/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ART_COMPILER_OPTIMIZING_NODES_SHARED_H_ #define ART_COMPILER_OPTIMIZING_NODES_SHARED_H_ // This `#include` should never be used by compilation, as this file (`nodes_shared.h`) is included // in `nodes.h`. However it helps editing tools (e.g. YouCompleteMe) by giving them better context // (defining `HInstruction` and co). #include "nodes.h" namespace art { class HMultiplyAccumulate final : public HExpression<3> { public: HMultiplyAccumulate(DataType::Type type, InstructionKind op, HInstruction* accumulator, HInstruction* mul_left, HInstruction* mul_right, uint32_t dex_pc = kNoDexPc) : HExpression(kMultiplyAccumulate, type, SideEffects::None(), dex_pc), op_kind_(op) { SetRawInputAt(kInputAccumulatorIndex, accumulator); SetRawInputAt(kInputMulLeftIndex, mul_left); SetRawInputAt(kInputMulRightIndex, mul_right); } bool IsClonable() const override { return true; } static constexpr int kInputAccumulatorIndex = 0; static constexpr int kInputMulLeftIndex = 1; static constexpr int kInputMulRightIndex = 2; bool CanBeMoved() const override { return true; } bool InstructionDataEquals(const HInstruction* other) const override { return op_kind_ == other->AsMultiplyAccumulate()->op_kind_; } InstructionKind GetOpKind() const { return op_kind_; } DECLARE_INSTRUCTION(MultiplyAccumulate); protected: DEFAULT_COPY_CONSTRUCTOR(MultiplyAccumulate); private: // Indicates if this is a MADD or MSUB. const InstructionKind op_kind_; }; class HBitwiseNegatedRight final : public HBinaryOperation { public: HBitwiseNegatedRight(DataType::Type result_type, InstructionKind op, HInstruction* left, HInstruction* right, uint32_t dex_pc = kNoDexPc) : HBinaryOperation(kBitwiseNegatedRight, result_type, left, right, SideEffects::None(), dex_pc), op_kind_(op) { DCHECK(op == HInstruction::kAnd || op == HInstruction::kOr || op == HInstruction::kXor) << op; } template auto Compute(T x, U y) const -> decltype(x & ~y) { static_assert(std::is_same::value && std::is_same::value, "Inconsistent negated bitwise types"); switch (op_kind_) { case HInstruction::kAnd: return x & ~y; case HInstruction::kOr: return x | ~y; case HInstruction::kXor: return x ^ ~y; default: LOG(FATAL) << "Unreachable"; UNREACHABLE(); } } HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const override { return GetBlock()->GetGraph()->GetIntConstant( Compute(x->GetValue(), y->GetValue()), GetDexPc()); } HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const override { return GetBlock()->GetGraph()->GetLongConstant( Compute(x->GetValue(), y->GetValue()), GetDexPc()); } HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED, HFloatConstant* y ATTRIBUTE_UNUSED) const override { LOG(FATAL) << DebugName() << " is not defined for float values"; UNREACHABLE(); } HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED, HDoubleConstant* y ATTRIBUTE_UNUSED) const override { LOG(FATAL) << DebugName() << " is not defined for double values"; UNREACHABLE(); } InstructionKind GetOpKind() const { return op_kind_; } DECLARE_INSTRUCTION(BitwiseNegatedRight); protected: DEFAULT_COPY_CONSTRUCTOR(BitwiseNegatedRight); private: // Specifies the bitwise operation, which will be then negated. const InstructionKind op_kind_; }; // This instruction computes part of the array access offset (data and index offset). // // For array accesses the element address has the following structure: // Address = CONST_OFFSET + base_addr + index << ELEM_SHIFT. Taking into account LDR/STR addressing // modes address part (CONST_OFFSET + index << ELEM_SHIFT) can be shared across array access with // the same data type and index. For example, for the following loop 5 accesses can share address // computation: // // void foo(int[] a, int[] b, int[] c) { // for (i...) { // a[i] = a[i] + 5; // b[i] = b[i] + c[i]; // } // } // // Note: as the instruction doesn't involve base array address into computations it has no side // effects (in comparison of HIntermediateAddress). class HIntermediateAddressIndex final : public HExpression<3> { public: HIntermediateAddressIndex( HInstruction* index, HInstruction* offset, HInstruction* shift, uint32_t dex_pc) : HExpression(kIntermediateAddressIndex, DataType::Type::kInt32, SideEffects::None(), dex_pc) { SetRawInputAt(0, index); SetRawInputAt(1, offset); SetRawInputAt(2, shift); } bool IsClonable() const override { return true; } bool CanBeMoved() const override { return true; } bool InstructionDataEquals(const HInstruction* other ATTRIBUTE_UNUSED) const override { return true; } bool IsActualObject() const override { return false; } HInstruction* GetIndex() const { return InputAt(0); } HInstruction* GetOffset() const { return InputAt(1); } HInstruction* GetShift() const { return InputAt(2); } DECLARE_INSTRUCTION(IntermediateAddressIndex); protected: DEFAULT_COPY_CONSTRUCTOR(IntermediateAddressIndex); }; class HDataProcWithShifterOp final : public HExpression<2> { public: enum OpKind { kLSL, // Logical shift left. kLSR, // Logical shift right. kASR, // Arithmetic shift right. kUXTB, // Unsigned extend byte. kUXTH, // Unsigned extend half-word. kUXTW, // Unsigned extend word. kSXTB, // Signed extend byte. kSXTH, // Signed extend half-word. kSXTW, // Signed extend word. // Aliases. kFirstShiftOp = kLSL, kLastShiftOp = kASR, kFirstExtensionOp = kUXTB, kLastExtensionOp = kSXTW }; HDataProcWithShifterOp(HInstruction* instr, HInstruction* left, HInstruction* right, OpKind op, // The shift argument is unused if the operation // is an extension. int shift = 0, uint32_t dex_pc = kNoDexPc) : HExpression(kDataProcWithShifterOp, instr->GetType(), SideEffects::None(), dex_pc), instr_kind_(instr->GetKind()), op_kind_(op), shift_amount_(shift & (instr->GetType() == DataType::Type::kInt32 ? kMaxIntShiftDistance : kMaxLongShiftDistance)) { DCHECK(!instr->HasSideEffects()); SetRawInputAt(0, left); SetRawInputAt(1, right); } bool IsClonable() const override { return true; } bool CanBeMoved() const override { return true; } bool InstructionDataEquals(const HInstruction* other_instr) const override { const HDataProcWithShifterOp* other = other_instr->AsDataProcWithShifterOp(); return instr_kind_ == other->instr_kind_ && op_kind_ == other->op_kind_ && shift_amount_ == other->shift_amount_; } static bool IsShiftOp(OpKind op_kind) { return kFirstShiftOp <= op_kind && op_kind <= kLastShiftOp; } static bool IsExtensionOp(OpKind op_kind) { return kFirstExtensionOp <= op_kind && op_kind <= kLastExtensionOp; } // Find the operation kind and shift amount from a bitfield move instruction. static void GetOpInfoFromInstruction(HInstruction* bitfield_op, /*out*/OpKind* op_kind, /*out*/int* shift_amount); InstructionKind GetInstrKind() const { return instr_kind_; } OpKind GetOpKind() const { return op_kind_; } int GetShiftAmount() const { return shift_amount_; } DECLARE_INSTRUCTION(DataProcWithShifterOp); protected: DEFAULT_COPY_CONSTRUCTOR(DataProcWithShifterOp); private: InstructionKind instr_kind_; OpKind op_kind_; int shift_amount_; friend std::ostream& operator<<(std::ostream& os, OpKind op); }; std::ostream& operator<<(std::ostream& os, const HDataProcWithShifterOp::OpKind op); } // namespace art #endif // ART_COMPILER_OPTIMIZING_NODES_SHARED_H_