1 //===-- MemorySSA.cpp - Memory SSA Builder---------------------------===//
2 //
3 // The LLVM Compiler Infrastructure
4 //
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
7 //
8 //===----------------------------------------------------------------===//
9 //
10 // This file implements the MemorySSA class.
11 //
12 //===----------------------------------------------------------------===//
13 #include "llvm/Transforms/Utils/MemorySSA.h"
14 #include "llvm/ADT/DenseMap.h"
15 #include "llvm/ADT/DenseSet.h"
16 #include "llvm/ADT/DepthFirstIterator.h"
17 #include "llvm/ADT/GraphTraits.h"
18 #include "llvm/ADT/PostOrderIterator.h"
19 #include "llvm/ADT/STLExtras.h"
20 #include "llvm/ADT/SmallPtrSet.h"
21 #include "llvm/ADT/SmallSet.h"
22 #include "llvm/ADT/Statistic.h"
23 #include "llvm/Analysis/AliasAnalysis.h"
24 #include "llvm/Analysis/CFG.h"
25 #include "llvm/Analysis/GlobalsModRef.h"
26 #include "llvm/Analysis/IteratedDominanceFrontier.h"
27 #include "llvm/Analysis/MemoryLocation.h"
28 #include "llvm/Analysis/PHITransAddr.h"
29 #include "llvm/IR/AssemblyAnnotationWriter.h"
30 #include "llvm/IR/DataLayout.h"
31 #include "llvm/IR/Dominators.h"
32 #include "llvm/IR/GlobalVariable.h"
33 #include "llvm/IR/IRBuilder.h"
34 #include "llvm/IR/IntrinsicInst.h"
35 #include "llvm/IR/LLVMContext.h"
36 #include "llvm/IR/Metadata.h"
37 #include "llvm/IR/Module.h"
38 #include "llvm/IR/PatternMatch.h"
39 #include "llvm/Support/Debug.h"
40 #include "llvm/Support/FormattedStream.h"
41 #include "llvm/Transforms/Scalar.h"
42 #include <algorithm>
43
44 #define DEBUG_TYPE "memoryssa"
45 using namespace llvm;
46 STATISTIC(NumClobberCacheLookups, "Number of Memory SSA version cache lookups");
47 STATISTIC(NumClobberCacheHits, "Number of Memory SSA version cache hits");
48 STATISTIC(NumClobberCacheInserts, "Number of MemorySSA version cache inserts");
49
50 INITIALIZE_PASS_BEGIN(MemorySSAWrapperPass, "memoryssa", "Memory SSA", false,
51 true)
52 INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass)
53 INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass)
54 INITIALIZE_PASS_END(MemorySSAWrapperPass, "memoryssa", "Memory SSA", false,
55 true)
56
57 INITIALIZE_PASS_BEGIN(MemorySSAPrinterLegacyPass, "print-memoryssa",
58 "Memory SSA Printer", false, false)
59 INITIALIZE_PASS_DEPENDENCY(MemorySSAWrapperPass)
60 INITIALIZE_PASS_END(MemorySSAPrinterLegacyPass, "print-memoryssa",
61 "Memory SSA Printer", false, false)
62
63 static cl::opt<bool>
64 VerifyMemorySSA("verify-memoryssa", cl::init(false), cl::Hidden,
65 cl::desc("Verify MemorySSA in legacy printer pass."));
66
67 namespace llvm {
68 /// \brief An assembly annotator class to print Memory SSA information in
69 /// comments.
70 class MemorySSAAnnotatedWriter : public AssemblyAnnotationWriter {
71 friend class MemorySSA;
72 const MemorySSA *MSSA;
73
74 public:
MemorySSAAnnotatedWriter(const MemorySSA * M)75 MemorySSAAnnotatedWriter(const MemorySSA *M) : MSSA(M) {}
76
emitBasicBlockStartAnnot(const BasicBlock * BB,formatted_raw_ostream & OS)77 virtual void emitBasicBlockStartAnnot(const BasicBlock *BB,
78 formatted_raw_ostream &OS) {
79 if (MemoryAccess *MA = MSSA->getMemoryAccess(BB))
80 OS << "; " << *MA << "\n";
81 }
82
emitInstructionAnnot(const Instruction * I,formatted_raw_ostream & OS)83 virtual void emitInstructionAnnot(const Instruction *I,
84 formatted_raw_ostream &OS) {
85 if (MemoryAccess *MA = MSSA->getMemoryAccess(I))
86 OS << "; " << *MA << "\n";
87 }
88 };
89
90 /// \brief A MemorySSAWalker that does AA walks and caching of lookups to
91 /// disambiguate accesses.
92 ///
93 /// FIXME: The current implementation of this can take quadratic space in rare
94 /// cases. This can be fixed, but it is something to note until it is fixed.
95 ///
96 /// In order to trigger this behavior, you need to store to N distinct locations
97 /// (that AA can prove don't alias), perform M stores to other memory
98 /// locations that AA can prove don't alias any of the initial N locations, and
99 /// then load from all of the N locations. In this case, we insert M cache
100 /// entries for each of the N loads.
101 ///
102 /// For example:
103 /// define i32 @foo() {
104 /// %a = alloca i32, align 4
105 /// %b = alloca i32, align 4
106 /// store i32 0, i32* %a, align 4
107 /// store i32 0, i32* %b, align 4
108 ///
109 /// ; Insert M stores to other memory that doesn't alias %a or %b here
110 ///
111 /// %c = load i32, i32* %a, align 4 ; Caches M entries in
112 /// ; CachedUpwardsClobberingAccess for the
113 /// ; MemoryLocation %a
114 /// %d = load i32, i32* %b, align 4 ; Caches M entries in
115 /// ; CachedUpwardsClobberingAccess for the
116 /// ; MemoryLocation %b
117 ///
118 /// ; For completeness' sake, loading %a or %b again would not cache *another*
119 /// ; M entries.
120 /// %r = add i32 %c, %d
121 /// ret i32 %r
122 /// }
123 class MemorySSA::CachingWalker final : public MemorySSAWalker {
124 public:
125 CachingWalker(MemorySSA *, AliasAnalysis *, DominatorTree *);
126 ~CachingWalker() override;
127
128 MemoryAccess *getClobberingMemoryAccess(const Instruction *) override;
129 MemoryAccess *getClobberingMemoryAccess(MemoryAccess *,
130 MemoryLocation &) override;
131 void invalidateInfo(MemoryAccess *) override;
132
133 protected:
134 struct UpwardsMemoryQuery;
135 MemoryAccess *doCacheLookup(const MemoryAccess *, const UpwardsMemoryQuery &,
136 const MemoryLocation &);
137
138 void doCacheInsert(const MemoryAccess *, MemoryAccess *,
139 const UpwardsMemoryQuery &, const MemoryLocation &);
140
141 void doCacheRemove(const MemoryAccess *, const UpwardsMemoryQuery &,
142 const MemoryLocation &);
143
144 private:
145 MemoryAccessPair UpwardsDFSWalk(MemoryAccess *, const MemoryLocation &,
146 UpwardsMemoryQuery &, bool);
147 MemoryAccess *getClobberingMemoryAccess(MemoryAccess *, UpwardsMemoryQuery &);
148 bool instructionClobbersQuery(const MemoryDef *, UpwardsMemoryQuery &,
149 const MemoryLocation &Loc) const;
150 void verifyRemoved(MemoryAccess *);
151 SmallDenseMap<ConstMemoryAccessPair, MemoryAccess *>
152 CachedUpwardsClobberingAccess;
153 DenseMap<const MemoryAccess *, MemoryAccess *> CachedUpwardsClobberingCall;
154 AliasAnalysis *AA;
155 DominatorTree *DT;
156 };
157 }
158
159 namespace {
160 struct RenamePassData {
161 DomTreeNode *DTN;
162 DomTreeNode::const_iterator ChildIt;
163 MemoryAccess *IncomingVal;
164
RenamePassData__anon27cdfc1b0111::RenamePassData165 RenamePassData(DomTreeNode *D, DomTreeNode::const_iterator It,
166 MemoryAccess *M)
167 : DTN(D), ChildIt(It), IncomingVal(M) {}
swap__anon27cdfc1b0111::RenamePassData168 void swap(RenamePassData &RHS) {
169 std::swap(DTN, RHS.DTN);
170 std::swap(ChildIt, RHS.ChildIt);
171 std::swap(IncomingVal, RHS.IncomingVal);
172 }
173 };
174 }
175
176 namespace llvm {
177 /// \brief Rename a single basic block into MemorySSA form.
178 /// Uses the standard SSA renaming algorithm.
179 /// \returns The new incoming value.
renameBlock(BasicBlock * BB,MemoryAccess * IncomingVal)180 MemoryAccess *MemorySSA::renameBlock(BasicBlock *BB,
181 MemoryAccess *IncomingVal) {
182 auto It = PerBlockAccesses.find(BB);
183 // Skip most processing if the list is empty.
184 if (It != PerBlockAccesses.end()) {
185 AccessList *Accesses = It->second.get();
186 for (MemoryAccess &L : *Accesses) {
187 switch (L.getValueID()) {
188 case Value::MemoryUseVal:
189 cast<MemoryUse>(&L)->setDefiningAccess(IncomingVal);
190 break;
191 case Value::MemoryDefVal:
192 // We can't legally optimize defs, because we only allow single
193 // memory phis/uses on operations, and if we optimize these, we can
194 // end up with multiple reaching defs. Uses do not have this
195 // problem, since they do not produce a value
196 cast<MemoryDef>(&L)->setDefiningAccess(IncomingVal);
197 IncomingVal = &L;
198 break;
199 case Value::MemoryPhiVal:
200 IncomingVal = &L;
201 break;
202 }
203 }
204 }
205
206 // Pass through values to our successors
207 for (const BasicBlock *S : successors(BB)) {
208 auto It = PerBlockAccesses.find(S);
209 // Rename the phi nodes in our successor block
210 if (It == PerBlockAccesses.end() || !isa<MemoryPhi>(It->second->front()))
211 continue;
212 AccessList *Accesses = It->second.get();
213 auto *Phi = cast<MemoryPhi>(&Accesses->front());
214 Phi->addIncoming(IncomingVal, BB);
215 }
216
217 return IncomingVal;
218 }
219
220 /// \brief This is the standard SSA renaming algorithm.
221 ///
222 /// We walk the dominator tree in preorder, renaming accesses, and then filling
223 /// in phi nodes in our successors.
renamePass(DomTreeNode * Root,MemoryAccess * IncomingVal,SmallPtrSet<BasicBlock *,16> & Visited)224 void MemorySSA::renamePass(DomTreeNode *Root, MemoryAccess *IncomingVal,
225 SmallPtrSet<BasicBlock *, 16> &Visited) {
226 SmallVector<RenamePassData, 32> WorkStack;
227 IncomingVal = renameBlock(Root->getBlock(), IncomingVal);
228 WorkStack.push_back({Root, Root->begin(), IncomingVal});
229 Visited.insert(Root->getBlock());
230
231 while (!WorkStack.empty()) {
232 DomTreeNode *Node = WorkStack.back().DTN;
233 DomTreeNode::const_iterator ChildIt = WorkStack.back().ChildIt;
234 IncomingVal = WorkStack.back().IncomingVal;
235
236 if (ChildIt == Node->end()) {
237 WorkStack.pop_back();
238 } else {
239 DomTreeNode *Child = *ChildIt;
240 ++WorkStack.back().ChildIt;
241 BasicBlock *BB = Child->getBlock();
242 Visited.insert(BB);
243 IncomingVal = renameBlock(BB, IncomingVal);
244 WorkStack.push_back({Child, Child->begin(), IncomingVal});
245 }
246 }
247 }
248
249 /// \brief Compute dominator levels, used by the phi insertion algorithm above.
computeDomLevels(DenseMap<DomTreeNode *,unsigned> & DomLevels)250 void MemorySSA::computeDomLevels(DenseMap<DomTreeNode *, unsigned> &DomLevels) {
251 for (auto DFI = df_begin(DT->getRootNode()), DFE = df_end(DT->getRootNode());
252 DFI != DFE; ++DFI)
253 DomLevels[*DFI] = DFI.getPathLength() - 1;
254 }
255
256 /// \brief This handles unreachable block accesses by deleting phi nodes in
257 /// unreachable blocks, and marking all other unreachable MemoryAccess's as
258 /// being uses of the live on entry definition.
markUnreachableAsLiveOnEntry(BasicBlock * BB)259 void MemorySSA::markUnreachableAsLiveOnEntry(BasicBlock *BB) {
260 assert(!DT->isReachableFromEntry(BB) &&
261 "Reachable block found while handling unreachable blocks");
262
263 // Make sure phi nodes in our reachable successors end up with a
264 // LiveOnEntryDef for our incoming edge, even though our block is forward
265 // unreachable. We could just disconnect these blocks from the CFG fully,
266 // but we do not right now.
267 for (const BasicBlock *S : successors(BB)) {
268 if (!DT->isReachableFromEntry(S))
269 continue;
270 auto It = PerBlockAccesses.find(S);
271 // Rename the phi nodes in our successor block
272 if (It == PerBlockAccesses.end() || !isa<MemoryPhi>(It->second->front()))
273 continue;
274 AccessList *Accesses = It->second.get();
275 auto *Phi = cast<MemoryPhi>(&Accesses->front());
276 Phi->addIncoming(LiveOnEntryDef.get(), BB);
277 }
278
279 auto It = PerBlockAccesses.find(BB);
280 if (It == PerBlockAccesses.end())
281 return;
282
283 auto &Accesses = It->second;
284 for (auto AI = Accesses->begin(), AE = Accesses->end(); AI != AE;) {
285 auto Next = std::next(AI);
286 // If we have a phi, just remove it. We are going to replace all
287 // users with live on entry.
288 if (auto *UseOrDef = dyn_cast<MemoryUseOrDef>(AI))
289 UseOrDef->setDefiningAccess(LiveOnEntryDef.get());
290 else
291 Accesses->erase(AI);
292 AI = Next;
293 }
294 }
295
MemorySSA(Function & Func,AliasAnalysis * AA,DominatorTree * DT)296 MemorySSA::MemorySSA(Function &Func, AliasAnalysis *AA, DominatorTree *DT)
297 : AA(AA), DT(DT), F(Func), LiveOnEntryDef(nullptr), Walker(nullptr),
298 NextID(0) {
299 buildMemorySSA();
300 }
301
MemorySSA(MemorySSA && MSSA)302 MemorySSA::MemorySSA(MemorySSA &&MSSA)
303 : AA(MSSA.AA), DT(MSSA.DT), F(MSSA.F),
304 ValueToMemoryAccess(std::move(MSSA.ValueToMemoryAccess)),
305 PerBlockAccesses(std::move(MSSA.PerBlockAccesses)),
306 LiveOnEntryDef(std::move(MSSA.LiveOnEntryDef)),
307 Walker(std::move(MSSA.Walker)), NextID(MSSA.NextID) {
308 // Update the Walker MSSA pointer so it doesn't point to the moved-from MSSA
309 // object any more.
310 Walker->MSSA = this;
311 }
312
~MemorySSA()313 MemorySSA::~MemorySSA() {
314 // Drop all our references
315 for (const auto &Pair : PerBlockAccesses)
316 for (MemoryAccess &MA : *Pair.second)
317 MA.dropAllReferences();
318 }
319
getOrCreateAccessList(const BasicBlock * BB)320 MemorySSA::AccessList *MemorySSA::getOrCreateAccessList(const BasicBlock *BB) {
321 auto Res = PerBlockAccesses.insert(std::make_pair(BB, nullptr));
322
323 if (Res.second)
324 Res.first->second = make_unique<AccessList>();
325 return Res.first->second.get();
326 }
327
buildMemorySSA()328 void MemorySSA::buildMemorySSA() {
329 // We create an access to represent "live on entry", for things like
330 // arguments or users of globals, where the memory they use is defined before
331 // the beginning of the function. We do not actually insert it into the IR.
332 // We do not define a live on exit for the immediate uses, and thus our
333 // semantics do *not* imply that something with no immediate uses can simply
334 // be removed.
335 BasicBlock &StartingPoint = F.getEntryBlock();
336 LiveOnEntryDef = make_unique<MemoryDef>(F.getContext(), nullptr, nullptr,
337 &StartingPoint, NextID++);
338
339 // We maintain lists of memory accesses per-block, trading memory for time. We
340 // could just look up the memory access for every possible instruction in the
341 // stream.
342 SmallPtrSet<BasicBlock *, 32> DefiningBlocks;
343 SmallPtrSet<BasicBlock *, 32> DefUseBlocks;
344 // Go through each block, figure out where defs occur, and chain together all
345 // the accesses.
346 for (BasicBlock &B : F) {
347 bool InsertIntoDef = false;
348 AccessList *Accesses = nullptr;
349 for (Instruction &I : B) {
350 MemoryUseOrDef *MUD = createNewAccess(&I);
351 if (!MUD)
352 continue;
353 InsertIntoDef |= isa<MemoryDef>(MUD);
354
355 if (!Accesses)
356 Accesses = getOrCreateAccessList(&B);
357 Accesses->push_back(MUD);
358 }
359 if (InsertIntoDef)
360 DefiningBlocks.insert(&B);
361 if (Accesses)
362 DefUseBlocks.insert(&B);
363 }
364
365 // Compute live-in.
366 // Live in is normally defined as "all the blocks on the path from each def to
367 // each of it's uses".
368 // MemoryDef's are implicit uses of previous state, so they are also uses.
369 // This means we don't really have def-only instructions. The only
370 // MemoryDef's that are not really uses are those that are of the LiveOnEntry
371 // variable (because LiveOnEntry can reach anywhere, and every def is a
372 // must-kill of LiveOnEntry).
373 // In theory, you could precisely compute live-in by using alias-analysis to
374 // disambiguate defs and uses to see which really pair up with which.
375 // In practice, this would be really expensive and difficult. So we simply
376 // assume all defs are also uses that need to be kept live.
377 // Because of this, the end result of this live-in computation will be "the
378 // entire set of basic blocks that reach any use".
379
380 SmallPtrSet<BasicBlock *, 32> LiveInBlocks;
381 SmallVector<BasicBlock *, 64> LiveInBlockWorklist(DefUseBlocks.begin(),
382 DefUseBlocks.end());
383 // Now that we have a set of blocks where a value is live-in, recursively add
384 // predecessors until we find the full region the value is live.
385 while (!LiveInBlockWorklist.empty()) {
386 BasicBlock *BB = LiveInBlockWorklist.pop_back_val();
387
388 // The block really is live in here, insert it into the set. If already in
389 // the set, then it has already been processed.
390 if (!LiveInBlocks.insert(BB).second)
391 continue;
392
393 // Since the value is live into BB, it is either defined in a predecessor or
394 // live into it to.
395 LiveInBlockWorklist.append(pred_begin(BB), pred_end(BB));
396 }
397
398 // Determine where our MemoryPhi's should go
399 ForwardIDFCalculator IDFs(*DT);
400 IDFs.setDefiningBlocks(DefiningBlocks);
401 IDFs.setLiveInBlocks(LiveInBlocks);
402 SmallVector<BasicBlock *, 32> IDFBlocks;
403 IDFs.calculate(IDFBlocks);
404
405 // Now place MemoryPhi nodes.
406 for (auto &BB : IDFBlocks) {
407 // Insert phi node
408 AccessList *Accesses = getOrCreateAccessList(BB);
409 MemoryPhi *Phi = new MemoryPhi(BB->getContext(), BB, NextID++);
410 ValueToMemoryAccess.insert(std::make_pair(BB, Phi));
411 // Phi's always are placed at the front of the block.
412 Accesses->push_front(Phi);
413 }
414
415 // Now do regular SSA renaming on the MemoryDef/MemoryUse. Visited will get
416 // filled in with all blocks.
417 SmallPtrSet<BasicBlock *, 16> Visited;
418 renamePass(DT->getRootNode(), LiveOnEntryDef.get(), Visited);
419
420 MemorySSAWalker *Walker = getWalker();
421
422 // Now optimize the MemoryUse's defining access to point to the nearest
423 // dominating clobbering def.
424 // This ensures that MemoryUse's that are killed by the same store are
425 // immediate users of that store, one of the invariants we guarantee.
426 for (auto DomNode : depth_first(DT)) {
427 BasicBlock *BB = DomNode->getBlock();
428 auto AI = PerBlockAccesses.find(BB);
429 if (AI == PerBlockAccesses.end())
430 continue;
431 AccessList *Accesses = AI->second.get();
432 for (auto &MA : *Accesses) {
433 if (auto *MU = dyn_cast<MemoryUse>(&MA)) {
434 Instruction *Inst = MU->getMemoryInst();
435 MU->setDefiningAccess(Walker->getClobberingMemoryAccess(Inst));
436 }
437 }
438 }
439
440 // Mark the uses in unreachable blocks as live on entry, so that they go
441 // somewhere.
442 for (auto &BB : F)
443 if (!Visited.count(&BB))
444 markUnreachableAsLiveOnEntry(&BB);
445 }
446
getWalker()447 MemorySSAWalker *MemorySSA::getWalker() {
448 if (Walker)
449 return Walker.get();
450
451 Walker = make_unique<CachingWalker>(this, AA, DT);
452 return Walker.get();
453 }
454
createMemoryPhi(BasicBlock * BB)455 MemoryPhi *MemorySSA::createMemoryPhi(BasicBlock *BB) {
456 assert(!getMemoryAccess(BB) && "MemoryPhi already exists for this BB");
457 AccessList *Accesses = getOrCreateAccessList(BB);
458 MemoryPhi *Phi = new MemoryPhi(BB->getContext(), BB, NextID++);
459 ValueToMemoryAccess.insert(std::make_pair(BB, Phi));
460 // Phi's always are placed at the front of the block.
461 Accesses->push_front(Phi);
462 return Phi;
463 }
464
createDefinedAccess(Instruction * I,MemoryAccess * Definition)465 MemoryUseOrDef *MemorySSA::createDefinedAccess(Instruction *I,
466 MemoryAccess *Definition) {
467 assert(!isa<PHINode>(I) && "Cannot create a defined access for a PHI");
468 MemoryUseOrDef *NewAccess = createNewAccess(I);
469 assert(
470 NewAccess != nullptr &&
471 "Tried to create a memory access for a non-memory touching instruction");
472 NewAccess->setDefiningAccess(Definition);
473 return NewAccess;
474 }
475
createMemoryAccessInBB(Instruction * I,MemoryAccess * Definition,const BasicBlock * BB,InsertionPlace Point)476 MemoryAccess *MemorySSA::createMemoryAccessInBB(Instruction *I,
477 MemoryAccess *Definition,
478 const BasicBlock *BB,
479 InsertionPlace Point) {
480 MemoryUseOrDef *NewAccess = createDefinedAccess(I, Definition);
481 auto *Accesses = getOrCreateAccessList(BB);
482 if (Point == Beginning) {
483 // It goes after any phi nodes
484 auto AI = std::find_if(
485 Accesses->begin(), Accesses->end(),
486 [](const MemoryAccess &MA) { return !isa<MemoryPhi>(MA); });
487
488 Accesses->insert(AI, NewAccess);
489 } else {
490 Accesses->push_back(NewAccess);
491 }
492
493 return NewAccess;
494 }
createMemoryAccessBefore(Instruction * I,MemoryAccess * Definition,MemoryAccess * InsertPt)495 MemoryAccess *MemorySSA::createMemoryAccessBefore(Instruction *I,
496 MemoryAccess *Definition,
497 MemoryAccess *InsertPt) {
498 assert(I->getParent() == InsertPt->getBlock() &&
499 "New and old access must be in the same block");
500 MemoryUseOrDef *NewAccess = createDefinedAccess(I, Definition);
501 auto *Accesses = getOrCreateAccessList(InsertPt->getBlock());
502 Accesses->insert(AccessList::iterator(InsertPt), NewAccess);
503 return NewAccess;
504 }
505
createMemoryAccessAfter(Instruction * I,MemoryAccess * Definition,MemoryAccess * InsertPt)506 MemoryAccess *MemorySSA::createMemoryAccessAfter(Instruction *I,
507 MemoryAccess *Definition,
508 MemoryAccess *InsertPt) {
509 assert(I->getParent() == InsertPt->getBlock() &&
510 "New and old access must be in the same block");
511 MemoryUseOrDef *NewAccess = createDefinedAccess(I, Definition);
512 auto *Accesses = getOrCreateAccessList(InsertPt->getBlock());
513 Accesses->insertAfter(AccessList::iterator(InsertPt), NewAccess);
514 return NewAccess;
515 }
516
517 /// \brief Helper function to create new memory accesses
createNewAccess(Instruction * I)518 MemoryUseOrDef *MemorySSA::createNewAccess(Instruction *I) {
519 // The assume intrinsic has a control dependency which we model by claiming
520 // that it writes arbitrarily. Ignore that fake memory dependency here.
521 // FIXME: Replace this special casing with a more accurate modelling of
522 // assume's control dependency.
523 if (IntrinsicInst *II = dyn_cast<IntrinsicInst>(I))
524 if (II->getIntrinsicID() == Intrinsic::assume)
525 return nullptr;
526
527 // Find out what affect this instruction has on memory.
528 ModRefInfo ModRef = AA->getModRefInfo(I);
529 bool Def = bool(ModRef & MRI_Mod);
530 bool Use = bool(ModRef & MRI_Ref);
531
532 // It's possible for an instruction to not modify memory at all. During
533 // construction, we ignore them.
534 if (!Def && !Use)
535 return nullptr;
536
537 assert((Def || Use) &&
538 "Trying to create a memory access with a non-memory instruction");
539
540 MemoryUseOrDef *MUD;
541 if (Def)
542 MUD = new MemoryDef(I->getContext(), nullptr, I, I->getParent(), NextID++);
543 else
544 MUD = new MemoryUse(I->getContext(), nullptr, I, I->getParent());
545 ValueToMemoryAccess.insert(std::make_pair(I, MUD));
546 return MUD;
547 }
548
findDominatingDef(BasicBlock * UseBlock,enum InsertionPlace Where)549 MemoryAccess *MemorySSA::findDominatingDef(BasicBlock *UseBlock,
550 enum InsertionPlace Where) {
551 // Handle the initial case
552 if (Where == Beginning)
553 // The only thing that could define us at the beginning is a phi node
554 if (MemoryPhi *Phi = getMemoryAccess(UseBlock))
555 return Phi;
556
557 DomTreeNode *CurrNode = DT->getNode(UseBlock);
558 // Need to be defined by our dominator
559 if (Where == Beginning)
560 CurrNode = CurrNode->getIDom();
561 Where = End;
562 while (CurrNode) {
563 auto It = PerBlockAccesses.find(CurrNode->getBlock());
564 if (It != PerBlockAccesses.end()) {
565 auto &Accesses = It->second;
566 for (MemoryAccess &RA : reverse(*Accesses)) {
567 if (isa<MemoryDef>(RA) || isa<MemoryPhi>(RA))
568 return &RA;
569 }
570 }
571 CurrNode = CurrNode->getIDom();
572 }
573 return LiveOnEntryDef.get();
574 }
575
576 /// \brief Returns true if \p Replacer dominates \p Replacee .
dominatesUse(const MemoryAccess * Replacer,const MemoryAccess * Replacee) const577 bool MemorySSA::dominatesUse(const MemoryAccess *Replacer,
578 const MemoryAccess *Replacee) const {
579 if (isa<MemoryUseOrDef>(Replacee))
580 return DT->dominates(Replacer->getBlock(), Replacee->getBlock());
581 const auto *MP = cast<MemoryPhi>(Replacee);
582 // For a phi node, the use occurs in the predecessor block of the phi node.
583 // Since we may occur multiple times in the phi node, we have to check each
584 // operand to ensure Replacer dominates each operand where Replacee occurs.
585 for (const Use &Arg : MP->operands()) {
586 if (Arg.get() != Replacee &&
587 !DT->dominates(Replacer->getBlock(), MP->getIncomingBlock(Arg)))
588 return false;
589 }
590 return true;
591 }
592
593 /// \brief If all arguments of a MemoryPHI are defined by the same incoming
594 /// argument, return that argument.
onlySingleValue(MemoryPhi * MP)595 static MemoryAccess *onlySingleValue(MemoryPhi *MP) {
596 MemoryAccess *MA = nullptr;
597
598 for (auto &Arg : MP->operands()) {
599 if (!MA)
600 MA = cast<MemoryAccess>(Arg);
601 else if (MA != Arg)
602 return nullptr;
603 }
604 return MA;
605 }
606
607 /// \brief Properly remove \p MA from all of MemorySSA's lookup tables.
608 ///
609 /// Because of the way the intrusive list and use lists work, it is important to
610 /// do removal in the right order.
removeFromLookups(MemoryAccess * MA)611 void MemorySSA::removeFromLookups(MemoryAccess *MA) {
612 assert(MA->use_empty() &&
613 "Trying to remove memory access that still has uses");
614 if (MemoryUseOrDef *MUD = dyn_cast<MemoryUseOrDef>(MA))
615 MUD->setDefiningAccess(nullptr);
616 // Invalidate our walker's cache if necessary
617 if (!isa<MemoryUse>(MA))
618 Walker->invalidateInfo(MA);
619 // The call below to erase will destroy MA, so we can't change the order we
620 // are doing things here
621 Value *MemoryInst;
622 if (MemoryUseOrDef *MUD = dyn_cast<MemoryUseOrDef>(MA)) {
623 MemoryInst = MUD->getMemoryInst();
624 } else {
625 MemoryInst = MA->getBlock();
626 }
627 ValueToMemoryAccess.erase(MemoryInst);
628
629 auto AccessIt = PerBlockAccesses.find(MA->getBlock());
630 std::unique_ptr<AccessList> &Accesses = AccessIt->second;
631 Accesses->erase(MA);
632 if (Accesses->empty())
633 PerBlockAccesses.erase(AccessIt);
634 }
635
removeMemoryAccess(MemoryAccess * MA)636 void MemorySSA::removeMemoryAccess(MemoryAccess *MA) {
637 assert(!isLiveOnEntryDef(MA) && "Trying to remove the live on entry def");
638 // We can only delete phi nodes if they have no uses, or we can replace all
639 // uses with a single definition.
640 MemoryAccess *NewDefTarget = nullptr;
641 if (MemoryPhi *MP = dyn_cast<MemoryPhi>(MA)) {
642 // Note that it is sufficient to know that all edges of the phi node have
643 // the same argument. If they do, by the definition of dominance frontiers
644 // (which we used to place this phi), that argument must dominate this phi,
645 // and thus, must dominate the phi's uses, and so we will not hit the assert
646 // below.
647 NewDefTarget = onlySingleValue(MP);
648 assert((NewDefTarget || MP->use_empty()) &&
649 "We can't delete this memory phi");
650 } else {
651 NewDefTarget = cast<MemoryUseOrDef>(MA)->getDefiningAccess();
652 }
653
654 // Re-point the uses at our defining access
655 if (!MA->use_empty())
656 MA->replaceAllUsesWith(NewDefTarget);
657
658 // The call below to erase will destroy MA, so we can't change the order we
659 // are doing things here
660 removeFromLookups(MA);
661 }
662
print(raw_ostream & OS) const663 void MemorySSA::print(raw_ostream &OS) const {
664 MemorySSAAnnotatedWriter Writer(this);
665 F.print(OS, &Writer);
666 }
667
dump() const668 void MemorySSA::dump() const {
669 MemorySSAAnnotatedWriter Writer(this);
670 F.print(dbgs(), &Writer);
671 }
672
verifyMemorySSA() const673 void MemorySSA::verifyMemorySSA() const {
674 verifyDefUses(F);
675 verifyDomination(F);
676 verifyOrdering(F);
677 }
678
679 /// \brief Verify that the order and existence of MemoryAccesses matches the
680 /// order and existence of memory affecting instructions.
verifyOrdering(Function & F) const681 void MemorySSA::verifyOrdering(Function &F) const {
682 // Walk all the blocks, comparing what the lookups think and what the access
683 // lists think, as well as the order in the blocks vs the order in the access
684 // lists.
685 SmallVector<MemoryAccess *, 32> ActualAccesses;
686 for (BasicBlock &B : F) {
687 const AccessList *AL = getBlockAccesses(&B);
688 MemoryAccess *Phi = getMemoryAccess(&B);
689 if (Phi)
690 ActualAccesses.push_back(Phi);
691 for (Instruction &I : B) {
692 MemoryAccess *MA = getMemoryAccess(&I);
693 assert((!MA || AL) && "We have memory affecting instructions "
694 "in this block but they are not in the "
695 "access list");
696 if (MA)
697 ActualAccesses.push_back(MA);
698 }
699 // Either we hit the assert, really have no accesses, or we have both
700 // accesses and an access list
701 if (!AL)
702 continue;
703 assert(AL->size() == ActualAccesses.size() &&
704 "We don't have the same number of accesses in the block as on the "
705 "access list");
706 auto ALI = AL->begin();
707 auto AAI = ActualAccesses.begin();
708 while (ALI != AL->end() && AAI != ActualAccesses.end()) {
709 assert(&*ALI == *AAI && "Not the same accesses in the same order");
710 ++ALI;
711 ++AAI;
712 }
713 ActualAccesses.clear();
714 }
715 }
716
717 /// \brief Verify the domination properties of MemorySSA by checking that each
718 /// definition dominates all of its uses.
verifyDomination(Function & F) const719 void MemorySSA::verifyDomination(Function &F) const {
720 for (BasicBlock &B : F) {
721 // Phi nodes are attached to basic blocks
722 if (MemoryPhi *MP = getMemoryAccess(&B)) {
723 for (User *U : MP->users()) {
724 BasicBlock *UseBlock;
725 // Phi operands are used on edges, we simulate the right domination by
726 // acting as if the use occurred at the end of the predecessor block.
727 if (MemoryPhi *P = dyn_cast<MemoryPhi>(U)) {
728 for (const auto &Arg : P->operands()) {
729 if (Arg == MP) {
730 UseBlock = P->getIncomingBlock(Arg);
731 break;
732 }
733 }
734 } else {
735 UseBlock = cast<MemoryAccess>(U)->getBlock();
736 }
737 (void)UseBlock;
738 assert(DT->dominates(MP->getBlock(), UseBlock) &&
739 "Memory PHI does not dominate it's uses");
740 }
741 }
742
743 for (Instruction &I : B) {
744 MemoryAccess *MD = dyn_cast_or_null<MemoryDef>(getMemoryAccess(&I));
745 if (!MD)
746 continue;
747
748 for (User *U : MD->users()) {
749 BasicBlock *UseBlock;
750 (void)UseBlock;
751 // Things are allowed to flow to phi nodes over their predecessor edge.
752 if (auto *P = dyn_cast<MemoryPhi>(U)) {
753 for (const auto &Arg : P->operands()) {
754 if (Arg == MD) {
755 UseBlock = P->getIncomingBlock(Arg);
756 break;
757 }
758 }
759 } else {
760 UseBlock = cast<MemoryAccess>(U)->getBlock();
761 }
762 assert(DT->dominates(MD->getBlock(), UseBlock) &&
763 "Memory Def does not dominate it's uses");
764 }
765 }
766 }
767 }
768
769 /// \brief Verify the def-use lists in MemorySSA, by verifying that \p Use
770 /// appears in the use list of \p Def.
771 ///
772 /// llvm_unreachable is used instead of asserts because this may be called in
773 /// a build without asserts. In that case, we don't want this to turn into a
774 /// nop.
verifyUseInDefs(MemoryAccess * Def,MemoryAccess * Use) const775 void MemorySSA::verifyUseInDefs(MemoryAccess *Def, MemoryAccess *Use) const {
776 // The live on entry use may cause us to get a NULL def here
777 if (!Def) {
778 if (!isLiveOnEntryDef(Use))
779 llvm_unreachable("Null def but use not point to live on entry def");
780 } else if (std::find(Def->user_begin(), Def->user_end(), Use) ==
781 Def->user_end()) {
782 llvm_unreachable("Did not find use in def's use list");
783 }
784 }
785
786 /// \brief Verify the immediate use information, by walking all the memory
787 /// accesses and verifying that, for each use, it appears in the
788 /// appropriate def's use list
verifyDefUses(Function & F) const789 void MemorySSA::verifyDefUses(Function &F) const {
790 for (BasicBlock &B : F) {
791 // Phi nodes are attached to basic blocks
792 if (MemoryPhi *Phi = getMemoryAccess(&B)) {
793 assert(Phi->getNumOperands() == static_cast<unsigned>(std::distance(
794 pred_begin(&B), pred_end(&B))) &&
795 "Incomplete MemoryPhi Node");
796 for (unsigned I = 0, E = Phi->getNumIncomingValues(); I != E; ++I)
797 verifyUseInDefs(Phi->getIncomingValue(I), Phi);
798 }
799
800 for (Instruction &I : B) {
801 if (MemoryAccess *MA = getMemoryAccess(&I)) {
802 assert(isa<MemoryUseOrDef>(MA) &&
803 "Found a phi node not attached to a bb");
804 verifyUseInDefs(cast<MemoryUseOrDef>(MA)->getDefiningAccess(), MA);
805 }
806 }
807 }
808 }
809
getMemoryAccess(const Value * I) const810 MemoryAccess *MemorySSA::getMemoryAccess(const Value *I) const {
811 return ValueToMemoryAccess.lookup(I);
812 }
813
getMemoryAccess(const BasicBlock * BB) const814 MemoryPhi *MemorySSA::getMemoryAccess(const BasicBlock *BB) const {
815 return cast_or_null<MemoryPhi>(getMemoryAccess((const Value *)BB));
816 }
817
818 /// \brief Determine, for two memory accesses in the same block,
819 /// whether \p Dominator dominates \p Dominatee.
820 /// \returns True if \p Dominator dominates \p Dominatee.
locallyDominates(const MemoryAccess * Dominator,const MemoryAccess * Dominatee) const821 bool MemorySSA::locallyDominates(const MemoryAccess *Dominator,
822 const MemoryAccess *Dominatee) const {
823
824 assert((Dominator->getBlock() == Dominatee->getBlock()) &&
825 "Asking for local domination when accesses are in different blocks!");
826
827 // A node dominates itself.
828 if (Dominatee == Dominator)
829 return true;
830
831 // When Dominatee is defined on function entry, it is not dominated by another
832 // memory access.
833 if (isLiveOnEntryDef(Dominatee))
834 return false;
835
836 // When Dominator is defined on function entry, it dominates the other memory
837 // access.
838 if (isLiveOnEntryDef(Dominator))
839 return true;
840
841 // Get the access list for the block
842 const AccessList *AccessList = getBlockAccesses(Dominator->getBlock());
843 AccessList::const_reverse_iterator It(Dominator->getIterator());
844
845 // If we hit the beginning of the access list before we hit dominatee, we must
846 // dominate it
847 return std::none_of(It, AccessList->rend(),
848 [&](const MemoryAccess &MA) { return &MA == Dominatee; });
849 }
850
851 const static char LiveOnEntryStr[] = "liveOnEntry";
852
print(raw_ostream & OS) const853 void MemoryDef::print(raw_ostream &OS) const {
854 MemoryAccess *UO = getDefiningAccess();
855
856 OS << getID() << " = MemoryDef(";
857 if (UO && UO->getID())
858 OS << UO->getID();
859 else
860 OS << LiveOnEntryStr;
861 OS << ')';
862 }
863
print(raw_ostream & OS) const864 void MemoryPhi::print(raw_ostream &OS) const {
865 bool First = true;
866 OS << getID() << " = MemoryPhi(";
867 for (const auto &Op : operands()) {
868 BasicBlock *BB = getIncomingBlock(Op);
869 MemoryAccess *MA = cast<MemoryAccess>(Op);
870 if (!First)
871 OS << ',';
872 else
873 First = false;
874
875 OS << '{';
876 if (BB->hasName())
877 OS << BB->getName();
878 else
879 BB->printAsOperand(OS, false);
880 OS << ',';
881 if (unsigned ID = MA->getID())
882 OS << ID;
883 else
884 OS << LiveOnEntryStr;
885 OS << '}';
886 }
887 OS << ')';
888 }
889
~MemoryAccess()890 MemoryAccess::~MemoryAccess() {}
891
print(raw_ostream & OS) const892 void MemoryUse::print(raw_ostream &OS) const {
893 MemoryAccess *UO = getDefiningAccess();
894 OS << "MemoryUse(";
895 if (UO && UO->getID())
896 OS << UO->getID();
897 else
898 OS << LiveOnEntryStr;
899 OS << ')';
900 }
901
dump() const902 void MemoryAccess::dump() const {
903 print(dbgs());
904 dbgs() << "\n";
905 }
906
907 char MemorySSAPrinterLegacyPass::ID = 0;
908
MemorySSAPrinterLegacyPass()909 MemorySSAPrinterLegacyPass::MemorySSAPrinterLegacyPass() : FunctionPass(ID) {
910 initializeMemorySSAPrinterLegacyPassPass(*PassRegistry::getPassRegistry());
911 }
912
getAnalysisUsage(AnalysisUsage & AU) const913 void MemorySSAPrinterLegacyPass::getAnalysisUsage(AnalysisUsage &AU) const {
914 AU.setPreservesAll();
915 AU.addRequired<MemorySSAWrapperPass>();
916 AU.addPreserved<MemorySSAWrapperPass>();
917 }
918
runOnFunction(Function & F)919 bool MemorySSAPrinterLegacyPass::runOnFunction(Function &F) {
920 auto &MSSA = getAnalysis<MemorySSAWrapperPass>().getMSSA();
921 MSSA.print(dbgs());
922 if (VerifyMemorySSA)
923 MSSA.verifyMemorySSA();
924 return false;
925 }
926
927 char MemorySSAAnalysis::PassID;
928
run(Function & F,AnalysisManager<Function> & AM)929 MemorySSA MemorySSAAnalysis::run(Function &F, AnalysisManager<Function> &AM) {
930 auto &DT = AM.getResult<DominatorTreeAnalysis>(F);
931 auto &AA = AM.getResult<AAManager>(F);
932 return MemorySSA(F, &AA, &DT);
933 }
934
run(Function & F,FunctionAnalysisManager & AM)935 PreservedAnalyses MemorySSAPrinterPass::run(Function &F,
936 FunctionAnalysisManager &AM) {
937 OS << "MemorySSA for function: " << F.getName() << "\n";
938 AM.getResult<MemorySSAAnalysis>(F).print(OS);
939
940 return PreservedAnalyses::all();
941 }
942
run(Function & F,FunctionAnalysisManager & AM)943 PreservedAnalyses MemorySSAVerifierPass::run(Function &F,
944 FunctionAnalysisManager &AM) {
945 AM.getResult<MemorySSAAnalysis>(F).verifyMemorySSA();
946
947 return PreservedAnalyses::all();
948 }
949
950 char MemorySSAWrapperPass::ID = 0;
951
MemorySSAWrapperPass()952 MemorySSAWrapperPass::MemorySSAWrapperPass() : FunctionPass(ID) {
953 initializeMemorySSAWrapperPassPass(*PassRegistry::getPassRegistry());
954 }
955
releaseMemory()956 void MemorySSAWrapperPass::releaseMemory() { MSSA.reset(); }
957
getAnalysisUsage(AnalysisUsage & AU) const958 void MemorySSAWrapperPass::getAnalysisUsage(AnalysisUsage &AU) const {
959 AU.setPreservesAll();
960 AU.addRequiredTransitive<DominatorTreeWrapperPass>();
961 AU.addRequiredTransitive<AAResultsWrapperPass>();
962 }
963
runOnFunction(Function & F)964 bool MemorySSAWrapperPass::runOnFunction(Function &F) {
965 auto &DT = getAnalysis<DominatorTreeWrapperPass>().getDomTree();
966 auto &AA = getAnalysis<AAResultsWrapperPass>().getAAResults();
967 MSSA.reset(new MemorySSA(F, &AA, &DT));
968 return false;
969 }
970
verifyAnalysis() const971 void MemorySSAWrapperPass::verifyAnalysis() const { MSSA->verifyMemorySSA(); }
972
print(raw_ostream & OS,const Module * M) const973 void MemorySSAWrapperPass::print(raw_ostream &OS, const Module *M) const {
974 MSSA->print(OS);
975 }
976
MemorySSAWalker(MemorySSA * M)977 MemorySSAWalker::MemorySSAWalker(MemorySSA *M) : MSSA(M) {}
978
CachingWalker(MemorySSA * M,AliasAnalysis * A,DominatorTree * D)979 MemorySSA::CachingWalker::CachingWalker(MemorySSA *M, AliasAnalysis *A,
980 DominatorTree *D)
981 : MemorySSAWalker(M), AA(A), DT(D) {}
982
~CachingWalker()983 MemorySSA::CachingWalker::~CachingWalker() {}
984
985 struct MemorySSA::CachingWalker::UpwardsMemoryQuery {
986 // True if we saw a phi whose predecessor was a backedge
987 bool SawBackedgePhi;
988 // True if our original query started off as a call
989 bool IsCall;
990 // The pointer location we started the query with. This will be empty if
991 // IsCall is true.
992 MemoryLocation StartingLoc;
993 // This is the instruction we were querying about.
994 const Instruction *Inst;
995 // Set of visited Instructions for this query.
996 DenseSet<MemoryAccessPair> Visited;
997 // Vector of visited call accesses for this query. This is separated out
998 // because you can always cache and lookup the result of call queries (IE when
999 // IsCall == true) for every call in the chain. The calls have no AA location
1000 // associated with them with them, and thus, no context dependence.
1001 SmallVector<const MemoryAccess *, 32> VisitedCalls;
1002 // The MemoryAccess we actually got called with, used to test local domination
1003 const MemoryAccess *OriginalAccess;
1004
UpwardsMemoryQueryllvm::MemorySSA::CachingWalker::UpwardsMemoryQuery1005 UpwardsMemoryQuery()
1006 : SawBackedgePhi(false), IsCall(false), Inst(nullptr),
1007 OriginalAccess(nullptr) {}
1008
UpwardsMemoryQueryllvm::MemorySSA::CachingWalker::UpwardsMemoryQuery1009 UpwardsMemoryQuery(const Instruction *Inst, const MemoryAccess *Access)
1010 : SawBackedgePhi(false), IsCall(ImmutableCallSite(Inst)), Inst(Inst),
1011 OriginalAccess(Access) {}
1012 };
1013
invalidateInfo(MemoryAccess * MA)1014 void MemorySSA::CachingWalker::invalidateInfo(MemoryAccess *MA) {
1015
1016 // TODO: We can do much better cache invalidation with differently stored
1017 // caches. For now, for MemoryUses, we simply remove them
1018 // from the cache, and kill the entire call/non-call cache for everything
1019 // else. The problem is for phis or defs, currently we'd need to follow use
1020 // chains down and invalidate anything below us in the chain that currently
1021 // terminates at this access.
1022
1023 // See if this is a MemoryUse, if so, just remove the cached info. MemoryUse
1024 // is by definition never a barrier, so nothing in the cache could point to
1025 // this use. In that case, we only need invalidate the info for the use
1026 // itself.
1027
1028 if (MemoryUse *MU = dyn_cast<MemoryUse>(MA)) {
1029 UpwardsMemoryQuery Q;
1030 Instruction *I = MU->getMemoryInst();
1031 Q.IsCall = bool(ImmutableCallSite(I));
1032 Q.Inst = I;
1033 if (!Q.IsCall)
1034 Q.StartingLoc = MemoryLocation::get(I);
1035 doCacheRemove(MA, Q, Q.StartingLoc);
1036 } else {
1037 // If it is not a use, the best we can do right now is destroy the cache.
1038 CachedUpwardsClobberingCall.clear();
1039 CachedUpwardsClobberingAccess.clear();
1040 }
1041
1042 #ifdef EXPENSIVE_CHECKS
1043 // Run this only when expensive checks are enabled.
1044 verifyRemoved(MA);
1045 #endif
1046 }
1047
doCacheRemove(const MemoryAccess * M,const UpwardsMemoryQuery & Q,const MemoryLocation & Loc)1048 void MemorySSA::CachingWalker::doCacheRemove(const MemoryAccess *M,
1049 const UpwardsMemoryQuery &Q,
1050 const MemoryLocation &Loc) {
1051 if (Q.IsCall)
1052 CachedUpwardsClobberingCall.erase(M);
1053 else
1054 CachedUpwardsClobberingAccess.erase({M, Loc});
1055 }
1056
doCacheInsert(const MemoryAccess * M,MemoryAccess * Result,const UpwardsMemoryQuery & Q,const MemoryLocation & Loc)1057 void MemorySSA::CachingWalker::doCacheInsert(const MemoryAccess *M,
1058 MemoryAccess *Result,
1059 const UpwardsMemoryQuery &Q,
1060 const MemoryLocation &Loc) {
1061 // This is fine for Phis, since there are times where we can't optimize them.
1062 // Making a def its own clobber is never correct, though.
1063 assert((Result != M || isa<MemoryPhi>(M)) &&
1064 "Something can't clobber itself!");
1065 ++NumClobberCacheInserts;
1066 if (Q.IsCall)
1067 CachedUpwardsClobberingCall[M] = Result;
1068 else
1069 CachedUpwardsClobberingAccess[{M, Loc}] = Result;
1070 }
1071
1072 MemoryAccess *
doCacheLookup(const MemoryAccess * M,const UpwardsMemoryQuery & Q,const MemoryLocation & Loc)1073 MemorySSA::CachingWalker::doCacheLookup(const MemoryAccess *M,
1074 const UpwardsMemoryQuery &Q,
1075 const MemoryLocation &Loc) {
1076 ++NumClobberCacheLookups;
1077 MemoryAccess *Result;
1078
1079 if (Q.IsCall)
1080 Result = CachedUpwardsClobberingCall.lookup(M);
1081 else
1082 Result = CachedUpwardsClobberingAccess.lookup({M, Loc});
1083
1084 if (Result)
1085 ++NumClobberCacheHits;
1086 return Result;
1087 }
1088
instructionClobbersQuery(const MemoryDef * MD,UpwardsMemoryQuery & Q,const MemoryLocation & Loc) const1089 bool MemorySSA::CachingWalker::instructionClobbersQuery(
1090 const MemoryDef *MD, UpwardsMemoryQuery &Q,
1091 const MemoryLocation &Loc) const {
1092 Instruction *DefMemoryInst = MD->getMemoryInst();
1093 assert(DefMemoryInst && "Defining instruction not actually an instruction");
1094
1095 if (!Q.IsCall)
1096 return AA->getModRefInfo(DefMemoryInst, Loc) & MRI_Mod;
1097
1098 // If this is a call, mark it for caching
1099 if (ImmutableCallSite(DefMemoryInst))
1100 Q.VisitedCalls.push_back(MD);
1101 ModRefInfo I = AA->getModRefInfo(DefMemoryInst, ImmutableCallSite(Q.Inst));
1102 return I != MRI_NoModRef;
1103 }
1104
UpwardsDFSWalk(MemoryAccess * StartingAccess,const MemoryLocation & Loc,UpwardsMemoryQuery & Q,bool FollowingBackedge)1105 MemoryAccessPair MemorySSA::CachingWalker::UpwardsDFSWalk(
1106 MemoryAccess *StartingAccess, const MemoryLocation &Loc,
1107 UpwardsMemoryQuery &Q, bool FollowingBackedge) {
1108 MemoryAccess *ModifyingAccess = nullptr;
1109
1110 auto DFI = df_begin(StartingAccess);
1111 for (auto DFE = df_end(StartingAccess); DFI != DFE;) {
1112 MemoryAccess *CurrAccess = *DFI;
1113 if (MSSA->isLiveOnEntryDef(CurrAccess))
1114 return {CurrAccess, Loc};
1115 // If this is a MemoryDef, check whether it clobbers our current query. This
1116 // needs to be done before consulting the cache, because the cache reports
1117 // the clobber for CurrAccess. If CurrAccess is a clobber for this query,
1118 // and we ask the cache for information first, then we might skip this
1119 // clobber, which is bad.
1120 if (auto *MD = dyn_cast<MemoryDef>(CurrAccess)) {
1121 // If we hit the top, stop following this path.
1122 // While we can do lookups, we can't sanely do inserts here unless we were
1123 // to track everything we saw along the way, since we don't know where we
1124 // will stop.
1125 if (instructionClobbersQuery(MD, Q, Loc)) {
1126 ModifyingAccess = CurrAccess;
1127 break;
1128 }
1129 }
1130 if (auto CacheResult = doCacheLookup(CurrAccess, Q, Loc))
1131 return {CacheResult, Loc};
1132
1133 // We need to know whether it is a phi so we can track backedges.
1134 // Otherwise, walk all upward defs.
1135 if (!isa<MemoryPhi>(CurrAccess)) {
1136 ++DFI;
1137 continue;
1138 }
1139
1140 #ifndef NDEBUG
1141 // The loop below visits the phi's children for us. Because phis are the
1142 // only things with multiple edges, skipping the children should always lead
1143 // us to the end of the loop.
1144 //
1145 // Use a copy of DFI because skipChildren would kill our search stack, which
1146 // would make caching anything on the way back impossible.
1147 auto DFICopy = DFI;
1148 assert(DFICopy.skipChildren() == DFE &&
1149 "Skipping phi's children doesn't end the DFS?");
1150 #endif
1151
1152 const MemoryAccessPair PHIPair(CurrAccess, Loc);
1153
1154 // Don't try to optimize this phi again if we've already tried to do so.
1155 if (!Q.Visited.insert(PHIPair).second) {
1156 ModifyingAccess = CurrAccess;
1157 break;
1158 }
1159
1160 std::size_t InitialVisitedCallSize = Q.VisitedCalls.size();
1161
1162 // Recurse on PHI nodes, since we need to change locations.
1163 // TODO: Allow graphtraits on pairs, which would turn this whole function
1164 // into a normal single depth first walk.
1165 MemoryAccess *FirstDef = nullptr;
1166 for (auto MPI = upward_defs_begin(PHIPair), MPE = upward_defs_end();
1167 MPI != MPE; ++MPI) {
1168 bool Backedge =
1169 !FollowingBackedge &&
1170 DT->dominates(CurrAccess->getBlock(), MPI.getPhiArgBlock());
1171
1172 MemoryAccessPair CurrentPair =
1173 UpwardsDFSWalk(MPI->first, MPI->second, Q, Backedge);
1174 // All the phi arguments should reach the same point if we can bypass
1175 // this phi. The alternative is that they hit this phi node, which
1176 // means we can skip this argument.
1177 if (FirstDef && CurrentPair.first != PHIPair.first &&
1178 CurrentPair.first != FirstDef) {
1179 ModifyingAccess = CurrAccess;
1180 break;
1181 }
1182
1183 if (!FirstDef)
1184 FirstDef = CurrentPair.first;
1185 }
1186
1187 // If we exited the loop early, go with the result it gave us.
1188 if (!ModifyingAccess) {
1189 assert(FirstDef && "Found a Phi with no upward defs?");
1190 ModifyingAccess = FirstDef;
1191 } else {
1192 // If we can't optimize this Phi, then we can't safely cache any of the
1193 // calls we visited when trying to optimize it. Wipe them out now.
1194 Q.VisitedCalls.resize(InitialVisitedCallSize);
1195 }
1196 break;
1197 }
1198
1199 if (!ModifyingAccess)
1200 return {MSSA->getLiveOnEntryDef(), Q.StartingLoc};
1201
1202 const BasicBlock *OriginalBlock = StartingAccess->getBlock();
1203 assert(DFI.getPathLength() > 0 && "We dropped our path?");
1204 unsigned N = DFI.getPathLength();
1205 // If we found a clobbering def, the last element in the path will be our
1206 // clobber, so we don't want to cache that to itself. OTOH, if we optimized a
1207 // phi, we can add the last thing in the path to the cache, since that won't
1208 // be the result.
1209 if (DFI.getPath(N - 1) == ModifyingAccess)
1210 --N;
1211 for (; N > 1; --N) {
1212 MemoryAccess *CacheAccess = DFI.getPath(N - 1);
1213 BasicBlock *CurrBlock = CacheAccess->getBlock();
1214 if (!FollowingBackedge)
1215 doCacheInsert(CacheAccess, ModifyingAccess, Q, Loc);
1216 if (DT->dominates(CurrBlock, OriginalBlock) &&
1217 (CurrBlock != OriginalBlock || !FollowingBackedge ||
1218 MSSA->locallyDominates(CacheAccess, StartingAccess)))
1219 break;
1220 }
1221
1222 // Cache everything else on the way back. The caller should cache
1223 // StartingAccess for us.
1224 for (; N > 1; --N) {
1225 MemoryAccess *CacheAccess = DFI.getPath(N - 1);
1226 doCacheInsert(CacheAccess, ModifyingAccess, Q, Loc);
1227 }
1228 assert(Q.Visited.size() < 1000 && "Visited too much");
1229
1230 return {ModifyingAccess, Loc};
1231 }
1232
1233 /// \brief Walk the use-def chains starting at \p MA and find
1234 /// the MemoryAccess that actually clobbers Loc.
1235 ///
1236 /// \returns our clobbering memory access
getClobberingMemoryAccess(MemoryAccess * StartingAccess,UpwardsMemoryQuery & Q)1237 MemoryAccess *MemorySSA::CachingWalker::getClobberingMemoryAccess(
1238 MemoryAccess *StartingAccess, UpwardsMemoryQuery &Q) {
1239 return UpwardsDFSWalk(StartingAccess, Q.StartingLoc, Q, false).first;
1240 }
1241
getClobberingMemoryAccess(MemoryAccess * StartingAccess,MemoryLocation & Loc)1242 MemoryAccess *MemorySSA::CachingWalker::getClobberingMemoryAccess(
1243 MemoryAccess *StartingAccess, MemoryLocation &Loc) {
1244 if (isa<MemoryPhi>(StartingAccess))
1245 return StartingAccess;
1246
1247 auto *StartingUseOrDef = cast<MemoryUseOrDef>(StartingAccess);
1248 if (MSSA->isLiveOnEntryDef(StartingUseOrDef))
1249 return StartingUseOrDef;
1250
1251 Instruction *I = StartingUseOrDef->getMemoryInst();
1252
1253 // Conservatively, fences are always clobbers, so don't perform the walk if we
1254 // hit a fence.
1255 if (isa<FenceInst>(I))
1256 return StartingUseOrDef;
1257
1258 UpwardsMemoryQuery Q;
1259 Q.OriginalAccess = StartingUseOrDef;
1260 Q.StartingLoc = Loc;
1261 Q.Inst = StartingUseOrDef->getMemoryInst();
1262 Q.IsCall = false;
1263
1264 if (auto CacheResult = doCacheLookup(StartingUseOrDef, Q, Q.StartingLoc))
1265 return CacheResult;
1266
1267 // Unlike the other function, do not walk to the def of a def, because we are
1268 // handed something we already believe is the clobbering access.
1269 MemoryAccess *DefiningAccess = isa<MemoryUse>(StartingUseOrDef)
1270 ? StartingUseOrDef->getDefiningAccess()
1271 : StartingUseOrDef;
1272
1273 MemoryAccess *Clobber = getClobberingMemoryAccess(DefiningAccess, Q);
1274 // Only cache this if it wouldn't make Clobber point to itself.
1275 if (Clobber != StartingAccess)
1276 doCacheInsert(Q.OriginalAccess, Clobber, Q, Q.StartingLoc);
1277 DEBUG(dbgs() << "Starting Memory SSA clobber for " << *I << " is ");
1278 DEBUG(dbgs() << *StartingUseOrDef << "\n");
1279 DEBUG(dbgs() << "Final Memory SSA clobber for " << *I << " is ");
1280 DEBUG(dbgs() << *Clobber << "\n");
1281 return Clobber;
1282 }
1283
1284 MemoryAccess *
getClobberingMemoryAccess(const Instruction * I)1285 MemorySSA::CachingWalker::getClobberingMemoryAccess(const Instruction *I) {
1286 // There should be no way to lookup an instruction and get a phi as the
1287 // access, since we only map BB's to PHI's. So, this must be a use or def.
1288 auto *StartingAccess = cast<MemoryUseOrDef>(MSSA->getMemoryAccess(I));
1289
1290 // We can't sanely do anything with a FenceInst, they conservatively
1291 // clobber all memory, and have no locations to get pointers from to
1292 // try to disambiguate
1293 if (isa<FenceInst>(I))
1294 return StartingAccess;
1295
1296 UpwardsMemoryQuery Q;
1297 Q.OriginalAccess = StartingAccess;
1298 Q.IsCall = bool(ImmutableCallSite(I));
1299 if (!Q.IsCall)
1300 Q.StartingLoc = MemoryLocation::get(I);
1301 Q.Inst = I;
1302 if (auto CacheResult = doCacheLookup(StartingAccess, Q, Q.StartingLoc))
1303 return CacheResult;
1304
1305 // Start with the thing we already think clobbers this location
1306 MemoryAccess *DefiningAccess = StartingAccess->getDefiningAccess();
1307
1308 // At this point, DefiningAccess may be the live on entry def.
1309 // If it is, we will not get a better result.
1310 if (MSSA->isLiveOnEntryDef(DefiningAccess))
1311 return DefiningAccess;
1312
1313 MemoryAccess *Result = getClobberingMemoryAccess(DefiningAccess, Q);
1314 // DFS won't cache a result for DefiningAccess. So, if DefiningAccess isn't
1315 // our clobber, be sure that it gets a cache entry, too.
1316 if (Result != DefiningAccess)
1317 doCacheInsert(DefiningAccess, Result, Q, Q.StartingLoc);
1318 doCacheInsert(Q.OriginalAccess, Result, Q, Q.StartingLoc);
1319 // TODO: When this implementation is more mature, we may want to figure out
1320 // what this additional caching buys us. It's most likely A Good Thing.
1321 if (Q.IsCall)
1322 for (const MemoryAccess *MA : Q.VisitedCalls)
1323 if (MA != Result)
1324 doCacheInsert(MA, Result, Q, Q.StartingLoc);
1325
1326 DEBUG(dbgs() << "Starting Memory SSA clobber for " << *I << " is ");
1327 DEBUG(dbgs() << *DefiningAccess << "\n");
1328 DEBUG(dbgs() << "Final Memory SSA clobber for " << *I << " is ");
1329 DEBUG(dbgs() << *Result << "\n");
1330
1331 return Result;
1332 }
1333
1334 // Verify that MA doesn't exist in any of the caches.
verifyRemoved(MemoryAccess * MA)1335 void MemorySSA::CachingWalker::verifyRemoved(MemoryAccess *MA) {
1336 #ifndef NDEBUG
1337 for (auto &P : CachedUpwardsClobberingAccess)
1338 assert(P.first.first != MA && P.second != MA &&
1339 "Found removed MemoryAccess in cache.");
1340 for (auto &P : CachedUpwardsClobberingCall)
1341 assert(P.first != MA && P.second != MA &&
1342 "Found removed MemoryAccess in cache.");
1343 #endif // !NDEBUG
1344 }
1345
1346 MemoryAccess *
getClobberingMemoryAccess(const Instruction * I)1347 DoNothingMemorySSAWalker::getClobberingMemoryAccess(const Instruction *I) {
1348 MemoryAccess *MA = MSSA->getMemoryAccess(I);
1349 if (auto *Use = dyn_cast<MemoryUseOrDef>(MA))
1350 return Use->getDefiningAccess();
1351 return MA;
1352 }
1353
getClobberingMemoryAccess(MemoryAccess * StartingAccess,MemoryLocation &)1354 MemoryAccess *DoNothingMemorySSAWalker::getClobberingMemoryAccess(
1355 MemoryAccess *StartingAccess, MemoryLocation &) {
1356 if (auto *Use = dyn_cast<MemoryUseOrDef>(StartingAccess))
1357 return Use->getDefiningAccess();
1358 return StartingAccess;
1359 }
1360 }
1361