/* * Copyright (C) 2016 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_UTILS_ARM_ASSEMBLER_ARM_VIXL_H_ #define ART_COMPILER_UTILS_ARM_ASSEMBLER_ARM_VIXL_H_ #include #include "base/arena_containers.h" #include "base/macros.h" #include "constants_arm.h" #include "dwarf/register.h" #include "offsets.h" #include "utils/arm/assembler_arm_shared.h" #include "utils/arm/managed_register_arm.h" #include "utils/assembler.h" #include "utils/jni_macro_assembler.h" // TODO(VIXL): Make VIXL compile with -Wshadow and remove pragmas. #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wshadow" #include "aarch32/macro-assembler-aarch32.h" #pragma GCC diagnostic pop namespace vixl32 = vixl::aarch32; namespace art { namespace arm { inline dwarf::Reg DWARFReg(vixl32::Register reg) { return dwarf::Reg::ArmCore(static_cast(reg.GetCode())); } inline dwarf::Reg DWARFReg(vixl32::SRegister reg) { return dwarf::Reg::ArmFp(static_cast(reg.GetCode())); } class ArmVIXLMacroAssembler final : public vixl32::MacroAssembler { public: // Most methods fit in a 1KB code buffer, which results in more optimal alloc/realloc and // fewer system calls than a larger default capacity. static constexpr size_t kDefaultCodeBufferCapacity = 1 * KB; ArmVIXLMacroAssembler() : vixl32::MacroAssembler(ArmVIXLMacroAssembler::kDefaultCodeBufferCapacity) {} // The following interfaces can generate CMP+Bcc or Cbz/Cbnz. // CMP+Bcc are generated by default. // If a hint is given (is_far_target = false) and rn and label can all fit into Cbz/Cbnz, // then Cbz/Cbnz is generated. // Prefer following interfaces to using vixl32::MacroAssembler::Cbz/Cbnz. // In T32, Cbz/Cbnz instructions have following limitations: // - Far targets, which are over 126 bytes away, are not supported. // - Only low registers can be encoded. // - Backward branches are not supported. void CompareAndBranchIfZero(vixl32::Register rn, vixl32::Label* label, bool is_far_target = true); void CompareAndBranchIfNonZero(vixl32::Register rn, vixl32::Label* label, bool is_far_target = true); // In T32 some of the instructions (add, mov, etc) outside an IT block // have only 32-bit encodings. But there are 16-bit flag setting // versions of these instructions (adds, movs, etc). In most of the // cases in ART we don't care if the instructions keep flags or not; // thus we can benefit from smaller code size. // VIXL will never generate flag setting versions (for example, adds // for Add macro instruction) unless vixl32::DontCare option is // explicitly specified. That's why we introduce wrappers to use // DontCare option by default. #define WITH_FLAGS_DONT_CARE_RD_RN_OP(func_name) \ void (func_name)(vixl32::Register rd, vixl32::Register rn, const vixl32::Operand& operand) { \ MacroAssembler::func_name(vixl32::DontCare, rd, rn, operand); \ } \ using MacroAssembler::func_name WITH_FLAGS_DONT_CARE_RD_RN_OP(Adc); WITH_FLAGS_DONT_CARE_RD_RN_OP(Sub); WITH_FLAGS_DONT_CARE_RD_RN_OP(Sbc); WITH_FLAGS_DONT_CARE_RD_RN_OP(Rsb); WITH_FLAGS_DONT_CARE_RD_RN_OP(Rsc); WITH_FLAGS_DONT_CARE_RD_RN_OP(Eor); WITH_FLAGS_DONT_CARE_RD_RN_OP(Orr); WITH_FLAGS_DONT_CARE_RD_RN_OP(Orn); WITH_FLAGS_DONT_CARE_RD_RN_OP(And); WITH_FLAGS_DONT_CARE_RD_RN_OP(Bic); WITH_FLAGS_DONT_CARE_RD_RN_OP(Asr); WITH_FLAGS_DONT_CARE_RD_RN_OP(Lsr); WITH_FLAGS_DONT_CARE_RD_RN_OP(Lsl); WITH_FLAGS_DONT_CARE_RD_RN_OP(Ror); #undef WITH_FLAGS_DONT_CARE_RD_RN_OP #define WITH_FLAGS_DONT_CARE_RD_OP(func_name) \ void (func_name)(vixl32::Register rd, const vixl32::Operand& operand) { \ MacroAssembler::func_name(vixl32::DontCare, rd, operand); \ } \ using MacroAssembler::func_name WITH_FLAGS_DONT_CARE_RD_OP(Mvn); WITH_FLAGS_DONT_CARE_RD_OP(Mov); #undef WITH_FLAGS_DONT_CARE_RD_OP // The following two functions don't fall into above categories. Overload them separately. void Rrx(vixl32::Register rd, vixl32::Register rn) { MacroAssembler::Rrx(vixl32::DontCare, rd, rn); } using MacroAssembler::Rrx; void Mul(vixl32::Register rd, vixl32::Register rn, vixl32::Register rm) { MacroAssembler::Mul(vixl32::DontCare, rd, rn, rm); } using MacroAssembler::Mul; // TODO: Remove when MacroAssembler::Add(FlagsUpdate, Condition, Register, Register, Operand) // makes the right decision about 16-bit encodings. void Add(vixl32::Register rd, vixl32::Register rn, const vixl32::Operand& operand) { if (rd.Is(rn) && operand.IsPlainRegister()) { MacroAssembler::Add(rd, rn, operand); } else { MacroAssembler::Add(vixl32::DontCare, rd, rn, operand); } } using MacroAssembler::Add; // These interfaces try to use 16-bit T2 encoding of B instruction. void B(vixl32::Label* label); // For B(label), we always try to use Narrow encoding, because 16-bit T2 encoding supports // jumping within 2KB range. For B(cond, label), because the supported branch range is 256 // bytes; we use the far_target hint to try to use 16-bit T1 encoding for short range jumps. void B(vixl32::Condition cond, vixl32::Label* label, bool is_far_target = true); // Use literal for generating double constant if it doesn't fit VMOV encoding. void Vmov(vixl32::DRegister rd, double imm) { if (vixl::VFP::IsImmFP64(imm)) { MacroAssembler::Vmov(rd, imm); } else { MacroAssembler::Vldr(rd, imm); } } using MacroAssembler::Vmov; }; class ArmVIXLAssembler final : public Assembler { private: class ArmException; public: explicit ArmVIXLAssembler(ArenaAllocator* allocator) : Assembler(allocator) { // Use Thumb2 instruction set. vixl_masm_.UseT32(); } virtual ~ArmVIXLAssembler() {} ArmVIXLMacroAssembler* GetVIXLAssembler() { return &vixl_masm_; } void FinalizeCode() override; // Size of generated code. size_t CodeSize() const override; const uint8_t* CodeBufferBaseAddress() const override; // Copy instructions out of assembly buffer into the given region of memory. void FinalizeInstructions(const MemoryRegion& region) override; void Bind(Label* label ATTRIBUTE_UNUSED) override { UNIMPLEMENTED(FATAL) << "Do not use Bind for ARM"; } void Jump(Label* label ATTRIBUTE_UNUSED) override { UNIMPLEMENTED(FATAL) << "Do not use Jump for ARM"; } // // Heap poisoning. // // Poison a heap reference contained in `reg`. void PoisonHeapReference(vixl32::Register reg); // Unpoison a heap reference contained in `reg`. void UnpoisonHeapReference(vixl32::Register reg); // Poison a heap reference contained in `reg` if heap poisoning is enabled. void MaybePoisonHeapReference(vixl32::Register reg); // Unpoison a heap reference contained in `reg` if heap poisoning is enabled. void MaybeUnpoisonHeapReference(vixl32::Register reg); // Emit code checking the status of the Marking Register, and aborting // the program if MR does not match the value stored in the art::Thread // object. // // Argument `temp` is used as a temporary register to generate code. // Argument `code` is used to identify the different occurrences of // MaybeGenerateMarkingRegisterCheck and is passed to the BKPT instruction. void GenerateMarkingRegisterCheck(vixl32::Register temp, int code = 0); void StoreToOffset(StoreOperandType type, vixl32::Register reg, vixl32::Register base, int32_t offset); void StoreSToOffset(vixl32::SRegister source, vixl32::Register base, int32_t offset); void StoreDToOffset(vixl32::DRegister source, vixl32::Register base, int32_t offset); void LoadImmediate(vixl32::Register dest, int32_t value); void LoadFromOffset(LoadOperandType type, vixl32::Register reg, vixl32::Register base, int32_t offset); void LoadSFromOffset(vixl32::SRegister reg, vixl32::Register base, int32_t offset); void LoadDFromOffset(vixl32::DRegister reg, vixl32::Register base, int32_t offset); void LoadRegisterList(RegList regs, size_t stack_offset); void StoreRegisterList(RegList regs, size_t stack_offset); bool ShifterOperandCanAlwaysHold(uint32_t immediate); bool ShifterOperandCanHold(Opcode opcode, uint32_t immediate, vixl::aarch32::FlagsUpdate update_flags = vixl::aarch32::DontCare); bool CanSplitLoadStoreOffset(int32_t allowed_offset_bits, int32_t offset, /*out*/ int32_t* add_to_base, /*out*/ int32_t* offset_for_load_store); int32_t AdjustLoadStoreOffset(int32_t allowed_offset_bits, vixl32::Register temp, vixl32::Register base, int32_t offset); int32_t GetAllowedLoadOffsetBits(LoadOperandType type); int32_t GetAllowedStoreOffsetBits(StoreOperandType type); void AddConstant(vixl32::Register rd, int32_t value); void AddConstant(vixl32::Register rd, vixl32::Register rn, int32_t value); void AddConstantInIt(vixl32::Register rd, vixl32::Register rn, int32_t value, vixl32::Condition cond = vixl32::al); template vixl::aarch32::Literal* CreateLiteralDestroyedWithPool(T value) { vixl::aarch32::Literal* literal = new vixl::aarch32::Literal(value, vixl32::RawLiteral::kPlacedWhenUsed, vixl32::RawLiteral::kDeletedOnPoolDestruction); return literal; } private: // VIXL assembler. ArmVIXLMacroAssembler vixl_masm_; }; // Thread register declaration. extern const vixl32::Register tr; // Marking register declaration. extern const vixl32::Register mr; } // namespace arm } // namespace art #endif // ART_COMPILER_UTILS_ARM_ASSEMBLER_ARM_VIXL_H_