSafetyChecks = true;
3317 return SCEVCheckBlock;
3318 }
3319
emitMemRuntimeChecks(Loop * L,BasicBlock * Bypass)3320 BasicBlock *InnerLoopVectorizer::emitMemRuntimeChecks(Loop *L,
3321 BasicBlock *Bypass) {
3322 // VPlan-native path does not do any analysis for runtime checks currently.
3323 if (EnableVPlanNativePath)
3324 return nullptr;
3325
3326 BasicBlock *const MemCheckBlock =
3327 RTChecks.emitMemRuntimeChecks(L, Bypass, LoopVectorPreHeader);
3328
3329 // Check if we generated code that checks in runtime if arrays overlap. We put
3330 // the checks into a separate block to make the more common case of few
3331 // elements faster.
3332 if (!MemCheckBlock)
3333 return nullptr;
3334
3335 if (MemCheckBlock->getParent()->hasOptSize() || OptForSizeBasedOnProfile) {
3336 assert(Cost->Hints->getForce() == LoopVectorizeHints::FK_Enabled &&
3337 "Cannot emit memory checks when optimizing for size, unless forced "
3338 "to vectorize.");
3339 ORE->emit([&]() {
3340 return OptimizationRemarkAnalysis(DEBUG_TYPE, "VectorizationCodeSize",
3341 L->getStartLoc(), L->getHeader())
3342 << "Code-size may be reduced by not forcing "
3343 "vectorization, or by source-code modifications "
3344 "eliminating the need for runtime checks "
3345 "(e.g., adding 'restrict').";
3346 });
3347 }
3348
3349 LoopBypassBlocks.push_back(MemCheckBlock);
3350
3351 AddedSafetyChecks = true;
3352
3353 // We currently don't use LoopVersioning for the actual loop cloning but we
3354 // still use it to add the noalias metadata.
3355 LVer = std::make_unique<LoopVersioning>(
3356 *Legal->getLAI(),
3357 Legal->getLAI()->getRuntimePointerChecking()->getChecks(), OrigLoop, LI,
3358 DT, PSE.getSE());
3359 LVer->prepareNoAliasMetadata();
3360 return MemCheckBlock;
3361 }
3362
emitTransformedIndex(IRBuilder<> & B,Value * Index,ScalarEvolution * SE,const DataLayout & DL,const InductionDescriptor & ID) const3363 Value *InnerLoopVectorizer::emitTransformedIndex(
3364 IRBuilder<> &B, Value *Index, ScalarEvolution *SE, const DataLayout &DL,
3365 const InductionDescriptor &ID) const {
3366
3367 SCEVExpander Exp(*SE, DL, "induction");
3368 auto Step = ID.getStep();
3369 auto StartValue = ID.getStartValue();
3370 assert(Index->getType()->getScalarType() == Step->getType() &&
3371 "Index scalar type does not match StepValue type");
3372
3373 // Note: the IR at this point is broken. We cannot use SE to create any new
3374 // SCEV and then expand it, hoping that SCEV's simplification will give us
3375 // a more optimal code. Unfortunately, attempt of doing so on invalid IR may
3376 // lead to various SCEV crashes. So all we can do is to use builder and rely
3377 // on InstCombine for future simplifications. Here we handle some trivial
3378 // cases only.
3379 auto CreateAdd = [&B](Value *X, Value *Y) {
3380 assert(X->getType() == Y->getType() && "Types don't match!");
3381 if (auto *CX = dyn_cast<ConstantInt>(X))
3382 if (CX->isZero())
3383 return Y;
3384 if (auto *CY = dyn_cast<ConstantInt>(Y))
3385 if (CY->isZero())
3386 return X;
3387 return B.CreateAdd(X, Y);
3388 };
3389
3390 // We allow X to be a vector type, in which case Y will potentially be
3391 // splatted into a vector with the same element count.
3392 auto CreateMul = [&B](Value *X, Value *Y) {
3393 assert(X->getType()->getScalarType() == Y->getType() &&
3394 "Types don't match!");
3395 if (auto *CX = dyn_cast<ConstantInt>(X))
3396 if (CX->isOne())
3397 return Y;
3398 if (auto *CY = dyn_cast<ConstantInt>(Y))
3399 if (CY->isOne())
3400 return X;
3401 VectorType *XVTy = dyn_cast<VectorType>(X->getType());
3402 if (XVTy && !isa<VectorType>(Y->getType()))
3403 Y = B.CreateVectorSplat(XVTy->getElementCount(), Y);
3404 return B.CreateMul(X, Y);
3405 };
3406
3407 // Get a suitable insert point for SCEV expansion. For blocks in the vector
3408 // loop, choose the end of the vector loop header (=LoopVectorBody), because
3409 // the DomTree is not kept up-to-date for additional blocks generated in the
3410 // vector loop. By using the header as insertion point, we guarantee that the
3411 // expanded instructions dominate all their uses.
3412 auto GetInsertPoint = [this, &B]() {
3413 BasicBlock *InsertBB = B.GetInsertPoint()->getParent();
3414 if (InsertBB != LoopVectorBody &&
3415 LI->getLoopFor(LoopVectorBody) == LI->getLoopFor(InsertBB))
3416 return LoopVectorBody->getTerminator();
3417 return &*B.GetInsertPoint();
3418 };
3419
3420 switch (ID.getKind()) {
3421 case InductionDescriptor::IK_IntInduction: {
3422 assert(!isa<VectorType>(Index->getType()) &&
3423 "Vector indices not supported for integer inductions yet");
3424 assert(Index->getType() == StartValue->getType() &&
3425 "Index type does not match StartValue type");
3426 if (ID.getConstIntStepValue() && ID.getConstIntStepValue()->isMinusOne())
3427 return B.CreateSub(StartValue, Index);
3428 auto *Offset = CreateMul(
3429 Index, Exp.expandCodeFor(Step, Index->getType(), GetInsertPoint()));
3430 return CreateAdd(StartValue, Offset);
3431 }
3432 case InductionDescriptor::IK_PtrInduction: {
3433 assert(isa<SCEVConstant>(Step) &&
3434 "Expected constant step for pointer induction");
3435 return B.CreateGEP(
3436 StartValue->getType()->getPointerElementType(), StartValue,
3437 CreateMul(Index,
3438 Exp.expandCodeFor(Step, Index->getType()->getScalarType(),
3439 GetInsertPoint())));
3440 }
3441 case InductionDescriptor::IK_FpInduction: {
3442 assert(!isa<VectorType>(Index->getType()) &&
3443 "Vector indices not supported for FP inductions yet");
3444 assert(Step->getType()->isFloatingPointTy() && "Expected FP Step value");
3445 auto InductionBinOp = ID.getInductionBinOp();
3446 assert(InductionBinOp &&
3447 (InductionBinOp->getOpcode() == Instruction::FAdd ||
3448 InductionBinOp->getOpcode() == Instruction::FSub) &&
3449 "Original bin op should be defined for FP induction");
3450
3451 Value *StepValue = cast<SCEVUnknown>(Step)->getValue();
3452 Value *MulExp = B.CreateFMul(StepValue, Index);
3453 return B.CreateBinOp(InductionBinOp->getOpcode(), StartValue, MulExp,
3454 "induction");
3455 }
3456 case InductionDescriptor::IK_NoInduction:
3457 return nullptr;
3458 }
3459 llvm_unreachable("invalid enum");
3460 }
3461
createVectorLoopSkeleton(StringRef Prefix)3462 Loop *InnerLoopVectorizer::createVectorLoopSkeleton(StringRef Prefix) {
3463 LoopScalarBody = OrigLoop->getHeader();
3464 LoopVectorPreHeader = OrigLoop->getLoopPreheader();
3465 assert(LoopVectorPreHeader && "Invalid loop structure");
3466 LoopExitBlock = OrigLoop->getUniqueExitBlock(); // may be nullptr
3467 assert((LoopExitBlock || Cost->requiresScalarEpilogue(VF)) &&
3468 "multiple exit loop without required epilogue?");
3469
3470 LoopMiddleBlock =
3471 SplitBlock(LoopVectorPreHeader, LoopVectorPreHeader->getTerminator(), DT,
3472 LI, nullptr, Twine(Prefix) + "middle.block");
3473 LoopScalarPreHeader =
3474 SplitBlock(LoopMiddleBlock, LoopMiddleBlock->getTerminator(), DT, LI,
3475 nullptr, Twine(Prefix) + "scalar.ph");
3476
3477 auto *ScalarLatchTerm = OrigLoop->getLoopLatch()->getTerminator();
3478
3479 // Set up the middle block terminator. Two cases:
3480 // 1) If we know that we must execute the scalar epilogue, emit an
3481 // unconditional branch.
3482 // 2) Otherwise, we must have a single unique exit block (due to how we
3483 // implement the multiple exit case). In this case, set up a conditonal
3484 // branch from the middle block to the loop scalar preheader, and the
3485 // exit block. completeLoopSkeleton will update the condition to use an
3486 // iteration check, if required to decide whether to execute the remainder.
3487 BranchInst *BrInst = Cost->requiresScalarEpilogue(VF) ?
3488 BranchInst::Create(LoopScalarPreHeader) :
3489 BranchInst::Create(LoopExitBlock, LoopScalarPreHeader,
3490 Builder.getTrue());
3491 BrInst->setDebugLoc(ScalarLatchTerm->getDebugLoc());
3492 ReplaceInstWithInst(LoopMiddleBlock->getTerminator(), BrInst);
3493
3494 // We intentionally don't let SplitBlock to update LoopInfo since
3495 // LoopVectorBody should belong to another loop than LoopVectorPreHeader.
3496 // LoopVectorBody is explicitly added to the correct place few lines later.
3497 LoopVectorBody =
3498 SplitBlock(LoopVectorPreHeader, LoopVectorPreHeader->getTerminator(), DT,
3499 nullptr, nullptr, Twine(Prefix) + "vector.body");
3500
3501 // Update dominator for loop exit.
3502 if (!Cost->requiresScalarEpilogue(VF))
3503 // If there is an epilogue which must run, there's no edge from the
3504 // middle block to exit blocks and thus no need to update the immediate
3505 // dominator of the exit blocks.
3506 DT->changeImmediateDominator(LoopExitBlock, LoopMiddleBlock);
3507
3508 // Create and register the new vector loop.
3509 Loop *Lp = LI->AllocateLoop();
3510 Loop *ParentLoop = OrigLoop->getParentLoop();
3511
3512 // Insert the new loop into the loop nest and register the new basic blocks
3513 // before calling any utilities such as SCEV that require valid LoopInfo.
3514 if (ParentLoop) {
3515 ParentLoop->addChildLoop(Lp);
3516 } else {
3517 LI->addTopLevelLoop(Lp);
3518 }
3519 Lp->addBasicBlockToLoop(LoopVectorBody, *LI);
3520 return Lp;
3521 }
3522
createInductionResumeValues(Loop * L,Value * VectorTripCount,std::pair<BasicBlock *,Value * > AdditionalBypass)3523 void InnerLoopVectorizer::createInductionResumeValues(
3524 Loop *L, Value *VectorTripCount,
3525 std::pair<BasicBlock *, Value *> AdditionalBypass) {
3526 assert(VectorTripCount && L && "Expected valid arguments");
3527 assert(((AdditionalBypass.first && AdditionalBypass.second) ||
3528 (!AdditionalBypass.first && !AdditionalBypass.second)) &&
3529 "Inconsistent information about additional bypass.");
3530 // We are going to resume the execution of the scalar loop.
3531 // Go over all of the induction variables that we found and fix the
3532 // PHIs that are left in the scalar version of the loop.
3533 // The starting values of PHI nodes depend on the counter of the last
3534 // iteration in the vectorized loop.
3535 // If we come from a bypass edge then we need to start from the original
3536 // start value.
3537 for (auto &InductionEntry : Legal->getInductionVars()) {
3538 PHINode *OrigPhi = InductionEntry.first;
3539 InductionDescriptor II = InductionEntry.second;
3540
3541 // Create phi nodes to merge from the backedge-taken check block.
3542 PHINode *BCResumeVal =
3543 PHINode::Create(OrigPhi->getType(), 3, "bc.resume.val",
3544 LoopScalarPreHeader->getTerminator());
3545 // Copy original phi DL over to the new one.
3546 BCResumeVal->setDebugLoc(OrigPhi->getDebugLoc());
3547 Value *&EndValue = IVEndValues[OrigPhi];
3548 Value *EndValueFromAdditionalBypass = AdditionalBypass.second;
3549 if (OrigPhi == OldInduction) {
3550 // We know what the end value is.
3551 EndValue = VectorTripCount;
3552 } else {
3553 IRBuilder<> B(L->getLoopPreheader()->getTerminator());
3554
3555 // Fast-math-flags propagate from the original induction instruction.
3556 if (II.getInductionBinOp() && isa<FPMathOperator>(II.getInductionBinOp()))
3557 B.setFastMathFlags(II.getInductionBinOp()->getFastMathFlags());
3558
3559 Type *StepType = II.getStep()->getType();
3560 Instruction::CastOps CastOp =
3561 CastInst::getCastOpcode(VectorTripCount, true, StepType, true);
3562 Value *CRD = B.CreateCast(CastOp, VectorTripCount, StepType, "cast.crd");
3563 const DataLayout &DL = LoopScalarBody->getModule()->getDataLayout();
3564 EndValue = emitTransformedIndex(B, CRD, PSE.getSE(), DL, II);
3565 EndValue->setName("ind.end");
3566
3567 // Compute the end value for the additional bypass (if applicable).
3568 if (AdditionalBypass.first) {
3569 B.SetInsertPoint(&(*AdditionalBypass.first->getFirstInsertionPt()));
3570 CastOp = CastInst::getCastOpcode(AdditionalBypass.second, true,
3571 StepType, true);
3572 CRD =
3573 B.CreateCast(CastOp, AdditionalBypass.second, StepType, "cast.crd");
3574 EndValueFromAdditionalBypass =
3575 emitTransformedIndex(B, CRD, PSE.getSE(), DL, II);
3576 EndValueFromAdditionalBypass->setName("ind.end");
3577 }
3578 }
3579 // The new PHI merges the original incoming value, in case of a bypass,
3580 // or the value at the end of the vectorized loop.
3581 BCResumeVal->addIncoming(EndValue, LoopMiddleBlock);
3582
3583 // Fix the scalar body counter (PHI node).
3584 // The old induction's phi node in the scalar body needs the truncated
3585 // value.
3586 for (BasicBlock *BB : LoopBypassBlocks)
3587 BCResumeVal->addIncoming(II.getStartValue(), BB);
3588
3589 if (AdditionalBypass.first)
3590 BCResumeVal->setIncomingValueForBlock(AdditionalBypass.first,
3591 EndValueFromAdditionalBypass);
3592
3593 OrigPhi->setIncomingValueForBlock(LoopScalarPreHeader, BCResumeVal);
3594 }
3595 }
3596
completeLoopSkeleton(Loop * L,MDNode * OrigLoopID)3597 BasicBlock *InnerLoopVectorizer::completeLoopSkeleton(Loop *L,
3598 MDNode *OrigLoopID) {
3599 assert(L && "Expected valid loop.");
3600
3601 // The trip counts should be cached by now.
3602 Value *Count = getOrCreateTripCount(L);
3603 Value *VectorTripCount = getOrCreateVectorTripCount(L);
3604
3605 auto *ScalarLatchTerm = OrigLoop->getLoopLatch()->getTerminator();
3606
3607 // Add a check in the middle block to see if we have completed
3608 // all of the iterations in the first vector loop. Three cases:
3609 // 1) If we require a scalar epilogue, there is no conditional branch as
3610 // we unconditionally branch to the scalar preheader. Do nothing.
3611 // 2) If (N - N%VF) == N, then we *don't* need to run the remainder.
3612 // Thus if tail is to be folded, we know we don't need to run the
3613 // remainder and we can use the previous value for the condition (true).
3614 // 3) Otherwise, construct a runtime check.
3615 if (!Cost->requiresScalarEpilogue(VF) && !Cost->foldTailByMasking()) {
3616 Instruction *CmpN = CmpInst::Create(Instruction::ICmp, CmpInst::ICMP_EQ,
3617 Count, VectorTripCount, "cmp.n",
3618 LoopMiddleBlock->getTerminator());
3619
3620 // Here we use the same DebugLoc as the scalar loop latch terminator instead
3621 // of the corresponding compare because they may have ended up with
3622 // different line numbers and we want to avoid awkward line stepping while
3623 // debugging. Eg. if the compare has got a line number inside the loop.
3624 CmpN->setDebugLoc(ScalarLatchTerm->getDebugLoc());
3625 cast<BranchInst>(LoopMiddleBlock->getTerminator())->setCondition(CmpN);
3626 }
3627
3628 // Get ready to start creating new instructions into the vectorized body.
3629 assert(LoopVectorPreHeader == L->getLoopPreheader() &&
3630 "Inconsistent vector loop preheader");
3631 Builder.SetInsertPoint(&*LoopVectorBody->getFirstInsertionPt());
3632
3633 Optional<MDNode *> VectorizedLoopID =
3634 makeFollowupLoopID(OrigLoopID, {LLVMLoopVectorizeFollowupAll,
3635 LLVMLoopVectorizeFollowupVectorized});
3636 if (VectorizedLoopID.hasValue()) {
3637 L->setLoopID(VectorizedLoopID.getValue());
3638
3639 // Do not setAlreadyVectorized if loop attributes have been defined
3640 // explicitly.
3641 return LoopVectorPreHeader;
3642 }
3643
3644 // Keep all loop hints from the original loop on the vector loop (we'll
3645 // replace the vectorizer-specific hints below).
3646 if (MDNode *LID = OrigLoop->getLoopID())
3647 L->setLoopID(LID);
3648
3649 LoopVectorizeHints Hints(L, true, *ORE);
3650 Hints.setAlreadyVectorized();
3651
3652 #ifdef EXPENSIVE_CHECKS
3653 assert(DT->verify(DominatorTree::VerificationLevel::Fast));
3654 LI->verify(*DT);
3655 #endif
3656
3657 return LoopVectorPreHeader;
3658 }
3659
createVectorizedLoopSkeleton()3660 BasicBlock *InnerLoopVectorizer::createVectorizedLoopSkeleton() {
3661 /*
3662 In this function we generate a new loop. The new loop will contain
3663 the vectorized instructions while the old loop will continue to run the
3664 scalar remainder.
3665
3666 [ ] <-- loop iteration number check.
3667 / |
3668 / v
3669 | [ ] <-- vector loop bypass (may consist of multiple blocks).
3670 | / |
3671 | / v
3672 || [ ] <-- vector pre header.
3673 |/ |
3674 | v
3675 | [ ] \
3676 | [ ]_| <-- vector loop.
3677 | |
3678 | v
3679 \ -[ ] <--- middle-block.
3680 \/ |
3681 /\ v
3682 | ->[ ] <--- new preheader.
3683 | |
3684 (opt) v <-- edge from middle to exit iff epilogue is not required.
3685 | [ ] \
3686 | [ ]_| <-- old scalar loop to handle remainder (scalar epilogue).
3687 \ |
3688 \ v
3689 >[ ] <-- exit block(s).
3690 ...
3691 */
3692
3693 // Get the metadata of the original loop before it gets modified.
3694 MDNode *OrigLoopID = OrigLoop->getLoopID();
3695
3696 // Workaround! Compute the trip count of the original loop and cache it
3697 // before we start modifying the CFG. This code has a systemic problem
3698 // wherein it tries to run analysis over partially constructed IR; this is
3699 // wrong, and not simply for SCEV. The trip count of the original loop
3700 // simply happens to be prone to hitting this in practice. In theory, we
3701 // can hit the same issue for any SCEV, or ValueTracking query done during
3702 // mutation. See PR49900.
3703 getOrCreateTripCount(OrigLoop);
3704
3705 // Create an empty vector loop, and prepare basic blocks for the runtime
3706 // checks.
3707 Loop *Lp = createVectorLoopSkeleton("");
3708
3709 // Now, compare the new count to zero. If it is zero skip the vector loop and
3710 // jump to the scalar loop. This check also covers the case where the
3711 // backedge-taken count is uint##_max: adding one to it will overflow leading
3712 // to an incorrect trip count of zero. In this (rare) case we will also jump
3713 // to the scalar loop.
3714 emitMinimumIterationCountCheck(Lp, LoopScalarPreHeader);
3715
3716 // Generate the code to check any assumptions that we've made for SCEV
3717 // expressions.
3718 emitSCEVChecks(Lp, LoopScalarPreHeader);
3719
3720 // Generate the code that checks in runtime if arrays overlap. We put the
3721 // checks into a separate block to make the more common case of few elements
3722 // faster.
3723 emitMemRuntimeChecks(Lp, LoopScalarPreHeader);
3724
3725 // Some loops have a single integer induction variable, while other loops
3726 // don't. One example is c++ iterators that often have multiple pointer
3727 // induction variables. In the code below we also support a case where we
3728 // don't have a single induction variable.
3729 //
3730 // We try to obtain an induction variable from the original loop as hard
3731 // as possible. However if we don't find one that:
3732 // - is an integer
3733 // - counts from zero, stepping by one
3734 // - is the size of the widest induction variable type
3735 // then we create a new one.
3736 OldInduction = Legal->getPrimaryInduction();
3737 Type *IdxTy = Legal->getWidestInductionType();
3738 Value *StartIdx = ConstantInt::get(IdxTy, 0);
3739 // The loop step is equal to the vectorization factor (num of SIMD elements)
3740 // times the unroll factor (num of SIMD instructions).
3741 Builder.SetInsertPoint(&*Lp->getHeader()->getFirstInsertionPt());
3742 Value *Step = createStepForVF(Builder, ConstantInt::get(IdxTy, UF), VF);
3743 Value *CountRoundDown = getOrCreateVectorTripCount(Lp);
3744 Induction =
3745 createInductionVariable(Lp, StartIdx, CountRoundDown, Step,
3746 getDebugLocFromInstOrOperands(OldInduction));
3747
3748 // Emit phis for the new starting index of the scalar loop.
3749 createInductionResumeValues(Lp, CountRoundDown);
3750
3751 return completeLoopSkeleton(Lp, OrigLoopID);
3752 }
3753
3754 // Fix up external users of the induction variable. At this point, we are
3755 // in LCSSA form, with all external PHIs that use the IV having one input value,
3756 // coming from the remainder loop. We need those PHIs to also have a correct
3757 // value for the IV when arriving directly from the middle block.
fixupIVUsers(PHINode * OrigPhi,const InductionDescriptor & II,Value * CountRoundDown,Value * EndValue,BasicBlock * MiddleBlock)3758 void InnerLoopVectorizer::fixupIVUsers(PHINode *OrigPhi,
3759 const InductionDescriptor &II,
3760 Value *CountRoundDown, Value *EndValue,
3761 BasicBlock *MiddleBlock) {
3762 // There are two kinds of external IV usages - those that use the value
3763 // computed in the last iteration (the PHI) and those that use the penultimate
3764 // value (the value that feeds into the phi from the loop latch).
3765 // We allow both, but they, obviously, have different values.
3766
3767 assert(OrigLoop->getUniqueExitBlock() && "Expected a single exit block");
3768
3769 DenseMap<Value *, Value *> MissingVals;
3770
3771 // An external user of the last iteration's value should see the value that
3772 // the remainder loop uses to initialize its own IV.
3773 Value *PostInc = OrigPhi->getIncomingValueForBlock(OrigLoop->getLoopLatch());
3774 for (User *U : PostInc->users()) {
3775 Instruction *UI = cast<Instruction>(U);
3776 if (!OrigLoop->contains(UI)) {
3777 assert(isa<PHINode>(UI) && "Expected LCSSA form");
3778 MissingVals[UI] = EndValue;
3779 }
3780 }
3781
3782 // An external user of the penultimate value need to see EndValue - Step.
3783 // The simplest way to get this is to recompute it from the constituent SCEVs,
3784 // that is Start + (Step * (CRD - 1)).
3785 for (User *U : OrigPhi->users()) {
3786 auto *UI = cast<Instruction>(U);
3787 if (!OrigLoop->contains(UI)) {
3788 const DataLayout &DL =
3789 OrigLoop->getHeader()->getModule()->getDataLayout();
3790 assert(isa<PHINode>(UI) && "Expected LCSSA form");
3791
3792 IRBuilder<> B(MiddleBlock->getTerminator());
3793
3794 // Fast-math-flags propagate from the original induction instruction.
3795 if (II.getInductionBinOp() && isa<FPMathOperator>(II.getInductionBinOp()))
3796 B.setFastMathFlags(II.getInductionBinOp()->getFastMathFlags());
3797
3798 Value *CountMinusOne = B.CreateSub(
3799 CountRoundDown, ConstantInt::get(CountRoundDown->getType(), 1));
3800 Value *CMO =
3801 !II.getStep()->getType()->isIntegerTy()
3802 ? B.CreateCast(Instruction::SIToFP, CountMinusOne,
3803 II.getStep()->getType())
3804 : B.CreateSExtOrTrunc(CountMinusOne, II.getStep()->getType());
3805 CMO->setName("cast.cmo");
3806 Value *Escape = emitTransformedIndex(B, CMO, PSE.getSE(), DL, II);
3807 Escape->setName("ind.escape");
3808 MissingVals[UI] = Escape;
3809 }
3810 }
3811
3812 for (auto &I : MissingVals) {
3813 PHINode *PHI = cast<PHINode>(I.first);
3814 // One corner case we have to handle is two IVs "chasing" each-other,
3815 // that is %IV2 = phi [...], [ %IV1, %latch ]
3816 // In this case, if IV1 has an external use, we need to avoid adding both
3817 // "last value of IV1" and "penultimate value of IV2". So, verify that we
3818 // don't already have an incoming value for the middle block.
3819 if (PHI->getBasicBlockIndex(MiddleBlock) == -1)
3820 PHI->addIncoming(I.second, MiddleBlock);
3821 }
3822 }
3823
3824 namespace {
3825
3826 struct CSEDenseMapInfo {
canHandle__anonae0bb1450e11::CSEDenseMapInfo3827 static bool canHandle(const Instruction *I) {
3828 return isa<InsertElementInst>(I) || isa<ExtractElementInst>(I) ||
3829 isa<ShuffleVectorInst>(I) || isa<GetElementPtrInst>(I);
3830 }
3831
getEmptyKey__anonae0bb1450e11::CSEDenseMapInfo3832 static inline Instruction *getEmptyKey() {
3833 return DenseMapInfo<Instruction *>::getEmptyKey();
3834 }
3835
getTombstoneKey__anonae0bb1450e11::CSEDenseMapInfo3836 static inline Instruction *getTombstoneKey() {
3837 return DenseMapInfo<Instruction *>::getTombstoneKey();
3838 }
3839
getHashValue__anonae0bb1450e11::CSEDenseMapInfo3840 static unsigned getHashValue(const Instruction *I) {
3841 assert(canHandle(I) && "Unknown instruction!");
3842 return hash_combine(I->getOpcode(), hash_combine_range(I->value_op_begin(),
3843 I->value_op_end()));
3844 }
3845
isEqual__anonae0bb1450e11::CSEDenseMapInfo3846 static bool isEqual(const Instruction *LHS, const Instruction *RHS) {
3847 if (LHS == getEmptyKey() || RHS == getEmptyKey() ||
3848 LHS == getTombstoneKey() || RHS == getTombstoneKey())
3849 return LHS == RHS;
3850 return LHS->isIdenticalTo(RHS);
3851 }
3852 };
3853
3854 } // end anonymous namespace
3855
3856 ///Perform cse of induction variable instructions.
cse(BasicBlock * BB)3857 static void cse(BasicBlock *BB) {
3858 // Perform simple cse.
3859 SmallDenseMap<Instruction *, Instruction *, 4, CSEDenseMapInfo> CSEMap;
3860 for (BasicBlock::iterator I = BB->begin(), E = BB->end(); I != E;) {
3861 Instruction *In = &*I++;
3862
3863 if (!CSEDenseMapInfo::canHandle(In))
3864 continue;
3865
3866 // Check if we can replace this instruction with any of the
3867 // visited instructions.
3868 if (Instruction *V = CSEMap.lookup(In)) {
3869 In->replaceAllUsesWith(V);
3870 In->eraseFromParent();
3871 continue;
3872 }
3873
3874 CSEMap[In] = In;
3875 }
3876 }
3877
3878 InstructionCost
getVectorCallCost(CallInst * CI,ElementCount VF,bool & NeedToScalarize) const3879 LoopVectorizationCostModel::getVectorCallCost(CallInst *CI, ElementCount VF,
3880 bool &NeedToScalarize) const {
3881 Function *F = CI->getCalledFunction();
3882 Type *ScalarRetTy = CI->getType();
3883 SmallVector<Type *, 4> Tys, ScalarTys;
3884 for (auto &ArgOp : CI->arg_operands())
3885 ScalarTys.push_back(ArgOp->getType());
3886
3887 // Estimate cost of scalarized vector call. The source operands are assumed
3888 // to be vectors, so we need to extract individual elements from there,
3889 // execute VF scalar calls, and then gather the result into the vector return
3890 // value.
3891 InstructionCost ScalarCallCost =
3892 TTI.getCallInstrCost(F, ScalarRetTy, ScalarTys, TTI::TCK_RecipThroughput);
3893 if (VF.isScalar())
3894 return ScalarCallCost;
3895
3896 // Compute corresponding vector type for return value and arguments.
3897 Type *RetTy = ToVectorTy(ScalarRetTy, VF);
3898 for (Type *ScalarTy : ScalarTys)
3899 Tys.push_back(ToVectorTy(ScalarTy, VF));
3900
3901 // Compute costs of unpacking argument values for the scalar calls and
3902 // packing the return values to a vector.
3903 InstructionCost ScalarizationCost = getScalarizationOverhead(CI, VF);
3904
3905 InstructionCost Cost =
3906 ScalarCallCost * VF.getKnownMinValue() + ScalarizationCost;
3907
3908 // If we can't emit a vector call for this function, then the currently found
3909 // cost is the cost we need to return.
3910 NeedToScalarize = true;
3911 VFShape Shape = VFShape::get(*CI, VF, false /*HasGlobalPred*/);
3912 Function *VecFunc = VFDatabase(*CI).getVectorizedFunction(Shape);
3913
3914 if (!TLI || CI->isNoBuiltin() || !VecFunc)
3915 return Cost;
3916
3917 // If the corresponding vector cost is cheaper, return its cost.
3918 InstructionCost VectorCallCost =
3919 TTI.getCallInstrCost(nullptr, RetTy, Tys, TTI::TCK_RecipThroughput);
3920 if (VectorCallCost < Cost) {
3921 NeedToScalarize = false;
3922 Cost = VectorCallCost;
3923 }
3924 return Cost;
3925 }
3926
MaybeVectorizeType(Type * Elt,ElementCount VF)3927 static Type *MaybeVectorizeType(Type *Elt, ElementCount VF) {
3928 if (VF.isScalar() || (!Elt->isIntOrPtrTy() && !Elt->isFloatingPointTy()))
3929 return Elt;
3930 return VectorType::get(Elt, VF);
3931 }
3932
3933 InstructionCost
getVectorIntrinsicCost(CallInst * CI,ElementCount VF) const3934 LoopVectorizationCostModel::getVectorIntrinsicCost(CallInst *CI,
3935 ElementCount VF) const {
3936 Intrinsic::ID ID = getVectorIntrinsicIDForCall(CI, TLI);
3937 assert(ID && "Expected intrinsic call!");
3938 Type *RetTy = MaybeVectorizeType(CI->getType(), VF);
3939 FastMathFlags FMF;
3940 if (auto *FPMO = dyn_cast<FPMathOperator>(CI))
3941 FMF = FPMO->getFastMathFlags();
3942
3943 SmallVector<const Value *> Arguments(CI->arg_begin(), CI->arg_end());
3944 FunctionType *FTy = CI->getCalledFunction()->getFunctionType();
3945 SmallVector<Type *> ParamTys;
3946 std::transform(FTy->param_begin(), FTy->param_end(),
3947 std::back_inserter(ParamTys),
3948 [&](Type *Ty) { return MaybeVectorizeType(Ty, VF); });
3949
3950 IntrinsicCostAttributes CostAttrs(ID, RetTy, Arguments, ParamTys, FMF,
3951 dyn_cast<IntrinsicInst>(CI));
3952 return TTI.getIntrinsicInstrCost(CostAttrs,
3953 TargetTransformInfo::TCK_RecipThroughput);
3954 }
3955
smallestIntegerVectorType(Type * T1,Type * T2)3956 static Type *smallestIntegerVectorType(Type *T1, Type *T2) {
3957 auto *I1 = cast<IntegerType>(cast<VectorType>(T1)->getElementType());
3958 auto *I2 = cast<IntegerType>(cast<VectorType>(T2)->getElementType());
3959 return I1->getBitWidth() < I2->getBitWidth() ? T1 : T2;
3960 }
3961
largestIntegerVectorType(Type * T1,Type * T2)3962 static Type *largestIntegerVectorType(Type *T1, Type *T2) {
3963 auto *I1 = cast<IntegerType>(cast<VectorType>(T1)->getElementType());
3964 auto *I2 = cast<IntegerType>(cast<VectorType>(T2)->getElementType());
3965 return I1->getBitWidth() > I2->getBitWidth() ? T1 : T2;
3966 }
3967
truncateToMinimalBitwidths(VPTransformState & State)3968 void InnerLoopVectorizer::truncateToMinimalBitwidths(VPTransformState &State) {
3969 // For every instruction `I` in MinBWs, truncate the operands, create a
3970 // truncated version of `I` and reextend its result. InstCombine runs
3971 // later and will remove any ext/trunc pairs.
3972 SmallPtrSet<Value *, 4> Erased;
3973 for (const auto &KV : Cost->getMinimalBitwidths()) {
3974 // If the value wasn't vectorized, we must maintain the original scalar
3975 // type. The absence of the value from State indicates that it
3976 // wasn't vectorized.
3977 VPValue *Def = State.Plan->getVPValue(KV.first);
3978 if (!State.hasAnyVectorValue(Def))
3979 continue;
3980 for (unsigned Part = 0; Part < UF; ++Part) {
3981 Value *I = State.get(Def, Part);
3982 if (Erased.count(I) || I->use_empty() || !isa<Instruction>(I))
3983 continue;
3984 Type *OriginalTy = I->getType();
3985 Type *ScalarTruncatedTy =
3986 IntegerType::get(OriginalTy->getContext(), KV.second);
3987 auto *TruncatedTy = VectorType::get(
3988 ScalarTruncatedTy, cast<VectorType>(OriginalTy)->getElementCount());
3989 if (TruncatedTy == OriginalTy)
3990 continue;
3991
3992 IRBuilder<> B(cast<Instruction>(I));
3993 auto ShrinkOperand = [&](Value *V) -> Value * {
3994 if (auto *ZI = dyn_cast<ZExtInst>(V))
3995 if (ZI->getSrcTy() == TruncatedTy)
3996 return ZI->getOperand(0);
3997 return B.CreateZExtOrTrunc(V, TruncatedTy);
3998 };
3999
4000 // The actual instruction modification depends on the instruction type,
4001 // unfortunately.
4002 Value *NewI = nullptr;
4003 if (auto *BO = dyn_cast<BinaryOperator>(I)) {
4004 NewI = B.CreateBinOp(BO->getOpcode(), ShrinkOperand(BO->getOperand(0)),
4005 ShrinkOperand(BO->getOperand(1)));
4006
4007 // Any wrapping introduced by shrinking this operation shouldn't be
4008 // considered undefined behavior. So, we can't unconditionally copy
4009 // arithmetic wrapping flags to NewI.
4010 cast<BinaryOperator>(NewI)->copyIRFlags(I, /*IncludeWrapFlags=*/false);
4011 } else if (auto *CI = dyn_cast<ICmpInst>(I)) {
4012 NewI =
4013 B.CreateICmp(CI->getPredicate(), ShrinkOperand(CI->getOperand(0)),
4014 ShrinkOperand(CI->getOperand(1)));
4015 } else if (auto *SI = dyn_cast<SelectInst>(I)) {
4016 NewI = B.CreateSelect(SI->getCondition(),
4017 ShrinkOperand(SI->getTrueValue()),
4018 ShrinkOperand(SI->getFalseValue()));
4019 } else if (auto *CI = dyn_cast<CastInst>(I)) {
4020 switch (CI->getOpcode()) {
4021 default:
4022 llvm_unreachable("Unhandled cast!");
4023 case Instruction::Trunc:
4024 NewI = ShrinkOperand(CI->getOperand(0));
4025 break;
4026 case Instruction::SExt:
4027 NewI = B.CreateSExtOrTrunc(
4028 CI->getOperand(0),
4029 smallestIntegerVectorType(OriginalTy, TruncatedTy));
4030 break;
4031 case Instruction::ZExt:
4032 NewI = B.CreateZExtOrTrunc(
4033 CI->getOperand(0),
4034 smallestIntegerVectorType(OriginalTy, TruncatedTy));
4035 break;
4036 }
4037 } else if (auto *SI = dyn_cast<ShuffleVectorInst>(I)) {
4038 auto Elements0 =
4039 cast<VectorType>(SI->getOperand(0)->getType())->getElementCount();
4040 auto *O0 = B.CreateZExtOrTrunc(
4041 SI->getOperand(0), VectorType::get(ScalarTruncatedTy, Elements0));
4042 auto Elements1 =
4043 cast<VectorType>(SI->getOperand(1)->getType())->getElementCount();
4044 auto *O1 = B.CreateZExtOrTrunc(
4045 SI->getOperand(1), VectorType::get(ScalarTruncatedTy, Elements1));
4046
4047 NewI = B.CreateShuffleVector(O0, O1, SI->getShuffleMask());
4048 } else if (isa<LoadInst>(I) || isa<PHINode>(I)) {
4049 // Don't do anything with the operands, just extend the result.
4050 continue;
4051 } else if (auto *IE = dyn_cast<InsertElementInst>(I)) {
4052 auto Elements =
4053 cast<VectorType>(IE->getOperand(0)->getType())->getElementCount();
4054 auto *O0 = B.CreateZExtOrTrunc(
4055 IE->getOperand(0), VectorType::get(ScalarTruncatedTy, Elements));
4056 auto *O1 = B.CreateZExtOrTrunc(IE->getOperand(1), ScalarTruncatedTy);
4057 NewI = B.CreateInsertElement(O0, O1, IE->getOperand(2));
4058 } else if (auto *EE = dyn_cast<ExtractElementInst>(I)) {
4059 auto Elements =
4060 cast<VectorType>(EE->getOperand(0)->getType())->getElementCount();
4061 auto *O0 = B.CreateZExtOrTrunc(
4062 EE->getOperand(0), VectorType::get(ScalarTruncatedTy, Elements));
4063 NewI = B.CreateExtractElement(O0, EE->getOperand(2));
4064 } else {
4065 // If we don't know what to do, be conservative and don't do anything.
4066 continue;
4067 }
4068
4069 // Lastly, extend the result.
4070 NewI->takeName(cast<Instruction>(I));
4071 Value *Res = B.CreateZExtOrTrunc(NewI, OriginalTy);
4072 I->replaceAllUsesWith(Res);
4073 cast<Instruction>(I)->eraseFromParent();
4074 Erased.insert(I);
4075 State.reset(Def, Res, Part);
4076 }
4077 }
4078
4079 // We'll have created a bunch of ZExts that are now parentless. Clean up.
4080 for (const auto &KV : Cost->getMinimalBitwidths()) {
4081 // If the value wasn't vectorized, we must maintain the original scalar
4082 // type. The absence of the value from State indicates that it
4083 // wasn't vectorized.
4084 VPValue *Def = State.Plan->getVPValue(KV.first);
4085 if (!State.hasAnyVectorValue(Def))
4086 continue;
4087 for (unsigned Part = 0; Part < UF; ++Part) {
4088 Value *I = State.get(Def, Part);
4089 ZExtInst *Inst = dyn_cast<ZExtInst>(I);
4090 if (Inst && Inst->use_empty()) {
4091 Value *NewI = Inst->getOperand(0);
4092 Inst->eraseFromParent();
4093 State.reset(Def, NewI, Part);
4094 }
4095 }
4096 }
4097 }
4098
fixVectorizedLoop(VPTransformState & State)4099 void InnerLoopVectorizer::fixVectorizedLoop(VPTransformState &State) {
4100 // Insert truncates and extends for any truncated instructions as hints to
4101 // InstCombine.
4102 if (VF.isVector())
4103 truncateToMinimalBitwidths(State);
4104
4105 // Fix widened non-induction PHIs by setting up the PHI operands.
4106 if (OrigPHIsToFix.size()) {
4107 assert(EnableVPlanNativePath &&
4108 "Unexpected non-induction PHIs for fixup in non VPlan-native path");
4109 fixNonInductionPHIs(State);
4110 }
4111
4112 // At this point every instruction in the original loop is widened to a
4113 // vector form. Now we need to fix the recurrences in the loop. These PHI
4114 // nodes are currently empty because we did not want to introduce cycles.
4115 // This is the second stage of vectorizing recurrences.
4116 fixCrossIterationPHIs(State);
4117
4118 // Forget the original basic block.
4119 PSE.getSE()->forgetLoop(OrigLoop);
4120
4121 // If we inserted an edge from the middle block to the unique exit block,
4122 // update uses outside the loop (phis) to account for the newly inserted
4123 // edge.
4124 if (!Cost->requiresScalarEpilogue(VF)) {
4125 // Fix-up external users of the induction variables.
4126 for (auto &Entry : Legal->getInductionVars())
4127 fixupIVUsers(Entry.first, Entry.second,
4128 getOrCreateVectorTripCount(LI->getLoopFor(LoopVectorBody)),
4129 IVEndValues[Entry.first], LoopMiddleBlock);
4130
4131 fixLCSSAPHIs(State);
4132 }
4133
4134 for (Instruction *PI : PredicatedInstructions)
4135 sinkScalarOperands(&*PI);
4136
4137 // Remove redundant induction instructions.
4138 cse(LoopVectorBody);
4139
4140 // Set/update profile weights for the vector and remainder loops as original
4141 // loop iterations are now distributed among them. Note that original loop
4142 // represented by LoopScalarBody becomes remainder loop after vectorization.
4143 //
4144 // For cases like foldTailByMasking() and requiresScalarEpiloque() we may
4145 // end up getting slightly roughened result but that should be OK since
4146 // profile is not inherently precise anyway. Note also possible bypass of
4147 // vector code caused by legality checks is ignored, assigning all the weight
4148 // to the vector loop, optimistically.
4149 //
4150 // For scalable vectorization we can't know at compile time how many iterations
4151 // of the loop are handled in one vector iteration, so instead assume a pessimistic
4152 // vscale of '1'.
4153 setProfileInfoAfterUnrolling(
4154 LI->getLoopFor(LoopScalarBody), LI->getLoopFor(LoopVectorBody),
4155 LI->getLoopFor(LoopScalarBody), VF.getKnownMinValue() * UF);
4156 }
4157
fixCrossIterationPHIs(VPTransformState & State)4158 void InnerLoopVectorizer::fixCrossIterationPHIs(VPTransformState &State) {
4159 // In order to support recurrences we need to be able to vectorize Phi nodes.
4160 // Phi nodes have cycles, so we need to vectorize them in two stages. This is
4161 // stage #2: We now need to fix the recurrences by adding incoming edges to
4162 // the currently empty PHI nodes. At this point every instruction in the
4163 // original loop is widened to a vector form so we can use them to construct
4164 // the incoming edges.
4165 VPBasicBlock *Header = State.Plan->getEntry()->getEntryBasicBlock();
4166 for (VPRecipeBase &R : Header->phis()) {
4167 if (auto *ReductionPhi = dyn_cast<VPReductionPHIRecipe>(&R))
4168 fixReduction(ReductionPhi, State);
4169 else if (auto *FOR = dyn_cast<VPFirstOrderRecurrencePHIRecipe>(&R))
4170 fixFirstOrderRecurrence(FOR, State);
4171 }
4172 }
4173
fixFirstOrderRecurrence(VPWidenPHIRecipe * PhiR,VPTransformState & State)4174 void InnerLoopVectorizer::fixFirstOrderRecurrence(VPWidenPHIRecipe *PhiR,
4175 VPTransformState &State) {
4176 // This is the second phase of vectorizing first-order recurrences. An
4177 // overview of the transformation is described below. Suppose we have the
4178 // following loop.
4179 //
4180 // for (int i = 0; i < n; ++i)
4181 // b[i] = a[i] - a[i - 1];
4182 //
4183 // There is a first-order recurrence on "a". For this loop, the shorthand
4184 // scalar IR looks like:
4185 //
4186 // scalar.ph:
4187 // s_init = a[-1]
4188 // br scalar.body
4189 //
4190 // scalar.body:
4191 // i = phi [0, scalar.ph], [i+1, scalar.body]
4192 // s1 = phi [s_init, scalar.ph], [s2, scalar.body]
4193 // s2 = a[i]
4194 // b[i] = s2 - s1
4195 // br cond, scalar.body, ...
4196 //
4197 // In this example, s1 is a recurrence because it's value depends on the
4198 // previous iteration. In the first phase of vectorization, we created a
4199 // vector phi v1 for s1. We now complete the vectorization and produce the
4200 // shorthand vector IR shown below (for VF = 4, UF = 1).
4201 //
4202 // vector.ph:
4203 // v_init = vector(..., ..., ..., a[-1])
4204 // br vector.body
4205 //
4206 // vector.body
4207 // i = phi [0, vector.ph], [i+4, vector.body]
4208 // v1 = phi [v_init, vector.ph], [v2, vector.body]
4209 // v2 = a[i, i+1, i+2, i+3];
4210 // v3 = vector(v1(3), v2(0, 1, 2))
4211 // b[i, i+1, i+2, i+3] = v2 - v3
4212 // br cond, vector.body, middle.block
4213 //
4214 // middle.block:
4215 // x = v2(3)
4216 // br scalar.ph
4217 //
4218 // scalar.ph:
4219 // s_init = phi [x, middle.block], [a[-1], otherwise]
4220 // br scalar.body
4221 //
4222 // After execution completes the vector loop, we extract the next value of
4223 // the recurrence (x) to use as the initial value in the scalar loop.
4224
4225 auto *IdxTy = Builder.getInt32Ty();
4226 auto *VecPhi = cast<PHINode>(State.get(PhiR, 0));
4227
4228 // Fix the latch value of the new recurrence in the vector loop.
4229 VPValue *PreviousDef = PhiR->getBackedgeValue();
4230 Value *Incoming = State.get(PreviousDef, UF - 1);
4231 VecPhi->addIncoming(Incoming, LI->getLoopFor(LoopVectorBody)->getLoopLatch());
4232
4233 // Extract the last vector element in the middle block. This will be the
4234 // initial value for the recurrence when jumping to the scalar loop.
4235 auto *ExtractForScalar = Incoming;
4236 if (VF.isVector()) {
4237 auto *One = ConstantInt::get(IdxTy, 1);
4238 Builder.SetInsertPoint(LoopMiddleBlock->getTerminator());
4239 auto *RuntimeVF = getRuntimeVF(Builder, IdxTy, VF);
4240 auto *LastIdx = Builder.CreateSub(RuntimeVF, One);
4241 ExtractForScalar = Builder.CreateExtractElement(ExtractForScalar, LastIdx,
4242 "vector.recur.extract");
4243 }
4244 // Extract the second last element in the middle block if the
4245 // Phi is used outside the loop. We need to extract the phi itself
4246 // and not the last element (the phi update in the current iteration). This
4247 // will be the value when jumping to the exit block from the LoopMiddleBlock,
4248 // when the scalar loop is not run at all.
4249 Value *ExtractForPhiUsedOutsideLoop = nullptr;
4250 if (VF.isVector()) {
4251 auto *RuntimeVF = getRuntimeVF(Builder, IdxTy, VF);
4252 auto *Idx = Builder.CreateSub(RuntimeVF, ConstantInt::get(IdxTy, 2));
4253 ExtractForPhiUsedOutsideLoop = Builder.CreateExtractElement(
4254 Incoming, Idx, "vector.recur.extract.for.phi");
4255 } else if (UF > 1)
4256 // When loop is unrolled without vectorizing, initialize
4257 // ExtractForPhiUsedOutsideLoop with the value just prior to unrolled value
4258 // of `Incoming`. This is analogous to the vectorized case above: extracting
4259 // the second last element when VF > 1.
4260 ExtractForPhiUsedOutsideLoop = State.get(PreviousDef, UF - 2);
4261
4262 // Fix the initial value of the original recurrence in the scalar loop.
4263 Builder.SetInsertPoint(&*LoopScalarPreHeader->begin());
4264 PHINode *Phi = cast<PHINode>(PhiR->getUnderlyingValue());
4265 auto *Start = Builder.CreatePHI(Phi->getType(), 2, "scalar.recur.init");
4266 auto *ScalarInit = PhiR->getStartValue()->getLiveInIRValue();
4267 for (auto *BB : predecessors(LoopScalarPreHeader)) {
4268 auto *Incoming = BB == LoopMiddleBlock ? ExtractForScalar : ScalarInit;
4269 Start->addIncoming(Incoming, BB);
4270 }
4271
4272 Phi->setIncomingValueForBlock(LoopScalarPreHeader, Start);
4273 Phi->setName("scalar.recur");
4274
4275 // Finally, fix users of the recurrence outside the loop. The users will need
4276 // either the last value of the scalar recurrence or the last value of the
4277 // vector recurrence we extracted in the middle block. Since the loop is in
4278 // LCSSA form, we just need to find all the phi nodes for the original scalar
4279 // recurrence in the exit block, and then add an edge for the middle block.
4280 // Note that LCSSA does not imply single entry when the original scalar loop
4281 // had multiple exiting edges (as we always run the last iteration in the
4282 // scalar epilogue); in that case, there is no edge from middle to exit and
4283 // and thus no phis which needed updated.
4284 if (!Cost->requiresScalarEpilogue(VF))
4285 for (PHINode &LCSSAPhi : LoopExitBlock->phis())
4286 if (any_of(LCSSAPhi.incoming_values(),
4287 [Phi](Value *V) { return V == Phi; }))
4288 LCSSAPhi.addIncoming(ExtractForPhiUsedOutsideLoop, LoopMiddleBlock);
4289 }
4290
fixReduction(VPReductionPHIRecipe * PhiR,VPTransformState & State)4291 void InnerLoopVectorizer::fixReduction(VPReductionPHIRecipe *PhiR,
4292 VPTransformState &State) {
4293 PHINode *OrigPhi = cast<PHINode>(PhiR->getUnderlyingValue());
4294 // Get it's reduction variable descriptor.
4295 assert(Legal->isReductionVariable(OrigPhi) &&
4296 "Unable to find the reduction variable");
4297 const RecurrenceDescriptor &RdxDesc = PhiR->getRecurrenceDescriptor();
4298
4299 RecurKind RK = RdxDesc.getRecurrenceKind();
4300 TrackingVH<Value> ReductionStartValue = RdxDesc.getRecurrenceStartValue();
4301 Instruction *LoopExitInst = RdxDesc.getLoopExitInstr();
4302 setDebugLocFromInst(ReductionStartValue);
4303
4304 VPValue *LoopExitInstDef = State.Plan->getVPValue(LoopExitInst);
4305 // This is the vector-clone of the value that leaves the loop.
4306 Type *VecTy = State.get(LoopExitInstDef, 0)->getType();
4307
4308 // Wrap flags are in general invalid after vectorization, clear them.
4309 clearReductionWrapFlags(RdxDesc, State);
4310
4311 // Fix the vector-loop phi.
4312
4313 // Reductions do not have to start at zero. They can start with
4314 // any loop invariant values.
4315 BasicBlock *VectorLoopLatch = LI->getLoopFor(LoopVectorBody)->getLoopLatch();
4316
4317 unsigned LastPartForNewPhi = PhiR->isOrdered() ? 1 : UF;
4318 for (unsigned Part = 0; Part < LastPartForNewPhi; ++Part) {
4319 Value *VecRdxPhi = State.get(PhiR->getVPSingleValue(), Part);
4320 Value *Val = State.get(PhiR->getBackedgeValue(), Part);
4321 if (PhiR->isOrdered())
4322 Val = State.get(PhiR->getBackedgeValue(), UF - 1);
4323
4324 cast<PHINode>(VecRdxPhi)->addIncoming(Val, VectorLoopLatch);
4325 }
4326
4327 // Before each round, move the insertion point right between
4328 // the PHIs and the values we are going to write.
4329 // This allows us to write both PHINodes and the extractelement
4330 // instructions.
4331 Builder.SetInsertPoint(&*LoopMiddleBlock->getFirstInsertionPt());
4332
4333 setDebugLocFromInst(LoopExitInst);
4334
4335 Type *PhiTy = OrigPhi->getType();
4336 // If tail is folded by masking, the vector value to leave the loop should be
4337 // a Select choosing between the vectorized LoopExitInst and vectorized Phi,
4338 // instead of the former. For an inloop reduction the reduction will already
4339 // be predicated, and does not need to be handled here.
4340 if (Cost->foldTailByMasking() && !PhiR->isInLoop()) {
4341 for (unsigned Part = 0; Part < UF; ++Part) {
4342 Value *VecLoopExitInst = State.get(LoopExitInstDef, Part);
4343 Value *Sel = nullptr;
4344 for (User *U : VecLoopExitInst->users()) {
4345 if (isa<SelectInst>(U)) {
4346 assert(!Sel && "Reduction exit feeding two selects");
4347 Sel = U;
4348 } else
4349 assert(isa<PHINode>(U) && "Reduction exit must feed Phi's or select");
4350 }
4351 assert(Sel && "Reduction exit feeds no select");
4352 State.reset(LoopExitInstDef, Sel, Part);
4353
4354 // If the target can create a predicated operator for the reduction at no
4355 // extra cost in the loop (for example a predicated vadd), it can be
4356 // cheaper for the select to remain in the loop than be sunk out of it,
4357 // and so use the select value for the phi instead of the old
4358 // LoopExitValue.
4359 if (PreferPredicatedReductionSelect ||
4360 TTI->preferPredicatedReductionSelect(
4361 RdxDesc.getOpcode(), PhiTy,
4362 TargetTransformInfo::ReductionFlags())) {
4363 auto *VecRdxPhi =
4364 cast<PHINode>(State.get(PhiR->getVPSingleValue(), Part));
4365 VecRdxPhi->setIncomingValueForBlock(
4366 LI->getLoopFor(LoopVectorBody)->getLoopLatch(), Sel);
4367 }
4368 }
4369 }
4370
4371 // If the vector reduction can be performed in a smaller type, we truncate
4372 // then extend the loop exit value to enable InstCombine to evaluate the
4373 // entire expression in the smaller type.
4374 if (VF.isVector() && PhiTy != RdxDesc.getRecurrenceType()) {
4375 assert(!PhiR->isInLoop() && "Unexpected truncated inloop reduction!");
4376 Type *RdxVecTy = VectorType::get(RdxDesc.getRecurrenceType(), VF);
4377 Builder.SetInsertPoint(
4378 LI->getLoopFor(LoopVectorBody)->getLoopLatch()->getTerminator());
4379 VectorParts RdxParts(UF);
4380 for (unsigned Part = 0; Part < UF; ++Part) {
4381 RdxParts[Part] = State.get(LoopExitInstDef, Part);
4382 Value *Trunc = Builder.CreateTrunc(RdxParts[Part], RdxVecTy);
4383 Value *Extnd = RdxDesc.isSigned() ? Builder.CreateSExt(Trunc, VecTy)
4384 : Builder.CreateZExt(Trunc, VecTy);
4385 for (Value::user_iterator UI = RdxParts[Part]->user_begin();
4386 UI != RdxParts[Part]->user_end();)
4387 if (*UI != Trunc) {
4388 (*UI++)->replaceUsesOfWith(RdxParts[Part], Extnd);
4389 RdxParts[Part] = Extnd;
4390 } else {
4391 ++UI;
4392 }
4393 }
4394 Builder.SetInsertPoint(&*LoopMiddleBlock->getFirstInsertionPt());
4395 for (unsigned Part = 0; Part < UF; ++Part) {
4396 RdxParts[Part] = Builder.CreateTrunc(RdxParts[Part], RdxVecTy);
4397 State.reset(LoopExitInstDef, RdxParts[Part], Part);
4398 }
4399 }
4400
4401 // Reduce all of the unrolled parts into a single vector.
4402 Value *ReducedPartRdx = State.get(LoopExitInstDef, 0);
4403 unsigned Op = RecurrenceDescriptor::getOpcode(RK);
4404
4405 // The middle block terminator has already been assigned a DebugLoc here (the
4406 // OrigLoop's single latch terminator). We want the whole middle block to
4407 // appear to execute on this line because: (a) it is all compiler generated,
4408 // (b) these instructions are always executed after evaluating the latch
4409 // conditional branch, and (c) other passes may add new predecessors which
4410 // terminate on this line. This is the easiest way to ensure we don't
4411 // accidentally cause an extra step back into the loop while debugging.
4412 setDebugLocFromInst(LoopMiddleBlock->getTerminator());
4413 if (PhiR->isOrdered())
4414 ReducedPartRdx = State.get(LoopExitInstDef, UF - 1);
4415 else {
4416 // Floating-point operations should have some FMF to enable the reduction.
4417 IRBuilderBase::FastMathFlagGuard FMFG(Builder);
4418 Builder.setFastMathFlags(RdxDesc.getFastMathFlags());
4419 for (unsigned Part = 1; Part < UF; ++Part) {
4420 Value *RdxPart = State.get(LoopExitInstDef, Part);
4421 if (Op != Instruction::ICmp && Op != Instruction::FCmp) {
4422 ReducedPartRdx = Builder.CreateBinOp(
4423 (Instruction::BinaryOps)Op, RdxPart, ReducedPartRdx, "bin.rdx");
4424 } else {
4425 ReducedPartRdx = createMinMaxOp(Builder, RK, ReducedPartRdx, RdxPart);
4426 }
4427 }
4428 }
4429
4430 // Create the reduction after the loop. Note that inloop reductions create the
4431 // target reduction in the loop using a Reduction recipe.
4432 if (VF.isVector() && !PhiR->isInLoop()) {
4433 ReducedPartRdx =
4434 createTargetReduction(Builder, TTI, RdxDesc, ReducedPartRdx);
4435 // If the reduction can be performed in a smaller type, we need to extend
4436 // the reduction to the wider type before we branch to the original loop.
4437 if (PhiTy != RdxDesc.getRecurrenceType())
4438 ReducedPartRdx = RdxDesc.isSigned()
4439 ? Builder.CreateSExt(ReducedPartRdx, PhiTy)
4440 : Builder.CreateZExt(ReducedPartRdx, PhiTy);
4441 }
4442
4443 // Create a phi node that merges control-flow from the backedge-taken check
4444 // block and the middle block.
4445 PHINode *BCBlockPhi = PHINode::Create(PhiTy, 2, "bc.merge.rdx",
4446 LoopScalarPreHeader->getTerminator());
4447 for (unsigned I = 0, E = LoopBypassBlocks.size(); I != E; ++I)
4448 BCBlockPhi->addIncoming(ReductionStartValue, LoopBypassBlocks[I]);
4449 BCBlockPhi->addIncoming(ReducedPartRdx, LoopMiddleBlock);
4450
4451 // Now, we need to fix the users of the reduction variable
4452 // inside and outside of the scalar remainder loop.
4453
4454 // We know that the loop is in LCSSA form. We need to update the PHI nodes
4455 // in the exit blocks. See comment on analogous loop in
4456 // fixFirstOrderRecurrence for a more complete explaination of the logic.
4457 if (!Cost->requiresScalarEpilogue(VF))
4458 for (PHINode &LCSSAPhi : LoopExitBlock->phis())
4459 if (any_of(LCSSAPhi.incoming_values(),
4460 [LoopExitInst](Value *V) { return V == LoopExitInst; }))
4461 LCSSAPhi.addIncoming(ReducedPartRdx, LoopMiddleBlock);
4462
4463 // Fix the scalar loop reduction variable with the incoming reduction sum
4464 // from the vector body and from the backedge value.
4465 int IncomingEdgeBlockIdx =
4466 OrigPhi->getBasicBlockIndex(OrigLoop->getLoopLatch());
4467 assert(IncomingEdgeBlockIdx >= 0 && "Invalid block index");
4468 // Pick the other block.
4469 int SelfEdgeBlockIdx = (IncomingEdgeBlockIdx ? 0 : 1);
4470 OrigPhi->setIncomingValue(SelfEdgeBlockIdx, BCBlockPhi);
4471 OrigPhi->setIncomingValue(IncomingEdgeBlockIdx, LoopExitInst);
4472 }
4473
clearReductionWrapFlags(const RecurrenceDescriptor & RdxDesc,VPTransformState & State)4474 void InnerLoopVectorizer::clearReductionWrapFlags(const RecurrenceDescriptor &RdxDesc,
4475 VPTransformState &State) {
4476 RecurKind RK = RdxDesc.getRecurrenceKind();
4477 if (RK != RecurKind::Add && RK != RecurKind::Mul)
4478 return;
4479
4480 Instruction *LoopExitInstr = RdxDesc.getLoopExitInstr();
4481 assert(LoopExitInstr && "null loop exit instruction");
4482 SmallVector<Instruction *, 8> Worklist;
4483 SmallPtrSet<Instruction *, 8> Visited;
4484 Worklist.push_back(LoopExitInstr);
4485 Visited.insert(LoopExitInstr);
4486
4487 while (!Worklist.empty()) {
4488 Instruction *Cur = Worklist.pop_back_val();
4489 if (isa<OverflowingBinaryOperator>(Cur))
4490 for (unsigned Part = 0; Part < UF; ++Part) {
4491 Value *V = State.get(State.Plan->getVPValue(Cur), Part);
4492 cast<Instruction>(V)->dropPoisonGeneratingFlags();
4493 }
4494
4495 for (User *U : Cur->users()) {
4496 Instruction *UI = cast<Instruction>(U);
4497 if ((Cur != LoopExitInstr || OrigLoop->contains(UI->getParent())) &&
4498 Visited.insert(UI).second)
4499 Worklist.push_back(UI);
4500 }
4501 }
4502 }
4503
fixLCSSAPHIs(VPTransformState & State)4504 void InnerLoopVectorizer::fixLCSSAPHIs(VPTransformState &State) {
4505 for (PHINode &LCSSAPhi : LoopExitBlock->phis()) {
4506 if (LCSSAPhi.getBasicBlockIndex(LoopMiddleBlock) != -1)
4507 // Some phis were already hand updated by the reduction and recurrence
4508 // code above, leave them alone.
4509 continue;
4510
4511 auto *IncomingValue = LCSSAPhi.getIncomingValue(0);
4512 // Non-instruction incoming values will have only one value.
4513
4514 VPLane Lane = VPLane::getFirstLane();
4515 if (isa<Instruction>(IncomingValue) &&
4516 !Cost->isUniformAfterVectorization(cast<Instruction>(IncomingValue),
4517 VF))
4518 Lane = VPLane::getLastLaneForVF(VF);
4519
4520 // Can be a loop invariant incoming value or the last scalar value to be
4521 // extracted from the vectorized loop.
4522 Builder.SetInsertPoint(LoopMiddleBlock->getTerminator());
4523 Value *lastIncomingValue =
4524 OrigLoop->isLoopInvariant(IncomingValue)
4525 ? IncomingValue
4526 : State.get(State.Plan->getVPValue(IncomingValue),
4527 VPIteration(UF - 1, Lane));
4528 LCSSAPhi.addIncoming(lastIncomingValue, LoopMiddleBlock);
4529 }
4530 }
4531
sinkScalarOperands(Instruction * PredInst)4532 void InnerLoopVectorizer::sinkScalarOperands(Instruction *PredInst) {
4533 // The basic block and loop containing the predicated instruction.
4534 auto *PredBB = PredInst->getParent();
4535 auto *VectorLoop = LI->getLoopFor(PredBB);
4536
4537 // Initialize a worklist with the operands of the predicated instruction.
4538 SetVector<Value *> Worklist(PredInst->op_begin(), PredInst->op_end());
4539
4540 // Holds instructions that we need to analyze again. An instruction may be
4541 // reanalyzed if we don't yet know if we can sink it or not.
4542 SmallVector<Instruction *, 8> InstsToReanalyze;
4543
4544 // Returns true if a given use occurs in the predicated block. Phi nodes use
4545 // their operands in their corresponding predecessor blocks.
4546 auto isBlockOfUsePredicated = [&](Use &U) -> bool {
4547 auto *I = cast<Instruction>(U.getUser());
4548 BasicBlock *BB = I->getParent();
4549 if (auto *Phi = dyn_cast<PHINode>(I))
4550 BB = Phi->getIncomingBlock(
4551 PHINode::getIncomingValueNumForOperand(U.getOperandNo()));
4552 return BB == PredBB;
4553 };
4554
4555 // Iteratively sink the scalarized operands of the predicated instruction
4556 // into the block we created for it. When an instruction is sunk, it's
4557 // operands are then added to the worklist. The algorithm ends after one pass
4558 // through the worklist doesn't sink a single instruction.
4559 bool Changed;
4560 do {
4561 // Add the instructions that need to be reanalyzed to the worklist, and
4562 // reset the changed indicator.
4563 Worklist.insert(InstsToReanalyze.begin(), InstsToReanalyze.end());
4564 InstsToReanalyze.clear();
4565 Changed = false;
4566
4567 while (!Worklist.empty()) {
4568 auto *I = dyn_cast<Instruction>(Worklist.pop_back_val());
4569
4570 // We can't sink an instruction if it is a phi node, is not in the loop,
4571 // or may have side effects.
4572 if (!I || isa<PHINode>(I) || !VectorLoop->contains(I) ||
4573 I->mayHaveSideEffects())
4574 continue;
4575
4576 // If the instruction is already in PredBB, check if we can sink its
4577 // operands. In that case, VPlan's sinkScalarOperands() succeeded in
4578 // sinking the scalar instruction I, hence it appears in PredBB; but it
4579 // may have failed to sink I's operands (recursively), which we try
4580 // (again) here.
4581 if (I->getParent() == PredBB) {
4582 Worklist.insert(I->op_begin(), I->op_end());
4583 continue;
4584 }
4585
4586 // It's legal to sink the instruction if all its uses occur in the
4587 // predicated block. Otherwise, there's nothing to do yet, and we may
4588 // need to reanalyze the instruction.
4589 if (!llvm::all_of(I->uses(), isBlockOfUsePredicated)) {
4590 InstsToReanalyze.push_back(I);
4591 continue;
4592 }
4593
4594 // Move the instruction to the beginning of the predicated block, and add
4595 // it's operands to the worklist.
4596 I->moveBefore(&*PredBB->getFirstInsertionPt());
4597 Worklist.insert(I->op_begin(), I->op_end());
4598
4599 // The sinking may have enabled other instructions to be sunk, so we will
4600 // need to iterate.
4601 Changed = true;
4602 }
4603 } while (Changed);
4604 }
4605
fixNonInductionPHIs(VPTransformState & State)4606 void InnerLoopVectorizer::fixNonInductionPHIs(VPTransformState &State) {
4607 for (PHINode *OrigPhi : OrigPHIsToFix) {
4608 VPWidenPHIRecipe *VPPhi =
4609 cast<VPWidenPHIRecipe>(State.Plan->getVPValue(OrigPhi));
4610 PHINode *NewPhi = cast<PHINode>(State.get(VPPhi, 0));
4611 // Make sure the builder has a valid insert point.
4612 Builder.SetInsertPoint(NewPhi);
4613 for (unsigned i = 0; i < VPPhi->getNumOperands(); ++i) {
4614 VPValue *Inc = VPPhi->getIncomingValue(i);
4615 VPBasicBlock *VPBB = VPPhi->getIncomingBlock(i);
4616 NewPhi->addIncoming(State.get(Inc, 0), State.CFG.VPBB2IRBB[VPBB]);
4617 }
4618 }
4619 }
4620
useOrderedReductions(RecurrenceDescriptor & RdxDesc)4621 bool InnerLoopVectorizer::useOrderedReductions(RecurrenceDescriptor &RdxDesc) {
4622 return Cost->useOrderedReductions(RdxDesc);
4623 }
4624
widenGEP(GetElementPtrInst * GEP,VPValue * VPDef,VPUser & Operands,unsigned UF,ElementCount VF,bool IsPtrLoopInvariant,SmallBitVector & IsIndexLoopInvariant,VPTransformState & State)4625 void InnerLoopVectorizer::widenGEP(GetElementPtrInst *GEP, VPValue *VPDef,
4626 VPUser &Operands, unsigned UF,
4627 ElementCount VF, bool IsPtrLoopInvariant,
4628 SmallBitVector &IsIndexLoopInvariant,
4629 VPTransformState &State) {
4630 // Construct a vector GEP by widening the operands of the scalar GEP as
4631 // necessary. We mark the vector GEP 'inbounds' if appropriate. A GEP
4632 // results in a vector of pointers when at least one operand of the GEP
4633 // is vector-typed. Thus, to keep the representation compact, we only use
4634 // vector-typed operands for loop-varying values.
4635
4636 if (VF.isVector() && IsPtrLoopInvariant && IsIndexLoopInvariant.all()) {
4637 // If we are vectorizing, but the GEP has only loop-invariant operands,
4638 // the GEP we build (by only using vector-typed operands for
4639 // loop-varying values) would be a scalar pointer. Thus, to ensure we
4640 // produce a vector of pointers, we need to either arbitrarily pick an
4641 // operand to broadcast, or broadcast a clone of the original GEP.
4642 // Here, we broadcast a clone of the original.
4643 //
4644 // TODO: If at some point we decide to scalarize instructions having
4645 // loop-invariant operands, this special case will no longer be
4646 // required. We would add the scalarization decision to
4647 // collectLoopScalars() and teach getVectorValue() to broadcast
4648 // the lane-zero scalar value.
4649 auto *Clone = Builder.Insert(GEP->clone());
4650 for (unsigned Part = 0; Part < UF; ++Part) {
4651 Value *EntryPart = Builder.CreateVectorSplat(VF, Clone);
4652 State.set(VPDef, EntryPart, Part);
4653 addMetadata(EntryPart, GEP);
4654 }
4655 } else {
4656 // If the GEP has at least one loop-varying operand, we are sure to
4657 // produce a vector of pointers. But if we are only unrolling, we want
4658 // to produce a scalar GEP for each unroll part. Thus, the GEP we
4659 // produce with the code below will be scalar (if VF == 1) or vector
4660 // (otherwise). Note that for the unroll-only case, we still maintain
4661 // values in the vector mapping with initVector, as we do for other
4662 // instructions.
4663 for (unsigned Part = 0; Part < UF; ++Part) {
4664 // The pointer operand of the new GEP. If it's loop-invariant, we
4665 // won't broadcast it.
4666 auto *Ptr = IsPtrLoopInvariant
4667 ? State.get(Operands.getOperand(0), VPIteration(0, 0))
4668 : State.get(Operands.getOperand(0), Part);
4669
4670 // Collect all the indices for the new GEP. If any index is
4671 // loop-invariant, we won't broadcast it.
4672 SmallVector<Value *, 4> Indices;
4673 for (unsigned I = 1, E = Operands.getNumOperands(); I < E; I++) {
4674 VPValue *Operand = Operands.getOperand(I);
4675 if (IsIndexLoopInvariant[I - 1])
4676 Indices.push_back(State.get(Operand, VPIteration(0, 0)));
4677 else
4678 Indices.push_back(State.get(Operand, Part));
4679 }
4680
4681 // Create the new GEP. Note that this GEP may be a scalar if VF == 1,
4682 // but it should be a vector, otherwise.
4683 auto *NewGEP =
4684 GEP->isInBounds()
4685 ? Builder.CreateInBoundsGEP(GEP->getSourceElementType(), Ptr,
4686 Indices)
4687 : Builder.CreateGEP(GEP->getSourceElementType(), Ptr, Indices);
4688 assert((VF.isScalar() || NewGEP->getType()->isVectorTy()) &&
4689 "NewGEP is not a pointer vector");
4690 State.set(VPDef, NewGEP, Part);
4691 addMetadata(NewGEP, GEP);
4692 }
4693 }
4694 }
4695
widenPHIInstruction(Instruction * PN,VPWidenPHIRecipe * PhiR,VPTransformState & State)4696 void InnerLoopVectorizer::widenPHIInstruction(Instruction *PN,
4697 VPWidenPHIRecipe *PhiR,
4698 VPTransformState &State) {
4699 PHINode *P = cast<PHINode>(PN);
4700 if (EnableVPlanNativePath) {
4701 // Currently we enter here in the VPlan-native path for non-induction
4702 // PHIs where all control flow is uniform. We simply widen these PHIs.
4703 // Create a vector phi with no operands - the vector phi operands will be
4704 // set at the end of vector code generation.
4705 Type *VecTy = (State.VF.isScalar())
4706 ? PN->getType()
4707 : VectorType::get(PN->getType(), State.VF);
4708 Value *VecPhi = Builder.CreatePHI(VecTy, PN->getNumOperands(), "vec.phi");
4709 State.set(PhiR, VecPhi, 0);
4710 OrigPHIsToFix.push_back(P);
4711
4712 return;
4713 }
4714
4715 assert(PN->getParent() == OrigLoop->getHeader() &&
4716 "Non-header phis should have been handled elsewhere");
4717
4718 // In order to support recurrences we need to be able to vectorize Phi nodes.
4719 // Phi nodes have cycles, so we need to vectorize them in two stages. This is
4720 // stage #1: We create a new vector PHI node with no incoming edges. We'll use
4721 // this value when we vectorize all of the instructions that use the PHI.
4722
4723 assert(!Legal->isReductionVariable(P) &&
4724 "reductions should be handled elsewhere");
4725
4726 setDebugLocFromInst(P);
4727
4728 // This PHINode must be an induction variable.
4729 // Make sure that we know about it.
4730 assert(Legal->getInductionVars().count(P) && "Not an induction variable");
4731
4732 InductionDescriptor II = Legal->getInductionVars().lookup(P);
4733 const DataLayout &DL = OrigLoop->getHeader()->getModule()->getDataLayout();
4734
4735 // FIXME: The newly created binary instructions should contain nsw/nuw flags,
4736 // which can be found from the original scalar operations.
4737 switch (II.getKind()) {
4738 case InductionDescriptor::IK_NoInduction:
4739 llvm_unreachable("Unknown induction");
4740 case InductionDescriptor::IK_IntInduction:
4741 case InductionDescriptor::IK_FpInduction:
4742 llvm_unreachable("Integer/fp induction is handled elsewhere.");
4743 case InductionDescriptor::IK_PtrInduction: {
4744 // Handle the pointer induction variable case.
4745 assert(P->getType()->isPointerTy() && "Unexpected type.");
4746
4747 if (Cost->isScalarAfterVectorization(P, State.VF)) {
4748 // This is the normalized GEP that starts counting at zero.
4749 Value *PtrInd =
4750 Builder.CreateSExtOrTrunc(Induction, II.getStep()->getType());
4751 // Determine the number of scalars we need to generate for each unroll
4752 // iteration. If the instruction is uniform, we only need to generate the
4753 // first lane. Otherwise, we generate all VF values.
4754 bool IsUniform = Cost->isUniformAfterVectorization(P, State.VF);
4755 unsigned Lanes = IsUniform ? 1 : State.VF.getKnownMinValue();
4756
4757 bool NeedsVectorIndex = !IsUniform && VF.isScalable();
4758 Value *UnitStepVec = nullptr, *PtrIndSplat = nullptr;
4759 if (NeedsVectorIndex) {
4760 Type *VecIVTy = VectorType::get(PtrInd->getType(), VF);
4761 UnitStepVec = Builder.CreateStepVector(VecIVTy);
4762 PtrIndSplat = Builder.CreateVectorSplat(VF, PtrInd);
4763 }
4764
4765 for (unsigned Part = 0; Part < UF; ++Part) {
4766 Value *PartStart = createStepForVF(
4767 Builder, ConstantInt::get(PtrInd->getType(), Part), VF);
4768
4769 if (NeedsVectorIndex) {
4770 Value *PartStartSplat = Builder.CreateVectorSplat(VF, PartStart);
4771 Value *Indices = Builder.CreateAdd(PartStartSplat, UnitStepVec);
4772 Value *GlobalIndices = Builder.CreateAdd(PtrIndSplat, Indices);
4773 Value *SclrGep =
4774 emitTransformedIndex(Builder, GlobalIndices, PSE.getSE(), DL, II);
4775 SclrGep->setName("next.gep");
4776 State.set(PhiR, SclrGep, Part);
4777 // We've cached the whole vector, which means we can support the
4778 // extraction of any lane.
4779 continue;
4780 }
4781
4782 for (unsigned Lane = 0; Lane < Lanes; ++Lane) {
4783 Value *Idx = Builder.CreateAdd(
4784 PartStart, ConstantInt::get(PtrInd->getType(), Lane));
4785 Value *GlobalIdx = Builder.CreateAdd(PtrInd, Idx);
4786 Value *SclrGep =
4787 emitTransformedIndex(Builder, GlobalIdx, PSE.getSE(), DL, II);
4788 SclrGep->setName("next.gep");
4789 State.set(PhiR, SclrGep, VPIteration(Part, Lane));
4790 }
4791 }
4792 return;
4793 }
4794 assert(isa<SCEVConstant>(II.getStep()) &&
4795 "Induction step not a SCEV constant!");
4796 Type *PhiType = II.getStep()->getType();
4797
4798 // Build a pointer phi
4799 Value *ScalarStartValue = II.getStartValue();
4800 Type *ScStValueType = ScalarStartValue->getType();
4801 PHINode *NewPointerPhi =
4802 PHINode::Create(ScStValueType, 2, "pointer.phi", Induction);
4803 NewPointerPhi->addIncoming(ScalarStartValue, LoopVectorPreHeader);
4804
4805 // A pointer induction, performed by using a gep
4806 BasicBlock *LoopLatch = LI->getLoopFor(LoopVectorBody)->getLoopLatch();
4807 Instruction *InductionLoc = LoopLatch->getTerminator();
4808 const SCEV *ScalarStep = II.getStep();
4809 SCEVExpander Exp(*PSE.getSE(), DL, "induction");
4810 Value *ScalarStepValue =
4811 Exp.expandCodeFor(ScalarStep, PhiType, InductionLoc);
4812 Value *RuntimeVF = getRuntimeVF(Builder, PhiType, VF);
4813 Value *NumUnrolledElems =
4814 Builder.CreateMul(RuntimeVF, ConstantInt::get(PhiType, State.UF));
4815 Value *InductionGEP = GetElementPtrInst::Create(
4816 ScStValueType->getPointerElementType(), NewPointerPhi,
4817 Builder.CreateMul(ScalarStepValue, NumUnrolledElems), "ptr.ind",
4818 InductionLoc);
4819 NewPointerPhi->addIncoming(InductionGEP, LoopLatch);
4820
4821 // Create UF many actual address geps that use the pointer
4822 // phi as base and a vectorized version of the step value
4823 // (<step*0, ..., step*N>) as offset.
4824 for (unsigned Part = 0; Part < State.UF; ++Part) {
4825 Type *VecPhiType = VectorType::get(PhiType, State.VF);
4826 Value *StartOffsetScalar =
4827 Builder.CreateMul(RuntimeVF, ConstantInt::get(PhiType, Part));
4828 Value *StartOffset =
4829 Builder.CreateVectorSplat(State.VF, StartOffsetScalar);
4830 // Create a vector of consecutive numbers from zero to VF.
4831 StartOffset =
4832 Builder.CreateAdd(StartOffset, Builder.CreateStepVector(VecPhiType));
4833
4834 Value *GEP = Builder.CreateGEP(
4835 ScStValueType->getPointerElementType(), NewPointerPhi,
4836 Builder.CreateMul(
4837 StartOffset, Builder.CreateVectorSplat(State.VF, ScalarStepValue),
4838 "vector.gep"));
4839 State.set(PhiR, GEP, Part);
4840 }
4841 }
4842 }
4843 }
4844
4845 /// A helper function for checking whether an integer division-related
4846 /// instruction may divide by zero (in which case it must be predicated if
4847 /// executed conditionally in the scalar code).
4848 /// TODO: It may be worthwhile to generalize and check isKnownNonZero().
4849 /// Non-zero divisors that are non compile-time constants will not be
4850 /// converted into multiplication, so we will still end up scalarizing
4851 /// the division, but can do so w/o predication.
mayDivideByZero(Instruction & I)4852 static bool mayDivideByZero(Instruction &I) {
4853 assert((I.getOpcode() == Instruction::UDiv ||
4854 I.getOpcode() == Instruction::SDiv ||
4855 I.getOpcode() == Instruction::URem ||
4856 I.getOpcode() == Instruction::SRem) &&
4857 "Unexpected instruction");
4858 Value *Divisor = I.getOperand(1);
4859 auto *CInt = dyn_cast<ConstantInt>(Divisor);
4860 return !CInt || CInt->isZero();
4861 }
4862
widenInstruction(Instruction & I,VPValue * Def,VPUser & User,VPTransformState & State)4863 void InnerLoopVectorizer::widenInstruction(Instruction &I, VPValue *Def,
4864 VPUser &User,
4865 VPTransformState &State) {
4866 switch (I.getOpcode()) {
4867 case Instruction::Call:
4868 case Instruction::Br:
4869 case Instruction::PHI:
4870 case Instruction::GetElementPtr:
4871 case Instruction::Select:
4872 llvm_unreachable("This instruction is handled by a different recipe.");
4873 case Instruction::UDiv:
4874 case Instruction::SDiv:
4875 case Instruction::SRem:
4876 case Instruction::URem:
4877 case Instruction::Add:
4878 case Instruction::FAdd:
4879 case Instruction::Sub:
4880 case Instruction::FSub:
4881 case Instruction::FNeg:
4882 case Instruction::Mul:
4883 case Instruction::FMul:
4884 case Instruction::FDiv:
4885 case Instruction::FRem:
4886 case Instruction::Shl:
4887 case Instruction::LShr:
4888 case Instruction::AShr:
4889 case Instruction::And:
4890 case Instruction::Or:
4891 case Instruction::Xor: {
4892 // Just widen unops and binops.
4893 setDebugLocFromInst(&I);
4894
4895 for (unsigned Part = 0; Part < UF; ++Part) {
4896 SmallVector<Value *, 2> Ops;
4897 for (VPValue *VPOp : User.operands())
4898 Ops.push_back(State.get(VPOp, Part));
4899
4900 Value *V = Builder.CreateNAryOp(I.getOpcode(), Ops);
4901
4902 if (auto *VecOp = dyn_cast<Instruction>(V))
4903 VecOp->copyIRFlags(&I);
4904
4905 // Use this vector value for all users of the original instruction.
4906 State.set(Def, V, Part);
4907 addMetadata(V, &I);
4908 }
4909
4910 break;
4911 }
4912 case Instruction::ICmp:
4913 case Instruction::FCmp: {
4914 // Widen compares. Generate vector compares.
4915 bool FCmp = (I.getOpcode() == Instruction::FCmp);
4916 auto *Cmp = cast<CmpInst>(&I);
4917 setDebugLocFromInst(Cmp);
4918 for (unsigned Part = 0; Part < UF; ++Part) {
4919 Value *A = State.get(User.getOperand(0), Part);
4920 Value *B = State.get(User.getOperand(1), Part);
4921 Value *C = nullptr;
4922 if (FCmp) {
4923 // Propagate fast math flags.
4924 IRBuilder<>::FastMathFlagGuard FMFG(Builder);
4925 Builder.setFastMathFlags(Cmp->getFastMathFlags());
4926 C = Builder.CreateFCmp(Cmp->getPredicate(), A, B);
4927 } else {
4928 C = Builder.CreateICmp(Cmp->getPredicate(), A, B);
4929 }
4930 State.set(Def, C, Part);
4931 addMetadata(C, &I);
4932 }
4933
4934 break;
4935 }
4936
4937 case Instruction::ZExt:
4938 case Instruction::SExt:
4939 case Instruction::FPToUI:
4940 case Instruction::FPToSI:
4941 case Instruction::FPExt:
4942 case Instruction::PtrToInt:
4943 case Instruction::IntToPtr:
4944 case Instruction::SIToFP:
4945 case Instruction::UIToFP:
4946 case Instruction::Trunc:
4947 case Instruction::FPTrunc:
4948 case Instruction::BitCast: {
4949 auto *CI = cast<CastInst>(&I);
4950 setDebugLocFromInst(CI);
4951
4952 /// Vectorize casts.
4953 Type *DestTy =
4954 (VF.isScalar()) ? CI->getType() : VectorType::get(CI->getType(), VF);
4955
4956 for (unsigned Part = 0; Part < UF; ++Part) {
4957 Value *A = State.get(User.getOperand(0), Part);
4958 Value *Cast = Builder.CreateCast(CI->getOpcode(), A, DestTy);
4959 State.set(Def, Cast, Part);
4960 addMetadata(Cast, &I);
4961 }
4962 break;
4963 }
4964 default:
4965 // This instruction is not vectorized by simple widening.
4966 LLVM_DEBUG(dbgs() << "LV: Found an unhandled instruction: " << I);
4967 llvm_unreachable("Unhandled instruction!");
4968 } // end of switch.
4969 }
4970
widenCallInstruction(CallInst & I,VPValue * Def,VPUser & ArgOperands,VPTransformState & State)4971 void InnerLoopVectorizer::widenCallInstruction(CallInst &I, VPValue *Def,
4972 VPUser &ArgOperands,
4973 VPTransformState &State) {
4974 assert(!isa<DbgInfoIntrinsic>(I) &&
4975 "DbgInfoIntrinsic should have been dropped during VPlan construction");
4976 setDebugLocFromInst(&I);
4977
4978 Module *M = I.getParent()->getParent()->getParent();
4979 auto *CI = cast<CallInst>(&I);
4980
4981 SmallVector<Type *, 4> Tys;
4982 for (Value *ArgOperand : CI->arg_operands())
4983 Tys.push_back(ToVectorTy(ArgOperand->getType(), VF.getKnownMinValue()));
4984
4985 Intrinsic::ID ID = getVectorIntrinsicIDForCall(CI, TLI);
4986
4987 // The flag shows whether we use Intrinsic or a usual Call for vectorized
4988 // version of the instruction.
4989 // Is it beneficial to perform intrinsic call compared to lib call?
4990 bool NeedToScalarize = false;
4991 InstructionCost CallCost = Cost->getVectorCallCost(CI, VF, NeedToScalarize);
4992 InstructionCost IntrinsicCost = ID ? Cost->getVectorIntrinsicCost(CI, VF) : 0;
4993 bool UseVectorIntrinsic = ID && IntrinsicCost <= CallCost;
4994 assert((UseVectorIntrinsic || !NeedToScalarize) &&
4995 "Instruction should be scalarized elsewhere.");
4996 assert((IntrinsicCost.isValid() || CallCost.isValid()) &&
4997 "Either the intrinsic cost or vector call cost must be valid");
4998
4999 for (unsigned Part = 0; Part < UF; ++Part) {
5000 SmallVector<Type *, 2> TysForDecl = {CI->getType()};
5001 SmallVector<Value *, 4> Args;
5002 for (auto &I : enumerate(ArgOperands.operands())) {
5003 // Some intrinsics have a scalar argument - don't replace it with a
5004 // vector.
5005 Value *Arg;
5006 if (!UseVectorIntrinsic || !hasVectorInstrinsicScalarOpd(ID, I.index()))
5007 Arg = State.get(I.value(), Part);
5008 else {
5009 Arg = State.get(I.value(), VPIteration(0, 0));
5010 if (hasVectorInstrinsicOverloadedScalarOpd(ID, I.index()))
5011 TysForDecl.push_back(Arg->getType());
5012 }
5013 Args.push_back(Arg);
5014 }
5015
5016 Function *VectorF;
5017 if (UseVectorIntrinsic) {
5018 // Use vector version of the intrinsic.
5019 if (VF.isVector())
5020 TysForDecl[0] = VectorType::get(CI->getType()->getScalarType(), VF);
5021 VectorF = Intrinsic::getDeclaration(M, ID, TysForDecl);
5022 assert(VectorF && "Can't retrieve vector intrinsic.");
5023 } else {
5024 // Use vector version of the function call.
5025 const VFShape Shape = VFShape::get(*CI, VF, false /*HasGlobalPred*/);
5026 #ifndef NDEBUG
5027 assert(VFDatabase(*CI).getVectorizedFunction(Shape) != nullptr &&
5028 "Can't create vector function.");
5029 #endif
5030 VectorF = VFDatabase(*CI).getVectorizedFunction(Shape);
5031 }
5032 SmallVector<OperandBundleDef, 1> OpBundles;
5033 CI->getOperandBundlesAsDefs(OpBundles);
5034 CallInst *V = Builder.CreateCall(VectorF, Args, OpBundles);
5035
5036 if (isa<FPMathOperator>(V))
5037 V->copyFastMathFlags(CI);
5038
5039 State.set(Def, V, Part);
5040 addMetadata(V, &I);
5041 }
5042 }
5043
widenSelectInstruction(SelectInst & I,VPValue * VPDef,VPUser & Operands,bool InvariantCond,VPTransformState & State)5044 void InnerLoopVectorizer::widenSelectInstruction(SelectInst &I, VPValue *VPDef,
5045 VPUser &Operands,
5046 bool InvariantCond,
5047 VPTransformState &State) {
5048 setDebugLocFromInst(&I);
5049
5050 // The condition can be loop invariant but still defined inside the
5051 // loop. This means that we can't just use the original 'cond' value.
5052 // We have to take the 'vectorized' value and pick the first lane.
5053 // Instcombine will make this a no-op.
5054 auto *InvarCond = InvariantCond
5055 ? State.get(Operands.getOperand(0), VPIteration(0, 0))
5056 : nullptr;
5057
5058 for (unsigned Part = 0; Part < UF; ++Part) {
5059 Value *Cond =
5060 InvarCond ? InvarCond : State.get(Operands.getOperand(0), Part);
5061 Value *Op0 = State.get(Operands.getOperand(1), Part);
5062 Value *Op1 = State.get(Operands.getOperand(2), Part);
5063 Value *Sel = Builder.CreateSelect(Cond, Op0, Op1);
5064 State.set(VPDef, Sel, Part);
5065 addMetadata(Sel, &I);
5066 }
5067 }
5068
collectLoopScalars(ElementCount VF)5069 void LoopVectorizationCostModel::collectLoopScalars(ElementCount VF) {
5070 // We should not collect Scalars more than once per VF. Right now, this
5071 // function is called from collectUniformsAndScalars(), which already does
5072 // this check. Collecting Scalars for VF=1 does not make any sense.
5073 assert(VF.isVector() && Scalars.find(VF) == Scalars.end() &&
5074 "This function should not be visited twice for the same VF");
5075
5076 SmallSetVector<Instruction *, 8> Worklist;
5077
5078 // These sets are used to seed the analysis with pointers used by memory
5079 // accesses that will remain scalar.
5080 SmallSetVector<Instruction *, 8> ScalarPtrs;
5081 SmallPtrSet<Instruction *, 8> PossibleNonScalarPtrs;
5082 auto *Latch = TheLoop->getLoopLatch();
5083
5084 // A helper that returns true if the use of Ptr by MemAccess will be scalar.
5085 // The pointer operands of loads and stores will be scalar as long as the
5086 // memory access is not a gather or scatter operation. The value operand of a
5087 // store will remain scalar if the store is scalarized.
5088 auto isScalarUse = [&](Instruction *MemAccess, Value *Ptr) {
5089 InstWidening WideningDecision = getWideningDecision(MemAccess, VF);
5090 assert(WideningDecision != CM_Unknown &&
5091 "Widening decision should be ready at this moment");
5092 if (auto *Store = dyn_cast<StoreInst>(MemAccess))
5093 if (Ptr == Store->getValueOperand())
5094 return WideningDecision == CM_Scalarize;
5095 assert(Ptr == getLoadStorePointerOperand(MemAccess) &&
5096 "Ptr is neither a value or pointer operand");
5097 return WideningDecision != CM_GatherScatter;
5098 };
5099
5100 // A helper that returns true if the given value is a bitcast or
5101 // getelementptr instruction contained in the loop.
5102 auto isLoopVaryingBitCastOrGEP = [&](Value *V) {
5103 return ((isa<BitCastInst>(V) && V->getType()->isPointerTy()) ||
5104 isa<GetElementPtrInst>(V)) &&
5105 !TheLoop->isLoopInvariant(V);
5106 };
5107
5108 auto isScalarPtrInduction = [&](Instruction *MemAccess, Value *Ptr) {
5109 if (!isa<PHINode>(Ptr) ||
5110 !Legal->getInductionVars().count(cast<PHINode>(Ptr)))
5111 return false;
5112 auto &Induction = Legal->getInductionVars()[cast<PHINode>(Ptr)];
5113 if (Induction.getKind() != InductionDescriptor::IK_PtrInduction)
5114 return false;
5115 return isScalarUse(MemAccess, Ptr);
5116 };
5117
5118 // A helper that evaluates a memory access's use of a pointer. If the
5119 // pointer is actually the pointer induction of a loop, it is being
5120 // inserted into Worklist. If the use will be a scalar use, and the
5121 // pointer is only used by memory accesses, we place the pointer in
5122 // ScalarPtrs. Otherwise, the pointer is placed in PossibleNonScalarPtrs.
5123 auto evaluatePtrUse = [&](Instruction *MemAccess, Value *Ptr) {
5124 if (isScalarPtrInduction(MemAccess, Ptr)) {
5125 Worklist.insert(cast<Instruction>(Ptr));
5126 LLVM_DEBUG(dbgs() << "LV: Found new scalar instruction: " << *Ptr
5127 << "\n");
5128
5129 Instruction *Update = cast<Instruction>(
5130 cast<PHINode>(Ptr)->getIncomingValueForBlock(Latch));
5131 ScalarPtrs.insert(Update);
5132 return;
5133 }
5134 // We only care about bitcast and getelementptr instructions contained in
5135 // the loop.
5136 if (!isLoopVaryingBitCastOrGEP(Ptr))
5137 return;
5138
5139 // If the pointer has already been identified as scalar (e.g., if it was
5140 // also identified as uniform), there's nothing to do.
5141 auto *I = cast<Instruction>(Ptr);
5142 if (Worklist.count(I))
5143 return;
5144
5145 // If all users of the pointer will be memory accesses and scalar, place the
5146 // pointer in ScalarPtrs. Otherwise, place the pointer in
5147 // PossibleNonScalarPtrs.
5148 if (llvm::all_of(I->users(), [&](User *U) {
5149 return (isa<LoadInst>(U) || isa<StoreInst>(U)) &&
5150 isScalarUse(cast<Instruction>(U), Ptr);
5151 }))
5152 ScalarPtrs.insert(I);
5153 else
5154 PossibleNonScalarPtrs.insert(I);
5155 };
5156
5157 // We seed the scalars analysis with three classes of instructions: (1)
5158 // instructions marked uniform-after-vectorization and (2) bitcast,
5159 // getelementptr and (pointer) phi instructions used by memory accesses
5160 // requiring a scalar use.
5161 //
5162 // (1) Add to the worklist all instructions that have been identified as
5163 // uniform-after-vectorization.
5164 Worklist.insert(Uniforms[VF].begin(), Uniforms[VF].end());
5165
5166 // (2) Add to the worklist all bitcast and getelementptr instructions used by
5167 // memory accesses requiring a scalar use. The pointer operands of loads and
5168 // stores will be scalar as long as the memory accesses is not a gather or
5169 // scatter operation. The value operand of a store will remain scalar if the
5170 // store is scalarized.
5171 for (auto *BB : TheLoop->blocks())
5172 for (auto &I : *BB) {
5173 if (auto *Load = dyn_cast<LoadInst>(&I)) {
5174 evaluatePtrUse(Load, Load->getPointerOperand());
5175 } else if (auto *Store = dyn_cast<StoreInst>(&I)) {
5176 evaluatePtrUse(Store, Store->getPointerOperand());
5177 evaluatePtrUse(Store, Store->getValueOperand());
5178 }
5179 }
5180 for (auto *I : ScalarPtrs)
5181 if (!PossibleNonScalarPtrs.count(I)) {
5182 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *I << "\n");
5183 Worklist.insert(I);
5184 }
5185
5186 // Insert the forced scalars.
5187 // FIXME: Currently widenPHIInstruction() often creates a dead vector
5188 // induction variable when the PHI user is scalarized.
5189 auto ForcedScalar = ForcedScalars.find(VF);
5190 if (ForcedScalar != ForcedScalars.end())
5191 for (auto *I : ForcedScalar->second)
5192 Worklist.insert(I);
5193
5194 // Expand the worklist by looking through any bitcasts and getelementptr
5195 // instructions we've already identified as scalar. This is similar to the
5196 // expansion step in collectLoopUniforms(); however, here we're only
5197 // expanding to include additional bitcasts and getelementptr instructions.
5198 unsigned Idx = 0;
5199 while (Idx != Worklist.size()) {
5200 Instruction *Dst = Worklist[Idx++];
5201 if (!isLoopVaryingBitCastOrGEP(Dst->getOperand(0)))
5202 continue;
5203 auto *Src = cast<Instruction>(Dst->getOperand(0));
5204 if (llvm::all_of(Src->users(), [&](User *U) -> bool {
5205 auto *J = cast<Instruction>(U);
5206 return !TheLoop->contains(J) || Worklist.count(J) ||
5207 ((isa<LoadInst>(J) || isa<StoreInst>(J)) &&
5208 isScalarUse(J, Src));
5209 })) {
5210 Worklist.insert(Src);
5211 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *Src << "\n");
5212 }
5213 }
5214
5215 // An induction variable will remain scalar if all users of the induction
5216 // variable and induction variable update remain scalar.
5217 for (auto &Induction : Legal->getInductionVars()) {
5218 auto *Ind = Induction.first;
5219 auto *IndUpdate = cast<Instruction>(Ind->getIncomingValueForBlock(Latch));
5220
5221 // If tail-folding is applied, the primary induction variable will be used
5222 // to feed a vector compare.
5223 if (Ind == Legal->getPrimaryInduction() && foldTailByMasking())
5224 continue;
5225
5226 // Determine if all users of the induction variable are scalar after
5227 // vectorization.
5228 auto ScalarInd = llvm::all_of(Ind->users(), [&](User *U) -> bool {
5229 auto *I = cast<Instruction>(U);
5230 return I == IndUpdate || !TheLoop->contains(I) || Worklist.count(I);
5231 });
5232 if (!ScalarInd)
5233 continue;
5234
5235 // Determine if all users of the induction variable update instruction are
5236 // scalar after vectorization.
5237 auto ScalarIndUpdate =
5238 llvm::all_of(IndUpdate->users(), [&](User *U) -> bool {
5239 auto *I = cast<Instruction>(U);
5240 return I == Ind || !TheLoop->contains(I) || Worklist.count(I);
5241 });
5242 if (!ScalarIndUpdate)
5243 continue;
5244
5245 // The induction variable and its update instruction will remain scalar.
5246 Worklist.insert(Ind);
5247 Worklist.insert(IndUpdate);
5248 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *Ind << "\n");
5249 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *IndUpdate
5250 << "\n");
5251 }
5252
5253 Scalars[VF].insert(Worklist.begin(), Worklist.end());
5254 }
5255
isScalarWithPredication(Instruction * I) const5256 bool LoopVectorizationCostModel::isScalarWithPredication(Instruction *I) const {
5257 if (!blockNeedsPredication(I->getParent()))
5258 return false;
5259 switch(I->getOpcode()) {
5260 default:
5261 break;
5262 case Instruction::Load:
5263 case Instruction::Store: {
5264 if (!Legal->isMaskRequired(I))
5265 return false;
5266 auto *Ptr = getLoadStorePointerOperand(I);
5267 auto *Ty = getLoadStoreType(I);
5268 const Align Alignment = getLoadStoreAlignment(I);
5269 return isa<LoadInst>(I) ? !(isLegalMaskedLoad(Ty, Ptr, Alignment) ||
5270 TTI.isLegalMaskedGather(Ty, Alignment))
5271 : !(isLegalMaskedStore(Ty, Ptr, Alignment) ||
5272 TTI.isLegalMaskedScatter(Ty, Alignment));
5273 }
5274 case Instruction::UDiv:
5275 case Instruction::SDiv:
5276 case Instruction::SRem:
5277 case Instruction::URem:
5278 return mayDivideByZero(*I);
5279 }
5280 return false;
5281 }
5282
interleavedAccessCanBeWidened(Instruction * I,ElementCount VF)5283 bool LoopVectorizationCostModel::interleavedAccessCanBeWidened(
5284 Instruction *I, ElementCount VF) {
5285 assert(isAccessInterleaved(I) && "Expecting interleaved access.");
5286 assert(getWideningDecision(I, VF) == CM_Unknown &&
5287 "Decision should not be set yet.");
5288 auto *Group = getInterleavedAccessGroup(I);
5289 assert(Group && "Must have a group.");
5290
5291 // If the instruction's allocated size doesn't equal it's type size, it
5292 // requires padding and will be scalarized.
5293 auto &DL = I->getModule()->getDataLayout();
5294 auto *ScalarTy = getLoadStoreType(I);
5295 if (hasIrregularType(ScalarTy, DL))
5296 return false;
5297
5298 // Check if masking is required.
5299 // A Group may need masking for one of two reasons: it resides in a block that
5300 // needs predication, or it was decided to use masking to deal with gaps.
5301 bool PredicatedAccessRequiresMasking =
5302 Legal->blockNeedsPredication(I->getParent()) && Legal->isMaskRequired(I);
5303 bool AccessWithGapsRequiresMasking =
5304 Group->requiresScalarEpilogue() && !isScalarEpilogueAllowed();
5305 if (!PredicatedAccessRequiresMasking && !AccessWithGapsRequiresMasking)
5306 return true;
5307
5308 // If masked interleaving is required, we expect that the user/target had
5309 // enabled it, because otherwise it either wouldn't have been created or
5310 // it should have been invalidated by the CostModel.
5311 assert(useMaskedInterleavedAccesses(TTI) &&
5312 "Masked interleave-groups for predicated accesses are not enabled.");
5313
5314 auto *Ty = getLoadStoreType(I);
5315 const Align Alignment = getLoadStoreAlignment(I);
5316 return isa<LoadInst>(I) ? TTI.isLegalMaskedLoad(Ty, Alignment)
5317 : TTI.isLegalMaskedStore(Ty, Alignment);
5318 }
5319
memoryInstructionCanBeWidened(Instruction * I,ElementCount VF)5320 bool LoopVectorizationCostModel::memoryInstructionCanBeWidened(
5321 Instruction *I, ElementCount VF) {
5322 // Get and ensure we have a valid memory instruction.
5323 LoadInst *LI = dyn_cast<LoadInst>(I);
5324 StoreInst *SI = dyn_cast<StoreInst>(I);
5325 assert((LI || SI) && "Invalid memory instruction");
5326
5327 auto *Ptr = getLoadStorePointerOperand(I);
5328
5329 // In order to be widened, the pointer should be consecutive, first of all.
5330 if (!Legal->isConsecutivePtr(Ptr))
5331 return false;
5332
5333 // If the instruction is a store located in a predicated block, it will be
5334 // scalarized.
5335 if (isScalarWithPredication(I))
5336 return false;
5337
5338 // If the instruction's allocated size doesn't equal it's type size, it
5339 // requires padding and will be scalarized.
5340 auto &DL = I->getModule()->getDataLayout();
5341 auto *ScalarTy = LI ? LI->getType() : SI->getValueOperand()->getType();
5342 if (hasIrregularType(ScalarTy, DL))
5343 return false;
5344
5345 return true;
5346 }
5347
collectLoopUniforms(ElementCount VF)5348 void LoopVectorizationCostModel::collectLoopUniforms(ElementCount VF) {
5349 // We should not collect Uniforms more than once per VF. Right now,
5350 // this function is called from collectUniformsAndScalars(), which
5351 // already does this check. Collecting Uniforms for VF=1 does not make any
5352 // sense.
5353
5354 assert(VF.isVector() && Uniforms.find(VF) == Uniforms.end() &&
5355 "This function should not be visited twice for the same VF");
5356
5357 // Visit the list of Uniforms. If we'll not find any uniform value, we'll
5358 // not analyze again. Uniforms.count(VF) will return 1.
5359 Uniforms[VF].clear();
5360
5361 // We now know that the loop is vectorizable!
5362 // Collect instructions inside the loop that will remain uniform after
5363 // vectorization.
5364
5365 // Global values, params and instructions outside of current loop are out of
5366 // scope.
5367 auto isOutOfScope = [&](Value *V) -> bool {
5368 Instruction *I = dyn_cast<Instruction>(V);
5369 return (!I || !TheLoop->contains(I));
5370 };
5371
5372 SetVector<Instruction *> Worklist;
5373 BasicBlock *Latch = TheLoop->getLoopLatch();
5374
5375 // Instructions that are scalar with predication must not be considered
5376 // uniform after vectorization, because that would create an erroneous
5377 // replicating region where only a single instance out of VF should be formed.
5378 // TODO: optimize such seldom cases if found important, see PR40816.
5379 auto addToWorklistIfAllowed = [&](Instruction *I) -> void {
5380 if (isOutOfScope(I)) {
5381 LLVM_DEBUG(dbgs() << "LV: Found not uniform due to scope: "
5382 << *I << "\n");
5383 return;
5384 }
5385 if (isScalarWithPredication(I)) {
5386 LLVM_DEBUG(dbgs() << "LV: Found not uniform being ScalarWithPredication: "
5387 << *I << "\n");
5388 return;
5389 }
5390 LLVM_DEBUG(dbgs() << "LV: Found uniform instruction: " << *I << "\n");
5391 Worklist.insert(I);
5392 };
5393
5394 // Start with the conditional branch. If the branch condition is an
5395 // instruction contained in the loop that is only used by the branch, it is
5396 // uniform.
5397 auto *Cmp = dyn_cast<Instruction>(Latch->getTerminator()->getOperand(0));
5398 if (Cmp && TheLoop->contains(Cmp) && Cmp->hasOneUse())
5399 addToWorklistIfAllowed(Cmp);
5400
5401 auto isUniformDecision = [&](Instruction *I, ElementCount VF) {
5402 InstWidening WideningDecision = getWideningDecision(I, VF);
5403 assert(WideningDecision != CM_Unknown &&
5404 "Widening decision should be ready at this moment");
5405
5406 // A uniform memory op is itself uniform. We exclude uniform stores
5407 // here as they demand the last lane, not the first one.
5408 if (isa<LoadInst>(I) && Legal->isUniformMemOp(*I)) {
5409 assert(WideningDecision == CM_Scalarize);
5410 return true;
5411 }
5412
5413 return (WideningDecision == CM_Widen ||
5414 WideningDecision == CM_Widen_Reverse ||
5415 WideningDecision == CM_Interleave);
5416 };
5417
5418 // Returns true if Ptr is the pointer operand of a memory access instruction
5419 // I, I is known to not require scalarization, and the pointer is not also
5420 // stored.
5421 auto isVectorizedMemAccessUse = [&](Instruction *I, Value *Ptr) -> bool {
5422 auto GetStoredValue = [I]() -> Value * {
5423 if (!isa<StoreInst>(I))
5424 return nullptr;
5425 return I->getOperand(0);
5426 };
5427 return getLoadStorePointerOperand(I) == Ptr && isUniformDecision(I, VF) &&
5428 GetStoredValue() != Ptr;
5429 };
5430
5431 // Holds a list of values which are known to have at least one uniform use.
5432 // Note that there may be other uses which aren't uniform. A "uniform use"
5433 // here is something which only demands lane 0 of the unrolled iterations;
5434 // it does not imply that all lanes produce the same value (e.g. this is not
5435 // the usual meaning of uniform)
5436 SetVector<Value *> HasUniformUse;
5437
5438 // Scan the loop for instructions which are either a) known to have only
5439 // lane 0 demanded or b) are uses which demand only lane 0 of their operand.
5440 for (auto *BB : TheLoop->blocks())
5441 for (auto &I : *BB) {
5442 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(&I)) {
5443 switch (II->getIntrinsicID()) {
5444 case Intrinsic::sideeffect:
5445 case Intrinsic::experimental_noalias_scope_decl:
5446 case Intrinsic::assume:
5447 case Intrinsic::lifetime_start:
5448 case Intrinsic::lifetime_end:
5449 if (TheLoop->hasLoopInvariantOperands(&I))
5450 addToWorklistIfAllowed(&I);
5451 break;
5452 default:
5453 break;
5454 }
5455 }
5456
5457 // If there's no pointer operand, there's nothing to do.
5458 auto *Ptr = getLoadStorePointerOperand(&I);
5459 if (!Ptr)
5460 continue;
5461
5462 // A uniform memory op is itself uniform. We exclude uniform stores
5463 // here as they demand the last lane, not the first one.
5464 if (isa<LoadInst>(I) && Legal->isUniformMemOp(I))
5465 addToWorklistIfAllowed(&I);
5466
5467 if (isVectorizedMemAccessUse(&I, Ptr)) {
5468 assert(isUniformDecision(&I, VF) && "consistency check");
5469 HasUniformUse.insert(Ptr);
5470 }
5471 }
5472
5473 // Add to the worklist any operands which have *only* uniform (e.g. lane 0
5474 // demanding) users. Since loops are assumed to be in LCSSA form, this
5475 // disallows uses outside the loop as well.
5476 for (auto *V : HasUniformUse) {
5477 if (isOutOfScope(V))
5478 continue;
5479 auto *I = cast<Instruction>(V);
5480 auto UsersAreMemAccesses =
5481 llvm::all_of(I->users(), [&](User *U) -> bool {
5482 return isVectorizedMemAccessUse(cast<Instruction>(U), V);
5483 });
5484 if (UsersAreMemAccesses)
5485 addToWorklistIfAllowed(I);
5486 }
5487
5488 // Expand Worklist in topological order: whenever a new instruction
5489 // is added , its users should be already inside Worklist. It ensures
5490 // a uniform instruction will only be used by uniform instructions.
5491 unsigned idx = 0;
5492 while (idx != Worklist.size()) {
5493 Instruction *I = Worklist[idx++];
5494
5495 for (auto OV : I->operand_values()) {
5496 // isOutOfScope operands cannot be uniform instructions.
5497 if (isOutOfScope(OV))
5498 continue;
5499 // First order recurrence Phi's should typically be considered
5500 // non-uniform.
5501 auto *OP = dyn_cast<PHINode>(OV);
5502 if (OP && Legal->isFirstOrderRecurrence(OP))
5503 continue;
5504 // If all the users of the operand are uniform, then add the
5505 // operand into the uniform worklist.
5506 auto *OI = cast<Instruction>(OV);
5507 if (llvm::all_of(OI->users(), [&](User *U) -> bool {
5508 auto *J = cast<Instruction>(U);
5509 return Worklist.count(J) || isVectorizedMemAccessUse(J, OI);
5510 }))
5511 addToWorklistIfAllowed(OI);
5512 }
5513 }
5514
5515 // For an instruction to be added into Worklist above, all its users inside
5516 // the loop should also be in Worklist. However, this condition cannot be
5517 // true for phi nodes that form a cyclic dependence. We must process phi
5518 // nodes separately. An induction variable will remain uniform if all users
5519 // of the induction variable and induction variable update remain uniform.
5520 // The code below handles both pointer and non-pointer induction variables.
5521 for (auto &Induction : Legal->getInductionVars()) {
5522 auto *Ind = Induction.first;
5523 auto *IndUpdate = cast<Instruction>(Ind->getIncomingValueForBlock(Latch));
5524
5525 // Determine if all users of the induction variable are uniform after
5526 // vectorization.
5527 auto UniformInd = llvm::all_of(Ind->users(), [&](User *U) -> bool {
5528 auto *I = cast<Instruction>(U);
5529 return I == IndUpdate || !TheLoop->contains(I) || Worklist.count(I) ||
5530 isVectorizedMemAccessUse(I, Ind);
5531 });
5532 if (!UniformInd)
5533 continue;
5534
5535 // Determine if all users of the induction variable update instruction are
5536 // uniform after vectorization.
5537 auto UniformIndUpdate =
5538 llvm::all_of(IndUpdate->users(), [&](User *U) -> bool {
5539 auto *I = cast<Instruction>(U);
5540 return I == Ind || !TheLoop->contains(I) || Worklist.count(I) ||
5541 isVectorizedMemAccessUse(I, IndUpdate);
5542 });
5543 if (!UniformIndUpdate)
5544 continue;
5545
5546 // The induction variable and its update instruction will remain uniform.
5547 addToWorklistIfAllowed(Ind);
5548 addToWorklistIfAllowed(IndUpdate);
5549 }
5550
5551 Uniforms[VF].insert(Worklist.begin(), Worklist.end());
5552 }
5553
runtimeChecksRequired()5554 bool LoopVectorizationCostModel::runtimeChecksRequired() {
5555 LLVM_DEBUG(dbgs() << "LV: Performing code size checks.\n");
5556
5557 if (Legal->getRuntimePointerChecking()->Need) {
5558 reportVectorizationFailure("Runtime ptr check is required with -Os/-Oz",
5559 "runtime pointer checks needed. Enable vectorization of this "
5560 "loop with '#pragma clang loop vectorize(enable)' when "
5561 "compiling with -Os/-Oz",
5562 "CantVersionLoopWithOptForSize", ORE, TheLoop);
5563 return true;
5564 }
5565
5566 if (!PSE.getUnionPredicate().getPredicates().empty()) {
5567 reportVectorizationFailure("Runtime SCEV check is required with -Os/-Oz",
5568 "runtime SCEV checks needed. Enable vectorization of this "
5569 "loop with '#pragma clang loop vectorize(enable)' when "
5570 "compiling with -Os/-Oz",
5571 "CantVersionLoopWithOptForSize", ORE, TheLoop);
5572 return true;
5573 }
5574
5575 // FIXME: Avoid specializing for stride==1 instead of bailing out.
5576 if (!Legal->getLAI()->getSymbolicStrides().empty()) {
5577 reportVectorizationFailure("Runtime stride check for small trip count",
5578 "runtime stride == 1 checks needed. Enable vectorization of "
5579 "this loop without such check by compiling with -Os/-Oz",
5580 "CantVersionLoopWithOptForSize", ORE, TheLoop);
5581 return true;
5582 }
5583
5584 return false;
5585 }
5586
5587 ElementCount
getMaxLegalScalableVF(unsigned MaxSafeElements)5588 LoopVectorizationCostModel::getMaxLegalScalableVF(unsigned MaxSafeElements) {
5589 if (!TTI.supportsScalableVectors() && !ForceTargetSupportsScalableVectors) {
5590 reportVectorizationInfo(
5591 "Disabling scalable vectorization, because target does not "
5592 "support scalable vectors.",
5593 "ScalableVectorsUnsupported", ORE, TheLoop);
5594 return ElementCount::getScalable(0);
5595 }
5596
5597 if (Hints->isScalableVectorizationDisabled()) {
5598 reportVectorizationInfo("Scalable vectorization is explicitly disabled",
5599 "ScalableVectorizationDisabled", ORE, TheLoop);
5600 return ElementCount::getScalable(0);
5601 }
5602
5603 auto MaxScalableVF = ElementCount::getScalable(
5604 std::numeric_limits<ElementCount::ScalarTy>::max());
5605
5606 // Test that the loop-vectorizer can legalize all operations for this MaxVF.
5607 // FIXME: While for scalable vectors this is currently sufficient, this should
5608 // be replaced by a more detailed mechanism that filters out specific VFs,
5609 // instead of invalidating vectorization for a whole set of VFs based on the
5610 // MaxVF.
5611
5612 // Disable scalable vectorization if the loop contains unsupported reductions.
5613 if (!canVectorizeReductions(MaxScalableVF)) {
5614 reportVectorizationInfo(
5615 "Scalable vectorization not supported for the reduction "
5616 "operations found in this loop.",
5617 "ScalableVFUnfeasible", ORE, TheLoop);
5618 return ElementCount::getScalable(0);
5619 }
5620
5621 // Disable scalable vectorization if the loop contains any instructions
5622 // with element types not supported for scalable vectors.
5623 if (any_of(ElementTypesInLoop, [&](Type *Ty) {
5624 return !Ty->isVoidTy() &&
5625 !this->TTI.isElementTypeLegalForScalableVector(Ty);
5626 })) {
5627 reportVectorizationInfo("Scalable vectorization is not supported "
5628 "for all element types found in this loop.",
5629 "ScalableVFUnfeasible", ORE, TheLoop);
5630 return ElementCount::getScalable(0);
5631 }
5632
5633 if (Legal->isSafeForAnyVectorWidth())
5634 return MaxScalableVF;
5635
5636 // Limit MaxScalableVF by the maximum safe dependence distance.
5637 Optional<unsigned> MaxVScale = TTI.getMaxVScale();
5638 MaxScalableVF = ElementCount::getScalable(
5639 MaxVScale ? (MaxSafeElements / MaxVScale.getValue()) : 0);
5640 if (!MaxScalableVF)
5641 reportVectorizationInfo(
5642 "Max legal vector width too small, scalable vectorization "
5643 "unfeasible.",
5644 "ScalableVFUnfeasible", ORE, TheLoop);
5645
5646 return MaxScalableVF;
5647 }
5648
5649 FixedScalableVFPair
computeFeasibleMaxVF(unsigned ConstTripCount,ElementCount UserVF)5650 LoopVectorizationCostModel::computeFeasibleMaxVF(unsigned ConstTripCount,
5651 ElementCount UserVF) {
5652 MinBWs = computeMinimumValueSizes(TheLoop->getBlocks(), *DB, &TTI);
5653 unsigned SmallestType, WidestType;
5654 std::tie(SmallestType, WidestType) = getSmallestAndWidestTypes();
5655
5656 // Get the maximum safe dependence distance in bits computed by LAA.
5657 // It is computed by MaxVF * sizeOf(type) * 8, where type is taken from
5658 // the memory accesses that is most restrictive (involved in the smallest
5659 // dependence distance).
5660 unsigned MaxSafeElements =
5661 PowerOf2Floor(Legal->getMaxSafeVectorWidthInBits() / WidestType);
5662
5663 auto MaxSafeFixedVF = ElementCount::getFixed(MaxSafeElements);
5664 auto MaxSafeScalableVF = getMaxLegalScalableVF(MaxSafeElements);
5665
5666 LLVM_DEBUG(dbgs() << "LV: The max safe fixed VF is: " << MaxSafeFixedVF
5667 << ".\n");
5668 LLVM_DEBUG(dbgs() << "LV: The max safe scalable VF is: " << MaxSafeScalableVF
5669 << ".\n");
5670
5671 // First analyze the UserVF, fall back if the UserVF should be ignored.
5672 if (UserVF) {
5673 auto MaxSafeUserVF =
5674 UserVF.isScalable() ? MaxSafeScalableVF : MaxSafeFixedVF;
5675
5676 if (ElementCount::isKnownLE(UserVF, MaxSafeUserVF)) {
5677 // If `VF=vscale x N` is safe, then so is `VF=N`
5678 if (UserVF.isScalable())
5679 return FixedScalableVFPair(
5680 ElementCount::getFixed(UserVF.getKnownMinValue()), UserVF);
5681 else
5682 return UserVF;
5683 }
5684
5685 assert(ElementCount::isKnownGT(UserVF, MaxSafeUserVF));
5686
5687 // Only clamp if the UserVF is not scalable. If the UserVF is scalable, it
5688 // is better to ignore the hint and let the compiler choose a suitable VF.
5689 if (!UserVF.isScalable()) {
5690 LLVM_DEBUG(dbgs() << "LV: User VF=" << UserVF
5691 << " is unsafe, clamping to max safe VF="
5692 << MaxSafeFixedVF << ".\n");
5693 ORE->emit([&]() {
5694 return OptimizationRemarkAnalysis(DEBUG_TYPE, "VectorizationFactor",
5695 TheLoop->getStartLoc(),
5696 TheLoop->getHeader())
5697 << "User-specified vectorization factor "
5698 << ore::NV("UserVectorizationFactor", UserVF)
5699 << " is unsafe, clamping to maximum safe vectorization factor "
5700 << ore::NV("VectorizationFactor", MaxSafeFixedVF);
5701 });
5702 return MaxSafeFixedVF;
5703 }
5704
5705 LLVM_DEBUG(dbgs() << "LV: User VF=" << UserVF
5706 << " is unsafe. Ignoring scalable UserVF.\n");
5707 ORE->emit([&]() {
5708 return OptimizationRemarkAnalysis(DEBUG_TYPE, "VectorizationFactor",
5709 TheLoop->getStartLoc(),
5710 TheLoop->getHeader())
5711 << "User-specified vectorization factor "
5712 << ore::NV("UserVectorizationFactor", UserVF)
5713 << " is unsafe. Ignoring the hint to let the compiler pick a "
5714 "suitable VF.";
5715 });
5716 }
5717
5718 LLVM_DEBUG(dbgs() << "LV: The Smallest and Widest types: " << SmallestType
5719 << " / " << WidestType << " bits.\n");
5720
5721 FixedScalableVFPair Result(ElementCount::getFixed(1),
5722 ElementCount::getScalable(0));
5723 if (auto MaxVF = getMaximizedVFForTarget(ConstTripCount, SmallestType,
5724 WidestType, MaxSafeFixedVF))
5725 Result.FixedVF = MaxVF;
5726
5727 if (auto MaxVF = getMaximizedVFForTarget(ConstTripCount, SmallestType,
5728 WidestType, MaxSafeScalableVF))
5729 if (MaxVF.isScalable()) {
5730 Result.ScalableVF = MaxVF;
5731 LLVM_DEBUG(dbgs() << "LV: Found feasible scalable VF = " << MaxVF
5732 << "\n");
5733 }
5734
5735 return Result;
5736 }
5737
5738 FixedScalableVFPair
computeMaxVF(ElementCount UserVF,unsigned UserIC)5739 LoopVectorizationCostModel::computeMaxVF(ElementCount UserVF, unsigned UserIC) {
5740 if (Legal->getRuntimePointerChecking()->Need && TTI.hasBranchDivergence()) {
5741 // TODO: It may by useful to do since it's still likely to be dynamically
5742 // uniform if the target can skip.
5743 reportVectorizationFailure(
5744 "Not inserting runtime ptr check for divergent target",
5745 "runtime pointer checks needed. Not enabled for divergent target",
5746 "CantVersionLoopWithDivergentTarget", ORE, TheLoop);
5747 return FixedScalableVFPair::getNone();
5748 }
5749
5750 unsigned TC = PSE.getSE()->getSmallConstantTripCount(TheLoop);
5751 LLVM_DEBUG(dbgs() << "LV: Found trip count: " << TC << '\n');
5752 if (TC == 1) {
5753 reportVectorizationFailure("Single iteration (non) loop",
5754 "loop trip count is one, irrelevant for vectorization",
5755 "SingleIterationLoop", ORE, TheLoop);
5756 return FixedScalableVFPair::getNone();
5757 }
5758
5759 switch (ScalarEpilogueStatus) {
5760 case CM_ScalarEpilogueAllowed:
5761 return computeFeasibleMaxVF(TC, UserVF);
5762 case CM_ScalarEpilogueNotAllowedUsePredicate:
5763 LLVM_FALLTHROUGH;
5764 case CM_ScalarEpilogueNotNeededUsePredicate:
5765 LLVM_DEBUG(
5766 dbgs() << "LV: vector predicate hint/switch found.\n"
5767 << "LV: Not allowing scalar epilogue, creating predicated "
5768 << "vector loop.\n");
5769 break;
5770 case CM_ScalarEpilogueNotAllowedLowTripLoop:
5771 // fallthrough as a special case of OptForSize
5772 case CM_ScalarEpilogueNotAllowedOptSize:
5773 if (ScalarEpilogueStatus == CM_ScalarEpilogueNotAllowedOptSize)
5774 LLVM_DEBUG(
5775 dbgs() << "LV: Not allowing scalar epilogue due to -Os/-Oz.\n");
5776 else
5777 LLVM_DEBUG(dbgs() << "LV: Not allowing scalar epilogue due to low trip "
5778 << "count.\n");
5779
5780 // Bail if runtime checks are required, which are not good when optimising
5781 // for size.
5782 if (runtimeChecksRequired())
5783 return FixedScalableVFPair::getNone();
5784
5785 break;
5786 }
5787
5788 // The only loops we can vectorize without a scalar epilogue, are loops with
5789 // a bottom-test and a single exiting block. We'd have to handle the fact
5790 // that not every instruction executes on the last iteration. This will
5791 // require a lane mask which varies through the vector loop body. (TODO)
5792 if (TheLoop->getExitingBlock() != TheLoop->getLoopLatch()) {
5793 // If there was a tail-folding hint/switch, but we can't fold the tail by
5794 // masking, fallback to a vectorization with a scalar epilogue.
5795 if (ScalarEpilogueStatus == CM_ScalarEpilogueNotNeededUsePredicate) {
5796 LLVM_DEBUG(dbgs() << "LV: Cannot fold tail by masking: vectorize with a "
5797 "scalar epilogue instead.\n");
5798 ScalarEpilogueStatus = CM_ScalarEpilogueAllowed;
5799 return computeFeasibleMaxVF(TC, UserVF);
5800 }
5801 return FixedScalableVFPair::getNone();
5802 }
5803
5804 // Now try the tail folding
5805
5806 // Invalidate interleave groups that require an epilogue if we can't mask
5807 // the interleave-group.
5808 if (!useMaskedInterleavedAccesses(TTI)) {
5809 assert(WideningDecisions.empty() && Uniforms.empty() && Scalars.empty() &&
5810 "No decisions should have been taken at this point");
5811 // Note: There is no need to invalidate any cost modeling decisions here, as
5812 // non where taken so far.
5813 InterleaveInfo.invalidateGroupsRequiringScalarEpilogue();
5814 }
5815
5816 FixedScalableVFPair MaxFactors = computeFeasibleMaxVF(TC, UserVF);
5817 // Avoid tail folding if the trip count is known to be a multiple of any VF
5818 // we chose.
5819 // FIXME: The condition below pessimises the case for fixed-width vectors,
5820 // when scalable VFs are also candidates for vectorization.
5821 if (MaxFactors.FixedVF.isVector() && !MaxFactors.ScalableVF) {
5822 ElementCount MaxFixedVF = MaxFactors.FixedVF;
5823 assert((UserVF.isNonZero() || isPowerOf2_32(MaxFixedVF.getFixedValue())) &&
5824 "MaxFixedVF must be a power of 2");
5825 unsigned MaxVFtimesIC = UserIC ? MaxFixedVF.getFixedValue() * UserIC
5826 : MaxFixedVF.getFixedValue();
5827 ScalarEvolution *SE = PSE.getSE();
5828 const SCEV *BackedgeTakenCount = PSE.getBackedgeTakenCount();
5829 const SCEV *ExitCount = SE->getAddExpr(
5830 BackedgeTakenCount, SE->getOne(BackedgeTakenCount->getType()));
5831 const SCEV *Rem = SE->getURemExpr(
5832 SE->applyLoopGuards(ExitCount, TheLoop),
5833 SE->getConstant(BackedgeTakenCount->getType(), MaxVFtimesIC));
5834 if (Rem->isZero()) {
5835 // Accept MaxFixedVF if we do not have a tail.
5836 LLVM_DEBUG(dbgs() << "LV: No tail will remain for any chosen VF.\n");
5837 return MaxFactors;
5838 }
5839 }
5840
5841 // For scalable vectors, don't use tail folding as this is currently not yet
5842 // supported. The code is likely to have ended up here if the tripcount is
5843 // low, in which case it makes sense not to use scalable vectors.
5844 if (MaxFactors.ScalableVF.isVector())
5845 MaxFactors.ScalableVF = ElementCount::getScalable(0);
5846
5847 // If we don't know the precise trip count, or if the trip count that we
5848 // found modulo the vectorization factor is not zero, try to fold the tail
5849 // by masking.
5850 // FIXME: look for a smaller MaxVF that does divide TC rather than masking.
5851 if (Legal->prepareToFoldTailByMasking()) {
5852 FoldTailByMasking = true;
5853 return MaxFactors;
5854 }
5855
5856 // If there was a tail-folding hint/switch, but we can't fold the tail by
5857 // masking, fallback to a vectorization with a scalar epilogue.
5858 if (ScalarEpilogueStatus == CM_ScalarEpilogueNotNeededUsePredicate) {
5859 LLVM_DEBUG(dbgs() << "LV: Cannot fold tail by masking: vectorize with a "
5860 "scalar epilogue instead.\n");
5861 ScalarEpilogueStatus = CM_ScalarEpilogueAllowed;
5862 return MaxFactors;
5863 }
5864
5865 if (ScalarEpilogueStatus == CM_ScalarEpilogueNotAllowedUsePredicate) {
5866 LLVM_DEBUG(dbgs() << "LV: Can't fold tail by masking: don't vectorize\n");
5867 return FixedScalableVFPair::getNone();
5868 }
5869
5870 if (TC == 0) {
5871 reportVectorizationFailure(
5872 "Unable to calculate the loop count due to complex control flow",
5873 "unable to calculate the loop count due to complex control flow",
5874 "UnknownLoopCountComplexCFG", ORE, TheLoop);
5875 return FixedScalableVFPair::getNone();
5876 }
5877
5878 reportVectorizationFailure(
5879 "Cannot optimize for size and vectorize at the same time.",
5880 "cannot optimize for size and vectorize at the same time. "
5881 "Enable vectorization of this loop with '#pragma clang loop "
5882 "vectorize(enable)' when compiling with -Os/-Oz",
5883 "NoTailLoopWithOptForSize", ORE, TheLoop);
5884 return FixedScalableVFPair::getNone();
5885 }
5886
getMaximizedVFForTarget(unsigned ConstTripCount,unsigned SmallestType,unsigned WidestType,const ElementCount & MaxSafeVF)5887 ElementCount LoopVectorizationCostModel::getMaximizedVFForTarget(
5888 unsigned ConstTripCount, unsigned SmallestType, unsigned WidestType,
5889 const ElementCount &MaxSafeVF) {
5890 bool ComputeScalableMaxVF = MaxSafeVF.isScalable();
5891 TypeSize WidestRegister = TTI.getRegisterBitWidth(
5892 ComputeScalableMaxVF ? TargetTransformInfo::RGK_ScalableVector
5893 : TargetTransformInfo::RGK_FixedWidthVector);
5894
5895 // Convenience function to return the minimum of two ElementCounts.
5896 auto MinVF = [](const ElementCount &LHS, const ElementCount &RHS) {
5897 assert((LHS.isScalable() == RHS.isScalable()) &&
5898 "Scalable flags must match");
5899 return ElementCount::isKnownLT(LHS, RHS) ? LHS : RHS;
5900 };
5901
5902 // Ensure MaxVF is a power of 2; the dependence distance bound may not be.
5903 // Note that both WidestRegister and WidestType may not be a powers of 2.
5904 auto MaxVectorElementCount = ElementCount::get(
5905 PowerOf2Floor(WidestRegister.getKnownMinSize() / WidestType),
5906 ComputeScalableMaxVF);
5907 MaxVectorElementCount = MinVF(MaxVectorElementCount, MaxSafeVF);
5908 LLVM_DEBUG(dbgs() << "LV: The Widest register safe to use is: "
5909 << (MaxVectorElementCount * WidestType) << " bits.\n");
5910
5911 if (!MaxVectorElementCount) {
5912 LLVM_DEBUG(dbgs() << "LV: The target has no "
5913 << (ComputeScalableMaxVF ? "scalable" : "fixed")
5914 << " vector registers.\n");
5915 return ElementCount::getFixed(1);
5916 }
5917
5918 const auto TripCountEC = ElementCount::getFixed(ConstTripCount);
5919 if (ConstTripCount &&
5920 ElementCount::isKnownLE(TripCountEC, MaxVectorElementCount) &&
5921 isPowerOf2_32(ConstTripCount)) {
5922 // We need to clamp the VF to be the ConstTripCount. There is no point in
5923 // choosing a higher viable VF as done in the loop below. If
5924 // MaxVectorElementCount is scalable, we only fall back on a fixed VF when
5925 // the TC is less than or equal to the known number of lanes.
5926 LLVM_DEBUG(dbgs() << "LV: Clamping the MaxVF to the constant trip count: "
5927 << ConstTripCount << "\n");
5928 return TripCountEC;
5929 }
5930
5931 ElementCount MaxVF = MaxVectorElementCount;
5932 if (TTI.shouldMaximizeVectorBandwidth() ||
5933 (MaximizeBandwidth && isScalarEpilogueAllowed())) {
5934 auto MaxVectorElementCountMaxBW = ElementCount::get(
5935 PowerOf2Floor(WidestRegister.getKnownMinSize() / SmallestType),
5936 ComputeScalableMaxVF);
5937 MaxVectorElementCountMaxBW = MinVF(MaxVectorElementCountMaxBW, MaxSafeVF);
5938
5939 // Collect all viable vectorization factors larger than the default MaxVF
5940 // (i.e. MaxVectorElementCount).
5941 SmallVector<ElementCount, 8> VFs;
5942 for (ElementCount VS = MaxVectorElementCount * 2;
5943 ElementCount::isKnownLE(VS, MaxVectorElementCountMaxBW); VS *= 2)
5944 VFs.push_back(VS);
5945
5946 // For each VF calculate its register usage.
5947 auto RUs = calculateRegisterUsage(VFs);
5948
5949 // Select the largest VF which doesn't require more registers than existing
5950 // ones.
5951 for (int i = RUs.size() - 1; i >= 0; --i) {
5952 bool Selected = true;
5953 for (auto &pair : RUs[i].MaxLocalUsers) {
5954 unsigned TargetNumRegisters = TTI.getNumberOfRegisters(pair.first);
5955 if (pair.second > TargetNumRegisters)
5956 Selected = false;
5957 }
5958 if (Selected) {
5959 MaxVF = VFs[i];
5960 break;
5961 }
5962 }
5963 if (ElementCount MinVF =
5964 TTI.getMinimumVF(SmallestType, ComputeScalableMaxVF)) {
5965 if (ElementCount::isKnownLT(MaxVF, MinVF)) {
5966 LLVM_DEBUG(dbgs() << "LV: Overriding calculated MaxVF(" << MaxVF
5967 << ") with target's minimum: " << MinVF << '\n');
5968 MaxVF = MinVF;
5969 }
5970 }
5971 }
5972 return MaxVF;
5973 }
5974
isMoreProfitable(const VectorizationFactor & A,const VectorizationFactor & B) const5975 bool LoopVectorizationCostModel::isMoreProfitable(
5976 const VectorizationFactor &A, const VectorizationFactor &B) const {
5977 InstructionCost CostA = A.Cost;
5978 InstructionCost CostB = B.Cost;
5979
5980 unsigned MaxTripCount = PSE.getSE()->getSmallConstantMaxTripCount(TheLoop);
5981
5982 if (!A.Width.isScalable() && !B.Width.isScalable() && FoldTailByMasking &&
5983 MaxTripCount) {
5984 // If we are folding the tail and the trip count is a known (possibly small)
5985 // constant, the trip count will be rounded up to an integer number of
5986 // iterations. The total cost will be PerIterationCost*ceil(TripCount/VF),
5987 // which we compare directly. When not folding the tail, the total cost will
5988 // be PerIterationCost*floor(TC/VF) + Scalar remainder cost, and so is
5989 // approximated with the per-lane cost below instead of using the tripcount
5990 // as here.
5991 auto RTCostA = CostA * divideCeil(MaxTripCount, A.Width.getFixedValue());
5992 auto RTCostB = CostB * divideCeil(MaxTripCount, B.Width.getFixedValue());
5993 return RTCostA < RTCostB;
5994 }
5995
5996 // When set to preferred, for now assume vscale may be larger than 1, so
5997 // that scalable vectorization is slightly favorable over fixed-width
5998 // vectorization.
5999 if (Hints->isScalableVectorizationPreferred())
6000 if (A.Width.isScalable() && !B.Width.isScalable())
6001 return (CostA * B.Width.getKnownMinValue()) <=
6002 (CostB * A.Width.getKnownMinValue());
6003
6004 // To avoid the need for FP division:
6005 // (CostA / A.Width) < (CostB / B.Width)
6006 // <=> (CostA * B.Width) < (CostB * A.Width)
6007 return (CostA * B.Width.getKnownMinValue()) <
6008 (CostB * A.Width.getKnownMinValue());
6009 }
6010
selectVectorizationFactor(const ElementCountSet & VFCandidates)6011 VectorizationFactor LoopVectorizationCostModel::selectVectorizationFactor(
6012 const ElementCountSet &VFCandidates) {
6013 InstructionCost ExpectedCost = expectedCost(ElementCount::getFixed(1)).first;
6014 LLVM_DEBUG(dbgs() << "LV: Scalar loop costs: " << ExpectedCost << ".\n");
6015 assert(ExpectedCost.isValid() && "Unexpected invalid cost for scalar loop");
6016 assert(VFCandidates.count(ElementCount::getFixed(1)) &&
6017 "Expected Scalar VF to be a candidate");
6018
6019 const VectorizationFactor ScalarCost(ElementCount::getFixed(1), ExpectedCost);
6020 VectorizationFactor ChosenFactor = ScalarCost;
6021
6022 bool ForceVectorization = Hints->getForce() == LoopVectorizeHints::FK_Enabled;
6023 if (ForceVectorization && VFCandidates.size() > 1) {
6024 // Ignore scalar width, because the user explicitly wants vectorization.
6025 // Initialize cost to max so that VF = 2 is, at least, chosen during cost
6026 // evaluation.
6027 ChosenFactor.Cost = InstructionCost::getMax();
6028 }
6029
6030 SmallVector<InstructionVFPair> InvalidCosts;
6031 for (const auto &i : VFCandidates) {
6032 // The cost for scalar VF=1 is already calculated, so ignore it.
6033 if (i.isScalar())
6034 continue;
6035
6036 VectorizationCostTy C = expectedCost(i, &InvalidCosts);
6037 VectorizationFactor Candidate(i, C.first);
6038 LLVM_DEBUG(
6039 dbgs() << "LV: Vector loop of width " << i << " costs: "
6040 << (Candidate.Cost / Candidate.Width.getKnownMinValue())
6041 << (i.isScalable() ? " (assuming a minimum vscale of 1)" : "")
6042 << ".\n");
6043
6044 if (!C.second && !ForceVectorization) {
6045 LLVM_DEBUG(
6046 dbgs() << "LV: Not considering vector loop of width " << i
6047 << " because it will not generate any vector instructions.\n");
6048 continue;
6049 }
6050
6051 // If profitable add it to ProfitableVF list.
6052 if (isMoreProfitable(Candidate, ScalarCost))
6053 ProfitableVFs.push_back(Candidate);
6054
6055 if (isMoreProfitable(Candidate, ChosenFactor))
6056 ChosenFactor = Candidate;
6057 }
6058
6059 // Emit a report of VFs with invalid costs in the loop.
6060 if (!InvalidCosts.empty()) {
6061 // Group the remarks per instruction, keeping the instruction order from
6062 // InvalidCosts.
6063 std::map<Instruction *, unsigned> Numbering;
6064 unsigned I = 0;
6065 for (auto &Pair : InvalidCosts)
6066 if (!Numbering.count(Pair.first))
6067 Numbering[Pair.first] = I++;
6068
6069 // Sort the list, first on instruction(number) then on VF.
6070 llvm::sort(InvalidCosts,
6071 [&Numbering](InstructionVFPair &A, InstructionVFPair &B) {
6072 if (Numbering[A.first] != Numbering[B.first])
6073 return Numbering[A.first] < Numbering[B.first];
6074 ElementCountComparator ECC;
6075 return ECC(A.second, B.second);
6076 });
6077
6078 // For a list of ordered instruction-vf pairs:
6079 // [(load, vf1), (load, vf2), (store, vf1)]
6080 // Group the instructions together to emit separate remarks for:
6081 // load (vf1, vf2)
6082 // store (vf1)
6083 auto Tail = ArrayRef<InstructionVFPair>(InvalidCosts);
6084 auto Subset = ArrayRef<InstructionVFPair>();
6085 do {
6086 if (Subset.empty())
6087 Subset = Tail.take_front(1);
6088
6089 Instruction *I = Subset.front().first;
6090
6091 // If the next instruction is different, or if there are no other pairs,
6092 // emit a remark for the collated subset. e.g.
6093 // [(load, vf1), (load, vf2))]
6094 // to emit:
6095 // remark: invalid costs for 'load' at VF=(vf, vf2)
6096 if (Subset == Tail || Tail[Subset.size()].first != I) {
6097 std::string OutString;
6098 raw_string_ostream OS(OutString);
6099 assert(!Subset.empty() && "Unexpected empty range");
6100 OS << "Instruction with invalid costs prevented vectorization at VF=(";
6101 for (auto &Pair : Subset)
6102 OS << (Pair.second == Subset.front().second ? "" : ", ")
6103 << Pair.second;
6104 OS << "):";
6105 if (auto *CI = dyn_cast<CallInst>(I))
6106 OS << " call to " << CI->getCalledFunction()->getName();
6107 else
6108 OS << " " << I->getOpcodeName();
6109 OS.flush();
6110 reportVectorizationInfo(OutString, "InvalidCost", ORE, TheLoop, I);
6111 Tail = Tail.drop_front(Subset.size());
6112 Subset = {};
6113 } else
6114 // Grow the subset by one element
6115 Subset = Tail.take_front(Subset.size() + 1);
6116 } while (!Tail.empty());
6117 }
6118
6119 if (!EnableCondStoresVectorization && NumPredStores) {
6120 reportVectorizationFailure("There are conditional stores.",
6121 "store that is conditionally executed prevents vectorization",
6122 "ConditionalStore", ORE, TheLoop);
6123 ChosenFactor = ScalarCost;
6124 }
6125
6126 LLVM_DEBUG(if (ForceVectorization && !ChosenFactor.Width.isScalar() &&
6127 ChosenFactor.Cost >= ScalarCost.Cost) dbgs()
6128 << "LV: Vectorization seems to be not beneficial, "
6129 << "but was forced by a user.\n");
6130 LLVM_DEBUG(dbgs() << "LV: Selecting VF: " << ChosenFactor.Width << ".\n");
6131 return ChosenFactor;
6132 }
6133
isCandidateForEpilogueVectorization(const Loop & L,ElementCount VF) const6134 bool LoopVectorizationCostModel::isCandidateForEpilogueVectorization(
6135 const Loop &L, ElementCount VF) const {
6136 // Cross iteration phis such as reductions need special handling and are
6137 // currently unsupported.
6138 if (any_of(L.getHeader()->phis(), [&](PHINode &Phi) {
6139 return Legal->isFirstOrderRecurrence(&Phi) ||
6140 Legal->isReductionVariable(&Phi);
6141 }))
6142 return false;
6143
6144 // Phis with uses outside of the loop require special handling and are
6145 // currently unsupported.
6146 for (auto &Entry : Legal->getInductionVars()) {
6147 // Look for uses of the value of the induction at the last iteration.
6148 Value *PostInc = Entry.first->getIncomingValueForBlock(L.getLoopLatch());
6149 for (User *U : PostInc->users())
6150 if (!L.contains(cast<Instruction>(U)))
6151 return false;
6152 // Look for uses of penultimate value of the induction.
6153 for (User *U : Entry.first->users())
6154 if (!L.contains(cast<Instruction>(U)))
6155 return false;
6156 }
6157
6158 // Induction variables that are widened require special handling that is
6159 // currently not supported.
6160 if (any_of(Legal->getInductionVars(), [&](auto &Entry) {
6161 return !(this->isScalarAfterVectorization(Entry.first, VF) ||
6162 this->isProfitableToScalarize(Entry.first, VF));
6163 }))
6164 return false;
6165
6166 // Epilogue vectorization code has not been auditted to ensure it handles
6167 // non-latch exits properly. It may be fine, but it needs auditted and
6168 // tested.
6169 if (L.getExitingBlock() != L.getLoopLatch())
6170 return false;
6171
6172 return true;
6173 }
6174
isEpilogueVectorizationProfitable(const ElementCount VF) const6175 bool LoopVectorizationCostModel::isEpilogueVectorizationProfitable(
6176 const ElementCount VF) const {
6177 // FIXME: We need a much better cost-model to take different parameters such
6178 // as register pressure, code size increase and cost of extra branches into
6179 // account. For now we apply a very crude heuristic and only consider loops
6180 // with vectorization factors larger than a certain value.
6181 // We also consider epilogue vectorization unprofitable for targets that don't
6182 // consider interleaving beneficial (eg. MVE).
6183 if (TTI.getMaxInterleaveFactor(VF.getKnownMinValue()) <= 1)
6184 return false;
6185 if (VF.getFixedValue() >= EpilogueVectorizationMinVF)
6186 return true;
6187 return false;
6188 }
6189
6190 VectorizationFactor
selectEpilogueVectorizationFactor(const ElementCount MainLoopVF,const LoopVectorizationPlanner & LVP)6191 LoopVectorizationCostModel::selectEpilogueVectorizationFactor(
6192 const ElementCount MainLoopVF, const LoopVectorizationPlanner &LVP) {
6193 VectorizationFactor Result = VectorizationFactor::Disabled();
6194 if (!EnableEpilogueVectorization) {
6195 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization is disabled.\n";);
6196 return Result;
6197 }
6198
6199 if (!isScalarEpilogueAllowed()) {
6200 LLVM_DEBUG(
6201 dbgs() << "LEV: Unable to vectorize epilogue because no epilogue is "
6202 "allowed.\n";);
6203 return Result;
6204 }
6205
6206 // FIXME: This can be fixed for scalable vectors later, because at this stage
6207 // the LoopVectorizer will only consider vectorizing a loop with scalable
6208 // vectors when the loop has a hint to enable vectorization for a given VF.
6209 if (MainLoopVF.isScalable()) {
6210 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization for scalable vectors not "
6211 "yet supported.\n");
6212 return Result;
6213 }
6214
6215 // Not really a cost consideration, but check for unsupported cases here to
6216 // simplify the logic.
6217 if (!isCandidateForEpilogueVectorization(*TheLoop, MainLoopVF)) {
6218 LLVM_DEBUG(
6219 dbgs() << "LEV: Unable to vectorize epilogue because the loop is "
6220 "not a supported candidate.\n";);
6221 return Result;
6222 }
6223
6224 if (EpilogueVectorizationForceVF > 1) {
6225 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization factor is forced.\n";);
6226 if (LVP.hasPlanWithVFs(
6227 {MainLoopVF, ElementCount::getFixed(EpilogueVectorizationForceVF)}))
6228 return {ElementCount::getFixed(EpilogueVectorizationForceVF), 0};
6229 else {
6230 LLVM_DEBUG(
6231 dbgs()
6232 << "LEV: Epilogue vectorization forced factor is not viable.\n";);
6233 return Result;
6234 }
6235 }
6236
6237 if (TheLoop->getHeader()->getParent()->hasOptSize() ||
6238 TheLoop->getHeader()->getParent()->hasMinSize()) {
6239 LLVM_DEBUG(
6240 dbgs()
6241 << "LEV: Epilogue vectorization skipped due to opt for size.\n";);
6242 return Result;
6243 }
6244
6245 if (!isEpilogueVectorizationProfitable(MainLoopVF))
6246 return Result;
6247
6248 for (auto &NextVF : ProfitableVFs)
6249 if (ElementCount::isKnownLT(NextVF.Width, MainLoopVF) &&
6250 (Result.Width.getFixedValue() == 1 ||
6251 isMoreProfitable(NextVF, Result)) &&
6252 LVP.hasPlanWithVFs({MainLoopVF, NextVF.Width}))
6253 Result = NextVF;
6254
6255 if (Result != VectorizationFactor::Disabled())
6256 LLVM_DEBUG(dbgs() << "LEV: Vectorizing epilogue loop with VF = "
6257 << Result.Width.getFixedValue() << "\n";);
6258 return Result;
6259 }
6260
6261 std::pair<unsigned, unsigned>
getSmallestAndWidestTypes()6262 LoopVectorizationCostModel::getSmallestAndWidestTypes() {
6263 unsigned MinWidth = -1U;
6264 unsigned MaxWidth = 8;
6265 const DataLayout &DL = TheFunction->getParent()->getDataLayout();
6266 for (Type *T : ElementTypesInLoop) {
6267 MinWidth = std::min<unsigned>(
6268 MinWidth, DL.getTypeSizeInBits(T->getScalarType()).getFixedSize());
6269 MaxWidth = std::max<unsigned>(
6270 MaxWidth, DL.getTypeSizeInBits(T->getScalarType()).getFixedSize());
6271 }
6272 return {MinWidth, MaxWidth};
6273 }
6274
collectElementTypesForWidening()6275 void LoopVectorizationCostModel::collectElementTypesForWidening() {
6276 ElementTypesInLoop.clear();
6277 // For each block.
6278 for (BasicBlock *BB : TheLoop->blocks()) {
6279 // For each instruction in the loop.
6280 for (Instruction &I : BB->instructionsWithoutDebug()) {
6281 Type *T = I.getType();
6282
6283 // Skip ignored values.
6284 if (ValuesToIgnore.count(&I))
6285 continue;
6286
6287 // Only examine Loads, Stores and PHINodes.
6288 if (!isa<LoadInst>(I) && !isa<StoreInst>(I) && !isa<PHINode>(I))
6289 continue;
6290
6291 // Examine PHI nodes that are reduction variables. Update the type to
6292 // account for the recurrence type.
6293 if (auto *PN = dyn_cast<PHINode>(&I)) {
6294 if (!Legal->isReductionVariable(PN))
6295 continue;
6296 const RecurrenceDescriptor &RdxDesc = Legal->getReductionVars()[PN];
6297 if (PreferInLoopReductions || useOrderedReductions(RdxDesc) ||
6298 TTI.preferInLoopReduction(RdxDesc.getOpcode(),
6299 RdxDesc.getRecurrenceType(),
6300 TargetTransformInfo::ReductionFlags()))
6301 continue;
6302 T = RdxDesc.getRecurrenceType();
6303 }
6304
6305 // Examine the stored values.
6306 if (auto *ST = dyn_cast<StoreInst>(&I))
6307 T = ST->getValueOperand()->getType();
6308
6309 // Ignore loaded pointer types and stored pointer types that are not
6310 // vectorizable.
6311 //
6312 // FIXME: The check here attempts to predict whether a load or store will
6313 // be vectorized. We only know this for certain after a VF has
6314 // been selected. Here, we assume that if an access can be
6315 // vectorized, it will be. We should also look at extending this
6316 // optimization to non-pointer types.
6317 //
6318 if (T->isPointerTy() && !isConsecutiveLoadOrStore(&I) &&
6319 !isAccessInterleaved(&I) && !isLegalGatherOrScatter(&I))
6320 continue;
6321
6322 ElementTypesInLoop.insert(T);
6323 }
6324 }
6325 }
6326
selectInterleaveCount(ElementCount VF,unsigned LoopCost)6327 unsigned LoopVectorizationCostModel::selectInterleaveCount(ElementCount VF,
6328 unsigned LoopCost) {
6329 // -- The interleave heuristics --
6330 // We interleave the loop in order to expose ILP and reduce the loop overhead.
6331 // There are many micro-architectural considerations that we can't predict
6332 // at this level. For example, frontend pressure (on decode or fetch) due to
6333 // code size, or the number and capabilities of the execution ports.
6334 //
6335 // We use the following heuristics to select the interleave count:
6336 // 1. If the code has reductions, then we interleave to break the cross
6337 // iteration dependency.
6338 // 2. If the loop is really small, then we interleave to reduce the loop
6339 // overhead.
6340 // 3. We don't interleave if we think that we will spill registers to memory
6341 // due to the increased register pressure.
6342
6343 if (!isScalarEpilogueAllowed())
6344 return 1;
6345
6346 // We used the distance for the interleave count.
6347 if (Legal->getMaxSafeDepDistBytes() != -1U)
6348 return 1;
6349
6350 auto BestKnownTC = getSmallBestKnownTC(*PSE.getSE(), TheLoop);
6351 const bool HasReductions = !Legal->getReductionVars().empty();
6352 // Do not interleave loops with a relatively small known or estimated trip
6353 // count. But we will interleave when InterleaveSmallLoopScalarReduction is
6354 // enabled, and the code has scalar reductions(HasReductions && VF = 1),
6355 // because with the above conditions interleaving can expose ILP and break
6356 // cross iteration dependences for reductions.
6357 if (BestKnownTC && (*BestKnownTC < TinyTripCountInterleaveThreshold) &&
6358 !(InterleaveSmallLoopScalarReduction && HasReductions && VF.isScalar()))
6359 return 1;
6360
6361 RegisterUsage R = calculateRegisterUsage({VF})[0];
6362 // We divide by these constants so assume that we have at least one
6363 // instruction that uses at least one register.
6364 for (auto& pair : R.MaxLocalUsers) {
6365 pair.second = std::max(pair.second, 1U);
6366 }
6367
6368 // We calculate the interleave count using the following formula.
6369 // Subtract the number of loop invariants from the number of available
6370 // registers. These registers are used by all of the interleaved instances.
6371 // Next, divide the remaining registers by the number of registers that is
6372 // required by the loop, in order to estimate how many parallel instances
6373 // fit without causing spills. All of this is rounded down if necessary to be
6374 // a power of two. We want power of two interleave count to simplify any
6375 // addressing operations or alignment considerations.
6376 // We also want power of two interleave counts to ensure that the induction
6377 // variable of the vector loop wraps to zero, when tail is folded by masking;
6378 // this currently happens when OptForSize, in which case IC is set to 1 above.
6379 unsigned IC = UINT_MAX;
6380
6381 for (auto& pair : R.MaxLocalUsers) {
6382 unsigned TargetNumRegisters = TTI.getNumberOfRegisters(pair.first);
6383 LLVM_DEBUG(dbgs() << "LV: The target has " << TargetNumRegisters
6384 << " registers of "
6385 << TTI.getRegisterClassName(pair.first) << " register class\n");
6386 if (VF.isScalar()) {
6387 if (ForceTargetNumScalarRegs.getNumOccurrences() > 0)
6388 TargetNumRegisters = ForceTargetNumScalarRegs;
6389 } else {
6390 if (ForceTargetNumVectorRegs.getNumOccurrences() > 0)
6391 TargetNumRegisters = ForceTargetNumVectorRegs;
6392 }
6393 unsigned MaxLocalUsers = pair.second;
6394 unsigned LoopInvariantRegs = 0;
6395 if (R.LoopInvariantRegs.find(pair.first) != R.LoopInvariantRegs.end())
6396 LoopInvariantRegs = R.LoopInvariantRegs[pair.first];
6397
6398 unsigned TmpIC = PowerOf2Floor((TargetNumRegisters - LoopInvariantRegs) / MaxLocalUsers);
6399 // Don't count the induction variable as interleaved.
6400 if (EnableIndVarRegisterHeur) {
6401 TmpIC =
6402 PowerOf2Floor((TargetNumRegisters - LoopInvariantRegs - 1) /
6403 std::max(1U, (MaxLocalUsers - 1)));
6404 }
6405
6406 IC = std::min(IC, TmpIC);
6407 }
6408
6409 // Clamp the interleave ranges to reasonable counts.
6410 unsigned MaxInterleaveCount =
6411 TTI.getMaxInterleaveFactor(VF.getKnownMinValue());
6412
6413 // Check if the user has overridden the max.
6414 if (VF.isScalar()) {
6415 if (ForceTargetMaxScalarInterleaveFactor.getNumOccurrences() > 0)
6416 MaxInterleaveCount = ForceTargetMaxScalarInterleaveFactor;
6417 } else {
6418 if (ForceTargetMaxVectorInterleaveFactor.getNumOccurrences() > 0)
6419 MaxInterleaveCount = ForceTargetMaxVectorInterleaveFactor;
6420 }
6421
6422 // If trip count is known or estimated compile time constant, limit the
6423 // interleave count to be less than the trip count divided by VF, provided it
6424 // is at least 1.
6425 //
6426 // For scalable vectors we can't know if interleaving is beneficial. It may
6427 // not be beneficial for small loops if none of the lanes in the second vector
6428 // iterations is enabled. However, for larger loops, there is likely to be a
6429 // similar benefit as for fixed-width vectors. For now, we choose to leave
6430 // the InterleaveCount as if vscale is '1', although if some information about
6431 // the vector is known (e.g. min vector size), we can make a better decision.
6432 if (BestKnownTC) {
6433 MaxInterleaveCount =
6434 std::min(*BestKnownTC / VF.getKnownMinValue(), MaxInterleaveCount);
6435 // Make sure MaxInterleaveCount is greater than 0.
6436 MaxInterleaveCount = std::max(1u, MaxInterleaveCount);
6437 }
6438
6439 assert(MaxInterleaveCount > 0 &&
6440 "Maximum interleave count must be greater than 0");
6441
6442 // Clamp the calculated IC to be between the 1 and the max interleave count
6443 // that the target and trip count allows.
6444 if (IC > MaxInterleaveCount)
6445 IC = MaxInterleaveCount;
6446 else
6447 // Make sure IC is greater than 0.
6448 IC = std::max(1u, IC);
6449
6450 assert(IC > 0 && "Interleave count must be greater than 0.");
6451
6452 // If we did not calculate the cost for VF (because the user selected the VF)
6453 // then we calculate the cost of VF here.
6454 if (LoopCost == 0) {
6455 InstructionCost C = expectedCost(VF).first;
6456 assert(C.isValid() && "Expected to have chosen a VF with valid cost");
6457 LoopCost = *C.getValue();
6458 }
6459
6460 assert(LoopCost && "Non-zero loop cost expected");
6461
6462 // Interleave if we vectorized this loop and there is a reduction that could
6463 // benefit from interleaving.
6464 if (VF.isVector() && HasReductions) {
6465 LLVM_DEBUG(dbgs() << "LV: Interleaving because of reductions.\n");
6466 return IC;
6467 }
6468
6469 // Note that if we've already vectorized the loop we will have done the
6470 // runtime check and so interleaving won't require further checks.
6471 bool InterleavingRequiresRuntimePointerCheck =
6472 (VF.isScalar() && Legal->getRuntimePointerChecking()->Need);
6473
6474 // We want to interleave small loops in order to reduce the loop overhead and
6475 // potentially expose ILP opportunities.
6476 LLVM_DEBUG(dbgs() << "LV: Loop cost is " << LoopCost << '\n'
6477 << "LV: IC is " << IC << '\n'
6478 << "LV: VF is " << VF << '\n');
6479 const bool AggressivelyInterleaveReductions =
6480 TTI.enableAggressiveInterleaving(HasReductions);
6481 if (!InterleavingRequiresRuntimePointerCheck && LoopCost < SmallLoopCost) {
6482 // We assume that the cost overhead is 1 and we use the cost model
6483 // to estimate the cost of the loop and interleave until the cost of the
6484 // loop overhead is about 5% of the cost of the loop.
6485 unsigned SmallIC =
6486 std::min(IC, (unsigned)PowerOf2Floor(SmallLoopCost / LoopCost));
6487
6488 // Interleave until store/load ports (estimated by max interleave count) are
6489 // saturated.
6490 unsigned NumStores = Legal->getNumStores();
6491 unsigned NumLoads = Legal->getNumLoads();
6492 unsigned StoresIC = IC / (NumStores ? NumStores : 1);
6493 unsigned LoadsIC = IC / (NumLoads ? NumLoads : 1);
6494
6495 // If we have a scalar reduction (vector reductions are already dealt with
6496 // by this point), we can increase the critical path length if the loop
6497 // we're interleaving is inside another loop. For tree-wise reductions
6498 // set the limit to 2, and for ordered reductions it's best to disable
6499 // interleaving entirely.
6500 if (HasReductions && TheLoop->getLoopDepth() > 1) {
6501 bool HasOrderedReductions =
6502 any_of(Legal->getReductionVars(), [&](auto &Reduction) -> bool {
6503 const RecurrenceDescriptor &RdxDesc = Reduction.second;
6504 return RdxDesc.isOrdered();
6505 });
6506 if (HasOrderedReductions) {
6507 LLVM_DEBUG(
6508 dbgs() << "LV: Not interleaving scalar ordered reductions.\n");
6509 return 1;
6510 }
6511
6512 unsigned F = static_cast<unsigned>(MaxNestedScalarReductionIC);
6513 SmallIC = std::min(SmallIC, F);
6514 StoresIC = std::min(StoresIC, F);
6515 LoadsIC = std::min(LoadsIC, F);
6516 }
6517
6518 if (EnableLoadStoreRuntimeInterleave &&
6519 std::max(StoresIC, LoadsIC) > SmallIC) {
6520 LLVM_DEBUG(
6521 dbgs() << "LV: Interleaving to saturate store or load ports.\n");
6522 return std::max(StoresIC, LoadsIC);
6523 }
6524
6525 // If there are scalar reductions and TTI has enabled aggressive
6526 // interleaving for reductions, we will interleave to expose ILP.
6527 if (InterleaveSmallLoopScalarReduction && VF.isScalar() &&
6528 AggressivelyInterleaveReductions) {
6529 LLVM_DEBUG(dbgs() << "LV: Interleaving to expose ILP.\n");
6530 // Interleave no less than SmallIC but not as aggressive as the normal IC
6531 // to satisfy the rare situation when resources are too limited.
6532 return std::max(IC / 2, SmallIC);
6533 } else {
6534 LLVM_DEBUG(dbgs() << "LV: Interleaving to reduce branch cost.\n");
6535 return SmallIC;
6536 }
6537 }
6538
6539 // Interleave if this is a large loop (small loops are already dealt with by
6540 // this point) that could benefit from interleaving.
6541 if (AggressivelyInterleaveReductions) {
6542 LLVM_DEBUG(dbgs() << "LV: Interleaving to expose ILP.\n");
6543 return IC;
6544 }
6545
6546 LLVM_DEBUG(dbgs() << "LV: Not Interleaving.\n");
6547 return 1;
6548 }
6549
6550 SmallVector<LoopVectorizationCostModel::RegisterUsage, 8>
calculateRegisterUsage(ArrayRef<ElementCount> VFs)6551 LoopVectorizationCostModel::calculateRegisterUsage(ArrayRef<ElementCount> VFs) {
6552 // This function calculates the register usage by measuring the highest number
6553 // of values that are alive at a single location. Obviously, this is a very
6554 // rough estimation. We scan the loop in a topological order in order and
6555 // assign a number to each instruction. We use RPO to ensure that defs are
6556 // met before their users. We assume that each instruction that has in-loop
6557 // users starts an interval. We record every time that an in-loop value is
6558 // used, so we have a list of the first and last occurrences of each
6559 // instruction. Next, we transpose this data structure into a multi map that
6560 // holds the list of intervals that *end* at a specific location. This multi
6561 // map allows us to perform a linear search. We scan the instructions linearly
6562 // and record each time that a new interval starts, by placing it in a set.
6563 // If we find this value in the multi-map then we remove it from the set.
6564 // The max register usage is the maximum size of the set.
6565 // We also search for instructions that are defined outside the loop, but are
6566 // used inside the loop. We need this number separately from the max-interval
6567 // usage number because when we unroll, loop-invariant values do not take
6568 // more register.
6569 LoopBlocksDFS DFS(TheLoop);
6570 DFS.perform(LI);
6571
6572 RegisterUsage RU;
6573
6574 // Each 'key' in the map opens a new interval. The values
6575 // of the map are the index of the 'last seen' usage of the
6576 // instruction that is the key.
6577 using IntervalMap = DenseMap<Instruction *, unsigned>;
6578
6579 // Maps instruction to its index.
6580 SmallVector<Instruction *, 64> IdxToInstr;
6581 // Marks the end of each interval.
6582 IntervalMap EndPoint;
6583 // Saves the list of instruction indices that are used in the loop.
6584 SmallPtrSet<Instruction *, 8> Ends;
6585 // Saves the list of values that are used in the loop but are
6586 // defined outside the loop, such as arguments and constants.
6587 SmallPtrSet<Value *, 8> LoopInvariants;
6588
6589 for (BasicBlock *BB : make_range(DFS.beginRPO(), DFS.endRPO())) {
6590 for (Instruction &I : BB->instructionsWithoutDebug()) {
6591 IdxToInstr.push_back(&I);
6592
6593 // Save the end location of each USE.
6594 for (Value *U : I.operands()) {
6595 auto *Instr = dyn_cast<Instruction>(U);
6596
6597 // Ignore non-instruction values such as arguments, constants, etc.
6598 if (!Instr)
6599 continue;
6600
6601 // If this instruction is outside the loop then record it and continue.
6602 if (!TheLoop->contains(Instr)) {
6603 LoopInvariants.insert(Instr);
6604 continue;
6605 }
6606
6607 // Overwrite previous end points.
6608 EndPoint[Instr] = IdxToInstr.size();
6609 Ends.insert(Instr);
6610 }
6611 }
6612 }
6613
6614 // Saves the list of intervals that end with the index in 'key'.
6615 using InstrList = SmallVector<Instruction *, 2>;
6616 DenseMap<unsigned, InstrList> TransposeEnds;
6617
6618 // Transpose the EndPoints to a list of values that end at each index.
6619 for (auto &Interval : EndPoint)
6620 TransposeEnds[Interval.second].push_back(Interval.first);
6621
6622 SmallPtrSet<Instruction *, 8> OpenIntervals;
6623 SmallVector<RegisterUsage, 8> RUs(VFs.size());
6624 SmallVector<SmallMapVector<unsigned, unsigned, 4>, 8> MaxUsages(VFs.size());
6625
6626 LLVM_DEBUG(dbgs() << "LV(REG): Calculating max register usage:\n");
6627
6628 // A lambda that gets the register usage for the given type and VF.
6629 const auto &TTICapture = TTI;
6630 auto GetRegUsage = [&TTICapture](Type *Ty, ElementCount VF) -> unsigned {
6631 if (Ty->isTokenTy() || !VectorType::isValidElementType(Ty))
6632 return 0;
6633 InstructionCost::CostType RegUsage =
6634 *TTICapture.getRegUsageForType(VectorType::get(Ty, VF)).getValue();
6635 assert(RegUsage >= 0 && RegUsage <= std::numeric_limits<unsigned>::max() &&
6636 "Nonsensical values for register usage.");
6637 return RegUsage;
6638 };
6639
6640 for (unsigned int i = 0, s = IdxToInstr.size(); i < s; ++i) {
6641 Instruction *I = IdxToInstr[i];
6642
6643 // Remove all of the instructions that end at this location.
6644 InstrList &List = TransposeEnds[i];
6645 for (Instruction *ToRemove : List)
6646 OpenIntervals.erase(ToRemove);
6647
6648 // Ignore instructions that are never used within the loop.
6649 if (!Ends.count(I))
6650 continue;
6651
6652 // Skip ignored values.
6653 if (ValuesToIgnore.count(I))
6654 continue;
6655
6656 // For each VF find the maximum usage of registers.
6657 for (unsigned j = 0, e = VFs.size(); j < e; ++j) {
6658 // Count the number of live intervals.
6659 SmallMapVector<unsigned, unsigned, 4> RegUsage;
6660
6661 if (VFs[j].isScalar()) {
6662 for (auto Inst : OpenIntervals) {
6663 unsigned ClassID = TTI.getRegisterClassForType(false, Inst->getType());
6664 if (RegUsage.find(ClassID) == RegUsage.end())
6665 RegUsage[ClassID] = 1;
6666 else
6667 RegUsage[ClassID] += 1;
6668 }
6669 } else {
6670 collectUniformsAndScalars(VFs[j]);
6671 for (auto Inst : OpenIntervals) {
6672 // Skip ignored values for VF > 1.
6673 if (VecValuesToIgnore.count(Inst))
6674 continue;
6675 if (isScalarAfterVectorization(Inst, VFs[j])) {
6676 unsigned ClassID = TTI.getRegisterClassForType(false, Inst->getType());
6677 if (RegUsage.find(ClassID) == RegUsage.end())
6678 RegUsage[ClassID] = 1;
6679 else
6680 RegUsage[ClassID] += 1;
6681 } else {
6682 unsigned ClassID = TTI.getRegisterClassForType(true, Inst->getType());
6683 if (RegUsage.find(ClassID) == RegUsage.end())
6684 RegUsage[ClassID] = GetRegUsage(Inst->getType(), VFs[j]);
6685 else
6686 RegUsage[ClassID] += GetRegUsage(Inst->getType(), VFs[j]);
6687 }
6688 }
6689 }
6690
6691 for (auto& pair : RegUsage) {
6692 if (MaxUsages[j].find(pair.first) != MaxUsages[j].end())
6693 MaxUsages[j][pair.first] = std::max(MaxUsages[j][pair.first], pair.second);
6694 else
6695 MaxUsages[j][pair.first] = pair.second;
6696 }
6697 }
6698
6699 LLVM_DEBUG(dbgs() << "LV(REG): At #" << i << " Interval # "
6700 << OpenIntervals.size() << '\n');
6701
6702 // Add the current instruction to the list of open intervals.
6703 OpenIntervals.insert(I);
6704 }
6705
6706 for (unsigned i = 0, e = VFs.size(); i < e; ++i) {
6707 SmallMapVector<unsigned, unsigned, 4> Invariant;
6708
6709 for (auto Inst : LoopInvariants) {
6710 unsigned Usage =
6711 VFs[i].isScalar() ? 1 : GetRegUsage(Inst->getType(), VFs[i]);
6712 unsigned ClassID =
6713 TTI.getRegisterClassForType(VFs[i].isVector(), Inst->getType());
6714 if (Invariant.find(ClassID) == Invariant.end())
6715 Invariant[ClassID] = Usage;
6716 else
6717 Invariant[ClassID] += Usage;
6718 }
6719
6720 LLVM_DEBUG({
6721 dbgs() << "LV(REG): VF = " << VFs[i] << '\n';
6722 dbgs() << "LV(REG): Found max usage: " << MaxUsages[i].size()
6723 << " item\n";
6724 for (const auto &pair : MaxUsages[i]) {
6725 dbgs() << "LV(REG): RegisterClass: "
6726 << TTI.getRegisterClassName(pair.first) << ", " << pair.second
6727 << " registers\n";
6728 }
6729 dbgs() << "LV(REG): Found invariant usage: " << Invariant.size()
6730 << " item\n";
6731 for (const auto &pair : Invariant) {
6732 dbgs() << "LV(REG): RegisterClass: "
6733 << TTI.getRegisterClassName(pair.first) << ", " << pair.second
6734 << " registers\n";
6735 }
6736 });
6737
6738 RU.LoopInvariantRegs = Invariant;
6739 RU.MaxLocalUsers = MaxUsages[i];
6740 RUs[i] = RU;
6741 }
6742
6743 return RUs;
6744 }
6745
useEmulatedMaskMemRefHack(Instruction * I)6746 bool LoopVectorizationCostModel::useEmulatedMaskMemRefHack(Instruction *I){
6747 // TODO: Cost model for emulated masked load/store is completely
6748 // broken. This hack guides the cost model to use an artificially
6749 // high enough value to practically disable vectorization with such
6750 // operations, except where previously deployed legality hack allowed
6751 // using very low cost values. This is to avoid regressions coming simply
6752 // from moving "masked load/store" check from legality to cost model.
6753 // Masked Load/Gather emulation was previously never allowed.
6754 // Limited number of Masked Store/Scatter emulation was allowed.
6755 assert(isPredicatedInst(I) &&
6756 "Expecting a scalar emulated instruction");
6757 return isa<LoadInst>(I) ||
6758 (isa<StoreInst>(I) &&
6759 NumPredStores > NumberOfStoresToPredicate);
6760 }
6761
collectInstsToScalarize(ElementCount VF)6762 void LoopVectorizationCostModel::collectInstsToScalarize(ElementCount VF) {
6763 // If we aren't vectorizing the loop, or if we've already collected the
6764 // instructions to scalarize, there's nothing to do. Collection may already
6765 // have occurred if we have a user-selected VF and are now computing the
6766 // expected cost for interleaving.
6767 if (VF.isScalar() || VF.isZero() ||
6768 InstsToScalarize.find(VF) != InstsToScalarize.end())
6769 return;
6770
6771 // Initialize a mapping for VF in InstsToScalalarize. If we find that it's
6772 // not profitable to scalarize any instructions, the presence of VF in the
6773 // map will indicate that we've analyzed it already.
6774 ScalarCostsTy &ScalarCostsVF = InstsToScalarize[VF];
6775
6776 // Find all the instructions that are scalar with predication in the loop and
6777 // determine if it would be better to not if-convert the blocks they are in.
6778 // If so, we also record the instructions to scalarize.
6779 for (BasicBlock *BB : TheLoop->blocks()) {
6780 if (!blockNeedsPredication(BB))
6781 continue;
6782 for (Instruction &I : *BB)
6783 if (isScalarWithPredication(&I)) {
6784 ScalarCostsTy ScalarCosts;
6785 // Do not apply discount if scalable, because that would lead to
6786 // invalid scalarization costs.
6787 // Do not apply discount logic if hacked cost is needed
6788 // for emulated masked memrefs.
6789 if (!VF.isScalable() && !useEmulatedMaskMemRefHack(&I) &&
6790 computePredInstDiscount(&I, ScalarCosts, VF) >= 0)
6791 ScalarCostsVF.insert(ScalarCosts.begin(), ScalarCosts.end());
6792 // Remember that BB will remain after vectorization.
6793 PredicatedBBsAfterVectorization.insert(BB);
6794 }
6795 }
6796 }
6797
computePredInstDiscount(Instruction * PredInst,ScalarCostsTy & ScalarCosts,ElementCount VF)6798 int LoopVectorizationCostModel::computePredInstDiscount(
6799 Instruction *PredInst, ScalarCostsTy &ScalarCosts, ElementCount VF) {
6800 assert(!isUniformAfterVectorization(PredInst, VF) &&
6801 "Instruction marked uniform-after-vectorization will be predicated");
6802
6803 // Initialize the discount to zero, meaning that the scalar version and the
6804 // vector version cost the same.
6805 InstructionCost Discount = 0;
6806
6807 // Holds instructions to analyze. The instructions we visit are mapped in
6808 // ScalarCosts. Those instructions are the ones that would be scalarized if
6809 // we find that the scalar version costs less.
6810 SmallVector<Instruction *, 8> Worklist;
6811
6812 // Returns true if the given instruction can be scalarized.
6813 auto canBeScalarized = [&](Instruction *I) -> bool {
6814 // We only attempt to scalarize instructions forming a single-use chain
6815 // from the original predicated block that would otherwise be vectorized.
6816 // Although not strictly necessary, we give up on instructions we know will
6817 // already be scalar to avoid traversing chains that are unlikely to be
6818 // beneficial.
6819 if (!I->hasOneUse() || PredInst->getParent() != I->getParent() ||
6820 isScalarAfterVectorization(I, VF))
6821 return false;
6822
6823 // If the instruction is scalar with predication, it will be analyzed
6824 // separately. We ignore it within the context of PredInst.
6825 if (isScalarWithPredication(I))
6826 return false;
6827
6828 // If any of the instruction's operands are uniform after vectorization,
6829 // the instruction cannot be scalarized. This prevents, for example, a
6830 // masked load from being scalarized.
6831 //
6832 // We assume we will only emit a value for lane zero of an instruction
6833 // marked uniform after vectorization, rather than VF identical values.
6834 // Thus, if we scalarize an instruction that uses a uniform, we would
6835 // create uses of values corresponding to the lanes we aren't emitting code
6836 // for. This behavior can be changed by allowing getScalarValue to clone
6837 // the lane zero values for uniforms rather than asserting.
6838 for (Use &U : I->operands())
6839 if (auto *J = dyn_cast<Instruction>(U.get()))
6840 if (isUniformAfterVectorization(J, VF))
6841 return false;
6842
6843 // Otherwise, we can scalarize the instruction.
6844 return true;
6845 };
6846
6847 // Compute the expected cost discount from scalarizing the entire expression
6848 // feeding the predicated instruction. We currently only consider expressions
6849 // that are single-use instruction chains.
6850 Worklist.push_back(PredInst);
6851 while (!Worklist.empty()) {
6852 Instruction *I = Worklist.pop_back_val();
6853
6854 // If we've already analyzed the instruction, there's nothing to do.
6855 if (ScalarCosts.find(I) != ScalarCosts.end())
6856 continue;
6857
6858 // Compute the cost of the vector instruction. Note that this cost already
6859 // includes the scalarization overhead of the predicated instruction.
6860 InstructionCost VectorCost = getInstructionCost(I, VF).first;
6861
6862 // Compute the cost of the scalarized instruction. This cost is the cost of
6863 // the instruction as if it wasn't if-converted and instead remained in the
6864 // predicated block. We will scale this cost by block probability after
6865 // computing the scalarization overhead.
6866 InstructionCost ScalarCost =
6867 VF.getFixedValue() *
6868 getInstructionCost(I, ElementCount::getFixed(1)).first;
6869
6870 // Compute the scalarization overhead of needed insertelement instructions
6871 // and phi nodes.
6872 if (isScalarWithPredication(I) && !I->getType()->isVoidTy()) {
6873 ScalarCost += TTI.getScalarizationOverhead(
6874 cast<VectorType>(ToVectorTy(I->getType(), VF)),
6875 APInt::getAllOnesValue(VF.getFixedValue()), true, false);
6876 ScalarCost +=
6877 VF.getFixedValue() *
6878 TTI.getCFInstrCost(Instruction::PHI, TTI::TCK_RecipThroughput);
6879 }
6880
6881 // Compute the scalarization overhead of needed extractelement
6882 // instructions. For each of the instruction's operands, if the operand can
6883 // be scalarized, add it to the worklist; otherwise, account for the
6884 // overhead.
6885 for (Use &U : I->operands())
6886 if (auto *J = dyn_cast<Instruction>(U.get())) {
6887 assert(VectorType::isValidElementType(J->getType()) &&
6888 "Instruction has non-scalar type");
6889 if (canBeScalarized(J))
6890 Worklist.push_back(J);
6891 else if (needsExtract(J, VF)) {
6892 ScalarCost += TTI.getScalarizationOverhead(
6893 cast<VectorType>(ToVectorTy(J->getType(), VF)),
6894 APInt::getAllOnesValue(VF.getFixedValue()), false, true);
6895 }
6896 }
6897
6898 // Scale the total scalar cost by block probability.
6899 ScalarCost /= getReciprocalPredBlockProb();
6900
6901 // Compute the discount. A non-negative discount means the vector version
6902 // of the instruction costs more, and scalarizing would be beneficial.
6903 Discount += VectorCost - ScalarCost;
6904 ScalarCosts[I] = ScalarCost;
6905 }
6906
6907 return *Discount.getValue();
6908 }
6909
6910 LoopVectorizationCostModel::VectorizationCostTy
expectedCost(ElementCount VF,SmallVectorImpl<InstructionVFPair> * Invalid)6911 LoopVectorizationCostModel::expectedCost(
6912 ElementCount VF, SmallVectorImpl<InstructionVFPair> *Invalid) {
6913 VectorizationCostTy Cost;
6914
6915 // For each block.
6916 for (BasicBlock *BB : TheLoop->blocks()) {
6917 VectorizationCostTy BlockCost;
6918
6919 // For each instruction in the old loop.
6920 for (Instruction &I : BB->instructionsWithoutDebug()) {
6921 // Skip ignored values.
6922 if (ValuesToIgnore.count(&I) ||
6923 (VF.isVector() && VecValuesToIgnore.count(&I)))
6924 continue;
6925
6926 VectorizationCostTy C = getInstructionCost(&I, VF);
6927
6928 // Check if we should override the cost.
6929 if (C.first.isValid() &&
6930 ForceTargetInstructionCost.getNumOccurrences() > 0)
6931 C.first = InstructionCost(ForceTargetInstructionCost);
6932
6933 // Keep a list of instructions with invalid costs.
6934 if (Invalid && !C.first.isValid())
6935 Invalid->emplace_back(&I, VF);
6936
6937 BlockCost.first += C.first;
6938 BlockCost.second |= C.second;
6939 LLVM_DEBUG(dbgs() << "LV: Found an estimated cost of " << C.first
6940 << " for VF " << VF << " For instruction: " << I
6941 << '\n');
6942 }
6943
6944 // If we are vectorizing a predicated block, it will have been
6945 // if-converted. This means that the block's instructions (aside from
6946 // stores and instructions that may divide by zero) will now be
6947 // unconditionally executed. For the scalar case, we may not always execute
6948 // the predicated block, if it is an if-else block. Thus, scale the block's
6949 // cost by the probability of executing it. blockNeedsPredication from
6950 // Legal is used so as to not include all blocks in tail folded loops.
6951 if (VF.isScalar() && Legal->blockNeedsPredication(BB))
6952 BlockCost.first /= getReciprocalPredBlockProb();
6953
6954 Cost.first += BlockCost.first;
6955 Cost.second |= BlockCost.second;
6956 }
6957
6958 return Cost;
6959 }
6960
6961 /// Gets Address Access SCEV after verifying that the access pattern
6962 /// is loop invariant except the induction variable dependence.
6963 ///
6964 /// This SCEV can be sent to the Target in order to estimate the address
6965 /// calculation cost.
getAddressAccessSCEV(Value * Ptr,LoopVectorizationLegality * Legal,PredicatedScalarEvolution & PSE,const Loop * TheLoop)6966 static const SCEV *getAddressAccessSCEV(
6967 Value *Ptr,
6968 LoopVectorizationLegality *Legal,
6969 PredicatedScalarEvolution &PSE,
6970 const Loop *TheLoop) {
6971
6972 auto *Gep = dyn_cast<GetElementPtrInst>(Ptr);
6973 if (!Gep)
6974 return nullptr;
6975
6976 // We are looking for a gep with all loop invariant indices except for one
6977 // which should be an induction variable.
6978 auto SE = PSE.getSE();
6979 unsigned NumOperands = Gep->getNumOperands();
6980 for (unsigned i = 1; i < NumOperands; ++i) {
6981 Value *Opd = Gep->getOperand(i);
6982 if (!SE->isLoopInvariant(SE->getSCEV(Opd), TheLoop) &&
6983 !Legal->isInductionVariable(Opd))
6984 return nullptr;
6985 }
6986
6987 // Now we know we have a GEP ptr, %inv, %ind, %inv. return the Ptr SCEV.
6988 return PSE.getSCEV(Ptr);
6989 }
6990
isStrideMul(Instruction * I,LoopVectorizationLegality * Legal)6991 static bool isStrideMul(Instruction *I, LoopVectorizationLegality *Legal) {
6992 return Legal->hasStride(I->getOperand(0)) ||
6993 Legal->hasStride(I->getOperand(1));
6994 }
6995
6996 InstructionCost
getMemInstScalarizationCost(Instruction * I,ElementCount VF)6997 LoopVectorizationCostModel::getMemInstScalarizationCost(Instruction *I,
6998 ElementCount VF) {
6999 assert(VF.isVector() &&
7000 "Scalarization cost of instruction implies vectorization.");
7001 if (VF.isScalable())
7002 return InstructionCost::getInvalid();
7003
7004 Type *ValTy = getLoadStoreType(I);
7005 auto SE = PSE.getSE();
7006
7007 unsigned AS = getLoadStoreAddressSpace(I);
7008 Value *Ptr = getLoadStorePointerOperand(I);
7009 Type *PtrTy = ToVectorTy(Ptr->getType(), VF);
7010
7011 // Figure out whether the access is strided and get the stride value
7012 // if it's known in compile time
7013 const SCEV *PtrSCEV = getAddressAccessSCEV(Ptr, Legal, PSE, TheLoop);
7014
7015 // Get the cost of the scalar memory instruction and address computation.
7016 InstructionCost Cost =
7017 VF.getKnownMinValue() * TTI.getAddressComputationCost(PtrTy, SE, PtrSCEV);
7018
7019 // Don't pass *I here, since it is scalar but will actually be part of a
7020 // vectorized loop where the user of it is a vectorized instruction.
7021 const Align Alignment = getLoadStoreAlignment(I);
7022 Cost += VF.getKnownMinValue() *
7023 TTI.getMemoryOpCost(I->getOpcode(), ValTy->getScalarType(), Alignment,
7024 AS, TTI::TCK_RecipThroughput);
7025
7026 // Get the overhead of the extractelement and insertelement instructions
7027 // we might create due to scalarization.
7028 Cost += getScalarizationOverhead(I, VF);
7029
7030 // If we have a predicated load/store, it will need extra i1 extracts and
7031 // conditional branches, but may not be executed for each vector lane. Scale
7032 // the cost by the probability of executing the predicated block.
7033 if (isPredicatedInst(I)) {
7034 Cost /= getReciprocalPredBlockProb();
7035
7036 // Add the cost of an i1 extract and a branch
7037 auto *Vec_i1Ty =
7038 VectorType::get(IntegerType::getInt1Ty(ValTy->getContext()), VF);
7039 Cost += TTI.getScalarizationOverhead(
7040 Vec_i1Ty, APInt::getAllOnesValue(VF.getKnownMinValue()),
7041 /*Insert=*/false, /*Extract=*/true);
7042 Cost += TTI.getCFInstrCost(Instruction::Br, TTI::TCK_RecipThroughput);
7043
7044 if (useEmulatedMaskMemRefHack(I))
7045 // Artificially setting to a high enough value to practically disable
7046 // vectorization with such operations.
7047 Cost = 3000000;
7048 }
7049
7050 return Cost;
7051 }
7052
7053 InstructionCost
getConsecutiveMemOpCost(Instruction * I,ElementCount VF)7054 LoopVectorizationCostModel::getConsecutiveMemOpCost(Instruction *I,
7055 ElementCount VF) {
7056 Type *ValTy = getLoadStoreType(I);
7057 auto *VectorTy = cast<VectorType>(ToVectorTy(ValTy, VF));
7058 Value *Ptr = getLoadStorePointerOperand(I);
7059 unsigned AS = getLoadStoreAddressSpace(I);
7060 int ConsecutiveStride = Legal->isConsecutivePtr(Ptr);
7061 enum TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput;
7062
7063 assert((ConsecutiveStride == 1 || ConsecutiveStride == -1) &&
7064 "Stride should be 1 or -1 for consecutive memory access");
7065 const Align Alignment = getLoadStoreAlignment(I);
7066 InstructionCost Cost = 0;
7067 if (Legal->isMaskRequired(I))
7068 Cost += TTI.getMaskedMemoryOpCost(I->getOpcode(), VectorTy, Alignment, AS,
7069 CostKind);
7070 else
7071 Cost += TTI.getMemoryOpCost(I->getOpcode(), VectorTy, Alignment, AS,
7072 CostKind, I);
7073
7074 bool Reverse = ConsecutiveStride < 0;
7075 if (Reverse)
7076 Cost +=
7077 TTI.getShuffleCost(TargetTransformInfo::SK_Reverse, VectorTy, None, 0);
7078 return Cost;
7079 }
7080
7081 InstructionCost
getUniformMemOpCost(Instruction * I,ElementCount VF)7082 LoopVectorizationCostModel::getUniformMemOpCost(Instruction *I,
7083 ElementCount VF) {
7084 assert(Legal->isUniformMemOp(*I));
7085
7086 Type *ValTy = getLoadStoreType(I);
7087 auto *VectorTy = cast<VectorType>(ToVectorTy(ValTy, VF));
7088 const Align Alignment = getLoadStoreAlignment(I);
7089 unsigned AS = getLoadStoreAddressSpace(I);
7090 enum TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput;
7091 if (isa<LoadInst>(I)) {
7092 return TTI.getAddressComputationCost(ValTy) +
7093 TTI.getMemoryOpCost(Instruction::Load, ValTy, Alignment, AS,
7094 CostKind) +
7095 TTI.getShuffleCost(TargetTransformInfo::SK_Broadcast, VectorTy);
7096 }
7097 StoreInst *SI = cast<StoreInst>(I);
7098
7099 bool isLoopInvariantStoreValue = Legal->isUniform(SI->getValueOperand());
7100 return TTI.getAddressComputationCost(ValTy) +
7101 TTI.getMemoryOpCost(Instruction::Store, ValTy, Alignment, AS,
7102 CostKind) +
7103 (isLoopInvariantStoreValue
7104 ? 0
7105 : TTI.getVectorInstrCost(Instruction::ExtractElement, VectorTy,
7106 VF.getKnownMinValue() - 1));
7107 }
7108
7109 InstructionCost
getGatherScatterCost(Instruction * I,ElementCount VF)7110 LoopVectorizationCostModel::getGatherScatterCost(Instruction *I,
7111 ElementCount VF) {
7112 Type *ValTy = getLoadStoreType(I);
7113 auto *VectorTy = cast<VectorType>(ToVectorTy(ValTy, VF));
7114 const Align Alignment = getLoadStoreAlignment(I);
7115 const Value *Ptr = getLoadStorePointerOperand(I);
7116
7117 return TTI.getAddressComputationCost(VectorTy) +
7118 TTI.getGatherScatterOpCost(
7119 I->getOpcode(), VectorTy, Ptr, Legal->isMaskRequired(I), Alignment,
7120 TargetTransformInfo::TCK_RecipThroughput, I);
7121 }
7122
7123 InstructionCost
getInterleaveGroupCost(Instruction * I,ElementCount VF)7124 LoopVectorizationCostModel::getInterleaveGroupCost(Instruction *I,
7125 ElementCount VF) {
7126 // TODO: Once we have support for interleaving with scalable vectors
7127 // we can calculate the cost properly here.
7128 if (VF.isScalable())
7129 return InstructionCost::getInvalid();
7130
7131 Type *ValTy = getLoadStoreType(I);
7132 auto *VectorTy = cast<VectorType>(ToVectorTy(ValTy, VF));
7133 unsigned AS = getLoadStoreAddressSpace(I);
7134
7135 auto Group = getInterleavedAccessGroup(I);
7136 assert(Group && "Fail to get an interleaved access group.");
7137
7138 unsigned InterleaveFactor = Group->getFactor();
7139 auto *WideVecTy = VectorType::get(ValTy, VF * InterleaveFactor);
7140
7141 // Holds the indices of existing members in an interleaved load group.
7142 // An interleaved store group doesn't need this as it doesn't allow gaps.
7143 SmallVector<unsigned, 4> Indices;
7144 if (isa<LoadInst>(I)) {
7145 for (unsigned i = 0; i < InterleaveFactor; i++)
7146 if (Group->getMember(i))
7147 Indices.push_back(i);
7148 }
7149
7150 // Calculate the cost of the whole interleaved group.
7151 bool UseMaskForGaps =
7152 Group->requiresScalarEpilogue() && !isScalarEpilogueAllowed();
7153 InstructionCost Cost = TTI.getInterleavedMemoryOpCost(
7154 I->getOpcode(), WideVecTy, Group->getFactor(), Indices, Group->getAlign(),
7155 AS, TTI::TCK_RecipThroughput, Legal->isMaskRequired(I), UseMaskForGaps);
7156
7157 if (Group->isReverse()) {
7158 // TODO: Add support for reversed masked interleaved access.
7159 assert(!Legal->isMaskRequired(I) &&
7160 "Reverse masked interleaved access not supported.");
7161 Cost +=
7162 Group->getNumMembers() *
7163 TTI.getShuffleCost(TargetTransformInfo::SK_Reverse, VectorTy, None, 0);
7164 }
7165 return Cost;
7166 }
7167
getReductionPatternCost(Instruction * I,ElementCount VF,Type * Ty,TTI::TargetCostKind CostKind)7168 Optional<InstructionCost> LoopVectorizationCostModel::getReductionPatternCost(
7169 Instruction *I, ElementCount VF, Type *Ty, TTI::TargetCostKind CostKind) {
7170 using namespace llvm::PatternMatch;
7171 // Early exit for no inloop reductions
7172 if (InLoopReductionChains.empty() || VF.isScalar() || !isa<VectorType>(Ty))
7173 return None;
7174 auto *VectorTy = cast<VectorType>(Ty);
7175
7176 // We are looking for a pattern of, and finding the minimal acceptable cost:
7177 // reduce(mul(ext(A), ext(B))) or
7178 // reduce(mul(A, B)) or
7179 // reduce(ext(A)) or
7180 // reduce(A).
7181 // The basic idea is that we walk down the tree to do that, finding the root
7182 // reduction instruction in InLoopReductionImmediateChains. From there we find
7183 // the pattern of mul/ext and test the cost of the entire pattern vs the cost
7184 // of the components. If the reduction cost is lower then we return it for the
7185 // reduction instruction and 0 for the other instructions in the pattern. If
7186 // it is not we return an invalid cost specifying the orignal cost method
7187 // should be used.
7188 Instruction *RetI = I;
7189 if (match(RetI, m_ZExtOrSExt(m_Value()))) {
7190 if (!RetI->hasOneUser())
7191 return None;
7192 RetI = RetI->user_back();
7193 }
7194 if (match(RetI, m_Mul(m_Value(), m_Value())) &&
7195 RetI->user_back()->getOpcode() == Instruction::Add) {
7196 if (!RetI->hasOneUser())
7197 return None;
7198 RetI = RetI->user_back();
7199 }
7200
7201 // Test if the found instruction is a reduction, and if not return an invalid
7202 // cost specifying the parent to use the original cost modelling.
7203 if (!InLoopReductionImmediateChains.count(RetI))
7204 return None;
7205
7206 // Find the reduction this chain is a part of and calculate the basic cost of
7207 // the reduction on its own.
7208 Instruction *LastChain = InLoopReductionImmediateChains[RetI];
7209 Instruction *ReductionPhi = LastChain;
7210 while (!isa<PHINode>(ReductionPhi))
7211 ReductionPhi = InLoopReductionImmediateChains[ReductionPhi];
7212
7213 const RecurrenceDescriptor &RdxDesc =
7214 Legal->getReductionVars()[cast<PHINode>(ReductionPhi)];
7215
7216 InstructionCost BaseCost = TTI.getArithmeticReductionCost(
7217 RdxDesc.getOpcode(), VectorTy, RdxDesc.getFastMathFlags(), CostKind);
7218
7219 // If we're using ordered reductions then we can just return the base cost
7220 // here, since getArithmeticReductionCost calculates the full ordered
7221 // reduction cost when FP reassociation is not allowed.
7222 if (useOrderedReductions(RdxDesc))
7223 return BaseCost;
7224
7225 // Get the operand that was not the reduction chain and match it to one of the
7226 // patterns, returning the better cost if it is found.
7227 Instruction *RedOp = RetI->getOperand(1) == LastChain
7228 ? dyn_cast<Instruction>(RetI->getOperand(0))
7229 : dyn_cast<Instruction>(RetI->getOperand(1));
7230
7231 VectorTy = VectorType::get(I->getOperand(0)->getType(), VectorTy);
7232
7233 Instruction *Op0, *Op1;
7234 if (RedOp && match(RedOp, m_ZExtOrSExt(m_Value())) &&
7235 !TheLoop->isLoopInvariant(RedOp)) {
7236 // Matched reduce(ext(A))
7237 bool IsUnsigned = isa<ZExtInst>(RedOp);
7238 auto *ExtType = VectorType::get(RedOp->getOperand(0)->getType(), VectorTy);
7239 InstructionCost RedCost = TTI.getExtendedAddReductionCost(
7240 /*IsMLA=*/false, IsUnsigned, RdxDesc.getRecurrenceType(), ExtType,
7241 CostKind);
7242
7243 InstructionCost ExtCost =
7244 TTI.getCastInstrCost(RedOp->getOpcode(), VectorTy, ExtType,
7245 TTI::CastContextHint::None, CostKind, RedOp);
7246 if (RedCost.isValid() && RedCost < BaseCost + ExtCost)
7247 return I == RetI ? RedCost : 0;
7248 } else if (RedOp &&
7249 match(RedOp, m_Mul(m_Instruction(Op0), m_Instruction(Op1)))) {
7250 if (match(Op0, m_ZExtOrSExt(m_Value())) &&
7251 Op0->getOpcode() == Op1->getOpcode() &&
7252 Op0->getOperand(0)->getType() == Op1->getOperand(0)->getType() &&
7253 !TheLoop->isLoopInvariant(Op0) && !TheLoop->isLoopInvariant(Op1)) {
7254 bool IsUnsigned = isa<ZExtInst>(Op0);
7255 auto *ExtType = VectorType::get(Op0->getOperand(0)->getType(), VectorTy);
7256 // Matched reduce(mul(ext, ext))
7257 InstructionCost ExtCost =
7258 TTI.getCastInstrCost(Op0->getOpcode(), VectorTy, ExtType,
7259 TTI::CastContextHint::None, CostKind, Op0);
7260 InstructionCost MulCost =
7261 TTI.getArithmeticInstrCost(Instruction::Mul, VectorTy, CostKind);
7262
7263 InstructionCost RedCost = TTI.getExtendedAddReductionCost(
7264 /*IsMLA=*/true, IsUnsigned, RdxDesc.getRecurrenceType(), ExtType,
7265 CostKind);
7266
7267 if (RedCost.isValid() && RedCost < ExtCost * 2 + MulCost + BaseCost)
7268 return I == RetI ? RedCost : 0;
7269 } else {
7270 // Matched reduce(mul())
7271 InstructionCost MulCost =
7272 TTI.getArithmeticInstrCost(Instruction::Mul, VectorTy, CostKind);
7273
7274 InstructionCost RedCost = TTI.getExtendedAddReductionCost(
7275 /*IsMLA=*/true, true, RdxDesc.getRecurrenceType(), VectorTy,
7276 CostKind);
7277
7278 if (RedCost.isValid() && RedCost < MulCost + BaseCost)
7279 return I == RetI ? RedCost : 0;
7280 }
7281 }
7282
7283 return I == RetI ? Optional<InstructionCost>(BaseCost) : None;
7284 }
7285
7286 InstructionCost
getMemoryInstructionCost(Instruction * I,ElementCount VF)7287 LoopVectorizationCostModel::getMemoryInstructionCost(Instruction *I,
7288 ElementCount VF) {
7289 // Calculate scalar cost only. Vectorization cost should be ready at this
7290 // moment.
7291 if (VF.isScalar()) {
7292 Type *ValTy = getLoadStoreType(I);
7293 const Align Alignment = getLoadStoreAlignment(I);
7294 unsigned AS = getLoadStoreAddressSpace(I);
7295
7296 return TTI.getAddressComputationCost(ValTy) +
7297 TTI.getMemoryOpCost(I->getOpcode(), ValTy, Alignment, AS,
7298 TTI::TCK_RecipThroughput, I);
7299 }
7300 return getWideningCost(I, VF);
7301 }
7302
7303 LoopVectorizationCostModel::VectorizationCostTy
getInstructionCost(Instruction * I,ElementCount VF)7304 LoopVectorizationCostModel::getInstructionCost(Instruction *I,
7305 ElementCount VF) {
7306 // If we know that this instruction will remain uniform, check the cost of
7307 // the scalar version.
7308 if (isUniformAfterVectorization(I, VF))
7309 VF = ElementCount::getFixed(1);
7310
7311 if (VF.isVector() && isProfitableToScalarize(I, VF))
7312 return VectorizationCostTy(InstsToScalarize[VF][I], false);
7313
7314 // Forced scalars do not have any scalarization overhead.
7315 auto ForcedScalar = ForcedScalars.find(VF);
7316 if (VF.isVector() && ForcedScalar != ForcedScalars.end()) {
7317 auto InstSet = ForcedScalar->second;
7318 if (InstSet.count(I))
7319 return VectorizationCostTy(
7320 (getInstructionCost(I, ElementCount::getFixed(1)).first *
7321 VF.getKnownMinValue()),
7322 false);
7323 }
7324
7325 Type *VectorTy;
7326 InstructionCost C = getInstructionCost(I, VF, VectorTy);
7327
7328 bool TypeNotScalarized =
7329 VF.isVector() && VectorTy->isVectorTy() &&
7330 TTI.getNumberOfParts(VectorTy) < VF.getKnownMinValue();
7331 return VectorizationCostTy(C, TypeNotScalarized);
7332 }
7333
7334 InstructionCost
getScalarizationOverhead(Instruction * I,ElementCount VF) const7335 LoopVectorizationCostModel::getScalarizationOverhead(Instruction *I,
7336 ElementCount VF) const {
7337
7338 // There is no mechanism yet to create a scalable scalarization loop,
7339 // so this is currently Invalid.
7340 if (VF.isScalable())
7341 return InstructionCost::getInvalid();
7342
7343 if (VF.isScalar())
7344 return 0;
7345
7346 InstructionCost Cost = 0;
7347 Type *RetTy = ToVectorTy(I->getType(), VF);
7348 if (!RetTy->isVoidTy() &&
7349 (!isa<LoadInst>(I) || !TTI.supportsEfficientVectorElementLoadStore()))
7350 Cost += TTI.getScalarizationOverhead(
7351 cast<VectorType>(RetTy), APInt::getAllOnesValue(VF.getKnownMinValue()),
7352 true, false);
7353
7354 // Some targets keep addresses scalar.
7355 if (isa<LoadInst>(I) && !TTI.prefersVectorizedAddressing())
7356 return Cost;
7357
7358 // Some targets support efficient element stores.
7359 if (isa<StoreInst>(I) && TTI.supportsEfficientVectorElementLoadStore())
7360 return Cost;
7361
7362 // Collect operands to consider.
7363 CallInst *CI = dyn_cast<CallInst>(I);
7364 Instruction::op_range Ops = CI ? CI->arg_operands() : I->operands();
7365
7366 // Skip operands that do not require extraction/scalarization and do not incur
7367 // any overhead.
7368 SmallVector<Type *> Tys;
7369 for (auto *V : filterExtractingOperands(Ops, VF))
7370 Tys.push_back(MaybeVectorizeType(V->getType(), VF));
7371 return Cost + TTI.getOperandsScalarizationOverhead(
7372 filterExtractingOperands(Ops, VF), Tys);
7373 }
7374
setCostBasedWideningDecision(ElementCount VF)7375 void LoopVectorizationCostModel::setCostBasedWideningDecision(ElementCount VF) {
7376 if (VF.isScalar())
7377 return;
7378 NumPredStores = 0;
7379 for (BasicBlock *BB : TheLoop->blocks()) {
7380 // For each instruction in the old loop.
7381 for (Instruction &I : *BB) {
7382 Value *Ptr = getLoadStorePointerOperand(&I);
7383 if (!Ptr)
7384 continue;
7385
7386 // TODO: We should generate better code and update the cost model for
7387 // predicated uniform stores. Today they are treated as any other
7388 // predicated store (see added test cases in
7389 // invariant-store-vectorization.ll).
7390 if (isa<StoreInst>(&I) && isScalarWithPredication(&I))
7391 NumPredStores++;
7392
7393 if (Legal->isUniformMemOp(I)) {
7394 // TODO: Avoid replicating loads and stores instead of
7395 // relying on instcombine to remove them.
7396 // Load: Scalar load + broadcast
7397 // Store: Scalar store + isLoopInvariantStoreValue ? 0 : extract
7398 InstructionCost Cost;
7399 if (isa<StoreInst>(&I) && VF.isScalable() &&
7400 isLegalGatherOrScatter(&I)) {
7401 Cost = getGatherScatterCost(&I, VF);
7402 setWideningDecision(&I, VF, CM_GatherScatter, Cost);
7403 } else {
7404 assert((isa<LoadInst>(&I) || !VF.isScalable()) &&
7405 "Cannot yet scalarize uniform stores");
7406 Cost = getUniformMemOpCost(&I, VF);
7407 setWideningDecision(&I, VF, CM_Scalarize, Cost);
7408 }
7409 continue;
7410 }
7411
7412 // We assume that widening is the best solution when possible.
7413 if (memoryInstructionCanBeWidened(&I, VF)) {
7414 InstructionCost Cost = getConsecutiveMemOpCost(&I, VF);
7415 int ConsecutiveStride =
7416 Legal->isConsecutivePtr(getLoadStorePointerOperand(&I));
7417 assert((ConsecutiveStride == 1 || ConsecutiveStride == -1) &&
7418 "Expected consecutive stride.");
7419 InstWidening Decision =
7420 ConsecutiveStride == 1 ? CM_Widen : CM_Widen_Reverse;
7421 setWideningDecision(&I, VF, Decision, Cost);
7422 continue;
7423 }
7424
7425 // Choose between Interleaving, Gather/Scatter or Scalarization.
7426 InstructionCost InterleaveCost = InstructionCost::getInvalid();
7427 unsigned NumAccesses = 1;
7428 if (isAccessInterleaved(&I)) {
7429 auto Group = getInterleavedAccessGroup(&I);
7430 assert(Group && "Fail to get an interleaved access group.");
7431
7432 // Make one decision for the whole group.
7433 if (getWideningDecision(&I, VF) != CM_Unknown)
7434 continue;
7435
7436 NumAccesses = Group->getNumMembers();
7437 if (interleavedAccessCanBeWidened(&I, VF))
7438 InterleaveCost = getInterleaveGroupCost(&I, VF);
7439 }
7440
7441 InstructionCost GatherScatterCost =
7442 isLegalGatherOrScatter(&I)
7443 ? getGatherScatterCost(&I, VF) * NumAccesses
7444 : InstructionCost::getInvalid();
7445
7446 InstructionCost ScalarizationCost =
7447 getMemInstScalarizationCost(&I, VF) * NumAccesses;
7448
7449 // Choose better solution for the current VF,
7450 // write down this decision and use it during vectorization.
7451 InstructionCost Cost;
7452 InstWidening Decision;
7453 if (InterleaveCost <= GatherScatterCost &&
7454 InterleaveCost < ScalarizationCost) {
7455 Decision = CM_Interleave;
7456 Cost = InterleaveCost;
7457 } else if (GatherScatterCost < ScalarizationCost) {
7458 Decision = CM_GatherScatter;
7459 Cost = GatherScatterCost;
7460 } else {
7461 Decision = CM_Scalarize;
7462 Cost = ScalarizationCost;
7463 }
7464 // If the instructions belongs to an interleave group, the whole group
7465 // receives the same decision. The whole group receives the cost, but
7466 // the cost will actually be assigned to one instruction.
7467 if (auto Group = getInterleavedAccessGroup(&I))
7468 setWideningDecision(Group, VF, Decision, Cost);
7469 else
7470 setWideningDecision(&I, VF, Decision, Cost);
7471 }
7472 }
7473
7474 // Make sure that any load of address and any other address computation
7475 // remains scalar unless there is gather/scatter support. This avoids
7476 // inevitable extracts into address registers, and also has the benefit of
7477 // activating LSR more, since that pass can't optimize vectorized
7478 // addresses.
7479 if (TTI.prefersVectorizedAddressing())
7480 return;
7481
7482 // Start with all scalar pointer uses.
7483 SmallPtrSet<Instruction *, 8> AddrDefs;
7484 for (BasicBlock *BB : TheLoop->blocks())
7485 for (Instruction &I : *BB) {
7486 Instruction *PtrDef =
7487 dyn_cast_or_null<Instruction>(getLoadStorePointerOperand(&I));
7488 if (PtrDef && TheLoop->contains(PtrDef) &&
7489 getWideningDecision(&I, VF) != CM_GatherScatter)
7490 AddrDefs.insert(PtrDef);
7491 }
7492
7493 // Add all instructions used to generate the addresses.
7494 SmallVector<Instruction *, 4> Worklist;
7495 append_range(Worklist, AddrDefs);
7496 while (!Worklist.empty()) {
7497 Instruction *I = Worklist.pop_back_val();
7498 for (auto &Op : I->operands())
7499 if (auto *InstOp = dyn_cast<Instruction>(Op))
7500 if ((InstOp->getParent() == I->getParent()) && !isa<PHINode>(InstOp) &&
7501 AddrDefs.insert(InstOp).second)
7502 Worklist.push_back(InstOp);
7503 }
7504
7505 for (auto *I : AddrDefs) {
7506 if (isa<LoadInst>(I)) {
7507 // Setting the desired widening decision should ideally be handled in
7508 // by cost functions, but since this involves the task of finding out
7509 // if the loaded register is involved in an address computation, it is
7510 // instead changed here when we know this is the case.
7511 InstWidening Decision = getWideningDecision(I, VF);
7512 if (Decision == CM_Widen || Decision == CM_Widen_Reverse)
7513 // Scalarize a widened load of address.
7514 setWideningDecision(
7515 I, VF, CM_Scalarize,
7516 (VF.getKnownMinValue() *
7517 getMemoryInstructionCost(I, ElementCount::getFixed(1))));
7518 else if (auto Group = getInterleavedAccessGroup(I)) {
7519 // Scalarize an interleave group of address loads.
7520 for (unsigned I = 0; I < Group->getFactor(); ++I) {
7521 if (Instruction *Member = Group->getMember(I))
7522 setWideningDecision(
7523 Member, VF, CM_Scalarize,
7524 (VF.getKnownMinValue() *
7525 getMemoryInstructionCost(Member, ElementCount::getFixed(1))));
7526 }
7527 }
7528 } else
7529 // Make sure I gets scalarized and a cost estimate without
7530 // scalarization overhead.
7531 ForcedScalars[VF].insert(I);
7532 }
7533 }
7534
7535 InstructionCost
getInstructionCost(Instruction * I,ElementCount VF,Type * & VectorTy)7536 LoopVectorizationCostModel::getInstructionCost(Instruction *I, ElementCount VF,
7537 Type *&VectorTy) {
7538 Type *RetTy = I->getType();
7539 if (canTruncateToMinimalBitwidth(I, VF))
7540 RetTy = IntegerType::get(RetTy->getContext(), MinBWs[I]);
7541 auto SE = PSE.getSE();
7542 TTI::TargetCostKind CostKind = TTI::TCK_RecipThroughput;
7543
7544 auto hasSingleCopyAfterVectorization = [this](Instruction *I,
7545 ElementCount VF) -> bool {
7546 if (VF.isScalar())
7547 return true;
7548
7549 auto Scalarized = InstsToScalarize.find(VF);
7550 assert(Scalarized != InstsToScalarize.end() &&
7551 "VF not yet analyzed for scalarization profitability");
7552 return !Scalarized->second.count(I) &&
7553 llvm::all_of(I->users(), [&](User *U) {
7554 auto *UI = cast<Instruction>(U);
7555 return !Scalarized->second.count(UI);
7556 });
7557 };
7558 (void) hasSingleCopyAfterVectorization;
7559
7560 if (isScalarAfterVectorization(I, VF)) {
7561 // With the exception of GEPs and PHIs, after scalarization there should
7562 // only be one copy of the instruction generated in the loop. This is
7563 // because the VF is either 1, or any instructions that need scalarizing
7564 // have already been dealt with by the the time we get here. As a result,
7565 // it means we don't have to multiply the instruction cost by VF.
7566 assert(I->getOpcode() == Instruction::GetElementPtr ||
7567 I->getOpcode() == Instruction::PHI ||
7568 (I->getOpcode() == Instruction::BitCast &&
7569 I->getType()->isPointerTy()) ||
7570 hasSingleCopyAfterVectorization(I, VF));
7571 VectorTy = RetTy;
7572 } else
7573 VectorTy = ToVectorTy(RetTy, VF);
7574
7575 // TODO: We need to estimate the cost of intrinsic calls.
7576 switch (I->getOpcode()) {
7577 case Instruction::GetElementPtr:
7578 // We mark this instruction as zero-cost because the cost of GEPs in
7579 // vectorized code depends on whether the corresponding memory instruction
7580 // is scalarized or not. Therefore, we handle GEPs with the memory
7581 // instruction cost.
7582 return 0;
7583 case Instruction::Br: {
7584 // In cases of scalarized and predicated instructions, there will be VF
7585 // predicated blocks in the vectorized loop. Each branch around these
7586 // blocks requires also an extract of its vector compare i1 element.
7587 bool ScalarPredicatedBB = false;
7588 BranchInst *BI = cast<BranchInst>(I);
7589 if (VF.isVector() && BI->isConditional() &&
7590 (PredicatedBBsAfterVectorization.count(BI->getSuccessor(0)) ||
7591 PredicatedBBsAfterVectorization.count(BI->getSuccessor(1))))
7592 ScalarPredicatedBB = true;
7593
7594 if (ScalarPredicatedBB) {
7595 // Not possible to scalarize scalable vector with predicated instructions.
7596 if (VF.isScalable())
7597 return InstructionCost::getInvalid();
7598 // Return cost for branches around scalarized and predicated blocks.
7599 auto *Vec_i1Ty =
7600 VectorType::get(IntegerType::getInt1Ty(RetTy->getContext()), VF);
7601 return (
7602 TTI.getScalarizationOverhead(
7603 Vec_i1Ty, APInt::getAllOnesValue(VF.getFixedValue()), false,
7604 true) +
7605 (TTI.getCFInstrCost(Instruction::Br, CostKind) * VF.getFixedValue()));
7606 } else if (I->getParent() == TheLoop->getLoopLatch() || VF.isScalar())
7607 // The back-edge branch will remain, as will all scalar branches.
7608 return TTI.getCFInstrCost(Instruction::Br, CostKind);
7609 else
7610 // This branch will be eliminated by if-conversion.
7611 return 0;
7612 // Note: We currently assume zero cost for an unconditional branch inside
7613 // a predicated block since it will become a fall-through, although we
7614 // may decide in the future to call TTI for all branches.
7615 }
7616 case Instruction::PHI: {
7617 auto *Phi = cast<PHINode>(I);
7618
7619 // First-order recurrences are replaced by vector shuffles inside the loop.
7620 // NOTE: Don't use ToVectorTy as SK_ExtractSubvector expects a vector type.
7621 if (VF.isVector() && Legal->isFirstOrderRecurrence(Phi))
7622 return TTI.getShuffleCost(
7623 TargetTransformInfo::SK_ExtractSubvector, cast<VectorType>(VectorTy),
7624 None, VF.getKnownMinValue() - 1, FixedVectorType::get(RetTy, 1));
7625
7626 // Phi nodes in non-header blocks (not inductions, reductions, etc.) are
7627 // converted into select instructions. We require N - 1 selects per phi
7628 // node, where N is the number of incoming values.
7629 if (VF.isVector() && Phi->getParent() != TheLoop->getHeader())
7630 return (Phi->getNumIncomingValues() - 1) *
7631 TTI.getCmpSelInstrCost(
7632 Instruction::Select, ToVectorTy(Phi->getType(), VF),
7633 ToVectorTy(Type::getInt1Ty(Phi->getContext()), VF),
7634 CmpInst::BAD_ICMP_PREDICATE, CostKind);
7635
7636 return TTI.getCFInstrCost(Instruction::PHI, CostKind);
7637 }
7638 case Instruction::UDiv:
7639 case Instruction::SDiv:
7640 case Instruction::URem:
7641 case Instruction::SRem:
7642 // If we have a predicated instruction, it may not be executed for each
7643 // vector lane. Get the scalarization cost and scale this amount by the
7644 // probability of executing the predicated block. If the instruction is not
7645 // predicated, we fall through to the next case.
7646 if (VF.isVector() && isScalarWithPredication(I)) {
7647 InstructionCost Cost = 0;
7648
7649 // These instructions have a non-void type, so account for the phi nodes
7650 // that we will create. This cost is likely to be zero. The phi node
7651 // cost, if any, should be scaled by the block probability because it
7652 // models a copy at the end of each predicated block.
7653 Cost += VF.getKnownMinValue() *
7654 TTI.getCFInstrCost(Instruction::PHI, CostKind);
7655
7656 // The cost of the non-predicated instruction.
7657 Cost += VF.getKnownMinValue() *
7658 TTI.getArithmeticInstrCost(I->getOpcode(), RetTy, CostKind);
7659
7660 // The cost of insertelement and extractelement instructions needed for
7661 // scalarization.
7662 Cost += getScalarizationOverhead(I, VF);
7663
7664 // Scale the cost by the probability of executing the predicated blocks.
7665 // This assumes the predicated block for each vector lane is equally
7666 // likely.
7667 return Cost / getReciprocalPredBlockProb();
7668 }
7669 LLVM_FALLTHROUGH;
7670 case Instruction::Add:
7671 case Instruction::FAdd:
7672 case Instruction::Sub:
7673 case Instruction::FSub:
7674 case Instruction::Mul:
7675 case Instruction::FMul:
7676 case Instruction::FDiv:
7677 case Instruction::FRem:
7678 case Instruction::Shl:
7679 case Instruction::LShr:
7680 case Instruction::AShr:
7681 case Instruction::And:
7682 case Instruction::Or:
7683 case Instruction::Xor: {
7684 // Since we will replace the stride by 1 the multiplication should go away.
7685 if (I->getOpcode() == Instruction::Mul && isStrideMul(I, Legal))
7686 return 0;
7687
7688 // Detect reduction patterns
7689 if (auto RedCost = getReductionPatternCost(I, VF, VectorTy, CostKind))
7690 return *RedCost;
7691
7692 // Certain instructions can be cheaper to vectorize if they have a constant
7693 // second vector operand. One example of this are shifts on x86.
7694 Value *Op2 = I->getOperand(1);
7695 TargetTransformInfo::OperandValueProperties Op2VP;
7696 TargetTransformInfo::OperandValueKind Op2VK =
7697 TTI.getOperandInfo(Op2, Op2VP);
7698 if (Op2VK == TargetTransformInfo::OK_AnyValue && Legal->isUniform(Op2))
7699 Op2VK = TargetTransformInfo::OK_UniformValue;
7700
7701 SmallVector<const Value *, 4> Operands(I->operand_values());
7702 return TTI.getArithmeticInstrCost(
7703 I->getOpcode(), VectorTy, CostKind, TargetTransformInfo::OK_AnyValue,
7704 Op2VK, TargetTransformInfo::OP_None, Op2VP, Operands, I);
7705 }
7706 case Instruction::FNeg: {
7707 return TTI.getArithmeticInstrCost(
7708 I->getOpcode(), VectorTy, CostKind, TargetTransformInfo::OK_AnyValue,
7709 TargetTransformInfo::OK_AnyValue, TargetTransformInfo::OP_None,
7710 TargetTransformInfo::OP_None, I->getOperand(0), I);
7711 }
7712 case Instruction::Select: {
7713 SelectInst *SI = cast<SelectInst>(I);
7714 const SCEV *CondSCEV = SE->getSCEV(SI->getCondition());
7715 bool ScalarCond = (SE->isLoopInvariant(CondSCEV, TheLoop));
7716
7717 const Value *Op0, *Op1;
7718 using namespace llvm::PatternMatch;
7719 if (!ScalarCond && (match(I, m_LogicalAnd(m_Value(Op0), m_Value(Op1))) ||
7720 match(I, m_LogicalOr(m_Value(Op0), m_Value(Op1))))) {
7721 // select x, y, false --> x & y
7722 // select x, true, y --> x | y
7723 TTI::OperandValueProperties Op1VP = TTI::OP_None;
7724 TTI::OperandValueProperties Op2VP = TTI::OP_None;
7725 TTI::OperandValueKind Op1VK = TTI::getOperandInfo(Op0, Op1VP);
7726 TTI::OperandValueKind Op2VK = TTI::getOperandInfo(Op1, Op2VP);
7727 assert(Op0->getType()->getScalarSizeInBits() == 1 &&
7728 Op1->getType()->getScalarSizeInBits() == 1);
7729
7730 SmallVector<const Value *, 2> Operands{Op0, Op1};
7731 return TTI.getArithmeticInstrCost(
7732 match(I, m_LogicalOr()) ? Instruction::Or : Instruction::And, VectorTy,
7733 CostKind, Op1VK, Op2VK, Op1VP, Op2VP, Operands, I);
7734 }
7735
7736 Type *CondTy = SI->getCondition()->getType();
7737 if (!ScalarCond)
7738 CondTy = VectorType::get(CondTy, VF);
7739 return TTI.getCmpSelInstrCost(I->getOpcode(), VectorTy, CondTy,
7740 CmpInst::BAD_ICMP_PREDICATE, CostKind, I);
7741 }
7742 case Instruction::ICmp:
7743 case Instruction::FCmp: {
7744 Type *ValTy = I->getOperand(0)->getType();
7745 Instruction *Op0AsInstruction = dyn_cast<Instruction>(I->getOperand(0));
7746 if (canTruncateToMinimalBitwidth(Op0AsInstruction, VF))
7747 ValTy = IntegerType::get(ValTy->getContext(), MinBWs[Op0AsInstruction]);
7748 VectorTy = ToVectorTy(ValTy, VF);
7749 return TTI.getCmpSelInstrCost(I->getOpcode(), VectorTy, nullptr,
7750 CmpInst::BAD_ICMP_PREDICATE, CostKind, I);
7751 }
7752 case Instruction::Store:
7753 case Instruction::Load: {
7754 ElementCount Width = VF;
7755 if (Width.isVector()) {
7756 InstWidening Decision = getWideningDecision(I, Width);
7757 assert(Decision != CM_Unknown &&
7758 "CM decision should be taken at this point");
7759 if (Decision == CM_Scalarize)
7760 Width = ElementCount::getFixed(1);
7761 }
7762 VectorTy = ToVectorTy(getLoadStoreType(I), Width);
7763 return getMemoryInstructionCost(I, VF);
7764 }
7765 case Instruction::BitCast:
7766 if (I->getType()->isPointerTy())
7767 return 0;
7768 LLVM_FALLTHROUGH;
7769 case Instruction::ZExt:
7770 case Instruction::SExt:
7771 case Instruction::FPToUI:
7772 case Instruction::FPToSI:
7773 case Instruction::FPExt:
7774 case Instruction::PtrToInt:
7775 case Instruction::IntToPtr:
7776 case Instruction::SIToFP:
7777 case Instruction::UIToFP:
7778 case Instruction::Trunc:
7779 case Instruction::FPTrunc: {
7780 // Computes the CastContextHint from a Load/Store instruction.
7781 auto ComputeCCH = [&](Instruction *I) -> TTI::CastContextHint {
7782 assert((isa<LoadInst>(I) || isa<StoreInst>(I)) &&
7783 "Expected a load or a store!");
7784
7785 if (VF.isScalar() || !TheLoop->contains(I))
7786 return TTI::CastContextHint::Normal;
7787
7788 switch (getWideningDecision(I, VF)) {
7789 case LoopVectorizationCostModel::CM_GatherScatter:
7790 return TTI::CastContextHint::GatherScatter;
7791 case LoopVectorizationCostModel::CM_Interleave:
7792 return TTI::CastContextHint::Interleave;
7793 case LoopVectorizationCostModel::CM_Scalarize:
7794 case LoopVectorizationCostModel::CM_Widen:
7795 return Legal->isMaskRequired(I) ? TTI::CastContextHint::Masked
7796 : TTI::CastContextHint::Normal;
7797 case LoopVectorizationCostModel::CM_Widen_Reverse:
7798 return TTI::CastContextHint::Reversed;
7799 case LoopVectorizationCostModel::CM_Unknown:
7800 llvm_unreachable("Instr did not go through cost modelling?");
7801 }
7802
7803 llvm_unreachable("Unhandled case!");
7804 };
7805
7806 unsigned Opcode = I->getOpcode();
7807 TTI::CastContextHint CCH = TTI::CastContextHint::None;
7808 // For Trunc, the context is the only user, which must be a StoreInst.
7809 if (Opcode == Instruction::Trunc || Opcode == Instruction::FPTrunc) {
7810 if (I->hasOneUse())
7811 if (StoreInst *Store = dyn_cast<StoreInst>(*I->user_begin()))
7812 CCH = ComputeCCH(Store);
7813 }
7814 // For Z/Sext, the context is the operand, which must be a LoadInst.
7815 else if (Opcode == Instruction::ZExt || Opcode == Instruction::SExt ||
7816 Opcode == Instruction::FPExt) {
7817 if (LoadInst *Load = dyn_cast<LoadInst>(I->getOperand(0)))
7818 CCH = ComputeCCH(Load);
7819 }
7820
7821 // We optimize the truncation of induction variables having constant
7822 // integer steps. The cost of these truncations is the same as the scalar
7823 // operation.
7824 if (isOptimizableIVTruncate(I, VF)) {
7825 auto *Trunc = cast<TruncInst>(I);
7826 return TTI.getCastInstrCost(Instruction::Trunc, Trunc->getDestTy(),
7827 Trunc->getSrcTy(), CCH, CostKind, Trunc);
7828 }
7829
7830 // Detect reduction patterns
7831 if (auto RedCost = getReductionPatternCost(I, VF, VectorTy, CostKind))
7832 return *RedCost;
7833
7834 Type *SrcScalarTy = I->getOperand(0)->getType();
7835 Type *SrcVecTy =
7836 VectorTy->isVectorTy() ? ToVectorTy(SrcScalarTy, VF) : SrcScalarTy;
7837 if (canTruncateToMinimalBitwidth(I, VF)) {
7838 // This cast is going to be shrunk. This may remove the cast or it might
7839 // turn it into slightly different cast. For example, if MinBW == 16,
7840 // "zext i8 %1 to i32" becomes "zext i8 %1 to i16".
7841 //
7842 // Calculate the modified src and dest types.
7843 Type *MinVecTy = VectorTy;
7844 if (Opcode == Instruction::Trunc) {
7845 SrcVecTy = smallestIntegerVectorType(SrcVecTy, MinVecTy);
7846 VectorTy =
7847 largestIntegerVectorType(ToVectorTy(I->getType(), VF), MinVecTy);
7848 } else if (Opcode == Instruction::ZExt || Opcode == Instruction::SExt) {
7849 SrcVecTy = largestIntegerVectorType(SrcVecTy, MinVecTy);
7850 VectorTy =
7851 smallestIntegerVectorType(ToVectorTy(I->getType(), VF), MinVecTy);
7852 }
7853 }
7854
7855 return TTI.getCastInstrCost(Opcode, VectorTy, SrcVecTy, CCH, CostKind, I);
7856 }
7857 case Instruction::Call: {
7858 bool NeedToScalarize;
7859 CallInst *CI = cast<CallInst>(I);
7860 InstructionCost CallCost = getVectorCallCost(CI, VF, NeedToScalarize);
7861 if (getVectorIntrinsicIDForCall(CI, TLI)) {
7862 InstructionCost IntrinsicCost = getVectorIntrinsicCost(CI, VF);
7863 return std::min(CallCost, IntrinsicCost);
7864 }
7865 return CallCost;
7866 }
7867 case Instruction::ExtractValue:
7868 return TTI.getInstructionCost(I, TTI::TCK_RecipThroughput);
7869 case Instruction::Alloca:
7870 // We cannot easily widen alloca to a scalable alloca, as
7871 // the result would need to be a vector of pointers.
7872 if (VF.isScalable())
7873 return InstructionCost::getInvalid();
7874 LLVM_FALLTHROUGH;
7875 default:
7876 // This opcode is unknown. Assume that it is the same as 'mul'.
7877 return TTI.getArithmeticInstrCost(Instruction::Mul, VectorTy, CostKind);
7878 } // end of switch.
7879 }
7880
7881 char LoopVectorize::ID = 0;
7882
7883 static const char lv_name[] = "Loop Vectorization";
7884
7885 INITIALIZE_PASS_BEGIN(LoopVectorize, LV_NAME, lv_name, false, false)
7886 INITIALIZE_PASS_DEPENDENCY(TargetTransformInfoWrapperPass)
7887 INITIALIZE_PASS_DEPENDENCY(BasicAAWrapperPass)
7888 INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass)
7889 INITIALIZE_PASS_DEPENDENCY(GlobalsAAWrapperPass)
7890 INITIALIZE_PASS_DEPENDENCY(AssumptionCacheTracker)
7891 INITIALIZE_PASS_DEPENDENCY(BlockFrequencyInfoWrapperPass)
7892 INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass)
7893 INITIALIZE_PASS_DEPENDENCY(ScalarEvolutionWrapperPass)
7894 INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass)
7895 INITIALIZE_PASS_DEPENDENCY(LoopAccessLegacyAnalysis)
7896 INITIALIZE_PASS_DEPENDENCY(DemandedBitsWrapperPass)
7897 INITIALIZE_PASS_DEPENDENCY(OptimizationRemarkEmitterWrapperPass)
7898 INITIALIZE_PASS_DEPENDENCY(ProfileSummaryInfoWrapperPass)
7899 INITIALIZE_PASS_DEPENDENCY(InjectTLIMappingsLegacy)
7900 INITIALIZE_PASS_END(LoopVectorize, LV_NAME, lv_name, false, false)
7901
7902 namespace llvm {
7903
createLoopVectorizePass()7904 Pass *createLoopVectorizePass() { return new LoopVectorize(); }
7905
createLoopVectorizePass(bool InterleaveOnlyWhenForced,bool VectorizeOnlyWhenForced)7906 Pass *createLoopVectorizePass(bool InterleaveOnlyWhenForced,
7907 bool VectorizeOnlyWhenForced) {
7908 return new LoopVectorize(InterleaveOnlyWhenForced, VectorizeOnlyWhenForced);
7909 }
7910
7911 } // end namespace llvm
7912
isConsecutiveLoadOrStore(Instruction * Inst)7913 bool LoopVectorizationCostModel::isConsecutiveLoadOrStore(Instruction *Inst) {
7914 // Check if the pointer operand of a load or store instruction is
7915 // consecutive.
7916 if (auto *Ptr = getLoadStorePointerOperand(Inst))
7917 return Legal->isConsecutivePtr(Ptr);
7918 return false;
7919 }
7920
collectValuesToIgnore()7921 void LoopVectorizationCostModel::collectValuesToIgnore() {
7922 // Ignore ephemeral values.
7923 CodeMetrics::collectEphemeralValues(TheLoop, AC, ValuesToIgnore);
7924
7925 // Ignore type-promoting instructions we identified during reduction
7926 // detection.
7927 for (auto &Reduction : Legal->getReductionVars()) {
7928 RecurrenceDescriptor &RedDes = Reduction.second;
7929 const SmallPtrSetImpl<Instruction *> &Casts = RedDes.getCastInsts();
7930 VecValuesToIgnore.insert(Casts.begin(), Casts.end());
7931 }
7932 // Ignore type-casting instructions we identified during induction
7933 // detection.
7934 for (auto &Induction : Legal->getInductionVars()) {
7935 InductionDescriptor &IndDes = Induction.second;
7936 const SmallVectorImpl<Instruction *> &Casts = IndDes.getCastInsts();
7937 VecValuesToIgnore.insert(Casts.begin(), Casts.end());
7938 }
7939 }
7940
collectInLoopReductions()7941 void LoopVectorizationCostModel::collectInLoopReductions() {
7942 for (auto &Reduction : Legal->getReductionVars()) {
7943 PHINode *Phi = Reduction.first;
7944 RecurrenceDescriptor &RdxDesc = Reduction.second;
7945
7946 // We don't collect reductions that are type promoted (yet).
7947 if (RdxDesc.getRecurrenceType() != Phi->getType())
7948 continue;
7949
7950 // If the target would prefer this reduction to happen "in-loop", then we
7951 // want to record it as such.
7952 unsigned Opcode = RdxDesc.getOpcode();
7953 if (!PreferInLoopReductions && !useOrderedReductions(RdxDesc) &&
7954 !TTI.preferInLoopReduction(Opcode, Phi->getType(),
7955 TargetTransformInfo::ReductionFlags()))
7956 continue;
7957
7958 // Check that we can correctly put the reductions into the loop, by
7959 // finding the chain of operations that leads from the phi to the loop
7960 // exit value.
7961 SmallVector<Instruction *, 4> ReductionOperations =
7962 RdxDesc.getReductionOpChain(Phi, TheLoop);
7963 bool InLoop = !ReductionOperations.empty();
7964 if (InLoop) {
7965 InLoopReductionChains[Phi] = ReductionOperations;
7966 // Add the elements to InLoopReductionImmediateChains for cost modelling.
7967 Instruction *LastChain = Phi;
7968 for (auto *I : ReductionOperations) {
7969 InLoopReductionImmediateChains[I] = LastChain;
7970 LastChain = I;
7971 }
7972 }
7973 LLVM_DEBUG(dbgs() << "LV: Using " << (InLoop ? "inloop" : "out of loop")
7974 << " reduction for phi: " << *Phi << "\n");
7975 }
7976 }
7977
7978 // TODO: we could return a pair of values that specify the max VF and
7979 // min VF, to be used in `buildVPlans(MinVF, MaxVF)` instead of
7980 // `buildVPlans(VF, VF)`. We cannot do it because VPLAN at the moment
7981 // doesn't have a cost model that can choose which plan to execute if
7982 // more than one is generated.
determineVPlanVF(const unsigned WidestVectorRegBits,LoopVectorizationCostModel & CM)7983 static unsigned determineVPlanVF(const unsigned WidestVectorRegBits,
7984 LoopVectorizationCostModel &CM) {
7985 unsigned WidestType;
7986 std::tie(std::ignore, WidestType) = CM.getSmallestAndWidestTypes();
7987 return WidestVectorRegBits / WidestType;
7988 }
7989
7990 VectorizationFactor
planInVPlanNativePath(ElementCount UserVF)7991 LoopVectorizationPlanner::planInVPlanNativePath(ElementCount UserVF) {
7992 assert(!UserVF.isScalable() && "scalable vectors not yet supported");
7993 ElementCount VF = UserVF;
7994 // Outer loop handling: They may require CFG and instruction level
7995 // transformations before even evaluating whether vectorization is profitable.
7996 // Since we cannot modify the incoming IR, we need to build VPlan upfront in
7997 // the vectorization pipeline.
7998 if (!OrigLoop->isInnermost()) {
7999 // If the user doesn't provide a vectorization factor, determine a
8000 // reasonable one.
8001 if (UserVF.isZero()) {
8002 VF = ElementCount::getFixed(determineVPlanVF(
8003 TTI->getRegisterBitWidth(TargetTransformInfo::RGK_FixedWidthVector)
8004 .getFixedSize(),
8005 CM));
8006 LLVM_DEBUG(dbgs() << "LV: VPlan computed VF " << VF << ".\n");
8007
8008 // Make sure we have a VF > 1 for stress testing.
8009 if (VPlanBuildStressTest && (VF.isScalar() || VF.isZero())) {
8010 LLVM_DEBUG(dbgs() << "LV: VPlan stress testing: "
8011 << "overriding computed VF.\n");
8012 VF = ElementCount::getFixed(4);
8013 }
8014 }
8015 assert(EnableVPlanNativePath && "VPlan-native path is not enabled.");
8016 assert(isPowerOf2_32(VF.getKnownMinValue()) &&
8017 "VF needs to be a power of two");
8018 LLVM_DEBUG(dbgs() << "LV: Using " << (!UserVF.isZero() ? "user " : "")
8019 << "VF " << VF << " to build VPlans.\n");
8020 buildVPlans(VF, VF);
8021
8022 // For VPlan build stress testing, we bail out after VPlan construction.
8023 if (VPlanBuildStressTest)
8024 return VectorizationFactor::Disabled();
8025
8026 return {VF, 0 /*Cost*/};
8027 }
8028
8029 LLVM_DEBUG(
8030 dbgs() << "LV: Not vectorizing. Inner loops aren't supported in the "
8031 "VPlan-native path.\n");
8032 return VectorizationFactor::Disabled();
8033 }
8034
8035 Optional<VectorizationFactor>
plan(ElementCount UserVF,unsigned UserIC)8036 LoopVectorizationPlanner::plan(ElementCount UserVF, unsigned UserIC) {
8037 assert(OrigLoop->isInnermost() && "Inner loop expected.");
8038 FixedScalableVFPair MaxFactors = CM.computeMaxVF(UserVF, UserIC);
8039 if (!MaxFactors) // Cases that should not to be vectorized nor interleaved.
8040 return None;
8041
8042 // Invalidate interleave groups if all blocks of loop will be predicated.
8043 if (CM.blockNeedsPredication(OrigLoop->getHeader()) &&
8044 !useMaskedInterleavedAccesses(*TTI)) {
8045 LLVM_DEBUG(
8046 dbgs()
8047 << "LV: Invalidate all interleaved groups due to fold-tail by masking "
8048 "which requires masked-interleaved support.\n");
8049 if (CM.InterleaveInfo.invalidateGroups())
8050 // Invalidating interleave groups also requires invalidating all decisions
8051 // based on them, which includes widening decisions and uniform and scalar
8052 // values.
8053 CM.invalidateCostModelingDecisions();
8054 }
8055
8056 ElementCount MaxUserVF =
8057 UserVF.isScalable() ? MaxFactors.ScalableVF : MaxFactors.FixedVF;
8058 bool UserVFIsLegal = ElementCount::isKnownLE(UserVF, MaxUserVF);
8059 if (!UserVF.isZero() && UserVFIsLegal) {
8060 assert(isPowerOf2_32(UserVF.getKnownMinValue()) &&
8061 "VF needs to be a power of two");
8062 // Collect the instructions (and their associated costs) that will be more
8063 // profitable to scalarize.
8064 if (CM.selectUserVectorizationFactor(UserVF)) {
8065 LLVM_DEBUG(dbgs() << "LV: Using user VF " << UserVF << ".\n");
8066 CM.collectInLoopReductions();
8067 buildVPlansWithVPRecipes(UserVF, UserVF);
8068 LLVM_DEBUG(printPlans(dbgs()));
8069 return {{UserVF, 0}};
8070 } else
8071 reportVectorizationInfo("UserVF ignored because of invalid costs.",
8072 "InvalidCost", ORE, OrigLoop);
8073 }
8074
8075 // Populate the set of Vectorization Factor Candidates.
8076 ElementCountSet VFCandidates;
8077 for (auto VF = ElementCount::getFixed(1);
8078 ElementCount::isKnownLE(VF, MaxFactors.FixedVF); VF *= 2)
8079 VFCandidates.insert(VF);
8080 for (auto VF = ElementCount::getScalable(1);
8081 ElementCount::isKnownLE(VF, MaxFactors.ScalableVF); VF *= 2)
8082 VFCandidates.insert(VF);
8083
8084 for (const auto &VF : VFCandidates) {
8085 // Collect Uniform and Scalar instructions after vectorization with VF.
8086 CM.collectUniformsAndScalars(VF);
8087
8088 // Collect the instructions (and their associated costs) that will be more
8089 // profitable to scalarize.
8090 if (VF.isVector())
8091 CM.collectInstsToScalarize(VF);
8092 }
8093
8094 CM.collectInLoopReductions();
8095 buildVPlansWithVPRecipes(ElementCount::getFixed(1), MaxFactors.FixedVF);
8096 buildVPlansWithVPRecipes(ElementCount::getScalable(1), MaxFactors.ScalableVF);
8097
8098 LLVM_DEBUG(printPlans(dbgs()));
8099 if (!MaxFactors.hasVector())
8100 return VectorizationFactor::Disabled();
8101
8102 // Select the optimal vectorization factor.
8103 auto SelectedVF = CM.selectVectorizationFactor(VFCandidates);
8104
8105 // Check if it is profitable to vectorize with runtime checks.
8106 unsigned NumRuntimePointerChecks = Requirements.getNumRuntimePointerChecks();
8107 if (SelectedVF.Width.getKnownMinValue() > 1 && NumRuntimePointerChecks) {
8108 bool PragmaThresholdReached =
8109 NumRuntimePointerChecks > PragmaVectorizeMemoryCheckThreshold;
8110 bool ThresholdReached =
8111 NumRuntimePointerChecks > VectorizerParams::RuntimeMemoryCheckThreshold;
8112 if ((ThresholdReached && !Hints.allowReordering()) ||
8113 PragmaThresholdReached) {
8114 ORE->emit([&]() {
8115 return OptimizationRemarkAnalysisAliasing(
8116 DEBUG_TYPE, "CantReorderMemOps", OrigLoop->getStartLoc(),
8117 OrigLoop->getHeader())
8118 << "loop not vectorized: cannot prove it is safe to reorder "
8119 "memory operations";
8120 });
8121 LLVM_DEBUG(dbgs() << "LV: Too many memory checks needed.\n");
8122 Hints.emitRemarkWithHints();
8123 return VectorizationFactor::Disabled();
8124 }
8125 }
8126 return SelectedVF;
8127 }
8128
setBestPlan(ElementCount VF,unsigned UF)8129 void LoopVectorizationPlanner::setBestPlan(ElementCount VF, unsigned UF) {
8130 LLVM_DEBUG(dbgs() << "Setting best plan to VF=" << VF << ", UF=" << UF
8131 << '\n');
8132 BestVF = VF;
8133 BestUF = UF;
8134
8135 erase_if(VPlans, [VF](const VPlanPtr &Plan) {
8136 return !Plan->hasVF(VF);
8137 });
8138 assert(VPlans.size() == 1 && "Best VF has not a single VPlan.");
8139 }
8140
executePlan(InnerLoopVectorizer & ILV,DominatorTree * DT)8141 void LoopVectorizationPlanner::executePlan(InnerLoopVectorizer &ILV,
8142 DominatorTree *DT) {
8143 // Perform the actual loop transformation.
8144
8145 // 1. Create a new empty loop. Unlink the old loop and connect the new one.
8146 assert(BestVF.hasValue() && "Vectorization Factor is missing");
8147 assert(VPlans.size() == 1 && "Not a single VPlan to execute.");
8148
8149 VPTransformState State{
8150 *BestVF, BestUF, LI, DT, ILV.Builder, &ILV, VPlans.front().get()};
8151 State.CFG.PrevBB = ILV.createVectorizedLoopSkeleton();
8152 State.TripCount = ILV.getOrCreateTripCount(nullptr);
8153 State.CanonicalIV = ILV.Induction;
8154
8155 ILV.printDebugTracesAtStart();
8156
8157 //===------------------------------------------------===//
8158 //
8159 // Notice: any optimization or new instruction that go
8160 // into the code below should also be implemented in
8161 // the cost-model.
8162 //
8163 //===------------------------------------------------===//
8164
8165 // 2. Copy and widen instructions from the old loop into the new loop.
8166 VPlans.front()->execute(&State);
8167
8168 // 3. Fix the vectorized code: take care of header phi's, live-outs,
8169 // predication, updating analyses.
8170 ILV.fixVectorizedLoop(State);
8171
8172 ILV.printDebugTracesAtEnd();
8173 }
8174
8175 #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
printPlans(raw_ostream & O)8176 void LoopVectorizationPlanner::printPlans(raw_ostream &O) {
8177 for (const auto &Plan : VPlans)
8178 if (PrintVPlansInDotFormat)
8179 Plan->printDOT(O);
8180 else
8181 Plan->print(O);
8182 }
8183 #endif
8184
collectTriviallyDeadInstructions(SmallPtrSetImpl<Instruction * > & DeadInstructions)8185 void LoopVectorizationPlanner::collectTriviallyDeadInstructions(
8186 SmallPtrSetImpl<Instruction *> &DeadInstructions) {
8187
8188 // We create new control-flow for the vectorized loop, so the original exit
8189 // conditions will be dead after vectorization if it's only used by the
8190 // terminator
8191 SmallVector<BasicBlock*> ExitingBlocks;
8192 OrigLoop->getExitingBlocks(ExitingBlocks);
8193 for (auto *BB : ExitingBlocks) {
8194 auto *Cmp = dyn_cast<Instruction>(BB->getTerminator()->getOperand(0));
8195 if (!Cmp || !Cmp->hasOneUse())
8196 continue;
8197
8198 // TODO: we should introduce a getUniqueExitingBlocks on Loop
8199 if (!DeadInstructions.insert(Cmp).second)
8200 continue;
8201
8202 // The operands of the icmp is often a dead trunc, used by IndUpdate.
8203 // TODO: can recurse through operands in general
8204 for (Value *Op : Cmp->operands()) {
8205 if (isa<TruncInst>(Op) && Op->hasOneUse())
8206 DeadInstructions.insert(cast<Instruction>(Op));
8207 }
8208 }
8209
8210 // We create new "steps" for induction variable updates to which the original
8211 // induction variables map. An original update instruction will be dead if
8212 // all its users except the induction variable are dead.
8213 auto *Latch = OrigLoop->getLoopLatch();
8214 for (auto &Induction : Legal->getInductionVars()) {
8215 PHINode *Ind = Induction.first;
8216 auto *IndUpdate = cast<Instruction>(Ind->getIncomingValueForBlock(Latch));
8217
8218 // If the tail is to be folded by masking, the primary induction variable,
8219 // if exists, isn't dead: it will be used for masking. Don't kill it.
8220 if (CM.foldTailByMasking() && IndUpdate == Legal->getPrimaryInduction())
8221 continue;
8222
8223 if (llvm::all_of(IndUpdate->users(), [&](User *U) -> bool {
8224 return U == Ind || DeadInstructions.count(cast<Instruction>(U));
8225 }))
8226 DeadInstructions.insert(IndUpdate);
8227
8228 // We record as "Dead" also the type-casting instructions we had identified
8229 // during induction analysis. We don't need any handling for them in the
8230 // vectorized loop because we have proven that, under a proper runtime
8231 // test guarding the vectorized loop, the value of the phi, and the casted
8232 // value of the phi, are the same. The last instruction in this casting chain
8233 // will get its scalar/vector/widened def from the scalar/vector/widened def
8234 // of the respective phi node. Any other casts in the induction def-use chain
8235 // have no other uses outside the phi update chain, and will be ignored.
8236 InductionDescriptor &IndDes = Induction.second;
8237 const SmallVectorImpl<Instruction *> &Casts = IndDes.getCastInsts();
8238 DeadInstructions.insert(Casts.begin(), Casts.end());
8239 }
8240 }
8241
reverseVector(Value * Vec)8242 Value *InnerLoopUnroller::reverseVector(Value *Vec) { return Vec; }
8243
getBroadcastInstrs(Value * V)8244 Value *InnerLoopUnroller::getBroadcastInstrs(Value *V) { return V; }
8245
getStepVector(Value * Val,int StartIdx,Value * Step,Instruction::BinaryOps BinOp)8246 Value *InnerLoopUnroller::getStepVector(Value *Val, int StartIdx, Value *Step,
8247 Instruction::BinaryOps BinOp) {
8248 // When unrolling and the VF is 1, we only need to add a simple scalar.
8249 Type *Ty = Val->getType();
8250 assert(!Ty->isVectorTy() && "Val must be a scalar");
8251
8252 if (Ty->isFloatingPointTy()) {
8253 Constant *C = ConstantFP::get(Ty, (double)StartIdx);
8254
8255 // Floating-point operations inherit FMF via the builder's flags.
8256 Value *MulOp = Builder.CreateFMul(C, Step);
8257 return Builder.CreateBinOp(BinOp, Val, MulOp);
8258 }
8259 Constant *C = ConstantInt::get(Ty, StartIdx);
8260 return Builder.CreateAdd(Val, Builder.CreateMul(C, Step), "induction");
8261 }
8262
AddRuntimeUnrollDisableMetaData(Loop * L)8263 static void AddRuntimeUnrollDisableMetaData(Loop *L) {
8264 SmallVector<Metadata *, 4> MDs;
8265 // Reserve first location for self reference to the LoopID metadata node.
8266 MDs.push_back(nullptr);
8267 bool IsUnrollMetadata = false;
8268 MDNode *LoopID = L->getLoopID();
8269 if (LoopID) {
8270 // First find existing loop unrolling disable metadata.
8271 for (unsigned i = 1, ie = LoopID->getNumOperands(); i < ie; ++i) {
8272 auto *MD = dyn_cast<MDNode>(LoopID->getOperand(i));
8273 if (MD) {
8274 const auto *S = dyn_cast<MDString>(MD->getOperand(0));
8275 IsUnrollMetadata =
8276 S && S->getString().startswith("llvm.loop.unroll.disable");
8277 }
8278 MDs.push_back(LoopID->getOperand(i));
8279 }
8280 }
8281
8282 if (!IsUnrollMetadata) {
8283 // Add runtime unroll disable metadata.
8284 LLVMContext &Context = L->getHeader()->getContext();
8285 SmallVector<Metadata *, 1> DisableOperands;
8286 DisableOperands.push_back(
8287 MDString::get(Context, "llvm.loop.unroll.runtime.disable"));
8288 MDNode *DisableNode = MDNode::get(Context, DisableOperands);
8289 MDs.push_back(DisableNode);
8290 MDNode *NewLoopID = MDNode::get(Context, MDs);
8291 // Set operand 0 to refer to the loop id itself.
8292 NewLoopID->replaceOperandWith(0, NewLoopID);
8293 L->setLoopID(NewLoopID);
8294 }
8295 }
8296
8297 //===--------------------------------------------------------------------===//
8298 // EpilogueVectorizerMainLoop
8299 //===--------------------------------------------------------------------===//
8300
8301 /// This function is partially responsible for generating the control flow
8302 /// depicted in https://llvm.org/docs/Vectorizers.html#epilogue-vectorization.
createEpilogueVectorizedLoopSkeleton()8303 BasicBlock *EpilogueVectorizerMainLoop::createEpilogueVectorizedLoopSkeleton() {
8304 MDNode *OrigLoopID = OrigLoop->getLoopID();
8305 Loop *Lp = createVectorLoopSkeleton("");
8306
8307 // Generate the code to check the minimum iteration count of the vector
8308 // epilogue (see below).
8309 EPI.EpilogueIterationCountCheck =
8310 emitMinimumIterationCountCheck(Lp, LoopScalarPreHeader, true);
8311 EPI.EpilogueIterationCountCheck->setName("iter.check");
8312
8313 // Generate the code to check any assumptions that we've made for SCEV
8314 // expressions.
8315 EPI.SCEVSafetyCheck = emitSCEVChecks(Lp, LoopScalarPreHeader);
8316
8317 // Generate the code that checks at runtime if arrays overlap. We put the
8318 // checks into a separate block to make the more common case of few elements
8319 // faster.
8320 EPI.MemSafetyCheck = emitMemRuntimeChecks(Lp, LoopScalarPreHeader);
8321
8322 // Generate the iteration count check for the main loop, *after* the check
8323 // for the epilogue loop, so that the path-length is shorter for the case
8324 // that goes directly through the vector epilogue. The longer-path length for
8325 // the main loop is compensated for, by the gain from vectorizing the larger
8326 // trip count. Note: the branch will get updated later on when we vectorize
8327 // the epilogue.
8328 EPI.MainLoopIterationCountCheck =
8329 emitMinimumIterationCountCheck(Lp, LoopScalarPreHeader, false);
8330
8331 // Generate the induction variable.
8332 OldInduction = Legal->getPrimaryInduction();
8333 Type *IdxTy = Legal->getWidestInductionType();
8334 Value *StartIdx = ConstantInt::get(IdxTy, 0);
8335 Constant *Step = ConstantInt::get(IdxTy, VF.getKnownMinValue() * UF);
8336 Value *CountRoundDown = getOrCreateVectorTripCount(Lp);
8337 EPI.VectorTripCount = CountRoundDown;
8338 Induction =
8339 createInductionVariable(Lp, StartIdx, CountRoundDown, Step,
8340 getDebugLocFromInstOrOperands(OldInduction));
8341
8342 // Skip induction resume value creation here because they will be created in
8343 // the second pass. If we created them here, they wouldn't be used anyway,
8344 // because the vplan in the second pass still contains the inductions from the
8345 // original loop.
8346
8347 return completeLoopSkeleton(Lp, OrigLoopID);
8348 }
8349
printDebugTracesAtStart()8350 void EpilogueVectorizerMainLoop::printDebugTracesAtStart() {
8351 LLVM_DEBUG({
8352 dbgs() << "Create Skeleton for epilogue vectorized loop (first pass)\n"
8353 << "Main Loop VF:" << EPI.MainLoopVF.getKnownMinValue()
8354 << ", Main Loop UF:" << EPI.MainLoopUF
8355 << ", Epilogue Loop VF:" << EPI.EpilogueVF.getKnownMinValue()
8356 << ", Epilogue Loop UF:" << EPI.EpilogueUF << "\n";
8357 });
8358 }
8359
printDebugTracesAtEnd()8360 void EpilogueVectorizerMainLoop::printDebugTracesAtEnd() {
8361 DEBUG_WITH_TYPE(VerboseDebug, {
8362 dbgs() << "intermediate fn:\n" << *Induction->getFunction() << "\n";
8363 });
8364 }
8365
emitMinimumIterationCountCheck(Loop * L,BasicBlock * Bypass,bool ForEpilogue)8366 BasicBlock *EpilogueVectorizerMainLoop::emitMinimumIterationCountCheck(
8367 Loop *L, BasicBlock *Bypass, bool ForEpilogue) {
8368 assert(L && "Expected valid Loop.");
8369 assert(Bypass && "Expected valid bypass basic block.");
8370 unsigned VFactor =
8371 ForEpilogue ? EPI.EpilogueVF.getKnownMinValue() : VF.getKnownMinValue();
8372 unsigned UFactor = ForEpilogue ? EPI.EpilogueUF : UF;
8373 Value *Count = getOrCreateTripCount(L);
8374 // Reuse existing vector loop preheader for TC checks.
8375 // Note that new preheader block is generated for vector loop.
8376 BasicBlock *const TCCheckBlock = LoopVectorPreHeader;
8377 IRBuilder<> Builder(TCCheckBlock->getTerminator());
8378
8379 // Generate code to check if the loop's trip count is less than VF * UF of the
8380 // main vector loop.
8381 auto P = Cost->requiresScalarEpilogue(ForEpilogue ? EPI.EpilogueVF : VF) ?
8382 ICmpInst::ICMP_ULE : ICmpInst::ICMP_ULT;
8383
8384 Value *CheckMinIters = Builder.CreateICmp(
8385 P, Count, ConstantInt::get(Count->getType(), VFactor * UFactor),
8386 "min.iters.check");
8387
8388 if (!ForEpilogue)
8389 TCCheckBlock->setName("vector.main.loop.iter.check");
8390
8391 // Create new preheader for vector loop.
8392 LoopVectorPreHeader = SplitBlock(TCCheckBlock, TCCheckBlock->getTerminator(),
8393 DT, LI, nullptr, "vector.ph");
8394
8395 if (ForEpilogue) {
8396 assert(DT->properlyDominates(DT->getNode(TCCheckBlock),
8397 DT->getNode(Bypass)->getIDom()) &&
8398 "TC check is expected to dominate Bypass");
8399
8400 // Update dominator for Bypass & LoopExit.
8401 DT->changeImmediateDominator(Bypass, TCCheckBlock);
8402 if (!Cost->requiresScalarEpilogue(EPI.EpilogueVF))
8403 // For loops with multiple exits, there's no edge from the middle block
8404 // to exit blocks (as the epilogue must run) and thus no need to update
8405 // the immediate dominator of the exit blocks.
8406 DT->changeImmediateDominator(LoopExitBlock, TCCheckBlock);
8407
8408 LoopBypassBlocks.push_back(TCCheckBlock);
8409
8410 // Save the trip count so we don't have to regenerate it in the
8411 // vec.epilog.iter.check. This is safe to do because the trip count
8412 // generated here dominates the vector epilog iter check.
8413 EPI.TripCount = Count;
8414 }
8415
8416 ReplaceInstWithInst(
8417 TCCheckBlock->getTerminator(),
8418 BranchInst::Create(Bypass, LoopVectorPreHeader, CheckMinIters));
8419
8420 return TCCheckBlock;
8421 }
8422
8423 //===--------------------------------------------------------------------===//
8424 // EpilogueVectorizerEpilogueLoop
8425 //===--------------------------------------------------------------------===//
8426
8427 /// This function is partially responsible for generating the control flow
8428 /// depicted in https://llvm.org/docs/Vectorizers.html#epilogue-vectorization.
8429 BasicBlock *
createEpilogueVectorizedLoopSkeleton()8430 EpilogueVectorizerEpilogueLoop::createEpilogueVectorizedLoopSkeleton() {
8431 MDNode *OrigLoopID = OrigLoop->getLoopID();
8432 Loop *Lp = createVectorLoopSkeleton("vec.epilog.");
8433
8434 // Now, compare the remaining count and if there aren't enough iterations to
8435 // execute the vectorized epilogue skip to the scalar part.
8436 BasicBlock *VecEpilogueIterationCountCheck = LoopVectorPreHeader;
8437 VecEpilogueIterationCountCheck->setName("vec.epilog.iter.check");
8438 LoopVectorPreHeader =
8439 SplitBlock(LoopVectorPreHeader, LoopVectorPreHeader->getTerminator(), DT,
8440 LI, nullptr, "vec.epilog.ph");
8441 emitMinimumVectorEpilogueIterCountCheck(Lp, LoopScalarPreHeader,
8442 VecEpilogueIterationCountCheck);
8443
8444 // Adjust the control flow taking the state info from the main loop
8445 // vectorization into account.
8446 assert(EPI.MainLoopIterationCountCheck && EPI.EpilogueIterationCountCheck &&
8447 "expected this to be saved from the previous pass.");
8448 EPI.MainLoopIterationCountCheck->getTerminator()->replaceUsesOfWith(
8449 VecEpilogueIterationCountCheck, LoopVectorPreHeader);
8450
8451 DT->changeImmediateDominator(LoopVectorPreHeader,
8452 EPI.MainLoopIterationCountCheck);
8453
8454 EPI.EpilogueIterationCountCheck->getTerminator()->replaceUsesOfWith(
8455 VecEpilogueIterationCountCheck, LoopScalarPreHeader);
8456
8457 if (EPI.SCEVSafetyCheck)
8458 EPI.SCEVSafetyCheck->getTerminator()->replaceUsesOfWith(
8459 VecEpilogueIterationCountCheck, LoopScalarPreHeader);
8460 if (EPI.MemSafetyCheck)
8461 EPI.MemSafetyCheck->getTerminator()->replaceUsesOfWith(
8462 VecEpilogueIterationCountCheck, LoopScalarPreHeader);
8463
8464 DT->changeImmediateDominator(
8465 VecEpilogueIterationCountCheck,
8466 VecEpilogueIterationCountCheck->getSinglePredecessor());
8467
8468 DT->changeImmediateDominator(LoopScalarPreHeader,
8469 EPI.EpilogueIterationCountCheck);
8470 if (!Cost->requiresScalarEpilogue(EPI.EpilogueVF))
8471 // If there is an epilogue which must run, there's no edge from the
8472 // middle block to exit blocks and thus no need to update the immediate
8473 // dominator of the exit blocks.
8474 DT->changeImmediateDominator(LoopExitBlock,
8475 EPI.EpilogueIterationCountCheck);
8476
8477 // Keep track of bypass blocks, as they feed start values to the induction
8478 // phis in the scalar loop preheader.
8479 if (EPI.SCEVSafetyCheck)
8480 LoopBypassBlocks.push_back(EPI.SCEVSafetyCheck);
8481 if (EPI.MemSafetyCheck)
8482 LoopBypassBlocks.push_back(EPI.MemSafetyCheck);
8483 LoopBypassBlocks.push_back(EPI.EpilogueIterationCountCheck);
8484
8485 // Generate a resume induction for the vector epilogue and put it in the
8486 // vector epilogue preheader
8487 Type *IdxTy = Legal->getWidestInductionType();
8488 PHINode *EPResumeVal = PHINode::Create(IdxTy, 2, "vec.epilog.resume.val",
8489 LoopVectorPreHeader->getFirstNonPHI());
8490 EPResumeVal->addIncoming(EPI.VectorTripCount, VecEpilogueIterationCountCheck);
8491 EPResumeVal->addIncoming(ConstantInt::get(IdxTy, 0),
8492 EPI.MainLoopIterationCountCheck);
8493
8494 // Generate the induction variable.
8495 OldInduction = Legal->getPrimaryInduction();
8496 Value *CountRoundDown = getOrCreateVectorTripCount(Lp);
8497 Constant *Step = ConstantInt::get(IdxTy, VF.getKnownMinValue() * UF);
8498 Value *StartIdx = EPResumeVal;
8499 Induction =
8500 createInductionVariable(Lp, StartIdx, CountRoundDown, Step,
8501 getDebugLocFromInstOrOperands(OldInduction));
8502
8503 // Generate induction resume values. These variables save the new starting
8504 // indexes for the scalar loop. They are used to test if there are any tail
8505 // iterations left once the vector loop has completed.
8506 // Note that when the vectorized epilogue is skipped due to iteration count
8507 // check, then the resume value for the induction variable comes from
8508 // the trip count of the main vector loop, hence passing the AdditionalBypass
8509 // argument.
8510 createInductionResumeValues(Lp, CountRoundDown,
8511 {VecEpilogueIterationCountCheck,
8512 EPI.VectorTripCount} /* AdditionalBypass */);
8513
8514 AddRuntimeUnrollDisableMetaData(Lp);
8515 return completeLoopSkeleton(Lp, OrigLoopID);
8516 }
8517
8518 BasicBlock *
emitMinimumVectorEpilogueIterCountCheck(Loop * L,BasicBlock * Bypass,BasicBlock * Insert)8519 EpilogueVectorizerEpilogueLoop::emitMinimumVectorEpilogueIterCountCheck(
8520 Loop *L, BasicBlock *Bypass, BasicBlock *Insert) {
8521
8522 assert(EPI.TripCount &&
8523 "Expected trip count to have been safed in the first pass.");
8524 assert(
8525 (!isa<Instruction>(EPI.TripCount) ||
8526 DT->dominates(cast<Instruction>(EPI.TripCount)->getParent(), Insert)) &&
8527 "saved trip count does not dominate insertion point.");
8528 Value *TC = EPI.TripCount;
8529 IRBuilder<> Builder(Insert->getTerminator());
8530 Value *Count = Builder.CreateSub(TC, EPI.VectorTripCount, "n.vec.remaining");
8531
8532 // Generate code to check if the loop's trip count is less than VF * UF of the
8533 // vector epilogue loop.
8534 auto P = Cost->requiresScalarEpilogue(EPI.EpilogueVF) ?
8535 ICmpInst::ICMP_ULE : ICmpInst::ICMP_ULT;
8536
8537 Value *CheckMinIters = Builder.CreateICmp(
8538 P, Count,
8539 ConstantInt::get(Count->getType(),
8540 EPI.EpilogueVF.getKnownMinValue() * EPI.EpilogueUF),
8541 "min.epilog.iters.check");
8542
8543 ReplaceInstWithInst(
8544 Insert->getTerminator(),
8545 BranchInst::Create(Bypass, LoopVectorPreHeader, CheckMinIters));
8546
8547 LoopBypassBlocks.push_back(Insert);
8548 return Insert;
8549 }
8550
printDebugTracesAtStart()8551 void EpilogueVectorizerEpilogueLoop::printDebugTracesAtStart() {
8552 LLVM_DEBUG({
8553 dbgs() << "Create Skeleton for epilogue vectorized loop (second pass)\n"
8554 << "Epilogue Loop VF:" << EPI.EpilogueVF.getKnownMinValue()
8555 << ", Epilogue Loop UF:" << EPI.EpilogueUF << "\n";
8556 });
8557 }
8558
printDebugTracesAtEnd()8559 void EpilogueVectorizerEpilogueLoop::printDebugTracesAtEnd() {
8560 DEBUG_WITH_TYPE(VerboseDebug, {
8561 dbgs() << "final fn:\n" << *Induction->getFunction() << "\n";
8562 });
8563 }
8564
getDecisionAndClampRange(const std::function<bool (ElementCount)> & Predicate,VFRange & Range)8565 bool LoopVectorizationPlanner::getDecisionAndClampRange(
8566 const std::function<bool(ElementCount)> &Predicate, VFRange &Range) {
8567 assert(!Range.isEmpty() && "Trying to test an empty VF range.");
8568 bool PredicateAtRangeStart = Predicate(Range.Start);
8569
8570 for (ElementCount TmpVF = Range.Start * 2;
8571 ElementCount::isKnownLT(TmpVF, Range.End); TmpVF *= 2)
8572 if (Predicate(TmpVF) != PredicateAtRangeStart) {
8573 Range.End = TmpVF;
8574 break;
8575 }
8576
8577 return PredicateAtRangeStart;
8578 }
8579
8580 /// Build VPlans for the full range of feasible VF's = {\p MinVF, 2 * \p MinVF,
8581 /// 4 * \p MinVF, ..., \p MaxVF} by repeatedly building a VPlan for a sub-range
8582 /// of VF's starting at a given VF and extending it as much as possible. Each
8583 /// vectorization decision can potentially shorten this sub-range during
8584 /// buildVPlan().
buildVPlans(ElementCount MinVF,ElementCount MaxVF)8585 void LoopVectorizationPlanner::buildVPlans(ElementCount MinVF,
8586 ElementCount MaxVF) {
8587 auto MaxVFPlusOne = MaxVF.getWithIncrement(1);
8588 for (ElementCount VF = MinVF; ElementCount::isKnownLT(VF, MaxVFPlusOne);) {
8589 VFRange SubRange = {VF, MaxVFPlusOne};
8590 VPlans.push_back(buildVPlan(SubRange));
8591 VF = SubRange.End;
8592 }
8593 }
8594
createEdgeMask(BasicBlock * Src,BasicBlock * Dst,VPlanPtr & Plan)8595 VPValue *VPRecipeBuilder::createEdgeMask(BasicBlock *Src, BasicBlock *Dst,
8596 VPlanPtr &Plan) {
8597 assert(is_contained(predecessors(Dst), Src) && "Invalid edge");
8598
8599 // Look for cached value.
8600 std::pair<BasicBlock *, BasicBlock *> Edge(Src, Dst);
8601 EdgeMaskCacheTy::iterator ECEntryIt = EdgeMaskCache.find(Edge);
8602 if (ECEntryIt != EdgeMaskCache.end())
8603 return ECEntryIt->second;
8604
8605 VPValue *SrcMask = createBlockInMask(Src, Plan);
8606
8607 // The terminator has to be a branch inst!
8608 BranchInst *BI = dyn_cast<BranchInst>(Src->getTerminator());
8609 assert(BI && "Unexpected terminator found");
8610
8611 if (!BI->isConditional() || BI->getSuccessor(0) == BI->getSuccessor(1))
8612 return EdgeMaskCache[Edge] = SrcMask;
8613
8614 // If source is an exiting block, we know the exit edge is dynamically dead
8615 // in the vector loop, and thus we don't need to restrict the mask. Avoid
8616 // adding uses of an otherwise potentially dead instruction.
8617 if (OrigLoop->isLoopExiting(Src))
8618 return EdgeMaskCache[Edge] = SrcMask;
8619
8620 VPValue *EdgeMask = Plan->getOrAddVPValue(BI->getCondition());
8621 assert(EdgeMask && "No Edge Mask found for condition");
8622
8623 if (BI->getSuccessor(0) != Dst)
8624 EdgeMask = Builder.createNot(EdgeMask);
8625
8626 if (SrcMask) { // Otherwise block in-mask is all-one, no need to AND.
8627 // The condition is 'SrcMask && EdgeMask', which is equivalent to
8628 // 'select i1 SrcMask, i1 EdgeMask, i1 false'.
8629 // The select version does not introduce new UB if SrcMask is false and
8630 // EdgeMask is poison. Using 'and' here introduces undefined behavior.
8631 VPValue *False = Plan->getOrAddVPValue(
8632 ConstantInt::getFalse(BI->getCondition()->getType()));
8633 EdgeMask = Builder.createSelect(SrcMask, EdgeMask, False);
8634 }
8635
8636 return EdgeMaskCache[Edge] = EdgeMask;
8637 }
8638
createBlockInMask(BasicBlock * BB,VPlanPtr & Plan)8639 VPValue *VPRecipeBuilder::createBlockInMask(BasicBlock *BB, VPlanPtr &Plan) {
8640 assert(OrigLoop->contains(BB) && "Block is not a part of a loop");
8641
8642 // Look for cached value.
8643 BlockMaskCacheTy::iterator BCEntryIt = BlockMaskCache.find(BB);
8644 if (BCEntryIt != BlockMaskCache.end())
8645 return BCEntryIt->second;
8646
8647 // All-one mask is modelled as no-mask following the convention for masked
8648 // load/store/gather/scatter. Initialize BlockMask to no-mask.
8649 VPValue *BlockMask = nullptr;
8650
8651 if (OrigLoop->getHeader() == BB) {
8652 if (!CM.blockNeedsPredication(BB))
8653 return BlockMaskCache[BB] = BlockMask; // Loop incoming mask is all-one.
8654
8655 // Create the block in mask as the first non-phi instruction in the block.
8656 VPBuilder::InsertPointGuard Guard(Builder);
8657 auto NewInsertionPoint = Builder.getInsertBlock()->getFirstNonPhi();
8658 Builder.setInsertPoint(Builder.getInsertBlock(), NewInsertionPoint);
8659
8660 // Introduce the early-exit compare IV <= BTC to form header block mask.
8661 // This is used instead of IV < TC because TC may wrap, unlike BTC.
8662 // Start by constructing the desired canonical IV.
8663 VPValue *IV = nullptr;
8664 if (Legal->getPrimaryInduction())
8665 IV = Plan->getOrAddVPValue(Legal->getPrimaryInduction());
8666 else {
8667 auto IVRecipe = new VPWidenCanonicalIVRecipe();
8668 Builder.getInsertBlock()->insert(IVRecipe, NewInsertionPoint);
8669 IV = IVRecipe->getVPSingleValue();
8670 }
8671 VPValue *BTC = Plan->getOrCreateBackedgeTakenCount();
8672 bool TailFolded = !CM.isScalarEpilogueAllowed();
8673
8674 if (TailFolded && CM.TTI.emitGetActiveLaneMask()) {
8675 // While ActiveLaneMask is a binary op that consumes the loop tripcount
8676 // as a second argument, we only pass the IV here and extract the
8677 // tripcount from the transform state where codegen of the VP instructions
8678 // happen.
8679 BlockMask = Builder.createNaryOp(VPInstruction::ActiveLaneMask, {IV});
8680 } else {
8681 BlockMask = Builder.createNaryOp(VPInstruction::ICmpULE, {IV, BTC});
8682 }
8683 return BlockMaskCache[BB] = BlockMask;
8684 }
8685
8686 // This is the block mask. We OR all incoming edges.
8687 for (auto *Predecessor : predecessors(BB)) {
8688 VPValue *EdgeMask = createEdgeMask(Predecessor, BB, Plan);
8689 if (!EdgeMask) // Mask of predecessor is all-one so mask of block is too.
8690 return BlockMaskCache[BB] = EdgeMask;
8691
8692 if (!BlockMask) { // BlockMask has its initialized nullptr value.
8693 BlockMask = EdgeMask;
8694 continue;
8695 }
8696
8697 BlockMask = Builder.createOr(BlockMask, EdgeMask);
8698 }
8699
8700 return BlockMaskCache[BB] = BlockMask;
8701 }
8702
tryToWidenMemory(Instruction * I,ArrayRef<VPValue * > Operands,VFRange & Range,VPlanPtr & Plan)8703 VPRecipeBase *VPRecipeBuilder::tryToWidenMemory(Instruction *I,
8704 ArrayRef<VPValue *> Operands,
8705 VFRange &Range,
8706 VPlanPtr &Plan) {
8707 assert((isa<LoadInst>(I) || isa<StoreInst>(I)) &&
8708 "Must be called with either a load or store");
8709
8710 auto willWiden = [&](ElementCount VF) -> bool {
8711 if (VF.isScalar())
8712 return false;
8713 LoopVectorizationCostModel::InstWidening Decision =
8714 CM.getWideningDecision(I, VF);
8715 assert(Decision != LoopVectorizationCostModel::CM_Unknown &&
8716 "CM decision should be taken at this point.");
8717 if (Decision == LoopVectorizationCostModel::CM_Interleave)
8718 return true;
8719 if (CM.isScalarAfterVectorization(I, VF) ||
8720 CM.isProfitableToScalarize(I, VF))
8721 return false;
8722 return Decision != LoopVectorizationCostModel::CM_Scalarize;
8723 };
8724
8725 if (!LoopVectorizationPlanner::getDecisionAndClampRange(willWiden, Range))
8726 return nullptr;
8727
8728 VPValue *Mask = nullptr;
8729 if (Legal->isMaskRequired(I))
8730 Mask = createBlockInMask(I->getParent(), Plan);
8731
8732 if (LoadInst *Load = dyn_cast<LoadInst>(I))
8733 return new VPWidenMemoryInstructionRecipe(*Load, Operands[0], Mask);
8734
8735 StoreInst *Store = cast<StoreInst>(I);
8736 return new VPWidenMemoryInstructionRecipe(*Store, Operands[1], Operands[0],
8737 Mask);
8738 }
8739
8740 VPWidenIntOrFpInductionRecipe *
tryToOptimizeInductionPHI(PHINode * Phi,ArrayRef<VPValue * > Operands) const8741 VPRecipeBuilder::tryToOptimizeInductionPHI(PHINode *Phi,
8742 ArrayRef<VPValue *> Operands) const {
8743 // Check if this is an integer or fp induction. If so, build the recipe that
8744 // produces its scalar and vector values.
8745 InductionDescriptor II = Legal->getInductionVars().lookup(Phi);
8746 if (II.getKind() == InductionDescriptor::IK_IntInduction ||
8747 II.getKind() == InductionDescriptor::IK_FpInduction) {
8748 assert(II.getStartValue() ==
8749 Phi->getIncomingValueForBlock(OrigLoop->getLoopPreheader()));
8750 const SmallVectorImpl<Instruction *> &Casts = II.getCastInsts();
8751 return new VPWidenIntOrFpInductionRecipe(
8752 Phi, Operands[0], Casts.empty() ? nullptr : Casts.front());
8753 }
8754
8755 return nullptr;
8756 }
8757
tryToOptimizeInductionTruncate(TruncInst * I,ArrayRef<VPValue * > Operands,VFRange & Range,VPlan & Plan) const8758 VPWidenIntOrFpInductionRecipe *VPRecipeBuilder::tryToOptimizeInductionTruncate(
8759 TruncInst *I, ArrayRef<VPValue *> Operands, VFRange &Range,
8760 VPlan &Plan) const {
8761 // Optimize the special case where the source is a constant integer
8762 // induction variable. Notice that we can only optimize the 'trunc' case
8763 // because (a) FP conversions lose precision, (b) sext/zext may wrap, and
8764 // (c) other casts depend on pointer size.
8765
8766 // Determine whether \p K is a truncation based on an induction variable that
8767 // can be optimized.
8768 auto isOptimizableIVTruncate =
8769 [&](Instruction *K) -> std::function<bool(ElementCount)> {
8770 return [=](ElementCount VF) -> bool {
8771 return CM.isOptimizableIVTruncate(K, VF);
8772 };
8773 };
8774
8775 if (LoopVectorizationPlanner::getDecisionAndClampRange(
8776 isOptimizableIVTruncate(I), Range)) {
8777
8778 InductionDescriptor II =
8779 Legal->getInductionVars().lookup(cast<PHINode>(I->getOperand(0)));
8780 VPValue *Start = Plan.getOrAddVPValue(II.getStartValue());
8781 return new VPWidenIntOrFpInductionRecipe(cast<PHINode>(I->getOperand(0)),
8782 Start, nullptr, I);
8783 }
8784 return nullptr;
8785 }
8786
tryToBlend(PHINode * Phi,ArrayRef<VPValue * > Operands,VPlanPtr & Plan)8787 VPRecipeOrVPValueTy VPRecipeBuilder::tryToBlend(PHINode *Phi,
8788 ArrayRef<VPValue *> Operands,
8789 VPlanPtr &Plan) {
8790 // If all incoming values are equal, the incoming VPValue can be used directly
8791 // instead of creating a new VPBlendRecipe.
8792 VPValue *FirstIncoming = Operands[0];
8793 if (all_of(Operands, [FirstIncoming](const VPValue *Inc) {
8794 return FirstIncoming == Inc;
8795 })) {
8796 return Operands[0];
8797 }
8798
8799 // We know that all PHIs in non-header blocks are converted into selects, so
8800 // we don't have to worry about the insertion order and we can just use the
8801 // builder. At this point we generate the predication tree. There may be
8802 // duplications since this is a simple recursive scan, but future
8803 // optimizations will clean it up.
8804 SmallVector<VPValue *, 2> OperandsWithMask;
8805 unsigned NumIncoming = Phi->getNumIncomingValues();
8806
8807 for (unsigned In = 0; In < NumIncoming; In++) {
8808 VPValue *EdgeMask =
8809 createEdgeMask(Phi->getIncomingBlock(In), Phi->getParent(), Plan);
8810 assert((EdgeMask || NumIncoming == 1) &&
8811 "Multiple predecessors with one having a full mask");
8812 OperandsWithMask.push_back(Operands[In]);
8813 if (EdgeMask)
8814 OperandsWithMask.push_back(EdgeMask);
8815 }
8816 return toVPRecipeResult(new VPBlendRecipe(Phi, OperandsWithMask));
8817 }
8818
tryToWidenCall(CallInst * CI,ArrayRef<VPValue * > Operands,VFRange & Range) const8819 VPWidenCallRecipe *VPRecipeBuilder::tryToWidenCall(CallInst *CI,
8820 ArrayRef<VPValue *> Operands,
8821 VFRange &Range) const {
8822
8823 bool IsPredicated = LoopVectorizationPlanner::getDecisionAndClampRange(
8824 [this, CI](ElementCount VF) { return CM.isScalarWithPredication(CI); },
8825 Range);
8826
8827 if (IsPredicated)
8828 return nullptr;
8829
8830 Intrinsic::ID ID = getVectorIntrinsicIDForCall(CI, TLI);
8831 if (ID && (ID == Intrinsic::assume || ID == Intrinsic::lifetime_end ||
8832 ID == Intrinsic::lifetime_start || ID == Intrinsic::sideeffect ||
8833 ID == Intrinsic::pseudoprobe ||
8834 ID == Intrinsic::experimental_noalias_scope_decl))
8835 return nullptr;
8836
8837 auto willWiden = [&](ElementCount VF) -> bool {
8838 Intrinsic::ID ID = getVectorIntrinsicIDForCall(CI, TLI);
8839 // The following case may be scalarized depending on the VF.
8840 // The flag shows whether we use Intrinsic or a usual Call for vectorized
8841 // version of the instruction.
8842 // Is it beneficial to perform intrinsic call compared to lib call?
8843 bool NeedToScalarize = false;
8844 InstructionCost CallCost = CM.getVectorCallCost(CI, VF, NeedToScalarize);
8845 InstructionCost IntrinsicCost = ID ? CM.getVectorIntrinsicCost(CI, VF) : 0;
8846 bool UseVectorIntrinsic = ID && IntrinsicCost <= CallCost;
8847 return UseVectorIntrinsic || !NeedToScalarize;
8848 };
8849
8850 if (!LoopVectorizationPlanner::getDecisionAndClampRange(willWiden, Range))
8851 return nullptr;
8852
8853 ArrayRef<VPValue *> Ops = Operands.take_front(CI->getNumArgOperands());
8854 return new VPWidenCallRecipe(*CI, make_range(Ops.begin(), Ops.end()));
8855 }
8856
shouldWiden(Instruction * I,VFRange & Range) const8857 bool VPRecipeBuilder::shouldWiden(Instruction *I, VFRange &Range) const {
8858 assert(!isa<BranchInst>(I) && !isa<PHINode>(I) && !isa<LoadInst>(I) &&
8859 !isa<StoreInst>(I) && "Instruction should have been handled earlier");
8860 // Instruction should be widened, unless it is scalar after vectorization,
8861 // scalarization is profitable or it is predicated.
8862 auto WillScalarize = [this, I](ElementCount VF) -> bool {
8863 return CM.isScalarAfterVectorization(I, VF) ||
8864 CM.isProfitableToScalarize(I, VF) || CM.isScalarWithPredication(I);
8865 };
8866 return !LoopVectorizationPlanner::getDecisionAndClampRange(WillScalarize,
8867 Range);
8868 }
8869
tryToWiden(Instruction * I,ArrayRef<VPValue * > Operands) const8870 VPWidenRecipe *VPRecipeBuilder::tryToWiden(Instruction *I,
8871 ArrayRef<VPValue *> Operands) const {
8872 auto IsVectorizableOpcode = [](unsigned Opcode) {
8873 switch (Opcode) {
8874 case Instruction::Add:
8875 case Instruction::And:
8876 case Instruction::AShr:
8877 case Instruction::BitCast:
8878 case Instruction::FAdd:
8879 case Instruction::FCmp:
8880 case Instruction::FDiv:
8881 case Instruction::FMul:
8882 case Instruction::FNeg:
8883 case Instruction::FPExt:
8884 case Instruction::FPToSI:
8885 case Instruction::FPToUI:
8886 case Instruction::FPTrunc:
8887 case Instruction::FRem:
8888 case Instruction::FSub:
8889 case Instruction::ICmp:
8890 case Instruction::IntToPtr:
8891 case Instruction::LShr:
8892 case Instruction::Mul:
8893 case Instruction::Or:
8894 case Instruction::PtrToInt:
8895 case Instruction::SDiv:
8896 case Instruction::Select:
8897 case Instruction::SExt:
8898 case Instruction::Shl:
8899 case Instruction::SIToFP:
8900 case Instruction::SRem:
8901 case Instruction::Sub:
8902 case Instruction::Trunc:
8903 case Instruction::UDiv:
8904 case Instruction::UIToFP:
8905 case Instruction::URem:
8906 case Instruction::Xor:
8907 case Instruction::ZExt:
8908 return true;
8909 }
8910 return false;
8911 };
8912
8913 if (!IsVectorizableOpcode(I->getOpcode()))
8914 return nullptr;
8915
8916 // Success: widen this instruction.
8917 return new VPWidenRecipe(*I, make_range(Operands.begin(), Operands.end()));
8918 }
8919
fixHeaderPhis()8920 void VPRecipeBuilder::fixHeaderPhis() {
8921 BasicBlock *OrigLatch = OrigLoop->getLoopLatch();
8922 for (VPWidenPHIRecipe *R : PhisToFix) {
8923 auto *PN = cast<PHINode>(R->getUnderlyingValue());
8924 VPRecipeBase *IncR =
8925 getRecipe(cast<Instruction>(PN->getIncomingValueForBlock(OrigLatch)));
8926 R->addOperand(IncR->getVPSingleValue());
8927 }
8928 }
8929
handleReplication(Instruction * I,VFRange & Range,VPBasicBlock * VPBB,VPlanPtr & Plan)8930 VPBasicBlock *VPRecipeBuilder::handleReplication(
8931 Instruction *I, VFRange &Range, VPBasicBlock *VPBB,
8932 VPlanPtr &Plan) {
8933 bool IsUniform = LoopVectorizationPlanner::getDecisionAndClampRange(
8934 [&](ElementCount VF) { return CM.isUniformAfterVectorization(I, VF); },
8935 Range);
8936
8937 bool IsPredicated = LoopVectorizationPlanner::getDecisionAndClampRange(
8938 [&](ElementCount VF) { return CM.isPredicatedInst(I); }, Range);
8939
8940 // Even if the instruction is not marked as uniform, there are certain
8941 // intrinsic calls that can be effectively treated as such, so we check for
8942 // them here. Conservatively, we only do this for scalable vectors, since
8943 // for fixed-width VFs we can always fall back on full scalarization.
8944 if (!IsUniform && Range.Start.isScalable() && isa<IntrinsicInst>(I)) {
8945 switch (cast<IntrinsicInst>(I)->getIntrinsicID()) {
8946 case Intrinsic::assume:
8947 case Intrinsic::lifetime_start:
8948 case Intrinsic::lifetime_end:
8949 // For scalable vectors if one of the operands is variant then we still
8950 // want to mark as uniform, which will generate one instruction for just
8951 // the first lane of the vector. We can't scalarize the call in the same
8952 // way as for fixed-width vectors because we don't know how many lanes
8953 // there are.
8954 //
8955 // The reasons for doing it this way for scalable vectors are:
8956 // 1. For the assume intrinsic generating the instruction for the first
8957 // lane is still be better than not generating any at all. For
8958 // example, the input may be a splat across all lanes.
8959 // 2. For the lifetime start/end intrinsics the pointer operand only
8960 // does anything useful when the input comes from a stack object,
8961 // which suggests it should always be uniform. For non-stack objects
8962 // the effect is to poison the object, which still allows us to
8963 // remove the call.
8964 IsUniform = true;
8965 break;
8966 default:
8967 break;
8968 }
8969 }
8970
8971 auto *Recipe = new VPReplicateRecipe(I, Plan->mapToVPValues(I->operands()),
8972 IsUniform, IsPredicated);
8973 setRecipe(I, Recipe);
8974 Plan->addVPValue(I, Recipe);
8975
8976 // Find if I uses a predicated instruction. If so, it will use its scalar
8977 // value. Avoid hoisting the insert-element which packs the scalar value into
8978 // a vector value, as that happens iff all users use the vector value.
8979 for (VPValue *Op : Recipe->operands()) {
8980 auto *PredR = dyn_cast_or_null<VPPredInstPHIRecipe>(Op->getDef());
8981 if (!PredR)
8982 continue;
8983 auto *RepR =
8984 cast_or_null<VPReplicateRecipe>(PredR->getOperand(0)->getDef());
8985 assert(RepR->isPredicated() &&
8986 "expected Replicate recipe to be predicated");
8987 RepR->setAlsoPack(false);
8988 }
8989
8990 // Finalize the recipe for Instr, first if it is not predicated.
8991 if (!IsPredicated) {
8992 LLVM_DEBUG(dbgs() << "LV: Scalarizing:" << *I << "\n");
8993 VPBB->appendRecipe(Recipe);
8994 return VPBB;
8995 }
8996 LLVM_DEBUG(dbgs() << "LV: Scalarizing and predicating:" << *I << "\n");
8997 assert(VPBB->getSuccessors().empty() &&
8998 "VPBB has successors when handling predicated replication.");
8999 // Record predicated instructions for above packing optimizations.
9000 VPBlockBase *Region = createReplicateRegion(I, Recipe, Plan);
9001 VPBlockUtils::insertBlockAfter(Region, VPBB);
9002 auto *RegSucc = new VPBasicBlock();
9003 VPBlockUtils::insertBlockAfter(RegSucc, Region);
9004 return RegSucc;
9005 }
9006
createReplicateRegion(Instruction * Instr,VPRecipeBase * PredRecipe,VPlanPtr & Plan)9007 VPRegionBlock *VPRecipeBuilder::createReplicateRegion(Instruction *Instr,
9008 VPRecipeBase *PredRecipe,
9009 VPlanPtr &Plan) {
9010 // Instructions marked for predication are replicated and placed under an
9011 // if-then construct to prevent side-effects.
9012
9013 // Generate recipes to compute the block mask for this region.
9014 VPValue *BlockInMask = createBlockInMask(Instr->getParent(), Plan);
9015
9016 // Build the triangular if-then region.
9017 std::string RegionName = (Twine("pred.") + Instr->getOpcodeName()).str();
9018 assert(Instr->getParent() && "Predicated instruction not in any basic block");
9019 auto *BOMRecipe = new VPBranchOnMaskRecipe(BlockInMask);
9020 auto *Entry = new VPBasicBlock(Twine(RegionName) + ".entry", BOMRecipe);
9021 auto *PHIRecipe = Instr->getType()->isVoidTy()
9022 ? nullptr
9023 : new VPPredInstPHIRecipe(Plan->getOrAddVPValue(Instr));
9024 if (PHIRecipe) {
9025 Plan->removeVPValueFor(Instr);
9026 Plan->addVPValue(Instr, PHIRecipe);
9027 }
9028 auto *Exit = new VPBasicBlock(Twine(RegionName) + ".continue", PHIRecipe);
9029 auto *Pred = new VPBasicBlock(Twine(RegionName) + ".if", PredRecipe);
9030 VPRegionBlock *Region = new VPRegionBlock(Entry, Exit, RegionName, true);
9031
9032 // Note: first set Entry as region entry and then connect successors starting
9033 // from it in order, to propagate the "parent" of each VPBasicBlock.
9034 VPBlockUtils::insertTwoBlocksAfter(Pred, Exit, BlockInMask, Entry);
9035 VPBlockUtils::connectBlocks(Pred, Exit);
9036
9037 return Region;
9038 }
9039
9040 VPRecipeOrVPValueTy
tryToCreateWidenRecipe(Instruction * Instr,ArrayRef<VPValue * > Operands,VFRange & Range,VPlanPtr & Plan)9041 VPRecipeBuilder::tryToCreateWidenRecipe(Instruction *Instr,
9042 ArrayRef<VPValue *> Operands,
9043 VFRange &Range, VPlanPtr &Plan) {
9044 // First, check for specific widening recipes that deal with calls, memory
9045 // operations, inductions and Phi nodes.
9046 if (auto *CI = dyn_cast<CallInst>(Instr))
9047 return toVPRecipeResult(tryToWidenCall(CI, Operands, Range));
9048
9049 if (isa<LoadInst>(Instr) || isa<StoreInst>(Instr))
9050 return toVPRecipeResult(tryToWidenMemory(Instr, Operands, Range, Plan));
9051
9052 VPRecipeBase *Recipe;
9053 if (auto Phi = dyn_cast<PHINode>(Instr)) {
9054 if (Phi->getParent() != OrigLoop->getHeader())
9055 return tryToBlend(Phi, Operands, Plan);
9056 if ((Recipe = tryToOptimizeInductionPHI(Phi, Operands)))
9057 return toVPRecipeResult(Recipe);
9058
9059 VPWidenPHIRecipe *PhiRecipe = nullptr;
9060 if (Legal->isReductionVariable(Phi) || Legal->isFirstOrderRecurrence(Phi)) {
9061 VPValue *StartV = Operands[0];
9062 if (Legal->isReductionVariable(Phi)) {
9063 RecurrenceDescriptor &RdxDesc = Legal->getReductionVars()[Phi];
9064 assert(RdxDesc.getRecurrenceStartValue() ==
9065 Phi->getIncomingValueForBlock(OrigLoop->getLoopPreheader()));
9066 PhiRecipe = new VPReductionPHIRecipe(Phi, RdxDesc, *StartV,
9067 CM.isInLoopReduction(Phi),
9068 CM.useOrderedReductions(RdxDesc));
9069 } else {
9070 PhiRecipe = new VPFirstOrderRecurrencePHIRecipe(Phi, *StartV);
9071 }
9072
9073 // Record the incoming value from the backedge, so we can add the incoming
9074 // value from the backedge after all recipes have been created.
9075 recordRecipeOf(cast<Instruction>(
9076 Phi->getIncomingValueForBlock(OrigLoop->getLoopLatch())));
9077 PhisToFix.push_back(PhiRecipe);
9078 } else {
9079 // TODO: record start and backedge value for remaining pointer induction
9080 // phis.
9081 assert(Phi->getType()->isPointerTy() &&
9082 "only pointer phis should be handled here");
9083 PhiRecipe = new VPWidenPHIRecipe(Phi);
9084 }
9085
9086 return toVPRecipeResult(PhiRecipe);
9087 }
9088
9089 if (isa<TruncInst>(Instr) &&
9090 (Recipe = tryToOptimizeInductionTruncate(cast<TruncInst>(Instr), Operands,
9091 Range, *Plan)))
9092 return toVPRecipeResult(Recipe);
9093
9094 if (!shouldWiden(Instr, Range))
9095 return nullptr;
9096
9097 if (auto GEP = dyn_cast<GetElementPtrInst>(Instr))
9098 return toVPRecipeResult(new VPWidenGEPRecipe(
9099 GEP, make_range(Operands.begin(), Operands.end()), OrigLoop));
9100
9101 if (auto *SI = dyn_cast<SelectInst>(Instr)) {
9102 bool InvariantCond =
9103 PSE.getSE()->isLoopInvariant(PSE.getSCEV(SI->getOperand(0)), OrigLoop);
9104 return toVPRecipeResult(new VPWidenSelectRecipe(
9105 *SI, make_range(Operands.begin(), Operands.end()), InvariantCond));
9106 }
9107
9108 return toVPRecipeResult(tryToWiden(Instr, Operands));
9109 }
9110
buildVPlansWithVPRecipes(ElementCount MinVF,ElementCount MaxVF)9111 void LoopVectorizationPlanner::buildVPlansWithVPRecipes(ElementCount MinVF,
9112 ElementCount MaxVF) {
9113 assert(OrigLoop->isInnermost() && "Inner loop expected.");
9114
9115 // Collect instructions from the original loop that will become trivially dead
9116 // in the vectorized loop. We don't need to vectorize these instructions. For
9117 // example, original induction update instructions can become dead because we
9118 // separately emit induction "steps" when generating code for the new loop.
9119 // Similarly, we create a new latch condition when setting up the structure
9120 // of the new loop, so the old one can become dead.
9121 SmallPtrSet<Instruction *, 4> DeadInstructions;
9122 collectTriviallyDeadInstructions(DeadInstructions);
9123
9124 // Add assume instructions we need to drop to DeadInstructions, to prevent
9125 // them from being added to the VPlan.
9126 // TODO: We only need to drop assumes in blocks that get flattend. If the
9127 // control flow is preserved, we should keep them.
9128 auto &ConditionalAssumes = Legal->getConditionalAssumes();
9129 DeadInstructions.insert(ConditionalAssumes.begin(), ConditionalAssumes.end());
9130
9131 MapVector<Instruction *, Instruction *> &SinkAfter = Legal->getSinkAfter();
9132 // Dead instructions do not need sinking. Remove them from SinkAfter.
9133 for (Instruction *I : DeadInstructions)
9134 SinkAfter.erase(I);
9135
9136 // Cannot sink instructions after dead instructions (there won't be any
9137 // recipes for them). Instead, find the first non-dead previous instruction.
9138 for (auto &P : Legal->getSinkAfter()) {
9139 Instruction *SinkTarget = P.second;
9140 Instruction *FirstInst = &*SinkTarget->getParent()->begin();
9141 (void)FirstInst;
9142 while (DeadInstructions.contains(SinkTarget)) {
9143 assert(
9144 SinkTarget != FirstInst &&
9145 "Must find a live instruction (at least the one feeding the "
9146 "first-order recurrence PHI) before reaching beginning of the block");
9147 SinkTarget = SinkTarget->getPrevNode();
9148 assert(SinkTarget != P.first &&
9149 "sink source equals target, no sinking required");
9150 }
9151 P.second = SinkTarget;
9152 }
9153
9154 auto MaxVFPlusOne = MaxVF.getWithIncrement(1);
9155 for (ElementCount VF = MinVF; ElementCount::isKnownLT(VF, MaxVFPlusOne);) {
9156 VFRange SubRange = {VF, MaxVFPlusOne};
9157 VPlans.push_back(
9158 buildVPlanWithVPRecipes(SubRange, DeadInstructions, SinkAfter));
9159 VF = SubRange.End;
9160 }
9161 }
9162
buildVPlanWithVPRecipes(VFRange & Range,SmallPtrSetImpl<Instruction * > & DeadInstructions,const MapVector<Instruction *,Instruction * > & SinkAfter)9163 VPlanPtr LoopVectorizationPlanner::buildVPlanWithVPRecipes(
9164 VFRange &Range, SmallPtrSetImpl<Instruction *> &DeadInstructions,
9165 const MapVector<Instruction *, Instruction *> &SinkAfter) {
9166
9167 SmallPtrSet<const InterleaveGroup<Instruction> *, 1> InterleaveGroups;
9168
9169 VPRecipeBuilder RecipeBuilder(OrigLoop, TLI, Legal, CM, PSE, Builder);
9170
9171 // ---------------------------------------------------------------------------
9172 // Pre-construction: record ingredients whose recipes we'll need to further
9173 // process after constructing the initial VPlan.
9174 // ---------------------------------------------------------------------------
9175
9176 // Mark instructions we'll need to sink later and their targets as
9177 // ingredients whose recipe we'll need to record.
9178 for (auto &Entry : SinkAfter) {
9179 RecipeBuilder.recordRecipeOf(Entry.first);
9180 RecipeBuilder.recordRecipeOf(Entry.second);
9181 }
9182 for (auto &Reduction : CM.getInLoopReductionChains()) {
9183 PHINode *Phi = Reduction.first;
9184 RecurKind Kind = Legal->getReductionVars()[Phi].getRecurrenceKind();
9185 const SmallVector<Instruction *, 4> &ReductionOperations = Reduction.second;
9186
9187 RecipeBuilder.recordRecipeOf(Phi);
9188 for (auto &R : ReductionOperations) {
9189 RecipeBuilder.recordRecipeOf(R);
9190 // For min/max reducitons, where we have a pair of icmp/select, we also
9191 // need to record the ICmp recipe, so it can be removed later.
9192 if (RecurrenceDescriptor::isMinMaxRecurrenceKind(Kind))
9193 RecipeBuilder.recordRecipeOf(cast<Instruction>(R->getOperand(0)));
9194 }
9195 }
9196
9197 // For each interleave group which is relevant for this (possibly trimmed)
9198 // Range, add it to the set of groups to be later applied to the VPlan and add
9199 // placeholders for its members' Recipes which we'll be replacing with a
9200 // single VPInterleaveRecipe.
9201 for (InterleaveGroup<Instruction> *IG : IAI.getInterleaveGroups()) {
9202 auto applyIG = [IG, this](ElementCount VF) -> bool {
9203 return (VF.isVector() && // Query is illegal for VF == 1
9204 CM.getWideningDecision(IG->getInsertPos(), VF) ==
9205 LoopVectorizationCostModel::CM_Interleave);
9206 };
9207 if (!getDecisionAndClampRange(applyIG, Range))
9208 continue;
9209 InterleaveGroups.insert(IG);
9210 for (unsigned i = 0; i < IG->getFactor(); i++)
9211 if (Instruction *Member = IG->getMember(i))
9212 RecipeBuilder.recordRecipeOf(Member);
9213 };
9214
9215 // ---------------------------------------------------------------------------
9216 // Build initial VPlan: Scan the body of the loop in a topological order to
9217 // visit each basic block after having visited its predecessor basic blocks.
9218 // ---------------------------------------------------------------------------
9219
9220 // Create a dummy pre-entry VPBasicBlock to start building the VPlan.
9221 auto Plan = std::make_unique<VPlan>();
9222 VPBasicBlock *VPBB = new VPBasicBlock("Pre-Entry");
9223 Plan->setEntry(VPBB);
9224
9225 // Scan the body of the loop in a topological order to visit each basic block
9226 // after having visited its predecessor basic blocks.
9227 LoopBlocksDFS DFS(OrigLoop);
9228 DFS.perform(LI);
9229
9230 for (BasicBlock *BB : make_range(DFS.beginRPO(), DFS.endRPO())) {
9231 // Relevant instructions from basic block BB will be grouped into VPRecipe
9232 // ingredients and fill a new VPBasicBlock.
9233 unsigned VPBBsForBB = 0;
9234 auto *FirstVPBBForBB = new VPBasicBlock(BB->getName());
9235 VPBlockUtils::insertBlockAfter(FirstVPBBForBB, VPBB);
9236 VPBB = FirstVPBBForBB;
9237 Builder.setInsertPoint(VPBB);
9238
9239 // Introduce each ingredient into VPlan.
9240 // TODO: Model and preserve debug instrinsics in VPlan.
9241 for (Instruction &I : BB->instructionsWithoutDebug()) {
9242 Instruction *Instr = &I;
9243
9244 // First filter out irrelevant instructions, to ensure no recipes are
9245 // built for them.
9246 if (isa<BranchInst>(Instr) || DeadInstructions.count(Instr))
9247 continue;
9248
9249 SmallVector<VPValue *, 4> Operands;
9250 auto *Phi = dyn_cast<PHINode>(Instr);
9251 if (Phi && Phi->getParent() == OrigLoop->getHeader()) {
9252 Operands.push_back(Plan->getOrAddVPValue(
9253 Phi->getIncomingValueForBlock(OrigLoop->getLoopPreheader())));
9254 } else {
9255 auto OpRange = Plan->mapToVPValues(Instr->operands());
9256 Operands = {OpRange.begin(), OpRange.end()};
9257 }
9258 if (auto RecipeOrValue = RecipeBuilder.tryToCreateWidenRecipe(
9259 Instr, Operands, Range, Plan)) {
9260 // If Instr can be simplified to an existing VPValue, use it.
9261 if (RecipeOrValue.is<VPValue *>()) {
9262 auto *VPV = RecipeOrValue.get<VPValue *>();
9263 Plan->addVPValue(Instr, VPV);
9264 // If the re-used value is a recipe, register the recipe for the
9265 // instruction, in case the recipe for Instr needs to be recorded.
9266 if (auto *R = dyn_cast_or_null<VPRecipeBase>(VPV->getDef()))
9267 RecipeBuilder.setRecipe(Instr, R);
9268 continue;
9269 }
9270 // Otherwise, add the new recipe.
9271 VPRecipeBase *Recipe = RecipeOrValue.get<VPRecipeBase *>();
9272 for (auto *Def : Recipe->definedValues()) {
9273 auto *UV = Def->getUnderlyingValue();
9274 Plan->addVPValue(UV, Def);
9275 }
9276
9277 RecipeBuilder.setRecipe(Instr, Recipe);
9278 VPBB->appendRecipe(Recipe);
9279 continue;
9280 }
9281
9282 // Otherwise, if all widening options failed, Instruction is to be
9283 // replicated. This may create a successor for VPBB.
9284 VPBasicBlock *NextVPBB =
9285 RecipeBuilder.handleReplication(Instr, Range, VPBB, Plan);
9286 if (NextVPBB != VPBB) {
9287 VPBB = NextVPBB;
9288 VPBB->setName(BB->hasName() ? BB->getName() + "." + Twine(VPBBsForBB++)
9289 : "");
9290 }
9291 }
9292 }
9293
9294 RecipeBuilder.fixHeaderPhis();
9295
9296 // Discard empty dummy pre-entry VPBasicBlock. Note that other VPBasicBlocks
9297 // may also be empty, such as the last one VPBB, reflecting original
9298 // basic-blocks with no recipes.
9299 VPBasicBlock *PreEntry = cast<VPBasicBlock>(Plan->getEntry());
9300 assert(PreEntry->empty() && "Expecting empty pre-entry block.");
9301 VPBlockBase *Entry = Plan->setEntry(PreEntry->getSingleSuccessor());
9302 VPBlockUtils::disconnectBlocks(PreEntry, Entry);
9303 delete PreEntry;
9304
9305 // ---------------------------------------------------------------------------
9306 // Transform initial VPlan: Apply previously taken decisions, in order, to
9307 // bring the VPlan to its final state.
9308 // ---------------------------------------------------------------------------
9309
9310 // Apply Sink-After legal constraints.
9311 auto GetReplicateRegion = [](VPRecipeBase *R) -> VPRegionBlock * {
9312 auto *Region = dyn_cast_or_null<VPRegionBlock>(R->getParent()->getParent());
9313 if (Region && Region->isReplicator()) {
9314 assert(Region->getNumSuccessors() == 1 &&
9315 Region->getNumPredecessors() == 1 && "Expected SESE region!");
9316 assert(R->getParent()->size() == 1 &&
9317 "A recipe in an original replicator region must be the only "
9318 "recipe in its block");
9319 return Region;
9320 }
9321 return nullptr;
9322 };
9323 for (auto &Entry : SinkAfter) {
9324 VPRecipeBase *Sink = RecipeBuilder.getRecipe(Entry.first);
9325 VPRecipeBase *Target = RecipeBuilder.getRecipe(Entry.second);
9326
9327 auto *TargetRegion = GetReplicateRegion(Target);
9328 auto *SinkRegion = GetReplicateRegion(Sink);
9329 if (!SinkRegion) {
9330 // If the sink source is not a replicate region, sink the recipe directly.
9331 if (TargetRegion) {
9332 // The target is in a replication region, make sure to move Sink to
9333 // the block after it, not into the replication region itself.
9334 VPBasicBlock *NextBlock =
9335 cast<VPBasicBlock>(TargetRegion->getSuccessors().front());
9336 Sink->moveBefore(*NextBlock, NextBlock->getFirstNonPhi());
9337 } else
9338 Sink->moveAfter(Target);
9339 continue;
9340 }
9341
9342 // The sink source is in a replicate region. Unhook the region from the CFG.
9343 auto *SinkPred = SinkRegion->getSinglePredecessor();
9344 auto *SinkSucc = SinkRegion->getSingleSuccessor();
9345 VPBlockUtils::disconnectBlocks(SinkPred, SinkRegion);
9346 VPBlockUtils::disconnectBlocks(SinkRegion, SinkSucc);
9347 VPBlockUtils::connectBlocks(SinkPred, SinkSucc);
9348
9349 if (TargetRegion) {
9350 // The target recipe is also in a replicate region, move the sink region
9351 // after the target region.
9352 auto *TargetSucc = TargetRegion->getSingleSuccessor();
9353 VPBlockUtils::disconnectBlocks(TargetRegion, TargetSucc);
9354 VPBlockUtils::connectBlocks(TargetRegion, SinkRegion);
9355 VPBlockUtils::connectBlocks(SinkRegion, TargetSucc);
9356 } else {
9357 // The sink source is in a replicate region, we need to move the whole
9358 // replicate region, which should only contain a single recipe in the
9359 // main block.
9360 auto *SplitBlock =
9361 Target->getParent()->splitAt(std::next(Target->getIterator()));
9362
9363 auto *SplitPred = SplitBlock->getSinglePredecessor();
9364
9365 VPBlockUtils::disconnectBlocks(SplitPred, SplitBlock);
9366 VPBlockUtils::connectBlocks(SplitPred, SinkRegion);
9367 VPBlockUtils::connectBlocks(SinkRegion, SplitBlock);
9368 if (VPBB == SplitPred)
9369 VPBB = SplitBlock;
9370 }
9371 }
9372
9373 // Introduce a recipe to combine the incoming and previous values of a
9374 // first-order recurrence.
9375 for (VPRecipeBase &R : Plan->getEntry()->getEntryBasicBlock()->phis()) {
9376 auto *RecurPhi = dyn_cast<VPFirstOrderRecurrencePHIRecipe>(&R);
9377 if (!RecurPhi)
9378 continue;
9379
9380 auto *RecurSplice = cast<VPInstruction>(
9381 Builder.createNaryOp(VPInstruction::FirstOrderRecurrenceSplice,
9382 {RecurPhi, RecurPhi->getBackedgeValue()}));
9383
9384 VPRecipeBase *PrevRecipe = RecurPhi->getBackedgeRecipe();
9385 if (auto *Region = GetReplicateRegion(PrevRecipe)) {
9386 VPBasicBlock *Succ = cast<VPBasicBlock>(Region->getSingleSuccessor());
9387 RecurSplice->moveBefore(*Succ, Succ->getFirstNonPhi());
9388 } else
9389 RecurSplice->moveAfter(PrevRecipe);
9390 RecurPhi->replaceAllUsesWith(RecurSplice);
9391 // Set the first operand of RecurSplice to RecurPhi again, after replacing
9392 // all users.
9393 RecurSplice->setOperand(0, RecurPhi);
9394 }
9395
9396 // Interleave memory: for each Interleave Group we marked earlier as relevant
9397 // for this VPlan, replace the Recipes widening its memory instructions with a
9398 // single VPInterleaveRecipe at its insertion point.
9399 for (auto IG : InterleaveGroups) {
9400 auto *Recipe = cast<VPWidenMemoryInstructionRecipe>(
9401 RecipeBuilder.getRecipe(IG->getInsertPos()));
9402 SmallVector<VPValue *, 4> StoredValues;
9403 for (unsigned i = 0; i < IG->getFactor(); ++i)
9404 if (auto *SI = dyn_cast_or_null<StoreInst>(IG->getMember(i))) {
9405 auto *StoreR =
9406 cast<VPWidenMemoryInstructionRecipe>(RecipeBuilder.getRecipe(SI));
9407 StoredValues.push_back(StoreR->getStoredValue());
9408 }
9409
9410 auto *VPIG = new VPInterleaveRecipe(IG, Recipe->getAddr(), StoredValues,
9411 Recipe->getMask());
9412 VPIG->insertBefore(Recipe);
9413 unsigned J = 0;
9414 for (unsigned i = 0; i < IG->getFactor(); ++i)
9415 if (Instruction *Member = IG->getMember(i)) {
9416 if (!Member->getType()->isVoidTy()) {
9417 VPValue *OriginalV = Plan->getVPValue(Member);
9418 Plan->removeVPValueFor(Member);
9419 Plan->addVPValue(Member, VPIG->getVPValue(J));
9420 OriginalV->replaceAllUsesWith(VPIG->getVPValue(J));
9421 J++;
9422 }
9423 RecipeBuilder.getRecipe(Member)->eraseFromParent();
9424 }
9425 }
9426
9427 // Adjust the recipes for any inloop reductions.
9428 adjustRecipesForInLoopReductions(Plan, RecipeBuilder, Range.Start);
9429
9430 // Finally, if tail is folded by masking, introduce selects between the phi
9431 // and the live-out instruction of each reduction, at the end of the latch.
9432 if (CM.foldTailByMasking() && !Legal->getReductionVars().empty()) {
9433 Builder.setInsertPoint(VPBB);
9434 auto *Cond = RecipeBuilder.createBlockInMask(OrigLoop->getHeader(), Plan);
9435 for (auto &Reduction : Legal->getReductionVars()) {
9436 if (CM.isInLoopReduction(Reduction.first))
9437 continue;
9438 VPValue *Phi = Plan->getOrAddVPValue(Reduction.first);
9439 VPValue *Red = Plan->getOrAddVPValue(Reduction.second.getLoopExitInstr());
9440 Builder.createNaryOp(Instruction::Select, {Cond, Red, Phi});
9441 }
9442 }
9443
9444 VPlanTransforms::sinkScalarOperands(*Plan);
9445 VPlanTransforms::mergeReplicateRegions(*Plan);
9446
9447 std::string PlanName;
9448 raw_string_ostream RSO(PlanName);
9449 ElementCount VF = Range.Start;
9450 Plan->addVF(VF);
9451 RSO << "Initial VPlan for VF={" << VF;
9452 for (VF *= 2; ElementCount::isKnownLT(VF, Range.End); VF *= 2) {
9453 Plan->addVF(VF);
9454 RSO << "," << VF;
9455 }
9456 RSO << "},UF>=1";
9457 RSO.flush();
9458 Plan->setName(PlanName);
9459
9460 return Plan;
9461 }
9462
buildVPlan(VFRange & Range)9463 VPlanPtr LoopVectorizationPlanner::buildVPlan(VFRange &Range) {
9464 // Outer loop handling: They may require CFG and instruction level
9465 // transformations before even evaluating whether vectorization is profitable.
9466 // Since we cannot modify the incoming IR, we need to build VPlan upfront in
9467 // the vectorization pipeline.
9468 assert(!OrigLoop->isInnermost());
9469 assert(EnableVPlanNativePath && "VPlan-native path is not enabled.");
9470
9471 // Create new empty VPlan
9472 auto Plan = std::make_unique<VPlan>();
9473
9474 // Build hierarchical CFG
9475 VPlanHCFGBuilder HCFGBuilder(OrigLoop, LI, *Plan);
9476 HCFGBuilder.buildHierarchicalCFG();
9477
9478 for (ElementCount VF = Range.Start; ElementCount::isKnownLT(VF, Range.End);
9479 VF *= 2)
9480 Plan->addVF(VF);
9481
9482 if (EnableVPlanPredication) {
9483 VPlanPredicator VPP(*Plan);
9484 VPP.predicate();
9485
9486 // Avoid running transformation to recipes until masked code generation in
9487 // VPlan-native path is in place.
9488 return Plan;
9489 }
9490
9491 SmallPtrSet<Instruction *, 1> DeadInstructions;
9492 VPlanTransforms::VPInstructionsToVPRecipes(OrigLoop, Plan,
9493 Legal->getInductionVars(),
9494 DeadInstructions, *PSE.getSE());
9495 return Plan;
9496 }
9497
9498 // Adjust the recipes for any inloop reductions. The chain of instructions
9499 // leading from the loop exit instr to the phi need to be converted to
9500 // reductions, with one operand being vector and the other being the scalar
9501 // reduction chain.
adjustRecipesForInLoopReductions(VPlanPtr & Plan,VPRecipeBuilder & RecipeBuilder,ElementCount MinVF)9502 void LoopVectorizationPlanner::adjustRecipesForInLoopReductions(
9503 VPlanPtr &Plan, VPRecipeBuilder &RecipeBuilder, ElementCount MinVF) {
9504 for (auto &Reduction : CM.getInLoopReductionChains()) {
9505 PHINode *Phi = Reduction.first;
9506 RecurrenceDescriptor &RdxDesc = Legal->getReductionVars()[Phi];
9507 const SmallVector<Instruction *, 4> &ReductionOperations = Reduction.second;
9508
9509 if (MinVF.isScalar() && !CM.useOrderedReductions(RdxDesc))
9510 continue;
9511
9512 // ReductionOperations are orders top-down from the phi's use to the
9513 // LoopExitValue. We keep a track of the previous item (the Chain) to tell
9514 // which of the two operands will remain scalar and which will be reduced.
9515 // For minmax the chain will be the select instructions.
9516 Instruction *Chain = Phi;
9517 for (Instruction *R : ReductionOperations) {
9518 VPRecipeBase *WidenRecipe = RecipeBuilder.getRecipe(R);
9519 RecurKind Kind = RdxDesc.getRecurrenceKind();
9520
9521 VPValue *ChainOp = Plan->getVPValue(Chain);
9522 unsigned FirstOpId;
9523 if (RecurrenceDescriptor::isMinMaxRecurrenceKind(Kind)) {
9524 assert(isa<VPWidenSelectRecipe>(WidenRecipe) &&
9525 "Expected to replace a VPWidenSelectSC");
9526 FirstOpId = 1;
9527 } else {
9528 assert((MinVF.isScalar() || isa<VPWidenRecipe>(WidenRecipe)) &&
9529 "Expected to replace a VPWidenSC");
9530 FirstOpId = 0;
9531 }
9532 unsigned VecOpId =
9533 R->getOperand(FirstOpId) == Chain ? FirstOpId + 1 : FirstOpId;
9534 VPValue *VecOp = Plan->getVPValue(R->getOperand(VecOpId));
9535
9536 auto *CondOp = CM.foldTailByMasking()
9537 ? RecipeBuilder.createBlockInMask(R->getParent(), Plan)
9538 : nullptr;
9539 VPReductionRecipe *RedRecipe = new VPReductionRecipe(
9540 &RdxDesc, R, ChainOp, VecOp, CondOp, TTI);
9541 WidenRecipe->getVPSingleValue()->replaceAllUsesWith(RedRecipe);
9542 Plan->removeVPValueFor(R);
9543 Plan->addVPValue(R, RedRecipe);
9544 WidenRecipe->getParent()->insert(RedRecipe, WidenRecipe->getIterator());
9545 WidenRecipe->getVPSingleValue()->replaceAllUsesWith(RedRecipe);
9546 WidenRecipe->eraseFromParent();
9547
9548 if (RecurrenceDescriptor::isMinMaxRecurrenceKind(Kind)) {
9549 VPRecipeBase *CompareRecipe =
9550 RecipeBuilder.getRecipe(cast<Instruction>(R->getOperand(0)));
9551 assert(isa<VPWidenRecipe>(CompareRecipe) &&
9552 "Expected to replace a VPWidenSC");
9553 assert(cast<VPWidenRecipe>(CompareRecipe)->getNumUsers() == 0 &&
9554 "Expected no remaining users");
9555 CompareRecipe->eraseFromParent();
9556 }
9557 Chain = R;
9558 }
9559 }
9560 }
9561
9562 #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
print(raw_ostream & O,const Twine & Indent,VPSlotTracker & SlotTracker) const9563 void VPInterleaveRecipe::print(raw_ostream &O, const Twine &Indent,
9564 VPSlotTracker &SlotTracker) const {
9565 O << Indent << "INTERLEAVE-GROUP with factor " << IG->getFactor() << " at ";
9566 IG->getInsertPos()->printAsOperand(O, false);
9567 O << ", ";
9568 getAddr()->printAsOperand(O, SlotTracker);
9569 VPValue *Mask = getMask();
9570 if (Mask) {
9571 O << ", ";
9572 Mask->printAsOperand(O, SlotTracker);
9573 }
9574 for (unsigned i = 0; i < IG->getFactor(); ++i)
9575 if (Instruction *I = IG->getMember(i))
9576 O << "\n" << Indent << " " << VPlanIngredient(I) << " " << i;
9577 }
9578 #endif
9579
execute(VPTransformState & State)9580 void VPWidenCallRecipe::execute(VPTransformState &State) {
9581 State.ILV->widenCallInstruction(*cast<CallInst>(getUnderlyingInstr()), this,
9582 *this, State);
9583 }
9584
execute(VPTransformState & State)9585 void VPWidenSelectRecipe::execute(VPTransformState &State) {
9586 State.ILV->widenSelectInstruction(*cast<SelectInst>(getUnderlyingInstr()),
9587 this, *this, InvariantCond, State);
9588 }
9589
execute(VPTransformState & State)9590 void VPWidenRecipe::execute(VPTransformState &State) {
9591 State.ILV->widenInstruction(*getUnderlyingInstr(), this, *this, State);
9592 }
9593
execute(VPTransformState & State)9594 void VPWidenGEPRecipe::execute(VPTransformState &State) {
9595 State.ILV->widenGEP(cast<GetElementPtrInst>(getUnderlyingInstr()), this,
9596 *this, State.UF, State.VF, IsPtrLoopInvariant,
9597 IsIndexLoopInvariant, State);
9598 }
9599
execute(VPTransformState & State)9600 void VPWidenIntOrFpInductionRecipe::execute(VPTransformState &State) {
9601 assert(!State.Instance && "Int or FP induction being replicated.");
9602 State.ILV->widenIntOrFpInduction(IV, getStartValue()->getLiveInIRValue(),
9603 getTruncInst(), getVPValue(0),
9604 getCastValue(), State);
9605 }
9606
execute(VPTransformState & State)9607 void VPWidenPHIRecipe::execute(VPTransformState &State) {
9608 State.ILV->widenPHIInstruction(cast<PHINode>(getUnderlyingValue()), this,
9609 State);
9610 }
9611
execute(VPTransformState & State)9612 void VPBlendRecipe::execute(VPTransformState &State) {
9613 State.ILV->setDebugLocFromInst(Phi, &State.Builder);
9614 // We know that all PHIs in non-header blocks are converted into
9615 // selects, so we don't have to worry about the insertion order and we
9616 // can just use the builder.
9617 // At this point we generate the predication tree. There may be
9618 // duplications since this is a simple recursive scan, but future
9619 // optimizations will clean it up.
9620
9621 unsigned NumIncoming = getNumIncomingValues();
9622
9623 // Generate a sequence of selects of the form:
9624 // SELECT(Mask3, In3,
9625 // SELECT(Mask2, In2,
9626 // SELECT(Mask1, In1,
9627 // In0)))
9628 // Note that Mask0 is never used: lanes for which no path reaches this phi and
9629 // are essentially undef are taken from In0.
9630 InnerLoopVectorizer::VectorParts Entry(State.UF);
9631 for (unsigned In = 0; In < NumIncoming; ++In) {
9632 for (unsigned Part = 0; Part < State.UF; ++Part) {
9633 // We might have single edge PHIs (blocks) - use an identity
9634 // 'select' for the first PHI operand.
9635 Value *In0 = State.get(getIncomingValue(In), Part);
9636 if (In == 0)
9637 Entry[Part] = In0; // Initialize with the first incoming value.
9638 else {
9639 // Select between the current value and the previous incoming edge
9640 // based on the incoming mask.
9641 Value *Cond = State.get(getMask(In), Part);
9642 Entry[Part] =
9643 State.Builder.CreateSelect(Cond, In0, Entry[Part], "predphi");
9644 }
9645 }
9646 }
9647 for (unsigned Part = 0; Part < State.UF; ++Part)
9648 State.set(this, Entry[Part], Part);
9649 }
9650
execute(VPTransformState & State)9651 void VPInterleaveRecipe::execute(VPTransformState &State) {
9652 assert(!State.Instance && "Interleave group being replicated.");
9653 State.ILV->vectorizeInterleaveGroup(IG, definedValues(), State, getAddr(),
9654 getStoredValues(), getMask());
9655 }
9656
execute(VPTransformState & State)9657 void VPReductionRecipe::execute(VPTransformState &State) {
9658 assert(!State.Instance && "Reduction being replicated.");
9659 Value *PrevInChain = State.get(getChainOp(), 0);
9660 for (unsigned Part = 0; Part < State.UF; ++Part) {
9661 RecurKind Kind = RdxDesc->getRecurrenceKind();
9662 bool IsOrdered = State.ILV->useOrderedReductions(*RdxDesc);
9663 Value *NewVecOp = State.get(getVecOp(), Part);
9664 if (VPValue *Cond = getCondOp()) {
9665 Value *NewCond = State.get(Cond, Part);
9666 VectorType *VecTy = cast<VectorType>(NewVecOp->getType());
9667 Constant *Iden = RecurrenceDescriptor::getRecurrenceIdentity(
9668 Kind, VecTy->getElementType(), RdxDesc->getFastMathFlags());
9669 Constant *IdenVec =
9670 ConstantVector::getSplat(VecTy->getElementCount(), Iden);
9671 Value *Select = State.Builder.CreateSelect(NewCond, NewVecOp, IdenVec);
9672 NewVecOp = Select;
9673 }
9674 Value *NewRed;
9675 Value *NextInChain;
9676 if (IsOrdered) {
9677 if (State.VF.isVector())
9678 NewRed = createOrderedReduction(State.Builder, *RdxDesc, NewVecOp,
9679 PrevInChain);
9680 else
9681 NewRed = State.Builder.CreateBinOp(
9682 (Instruction::BinaryOps)getUnderlyingInstr()->getOpcode(),
9683 PrevInChain, NewVecOp);
9684 PrevInChain = NewRed;
9685 } else {
9686 PrevInChain = State.get(getChainOp(), Part);
9687 NewRed = createTargetReduction(State.Builder, TTI, *RdxDesc, NewVecOp);
9688 }
9689 if (RecurrenceDescriptor::isMinMaxRecurrenceKind(Kind)) {
9690 NextInChain =
9691 createMinMaxOp(State.Builder, RdxDesc->getRecurrenceKind(),
9692 NewRed, PrevInChain);
9693 } else if (IsOrdered)
9694 NextInChain = NewRed;
9695 else {
9696 NextInChain = State.Builder.CreateBinOp(
9697 (Instruction::BinaryOps)getUnderlyingInstr()->getOpcode(), NewRed,
9698 PrevInChain);
9699 }
9700 State.set(this, NextInChain, Part);
9701 }
9702 }
9703
execute(VPTransformState & State)9704 void VPReplicateRecipe::execute(VPTransformState &State) {
9705 if (State.Instance) { // Generate a single instance.
9706 assert(!State.VF.isScalable() && "Can't scalarize a scalable vector");
9707 State.ILV->scalarizeInstruction(getUnderlyingInstr(), this, *this,
9708 *State.Instance, IsPredicated, State);
9709 // Insert scalar instance packing it into a vector.
9710 if (AlsoPack && State.VF.isVector()) {
9711 // If we're constructing lane 0, initialize to start from poison.
9712 if (State.Instance->Lane.isFirstLane()) {
9713 assert(!State.VF.isScalable() && "VF is assumed to be non scalable.");
9714 Value *Poison = PoisonValue::get(
9715 VectorType::get(getUnderlyingValue()->getType(), State.VF));
9716 State.set(this, Poison, State.Instance->Part);
9717 }
9718 State.ILV->packScalarIntoVectorValue(this, *State.Instance, State);
9719 }
9720 return;
9721 }
9722
9723 // Generate scalar instances for all VF lanes of all UF parts, unless the
9724 // instruction is uniform inwhich case generate only the first lane for each
9725 // of the UF parts.
9726 unsigned EndLane = IsUniform ? 1 : State.VF.getKnownMinValue();
9727 assert((!State.VF.isScalable() || IsUniform) &&
9728 "Can't scalarize a scalable vector");
9729 for (unsigned Part = 0; Part < State.UF; ++Part)
9730 for (unsigned Lane = 0; Lane < EndLane; ++Lane)
9731 State.ILV->scalarizeInstruction(getUnderlyingInstr(), this, *this,
9732 VPIteration(Part, Lane), IsPredicated,
9733 State);
9734 }
9735
execute(VPTransformState & State)9736 void VPBranchOnMaskRecipe::execute(VPTransformState &State) {
9737 assert(State.Instance && "Branch on Mask works only on single instance.");
9738
9739 unsigned Part = State.Instance->Part;
9740 unsigned Lane = State.Instance->Lane.getKnownLane();
9741
9742 Value *ConditionBit = nullptr;
9743 VPValue *BlockInMask = getMask();
9744 if (BlockInMask) {
9745 ConditionBit = State.get(BlockInMask, Part);
9746 if (ConditionBit->getType()->isVectorTy())
9747 ConditionBit = State.Builder.CreateExtractElement(
9748 ConditionBit, State.Builder.getInt32(Lane));
9749 } else // Block in mask is all-one.
9750 ConditionBit = State.Builder.getTrue();
9751
9752 // Replace the temporary unreachable terminator with a new conditional branch,
9753 // whose two destinations will be set later when they are created.
9754 auto *CurrentTerminator = State.CFG.PrevBB->getTerminator();
9755 assert(isa<UnreachableInst>(CurrentTerminator) &&
9756 "Expected to replace unreachable terminator with conditional branch.");
9757 auto *CondBr = BranchInst::Create(State.CFG.PrevBB, nullptr, ConditionBit);
9758 CondBr->setSuccessor(0, nullptr);
9759 ReplaceInstWithInst(CurrentTerminator, CondBr);
9760 }
9761
execute(VPTransformState & State)9762 void VPPredInstPHIRecipe::execute(VPTransformState &State) {
9763 assert(State.Instance && "Predicated instruction PHI works per instance.");
9764 Instruction *ScalarPredInst =
9765 cast<Instruction>(State.get(getOperand(0), *State.Instance));
9766 BasicBlock *PredicatedBB = ScalarPredInst->getParent();
9767 BasicBlock *PredicatingBB = PredicatedBB->getSinglePredecessor();
9768 assert(PredicatingBB && "Predicated block has no single predecessor.");
9769 assert(isa<VPReplicateRecipe>(getOperand(0)) &&
9770 "operand must be VPReplicateRecipe");
9771
9772 // By current pack/unpack logic we need to generate only a single phi node: if
9773 // a vector value for the predicated instruction exists at this point it means
9774 // the instruction has vector users only, and a phi for the vector value is
9775 // needed. In this case the recipe of the predicated instruction is marked to
9776 // also do that packing, thereby "hoisting" the insert-element sequence.
9777 // Otherwise, a phi node for the scalar value is needed.
9778 unsigned Part = State.Instance->Part;
9779 if (State.hasVectorValue(getOperand(0), Part)) {
9780 Value *VectorValue = State.get(getOperand(0), Part);
9781 InsertElementInst *IEI = cast<InsertElementInst>(VectorValue);
9782 PHINode *VPhi = State.Builder.CreatePHI(IEI->getType(), 2);
9783 VPhi->addIncoming(IEI->getOperand(0), PredicatingBB); // Unmodified vector.
9784 VPhi->addIncoming(IEI, PredicatedBB); // New vector with inserted element.
9785 if (State.hasVectorValue(this, Part))
9786 State.reset(this, VPhi, Part);
9787 else
9788 State.set(this, VPhi, Part);
9789 // NOTE: Currently we need to update the value of the operand, so the next
9790 // predicated iteration inserts its generated value in the correct vector.
9791 State.reset(getOperand(0), VPhi, Part);
9792 } else {
9793 Type *PredInstType = getOperand(0)->getUnderlyingValue()->getType();
9794 PHINode *Phi = State.Builder.CreatePHI(PredInstType, 2);
9795 Phi->addIncoming(PoisonValue::get(ScalarPredInst->getType()),
9796 PredicatingBB);
9797 Phi->addIncoming(ScalarPredInst, PredicatedBB);
9798 if (State.hasScalarValue(this, *State.Instance))
9799 State.reset(this, Phi, *State.Instance);
9800 else
9801 State.set(this, Phi, *State.Instance);
9802 // NOTE: Currently we need to update the value of the operand, so the next
9803 // predicated iteration inserts its generated value in the correct vector.
9804 State.reset(getOperand(0), Phi, *State.Instance);
9805 }
9806 }
9807
execute(VPTransformState & State)9808 void VPWidenMemoryInstructionRecipe::execute(VPTransformState &State) {
9809 VPValue *StoredValue = isStore() ? getStoredValue() : nullptr;
9810 State.ILV->vectorizeMemoryInstruction(
9811 &Ingredient, State, StoredValue ? nullptr : getVPSingleValue(), getAddr(),
9812 StoredValue, getMask());
9813 }
9814
9815 // Determine how to lower the scalar epilogue, which depends on 1) optimising
9816 // for minimum code-size, 2) predicate compiler options, 3) loop hints forcing
9817 // predication, and 4) a TTI hook that analyses whether the loop is suitable
9818 // for predication.
getScalarEpilogueLowering(Function * F,Loop * L,LoopVectorizeHints & Hints,ProfileSummaryInfo * PSI,BlockFrequencyInfo * BFI,TargetTransformInfo * TTI,TargetLibraryInfo * TLI,AssumptionCache * AC,LoopInfo * LI,ScalarEvolution * SE,DominatorTree * DT,LoopVectorizationLegality & LVL)9819 static ScalarEpilogueLowering getScalarEpilogueLowering(
9820 Function *F, Loop *L, LoopVectorizeHints &Hints, ProfileSummaryInfo *PSI,
9821 BlockFrequencyInfo *BFI, TargetTransformInfo *TTI, TargetLibraryInfo *TLI,
9822 AssumptionCache *AC, LoopInfo *LI, ScalarEvolution *SE, DominatorTree *DT,
9823 LoopVectorizationLegality &LVL) {
9824 // 1) OptSize takes precedence over all other options, i.e. if this is set,
9825 // don't look at hints or options, and don't request a scalar epilogue.
9826 // (For PGSO, as shouldOptimizeForSize isn't currently accessible from
9827 // LoopAccessInfo (due to code dependency and not being able to reliably get
9828 // PSI/BFI from a loop analysis under NPM), we cannot suppress the collection
9829 // of strides in LoopAccessInfo::analyzeLoop() and vectorize without
9830 // versioning when the vectorization is forced, unlike hasOptSize. So revert
9831 // back to the old way and vectorize with versioning when forced. See D81345.)
9832 if (F->hasOptSize() || (llvm::shouldOptimizeForSize(L->getHeader(), PSI, BFI,
9833 PGSOQueryType::IRPass) &&
9834 Hints.getForce() != LoopVectorizeHints::FK_Enabled))
9835 return CM_ScalarEpilogueNotAllowedOptSize;
9836
9837 // 2) If set, obey the directives
9838 if (PreferPredicateOverEpilogue.getNumOccurrences()) {
9839 switch (PreferPredicateOverEpilogue) {
9840 case PreferPredicateTy::ScalarEpilogue:
9841 return CM_ScalarEpilogueAllowed;
9842 case PreferPredicateTy::PredicateElseScalarEpilogue:
9843 return CM_ScalarEpilogueNotNeededUsePredicate;
9844 case PreferPredicateTy::PredicateOrDontVectorize:
9845 return CM_ScalarEpilogueNotAllowedUsePredicate;
9846 };
9847 }
9848
9849 // 3) If set, obey the hints
9850 switch (Hints.getPredicate()) {
9851 case LoopVectorizeHints::FK_Enabled:
9852 return CM_ScalarEpilogueNotNeededUsePredicate;
9853 case LoopVectorizeHints::FK_Disabled:
9854 return CM_ScalarEpilogueAllowed;
9855 };
9856
9857 // 4) if the TTI hook indicates this is profitable, request predication.
9858 if (TTI->preferPredicateOverEpilogue(L, LI, *SE, *AC, TLI, DT,
9859 LVL.getLAI()))
9860 return CM_ScalarEpilogueNotNeededUsePredicate;
9861
9862 return CM_ScalarEpilogueAllowed;
9863 }
9864
get(VPValue * Def,unsigned Part)9865 Value *VPTransformState::get(VPValue *Def, unsigned Part) {
9866 // If Values have been set for this Def return the one relevant for \p Part.
9867 if (hasVectorValue(Def, Part))
9868 return Data.PerPartOutput[Def][Part];
9869
9870 if (!hasScalarValue(Def, {Part, 0})) {
9871 Value *IRV = Def->getLiveInIRValue();
9872 Value *B = ILV->getBroadcastInstrs(IRV);
9873 set(Def, B, Part);
9874 return B;
9875 }
9876
9877 Value *ScalarValue = get(Def, {Part, 0});
9878 // If we aren't vectorizing, we can just copy the scalar map values over
9879 // to the vector map.
9880 if (VF.isScalar()) {
9881 set(Def, ScalarValue, Part);
9882 return ScalarValue;
9883 }
9884
9885 auto *RepR = dyn_cast<VPReplicateRecipe>(Def);
9886 bool IsUniform = RepR && RepR->isUniform();
9887
9888 unsigned LastLane = IsUniform ? 0 : VF.getKnownMinValue() - 1;
9889 // Check if there is a scalar value for the selected lane.
9890 if (!hasScalarValue(Def, {Part, LastLane})) {
9891 // At the moment, VPWidenIntOrFpInductionRecipes can also be uniform.
9892 assert(isa<VPWidenIntOrFpInductionRecipe>(Def->getDef()) &&
9893 "unexpected recipe found to be invariant");
9894 IsUniform = true;
9895 LastLane = 0;
9896 }
9897
9898 auto *LastInst = cast<Instruction>(get(Def, {Part, LastLane}));
9899 // Set the insert point after the last scalarized instruction or after the
9900 // last PHI, if LastInst is a PHI. This ensures the insertelement sequence
9901 // will directly follow the scalar definitions.
9902 auto OldIP = Builder.saveIP();
9903 auto NewIP =
9904 isa<PHINode>(LastInst)
9905 ? BasicBlock::iterator(LastInst->getParent()->getFirstNonPHI())
9906 : std::next(BasicBlock::iterator(LastInst));
9907 Builder.SetInsertPoint(&*NewIP);
9908
9909 // However, if we are vectorizing, we need to construct the vector values.
9910 // If the value is known to be uniform after vectorization, we can just
9911 // broadcast the scalar value corresponding to lane zero for each unroll
9912 // iteration. Otherwise, we construct the vector values using
9913 // insertelement instructions. Since the resulting vectors are stored in
9914 // State, we will only generate the insertelements once.
9915 Value *VectorValue = nullptr;
9916 if (IsUniform) {
9917 VectorValue = ILV->getBroadcastInstrs(ScalarValue);
9918 set(Def, VectorValue, Part);
9919 } else {
9920 // Initialize packing with insertelements to start from undef.
9921 assert(!VF.isScalable() && "VF is assumed to be non scalable.");
9922 Value *Undef = PoisonValue::get(VectorType::get(LastInst->getType(), VF));
9923 set(Def, Undef, Part);
9924 for (unsigned Lane = 0; Lane < VF.getKnownMinValue(); ++Lane)
9925 ILV->packScalarIntoVectorValue(Def, {Part, Lane}, *this);
9926 VectorValue = get(Def, Part);
9927 }
9928 Builder.restoreIP(OldIP);
9929 return VectorValue;
9930 }
9931
9932 // Process the loop in the VPlan-native vectorization path. This path builds
9933 // VPlan upfront in the vectorization pipeline, which allows to apply
9934 // VPlan-to-VPlan transformations from the very beginning without modifying the
9935 // input LLVM IR.
processLoopInVPlanNativePath(Loop * L,PredicatedScalarEvolution & PSE,LoopInfo * LI,DominatorTree * DT,LoopVectorizationLegality * LVL,TargetTransformInfo * TTI,TargetLibraryInfo * TLI,DemandedBits * DB,AssumptionCache * AC,OptimizationRemarkEmitter * ORE,BlockFrequencyInfo * BFI,ProfileSummaryInfo * PSI,LoopVectorizeHints & Hints,LoopVectorizationRequirements & Requirements)9936 static bool processLoopInVPlanNativePath(
9937 Loop *L, PredicatedScalarEvolution &PSE, LoopInfo *LI, DominatorTree *DT,
9938 LoopVectorizationLegality *LVL, TargetTransformInfo *TTI,
9939 TargetLibraryInfo *TLI, DemandedBits *DB, AssumptionCache *AC,
9940 OptimizationRemarkEmitter *ORE, BlockFrequencyInfo *BFI,
9941 ProfileSummaryInfo *PSI, LoopVectorizeHints &Hints,
9942 LoopVectorizationRequirements &Requirements) {
9943
9944 if (isa<SCEVCouldNotCompute>(PSE.getBackedgeTakenCount())) {
9945 LLVM_DEBUG(dbgs() << "LV: cannot compute the outer-loop trip count\n");
9946 return false;
9947 }
9948 assert(EnableVPlanNativePath && "VPlan-native path is disabled.");
9949 Function *F = L->getHeader()->getParent();
9950 InterleavedAccessInfo IAI(PSE, L, DT, LI, LVL->getLAI());
9951
9952 ScalarEpilogueLowering SEL = getScalarEpilogueLowering(
9953 F, L, Hints, PSI, BFI, TTI, TLI, AC, LI, PSE.getSE(), DT, *LVL);
9954
9955 LoopVectorizationCostModel CM(SEL, L, PSE, LI, LVL, *TTI, TLI, DB, AC, ORE, F,
9956 &Hints, IAI);
9957 // Use the planner for outer loop vectorization.
9958 // TODO: CM is not used at this point inside the planner. Turn CM into an
9959 // optional argument if we don't need it in the future.
9960 LoopVectorizationPlanner LVP(L, LI, TLI, TTI, LVL, CM, IAI, PSE, Hints,
9961 Requirements, ORE);
9962
9963 // Get user vectorization factor.
9964 ElementCount UserVF = Hints.getWidth();
9965
9966 CM.collectElementTypesForWidening();
9967
9968 // Plan how to best vectorize, return the best VF and its cost.
9969 const VectorizationFactor VF = LVP.planInVPlanNativePath(UserVF);
9970
9971 // If we are stress testing VPlan builds, do not attempt to generate vector
9972 // code. Masked vector code generation support will follow soon.
9973 // Also, do not attempt to vectorize if no vector code will be produced.
9974 if (VPlanBuildStressTest || EnableVPlanPredication ||
9975 VectorizationFactor::Disabled() == VF)
9976 return false;
9977
9978 LVP.setBestPlan(VF.Width, 1);
9979
9980 {
9981 GeneratedRTChecks Checks(*PSE.getSE(), DT, LI,
9982 F->getParent()->getDataLayout());
9983 InnerLoopVectorizer LB(L, PSE, LI, DT, TLI, TTI, AC, ORE, VF.Width, 1, LVL,
9984 &CM, BFI, PSI, Checks);
9985 LLVM_DEBUG(dbgs() << "Vectorizing outer loop in \""
9986 << L->getHeader()->getParent()->getName() << "\"\n");
9987 LVP.executePlan(LB, DT);
9988 }
9989
9990 // Mark the loop as already vectorized to avoid vectorizing again.
9991 Hints.setAlreadyVectorized();
9992 assert(!verifyFunction(*L->getHeader()->getParent(), &dbgs()));
9993 return true;
9994 }
9995
9996 // Emit a remark if there are stores to floats that required a floating point
9997 // extension. If the vectorized loop was generated with floating point there
9998 // will be a performance penalty from the conversion overhead and the change in
9999 // the vector width.
checkMixedPrecision(Loop * L,OptimizationRemarkEmitter * ORE)10000 static void checkMixedPrecision(Loop *L, OptimizationRemarkEmitter *ORE) {
10001 SmallVector<Instruction *, 4> Worklist;
10002 for (BasicBlock *BB : L->getBlocks()) {
10003 for (Instruction &Inst : *BB) {
10004 if (auto *S = dyn_cast<StoreInst>(&Inst)) {
10005 if (S->getValueOperand()->getType()->isFloatTy())
10006 Worklist.push_back(S);
10007 }
10008 }
10009 }
10010
10011 // Traverse the floating point stores upwards searching, for floating point
10012 // conversions.
10013 SmallPtrSet<const Instruction *, 4> Visited;
10014 SmallPtrSet<const Instruction *, 4> EmittedRemark;
10015 while (!Worklist.empty()) {
10016 auto *I = Worklist.pop_back_val();
10017 if (!L->contains(I))
10018 continue;
10019 if (!Visited.insert(I).second)
10020 continue;
10021
10022 // Emit a remark if the floating point store required a floating
10023 // point conversion.
10024 // TODO: More work could be done to identify the root cause such as a
10025 // constant or a function return type and point the user to it.
10026 if (isa<FPExtInst>(I) && EmittedRemark.insert(I).second)
10027 ORE->emit([&]() {
10028 return OptimizationRemarkAnalysis(LV_NAME, "VectorMixedPrecision",
10029 I->getDebugLoc(), L->getHeader())
10030 << "floating point conversion changes vector width. "
10031 << "Mixed floating point precision requires an up/down "
10032 << "cast that will negatively impact performance.";
10033 });
10034
10035 for (Use &Op : I->operands())
10036 if (auto *OpI = dyn_cast<Instruction>(Op))
10037 Worklist.push_back(OpI);
10038 }
10039 }
10040
LoopVectorizePass(LoopVectorizeOptions Opts)10041 LoopVectorizePass::LoopVectorizePass(LoopVectorizeOptions Opts)
10042 : InterleaveOnlyWhenForced(Opts.InterleaveOnlyWhenForced ||
10043 !EnableLoopInterleaving),
10044 VectorizeOnlyWhenForced(Opts.VectorizeOnlyWhenForced ||
10045 !EnableLoopVectorization) {}
10046
processLoop(Loop * L)10047 bool LoopVectorizePass::processLoop(Loop *L) {
10048 assert((EnableVPlanNativePath || L->isInnermost()) &&
10049 "VPlan-native path is not enabled. Only process inner loops.");
10050
10051 #ifndef NDEBUG
10052 const std::string DebugLocStr = getDebugLocString(L);
10053 #endif /* NDEBUG */
10054
10055 LLVM_DEBUG(dbgs() << "\nLV: Checking a loop in \""
10056 << L->getHeader()->getParent()->getName() << "\" from "
10057 << DebugLocStr << "\n");
10058
10059 LoopVectorizeHints Hints(L, InterleaveOnlyWhenForced, *ORE);
10060
10061 LLVM_DEBUG(
10062 dbgs() << "LV: Loop hints:"
10063 << " force="
10064 << (Hints.getForce() == LoopVectorizeHints::FK_Disabled
10065 ? "disabled"
10066 : (Hints.getForce() == LoopVectorizeHints::FK_Enabled
10067 ? "enabled"
10068 : "?"))
10069 << " width=" << Hints.getWidth()
10070 << " interleave=" << Hints.getInterleave() << "\n");
10071
10072 // Function containing loop
10073 Function *F = L->getHeader()->getParent();
10074
10075 // Looking at the diagnostic output is the only way to determine if a loop
10076 // was vectorized (other than looking at the IR or machine code), so it
10077 // is important to generate an optimization remark for each loop. Most of
10078 // these messages are generated as OptimizationRemarkAnalysis. Remarks
10079 // generated as OptimizationRemark and OptimizationRemarkMissed are
10080 // less verbose reporting vectorized loops and unvectorized loops that may
10081 // benefit from vectorization, respectively.
10082
10083 if (!Hints.allowVectorization(F, L, VectorizeOnlyWhenForced)) {
10084 LLVM_DEBUG(dbgs() << "LV: Loop hints prevent vectorization.\n");
10085 return false;
10086 }
10087
10088 PredicatedScalarEvolution PSE(*SE, *L);
10089
10090 // Check if it is legal to vectorize the loop.
10091 LoopVectorizationRequirements Requirements;
10092 LoopVectorizationLegality LVL(L, PSE, DT, TTI, TLI, AA, F, GetLAA, LI, ORE,
10093 &Requirements, &Hints, DB, AC, BFI, PSI);
10094 if (!LVL.canVectorize(EnableVPlanNativePath)) {
10095 LLVM_DEBUG(dbgs() << "LV: Not vectorizing: Cannot prove legality.\n");
10096 Hints.emitRemarkWithHints();
10097 return false;
10098 }
10099
10100 // Check the function attributes and profiles to find out if this function
10101 // should be optimized for size.
10102 ScalarEpilogueLowering SEL = getScalarEpilogueLowering(
10103 F, L, Hints, PSI, BFI, TTI, TLI, AC, LI, PSE.getSE(), DT, LVL);
10104
10105 // Entrance to the VPlan-native vectorization path. Outer loops are processed
10106 // here. They may require CFG and instruction level transformations before
10107 // even evaluating whether vectorization is profitable. Since we cannot modify
10108 // the incoming IR, we need to build VPlan upfront in the vectorization
10109 // pipeline.
10110 if (!L->isInnermost())
10111 return processLoopInVPlanNativePath(L, PSE, LI, DT, &LVL, TTI, TLI, DB, AC,
10112 ORE, BFI, PSI, Hints, Requirements);
10113
10114 assert(L->isInnermost() && "Inner loop expected.");
10115
10116 // Check the loop for a trip count threshold: vectorize loops with a tiny trip
10117 // count by optimizing for size, to minimize overheads.
10118 auto ExpectedTC = getSmallBestKnownTC(*SE, L);
10119 if (ExpectedTC && *ExpectedTC < TinyTripCountVectorThreshold) {
10120 LLVM_DEBUG(dbgs() << "LV: Found a loop with a very small trip count. "
10121 << "This loop is worth vectorizing only if no scalar "
10122 << "iteration overheads are incurred.");
10123 if (Hints.getForce() == LoopVectorizeHints::FK_Enabled)
10124 LLVM_DEBUG(dbgs() << " But vectorizing was explicitly forced.\n");
10125 else {
10126 LLVM_DEBUG(dbgs() << "\n");
10127 SEL = CM_ScalarEpilogueNotAllowedLowTripLoop;
10128 }
10129 }
10130
10131 // Check the function attributes to see if implicit floats are allowed.
10132 // FIXME: This check doesn't seem possibly correct -- what if the loop is
10133 // an integer loop and the vector instructions selected are purely integer
10134 // vector instructions?
10135 if (F->hasFnAttribute(Attribute::NoImplicitFloat)) {
10136 reportVectorizationFailure(
10137 "Can't vectorize when the NoImplicitFloat attribute is used",
10138 "loop not vectorized due to NoImplicitFloat attribute",
10139 "NoImplicitFloat", ORE, L);
10140 Hints.emitRemarkWithHints();
10141 return false;
10142 }
10143
10144 // Check if the target supports potentially unsafe FP vectorization.
10145 // FIXME: Add a check for the type of safety issue (denormal, signaling)
10146 // for the target we're vectorizing for, to make sure none of the
10147 // additional fp-math flags can help.
10148 if (Hints.isPotentiallyUnsafe() &&
10149 TTI->isFPVectorizationPotentiallyUnsafe()) {
10150 reportVectorizationFailure(
10151 "Potentially unsafe FP op prevents vectorization",
10152 "loop not vectorized due to unsafe FP support.",
10153 "UnsafeFP", ORE, L);
10154 Hints.emitRemarkWithHints();
10155 return false;
10156 }
10157
10158 if (!LVL.canVectorizeFPMath(EnableStrictReductions)) {
10159 ORE->emit([&]() {
10160 auto *ExactFPMathInst = Requirements.getExactFPInst();
10161 return OptimizationRemarkAnalysisFPCommute(DEBUG_TYPE, "CantReorderFPOps",
10162 ExactFPMathInst->getDebugLoc(),
10163 ExactFPMathInst->getParent())
10164 << "loop not vectorized: cannot prove it is safe to reorder "
10165 "floating-point operations";
10166 });
10167 LLVM_DEBUG(dbgs() << "LV: loop not vectorized: cannot prove it is safe to "
10168 "reorder floating-point operations\n");
10169 Hints.emitRemarkWithHints();
10170 return false;
10171 }
10172
10173 bool UseInterleaved = TTI->enableInterleavedAccessVectorization();
10174 InterleavedAccessInfo IAI(PSE, L, DT, LI, LVL.getLAI());
10175
10176 // If an override option has been passed in for interleaved accesses, use it.
10177 if (EnableInterleavedMemAccesses.getNumOccurrences() > 0)
10178 UseInterleaved = EnableInterleavedMemAccesses;
10179
10180 // Analyze interleaved memory accesses.
10181 if (UseInterleaved) {
10182 IAI.analyzeInterleaving(useMaskedInterleavedAccesses(*TTI));
10183 }
10184
10185 // Use the cost model.
10186 LoopVectorizationCostModel CM(SEL, L, PSE, LI, &LVL, *TTI, TLI, DB, AC, ORE,
10187 F, &Hints, IAI);
10188 CM.collectValuesToIgnore();
10189 CM.collectElementTypesForWidening();
10190
10191 // Use the planner for vectorization.
10192 LoopVectorizationPlanner LVP(L, LI, TLI, TTI, &LVL, CM, IAI, PSE, Hints,
10193 Requirements, ORE);
10194
10195 // Get user vectorization factor and interleave count.
10196 ElementCount UserVF = Hints.getWidth();
10197 unsigned UserIC = Hints.getInterleave();
10198
10199 // Plan how to best vectorize, return the best VF and its cost.
10200 Optional<VectorizationFactor> MaybeVF = LVP.plan(UserVF, UserIC);
10201
10202 VectorizationFactor VF = VectorizationFactor::Disabled();
10203 unsigned IC = 1;
10204
10205 if (MaybeVF) {
10206 VF = *MaybeVF;
10207 // Select the interleave count.
10208 IC = CM.selectInterleaveCount(VF.Width, *VF.Cost.getValue());
10209 }
10210
10211 // Identify the diagnostic messages that should be produced.
10212 std::pair<StringRef, std::string> VecDiagMsg, IntDiagMsg;
10213 bool VectorizeLoop = true, InterleaveLoop = true;
10214 if (VF.Width.isScalar()) {
10215 LLVM_DEBUG(dbgs() << "LV: Vectorization is possible but not beneficial.\n");
10216 VecDiagMsg = std::make_pair(
10217 "VectorizationNotBeneficial",
10218 "the cost-model indicates that vectorization is not beneficial");
10219 VectorizeLoop = false;
10220 }
10221
10222 if (!MaybeVF && UserIC > 1) {
10223 // Tell the user interleaving was avoided up-front, despite being explicitly
10224 // requested.
10225 LLVM_DEBUG(dbgs() << "LV: Ignoring UserIC, because vectorization and "
10226 "interleaving should be avoided up front\n");
10227 IntDiagMsg = std::make_pair(
10228 "InterleavingAvoided",
10229 "Ignoring UserIC, because interleaving was avoided up front");
10230 InterleaveLoop = false;
10231 } else if (IC == 1 && UserIC <= 1) {
10232 // Tell the user interleaving is not beneficial.
10233 LLVM_DEBUG(dbgs() << "LV: Interleaving is not beneficial.\n");
10234 IntDiagMsg = std::make_pair(
10235 "InterleavingNotBeneficial",
10236 "the cost-model indicates that interleaving is not beneficial");
10237 InterleaveLoop = false;
10238 if (UserIC == 1) {
10239 IntDiagMsg.first = "InterleavingNotBeneficialAndDisabled";
10240 IntDiagMsg.second +=
10241 " and is explicitly disabled or interleave count is set to 1";
10242 }
10243 } else if (IC > 1 && UserIC == 1) {
10244 // Tell the user interleaving is beneficial, but it explicitly disabled.
10245 LLVM_DEBUG(
10246 dbgs() << "LV: Interleaving is beneficial but is explicitly disabled.");
10247 IntDiagMsg = std::make_pair(
10248 "InterleavingBeneficialButDisabled",
10249 "the cost-model indicates that interleaving is beneficial "
10250 "but is explicitly disabled or interleave count is set to 1");
10251 InterleaveLoop = false;
10252 }
10253
10254 // Override IC if user provided an interleave count.
10255 IC = UserIC > 0 ? UserIC : IC;
10256
10257 // Emit diagnostic messages, if any.
10258 const char *VAPassName = Hints.vectorizeAnalysisPassName();
10259 if (!VectorizeLoop && !InterleaveLoop) {
10260 // Do not vectorize or interleaving the loop.
10261 ORE->emit([&]() {
10262 return OptimizationRemarkMissed(VAPassName, VecDiagMsg.first,
10263 L->getStartLoc(), L->getHeader())
10264 << VecDiagMsg.second;
10265 });
10266 ORE->emit([&]() {
10267 return OptimizationRemarkMissed(LV_NAME, IntDiagMsg.first,
10268 L->getStartLoc(), L->getHeader())
10269 << IntDiagMsg.second;
10270 });
10271 return false;
10272 } else if (!VectorizeLoop && InterleaveLoop) {
10273 LLVM_DEBUG(dbgs() << "LV: Interleave Count is " << IC << '\n');
10274 ORE->emit([&]() {
10275 return OptimizationRemarkAnalysis(VAPassName, VecDiagMsg.first,
10276 L->getStartLoc(), L->getHeader())
10277 << VecDiagMsg.second;
10278 });
10279 } else if (VectorizeLoop && !InterleaveLoop) {
10280 LLVM_DEBUG(dbgs() << "LV: Found a vectorizable loop (" << VF.Width
10281 << ") in " << DebugLocStr << '\n');
10282 ORE->emit([&]() {
10283 return OptimizationRemarkAnalysis(LV_NAME, IntDiagMsg.first,
10284 L->getStartLoc(), L->getHeader())
10285 << IntDiagMsg.second;
10286 });
10287 } else if (VectorizeLoop && InterleaveLoop) {
10288 LLVM_DEBUG(dbgs() << "LV: Found a vectorizable loop (" << VF.Width
10289 << ") in " << DebugLocStr << '\n');
10290 LLVM_DEBUG(dbgs() << "LV: Interleave Count is " << IC << '\n');
10291 }
10292
10293 bool DisableRuntimeUnroll = false;
10294 MDNode *OrigLoopID = L->getLoopID();
10295 {
10296 // Optimistically generate runtime checks. Drop them if they turn out to not
10297 // be profitable. Limit the scope of Checks, so the cleanup happens
10298 // immediately after vector codegeneration is done.
10299 GeneratedRTChecks Checks(*PSE.getSE(), DT, LI,
10300 F->getParent()->getDataLayout());
10301 if (!VF.Width.isScalar() || IC > 1)
10302 Checks.Create(L, *LVL.getLAI(), PSE.getUnionPredicate());
10303 LVP.setBestPlan(VF.Width, IC);
10304
10305 using namespace ore;
10306 if (!VectorizeLoop) {
10307 assert(IC > 1 && "interleave count should not be 1 or 0");
10308 // If we decided that it is not legal to vectorize the loop, then
10309 // interleave it.
10310 InnerLoopUnroller Unroller(L, PSE, LI, DT, TLI, TTI, AC, ORE, IC, &LVL,
10311 &CM, BFI, PSI, Checks);
10312 LVP.executePlan(Unroller, DT);
10313
10314 ORE->emit([&]() {
10315 return OptimizationRemark(LV_NAME, "Interleaved", L->getStartLoc(),
10316 L->getHeader())
10317 << "interleaved loop (interleaved count: "
10318 << NV("InterleaveCount", IC) << ")";
10319 });
10320 } else {
10321 // If we decided that it is *legal* to vectorize the loop, then do it.
10322
10323 // Consider vectorizing the epilogue too if it's profitable.
10324 VectorizationFactor EpilogueVF =
10325 CM.selectEpilogueVectorizationFactor(VF.Width, LVP);
10326 if (EpilogueVF.Width.isVector()) {
10327
10328 // The first pass vectorizes the main loop and creates a scalar epilogue
10329 // to be vectorized by executing the plan (potentially with a different
10330 // factor) again shortly afterwards.
10331 EpilogueLoopVectorizationInfo EPI(VF.Width.getKnownMinValue(), IC,
10332 EpilogueVF.Width.getKnownMinValue(),
10333 1);
10334 EpilogueVectorizerMainLoop MainILV(L, PSE, LI, DT, TLI, TTI, AC, ORE,
10335 EPI, &LVL, &CM, BFI, PSI, Checks);
10336
10337 LVP.setBestPlan(EPI.MainLoopVF, EPI.MainLoopUF);
10338 LVP.executePlan(MainILV, DT);
10339 ++LoopsVectorized;
10340
10341 simplifyLoop(L, DT, LI, SE, AC, nullptr, false /* PreserveLCSSA */);
10342 formLCSSARecursively(*L, *DT, LI, SE);
10343
10344 // Second pass vectorizes the epilogue and adjusts the control flow
10345 // edges from the first pass.
10346 LVP.setBestPlan(EPI.EpilogueVF, EPI.EpilogueUF);
10347 EPI.MainLoopVF = EPI.EpilogueVF;
10348 EPI.MainLoopUF = EPI.EpilogueUF;
10349 EpilogueVectorizerEpilogueLoop EpilogILV(L, PSE, LI, DT, TLI, TTI, AC,
10350 ORE, EPI, &LVL, &CM, BFI, PSI,
10351 Checks);
10352 LVP.executePlan(EpilogILV, DT);
10353 ++LoopsEpilogueVectorized;
10354
10355 if (!MainILV.areSafetyChecksAdded())
10356 DisableRuntimeUnroll = true;
10357 } else {
10358 InnerLoopVectorizer LB(L, PSE, LI, DT, TLI, TTI, AC, ORE, VF.Width, IC,
10359 &LVL, &CM, BFI, PSI, Checks);
10360 LVP.executePlan(LB, DT);
10361 ++LoopsVectorized;
10362
10363 // Add metadata to disable runtime unrolling a scalar loop when there
10364 // are no runtime checks about strides and memory. A scalar loop that is
10365 // rarely used is not worth unrolling.
10366 if (!LB.areSafetyChecksAdded())
10367 DisableRuntimeUnroll = true;
10368 }
10369 // Report the vectorization decision.
10370 ORE->emit([&]() {
10371 return OptimizationRemark(LV_NAME, "Vectorized", L->getStartLoc(),
10372 L->getHeader())
10373 << "vectorized loop (vectorization width: "
10374 << NV("VectorizationFactor", VF.Width)
10375 << ", interleaved count: " << NV("InterleaveCount", IC) << ")";
10376 });
10377 }
10378
10379 if (ORE->allowExtraAnalysis(LV_NAME))
10380 checkMixedPrecision(L, ORE);
10381 }
10382
10383 Optional<MDNode *> RemainderLoopID =
10384 makeFollowupLoopID(OrigLoopID, {LLVMLoopVectorizeFollowupAll,
10385 LLVMLoopVectorizeFollowupEpilogue});
10386 if (RemainderLoopID.hasValue()) {
10387 L->setLoopID(RemainderLoopID.getValue());
10388 } else {
10389 if (DisableRuntimeUnroll)
10390 AddRuntimeUnrollDisableMetaData(L);
10391
10392 // Mark the loop as already vectorized to avoid vectorizing again.
10393 Hints.setAlreadyVectorized();
10394 }
10395
10396 assert(!verifyFunction(*L->getHeader()->getParent(), &dbgs()));
10397 return true;
10398 }
10399
runImpl(Function & F,ScalarEvolution & SE_,LoopInfo & LI_,TargetTransformInfo & TTI_,DominatorTree & DT_,BlockFrequencyInfo & BFI_,TargetLibraryInfo * TLI_,DemandedBits & DB_,AAResults & AA_,AssumptionCache & AC_,std::function<const LoopAccessInfo & (Loop &)> & GetLAA_,OptimizationRemarkEmitter & ORE_,ProfileSummaryInfo * PSI_)10400 LoopVectorizeResult LoopVectorizePass::runImpl(
10401 Function &F, ScalarEvolution &SE_, LoopInfo &LI_, TargetTransformInfo &TTI_,
10402 DominatorTree &DT_, BlockFrequencyInfo &BFI_, TargetLibraryInfo *TLI_,
10403 DemandedBits &DB_, AAResults &AA_, AssumptionCache &AC_,
10404 std::function<const LoopAccessInfo &(Loop &)> &GetLAA_,
10405 OptimizationRemarkEmitter &ORE_, ProfileSummaryInfo *PSI_) {
10406 SE = &SE_;
10407 LI = &LI_;
10408 TTI = &TTI_;
10409 DT = &DT_;
10410 BFI = &BFI_;
10411 TLI = TLI_;
10412 AA = &AA_;
10413 AC = &AC_;
10414 GetLAA = &GetLAA_;
10415 DB = &DB_;
10416 ORE = &ORE_;
10417 PSI = PSI_;
10418
10419 // Don't attempt if
10420 // 1. the target claims to have no vector registers, and
10421 // 2. interleaving won't help ILP.
10422 //
10423 // The second condition is necessary because, even if the target has no
10424 // vector registers, loop vectorization may still enable scalar
10425 // interleaving.
10426 if (!TTI->getNumberOfRegisters(TTI->getRegisterClassForType(true)) &&
10427 TTI->getMaxInterleaveFactor(1) < 2)
10428 return LoopVectorizeResult(false, false);
10429
10430 bool Changed = false, CFGChanged = false;
10431
10432 // The vectorizer requires loops to be in simplified form.
10433 // Since simplification may add new inner loops, it has to run before the
10434 // legality and profitability checks. This means running the loop vectorizer
10435 // will simplify all loops, regardless of whether anything end up being
10436 // vectorized.
10437 for (auto &L : *LI)
10438 Changed |= CFGChanged |=
10439 simplifyLoop(L, DT, LI, SE, AC, nullptr, false /* PreserveLCSSA */);
10440
10441 // Build up a worklist of inner-loops to vectorize. This is necessary as
10442 // the act of vectorizing or partially unrolling a loop creates new loops
10443 // and can invalidate iterators across the loops.
10444 SmallVector<Loop *, 8> Worklist;
10445
10446 for (Loop *L : *LI)
10447 collectSupportedLoops(*L, LI, ORE, Worklist);
10448
10449 LoopsAnalyzed += Worklist.size();
10450
10451 // Now walk the identified inner loops.
10452 while (!Worklist.empty()) {
10453 Loop *L = Worklist.pop_back_val();
10454
10455 // For the inner loops we actually process, form LCSSA to simplify the
10456 // transform.
10457 Changed |= formLCSSARecursively(*L, *DT, LI, SE);
10458
10459 Changed |= CFGChanged |= processLoop(L);
10460 }
10461
10462 // Process each loop nest in the function.
10463 return LoopVectorizeResult(Changed, CFGChanged);
10464 }
10465
run(Function & F,FunctionAnalysisManager & AM)10466 PreservedAnalyses LoopVectorizePass::run(Function &F,
10467 FunctionAnalysisManager &AM) {
10468 auto &SE = AM.getResult<ScalarEvolutionAnalysis>(F);
10469 auto &LI = AM.getResult<LoopAnalysis>(F);
10470 auto &TTI = AM.getResult<TargetIRAnalysis>(F);
10471 auto &DT = AM.getResult<DominatorTreeAnalysis>(F);
10472 auto &BFI = AM.getResult<BlockFrequencyAnalysis>(F);
10473 auto &TLI = AM.getResult<TargetLibraryAnalysis>(F);
10474 auto &AA = AM.getResult<AAManager>(F);
10475 auto &AC = AM.getResult<AssumptionAnalysis>(F);
10476 auto &DB = AM.getResult<DemandedBitsAnalysis>(F);
10477 auto &ORE = AM.getResult<OptimizationRemarkEmitterAnalysis>(F);
10478 MemorySSA *MSSA = EnableMSSALoopDependency
10479 ? &AM.getResult<MemorySSAAnalysis>(F).getMSSA()
10480 : nullptr;
10481
10482 auto &LAM = AM.getResult<LoopAnalysisManagerFunctionProxy>(F).getManager();
10483 std::function<const LoopAccessInfo &(Loop &)> GetLAA =
10484 [&](Loop &L) -> const LoopAccessInfo & {
10485 LoopStandardAnalysisResults AR = {AA, AC, DT, LI, SE,
10486 TLI, TTI, nullptr, MSSA};
10487 return LAM.getResult<LoopAccessAnalysis>(L, AR);
10488 };
10489 auto &MAMProxy = AM.getResult<ModuleAnalysisManagerFunctionProxy>(F);
10490 ProfileSummaryInfo *PSI =
10491 MAMProxy.getCachedResult<ProfileSummaryAnalysis>(*F.getParent());
10492 LoopVectorizeResult Result =
10493 runImpl(F, SE, LI, TTI, DT, BFI, &TLI, DB, AA, AC, GetLAA, ORE, PSI);
10494 if (!Result.MadeAnyChange)
10495 return PreservedAnalyses::all();
10496 PreservedAnalyses PA;
10497
10498 // We currently do not preserve loopinfo/dominator analyses with outer loop
10499 // vectorization. Until this is addressed, mark these analyses as preserved
10500 // only for non-VPlan-native path.
10501 // TODO: Preserve Loop and Dominator analyses for VPlan-native path.
10502 if (!EnableVPlanNativePath) {
10503 PA.preserve<LoopAnalysis>();
10504 PA.preserve<DominatorTreeAnalysis>();
10505 }
10506 if (!Result.MadeCFGChange)
10507 PA.preserveSet<CFGAnalyses>();
10508 return PA;
10509 }
10510