1 /*
2  * Copyright (C) 2014 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 #include "nodes.h"
17 
18 #include <cfloat>
19 
20 #include "art_method-inl.h"
21 #include "base/bit_utils.h"
22 #include "base/bit_vector-inl.h"
23 #include "base/logging.h"
24 #include "base/stl_util.h"
25 #include "class_linker-inl.h"
26 #include "class_root.h"
27 #include "code_generator.h"
28 #include "common_dominator.h"
29 #include "intrinsics.h"
30 #include "mirror/class-inl.h"
31 #include "scoped_thread_state_change-inl.h"
32 #include "ssa_builder.h"
33 
34 namespace art {
35 
36 // Enable floating-point static evaluation during constant folding
37 // only if all floating-point operations and constants evaluate in the
38 // range and precision of the type used (i.e., 32-bit float, 64-bit
39 // double).
40 static constexpr bool kEnableFloatingPointStaticEvaluation = (FLT_EVAL_METHOD == 0);
41 
InitializeInexactObjectRTI(VariableSizedHandleScope * handles)42 void HGraph::InitializeInexactObjectRTI(VariableSizedHandleScope* handles) {
43   ScopedObjectAccess soa(Thread::Current());
44   // Create the inexact Object reference type and store it in the HGraph.
45   inexact_object_rti_ = ReferenceTypeInfo::Create(
46       handles->NewHandle(GetClassRoot<mirror::Object>()),
47       /* is_exact= */ false);
48 }
49 
AddBlock(HBasicBlock * block)50 void HGraph::AddBlock(HBasicBlock* block) {
51   block->SetBlockId(blocks_.size());
52   blocks_.push_back(block);
53 }
54 
FindBackEdges(ArenaBitVector * visited)55 void HGraph::FindBackEdges(ArenaBitVector* visited) {
56   // "visited" must be empty on entry, it's an output argument for all visited (i.e. live) blocks.
57   DCHECK_EQ(visited->GetHighestBitSet(), -1);
58 
59   // Allocate memory from local ScopedArenaAllocator.
60   ScopedArenaAllocator allocator(GetArenaStack());
61   // Nodes that we're currently visiting, indexed by block id.
62   ArenaBitVector visiting(
63       &allocator, blocks_.size(), /* expandable= */ false, kArenaAllocGraphBuilder);
64   visiting.ClearAllBits();
65   // Number of successors visited from a given node, indexed by block id.
66   ScopedArenaVector<size_t> successors_visited(blocks_.size(),
67                                                0u,
68                                                allocator.Adapter(kArenaAllocGraphBuilder));
69   // Stack of nodes that we're currently visiting (same as marked in "visiting" above).
70   ScopedArenaVector<HBasicBlock*> worklist(allocator.Adapter(kArenaAllocGraphBuilder));
71   constexpr size_t kDefaultWorklistSize = 8;
72   worklist.reserve(kDefaultWorklistSize);
73   visited->SetBit(entry_block_->GetBlockId());
74   visiting.SetBit(entry_block_->GetBlockId());
75   worklist.push_back(entry_block_);
76 
77   while (!worklist.empty()) {
78     HBasicBlock* current = worklist.back();
79     uint32_t current_id = current->GetBlockId();
80     if (successors_visited[current_id] == current->GetSuccessors().size()) {
81       visiting.ClearBit(current_id);
82       worklist.pop_back();
83     } else {
84       HBasicBlock* successor = current->GetSuccessors()[successors_visited[current_id]++];
85       uint32_t successor_id = successor->GetBlockId();
86       if (visiting.IsBitSet(successor_id)) {
87         DCHECK(ContainsElement(worklist, successor));
88         successor->AddBackEdge(current);
89       } else if (!visited->IsBitSet(successor_id)) {
90         visited->SetBit(successor_id);
91         visiting.SetBit(successor_id);
92         worklist.push_back(successor);
93       }
94     }
95   }
96 }
97 
98 // Remove the environment use records of the instruction for users.
RemoveEnvironmentUses(HInstruction * instruction)99 void RemoveEnvironmentUses(HInstruction* instruction) {
100   for (HEnvironment* environment = instruction->GetEnvironment();
101        environment != nullptr;
102        environment = environment->GetParent()) {
103     for (size_t i = 0, e = environment->Size(); i < e; ++i) {
104       if (environment->GetInstructionAt(i) != nullptr) {
105         environment->RemoveAsUserOfInput(i);
106       }
107     }
108   }
109 }
110 
111 // Return whether the instruction has an environment and it's used by others.
HasEnvironmentUsedByOthers(HInstruction * instruction)112 bool HasEnvironmentUsedByOthers(HInstruction* instruction) {
113   for (HEnvironment* environment = instruction->GetEnvironment();
114        environment != nullptr;
115        environment = environment->GetParent()) {
116     for (size_t i = 0, e = environment->Size(); i < e; ++i) {
117       HInstruction* user = environment->GetInstructionAt(i);
118       if (user != nullptr) {
119         return true;
120       }
121     }
122   }
123   return false;
124 }
125 
126 // Reset environment records of the instruction itself.
ResetEnvironmentInputRecords(HInstruction * instruction)127 void ResetEnvironmentInputRecords(HInstruction* instruction) {
128   for (HEnvironment* environment = instruction->GetEnvironment();
129        environment != nullptr;
130        environment = environment->GetParent()) {
131     for (size_t i = 0, e = environment->Size(); i < e; ++i) {
132       DCHECK(environment->GetHolder() == instruction);
133       if (environment->GetInstructionAt(i) != nullptr) {
134         environment->SetRawEnvAt(i, nullptr);
135       }
136     }
137   }
138 }
139 
RemoveAsUser(HInstruction * instruction)140 static void RemoveAsUser(HInstruction* instruction) {
141   instruction->RemoveAsUserOfAllInputs();
142   RemoveEnvironmentUses(instruction);
143 }
144 
RemoveInstructionsAsUsersFromDeadBlocks(const ArenaBitVector & visited) const145 void HGraph::RemoveInstructionsAsUsersFromDeadBlocks(const ArenaBitVector& visited) const {
146   for (size_t i = 0; i < blocks_.size(); ++i) {
147     if (!visited.IsBitSet(i)) {
148       HBasicBlock* block = blocks_[i];
149       if (block == nullptr) continue;
150       for (HInstructionIterator it(block->GetPhis()); !it.Done(); it.Advance()) {
151         RemoveAsUser(it.Current());
152       }
153       for (HInstructionIterator it(block->GetInstructions()); !it.Done(); it.Advance()) {
154         RemoveAsUser(it.Current());
155       }
156     }
157   }
158 }
159 
RemoveDeadBlocks(const ArenaBitVector & visited)160 void HGraph::RemoveDeadBlocks(const ArenaBitVector& visited) {
161   for (size_t i = 0; i < blocks_.size(); ++i) {
162     if (!visited.IsBitSet(i)) {
163       HBasicBlock* block = blocks_[i];
164       if (block == nullptr) continue;
165       // We only need to update the successor, which might be live.
166       for (HBasicBlock* successor : block->GetSuccessors()) {
167         successor->RemovePredecessor(block);
168       }
169       // Remove the block from the list of blocks, so that further analyses
170       // never see it.
171       blocks_[i] = nullptr;
172       if (block->IsExitBlock()) {
173         SetExitBlock(nullptr);
174       }
175       // Mark the block as removed. This is used by the HGraphBuilder to discard
176       // the block as a branch target.
177       block->SetGraph(nullptr);
178     }
179   }
180 }
181 
BuildDominatorTree()182 GraphAnalysisResult HGraph::BuildDominatorTree() {
183   // Allocate memory from local ScopedArenaAllocator.
184   ScopedArenaAllocator allocator(GetArenaStack());
185 
186   ArenaBitVector visited(&allocator, blocks_.size(), false, kArenaAllocGraphBuilder);
187   visited.ClearAllBits();
188 
189   // (1) Find the back edges in the graph doing a DFS traversal.
190   FindBackEdges(&visited);
191 
192   // (2) Remove instructions and phis from blocks not visited during
193   //     the initial DFS as users from other instructions, so that
194   //     users can be safely removed before uses later.
195   RemoveInstructionsAsUsersFromDeadBlocks(visited);
196 
197   // (3) Remove blocks not visited during the initial DFS.
198   //     Step (5) requires dead blocks to be removed from the
199   //     predecessors list of live blocks.
200   RemoveDeadBlocks(visited);
201 
202   // (4) Simplify the CFG now, so that we don't need to recompute
203   //     dominators and the reverse post order.
204   SimplifyCFG();
205 
206   // (5) Compute the dominance information and the reverse post order.
207   ComputeDominanceInformation();
208 
209   // (6) Analyze loops discovered through back edge analysis, and
210   //     set the loop information on each block.
211   GraphAnalysisResult result = AnalyzeLoops();
212   if (result != kAnalysisSuccess) {
213     return result;
214   }
215 
216   // (7) Precompute per-block try membership before entering the SSA builder,
217   //     which needs the information to build catch block phis from values of
218   //     locals at throwing instructions inside try blocks.
219   ComputeTryBlockInformation();
220 
221   return kAnalysisSuccess;
222 }
223 
ClearDominanceInformation()224 void HGraph::ClearDominanceInformation() {
225   for (HBasicBlock* block : GetReversePostOrder()) {
226     block->ClearDominanceInformation();
227   }
228   reverse_post_order_.clear();
229 }
230 
ClearLoopInformation()231 void HGraph::ClearLoopInformation() {
232   SetHasIrreducibleLoops(false);
233   for (HBasicBlock* block : GetReversePostOrder()) {
234     block->SetLoopInformation(nullptr);
235   }
236 }
237 
ClearDominanceInformation()238 void HBasicBlock::ClearDominanceInformation() {
239   dominated_blocks_.clear();
240   dominator_ = nullptr;
241 }
242 
GetFirstInstructionDisregardMoves() const243 HInstruction* HBasicBlock::GetFirstInstructionDisregardMoves() const {
244   HInstruction* instruction = GetFirstInstruction();
245   while (instruction->IsParallelMove()) {
246     instruction = instruction->GetNext();
247   }
248   return instruction;
249 }
250 
UpdateDominatorOfSuccessor(HBasicBlock * block,HBasicBlock * successor)251 static bool UpdateDominatorOfSuccessor(HBasicBlock* block, HBasicBlock* successor) {
252   DCHECK(ContainsElement(block->GetSuccessors(), successor));
253 
254   HBasicBlock* old_dominator = successor->GetDominator();
255   HBasicBlock* new_dominator =
256       (old_dominator == nullptr) ? block
257                                  : CommonDominator::ForPair(old_dominator, block);
258 
259   if (old_dominator == new_dominator) {
260     return false;
261   } else {
262     successor->SetDominator(new_dominator);
263     return true;
264   }
265 }
266 
ComputeDominanceInformation()267 void HGraph::ComputeDominanceInformation() {
268   DCHECK(reverse_post_order_.empty());
269   reverse_post_order_.reserve(blocks_.size());
270   reverse_post_order_.push_back(entry_block_);
271 
272   // Allocate memory from local ScopedArenaAllocator.
273   ScopedArenaAllocator allocator(GetArenaStack());
274   // Number of visits of a given node, indexed by block id.
275   ScopedArenaVector<size_t> visits(blocks_.size(), 0u, allocator.Adapter(kArenaAllocGraphBuilder));
276   // Number of successors visited from a given node, indexed by block id.
277   ScopedArenaVector<size_t> successors_visited(blocks_.size(),
278                                                0u,
279                                                allocator.Adapter(kArenaAllocGraphBuilder));
280   // Nodes for which we need to visit successors.
281   ScopedArenaVector<HBasicBlock*> worklist(allocator.Adapter(kArenaAllocGraphBuilder));
282   constexpr size_t kDefaultWorklistSize = 8;
283   worklist.reserve(kDefaultWorklistSize);
284   worklist.push_back(entry_block_);
285 
286   while (!worklist.empty()) {
287     HBasicBlock* current = worklist.back();
288     uint32_t current_id = current->GetBlockId();
289     if (successors_visited[current_id] == current->GetSuccessors().size()) {
290       worklist.pop_back();
291     } else {
292       HBasicBlock* successor = current->GetSuccessors()[successors_visited[current_id]++];
293       UpdateDominatorOfSuccessor(current, successor);
294 
295       // Once all the forward edges have been visited, we know the immediate
296       // dominator of the block. We can then start visiting its successors.
297       if (++visits[successor->GetBlockId()] ==
298           successor->GetPredecessors().size() - successor->NumberOfBackEdges()) {
299         reverse_post_order_.push_back(successor);
300         worklist.push_back(successor);
301       }
302     }
303   }
304 
305   // Check if the graph has back edges not dominated by their respective headers.
306   // If so, we need to update the dominators of those headers and recursively of
307   // their successors. We do that with a fix-point iteration over all blocks.
308   // The algorithm is guaranteed to terminate because it loops only if the sum
309   // of all dominator chains has decreased in the current iteration.
310   bool must_run_fix_point = false;
311   for (HBasicBlock* block : blocks_) {
312     if (block != nullptr &&
313         block->IsLoopHeader() &&
314         block->GetLoopInformation()->HasBackEdgeNotDominatedByHeader()) {
315       must_run_fix_point = true;
316       break;
317     }
318   }
319   if (must_run_fix_point) {
320     bool update_occurred = true;
321     while (update_occurred) {
322       update_occurred = false;
323       for (HBasicBlock* block : GetReversePostOrder()) {
324         for (HBasicBlock* successor : block->GetSuccessors()) {
325           update_occurred |= UpdateDominatorOfSuccessor(block, successor);
326         }
327       }
328     }
329   }
330 
331   // Make sure that there are no remaining blocks whose dominator information
332   // needs to be updated.
333   if (kIsDebugBuild) {
334     for (HBasicBlock* block : GetReversePostOrder()) {
335       for (HBasicBlock* successor : block->GetSuccessors()) {
336         DCHECK(!UpdateDominatorOfSuccessor(block, successor));
337       }
338     }
339   }
340 
341   // Populate `dominated_blocks_` information after computing all dominators.
342   // The potential presence of irreducible loops requires to do it after.
343   for (HBasicBlock* block : GetReversePostOrder()) {
344     if (!block->IsEntryBlock()) {
345       block->GetDominator()->AddDominatedBlock(block);
346     }
347   }
348 }
349 
SplitEdge(HBasicBlock * block,HBasicBlock * successor)350 HBasicBlock* HGraph::SplitEdge(HBasicBlock* block, HBasicBlock* successor) {
351   HBasicBlock* new_block = new (allocator_) HBasicBlock(this, successor->GetDexPc());
352   AddBlock(new_block);
353   // Use `InsertBetween` to ensure the predecessor index and successor index of
354   // `block` and `successor` are preserved.
355   new_block->InsertBetween(block, successor);
356   return new_block;
357 }
358 
SplitCriticalEdge(HBasicBlock * block,HBasicBlock * successor)359 void HGraph::SplitCriticalEdge(HBasicBlock* block, HBasicBlock* successor) {
360   // Insert a new node between `block` and `successor` to split the
361   // critical edge.
362   HBasicBlock* new_block = SplitEdge(block, successor);
363   new_block->AddInstruction(new (allocator_) HGoto(successor->GetDexPc()));
364   if (successor->IsLoopHeader()) {
365     // If we split at a back edge boundary, make the new block the back edge.
366     HLoopInformation* info = successor->GetLoopInformation();
367     if (info->IsBackEdge(*block)) {
368       info->RemoveBackEdge(block);
369       info->AddBackEdge(new_block);
370     }
371   }
372 }
373 
374 // Reorder phi inputs to match reordering of the block's predecessors.
FixPhisAfterPredecessorsReodering(HBasicBlock * block,size_t first,size_t second)375 static void FixPhisAfterPredecessorsReodering(HBasicBlock* block, size_t first, size_t second) {
376   for (HInstructionIterator it(block->GetPhis()); !it.Done(); it.Advance()) {
377     HPhi* phi = it.Current()->AsPhi();
378     HInstruction* first_instr = phi->InputAt(first);
379     HInstruction* second_instr = phi->InputAt(second);
380     phi->ReplaceInput(first_instr, second);
381     phi->ReplaceInput(second_instr, first);
382   }
383 }
384 
385 // Make sure that the first predecessor of a loop header is the incoming block.
OrderLoopHeaderPredecessors(HBasicBlock * header)386 void HGraph::OrderLoopHeaderPredecessors(HBasicBlock* header) {
387   DCHECK(header->IsLoopHeader());
388   HLoopInformation* info = header->GetLoopInformation();
389   if (info->IsBackEdge(*header->GetPredecessors()[0])) {
390     HBasicBlock* to_swap = header->GetPredecessors()[0];
391     for (size_t pred = 1, e = header->GetPredecessors().size(); pred < e; ++pred) {
392       HBasicBlock* predecessor = header->GetPredecessors()[pred];
393       if (!info->IsBackEdge(*predecessor)) {
394         header->predecessors_[pred] = to_swap;
395         header->predecessors_[0] = predecessor;
396         FixPhisAfterPredecessorsReodering(header, 0, pred);
397         break;
398       }
399     }
400   }
401 }
402 
403 // Transform control flow of the loop to a single preheader format (don't touch the data flow).
404 // New_preheader can be already among the header predecessors - this situation will be correctly
405 // processed.
FixControlForNewSinglePreheader(HBasicBlock * header,HBasicBlock * new_preheader)406 static void FixControlForNewSinglePreheader(HBasicBlock* header, HBasicBlock* new_preheader) {
407   HLoopInformation* loop_info = header->GetLoopInformation();
408   for (size_t pred = 0; pred < header->GetPredecessors().size(); ++pred) {
409     HBasicBlock* predecessor = header->GetPredecessors()[pred];
410     if (!loop_info->IsBackEdge(*predecessor) && predecessor != new_preheader) {
411       predecessor->ReplaceSuccessor(header, new_preheader);
412       pred--;
413     }
414   }
415 }
416 
417 //             == Before ==                                               == After ==
418 //      _________         _________                               _________         _________
419 //     | B0      |       | B1      |      (old preheaders)       | B0      |       | B1      |
420 //     |=========|       |=========|                             |=========|       |=========|
421 //     | i0 = .. |       | i1 = .. |                             | i0 = .. |       | i1 = .. |
422 //     |_________|       |_________|                             |_________|       |_________|
423 //           \               /                                         \              /
424 //            \             /                                        ___v____________v___
425 //             \           /               (new preheader)          | B20 <- B0, B1      |
426 //              |         |                                         |====================|
427 //              |         |                                         | i20 = phi(i0, i1)  |
428 //              |         |                                         |____________________|
429 //              |         |                                                   |
430 //    /\        |         |        /\                           /\            |              /\
431 //   /  v_______v_________v_______v  \                         /  v___________v_____________v  \
432 //  |  | B10 <- B0, B1, B2, B3     |  |                       |  | B10 <- B20, B2, B3        |  |
433 //  |  |===========================|  |       (header)        |  |===========================|  |
434 //  |  | i10 = phi(i0, i1, i2, i3) |  |                       |  | i10 = phi(i20, i2, i3)    |  |
435 //  |  |___________________________|  |                       |  |___________________________|  |
436 //  |        /               \        |                       |        /               \        |
437 //  |      ...              ...       |                       |      ...              ...       |
438 //  |   _________         _________   |                       |   _________         _________   |
439 //  |  | B2      |       | B3      |  |                       |  | B2      |       | B3      |  |
440 //  |  |=========|       |=========|  |     (back edges)      |  |=========|       |=========|  |
441 //  |  | i2 = .. |       | i3 = .. |  |                       |  | i2 = .. |       | i3 = .. |  |
442 //  |  |_________|       |_________|  |                       |  |_________|       |_________|  |
443 //   \     /                   \     /                         \     /                   \     /
444 //    \___/                     \___/                           \___/                     \___/
445 //
TransformLoopToSinglePreheaderFormat(HBasicBlock * header)446 void HGraph::TransformLoopToSinglePreheaderFormat(HBasicBlock* header) {
447   HLoopInformation* loop_info = header->GetLoopInformation();
448 
449   HBasicBlock* preheader = new (allocator_) HBasicBlock(this, header->GetDexPc());
450   AddBlock(preheader);
451   preheader->AddInstruction(new (allocator_) HGoto(header->GetDexPc()));
452 
453   // If the old header has no Phis then we only need to fix the control flow.
454   if (header->GetPhis().IsEmpty()) {
455     FixControlForNewSinglePreheader(header, preheader);
456     preheader->AddSuccessor(header);
457     return;
458   }
459 
460   // Find the first non-back edge block in the header's predecessors list.
461   size_t first_nonbackedge_pred_pos = 0;
462   bool found = false;
463   for (size_t pred = 0; pred < header->GetPredecessors().size(); ++pred) {
464     HBasicBlock* predecessor = header->GetPredecessors()[pred];
465     if (!loop_info->IsBackEdge(*predecessor)) {
466       first_nonbackedge_pred_pos = pred;
467       found = true;
468       break;
469     }
470   }
471 
472   DCHECK(found);
473 
474   // Fix the data-flow.
475   for (HInstructionIterator it(header->GetPhis()); !it.Done(); it.Advance()) {
476     HPhi* header_phi = it.Current()->AsPhi();
477 
478     HPhi* preheader_phi = new (GetAllocator()) HPhi(GetAllocator(),
479                                                     header_phi->GetRegNumber(),
480                                                     0,
481                                                     header_phi->GetType());
482     if (header_phi->GetType() == DataType::Type::kReference) {
483       preheader_phi->SetReferenceTypeInfo(header_phi->GetReferenceTypeInfo());
484     }
485     preheader->AddPhi(preheader_phi);
486 
487     HInstruction* orig_input = header_phi->InputAt(first_nonbackedge_pred_pos);
488     header_phi->ReplaceInput(preheader_phi, first_nonbackedge_pred_pos);
489     preheader_phi->AddInput(orig_input);
490 
491     for (size_t input_pos = first_nonbackedge_pred_pos + 1;
492          input_pos < header_phi->InputCount();
493          input_pos++) {
494       HInstruction* input = header_phi->InputAt(input_pos);
495       HBasicBlock* pred_block = header->GetPredecessors()[input_pos];
496 
497       if (loop_info->Contains(*pred_block)) {
498         DCHECK(loop_info->IsBackEdge(*pred_block));
499       } else {
500         preheader_phi->AddInput(input);
501         header_phi->RemoveInputAt(input_pos);
502         input_pos--;
503       }
504     }
505   }
506 
507   // Fix the control-flow.
508   HBasicBlock* first_pred = header->GetPredecessors()[first_nonbackedge_pred_pos];
509   preheader->InsertBetween(first_pred, header);
510 
511   FixControlForNewSinglePreheader(header, preheader);
512 }
513 
SimplifyLoop(HBasicBlock * header)514 void HGraph::SimplifyLoop(HBasicBlock* header) {
515   HLoopInformation* info = header->GetLoopInformation();
516 
517   // Make sure the loop has only one pre header. This simplifies SSA building by having
518   // to just look at the pre header to know which locals are initialized at entry of the
519   // loop. Also, don't allow the entry block to be a pre header: this simplifies inlining
520   // this graph.
521   size_t number_of_incomings = header->GetPredecessors().size() - info->NumberOfBackEdges();
522   if (number_of_incomings != 1 || (GetEntryBlock()->GetSingleSuccessor() == header)) {
523     TransformLoopToSinglePreheaderFormat(header);
524   }
525 
526   OrderLoopHeaderPredecessors(header);
527 
528   HInstruction* first_instruction = header->GetFirstInstruction();
529   if (first_instruction != nullptr && first_instruction->IsSuspendCheck()) {
530     // Called from DeadBlockElimination. Update SuspendCheck pointer.
531     info->SetSuspendCheck(first_instruction->AsSuspendCheck());
532   }
533 }
534 
ComputeTryBlockInformation()535 void HGraph::ComputeTryBlockInformation() {
536   // Iterate in reverse post order to propagate try membership information from
537   // predecessors to their successors.
538   for (HBasicBlock* block : GetReversePostOrder()) {
539     if (block->IsEntryBlock() || block->IsCatchBlock()) {
540       // Catch blocks after simplification have only exceptional predecessors
541       // and hence are never in tries.
542       continue;
543     }
544 
545     // Infer try membership from the first predecessor. Having simplified loops,
546     // the first predecessor can never be a back edge and therefore it must have
547     // been visited already and had its try membership set.
548     HBasicBlock* first_predecessor = block->GetPredecessors()[0];
549     DCHECK(!block->IsLoopHeader() || !block->GetLoopInformation()->IsBackEdge(*first_predecessor));
550     const HTryBoundary* try_entry = first_predecessor->ComputeTryEntryOfSuccessors();
551     if (try_entry != nullptr &&
552         (block->GetTryCatchInformation() == nullptr ||
553          try_entry != &block->GetTryCatchInformation()->GetTryEntry())) {
554       // We are either setting try block membership for the first time or it
555       // has changed.
556       block->SetTryCatchInformation(new (allocator_) TryCatchInformation(*try_entry));
557     }
558   }
559 }
560 
SimplifyCFG()561 void HGraph::SimplifyCFG() {
562 // Simplify the CFG for future analysis, and code generation:
563   // (1): Split critical edges.
564   // (2): Simplify loops by having only one preheader.
565   // NOTE: We're appending new blocks inside the loop, so we need to use index because iterators
566   // can be invalidated. We remember the initial size to avoid iterating over the new blocks.
567   for (size_t block_id = 0u, end = blocks_.size(); block_id != end; ++block_id) {
568     HBasicBlock* block = blocks_[block_id];
569     if (block == nullptr) continue;
570     if (block->GetSuccessors().size() > 1) {
571       // Only split normal-flow edges. We cannot split exceptional edges as they
572       // are synthesized (approximate real control flow), and we do not need to
573       // anyway. Moves that would be inserted there are performed by the runtime.
574       ArrayRef<HBasicBlock* const> normal_successors = block->GetNormalSuccessors();
575       for (size_t j = 0, e = normal_successors.size(); j < e; ++j) {
576         HBasicBlock* successor = normal_successors[j];
577         DCHECK(!successor->IsCatchBlock());
578         if (successor == exit_block_) {
579           // (Throw/Return/ReturnVoid)->TryBoundary->Exit. Special case which we
580           // do not want to split because Goto->Exit is not allowed.
581           DCHECK(block->IsSingleTryBoundary());
582         } else if (successor->GetPredecessors().size() > 1) {
583           SplitCriticalEdge(block, successor);
584           // SplitCriticalEdge could have invalidated the `normal_successors`
585           // ArrayRef. We must re-acquire it.
586           normal_successors = block->GetNormalSuccessors();
587           DCHECK_EQ(normal_successors[j]->GetSingleSuccessor(), successor);
588           DCHECK_EQ(e, normal_successors.size());
589         }
590       }
591     }
592     if (block->IsLoopHeader()) {
593       SimplifyLoop(block);
594     } else if (!block->IsEntryBlock() &&
595                block->GetFirstInstruction() != nullptr &&
596                block->GetFirstInstruction()->IsSuspendCheck()) {
597       // We are being called by the dead code elimiation pass, and what used to be
598       // a loop got dismantled. Just remove the suspend check.
599       block->RemoveInstruction(block->GetFirstInstruction());
600     }
601   }
602 }
603 
AnalyzeLoops() const604 GraphAnalysisResult HGraph::AnalyzeLoops() const {
605   // We iterate post order to ensure we visit inner loops before outer loops.
606   // `PopulateRecursive` needs this guarantee to know whether a natural loop
607   // contains an irreducible loop.
608   for (HBasicBlock* block : GetPostOrder()) {
609     if (block->IsLoopHeader()) {
610       if (block->IsCatchBlock()) {
611         // TODO: Dealing with exceptional back edges could be tricky because
612         //       they only approximate the real control flow. Bail out for now.
613         VLOG(compiler) << "Not compiled: Exceptional back edges";
614         return kAnalysisFailThrowCatchLoop;
615       }
616       block->GetLoopInformation()->Populate();
617     }
618   }
619   return kAnalysisSuccess;
620 }
621 
Dump(std::ostream & os)622 void HLoopInformation::Dump(std::ostream& os) {
623   os << "header: " << header_->GetBlockId() << std::endl;
624   os << "pre header: " << GetPreHeader()->GetBlockId() << std::endl;
625   for (HBasicBlock* block : back_edges_) {
626     os << "back edge: " << block->GetBlockId() << std::endl;
627   }
628   for (HBasicBlock* block : header_->GetPredecessors()) {
629     os << "predecessor: " << block->GetBlockId() << std::endl;
630   }
631   for (uint32_t idx : blocks_.Indexes()) {
632     os << "  in loop: " << idx << std::endl;
633   }
634 }
635 
InsertConstant(HConstant * constant)636 void HGraph::InsertConstant(HConstant* constant) {
637   // New constants are inserted before the SuspendCheck at the bottom of the
638   // entry block. Note that this method can be called from the graph builder and
639   // the entry block therefore may not end with SuspendCheck->Goto yet.
640   HInstruction* insert_before = nullptr;
641 
642   HInstruction* gota = entry_block_->GetLastInstruction();
643   if (gota != nullptr && gota->IsGoto()) {
644     HInstruction* suspend_check = gota->GetPrevious();
645     if (suspend_check != nullptr && suspend_check->IsSuspendCheck()) {
646       insert_before = suspend_check;
647     } else {
648       insert_before = gota;
649     }
650   }
651 
652   if (insert_before == nullptr) {
653     entry_block_->AddInstruction(constant);
654   } else {
655     entry_block_->InsertInstructionBefore(constant, insert_before);
656   }
657 }
658 
GetNullConstant(uint32_t dex_pc)659 HNullConstant* HGraph::GetNullConstant(uint32_t dex_pc) {
660   // For simplicity, don't bother reviving the cached null constant if it is
661   // not null and not in a block. Otherwise, we need to clear the instruction
662   // id and/or any invariants the graph is assuming when adding new instructions.
663   if ((cached_null_constant_ == nullptr) || (cached_null_constant_->GetBlock() == nullptr)) {
664     cached_null_constant_ = new (allocator_) HNullConstant(dex_pc);
665     cached_null_constant_->SetReferenceTypeInfo(inexact_object_rti_);
666     InsertConstant(cached_null_constant_);
667   }
668   if (kIsDebugBuild) {
669     ScopedObjectAccess soa(Thread::Current());
670     DCHECK(cached_null_constant_->GetReferenceTypeInfo().IsValid());
671   }
672   return cached_null_constant_;
673 }
674 
GetCurrentMethod()675 HCurrentMethod* HGraph::GetCurrentMethod() {
676   // For simplicity, don't bother reviving the cached current method if it is
677   // not null and not in a block. Otherwise, we need to clear the instruction
678   // id and/or any invariants the graph is assuming when adding new instructions.
679   if ((cached_current_method_ == nullptr) || (cached_current_method_->GetBlock() == nullptr)) {
680     cached_current_method_ = new (allocator_) HCurrentMethod(
681         Is64BitInstructionSet(instruction_set_) ? DataType::Type::kInt64 : DataType::Type::kInt32,
682         entry_block_->GetDexPc());
683     if (entry_block_->GetFirstInstruction() == nullptr) {
684       entry_block_->AddInstruction(cached_current_method_);
685     } else {
686       entry_block_->InsertInstructionBefore(
687           cached_current_method_, entry_block_->GetFirstInstruction());
688     }
689   }
690   return cached_current_method_;
691 }
692 
GetMethodName() const693 const char* HGraph::GetMethodName() const {
694   const dex::MethodId& method_id = dex_file_.GetMethodId(method_idx_);
695   return dex_file_.GetMethodName(method_id);
696 }
697 
PrettyMethod(bool with_signature) const698 std::string HGraph::PrettyMethod(bool with_signature) const {
699   return dex_file_.PrettyMethod(method_idx_, with_signature);
700 }
701 
GetConstant(DataType::Type type,int64_t value,uint32_t dex_pc)702 HConstant* HGraph::GetConstant(DataType::Type type, int64_t value, uint32_t dex_pc) {
703   switch (type) {
704     case DataType::Type::kBool:
705       DCHECK(IsUint<1>(value));
706       FALLTHROUGH_INTENDED;
707     case DataType::Type::kUint8:
708     case DataType::Type::kInt8:
709     case DataType::Type::kUint16:
710     case DataType::Type::kInt16:
711     case DataType::Type::kInt32:
712       DCHECK(IsInt(DataType::Size(type) * kBitsPerByte, value));
713       return GetIntConstant(static_cast<int32_t>(value), dex_pc);
714 
715     case DataType::Type::kInt64:
716       return GetLongConstant(value, dex_pc);
717 
718     default:
719       LOG(FATAL) << "Unsupported constant type";
720       UNREACHABLE();
721   }
722 }
723 
CacheFloatConstant(HFloatConstant * constant)724 void HGraph::CacheFloatConstant(HFloatConstant* constant) {
725   int32_t value = bit_cast<int32_t, float>(constant->GetValue());
726   DCHECK(cached_float_constants_.find(value) == cached_float_constants_.end());
727   cached_float_constants_.Overwrite(value, constant);
728 }
729 
CacheDoubleConstant(HDoubleConstant * constant)730 void HGraph::CacheDoubleConstant(HDoubleConstant* constant) {
731   int64_t value = bit_cast<int64_t, double>(constant->GetValue());
732   DCHECK(cached_double_constants_.find(value) == cached_double_constants_.end());
733   cached_double_constants_.Overwrite(value, constant);
734 }
735 
Add(HBasicBlock * block)736 void HLoopInformation::Add(HBasicBlock* block) {
737   blocks_.SetBit(block->GetBlockId());
738 }
739 
Remove(HBasicBlock * block)740 void HLoopInformation::Remove(HBasicBlock* block) {
741   blocks_.ClearBit(block->GetBlockId());
742 }
743 
PopulateRecursive(HBasicBlock * block)744 void HLoopInformation::PopulateRecursive(HBasicBlock* block) {
745   if (blocks_.IsBitSet(block->GetBlockId())) {
746     return;
747   }
748 
749   blocks_.SetBit(block->GetBlockId());
750   block->SetInLoop(this);
751   if (block->IsLoopHeader()) {
752     // We're visiting loops in post-order, so inner loops must have been
753     // populated already.
754     DCHECK(block->GetLoopInformation()->IsPopulated());
755     if (block->GetLoopInformation()->IsIrreducible()) {
756       contains_irreducible_loop_ = true;
757     }
758   }
759   for (HBasicBlock* predecessor : block->GetPredecessors()) {
760     PopulateRecursive(predecessor);
761   }
762 }
763 
PopulateIrreducibleRecursive(HBasicBlock * block,ArenaBitVector * finalized)764 void HLoopInformation::PopulateIrreducibleRecursive(HBasicBlock* block, ArenaBitVector* finalized) {
765   size_t block_id = block->GetBlockId();
766 
767   // If `block` is in `finalized`, we know its membership in the loop has been
768   // decided and it does not need to be revisited.
769   if (finalized->IsBitSet(block_id)) {
770     return;
771   }
772 
773   bool is_finalized = false;
774   if (block->IsLoopHeader()) {
775     // If we hit a loop header in an irreducible loop, we first check if the
776     // pre header of that loop belongs to the currently analyzed loop. If it does,
777     // then we visit the back edges.
778     // Note that we cannot use GetPreHeader, as the loop may have not been populated
779     // yet.
780     HBasicBlock* pre_header = block->GetPredecessors()[0];
781     PopulateIrreducibleRecursive(pre_header, finalized);
782     if (blocks_.IsBitSet(pre_header->GetBlockId())) {
783       block->SetInLoop(this);
784       blocks_.SetBit(block_id);
785       finalized->SetBit(block_id);
786       is_finalized = true;
787 
788       HLoopInformation* info = block->GetLoopInformation();
789       for (HBasicBlock* back_edge : info->GetBackEdges()) {
790         PopulateIrreducibleRecursive(back_edge, finalized);
791       }
792     }
793   } else {
794     // Visit all predecessors. If one predecessor is part of the loop, this
795     // block is also part of this loop.
796     for (HBasicBlock* predecessor : block->GetPredecessors()) {
797       PopulateIrreducibleRecursive(predecessor, finalized);
798       if (!is_finalized && blocks_.IsBitSet(predecessor->GetBlockId())) {
799         block->SetInLoop(this);
800         blocks_.SetBit(block_id);
801         finalized->SetBit(block_id);
802         is_finalized = true;
803       }
804     }
805   }
806 
807   // All predecessors have been recursively visited. Mark finalized if not marked yet.
808   if (!is_finalized) {
809     finalized->SetBit(block_id);
810   }
811 }
812 
Populate()813 void HLoopInformation::Populate() {
814   DCHECK_EQ(blocks_.NumSetBits(), 0u) << "Loop information has already been populated";
815   // Populate this loop: starting with the back edge, recursively add predecessors
816   // that are not already part of that loop. Set the header as part of the loop
817   // to end the recursion.
818   // This is a recursive implementation of the algorithm described in
819   // "Advanced Compiler Design & Implementation" (Muchnick) p192.
820   HGraph* graph = header_->GetGraph();
821   blocks_.SetBit(header_->GetBlockId());
822   header_->SetInLoop(this);
823 
824   bool is_irreducible_loop = HasBackEdgeNotDominatedByHeader();
825 
826   if (is_irreducible_loop) {
827     // Allocate memory from local ScopedArenaAllocator.
828     ScopedArenaAllocator allocator(graph->GetArenaStack());
829     ArenaBitVector visited(&allocator,
830                            graph->GetBlocks().size(),
831                            /* expandable= */ false,
832                            kArenaAllocGraphBuilder);
833     visited.ClearAllBits();
834     // Stop marking blocks at the loop header.
835     visited.SetBit(header_->GetBlockId());
836 
837     for (HBasicBlock* back_edge : GetBackEdges()) {
838       PopulateIrreducibleRecursive(back_edge, &visited);
839     }
840   } else {
841     for (HBasicBlock* back_edge : GetBackEdges()) {
842       PopulateRecursive(back_edge);
843     }
844   }
845 
846   if (!is_irreducible_loop && graph->IsCompilingOsr()) {
847     // When compiling in OSR mode, all loops in the compiled method may be entered
848     // from the interpreter. We treat this OSR entry point just like an extra entry
849     // to an irreducible loop, so we need to mark the method's loops as irreducible.
850     // This does not apply to inlined loops which do not act as OSR entry points.
851     if (suspend_check_ == nullptr) {
852       // Just building the graph in OSR mode, this loop is not inlined. We never build an
853       // inner graph in OSR mode as we can do OSR transition only from the outer method.
854       is_irreducible_loop = true;
855     } else {
856       // Look at the suspend check's environment to determine if the loop was inlined.
857       DCHECK(suspend_check_->HasEnvironment());
858       if (!suspend_check_->GetEnvironment()->IsFromInlinedInvoke()) {
859         is_irreducible_loop = true;
860       }
861     }
862   }
863   if (is_irreducible_loop) {
864     irreducible_ = true;
865     contains_irreducible_loop_ = true;
866     graph->SetHasIrreducibleLoops(true);
867   }
868   graph->SetHasLoops(true);
869 }
870 
PopulateInnerLoopUpwards(HLoopInformation * inner_loop)871 void HLoopInformation::PopulateInnerLoopUpwards(HLoopInformation* inner_loop) {
872   DCHECK(inner_loop->GetPreHeader()->GetLoopInformation() == this);
873   blocks_.Union(&inner_loop->blocks_);
874   HLoopInformation* outer_loop = GetPreHeader()->GetLoopInformation();
875   if (outer_loop != nullptr) {
876     outer_loop->PopulateInnerLoopUpwards(this);
877   }
878 }
879 
GetPreHeader() const880 HBasicBlock* HLoopInformation::GetPreHeader() const {
881   HBasicBlock* block = header_->GetPredecessors()[0];
882   DCHECK(irreducible_ || (block == header_->GetDominator()));
883   return block;
884 }
885 
Contains(const HBasicBlock & block) const886 bool HLoopInformation::Contains(const HBasicBlock& block) const {
887   return blocks_.IsBitSet(block.GetBlockId());
888 }
889 
IsIn(const HLoopInformation & other) const890 bool HLoopInformation::IsIn(const HLoopInformation& other) const {
891   return other.blocks_.IsBitSet(header_->GetBlockId());
892 }
893 
IsDefinedOutOfTheLoop(HInstruction * instruction) const894 bool HLoopInformation::IsDefinedOutOfTheLoop(HInstruction* instruction) const {
895   return !blocks_.IsBitSet(instruction->GetBlock()->GetBlockId());
896 }
897 
GetLifetimeEnd() const898 size_t HLoopInformation::GetLifetimeEnd() const {
899   size_t last_position = 0;
900   for (HBasicBlock* back_edge : GetBackEdges()) {
901     last_position = std::max(back_edge->GetLifetimeEnd(), last_position);
902   }
903   return last_position;
904 }
905 
HasBackEdgeNotDominatedByHeader() const906 bool HLoopInformation::HasBackEdgeNotDominatedByHeader() const {
907   for (HBasicBlock* back_edge : GetBackEdges()) {
908     DCHECK(back_edge->GetDominator() != nullptr);
909     if (!header_->Dominates(back_edge)) {
910       return true;
911     }
912   }
913   return false;
914 }
915 
DominatesAllBackEdges(HBasicBlock * block)916 bool HLoopInformation::DominatesAllBackEdges(HBasicBlock* block) {
917   for (HBasicBlock* back_edge : GetBackEdges()) {
918     if (!block->Dominates(back_edge)) {
919       return false;
920     }
921   }
922   return true;
923 }
924 
925 
HasExitEdge() const926 bool HLoopInformation::HasExitEdge() const {
927   // Determine if this loop has at least one exit edge.
928   HBlocksInLoopReversePostOrderIterator it_loop(*this);
929   for (; !it_loop.Done(); it_loop.Advance()) {
930     for (HBasicBlock* successor : it_loop.Current()->GetSuccessors()) {
931       if (!Contains(*successor)) {
932         return true;
933       }
934     }
935   }
936   return false;
937 }
938 
Dominates(HBasicBlock * other) const939 bool HBasicBlock::Dominates(HBasicBlock* other) const {
940   // Walk up the dominator tree from `other`, to find out if `this`
941   // is an ancestor.
942   HBasicBlock* current = other;
943   while (current != nullptr) {
944     if (current == this) {
945       return true;
946     }
947     current = current->GetDominator();
948   }
949   return false;
950 }
951 
UpdateInputsUsers(HInstruction * instruction)952 static void UpdateInputsUsers(HInstruction* instruction) {
953   HInputsRef inputs = instruction->GetInputs();
954   for (size_t i = 0; i < inputs.size(); ++i) {
955     inputs[i]->AddUseAt(instruction, i);
956   }
957   // Environment should be created later.
958   DCHECK(!instruction->HasEnvironment());
959 }
960 
ReplaceAndRemovePhiWith(HPhi * initial,HPhi * replacement)961 void HBasicBlock::ReplaceAndRemovePhiWith(HPhi* initial, HPhi* replacement) {
962   DCHECK(initial->GetBlock() == this);
963   InsertPhiAfter(replacement, initial);
964   initial->ReplaceWith(replacement);
965   RemovePhi(initial);
966 }
967 
ReplaceAndRemoveInstructionWith(HInstruction * initial,HInstruction * replacement)968 void HBasicBlock::ReplaceAndRemoveInstructionWith(HInstruction* initial,
969                                                   HInstruction* replacement) {
970   DCHECK(initial->GetBlock() == this);
971   if (initial->IsControlFlow()) {
972     // We can only replace a control flow instruction with another control flow instruction.
973     DCHECK(replacement->IsControlFlow());
974     DCHECK_EQ(replacement->GetId(), -1);
975     DCHECK_EQ(replacement->GetType(), DataType::Type::kVoid);
976     DCHECK_EQ(initial->GetBlock(), this);
977     DCHECK_EQ(initial->GetType(), DataType::Type::kVoid);
978     DCHECK(initial->GetUses().empty());
979     DCHECK(initial->GetEnvUses().empty());
980     replacement->SetBlock(this);
981     replacement->SetId(GetGraph()->GetNextInstructionId());
982     instructions_.InsertInstructionBefore(replacement, initial);
983     UpdateInputsUsers(replacement);
984   } else {
985     InsertInstructionBefore(replacement, initial);
986     initial->ReplaceWith(replacement);
987   }
988   RemoveInstruction(initial);
989 }
990 
Add(HInstructionList * instruction_list,HBasicBlock * block,HInstruction * instruction)991 static void Add(HInstructionList* instruction_list,
992                 HBasicBlock* block,
993                 HInstruction* instruction) {
994   DCHECK(instruction->GetBlock() == nullptr);
995   DCHECK_EQ(instruction->GetId(), -1);
996   instruction->SetBlock(block);
997   instruction->SetId(block->GetGraph()->GetNextInstructionId());
998   UpdateInputsUsers(instruction);
999   instruction_list->AddInstruction(instruction);
1000 }
1001 
AddInstruction(HInstruction * instruction)1002 void HBasicBlock::AddInstruction(HInstruction* instruction) {
1003   Add(&instructions_, this, instruction);
1004 }
1005 
AddPhi(HPhi * phi)1006 void HBasicBlock::AddPhi(HPhi* phi) {
1007   Add(&phis_, this, phi);
1008 }
1009 
InsertInstructionBefore(HInstruction * instruction,HInstruction * cursor)1010 void HBasicBlock::InsertInstructionBefore(HInstruction* instruction, HInstruction* cursor) {
1011   DCHECK(!cursor->IsPhi());
1012   DCHECK(!instruction->IsPhi());
1013   DCHECK_EQ(instruction->GetId(), -1);
1014   DCHECK_NE(cursor->GetId(), -1);
1015   DCHECK_EQ(cursor->GetBlock(), this);
1016   DCHECK(!instruction->IsControlFlow());
1017   instruction->SetBlock(this);
1018   instruction->SetId(GetGraph()->GetNextInstructionId());
1019   UpdateInputsUsers(instruction);
1020   instructions_.InsertInstructionBefore(instruction, cursor);
1021 }
1022 
InsertInstructionAfter(HInstruction * instruction,HInstruction * cursor)1023 void HBasicBlock::InsertInstructionAfter(HInstruction* instruction, HInstruction* cursor) {
1024   DCHECK(!cursor->IsPhi());
1025   DCHECK(!instruction->IsPhi());
1026   DCHECK_EQ(instruction->GetId(), -1);
1027   DCHECK_NE(cursor->GetId(), -1);
1028   DCHECK_EQ(cursor->GetBlock(), this);
1029   DCHECK(!instruction->IsControlFlow());
1030   DCHECK(!cursor->IsControlFlow());
1031   instruction->SetBlock(this);
1032   instruction->SetId(GetGraph()->GetNextInstructionId());
1033   UpdateInputsUsers(instruction);
1034   instructions_.InsertInstructionAfter(instruction, cursor);
1035 }
1036 
InsertPhiAfter(HPhi * phi,HPhi * cursor)1037 void HBasicBlock::InsertPhiAfter(HPhi* phi, HPhi* cursor) {
1038   DCHECK_EQ(phi->GetId(), -1);
1039   DCHECK_NE(cursor->GetId(), -1);
1040   DCHECK_EQ(cursor->GetBlock(), this);
1041   phi->SetBlock(this);
1042   phi->SetId(GetGraph()->GetNextInstructionId());
1043   UpdateInputsUsers(phi);
1044   phis_.InsertInstructionAfter(phi, cursor);
1045 }
1046 
Remove(HInstructionList * instruction_list,HBasicBlock * block,HInstruction * instruction,bool ensure_safety)1047 static void Remove(HInstructionList* instruction_list,
1048                    HBasicBlock* block,
1049                    HInstruction* instruction,
1050                    bool ensure_safety) {
1051   DCHECK_EQ(block, instruction->GetBlock());
1052   instruction->SetBlock(nullptr);
1053   instruction_list->RemoveInstruction(instruction);
1054   if (ensure_safety) {
1055     DCHECK(instruction->GetUses().empty());
1056     DCHECK(instruction->GetEnvUses().empty());
1057     RemoveAsUser(instruction);
1058   }
1059 }
1060 
RemoveInstruction(HInstruction * instruction,bool ensure_safety)1061 void HBasicBlock::RemoveInstruction(HInstruction* instruction, bool ensure_safety) {
1062   DCHECK(!instruction->IsPhi());
1063   Remove(&instructions_, this, instruction, ensure_safety);
1064 }
1065 
RemovePhi(HPhi * phi,bool ensure_safety)1066 void HBasicBlock::RemovePhi(HPhi* phi, bool ensure_safety) {
1067   Remove(&phis_, this, phi, ensure_safety);
1068 }
1069 
RemoveInstructionOrPhi(HInstruction * instruction,bool ensure_safety)1070 void HBasicBlock::RemoveInstructionOrPhi(HInstruction* instruction, bool ensure_safety) {
1071   if (instruction->IsPhi()) {
1072     RemovePhi(instruction->AsPhi(), ensure_safety);
1073   } else {
1074     RemoveInstruction(instruction, ensure_safety);
1075   }
1076 }
1077 
CopyFrom(ArrayRef<HInstruction * const> locals)1078 void HEnvironment::CopyFrom(ArrayRef<HInstruction* const> locals) {
1079   for (size_t i = 0; i < locals.size(); i++) {
1080     HInstruction* instruction = locals[i];
1081     SetRawEnvAt(i, instruction);
1082     if (instruction != nullptr) {
1083       instruction->AddEnvUseAt(this, i);
1084     }
1085   }
1086 }
1087 
CopyFrom(HEnvironment * env)1088 void HEnvironment::CopyFrom(HEnvironment* env) {
1089   for (size_t i = 0; i < env->Size(); i++) {
1090     HInstruction* instruction = env->GetInstructionAt(i);
1091     SetRawEnvAt(i, instruction);
1092     if (instruction != nullptr) {
1093       instruction->AddEnvUseAt(this, i);
1094     }
1095   }
1096 }
1097 
CopyFromWithLoopPhiAdjustment(HEnvironment * env,HBasicBlock * loop_header)1098 void HEnvironment::CopyFromWithLoopPhiAdjustment(HEnvironment* env,
1099                                                  HBasicBlock* loop_header) {
1100   DCHECK(loop_header->IsLoopHeader());
1101   for (size_t i = 0; i < env->Size(); i++) {
1102     HInstruction* instruction = env->GetInstructionAt(i);
1103     SetRawEnvAt(i, instruction);
1104     if (instruction == nullptr) {
1105       continue;
1106     }
1107     if (instruction->IsLoopHeaderPhi() && (instruction->GetBlock() == loop_header)) {
1108       // At the end of the loop pre-header, the corresponding value for instruction
1109       // is the first input of the phi.
1110       HInstruction* initial = instruction->AsPhi()->InputAt(0);
1111       SetRawEnvAt(i, initial);
1112       initial->AddEnvUseAt(this, i);
1113     } else {
1114       instruction->AddEnvUseAt(this, i);
1115     }
1116   }
1117 }
1118 
RemoveAsUserOfInput(size_t index) const1119 void HEnvironment::RemoveAsUserOfInput(size_t index) const {
1120   const HUserRecord<HEnvironment*>& env_use = vregs_[index];
1121   HInstruction* user = env_use.GetInstruction();
1122   auto before_env_use_node = env_use.GetBeforeUseNode();
1123   user->env_uses_.erase_after(before_env_use_node);
1124   user->FixUpUserRecordsAfterEnvUseRemoval(before_env_use_node);
1125 }
1126 
ReplaceInput(HInstruction * replacement,size_t index)1127 void HEnvironment::ReplaceInput(HInstruction* replacement, size_t index) {
1128   const HUserRecord<HEnvironment*>& env_use_record = vregs_[index];
1129   HInstruction* orig_instr = env_use_record.GetInstruction();
1130 
1131   DCHECK(orig_instr != replacement);
1132 
1133   HUseList<HEnvironment*>::iterator before_use_node = env_use_record.GetBeforeUseNode();
1134   // Note: fixup_end remains valid across splice_after().
1135   auto fixup_end = replacement->env_uses_.empty() ? replacement->env_uses_.begin()
1136                                                   : ++replacement->env_uses_.begin();
1137   replacement->env_uses_.splice_after(replacement->env_uses_.before_begin(),
1138                                       env_use_record.GetInstruction()->env_uses_,
1139                                       before_use_node);
1140   replacement->FixUpUserRecordsAfterEnvUseInsertion(fixup_end);
1141   orig_instr->FixUpUserRecordsAfterEnvUseRemoval(before_use_node);
1142 }
1143 
GetNextDisregardingMoves() const1144 HInstruction* HInstruction::GetNextDisregardingMoves() const {
1145   HInstruction* next = GetNext();
1146   while (next != nullptr && next->IsParallelMove()) {
1147     next = next->GetNext();
1148   }
1149   return next;
1150 }
1151 
GetPreviousDisregardingMoves() const1152 HInstruction* HInstruction::GetPreviousDisregardingMoves() const {
1153   HInstruction* previous = GetPrevious();
1154   while (previous != nullptr && previous->IsParallelMove()) {
1155     previous = previous->GetPrevious();
1156   }
1157   return previous;
1158 }
1159 
AddInstruction(HInstruction * instruction)1160 void HInstructionList::AddInstruction(HInstruction* instruction) {
1161   if (first_instruction_ == nullptr) {
1162     DCHECK(last_instruction_ == nullptr);
1163     first_instruction_ = last_instruction_ = instruction;
1164   } else {
1165     DCHECK(last_instruction_ != nullptr);
1166     last_instruction_->next_ = instruction;
1167     instruction->previous_ = last_instruction_;
1168     last_instruction_ = instruction;
1169   }
1170 }
1171 
InsertInstructionBefore(HInstruction * instruction,HInstruction * cursor)1172 void HInstructionList::InsertInstructionBefore(HInstruction* instruction, HInstruction* cursor) {
1173   DCHECK(Contains(cursor));
1174   if (cursor == first_instruction_) {
1175     cursor->previous_ = instruction;
1176     instruction->next_ = cursor;
1177     first_instruction_ = instruction;
1178   } else {
1179     instruction->previous_ = cursor->previous_;
1180     instruction->next_ = cursor;
1181     cursor->previous_ = instruction;
1182     instruction->previous_->next_ = instruction;
1183   }
1184 }
1185 
InsertInstructionAfter(HInstruction * instruction,HInstruction * cursor)1186 void HInstructionList::InsertInstructionAfter(HInstruction* instruction, HInstruction* cursor) {
1187   DCHECK(Contains(cursor));
1188   if (cursor == last_instruction_) {
1189     cursor->next_ = instruction;
1190     instruction->previous_ = cursor;
1191     last_instruction_ = instruction;
1192   } else {
1193     instruction->next_ = cursor->next_;
1194     instruction->previous_ = cursor;
1195     cursor->next_ = instruction;
1196     instruction->next_->previous_ = instruction;
1197   }
1198 }
1199 
RemoveInstruction(HInstruction * instruction)1200 void HInstructionList::RemoveInstruction(HInstruction* instruction) {
1201   if (instruction->previous_ != nullptr) {
1202     instruction->previous_->next_ = instruction->next_;
1203   }
1204   if (instruction->next_ != nullptr) {
1205     instruction->next_->previous_ = instruction->previous_;
1206   }
1207   if (instruction == first_instruction_) {
1208     first_instruction_ = instruction->next_;
1209   }
1210   if (instruction == last_instruction_) {
1211     last_instruction_ = instruction->previous_;
1212   }
1213 }
1214 
Contains(HInstruction * instruction) const1215 bool HInstructionList::Contains(HInstruction* instruction) const {
1216   for (HInstructionIterator it(*this); !it.Done(); it.Advance()) {
1217     if (it.Current() == instruction) {
1218       return true;
1219     }
1220   }
1221   return false;
1222 }
1223 
FoundBefore(const HInstruction * instruction1,const HInstruction * instruction2) const1224 bool HInstructionList::FoundBefore(const HInstruction* instruction1,
1225                                    const HInstruction* instruction2) const {
1226   DCHECK_EQ(instruction1->GetBlock(), instruction2->GetBlock());
1227   for (HInstructionIterator it(*this); !it.Done(); it.Advance()) {
1228     if (it.Current() == instruction1) {
1229       return true;
1230     }
1231     if (it.Current() == instruction2) {
1232       return false;
1233     }
1234   }
1235   LOG(FATAL) << "Did not find an order between two instructions of the same block.";
1236   UNREACHABLE();
1237 }
1238 
StrictlyDominates(HInstruction * other_instruction) const1239 bool HInstruction::StrictlyDominates(HInstruction* other_instruction) const {
1240   if (other_instruction == this) {
1241     // An instruction does not strictly dominate itself.
1242     return false;
1243   }
1244   HBasicBlock* block = GetBlock();
1245   HBasicBlock* other_block = other_instruction->GetBlock();
1246   if (block != other_block) {
1247     return GetBlock()->Dominates(other_instruction->GetBlock());
1248   } else {
1249     // If both instructions are in the same block, ensure this
1250     // instruction comes before `other_instruction`.
1251     if (IsPhi()) {
1252       if (!other_instruction->IsPhi()) {
1253         // Phis appear before non phi-instructions so this instruction
1254         // dominates `other_instruction`.
1255         return true;
1256       } else {
1257         // There is no order among phis.
1258         LOG(FATAL) << "There is no dominance between phis of a same block.";
1259         UNREACHABLE();
1260       }
1261     } else {
1262       // `this` is not a phi.
1263       if (other_instruction->IsPhi()) {
1264         // Phis appear before non phi-instructions so this instruction
1265         // does not dominate `other_instruction`.
1266         return false;
1267       } else {
1268         // Check whether this instruction comes before
1269         // `other_instruction` in the instruction list.
1270         return block->GetInstructions().FoundBefore(this, other_instruction);
1271       }
1272     }
1273   }
1274 }
1275 
RemoveEnvironment()1276 void HInstruction::RemoveEnvironment() {
1277   RemoveEnvironmentUses(this);
1278   environment_ = nullptr;
1279 }
1280 
ReplaceWith(HInstruction * other)1281 void HInstruction::ReplaceWith(HInstruction* other) {
1282   DCHECK(other != nullptr);
1283   // Note: fixup_end remains valid across splice_after().
1284   auto fixup_end = other->uses_.empty() ? other->uses_.begin() : ++other->uses_.begin();
1285   other->uses_.splice_after(other->uses_.before_begin(), uses_);
1286   other->FixUpUserRecordsAfterUseInsertion(fixup_end);
1287 
1288   // Note: env_fixup_end remains valid across splice_after().
1289   auto env_fixup_end =
1290       other->env_uses_.empty() ? other->env_uses_.begin() : ++other->env_uses_.begin();
1291   other->env_uses_.splice_after(other->env_uses_.before_begin(), env_uses_);
1292   other->FixUpUserRecordsAfterEnvUseInsertion(env_fixup_end);
1293 
1294   DCHECK(uses_.empty());
1295   DCHECK(env_uses_.empty());
1296 }
1297 
ReplaceUsesDominatedBy(HInstruction * dominator,HInstruction * replacement)1298 void HInstruction::ReplaceUsesDominatedBy(HInstruction* dominator, HInstruction* replacement) {
1299   const HUseList<HInstruction*>& uses = GetUses();
1300   for (auto it = uses.begin(), end = uses.end(); it != end; /* ++it below */) {
1301     HInstruction* user = it->GetUser();
1302     size_t index = it->GetIndex();
1303     // Increment `it` now because `*it` may disappear thanks to user->ReplaceInput().
1304     ++it;
1305     if (dominator->StrictlyDominates(user)) {
1306       user->ReplaceInput(replacement, index);
1307     } else if (user->IsPhi() && !user->AsPhi()->IsCatchPhi()) {
1308       // If the input flows from a block dominated by `dominator`, we can replace it.
1309       // We do not perform this for catch phis as we don't have control flow support
1310       // for their inputs.
1311       const ArenaVector<HBasicBlock*>& predecessors = user->GetBlock()->GetPredecessors();
1312       HBasicBlock* predecessor = predecessors[index];
1313       if (dominator->GetBlock()->Dominates(predecessor)) {
1314         user->ReplaceInput(replacement, index);
1315       }
1316     }
1317   }
1318 }
1319 
ReplaceEnvUsesDominatedBy(HInstruction * dominator,HInstruction * replacement)1320 void HInstruction::ReplaceEnvUsesDominatedBy(HInstruction* dominator, HInstruction* replacement) {
1321   const HUseList<HEnvironment*>& uses = GetEnvUses();
1322   for (auto it = uses.begin(), end = uses.end(); it != end; /* ++it below */) {
1323     HEnvironment* user = it->GetUser();
1324     size_t index = it->GetIndex();
1325     // Increment `it` now because `*it` may disappear thanks to user->ReplaceInput().
1326     ++it;
1327     if (dominator->StrictlyDominates(user->GetHolder())) {
1328       user->ReplaceInput(replacement, index);
1329     }
1330   }
1331 }
1332 
ReplaceInput(HInstruction * replacement,size_t index)1333 void HInstruction::ReplaceInput(HInstruction* replacement, size_t index) {
1334   HUserRecord<HInstruction*> input_use = InputRecordAt(index);
1335   if (input_use.GetInstruction() == replacement) {
1336     // Nothing to do.
1337     return;
1338   }
1339   HUseList<HInstruction*>::iterator before_use_node = input_use.GetBeforeUseNode();
1340   // Note: fixup_end remains valid across splice_after().
1341   auto fixup_end =
1342       replacement->uses_.empty() ? replacement->uses_.begin() : ++replacement->uses_.begin();
1343   replacement->uses_.splice_after(replacement->uses_.before_begin(),
1344                                   input_use.GetInstruction()->uses_,
1345                                   before_use_node);
1346   replacement->FixUpUserRecordsAfterUseInsertion(fixup_end);
1347   input_use.GetInstruction()->FixUpUserRecordsAfterUseRemoval(before_use_node);
1348 }
1349 
EnvironmentSize() const1350 size_t HInstruction::EnvironmentSize() const {
1351   return HasEnvironment() ? environment_->Size() : 0;
1352 }
1353 
AddInput(HInstruction * input)1354 void HVariableInputSizeInstruction::AddInput(HInstruction* input) {
1355   DCHECK(input->GetBlock() != nullptr);
1356   inputs_.push_back(HUserRecord<HInstruction*>(input));
1357   input->AddUseAt(this, inputs_.size() - 1);
1358 }
1359 
InsertInputAt(size_t index,HInstruction * input)1360 void HVariableInputSizeInstruction::InsertInputAt(size_t index, HInstruction* input) {
1361   inputs_.insert(inputs_.begin() + index, HUserRecord<HInstruction*>(input));
1362   input->AddUseAt(this, index);
1363   // Update indexes in use nodes of inputs that have been pushed further back by the insert().
1364   for (size_t i = index + 1u, e = inputs_.size(); i < e; ++i) {
1365     DCHECK_EQ(inputs_[i].GetUseNode()->GetIndex(), i - 1u);
1366     inputs_[i].GetUseNode()->SetIndex(i);
1367   }
1368 }
1369 
RemoveInputAt(size_t index)1370 void HVariableInputSizeInstruction::RemoveInputAt(size_t index) {
1371   RemoveAsUserOfInput(index);
1372   inputs_.erase(inputs_.begin() + index);
1373   // Update indexes in use nodes of inputs that have been pulled forward by the erase().
1374   for (size_t i = index, e = inputs_.size(); i < e; ++i) {
1375     DCHECK_EQ(inputs_[i].GetUseNode()->GetIndex(), i + 1u);
1376     inputs_[i].GetUseNode()->SetIndex(i);
1377   }
1378 }
1379 
RemoveAllInputs()1380 void HVariableInputSizeInstruction::RemoveAllInputs() {
1381   RemoveAsUserOfAllInputs();
1382   DCHECK(!HasNonEnvironmentUses());
1383 
1384   inputs_.clear();
1385   DCHECK_EQ(0u, InputCount());
1386 }
1387 
RemoveConstructorFences(HInstruction * instruction)1388 size_t HConstructorFence::RemoveConstructorFences(HInstruction* instruction) {
1389   DCHECK(instruction->GetBlock() != nullptr);
1390   // Removing constructor fences only makes sense for instructions with an object return type.
1391   DCHECK_EQ(DataType::Type::kReference, instruction->GetType());
1392 
1393   // Return how many instructions were removed for statistic purposes.
1394   size_t remove_count = 0;
1395 
1396   // Efficient implementation that simultaneously (in one pass):
1397   // * Scans the uses list for all constructor fences.
1398   // * Deletes that constructor fence from the uses list of `instruction`.
1399   // * Deletes `instruction` from the constructor fence's inputs.
1400   // * Deletes the constructor fence if it now has 0 inputs.
1401 
1402   const HUseList<HInstruction*>& uses = instruction->GetUses();
1403   // Warning: Although this is "const", we might mutate the list when calling RemoveInputAt.
1404   for (auto it = uses.begin(), end = uses.end(); it != end; ) {
1405     const HUseListNode<HInstruction*>& use_node = *it;
1406     HInstruction* const use_instruction = use_node.GetUser();
1407 
1408     // Advance the iterator immediately once we fetch the use_node.
1409     // Warning: If the input is removed, the current iterator becomes invalid.
1410     ++it;
1411 
1412     if (use_instruction->IsConstructorFence()) {
1413       HConstructorFence* ctor_fence = use_instruction->AsConstructorFence();
1414       size_t input_index = use_node.GetIndex();
1415 
1416       // Process the candidate instruction for removal
1417       // from the graph.
1418 
1419       // Constructor fence instructions are never
1420       // used by other instructions.
1421       //
1422       // If we wanted to make this more generic, it
1423       // could be a runtime if statement.
1424       DCHECK(!ctor_fence->HasUses());
1425 
1426       // A constructor fence's return type is "kPrimVoid"
1427       // and therefore it can't have any environment uses.
1428       DCHECK(!ctor_fence->HasEnvironmentUses());
1429 
1430       // Remove the inputs first, otherwise removing the instruction
1431       // will try to remove its uses while we are already removing uses
1432       // and this operation will fail.
1433       DCHECK_EQ(instruction, ctor_fence->InputAt(input_index));
1434 
1435       // Removing the input will also remove the `use_node`.
1436       // (Do not look at `use_node` after this, it will be a dangling reference).
1437       ctor_fence->RemoveInputAt(input_index);
1438 
1439       // Once all inputs are removed, the fence is considered dead and
1440       // is removed.
1441       if (ctor_fence->InputCount() == 0u) {
1442         ctor_fence->GetBlock()->RemoveInstruction(ctor_fence);
1443         ++remove_count;
1444       }
1445     }
1446   }
1447 
1448   if (kIsDebugBuild) {
1449     // Post-condition checks:
1450     // * None of the uses of `instruction` are a constructor fence.
1451     // * The `instruction` itself did not get removed from a block.
1452     for (const HUseListNode<HInstruction*>& use_node : instruction->GetUses()) {
1453       CHECK(!use_node.GetUser()->IsConstructorFence());
1454     }
1455     CHECK(instruction->GetBlock() != nullptr);
1456   }
1457 
1458   return remove_count;
1459 }
1460 
Merge(HConstructorFence * other)1461 void HConstructorFence::Merge(HConstructorFence* other) {
1462   // Do not delete yourself from the graph.
1463   DCHECK(this != other);
1464   // Don't try to merge with an instruction not associated with a block.
1465   DCHECK(other->GetBlock() != nullptr);
1466   // A constructor fence's return type is "kPrimVoid"
1467   // and therefore it cannot have any environment uses.
1468   DCHECK(!other->HasEnvironmentUses());
1469 
1470   auto has_input = [](HInstruction* haystack, HInstruction* needle) {
1471     // Check if `haystack` has `needle` as any of its inputs.
1472     for (size_t input_count = 0; input_count < haystack->InputCount(); ++input_count) {
1473       if (haystack->InputAt(input_count) == needle) {
1474         return true;
1475       }
1476     }
1477     return false;
1478   };
1479 
1480   // Add any inputs from `other` into `this` if it wasn't already an input.
1481   for (size_t input_count = 0; input_count < other->InputCount(); ++input_count) {
1482     HInstruction* other_input = other->InputAt(input_count);
1483     if (!has_input(this, other_input)) {
1484       AddInput(other_input);
1485     }
1486   }
1487 
1488   other->GetBlock()->RemoveInstruction(other);
1489 }
1490 
GetAssociatedAllocation(bool ignore_inputs)1491 HInstruction* HConstructorFence::GetAssociatedAllocation(bool ignore_inputs) {
1492   HInstruction* new_instance_inst = GetPrevious();
1493   // Check if the immediately preceding instruction is a new-instance/new-array.
1494   // Otherwise this fence is for protecting final fields.
1495   if (new_instance_inst != nullptr &&
1496       (new_instance_inst->IsNewInstance() || new_instance_inst->IsNewArray())) {
1497     if (ignore_inputs) {
1498       // If inputs are ignored, simply check if the predecessor is
1499       // *any* HNewInstance/HNewArray.
1500       //
1501       // Inputs are normally only ignored for prepare_for_register_allocation,
1502       // at which point *any* prior HNewInstance/Array can be considered
1503       // associated.
1504       return new_instance_inst;
1505     } else {
1506       // Normal case: There must be exactly 1 input and the previous instruction
1507       // must be that input.
1508       if (InputCount() == 1u && InputAt(0) == new_instance_inst) {
1509         return new_instance_inst;
1510       }
1511     }
1512   }
1513   return nullptr;
1514 }
1515 
1516 #define DEFINE_ACCEPT(name, super)                                             \
1517 void H##name::Accept(HGraphVisitor* visitor) {                                 \
1518   visitor->Visit##name(this);                                                  \
1519 }
1520 
FOR_EACH_CONCRETE_INSTRUCTION(DEFINE_ACCEPT)1521 FOR_EACH_CONCRETE_INSTRUCTION(DEFINE_ACCEPT)
1522 
1523 #undef DEFINE_ACCEPT
1524 
1525 void HGraphVisitor::VisitInsertionOrder() {
1526   const ArenaVector<HBasicBlock*>& blocks = graph_->GetBlocks();
1527   for (HBasicBlock* block : blocks) {
1528     if (block != nullptr) {
1529       VisitBasicBlock(block);
1530     }
1531   }
1532 }
1533 
VisitReversePostOrder()1534 void HGraphVisitor::VisitReversePostOrder() {
1535   for (HBasicBlock* block : graph_->GetReversePostOrder()) {
1536     VisitBasicBlock(block);
1537   }
1538 }
1539 
VisitBasicBlock(HBasicBlock * block)1540 void HGraphVisitor::VisitBasicBlock(HBasicBlock* block) {
1541   for (HInstructionIterator it(block->GetPhis()); !it.Done(); it.Advance()) {
1542     it.Current()->Accept(this);
1543   }
1544   for (HInstructionIterator it(block->GetInstructions()); !it.Done(); it.Advance()) {
1545     it.Current()->Accept(this);
1546   }
1547 }
1548 
TryStaticEvaluation() const1549 HConstant* HTypeConversion::TryStaticEvaluation() const {
1550   HGraph* graph = GetBlock()->GetGraph();
1551   if (GetInput()->IsIntConstant()) {
1552     int32_t value = GetInput()->AsIntConstant()->GetValue();
1553     switch (GetResultType()) {
1554       case DataType::Type::kInt8:
1555         return graph->GetIntConstant(static_cast<int8_t>(value), GetDexPc());
1556       case DataType::Type::kUint8:
1557         return graph->GetIntConstant(static_cast<uint8_t>(value), GetDexPc());
1558       case DataType::Type::kInt16:
1559         return graph->GetIntConstant(static_cast<int16_t>(value), GetDexPc());
1560       case DataType::Type::kUint16:
1561         return graph->GetIntConstant(static_cast<uint16_t>(value), GetDexPc());
1562       case DataType::Type::kInt64:
1563         return graph->GetLongConstant(static_cast<int64_t>(value), GetDexPc());
1564       case DataType::Type::kFloat32:
1565         return graph->GetFloatConstant(static_cast<float>(value), GetDexPc());
1566       case DataType::Type::kFloat64:
1567         return graph->GetDoubleConstant(static_cast<double>(value), GetDexPc());
1568       default:
1569         return nullptr;
1570     }
1571   } else if (GetInput()->IsLongConstant()) {
1572     int64_t value = GetInput()->AsLongConstant()->GetValue();
1573     switch (GetResultType()) {
1574       case DataType::Type::kInt8:
1575         return graph->GetIntConstant(static_cast<int8_t>(value), GetDexPc());
1576       case DataType::Type::kUint8:
1577         return graph->GetIntConstant(static_cast<uint8_t>(value), GetDexPc());
1578       case DataType::Type::kInt16:
1579         return graph->GetIntConstant(static_cast<int16_t>(value), GetDexPc());
1580       case DataType::Type::kUint16:
1581         return graph->GetIntConstant(static_cast<uint16_t>(value), GetDexPc());
1582       case DataType::Type::kInt32:
1583         return graph->GetIntConstant(static_cast<int32_t>(value), GetDexPc());
1584       case DataType::Type::kFloat32:
1585         return graph->GetFloatConstant(static_cast<float>(value), GetDexPc());
1586       case DataType::Type::kFloat64:
1587         return graph->GetDoubleConstant(static_cast<double>(value), GetDexPc());
1588       default:
1589         return nullptr;
1590     }
1591   } else if (GetInput()->IsFloatConstant()) {
1592     float value = GetInput()->AsFloatConstant()->GetValue();
1593     switch (GetResultType()) {
1594       case DataType::Type::kInt32:
1595         if (std::isnan(value))
1596           return graph->GetIntConstant(0, GetDexPc());
1597         if (value >= static_cast<float>(kPrimIntMax))
1598           return graph->GetIntConstant(kPrimIntMax, GetDexPc());
1599         if (value <= kPrimIntMin)
1600           return graph->GetIntConstant(kPrimIntMin, GetDexPc());
1601         return graph->GetIntConstant(static_cast<int32_t>(value), GetDexPc());
1602       case DataType::Type::kInt64:
1603         if (std::isnan(value))
1604           return graph->GetLongConstant(0, GetDexPc());
1605         if (value >= static_cast<float>(kPrimLongMax))
1606           return graph->GetLongConstant(kPrimLongMax, GetDexPc());
1607         if (value <= kPrimLongMin)
1608           return graph->GetLongConstant(kPrimLongMin, GetDexPc());
1609         return graph->GetLongConstant(static_cast<int64_t>(value), GetDexPc());
1610       case DataType::Type::kFloat64:
1611         return graph->GetDoubleConstant(static_cast<double>(value), GetDexPc());
1612       default:
1613         return nullptr;
1614     }
1615   } else if (GetInput()->IsDoubleConstant()) {
1616     double value = GetInput()->AsDoubleConstant()->GetValue();
1617     switch (GetResultType()) {
1618       case DataType::Type::kInt32:
1619         if (std::isnan(value))
1620           return graph->GetIntConstant(0, GetDexPc());
1621         if (value >= kPrimIntMax)
1622           return graph->GetIntConstant(kPrimIntMax, GetDexPc());
1623         if (value <= kPrimLongMin)
1624           return graph->GetIntConstant(kPrimIntMin, GetDexPc());
1625         return graph->GetIntConstant(static_cast<int32_t>(value), GetDexPc());
1626       case DataType::Type::kInt64:
1627         if (std::isnan(value))
1628           return graph->GetLongConstant(0, GetDexPc());
1629         if (value >= static_cast<double>(kPrimLongMax))
1630           return graph->GetLongConstant(kPrimLongMax, GetDexPc());
1631         if (value <= kPrimLongMin)
1632           return graph->GetLongConstant(kPrimLongMin, GetDexPc());
1633         return graph->GetLongConstant(static_cast<int64_t>(value), GetDexPc());
1634       case DataType::Type::kFloat32:
1635         return graph->GetFloatConstant(static_cast<float>(value), GetDexPc());
1636       default:
1637         return nullptr;
1638     }
1639   }
1640   return nullptr;
1641 }
1642 
TryStaticEvaluation() const1643 HConstant* HUnaryOperation::TryStaticEvaluation() const {
1644   if (GetInput()->IsIntConstant()) {
1645     return Evaluate(GetInput()->AsIntConstant());
1646   } else if (GetInput()->IsLongConstant()) {
1647     return Evaluate(GetInput()->AsLongConstant());
1648   } else if (kEnableFloatingPointStaticEvaluation) {
1649     if (GetInput()->IsFloatConstant()) {
1650       return Evaluate(GetInput()->AsFloatConstant());
1651     } else if (GetInput()->IsDoubleConstant()) {
1652       return Evaluate(GetInput()->AsDoubleConstant());
1653     }
1654   }
1655   return nullptr;
1656 }
1657 
TryStaticEvaluation() const1658 HConstant* HBinaryOperation::TryStaticEvaluation() const {
1659   if (GetLeft()->IsIntConstant() && GetRight()->IsIntConstant()) {
1660     return Evaluate(GetLeft()->AsIntConstant(), GetRight()->AsIntConstant());
1661   } else if (GetLeft()->IsLongConstant()) {
1662     if (GetRight()->IsIntConstant()) {
1663       // The binop(long, int) case is only valid for shifts and rotations.
1664       DCHECK(IsShl() || IsShr() || IsUShr() || IsRor()) << DebugName();
1665       return Evaluate(GetLeft()->AsLongConstant(), GetRight()->AsIntConstant());
1666     } else if (GetRight()->IsLongConstant()) {
1667       return Evaluate(GetLeft()->AsLongConstant(), GetRight()->AsLongConstant());
1668     }
1669   } else if (GetLeft()->IsNullConstant() && GetRight()->IsNullConstant()) {
1670     // The binop(null, null) case is only valid for equal and not-equal conditions.
1671     DCHECK(IsEqual() || IsNotEqual()) << DebugName();
1672     return Evaluate(GetLeft()->AsNullConstant(), GetRight()->AsNullConstant());
1673   } else if (kEnableFloatingPointStaticEvaluation) {
1674     if (GetLeft()->IsFloatConstant() && GetRight()->IsFloatConstant()) {
1675       return Evaluate(GetLeft()->AsFloatConstant(), GetRight()->AsFloatConstant());
1676     } else if (GetLeft()->IsDoubleConstant() && GetRight()->IsDoubleConstant()) {
1677       return Evaluate(GetLeft()->AsDoubleConstant(), GetRight()->AsDoubleConstant());
1678     }
1679   }
1680   return nullptr;
1681 }
1682 
GetConstantRight() const1683 HConstant* HBinaryOperation::GetConstantRight() const {
1684   if (GetRight()->IsConstant()) {
1685     return GetRight()->AsConstant();
1686   } else if (IsCommutative() && GetLeft()->IsConstant()) {
1687     return GetLeft()->AsConstant();
1688   } else {
1689     return nullptr;
1690   }
1691 }
1692 
1693 // If `GetConstantRight()` returns one of the input, this returns the other
1694 // one. Otherwise it returns null.
GetLeastConstantLeft() const1695 HInstruction* HBinaryOperation::GetLeastConstantLeft() const {
1696   HInstruction* most_constant_right = GetConstantRight();
1697   if (most_constant_right == nullptr) {
1698     return nullptr;
1699   } else if (most_constant_right == GetLeft()) {
1700     return GetRight();
1701   } else {
1702     return GetLeft();
1703   }
1704 }
1705 
operator <<(std::ostream & os,const ComparisonBias & rhs)1706 std::ostream& operator<<(std::ostream& os, const ComparisonBias& rhs) {
1707   switch (rhs) {
1708     case ComparisonBias::kNoBias:
1709       return os << "no_bias";
1710     case ComparisonBias::kGtBias:
1711       return os << "gt_bias";
1712     case ComparisonBias::kLtBias:
1713       return os << "lt_bias";
1714     default:
1715       LOG(FATAL) << "Unknown ComparisonBias: " << static_cast<int>(rhs);
1716       UNREACHABLE();
1717   }
1718 }
1719 
IsBeforeWhenDisregardMoves(HInstruction * instruction) const1720 bool HCondition::IsBeforeWhenDisregardMoves(HInstruction* instruction) const {
1721   return this == instruction->GetPreviousDisregardingMoves();
1722 }
1723 
Equals(const HInstruction * other) const1724 bool HInstruction::Equals(const HInstruction* other) const {
1725   if (GetKind() != other->GetKind()) return false;
1726   if (GetType() != other->GetType()) return false;
1727   if (!InstructionDataEquals(other)) return false;
1728   HConstInputsRef inputs = GetInputs();
1729   HConstInputsRef other_inputs = other->GetInputs();
1730   if (inputs.size() != other_inputs.size()) return false;
1731   for (size_t i = 0; i != inputs.size(); ++i) {
1732     if (inputs[i] != other_inputs[i]) return false;
1733   }
1734 
1735   DCHECK_EQ(ComputeHashCode(), other->ComputeHashCode());
1736   return true;
1737 }
1738 
operator <<(std::ostream & os,const HInstruction::InstructionKind & rhs)1739 std::ostream& operator<<(std::ostream& os, const HInstruction::InstructionKind& rhs) {
1740 #define DECLARE_CASE(type, super) case HInstruction::k##type: os << #type; break;
1741   switch (rhs) {
1742     FOR_EACH_CONCRETE_INSTRUCTION(DECLARE_CASE)
1743     default:
1744       os << "Unknown instruction kind " << static_cast<int>(rhs);
1745       break;
1746   }
1747 #undef DECLARE_CASE
1748   return os;
1749 }
1750 
MoveBefore(HInstruction * cursor,bool do_checks)1751 void HInstruction::MoveBefore(HInstruction* cursor, bool do_checks) {
1752   if (do_checks) {
1753     DCHECK(!IsPhi());
1754     DCHECK(!IsControlFlow());
1755     DCHECK(CanBeMoved() ||
1756            // HShouldDeoptimizeFlag can only be moved by CHAGuardOptimization.
1757            IsShouldDeoptimizeFlag());
1758     DCHECK(!cursor->IsPhi());
1759   }
1760 
1761   next_->previous_ = previous_;
1762   if (previous_ != nullptr) {
1763     previous_->next_ = next_;
1764   }
1765   if (block_->instructions_.first_instruction_ == this) {
1766     block_->instructions_.first_instruction_ = next_;
1767   }
1768   DCHECK_NE(block_->instructions_.last_instruction_, this);
1769 
1770   previous_ = cursor->previous_;
1771   if (previous_ != nullptr) {
1772     previous_->next_ = this;
1773   }
1774   next_ = cursor;
1775   cursor->previous_ = this;
1776   block_ = cursor->block_;
1777 
1778   if (block_->instructions_.first_instruction_ == cursor) {
1779     block_->instructions_.first_instruction_ = this;
1780   }
1781 }
1782 
MoveBeforeFirstUserAndOutOfLoops()1783 void HInstruction::MoveBeforeFirstUserAndOutOfLoops() {
1784   DCHECK(!CanThrow());
1785   DCHECK(!HasSideEffects());
1786   DCHECK(!HasEnvironmentUses());
1787   DCHECK(HasNonEnvironmentUses());
1788   DCHECK(!IsPhi());  // Makes no sense for Phi.
1789   DCHECK_EQ(InputCount(), 0u);
1790 
1791   // Find the target block.
1792   auto uses_it = GetUses().begin();
1793   auto uses_end = GetUses().end();
1794   HBasicBlock* target_block = uses_it->GetUser()->GetBlock();
1795   ++uses_it;
1796   while (uses_it != uses_end && uses_it->GetUser()->GetBlock() == target_block) {
1797     ++uses_it;
1798   }
1799   if (uses_it != uses_end) {
1800     // This instruction has uses in two or more blocks. Find the common dominator.
1801     CommonDominator finder(target_block);
1802     for (; uses_it != uses_end; ++uses_it) {
1803       finder.Update(uses_it->GetUser()->GetBlock());
1804     }
1805     target_block = finder.Get();
1806     DCHECK(target_block != nullptr);
1807   }
1808   // Move to the first dominator not in a loop.
1809   while (target_block->IsInLoop()) {
1810     target_block = target_block->GetDominator();
1811     DCHECK(target_block != nullptr);
1812   }
1813 
1814   // Find insertion position.
1815   HInstruction* insert_pos = nullptr;
1816   for (const HUseListNode<HInstruction*>& use : GetUses()) {
1817     if (use.GetUser()->GetBlock() == target_block &&
1818         (insert_pos == nullptr || use.GetUser()->StrictlyDominates(insert_pos))) {
1819       insert_pos = use.GetUser();
1820     }
1821   }
1822   if (insert_pos == nullptr) {
1823     // No user in `target_block`, insert before the control flow instruction.
1824     insert_pos = target_block->GetLastInstruction();
1825     DCHECK(insert_pos->IsControlFlow());
1826     // Avoid splitting HCondition from HIf to prevent unnecessary materialization.
1827     if (insert_pos->IsIf()) {
1828       HInstruction* if_input = insert_pos->AsIf()->InputAt(0);
1829       if (if_input == insert_pos->GetPrevious()) {
1830         insert_pos = if_input;
1831       }
1832     }
1833   }
1834   MoveBefore(insert_pos);
1835 }
1836 
SplitBefore(HInstruction * cursor)1837 HBasicBlock* HBasicBlock::SplitBefore(HInstruction* cursor) {
1838   DCHECK(!graph_->IsInSsaForm()) << "Support for SSA form not implemented.";
1839   DCHECK_EQ(cursor->GetBlock(), this);
1840 
1841   HBasicBlock* new_block =
1842       new (GetGraph()->GetAllocator()) HBasicBlock(GetGraph(), cursor->GetDexPc());
1843   new_block->instructions_.first_instruction_ = cursor;
1844   new_block->instructions_.last_instruction_ = instructions_.last_instruction_;
1845   instructions_.last_instruction_ = cursor->previous_;
1846   if (cursor->previous_ == nullptr) {
1847     instructions_.first_instruction_ = nullptr;
1848   } else {
1849     cursor->previous_->next_ = nullptr;
1850     cursor->previous_ = nullptr;
1851   }
1852 
1853   new_block->instructions_.SetBlockOfInstructions(new_block);
1854   AddInstruction(new (GetGraph()->GetAllocator()) HGoto(new_block->GetDexPc()));
1855 
1856   for (HBasicBlock* successor : GetSuccessors()) {
1857     successor->predecessors_[successor->GetPredecessorIndexOf(this)] = new_block;
1858   }
1859   new_block->successors_.swap(successors_);
1860   DCHECK(successors_.empty());
1861   AddSuccessor(new_block);
1862 
1863   GetGraph()->AddBlock(new_block);
1864   return new_block;
1865 }
1866 
CreateImmediateDominator()1867 HBasicBlock* HBasicBlock::CreateImmediateDominator() {
1868   DCHECK(!graph_->IsInSsaForm()) << "Support for SSA form not implemented.";
1869   DCHECK(!IsCatchBlock()) << "Support for updating try/catch information not implemented.";
1870 
1871   HBasicBlock* new_block = new (GetGraph()->GetAllocator()) HBasicBlock(GetGraph(), GetDexPc());
1872 
1873   for (HBasicBlock* predecessor : GetPredecessors()) {
1874     predecessor->successors_[predecessor->GetSuccessorIndexOf(this)] = new_block;
1875   }
1876   new_block->predecessors_.swap(predecessors_);
1877   DCHECK(predecessors_.empty());
1878   AddPredecessor(new_block);
1879 
1880   GetGraph()->AddBlock(new_block);
1881   return new_block;
1882 }
1883 
SplitBeforeForInlining(HInstruction * cursor)1884 HBasicBlock* HBasicBlock::SplitBeforeForInlining(HInstruction* cursor) {
1885   DCHECK_EQ(cursor->GetBlock(), this);
1886 
1887   HBasicBlock* new_block =
1888       new (GetGraph()->GetAllocator()) HBasicBlock(GetGraph(), cursor->GetDexPc());
1889   new_block->instructions_.first_instruction_ = cursor;
1890   new_block->instructions_.last_instruction_ = instructions_.last_instruction_;
1891   instructions_.last_instruction_ = cursor->previous_;
1892   if (cursor->previous_ == nullptr) {
1893     instructions_.first_instruction_ = nullptr;
1894   } else {
1895     cursor->previous_->next_ = nullptr;
1896     cursor->previous_ = nullptr;
1897   }
1898 
1899   new_block->instructions_.SetBlockOfInstructions(new_block);
1900 
1901   for (HBasicBlock* successor : GetSuccessors()) {
1902     successor->predecessors_[successor->GetPredecessorIndexOf(this)] = new_block;
1903   }
1904   new_block->successors_.swap(successors_);
1905   DCHECK(successors_.empty());
1906 
1907   for (HBasicBlock* dominated : GetDominatedBlocks()) {
1908     dominated->dominator_ = new_block;
1909   }
1910   new_block->dominated_blocks_.swap(dominated_blocks_);
1911   DCHECK(dominated_blocks_.empty());
1912   return new_block;
1913 }
1914 
SplitAfterForInlining(HInstruction * cursor)1915 HBasicBlock* HBasicBlock::SplitAfterForInlining(HInstruction* cursor) {
1916   DCHECK(!cursor->IsControlFlow());
1917   DCHECK_NE(instructions_.last_instruction_, cursor);
1918   DCHECK_EQ(cursor->GetBlock(), this);
1919 
1920   HBasicBlock* new_block = new (GetGraph()->GetAllocator()) HBasicBlock(GetGraph(), GetDexPc());
1921   new_block->instructions_.first_instruction_ = cursor->GetNext();
1922   new_block->instructions_.last_instruction_ = instructions_.last_instruction_;
1923   cursor->next_->previous_ = nullptr;
1924   cursor->next_ = nullptr;
1925   instructions_.last_instruction_ = cursor;
1926 
1927   new_block->instructions_.SetBlockOfInstructions(new_block);
1928   for (HBasicBlock* successor : GetSuccessors()) {
1929     successor->predecessors_[successor->GetPredecessorIndexOf(this)] = new_block;
1930   }
1931   new_block->successors_.swap(successors_);
1932   DCHECK(successors_.empty());
1933 
1934   for (HBasicBlock* dominated : GetDominatedBlocks()) {
1935     dominated->dominator_ = new_block;
1936   }
1937   new_block->dominated_blocks_.swap(dominated_blocks_);
1938   DCHECK(dominated_blocks_.empty());
1939   return new_block;
1940 }
1941 
ComputeTryEntryOfSuccessors() const1942 const HTryBoundary* HBasicBlock::ComputeTryEntryOfSuccessors() const {
1943   if (EndsWithTryBoundary()) {
1944     HTryBoundary* try_boundary = GetLastInstruction()->AsTryBoundary();
1945     if (try_boundary->IsEntry()) {
1946       DCHECK(!IsTryBlock());
1947       return try_boundary;
1948     } else {
1949       DCHECK(IsTryBlock());
1950       DCHECK(try_catch_information_->GetTryEntry().HasSameExceptionHandlersAs(*try_boundary));
1951       return nullptr;
1952     }
1953   } else if (IsTryBlock()) {
1954     return &try_catch_information_->GetTryEntry();
1955   } else {
1956     return nullptr;
1957   }
1958 }
1959 
HasThrowingInstructions() const1960 bool HBasicBlock::HasThrowingInstructions() const {
1961   for (HInstructionIterator it(GetInstructions()); !it.Done(); it.Advance()) {
1962     if (it.Current()->CanThrow()) {
1963       return true;
1964     }
1965   }
1966   return false;
1967 }
1968 
HasOnlyOneInstruction(const HBasicBlock & block)1969 static bool HasOnlyOneInstruction(const HBasicBlock& block) {
1970   return block.GetPhis().IsEmpty()
1971       && !block.GetInstructions().IsEmpty()
1972       && block.GetFirstInstruction() == block.GetLastInstruction();
1973 }
1974 
IsSingleGoto() const1975 bool HBasicBlock::IsSingleGoto() const {
1976   return HasOnlyOneInstruction(*this) && GetLastInstruction()->IsGoto();
1977 }
1978 
IsSingleReturn() const1979 bool HBasicBlock::IsSingleReturn() const {
1980   return HasOnlyOneInstruction(*this) && GetLastInstruction()->IsReturn();
1981 }
1982 
IsSingleReturnOrReturnVoidAllowingPhis() const1983 bool HBasicBlock::IsSingleReturnOrReturnVoidAllowingPhis() const {
1984   return (GetFirstInstruction() == GetLastInstruction()) &&
1985          (GetLastInstruction()->IsReturn() || GetLastInstruction()->IsReturnVoid());
1986 }
1987 
IsSingleTryBoundary() const1988 bool HBasicBlock::IsSingleTryBoundary() const {
1989   return HasOnlyOneInstruction(*this) && GetLastInstruction()->IsTryBoundary();
1990 }
1991 
EndsWithControlFlowInstruction() const1992 bool HBasicBlock::EndsWithControlFlowInstruction() const {
1993   return !GetInstructions().IsEmpty() && GetLastInstruction()->IsControlFlow();
1994 }
1995 
EndsWithReturn() const1996 bool HBasicBlock::EndsWithReturn() const {
1997   return !GetInstructions().IsEmpty() &&
1998       (GetLastInstruction()->IsReturn() || GetLastInstruction()->IsReturnVoid());
1999 }
2000 
EndsWithIf() const2001 bool HBasicBlock::EndsWithIf() const {
2002   return !GetInstructions().IsEmpty() && GetLastInstruction()->IsIf();
2003 }
2004 
EndsWithTryBoundary() const2005 bool HBasicBlock::EndsWithTryBoundary() const {
2006   return !GetInstructions().IsEmpty() && GetLastInstruction()->IsTryBoundary();
2007 }
2008 
HasSinglePhi() const2009 bool HBasicBlock::HasSinglePhi() const {
2010   return !GetPhis().IsEmpty() && GetFirstPhi()->GetNext() == nullptr;
2011 }
2012 
GetNormalSuccessors() const2013 ArrayRef<HBasicBlock* const> HBasicBlock::GetNormalSuccessors() const {
2014   if (EndsWithTryBoundary()) {
2015     // The normal-flow successor of HTryBoundary is always stored at index zero.
2016     DCHECK_EQ(successors_[0], GetLastInstruction()->AsTryBoundary()->GetNormalFlowSuccessor());
2017     return ArrayRef<HBasicBlock* const>(successors_).SubArray(0u, 1u);
2018   } else {
2019     // All successors of blocks not ending with TryBoundary are normal.
2020     return ArrayRef<HBasicBlock* const>(successors_);
2021   }
2022 }
2023 
GetExceptionalSuccessors() const2024 ArrayRef<HBasicBlock* const> HBasicBlock::GetExceptionalSuccessors() const {
2025   if (EndsWithTryBoundary()) {
2026     return GetLastInstruction()->AsTryBoundary()->GetExceptionHandlers();
2027   } else {
2028     // Blocks not ending with TryBoundary do not have exceptional successors.
2029     return ArrayRef<HBasicBlock* const>();
2030   }
2031 }
2032 
HasSameExceptionHandlersAs(const HTryBoundary & other) const2033 bool HTryBoundary::HasSameExceptionHandlersAs(const HTryBoundary& other) const {
2034   ArrayRef<HBasicBlock* const> handlers1 = GetExceptionHandlers();
2035   ArrayRef<HBasicBlock* const> handlers2 = other.GetExceptionHandlers();
2036 
2037   size_t length = handlers1.size();
2038   if (length != handlers2.size()) {
2039     return false;
2040   }
2041 
2042   // Exception handlers need to be stored in the same order.
2043   for (size_t i = 0; i < length; ++i) {
2044     if (handlers1[i] != handlers2[i]) {
2045       return false;
2046     }
2047   }
2048   return true;
2049 }
2050 
CountSize() const2051 size_t HInstructionList::CountSize() const {
2052   size_t size = 0;
2053   HInstruction* current = first_instruction_;
2054   for (; current != nullptr; current = current->GetNext()) {
2055     size++;
2056   }
2057   return size;
2058 }
2059 
SetBlockOfInstructions(HBasicBlock * block) const2060 void HInstructionList::SetBlockOfInstructions(HBasicBlock* block) const {
2061   for (HInstruction* current = first_instruction_;
2062        current != nullptr;
2063        current = current->GetNext()) {
2064     current->SetBlock(block);
2065   }
2066 }
2067 
AddAfter(HInstruction * cursor,const HInstructionList & instruction_list)2068 void HInstructionList::AddAfter(HInstruction* cursor, const HInstructionList& instruction_list) {
2069   DCHECK(Contains(cursor));
2070   if (!instruction_list.IsEmpty()) {
2071     if (cursor == last_instruction_) {
2072       last_instruction_ = instruction_list.last_instruction_;
2073     } else {
2074       cursor->next_->previous_ = instruction_list.last_instruction_;
2075     }
2076     instruction_list.last_instruction_->next_ = cursor->next_;
2077     cursor->next_ = instruction_list.first_instruction_;
2078     instruction_list.first_instruction_->previous_ = cursor;
2079   }
2080 }
2081 
AddBefore(HInstruction * cursor,const HInstructionList & instruction_list)2082 void HInstructionList::AddBefore(HInstruction* cursor, const HInstructionList& instruction_list) {
2083   DCHECK(Contains(cursor));
2084   if (!instruction_list.IsEmpty()) {
2085     if (cursor == first_instruction_) {
2086       first_instruction_ = instruction_list.first_instruction_;
2087     } else {
2088       cursor->previous_->next_ = instruction_list.first_instruction_;
2089     }
2090     instruction_list.last_instruction_->next_ = cursor;
2091     instruction_list.first_instruction_->previous_ = cursor->previous_;
2092     cursor->previous_ = instruction_list.last_instruction_;
2093   }
2094 }
2095 
Add(const HInstructionList & instruction_list)2096 void HInstructionList::Add(const HInstructionList& instruction_list) {
2097   if (IsEmpty()) {
2098     first_instruction_ = instruction_list.first_instruction_;
2099     last_instruction_ = instruction_list.last_instruction_;
2100   } else {
2101     AddAfter(last_instruction_, instruction_list);
2102   }
2103 }
2104 
2105 // Should be called on instructions in a dead block in post order. This method
2106 // assumes `insn` has been removed from all users with the exception of catch
2107 // phis because of missing exceptional edges in the graph. It removes the
2108 // instruction from catch phi uses, together with inputs of other catch phis in
2109 // the catch block at the same index, as these must be dead too.
RemoveUsesOfDeadInstruction(HInstruction * insn)2110 static void RemoveUsesOfDeadInstruction(HInstruction* insn) {
2111   DCHECK(!insn->HasEnvironmentUses());
2112   while (insn->HasNonEnvironmentUses()) {
2113     const HUseListNode<HInstruction*>& use = insn->GetUses().front();
2114     size_t use_index = use.GetIndex();
2115     HBasicBlock* user_block =  use.GetUser()->GetBlock();
2116     DCHECK(use.GetUser()->IsPhi() && user_block->IsCatchBlock());
2117     for (HInstructionIterator phi_it(user_block->GetPhis()); !phi_it.Done(); phi_it.Advance()) {
2118       phi_it.Current()->AsPhi()->RemoveInputAt(use_index);
2119     }
2120   }
2121 }
2122 
DisconnectAndDelete()2123 void HBasicBlock::DisconnectAndDelete() {
2124   // Dominators must be removed after all the blocks they dominate. This way
2125   // a loop header is removed last, a requirement for correct loop information
2126   // iteration.
2127   DCHECK(dominated_blocks_.empty());
2128 
2129   // The following steps gradually remove the block from all its dependants in
2130   // post order (b/27683071).
2131 
2132   // (1) Store a basic block that we'll use in step (5) to find loops to be updated.
2133   //     We need to do this before step (4) which destroys the predecessor list.
2134   HBasicBlock* loop_update_start = this;
2135   if (IsLoopHeader()) {
2136     HLoopInformation* loop_info = GetLoopInformation();
2137     // All other blocks in this loop should have been removed because the header
2138     // was their dominator.
2139     // Note that we do not remove `this` from `loop_info` as it is unreachable.
2140     DCHECK(!loop_info->IsIrreducible());
2141     DCHECK_EQ(loop_info->GetBlocks().NumSetBits(), 1u);
2142     DCHECK_EQ(static_cast<uint32_t>(loop_info->GetBlocks().GetHighestBitSet()), GetBlockId());
2143     loop_update_start = loop_info->GetPreHeader();
2144   }
2145 
2146   // (2) Disconnect the block from its successors and update their phis.
2147   for (HBasicBlock* successor : successors_) {
2148     // Delete this block from the list of predecessors.
2149     size_t this_index = successor->GetPredecessorIndexOf(this);
2150     successor->predecessors_.erase(successor->predecessors_.begin() + this_index);
2151 
2152     // Check that `successor` has other predecessors, otherwise `this` is the
2153     // dominator of `successor` which violates the order DCHECKed at the top.
2154     DCHECK(!successor->predecessors_.empty());
2155 
2156     // Remove this block's entries in the successor's phis. Skip exceptional
2157     // successors because catch phi inputs do not correspond to predecessor
2158     // blocks but throwing instructions. The inputs of the catch phis will be
2159     // updated in step (3).
2160     if (!successor->IsCatchBlock()) {
2161       if (successor->predecessors_.size() == 1u) {
2162         // The successor has just one predecessor left. Replace phis with the only
2163         // remaining input.
2164         for (HInstructionIterator phi_it(successor->GetPhis()); !phi_it.Done(); phi_it.Advance()) {
2165           HPhi* phi = phi_it.Current()->AsPhi();
2166           phi->ReplaceWith(phi->InputAt(1 - this_index));
2167           successor->RemovePhi(phi);
2168         }
2169       } else {
2170         for (HInstructionIterator phi_it(successor->GetPhis()); !phi_it.Done(); phi_it.Advance()) {
2171           phi_it.Current()->AsPhi()->RemoveInputAt(this_index);
2172         }
2173       }
2174     }
2175   }
2176   successors_.clear();
2177 
2178   // (3) Remove instructions and phis. Instructions should have no remaining uses
2179   //     except in catch phis. If an instruction is used by a catch phi at `index`,
2180   //     remove `index`-th input of all phis in the catch block since they are
2181   //     guaranteed dead. Note that we may miss dead inputs this way but the
2182   //     graph will always remain consistent.
2183   for (HBackwardInstructionIterator it(GetInstructions()); !it.Done(); it.Advance()) {
2184     HInstruction* insn = it.Current();
2185     RemoveUsesOfDeadInstruction(insn);
2186     RemoveInstruction(insn);
2187   }
2188   for (HInstructionIterator it(GetPhis()); !it.Done(); it.Advance()) {
2189     HPhi* insn = it.Current()->AsPhi();
2190     RemoveUsesOfDeadInstruction(insn);
2191     RemovePhi(insn);
2192   }
2193 
2194   // (4) Disconnect the block from its predecessors and update their
2195   //     control-flow instructions.
2196   for (HBasicBlock* predecessor : predecessors_) {
2197     // We should not see any back edges as they would have been removed by step (3).
2198     DCHECK(!IsInLoop() || !GetLoopInformation()->IsBackEdge(*predecessor));
2199 
2200     HInstruction* last_instruction = predecessor->GetLastInstruction();
2201     if (last_instruction->IsTryBoundary() && !IsCatchBlock()) {
2202       // This block is the only normal-flow successor of the TryBoundary which
2203       // makes `predecessor` dead. Since DCE removes blocks in post order,
2204       // exception handlers of this TryBoundary were already visited and any
2205       // remaining handlers therefore must be live. We remove `predecessor` from
2206       // their list of predecessors.
2207       DCHECK_EQ(last_instruction->AsTryBoundary()->GetNormalFlowSuccessor(), this);
2208       while (predecessor->GetSuccessors().size() > 1) {
2209         HBasicBlock* handler = predecessor->GetSuccessors()[1];
2210         DCHECK(handler->IsCatchBlock());
2211         predecessor->RemoveSuccessor(handler);
2212         handler->RemovePredecessor(predecessor);
2213       }
2214     }
2215 
2216     predecessor->RemoveSuccessor(this);
2217     uint32_t num_pred_successors = predecessor->GetSuccessors().size();
2218     if (num_pred_successors == 1u) {
2219       // If we have one successor after removing one, then we must have
2220       // had an HIf, HPackedSwitch or HTryBoundary, as they have more than one
2221       // successor. Replace those with a HGoto.
2222       DCHECK(last_instruction->IsIf() ||
2223              last_instruction->IsPackedSwitch() ||
2224              (last_instruction->IsTryBoundary() && IsCatchBlock()));
2225       predecessor->RemoveInstruction(last_instruction);
2226       predecessor->AddInstruction(new (graph_->GetAllocator()) HGoto(last_instruction->GetDexPc()));
2227     } else if (num_pred_successors == 0u) {
2228       // The predecessor has no remaining successors and therefore must be dead.
2229       // We deliberately leave it without a control-flow instruction so that the
2230       // GraphChecker fails unless it is not removed during the pass too.
2231       predecessor->RemoveInstruction(last_instruction);
2232     } else {
2233       // There are multiple successors left. The removed block might be a successor
2234       // of a PackedSwitch which will be completely removed (perhaps replaced with
2235       // a Goto), or we are deleting a catch block from a TryBoundary. In either
2236       // case, leave `last_instruction` as is for now.
2237       DCHECK(last_instruction->IsPackedSwitch() ||
2238              (last_instruction->IsTryBoundary() && IsCatchBlock()));
2239     }
2240   }
2241   predecessors_.clear();
2242 
2243   // (5) Remove the block from all loops it is included in. Skip the inner-most
2244   //     loop if this is the loop header (see definition of `loop_update_start`)
2245   //     because the loop header's predecessor list has been destroyed in step (4).
2246   for (HLoopInformationOutwardIterator it(*loop_update_start); !it.Done(); it.Advance()) {
2247     HLoopInformation* loop_info = it.Current();
2248     loop_info->Remove(this);
2249     if (loop_info->IsBackEdge(*this)) {
2250       // If this was the last back edge of the loop, we deliberately leave the
2251       // loop in an inconsistent state and will fail GraphChecker unless the
2252       // entire loop is removed during the pass.
2253       loop_info->RemoveBackEdge(this);
2254     }
2255   }
2256 
2257   // (6) Disconnect from the dominator.
2258   dominator_->RemoveDominatedBlock(this);
2259   SetDominator(nullptr);
2260 
2261   // (7) Delete from the graph, update reverse post order.
2262   graph_->DeleteDeadEmptyBlock(this);
2263   SetGraph(nullptr);
2264 }
2265 
MergeInstructionsWith(HBasicBlock * other)2266 void HBasicBlock::MergeInstructionsWith(HBasicBlock* other) {
2267   DCHECK(EndsWithControlFlowInstruction());
2268   RemoveInstruction(GetLastInstruction());
2269   instructions_.Add(other->GetInstructions());
2270   other->instructions_.SetBlockOfInstructions(this);
2271   other->instructions_.Clear();
2272 }
2273 
MergeWith(HBasicBlock * other)2274 void HBasicBlock::MergeWith(HBasicBlock* other) {
2275   DCHECK_EQ(GetGraph(), other->GetGraph());
2276   DCHECK(ContainsElement(dominated_blocks_, other));
2277   DCHECK_EQ(GetSingleSuccessor(), other);
2278   DCHECK_EQ(other->GetSinglePredecessor(), this);
2279   DCHECK(other->GetPhis().IsEmpty());
2280 
2281   // Move instructions from `other` to `this`.
2282   MergeInstructionsWith(other);
2283 
2284   // Remove `other` from the loops it is included in.
2285   for (HLoopInformationOutwardIterator it(*other); !it.Done(); it.Advance()) {
2286     HLoopInformation* loop_info = it.Current();
2287     loop_info->Remove(other);
2288     if (loop_info->IsBackEdge(*other)) {
2289       loop_info->ReplaceBackEdge(other, this);
2290     }
2291   }
2292 
2293   // Update links to the successors of `other`.
2294   successors_.clear();
2295   for (HBasicBlock* successor : other->GetSuccessors()) {
2296     successor->predecessors_[successor->GetPredecessorIndexOf(other)] = this;
2297   }
2298   successors_.swap(other->successors_);
2299   DCHECK(other->successors_.empty());
2300 
2301   // Update the dominator tree.
2302   RemoveDominatedBlock(other);
2303   for (HBasicBlock* dominated : other->GetDominatedBlocks()) {
2304     dominated->SetDominator(this);
2305   }
2306   dominated_blocks_.insert(
2307       dominated_blocks_.end(), other->dominated_blocks_.begin(), other->dominated_blocks_.end());
2308   other->dominated_blocks_.clear();
2309   other->dominator_ = nullptr;
2310 
2311   // Clear the list of predecessors of `other` in preparation of deleting it.
2312   other->predecessors_.clear();
2313 
2314   // Delete `other` from the graph. The function updates reverse post order.
2315   graph_->DeleteDeadEmptyBlock(other);
2316   other->SetGraph(nullptr);
2317 }
2318 
MergeWithInlined(HBasicBlock * other)2319 void HBasicBlock::MergeWithInlined(HBasicBlock* other) {
2320   DCHECK_NE(GetGraph(), other->GetGraph());
2321   DCHECK(GetDominatedBlocks().empty());
2322   DCHECK(GetSuccessors().empty());
2323   DCHECK(!EndsWithControlFlowInstruction());
2324   DCHECK(other->GetSinglePredecessor()->IsEntryBlock());
2325   DCHECK(other->GetPhis().IsEmpty());
2326   DCHECK(!other->IsInLoop());
2327 
2328   // Move instructions from `other` to `this`.
2329   instructions_.Add(other->GetInstructions());
2330   other->instructions_.SetBlockOfInstructions(this);
2331 
2332   // Update links to the successors of `other`.
2333   successors_.clear();
2334   for (HBasicBlock* successor : other->GetSuccessors()) {
2335     successor->predecessors_[successor->GetPredecessorIndexOf(other)] = this;
2336   }
2337   successors_.swap(other->successors_);
2338   DCHECK(other->successors_.empty());
2339 
2340   // Update the dominator tree.
2341   for (HBasicBlock* dominated : other->GetDominatedBlocks()) {
2342     dominated->SetDominator(this);
2343   }
2344   dominated_blocks_.insert(
2345       dominated_blocks_.end(), other->dominated_blocks_.begin(), other->dominated_blocks_.end());
2346   other->dominated_blocks_.clear();
2347   other->dominator_ = nullptr;
2348   other->graph_ = nullptr;
2349 }
2350 
ReplaceWith(HBasicBlock * other)2351 void HBasicBlock::ReplaceWith(HBasicBlock* other) {
2352   while (!GetPredecessors().empty()) {
2353     HBasicBlock* predecessor = GetPredecessors()[0];
2354     predecessor->ReplaceSuccessor(this, other);
2355   }
2356   while (!GetSuccessors().empty()) {
2357     HBasicBlock* successor = GetSuccessors()[0];
2358     successor->ReplacePredecessor(this, other);
2359   }
2360   for (HBasicBlock* dominated : GetDominatedBlocks()) {
2361     other->AddDominatedBlock(dominated);
2362   }
2363   GetDominator()->ReplaceDominatedBlock(this, other);
2364   other->SetDominator(GetDominator());
2365   dominator_ = nullptr;
2366   graph_ = nullptr;
2367 }
2368 
DeleteDeadEmptyBlock(HBasicBlock * block)2369 void HGraph::DeleteDeadEmptyBlock(HBasicBlock* block) {
2370   DCHECK_EQ(block->GetGraph(), this);
2371   DCHECK(block->GetSuccessors().empty());
2372   DCHECK(block->GetPredecessors().empty());
2373   DCHECK(block->GetDominatedBlocks().empty());
2374   DCHECK(block->GetDominator() == nullptr);
2375   DCHECK(block->GetInstructions().IsEmpty());
2376   DCHECK(block->GetPhis().IsEmpty());
2377 
2378   if (block->IsExitBlock()) {
2379     SetExitBlock(nullptr);
2380   }
2381 
2382   RemoveElement(reverse_post_order_, block);
2383   blocks_[block->GetBlockId()] = nullptr;
2384   block->SetGraph(nullptr);
2385 }
2386 
UpdateLoopAndTryInformationOfNewBlock(HBasicBlock * block,HBasicBlock * reference,bool replace_if_back_edge)2387 void HGraph::UpdateLoopAndTryInformationOfNewBlock(HBasicBlock* block,
2388                                                    HBasicBlock* reference,
2389                                                    bool replace_if_back_edge) {
2390   if (block->IsLoopHeader()) {
2391     // Clear the information of which blocks are contained in that loop. Since the
2392     // information is stored as a bit vector based on block ids, we have to update
2393     // it, as those block ids were specific to the callee graph and we are now adding
2394     // these blocks to the caller graph.
2395     block->GetLoopInformation()->ClearAllBlocks();
2396   }
2397 
2398   // If not already in a loop, update the loop information.
2399   if (!block->IsInLoop()) {
2400     block->SetLoopInformation(reference->GetLoopInformation());
2401   }
2402 
2403   // If the block is in a loop, update all its outward loops.
2404   HLoopInformation* loop_info = block->GetLoopInformation();
2405   if (loop_info != nullptr) {
2406     for (HLoopInformationOutwardIterator loop_it(*block);
2407          !loop_it.Done();
2408          loop_it.Advance()) {
2409       loop_it.Current()->Add(block);
2410     }
2411     if (replace_if_back_edge && loop_info->IsBackEdge(*reference)) {
2412       loop_info->ReplaceBackEdge(reference, block);
2413     }
2414   }
2415 
2416   // Copy TryCatchInformation if `reference` is a try block, not if it is a catch block.
2417   TryCatchInformation* try_catch_info = reference->IsTryBlock()
2418       ? reference->GetTryCatchInformation()
2419       : nullptr;
2420   block->SetTryCatchInformation(try_catch_info);
2421 }
2422 
InlineInto(HGraph * outer_graph,HInvoke * invoke)2423 HInstruction* HGraph::InlineInto(HGraph* outer_graph, HInvoke* invoke) {
2424   DCHECK(HasExitBlock()) << "Unimplemented scenario";
2425   // Update the environments in this graph to have the invoke's environment
2426   // as parent.
2427   {
2428     // Skip the entry block, we do not need to update the entry's suspend check.
2429     for (HBasicBlock* block : GetReversePostOrderSkipEntryBlock()) {
2430       for (HInstructionIterator instr_it(block->GetInstructions());
2431            !instr_it.Done();
2432            instr_it.Advance()) {
2433         HInstruction* current = instr_it.Current();
2434         if (current->NeedsEnvironment()) {
2435           DCHECK(current->HasEnvironment());
2436           current->GetEnvironment()->SetAndCopyParentChain(
2437               outer_graph->GetAllocator(), invoke->GetEnvironment());
2438         }
2439       }
2440     }
2441   }
2442   outer_graph->UpdateMaximumNumberOfOutVRegs(GetMaximumNumberOfOutVRegs());
2443 
2444   if (HasBoundsChecks()) {
2445     outer_graph->SetHasBoundsChecks(true);
2446   }
2447   if (HasLoops()) {
2448     outer_graph->SetHasLoops(true);
2449   }
2450   if (HasIrreducibleLoops()) {
2451     outer_graph->SetHasIrreducibleLoops(true);
2452   }
2453   if (HasTryCatch()) {
2454     outer_graph->SetHasTryCatch(true);
2455   }
2456   if (HasSIMD()) {
2457     outer_graph->SetHasSIMD(true);
2458   }
2459 
2460   HInstruction* return_value = nullptr;
2461   if (GetBlocks().size() == 3) {
2462     // Inliner already made sure we don't inline methods that always throw.
2463     DCHECK(!GetBlocks()[1]->GetLastInstruction()->IsThrow());
2464     // Simple case of an entry block, a body block, and an exit block.
2465     // Put the body block's instruction into `invoke`'s block.
2466     HBasicBlock* body = GetBlocks()[1];
2467     DCHECK(GetBlocks()[0]->IsEntryBlock());
2468     DCHECK(GetBlocks()[2]->IsExitBlock());
2469     DCHECK(!body->IsExitBlock());
2470     DCHECK(!body->IsInLoop());
2471     HInstruction* last = body->GetLastInstruction();
2472 
2473     // Note that we add instructions before the invoke only to simplify polymorphic inlining.
2474     invoke->GetBlock()->instructions_.AddBefore(invoke, body->GetInstructions());
2475     body->GetInstructions().SetBlockOfInstructions(invoke->GetBlock());
2476 
2477     // Replace the invoke with the return value of the inlined graph.
2478     if (last->IsReturn()) {
2479       return_value = last->InputAt(0);
2480     } else {
2481       DCHECK(last->IsReturnVoid());
2482     }
2483 
2484     invoke->GetBlock()->RemoveInstruction(last);
2485   } else {
2486     // Need to inline multiple blocks. We split `invoke`'s block
2487     // into two blocks, merge the first block of the inlined graph into
2488     // the first half, and replace the exit block of the inlined graph
2489     // with the second half.
2490     ArenaAllocator* allocator = outer_graph->GetAllocator();
2491     HBasicBlock* at = invoke->GetBlock();
2492     // Note that we split before the invoke only to simplify polymorphic inlining.
2493     HBasicBlock* to = at->SplitBeforeForInlining(invoke);
2494 
2495     HBasicBlock* first = entry_block_->GetSuccessors()[0];
2496     DCHECK(!first->IsInLoop());
2497     at->MergeWithInlined(first);
2498     exit_block_->ReplaceWith(to);
2499 
2500     // Update the meta information surrounding blocks:
2501     // (1) the graph they are now in,
2502     // (2) the reverse post order of that graph,
2503     // (3) their potential loop information, inner and outer,
2504     // (4) try block membership.
2505     // Note that we do not need to update catch phi inputs because they
2506     // correspond to the register file of the outer method which the inlinee
2507     // cannot modify.
2508 
2509     // We don't add the entry block, the exit block, and the first block, which
2510     // has been merged with `at`.
2511     static constexpr int kNumberOfSkippedBlocksInCallee = 3;
2512 
2513     // We add the `to` block.
2514     static constexpr int kNumberOfNewBlocksInCaller = 1;
2515     size_t blocks_added = (reverse_post_order_.size() - kNumberOfSkippedBlocksInCallee)
2516         + kNumberOfNewBlocksInCaller;
2517 
2518     // Find the location of `at` in the outer graph's reverse post order. The new
2519     // blocks will be added after it.
2520     size_t index_of_at = IndexOfElement(outer_graph->reverse_post_order_, at);
2521     MakeRoomFor(&outer_graph->reverse_post_order_, blocks_added, index_of_at);
2522 
2523     // Do a reverse post order of the blocks in the callee and do (1), (2), (3)
2524     // and (4) to the blocks that apply.
2525     for (HBasicBlock* current : GetReversePostOrder()) {
2526       if (current != exit_block_ && current != entry_block_ && current != first) {
2527         DCHECK(current->GetTryCatchInformation() == nullptr);
2528         DCHECK(current->GetGraph() == this);
2529         current->SetGraph(outer_graph);
2530         outer_graph->AddBlock(current);
2531         outer_graph->reverse_post_order_[++index_of_at] = current;
2532         UpdateLoopAndTryInformationOfNewBlock(current, at,  /* replace_if_back_edge= */ false);
2533       }
2534     }
2535 
2536     // Do (1), (2), (3) and (4) to `to`.
2537     to->SetGraph(outer_graph);
2538     outer_graph->AddBlock(to);
2539     outer_graph->reverse_post_order_[++index_of_at] = to;
2540     // Only `to` can become a back edge, as the inlined blocks
2541     // are predecessors of `to`.
2542     UpdateLoopAndTryInformationOfNewBlock(to, at, /* replace_if_back_edge= */ true);
2543 
2544     // Update all predecessors of the exit block (now the `to` block)
2545     // to not `HReturn` but `HGoto` instead. Special case throwing blocks
2546     // to now get the outer graph exit block as successor. Note that the inliner
2547     // currently doesn't support inlining methods with try/catch.
2548     HPhi* return_value_phi = nullptr;
2549     bool rerun_dominance = false;
2550     bool rerun_loop_analysis = false;
2551     for (size_t pred = 0; pred < to->GetPredecessors().size(); ++pred) {
2552       HBasicBlock* predecessor = to->GetPredecessors()[pred];
2553       HInstruction* last = predecessor->GetLastInstruction();
2554       if (last->IsThrow()) {
2555         DCHECK(!at->IsTryBlock());
2556         predecessor->ReplaceSuccessor(to, outer_graph->GetExitBlock());
2557         --pred;
2558         // We need to re-run dominance information, as the exit block now has
2559         // a new dominator.
2560         rerun_dominance = true;
2561         if (predecessor->GetLoopInformation() != nullptr) {
2562           // The exit block and blocks post dominated by the exit block do not belong
2563           // to any loop. Because we do not compute the post dominators, we need to re-run
2564           // loop analysis to get the loop information correct.
2565           rerun_loop_analysis = true;
2566         }
2567       } else {
2568         if (last->IsReturnVoid()) {
2569           DCHECK(return_value == nullptr);
2570           DCHECK(return_value_phi == nullptr);
2571         } else {
2572           DCHECK(last->IsReturn());
2573           if (return_value_phi != nullptr) {
2574             return_value_phi->AddInput(last->InputAt(0));
2575           } else if (return_value == nullptr) {
2576             return_value = last->InputAt(0);
2577           } else {
2578             // There will be multiple returns.
2579             return_value_phi = new (allocator) HPhi(
2580                 allocator, kNoRegNumber, 0, HPhi::ToPhiType(invoke->GetType()), to->GetDexPc());
2581             to->AddPhi(return_value_phi);
2582             return_value_phi->AddInput(return_value);
2583             return_value_phi->AddInput(last->InputAt(0));
2584             return_value = return_value_phi;
2585           }
2586         }
2587         predecessor->AddInstruction(new (allocator) HGoto(last->GetDexPc()));
2588         predecessor->RemoveInstruction(last);
2589       }
2590     }
2591     if (rerun_loop_analysis) {
2592       DCHECK(!outer_graph->HasIrreducibleLoops())
2593           << "Recomputing loop information in graphs with irreducible loops "
2594           << "is unsupported, as it could lead to loop header changes";
2595       outer_graph->ClearLoopInformation();
2596       outer_graph->ClearDominanceInformation();
2597       outer_graph->BuildDominatorTree();
2598     } else if (rerun_dominance) {
2599       outer_graph->ClearDominanceInformation();
2600       outer_graph->ComputeDominanceInformation();
2601     }
2602   }
2603 
2604   // Walk over the entry block and:
2605   // - Move constants from the entry block to the outer_graph's entry block,
2606   // - Replace HParameterValue instructions with their real value.
2607   // - Remove suspend checks, that hold an environment.
2608   // We must do this after the other blocks have been inlined, otherwise ids of
2609   // constants could overlap with the inner graph.
2610   size_t parameter_index = 0;
2611   for (HInstructionIterator it(entry_block_->GetInstructions()); !it.Done(); it.Advance()) {
2612     HInstruction* current = it.Current();
2613     HInstruction* replacement = nullptr;
2614     if (current->IsNullConstant()) {
2615       replacement = outer_graph->GetNullConstant(current->GetDexPc());
2616     } else if (current->IsIntConstant()) {
2617       replacement = outer_graph->GetIntConstant(
2618           current->AsIntConstant()->GetValue(), current->GetDexPc());
2619     } else if (current->IsLongConstant()) {
2620       replacement = outer_graph->GetLongConstant(
2621           current->AsLongConstant()->GetValue(), current->GetDexPc());
2622     } else if (current->IsFloatConstant()) {
2623       replacement = outer_graph->GetFloatConstant(
2624           current->AsFloatConstant()->GetValue(), current->GetDexPc());
2625     } else if (current->IsDoubleConstant()) {
2626       replacement = outer_graph->GetDoubleConstant(
2627           current->AsDoubleConstant()->GetValue(), current->GetDexPc());
2628     } else if (current->IsParameterValue()) {
2629       if (kIsDebugBuild
2630           && invoke->IsInvokeStaticOrDirect()
2631           && invoke->AsInvokeStaticOrDirect()->IsStaticWithExplicitClinitCheck()) {
2632         // Ensure we do not use the last input of `invoke`, as it
2633         // contains a clinit check which is not an actual argument.
2634         size_t last_input_index = invoke->InputCount() - 1;
2635         DCHECK(parameter_index != last_input_index);
2636       }
2637       replacement = invoke->InputAt(parameter_index++);
2638     } else if (current->IsCurrentMethod()) {
2639       replacement = outer_graph->GetCurrentMethod();
2640     } else {
2641       DCHECK(current->IsGoto() || current->IsSuspendCheck());
2642       entry_block_->RemoveInstruction(current);
2643     }
2644     if (replacement != nullptr) {
2645       current->ReplaceWith(replacement);
2646       // If the current is the return value then we need to update the latter.
2647       if (current == return_value) {
2648         DCHECK_EQ(entry_block_, return_value->GetBlock());
2649         return_value = replacement;
2650       }
2651     }
2652   }
2653 
2654   return return_value;
2655 }
2656 
2657 /*
2658  * Loop will be transformed to:
2659  *       old_pre_header
2660  *             |
2661  *          if_block
2662  *           /    \
2663  *  true_block   false_block
2664  *           \    /
2665  *       new_pre_header
2666  *             |
2667  *           header
2668  */
TransformLoopHeaderForBCE(HBasicBlock * header)2669 void HGraph::TransformLoopHeaderForBCE(HBasicBlock* header) {
2670   DCHECK(header->IsLoopHeader());
2671   HBasicBlock* old_pre_header = header->GetDominator();
2672 
2673   // Need extra block to avoid critical edge.
2674   HBasicBlock* if_block = new (allocator_) HBasicBlock(this, header->GetDexPc());
2675   HBasicBlock* true_block = new (allocator_) HBasicBlock(this, header->GetDexPc());
2676   HBasicBlock* false_block = new (allocator_) HBasicBlock(this, header->GetDexPc());
2677   HBasicBlock* new_pre_header = new (allocator_) HBasicBlock(this, header->GetDexPc());
2678   AddBlock(if_block);
2679   AddBlock(true_block);
2680   AddBlock(false_block);
2681   AddBlock(new_pre_header);
2682 
2683   header->ReplacePredecessor(old_pre_header, new_pre_header);
2684   old_pre_header->successors_.clear();
2685   old_pre_header->dominated_blocks_.clear();
2686 
2687   old_pre_header->AddSuccessor(if_block);
2688   if_block->AddSuccessor(true_block);  // True successor
2689   if_block->AddSuccessor(false_block);  // False successor
2690   true_block->AddSuccessor(new_pre_header);
2691   false_block->AddSuccessor(new_pre_header);
2692 
2693   old_pre_header->dominated_blocks_.push_back(if_block);
2694   if_block->SetDominator(old_pre_header);
2695   if_block->dominated_blocks_.push_back(true_block);
2696   true_block->SetDominator(if_block);
2697   if_block->dominated_blocks_.push_back(false_block);
2698   false_block->SetDominator(if_block);
2699   if_block->dominated_blocks_.push_back(new_pre_header);
2700   new_pre_header->SetDominator(if_block);
2701   new_pre_header->dominated_blocks_.push_back(header);
2702   header->SetDominator(new_pre_header);
2703 
2704   // Fix reverse post order.
2705   size_t index_of_header = IndexOfElement(reverse_post_order_, header);
2706   MakeRoomFor(&reverse_post_order_, 4, index_of_header - 1);
2707   reverse_post_order_[index_of_header++] = if_block;
2708   reverse_post_order_[index_of_header++] = true_block;
2709   reverse_post_order_[index_of_header++] = false_block;
2710   reverse_post_order_[index_of_header++] = new_pre_header;
2711 
2712   // The pre_header can never be a back edge of a loop.
2713   DCHECK((old_pre_header->GetLoopInformation() == nullptr) ||
2714          !old_pre_header->GetLoopInformation()->IsBackEdge(*old_pre_header));
2715   UpdateLoopAndTryInformationOfNewBlock(
2716       if_block, old_pre_header, /* replace_if_back_edge= */ false);
2717   UpdateLoopAndTryInformationOfNewBlock(
2718       true_block, old_pre_header, /* replace_if_back_edge= */ false);
2719   UpdateLoopAndTryInformationOfNewBlock(
2720       false_block, old_pre_header, /* replace_if_back_edge= */ false);
2721   UpdateLoopAndTryInformationOfNewBlock(
2722       new_pre_header, old_pre_header, /* replace_if_back_edge= */ false);
2723 }
2724 
TransformLoopForVectorization(HBasicBlock * header,HBasicBlock * body,HBasicBlock * exit)2725 HBasicBlock* HGraph::TransformLoopForVectorization(HBasicBlock* header,
2726                                                    HBasicBlock* body,
2727                                                    HBasicBlock* exit) {
2728   DCHECK(header->IsLoopHeader());
2729   HLoopInformation* loop = header->GetLoopInformation();
2730 
2731   // Add new loop blocks.
2732   HBasicBlock* new_pre_header = new (allocator_) HBasicBlock(this, header->GetDexPc());
2733   HBasicBlock* new_header = new (allocator_) HBasicBlock(this, header->GetDexPc());
2734   HBasicBlock* new_body = new (allocator_) HBasicBlock(this, header->GetDexPc());
2735   AddBlock(new_pre_header);
2736   AddBlock(new_header);
2737   AddBlock(new_body);
2738 
2739   // Set up control flow.
2740   header->ReplaceSuccessor(exit, new_pre_header);
2741   new_pre_header->AddSuccessor(new_header);
2742   new_header->AddSuccessor(exit);
2743   new_header->AddSuccessor(new_body);
2744   new_body->AddSuccessor(new_header);
2745 
2746   // Set up dominators.
2747   header->ReplaceDominatedBlock(exit, new_pre_header);
2748   new_pre_header->SetDominator(header);
2749   new_pre_header->dominated_blocks_.push_back(new_header);
2750   new_header->SetDominator(new_pre_header);
2751   new_header->dominated_blocks_.push_back(new_body);
2752   new_body->SetDominator(new_header);
2753   new_header->dominated_blocks_.push_back(exit);
2754   exit->SetDominator(new_header);
2755 
2756   // Fix reverse post order.
2757   size_t index_of_header = IndexOfElement(reverse_post_order_, header);
2758   MakeRoomFor(&reverse_post_order_, 2, index_of_header);
2759   reverse_post_order_[++index_of_header] = new_pre_header;
2760   reverse_post_order_[++index_of_header] = new_header;
2761   size_t index_of_body = IndexOfElement(reverse_post_order_, body);
2762   MakeRoomFor(&reverse_post_order_, 1, index_of_body - 1);
2763   reverse_post_order_[index_of_body] = new_body;
2764 
2765   // Add gotos and suspend check (client must add conditional in header).
2766   new_pre_header->AddInstruction(new (allocator_) HGoto());
2767   HSuspendCheck* suspend_check = new (allocator_) HSuspendCheck(header->GetDexPc());
2768   new_header->AddInstruction(suspend_check);
2769   new_body->AddInstruction(new (allocator_) HGoto());
2770   suspend_check->CopyEnvironmentFromWithLoopPhiAdjustment(
2771       loop->GetSuspendCheck()->GetEnvironment(), header);
2772 
2773   // Update loop information.
2774   new_header->AddBackEdge(new_body);
2775   new_header->GetLoopInformation()->SetSuspendCheck(suspend_check);
2776   new_header->GetLoopInformation()->Populate();
2777   new_pre_header->SetLoopInformation(loop->GetPreHeader()->GetLoopInformation());  // outward
2778   HLoopInformationOutwardIterator it(*new_header);
2779   for (it.Advance(); !it.Done(); it.Advance()) {
2780     it.Current()->Add(new_pre_header);
2781     it.Current()->Add(new_header);
2782     it.Current()->Add(new_body);
2783   }
2784   return new_pre_header;
2785 }
2786 
CheckAgainstUpperBound(ReferenceTypeInfo rti,ReferenceTypeInfo upper_bound_rti)2787 static void CheckAgainstUpperBound(ReferenceTypeInfo rti, ReferenceTypeInfo upper_bound_rti)
2788     REQUIRES_SHARED(Locks::mutator_lock_) {
2789   if (rti.IsValid()) {
2790     DCHECK(upper_bound_rti.IsSupertypeOf(rti))
2791         << " upper_bound_rti: " << upper_bound_rti
2792         << " rti: " << rti;
2793     DCHECK(!upper_bound_rti.GetTypeHandle()->CannotBeAssignedFromOtherTypes() || rti.IsExact())
2794         << " upper_bound_rti: " << upper_bound_rti
2795         << " rti: " << rti;
2796   }
2797 }
2798 
SetReferenceTypeInfo(ReferenceTypeInfo rti)2799 void HInstruction::SetReferenceTypeInfo(ReferenceTypeInfo rti) {
2800   if (kIsDebugBuild) {
2801     DCHECK_EQ(GetType(), DataType::Type::kReference);
2802     ScopedObjectAccess soa(Thread::Current());
2803     DCHECK(rti.IsValid()) << "Invalid RTI for " << DebugName();
2804     if (IsBoundType()) {
2805       // Having the test here spares us from making the method virtual just for
2806       // the sake of a DCHECK.
2807       CheckAgainstUpperBound(rti, AsBoundType()->GetUpperBound());
2808     }
2809   }
2810   reference_type_handle_ = rti.GetTypeHandle();
2811   SetPackedFlag<kFlagReferenceTypeIsExact>(rti.IsExact());
2812 }
2813 
InstructionDataEquals(const HInstruction * other) const2814 bool HBoundType::InstructionDataEquals(const HInstruction* other) const {
2815   const HBoundType* other_bt = other->AsBoundType();
2816   ScopedObjectAccess soa(Thread::Current());
2817   return GetUpperBound().IsEqual(other_bt->GetUpperBound()) &&
2818          GetUpperCanBeNull() == other_bt->GetUpperCanBeNull() &&
2819          CanBeNull() == other_bt->CanBeNull();
2820 }
2821 
SetUpperBound(const ReferenceTypeInfo & upper_bound,bool can_be_null)2822 void HBoundType::SetUpperBound(const ReferenceTypeInfo& upper_bound, bool can_be_null) {
2823   if (kIsDebugBuild) {
2824     ScopedObjectAccess soa(Thread::Current());
2825     DCHECK(upper_bound.IsValid());
2826     DCHECK(!upper_bound_.IsValid()) << "Upper bound should only be set once.";
2827     CheckAgainstUpperBound(GetReferenceTypeInfo(), upper_bound);
2828   }
2829   upper_bound_ = upper_bound;
2830   SetPackedFlag<kFlagUpperCanBeNull>(can_be_null);
2831 }
2832 
Create(TypeHandle type_handle,bool is_exact)2833 ReferenceTypeInfo ReferenceTypeInfo::Create(TypeHandle type_handle, bool is_exact) {
2834   if (kIsDebugBuild) {
2835     ScopedObjectAccess soa(Thread::Current());
2836     DCHECK(IsValidHandle(type_handle));
2837     if (!is_exact) {
2838       DCHECK(!type_handle->CannotBeAssignedFromOtherTypes())
2839           << "Callers of ReferenceTypeInfo::Create should ensure is_exact is properly computed";
2840     }
2841   }
2842   return ReferenceTypeInfo(type_handle, is_exact);
2843 }
2844 
operator <<(std::ostream & os,const ReferenceTypeInfo & rhs)2845 std::ostream& operator<<(std::ostream& os, const ReferenceTypeInfo& rhs) {
2846   ScopedObjectAccess soa(Thread::Current());
2847   os << "["
2848      << " is_valid=" << rhs.IsValid()
2849      << " type=" << (!rhs.IsValid() ? "?" : mirror::Class::PrettyClass(rhs.GetTypeHandle().Get()))
2850      << " is_exact=" << rhs.IsExact()
2851      << " ]";
2852   return os;
2853 }
2854 
HasAnyEnvironmentUseBefore(HInstruction * other)2855 bool HInstruction::HasAnyEnvironmentUseBefore(HInstruction* other) {
2856   // For now, assume that instructions in different blocks may use the
2857   // environment.
2858   // TODO: Use the control flow to decide if this is true.
2859   if (GetBlock() != other->GetBlock()) {
2860     return true;
2861   }
2862 
2863   // We know that we are in the same block. Walk from 'this' to 'other',
2864   // checking to see if there is any instruction with an environment.
2865   HInstruction* current = this;
2866   for (; current != other && current != nullptr; current = current->GetNext()) {
2867     // This is a conservative check, as the instruction result may not be in
2868     // the referenced environment.
2869     if (current->HasEnvironment()) {
2870       return true;
2871     }
2872   }
2873 
2874   // We should have been called with 'this' before 'other' in the block.
2875   // Just confirm this.
2876   DCHECK(current != nullptr);
2877   return false;
2878 }
2879 
SetIntrinsic(Intrinsics intrinsic,IntrinsicNeedsEnvironmentOrCache needs_env_or_cache,IntrinsicSideEffects side_effects,IntrinsicExceptions exceptions)2880 void HInvoke::SetIntrinsic(Intrinsics intrinsic,
2881                            IntrinsicNeedsEnvironmentOrCache needs_env_or_cache,
2882                            IntrinsicSideEffects side_effects,
2883                            IntrinsicExceptions exceptions) {
2884   intrinsic_ = intrinsic;
2885   IntrinsicOptimizations opt(this);
2886 
2887   // Adjust method's side effects from intrinsic table.
2888   switch (side_effects) {
2889     case kNoSideEffects: SetSideEffects(SideEffects::None()); break;
2890     case kReadSideEffects: SetSideEffects(SideEffects::AllReads()); break;
2891     case kWriteSideEffects: SetSideEffects(SideEffects::AllWrites()); break;
2892     case kAllSideEffects: SetSideEffects(SideEffects::AllExceptGCDependency()); break;
2893   }
2894 
2895   if (needs_env_or_cache == kNoEnvironmentOrCache) {
2896     opt.SetDoesNotNeedDexCache();
2897     opt.SetDoesNotNeedEnvironment();
2898   } else {
2899     // If we need an environment, that means there will be a call, which can trigger GC.
2900     SetSideEffects(GetSideEffects().Union(SideEffects::CanTriggerGC()));
2901   }
2902   // Adjust method's exception status from intrinsic table.
2903   SetCanThrow(exceptions == kCanThrow);
2904 }
2905 
IsStringAlloc() const2906 bool HNewInstance::IsStringAlloc() const {
2907   return GetEntrypoint() == kQuickAllocStringObject;
2908 }
2909 
NeedsEnvironment() const2910 bool HInvoke::NeedsEnvironment() const {
2911   if (!IsIntrinsic()) {
2912     return true;
2913   }
2914   IntrinsicOptimizations opt(*this);
2915   return !opt.GetDoesNotNeedEnvironment();
2916 }
2917 
GetDexFileForPcRelativeDexCache() const2918 const DexFile& HInvokeStaticOrDirect::GetDexFileForPcRelativeDexCache() const {
2919   ArtMethod* caller = GetEnvironment()->GetMethod();
2920   ScopedObjectAccess soa(Thread::Current());
2921   // `caller` is null for a top-level graph representing a method whose declaring
2922   // class was not resolved.
2923   return caller == nullptr ? GetBlock()->GetGraph()->GetDexFile() : *caller->GetDexFile();
2924 }
2925 
NeedsDexCacheOfDeclaringClass() const2926 bool HInvokeStaticOrDirect::NeedsDexCacheOfDeclaringClass() const {
2927   if (GetMethodLoadKind() != MethodLoadKind::kRuntimeCall) {
2928     return false;
2929   }
2930   if (!IsIntrinsic()) {
2931     return true;
2932   }
2933   IntrinsicOptimizations opt(*this);
2934   return !opt.GetDoesNotNeedDexCache();
2935 }
2936 
operator <<(std::ostream & os,HInvokeStaticOrDirect::MethodLoadKind rhs)2937 std::ostream& operator<<(std::ostream& os, HInvokeStaticOrDirect::MethodLoadKind rhs) {
2938   switch (rhs) {
2939     case HInvokeStaticOrDirect::MethodLoadKind::kStringInit:
2940       return os << "StringInit";
2941     case HInvokeStaticOrDirect::MethodLoadKind::kRecursive:
2942       return os << "Recursive";
2943     case HInvokeStaticOrDirect::MethodLoadKind::kBootImageLinkTimePcRelative:
2944       return os << "BootImageLinkTimePcRelative";
2945     case HInvokeStaticOrDirect::MethodLoadKind::kBootImageRelRo:
2946       return os << "BootImageRelRo";
2947     case HInvokeStaticOrDirect::MethodLoadKind::kBssEntry:
2948       return os << "BssEntry";
2949     case HInvokeStaticOrDirect::MethodLoadKind::kJitDirectAddress:
2950       return os << "JitDirectAddress";
2951     case HInvokeStaticOrDirect::MethodLoadKind::kRuntimeCall:
2952       return os << "RuntimeCall";
2953     default:
2954       LOG(FATAL) << "Unknown MethodLoadKind: " << static_cast<int>(rhs);
2955       UNREACHABLE();
2956   }
2957 }
2958 
operator <<(std::ostream & os,HInvokeStaticOrDirect::ClinitCheckRequirement rhs)2959 std::ostream& operator<<(std::ostream& os, HInvokeStaticOrDirect::ClinitCheckRequirement rhs) {
2960   switch (rhs) {
2961     case HInvokeStaticOrDirect::ClinitCheckRequirement::kExplicit:
2962       return os << "explicit";
2963     case HInvokeStaticOrDirect::ClinitCheckRequirement::kImplicit:
2964       return os << "implicit";
2965     case HInvokeStaticOrDirect::ClinitCheckRequirement::kNone:
2966       return os << "none";
2967     default:
2968       LOG(FATAL) << "Unknown ClinitCheckRequirement: " << static_cast<int>(rhs);
2969       UNREACHABLE();
2970   }
2971 }
2972 
InstructionDataEquals(const HInstruction * other) const2973 bool HLoadClass::InstructionDataEquals(const HInstruction* other) const {
2974   const HLoadClass* other_load_class = other->AsLoadClass();
2975   // TODO: To allow GVN for HLoadClass from different dex files, we should compare the type
2976   // names rather than type indexes. However, we shall also have to re-think the hash code.
2977   if (type_index_ != other_load_class->type_index_ ||
2978       GetPackedFields() != other_load_class->GetPackedFields()) {
2979     return false;
2980   }
2981   switch (GetLoadKind()) {
2982     case LoadKind::kBootImageRelRo:
2983     case LoadKind::kJitBootImageAddress:
2984     case LoadKind::kJitTableAddress: {
2985       ScopedObjectAccess soa(Thread::Current());
2986       return GetClass().Get() == other_load_class->GetClass().Get();
2987     }
2988     default:
2989       DCHECK(HasTypeReference(GetLoadKind()));
2990       return IsSameDexFile(GetDexFile(), other_load_class->GetDexFile());
2991   }
2992 }
2993 
operator <<(std::ostream & os,HLoadClass::LoadKind rhs)2994 std::ostream& operator<<(std::ostream& os, HLoadClass::LoadKind rhs) {
2995   switch (rhs) {
2996     case HLoadClass::LoadKind::kReferrersClass:
2997       return os << "ReferrersClass";
2998     case HLoadClass::LoadKind::kBootImageLinkTimePcRelative:
2999       return os << "BootImageLinkTimePcRelative";
3000     case HLoadClass::LoadKind::kBootImageRelRo:
3001       return os << "BootImageRelRo";
3002     case HLoadClass::LoadKind::kBssEntry:
3003       return os << "BssEntry";
3004     case HLoadClass::LoadKind::kJitBootImageAddress:
3005       return os << "JitBootImageAddress";
3006     case HLoadClass::LoadKind::kJitTableAddress:
3007       return os << "JitTableAddress";
3008     case HLoadClass::LoadKind::kRuntimeCall:
3009       return os << "RuntimeCall";
3010     default:
3011       LOG(FATAL) << "Unknown HLoadClass::LoadKind: " << static_cast<int>(rhs);
3012       UNREACHABLE();
3013   }
3014 }
3015 
InstructionDataEquals(const HInstruction * other) const3016 bool HLoadString::InstructionDataEquals(const HInstruction* other) const {
3017   const HLoadString* other_load_string = other->AsLoadString();
3018   // TODO: To allow GVN for HLoadString from different dex files, we should compare the strings
3019   // rather than their indexes. However, we shall also have to re-think the hash code.
3020   if (string_index_ != other_load_string->string_index_ ||
3021       GetPackedFields() != other_load_string->GetPackedFields()) {
3022     return false;
3023   }
3024   switch (GetLoadKind()) {
3025     case LoadKind::kBootImageRelRo:
3026     case LoadKind::kJitBootImageAddress:
3027     case LoadKind::kJitTableAddress: {
3028       ScopedObjectAccess soa(Thread::Current());
3029       return GetString().Get() == other_load_string->GetString().Get();
3030     }
3031     default:
3032       return IsSameDexFile(GetDexFile(), other_load_string->GetDexFile());
3033   }
3034 }
3035 
operator <<(std::ostream & os,HLoadString::LoadKind rhs)3036 std::ostream& operator<<(std::ostream& os, HLoadString::LoadKind rhs) {
3037   switch (rhs) {
3038     case HLoadString::LoadKind::kBootImageLinkTimePcRelative:
3039       return os << "BootImageLinkTimePcRelative";
3040     case HLoadString::LoadKind::kBootImageRelRo:
3041       return os << "BootImageRelRo";
3042     case HLoadString::LoadKind::kBssEntry:
3043       return os << "BssEntry";
3044     case HLoadString::LoadKind::kJitBootImageAddress:
3045       return os << "JitBootImageAddress";
3046     case HLoadString::LoadKind::kJitTableAddress:
3047       return os << "JitTableAddress";
3048     case HLoadString::LoadKind::kRuntimeCall:
3049       return os << "RuntimeCall";
3050     default:
3051       LOG(FATAL) << "Unknown HLoadString::LoadKind: " << static_cast<int>(rhs);
3052       UNREACHABLE();
3053   }
3054 }
3055 
RemoveEnvironmentUsers()3056 void HInstruction::RemoveEnvironmentUsers() {
3057   for (const HUseListNode<HEnvironment*>& use : GetEnvUses()) {
3058     HEnvironment* user = use.GetUser();
3059     user->SetRawEnvAt(use.GetIndex(), nullptr);
3060   }
3061   env_uses_.clear();
3062 }
3063 
ReplaceInstrOrPhiByClone(HInstruction * instr)3064 HInstruction* ReplaceInstrOrPhiByClone(HInstruction* instr) {
3065   HInstruction* clone = instr->Clone(instr->GetBlock()->GetGraph()->GetAllocator());
3066   HBasicBlock* block = instr->GetBlock();
3067 
3068   if (instr->IsPhi()) {
3069     HPhi* phi = instr->AsPhi();
3070     DCHECK(!phi->HasEnvironment());
3071     HPhi* phi_clone = clone->AsPhi();
3072     block->ReplaceAndRemovePhiWith(phi, phi_clone);
3073   } else {
3074     block->ReplaceAndRemoveInstructionWith(instr, clone);
3075     if (instr->HasEnvironment()) {
3076       clone->CopyEnvironmentFrom(instr->GetEnvironment());
3077       HLoopInformation* loop_info = block->GetLoopInformation();
3078       if (instr->IsSuspendCheck() && loop_info != nullptr) {
3079         loop_info->SetSuspendCheck(clone->AsSuspendCheck());
3080       }
3081     }
3082   }
3083   return clone;
3084 }
3085 
3086 // Returns an instruction with the opposite Boolean value from 'cond'.
InsertOppositeCondition(HInstruction * cond,HInstruction * cursor)3087 HInstruction* HGraph::InsertOppositeCondition(HInstruction* cond, HInstruction* cursor) {
3088   ArenaAllocator* allocator = GetAllocator();
3089 
3090   if (cond->IsCondition() &&
3091       !DataType::IsFloatingPointType(cond->InputAt(0)->GetType())) {
3092     // Can't reverse floating point conditions.  We have to use HBooleanNot in that case.
3093     HInstruction* lhs = cond->InputAt(0);
3094     HInstruction* rhs = cond->InputAt(1);
3095     HInstruction* replacement = nullptr;
3096     switch (cond->AsCondition()->GetOppositeCondition()) {  // get *opposite*
3097       case kCondEQ: replacement = new (allocator) HEqual(lhs, rhs); break;
3098       case kCondNE: replacement = new (allocator) HNotEqual(lhs, rhs); break;
3099       case kCondLT: replacement = new (allocator) HLessThan(lhs, rhs); break;
3100       case kCondLE: replacement = new (allocator) HLessThanOrEqual(lhs, rhs); break;
3101       case kCondGT: replacement = new (allocator) HGreaterThan(lhs, rhs); break;
3102       case kCondGE: replacement = new (allocator) HGreaterThanOrEqual(lhs, rhs); break;
3103       case kCondB:  replacement = new (allocator) HBelow(lhs, rhs); break;
3104       case kCondBE: replacement = new (allocator) HBelowOrEqual(lhs, rhs); break;
3105       case kCondA:  replacement = new (allocator) HAbove(lhs, rhs); break;
3106       case kCondAE: replacement = new (allocator) HAboveOrEqual(lhs, rhs); break;
3107       default:
3108         LOG(FATAL) << "Unexpected condition";
3109         UNREACHABLE();
3110     }
3111     cursor->GetBlock()->InsertInstructionBefore(replacement, cursor);
3112     return replacement;
3113   } else if (cond->IsIntConstant()) {
3114     HIntConstant* int_const = cond->AsIntConstant();
3115     if (int_const->IsFalse()) {
3116       return GetIntConstant(1);
3117     } else {
3118       DCHECK(int_const->IsTrue()) << int_const->GetValue();
3119       return GetIntConstant(0);
3120     }
3121   } else {
3122     HInstruction* replacement = new (allocator) HBooleanNot(cond);
3123     cursor->GetBlock()->InsertInstructionBefore(replacement, cursor);
3124     return replacement;
3125   }
3126 }
3127 
operator <<(std::ostream & os,const MoveOperands & rhs)3128 std::ostream& operator<<(std::ostream& os, const MoveOperands& rhs) {
3129   os << "["
3130      << " source=" << rhs.GetSource()
3131      << " destination=" << rhs.GetDestination()
3132      << " type=" << rhs.GetType()
3133      << " instruction=";
3134   if (rhs.GetInstruction() != nullptr) {
3135     os << rhs.GetInstruction()->DebugName() << ' ' << rhs.GetInstruction()->GetId();
3136   } else {
3137     os << "null";
3138   }
3139   os << " ]";
3140   return os;
3141 }
3142 
operator <<(std::ostream & os,TypeCheckKind rhs)3143 std::ostream& operator<<(std::ostream& os, TypeCheckKind rhs) {
3144   switch (rhs) {
3145     case TypeCheckKind::kUnresolvedCheck:
3146       return os << "unresolved_check";
3147     case TypeCheckKind::kExactCheck:
3148       return os << "exact_check";
3149     case TypeCheckKind::kClassHierarchyCheck:
3150       return os << "class_hierarchy_check";
3151     case TypeCheckKind::kAbstractClassCheck:
3152       return os << "abstract_class_check";
3153     case TypeCheckKind::kInterfaceCheck:
3154       return os << "interface_check";
3155     case TypeCheckKind::kArrayObjectCheck:
3156       return os << "array_object_check";
3157     case TypeCheckKind::kArrayCheck:
3158       return os << "array_check";
3159     case TypeCheckKind::kBitstringCheck:
3160       return os << "bitstring_check";
3161     default:
3162       LOG(FATAL) << "Unknown TypeCheckKind: " << static_cast<int>(rhs);
3163       UNREACHABLE();
3164   }
3165 }
3166 
operator <<(std::ostream & os,const MemBarrierKind & kind)3167 std::ostream& operator<<(std::ostream& os, const MemBarrierKind& kind) {
3168   switch (kind) {
3169     case MemBarrierKind::kAnyStore:
3170       return os << "AnyStore";
3171     case MemBarrierKind::kLoadAny:
3172       return os << "LoadAny";
3173     case MemBarrierKind::kStoreStore:
3174       return os << "StoreStore";
3175     case MemBarrierKind::kAnyAny:
3176       return os << "AnyAny";
3177     case MemBarrierKind::kNTStoreStore:
3178       return os << "NTStoreStore";
3179 
3180     default:
3181       LOG(FATAL) << "Unknown MemBarrierKind: " << static_cast<int>(kind);
3182       UNREACHABLE();
3183   }
3184 }
3185 
3186 // Check that intrinsic enum values fit within space set aside in ArtMethod modifier flags.
3187 #define CHECK_INTRINSICS_ENUM_VALUES(Name, InvokeType, _, SideEffects, Exceptions, ...) \
3188   static_assert( \
3189     static_cast<uint32_t>(Intrinsics::k ## Name) <= (kAccIntrinsicBits >> CTZ(kAccIntrinsicBits)), \
3190     "Instrinsics enumeration space overflow.");
3191 #include "intrinsics_list.h"
INTRINSICS_LIST(CHECK_INTRINSICS_ENUM_VALUES)3192   INTRINSICS_LIST(CHECK_INTRINSICS_ENUM_VALUES)
3193 #undef INTRINSICS_LIST
3194 #undef CHECK_INTRINSICS_ENUM_VALUES
3195 
3196 // Function that returns whether an intrinsic needs an environment or not.
3197 static inline IntrinsicNeedsEnvironmentOrCache NeedsEnvironmentOrCacheIntrinsic(Intrinsics i) {
3198   switch (i) {
3199     case Intrinsics::kNone:
3200       return kNeedsEnvironmentOrCache;  // Non-sensical for intrinsic.
3201 #define OPTIMIZING_INTRINSICS(Name, InvokeType, NeedsEnvOrCache, SideEffects, Exceptions, ...) \
3202     case Intrinsics::k ## Name: \
3203       return NeedsEnvOrCache;
3204 #include "intrinsics_list.h"
3205       INTRINSICS_LIST(OPTIMIZING_INTRINSICS)
3206 #undef INTRINSICS_LIST
3207 #undef OPTIMIZING_INTRINSICS
3208   }
3209   return kNeedsEnvironmentOrCache;
3210 }
3211 
3212 // Function that returns whether an intrinsic has side effects.
GetSideEffectsIntrinsic(Intrinsics i)3213 static inline IntrinsicSideEffects GetSideEffectsIntrinsic(Intrinsics i) {
3214   switch (i) {
3215     case Intrinsics::kNone:
3216       return kAllSideEffects;
3217 #define OPTIMIZING_INTRINSICS(Name, InvokeType, NeedsEnvOrCache, SideEffects, Exceptions, ...) \
3218     case Intrinsics::k ## Name: \
3219       return SideEffects;
3220 #include "intrinsics_list.h"
3221       INTRINSICS_LIST(OPTIMIZING_INTRINSICS)
3222 #undef INTRINSICS_LIST
3223 #undef OPTIMIZING_INTRINSICS
3224   }
3225   return kAllSideEffects;
3226 }
3227 
3228 // Function that returns whether an intrinsic can throw exceptions.
GetExceptionsIntrinsic(Intrinsics i)3229 static inline IntrinsicExceptions GetExceptionsIntrinsic(Intrinsics i) {
3230   switch (i) {
3231     case Intrinsics::kNone:
3232       return kCanThrow;
3233 #define OPTIMIZING_INTRINSICS(Name, InvokeType, NeedsEnvOrCache, SideEffects, Exceptions, ...) \
3234     case Intrinsics::k ## Name: \
3235       return Exceptions;
3236 #include "intrinsics_list.h"
3237       INTRINSICS_LIST(OPTIMIZING_INTRINSICS)
3238 #undef INTRINSICS_LIST
3239 #undef OPTIMIZING_INTRINSICS
3240   }
3241   return kCanThrow;
3242 }
3243 
SetResolvedMethod(ArtMethod * method)3244 void HInvoke::SetResolvedMethod(ArtMethod* method) {
3245   // TODO: b/65872996 The intent is that polymorphic signature methods should
3246   // be compiler intrinsics. At present, they are only interpreter intrinsics.
3247   if (method != nullptr &&
3248       method->IsIntrinsic() &&
3249       !method->IsPolymorphicSignature()) {
3250     Intrinsics intrinsic = static_cast<Intrinsics>(method->GetIntrinsic());
3251     SetIntrinsic(intrinsic,
3252                  NeedsEnvironmentOrCacheIntrinsic(intrinsic),
3253                  GetSideEffectsIntrinsic(intrinsic),
3254                  GetExceptionsIntrinsic(intrinsic));
3255   }
3256   resolved_method_ = method;
3257 }
3258 
3259 }  // namespace art
3260