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1 /*
2  * Copyright (C) 2017 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 #ifndef ART_COMPILER_OPTIMIZING_NODES_VECTOR_H_
18 #define ART_COMPILER_OPTIMIZING_NODES_VECTOR_H_
19 
20 // This #include should never be used by compilation, because this header file (nodes_vector.h)
21 // is included in the header file nodes.h itself. However it gives editing tools better context.
22 #include "nodes.h"
23 
24 namespace art {
25 
26 // Memory alignment, represented as an offset relative to a base, where 0 <= offset < base,
27 // and base is a power of two. For example, the value Alignment(16, 0) means memory is
28 // perfectly aligned at a 16-byte boundary, whereas the value Alignment(16, 4) means
29 // memory is always exactly 4 bytes above such a boundary.
30 class Alignment {
31  public:
Alignment(size_t base,size_t offset)32   Alignment(size_t base, size_t offset) : base_(base), offset_(offset) {
33     DCHECK_LT(offset, base);
34     DCHECK(IsPowerOfTwo(base));
35   }
36 
37   // Returns true if memory is at least aligned at the given boundary.
38   // Assumes requested base is power of two.
IsAlignedAt(size_t base)39   bool IsAlignedAt(size_t base) const {
40     DCHECK_NE(0u, base);
41     DCHECK(IsPowerOfTwo(base));
42     return ((offset_ | base_) & (base - 1u)) == 0;
43   }
44 
Base()45   size_t Base() const { return base_; }
46 
Offset()47   size_t Offset() const { return offset_; }
48 
ToString()49   std::string ToString() const {
50     return "ALIGN(" + std::to_string(base_) + "," + std::to_string(offset_) + ")";
51   }
52 
53   bool operator==(const Alignment& other) const {
54     return base_ == other.base_ && offset_ == other.offset_;
55   }
56 
57  private:
58   size_t base_;
59   size_t offset_;
60 };
61 
62 //
63 // Definitions of abstract vector operations in HIR.
64 //
65 
66 // Abstraction of a vector operation, i.e., an operation that performs
67 // GetVectorLength() x GetPackedType() operations simultaneously.
68 class HVecOperation : public HVariableInputSizeInstruction {
69  public:
70   // A SIMD operation looks like a FPU location.
71   // TODO: we could introduce SIMD types in HIR.
72   static constexpr DataType::Type kSIMDType = DataType::Type::kFloat64;
73 
HVecOperation(InstructionKind kind,ArenaAllocator * allocator,DataType::Type packed_type,SideEffects side_effects,size_t number_of_inputs,size_t vector_length,uint32_t dex_pc)74   HVecOperation(InstructionKind kind,
75                 ArenaAllocator* allocator,
76                 DataType::Type packed_type,
77                 SideEffects side_effects,
78                 size_t number_of_inputs,
79                 size_t vector_length,
80                 uint32_t dex_pc)
81       : HVariableInputSizeInstruction(kind,
82                                       kSIMDType,
83                                       side_effects,
84                                       dex_pc,
85                                       allocator,
86                                       number_of_inputs,
87                                       kArenaAllocVectorNode),
88         vector_length_(vector_length) {
89     SetPackedField<PackedTypeField>(packed_type);
90     DCHECK_LT(1u, vector_length);
91   }
92 
93   // Returns the number of elements packed in a vector.
GetVectorLength()94   size_t GetVectorLength() const {
95     return vector_length_;
96   }
97 
98   // Returns the number of bytes in a full vector.
GetVectorNumberOfBytes()99   size_t GetVectorNumberOfBytes() const {
100     return vector_length_ * DataType::Size(GetPackedType());
101   }
102 
103   // Returns the true component type packed in a vector.
GetPackedType()104   DataType::Type GetPackedType() const {
105     return GetPackedField<PackedTypeField>();
106   }
107 
108   // Assumes vector nodes cannot be moved by default. Each concrete implementation
109   // that can be moved should override this method and return true.
110   //
111   // Note: similar approach is used for instruction scheduling (if it is turned on for the target):
112   // by default HScheduler::IsSchedulable returns false for a particular HVecOperation.
113   // HScheduler${ARCH}::IsSchedulable can be overridden to return true for an instruction (see
114   // scheduler_arm64.h for example) if it is safe to schedule it; in this case one *must* also
115   // look at/update HScheduler${ARCH}::IsSchedulingBarrier for this instruction.
116   //
117   // Note: For newly introduced vector instructions HScheduler${ARCH}::IsSchedulingBarrier must be
118   // altered to return true if the instruction might reside outside the SIMD loop body since SIMD
119   // registers are not kept alive across vector loop boundaries (yet).
CanBeMoved()120   bool CanBeMoved() const override { return false; }
121 
122   // Tests if all data of a vector node (vector length and packed type) is equal.
123   // Each concrete implementation that adds more fields should test equality of
124   // those fields in its own method *and* call all super methods.
InstructionDataEquals(const HInstruction * other)125   bool InstructionDataEquals(const HInstruction* other) const override {
126     DCHECK(other->IsVecOperation());
127     const HVecOperation* o = other->AsVecOperation();
128     return GetVectorLength() == o->GetVectorLength() && GetPackedType() == o->GetPackedType();
129   }
130 
131   // Maps an integral type to the same-size signed type and leaves other types alone.
ToSignedType(DataType::Type type)132   static DataType::Type ToSignedType(DataType::Type type) {
133     switch (type) {
134       case DataType::Type::kBool:  // 1-byte storage unit
135       case DataType::Type::kUint8:
136         return DataType::Type::kInt8;
137       case DataType::Type::kUint16:
138         return DataType::Type::kInt16;
139       default:
140         DCHECK(type != DataType::Type::kVoid && type != DataType::Type::kReference) << type;
141         return type;
142     }
143   }
144 
145   // Maps an integral type to the same-size unsigned type and leaves other types alone.
ToUnsignedType(DataType::Type type)146   static DataType::Type ToUnsignedType(DataType::Type type) {
147     switch (type) {
148       case DataType::Type::kBool:  // 1-byte storage unit
149       case DataType::Type::kInt8:
150         return DataType::Type::kUint8;
151       case DataType::Type::kInt16:
152         return DataType::Type::kUint16;
153       default:
154         DCHECK(type != DataType::Type::kVoid && type != DataType::Type::kReference) << type;
155         return type;
156     }
157   }
158 
159   // Maps an integral type to the same-size (un)signed type. Leaves other types alone.
ToProperType(DataType::Type type,bool is_unsigned)160   static DataType::Type ToProperType(DataType::Type type, bool is_unsigned) {
161     return is_unsigned ? ToUnsignedType(type) : ToSignedType(type);
162   }
163 
164   // Helper method to determine if an instruction returns a SIMD value.
165   // TODO: This method is needed until we introduce SIMD as proper type.
ReturnsSIMDValue(HInstruction * instruction)166   static bool ReturnsSIMDValue(HInstruction* instruction) {
167     if (instruction->IsVecOperation()) {
168       return !instruction->IsVecExtractScalar();  // only scalar returning vec op
169     } else if (instruction->IsPhi()) {
170       // Vectorizer only uses Phis in reductions, so checking for a 2-way phi
171       // with a direct vector operand as second argument suffices.
172       return
173           instruction->GetType() == kSIMDType &&
174           instruction->InputCount() == 2 &&
175           instruction->InputAt(1)->IsVecOperation();
176     }
177     return false;
178   }
179 
180   DECLARE_ABSTRACT_INSTRUCTION(VecOperation);
181 
182  protected:
183   // Additional packed bits.
184   static constexpr size_t kFieldPackedType = HInstruction::kNumberOfGenericPackedBits;
185   static constexpr size_t kFieldPackedTypeSize =
186       MinimumBitsToStore(static_cast<size_t>(DataType::Type::kLast));
187   static constexpr size_t kNumberOfVectorOpPackedBits = kFieldPackedType + kFieldPackedTypeSize;
188   static_assert(kNumberOfVectorOpPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
189   using PackedTypeField = BitField<DataType::Type, kFieldPackedType, kFieldPackedTypeSize>;
190 
191   DEFAULT_COPY_CONSTRUCTOR(VecOperation);
192 
193  private:
194   const size_t vector_length_;
195 };
196 
197 // Abstraction of a unary vector operation.
198 class HVecUnaryOperation : public HVecOperation {
199  public:
HVecUnaryOperation(InstructionKind kind,ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)200   HVecUnaryOperation(InstructionKind kind,
201                      ArenaAllocator* allocator,
202                      HInstruction* input,
203                      DataType::Type packed_type,
204                      size_t vector_length,
205                      uint32_t dex_pc)
206       : HVecOperation(kind,
207                       allocator,
208                       packed_type,
209                       SideEffects::None(),
210                       /* number_of_inputs= */ 1,
211                       vector_length,
212                       dex_pc) {
213     SetRawInputAt(0, input);
214   }
215 
GetInput()216   HInstruction* GetInput() const { return InputAt(0); }
217 
218   DECLARE_ABSTRACT_INSTRUCTION(VecUnaryOperation);
219 
220  protected:
221   DEFAULT_COPY_CONSTRUCTOR(VecUnaryOperation);
222 };
223 
224 // Abstraction of a binary vector operation.
225 class HVecBinaryOperation : public HVecOperation {
226  public:
HVecBinaryOperation(InstructionKind kind,ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)227   HVecBinaryOperation(InstructionKind kind,
228                       ArenaAllocator* allocator,
229                       HInstruction* left,
230                       HInstruction* right,
231                       DataType::Type packed_type,
232                       size_t vector_length,
233                       uint32_t dex_pc)
234       : HVecOperation(kind,
235                       allocator,
236                       packed_type,
237                       SideEffects::None(),
238                       /* number_of_inputs= */ 2,
239                       vector_length,
240                       dex_pc) {
241     SetRawInputAt(0, left);
242     SetRawInputAt(1, right);
243   }
244 
GetLeft()245   HInstruction* GetLeft() const { return InputAt(0); }
GetRight()246   HInstruction* GetRight() const { return InputAt(1); }
247 
248   DECLARE_ABSTRACT_INSTRUCTION(VecBinaryOperation);
249 
250  protected:
251   DEFAULT_COPY_CONSTRUCTOR(VecBinaryOperation);
252 };
253 
254 // Abstraction of a vector operation that references memory, with an alignment.
255 // The Android runtime guarantees elements have at least natural alignment.
256 class HVecMemoryOperation : public HVecOperation {
257  public:
HVecMemoryOperation(InstructionKind kind,ArenaAllocator * allocator,DataType::Type packed_type,SideEffects side_effects,size_t number_of_inputs,size_t vector_length,uint32_t dex_pc)258   HVecMemoryOperation(InstructionKind kind,
259                       ArenaAllocator* allocator,
260                       DataType::Type packed_type,
261                       SideEffects side_effects,
262                       size_t number_of_inputs,
263                       size_t vector_length,
264                       uint32_t dex_pc)
265       : HVecOperation(kind,
266                       allocator,
267                       packed_type,
268                       side_effects,
269                       number_of_inputs,
270                       vector_length,
271                       dex_pc),
272         alignment_(DataType::Size(packed_type), 0) {
273     DCHECK_GE(number_of_inputs, 2u);
274   }
275 
SetAlignment(Alignment alignment)276   void SetAlignment(Alignment alignment) { alignment_ = alignment; }
277 
GetAlignment()278   Alignment GetAlignment() const { return alignment_; }
279 
GetArray()280   HInstruction* GetArray() const { return InputAt(0); }
GetIndex()281   HInstruction* GetIndex() const { return InputAt(1); }
282 
InstructionDataEquals(const HInstruction * other)283   bool InstructionDataEquals(const HInstruction* other) const override {
284     DCHECK(other->IsVecMemoryOperation());
285     const HVecMemoryOperation* o = other->AsVecMemoryOperation();
286     return HVecOperation::InstructionDataEquals(o) && GetAlignment() == o->GetAlignment();
287   }
288 
289   DECLARE_ABSTRACT_INSTRUCTION(VecMemoryOperation);
290 
291  protected:
292   DEFAULT_COPY_CONSTRUCTOR(VecMemoryOperation);
293 
294  private:
295   Alignment alignment_;
296 };
297 
298 // Packed type consistency checker ("same vector length" integral types may mix freely).
299 // Tests relaxed type consistency in which packed same-size integral types can co-exist,
300 // but other type mixes are an error.
HasConsistentPackedTypes(HInstruction * input,DataType::Type type)301 inline static bool HasConsistentPackedTypes(HInstruction* input, DataType::Type type) {
302   if (input->IsPhi()) {
303     return input->GetType() == HVecOperation::kSIMDType;  // carries SIMD
304   }
305   DCHECK(input->IsVecOperation());
306   DataType::Type input_type = input->AsVecOperation()->GetPackedType();
307   DCHECK_EQ(HVecOperation::ToUnsignedType(input_type) == HVecOperation::ToUnsignedType(type),
308             HVecOperation::ToSignedType(input_type) == HVecOperation::ToSignedType(type));
309   return HVecOperation::ToSignedType(input_type) == HVecOperation::ToSignedType(type);
310 }
311 
312 //
313 // Definitions of concrete unary vector operations in HIR.
314 //
315 
316 // Replicates the given scalar into a vector,
317 // viz. replicate(x) = [ x, .. , x ].
318 class HVecReplicateScalar final : public HVecUnaryOperation {
319  public:
HVecReplicateScalar(ArenaAllocator * allocator,HInstruction * scalar,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)320   HVecReplicateScalar(ArenaAllocator* allocator,
321                       HInstruction* scalar,
322                       DataType::Type packed_type,
323                       size_t vector_length,
324                       uint32_t dex_pc)
325       : HVecUnaryOperation(
326             kVecReplicateScalar, allocator, scalar, packed_type, vector_length, dex_pc) {
327     DCHECK(!ReturnsSIMDValue(scalar));
328   }
329 
330   // A replicate needs to stay in place, since SIMD registers are not
331   // kept alive across vector loop boundaries (yet).
CanBeMoved()332   bool CanBeMoved() const override { return false; }
333 
334   DECLARE_INSTRUCTION(VecReplicateScalar);
335 
336  protected:
337   DEFAULT_COPY_CONSTRUCTOR(VecReplicateScalar);
338 };
339 
340 // Extracts a particular scalar from the given vector,
341 // viz. extract[ x1, .. , xn ] = x_i.
342 //
343 // TODO: for now only i == 1 case supported.
344 class HVecExtractScalar final : public HVecUnaryOperation {
345  public:
HVecExtractScalar(ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,size_t index,uint32_t dex_pc)346   HVecExtractScalar(ArenaAllocator* allocator,
347                     HInstruction* input,
348                     DataType::Type packed_type,
349                     size_t vector_length,
350                     size_t index,
351                     uint32_t dex_pc)
352       : HVecUnaryOperation(
353             kVecExtractScalar, allocator, input, packed_type, vector_length, dex_pc) {
354     DCHECK(HasConsistentPackedTypes(input, packed_type));
355     DCHECK_LT(index, vector_length);
356     DCHECK_EQ(index, 0u);
357     // Yields a single component in the vector.
358     // Overrides the kSIMDType set by the VecOperation constructor.
359     SetPackedField<TypeField>(packed_type);
360   }
361 
362   // An extract needs to stay in place, since SIMD registers are not
363   // kept alive across vector loop boundaries (yet).
CanBeMoved()364   bool CanBeMoved() const override { return false; }
365 
366   DECLARE_INSTRUCTION(VecExtractScalar);
367 
368  protected:
369   DEFAULT_COPY_CONSTRUCTOR(VecExtractScalar);
370 };
371 
372 // Reduces the given vector into the first element as sum/min/max,
373 // viz. sum-reduce[ x1, .. , xn ] = [ y, ---- ], where y = sum xi
374 // and the "-" denotes "don't care" (implementation dependent).
375 class HVecReduce final : public HVecUnaryOperation {
376  public:
377   enum ReductionKind {
378     kSum = 1,
379     kMin = 2,
380     kMax = 3
381   };
382 
HVecReduce(ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,ReductionKind reduction_kind,uint32_t dex_pc)383   HVecReduce(ArenaAllocator* allocator,
384              HInstruction* input,
385              DataType::Type packed_type,
386              size_t vector_length,
387              ReductionKind reduction_kind,
388              uint32_t dex_pc)
389       : HVecUnaryOperation(kVecReduce, allocator, input, packed_type, vector_length, dex_pc),
390         reduction_kind_(reduction_kind) {
391     DCHECK(HasConsistentPackedTypes(input, packed_type));
392   }
393 
GetReductionKind()394   ReductionKind GetReductionKind() const { return reduction_kind_; }
395 
CanBeMoved()396   bool CanBeMoved() const override { return true; }
397 
InstructionDataEquals(const HInstruction * other)398   bool InstructionDataEquals(const HInstruction* other) const override {
399     DCHECK(other->IsVecReduce());
400     const HVecReduce* o = other->AsVecReduce();
401     return HVecOperation::InstructionDataEquals(o) && GetReductionKind() == o->GetReductionKind();
402   }
403 
404   DECLARE_INSTRUCTION(VecReduce);
405 
406  protected:
407   DEFAULT_COPY_CONSTRUCTOR(VecReduce);
408 
409  private:
410   const ReductionKind reduction_kind_;
411 };
412 
413 // Converts every component in the vector,
414 // viz. cnv[ x1, .. , xn ]  = [ cnv(x1), .. , cnv(xn) ].
415 class HVecCnv final : public HVecUnaryOperation {
416  public:
HVecCnv(ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)417   HVecCnv(ArenaAllocator* allocator,
418           HInstruction* input,
419           DataType::Type packed_type,
420           size_t vector_length,
421           uint32_t dex_pc)
422       : HVecUnaryOperation(kVecCnv, allocator, input, packed_type, vector_length, dex_pc) {
423     DCHECK(input->IsVecOperation());
424     DCHECK_NE(GetInputType(), GetResultType());  // actual convert
425   }
426 
GetInputType()427   DataType::Type GetInputType() const { return InputAt(0)->AsVecOperation()->GetPackedType(); }
GetResultType()428   DataType::Type GetResultType() const { return GetPackedType(); }
429 
CanBeMoved()430   bool CanBeMoved() const override { return true; }
431 
432   DECLARE_INSTRUCTION(VecCnv);
433 
434  protected:
435   DEFAULT_COPY_CONSTRUCTOR(VecCnv);
436 };
437 
438 // Negates every component in the vector,
439 // viz. neg[ x1, .. , xn ]  = [ -x1, .. , -xn ].
440 class HVecNeg final : public HVecUnaryOperation {
441  public:
HVecNeg(ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)442   HVecNeg(ArenaAllocator* allocator,
443           HInstruction* input,
444           DataType::Type packed_type,
445           size_t vector_length,
446           uint32_t dex_pc)
447       : HVecUnaryOperation(kVecNeg, allocator, input, packed_type, vector_length, dex_pc) {
448     DCHECK(HasConsistentPackedTypes(input, packed_type));
449   }
450 
CanBeMoved()451   bool CanBeMoved() const override { return true; }
452 
453   DECLARE_INSTRUCTION(VecNeg);
454 
455  protected:
456   DEFAULT_COPY_CONSTRUCTOR(VecNeg);
457 };
458 
459 // Takes absolute value of every component in the vector,
460 // viz. abs[ x1, .. , xn ]  = [ |x1|, .. , |xn| ]
461 // for signed operand x.
462 class HVecAbs final : public HVecUnaryOperation {
463  public:
HVecAbs(ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)464   HVecAbs(ArenaAllocator* allocator,
465           HInstruction* input,
466           DataType::Type packed_type,
467           size_t vector_length,
468           uint32_t dex_pc)
469       : HVecUnaryOperation(kVecAbs, allocator, input, packed_type, vector_length, dex_pc) {
470     DCHECK(HasConsistentPackedTypes(input, packed_type));
471   }
472 
CanBeMoved()473   bool CanBeMoved() const override { return true; }
474 
475   DECLARE_INSTRUCTION(VecAbs);
476 
477  protected:
478   DEFAULT_COPY_CONSTRUCTOR(VecAbs);
479 };
480 
481 // Bitwise- or boolean-nots every component in the vector,
482 // viz. not[ x1, .. , xn ]  = [ ~x1, .. , ~xn ], or
483 //      not[ x1, .. , xn ]  = [ !x1, .. , !xn ] for boolean.
484 class HVecNot final : public HVecUnaryOperation {
485  public:
HVecNot(ArenaAllocator * allocator,HInstruction * input,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)486   HVecNot(ArenaAllocator* allocator,
487           HInstruction* input,
488           DataType::Type packed_type,
489           size_t vector_length,
490           uint32_t dex_pc)
491       : HVecUnaryOperation(kVecNot, allocator, input, packed_type, vector_length, dex_pc) {
492     DCHECK(input->IsVecOperation());
493   }
494 
CanBeMoved()495   bool CanBeMoved() const override { return true; }
496 
497   DECLARE_INSTRUCTION(VecNot);
498 
499  protected:
500   DEFAULT_COPY_CONSTRUCTOR(VecNot);
501 };
502 
503 //
504 // Definitions of concrete binary vector operations in HIR.
505 //
506 
507 // Adds every component in the two vectors,
508 // viz. [ x1, .. , xn ] + [ y1, .. , yn ] = [ x1 + y1, .. , xn + yn ].
509 class HVecAdd final : public HVecBinaryOperation {
510  public:
HVecAdd(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)511   HVecAdd(ArenaAllocator* allocator,
512           HInstruction* left,
513           HInstruction* right,
514           DataType::Type packed_type,
515           size_t vector_length,
516           uint32_t dex_pc)
517       : HVecBinaryOperation(kVecAdd, allocator, left, right, packed_type, vector_length, dex_pc) {
518     DCHECK(HasConsistentPackedTypes(left, packed_type));
519     DCHECK(HasConsistentPackedTypes(right, packed_type));
520   }
521 
CanBeMoved()522   bool CanBeMoved() const override { return true; }
523 
524   DECLARE_INSTRUCTION(VecAdd);
525 
526  protected:
527   DEFAULT_COPY_CONSTRUCTOR(VecAdd);
528 };
529 
530 // Adds every component in the two vectors using saturation arithmetic,
531 // viz. [ x1, .. , xn ] + [ y1, .. , yn ] = [ x1 +_sat y1, .. , xn +_sat yn ]
532 // for either both signed or both unsigned operands x, y (reflected in packed_type).
533 class HVecSaturationAdd final : public HVecBinaryOperation {
534  public:
HVecSaturationAdd(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)535   HVecSaturationAdd(ArenaAllocator* allocator,
536                     HInstruction* left,
537                     HInstruction* right,
538                     DataType::Type packed_type,
539                     size_t vector_length,
540                     uint32_t dex_pc)
541       : HVecBinaryOperation(
542           kVecSaturationAdd, allocator, left, right, packed_type, vector_length, dex_pc) {
543     DCHECK(HasConsistentPackedTypes(left, packed_type));
544     DCHECK(HasConsistentPackedTypes(right, packed_type));
545   }
546 
CanBeMoved()547   bool CanBeMoved() const override { return true; }
548 
549   DECLARE_INSTRUCTION(VecSaturationAdd);
550 
551  protected:
552   DEFAULT_COPY_CONSTRUCTOR(VecSaturationAdd);
553 };
554 
555 // Performs halving add on every component in the two vectors, viz.
556 // rounded   [ x1, .. , xn ] hradd [ y1, .. , yn ] = [ (x1 + y1 + 1) >> 1, .. , (xn + yn + 1) >> 1 ]
557 // truncated [ x1, .. , xn ] hadd  [ y1, .. , yn ] = [ (x1 + y1)     >> 1, .. , (xn + yn )    >> 1 ]
558 // for either both signed or both unsigned operands x, y (reflected in packed_type).
559 class HVecHalvingAdd final : public HVecBinaryOperation {
560  public:
HVecHalvingAdd(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,bool is_rounded,uint32_t dex_pc)561   HVecHalvingAdd(ArenaAllocator* allocator,
562                  HInstruction* left,
563                  HInstruction* right,
564                  DataType::Type packed_type,
565                  size_t vector_length,
566                  bool is_rounded,
567                  uint32_t dex_pc)
568       : HVecBinaryOperation(
569             kVecHalvingAdd, allocator, left, right, packed_type, vector_length, dex_pc) {
570     DCHECK(HasConsistentPackedTypes(left, packed_type));
571     DCHECK(HasConsistentPackedTypes(right, packed_type));
572     SetPackedFlag<kFieldHAddIsRounded>(is_rounded);
573   }
574 
IsRounded()575   bool IsRounded() const { return GetPackedFlag<kFieldHAddIsRounded>(); }
576 
CanBeMoved()577   bool CanBeMoved() const override { return true; }
578 
InstructionDataEquals(const HInstruction * other)579   bool InstructionDataEquals(const HInstruction* other) const override {
580     DCHECK(other->IsVecHalvingAdd());
581     const HVecHalvingAdd* o = other->AsVecHalvingAdd();
582     return HVecOperation::InstructionDataEquals(o) && IsRounded() == o->IsRounded();
583   }
584 
585   DECLARE_INSTRUCTION(VecHalvingAdd);
586 
587  protected:
588   DEFAULT_COPY_CONSTRUCTOR(VecHalvingAdd);
589 
590  private:
591   // Additional packed bits.
592   static constexpr size_t kFieldHAddIsRounded = HVecOperation::kNumberOfVectorOpPackedBits;
593   static constexpr size_t kNumberOfHAddPackedBits = kFieldHAddIsRounded + 1;
594   static_assert(kNumberOfHAddPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
595 };
596 
597 // Subtracts every component in the two vectors,
598 // viz. [ x1, .. , xn ] - [ y1, .. , yn ] = [ x1 - y1, .. , xn - yn ].
599 class HVecSub final : public HVecBinaryOperation {
600  public:
HVecSub(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)601   HVecSub(ArenaAllocator* allocator,
602           HInstruction* left,
603           HInstruction* right,
604           DataType::Type packed_type,
605           size_t vector_length,
606           uint32_t dex_pc)
607       : HVecBinaryOperation(kVecSub, allocator, left, right, packed_type, vector_length, dex_pc) {
608     DCHECK(HasConsistentPackedTypes(left, packed_type));
609     DCHECK(HasConsistentPackedTypes(right, packed_type));
610   }
611 
CanBeMoved()612   bool CanBeMoved() const override { return true; }
613 
614   DECLARE_INSTRUCTION(VecSub);
615 
616  protected:
617   DEFAULT_COPY_CONSTRUCTOR(VecSub);
618 };
619 
620 // Subtracts every component in the two vectors using saturation arithmetic,
621 // viz. [ x1, .. , xn ] + [ y1, .. , yn ] = [ x1 -_sat y1, .. , xn -_sat yn ]
622 // for either both signed or both unsigned operands x, y (reflected in packed_type).
623 class HVecSaturationSub final : public HVecBinaryOperation {
624  public:
HVecSaturationSub(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)625   HVecSaturationSub(ArenaAllocator* allocator,
626                     HInstruction* left,
627                     HInstruction* right,
628                     DataType::Type packed_type,
629                     size_t vector_length,
630                     uint32_t dex_pc)
631       : HVecBinaryOperation(
632           kVecSaturationSub, allocator, left, right, packed_type, vector_length, dex_pc) {
633     DCHECK(HasConsistentPackedTypes(left, packed_type));
634     DCHECK(HasConsistentPackedTypes(right, packed_type));
635   }
636 
CanBeMoved()637   bool CanBeMoved() const override { return true; }
638 
639   DECLARE_INSTRUCTION(VecSaturationSub);
640 
641  protected:
642   DEFAULT_COPY_CONSTRUCTOR(VecSaturationSub);
643 };
644 
645 // Multiplies every component in the two vectors,
646 // viz. [ x1, .. , xn ] * [ y1, .. , yn ] = [ x1 * y1, .. , xn * yn ].
647 class HVecMul final : public HVecBinaryOperation {
648  public:
HVecMul(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)649   HVecMul(ArenaAllocator* allocator,
650           HInstruction* left,
651           HInstruction* right,
652           DataType::Type packed_type,
653           size_t vector_length,
654           uint32_t dex_pc)
655       : HVecBinaryOperation(kVecMul, allocator, left, right, packed_type, vector_length, dex_pc) {
656     DCHECK(HasConsistentPackedTypes(left, packed_type));
657     DCHECK(HasConsistentPackedTypes(right, packed_type));
658   }
659 
CanBeMoved()660   bool CanBeMoved() const override { return true; }
661 
662   DECLARE_INSTRUCTION(VecMul);
663 
664  protected:
665   DEFAULT_COPY_CONSTRUCTOR(VecMul);
666 };
667 
668 // Divides every component in the two vectors,
669 // viz. [ x1, .. , xn ] / [ y1, .. , yn ] = [ x1 / y1, .. , xn / yn ].
670 class HVecDiv final : public HVecBinaryOperation {
671  public:
HVecDiv(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)672   HVecDiv(ArenaAllocator* allocator,
673           HInstruction* left,
674           HInstruction* right,
675           DataType::Type packed_type,
676           size_t vector_length,
677           uint32_t dex_pc)
678       : HVecBinaryOperation(kVecDiv, allocator, left, right, packed_type, vector_length, dex_pc) {
679     DCHECK(HasConsistentPackedTypes(left, packed_type));
680     DCHECK(HasConsistentPackedTypes(right, packed_type));
681   }
682 
CanBeMoved()683   bool CanBeMoved() const override { return true; }
684 
685   DECLARE_INSTRUCTION(VecDiv);
686 
687  protected:
688   DEFAULT_COPY_CONSTRUCTOR(VecDiv);
689 };
690 
691 // Takes minimum of every component in the two vectors,
692 // viz. MIN( [ x1, .. , xn ] , [ y1, .. , yn ]) = [ min(x1, y1), .. , min(xn, yn) ]
693 // for either both signed or both unsigned operands x, y (reflected in packed_type).
694 class HVecMin final : public HVecBinaryOperation {
695  public:
HVecMin(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)696   HVecMin(ArenaAllocator* allocator,
697           HInstruction* left,
698           HInstruction* right,
699           DataType::Type packed_type,
700           size_t vector_length,
701           uint32_t dex_pc)
702       : HVecBinaryOperation(kVecMin, allocator, left, right, packed_type, vector_length, dex_pc) {
703     DCHECK(HasConsistentPackedTypes(left, packed_type));
704     DCHECK(HasConsistentPackedTypes(right, packed_type));
705   }
706 
CanBeMoved()707   bool CanBeMoved() const override { return true; }
708 
709   DECLARE_INSTRUCTION(VecMin);
710 
711  protected:
712   DEFAULT_COPY_CONSTRUCTOR(VecMin);
713 };
714 
715 // Takes maximum of every component in the two vectors,
716 // viz. MAX( [ x1, .. , xn ] , [ y1, .. , yn ]) = [ max(x1, y1), .. , max(xn, yn) ]
717 // for either both signed or both unsigned operands x, y (reflected in packed_type).
718 class HVecMax final : public HVecBinaryOperation {
719  public:
HVecMax(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)720   HVecMax(ArenaAllocator* allocator,
721           HInstruction* left,
722           HInstruction* right,
723           DataType::Type packed_type,
724           size_t vector_length,
725           uint32_t dex_pc)
726       : HVecBinaryOperation(kVecMax, allocator, left, right, packed_type, vector_length, dex_pc) {
727     DCHECK(HasConsistentPackedTypes(left, packed_type));
728     DCHECK(HasConsistentPackedTypes(right, packed_type));
729   }
730 
CanBeMoved()731   bool CanBeMoved() const override { return true; }
732 
733   DECLARE_INSTRUCTION(VecMax);
734 
735  protected:
736   DEFAULT_COPY_CONSTRUCTOR(VecMax);
737 };
738 
739 // Bitwise-ands every component in the two vectors,
740 // viz. [ x1, .. , xn ] & [ y1, .. , yn ] = [ x1 & y1, .. , xn & yn ].
741 class HVecAnd final : public HVecBinaryOperation {
742  public:
HVecAnd(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)743   HVecAnd(ArenaAllocator* allocator,
744           HInstruction* left,
745           HInstruction* right,
746           DataType::Type packed_type,
747           size_t vector_length,
748           uint32_t dex_pc)
749       : HVecBinaryOperation(kVecAnd, allocator, left, right, packed_type, vector_length, dex_pc) {
750     DCHECK(left->IsVecOperation() && right->IsVecOperation());
751   }
752 
CanBeMoved()753   bool CanBeMoved() const override { return true; }
754 
755   DECLARE_INSTRUCTION(VecAnd);
756 
757  protected:
758   DEFAULT_COPY_CONSTRUCTOR(VecAnd);
759 };
760 
761 // Bitwise-and-nots every component in the two vectors,
762 // viz. [ x1, .. , xn ] and-not [ y1, .. , yn ] = [ ~x1 & y1, .. , ~xn & yn ].
763 class HVecAndNot final : public HVecBinaryOperation {
764  public:
HVecAndNot(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)765   HVecAndNot(ArenaAllocator* allocator,
766              HInstruction* left,
767              HInstruction* right,
768              DataType::Type packed_type,
769              size_t vector_length,
770              uint32_t dex_pc)
771          : HVecBinaryOperation(
772                kVecAndNot, allocator, left, right, packed_type, vector_length, dex_pc) {
773     DCHECK(left->IsVecOperation() && right->IsVecOperation());
774   }
775 
CanBeMoved()776   bool CanBeMoved() const override { return true; }
777 
778   DECLARE_INSTRUCTION(VecAndNot);
779 
780  protected:
781   DEFAULT_COPY_CONSTRUCTOR(VecAndNot);
782 };
783 
784 // Bitwise-ors every component in the two vectors,
785 // viz. [ x1, .. , xn ] | [ y1, .. , yn ] = [ x1 | y1, .. , xn | yn ].
786 class HVecOr final : public HVecBinaryOperation {
787  public:
HVecOr(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)788   HVecOr(ArenaAllocator* allocator,
789          HInstruction* left,
790          HInstruction* right,
791          DataType::Type packed_type,
792          size_t vector_length,
793          uint32_t dex_pc)
794       : HVecBinaryOperation(kVecOr, allocator, left, right, packed_type, vector_length, dex_pc) {
795     DCHECK(left->IsVecOperation() && right->IsVecOperation());
796   }
797 
CanBeMoved()798   bool CanBeMoved() const override { return true; }
799 
800   DECLARE_INSTRUCTION(VecOr);
801 
802  protected:
803   DEFAULT_COPY_CONSTRUCTOR(VecOr);
804 };
805 
806 // Bitwise-xors every component in the two vectors,
807 // viz. [ x1, .. , xn ] ^ [ y1, .. , yn ] = [ x1 ^ y1, .. , xn ^ yn ].
808 class HVecXor final : public HVecBinaryOperation {
809  public:
HVecXor(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)810   HVecXor(ArenaAllocator* allocator,
811           HInstruction* left,
812           HInstruction* right,
813           DataType::Type packed_type,
814           size_t vector_length,
815           uint32_t dex_pc)
816       : HVecBinaryOperation(kVecXor, allocator, left, right, packed_type, vector_length, dex_pc) {
817     DCHECK(left->IsVecOperation() && right->IsVecOperation());
818   }
819 
CanBeMoved()820   bool CanBeMoved() const override { return true; }
821 
822   DECLARE_INSTRUCTION(VecXor);
823 
824  protected:
825   DEFAULT_COPY_CONSTRUCTOR(VecXor);
826 };
827 
828 // Logically shifts every component in the vector left by the given distance,
829 // viz. [ x1, .. , xn ] << d = [ x1 << d, .. , xn << d ].
830 class HVecShl final : public HVecBinaryOperation {
831  public:
HVecShl(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)832   HVecShl(ArenaAllocator* allocator,
833           HInstruction* left,
834           HInstruction* right,
835           DataType::Type packed_type,
836           size_t vector_length,
837           uint32_t dex_pc)
838       : HVecBinaryOperation(kVecShl, allocator, left, right, packed_type, vector_length, dex_pc) {
839     DCHECK(HasConsistentPackedTypes(left, packed_type));
840   }
841 
CanBeMoved()842   bool CanBeMoved() const override { return true; }
843 
844   DECLARE_INSTRUCTION(VecShl);
845 
846  protected:
847   DEFAULT_COPY_CONSTRUCTOR(VecShl);
848 };
849 
850 // Arithmetically shifts every component in the vector right by the given distance,
851 // viz. [ x1, .. , xn ] >> d = [ x1 >> d, .. , xn >> d ].
852 class HVecShr final : public HVecBinaryOperation {
853  public:
HVecShr(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)854   HVecShr(ArenaAllocator* allocator,
855           HInstruction* left,
856           HInstruction* right,
857           DataType::Type packed_type,
858           size_t vector_length,
859           uint32_t dex_pc)
860       : HVecBinaryOperation(kVecShr, allocator, left, right, packed_type, vector_length, dex_pc) {
861     DCHECK(HasConsistentPackedTypes(left, packed_type));
862   }
863 
CanBeMoved()864   bool CanBeMoved() const override { return true; }
865 
866   DECLARE_INSTRUCTION(VecShr);
867 
868  protected:
869   DEFAULT_COPY_CONSTRUCTOR(VecShr);
870 };
871 
872 // Logically shifts every component in the vector right by the given distance,
873 // viz. [ x1, .. , xn ] >>> d = [ x1 >>> d, .. , xn >>> d ].
874 class HVecUShr final : public HVecBinaryOperation {
875  public:
HVecUShr(ArenaAllocator * allocator,HInstruction * left,HInstruction * right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)876   HVecUShr(ArenaAllocator* allocator,
877            HInstruction* left,
878            HInstruction* right,
879            DataType::Type packed_type,
880            size_t vector_length,
881            uint32_t dex_pc)
882       : HVecBinaryOperation(kVecUShr, allocator, left, right, packed_type, vector_length, dex_pc) {
883     DCHECK(HasConsistentPackedTypes(left, packed_type));
884   }
885 
CanBeMoved()886   bool CanBeMoved() const override { return true; }
887 
888   DECLARE_INSTRUCTION(VecUShr);
889 
890  protected:
891   DEFAULT_COPY_CONSTRUCTOR(VecUShr);
892 };
893 
894 //
895 // Definitions of concrete miscellaneous vector operations in HIR.
896 //
897 
898 // Assigns the given scalar elements to a vector,
899 // viz. set( array(x1, .. , xn) ) = [ x1, .. ,            xn ] if n == m,
900 //      set( array(x1, .. , xm) ) = [ x1, .. , xm, 0, .. , 0 ] if m <  n.
901 class HVecSetScalars final : public HVecOperation {
902  public:
HVecSetScalars(ArenaAllocator * allocator,HInstruction * scalars[],DataType::Type packed_type,size_t vector_length,size_t number_of_scalars,uint32_t dex_pc)903   HVecSetScalars(ArenaAllocator* allocator,
904                  HInstruction* scalars[],
905                  DataType::Type packed_type,
906                  size_t vector_length,
907                  size_t number_of_scalars,
908                  uint32_t dex_pc)
909       : HVecOperation(kVecSetScalars,
910                       allocator,
911                       packed_type,
912                       SideEffects::None(),
913                       number_of_scalars,
914                       vector_length,
915                       dex_pc) {
916     for (size_t i = 0; i < number_of_scalars; i++) {
917       DCHECK(!ReturnsSIMDValue(scalars[i]));
918       SetRawInputAt(0, scalars[i]);
919     }
920   }
921 
922   // Setting scalars needs to stay in place, since SIMD registers are not
923   // kept alive across vector loop boundaries (yet).
CanBeMoved()924   bool CanBeMoved() const override { return false; }
925 
926   DECLARE_INSTRUCTION(VecSetScalars);
927 
928  protected:
929   DEFAULT_COPY_CONSTRUCTOR(VecSetScalars);
930 };
931 
932 // Multiplies every component in the two vectors, adds the result vector to the accumulator vector,
933 // viz. [ a1, .. , an ] + [ x1, .. , xn ] * [ y1, .. , yn ] = [ a1 + x1 * y1, .. , an + xn * yn ].
934 // For floating point types, Java rounding behavior must be preserved; the products are rounded to
935 // the proper precision before being added. "Fused" multiply-add operations available on several
936 // architectures are not usable since they would violate Java language rules.
937 class HVecMultiplyAccumulate final : public HVecOperation {
938  public:
HVecMultiplyAccumulate(ArenaAllocator * allocator,InstructionKind op,HInstruction * accumulator,HInstruction * mul_left,HInstruction * mul_right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)939   HVecMultiplyAccumulate(ArenaAllocator* allocator,
940                          InstructionKind op,
941                          HInstruction* accumulator,
942                          HInstruction* mul_left,
943                          HInstruction* mul_right,
944                          DataType::Type packed_type,
945                          size_t vector_length,
946                          uint32_t dex_pc)
947       : HVecOperation(kVecMultiplyAccumulate,
948                       allocator,
949                       packed_type,
950                       SideEffects::None(),
951                       /* number_of_inputs= */ 3,
952                       vector_length,
953                       dex_pc),
954         op_kind_(op) {
955     DCHECK(op == InstructionKind::kAdd || op == InstructionKind::kSub);
956     DCHECK(HasConsistentPackedTypes(accumulator, packed_type));
957     DCHECK(HasConsistentPackedTypes(mul_left, packed_type));
958     DCHECK(HasConsistentPackedTypes(mul_right, packed_type));
959     // Remove the following if we add an architecture that supports floating point multiply-add
960     // with Java-compatible rounding.
961     DCHECK(DataType::IsIntegralType(packed_type));
962     SetRawInputAt(0, accumulator);
963     SetRawInputAt(1, mul_left);
964     SetRawInputAt(2, mul_right);
965   }
966 
CanBeMoved()967   bool CanBeMoved() const override { return true; }
968 
InstructionDataEquals(const HInstruction * other)969   bool InstructionDataEquals(const HInstruction* other) const override {
970     DCHECK(other->IsVecMultiplyAccumulate());
971     const HVecMultiplyAccumulate* o = other->AsVecMultiplyAccumulate();
972     return HVecOperation::InstructionDataEquals(o) && GetOpKind() == o->GetOpKind();
973   }
974 
GetOpKind()975   InstructionKind GetOpKind() const { return op_kind_; }
976 
977   DECLARE_INSTRUCTION(VecMultiplyAccumulate);
978 
979  protected:
980   DEFAULT_COPY_CONSTRUCTOR(VecMultiplyAccumulate);
981 
982  private:
983   // Indicates if this is a MADD or MSUB.
984   const InstructionKind op_kind_;
985 };
986 
987 // Takes the absolute difference of two vectors, and adds the results to
988 // same-precision or wider-precision components in the accumulator,
989 // viz. SAD([ a1, .. , am ], [ x1, .. , xn ], [ y1, .. , yn ]) =
990 //          [ a1 + sum abs(xi-yi), .. , am + sum abs(xj-yj) ],
991 //      for m <= n, non-overlapping sums, and signed operands x, y.
992 class HVecSADAccumulate final : public HVecOperation {
993  public:
HVecSADAccumulate(ArenaAllocator * allocator,HInstruction * accumulator,HInstruction * sad_left,HInstruction * sad_right,DataType::Type packed_type,size_t vector_length,uint32_t dex_pc)994   HVecSADAccumulate(ArenaAllocator* allocator,
995                     HInstruction* accumulator,
996                     HInstruction* sad_left,
997                     HInstruction* sad_right,
998                     DataType::Type packed_type,
999                     size_t vector_length,
1000                     uint32_t dex_pc)
1001       : HVecOperation(kVecSADAccumulate,
1002                       allocator,
1003                       packed_type,
1004                       SideEffects::None(),
1005                       /* number_of_inputs= */ 3,
1006                       vector_length,
1007                       dex_pc) {
1008     DCHECK(HasConsistentPackedTypes(accumulator, packed_type));
1009     DCHECK(sad_left->IsVecOperation());
1010     DCHECK(sad_right->IsVecOperation());
1011     DCHECK_EQ(ToSignedType(sad_left->AsVecOperation()->GetPackedType()),
1012               ToSignedType(sad_right->AsVecOperation()->GetPackedType()));
1013     SetRawInputAt(0, accumulator);
1014     SetRawInputAt(1, sad_left);
1015     SetRawInputAt(2, sad_right);
1016   }
1017 
1018   DECLARE_INSTRUCTION(VecSADAccumulate);
1019 
1020  protected:
1021   DEFAULT_COPY_CONSTRUCTOR(VecSADAccumulate);
1022 };
1023 
1024 // Performs dot product of two vectors and adds the result to wider precision components in
1025 // the accumulator.
1026 //
1027 // viz. DOT_PRODUCT([ a1, .. , am], [ x1, .. , xn ], [ y1, .. , yn ]) =
1028 //                  [ a1 + sum(xi * yi), .. , am + sum(xj * yj) ],
1029 //      for m <= n, non-overlapping sums,
1030 //      for either both signed or both unsigned operands x, y.
1031 //
1032 // Notes:
1033 //   - packed type reflects the type of sum reduction, not the type of the operands.
1034 //   - IsZeroExtending() is used to determine the kind of signed/zero extension to be
1035 //     performed for the operands.
1036 //
1037 // TODO: Support types other than kInt32 for packed type.
1038 class HVecDotProd final : public HVecOperation {
1039  public:
HVecDotProd(ArenaAllocator * allocator,HInstruction * accumulator,HInstruction * left,HInstruction * right,DataType::Type packed_type,bool is_zero_extending,size_t vector_length,uint32_t dex_pc)1040   HVecDotProd(ArenaAllocator* allocator,
1041               HInstruction* accumulator,
1042               HInstruction* left,
1043               HInstruction* right,
1044               DataType::Type packed_type,
1045               bool is_zero_extending,
1046               size_t vector_length,
1047               uint32_t dex_pc)
1048     : HVecOperation(kVecDotProd,
1049                     allocator,
1050                     packed_type,
1051                     SideEffects::None(),
1052                     /* number_of_inputs= */ 3,
1053                     vector_length,
1054                     dex_pc) {
1055     DCHECK(HasConsistentPackedTypes(accumulator, packed_type));
1056     DCHECK(DataType::IsIntegralType(packed_type));
1057     DCHECK(left->IsVecOperation());
1058     DCHECK(right->IsVecOperation());
1059     DCHECK_EQ(ToSignedType(left->AsVecOperation()->GetPackedType()),
1060               ToSignedType(right->AsVecOperation()->GetPackedType()));
1061     SetRawInputAt(0, accumulator);
1062     SetRawInputAt(1, left);
1063     SetRawInputAt(2, right);
1064     SetPackedFlag<kFieldHDotProdIsZeroExtending>(is_zero_extending);
1065   }
1066 
IsZeroExtending()1067   bool IsZeroExtending() const { return GetPackedFlag<kFieldHDotProdIsZeroExtending>(); }
1068 
CanBeMoved()1069   bool CanBeMoved() const override { return true; }
1070 
1071   DECLARE_INSTRUCTION(VecDotProd);
1072 
1073  protected:
1074   DEFAULT_COPY_CONSTRUCTOR(VecDotProd);
1075 
1076  private:
1077   // Additional packed bits.
1078   static constexpr size_t kFieldHDotProdIsZeroExtending =
1079       HVecOperation::kNumberOfVectorOpPackedBits;
1080   static constexpr size_t kNumberOfHDotProdPackedBits = kFieldHDotProdIsZeroExtending + 1;
1081   static_assert(kNumberOfHDotProdPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
1082 };
1083 
1084 // Loads a vector from memory, viz. load(mem, 1)
1085 // yield the vector [ mem(1), .. , mem(n) ].
1086 class HVecLoad final : public HVecMemoryOperation {
1087  public:
HVecLoad(ArenaAllocator * allocator,HInstruction * base,HInstruction * index,DataType::Type packed_type,SideEffects side_effects,size_t vector_length,bool is_string_char_at,uint32_t dex_pc)1088   HVecLoad(ArenaAllocator* allocator,
1089            HInstruction* base,
1090            HInstruction* index,
1091            DataType::Type packed_type,
1092            SideEffects side_effects,
1093            size_t vector_length,
1094            bool is_string_char_at,
1095            uint32_t dex_pc)
1096       : HVecMemoryOperation(kVecLoad,
1097                             allocator,
1098                             packed_type,
1099                             side_effects,
1100                             /* number_of_inputs= */ 2,
1101                             vector_length,
1102                             dex_pc) {
1103     SetRawInputAt(0, base);
1104     SetRawInputAt(1, index);
1105     SetPackedFlag<kFieldIsStringCharAt>(is_string_char_at);
1106   }
1107 
IsStringCharAt()1108   bool IsStringCharAt() const { return GetPackedFlag<kFieldIsStringCharAt>(); }
1109 
CanBeMoved()1110   bool CanBeMoved() const override { return true; }
1111 
InstructionDataEquals(const HInstruction * other)1112   bool InstructionDataEquals(const HInstruction* other) const override {
1113     DCHECK(other->IsVecLoad());
1114     const HVecLoad* o = other->AsVecLoad();
1115     return HVecMemoryOperation::InstructionDataEquals(o) && IsStringCharAt() == o->IsStringCharAt();
1116   }
1117 
1118   DECLARE_INSTRUCTION(VecLoad);
1119 
1120  protected:
1121   DEFAULT_COPY_CONSTRUCTOR(VecLoad);
1122 
1123  private:
1124   // Additional packed bits.
1125   static constexpr size_t kFieldIsStringCharAt = HVecOperation::kNumberOfVectorOpPackedBits;
1126   static constexpr size_t kNumberOfVecLoadPackedBits = kFieldIsStringCharAt + 1;
1127   static_assert(kNumberOfVecLoadPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
1128 };
1129 
1130 // Stores a vector to memory, viz. store(m, 1, [x1, .. , xn] )
1131 // sets mem(1) = x1, .. , mem(n) = xn.
1132 class HVecStore final : public HVecMemoryOperation {
1133  public:
HVecStore(ArenaAllocator * allocator,HInstruction * base,HInstruction * index,HInstruction * value,DataType::Type packed_type,SideEffects side_effects,size_t vector_length,uint32_t dex_pc)1134   HVecStore(ArenaAllocator* allocator,
1135             HInstruction* base,
1136             HInstruction* index,
1137             HInstruction* value,
1138             DataType::Type packed_type,
1139             SideEffects side_effects,
1140             size_t vector_length,
1141             uint32_t dex_pc)
1142       : HVecMemoryOperation(kVecStore,
1143                             allocator,
1144                             packed_type,
1145                             side_effects,
1146                             /* number_of_inputs= */ 3,
1147                             vector_length,
1148                             dex_pc) {
1149     DCHECK(HasConsistentPackedTypes(value, packed_type));
1150     SetRawInputAt(0, base);
1151     SetRawInputAt(1, index);
1152     SetRawInputAt(2, value);
1153   }
1154 
1155   // A store needs to stay in place.
CanBeMoved()1156   bool CanBeMoved() const override { return false; }
1157 
GetValue()1158   HInstruction* GetValue() const { return InputAt(2); }
1159 
1160   DECLARE_INSTRUCTION(VecStore);
1161 
1162  protected:
1163   DEFAULT_COPY_CONSTRUCTOR(VecStore)
1164 };
1165 
1166 }  // namespace art
1167 
1168 #endif  // ART_COMPILER_OPTIMIZING_NODES_VECTOR_H_
1169