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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 
17 #include "bounds_check_elimination.h"
18 
19 #include <limits>
20 
21 #include "base/scoped_arena_allocator.h"
22 #include "base/scoped_arena_containers.h"
23 #include "induction_var_range.h"
24 #include "nodes.h"
25 #include "side_effects_analysis.h"
26 
27 namespace art {
28 
29 class MonotonicValueRange;
30 
31 /**
32  * A value bound is represented as a pair of value and constant,
33  * e.g. array.length - 1.
34  */
35 class ValueBound : public ValueObject {
36  public:
ValueBound(HInstruction * instruction,int32_t constant)37   ValueBound(HInstruction* instruction, int32_t constant) {
38     if (instruction != nullptr && instruction->IsIntConstant()) {
39       // Normalize ValueBound with constant instruction.
40       int32_t instr_const = instruction->AsIntConstant()->GetValue();
41       if (!WouldAddOverflowOrUnderflow(instr_const, constant)) {
42         instruction_ = nullptr;
43         constant_ = instr_const + constant;
44         return;
45       }
46     }
47     instruction_ = instruction;
48     constant_ = constant;
49   }
50 
51   // Return whether (left + right) overflows or underflows.
WouldAddOverflowOrUnderflow(int32_t left,int32_t right)52   static bool WouldAddOverflowOrUnderflow(int32_t left, int32_t right) {
53     if (right == 0) {
54       return false;
55     }
56     if ((right > 0) && (left <= (std::numeric_limits<int32_t>::max() - right))) {
57       // No overflow.
58       return false;
59     }
60     if ((right < 0) && (left >= (std::numeric_limits<int32_t>::min() - right))) {
61       // No underflow.
62       return false;
63     }
64     return true;
65   }
66 
67   // Return true if instruction can be expressed as "left_instruction + right_constant".
IsAddOrSubAConstant(HInstruction * instruction,HInstruction ** left_instruction,int32_t * right_constant)68   static bool IsAddOrSubAConstant(HInstruction* instruction,
69                                   /* out */ HInstruction** left_instruction,
70                                   /* out */ int32_t* right_constant) {
71     HInstruction* left_so_far = nullptr;
72     int32_t right_so_far = 0;
73     while (instruction->IsAdd() || instruction->IsSub()) {
74       HBinaryOperation* bin_op = instruction->AsBinaryOperation();
75       HInstruction* left = bin_op->GetLeft();
76       HInstruction* right = bin_op->GetRight();
77       if (right->IsIntConstant()) {
78         int32_t v = right->AsIntConstant()->GetValue();
79         int32_t c = instruction->IsAdd() ? v : -v;
80         if (!WouldAddOverflowOrUnderflow(right_so_far, c)) {
81           instruction = left;
82           left_so_far = left;
83           right_so_far += c;
84           continue;
85         }
86       }
87       break;
88     }
89     // Return result: either false and "null+0" or true and "instr+constant".
90     *left_instruction = left_so_far;
91     *right_constant = right_so_far;
92     return left_so_far != nullptr;
93   }
94 
95   // Expresses any instruction as a value bound.
AsValueBound(HInstruction * instruction)96   static ValueBound AsValueBound(HInstruction* instruction) {
97     if (instruction->IsIntConstant()) {
98       return ValueBound(nullptr, instruction->AsIntConstant()->GetValue());
99     }
100     HInstruction *left;
101     int32_t right;
102     if (IsAddOrSubAConstant(instruction, &left, &right)) {
103       return ValueBound(left, right);
104     }
105     return ValueBound(instruction, 0);
106   }
107 
108   // Try to detect useful value bound format from an instruction, e.g.
109   // a constant or array length related value.
DetectValueBoundFromValue(HInstruction * instruction,bool * found)110   static ValueBound DetectValueBoundFromValue(HInstruction* instruction, /* out */ bool* found) {
111     DCHECK(instruction != nullptr);
112     if (instruction->IsIntConstant()) {
113       *found = true;
114       return ValueBound(nullptr, instruction->AsIntConstant()->GetValue());
115     }
116 
117     if (instruction->IsArrayLength()) {
118       *found = true;
119       return ValueBound(instruction, 0);
120     }
121     // Try to detect (array.length + c) format.
122     HInstruction *left;
123     int32_t right;
124     if (IsAddOrSubAConstant(instruction, &left, &right)) {
125       if (left->IsArrayLength()) {
126         *found = true;
127         return ValueBound(left, right);
128       }
129     }
130 
131     // No useful bound detected.
132     *found = false;
133     return ValueBound::Max();
134   }
135 
GetInstruction() const136   HInstruction* GetInstruction() const { return instruction_; }
GetConstant() const137   int32_t GetConstant() const { return constant_; }
138 
IsRelatedToArrayLength() const139   bool IsRelatedToArrayLength() const {
140     // Some bounds are created with HNewArray* as the instruction instead
141     // of HArrayLength*. They are treated the same.
142     return (instruction_ != nullptr) &&
143            (instruction_->IsArrayLength() || instruction_->IsNewArray());
144   }
145 
IsConstant() const146   bool IsConstant() const {
147     return instruction_ == nullptr;
148   }
149 
Min()150   static ValueBound Min() { return ValueBound(nullptr, std::numeric_limits<int32_t>::min()); }
Max()151   static ValueBound Max() { return ValueBound(nullptr, std::numeric_limits<int32_t>::max()); }
152 
Equals(ValueBound bound) const153   bool Equals(ValueBound bound) const {
154     return instruction_ == bound.instruction_ && constant_ == bound.constant_;
155   }
156 
Equal(HInstruction * instruction1,HInstruction * instruction2)157   static bool Equal(HInstruction* instruction1, HInstruction* instruction2) {
158     if (instruction1 == instruction2) {
159       return true;
160     }
161     if (instruction1 == nullptr || instruction2 == nullptr) {
162       return false;
163     }
164     instruction1 = HuntForDeclaration(instruction1);
165     instruction2 = HuntForDeclaration(instruction2);
166     return instruction1 == instruction2;
167   }
168 
169   // Returns if it's certain this->bound >= `bound`.
GreaterThanOrEqualTo(ValueBound bound) const170   bool GreaterThanOrEqualTo(ValueBound bound) const {
171     if (Equal(instruction_, bound.instruction_)) {
172       return constant_ >= bound.constant_;
173     }
174     // Not comparable. Just return false.
175     return false;
176   }
177 
178   // Returns if it's certain this->bound <= `bound`.
LessThanOrEqualTo(ValueBound bound) const179   bool LessThanOrEqualTo(ValueBound bound) const {
180     if (Equal(instruction_, bound.instruction_)) {
181       return constant_ <= bound.constant_;
182     }
183     // Not comparable. Just return false.
184     return false;
185   }
186 
187   // Returns if it's certain this->bound > `bound`.
GreaterThan(ValueBound bound) const188   bool GreaterThan(ValueBound bound) const {
189     if (Equal(instruction_, bound.instruction_)) {
190       return constant_ > bound.constant_;
191     }
192     // Not comparable. Just return false.
193     return false;
194   }
195 
196   // Returns if it's certain this->bound < `bound`.
LessThan(ValueBound bound) const197   bool LessThan(ValueBound bound) const {
198     if (Equal(instruction_, bound.instruction_)) {
199       return constant_ < bound.constant_;
200     }
201     // Not comparable. Just return false.
202     return false;
203   }
204 
205   // Try to narrow lower bound. Returns the greatest of the two if possible.
206   // Pick one if they are not comparable.
NarrowLowerBound(ValueBound bound1,ValueBound bound2)207   static ValueBound NarrowLowerBound(ValueBound bound1, ValueBound bound2) {
208     if (bound1.GreaterThanOrEqualTo(bound2)) {
209       return bound1;
210     }
211     if (bound2.GreaterThanOrEqualTo(bound1)) {
212       return bound2;
213     }
214 
215     // Not comparable. Just pick one. We may lose some info, but that's ok.
216     // Favor constant as lower bound.
217     return bound1.IsConstant() ? bound1 : bound2;
218   }
219 
220   // Try to narrow upper bound. Returns the lowest of the two if possible.
221   // Pick one if they are not comparable.
NarrowUpperBound(ValueBound bound1,ValueBound bound2)222   static ValueBound NarrowUpperBound(ValueBound bound1, ValueBound bound2) {
223     if (bound1.LessThanOrEqualTo(bound2)) {
224       return bound1;
225     }
226     if (bound2.LessThanOrEqualTo(bound1)) {
227       return bound2;
228     }
229 
230     // Not comparable. Just pick one. We may lose some info, but that's ok.
231     // Favor array length as upper bound.
232     return bound1.IsRelatedToArrayLength() ? bound1 : bound2;
233   }
234 
235   // Add a constant to a ValueBound.
236   // `overflow` or `underflow` will return whether the resulting bound may
237   // overflow or underflow an int.
Add(int32_t c,bool * overflow,bool * underflow) const238   ValueBound Add(int32_t c, /* out */ bool* overflow, /* out */ bool* underflow) const {
239     *overflow = *underflow = false;
240     if (c == 0) {
241       return *this;
242     }
243 
244     int32_t new_constant;
245     if (c > 0) {
246       if (constant_ > (std::numeric_limits<int32_t>::max() - c)) {
247         *overflow = true;
248         return Max();
249       }
250 
251       new_constant = constant_ + c;
252       // (array.length + non-positive-constant) won't overflow an int.
253       if (IsConstant() || (IsRelatedToArrayLength() && new_constant <= 0)) {
254         return ValueBound(instruction_, new_constant);
255       }
256       // Be conservative.
257       *overflow = true;
258       return Max();
259     } else {
260       if (constant_ < (std::numeric_limits<int32_t>::min() - c)) {
261         *underflow = true;
262         return Min();
263       }
264 
265       new_constant = constant_ + c;
266       // Regardless of the value new_constant, (array.length+new_constant) will
267       // never underflow since array.length is no less than 0.
268       if (IsConstant() || IsRelatedToArrayLength()) {
269         return ValueBound(instruction_, new_constant);
270       }
271       // Be conservative.
272       *underflow = true;
273       return Min();
274     }
275   }
276 
277  private:
278   HInstruction* instruction_;
279   int32_t constant_;
280 };
281 
282 /**
283  * Represent a range of lower bound and upper bound, both being inclusive.
284  * Currently a ValueRange may be generated as a result of the following:
285  * comparisons related to array bounds, array bounds check, add/sub on top
286  * of an existing value range, NewArray or a loop phi corresponding to an
287  * incrementing/decrementing array index (MonotonicValueRange).
288  */
289 class ValueRange : public ArenaObject<kArenaAllocBoundsCheckElimination> {
290  public:
ValueRange(ScopedArenaAllocator * allocator,ValueBound lower,ValueBound upper)291   ValueRange(ScopedArenaAllocator* allocator, ValueBound lower, ValueBound upper)
292       : allocator_(allocator), lower_(lower), upper_(upper) {}
293 
~ValueRange()294   virtual ~ValueRange() {}
295 
AsMonotonicValueRange()296   virtual MonotonicValueRange* AsMonotonicValueRange() { return nullptr; }
IsMonotonicValueRange()297   bool IsMonotonicValueRange() {
298     return AsMonotonicValueRange() != nullptr;
299   }
300 
GetAllocator() const301   ScopedArenaAllocator* GetAllocator() const { return allocator_; }
GetLower() const302   ValueBound GetLower() const { return lower_; }
GetUpper() const303   ValueBound GetUpper() const { return upper_; }
304 
IsConstantValueRange() const305   bool IsConstantValueRange() const { return lower_.IsConstant() && upper_.IsConstant(); }
306 
307   // If it's certain that this value range fits in other_range.
FitsIn(ValueRange * other_range) const308   virtual bool FitsIn(ValueRange* other_range) const {
309     if (other_range == nullptr) {
310       return true;
311     }
312     DCHECK(!other_range->IsMonotonicValueRange());
313     return lower_.GreaterThanOrEqualTo(other_range->lower_) &&
314            upper_.LessThanOrEqualTo(other_range->upper_);
315   }
316 
317   // Returns the intersection of this and range.
318   // If it's not possible to do intersection because some
319   // bounds are not comparable, it's ok to pick either bound.
Narrow(ValueRange * range)320   virtual ValueRange* Narrow(ValueRange* range) {
321     if (range == nullptr) {
322       return this;
323     }
324 
325     if (range->IsMonotonicValueRange()) {
326       return this;
327     }
328 
329     return new (allocator_) ValueRange(
330         allocator_,
331         ValueBound::NarrowLowerBound(lower_, range->lower_),
332         ValueBound::NarrowUpperBound(upper_, range->upper_));
333   }
334 
335   // Shift a range by a constant.
Add(int32_t constant) const336   ValueRange* Add(int32_t constant) const {
337     bool overflow, underflow;
338     ValueBound lower = lower_.Add(constant, &overflow, &underflow);
339     if (underflow) {
340       // Lower bound underflow will wrap around to positive values
341       // and invalidate the upper bound.
342       return nullptr;
343     }
344     ValueBound upper = upper_.Add(constant, &overflow, &underflow);
345     if (overflow) {
346       // Upper bound overflow will wrap around to negative values
347       // and invalidate the lower bound.
348       return nullptr;
349     }
350     return new (allocator_) ValueRange(allocator_, lower, upper);
351   }
352 
353  private:
354   ScopedArenaAllocator* const allocator_;
355   const ValueBound lower_;  // inclusive
356   const ValueBound upper_;  // inclusive
357 
358   DISALLOW_COPY_AND_ASSIGN(ValueRange);
359 };
360 
361 /**
362  * A monotonically incrementing/decrementing value range, e.g.
363  * the variable i in "for (int i=0; i<array.length; i++)".
364  * Special care needs to be taken to account for overflow/underflow
365  * of such value ranges.
366  */
367 class MonotonicValueRange : public ValueRange {
368  public:
MonotonicValueRange(ScopedArenaAllocator * allocator,HPhi * induction_variable,HInstruction * initial,int32_t increment,ValueBound bound)369   MonotonicValueRange(ScopedArenaAllocator* allocator,
370                       HPhi* induction_variable,
371                       HInstruction* initial,
372                       int32_t increment,
373                       ValueBound bound)
374       // To be conservative, give it full range [Min(), Max()] in case it's
375       // used as a regular value range, due to possible overflow/underflow.
376       : ValueRange(allocator, ValueBound::Min(), ValueBound::Max()),
377         induction_variable_(induction_variable),
378         initial_(initial),
379         increment_(increment),
380         bound_(bound) {}
381 
~MonotonicValueRange()382   virtual ~MonotonicValueRange() {}
383 
GetIncrement() const384   int32_t GetIncrement() const { return increment_; }
GetBound() const385   ValueBound GetBound() const { return bound_; }
GetLoopHeader() const386   HBasicBlock* GetLoopHeader() const {
387     DCHECK(induction_variable_->GetBlock()->IsLoopHeader());
388     return induction_variable_->GetBlock();
389   }
390 
AsMonotonicValueRange()391   MonotonicValueRange* AsMonotonicValueRange() override { return this; }
392 
393   // If it's certain that this value range fits in other_range.
FitsIn(ValueRange * other_range) const394   bool FitsIn(ValueRange* other_range) const override {
395     if (other_range == nullptr) {
396       return true;
397     }
398     DCHECK(!other_range->IsMonotonicValueRange());
399     return false;
400   }
401 
402   // Try to narrow this MonotonicValueRange given another range.
403   // Ideally it will return a normal ValueRange. But due to
404   // possible overflow/underflow, that may not be possible.
Narrow(ValueRange * range)405   ValueRange* Narrow(ValueRange* range) override {
406     if (range == nullptr) {
407       return this;
408     }
409     DCHECK(!range->IsMonotonicValueRange());
410 
411     if (increment_ > 0) {
412       // Monotonically increasing.
413       ValueBound lower = ValueBound::NarrowLowerBound(bound_, range->GetLower());
414       if (!lower.IsConstant() || lower.GetConstant() == std::numeric_limits<int32_t>::min()) {
415         // Lower bound isn't useful. Leave it to deoptimization.
416         return this;
417       }
418 
419       // We currently conservatively assume max array length is Max().
420       // If we can make assumptions about the max array length, e.g. due to the max heap size,
421       // divided by the element size (such as 4 bytes for each integer array), we can
422       // lower this number and rule out some possible overflows.
423       int32_t max_array_len = std::numeric_limits<int32_t>::max();
424 
425       // max possible integer value of range's upper value.
426       int32_t upper = std::numeric_limits<int32_t>::max();
427       // Try to lower upper.
428       ValueBound upper_bound = range->GetUpper();
429       if (upper_bound.IsConstant()) {
430         upper = upper_bound.GetConstant();
431       } else if (upper_bound.IsRelatedToArrayLength() && upper_bound.GetConstant() <= 0) {
432         // Normal case. e.g. <= array.length - 1.
433         upper = max_array_len + upper_bound.GetConstant();
434       }
435 
436       // If we can prove for the last number in sequence of initial_,
437       // initial_ + increment_, initial_ + 2 x increment_, ...
438       // that's <= upper, (last_num_in_sequence + increment_) doesn't trigger overflow,
439       // then this MonoticValueRange is narrowed to a normal value range.
440 
441       // Be conservative first, assume last number in the sequence hits upper.
442       int32_t last_num_in_sequence = upper;
443       if (initial_->IsIntConstant()) {
444         int32_t initial_constant = initial_->AsIntConstant()->GetValue();
445         if (upper <= initial_constant) {
446           last_num_in_sequence = upper;
447         } else {
448           // Cast to int64_t for the substraction part to avoid int32_t overflow.
449           last_num_in_sequence = initial_constant +
450               ((int64_t)upper - (int64_t)initial_constant) / increment_ * increment_;
451         }
452       }
453       if (last_num_in_sequence <= (std::numeric_limits<int32_t>::max() - increment_)) {
454         // No overflow. The sequence will be stopped by the upper bound test as expected.
455         return new (GetAllocator()) ValueRange(GetAllocator(), lower, range->GetUpper());
456       }
457 
458       // There might be overflow. Give up narrowing.
459       return this;
460     } else {
461       DCHECK_NE(increment_, 0);
462       // Monotonically decreasing.
463       ValueBound upper = ValueBound::NarrowUpperBound(bound_, range->GetUpper());
464       if ((!upper.IsConstant() || upper.GetConstant() == std::numeric_limits<int32_t>::max()) &&
465           !upper.IsRelatedToArrayLength()) {
466         // Upper bound isn't useful. Leave it to deoptimization.
467         return this;
468       }
469 
470       // Need to take care of underflow. Try to prove underflow won't happen
471       // for common cases.
472       if (range->GetLower().IsConstant()) {
473         int32_t constant = range->GetLower().GetConstant();
474         if (constant >= (std::numeric_limits<int32_t>::min() - increment_)) {
475           return new (GetAllocator()) ValueRange(GetAllocator(), range->GetLower(), upper);
476         }
477       }
478 
479       // For non-constant lower bound, just assume might be underflow. Give up narrowing.
480       return this;
481     }
482   }
483 
484  private:
485   HPhi* const induction_variable_;  // Induction variable for this monotonic value range.
486   HInstruction* const initial_;     // Initial value.
487   const int32_t increment_;         // Increment for each loop iteration.
488   const ValueBound bound_;          // Additional value bound info for initial_.
489 
490   DISALLOW_COPY_AND_ASSIGN(MonotonicValueRange);
491 };
492 
493 class BCEVisitor : public HGraphVisitor {
494  public:
495   // The least number of bounds checks that should be eliminated by triggering
496   // the deoptimization technique.
497   static constexpr size_t kThresholdForAddingDeoptimize = 2;
498 
499   // Very large lengths are considered an anomaly. This is a threshold beyond which we don't
500   // bother to apply the deoptimization technique since it's likely, or sometimes certain,
501   // an AIOOBE will be thrown.
502   static constexpr uint32_t kMaxLengthForAddingDeoptimize =
503       std::numeric_limits<int32_t>::max() - 1024 * 1024;
504 
505   // Added blocks for loop body entry test.
IsAddedBlock(HBasicBlock * block) const506   bool IsAddedBlock(HBasicBlock* block) const {
507     return block->GetBlockId() >= initial_block_size_;
508   }
509 
BCEVisitor(HGraph * graph,const SideEffectsAnalysis & side_effects,HInductionVarAnalysis * induction_analysis)510   BCEVisitor(HGraph* graph,
511              const SideEffectsAnalysis& side_effects,
512              HInductionVarAnalysis* induction_analysis)
513       : HGraphVisitor(graph),
514         allocator_(graph->GetArenaStack()),
515         maps_(graph->GetBlocks().size(),
516               ScopedArenaSafeMap<int, ValueRange*>(
517                   std::less<int>(),
518                   allocator_.Adapter(kArenaAllocBoundsCheckElimination)),
519               allocator_.Adapter(kArenaAllocBoundsCheckElimination)),
520         first_index_bounds_check_map_(std::less<int>(),
521                                       allocator_.Adapter(kArenaAllocBoundsCheckElimination)),
522         early_exit_loop_(std::less<uint32_t>(),
523                          allocator_.Adapter(kArenaAllocBoundsCheckElimination)),
524         taken_test_loop_(std::less<uint32_t>(),
525                          allocator_.Adapter(kArenaAllocBoundsCheckElimination)),
526         finite_loop_(allocator_.Adapter(kArenaAllocBoundsCheckElimination)),
527         has_dom_based_dynamic_bce_(false),
528         initial_block_size_(graph->GetBlocks().size()),
529         side_effects_(side_effects),
530         induction_range_(induction_analysis),
531         next_(nullptr) {}
532 
VisitBasicBlock(HBasicBlock * block)533   void VisitBasicBlock(HBasicBlock* block) override {
534     DCHECK(!IsAddedBlock(block));
535     first_index_bounds_check_map_.clear();
536     // Visit phis and instructions using a safe iterator. The iteration protects
537     // against deleting the current instruction during iteration. However, it
538     // must advance next_ if that instruction is deleted during iteration.
539     for (HInstruction* instruction = block->GetFirstPhi(); instruction != nullptr;) {
540       DCHECK(instruction->IsInBlock());
541       next_ = instruction->GetNext();
542       instruction->Accept(this);
543       instruction = next_;
544     }
545     for (HInstruction* instruction = block->GetFirstInstruction(); instruction != nullptr;) {
546       DCHECK(instruction->IsInBlock());
547       next_ = instruction->GetNext();
548       instruction->Accept(this);
549       instruction = next_;
550     }
551     // We should never deoptimize from an osr method, otherwise we might wrongly optimize
552     // code dominated by the deoptimization.
553     if (!GetGraph()->IsCompilingOsr()) {
554       AddComparesWithDeoptimization(block);
555     }
556   }
557 
Finish()558   void Finish() {
559     // Preserve SSA structure which may have been broken by adding one or more
560     // new taken-test structures (see TransformLoopForDeoptimizationIfNeeded()).
561     InsertPhiNodes();
562 
563     // Clear the loop data structures.
564     early_exit_loop_.clear();
565     taken_test_loop_.clear();
566     finite_loop_.clear();
567   }
568 
569  private:
570   // Return the map of proven value ranges at the beginning of a basic block.
GetValueRangeMap(HBasicBlock * basic_block)571   ScopedArenaSafeMap<int, ValueRange*>* GetValueRangeMap(HBasicBlock* basic_block) {
572     if (IsAddedBlock(basic_block)) {
573       // Added blocks don't keep value ranges.
574       return nullptr;
575     }
576     return &maps_[basic_block->GetBlockId()];
577   }
578 
579   // Traverse up the dominator tree to look for value range info.
LookupValueRange(HInstruction * instruction,HBasicBlock * basic_block)580   ValueRange* LookupValueRange(HInstruction* instruction, HBasicBlock* basic_block) {
581     while (basic_block != nullptr) {
582       ScopedArenaSafeMap<int, ValueRange*>* map = GetValueRangeMap(basic_block);
583       if (map != nullptr) {
584         if (map->find(instruction->GetId()) != map->end()) {
585           return map->Get(instruction->GetId());
586         }
587       } else {
588         DCHECK(IsAddedBlock(basic_block));
589       }
590       basic_block = basic_block->GetDominator();
591     }
592     // Didn't find any.
593     return nullptr;
594   }
595 
596   // Helper method to assign a new range to an instruction in given basic block.
AssignRange(HBasicBlock * basic_block,HInstruction * instruction,ValueRange * range)597   void AssignRange(HBasicBlock* basic_block, HInstruction* instruction, ValueRange* range) {
598     DCHECK(!range->IsMonotonicValueRange() || instruction->IsLoopHeaderPhi());
599     GetValueRangeMap(basic_block)->Overwrite(instruction->GetId(), range);
600   }
601 
602   // Narrow the value range of `instruction` at the end of `basic_block` with `range`,
603   // and push the narrowed value range to `successor`.
ApplyRangeFromComparison(HInstruction * instruction,HBasicBlock * basic_block,HBasicBlock * successor,ValueRange * range)604   void ApplyRangeFromComparison(HInstruction* instruction, HBasicBlock* basic_block,
605                                 HBasicBlock* successor, ValueRange* range) {
606     ValueRange* existing_range = LookupValueRange(instruction, basic_block);
607     if (existing_range == nullptr) {
608       if (range != nullptr) {
609         AssignRange(successor, instruction, range);
610       }
611       return;
612     }
613     if (existing_range->IsMonotonicValueRange()) {
614       DCHECK(instruction->IsLoopHeaderPhi());
615       // Make sure the comparison is in the loop header so each increment is
616       // checked with a comparison.
617       if (instruction->GetBlock() != basic_block) {
618         return;
619       }
620     }
621     AssignRange(successor, instruction, existing_range->Narrow(range));
622   }
623 
624   // Special case that we may simultaneously narrow two MonotonicValueRange's to
625   // regular value ranges.
HandleIfBetweenTwoMonotonicValueRanges(HIf * instruction,HInstruction * left,HInstruction * right,IfCondition cond,MonotonicValueRange * left_range,MonotonicValueRange * right_range)626   void HandleIfBetweenTwoMonotonicValueRanges(HIf* instruction,
627                                               HInstruction* left,
628                                               HInstruction* right,
629                                               IfCondition cond,
630                                               MonotonicValueRange* left_range,
631                                               MonotonicValueRange* right_range) {
632     DCHECK(left->IsLoopHeaderPhi());
633     DCHECK(right->IsLoopHeaderPhi());
634     if (instruction->GetBlock() != left->GetBlock()) {
635       // Comparison needs to be in loop header to make sure it's done after each
636       // increment/decrement.
637       return;
638     }
639 
640     // Handle common cases which also don't have overflow/underflow concerns.
641     if (left_range->GetIncrement() == 1 &&
642         left_range->GetBound().IsConstant() &&
643         right_range->GetIncrement() == -1 &&
644         right_range->GetBound().IsRelatedToArrayLength() &&
645         right_range->GetBound().GetConstant() < 0) {
646       HBasicBlock* successor = nullptr;
647       int32_t left_compensation = 0;
648       int32_t right_compensation = 0;
649       if (cond == kCondLT) {
650         left_compensation = -1;
651         right_compensation = 1;
652         successor = instruction->IfTrueSuccessor();
653       } else if (cond == kCondLE) {
654         successor = instruction->IfTrueSuccessor();
655       } else if (cond == kCondGT) {
656         successor = instruction->IfFalseSuccessor();
657       } else if (cond == kCondGE) {
658         left_compensation = -1;
659         right_compensation = 1;
660         successor = instruction->IfFalseSuccessor();
661       } else {
662         // We don't handle '=='/'!=' test in case left and right can cross and
663         // miss each other.
664         return;
665       }
666 
667       if (successor != nullptr) {
668         bool overflow;
669         bool underflow;
670         ValueRange* new_left_range = new (&allocator_) ValueRange(
671             &allocator_,
672             left_range->GetBound(),
673             right_range->GetBound().Add(left_compensation, &overflow, &underflow));
674         if (!overflow && !underflow) {
675           ApplyRangeFromComparison(left, instruction->GetBlock(), successor,
676                                    new_left_range);
677         }
678 
679         ValueRange* new_right_range = new (&allocator_) ValueRange(
680             &allocator_,
681             left_range->GetBound().Add(right_compensation, &overflow, &underflow),
682             right_range->GetBound());
683         if (!overflow && !underflow) {
684           ApplyRangeFromComparison(right, instruction->GetBlock(), successor,
685                                    new_right_range);
686         }
687       }
688     }
689   }
690 
691   // Handle "if (left cmp_cond right)".
HandleIf(HIf * instruction,HInstruction * left,HInstruction * right,IfCondition cond)692   void HandleIf(HIf* instruction, HInstruction* left, HInstruction* right, IfCondition cond) {
693     HBasicBlock* block = instruction->GetBlock();
694 
695     HBasicBlock* true_successor = instruction->IfTrueSuccessor();
696     // There should be no critical edge at this point.
697     DCHECK_EQ(true_successor->GetPredecessors().size(), 1u);
698 
699     HBasicBlock* false_successor = instruction->IfFalseSuccessor();
700     // There should be no critical edge at this point.
701     DCHECK_EQ(false_successor->GetPredecessors().size(), 1u);
702 
703     ValueRange* left_range = LookupValueRange(left, block);
704     MonotonicValueRange* left_monotonic_range = nullptr;
705     if (left_range != nullptr) {
706       left_monotonic_range = left_range->AsMonotonicValueRange();
707       if (left_monotonic_range != nullptr) {
708         HBasicBlock* loop_head = left_monotonic_range->GetLoopHeader();
709         if (instruction->GetBlock() != loop_head) {
710           // For monotonic value range, don't handle `instruction`
711           // if it's not defined in the loop header.
712           return;
713         }
714       }
715     }
716 
717     bool found;
718     ValueBound bound = ValueBound::DetectValueBoundFromValue(right, &found);
719     // Each comparison can establish a lower bound and an upper bound
720     // for the left hand side.
721     ValueBound lower = bound;
722     ValueBound upper = bound;
723     if (!found) {
724       // No constant or array.length+c format bound found.
725       // For i<j, we can still use j's upper bound as i's upper bound. Same for lower.
726       ValueRange* right_range = LookupValueRange(right, block);
727       if (right_range != nullptr) {
728         if (right_range->IsMonotonicValueRange()) {
729           if (left_range != nullptr && left_range->IsMonotonicValueRange()) {
730             HandleIfBetweenTwoMonotonicValueRanges(instruction, left, right, cond,
731                                                    left_range->AsMonotonicValueRange(),
732                                                    right_range->AsMonotonicValueRange());
733             return;
734           }
735         }
736         lower = right_range->GetLower();
737         upper = right_range->GetUpper();
738       } else {
739         lower = ValueBound::Min();
740         upper = ValueBound::Max();
741       }
742     }
743 
744     bool overflow, underflow;
745     if (cond == kCondLT || cond == kCondLE) {
746       if (!upper.Equals(ValueBound::Max())) {
747         int32_t compensation = (cond == kCondLT) ? -1 : 0;  // upper bound is inclusive
748         ValueBound new_upper = upper.Add(compensation, &overflow, &underflow);
749         if (overflow || underflow) {
750           return;
751         }
752         ValueRange* new_range = new (&allocator_) ValueRange(
753             &allocator_, ValueBound::Min(), new_upper);
754         ApplyRangeFromComparison(left, block, true_successor, new_range);
755       }
756 
757       // array.length as a lower bound isn't considered useful.
758       if (!lower.Equals(ValueBound::Min()) && !lower.IsRelatedToArrayLength()) {
759         int32_t compensation = (cond == kCondLE) ? 1 : 0;  // lower bound is inclusive
760         ValueBound new_lower = lower.Add(compensation, &overflow, &underflow);
761         if (overflow || underflow) {
762           return;
763         }
764         ValueRange* new_range = new (&allocator_) ValueRange(
765             &allocator_, new_lower, ValueBound::Max());
766         ApplyRangeFromComparison(left, block, false_successor, new_range);
767       }
768     } else if (cond == kCondGT || cond == kCondGE) {
769       // array.length as a lower bound isn't considered useful.
770       if (!lower.Equals(ValueBound::Min()) && !lower.IsRelatedToArrayLength()) {
771         int32_t compensation = (cond == kCondGT) ? 1 : 0;  // lower bound is inclusive
772         ValueBound new_lower = lower.Add(compensation, &overflow, &underflow);
773         if (overflow || underflow) {
774           return;
775         }
776         ValueRange* new_range = new (&allocator_) ValueRange(
777             &allocator_, new_lower, ValueBound::Max());
778         ApplyRangeFromComparison(left, block, true_successor, new_range);
779       }
780 
781       if (!upper.Equals(ValueBound::Max())) {
782         int32_t compensation = (cond == kCondGE) ? -1 : 0;  // upper bound is inclusive
783         ValueBound new_upper = upper.Add(compensation, &overflow, &underflow);
784         if (overflow || underflow) {
785           return;
786         }
787         ValueRange* new_range = new (&allocator_) ValueRange(
788             &allocator_, ValueBound::Min(), new_upper);
789         ApplyRangeFromComparison(left, block, false_successor, new_range);
790       }
791     } else if (cond == kCondNE || cond == kCondEQ) {
792       if (left->IsArrayLength()) {
793         if (lower.IsConstant() && upper.IsConstant()) {
794           // Special case:
795           //   length == [c,d] yields [c, d] along true
796           //   length != [c,d] yields [c, d] along false
797           if (!lower.Equals(ValueBound::Min()) || !upper.Equals(ValueBound::Max())) {
798             ValueRange* new_range = new (&allocator_) ValueRange(&allocator_, lower, upper);
799             ApplyRangeFromComparison(
800                 left, block, cond == kCondEQ ? true_successor : false_successor, new_range);
801           }
802           // In addition:
803           //   length == 0 yields [1, max] along false
804           //   length != 0 yields [1, max] along true
805           if (lower.GetConstant() == 0 && upper.GetConstant() == 0) {
806             ValueRange* new_range = new (&allocator_) ValueRange(
807                 &allocator_, ValueBound(nullptr, 1), ValueBound::Max());
808             ApplyRangeFromComparison(
809                 left, block, cond == kCondEQ ? false_successor : true_successor, new_range);
810           }
811         }
812       } else if (lower.IsRelatedToArrayLength() && lower.Equals(upper)) {
813         // Special aliasing case, with x not array length itself:
814         //   x == [length,length] yields x == length along true
815         //   x != [length,length] yields x == length along false
816         ValueRange* new_range = new (&allocator_) ValueRange(&allocator_, lower, upper);
817         ApplyRangeFromComparison(
818             left, block, cond == kCondEQ ? true_successor : false_successor, new_range);
819       }
820     }
821   }
822 
VisitBoundsCheck(HBoundsCheck * bounds_check)823   void VisitBoundsCheck(HBoundsCheck* bounds_check) override {
824     HBasicBlock* block = bounds_check->GetBlock();
825     HInstruction* index = bounds_check->InputAt(0);
826     HInstruction* array_length = bounds_check->InputAt(1);
827     DCHECK(array_length->IsIntConstant() ||
828            array_length->IsArrayLength() ||
829            array_length->IsPhi());
830     bool try_dynamic_bce = true;
831     // Analyze index range.
832     if (!index->IsIntConstant()) {
833       // Non-constant index.
834       ValueBound lower = ValueBound(nullptr, 0);        // constant 0
835       ValueBound upper = ValueBound(array_length, -1);  // array_length - 1
836       ValueRange array_range(&allocator_, lower, upper);
837       // Try index range obtained by dominator-based analysis.
838       ValueRange* index_range = LookupValueRange(index, block);
839       if (index_range != nullptr) {
840         if (index_range->FitsIn(&array_range)) {
841           ReplaceInstruction(bounds_check, index);
842           return;
843         } else if (index_range->IsConstantValueRange()) {
844           // If the non-constant index turns out to have a constant range,
845           // make one more attempt to get a constant in the array range.
846           ValueRange* existing_range = LookupValueRange(array_length, block);
847           if (existing_range != nullptr &&
848               existing_range->IsConstantValueRange() &&
849               existing_range->GetLower().GetConstant() > 0) {
850             ValueBound constant_upper(nullptr, existing_range->GetLower().GetConstant() - 1);
851             ValueRange constant_array_range(&allocator_, lower, constant_upper);
852             if (index_range->FitsIn(&constant_array_range)) {
853               ReplaceInstruction(bounds_check, index);
854               return;
855             }
856           }
857         }
858       }
859       // Try index range obtained by induction variable analysis.
860       // Disables dynamic bce if OOB is certain.
861       if (InductionRangeFitsIn(&array_range, bounds_check, &try_dynamic_bce)) {
862         ReplaceInstruction(bounds_check, index);
863         return;
864       }
865     } else {
866       // Constant index.
867       int32_t constant = index->AsIntConstant()->GetValue();
868       if (constant < 0) {
869         // Will always throw exception.
870         return;
871       } else if (array_length->IsIntConstant()) {
872         if (constant < array_length->AsIntConstant()->GetValue()) {
873           ReplaceInstruction(bounds_check, index);
874         }
875         return;
876       }
877       // Analyze array length range.
878       DCHECK(array_length->IsArrayLength());
879       ValueRange* existing_range = LookupValueRange(array_length, block);
880       if (existing_range != nullptr) {
881         ValueBound lower = existing_range->GetLower();
882         DCHECK(lower.IsConstant());
883         if (constant < lower.GetConstant()) {
884           ReplaceInstruction(bounds_check, index);
885           return;
886         } else {
887           // Existing range isn't strong enough to eliminate the bounds check.
888           // Fall through to update the array_length range with info from this
889           // bounds check.
890         }
891       }
892       // Once we have an array access like 'array[5] = 1', we record array.length >= 6.
893       // We currently don't do it for non-constant index since a valid array[i] can't prove
894       // a valid array[i-1] yet due to the lower bound side.
895       if (constant == std::numeric_limits<int32_t>::max()) {
896         // Max() as an index will definitely throw AIOOBE.
897         return;
898       } else {
899         ValueBound lower = ValueBound(nullptr, constant + 1);
900         ValueBound upper = ValueBound::Max();
901         ValueRange* range = new (&allocator_) ValueRange(&allocator_, lower, upper);
902         AssignRange(block, array_length, range);
903       }
904     }
905 
906     // If static analysis fails, and OOB is not certain, try dynamic elimination.
907     if (try_dynamic_bce) {
908       // Try loop-based dynamic elimination.
909       HLoopInformation* loop = bounds_check->GetBlock()->GetLoopInformation();
910       bool needs_finite_test = false;
911       bool needs_taken_test = false;
912       if (DynamicBCESeemsProfitable(loop, bounds_check->GetBlock()) &&
913           induction_range_.CanGenerateRange(
914               bounds_check, index, &needs_finite_test, &needs_taken_test) &&
915           CanHandleInfiniteLoop(loop, index, needs_finite_test) &&
916           // Do this test last, since it may generate code.
917           CanHandleLength(loop, array_length, needs_taken_test)) {
918         TransformLoopForDeoptimizationIfNeeded(loop, needs_taken_test);
919         TransformLoopForDynamicBCE(loop, bounds_check);
920         return;
921       }
922       // Otherwise, prepare dominator-based dynamic elimination.
923       if (first_index_bounds_check_map_.find(array_length->GetId()) ==
924           first_index_bounds_check_map_.end()) {
925         // Remember the first bounds check against each array_length. That bounds check
926         // instruction has an associated HEnvironment where we may add an HDeoptimize
927         // to eliminate subsequent bounds checks against the same array_length.
928         first_index_bounds_check_map_.Put(array_length->GetId(), bounds_check);
929       }
930     }
931   }
932 
HasSameInputAtBackEdges(HPhi * phi)933   static bool HasSameInputAtBackEdges(HPhi* phi) {
934     DCHECK(phi->IsLoopHeaderPhi());
935     HConstInputsRef inputs = phi->GetInputs();
936     // Start with input 1. Input 0 is from the incoming block.
937     const HInstruction* input1 = inputs[1];
938     DCHECK(phi->GetBlock()->GetLoopInformation()->IsBackEdge(
939         *phi->GetBlock()->GetPredecessors()[1]));
940     for (size_t i = 2; i < inputs.size(); ++i) {
941       DCHECK(phi->GetBlock()->GetLoopInformation()->IsBackEdge(
942           *phi->GetBlock()->GetPredecessors()[i]));
943       if (input1 != inputs[i]) {
944         return false;
945       }
946     }
947     return true;
948   }
949 
VisitPhi(HPhi * phi)950   void VisitPhi(HPhi* phi) override {
951     if (phi->IsLoopHeaderPhi()
952         && (phi->GetType() == DataType::Type::kInt32)
953         && HasSameInputAtBackEdges(phi)) {
954       HInstruction* instruction = phi->InputAt(1);
955       HInstruction *left;
956       int32_t increment;
957       if (ValueBound::IsAddOrSubAConstant(instruction, &left, &increment)) {
958         if (left == phi) {
959           HInstruction* initial_value = phi->InputAt(0);
960           ValueRange* range = nullptr;
961           if (increment == 0) {
962             // Add constant 0. It's really a fixed value.
963             range = new (&allocator_) ValueRange(
964                 &allocator_,
965                 ValueBound(initial_value, 0),
966                 ValueBound(initial_value, 0));
967           } else {
968             // Monotonically increasing/decreasing.
969             bool found;
970             ValueBound bound = ValueBound::DetectValueBoundFromValue(
971                 initial_value, &found);
972             if (!found) {
973               // No constant or array.length+c bound found.
974               // For i=j, we can still use j's upper bound as i's upper bound.
975               // Same for lower.
976               ValueRange* initial_range = LookupValueRange(initial_value, phi->GetBlock());
977               if (initial_range != nullptr) {
978                 bound = increment > 0 ? initial_range->GetLower() :
979                                         initial_range->GetUpper();
980               } else {
981                 bound = increment > 0 ? ValueBound::Min() : ValueBound::Max();
982               }
983             }
984             range = new (&allocator_) MonotonicValueRange(
985                 &allocator_,
986                 phi,
987                 initial_value,
988                 increment,
989                 bound);
990           }
991           AssignRange(phi->GetBlock(), phi, range);
992         }
993       }
994     }
995   }
996 
VisitIf(HIf * instruction)997   void VisitIf(HIf* instruction) override {
998     if (instruction->InputAt(0)->IsCondition()) {
999       HCondition* cond = instruction->InputAt(0)->AsCondition();
1000       HandleIf(instruction, cond->GetLeft(), cond->GetRight(), cond->GetCondition());
1001     }
1002   }
1003 
VisitAdd(HAdd * add)1004   void VisitAdd(HAdd* add) override {
1005     HInstruction* right = add->GetRight();
1006     if (right->IsIntConstant()) {
1007       ValueRange* left_range = LookupValueRange(add->GetLeft(), add->GetBlock());
1008       if (left_range == nullptr) {
1009         return;
1010       }
1011       ValueRange* range = left_range->Add(right->AsIntConstant()->GetValue());
1012       if (range != nullptr) {
1013         AssignRange(add->GetBlock(), add, range);
1014       }
1015     }
1016   }
1017 
VisitSub(HSub * sub)1018   void VisitSub(HSub* sub) override {
1019     HInstruction* left = sub->GetLeft();
1020     HInstruction* right = sub->GetRight();
1021     if (right->IsIntConstant()) {
1022       ValueRange* left_range = LookupValueRange(left, sub->GetBlock());
1023       if (left_range == nullptr) {
1024         return;
1025       }
1026       ValueRange* range = left_range->Add(-right->AsIntConstant()->GetValue());
1027       if (range != nullptr) {
1028         AssignRange(sub->GetBlock(), sub, range);
1029         return;
1030       }
1031     }
1032 
1033     // Here we are interested in the typical triangular case of nested loops,
1034     // such as the inner loop 'for (int j=0; j<array.length-i; j++)' where i
1035     // is the index for outer loop. In this case, we know j is bounded by array.length-1.
1036 
1037     // Try to handle (array.length - i) or (array.length + c - i) format.
1038     HInstruction* left_of_left;  // left input of left.
1039     int32_t right_const = 0;
1040     if (ValueBound::IsAddOrSubAConstant(left, &left_of_left, &right_const)) {
1041       left = left_of_left;
1042     }
1043     // The value of left input of the sub equals (left + right_const).
1044 
1045     if (left->IsArrayLength()) {
1046       HInstruction* array_length = left->AsArrayLength();
1047       ValueRange* right_range = LookupValueRange(right, sub->GetBlock());
1048       if (right_range != nullptr) {
1049         ValueBound lower = right_range->GetLower();
1050         ValueBound upper = right_range->GetUpper();
1051         if (lower.IsConstant() && upper.IsRelatedToArrayLength()) {
1052           HInstruction* upper_inst = upper.GetInstruction();
1053           // Make sure it's the same array.
1054           if (ValueBound::Equal(array_length, upper_inst)) {
1055             int32_t c0 = right_const;
1056             int32_t c1 = lower.GetConstant();
1057             int32_t c2 = upper.GetConstant();
1058             // (array.length + c0 - v) where v is in [c1, array.length + c2]
1059             // gets [c0 - c2, array.length + c0 - c1] as its value range.
1060             if (!ValueBound::WouldAddOverflowOrUnderflow(c0, -c2) &&
1061                 !ValueBound::WouldAddOverflowOrUnderflow(c0, -c1)) {
1062               if ((c0 - c1) <= 0) {
1063                 // array.length + (c0 - c1) won't overflow/underflow.
1064                 ValueRange* range = new (&allocator_) ValueRange(
1065                     &allocator_,
1066                     ValueBound(nullptr, right_const - upper.GetConstant()),
1067                     ValueBound(array_length, right_const - lower.GetConstant()));
1068                 AssignRange(sub->GetBlock(), sub, range);
1069               }
1070             }
1071           }
1072         }
1073       }
1074     }
1075   }
1076 
FindAndHandlePartialArrayLength(HBinaryOperation * instruction)1077   void FindAndHandlePartialArrayLength(HBinaryOperation* instruction) {
1078     DCHECK(instruction->IsDiv() || instruction->IsShr() || instruction->IsUShr());
1079     HInstruction* right = instruction->GetRight();
1080     int32_t right_const;
1081     if (right->IsIntConstant()) {
1082       right_const = right->AsIntConstant()->GetValue();
1083       // Detect division by two or more.
1084       if ((instruction->IsDiv() && right_const <= 1) ||
1085           (instruction->IsShr() && right_const < 1) ||
1086           (instruction->IsUShr() && right_const < 1)) {
1087         return;
1088       }
1089     } else {
1090       return;
1091     }
1092 
1093     // Try to handle array.length/2 or (array.length-1)/2 format.
1094     HInstruction* left = instruction->GetLeft();
1095     HInstruction* left_of_left;  // left input of left.
1096     int32_t c = 0;
1097     if (ValueBound::IsAddOrSubAConstant(left, &left_of_left, &c)) {
1098       left = left_of_left;
1099     }
1100     // The value of left input of instruction equals (left + c).
1101 
1102     // (array_length + 1) or smaller divided by two or more
1103     // always generate a value in [Min(), array_length].
1104     // This is true even if array_length is Max().
1105     if (left->IsArrayLength() && c <= 1) {
1106       if (instruction->IsUShr() && c < 0) {
1107         // Make sure for unsigned shift, left side is not negative.
1108         // e.g. if array_length is 2, ((array_length - 3) >>> 2) is way bigger
1109         // than array_length.
1110         return;
1111       }
1112       ValueRange* range = new (&allocator_) ValueRange(
1113           &allocator_,
1114           ValueBound(nullptr, std::numeric_limits<int32_t>::min()),
1115           ValueBound(left, 0));
1116       AssignRange(instruction->GetBlock(), instruction, range);
1117     }
1118   }
1119 
VisitDiv(HDiv * div)1120   void VisitDiv(HDiv* div) override {
1121     FindAndHandlePartialArrayLength(div);
1122   }
1123 
VisitShr(HShr * shr)1124   void VisitShr(HShr* shr) override {
1125     FindAndHandlePartialArrayLength(shr);
1126   }
1127 
VisitUShr(HUShr * ushr)1128   void VisitUShr(HUShr* ushr) override {
1129     FindAndHandlePartialArrayLength(ushr);
1130   }
1131 
VisitAnd(HAnd * instruction)1132   void VisitAnd(HAnd* instruction) override {
1133     if (instruction->GetRight()->IsIntConstant()) {
1134       int32_t constant = instruction->GetRight()->AsIntConstant()->GetValue();
1135       if (constant > 0) {
1136         // constant serves as a mask so any number masked with it
1137         // gets a [0, constant] value range.
1138         ValueRange* range = new (&allocator_) ValueRange(
1139             &allocator_,
1140             ValueBound(nullptr, 0),
1141             ValueBound(nullptr, constant));
1142         AssignRange(instruction->GetBlock(), instruction, range);
1143       }
1144     }
1145   }
1146 
VisitRem(HRem * instruction)1147   void VisitRem(HRem* instruction) override {
1148     HInstruction* left = instruction->GetLeft();
1149     HInstruction* right = instruction->GetRight();
1150 
1151     // Handle 'i % CONST' format expression in array index, e.g:
1152     //   array[i % 20];
1153     if (right->IsIntConstant()) {
1154       int32_t right_const = std::abs(right->AsIntConstant()->GetValue());
1155       if (right_const == 0) {
1156         return;
1157       }
1158       // The sign of divisor CONST doesn't affect the sign final value range.
1159       // For example:
1160       // if (i > 0) {
1161       //   array[i % 10];  // index value range [0, 9]
1162       //   array[i % -10]; // index value range [0, 9]
1163       // }
1164       ValueRange* right_range = new (&allocator_) ValueRange(
1165           &allocator_,
1166           ValueBound(nullptr, 1 - right_const),
1167           ValueBound(nullptr, right_const - 1));
1168 
1169       ValueRange* left_range = LookupValueRange(left, instruction->GetBlock());
1170       if (left_range != nullptr) {
1171         right_range = right_range->Narrow(left_range);
1172       }
1173       AssignRange(instruction->GetBlock(), instruction, right_range);
1174       return;
1175     }
1176 
1177     // Handle following pattern:
1178     // i0 NullCheck
1179     // i1 ArrayLength[i0]
1180     // i2 DivByZeroCheck [i1]  <-- right
1181     // i3 Rem [i5, i2]         <-- we are here.
1182     // i4 BoundsCheck [i3,i1]
1183     if (right->IsDivZeroCheck()) {
1184       // if array_length can pass div-by-zero check,
1185       // array_length must be > 0.
1186       right = right->AsDivZeroCheck()->InputAt(0);
1187     }
1188 
1189     // Handle 'i % array.length' format expression in array index, e.g:
1190     //   array[(i+7) % array.length];
1191     if (right->IsArrayLength()) {
1192       ValueBound lower = ValueBound::Min();  // ideally, lower should be '1-array_length'.
1193       ValueBound upper = ValueBound(right, -1);  // array_length - 1
1194       ValueRange* right_range = new (&allocator_) ValueRange(
1195           &allocator_,
1196           lower,
1197           upper);
1198       ValueRange* left_range = LookupValueRange(left, instruction->GetBlock());
1199       if (left_range != nullptr) {
1200         right_range = right_range->Narrow(left_range);
1201       }
1202       AssignRange(instruction->GetBlock(), instruction, right_range);
1203       return;
1204     }
1205   }
1206 
VisitNewArray(HNewArray * new_array)1207   void VisitNewArray(HNewArray* new_array) override {
1208     HInstruction* len = new_array->GetLength();
1209     if (!len->IsIntConstant()) {
1210       HInstruction *left;
1211       int32_t right_const;
1212       if (ValueBound::IsAddOrSubAConstant(len, &left, &right_const)) {
1213         // (left + right_const) is used as size to new the array.
1214         // We record "-right_const <= left <= new_array - right_const";
1215         ValueBound lower = ValueBound(nullptr, -right_const);
1216         // We use new_array for the bound instead of new_array.length,
1217         // which isn't available as an instruction yet. new_array will
1218         // be treated the same as new_array.length when it's used in a ValueBound.
1219         ValueBound upper = ValueBound(new_array, -right_const);
1220         ValueRange* range = new (&allocator_) ValueRange(&allocator_, lower, upper);
1221         ValueRange* existing_range = LookupValueRange(left, new_array->GetBlock());
1222         if (existing_range != nullptr) {
1223           range = existing_range->Narrow(range);
1224         }
1225         AssignRange(new_array->GetBlock(), left, range);
1226       }
1227     }
1228   }
1229 
1230   /**
1231     * After null/bounds checks are eliminated, some invariant array references
1232     * may be exposed underneath which can be hoisted out of the loop to the
1233     * preheader or, in combination with dynamic bce, the deoptimization block.
1234     *
1235     * for (int i = 0; i < n; i++) {
1236     *                                <-------+
1237     *   for (int j = 0; j < n; j++)          |
1238     *     a[i][j] = 0;               --a[i]--+
1239     * }
1240     *
1241     * Note: this optimization is no longer applied after dominator-based dynamic deoptimization
1242     * has occurred (see AddCompareWithDeoptimization()), since in those cases it would be
1243     * unsafe to hoist array references across their deoptimization instruction inside a loop.
1244     */
VisitArrayGet(HArrayGet * array_get)1245   void VisitArrayGet(HArrayGet* array_get) override {
1246     if (!has_dom_based_dynamic_bce_ && array_get->IsInLoop()) {
1247       HLoopInformation* loop = array_get->GetBlock()->GetLoopInformation();
1248       if (loop->IsDefinedOutOfTheLoop(array_get->InputAt(0)) &&
1249           loop->IsDefinedOutOfTheLoop(array_get->InputAt(1))) {
1250         SideEffects loop_effects = side_effects_.GetLoopEffects(loop->GetHeader());
1251         if (!array_get->GetSideEffects().MayDependOn(loop_effects)) {
1252           // We can hoist ArrayGet only if its execution is guaranteed on every iteration.
1253           // In other words only if array_get_bb dominates all back branches.
1254           if (loop->DominatesAllBackEdges(array_get->GetBlock())) {
1255             HoistToPreHeaderOrDeoptBlock(loop, array_get);
1256           }
1257         }
1258       }
1259     }
1260   }
1261 
1262   /** Performs dominator-based dynamic elimination on suitable set of bounds checks. */
AddCompareWithDeoptimization(HBasicBlock * block,HInstruction * array_length,HInstruction * base,int32_t min_c,int32_t max_c)1263   void AddCompareWithDeoptimization(HBasicBlock* block,
1264                                     HInstruction* array_length,
1265                                     HInstruction* base,
1266                                     int32_t min_c, int32_t max_c) {
1267     HBoundsCheck* bounds_check =
1268         first_index_bounds_check_map_.Get(array_length->GetId())->AsBoundsCheck();
1269     // Construct deoptimization on single or double bounds on range [base-min_c,base+max_c],
1270     // for example either for a[0]..a[3] just 3 or for a[base-1]..a[base+3] both base-1
1271     // and base+3, since we made the assumption any in between value may occur too.
1272     // In code, using unsigned comparisons:
1273     // (1) constants only
1274     //       if (max_c >= a.length) deoptimize;
1275     // (2) general case
1276     //       if (base-min_c >  base+max_c) deoptimize;
1277     //       if (base+max_c >= a.length  ) deoptimize;
1278     static_assert(kMaxLengthForAddingDeoptimize < std::numeric_limits<int32_t>::max(),
1279                   "Incorrect max length may be subject to arithmetic wrap-around");
1280     HInstruction* upper = GetGraph()->GetIntConstant(max_c);
1281     if (base == nullptr) {
1282       DCHECK_GE(min_c, 0);
1283     } else {
1284       HInstruction* lower = new (GetGraph()->GetAllocator())
1285           HAdd(DataType::Type::kInt32, base, GetGraph()->GetIntConstant(min_c));
1286       upper = new (GetGraph()->GetAllocator()) HAdd(DataType::Type::kInt32, base, upper);
1287       block->InsertInstructionBefore(lower, bounds_check);
1288       block->InsertInstructionBefore(upper, bounds_check);
1289       InsertDeoptInBlock(bounds_check, new (GetGraph()->GetAllocator()) HAbove(lower, upper));
1290     }
1291     InsertDeoptInBlock(
1292         bounds_check, new (GetGraph()->GetAllocator()) HAboveOrEqual(upper, array_length));
1293     // Flag that this kind of deoptimization has occurred.
1294     has_dom_based_dynamic_bce_ = true;
1295   }
1296 
1297   /** Attempts dominator-based dynamic elimination on remaining candidates. */
AddComparesWithDeoptimization(HBasicBlock * block)1298   void AddComparesWithDeoptimization(HBasicBlock* block) {
1299     for (const auto& entry : first_index_bounds_check_map_) {
1300       HBoundsCheck* bounds_check = entry.second;
1301       HInstruction* index = bounds_check->InputAt(0);
1302       HInstruction* array_length = bounds_check->InputAt(1);
1303       if (!array_length->IsArrayLength()) {
1304         continue;  // disregard phis and constants
1305       }
1306       // Collect all bounds checks that are still there and that are related as "a[base + constant]"
1307       // for a base instruction (possibly absent) and various constants. Note that no attempt
1308       // is made to partition the set into matching subsets (viz. a[0], a[1] and a[base+1] and
1309       // a[base+2] are considered as one set).
1310       // TODO: would such a partitioning be worthwhile?
1311       ValueBound value = ValueBound::AsValueBound(index);
1312       HInstruction* base = value.GetInstruction();
1313       int32_t min_c = base == nullptr ? 0 : value.GetConstant();
1314       int32_t max_c = value.GetConstant();
1315       ScopedArenaVector<HBoundsCheck*> candidates(
1316           allocator_.Adapter(kArenaAllocBoundsCheckElimination));
1317       ScopedArenaVector<HBoundsCheck*> standby(
1318           allocator_.Adapter(kArenaAllocBoundsCheckElimination));
1319       for (const HUseListNode<HInstruction*>& use : array_length->GetUses()) {
1320         // Another bounds check in same or dominated block?
1321         HInstruction* user = use.GetUser();
1322         HBasicBlock* other_block = user->GetBlock();
1323         if (user->IsBoundsCheck() && block->Dominates(other_block)) {
1324           HBoundsCheck* other_bounds_check = user->AsBoundsCheck();
1325           HInstruction* other_index = other_bounds_check->InputAt(0);
1326           HInstruction* other_array_length = other_bounds_check->InputAt(1);
1327           ValueBound other_value = ValueBound::AsValueBound(other_index);
1328           if (array_length == other_array_length && base == other_value.GetInstruction()) {
1329             // Reject certain OOB if BoundsCheck(l, l) occurs on considered subset.
1330             if (array_length == other_index) {
1331               candidates.clear();
1332               standby.clear();
1333               break;
1334             }
1335             // Since a subsequent dominated block could be under a conditional, only accept
1336             // the other bounds check if it is in same block or both blocks dominate the exit.
1337             // TODO: we could improve this by testing proper post-dominance, or even if this
1338             //       constant is seen along *all* conditional paths that follow.
1339             HBasicBlock* exit = GetGraph()->GetExitBlock();
1340             if (block == user->GetBlock() ||
1341                 (block->Dominates(exit) && other_block->Dominates(exit))) {
1342               int32_t other_c = other_value.GetConstant();
1343               min_c = std::min(min_c, other_c);
1344               max_c = std::max(max_c, other_c);
1345               candidates.push_back(other_bounds_check);
1346             } else {
1347               // Add this candidate later only if it falls into the range.
1348               standby.push_back(other_bounds_check);
1349             }
1350           }
1351         }
1352       }
1353       // Add standby candidates that fall in selected range.
1354       for (HBoundsCheck* other_bounds_check : standby) {
1355         HInstruction* other_index = other_bounds_check->InputAt(0);
1356         int32_t other_c = ValueBound::AsValueBound(other_index).GetConstant();
1357         if (min_c <= other_c && other_c <= max_c) {
1358           candidates.push_back(other_bounds_check);
1359         }
1360       }
1361       // Perform dominator-based deoptimization if it seems profitable, where we eliminate
1362       // bounds checks and replace these with deopt checks that guard against any possible
1363       // OOB. Note that we reject cases where the distance min_c:max_c range gets close to
1364       // the maximum possible array length, since those cases are likely to always deopt
1365       // (such situations do not necessarily go OOB, though, since the array could be really
1366       // large, or the programmer could rely on arithmetic wrap-around from max to min).
1367       size_t threshold = kThresholdForAddingDeoptimize + (base == nullptr ? 0 : 1);  // extra test?
1368       uint32_t distance = static_cast<uint32_t>(max_c) - static_cast<uint32_t>(min_c);
1369       if (candidates.size() >= threshold &&
1370           (base != nullptr || min_c >= 0) &&  // reject certain OOB
1371            distance <= kMaxLengthForAddingDeoptimize) {  // reject likely/certain deopt
1372         AddCompareWithDeoptimization(block, array_length, base, min_c, max_c);
1373         for (HBoundsCheck* other_bounds_check : candidates) {
1374           // Only replace if still in the graph. This avoids visiting the same
1375           // bounds check twice if it occurred multiple times in the use list.
1376           if (other_bounds_check->IsInBlock()) {
1377             ReplaceInstruction(other_bounds_check, other_bounds_check->InputAt(0));
1378           }
1379         }
1380       }
1381     }
1382   }
1383 
1384   /**
1385    * Returns true if static range analysis based on induction variables can determine the bounds
1386    * check on the given array range is always satisfied with the computed index range. The output
1387    * parameter try_dynamic_bce is set to false if OOB is certain.
1388    */
InductionRangeFitsIn(ValueRange * array_range,HBoundsCheck * context,bool * try_dynamic_bce)1389   bool InductionRangeFitsIn(ValueRange* array_range,
1390                             HBoundsCheck* context,
1391                             bool* try_dynamic_bce) {
1392     InductionVarRange::Value v1;
1393     InductionVarRange::Value v2;
1394     bool needs_finite_test = false;
1395     HInstruction* index = context->InputAt(0);
1396     HInstruction* hint = HuntForDeclaration(context->InputAt(1));
1397     if (induction_range_.GetInductionRange(context, index, hint, &v1, &v2, &needs_finite_test)) {
1398       if (v1.is_known && (v1.a_constant == 0 || v1.a_constant == 1) &&
1399           v2.is_known && (v2.a_constant == 0 || v2.a_constant == 1)) {
1400         DCHECK(v1.a_constant == 1 || v1.instruction == nullptr);
1401         DCHECK(v2.a_constant == 1 || v2.instruction == nullptr);
1402         ValueRange index_range(&allocator_,
1403                                ValueBound(v1.instruction, v1.b_constant),
1404                                ValueBound(v2.instruction, v2.b_constant));
1405         // If analysis reveals a certain OOB, disable dynamic BCE. Otherwise,
1406         // use analysis for static bce only if loop is finite.
1407         if (index_range.GetLower().LessThan(array_range->GetLower()) ||
1408             index_range.GetUpper().GreaterThan(array_range->GetUpper())) {
1409           *try_dynamic_bce = false;
1410         } else if (!needs_finite_test && index_range.FitsIn(array_range)) {
1411           return true;
1412         }
1413       }
1414     }
1415     return false;
1416   }
1417 
1418   /**
1419    * Performs loop-based dynamic elimination on a bounds check. In order to minimize the
1420    * number of eventually generated tests, related bounds checks with tests that can be
1421    * combined with tests for the given bounds check are collected first.
1422    */
TransformLoopForDynamicBCE(HLoopInformation * loop,HBoundsCheck * bounds_check)1423   void TransformLoopForDynamicBCE(HLoopInformation* loop, HBoundsCheck* bounds_check) {
1424     HInstruction* index = bounds_check->InputAt(0);
1425     HInstruction* array_length = bounds_check->InputAt(1);
1426     DCHECK(loop->IsDefinedOutOfTheLoop(array_length));  // pre-checked
1427     DCHECK(loop->DominatesAllBackEdges(bounds_check->GetBlock()));
1428     // Collect all bounds checks in the same loop that are related as "a[base + constant]"
1429     // for a base instruction (possibly absent) and various constants.
1430     ValueBound value = ValueBound::AsValueBound(index);
1431     HInstruction* base = value.GetInstruction();
1432     int32_t min_c = base == nullptr ? 0 : value.GetConstant();
1433     int32_t max_c = value.GetConstant();
1434     ScopedArenaVector<HBoundsCheck*> candidates(
1435         allocator_.Adapter(kArenaAllocBoundsCheckElimination));
1436     ScopedArenaVector<HBoundsCheck*> standby(
1437         allocator_.Adapter(kArenaAllocBoundsCheckElimination));
1438     for (const HUseListNode<HInstruction*>& use : array_length->GetUses()) {
1439       HInstruction* user = use.GetUser();
1440       if (user->IsBoundsCheck() && loop == user->GetBlock()->GetLoopInformation()) {
1441         HBoundsCheck* other_bounds_check = user->AsBoundsCheck();
1442         HInstruction* other_index = other_bounds_check->InputAt(0);
1443         HInstruction* other_array_length = other_bounds_check->InputAt(1);
1444         ValueBound other_value = ValueBound::AsValueBound(other_index);
1445         int32_t other_c = other_value.GetConstant();
1446         if (array_length == other_array_length && base == other_value.GetInstruction()) {
1447           // Ensure every candidate could be picked for code generation.
1448           bool b1 = false, b2 = false;
1449           if (!induction_range_.CanGenerateRange(other_bounds_check, other_index, &b1, &b2)) {
1450             continue;
1451           }
1452           // Does the current basic block dominate all back edges? If not,
1453           // add this candidate later only if it falls into the range.
1454           if (!loop->DominatesAllBackEdges(user->GetBlock())) {
1455             standby.push_back(other_bounds_check);
1456             continue;
1457           }
1458           min_c = std::min(min_c, other_c);
1459           max_c = std::max(max_c, other_c);
1460           candidates.push_back(other_bounds_check);
1461         }
1462       }
1463     }
1464     // Add standby candidates that fall in selected range.
1465     for (HBoundsCheck* other_bounds_check : standby) {
1466       HInstruction* other_index = other_bounds_check->InputAt(0);
1467       int32_t other_c = ValueBound::AsValueBound(other_index).GetConstant();
1468       if (min_c <= other_c && other_c <= max_c) {
1469         candidates.push_back(other_bounds_check);
1470       }
1471     }
1472     // Perform loop-based deoptimization if it seems profitable, where we eliminate bounds
1473     // checks and replace these with deopt checks that guard against any possible OOB.
1474     DCHECK_LT(0u, candidates.size());
1475     uint32_t distance = static_cast<uint32_t>(max_c) - static_cast<uint32_t>(min_c);
1476     if ((base != nullptr || min_c >= 0) &&  // reject certain OOB
1477         distance <= kMaxLengthForAddingDeoptimize) {  // reject likely/certain deopt
1478       HBasicBlock* block = GetPreHeader(loop, bounds_check);
1479       HInstruction* min_lower = nullptr;
1480       HInstruction* min_upper = nullptr;
1481       HInstruction* max_lower = nullptr;
1482       HInstruction* max_upper = nullptr;
1483       // Iterate over all bounds checks.
1484       for (HBoundsCheck* other_bounds_check : candidates) {
1485         // Only handle if still in the graph. This avoids visiting the same
1486         // bounds check twice if it occurred multiple times in the use list.
1487         if (other_bounds_check->IsInBlock()) {
1488           HInstruction* other_index = other_bounds_check->InputAt(0);
1489           int32_t other_c = ValueBound::AsValueBound(other_index).GetConstant();
1490           // Generate code for either the maximum or minimum. Range analysis already was queried
1491           // whether code generation on the original and, thus, related bounds check was possible.
1492           // It handles either loop invariants (lower is not set) or unit strides.
1493           if (other_c == max_c) {
1494             induction_range_.GenerateRange(
1495                 other_bounds_check, other_index, GetGraph(), block, &max_lower, &max_upper);
1496           } else if (other_c == min_c && base != nullptr) {
1497             induction_range_.GenerateRange(
1498                 other_bounds_check, other_index, GetGraph(), block, &min_lower, &min_upper);
1499           }
1500           ReplaceInstruction(other_bounds_check, other_index);
1501         }
1502       }
1503       // In code, using unsigned comparisons:
1504       // (1) constants only
1505       //       if (max_upper >= a.length ) deoptimize;
1506       // (2) two symbolic invariants
1507       //       if (min_upper >  max_upper) deoptimize;   unless min_c == max_c
1508       //       if (max_upper >= a.length ) deoptimize;
1509       // (3) general case, unit strides (where lower would exceed upper for arithmetic wrap-around)
1510       //       if (min_lower >  max_lower) deoptimize;   unless min_c == max_c
1511       //       if (max_lower >  max_upper) deoptimize;
1512       //       if (max_upper >= a.length ) deoptimize;
1513       if (base == nullptr) {
1514         // Constants only.
1515         DCHECK_GE(min_c, 0);
1516         DCHECK(min_lower == nullptr && min_upper == nullptr &&
1517                max_lower == nullptr && max_upper != nullptr);
1518       } else if (max_lower == nullptr) {
1519         // Two symbolic invariants.
1520         if (min_c != max_c) {
1521           DCHECK(min_lower == nullptr && min_upper != nullptr &&
1522                  max_lower == nullptr && max_upper != nullptr);
1523           InsertDeoptInLoop(
1524               loop, block, new (GetGraph()->GetAllocator()) HAbove(min_upper, max_upper));
1525         } else {
1526           DCHECK(min_lower == nullptr && min_upper == nullptr &&
1527                  max_lower == nullptr && max_upper != nullptr);
1528         }
1529       } else {
1530         // General case, unit strides.
1531         if (min_c != max_c) {
1532           DCHECK(min_lower != nullptr && min_upper != nullptr &&
1533                  max_lower != nullptr && max_upper != nullptr);
1534           InsertDeoptInLoop(
1535               loop, block, new (GetGraph()->GetAllocator()) HAbove(min_lower, max_lower));
1536         } else {
1537           DCHECK(min_lower == nullptr && min_upper == nullptr &&
1538                  max_lower != nullptr && max_upper != nullptr);
1539         }
1540         InsertDeoptInLoop(
1541             loop, block, new (GetGraph()->GetAllocator()) HAbove(max_lower, max_upper));
1542       }
1543       InsertDeoptInLoop(
1544           loop, block, new (GetGraph()->GetAllocator()) HAboveOrEqual(max_upper, array_length));
1545     } else {
1546       // TODO: if rejected, avoid doing this again for subsequent instructions in this set?
1547     }
1548   }
1549 
1550   /**
1551    * Returns true if heuristics indicate that dynamic bce may be profitable.
1552    */
DynamicBCESeemsProfitable(HLoopInformation * loop,HBasicBlock * block)1553   bool DynamicBCESeemsProfitable(HLoopInformation* loop, HBasicBlock* block) {
1554     if (loop != nullptr) {
1555       // The loop preheader of an irreducible loop does not dominate all the blocks in
1556       // the loop. We would need to find the common dominator of all blocks in the loop.
1557       if (loop->IsIrreducible()) {
1558         return false;
1559       }
1560       // We should never deoptimize from an osr method, otherwise we might wrongly optimize
1561       // code dominated by the deoptimization.
1562       if (GetGraph()->IsCompilingOsr()) {
1563         return false;
1564       }
1565       // A try boundary preheader is hard to handle.
1566       // TODO: remove this restriction.
1567       if (loop->GetPreHeader()->GetLastInstruction()->IsTryBoundary()) {
1568         return false;
1569       }
1570       // Does loop have early-exits? If so, the full range may not be covered by the loop
1571       // at runtime and testing the range may apply deoptimization unnecessarily.
1572       if (IsEarlyExitLoop(loop)) {
1573         return false;
1574       }
1575       // Does the current basic block dominate all back edges? If not,
1576       // don't apply dynamic bce to something that may not be executed.
1577       return loop->DominatesAllBackEdges(block);
1578     }
1579     return false;
1580   }
1581 
1582   /**
1583    * Returns true if the loop has early exits, which implies it may not cover
1584    * the full range computed by range analysis based on induction variables.
1585    */
IsEarlyExitLoop(HLoopInformation * loop)1586   bool IsEarlyExitLoop(HLoopInformation* loop) {
1587     const uint32_t loop_id = loop->GetHeader()->GetBlockId();
1588     // If loop has been analyzed earlier for early-exit, don't repeat the analysis.
1589     auto it = early_exit_loop_.find(loop_id);
1590     if (it != early_exit_loop_.end()) {
1591       return it->second;
1592     }
1593     // First time early-exit analysis for this loop. Since analysis requires scanning
1594     // the full loop-body, results of the analysis is stored for subsequent queries.
1595     HBlocksInLoopReversePostOrderIterator it_loop(*loop);
1596     for (it_loop.Advance(); !it_loop.Done(); it_loop.Advance()) {
1597       for (HBasicBlock* successor : it_loop.Current()->GetSuccessors()) {
1598         if (!loop->Contains(*successor)) {
1599           early_exit_loop_.Put(loop_id, true);
1600           return true;
1601         }
1602       }
1603     }
1604     early_exit_loop_.Put(loop_id, false);
1605     return false;
1606   }
1607 
1608   /**
1609    * Returns true if the array length is already loop invariant, or can be made so
1610    * by handling the null check under the hood of the array length operation.
1611    */
CanHandleLength(HLoopInformation * loop,HInstruction * length,bool needs_taken_test)1612   bool CanHandleLength(HLoopInformation* loop, HInstruction* length, bool needs_taken_test) {
1613     if (loop->IsDefinedOutOfTheLoop(length)) {
1614       return true;
1615     } else if (length->IsArrayLength() && length->GetBlock()->GetLoopInformation() == loop) {
1616       if (CanHandleNullCheck(loop, length->InputAt(0), needs_taken_test)) {
1617         HoistToPreHeaderOrDeoptBlock(loop, length);
1618         return true;
1619       }
1620     }
1621     return false;
1622   }
1623 
1624   /**
1625    * Returns true if the null check is already loop invariant, or can be made so
1626    * by generating a deoptimization test.
1627    */
CanHandleNullCheck(HLoopInformation * loop,HInstruction * check,bool needs_taken_test)1628   bool CanHandleNullCheck(HLoopInformation* loop, HInstruction* check, bool needs_taken_test) {
1629     if (loop->IsDefinedOutOfTheLoop(check)) {
1630       return true;
1631     } else if (check->IsNullCheck() && check->GetBlock()->GetLoopInformation() == loop) {
1632       HInstruction* array = check->InputAt(0);
1633       if (loop->IsDefinedOutOfTheLoop(array)) {
1634         // Generate: if (array == null) deoptimize;
1635         TransformLoopForDeoptimizationIfNeeded(loop, needs_taken_test);
1636         HBasicBlock* block = GetPreHeader(loop, check);
1637         HInstruction* cond =
1638             new (GetGraph()->GetAllocator()) HEqual(array, GetGraph()->GetNullConstant());
1639         InsertDeoptInLoop(loop, block, cond, /* is_null_check= */ true);
1640         ReplaceInstruction(check, array);
1641         return true;
1642       }
1643     }
1644     return false;
1645   }
1646 
1647   /**
1648    * Returns true if compiler can apply dynamic bce to loops that may be infinite
1649    * (e.g. for (int i = 0; i <= U; i++) with U = MAX_INT), which would invalidate
1650    * the range analysis evaluation code by "overshooting" the computed range.
1651    * Since deoptimization would be a bad choice, and there is no other version
1652    * of the loop to use, dynamic bce in such cases is only allowed if other tests
1653    * ensure the loop is finite.
1654    */
CanHandleInfiniteLoop(HLoopInformation * loop,HInstruction * index,bool needs_infinite_test)1655   bool CanHandleInfiniteLoop(HLoopInformation* loop, HInstruction* index, bool needs_infinite_test) {
1656     if (needs_infinite_test) {
1657       // If we already forced the loop to be finite, allow directly.
1658       const uint32_t loop_id = loop->GetHeader()->GetBlockId();
1659       if (finite_loop_.find(loop_id) != finite_loop_.end()) {
1660         return true;
1661       }
1662       // Otherwise, allow dynamic bce if the index (which is necessarily an induction at
1663       // this point) is the direct loop index (viz. a[i]), since then the runtime tests
1664       // ensure upper bound cannot cause an infinite loop.
1665       HInstruction* control = loop->GetHeader()->GetLastInstruction();
1666       if (control->IsIf()) {
1667         HInstruction* if_expr = control->AsIf()->InputAt(0);
1668         if (if_expr->IsCondition()) {
1669           HCondition* condition = if_expr->AsCondition();
1670           if (index == condition->InputAt(0) ||
1671               index == condition->InputAt(1)) {
1672             finite_loop_.insert(loop_id);
1673             return true;
1674           }
1675         }
1676       }
1677       return false;
1678     }
1679     return true;
1680   }
1681 
1682   /**
1683    * Returns appropriate preheader for the loop, depending on whether the
1684    * instruction appears in the loop header or proper loop-body.
1685    */
GetPreHeader(HLoopInformation * loop,HInstruction * instruction)1686   HBasicBlock* GetPreHeader(HLoopInformation* loop, HInstruction* instruction) {
1687     // Use preheader unless there is an earlier generated deoptimization block since
1688     // hoisted expressions may depend on and/or used by the deoptimization tests.
1689     HBasicBlock* header = loop->GetHeader();
1690     const uint32_t loop_id = header->GetBlockId();
1691     auto it = taken_test_loop_.find(loop_id);
1692     if (it != taken_test_loop_.end()) {
1693       HBasicBlock* block = it->second;
1694       // If always taken, keep it that way by returning the original preheader,
1695       // which can be found by following the predecessor of the true-block twice.
1696       if (instruction->GetBlock() == header) {
1697         return block->GetSinglePredecessor()->GetSinglePredecessor();
1698       }
1699       return block;
1700     }
1701     return loop->GetPreHeader();
1702   }
1703 
1704   /** Inserts a deoptimization test in a loop preheader. */
InsertDeoptInLoop(HLoopInformation * loop,HBasicBlock * block,HInstruction * condition,bool is_null_check=false)1705   void InsertDeoptInLoop(HLoopInformation* loop,
1706                          HBasicBlock* block,
1707                          HInstruction* condition,
1708                          bool is_null_check = false) {
1709     HInstruction* suspend = loop->GetSuspendCheck();
1710     block->InsertInstructionBefore(condition, block->GetLastInstruction());
1711     DeoptimizationKind kind =
1712         is_null_check ? DeoptimizationKind::kLoopNullBCE : DeoptimizationKind::kLoopBoundsBCE;
1713     HDeoptimize* deoptimize = new (GetGraph()->GetAllocator()) HDeoptimize(
1714         GetGraph()->GetAllocator(), condition, kind, suspend->GetDexPc());
1715     block->InsertInstructionBefore(deoptimize, block->GetLastInstruction());
1716     if (suspend->HasEnvironment()) {
1717       deoptimize->CopyEnvironmentFromWithLoopPhiAdjustment(
1718           suspend->GetEnvironment(), loop->GetHeader());
1719     }
1720   }
1721 
1722   /** Inserts a deoptimization test right before a bounds check. */
InsertDeoptInBlock(HBoundsCheck * bounds_check,HInstruction * condition)1723   void InsertDeoptInBlock(HBoundsCheck* bounds_check, HInstruction* condition) {
1724     HBasicBlock* block = bounds_check->GetBlock();
1725     block->InsertInstructionBefore(condition, bounds_check);
1726     HDeoptimize* deoptimize = new (GetGraph()->GetAllocator()) HDeoptimize(
1727         GetGraph()->GetAllocator(),
1728         condition,
1729         DeoptimizationKind::kBlockBCE,
1730         bounds_check->GetDexPc());
1731     block->InsertInstructionBefore(deoptimize, bounds_check);
1732     deoptimize->CopyEnvironmentFrom(bounds_check->GetEnvironment());
1733   }
1734 
1735   /** Hoists instruction out of the loop to preheader or deoptimization block. */
HoistToPreHeaderOrDeoptBlock(HLoopInformation * loop,HInstruction * instruction)1736   void HoistToPreHeaderOrDeoptBlock(HLoopInformation* loop, HInstruction* instruction) {
1737     HBasicBlock* block = GetPreHeader(loop, instruction);
1738     DCHECK(!instruction->HasEnvironment());
1739     instruction->MoveBefore(block->GetLastInstruction());
1740   }
1741 
1742   /**
1743    * Adds a new taken-test structure to a loop if needed and not already done.
1744    * The taken-test protects range analysis evaluation code to avoid any
1745    * deoptimization caused by incorrect trip-count evaluation in non-taken loops.
1746    *
1747    *          old_preheader
1748    *               |
1749    *            if_block          <- taken-test protects deoptimization block
1750    *            /      \
1751    *     true_block  false_block  <- deoptimizations/invariants are placed in true_block
1752    *            \       /
1753    *          new_preheader       <- may require phi nodes to preserve SSA structure
1754    *                |
1755    *             header
1756    *
1757    * For example, this loop:
1758    *
1759    *   for (int i = lower; i < upper; i++) {
1760    *     array[i] = 0;
1761    *   }
1762    *
1763    * will be transformed to:
1764    *
1765    *   if (lower < upper) {
1766    *     if (array == null) deoptimize;
1767    *     array_length = array.length;
1768    *     if (lower > upper)         deoptimize;  // unsigned
1769    *     if (upper >= array_length) deoptimize;  // unsigned
1770    *   } else {
1771    *     array_length = 0;
1772    *   }
1773    *   for (int i = lower; i < upper; i++) {
1774    *     // Loop without null check and bounds check, and any array.length replaced with array_length.
1775    *     array[i] = 0;
1776    *   }
1777    */
TransformLoopForDeoptimizationIfNeeded(HLoopInformation * loop,bool needs_taken_test)1778   void TransformLoopForDeoptimizationIfNeeded(HLoopInformation* loop, bool needs_taken_test) {
1779     // Not needed (can use preheader) or already done (can reuse)?
1780     const uint32_t loop_id = loop->GetHeader()->GetBlockId();
1781     if (!needs_taken_test || taken_test_loop_.find(loop_id) != taken_test_loop_.end()) {
1782       return;
1783     }
1784 
1785     // Generate top test structure.
1786     HBasicBlock* header = loop->GetHeader();
1787     GetGraph()->TransformLoopHeaderForBCE(header);
1788     HBasicBlock* new_preheader = loop->GetPreHeader();
1789     HBasicBlock* if_block = new_preheader->GetDominator();
1790     HBasicBlock* true_block = if_block->GetSuccessors()[0];  // True successor.
1791     HBasicBlock* false_block = if_block->GetSuccessors()[1];  // False successor.
1792 
1793     // Goto instructions.
1794     true_block->AddInstruction(new (GetGraph()->GetAllocator()) HGoto());
1795     false_block->AddInstruction(new (GetGraph()->GetAllocator()) HGoto());
1796     new_preheader->AddInstruction(new (GetGraph()->GetAllocator()) HGoto());
1797 
1798     // Insert the taken-test to see if the loop body is entered. If the
1799     // loop isn't entered at all, it jumps around the deoptimization block.
1800     if_block->AddInstruction(new (GetGraph()->GetAllocator()) HGoto());  // placeholder
1801     HInstruction* condition = induction_range_.GenerateTakenTest(
1802         header->GetLastInstruction(), GetGraph(), if_block);
1803     DCHECK(condition != nullptr);
1804     if_block->RemoveInstruction(if_block->GetLastInstruction());
1805     if_block->AddInstruction(new (GetGraph()->GetAllocator()) HIf(condition));
1806 
1807     taken_test_loop_.Put(loop_id, true_block);
1808   }
1809 
1810   /**
1811    * Inserts phi nodes that preserve SSA structure in generated top test structures.
1812    * All uses of instructions in the deoptimization block that reach the loop need
1813    * a phi node in the new loop preheader to fix the dominance relation.
1814    *
1815    * Example:
1816    *           if_block
1817    *            /      \
1818    *         x_0 = ..  false_block
1819    *            \       /
1820    *           x_1 = phi(x_0, null)   <- synthetic phi
1821    *               |
1822    *          new_preheader
1823    */
InsertPhiNodes()1824   void InsertPhiNodes() {
1825     // Scan all new deoptimization blocks.
1826     for (const auto& entry : taken_test_loop_) {
1827       HBasicBlock* true_block = entry.second;
1828       HBasicBlock* new_preheader = true_block->GetSingleSuccessor();
1829       // Scan all instructions in a new deoptimization block.
1830       for (HInstructionIterator it(true_block->GetInstructions()); !it.Done(); it.Advance()) {
1831         HInstruction* instruction = it.Current();
1832         DataType::Type type = instruction->GetType();
1833         HPhi* phi = nullptr;
1834         // Scan all uses of an instruction and replace each later use with a phi node.
1835         const HUseList<HInstruction*>& uses = instruction->GetUses();
1836         for (auto it2 = uses.begin(), end2 = uses.end(); it2 != end2; /* ++it2 below */) {
1837           HInstruction* user = it2->GetUser();
1838           size_t index = it2->GetIndex();
1839           // Increment `it2` now because `*it2` may disappear thanks to user->ReplaceInput().
1840           ++it2;
1841           if (user->GetBlock() != true_block) {
1842             if (phi == nullptr) {
1843               phi = NewPhi(new_preheader, instruction, type);
1844             }
1845             user->ReplaceInput(phi, index);  // Removes the use node from the list.
1846             induction_range_.Replace(user, instruction, phi);  // update induction
1847           }
1848         }
1849         // Scan all environment uses of an instruction and replace each later use with a phi node.
1850         const HUseList<HEnvironment*>& env_uses = instruction->GetEnvUses();
1851         for (auto it2 = env_uses.begin(), end2 = env_uses.end(); it2 != end2; /* ++it2 below */) {
1852           HEnvironment* user = it2->GetUser();
1853           size_t index = it2->GetIndex();
1854           // Increment `it2` now because `*it2` may disappear thanks to user->RemoveAsUserOfInput().
1855           ++it2;
1856           if (user->GetHolder()->GetBlock() != true_block) {
1857             if (phi == nullptr) {
1858               phi = NewPhi(new_preheader, instruction, type);
1859             }
1860             user->RemoveAsUserOfInput(index);
1861             user->SetRawEnvAt(index, phi);
1862             phi->AddEnvUseAt(user, index);
1863           }
1864         }
1865       }
1866     }
1867   }
1868 
1869   /**
1870    * Construct a phi(instruction, 0) in the new preheader to fix the dominance relation.
1871    * These are synthetic phi nodes without a virtual register.
1872    */
NewPhi(HBasicBlock * new_preheader,HInstruction * instruction,DataType::Type type)1873   HPhi* NewPhi(HBasicBlock* new_preheader,
1874                HInstruction* instruction,
1875                DataType::Type type) {
1876     HGraph* graph = GetGraph();
1877     HInstruction* zero;
1878     switch (type) {
1879       case DataType::Type::kReference: zero = graph->GetNullConstant(); break;
1880       case DataType::Type::kFloat32: zero = graph->GetFloatConstant(0); break;
1881       case DataType::Type::kFloat64: zero = graph->GetDoubleConstant(0); break;
1882       default: zero = graph->GetConstant(type, 0); break;
1883     }
1884     HPhi* phi = new (graph->GetAllocator())
1885         HPhi(graph->GetAllocator(), kNoRegNumber, /*number_of_inputs*/ 2, HPhi::ToPhiType(type));
1886     phi->SetRawInputAt(0, instruction);
1887     phi->SetRawInputAt(1, zero);
1888     if (type == DataType::Type::kReference) {
1889       phi->SetReferenceTypeInfo(instruction->GetReferenceTypeInfo());
1890     }
1891     new_preheader->AddPhi(phi);
1892     return phi;
1893   }
1894 
1895   /** Helper method to replace an instruction with another instruction. */
ReplaceInstruction(HInstruction * instruction,HInstruction * replacement)1896   void ReplaceInstruction(HInstruction* instruction, HInstruction* replacement) {
1897     // Safe iteration.
1898     if (instruction == next_) {
1899       next_ = next_->GetNext();
1900     }
1901     // Replace and remove.
1902     instruction->ReplaceWith(replacement);
1903     instruction->GetBlock()->RemoveInstruction(instruction);
1904   }
1905 
1906   // Use local allocator for allocating memory.
1907   ScopedArenaAllocator allocator_;
1908 
1909   // A set of maps, one per basic block, from instruction to range.
1910   ScopedArenaVector<ScopedArenaSafeMap<int, ValueRange*>> maps_;
1911 
1912   // Map an HArrayLength instruction's id to the first HBoundsCheck instruction
1913   // in a block that checks an index against that HArrayLength.
1914   ScopedArenaSafeMap<int, HBoundsCheck*> first_index_bounds_check_map_;
1915 
1916   // Early-exit loop bookkeeping.
1917   ScopedArenaSafeMap<uint32_t, bool> early_exit_loop_;
1918 
1919   // Taken-test loop bookkeeping.
1920   ScopedArenaSafeMap<uint32_t, HBasicBlock*> taken_test_loop_;
1921 
1922   // Finite loop bookkeeping.
1923   ScopedArenaSet<uint32_t> finite_loop_;
1924 
1925   // Flag that denotes whether dominator-based dynamic elimination has occurred.
1926   bool has_dom_based_dynamic_bce_;
1927 
1928   // Initial number of blocks.
1929   uint32_t initial_block_size_;
1930 
1931   // Side effects.
1932   const SideEffectsAnalysis& side_effects_;
1933 
1934   // Range analysis based on induction variables.
1935   InductionVarRange induction_range_;
1936 
1937   // Safe iteration.
1938   HInstruction* next_;
1939 
1940   DISALLOW_COPY_AND_ASSIGN(BCEVisitor);
1941 };
1942 
Run()1943 bool BoundsCheckElimination::Run() {
1944   if (!graph_->HasBoundsChecks()) {
1945     return false;
1946   }
1947 
1948   // Reverse post order guarantees a node's dominators are visited first.
1949   // We want to visit in the dominator-based order since if a value is known to
1950   // be bounded by a range at one instruction, it must be true that all uses of
1951   // that value dominated by that instruction fits in that range. Range of that
1952   // value can be narrowed further down in the dominator tree.
1953   BCEVisitor visitor(graph_, side_effects_, induction_analysis_);
1954   for (size_t i = 0, size = graph_->GetReversePostOrder().size(); i != size; ++i) {
1955     HBasicBlock* current = graph_->GetReversePostOrder()[i];
1956     if (visitor.IsAddedBlock(current)) {
1957       // Skip added blocks. Their effects are already taken care of.
1958       continue;
1959     }
1960     visitor.VisitBasicBlock(current);
1961     // Skip forward to the current block in case new basic blocks were inserted
1962     // (which always appear earlier in reverse post order) to avoid visiting the
1963     // same basic block twice.
1964     size_t new_size = graph_->GetReversePostOrder().size();
1965     DCHECK_GE(new_size, size);
1966     i += new_size - size;
1967     DCHECK_EQ(current, graph_->GetReversePostOrder()[i]);
1968     size = new_size;
1969   }
1970 
1971   // Perform cleanup.
1972   visitor.Finish();
1973 
1974   return true;
1975 }
1976 
1977 }  // namespace art
1978