1 //===- LoopFuse.cpp - Loop Fusion Pass ------------------------------------===//
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 /// \file
10 /// This file implements the loop fusion pass.
11 /// The implementation is largely based on the following document:
12 ///
13 /// Code Transformations to Augment the Scope of Loop Fusion in a
14 /// Production Compiler
15 /// Christopher Mark Barton
16 /// MSc Thesis
17 /// https://webdocs.cs.ualberta.ca/~amaral/thesis/ChristopherBartonMSc.pdf
18 ///
19 /// The general approach taken is to collect sets of control flow equivalent
20 /// loops and test whether they can be fused. The necessary conditions for
21 /// fusion are:
22 /// 1. The loops must be adjacent (there cannot be any statements between
23 /// the two loops).
24 /// 2. The loops must be conforming (they must execute the same number of
25 /// iterations).
26 /// 3. The loops must be control flow equivalent (if one loop executes, the
27 /// other is guaranteed to execute).
28 /// 4. There cannot be any negative distance dependencies between the loops.
29 /// If all of these conditions are satisfied, it is safe to fuse the loops.
30 ///
31 /// This implementation creates FusionCandidates that represent the loop and the
32 /// necessary information needed by fusion. It then operates on the fusion
33 /// candidates, first confirming that the candidate is eligible for fusion. The
34 /// candidates are then collected into control flow equivalent sets, sorted in
35 /// dominance order. Each set of control flow equivalent candidates is then
36 /// traversed, attempting to fuse pairs of candidates in the set. If all
37 /// requirements for fusion are met, the two candidates are fused, creating a
38 /// new (fused) candidate which is then added back into the set to consider for
39 /// additional fusion.
40 ///
41 /// This implementation currently does not make any modifications to remove
42 /// conditions for fusion. Code transformations to make loops conform to each of
43 /// the conditions for fusion are discussed in more detail in the document
44 /// above. These can be added to the current implementation in the future.
45 //===----------------------------------------------------------------------===//
46
47 #include "llvm/Transforms/Scalar/LoopFuse.h"
48 #include "llvm/ADT/Statistic.h"
49 #include "llvm/Analysis/AssumptionCache.h"
50 #include "llvm/Analysis/DependenceAnalysis.h"
51 #include "llvm/Analysis/DomTreeUpdater.h"
52 #include "llvm/Analysis/LoopInfo.h"
53 #include "llvm/Analysis/OptimizationRemarkEmitter.h"
54 #include "llvm/Analysis/PostDominators.h"
55 #include "llvm/Analysis/ScalarEvolution.h"
56 #include "llvm/Analysis/ScalarEvolutionExpressions.h"
57 #include "llvm/Analysis/TargetTransformInfo.h"
58 #include "llvm/IR/Function.h"
59 #include "llvm/IR/Verifier.h"
60 #include "llvm/Support/CommandLine.h"
61 #include "llvm/Support/Debug.h"
62 #include "llvm/Support/raw_ostream.h"
63 #include "llvm/Transforms/Utils.h"
64 #include "llvm/Transforms/Utils/BasicBlockUtils.h"
65 #include "llvm/Transforms/Utils/CodeMoverUtils.h"
66 #include "llvm/Transforms/Utils/LoopPeel.h"
67 #include "llvm/Transforms/Utils/LoopSimplify.h"
68
69 using namespace llvm;
70
71 #define DEBUG_TYPE "loop-fusion"
72
73 STATISTIC(FuseCounter, "Loops fused");
74 STATISTIC(NumFusionCandidates, "Number of candidates for loop fusion");
75 STATISTIC(InvalidPreheader, "Loop has invalid preheader");
76 STATISTIC(InvalidHeader, "Loop has invalid header");
77 STATISTIC(InvalidExitingBlock, "Loop has invalid exiting blocks");
78 STATISTIC(InvalidExitBlock, "Loop has invalid exit block");
79 STATISTIC(InvalidLatch, "Loop has invalid latch");
80 STATISTIC(InvalidLoop, "Loop is invalid");
81 STATISTIC(AddressTakenBB, "Basic block has address taken");
82 STATISTIC(MayThrowException, "Loop may throw an exception");
83 STATISTIC(ContainsVolatileAccess, "Loop contains a volatile access");
84 STATISTIC(NotSimplifiedForm, "Loop is not in simplified form");
85 STATISTIC(InvalidDependencies, "Dependencies prevent fusion");
86 STATISTIC(UnknownTripCount, "Loop has unknown trip count");
87 STATISTIC(UncomputableTripCount, "SCEV cannot compute trip count of loop");
88 STATISTIC(NonEqualTripCount, "Loop trip counts are not the same");
89 STATISTIC(NonAdjacent, "Loops are not adjacent");
90 STATISTIC(
91 NonEmptyPreheader,
92 "Loop has a non-empty preheader with instructions that cannot be moved");
93 STATISTIC(FusionNotBeneficial, "Fusion is not beneficial");
94 STATISTIC(NonIdenticalGuards, "Candidates have different guards");
95 STATISTIC(NonEmptyExitBlock, "Candidate has a non-empty exit block with "
96 "instructions that cannot be moved");
97 STATISTIC(NonEmptyGuardBlock, "Candidate has a non-empty guard block with "
98 "instructions that cannot be moved");
99 STATISTIC(NotRotated, "Candidate is not rotated");
100 STATISTIC(OnlySecondCandidateIsGuarded,
101 "The second candidate is guarded while the first one is not");
102 STATISTIC(NumHoistedInsts, "Number of hoisted preheader instructions.");
103 STATISTIC(NumSunkInsts, "Number of hoisted preheader instructions.");
104
105 enum FusionDependenceAnalysisChoice {
106 FUSION_DEPENDENCE_ANALYSIS_SCEV,
107 FUSION_DEPENDENCE_ANALYSIS_DA,
108 FUSION_DEPENDENCE_ANALYSIS_ALL,
109 };
110
111 static cl::opt<FusionDependenceAnalysisChoice> FusionDependenceAnalysis(
112 "loop-fusion-dependence-analysis",
113 cl::desc("Which dependence analysis should loop fusion use?"),
114 cl::values(clEnumValN(FUSION_DEPENDENCE_ANALYSIS_SCEV, "scev",
115 "Use the scalar evolution interface"),
116 clEnumValN(FUSION_DEPENDENCE_ANALYSIS_DA, "da",
117 "Use the dependence analysis interface"),
118 clEnumValN(FUSION_DEPENDENCE_ANALYSIS_ALL, "all",
119 "Use all available analyses")),
120 cl::Hidden, cl::init(FUSION_DEPENDENCE_ANALYSIS_ALL));
121
122 static cl::opt<unsigned> FusionPeelMaxCount(
123 "loop-fusion-peel-max-count", cl::init(0), cl::Hidden,
124 cl::desc("Max number of iterations to be peeled from a loop, such that "
125 "fusion can take place"));
126
127 #ifndef NDEBUG
128 static cl::opt<bool>
129 VerboseFusionDebugging("loop-fusion-verbose-debug",
130 cl::desc("Enable verbose debugging for Loop Fusion"),
131 cl::Hidden, cl::init(false));
132 #endif
133
134 namespace {
135 /// This class is used to represent a candidate for loop fusion. When it is
136 /// constructed, it checks the conditions for loop fusion to ensure that it
137 /// represents a valid candidate. It caches several parts of a loop that are
138 /// used throughout loop fusion (e.g., loop preheader, loop header, etc) instead
139 /// of continually querying the underlying Loop to retrieve these values. It is
140 /// assumed these will not change throughout loop fusion.
141 ///
142 /// The invalidate method should be used to indicate that the FusionCandidate is
143 /// no longer a valid candidate for fusion. Similarly, the isValid() method can
144 /// be used to ensure that the FusionCandidate is still valid for fusion.
145 struct FusionCandidate {
146 /// Cache of parts of the loop used throughout loop fusion. These should not
147 /// need to change throughout the analysis and transformation.
148 /// These parts are cached to avoid repeatedly looking up in the Loop class.
149
150 /// Preheader of the loop this candidate represents
151 BasicBlock *Preheader;
152 /// Header of the loop this candidate represents
153 BasicBlock *Header;
154 /// Blocks in the loop that exit the loop
155 BasicBlock *ExitingBlock;
156 /// The successor block of this loop (where the exiting blocks go to)
157 BasicBlock *ExitBlock;
158 /// Latch of the loop
159 BasicBlock *Latch;
160 /// The loop that this fusion candidate represents
161 Loop *L;
162 /// Vector of instructions in this loop that read from memory
163 SmallVector<Instruction *, 16> MemReads;
164 /// Vector of instructions in this loop that write to memory
165 SmallVector<Instruction *, 16> MemWrites;
166 /// Are all of the members of this fusion candidate still valid
167 bool Valid;
168 /// Guard branch of the loop, if it exists
169 BranchInst *GuardBranch;
170 /// Peeling Paramaters of the Loop.
171 TTI::PeelingPreferences PP;
172 /// Can you Peel this Loop?
173 bool AbleToPeel;
174 /// Has this loop been Peeled
175 bool Peeled;
176
177 /// Dominator and PostDominator trees are needed for the
178 /// FusionCandidateCompare function, required by FusionCandidateSet to
179 /// determine where the FusionCandidate should be inserted into the set. These
180 /// are used to establish ordering of the FusionCandidates based on dominance.
181 DominatorTree &DT;
182 const PostDominatorTree *PDT;
183
184 OptimizationRemarkEmitter &ORE;
185
FusionCandidate__anond06fd9000111::FusionCandidate186 FusionCandidate(Loop *L, DominatorTree &DT, const PostDominatorTree *PDT,
187 OptimizationRemarkEmitter &ORE, TTI::PeelingPreferences PP)
188 : Preheader(L->getLoopPreheader()), Header(L->getHeader()),
189 ExitingBlock(L->getExitingBlock()), ExitBlock(L->getExitBlock()),
190 Latch(L->getLoopLatch()), L(L), Valid(true),
191 GuardBranch(L->getLoopGuardBranch()), PP(PP), AbleToPeel(canPeel(L)),
192 Peeled(false), DT(DT), PDT(PDT), ORE(ORE) {
193
194 // Walk over all blocks in the loop and check for conditions that may
195 // prevent fusion. For each block, walk over all instructions and collect
196 // the memory reads and writes If any instructions that prevent fusion are
197 // found, invalidate this object and return.
198 for (BasicBlock *BB : L->blocks()) {
199 if (BB->hasAddressTaken()) {
200 invalidate();
201 reportInvalidCandidate(AddressTakenBB);
202 return;
203 }
204
205 for (Instruction &I : *BB) {
206 if (I.mayThrow()) {
207 invalidate();
208 reportInvalidCandidate(MayThrowException);
209 return;
210 }
211 if (StoreInst *SI = dyn_cast<StoreInst>(&I)) {
212 if (SI->isVolatile()) {
213 invalidate();
214 reportInvalidCandidate(ContainsVolatileAccess);
215 return;
216 }
217 }
218 if (LoadInst *LI = dyn_cast<LoadInst>(&I)) {
219 if (LI->isVolatile()) {
220 invalidate();
221 reportInvalidCandidate(ContainsVolatileAccess);
222 return;
223 }
224 }
225 if (I.mayWriteToMemory())
226 MemWrites.push_back(&I);
227 if (I.mayReadFromMemory())
228 MemReads.push_back(&I);
229 }
230 }
231 }
232
233 /// Check if all members of the class are valid.
isValid__anond06fd9000111::FusionCandidate234 bool isValid() const {
235 return Preheader && Header && ExitingBlock && ExitBlock && Latch && L &&
236 !L->isInvalid() && Valid;
237 }
238
239 /// Verify that all members are in sync with the Loop object.
verify__anond06fd9000111::FusionCandidate240 void verify() const {
241 assert(isValid() && "Candidate is not valid!!");
242 assert(!L->isInvalid() && "Loop is invalid!");
243 assert(Preheader == L->getLoopPreheader() && "Preheader is out of sync");
244 assert(Header == L->getHeader() && "Header is out of sync");
245 assert(ExitingBlock == L->getExitingBlock() &&
246 "Exiting Blocks is out of sync");
247 assert(ExitBlock == L->getExitBlock() && "Exit block is out of sync");
248 assert(Latch == L->getLoopLatch() && "Latch is out of sync");
249 }
250
251 /// Get the entry block for this fusion candidate.
252 ///
253 /// If this fusion candidate represents a guarded loop, the entry block is the
254 /// loop guard block. If it represents an unguarded loop, the entry block is
255 /// the preheader of the loop.
getEntryBlock__anond06fd9000111::FusionCandidate256 BasicBlock *getEntryBlock() const {
257 if (GuardBranch)
258 return GuardBranch->getParent();
259 else
260 return Preheader;
261 }
262
263 /// After Peeling the loop is modified quite a bit, hence all of the Blocks
264 /// need to be updated accordingly.
updateAfterPeeling__anond06fd9000111::FusionCandidate265 void updateAfterPeeling() {
266 Preheader = L->getLoopPreheader();
267 Header = L->getHeader();
268 ExitingBlock = L->getExitingBlock();
269 ExitBlock = L->getExitBlock();
270 Latch = L->getLoopLatch();
271 verify();
272 }
273
274 /// Given a guarded loop, get the successor of the guard that is not in the
275 /// loop.
276 ///
277 /// This method returns the successor of the loop guard that is not located
278 /// within the loop (i.e., the successor of the guard that is not the
279 /// preheader).
280 /// This method is only valid for guarded loops.
getNonLoopBlock__anond06fd9000111::FusionCandidate281 BasicBlock *getNonLoopBlock() const {
282 assert(GuardBranch && "Only valid on guarded loops.");
283 assert(GuardBranch->isConditional() &&
284 "Expecting guard to be a conditional branch.");
285 if (Peeled)
286 return GuardBranch->getSuccessor(1);
287 return (GuardBranch->getSuccessor(0) == Preheader)
288 ? GuardBranch->getSuccessor(1)
289 : GuardBranch->getSuccessor(0);
290 }
291
292 #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
dump__anond06fd9000111::FusionCandidate293 LLVM_DUMP_METHOD void dump() const {
294 dbgs() << "\tGuardBranch: ";
295 if (GuardBranch)
296 dbgs() << *GuardBranch;
297 else
298 dbgs() << "nullptr";
299 dbgs() << "\n"
300 << (GuardBranch ? GuardBranch->getName() : "nullptr") << "\n"
301 << "\tPreheader: " << (Preheader ? Preheader->getName() : "nullptr")
302 << "\n"
303 << "\tHeader: " << (Header ? Header->getName() : "nullptr") << "\n"
304 << "\tExitingBB: "
305 << (ExitingBlock ? ExitingBlock->getName() : "nullptr") << "\n"
306 << "\tExitBB: " << (ExitBlock ? ExitBlock->getName() : "nullptr")
307 << "\n"
308 << "\tLatch: " << (Latch ? Latch->getName() : "nullptr") << "\n"
309 << "\tEntryBlock: "
310 << (getEntryBlock() ? getEntryBlock()->getName() : "nullptr")
311 << "\n";
312 }
313 #endif
314
315 /// Determine if a fusion candidate (representing a loop) is eligible for
316 /// fusion. Note that this only checks whether a single loop can be fused - it
317 /// does not check whether it is *legal* to fuse two loops together.
isEligibleForFusion__anond06fd9000111::FusionCandidate318 bool isEligibleForFusion(ScalarEvolution &SE) const {
319 if (!isValid()) {
320 LLVM_DEBUG(dbgs() << "FC has invalid CFG requirements!\n");
321 if (!Preheader)
322 ++InvalidPreheader;
323 if (!Header)
324 ++InvalidHeader;
325 if (!ExitingBlock)
326 ++InvalidExitingBlock;
327 if (!ExitBlock)
328 ++InvalidExitBlock;
329 if (!Latch)
330 ++InvalidLatch;
331 if (L->isInvalid())
332 ++InvalidLoop;
333
334 return false;
335 }
336
337 // Require ScalarEvolution to be able to determine a trip count.
338 if (!SE.hasLoopInvariantBackedgeTakenCount(L)) {
339 LLVM_DEBUG(dbgs() << "Loop " << L->getName()
340 << " trip count not computable!\n");
341 return reportInvalidCandidate(UnknownTripCount);
342 }
343
344 if (!L->isLoopSimplifyForm()) {
345 LLVM_DEBUG(dbgs() << "Loop " << L->getName()
346 << " is not in simplified form!\n");
347 return reportInvalidCandidate(NotSimplifiedForm);
348 }
349
350 if (!L->isRotatedForm()) {
351 LLVM_DEBUG(dbgs() << "Loop " << L->getName() << " is not rotated!\n");
352 return reportInvalidCandidate(NotRotated);
353 }
354
355 return true;
356 }
357
358 private:
359 // This is only used internally for now, to clear the MemWrites and MemReads
360 // list and setting Valid to false. I can't envision other uses of this right
361 // now, since once FusionCandidates are put into the FusionCandidateSet they
362 // are immutable. Thus, any time we need to change/update a FusionCandidate,
363 // we must create a new one and insert it into the FusionCandidateSet to
364 // ensure the FusionCandidateSet remains ordered correctly.
invalidate__anond06fd9000111::FusionCandidate365 void invalidate() {
366 MemWrites.clear();
367 MemReads.clear();
368 Valid = false;
369 }
370
reportInvalidCandidate__anond06fd9000111::FusionCandidate371 bool reportInvalidCandidate(llvm::Statistic &Stat) const {
372 using namespace ore;
373 assert(L && Preheader && "Fusion candidate not initialized properly!");
374 #if LLVM_ENABLE_STATS
375 ++Stat;
376 ORE.emit(OptimizationRemarkAnalysis(DEBUG_TYPE, Stat.getName(),
377 L->getStartLoc(), Preheader)
378 << "[" << Preheader->getParent()->getName() << "]: "
379 << "Loop is not a candidate for fusion: " << Stat.getDesc());
380 #endif
381 return false;
382 }
383 };
384
385 struct FusionCandidateCompare {
386 /// Comparison functor to sort two Control Flow Equivalent fusion candidates
387 /// into dominance order.
388 /// If LHS dominates RHS and RHS post-dominates LHS, return true;
389 /// If RHS dominates LHS and LHS post-dominates RHS, return false;
390 /// If both LHS and RHS are not dominating each other then, non-strictly
391 /// post dominate check will decide the order of candidates. If RHS
392 /// non-strictly post dominates LHS then, return true. If LHS non-strictly
393 /// post dominates RHS then, return false. If both are non-strictly post
394 /// dominate each other then, level in the post dominator tree will decide
395 /// the order of candidates.
operator ()__anond06fd9000111::FusionCandidateCompare396 bool operator()(const FusionCandidate &LHS,
397 const FusionCandidate &RHS) const {
398 const DominatorTree *DT = &(LHS.DT);
399
400 BasicBlock *LHSEntryBlock = LHS.getEntryBlock();
401 BasicBlock *RHSEntryBlock = RHS.getEntryBlock();
402
403 // Do not save PDT to local variable as it is only used in asserts and thus
404 // will trigger an unused variable warning if building without asserts.
405 assert(DT && LHS.PDT && "Expecting valid dominator tree");
406
407 // Do this compare first so if LHS == RHS, function returns false.
408 if (DT->dominates(RHSEntryBlock, LHSEntryBlock)) {
409 // RHS dominates LHS
410 // Verify LHS post-dominates RHS
411 assert(LHS.PDT->dominates(LHSEntryBlock, RHSEntryBlock));
412 return false;
413 }
414
415 if (DT->dominates(LHSEntryBlock, RHSEntryBlock)) {
416 // Verify RHS Postdominates LHS
417 assert(LHS.PDT->dominates(RHSEntryBlock, LHSEntryBlock));
418 return true;
419 }
420
421 // If two FusionCandidates are in the same level of dominator tree,
422 // they will not dominate each other, but may still be control flow
423 // equivalent. To sort those FusionCandidates, nonStrictlyPostDominate()
424 // function is needed.
425 bool WrongOrder =
426 nonStrictlyPostDominate(LHSEntryBlock, RHSEntryBlock, DT, LHS.PDT);
427 bool RightOrder =
428 nonStrictlyPostDominate(RHSEntryBlock, LHSEntryBlock, DT, LHS.PDT);
429 if (WrongOrder && RightOrder) {
430 // If common predecessor of LHS and RHS post dominates both
431 // FusionCandidates then, Order of FusionCandidate can be
432 // identified by its level in post dominator tree.
433 DomTreeNode *LNode = LHS.PDT->getNode(LHSEntryBlock);
434 DomTreeNode *RNode = LHS.PDT->getNode(RHSEntryBlock);
435 return LNode->getLevel() > RNode->getLevel();
436 } else if (WrongOrder)
437 return false;
438 else if (RightOrder)
439 return true;
440
441 // If LHS does not non-strict Postdominate RHS and RHS does not non-strict
442 // Postdominate LHS then, there is no dominance relationship between the
443 // two FusionCandidates. Thus, they should not be in the same set together.
444 llvm_unreachable(
445 "No dominance relationship between these fusion candidates!");
446 }
447 };
448
449 using LoopVector = SmallVector<Loop *, 4>;
450
451 // Set of Control Flow Equivalent (CFE) Fusion Candidates, sorted in dominance
452 // order. Thus, if FC0 comes *before* FC1 in a FusionCandidateSet, then FC0
453 // dominates FC1 and FC1 post-dominates FC0.
454 // std::set was chosen because we want a sorted data structure with stable
455 // iterators. A subsequent patch to loop fusion will enable fusing non-adjacent
456 // loops by moving intervening code around. When this intervening code contains
457 // loops, those loops will be moved also. The corresponding FusionCandidates
458 // will also need to be moved accordingly. As this is done, having stable
459 // iterators will simplify the logic. Similarly, having an efficient insert that
460 // keeps the FusionCandidateSet sorted will also simplify the implementation.
461 using FusionCandidateSet = std::set<FusionCandidate, FusionCandidateCompare>;
462 using FusionCandidateCollection = SmallVector<FusionCandidateSet, 4>;
463
464 #if !defined(NDEBUG)
operator <<(llvm::raw_ostream & OS,const FusionCandidate & FC)465 static llvm::raw_ostream &operator<<(llvm::raw_ostream &OS,
466 const FusionCandidate &FC) {
467 if (FC.isValid())
468 OS << FC.Preheader->getName();
469 else
470 OS << "<Invalid>";
471
472 return OS;
473 }
474
operator <<(llvm::raw_ostream & OS,const FusionCandidateSet & CandSet)475 static llvm::raw_ostream &operator<<(llvm::raw_ostream &OS,
476 const FusionCandidateSet &CandSet) {
477 for (const FusionCandidate &FC : CandSet)
478 OS << FC << '\n';
479
480 return OS;
481 }
482
483 static void
printFusionCandidates(const FusionCandidateCollection & FusionCandidates)484 printFusionCandidates(const FusionCandidateCollection &FusionCandidates) {
485 dbgs() << "Fusion Candidates: \n";
486 for (const auto &CandidateSet : FusionCandidates) {
487 dbgs() << "*** Fusion Candidate Set ***\n";
488 dbgs() << CandidateSet;
489 dbgs() << "****************************\n";
490 }
491 }
492 #endif
493
494 /// Collect all loops in function at the same nest level, starting at the
495 /// outermost level.
496 ///
497 /// This data structure collects all loops at the same nest level for a
498 /// given function (specified by the LoopInfo object). It starts at the
499 /// outermost level.
500 struct LoopDepthTree {
501 using LoopsOnLevelTy = SmallVector<LoopVector, 4>;
502 using iterator = LoopsOnLevelTy::iterator;
503 using const_iterator = LoopsOnLevelTy::const_iterator;
504
LoopDepthTree__anond06fd9000111::LoopDepthTree505 LoopDepthTree(LoopInfo &LI) : Depth(1) {
506 if (!LI.empty())
507 LoopsOnLevel.emplace_back(LoopVector(LI.rbegin(), LI.rend()));
508 }
509
510 /// Test whether a given loop has been removed from the function, and thus is
511 /// no longer valid.
isRemovedLoop__anond06fd9000111::LoopDepthTree512 bool isRemovedLoop(const Loop *L) const { return RemovedLoops.count(L); }
513
514 /// Record that a given loop has been removed from the function and is no
515 /// longer valid.
removeLoop__anond06fd9000111::LoopDepthTree516 void removeLoop(const Loop *L) { RemovedLoops.insert(L); }
517
518 /// Descend the tree to the next (inner) nesting level
descend__anond06fd9000111::LoopDepthTree519 void descend() {
520 LoopsOnLevelTy LoopsOnNextLevel;
521
522 for (const LoopVector &LV : *this)
523 for (Loop *L : LV)
524 if (!isRemovedLoop(L) && L->begin() != L->end())
525 LoopsOnNextLevel.emplace_back(LoopVector(L->begin(), L->end()));
526
527 LoopsOnLevel = LoopsOnNextLevel;
528 RemovedLoops.clear();
529 Depth++;
530 }
531
empty__anond06fd9000111::LoopDepthTree532 bool empty() const { return size() == 0; }
size__anond06fd9000111::LoopDepthTree533 size_t size() const { return LoopsOnLevel.size() - RemovedLoops.size(); }
getDepth__anond06fd9000111::LoopDepthTree534 unsigned getDepth() const { return Depth; }
535
begin__anond06fd9000111::LoopDepthTree536 iterator begin() { return LoopsOnLevel.begin(); }
end__anond06fd9000111::LoopDepthTree537 iterator end() { return LoopsOnLevel.end(); }
begin__anond06fd9000111::LoopDepthTree538 const_iterator begin() const { return LoopsOnLevel.begin(); }
end__anond06fd9000111::LoopDepthTree539 const_iterator end() const { return LoopsOnLevel.end(); }
540
541 private:
542 /// Set of loops that have been removed from the function and are no longer
543 /// valid.
544 SmallPtrSet<const Loop *, 8> RemovedLoops;
545
546 /// Depth of the current level, starting at 1 (outermost loops).
547 unsigned Depth;
548
549 /// Vector of loops at the current depth level that have the same parent loop
550 LoopsOnLevelTy LoopsOnLevel;
551 };
552
553 #ifndef NDEBUG
printLoopVector(const LoopVector & LV)554 static void printLoopVector(const LoopVector &LV) {
555 dbgs() << "****************************\n";
556 for (auto *L : LV)
557 printLoop(*L, dbgs());
558 dbgs() << "****************************\n";
559 }
560 #endif
561
562 struct LoopFuser {
563 private:
564 // Sets of control flow equivalent fusion candidates for a given nest level.
565 FusionCandidateCollection FusionCandidates;
566
567 LoopDepthTree LDT;
568 DomTreeUpdater DTU;
569
570 LoopInfo &LI;
571 DominatorTree &DT;
572 DependenceInfo &DI;
573 ScalarEvolution &SE;
574 PostDominatorTree &PDT;
575 OptimizationRemarkEmitter &ORE;
576 AssumptionCache &AC;
577 const TargetTransformInfo &TTI;
578
579 public:
LoopFuser__anond06fd9000111::LoopFuser580 LoopFuser(LoopInfo &LI, DominatorTree &DT, DependenceInfo &DI,
581 ScalarEvolution &SE, PostDominatorTree &PDT,
582 OptimizationRemarkEmitter &ORE, const DataLayout &DL,
583 AssumptionCache &AC, const TargetTransformInfo &TTI)
584 : LDT(LI), DTU(DT, PDT, DomTreeUpdater::UpdateStrategy::Lazy), LI(LI),
585 DT(DT), DI(DI), SE(SE), PDT(PDT), ORE(ORE), AC(AC), TTI(TTI) {}
586
587 /// This is the main entry point for loop fusion. It will traverse the
588 /// specified function and collect candidate loops to fuse, starting at the
589 /// outermost nesting level and working inwards.
fuseLoops__anond06fd9000111::LoopFuser590 bool fuseLoops(Function &F) {
591 #ifndef NDEBUG
592 if (VerboseFusionDebugging) {
593 LI.print(dbgs());
594 }
595 #endif
596
597 LLVM_DEBUG(dbgs() << "Performing Loop Fusion on function " << F.getName()
598 << "\n");
599 bool Changed = false;
600
601 while (!LDT.empty()) {
602 LLVM_DEBUG(dbgs() << "Got " << LDT.size() << " loop sets for depth "
603 << LDT.getDepth() << "\n";);
604
605 for (const LoopVector &LV : LDT) {
606 assert(LV.size() > 0 && "Empty loop set was build!");
607
608 // Skip singleton loop sets as they do not offer fusion opportunities on
609 // this level.
610 if (LV.size() == 1)
611 continue;
612 #ifndef NDEBUG
613 if (VerboseFusionDebugging) {
614 LLVM_DEBUG({
615 dbgs() << " Visit loop set (#" << LV.size() << "):\n";
616 printLoopVector(LV);
617 });
618 }
619 #endif
620
621 collectFusionCandidates(LV);
622 Changed |= fuseCandidates();
623 }
624
625 // Finished analyzing candidates at this level.
626 // Descend to the next level and clear all of the candidates currently
627 // collected. Note that it will not be possible to fuse any of the
628 // existing candidates with new candidates because the new candidates will
629 // be at a different nest level and thus not be control flow equivalent
630 // with all of the candidates collected so far.
631 LLVM_DEBUG(dbgs() << "Descend one level!\n");
632 LDT.descend();
633 FusionCandidates.clear();
634 }
635
636 if (Changed)
637 LLVM_DEBUG(dbgs() << "Function after Loop Fusion: \n"; F.dump(););
638
639 #ifndef NDEBUG
640 assert(DT.verify());
641 assert(PDT.verify());
642 LI.verify(DT);
643 SE.verify();
644 #endif
645
646 LLVM_DEBUG(dbgs() << "Loop Fusion complete\n");
647 return Changed;
648 }
649
650 private:
651 /// Determine if two fusion candidates are control flow equivalent.
652 ///
653 /// Two fusion candidates are control flow equivalent if when one executes,
654 /// the other is guaranteed to execute. This is determined using dominators
655 /// and post-dominators: if A dominates B and B post-dominates A then A and B
656 /// are control-flow equivalent.
isControlFlowEquivalent__anond06fd9000111::LoopFuser657 bool isControlFlowEquivalent(const FusionCandidate &FC0,
658 const FusionCandidate &FC1) const {
659 assert(FC0.Preheader && FC1.Preheader && "Expecting valid preheaders");
660
661 return ::isControlFlowEquivalent(*FC0.getEntryBlock(), *FC1.getEntryBlock(),
662 DT, PDT);
663 }
664
665 /// Iterate over all loops in the given loop set and identify the loops that
666 /// are eligible for fusion. Place all eligible fusion candidates into Control
667 /// Flow Equivalent sets, sorted by dominance.
collectFusionCandidates__anond06fd9000111::LoopFuser668 void collectFusionCandidates(const LoopVector &LV) {
669 for (Loop *L : LV) {
670 TTI::PeelingPreferences PP =
671 gatherPeelingPreferences(L, SE, TTI, std::nullopt, std::nullopt);
672 FusionCandidate CurrCand(L, DT, &PDT, ORE, PP);
673 if (!CurrCand.isEligibleForFusion(SE))
674 continue;
675
676 // Go through each list in FusionCandidates and determine if L is control
677 // flow equivalent with the first loop in that list. If it is, append LV.
678 // If not, go to the next list.
679 // If no suitable list is found, start another list and add it to
680 // FusionCandidates.
681 bool FoundSet = false;
682
683 for (auto &CurrCandSet : FusionCandidates) {
684 if (isControlFlowEquivalent(*CurrCandSet.begin(), CurrCand)) {
685 CurrCandSet.insert(CurrCand);
686 FoundSet = true;
687 #ifndef NDEBUG
688 if (VerboseFusionDebugging)
689 LLVM_DEBUG(dbgs() << "Adding " << CurrCand
690 << " to existing candidate set\n");
691 #endif
692 break;
693 }
694 }
695 if (!FoundSet) {
696 // No set was found. Create a new set and add to FusionCandidates
697 #ifndef NDEBUG
698 if (VerboseFusionDebugging)
699 LLVM_DEBUG(dbgs() << "Adding " << CurrCand << " to new set\n");
700 #endif
701 FusionCandidateSet NewCandSet;
702 NewCandSet.insert(CurrCand);
703 FusionCandidates.push_back(NewCandSet);
704 }
705 NumFusionCandidates++;
706 }
707 }
708
709 /// Determine if it is beneficial to fuse two loops.
710 ///
711 /// For now, this method simply returns true because we want to fuse as much
712 /// as possible (primarily to test the pass). This method will evolve, over
713 /// time, to add heuristics for profitability of fusion.
isBeneficialFusion__anond06fd9000111::LoopFuser714 bool isBeneficialFusion(const FusionCandidate &FC0,
715 const FusionCandidate &FC1) {
716 return true;
717 }
718
719 /// Determine if two fusion candidates have the same trip count (i.e., they
720 /// execute the same number of iterations).
721 ///
722 /// This function will return a pair of values. The first is a boolean,
723 /// stating whether or not the two candidates are known at compile time to
724 /// have the same TripCount. The second is the difference in the two
725 /// TripCounts. This information can be used later to determine whether or not
726 /// peeling can be performed on either one of the candidates.
727 std::pair<bool, std::optional<unsigned>>
haveIdenticalTripCounts__anond06fd9000111::LoopFuser728 haveIdenticalTripCounts(const FusionCandidate &FC0,
729 const FusionCandidate &FC1) const {
730 const SCEV *TripCount0 = SE.getBackedgeTakenCount(FC0.L);
731 if (isa<SCEVCouldNotCompute>(TripCount0)) {
732 UncomputableTripCount++;
733 LLVM_DEBUG(dbgs() << "Trip count of first loop could not be computed!");
734 return {false, std::nullopt};
735 }
736
737 const SCEV *TripCount1 = SE.getBackedgeTakenCount(FC1.L);
738 if (isa<SCEVCouldNotCompute>(TripCount1)) {
739 UncomputableTripCount++;
740 LLVM_DEBUG(dbgs() << "Trip count of second loop could not be computed!");
741 return {false, std::nullopt};
742 }
743
744 LLVM_DEBUG(dbgs() << "\tTrip counts: " << *TripCount0 << " & "
745 << *TripCount1 << " are "
746 << (TripCount0 == TripCount1 ? "identical" : "different")
747 << "\n");
748
749 if (TripCount0 == TripCount1)
750 return {true, 0};
751
752 LLVM_DEBUG(dbgs() << "The loops do not have the same tripcount, "
753 "determining the difference between trip counts\n");
754
755 // Currently only considering loops with a single exit point
756 // and a non-constant trip count.
757 const unsigned TC0 = SE.getSmallConstantTripCount(FC0.L);
758 const unsigned TC1 = SE.getSmallConstantTripCount(FC1.L);
759
760 // If any of the tripcounts are zero that means that loop(s) do not have
761 // a single exit or a constant tripcount.
762 if (TC0 == 0 || TC1 == 0) {
763 LLVM_DEBUG(dbgs() << "Loop(s) do not have a single exit point or do not "
764 "have a constant number of iterations. Peeling "
765 "is not benefical\n");
766 return {false, std::nullopt};
767 }
768
769 std::optional<unsigned> Difference;
770 int Diff = TC0 - TC1;
771
772 if (Diff > 0)
773 Difference = Diff;
774 else {
775 LLVM_DEBUG(
776 dbgs() << "Difference is less than 0. FC1 (second loop) has more "
777 "iterations than the first one. Currently not supported\n");
778 }
779
780 LLVM_DEBUG(dbgs() << "Difference in loop trip count is: " << Difference
781 << "\n");
782
783 return {false, Difference};
784 }
785
peelFusionCandidate__anond06fd9000111::LoopFuser786 void peelFusionCandidate(FusionCandidate &FC0, const FusionCandidate &FC1,
787 unsigned PeelCount) {
788 assert(FC0.AbleToPeel && "Should be able to peel loop");
789
790 LLVM_DEBUG(dbgs() << "Attempting to peel first " << PeelCount
791 << " iterations of the first loop. \n");
792
793 ValueToValueMapTy VMap;
794 FC0.Peeled = peelLoop(FC0.L, PeelCount, &LI, &SE, DT, &AC, true, VMap);
795 if (FC0.Peeled) {
796 LLVM_DEBUG(dbgs() << "Done Peeling\n");
797
798 #ifndef NDEBUG
799 auto IdenticalTripCount = haveIdenticalTripCounts(FC0, FC1);
800
801 assert(IdenticalTripCount.first && *IdenticalTripCount.second == 0 &&
802 "Loops should have identical trip counts after peeling");
803 #endif
804
805 FC0.PP.PeelCount += PeelCount;
806
807 // Peeling does not update the PDT
808 PDT.recalculate(*FC0.Preheader->getParent());
809
810 FC0.updateAfterPeeling();
811
812 // In this case the iterations of the loop are constant, so the first
813 // loop will execute completely (will not jump from one of
814 // the peeled blocks to the second loop). Here we are updating the
815 // branch conditions of each of the peeled blocks, such that it will
816 // branch to its successor which is not the preheader of the second loop
817 // in the case of unguarded loops, or the succesors of the exit block of
818 // the first loop otherwise. Doing this update will ensure that the entry
819 // block of the first loop dominates the entry block of the second loop.
820 BasicBlock *BB =
821 FC0.GuardBranch ? FC0.ExitBlock->getUniqueSuccessor() : FC1.Preheader;
822 if (BB) {
823 SmallVector<DominatorTree::UpdateType, 8> TreeUpdates;
824 SmallVector<Instruction *, 8> WorkList;
825 for (BasicBlock *Pred : predecessors(BB)) {
826 if (Pred != FC0.ExitBlock) {
827 WorkList.emplace_back(Pred->getTerminator());
828 TreeUpdates.emplace_back(
829 DominatorTree::UpdateType(DominatorTree::Delete, Pred, BB));
830 }
831 }
832 // Cannot modify the predecessors inside the above loop as it will cause
833 // the iterators to be nullptrs, causing memory errors.
834 for (Instruction *CurrentBranch : WorkList) {
835 BasicBlock *Succ = CurrentBranch->getSuccessor(0);
836 if (Succ == BB)
837 Succ = CurrentBranch->getSuccessor(1);
838 ReplaceInstWithInst(CurrentBranch, BranchInst::Create(Succ));
839 }
840
841 DTU.applyUpdates(TreeUpdates);
842 DTU.flush();
843 }
844 LLVM_DEBUG(
845 dbgs() << "Sucessfully peeled " << FC0.PP.PeelCount
846 << " iterations from the first loop.\n"
847 "Both Loops have the same number of iterations now.\n");
848 }
849 }
850
851 /// Walk each set of control flow equivalent fusion candidates and attempt to
852 /// fuse them. This does a single linear traversal of all candidates in the
853 /// set. The conditions for legal fusion are checked at this point. If a pair
854 /// of fusion candidates passes all legality checks, they are fused together
855 /// and a new fusion candidate is created and added to the FusionCandidateSet.
856 /// The original fusion candidates are then removed, as they are no longer
857 /// valid.
fuseCandidates__anond06fd9000111::LoopFuser858 bool fuseCandidates() {
859 bool Fused = false;
860 LLVM_DEBUG(printFusionCandidates(FusionCandidates));
861 for (auto &CandidateSet : FusionCandidates) {
862 if (CandidateSet.size() < 2)
863 continue;
864
865 LLVM_DEBUG(dbgs() << "Attempting fusion on Candidate Set:\n"
866 << CandidateSet << "\n");
867
868 for (auto FC0 = CandidateSet.begin(); FC0 != CandidateSet.end(); ++FC0) {
869 assert(!LDT.isRemovedLoop(FC0->L) &&
870 "Should not have removed loops in CandidateSet!");
871 auto FC1 = FC0;
872 for (++FC1; FC1 != CandidateSet.end(); ++FC1) {
873 assert(!LDT.isRemovedLoop(FC1->L) &&
874 "Should not have removed loops in CandidateSet!");
875
876 LLVM_DEBUG(dbgs() << "Attempting to fuse candidate \n"; FC0->dump();
877 dbgs() << " with\n"; FC1->dump(); dbgs() << "\n");
878
879 FC0->verify();
880 FC1->verify();
881
882 // Check if the candidates have identical tripcounts (first value of
883 // pair), and if not check the difference in the tripcounts between
884 // the loops (second value of pair). The difference is not equal to
885 // std::nullopt iff the loops iterate a constant number of times, and
886 // have a single exit.
887 std::pair<bool, std::optional<unsigned>> IdenticalTripCountRes =
888 haveIdenticalTripCounts(*FC0, *FC1);
889 bool SameTripCount = IdenticalTripCountRes.first;
890 std::optional<unsigned> TCDifference = IdenticalTripCountRes.second;
891
892 // Here we are checking that FC0 (the first loop) can be peeled, and
893 // both loops have different tripcounts.
894 if (FC0->AbleToPeel && !SameTripCount && TCDifference) {
895 if (*TCDifference > FusionPeelMaxCount) {
896 LLVM_DEBUG(dbgs()
897 << "Difference in loop trip counts: " << *TCDifference
898 << " is greater than maximum peel count specificed: "
899 << FusionPeelMaxCount << "\n");
900 } else {
901 // Dependent on peeling being performed on the first loop, and
902 // assuming all other conditions for fusion return true.
903 SameTripCount = true;
904 }
905 }
906
907 if (!SameTripCount) {
908 LLVM_DEBUG(dbgs() << "Fusion candidates do not have identical trip "
909 "counts. Not fusing.\n");
910 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
911 NonEqualTripCount);
912 continue;
913 }
914
915 if (!isAdjacent(*FC0, *FC1)) {
916 LLVM_DEBUG(dbgs()
917 << "Fusion candidates are not adjacent. Not fusing.\n");
918 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1, NonAdjacent);
919 continue;
920 }
921
922 if ((!FC0->GuardBranch && FC1->GuardBranch) ||
923 (FC0->GuardBranch && !FC1->GuardBranch)) {
924 LLVM_DEBUG(dbgs() << "The one of candidate is guarded while the "
925 "another one is not. Not fusing.\n");
926 reportLoopFusion<OptimizationRemarkMissed>(
927 *FC0, *FC1, OnlySecondCandidateIsGuarded);
928 continue;
929 }
930
931 // Ensure that FC0 and FC1 have identical guards.
932 // If one (or both) are not guarded, this check is not necessary.
933 if (FC0->GuardBranch && FC1->GuardBranch &&
934 !haveIdenticalGuards(*FC0, *FC1) && !TCDifference) {
935 LLVM_DEBUG(dbgs() << "Fusion candidates do not have identical "
936 "guards. Not Fusing.\n");
937 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
938 NonIdenticalGuards);
939 continue;
940 }
941
942 if (FC0->GuardBranch) {
943 assert(FC1->GuardBranch && "Expecting valid FC1 guard branch");
944
945 if (!isSafeToMoveBefore(*FC0->ExitBlock,
946 *FC1->ExitBlock->getFirstNonPHIOrDbg(), DT,
947 &PDT, &DI)) {
948 LLVM_DEBUG(dbgs() << "Fusion candidate contains unsafe "
949 "instructions in exit block. Not fusing.\n");
950 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
951 NonEmptyExitBlock);
952 continue;
953 }
954
955 if (!isSafeToMoveBefore(
956 *FC1->GuardBranch->getParent(),
957 *FC0->GuardBranch->getParent()->getTerminator(), DT, &PDT,
958 &DI)) {
959 LLVM_DEBUG(dbgs()
960 << "Fusion candidate contains unsafe "
961 "instructions in guard block. Not fusing.\n");
962 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
963 NonEmptyGuardBlock);
964 continue;
965 }
966 }
967
968 // Check the dependencies across the loops and do not fuse if it would
969 // violate them.
970 if (!dependencesAllowFusion(*FC0, *FC1)) {
971 LLVM_DEBUG(dbgs() << "Memory dependencies do not allow fusion!\n");
972 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
973 InvalidDependencies);
974 continue;
975 }
976
977 // If the second loop has instructions in the pre-header, attempt to
978 // hoist them up to the first loop's pre-header or sink them into the
979 // body of the second loop.
980 SmallVector<Instruction *, 4> SafeToHoist;
981 SmallVector<Instruction *, 4> SafeToSink;
982 // At this point, this is the last remaining legality check.
983 // Which means if we can make this pre-header empty, we can fuse
984 // these loops
985 if (!isEmptyPreheader(*FC1)) {
986 LLVM_DEBUG(dbgs() << "Fusion candidate does not have empty "
987 "preheader.\n");
988
989 // If it is not safe to hoist/sink all instructions in the
990 // pre-header, we cannot fuse these loops.
991 if (!collectMovablePreheaderInsts(*FC0, *FC1, SafeToHoist,
992 SafeToSink)) {
993 LLVM_DEBUG(dbgs() << "Could not hoist/sink all instructions in "
994 "Fusion Candidate Pre-header.\n"
995 << "Not Fusing.\n");
996 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
997 NonEmptyPreheader);
998 continue;
999 }
1000 }
1001
1002 bool BeneficialToFuse = isBeneficialFusion(*FC0, *FC1);
1003 LLVM_DEBUG(dbgs()
1004 << "\tFusion appears to be "
1005 << (BeneficialToFuse ? "" : "un") << "profitable!\n");
1006 if (!BeneficialToFuse) {
1007 reportLoopFusion<OptimizationRemarkMissed>(*FC0, *FC1,
1008 FusionNotBeneficial);
1009 continue;
1010 }
1011 // All analysis has completed and has determined that fusion is legal
1012 // and profitable. At this point, start transforming the code and
1013 // perform fusion.
1014
1015 // Execute the hoist/sink operations on preheader instructions
1016 movePreheaderInsts(*FC0, *FC1, SafeToHoist, SafeToSink);
1017
1018 LLVM_DEBUG(dbgs() << "\tFusion is performed: " << *FC0 << " and "
1019 << *FC1 << "\n");
1020
1021 FusionCandidate FC0Copy = *FC0;
1022 // Peel the loop after determining that fusion is legal. The Loops
1023 // will still be safe to fuse after the peeling is performed.
1024 bool Peel = TCDifference && *TCDifference > 0;
1025 if (Peel)
1026 peelFusionCandidate(FC0Copy, *FC1, *TCDifference);
1027
1028 // Report fusion to the Optimization Remarks.
1029 // Note this needs to be done *before* performFusion because
1030 // performFusion will change the original loops, making it not
1031 // possible to identify them after fusion is complete.
1032 reportLoopFusion<OptimizationRemark>((Peel ? FC0Copy : *FC0), *FC1,
1033 FuseCounter);
1034
1035 FusionCandidate FusedCand(
1036 performFusion((Peel ? FC0Copy : *FC0), *FC1), DT, &PDT, ORE,
1037 FC0Copy.PP);
1038 FusedCand.verify();
1039 assert(FusedCand.isEligibleForFusion(SE) &&
1040 "Fused candidate should be eligible for fusion!");
1041
1042 // Notify the loop-depth-tree that these loops are not valid objects
1043 LDT.removeLoop(FC1->L);
1044
1045 CandidateSet.erase(FC0);
1046 CandidateSet.erase(FC1);
1047
1048 auto InsertPos = CandidateSet.insert(FusedCand);
1049
1050 assert(InsertPos.second &&
1051 "Unable to insert TargetCandidate in CandidateSet!");
1052
1053 // Reset FC0 and FC1 the new (fused) candidate. Subsequent iterations
1054 // of the FC1 loop will attempt to fuse the new (fused) loop with the
1055 // remaining candidates in the current candidate set.
1056 FC0 = FC1 = InsertPos.first;
1057
1058 LLVM_DEBUG(dbgs() << "Candidate Set (after fusion): " << CandidateSet
1059 << "\n");
1060
1061 Fused = true;
1062 }
1063 }
1064 }
1065 return Fused;
1066 }
1067
1068 // Returns true if the instruction \p I can be hoisted to the end of the
1069 // preheader of \p FC0. \p SafeToHoist contains the instructions that are
1070 // known to be safe to hoist. The instructions encountered that cannot be
1071 // hoisted are in \p NotHoisting.
1072 // TODO: Move functionality into CodeMoverUtils
canHoistInst__anond06fd9000111::LoopFuser1073 bool canHoistInst(Instruction &I,
1074 const SmallVector<Instruction *, 4> &SafeToHoist,
1075 const SmallVector<Instruction *, 4> &NotHoisting,
1076 const FusionCandidate &FC0) const {
1077 const BasicBlock *FC0PreheaderTarget = FC0.Preheader->getSingleSuccessor();
1078 assert(FC0PreheaderTarget &&
1079 "Expected single successor for loop preheader.");
1080
1081 for (Use &Op : I.operands()) {
1082 if (auto *OpInst = dyn_cast<Instruction>(Op)) {
1083 bool OpHoisted = is_contained(SafeToHoist, OpInst);
1084 // Check if we have already decided to hoist this operand. In this
1085 // case, it does not dominate FC0 *yet*, but will after we hoist it.
1086 if (!(OpHoisted || DT.dominates(OpInst, FC0PreheaderTarget))) {
1087 return false;
1088 }
1089 }
1090 }
1091
1092 // PHIs in FC1's header only have FC0 blocks as predecessors. PHIs
1093 // cannot be hoisted and should be sunk to the exit of the fused loop.
1094 if (isa<PHINode>(I))
1095 return false;
1096
1097 // If this isn't a memory inst, hoisting is safe
1098 if (!I.mayReadOrWriteMemory())
1099 return true;
1100
1101 LLVM_DEBUG(dbgs() << "Checking if this mem inst can be hoisted.\n");
1102 for (Instruction *NotHoistedInst : NotHoisting) {
1103 if (auto D = DI.depends(&I, NotHoistedInst, true)) {
1104 // Dependency is not read-before-write, write-before-read or
1105 // write-before-write
1106 if (D->isFlow() || D->isAnti() || D->isOutput()) {
1107 LLVM_DEBUG(dbgs() << "Inst depends on an instruction in FC1's "
1108 "preheader that is not being hoisted.\n");
1109 return false;
1110 }
1111 }
1112 }
1113
1114 for (Instruction *ReadInst : FC0.MemReads) {
1115 if (auto D = DI.depends(ReadInst, &I, true)) {
1116 // Dependency is not read-before-write
1117 if (D->isAnti()) {
1118 LLVM_DEBUG(dbgs() << "Inst depends on a read instruction in FC0.\n");
1119 return false;
1120 }
1121 }
1122 }
1123
1124 for (Instruction *WriteInst : FC0.MemWrites) {
1125 if (auto D = DI.depends(WriteInst, &I, true)) {
1126 // Dependency is not write-before-read or write-before-write
1127 if (D->isFlow() || D->isOutput()) {
1128 LLVM_DEBUG(dbgs() << "Inst depends on a write instruction in FC0.\n");
1129 return false;
1130 }
1131 }
1132 }
1133 return true;
1134 }
1135
1136 // Returns true if the instruction \p I can be sunk to the top of the exit
1137 // block of \p FC1.
1138 // TODO: Move functionality into CodeMoverUtils
canSinkInst__anond06fd9000111::LoopFuser1139 bool canSinkInst(Instruction &I, const FusionCandidate &FC1) const {
1140 for (User *U : I.users()) {
1141 if (auto *UI{dyn_cast<Instruction>(U)}) {
1142 // Cannot sink if user in loop
1143 // If FC1 has phi users of this value, we cannot sink it into FC1.
1144 if (FC1.L->contains(UI)) {
1145 // Cannot hoist or sink this instruction. No hoisting/sinking
1146 // should take place, loops should not fuse
1147 return false;
1148 }
1149 }
1150 }
1151
1152 // If this isn't a memory inst, sinking is safe
1153 if (!I.mayReadOrWriteMemory())
1154 return true;
1155
1156 for (Instruction *ReadInst : FC1.MemReads) {
1157 if (auto D = DI.depends(&I, ReadInst, true)) {
1158 // Dependency is not write-before-read
1159 if (D->isFlow()) {
1160 LLVM_DEBUG(dbgs() << "Inst depends on a read instruction in FC1.\n");
1161 return false;
1162 }
1163 }
1164 }
1165
1166 for (Instruction *WriteInst : FC1.MemWrites) {
1167 if (auto D = DI.depends(&I, WriteInst, true)) {
1168 // Dependency is not write-before-write or read-before-write
1169 if (D->isOutput() || D->isAnti()) {
1170 LLVM_DEBUG(dbgs() << "Inst depends on a write instruction in FC1.\n");
1171 return false;
1172 }
1173 }
1174 }
1175
1176 return true;
1177 }
1178
1179 /// Collect instructions in the \p FC1 Preheader that can be hoisted
1180 /// to the \p FC0 Preheader or sunk into the \p FC1 Body
collectMovablePreheaderInsts__anond06fd9000111::LoopFuser1181 bool collectMovablePreheaderInsts(
1182 const FusionCandidate &FC0, const FusionCandidate &FC1,
1183 SmallVector<Instruction *, 4> &SafeToHoist,
1184 SmallVector<Instruction *, 4> &SafeToSink) const {
1185 BasicBlock *FC1Preheader = FC1.Preheader;
1186 // Save the instructions that are not being hoisted, so we know not to hoist
1187 // mem insts that they dominate.
1188 SmallVector<Instruction *, 4> NotHoisting;
1189
1190 for (Instruction &I : *FC1Preheader) {
1191 // Can't move a branch
1192 if (&I == FC1Preheader->getTerminator())
1193 continue;
1194 // If the instruction has side-effects, give up.
1195 // TODO: The case of mayReadFromMemory we can handle but requires
1196 // additional work with a dependence analysis so for now we give
1197 // up on memory reads.
1198 if (I.mayThrow() || !I.willReturn()) {
1199 LLVM_DEBUG(dbgs() << "Inst: " << I << " may throw or won't return.\n");
1200 return false;
1201 }
1202
1203 LLVM_DEBUG(dbgs() << "Checking Inst: " << I << "\n");
1204
1205 if (I.isAtomic() || I.isVolatile()) {
1206 LLVM_DEBUG(
1207 dbgs() << "\tInstruction is volatile or atomic. Cannot move it.\n");
1208 return false;
1209 }
1210
1211 if (canHoistInst(I, SafeToHoist, NotHoisting, FC0)) {
1212 SafeToHoist.push_back(&I);
1213 LLVM_DEBUG(dbgs() << "\tSafe to hoist.\n");
1214 } else {
1215 LLVM_DEBUG(dbgs() << "\tCould not hoist. Trying to sink...\n");
1216 NotHoisting.push_back(&I);
1217
1218 if (canSinkInst(I, FC1)) {
1219 SafeToSink.push_back(&I);
1220 LLVM_DEBUG(dbgs() << "\tSafe to sink.\n");
1221 } else {
1222 LLVM_DEBUG(dbgs() << "\tCould not sink.\n");
1223 return false;
1224 }
1225 }
1226 }
1227 LLVM_DEBUG(
1228 dbgs() << "All preheader instructions could be sunk or hoisted!\n");
1229 return true;
1230 }
1231
1232 /// Rewrite all additive recurrences in a SCEV to use a new loop.
1233 class AddRecLoopReplacer : public SCEVRewriteVisitor<AddRecLoopReplacer> {
1234 public:
AddRecLoopReplacer(ScalarEvolution & SE,const Loop & OldL,const Loop & NewL,bool UseMax=true)1235 AddRecLoopReplacer(ScalarEvolution &SE, const Loop &OldL, const Loop &NewL,
1236 bool UseMax = true)
1237 : SCEVRewriteVisitor(SE), Valid(true), UseMax(UseMax), OldL(OldL),
1238 NewL(NewL) {}
1239
visitAddRecExpr(const SCEVAddRecExpr * Expr)1240 const SCEV *visitAddRecExpr(const SCEVAddRecExpr *Expr) {
1241 const Loop *ExprL = Expr->getLoop();
1242 SmallVector<const SCEV *, 2> Operands;
1243 if (ExprL == &OldL) {
1244 append_range(Operands, Expr->operands());
1245 return SE.getAddRecExpr(Operands, &NewL, Expr->getNoWrapFlags());
1246 }
1247
1248 if (OldL.contains(ExprL)) {
1249 bool Pos = SE.isKnownPositive(Expr->getStepRecurrence(SE));
1250 if (!UseMax || !Pos || !Expr->isAffine()) {
1251 Valid = false;
1252 return Expr;
1253 }
1254 return visit(Expr->getStart());
1255 }
1256
1257 for (const SCEV *Op : Expr->operands())
1258 Operands.push_back(visit(Op));
1259 return SE.getAddRecExpr(Operands, ExprL, Expr->getNoWrapFlags());
1260 }
1261
wasValidSCEV() const1262 bool wasValidSCEV() const { return Valid; }
1263
1264 private:
1265 bool Valid, UseMax;
1266 const Loop &OldL, &NewL;
1267 };
1268
1269 /// Return false if the access functions of \p I0 and \p I1 could cause
1270 /// a negative dependence.
accessDiffIsPositive__anond06fd9000111::LoopFuser1271 bool accessDiffIsPositive(const Loop &L0, const Loop &L1, Instruction &I0,
1272 Instruction &I1, bool EqualIsInvalid) {
1273 Value *Ptr0 = getLoadStorePointerOperand(&I0);
1274 Value *Ptr1 = getLoadStorePointerOperand(&I1);
1275 if (!Ptr0 || !Ptr1)
1276 return false;
1277
1278 const SCEV *SCEVPtr0 = SE.getSCEVAtScope(Ptr0, &L0);
1279 const SCEV *SCEVPtr1 = SE.getSCEVAtScope(Ptr1, &L1);
1280 #ifndef NDEBUG
1281 if (VerboseFusionDebugging)
1282 LLVM_DEBUG(dbgs() << " Access function check: " << *SCEVPtr0 << " vs "
1283 << *SCEVPtr1 << "\n");
1284 #endif
1285 AddRecLoopReplacer Rewriter(SE, L0, L1);
1286 SCEVPtr0 = Rewriter.visit(SCEVPtr0);
1287 #ifndef NDEBUG
1288 if (VerboseFusionDebugging)
1289 LLVM_DEBUG(dbgs() << " Access function after rewrite: " << *SCEVPtr0
1290 << " [Valid: " << Rewriter.wasValidSCEV() << "]\n");
1291 #endif
1292 if (!Rewriter.wasValidSCEV())
1293 return false;
1294
1295 // TODO: isKnownPredicate doesnt work well when one SCEV is loop carried (by
1296 // L0) and the other is not. We could check if it is monotone and test
1297 // the beginning and end value instead.
1298
1299 BasicBlock *L0Header = L0.getHeader();
1300 auto HasNonLinearDominanceRelation = [&](const SCEV *S) {
1301 const SCEVAddRecExpr *AddRec = dyn_cast<SCEVAddRecExpr>(S);
1302 if (!AddRec)
1303 return false;
1304 return !DT.dominates(L0Header, AddRec->getLoop()->getHeader()) &&
1305 !DT.dominates(AddRec->getLoop()->getHeader(), L0Header);
1306 };
1307 if (SCEVExprContains(SCEVPtr1, HasNonLinearDominanceRelation))
1308 return false;
1309
1310 ICmpInst::Predicate Pred =
1311 EqualIsInvalid ? ICmpInst::ICMP_SGT : ICmpInst::ICMP_SGE;
1312 bool IsAlwaysGE = SE.isKnownPredicate(Pred, SCEVPtr0, SCEVPtr1);
1313 #ifndef NDEBUG
1314 if (VerboseFusionDebugging)
1315 LLVM_DEBUG(dbgs() << " Relation: " << *SCEVPtr0
1316 << (IsAlwaysGE ? " >= " : " may < ") << *SCEVPtr1
1317 << "\n");
1318 #endif
1319 return IsAlwaysGE;
1320 }
1321
1322 /// Return true if the dependences between @p I0 (in @p L0) and @p I1 (in
1323 /// @p L1) allow loop fusion of @p L0 and @p L1. The dependence analyses
1324 /// specified by @p DepChoice are used to determine this.
dependencesAllowFusion__anond06fd9000111::LoopFuser1325 bool dependencesAllowFusion(const FusionCandidate &FC0,
1326 const FusionCandidate &FC1, Instruction &I0,
1327 Instruction &I1, bool AnyDep,
1328 FusionDependenceAnalysisChoice DepChoice) {
1329 #ifndef NDEBUG
1330 if (VerboseFusionDebugging) {
1331 LLVM_DEBUG(dbgs() << "Check dep: " << I0 << " vs " << I1 << " : "
1332 << DepChoice << "\n");
1333 }
1334 #endif
1335 switch (DepChoice) {
1336 case FUSION_DEPENDENCE_ANALYSIS_SCEV:
1337 return accessDiffIsPositive(*FC0.L, *FC1.L, I0, I1, AnyDep);
1338 case FUSION_DEPENDENCE_ANALYSIS_DA: {
1339 auto DepResult = DI.depends(&I0, &I1, true);
1340 if (!DepResult)
1341 return true;
1342 #ifndef NDEBUG
1343 if (VerboseFusionDebugging) {
1344 LLVM_DEBUG(dbgs() << "DA res: "; DepResult->dump(dbgs());
1345 dbgs() << " [#l: " << DepResult->getLevels() << "][Ordered: "
1346 << (DepResult->isOrdered() ? "true" : "false")
1347 << "]\n");
1348 LLVM_DEBUG(dbgs() << "DepResult Levels: " << DepResult->getLevels()
1349 << "\n");
1350 }
1351 #endif
1352
1353 if (DepResult->getNextPredecessor() || DepResult->getNextSuccessor())
1354 LLVM_DEBUG(
1355 dbgs() << "TODO: Implement pred/succ dependence handling!\n");
1356
1357 // TODO: Can we actually use the dependence info analysis here?
1358 return false;
1359 }
1360
1361 case FUSION_DEPENDENCE_ANALYSIS_ALL:
1362 return dependencesAllowFusion(FC0, FC1, I0, I1, AnyDep,
1363 FUSION_DEPENDENCE_ANALYSIS_SCEV) ||
1364 dependencesAllowFusion(FC0, FC1, I0, I1, AnyDep,
1365 FUSION_DEPENDENCE_ANALYSIS_DA);
1366 }
1367
1368 llvm_unreachable("Unknown fusion dependence analysis choice!");
1369 }
1370
1371 /// Perform a dependence check and return if @p FC0 and @p FC1 can be fused.
dependencesAllowFusion__anond06fd9000111::LoopFuser1372 bool dependencesAllowFusion(const FusionCandidate &FC0,
1373 const FusionCandidate &FC1) {
1374 LLVM_DEBUG(dbgs() << "Check if " << FC0 << " can be fused with " << FC1
1375 << "\n");
1376 assert(FC0.L->getLoopDepth() == FC1.L->getLoopDepth());
1377 assert(DT.dominates(FC0.getEntryBlock(), FC1.getEntryBlock()));
1378
1379 for (Instruction *WriteL0 : FC0.MemWrites) {
1380 for (Instruction *WriteL1 : FC1.MemWrites)
1381 if (!dependencesAllowFusion(FC0, FC1, *WriteL0, *WriteL1,
1382 /* AnyDep */ false,
1383 FusionDependenceAnalysis)) {
1384 InvalidDependencies++;
1385 return false;
1386 }
1387 for (Instruction *ReadL1 : FC1.MemReads)
1388 if (!dependencesAllowFusion(FC0, FC1, *WriteL0, *ReadL1,
1389 /* AnyDep */ false,
1390 FusionDependenceAnalysis)) {
1391 InvalidDependencies++;
1392 return false;
1393 }
1394 }
1395
1396 for (Instruction *WriteL1 : FC1.MemWrites) {
1397 for (Instruction *WriteL0 : FC0.MemWrites)
1398 if (!dependencesAllowFusion(FC0, FC1, *WriteL0, *WriteL1,
1399 /* AnyDep */ false,
1400 FusionDependenceAnalysis)) {
1401 InvalidDependencies++;
1402 return false;
1403 }
1404 for (Instruction *ReadL0 : FC0.MemReads)
1405 if (!dependencesAllowFusion(FC0, FC1, *ReadL0, *WriteL1,
1406 /* AnyDep */ false,
1407 FusionDependenceAnalysis)) {
1408 InvalidDependencies++;
1409 return false;
1410 }
1411 }
1412
1413 // Walk through all uses in FC1. For each use, find the reaching def. If the
1414 // def is located in FC0 then it is not safe to fuse.
1415 for (BasicBlock *BB : FC1.L->blocks())
1416 for (Instruction &I : *BB)
1417 for (auto &Op : I.operands())
1418 if (Instruction *Def = dyn_cast<Instruction>(Op))
1419 if (FC0.L->contains(Def->getParent())) {
1420 InvalidDependencies++;
1421 return false;
1422 }
1423
1424 return true;
1425 }
1426
1427 /// Determine if two fusion candidates are adjacent in the CFG.
1428 ///
1429 /// This method will determine if there are additional basic blocks in the CFG
1430 /// between the exit of \p FC0 and the entry of \p FC1.
1431 /// If the two candidates are guarded loops, then it checks whether the
1432 /// non-loop successor of the \p FC0 guard branch is the entry block of \p
1433 /// FC1. If not, then the loops are not adjacent. If the two candidates are
1434 /// not guarded loops, then it checks whether the exit block of \p FC0 is the
1435 /// preheader of \p FC1.
isAdjacent__anond06fd9000111::LoopFuser1436 bool isAdjacent(const FusionCandidate &FC0,
1437 const FusionCandidate &FC1) const {
1438 // If the successor of the guard branch is FC1, then the loops are adjacent
1439 if (FC0.GuardBranch)
1440 return FC0.getNonLoopBlock() == FC1.getEntryBlock();
1441 else
1442 return FC0.ExitBlock == FC1.getEntryBlock();
1443 }
1444
isEmptyPreheader__anond06fd9000111::LoopFuser1445 bool isEmptyPreheader(const FusionCandidate &FC) const {
1446 return FC.Preheader->size() == 1;
1447 }
1448
1449 /// Hoist \p FC1 Preheader instructions to \p FC0 Preheader
1450 /// and sink others into the body of \p FC1.
movePreheaderInsts__anond06fd9000111::LoopFuser1451 void movePreheaderInsts(const FusionCandidate &FC0,
1452 const FusionCandidate &FC1,
1453 SmallVector<Instruction *, 4> &HoistInsts,
1454 SmallVector<Instruction *, 4> &SinkInsts) const {
1455 // All preheader instructions except the branch must be hoisted or sunk
1456 assert(HoistInsts.size() + SinkInsts.size() == FC1.Preheader->size() - 1 &&
1457 "Attempting to sink and hoist preheader instructions, but not all "
1458 "the preheader instructions are accounted for.");
1459
1460 NumHoistedInsts += HoistInsts.size();
1461 NumSunkInsts += SinkInsts.size();
1462
1463 LLVM_DEBUG(if (VerboseFusionDebugging) {
1464 if (!HoistInsts.empty())
1465 dbgs() << "Hoisting: \n";
1466 for (Instruction *I : HoistInsts)
1467 dbgs() << *I << "\n";
1468 if (!SinkInsts.empty())
1469 dbgs() << "Sinking: \n";
1470 for (Instruction *I : SinkInsts)
1471 dbgs() << *I << "\n";
1472 });
1473
1474 for (Instruction *I : HoistInsts) {
1475 assert(I->getParent() == FC1.Preheader);
1476 I->moveBefore(*FC0.Preheader,
1477 FC0.Preheader->getTerminator()->getIterator());
1478 }
1479 // insert instructions in reverse order to maintain dominance relationship
1480 for (Instruction *I : reverse(SinkInsts)) {
1481 assert(I->getParent() == FC1.Preheader);
1482 I->moveBefore(*FC1.ExitBlock, FC1.ExitBlock->getFirstInsertionPt());
1483 }
1484 }
1485
1486 /// Determine if two fusion candidates have identical guards
1487 ///
1488 /// This method will determine if two fusion candidates have the same guards.
1489 /// The guards are considered the same if:
1490 /// 1. The instructions to compute the condition used in the compare are
1491 /// identical.
1492 /// 2. The successors of the guard have the same flow into/around the loop.
1493 /// If the compare instructions are identical, then the first successor of the
1494 /// guard must go to the same place (either the preheader of the loop or the
1495 /// NonLoopBlock). In other words, the first successor of both loops must
1496 /// both go into the loop (i.e., the preheader) or go around the loop (i.e.,
1497 /// the NonLoopBlock). The same must be true for the second successor.
haveIdenticalGuards__anond06fd9000111::LoopFuser1498 bool haveIdenticalGuards(const FusionCandidate &FC0,
1499 const FusionCandidate &FC1) const {
1500 assert(FC0.GuardBranch && FC1.GuardBranch &&
1501 "Expecting FC0 and FC1 to be guarded loops.");
1502
1503 if (auto FC0CmpInst =
1504 dyn_cast<Instruction>(FC0.GuardBranch->getCondition()))
1505 if (auto FC1CmpInst =
1506 dyn_cast<Instruction>(FC1.GuardBranch->getCondition()))
1507 if (!FC0CmpInst->isIdenticalTo(FC1CmpInst))
1508 return false;
1509
1510 // The compare instructions are identical.
1511 // Now make sure the successor of the guards have the same flow into/around
1512 // the loop
1513 if (FC0.GuardBranch->getSuccessor(0) == FC0.Preheader)
1514 return (FC1.GuardBranch->getSuccessor(0) == FC1.Preheader);
1515 else
1516 return (FC1.GuardBranch->getSuccessor(1) == FC1.Preheader);
1517 }
1518
1519 /// Modify the latch branch of FC to be unconditional since successors of the
1520 /// branch are the same.
simplifyLatchBranch__anond06fd9000111::LoopFuser1521 void simplifyLatchBranch(const FusionCandidate &FC) const {
1522 BranchInst *FCLatchBranch = dyn_cast<BranchInst>(FC.Latch->getTerminator());
1523 if (FCLatchBranch) {
1524 assert(FCLatchBranch->isConditional() &&
1525 FCLatchBranch->getSuccessor(0) == FCLatchBranch->getSuccessor(1) &&
1526 "Expecting the two successors of FCLatchBranch to be the same");
1527 BranchInst *NewBranch =
1528 BranchInst::Create(FCLatchBranch->getSuccessor(0));
1529 ReplaceInstWithInst(FCLatchBranch, NewBranch);
1530 }
1531 }
1532
1533 /// Move instructions from FC0.Latch to FC1.Latch. If FC0.Latch has an unique
1534 /// successor, then merge FC0.Latch with its unique successor.
mergeLatch__anond06fd9000111::LoopFuser1535 void mergeLatch(const FusionCandidate &FC0, const FusionCandidate &FC1) {
1536 moveInstructionsToTheBeginning(*FC0.Latch, *FC1.Latch, DT, PDT, DI);
1537 if (BasicBlock *Succ = FC0.Latch->getUniqueSuccessor()) {
1538 MergeBlockIntoPredecessor(Succ, &DTU, &LI);
1539 DTU.flush();
1540 }
1541 }
1542
1543 /// Fuse two fusion candidates, creating a new fused loop.
1544 ///
1545 /// This method contains the mechanics of fusing two loops, represented by \p
1546 /// FC0 and \p FC1. It is assumed that \p FC0 dominates \p FC1 and \p FC1
1547 /// postdominates \p FC0 (making them control flow equivalent). It also
1548 /// assumes that the other conditions for fusion have been met: adjacent,
1549 /// identical trip counts, and no negative distance dependencies exist that
1550 /// would prevent fusion. Thus, there is no checking for these conditions in
1551 /// this method.
1552 ///
1553 /// Fusion is performed by rewiring the CFG to update successor blocks of the
1554 /// components of tho loop. Specifically, the following changes are done:
1555 ///
1556 /// 1. The preheader of \p FC1 is removed as it is no longer necessary
1557 /// (because it is currently only a single statement block).
1558 /// 2. The latch of \p FC0 is modified to jump to the header of \p FC1.
1559 /// 3. The latch of \p FC1 i modified to jump to the header of \p FC0.
1560 /// 4. All blocks from \p FC1 are removed from FC1 and added to FC0.
1561 ///
1562 /// All of these modifications are done with dominator tree updates, thus
1563 /// keeping the dominator (and post dominator) information up-to-date.
1564 ///
1565 /// This can be improved in the future by actually merging blocks during
1566 /// fusion. For example, the preheader of \p FC1 can be merged with the
1567 /// preheader of \p FC0. This would allow loops with more than a single
1568 /// statement in the preheader to be fused. Similarly, the latch blocks of the
1569 /// two loops could also be fused into a single block. This will require
1570 /// analysis to prove it is safe to move the contents of the block past
1571 /// existing code, which currently has not been implemented.
performFusion__anond06fd9000111::LoopFuser1572 Loop *performFusion(const FusionCandidate &FC0, const FusionCandidate &FC1) {
1573 assert(FC0.isValid() && FC1.isValid() &&
1574 "Expecting valid fusion candidates");
1575
1576 LLVM_DEBUG(dbgs() << "Fusion Candidate 0: \n"; FC0.dump();
1577 dbgs() << "Fusion Candidate 1: \n"; FC1.dump(););
1578
1579 // Move instructions from the preheader of FC1 to the end of the preheader
1580 // of FC0.
1581 moveInstructionsToTheEnd(*FC1.Preheader, *FC0.Preheader, DT, PDT, DI);
1582
1583 // Fusing guarded loops is handled slightly differently than non-guarded
1584 // loops and has been broken out into a separate method instead of trying to
1585 // intersperse the logic within a single method.
1586 if (FC0.GuardBranch)
1587 return fuseGuardedLoops(FC0, FC1);
1588
1589 assert(FC1.Preheader ==
1590 (FC0.Peeled ? FC0.ExitBlock->getUniqueSuccessor() : FC0.ExitBlock));
1591 assert(FC1.Preheader->size() == 1 &&
1592 FC1.Preheader->getSingleSuccessor() == FC1.Header);
1593
1594 // Remember the phi nodes originally in the header of FC0 in order to rewire
1595 // them later. However, this is only necessary if the new loop carried
1596 // values might not dominate the exiting branch. While we do not generally
1597 // test if this is the case but simply insert intermediate phi nodes, we
1598 // need to make sure these intermediate phi nodes have different
1599 // predecessors. To this end, we filter the special case where the exiting
1600 // block is the latch block of the first loop. Nothing needs to be done
1601 // anyway as all loop carried values dominate the latch and thereby also the
1602 // exiting branch.
1603 SmallVector<PHINode *, 8> OriginalFC0PHIs;
1604 if (FC0.ExitingBlock != FC0.Latch)
1605 for (PHINode &PHI : FC0.Header->phis())
1606 OriginalFC0PHIs.push_back(&PHI);
1607
1608 // Replace incoming blocks for header PHIs first.
1609 FC1.Preheader->replaceSuccessorsPhiUsesWith(FC0.Preheader);
1610 FC0.Latch->replaceSuccessorsPhiUsesWith(FC1.Latch);
1611
1612 // Then modify the control flow and update DT and PDT.
1613 SmallVector<DominatorTree::UpdateType, 8> TreeUpdates;
1614
1615 // The old exiting block of the first loop (FC0) has to jump to the header
1616 // of the second as we need to execute the code in the second header block
1617 // regardless of the trip count. That is, if the trip count is 0, so the
1618 // back edge is never taken, we still have to execute both loop headers,
1619 // especially (but not only!) if the second is a do-while style loop.
1620 // However, doing so might invalidate the phi nodes of the first loop as
1621 // the new values do only need to dominate their latch and not the exiting
1622 // predicate. To remedy this potential problem we always introduce phi
1623 // nodes in the header of the second loop later that select the loop carried
1624 // value, if the second header was reached through an old latch of the
1625 // first, or undef otherwise. This is sound as exiting the first implies the
1626 // second will exit too, __without__ taking the back-edge. [Their
1627 // trip-counts are equal after all.
1628 // KB: Would this sequence be simpler to just make FC0.ExitingBlock go
1629 // to FC1.Header? I think this is basically what the three sequences are
1630 // trying to accomplish; however, doing this directly in the CFG may mean
1631 // the DT/PDT becomes invalid
1632 if (!FC0.Peeled) {
1633 FC0.ExitingBlock->getTerminator()->replaceUsesOfWith(FC1.Preheader,
1634 FC1.Header);
1635 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1636 DominatorTree::Delete, FC0.ExitingBlock, FC1.Preheader));
1637 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1638 DominatorTree::Insert, FC0.ExitingBlock, FC1.Header));
1639 } else {
1640 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1641 DominatorTree::Delete, FC0.ExitBlock, FC1.Preheader));
1642
1643 // Remove the ExitBlock of the first Loop (also not needed)
1644 FC0.ExitingBlock->getTerminator()->replaceUsesOfWith(FC0.ExitBlock,
1645 FC1.Header);
1646 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1647 DominatorTree::Delete, FC0.ExitingBlock, FC0.ExitBlock));
1648 FC0.ExitBlock->getTerminator()->eraseFromParent();
1649 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1650 DominatorTree::Insert, FC0.ExitingBlock, FC1.Header));
1651 new UnreachableInst(FC0.ExitBlock->getContext(), FC0.ExitBlock);
1652 }
1653
1654 // The pre-header of L1 is not necessary anymore.
1655 assert(pred_empty(FC1.Preheader));
1656 FC1.Preheader->getTerminator()->eraseFromParent();
1657 new UnreachableInst(FC1.Preheader->getContext(), FC1.Preheader);
1658 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1659 DominatorTree::Delete, FC1.Preheader, FC1.Header));
1660
1661 // Moves the phi nodes from the second to the first loops header block.
1662 while (PHINode *PHI = dyn_cast<PHINode>(&FC1.Header->front())) {
1663 if (SE.isSCEVable(PHI->getType()))
1664 SE.forgetValue(PHI);
1665 if (PHI->hasNUsesOrMore(1))
1666 PHI->moveBefore(&*FC0.Header->getFirstInsertionPt());
1667 else
1668 PHI->eraseFromParent();
1669 }
1670
1671 // Introduce new phi nodes in the second loop header to ensure
1672 // exiting the first and jumping to the header of the second does not break
1673 // the SSA property of the phis originally in the first loop. See also the
1674 // comment above.
1675 BasicBlock::iterator L1HeaderIP = FC1.Header->begin();
1676 for (PHINode *LCPHI : OriginalFC0PHIs) {
1677 int L1LatchBBIdx = LCPHI->getBasicBlockIndex(FC1.Latch);
1678 assert(L1LatchBBIdx >= 0 &&
1679 "Expected loop carried value to be rewired at this point!");
1680
1681 Value *LCV = LCPHI->getIncomingValue(L1LatchBBIdx);
1682
1683 PHINode *L1HeaderPHI =
1684 PHINode::Create(LCV->getType(), 2, LCPHI->getName() + ".afterFC0");
1685 L1HeaderPHI->insertBefore(L1HeaderIP);
1686 L1HeaderPHI->addIncoming(LCV, FC0.Latch);
1687 L1HeaderPHI->addIncoming(PoisonValue::get(LCV->getType()),
1688 FC0.ExitingBlock);
1689
1690 LCPHI->setIncomingValue(L1LatchBBIdx, L1HeaderPHI);
1691 }
1692
1693 // Replace latch terminator destinations.
1694 FC0.Latch->getTerminator()->replaceUsesOfWith(FC0.Header, FC1.Header);
1695 FC1.Latch->getTerminator()->replaceUsesOfWith(FC1.Header, FC0.Header);
1696
1697 // Modify the latch branch of FC0 to be unconditional as both successors of
1698 // the branch are the same.
1699 simplifyLatchBranch(FC0);
1700
1701 // If FC0.Latch and FC0.ExitingBlock are the same then we have already
1702 // performed the updates above.
1703 if (FC0.Latch != FC0.ExitingBlock)
1704 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1705 DominatorTree::Insert, FC0.Latch, FC1.Header));
1706
1707 TreeUpdates.emplace_back(DominatorTree::UpdateType(DominatorTree::Delete,
1708 FC0.Latch, FC0.Header));
1709 TreeUpdates.emplace_back(DominatorTree::UpdateType(DominatorTree::Insert,
1710 FC1.Latch, FC0.Header));
1711 TreeUpdates.emplace_back(DominatorTree::UpdateType(DominatorTree::Delete,
1712 FC1.Latch, FC1.Header));
1713
1714 // Update DT/PDT
1715 DTU.applyUpdates(TreeUpdates);
1716
1717 LI.removeBlock(FC1.Preheader);
1718 DTU.deleteBB(FC1.Preheader);
1719 if (FC0.Peeled) {
1720 LI.removeBlock(FC0.ExitBlock);
1721 DTU.deleteBB(FC0.ExitBlock);
1722 }
1723
1724 DTU.flush();
1725
1726 // Is there a way to keep SE up-to-date so we don't need to forget the loops
1727 // and rebuild the information in subsequent passes of fusion?
1728 // Note: Need to forget the loops before merging the loop latches, as
1729 // mergeLatch may remove the only block in FC1.
1730 SE.forgetLoop(FC1.L);
1731 SE.forgetLoop(FC0.L);
1732 SE.forgetLoopDispositions();
1733
1734 // Move instructions from FC0.Latch to FC1.Latch.
1735 // Note: mergeLatch requires an updated DT.
1736 mergeLatch(FC0, FC1);
1737
1738 // Merge the loops.
1739 SmallVector<BasicBlock *, 8> Blocks(FC1.L->blocks());
1740 for (BasicBlock *BB : Blocks) {
1741 FC0.L->addBlockEntry(BB);
1742 FC1.L->removeBlockFromLoop(BB);
1743 if (LI.getLoopFor(BB) != FC1.L)
1744 continue;
1745 LI.changeLoopFor(BB, FC0.L);
1746 }
1747 while (!FC1.L->isInnermost()) {
1748 const auto &ChildLoopIt = FC1.L->begin();
1749 Loop *ChildLoop = *ChildLoopIt;
1750 FC1.L->removeChildLoop(ChildLoopIt);
1751 FC0.L->addChildLoop(ChildLoop);
1752 }
1753
1754 // Delete the now empty loop L1.
1755 LI.erase(FC1.L);
1756
1757 #ifndef NDEBUG
1758 assert(!verifyFunction(*FC0.Header->getParent(), &errs()));
1759 assert(DT.verify(DominatorTree::VerificationLevel::Fast));
1760 assert(PDT.verify());
1761 LI.verify(DT);
1762 SE.verify();
1763 #endif
1764
1765 LLVM_DEBUG(dbgs() << "Fusion done:\n");
1766
1767 return FC0.L;
1768 }
1769
1770 /// Report details on loop fusion opportunities.
1771 ///
1772 /// This template function can be used to report both successful and missed
1773 /// loop fusion opportunities, based on the RemarkKind. The RemarkKind should
1774 /// be one of:
1775 /// - OptimizationRemarkMissed to report when loop fusion is unsuccessful
1776 /// given two valid fusion candidates.
1777 /// - OptimizationRemark to report successful fusion of two fusion
1778 /// candidates.
1779 /// The remarks will be printed using the form:
1780 /// <path/filename>:<line number>:<column number>: [<function name>]:
1781 /// <Cand1 Preheader> and <Cand2 Preheader>: <Stat Description>
1782 template <typename RemarkKind>
reportLoopFusion__anond06fd9000111::LoopFuser1783 void reportLoopFusion(const FusionCandidate &FC0, const FusionCandidate &FC1,
1784 llvm::Statistic &Stat) {
1785 assert(FC0.Preheader && FC1.Preheader &&
1786 "Expecting valid fusion candidates");
1787 using namespace ore;
1788 #if LLVM_ENABLE_STATS
1789 ++Stat;
1790 ORE.emit(RemarkKind(DEBUG_TYPE, Stat.getName(), FC0.L->getStartLoc(),
1791 FC0.Preheader)
1792 << "[" << FC0.Preheader->getParent()->getName()
1793 << "]: " << NV("Cand1", StringRef(FC0.Preheader->getName()))
1794 << " and " << NV("Cand2", StringRef(FC1.Preheader->getName()))
1795 << ": " << Stat.getDesc());
1796 #endif
1797 }
1798
1799 /// Fuse two guarded fusion candidates, creating a new fused loop.
1800 ///
1801 /// Fusing guarded loops is handled much the same way as fusing non-guarded
1802 /// loops. The rewiring of the CFG is slightly different though, because of
1803 /// the presence of the guards around the loops and the exit blocks after the
1804 /// loop body. As such, the new loop is rewired as follows:
1805 /// 1. Keep the guard branch from FC0 and use the non-loop block target
1806 /// from the FC1 guard branch.
1807 /// 2. Remove the exit block from FC0 (this exit block should be empty
1808 /// right now).
1809 /// 3. Remove the guard branch for FC1
1810 /// 4. Remove the preheader for FC1.
1811 /// The exit block successor for the latch of FC0 is updated to be the header
1812 /// of FC1 and the non-exit block successor of the latch of FC1 is updated to
1813 /// be the header of FC0, thus creating the fused loop.
fuseGuardedLoops__anond06fd9000111::LoopFuser1814 Loop *fuseGuardedLoops(const FusionCandidate &FC0,
1815 const FusionCandidate &FC1) {
1816 assert(FC0.GuardBranch && FC1.GuardBranch && "Expecting guarded loops");
1817
1818 BasicBlock *FC0GuardBlock = FC0.GuardBranch->getParent();
1819 BasicBlock *FC1GuardBlock = FC1.GuardBranch->getParent();
1820 BasicBlock *FC0NonLoopBlock = FC0.getNonLoopBlock();
1821 BasicBlock *FC1NonLoopBlock = FC1.getNonLoopBlock();
1822 BasicBlock *FC0ExitBlockSuccessor = FC0.ExitBlock->getUniqueSuccessor();
1823
1824 // Move instructions from the exit block of FC0 to the beginning of the exit
1825 // block of FC1, in the case that the FC0 loop has not been peeled. In the
1826 // case that FC0 loop is peeled, then move the instructions of the successor
1827 // of the FC0 Exit block to the beginning of the exit block of FC1.
1828 moveInstructionsToTheBeginning(
1829 (FC0.Peeled ? *FC0ExitBlockSuccessor : *FC0.ExitBlock), *FC1.ExitBlock,
1830 DT, PDT, DI);
1831
1832 // Move instructions from the guard block of FC1 to the end of the guard
1833 // block of FC0.
1834 moveInstructionsToTheEnd(*FC1GuardBlock, *FC0GuardBlock, DT, PDT, DI);
1835
1836 assert(FC0NonLoopBlock == FC1GuardBlock && "Loops are not adjacent");
1837
1838 SmallVector<DominatorTree::UpdateType, 8> TreeUpdates;
1839
1840 ////////////////////////////////////////////////////////////////////////////
1841 // Update the Loop Guard
1842 ////////////////////////////////////////////////////////////////////////////
1843 // The guard for FC0 is updated to guard both FC0 and FC1. This is done by
1844 // changing the NonLoopGuardBlock for FC0 to the NonLoopGuardBlock for FC1.
1845 // Thus, one path from the guard goes to the preheader for FC0 (and thus
1846 // executes the new fused loop) and the other path goes to the NonLoopBlock
1847 // for FC1 (where FC1 guard would have gone if FC1 was not executed).
1848 FC1NonLoopBlock->replacePhiUsesWith(FC1GuardBlock, FC0GuardBlock);
1849 FC0.GuardBranch->replaceUsesOfWith(FC0NonLoopBlock, FC1NonLoopBlock);
1850
1851 BasicBlock *BBToUpdate = FC0.Peeled ? FC0ExitBlockSuccessor : FC0.ExitBlock;
1852 BBToUpdate->getTerminator()->replaceUsesOfWith(FC1GuardBlock, FC1.Header);
1853
1854 // The guard of FC1 is not necessary anymore.
1855 FC1.GuardBranch->eraseFromParent();
1856 new UnreachableInst(FC1GuardBlock->getContext(), FC1GuardBlock);
1857
1858 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1859 DominatorTree::Delete, FC1GuardBlock, FC1.Preheader));
1860 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1861 DominatorTree::Delete, FC1GuardBlock, FC1NonLoopBlock));
1862 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1863 DominatorTree::Delete, FC0GuardBlock, FC1GuardBlock));
1864 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1865 DominatorTree::Insert, FC0GuardBlock, FC1NonLoopBlock));
1866
1867 if (FC0.Peeled) {
1868 // Remove the Block after the ExitBlock of FC0
1869 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1870 DominatorTree::Delete, FC0ExitBlockSuccessor, FC1GuardBlock));
1871 FC0ExitBlockSuccessor->getTerminator()->eraseFromParent();
1872 new UnreachableInst(FC0ExitBlockSuccessor->getContext(),
1873 FC0ExitBlockSuccessor);
1874 }
1875
1876 assert(pred_empty(FC1GuardBlock) &&
1877 "Expecting guard block to have no predecessors");
1878 assert(succ_empty(FC1GuardBlock) &&
1879 "Expecting guard block to have no successors");
1880
1881 // Remember the phi nodes originally in the header of FC0 in order to rewire
1882 // them later. However, this is only necessary if the new loop carried
1883 // values might not dominate the exiting branch. While we do not generally
1884 // test if this is the case but simply insert intermediate phi nodes, we
1885 // need to make sure these intermediate phi nodes have different
1886 // predecessors. To this end, we filter the special case where the exiting
1887 // block is the latch block of the first loop. Nothing needs to be done
1888 // anyway as all loop carried values dominate the latch and thereby also the
1889 // exiting branch.
1890 // KB: This is no longer necessary because FC0.ExitingBlock == FC0.Latch
1891 // (because the loops are rotated. Thus, nothing will ever be added to
1892 // OriginalFC0PHIs.
1893 SmallVector<PHINode *, 8> OriginalFC0PHIs;
1894 if (FC0.ExitingBlock != FC0.Latch)
1895 for (PHINode &PHI : FC0.Header->phis())
1896 OriginalFC0PHIs.push_back(&PHI);
1897
1898 assert(OriginalFC0PHIs.empty() && "Expecting OriginalFC0PHIs to be empty!");
1899
1900 // Replace incoming blocks for header PHIs first.
1901 FC1.Preheader->replaceSuccessorsPhiUsesWith(FC0.Preheader);
1902 FC0.Latch->replaceSuccessorsPhiUsesWith(FC1.Latch);
1903
1904 // The old exiting block of the first loop (FC0) has to jump to the header
1905 // of the second as we need to execute the code in the second header block
1906 // regardless of the trip count. That is, if the trip count is 0, so the
1907 // back edge is never taken, we still have to execute both loop headers,
1908 // especially (but not only!) if the second is a do-while style loop.
1909 // However, doing so might invalidate the phi nodes of the first loop as
1910 // the new values do only need to dominate their latch and not the exiting
1911 // predicate. To remedy this potential problem we always introduce phi
1912 // nodes in the header of the second loop later that select the loop carried
1913 // value, if the second header was reached through an old latch of the
1914 // first, or undef otherwise. This is sound as exiting the first implies the
1915 // second will exit too, __without__ taking the back-edge (their
1916 // trip-counts are equal after all).
1917 FC0.ExitingBlock->getTerminator()->replaceUsesOfWith(FC0.ExitBlock,
1918 FC1.Header);
1919
1920 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1921 DominatorTree::Delete, FC0.ExitingBlock, FC0.ExitBlock));
1922 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1923 DominatorTree::Insert, FC0.ExitingBlock, FC1.Header));
1924
1925 // Remove FC0 Exit Block
1926 // The exit block for FC0 is no longer needed since control will flow
1927 // directly to the header of FC1. Since it is an empty block, it can be
1928 // removed at this point.
1929 // TODO: In the future, we can handle non-empty exit blocks my merging any
1930 // instructions from FC0 exit block into FC1 exit block prior to removing
1931 // the block.
1932 assert(pred_empty(FC0.ExitBlock) && "Expecting exit block to be empty");
1933 FC0.ExitBlock->getTerminator()->eraseFromParent();
1934 new UnreachableInst(FC0.ExitBlock->getContext(), FC0.ExitBlock);
1935
1936 // Remove FC1 Preheader
1937 // The pre-header of L1 is not necessary anymore.
1938 assert(pred_empty(FC1.Preheader));
1939 FC1.Preheader->getTerminator()->eraseFromParent();
1940 new UnreachableInst(FC1.Preheader->getContext(), FC1.Preheader);
1941 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1942 DominatorTree::Delete, FC1.Preheader, FC1.Header));
1943
1944 // Moves the phi nodes from the second to the first loops header block.
1945 while (PHINode *PHI = dyn_cast<PHINode>(&FC1.Header->front())) {
1946 if (SE.isSCEVable(PHI->getType()))
1947 SE.forgetValue(PHI);
1948 if (PHI->hasNUsesOrMore(1))
1949 PHI->moveBefore(&*FC0.Header->getFirstInsertionPt());
1950 else
1951 PHI->eraseFromParent();
1952 }
1953
1954 // Introduce new phi nodes in the second loop header to ensure
1955 // exiting the first and jumping to the header of the second does not break
1956 // the SSA property of the phis originally in the first loop. See also the
1957 // comment above.
1958 BasicBlock::iterator L1HeaderIP = FC1.Header->begin();
1959 for (PHINode *LCPHI : OriginalFC0PHIs) {
1960 int L1LatchBBIdx = LCPHI->getBasicBlockIndex(FC1.Latch);
1961 assert(L1LatchBBIdx >= 0 &&
1962 "Expected loop carried value to be rewired at this point!");
1963
1964 Value *LCV = LCPHI->getIncomingValue(L1LatchBBIdx);
1965
1966 PHINode *L1HeaderPHI =
1967 PHINode::Create(LCV->getType(), 2, LCPHI->getName() + ".afterFC0");
1968 L1HeaderPHI->insertBefore(L1HeaderIP);
1969 L1HeaderPHI->addIncoming(LCV, FC0.Latch);
1970 L1HeaderPHI->addIncoming(UndefValue::get(LCV->getType()),
1971 FC0.ExitingBlock);
1972
1973 LCPHI->setIncomingValue(L1LatchBBIdx, L1HeaderPHI);
1974 }
1975
1976 // Update the latches
1977
1978 // Replace latch terminator destinations.
1979 FC0.Latch->getTerminator()->replaceUsesOfWith(FC0.Header, FC1.Header);
1980 FC1.Latch->getTerminator()->replaceUsesOfWith(FC1.Header, FC0.Header);
1981
1982 // Modify the latch branch of FC0 to be unconditional as both successors of
1983 // the branch are the same.
1984 simplifyLatchBranch(FC0);
1985
1986 // If FC0.Latch and FC0.ExitingBlock are the same then we have already
1987 // performed the updates above.
1988 if (FC0.Latch != FC0.ExitingBlock)
1989 TreeUpdates.emplace_back(DominatorTree::UpdateType(
1990 DominatorTree::Insert, FC0.Latch, FC1.Header));
1991
1992 TreeUpdates.emplace_back(DominatorTree::UpdateType(DominatorTree::Delete,
1993 FC0.Latch, FC0.Header));
1994 TreeUpdates.emplace_back(DominatorTree::UpdateType(DominatorTree::Insert,
1995 FC1.Latch, FC0.Header));
1996 TreeUpdates.emplace_back(DominatorTree::UpdateType(DominatorTree::Delete,
1997 FC1.Latch, FC1.Header));
1998
1999 // All done
2000 // Apply the updates to the Dominator Tree and cleanup.
2001
2002 assert(succ_empty(FC1GuardBlock) && "FC1GuardBlock has successors!!");
2003 assert(pred_empty(FC1GuardBlock) && "FC1GuardBlock has predecessors!!");
2004
2005 // Update DT/PDT
2006 DTU.applyUpdates(TreeUpdates);
2007
2008 LI.removeBlock(FC1GuardBlock);
2009 LI.removeBlock(FC1.Preheader);
2010 LI.removeBlock(FC0.ExitBlock);
2011 if (FC0.Peeled) {
2012 LI.removeBlock(FC0ExitBlockSuccessor);
2013 DTU.deleteBB(FC0ExitBlockSuccessor);
2014 }
2015 DTU.deleteBB(FC1GuardBlock);
2016 DTU.deleteBB(FC1.Preheader);
2017 DTU.deleteBB(FC0.ExitBlock);
2018 DTU.flush();
2019
2020 // Is there a way to keep SE up-to-date so we don't need to forget the loops
2021 // and rebuild the information in subsequent passes of fusion?
2022 // Note: Need to forget the loops before merging the loop latches, as
2023 // mergeLatch may remove the only block in FC1.
2024 SE.forgetLoop(FC1.L);
2025 SE.forgetLoop(FC0.L);
2026 SE.forgetLoopDispositions();
2027
2028 // Move instructions from FC0.Latch to FC1.Latch.
2029 // Note: mergeLatch requires an updated DT.
2030 mergeLatch(FC0, FC1);
2031
2032 // Merge the loops.
2033 SmallVector<BasicBlock *, 8> Blocks(FC1.L->blocks());
2034 for (BasicBlock *BB : Blocks) {
2035 FC0.L->addBlockEntry(BB);
2036 FC1.L->removeBlockFromLoop(BB);
2037 if (LI.getLoopFor(BB) != FC1.L)
2038 continue;
2039 LI.changeLoopFor(BB, FC0.L);
2040 }
2041 while (!FC1.L->isInnermost()) {
2042 const auto &ChildLoopIt = FC1.L->begin();
2043 Loop *ChildLoop = *ChildLoopIt;
2044 FC1.L->removeChildLoop(ChildLoopIt);
2045 FC0.L->addChildLoop(ChildLoop);
2046 }
2047
2048 // Delete the now empty loop L1.
2049 LI.erase(FC1.L);
2050
2051 #ifndef NDEBUG
2052 assert(!verifyFunction(*FC0.Header->getParent(), &errs()));
2053 assert(DT.verify(DominatorTree::VerificationLevel::Fast));
2054 assert(PDT.verify());
2055 LI.verify(DT);
2056 SE.verify();
2057 #endif
2058
2059 LLVM_DEBUG(dbgs() << "Fusion done:\n");
2060
2061 return FC0.L;
2062 }
2063 };
2064 } // namespace
2065
run(Function & F,FunctionAnalysisManager & AM)2066 PreservedAnalyses LoopFusePass::run(Function &F, FunctionAnalysisManager &AM) {
2067 auto &LI = AM.getResult<LoopAnalysis>(F);
2068 auto &DT = AM.getResult<DominatorTreeAnalysis>(F);
2069 auto &DI = AM.getResult<DependenceAnalysis>(F);
2070 auto &SE = AM.getResult<ScalarEvolutionAnalysis>(F);
2071 auto &PDT = AM.getResult<PostDominatorTreeAnalysis>(F);
2072 auto &ORE = AM.getResult<OptimizationRemarkEmitterAnalysis>(F);
2073 auto &AC = AM.getResult<AssumptionAnalysis>(F);
2074 const TargetTransformInfo &TTI = AM.getResult<TargetIRAnalysis>(F);
2075 const DataLayout &DL = F.getDataLayout();
2076
2077 // Ensure loops are in simplifed form which is a pre-requisite for loop fusion
2078 // pass. Added only for new PM since the legacy PM has already added
2079 // LoopSimplify pass as a dependency.
2080 bool Changed = false;
2081 for (auto &L : LI) {
2082 Changed |=
2083 simplifyLoop(L, &DT, &LI, &SE, &AC, nullptr, false /* PreserveLCSSA */);
2084 }
2085 if (Changed)
2086 PDT.recalculate(F);
2087
2088 LoopFuser LF(LI, DT, DI, SE, PDT, ORE, DL, AC, TTI);
2089 Changed |= LF.fuseLoops(F);
2090 if (!Changed)
2091 return PreservedAnalyses::all();
2092
2093 PreservedAnalyses PA;
2094 PA.preserve<DominatorTreeAnalysis>();
2095 PA.preserve<PostDominatorTreeAnalysis>();
2096 PA.preserve<ScalarEvolutionAnalysis>();
2097 PA.preserve<LoopAnalysis>();
2098 return PA;
2099 }
2100