// Copyright 2013 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_ARM64_MACRO_ASSEMBLER_ARM64_INL_H_ #define V8_ARM64_MACRO_ASSEMBLER_ARM64_INL_H_ #include #include "src/globals.h" #include "src/arm64/assembler-arm64-inl.h" #include "src/arm64/assembler-arm64.h" #include "src/arm64/instrument-arm64.h" #include "src/arm64/macro-assembler-arm64.h" #include "src/base/bits.h" namespace v8 { namespace internal { MemOperand FieldMemOperand(Register object, int offset) { return MemOperand(object, offset - kHeapObjectTag); } MemOperand UntagSmiFieldMemOperand(Register object, int offset) { return UntagSmiMemOperand(object, offset - kHeapObjectTag); } MemOperand UntagSmiMemOperand(Register object, int offset) { // Assumes that Smis are shifted by 32 bits and little endianness. STATIC_ASSERT(kSmiShift == 32); return MemOperand(object, offset + (kSmiShift / kBitsPerByte)); } Handle MacroAssembler::CodeObject() { DCHECK(!code_object_.is_null()); return code_object_; } void MacroAssembler::And(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, AND); } void MacroAssembler::Ands(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, ANDS); } void MacroAssembler::Tst(const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); LogicalMacro(AppropriateZeroRegFor(rn), rn, operand, ANDS); } void MacroAssembler::Bic(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, BIC); } void MacroAssembler::Bics(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, BICS); } void MacroAssembler::Orr(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, ORR); } void MacroAssembler::Orn(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, ORN); } void MacroAssembler::Eor(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, EOR); } void MacroAssembler::Eon(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); LogicalMacro(rd, rn, operand, EON); } void MacroAssembler::Ccmp(const Register& rn, const Operand& operand, StatusFlags nzcv, Condition cond) { DCHECK(allow_macro_instructions_); if (operand.IsImmediate() && (operand.ImmediateValue() < 0)) { ConditionalCompareMacro(rn, -operand.ImmediateValue(), nzcv, cond, CCMN); } else { ConditionalCompareMacro(rn, operand, nzcv, cond, CCMP); } } void MacroAssembler::Ccmn(const Register& rn, const Operand& operand, StatusFlags nzcv, Condition cond) { DCHECK(allow_macro_instructions_); if (operand.IsImmediate() && (operand.ImmediateValue() < 0)) { ConditionalCompareMacro(rn, -operand.ImmediateValue(), nzcv, cond, CCMP); } else { ConditionalCompareMacro(rn, operand, nzcv, cond, CCMN); } } void MacroAssembler::Add(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); if (operand.IsImmediate() && (operand.ImmediateValue() < 0) && IsImmAddSub(-operand.ImmediateValue())) { AddSubMacro(rd, rn, -operand.ImmediateValue(), LeaveFlags, SUB); } else { AddSubMacro(rd, rn, operand, LeaveFlags, ADD); } } void MacroAssembler::Adds(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); if (operand.IsImmediate() && (operand.ImmediateValue() < 0) && IsImmAddSub(-operand.ImmediateValue())) { AddSubMacro(rd, rn, -operand.ImmediateValue(), SetFlags, SUB); } else { AddSubMacro(rd, rn, operand, SetFlags, ADD); } } void MacroAssembler::Sub(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); if (operand.IsImmediate() && (operand.ImmediateValue() < 0) && IsImmAddSub(-operand.ImmediateValue())) { AddSubMacro(rd, rn, -operand.ImmediateValue(), LeaveFlags, ADD); } else { AddSubMacro(rd, rn, operand, LeaveFlags, SUB); } } void MacroAssembler::Subs(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); if (operand.IsImmediate() && (operand.ImmediateValue() < 0) && IsImmAddSub(-operand.ImmediateValue())) { AddSubMacro(rd, rn, -operand.ImmediateValue(), SetFlags, ADD); } else { AddSubMacro(rd, rn, operand, SetFlags, SUB); } } void MacroAssembler::Cmn(const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); Adds(AppropriateZeroRegFor(rn), rn, operand); } void MacroAssembler::Cmp(const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); Subs(AppropriateZeroRegFor(rn), rn, operand); } void MacroAssembler::Neg(const Register& rd, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); if (operand.IsImmediate()) { Mov(rd, -operand.ImmediateValue()); } else { Sub(rd, AppropriateZeroRegFor(rd), operand); } } void MacroAssembler::Negs(const Register& rd, const Operand& operand) { DCHECK(allow_macro_instructions_); Subs(rd, AppropriateZeroRegFor(rd), operand); } void MacroAssembler::Adc(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); AddSubWithCarryMacro(rd, rn, operand, LeaveFlags, ADC); } void MacroAssembler::Adcs(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); AddSubWithCarryMacro(rd, rn, operand, SetFlags, ADC); } void MacroAssembler::Sbc(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); AddSubWithCarryMacro(rd, rn, operand, LeaveFlags, SBC); } void MacroAssembler::Sbcs(const Register& rd, const Register& rn, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); AddSubWithCarryMacro(rd, rn, operand, SetFlags, SBC); } void MacroAssembler::Ngc(const Register& rd, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); Register zr = AppropriateZeroRegFor(rd); Sbc(rd, zr, operand); } void MacroAssembler::Ngcs(const Register& rd, const Operand& operand) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); Register zr = AppropriateZeroRegFor(rd); Sbcs(rd, zr, operand); } void MacroAssembler::Mvn(const Register& rd, uint64_t imm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); Mov(rd, ~imm); } #define DEFINE_FUNCTION(FN, REGTYPE, REG, OP) \ void MacroAssembler::FN(const REGTYPE REG, const MemOperand& addr) { \ DCHECK(allow_macro_instructions_); \ LoadStoreMacro(REG, addr, OP); \ } LS_MACRO_LIST(DEFINE_FUNCTION) #undef DEFINE_FUNCTION #define DEFINE_FUNCTION(FN, REGTYPE, REG, REG2, OP) \ void MacroAssembler::FN(const REGTYPE REG, const REGTYPE REG2, \ const MemOperand& addr) { \ DCHECK(allow_macro_instructions_); \ LoadStorePairMacro(REG, REG2, addr, OP); \ } LSPAIR_MACRO_LIST(DEFINE_FUNCTION) #undef DEFINE_FUNCTION void MacroAssembler::Asr(const Register& rd, const Register& rn, unsigned shift) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); asr(rd, rn, shift); } void MacroAssembler::Asr(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); asrv(rd, rn, rm); } void MacroAssembler::B(Label* label) { b(label); CheckVeneerPool(false, false); } void MacroAssembler::B(Condition cond, Label* label) { DCHECK(allow_macro_instructions_); B(label, cond); } void MacroAssembler::Bfi(const Register& rd, const Register& rn, unsigned lsb, unsigned width) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); bfi(rd, rn, lsb, width); } void MacroAssembler::Bfxil(const Register& rd, const Register& rn, unsigned lsb, unsigned width) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); bfxil(rd, rn, lsb, width); } void MacroAssembler::Bind(Label* label) { DCHECK(allow_macro_instructions_); bind(label); } void MacroAssembler::Bl(Label* label) { DCHECK(allow_macro_instructions_); bl(label); } void MacroAssembler::Blr(const Register& xn) { DCHECK(allow_macro_instructions_); DCHECK(!xn.IsZero()); blr(xn); } void MacroAssembler::Br(const Register& xn) { DCHECK(allow_macro_instructions_); DCHECK(!xn.IsZero()); br(xn); } void MacroAssembler::Brk(int code) { DCHECK(allow_macro_instructions_); brk(code); } void MacroAssembler::Cinc(const Register& rd, const Register& rn, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); cinc(rd, rn, cond); } void MacroAssembler::Cinv(const Register& rd, const Register& rn, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); cinv(rd, rn, cond); } void MacroAssembler::Cls(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); cls(rd, rn); } void MacroAssembler::Clz(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); clz(rd, rn); } void MacroAssembler::Cneg(const Register& rd, const Register& rn, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); cneg(rd, rn, cond); } // Conditionally zero the destination register. Only X registers are supported // due to the truncation side-effect when used on W registers. void MacroAssembler::CzeroX(const Register& rd, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsSP() && rd.Is64Bits()); DCHECK((cond != al) && (cond != nv)); csel(rd, xzr, rd, cond); } // Conditionally move a value into the destination register. Only X registers // are supported due to the truncation side-effect when used on W registers. void MacroAssembler::CmovX(const Register& rd, const Register& rn, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsSP()); DCHECK(rd.Is64Bits() && rn.Is64Bits()); DCHECK((cond != al) && (cond != nv)); if (!rd.is(rn)) { csel(rd, rn, rd, cond); } } void MacroAssembler::Cset(const Register& rd, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); cset(rd, cond); } void MacroAssembler::Csetm(const Register& rd, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); csetm(rd, cond); } void MacroAssembler::Csinc(const Register& rd, const Register& rn, const Register& rm, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); csinc(rd, rn, rm, cond); } void MacroAssembler::Csinv(const Register& rd, const Register& rn, const Register& rm, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); csinv(rd, rn, rm, cond); } void MacroAssembler::Csneg(const Register& rd, const Register& rn, const Register& rm, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); DCHECK((cond != al) && (cond != nv)); csneg(rd, rn, rm, cond); } void MacroAssembler::Dmb(BarrierDomain domain, BarrierType type) { DCHECK(allow_macro_instructions_); dmb(domain, type); } void MacroAssembler::Dsb(BarrierDomain domain, BarrierType type) { DCHECK(allow_macro_instructions_); dsb(domain, type); } void MacroAssembler::Debug(const char* message, uint32_t code, Instr params) { DCHECK(allow_macro_instructions_); debug(message, code, params); } void MacroAssembler::Extr(const Register& rd, const Register& rn, const Register& rm, unsigned lsb) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); extr(rd, rn, rm, lsb); } void MacroAssembler::Fabs(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); fabs(fd, fn); } void MacroAssembler::Fadd(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fadd(fd, fn, fm); } void MacroAssembler::Fccmp(const FPRegister& fn, const FPRegister& fm, StatusFlags nzcv, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK((cond != al) && (cond != nv)); fccmp(fn, fm, nzcv, cond); } void MacroAssembler::Fcmp(const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fcmp(fn, fm); } void MacroAssembler::Fcmp(const FPRegister& fn, double value) { DCHECK(allow_macro_instructions_); if (value != 0.0) { UseScratchRegisterScope temps(this); FPRegister tmp = temps.AcquireSameSizeAs(fn); Fmov(tmp, value); fcmp(fn, tmp); } else { fcmp(fn, value); } } void MacroAssembler::Fcsel(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm, Condition cond) { DCHECK(allow_macro_instructions_); DCHECK((cond != al) && (cond != nv)); fcsel(fd, fn, fm, cond); } void MacroAssembler::Fcvt(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); fcvt(fd, fn); } void MacroAssembler::Fcvtas(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtas(rd, fn); } void MacroAssembler::Fcvtau(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtau(rd, fn); } void MacroAssembler::Fcvtms(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtms(rd, fn); } void MacroAssembler::Fcvtmu(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtmu(rd, fn); } void MacroAssembler::Fcvtns(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtns(rd, fn); } void MacroAssembler::Fcvtnu(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtnu(rd, fn); } void MacroAssembler::Fcvtzs(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtzs(rd, fn); } void MacroAssembler::Fcvtzu(const Register& rd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fcvtzu(rd, fn); } void MacroAssembler::Fdiv(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fdiv(fd, fn, fm); } void MacroAssembler::Fmadd(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm, const FPRegister& fa) { DCHECK(allow_macro_instructions_); fmadd(fd, fn, fm, fa); } void MacroAssembler::Fmax(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fmax(fd, fn, fm); } void MacroAssembler::Fmaxnm(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fmaxnm(fd, fn, fm); } void MacroAssembler::Fmin(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fmin(fd, fn, fm); } void MacroAssembler::Fminnm(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fminnm(fd, fn, fm); } void MacroAssembler::Fmov(FPRegister fd, FPRegister fn) { DCHECK(allow_macro_instructions_); // Only emit an instruction if fd and fn are different, and they are both D // registers. fmov(s0, s0) is not a no-op because it clears the top word of // d0. Technically, fmov(d0, d0) is not a no-op either because it clears the // top of q0, but FPRegister does not currently support Q registers. if (!fd.Is(fn) || !fd.Is64Bits()) { fmov(fd, fn); } } void MacroAssembler::Fmov(FPRegister fd, Register rn) { DCHECK(allow_macro_instructions_); fmov(fd, rn); } void MacroAssembler::Fmov(FPRegister fd, double imm) { DCHECK(allow_macro_instructions_); if (fd.Is32Bits()) { Fmov(fd, static_cast(imm)); return; } DCHECK(fd.Is64Bits()); if (IsImmFP64(imm)) { fmov(fd, imm); } else if ((imm == 0.0) && (copysign(1.0, imm) == 1.0)) { fmov(fd, xzr); } else { Ldr(fd, imm); } } void MacroAssembler::Fmov(FPRegister fd, float imm) { DCHECK(allow_macro_instructions_); if (fd.Is64Bits()) { Fmov(fd, static_cast(imm)); return; } DCHECK(fd.Is32Bits()); if (IsImmFP32(imm)) { fmov(fd, imm); } else if ((imm == 0.0) && (copysign(1.0, imm) == 1.0)) { fmov(fd, wzr); } else { UseScratchRegisterScope temps(this); Register tmp = temps.AcquireW(); // TODO(all): Use Assembler::ldr(const FPRegister& ft, float imm). Mov(tmp, float_to_rawbits(imm)); Fmov(fd, tmp); } } void MacroAssembler::Fmov(Register rd, FPRegister fn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); fmov(rd, fn); } void MacroAssembler::Fmsub(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm, const FPRegister& fa) { DCHECK(allow_macro_instructions_); fmsub(fd, fn, fm, fa); } void MacroAssembler::Fmul(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fmul(fd, fn, fm); } void MacroAssembler::Fneg(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); fneg(fd, fn); } void MacroAssembler::Fnmadd(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm, const FPRegister& fa) { DCHECK(allow_macro_instructions_); fnmadd(fd, fn, fm, fa); } void MacroAssembler::Fnmsub(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm, const FPRegister& fa) { DCHECK(allow_macro_instructions_); fnmsub(fd, fn, fm, fa); } void MacroAssembler::Frinta(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); frinta(fd, fn); } void MacroAssembler::Frintm(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); frintm(fd, fn); } void MacroAssembler::Frintn(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); frintn(fd, fn); } void MacroAssembler::Frintz(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); frintz(fd, fn); } void MacroAssembler::Fsqrt(const FPRegister& fd, const FPRegister& fn) { DCHECK(allow_macro_instructions_); fsqrt(fd, fn); } void MacroAssembler::Fsub(const FPRegister& fd, const FPRegister& fn, const FPRegister& fm) { DCHECK(allow_macro_instructions_); fsub(fd, fn, fm); } void MacroAssembler::Hint(SystemHint code) { DCHECK(allow_macro_instructions_); hint(code); } void MacroAssembler::Hlt(int code) { DCHECK(allow_macro_instructions_); hlt(code); } void MacroAssembler::Isb() { DCHECK(allow_macro_instructions_); isb(); } void MacroAssembler::Ldnp(const CPURegister& rt, const CPURegister& rt2, const MemOperand& src) { DCHECK(allow_macro_instructions_); DCHECK(!AreAliased(rt, rt2)); ldnp(rt, rt2, src); } void MacroAssembler::Ldr(const CPURegister& rt, const Immediate& imm) { DCHECK(allow_macro_instructions_); ldr(rt, imm); } void MacroAssembler::Ldr(const CPURegister& rt, double imm) { DCHECK(allow_macro_instructions_); DCHECK(rt.Is64Bits()); ldr(rt, Immediate(double_to_rawbits(imm))); } void MacroAssembler::Lsl(const Register& rd, const Register& rn, unsigned shift) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); lsl(rd, rn, shift); } void MacroAssembler::Lsl(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); lslv(rd, rn, rm); } void MacroAssembler::Lsr(const Register& rd, const Register& rn, unsigned shift) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); lsr(rd, rn, shift); } void MacroAssembler::Lsr(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); lsrv(rd, rn, rm); } void MacroAssembler::Madd(const Register& rd, const Register& rn, const Register& rm, const Register& ra) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); madd(rd, rn, rm, ra); } void MacroAssembler::Mneg(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); mneg(rd, rn, rm); } void MacroAssembler::Mov(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); // Emit a register move only if the registers are distinct, or if they are // not X registers. Note that mov(w0, w0) is not a no-op because it clears // the top word of x0. if (!rd.Is(rn) || !rd.Is64Bits()) { Assembler::mov(rd, rn); } } void MacroAssembler::Movk(const Register& rd, uint64_t imm, int shift) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); movk(rd, imm, shift); } void MacroAssembler::Mrs(const Register& rt, SystemRegister sysreg) { DCHECK(allow_macro_instructions_); DCHECK(!rt.IsZero()); mrs(rt, sysreg); } void MacroAssembler::Msr(SystemRegister sysreg, const Register& rt) { DCHECK(allow_macro_instructions_); msr(sysreg, rt); } void MacroAssembler::Msub(const Register& rd, const Register& rn, const Register& rm, const Register& ra) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); msub(rd, rn, rm, ra); } void MacroAssembler::Mul(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); mul(rd, rn, rm); } void MacroAssembler::Rbit(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); rbit(rd, rn); } void MacroAssembler::Ret(const Register& xn) { DCHECK(allow_macro_instructions_); DCHECK(!xn.IsZero()); ret(xn); CheckVeneerPool(false, false); } void MacroAssembler::Rev(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); rev(rd, rn); } void MacroAssembler::Rev16(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); rev16(rd, rn); } void MacroAssembler::Rev32(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); rev32(rd, rn); } void MacroAssembler::Ror(const Register& rd, const Register& rs, unsigned shift) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); ror(rd, rs, shift); } void MacroAssembler::Ror(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); rorv(rd, rn, rm); } void MacroAssembler::Sbfiz(const Register& rd, const Register& rn, unsigned lsb, unsigned width) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); sbfiz(rd, rn, lsb, width); } void MacroAssembler::Sbfx(const Register& rd, const Register& rn, unsigned lsb, unsigned width) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); sbfx(rd, rn, lsb, width); } void MacroAssembler::Scvtf(const FPRegister& fd, const Register& rn, unsigned fbits) { DCHECK(allow_macro_instructions_); scvtf(fd, rn, fbits); } void MacroAssembler::Sdiv(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); sdiv(rd, rn, rm); } void MacroAssembler::Smaddl(const Register& rd, const Register& rn, const Register& rm, const Register& ra) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); smaddl(rd, rn, rm, ra); } void MacroAssembler::Smsubl(const Register& rd, const Register& rn, const Register& rm, const Register& ra) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); smsubl(rd, rn, rm, ra); } void MacroAssembler::Smull(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); smull(rd, rn, rm); } void MacroAssembler::Smulh(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); smulh(rd, rn, rm); } void MacroAssembler::Stnp(const CPURegister& rt, const CPURegister& rt2, const MemOperand& dst) { DCHECK(allow_macro_instructions_); stnp(rt, rt2, dst); } void MacroAssembler::Sxtb(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); sxtb(rd, rn); } void MacroAssembler::Sxth(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); sxth(rd, rn); } void MacroAssembler::Sxtw(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); sxtw(rd, rn); } void MacroAssembler::Ubfiz(const Register& rd, const Register& rn, unsigned lsb, unsigned width) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); ubfiz(rd, rn, lsb, width); } void MacroAssembler::Ubfx(const Register& rd, const Register& rn, unsigned lsb, unsigned width) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); ubfx(rd, rn, lsb, width); } void MacroAssembler::Ucvtf(const FPRegister& fd, const Register& rn, unsigned fbits) { DCHECK(allow_macro_instructions_); ucvtf(fd, rn, fbits); } void MacroAssembler::Udiv(const Register& rd, const Register& rn, const Register& rm) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); udiv(rd, rn, rm); } void MacroAssembler::Umaddl(const Register& rd, const Register& rn, const Register& rm, const Register& ra) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); umaddl(rd, rn, rm, ra); } void MacroAssembler::Umsubl(const Register& rd, const Register& rn, const Register& rm, const Register& ra) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); umsubl(rd, rn, rm, ra); } void MacroAssembler::Uxtb(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); uxtb(rd, rn); } void MacroAssembler::Uxth(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); uxth(rd, rn); } void MacroAssembler::Uxtw(const Register& rd, const Register& rn) { DCHECK(allow_macro_instructions_); DCHECK(!rd.IsZero()); uxtw(rd, rn); } void MacroAssembler::BumpSystemStackPointer(const Operand& space) { DCHECK(!csp.Is(sp_)); if (!TmpList()->IsEmpty()) { if (CpuFeatures::IsSupported(ALWAYS_ALIGN_CSP)) { UseScratchRegisterScope temps(this); Register temp = temps.AcquireX(); Sub(temp, StackPointer(), space); Bic(csp, temp, 0xf); } else { Sub(csp, StackPointer(), space); } } else { // TODO(jbramley): Several callers rely on this not using scratch // registers, so we use the assembler directly here. However, this means // that large immediate values of 'space' cannot be handled cleanly. (Only // 24-bits immediates or values of 'space' that can be encoded in one // instruction are accepted.) Once we implement our flexible scratch // register idea, we could greatly simplify this function. InstructionAccurateScope scope(this); DCHECK(space.IsImmediate()); // Align to 16 bytes. uint64_t imm = RoundUp(space.ImmediateValue(), 0x10); DCHECK(is_uint24(imm)); Register source = StackPointer(); if (CpuFeatures::IsSupported(ALWAYS_ALIGN_CSP)) { bic(csp, source, 0xf); source = csp; } if (!is_uint12(imm)) { int64_t imm_top_12_bits = imm >> 12; sub(csp, source, imm_top_12_bits << 12); source = csp; imm -= imm_top_12_bits << 12; } if (imm > 0) { sub(csp, source, imm); } } AssertStackConsistency(); } void MacroAssembler::SyncSystemStackPointer() { DCHECK(emit_debug_code()); DCHECK(!csp.Is(sp_)); { InstructionAccurateScope scope(this); if (CpuFeatures::IsSupported(ALWAYS_ALIGN_CSP)) { bic(csp, StackPointer(), 0xf); } else { mov(csp, StackPointer()); } } AssertStackConsistency(); } void MacroAssembler::InitializeRootRegister() { ExternalReference roots_array_start = ExternalReference::roots_array_start(isolate()); Mov(root, Operand(roots_array_start)); } void MacroAssembler::SmiTag(Register dst, Register src) { STATIC_ASSERT(kXRegSizeInBits == static_cast(kSmiShift + kSmiValueSize)); DCHECK(dst.Is64Bits() && src.Is64Bits()); Lsl(dst, src, kSmiShift); } void MacroAssembler::SmiTag(Register smi) { SmiTag(smi, smi); } void MacroAssembler::SmiUntag(Register dst, Register src) { STATIC_ASSERT(kXRegSizeInBits == static_cast(kSmiShift + kSmiValueSize)); DCHECK(dst.Is64Bits() && src.Is64Bits()); if (FLAG_enable_slow_asserts) { AssertSmi(src); } Asr(dst, src, kSmiShift); } void MacroAssembler::SmiUntag(Register smi) { SmiUntag(smi, smi); } void MacroAssembler::SmiUntagToDouble(FPRegister dst, Register src, UntagMode mode) { DCHECK(dst.Is64Bits() && src.Is64Bits()); if (FLAG_enable_slow_asserts && (mode == kNotSpeculativeUntag)) { AssertSmi(src); } Scvtf(dst, src, kSmiShift); } void MacroAssembler::SmiUntagToFloat(FPRegister dst, Register src, UntagMode mode) { DCHECK(dst.Is32Bits() && src.Is64Bits()); if (FLAG_enable_slow_asserts && (mode == kNotSpeculativeUntag)) { AssertSmi(src); } Scvtf(dst, src, kSmiShift); } void MacroAssembler::SmiTagAndPush(Register src) { STATIC_ASSERT((static_cast(kSmiShift) == kWRegSizeInBits) && (static_cast(kSmiValueSize) == kWRegSizeInBits) && (kSmiTag == 0)); Push(src.W(), wzr); } void MacroAssembler::SmiTagAndPush(Register src1, Register src2) { STATIC_ASSERT((static_cast(kSmiShift) == kWRegSizeInBits) && (static_cast(kSmiValueSize) == kWRegSizeInBits) && (kSmiTag == 0)); Push(src1.W(), wzr, src2.W(), wzr); } void MacroAssembler::JumpIfSmi(Register value, Label* smi_label, Label* not_smi_label) { STATIC_ASSERT((kSmiTagSize == 1) && (kSmiTag == 0)); // Check if the tag bit is set. if (smi_label) { Tbz(value, 0, smi_label); if (not_smi_label) { B(not_smi_label); } } else { DCHECK(not_smi_label); Tbnz(value, 0, not_smi_label); } } void MacroAssembler::JumpIfNotSmi(Register value, Label* not_smi_label) { JumpIfSmi(value, NULL, not_smi_label); } void MacroAssembler::JumpIfBothSmi(Register value1, Register value2, Label* both_smi_label, Label* not_smi_label) { STATIC_ASSERT((kSmiTagSize == 1) && (kSmiTag == 0)); UseScratchRegisterScope temps(this); Register tmp = temps.AcquireX(); // Check if both tag bits are clear. Orr(tmp, value1, value2); JumpIfSmi(tmp, both_smi_label, not_smi_label); } void MacroAssembler::JumpIfEitherSmi(Register value1, Register value2, Label* either_smi_label, Label* not_smi_label) { STATIC_ASSERT((kSmiTagSize == 1) && (kSmiTag == 0)); UseScratchRegisterScope temps(this); Register tmp = temps.AcquireX(); // Check if either tag bit is clear. And(tmp, value1, value2); JumpIfSmi(tmp, either_smi_label, not_smi_label); } void MacroAssembler::JumpIfEitherNotSmi(Register value1, Register value2, Label* not_smi_label) { JumpIfBothSmi(value1, value2, NULL, not_smi_label); } void MacroAssembler::JumpIfBothNotSmi(Register value1, Register value2, Label* not_smi_label) { JumpIfEitherSmi(value1, value2, NULL, not_smi_label); } void MacroAssembler::ObjectTag(Register tagged_obj, Register obj) { STATIC_ASSERT(kHeapObjectTag == 1); if (emit_debug_code()) { Label ok; Tbz(obj, 0, &ok); Abort(kObjectTagged); Bind(&ok); } Orr(tagged_obj, obj, kHeapObjectTag); } void MacroAssembler::ObjectUntag(Register untagged_obj, Register obj) { STATIC_ASSERT(kHeapObjectTag == 1); if (emit_debug_code()) { Label ok; Tbnz(obj, 0, &ok); Abort(kObjectNotTagged); Bind(&ok); } Bic(untagged_obj, obj, kHeapObjectTag); } void MacroAssembler::IsObjectNameType(Register object, Register type, Label* fail) { CompareObjectType(object, type, type, LAST_NAME_TYPE); B(hi, fail); } void MacroAssembler::IsObjectJSObjectType(Register heap_object, Register map, Register scratch, Label* fail) { Ldr(map, FieldMemOperand(heap_object, HeapObject::kMapOffset)); IsInstanceJSObjectType(map, scratch, fail); } void MacroAssembler::IsInstanceJSObjectType(Register map, Register scratch, Label* fail) { Ldrb(scratch, FieldMemOperand(map, Map::kInstanceTypeOffset)); // If cmp result is lt, the following ccmp will clear all flags. // Z == 0, N == V implies gt condition. Cmp(scratch, FIRST_NONCALLABLE_SPEC_OBJECT_TYPE); Ccmp(scratch, LAST_NONCALLABLE_SPEC_OBJECT_TYPE, NoFlag, ge); // If we didn't get a valid label object just fall through and leave the // flags updated. if (fail != NULL) { B(gt, fail); } } void MacroAssembler::IsObjectJSStringType(Register object, Register type, Label* not_string, Label* string) { Ldr(type, FieldMemOperand(object, HeapObject::kMapOffset)); Ldrb(type.W(), FieldMemOperand(type, Map::kInstanceTypeOffset)); STATIC_ASSERT(kStringTag == 0); DCHECK((string != NULL) || (not_string != NULL)); if (string == NULL) { TestAndBranchIfAnySet(type.W(), kIsNotStringMask, not_string); } else if (not_string == NULL) { TestAndBranchIfAllClear(type.W(), kIsNotStringMask, string); } else { TestAndBranchIfAnySet(type.W(), kIsNotStringMask, not_string); B(string); } } void MacroAssembler::Push(Handle handle) { UseScratchRegisterScope temps(this); Register tmp = temps.AcquireX(); Mov(tmp, Operand(handle)); Push(tmp); } void MacroAssembler::Claim(uint64_t count, uint64_t unit_size) { uint64_t size = count * unit_size; if (size == 0) { return; } if (csp.Is(StackPointer())) { DCHECK(size % 16 == 0); } else { BumpSystemStackPointer(size); } Sub(StackPointer(), StackPointer(), size); } void MacroAssembler::Claim(const Register& count, uint64_t unit_size) { if (unit_size == 0) return; DCHECK(base::bits::IsPowerOfTwo64(unit_size)); const int shift = CountTrailingZeros(unit_size, kXRegSizeInBits); const Operand size(count, LSL, shift); if (size.IsZero()) { return; } if (!csp.Is(StackPointer())) { BumpSystemStackPointer(size); } Sub(StackPointer(), StackPointer(), size); } void MacroAssembler::ClaimBySMI(const Register& count_smi, uint64_t unit_size) { DCHECK(unit_size == 0 || base::bits::IsPowerOfTwo64(unit_size)); const int shift = CountTrailingZeros(unit_size, kXRegSizeInBits) - kSmiShift; const Operand size(count_smi, (shift >= 0) ? (LSL) : (LSR), (shift >= 0) ? (shift) : (-shift)); if (size.IsZero()) { return; } if (!csp.Is(StackPointer())) { BumpSystemStackPointer(size); } Sub(StackPointer(), StackPointer(), size); } void MacroAssembler::Drop(uint64_t count, uint64_t unit_size) { uint64_t size = count * unit_size; if (size == 0) { return; } Add(StackPointer(), StackPointer(), size); if (csp.Is(StackPointer())) { DCHECK(size % 16 == 0); } else if (emit_debug_code()) { // It is safe to leave csp where it is when unwinding the JavaScript stack, // but if we keep it matching StackPointer, the simulator can detect memory // accesses in the now-free part of the stack. SyncSystemStackPointer(); } } void MacroAssembler::Drop(const Register& count, uint64_t unit_size) { if (unit_size == 0) return; DCHECK(base::bits::IsPowerOfTwo64(unit_size)); const int shift = CountTrailingZeros(unit_size, kXRegSizeInBits); const Operand size(count, LSL, shift); if (size.IsZero()) { return; } Add(StackPointer(), StackPointer(), size); if (!csp.Is(StackPointer()) && emit_debug_code()) { // It is safe to leave csp where it is when unwinding the JavaScript stack, // but if we keep it matching StackPointer, the simulator can detect memory // accesses in the now-free part of the stack. SyncSystemStackPointer(); } } void MacroAssembler::DropBySMI(const Register& count_smi, uint64_t unit_size) { DCHECK(unit_size == 0 || base::bits::IsPowerOfTwo64(unit_size)); const int shift = CountTrailingZeros(unit_size, kXRegSizeInBits) - kSmiShift; const Operand size(count_smi, (shift >= 0) ? (LSL) : (LSR), (shift >= 0) ? (shift) : (-shift)); if (size.IsZero()) { return; } Add(StackPointer(), StackPointer(), size); if (!csp.Is(StackPointer()) && emit_debug_code()) { // It is safe to leave csp where it is when unwinding the JavaScript stack, // but if we keep it matching StackPointer, the simulator can detect memory // accesses in the now-free part of the stack. SyncSystemStackPointer(); } } void MacroAssembler::CompareAndBranch(const Register& lhs, const Operand& rhs, Condition cond, Label* label) { if (rhs.IsImmediate() && (rhs.ImmediateValue() == 0) && ((cond == eq) || (cond == ne))) { if (cond == eq) { Cbz(lhs, label); } else { Cbnz(lhs, label); } } else { Cmp(lhs, rhs); B(cond, label); } } void MacroAssembler::TestAndBranchIfAnySet(const Register& reg, const uint64_t bit_pattern, Label* label) { int bits = reg.SizeInBits(); DCHECK(CountSetBits(bit_pattern, bits) > 0); if (CountSetBits(bit_pattern, bits) == 1) { Tbnz(reg, MaskToBit(bit_pattern), label); } else { Tst(reg, bit_pattern); B(ne, label); } } void MacroAssembler::TestAndBranchIfAllClear(const Register& reg, const uint64_t bit_pattern, Label* label) { int bits = reg.SizeInBits(); DCHECK(CountSetBits(bit_pattern, bits) > 0); if (CountSetBits(bit_pattern, bits) == 1) { Tbz(reg, MaskToBit(bit_pattern), label); } else { Tst(reg, bit_pattern); B(eq, label); } } void MacroAssembler::InlineData(uint64_t data) { DCHECK(is_uint16(data)); InstructionAccurateScope scope(this, 1); movz(xzr, data); } void MacroAssembler::EnableInstrumentation() { InstructionAccurateScope scope(this, 1); movn(xzr, InstrumentStateEnable); } void MacroAssembler::DisableInstrumentation() { InstructionAccurateScope scope(this, 1); movn(xzr, InstrumentStateDisable); } void MacroAssembler::AnnotateInstrumentation(const char* marker_name) { DCHECK(strlen(marker_name) == 2); // We allow only printable characters in the marker names. Unprintable // characters are reserved for controlling features of the instrumentation. DCHECK(isprint(marker_name[0]) && isprint(marker_name[1])); InstructionAccurateScope scope(this, 1); movn(xzr, (marker_name[1] << 8) | marker_name[0]); } } } // namespace v8::internal #endif // V8_ARM64_MACRO_ASSEMBLER_ARM64_INL_H_