1b417d464SFiona Glaser //===--------- LoopSimplifyCFG.cpp - Loop CFG Simplification Pass ---------===//
2b417d464SFiona Glaser //
32946cd70SChandler Carruth // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
42946cd70SChandler Carruth // See https://llvm.org/LICENSE.txt for license information.
52946cd70SChandler Carruth // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6b417d464SFiona Glaser //
7b417d464SFiona Glaser //===----------------------------------------------------------------------===//
8b417d464SFiona Glaser //
9b417d464SFiona Glaser // This file implements the Loop SimplifyCFG Pass. This pass is responsible for
10b417d464SFiona Glaser // basic loop CFG cleanup, primarily to assist other loop passes. If you
11b417d464SFiona Glaser // encounter a noncanonical CFG construct that causes another loop pass to
12b417d464SFiona Glaser // perform suboptimally, this is the place to fix it up.
13b417d464SFiona Glaser //
14b417d464SFiona Glaser //===----------------------------------------------------------------------===//
15b417d464SFiona Glaser
16ab6a513bSJustin Bogner #include "llvm/Transforms/Scalar/LoopSimplifyCFG.h"
17b417d464SFiona Glaser #include "llvm/ADT/SmallVector.h"
18b417d464SFiona Glaser #include "llvm/ADT/Statistic.h"
19b417d464SFiona Glaser #include "llvm/Analysis/DependenceAnalysis.h"
205f436fc5SRichard Trieu #include "llvm/Analysis/DomTreeUpdater.h"
21b417d464SFiona Glaser #include "llvm/Analysis/LoopInfo.h"
2244d86982SSimon Pilgrim #include "llvm/Analysis/LoopIterator.h"
23b417d464SFiona Glaser #include "llvm/Analysis/LoopPass.h"
248b83d685SAlina Sbirlea #include "llvm/Analysis/MemorySSA.h"
258b83d685SAlina Sbirlea #include "llvm/Analysis/MemorySSAUpdater.h"
26b417d464SFiona Glaser #include "llvm/Analysis/ScalarEvolution.h"
27b417d464SFiona Glaser #include "llvm/IR/Dominators.h"
281055e9e3SNikita Popov #include "llvm/IR/IRBuilder.h"
2905da2fe5SReid Kleckner #include "llvm/InitializePasses.h"
304c1a1d3cSReid Kleckner #include "llvm/Support/CommandLine.h"
31ab6a513bSJustin Bogner #include "llvm/Transforms/Scalar.h"
323bab7e1aSChandler Carruth #include "llvm/Transforms/Scalar/LoopPassManager.h"
33dfd14adeSAlina Sbirlea #include "llvm/Transforms/Utils/BasicBlockUtils.h"
3431088a9dSChandler Carruth #include "llvm/Transforms/Utils/LoopUtils.h"
35b417d464SFiona Glaser using namespace llvm;
36b417d464SFiona Glaser
37b417d464SFiona Glaser #define DEBUG_TYPE "loop-simplifycfg"
38b417d464SFiona Glaser
39e1c2dc27SMax Kazantsev static cl::opt<bool> EnableTermFolding("enable-loop-simplifycfg-term-folding",
405cf777e4SMax Kazantsev cl::init(true));
41e1c2dc27SMax Kazantsev
42c04b5307SMax Kazantsev STATISTIC(NumTerminatorsFolded,
43c04b5307SMax Kazantsev "Number of terminators folded to unconditional branches");
44347c5837SMax Kazantsev STATISTIC(NumLoopBlocksDeleted,
45347c5837SMax Kazantsev "Number of loop blocks deleted");
46edabb9aeSMax Kazantsev STATISTIC(NumLoopExitsDeleted,
47edabb9aeSMax Kazantsev "Number of loop exiting edges deleted");
48c04b5307SMax Kazantsev
49c04b5307SMax Kazantsev /// If \p BB is a switch or a conditional branch, but only one of its successors
50c04b5307SMax Kazantsev /// can be reached from this block in runtime, return this successor. Otherwise,
51c04b5307SMax Kazantsev /// return nullptr.
getOnlyLiveSuccessor(BasicBlock * BB)52c04b5307SMax Kazantsev static BasicBlock *getOnlyLiveSuccessor(BasicBlock *BB) {
53c04b5307SMax Kazantsev Instruction *TI = BB->getTerminator();
54c04b5307SMax Kazantsev if (BranchInst *BI = dyn_cast<BranchInst>(TI)) {
55c04b5307SMax Kazantsev if (BI->isUnconditional())
56c04b5307SMax Kazantsev return nullptr;
57c04b5307SMax Kazantsev if (BI->getSuccessor(0) == BI->getSuccessor(1))
58c04b5307SMax Kazantsev return BI->getSuccessor(0);
59c04b5307SMax Kazantsev ConstantInt *Cond = dyn_cast<ConstantInt>(BI->getCondition());
60c04b5307SMax Kazantsev if (!Cond)
61c04b5307SMax Kazantsev return nullptr;
62c04b5307SMax Kazantsev return Cond->isZero() ? BI->getSuccessor(1) : BI->getSuccessor(0);
63c04b5307SMax Kazantsev }
64c04b5307SMax Kazantsev
65c04b5307SMax Kazantsev if (SwitchInst *SI = dyn_cast<SwitchInst>(TI)) {
66c04b5307SMax Kazantsev auto *CI = dyn_cast<ConstantInt>(SI->getCondition());
67c04b5307SMax Kazantsev if (!CI)
68c04b5307SMax Kazantsev return nullptr;
69c04b5307SMax Kazantsev for (auto Case : SI->cases())
70c04b5307SMax Kazantsev if (Case.getCaseValue() == CI)
71c04b5307SMax Kazantsev return Case.getCaseSuccessor();
72c04b5307SMax Kazantsev return SI->getDefaultDest();
73c04b5307SMax Kazantsev }
74c04b5307SMax Kazantsev
75c04b5307SMax Kazantsev return nullptr;
76c04b5307SMax Kazantsev }
77c04b5307SMax Kazantsev
78c065b025SMax Kazantsev /// Removes \p BB from all loops from [FirstLoop, LastLoop) in parent chain.
removeBlockFromLoops(BasicBlock * BB,Loop * FirstLoop,Loop * LastLoop=nullptr)79c065b025SMax Kazantsev static void removeBlockFromLoops(BasicBlock *BB, Loop *FirstLoop,
80c065b025SMax Kazantsev Loop *LastLoop = nullptr) {
81c065b025SMax Kazantsev assert((!LastLoop || LastLoop->contains(FirstLoop->getHeader())) &&
82c065b025SMax Kazantsev "First loop is supposed to be inside of last loop!");
83c065b025SMax Kazantsev assert(FirstLoop->contains(BB) && "Must be a loop block!");
84c065b025SMax Kazantsev for (Loop *Current = FirstLoop; Current != LastLoop;
85c065b025SMax Kazantsev Current = Current->getParentLoop())
86c065b025SMax Kazantsev Current->removeBlockFromLoop(BB);
87c065b025SMax Kazantsev }
88c065b025SMax Kazantsev
89d72c1a0cSMax Kazantsev /// Find innermost loop that contains at least one block from \p BBs and
90d72c1a0cSMax Kazantsev /// contains the header of loop \p L.
getInnermostLoopFor(SmallPtrSetImpl<BasicBlock * > & BBs,Loop & L,LoopInfo & LI)91d72c1a0cSMax Kazantsev static Loop *getInnermostLoopFor(SmallPtrSetImpl<BasicBlock *> &BBs,
920f943269SMax Kazantsev Loop &L, LoopInfo &LI) {
934561475eSMax Kazantsev Loop *Innermost = nullptr;
940f943269SMax Kazantsev for (BasicBlock *BB : BBs) {
950f943269SMax Kazantsev Loop *BBL = LI.getLoopFor(BB);
964561475eSMax Kazantsev while (BBL && !BBL->contains(L.getHeader()))
974561475eSMax Kazantsev BBL = BBL->getParentLoop();
984561475eSMax Kazantsev if (BBL == &L)
994561475eSMax Kazantsev BBL = BBL->getParentLoop();
1004561475eSMax Kazantsev if (!BBL)
1014561475eSMax Kazantsev continue;
1024561475eSMax Kazantsev if (!Innermost || BBL->getLoopDepth() > Innermost->getLoopDepth())
1034561475eSMax Kazantsev Innermost = BBL;
1040f943269SMax Kazantsev }
1054561475eSMax Kazantsev return Innermost;
1060f943269SMax Kazantsev }
1070f943269SMax Kazantsev
108b17d2136SBenjamin Kramer namespace {
109c04b5307SMax Kazantsev /// Helper class that can turn branches and switches with constant conditions
110c04b5307SMax Kazantsev /// into unconditional branches.
111c04b5307SMax Kazantsev class ConstantTerminatorFoldingImpl {
112c04b5307SMax Kazantsev private:
113c04b5307SMax Kazantsev Loop &L;
114c04b5307SMax Kazantsev LoopInfo &LI;
115c04b5307SMax Kazantsev DominatorTree &DT;
116201534d7SMax Kazantsev ScalarEvolution &SE;
1179cf417dbSMax Kazantsev MemorySSAUpdater *MSSAU;
118136f09beSMax Kazantsev LoopBlocksDFS DFS;
119623c38d6SSimon Pilgrim DomTreeUpdater DTU;
1206b63d3a2SMax Kazantsev SmallVector<DominatorTree::UpdateType, 16> DTUpdates;
121c04b5307SMax Kazantsev
122a523a211SMax Kazantsev // Whether or not the current loop has irreducible CFG.
123a523a211SMax Kazantsev bool HasIrreducibleCFG = false;
124c04b5307SMax Kazantsev // Whether or not the current loop will still exist after terminator constant
125c04b5307SMax Kazantsev // folding will be done. In theory, there are two ways how it can happen:
126c04b5307SMax Kazantsev // 1. Loop's latch(es) become unreachable from loop header;
127c04b5307SMax Kazantsev // 2. Loop's header becomes unreachable from method entry.
128c04b5307SMax Kazantsev // In practice, the second situation is impossible because we only modify the
129c04b5307SMax Kazantsev // current loop and its preheader and do not affect preheader's reachibility
130c04b5307SMax Kazantsev // from any other block. So this variable set to true means that loop's latch
131c04b5307SMax Kazantsev // has become unreachable from loop header.
132c04b5307SMax Kazantsev bool DeleteCurrentLoop = false;
133c04b5307SMax Kazantsev
134c04b5307SMax Kazantsev // The blocks of the original loop that will still be reachable from entry
135c04b5307SMax Kazantsev // after the constant folding.
136c04b5307SMax Kazantsev SmallPtrSet<BasicBlock *, 8> LiveLoopBlocks;
137c04b5307SMax Kazantsev // The blocks of the original loop that will become unreachable from entry
138c04b5307SMax Kazantsev // after the constant folding.
13980e4b40fSMax Kazantsev SmallVector<BasicBlock *, 8> DeadLoopBlocks;
140c04b5307SMax Kazantsev // The exits of the original loop that will still be reachable from entry
141c04b5307SMax Kazantsev // after the constant folding.
142c04b5307SMax Kazantsev SmallPtrSet<BasicBlock *, 8> LiveExitBlocks;
143c04b5307SMax Kazantsev // The exits of the original loop that will become unreachable from entry
144c04b5307SMax Kazantsev // after the constant folding.
14556a24430SMax Kazantsev SmallVector<BasicBlock *, 8> DeadExitBlocks;
146c04b5307SMax Kazantsev // The blocks that will still be a part of the current loop after folding.
147c04b5307SMax Kazantsev SmallPtrSet<BasicBlock *, 8> BlocksInLoopAfterFolding;
148c04b5307SMax Kazantsev // The blocks that have terminators with constant condition that can be
149c04b5307SMax Kazantsev // folded. Note: fold candidates should be in L but not in any of its
150c04b5307SMax Kazantsev // subloops to avoid complex LI updates.
151c04b5307SMax Kazantsev SmallVector<BasicBlock *, 8> FoldCandidates;
152c04b5307SMax Kazantsev
dump() const153c04b5307SMax Kazantsev void dump() const {
154c04b5307SMax Kazantsev dbgs() << "Constant terminator folding for loop " << L << "\n";
155c04b5307SMax Kazantsev dbgs() << "After terminator constant-folding, the loop will";
156c04b5307SMax Kazantsev if (!DeleteCurrentLoop)
157c04b5307SMax Kazantsev dbgs() << " not";
158c04b5307SMax Kazantsev dbgs() << " be destroyed\n";
15956a24430SMax Kazantsev auto PrintOutVector = [&](const char *Message,
16056a24430SMax Kazantsev const SmallVectorImpl<BasicBlock *> &S) {
16156a24430SMax Kazantsev dbgs() << Message << "\n";
16256a24430SMax Kazantsev for (const BasicBlock *BB : S)
163c04b5307SMax Kazantsev dbgs() << "\t" << BB->getName() << "\n";
16456a24430SMax Kazantsev };
165c04b5307SMax Kazantsev auto PrintOutSet = [&](const char *Message,
166c04b5307SMax Kazantsev const SmallPtrSetImpl<BasicBlock *> &S) {
167c04b5307SMax Kazantsev dbgs() << Message << "\n";
168c04b5307SMax Kazantsev for (const BasicBlock *BB : S)
169c04b5307SMax Kazantsev dbgs() << "\t" << BB->getName() << "\n";
170c04b5307SMax Kazantsev };
17156a24430SMax Kazantsev PrintOutVector("Blocks in which we can constant-fold terminator:",
17256a24430SMax Kazantsev FoldCandidates);
173c04b5307SMax Kazantsev PrintOutSet("Live blocks from the original loop:", LiveLoopBlocks);
17480e4b40fSMax Kazantsev PrintOutVector("Dead blocks from the original loop:", DeadLoopBlocks);
175c04b5307SMax Kazantsev PrintOutSet("Live exit blocks:", LiveExitBlocks);
17656a24430SMax Kazantsev PrintOutVector("Dead exit blocks:", DeadExitBlocks);
177c04b5307SMax Kazantsev if (!DeleteCurrentLoop)
178c04b5307SMax Kazantsev PrintOutSet("The following blocks will still be part of the loop:",
179c04b5307SMax Kazantsev BlocksInLoopAfterFolding);
180c04b5307SMax Kazantsev }
181c04b5307SMax Kazantsev
182a523a211SMax Kazantsev /// Whether or not the current loop has irreducible CFG.
hasIrreducibleCFG(LoopBlocksDFS & DFS)183a523a211SMax Kazantsev bool hasIrreducibleCFG(LoopBlocksDFS &DFS) {
184a523a211SMax Kazantsev assert(DFS.isComplete() && "DFS is expected to be finished");
185a523a211SMax Kazantsev // Index of a basic block in RPO traversal.
186a523a211SMax Kazantsev DenseMap<const BasicBlock *, unsigned> RPO;
187a523a211SMax Kazantsev unsigned Current = 0;
188a523a211SMax Kazantsev for (auto I = DFS.beginRPO(), E = DFS.endRPO(); I != E; ++I)
189a523a211SMax Kazantsev RPO[*I] = Current++;
190a523a211SMax Kazantsev
191a523a211SMax Kazantsev for (auto I = DFS.beginRPO(), E = DFS.endRPO(); I != E; ++I) {
192a523a211SMax Kazantsev BasicBlock *BB = *I;
193a523a211SMax Kazantsev for (auto *Succ : successors(BB))
194a523a211SMax Kazantsev if (L.contains(Succ) && !LI.isLoopHeader(Succ) && RPO[BB] > RPO[Succ])
195a523a211SMax Kazantsev // If an edge goes from a block with greater order number into a block
196a523a211SMax Kazantsev // with lesses number, and it is not a loop backedge, then it can only
197a523a211SMax Kazantsev // be a part of irreducible non-loop cycle.
198a523a211SMax Kazantsev return true;
199a523a211SMax Kazantsev }
200a523a211SMax Kazantsev return false;
201a523a211SMax Kazantsev }
202a523a211SMax Kazantsev
203c04b5307SMax Kazantsev /// Fill all information about status of blocks and exits of the current loop
204c04b5307SMax Kazantsev /// if constant folding of all branches will be done.
analyze()205c04b5307SMax Kazantsev void analyze() {
206c04b5307SMax Kazantsev DFS.perform(&LI);
207c04b5307SMax Kazantsev assert(DFS.isComplete() && "DFS is expected to be finished");
208c04b5307SMax Kazantsev
209a523a211SMax Kazantsev // TODO: The algorithm below relies on both RPO and Postorder traversals.
210a523a211SMax Kazantsev // When the loop has only reducible CFG inside, then the invariant "all
211a523a211SMax Kazantsev // predecessors of X are processed before X in RPO" is preserved. However
212a523a211SMax Kazantsev // an irreducible loop can break this invariant (e.g. latch does not have to
213a523a211SMax Kazantsev // be the last block in the traversal in this case, and the algorithm relies
214a523a211SMax Kazantsev // on this). We can later decide to support such cases by altering the
215a523a211SMax Kazantsev // algorithms, but so far we just give up analyzing them.
216a523a211SMax Kazantsev if (hasIrreducibleCFG(DFS)) {
217a523a211SMax Kazantsev HasIrreducibleCFG = true;
218a523a211SMax Kazantsev return;
219a523a211SMax Kazantsev }
220a523a211SMax Kazantsev
221c04b5307SMax Kazantsev // Collect live and dead loop blocks and exits.
222c04b5307SMax Kazantsev LiveLoopBlocks.insert(L.getHeader());
223c04b5307SMax Kazantsev for (auto I = DFS.beginRPO(), E = DFS.endRPO(); I != E; ++I) {
224c04b5307SMax Kazantsev BasicBlock *BB = *I;
225c04b5307SMax Kazantsev
226c04b5307SMax Kazantsev // If a loop block wasn't marked as live so far, then it's dead.
227c04b5307SMax Kazantsev if (!LiveLoopBlocks.count(BB)) {
22880e4b40fSMax Kazantsev DeadLoopBlocks.push_back(BB);
229c04b5307SMax Kazantsev continue;
230c04b5307SMax Kazantsev }
231c04b5307SMax Kazantsev
232c04b5307SMax Kazantsev BasicBlock *TheOnlySucc = getOnlyLiveSuccessor(BB);
233c04b5307SMax Kazantsev
234c04b5307SMax Kazantsev // If a block has only one live successor, it's a candidate on constant
235c04b5307SMax Kazantsev // folding. Only handle blocks from current loop: branches in child loops
236c04b5307SMax Kazantsev // are skipped because if they can be folded, they should be folded during
237c04b5307SMax Kazantsev // the processing of child loops.
23856515a2cSMax Kazantsev bool TakeFoldCandidate = TheOnlySucc && LI.getLoopFor(BB) == &L;
23956515a2cSMax Kazantsev if (TakeFoldCandidate)
240c04b5307SMax Kazantsev FoldCandidates.push_back(BB);
241c04b5307SMax Kazantsev
242c04b5307SMax Kazantsev // Handle successors.
243c04b5307SMax Kazantsev for (BasicBlock *Succ : successors(BB))
24456515a2cSMax Kazantsev if (!TakeFoldCandidate || TheOnlySucc == Succ) {
245d9f59f8cSMax Kazantsev if (L.contains(Succ))
246d9f59f8cSMax Kazantsev LiveLoopBlocks.insert(Succ);
247d9f59f8cSMax Kazantsev else
248d9f59f8cSMax Kazantsev LiveExitBlocks.insert(Succ);
249d9f59f8cSMax Kazantsev }
250c04b5307SMax Kazantsev }
251c04b5307SMax Kazantsev
2520d3add21SZarko Todorovski // Amount of dead and live loop blocks should match the total number of
2530d3add21SZarko Todorovski // blocks in loop.
254c04b5307SMax Kazantsev assert(L.getNumBlocks() == LiveLoopBlocks.size() + DeadLoopBlocks.size() &&
255c04b5307SMax Kazantsev "Malformed block sets?");
256c04b5307SMax Kazantsev
2574a699ae9SFlorian Hahn // Now, all exit blocks that are not marked as live are dead, if all their
2584a699ae9SFlorian Hahn // predecessors are in the loop. This may not be the case, as the input loop
2594a699ae9SFlorian Hahn // may not by in loop-simplify/canonical form.
260d9f59f8cSMax Kazantsev SmallVector<BasicBlock *, 8> ExitBlocks;
261d9f59f8cSMax Kazantsev L.getExitBlocks(ExitBlocks);
262a4ccfc18SMax Kazantsev SmallPtrSet<BasicBlock *, 8> UniqueDeadExits;
263c04b5307SMax Kazantsev for (auto *ExitBlock : ExitBlocks)
264a4ccfc18SMax Kazantsev if (!LiveExitBlocks.count(ExitBlock) &&
2654a699ae9SFlorian Hahn UniqueDeadExits.insert(ExitBlock).second &&
2664a699ae9SFlorian Hahn all_of(predecessors(ExitBlock),
2674a699ae9SFlorian Hahn [this](BasicBlock *Pred) { return L.contains(Pred); }))
26856a24430SMax Kazantsev DeadExitBlocks.push_back(ExitBlock);
269c04b5307SMax Kazantsev
270c04b5307SMax Kazantsev // Whether or not the edge From->To will still be present in graph after the
271c04b5307SMax Kazantsev // folding.
272c04b5307SMax Kazantsev auto IsEdgeLive = [&](BasicBlock *From, BasicBlock *To) {
273c04b5307SMax Kazantsev if (!LiveLoopBlocks.count(From))
274c04b5307SMax Kazantsev return false;
275c04b5307SMax Kazantsev BasicBlock *TheOnlySucc = getOnlyLiveSuccessor(From);
27638cd9acbSMax Kazantsev return !TheOnlySucc || TheOnlySucc == To || LI.getLoopFor(From) != &L;
277c04b5307SMax Kazantsev };
278c04b5307SMax Kazantsev
279c04b5307SMax Kazantsev // The loop will not be destroyed if its latch is live.
280c04b5307SMax Kazantsev DeleteCurrentLoop = !IsEdgeLive(L.getLoopLatch(), L.getHeader());
281c04b5307SMax Kazantsev
282c04b5307SMax Kazantsev // If we are going to delete the current loop completely, no extra analysis
283c04b5307SMax Kazantsev // is needed.
284c04b5307SMax Kazantsev if (DeleteCurrentLoop)
285c04b5307SMax Kazantsev return;
286c04b5307SMax Kazantsev
287c04b5307SMax Kazantsev // Otherwise, we should check which blocks will still be a part of the
288c04b5307SMax Kazantsev // current loop after the transform.
289c04b5307SMax Kazantsev BlocksInLoopAfterFolding.insert(L.getLoopLatch());
290c04b5307SMax Kazantsev // If the loop is live, then we should compute what blocks are still in
291c04b5307SMax Kazantsev // loop after all branch folding has been done. A block is in loop if
292c04b5307SMax Kazantsev // it has a live edge to another block that is in the loop; by definition,
293c04b5307SMax Kazantsev // latch is in the loop.
294c04b5307SMax Kazantsev auto BlockIsInLoop = [&](BasicBlock *BB) {
295c04b5307SMax Kazantsev return any_of(successors(BB), [&](BasicBlock *Succ) {
296c04b5307SMax Kazantsev return BlocksInLoopAfterFolding.count(Succ) && IsEdgeLive(BB, Succ);
297c04b5307SMax Kazantsev });
298c04b5307SMax Kazantsev };
299c04b5307SMax Kazantsev for (auto I = DFS.beginPostorder(), E = DFS.endPostorder(); I != E; ++I) {
300c04b5307SMax Kazantsev BasicBlock *BB = *I;
301c04b5307SMax Kazantsev if (BlockIsInLoop(BB))
302c04b5307SMax Kazantsev BlocksInLoopAfterFolding.insert(BB);
303c04b5307SMax Kazantsev }
304c04b5307SMax Kazantsev
305c04b5307SMax Kazantsev assert(BlocksInLoopAfterFolding.count(L.getHeader()) &&
306c04b5307SMax Kazantsev "Header not in loop?");
307b565e609SMax Kazantsev assert(BlocksInLoopAfterFolding.size() <= LiveLoopBlocks.size() &&
308b565e609SMax Kazantsev "All blocks that stay in loop should be live!");
309c04b5307SMax Kazantsev }
310c04b5307SMax Kazantsev
311edabb9aeSMax Kazantsev /// We need to preserve static reachibility of all loop exit blocks (this is)
312edabb9aeSMax Kazantsev /// required by loop pass manager. In order to do it, we make the following
313edabb9aeSMax Kazantsev /// trick:
314edabb9aeSMax Kazantsev ///
315edabb9aeSMax Kazantsev /// preheader:
316edabb9aeSMax Kazantsev /// <preheader code>
317edabb9aeSMax Kazantsev /// br label %loop_header
318edabb9aeSMax Kazantsev ///
319edabb9aeSMax Kazantsev /// loop_header:
320edabb9aeSMax Kazantsev /// ...
321edabb9aeSMax Kazantsev /// br i1 false, label %dead_exit, label %loop_block
322edabb9aeSMax Kazantsev /// ...
323edabb9aeSMax Kazantsev ///
324edabb9aeSMax Kazantsev /// We cannot simply remove edge from the loop to dead exit because in this
325edabb9aeSMax Kazantsev /// case dead_exit (and its successors) may become unreachable. To avoid that,
326edabb9aeSMax Kazantsev /// we insert the following fictive preheader:
327edabb9aeSMax Kazantsev ///
328edabb9aeSMax Kazantsev /// preheader:
329edabb9aeSMax Kazantsev /// <preheader code>
330edabb9aeSMax Kazantsev /// switch i32 0, label %preheader-split,
331edabb9aeSMax Kazantsev /// [i32 1, label %dead_exit_1],
332edabb9aeSMax Kazantsev /// [i32 2, label %dead_exit_2],
333edabb9aeSMax Kazantsev /// ...
334edabb9aeSMax Kazantsev /// [i32 N, label %dead_exit_N],
335edabb9aeSMax Kazantsev ///
336edabb9aeSMax Kazantsev /// preheader-split:
337edabb9aeSMax Kazantsev /// br label %loop_header
338edabb9aeSMax Kazantsev ///
339edabb9aeSMax Kazantsev /// loop_header:
340edabb9aeSMax Kazantsev /// ...
341edabb9aeSMax Kazantsev /// br i1 false, label %dead_exit_N, label %loop_block
342edabb9aeSMax Kazantsev /// ...
343edabb9aeSMax Kazantsev ///
344edabb9aeSMax Kazantsev /// Doing so, we preserve static reachibility of all dead exits and can later
345edabb9aeSMax Kazantsev /// remove edges from the loop to these blocks.
handleDeadExits()346edabb9aeSMax Kazantsev void handleDeadExits() {
347edabb9aeSMax Kazantsev // If no dead exits, nothing to do.
348edabb9aeSMax Kazantsev if (DeadExitBlocks.empty())
349edabb9aeSMax Kazantsev return;
350edabb9aeSMax Kazantsev
351edabb9aeSMax Kazantsev // Construct split preheader and the dummy switch to thread edges from it to
352edabb9aeSMax Kazantsev // dead exits.
353edabb9aeSMax Kazantsev BasicBlock *Preheader = L.getLoopPreheader();
354d2d32443SAlina Sbirlea BasicBlock *NewPreheader = llvm::SplitBlock(
355d2d32443SAlina Sbirlea Preheader, Preheader->getTerminator(), &DT, &LI, MSSAU);
356d2d32443SAlina Sbirlea
357edabb9aeSMax Kazantsev IRBuilder<> Builder(Preheader->getTerminator());
358edabb9aeSMax Kazantsev SwitchInst *DummySwitch =
359edabb9aeSMax Kazantsev Builder.CreateSwitch(Builder.getInt32(0), NewPreheader);
360edabb9aeSMax Kazantsev Preheader->getTerminator()->eraseFromParent();
361edabb9aeSMax Kazantsev
362edabb9aeSMax Kazantsev unsigned DummyIdx = 1;
363edabb9aeSMax Kazantsev for (BasicBlock *BB : DeadExitBlocks) {
3645d6cd619SYevgeny Rouban // Eliminate all Phis and LandingPads from dead exits.
3655d6cd619SYevgeny Rouban // TODO: Consider removing all instructions in this dead block.
3665d6cd619SYevgeny Rouban SmallVector<Instruction *, 4> DeadInstructions;
367edabb9aeSMax Kazantsev for (auto &PN : BB->phis())
3685d6cd619SYevgeny Rouban DeadInstructions.push_back(&PN);
369edabb9aeSMax Kazantsev
3705d6cd619SYevgeny Rouban if (auto *LandingPad = dyn_cast<LandingPadInst>(BB->getFirstNonPHI()))
3715d6cd619SYevgeny Rouban DeadInstructions.emplace_back(LandingPad);
3725d6cd619SYevgeny Rouban
3735d6cd619SYevgeny Rouban for (Instruction *I : DeadInstructions) {
3743fa2411dSNuno Lopes I->replaceAllUsesWith(PoisonValue::get(I->getType()));
3755d6cd619SYevgeny Rouban I->eraseFromParent();
376edabb9aeSMax Kazantsev }
3775d6cd619SYevgeny Rouban
378edabb9aeSMax Kazantsev assert(DummyIdx != 0 && "Too many dead exits!");
379edabb9aeSMax Kazantsev DummySwitch->addCase(Builder.getInt32(DummyIdx++), BB);
3806b63d3a2SMax Kazantsev DTUpdates.push_back({DominatorTree::Insert, Preheader, BB});
381edabb9aeSMax Kazantsev ++NumLoopExitsDeleted;
382edabb9aeSMax Kazantsev }
383edabb9aeSMax Kazantsev
384edabb9aeSMax Kazantsev assert(L.getLoopPreheader() == NewPreheader && "Malformed CFG?");
385edabb9aeSMax Kazantsev if (Loop *OuterLoop = LI.getLoopFor(Preheader)) {
386edabb9aeSMax Kazantsev // When we break dead edges, the outer loop may become unreachable from
387edabb9aeSMax Kazantsev // the current loop. We need to fix loop info accordingly. For this, we
388edabb9aeSMax Kazantsev // find the most nested loop that still contains L and remove L from all
389edabb9aeSMax Kazantsev // loops that are inside of it.
390d72c1a0cSMax Kazantsev Loop *StillReachable = getInnermostLoopFor(LiveExitBlocks, L, LI);
391edabb9aeSMax Kazantsev
392edabb9aeSMax Kazantsev // Okay, our loop is no longer in the outer loop (and maybe not in some of
393edabb9aeSMax Kazantsev // its parents as well). Make the fixup.
394edabb9aeSMax Kazantsev if (StillReachable != OuterLoop) {
395edabb9aeSMax Kazantsev LI.changeLoopFor(NewPreheader, StillReachable);
396c065b025SMax Kazantsev removeBlockFromLoops(NewPreheader, OuterLoop, StillReachable);
397edabb9aeSMax Kazantsev for (auto *BB : L.blocks())
398c065b025SMax Kazantsev removeBlockFromLoops(BB, OuterLoop, StillReachable);
399edabb9aeSMax Kazantsev OuterLoop->removeChildLoop(&L);
400edabb9aeSMax Kazantsev if (StillReachable)
401edabb9aeSMax Kazantsev StillReachable->addChildLoop(&L);
402edabb9aeSMax Kazantsev else
403edabb9aeSMax Kazantsev LI.addTopLevelLoop(&L);
40461a8d3fbSMax Kazantsev
40561a8d3fbSMax Kazantsev // Some values from loops in [OuterLoop, StillReachable) could be used
40661a8d3fbSMax Kazantsev // in the current loop. Now it is not their child anymore, so such uses
40761a8d3fbSMax Kazantsev // require LCSSA Phis.
40861a8d3fbSMax Kazantsev Loop *FixLCSSALoop = OuterLoop;
40961a8d3fbSMax Kazantsev while (FixLCSSALoop->getParentLoop() != StillReachable)
41061a8d3fbSMax Kazantsev FixLCSSALoop = FixLCSSALoop->getParentLoop();
41161a8d3fbSMax Kazantsev assert(FixLCSSALoop && "Should be a loop!");
4126b63d3a2SMax Kazantsev // We need all DT updates to be done before forming LCSSA.
413d2d32443SAlina Sbirlea if (MSSAU)
41463aeaf75SAlina Sbirlea MSSAU->applyUpdates(DTUpdates, DT, /*UpdateDT=*/true);
41563aeaf75SAlina Sbirlea else
41663aeaf75SAlina Sbirlea DTU.applyUpdates(DTUpdates);
4176b63d3a2SMax Kazantsev DTUpdates.clear();
41861a8d3fbSMax Kazantsev formLCSSARecursively(*FixLCSSALoop, DT, &LI, &SE);
419edabb9aeSMax Kazantsev }
420edabb9aeSMax Kazantsev }
421d2d32443SAlina Sbirlea
422d2d32443SAlina Sbirlea if (MSSAU) {
423d2d32443SAlina Sbirlea // Clear all updates now. Facilitates deletes that follow.
42463aeaf75SAlina Sbirlea MSSAU->applyUpdates(DTUpdates, DT, /*UpdateDT=*/true);
425d2d32443SAlina Sbirlea DTUpdates.clear();
426d2d32443SAlina Sbirlea if (VerifyMemorySSA)
427d2d32443SAlina Sbirlea MSSAU->getMemorySSA()->verifyMemorySSA();
428d2d32443SAlina Sbirlea }
429edabb9aeSMax Kazantsev }
430edabb9aeSMax Kazantsev
431347c5837SMax Kazantsev /// Delete loop blocks that have become unreachable after folding. Make all
432347c5837SMax Kazantsev /// relevant updates to DT and LI.
deleteDeadLoopBlocks()433347c5837SMax Kazantsev void deleteDeadLoopBlocks() {
43480e4b40fSMax Kazantsev if (MSSAU) {
435db101864SAlina Sbirlea SmallSetVector<BasicBlock *, 8> DeadLoopBlocksSet(DeadLoopBlocks.begin(),
43680e4b40fSMax Kazantsev DeadLoopBlocks.end());
43780e4b40fSMax Kazantsev MSSAU->removeBlocks(DeadLoopBlocksSet);
43880e4b40fSMax Kazantsev }
439bf6af8fbSMax Kazantsev
440bf6af8fbSMax Kazantsev // The function LI.erase has some invariants that need to be preserved when
441bf6af8fbSMax Kazantsev // it tries to remove a loop which is not the top-level loop. In particular,
442bf6af8fbSMax Kazantsev // it requires loop's preheader to be strictly in loop's parent. We cannot
443bf6af8fbSMax Kazantsev // just remove blocks one by one, because after removal of preheader we may
444bf6af8fbSMax Kazantsev // break this invariant for the dead loop. So we detatch and erase all dead
445bf6af8fbSMax Kazantsev // loops beforehand.
446bf6af8fbSMax Kazantsev for (auto *BB : DeadLoopBlocks)
447bf6af8fbSMax Kazantsev if (LI.isLoopHeader(BB)) {
448bf6af8fbSMax Kazantsev assert(LI.getLoopFor(BB) != &L && "Attempt to remove current loop!");
449bf6af8fbSMax Kazantsev Loop *DL = LI.getLoopFor(BB);
45089c1e35fSStefanos Baziotis if (!DL->isOutermost()) {
451bf6af8fbSMax Kazantsev for (auto *PL = DL->getParentLoop(); PL; PL = PL->getParentLoop())
452bf6af8fbSMax Kazantsev for (auto *BB : DL->getBlocks())
453bf6af8fbSMax Kazantsev PL->removeBlockFromLoop(BB);
454bf6af8fbSMax Kazantsev DL->getParentLoop()->removeChildLoop(DL);
455bf6af8fbSMax Kazantsev LI.addTopLevelLoop(DL);
456bf6af8fbSMax Kazantsev }
457bf6af8fbSMax Kazantsev LI.erase(DL);
458bf6af8fbSMax Kazantsev }
459bf6af8fbSMax Kazantsev
460347c5837SMax Kazantsev for (auto *BB : DeadLoopBlocks) {
461347c5837SMax Kazantsev assert(BB != L.getHeader() &&
462347c5837SMax Kazantsev "Header of the current loop cannot be dead!");
463347c5837SMax Kazantsev LLVM_DEBUG(dbgs() << "Deleting dead loop block " << BB->getName()
464347c5837SMax Kazantsev << "\n");
465347c5837SMax Kazantsev LI.removeBlock(BB);
466347c5837SMax Kazantsev }
4678b134169SMax Kazantsev
468cf0357a5SNikita Popov detachDeadBlocks(DeadLoopBlocks, &DTUpdates, /*KeepOneInputPHIs*/true);
4696b63d3a2SMax Kazantsev DTU.applyUpdates(DTUpdates);
4706b63d3a2SMax Kazantsev DTUpdates.clear();
4716b63d3a2SMax Kazantsev for (auto *BB : DeadLoopBlocks)
4729aae9da9SMax Kazantsev DTU.deleteBB(BB);
4736b63d3a2SMax Kazantsev
4748b134169SMax Kazantsev NumLoopBlocksDeleted += DeadLoopBlocks.size();
475347c5837SMax Kazantsev }
476347c5837SMax Kazantsev
477c04b5307SMax Kazantsev /// Constant-fold terminators of blocks acculumated in FoldCandidates into the
478c04b5307SMax Kazantsev /// unconditional branches.
foldTerminators()479c04b5307SMax Kazantsev void foldTerminators() {
480c04b5307SMax Kazantsev for (BasicBlock *BB : FoldCandidates) {
481c04b5307SMax Kazantsev assert(LI.getLoopFor(BB) == &L && "Should be a loop block!");
482c04b5307SMax Kazantsev BasicBlock *TheOnlySucc = getOnlyLiveSuccessor(BB);
483c04b5307SMax Kazantsev assert(TheOnlySucc && "Should have one live successor!");
484c04b5307SMax Kazantsev
485c04b5307SMax Kazantsev LLVM_DEBUG(dbgs() << "Replacing terminator of " << BB->getName()
486c04b5307SMax Kazantsev << " with an unconditional branch to the block "
487c04b5307SMax Kazantsev << TheOnlySucc->getName() << "\n");
488c04b5307SMax Kazantsev
489c04b5307SMax Kazantsev SmallPtrSet<BasicBlock *, 2> DeadSuccessors;
490c04b5307SMax Kazantsev // Remove all BB's successors except for the live one.
491c4e4d644SMax Kazantsev unsigned TheOnlySuccDuplicates = 0;
492c04b5307SMax Kazantsev for (auto *Succ : successors(BB))
493c04b5307SMax Kazantsev if (Succ != TheOnlySucc) {
494c04b5307SMax Kazantsev DeadSuccessors.insert(Succ);
495cb8e2403SMax Kazantsev // If our successor lies in a different loop, we don't want to remove
496cb8e2403SMax Kazantsev // the one-input Phi because it is a LCSSA Phi.
497cb8e2403SMax Kazantsev bool PreserveLCSSAPhi = !L.contains(Succ);
498cb8e2403SMax Kazantsev Succ->removePredecessor(BB, PreserveLCSSAPhi);
4999cf417dbSMax Kazantsev if (MSSAU)
5009cf417dbSMax Kazantsev MSSAU->removeEdge(BB, Succ);
501c4e4d644SMax Kazantsev } else
502c4e4d644SMax Kazantsev ++TheOnlySuccDuplicates;
503c4e4d644SMax Kazantsev
504c4e4d644SMax Kazantsev assert(TheOnlySuccDuplicates > 0 && "Should be!");
505c4e4d644SMax Kazantsev // If TheOnlySucc was BB's successor more than once, after transform it
506c4e4d644SMax Kazantsev // will be its successor only once. Remove redundant inputs from
507c4e4d644SMax Kazantsev // TheOnlySucc's Phis.
508c4e4d644SMax Kazantsev bool PreserveLCSSAPhi = !L.contains(TheOnlySucc);
509c4e4d644SMax Kazantsev for (unsigned Dup = 1; Dup < TheOnlySuccDuplicates; ++Dup)
510c4e4d644SMax Kazantsev TheOnlySucc->removePredecessor(BB, PreserveLCSSAPhi);
5119cf417dbSMax Kazantsev if (MSSAU && TheOnlySuccDuplicates > 1)
5129cf417dbSMax Kazantsev MSSAU->removeDuplicatePhiEdgesBetween(BB, TheOnlySucc);
513c04b5307SMax Kazantsev
514c04b5307SMax Kazantsev IRBuilder<> Builder(BB->getContext());
515c04b5307SMax Kazantsev Instruction *Term = BB->getTerminator();
516c04b5307SMax Kazantsev Builder.SetInsertPoint(Term);
517c04b5307SMax Kazantsev Builder.CreateBr(TheOnlySucc);
518c04b5307SMax Kazantsev Term->eraseFromParent();
519c04b5307SMax Kazantsev
520c04b5307SMax Kazantsev for (auto *DeadSucc : DeadSuccessors)
5216b63d3a2SMax Kazantsev DTUpdates.push_back({DominatorTree::Delete, BB, DeadSucc});
522c04b5307SMax Kazantsev
523c04b5307SMax Kazantsev ++NumTerminatorsFolded;
524c04b5307SMax Kazantsev }
525c04b5307SMax Kazantsev }
526c04b5307SMax Kazantsev
527c04b5307SMax Kazantsev public:
ConstantTerminatorFoldingImpl(Loop & L,LoopInfo & LI,DominatorTree & DT,ScalarEvolution & SE,MemorySSAUpdater * MSSAU)5289cf417dbSMax Kazantsev ConstantTerminatorFoldingImpl(Loop &L, LoopInfo &LI, DominatorTree &DT,
529201534d7SMax Kazantsev ScalarEvolution &SE,
5309cf417dbSMax Kazantsev MemorySSAUpdater *MSSAU)
531136f09beSMax Kazantsev : L(L), LI(LI), DT(DT), SE(SE), MSSAU(MSSAU), DFS(&L),
5326b63d3a2SMax Kazantsev DTU(DT, DomTreeUpdater::UpdateStrategy::Eager) {}
run()533c04b5307SMax Kazantsev bool run() {
534c04b5307SMax Kazantsev assert(L.getLoopLatch() && "Should be single latch!");
535c04b5307SMax Kazantsev
536c04b5307SMax Kazantsev // Collect all available information about status of blocks after constant
537c04b5307SMax Kazantsev // folding.
538c04b5307SMax Kazantsev analyze();
53930095d97SMax Kazantsev BasicBlock *Header = L.getHeader();
54030095d97SMax Kazantsev (void)Header;
541c04b5307SMax Kazantsev
54230095d97SMax Kazantsev LLVM_DEBUG(dbgs() << "In function " << Header->getParent()->getName()
543c04b5307SMax Kazantsev << ": ");
544c04b5307SMax Kazantsev
545a523a211SMax Kazantsev if (HasIrreducibleCFG) {
546a523a211SMax Kazantsev LLVM_DEBUG(dbgs() << "Loops with irreducible CFG are not supported!\n");
547a523a211SMax Kazantsev return false;
548a523a211SMax Kazantsev }
549a523a211SMax Kazantsev
550c04b5307SMax Kazantsev // Nothing to constant-fold.
551c04b5307SMax Kazantsev if (FoldCandidates.empty()) {
552c04b5307SMax Kazantsev LLVM_DEBUG(
553c04b5307SMax Kazantsev dbgs() << "No constant terminator folding candidates found in loop "
55430095d97SMax Kazantsev << Header->getName() << "\n");
555c04b5307SMax Kazantsev return false;
556c04b5307SMax Kazantsev }
557c04b5307SMax Kazantsev
558c04b5307SMax Kazantsev // TODO: Support deletion of the current loop.
559c04b5307SMax Kazantsev if (DeleteCurrentLoop) {
560c04b5307SMax Kazantsev LLVM_DEBUG(
561c04b5307SMax Kazantsev dbgs()
56230095d97SMax Kazantsev << "Give up constant terminator folding in loop " << Header->getName()
563c04b5307SMax Kazantsev << ": we don't currently support deletion of the current loop.\n");
564c04b5307SMax Kazantsev return false;
565c04b5307SMax Kazantsev }
566c04b5307SMax Kazantsev
567c04b5307SMax Kazantsev // TODO: Support blocks that are not dead, but also not in loop after the
568c04b5307SMax Kazantsev // folding.
569347c5837SMax Kazantsev if (BlocksInLoopAfterFolding.size() + DeadLoopBlocks.size() !=
570347c5837SMax Kazantsev L.getNumBlocks()) {
571c04b5307SMax Kazantsev LLVM_DEBUG(
572c04b5307SMax Kazantsev dbgs() << "Give up constant terminator folding in loop "
57330095d97SMax Kazantsev << Header->getName() << ": we don't currently"
574c04b5307SMax Kazantsev " support blocks that are not dead, but will stop "
575c04b5307SMax Kazantsev "being a part of the loop after constant-folding.\n");
576c04b5307SMax Kazantsev return false;
577c04b5307SMax Kazantsev }
578c04b5307SMax Kazantsev
579*82309831SMax Kazantsev // TODO: Tokens may breach LCSSA form by default. However, the transform for
580*82309831SMax Kazantsev // dead exit blocks requires LCSSA form to be maintained for all values,
581*82309831SMax Kazantsev // tokens included, otherwise it may break use-def dominance (see PR56243).
582*82309831SMax Kazantsev if (!DeadExitBlocks.empty() && !L.isLCSSAForm(DT, /*IgnoreTokens*/ false)) {
583*82309831SMax Kazantsev assert(L.isLCSSAForm(DT, /*IgnoreTokens*/ true) &&
584*82309831SMax Kazantsev "LCSSA broken not by tokens?");
585*82309831SMax Kazantsev LLVM_DEBUG(dbgs() << "Give up constant terminator folding in loop "
586*82309831SMax Kazantsev << Header->getName()
587*82309831SMax Kazantsev << ": tokens uses potentially break LCSSA form.\n");
588*82309831SMax Kazantsev return false;
589*82309831SMax Kazantsev }
590*82309831SMax Kazantsev
591201534d7SMax Kazantsev SE.forgetTopmostLoop(&L);
592c04b5307SMax Kazantsev // Dump analysis results.
593c04b5307SMax Kazantsev LLVM_DEBUG(dump());
594c04b5307SMax Kazantsev
595c04b5307SMax Kazantsev LLVM_DEBUG(dbgs() << "Constant-folding " << FoldCandidates.size()
59630095d97SMax Kazantsev << " terminators in loop " << Header->getName() << "\n");
597c04b5307SMax Kazantsev
598c04b5307SMax Kazantsev // Make the actual transforms.
599edabb9aeSMax Kazantsev handleDeadExits();
600c04b5307SMax Kazantsev foldTerminators();
601c04b5307SMax Kazantsev
602347c5837SMax Kazantsev if (!DeadLoopBlocks.empty()) {
603347c5837SMax Kazantsev LLVM_DEBUG(dbgs() << "Deleting " << DeadLoopBlocks.size()
60430095d97SMax Kazantsev << " dead blocks in loop " << Header->getName() << "\n");
605347c5837SMax Kazantsev deleteDeadLoopBlocks();
6066b63d3a2SMax Kazantsev } else {
6076b63d3a2SMax Kazantsev // If we didn't do updates inside deleteDeadLoopBlocks, do them here.
6086b63d3a2SMax Kazantsev DTU.applyUpdates(DTUpdates);
6096b63d3a2SMax Kazantsev DTUpdates.clear();
610347c5837SMax Kazantsev }
611347c5837SMax Kazantsev
612d2d32443SAlina Sbirlea if (MSSAU && VerifyMemorySSA)
613d2d32443SAlina Sbirlea MSSAU->getMemorySSA()->verifyMemorySSA();
614d2d32443SAlina Sbirlea
615c04b5307SMax Kazantsev #ifndef NDEBUG
616c04b5307SMax Kazantsev // Make sure that we have preserved all data structures after the transform.
6170822bfc6SYevgeny Rouban #if defined(EXPENSIVE_CHECKS)
6180822bfc6SYevgeny Rouban assert(DT.verify(DominatorTree::VerificationLevel::Full) &&
6190822bfc6SYevgeny Rouban "DT broken after transform!");
6200822bfc6SYevgeny Rouban #else
6210822bfc6SYevgeny Rouban assert(DT.verify(DominatorTree::VerificationLevel::Fast) &&
6220822bfc6SYevgeny Rouban "DT broken after transform!");
6230822bfc6SYevgeny Rouban #endif
62430095d97SMax Kazantsev assert(DT.isReachableFromEntry(Header));
625c04b5307SMax Kazantsev LI.verify(DT);
626c04b5307SMax Kazantsev #endif
627c04b5307SMax Kazantsev
628c04b5307SMax Kazantsev return true;
629c04b5307SMax Kazantsev }
630ebd95ea8SMax Kazantsev
foldingBreaksCurrentLoop() const631ebd95ea8SMax Kazantsev bool foldingBreaksCurrentLoop() const {
632ebd95ea8SMax Kazantsev return DeleteCurrentLoop;
633ebd95ea8SMax Kazantsev }
634c04b5307SMax Kazantsev };
635b17d2136SBenjamin Kramer } // namespace
636c04b5307SMax Kazantsev
637c04b5307SMax Kazantsev /// Turn branches and switches with known constant conditions into unconditional
638c04b5307SMax Kazantsev /// branches.
constantFoldTerminators(Loop & L,DominatorTree & DT,LoopInfo & LI,ScalarEvolution & SE,MemorySSAUpdater * MSSAU,bool & IsLoopDeleted)6399cf417dbSMax Kazantsev static bool constantFoldTerminators(Loop &L, DominatorTree &DT, LoopInfo &LI,
640201534d7SMax Kazantsev ScalarEvolution &SE,
641ebd95ea8SMax Kazantsev MemorySSAUpdater *MSSAU,
642ebd95ea8SMax Kazantsev bool &IsLoopDeleted) {
643e1c2dc27SMax Kazantsev if (!EnableTermFolding)
644e1c2dc27SMax Kazantsev return false;
645e1c2dc27SMax Kazantsev
646c04b5307SMax Kazantsev // To keep things simple, only process loops with single latch. We
647c04b5307SMax Kazantsev // canonicalize most loops to this form. We can support multi-latch if needed.
648c04b5307SMax Kazantsev if (!L.getLoopLatch())
649c04b5307SMax Kazantsev return false;
650c04b5307SMax Kazantsev
651201534d7SMax Kazantsev ConstantTerminatorFoldingImpl BranchFolder(L, LI, DT, SE, MSSAU);
652ebd95ea8SMax Kazantsev bool Changed = BranchFolder.run();
653ebd95ea8SMax Kazantsev IsLoopDeleted = Changed && BranchFolder.foldingBreaksCurrentLoop();
654ebd95ea8SMax Kazantsev return Changed;
655c04b5307SMax Kazantsev }
656c04b5307SMax Kazantsev
mergeBlocksIntoPredecessors(Loop & L,DominatorTree & DT,LoopInfo & LI,MemorySSAUpdater * MSSAU)65746955b58SMax Kazantsev static bool mergeBlocksIntoPredecessors(Loop &L, DominatorTree &DT,
65846955b58SMax Kazantsev LoopInfo &LI, MemorySSAUpdater *MSSAU) {
659b417d464SFiona Glaser bool Changed = false;
66021a8b605SChijun Sima DomTreeUpdater DTU(DT, DomTreeUpdater::UpdateStrategy::Eager);
661b417d464SFiona Glaser // Copy blocks into a temporary array to avoid iterator invalidation issues
662b417d464SFiona Glaser // as we remove them.
663e6bca0eeSSanjoy Das SmallVector<WeakTrackingVH, 16> Blocks(L.blocks());
664b417d464SFiona Glaser
665b417d464SFiona Glaser for (auto &Block : Blocks) {
666b417d464SFiona Glaser // Attempt to merge blocks in the trivial case. Don't modify blocks which
667b417d464SFiona Glaser // belong to other loops.
66836e8230dSFiona Glaser BasicBlock *Succ = cast_or_null<BasicBlock>(Block);
669b417d464SFiona Glaser if (!Succ)
670b417d464SFiona Glaser continue;
671b417d464SFiona Glaser
672b417d464SFiona Glaser BasicBlock *Pred = Succ->getSinglePredecessor();
673ab6a513bSJustin Bogner if (!Pred || !Pred->getSingleSuccessor() || LI.getLoopFor(Pred) != &L)
674b417d464SFiona Glaser continue;
675b417d464SFiona Glaser
676dfd14adeSAlina Sbirlea // Merge Succ into Pred and delete it.
6778b83d685SAlina Sbirlea MergeBlockIntoPredecessor(Succ, &DTU, &LI, MSSAU);
678e6a9c248SDavid Green
679da4baa2aSAlina Sbirlea if (MSSAU && VerifyMemorySSA)
680da4baa2aSAlina Sbirlea MSSAU->getMemorySSA()->verifyMemorySSA();
681da4baa2aSAlina Sbirlea
682b417d464SFiona Glaser Changed = true;
683b417d464SFiona Glaser }
684b417d464SFiona Glaser
685b417d464SFiona Glaser return Changed;
686b417d464SFiona Glaser }
687b417d464SFiona Glaser
simplifyLoopCFG(Loop & L,DominatorTree & DT,LoopInfo & LI,ScalarEvolution & SE,MemorySSAUpdater * MSSAU,bool & IsLoopDeleted)68846955b58SMax Kazantsev static bool simplifyLoopCFG(Loop &L, DominatorTree &DT, LoopInfo &LI,
689ebd95ea8SMax Kazantsev ScalarEvolution &SE, MemorySSAUpdater *MSSAU,
6901c03cc5aSAlina Sbirlea bool &IsLoopDeleted) {
69146955b58SMax Kazantsev bool Changed = false;
69246955b58SMax Kazantsev
693c04b5307SMax Kazantsev // Constant-fold terminators with known constant conditions.
6941c03cc5aSAlina Sbirlea Changed |= constantFoldTerminators(L, DT, LI, SE, MSSAU, IsLoopDeleted);
695ebd95ea8SMax Kazantsev
6961c03cc5aSAlina Sbirlea if (IsLoopDeleted)
697ebd95ea8SMax Kazantsev return true;
698c04b5307SMax Kazantsev
69946955b58SMax Kazantsev // Eliminate unconditional branches by merging blocks into their predecessors.
70046955b58SMax Kazantsev Changed |= mergeBlocksIntoPredecessors(L, DT, LI, MSSAU);
70146955b58SMax Kazantsev
70246955b58SMax Kazantsev if (Changed)
70346955b58SMax Kazantsev SE.forgetTopmostLoop(&L);
70446955b58SMax Kazantsev
70546955b58SMax Kazantsev return Changed;
70646955b58SMax Kazantsev }
70746955b58SMax Kazantsev
run(Loop & L,LoopAnalysisManager & AM,LoopStandardAnalysisResults & AR,LPMUpdater & LPMU)708410eaeb0SChandler Carruth PreservedAnalyses LoopSimplifyCFGPass::run(Loop &L, LoopAnalysisManager &AM,
709410eaeb0SChandler Carruth LoopStandardAnalysisResults &AR,
710ebd95ea8SMax Kazantsev LPMUpdater &LPMU) {
7118b83d685SAlina Sbirlea Optional<MemorySSAUpdater> MSSAU;
712f92109dcSAlina Sbirlea if (AR.MSSA)
7138b83d685SAlina Sbirlea MSSAU = MemorySSAUpdater(AR.MSSA);
714ebd95ea8SMax Kazantsev bool DeleteCurrentLoop = false;
7158b83d685SAlina Sbirlea if (!simplifyLoopCFG(L, AR.DT, AR.LI, AR.SE,
716d66cbc56SKazu Hirata MSSAU ? MSSAU.getPointer() : nullptr, DeleteCurrentLoop))
717ab6a513bSJustin Bogner return PreservedAnalyses::all();
718ca68a3ecSChandler Carruth
719ebd95ea8SMax Kazantsev if (DeleteCurrentLoop)
720ebd95ea8SMax Kazantsev LPMU.markLoopAsDeleted(L, "loop-simplifycfg");
721ebd95ea8SMax Kazantsev
7223cef1f7dSAlina Sbirlea auto PA = getLoopPassPreservedAnalyses();
723f92109dcSAlina Sbirlea if (AR.MSSA)
7243cef1f7dSAlina Sbirlea PA.preserve<MemorySSAAnalysis>();
7253cef1f7dSAlina Sbirlea return PA;
726ab6a513bSJustin Bogner }
727ab6a513bSJustin Bogner
728ab6a513bSJustin Bogner namespace {
729ab6a513bSJustin Bogner class LoopSimplifyCFGLegacyPass : public LoopPass {
730ab6a513bSJustin Bogner public:
731ab6a513bSJustin Bogner static char ID; // Pass ID, replacement for typeid
LoopSimplifyCFGLegacyPass()732ab6a513bSJustin Bogner LoopSimplifyCFGLegacyPass() : LoopPass(ID) {
733ab6a513bSJustin Bogner initializeLoopSimplifyCFGLegacyPassPass(*PassRegistry::getPassRegistry());
734ab6a513bSJustin Bogner }
735ab6a513bSJustin Bogner
runOnLoop(Loop * L,LPPassManager & LPM)736ebd95ea8SMax Kazantsev bool runOnLoop(Loop *L, LPPassManager &LPM) override {
737aa641a51SAndrew Kaylor if (skipLoop(L))
738b417d464SFiona Glaser return false;
739b417d464SFiona Glaser
740ab6a513bSJustin Bogner DominatorTree &DT = getAnalysis<DominatorTreeWrapperPass>().getDomTree();
741ab6a513bSJustin Bogner LoopInfo &LI = getAnalysis<LoopInfoWrapperPass>().getLoopInfo();
742e6a9c248SDavid Green ScalarEvolution &SE = getAnalysis<ScalarEvolutionWrapperPass>().getSE();
743f7ca5428SAlina Sbirlea auto *MSSAA = getAnalysisIfAvailable<MemorySSAWrapperPass>();
744f7ca5428SAlina Sbirlea Optional<MemorySSAUpdater> MSSAU;
745f7ca5428SAlina Sbirlea if (MSSAA)
746f7ca5428SAlina Sbirlea MSSAU = MemorySSAUpdater(&MSSAA->getMSSA());
747f7ca5428SAlina Sbirlea if (MSSAA && VerifyMemorySSA)
748f7ca5428SAlina Sbirlea MSSAU->getMemorySSA()->verifyMemorySSA();
749ebd95ea8SMax Kazantsev bool DeleteCurrentLoop = false;
750d08f34b5SKazu Hirata bool Changed =
751d08f34b5SKazu Hirata simplifyLoopCFG(*L, DT, LI, SE, MSSAU ? MSSAU.getPointer() : nullptr,
752f7ca5428SAlina Sbirlea DeleteCurrentLoop);
753ebd95ea8SMax Kazantsev if (DeleteCurrentLoop)
754ebd95ea8SMax Kazantsev LPM.markLoopAsDeleted(*L);
755ebd95ea8SMax Kazantsev return Changed;
756ab6a513bSJustin Bogner }
757ab6a513bSJustin Bogner
getAnalysisUsage(AnalysisUsage & AU) const758ab6a513bSJustin Bogner void getAnalysisUsage(AnalysisUsage &AU) const override {
7598b83d685SAlina Sbirlea AU.addPreserved<MemorySSAWrapperPass>();
76049c22190SChandler Carruth AU.addPreserved<DependenceAnalysisWrapperPass>();
761ab6a513bSJustin Bogner getLoopAnalysisUsage(AU);
762ab6a513bSJustin Bogner }
763ab6a513bSJustin Bogner };
7641c03cc5aSAlina Sbirlea } // end namespace
765ab6a513bSJustin Bogner
766ab6a513bSJustin Bogner char LoopSimplifyCFGLegacyPass::ID = 0;
767ab6a513bSJustin Bogner INITIALIZE_PASS_BEGIN(LoopSimplifyCFGLegacyPass, "loop-simplifycfg",
768ab6a513bSJustin Bogner "Simplify loop CFG", false, false)
INITIALIZE_PASS_DEPENDENCY(LoopPass)769ab6a513bSJustin Bogner INITIALIZE_PASS_DEPENDENCY(LoopPass)
7708b83d685SAlina Sbirlea INITIALIZE_PASS_DEPENDENCY(MemorySSAWrapperPass)
771ab6a513bSJustin Bogner INITIALIZE_PASS_END(LoopSimplifyCFGLegacyPass, "loop-simplifycfg",
772ab6a513bSJustin Bogner "Simplify loop CFG", false, false)
773ab6a513bSJustin Bogner
774ab6a513bSJustin Bogner Pass *llvm::createLoopSimplifyCFGPass() {
775ab6a513bSJustin Bogner return new LoopSimplifyCFGLegacyPass();
776b417d464SFiona Glaser }
777