LLVM 24.0.0git
LoopVectorize.cpp
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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/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
58#include "VPRecipeBuilder.h"
59#include "VPlan.h"
60#include "VPlanAnalysis.h"
61#include "VPlanCFG.h"
62#include "VPlanHelpers.h"
63#include "VPlanPatternMatch.h"
64#include "VPlanTransforms.h"
65#include "VPlanUtils.h"
66#include "VPlanVerifier.h"
67#include "llvm/ADT/APInt.h"
68#include "llvm/ADT/ArrayRef.h"
69#include "llvm/ADT/DenseMap.h"
71#include "llvm/ADT/Hashing.h"
72#include "llvm/ADT/MapVector.h"
73#include "llvm/ADT/STLExtras.h"
76#include "llvm/ADT/Statistic.h"
77#include "llvm/ADT/StringRef.h"
78#include "llvm/ADT/Twine.h"
79#include "llvm/ADT/TypeSwitch.h"
84#include "llvm/Analysis/CFG.h"
101#include "llvm/IR/Attributes.h"
102#include "llvm/IR/BasicBlock.h"
103#include "llvm/IR/CFG.h"
104#include "llvm/IR/Constant.h"
105#include "llvm/IR/Constants.h"
106#include "llvm/IR/DataLayout.h"
107#include "llvm/IR/DebugInfo.h"
108#include "llvm/IR/DebugLoc.h"
109#include "llvm/IR/DerivedTypes.h"
111#include "llvm/IR/Dominators.h"
112#include "llvm/IR/Function.h"
113#include "llvm/IR/IRBuilder.h"
114#include "llvm/IR/InstrTypes.h"
115#include "llvm/IR/Instruction.h"
116#include "llvm/IR/Instructions.h"
118#include "llvm/IR/Intrinsics.h"
119#include "llvm/IR/MDBuilder.h"
120#include "llvm/IR/Metadata.h"
121#include "llvm/IR/Module.h"
122#include "llvm/IR/Operator.h"
123#include "llvm/IR/PatternMatch.h"
125#include "llvm/IR/Type.h"
126#include "llvm/IR/Use.h"
127#include "llvm/IR/User.h"
128#include "llvm/IR/Value.h"
129#include "llvm/IR/Verifier.h"
130#include "llvm/Support/Casting.h"
132#include "llvm/Support/Debug.h"
147#include <algorithm>
148#include <cassert>
149#include <cmath>
150#include <cstdint>
151#include <functional>
152#include <iterator>
153#include <limits>
154#include <memory>
155#include <string>
156#include <tuple>
157#include <utility>
158
159using namespace llvm;
160using namespace SCEVPatternMatch;
161using namespace LoopVectorizationUtils;
162
163#define LV_NAME "loop-vectorize"
164#define DEBUG_TYPE LV_NAME
165
166#ifndef NDEBUG
167const char VerboseDebug[] = DEBUG_TYPE "-verbose";
168#endif
169
170STATISTIC(LoopsVectorized, "Number of loops vectorized");
171STATISTIC(LoopsAnalyzed, "Number of loops analyzed for vectorization");
172STATISTIC(LoopsEpilogueVectorized, "Number of epilogues vectorized");
173STATISTIC(LoopsEarlyExitVectorized, "Number of early exit loops vectorized");
174STATISTIC(LoopsPartialAliasVectorized,
175 "Number of partial aliasing loops vectorized");
176
178 "enable-epilogue-vectorization", cl::init(true), cl::Hidden,
179 cl::desc("Enable vectorization of epilogue loops."));
180
182 "epilogue-vectorization-force-VF", cl::init(ElementCount::getFixed(1)),
184 cl::desc("When epilogue vectorization is enabled, and a value greater than "
185 "1 is specified, forces the given VF for all applicable epilogue "
186 "loops. Note: This allows all scalable VFs >= vscale x 1."));
187
189 "epilogue-vectorization-minimum-VF", cl::Hidden,
190 cl::desc("Only loops with vectorization factor equal to or larger than "
191 "the specified value are considered for epilogue vectorization."));
192
193/// Loops with a known constant trip count below this number are vectorized only
194/// if no scalar iteration overheads are incurred.
196 "vectorizer-min-trip-count", cl::init(16), cl::Hidden,
197 cl::desc("Loops with a constant trip count that is smaller than this "
198 "value are vectorized only if no scalar iteration overheads "
199 "are incurred."));
200
202 "vectorize-memory-check-threshold", cl::init(128), cl::Hidden,
203 cl::desc("The maximum allowed number of runtime memory checks"));
204
206 "force-partial-aliasing-vectorization", cl::init(false), cl::Hidden,
207 cl::desc("Replace pointer diff checks with alias masks."));
208
209/// Option tail-folding-policy controls the tail-folding strategy and lists all
210/// available options. The vectorizer will attempt to fold the tail-loop into
211/// the vector loop (main/epilogue loops) and predicate the instructions
212/// accordingly. If tail-folding fails, there are different fallback strategies
213/// depending on these values:
215
217 "tail-folding-policy", cl::init(TailFoldingPolicyTy::None), cl::Hidden,
218 cl::desc("Tail-folding preferences over creating an epilogue loop."),
220 clEnumValN(TailFoldingPolicyTy::None, "dont-fold-tail",
221 "Don't tail-fold loops."),
223 "prefer tail-folding, otherwise create an epilogue when "
224 "appropriate."),
226 "always tail-fold, don't attempt vectorization if "
227 "tail-folding fails.")));
228
230 "epilogue-tail-folding-policy", cl::Hidden,
231 cl::desc(
232 "Epilogue-tail-folding preferences over creating an epilogue loop."),
234 clEnumValN(TailFoldingPolicyTy::None, "dont-fold-tail",
235 "Don't tail-fold loops."),
237 "prefer tail-folding, otherwise create an epilogue when "
238 "appropriate.")));
239
241 "force-tail-folding-style", cl::desc("Force the tail folding style"),
244 clEnumValN(TailFoldingStyle::None, "none", "Disable tail folding"),
247 "Create lane mask for data only, using active.lane.mask intrinsic"),
249 "data-without-lane-mask",
250 "Create lane mask with compare/stepvector"),
252 "Create lane mask using active.lane.mask intrinsic, and use "
253 "it for both data and control flow"),
255 "Use predicated EVL instructions for tail folding. If EVL "
256 "is unsupported, fallback to data-without-lane-mask.")));
257
259 "enable-wide-lane-mask", cl::init(false), cl::Hidden,
260 cl::desc("Enable use of wide lane masks when used for control flow in "
261 "tail-folded loops"));
262
264 "enable-interleaved-mem-accesses", cl::init(false), cl::Hidden,
265 cl::desc("Enable vectorization on interleaved memory accesses in a loop"));
266
267/// An interleave-group may need masking if it resides in a block that needs
268/// predication, or in order to mask away gaps.
270 "enable-masked-interleaved-mem-accesses", cl::init(false), cl::Hidden,
271 cl::desc("Enable vectorization on masked interleaved memory accesses in a loop"));
272
274 "force-target-num-scalar-regs", cl::init(0), cl::Hidden,
275 cl::desc("A flag that overrides the target's number of scalar registers."));
276
278 "force-target-num-vector-regs", cl::init(0), cl::Hidden,
279 cl::desc("A flag that overrides the target's number of vector registers."));
280
282 "force-target-max-scalar-interleave", cl::init(0), cl::Hidden,
283 cl::desc("A flag that overrides the target's max interleave factor for "
284 "scalar loops."));
285
287 "force-target-max-vector-interleave", cl::init(0), cl::Hidden,
288 cl::desc("A flag that overrides the target's max interleave factor for "
289 "vectorized loops."));
290
292 "force-target-instruction-cost", cl::init(0), cl::Hidden,
293 cl::desc("A flag that overrides the target's expected cost for "
294 "an instruction to a single constant value. Mostly "
295 "useful for getting consistent testing."));
296
298 "small-loop-cost", cl::init(20), cl::Hidden,
299 cl::desc(
300 "The cost of a loop that is considered 'small' by the interleaver."));
301
303 "loop-vectorize-with-block-frequency", cl::init(true), cl::Hidden,
304 cl::desc("Enable the use of the block frequency analysis to access PGO "
305 "heuristics minimizing code growth in cold regions and being more "
306 "aggressive in hot regions."));
307
308// Runtime interleave loops for load/store throughput.
310 "enable-loadstore-runtime-interleave", cl::init(true), cl::Hidden,
311 cl::desc(
312 "Enable runtime interleaving until load/store ports are saturated"));
313
314/// The number of stores in a loop that are allowed to need predication.
316 "vectorize-num-stores-pred", cl::init(1), cl::Hidden,
317 cl::desc("Max number of stores to be predicated behind an if."));
318
319// TODO: Move size-based thresholds out of legality checking, make cost based
320// decisions instead of hard thresholds.
322 "vectorize-scev-check-threshold", cl::init(16), cl::Hidden,
323 cl::desc("The maximum number of SCEV checks allowed."));
324
326 "pragma-vectorize-scev-check-threshold", cl::init(128), cl::Hidden,
327 cl::desc("The maximum number of SCEV checks allowed with a "
328 "vectorize(enable) pragma"));
329
331 "enable-ind-var-reg-heur", cl::init(true), cl::Hidden,
332 cl::desc("Count the induction variable only once when interleaving"));
333
335 "max-nested-scalar-reduction-interleave", cl::init(2), cl::Hidden,
336 cl::desc("The maximum interleave count to use when interleaving a scalar "
337 "reduction in a nested loop."));
338
340 "force-ordered-reductions", cl::init(false), cl::Hidden,
341 cl::desc("Enable the vectorisation of loops with in-order (strict) "
342 "FP reductions"));
343
345 "prefer-predicated-reduction-select", cl::init(false), cl::Hidden,
346 cl::desc(
347 "Prefer predicating a reduction operation over an after loop select."));
348
350 "enable-vplan-native-path", cl::Hidden,
351 cl::desc("Enable VPlan-native vectorization path with "
352 "support for outer loop vectorization."));
353
355 llvm::VerifyEachVPlan("vplan-verify-each",
356#ifdef EXPENSIVE_CHECKS
357 cl::init(true),
358#else
359 cl::init(false),
360#endif
362 cl::desc("Verify VPlans after VPlan transforms."));
363
364#if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
366 "vplan-print-before-all", cl::init(false), cl::Hidden,
367 cl::desc("Print VPlans before all VPlan transformations."));
368
370 "vplan-print-after-all", cl::init(false), cl::Hidden,
371 cl::desc("Print VPlans after all VPlan transformations."));
372
374 "vplan-print-before", cl::Hidden,
375 cl::desc("Print VPlans before specified VPlan transformations (regexp)."));
376
378 "vplan-print-after", cl::Hidden,
379 cl::desc("Print VPlans after specified VPlan transformations (regexp)."));
380
382 "vplan-print-vector-region-scope", cl::init(false), cl::Hidden,
383 cl::desc("Limit VPlan printing to vector loop region in "
384 "`-vplan-print-after*` if the plan has one."));
385#endif
386
387// This flag enables the stress testing of the VPlan H-CFG construction in the
388// VPlan-native vectorization path. It must be used in conjuction with
389// -enable-vplan-native-path. -vplan-verify-hcfg can also be used to enable the
390// verification of the H-CFGs built.
392 "vplan-build-outerloop-stress-test", cl::init(false), cl::Hidden,
393 cl::desc(
394 "Build VPlan for every supported loop nest in the function and bail "
395 "out right after the build (stress test the VPlan H-CFG construction "
396 "in the VPlan-native vectorization path)."));
397
399 "interleave-loops", cl::init(true), cl::Hidden,
400 cl::desc("Enable loop interleaving in Loop vectorization passes"));
402 "vectorize-loops", cl::init(true), cl::Hidden,
403 cl::desc("Run the Loop vectorization passes"));
404
406 ForceMaskedDivRem("force-widen-divrem-via-masked-intrinsic", cl::Hidden,
407 cl::desc("Override cost based masked intrinsic widening "
408 "for div/rem instructions"));
409
411 "enable-early-exit-vectorization", cl::init(true), cl::Hidden,
412 cl::desc(
413 "Enable vectorization of early exit loops with uncountable exits."));
414
416 "enable-early-exit-vectorization-with-side-effects", cl::init(false),
418 cl::desc("Enable vectorization of early exit loops with uncountable exits "
419 "and side effects"));
420
421// Returns true if the epilogue VF has been set to a non-zero value other than
422// VF=1 (scalar).
427
428// Likelyhood of bypassing the vectorized loop because there are zero trips left
429// after prolog. See `emitIterationCountCheck`.
430static constexpr uint32_t MinItersBypassWeights[] = {1, 127};
431
432/// A version of ScalarEvolution::getSmallConstantTripCount that returns an
433/// ElementCount to include loops whose trip count is a function of vscale.
435 const Loop *L) {
436 if (unsigned ExpectedTC = SE->getSmallConstantTripCount(L))
437 return ElementCount::getFixed(ExpectedTC);
438
439 const SCEV *BTC = SE->getBackedgeTakenCount(L);
441 return ElementCount::getFixed(0);
442
443 const SCEV *ExitCount = SE->getTripCountFromExitCount(BTC, BTC->getType(), L);
444 if (isa<SCEVVScale>(ExitCount))
446
447 const APInt *Scale;
448 if (match(ExitCount, m_scev_Mul(m_scev_APInt(Scale), m_SCEVVScale())))
449 if (cast<SCEVMulExpr>(ExitCount)->hasNoUnsignedWrap())
450 if (Scale->getActiveBits() <= 32)
452
453 return ElementCount::getFixed(0);
454}
455
456/// Get the maximum trip count for \p L from the SCEV unsigned range, excluding
457/// zero from the range. Only valid when not folding the tail, as the minimum
458/// iteration count check guards against a zero trip count. Returns 0 if
459/// unknown.
461 Loop *L) {
462 const SCEV *BTC = PSE.getBackedgeTakenCount();
464 return 0;
465 ScalarEvolution *SE = PSE.getSE();
466 const SCEV *TripCount = SE->getTripCountFromExitCount(BTC, BTC->getType(), L);
467 ConstantRange TCRange = SE->getUnsignedRange(TripCount);
468 APInt MaxTCFromRange = TCRange.getUnsignedMax();
469 if (!MaxTCFromRange.isZero() && MaxTCFromRange.getActiveBits() <= 32)
470 return MaxTCFromRange.getZExtValue();
471 return 0;
472}
473
474/// Returns "best known" trip count, which is either a valid positive trip count
475/// or std::nullopt when an estimate cannot be made (including when the trip
476/// count would overflow), for the specified loop \p L as defined by the
477/// following procedure:
478/// 1) Returns exact trip count if it is known.
479/// 2) Returns expected trip count according to profile data if any.
480/// 3) Returns upper bound estimate if known, if \p CanUseConstantMax, and
481/// if \p ComputeUpperBoundOnly is false.
482/// 4) Returns the maximum trip count from the SCEV range excluding zero,
483/// if \p CanUseConstantMax and \p CanExcludeZeroTrips.
484/// 5) Returns std::nullopt if all of the above failed.
485static std::optional<ElementCount> getSmallBestKnownTC(
486 PredicatedScalarEvolution &PSE, Loop *L, bool CanUseConstantMax = true,
487 bool CanExcludeZeroTrips = false, bool ComputeUpperBoundOnly = false) {
488 // Check if exact trip count is known.
489 if (auto ExpectedTC = getSmallConstantTripCount(PSE.getSE(), L))
490 return ExpectedTC;
491
492 // Check if there is an expected trip count available from profile data.
493 if (LoopVectorizeWithBlockFrequency && !ComputeUpperBoundOnly)
494 if (auto EstimatedTC = getLoopEstimatedTripCount(L))
495 return ElementCount::getFixed(*EstimatedTC);
496
497 if (!CanUseConstantMax)
498 return std::nullopt;
499
500 // Check if upper bound estimate is known.
501 if (unsigned ExpectedTC = PSE.getSmallConstantMaxTripCount())
502 return ElementCount::getFixed(ExpectedTC);
503
504 // Get the maximum trip count from the SCEV range excluding zero. This is
505 // only safe when not folding the tail, as the minimum iteration count check
506 // prevents entering the vector loop with a zero trip count.
507 if (CanUseConstantMax && CanExcludeZeroTrips)
508 if (unsigned RefinedTC = getMaxTCFromNonZeroRange(PSE, L))
509 return ElementCount::getFixed(RefinedTC);
510
511 return std::nullopt;
512}
513
514namespace {
515// Forward declare GeneratedRTChecks.
516class GeneratedRTChecks;
517
518using SCEV2ValueTy = DenseMap<const SCEV *, Value *>;
519} // namespace
520
521namespace llvm {
522
524
525/// InnerLoopVectorizer vectorizes loops which contain only one basic
526/// block to a specified vectorization factor (VF).
527/// This class performs the widening of scalars into vectors, or multiple
528/// scalars. This class also implements the following features:
529/// * It inserts an epilogue loop for handling loops that don't have iteration
530/// counts that are known to be a multiple of the vectorization factor.
531/// * It handles the code generation for reduction variables.
532/// * Scalarization (implementation using scalars) of un-vectorizable
533/// instructions.
534/// InnerLoopVectorizer does not perform any vectorization-legality
535/// checks, and relies on the caller to check for the different legality
536/// aspects. The InnerLoopVectorizer relies on the
537/// LoopVectorizationLegality class to provide information about the induction
538/// and reduction variables that were found to a given vectorization factor.
540public:
544 ElementCount VecWidth, unsigned UnrollFactor,
546 GeneratedRTChecks &RTChecks, VPlan &Plan)
547 : OrigLoop(OrigLoop), PSE(PSE), LI(LI), DT(DT), TTI(TTI), AC(AC),
548 VF(VecWidth), UF(UnrollFactor), Builder(PSE.getSE()->getContext()),
551 Plan.getVectorLoopRegion()->getSinglePredecessor())) {}
552
553 virtual ~InnerLoopVectorizer() = default;
554
555 /// Creates a basic block for the scalar preheader. Both
556 /// EpilogueVectorizerMainLoop and EpilogueVectorizerEpilogueLoop overwrite
557 /// the method to create additional blocks and checks needed for epilogue
558 /// vectorization.
560
561 /// Fix the vectorized code, taking care of header phi's, and more.
563
564protected:
566
567 /// Create and return a new IR basic block for the scalar preheader whose name
568 /// is prefixed with \p Prefix.
570
571 /// Allow subclasses to override and print debug traces before/after vplan
572 /// execution, when trace information is requested.
573 virtual void printDebugTracesAtStart() {}
574 virtual void printDebugTracesAtEnd() {}
575
576 /// The original loop.
578
579 /// A wrapper around ScalarEvolution used to add runtime SCEV checks. Applies
580 /// dynamic knowledge to simplify SCEV expressions and converts them to a
581 /// more usable form.
583
584 /// Loop Info.
586
587 /// Dominator Tree.
589
590 /// Target Transform Info.
592
593 /// Assumption Cache.
595
596 /// The vectorization SIMD factor to use. Each vector will have this many
597 /// vector elements.
599
600 /// The vectorization unroll factor to use. Each scalar is vectorized to this
601 /// many different vector instructions.
602 unsigned UF;
603
604 /// The builder that we use
606
607 // --- Vectorization state ---
608
609 /// The profitablity analysis.
611
612 /// Structure to hold information about generated runtime checks, responsible
613 /// for cleaning the checks, if vectorization turns out unprofitable.
614 GeneratedRTChecks &RTChecks;
615
617
618 /// The vector preheader block of \p Plan, used as target for check blocks
619 /// introduced during skeleton creation.
621};
622
623/// Encapsulate information regarding vectorization of a loop and its epilogue.
624/// This information is meant to be updated and used across two stages of
625/// epilogue vectorization.
628 unsigned MainLoopUF = 0;
630 unsigned EpilogueUF = 0;
635
637 ElementCount EVF, unsigned EUF,
639 : MainLoopVF(MVF), MainLoopUF(MUF), EpilogueVF(EVF), EpilogueUF(EUF),
641 assert(EUF == 1 &&
642 "A high UF for the epilogue loop is likely not beneficial.");
643 }
644};
645
646/// An extension of the inner loop vectorizer that creates a skeleton for a
647/// vectorized loop that has its epilogue (residual) also vectorized.
648/// The idea is to run the vplan on a given loop twice, firstly to setup the
649/// skeleton and vectorize the main loop, and secondly to complete the skeleton
650/// from the first step and vectorize the epilogue. This is achieved by
651/// deriving two concrete strategy classes from this base class and invoking
652/// them in succession from the loop vectorizer planner.
654public:
661 GeneratedRTChecks &Checks, VPlan &Plan,
662 ElementCount VecWidth, unsigned UnrollFactor)
663 : InnerLoopVectorizer(OrigLoop, PSE, LI, DT, TTI, AC, VecWidth,
664 UnrollFactor, CM, Checks, Plan),
665 EPI(EPI) {}
666
667 /// Holds and updates state information required to vectorize the main loop
668 /// and its epilogue in two separate passes. This setup helps us avoid
669 /// regenerating and recomputing runtime safety checks. It also helps us to
670 /// shorten the iteration-count-check path length for the cases where the
671 /// iteration count of the loop is so small that the main vector loop is
672 /// completely skipped.
674};
675
676/// A specialized derived class of inner loop vectorizer that performs
677/// vectorization of *main* loops in the process of vectorizing loops and their
678/// epilogues.
680public:
691
692protected:
693 void printDebugTracesAtStart() override;
694 void printDebugTracesAtEnd() override;
695};
696
697// A specialized derived class of inner loop vectorizer that performs
698// vectorization of *epilogue* loops in the process of vectorizing loops and
699// their epilogues.
701public:
712 /// Implements the interface for creating a vectorized skeleton using the
713 /// *epilogue loop* strategy (i.e., the second pass of VPlan execution).
715
716protected:
717 void printDebugTracesAtStart() override;
718 void printDebugTracesAtEnd() override;
719};
720} // end namespace llvm
721
722/// Look for a meaningful debug location on the instruction or its operands.
724 if (!I)
725 return DebugLoc::getUnknown();
726
728 if (I->getDebugLoc() != Empty)
729 return I->getDebugLoc();
730
731 for (Use &Op : I->operands()) {
732 if (Instruction *OpInst = dyn_cast<Instruction>(Op))
733 if (OpInst->getDebugLoc() != Empty)
734 return OpInst->getDebugLoc();
735 }
736
737 return I->getDebugLoc();
738}
739
740namespace llvm {
741
742/// Return the runtime value for VF.
744 return B.CreateElementCount(Ty, VF);
745}
746
747} // end namespace llvm
748
749namespace llvm {
750
751// Loop vectorization cost-model hints how the epilogue/tail loop should be
752// lowered.
754
755 // The default: allowing epilogues.
757
758 // Vectorization with OptForSize: don't allow epilogues.
760
761 // A special case of vectorisation with OptForSize: loops with a very small
762 // trip count are considered for vectorization under OptForSize, thereby
763 // making sure the cost of their loop body is dominant, free of runtime
764 // guards and scalar iteration overheads.
766
767 // Loop hint indicating an epilogue is undesired, apply tail folding.
769
770 // Directive indicating we must either fold the epilogue/tail or not vectorize
772};
773
775
776/// LoopVectorizationCostModel - estimates the expected speedups due to
777/// vectorization.
778/// In many cases vectorization is not profitable. This can happen because of
779/// a number of reasons. In this class we mainly attempt to predict the
780/// expected speedup/slowdowns due to the supported instruction set. We use the
781/// TargetTransformInfo to query the different backends for the cost of
782/// different operations.
785
786public:
800
801 /// \return An upper bound for the vectorization factors (both fixed and
802 /// scalable). If the factors are 0, vectorization and interleaving should be
803 /// avoided up front.
804 FixedScalableVFPair computeMaxVF(ElementCount UserVF, unsigned UserIC);
805
806 /// Memory access instruction may be vectorized in more than one way.
807 /// Form of instruction after vectorization depends on cost.
808 /// This function takes cost-based decisions for Load/Store instructions
809 /// and collects them in a map. This decisions map is used for building
810 /// the lists of loop-uniform and loop-scalar instructions.
811 /// The calculated cost is saved with widening decision in order to
812 /// avoid redundant calculations.
813 void setCostBasedWideningDecision(ElementCount VF);
814
815 /// Collect values we want to ignore in the cost model.
816 void collectValuesToIgnore();
817
818 /// \returns True if it is more profitable to scalarize instruction \p I for
819 /// vectorization factor \p VF.
821 assert(VF.isVector() &&
822 "Profitable to scalarize relevant only for VF > 1.");
823 assert(
824 TheLoop->isInnermost() &&
825 "cost-model should not be used for outer loops (in VPlan-native path)");
826
827 auto Scalars = InstsToScalarize.find(VF);
828 assert(Scalars != InstsToScalarize.end() &&
829 "VF not yet analyzed for scalarization profitability");
830 return Scalars->second.contains(I);
831 }
832
833 /// Returns true if \p I is known to be uniform after vectorization.
835 assert(
836 TheLoop->isInnermost() &&
837 "cost-model should not be used for outer loops (in VPlan-native path)");
838
839 // If VF is scalar, then all instructions are trivially uniform.
840 if (VF.isScalar())
841 return true;
842
843 // Pseudo probes must be duplicated per vector lane so that the
844 // profiled loop trip count is not undercounted.
846 return false;
847
848 auto UniformsPerVF = Uniforms.find(VF);
849 assert(UniformsPerVF != Uniforms.end() &&
850 "VF not yet analyzed for uniformity");
851 return UniformsPerVF->second.count(I);
852 }
853
854 /// Returns true if \p I is known to be scalar after vectorization.
856 assert(
857 TheLoop->isInnermost() &&
858 "cost-model should not be used for outer loops (in VPlan-native path)");
859 if (VF.isScalar())
860 return true;
861
862 auto ScalarsPerVF = Scalars.find(VF);
863 assert(ScalarsPerVF != Scalars.end() &&
864 "Scalar values are not calculated for VF");
865 return ScalarsPerVF->second.count(I);
866 }
867
868 /// \returns True if instruction \p I can be truncated to a smaller bitwidth
869 /// for vectorization factor \p VF.
871 const auto &MinBWs = Config.getMinimalBitwidths();
872 // Truncs must truncate at most to their destination type.
873 if (isa_and_nonnull<TruncInst>(I) && MinBWs.contains(I) &&
874 I->getType()->getScalarSizeInBits() < MinBWs.lookup(I))
875 return false;
876 return VF.isVector() && MinBWs.contains(I) &&
879 }
880
881 /// Decision that was taken during cost calculation for memory instruction.
884 CM_Widen, // For consecutive accesses with stride +1.
885 CM_Widen_Reverse, // For consecutive accesses with stride -1.
889 /// A widening decision that has been invalidated after replacing the
890 /// corresponding recipe during VPlan transforms.
891 /// TODO: Remove once the legacy exit cost computation is retired.
893 };
894
895 /// Save vectorization decision \p W and \p Cost taken by the cost model for
896 /// instruction \p I and vector width \p VF.
899 assert(VF.isVector() && "Expected VF >=2");
900 WideningDecisions[{I, VF}] = {W, Cost};
901 }
902
903 /// Save vectorization decision \p W and \p Cost taken by the cost model for
904 /// interleaving group \p Grp and vector width \p VF.
908 assert(VF.isVector() && "Expected VF >=2");
909 /// Broadcast this decicion to all instructions inside the group.
910 /// When interleaving, the cost will only be assigned one instruction, the
911 /// insert position. For other cases, add the appropriate fraction of the
912 /// total cost to each instruction. This ensures accurate costs are used,
913 /// even if the insert position instruction is not used.
914 InstructionCost InsertPosCost = Cost;
915 InstructionCost OtherMemberCost = 0;
916 if (W != CM_Interleave)
917 OtherMemberCost = InsertPosCost = Cost / Grp->getNumMembers();
918 ;
919 for (auto *I : Grp->members()) {
920 if (Grp->getInsertPos() == I)
921 WideningDecisions[{I, VF}] = {W, InsertPosCost};
922 else
923 WideningDecisions[{I, VF}] = {W, OtherMemberCost};
924 }
925 }
926
927 /// Return the cost model decision for the given instruction \p I and vector
928 /// width \p VF. Return CM_Unknown if this instruction did not pass
929 /// through the cost modeling.
931 assert(VF.isVector() && "Expected VF to be a vector VF");
932 assert(
933 TheLoop->isInnermost() &&
934 "cost-model should not be used for outer loops (in VPlan-native path)");
935
936 std::pair<Instruction *, ElementCount> InstOnVF(I, VF);
937 auto Itr = WideningDecisions.find(InstOnVF);
938 if (Itr == WideningDecisions.end())
939 return CM_Unknown;
940 return Itr->second.first;
941 }
942
943 /// Return the vectorization cost for the given instruction \p I and vector
944 /// width \p VF.
946 assert(VF.isVector() && "Expected VF >=2");
947 std::pair<Instruction *, ElementCount> InstOnVF(I, VF);
948 assert(WideningDecisions.contains(InstOnVF) &&
949 "The cost is not calculated");
950 return WideningDecisions[InstOnVF].second;
951 }
952
953 /// Return True if instruction \p I is an optimizable truncate whose operand
954 /// is an induction variable. Such a truncate will be removed by adding a new
955 /// induction variable with the destination type.
957 // If the instruction is not a truncate, return false.
958 auto *Trunc = dyn_cast<TruncInst>(I);
959 if (!Trunc)
960 return false;
961
962 // Get the source and destination types of the truncate.
963 Type *SrcTy = toVectorTy(Trunc->getSrcTy(), VF);
964 Type *DestTy = toVectorTy(Trunc->getDestTy(), VF);
965
966 // If the truncate is free for the given types, return false. Replacing a
967 // free truncate with an induction variable would add an induction variable
968 // update instruction to each iteration of the loop. We exclude from this
969 // check the primary induction variable since it will need an update
970 // instruction regardless.
971 Value *Op = Trunc->getOperand(0);
972 if (Op != Legal->getPrimaryInduction() && TTI.isTruncateFree(SrcTy, DestTy))
973 return false;
974
975 // If the truncated value is not an induction variable, return false.
976 return Legal->isInductionPhi(Op);
977 }
978
979 /// Collects the instructions to scalarize for each predicated instruction in
980 /// the loop.
981 void collectInstsToScalarize(ElementCount VF);
982
983 /// Collect values that will not be widened, including Uniforms, Scalars, and
984 /// Instructions to Scalarize for the given \p VF.
985 /// The sets depend on CM decision for Load/Store instructions
986 /// that may be vectorized as interleave, gather-scatter or scalarized.
987 /// Also make a decision on what to do about call instructions in the loop
988 /// at that VF -- scalarize, call a known vector routine, or call a
989 /// vector intrinsic.
991 // Do the analysis once.
992 if (VF.isScalar() || Uniforms.contains(VF))
993 return;
995 collectLoopUniforms(VF);
996 collectLoopScalars(VF);
998 }
999
1000 /// Given costs for both strategies, return true if the scalar predication
1001 /// lowering should be used for div/rem. This incorporates an override
1002 /// option so it is not simply a cost comparison.
1004 InstructionCost MaskedCost) const {
1005 switch (ForceMaskedDivRem) {
1007 return ScalarCost < MaskedCost;
1009 return false;
1011 return true;
1012 }
1013 llvm_unreachable("impossible case value");
1014 }
1015
1016 /// Returns true if \p I is an instruction which requires predication and
1017 /// for which our chosen predication strategy is scalarization (i.e. we
1018 /// don't have an alternate strategy such as masking available).
1019 /// \p VF is the vectorization factor that will be used to vectorize \p I.
1020 bool isScalarWithPredication(Instruction *I, ElementCount VF);
1021
1022 /// Wrapper function for LoopVectorizationLegality::isMaskRequired,
1023 /// that passes the Instruction \p I and if we fold tail.
1024 bool isMaskRequired(Instruction *I) const;
1025
1026 /// Returns true if \p I is an instruction that needs to be predicated
1027 /// at runtime. The result is independent of the predication mechanism.
1028 /// Superset of instructions that return true for isScalarWithPredication.
1029 bool isPredicatedInst(Instruction *I) const;
1030
1031 /// A helper function that returns how much we should divide the cost of a
1032 /// predicated block by. Typically this is the reciprocal of the block
1033 /// probability, i.e. if we return X we are assuming the predicated block will
1034 /// execute once for every X iterations of the loop header so the block should
1035 /// only contribute 1/X of its cost to the total cost calculation, but when
1036 /// optimizing for code size it will just be 1 as code size costs don't depend
1037 /// on execution probabilities.
1038 ///
1039 /// Note that if a block wasn't originally predicated but was predicated due
1040 /// to tail folding, the divisor will still be 1 because it will execute for
1041 /// every iteration of the loop header.
1042 inline uint64_t
1043 getPredBlockCostDivisor(TargetTransformInfo::TargetCostKind CostKind,
1044 const BasicBlock *BB);
1045
1046 /// Returns true if an artificially high cost for emulated masked memrefs
1047 /// should be used.
1048 bool useEmulatedMaskMemRefHack(Instruction *I, ElementCount VF);
1049
1050 /// Return the costs for our two available strategies for lowering a
1051 /// div/rem operation which requires speculating at least one lane.
1052 /// First result is for scalarization (will be invalid for scalable
1053 /// vectors); second is for the masked intrinsic strategy.
1054 std::pair<InstructionCost, InstructionCost>
1055 getDivRemSpeculationCost(Instruction *I, ElementCount VF);
1056
1057 /// If \p I is a memory instruction with a consecutive pointer that can be
1058 /// widened, returns the widening kind (CM_Widen or CM_Widen_Reverse) and
1059 /// std::nullopt otherwise.
1060 std::optional<InstWidening> memoryInstructionCanBeWidened(Instruction *I,
1061 ElementCount VF);
1062
1063 /// Returns true if \p I is a memory instruction in an interleaved-group
1064 /// of memory accesses that can be vectorized with wide vector loads/stores
1065 /// and shuffles.
1066 bool interleavedAccessCanBeWidened(Instruction *I, ElementCount VF) const;
1067
1068 /// Check if \p Instr belongs to any interleaved access group.
1070 return InterleaveInfo.isInterleaved(Instr);
1071 }
1072
1073 /// Get the interleaved access group that \p Instr belongs to.
1076 return InterleaveInfo.getInterleaveGroup(Instr);
1077 }
1078
1079 /// Returns true if we're required to use a scalar epilogue for at least
1080 /// the final iteration of the original loop.
1081 bool requiresScalarEpilogue(bool IsVectorizing) const {
1082 if (!isEpilogueAllowed()) {
1083 LLVM_DEBUG(dbgs() << "LV: Loop does not require scalar epilogue\n");
1084 return false;
1085 }
1086 // If we might exit from anywhere but the latch and early exit vectorization
1087 // is disabled, we must run the exiting iteration in scalar form.
1088 if (TheLoop->getExitingBlock() != TheLoop->getLoopLatch() &&
1089 !(EnableEarlyExitVectorization && Legal->hasUncountableEarlyExit())) {
1090 LLVM_DEBUG(dbgs() << "LV: Loop requires scalar epilogue: not exiting "
1091 "from latch block\n");
1092 return true;
1093 }
1094 if (IsVectorizing && InterleaveInfo.requiresScalarEpilogue()) {
1095 LLVM_DEBUG(dbgs() << "LV: Loop requires scalar epilogue: "
1096 "interleaved group requires scalar epilogue\n");
1097 return true;
1098 }
1099 LLVM_DEBUG(dbgs() << "LV: Loop does not require scalar epilogue\n");
1100 return false;
1101 }
1102
1103 /// Returns true if an epilogue is allowed (e.g., not prevented by
1104 /// optsize or a loop hint annotation).
1105 bool isEpilogueAllowed() const {
1106 return EpilogueLoweringStatus == CM_EpilogueAllowed;
1107 }
1108
1109 /// Returns true if tail-folding is preferred over an epilogue.
1111 return EpilogueLoweringStatus == CM_EpilogueNotNeededFoldTail ||
1112 EpilogueLoweringStatus == CM_EpilogueNotAllowedFoldTail;
1113 }
1114
1115 /// Returns the TailFoldingStyle that is best for the current loop.
1117 return ChosenTailFoldingStyle;
1118 }
1119
1120 /// Selects and saves TailFoldingStyle.
1121 /// \param IsScalableVF true if scalable vector factors enabled.
1122 /// \param UserIC User specific interleave count.
1123 void setTailFoldingStyle(bool IsScalableVF, unsigned UserIC) {
1124 assert(ChosenTailFoldingStyle == TailFoldingStyle::None &&
1125 "Tail folding must not be selected yet.");
1126 if (!Legal->canFoldTailByMasking()) {
1127 ChosenTailFoldingStyle = TailFoldingStyle::None;
1128 return;
1129 }
1130
1131 // Default to TTI preference, but allow command line override.
1132 ChosenTailFoldingStyle = TTI.getPreferredTailFoldingStyle();
1133 if (ForceTailFoldingStyle.getNumOccurrences())
1134 ChosenTailFoldingStyle = ForceTailFoldingStyle.getValue();
1135
1136 if (ChosenTailFoldingStyle != TailFoldingStyle::DataWithEVL)
1137 return;
1138 // Override EVL styles if needed.
1139 // FIXME: Investigate opportunity for fixed vector factor.
1140 bool EVLIsLegal = UserIC <= 1 && IsScalableVF &&
1141 TTI.hasActiveVectorLength() && !EnableVPlanNativePath;
1142 if (EVLIsLegal)
1143 return;
1144 // If for some reason EVL mode is unsupported, fallback to an epilogue
1145 // if it's allowed, or DataWithoutLaneMask otherwise.
1146 if (EpilogueLoweringStatus == CM_EpilogueAllowed ||
1147 EpilogueLoweringStatus == CM_EpilogueNotNeededFoldTail)
1148 ChosenTailFoldingStyle = TailFoldingStyle::None;
1149 else
1150 ChosenTailFoldingStyle = TailFoldingStyle::DataWithoutLaneMask;
1151
1152 LLVM_DEBUG(
1153 dbgs() << "LV: Preference for VP intrinsics indicated. Will "
1154 "not try to generate VP Intrinsics "
1155 << (UserIC > 1
1156 ? "since interleave count specified is greater than 1.\n"
1157 : "due to non-interleaving reasons.\n"));
1158 }
1159
1160 /// Returns true if all loop blocks should be masked to fold tail loop.
1161 bool foldTailByMasking() const {
1163 }
1164
1166 assert(foldTailByMasking() && "Expected tail folding to be enabled!");
1168 "Did not expect to enable alias masking with EVL!");
1169 assert(PartialAliasMaskingStatus == AliasMaskingStatus::NotDecided);
1170
1171 // Assume we fail to enable alias masking (in case we early exit).
1172 PartialAliasMaskingStatus = AliasMaskingStatus::Disabled;
1173
1174 // Note: FixedOrderRecurrences are not supported yet as we cannot handle
1175 // the required `splice.right` with the alias-mask.
1177 !Legal->getFixedOrderRecurrences().empty())
1178 return;
1179
1180 const RuntimePointerChecking *Checks = Legal->getRuntimePointerChecking();
1181 if (!Checks)
1182 return;
1183
1184 auto DiffChecks = Checks->getDiffChecks();
1185 if (!DiffChecks || DiffChecks->empty())
1186 return;
1187
1188 [[maybe_unused]] auto HasPointerArgs = [](CallBase *CB) {
1189 return any_of(CB->args(), [](Value const *Arg) {
1190 return Arg->getType()->isPointerTy();
1191 });
1192 };
1193
1194 for (BasicBlock *BB : TheLoop->blocks()) {
1195 for (Instruction &I : *BB) {
1197 [[maybe_unused]] auto *Call = dyn_cast<CallInst>(&I);
1198 assert(
1199 (!I.mayReadOrWriteMemory() || (Call && !HasPointerArgs(Call))) &&
1200 "Skipped unexpected memory access");
1201 continue;
1202 }
1203
1204 Type *ScalarTy = getLoadStoreType(&I);
1206
1207 // Currently, we can't handle alias masking in reverse. Reversing the
1208 // alias mask is not correct (or necessary). When combined with
1209 // tail-folding the active lane mask should only be reversed where the
1210 // alias-mask is true.
1211 if (Legal->isConsecutivePtr(ScalarTy, Ptr) == -1)
1212 return;
1213 }
1214 }
1215
1216 PartialAliasMaskingStatus = AliasMaskingStatus::Enabled;
1217 }
1218
1219 /// Returns true if all loop blocks should have partial aliases masked.
1220 bool maskPartialAliasing() const {
1221 return PartialAliasMaskingStatus == AliasMaskingStatus::Enabled;
1222 }
1223
1224 /// Returns true if the use of wide lane masks is requested and the loop is
1225 /// using tail-folding with a lane mask for control flow.
1228 return false;
1229
1231 }
1232
1233 /// Returns true if the instructions in this block requires predication
1234 /// for any reason, e.g. because tail folding now requires a predicate
1235 /// or because the block in the original loop was predicated.
1237 return foldTailByMasking() || Legal->blockNeedsPredication(BB);
1238 }
1239
1240 /// Returns true if VP intrinsics with explicit vector length support should
1241 /// be generated in the tail folded loop.
1245
1246 /// Returns true if the predicated reduction select should be used to set the
1247 /// incoming value for the reduction phi.
1248 bool usePredicatedReductionSelect(RecurKind RecurrenceKind) const {
1249 // Force to use predicated reduction select since the EVL of the
1250 // second-to-last iteration might not be VF*UF.
1251 if (foldTailWithEVL())
1252 return true;
1253
1254 // Force a predicated select with alias-masking to avoid propagating poison
1255 // values to the header phi for lanes outside the alias-mask.
1256 if (maskPartialAliasing())
1257 return true;
1258
1259 // Note: For FindLast recurrences we prefer a predicated select to simplify
1260 // matching in handleFindLastReductions(), rather than handle multiple
1261 // cases.
1263 return true;
1264
1266 TTI.preferPredicatedReductionSelect();
1267 }
1268
1269 /// Estimate cost of an intrinsic call instruction CI if it were vectorized
1270 /// with factor VF. Return the cost of the instruction, including
1271 /// scalarization overhead if it's needed.
1272 InstructionCost getVectorIntrinsicCost(CallInst *CI, ElementCount VF) const;
1273
1274 /// Estimate cost of a call instruction CI if it were vectorized with factor
1275 /// VF. Return the cost of the instruction, including scalarization overhead
1276 /// if it's needed.
1277 InstructionCost getVectorCallCost(CallInst *CI, ElementCount VF) const;
1278
1279 /// Invalidates decisions already taken by the cost model.
1281 WideningDecisions.clear();
1282 Uniforms.clear();
1283 Scalars.clear();
1284 }
1285
1286 /// Returns the expected execution cost. The unit of the cost does
1287 /// not matter because we use the 'cost' units to compare different
1288 /// vector widths. The cost that is returned is *not* normalized by
1289 /// the factor width.
1290 InstructionCost expectedCost(ElementCount VF);
1291
1292 /// Returns true if epilogue vectorization is considered profitable, and
1293 /// false otherwise.
1294 /// \p VF is the vectorization factor chosen for the original loop.
1295 /// \p Multiplier is an aditional scaling factor applied to VF before
1296 /// comparing to EpilogueVectorizationMinVF.
1297 bool isEpilogueVectorizationProfitable(const ElementCount VF,
1298 const unsigned IC) const;
1299
1300 /// Returns the execution time cost of an instruction for a given vector
1301 /// width. Vector width of one means scalar.
1302 InstructionCost getInstructionCost(Instruction *I, ElementCount VF);
1303
1304 /// Return the cost of instructions in an inloop reduction pattern, if I is
1305 /// part of that pattern.
1306 std::optional<InstructionCost> getReductionPatternCost(Instruction *I,
1307 ElementCount VF,
1308 Type *VectorTy) const;
1309
1310 /// Returns true if \p Op should be considered invariant and if it is
1311 /// trivially hoistable.
1312 bool shouldConsiderInvariant(Value *Op);
1313
1314 /// Returns true if \p I has been forced to be scalarized at \p VF.
1316 auto FS = ForcedScalars.find(VF);
1317 return FS != ForcedScalars.end() && FS->second.contains(I);
1318 }
1319
1320private:
1321 unsigned NumPredStores = 0;
1322
1323 /// VF selection state independent of cost-modeling decisions.
1324 VFSelectionContext &Config;
1325
1326 /// Wrapper around LoopVectorizationLegality::isUniform() that takes into
1327 /// account if alias-masking is enabled. We consider the VF to be unknown when
1328 /// alias masking.
1329 bool isUniform(Value *V, ElementCount VF) const {
1330 // With alias-masking our runtime VF is [2, VF] (and not necessarily a
1331 // power-of-two). Something that is uniform for VF may not be for the full
1332 // range.
1333 assert(PartialAliasMaskingStatus != AliasMaskingStatus::NotDecided &&
1334 "alias-mask status must be decided already");
1335 return Legal->isUniform(V, PartialAliasMaskingStatus ==
1337 ? std::optional(VF)
1338 : std::nullopt);
1339 }
1340
1341 /// Wrapper around LoopVectorizationLegality::isUniformMemOp() that takes into
1342 /// account if alias-masking is enabled. We consider the VF to be unknown when
1343 /// alias masking.
1344 bool isUniformMemOp(Instruction &I, ElementCount VF) const {
1345 assert(PartialAliasMaskingStatus != AliasMaskingStatus::NotDecided &&
1346 "alias-mask status must be decided already");
1347 return Legal->isUniformMemOp(I, PartialAliasMaskingStatus ==
1349 ? std::optional(VF)
1350 : std::nullopt);
1351 }
1352
1353 /// Calculate vectorization cost of memory instruction \p I.
1354 InstructionCost getMemoryInstructionCost(Instruction *I, ElementCount VF);
1355
1356 /// The cost computation for scalarized memory instruction.
1357 InstructionCost getMemInstScalarizationCost(Instruction *I, ElementCount VF);
1358
1359 /// The cost computation for interleaving group of memory instructions.
1360 InstructionCost getInterleaveGroupCost(Instruction *I, ElementCount VF);
1361
1362 /// The cost computation for Gather/Scatter instruction.
1363 InstructionCost getGatherScatterCost(Instruction *I, ElementCount VF);
1364
1365 /// The cost computation for widening instruction \p I with consecutive
1366 /// memory access.
1367 InstructionCost getConsecutiveMemOpCost(Instruction *I, ElementCount VF,
1368 InstWidening Kind);
1369
1370 /// The cost calculation for Load/Store instruction \p I with uniform pointer -
1371 /// Load: scalar load + broadcast.
1372 /// Store: scalar store + (loop invariant value stored? 0 : extract of last
1373 /// element)
1374 InstructionCost getUniformMemOpCost(Instruction *I, ElementCount VF);
1375
1376 /// Estimate the overhead of scalarizing an instruction. This is a
1377 /// convenience wrapper for the type-based getScalarizationOverhead API.
1379 ElementCount VF) const;
1380
1381 /// A type representing the costs for instructions if they were to be
1382 /// scalarized rather than vectorized. The entries are Instruction-Cost
1383 /// pairs.
1384 using ScalarCostsTy = MapVector<Instruction *, InstructionCost>;
1385
1386 /// A set containing all BasicBlocks that are known to present after
1387 /// vectorization as a predicated block.
1388 DenseMap<ElementCount, SmallPtrSet<BasicBlock *, 4>>
1389 PredicatedBBsAfterVectorization;
1390
1391 /// Records whether it is allowed to have the original scalar loop execute at
1392 /// least once. This may be needed as a fallback loop in case runtime
1393 /// aliasing/dependence checks fail, or to handle the tail/remainder
1394 /// iterations when the trip count is unknown or doesn't divide by the VF,
1395 /// or as a peel-loop to handle gaps in interleave-groups.
1396 /// Under optsize and when the trip count is very small we don't allow any
1397 /// iterations to execute in the scalar loop.
1398 EpilogueLowering EpilogueLoweringStatus = CM_EpilogueAllowed;
1399
1400 /// Control finally chosen tail folding style.
1401 TailFoldingStyle ChosenTailFoldingStyle = TailFoldingStyle::None;
1402
1403 /// If partial alias masking is enabled/disabled or not decided.
1404 AliasMaskingStatus PartialAliasMaskingStatus = AliasMaskingStatus::NotDecided;
1405
1406 /// A map holding scalar costs for different vectorization factors. The
1407 /// presence of a cost for an instruction in the mapping indicates that the
1408 /// instruction will be scalarized when vectorizing with the associated
1409 /// vectorization factor. The entries are VF-ScalarCostTy pairs.
1410 MapVector<ElementCount, ScalarCostsTy> InstsToScalarize;
1411
1412 /// Holds the instructions known to be uniform after vectorization.
1413 /// The data is collected per VF.
1414 DenseMap<ElementCount, SmallPtrSet<Instruction *, 4>> Uniforms;
1415
1416 /// Holds the instructions known to be scalar after vectorization.
1417 /// The data is collected per VF.
1418 DenseMap<ElementCount, SmallPtrSet<Instruction *, 4>> Scalars;
1419
1420 /// Holds the instructions (address computations) that are forced to be
1421 /// scalarized.
1422 DenseMap<ElementCount, SmallPtrSet<Instruction *, 4>> ForcedScalars;
1423
1424 /// Returns the expected difference in cost from scalarizing the expression
1425 /// feeding a predicated instruction \p PredInst. The instructions to
1426 /// scalarize and their scalar costs are collected in \p ScalarCosts. A
1427 /// non-negative return value implies the expression will be scalarized.
1428 /// Currently, only single-use chains are considered for scalarization.
1429 InstructionCost computePredInstDiscount(Instruction *PredInst,
1430 ScalarCostsTy &ScalarCosts,
1431 ElementCount VF);
1432
1433 /// Collect the instructions that are uniform after vectorization. An
1434 /// instruction is uniform if we represent it with a single scalar value in
1435 /// the vectorized loop corresponding to each vector iteration. Examples of
1436 /// uniform instructions include pointer operands of consecutive or
1437 /// interleaved memory accesses. Note that although uniformity implies an
1438 /// instruction will be scalar, the reverse is not true. In general, a
1439 /// scalarized instruction will be represented by VF scalar values in the
1440 /// vectorized loop, each corresponding to an iteration of the original
1441 /// scalar loop.
1442 void collectLoopUniforms(ElementCount VF);
1443
1444 /// Collect the instructions that are scalar after vectorization. An
1445 /// instruction is scalar if it is known to be uniform or will be scalarized
1446 /// during vectorization. collectLoopScalars should only add non-uniform nodes
1447 /// to the list if they are used by a load/store instruction that is marked as
1448 /// CM_Scalarize. Non-uniform scalarized instructions will be represented by
1449 /// VF values in the vectorized loop, each corresponding to an iteration of
1450 /// the original scalar loop.
1451 void collectLoopScalars(ElementCount VF);
1452
1453 /// Keeps cost model vectorization decision and cost for instructions.
1454 /// Right now it is used for memory instructions only.
1455 using DecisionList = DenseMap<std::pair<Instruction *, ElementCount>,
1456 std::pair<InstWidening, InstructionCost>>;
1457
1458 DecisionList WideningDecisions;
1459
1460 /// Returns true if \p V is expected to be vectorized and it needs to be
1461 /// extracted.
1462 bool needsExtract(Value *V, ElementCount VF) const {
1464 if (VF.isScalar() || !I || !TheLoop->contains(I) ||
1465 TheLoop->isLoopInvariant(I) ||
1466 getWideningDecision(I, VF) == CM_Scalarize)
1467 return false;
1468
1469 // Assume we can vectorize V (and hence we need extraction) if the
1470 // scalars are not computed yet. This can happen, because it is called
1471 // via getScalarizationOverhead from setCostBasedWideningDecision, before
1472 // the scalars are collected. That should be a safe assumption in most
1473 // cases, because we check if the operands have vectorizable types
1474 // beforehand in LoopVectorizationLegality.
1475 return !Scalars.contains(VF) || !isScalarAfterVectorization(I, VF);
1476 };
1477
1478 /// Returns a range containing only operands needing to be extracted.
1479 SmallVector<Value *, 4> filterExtractingOperands(Instruction::op_range Ops,
1480 ElementCount VF) const {
1481
1482 SmallPtrSet<const Value *, 4> UniqueOperands;
1483 SmallVector<Value *, 4> Res;
1484 for (Value *Op : Ops) {
1485 if (isa<Constant>(Op) || !UniqueOperands.insert(Op).second ||
1486 !needsExtract(Op, VF))
1487 continue;
1488 Res.push_back(Op);
1489 }
1490 return Res;
1491 }
1492
1493public:
1494 /// The loop that we evaluate.
1496
1497 /// Predicated scalar evolution analysis.
1499
1500 /// Loop Info analysis.
1502
1503 /// Vectorization legality.
1505
1506 /// Vector target information.
1508
1509 /// Target Library Info.
1511
1512 /// Assumption cache.
1514
1515 /// Interface to emit optimization remarks.
1517
1518 /// A function to lazily fetch BlockFrequencyInfo. This avoids computing it
1519 /// unless necessary, e.g. when the loop isn't legal to vectorize or when
1520 /// there is no predication.
1521 std::function<BlockFrequencyInfo &()> GetBFI;
1522 /// The BlockFrequencyInfo returned from GetBFI.
1524 /// Returns the BlockFrequencyInfo for the function if cached, otherwise
1525 /// fetches it via GetBFI. Avoids an indirect call to the std::function.
1527 if (!BFI)
1528 BFI = &GetBFI();
1529 return *BFI;
1530 }
1531
1533
1534 /// Loop Vectorize Hint.
1536
1537 /// The interleave access information contains groups of interleaved accesses
1538 /// with the same stride and close to each other.
1540
1541 /// Values to ignore in the cost model.
1543
1544 /// Values to ignore in the cost model when VF > 1.
1546};
1547} // end namespace llvm
1548
1549namespace {
1550/// Helper struct to manage generating runtime checks for vectorization.
1551///
1552/// The runtime checks are created up-front in temporary blocks to allow better
1553/// estimating the cost and un-linked from the existing IR. After deciding to
1554/// vectorize, the checks are moved back. If deciding not to vectorize, the
1555/// temporary blocks are completely removed.
1556class GeneratedRTChecks {
1557 /// Basic block which contains the generated SCEV checks, if any.
1558 BasicBlock *SCEVCheckBlock = nullptr;
1559
1560 /// The value representing the result of the generated SCEV checks. If it is
1561 /// nullptr no SCEV checks have been generated.
1562 Value *SCEVCheckCond = nullptr;
1563
1564 /// Basic block which contains the generated memory runtime checks, if any.
1565 BasicBlock *MemCheckBlock = nullptr;
1566
1567 /// The value representing the result of the generated memory runtime checks.
1568 /// If it is nullptr no memory runtime checks have been generated.
1569 Value *MemRuntimeCheckCond = nullptr;
1570
1571 DominatorTree *DT;
1572 LoopInfo *LI;
1574
1575 SCEVExpander SCEVExp;
1576 SCEVExpander MemCheckExp;
1577
1578 bool CostTooHigh = false;
1579
1580 Loop *OuterLoop = nullptr;
1581
1583
1584 /// The kind of cost that we are calculating
1586
1587 /// True if the loop is alias-masked (which allows us to omit diff checks).
1588 bool LoopUsesPartialAliasMasking = false;
1589
1590public:
1591 GeneratedRTChecks(PredicatedScalarEvolution &PSE, DominatorTree *DT,
1594 bool LoopUsesPartialAliasMasking)
1595 : DT(DT), LI(LI), TTI(TTI),
1596 SCEVExp(*PSE.getSE(), "scev.check", /*PreserveLCSSA=*/false),
1597 MemCheckExp(*PSE.getSE(), "scev.check", /*PreserveLCSSA=*/false),
1598 PSE(PSE), CostKind(CostKind),
1599 LoopUsesPartialAliasMasking(LoopUsesPartialAliasMasking) {}
1600
1601 /// Generate runtime checks in SCEVCheckBlock and MemCheckBlock, so we can
1602 /// accurately estimate the cost of the runtime checks. The blocks are
1603 /// un-linked from the IR and are added back during vector code generation. If
1604 /// there is no vector code generation, the check blocks are removed
1605 /// completely.
1606 void create(Loop *L, const LoopAccessInfo &LAI,
1607 const SCEVPredicate &UnionPred, ElementCount VF, unsigned IC,
1608 OptimizationRemarkEmitter &ORE) {
1609
1610 // Hard cutoff to limit compile-time increase in case a very large number of
1611 // runtime checks needs to be generated.
1612 // TODO: Skip cutoff if the loop is guaranteed to execute, e.g. due to
1613 // profile info.
1614 CostTooHigh =
1616 if (CostTooHigh) {
1617 // Mark runtime checks as never succeeding when they exceed the threshold.
1618 MemRuntimeCheckCond = ConstantInt::getTrue(L->getHeader()->getContext());
1619 SCEVCheckCond = ConstantInt::getTrue(L->getHeader()->getContext());
1620 ORE.emit([&]() {
1621 return OptimizationRemarkAnalysisAliasing(
1622 DEBUG_TYPE, "TooManyMemoryRuntimeChecks", L->getStartLoc(),
1623 L->getHeader())
1624 << "loop not vectorized: too many memory checks needed";
1625 });
1626 LLVM_DEBUG(dbgs() << "LV: Too many memory checks needed.\n");
1627 return;
1628 }
1629
1630 BasicBlock *LoopHeader = L->getHeader();
1631 BasicBlock *Preheader = L->getLoopPreheader();
1632
1633 // Use SplitBlock to create blocks for SCEV & memory runtime checks to
1634 // ensure the blocks are properly added to LoopInfo & DominatorTree. Those
1635 // may be used by SCEVExpander. The blocks will be un-linked from their
1636 // predecessors and removed from LI & DT at the end of the function.
1637 if (!UnionPred.isAlwaysTrue()) {
1638 SCEVCheckBlock = SplitBlock(Preheader, Preheader->getTerminator(), DT, LI,
1639 nullptr, "vector.scevcheck");
1640
1641 SCEVCheckCond = SCEVExp.expandCodeForPredicate(
1642 &UnionPred, SCEVCheckBlock->getTerminator());
1643 if (isa<Constant>(SCEVCheckCond)) {
1644 // Clean up directly after expanding the predicate to a constant, to
1645 // avoid further expansions re-using anything left over from SCEVExp.
1646 SCEVExpanderCleaner SCEVCleaner(SCEVExp);
1647 SCEVCleaner.cleanup();
1648 }
1649 }
1650
1651 const auto &RtPtrChecking = *LAI.getRuntimePointerChecking();
1652 // TODO: We need to estimate the cost of alias-masking in
1653 // GeneratedRTChecks::getCost(). We can't check the MemCheckBlock as the
1654 // alias-mask is generated later in VPlan.
1655 if (RtPtrChecking.Need && !LoopUsesPartialAliasMasking) {
1656 auto *Pred = SCEVCheckBlock ? SCEVCheckBlock : Preheader;
1657 MemCheckBlock = SplitBlock(Pred, Pred->getTerminator(), DT, LI, nullptr,
1658 "vector.memcheck");
1659
1660 auto DiffChecks = RtPtrChecking.getDiffChecks();
1661 if (DiffChecks) {
1662 Value *RuntimeVF = nullptr;
1663 MemRuntimeCheckCond = addDiffRuntimeChecks(
1664 MemCheckBlock->getTerminator(), *DiffChecks, MemCheckExp,
1665 [VF, &RuntimeVF](IRBuilderBase &B, unsigned Bits) {
1666 if (!RuntimeVF)
1667 RuntimeVF = getRuntimeVF(B, B.getIntNTy(Bits), VF);
1668 return RuntimeVF;
1669 },
1670 IC);
1671 } else {
1672 MemRuntimeCheckCond = addRuntimeChecks(
1673 MemCheckBlock->getTerminator(), L, RtPtrChecking.getChecks(),
1675 }
1676 assert(MemRuntimeCheckCond &&
1677 "no RT checks generated although RtPtrChecking "
1678 "claimed checks are required");
1679 }
1680
1681 SCEVExp.eraseDeadInstructions(SCEVCheckCond);
1682
1683 if (!MemCheckBlock && !SCEVCheckBlock)
1684 return;
1685
1686 // Unhook the temporary block with the checks, update various places
1687 // accordingly.
1688 if (SCEVCheckBlock)
1689 SCEVCheckBlock->replaceAllUsesWith(Preheader);
1690 if (MemCheckBlock)
1691 MemCheckBlock->replaceAllUsesWith(Preheader);
1692
1693 if (SCEVCheckBlock) {
1694 SCEVCheckBlock->getTerminator()->moveBefore(
1695 Preheader->getTerminator()->getIterator());
1696 auto *UI = new UnreachableInst(Preheader->getContext(), SCEVCheckBlock);
1697 UI->setDebugLoc(DebugLoc::getTemporary());
1698 Preheader->getTerminator()->eraseFromParent();
1699 }
1700 if (MemCheckBlock) {
1701 MemCheckBlock->getTerminator()->moveBefore(
1702 Preheader->getTerminator()->getIterator());
1703 auto *UI = new UnreachableInst(Preheader->getContext(), MemCheckBlock);
1704 UI->setDebugLoc(DebugLoc::getTemporary());
1705 Preheader->getTerminator()->eraseFromParent();
1706 }
1707
1708 DT->changeImmediateDominator(LoopHeader, Preheader);
1709 if (MemCheckBlock) {
1710 DT->eraseNode(MemCheckBlock);
1711 LI->removeBlock(MemCheckBlock);
1712 }
1713 if (SCEVCheckBlock) {
1714 DT->eraseNode(SCEVCheckBlock);
1715 LI->removeBlock(SCEVCheckBlock);
1716 }
1717
1718 // Outer loop is used as part of the later cost calculations.
1719 OuterLoop = L->getParentLoop();
1720 }
1721
1723 if (SCEVCheckBlock || MemCheckBlock)
1724 LLVM_DEBUG(dbgs() << "Calculating cost of runtime checks:\n");
1725
1726 if (CostTooHigh) {
1728 Cost.setInvalid();
1729 LLVM_DEBUG(dbgs() << " number of checks exceeded threshold\n");
1730 return Cost;
1731 }
1732
1733 InstructionCost RTCheckCost = 0;
1734 if (SCEVCheckBlock)
1735 for (Instruction &I : *SCEVCheckBlock) {
1736 if (SCEVCheckBlock->getTerminator() == &I)
1737 continue;
1739 LLVM_DEBUG(dbgs() << " " << C << " for " << I << "\n");
1740 RTCheckCost += C;
1741 }
1742 if (MemCheckBlock) {
1743 InstructionCost MemCheckCost = 0;
1744 for (Instruction &I : *MemCheckBlock) {
1745 if (MemCheckBlock->getTerminator() == &I)
1746 continue;
1748 LLVM_DEBUG(dbgs() << " " << C << " for " << I << "\n");
1749 MemCheckCost += C;
1750 }
1751
1752 // If the runtime memory checks are being created inside an outer loop
1753 // we should find out if these checks are outer loop invariant. If so,
1754 // the checks will likely be hoisted out and so the effective cost will
1755 // reduce according to the outer loop trip count.
1756 if (OuterLoop) {
1757 ScalarEvolution *SE = MemCheckExp.getSE();
1758 // TODO: If profitable, we could refine this further by analysing every
1759 // individual memory check, since there could be a mixture of loop
1760 // variant and invariant checks that mean the final condition is
1761 // variant.
1762 const SCEV *Cond = SE->getSCEV(MemRuntimeCheckCond);
1763 if (SE->isLoopInvariant(Cond, OuterLoop)) {
1764 // It seems reasonable to assume that we can reduce the effective
1765 // cost of the checks even when we know nothing about the trip
1766 // count. Assume that the outer loop executes at least twice.
1767 unsigned BestTripCount = 2;
1768
1769 // Get the best known TC estimate.
1770 if (auto EstimatedTC = getSmallBestKnownTC(
1771 PSE, OuterLoop, /* CanUseConstantMax = */ false))
1772 if (EstimatedTC->isFixed())
1773 BestTripCount = EstimatedTC->getFixedValue();
1774
1775 InstructionCost NewMemCheckCost = MemCheckCost / BestTripCount;
1776
1777 // Let's ensure the cost is always at least 1.
1778 NewMemCheckCost = std::max(NewMemCheckCost.getValue(),
1779 (InstructionCost::CostType)1);
1780
1781 if (BestTripCount > 1)
1783 << "We expect runtime memory checks to be hoisted "
1784 << "out of the outer loop. Cost reduced from "
1785 << MemCheckCost << " to " << NewMemCheckCost << '\n');
1786
1787 MemCheckCost = NewMemCheckCost;
1788 }
1789 }
1790
1791 RTCheckCost += MemCheckCost;
1792 }
1793
1794 if (SCEVCheckBlock || MemCheckBlock)
1795 LLVM_DEBUG(dbgs() << "Total cost of runtime checks: " << RTCheckCost
1796 << "\n");
1797
1798 return RTCheckCost;
1799 }
1800
1801 /// Remove the created SCEV & memory runtime check blocks & instructions, if
1802 /// unused.
1803 ~GeneratedRTChecks() {
1804 SCEVExpanderCleaner SCEVCleaner(SCEVExp);
1805 SCEVExpanderCleaner MemCheckCleaner(MemCheckExp);
1806 bool SCEVChecksUsed = !SCEVCheckBlock || !pred_empty(SCEVCheckBlock);
1807 bool MemChecksUsed = !MemCheckBlock || !pred_empty(MemCheckBlock);
1808 if (SCEVChecksUsed)
1809 SCEVCleaner.markResultUsed();
1810
1811 if (MemChecksUsed) {
1812 MemCheckCleaner.markResultUsed();
1813 } else {
1814 auto &SE = *MemCheckExp.getSE();
1815 // Memory runtime check generation creates compares that use expanded
1816 // values. Remove them before running the SCEVExpanderCleaners.
1817 for (auto &I : make_early_inc_range(reverse(*MemCheckBlock))) {
1818 if (MemCheckExp.isInsertedInstruction(&I))
1819 continue;
1820 SE.forgetValue(&I);
1821 I.eraseFromParent();
1822 }
1823 }
1824 MemCheckCleaner.cleanup();
1825 SCEVCleaner.cleanup();
1826
1827 if (!SCEVChecksUsed)
1828 SCEVCheckBlock->eraseFromParent();
1829 if (!MemChecksUsed)
1830 MemCheckBlock->eraseFromParent();
1831 }
1832
1833 /// Retrieves the SCEVCheckCond and SCEVCheckBlock that were generated as IR
1834 /// outside VPlan.
1835 std::pair<Value *, BasicBlock *> getSCEVChecks() const {
1836 using namespace llvm::PatternMatch;
1837 if (!SCEVCheckCond || match(SCEVCheckCond, m_ZeroInt()))
1838 return {nullptr, nullptr};
1839
1840 return {SCEVCheckCond, SCEVCheckBlock};
1841 }
1842
1843 /// Retrieves the MemCheckCond and MemCheckBlock that were generated as IR
1844 /// outside VPlan.
1845 std::pair<Value *, BasicBlock *> getMemRuntimeChecks() const {
1846 using namespace llvm::PatternMatch;
1847 if (MemRuntimeCheckCond && match(MemRuntimeCheckCond, m_ZeroInt()))
1848 return {nullptr, nullptr};
1849 return {MemRuntimeCheckCond, MemCheckBlock};
1850 }
1851
1852 /// Return true if any runtime checks have been added
1853 bool hasChecks() const {
1854 return getSCEVChecks().first || getMemRuntimeChecks().first;
1855 }
1856};
1857} // namespace
1858
1860 return Style == TailFoldingStyle::Data ||
1862}
1863
1867
1868// Return true if \p OuterLp is an outer loop annotated with hints for explicit
1869// vectorization. The loop needs to be annotated with #pragma omp simd
1870// simdlen(#) or #pragma clang vectorize(enable) vectorize_width(#). If the
1871// vector length information is not provided, vectorization is not considered
1872// explicit. Interleave hints are not allowed either. These limitations will be
1873// relaxed in the future.
1874// Please, note that we are currently forced to abuse the pragma 'clang
1875// vectorize' semantics. This pragma provides *auto-vectorization hints*
1876// (i.e., LV must check that vectorization is legal) whereas pragma 'omp simd'
1877// provides *explicit vectorization hints* (LV can bypass legal checks and
1878// assume that vectorization is legal). However, both hints are implemented
1879// using the same metadata (llvm.loop.vectorize, processed by
1880// LoopVectorizeHints). This will be fixed in the future when the native IR
1881// representation for pragma 'omp simd' is introduced.
1882static bool isExplicitVecOuterLoop(Loop *OuterLp,
1884 assert(!OuterLp->isInnermost() && "This is not an outer loop");
1885 LoopVectorizeHints Hints(OuterLp, true /*DisableInterleaving*/, *ORE);
1886
1887 // Only outer loops with an explicit vectorization hint are supported.
1888 // Unannotated outer loops are ignored.
1890 return false;
1891
1892 Function *Fn = OuterLp->getHeader()->getParent();
1893 if (!Hints.allowVectorization(Fn, OuterLp,
1894 true /*VectorizeOnlyWhenForced*/)) {
1895 LLVM_DEBUG(dbgs() << "LV: Loop hints prevent outer loop vectorization.\n");
1896 return false;
1897 }
1898
1899 if (Hints.getInterleave() > 1) {
1900 // TODO: Interleave support is future work.
1901 LLVM_DEBUG(dbgs() << "LV: Not vectorizing: Interleave is not supported for "
1902 "outer loops.\n");
1903 Hints.emitRemarkWithHints();
1904 return false;
1905 }
1906
1907 return true;
1908}
1909
1913 // Collect inner loops and outer loops without irreducible control flow. For
1914 // now, only collect outer loops that have explicit vectorization hints. If we
1915 // are stress testing the VPlan H-CFG construction, we collect the outermost
1916 // loop of every loop nest.
1917 if (L.isInnermost() || VPlanBuildOuterloopStressTest ||
1919 LoopBlocksRPO RPOT(&L);
1920 RPOT.perform(LI);
1922 V.push_back(&L);
1923 // TODO: Collect inner loops inside marked outer loops in case
1924 // vectorization fails for the outer loop. Do not invoke
1925 // 'containsIrreducibleCFG' again for inner loops when the outer loop is
1926 // already known to be reducible. We can use an inherited attribute for
1927 // that.
1928 return;
1929 }
1930 }
1931 for (Loop *InnerL : L)
1932 collectSupportedLoops(*InnerL, LI, ORE, V);
1933}
1934
1935//===----------------------------------------------------------------------===//
1936// Implementation of LoopVectorizationLegality, InnerLoopVectorizer and
1937// LoopVectorizationCostModel and LoopVectorizationPlanner.
1938//===----------------------------------------------------------------------===//
1939
1940/// For the given VF and UF and maximum trip count computed for the loop, return
1941/// whether the induction variable might overflow in the vectorized loop. If not,
1942/// then we know a runtime overflow check always evaluates to false and can be
1943/// removed.
1945 const LoopVectorizationCostModel *Cost,
1946 ElementCount VF, std::optional<unsigned> UF = std::nullopt) {
1947 // Always be conservative if we don't know the exact unroll factor.
1948 unsigned MaxUF = UF ? *UF
1949 : std::max(Cost->TTI.getMaxInterleaveFactor(VF, false),
1950 Cost->TTI.getMaxInterleaveFactor(VF, true));
1951
1952 IntegerType *IdxTy = Cost->Legal->getWidestInductionType();
1953 APInt MaxUIntTripCount = IdxTy->getMask();
1954
1955 // We know the runtime overflow check is known false iff the (max) trip-count
1956 // is known and (max) trip-count + (VF * UF) does not overflow in the type of
1957 // the vector loop induction variable.
1958 if (std::optional<ElementCount> TC = getSmallBestKnownTC(
1959 Cost->PSE, Cost->TheLoop,
1960 /*CanUseConstantMax=*/true, /*CanExcludeZeroTrips=*/false,
1961 /*ComputeUpperBoundOnly=*/true)) {
1962 unsigned MaxVF = VF.getKnownMinValue();
1963 unsigned MaxTC = TC->getKnownMinValue();
1964 if (VF.isScalable() || TC->isScalable()) {
1965 std::optional<unsigned> MaxVScale =
1966 getMaxVScale(*Cost->TheFunction, Cost->TTI);
1967 if (!MaxVScale)
1968 return false;
1969 if (VF.isScalable())
1970 MaxVF *= *MaxVScale;
1971 if (TC->isScalable()) {
1972 bool Overflow;
1973 MaxTC = SaturatingMultiply(MaxTC, *MaxVScale, &Overflow);
1974 if (Overflow)
1975 return false;
1976 }
1977 }
1978
1979 return (MaxUIntTripCount - MaxTC).ugt(MaxVF * MaxUF);
1980 }
1981
1982 return false;
1983}
1984
1985// Return whether we allow using masked interleave-groups (for dealing with
1986// strided loads/stores that reside in predicated blocks, or for dealing
1987// with gaps).
1989 // If an override option has been passed in for interleaved accesses, use it.
1990 if (EnableMaskedInterleavedMemAccesses.getNumOccurrences() > 0)
1992
1993 return TTI.enableMaskedInterleavedAccessVectorization();
1994}
1995
1996/// Replace \p VPBB with a VPIRBasicBlock wrapping \p IRBB. All recipes from \p
1997/// VPBB are moved to the end of the newly created VPIRBasicBlock. All
1998/// predecessors and successors of VPBB, if any, are rewired to the new
1999/// VPIRBasicBlock. If \p VPBB may be unreachable, \p Plan must be passed.
2001 BasicBlock *IRBB,
2002 VPlan *Plan = nullptr) {
2003 if (!Plan)
2004 Plan = VPBB->getPlan();
2005 VPIRBasicBlock *IRVPBB = Plan->createVPIRBasicBlock(IRBB);
2006 auto IP = IRVPBB->begin();
2007 for (auto &R : make_early_inc_range(VPBB->phis()))
2008 R.moveBefore(*IRVPBB, IP);
2009
2010 for (auto &R :
2012 R.moveBefore(*IRVPBB, IRVPBB->end());
2013
2014 VPBlockUtils::reassociateBlocks(VPBB, IRVPBB);
2015 // VPBB is now dead and will be cleaned up when the plan gets destroyed.
2016 return IRVPBB;
2017}
2018
2020 BasicBlock *VectorPH = OrigLoop->getLoopPreheader();
2021 assert(VectorPH && "Invalid loop structure");
2022
2023 // NOTE: The Plan's scalar preheader VPBB isn't replaced with a VPIRBasicBlock
2024 // wrapping the newly created scalar preheader here at the moment, because the
2025 // Plan's scalar preheader may be unreachable at this point. Instead it is
2026 // replaced in executePlan.
2027 return SplitBlock(VectorPH, VectorPH->getTerminator(), DT, LI, nullptr,
2028 Twine(Prefix) + "scalar.ph");
2029}
2030
2031/// Knowing that loop \p L executes a single vector iteration, add instructions
2032/// that will get simplified and thus should not have any cost to \p
2033/// InstsToIgnore.
2036 SmallPtrSetImpl<Instruction *> &InstsToIgnore) {
2037 auto *Cmp = L->getLatchCmpInst();
2038 if (Cmp)
2039 InstsToIgnore.insert(Cmp);
2040 for (const auto &KV : IL) {
2041 // Extract the key by hand so that it can be used in the lambda below. Note
2042 // that captured structured bindings are a C++20 extension.
2043 const PHINode *IV = KV.first;
2044
2045 // Get next iteration value of the induction variable.
2046 Instruction *IVInst =
2047 cast<Instruction>(IV->getIncomingValueForBlock(L->getLoopLatch()));
2048 if (all_of(IVInst->users(),
2049 [&](const User *U) { return U == IV || U == Cmp; }))
2050 InstsToIgnore.insert(IVInst);
2051 }
2052}
2053
2055 // Create a new IR basic block for the scalar preheader.
2056 BasicBlock *ScalarPH = createScalarPreheader("");
2057 return ScalarPH->getSinglePredecessor();
2058}
2059
2060namespace {
2061
2062struct CSEDenseMapInfo {
2063 static bool canHandle(const Instruction *I) {
2066 }
2067
2068 static unsigned getHashValue(const Instruction *I) {
2069 assert(canHandle(I) && "Unknown instruction!");
2070 return hash_combine(I->getOpcode(),
2071 hash_combine_range(I->operand_values()));
2072 }
2073
2074 static bool isEqual(const Instruction *LHS, const Instruction *RHS) {
2075 return LHS->isIdenticalTo(RHS);
2076 }
2077};
2078
2079} // end anonymous namespace
2080
2081/// FIXME: This legacy common-subexpression-elimination routine is scheduled for
2082/// removal, in favor of the VPlan-based one.
2083static void legacyCSE(BasicBlock *BB) {
2084 // Perform simple cse.
2086 for (Instruction &In : llvm::make_early_inc_range(*BB)) {
2087 if (!CSEDenseMapInfo::canHandle(&In))
2088 continue;
2089
2090 // Check if we can replace this instruction with any of the
2091 // visited instructions.
2092 if (Instruction *V = CSEMap.lookup(&In)) {
2093 In.replaceAllUsesWith(V);
2094 In.eraseFromParent();
2095 continue;
2096 }
2097
2098 CSEMap[&In] = &In;
2099 }
2100}
2101
2102/// This function attempts to return a value that represents the ElementCount
2103/// at runtime. For fixed-width VFs we know this precisely at compile
2104/// time, but for scalable VFs we calculate it based on an estimate of the
2105/// vscale value.
2107 std::optional<unsigned> VScale) {
2108 unsigned EstimatedVF = VF.getKnownMinValue();
2109 if (VF.isScalable())
2110 if (VScale)
2111 EstimatedVF *= *VScale;
2112 assert(EstimatedVF >= 1 && "Estimated VF shouldn't be less than 1");
2113 return EstimatedVF;
2114}
2115
2116/// Returns the vector library variant function of \p CI usable at \p VF,
2117/// respecting \p MaskRequired, or nullptr if none is found: a mapping with
2118/// matching VF, masked if required, whose vector function is declared in the
2119/// module.
2121 bool MaskRequired,
2122 const TargetLibraryInfo *TLI) {
2123 if (!TLI || CI.isNoBuiltin())
2124 return nullptr;
2125 for (const VFInfo &Info : VFDatabase::getMappings(CI))
2126 if (Info.Shape.VF == VF && (!MaskRequired || Info.isMasked()))
2127 if (Function *F = CI.getModule()->getFunction(Info.VectorName))
2128 return F;
2129 return nullptr;
2130}
2131
2132/// Returns true iff \p CI has a library vector variant usable at \p VF.
2134 bool MaskRequired,
2135 const TargetLibraryInfo *TLI) {
2136 return getVectorLibraryVariantFor(CI, VF, MaskRequired, TLI) != nullptr;
2137}
2138
2141 ElementCount VF) const {
2142 Type *RetTy = CI->getType();
2144 for (auto &ArgOp : CI->args())
2145 Tys.push_back(ArgOp->getType());
2146
2147 InstructionCost ScalarCallCost = TTI.getCallInstrCost(
2148 CI->getCalledFunction(), RetTy, Tys, Config.CostKind);
2149
2150 // Cost of the scalar call (scalar VF) or its scalarization (vector VF). The
2151 // scalarization cost is only meaningful for fixed VFs.
2154 : ScalarCallCost * VF.getKnownMinValue() +
2156
2157 // The call may be vectorized at this VF, via a vector intrinsic or a vector
2158 // library variant.
2160 Cost = std::min(Cost, getVectorIntrinsicCost(CI, VF));
2161
2162 if (Function *Variant =
2164 Cost = std::min(Cost,
2165 TTI.getCallInstrCost(
2166 /*F=*/nullptr, Variant->getReturnType(),
2167 Variant->getFunctionType()->params(), Config.CostKind));
2168
2169 return Cost;
2170}
2171
2173 if (VF.isScalar() || !canVectorizeTy(Ty))
2174 return Ty;
2175 return toVectorizedTy(Ty, VF);
2176}
2177
2180 ElementCount VF) const {
2182 assert(ID && "Expected intrinsic call!");
2183 Type *RetTy = maybeVectorizeType(CI->getType(), VF);
2184 FastMathFlags FMF;
2185 if (auto *FPMO = dyn_cast<FPMathOperator>(CI))
2186 FMF = FPMO->getFastMathFlags();
2187
2190 SmallVector<Type *> ParamTys;
2191 std::transform(FTy->param_begin(), FTy->param_end(),
2192 std::back_inserter(ParamTys),
2193 [&](Type *Ty) { return maybeVectorizeType(Ty, VF); });
2194
2195 IntrinsicCostAttributes CostAttrs(ID, RetTy, Arguments, ParamTys, FMF,
2198 return TTI.getIntrinsicInstrCost(CostAttrs, Config.CostKind);
2199}
2200
2202 // Don't apply optimizations below when no (vector) loop remains, as they all
2203 // require one at the moment.
2204 VPBasicBlock *HeaderVPBB =
2205 vputils::getFirstLoopHeader(*State.Plan, State.VPDT);
2206 if (!HeaderVPBB)
2207 return;
2208
2209 BasicBlock *HeaderBB = State.CFG.VPBB2IRBB[HeaderVPBB];
2210
2211 // Remove redundant induction instructions.
2212 legacyCSE(HeaderBB);
2213}
2214
2215void LoopVectorizationCostModel::collectLoopScalars(ElementCount VF) {
2216 // We should not collect Scalars more than once per VF. Right now, this
2217 // function is called from collectUniformsAndScalars(), which already does
2218 // this check. Collecting Scalars for VF=1 does not make any sense.
2219 assert(VF.isVector() && !Scalars.contains(VF) &&
2220 "This function should not be visited twice for the same VF");
2221
2222 // This avoids any chances of creating a REPLICATE recipe during planning
2223 // since that would result in generation of scalarized code during execution,
2224 // which is not supported for scalable vectors.
2225 if (VF.isScalable()) {
2226 Scalars[VF].insert_range(Uniforms[VF]);
2227 return;
2228 }
2229
2231
2232 // These sets are used to seed the analysis with pointers used by memory
2233 // accesses that will remain scalar.
2235 SmallPtrSet<Instruction *, 8> PossibleNonScalarPtrs;
2236 auto *Latch = TheLoop->getLoopLatch();
2237
2238 // A helper that returns true if the use of Ptr by MemAccess will be scalar.
2239 // The pointer operands of loads and stores will be scalar as long as the
2240 // memory access is not a gather or scatter operation. The value operand of a
2241 // store will remain scalar if the store is scalarized.
2242 auto IsScalarUse = [&](Instruction *MemAccess, Value *Ptr) {
2243 InstWidening WideningDecision = getWideningDecision(MemAccess, VF);
2244 assert(WideningDecision != CM_Unknown &&
2245 "Widening decision should be ready at this moment");
2246 if (auto *Store = dyn_cast<StoreInst>(MemAccess))
2247 if (Ptr == Store->getValueOperand())
2248 return WideningDecision == CM_Scalarize;
2249 assert(Ptr == getLoadStorePointerOperand(MemAccess) &&
2250 "Ptr is neither a value or pointer operand");
2251 return WideningDecision != CM_GatherScatter;
2252 };
2253
2254 // A helper that returns true if the given value is a getelementptr
2255 // instruction contained in the loop.
2256 auto IsLoopVaryingGEP = [&](Value *V) {
2257 return isa<GetElementPtrInst>(V) && !TheLoop->isLoopInvariant(V);
2258 };
2259
2260 // A helper that evaluates a memory access's use of a pointer. If the use will
2261 // be a scalar use and the pointer is only used by memory accesses, we place
2262 // the pointer in ScalarPtrs. Otherwise, the pointer is placed in
2263 // PossibleNonScalarPtrs.
2264 auto EvaluatePtrUse = [&](Instruction *MemAccess, Value *Ptr) {
2265 // We only care about bitcast and getelementptr instructions contained in
2266 // the loop.
2267 if (!IsLoopVaryingGEP(Ptr))
2268 return;
2269
2270 // If the pointer has already been identified as scalar (e.g., if it was
2271 // also identified as uniform), there's nothing to do.
2272 auto *I = cast<Instruction>(Ptr);
2273 if (Worklist.count(I))
2274 return;
2275
2276 // If the use of the pointer will be a scalar use, and all users of the
2277 // pointer are memory accesses, place the pointer in ScalarPtrs. Otherwise,
2278 // place the pointer in PossibleNonScalarPtrs.
2279 if (IsScalarUse(MemAccess, Ptr) &&
2281 ScalarPtrs.insert(I);
2282 else
2283 PossibleNonScalarPtrs.insert(I);
2284 };
2285
2286 // We seed the scalars analysis with three classes of instructions: (1)
2287 // instructions marked uniform-after-vectorization and (2) bitcast,
2288 // getelementptr and (pointer) phi instructions used by memory accesses
2289 // requiring a scalar use.
2290 //
2291 // (1) Add to the worklist all instructions that have been identified as
2292 // uniform-after-vectorization.
2293 Worklist.insert_range(Uniforms[VF]);
2294
2295 // (2) Add to the worklist all bitcast and getelementptr instructions used by
2296 // memory accesses requiring a scalar use. The pointer operands of loads and
2297 // stores will be scalar unless the operation is a gather or scatter.
2298 // The value operand of a store will remain scalar if the store is scalarized.
2299 for (auto *BB : TheLoop->blocks())
2300 for (auto &I : *BB) {
2301 if (auto *Load = dyn_cast<LoadInst>(&I)) {
2302 EvaluatePtrUse(Load, Load->getPointerOperand());
2303 } else if (auto *Store = dyn_cast<StoreInst>(&I)) {
2304 EvaluatePtrUse(Store, Store->getPointerOperand());
2305 EvaluatePtrUse(Store, Store->getValueOperand());
2306 }
2307 }
2308 for (auto *I : ScalarPtrs)
2309 if (!PossibleNonScalarPtrs.count(I)) {
2310 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *I << "\n");
2311 Worklist.insert(I);
2312 }
2313
2314 // Insert the forced scalars.
2315 // FIXME: Currently VPWidenPHIRecipe() often creates a dead vector
2316 // induction variable when the PHI user is scalarized.
2317 auto ForcedScalar = ForcedScalars.find(VF);
2318 if (ForcedScalar != ForcedScalars.end())
2319 for (auto *I : ForcedScalar->second) {
2320 LLVM_DEBUG(dbgs() << "LV: Found (forced) scalar instruction: " << *I << "\n");
2321 Worklist.insert(I);
2322 }
2323
2324 // Expand the worklist by looking through any bitcasts and getelementptr
2325 // instructions we've already identified as scalar. This is similar to the
2326 // expansion step in collectLoopUniforms(); however, here we're only
2327 // expanding to include additional bitcasts and getelementptr instructions.
2328 unsigned Idx = 0;
2329 while (Idx != Worklist.size()) {
2330 Instruction *Dst = Worklist[Idx++];
2331 if (!IsLoopVaryingGEP(Dst->getOperand(0)))
2332 continue;
2333 auto *Src = cast<Instruction>(Dst->getOperand(0));
2334 if (llvm::all_of(Src->users(), [&](User *U) -> bool {
2335 auto *J = cast<Instruction>(U);
2336 return !TheLoop->contains(J) || Worklist.count(J) ||
2337 ((isa<LoadInst>(J) || isa<StoreInst>(J)) &&
2338 IsScalarUse(J, Src));
2339 })) {
2340 Worklist.insert(Src);
2341 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *Src << "\n");
2342 }
2343 }
2344
2345 // An induction variable will remain scalar if all users of the induction
2346 // variable and induction variable update remain scalar.
2347 for (const auto &Induction : Legal->getInductionVars()) {
2348 auto *Ind = Induction.first;
2349 auto *IndUpdate = cast<Instruction>(Ind->getIncomingValueForBlock(Latch));
2350
2351 // If tail-folding is applied, the primary induction variable will be used
2352 // to feed a vector compare.
2353 if (Ind == Legal->getPrimaryInduction() && foldTailByMasking())
2354 continue;
2355
2356 // Returns true if \p Indvar is a pointer induction that is used directly by
2357 // load/store instruction \p I.
2358 auto IsDirectLoadStoreFromPtrIndvar = [&](Instruction *Indvar,
2359 Instruction *I) {
2360 return Induction.second.getKind() ==
2363 Indvar == getLoadStorePointerOperand(I) && IsScalarUse(I, Indvar);
2364 };
2365
2366 // Determine if all users of the induction variable are scalar after
2367 // vectorization.
2368 bool ScalarInd = all_of(Ind->users(), [&](User *U) -> bool {
2369 auto *I = cast<Instruction>(U);
2370 return I == IndUpdate || !TheLoop->contains(I) || Worklist.count(I) ||
2371 IsDirectLoadStoreFromPtrIndvar(Ind, I);
2372 });
2373 if (!ScalarInd)
2374 continue;
2375
2376 // If the induction variable update is a fixed-order recurrence, neither the
2377 // induction variable or its update should be marked scalar after
2378 // vectorization.
2379 auto *IndUpdatePhi = dyn_cast<PHINode>(IndUpdate);
2380 if (IndUpdatePhi && Legal->isFixedOrderRecurrence(IndUpdatePhi))
2381 continue;
2382
2383 // Determine if all users of the induction variable update instruction are
2384 // scalar after vectorization.
2385 bool ScalarIndUpdate = all_of(IndUpdate->users(), [&](User *U) -> bool {
2386 auto *I = cast<Instruction>(U);
2387 return I == Ind || !TheLoop->contains(I) || Worklist.count(I) ||
2388 IsDirectLoadStoreFromPtrIndvar(IndUpdate, I);
2389 });
2390 if (!ScalarIndUpdate)
2391 continue;
2392
2393 // The induction variable and its update instruction will remain scalar.
2394 Worklist.insert(Ind);
2395 Worklist.insert(IndUpdate);
2396 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *Ind << "\n");
2397 LLVM_DEBUG(dbgs() << "LV: Found scalar instruction: " << *IndUpdate
2398 << "\n");
2399 }
2400
2401 Scalars[VF].insert_range(Worklist);
2402}
2403
2405 ElementCount VF) {
2406 if (!isPredicatedInst(I))
2407 return false;
2408
2409 // Do we have a non-scalar lowering for this predicated
2410 // instruction? No - it is scalar with predication.
2411 switch(I->getOpcode()) {
2412 default:
2413 return true;
2414 case Instruction::Call: {
2415 if (VF.isScalar())
2416 return true;
2417 auto *CI = cast<CallInst>(I);
2418 // A vector intrinsic or library variant lowering avoids scalarization.
2419 return !getVectorIntrinsicIDForCall(CI, TLI) &&
2421 }
2422 case Instruction::Load:
2423 case Instruction::Store: {
2424 bool IsConsecutive = Legal->isConsecutivePtr(getLoadStoreType(I),
2426 return !(IsConsecutive && Config.isLegalMaskedLoadOrStore(I, VF)) &&
2427 !Config.isLegalGatherOrScatter(I, VF);
2428 }
2429 case Instruction::UDiv:
2430 case Instruction::SDiv:
2431 case Instruction::SRem:
2432 case Instruction::URem: {
2433 // We have the option to use the llvm.masked.udiv intrinsics to avoid
2434 // predication. The cost based decision here will always select the masked
2435 // intrinsics for scalable vectors as scalarization isn't legal.
2436 const auto [ScalarCost, MaskedCost] = getDivRemSpeculationCost(I, VF);
2437 return isDivRemScalarWithPredication(ScalarCost, MaskedCost);
2438 }
2439 }
2440}
2441
2443 return Legal->isMaskRequired(I, foldTailByMasking());
2444}
2445
2446// TODO: Fold into LoopVectorizationLegality::isMaskRequired.
2448 // TODO: We can use the loop-preheader as context point here and get
2449 // context sensitive reasoning for isSafeToSpeculativelyExecute.
2453 return false;
2454
2455 // If the instruction was executed conditionally in the original scalar loop,
2456 // predication is needed with a mask whose lanes are all possibly inactive.
2457 if (Legal->blockNeedsPredication(I->getParent()))
2458 return true;
2459
2460 // If we're not folding the tail by masking and not vectorizing a loop with
2461 // uncountable exits and side effects, predication is unnecessary.
2462 if (!foldTailByMasking() && !Legal->hasUncountableExitWithSideEffects())
2463 return false;
2464
2465 // All that remain are instructions with side-effects originally executed in
2466 // the loop unconditionally, but now execute under a tail-fold mask (only)
2467 // having at least one active lane (the first). If the side-effects of the
2468 // instruction are invariant, executing it w/o (the tail-folding) mask is safe
2469 // - it will cause the same side-effects as when masked.
2470 switch(I->getOpcode()) {
2471 default:
2473 "instruction should have been considered by earlier checks");
2474 case Instruction::Call:
2475 // Side-effects of a Call are assumed to be non-invariant, needing a
2476 // (fold-tail) mask.
2478 "should have returned earlier for calls not needing a mask");
2479 return true;
2480 case Instruction::Load:
2481 // If the address is loop invariant no predication is needed.
2482 return !Legal->isInvariant(getLoadStorePointerOperand(I));
2483 case Instruction::Store: {
2484 // For stores, we need to prove both speculation safety (which follows from
2485 // the same argument as loads), but also must prove the value being stored
2486 // is correct. The easiest form of the later is to require that all values
2487 // stored are the same.
2488 return !(Legal->isInvariant(getLoadStorePointerOperand(I)) &&
2489 TheLoop->isLoopInvariant(cast<StoreInst>(I)->getValueOperand()));
2490 }
2491 case Instruction::UDiv:
2492 case Instruction::URem:
2493 // If the divisor is loop-invariant no predication is needed.
2494 return !Legal->isInvariant(I->getOperand(1));
2495 case Instruction::SDiv:
2496 case Instruction::SRem:
2497 // Conservative for now, since masked-off lanes may be poison and could
2498 // trigger signed overflow.
2499 return true;
2500 }
2501}
2502
2506 return 1;
2507 // If the block wasn't originally predicated then return early to avoid
2508 // computing BlockFrequencyInfo unnecessarily.
2509 if (!Legal->blockNeedsPredication(BB))
2510 return 1;
2511
2512 uint64_t HeaderFreq =
2513 getBFI().getBlockFreq(TheLoop->getHeader()).getFrequency();
2514 uint64_t BBFreq = getBFI().getBlockFreq(BB).getFrequency();
2515 assert(HeaderFreq >= BBFreq &&
2516 "Header has smaller block freq than dominated BB?");
2517 return std::round((double)HeaderFreq / BBFreq);
2518}
2519
2521 switch (Opcode) {
2522 case Instruction::UDiv:
2523 return Intrinsic::masked_udiv;
2524 case Instruction::SDiv:
2525 return Intrinsic::masked_sdiv;
2526 case Instruction::URem:
2527 return Intrinsic::masked_urem;
2528 case Instruction::SRem:
2529 return Intrinsic::masked_srem;
2530 default:
2531 llvm_unreachable("Unexpected opcode");
2532 }
2533}
2534
2535std::pair<InstructionCost, InstructionCost>
2537 ElementCount VF) {
2538 assert(I->getOpcode() == Instruction::UDiv ||
2539 I->getOpcode() == Instruction::SDiv ||
2540 I->getOpcode() == Instruction::SRem ||
2541 I->getOpcode() == Instruction::URem);
2543
2544 // Scalarization isn't legal for scalable vector types
2545 InstructionCost ScalarizationCost = InstructionCost::getInvalid();
2546 if (!VF.isScalable()) {
2547 // Get the scalarization cost and scale this amount by the probability of
2548 // executing the predicated block. If the instruction is not predicated,
2549 // we fall through to the next case.
2550 ScalarizationCost = 0;
2551
2552 // These instructions have a non-void type, so account for the phi nodes
2553 // that we will create. This cost is likely to be zero. The phi node
2554 // cost, if any, should be scaled by the block probability because it
2555 // models a copy at the end of each predicated block.
2556 ScalarizationCost += VF.getFixedValue() *
2557 TTI.getCFInstrCost(Instruction::PHI, Config.CostKind);
2558
2559 // The cost of the non-predicated instruction.
2560 ScalarizationCost +=
2561 VF.getFixedValue() * TTI.getArithmeticInstrCost(
2562 I->getOpcode(), I->getType(), Config.CostKind);
2563
2564 // The cost of insertelement and extractelement instructions needed for
2565 // scalarization.
2566 ScalarizationCost += getScalarizationOverhead(I, VF);
2567
2568 // Scale the cost by the probability of executing the predicated blocks.
2569 // This assumes the predicated block for each vector lane is equally
2570 // likely.
2571 ScalarizationCost =
2572 ScalarizationCost /
2573 getPredBlockCostDivisor(Config.CostKind, I->getParent());
2574 }
2575
2576 auto *VecTy = toVectorTy(I->getType(), VF);
2577 auto *MaskTy = toVectorTy(Type::getInt1Ty(I->getContext()), VF);
2578 IntrinsicCostAttributes ICA(getMaskedDivRemIntrinsic(I->getOpcode()), VecTy,
2579 {VecTy, VecTy, MaskTy});
2580 InstructionCost MaskedCost = TTI.getIntrinsicInstrCost(ICA, Config.CostKind);
2581 return {ScalarizationCost, MaskedCost};
2582}
2583
2585 Instruction *I, ElementCount VF) const {
2586 assert(isAccessInterleaved(I) && "Expecting interleaved access.");
2588 "Decision should not be set yet.");
2589 auto *Group = getInterleavedAccessGroup(I);
2590 assert(Group && "Must have a group.");
2591 unsigned InterleaveFactor = Group->getFactor();
2592
2593 // If the instruction's allocated size doesn't equal its type size, it
2594 // requires padding and will be scalarized.
2595 auto &DL = I->getDataLayout();
2596 auto *ScalarTy = getLoadStoreType(I);
2597 if (hasIrregularType(ScalarTy, DL))
2598 return false;
2599
2600 // For scalable vectors, the interleave factors must be <= 8 since we require
2601 // the (de)interleaveN intrinsics instead of shufflevectors.
2602 if (VF.isScalable() && InterleaveFactor > 8)
2603 return false;
2604
2605 // If the group involves a non-integral pointer, we may not be able to
2606 // losslessly cast all values to a common type.
2607 bool ScalarNI = DL.isNonIntegralPointerType(ScalarTy);
2608 for (Instruction *Member : Group->members()) {
2609 auto *MemberTy = getLoadStoreType(Member);
2610 bool MemberNI = DL.isNonIntegralPointerType(MemberTy);
2611 // Don't coerce non-integral pointers to integers or vice versa.
2612 if (MemberNI != ScalarNI)
2613 // TODO: Consider adding special nullptr value case here
2614 return false;
2615 if (MemberNI && ScalarNI &&
2616 ScalarTy->getPointerAddressSpace() !=
2617 MemberTy->getPointerAddressSpace())
2618 return false;
2619 }
2620
2621 // Check if masking is required.
2622 // A Group may need masking for one of two reasons: it resides in a block that
2623 // needs predication, or it was decided to use masking to deal with gaps
2624 // (either a gap at the end of a load-access that may result in a speculative
2625 // load, or any gaps in a store-access).
2626 bool PredicatedAccessRequiresMasking =
2628 bool LoadAccessWithGapsRequiresEpilogMasking =
2629 isa<LoadInst>(I) && Group->requiresScalarEpilogue() &&
2631 bool StoreAccessWithGapsRequiresMasking =
2632 isa<StoreInst>(I) && !Group->isFull();
2633 if (!PredicatedAccessRequiresMasking &&
2634 !LoadAccessWithGapsRequiresEpilogMasking &&
2635 !StoreAccessWithGapsRequiresMasking)
2636 return true;
2637
2638 // If masked interleaving is required, we expect that the user/target had
2639 // enabled it, because otherwise it either wouldn't have been created or
2640 // it should have been invalidated by the CostModel.
2642 "Masked interleave-groups for predicated accesses are not enabled.");
2643
2644 if (Group->isReverse())
2645 return false;
2646
2647 // TODO: Support interleaved access that requires a gap mask for scalable VFs.
2648 bool NeedsMaskForGaps = LoadAccessWithGapsRequiresEpilogMasking ||
2649 StoreAccessWithGapsRequiresMasking;
2650 if (VF.isScalable() && NeedsMaskForGaps)
2651 return false;
2652
2653 return Config.isLegalMaskedLoadOrStore(I, VF);
2654}
2655
2656std::optional<LoopVectorizationCostModel::InstWidening>
2658 ElementCount VF) {
2659 // Get and ensure we have a valid memory instruction.
2660 assert((isa<LoadInst, StoreInst>(I)) && "Invalid memory instruction");
2661
2662 auto *Ptr = getLoadStorePointerOperand(I);
2663 auto *ScalarTy = getLoadStoreType(I);
2664
2665 // In order to be widened, the pointer should be consecutive, first of all.
2666 int Stride = Legal->isConsecutivePtr(ScalarTy, Ptr);
2667 if (!Stride)
2668 return std::nullopt;
2669
2670 // If the instruction is a store located in a predicated block, it will be
2671 // scalarized.
2672 if (isScalarWithPredication(I, VF))
2673 return std::nullopt;
2674
2675 // If the instruction's allocated size doesn't equal it's type size, it
2676 // requires padding and will be scalarized.
2677 auto &DL = I->getDataLayout();
2678 if (hasIrregularType(ScalarTy, DL))
2679 return std::nullopt;
2680
2681 return Stride == 1 ? CM_Widen : CM_Widen_Reverse;
2682}
2683
2684void LoopVectorizationCostModel::collectLoopUniforms(ElementCount VF) {
2685 // We should not collect Uniforms more than once per VF. Right now,
2686 // this function is called from collectUniformsAndScalars(), which
2687 // already does this check. Collecting Uniforms for VF=1 does not make any
2688 // sense.
2689
2690 assert(VF.isVector() && !Uniforms.contains(VF) &&
2691 "This function should not be visited twice for the same VF");
2692
2693 // Visit the list of Uniforms. If we find no uniform value, we won't
2694 // analyze again. Uniforms.count(VF) will return 1.
2695 Uniforms[VF].clear();
2696
2697 // Now we know that the loop is vectorizable!
2698 // Collect instructions inside the loop that will remain uniform after
2699 // vectorization.
2700
2701 // Global values, params and instructions outside of current loop are out of
2702 // scope.
2703 auto IsOutOfScope = [&](Value *V) -> bool {
2705 return (!I || !TheLoop->contains(I));
2706 };
2707
2708 // Worklist containing uniform instructions demanding lane 0.
2709 SetVector<Instruction *> Worklist;
2710
2711 // Add uniform instructions demanding lane 0 to the worklist. Instructions
2712 // that require predication must not be considered uniform after
2713 // vectorization, because that would create an erroneous replicating region
2714 // where only a single instance out of VF should be formed.
2715 auto AddToWorklistIfAllowed = [&](Instruction *I) -> void {
2716 if (IsOutOfScope(I)) {
2717 LLVM_DEBUG(dbgs() << "LV: Found not uniform due to scope: "
2718 << *I << "\n");
2719 return;
2720 }
2721 if (isPredicatedInst(I)) {
2722 LLVM_DEBUG(
2723 dbgs() << "LV: Found not uniform due to requiring predication: " << *I
2724 << "\n");
2725 return;
2726 }
2727 LLVM_DEBUG(dbgs() << "LV: Found uniform instruction: " << *I << "\n");
2728 Worklist.insert(I);
2729 };
2730
2731 // Start with the conditional branches exiting the loop. If the branch
2732 // condition is an instruction contained in the loop that is only used by the
2733 // branch, it is uniform. Note conditions from uncountable early exits are not
2734 // uniform.
2736 TheLoop->getExitingBlocks(Exiting);
2737 for (BasicBlock *E : Exiting) {
2738 if (Legal->hasUncountableEarlyExit() && TheLoop->getLoopLatch() != E)
2739 continue;
2740 auto *Cmp = dyn_cast<Instruction>(E->getTerminator()->getOperand(0));
2741 if (Cmp && TheLoop->contains(Cmp) && Cmp->hasOneUse())
2742 AddToWorklistIfAllowed(Cmp);
2743 }
2744
2745 auto PrevVF = VF.divideCoefficientBy(2);
2746 // Return true if all lanes perform the same memory operation, and we can
2747 // thus choose to execute only one.
2748 auto IsUniformMemOpUse = [&](Instruction *I) {
2749 // If the value was already known to not be uniform for the previous
2750 // (smaller VF), it cannot be uniform for the larger VF.
2751 if (PrevVF.isVector()) {
2752 auto Iter = Uniforms.find(PrevVF);
2753 if (Iter != Uniforms.end() && !Iter->second.contains(I))
2754 return false;
2755 }
2756 if (!isUniformMemOp(*I, VF))
2757 return false;
2758 if (isa<LoadInst>(I))
2759 // Loading the same address always produces the same result - at least
2760 // assuming aliasing and ordering which have already been checked.
2761 return true;
2762 // Storing the same value on every iteration.
2763 return TheLoop->isLoopInvariant(cast<StoreInst>(I)->getValueOperand());
2764 };
2765
2766 auto IsUniformDecision = [&](Instruction *I, ElementCount VF) {
2767 InstWidening WideningDecision = getWideningDecision(I, VF);
2768 assert(WideningDecision != CM_Unknown &&
2769 "Widening decision should be ready at this moment");
2770
2771 if (IsUniformMemOpUse(I))
2772 return true;
2773
2774 return (WideningDecision == CM_Widen ||
2775 WideningDecision == CM_Widen_Reverse ||
2776 WideningDecision == CM_Interleave);
2777 };
2778
2779 // Returns true if Ptr is the pointer operand of a memory access instruction
2780 // I, I is known to not require scalarization, and the pointer is not also
2781 // stored.
2782 auto IsVectorizedMemAccessUse = [&](Instruction *I, Value *Ptr) -> bool {
2783 if (isa<StoreInst>(I) && I->getOperand(0) == Ptr)
2784 return false;
2785 return getLoadStorePointerOperand(I) == Ptr &&
2786 (IsUniformDecision(I, VF) || Legal->isInvariant(Ptr));
2787 };
2788
2789 // Holds a list of values which are known to have at least one uniform use.
2790 // Note that there may be other uses which aren't uniform. A "uniform use"
2791 // here is something which only demands lane 0 of the unrolled iterations;
2792 // it does not imply that all lanes produce the same value (e.g. this is not
2793 // the usual meaning of uniform)
2794 SetVector<Value *> HasUniformUse;
2795
2796 // Scan the loop for instructions which are either a) known to have only
2797 // lane 0 demanded or b) are uses which demand only lane 0 of their operand.
2798 for (auto *BB : TheLoop->blocks())
2799 for (auto &I : *BB) {
2800 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(&I)) {
2801 switch (II->getIntrinsicID()) {
2802 case Intrinsic::sideeffect:
2803 case Intrinsic::experimental_noalias_scope_decl:
2804 case Intrinsic::assume:
2805 case Intrinsic::lifetime_start:
2806 case Intrinsic::lifetime_end:
2807 if (TheLoop->hasLoopInvariantOperands(&I))
2808 AddToWorklistIfAllowed(&I);
2809 break;
2810 default:
2811 break;
2812 }
2813 }
2814
2815 if (auto *EVI = dyn_cast<ExtractValueInst>(&I)) {
2816 if (IsOutOfScope(EVI->getAggregateOperand())) {
2817 AddToWorklistIfAllowed(EVI);
2818 continue;
2819 }
2820 // Only ExtractValue instructions where the aggregate value comes from a
2821 // call are allowed to be non-uniform.
2822 assert(isa<CallInst>(EVI->getAggregateOperand()) &&
2823 "Expected aggregate value to be call return value");
2824 }
2825
2826 // If there's no pointer operand, there's nothing to do.
2827 auto *Ptr = getLoadStorePointerOperand(&I);
2828 if (!Ptr)
2829 continue;
2830
2831 // If the pointer can be proven to be uniform, always add it to the
2832 // worklist.
2833 if (isa<Instruction>(Ptr) && isUniform(Ptr, VF))
2834 AddToWorklistIfAllowed(cast<Instruction>(Ptr));
2835
2836 if (IsUniformMemOpUse(&I))
2837 AddToWorklistIfAllowed(&I);
2838
2839 if (IsVectorizedMemAccessUse(&I, Ptr))
2840 HasUniformUse.insert(Ptr);
2841 }
2842
2843 // Add to the worklist any operands which have *only* uniform (e.g. lane 0
2844 // demanding) users. Since loops are assumed to be in LCSSA form, this
2845 // disallows uses outside the loop as well.
2846 for (auto *V : HasUniformUse) {
2847 if (IsOutOfScope(V))
2848 continue;
2849 auto *I = cast<Instruction>(V);
2850 bool UsersAreMemAccesses = all_of(I->users(), [&](User *U) -> bool {
2851 auto *UI = cast<Instruction>(U);
2852 return TheLoop->contains(UI) && IsVectorizedMemAccessUse(UI, V);
2853 });
2854 if (UsersAreMemAccesses)
2855 AddToWorklistIfAllowed(I);
2856 }
2857
2858 // Expand Worklist in topological order: whenever a new instruction
2859 // is added , its users should be already inside Worklist. It ensures
2860 // a uniform instruction will only be used by uniform instructions.
2861 unsigned Idx = 0;
2862 while (Idx != Worklist.size()) {
2863 Instruction *I = Worklist[Idx++];
2864
2865 for (auto *OV : I->operand_values()) {
2866 // isOutOfScope operands cannot be uniform instructions.
2867 if (IsOutOfScope(OV))
2868 continue;
2869 // First order recurrence Phi's should typically be considered
2870 // non-uniform.
2871 auto *OP = dyn_cast<PHINode>(OV);
2872 if (OP && Legal->isFixedOrderRecurrence(OP))
2873 continue;
2874 // If all the users of the operand are uniform, then add the
2875 // operand into the uniform worklist.
2876 auto *OI = cast<Instruction>(OV);
2877 if (llvm::all_of(OI->users(), [&](User *U) -> bool {
2878 auto *J = cast<Instruction>(U);
2879 return Worklist.count(J) || IsVectorizedMemAccessUse(J, OI);
2880 }))
2881 AddToWorklistIfAllowed(OI);
2882 }
2883 }
2884
2885 // For an instruction to be added into Worklist above, all its users inside
2886 // the loop should also be in Worklist. However, this condition cannot be
2887 // true for phi nodes that form a cyclic dependence. We must process phi
2888 // nodes separately. An induction variable will remain uniform if all users
2889 // of the induction variable and induction variable update remain uniform.
2890 // The code below handles both pointer and non-pointer induction variables.
2891 BasicBlock *Latch = TheLoop->getLoopLatch();
2892 for (const auto &Induction : Legal->getInductionVars()) {
2893 auto *Ind = Induction.first;
2894 auto *IndUpdate = cast<Instruction>(Ind->getIncomingValueForBlock(Latch));
2895
2896 // Determine if all users of the induction variable are uniform after
2897 // vectorization.
2898 bool UniformInd = all_of(Ind->users(), [&](User *U) -> bool {
2899 auto *I = cast<Instruction>(U);
2900 return I == IndUpdate || !TheLoop->contains(I) || Worklist.count(I) ||
2901 IsVectorizedMemAccessUse(I, Ind);
2902 });
2903 if (!UniformInd)
2904 continue;
2905
2906 // Determine if all users of the induction variable update instruction are
2907 // uniform after vectorization.
2908 bool UniformIndUpdate = all_of(IndUpdate->users(), [&](User *U) -> bool {
2909 auto *I = cast<Instruction>(U);
2910 return I == Ind || Worklist.count(I) ||
2911 IsVectorizedMemAccessUse(I, IndUpdate);
2912 });
2913 if (!UniformIndUpdate)
2914 continue;
2915
2916 // The induction variable and its update instruction will remain uniform.
2917 AddToWorklistIfAllowed(Ind);
2918 AddToWorklistIfAllowed(IndUpdate);
2919 }
2920
2921 Uniforms[VF].insert_range(Worklist);
2922}
2923
2924FixedScalableVFPair
2926 // Make sure once we return PartialAliasMaskingStatus is not "NotDecided".
2927 scope_exit EnsureAliasMaskingStatusIsDecidedOnReturn([this] {
2928 if (PartialAliasMaskingStatus == AliasMaskingStatus::NotDecided)
2929 PartialAliasMaskingStatus = AliasMaskingStatus::Disabled;
2930 });
2931
2932 // For outer loops, use simple type-based heuristic VF. No cost model or
2933 // memory dependence analysis is available.
2934 if (!TheLoop->isInnermost()) {
2935 return Config.computeVPlanOuterloopVF(UserVF);
2936 }
2937
2938 if (Legal->getRuntimePointerChecking()->Need && TTI.hasBranchDivergence()) {
2939 // TODO: It may be useful to do since it's still likely to be dynamically
2940 // uniform if the target can skip.
2942 "Not inserting runtime ptr check for divergent target",
2943 "runtime pointer checks needed. Not enabled for divergent target",
2944 "CantVersionLoopWithDivergentTarget", ORE, TheLoop);
2946 }
2947
2948 ScalarEvolution *SE = PSE.getSE();
2950 unsigned MaxTC = PSE.getSmallConstantMaxTripCount();
2951 if (!MaxTC && EpilogueLoweringStatus == CM_EpilogueAllowed)
2953 LLVM_DEBUG(dbgs() << "LV: Found trip count: " << TC << '\n');
2954 if (TC != ElementCount::getFixed(MaxTC))
2955 LLVM_DEBUG(dbgs() << "LV: Found maximum trip count: " << MaxTC << '\n');
2956 if (TC.isScalar()) {
2958 "Single iteration (non) loop",
2959 "loop trip count is one, irrelevant for vectorization",
2960 "SingleIterationLoop", ORE, TheLoop);
2962 }
2963
2964 // If BTC matches the widest induction type and is -1 then the trip count
2965 // computation will wrap to 0 and the vector trip count will be 0. Do not try
2966 // to vectorize.
2967 const SCEV *BTC = SE->getBackedgeTakenCount(TheLoop);
2968 if (!isa<SCEVCouldNotCompute>(BTC) &&
2969 BTC->getType()->getScalarSizeInBits() >=
2970 Legal->getWidestInductionType()->getScalarSizeInBits() &&
2972 SE->getMinusOne(BTC->getType()))) {
2974 "Trip count computation wrapped",
2975 "backedge-taken count is -1, loop trip count wrapped to 0",
2976 "TripCountWrapped", ORE, TheLoop);
2978 }
2979
2980 assert(WideningDecisions.empty() && Uniforms.empty() && Scalars.empty() &&
2981 "No cost-modeling decisions should have been taken at this point");
2982
2983 switch (EpilogueLoweringStatus) {
2984 case CM_EpilogueAllowed:
2985 return Config.computeFeasibleMaxVF(MaxTC, UserVF, UserIC, false,
2988 [[fallthrough]];
2990 LLVM_DEBUG(dbgs() << "LV: tail-folding hint/switch found.\n"
2991 << "LV: Not allowing epilogue, creating tail-folded "
2992 << "vector loop.\n");
2993 break;
2995 // fallthrough as a special case of OptForSize
2997 if (EpilogueLoweringStatus == CM_EpilogueNotAllowedOptSize)
2998 LLVM_DEBUG(dbgs() << "LV: Not allowing epilogue due to -Os/-Oz.\n");
2999 else
3000 LLVM_DEBUG(dbgs() << "LV: Not allowing epilogue due to low trip "
3001 << "count.\n");
3002
3003 // Bail if runtime checks are required, which are not good when optimising
3004 // for size.
3005 if (Config.runtimeChecksRequired())
3007
3008 break;
3009 }
3010
3011 // Now try the tail folding
3012
3013 // Invalidate interleave groups that require an epilogue if we can't mask
3014 // the interleave-group.
3016 // Note: There is no need to invalidate any cost modeling decisions here, as
3017 // none were taken so far (see assertion above).
3018 InterleaveInfo.invalidateGroupsRequiringScalarEpilogue();
3019 }
3020
3021 FixedScalableVFPair MaxFactors = Config.computeFeasibleMaxVF(
3022 MaxTC, UserVF, UserIC, true, requiresScalarEpilogue(true));
3023
3024 // Avoid tail folding if the trip count is known to be a multiple of any VF
3025 // we choose.
3026 std::optional<unsigned> MaxPowerOf2RuntimeVF =
3027 MaxFactors.FixedVF.getFixedValue();
3028 if (MaxFactors.ScalableVF) {
3029 std::optional<unsigned> MaxVScale = getMaxVScale(*TheFunction, TTI);
3030 if (MaxVScale) {
3031 MaxPowerOf2RuntimeVF = std::max<unsigned>(
3032 *MaxPowerOf2RuntimeVF,
3033 *MaxVScale * MaxFactors.ScalableVF.getKnownMinValue());
3034 } else
3035 MaxPowerOf2RuntimeVF = std::nullopt; // Stick with tail-folding for now.
3036 }
3037
3038 auto NoScalarEpilogueNeeded = [this, &UserIC](unsigned MaxVF) {
3039 // Return false if the loop is neither a single-latch-exit loop nor an
3040 // early-exit loop as tail-folding is not supported in that case.
3041 if (TheLoop->getExitingBlock() != TheLoop->getLoopLatch() &&
3042 !Legal->hasUncountableEarlyExit())
3043 return false;
3044 unsigned MaxVFtimesIC = UserIC ? MaxVF * UserIC : MaxVF;
3045 ScalarEvolution *SE = PSE.getSE();
3046 // Calling getSymbolicMaxBackedgeTakenCount enables support for loops
3047 // with uncountable exits. For countable loops, the symbolic maximum must
3048 // remain identical to the known back-edge taken count.
3049 const SCEV *BackedgeTakenCount = PSE.getSymbolicMaxBackedgeTakenCount();
3050 assert((Legal->hasUncountableEarlyExit() ||
3051 BackedgeTakenCount == PSE.getBackedgeTakenCount()) &&
3052 "Invalid loop count");
3053 const SCEV *ExitCount = SE->getAddExpr(
3054 BackedgeTakenCount, SE->getOne(BackedgeTakenCount->getType()));
3055 const SCEV *Rem = SE->getURemExpr(
3056 SE->applyLoopGuards(ExitCount, TheLoop),
3057 SE->getConstant(BackedgeTakenCount->getType(), MaxVFtimesIC));
3058 return Rem->isZero();
3059 };
3060
3061 if (MaxPowerOf2RuntimeVF > 0u) {
3062 assert((UserVF.isNonZero() || isPowerOf2_32(*MaxPowerOf2RuntimeVF)) &&
3063 "MaxFixedVF must be a power of 2");
3064 if (NoScalarEpilogueNeeded(*MaxPowerOf2RuntimeVF)) {
3065 // Accept MaxFixedVF if we do not have a tail.
3066 LLVM_DEBUG(dbgs() << "LV: No tail will remain for any chosen VF.\n");
3067 return MaxFactors;
3068 }
3069 }
3070
3071 auto ExpectedTC = getSmallBestKnownTC(PSE, TheLoop);
3072 if (ExpectedTC && ExpectedTC->isFixed() &&
3073 ExpectedTC->getFixedValue() <=
3074 TTI.getMinTripCountTailFoldingThreshold()) {
3075 if (MaxPowerOf2RuntimeVF > 0u) {
3076 // If we have a low-trip-count, and the fixed-width VF is known to divide
3077 // the trip count but the scalable factor does not, use the fixed-width
3078 // factor in preference to allow the generation of a non-predicated loop.
3079 if (EpilogueLoweringStatus == CM_EpilogueNotAllowedLowTripLoop &&
3080 NoScalarEpilogueNeeded(MaxFactors.FixedVF.getFixedValue())) {
3081 LLVM_DEBUG(dbgs() << "LV: Picking a fixed-width so that no tail will "
3082 "remain for any chosen VF.\n");
3083 MaxFactors.ScalableVF = ElementCount::getScalable(0);
3084 return MaxFactors;
3085 }
3086 }
3087
3089 "The trip count is below the minial threshold value.",
3090 "loop trip count is too low, avoiding vectorization", "LowTripCount",
3091 ORE, TheLoop);
3093 }
3094
3095 // If we don't know the precise trip count, or if the trip count that we
3096 // found modulo the vectorization factor is not zero, try to fold the tail
3097 // by masking.
3098 // FIXME: look for a smaller MaxVF that does divide TC rather than masking.
3099 bool ContainsScalableVF = MaxFactors.ScalableVF.isNonZero();
3100 setTailFoldingStyle(ContainsScalableVF, UserIC);
3101 if (foldTailByMasking()) {
3102 if (foldTailWithEVL()) {
3103 LLVM_DEBUG(
3104 dbgs()
3105 << "LV: tail is folded with EVL, forcing unroll factor to be 1. Will "
3106 "try to generate VP Intrinsics with scalable vector "
3107 "factors only.\n");
3108 // Tail folded loop using VP intrinsics restricts the VF to be scalable
3109 // for now.
3110 // TODO: extend it for fixed vectors, if required.
3111 assert(ContainsScalableVF && "Expected scalable vector factor.");
3112
3113 MaxFactors.FixedVF = ElementCount::getFixed(1);
3114 } else {
3116 }
3117 return MaxFactors;
3118 }
3119
3120 // If there was a tail-folding hint/switch, but we can't fold the tail by
3121 // masking, fallback to a vectorization with an epilogue.
3122 if (EpilogueLoweringStatus == CM_EpilogueNotNeededFoldTail) {
3123 LLVM_DEBUG(dbgs() << "LV: Cannot fold tail by masking: vectorize with an "
3124 "epilogue instead.\n");
3125 EpilogueLoweringStatus = CM_EpilogueAllowed;
3126 return MaxFactors;
3127 }
3128
3129 if (EpilogueLoweringStatus == CM_EpilogueNotAllowedFoldTail) {
3130 LLVM_DEBUG(dbgs() << "LV: Can't fold tail by masking: don't vectorize\n");
3132 }
3133
3134 if (TC.isZero()) {
3136 "unable to calculate the loop count due to complex control flow",
3137 "UnknownLoopCountComplexCFG", ORE, TheLoop);
3139 }
3140
3142 "Cannot optimize for size and vectorize at the same time.",
3143 "cannot optimize for size and vectorize at the same time. "
3144 "Enable vectorization of this loop with '#pragma clang loop "
3145 "vectorize(enable)' when compiling with -Os/-Oz",
3146 "NoTailLoopWithOptForSize", ORE, TheLoop);
3148}
3149
3152 using RecipeVFPair = std::pair<VPRecipeBase *, ElementCount>;
3153 SmallVector<RecipeVFPair> InvalidCosts;
3154 for (const auto &Plan : VPlans) {
3155 for (ElementCount VF : Plan->vectorFactors()) {
3156 // The VPlan-based cost model is designed for computing vector cost.
3157 // Querying VPlan-based cost model with a scarlar VF will cause some
3158 // errors because we expect the VF is vector for most of the widen
3159 // recipes.
3160 if (VF.isScalar())
3161 continue;
3162
3163 VPCostContext CostCtx(CM.TTI, *CM.TLI, *Plan, CM, Config.CostKind, CM.PSE,
3164 OrigLoop);
3165 precomputeCosts(*Plan, VF, CostCtx);
3166 auto Iter = vp_depth_first_deep(Plan->getVectorLoopRegion()->getEntry());
3168 for (auto &R : *VPBB) {
3169 if (!R.cost(VF, CostCtx).isValid())
3170 InvalidCosts.emplace_back(&R, VF);
3171 }
3172 }
3173 }
3174 }
3175 if (InvalidCosts.empty())
3176 return;
3177
3178 // Emit a report of VFs with invalid costs in the loop.
3179
3180 // Group the remarks per recipe, keeping the recipe order from InvalidCosts.
3182 unsigned I = 0;
3183 for (auto &Pair : InvalidCosts)
3184 if (Numbering.try_emplace(Pair.first, I).second)
3185 ++I;
3186
3187 // Sort the list, first on recipe(number) then on VF.
3188 sort(InvalidCosts, [&Numbering](RecipeVFPair &A, RecipeVFPair &B) {
3189 unsigned NA = Numbering[A.first];
3190 unsigned NB = Numbering[B.first];
3191 if (NA != NB)
3192 return NA < NB;
3193 return ElementCount::isKnownLT(A.second, B.second);
3194 });
3195
3196 // For a list of ordered recipe-VF pairs:
3197 // [(load, VF1), (load, VF2), (store, VF1)]
3198 // group the recipes together to emit separate remarks for:
3199 // load (VF1, VF2)
3200 // store (VF1)
3201 auto Tail = ArrayRef<RecipeVFPair>(InvalidCosts);
3202 auto Subset = ArrayRef<RecipeVFPair>();
3203 do {
3204 if (Subset.empty())
3205 Subset = Tail.take_front(1);
3206
3207 VPRecipeBase *R = Subset.front().first;
3208
3209 unsigned Opcode =
3211 .Case([](const VPHeaderPHIRecipe *R) { return Instruction::PHI; })
3212 .Case(
3213 [](const VPWidenStoreRecipe *R) { return Instruction::Store; })
3214 .Case([](const VPWidenLoadRecipe *R) { return Instruction::Load; })
3215 .Case<VPWidenCallRecipe, VPWidenIntrinsicRecipe>(
3216 [](const auto *R) { return Instruction::Call; })
3219 [](const auto *R) { return R->getOpcode(); })
3220 .Case([](const VPInterleaveRecipe *R) {
3221 return R->getStoredValues().empty() ? Instruction::Load
3222 : Instruction::Store;
3223 })
3224 .Case([](const VPReductionRecipe *R) {
3225 return RecurrenceDescriptor::getOpcode(R->getRecurrenceKind());
3226 });
3227
3228 // If the next recipe is different, or if there are no other pairs,
3229 // emit a remark for the collated subset. e.g.
3230 // [(load, VF1), (load, VF2))]
3231 // to emit:
3232 // remark: invalid costs for 'load' at VF=(VF1, VF2)
3233 if (Subset == Tail || Tail[Subset.size()].first != R) {
3234 std::string OutString;
3235 raw_string_ostream OS(OutString);
3236 assert(!Subset.empty() && "Unexpected empty range");
3237 OS << "Recipe with invalid costs prevented vectorization at VF=(";
3238 for (const auto &Pair : Subset)
3239 OS << (Pair.second == Subset.front().second ? "" : ", ") << Pair.second;
3240 OS << "):";
3241 if (Opcode == Instruction::Call) {
3242 StringRef Name = "";
3243 if (auto *Int = dyn_cast<VPWidenIntrinsicRecipe>(R)) {
3244 Name = Int->getIntrinsicName();
3245 } else {
3246 auto *WidenCall = dyn_cast<VPWidenCallRecipe>(R);
3247 Function *CalledFn =
3248 WidenCall ? WidenCall->getCalledScalarFunction()
3249 : cast<Function>(R->getOperand(R->getNumOperands() - 1)
3250 ->getLiveInIRValue());
3251 Name = CalledFn->getName();
3252 }
3253 OS << " call to " << Name;
3254 } else
3255 OS << " " << Instruction::getOpcodeName(Opcode);
3256 reportVectorizationInfo(OutString, "InvalidCost", ORE, OrigLoop, nullptr,
3257 R->getDebugLoc());
3258 Tail = Tail.drop_front(Subset.size());
3259 Subset = {};
3260 } else
3261 // Grow the subset by one element
3262 Subset = Tail.take_front(Subset.size() + 1);
3263 } while (!Tail.empty());
3264}
3265
3266/// Check if any recipe of \p Plan will generate a vector value, which will be
3267/// assigned a vector register.
3269 const TargetTransformInfo &TTI) {
3270 assert(VF.isVector() && "Checking a scalar VF?");
3271 DenseSet<VPRecipeBase *> EphemeralRecipes;
3272 collectEphemeralRecipesForVPlan(Plan, EphemeralRecipes);
3273 // Set of already visited types.
3274 DenseSet<Type *> Visited;
3277 for (VPRecipeBase &R : *VPBB) {
3278 if (EphemeralRecipes.contains(&R))
3279 continue;
3280 // Continue early if the recipe is considered to not produce a vector
3281 // result. Note that this includes VPInstruction where some opcodes may
3282 // produce a vector, to preserve existing behavior as VPInstructions model
3283 // aspects not directly mapped to existing IR instructions.
3284 switch (R.getVPRecipeID()) {
3285 case VPRecipeBase::VPDerivedIVSC:
3286 case VPRecipeBase::VPScalarIVStepsSC:
3287 case VPRecipeBase::VPReplicateSC:
3288 case VPRecipeBase::VPInstructionSC:
3289 case VPRecipeBase::VPCurrentIterationPHISC:
3290 case VPRecipeBase::VPVectorPointerSC:
3291 case VPRecipeBase::VPVectorEndPointerSC:
3292 case VPRecipeBase::VPExpandSCEVSC:
3293 case VPRecipeBase::VPPredInstPHISC:
3294 case VPRecipeBase::VPBranchOnMaskSC:
3295 continue;
3296 case VPRecipeBase::VPReductionSC:
3297 case VPRecipeBase::VPActiveLaneMaskPHISC:
3298 case VPRecipeBase::VPWidenCallSC:
3299 case VPRecipeBase::VPWidenCanonicalIVSC:
3300 case VPRecipeBase::VPWidenCastSC:
3301 case VPRecipeBase::VPWidenGEPSC:
3302 case VPRecipeBase::VPWidenIntrinsicSC:
3303 case VPRecipeBase::VPWidenMemIntrinsicSC:
3304 case VPRecipeBase::VPWidenSC:
3305 case VPRecipeBase::VPBlendSC:
3306 case VPRecipeBase::VPFirstOrderRecurrencePHISC:
3307 case VPRecipeBase::VPHistogramSC:
3308 case VPRecipeBase::VPWidenPHISC:
3309 case VPRecipeBase::VPWidenIntOrFpInductionSC:
3310 case VPRecipeBase::VPWidenPointerInductionSC:
3311 case VPRecipeBase::VPReductionPHISC:
3312 case VPRecipeBase::VPInterleaveEVLSC:
3313 case VPRecipeBase::VPInterleaveSC:
3314 case VPRecipeBase::VPWidenLoadEVLSC:
3315 case VPRecipeBase::VPWidenLoadSC:
3316 case VPRecipeBase::VPWidenStoreEVLSC:
3317 case VPRecipeBase::VPWidenStoreSC:
3318 break;
3319 default:
3320 llvm_unreachable("unhandled recipe");
3321 }
3322
3323 auto WillGenerateTargetVectors = [&TTI, VF](Type *VectorTy) {
3324 unsigned NumLegalParts = TTI.getNumberOfParts(VectorTy);
3325 if (!NumLegalParts)
3326 return false;
3327 if (VF.isScalable()) {
3328 // <vscale x 1 x iN> is assumed to be profitable over iN because
3329 // scalable registers are a distinct register class from scalar
3330 // ones. If we ever find a target which wants to lower scalable
3331 // vectors back to scalars, we'll need to update this code to
3332 // explicitly ask TTI about the register class uses for each part.
3333 return NumLegalParts <= VF.getKnownMinValue();
3334 }
3335 // Two or more elements that share a register - are vectorized.
3336 return NumLegalParts < VF.getFixedValue();
3337 };
3338
3339 // If no def nor is a store, e.g., branches, continue - no value to check.
3340 if (R.getNumDefinedValues() == 0 &&
3342 continue;
3343 // For multi-def recipes, currently only interleaved loads, suffice to
3344 // check first def only.
3345 // For stores check their stored value; for interleaved stores suffice
3346 // the check first stored value only. In all cases this is the second
3347 // operand.
3348 VPValue *ToCheck =
3349 R.getNumDefinedValues() >= 1 ? R.getVPValue(0) : R.getOperand(1);
3350 Type *ScalarTy = ToCheck->getScalarType();
3351 if (!Visited.insert({ScalarTy}).second)
3352 continue;
3353 Type *WideTy = toVectorizedTy(ScalarTy, VF);
3354 if (any_of(getContainedTypes(WideTy), WillGenerateTargetVectors))
3355 return true;
3356 }
3357 }
3358
3359 return false;
3360}
3361
3362static bool hasReplicatorRegion(VPlan &Plan) {
3364 Plan.getVectorLoopRegion()->getEntry())),
3365 [](auto *VPRB) { return VPRB->isReplicator(); });
3366}
3367
3368/// Returns true if the VPlan contains a VPReductionPHIRecipe with
3369/// FindLast recurrence kind.
3370static bool hasFindLastReductionPhi(VPlan &Plan) {
3372 [](VPRecipeBase &R) {
3373 auto *RedPhi = dyn_cast<VPReductionPHIRecipe>(&R);
3374 return RedPhi &&
3375 RecurrenceDescriptor::isFindLastRecurrenceKind(
3376 RedPhi->getRecurrenceKind());
3377 });
3378}
3379
3380/// Returns true if the VPlan contains header phi recipes that are not currently
3381/// supported for epilogue vectorization.
3383 return any_of(
3385 [](VPRecipeBase &R) {
3386 switch (R.getVPRecipeID()) {
3387 case VPRecipeBase::VPFirstOrderRecurrencePHISC:
3388 // TODO: Add support for fixed-order recurrences.
3389 return true;
3390 case VPRecipeBase::VPWidenIntOrFpInductionSC:
3391 return !cast<VPWidenIntOrFpInductionRecipe>(&R)->getPHINode();
3392 case VPRecipeBase::VPReductionPHISC: {
3393 auto *RedPhi = cast<VPReductionPHIRecipe>(&R);
3394 // TODO: Support FMinNum/FMaxNum, FindLast reductions, and reductions
3395 // without underlying values.
3396 RecurKind Kind = RedPhi->getRecurrenceKind();
3397 if (RecurrenceDescriptor::isFPMinMaxNumRecurrenceKind(Kind) ||
3398 RecurrenceDescriptor::isFindLastRecurrenceKind(Kind) ||
3399 !RedPhi->getUnderlyingValue())
3400 return true;
3401 // TODO: Add support for FindIV reductions with sunk expressions: the
3402 // resume value from the main loop is in expression domain (e.g.,
3403 // mul(ReducedIV, 3)), but the epilogue tracks raw IV values. A sunk
3404 // expression is identified by a non-VPInstruction user of
3405 // ComputeReductionResult.
3406 if (RecurrenceDescriptor::isFindIVRecurrenceKind(Kind)) {
3407 auto *RdxResult = vputils::findComputeReductionResult(RedPhi);
3408 assert(RdxResult &&
3409 "FindIV reduction must have ComputeReductionResult");
3410 return any_of(RdxResult->users(),
3411 std::not_fn(IsaPred<VPInstruction>));
3412 }
3413 return false;
3414 }
3415 default:
3416 return false;
3417 };
3418 });
3419}
3420
3421bool LoopVectorizationPlanner::isCandidateForEpilogueVectorization(
3422 VPlan &MainPlan) const {
3423 // Bail out if the plan contains header phi recipes not yet supported
3424 // for epilogue vectorization.
3425 if (hasUnsupportedHeaderPhiRecipe(MainPlan))
3426 return false;
3427
3428 // Epilogue vectorization code has not been auditted to ensure it handles
3429 // non-latch exits properly. It may be fine, but it needs auditted and
3430 // tested.
3431 // TODO: Add support for loops with an early exit.
3432 if (OrigLoop->getExitingBlock() != OrigLoop->getLoopLatch())
3433 return false;
3434
3435 return true;
3436}
3437
3439 const ElementCount VF, const unsigned IC) const {
3440 // FIXME: We need a much better cost-model to take different parameters such
3441 // as register pressure, code size increase and cost of extra branches into
3442 // account. For now we apply a very crude heuristic and only consider loops
3443 // with vectorization factors larger than a certain value.
3444
3445 // Allow the target to opt out.
3446 if (!TTI.preferEpilogueVectorization(VF * IC))
3447 return false;
3448
3449 unsigned MinVFThreshold = EpilogueVectorizationMinVF.getNumOccurrences() > 0
3451 : TTI.getEpilogueVectorizationMinVF();
3452 return estimateElementCount(VF * IC, Config.getVScaleForTuning()) >=
3453 MinVFThreshold;
3454}
3455
3457 VPlan &MainPlan, ElementCount MainLoopVF, unsigned IC) {
3459 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization is disabled.\n");
3460 return nullptr;
3461 }
3462
3463 if (!CM.isEpilogueAllowed()) {
3464 LLVM_DEBUG(dbgs() << "LEV: Unable to vectorize epilogue because no "
3465 "epilogue is allowed.\n");
3466 return nullptr;
3467 }
3468
3469 if (CM.maskPartialAliasing()) {
3470 LLVM_DEBUG(
3471 dbgs()
3472 << "LEV: Epilogue vectorization not supported with alias masking.\n");
3473 return nullptr;
3474 }
3475
3476 // Not really a cost consideration, but check for unsupported cases here to
3477 // simplify the logic.
3478 if (!isCandidateForEpilogueVectorization(MainPlan)) {
3479 LLVM_DEBUG(dbgs() << "LEV: Unable to vectorize epilogue because the loop "
3480 "is not a supported candidate.\n");
3481 return nullptr;
3482 }
3483
3484 if (hasForcedEpilogueVF()) {
3486 Config.getVScaleForTuning()) >=
3487 IC * estimateElementCount(MainLoopVF, Config.getVScaleForTuning())) {
3488 // Note that the main loop leaves IC * MainLoopVF iterations iff a scalar
3489 // epilogue is required, but then the epilogue loop also requires a scalar
3490 // epilogue.
3491 LLVM_DEBUG(dbgs() << "LEV: Forced epilogue VF results in dead epilogue "
3492 "vector loop, skipping vectorizing epilogue.\n");
3493 return nullptr;
3494 }
3495
3496 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization factor is forced.\n");
3498 std::unique_ptr<VPlan> Clone(
3500 Clone->setVF(EpilogueVectorizationForceVF);
3501 return Clone;
3502 }
3503
3504 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization forced factor is not "
3505 "viable.\n");
3506 return nullptr;
3507 }
3508
3509 if (OrigLoop->getHeader()->getParent()->hasOptSize()) {
3510 LLVM_DEBUG(
3511 dbgs() << "LEV: Epilogue vectorization skipped due to opt for size.\n");
3512 return nullptr;
3513 }
3514
3515 if (!CM.isEpilogueVectorizationProfitable(MainLoopVF, IC)) {
3516 LLVM_DEBUG(dbgs() << "LEV: Epilogue vectorization is not profitable for "
3517 "this loop\n");
3518 return nullptr;
3519 }
3520
3521 // Check if a plan's vector loop processes fewer iterations than VF (e.g. when
3522 // interleave groups have been narrowed) narrowInterleaveGroups) and return
3523 // the adjusted, effective VF.
3524 using namespace VPlanPatternMatch;
3525 auto GetEffectiveVF = [](VPlan &Plan, ElementCount VF) -> ElementCount {
3526 auto *Exiting = Plan.getVectorLoopRegion()->getExitingBasicBlock();
3527 if (match(&Exiting->back(),
3528 m_BranchOnCount(m_Add(m_CanonicalIV(), m_Specific(&Plan.getUF())),
3529 m_VPValue())))
3530 return ElementCount::get(1, VF.isScalable());
3531 return VF;
3532 };
3533
3534 // Check if the main loop processes fewer than MainLoopVF elements per
3535 // iteration (e.g. due to narrowing interleave groups). Adjust MainLoopVF
3536 // as needed.
3537 MainLoopVF = GetEffectiveVF(MainPlan, MainLoopVF);
3538
3539 // If MainLoopVF = vscale x 2, and vscale is expected to be 4, then we know
3540 // the main loop handles 8 lanes per iteration. We could still benefit from
3541 // vectorizing the epilogue loop with VF=4.
3542 ElementCount EstimatedRuntimeVF = ElementCount::getFixed(
3543 estimateElementCount(MainLoopVF, Config.getVScaleForTuning()));
3544
3545 Type *TCType = Legal->getWidestInductionType();
3546 const SCEV *RemainingIterations = nullptr;
3547 unsigned MaxTripCount = 0;
3548 const SCEV *TC = vputils::getSCEVExprForVPValue(MainPlan.getTripCount(), PSE);
3549 assert(!isa<SCEVCouldNotCompute>(TC) && "Trip count SCEV must be computable");
3550 const SCEV *KnownMinTC;
3551 bool ScalableTC = match(TC, m_scev_c_Mul(m_SCEV(KnownMinTC), m_SCEVVScale()));
3552 bool ScalableRemIter = false;
3553 ScalarEvolution &SE = *PSE.getSE();
3554 // Use versions of TC and VF in which both are either scalable or fixed.
3555 if (ScalableTC == MainLoopVF.isScalable()) {
3556 ScalableRemIter = ScalableTC;
3557 RemainingIterations =
3558 SE.getURemExpr(TC, SE.getElementCount(TCType, MainLoopVF * IC));
3559 } else if (ScalableTC) {
3560 const SCEV *EstimatedTC = SE.getMulExpr(
3561 KnownMinTC,
3562 SE.getConstant(TCType, Config.getVScaleForTuning().value_or(1)));
3563 RemainingIterations = SE.getURemExpr(
3564 EstimatedTC, SE.getElementCount(TCType, MainLoopVF * IC));
3565 } else
3566 RemainingIterations =
3567 SE.getURemExpr(TC, SE.getElementCount(TCType, EstimatedRuntimeVF * IC));
3568
3569 // No iterations left to process in the epilogue.
3570 if (RemainingIterations->isZero())
3571 return nullptr;
3572
3573 if (MainLoopVF.isFixed()) {
3574 MaxTripCount = MainLoopVF.getFixedValue() * IC - 1;
3575 if (SE.isKnownPredicate(CmpInst::ICMP_ULT, RemainingIterations,
3576 SE.getConstant(TCType, MaxTripCount))) {
3577 MaxTripCount = SE.getUnsignedRangeMax(RemainingIterations).getZExtValue();
3578 }
3579 LLVM_DEBUG(dbgs() << "LEV: Maximum Trip Count for Epilogue: "
3580 << MaxTripCount << "\n");
3581 }
3582
3583 auto SkipVF = [&](const SCEV *VF, const SCEV *RemIter) -> bool {
3584 return SE.isKnownPredicate(CmpInst::ICMP_UGT, VF, RemIter);
3585 };
3587 VPlan *BestPlan = nullptr;
3588 for (auto &NextVF : ProfitableVFs) {
3589 // Skip candidate VFs without a corresponding VPlan.
3590 if (!hasPlanWithVF(NextVF.Width))
3591 continue;
3592
3593 VPlan &CurrentPlan = getPlanFor(NextVF.Width);
3594 ElementCount EffectiveVF = GetEffectiveVF(CurrentPlan, NextVF.Width);
3595 // Skip fixed vector VFs > than the estimated runtime VF, or any VF > than
3596 // the VF of the main loop.
3597 if ((!EffectiveVF.isScalable() && MainLoopVF.isScalable() &&
3598 ElementCount::isKnownGT(EffectiveVF, EstimatedRuntimeVF)) ||
3599 ElementCount::isKnownGT(EffectiveVF, MainLoopVF))
3600 continue;
3601
3602 // If EffectiveVF is greater than the number of remaining iterations, the
3603 // epilogue loop would be dead. Skip such factors. If the epilogue plan
3604 // also has narrowed interleave groups, use the effective VF since
3605 // the epilogue step will be reduced to its IC.
3606 // TODO: We should also consider comparing against a scalable
3607 // RemainingIterations when SCEV be able to evaluate non-canonical
3608 // vscale-based expressions.
3609 if (!ScalableRemIter) {
3610 // Handle the case where EffectiveVF and RemainingIterations are in
3611 // different numerical spaces.
3612 if (EffectiveVF.isScalable())
3613 EffectiveVF = ElementCount::getFixed(
3614 estimateElementCount(EffectiveVF, Config.getVScaleForTuning()));
3615 if (SkipVF(SE.getElementCount(TCType, EffectiveVF), RemainingIterations))
3616 continue;
3617 }
3618
3619 if (Result.Width.isScalar() ||
3620 isMoreProfitable(NextVF, Result, MaxTripCount, !hasTailFolded(MainPlan),
3621 /*IsEpilogue*/ true)) {
3622 Result = NextVF;
3623 BestPlan = &CurrentPlan;
3624 }
3625 }
3626
3627 if (!BestPlan)
3628 return nullptr;
3629
3630 LLVM_DEBUG(dbgs() << "LEV: Vectorizing epilogue loop with VF = "
3631 << Result.Width << "\n");
3632 std::unique_ptr<VPlan> Clone(BestPlan->duplicate());
3633 Clone->setVF(Result.Width);
3634 return Clone;
3635}
3636
3637unsigned
3639 InstructionCost LoopCost) {
3640 // -- The interleave heuristics --
3641 // We interleave the loop in order to expose ILP and reduce the loop overhead.
3642 // There are many micro-architectural considerations that we can't predict
3643 // at this level. For example, frontend pressure (on decode or fetch) due to
3644 // code size, or the number and capabilities of the execution ports.
3645 //
3646 // We use the following heuristics to select the interleave count:
3647 // 1. If the code has reductions, then we interleave to break the cross
3648 // iteration dependency.
3649 // 2. If the loop is really small, then we interleave to reduce the loop
3650 // overhead.
3651 // 3. We don't interleave if we think that we will spill registers to memory
3652 // due to the increased register pressure.
3653
3654 // Only interleave tail-folded loops if wide lane masks are requested, as the
3655 // overhead of multiple instructions to calculate the predicate is likely
3656 // not beneficial. If an epilogue is not allowed for any other reason,
3657 // do not interleave.
3658 if (!CM.isEpilogueAllowed() &&
3659 !(CM.preferTailFoldedLoop() && CM.useWideActiveLaneMask()))
3660 return 1;
3661
3664 LLVM_DEBUG(dbgs() << "LV: Loop requires variable-length step. "
3665 "Unroll factor forced to be 1.\n");
3666 return 1;
3667 }
3668
3669 // We used the distance for the interleave count.
3670 if (!Legal->isSafeForAnyVectorWidth())
3671 return 1;
3672
3673 // We don't attempt to perform interleaving for loops with uncountable early
3674 // exits because the VPInstruction::AnyOf code cannot currently handle
3675 // multiple parts.
3676 if (Plan.hasEarlyExit())
3677 return 1;
3678
3679 const bool HasReductions =
3682
3683 // FIXME: implement interleaving for FindLast transform correctly.
3684 if (hasFindLastReductionPhi(Plan))
3685 return 1;
3686
3687 VPRegisterUsage R =
3688 calculateRegisterUsageForPlan(Plan, {VF}, TTI, CM.ValuesToIgnore)[0];
3689
3690 // If we did not calculate the cost for VF (because the user selected the VF)
3691 // then we calculate the cost of VF here.
3692 if (LoopCost == 0) {
3693 if (VF.isScalar())
3694 LoopCost = CM.expectedCost(VF);
3695 else
3696 LoopCost = cost(Plan, VF, &R);
3697 assert(LoopCost.isValid() && "Expected to have chosen a VF with valid cost");
3698
3699 // Loop body is free and there is no need for interleaving.
3700 if (LoopCost == 0)
3701 return 1;
3702 }
3703
3704 // We divide by these constants so assume that we have at least one
3705 // instruction that uses at least one register.
3706 for (auto &Pair : R.MaxLocalUsers) {
3707 Pair.second = std::max(Pair.second, 1U);
3708 }
3709
3710 // We calculate the interleave count using the following formula.
3711 // Subtract the number of loop invariants from the number of available
3712 // registers. These registers are used by all of the interleaved instances.
3713 // Next, divide the remaining registers by the number of registers that is
3714 // required by the loop, in order to estimate how many parallel instances
3715 // fit without causing spills. All of this is rounded down if necessary to be
3716 // a power of two. We want power of two interleave count to simplify any
3717 // addressing operations or alignment considerations.
3718 // We also want power of two interleave counts to ensure that the induction
3719 // variable of the vector loop wraps to zero, when tail is folded by masking;
3720 // this currently happens when OptForSize, in which case IC is set to 1 above.
3721 unsigned IC = UINT_MAX;
3722
3723 for (const auto &Pair : R.MaxLocalUsers) {
3724 unsigned TargetNumRegisters = TTI.getNumberOfRegisters(Pair.first);
3725 LLVM_DEBUG(dbgs() << "LV: The target has " << TargetNumRegisters
3726 << " registers of "
3727 << TTI.getRegisterClassName(Pair.first)
3728 << " register class\n");
3729 if (VF.isScalar()) {
3730 if (ForceTargetNumScalarRegs.getNumOccurrences() > 0)
3731 TargetNumRegisters = ForceTargetNumScalarRegs;
3732 } else {
3733 if (ForceTargetNumVectorRegs.getNumOccurrences() > 0)
3734 TargetNumRegisters = ForceTargetNumVectorRegs;
3735 }
3736 unsigned MaxLocalUsers = Pair.second;
3737 unsigned LoopInvariantRegs = 0;
3738 if (R.LoopInvariantRegs.contains(Pair.first))
3739 LoopInvariantRegs = R.LoopInvariantRegs[Pair.first];
3740
3741 unsigned TmpIC = llvm::bit_floor((TargetNumRegisters - LoopInvariantRegs) /
3742 MaxLocalUsers);
3743 // Don't count the induction variable as interleaved.
3745 TmpIC = llvm::bit_floor((TargetNumRegisters - LoopInvariantRegs - 1) /
3746 std::max(1U, (MaxLocalUsers - 1)));
3747 }
3748
3749 IC = std::min(IC, TmpIC);
3750 }
3751
3752 // Clamp the interleave ranges to reasonable counts.
3753 bool HasUnorderedReductions =
3754 HasReductions &&
3756 [](VPRecipeBase &R) {
3757 auto *RedR = dyn_cast<VPReductionPHIRecipe>(&R);
3758 return RedR && RedR->isOrdered();
3759 });
3760 unsigned MaxInterleaveCount =
3761 TTI.getMaxInterleaveFactor(VF, HasUnorderedReductions);
3762 LLVM_DEBUG(dbgs() << "LV: MaxInterleaveFactor for the target is "
3763 << MaxInterleaveCount << "\n");
3764
3765 // Check if the user has overridden the max.
3766 if (VF.isScalar()) {
3767 if (ForceTargetMaxScalarInterleaveFactor.getNumOccurrences() > 0)
3768 MaxInterleaveCount = ForceTargetMaxScalarInterleaveFactor;
3769 } else {
3770 if (ForceTargetMaxVectorInterleaveFactor.getNumOccurrences() > 0)
3771 MaxInterleaveCount = ForceTargetMaxVectorInterleaveFactor;
3772 }
3773
3774 // Try to get the exact trip count, or an estimate based on profiling data or
3775 // ConstantMax from PSE, failing that.
3776 auto BestKnownTC =
3777 getSmallBestKnownTC(PSE, OrigLoop,
3778 /*CanUseConstantMax=*/true,
3779 /*CanExcludeZeroTrips=*/CM.isEpilogueAllowed());
3780
3781 // For fixed length VFs treat a scalable trip count as unknown.
3782 if (BestKnownTC && (BestKnownTC->isFixed() || VF.isScalable())) {
3783 // Re-evaluate trip counts and VFs to be in the same numerical space.
3784 unsigned AvailableTC =
3785 estimateElementCount(*BestKnownTC, Config.getVScaleForTuning());
3786 unsigned EstimatedVF =
3787 estimateElementCount(VF, Config.getVScaleForTuning());
3788
3789 // At least one iteration must be scalar when this constraint holds. So the
3790 // maximum available iterations for interleaving is one less.
3791 if (requiresScalarEpilogue(Plan, VF))
3792 --AvailableTC;
3793
3794 unsigned InterleaveCountLB = bit_floor(std::max(
3795 1u, std::min(AvailableTC / (EstimatedVF * 2), MaxInterleaveCount)));
3796
3797 if (getSmallConstantTripCount(PSE.getSE(), OrigLoop).isNonZero()) {
3798 // If the best known trip count is exact, we select between two
3799 // prospective ICs, where
3800 //
3801 // 1) the aggressive IC is capped by the trip count divided by VF
3802 // 2) the conservative IC is capped by the trip count divided by (VF * 2)
3803 //
3804 // The final IC is selected in a way that the epilogue loop trip count is
3805 // minimized while maximizing the IC itself, so that we either run the
3806 // vector loop at least once if it generates a small epilogue loop, or
3807 // else we run the vector loop at least twice.
3808
3809 unsigned InterleaveCountUB = bit_floor(std::max(
3810 1u, std::min(AvailableTC / EstimatedVF, MaxInterleaveCount)));
3811 MaxInterleaveCount = InterleaveCountLB;
3812
3813 if (InterleaveCountUB != InterleaveCountLB) {
3814 unsigned TailTripCountUB =
3815 (AvailableTC % (EstimatedVF * InterleaveCountUB));
3816 unsigned TailTripCountLB =
3817 (AvailableTC % (EstimatedVF * InterleaveCountLB));
3818 // If both produce same scalar tail, maximize the IC to do the same work
3819 // in fewer vector loop iterations
3820 if (TailTripCountUB == TailTripCountLB)
3821 MaxInterleaveCount = InterleaveCountUB;
3822 }
3823 } else {
3824 // If trip count is an estimated compile time constant, limit the
3825 // IC to be capped by the trip count divided by VF * 2, such that the
3826 // vector loop runs at least twice to make interleaving seem profitable
3827 // when there is an epilogue loop present. Since exact Trip count is not
3828 // known we choose to be conservative in our IC estimate.
3829 MaxInterleaveCount = InterleaveCountLB;
3830 }
3831 }
3832
3833 assert(MaxInterleaveCount > 0 &&
3834 "Maximum interleave count must be greater than 0");
3835
3836 // Clamp the calculated IC to be between the 1 and the max interleave count
3837 // that the target and trip count allows.
3838 if (IC > MaxInterleaveCount)
3839 IC = MaxInterleaveCount;
3840 else
3841 // Make sure IC is greater than 0.
3842 IC = std::max(1u, IC);
3843
3844 assert(IC > 0 && "Interleave count must be greater than 0.");
3845
3846 // Interleave if we vectorized this loop and there is a reduction that could
3847 // benefit from interleaving.
3848 if (VF.isVector() && HasReductions) {
3849 LLVM_DEBUG(dbgs() << "LV: Interleaving because of reductions.\n");
3850 return IC;
3851 }
3852
3853 // For any scalar loop that either requires runtime checks or tail-folding we
3854 // are better off leaving this to the unroller. Note that if we've already
3855 // vectorized the loop we will have done the runtime check and so interleaving
3856 // won't require further checks.
3857 bool ScalarInterleavingRequiresPredication =
3858 (VF.isScalar() && any_of(OrigLoop->blocks(), [this](BasicBlock *BB) {
3859 return Legal->blockNeedsPredication(BB);
3860 }));
3861 bool ScalarInterleavingRequiresRuntimePointerCheck =
3862 (VF.isScalar() && Legal->getRuntimePointerChecking()->Need);
3863
3864 // We want to interleave small loops in order to reduce the loop overhead and
3865 // potentially expose ILP opportunities.
3866 LLVM_DEBUG(dbgs() << "LV: Loop cost is " << LoopCost << '\n'
3867 << "LV: IC is " << IC << '\n'
3868 << "LV: VF is " << VF << '\n');
3869 const bool AggressivelyInterleave =
3870 TTI.enableAggressiveInterleaving(HasReductions);
3871 if (!ScalarInterleavingRequiresRuntimePointerCheck &&
3872 !ScalarInterleavingRequiresPredication && LoopCost < SmallLoopCost) {
3873 // We assume that the cost overhead is 1 and we use the cost model
3874 // to estimate the cost of the loop and interleave until the cost of the
3875 // loop overhead is about 5% of the cost of the loop.
3876 unsigned SmallIC = std::min(IC, (unsigned)llvm::bit_floor<uint64_t>(
3877 SmallLoopCost / LoopCost.getValue()));
3878
3879 // Interleave until store/load ports (estimated by max interleave count) are
3880 // saturated.
3881 unsigned NumStores = 0;
3882 unsigned NumLoads = 0;
3885 for (VPRecipeBase &R : *VPBB) {
3887 NumLoads++;
3888 continue;
3889 }
3891 NumStores++;
3892 continue;
3893 }
3894
3895 if (auto *InterleaveR = dyn_cast<VPInterleaveRecipe>(&R)) {
3896 if (unsigned StoreOps = InterleaveR->getNumStoreOperands())
3897 NumStores += StoreOps;
3898 else
3899 NumLoads += InterleaveR->getNumDefinedValues();
3900 continue;
3901 }
3902 if (auto *RepR = dyn_cast<VPReplicateRecipe>(&R)) {
3903 NumLoads += isa<LoadInst>(RepR->getUnderlyingInstr());
3904 NumStores += isa<StoreInst>(RepR->getUnderlyingInstr());
3905 continue;
3906 }
3907 if (isa<VPHistogramRecipe>(&R)) {
3908 NumLoads++;
3909 NumStores++;
3910 continue;
3911 }
3912 }
3913 }
3914 unsigned StoresIC = IC / (NumStores ? NumStores : 1);
3915 unsigned LoadsIC = IC / (NumLoads ? NumLoads : 1);
3916
3917 // There is little point in interleaving for reductions containing selects
3918 // and compares when VF=1 since it may just create more overhead than it's
3919 // worth for loops with small trip counts. This is because we still have to
3920 // do the final reduction after the loop.
3921 bool HasSelectCmpReductions =
3922 HasReductions &&
3924 [](VPRecipeBase &R) {
3925 auto *RedR = dyn_cast<VPReductionPHIRecipe>(&R);
3926 return RedR && (RecurrenceDescriptor::isAnyOfRecurrenceKind(
3927 RedR->getRecurrenceKind()) ||
3928 RecurrenceDescriptor::isFindIVRecurrenceKind(
3929 RedR->getRecurrenceKind()));
3930 });
3931 if (HasSelectCmpReductions) {
3932 LLVM_DEBUG(dbgs() << "LV: Not interleaving select-cmp reductions.\n");
3933 return 1;
3934 }
3935
3936 // If we have a scalar reduction (vector reductions are already dealt with
3937 // by this point), we can increase the critical path length if the loop
3938 // we're interleaving is inside another loop. For tree-wise reductions
3939 // set the limit to 2, and for ordered reductions it's best to disable
3940 // interleaving entirely.
3941 if (HasReductions && OrigLoop->getLoopDepth() > 1) {
3942 bool HasOrderedReductions =
3944 [](VPRecipeBase &R) {
3945 auto *RedR = dyn_cast<VPReductionPHIRecipe>(&R);
3946
3947 return RedR && RedR->isOrdered();
3948 });
3949 if (HasOrderedReductions) {
3950 LLVM_DEBUG(
3951 dbgs() << "LV: Not interleaving scalar ordered reductions.\n");
3952 return 1;
3953 }
3954
3955 unsigned F = MaxNestedScalarReductionIC;
3956 SmallIC = std::min(SmallIC, F);
3957 StoresIC = std::min(StoresIC, F);
3958 LoadsIC = std::min(LoadsIC, F);
3959 }
3960
3962 std::max(StoresIC, LoadsIC) > SmallIC) {
3963 LLVM_DEBUG(
3964 dbgs() << "LV: Interleaving to saturate store or load ports.\n");
3965 return std::max(StoresIC, LoadsIC);
3966 }
3967
3968 // If there are scalar reductions and TTI has enabled aggressive
3969 // interleaving for reductions, we will interleave to expose ILP.
3970 if (VF.isScalar() && AggressivelyInterleave) {
3971 LLVM_DEBUG(dbgs() << "LV: Interleaving to expose ILP.\n");
3972 // Interleave no less than SmallIC but not as aggressive as the normal IC
3973 // to satisfy the rare situation when resources are too limited.
3974 return std::max(IC / 2, SmallIC);
3975 }
3976
3977 LLVM_DEBUG(dbgs() << "LV: Interleaving to reduce branch cost.\n");
3978 return SmallIC;
3979 }
3980
3981 // Interleave if this is a large loop (small loops are already dealt with by
3982 // this point) that could benefit from interleaving.
3983 if (AggressivelyInterleave) {
3984 LLVM_DEBUG(dbgs() << "LV: Interleaving to expose ILP.\n");
3985 return IC;
3986 }
3987
3988 LLVM_DEBUG(dbgs() << "LV: Not Interleaving.\n");
3989 return 1;
3990}
3991
3993 ElementCount VF) {
3994 // TODO: Cost model for emulated masked load/store is completely
3995 // broken. This hack guides the cost model to use an artificially
3996 // high enough value to practically disable vectorization with such
3997 // operations, except where previously deployed legality hack allowed
3998 // using very low cost values. This is to avoid regressions coming simply
3999 // from moving "masked load/store" check from legality to cost model.
4000 // Masked Load/Gather emulation was previously never allowed.
4001 // Limited number of Masked Store/Scatter emulation was allowed.
4003 "Expecting a scalar emulated instruction");
4004 return isa<LoadInst>(I) ||
4005 (isa<StoreInst>(I) &&
4006 NumPredStores > NumberOfStoresToPredicate);
4007}
4008
4010 assert(VF.isVector() && "Expected VF >= 2");
4011
4012 // If we've already collected the instructions to scalarize or the predicated
4013 // BBs after vectorization, there's nothing to do. Collection may already have
4014 // occurred if we have a user-selected VF and are now computing the expected
4015 // cost for interleaving.
4016 if (InstsToScalarize.contains(VF) ||
4017 PredicatedBBsAfterVectorization.contains(VF))
4018 return;
4019
4020 // Initialize a mapping for VF in InstsToScalalarize. If we find that it's
4021 // not profitable to scalarize any instructions, the presence of VF in the
4022 // map will indicate that we've analyzed it already.
4023 ScalarCostsTy &ScalarCostsVF = InstsToScalarize[VF];
4024
4025 // Find all the instructions that are scalar with predication in the loop and
4026 // determine if it would be better to not if-convert the blocks they are in.
4027 // If so, we also record the instructions to scalarize.
4028 for (BasicBlock *BB : TheLoop->blocks()) {
4030 continue;
4031 for (Instruction &I : *BB)
4032 if (isScalarWithPredication(&I, VF)) {
4033 ScalarCostsTy ScalarCosts;
4034 // Do not apply discount logic for:
4035 // 1. Scalars after vectorization, as there will only be a single copy
4036 // of the instruction.
4037 // 2. Scalable VF, as that would lead to invalid scalarization costs.
4038 // 3. Emulated masked memrefs, if a hacked cost is needed.
4039 if (!isScalarAfterVectorization(&I, VF) && !VF.isScalable() &&
4041 computePredInstDiscount(&I, ScalarCosts, VF) >= 0) {
4042 for (const auto &[I, IC] : ScalarCosts)
4043 ScalarCostsVF.insert({I, IC});
4044 }
4045 // Remember that BB will remain after vectorization.
4046 PredicatedBBsAfterVectorization[VF].insert(BB);
4047 for (auto *Pred : predecessors(BB)) {
4048 if (Pred->getSingleSuccessor() == BB)
4049 PredicatedBBsAfterVectorization[VF].insert(Pred);
4050 }
4051 }
4052 }
4053}
4054
4055InstructionCost LoopVectorizationCostModel::computePredInstDiscount(
4056 Instruction *PredInst, ScalarCostsTy &ScalarCosts, ElementCount VF) {
4057 assert(!isUniformAfterVectorization(PredInst, VF) &&
4058 "Instruction marked uniform-after-vectorization will be predicated");
4059
4060 // Initialize the discount to zero, meaning that the scalar version and the
4061 // vector version cost the same.
4062 InstructionCost Discount = 0;
4063
4064 // Holds instructions to analyze. The instructions we visit are mapped in
4065 // ScalarCosts. Those instructions are the ones that would be scalarized if
4066 // we find that the scalar version costs less.
4068
4069 // Returns true if the given instruction can be scalarized.
4070 auto CanBeScalarized = [&](Instruction *I) -> bool {
4071 // We only attempt to scalarize instructions forming a single-use chain
4072 // from the original predicated block that would otherwise be vectorized.
4073 // Although not strictly necessary, we give up on instructions we know will
4074 // already be scalar to avoid traversing chains that are unlikely to be
4075 // beneficial.
4076 if (!I->hasOneUse() || PredInst->getParent() != I->getParent() ||
4078 return false;
4079
4080 // If the instruction is scalar with predication, it will be analyzed
4081 // separately. We ignore it within the context of PredInst.
4082 if (isScalarWithPredication(I, VF))
4083 return false;
4084
4085 // If any of the instruction's operands are uniform after vectorization,
4086 // the instruction cannot be scalarized. This prevents, for example, a
4087 // masked load from being scalarized.
4088 //
4089 // We assume we will only emit a value for lane zero of an instruction
4090 // marked uniform after vectorization, rather than VF identical values.
4091 // Thus, if we scalarize an instruction that uses a uniform, we would
4092 // create uses of values corresponding to the lanes we aren't emitting code
4093 // for. This behavior can be changed by allowing getScalarValue to clone
4094 // the lane zero values for uniforms rather than asserting.
4095 for (Use &U : I->operands())
4096 if (auto *J = dyn_cast<Instruction>(U.get()))
4097 if (isUniformAfterVectorization(J, VF))
4098 return false;
4099
4100 // Otherwise, we can scalarize the instruction.
4101 return true;
4102 };
4103
4104 // Compute the expected cost discount from scalarizing the entire expression
4105 // feeding the predicated instruction. We currently only consider expressions
4106 // that are single-use instruction chains.
4107 Worklist.push_back(PredInst);
4108 while (!Worklist.empty()) {
4109 Instruction *I = Worklist.pop_back_val();
4110
4111 // If we've already analyzed the instruction, there's nothing to do.
4112 if (ScalarCosts.contains(I))
4113 continue;
4114
4115 // Cannot scalarize fixed-order recurrence phis at the moment.
4116 if (isa<PHINode>(I) && Legal->isFixedOrderRecurrence(cast<PHINode>(I)))
4117 continue;
4118
4119 // Compute the cost of the vector instruction. Note that this cost already
4120 // includes the scalarization overhead of the predicated instruction.
4121 InstructionCost VectorCost = getInstructionCost(I, VF);
4122
4123 // Compute the cost of the scalarized instruction. This cost is the cost of
4124 // the instruction as if it wasn't if-converted and instead remained in the
4125 // predicated block. We will scale this cost by block probability after
4126 // computing the scalarization overhead.
4127 InstructionCost ScalarCost =
4129
4130 // Compute the scalarization overhead of needed insertelement instructions
4131 // and phi nodes.
4132 if (isScalarWithPredication(I, VF) && !I->getType()->isVoidTy()) {
4133 Type *WideTy = toVectorizedTy(I->getType(), VF);
4134 for (Type *VectorTy : getContainedTypes(WideTy)) {
4135 ScalarCost += TTI.getScalarizationOverhead(
4137 /*Insert=*/true,
4138 /*Extract=*/false, Config.CostKind);
4139 }
4140 ScalarCost += VF.getFixedValue() *
4141 TTI.getCFInstrCost(Instruction::PHI, Config.CostKind);
4142 }
4143
4144 // Compute the scalarization overhead of needed extractelement
4145 // instructions. For each of the instruction's operands, if the operand can
4146 // be scalarized, add it to the worklist; otherwise, account for the
4147 // overhead.
4148 for (Use &U : I->operands())
4149 if (auto *J = dyn_cast<Instruction>(U.get())) {
4150 assert(canVectorizeTy(J->getType()) &&
4151 "Instruction has non-scalar type");
4152 if (CanBeScalarized(J))
4153 Worklist.push_back(J);
4154 else if (needsExtract(J, VF)) {
4155 Type *WideTy = toVectorizedTy(J->getType(), VF);
4156 for (Type *VectorTy : getContainedTypes(WideTy)) {
4157 ScalarCost += TTI.getScalarizationOverhead(
4158 cast<VectorType>(VectorTy),
4159 APInt::getAllOnes(VF.getFixedValue()), /*Insert*/ false,
4160 /*Extract*/ true, Config.CostKind);
4161 }
4162 }
4163 }
4164
4165 // Scale the total scalar cost by block probability.
4166 ScalarCost /= getPredBlockCostDivisor(Config.CostKind, I->getParent());
4167
4168 // Compute the discount. A non-negative discount means the vector version
4169 // of the instruction costs more, and scalarizing would be beneficial.
4170 Discount += VectorCost - ScalarCost;
4171 ScalarCosts[I] = ScalarCost;
4172 }
4173
4174 return Discount;
4175}
4176
4179 assert(VF.isScalar() && "must only be called for scalar VFs");
4180
4181 // For each block.
4182 for (BasicBlock *BB : TheLoop->blocks()) {
4183 InstructionCost BlockCost;
4184
4185 // For each instruction in the old loop.
4186 for (Instruction &I : *BB) {
4187 // Skip ignored values.
4188 if (ValuesToIgnore.count(&I) ||
4189 (VF.isVector() && VecValuesToIgnore.count(&I)))
4190 continue;
4191
4193
4194 // Check if we should override the cost.
4195 if (C.isValid() && ForceTargetInstructionCost.getNumOccurrences() > 0)
4197
4198 BlockCost += C;
4199 LLVM_DEBUG(dbgs() << "LV: Found an estimated cost of " << C << " for VF "
4200 << VF << " For instruction: " << I << '\n');
4201 }
4202
4203 // In the scalar loop, we may not always execute the predicated block, if it
4204 // is an if-else block. Thus, scale the block's cost by the probability of
4205 // executing it. getPredBlockCostDivisor will return 1 for blocks that are
4206 // only predicated by the header mask when folding the tail.
4207 Cost += BlockCost / getPredBlockCostDivisor(Config.CostKind, BB);
4208 }
4209
4210 return Cost;
4211}
4212
4213/// Gets the address access SCEV for Ptr, if it should be used for cost modeling
4214/// according to isAddressSCEVForCost.
4215///
4216/// This SCEV can be sent to the Target in order to estimate the address
4217/// calculation cost.
4219 Value *Ptr,
4221 const Loop *TheLoop) {
4222 const SCEV *Addr = PSE.getSCEV(Ptr);
4223 return vputils::isAddressSCEVForCost(Addr, *PSE.getSE(), TheLoop) ? Addr
4224 : nullptr;
4225}
4226
4228LoopVectorizationCostModel::getMemInstScalarizationCost(Instruction *I,
4229 ElementCount VF) {
4230 assert(VF.isVector() &&
4231 "Scalarization cost of instruction implies vectorization.");
4232 if (VF.isScalable())
4234
4235 Type *ValTy = getLoadStoreType(I);
4236 auto *SE = PSE.getSE();
4237
4238 unsigned AS = getLoadStoreAddressSpace(I);
4240 Type *PtrTy = toVectorTy(Ptr->getType(), VF);
4241 // NOTE: PtrTy is a vector to signal `TTI::getAddressComputationCost`
4242 // that it is being called from this specific place.
4243
4244 // Figure out whether the access is strided and get the stride value
4245 // if it's known in compile time
4246 const SCEV *PtrSCEV = getAddressAccessSCEV(Ptr, PSE, TheLoop);
4247
4248 // Get the cost of the scalar memory instruction and address computation.
4250 VF.getFixedValue() *
4251 TTI.getAddressComputationCost(PtrTy, SE, PtrSCEV, Config.CostKind);
4252
4253 // Don't pass *I here, since it is scalar but will actually be part of a
4254 // vectorized loop where the user of it is a vectorized instruction.
4255 const Align Alignment = getLoadStoreAlignment(I);
4256 TTI::OperandValueInfo OpInfo = TTI::getOperandInfo(I->getOperand(0));
4257 Cost += VF.getFixedValue() *
4258 TTI.getMemoryOpCost(I->getOpcode(), ValTy->getScalarType(), Alignment,
4259 AS, Config.CostKind, OpInfo);
4260
4261 // Get the overhead of the extractelement and insertelement instructions
4262 // we might create due to scalarization.
4263 Cost += getScalarizationOverhead(I, VF);
4264
4265 // If we have a predicated load/store, it will need extra i1 extracts and
4266 // conditional branches, but may not be executed for each vector lane. Scale
4267 // the cost by the probability of executing the predicated block.
4268 if (isPredicatedInst(I)) {
4269 Cost /= getPredBlockCostDivisor(Config.CostKind, I->getParent());
4270
4271 // Add the cost of an i1 extract and a branch
4272 auto *VecI1Ty =
4274 Cost += TTI.getScalarizationOverhead(
4275 VecI1Ty, APInt::getAllOnes(VF.getFixedValue()),
4276 /*Insert=*/false, /*Extract=*/true, Config.CostKind);
4277 Cost += TTI.getCFInstrCost(Instruction::CondBr, Config.CostKind);
4278
4280 // Artificially setting to a high enough value to practically disable
4281 // vectorization with such operations.
4282 Cost = 3000000;
4283 }
4284
4285 return Cost;
4286}
4287
4288InstructionCost LoopVectorizationCostModel::getConsecutiveMemOpCost(
4289 Instruction *I, ElementCount VF, InstWidening Kind) {
4290 assert((Kind == CM_Widen || Kind == CM_Widen_Reverse) &&
4291 "Expected a consecutive widening decision");
4292 Type *ValTy = getLoadStoreType(I);
4293 auto *VectorTy = cast<VectorType>(toVectorTy(ValTy, VF));
4294 unsigned AS = getLoadStoreAddressSpace(I);
4295
4296 const Align Alignment = getLoadStoreAlignment(I);
4298 if (isMaskRequired(I)) {
4299 unsigned IID = I->getOpcode() == Instruction::Load
4300 ? Intrinsic::masked_load
4301 : Intrinsic::masked_store;
4302 Cost += TTI.getMemIntrinsicInstrCost(
4303 MemIntrinsicCostAttributes(IID, VectorTy, Alignment, AS),
4304 Config.CostKind);
4305 } else {
4306 TTI::OperandValueInfo OpInfo = TTI::getOperandInfo(I->getOperand(0));
4307 Cost += TTI.getMemoryOpCost(I->getOpcode(), VectorTy, Alignment, AS,
4308 Config.CostKind, OpInfo, I);
4309 }
4310
4311 if (Kind == CM_Widen_Reverse)
4312 Cost += TTI.getShuffleCost(TargetTransformInfo::SK_Reverse, VectorTy,
4313 VectorTy, {}, Config.CostKind, 0);
4314 return Cost;
4315}
4316
4318LoopVectorizationCostModel::getUniformMemOpCost(Instruction *I,
4319 ElementCount VF) {
4320 assert(isUniformMemOp(*I, VF));
4321
4322 Type *ValTy = getLoadStoreType(I);
4324 auto *VectorTy = cast<VectorType>(toVectorTy(ValTy, VF));
4325 const Align Alignment = getLoadStoreAlignment(I);
4326 unsigned AS = getLoadStoreAddressSpace(I);
4327 if (isa<LoadInst>(I)) {
4328 return TTI.getAddressComputationCost(PtrTy, nullptr, nullptr,
4329 Config.CostKind) +
4330 TTI.getMemoryOpCost(Instruction::Load, ValTy, Alignment, AS,
4331 Config.CostKind) +
4332 TTI.getShuffleCost(TargetTransformInfo::SK_Broadcast, VectorTy,
4333 VectorTy, {}, Config.CostKind);
4334 }
4335 StoreInst *SI = cast<StoreInst>(I);
4336
4337 bool IsLoopInvariantStoreValue = Legal->isInvariant(SI->getValueOperand());
4338 // TODO: We have existing tests that request the cost of extracting element
4339 // VF.getKnownMinValue() - 1 from a scalable vector. This does not represent
4340 // the actual generated code, which involves extracting the last element of
4341 // a scalable vector where the lane to extract is unknown at compile time.
4343 TTI.getAddressComputationCost(PtrTy, nullptr, nullptr, Config.CostKind) +
4344 TTI.getMemoryOpCost(Instruction::Store, ValTy, Alignment, AS,
4345 Config.CostKind);
4346 if (!IsLoopInvariantStoreValue)
4347 Cost += TTI.getIndexedVectorInstrCostFromEnd(Instruction::ExtractElement,
4348 VectorTy, Config.CostKind, 0);
4349 return Cost;
4350}
4351
4353LoopVectorizationCostModel::getGatherScatterCost(Instruction *I,
4354 ElementCount VF) {
4355 Type *ValTy = getLoadStoreType(I);
4356 auto *VectorTy = cast<VectorType>(toVectorTy(ValTy, VF));
4357 const Align Alignment = getLoadStoreAlignment(I);
4359 Type *PtrTy = Ptr->getType();
4360
4361 if (!isUniform(Ptr, VF))
4362 PtrTy = toVectorTy(PtrTy, VF);
4363
4364 unsigned IID = I->getOpcode() == Instruction::Load
4365 ? Intrinsic::masked_gather
4366 : Intrinsic::masked_scatter;
4367 return TTI.getAddressComputationCost(PtrTy, nullptr, nullptr,
4368 Config.CostKind) +
4369 TTI.getMemIntrinsicInstrCost(
4370 MemIntrinsicCostAttributes(IID, VectorTy, Ptr, isMaskRequired(I),
4371 Alignment, I),
4372 Config.CostKind);
4373}
4374
4376LoopVectorizationCostModel::getInterleaveGroupCost(Instruction *I,
4377 ElementCount VF) {
4378 const auto *Group = getInterleavedAccessGroup(I);
4379 assert(Group && "Fail to get an interleaved access group.");
4380
4381 Instruction *InsertPos = Group->getInsertPos();
4382 Type *ValTy = getLoadStoreType(InsertPos);
4383 auto *VectorTy = cast<VectorType>(toVectorTy(ValTy, VF));
4384 unsigned AS = getLoadStoreAddressSpace(InsertPos);
4385
4386 unsigned InterleaveFactor = Group->getFactor();
4387 auto *WideVecTy = VectorType::get(ValTy, VF * InterleaveFactor);
4388
4389 // Holds the indices of existing members in the interleaved group.
4390 SmallVector<unsigned, 4> Indices;
4391 for (unsigned IF = 0; IF < InterleaveFactor; IF++)
4392 if (Group->getMember(IF))
4393 Indices.push_back(IF);
4394
4395 // Calculate the cost of the whole interleaved group.
4396 bool UseMaskForGaps =
4397 (Group->requiresScalarEpilogue() && !isEpilogueAllowed()) ||
4398 (isa<StoreInst>(I) && !Group->isFull());
4399 InstructionCost Cost = TTI.getInterleavedMemoryOpCost(
4400 InsertPos->getOpcode(), WideVecTy, Group->getFactor(), Indices,
4401 Group->getAlign(), AS, Config.CostKind, isMaskRequired(I),
4402 UseMaskForGaps);
4403
4404 if (Group->isReverse()) {
4405 // TODO: Add support for reversed masked interleaved access.
4407 "Reverse masked interleaved access not supported.");
4408 Cost += Group->getNumMembers() *
4409 TTI.getShuffleCost(TargetTransformInfo::SK_Reverse, VectorTy,
4410 VectorTy, {}, Config.CostKind, 0);
4411 }
4412 return Cost;
4413}
4414
4415std::optional<InstructionCost>
4417 ElementCount VF,
4418 Type *Ty) const {
4419 using namespace llvm::PatternMatch;
4420 // Early exit for no inloop reductions
4421 if (Config.getInLoopReductions().empty() || VF.isScalar() ||
4422 !isa<VectorType>(Ty))
4423 return std::nullopt;
4424 auto *VectorTy = cast<VectorType>(Ty);
4425
4426 // We are looking for a pattern of, and finding the minimal acceptable cost:
4427 // reduce(mul(ext(A), ext(B))) or
4428 // reduce(mul(A, B)) or
4429 // reduce(ext(A)) or
4430 // reduce(A).
4431 // The basic idea is that we walk down the tree to do that, finding the root
4432 // reduction instruction in InLoopReductionImmediateChains. From there we find
4433 // the pattern of mul/ext and test the cost of the entire pattern vs the cost
4434 // of the components. If the reduction cost is lower then we return it for the
4435 // reduction instruction and 0 for the other instructions in the pattern. If
4436 // it is not we return an invalid cost specifying the orignal cost method
4437 // should be used.
4438 Instruction *RetI = I;
4439 if (match(RetI, m_ZExtOrSExt(m_Value()))) {
4440 if (!RetI->hasOneUser())
4441 return std::nullopt;
4442 RetI = RetI->user_back();
4443 }
4444
4445 if (match(RetI, m_OneUse(m_Mul(m_Value(), m_Value()))) &&
4446 RetI->user_back()->getOpcode() == Instruction::Add) {
4447 RetI = RetI->user_back();
4448 }
4449
4450 // Test if the found instruction is a reduction, and if not return an invalid
4451 // cost specifying the parent to use the original cost modelling.
4452 Instruction *LastChain = Config.getInLoopReductionImmediateChain(RetI);
4453 if (!LastChain)
4454 return std::nullopt;
4455
4456 // Find the reduction this chain is a part of and calculate the basic cost of
4457 // the reduction on its own.
4458 Instruction *ReductionPhi = LastChain;
4459 while (!isa<PHINode>(ReductionPhi))
4460 ReductionPhi = Config.getInLoopReductionImmediateChain(ReductionPhi);
4461
4462 const RecurrenceDescriptor &RdxDesc =
4463 Legal->getRecurrenceDescriptor(cast<PHINode>(ReductionPhi));
4464
4465 InstructionCost BaseCost;
4466 RecurKind RK = RdxDesc.getRecurrenceKind();
4469 BaseCost = TTI.getMinMaxReductionCost(
4470 MinMaxID, VectorTy, RdxDesc.getFastMathFlags(), Config.CostKind);
4471 } else {
4472 BaseCost = TTI.getArithmeticReductionCost(RdxDesc.getOpcode(), VectorTy,
4473 RdxDesc.getFastMathFlags(),
4474 Config.CostKind);
4475 }
4476
4477 // For a call to the llvm.fmuladd intrinsic we need to add the cost of a
4478 // normal fmul instruction to the cost of the fadd reduction.
4479 if (RK == RecurKind::FMulAdd)
4480 BaseCost += TTI.getArithmeticInstrCost(Instruction::FMul, VectorTy,
4481 Config.CostKind);
4482
4483 // If we're using ordered reductions then we can just return the base cost
4484 // here, since getArithmeticReductionCost calculates the full ordered
4485 // reduction cost when FP reassociation is not allowed.
4486 if (Config.useOrderedReductions(RdxDesc))
4487 return BaseCost;
4488
4489 // Get the operand that was not the reduction chain and match it to one of the
4490 // patterns, returning the better cost if it is found.
4491 Instruction *RedOp = RetI->getOperand(1) == LastChain
4494
4495 VectorTy = VectorType::get(I->getOperand(0)->getType(), VectorTy);
4496
4497 Instruction *Op0, *Op1;
4498 if (RedOp && RdxDesc.getOpcode() == Instruction::Add &&
4499 match(RedOp,
4501 match(Op0, m_ZExtOrSExt(m_Value())) &&
4502 Op0->getOpcode() == Op1->getOpcode() &&
4503 Op0->getOperand(0)->getType() == Op1->getOperand(0)->getType() &&
4504 !TheLoop->isLoopInvariant(Op0) && !TheLoop->isLoopInvariant(Op1) &&
4505 (Op0->getOpcode() == RedOp->getOpcode() || Op0 == Op1)) {
4506
4507 // Matched reduce.add(ext(mul(ext(A), ext(B)))
4508 // Note that the extend opcodes need to all match, or if A==B they will have
4509 // been converted to zext(mul(sext(A), sext(A))) as it is known positive,
4510 // which is equally fine.
4511 bool IsUnsigned = isa<ZExtInst>(Op0);
4512 auto *ExtType = VectorType::get(Op0->getOperand(0)->getType(), VectorTy);
4513 auto *MulType = VectorType::get(Op0->getType(), VectorTy);
4514
4515 InstructionCost ExtCost =
4516 TTI.getCastInstrCost(Op0->getOpcode(), MulType, ExtType,
4517 TTI::CastContextHint::None, Config.CostKind, Op0);
4518 InstructionCost MulCost =
4519 TTI.getArithmeticInstrCost(Instruction::Mul, MulType, Config.CostKind);
4520 InstructionCost Ext2Cost = TTI.getCastInstrCost(
4521 RedOp->getOpcode(), VectorTy, MulType, TTI::CastContextHint::None,
4522 Config.CostKind, RedOp);
4523
4524 InstructionCost RedCost = TTI.getMulAccReductionCost(
4525 IsUnsigned, RdxDesc.getOpcode(), RdxDesc.getRecurrenceType(), ExtType,
4526 Config.CostKind);
4527
4528 if (RedCost.isValid() &&
4529 RedCost < ExtCost * 2 + MulCost + Ext2Cost + BaseCost)
4530 return I == RetI ? RedCost : 0;
4531 } else if (RedOp && match(RedOp, m_ZExtOrSExt(m_Value())) &&
4532 !TheLoop->isLoopInvariant(RedOp)) {
4533 // Matched reduce(ext(A))
4534 bool IsUnsigned = isa<ZExtInst>(RedOp);
4535 auto *ExtType = VectorType::get(RedOp->getOperand(0)->getType(), VectorTy);
4536 InstructionCost RedCost = TTI.getExtendedReductionCost(
4537 RdxDesc.getOpcode(), IsUnsigned, RdxDesc.getRecurrenceType(), ExtType,
4538 RdxDesc.getFastMathFlags(), Config.CostKind);
4539
4540 InstructionCost ExtCost = TTI.getCastInstrCost(
4541 RedOp->getOpcode(), VectorTy, ExtType, TTI::CastContextHint::None,
4542 Config.CostKind, RedOp);
4543 if (RedCost.isValid() && RedCost < BaseCost + ExtCost)
4544 return I == RetI ? RedCost : 0;
4545 } else if (RedOp && RdxDesc.getOpcode() == Instruction::Add &&
4546 match(RedOp, m_Mul(m_Instruction(Op0), m_Instruction(Op1)))) {
4547 if (match(Op0, m_ZExtOrSExt(m_Value())) &&
4548 Op0->getOpcode() == Op1->getOpcode() &&
4549 !TheLoop->isLoopInvariant(Op0) && !TheLoop->isLoopInvariant(Op1)) {
4550 bool IsUnsigned = isa<ZExtInst>(Op0);
4551 Type *Op0Ty = Op0->getOperand(0)->getType();
4552 Type *Op1Ty = Op1->getOperand(0)->getType();
4553 Type *LargestOpTy =
4554 Op0Ty->getIntegerBitWidth() < Op1Ty->getIntegerBitWidth() ? Op1Ty
4555 : Op0Ty;
4556 auto *ExtType = VectorType::get(LargestOpTy, VectorTy);
4557
4558 // Matched reduce.add(mul(ext(A), ext(B))), where the two ext may be of
4559 // different sizes. We take the largest type as the ext to reduce, and add
4560 // the remaining cost as, for example reduce(mul(ext(ext(A)), ext(B))).
4561 InstructionCost ExtCost0 = TTI.getCastInstrCost(
4562 Op0->getOpcode(), VectorTy, VectorType::get(Op0Ty, VectorTy),
4563 TTI::CastContextHint::None, Config.CostKind, Op0);
4564 InstructionCost ExtCost1 = TTI.getCastInstrCost(
4565 Op1->getOpcode(), VectorTy, VectorType::get(Op1Ty, VectorTy),
4566 TTI::CastContextHint::None, Config.CostKind, Op1);
4567 InstructionCost MulCost = TTI.getArithmeticInstrCost(
4568 Instruction::Mul, VectorTy, Config.CostKind);
4569
4570 InstructionCost RedCost = TTI.getMulAccReductionCost(
4571 IsUnsigned, RdxDesc.getOpcode(), RdxDesc.getRecurrenceType(), ExtType,
4572 Config.CostKind);
4573 InstructionCost ExtraExtCost = 0;
4574 if (Op0Ty != LargestOpTy || Op1Ty != LargestOpTy) {
4575 Instruction *ExtraExtOp = (Op0Ty != LargestOpTy) ? Op0 : Op1;
4576 ExtraExtCost = TTI.getCastInstrCost(
4577 ExtraExtOp->getOpcode(), ExtType,
4578 VectorType::get(ExtraExtOp->getOperand(0)->getType(), VectorTy),
4579 TTI::CastContextHint::None, Config.CostKind, ExtraExtOp);
4580 }
4581
4582 if (RedCost.isValid() &&
4583 (RedCost + ExtraExtCost) < (ExtCost0 + ExtCost1 + MulCost + BaseCost))
4584 return I == RetI ? RedCost : 0;
4585 } else if (!match(I, m_ZExtOrSExt(m_Value()))) {
4586 // Matched reduce.add(mul())
4587 InstructionCost MulCost = TTI.getArithmeticInstrCost(
4588 Instruction::Mul, VectorTy, Config.CostKind);
4589
4590 InstructionCost RedCost = TTI.getMulAccReductionCost(
4591 true, RdxDesc.getOpcode(), RdxDesc.getRecurrenceType(), VectorTy,
4592 Config.CostKind);
4593
4594 if (RedCost.isValid() && RedCost < MulCost + BaseCost)
4595 return I == RetI ? RedCost : 0;
4596 }
4597 }
4598
4599 return I == RetI ? std::optional<InstructionCost>(BaseCost) : std::nullopt;
4600}
4601
4603LoopVectorizationCostModel::getMemoryInstructionCost(Instruction *I,
4604 ElementCount VF) {
4605 // Calculate scalar cost only. Vectorization cost should be ready at this
4606 // moment.
4607 if (VF.isScalar()) {
4608 Type *ValTy = getLoadStoreType(I);
4610 const Align Alignment = getLoadStoreAlignment(I);
4611 unsigned AS = getLoadStoreAddressSpace(I);
4612
4613 TTI::OperandValueInfo OpInfo = TTI::getOperandInfo(I->getOperand(0));
4614 return TTI.getAddressComputationCost(PtrTy, nullptr, nullptr,
4615 Config.CostKind) +
4616 TTI.getMemoryOpCost(I->getOpcode(), ValTy, Alignment, AS,
4617 Config.CostKind, OpInfo, I);
4618 }
4619 return getWideningCost(I, VF);
4620}
4621
4623LoopVectorizationCostModel::getScalarizationOverhead(Instruction *I,
4624 ElementCount VF) const {
4625
4626 // There is no mechanism yet to create a scalable scalarization loop,
4627 // so this is currently Invalid.
4628 if (VF.isScalable())
4630
4631 if (VF.isScalar())
4632 return 0;
4633
4635 Type *RetTy = toVectorizedTy(I->getType(), VF);
4636 if (!RetTy->isVoidTy() &&
4637 (!isa<LoadInst>(I) || !TTI.supportsEfficientVectorElementLoadStore())) {
4638
4640 if (isa<LoadInst>(I))
4642 else if (isa<StoreInst>(I))
4644
4645 for (Type *VectorTy : getContainedTypes(RetTy)) {
4646 Cost += TTI.getScalarizationOverhead(
4648 /*Insert=*/true, /*Extract=*/false, Config.CostKind,
4649 /*ForPoisonSrc=*/true, {}, VIC);
4650 }
4651 }
4652
4653 // Some targets keep addresses scalar.
4654 if (isa<LoadInst>(I) && !TTI.prefersVectorizedAddressing())
4655 return Cost;
4656
4657 // Some targets support efficient element stores.
4658 if (isa<StoreInst>(I) && TTI.supportsEfficientVectorElementLoadStore())
4659 return Cost;
4660
4661 // Collect operands to consider.
4662 CallInst *CI = dyn_cast<CallInst>(I);
4663 Instruction::op_range Ops = CI ? CI->args() : I->operands();
4664
4665 // Skip operands that do not require extraction/scalarization and do not incur
4666 // any overhead.
4668 for (auto *V : filterExtractingOperands(Ops, VF))
4669 Tys.push_back(maybeVectorizeType(V->getType(), VF));
4670
4674 return Cost +
4675 TTI.getOperandsScalarizationOverhead(Tys, Config.CostKind, OperandVIC);
4676}
4677
4679 if (VF.isScalar())
4680 return;
4681
4682 // TODO: We should generate better code and update the cost model for
4683 // predicated uniform stores. Today they are treated as any other
4684 // predicated store (see added test cases in
4685 // invariant-store-vectorization.ll).
4686 NumPredStores = 0;
4687 for (BasicBlock *BB : TheLoop->blocks())
4688 for (Instruction &I : *BB)
4690 ++NumPredStores;
4691
4692 for (BasicBlock *BB : TheLoop->blocks()) {
4693 // For each instruction in the old loop.
4694 for (Instruction &I : *BB) {
4696 if (!Ptr)
4697 continue;
4698
4699 if (isUniformMemOp(I, VF)) {
4700 auto IsLegalToScalarize = [&]() {
4701 if (!VF.isScalable())
4702 // Scalarization of fixed length vectors "just works".
4703 return true;
4704
4705 // We have dedicated lowering for unpredicated uniform loads and
4706 // stores. Note that even with tail folding we know that at least
4707 // one lane is active (i.e. generalized predication is not possible
4708 // here), and the logic below depends on this fact.
4709 if (!foldTailByMasking())
4710 return true;
4711
4712 // For scalable vectors, a uniform memop load is always
4713 // uniform-by-parts and we know how to scalarize that.
4714 if (isa<LoadInst>(I))
4715 return true;
4716
4717 // A uniform store isn't neccessarily uniform-by-part
4718 // and we can't assume scalarization.
4719 auto &SI = cast<StoreInst>(I);
4720 return TheLoop->isLoopInvariant(SI.getValueOperand());
4721 };
4722
4723 const InstructionCost GatherScatterCost =
4724 Config.isLegalGatherOrScatter(&I, VF)
4725 ? getGatherScatterCost(&I, VF)
4727
4728 // Load: Scalar load + broadcast
4729 // Store: Scalar store + isLoopInvariantStoreValue ? 0 : extract
4730 // FIXME: This cost is a significant under-estimate for tail folded
4731 // memory ops.
4732 const InstructionCost ScalarizationCost =
4733 IsLegalToScalarize() ? getUniformMemOpCost(&I, VF)
4735
4736 // Choose better solution for the current VF, Note that Invalid
4737 // costs compare as maximumal large. If both are invalid, we get
4738 // scalable invalid which signals a failure and a vectorization abort.
4739 if (GatherScatterCost < ScalarizationCost)
4740 setWideningDecision(&I, VF, CM_GatherScatter, GatherScatterCost);
4741 else
4742 setWideningDecision(&I, VF, CM_Scalarize, ScalarizationCost);
4743 continue;
4744 }
4745
4746 // We assume that widening is the best solution when possible.
4747 if (std::optional<InstWidening> Decision =
4749 setWideningDecision(&I, VF, *Decision,
4750 getConsecutiveMemOpCost(&I, VF, *Decision));
4751 continue;
4752 }
4753
4754 // Choose between Interleaving, Gather/Scatter or Scalarization.
4756 unsigned NumAccesses = 1;
4757 if (isAccessInterleaved(&I)) {
4758 const auto *Group = getInterleavedAccessGroup(&I);
4759 assert(Group && "Fail to get an interleaved access group.");
4760
4761 // Make one decision for the whole group.
4762 if (getWideningDecision(&I, VF) != CM_Unknown)
4763 continue;
4764
4765 NumAccesses = Group->getNumMembers();
4767 InterleaveCost = getInterleaveGroupCost(&I, VF);
4768 }
4769
4770 InstructionCost GatherScatterCost =
4771 Config.isLegalGatherOrScatter(&I, VF)
4772 ? getGatherScatterCost(&I, VF) * NumAccesses
4774
4775 InstructionCost ScalarizationCost =
4776 getMemInstScalarizationCost(&I, VF) * NumAccesses;
4777
4778 // Choose better solution for the current VF,
4779 // write down this decision and use it during vectorization.
4781 InstWidening Decision;
4782 if (InterleaveCost <= GatherScatterCost &&
4783 InterleaveCost < ScalarizationCost) {
4784 Decision = CM_Interleave;
4785 Cost = InterleaveCost;
4786 } else if (GatherScatterCost < ScalarizationCost) {
4787 Decision = CM_GatherScatter;
4788 Cost = GatherScatterCost;
4789 } else {
4790 Decision = CM_Scalarize;
4791 Cost = ScalarizationCost;
4792 }
4793 // If the instructions belongs to an interleave group, the whole group
4794 // receives the same decision. The whole group receives the cost, but
4795 // the cost will actually be assigned to one instruction.
4796 if (const auto *Group = getInterleavedAccessGroup(&I)) {
4797 if (Decision == CM_Scalarize) {
4798 for (Instruction *I : Group->members())
4799 setWideningDecision(I, VF, Decision,
4800 getMemInstScalarizationCost(I, VF));
4801 } else {
4802 setWideningDecision(Group, VF, Decision, Cost);
4803 }
4804 } else
4805 setWideningDecision(&I, VF, Decision, Cost);
4806 }
4807 }
4808
4809 // Make sure that any load of address and any other address computation
4810 // remains scalar unless there is gather/scatter support. This avoids
4811 // inevitable extracts into address registers, and also has the benefit of
4812 // activating LSR more, since that pass can't optimize vectorized
4813 // addresses.
4814 if (TTI.prefersVectorizedAddressing())
4815 return;
4816
4817 // Start with all scalar pointer uses.
4819 for (BasicBlock *BB : TheLoop->blocks())
4820 for (Instruction &I : *BB) {
4821 Instruction *PtrDef =
4823 if (PtrDef && TheLoop->contains(PtrDef) &&
4825 AddrDefs.insert(PtrDef);
4826 }
4827
4828 // Add all instructions used to generate the addresses.
4830 append_range(Worklist, AddrDefs);
4831 while (!Worklist.empty()) {
4832 Instruction *I = Worklist.pop_back_val();
4833 for (auto &Op : I->operands())
4834 if (auto *InstOp = dyn_cast<Instruction>(Op))
4835 if (TheLoop->contains(InstOp) && !isa<PHINode>(InstOp) &&
4836 AddrDefs.insert(InstOp))
4837 Worklist.push_back(InstOp);
4838 }
4839
4840 auto UpdateMemOpUserCost = [this, VF](LoadInst *LI) {
4841 // If there are direct memory op users of the newly scalarized load,
4842 // their cost may have changed because there's no scalarization
4843 // overhead for the operand. Update it.
4844 for (User *U : LI->users()) {
4846 continue;
4848 continue;
4851 getMemInstScalarizationCost(cast<Instruction>(U), VF));
4852 }
4853 };
4854 for (auto *I : AddrDefs) {
4855 if (isa<LoadInst>(I)) {
4856 // Setting the desired widening decision should ideally be handled in
4857 // by cost functions, but since this involves the task of finding out
4858 // if the loaded register is involved in an address computation, it is
4859 // instead changed here when we know this is the case.
4860 InstWidening Decision = getWideningDecision(I, VF);
4861 if (!isPredicatedInst(I) &&
4862 (Decision == CM_Widen || Decision == CM_Widen_Reverse ||
4863 (!isUniformMemOp(*I, VF) && Decision == CM_Scalarize))) {
4864 // Scalarize a widened load of address or update the cost of a scalar
4865 // load of an address.
4867 I, VF, CM_Scalarize,
4868 (VF.getKnownMinValue() *
4869 getMemoryInstructionCost(I, ElementCount::getFixed(1))));
4870 UpdateMemOpUserCost(cast<LoadInst>(I));
4871 } else if (const auto *Group = getInterleavedAccessGroup(I)) {
4872 // Scalarize all members of this interleaved group when any member
4873 // is used as an address. The address-used load skips scalarization
4874 // overhead, other members include it.
4875 for (Instruction *Member : Group->members()) {
4876 InstructionCost Cost = AddrDefs.contains(Member)
4877 ? (VF.getKnownMinValue() *
4878 getMemoryInstructionCost(
4879 Member, ElementCount::getFixed(1)))
4880 : getMemInstScalarizationCost(Member, VF);
4882 UpdateMemOpUserCost(cast<LoadInst>(Member));
4883 }
4884 }
4885 } else {
4886 // Cannot scalarize fixed-order recurrence phis at the moment.
4887 if (isa<PHINode>(I) && Legal->isFixedOrderRecurrence(cast<PHINode>(I)))
4888 continue;
4889
4890 // Make sure I gets scalarized and a cost estimate without
4891 // scalarization overhead.
4892 ForcedScalars[VF].insert(I);
4893 }
4894 }
4895}
4896
4898 if (!Legal->isInvariant(Op))
4899 return false;
4900 // Consider Op invariant, if it or its operands aren't predicated
4901 // instruction in the loop. In that case, it is not trivially hoistable.
4902 auto *OpI = dyn_cast<Instruction>(Op);
4903 return !OpI || !TheLoop->contains(OpI) ||
4904 (!isPredicatedInst(OpI) &&
4905 (!isa<PHINode>(OpI) || OpI->getParent() != TheLoop->getHeader()) &&
4906 all_of(OpI->operands(),
4907 [this](Value *Op) { return shouldConsiderInvariant(Op); }));
4908}
4909
4912 ElementCount VF) {
4913 // If we know that this instruction will remain uniform, check the cost of
4914 // the scalar version.
4916 VF = ElementCount::getFixed(1);
4917
4918 if (VF.isVector() && isProfitableToScalarize(I, VF))
4919 return InstsToScalarize[VF][I];
4920
4921 // Forced scalars do not have any scalarization overhead.
4922 auto ForcedScalar = ForcedScalars.find(VF);
4923 if (VF.isVector() && ForcedScalar != ForcedScalars.end()) {
4924 auto InstSet = ForcedScalar->second;
4925 if (InstSet.count(I))
4927 VF.getKnownMinValue();
4928 }
4929
4930 const auto &MinBWs = Config.getMinimalBitwidths();
4931 uint64_t InstrMinBWs = MinBWs.lookup(I);
4932 Type *RetTy = I->getType();
4934 RetTy = IntegerType::get(RetTy->getContext(), InstrMinBWs);
4935 auto *SE = PSE.getSE();
4936
4937 Type *VectorTy;
4938 if (isScalarAfterVectorization(I, VF)) {
4939 [[maybe_unused]] auto HasSingleCopyAfterVectorization =
4940 [this](Instruction *I, ElementCount VF) -> bool {
4941 if (VF.isScalar())
4942 return true;
4943
4944 auto Scalarized = InstsToScalarize.find(VF);
4945 assert(Scalarized != InstsToScalarize.end() &&
4946 "VF not yet analyzed for scalarization profitability");
4947 return !Scalarized->second.count(I) &&
4948 llvm::all_of(I->users(), [&](User *U) {
4949 auto *UI = cast<Instruction>(U);
4950 return !Scalarized->second.count(UI);
4951 });
4952 };
4953
4954 // With the exception of GEPs and PHIs, after scalarization there should
4955 // only be one copy of the instruction generated in the loop. This is
4956 // because the VF is either 1, or any instructions that need scalarizing
4957 // have already been dealt with by the time we get here. As a result,
4958 // it means we don't have to multiply the instruction cost by VF.
4959 assert(I->getOpcode() == Instruction::GetElementPtr ||
4960 I->getOpcode() == Instruction::PHI ||
4961 (I->getOpcode() == Instruction::BitCast &&
4962 I->getType()->isPointerTy()) ||
4963 HasSingleCopyAfterVectorization(I, VF));
4964 VectorTy = RetTy;
4965 } else
4966 VectorTy = toVectorizedTy(RetTy, VF);
4967
4968 if (VF.isVector() && VectorTy->isVectorTy() &&
4969 !TTI.getNumberOfParts(VectorTy))
4971
4972 // TODO: We need to estimate the cost of intrinsic calls.
4973 switch (I->getOpcode()) {
4974 case Instruction::GetElementPtr:
4975 // We mark this instruction as zero-cost because the cost of GEPs in
4976 // vectorized code depends on whether the corresponding memory instruction
4977 // is scalarized or not. Therefore, we handle GEPs with the memory
4978 // instruction cost.
4979 return 0;
4980 case Instruction::UncondBr:
4981 case Instruction::CondBr: {
4982 // In cases of scalarized and predicated instructions, there will be VF
4983 // predicated blocks in the vectorized loop. Each branch around these
4984 // blocks requires also an extract of its vector compare i1 element.
4985 // Note that the conditional branch from the loop latch will be replaced by
4986 // a single branch controlling the loop, so there is no extra overhead from
4987 // scalarization.
4988 bool ScalarPredicatedBB = false;
4990 if (VF.isVector() && BI &&
4991 (PredicatedBBsAfterVectorization[VF].count(BI->getSuccessor(0)) ||
4992 PredicatedBBsAfterVectorization[VF].count(BI->getSuccessor(1))) &&
4993 BI->getParent() != TheLoop->getLoopLatch())
4994 ScalarPredicatedBB = true;
4995
4996 if (ScalarPredicatedBB) {
4997 // Not possible to scalarize scalable vector with predicated instructions.
4998 if (VF.isScalable())
5000 // Return cost for branches around scalarized and predicated blocks.
5001 auto *VecI1Ty =
5003 return (TTI.getScalarizationOverhead(
5004 VecI1Ty, APInt::getAllOnes(VF.getFixedValue()),
5005 /*Insert*/ false, /*Extract*/ true, Config.CostKind) +
5006 (TTI.getCFInstrCost(Instruction::CondBr, Config.CostKind) *
5007 VF.getFixedValue()));
5008 }
5009
5010 if (I->getParent() == TheLoop->getLoopLatch() || VF.isScalar())
5011 // The back-edge branch will remain, as will all scalar branches.
5012 return TTI.getCFInstrCost(Instruction::UncondBr, Config.CostKind);
5013
5014 // This branch will be eliminated by if-conversion.
5015 return 0;
5016 // Note: We currently assume zero cost for an unconditional branch inside
5017 // a predicated block since it will become a fall-through, although we
5018 // may decide in the future to call TTI for all branches.
5019 }
5020 case Instruction::Switch: {
5021 if (VF.isScalar())
5022 return TTI.getCFInstrCost(Instruction::Switch, Config.CostKind);
5023 auto *Switch = cast<SwitchInst>(I);
5024 return Switch->getNumCases() *
5025 TTI.getCmpSelInstrCost(
5026 Instruction::ICmp,
5027 toVectorTy(Switch->getCondition()->getType(), VF),
5028 toVectorTy(Type::getInt1Ty(I->getContext()), VF),
5029 CmpInst::ICMP_EQ, Config.CostKind);
5030 }
5031 case Instruction::PHI: {
5032 auto *Phi = cast<PHINode>(I);
5033
5034 // First-order recurrences are replaced by vector shuffles inside the loop.
5035 if (VF.isVector() && Legal->isFixedOrderRecurrence(Phi)) {
5036 return TTI.getShuffleCost(
5038 cast<VectorType>(VectorTy), {}, Config.CostKind, -1);
5039 }
5040
5041 // Phi nodes in non-header blocks (not inductions, reductions, etc.) are
5042 // converted into select instructions. We require N - 1 selects per phi
5043 // node, where N is the number of incoming values.
5044 if (VF.isVector() && Phi->getParent() != TheLoop->getHeader()) {
5045 Type *ResultTy = Phi->getType();
5046
5047 // All instructions in an Any-of reduction chain are narrowed to bool.
5048 // Check if that is the case for this phi node.
5049 auto *HeaderUser = cast_if_present<PHINode>(
5050 find_singleton<User>(Phi->users(), [this](User *U, bool) -> User * {
5051 auto *Phi = dyn_cast<PHINode>(U);
5052 if (Phi && Phi->getParent() == TheLoop->getHeader())
5053 return Phi;
5054 return nullptr;
5055 }));
5056 if (HeaderUser) {
5057 auto &ReductionVars = Legal->getReductionVars();
5058 auto Iter = ReductionVars.find(HeaderUser);
5059 if (Iter != ReductionVars.end() &&
5061 Iter->second.getRecurrenceKind()))
5062 ResultTy = Type::getInt1Ty(Phi->getContext());
5063 }
5064 return (Phi->getNumIncomingValues() - 1) *
5065 TTI.getCmpSelInstrCost(
5066 Instruction::Select, toVectorTy(ResultTy, VF),
5067 toVectorTy(Type::getInt1Ty(Phi->getContext()), VF),
5068 CmpInst::BAD_ICMP_PREDICATE, Config.CostKind);
5069 }
5070
5071 // When tail folding with EVL, if the phi is part of an out of loop
5072 // reduction then it will be transformed into a wide vp_merge.
5073 if (VF.isVector() && foldTailWithEVL() &&
5074 Legal->getReductionVars().contains(Phi) &&
5075 !Config.isInLoopReduction(Phi)) {
5077 Intrinsic::vp_merge, toVectorTy(Phi->getType(), VF),
5078 {toVectorTy(Type::getInt1Ty(Phi->getContext()), VF)});
5079 return TTI.getIntrinsicInstrCost(ICA, Config.CostKind);
5080 }
5081
5082 return TTI.getCFInstrCost(Instruction::PHI, Config.CostKind);
5083 }
5084 case Instruction::UDiv:
5085 case Instruction::SDiv:
5086 case Instruction::URem:
5087 case Instruction::SRem:
5088 if (VF.isVector() && isPredicatedInst(I)) {
5089 const auto [ScalarCost, MaskedCost] = getDivRemSpeculationCost(I, VF);
5090 return isDivRemScalarWithPredication(ScalarCost, MaskedCost) ? ScalarCost
5091 : MaskedCost;
5092 }
5093 // We've proven all lanes safe to speculate, fall through.
5094 [[fallthrough]];
5095 case Instruction::Add:
5096 case Instruction::Sub: {
5097 auto Info = Legal->getHistogramInfo(I);
5098 if (Info && VF.isVector()) {
5099 const HistogramInfo *HGram = Info.value();
5100 // Assume that a non-constant update value (or a constant != 1) requires
5101 // a multiply, and add that into the cost.
5103 ConstantInt *RHS = dyn_cast<ConstantInt>(I->getOperand(1));
5104 if (!RHS || RHS->getZExtValue() != 1)
5105 MulCost = TTI.getArithmeticInstrCost(Instruction::Mul, VectorTy,
5106 Config.CostKind);
5107
5108 // Find the cost of the histogram operation itself.
5109 Type *PtrTy = VectorType::get(HGram->Load->getPointerOperandType(), VF);
5110 Type *ScalarTy = I->getType();
5111 Type *MaskTy = VectorType::get(Type::getInt1Ty(I->getContext()), VF);
5112 IntrinsicCostAttributes ICA(Intrinsic::experimental_vector_histogram_add,
5113 Type::getVoidTy(I->getContext()),
5114 {PtrTy, ScalarTy, MaskTy});
5115
5116 // Add the costs together with the add/sub operation.
5117 return TTI.getIntrinsicInstrCost(ICA, Config.CostKind) + MulCost +
5118 TTI.getArithmeticInstrCost(I->getOpcode(), VectorTy,
5119 Config.CostKind);
5120 }
5121 [[fallthrough]];
5122 }
5123 case Instruction::FAdd:
5124 case Instruction::FSub:
5125 case Instruction::Mul:
5126 case Instruction::FMul:
5127 case Instruction::FDiv:
5128 case Instruction::FRem:
5129 case Instruction::Shl:
5130 case Instruction::LShr:
5131 case Instruction::AShr:
5132 case Instruction::And:
5133 case Instruction::Or:
5134 case Instruction::Xor: {
5135 // If we're speculating on the stride being 1, the multiplication may
5136 // fold away. We can generalize this for all operations using the notion
5137 // of neutral elements. (TODO)
5138 if (I->getOpcode() == Instruction::Mul &&
5139 ((TheLoop->isLoopInvariant(I->getOperand(0)) &&
5140 PSE.getSCEV(I->getOperand(0))->isOne()) ||
5141 (TheLoop->isLoopInvariant(I->getOperand(1)) &&
5142 PSE.getSCEV(I->getOperand(1))->isOne())))
5143 return 0;
5144
5145 // Detect reduction patterns
5146 if (auto RedCost = getReductionPatternCost(I, VF, VectorTy))
5147 return *RedCost;
5148
5149 // Certain instructions can be cheaper to vectorize if they have a constant
5150 // second vector operand. One example of this are shifts on x86.
5151 Value *Op2 = I->getOperand(1);
5152 if (!isa<Constant>(Op2) && TheLoop->isLoopInvariant(Op2) &&
5153 PSE.getSE()->isSCEVable(Op2->getType()) &&
5154 isa<SCEVConstant>(PSE.getSCEV(Op2))) {
5155 Op2 = cast<SCEVConstant>(PSE.getSCEV(Op2))->getValue();
5156 }
5157 auto Op2Info = TTI.getOperandInfo(Op2);
5158 if (Op2Info.Kind == TargetTransformInfo::OK_AnyValue &&
5161
5162 SmallVector<const Value *, 4> Operands(I->operand_values());
5163 return TTI.getArithmeticInstrCost(
5164 I->getOpcode(), VectorTy, Config.CostKind,
5165 {TargetTransformInfo::OK_AnyValue, TargetTransformInfo::OP_None},
5166 Op2Info, Operands, I, TLI);
5167 }
5168 case Instruction::FNeg: {
5169 return TTI.getArithmeticInstrCost(
5170 I->getOpcode(), VectorTy, Config.CostKind,
5171 {TargetTransformInfo::OK_AnyValue, TargetTransformInfo::OP_None},
5172 {TargetTransformInfo::OK_AnyValue, TargetTransformInfo::OP_None},
5173 I->getOperand(0), I);
5174 }
5175 case Instruction::Select: {
5177 const SCEV *CondSCEV = SE->getSCEV(SI->getCondition());
5178 bool ScalarCond = (SE->isLoopInvariant(CondSCEV, TheLoop));
5179
5180 const Value *Op0, *Op1;
5181 using namespace llvm::PatternMatch;
5182 if (!ScalarCond && (match(I, m_LogicalAnd(m_Value(Op0), m_Value(Op1))) ||
5183 match(I, m_LogicalOr(m_Value(Op0), m_Value(Op1))))) {
5184 // select x, y, false --> x & y
5185 // select x, true, y --> x | y
5186 const auto [Op1VK, Op1VP] = TTI::getOperandInfo(Op0);
5187 const auto [Op2VK, Op2VP] = TTI::getOperandInfo(Op1);
5188 assert(Op0->getType()->getScalarSizeInBits() == 1 &&
5189 Op1->getType()->getScalarSizeInBits() == 1);
5190
5191 return TTI.getArithmeticInstrCost(
5192 match(I, m_LogicalOr()) ? Instruction::Or : Instruction::And,
5193 VectorTy, Config.CostKind, {Op1VK, Op1VP}, {Op2VK, Op2VP}, {Op0, Op1},
5194 I);
5195 }
5196
5197 Type *CondTy = SI->getCondition()->getType();
5198 if (!ScalarCond)
5199 CondTy = VectorType::get(CondTy, VF);
5200
5202 if (auto *Cmp = dyn_cast<CmpInst>(SI->getCondition()))
5203 Pred = Cmp->getPredicate();
5204 return TTI.getCmpSelInstrCost(
5205 I->getOpcode(), VectorTy, CondTy, Pred, Config.CostKind,
5206 {TTI::OK_AnyValue, TTI::OP_None}, {TTI::OK_AnyValue, TTI::OP_None}, I);
5207 }
5208 case Instruction::ICmp:
5209 case Instruction::FCmp: {
5210 Type *ValTy = I->getOperand(0)->getType();
5211
5213 [[maybe_unused]] Instruction *Op0AsInstruction =
5214 dyn_cast<Instruction>(I->getOperand(0));
5215 assert((!canTruncateToMinimalBitwidth(Op0AsInstruction, VF) ||
5216 InstrMinBWs == MinBWs.lookup(Op0AsInstruction)) &&
5217 "if both the operand and the compare are marked for "
5218 "truncation, they must have the same bitwidth");
5219 ValTy = IntegerType::get(ValTy->getContext(), InstrMinBWs);
5220 }
5221
5222 VectorTy = toVectorTy(ValTy, VF);
5223 return TTI.getCmpSelInstrCost(
5224 I->getOpcode(), VectorTy, CmpInst::makeCmpResultType(VectorTy),
5225 cast<CmpInst>(I)->getPredicate(), Config.CostKind,
5226 {TTI::OK_AnyValue, TTI::OP_None}, {TTI::OK_AnyValue, TTI::OP_None}, I);
5227 }
5228 case Instruction::Store:
5229 case Instruction::Load: {
5230 ElementCount Width = VF;
5231 if (Width.isVector()) {
5232 InstWidening Decision = getWideningDecision(I, Width);
5233 assert(Decision != CM_Unknown &&
5234 "CM decision should be taken at this point");
5237 if (Decision == CM_Scalarize)
5238 Width = ElementCount::getFixed(1);
5239 }
5240 VectorTy = toVectorTy(getLoadStoreType(I), Width);
5241 return getMemoryInstructionCost(I, VF);
5242 }
5243 case Instruction::BitCast:
5244 if (I->getType()->isPointerTy())
5245 return 0;
5246 [[fallthrough]];
5247 case Instruction::ZExt:
5248 case Instruction::SExt:
5249 case Instruction::FPToUI:
5250 case Instruction::FPToSI:
5251 case Instruction::FPExt:
5252 case Instruction::PtrToInt:
5253 case Instruction::IntToPtr:
5254 case Instruction::SIToFP:
5255 case Instruction::UIToFP:
5256 case Instruction::Trunc:
5257 case Instruction::FPTrunc: {
5258 // Computes the CastContextHint from a Load/Store instruction.
5259 auto ComputeCCH = [&](Instruction *I) -> TTI::CastContextHint {
5261 "Expected a load or a store!");
5262
5263 if (VF.isScalar() || !TheLoop->contains(I))
5265
5266 switch (getWideningDecision(I, VF)) {
5278 llvm_unreachable("Instr did not go through cost modelling?");
5281 }
5282
5283 llvm_unreachable("Unhandled case!");
5284 };
5285
5286 unsigned Opcode = I->getOpcode();
5288 // For Trunc, the context is the only user, which must be a StoreInst.
5289 if (Opcode == Instruction::Trunc || Opcode == Instruction::FPTrunc) {
5290 if (I->hasOneUse())
5291 if (StoreInst *Store = dyn_cast<StoreInst>(*I->user_begin()))
5292 CCH = ComputeCCH(Store);
5293 }
5294 // For Z/Sext, the context is the operand, which must be a LoadInst.
5295 else if (Opcode == Instruction::ZExt || Opcode == Instruction::SExt ||
5296 Opcode == Instruction::FPExt) {
5297 if (LoadInst *Load = dyn_cast<LoadInst>(I->getOperand(0)))
5298 CCH = ComputeCCH(Load);
5299 }
5300
5301 // We optimize the truncation of induction variables having constant
5302 // integer steps. The cost of these truncations is the same as the scalar
5303 // operation.
5304 if (isOptimizableIVTruncate(I, VF)) {
5305 auto *Trunc = cast<TruncInst>(I);
5306 return TTI.getCastInstrCost(Instruction::Trunc, Trunc->getDestTy(),
5307 Trunc->getSrcTy(), CCH, Config.CostKind,
5308 Trunc);
5309 }
5310
5311 // Detect reduction patterns
5312 if (auto RedCost = getReductionPatternCost(I, VF, VectorTy))
5313 return *RedCost;
5314
5315 Type *SrcScalarTy = I->getOperand(0)->getType();
5316 Instruction *Op0AsInstruction = dyn_cast<Instruction>(I->getOperand(0));
5317 if (canTruncateToMinimalBitwidth(Op0AsInstruction, VF))
5318 SrcScalarTy = IntegerType::get(SrcScalarTy->getContext(),
5319 MinBWs.lookup(Op0AsInstruction));
5320 Type *SrcVecTy =
5321 VectorTy->isVectorTy() ? toVectorTy(SrcScalarTy, VF) : SrcScalarTy;
5322
5324 // If the result type is <= the source type, there will be no extend
5325 // after truncating the users to the minimal required bitwidth.
5326 if (VectorTy->getScalarSizeInBits() <= SrcVecTy->getScalarSizeInBits() &&
5327 (I->getOpcode() == Instruction::ZExt ||
5328 I->getOpcode() == Instruction::SExt))
5329 return 0;
5330 }
5331
5332 return TTI.getCastInstrCost(Opcode, VectorTy, SrcVecTy, CCH,
5333 Config.CostKind, I);
5334 }
5335 case Instruction::Call:
5336 return getVectorCallCost(cast<CallInst>(I), VF);
5337 case Instruction::ExtractValue:
5338 return TTI.getInstructionCost(I, Config.CostKind);
5339 case Instruction::Alloca:
5340 // We cannot easily widen alloca to a scalable alloca, as
5341 // the result would need to be a vector of pointers.
5342 if (VF.isScalable())
5344 return TTI.getArithmeticInstrCost(Instruction::Mul, RetTy, Config.CostKind);
5345 case Instruction::Freeze:
5346 return TTI::TCC_Free;
5347 default:
5348 // This opcode is unknown. Assume that it is the same as 'mul'.
5349 return TTI.getArithmeticInstrCost(Instruction::Mul, VectorTy,
5350 Config.CostKind);
5351 } // end of switch.
5352}
5353
5355 // Ignore ephemeral values.
5357
5358 SmallVector<Value *, 4> DeadInterleavePointerOps;
5360
5361 // If a scalar epilogue is required, users outside the loop won't use
5362 // live-outs from the vector loop but from the scalar epilogue. Ignore them if
5363 // that is the case.
5364 bool RequiresScalarEpilogue = requiresScalarEpilogue(true);
5365 auto IsLiveOutDead = [this, RequiresScalarEpilogue](User *U) {
5366 return RequiresScalarEpilogue &&
5367 !TheLoop->contains(cast<Instruction>(U)->getParent());
5368 };
5369
5371 DFS.perform(LI);
5372 for (BasicBlock *BB : reverse(make_range(DFS.beginRPO(), DFS.endRPO())))
5373 for (Instruction &I : reverse(*BB)) {
5374 if (VecValuesToIgnore.contains(&I) || ValuesToIgnore.contains(&I))
5375 continue;
5376
5377 // Add instructions that would be trivially dead and are only used by
5378 // values already ignored to DeadOps to seed worklist.
5380 all_of(I.users(), [this, IsLiveOutDead](User *U) {
5381 return VecValuesToIgnore.contains(U) ||
5382 ValuesToIgnore.contains(U) || IsLiveOutDead(U);
5383 }))
5384 DeadOps.push_back(&I);
5385
5386 // For interleave groups, we only create a pointer for the start of the
5387 // interleave group. Queue up addresses of group members except the insert
5388 // position for further processing.
5389 if (isAccessInterleaved(&I)) {
5390 auto *Group = getInterleavedAccessGroup(&I);
5391 if (Group->getInsertPos() == &I)
5392 continue;
5393 Value *PointerOp = getLoadStorePointerOperand(&I);
5394 DeadInterleavePointerOps.push_back(PointerOp);
5395 }
5396
5397 // Queue branches for analysis. They are dead, if their successors only
5398 // contain dead instructions.
5399 if (isa<CondBrInst>(&I))
5400 DeadOps.push_back(&I);
5401 }
5402
5403 // Mark ops feeding interleave group members as free, if they are only used
5404 // by other dead computations.
5405 for (unsigned I = 0; I != DeadInterleavePointerOps.size(); ++I) {
5406 auto *Op = dyn_cast<Instruction>(DeadInterleavePointerOps[I]);
5407 if (!Op || !TheLoop->contains(Op) || any_of(Op->users(), [this](User *U) {
5408 Instruction *UI = cast<Instruction>(U);
5409 return !VecValuesToIgnore.contains(U) &&
5410 (!isAccessInterleaved(UI) ||
5411 getInterleavedAccessGroup(UI)->getInsertPos() == UI);
5412 }))
5413 continue;
5414 VecValuesToIgnore.insert(Op);
5415 append_range(DeadInterleavePointerOps, Op->operands());
5416 }
5417
5418 // Mark ops that would be trivially dead and are only used by ignored
5419 // instructions as free.
5420 BasicBlock *Header = TheLoop->getHeader();
5421
5422 // Returns true if the block contains only dead instructions. Such blocks will
5423 // be removed by VPlan-to-VPlan transforms and won't be considered by the
5424 // VPlan-based cost model, so skip them in the legacy cost-model as well.
5425 auto IsEmptyBlock = [this](BasicBlock *BB) {
5426 return all_of(*BB, [this](Instruction &I) {
5427 return ValuesToIgnore.contains(&I) || VecValuesToIgnore.contains(&I) ||
5429 });
5430 };
5431 for (unsigned I = 0; I != DeadOps.size(); ++I) {
5432 auto *Op = dyn_cast<Instruction>(DeadOps[I]);
5433
5434 // Check if the branch should be considered dead.
5435 if (auto *Br = dyn_cast_or_null<CondBrInst>(Op)) {
5436 BasicBlock *ThenBB = Br->getSuccessor(0);
5437 BasicBlock *ElseBB = Br->getSuccessor(1);
5438 // Don't considers branches leaving the loop for simplification.
5439 if (!TheLoop->contains(ThenBB) || !TheLoop->contains(ElseBB))
5440 continue;
5441 bool ThenEmpty = IsEmptyBlock(ThenBB);
5442 bool ElseEmpty = IsEmptyBlock(ElseBB);
5443 if ((ThenEmpty && ElseEmpty) ||
5444 (ThenEmpty && ThenBB->getSingleSuccessor() == ElseBB &&
5445 ElseBB->phis().empty()) ||
5446 (ElseEmpty && ElseBB->getSingleSuccessor() == ThenBB &&
5447 ThenBB->phis().empty())) {
5448 VecValuesToIgnore.insert(Br);
5449 DeadOps.push_back(Br->getCondition());
5450 }
5451 continue;
5452 }
5453
5454 // Skip any op that shouldn't be considered dead.
5455 if (!Op || !TheLoop->contains(Op) ||
5456 (isa<PHINode>(Op) && Op->getParent() == Header) ||
5458 any_of(Op->users(), [this, IsLiveOutDead](User *U) {
5459 return !VecValuesToIgnore.contains(U) &&
5460 !ValuesToIgnore.contains(U) && !IsLiveOutDead(U);
5461 }))
5462 continue;
5463
5464 // If all of Op's users are in ValuesToIgnore, add it to ValuesToIgnore
5465 // which applies for both scalar and vector versions. Otherwise it is only
5466 // dead in vector versions, so only add it to VecValuesToIgnore.
5467 if (all_of(Op->users(),
5468 [this](User *U) { return ValuesToIgnore.contains(U); }))
5469 ValuesToIgnore.insert(Op);
5470
5471 VecValuesToIgnore.insert(Op);
5472 append_range(DeadOps, Op->operands());
5473 }
5474
5475 // Ignore type-promoting instructions we identified during reduction
5476 // detection.
5477 for (const auto &Reduction : Legal->getReductionVars()) {
5478 const RecurrenceDescriptor &RedDes = Reduction.second;
5479 const SmallPtrSetImpl<Instruction *> &Casts = RedDes.getCastInsts();
5480 VecValuesToIgnore.insert_range(Casts);
5481 }
5482 // Ignore type-casting instructions we identified during induction
5483 // detection.
5484 for (const auto &Induction : Legal->getInductionVars()) {
5485 const InductionDescriptor &IndDes = Induction.second;
5486 VecValuesToIgnore.insert_range(IndDes.getCastInsts());
5487 }
5488}
5489
5490void LoopVectorizationPlanner::plan(ElementCount UserVF, unsigned UserIC) {
5491 CM.collectValuesToIgnore();
5492 Config.collectElementTypesForWidening(&CM.ValuesToIgnore);
5493
5494 FixedScalableVFPair MaxFactors = CM.computeMaxVF(UserVF, UserIC);
5495 if (!MaxFactors) // Cases that should not to be vectorized nor interleaved.
5496 return;
5497
5498 Config.collectInLoopReductions();
5499 // Cases that may be vectorized may be optimized by unit stride predicates.
5500 // TODO: Currently unit stride predicates are added unconditionally, even if
5501 // they are not used for the selected VF (e.g. when only interleaving).
5502 if (MaxFactors.FixedVF.isVector() || MaxFactors.ScalableVF.isVector())
5503 Legal->collectUnitStridePredicates();
5504
5505 auto VPlan1 = tryToBuildVPlan1();
5506 if (!VPlan1)
5507 return;
5508
5509 if (!OrigLoop->isInnermost()) {
5510 // For outer loops, computeMaxVF returns a single non-scalar VF; build a
5511 // plan for that VF only.
5512 ElementCount VF =
5513 MaxFactors.FixedVF ? MaxFactors.FixedVF : MaxFactors.ScalableVF;
5514 buildVPlans(*VPlan1, VF, VF);
5516 return;
5517 }
5518
5519 // Compute the minimal bitwidths required for integer operations in the loop
5520 // for later use by the cost model.
5521 Config.computeMinimalBitwidths();
5522
5523 // Invalidate interleave groups if all blocks of loop will be predicated.
5524 if (CM.blockNeedsPredicationForAnyReason(OrigLoop->getHeader()) &&
5526 LLVM_DEBUG(
5527 dbgs()
5528 << "LV: Invalidate all interleaved groups due to fold-tail by masking "
5529 "which requires masked-interleaved support.\n");
5530 if (CM.InterleaveInfo.invalidateGroups())
5531 // Invalidating interleave groups also requires invalidating all decisions
5532 // based on them, which includes widening decisions and uniform and scalar
5533 // values.
5534 CM.invalidateCostModelingDecisions();
5535 }
5536
5537 if (CM.foldTailByMasking())
5538 Legal->prepareToFoldTailByMasking();
5539
5540 ElementCount MaxUserVF =
5541 UserVF.isScalable() ? MaxFactors.ScalableVF : MaxFactors.FixedVF;
5542 if (UserVF) {
5543 if (!ElementCount::isKnownLE(UserVF, MaxUserVF)) {
5545 "UserVF ignored because it may be larger than the maximal safe VF",
5546 "InvalidUserVF", ORE, OrigLoop);
5547 } else {
5549 "VF needs to be a power of two");
5550 // Collect the instructions (and their associated costs) that will be more
5551 // profitable to scalarize.
5552 CM.collectNonVectorizedAndSetWideningDecisions(UserVF);
5554 if (EpilogueUserVF.isVector() &&
5555 ElementCount::isKnownLT(EpilogueUserVF, UserVF)) {
5556 CM.collectNonVectorizedAndSetWideningDecisions(EpilogueUserVF);
5557 buildVPlans(*VPlan1, EpilogueUserVF, EpilogueUserVF);
5558 }
5559 buildVPlans(*VPlan1, UserVF, UserVF);
5560 if (!VPlans.empty() && VPlans.back()->getSingleVF() == UserVF) {
5561 // For scalar VF, skip VPlan cost check as VPlan cost is designed for
5562 // vector VFs only.
5563 if (UserVF.isScalar() ||
5564 cost(*VPlans.back(), UserVF, /*RU=*/nullptr).isValid()) {
5565 LLVM_DEBUG(dbgs() << "LV: Using user VF " << UserVF << ".\n");
5567 return;
5568 }
5569 }
5570 VPlans.clear();
5571 reportVectorizationInfo("UserVF ignored because of invalid costs.",
5572 "InvalidCost", ORE, OrigLoop);
5573 }
5574 }
5575
5576 // Collect the Vectorization Factor Candidates.
5577 SmallVector<ElementCount> VFCandidates;
5578 for (auto VF = ElementCount::getFixed(1);
5579 ElementCount::isKnownLE(VF, MaxFactors.FixedVF); VF *= 2)
5580 VFCandidates.push_back(VF);
5581 for (auto VF = ElementCount::getScalable(1);
5582 ElementCount::isKnownLE(VF, MaxFactors.ScalableVF); VF *= 2)
5583 VFCandidates.push_back(VF);
5584
5585 for (const auto &VF : VFCandidates) {
5586 // Collect Uniform and Scalar instructions after vectorization with VF.
5587 CM.collectNonVectorizedAndSetWideningDecisions(VF);
5588 }
5589
5590 buildVPlans(*VPlan1, ElementCount::getFixed(1), MaxFactors.FixedVF);
5591 buildVPlans(*VPlan1, ElementCount::getScalable(1), MaxFactors.ScalableVF);
5592
5594}
5595
5597 ElementCount VF) const {
5598 InstructionCost Cost = CM.getInstructionCost(UI, VF);
5599 if (Cost.isValid() && ForceTargetInstructionCost.getNumOccurrences())
5601 return Cost;
5602}
5603
5604bool VPCostContext::skipCostComputation(Instruction *UI, bool IsVector) const {
5605 return CM.ValuesToIgnore.contains(UI) ||
5606 (IsVector && CM.VecValuesToIgnore.contains(UI)) ||
5607 SkipCostComputation.contains(UI);
5608}
5609
5615
5617 return CM.getPredBlockCostDivisor(CostKind, BB);
5618}
5619
5621 return CM.isScalarWithPredication(I, VF) ||
5622 CM.isUniformAfterVectorization(I, VF) || CM.isForcedScalar(I, VF) ||
5623 (VF.isVector() && CM.isProfitableToScalarize(I, VF));
5624}
5625
5627 return CM.isMaskRequired(I);
5628}
5629
5631LoopVectorizationPlanner::precomputeCosts(VPlan &Plan, ElementCount VF,
5632 VPCostContext &CostCtx) const {
5634 // Cost modeling for inductions is inaccurate in the legacy cost model
5635 // compared to the recipes that are generated. To match here initially during
5636 // VPlan cost model bring up directly use the induction costs from the legacy
5637 // cost model. Note that we do this as pre-processing; the VPlan may not have
5638 // any recipes associated with the original induction increment instruction
5639 // and may replace truncates with VPWidenIntOrFpInductionRecipe. We precompute
5640 // the cost of induction phis and increments (both that are represented by
5641 // recipes and those that are not), to avoid distinguishing between them here,
5642 // and skip all recipes that represent induction phis and increments (the
5643 // former case) later on, if they exist, to avoid counting them twice.
5644 // Similarly we pre-compute the cost of any optimized truncates.
5645 // TODO: Switch to more accurate costing based on VPlan.
5646 for (const auto &[IV, IndDesc] : Legal->getInductionVars()) {
5648 IV->getIncomingValueForBlock(OrigLoop->getLoopLatch()));
5649 SmallVector<Instruction *> IVInsts = {IVInc};
5650 for (unsigned I = 0; I != IVInsts.size(); I++) {
5651 for (Value *Op : IVInsts[I]->operands()) {
5652 auto *OpI = dyn_cast<Instruction>(Op);
5653 if (Op == IV || !OpI || !OrigLoop->contains(OpI) || !Op->hasOneUse())
5654 continue;
5655 IVInsts.push_back(OpI);
5656 }
5657 }
5658 IVInsts.push_back(IV);
5659 for (User *U : IV->users()) {
5660 auto *CI = cast<Instruction>(U);
5661 if (!CostCtx.CM.isOptimizableIVTruncate(CI, VF))
5662 continue;
5663 IVInsts.push_back(CI);
5664 }
5665
5666 // If the vector loop gets executed exactly once with the given VF, ignore
5667 // the costs of comparison and induction instructions, as they'll get
5668 // simplified away.
5669 // TODO: Remove this code after stepping away from the legacy cost model and
5670 // adding code to simplify VPlans before calculating their costs.
5671 auto TC = getSmallConstantTripCount(PSE.getSE(), OrigLoop);
5672 if (TC == VF && !hasTailFolded(Plan))
5673 addFullyUnrolledInstructionsToIgnore(OrigLoop, Legal->getInductionVars(),
5674 CostCtx.SkipCostComputation);
5675
5676 for (Instruction *IVInst : IVInsts) {
5677 if (CostCtx.skipCostComputation(IVInst, VF.isVector()))
5678 continue;
5679 InstructionCost InductionCost = CostCtx.getLegacyCost(IVInst, VF);
5680 LLVM_DEBUG({
5681 dbgs() << "Cost of " << InductionCost << " for VF " << VF
5682 << ": induction instruction " << *IVInst << "\n";
5683 });
5684 Cost += InductionCost;
5685 CostCtx.SkipCostComputation.insert(IVInst);
5686 }
5687 }
5688
5689 // Pre-compute the costs for branches except for the backedge, as the number
5690 // of replicate regions in a VPlan may not directly match the number of
5691 // branches, which would lead to different decisions.
5692 // TODO: Compute cost of branches for each replicate region in the VPlan,
5693 // which is more accurate than the legacy cost model.
5694 for (BasicBlock *BB : OrigLoop->blocks()) {
5695 if (CostCtx.skipCostComputation(BB->getTerminator(), VF.isVector()))
5696 continue;
5697 CostCtx.SkipCostComputation.insert(BB->getTerminator());
5698 if (BB == OrigLoop->getLoopLatch())
5699 continue;
5700 auto BranchCost = CostCtx.getLegacyCost(BB->getTerminator(), VF);
5701 Cost += BranchCost;
5702 }
5703
5704 // Don't apply special costs when instruction cost is forced to make sure the
5705 // forced cost is used for each recipe.
5706 if (ForceTargetInstructionCost.getNumOccurrences())
5707 return Cost;
5708
5709 // Pre-compute costs for instructions that are forced-scalar or profitable to
5710 // scalarize. For most such instructions, their scalarization costs are
5711 // accounted for here using the legacy cost model. However, some opcodes
5712 // are excluded from these precomputed scalarization costs and are instead
5713 // modeled later by the VPlan cost model (see UseVPlanCostModel below).
5714 for (Instruction *ForcedScalar : CM.ForcedScalars[VF]) {
5715 if (CostCtx.skipCostComputation(ForcedScalar, VF.isVector()))
5716 continue;
5717 CostCtx.SkipCostComputation.insert(ForcedScalar);
5718 InstructionCost ForcedCost = CostCtx.getLegacyCost(ForcedScalar, VF);
5719 LLVM_DEBUG({
5720 dbgs() << "Cost of " << ForcedCost << " for VF " << VF
5721 << ": forced scalar " << *ForcedScalar << "\n";
5722 });
5723 Cost += ForcedCost;
5724 }
5725
5726 auto UseVPlanCostModel = [](Instruction *I) -> bool {
5727 switch (I->getOpcode()) {
5728 case Instruction::SDiv:
5729 case Instruction::UDiv:
5730 case Instruction::SRem:
5731 case Instruction::URem:
5732 return true;
5733 default:
5734 return false;
5735 }
5736 };
5737 for (const auto &[Scalarized, ScalarCost] : CM.InstsToScalarize[VF]) {
5738 if (UseVPlanCostModel(Scalarized) ||
5739 CostCtx.skipCostComputation(Scalarized, VF.isVector()))
5740 continue;
5741 CostCtx.SkipCostComputation.insert(Scalarized);
5742 LLVM_DEBUG({
5743 dbgs() << "Cost of " << ScalarCost << " for VF " << VF
5744 << ": profitable to scalarize " << *Scalarized << "\n";
5745 });
5746 Cost += ScalarCost;
5747 }
5748
5749 return Cost;
5750}
5751
5752InstructionCost LoopVectorizationPlanner::cost(VPlan &Plan, ElementCount VF,
5753 VPRegisterUsage *RU) const {
5754 VPCostContext CostCtx(CM.TTI, *CM.TLI, Plan, CM, Config.CostKind, PSE,
5755 OrigLoop);
5756 InstructionCost Cost = precomputeCosts(Plan, VF, CostCtx);
5757
5758 // Now compute and add the VPlan-based cost.
5759 Cost += Plan.cost(VF, CostCtx);
5760
5761 // Add the cost of spills due to excess register usage
5762 if (RU && Config.shouldConsiderRegPressureForVF(VF))
5763 Cost += RU->spillCost(CM.TTI, Config.CostKind, ForceTargetNumVectorRegs);
5764
5765#ifndef NDEBUG
5766 unsigned EstimatedWidth =
5767 estimateElementCount(VF, Config.getVScaleForTuning());
5768 LLVM_DEBUG(dbgs() << "Cost for VF " << VF << ": " << Cost
5769 << " (Estimated cost per lane: ");
5770 if (Cost.isValid()) {
5771 APFloat CostPerLane(APFloat::IEEEdouble());
5772 APFloat EstimatedWidthAsAPFloat(APFloat::IEEEdouble());
5773 (void)CostPerLane.convertFromAPInt(APInt(64, (uint64_t)Cost.getValue()),
5774 false, APFloat::rmTowardZero);
5775 (void)EstimatedWidthAsAPFloat.convertFromAPInt(
5776 APInt(64, (uint64_t)EstimatedWidth), false, APFloat::rmTowardZero);
5777 (void)CostPerLane.divide(EstimatedWidthAsAPFloat, APFloat::rmTowardZero);
5778
5779 SmallString<16> Str;
5780 CostPerLane.toString(Str, 3);
5781 LLVM_DEBUG(dbgs() << Str);
5782 } else /* No point dividing an invalid cost - it will still be invalid */
5783 LLVM_DEBUG(dbgs() << "Invalid");
5784 LLVM_DEBUG(dbgs() << ")\n");
5785#endif
5786 return Cost;
5787}
5788
5789std::pair<VectorizationFactor, VPlan *>
5791 if (VPlans.empty())
5792 return {VectorizationFactor::Disabled(), nullptr};
5793 // If there is a single VPlan with a single VF, return it directly.
5794 VPlan &FirstPlan = *VPlans[0];
5795
5796 ElementCount UserVF = Hints.getWidth();
5797 if (VPlans.size() == 1) {
5798 // For outer loops, the plan has a single vector VF determined by the
5799 // heuristic.
5800 assert((FirstPlan.hasScalarVFOnly() || hasPlanWithVF(UserVF) ||
5801 FirstPlan.isOuterLoop()) &&
5802 "must have a single scalar VF, UserVF or an outer loop");
5803 return {VectorizationFactor(FirstPlan.getSingleVF(), 0, 0), &FirstPlan};
5804 }
5805
5806 if (hasPlanWithVF(UserVF) && hasForcedEpilogueVF()) {
5807 assert(VPlans.size() == 2 && "Must have exactly 2 VPlans built");
5808 assert(VPlans[0]->getSingleVF() == EpilogueVectorizationForceVF &&
5809 "expected first plan to be for the forced epilogue VF");
5810 assert(VPlans[1]->getSingleVF() == UserVF &&
5811 "expected second plan to be for the forced UserVF");
5812 return {VectorizationFactor(UserVF, 0, 0), VPlans[1].get()};
5813 }
5814
5815 LLVM_DEBUG(dbgs() << "LV: Computing best VF using cost kind: "
5816 << (Config.CostKind == TTI::TCK_RecipThroughput
5817 ? "Reciprocal Throughput\n"
5818 : Config.CostKind == TTI::TCK_Latency
5819 ? "Instruction Latency\n"
5820 : Config.CostKind == TTI::TCK_CodeSize ? "Code Size\n"
5821 : Config.CostKind == TTI::TCK_SizeAndLatency
5822 ? "Code Size and Latency\n"
5823 : "Unknown\n"));
5824
5826 assert(FirstPlan.hasVF(ScalarVF) &&
5827 "More than a single plan/VF w/o any plan having scalar VF");
5828
5829 // TODO: Compute scalar cost using VPlan-based cost model.
5830 InstructionCost ScalarCost = CM.expectedCost(ScalarVF);
5831 LLVM_DEBUG(dbgs() << "LV: Scalar loop costs: " << ScalarCost << ".\n");
5832 VectorizationFactor ScalarFactor(ScalarVF, ScalarCost, ScalarCost);
5833 VectorizationFactor BestFactor = ScalarFactor;
5834
5835 bool ForceVectorization = Hints.getForce() == LoopVectorizeHints::FK_Enabled;
5836 if (ForceVectorization) {
5837 // Ignore scalar width, because the user explicitly wants vectorization.
5838 // Initialize cost to max so that VF = 2 is, at least, chosen during cost
5839 // evaluation.
5840 BestFactor.Cost = InstructionCost::getMax();
5841 }
5842
5843 VPlan *PlanForBestVF = &FirstPlan;
5844
5845 for (auto &P : VPlans) {
5846 ArrayRef<ElementCount> VFs(P->vectorFactors().begin(),
5847 P->vectorFactors().end());
5848
5850 bool ConsiderRegPressure = any_of(VFs, [this](ElementCount VF) {
5851 return Config.shouldConsiderRegPressureForVF(VF);
5852 });
5854 RUs = calculateRegisterUsageForPlan(*P, VFs, TTI, CM.ValuesToIgnore);
5855
5856 for (unsigned I = 0; I < VFs.size(); I++) {
5857 ElementCount VF = VFs[I];
5858 if (VF.isScalar())
5859 continue;
5860 if (!ForceVectorization && !willGenerateVectors(*P, VF, TTI)) {
5861 LLVM_DEBUG(
5862 dbgs()
5863 << "LV: Not considering vector loop of width " << VF
5864 << " because it will not generate any vector instructions.\n");
5865 continue;
5866 }
5867 if (Config.OptForSize && !ForceVectorization && hasReplicatorRegion(*P)) {
5868 LLVM_DEBUG(
5869 dbgs()
5870 << "LV: Not considering vector loop of width " << VF
5871 << " because it would cause replicated blocks to be generated,"
5872 << " which isn't allowed when optimizing for size.\n");
5873 continue;
5874 }
5875
5877 cost(*P, VF, ConsiderRegPressure ? &RUs[I] : nullptr);
5878 VectorizationFactor CurrentFactor(VF, Cost, ScalarCost);
5879
5880 if (isMoreProfitable(CurrentFactor, BestFactor, P->hasScalarTail())) {
5881 BestFactor = CurrentFactor;
5882 PlanForBestVF = P.get();
5883 }
5884
5885 // If profitable add it to ProfitableVF list.
5886 if (isMoreProfitable(CurrentFactor, ScalarFactor, P->hasScalarTail()))
5887 ProfitableVFs.push_back(CurrentFactor);
5888 }
5889 }
5890
5891 VPlan &BestPlan = *PlanForBestVF;
5892
5893 assert((BestFactor.Width.isScalar() || BestFactor.ScalarCost > 0) &&
5894 "when vectorizing, the scalar cost must be computed.");
5895
5896 LLVM_DEBUG(dbgs() << "LV: Selecting VF: " << BestFactor.Width << ".\n");
5897 return {BestFactor, &BestPlan};
5898}
5899
5901 ElementCount BestVF, unsigned BestUF, VPlan &BestVPlan,
5903 EpilogueVectorizationKind EpilogueVecKind) {
5904 assert(BestVPlan.hasVF(BestVF) &&
5905 "Trying to execute plan with unsupported VF");
5906 assert(BestVPlan.hasUF(BestUF) &&
5907 "Trying to execute plan with unsupported UF");
5908 if (BestVPlan.hasEarlyExit())
5909 ++LoopsEarlyExitVectorized;
5910
5912 *PSE.getSE(), CM.TTI, Config.CostKind, BestVF, BestUF,
5913 CM.ValuesToIgnore);
5914 // TODO: Move to VPlan transform stage once the transition to the VPlan-based
5915 // cost model is complete for better cost estimates.
5916 RUN_VPLAN_PASS(VPlanTransforms::unrollByUF, BestVPlan, BestUF);
5920 bool HasBranchWeights =
5921 hasBranchWeightMD(*OrigLoop->getLoopLatch()->getTerminator());
5922 if (HasBranchWeights) {
5923 std::optional<unsigned> VScale = Config.getVScaleForTuning();
5925 BestVPlan, BestVF, VScale);
5926 }
5927
5928 if (CM.maskPartialAliasing()) {
5929 assert(BestVPlan.hasTailFolded() && "Expected tail folding to be enabled");
5931 *CM.Legal->getRuntimePointerChecking()->getDiffChecks(),
5932 HasBranchWeights);
5933 ++LoopsPartialAliasVectorized;
5934 }
5935
5936 // Retrieving VectorPH now when it's easier while VPlan still has Regions.
5937 VPBasicBlock *VectorPH = cast<VPBasicBlock>(BestVPlan.getVectorPreheader());
5938
5940 BestVF, BestUF, PSE);
5941 RUN_VPLAN_PASS(VPlanTransforms::optimizeForVFAndUF, BestVPlan, BestVF, BestUF,
5942 PSE);
5944 // Check if scalar epilogue is required, before simplifying constant branches.
5945 const bool RequiresScalarEpilogue = requiresScalarEpilogue(BestVPlan, BestVF);
5946 if (EpilogueVecKind == EpilogueVectorizationKind::None)
5948 /*OnlyLatches=*/false);
5949 if (BestVPlan.getEntry()->getSingleSuccessor() ==
5950 BestVPlan.getScalarPreheader()) {
5951 // TODO: The vector loop would be dead, should not even try to vectorize.
5952 ORE->emit([&]() {
5953 return OptimizationRemarkAnalysis(DEBUG_TYPE, "VectorizationDead",
5954 OrigLoop->getStartLoc(),
5955 OrigLoop->getHeader())
5956 << "Created vector loop never executes due to insufficient trip "
5957 "count.";
5958 });
5960 }
5961
5963
5965 // Convert the exit condition to AVLNext == 0 for EVL tail folded loops.
5967 // Regions are dissolved after optimizing for VF and UF, which completely
5968 // removes unneeded loop regions first.
5969 const bool HasTailFolded = hasTailFolded(BestVPlan);
5971 // Expand BranchOnTwoConds after dissolution, when latch has direct access to
5972 // its successors.
5974 // Convert loops with variable-length stepping after regions are dissolved.
5976 // Remove dead back-edges for single-iteration loops with BranchOnCond(true).
5977 // Only process loop latches to avoid removing edges from the middle block,
5978 // which may be needed for epilogue vectorization.
5979 VPlanTransforms::removeBranchOnConst(BestVPlan, /*OnlyLatches=*/true);
5981 std::optional<uint64_t> MaxRuntimeStep;
5982 if (auto MaxVScale = getMaxVScale(*CM.TheFunction, CM.TTI))
5983 MaxRuntimeStep = uint64_t(*MaxVScale) * BestVF.getKnownMinValue() * BestUF;
5984 assert((OrigLoop->getUniqueLatchExitBlock() || RequiresScalarEpilogue) &&
5985 "loops not exiting via the latch without required epilogue?");
5987 BestVPlan, VectorPH, HasTailFolded, RequiresScalarEpilogue,
5988 &BestVPlan.getVFxUF(), MaxRuntimeStep);
5989 VPlanTransforms::materializeFactors(BestVPlan, VectorPH, BestVF);
5990 // Limit expansions to VPInstruction to when not vectorizing the epilogue.
5991 // Currently this code path still relies on code re-using SCEVs expanded
5992 // directly to IR instructions.
5993 if (EpilogueVecKind == EpilogueVectorizationKind::None)
5994 VPlanTransforms::expandSCEVsToVPInstructions(BestVPlan, *PSE.getSE());
5995 VPlanTransforms::cse(BestVPlan);
5997 // Removing branches and incoming values may expose additional simplification
5998 // opportunities.
6000 /*OnlyLatches=*/EpilogueVecKind !=
6003 VPlanTransforms::simplifyKnownEVL(BestVPlan, BestVF, PSE);
6004
6005 // 0. Generate SCEV-dependent code in the entry, including TripCount, before
6006 // making any changes to the CFG.
6007 DenseMap<const SCEV *, Value *> ExpandedSCEVs =
6008 VPlanTransforms::expandSCEVs(BestVPlan, *PSE.getSE());
6009
6010 // Perform the actual loop transformation.
6011 VPTransformState State(&TTI, BestVF, LI, DT, ILV.AC, ILV.Builder, &BestVPlan,
6012 OrigLoop->getParentLoop());
6013
6014#ifdef EXPENSIVE_CHECKS
6015 assert(DT->verify(DominatorTree::VerificationLevel::Fast));
6016#endif
6017
6018 // 1. Set up the skeleton for vectorization, including vector pre-header and
6019 // middle block. The vector loop is created during VPlan execution.
6020 State.CFG.PrevBB = ILV.createVectorizedLoopSkeleton();
6021 if (VPBasicBlock *ScalarPH = BestVPlan.getScalarPreheader())
6022 replaceVPBBWithIRVPBB(ScalarPH, State.CFG.PrevBB->getSingleSuccessor(),
6023 &BestVPlan);
6025
6026 assert(verifyVPlanIsValid(BestVPlan) && "final VPlan is invalid");
6027
6028 // After vectorization, the exit blocks of the original loop will have
6029 // additional predecessors. Invalidate SCEVs for the exit phis in case SE
6030 // looked through single-entry phis.
6031 ScalarEvolution &SE = *PSE.getSE();
6032 for (VPIRBasicBlock *Exit : BestVPlan.getExitBlocks()) {
6033 if (!Exit->hasPredecessors())
6034 continue;
6035 for (VPRecipeBase &PhiR : Exit->phis())
6037 &cast<VPIRPhi>(PhiR).getIRPhi());
6038 }
6039 // Forget the original loop and block dispositions.
6040 SE.forgetLoop(OrigLoop);
6042
6044
6045 //===------------------------------------------------===//
6046 //
6047 // Notice: any optimization or new instruction that go
6048 // into the code below should also be implemented in
6049 // the cost-model.
6050 //
6051 //===------------------------------------------------===//
6052
6053 // Retrieve loop information before executing the plan, which may remove the
6054 // original loop, if it becomes unreachable.
6055 MDNode *LID = OrigLoop->getLoopID();
6056 unsigned OrigLoopInvocationWeight = 0;
6057 std::optional<unsigned> OrigAverageTripCount =
6058 getLoopEstimatedTripCount(OrigLoop, &OrigLoopInvocationWeight);
6059
6060 BestVPlan.execute(&State);
6061
6062 // 2.6. Maintain Loop Hints
6063 // Keep all loop hints from the original loop on the vector loop (we'll
6064 // replace the vectorizer-specific hints below).
6065 VPBasicBlock *HeaderVPBB = vputils::getFirstLoopHeader(BestVPlan, State.VPDT);
6066 // Add metadata to disable runtime unrolling a scalar loop when there
6067 // are no runtime checks about strides and memory. A scalar loop that is
6068 // rarely used is not worth unrolling.
6069 bool DisableRuntimeUnroll = !ILV.RTChecks.hasChecks() && !BestVF.isScalar();
6071 HeaderVPBB ? LI->getLoopFor(State.CFG.VPBB2IRBB.lookup(HeaderVPBB))
6072 : nullptr,
6073 HeaderVPBB, BestVPlan,
6074 EpilogueVecKind == EpilogueVectorizationKind::Epilogue, LID,
6075 OrigAverageTripCount, OrigLoopInvocationWeight,
6076 estimateElementCount(BestVF * BestUF, Config.getVScaleForTuning()),
6077 DisableRuntimeUnroll);
6078
6079 // 3. Fix the vectorized code: take care of header phi's, live-outs,
6080 // predication, updating analyses.
6081 ILV.fixVectorizedLoop(State);
6082
6084
6085 return ExpandedSCEVs;
6086}
6087
6088//===--------------------------------------------------------------------===//
6089// EpilogueVectorizerMainLoop
6090//===--------------------------------------------------------------------===//
6091
6093 LLVM_DEBUG({
6094 dbgs() << "Create Skeleton for epilogue vectorized loop (first pass)\n"
6095 << "Main Loop VF:" << EPI.MainLoopVF
6096 << ", Main Loop UF:" << EPI.MainLoopUF
6097 << ", Epilogue Loop VF:" << EPI.EpilogueVF
6098 << ", Epilogue Loop UF:" << EPI.EpilogueUF << "\n";
6099 });
6100}
6101
6104 dbgs() << "intermediate fn:\n"
6105 << *OrigLoop->getHeader()->getParent() << "\n";
6106 });
6107}
6108
6109//===--------------------------------------------------------------------===//
6110// EpilogueVectorizerEpilogueLoop
6111//===--------------------------------------------------------------------===//
6112
6113/// This function creates a new scalar preheader, using the previous one as
6114/// entry block to the epilogue VPlan. The minimum iteration check is being
6115/// represented in VPlan.
6117 BasicBlock *NewScalarPH = createScalarPreheader("vec.epilog.");
6118 BasicBlock *OriginalScalarPH = NewScalarPH->getSinglePredecessor();
6119 OriginalScalarPH->setName("vec.epilog.iter.check");
6120 VPIRBasicBlock *NewEntry = Plan.createVPIRBasicBlock(OriginalScalarPH);
6121 VPBasicBlock *OldEntry = Plan.getEntry();
6122 for (auto &R : make_early_inc_range(*OldEntry)) {
6123 // Skip moving VPIRInstructions (including VPIRPhis), which are unmovable by
6124 // defining.
6125 if (isa<VPIRInstruction>(&R))
6126 continue;
6127 R.moveBefore(*NewEntry, NewEntry->end());
6128 }
6129
6130 VPBlockUtils::reassociateBlocks(OldEntry, NewEntry);
6131 Plan.setEntry(NewEntry);
6132 // OldEntry is now dead and will be cleaned up when the plan gets destroyed.
6133
6134 return OriginalScalarPH;
6135}
6136
6138 LLVM_DEBUG({
6139 dbgs() << "Create Skeleton for epilogue vectorized loop (second pass)\n"
6140 << "Epilogue Loop VF:" << EPI.EpilogueVF
6141 << ", Epilogue Loop UF:" << EPI.EpilogueUF << "\n";
6142 });
6143}
6144
6147 dbgs() << "final fn:\n" << *OrigLoop->getHeader()->getParent() << "\n";
6148 });
6149}
6150
6152 return CM.isPredicatedInst(I);
6153}
6154
6156 return CM.TTI.prefersVectorizedAddressing();
6157}
6158
6160 VFRange &Range) {
6161 assert((VPI->getOpcode() == Instruction::Load ||
6162 VPI->getOpcode() == Instruction::Store) &&
6163 "Must be called with either a load or store");
6165
6166 auto WillWiden = [&](ElementCount VF) -> bool {
6168 CM.getWideningDecision(I, VF);
6170 "CM decision should be taken at this point.");
6172 return true;
6173 if (CM.isScalarAfterVectorization(I, VF) ||
6174 CM.isProfitableToScalarize(I, VF))
6175 return false;
6177 };
6178
6180 return nullptr;
6181
6182 // If a mask is not required, drop it - use unmasked version for safe loads.
6183 // TODO: Determine if mask is needed in VPlan.
6184 VPValue *Mask = CM.isMaskRequired(I) ? VPI->getMask() : nullptr;
6185
6186 // Determine if the pointer operand of the access is either consecutive or
6187 // reverse consecutive.
6189 CM.getWideningDecision(I, Range.Start);
6191 bool Consecutive =
6193
6194 VPValue *Ptr = VPI->getOpcode() == Instruction::Load ? VPI->getOperand(0)
6195 : VPI->getOperand(1);
6196 if (Consecutive) {
6197 Builder.setInsertPoint(VPI);
6198 Ptr = Builder.createConsecutiveVectorPointer(Ptr, getLoadStoreType(I),
6199 Reverse, VPI->getDebugLoc());
6200 }
6201
6202 if (Reverse && Mask)
6203 Mask = Builder.createNaryOp(VPInstruction::Reverse, Mask, I->getDebugLoc());
6204
6205 if (VPI->getOpcode() == Instruction::Load) {
6206 auto *Load = cast<LoadInst>(I);
6207 auto *LoadR = new VPWidenLoadRecipe(*Load, Ptr, Mask, Consecutive, *VPI,
6208 Load->getDebugLoc());
6209 if (Reverse) {
6210 Builder.insert(LoadR);
6211 return new VPInstruction(VPInstruction::Reverse, LoadR, {}, {},
6212 LoadR->getDebugLoc());
6213 }
6214 return LoadR;
6215 }
6216
6217 StoreInst *Store = cast<StoreInst>(I);
6218 VPValue *StoredVal = VPI->getOperand(0);
6219 if (Reverse)
6220 StoredVal = Builder.createNaryOp(VPInstruction::Reverse, StoredVal,
6221 Store->getDebugLoc());
6222 return new VPWidenStoreRecipe(*Store, Ptr, StoredVal, Mask, Consecutive, *VPI,
6223 Store->getDebugLoc());
6224}
6225
6227VPRecipeBuilder::tryToOptimizeInductionTruncate(VPInstruction *VPI,
6228 VFRange &Range) {
6229 auto *I = cast<TruncInst>(VPI->getUnderlyingInstr());
6230 // Optimize the special case where the source is a constant integer
6231 // induction variable. Notice that we can only optimize the 'trunc' case
6232 // because (a) FP conversions lose precision, (b) sext/zext may wrap, and
6233 // (c) other casts depend on pointer size.
6234
6235 // Determine whether \p K is a truncation based on an induction variable that
6236 // can be optimized.
6239 I),
6240 Range))
6241 return nullptr;
6242
6244 VPI->getOperand(0)->getDefiningRecipe());
6245 PHINode *Phi = WidenIV->getPHINode();
6246 VPIRValue *Start = WidenIV->getStartValue();
6247 const InductionDescriptor &IndDesc = WidenIV->getInductionDescriptor();
6248
6249 // Wrap flags from the original induction do not apply to the truncated type,
6250 // so do not propagate them.
6251 VPIRFlags Flags = VPIRFlags::WrapFlagsTy(false, false);
6252 VPValue *Step =
6255 Phi, Start, Step, &Plan.getVF(), IndDesc, I, Flags, VPI->getDebugLoc());
6256}
6257
6258bool VPRecipeBuilder::shouldWiden(Instruction *I, VFRange &Range) const {
6260 "Instruction should have been handled earlier");
6261 // Instruction should be widened, unless it is scalar after vectorization,
6262 // scalarization is profitable or it is predicated.
6263 auto WillScalarize = [this, I](ElementCount VF) -> bool {
6264 return CM.isScalarAfterVectorization(I, VF) ||
6265 CM.isProfitableToScalarize(I, VF) ||
6266 CM.isScalarWithPredication(I, VF);
6267 };
6269 Range);
6270}
6271
6272VPRecipeWithIRFlags *VPRecipeBuilder::tryToWiden(VPInstruction *VPI) {
6273 auto *I = VPI->getUnderlyingInstr();
6274 switch (VPI->getOpcode()) {
6275 default:
6276 return nullptr;
6277 case Instruction::SDiv:
6278 case Instruction::UDiv:
6279 case Instruction::SRem:
6280 case Instruction::URem:
6281 // If not provably safe, use a masked intrinsic.
6282 if (CM.isPredicatedInst(I))
6283 return new VPWidenIntrinsicRecipe(
6285 I->getType(), {}, {}, VPI->getDebugLoc());
6286 [[fallthrough]];
6287 case Instruction::Add:
6288 case Instruction::And:
6289 case Instruction::AShr:
6290 case Instruction::FAdd:
6291 case Instruction::FCmp:
6292 case Instruction::FDiv:
6293 case Instruction::FMul:
6294 case Instruction::FNeg:
6295 case Instruction::FRem:
6296 case Instruction::FSub:
6297 case Instruction::ICmp:
6298 case Instruction::LShr:
6299 case Instruction::Mul:
6300 case Instruction::Or:
6301 case Instruction::Select:
6302 case Instruction::Shl:
6303 case Instruction::Sub:
6304 case Instruction::Xor:
6305 case Instruction::Freeze:
6306 return new VPWidenRecipe(*I, VPI->operandsWithoutMask(), *VPI, *VPI,
6307 VPI->getDebugLoc());
6308 case Instruction::ExtractValue: {
6310 auto *EVI = cast<ExtractValueInst>(I);
6311 assert(EVI->getNumIndices() == 1 && "Expected one extractvalue index");
6312 unsigned Idx = EVI->getIndices()[0];
6313 NewOps.push_back(Plan.getConstantInt(32, Idx));
6314 return new VPWidenRecipe(*I, NewOps, *VPI, *VPI, VPI->getDebugLoc());
6315 }
6316 };
6317}
6318
6320 if (VPI->getOpcode() != Instruction::Store)
6321 return nullptr;
6322
6323 auto HistInfo =
6324 Legal->getHistogramInfo(cast<StoreInst>(VPI->getUnderlyingInstr()));
6325 if (!HistInfo)
6326 return nullptr;
6327
6328 const HistogramInfo *HI = *HistInfo;
6329 // FIXME: Support other operations.
6330 unsigned Opcode = HI->Update->getOpcode();
6331 assert((Opcode == Instruction::Add || Opcode == Instruction::Sub) &&
6332 "Histogram update operation must be an Add or Sub");
6333
6335 // Bucket address.
6336 HGramOps.push_back(VPI->getOperand(1));
6337 // Increment value.
6338 HGramOps.push_back(Plan.getOrAddLiveIn(HI->Update->getOperand(1)));
6339
6340 // In case of predicated execution (due to tail-folding, or conditional
6341 // execution, or both), pass the relevant mask.
6342 if (CM.isMaskRequired(HI->Store))
6343 HGramOps.push_back(VPI->getMask());
6344
6345 return new VPHistogramRecipe(Opcode, HGramOps, cast<VPIRMetadata>(*VPI),
6346 VPI->getDebugLoc());
6347}
6348
6350 VPInstruction *VPI, VPBuilder &FinalRedStoresBuilder) {
6351 StoreInst *SI;
6352 if ((SI = dyn_cast<StoreInst>(VPI->getUnderlyingInstr())) &&
6353 Legal->isInvariantAddressOfReduction(SI->getPointerOperand())) {
6354 // Only create recipe for the final invariant store of the reduction.
6355 if (Legal->isInvariantStoreOfReduction(SI)) {
6356 VPValue *Val = VPI->getOperand(0);
6357 VPValue *Addr = VPI->getOperand(1);
6358 // We need to store the exiting value of the reduction, so use the blend
6359 // if tail folded.
6360 if (auto *Blend = VPlanPatternMatch::findUserOf<VPBlendRecipe>(Val))
6361 Val = Blend;
6362 [[maybe_unused]] auto *Rdx =
6364 assert((!Rdx || Rdx->getBackedgeValue() == Val) &&
6365 "Store of reduction thats not the backedge value?");
6366 auto *Recipe = new VPReplicateRecipe(
6367 SI, {Val, Addr}, true /* IsUniform */, nullptr /*Mask*/, *VPI, *VPI,
6368 VPI->getDebugLoc());
6369 FinalRedStoresBuilder.insert(Recipe);
6370 }
6371 VPI->eraseFromParent();
6372 return true;
6373 }
6374
6375 return false;
6376}
6377
6379 VFRange &Range) {
6380 auto *I = VPI->getUnderlyingInstr();
6382 [&](ElementCount VF) { return CM.isUniformAfterVectorization(I, VF); },
6383 Range);
6384
6385 bool IsPredicated = CM.isPredicatedInst(I);
6386
6387 // Even if the instruction is not marked as uniform, there are certain
6388 // intrinsic calls that can be effectively treated as such, so we check for
6389 // them here. Conservatively, we only do this for scalable vectors, since
6390 // for fixed-width VFs we can always fall back on full scalarization.
6391 if (!IsUniform && Range.Start.isScalable() && isa<IntrinsicInst>(I)) {
6392 switch (cast<IntrinsicInst>(I)->getIntrinsicID()) {
6393 case Intrinsic::assume:
6394 case Intrinsic::lifetime_start:
6395 case Intrinsic::lifetime_end:
6396 // For scalable vectors if one of the operands is variant then we still
6397 // want to mark as uniform, which will generate one instruction for just
6398 // the first lane of the vector. We can't scalarize the call in the same
6399 // way as for fixed-width vectors because we don't know how many lanes
6400 // there are.
6401 //
6402 // The reasons for doing it this way for scalable vectors are:
6403 // 1. For the assume intrinsic generating the instruction for the first
6404 // lane is still be better than not generating any at all. For
6405 // example, the input may be a splat across all lanes.
6406 // 2. For the lifetime start/end intrinsics the pointer operand only
6407 // does anything useful when the input comes from a stack object,
6408 // which suggests it should always be uniform. For non-stack objects
6409 // the effect is to poison the object, which still allows us to
6410 // remove the call.
6411 IsUniform = true;
6412 break;
6413 default:
6414 break;
6415 }
6416 }
6417 VPValue *BlockInMask = nullptr;
6418 if (!IsPredicated) {
6419 // Finalize the recipe for Instr, first if it is not predicated.
6420 LLVM_DEBUG(dbgs() << "LV: Scalarizing:" << *I << "\n");
6421 } else {
6422 LLVM_DEBUG(dbgs() << "LV: Scalarizing and predicating:" << *I << "\n");
6423 // Instructions marked for predication are replicated and a mask operand is
6424 // added initially. Masked replicate recipes will later be placed under an
6425 // if-then construct to prevent side-effects. Generate recipes to compute
6426 // the block mask for this region.
6427 BlockInMask = VPI->getMask();
6428 }
6429
6430 // Note that there is some custom logic to mark some intrinsics as uniform
6431 // manually above for scalable vectors, which this assert needs to account for
6432 // as well.
6433 assert((Range.Start.isScalar() || !IsUniform || !IsPredicated ||
6434 (Range.Start.isScalable() && isa<IntrinsicInst>(I))) &&
6435 "Should not predicate a uniform recipe");
6436 if (IsUniform) {
6438 VPI->getOpcode(), VPI->operandsWithoutMask(), BlockInMask, *VPI, *VPI,
6439 VPI->getDebugLoc(), I);
6440 }
6441 auto *Recipe = new VPReplicateRecipe(I, VPI->operandsWithoutMask(),
6442 /*IsSingleScalar=*/false, BlockInMask,
6443 *VPI, *VPI, VPI->getDebugLoc());
6444 return Recipe;
6445}
6446
6449 VFRange &Range) {
6450 assert(!R->isPhi() && "phis must be handled earlier");
6451 // First, check for specific widening recipes that deal with optimizing
6452 // truncates and memory operations.
6453 auto *VPI = cast<VPInstruction>(R);
6454 assert(VPI->getOpcode() != Instruction::Call &&
6455 "Call should have been handled by makeCallWideningDecisions");
6456
6457 VPRecipeBase *Recipe;
6458 if (VPI->getOpcode() == Instruction::Trunc &&
6459 (Recipe = tryToOptimizeInductionTruncate(VPI, Range)))
6460 return Recipe;
6461
6462 // All widen recipes below deal only with VF > 1.
6464 [&](ElementCount VF) { return VF.isScalar(); }, Range))
6465 return nullptr;
6466
6467 Instruction *Instr = R->getUnderlyingInstr();
6468 assert(!is_contained({Instruction::Load, Instruction::Store},
6469 VPI->getOpcode()) &&
6470 "Should have been handled prior to this!");
6471
6472 if (!shouldWiden(Instr, Range))
6473 return nullptr;
6474
6475 if (VPI->getOpcode() == Instruction::GetElementPtr) {
6476 auto *GEP = cast<GetElementPtrInst>(Instr);
6477 return new VPWidenGEPRecipe(GEP->getSourceElementType(),
6478 VPI->operandsWithoutMask(), *VPI,
6479 VPI->getDebugLoc(), GEP);
6480 }
6481
6482 if (Instruction::isCast(VPI->getOpcode())) {
6483 auto *CI = cast<CastInst>(Instr);
6484 auto *CastR = cast<VPInstructionWithType>(VPI);
6485 return new VPWidenCastRecipe(CI->getOpcode(), VPI->getOperand(0),
6486 CastR->getResultType(), CI, *VPI, *VPI,
6487 VPI->getDebugLoc());
6488 }
6489
6490 return tryToWiden(VPI);
6491}
6492
6493// To allow RUN_VPLAN_PASS to print the VPlan after VF/UF independent
6494// optimizations.
6496
6497VPlanPtr LoopVectorizationPlanner::tryToBuildVPlan1() {
6498 bool IsInnerLoop = OrigLoop->isInnermost();
6499
6500 // Set up loop versioning for inner loops with memory runtime checks.
6501 // Outer loops don't have LoopAccessInfo since canVectorizeMemory() is not
6502 // called for them.
6503 std::optional<LoopVersioning> LVer;
6504 if (IsInnerLoop) {
6505 const LoopAccessInfo *LAI = Legal->getLAI();
6506 LVer.emplace(*LAI, LAI->getRuntimePointerChecking()->getChecks(), OrigLoop,
6507 LI, DT, PSE.getSE());
6508 if (!LAI->getRuntimePointerChecking()->getChecks().empty() &&
6510 // Only use noalias metadata when using memory checks guaranteeing no
6511 // overlap across all iterations.
6512 LVer->prepareNoAliasMetadata();
6513 }
6514 }
6515
6516 // Create initial base VPlan0, to serve as common starting point for all
6517 // candidates built later for specific VF ranges.
6518 auto VPlan0 = VPlanTransforms::buildVPlan0(OrigLoop, *LI,
6519 Legal->getWidestInductionType(),
6520 PSE, LVer ? &*LVer : nullptr);
6521
6522 VPDominatorTree VPDT(*VPlan0);
6523 if (const LoopAccessInfo *LAI = Legal->getLAI())
6525 LAI->getSymbolicStrides(), VPDT);
6528
6529 // Create recipes for header phis. For outer loops, reductions, recurrences
6530 // and in-loop reductions are empty since legality doesn't detect them.
6532 *OrigLoop, VPDT, Legal->getInductionVars(),
6533 Legal->getReductionVars(),
6534 Legal->getFixedOrderRecurrences(),
6535 Config.getInLoopReductions(), Hints.allowReordering())) {
6536 return nullptr;
6537 }
6538
6539 if (const LoopAccessInfo *LAI = Legal->getLAI())
6541 LAI->getSymbolicStrides(), VPDT);
6542
6543 // Add surviving induction predicates to PSE and check constraints.
6544 bool ForceVectorization = Hints.getForce() == LoopVectorizeHints::FK_Enabled;
6545 bool OptForSize =
6546 !ForceVectorization &&
6547 (CM.EpilogueLoweringStatus == CM_EpilogueNotAllowedOptSize ||
6548 CM.EpilogueLoweringStatus == CM_EpilogueNotAllowedLowTripLoop);
6549 unsigned SCEVCheckThreshold = ForceVectorization
6553 OptForSize, SCEVCheckThreshold, ORE, OrigLoop))
6554 return nullptr;
6555
6557
6558 // If we're vectorizing a loop with an uncountable exit, make sure that the
6559 // recipes are safe to handle.
6560 // TODO: Remove this once we can properly check the VPlan itself for both
6561 // the presence of an uncountable exit and the presence of stores in
6562 // the loop inside handleEarlyExits itself.
6564 if (Legal->hasUncountableEarlyExit())
6565 EEStyle = Legal->hasUncountableExitWithSideEffects()
6568
6570 OrigLoop, PSE, *DT, Legal->getAssumptionCache())) {
6571 return nullptr;
6572 }
6573
6575 getDebugLocFromInstOrOperands(Legal->getPrimaryInduction()));
6576 if (CM.foldTailByMasking())
6579
6580 return VPlan0;
6581}
6582
6583void LoopVectorizationPlanner::buildVPlans(VPlan &VPlan1, ElementCount MinVF,
6584 ElementCount MaxVF) {
6585 if (ElementCount::isKnownGT(MinVF, MaxVF))
6586 return;
6587
6588 auto MaxVFTimes2 = MaxVF * 2;
6589 for (ElementCount VF = MinVF; ElementCount::isKnownLT(VF, MaxVFTimes2);) {
6590 VFRange SubRange = {VF, MaxVFTimes2};
6591 auto Plan =
6592 tryToBuildVPlan(std::unique_ptr<VPlan>(VPlan1.duplicate()), SubRange);
6593 VF = SubRange.End;
6594
6595 if (!Plan)
6596 continue;
6597
6598 // Now optimize the initial VPlan.
6602 Config.getMinimalBitwidths());
6604 // TODO: try to put addExplicitVectorLength close to addActiveLaneMask
6605 if (CM.foldTailWithEVL()) {
6607 Config.getMaxSafeElements());
6609 }
6610
6611 if (auto P =
6613 VPlans.push_back(std::move(P));
6614
6615 TailFoldingStyle Style = CM.getTailFoldingStyle();
6617 useActiveLaneMask(Style),
6619
6621 assert(verifyVPlanIsValid(*Plan) && "VPlan is invalid");
6622 VPlans.push_back(std::move(Plan));
6623 }
6624}
6625
6626VPlanPtr LoopVectorizationPlanner::tryToBuildVPlan(VPlanPtr Plan,
6627 VFRange &Range) {
6628
6629 // For outer loops, the plan only needs basic recipe conversion and induction
6630 // live-out optimization; the full inner-loop recipe building below does not
6631 // apply (no widening decisions, interleave groups, reductions, etc.).
6632 if (Plan->isOuterLoop()) {
6633 for (ElementCount VF : Range)
6634 Plan->addVF(VF);
6636 *Plan, *TLI))
6637 return nullptr;
6639 return Plan;
6640 }
6641
6642 using namespace llvm::VPlanPatternMatch;
6643 SmallPtrSet<const InterleaveGroup<Instruction> *, 1> InterleaveGroups;
6644
6645 // ---------------------------------------------------------------------------
6646 // Build initial VPlan: Scan the body of the loop in a topological order to
6647 // visit each basic block after having visited its predecessor basic blocks.
6648 // ---------------------------------------------------------------------------
6649
6650 bool RequiresScalarEpilogueCheck =
6652 [this](ElementCount VF) {
6653 return !CM.requiresScalarEpilogue(VF.isVector());
6654 },
6655 Range);
6656 // Update the branch in the middle block if a scalar epilogue is required.
6657 VPBasicBlock *MiddleVPBB = Plan->getMiddleBlock();
6658 if (!RequiresScalarEpilogueCheck && MiddleVPBB->getNumSuccessors() == 2) {
6659 auto *BranchOnCond = cast<VPInstruction>(MiddleVPBB->getTerminator());
6660 assert(MiddleVPBB->getSuccessors()[1] == Plan->getScalarPreheader() &&
6661 "second successor must be scalar preheader");
6662 BranchOnCond->setOperand(0, Plan->getFalse());
6663 }
6664
6665 // Don't use getDecisionAndClampRange here, because we don't know the UF
6666 // so this function is better to be conservative, rather than to split
6667 // it up into different VPlans.
6668 // TODO: Consider using getDecisionAndClampRange here to split up VPlans.
6669 bool IVUpdateMayOverflow = false;
6670 for (ElementCount VF : Range)
6671 IVUpdateMayOverflow |= !isIndvarOverflowCheckKnownFalse(&CM, VF);
6672
6673 TailFoldingStyle Style = CM.getTailFoldingStyle();
6674 // Use NUW for the induction increment if we proved that it won't overflow in
6675 // the vector loop or when not folding the tail. In the later case, we know
6676 // that the canonical induction increment will not overflow as the vector trip
6677 // count is >= increment and a multiple of the increment.
6678 VPRegionBlock *LoopRegion = Plan->getVectorLoopRegion();
6679 bool HasNUW = !IVUpdateMayOverflow || Style == TailFoldingStyle::None;
6680 if (!HasNUW) {
6681 auto *IVInc =
6682 LoopRegion->getExitingBasicBlock()->getTerminator()->getOperand(0);
6683 assert(match(IVInc,
6684 m_VPInstruction<Instruction::Add>(
6685 m_Specific(LoopRegion->getCanonicalIV()), m_VPValue())) &&
6686 "Did not find the canonical IV increment");
6687 LoopRegion->clearCanonicalIVNUW(cast<VPInstruction>(IVInc));
6688 }
6689
6690 // ---------------------------------------------------------------------------
6691 // Pre-construction: record ingredients whose recipes we'll need to further
6692 // process after constructing the initial VPlan.
6693 // ---------------------------------------------------------------------------
6694
6695 // For each interleave group which is relevant for this (possibly trimmed)
6696 // Range, add it to the set of groups to be later applied to the VPlan and add
6697 // placeholders for its members' Recipes which we'll be replacing with a
6698 // single VPInterleaveRecipe.
6699 for (InterleaveGroup<Instruction> *IG : IAI.getInterleaveGroups()) {
6700 auto ApplyIG = [IG, this](ElementCount VF) -> bool {
6701 bool Result = (VF.isVector() && // Query is illegal for VF == 1
6702 CM.getWideningDecision(IG->getInsertPos(), VF) ==
6704 // For scalable vectors, the interleave factors must be <= 8 since we
6705 // require the (de)interleaveN intrinsics instead of shufflevectors.
6706 assert((!Result || !VF.isScalable() || IG->getFactor() <= 8) &&
6707 "Unsupported interleave factor for scalable vectors");
6708 return Result;
6709 };
6710 if (!getDecisionAndClampRange(ApplyIG, Range))
6711 continue;
6712 InterleaveGroups.insert(IG);
6713 }
6714
6715 // ---------------------------------------------------------------------------
6716 // Construct wide recipes and apply predication for original scalar
6717 // VPInstructions in the loop.
6718 // ---------------------------------------------------------------------------
6719 VPRecipeBuilder RecipeBuilder(*Plan, Legal, CM, Builder);
6720
6721 // Scan the body of the loop in a topological order to visit each basic block
6722 // after having visited its predecessor basic blocks.
6723 VPBasicBlock *HeaderVPBB = LoopRegion->getEntryBasicBlock();
6724 ReversePostOrderTraversal<VPBlockShallowTraversalWrapper<VPBlockBase *>> RPOT(
6725 HeaderVPBB);
6726
6728 Range.Start);
6729
6730 VPCostContext CostCtx(CM.TTI, *CM.TLI, *Plan, CM, Config.CostKind, CM.PSE,
6731 OrigLoop);
6732
6734 RecipeBuilder, CostCtx);
6735
6737
6739 RecipeBuilder, CostCtx);
6740
6741 // Now process all other blocks and instructions.
6742 for (VPBasicBlock *VPBB : VPBlockUtils::blocksOnly<VPBasicBlock>(RPOT)) {
6743 // Convert input VPInstructions to widened recipes.
6744 for (VPRecipeBase &R : make_early_inc_range(
6745 make_range(VPBB->getFirstNonPhi(), VPBB->end()))) {
6746 // Skip recipes that do not need transforming or have already been
6747 // transformed.
6748 if (isa<VPWidenCanonicalIVRecipe, VPBlendRecipe, VPReductionRecipe,
6749 VPReplicateRecipe, VPWidenLoadRecipe, VPWidenStoreRecipe,
6750 VPWidenCallRecipe, VPWidenIntrinsicRecipe, VPVectorPointerRecipe,
6751 VPVectorEndPointerRecipe, VPHistogramRecipe>(&R) ||
6754 vputils::onlyFirstLaneUsed(R.getVPSingleValue())))
6755 continue;
6756 auto *VPI = cast<VPInstruction>(&R);
6757 if (!VPI->getUnderlyingValue())
6758 continue;
6759
6760 // TODO: Gradually replace uses of underlying instruction by analyses on
6761 // VPlan. Migrate code relying on the underlying instruction from VPlan0
6762 // to construct recipes below to not use the underlying instruction.
6764 Builder.setInsertPoint(VPI);
6765
6766 VPRecipeBase *Recipe =
6767 RecipeBuilder.tryToCreateWidenNonPhiRecipe(VPI, Range);
6768 if (!Recipe)
6769 Recipe =
6770 RecipeBuilder.handleReplication(cast<VPInstruction>(VPI), Range);
6771
6772 if (isa<VPWidenIntOrFpInductionRecipe>(Recipe) && isa<TruncInst>(Instr)) {
6773 // Optimized a truncate to VPWidenIntOrFpInductionRecipe. It needs to be
6774 // moved to the phi section in the header.
6775 Recipe->insertBefore(*HeaderVPBB, HeaderVPBB->getFirstNonPhi());
6776 } else {
6777 Builder.insert(Recipe);
6778 }
6779 if (Recipe->getNumDefinedValues() == 1) {
6780 VPI->replaceAllUsesWith(Recipe->getVPSingleValue());
6781 } else {
6782 assert(Recipe->getNumDefinedValues() == 0 &&
6783 "Unexpected multidef recipe");
6784 }
6785 R.eraseFromParent();
6786 }
6787 }
6788
6789 assert(isa<VPRegionBlock>(LoopRegion) &&
6790 !LoopRegion->getEntryBasicBlock()->empty() &&
6791 "entry block must be set to a VPRegionBlock having a non-empty entry "
6792 "VPBasicBlock");
6793
6795 Range);
6796
6797 // ---------------------------------------------------------------------------
6798 // Transform initial VPlan: Apply previously taken decisions, in order, to
6799 // bring the VPlan to its final state.
6800 // ---------------------------------------------------------------------------
6801
6802 addReductionResultComputation(Plan, RecipeBuilder, Range.Start);
6803
6804 // Optimize FindIV reductions to use sentinel-based approach when possible.
6806 *OrigLoop);
6808
6809 // Apply mandatory transformation to handle reductions with multiple in-loop
6810 // uses if possible, bail out otherwise.
6812 OrigLoop))
6813 return nullptr;
6814 // Apply mandatory transformation to handle FP maxnum/minnum reduction with
6815 // NaNs if possible, bail out otherwise.
6817 return nullptr;
6818
6819 // Create whole-vector selects for find-last recurrences.
6821 return nullptr;
6822
6824
6825 // Create partial reduction recipes for scaled reductions and transform
6826 // recipes to abstract recipes if it is legal and beneficial and clamp the
6827 // range for better cost estimation.
6828 // TODO: Enable following transform when the EVL-version of extended-reduction
6829 // and mulacc-reduction are implemented.
6830 if (!CM.foldTailWithEVL()) {
6832 Range);
6834 Range);
6835 }
6836
6837 // Interleave memory: for each Interleave Group we marked earlier as relevant
6838 // for this VPlan, replace the Recipes widening its memory instructions with a
6839 // single VPInterleaveRecipe at its insertion point.
6841 InterleaveGroups, CM.isEpilogueAllowed());
6842
6843 // Convert memory recipes to strided access recipes if the strided access is
6844 // legal and profitable.
6846 *OrigLoop, CostCtx, Range);
6847
6848 // Ensure scalar VF plans only contain VF=1, as required by hasScalarVFOnly.
6849 if (Range.Start.isScalar())
6850 Range.End = Range.Start * 2;
6851
6852 for (ElementCount VF : Range)
6853 Plan->addVF(VF);
6854 Plan->setName("Initial VPlan");
6855
6857
6858 if (CM.maskPartialAliasing())
6860
6861 assert(verifyVPlanIsValid(*Plan) && "VPlan is invalid");
6862 return Plan;
6863}
6864
6865void LoopVectorizationPlanner::addReductionResultComputation(
6866 VPlanPtr &Plan, VPRecipeBuilder &RecipeBuilder, ElementCount MinVF) {
6867 using namespace VPlanPatternMatch;
6868 VPRegionBlock *VectorLoopRegion = Plan->getVectorLoopRegion();
6869 VPBasicBlock *MiddleVPBB = Plan->getMiddleBlock();
6870 VPBasicBlock *LatchVPBB = VectorLoopRegion->getExitingBasicBlock();
6871 Builder.setInsertPoint(&*std::prev(std::prev(LatchVPBB->end())));
6872 VPBasicBlock::iterator IP = MiddleVPBB->getFirstNonPhi();
6873 VPValue *HeaderMask = Plan->getVectorLoopRegion()->getHeaderMask();
6874 for (VPRecipeBase &R :
6875 Plan->getVectorLoopRegion()->getEntryBasicBlock()->phis()) {
6876 VPReductionPHIRecipe *PhiR = dyn_cast<VPReductionPHIRecipe>(&R);
6877 if (!PhiR)
6878 continue;
6879
6880 RecurKind RecurrenceKind = PhiR->getRecurrenceKind();
6881 const RecurrenceDescriptor &RdxDesc = Legal->getRecurrenceDescriptor(
6883 Type *PhiTy = PhiR->getScalarType();
6884
6885 // Convert a VPBlendRecipe backedge to a select.
6886 if (auto *Blend = dyn_cast<VPBlendRecipe>(PhiR->getBackedgeValue())) {
6887 if (Blend->getNumIncomingValues() == 2 &&
6888 Blend->getMask(0) == HeaderMask) {
6889 auto *Sel = VPBuilder(Blend).createSelect(
6890 Blend->getMask(0), Blend->getIncomingValue(0),
6891 Blend->getIncomingValue(1), {}, "", *Blend);
6892 Blend->replaceAllUsesWith(Sel);
6893 Blend->eraseFromParent();
6894 }
6895 }
6896
6897 auto *OrigExitingVPV = PhiR->getBackedgeValue();
6898 auto *NewExitingVPV = OrigExitingVPV;
6899
6900 // Remove the predicated select if the target doesn't want it.
6901 VPValue *V;
6902 if (!CM.usePredicatedReductionSelect(RecurrenceKind) &&
6903 match(PhiR->getBackedgeValue(),
6904 m_Select(m_Specific(HeaderMask), m_VPValue(V), m_Specific(PhiR))))
6905 PhiR->setBackedgeValue(V);
6906
6907 // We want code in the middle block to appear to execute on the location of
6908 // the scalar loop's latch terminator because: (a) it is all compiler
6909 // generated, (b) these instructions are always executed after evaluating
6910 // the latch conditional branch, and (c) other passes may add new
6911 // predecessors which terminate on this line. This is the easiest way to
6912 // ensure we don't accidentally cause an extra step back into the loop while
6913 // debugging.
6914 DebugLoc ExitDL = OrigLoop->getLoopLatch()->getTerminator()->getDebugLoc();
6915
6916 // TODO: At the moment ComputeReductionResult also drives creation of the
6917 // bc.merge.rdx phi nodes, hence it needs to be created unconditionally here
6918 // even for in-loop reductions, until the reduction resume value handling is
6919 // also modeled in VPlan.
6920 VPInstruction *FinalReductionResult;
6921 VPBuilder::InsertPointGuard Guard(Builder);
6922 Builder.setInsertPoint(MiddleVPBB, IP);
6923 // For AnyOf reductions, find the select among PhiR's users and convert
6924 // the reduction phi to operate on bools before creating the final
6925 // reduction result.
6926 if (RecurrenceDescriptor::isAnyOfRecurrenceKind(RecurrenceKind)) {
6927 auto *AnyOfSelect = cast<VPSingleDefRecipe>(
6929 VPValue *Start = PhiR->getStartValue();
6930 bool TrueValIsPhi = AnyOfSelect->getOperand(1) == PhiR;
6931 // NewVal is the non-phi operand of the select.
6932 VPValue *NewVal = TrueValIsPhi ? AnyOfSelect->getOperand(2)
6933 : AnyOfSelect->getOperand(1);
6934
6935 // Adjust AnyOf reductions; replace the reduction phi for the selected
6936 // value with a boolean reduction phi node to check if the condition is
6937 // true in any iteration. The final value is selected by the final
6938 // ComputeReductionResult.
6939 VPValue *Cmp = AnyOfSelect->getOperand(0);
6940 // If the compare is checking the reduction PHI node, adjust it to check
6941 // the start value.
6942 if (VPRecipeBase *CmpR = Cmp->getDefiningRecipe())
6943 CmpR->replaceUsesOfWith(PhiR, PhiR->getStartValue());
6944 Builder.setInsertPoint(AnyOfSelect);
6945
6946 // If the true value of the select is the reduction phi, the new value
6947 // is selected if the negated condition is true in any iteration.
6948 if (TrueValIsPhi)
6949 Cmp = Builder.createNot(Cmp);
6950
6951 // Build a fresh i1 chain (phi, or, and i1 versions of any blend/select
6952 // the exiting value flows through).
6953 auto *NewPhiR =
6954 PhiR->cloneWithOperands(Plan->getFalse(), Plan->getFalse());
6955 NewPhiR->insertBefore(PhiR);
6956 VPValue *NewExiting = Builder.createOr(NewPhiR, Cmp);
6957
6958 // The exiting value may flow through a chain of VPBlendRecipes and
6959 // select recipes (VPInstruction, VPWidenRecipe or VPReplicateRecipe with
6960 // Select opcode) before reaching OrigExitingVPV. Clone each chain link
6961 // in topological order so each clone refers to the already-rewritten i1
6962 // operands via Substitutions.
6963 DenseMap<VPValue *, VPValue *> Substitutions = {{AnyOfSelect, NewExiting},
6964 {PhiR, NewPhiR}};
6965 std::function<void(VPSingleDefRecipe *)> CloneChain =
6966 [&](VPSingleDefRecipe *Old) {
6967 if (Substitutions.contains(Old))
6968 return;
6970 for (VPValue *Op : Old->operands()) {
6971 if (isa<VPBlendRecipe>(Op) ||
6973 CloneChain(cast<VPSingleDefRecipe>(Op));
6974 NewOps.push_back(Substitutions.lookup_or(Op, Op));
6975 }
6976 VPSingleDefRecipe *New;
6977 if (auto *B = dyn_cast<VPBlendRecipe>(Old))
6978 New = B->cloneWithOperands(NewOps);
6979 else if (auto *W = dyn_cast<VPWidenRecipe>(Old))
6980 New = W->cloneWithOperands(NewOps);
6981 else if (auto *Rep = dyn_cast<VPReplicateRecipe>(Old))
6982 New = Rep->cloneWithOperands(NewOps);
6983 else
6984 New = cast<VPInstruction>(Old)->cloneWithOperands(NewOps);
6985 New->insertBefore(Old);
6986 Substitutions[Old] = New;
6987 };
6988
6989 if (OrigExitingVPV != AnyOfSelect) {
6990 CloneChain(cast<VPSingleDefRecipe>(OrigExitingVPV));
6991 NewExiting = Substitutions.lookup(OrigExitingVPV);
6992 }
6993 NewPhiR->setOperand(1, NewExiting);
6994 PhiR->replaceAllUsesWith(Plan->getPoison(PhiR->getScalarType()));
6995
6996 Builder.setInsertPoint(MiddleVPBB, IP);
6997 FinalReductionResult =
6998 Builder.createAnyOfReduction(NewExiting, NewVal, Start, ExitDL);
6999 } else {
7000 // If the vector reduction can be performed in a smaller type, we
7001 // truncate then extend the loop exit value to enable InstCombine to
7002 // evaluate the entire expression in the smaller type.
7003 VPValue *ReductionOp = NewExitingVPV;
7004 Instruction::CastOps ExtendOpc = Instruction::CastOpsEnd;
7005 if (MinVF.isVector() && PhiTy != RdxDesc.getRecurrenceType()) {
7006 assert(!PhiR->isInLoop() && "Unexpected truncated inloop reduction!");
7008 "Unexpected truncated min-max recurrence!");
7009 Type *RdxTy = RdxDesc.getRecurrenceType();
7010 ExtendOpc = RdxDesc.isSigned() ? Instruction::SExt : Instruction::ZExt;
7011 {
7012 VPBuilder::InsertPointGuard Guard(Builder);
7013 Builder.setInsertPoint(
7014 NewExitingVPV->getDefiningRecipe()->getParent(),
7015 std::next(NewExitingVPV->getDefiningRecipe()->getIterator()));
7016 ReductionOp =
7017 Builder.createWidenCast(Instruction::Trunc, NewExitingVPV, RdxTy);
7018 VPWidenCastRecipe *Extnd =
7019 Builder.createWidenCast(ExtendOpc, ReductionOp, PhiTy);
7020 if (PhiR->getOperand(1) == NewExitingVPV)
7021 PhiR->setOperand(1, Extnd);
7022 }
7023 }
7024
7025 VPIRFlags Flags(RecurrenceKind, PhiR->isOrdered(), PhiR->isInLoop(),
7026 PhiR->getFastMathFlagsOrNone());
7027 FinalReductionResult = Builder.createNaryOp(
7028 VPInstruction::ComputeReductionResult, {ReductionOp}, Flags, ExitDL);
7029 if (ExtendOpc != Instruction::CastOpsEnd)
7030 FinalReductionResult = Builder.createScalarCast(
7031 ExtendOpc, FinalReductionResult, PhiTy, {});
7032 }
7033
7034 // Update all users outside the vector region. Also replace redundant
7035 // extracts.
7036 for (auto *U : to_vector(OrigExitingVPV->users())) {
7037 auto *Parent = cast<VPRecipeBase>(U)->getParent();
7038 if (FinalReductionResult == U || Parent->getParent())
7039 continue;
7040 // Skip ComputeReductionResult and FindIV reductions when they are not the
7041 // final result.
7042 if (match(U, m_VPInstruction<VPInstruction::ComputeReductionResult>()) ||
7044 match(U, m_VPInstruction<Instruction::ICmp>())))
7045 continue;
7046 U->replaceUsesOfWith(OrigExitingVPV, FinalReductionResult);
7047
7048 // Look through ExtractLastPart.
7050 U = cast<VPInstruction>(U)->getSingleUser();
7051
7054 cast<VPInstruction>(U)->replaceAllUsesWith(FinalReductionResult);
7055 }
7056
7057 RecurKind RK = PhiR->getRecurrenceKind();
7062 VPBuilder PHBuilder(Plan->getVectorPreheader());
7063 VPValue *Iden = Plan->getOrAddLiveIn(
7064 getRecurrenceIdentity(RK, PhiTy, PhiR->getFastMathFlagsOrNone()));
7065 auto *ScaleFactorVPV = Plan->getConstantInt(32, 1);
7066 VPValue *StartV = PHBuilder.createNaryOp(
7068 {PhiR->getStartValue(), Iden, ScaleFactorVPV}, *PhiR);
7069 PhiR->setOperand(0, StartV);
7070 }
7071 }
7072
7074}
7075
7077 VPlan &Plan, GeneratedRTChecks &RTChecks, bool HasBranchWeights) const {
7078 const auto &[SCEVCheckCond, SCEVCheckBlock] = RTChecks.getSCEVChecks();
7079 if (SCEVCheckBlock && SCEVCheckBlock->hasNPredecessors(0)) {
7080 assert((!Config.OptForSize ||
7081 CM.Hints->getForce() == LoopVectorizeHints::FK_Enabled) &&
7082 "Cannot SCEV check stride or overflow when optimizing for size");
7084 SCEVCheckBlock, HasBranchWeights);
7085 }
7086 const auto &[MemCheckCond, MemCheckBlock] = RTChecks.getMemRuntimeChecks();
7087 if (MemCheckBlock && MemCheckBlock->hasNPredecessors(0)) {
7088 // VPlan-native path does not do any analysis for runtime checks
7089 // currently.
7091 "Runtime checks are not supported for outer loops yet");
7092
7093 if (Config.OptForSize) {
7094 assert(
7095 CM.Hints->getForce() == LoopVectorizeHints::FK_Enabled &&
7096 "Cannot emit memory checks when optimizing for size, unless forced "
7097 "to vectorize.");
7098 ORE->emit([&]() {
7099 return OptimizationRemarkAnalysis(DEBUG_TYPE, "VectorizationCodeSize",
7100 OrigLoop->getStartLoc(),
7101 OrigLoop->getHeader())
7102 << "Code-size may be reduced by not forcing "
7103 "vectorization, or by source-code modifications "
7104 "eliminating the need for runtime checks "
7105 "(e.g., adding 'restrict').";
7106 });
7107 }
7109 MemCheckBlock, HasBranchWeights);
7110 }
7111}
7112
7114 ElementCount VF) const {
7115 // A scalar epilogue is required, if we unconditionally execute the scalar
7116 // loop. Must be called before removeBranchOnConst.
7117 VPBasicBlock *MiddleVPBB = Plan.getMiddleBlock();
7118 bool Result = MiddleVPBB->getSingleSuccessor() == Plan.getScalarPreheader();
7119 assert(CM.requiresScalarEpilogue(VF.isVector()) == Result &&
7120 "CM.requiresScalarEpilogue and the VPlan-based check must agree");
7121 return Result;
7122}
7123
7125 bool Result = Plan.hasTailFolded();
7126 assert(CM.foldTailByMasking() == Result &&
7127 "CM.foldTailByMasking and the VPlan-based check must agree");
7128 return Result;
7129}
7130
7132 VPlan &Plan, ElementCount VF, unsigned UF,
7133 ElementCount MinProfitableTripCount) const {
7134 const uint32_t *BranchWeights =
7135 hasBranchWeightMD(*OrigLoop->getLoopLatch()->getTerminator())
7137 : nullptr;
7139 MinProfitableTripCount, requiresScalarEpilogue(Plan, VF),
7140 hasTailFolded(Plan), OrigLoop, BranchWeights,
7141 OrigLoop->getLoopPredecessor()->getTerminator()->getDebugLoc(),
7142 PSE, Plan.getEntry());
7143}
7144
7145// Determine how to lower the epilogue, which depends on 1) optimising
7146// for minimum code-size, 2) tail-folding compiler options, 3) loop
7147// hints forcing tail-folding, and 4) a TTI hook that analyses whether the loop
7148// is suitable for tail-folding.
7149// This function determines epilogue lowering for the main vector loop while
7150// epilogue lowering for the tail-folded epilogue path will be handled
7151// separately in getEpilogueTailLowering.
7152static EpilogueLowering
7154 bool OptForSize, TargetTransformInfo *TTI,
7156 InterleavedAccessInfo *IAI) {
7157 // 1) OptSize takes precedence over all other options, i.e. if this is set,
7158 // don't look at hints or options, and don't request an epilogue.
7159 if (F->hasOptSize() ||
7160 (OptForSize && Hints.getForce() != LoopVectorizeHints::FK_Enabled))
7162
7163 // 2) If set, obey the directives
7164 if (TailFoldingPolicy.getNumOccurrences()) {
7165 switch (TailFoldingPolicy) {
7167 return CM_EpilogueAllowed;
7172 };
7173 }
7174
7175 // 3) If set, obey the hints
7176 switch (Hints.getPredicate()) {
7180 return CM_EpilogueAllowed;
7181 };
7182
7183 // 4) if the TTI hook indicates this is profitable, request tail-folding.
7184 TailFoldingInfo TFI(TLI, &LVL, IAI);
7185 if (TTI->preferTailFoldingOverEpilogue(&TFI))
7187
7188 return CM_EpilogueAllowed;
7189}
7190
7191/// Determine how to lower the epilogue for the vector epilogue loop.
7192/// Check if there are any conflicts that prevent tail-folding the epilogue.
7193/// \return CM_EpilogueNotNeededFoldTail if epilogue tail-folding is possible,
7194/// otherwise CM_EpilogueAllowed.
7195static EpilogueLowering
7198 // Epilogue TF is only enabled when explicitly requested via command line.
7199 if (!EpilogueTailFoldingPolicy.getNumOccurrences() ||
7201 return CM_EpilogueAllowed;
7202
7205 "Options conflict, epilogue vectorization is disallowed while "
7206 "epilogue tail-folding allowed!\n",
7207 "UnsupportedEpilogueTailFoldingPolicy", ORE, L);
7208 return CM_EpilogueAllowed;
7209 }
7210
7211 // If scalar epilogue is explicitly required, we can't apply TF.
7212 if (MainCM.requiresScalarEpilogue(/*IsVectorizing*/ true)) {
7213 LLVM_DEBUG(dbgs() << "LV: Epilogue tail-folding can't be applied because "
7214 "scalar epilogue is required\n"
7215 "LV: Fall back to a normal epilogue\n");
7216 return CM_EpilogueAllowed;
7217 }
7218
7219 // If having epilogue is NOT allowed, then no epilogue to apply TF for.
7220 if (!MainCM.isEpilogueAllowed()) {
7221 LLVM_DEBUG(dbgs() << "LV: No epilogue to apply tail-folding for.\n"
7222 "LV: Fall back to a normal epilogue\n");
7223 return CM_EpilogueAllowed;
7224 }
7225
7226 // We can apply tail-folding on the vectorized epilogue loop.
7228}
7229
7230// Emit a remark if there are stores to floats that required a floating point
7231// extension. If the vectorized loop was generated with floating point there
7232// will be a performance penalty from the conversion overhead and the change in
7233// the vector width.
7236 for (BasicBlock *BB : L->getBlocks()) {
7237 for (Instruction &Inst : *BB) {
7238 if (auto *S = dyn_cast<StoreInst>(&Inst)) {
7239 if (S->getValueOperand()->getType()->isFloatTy())
7240 Worklist.push_back(S);
7241 }
7242 }
7243 }
7244
7245 // Traverse the floating point stores upwards searching, for floating point
7246 // conversions.
7249 while (!Worklist.empty()) {
7250 auto *I = Worklist.pop_back_val();
7251 if (!L->contains(I))
7252 continue;
7253 if (!Visited.insert(I).second)
7254 continue;
7255
7256 // Emit a remark if the floating point store required a floating
7257 // point conversion.
7258 // TODO: More work could be done to identify the root cause such as a
7259 // constant or a function return type and point the user to it.
7260 if (isa<FPExtInst>(I) && EmittedRemark.insert(I).second)
7261 ORE->emit([&]() {
7262 return OptimizationRemarkAnalysis(LV_NAME, "VectorMixedPrecision",
7263 I->getDebugLoc(), L->getHeader())
7264 << "floating point conversion changes vector width. "
7265 << "Mixed floating point precision requires an up/down "
7266 << "cast that will negatively impact performance.";
7267 });
7268
7269 for (Use &Op : I->operands())
7270 if (auto *OpI = dyn_cast<Instruction>(Op))
7271 Worklist.push_back(OpI);
7272 }
7273}
7274
7275/// For loops with uncountable early exits, find the cost of doing work when
7276/// exiting the loop early, such as calculating the final exit values of
7277/// variables used outside the loop.
7278/// TODO: This is currently overly pessimistic because the loop may not take
7279/// the early exit, but better to keep this conservative for now. In future,
7280/// it might be possible to relax this by using branch probabilities.
7282 VPlan &Plan, ElementCount VF) {
7283 InstructionCost Cost = 0;
7284 for (auto *ExitVPBB : Plan.getExitBlocks()) {
7285 for (auto *PredVPBB : ExitVPBB->getPredecessors()) {
7286 // If the predecessor is not the middle.block, then it must be the
7287 // vector.early.exit block, which may contain work to calculate the exit
7288 // values of variables used outside the loop.
7289 if (PredVPBB != Plan.getMiddleBlock()) {
7290 LLVM_DEBUG(dbgs() << "Calculating cost of work in exit block "
7291 << PredVPBB->getName() << ":\n");
7292 Cost += PredVPBB->cost(VF, CostCtx);
7293 }
7294 }
7295 }
7296 return Cost;
7297}
7298
7299/// This function determines whether or not it's still profitable to vectorize
7300/// the loop given the extra work we have to do outside of the loop:
7301/// 1. Perform the runtime checks before entering the loop to ensure it's safe
7302/// to vectorize.
7303/// 2. In the case of loops with uncountable early exits, we may have to do
7304/// extra work when exiting the loop early, such as calculating the final
7305/// exit values of variables used outside the loop.
7306/// 3. The middle block.
7307static bool isOutsideLoopWorkProfitable(GeneratedRTChecks &Checks,
7308 VectorizationFactor &VF, Loop *L,
7310 VPCostContext &CostCtx, VPlan &Plan,
7311 EpilogueLowering SEL,
7312 std::optional<unsigned> VScale) {
7313 InstructionCost RtC = Checks.getCost();
7314 if (!RtC.isValid())
7315 return false;
7316
7317 // When interleaving only scalar and vector cost will be equal, which in turn
7318 // would lead to a divide by 0. Fall back to hard threshold.
7319 if (VF.Width.isScalar()) {
7320 // TODO: Should we rename VectorizeMemoryCheckThreshold?
7322 LLVM_DEBUG(
7323 dbgs()
7324 << "LV: Interleaving only is not profitable due to runtime checks\n");
7325 return false;
7326 }
7327 return true;
7328 }
7329
7330 // The scalar cost should only be 0 when vectorizing with a user specified
7331 // VF/IC. In those cases, runtime checks should always be generated.
7332 uint64_t ScalarC = VF.ScalarCost.getValue();
7333 if (ScalarC == 0)
7334 return true;
7335
7336 InstructionCost TotalCost = RtC;
7337 // Add on the cost of any work required in the vector early exit block, if
7338 // one exists.
7339 TotalCost += calculateEarlyExitCost(CostCtx, Plan, VF.Width);
7340 TotalCost += Plan.getMiddleBlock()->cost(VF.Width, CostCtx);
7341
7342 // First, compute the minimum iteration count required so that the vector
7343 // loop outperforms the scalar loop.
7344 // The total cost of the scalar loop is
7345 // ScalarC * TC
7346 // where
7347 // * TC is the actual trip count of the loop.
7348 // * ScalarC is the cost of a single scalar iteration.
7349 //
7350 // The total cost of the vector loop is
7351 // TotalCost + VecC * (TC / VF) + EpiC
7352 // where
7353 // * TotalCost is the sum of the costs cost of
7354 // - the generated runtime checks, i.e. RtC
7355 // - performing any additional work in the vector.early.exit block for
7356 // loops with uncountable early exits.
7357 // - the middle block, if ExpectedTC <= VF.Width.
7358 // * VecC is the cost of a single vector iteration.
7359 // * TC is the actual trip count of the loop
7360 // * VF is the vectorization factor
7361 // * EpiCost is the cost of the generated epilogue, including the cost
7362 // of the remaining scalar operations.
7363 //
7364 // Vectorization is profitable once the total vector cost is less than the
7365 // total scalar cost:
7366 // TotalCost + VecC * (TC / VF) + EpiC < ScalarC * TC
7367 //
7368 // Now we can compute the minimum required trip count TC as
7369 // VF * (TotalCost + EpiC) / (ScalarC * VF - VecC) < TC
7370 //
7371 // For now we assume the epilogue cost EpiC = 0 for simplicity. Note that
7372 // the computations are performed on doubles, not integers and the result
7373 // is rounded up, hence we get an upper estimate of the TC.
7374 unsigned IntVF = estimateElementCount(VF.Width, VScale);
7375 uint64_t Div = ScalarC * IntVF - VF.Cost.getValue();
7376 uint64_t MinTC1 =
7377 Div == 0 ? 0 : divideCeil(TotalCost.getValue() * IntVF, Div);
7378
7379 // Second, compute a minimum iteration count so that the cost of the
7380 // runtime checks is only a fraction of the total scalar loop cost. This
7381 // adds a loop-dependent bound on the overhead incurred if the runtime
7382 // checks fail. In case the runtime checks fail, the cost is RtC + ScalarC
7383 // * TC. To bound the runtime check to be a fraction 1/X of the scalar
7384 // cost, compute
7385 // RtC < ScalarC * TC * (1 / X) ==> RtC * X / ScalarC < TC
7386 uint64_t MinTC2 = divideCeil(RtC.getValue() * 10, ScalarC);
7387
7388 // Now pick the larger minimum. If it is not a multiple of VF and an epilogue
7389 // is allowed, choose the next closest multiple of VF. This should partly
7390 // compensate for ignoring the epilogue cost.
7391 uint64_t MinTC = std::max(MinTC1, MinTC2);
7392 if (SEL == CM_EpilogueAllowed)
7393 MinTC = alignTo(MinTC, IntVF);
7395
7396 LLVM_DEBUG(
7397 dbgs() << "LV: Minimum required TC for runtime checks to be profitable:"
7398 << VF.MinProfitableTripCount << "\n");
7399
7400 // Skip vectorization if the expected trip count is less than the minimum
7401 // required trip count.
7402 if (auto ExpectedTC = getSmallBestKnownTC(PSE, L)) {
7403 if (ElementCount::isKnownLT(*ExpectedTC, VF.MinProfitableTripCount)) {
7404 LLVM_DEBUG(dbgs() << "LV: Vectorization is not beneficial: expected "
7405 "trip count < minimum profitable VF ("
7406 << *ExpectedTC << " < " << VF.MinProfitableTripCount
7407 << ")\n");
7408
7409 return false;
7410 }
7411 }
7412 return true;
7413}
7414
7416 : InterleaveOnlyWhenForced(Opts.InterleaveOnlyWhenForced ||
7418 VectorizeOnlyWhenForced(Opts.VectorizeOnlyWhenForced ||
7420
7421/// Prepare \p MainPlan for vectorizing the main vector loop during epilogue
7422/// vectorization.
7425 using namespace VPlanPatternMatch;
7426 // When vectorizing the epilogue, FindFirstIV & FindLastIV reductions can
7427 // introduce multiple uses of undef/poison. If the reduction start value may
7428 // be undef or poison it needs to be frozen and the frozen start has to be
7429 // used when computing the reduction result. We also need to use the frozen
7430 // value in the resume phi generated by the main vector loop, as this is also
7431 // used to compute the reduction result after the epilogue vector loop.
7432 auto AddFreezeForFindLastIVReductions = [](VPlan &Plan,
7433 bool UpdateResumePhis) {
7434 VPBuilder Builder(Plan.getEntry());
7435 for (VPRecipeBase &R : *Plan.getMiddleBlock()) {
7436 auto *VPI = dyn_cast<VPInstruction>(&R);
7437 if (!VPI)
7438 continue;
7439 VPValue *OrigStart;
7440 if (!matchFindIVResult(VPI, m_VPValue(), m_VPValue(OrigStart)))
7441 continue;
7443 continue;
7444 VPInstruction *Freeze =
7445 Builder.createNaryOp(Instruction::Freeze, {OrigStart}, {}, "fr");
7446 VPI->setOperand(2, Freeze);
7447 if (UpdateResumePhis)
7448 OrigStart->replaceUsesWithIf(Freeze, [Freeze](VPUser &U, unsigned) {
7449 return Freeze != &U && isa<VPPhi>(&U);
7450 });
7451 }
7452 };
7453 AddFreezeForFindLastIVReductions(MainPlan, true);
7454 AddFreezeForFindLastIVReductions(EpiPlan, false);
7455
7456 VPValue *VectorTC = nullptr;
7457 auto *Term =
7459 [[maybe_unused]] bool MatchedTC =
7460 match(Term, m_BranchOnCount(m_VPValue(), m_VPValue(VectorTC)));
7461 assert(MatchedTC && "must match vector trip count");
7462
7463 // If there is a suitable resume value for the canonical induction in the
7464 // scalar (which will become vector) epilogue loop, use it and move it to the
7465 // beginning of the scalar preheader. Otherwise create it below.
7466 VPBasicBlock *MainScalarPH = MainPlan.getScalarPreheader();
7467 auto ResumePhiIter =
7468 find_if(MainScalarPH->phis(), [VectorTC](VPRecipeBase &R) {
7469 return match(&R, m_VPInstruction<Instruction::PHI>(m_Specific(VectorTC),
7470 m_ZeroInt()));
7471 });
7472 VPPhi *ResumePhi = nullptr;
7473 if (ResumePhiIter == MainScalarPH->phis().end()) {
7475 "canonical IV must exist");
7476 Type *Ty = VectorTC->getScalarType();
7477 VPBuilder ScalarPHBuilder(MainScalarPH, MainScalarPH->begin());
7478 ResumePhi = ScalarPHBuilder.createScalarPhi(
7479 {VectorTC, MainPlan.getZero(Ty)}, {}, "vec.epilog.resume.val");
7480 } else {
7481 ResumePhi = cast<VPPhi>(&*ResumePhiIter);
7482 ResumePhi->setName("vec.epilog.resume.val");
7483 if (&MainScalarPH->front() != ResumePhi)
7484 ResumePhi->moveBefore(*MainScalarPH, MainScalarPH->begin());
7485 }
7486
7487 // Create a ResumeForEpilogue for the canonical IV resume and its bypass value
7488 // as the first non-phi, to keep them alive for the epilogue.
7489 VPBuilder ResumeBuilder(MainScalarPH);
7491 {ResumePhi, ResumePhi->getOperand(1)});
7492
7493 // Create ResumeForEpilogue instructions for the resume phis of the
7494 // VPIRPhis and their bypass values in the scalar header of the main plan and
7495 // return them so they can be used as resume values when vectorizing the
7496 // epilogue.
7497 return to_vector(
7498 map_range(MainPlan.getScalarHeader()->phis(), [&](VPRecipeBase &R) {
7499 assert(isa<VPIRPhi>(R) &&
7500 "only VPIRPhis expected in the scalar header");
7501 VPValue *MainResumePhi = R.getOperand(0);
7502 VPValue *Bypass = MainResumePhi->getDefiningRecipe()->getOperand(1);
7503 return ResumeBuilder.createNaryOp(VPInstruction::ResumeForEpilogue,
7504 {MainResumePhi, Bypass});
7505 }));
7506}
7507
7508/// Prepare \p Plan for vectorizing the epilogue loop. That is, re-use expanded
7509/// SCEVs from \p ExpandedSCEVs and set resume values for header recipes. Some
7510/// reductions require creating new instructions to compute the resume values.
7511/// They are collected in a vector and returned. They must be moved to the
7512/// preheader of the vector epilogue loop, after created by the execution of \p
7513/// Plan.
7515 VPlan &MainPlan, VPlan &Plan, Loop *L, const SCEV2ValueTy &ExpandedSCEVs,
7518 ArrayRef<VPInstruction *> ResumeValues) {
7519 // Build a map from the scalar-header PHI to the ResumeForEpilogue markers
7520 // from the main plan.
7521 // TODO: Replace the IR PHI key.
7522 DenseMap<PHINode *, VPInstruction *> IRPhiToResumeForEpi;
7523 for (auto [HeaderPhi, ResumeForEpi] :
7524 zip_equal(MainPlan.getScalarHeader()->phis(), ResumeValues))
7525 IRPhiToResumeForEpi[&cast<VPIRPhi>(HeaderPhi).getIRPhi()] = ResumeForEpi;
7526 VPRegionBlock *VectorLoop = Plan.getVectorLoopRegion();
7527 VPBasicBlock *Header = VectorLoop->getEntryBasicBlock();
7528 Header->setName("vec.epilog.vector.body");
7529
7530 VPValue *IV = VectorLoop->getCanonicalIV();
7531 // When vectorizing the epilogue loop, the canonical induction needs to start
7532 // at the resume value from the main vector loop. Find the resume value
7533 // created during execution of the main VPlan. Add this resume value as an
7534 // offset to the canonical IV of the epilogue loop.
7535 using namespace llvm::PatternMatch;
7536 VPInstruction *ResumeForEpilogue =
7538 Value *EPResumeVal = ResumeForEpilogue->getUnderlyingValue();
7539 if (auto *ResumePhi = dyn_cast<PHINode>(EPResumeVal)) {
7540 for (Value *Inc : ResumePhi->incoming_values()) {
7541 if (match(Inc, m_SpecificInt(0)))
7542 continue;
7543 assert(!EPI.VectorTripCount &&
7544 "Must only have a single non-zero incoming value");
7545 EPI.VectorTripCount = Inc;
7546 }
7547 // If we didn't find a non-zero vector trip count, all incoming values
7548 // must be zero, which also means the vector trip count is zero.
7549 if (!EPI.VectorTripCount) {
7550 assert(ResumePhi->getNumIncomingValues() > 0 &&
7551 all_of(ResumePhi->incoming_values(), match_fn(m_SpecificInt(0))) &&
7552 "all incoming values must be 0");
7553 EPI.VectorTripCount = ResumePhi->getIncomingValue(0);
7554 }
7555 } else {
7556 EPI.VectorTripCount = EPResumeVal;
7557 }
7558 VPValue *VPV = Plan.getOrAddLiveIn(EPResumeVal);
7559 assert(all_of(IV->users(),
7560 [](const VPUser *U) {
7561 if (isa<VPScalarIVStepsRecipe, VPDerivedIVRecipe>(U))
7562 return true;
7563 unsigned Opc = cast<VPInstruction>(U)->getOpcode();
7564 return Instruction::isCast(Opc) || Opc == Instruction::Add;
7565 }) &&
7566 "the canonical IV should only be used by its increment or "
7567 "ScalarIVSteps when resetting the start value");
7568 VPBuilder Builder(Header, Header->getFirstNonPhi());
7569 VPInstruction *Add = Builder.createAdd(IV, VPV);
7570 // Replace all users of the canonical IV and its increment with the offset
7571 // version, except for the Add itself and the canonical IV increment.
7573 assert(Increment && "Must have a canonical IV increment at this point");
7574 IV->replaceUsesWithIf(Add, [Add, Increment](VPUser &U, unsigned) {
7575 return &U != Add && &U != Increment;
7576 });
7577 VPInstruction *OffsetIVInc =
7579 Increment->replaceAllUsesWith(OffsetIVInc);
7580 OffsetIVInc->setOperand(0, Increment);
7581
7583 SmallVector<Instruction *> InstsToMove;
7584 // Ensure that the start values for all header phi recipes are updated before
7585 // vectorizing the epilogue loop.
7586 for (VPRecipeBase &R : Header->phis()) {
7587 Value *ResumeV = nullptr;
7588 // TODO: Move setting of resume values to prepareToExecute.
7589 if (auto *ReductionPhi = dyn_cast<VPReductionPHIRecipe>(&R)) {
7590 // Find the reduction result by searching users of the phi or its backedge
7591 // value.
7592 auto IsReductionResult = [](VPRecipeBase *R) {
7593 auto *VPI = dyn_cast<VPInstruction>(R);
7594 return VPI && VPI->getOpcode() == VPInstruction::ComputeReductionResult;
7595 };
7596 auto *RdxResult = cast<VPInstruction>(
7597 vputils::findRecipe(ReductionPhi->getBackedgeValue(), IsReductionResult));
7598 assert(RdxResult && "expected to find reduction result");
7599
7600 VPInstruction *ResumeForEpi = IRPhiToResumeForEpi.at(
7601 cast<PHINode>(ReductionPhi->getUnderlyingInstr()));
7602 ResumeV = ResumeForEpi->getUnderlyingValue();
7603
7604 // Check for FindIV pattern by looking for icmp user of RdxResult.
7605 // The pattern is: select(icmp ne RdxResult, Sentinel), RdxResult, Start
7606 using namespace VPlanPatternMatch;
7607 VPValue *SentinelVPV = nullptr;
7608 bool IsFindIV = any_of(RdxResult->users(), [&](VPUser *U) {
7609 return match(U, VPlanPatternMatch::m_SpecificICmp(
7610 ICmpInst::ICMP_NE, m_Specific(RdxResult),
7611 m_VPValue(SentinelVPV)));
7612 });
7613
7614 RecurKind RK = ReductionPhi->getRecurrenceKind();
7615 if (RecurrenceDescriptor::isAnyOfRecurrenceKind(RK) || IsFindIV) {
7616 auto *ResumePhi = cast<PHINode>(ResumeV);
7617 VPValue *BypassOp = ResumeForEpi->getOperand(1);
7618 assert((isa<VPIRValue>(BypassOp) ||
7620 BypassOp,
7622 "expected live-in or Freeze");
7623 Value *StartV = BypassOp->getUnderlyingValue();
7624 IRBuilder<> Builder(ResumePhi->getParent(),
7625 ResumePhi->getParent()->getFirstNonPHIIt());
7626
7628 // VPReductionPHIRecipes for AnyOf reductions expect a boolean as
7629 // start value; compare the final value from the main vector loop
7630 // to the start value.
7631 ResumeV = Builder.CreateICmpNE(ResumeV, StartV);
7632 if (auto *I = dyn_cast<Instruction>(ResumeV))
7633 InstsToMove.push_back(I);
7634 } else {
7635 assert(SentinelVPV && "expected to find icmp using RdxResult");
7636 if (auto *FreezeI = dyn_cast<FreezeInst>(StartV))
7637 ToFrozen[FreezeI->getOperand(0)] = StartV;
7638
7639 // Adjust resume: select(icmp eq ResumeV, StartV), Sentinel, ResumeV
7640 Value *Cmp = Builder.CreateICmpEQ(ResumeV, StartV);
7641 if (auto *I = dyn_cast<Instruction>(Cmp))
7642 InstsToMove.push_back(I);
7643 ResumeV = Builder.CreateSelect(Cmp, SentinelVPV->getLiveInIRValue(),
7644 ResumeV);
7645 if (auto *I = dyn_cast<Instruction>(ResumeV))
7646 InstsToMove.push_back(I);
7647 }
7648 } else {
7649 VPValue *StartVal = Plan.getOrAddLiveIn(ResumeV);
7650 auto *PhiR = dyn_cast<VPReductionPHIRecipe>(&R);
7651 if (auto *VPI = dyn_cast<VPInstruction>(PhiR->getStartValue())) {
7653 "unexpected start value");
7654 // Partial sub-reductions always start at 0 and account for the
7655 // reduction start value in a final subtraction. Update it to use the
7656 // resume value from the main vector loop.
7657 if (PhiR->getVFScaleFactor() > 1 &&
7659 PhiR->getRecurrenceKind())) {
7660 auto *Sub = cast<VPInstruction>(RdxResult->getSingleUser());
7661 assert((Sub->getOpcode() == Instruction::Sub ||
7662 Sub->getOpcode() == Instruction::FSub) &&
7663 "Unexpected opcode");
7664 assert(isa<VPIRValue>(Sub->getOperand(0)) &&
7665 "Expected operand to match the original start value of the "
7666 "reduction");
7667 // For integer sub-reductions, verify start value is zero.
7668 // For FP sub-reductions, verify start value is negative zero.
7669 [[maybe_unused]] auto StartValueIsIdentity = [&] {
7670 Value *IdentityValue = getRecurrenceIdentity(
7671 PhiR->getRecurrenceKind(), ResumeV->getType(),
7672 PhiR->getFastMathFlagsOrNone());
7673 auto *StartValue = dyn_cast<VPIRValue>(VPI->getOperand(0));
7674 return StartValue && StartValue->getValue() == IdentityValue;
7675 };
7676 assert(StartValueIsIdentity() &&
7677 "Expected start value for partial sub-reduction to be zero "
7678 "(or negative zero)");
7679
7680 Sub->setOperand(0, StartVal);
7681 } else
7682 VPI->setOperand(0, StartVal);
7683 continue;
7684 }
7685 }
7686 } else {
7687 // Retrieve the induction resume value via ResumeForEpilogue.
7688 PHINode *IndPhi = cast<VPWidenInductionRecipe>(&R)->getPHINode();
7689 ResumeV = IRPhiToResumeForEpi.at(IndPhi)->getUnderlyingValue();
7690 }
7691 assert(ResumeV && "Must have a resume value");
7692 VPValue *StartVal = Plan.getOrAddLiveIn(ResumeV);
7693 cast<VPHeaderPHIRecipe>(&R)->setStartValue(StartVal);
7694 }
7695
7696 // For some VPValues in the epilogue plan we must re-use the generated IR
7697 // values from the main plan. Replace them with live-in VPValues.
7698 // TODO: This is a workaround needed for epilogue vectorization and it
7699 // should be removed once induction resume value creation is done
7700 // directly in VPlan.
7701 for (auto &R : make_early_inc_range(*Plan.getEntry())) {
7702 // Re-use frozen values from the main plan for Freeze VPInstructions in the
7703 // epilogue plan. This ensures all users use the same frozen value.
7704 auto *VPI = dyn_cast<VPInstruction>(&R);
7705 if (VPI && VPI->getOpcode() == Instruction::Freeze) {
7707 ToFrozen.lookup(VPI->getOperand(0)->getLiveInIRValue())));
7708 continue;
7709 }
7710
7711 // Re-use the trip count and steps expanded for the main loop, as
7712 // skeleton creation needs it as a value that dominates both the scalar
7713 // and vector epilogue loops
7714 auto *ExpandR = dyn_cast<VPExpandSCEVRecipe>(&R);
7715 if (!ExpandR)
7716 continue;
7717 VPValue *ExpandedVal =
7718 Plan.getOrAddLiveIn(ExpandedSCEVs.lookup(ExpandR->getSCEV()));
7719 ExpandR->replaceAllUsesWith(ExpandedVal);
7720 if (Plan.getTripCount() == ExpandR)
7721 Plan.resetTripCount(ExpandedVal);
7722 ExpandR->eraseFromParent();
7723 }
7724
7725 auto VScale = Config.getVScaleForTuning();
7726 unsigned MainLoopStep =
7727 estimateElementCount(EPI.MainLoopVF * EPI.MainLoopUF, VScale);
7728 unsigned EpilogueLoopStep =
7729 estimateElementCount(EPI.EpilogueVF * EPI.EpilogueUF, VScale);
7733 EPI.EpilogueVF, EPI.EpilogueUF, MainLoopStep, EpilogueLoopStep, SE);
7734
7735 return InstsToMove;
7736}
7737
7738static void
7740 VPlan &BestEpiPlan,
7741 ArrayRef<VPInstruction *> ResumeValues) {
7742 // Fix resume values from the additional bypass block.
7743 BasicBlock *PH = L->getLoopPreheader();
7744 for (auto *Pred : predecessors(PH)) {
7745 for (PHINode &Phi : PH->phis()) {
7746 if (Phi.getBasicBlockIndex(Pred) != -1)
7747 continue;
7748 Phi.addIncoming(Phi.getIncomingValueForBlock(BypassBlock), Pred);
7749 }
7750 }
7751 auto *ScalarPH = cast<VPIRBasicBlock>(BestEpiPlan.getScalarPreheader());
7752 if (ScalarPH->hasPredecessors()) {
7753 // Fix resume values for inductions and reductions from the additional
7754 // bypass block using the incoming values from the main loop's resume phis.
7755 // ResumeValues correspond 1:1 with the scalar loop header phis.
7756 for (auto [ResumeV, HeaderPhi] :
7757 zip(ResumeValues, BestEpiPlan.getScalarHeader()->phis())) {
7758 auto *HeaderPhiR = cast<VPIRPhi>(&HeaderPhi);
7759 auto *EpiResumePhi =
7760 cast<PHINode>(HeaderPhiR->getIRPhi().getIncomingValueForBlock(PH));
7761 if (EpiResumePhi->getBasicBlockIndex(BypassBlock) == -1)
7762 continue;
7763 auto *MainResumePhi = cast<PHINode>(ResumeV->getUnderlyingValue());
7764 EpiResumePhi->setIncomingValueForBlock(
7765 BypassBlock, MainResumePhi->getIncomingValueForBlock(BypassBlock));
7766 }
7767 }
7768}
7769
7770/// Connect the epilogue vector loop generated for \p EpiPlan to the main vector
7771/// loop, after both plans have executed, updating branches from the iteration
7772/// and runtime checks of the main loop, as well as updating various phis. \p
7773/// InstsToMove contains instructions that need to be moved to the preheader of
7774/// the epilogue vector loop.
7775static void connectEpilogueVectorLoop(VPlan &EpiPlan, Loop *L,
7777 DominatorTree *DT,
7778 GeneratedRTChecks &Checks,
7779 ArrayRef<Instruction *> InstsToMove,
7780 ArrayRef<VPInstruction *> ResumeValues) {
7781 BasicBlock *VecEpilogueIterationCountCheck =
7782 cast<VPIRBasicBlock>(EpiPlan.getEntry())->getIRBasicBlock();
7783
7784 BasicBlock *VecEpiloguePreHeader =
7785 cast<CondBrInst>(VecEpilogueIterationCountCheck->getTerminator())
7786 ->getSuccessor(1);
7787 // Adjust the control flow taking the state info from the main loop
7788 // vectorization into account.
7790 "expected this to be saved from the previous pass.");
7791 DomTreeUpdater DTU(DT, DomTreeUpdater::UpdateStrategy::Eager);
7792
7793 // Helper to redirect an edge from \p BB to \p VecEpilogueIterationCountCheck
7794 // to \p NewSucc instead, updating the DomTree.
7795 auto RedirectEdge = [&](BasicBlock *BB, BasicBlock *NewSucc) {
7796 BB->getTerminator()->replaceUsesOfWith(VecEpilogueIterationCountCheck,
7797 NewSucc);
7798 DTU.applyUpdates(
7799 {{DominatorTree::Delete, BB, VecEpilogueIterationCountCheck},
7800 {DominatorTree::Insert, BB, NewSucc}});
7801 };
7802
7803 RedirectEdge(EPI.MainLoopIterationCountCheck, VecEpiloguePreHeader);
7804
7805 BasicBlock *ScalarPH =
7806 cast<VPIRBasicBlock>(EpiPlan.getScalarPreheader())->getIRBasicBlock();
7807 RedirectEdge(EPI.EpilogueIterationCountCheck, ScalarPH);
7808
7809 // Adjust the terminators of runtime check blocks and phis using them.
7810 BasicBlock *SCEVCheckBlock = Checks.getSCEVChecks().second;
7811 BasicBlock *MemCheckBlock = Checks.getMemRuntimeChecks().second;
7812 if (SCEVCheckBlock)
7813 RedirectEdge(SCEVCheckBlock, ScalarPH);
7814 if (MemCheckBlock)
7815 RedirectEdge(MemCheckBlock, ScalarPH);
7816
7817 // The vec.epilog.iter.check block may contain Phi nodes from inductions
7818 // or reductions which merge control-flow from the latch block and the
7819 // middle block. Update the incoming values here and move the Phi into the
7820 // preheader.
7821 SmallVector<PHINode *, 4> PhisInBlock(
7822 llvm::make_pointer_range(VecEpilogueIterationCountCheck->phis()));
7823
7824 for (PHINode *Phi : PhisInBlock) {
7825 Phi->moveBefore(VecEpiloguePreHeader->getFirstNonPHIIt());
7826 Phi->replaceIncomingBlockWith(
7827 VecEpilogueIterationCountCheck->getSinglePredecessor(),
7828 VecEpilogueIterationCountCheck);
7829
7830 // If the phi doesn't have an incoming value from the
7831 // EpilogueIterationCountCheck, we are done. Otherwise remove the
7832 // incoming value and also those from other check blocks. This is needed
7833 // for reduction phis only.
7834 if (none_of(Phi->blocks(), [&](BasicBlock *IncB) {
7835 return EPI.EpilogueIterationCountCheck == IncB;
7836 }))
7837 continue;
7838 for (BasicBlock *BB :
7839 {EPI.EpilogueIterationCountCheck, SCEVCheckBlock, MemCheckBlock}) {
7840 if (BB)
7841 Phi->removeIncomingValue(BB);
7842 }
7843 }
7844
7845 auto IP = VecEpiloguePreHeader->getFirstNonPHIIt();
7846 for (auto *I : InstsToMove)
7847 I->moveBefore(IP);
7848
7849 // VecEpilogueIterationCountCheck conditionally skips over the epilogue loop
7850 // after executing the main loop. We need to update the resume values of
7851 // inductions and reductions during epilogue vectorization.
7852 fixScalarResumeValuesFromBypass(VecEpilogueIterationCountCheck, L, EpiPlan,
7853 ResumeValues);
7854
7855 // Remove dead phis that were moved to the epilogue preheader but are unused
7856 // (e.g., resume phis for inductions not widened in the epilogue vector loop).
7857 for (PHINode &Phi : make_early_inc_range(VecEpiloguePreHeader->phis()))
7858 if (Phi.use_empty())
7859 Phi.eraseFromParent();
7860}
7861
7863 assert((EnableVPlanNativePath || L->isInnermost()) &&
7864 "VPlan-native path is not enabled. Only process inner loops.");
7865
7866 LLVM_DEBUG(dbgs() << "\nLV: Checking a loop in '"
7867 << L->getHeader()->getParent()->getName() << "' from "
7868 << L->getLocStr() << "\n");
7869
7870 LoopVectorizeHints Hints(L, InterleaveOnlyWhenForced, *ORE, TTI);
7871
7872 LLVM_DEBUG(
7873 dbgs() << "LV: Loop hints:"
7874 << " force="
7876 ? "disabled"
7878 ? "enabled"
7879 : "?"))
7880 << " width=" << Hints.getWidth()
7881 << " interleave=" << Hints.getInterleave() << "\n");
7882
7883 // Function containing loop
7884 Function *F = L->getHeader()->getParent();
7885
7886 // Looking at the diagnostic output is the only way to determine if a loop
7887 // was vectorized (other than looking at the IR or machine code), so it
7888 // is important to generate an optimization remark for each loop. Most of
7889 // these messages are generated as OptimizationRemarkAnalysis. Remarks
7890 // generated as OptimizationRemark and OptimizationRemarkMissed are
7891 // less verbose reporting vectorized loops and unvectorized loops that may
7892 // benefit from vectorization, respectively.
7893
7894 if (!Hints.allowVectorization(F, L, VectorizeOnlyWhenForced)) {
7895 LLVM_DEBUG(dbgs() << "LV: Loop hints prevent vectorization.\n");
7896 return false;
7897 }
7898
7899 PredicatedScalarEvolution PSE(*SE, *L);
7900
7901 // Query this against the original loop and save it here because the profile
7902 // of the original loop header may change as the transformation happens.
7903 bool OptForSize = llvm::shouldOptimizeForSize(
7904 L->getHeader(), PSI,
7905 PSI && PSI->hasProfileSummary() ? &GetBFI() : nullptr,
7907
7908 // Check if it is legal to vectorize the loop.
7909 LoopVectorizationRequirements Requirements;
7910 LoopVectorizationLegality LVL(L, PSE, DT, TTI, TLI, F, *LAIs, LI, ORE,
7911 &Requirements, &Hints, DB, AC,
7912 /*AllowRuntimeSCEVChecks=*/!OptForSize, AA);
7914 LLVM_DEBUG(dbgs() << "LV: Not vectorizing: Cannot prove legality.\n");
7915 Hints.emitRemarkWithHints();
7916 return false;
7917 }
7918
7919 bool IsInnerLoop = L->isInnermost();
7920
7921 // Outer loops require a computable trip count.
7922 if (!IsInnerLoop && isa<SCEVCouldNotCompute>(PSE.getBackedgeTakenCount())) {
7923 LLVM_DEBUG(dbgs() << "LV: cannot compute the outer-loop trip count\n");
7924 return false;
7925 }
7926
7927 if (LVL.hasUncountableEarlyExit()) {
7929 reportVectorizationFailure("Auto-vectorization of loops with uncountable "
7930 "early exit is not enabled",
7931 "UncountableEarlyExitLoopsDisabled", ORE, L);
7932 return false;
7933 }
7936 reportVectorizationFailure("Auto-vectorization of loops with uncountable "
7937 "early exit and side effects is not enabled",
7938 "UncountableEarlyExitSideEffectLoopsDisabled",
7939 ORE, L);
7940 return false;
7941 }
7942 }
7943
7944 InterleavedAccessInfo IAI(PSE, L, DT, LI, LVL.getLAI(), OptForSize);
7945 bool UseInterleaved =
7946 IsInnerLoop && TTI->enableInterleavedAccessVectorization();
7947
7948 // If an override option has been passed in for interleaved accesses, use it.
7949 if (EnableInterleavedMemAccesses.getNumOccurrences() > 0)
7950 UseInterleaved = IsInnerLoop && EnableInterleavedMemAccesses;
7951
7952 // Analyze interleaved memory accesses.
7953 if (UseInterleaved)
7955
7956 if (LVL.hasUncountableEarlyExit()) {
7957 BasicBlock *LoopLatch = L->getLoopLatch();
7958 if (IAI.requiresScalarEpilogue() ||
7959 any_of(LVL.getCountableExitingBlocks(), not_equal_to(LoopLatch))) {
7960 reportVectorizationFailure("Auto-vectorization of early exit loops "
7961 "requiring a scalar epilogue is unsupported",
7962 "UncountableEarlyExitUnsupported", ORE, L);
7963 return false;
7964 }
7965 }
7966
7967 // Check the function attributes and profiles to find out if this function
7968 // should be optimized for size.
7969 EpilogueLowering SEL =
7970 getEpilogueLowering(F, L, Hints, OptForSize, TTI, TLI, LVL, &IAI);
7971
7972 // Check the loop for a trip count threshold: vectorize loops with a tiny trip
7973 // count by optimizing for size, to minimize overheads.
7974 auto ExpectedTC = getSmallBestKnownTC(PSE, L);
7975 if (ExpectedTC && ExpectedTC->isFixed() &&
7976 ExpectedTC->getFixedValue() < TinyTripCountVectorThreshold) {
7977 LLVM_DEBUG(dbgs() << "LV: Found a loop with a very small trip count. "
7978 << "This loop is worth vectorizing only if no scalar "
7979 << "iteration overheads are incurred.");
7981 LLVM_DEBUG(dbgs() << " But vectorizing was explicitly forced.\n");
7982 else {
7983 LLVM_DEBUG(dbgs() << "\n");
7984 // Tail-folded loops are efficient even when the loop
7985 // iteration count is low. However, setting the epilogue policy to
7986 // `CM_EpilogueNotAllowedLowTripLoop` prevents vectorizing loops
7987 // with runtime checks. It's more effective to let
7988 // `isOutsideLoopWorkProfitable` determine if vectorization is
7989 // beneficial for the loop.
7992 }
7993 }
7994
7995 // Check the function attributes to see if implicit floats or vectors are
7996 // allowed.
7997 if (F->hasFnAttribute(Attribute::NoImplicitFloat)) {
7999 "Can't vectorize when the NoImplicitFloat attribute is used",
8000 "loop not vectorized due to NoImplicitFloat attribute",
8001 "NoImplicitFloat", ORE, L);
8002 Hints.emitRemarkWithHints();
8003 return false;
8004 }
8005
8006 // Check if the target supports potentially unsafe FP vectorization.
8007 // FIXME: Add a check for the type of safety issue (denormal, signaling)
8008 // for the target we're vectorizing for, to make sure none of the
8009 // additional fp-math flags can help.
8010 if (Hints.isPotentiallyUnsafe() &&
8011 TTI->isFPVectorizationPotentiallyUnsafe()) {
8013 "Potentially unsafe FP op prevents vectorization",
8014 "loop not vectorized due to unsafe FP support.", "UnsafeFP", ORE, L);
8015 Hints.emitRemarkWithHints();
8016 return false;
8017 }
8018
8019 bool AllowOrderedReductions;
8020 // If the flag is set, use that instead and override the TTI behaviour.
8021 if (ForceOrderedReductions.getNumOccurrences() > 0)
8022 AllowOrderedReductions = ForceOrderedReductions;
8023 else
8024 AllowOrderedReductions = TTI->enableOrderedReductions();
8025 if (!LVL.canVectorizeFPMath(AllowOrderedReductions)) {
8026 ORE->emit([&]() {
8027 auto *ExactFPMathInst = Requirements.getExactFPInst();
8028 return OptimizationRemarkAnalysisFPCommute(DEBUG_TYPE, "CantReorderFPOps",
8029 ExactFPMathInst->getDebugLoc(),
8030 ExactFPMathInst->getParent())
8031 << "loop not vectorized: cannot prove it is safe to reorder "
8032 "floating-point operations";
8033 });
8034 LLVM_DEBUG(dbgs() << "LV: loop not vectorized: cannot prove it is safe to "
8035 "reorder floating-point operations\n");
8036 Hints.emitRemarkWithHints();
8037 return false;
8038 }
8039
8040 // Use the cost model.
8041 VFSelectionContext Config(*TTI, &LVL, L, *F, PSE, DB, ORE, &Hints,
8042 OptForSize);
8043 LoopVectorizationCostModel CM(SEL, L, PSE, LI, &LVL, *TTI, TLI, AC, ORE,
8044 GetBFI, F, &Hints, IAI, Config);
8045 // Use the planner for vectorization.
8046 LoopVectorizationPlanner LVP(L, LI, DT, TLI, *TTI, &LVL, CM, Config, IAI, PSE,
8047 Hints, ORE);
8048
8049 EpilogueLowering EpilogueTailLoweringStatus =
8051 if (EpilogueTailLoweringStatus ==
8053 // TODO: Apply tail-folding on the vectorized epilogue loop.
8054 LLVM_DEBUG(dbgs() << "LV: epilogue tail-folding is not supported yet\n");
8056 "The epilogue-tail-folding policy prefer-fold-tail is not supported "
8057 "yet, fall back to a normal epilogue",
8058 "UnsupportedEpilogueTailFoldingPolicy", ORE, L);
8059 }
8060
8061 // Get user vectorization factor and interleave count.
8062 ElementCount UserVF = Hints.getWidth();
8063 unsigned UserIC = Hints.getInterleave();
8064 // Outer loops don't have LoopAccessInfo, so skip the safety check and reset
8065 // UserIC (interleaving is not supported for outer loops).
8066 if (!IsInnerLoop)
8067 UserIC = 0;
8068 else if (UserIC > 1 && !LVL.isSafeForAnyVectorWidth())
8069 UserIC = 1;
8070
8071 // Plan how to best vectorize.
8072 LVP.plan(UserVF, UserIC);
8073 auto [VF, BestPlanPtr] = LVP.computeBestVF();
8074 unsigned IC = 1;
8075
8076 // For VPlan build stress testing of outer loops, bail after plan
8077 // construction.
8078 if (!IsInnerLoop && VPlanBuildOuterloopStressTest)
8079 return false;
8080
8081 if (IsInnerLoop && ORE->allowExtraAnalysis(LV_NAME))
8083
8084 assert((IsInnerLoop || !CM.maskPartialAliasing()) &&
8085 "Did not expect to alias-mask outer loop");
8086
8087 GeneratedRTChecks Checks(PSE, DT, LI, TTI, Config.CostKind,
8088 CM.maskPartialAliasing());
8089 if (IsInnerLoop && LVP.hasPlanWithVF(VF.Width)) {
8090 // Select the interleave count.
8091 IC = LVP.selectInterleaveCount(*BestPlanPtr, VF.Width, VF.Cost);
8092
8093 unsigned SelectedIC = std::max(IC, UserIC);
8094 // Optimistically generate runtime checks if they are needed. Drop them if
8095 // they turn out to not be profitable.
8096 if (VF.Width.isVector() || SelectedIC > 1) {
8097 Checks.create(L, *LVL.getLAI(), PSE.getPredicate(), VF.Width, SelectedIC,
8098 *ORE);
8099
8100 // Bail out early if either the SCEV or memory runtime checks are known to
8101 // fail. In that case, the vector loop would never execute.
8102 using namespace llvm::PatternMatch;
8103 if (Checks.getSCEVChecks().first &&
8104 match(Checks.getSCEVChecks().first, m_One()))
8105 return false;
8106 if (Checks.getMemRuntimeChecks().first &&
8107 match(Checks.getMemRuntimeChecks().first, m_One()))
8108 return false;
8109 }
8110
8111 // Check if it is profitable to vectorize with runtime checks.
8112 bool ForceVectorization =
8114 VPCostContext CostCtx(CM.TTI, *CM.TLI, *BestPlanPtr, CM, Config.CostKind,
8115 CM.PSE, L);
8116 if (!ForceVectorization &&
8117 !isOutsideLoopWorkProfitable(Checks, VF, L, PSE, CostCtx, *BestPlanPtr,
8118 SEL, Config.getVScaleForTuning())) {
8119 ORE->emit([&]() {
8121 DEBUG_TYPE, "CantReorderMemOps", L->getStartLoc(),
8122 L->getHeader())
8123 << "loop not vectorized: cannot prove it is safe to reorder "
8124 "memory operations";
8125 });
8126 LLVM_DEBUG(dbgs() << "LV: Too many memory checks needed.\n");
8127 Hints.emitRemarkWithHints();
8128 return false;
8129 }
8130 }
8131
8132 // Identify the diagnostic messages that should be produced.
8133 std::pair<StringRef, std::string> VecDiagMsg, IntDiagMsg;
8134 bool VectorizeLoop = true, InterleaveLoop = true;
8135 if (VF.Width.isScalar()) {
8136 LLVM_DEBUG(dbgs() << "LV: Vectorization is possible but not beneficial.\n");
8137 VecDiagMsg = {
8138 "VectorizationNotBeneficial",
8139 "the cost-model indicates that vectorization is not beneficial"};
8140 VectorizeLoop = false;
8141 }
8142
8143 if (UserIC == 1 && Hints.getInterleave() > 1) {
8145 "UserIC should only be ignored due to unsafe dependencies");
8146 LLVM_DEBUG(dbgs() << "LV: Ignoring user-specified interleave count.\n");
8147 IntDiagMsg = {"InterleavingUnsafe",
8148 "Ignoring user-specified interleave count due to possibly "
8149 "unsafe dependencies in the loop."};
8150 InterleaveLoop = false;
8151 } else if (!LVP.hasPlanWithVF(VF.Width) && UserIC > 1) {
8152 // Tell the user interleaving was avoided up-front, despite being explicitly
8153 // requested.
8154 LLVM_DEBUG(dbgs() << "LV: Ignoring UserIC, because vectorization and "
8155 "interleaving should be avoided up front\n");
8156 IntDiagMsg = {"InterleavingAvoided",
8157 "Ignoring UserIC, because interleaving was avoided up front"};
8158 InterleaveLoop = false;
8159 } else if (IC == 1 && UserIC <= 1) {
8160 // Tell the user interleaving is not beneficial.
8161 LLVM_DEBUG(dbgs() << "LV: Interleaving is not beneficial.\n");
8162 IntDiagMsg = {
8163 "InterleavingNotBeneficial",
8164 "the cost-model indicates that interleaving is not beneficial"};
8165 InterleaveLoop = false;
8166 if (UserIC == 1) {
8167 IntDiagMsg.first = "InterleavingNotBeneficialAndDisabled";
8168 IntDiagMsg.second +=
8169 " and is explicitly disabled or interleave count is set to 1";
8170 }
8171 } else if (IC > 1 && UserIC == 1) {
8172 // Tell the user interleaving is beneficial, but it explicitly disabled.
8173 LLVM_DEBUG(dbgs() << "LV: Interleaving is beneficial but is explicitly "
8174 "disabled.\n");
8175 IntDiagMsg = {"InterleavingBeneficialButDisabled",
8176 "the cost-model indicates that interleaving is beneficial "
8177 "but is explicitly disabled or interleave count is set to 1"};
8178 InterleaveLoop = false;
8179 }
8180
8181 // If there is a histogram in the loop, do not just interleave without
8182 // vectorizing. The order of operations will be incorrect without the
8183 // histogram intrinsics, which are only used for recipes with VF > 1.
8184 if (!VectorizeLoop && InterleaveLoop && LVL.hasHistograms()) {
8185 LLVM_DEBUG(dbgs() << "LV: Not interleaving without vectorization due "
8186 << "to histogram operations.\n");
8187 IntDiagMsg = {
8188 "HistogramPreventsScalarInterleaving",
8189 "Unable to interleave without vectorization due to constraints on "
8190 "the order of histogram operations"};
8191 InterleaveLoop = false;
8192 }
8193
8194 // Override IC if user provided an interleave count.
8195 IC = UserIC > 0 ? UserIC : IC;
8196
8197 if (CM.maskPartialAliasing()) {
8198 LLVM_DEBUG(
8199 dbgs()
8200 << "LV: Not interleaving due to partial aliasing vectorization.\n");
8201 IntDiagMsg = {
8202 "PartialAliasingVectorization",
8203 "Unable to interleave due to partial aliasing vectorization."};
8204 InterleaveLoop = false;
8205 IC = 1;
8206 }
8207
8208 // FIXME: Enable interleaving for EE-with-side-effects.
8209 if (InterleaveLoop && LVL.hasUncountableExitWithSideEffects()) {
8210 LLVM_DEBUG(dbgs() << "LV: Not interleaving due to EE with side effects.\n");
8211 IntDiagMsg = {"EEWithSideEffectsPreventsInterleaving",
8212 "Unable to interleave due to early exit with side effects."};
8213 InterleaveLoop = false;
8214 IC = 1;
8215 }
8216
8217 // Emit diagnostic messages, if any.
8218 if (!VectorizeLoop && !InterleaveLoop) {
8219 // Do not vectorize or interleaving the loop.
8220 ORE->emit([&]() {
8221 return OptimizationRemarkMissed(LV_NAME, VecDiagMsg.first,
8222 L->getStartLoc(), L->getHeader())
8223 << VecDiagMsg.second;
8224 });
8225 ORE->emit([&]() {
8226 return OptimizationRemarkMissed(LV_NAME, IntDiagMsg.first,
8227 L->getStartLoc(), L->getHeader())
8228 << IntDiagMsg.second;
8229 });
8230 return false;
8231 }
8232
8233 if (!VectorizeLoop && InterleaveLoop) {
8234 LLVM_DEBUG(dbgs() << "LV: Interleave Count is " << IC << '\n');
8235 ORE->emit([&]() {
8236 return OptimizationRemarkAnalysis(LV_NAME, VecDiagMsg.first,
8237 L->getStartLoc(), L->getHeader())
8238 << VecDiagMsg.second;
8239 });
8240 } else if (VectorizeLoop && !InterleaveLoop) {
8241 LLVM_DEBUG(dbgs() << "LV: Found a vectorizable loop (" << VF.Width
8242 << ") in " << L->getLocStr() << '\n');
8243 ORE->emit([&]() {
8244 return OptimizationRemarkAnalysis(LV_NAME, IntDiagMsg.first,
8245 L->getStartLoc(), L->getHeader())
8246 << IntDiagMsg.second;
8247 });
8248 } else if (VectorizeLoop && InterleaveLoop) {
8249 LLVM_DEBUG(dbgs() << "LV: Found a vectorizable loop (" << VF.Width
8250 << ") in " << L->getLocStr() << '\n');
8251 LLVM_DEBUG(dbgs() << "LV: Interleave Count is " << IC << '\n');
8252 }
8253
8254 // Report the vectorization decision.
8255 if (VF.Width.isScalar()) {
8256 using namespace ore;
8257 assert(IC > 1);
8258 ORE->emit([&]() {
8259 return OptimizationRemark(LV_NAME, "Interleaved", L->getStartLoc(),
8260 L->getHeader())
8261 << "interleaved loop (interleaved count: "
8262 << NV("InterleaveCount", IC) << ")";
8263 });
8264 } else {
8265 // Report the vectorization decision.
8266 reportVectorization(ORE, L, VF.Width, IC);
8267 }
8268 if (ORE->allowExtraAnalysis(LV_NAME))
8270
8271 // If we decided that it is *legal* to interleave or vectorize the loop, then
8272 // do it.
8273
8274 VPlan &BestPlan = *BestPlanPtr;
8275 // Consider vectorizing the epilogue too if it's profitable.
8276 std::unique_ptr<VPlan> EpiPlan =
8277 LVP.selectBestEpiloguePlan(BestPlan, VF.Width, IC);
8278 bool HasBranchWeights =
8279 hasBranchWeightMD(*L->getLoopLatch()->getTerminator());
8280 if (EpiPlan) {
8281 VPlan &BestEpiPlan = *EpiPlan;
8282 VPlan &BestMainPlan = BestPlan;
8283 ElementCount EpilogueVF = BestEpiPlan.getSingleVF();
8284
8285 // The first pass vectorizes the main loop and creates a scalar epilogue
8286 // to be vectorized by executing the plan (potentially with a different
8287 // factor) again shortly afterwards.
8288 BestEpiPlan.getMiddleBlock()->setName("vec.epilog.middle.block");
8289 BestEpiPlan.getVectorPreheader()->setName("vec.epilog.ph");
8290 SmallVector<VPInstruction *> ResumeValues =
8291 preparePlanForMainVectorLoop(BestMainPlan, BestEpiPlan);
8292 EpilogueLoopVectorizationInfo EPI(VF.Width, IC, EpilogueVF, 1, BestEpiPlan);
8293
8294 // Add minimum iteration check for the epilogue plan, followed by runtime
8295 // checks for the main plan.
8296 LVP.addMinimumIterationCheck(BestMainPlan, EPI.EpilogueVF, EPI.EpilogueUF,
8298 LVP.attachRuntimeChecks(BestMainPlan, Checks, HasBranchWeights);
8300 EPI.MainLoopVF, EPI.MainLoopUF,
8301 LVP.requiresScalarEpilogue(BestMainPlan, EPI.MainLoopVF), L,
8302 HasBranchWeights ? MinItersBypassWeights : nullptr,
8303 L->getLoopPredecessor()->getTerminator()->getDebugLoc(),
8304 PSE);
8305
8306 EpilogueVectorizerMainLoop MainILV(L, PSE, LI, DT, TTI, AC, EPI, &CM,
8307 Checks, BestMainPlan);
8308 auto ExpandedSCEVs = LVP.executePlan(
8309 EPI.MainLoopVF, EPI.MainLoopUF, BestMainPlan, MainILV, DT,
8311 ++LoopsVectorized;
8312
8313 // Derive EPI fields from VPlan-generated IR.
8314 BasicBlock *EntryBB =
8315 cast<VPIRBasicBlock>(BestMainPlan.getEntry())->getIRBasicBlock();
8316 EntryBB->setName("iter.check");
8317 EPI.EpilogueIterationCountCheck = EntryBB;
8318 // The check chain is: Entry -> [SCEV] -> [Mem] -> MainCheck -> VecPH.
8319 // MainCheck is the non-bypass successor of the last runtime check block
8320 // (or Entry if there are no runtime checks).
8321 BasicBlock *LastCheck = EntryBB;
8322 if (BasicBlock *MemBB = Checks.getMemRuntimeChecks().second)
8323 LastCheck = MemBB;
8324 else if (BasicBlock *SCEVBB = Checks.getSCEVChecks().second)
8325 LastCheck = SCEVBB;
8326 BasicBlock *ScalarPH = L->getLoopPreheader();
8327 auto *BI = cast<CondBrInst>(LastCheck->getTerminator());
8329 BI->getSuccessor(BI->getSuccessor(0) == ScalarPH);
8330
8331 // Second pass vectorizes the epilogue and adjusts the control flow
8332 // edges from the first pass.
8333 EpilogueVectorizerEpilogueLoop EpilogILV(L, PSE, LI, DT, TTI, AC, EPI, &CM,
8334 Checks, BestEpiPlan);
8336 BestMainPlan, BestEpiPlan, L, ExpandedSCEVs, EPI, LVP, Config,
8337 *PSE.getSE(), ResumeValues);
8338 LVP.attachRuntimeChecks(BestEpiPlan, Checks, HasBranchWeights);
8339 LVP.executePlan(
8340 EPI.EpilogueVF, EPI.EpilogueUF, BestEpiPlan, EpilogILV, DT,
8342 connectEpilogueVectorLoop(BestEpiPlan, L, EPI, DT, Checks, InstsToMove,
8343 ResumeValues);
8344 ++LoopsEpilogueVectorized;
8345 } else {
8346 InnerLoopVectorizer LB(L, PSE, LI, DT, TTI, AC, VF.Width, IC, &CM, Checks,
8347 BestPlan);
8348 LVP.addMinimumIterationCheck(BestPlan, VF.Width, IC,
8349 VF.MinProfitableTripCount);
8350 LVP.attachRuntimeChecks(BestPlan, Checks, HasBranchWeights);
8351
8352 if (!IsInnerLoop)
8353 LLVM_DEBUG(dbgs() << "Vectorizing outer loop in \"" << F->getName()
8354 << "\"\n");
8355 LVP.executePlan(VF.Width, IC, BestPlan, LB, DT);
8356 ++LoopsVectorized;
8357 }
8358
8359 assert(DT->verify(DominatorTree::VerificationLevel::Fast) &&
8360 "DT not preserved correctly");
8361 assert(!verifyFunction(*F, &dbgs()));
8362
8363 return true;
8364}
8365
8367
8368 // Don't attempt if
8369 // 1. the target claims to have no vector registers, and
8370 // 2. interleaving won't help ILP.
8371 //
8372 // The second condition is necessary because, even if the target has no
8373 // vector registers, loop vectorization may still enable scalar
8374 // interleaving.
8375 if (!TTI->getNumberOfRegisters(TTI->getRegisterClassForType(true)) &&
8376 (TTI->getMaxInterleaveFactor(ElementCount::getFixed(1), false) < 2 ||
8377 TTI->getMaxInterleaveFactor(ElementCount::getFixed(1), true) < 2))
8378 return LoopVectorizeResult(false, false);
8379
8380 bool Changed = false, CFGChanged = false;
8381
8382 // The vectorizer requires loops to be in simplified form.
8383 // Since simplification may add new inner loops, it has to run before the
8384 // legality and profitability checks. This means running the loop vectorizer
8385 // will simplify all loops, regardless of whether anything end up being
8386 // vectorized.
8387 for (const auto &L : *LI)
8388 Changed |= CFGChanged |=
8389 simplifyLoop(L, DT, LI, SE, AC, nullptr, false /* PreserveLCSSA */);
8390
8391 // Build up a worklist of inner-loops to vectorize. This is necessary as
8392 // the act of vectorizing or partially unrolling a loop creates new loops
8393 // and can invalidate iterators across the loops.
8394 SmallVector<Loop *, 8> Worklist;
8395
8396 for (Loop *L : *LI)
8397 collectSupportedLoops(*L, LI, ORE, Worklist);
8398
8399 LoopsAnalyzed += Worklist.size();
8400
8401 // Now walk the identified inner loops.
8402 while (!Worklist.empty()) {
8403 Loop *L = Worklist.pop_back_val();
8404
8405 // For the inner loops we actually process, form LCSSA to simplify the
8406 // transform.
8407 Changed |= formLCSSARecursively(*L, *DT, LI, SE);
8408
8409 Changed |= CFGChanged |= processLoop(L);
8410
8411 if (Changed) {
8412 LAIs->clear();
8413
8414#ifndef NDEBUG
8415 if (VerifySCEV)
8416 SE->verify();
8417#endif
8418 }
8419 }
8420
8421 // Process each loop nest in the function.
8422 return LoopVectorizeResult(Changed, CFGChanged);
8423}
8424
8427 LI = &AM.getResult<LoopAnalysis>(F);
8428 // There are no loops in the function. Return before computing other
8429 // expensive analyses.
8430 if (LI->empty())
8431 return PreservedAnalyses::all();
8440 AA = &AM.getResult<AAManager>(F);
8441
8442 auto &MAMProxy = AM.getResult<ModuleAnalysisManagerFunctionProxy>(F);
8443 PSI = MAMProxy.getCachedResult<ProfileSummaryAnalysis>(*F.getParent());
8444 GetBFI = [&AM, &F]() -> BlockFrequencyInfo & {
8446 };
8447 LoopVectorizeResult Result = runImpl(F);
8448 if (!Result.MadeAnyChange)
8449 return PreservedAnalyses::all();
8451
8452 if (isAssignmentTrackingEnabled(*F.getParent())) {
8453 for (auto &BB : F)
8455 }
8456
8457 PA.preserve<LoopAnalysis>();
8461
8462 if (Result.MadeCFGChange) {
8463 // Making CFG changes likely means a loop got vectorized. Indicate that
8464 // extra simplification passes should be run.
8465 // TODO: MadeCFGChanges is not a prefect proxy. Extra passes should only
8466 // be run if runtime checks have been added.
8469 } else {
8471 }
8472 return PA;
8473}
8474
8476 raw_ostream &OS, function_ref<StringRef(StringRef)> MapClassName2PassName) {
8477 static_cast<PassInfoMixin<LoopVectorizePass> *>(this)->printPipeline(
8478 OS, MapClassName2PassName);
8479
8480 OS << '<';
8481 OS << (InterleaveOnlyWhenForced ? "" : "no-") << "interleave-forced-only;";
8482 OS << (VectorizeOnlyWhenForced ? "" : "no-") << "vectorize-forced-only;";
8483 OS << '>';
8484}
for(const MachineOperand &MO :llvm::drop_begin(OldMI.operands(), Desc.getNumOperands()))
static unsigned getIntrinsicID(const SDNode *N)
assert(UImm &&(UImm !=~static_cast< T >(0)) &&"Invalid immediate!")
AMDGPU Lower Kernel Arguments
This file implements a class to represent arbitrary precision integral constant values and operations...
MachineBasicBlock MachineBasicBlock::iterator DebugLoc DL
static bool isEqual(const Function &Caller, const Function &Callee)
This file contains the simple types necessary to represent the attributes associated with functions a...
static const Function * getParent(const Value *V)
This is the interface for LLVM's primary stateless and local alias analysis.
static bool IsEmptyBlock(MachineBasicBlock *MBB)
static GCRegistry::Add< ErlangGC > A("erlang", "erlang-compatible garbage collector")
static GCRegistry::Add< CoreCLRGC > E("coreclr", "CoreCLR-compatible GC")
static GCRegistry::Add< OcamlGC > B("ocaml", "ocaml 3.10-compatible GC")
#define clEnumValN(ENUMVAL, FLAGNAME, DESC)
This file contains the declarations for the subclasses of Constant, which represent the different fla...
static cl::opt< OutputCostKind > CostKind("cost-kind", cl::desc("Target cost kind"), cl::init(OutputCostKind::RecipThroughput), cl::values(clEnumValN(OutputCostKind::RecipThroughput, "throughput", "Reciprocal throughput"), clEnumValN(OutputCostKind::Latency, "latency", "Instruction latency"), clEnumValN(OutputCostKind::CodeSize, "code-size", "Code size"), clEnumValN(OutputCostKind::SizeAndLatency, "size-latency", "Code size and latency"), clEnumValN(OutputCostKind::All, "all", "Print all cost kinds")))
static InstructionCost getCost(Instruction &Inst, TTI::TargetCostKind CostKind, TargetTransformInfo &TTI)
Definition CostModel.cpp:73
This file defines DenseMapInfo traits for DenseMap.
This file defines the DenseMap class.
#define DEBUG_TYPE
This is the interface for a simple mod/ref and alias analysis over globals.
Hexagon Common GEP
This file provides various utilities for inspecting and working with the control flow graph in LLVM I...
Module.h This file contains the declarations for the Module class.
This defines the Use class.
static bool hasNoUnsignedWrap(BinaryOperator &I)
This file defines an InstructionCost class that is used when calculating the cost of an instruction,...
const AbstractManglingParser< Derived, Alloc >::OperatorInfo AbstractManglingParser< Derived, Alloc >::Ops[]
static cl::opt< ElementCount, true > VectorizationFactor("force-vector-width", cl::Hidden, cl::desc("Sets the SIMD width. Zero is autoselect."), cl::location(VectorizerParams::VectorizationFactor))
This header provides classes for managing per-loop analyses.
static const char * VerboseDebug
#define LV_NAME
This file defines the LoopVectorizationLegality class.
cl::opt< bool > VPlanBuildOuterloopStressTest
static cl::opt< bool > ConsiderRegPressure("vectorizer-consider-reg-pressure", cl::init(false), cl::Hidden, cl::desc("Discard VFs if their register pressure is too high."))
This file provides a LoopVectorizationPlanner class.
static void collectSupportedLoops(Loop &L, LoopInfo *LI, OptimizationRemarkEmitter *ORE, SmallVectorImpl< Loop * > &V)
static cl::opt< unsigned > EpilogueVectorizationMinVF("epilogue-vectorization-minimum-VF", cl::Hidden, cl::desc("Only loops with vectorization factor equal to or larger than " "the specified value are considered for epilogue vectorization."))
static unsigned getMaxTCFromNonZeroRange(PredicatedScalarEvolution &PSE, Loop *L)
Get the maximum trip count for L from the SCEV unsigned range, excluding zero from the range.
static SmallVector< Instruction * > preparePlanForEpilogueVectorLoop(VPlan &MainPlan, VPlan &Plan, Loop *L, const SCEV2ValueTy &ExpandedSCEVs, EpilogueLoopVectorizationInfo &EPI, LoopVectorizationPlanner &LVP, VFSelectionContext &Config, ScalarEvolution &SE, ArrayRef< VPInstruction * > ResumeValues)
Prepare Plan for vectorizing the epilogue loop.
static Type * maybeVectorizeType(Type *Ty, ElementCount VF)
static ElementCount getSmallConstantTripCount(ScalarEvolution *SE, const Loop *L)
A version of ScalarEvolution::getSmallConstantTripCount that returns an ElementCount to include loops...
static bool hasUnsupportedHeaderPhiRecipe(VPlan &Plan)
Returns true if the VPlan contains header phi recipes that are not currently supported for epilogue v...
static cl::opt< unsigned > VectorizeMemoryCheckThreshold("vectorize-memory-check-threshold", cl::init(128), cl::Hidden, cl::desc("The maximum allowed number of runtime memory checks"))
static void connectEpilogueVectorLoop(VPlan &EpiPlan, Loop *L, EpilogueLoopVectorizationInfo &EPI, DominatorTree *DT, GeneratedRTChecks &Checks, ArrayRef< Instruction * > InstsToMove, ArrayRef< VPInstruction * > ResumeValues)
Connect the epilogue vector loop generated for EpiPlan to the main vector loop, after both plans have...
static cl::opt< unsigned > TinyTripCountVectorThreshold("vectorizer-min-trip-count", cl::init(16), cl::Hidden, cl::desc("Loops with a constant trip count that is smaller than this " "value are vectorized only if no scalar iteration overheads " "are incurred."))
Loops with a known constant trip count below this number are vectorized only if no scalar iteration o...
static cl::opt< unsigned > PragmaVectorizeSCEVCheckThreshold("pragma-vectorize-scev-check-threshold", cl::init(128), cl::Hidden, cl::desc("The maximum number of SCEV checks allowed with a " "vectorize(enable) pragma"))
static cl::opt< cl::boolOrDefault > ForceMaskedDivRem("force-widen-divrem-via-masked-intrinsic", cl::Hidden, cl::desc("Override cost based masked intrinsic widening " "for div/rem instructions"))
static void legacyCSE(BasicBlock *BB)
FIXME: This legacy common-subexpression-elimination routine is scheduled for removal,...
static VPIRBasicBlock * replaceVPBBWithIRVPBB(VPBasicBlock *VPBB, BasicBlock *IRBB, VPlan *Plan=nullptr)
Replace VPBB with a VPIRBasicBlock wrapping IRBB.
static Intrinsic::ID getMaskedDivRemIntrinsic(unsigned Opcode)
static DebugLoc getDebugLocFromInstOrOperands(Instruction *I)
Look for a meaningful debug location on the instruction or its operands.
TailFoldingPolicyTy
Option tail-folding-policy controls the tail-folding strategy and lists all available options.
static bool useActiveLaneMaskForControlFlow(TailFoldingStyle Style)
static cl::opt< TailFoldingPolicyTy > EpilogueTailFoldingPolicy("epilogue-tail-folding-policy", cl::Hidden, cl::desc("Epilogue-tail-folding preferences over creating an epilogue loop."), cl::values(clEnumValN(TailFoldingPolicyTy::None, "dont-fold-tail", "Don't tail-fold loops."), clEnumValN(TailFoldingPolicyTy::PreferFoldTail, "prefer-fold-tail", "prefer tail-folding, otherwise create an epilogue when " "appropriate.")))
static cl::opt< bool > EnableEarlyExitVectorization("enable-early-exit-vectorization", cl::init(true), cl::Hidden, cl::desc("Enable vectorization of early exit loops with uncountable exits."))
static unsigned estimateElementCount(ElementCount VF, std::optional< unsigned > VScale)
This function attempts to return a value that represents the ElementCount at runtime.
static bool hasVectorLibraryVariantFor(const CallInst &CI, ElementCount VF, bool MaskRequired, const TargetLibraryInfo *TLI)
Returns true iff CI has a library vector variant usable at VF.
static constexpr uint32_t MinItersBypassWeights[]
static cl::opt< unsigned > ForceTargetNumScalarRegs("force-target-num-scalar-regs", cl::init(0), cl::Hidden, cl::desc("A flag that overrides the target's number of scalar registers."))
static SmallVector< VPInstruction * > preparePlanForMainVectorLoop(VPlan &MainPlan, VPlan &EpiPlan)
Prepare MainPlan for vectorizing the main vector loop during epilogue vectorization.
static cl::opt< unsigned > SmallLoopCost("small-loop-cost", cl::init(20), cl::Hidden, cl::desc("The cost of a loop that is considered 'small' by the interleaver."))
static cl::opt< bool > ForcePartialAliasingVectorization("force-partial-aliasing-vectorization", cl::init(false), cl::Hidden, cl::desc("Replace pointer diff checks with alias masks."))
static Function * getVectorLibraryVariantFor(const CallInst &CI, ElementCount VF, bool MaskRequired, const TargetLibraryInfo *TLI)
Returns the vector library variant function of CI usable at VF, respecting MaskRequired,...
static cl::opt< unsigned > ForceTargetNumVectorRegs("force-target-num-vector-regs", cl::init(0), cl::Hidden, cl::desc("A flag that overrides the target's number of vector registers."))
static bool isExplicitVecOuterLoop(Loop *OuterLp, OptimizationRemarkEmitter *ORE)
static cl::opt< bool > EnableIndVarRegisterHeur("enable-ind-var-reg-heur", cl::init(true), cl::Hidden, cl::desc("Count the induction variable only once when interleaving"))
static bool hasForcedEpilogueVF()
static cl::opt< TailFoldingStyle > ForceTailFoldingStyle("force-tail-folding-style", cl::desc("Force the tail folding style"), cl::init(TailFoldingStyle::None), cl::values(clEnumValN(TailFoldingStyle::None, "none", "Disable tail folding"), clEnumValN(TailFoldingStyle::Data, "data", "Create lane mask for data only, using active.lane.mask intrinsic"), clEnumValN(TailFoldingStyle::DataWithoutLaneMask, "data-without-lane-mask", "Create lane mask with compare/stepvector"), clEnumValN(TailFoldingStyle::DataAndControlFlow, "data-and-control", "Create lane mask using active.lane.mask intrinsic, and use " "it for both data and control flow"), clEnumValN(TailFoldingStyle::DataWithEVL, "data-with-evl", "Use predicated EVL instructions for tail folding. If EVL " "is unsupported, fallback to data-without-lane-mask.")))
static void printOptimizedVPlan(VPlan &)
static cl::opt< bool > EnableEpilogueVectorization("enable-epilogue-vectorization", cl::init(true), cl::Hidden, cl::desc("Enable vectorization of epilogue loops."))
static cl::opt< bool > PreferPredicatedReductionSelect("prefer-predicated-reduction-select", cl::init(false), cl::Hidden, cl::desc("Prefer predicating a reduction operation over an after loop select."))
static const SCEV * getAddressAccessSCEV(Value *Ptr, PredicatedScalarEvolution &PSE, const Loop *TheLoop)
Gets the address access SCEV for Ptr, if it should be used for cost modeling according to isAddressSC...
static cl::opt< bool > EnableLoadStoreRuntimeInterleave("enable-loadstore-runtime-interleave", cl::init(true), cl::Hidden, cl::desc("Enable runtime interleaving until load/store ports are saturated"))
static cl::opt< bool > LoopVectorizeWithBlockFrequency("loop-vectorize-with-block-frequency", cl::init(true), cl::Hidden, cl::desc("Enable the use of the block frequency analysis to access PGO " "heuristics minimizing code growth in cold regions and being more " "aggressive in hot regions."))
static bool useActiveLaneMask(TailFoldingStyle Style)
static bool hasReplicatorRegion(VPlan &Plan)
static std::optional< ElementCount > getSmallBestKnownTC(PredicatedScalarEvolution &PSE, Loop *L, bool CanUseConstantMax=true, bool CanExcludeZeroTrips=false, bool ComputeUpperBoundOnly=false)
Returns "best known" trip count, which is either a valid positive trip count or std::nullopt when an ...
static EpilogueLowering getEpilogueTailLowering(const LoopVectorizationCostModel &MainCM, const Loop *L, OptimizationRemarkEmitter *ORE)
Determine how to lower the epilogue for the vector epilogue loop.
static bool isIndvarOverflowCheckKnownFalse(const LoopVectorizationCostModel *Cost, ElementCount VF, std::optional< unsigned > UF=std::nullopt)
For the given VF and UF and maximum trip count computed for the loop, return whether the induction va...
static void addFullyUnrolledInstructionsToIgnore(Loop *L, const LoopVectorizationLegality::InductionList &IL, SmallPtrSetImpl< Instruction * > &InstsToIgnore)
Knowing that loop L executes a single vector iteration, add instructions that will get simplified and...
static bool hasFindLastReductionPhi(VPlan &Plan)
Returns true if the VPlan contains a VPReductionPHIRecipe with FindLast recurrence kind.
static cl::opt< bool > EnableInterleavedMemAccesses("enable-interleaved-mem-accesses", cl::init(false), cl::Hidden, cl::desc("Enable vectorization on interleaved memory accesses in a loop"))
static cl::opt< unsigned > VectorizeSCEVCheckThreshold("vectorize-scev-check-threshold", cl::init(16), cl::Hidden, cl::desc("The maximum number of SCEV checks allowed."))
static cl::opt< bool > EnableMaskedInterleavedMemAccesses("enable-masked-interleaved-mem-accesses", cl::init(false), cl::Hidden, cl::desc("Enable vectorization on masked interleaved memory accesses in a loop"))
An interleave-group may need masking if it resides in a block that needs predication,...
static cl::opt< bool > ForceOrderedReductions("force-ordered-reductions", cl::init(false), cl::Hidden, cl::desc("Enable the vectorisation of loops with in-order (strict) " "FP reductions"))
static cl::opt< bool > EnableEarlyExitVectorizationWithSideEffects("enable-early-exit-vectorization-with-side-effects", cl::init(false), cl::Hidden, cl::desc("Enable vectorization of early exit loops with uncountable exits " "and side effects"))
static cl::opt< TailFoldingPolicyTy > TailFoldingPolicy("tail-folding-policy", cl::init(TailFoldingPolicyTy::None), cl::Hidden, cl::desc("Tail-folding preferences over creating an epilogue loop."), cl::values(clEnumValN(TailFoldingPolicyTy::None, "dont-fold-tail", "Don't tail-fold loops."), clEnumValN(TailFoldingPolicyTy::PreferFoldTail, "prefer-fold-tail", "prefer tail-folding, otherwise create an epilogue when " "appropriate."), clEnumValN(TailFoldingPolicyTy::MustFoldTail, "must-fold-tail", "always tail-fold, don't attempt vectorization if " "tail-folding fails.")))
static bool isOutsideLoopWorkProfitable(GeneratedRTChecks &Checks, VectorizationFactor &VF, Loop *L, PredicatedScalarEvolution &PSE, VPCostContext &CostCtx, VPlan &Plan, EpilogueLowering SEL, std::optional< unsigned > VScale)
This function determines whether or not it's still profitable to vectorize the loop given the extra w...
static InstructionCost calculateEarlyExitCost(VPCostContext &CostCtx, VPlan &Plan, ElementCount VF)
For loops with uncountable early exits, find the cost of doing work when exiting the loop early,...
cl::opt< bool > VPlanBuildOuterloopStressTest("vplan-build-outerloop-stress-test", cl::init(false), cl::Hidden, cl::desc("Build VPlan for every supported loop nest in the function and bail " "out right after the build (stress test the VPlan H-CFG construction " "in the VPlan-native vectorization path)."))
static cl::opt< unsigned > ForceTargetMaxVectorInterleaveFactor("force-target-max-vector-interleave", cl::init(0), cl::Hidden, cl::desc("A flag that overrides the target's max interleave factor for " "vectorized loops."))
static bool useMaskedInterleavedAccesses(const TargetTransformInfo &TTI)
cl::opt< unsigned > NumberOfStoresToPredicate("vectorize-num-stores-pred", cl::init(1), cl::Hidden, cl::desc("Max number of stores to be predicated behind an if."))
The number of stores in a loop that are allowed to need predication.
static EpilogueLowering getEpilogueLowering(Function *F, Loop *L, LoopVectorizeHints &Hints, bool OptForSize, TargetTransformInfo *TTI, TargetLibraryInfo *TLI, LoopVectorizationLegality &LVL, InterleavedAccessInfo *IAI)
static void fixScalarResumeValuesFromBypass(BasicBlock *BypassBlock, Loop *L, VPlan &BestEpiPlan, ArrayRef< VPInstruction * > ResumeValues)
static cl::opt< unsigned > MaxNestedScalarReductionIC("max-nested-scalar-reduction-interleave", cl::init(2), cl::Hidden, cl::desc("The maximum interleave count to use when interleaving a scalar " "reduction in a nested loop."))
static cl::opt< unsigned > ForceTargetMaxScalarInterleaveFactor("force-target-max-scalar-interleave", cl::init(0), cl::Hidden, cl::desc("A flag that overrides the target's max interleave factor for " "scalar loops."))
static void checkMixedPrecision(Loop *L, OptimizationRemarkEmitter *ORE)
static cl::opt< ElementCount > EpilogueVectorizationForceVF("epilogue-vectorization-force-VF", cl::init(ElementCount::getFixed(1)), cl::Hidden, cl::desc("When epilogue vectorization is enabled, and a value greater than " "1 is specified, forces the given VF for all applicable epilogue " "loops. Note: This allows all scalable VFs >= vscale x 1."))
static bool willGenerateVectors(VPlan &Plan, ElementCount VF, const TargetTransformInfo &TTI)
Check if any recipe of Plan will generate a vector value, which will be assigned a vector register.
#define F(x, y, z)
Definition MD5.cpp:54
#define I(x, y, z)
Definition MD5.cpp:57
This file implements a map that provides insertion order iteration.
This file contains the declarations for metadata subclasses.
ConstantRange Range(APInt(BitWidth, Low), APInt(BitWidth, High))
uint64_t IntrinsicInst * II
#define P(N)
This file contains the declarations for profiling metadata utility functions.
const SmallVectorImpl< MachineOperand > & Cond
static InstructionCost getScalarizationOverhead(const TargetTransformInfo &TTI, Type *ScalarTy, VectorType *Ty, const APInt &DemandedElts, bool Insert, bool Extract, TTI::TargetCostKind CostKind, bool ForPoisonSrc=true, ArrayRef< Value * > VL={}, TTI::VectorInstrContext VIC=TTI::VectorInstrContext::None)
This is similar to TargetTransformInfo::getScalarizationOverhead, but if ScalarTy is a FixedVectorTyp...
Func getContext().diagnose(DiagnosticInfoUnsupported(Func
This file contains some templates that are useful if you are working with the STL at all.
#define OP(OPC)
Definition Instruction.h:46
This file defines the SmallPtrSet class.
This file defines the SmallVector class.
This file defines the 'Statistic' class, which is designed to be an easy way to expose various metric...
#define STATISTIC(VARNAME, DESC)
Definition Statistic.h:171
#define LLVM_DEBUG(...)
Definition Debug.h:119
#define DEBUG_WITH_TYPE(TYPE,...)
DEBUG_WITH_TYPE macro - This macro should be used by passes to emit debug information.
Definition Debug.h:72
This pass exposes codegen information to IR-level passes.
LocallyHashedType DenseMapInfo< LocallyHashedType >::Empty
This file implements the TypeSwitch template, which mimics a switch() statement whose cases are type ...
This file contains the declarations of different VPlan-related auxiliary helpers.
This file provides utility VPlan to VPlan transformations.
#define RUN_VPLAN_PASS(PASS,...)
#define RUN_VPLAN_PASS_NO_VERIFY(PASS,...)
This file declares the class VPlanVerifier, which contains utility functions to check the consistency...
This file contains the declarations of the Vectorization Plan base classes:
Value * RHS
Value * LHS
static const uint32_t IV[8]
Definition blake3_impl.h:83
A manager for alias analyses.
static constexpr roundingMode rmTowardZero
Definition APFloat.h:349
static const fltSemantics & IEEEdouble()
Definition APFloat.h:298
Class for arbitrary precision integers.
Definition APInt.h:78
static APInt getAllOnes(unsigned numBits)
Return an APInt of a specified width with all bits set.
Definition APInt.h:235
uint64_t getZExtValue() const
Get zero extended value.
Definition APInt.h:1565
unsigned getActiveBits() const
Compute the number of active bits in the value.
Definition APInt.h:1537
bool isZero() const
Determine if this value is zero, i.e. all bits are clear.
Definition APInt.h:381
PassT::Result & getResult(IRUnitT &IR, ExtraArgTs... ExtraArgs)
Get the result of an analysis pass for a given IR unit.
Represent a constant reference to an array (0 or more elements consecutively in memory),...
Definition ArrayRef.h:40
size_t size() const
Get the array size.
Definition ArrayRef.h:141
A function analysis which provides an AssumptionCache.
A cache of @llvm.assume calls within a function.
LLVM Basic Block Representation.
Definition BasicBlock.h:62
iterator_range< const_phi_iterator > phis() const
Returns a range that iterates over the phis in the basic block.
Definition BasicBlock.h:530
const Function * getParent() const
Return the enclosing method, or null if none.
Definition BasicBlock.h:213
LLVM_ABI InstListType::const_iterator getFirstNonPHIIt() const
Returns an iterator to the first instruction in this block that is not a PHINode instruction.
LLVM_ABI const BasicBlock * getSinglePredecessor() const
Return the predecessor of this block if it has a single predecessor block.
LLVM_ABI const BasicBlock * getSingleSuccessor() const
Return the successor of this block if it has a single successor.
LLVM_ABI LLVMContext & getContext() const
Get the context in which this basic block lives.
const Instruction * getTerminator() const LLVM_READONLY
Returns the terminator instruction; assumes that the block is well-formed.
Definition BasicBlock.h:237
Analysis pass which computes BlockFrequencyInfo.
BlockFrequencyInfo pass uses BlockFrequencyInfoImpl implementation to estimate IR basic block frequen...
Represents analyses that only rely on functions' control flow.
Definition Analysis.h:73
Base class for all callable instructions (InvokeInst and CallInst) Holds everything related to callin...
bool isNoBuiltin() const
Return true if the call should not be treated as a call to a builtin.
Function * getCalledFunction() const
Returns the function called, or null if this is an indirect function invocation or the function signa...
iterator_range< User::op_iterator > args()
Iteration adapter for range-for loops.
This class represents a function call, abstracting a target machine's calling convention.
static Type * makeCmpResultType(Type *opnd_type)
Create a result type for fcmp/icmp.
Predicate
This enumeration lists the possible predicates for CmpInst subclasses.
Definition InstrTypes.h:740
@ ICMP_UGT
unsigned greater than
Definition InstrTypes.h:763
@ ICMP_ULT
unsigned less than
Definition InstrTypes.h:765
Conditional Branch instruction.
BasicBlock * getSuccessor(unsigned i) const
This is the shared class of boolean and integer constants.
Definition Constants.h:87
static LLVM_ABI ConstantInt * getTrue(LLVMContext &Context)
This class represents a range of values.
LLVM_ABI APInt getUnsignedMax() const
Return the largest unsigned value contained in the ConstantRange.
A debug info location.
Definition DebugLoc.h:126
static DebugLoc getTemporary()
Definition DebugLoc.h:152
static DebugLoc getUnknown()
Definition DebugLoc.h:153
An analysis that produces DemandedBits for a function.
ValueT & at(const_arg_type_t< KeyT > Val)
Return the entry for the specified key, or abort if no such entry exists.
Definition DenseMap.h:268
ValueT lookup(const_arg_type_t< KeyT > Val) const
Return the entry for the specified key, or a default constructed value if no such entry exists.
Definition DenseMap.h:250
iterator find(const_arg_type_t< KeyT > Val)
Definition DenseMap.h:223
std::pair< iterator, bool > try_emplace(KeyT &&Key, Ts &&...Args)
Definition DenseMap.h:299
iterator end()
Definition DenseMap.h:141
bool contains(const_arg_type_t< KeyT > Val) const
Return true if the specified key is in the map, false otherwise.
Definition DenseMap.h:214
void insert_range(Range &&R)
Inserts range of 'std::pair<KeyT, ValueT>' values into the map.
Definition DenseMap.h:337
ValueT lookup_or(const_arg_type_t< KeyT > Val, U &&Default) const
Definition DenseMap.h:260
Implements a dense probed hash-table based set.
Definition DenseSet.h:281
Analysis pass which computes a DominatorTree.
Definition Dominators.h:270
void changeImmediateDominator(DomTreeNodeBase< NodeT > *N, DomTreeNodeBase< NodeT > *NewIDom)
changeImmediateDominator - This method is used to update the dominator tree information when a node's...
void eraseNode(NodeT *BB)
eraseNode - Removes a node from the dominator tree.
Concrete subclass of DominatorTreeBase that is used to compute a normal dominator tree.
Definition Dominators.h:151
constexpr bool isVector() const
One or more elements.
Definition TypeSize.h:324
static constexpr ElementCount getScalable(ScalarTy MinVal)
Definition TypeSize.h:312
static constexpr ElementCount getFixed(ScalarTy MinVal)
Definition TypeSize.h:309
static constexpr ElementCount get(ScalarTy MinVal, bool Scalable)
Definition TypeSize.h:315
constexpr bool isScalar() const
Exactly one element.
Definition TypeSize.h:320
EpilogueVectorizerEpilogueLoop(Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI, DominatorTree *DT, const TargetTransformInfo *TTI, AssumptionCache *AC, EpilogueLoopVectorizationInfo &EPI, LoopVectorizationCostModel *CM, GeneratedRTChecks &Checks, VPlan &Plan)
BasicBlock * createVectorizedLoopSkeleton() final
Implements the interface for creating a vectorized skeleton using the epilogue loop strategy (i....
void printDebugTracesAtStart() override
Allow subclasses to override and print debug traces before/after vplan execution, when trace informat...
A specialized derived class of inner loop vectorizer that performs vectorization of main loops in the...
void printDebugTracesAtStart() override
Allow subclasses to override and print debug traces before/after vplan execution, when trace informat...
EpilogueVectorizerMainLoop(Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI, DominatorTree *DT, const TargetTransformInfo *TTI, AssumptionCache *AC, EpilogueLoopVectorizationInfo &EPI, LoopVectorizationCostModel *CM, GeneratedRTChecks &Check, VPlan &Plan)
Convenience struct for specifying and reasoning about fast-math flags.
Definition FMF.h:23
Class to represent function types.
param_iterator param_begin() const
param_iterator param_end() const
FunctionType * getFunctionType() const
Returns the FunctionType for me.
Definition Function.h:211
void applyUpdates(ArrayRef< UpdateT > Updates)
Submit updates to all available trees.
Common base class shared among various IRBuilders.
Definition IRBuilder.h:114
This provides a uniform API for creating instructions and inserting them into a basic block: either a...
Definition IRBuilder.h:2893
A struct for saving information about induction variables.
const SCEV * getStep() const
ArrayRef< Instruction * > getCastInsts() const
Returns an ArrayRef to the type cast instructions in the induction update chain, that are redundant w...
@ IK_PtrInduction
Pointer induction var. Step = C.
InnerLoopAndEpilogueVectorizer(Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI, DominatorTree *DT, const TargetTransformInfo *TTI, AssumptionCache *AC, EpilogueLoopVectorizationInfo &EPI, LoopVectorizationCostModel *CM, GeneratedRTChecks &Checks, VPlan &Plan, ElementCount VecWidth, unsigned UnrollFactor)
EpilogueLoopVectorizationInfo & EPI
Holds and updates state information required to vectorize the main loop and its epilogue in two separ...
InnerLoopVectorizer vectorizes loops which contain only one basic block to a specified vectorization ...
virtual void printDebugTracesAtStart()
Allow subclasses to override and print debug traces before/after vplan execution, when trace informat...
const TargetTransformInfo * TTI
Target Transform Info.
LoopVectorizationCostModel * Cost
The profitablity analysis.
friend class LoopVectorizationPlanner
InnerLoopVectorizer(Loop *OrigLoop, PredicatedScalarEvolution &PSE, LoopInfo *LI, DominatorTree *DT, const TargetTransformInfo *TTI, AssumptionCache *AC, ElementCount VecWidth, unsigned UnrollFactor, LoopVectorizationCostModel *CM, GeneratedRTChecks &RTChecks, VPlan &Plan)
PredicatedScalarEvolution & PSE
A wrapper around ScalarEvolution used to add runtime SCEV checks.
LoopInfo * LI
Loop Info.
DominatorTree * DT
Dominator Tree.
void fixVectorizedLoop(VPTransformState &State)
Fix the vectorized code, taking care of header phi's, and more.
virtual BasicBlock * createVectorizedLoopSkeleton()
Creates a basic block for the scalar preheader.
virtual void printDebugTracesAtEnd()
AssumptionCache * AC
Assumption Cache.
IRBuilder Builder
The builder that we use.
VPBasicBlock * VectorPHVPBB
The vector preheader block of Plan, used as target for check blocks introduced during skeleton creati...
unsigned UF
The vectorization unroll factor to use.
GeneratedRTChecks & RTChecks
Structure to hold information about generated runtime checks, responsible for cleaning the checks,...
virtual ~InnerLoopVectorizer()=default
ElementCount VF
The vectorization SIMD factor to use.
Loop * OrigLoop
The original loop.
BasicBlock * createScalarPreheader(StringRef Prefix)
Create and return a new IR basic block for the scalar preheader whose name is prefixed with Prefix.
static InstructionCost getInvalid(CostType Val=0)
static InstructionCost getMax()
CostType getValue() const
This function is intended to be used as sparingly as possible, since the class provides the full rang...
bool isCast() const
LLVM_ABI const Module * getModule() const
Return the module owning the function this instruction belongs to or nullptr it the function does not...
LLVM_ABI void moveBefore(InstListType::iterator InsertPos)
Unlink this instruction from its current basic block and insert it into the basic block that MovePos ...
LLVM_ABI InstListType::iterator eraseFromParent()
This method unlinks 'this' from the containing basic block and deletes it.
Instruction * user_back()
Specialize the methods defined in Value, as we know that an instruction can only be used by other ins...
const char * getOpcodeName() const
unsigned getOpcode() const
Returns a member of one of the enums like Instruction::Add.
Class to represent integer types.
static LLVM_ABI IntegerType * get(LLVMContext &C, unsigned NumBits)
This static method is the primary way of constructing an IntegerType.
Definition Type.cpp:348
LLVM_ABI APInt getMask() const
For example, this is 0xFF for an 8 bit integer, 0xFFFF for i16, etc.
Definition Type.cpp:372
The group of interleaved loads/stores sharing the same stride and close to each other.
auto members() const
Return an iterator range over the non-null members of this group, in index order.
InstTy * getInsertPos() const
uint32_t getNumMembers() const
Drive the analysis of interleaved memory accesses in the loop.
bool requiresScalarEpilogue() const
Returns true if an interleaved group that may access memory out-of-bounds requires a scalar epilogue ...
LLVM_ABI void analyzeInterleaving(bool EnableMaskedInterleavedGroup)
Analyze the interleaved accesses and collect them in interleave groups.
An instruction for reading from memory.
Type * getPointerOperandType() const
This analysis provides dependence information for the memory accesses of a loop.
const RuntimePointerChecking * getRuntimePointerChecking() const
unsigned getNumRuntimePointerChecks() const
Number of memchecks required to prove independence of otherwise may-alias pointers.
const DenseMap< Value *, const SCEV * > & getSymbolicStrides() const
If an access has a symbolic strides, this maps the pointer value to the stride symbol.
Analysis pass that exposes the LoopInfo for a function.
Definition LoopInfo.h:587
bool contains(const LoopT *L) const
Return true if the specified loop is contained within in this loop.
BlockT * getLoopLatch() const
If there is a single latch block for this loop, return it.
bool isInnermost() const
Return true if the loop does not contain any (natural) loops.
BlockT * getHeader() const
Store the result of a depth first search within basic blocks contained by a single loop.
RPOIterator beginRPO() const
Reverse iterate over the cached postorder blocks.
LLVM_ABI void perform(const LoopInfo *LI)
Traverse the loop blocks and store the DFS result.
RPOIterator endRPO() const
Wrapper class to LoopBlocksDFS that provides a standard begin()/end() interface for the DFS reverse p...
void perform(const LoopInfo *LI)
Traverse the loop blocks and store the DFS result.
void removeBlock(BlockT *BB)
This method completely removes BB from all data structures, including all of the Loop objects it is n...
LoopVectorizationCostModel - estimates the expected speedups due to vectorization.
bool isEpilogueVectorizationProfitable(const ElementCount VF, const unsigned IC) const
Returns true if epilogue vectorization is considered profitable, and false otherwise.
bool useWideActiveLaneMask() const
Returns true if the use of wide lane masks is requested and the loop is using tail-folding with a lan...
bool isPredicatedInst(Instruction *I) const
Returns true if I is an instruction that needs to be predicated at runtime.
void collectValuesToIgnore()
Collect values we want to ignore in the cost model.
BlockFrequencyInfo * BFI
The BlockFrequencyInfo returned from GetBFI.
BlockFrequencyInfo & getBFI()
Returns the BlockFrequencyInfo for the function if cached, otherwise fetches it via GetBFI.
bool isForcedScalar(Instruction *I, ElementCount VF) const
Returns true if I has been forced to be scalarized at VF.
bool isUniformAfterVectorization(Instruction *I, ElementCount VF) const
Returns true if I is known to be uniform after vectorization.
bool preferTailFoldedLoop() const
Returns true if tail-folding is preferred over an epilogue.
bool useEmulatedMaskMemRefHack(Instruction *I, ElementCount VF)
Returns true if an artificially high cost for emulated masked memrefs should be used.
void collectNonVectorizedAndSetWideningDecisions(ElementCount VF)
Collect values that will not be widened, including Uniforms, Scalars, and Instructions to Scalarize f...
bool isMaskRequired(Instruction *I) const
Wrapper function for LoopVectorizationLegality::isMaskRequired, that passes the Instruction I and if ...
PredicatedScalarEvolution & PSE
Predicated scalar evolution analysis.
const LoopVectorizeHints * Hints
Loop Vectorize Hint.
const TargetTransformInfo & TTI
Vector target information.
LoopVectorizationLegality * Legal
Vectorization legality.
uint64_t getPredBlockCostDivisor(TargetTransformInfo::TargetCostKind CostKind, const BasicBlock *BB)
A helper function that returns how much we should divide the cost of a predicated block by.
std::optional< InstWidening > memoryInstructionCanBeWidened(Instruction *I, ElementCount VF)
If I is a memory instruction with a consecutive pointer that can be widened, returns the widening kin...
std::optional< InstructionCost > getReductionPatternCost(Instruction *I, ElementCount VF, Type *VectorTy) const
Return the cost of instructions in an inloop reduction pattern, if I is part of that pattern.
InstructionCost getInstructionCost(Instruction *I, ElementCount VF)
Returns the execution time cost of an instruction for a given vector width.
bool interleavedAccessCanBeWidened(Instruction *I, ElementCount VF) const
Returns true if I is a memory instruction in an interleaved-group of memory accesses that can be vect...
const TargetLibraryInfo * TLI
Target Library Info.
const InterleaveGroup< Instruction > * getInterleavedAccessGroup(Instruction *Instr) const
Get the interleaved access group that Instr belongs to.
InstructionCost getVectorIntrinsicCost(CallInst *CI, ElementCount VF) const
Estimate cost of an intrinsic call instruction CI if it were vectorized with factor VF.
bool maskPartialAliasing() const
Returns true if all loop blocks should have partial aliases masked.
bool isScalarAfterVectorization(Instruction *I, ElementCount VF) const
Returns true if I is known to be scalar after vectorization.
bool isOptimizableIVTruncate(Instruction *I, ElementCount VF)
Return True if instruction I is an optimizable truncate whose operand is an induction variable.
FixedScalableVFPair computeMaxVF(ElementCount UserVF, unsigned UserIC)
Loop * TheLoop
The loop that we evaluate.
InterleavedAccessInfo & InterleaveInfo
The interleave access information contains groups of interleaved accesses with the same stride and cl...
SmallPtrSet< const Value *, 16 > ValuesToIgnore
Values to ignore in the cost model.
void invalidateCostModelingDecisions()
Invalidates decisions already taken by the cost model.
bool isAccessInterleaved(Instruction *Instr) const
Check if Instr belongs to any interleaved access group.
void setTailFoldingStyle(bool IsScalableVF, unsigned UserIC)
Selects and saves TailFoldingStyle.
OptimizationRemarkEmitter * ORE
Interface to emit optimization remarks.
LoopInfo * LI
Loop Info analysis.
bool requiresScalarEpilogue(bool IsVectorizing) const
Returns true if we're required to use a scalar epilogue for at least the final iteration of the origi...
SmallPtrSet< const Value *, 16 > VecValuesToIgnore
Values to ignore in the cost model when VF > 1.
bool isProfitableToScalarize(Instruction *I, ElementCount VF) const
void setWideningDecision(const InterleaveGroup< Instruction > *Grp, ElementCount VF, InstWidening W, InstructionCost Cost)
Save vectorization decision W and Cost taken by the cost model for interleaving group Grp and vector ...
bool isEpilogueAllowed() const
Returns true if an epilogue is allowed (e.g., not prevented by optsize or a loop hint annotation).
bool canTruncateToMinimalBitwidth(Instruction *I, ElementCount VF) const
bool shouldConsiderInvariant(Value *Op)
Returns true if Op should be considered invariant and if it is trivially hoistable.
bool foldTailByMasking() const
Returns true if all loop blocks should be masked to fold tail loop.
bool foldTailWithEVL() const
Returns true if VP intrinsics with explicit vector length support should be generated in the tail fol...
bool blockNeedsPredicationForAnyReason(BasicBlock *BB) const
Returns true if the instructions in this block requires predication for any reason,...
AssumptionCache * AC
Assumption cache.
void setWideningDecision(Instruction *I, ElementCount VF, InstWidening W, InstructionCost Cost)
Save vectorization decision W and Cost taken by the cost model for instruction I and vector width VF.
InstWidening
Decision that was taken during cost calculation for memory instruction.
@ CM_InvalidatedDecision
A widening decision that has been invalidated after replacing the corresponding recipe during VPlan t...
bool usePredicatedReductionSelect(RecurKind RecurrenceKind) const
Returns true if the predicated reduction select should be used to set the incoming value for the redu...
LoopVectorizationCostModel(EpilogueLowering SEL, Loop *L, PredicatedScalarEvolution &PSE, LoopInfo *LI, LoopVectorizationLegality *Legal, const TargetTransformInfo &TTI, const TargetLibraryInfo *TLI, AssumptionCache *AC, OptimizationRemarkEmitter *ORE, std::function< BlockFrequencyInfo &()> GetBFI, const Function *F, const LoopVectorizeHints *Hints, InterleavedAccessInfo &IAI, VFSelectionContext &Config)
std::pair< InstructionCost, InstructionCost > getDivRemSpeculationCost(Instruction *I, ElementCount VF)
Return the costs for our two available strategies for lowering a div/rem operation which requires spe...
InstructionCost getVectorCallCost(CallInst *CI, ElementCount VF) const
Estimate cost of a call instruction CI if it were vectorized with factor VF.
bool isScalarWithPredication(Instruction *I, ElementCount VF)
Returns true if I is an instruction which requires predication and for which our chosen predication s...
std::function< BlockFrequencyInfo &()> GetBFI
A function to lazily fetch BlockFrequencyInfo.
InstructionCost expectedCost(ElementCount VF)
Returns the expected execution cost.
void setCostBasedWideningDecision(ElementCount VF)
Memory access instruction may be vectorized in more than one way.
bool isDivRemScalarWithPredication(InstructionCost ScalarCost, InstructionCost MaskedCost) const
Given costs for both strategies, return true if the scalar predication lowering should be used for di...
InstWidening getWideningDecision(Instruction *I, ElementCount VF) const
Return the cost model decision for the given instruction I and vector width VF.
InstructionCost getWideningCost(Instruction *I, ElementCount VF)
Return the vectorization cost for the given instruction I and vector width VF.
TailFoldingStyle getTailFoldingStyle() const
Returns the TailFoldingStyle that is best for the current loop.
void collectInstsToScalarize(ElementCount VF)
Collects the instructions to scalarize for each predicated instruction in the loop.
LoopVectorizationLegality checks if it is legal to vectorize a loop, and to what vectorization factor...
MapVector< PHINode *, InductionDescriptor > InductionList
InductionList saves induction variables and maps them to the induction descriptor.
LLVM_ABI bool canVectorize(bool UseVPlanNativePath)
Returns true if it is legal to vectorize this loop.
bool hasUncountableExitWithSideEffects() const
Returns true if this is an early exit loop with state-changing or potentially-faulting operations and...
LLVM_ABI bool canVectorizeFPMath(bool EnableStrictReductions)
Returns true if it is legal to vectorize the FP math operations in this loop.
const SmallVector< BasicBlock *, 4 > & getCountableExitingBlocks() const
Returns all exiting blocks with a countable exit, i.e.
bool hasUncountableEarlyExit() const
Returns true if the loop has uncountable early exits, i.e.
bool hasHistograms() const
Returns a list of all known histogram operations in the loop.
const LoopAccessInfo * getLAI() const
Planner drives the vectorization process after having passed Legality checks.
DenseMap< const SCEV *, Value * > executePlan(ElementCount VF, unsigned UF, VPlan &BestPlan, InnerLoopVectorizer &LB, DominatorTree *DT, EpilogueVectorizationKind EpilogueVecKind=EpilogueVectorizationKind::None)
EpilogueVectorizationKind
Generate the IR code for the vectorized loop captured in VPlan BestPlan according to the best selecte...
@ MainLoop
Vectorizing the main loop of epilogue vectorization.
VPlan & getPlanFor(ElementCount VF) const
Return the VPlan for VF.
Definition VPlan.cpp:1689
void updateLoopMetadataAndProfileInfo(Loop *VectorLoop, VPBasicBlock *HeaderVPBB, const VPlan &Plan, bool VectorizingEpilogue, MDNode *OrigLoopID, std::optional< unsigned > OrigAverageTripCount, unsigned OrigLoopInvocationWeight, unsigned EstimatedVFxUF, bool DisableRuntimeUnroll)
Update loop metadata and profile info for both the scalar remainder loop and VectorLoop,...
Definition VPlan.cpp:1740
bool hasTailFolded(const VPlan &Plan) const
Returns true if Plan folds the tail by masking.
void attachRuntimeChecks(VPlan &Plan, GeneratedRTChecks &RTChecks, bool HasBranchWeights) const
Attach the runtime checks of RTChecks to Plan.
unsigned selectInterleaveCount(VPlan &Plan, ElementCount VF, InstructionCost LoopCost)
bool requiresScalarEpilogue(VPlan &Plan, ElementCount VF) const
Returns true if Plan requires a scalar epilogue after the vector loop.
void emitInvalidCostRemarks(OptimizationRemarkEmitter *ORE)
Emit remarks for recipes with invalid costs in the available VPlans.
static bool getDecisionAndClampRange(const std::function< bool(ElementCount)> &Predicate, VFRange &Range)
Test a Predicate on a Range of VF's.
Definition VPlan.cpp:1654
void printPlans(raw_ostream &O)
Definition VPlan.cpp:1846
void plan(ElementCount UserVF, unsigned UserIC)
Build VPlans for the specified UserVF and UserIC if they are non-zero or all applicable candidate VFs...
std::unique_ptr< VPlan > selectBestEpiloguePlan(VPlan &MainPlan, ElementCount MainLoopVF, unsigned IC)
void addMinimumIterationCheck(VPlan &Plan, ElementCount VF, unsigned UF, ElementCount MinProfitableTripCount) const
Create a check to Plan to see if the vector loop should be executed based on its trip count.
bool hasPlanWithVF(ElementCount VF) const
Look through the existing plans and return true if we have one with vectorization factor VF.
std::pair< VectorizationFactor, VPlan * > computeBestVF()
Compute and return the most profitable vectorization factor and the corresponding best VPlan.
This holds vectorization requirements that must be verified late in the process.
Utility class for getting and setting loop vectorizer hints in the form of loop metadata.
LLVM_ABI bool allowVectorization(Function *F, Loop *L, bool VectorizeOnlyWhenForced) const
LLVM_ABI void emitRemarkWithHints() const
Dumps all the hint information.
Represents a single loop in the control flow graph.
Definition LoopInfo.h:40
Metadata node.
Definition Metadata.h:1069
std::pair< iterator, bool > insert(const std::pair< KeyT, ValueT > &KV)
Definition MapVector.h:126
Function * getFunction(StringRef Name) const
Look up the specified function in the module symbol table.
Definition Module.cpp:235
Diagnostic information for optimization analysis remarks related to pointer aliasing.
Diagnostic information for optimization analysis remarks related to floating-point non-commutativity.
Diagnostic information for optimization analysis remarks.
The optimization diagnostic interface.
LLVM_ABI void emit(DiagnosticInfoOptimizationBase &OptDiag)
Output the remark via the diagnostic handler and to the optimization record file.
Diagnostic information for missed-optimization remarks.
Diagnostic information for applied optimization remarks.
An interface layer with SCEV used to manage how we see SCEV expressions for values in the context of ...
ScalarEvolution * getSE() const
Returns the ScalarEvolution analysis used.
LLVM_ABI const SCEVPredicate & getPredicate() const
LLVM_ABI unsigned getSmallConstantMaxTripCount()
Returns the upper bound of the loop trip count as a normal unsigned value, or 0 if the trip count is ...
LLVM_ABI const SCEV * getBackedgeTakenCount()
Get the (predicated) backedge count for the analyzed loop.
LLVM_ABI const SCEV * getSCEV(Value *V)
Returns the SCEV expression of V, in the context of the current SCEV predicate.
A set of analyses that are preserved following a run of a transformation pass.
Definition Analysis.h:112
static PreservedAnalyses all()
Construct a special preserved set that preserves all passes.
Definition Analysis.h:118
PreservedAnalyses & preserveSet()
Mark an analysis set as preserved.
Definition Analysis.h:151
PreservedAnalyses & preserve()
Mark an analysis as preserved.
Definition Analysis.h:132
An analysis pass based on the new PM to deliver ProfileSummaryInfo.
The RecurrenceDescriptor is used to identify recurrences variables in a loop.
FastMathFlags getFastMathFlags() const
static LLVM_ABI unsigned getOpcode(RecurKind Kind)
Returns the opcode corresponding to the RecurrenceKind.
Type * getRecurrenceType() const
Returns the type of the recurrence.
const SmallPtrSet< Instruction *, 8 > & getCastInsts() const
Returns a reference to the instructions used for type-promoting the recurrence.
static bool isFindLastRecurrenceKind(RecurKind Kind)
Returns true if the recurrence kind is of the form select(cmp(),x,y) where one of (x,...
static bool isAnyOfRecurrenceKind(RecurKind Kind)
Returns true if the recurrence kind is of the form select(cmp(),x,y) where one of (x,...
static LLVM_ABI bool isSubRecurrenceKind(RecurKind Kind)
Returns true if the recurrence kind is for a sub operation.
bool isSigned() const
Returns true if all source operands of the recurrence are SExtInsts.
RecurKind getRecurrenceKind() const
static bool isFindIVRecurrenceKind(RecurKind Kind)
Returns true if the recurrence kind is of the form select(cmp(),x,y) where one of (x,...
static bool isMinMaxRecurrenceKind(RecurKind Kind)
Returns true if the recurrence kind is any min/max kind.
Holds information about the memory runtime legality checks to verify that a group of pointers do not ...
std::optional< ArrayRef< PointerDiffInfo > > getDiffChecks() const
const SmallVectorImpl< RuntimePointerCheck > & getChecks() const
Returns the checks that generateChecks created.
This class uses information about analyze scalars to rewrite expressions in canonical form.
ScalarEvolution * getSE()
bool isInsertedInstruction(Instruction *I) const
Return true if the specified instruction was inserted by the code rewriter.
LLVM_ABI Value * expandCodeForPredicate(const SCEVPredicate *Pred, Instruction *Loc)
Generates a code sequence that evaluates this predicate.
LLVM_ABI void eraseDeadInstructions(Value *Root)
Remove inserted instructions that are dead, e.g.
virtual bool isAlwaysTrue() const =0
Returns true if the predicate is always true.
This class represents an analyzed expression in the program.
LLVM_ABI bool isZero() const
Return true if the expression is a constant zero.
LLVM_ABI Type * getType() const
Return the LLVM type of this SCEV expression.
Analysis pass that exposes the ScalarEvolution for a function.
The main scalar evolution driver.
LLVM_ABI const SCEV * getURemExpr(SCEVUse LHS, SCEVUse RHS)
Represents an unsigned remainder expression based on unsigned division.
LLVM_ABI const SCEV * getBackedgeTakenCount(const Loop *L, ExitCountKind Kind=Exact)
If the specified loop has a predictable backedge-taken count, return it, otherwise return a SCEVCould...
LLVM_ABI const SCEV * getConstant(ConstantInt *V)
LLVM_ABI const SCEV * getSCEV(Value *V)
Return a SCEV expression for the full generality of the specified expression.
LLVM_ABI const SCEV * getTripCountFromExitCount(const SCEV *ExitCount)
A version of getTripCountFromExitCount below which always picks an evaluation type which can not resu...
const SCEV * getOne(Type *Ty)
Return a SCEV for the constant 1 of a specific type.
LLVM_ABI void forgetLoop(const Loop *L)
This method should be called by the client when it has changed a loop in a way that may effect Scalar...
LLVM_ABI bool isLoopInvariant(const SCEV *S, const Loop *L)
Return true if the value of the given SCEV is unchanging in the specified loop.
LLVM_ABI const SCEV * getElementCount(Type *Ty, ElementCount EC, SCEV::NoWrapFlags Flags=SCEV::FlagAnyWrap)
ConstantRange getUnsignedRange(const SCEV *S)
Determine the unsigned range for a particular SCEV.
LLVM_ABI void forgetValue(Value *V)
This method should be called by the client when it has changed a value in a way that may effect its v...
LLVM_ABI void forgetBlockAndLoopDispositions(Value *V=nullptr)
Called when the client has changed the disposition of values in a loop or block.
const SCEV * getMinusOne(Type *Ty)
Return a SCEV for the constant -1 of a specific type.
LLVM_ABI void forgetLcssaPhiWithNewPredecessor(Loop *L, PHINode *V)
Forget LCSSA phi node V of loop L to which a new predecessor was added, such that it may no longer be...
LLVM_ABI const SCEV * getMulExpr(SmallVectorImpl< SCEVUse > &Ops, SCEV::NoWrapFlags Flags=SCEV::FlagAnyWrap, unsigned Depth=0)
Get a canonical multiply expression, or something simpler if possible.
LLVM_ABI unsigned getSmallConstantTripCount(const Loop *L)
Returns the exact trip count of the loop if we can compute it, and the result is a small constant.
APInt getUnsignedRangeMax(const SCEV *S)
Determine the max of the unsigned range for a particular SCEV.
LLVM_ABI const SCEV * getAddExpr(SmallVectorImpl< SCEVUse > &Ops, SCEV::NoWrapFlags Flags=SCEV::FlagAnyWrap, unsigned Depth=0)
Get a canonical add expression, or something simpler if possible.
LLVM_ABI bool isKnownPredicate(CmpPredicate Pred, SCEVUse LHS, SCEVUse RHS)
Test if the given expression is known to satisfy the condition described by Pred, LHS,...
LLVM_ABI const SCEV * applyLoopGuards(const SCEV *Expr, const Loop *L)
Try to apply information from loop guards for L to Expr.
This class represents the LLVM 'select' instruction.
A vector that has set insertion semantics.
Definition SetVector.h:57
size_type size() const
Determine the number of elements in the SetVector.
Definition SetVector.h:103
void insert_range(Range &&R)
Definition SetVector.h:176
size_type count(const_arg_type key) const
Count the number of elements of a given key in the SetVector.
Definition SetVector.h:262
bool contains(const_arg_type key) const
Check if the SetVector contains the given key.
Definition SetVector.h:252
bool insert(const value_type &X)
Insert a new element into the SetVector.
Definition SetVector.h:151
A templated base class for SmallPtrSet which provides the typesafe interface that is common across al...
size_type count(ConstPtrType Ptr) const
count - Return 1 if the specified pointer is in the set, 0 otherwise.
std::pair< iterator, bool > insert(PtrType Ptr)
Inserts Ptr if and only if there is no element in the container equal to Ptr.
SmallPtrSet - This class implements a set which is optimized for holding SmallSize or less elements.
A SetVector that performs no allocations if smaller than a certain size.
Definition SetVector.h:339
This class consists of common code factored out of the SmallVector class to reduce code duplication b...
reference emplace_back(ArgTypes &&... Args)
void push_back(const T &Elt)
This is a 'vector' (really, a variable-sized array), optimized for the case when the array is small.
An instruction for storing to memory.
Represent a constant reference to a string, i.e.
Definition StringRef.h:56
Analysis pass providing the TargetTransformInfo.
Analysis pass providing the TargetLibraryInfo.
Provides information about what library functions are available for the current target.
This pass provides access to the codegen interfaces that are needed for IR-level transformations.
VectorInstrContext
Represents a hint about the context in which an insert/extract is used.
@ None
The insert/extract is not used with a load/store.
@ Load
The value being inserted comes from a load (InsertElement only).
@ Store
The extracted value is stored (ExtractElement only).
static LLVM_ABI OperandValueInfo getOperandInfo(const Value *V)
Collect properties of V used in cost analysis, e.g. OP_PowerOf2.
TargetCostKind
The kind of cost model.
@ TCK_RecipThroughput
Reciprocal throughput.
@ TCK_CodeSize
Instruction code size.
@ TCK_SizeAndLatency
The weighted sum of size and latency.
@ TCK_Latency
The latency of instruction.
@ TCC_Free
Expected to fold away in lowering.
LLVM_ABI InstructionCost getInstructionCost(const User *U, ArrayRef< const Value * > Operands, TargetCostKind CostKind) const
Estimate the cost of a given IR user when lowered.
@ SK_Splice
Concatenates elements from the first input vector with elements of the second input vector.
@ SK_Broadcast
Broadcast element 0 to all other elements.
@ SK_Reverse
Reverse the order of the vector.
CastContextHint
Represents a hint about the context in which a cast is used.
@ Reversed
The cast is used with a reversed load/store.
@ Masked
The cast is used with a masked load/store.
@ Normal
The cast is used with a normal load/store.
@ Interleave
The cast is used with an interleaved load/store.
@ GatherScatter
The cast is used with a gather/scatter.
Twine - A lightweight data structure for efficiently representing the concatenation of temporary valu...
Definition Twine.h:82
This class implements a switch-like dispatch statement for a value of 'T' using dyn_cast functionalit...
Definition TypeSwitch.h:89
TypeSwitch< T, ResultT > & Case(CallableT &&caseFn)
Add a case on the given type.
Definition TypeSwitch.h:98
The instances of the Type class are immutable: once they are created, they are never changed.
Definition Type.h:46
LLVM_ABI unsigned getIntegerBitWidth() const
bool isVectorTy() const
True if this is an instance of VectorType.
Definition Type.h:288
static LLVM_ABI Type * getVoidTy(LLVMContext &C)
Definition Type.cpp:282
Type * getScalarType() const
If this is a vector type, return the element type, otherwise return 'this'.
Definition Type.h:368
LLVMContext & getContext() const
Return the LLVMContext in which this type was uniqued.
Definition Type.h:130
LLVM_ABI unsigned getScalarSizeInBits() const LLVM_READONLY
If this is a vector type, return the getPrimitiveSizeInBits value for the element type.
Definition Type.cpp:232
static LLVM_ABI IntegerType * getInt1Ty(LLVMContext &C)
Definition Type.cpp:306
bool isVoidTy() const
Return true if this is 'void'.
Definition Type.h:141
A Use represents the edge between a Value definition and its users.
Definition Use.h:35
iterator_range< op_iterator > op_range
Definition User.h:256
LLVM_ABI bool replaceUsesOfWith(Value *From, Value *To)
Replace uses of one Value with another.
Definition User.cpp:25
Value * getOperand(unsigned i) const
Definition User.h:207
static SmallVector< VFInfo, 8 > getMappings(const CallInst &CI)
Retrieve all the VFInfo instances associated to the CallInst CI.
Definition VectorUtils.h:76
Holds state needed to make cost decisions before computing costs per-VF, including the maximum VFs.
const TTI::TargetCostKind CostKind
The kind of cost that we are calculating.
std::optional< unsigned > getVScaleForTuning() const
VPBasicBlock serves as the leaf of the Hierarchical Control-Flow Graph.
Definition VPlan.h:4359
RecipeListTy::iterator iterator
Instruction iterators...
Definition VPlan.h:4386
iterator end()
Definition VPlan.h:4396
iterator begin()
Recipe iterator methods.
Definition VPlan.h:4394
iterator_range< iterator > phis()
Returns an iterator range over the PHI-like recipes in the block.
Definition VPlan.h:4447
InstructionCost cost(ElementCount VF, VPCostContext &Ctx) override
Return the cost of this VPBasicBlock.
Definition VPlan.cpp:759
iterator getFirstNonPhi()
Return the position of the first non-phi node recipe in the block.
Definition VPlan.cpp:266
const VPRecipeBase & front() const
Definition VPlan.h:4406
VPRecipeBase * getTerminator()
If the block has multiple successors, return the branch recipe terminating the block.
Definition VPlan.cpp:639
bool empty() const
Definition VPlan.h:4405
const VPBasicBlock * getExitingBasicBlock() const
Definition VPlan.cpp:236
void setName(const Twine &newName)
Definition VPlan.h:177
VPlan * getPlan()
Definition VPlan.cpp:211
const VPBasicBlock * getEntryBasicBlock() const
Definition VPlan.cpp:216
VPBlockBase * getSingleSuccessor() const
Definition VPlan.h:225
static void reassociateBlocks(VPBlockBase *Old, VPBlockBase *New)
Reassociate all the blocks connected to Old so that they now point to New.
Definition VPlanUtils.h:281
static auto blocksOnly(T &&Range)
Return an iterator range over Range which only includes BlockTy blocks.
Definition VPlanUtils.h:309
VPlan-based builder utility analogous to IRBuilder.
VPInstruction * createAdd(VPValue *LHS, VPValue *RHS, DebugLoc DL=DebugLoc::getUnknown(), const Twine &Name="", VPRecipeWithIRFlags::WrapFlagsTy WrapFlags={false, false})
T * insert(T *R)
Insert R at the current insertion point. Returns R unchanged.
static VPBuilder getToInsertAfter(VPRecipeBase *R)
Create a VPBuilder to insert after R.
VPPhi * createScalarPhi(ArrayRef< VPValue * > IncomingValues, DebugLoc DL=DebugLoc::getUnknown(), const Twine &Name="", const VPIRFlags &Flags={}, Type *ResultTy=nullptr)
VPInstruction * createNaryOp(unsigned Opcode, ArrayRef< VPValue * > Operands, Instruction *Inst=nullptr, const VPIRFlags &Flags={}, const VPIRMetadata &MD={}, DebugLoc DL=DebugLoc::getUnknown(), const Twine &Name="", Type *ResultTy=nullptr)
Create an N-ary operation with Opcode, Operands and set Inst as its underlying Instruction.
static VPSingleDefRecipe * createSingleScalarOp(unsigned Opcode, ArrayRef< VPValue * > Operands, VPValue *Mask, const VPIRFlags &Flags, const VPIRMetadata &Metadata, DebugLoc DL, Instruction *UV)
Create a single-scalar recipe with Opcode and Operands without inserting it.
unsigned getNumDefinedValues() const
Returns the number of values defined by the VPDef.
Definition VPlanValue.h:576
VPValue * getVPSingleValue()
Returns the only VPValue defined by the VPDef.
Definition VPlanValue.h:549
A pure virtual base class for all recipes modeling header phis, including phis for first order recurr...
Definition VPlan.h:2431
virtual VPValue * getBackedgeValue()
Returns the incoming value from the loop backedge.
Definition VPlan.h:2478
void setBackedgeValue(VPValue *V)
Update the incoming value from the loop backedge.
Definition VPlan.h:2483
VPValue * getStartValue()
Returns the start value of the phi, if one is set.
Definition VPlan.h:2467
A recipe representing a sequence of load -> update -> store as part of a histogram operation.
Definition VPlan.h:2158
A special type of VPBasicBlock that wraps an existing IR basic block.
Definition VPlan.h:4512
Class to record and manage LLVM IR flags.
Definition VPlan.h:693
LLVM_ABI_FOR_TEST FastMathFlags getFastMathFlagsOrNone() const
This is a concrete Recipe that models a single VPlan-level instruction.
Definition VPlan.h:1222
iterator_range< operand_iterator > operandsWithoutMask()
Returns an iterator range over the operands excluding the mask operand if present.
Definition VPlan.h:1491
@ ResumeForEpilogue
Explicit user for the resume phi of the canonical induction in the main VPlan, used by the epilogue v...
Definition VPlan.h:1318
@ ReductionStartVector
Start vector for reductions with 3 operands: the original start value, the identity value for the red...
Definition VPlan.h:1311
@ ComputeReductionResult
Reduce the operands to the final reduction result using the operation specified via the operation's V...
Definition VPlan.h:1268
unsigned getOpcode() const
Definition VPlan.h:1413
void setName(StringRef NewName)
Set the symbolic name for the VPInstruction.
Definition VPlan.h:1519
VPValue * getMask() const
Returns the mask for the VPInstruction.
Definition VPlan.h:1485
VPInterleaveRecipe is a recipe for transforming an interleave group of load or stores into one wide l...
Definition VPlan.h:3118
VPRecipeBase is a base class modeling a sequence of one or more output IR instructions.
Definition VPlan.h:400
DebugLoc getDebugLoc() const
Returns the debug location of the recipe.
Definition VPlan.h:550
void moveBefore(VPBasicBlock &BB, iplist< VPRecipeBase >::iterator I)
Unlink this recipe and insert into BB before I.
void insertBefore(VPRecipeBase *InsertPos)
Insert an unlinked recipe into a basic block immediately before the specified recipe.
iplist< VPRecipeBase >::iterator eraseFromParent()
This method unlinks 'this' from the containing basic block and deletes it.
Helper class to create VPRecipies from IR instructions.
VPRecipeBase * tryToCreateWidenNonPhiRecipe(VPSingleDefRecipe *R, VFRange &Range)
Create and return a widened recipe for a non-phi recipe R if one can be created within the given VF R...
VPHistogramRecipe * widenIfHistogram(VPInstruction *VPI)
If VPI represents a histogram operation (as determined by LoopVectorizationLegality) make that safe f...
bool prefersVectorizedAddressing() const
Returns true if the target prefers vectorized addressing.
VPRecipeBase * tryToWidenMemory(VPInstruction *VPI, VFRange &Range)
Check if the load or store instruction VPI should widened for Range.Start and potentially masked.
bool replaceWithFinalIfReductionStore(VPInstruction *VPI, VPBuilder &FinalRedStoresBuilder)
If VPI is a store of a reduction into an invariant address, delete it.
VPSingleDefRecipe * handleReplication(VPInstruction *VPI, VFRange &Range)
Build a replicating or single-scalar recipe for VPI.
bool isPredicatedInst(Instruction *I) const
Returns true if I needs to be predicated (i.e.
Type * getScalarType() const
Returns the scalar type of this VPRecipeValue.
Definition VPlanValue.h:352
bool isOrdered() const
Returns true, if the phi is part of an ordered reduction.
Definition VPlan.h:2903
unsigned getVFScaleFactor() const
Get the factor that the VF of this recipe's output should be scaled by, or 1 if it isn't scaled.
Definition VPlan.h:2887
bool isInLoop() const
Returns true if the phi is part of an in-loop reduction.
Definition VPlan.h:2906
VPReductionPHIRecipe * cloneWithOperands(VPValue *Start, VPValue *BackedgeValue)
Definition VPlan.h:2869
RecurKind getRecurrenceKind() const
Returns the recurrence kind of the reduction.
Definition VPlan.h:2900
A recipe to represent inloop, ordered or partial reduction operations.
Definition VPlan.h:3211
VPRegionBlock represents a collection of VPBasicBlocks and VPRegionBlocks which form a Single-Entry-S...
Definition VPlan.h:4584
const VPBlockBase * getEntry() const
Definition VPlan.h:4628
void clearCanonicalIVNUW(VPInstruction *Increment)
Unsets NUW for the canonical IV increment Increment, for loop regions.
Definition VPlan.h:4743
VPRegionValue * getCanonicalIV()
Return the canonical induction variable of the region, null for replicating regions.
Definition VPlan.h:4696
VPReplicateRecipe replicates a given instruction producing multiple scalar copies of the original sca...
Definition VPlan.h:3375
VPSingleDefRecipe is a base class for recipes that model a sequence of one or more output IR that def...
Definition VPlan.h:608
Instruction * getUnderlyingInstr()
Returns the underlying instruction.
Definition VPlan.h:678
This class augments VPValue with operands which provide the inverse def-use edges from VPValue's user...
Definition VPlanValue.h:399
operand_range operands()
Definition VPlanValue.h:472
void setOperand(unsigned I, VPValue *New)
Definition VPlanValue.h:445
VPValue * getOperand(unsigned N) const
Definition VPlanValue.h:440
This is the base class of the VPlan Def/Use graph, used for modeling the data flow into,...
Definition VPlanValue.h:50
Type * getScalarType() const
Returns the scalar type of this VPValue, dispatching based on the concrete subclass.
Definition VPlan.cpp:149
Value * getLiveInIRValue() const
Return the underlying IR value for a VPIRValue.
Definition VPlan.cpp:143
VPRecipeBase * getDefiningRecipe()
Returns the recipe defining this VPValue or nullptr if it is not defined by a recipe,...
Definition VPlan.cpp:130
Value * getUnderlyingValue() const
Return the underlying Value attached to this VPValue.
Definition VPlanValue.h:75
void replaceAllUsesWith(VPValue *New)
Definition VPlan.cpp:1468
void replaceUsesWithIf(VPValue *New, llvm::function_ref< bool(VPUser &U, unsigned Idx)> ShouldReplace)
Go through the uses list for this VPValue and make each use point to New if the callback ShouldReplac...
Definition VPlan.cpp:1474
VPWidenCastRecipe is a recipe to create vector cast instructions.
Definition VPlan.h:1874
A recipe for handling GEP instructions.
Definition VPlan.h:2201
A recipe for handling phi nodes of integer and floating-point inductions, producing their vector valu...
Definition VPlan.h:2605
VPWidenRecipe is a recipe for producing a widened instruction using the opcode and operands of the re...
Definition VPlan.h:1813
VPlan models a candidate for vectorization, encoding various decisions take to produce efficient outp...
Definition VPlan.h:4763
bool hasVF(ElementCount VF) const
Definition VPlan.h:4988
ElementCount getSingleVF() const
Returns the single VF of the plan, asserting that the plan has exactly one VF.
Definition VPlan.h:5001
VPBasicBlock * getEntry()
Definition VPlan.h:4859
VPValue * getTripCount() const
The trip count of the original loop.
Definition VPlan.h:4924
VPSymbolicValue & getVFxUF()
Returns VF * UF of the vector loop region.
Definition VPlan.h:4964
bool hasUF(unsigned UF) const
Definition VPlan.h:5013
ArrayRef< VPIRBasicBlock * > getExitBlocks() const
Return an ArrayRef containing VPIRBasicBlocks wrapping the exit blocks of the original scalar loop.
Definition VPlan.h:4918
VPIRValue * getOrAddLiveIn(Value *V)
Gets the live-in VPIRValue for V or adds a new live-in (if none exists yet) for V.
Definition VPlan.h:5038
VPIRValue * getZero(Type *Ty)
Return a VPIRValue wrapping the null value of type Ty.
Definition VPlan.h:5064
LLVM_ABI_FOR_TEST VPRegionBlock * getVectorLoopRegion()
Returns the VPRegionBlock of the vector loop.
Definition VPlan.cpp:1060
bool hasEarlyExit() const
Returns true if the VPlan is based on a loop with an early exit.
Definition VPlan.h:5163
InstructionCost cost(ElementCount VF, VPCostContext &Ctx)
Return the cost of this plan.
Definition VPlan.cpp:1042
LLVM_ABI_FOR_TEST bool isOuterLoop() const
Returns true if this VPlan is for an outer loop, i.e., its vector loop region contains a nested loop ...
Definition VPlan.cpp:1075
void resetTripCount(VPValue *NewTripCount)
Resets the trip count for the VPlan.
Definition VPlan.h:4938
VPBasicBlock * getMiddleBlock()
Returns the 'middle' block of the plan, that is the block that selects whether to execute the scalar ...
Definition VPlan.h:4894
VPBasicBlock * getVectorPreheader() const
Returns the preheader of the vector loop region, if one exists, or null otherwise.
Definition VPlan.h:4864
VPSymbolicValue & getUF()
Returns the UF of the vector loop region.
Definition VPlan.h:4961
bool hasScalarVFOnly() const
Definition VPlan.h:5006
VPBasicBlock * getScalarPreheader() const
Return the VPBasicBlock for the preheader of the scalar loop.
Definition VPlan.h:4908
void execute(VPTransformState *State)
Generate the IR code for this VPlan.
Definition VPlan.cpp:919
bool hasTailFolded() const
Returns true if the vector loop region is tail-folded.
Definition VPlan.h:4880
VPIRBasicBlock * getScalarHeader() const
Return the VPIRBasicBlock wrapping the header of the scalar loop.
Definition VPlan.h:4914
VPSymbolicValue & getVF()
Returns the VF of the vector loop region.
Definition VPlan.h:4957
LLVM_ABI_FOR_TEST VPlan * duplicate()
Clone the current VPlan, update all VPValues of the new VPlan and cloned recipes to refer to the clon...
Definition VPlan.cpp:1216
LLVM Value Representation.
Definition Value.h:75
Type * getType() const
All values are typed, get the type of this value.
Definition Value.h:255
LLVM_ABI bool hasOneUser() const
Return true if there is exactly one user of this value.
Definition Value.cpp:163
LLVM_ABI void setName(const Twine &Name)
Change the name of the value.
Definition Value.cpp:394
LLVM_ABI void replaceAllUsesWith(Value *V)
Change all uses of this to point to a new Value.
Definition Value.cpp:553
iterator_range< user_iterator > users()
Definition Value.h:426
LLVM_ABI StringRef getName() const
Return a constant reference to the value's name.
Definition Value.cpp:319
static LLVM_ABI VectorType * get(Type *ElementType, ElementCount EC)
This static method is the primary way to construct an VectorType.
std::pair< iterator, bool > insert(const ValueT &V)
Definition DenseSet.h:209
bool contains(const_arg_type_t< ValueT > V) const
Check if the set contains the given element.
Definition DenseSet.h:182
constexpr ScalarTy getFixedValue() const
Definition TypeSize.h:200
static constexpr bool isKnownLE(const FixedOrScalableQuantity &LHS, const FixedOrScalableQuantity &RHS)
Definition TypeSize.h:230
constexpr bool isNonZero() const
Definition TypeSize.h:155
static constexpr bool isKnownLT(const FixedOrScalableQuantity &LHS, const FixedOrScalableQuantity &RHS)
Definition TypeSize.h:216
constexpr bool isScalable() const
Returns whether the quantity is scaled by a runtime quantity (vscale).
Definition TypeSize.h:168
constexpr bool isFixed() const
Returns true if the quantity is not scaled by vscale.
Definition TypeSize.h:171
constexpr ScalarTy getKnownMinValue() const
Returns the minimum value this quantity can represent.
Definition TypeSize.h:165
constexpr bool isZero() const
Definition TypeSize.h:153
static constexpr bool isKnownGT(const FixedOrScalableQuantity &LHS, const FixedOrScalableQuantity &RHS)
Definition TypeSize.h:223
constexpr LeafTy divideCoefficientBy(ScalarTy RHS) const
We do not provide the '/' operator here because division for polynomial types does not work in the sa...
Definition TypeSize.h:252
An efficient, type-erasing, non-owning reference to a callable.
const ParentTy * getParent() const
Definition ilist_node.h:34
self_iterator getIterator()
Definition ilist_node.h:123
IteratorT end() const
This class implements an extremely fast bulk output stream that can only output to a stream.
Definition raw_ostream.h:53
A raw_ostream that writes to an std::string.
CallInst * Call
Changed
This provides a very simple, boring adaptor for a begin and end iterator into a range type.
#define llvm_unreachable(msg)
Marks that the current location is not supposed to be reachable.
constexpr char Align[]
Key for Kernel::Arg::Metadata::mAlign.
unsigned ID
LLVM IR allows to use arbitrary numbers as calling convention identifiers.
Definition CallingConv.h:24
@ Tail
Attemps to make calls as fast as possible while guaranteeing that tail call optimization can always b...
Definition CallingConv.h:76
@ C
The default llvm calling convention, compatible with C.
Definition CallingConv.h:34
@ BasicBlock
Various leaf nodes.
Definition ISDOpcodes.h:81
void reportVectorizationFailure(const StringRef DebugMsg, const StringRef OREMsg, const StringRef ORETag, OptimizationRemarkEmitter *ORE, const Loop *TheLoop, Instruction *I=nullptr)
Reports a vectorization failure: print DebugMsg for debugging purposes along with the corresponding o...
void reportVectorizationInfo(const StringRef Msg, const StringRef ORETag, OptimizationRemarkEmitter *ORE, const Loop *TheLoop, Instruction *I=nullptr, DebugLoc DL={})
Reports an informative message: print Msg for debugging purposes as well as an optimization remark.
void reportVectorization(OptimizationRemarkEmitter *ORE, Loop *TheLoop, ElementCount VFWidth, unsigned IC)
Report successful vectorization of the loop.
SpecificConstantMatch m_ZeroInt()
Convenience matchers for specific integer values.
OneUse_match< SubPat > m_OneUse(const SubPat &SP)
match_combine_or< Ty... > m_CombineOr(const Ty &...Ps)
Combine pattern matchers matching any of Ps patterns.
BinaryOp_match< LHS, RHS, Instruction::Add > m_Add(const LHS &L, const RHS &R)
specific_intval< false > m_SpecificInt(const APInt &V)
Match a specific integer value or vector with all elements equal to the value.
bool match(Val *V, const Pattern &P)
match_bind< Instruction > m_Instruction(Instruction *&I)
Match an instruction, capturing it if we match.
specificval_ty m_Specific(const Value *V)
Match if we have a specific specified value.
auto match_fn(const Pattern &P)
A match functor that can be used as a UnaryPredicate in functional algorithms like all_of.
cst_pred_ty< is_one > m_One()
Match an integer 1 or a vector with all elements equal to 1.
ThreeOps_match< Cond, LHS, RHS, Instruction::Select > m_Select(const Cond &C, const LHS &L, const RHS &R)
Matches SelectInst.
auto m_Value()
Match an arbitrary value and ignore it.
BinaryOp_match< LHS, RHS, Instruction::Mul > m_Mul(const LHS &L, const RHS &R)
auto m_LogicalOr()
Matches L || R where L and R are arbitrary values.
match_combine_or< CastInst_match< OpTy, ZExtInst >, CastInst_match< OpTy, SExtInst > > m_ZExtOrSExt(const OpTy &Op)
auto m_LogicalAnd()
Matches L && R where L and R are arbitrary values.
bind_cst_ty m_scev_APInt(const APInt *&C)
Match an SCEV constant and bind it to an APInt.
match_bind< const SCEVMulExpr > m_scev_Mul(const SCEVMulExpr *&V)
bool match(const SCEV *S, const Pattern &P)
SCEVBinaryExpr_match< SCEVMulExpr, Op0_t, Op1_t, SCEV::FlagAnyWrap, true > m_scev_c_Mul(const Op0_t &Op0, const Op1_t &Op1)
bool matchFindIVResult(VPInstruction *VPI, Op0_t ReducedIV, Op1_t Start)
Match FindIV result pattern: select(icmp ne ComputeReductionResult(ReducedIV), Sentinel),...
VPInstruction_match< VPInstruction::ExtractLastLane, Op0_t > m_ExtractLastLane(const Op0_t &Op0)
VPInstruction_match< VPInstruction::BranchOnCount > m_BranchOnCount()
auto m_VPValue()
Match an arbitrary VPValue and ignore it.
VPInstruction_match< VPInstruction::ExtractLastPart, Op0_t > m_ExtractLastPart(const Op0_t &Op0)
VPRecipeBase * findUserOf(VPValue *V, const MatchT &P)
If V is used by a recipe matching pattern P, return it.
bool match(Val *V, const Pattern &P)
match_bind< VPInstruction > m_VPInstruction(VPInstruction *&V)
Match a VPInstruction, capturing if we match.
VPInstruction_match< VPInstruction::ExtractLane, Op0_t, Op1_t > m_ExtractLane(const Op0_t &Op0, const Op1_t &Op1)
ValuesClass values(OptsTy... Options)
Helper to build a ValuesClass by forwarding a variable number of arguments as an initializer list to ...
initializer< Ty > init(const Ty &Val)
Add a small namespace to avoid name clashes with the classes used in the streaming interface.
NodeAddr< InstrNode * > Instr
Definition RDFGraph.h:391
friend class Instruction
Iterator for Instructions in a `BasicBlock.
Definition BasicBlock.h:73
VPValue * getOrCreateVPValueForSCEVExpr(VPlan &Plan, const SCEV *Expr)
Get or create a VPValue that corresponds to the expansion of Expr.
VPBasicBlock * getFirstLoopHeader(VPlan &Plan, VPDominatorTree &VPDT)
Returns the header block of the first, top-level loop, or null if none exist.
bool isAddressSCEVForCost(const SCEV *Addr, ScalarEvolution &SE, const Loop *L)
Returns true if Addr is an address SCEV that can be passed to TTI::getAddressComputationCost,...
VPInstruction * findCanonicalIVIncrement(VPlan &Plan)
Find the canonical IV increment of Plan's vector loop region.
bool onlyFirstLaneUsed(const VPValue *Def)
Returns true if only the first lane of Def is used.
VPRecipeBase * findRecipe(VPValue *Start, PredT Pred)
Search Start's users for a recipe satisfying Pred, looking through recipes with definitions.
Definition VPlanUtils.h:133
const SCEV * getSCEVExprForVPValue(const VPValue *V, PredicatedScalarEvolution &PSE, const Loop *L=nullptr)
Return the SCEV expression for V.
This is an optimization pass for GlobalISel generic memory operations.
LLVM_ABI bool simplifyLoop(Loop *L, DominatorTree *DT, LoopInfo *LI, ScalarEvolution *SE, AssumptionCache *AC, MemorySSAUpdater *MSSAU, bool PreserveLCSSA)
Simplify each loop in a loop nest recursively.
detail::zippy< detail::zip_shortest, T, U, Args... > zip(T &&t, U &&u, Args &&...args)
zip iterator for two or more iteratable types.
Definition STLExtras.h:830
constexpr auto not_equal_to(T &&Arg)
Functor variant of std::not_equal_to that can be used as a UnaryPredicate in functional algorithms li...
Definition STLExtras.h:2180
LLVM_ABI Value * addRuntimeChecks(Instruction *Loc, Loop *TheLoop, const SmallVectorImpl< RuntimePointerCheck > &PointerChecks, SCEVExpander &Expander, bool HoistRuntimeChecks=false)
Add code that checks at runtime if the accessed arrays in PointerChecks overlap.
auto cast_if_present(const Y &Val)
cast_if_present<X> - Functionally identical to cast, except that a null value is accepted.
Definition Casting.h:683
LLVM_ABI bool RemoveRedundantDbgInstrs(BasicBlock *BB)
Try to remove redundant dbg.value instructions from given basic block.
LLVM_ABI_FOR_TEST cl::opt< bool > VerifyEachVPlan
LLVM_ABI std::optional< unsigned > getLoopEstimatedTripCount(Loop *L, unsigned *EstimatedLoopInvocationWeight=nullptr)
Return either:
bool all_of(R &&range, UnaryPredicate P)
Provide wrappers to std::all_of which take ranges instead of having to pass begin/end explicitly.
Definition STLExtras.h:1739
unsigned getLoadStoreAddressSpace(const Value *I)
A helper function that returns the address space of the pointer operand of load or store instruction.
LLVM_ABI Intrinsic::ID getMinMaxReductionIntrinsicOp(Intrinsic::ID RdxID)
Returns the min/max intrinsic used when expanding a min/max reduction.
LLVM_ABI Intrinsic::ID getVectorIntrinsicIDForCall(const CallInst *CI, const TargetLibraryInfo *TLI)
Returns intrinsic ID for call.
detail::zippy< detail::zip_first, T, U, Args... > zip_equal(T &&t, U &&u, Args &&...args)
zip iterator that assumes that all iteratees have the same length.
Definition STLExtras.h:840
InstructionCost Cost
decltype(auto) dyn_cast(const From &Val)
dyn_cast<X> - Return the argument parameter cast to the specified type.
Definition Casting.h:643
LLVM_ABI bool verifyFunction(const Function &F, raw_ostream *OS=nullptr)
Check a function for errors, useful for use when debugging a pass.
const Value * getLoadStorePointerOperand(const Value *V)
A helper function that returns the pointer operand of a load or store instruction.
OuterAnalysisManagerProxy< ModuleAnalysisManager, Function > ModuleAnalysisManagerFunctionProxy
Provide the ModuleAnalysisManager to Function proxy.
Value * getRuntimeVF(IRBuilderBase &B, Type *Ty, ElementCount VF)
Return the runtime value for VF.
LLVM_ABI bool formLCSSARecursively(Loop &L, const DominatorTree &DT, const LoopInfo *LI, ScalarEvolution *SE)
Put a loop nest into LCSSA form.
Definition LCSSA.cpp:449
iterator_range< T > make_range(T x, T y)
Convenience function for iterating over sub-ranges.
void append_range(Container &C, Range &&R)
Wrapper function to append range R to container C.
Definition STLExtras.h:2208
LLVM_ABI bool shouldOptimizeForSize(const MachineFunction *MF, ProfileSummaryInfo *PSI, const MachineBlockFrequencyInfo *BFI, PGSOQueryType QueryType=PGSOQueryType::Other)
Returns true if machine function MF is suggested to be size-optimized based on the profile.
iterator_range< early_inc_iterator_impl< detail::IterOfRange< RangeT > > > make_early_inc_range(RangeT &&Range)
Make a range that does early increment to allow mutation of the underlying range without disrupting i...
Definition STLExtras.h:633
Align getLoadStoreAlignment(const Value *I)
A helper function that returns the alignment of load or store instruction.
iterator_range< df_iterator< VPBlockShallowTraversalWrapper< VPBlockBase * > > > vp_depth_first_shallow(VPBlockBase *G)
Returns an iterator range to traverse the graph starting at G in depth-first order.
Definition VPlanCFG.h:250
LLVM_ABI bool VerifySCEV
LLVM_ABI_FOR_TEST cl::opt< bool > VPlanPrintAfterAll
LLVM_ABI bool isSafeToSpeculativelyExecute(const Instruction *I, const Instruction *CtxI=nullptr, AssumptionCache *AC=nullptr, const DominatorTree *DT=nullptr, const TargetLibraryInfo *TLI=nullptr, bool UseVariableInfo=true, bool IgnoreUBImplyingAttrs=true)
Return true if the instruction does not have any effects besides calculating the result and does not ...
bool isa_and_nonnull(const Y &Val)
Definition Casting.h:676
iterator_range< df_iterator< VPBlockDeepTraversalWrapper< VPBlockBase * > > > vp_depth_first_deep(VPBlockBase *G)
Returns an iterator range to traverse the graph starting at G in depth-first order while traversing t...
Definition VPlanCFG.h:285
SmallVector< VPRegisterUsage, 8 > calculateRegisterUsageForPlan(VPlan &Plan, ArrayRef< ElementCount > VFs, const TargetTransformInfo &TTI, const SmallPtrSetImpl< const Value * > &ValuesToIgnore)
Estimate the register usage for Plan and vectorization factors in VFs by calculating the highest numb...
auto map_range(ContainerTy &&C, FuncTy F)
Return a range that applies F to the elements of C.
Definition STLExtras.h:365
RelativeUniformCounterPtr ValuesPtrExpr VTableAddr Value
Definition InstrProf.h:143
constexpr auto bind_front(FnT &&Fn, BindArgsT &&...BindArgs)
C++20 bind_front.
auto dyn_cast_or_null(const Y &Val)
Definition Casting.h:753
bool any_of(R &&range, UnaryPredicate P)
Provide wrappers to std::any_of which take ranges instead of having to pass begin/end explicitly.
Definition STLExtras.h:1746
void collectEphemeralRecipesForVPlan(VPlan &Plan, DenseSet< VPRecipeBase * > &EphRecipes)
auto reverse(ContainerTy &&C)
Definition STLExtras.h:407
bool containsIrreducibleCFG(RPOTraversalT &RPOTraversal, const LoopInfoT &LI)
Return true if the control flow in RPOTraversal is irreducible.
Definition CFG.h:154
constexpr bool isPowerOf2_32(uint32_t Value)
Return true if the argument is a power of two > 0.
Definition MathExtras.h:279
void sort(IteratorTy Start, IteratorTy End)
Definition STLExtras.h:1636
bool hasIrregularType(Type *Ty, const DataLayout &DL)
A helper function that returns true if the given type is irregular.
LLVM_ABI_FOR_TEST cl::opt< bool > EnableWideActiveLaneMask
UncountableExitStyle
Different methods of handling early exits.
Definition VPlan.h:79
@ ReadOnly
No side effects to worry about, so we can process any uncountable exits in the loop and branch either...
Definition VPlan.h:84
@ MaskedHandleExitInScalarLoop
All memory operations other than the load(s) required to determine whether an uncountable exit occurr...
Definition VPlan.h:89
LLVM_ABI raw_ostream & dbgs()
dbgs() - This returns a reference to a raw_ostream for debugging messages.
Definition Debug.cpp:209
bool none_of(R &&Range, UnaryPredicate P)
Provide wrappers to std::none_of which take ranges instead of having to pass begin/end explicitly.
Definition STLExtras.h:1753
LLVM_ABI cl::opt< bool > EnableLoopVectorization
constexpr uint64_t alignTo(uint64_t Size, Align A)
Returns a multiple of A needed to store Size bytes.
Definition Alignment.h:144
LLVM_ABI_FOR_TEST cl::list< std::string > VPlanPrintAfterPasses
LLVM_ABI bool wouldInstructionBeTriviallyDead(const Instruction *I, const TargetLibraryInfo *TLI=nullptr)
Return true if the result produced by the instruction would have no side effects if it was not used.
Definition Local.cpp:422
SmallVector< ValueTypeFromRangeType< R >, Size > to_vector(R &&Range)
Given a range of type R, iterate the entire range and return a SmallVector with elements of the vecto...
Type * toVectorizedTy(Type *Ty, ElementCount EC)
A helper for converting to vectorized types.
T * find_singleton(R &&Range, Predicate P, bool AllowRepeats=false)
Return the single value in Range that satisfies P(<member of Range> *, AllowRepeats)->T * returning n...
Definition STLExtras.h:1837
class LLVM_GSL_OWNER SmallVector
Forward declaration of SmallVector so that calculateSmallVectorDefaultInlinedElements can reference s...
std::optional< unsigned > getMaxVScale(const Function &F, const TargetTransformInfo &TTI)
cl::opt< unsigned > ForceTargetInstructionCost
bool isa(const From &Val)
isa<X> - Return true if the parameter to the template is an instance of one of the template type argu...
Definition Casting.h:547
constexpr T divideCeil(U Numerator, V Denominator)
Returns the integer ceil(Numerator / Denominator).
Definition MathExtras.h:394
bool canVectorizeTy(Type *Ty)
Returns true if Ty is a valid vector element type, void, or an unpacked literal struct where all elem...
TargetTransformInfo TTI
@ CM_EpilogueNotAllowedLowTripLoop
@ CM_EpilogueNotNeededFoldTail
@ CM_EpilogueNotAllowedFoldTail
@ CM_EpilogueNotAllowedOptSize
@ CM_EpilogueAllowed
std::enable_if_t< std::is_unsigned_v< T >, T > SaturatingMultiply(T X, T Y, bool *ResultOverflowed=nullptr)
Multiply two unsigned integers, X and Y, of type T.
Definition MathExtras.h:638
LLVM_ABI bool isAssignmentTrackingEnabled(const Module &M)
Return true if assignment tracking is enabled for module M.
LLVM_ABI_FOR_TEST cl::list< std::string > VPlanPrintBeforePasses
RecurKind
These are the kinds of recurrences that we support.
@ FMulAdd
Sum of float products with llvm.fmuladd(a * b + sum).
@ Sub
Subtraction of integers.
@ Add
Sum of integers.
LLVM_ABI Value * getRecurrenceIdentity(RecurKind K, Type *Tp, FastMathFlags FMF)
Given information about an recurrence kind, return the identity for the @llvm.vector....
LLVM_ABI BasicBlock * SplitBlock(BasicBlock *Old, BasicBlock::iterator SplitPt, DominatorTree *DT, LoopInfo *LI=nullptr, MemorySSAUpdater *MSSAU=nullptr, const Twine &BBName="")
Split the specified block at the specified instruction.
DWARFExpression::Operation Op
LLVM_ABI bool isGuaranteedNotToBeUndefOrPoison(const Value *V, AssumptionCache *AC=nullptr, const Instruction *CtxI=nullptr, const DominatorTree *DT=nullptr, unsigned Depth=0)
Return true if this function can prove that V does not have undef bits and is never poison.
ArrayRef(const T &OneElt) -> ArrayRef< T >
decltype(auto) cast(const From &Val)
cast<X> - Return the argument parameter cast to the specified type.
Definition Casting.h:559
LLVM_ABI_FOR_TEST cl::opt< bool > VPlanPrintBeforeAll
auto find_if(R &&Range, UnaryPredicate P)
Provide wrappers to std::find_if which take ranges instead of having to pass begin/end explicitly.
Definition STLExtras.h:1772
auto predecessors(const MachineBasicBlock *BB)
iterator_range< pointer_iterator< WrappedIteratorT > > make_pointer_range(RangeT &&Range)
Definition iterator.h:368
bool is_contained(R &&Range, const E &Element)
Returns true if Element is found in Range.
Definition STLExtras.h:1947
cl::opt< bool > EnableVPlanNativePath
Type * getLoadStoreType(const Value *I)
A helper function that returns the type of a load or store instruction.
ArrayRef< Type * > getContainedTypes(Type *const &Ty)
Returns the types contained in Ty.
LLVM_ABI Value * addDiffRuntimeChecks(Instruction *Loc, ArrayRef< PointerDiffInfo > Checks, SCEVExpander &Expander, function_ref< Value *(IRBuilderBase &, unsigned)> GetVF, unsigned IC)
bool pred_empty(const BasicBlock *BB)
Definition CFG.h:107
@ None
Don't use tail folding.
@ DataWithEVL
Use predicated EVL instructions for tail-folding.
@ DataAndControlFlow
Use predicate to control both data and control flow.
@ DataWithoutLaneMask
Same as Data, but avoids using the get.active.lane.mask intrinsic to calculate the mask and instead i...
@ Data
Use predicate only to mask operations on data in the loop.
AnalysisManager< Function > FunctionAnalysisManager
Convenience typedef for the Function analysis manager.
LLVM_ABI bool hasBranchWeightMD(const Instruction &I)
Checks if an instructions has Branch Weight Metadata.
hash_code hash_combine(const Ts &...args)
Combine values into a single hash_code.
Definition Hashing.h:305
@ Increment
Incrementally increasing token ID.
Definition AllocToken.h:26
@ Enabled
Convert any .debug_str_offsets tables to DWARF64 if needed.
Definition DWP.h:31
@ Disabled
Don't do any conversion of .debug_str_offsets tables.
Definition DWP.h:30
T bit_floor(T Value)
Returns the largest integral power of two no greater than Value if Value is nonzero.
Definition bit.h:347
Type * toVectorTy(Type *Scalar, ElementCount EC)
A helper function for converting Scalar types to vector types.
std::unique_ptr< VPlan > VPlanPtr
Definition VPlan.h:74
constexpr detail::IsaCheckPredicate< Types... > IsaPred
Function object wrapper for the llvm::isa type check.
Definition Casting.h:866
LLVM_ABI_FOR_TEST bool verifyVPlanIsValid(const VPlan &Plan)
Verify invariants for general VPlans.
hash_code hash_combine_range(InputIteratorT first, InputIteratorT last)
Compute a hash_code for a sequence of values.
Definition Hashing.h:285
LLVM_ABI_FOR_TEST cl::opt< bool > VPlanPrintVectorRegionScope
LLVM_ABI cl::opt< bool > EnableLoopInterleaving
This struct is a compact representation of a valid (non-zero power of two) alignment.
Definition Alignment.h:39
A special type used by analysis passes to provide an address that identifies that particular analysis...
Definition Analysis.h:29
static LLVM_ABI void collectEphemeralValues(const Loop *L, AssumptionCache *AC, SmallPtrSetImpl< const Value * > &EphValues)
Collect a loop's ephemeral values (those used only by an assume or similar intrinsics in the loop).
Encapsulate information regarding vectorization of a loop and its epilogue.
EpilogueLoopVectorizationInfo(ElementCount MVF, unsigned MUF, ElementCount EVF, unsigned EUF, VPlan &EpiloguePlan)
A class that represents two vectorization factors (initialized with 0 by default).
static FixedScalableVFPair getNone()
This holds details about a histogram operation – a load -> update -> store sequence where each lane i...
TargetLibraryInfo * TLI
LLVM_ABI LoopVectorizeResult runImpl(Function &F)
LLVM_ABI bool processLoop(Loop *L)
ProfileSummaryInfo * PSI
LoopAccessInfoManager * LAIs
LLVM_ABI void printPipeline(raw_ostream &OS, function_ref< StringRef(StringRef)> MapClassName2PassName)
LLVM_ABI LoopVectorizePass(LoopVectorizeOptions Opts={})
ScalarEvolution * SE
AssumptionCache * AC
LLVM_ABI PreservedAnalyses run(Function &F, FunctionAnalysisManager &AM)
OptimizationRemarkEmitter * ORE
std::function< BlockFrequencyInfo &()> GetBFI
TargetTransformInfo * TTI
Storage for information about made changes.
A CRTP mix-in to automatically provide informational APIs needed for passes.
Definition PassManager.h:89
A marker analysis to determine if extra passes should be run after loop vectorization.
static LLVM_ABI AnalysisKey Key
Holds the VFShape for a specific scalar to vector function mapping.
A range of powers-of-2 vectorization factors with fixed start and adjustable end.
ElementCount End
Struct to hold various analysis needed for cost computations.
LoopVectorizationCostModel & CM
bool skipCostComputation(Instruction *UI, bool IsVector) const
Return true if the cost for UI shouldn't be computed, e.g.
InstructionCost getLegacyCost(Instruction *UI, ElementCount VF) const
Return the cost for UI with VF using the legacy cost model as fallback until computing the cost of al...
bool isMaskRequired(Instruction *I) const
Forwards to LoopVectorizationCostModel::isMaskRequired.
void invalidateWideningDecision(Instruction *I, ElementCount VF)
Mark the widening decision for I at VF as invalidated since a VPlan transform replaced the original r...
bool willBeScalarized(Instruction *I, ElementCount VF) const
Returns true if I is known to be scalarized at VF.
uint64_t getPredBlockCostDivisor(BasicBlock *BB) const
TargetTransformInfo::TargetCostKind CostKind
SmallPtrSet< Instruction *, 8 > SkipCostComputation
A VPValue representing a live-in from the input IR or a constant.
Definition VPlanValue.h:277
A pure-virtual common base class for recipes defining a single VPValue and using IR flags.
Definition VPlan.h:1113
A struct that represents some properties of the register usage of a loop.
InstructionCost spillCost(const TargetTransformInfo &TTI, TargetTransformInfo::TargetCostKind CostKind, unsigned OverrideMaxNumRegs=0) const
Calculate the estimated cost of any spills due to using more registers than the number available for ...
VPTransformState holds information passed down when "executing" a VPlan, needed for generating the ou...
A recipe for widening load operations, using the address to load from and an optional mask.
Definition VPlan.h:3782
A recipe for widening store operations, using the stored value, the address to store to and an option...
Definition VPlan.h:3881
static LLVM_ABI_FOR_TEST bool tryToConvertVPInstructionsToVPRecipes(VPlan &Plan, const TargetLibraryInfo &TLI)
Replaces the VPInstructions in Plan with corresponding widen recipes.
static void expandSCEVsToVPInstructions(VPlan &Plan, ScalarEvolution &SE)
Try to expand VPExpandSCEVRecipes in Plan's entry block to VPInstructions.
static void materializeBroadcasts(VPlan &Plan)
Add explicit broadcasts for live-ins and VPValues defined in Plan's entry block if they are used as v...
static void materializePacksAndUnpacks(VPlan &Plan)
Add explicit Build[Struct]Vector recipes to Pack multiple scalar values into vectors and Unpack recip...
static void createInterleaveGroups(VPlan &Plan, const SmallPtrSetImpl< const InterleaveGroup< Instruction > * > &InterleaveGroups, const bool &EpilogueAllowed)
static bool simplifyKnownEVL(VPlan &Plan, ElementCount VF, PredicatedScalarEvolution &PSE)
Try to simplify VPInstruction::ExplicitVectorLength recipes when the AVL is known to be <= VF,...
static void introduceMasksAndLinearize(VPlan &Plan)
Predicate and linearize the control-flow in the only loop region of Plan.
static void materializeFactors(VPlan &Plan, VPBasicBlock *VectorPH, ElementCount VF)
Materialize UF, VF and VFxUF to be computed explicitly using VPInstructions.
static void foldTailByMasking(VPlan &Plan)
Adapts the vector loop region for tail folding by introducing a header mask and conditionally executi...
static void materializeBackedgeTakenCount(VPlan &Plan, VPBasicBlock *VectorPH)
Materialize the backedge-taken count to be computed explicitly using VPInstructions.
static void addMinimumVectorEpilogueIterationCheck(VPlan &Plan, Value *VectorTripCount, bool RequiresScalarEpilogue, ElementCount EpilogueVF, unsigned EpilogueUF, unsigned MainLoopStep, unsigned EpilogueLoopStep, ScalarEvolution &SE)
Add a check to Plan to see if the epilogue vector loop should be executed.
static bool handleMultiUseReductions(VPlan &Plan, OptimizationRemarkEmitter *ORE, Loop *TheLoop)
Try to legalize reductions with multiple in-loop uses.
static void replaceWideCanonicalIVWithWideIV(VPlan &Plan, ScalarEvolution &SE, const TargetTransformInfo &TTI, TargetTransformInfo::TargetCostKind CostKind, ElementCount VF, unsigned UF, const SmallPtrSetImpl< const Value * > &ValuesToIgnore)
Replace a VPWidenCanonicalIVRecipe if it is present in Plan, with a VPWidenIntOrFpInductionRecipe,...
static void convertToVariableLengthStep(VPlan &Plan)
Transform loops with variable-length stepping after region dissolution.
static void materializeHeaderMask(VPlan &Plan, bool UseActiveLaneMask, bool UseActiveLaneMaskForControlFlow)
Materialize the abstract header mask of the loop region into concrete recipes: an active-lane-mask if...
static void addBranchWeightToMiddleTerminator(VPlan &Plan, ElementCount VF, std::optional< unsigned > VScaleForTuning)
Add branch weight metadata, if the Plan's middle block is terminated by a BranchOnCond recipe.
static std::unique_ptr< VPlan > narrowInterleaveGroups(VPlan &Plan, const TargetTransformInfo &TTI)
Try to find a single VF among Plan's VFs for which all interleave groups (with known minimum VF eleme...
static bool handleFindLastReductions(VPlan &Plan)
Check if Plan contains any FindLast reductions.
static void createInLoopReductionRecipes(VPlan &Plan, ElementCount MinVF)
Create VPReductionRecipes for in-loop reductions.
static void optimizeInductionLiveOutUsers(VPlan &Plan, PredicatedScalarEvolution &PSE)
If there's a single exit block, optimize its phi recipes that use exiting IV values by feeding them p...
static void materializeAliasMaskCheckBlock(VPlan &Plan, ArrayRef< PointerDiffInfo > DiffChecks, bool HasBranchWeights)
Materializes the alias mask within a check block before the loop.
static void unrollByUF(VPlan &Plan, unsigned UF)
Explicitly unroll Plan by UF.
static DenseMap< const SCEV *, Value * > expandSCEVs(VPlan &Plan, ScalarEvolution &SE)
Expand remaining VPExpandSCEVRecipes in Plan's entry block using SCEVExpander.
static void convertToConcreteRecipes(VPlan &Plan)
Lower abstract recipes to concrete ones, that can be codegen'd.
static LLVM_ABI_FOR_TEST void createLoopRegions(VPlan &Plan, DebugLoc DL)
Replace loops in Plan's flat CFG with VPRegionBlocks, turning Plan's flat CFG into a hierarchical CFG...
static void makeMemOpWideningDecisions(VPlan &Plan, VFRange &Range, VPRecipeBuilder &RecipeBuilder, VPCostContext &CostCtx)
Convert load/store VPInstructions in Plan into widened or replicate recipes.
static LLVM_ABI_FOR_TEST std::unique_ptr< VPlan > buildVPlan0(Loop *TheLoop, LoopInfo &LI, Type *InductionTy, PredicatedScalarEvolution &PSE, LoopVersioning *LVer=nullptr)
Create a base VPlan0, serving as the common starting point for all later candidates.
static LLVM_ABI_FOR_TEST void addMiddleCheck(VPlan &Plan)
If a check is needed to guard executing the scalar epilogue loop, it will be added to the middle bloc...
static bool createHeaderPhiRecipes(VPlan &Plan, PredicatedScalarEvolution &PSE, Loop &OrigLoop, const VPDominatorTree &VPDT, const MapVector< PHINode *, InductionDescriptor > &Inductions, const MapVector< PHINode *, RecurrenceDescriptor > &Reductions, const SmallPtrSetImpl< const PHINode * > &FixedOrderRecurrences, const SmallPtrSetImpl< PHINode * > &InLoopReductions, bool AllowReordering)
Replace VPPhi recipes in Plan's header with corresponding VPHeaderPHIRecipe subclasses for inductions...
static void expandBranchOnTwoConds(VPlan &Plan)
Expand BranchOnTwoConds instructions into explicit CFG with BranchOnCond instructions.
static void materializeVectorTripCount(VPlan &Plan, VPBasicBlock *VectorPHVPBB, bool TailByMasking, bool RequiresScalarEpilogue, VPValue *Step, std::optional< uint64_t > MaxRuntimeStep=std::nullopt)
Materialize vector trip count computations to a set of VPInstructions.
static void hoistPredicatedLoads(VPlan &Plan, PredicatedScalarEvolution &PSE, const Loop *L)
Hoist predicated loads from the same address to the loop entry block, if they are guaranteed to execu...
static void attachAliasMaskToHeaderMask(VPlan &Plan)
Attaches the alias-mask to the existing header-mask.
static void optimizeFindIVReductions(VPlan &Plan, PredicatedScalarEvolution &PSE, Loop &L)
Optimize FindLast reductions selecting IVs (or expressions of IVs) by converting them to FindIV reduc...
static void convertToAbstractRecipes(VPlan &Plan, VPCostContext &Ctx, VFRange &Range)
This function converts initial recipes to the abstract recipes and clamps Range based on cost model f...
static void materializeConstantVectorTripCount(VPlan &Plan, ElementCount BestVF, unsigned BestUF, PredicatedScalarEvolution &PSE)
static void makeScalarizationDecisions(VPlan &Plan, VFRange &Range)
Make VPlan-based scalarization decision prior to delegating to the ones made by the legacy CM.
static void addExplicitVectorLength(VPlan &Plan, const std::optional< unsigned > &MaxEVLSafeElements)
Add a VPCurrentIterationPHIRecipe and related recipes to Plan and replaces all uses of the canonical ...
static void makeCallWideningDecisions(VPlan &Plan, VFRange &Range, VPRecipeBuilder &RecipeBuilder, VPCostContext &CostCtx)
Convert call VPInstructions in Plan into widened call, vector intrinsic or replicate recipes based on...
static void adjustFirstOrderRecurrenceMiddleUsers(VPlan &Plan, VFRange &Range)
Adjust first-order recurrence users in the middle block: create penultimate element extracts for LCSS...
static void optimizeEVLMasks(VPlan &Plan)
Optimize recipes which use an EVL-based header mask to VP intrinsics, for example:
static LLVM_ABI_FOR_TEST bool handleEarlyExits(VPlan &Plan, UncountableExitStyle Style, Loop *TheLoop, PredicatedScalarEvolution &PSE, DominatorTree &DT, AssumptionCache *AC)
Update Plan to account for all early exits.
static bool handleMaxMinNumReductions(VPlan &Plan)
Check if Plan contains any FMaxNum or FMinNum reductions.
static void removeDeadRecipes(VPlan &Plan)
Remove dead recipes from Plan.
static void attachCheckBlock(VPlan &Plan, Value *Cond, BasicBlock *CheckBlock, bool AddBranchWeights)
static void simplifyRecipes(VPlan &Plan)
Perform instcombine-like simplifications on recipes in Plan.
static void sinkPredicatedStores(VPlan &Plan, PredicatedScalarEvolution &PSE, const Loop *L)
Sink predicated stores to the same address with complementary predicates (P and NOT P) to an uncondit...
static bool finalizeSCEVPredicates(VPlan &Plan, PredicatedScalarEvolution &PSE, bool OptForSize, unsigned SCEVCheckThreshold, OptimizationRemarkEmitter *ORE, Loop *TheLoop)
Finalize SCEV predicates by adding induction predicates from Plan to PSE and checking constraints.
static void replaceSymbolicStrides(VPlan &Plan, PredicatedScalarEvolution &PSE, const DenseMap< Value *, const SCEV * > &StridesMap, const VPDominatorTree &VPDT)
Replace symbolic strides from StridesMap in Plan with constants when possible.
static void replicateByVF(VPlan &Plan, ElementCount VF)
Replace replicating VPReplicateRecipe, VPScalarIVStepsRecipe and VPInstruction in Plan with VF single...
static bool removeBranchOnConst(VPlan &Plan, bool OnlyLatches=false)
Remove BranchOnCond recipes with true or false conditions together with removing dead edges to their ...
static void convertToStridedAccesses(VPlan &Plan, PredicatedScalarEvolution &PSE, Loop &L, VPCostContext &Ctx, VFRange &Range)
Transform widen memory recipes into strided access recipes when legal and profitable.
static void addIterationCountCheckBlock(VPlan &Plan, ElementCount VF, unsigned UF, bool RequiresScalarEpilogue, Loop *OrigLoop, const uint32_t *MinItersBypassWeights, DebugLoc DL, PredicatedScalarEvolution &PSE)
Add a new check block before the vector preheader to Plan to check if the main vector loop should be ...
static void clearReductionWrapFlags(VPlan &Plan)
Clear NSW/NUW flags from reduction instructions if necessary.
static void createPartialReductions(VPlan &Plan, VPCostContext &CostCtx, VFRange &Range)
Detect and create partial reduction recipes for scaled reductions in Plan.
static void addMinimumIterationCheck(VPlan &Plan, ElementCount VF, unsigned UF, ElementCount MinProfitableTripCount, bool RequiresScalarEpilogue, bool TailFolded, Loop *OrigLoop, const uint32_t *MinItersBypassWeights, DebugLoc DL, PredicatedScalarEvolution &PSE, VPBasicBlock *CheckBlock)
static void cse(VPlan &Plan)
Perform common-subexpression-elimination on Plan.
static LLVM_ABI_FOR_TEST void optimize(VPlan &Plan)
Apply VPlan-to-VPlan optimizations to Plan, including induction recipe optimizations,...
static void dissolveLoopRegions(VPlan &Plan)
Replace loop regions with explicit CFG.
static void truncateToMinimalBitwidths(VPlan &Plan, const MapVector< Instruction *, uint64_t > &MinBWs)
Insert truncates and extends for any truncated recipe.
static void dropPoisonGeneratingRecipes(VPlan &Plan)
Drop poison flags from recipes that may generate a poison value that is used after vectorization,...
static void optimizeForVFAndUF(VPlan &Plan, ElementCount BestVF, unsigned BestUF, PredicatedScalarEvolution &PSE)
Optimize Plan based on BestVF and BestUF.
static void convertEVLExitCond(VPlan &Plan)
Replaces the exit condition from (branch-on-cond eq CanonicalIVInc, VectorTripCount) to (branch-on-co...
TODO: The following VectorizationFactor was pulled out of LoopVectorizationCostModel class.
InstructionCost Cost
Cost of the loop with that width.
ElementCount MinProfitableTripCount
The minimum trip count required to make vectorization profitable, e.g.
ElementCount Width
Vector width with best cost.
InstructionCost ScalarCost
Cost of the scalar loop.
static VectorizationFactor Disabled()
Width 1 means no vectorization, cost 0 means uncomputed cost.
static LLVM_ABI bool HoistRuntimeChecks