/* * Copyright (C) 2011 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_H_ #define ART_COMPILER_UTILS_ARM_ASSEMBLER_ARM_H_ #include #include "base/logging.h" #include "constants_arm.h" #include "utils/arm/managed_register_arm.h" #include "utils/assembler.h" #include "offsets.h" #include "utils.h" namespace art { namespace arm { class ShifterOperand { public: ShifterOperand() : type_(kUnknown), rm_(kNoRegister), rs_(kNoRegister), is_rotate_(false), is_shift_(false), shift_(kNoShift), rotate_(0), immed_(0) { } explicit ShifterOperand(uint32_t immed); // Data-processing operands - Register explicit ShifterOperand(Register rm) : type_(kRegister), rm_(rm), rs_(kNoRegister), is_rotate_(false), is_shift_(false), shift_(kNoShift), rotate_(0), immed_(0) { } ShifterOperand(uint32_t rotate, uint32_t immed8) : type_(kImmediate), rm_(kNoRegister), rs_(kNoRegister), is_rotate_(true), is_shift_(false), shift_(kNoShift), rotate_(rotate), immed_(immed8) { } ShifterOperand(Register rm, Shift shift, uint32_t shift_imm = 0) : type_(kRegister), rm_(rm), rs_(kNoRegister), is_rotate_(false), is_shift_(true), shift_(shift), rotate_(0), immed_(shift_imm) { } // Data-processing operands - Logical shift/rotate by register ShifterOperand(Register rm, Shift shift, Register rs) : type_(kRegister), rm_(rm), rs_(rs), is_rotate_(false), is_shift_(true), shift_(shift), rotate_(0), immed_(0) { } bool is_valid() const { return (type_ == kImmediate) || (type_ == kRegister); } uint32_t type() const { CHECK(is_valid()); return type_; } uint32_t encodingArm() const; uint32_t encodingThumb() const; bool IsEmpty() const { return type_ == kUnknown; } bool IsImmediate() const { return type_ == kImmediate; } bool IsRegister() const { return type_ == kRegister; } bool IsShift() const { return is_shift_; } uint32_t GetImmediate() const { return immed_; } Shift GetShift() const { return shift_; } Register GetRegister() const { return rm_; } enum Type { kUnknown = -1, kRegister, kImmediate }; static bool CanHoldArm(uint32_t immediate, ShifterOperand* shifter_op) { // Avoid the more expensive test for frequent small immediate values. if (immediate < (1 << kImmed8Bits)) { shifter_op->type_ = kImmediate; shifter_op->is_rotate_ = true; shifter_op->rotate_ = 0; shifter_op->immed_ = immediate; return true; } // Note that immediate must be unsigned for the test to work correctly. for (int rot = 0; rot < 16; rot++) { uint32_t imm8 = (immediate << 2*rot) | (immediate >> (32 - 2*rot)); if (imm8 < (1 << kImmed8Bits)) { shifter_op->type_ = kImmediate; shifter_op->is_rotate_ = true; shifter_op->rotate_ = rot; shifter_op->immed_ = imm8; return true; } } return false; } static bool CanHoldThumb(Register rd, Register rn, Opcode opcode, uint32_t immediate, ShifterOperand* shifter_op); private: Type type_; Register rm_; Register rs_; bool is_rotate_; bool is_shift_; Shift shift_; uint32_t rotate_; uint32_t immed_; #ifdef SOURCE_ASSEMBLER_SUPPORT friend class BinaryAssembler; #endif }; enum LoadOperandType { kLoadSignedByte, kLoadUnsignedByte, kLoadSignedHalfword, kLoadUnsignedHalfword, kLoadWord, kLoadWordPair, kLoadSWord, kLoadDWord }; enum StoreOperandType { kStoreByte, kStoreHalfword, kStoreWord, kStoreWordPair, kStoreSWord, kStoreDWord }; // Load/store multiple addressing mode. enum BlockAddressMode { // bit encoding P U W DA = (0|0|0) << 21, // decrement after IA = (0|4|0) << 21, // increment after DB = (8|0|0) << 21, // decrement before IB = (8|4|0) << 21, // increment before DA_W = (0|0|1) << 21, // decrement after with writeback to base IA_W = (0|4|1) << 21, // increment after with writeback to base DB_W = (8|0|1) << 21, // decrement before with writeback to base IB_W = (8|4|1) << 21 // increment before with writeback to base }; class Address { public: // Memory operand addressing mode (in ARM encoding form. For others we need // to adjust) enum Mode { // bit encoding P U W Offset = (8|4|0) << 21, // offset (w/o writeback to base) PreIndex = (8|4|1) << 21, // pre-indexed addressing with writeback PostIndex = (0|4|0) << 21, // post-indexed addressing with writeback NegOffset = (8|0|0) << 21, // negative offset (w/o writeback to base) NegPreIndex = (8|0|1) << 21, // negative pre-indexed with writeback NegPostIndex = (0|0|0) << 21 // negative post-indexed with writeback }; Address(Register rn, int32_t offset = 0, Mode am = Offset) : rn_(rn), rm_(R0), offset_(offset), am_(am), is_immed_offset_(true), shift_(LSL) { } Address(Register rn, Register rm, Mode am = Offset) : rn_(rn), rm_(rm), offset_(0), am_(am), is_immed_offset_(false), shift_(LSL) { CHECK_NE(rm, PC); } Address(Register rn, Register rm, Shift shift, uint32_t count, Mode am = Offset) : rn_(rn), rm_(rm), offset_(count), am_(am), is_immed_offset_(false), shift_(shift) { CHECK_NE(rm, PC); } // LDR(literal) - pc relative load. explicit Address(int32_t offset) : rn_(PC), rm_(R0), offset_(offset), am_(Offset), is_immed_offset_(false), shift_(LSL) { } static bool CanHoldLoadOffsetArm(LoadOperandType type, int offset); static bool CanHoldStoreOffsetArm(StoreOperandType type, int offset); static bool CanHoldLoadOffsetThumb(LoadOperandType type, int offset); static bool CanHoldStoreOffsetThumb(StoreOperandType type, int offset); uint32_t encodingArm() const; uint32_t encodingThumb(bool is_32bit) const; uint32_t encoding3() const; uint32_t vencoding() const; uint32_t encodingThumbLdrdStrd() const; Register GetRegister() const { return rn_; } Register GetRegisterOffset() const { return rm_; } int32_t GetOffset() const { return offset_; } Mode GetMode() const { return am_; } bool IsImmediate() const { return is_immed_offset_; } Shift GetShift() const { return shift_; } int32_t GetShiftCount() const { CHECK(!is_immed_offset_); return offset_; } private: Register rn_; Register rm_; int32_t offset_; // Used as shift amount for register offset. Mode am_; bool is_immed_offset_; Shift shift_; }; // Instruction encoding bits. enum { H = 1 << 5, // halfword (or byte) L = 1 << 20, // load (or store) S = 1 << 20, // set condition code (or leave unchanged) W = 1 << 21, // writeback base register (or leave unchanged) A = 1 << 21, // accumulate in multiply instruction (or not) B = 1 << 22, // unsigned byte (or word) N = 1 << 22, // long (or short) U = 1 << 23, // positive (or negative) offset/index P = 1 << 24, // offset/pre-indexed addressing (or post-indexed addressing) I = 1 << 25, // immediate shifter operand (or not) B0 = 1, B1 = 1 << 1, B2 = 1 << 2, B3 = 1 << 3, B4 = 1 << 4, B5 = 1 << 5, B6 = 1 << 6, B7 = 1 << 7, B8 = 1 << 8, B9 = 1 << 9, B10 = 1 << 10, B11 = 1 << 11, B12 = 1 << 12, B13 = 1 << 13, B14 = 1 << 14, B15 = 1 << 15, B16 = 1 << 16, B17 = 1 << 17, B18 = 1 << 18, B19 = 1 << 19, B20 = 1 << 20, B21 = 1 << 21, B22 = 1 << 22, B23 = 1 << 23, B24 = 1 << 24, B25 = 1 << 25, B26 = 1 << 26, B27 = 1 << 27, B28 = 1 << 28, B29 = 1 << 29, B30 = 1 << 30, B31 = 1 << 31, // Instruction bit masks. RdMask = 15 << 12, // in str instruction CondMask = 15 << 28, CoprocessorMask = 15 << 8, OpCodeMask = 15 << 21, // in data-processing instructions Imm24Mask = (1 << 24) - 1, Off12Mask = (1 << 12) - 1, // ldrex/strex register field encodings. kLdExRnShift = 16, kLdExRtShift = 12, kStrExRnShift = 16, kStrExRdShift = 12, kStrExRtShift = 0, }; // IfThen state for IT instructions. enum ItState { kItOmitted, kItThen, kItT = kItThen, kItElse, kItE = kItElse }; constexpr uint32_t kNoItCondition = 3; constexpr uint32_t kInvalidModifiedImmediate = -1; extern const char* kRegisterNames[]; extern const char* kConditionNames[]; extern std::ostream& operator<<(std::ostream& os, const Register& rhs); extern std::ostream& operator<<(std::ostream& os, const SRegister& rhs); extern std::ostream& operator<<(std::ostream& os, const DRegister& rhs); extern std::ostream& operator<<(std::ostream& os, const Condition& rhs); // This is an abstract ARM assembler. Subclasses provide assemblers for the individual // instruction sets (ARM32, Thumb2, etc.) // class ArmAssembler : public Assembler { public: virtual ~ArmAssembler() {} // Is this assembler for the thumb instruction set? virtual bool IsThumb() const = 0; // Data-processing instructions. virtual void and_(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void eor(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void sub(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void subs(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void rsb(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void rsbs(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void add(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void adds(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void adc(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void sbc(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void rsc(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void tst(Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void teq(Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void cmp(Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void cmn(Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void orr(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void orrs(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void mov(Register rd, const ShifterOperand& so, Condition cond = AL) = 0; virtual void movs(Register rd, const ShifterOperand& so, Condition cond = AL) = 0; virtual void bic(Register rd, Register rn, const ShifterOperand& so, Condition cond = AL) = 0; virtual void mvn(Register rd, const ShifterOperand& so, Condition cond = AL) = 0; virtual void mvns(Register rd, const ShifterOperand& so, Condition cond = AL) = 0; // Miscellaneous data-processing instructions. virtual void clz(Register rd, Register rm, Condition cond = AL) = 0; virtual void movw(Register rd, uint16_t imm16, Condition cond = AL) = 0; virtual void movt(Register rd, uint16_t imm16, Condition cond = AL) = 0; // Multiply instructions. virtual void mul(Register rd, Register rn, Register rm, Condition cond = AL) = 0; virtual void mla(Register rd, Register rn, Register rm, Register ra, Condition cond = AL) = 0; virtual void mls(Register rd, Register rn, Register rm, Register ra, Condition cond = AL) = 0; virtual void umull(Register rd_lo, Register rd_hi, Register rn, Register rm, Condition cond = AL) = 0; virtual void sdiv(Register rd, Register rn, Register rm, Condition cond = AL) = 0; virtual void udiv(Register rd, Register rn, Register rm, Condition cond = AL) = 0; // Load/store instructions. virtual void ldr(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void str(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void ldrb(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void strb(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void ldrh(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void strh(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void ldrsb(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void ldrsh(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void ldrd(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void strd(Register rd, const Address& ad, Condition cond = AL) = 0; virtual void ldm(BlockAddressMode am, Register base, RegList regs, Condition cond = AL) = 0; virtual void stm(BlockAddressMode am, Register base, RegList regs, Condition cond = AL) = 0; virtual void ldrex(Register rd, Register rn, Condition cond = AL) = 0; virtual void strex(Register rd, Register rt, Register rn, Condition cond = AL) = 0; // Miscellaneous instructions. virtual void clrex(Condition cond = AL) = 0; virtual void nop(Condition cond = AL) = 0; // Note that gdb sets breakpoints using the undefined instruction 0xe7f001f0. virtual void bkpt(uint16_t imm16) = 0; virtual void svc(uint32_t imm24) = 0; virtual void it(Condition firstcond, ItState i1 = kItOmitted, ItState i2 = kItOmitted, ItState i3 = kItOmitted) { // Ignored if not supported. } virtual void cbz(Register rn, Label* target) = 0; virtual void cbnz(Register rn, Label* target) = 0; // Floating point instructions (VFPv3-D16 and VFPv3-D32 profiles). virtual void vmovsr(SRegister sn, Register rt, Condition cond = AL) = 0; virtual void vmovrs(Register rt, SRegister sn, Condition cond = AL) = 0; virtual void vmovsrr(SRegister sm, Register rt, Register rt2, Condition cond = AL) = 0; virtual void vmovrrs(Register rt, Register rt2, SRegister sm, Condition cond = AL) = 0; virtual void vmovdrr(DRegister dm, Register rt, Register rt2, Condition cond = AL) = 0; virtual void vmovrrd(Register rt, Register rt2, DRegister dm, Condition cond = AL) = 0; virtual void vmovs(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vmovd(DRegister dd, DRegister dm, Condition cond = AL) = 0; // Returns false if the immediate cannot be encoded. virtual bool vmovs(SRegister sd, float s_imm, Condition cond = AL) = 0; virtual bool vmovd(DRegister dd, double d_imm, Condition cond = AL) = 0; virtual void vldrs(SRegister sd, const Address& ad, Condition cond = AL) = 0; virtual void vstrs(SRegister sd, const Address& ad, Condition cond = AL) = 0; virtual void vldrd(DRegister dd, const Address& ad, Condition cond = AL) = 0; virtual void vstrd(DRegister dd, const Address& ad, Condition cond = AL) = 0; virtual void vadds(SRegister sd, SRegister sn, SRegister sm, Condition cond = AL) = 0; virtual void vaddd(DRegister dd, DRegister dn, DRegister dm, Condition cond = AL) = 0; virtual void vsubs(SRegister sd, SRegister sn, SRegister sm, Condition cond = AL) = 0; virtual void vsubd(DRegister dd, DRegister dn, DRegister dm, Condition cond = AL) = 0; virtual void vmuls(SRegister sd, SRegister sn, SRegister sm, Condition cond = AL) = 0; virtual void vmuld(DRegister dd, DRegister dn, DRegister dm, Condition cond = AL) = 0; virtual void vmlas(SRegister sd, SRegister sn, SRegister sm, Condition cond = AL) = 0; virtual void vmlad(DRegister dd, DRegister dn, DRegister dm, Condition cond = AL) = 0; virtual void vmlss(SRegister sd, SRegister sn, SRegister sm, Condition cond = AL) = 0; virtual void vmlsd(DRegister dd, DRegister dn, DRegister dm, Condition cond = AL) = 0; virtual void vdivs(SRegister sd, SRegister sn, SRegister sm, Condition cond = AL) = 0; virtual void vdivd(DRegister dd, DRegister dn, DRegister dm, Condition cond = AL) = 0; virtual void vabss(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vabsd(DRegister dd, DRegister dm, Condition cond = AL) = 0; virtual void vnegs(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vnegd(DRegister dd, DRegister dm, Condition cond = AL) = 0; virtual void vsqrts(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vsqrtd(DRegister dd, DRegister dm, Condition cond = AL) = 0; virtual void vcvtsd(SRegister sd, DRegister dm, Condition cond = AL) = 0; virtual void vcvtds(DRegister dd, SRegister sm, Condition cond = AL) = 0; virtual void vcvtis(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vcvtid(SRegister sd, DRegister dm, Condition cond = AL) = 0; virtual void vcvtsi(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vcvtdi(DRegister dd, SRegister sm, Condition cond = AL) = 0; virtual void vcvtus(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vcvtud(SRegister sd, DRegister dm, Condition cond = AL) = 0; virtual void vcvtsu(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vcvtdu(DRegister dd, SRegister sm, Condition cond = AL) = 0; virtual void vcmps(SRegister sd, SRegister sm, Condition cond = AL) = 0; virtual void vcmpd(DRegister dd, DRegister dm, Condition cond = AL) = 0; virtual void vcmpsz(SRegister sd, Condition cond = AL) = 0; virtual void vcmpdz(DRegister dd, Condition cond = AL) = 0; virtual void vmstat(Condition cond = AL) = 0; // VMRS APSR_nzcv, FPSCR virtual void vpushs(SRegister reg, int nregs, Condition cond = AL) = 0; virtual void vpushd(DRegister reg, int nregs, Condition cond = AL) = 0; virtual void vpops(SRegister reg, int nregs, Condition cond = AL) = 0; virtual void vpopd(DRegister reg, int nregs, Condition cond = AL) = 0; // Branch instructions. virtual void b(Label* label, Condition cond = AL) = 0; virtual void bl(Label* label, Condition cond = AL) = 0; virtual void blx(Register rm, Condition cond = AL) = 0; virtual void bx(Register rm, Condition cond = AL) = 0; void Pad(uint32_t bytes); // Macros. // Most of these are pure virtual as they need to be implemented per instruction set. // Add signed constant value to rd. May clobber IP. virtual void AddConstant(Register rd, int32_t value, Condition cond = AL) = 0; virtual void AddConstant(Register rd, Register rn, int32_t value, Condition cond = AL) = 0; virtual void AddConstantSetFlags(Register rd, Register rn, int32_t value, Condition cond = AL) = 0; virtual void AddConstantWithCarry(Register rd, Register rn, int32_t value, Condition cond = AL) = 0; // Load and Store. May clobber IP. virtual void LoadImmediate(Register rd, int32_t value, Condition cond = AL) = 0; virtual void LoadSImmediate(SRegister sd, float value, Condition cond = AL) = 0; virtual void LoadDImmediate(DRegister dd, double value, Register scratch, Condition cond = AL) = 0; virtual void MarkExceptionHandler(Label* label) = 0; virtual void LoadFromOffset(LoadOperandType type, Register reg, Register base, int32_t offset, Condition cond = AL) = 0; virtual void StoreToOffset(StoreOperandType type, Register reg, Register base, int32_t offset, Condition cond = AL) = 0; virtual void LoadSFromOffset(SRegister reg, Register base, int32_t offset, Condition cond = AL) = 0; virtual void StoreSToOffset(SRegister reg, Register base, int32_t offset, Condition cond = AL) = 0; virtual void LoadDFromOffset(DRegister reg, Register base, int32_t offset, Condition cond = AL) = 0; virtual void StoreDToOffset(DRegister reg, Register base, int32_t offset, Condition cond = AL) = 0; virtual void Push(Register rd, Condition cond = AL) = 0; virtual void Pop(Register rd, Condition cond = AL) = 0; virtual void PushList(RegList regs, Condition cond = AL) = 0; virtual void PopList(RegList regs, Condition cond = AL) = 0; virtual void Mov(Register rd, Register rm, Condition cond = AL) = 0; // Convenience shift instructions. Use mov instruction with shifter operand // for variants setting the status flags or using a register shift count. virtual void Lsl(Register rd, Register rm, uint32_t shift_imm, bool setcc = false, Condition cond = AL) = 0; virtual void Lsr(Register rd, Register rm, uint32_t shift_imm, bool setcc = false, Condition cond = AL) = 0; virtual void Asr(Register rd, Register rm, uint32_t shift_imm, bool setcc = false, Condition cond = AL) = 0; virtual void Ror(Register rd, Register rm, uint32_t shift_imm, bool setcc = false, Condition cond = AL) = 0; virtual void Rrx(Register rd, Register rm, bool setcc = false, Condition cond = AL) = 0; virtual void Lsl(Register rd, Register rm, Register rn, bool setcc = false, Condition cond = AL) = 0; virtual void Lsr(Register rd, Register rm, Register rn, bool setcc = false, Condition cond = AL) = 0; virtual void Asr(Register rd, Register rm, Register rn, bool setcc = false, Condition cond = AL) = 0; virtual void Ror(Register rd, Register rm, Register rn, bool setcc = false, Condition cond = AL) = 0; static bool IsInstructionForExceptionHandling(uword pc); virtual void Bind(Label* label) = 0; virtual void CompareAndBranchIfZero(Register r, Label* label) = 0; virtual void CompareAndBranchIfNonZero(Register r, Label* label) = 0; // // Overridden common assembler high-level functionality // // Emit code that will create an activation on the stack void BuildFrame(size_t frame_size, ManagedRegister method_reg, const std::vector& callee_save_regs, const ManagedRegisterEntrySpills& entry_spills) OVERRIDE; // Emit code that will remove an activation from the stack void RemoveFrame(size_t frame_size, const std::vector& callee_save_regs) OVERRIDE; void IncreaseFrameSize(size_t adjust) OVERRIDE; void DecreaseFrameSize(size_t adjust) OVERRIDE; // Store routines void Store(FrameOffset offs, ManagedRegister src, size_t size) OVERRIDE; void StoreRef(FrameOffset dest, ManagedRegister src) OVERRIDE; void StoreRawPtr(FrameOffset dest, ManagedRegister src) OVERRIDE; void StoreImmediateToFrame(FrameOffset dest, uint32_t imm, ManagedRegister scratch) OVERRIDE; void StoreImmediateToThread32(ThreadOffset<4> dest, uint32_t imm, ManagedRegister scratch) OVERRIDE; void StoreStackOffsetToThread32(ThreadOffset<4> thr_offs, FrameOffset fr_offs, ManagedRegister scratch) OVERRIDE; void StoreStackPointerToThread32(ThreadOffset<4> thr_offs) OVERRIDE; void StoreSpanning(FrameOffset dest, ManagedRegister src, FrameOffset in_off, ManagedRegister scratch) OVERRIDE; // Load routines void Load(ManagedRegister dest, FrameOffset src, size_t size) OVERRIDE; void LoadFromThread32(ManagedRegister dest, ThreadOffset<4> src, size_t size) OVERRIDE; void LoadRef(ManagedRegister dest, FrameOffset src) OVERRIDE; void LoadRef(ManagedRegister dest, ManagedRegister base, MemberOffset offs) OVERRIDE; void LoadRawPtr(ManagedRegister dest, ManagedRegister base, Offset offs) OVERRIDE; void LoadRawPtrFromThread32(ManagedRegister dest, ThreadOffset<4> offs) OVERRIDE; // Copying routines void Move(ManagedRegister dest, ManagedRegister src, size_t size) OVERRIDE; void CopyRawPtrFromThread32(FrameOffset fr_offs, ThreadOffset<4> thr_offs, ManagedRegister scratch) OVERRIDE; void CopyRawPtrToThread32(ThreadOffset<4> thr_offs, FrameOffset fr_offs, ManagedRegister scratch) OVERRIDE; void CopyRef(FrameOffset dest, FrameOffset src, ManagedRegister scratch) OVERRIDE; void Copy(FrameOffset dest, FrameOffset src, ManagedRegister scratch, size_t size) OVERRIDE; void Copy(FrameOffset dest, ManagedRegister src_base, Offset src_offset, ManagedRegister scratch, size_t size) OVERRIDE; void Copy(ManagedRegister dest_base, Offset dest_offset, FrameOffset src, ManagedRegister scratch, size_t size) OVERRIDE; void Copy(FrameOffset dest, FrameOffset src_base, Offset src_offset, ManagedRegister scratch, size_t size) OVERRIDE; void Copy(ManagedRegister dest, Offset dest_offset, ManagedRegister src, Offset src_offset, ManagedRegister scratch, size_t size) OVERRIDE; void Copy(FrameOffset dest, Offset dest_offset, FrameOffset src, Offset src_offset, ManagedRegister scratch, size_t size) OVERRIDE; // Sign extension void SignExtend(ManagedRegister mreg, size_t size) OVERRIDE; // Zero extension void ZeroExtend(ManagedRegister mreg, size_t size) OVERRIDE; // Exploit fast access in managed code to Thread::Current() void GetCurrentThread(ManagedRegister tr) OVERRIDE; void GetCurrentThread(FrameOffset dest_offset, ManagedRegister scratch) OVERRIDE; // Set up out_reg to hold a Object** into the handle scope, or to be NULL if the // value is null and null_allowed. in_reg holds a possibly stale reference // that can be used to avoid loading the handle scope entry to see if the value is // NULL. void CreateHandleScopeEntry(ManagedRegister out_reg, FrameOffset handlescope_offset, ManagedRegister in_reg, bool null_allowed) OVERRIDE; // Set up out_off to hold a Object** into the handle scope, or to be NULL if the // value is null and null_allowed. void CreateHandleScopeEntry(FrameOffset out_off, FrameOffset handlescope_offset, ManagedRegister scratch, bool null_allowed) OVERRIDE; // src holds a handle scope entry (Object**) load this into dst void LoadReferenceFromHandleScope(ManagedRegister dst, ManagedRegister src) OVERRIDE; // Heap::VerifyObject on src. In some cases (such as a reference to this) we // know that src may not be null. void VerifyObject(ManagedRegister src, bool could_be_null) OVERRIDE; void VerifyObject(FrameOffset src, bool could_be_null) OVERRIDE; // Call to address held at [base+offset] void Call(ManagedRegister base, Offset offset, ManagedRegister scratch) OVERRIDE; void Call(FrameOffset base, Offset offset, ManagedRegister scratch) OVERRIDE; void CallFromThread32(ThreadOffset<4> offset, ManagedRegister scratch) OVERRIDE; // Generate code to check if Thread::Current()->exception_ is non-null // and branch to a ExceptionSlowPath if it is. void ExceptionPoll(ManagedRegister scratch, size_t stack_adjust) OVERRIDE; static uint32_t ModifiedImmediate(uint32_t value); static bool IsLowRegister(Register r) { return r < R8; } static bool IsHighRegister(Register r) { return r >= R8; } protected: // Returns whether or not the given register is used for passing parameters. static int RegisterCompare(const Register* reg1, const Register* reg2) { return *reg1 - *reg2; } }; // Slowpath entered when Thread::Current()->_exception is non-null class ArmExceptionSlowPath FINAL : public SlowPath { public: explicit ArmExceptionSlowPath(ArmManagedRegister scratch, size_t stack_adjust) : scratch_(scratch), stack_adjust_(stack_adjust) { } void Emit(Assembler *sp_asm) OVERRIDE; private: const ArmManagedRegister scratch_; const size_t stack_adjust_; }; } // namespace arm } // namespace art #endif // ART_COMPILER_UTILS_ARM_ASSEMBLER_ARM_H_