Source code
Revision control
Copy as Markdown
Other Tools
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
#include "jit/arm/MacroAssembler-arm.h"
#include "mozilla/Casting.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/MathAlgorithms.h"
#include "mozilla/Maybe.h"
#include "jsmath.h"
#include "jit/arm/Simulator-arm.h"
#include "jit/AtomicOp.h"
#include "jit/AtomicOperations.h"
#include "jit/Bailouts.h"
#include "jit/BaselineFrame.h"
#include "jit/JitFrames.h"
#include "jit/JitRuntime.h"
#include "jit/MacroAssembler.h"
#include "jit/MoveEmitter.h"
#include "js/ScalarType.h" // js::Scalar::Type
#include "util/Memory.h"
#include "vm/BigIntType.h"
#include "vm/JitActivation.h" // js::jit::JitActivation
#include "vm/JSContext.h"
#include "vm/StringType.h"
#include "jit/MacroAssembler-inl.h"
using namespace js;
using namespace jit;
using mozilla::Abs;
using mozilla::BitwiseCast;
using mozilla::DebugOnly;
using mozilla::IsPositiveZero;
using mozilla::Maybe;
bool isValueDTRDCandidate(ValueOperand& val) {
// In order to be used for a DTRD memory function, the two target registers
// need to be a) Adjacent, with the tag larger than the payload, and b)
// Aligned to a multiple of two.
if ((val.typeReg().code() != (val.payloadReg().code() + 1))) {
return false;
}
if ((val.payloadReg().code() & 1) != 0) {
return false;
}
return true;
}
void MacroAssemblerARM::convertBoolToInt32(Register source, Register dest) {
// Note that C++ bool is only 1 byte, so zero extend it to clear the
// higher-order bits.
as_and(dest, source, Imm8(0xff));
}
void MacroAssemblerARM::convertInt32ToDouble(Register src,
FloatRegister dest_) {
// Direct conversions aren't possible.
VFPRegister dest = VFPRegister(dest_);
as_vxfer(src, InvalidReg, dest.sintOverlay(), CoreToFloat);
as_vcvt(dest, dest.sintOverlay());
}
void MacroAssemblerARM::convertInt32ToDouble(const Address& src,
FloatRegister dest) {
ScratchDoubleScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_vldr(src, scratch, scratch2);
as_vcvt(dest, VFPRegister(scratch).sintOverlay());
}
void MacroAssemblerARM::convertInt32ToDouble(const BaseIndex& src,
FloatRegister dest) {
Register base = src.base;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
if (src.offset != 0) {
ma_add(base, Imm32(src.offset), scratch, scratch2);
base = scratch;
}
ma_ldr(DTRAddr(base, DtrRegImmShift(src.index, LSL, scale)), scratch);
convertInt32ToDouble(scratch, dest);
}
void MacroAssemblerARM::convertUInt32ToDouble(Register src,
FloatRegister dest_) {
// Direct conversions aren't possible.
VFPRegister dest = VFPRegister(dest_);
as_vxfer(src, InvalidReg, dest.uintOverlay(), CoreToFloat);
as_vcvt(dest, dest.uintOverlay());
}
static const double TO_DOUBLE_HIGH_SCALE = 0x100000000;
void MacroAssemblerARM::convertUInt32ToFloat32(Register src,
FloatRegister dest_) {
// Direct conversions aren't possible.
VFPRegister dest = VFPRegister(dest_);
as_vxfer(src, InvalidReg, dest.uintOverlay(), CoreToFloat);
as_vcvt(VFPRegister(dest).singleOverlay(), dest.uintOverlay());
}
void MacroAssemblerARM::convertDoubleToFloat32(FloatRegister src,
FloatRegister dest,
Condition c) {
as_vcvt(VFPRegister(dest).singleOverlay(), VFPRegister(src), false, c);
}
// Checks whether a double is representable as a 32-bit integer. If so, the
// integer is written to the output register. Otherwise, a bailout is taken to
// the given snapshot. This function overwrites the scratch float register.
void MacroAssemblerARM::convertDoubleToInt32(FloatRegister src, Register dest,
Label* fail,
bool negativeZeroCheck) {
// Convert the floating point value to an integer, if it did not fit, then
// when we convert it *back* to a float, it will have a different value,
// which we can test.
ScratchDoubleScope scratchDouble(asMasm());
ScratchRegisterScope scratch(asMasm());
FloatRegister scratchSIntReg = scratchDouble.sintOverlay();
ma_vcvt_F64_I32(src, scratchSIntReg);
// Move the value into the dest register.
ma_vxfer(scratchSIntReg, dest);
ma_vcvt_I32_F64(scratchSIntReg, scratchDouble);
ma_vcmp(src, scratchDouble);
as_vmrs(pc);
ma_b(fail, Assembler::VFP_NotEqualOrUnordered);
if (negativeZeroCheck) {
as_cmp(dest, Imm8(0));
// Test and bail for -0.0, when integer result is 0. Move the top word
// of the double into the output reg, if it is non-zero, then the
// original value was -0.0.
as_vxfer(dest, InvalidReg, src, FloatToCore, Assembler::Equal, 1);
ma_cmp(dest, Imm32(0x80000000), scratch, Assembler::Equal);
ma_b(fail, Assembler::Equal);
}
}
// Checks whether a float32 is representable as a 32-bit integer. If so, the
// integer is written to the output register. Otherwise, a bailout is taken to
// the given snapshot. This function overwrites the scratch float register.
void MacroAssemblerARM::convertFloat32ToInt32(FloatRegister src, Register dest,
Label* fail,
bool negativeZeroCheck) {
// Converting the floating point value to an integer and then converting it
// back to a float32 would not work, as float to int32 conversions are
// clamping (e.g. float(INT32_MAX + 1) would get converted into INT32_MAX
// and then back to float(INT32_MAX + 1)). If this ever happens, we just
// bail out.
ScratchFloat32Scope scratchFloat(asMasm());
ScratchRegisterScope scratch(asMasm());
FloatRegister ScratchSIntReg = scratchFloat.sintOverlay();
ma_vcvt_F32_I32(src, ScratchSIntReg);
// Store the result
ma_vxfer(ScratchSIntReg, dest);
ma_vcvt_I32_F32(ScratchSIntReg, scratchFloat);
ma_vcmp(src, scratchFloat);
as_vmrs(pc);
ma_b(fail, Assembler::VFP_NotEqualOrUnordered);
// Bail out in the clamped cases.
ma_cmp(dest, Imm32(0x7fffffff), scratch);
ma_cmp(dest, Imm32(0x80000000), scratch, Assembler::NotEqual);
ma_b(fail, Assembler::Equal);
if (negativeZeroCheck) {
as_cmp(dest, Imm8(0));
// Test and bail for -0.0, when integer result is 0. Move the float into
// the output reg, and if it is non-zero then the original value was
// -0.0
as_vxfer(dest, InvalidReg, VFPRegister(src).singleOverlay(), FloatToCore,
Assembler::Equal, 0);
ma_cmp(dest, Imm32(0x80000000), scratch, Assembler::Equal);
ma_b(fail, Assembler::Equal);
}
}
void MacroAssemblerARM::convertFloat32ToDouble(FloatRegister src,
FloatRegister dest) {
MOZ_ASSERT(dest.isDouble());
MOZ_ASSERT(src.isSingle());
as_vcvt(VFPRegister(dest), VFPRegister(src).singleOverlay());
}
void MacroAssemblerARM::convertInt32ToFloat32(Register src,
FloatRegister dest) {
// Direct conversions aren't possible.
as_vxfer(src, InvalidReg, dest.sintOverlay(), CoreToFloat);
as_vcvt(dest.singleOverlay(), dest.sintOverlay());
}
void MacroAssemblerARM::convertInt32ToFloat32(const Address& src,
FloatRegister dest) {
ScratchFloat32Scope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_vldr(src, scratch, scratch2);
as_vcvt(dest, VFPRegister(scratch).sintOverlay());
}
bool MacroAssemblerARM::alu_dbl(Register src1, Imm32 imm, Register dest,
ALUOp op, SBit s, Condition c) {
if ((s == SetCC && !condsAreSafe(op)) || !can_dbl(op)) {
return false;
}
ALUOp interop = getDestVariant(op);
Imm8::TwoImm8mData both = Imm8::EncodeTwoImms(imm.value);
if (both.fst().invalid()) {
return false;
}
// For the most part, there is no good reason to set the condition codes for
// the first instruction. We can do better things if the second instruction
// doesn't have a dest, such as check for overflow by doing first operation
// don't do second operation if first operation overflowed. This preserves
// the overflow condition code. Unfortunately, it is horribly brittle.
as_alu(dest, src1, Operand2(both.fst()), interop, LeaveCC, c);
as_alu(dest, dest, Operand2(both.snd()), op, s, c);
return true;
}
void MacroAssemblerARM::ma_alu(Register src1, Imm32 imm, Register dest,
AutoRegisterScope& scratch, ALUOp op, SBit s,
Condition c) {
// ma_mov should be used for moves.
MOZ_ASSERT(op != OpMov);
MOZ_ASSERT(op != OpMvn);
MOZ_ASSERT(src1 != scratch);
// As it turns out, if you ask for a compare-like instruction you *probably*
// want it to set condition codes.
MOZ_ASSERT_IF(dest == InvalidReg, s == SetCC);
// The operator gives us the ability to determine how this can be used.
Imm8 imm8 = Imm8(imm.value);
// One instruction: If we can encode it using an imm8m, then do so.
if (!imm8.invalid()) {
as_alu(dest, src1, imm8, op, s, c);
return;
}
// One instruction, negated:
Imm32 negImm = imm;
Register negDest;
ALUOp negOp = ALUNeg(op, dest, scratch, &negImm, &negDest);
Imm8 negImm8 = Imm8(negImm.value);
// 'add r1, r2, -15' can be replaced with 'sub r1, r2, 15'.
// The dest can be replaced (InvalidReg => scratch).
// This is useful if we wish to negate tst. tst has an invalid (aka not
// used) dest, but its negation bic requires a dest.
if (negOp != OpInvalid && !negImm8.invalid()) {
as_alu(negDest, src1, negImm8, negOp, s, c);
return;
}
// Start by attempting to generate a two instruction form. Some things
// cannot be made into two-inst forms correctly. Namely, adds dest, src,
// 0xffff. Since we want the condition codes (and don't know which ones
// will be checked), we need to assume that the overflow flag will be
// checked and add{,s} dest, src, 0xff00; add{,s} dest, dest, 0xff is not
// guaranteed to set the overflof flag the same as the (theoretical) one
// instruction variant.
if (alu_dbl(src1, imm, dest, op, s, c)) {
return;
}
// And try with its negative.
if (negOp != OpInvalid && alu_dbl(src1, negImm, negDest, negOp, s, c)) {
return;
}
ma_mov(imm, scratch, c);
as_alu(dest, src1, O2Reg(scratch), op, s, c);
}
void MacroAssemblerARM::ma_alu(Register src1, Operand op2, Register dest,
ALUOp op, SBit s, Assembler::Condition c) {
MOZ_ASSERT(op2.tag() == Operand::Tag::OP2);
as_alu(dest, src1, op2.toOp2(), op, s, c);
}
void MacroAssemblerARM::ma_alu(Register src1, Operand2 op2, Register dest,
ALUOp op, SBit s, Condition c) {
as_alu(dest, src1, op2, op, s, c);
}
void MacroAssemblerARM::ma_nop() { as_nop(); }
BufferOffset MacroAssemblerARM::ma_movPatchable(Imm32 imm_, Register dest,
Assembler::Condition c) {
int32_t imm = imm_.value;
if (HasMOVWT()) {
BufferOffset offset = as_movw(dest, Imm16(imm & 0xffff), c);
as_movt(dest, Imm16(imm >> 16 & 0xffff), c);
return offset;
} else {
return as_Imm32Pool(dest, imm, c);
}
}
BufferOffset MacroAssemblerARM::ma_movPatchable(ImmPtr imm, Register dest,
Assembler::Condition c) {
return ma_movPatchable(Imm32(int32_t(imm.value)), dest, c);
}
/* static */
template <class Iter>
void MacroAssemblerARM::ma_mov_patch(Imm32 imm32, Register dest,
Assembler::Condition c, RelocStyle rs,
Iter iter) {
// The current instruction must be an actual instruction,
// not automatically-inserted boilerplate.
MOZ_ASSERT(iter.cur());
MOZ_ASSERT(iter.cur() == iter.maybeSkipAutomaticInstructions());
int32_t imm = imm32.value;
switch (rs) {
case L_MOVWT:
Assembler::as_movw_patch(dest, Imm16(imm & 0xffff), c, iter.cur());
Assembler::as_movt_patch(dest, Imm16(imm >> 16 & 0xffff), c, iter.next());
break;
case L_LDR:
Assembler::WritePoolEntry(iter.cur(), c, imm);
break;
}
}
template void MacroAssemblerARM::ma_mov_patch(Imm32 imm32, Register dest,
Assembler::Condition c,
RelocStyle rs,
InstructionIterator iter);
template void MacroAssemblerARM::ma_mov_patch(Imm32 imm32, Register dest,
Assembler::Condition c,
RelocStyle rs,
BufferInstructionIterator iter);
void MacroAssemblerARM::ma_mov(Register src, Register dest, SBit s,
Assembler::Condition c) {
if (s == SetCC || dest != src) {
as_mov(dest, O2Reg(src), s, c);
}
}
void MacroAssemblerARM::ma_mov(Imm32 imm, Register dest,
Assembler::Condition c) {
// Try mov with Imm8 operand.
Imm8 imm8 = Imm8(imm.value);
if (!imm8.invalid()) {
as_alu(dest, InvalidReg, imm8, OpMov, LeaveCC, c);
return;
}
// Try mvn with Imm8 operand.
Imm8 negImm8 = Imm8(~imm.value);
if (!negImm8.invalid()) {
as_alu(dest, InvalidReg, negImm8, OpMvn, LeaveCC, c);
return;
}
// Try movw/movt.
if (HasMOVWT()) {
// ARMv7 supports movw/movt. movw zero-extends its 16 bit argument,
// so we can set the register this way. movt leaves the bottom 16
// bits in tact, so we always need a movw.
as_movw(dest, Imm16(imm.value & 0xffff), c);
if (uint32_t(imm.value) >> 16) {
as_movt(dest, Imm16(uint32_t(imm.value) >> 16), c);
}
return;
}
// If we don't have movw/movt, we need a load.
as_Imm32Pool(dest, imm.value, c);
}
void MacroAssemblerARM::ma_mov(ImmWord imm, Register dest,
Assembler::Condition c) {
ma_mov(Imm32(imm.value), dest, c);
}
void MacroAssemblerARM::ma_mov(ImmGCPtr ptr, Register dest) {
BufferOffset offset =
ma_movPatchable(Imm32(uintptr_t(ptr.value)), dest, Always);
writeDataRelocation(offset, ptr);
}
// Shifts (just a move with a shifting op2)
void MacroAssemblerARM::ma_lsl(Imm32 shift, Register src, Register dst) {
as_mov(dst, lsl(src, shift.value));
}
void MacroAssemblerARM::ma_lsr(Imm32 shift, Register src, Register dst) {
as_mov(dst, lsr(src, shift.value));
}
void MacroAssemblerARM::ma_asr(Imm32 shift, Register src, Register dst) {
as_mov(dst, asr(src, shift.value));
}
void MacroAssemblerARM::ma_ror(Imm32 shift, Register src, Register dst) {
as_mov(dst, ror(src, shift.value));
}
void MacroAssemblerARM::ma_rol(Imm32 shift, Register src, Register dst) {
as_mov(dst, rol(src, shift.value));
}
// Shifts (just a move with a shifting op2)
void MacroAssemblerARM::ma_lsl(Register shift, Register src, Register dst) {
as_mov(dst, lsl(src, shift));
}
void MacroAssemblerARM::ma_lsr(Register shift, Register src, Register dst) {
as_mov(dst, lsr(src, shift));
}
void MacroAssemblerARM::ma_asr(Register shift, Register src, Register dst) {
as_mov(dst, asr(src, shift));
}
void MacroAssemblerARM::ma_ror(Register shift, Register src, Register dst) {
as_mov(dst, ror(src, shift));
}
void MacroAssemblerARM::ma_rol(Register shift, Register src, Register dst,
AutoRegisterScope& scratch) {
as_rsb(scratch, shift, Imm8(32));
as_mov(dst, ror(src, scratch));
}
// Move not (dest <- ~src)
void MacroAssemblerARM::ma_mvn(Register src1, Register dest, SBit s,
Assembler::Condition c) {
as_alu(dest, InvalidReg, O2Reg(src1), OpMvn, s, c);
}
// Negate (dest <- -src), src is a register, rather than a general op2.
void MacroAssemblerARM::ma_neg(Register src1, Register dest, SBit s,
Assembler::Condition c) {
as_rsb(dest, src1, Imm8(0), s, c);
}
void MacroAssemblerARM::ma_neg(Register64 src, Register64 dest) {
as_rsb(dest.low, src.low, Imm8(0), SetCC);
as_rsc(dest.high, src.high, Imm8(0));
}
// And.
void MacroAssemblerARM::ma_and(Register src, Register dest, SBit s,
Assembler::Condition c) {
ma_and(dest, src, dest);
}
void MacroAssemblerARM::ma_and(Register src1, Register src2, Register dest,
SBit s, Assembler::Condition c) {
as_and(dest, src1, O2Reg(src2), s, c);
}
void MacroAssemblerARM::ma_and(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(dest, imm, dest, scratch, OpAnd, s, c);
}
void MacroAssemblerARM::ma_and(Imm32 imm, Register src1, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(src1, imm, dest, scratch, OpAnd, s, c);
}
// Bit clear (dest <- dest & ~imm) or (dest <- src1 & ~src2).
void MacroAssemblerARM::ma_bic(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(dest, imm, dest, scratch, OpBic, s, c);
}
// Exclusive or.
void MacroAssemblerARM::ma_eor(Register src, Register dest, SBit s,
Assembler::Condition c) {
ma_eor(dest, src, dest, s, c);
}
void MacroAssemblerARM::ma_eor(Register src1, Register src2, Register dest,
SBit s, Assembler::Condition c) {
as_eor(dest, src1, O2Reg(src2), s, c);
}
void MacroAssemblerARM::ma_eor(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(dest, imm, dest, scratch, OpEor, s, c);
}
void MacroAssemblerARM::ma_eor(Imm32 imm, Register src1, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(src1, imm, dest, scratch, OpEor, s, c);
}
// Or.
void MacroAssemblerARM::ma_orr(Register src, Register dest, SBit s,
Assembler::Condition c) {
ma_orr(dest, src, dest, s, c);
}
void MacroAssemblerARM::ma_orr(Register src1, Register src2, Register dest,
SBit s, Assembler::Condition c) {
as_orr(dest, src1, O2Reg(src2), s, c);
}
void MacroAssemblerARM::ma_orr(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(dest, imm, dest, scratch, OpOrr, s, c);
}
void MacroAssemblerARM::ma_orr(Imm32 imm, Register src1, Register dest,
AutoRegisterScope& scratch, SBit s,
Assembler::Condition c) {
ma_alu(src1, imm, dest, scratch, OpOrr, s, c);
}
// Arithmetic-based ops.
// Add with carry.
void MacroAssemblerARM::ma_adc(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(dest, imm, dest, scratch, OpAdc, s, c);
}
void MacroAssemblerARM::ma_adc(Register src, Register dest, SBit s,
Condition c) {
as_alu(dest, dest, O2Reg(src), OpAdc, s, c);
}
void MacroAssemblerARM::ma_adc(Register src1, Register src2, Register dest,
SBit s, Condition c) {
as_alu(dest, src1, O2Reg(src2), OpAdc, s, c);
}
void MacroAssemblerARM::ma_adc(Register src1, Imm32 op, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(src1, op, dest, scratch, OpAdc, s, c);
}
// Add.
void MacroAssemblerARM::ma_add(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(dest, imm, dest, scratch, OpAdd, s, c);
}
void MacroAssemblerARM::ma_add(Register src1, Register dest, SBit s,
Condition c) {
ma_alu(dest, O2Reg(src1), dest, OpAdd, s, c);
}
void MacroAssemblerARM::ma_add(Register src1, Register src2, Register dest,
SBit s, Condition c) {
as_alu(dest, src1, O2Reg(src2), OpAdd, s, c);
}
void MacroAssemblerARM::ma_add(Register src1, Operand op, Register dest, SBit s,
Condition c) {
ma_alu(src1, op, dest, OpAdd, s, c);
}
void MacroAssemblerARM::ma_add(Register src1, Imm32 op, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(src1, op, dest, scratch, OpAdd, s, c);
}
// Subtract with carry.
void MacroAssemblerARM::ma_sbc(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(dest, imm, dest, scratch, OpSbc, s, c);
}
void MacroAssemblerARM::ma_sbc(Register src1, Register dest, SBit s,
Condition c) {
as_alu(dest, dest, O2Reg(src1), OpSbc, s, c);
}
void MacroAssemblerARM::ma_sbc(Register src1, Register src2, Register dest,
SBit s, Condition c) {
as_alu(dest, src1, O2Reg(src2), OpSbc, s, c);
}
// Subtract.
void MacroAssemblerARM::ma_sub(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(dest, imm, dest, scratch, OpSub, s, c);
}
void MacroAssemblerARM::ma_sub(Register src1, Register dest, SBit s,
Condition c) {
ma_alu(dest, Operand(src1), dest, OpSub, s, c);
}
void MacroAssemblerARM::ma_sub(Register src1, Register src2, Register dest,
SBit s, Condition c) {
ma_alu(src1, Operand(src2), dest, OpSub, s, c);
}
void MacroAssemblerARM::ma_sub(Register src1, Operand op, Register dest, SBit s,
Condition c) {
ma_alu(src1, op, dest, OpSub, s, c);
}
void MacroAssemblerARM::ma_sub(Register src1, Imm32 op, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(src1, op, dest, scratch, OpSub, s, c);
}
// Reverse subtract.
void MacroAssemblerARM::ma_rsb(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(dest, imm, dest, scratch, OpRsb, s, c);
}
void MacroAssemblerARM::ma_rsb(Register src1, Register dest, SBit s,
Condition c) {
as_alu(dest, src1, O2Reg(dest), OpRsb, s, c);
}
void MacroAssemblerARM::ma_rsb(Register src1, Register src2, Register dest,
SBit s, Condition c) {
as_alu(dest, src1, O2Reg(src2), OpRsb, s, c);
}
void MacroAssemblerARM::ma_rsb(Register src1, Imm32 op2, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(src1, op2, dest, scratch, OpRsb, s, c);
}
// Reverse subtract with carry.
void MacroAssemblerARM::ma_rsc(Imm32 imm, Register dest,
AutoRegisterScope& scratch, SBit s,
Condition c) {
ma_alu(dest, imm, dest, scratch, OpRsc, s, c);
}
void MacroAssemblerARM::ma_rsc(Register src1, Register dest, SBit s,
Condition c) {
as_alu(dest, dest, O2Reg(src1), OpRsc, s, c);
}
void MacroAssemblerARM::ma_rsc(Register src1, Register src2, Register dest,
SBit s, Condition c) {
as_alu(dest, src1, O2Reg(src2), OpRsc, s, c);
}
// Compares/tests.
// Compare negative (sets condition codes as src1 + src2 would).
void MacroAssemblerARM::ma_cmn(Register src1, Imm32 imm,
AutoRegisterScope& scratch, Condition c) {
ma_alu(src1, imm, InvalidReg, scratch, OpCmn, SetCC, c);
}
void MacroAssemblerARM::ma_cmn(Register src1, Register src2, Condition c) {
as_alu(InvalidReg, src2, O2Reg(src1), OpCmn, SetCC, c);
}
void MacroAssemblerARM::ma_cmn(Register src1, Operand op, Condition c) {
MOZ_CRASH("Feature NYI");
}
// Compare (src - src2).
void MacroAssemblerARM::ma_cmp(Register src1, Imm32 imm,
AutoRegisterScope& scratch, Condition c) {
ma_alu(src1, imm, InvalidReg, scratch, OpCmp, SetCC, c);
}
void MacroAssemblerARM::ma_cmp(Register src1, ImmTag tag, Condition c) {
// ImmTag comparisons can always be done without use of a scratch register.
Imm8 negtag = Imm8(-tag.value);
MOZ_ASSERT(!negtag.invalid());
as_cmn(src1, negtag, c);
}
void MacroAssemblerARM::ma_cmp(Register src1, ImmWord ptr,
AutoRegisterScope& scratch, Condition c) {
ma_cmp(src1, Imm32(ptr.value), scratch, c);
}
void MacroAssemblerARM::ma_cmp(Register src1, ImmGCPtr ptr,
AutoRegisterScope& scratch, Condition c) {
ma_mov(ptr, scratch);
ma_cmp(src1, scratch, c);
}
void MacroAssemblerARM::ma_cmp(Register src1, Operand op,
AutoRegisterScope& scratch,
AutoRegisterScope& scratch2, Condition c) {
switch (op.tag()) {
case Operand::Tag::OP2:
as_cmp(src1, op.toOp2(), c);
break;
case Operand::Tag::MEM:
ma_ldr(op.toAddress(), scratch, scratch2);
as_cmp(src1, O2Reg(scratch), c);
break;
default:
MOZ_CRASH("trying to compare FP and integer registers");
}
}
void MacroAssemblerARM::ma_cmp(Register src1, Register src2, Condition c) {
as_cmp(src1, O2Reg(src2), c);
}
// Test for equality, (src1 ^ src2).
void MacroAssemblerARM::ma_teq(Register src1, Imm32 imm,
AutoRegisterScope& scratch, Condition c) {
ma_alu(src1, imm, InvalidReg, scratch, OpTeq, SetCC, c);
}
void MacroAssemblerARM::ma_teq(Register src1, Register src2, Condition c) {
as_tst(src1, O2Reg(src2), c);
}
void MacroAssemblerARM::ma_teq(Register src1, Operand op, Condition c) {
as_teq(src1, op.toOp2(), c);
}
// Test (src1 & src2).
void MacroAssemblerARM::ma_tst(Register src1, Imm32 imm,
AutoRegisterScope& scratch, Condition c) {
ma_alu(src1, imm, InvalidReg, scratch, OpTst, SetCC, c);
}
void MacroAssemblerARM::ma_tst(Register src1, Register src2, Condition c) {
as_tst(src1, O2Reg(src2), c);
}
void MacroAssemblerARM::ma_tst(Register src1, Operand op, Condition c) {
as_tst(src1, op.toOp2(), c);
}
void MacroAssemblerARM::ma_mul(Register src1, Register src2, Register dest) {
as_mul(dest, src1, src2);
}
void MacroAssemblerARM::ma_mul(Register src1, Imm32 imm, Register dest,
AutoRegisterScope& scratch) {
ma_mov(imm, scratch);
as_mul(dest, src1, scratch);
}
Assembler::Condition MacroAssemblerARM::ma_check_mul(Register src1,
Register src2,
Register dest,
AutoRegisterScope& scratch,
Condition cond) {
// TODO: this operation is illegal on armv6 and earlier
// if src2 == scratch or src2 == dest.
if (cond == Equal || cond == NotEqual) {
as_smull(scratch, dest, src1, src2, SetCC);
return cond;
}
if (cond == Overflow) {
as_smull(scratch, dest, src1, src2);
as_cmp(scratch, asr(dest, 31));
return NotEqual;
}
MOZ_CRASH("Condition NYI");
}
Assembler::Condition MacroAssemblerARM::ma_check_mul(Register src1, Imm32 imm,
Register dest,
AutoRegisterScope& scratch,
Condition cond) {
ma_mov(imm, scratch);
if (cond == Equal || cond == NotEqual) {
as_smull(scratch, dest, scratch, src1, SetCC);
return cond;
}
if (cond == Overflow) {
as_smull(scratch, dest, scratch, src1);
as_cmp(scratch, asr(dest, 31));
return NotEqual;
}
MOZ_CRASH("Condition NYI");
}
void MacroAssemblerARM::ma_umull(Register src1, Imm32 imm, Register destHigh,
Register destLow, AutoRegisterScope& scratch) {
ma_mov(imm, scratch);
as_umull(destHigh, destLow, src1, scratch);
}
void MacroAssemblerARM::ma_umull(Register src1, Register src2,
Register destHigh, Register destLow) {
as_umull(destHigh, destLow, src1, src2);
}
void MacroAssemblerARM::ma_mod_mask(Register src, Register dest, Register hold,
Register tmp, AutoRegisterScope& scratch,
AutoRegisterScope& scratch2,
int32_t shift) {
// We wish to compute x % (1<<y) - 1 for a known constant, y.
//
// 1. Let b = (1<<y) and C = (1<<y)-1, then think of the 32 bit dividend as
// a number in base b, namely c_0*1 + c_1*b + c_2*b^2 ... c_n*b^n
//
// 2. Since both addition and multiplication commute with modulus:
// x % C == (c_0 + c_1*b + ... + c_n*b^n) % C ==
// (c_0 % C) + (c_1%C) * (b % C) + (c_2 % C) * (b^2 % C)...
//
// 3. Since b == C + 1, b % C == 1, and b^n % C == 1 the whole thing
// simplifies to: c_0 + c_1 + c_2 ... c_n % C
//
// Each c_n can easily be computed by a shift/bitextract, and the modulus
// can be maintained by simply subtracting by C whenever the number gets
// over C.
int32_t mask = (1 << shift) - 1;
Label head;
// Register 'hold' holds -1 if the value was negative, 1 otherwise. The
// scratch reg holds the remaining bits that have not been processed lr
// serves as a temporary location to store extracted bits into as well as
// holding the trial subtraction as a temp value dest is the accumulator
// (and holds the final result)
//
// Move the whole value into tmp, setting the codition codes so we can muck
// with them later.
as_mov(tmp, O2Reg(src), SetCC);
// Zero out the dest.
ma_mov(Imm32(0), dest);
// Set the hold appropriately.
ma_mov(Imm32(1), hold);
ma_mov(Imm32(-1), hold, Signed);
as_rsb(tmp, tmp, Imm8(0), SetCC, Signed);
// Begin the main loop.
bind(&head);
{
// Extract the bottom bits.
ma_and(Imm32(mask), tmp, scratch, scratch2);
// Add those bits to the accumulator.
ma_add(scratch, dest, dest);
// Do a trial subtraction, this is the same operation as cmp, but we store
// the dest.
ma_sub(dest, Imm32(mask), scratch, scratch2, SetCC);
// If (sum - C) > 0, store sum - C back into sum, thus performing a modulus.
ma_mov(scratch, dest, LeaveCC, NotSigned);
// Get rid of the bits that we extracted before, and set the condition
// codes.
as_mov(tmp, lsr(tmp, shift), SetCC);
// If the shift produced zero, finish, otherwise, continue in the loop.
ma_b(&head, NonZero);
}
// Check the hold to see if we need to negate the result. Hold can only be
// 1 or -1, so this will never set the 0 flag.
as_cmp(hold, Imm8(0));
// If the hold was non-zero, negate the result to be in line with what JS
// wants this will set the condition codes if we try to negate.
as_rsb(dest, dest, Imm8(0), SetCC, Signed);
// Since the Zero flag is not set by the compare, we can *only* set the Zero
// flag in the rsb, so Zero is set iff we negated zero (e.g. the result of
// the computation was -0.0).
}
void MacroAssemblerARM::ma_smod(Register num, Register div, Register dest,
AutoRegisterScope& scratch) {
as_sdiv(scratch, num, div);
as_mls(dest, num, scratch, div);
}
void MacroAssemblerARM::ma_umod(Register num, Register div, Register dest,
AutoRegisterScope& scratch) {
as_udiv(scratch, num, div);
as_mls(dest, num, scratch, div);
}
// Division
void MacroAssemblerARM::ma_sdiv(Register num, Register div, Register dest,
Condition cond) {
as_sdiv(dest, num, div, cond);
}
void MacroAssemblerARM::ma_udiv(Register num, Register div, Register dest,
Condition cond) {
as_udiv(dest, num, div, cond);
}
// Miscellaneous instructions.
void MacroAssemblerARM::ma_clz(Register src, Register dest, Condition cond) {
as_clz(dest, src, cond);
}
void MacroAssemblerARM::ma_ctz(Register src, Register dest,
AutoRegisterScope& scratch) {
// int c = __clz(a & -a);
// return a ? 31 - c : c;
as_rsb(scratch, src, Imm8(0), SetCC);
as_and(dest, src, O2Reg(scratch), LeaveCC);
as_clz(dest, dest);
as_rsb(dest, dest, Imm8(0x1F), LeaveCC, Assembler::NotEqual);
}
// Memory.
// Shortcut for when we know we're transferring 32 bits of data.
void MacroAssemblerARM::ma_dtr(LoadStore ls, Register rn, Imm32 offset,
Register rt, AutoRegisterScope& scratch,
Index mode, Assembler::Condition cc) {
ma_dataTransferN(ls, 32, true, rn, offset, rt, scratch, mode, cc);
}
FaultingCodeOffset MacroAssemblerARM::ma_dtr(LoadStore ls, Register rt,
const Address& addr,
AutoRegisterScope& scratch,
Index mode, Condition cc) {
BufferOffset offset = ma_dataTransferN(
ls, 32, true, addr.base, Imm32(addr.offset), rt, scratch, mode, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_str(Register rt, DTRAddr addr,
Index mode, Condition cc) {
BufferOffset offset = as_dtr(IsStore, 32, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_str(Register rt, const Address& addr,
AutoRegisterScope& scratch,
Index mode, Condition cc) {
return ma_dtr(IsStore, rt, addr, scratch, mode, cc);
}
void MacroAssemblerARM::ma_strd(Register rt, DebugOnly<Register> rt2,
EDtrAddr addr, Index mode, Condition cc) {
MOZ_ASSERT((rt.code() & 1) == 0);
MOZ_ASSERT(rt2.value.code() == rt.code() + 1);
as_extdtr(IsStore, 64, true, mode, rt, addr, cc);
}
FaultingCodeOffset MacroAssemblerARM::ma_ldr(DTRAddr addr, Register rt,
Index mode, Condition cc) {
BufferOffset offset = as_dtr(IsLoad, 32, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_ldr(const Address& addr, Register rt,
AutoRegisterScope& scratch,
Index mode, Condition cc) {
return ma_dtr(IsLoad, rt, addr, scratch, mode, cc);
}
FaultingCodeOffset MacroAssemblerARM::ma_ldrb(DTRAddr addr, Register rt,
Index mode, Condition cc) {
BufferOffset offset = as_dtr(IsLoad, 8, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_ldrsh(EDtrAddr addr, Register rt,
Index mode, Condition cc) {
BufferOffset offset = as_extdtr(IsLoad, 16, true, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_ldrh(EDtrAddr addr, Register rt,
Index mode, Condition cc) {
BufferOffset offset = as_extdtr(IsLoad, 16, false, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_ldrsb(EDtrAddr addr, Register rt,
Index mode, Condition cc) {
BufferOffset offset = as_extdtr(IsLoad, 8, true, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
void MacroAssemblerARM::ma_ldrd(EDtrAddr addr, Register rt,
DebugOnly<Register> rt2, Index mode,
Condition cc) {
MOZ_ASSERT((rt.code() & 1) == 0);
MOZ_ASSERT(rt2.value.code() == rt.code() + 1);
MOZ_ASSERT(addr.maybeOffsetRegister() !=
rt); // Undefined behavior if rm == rt/rt2.
MOZ_ASSERT(addr.maybeOffsetRegister() != rt2);
as_extdtr(IsLoad, 64, true, mode, rt, addr, cc);
}
FaultingCodeOffset MacroAssemblerARM::ma_strh(Register rt, EDtrAddr addr,
Index mode, Condition cc) {
BufferOffset offset = as_extdtr(IsStore, 16, false, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARM::ma_strb(Register rt, DTRAddr addr,
Index mode, Condition cc) {
BufferOffset offset = as_dtr(IsStore, 8, mode, rt, addr, cc);
return FaultingCodeOffset(offset.getOffset());
}
// Specialty for moving N bits of data, where n == 8,16,32,64.
BufferOffset MacroAssemblerARM::ma_dataTransferN(
LoadStore ls, int size, bool IsSigned, Register rn, Register rm,
Register rt, AutoRegisterScope& scratch, Index mode,
Assembler::Condition cc, Scale scale) {
MOZ_ASSERT(size == 8 || size == 16 || size == 32 || size == 64);
if (size == 32 || (size == 8 && !IsSigned)) {
return as_dtr(ls, size, mode, rt,
DTRAddr(rn, DtrRegImmShift(rm, LSL, scale)), cc);
}
if (scale != TimesOne) {
ma_lsl(Imm32(scale), rm, scratch);
rm = scratch;
}
return as_extdtr(ls, size, IsSigned, mode, rt, EDtrAddr(rn, EDtrOffReg(rm)),
cc);
}
// No scratch register is required if scale is TimesOne.
BufferOffset MacroAssemblerARM::ma_dataTransferN(LoadStore ls, int size,
bool IsSigned, Register rn,
Register rm, Register rt,
Index mode,
Assembler::Condition cc) {
MOZ_ASSERT(size == 8 || size == 16 || size == 32 || size == 64);
if (size == 32 || (size == 8 && !IsSigned)) {
return as_dtr(ls, size, mode, rt,
DTRAddr(rn, DtrRegImmShift(rm, LSL, TimesOne)), cc);
}
return as_extdtr(ls, size, IsSigned, mode, rt, EDtrAddr(rn, EDtrOffReg(rm)),
cc);
}
BufferOffset MacroAssemblerARM::ma_dataTransferN(LoadStore ls, int size,
bool IsSigned, Register rn,
Imm32 offset, Register rt,
AutoRegisterScope& scratch,
Index mode,
Assembler::Condition cc) {
MOZ_ASSERT(!(ls == IsLoad && mode == PostIndex && rt == pc),
"Large-offset PostIndex loading into PC requires special logic: "
"see ma_popn_pc().");
int off = offset.value;
// We can encode this as a standard ldr.
if (size == 32 || (size == 8 && !IsSigned)) {
if (off < 4096 && off > -4096) {
// This encodes as a single instruction, Emulating mode's behavior
// in a multi-instruction sequence is not necessary.
return as_dtr(ls, size, mode, rt, DTRAddr(rn, DtrOffImm(off)), cc);
}
// We cannot encode this offset in a single ldr. For mode == index,
// try to encode it as |add scratch, base, imm; ldr dest, [scratch,
// +offset]|. This does not wark for mode == PreIndex or mode == PostIndex.
// PreIndex is simple, just do the add into the base register first,
// then do a PreIndex'ed load. PostIndexed loads can be tricky.
// Normally, doing the load with an index of 0, then doing an add would
// work, but if the destination is the PC, you don't get to execute the
// instruction after the branch, which will lead to the base register
// not being updated correctly. Explicitly handle this case, without
// doing anything fancy, then handle all of the other cases.
// mode == Offset
// add scratch, base, offset_hi
// ldr dest, [scratch, +offset_lo]
//
// mode == PreIndex
// add base, base, offset_hi
// ldr dest, [base, +offset_lo]!
int bottom = off & 0xfff;
int neg_bottom = 0x1000 - bottom;
MOZ_ASSERT(rn != scratch);
MOZ_ASSERT(mode != PostIndex);
// At this point, both off - bottom and off + neg_bottom will be
// reasonable-ish quantities.
//
// Note a neg_bottom of 0x1000 can not be encoded as an immediate
// negative offset in the instruction and this occurs when bottom is
// zero, so this case is guarded against below.
if (off < 0) {
Operand2 sub_off = Imm8(-(off - bottom)); // sub_off = bottom - off
if (!sub_off.invalid()) {
// - sub_off = off - bottom
as_sub(scratch, rn, sub_off, LeaveCC, cc);
return as_dtr(ls, size, Offset, rt, DTRAddr(scratch, DtrOffImm(bottom)),
cc);
}
// sub_off = -neg_bottom - off
sub_off = Imm8(-(off + neg_bottom));
if (!sub_off.invalid() && bottom != 0) {
// Guarded against by: bottom != 0
MOZ_ASSERT(neg_bottom < 0x1000);
// - sub_off = neg_bottom + off
as_sub(scratch, rn, sub_off, LeaveCC, cc);
return as_dtr(ls, size, Offset, rt,
DTRAddr(scratch, DtrOffImm(-neg_bottom)), cc);
}
} else {
// sub_off = off - bottom
Operand2 sub_off = Imm8(off - bottom);
if (!sub_off.invalid()) {
// sub_off = off - bottom
as_add(scratch, rn, sub_off, LeaveCC, cc);
return as_dtr(ls, size, Offset, rt, DTRAddr(scratch, DtrOffImm(bottom)),
cc);
}
// sub_off = neg_bottom + off
sub_off = Imm8(off + neg_bottom);
if (!sub_off.invalid() && bottom != 0) {
// Guarded against by: bottom != 0
MOZ_ASSERT(neg_bottom < 0x1000);
// sub_off = neg_bottom + off
as_add(scratch, rn, sub_off, LeaveCC, cc);
return as_dtr(ls, size, Offset, rt,
DTRAddr(scratch, DtrOffImm(-neg_bottom)), cc);
}
}
ma_mov(offset, scratch);
return as_dtr(ls, size, mode, rt,
DTRAddr(rn, DtrRegImmShift(scratch, LSL, 0)));
} else {
// Should attempt to use the extended load/store instructions.
if (off < 256 && off > -256) {
return as_extdtr(ls, size, IsSigned, mode, rt,
EDtrAddr(rn, EDtrOffImm(off)), cc);
}
// We cannot encode this offset in a single extldr. Try to encode it as
// an add scratch, base, imm; extldr dest, [scratch, +offset].
int bottom = off & 0xff;
int neg_bottom = 0x100 - bottom;
// At this point, both off - bottom and off + neg_bottom will be
// reasonable-ish quantities.
//
// Note a neg_bottom of 0x100 can not be encoded as an immediate
// negative offset in the instruction and this occurs when bottom is
// zero, so this case is guarded against below.
if (off < 0) {
// sub_off = bottom - off
Operand2 sub_off = Imm8(-(off - bottom));
if (!sub_off.invalid()) {
// - sub_off = off - bottom
as_sub(scratch, rn, sub_off, LeaveCC, cc);
return as_extdtr(ls, size, IsSigned, Offset, rt,
EDtrAddr(scratch, EDtrOffImm(bottom)), cc);
}
// sub_off = -neg_bottom - off
sub_off = Imm8(-(off + neg_bottom));
if (!sub_off.invalid() && bottom != 0) {
// Guarded against by: bottom != 0
MOZ_ASSERT(neg_bottom < 0x100);
// - sub_off = neg_bottom + off
as_sub(scratch, rn, sub_off, LeaveCC, cc);
return as_extdtr(ls, size, IsSigned, Offset, rt,
EDtrAddr(scratch, EDtrOffImm(-neg_bottom)), cc);
}
} else {
// sub_off = off - bottom
Operand2 sub_off = Imm8(off - bottom);
if (!sub_off.invalid()) {
// sub_off = off - bottom
as_add(scratch, rn, sub_off, LeaveCC, cc);
return as_extdtr(ls, size, IsSigned, Offset, rt,
EDtrAddr(scratch, EDtrOffImm(bottom)), cc);
}
// sub_off = neg_bottom + off
sub_off = Imm8(off + neg_bottom);
if (!sub_off.invalid() && bottom != 0) {
// Guarded against by: bottom != 0
MOZ_ASSERT(neg_bottom < 0x100);
// sub_off = neg_bottom + off
as_add(scratch, rn, sub_off, LeaveCC, cc);
return as_extdtr(ls, size, IsSigned, Offset, rt,
EDtrAddr(scratch, EDtrOffImm(-neg_bottom)), cc);
}
}
ma_mov(offset, scratch);
return as_extdtr(ls, size, IsSigned, mode, rt,
EDtrAddr(rn, EDtrOffReg(scratch)), cc);
}
}
void MacroAssemblerARM::ma_pop(Register r) {
as_dtr(IsLoad, 32, PostIndex, r, DTRAddr(sp, DtrOffImm(4)));
}
void MacroAssemblerARM::ma_popn_pc(Imm32 n, AutoRegisterScope& scratch,
AutoRegisterScope& scratch2) {
// pc <- [sp]; sp += n
int32_t nv = n.value;
if (nv < 4096 && nv >= -4096) {
as_dtr(IsLoad, 32, PostIndex, pc, DTRAddr(sp, DtrOffImm(nv)));
} else {
ma_mov(sp, scratch);
ma_add(Imm32(n), sp, scratch2);
as_dtr(IsLoad, 32, Offset, pc, DTRAddr(scratch, DtrOffImm(0)));
}
}
void MacroAssemblerARM::ma_push(Register r) {
MOZ_ASSERT(r != sp, "Use ma_push_sp().");
as_dtr(IsStore, 32, PreIndex, r, DTRAddr(sp, DtrOffImm(-4)));
}
void MacroAssemblerARM::ma_push_sp(Register r, AutoRegisterScope& scratch) {
// Pushing sp is not well-defined: use two instructions.
MOZ_ASSERT(r == sp);
ma_mov(sp, scratch);
as_dtr(IsStore, 32, PreIndex, scratch, DTRAddr(sp, DtrOffImm(-4)));
}
void MacroAssemblerARM::ma_vpop(VFPRegister r) {
startFloatTransferM(IsLoad, sp, IA, WriteBack);
transferFloatReg(r);
finishFloatTransfer();
}
void MacroAssemblerARM::ma_vpush(VFPRegister r) {
startFloatTransferM(IsStore, sp, DB, WriteBack);
transferFloatReg(r);
finishFloatTransfer();
}
// Barriers
void MacroAssemblerARM::ma_dmb(BarrierOption option) {
if (HasDMBDSBISB()) {
as_dmb(option);
} else {
as_dmb_trap();
}
}
void MacroAssemblerARM::ma_dsb(BarrierOption option) {
if (HasDMBDSBISB()) {
as_dsb(option);
} else {
as_dsb_trap();
}
}
// Branches when done from within arm-specific code.
BufferOffset MacroAssemblerARM::ma_b(Label* dest, Assembler::Condition c) {
return as_b(dest, c);
}
void MacroAssemblerARM::ma_bx(Register dest, Assembler::Condition c) {
as_bx(dest, c);
}
void MacroAssemblerARM::ma_b(void* target, Assembler::Condition c) {
// An immediate pool is used for easier patching.
as_Imm32Pool(pc, uint32_t(target), c);
}
// This is almost NEVER necessary: we'll basically never be calling a label,
// except possibly in the crazy bailout-table case.
void MacroAssemblerARM::ma_bl(Label* dest, Assembler::Condition c) {
as_bl(dest, c);
}
void MacroAssemblerARM::ma_blx(Register reg, Assembler::Condition c) {
as_blx(reg, c);
}
// VFP/ALU
void MacroAssemblerARM::ma_vadd(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vadd(VFPRegister(dst), VFPRegister(src1), VFPRegister(src2));
}
void MacroAssemblerARM::ma_vadd_f32(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vadd(VFPRegister(dst).singleOverlay(), VFPRegister(src1).singleOverlay(),
VFPRegister(src2).singleOverlay());
}
void MacroAssemblerARM::ma_vsub(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vsub(VFPRegister(dst), VFPRegister(src1), VFPRegister(src2));
}
void MacroAssemblerARM::ma_vsub_f32(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vsub(VFPRegister(dst).singleOverlay(), VFPRegister(src1).singleOverlay(),
VFPRegister(src2).singleOverlay());
}
void MacroAssemblerARM::ma_vmul(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vmul(VFPRegister(dst), VFPRegister(src1), VFPRegister(src2));
}
void MacroAssemblerARM::ma_vmul_f32(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vmul(VFPRegister(dst).singleOverlay(), VFPRegister(src1).singleOverlay(),
VFPRegister(src2).singleOverlay());
}
void MacroAssemblerARM::ma_vdiv(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vdiv(VFPRegister(dst), VFPRegister(src1), VFPRegister(src2));
}
void MacroAssemblerARM::ma_vdiv_f32(FloatRegister src1, FloatRegister src2,
FloatRegister dst) {
as_vdiv(VFPRegister(dst).singleOverlay(), VFPRegister(src1).singleOverlay(),
VFPRegister(src2).singleOverlay());
}
void MacroAssemblerARM::ma_vmov(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vmov(dest, src, cc);
}
void MacroAssemblerARM::ma_vmov_f32(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vmov(VFPRegister(dest).singleOverlay(), VFPRegister(src).singleOverlay(),
cc);
}
void MacroAssemblerARM::ma_vneg(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vneg(dest, src, cc);
}
void MacroAssemblerARM::ma_vneg_f32(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vneg(VFPRegister(dest).singleOverlay(), VFPRegister(src).singleOverlay(),
cc);
}
void MacroAssemblerARM::ma_vabs(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vabs(dest, src, cc);
}
void MacroAssemblerARM::ma_vabs_f32(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vabs(VFPRegister(dest).singleOverlay(), VFPRegister(src).singleOverlay(),
cc);
}
void MacroAssemblerARM::ma_vsqrt(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vsqrt(dest, src, cc);
}
void MacroAssemblerARM::ma_vsqrt_f32(FloatRegister src, FloatRegister dest,
Condition cc) {
as_vsqrt(VFPRegister(dest).singleOverlay(), VFPRegister(src).singleOverlay(),
cc);
}
static inline uint32_t DoubleHighWord(double d) {
return static_cast<uint32_t>(BitwiseCast<uint64_t>(d) >> 32);
}
static inline uint32_t DoubleLowWord(double d) {
return static_cast<uint32_t>(BitwiseCast<uint64_t>(d)) & uint32_t(0xffffffff);
}
void MacroAssemblerARM::ma_vimm(double value, FloatRegister dest,
Condition cc) {
if (HasVFPv3()) {
if (DoubleLowWord(value) == 0) {
if (DoubleHighWord(value) == 0) {
// To zero a register, load 1.0, then execute dN <- dN - dN
as_vimm(dest, VFPImm::One, cc);
as_vsub(dest, dest, dest, cc);
return;
}
VFPImm enc(DoubleHighWord(value));
if (enc.isValid()) {
as_vimm(dest, enc, cc);
return;
}
}
}
// Fall back to putting the value in a pool.
as_FImm64Pool(dest, value, cc);
}
void MacroAssemblerARM::ma_vimm_f32(float value, FloatRegister dest,
Condition cc) {
VFPRegister vd = VFPRegister(dest).singleOverlay();
if (HasVFPv3()) {
if (IsPositiveZero(value)) {
// To zero a register, load 1.0, then execute sN <- sN - sN.
as_vimm(vd, VFPImm::One, cc);
as_vsub(vd, vd, vd, cc);
return;
}
// Note that the vimm immediate float32 instruction encoding differs
// from the vimm immediate double encoding, but this difference matches
// the difference in the floating point formats, so it is possible to
// convert the float32 to a double and then use the double encoding
// paths. It is still necessary to firstly check that the double low
// word is zero because some float32 numbers set these bits and this can
// not be ignored.
double doubleValue(value);
if (DoubleLowWord(doubleValue) == 0) {
VFPImm enc(DoubleHighWord(doubleValue));
if (enc.isValid()) {
as_vimm(vd, enc, cc);
return;
}
}
}
// Fall back to putting the value in a pool.
as_FImm32Pool(vd, value, cc);
}
void MacroAssemblerARM::ma_vcmp(FloatRegister src1, FloatRegister src2,
Condition cc) {
as_vcmp(VFPRegister(src1), VFPRegister(src2), cc);
}
void MacroAssemblerARM::ma_vcmp_f32(FloatRegister src1, FloatRegister src2,
Condition cc) {
as_vcmp(VFPRegister(src1).singleOverlay(), VFPRegister(src2).singleOverlay(),
cc);
}
void MacroAssemblerARM::ma_vcmpz(FloatRegister src1, Condition cc) {
as_vcmpz(VFPRegister(src1), cc);
}
void MacroAssemblerARM::ma_vcmpz_f32(FloatRegister src1, Condition cc) {
as_vcmpz(VFPRegister(src1).singleOverlay(), cc);
}
void MacroAssemblerARM::ma_vcvt_F64_I32(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isDouble());
MOZ_ASSERT(dest.isSInt());
as_vcvt(dest, src, false, cc);
}
void MacroAssemblerARM::ma_vcvt_F64_U32(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isDouble());
MOZ_ASSERT(dest.isUInt());
as_vcvt(dest, src, false, cc);
}
void MacroAssemblerARM::ma_vcvt_I32_F64(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isSInt());
MOZ_ASSERT(dest.isDouble());
as_vcvt(dest, src, false, cc);
}
void MacroAssemblerARM::ma_vcvt_U32_F64(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isUInt());
MOZ_ASSERT(dest.isDouble());
as_vcvt(dest, src, false, cc);
}
void MacroAssemblerARM::ma_vcvt_F32_I32(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isSingle());
MOZ_ASSERT(dest.isSInt());
as_vcvt(VFPRegister(dest).sintOverlay(), VFPRegister(src).singleOverlay(),
false, cc);
}
void MacroAssemblerARM::ma_vcvt_F32_U32(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isSingle());
MOZ_ASSERT(dest.isUInt());
as_vcvt(VFPRegister(dest).uintOverlay(), VFPRegister(src).singleOverlay(),
false, cc);
}
void MacroAssemblerARM::ma_vcvt_I32_F32(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isSInt());
MOZ_ASSERT(dest.isSingle());
as_vcvt(VFPRegister(dest).singleOverlay(), VFPRegister(src).sintOverlay(),
false, cc);
}
void MacroAssemblerARM::ma_vcvt_U32_F32(FloatRegister src, FloatRegister dest,
Condition cc) {
MOZ_ASSERT(src.isUInt());
MOZ_ASSERT(dest.isSingle());
as_vcvt(VFPRegister(dest).singleOverlay(), VFPRegister(src).uintOverlay(),
false, cc);
}
void MacroAssemblerARM::ma_vxfer(FloatRegister src, Register dest,
Condition cc) {
as_vxfer(dest, InvalidReg, VFPRegister(src).singleOverlay(), FloatToCore, cc);
}
void MacroAssemblerARM::ma_vxfer(FloatRegister src, Register dest1,
Register dest2, Condition cc) {
as_vxfer(dest1, dest2, VFPRegister(src), FloatToCore, cc);
}
void MacroAssemblerARM::ma_vxfer(Register src, FloatRegister dest,
Condition cc) {
as_vxfer(src, InvalidReg, VFPRegister(dest).singleOverlay(), CoreToFloat, cc);
}
void MacroAssemblerARM::ma_vxfer(Register src1, Register src2,
FloatRegister dest, Condition cc) {
as_vxfer(src1, src2, VFPRegister(dest), CoreToFloat, cc);
}
BufferOffset MacroAssemblerARM::ma_vdtr(LoadStore ls, const Address& addr,
VFPRegister rt,
AutoRegisterScope& scratch,
Condition cc) {
int off = addr.offset;
MOZ_ASSERT((off & 3) == 0);
Register base = addr.base;
if (off > -1024 && off < 1024) {
return as_vdtr(ls, rt, Operand(addr).toVFPAddr(), cc);
}
// We cannot encode this offset in a a single ldr. Try to encode it as an
// add scratch, base, imm; ldr dest, [scratch, +offset].
int bottom = off & (0xff << 2);
int neg_bottom = (0x100 << 2) - bottom;
// At this point, both off - bottom and off + neg_bottom will be
// reasonable-ish quantities.
//
// Note a neg_bottom of 0x400 can not be encoded as an immediate negative
// offset in the instruction and this occurs when bottom is zero, so this
// case is guarded against below.
if (off < 0) {
// sub_off = bottom - off
Operand2 sub_off = Imm8(-(off - bottom));
if (!sub_off.invalid()) {
// - sub_off = off - bottom
as_sub(scratch, base, sub_off, LeaveCC, cc);
return as_vdtr(ls, rt, VFPAddr(scratch, VFPOffImm(bottom)), cc);
}
// sub_off = -neg_bottom - off
sub_off = Imm8(-(off + neg_bottom));
if (!sub_off.invalid() && bottom != 0) {
// Guarded against by: bottom != 0
MOZ_ASSERT(neg_bottom < 0x400);
// - sub_off = neg_bottom + off
as_sub(scratch, base, sub_off, LeaveCC, cc);
return as_vdtr(ls, rt, VFPAddr(scratch, VFPOffImm(-neg_bottom)), cc);
}
} else {
// sub_off = off - bottom
Operand2 sub_off = Imm8(off - bottom);
if (!sub_off.invalid()) {
// sub_off = off - bottom
as_add(scratch, base, sub_off, LeaveCC, cc);
return as_vdtr(ls, rt, VFPAddr(scratch, VFPOffImm(bottom)), cc);
}
// sub_off = neg_bottom + off
sub_off = Imm8(off + neg_bottom);
if (!sub_off.invalid() && bottom != 0) {
// Guarded against by: bottom != 0
MOZ_ASSERT(neg_bottom < 0x400);
// sub_off = neg_bottom + off
as_add(scratch, base, sub_off, LeaveCC, cc);
return as_vdtr(ls, rt, VFPAddr(scratch, VFPOffImm(-neg_bottom)), cc);
}
}
// Safe to use scratch as dest, since ma_add() overwrites dest at the end
// and can't use it as internal scratch since it may also == base.
ma_add(base, Imm32(off), scratch, scratch, LeaveCC, cc);
return as_vdtr(ls, rt, VFPAddr(scratch, VFPOffImm(0)), cc);
}
BufferOffset MacroAssemblerARM::ma_vldr(VFPAddr addr, VFPRegister dest,
Condition cc) {
return as_vdtr(IsLoad, dest, addr, cc);
}
BufferOffset MacroAssemblerARM::ma_vldr(const Address& addr, VFPRegister dest,
AutoRegisterScope& scratch,
Condition cc) {
return ma_vdtr(IsLoad, addr, dest, scratch, cc);
}
BufferOffset MacroAssemblerARM::ma_vldr(VFPRegister src, Register base,
Register index,
AutoRegisterScope& scratch,
int32_t shift, Condition cc) {
as_add(scratch, base, lsl(index, shift), LeaveCC, cc);
return as_vdtr(IsLoad, src, Operand(Address(scratch, 0)).toVFPAddr(), cc);
}
BufferOffset MacroAssemblerARM::ma_vstr(VFPRegister src, VFPAddr addr,
Condition cc) {
return as_vdtr(IsStore, src, addr, cc);
}
BufferOffset MacroAssemblerARM::ma_vstr(VFPRegister src, const Address& addr,
AutoRegisterScope& scratch,
Condition cc) {
return ma_vdtr(IsStore, addr, src, scratch, cc);
}
BufferOffset MacroAssemblerARM::ma_vstr(
VFPRegister src, Register base, Register index, AutoRegisterScope& scratch,
AutoRegisterScope& scratch2, int32_t shift, int32_t offset, Condition cc) {
as_add(scratch, base, lsl(index, shift), LeaveCC, cc);
return ma_vstr(src, Address(scratch, offset), scratch2, cc);
}
// Without an offset, no second scratch register is necessary.
BufferOffset MacroAssemblerARM::ma_vstr(VFPRegister src, Register base,
Register index,
AutoRegisterScope& scratch,
int32_t shift, Condition cc) {
as_add(scratch, base, lsl(index, shift), LeaveCC, cc);
return as_vdtr(IsStore, src, Operand(Address(scratch, 0)).toVFPAddr(), cc);
}
bool MacroAssemblerARMCompat::buildOOLFakeExitFrame(void* fakeReturnAddr) {
asMasm().PushFrameDescriptor(FrameType::IonJS); // descriptor_
asMasm().Push(ImmPtr(fakeReturnAddr));
asMasm().Push(FramePointer);
return true;
}
void MacroAssemblerARMCompat::move32(Imm32 imm, Register dest) {
ma_mov(imm, dest);
}
void MacroAssemblerARMCompat::move32(Register src, Register dest) {
ma_mov(src, dest);
}
void MacroAssemblerARMCompat::movePtr(Register src, Register dest) {
ma_mov(src, dest);
}
void MacroAssemblerARMCompat::movePtr(ImmWord imm, Register dest) {
ma_mov(Imm32(imm.value), dest);
}
void MacroAssemblerARMCompat::movePtr(ImmGCPtr imm, Register dest) {
ma_mov(imm, dest);
}
void MacroAssemblerARMCompat::movePtr(ImmPtr imm, Register dest) {
movePtr(ImmWord(uintptr_t(imm.value)), dest);
}
void MacroAssemblerARMCompat::movePtr(wasm::SymbolicAddress imm,
Register dest) {
append(wasm::SymbolicAccess(CodeOffset(currentOffset()), imm));
ma_movPatchable(Imm32(-1), dest, Always);
}
FaultingCodeOffset MacroAssemblerARMCompat::load8ZeroExtend(
const Address& address, Register dest) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_dataTransferN(IsLoad, 8, false, address.base,
Imm32(address.offset), dest, scratch);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARMCompat::load8ZeroExtend(
const BaseIndex& src, Register dest) {
Register base = src.base;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
FaultingCodeOffset fco;
if (src.offset == 0) {
fco = ma_ldrb(DTRAddr(base, DtrRegImmShift(src.index, LSL, scale)), dest);
} else {
ma_add(base, Imm32(src.offset), scratch, scratch2);
fco =
ma_ldrb(DTRAddr(scratch, DtrRegImmShift(src.index, LSL, scale)), dest);
}
return fco;
}
FaultingCodeOffset MacroAssemblerARMCompat::load8SignExtend(
const Address& address, Register dest) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_dataTransferN(IsLoad, 8, true, address.base,
Imm32(address.offset), dest, scratch);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARMCompat::load8SignExtend(
const BaseIndex& src, Register dest) {
Register index = src.index;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
// ARMv7 does not have LSL on an index register with an extended load.
if (src.scale != TimesOne) {
ma_lsl(Imm32::ShiftOf(src.scale), index, scratch);
index = scratch;
}
if (src.offset != 0) {
if (index != scratch) {
ma_mov(index, scratch);
index = scratch;
}
ma_add(Imm32(src.offset), index, scratch2);
}
return ma_ldrsb(EDtrAddr(src.base, EDtrOffReg(index)), dest);
}
FaultingCodeOffset MacroAssemblerARMCompat::load16ZeroExtend(
const Address& address, Register dest) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_dataTransferN(IsLoad, 16, false, address.base,
Imm32(address.offset), dest, scratch);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARMCompat::load16ZeroExtend(
const BaseIndex& src, Register dest) {
Register index = src.index;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
// ARMv7 does not have LSL on an index register with an extended load.
if (src.scale != TimesOne) {
ma_lsl(Imm32::ShiftOf(src.scale), index, scratch);
index = scratch;
}
if (src.offset != 0) {
if (index != scratch) {
ma_mov(index, scratch);
index = scratch;
}
ma_add(Imm32(src.offset), index, scratch2);
}
return ma_ldrh(EDtrAddr(src.base, EDtrOffReg(index)), dest);
}
FaultingCodeOffset MacroAssemblerARMCompat::load16SignExtend(
const Address& address, Register dest) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_dataTransferN(IsLoad, 16, true, address.base,
Imm32(address.offset), dest, scratch);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARMCompat::load16SignExtend(
const BaseIndex& src, Register dest) {
Register index = src.index;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
// We don't have LSL on index register yet.
if (src.scale != TimesOne) {
ma_lsl(Imm32::ShiftOf(src.scale), index, scratch);
index = scratch;
}
if (src.offset != 0) {
if (index != scratch) {
ma_mov(index, scratch);
index = scratch;
}
ma_add(Imm32(src.offset), index, scratch2);
}
return ma_ldrsh(EDtrAddr(src.base, EDtrOffReg(index)), dest);
}
FaultingCodeOffset MacroAssemblerARMCompat::load32(const Address& address,
Register dest) {
return loadPtr(address, dest);
}
FaultingCodeOffset MacroAssemblerARMCompat::load32(const BaseIndex& address,
Register dest) {
return loadPtr(address, dest);
}
void MacroAssemblerARMCompat::load32(AbsoluteAddress address, Register dest) {
loadPtr(address, dest);
}
FaultingCodeOffset MacroAssemblerARMCompat::loadPtr(const Address& address,
Register dest) {
ScratchRegisterScope scratch(asMasm());
return ma_ldr(address, dest, scratch);
}
FaultingCodeOffset MacroAssemblerARMCompat::loadPtr(const BaseIndex& src,
Register dest) {
Register base = src.base;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
FaultingCodeOffset fco;
if (src.offset != 0) {
ma_add(base, Imm32(src.offset), scratch, scratch2);
fco = ma_ldr(DTRAddr(scratch, DtrRegImmShift(src.index, LSL, scale)), dest);
} else {
fco = ma_ldr(DTRAddr(base, DtrRegImmShift(src.index, LSL, scale)), dest);
}
return fco;
}
void MacroAssemblerARMCompat::loadPtr(AbsoluteAddress address, Register dest) {
MOZ_ASSERT(dest != pc); // Use dest as a scratch register.
movePtr(ImmWord(uintptr_t(address.addr)), dest);
loadPtr(Address(dest, 0), dest);
}
void MacroAssemblerARMCompat::loadPtr(wasm::SymbolicAddress address,
Register dest) {
MOZ_ASSERT(dest != pc); // Use dest as a scratch register.
movePtr(address, dest);
loadPtr(Address(dest, 0), dest);
}
void MacroAssemblerARMCompat::loadPrivate(const Address& address,
Register dest) {
ScratchRegisterScope scratch(asMasm());
ma_ldr(ToPayload(address), dest, scratch);
}
FaultingCodeOffset MacroAssemblerARMCompat::loadDouble(const Address& address,
FloatRegister dest) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_vldr(address, dest, scratch);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARMCompat::loadDouble(const BaseIndex& src,
FloatRegister dest) {
// VFP instructions don't even support register Base + register Index modes,
// so just add the index, then handle the offset like normal.
Register base = src.base;
Register index = src.index;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
int32_t offset = src.offset;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
as_add(scratch, base, lsl(index, scale));
BufferOffset boffset = ma_vldr(Address(scratch, offset), dest, scratch2);
return FaultingCodeOffset(boffset.getOffset());
}
void MacroAssemblerARMCompat::loadFloatAsDouble(const Address& address,
FloatRegister dest) {
ScratchRegisterScope scratch(asMasm());
VFPRegister rt = dest;
ma_vldr(address, rt.singleOverlay(), scratch);
as_vcvt(rt, rt.singleOverlay());
}
void MacroAssemblerARMCompat::loadFloatAsDouble(const BaseIndex& src,
FloatRegister dest) {
// VFP instructions don't even support register Base + register Index modes,
// so just add the index, then handle the offset like normal.
Register base = src.base;
Register index = src.index;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
int32_t offset = src.offset;
VFPRegister rt = dest;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
as_add(scratch, base, lsl(index, scale));
ma_vldr(Address(scratch, offset), rt.singleOverlay(), scratch2);
as_vcvt(rt, rt.singleOverlay());
}
FaultingCodeOffset MacroAssemblerARMCompat::loadFloat32(const Address& address,
FloatRegister dest) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset =
ma_vldr(address, VFPRegister(dest).singleOverlay(), scratch);
return FaultingCodeOffset(offset.getOffset());
}
FaultingCodeOffset MacroAssemblerARMCompat::loadFloat32(const BaseIndex& src,
FloatRegister dest) {
// VFP instructions don't even support register Base + register Index modes,
// so just add the index, then handle the offset like normal.
Register base = src.base;
Register index = src.index;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
int32_t offset = src.offset;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
as_add(scratch, base, lsl(index, scale));
BufferOffset boffset = ma_vldr(Address(scratch, offset),
VFPRegister(dest).singleOverlay(), scratch2);
return FaultingCodeOffset(boffset.getOffset());
}
void MacroAssemblerARMCompat::store8(Imm32 imm, const Address& address) {
SecondScratchRegisterScope scratch2(asMasm());
ma_mov(imm, scratch2);
store8(scratch2, address);
}
FaultingCodeOffset MacroAssemblerARMCompat::store8(Register src,
const Address& address) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_dataTransferN(IsStore, 8, false, address.base,
Imm32(address.offset), src, scratch);
return FaultingCodeOffset(offset.getOffset());
}
void MacroAssemblerARMCompat::store8(Imm32 imm, const BaseIndex& dest) {
Register base = dest.base;
uint32_t scale = Imm32::ShiftOf(dest.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
if (dest.offset != 0) {
ma_add(base, Imm32(dest.offset), scratch, scratch2);
ma_mov(imm, scratch2);
ma_strb(scratch2, DTRAddr(scratch, DtrRegImmShift(dest.index, LSL, scale)));
} else {
ma_mov(imm, scratch2);
ma_strb(scratch2, DTRAddr(base, DtrRegImmShift(dest.index, LSL, scale)));
}
}
FaultingCodeOffset MacroAssemblerARMCompat::store8(Register src,
const BaseIndex& dest) {
Register base = dest.base;
uint32_t scale = Imm32::ShiftOf(dest.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
FaultingCodeOffset fco;
if (dest.offset != 0) {
ma_add(base, Imm32(dest.offset), scratch, scratch2);
fco =
ma_strb(src, DTRAddr(scratch, DtrRegImmShift(dest.index, LSL, scale)));
} else {
fco = ma_strb(src, DTRAddr(base, DtrRegImmShift(dest.index, LSL, scale)));
}
return fco;
}
void MacroAssemblerARMCompat::store16(Imm32 imm, const Address& address) {
SecondScratchRegisterScope scratch2(asMasm());
ma_mov(imm, scratch2);
store16(scratch2, address);
}
FaultingCodeOffset MacroAssemblerARMCompat::store16(Register src,
const Address& address) {
ScratchRegisterScope scratch(asMasm());
BufferOffset offset = ma_dataTransferN(IsStore, 16, false, address.base,
Imm32(address.offset), src, scratch);
return FaultingCodeOffset(offset.getOffset());
}
void MacroAssemblerARMCompat::store16(Imm32 imm, const BaseIndex& dest) {
Register index = dest.index;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
// We don't have LSL on index register yet.
if (dest.scale != TimesOne) {
ma_lsl(Imm32::ShiftOf(dest.scale), index, scratch);
index = scratch;
}
if (dest.offset != 0) {
ma_add(index, Imm32(dest.offset), scratch, scratch2);
index = scratch;
}
ma_mov(imm, scratch2);
ma_strh(scratch2, EDtrAddr(dest.base, EDtrOffReg(index)));
}
FaultingCodeOffset MacroAssemblerARMCompat::store16(Register src,
const BaseIndex& address) {
Register index = address.index;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
// We don't have LSL on index register yet.
if (address.scale != TimesOne) {
ma_lsl(Imm32::ShiftOf(address.scale), index, scratch);
index = scratch;
}
if (address.offset != 0) {
ma_add(index, Imm32(address.offset), scratch, scratch2);
index = scratch;
}
return ma_strh(src, EDtrAddr(address.base, EDtrOffReg(index)));
}
void MacroAssemblerARMCompat::store32(Register src, AbsoluteAddress address) {
storePtr(src, address);
}
FaultingCodeOffset MacroAssemblerARMCompat::store32(Register src,
const Address& address) {
return storePtr(src, address);
}
void MacroAssemblerARMCompat::store32(Imm32 src, const Address& address) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
move32(src, scratch);
ma_str(scratch, address, scratch2);
}
void MacroAssemblerARMCompat::store32(Imm32 imm, const BaseIndex& dest) {
Register base = dest.base;
uint32_t scale = Imm32::ShiftOf(dest.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
if (dest.offset != 0) {
ma_add(base, Imm32(dest.offset), scratch, scratch2);
ma_mov(imm, scratch2);
ma_str(scratch2, DTRAddr(scratch, DtrRegImmShift(dest.index, LSL, scale)));
} else {
ma_mov(imm, scratch);
ma_str(scratch, DTRAddr(base, DtrRegImmShift(dest.index, LSL, scale)));
}
}
FaultingCodeOffset MacroAssemblerARMCompat::store32(Register src,
const BaseIndex& dest) {
Register base = dest.base;
uint32_t scale = Imm32::ShiftOf(dest.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
FaultingCodeOffset fco;
if (dest.offset != 0) {
ma_add(base, Imm32(dest.offset), scratch, scratch2);
fco = ma_str(src, DTRAddr(scratch, DtrRegImmShift(dest.index, LSL, scale)));
} else {
fco = ma_str(src, DTRAddr(base, DtrRegImmShift(dest.index, LSL, scale)));
}
return fco;
}
void MacroAssemblerARMCompat::storePtr(ImmWord imm, const Address& address) {
store32(Imm32(imm.value), address);
}
void MacroAssemblerARMCompat::storePtr(ImmWord imm, const BaseIndex& address) {
store32(Imm32(imm.value), address);
}
void MacroAssemblerARMCompat::storePtr(ImmPtr imm, const Address& address) {
store32(Imm32(uintptr_t(imm.value)), address);
}
void MacroAssemblerARMCompat::storePtr(ImmPtr imm, const BaseIndex& address) {
store32(Imm32(uintptr_t(imm.value)), address);
}
void MacroAssemblerARMCompat::storePtr(ImmGCPtr imm, const Address& address) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_mov(imm, scratch);
ma_str(scratch, address, scratch2);
}
void MacroAssemblerARMCompat::storePtr(ImmGCPtr imm, const BaseIndex& address) {
Register base = address.base;
uint32_t scale = Imm32::ShiftOf(address.scale).value;
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
if (address.offset != 0) {
ma_add(base, Imm32(address.offset), scratch, scratch2);
ma_mov(imm, scratch2);
ma_str(scratch2,
DTRAddr(scratch, DtrRegImmShift(address.index, LSL, scale)));
} else {
ma_mov(imm, scratch);
ma_str(scratch, DTRAddr(base, DtrRegImmShift(address.index, LSL, scale)));
}
}
FaultingCodeOffset MacroAssemblerARMCompat::storePtr(Register src,
const Address& address) {
SecondScratchRegisterScope scratch2(asMasm());
return ma_str(src, address, scratch2);
}
FaultingCodeOffset MacroAssemblerARMCompat::storePtr(Register src,
const BaseIndex& address) {
return store32(src, address);
}
void MacroAssemblerARMCompat::storePtr(Register src, AbsoluteAddress dest) {
ScratchRegisterScope scratch(asMasm());
movePtr(ImmWord(uintptr_t(dest.addr)), scratch);
ma_str(src, DTRAddr(scratch, DtrOffImm(0)));
}
// Note: this function clobbers the input register.
void MacroAssembler::clampDoubleToUint8(FloatRegister input, Register output) {
if (HasVFPv3()) {
Label notSplit;
{
ScratchDoubleScope scratchDouble(*this);
MOZ_ASSERT(input != scratchDouble);
loadConstantDouble(0.5, scratchDouble);
ma_vadd(input, scratchDouble, scratchDouble);
// Convert the double into an unsigned fixed point value with 24 bits of
// precision. The resulting number will look like 0xII.DDDDDD
as_vcvtFixed(scratchDouble, false, 24, true);
}
// Move the fixed point value into an integer register.
{
ScratchFloat32Scope scratchFloat(*this);
as_vxfer(output, InvalidReg, scratchFloat.uintOverlay(), FloatToCore);
}
ScratchRegisterScope scratch(*this);
// See if this value *might* have been an exact integer after adding
// 0.5. This tests the 1/2 through 1/16,777,216th places, but 0.5 needs
// to be tested out to the 1/140,737,488,355,328th place.
ma_tst(output, Imm32(0x00ffffff), scratch);
// Convert to a uint8 by shifting out all of the fraction bits.
ma_lsr(Imm32(24), output, output);
// If any of the bottom 24 bits were non-zero, then we're good, since
// this number can't be exactly XX.0
ma_b(¬Split, NonZero);
as_vxfer(scratch, InvalidReg, input, FloatToCore);
as_cmp(scratch, Imm8(0));
// If the lower 32 bits of the double were 0, then this was an exact number,
// and it should be even.
as_bic(output, output, Imm8(1), LeaveCC, Zero);
bind(¬Split);
} else {
ScratchDoubleScope scratchDouble(*this);
MOZ_ASSERT(input != scratchDouble);
loadConstantDouble(0.5, scratchDouble);
Label outOfRange;
ma_vcmpz(input);
// Do the add, in place so we can reference it later.
ma_vadd(input, scratchDouble, input);
// Do the conversion to an integer.
as_vcvt(VFPRegister(scratchDouble).uintOverlay(), VFPRegister(input));
// Copy the converted value out.
as_vxfer(output, InvalidReg, scratchDouble, FloatToCore);
as_vmrs(pc);
ma_mov(Imm32(0), output, Overflow); // NaN => 0
ma_b(&outOfRange, Overflow); // NaN
as_cmp(output, Imm8(0xff));
ma_mov(Imm32(0xff), output, Above);
ma_b(&outOfRange, Above);
// Convert it back to see if we got the same value back.
as_vcvt(scratchDouble, VFPRegister(scratchDouble).uintOverlay());
// Do the check.
as_vcmp(scratchDouble, input);
as_vmrs(pc);
as_bic(output, output, Imm8(1), LeaveCC, Zero);
bind(&outOfRange);
}
}
void MacroAssemblerARMCompat::cmp32(Register lhs, Imm32 rhs) {
ScratchRegisterScope scratch(asMasm());
ma_cmp(lhs, rhs, scratch);
}
void MacroAssemblerARMCompat::cmp32(Register lhs, Register rhs) {
ma_cmp(lhs, rhs);
}
void MacroAssemblerARMCompat::cmp32(const Address& lhs, Imm32 rhs) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs, scratch2);
}
void MacroAssemblerARMCompat::cmp32(const Address& lhs, Register rhs) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs);
}
void MacroAssemblerARMCompat::cmpPtr(Register lhs, ImmWord rhs) {
cmp32(lhs, Imm32(rhs.value));
}
void MacroAssemblerARMCompat::cmpPtr(Register lhs, ImmPtr rhs) {
cmpPtr(lhs, ImmWord(uintptr_t(rhs.value)));
}
void MacroAssemblerARMCompat::cmpPtr(Register lhs, Register rhs) {
ma_cmp(lhs, rhs);
}
void MacroAssemblerARMCompat::cmpPtr(Register lhs, ImmGCPtr rhs) {
ScratchRegisterScope scratch(asMasm());
ma_cmp(lhs, rhs, scratch);
}
void MacroAssemblerARMCompat::cmpPtr(Register lhs, Imm32 rhs) {
cmp32(lhs, rhs);
}
void MacroAssemblerARMCompat::cmpPtr(const Address& lhs, Register rhs) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs);
}
void MacroAssemblerARMCompat::cmpPtr(const Address& lhs, ImmWord rhs) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, Imm32(rhs.value), scratch2);
}
void MacroAssemblerARMCompat::cmpPtr(const Address& lhs, ImmPtr rhs) {
cmpPtr(lhs, ImmWord(uintptr_t(rhs.value)));
}
void MacroAssemblerARMCompat::cmpPtr(const Address& lhs, ImmGCPtr rhs) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs, scratch2);
}
void MacroAssemblerARMCompat::cmpPtr(const Address& lhs, Imm32 rhs) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(lhs, scratch, scratch2);
ma_cmp(scratch, rhs, scratch2);
}
void MacroAssemblerARMCompat::setStackArg(Register reg, uint32_t arg) {
ScratchRegisterScope scratch(asMasm());
ma_dataTransferN(IsStore, 32, true, sp, Imm32(arg * sizeof(intptr_t)), reg,
scratch);
}
void MacroAssemblerARMCompat::minMaxDouble(FloatRegister srcDest,
FloatRegister second, bool canBeNaN,
bool isMax) {
FloatRegister first = srcDest;
Label nan, equal, returnSecond, done;
Assembler::Condition cond = isMax ? Assembler::VFP_LessThanOrEqual
: Assembler::VFP_GreaterThanOrEqual;
compareDouble(first, second);
// First or second is NaN, result is NaN.
ma_b(&nan, Assembler::VFP_Unordered);
// Make sure we handle -0 and 0 right.
ma_b(&equal, Assembler::VFP_Equal);
ma_b(&returnSecond, cond);
ma_b(&done);
// Check for zero.
bind(&equal);
compareDouble(first, NoVFPRegister);
// First wasn't 0 or -0, so just return it.
ma_b(&done, Assembler::VFP_NotEqualOrUnordered);
// So now both operands are either -0 or 0.
if (isMax) {
// -0 + -0 = -0 and -0 + 0 = 0.
ma_vadd(second, first, first);
} else {
ma_vneg(first, first);
ma_vsub(first, second, first);
ma_vneg(first, first);
}
ma_b(&done);
bind(&nan);
// If the first argument is the NaN, return it; otherwise return the second
// operand.
compareDouble(first, first);
ma_vmov(first, srcDest, Assembler::VFP_Unordered);
ma_b(&done, Assembler::VFP_Unordered);
bind(&returnSecond);
ma_vmov(second, srcDest);
bind(&done);
}
void MacroAssemblerARMCompat::minMaxFloat32(FloatRegister srcDest,
FloatRegister second, bool canBeNaN,
bool isMax) {
FloatRegister first = srcDest;
Label nan, equal, returnSecond, done;
Assembler::Condition cond = isMax ? Assembler::VFP_LessThanOrEqual
: Assembler::VFP_GreaterThanOrEqual;
compareFloat(first, second);
// First or second is NaN, result is NaN.
ma_b(&nan, Assembler::VFP_Unordered);
// Make sure we handle -0 and 0 right.
ma_b(&equal, Assembler::VFP_Equal);
ma_b(&returnSecond, cond);
ma_b(&done);
// Check for zero.
bind(&equal);
compareFloat(first, NoVFPRegister);
// First wasn't 0 or -0, so just return it.
ma_b(&done, Assembler::VFP_NotEqualOrUnordered);
// So now both operands are either -0 or 0.
if (isMax) {
// -0 + -0 = -0 and -0 + 0 = 0.
ma_vadd_f32(second, first, first);
} else {
ma_vneg_f32(first, first);
ma_vsub_f32(first, second, first);
ma_vneg_f32(first, first);
}
ma_b(&done);
bind(&nan);
// See comment in minMaxDouble.
compareFloat(first, first);
ma_vmov_f32(first, srcDest, Assembler::VFP_Unordered);
ma_b(&done, Assembler::VFP_Unordered);
bind(&returnSecond);
ma_vmov_f32(second, srcDest);
bind(&done);
}
void MacroAssemblerARMCompat::compareDouble(FloatRegister lhs,
FloatRegister rhs) {
// Compare the doubles, setting vector status flags.
if (rhs.isMissing()) {
ma_vcmpz(lhs);
} else {
ma_vcmp(lhs, rhs);
}
// Move vector status bits to normal status flags.
as_vmrs(pc);
}
void MacroAssemblerARMCompat::compareFloat(FloatRegister lhs,
FloatRegister rhs) {
// Compare the doubles, setting vector status flags.
if (rhs.isMissing()) {
as_vcmpz(VFPRegister(lhs).singleOverlay());
} else {
as_vcmp(VFPRegister(lhs).singleOverlay(), VFPRegister(rhs).singleOverlay());
}
// Move vector status bits to normal status flags.
as_vmrs(pc);
}
Assembler::Condition MacroAssemblerARMCompat::testInt32(
Assembler::Condition cond, const ValueOperand& value) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
ma_cmp(value.typeReg(), ImmType(JSVAL_TYPE_INT32));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testBoolean(
Assembler::Condition cond, const ValueOperand& value) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
ma_cmp(value.typeReg(), ImmType(JSVAL_TYPE_BOOLEAN));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testDouble(
Assembler::Condition cond, const ValueOperand& value) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
Assembler::Condition actual = (cond == Equal) ? Below : AboveOrEqual;
ScratchRegisterScope scratch(asMasm());
ma_cmp(value.typeReg(), ImmTag(JSVAL_TAG_CLEAR), scratch);
return actual;
}
Assembler::Condition MacroAssemblerARMCompat::testNull(
Assembler::Condition cond, const ValueOperand& value) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
ma_cmp(value.typeReg(), ImmType(JSVAL_TYPE_NULL));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testUndefined(
Assembler::Condition cond, const ValueOperand& value) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
ma_cmp(value.typeReg(), ImmType(JSVAL_TYPE_UNDEFINED));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testString(
Assembler::Condition cond, const ValueOperand& value) {
return testString(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testSymbol(
Assembler::Condition cond, const ValueOperand& value) {
return testSymbol(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testBigInt(
Assembler::Condition cond, const ValueOperand& value) {
return testBigInt(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testObject(
Assembler::Condition cond, const ValueOperand& value) {
return testObject(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testNumber(
Assembler::Condition cond, const ValueOperand& value) {
return testNumber(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testMagic(
Assembler::Condition cond, const ValueOperand& value) {
return testMagic(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testPrimitive(
Assembler::Condition cond, const ValueOperand& value) {
return testPrimitive(cond, value.typeReg());
}
Assembler::Condition MacroAssemblerARMCompat::testGCThing(
Assembler::Condition cond, const ValueOperand& value) {
return testGCThing(cond, value.typeReg());
}
// Register-based tests.
Assembler::Condition MacroAssemblerARMCompat::testInt32(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_INT32));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testBoolean(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_BOOLEAN));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testNull(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_NULL));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testUndefined(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_UNDEFINED));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testString(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_STRING));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testSymbol(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_SYMBOL));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testBigInt(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_BIGINT));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testObject(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_OBJECT));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testMagic(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JSVAL_TAG_MAGIC));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testPrimitive(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JS::detail::ValueUpperExclPrimitiveTag));
return cond == Equal ? Below : AboveOrEqual;
}
Assembler::Condition MacroAssemblerARMCompat::testGCThing(
Assembler::Condition cond, Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JS::detail::ValueLowerInclGCThingTag));
return cond == Equal ? AboveOrEqual : Below;
}
Assembler::Condition MacroAssemblerARMCompat::testGCThing(
Assembler::Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
ma_cmp(tag, ImmTag(JS::detail::ValueLowerInclGCThingTag));
return cond == Equal ? AboveOrEqual : Below;
}
Assembler::Condition MacroAssemblerARMCompat::testMagic(
Assembler::Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_MAGIC));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testInt32(
Assembler::Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_INT32));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testDouble(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testDouble(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testBoolean(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testBoolean(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testNull(Condition cond,
const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testNull(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testUndefined(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testUndefined(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testString(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testString(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testSymbol(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testSymbol(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testBigInt(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testBigInt(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testObject(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testObject(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testNumber(
Condition cond, const Address& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
return testNumber(cond, tag);
}
Assembler::Condition MacroAssemblerARMCompat::testDouble(Condition cond,
Register tag) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
Condition actual = (cond == Equal) ? Below : AboveOrEqual;
ma_cmp(tag, ImmTag(JSVAL_TAG_CLEAR));
return actual;
}
Assembler::Condition MacroAssemblerARMCompat::testNumber(Condition cond,
Register tag) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ma_cmp(tag, ImmTag(JS::detail::ValueUpperInclNumberTag));
return cond == Equal ? BelowOrEqual : Above;
}
Assembler::Condition MacroAssemblerARMCompat::testUndefined(
Condition cond, const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_UNDEFINED));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testNull(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_NULL));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testBoolean(
Condition cond, const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_BOOLEAN));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testString(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_STRING));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testSymbol(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_SYMBOL));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testBigInt(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_BIGINT));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testInt32(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_INT32));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testObject(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_OBJECT));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testDouble(Condition cond,
const BaseIndex& src) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
Assembler::Condition actual = (cond == Equal) ? Below : AboveOrEqual;
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(src, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_CLEAR));
return actual;
}
Assembler::Condition MacroAssemblerARMCompat::testMagic(
Condition cond, const BaseIndex& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
ma_cmp(tag, ImmTag(JSVAL_TAG_MAGIC));
return cond;
}
Assembler::Condition MacroAssemblerARMCompat::testGCThing(
Condition cond, const BaseIndex& address) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
ScratchRegisterScope scratch(asMasm());
Register tag = extractTag(address, scratch);
ma_cmp(tag, ImmTag(JS::detail::ValueLowerInclGCThingTag));
return cond == Equal ? AboveOrEqual : Below;
}
// Unboxing code.
void MacroAssemblerARMCompat::unboxNonDouble(const ValueOperand& operand,
Register dest, JSValueType type) {
auto movPayloadToDest = [&]() {
if (operand.payloadReg() != dest) {
ma_mov(operand.payloadReg(), dest, LeaveCC);
}
};
if (!JitOptions.spectreValueMasking) {
movPayloadToDest();
return;
}
// Spectre mitigation: We zero the payload if the tag does not match the
// expected type and if this is a pointer type.
if (type == JSVAL_TYPE_INT32 || type == JSVAL_TYPE_BOOLEAN) {
movPayloadToDest();
return;
}
// We zero the destination register and move the payload into it if
// the tag corresponds to the given type.
ma_cmp(operand.typeReg(), ImmType(type));
movPayloadToDest();
ma_mov(Imm32(0), dest, NotEqual);
}
void MacroAssemblerARMCompat::unboxNonDouble(const Address& src, Register dest,
JSValueType type) {
ScratchRegisterScope scratch(asMasm());
if (!JitOptions.spectreValueMasking) {
ma_ldr(ToPayload(src), dest, scratch);
return;
}
// Spectre mitigation: We zero the payload if the tag does not match the
// expected type and if this is a pointer type.
if (type == JSVAL_TYPE_INT32 || type == JSVAL_TYPE_BOOLEAN) {
ma_ldr(ToPayload(src), dest, scratch);
return;
}
// We zero the destination register and move the payload into it if
// the tag corresponds to the given type.
ma_ldr(ToType(src), scratch, scratch);
ma_cmp(scratch, ImmType(type));
ma_ldr(ToPayload(src), dest, scratch, Offset, Equal);
ma_mov(Imm32(0), dest, NotEqual);
}
void MacroAssemblerARMCompat::unboxNonDouble(const BaseIndex& src,
Register dest, JSValueType type) {
SecondScratchRegisterScope scratch2(asMasm());
ma_alu(src.base, lsl(src.index, src.scale), scratch2, OpAdd);
Address value(scratch2, src.offset);
unboxNonDouble(value, dest, type);
}
void MacroAssemblerARMCompat::unboxDouble(const ValueOperand& operand,
FloatRegister dest) {
MOZ_ASSERT(dest.isDouble());
as_vxfer(operand.payloadReg(), operand.typeReg(), VFPRegister(dest),
CoreToFloat);
}
void MacroAssemblerARMCompat::unboxDouble(const Address& src,
FloatRegister dest) {
MOZ_ASSERT(dest.isDouble());
loadDouble(src, dest);
}
void MacroAssemblerARMCompat::unboxDouble(const BaseIndex& src,
FloatRegister dest) {
MOZ_ASSERT(dest.isDouble());
loadDouble(src, dest);
}
void MacroAssemblerARMCompat::unboxValue(const ValueOperand& src,
AnyRegister dest, JSValueType type) {
if (dest.isFloat()) {
Label notInt32, end;
asMasm().branchTestInt32(Assembler::NotEqual, src, ¬Int32);
convertInt32ToDouble(src.payloadReg(), dest.fpu());
ma_b(&end);
bind(¬Int32);
unboxDouble(src, dest.fpu());
bind(&end);
} else {
unboxNonDouble(src, dest.gpr(), type);
}
}
void MacroAssemblerARMCompat::boxDouble(FloatRegister src,
const ValueOperand& dest,
FloatRegister) {
as_vxfer(dest.payloadReg(), dest.typeReg(), VFPRegister(src), FloatToCore);
}
void MacroAssemblerARMCompat::boxNonDouble(JSValueType type, Register src,
const ValueOperand& dest) {
if (src != dest.payloadReg()) {
ma_mov(src, dest.payloadReg());
}
ma_mov(ImmType(type), dest.typeReg());
}
void MacroAssemblerARMCompat::boolValueToDouble(const ValueOperand& operand,
FloatRegister dest) {
VFPRegister d = VFPRegister(dest);
loadConstantDouble(1.0, dest);
as_cmp(operand.payloadReg(), Imm8(0));
// If the source is 0, then subtract the dest from itself, producing 0.
as_vsub(d, d, d, Equal);
}
void MacroAssemblerARMCompat::int32ValueToDouble(const ValueOperand& operand,
FloatRegister dest) {
// Transfer the integral value to a floating point register.
VFPRegister vfpdest = VFPRegister(dest);
as_vxfer(operand.payloadReg(), InvalidReg, vfpdest.sintOverlay(),
CoreToFloat);
// Convert the value to a double.
as_vcvt(vfpdest, vfpdest.sintOverlay());
}
void MacroAssemblerARMCompat::boolValueToFloat32(const ValueOperand& operand,
FloatRegister dest) {
VFPRegister d = VFPRegister(dest).singleOverlay();
loadConstantFloat32(1.0, dest);
as_cmp(operand.payloadReg(), Imm8(0));
// If the source is 0, then subtract the dest from itself, producing 0.
as_vsub(d, d, d, Equal);
}
void MacroAssemblerARMCompat::int32ValueToFloat32(const ValueOperand& operand,
FloatRegister dest) {
// Transfer the integral value to a floating point register.
VFPRegister vfpdest = VFPRegister(dest).singleOverlay();
as_vxfer(operand.payloadReg(), InvalidReg, vfpdest.sintOverlay(),
CoreToFloat);
// Convert the value to a float.
as_vcvt(vfpdest, vfpdest.sintOverlay());
}
void MacroAssemblerARMCompat::loadConstantFloat32(float f, FloatRegister dest) {
ma_vimm_f32(f, dest);
}
void MacroAssemblerARMCompat::loadInt32OrDouble(const Address& src,
FloatRegister dest) {
Label notInt32, end;
// If it's an int, convert to a double.
{
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(ToType(src), scratch, scratch2);
asMasm().branchTestInt32(Assembler::NotEqual, scratch, ¬Int32);
ma_ldr(ToPayload(src), scratch, scratch2);
convertInt32ToDouble(scratch, dest);
ma_b(&end);
}
// Not an int, just load as double.
bind(¬Int32);
{
ScratchRegisterScope scratch(asMasm());
ma_vldr(src, dest, scratch);
}
bind(&end);
}
void MacroAssemblerARMCompat::loadInt32OrDouble(Register base, Register index,
FloatRegister dest,
int32_t shift) {
Label notInt32, end;
static_assert(NUNBOX32_PAYLOAD_OFFSET == 0);
ScratchRegisterScope scratch(asMasm());
// If it's an int, convert it to double.
ma_alu(base, lsl(index, shift), scratch, OpAdd);
// Since we only have one scratch register, we need to stomp over it with
// the tag.
ma_ldr(DTRAddr(scratch, DtrOffImm(NUNBOX32_TYPE_OFFSET)), scratch);
asMasm().branchTestInt32(Assembler::NotEqual, scratch, ¬Int32);
// Implicitly requires NUNBOX32_PAYLOAD_OFFSET == 0: no offset provided
ma_ldr(DTRAddr(base, DtrRegImmShift(index, LSL, shift)), scratch);
convertInt32ToDouble(scratch, dest);
ma_b(&end);
// Not an int, just load as double.
bind(¬Int32);
// First, recompute the offset that had been stored in the scratch register
// since the scratch register was overwritten loading in the type.
ma_alu(base, lsl(index, shift), scratch, OpAdd);
ma_vldr(VFPAddr(scratch, VFPOffImm(0)), dest);
bind(&end);
}
void MacroAssemblerARMCompat::loadConstantDouble(double dp,
FloatRegister dest) {
ma_vimm(dp, dest);
}
// Treat the value as a boolean, and set condition codes accordingly.
Assembler::Condition MacroAssemblerARMCompat::testInt32Truthy(
bool truthy, const ValueOperand& operand) {
ma_tst(operand.payloadReg(), operand.payloadReg());
return truthy ? NonZero : Zero;
}
Assembler::Condition MacroAssemblerARMCompat::testBooleanTruthy(
bool truthy, const ValueOperand& operand) {
ma_tst(operand.payloadReg(), operand.payloadReg());
return truthy ? NonZero : Zero;
}
Assembler::Condition MacroAssemblerARMCompat::testDoubleTruthy(
bool truthy, FloatRegister reg) {
as_vcmpz(VFPRegister(reg));
as_vmrs(pc);
as_cmp(r0, O2Reg(r0), Overflow);
return truthy ? NonZero : Zero;
}
Register MacroAssemblerARMCompat::extractObject(const Address& address,
Register scratch) {
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(ToPayload(address), scratch, scratch2);
return scratch;
}
Register MacroAssemblerARMCompat::extractTag(const Address& address,
Register scratch) {
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(ToType(address), scratch, scratch2);
return scratch;
}
Register MacroAssemblerARMCompat::extractTag(const BaseIndex& address,
Register scratch) {
ma_alu(address.base, lsl(address.index, address.scale), scratch, OpAdd,
LeaveCC);
return extractTag(Address(scratch, address.offset), scratch);
}
/////////////////////////////////////////////////////////////////
// X86/X64-common (ARM too now) interface.
/////////////////////////////////////////////////////////////////
void MacroAssemblerARMCompat::storeValue(ValueOperand val, const Address& dst) {
SecondScratchRegisterScope scratch2(asMasm());
ma_str(val.payloadReg(), ToPayload(dst), scratch2);
ma_str(val.typeReg(), ToType(dst), scratch2);
}
void MacroAssemblerARMCompat::storeValue(ValueOperand val,
const BaseIndex& dest) {
ScratchRegisterScope scratch(asMasm());
if (isValueDTRDCandidate(val) && Abs(dest.offset) <= 255) {
Register tmpIdx;
if (dest.offset == 0) {
if (dest.scale == TimesOne) {
tmpIdx = dest.index;
} else {
ma_lsl(Imm32(dest.scale), dest.index, scratch);
tmpIdx = scratch;
}
ma_strd(val.payloadReg(), val.typeReg(),
EDtrAddr(dest.base, EDtrOffReg(tmpIdx)));
} else {
ma_alu(dest.base, lsl(dest.index, dest.scale), scratch, OpAdd);
ma_strd(val.payloadReg(), val.typeReg(),
EDtrAddr(scratch, EDtrOffImm(dest.offset)));
}
} else {
ma_alu(dest.base, lsl(dest.index, dest.scale), scratch, OpAdd);
storeValue(val, Address(scratch, dest.offset));
}
}
void MacroAssemblerARMCompat::loadValue(const BaseIndex& addr,
ValueOperand val) {
ScratchRegisterScope scratch(asMasm());
if (isValueDTRDCandidate(val) && Abs(addr.offset) <= 255) {
Register tmpIdx;
if (addr.offset == 0) {
if (addr.scale == TimesOne) {
// If the offset register is the same as one of the destination
// registers, LDRD's behavior is undefined. Use the scratch
// register to avoid this.
if (val.aliases(addr.index)) {
ma_mov(addr.index, scratch);
tmpIdx = scratch;
} else {
tmpIdx = addr.index;
}
} else {
ma_lsl(Imm32(addr.scale), addr.index, scratch);
tmpIdx = scratch;
}
ma_ldrd(EDtrAddr(addr.base, EDtrOffReg(tmpIdx)), val.payloadReg(),
val.typeReg());
} else {
ma_alu(addr.base, lsl(addr.index, addr.scale), scratch, OpAdd);
ma_ldrd(EDtrAddr(scratch, EDtrOffImm(addr.offset)), val.payloadReg(),
val.typeReg());
}
} else {
ma_alu(addr.base, lsl(addr.index, addr.scale), scratch, OpAdd);
loadValue(Address(scratch, addr.offset), val);
}
}
void MacroAssemblerARMCompat::loadValue(Address src, ValueOperand val) {
// TODO: copy this code into a generic function that acts on all sequences
// of memory accesses
if (isValueDTRDCandidate(val)) {
// If the value we want is in two consecutive registers starting with an
// even register, they can be combined as a single ldrd.
int offset = src.offset;
if (offset < 256 && offset > -256) {
ma_ldrd(EDtrAddr(src.base, EDtrOffImm(src.offset)), val.payloadReg(),
val.typeReg());
return;
}
}
// If the value is lower than the type, then we may be able to use an ldm
// instruction.
if (val.payloadReg().code() < val.typeReg().code()) {
if (src.offset <= 4 && src.offset >= -8 && (src.offset & 3) == 0) {
// Turns out each of the 4 value -8, -4, 0, 4 corresponds exactly
// with one of LDM{DB, DA, IA, IB}
DTMMode mode;
switch (src.offset) {
case -8:
mode = DB;
break;
case -4:
mode = DA;
break;
case 0:
mode = IA;
break;
case 4:
mode = IB;
break;
default:
MOZ_CRASH("Bogus Offset for LoadValue as DTM");
}
startDataTransferM(IsLoad, src.base, mode);
transferReg(val.payloadReg());
transferReg(val.typeReg());
finishDataTransfer();
return;
}
}
loadUnalignedValue(src, val);
}
void MacroAssemblerARMCompat::loadUnalignedValue(const Address& src,
ValueOperand dest) {
Address payload = ToPayload(src);
Address type = ToType(src);
// Ensure that loading the payload does not erase the pointer to the Value
// in memory.
if (type.base != dest.payloadReg()) {
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(payload, dest.payloadReg(), scratch2);
ma_ldr(type, dest.typeReg(), scratch2);
} else {
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(type, dest.typeReg(), scratch2);
ma_ldr(payload, dest.payloadReg(), scratch2);
}
}
void MacroAssemblerARMCompat::tagValue(JSValueType type, Register payload,
ValueOperand dest) {
MOZ_ASSERT(dest.typeReg() != dest.payloadReg());
if (payload != dest.payloadReg()) {
ma_mov(payload, dest.payloadReg());
}
ma_mov(ImmType(type), dest.typeReg());
}
void MacroAssemblerARMCompat::pushValue(ValueOperand val) {
ma_push(val.typeReg());
ma_push(val.payloadReg());
}
void MacroAssemblerARMCompat::pushValue(const Address& addr) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_ldr(ToType(addr), scratch, scratch2);
ma_push(scratch);
ma_ldr(ToPayloadAfterStackPush(addr), scratch, scratch2);
ma_push(scratch);
}
void MacroAssemblerARMCompat::pushValue(const BaseIndex& addr,
Register scratch) {
computeEffectiveAddress(addr, scratch);
pushValue(Address(scratch, 0));
}
void MacroAssemblerARMCompat::popValue(ValueOperand val) {
ma_pop(val.payloadReg());
ma_pop(val.typeReg());
}
void MacroAssemblerARMCompat::storePayload(const Value& val,
const Address& dest) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
if (val.isGCThing()) {
ma_mov(ImmGCPtr(val.toGCThing()), scratch);
} else {
ma_mov(Imm32(val.toNunboxPayload()), scratch);
}
ma_str(scratch, ToPayload(dest), scratch2);
}
void MacroAssemblerARMCompat::storePayload(Register src, const Address& dest) {
ScratchRegisterScope scratch(asMasm());
ma_str(src, ToPayload(dest), scratch);
}
void MacroAssemblerARMCompat::storePayload(const Value& val,
const BaseIndex& dest) {
unsigned shift = ScaleToShift(dest.scale);
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
if (val.isGCThing()) {
ma_mov(ImmGCPtr(val.toGCThing()), scratch);
} else {
ma_mov(Imm32(val.toNunboxPayload()), scratch);
}
// If NUNBOX32_PAYLOAD_OFFSET is not zero, the memory operand [base + index
// << shift + imm] cannot be encoded into a single instruction, and cannot
// be integrated into the as_dtr call.
static_assert(NUNBOX32_PAYLOAD_OFFSET == 0);
// If an offset is used, modify the base so that a [base + index << shift]
// instruction format can be used.
if (dest.offset != 0) {
ma_add(dest.base, Imm32(dest.offset), dest.base, scratch2);
}
as_dtr(IsStore, 32, Offset, scratch,
DTRAddr(dest.base, DtrRegImmShift(dest.index, LSL, shift)));
// Restore the original value of the base, if necessary.
if (dest.offset != 0) {
ma_sub(dest.base, Imm32(dest.offset), dest.base, scratch);
}
}
void MacroAssemblerARMCompat::storePayload(Register src,
const BaseIndex& dest) {
unsigned shift = ScaleToShift(dest.scale);
MOZ_ASSERT(shift < 32);
ScratchRegisterScope scratch(asMasm());
// If NUNBOX32_PAYLOAD_OFFSET is not zero, the memory operand [base + index
// << shift + imm] cannot be encoded into a single instruction, and cannot
// be integrated into the as_dtr call.
static_assert(NUNBOX32_PAYLOAD_OFFSET == 0);
// Save/restore the base if the BaseIndex has an offset, as above.
if (dest.offset != 0) {
ma_add(dest.base, Imm32(dest.offset), dest.base, scratch);
}
// Technically, shift > -32 can be handle by changing LSL to ASR, but should
// never come up, and this is one less code path to get wrong.
as_dtr(IsStore, 32, Offset, src,
DTRAddr(dest.base, DtrRegImmShift(dest.index, LSL, shift)));
if (dest.offset != 0) {
ma_sub(dest.base, Imm32(dest.offset), dest.base, scratch);
}
}
void MacroAssemblerARMCompat::storeTypeTag(ImmTag tag, const Address& dest) {
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_mov(tag, scratch);
ma_str(scratch, ToType(dest), scratch2);
}
void MacroAssemblerARMCompat::storeTypeTag(ImmTag tag, const BaseIndex& dest) {
Register base = dest.base;
Register index = dest.index;
unsigned shift = ScaleToShift(dest.scale);
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
MOZ_ASSERT(base != scratch && base != scratch2);
MOZ_ASSERT(index != scratch && index != scratch2);
ma_add(base, Imm32(dest.offset + NUNBOX32_TYPE_OFFSET), scratch2, scratch);
ma_mov(tag, scratch);
ma_str(scratch, DTRAddr(scratch2, DtrRegImmShift(index, LSL, shift)));
}
void MacroAssemblerARM::ma_call(ImmPtr dest) {
ma_movPatchable(dest, CallReg, Always);
as_blx(CallReg);
}
void MacroAssemblerARMCompat::breakpoint() { as_bkpt(); }
void MacroAssemblerARMCompat::simulatorStop(const char* msg) {
#ifdef JS_SIMULATOR_ARM
MOZ_ASSERT(sizeof(char*) == 4);
writeInst(0xefffffff);
writeInst((int)msg);
#endif
}
void MacroAssemblerARMCompat::ensureDouble(const ValueOperand& source,
FloatRegister dest, Label* failure) {
Label isDouble, done;
asMasm().branchTestDouble(Assembler::Equal, source.typeReg(), &isDouble);
asMasm().branchTestInt32(Assembler::NotEqual, source.typeReg(), failure);
convertInt32ToDouble(source.payloadReg(), dest);
jump(&done);
bind(&isDouble);
unboxDouble(source, dest);
bind(&done);
}
void MacroAssemblerARMCompat::breakpoint(Condition cc) {
ma_ldr(DTRAddr(r12, DtrRegImmShift(r12, LSL, 0, IsDown)), r12, Offset, cc);
}
void MacroAssemblerARMCompat::checkStackAlignment() {
asMasm().assertStackAlignment(ABIStackAlignment);
}
void MacroAssemblerARMCompat::handleFailureWithHandlerTail(
Label* profilerExitTail, Label* bailoutTail) {
// Reserve space for exception information.
int size = (sizeof(ResumeFromException) + 7) & ~7;
Imm8 size8(size);
as_sub(sp, sp, size8);
ma_mov(sp, r0);
// Call the handler.
using Fn = void (*)(ResumeFromException* rfe);
asMasm().setupUnalignedABICall(r1);
asMasm().passABIArg(r0);
asMasm().callWithABI<Fn, HandleException>(
ABIType::General, CheckUnsafeCallWithABI::DontCheckHasExitFrame);
Label entryFrame;
Label catch_;
Label finally;
Label returnBaseline;
Label returnIon;
Label bailout;
Label wasm;
Label wasmCatch;
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfKind()), r0, scratch);
}
asMasm().branch32(Assembler::Equal, r0,
Imm32(ExceptionResumeKind::EntryFrame), &entryFrame);
asMasm().branch32(Assembler::Equal, r0, Imm32(ExceptionResumeKind::Catch),
&catch_);
asMasm().branch32(Assembler::Equal, r0, Imm32(ExceptionResumeKind::Finally),
&finally);
asMasm().branch32(Assembler::Equal, r0,
Imm32(ExceptionResumeKind::ForcedReturnBaseline),
&returnBaseline);
asMasm().branch32(Assembler::Equal, r0,
Imm32(ExceptionResumeKind::ForcedReturnIon), &returnIon);
asMasm().branch32(Assembler::Equal, r0, Imm32(ExceptionResumeKind::Bailout),
&bailout);
asMasm().branch32(Assembler::Equal, r0, Imm32(ExceptionResumeKind::Wasm),
&wasm);
asMasm().branch32(Assembler::Equal, r0, Imm32(ExceptionResumeKind::WasmCatch),
&wasmCatch);
breakpoint(); // Invalid kind.
// No exception handler. Load the error value, restore state and return from
// the entry frame.
bind(&entryFrame);
asMasm().moveValue(MagicValue(JS_ION_ERROR), JSReturnOperand);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
}
// We're going to be returning by the ion calling convention, which returns
// by ??? (for now, I think ldr pc, [sp]!)
as_dtr(IsLoad, 32, PostIndex, pc, DTRAddr(sp, DtrOffImm(4)));
// If we found a catch handler, this must be a baseline frame. Restore state
// and jump to the catch block.
bind(&catch_);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfTarget()), r0, scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
}
jump(r0);
// If we found a finally block, this must be a baseline frame. Push three
// values expected by the finally block: the exception, the exception stack,
// and BooleanValue(true).
bind(&finally);
ValueOperand exception = ValueOperand(r1, r2);
loadValue(Operand(sp, ResumeFromException::offsetOfException()), exception);
ValueOperand exceptionStack = ValueOperand(r3, r4);
loadValue(Operand(sp, ResumeFromException::offsetOfExceptionStack()),
exceptionStack);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfTarget()), r0, scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
}
pushValue(exception);
pushValue(exceptionStack);
pushValue(BooleanValue(true));
jump(r0);
// Return BaselineFrame->returnValue() to the caller.
// Used in debug mode and for GeneratorReturn.
Label profilingInstrumentation;
bind(&returnBaseline);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
}
loadValue(Address(r11, BaselineFrame::reverseOffsetOfReturnValue()),
JSReturnOperand);
jump(&profilingInstrumentation);
// Return the given value to the caller.
bind(&returnIon);
loadValue(Address(sp, ResumeFromException::offsetOfException()),
JSReturnOperand);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
}
// If profiling is enabled, then update the lastProfilingFrame to refer to
// caller frame before returning. This code is shared by ForcedReturnIon
// and ForcedReturnBaseline.
bind(&profilingInstrumentation);
{
Label skipProfilingInstrumentation;
// Test if profiler enabled.
AbsoluteAddress addressOfEnabled(
asMasm().runtime()->geckoProfiler().addressOfEnabled());
asMasm().branch32(Assembler::Equal, addressOfEnabled, Imm32(0),
&skipProfilingInstrumentation);
jump(profilerExitTail);
bind(&skipProfilingInstrumentation);
}
ma_mov(r11, sp);
pop(r11);
ret();
// If we are bailing out to baseline to handle an exception, jump to the
// bailout tail stub. Load 1 (true) in ReturnReg to indicate success.
bind(&bailout);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfBailoutInfo()), r2,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
ma_mov(Imm32(1), ReturnReg);
}
jump(bailoutTail);
// If we are throwing and the innermost frame was a wasm frame, reset SP and
// FP; SP is pointing to the unwound return address to the wasm entry, so
// we can just ret().
bind(&wasm);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
ma_mov(Imm32(int32_t(wasm::FailInstanceReg)), InstanceReg);
}
as_dtr(IsLoad, 32, PostIndex, pc, DTRAddr(sp, DtrOffImm(4)));
// Found a wasm catch handler, restore state and jump to it.
bind(&wasmCatch);
{
ScratchRegisterScope scratch(asMasm());
ma_ldr(Address(sp, ResumeFromException::offsetOfTarget()), r1, scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfFramePointer()), r11,
scratch);
ma_ldr(Address(sp, ResumeFromException::offsetOfStackPointer()), sp,
scratch);
}
jump(r1);
}
Assembler::Condition MacroAssemblerARMCompat::testStringTruthy(
bool truthy, const ValueOperand& value) {
Register string = value.payloadReg();
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_dtr(IsLoad, string, Imm32(JSString::offsetOfLength()), scratch, scratch2);
as_cmp(scratch, Imm8(0));
return truthy ? Assembler::NotEqual : Assembler::Equal;
}
Assembler::Condition MacroAssemblerARMCompat::testBigIntTruthy(
bool truthy, const ValueOperand& value) {
Register bi = value.payloadReg();
ScratchRegisterScope scratch(asMasm());
SecondScratchRegisterScope scratch2(asMasm());
ma_dtr(IsLoad, bi, Imm32(BigInt::offsetOfDigitLength()), scratch, scratch2);
as_cmp(scratch, Imm8(0));
return truthy ? Assembler::NotEqual : Assembler::Equal;
}
void MacroAssemblerARMCompat::floor(FloatRegister input, Register output,
Label* bail) {
Label handleZero;
Label handleNeg;
Label fin;
ScratchDoubleScope scratchDouble(asMasm());
compareDouble(input, NoVFPRegister);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handleNeg, Assembler::Signed);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
// The argument is a positive number, truncation is the path to glory. Since
// it is known to be > 0.0, explicitly convert to a larger range, then a
// value that rounds to INT_MAX is explicitly different from an argument
// that clamps to INT_MAX.
ma_vcvt_F64_U32(input, scratchDouble.uintOverlay());
ma_vxfer(scratchDouble.uintOverlay(), output);
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
ma_b(&fin);
bind(&handleZero);
// Move the top word of the double into the output reg, if it is non-zero,
// then the original value was -0.0.
as_vxfer(output, InvalidReg, input, FloatToCore, Always, 1);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
bind(&handleNeg);
// Negative case, negate, then start dancing.
ma_vneg(input, input);
ma_vcvt_F64_U32(input, scratchDouble.uintOverlay());
ma_vxfer(scratchDouble.uintOverlay(), output);
ma_vcvt_U32_F64(scratchDouble.uintOverlay(), scratchDouble);
compareDouble(scratchDouble, input);
as_add(output, output, Imm8(1), LeaveCC, NotEqual);
// Negate the output. Since INT_MIN < -INT_MAX, even after adding 1, the
// result will still be a negative number.
as_rsb(output, output, Imm8(0), SetCC);
// Flip the negated input back to its original value.
ma_vneg(input, input);
// If the result looks non-negative, then this value didn't actually fit
// into the int range, and special handling is required. Zero is also caught
// by this case, but floor of a negative number should never be zero.
ma_b(bail, NotSigned);
bind(&fin);
}
void MacroAssemblerARMCompat::floorf(FloatRegister input, Register output,
Label* bail) {
Label handleZero;
Label handleNeg;
Label fin;
compareFloat(input, NoVFPRegister);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handleNeg, Assembler::Signed);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
// The argument is a positive number, truncation is the path to glory; Since
// it is known to be > 0.0, explicitly convert to a larger range, then a
// value that rounds to INT_MAX is explicitly different from an argument
// that clamps to INT_MAX.
{
ScratchFloat32Scope scratch(asMasm());
ma_vcvt_F32_U32(input, scratch.uintOverlay());
ma_vxfer(VFPRegister(scratch).uintOverlay(), output);
}
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
ma_b(&fin);
bind(&handleZero);
// Move the top word of the double into the output reg, if it is non-zero,
// then the original value was -0.0.
as_vxfer(output, InvalidReg, VFPRegister(input).singleOverlay(), FloatToCore,
Always, 0);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
bind(&handleNeg);
// Negative case, negate, then start dancing.
{
ScratchFloat32Scope scratch(asMasm());
ma_vneg_f32(input, input);
ma_vcvt_F32_U32(input, scratch.uintOverlay());
ma_vxfer(VFPRegister(scratch).uintOverlay(), output);
ma_vcvt_U32_F32(scratch.uintOverlay(), scratch);
compareFloat(scratch, input);
as_add(output, output, Imm8(1), LeaveCC, NotEqual);
}
// Negate the output. Since INT_MIN < -INT_MAX, even after adding 1, the
// result will still be a negative number.
as_rsb(output, output, Imm8(0), SetCC);
// Flip the negated input back to its original value.
ma_vneg_f32(input, input);
// If the result looks non-negative, then this value didn't actually fit
// into the int range, and special handling is required. Zero is also caught
// by this case, but floor of a negative number should never be zero.
ma_b(bail, NotSigned);
bind(&fin);
}
void MacroAssemblerARMCompat::ceil(FloatRegister input, Register output,
Label* bail) {
Label handleZero;
Label handlePos;
Label fin;
compareDouble(input, NoVFPRegister);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handlePos, Assembler::NotSigned);
ScratchDoubleScope scratchDouble(asMasm());
// We are in the ]-Inf; 0[ range
// If we are in the ]-1; 0[ range => bailout
loadConstantDouble(-1.0, scratchDouble);
compareDouble(input, scratchDouble);
ma_b(bail, Assembler::GreaterThan);
// We are in the ]-Inf; -1] range: ceil(x) == -floor(-x) and floor can be
// computed with direct truncation here (x > 0).
ma_vneg(input, scratchDouble);
FloatRegister ScratchUIntReg = scratchDouble.uintOverlay();
ma_vcvt_F64_U32(scratchDouble, ScratchUIntReg);
ma_vxfer(ScratchUIntReg, output);
ma_neg(output, output, SetCC);
ma_b(bail, NotSigned);
ma_b(&fin);
// Test for 0.0 / -0.0: if the top word of the input double is not zero,
// then it was -0 and we need to bail out.
bind(&handleZero);
as_vxfer(output, InvalidReg, input, FloatToCore, Always, 1);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
// We are in the ]0; +inf] range: truncate integer values, maybe add 1 for
// non integer values, maybe bail if overflow.
bind(&handlePos);
ma_vcvt_F64_U32(input, ScratchUIntReg);
ma_vxfer(ScratchUIntReg, output);
ma_vcvt_U32_F64(ScratchUIntReg, scratchDouble);
compareDouble(scratchDouble, input);
as_add(output, output, Imm8(1), LeaveCC, NotEqual);
// Bail out if the add overflowed or the result is non positive.
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
ma_b(bail, Zero);
bind(&fin);
}
void MacroAssemblerARMCompat::ceilf(FloatRegister input, Register output,
Label* bail) {
Label handleZero;
Label handlePos;
Label fin;
compareFloat(input, NoVFPRegister);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handlePos, Assembler::NotSigned);
// We are in the ]-Inf; 0[ range
// If we are in the ]-1; 0[ range => bailout
{
ScratchFloat32Scope scratch(asMasm());
loadConstantFloat32(-1.f, scratch);
compareFloat(input, scratch);
ma_b(bail, Assembler::GreaterThan);
}
// We are in the ]-Inf; -1] range: ceil(x) == -floor(-x) and floor can be
// computed with direct truncation here (x > 0).
{
ScratchDoubleScope scratchDouble(asMasm());
FloatRegister scratchFloat = scratchDouble.asSingle();
FloatRegister scratchUInt = scratchDouble.uintOverlay();
ma_vneg_f32(input, scratchFloat);
ma_vcvt_F32_U32(scratchFloat, scratchUInt);
ma_vxfer(scratchUInt, output);
ma_neg(output, output, SetCC);
ma_b(bail, NotSigned);
ma_b(&fin);
}
// Test for 0.0 / -0.0: if the top word of the input double is not zero,
// then it was -0 and we need to bail out.
bind(&handleZero);
as_vxfer(output, InvalidReg, VFPRegister(input).singleOverlay(), FloatToCore,
Always, 0);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
// We are in the ]0; +inf] range: truncate integer values, maybe add 1 for
// non integer values, maybe bail if overflow.
bind(&handlePos);
{
ScratchDoubleScope scratchDouble(asMasm());
FloatRegister scratchFloat = scratchDouble.asSingle();
FloatRegister scratchUInt = scratchDouble.uintOverlay();
ma_vcvt_F32_U32(input, scratchUInt);
ma_vxfer(scratchUInt, output);
ma_vcvt_U32_F32(scratchUInt, scratchFloat);
compareFloat(scratchFloat, input);
as_add(output, output, Imm8(1), LeaveCC, NotEqual);
// Bail on overflow or non-positive result.
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
ma_b(bail, Zero);
}
bind(&fin);
}
CodeOffset MacroAssemblerARMCompat::toggledJump(Label* label) {
// Emit a B that can be toggled to a CMP. See ToggleToJmp(), ToggleToCmp().
BufferOffset b = ma_b(label, Always);
CodeOffset ret(b.getOffset());
return ret;
}
CodeOffset MacroAssemblerARMCompat::toggledCall(JitCode* target, bool enabled) {
BufferOffset bo = nextOffset();
addPendingJump(bo, ImmPtr(target->raw()), RelocationKind::JITCODE);
ScratchRegisterScope scratch(asMasm());
ma_movPatchable(ImmPtr(target->raw()), scratch, Always);
if (enabled) {
ma_blx(scratch);
} else {
ma_nop();
}
return CodeOffset(bo.getOffset());
}
void MacroAssemblerARMCompat::round(FloatRegister input, Register output,
Label* bail, FloatRegister tmp) {
Label handleZero;
Label handleNeg;
Label fin;
ScratchDoubleScope scratchDouble(asMasm());
// Do a compare based on the original value, then do most other things based
// on the shifted value.
ma_vcmpz(input);
// Since we already know the sign bit, flip all numbers to be positive,
// stored in tmp.
ma_vabs(input, tmp);
as_vmrs(pc);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handleNeg, Assembler::Signed);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
// The argument is a positive number, truncation is the path to glory; Since
// it is known to be > 0.0, explicitly convert to a larger range, then a
// value that rounds to INT_MAX is explicitly different from an argument
// that clamps to INT_MAX.
// Add the biggest number less than 0.5 (not 0.5, because adding that to
// the biggest number less than 0.5 would undesirably round up to 1), and
// store the result into tmp.
loadConstantDouble(GetBiggestNumberLessThan(0.5), scratchDouble);
ma_vadd(scratchDouble, tmp, tmp);
ma_vcvt_F64_U32(tmp, scratchDouble.uintOverlay());
ma_vxfer(VFPRegister(scratchDouble).uintOverlay(), output);
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
ma_b(&fin);
bind(&handleZero);
// Move the top word of the double into the output reg, if it is non-zero,
// then the original value was -0.0
as_vxfer(output, InvalidReg, input, FloatToCore, Always, 1);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
bind(&handleNeg);
// Negative case, negate, then start dancing. This number may be positive,
// since we added 0.5.
// Add 0.5 to negative numbers, store the result into tmp
loadConstantDouble(0.5, scratchDouble);
ma_vadd(scratchDouble, tmp, tmp);
ma_vcvt_F64_U32(tmp, scratchDouble.uintOverlay());
ma_vxfer(VFPRegister(scratchDouble).uintOverlay(), output);
// -output is now a correctly rounded value, unless the original value was
// exactly halfway between two integers, at which point, it has been rounded
// away from zero, when it should be rounded towards \infty.
ma_vcvt_U32_F64(scratchDouble.uintOverlay(), scratchDouble);
compareDouble(scratchDouble, tmp);
as_sub(output, output, Imm8(1), LeaveCC, Equal);
// Negate the output. Since INT_MIN < -INT_MAX, even after adding 1, the
// result will still be a negative number.
as_rsb(output, output, Imm8(0), SetCC);
// If the result looks non-negative, then this value didn't actually fit
// into the int range, and special handling is required, or it was zero,
// which means the result is actually -0.0 which also requires special
// handling.
ma_b(bail, NotSigned);
bind(&fin);
}
void MacroAssemblerARMCompat::roundf(FloatRegister input, Register output,
Label* bail, FloatRegister tmp) {
Label handleZero;
Label handleNeg;
Label fin;
ScratchFloat32Scope scratchFloat(asMasm());
// Do a compare based on the original value, then do most other things based
// on the shifted value.
compareFloat(input, NoVFPRegister);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handleNeg, Assembler::Signed);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
// The argument is a positive number, truncation is the path to glory; Since
// it is known to be > 0.0, explicitly convert to a larger range, then a
// value that rounds to INT_MAX is explicitly different from an argument
// that clamps to INT_MAX.
// Add the biggest number less than 0.5f (not 0.5f, because adding that to
// the biggest number less than 0.5f would undesirably round up to 1), and
// store the result into tmp.
loadConstantFloat32(GetBiggestNumberLessThan(0.5f), scratchFloat);
ma_vadd_f32(scratchFloat, input, tmp);
// Note: it doesn't matter whether x + .5 === x or not here, as it doesn't
// affect the semantics of the float to unsigned conversion (in particular,
// we are not applying any fixup after the operation).
ma_vcvt_F32_U32(tmp, scratchFloat.uintOverlay());
ma_vxfer(VFPRegister(scratchFloat).uintOverlay(), output);
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
ma_b(&fin);
bind(&handleZero);
// Move the whole float32 into the output reg, if it is non-zero, then the
// original value was -0.0.
as_vxfer(output, InvalidReg, input, FloatToCore, Always, 0);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
bind(&handleNeg);
// Add 0.5 to negative numbers, storing the result into tmp.
ma_vneg_f32(input, tmp);
loadConstantFloat32(0.5f, scratchFloat);
ma_vadd_f32(tmp, scratchFloat, scratchFloat);
// Adding 0.5 to a float input has chances to yield the wrong result, if
// the input is too large. In this case, skip the -1 adjustment made below.
compareFloat(scratchFloat, tmp);
// Negative case, negate, then start dancing. This number may be positive,
// since we added 0.5.
// /!\ The conditional jump afterwards depends on these two instructions
// *not* setting the status flags. They need to not change after the
// comparison above.
ma_vcvt_F32_U32(scratchFloat, tmp.uintOverlay());
ma_vxfer(VFPRegister(tmp).uintOverlay(), output);
Label flipSign;
ma_b(&flipSign, Equal);
// -output is now a correctly rounded value, unless the original value was
// exactly halfway between two integers, at which point, it has been rounded
// away from zero, when it should be rounded towards \infty.
ma_vcvt_U32_F32(tmp.uintOverlay(), tmp);
compareFloat(tmp, scratchFloat);
as_sub(output, output, Imm8(1), LeaveCC, Equal);
// Negate the output. Since INT_MIN < -INT_MAX, even after adding 1, the
// result will still be a negative number.
bind(&flipSign);
as_rsb(output, output, Imm8(0), SetCC);
// If the result looks non-negative, then this value didn't actually fit
// into the int range, and special handling is required, or it was zero,
// which means the result is actually -0.0 which also requires special
// handling.
ma_b(bail, NotSigned);
bind(&fin);
}
void MacroAssemblerARMCompat::trunc(FloatRegister input, Register output,
Label* bail) {
Label handleZero;
Label handlePos;
Label fin;
compareDouble(input, NoVFPRegister);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handlePos, Assembler::NotSigned);
ScratchDoubleScope scratchDouble(asMasm());
// We are in the ]-Inf; 0[ range
// If we are in the ]-1; 0[ range => bailout
loadConstantDouble(-1.0, scratchDouble);
compareDouble(input, scratchDouble);
ma_b(bail, Assembler::GreaterThan);
// We are in the ]-Inf; -1] range: trunc(x) == -floor(-x) and floor can be
// computed with direct truncation here (x > 0).
ma_vneg(input, scratchDouble);
ma_vcvt_F64_U32(scratchDouble, scratchDouble.uintOverlay());
ma_vxfer(scratchDouble.uintOverlay(), output);
ma_neg(output, output, SetCC);
ma_b(bail, NotSigned);
ma_b(&fin);
// Test for 0.0 / -0.0: if the top word of the input double is not zero,
// then it was -0 and we need to bail out.
bind(&handleZero);
as_vxfer(output, InvalidReg, input, FloatToCore, Always, 1);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
// We are in the ]0; +inf] range: truncation is the path to glory. Since
// it is known to be > 0.0, explicitly convert to a larger range, then a
// value that rounds to INT_MAX is explicitly different from an argument
// that clamps to INT_MAX.
bind(&handlePos);
ma_vcvt_F64_U32(input, scratchDouble.uintOverlay());
ma_vxfer(scratchDouble.uintOverlay(), output);
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
bind(&fin);
}
void MacroAssemblerARMCompat::truncf(FloatRegister input, Register output,
Label* bail) {
Label handleZero;
Label handlePos;
Label fin;
compareFloat(input, NoVFPRegister);
// NaN is always a bail condition, just bail directly.
ma_b(bail, Assembler::Overflow);
ma_b(&handleZero, Assembler::Equal);
ma_b(&handlePos, Assembler::NotSigned);
// We are in the ]-Inf; 0[ range
// If we are in the ]-1; 0[ range => bailout
{
ScratchFloat32Scope scratch(asMasm());
loadConstantFloat32(-1.f, scratch);
compareFloat(input, scratch);
ma_b(bail, Assembler::GreaterThan);
}
// We are in the ]-Inf; -1] range: trunc(x) == -floor(-x) and floor can be
// computed with direct truncation here (x > 0).
{
ScratchDoubleScope scratchDouble(asMasm());
FloatRegister scratchFloat = scratchDouble.asSingle();
FloatRegister scratchUInt = scratchDouble.uintOverlay();
ma_vneg_f32(input, scratchFloat);
ma_vcvt_F32_U32(scratchFloat, scratchUInt);
ma_vxfer(scratchUInt, output);
ma_neg(output, output, SetCC);
ma_b(bail, NotSigned);
ma_b(&fin);
}
// Test for 0.0 / -0.0: if the top word of the input double is not zero,
// then it was -0 and we need to bail out.
bind(&handleZero);
as_vxfer(output, InvalidReg, VFPRegister(input).singleOverlay(), FloatToCore,
Always, 0);
as_cmp(output, Imm8(0));
ma_b(bail, NonZero);
ma_b(&fin);
// We are in the ]0; +inf] range: truncation is the path to glory; Since
// it is known to be > 0.0, explicitly convert to a larger range, then a
// value that rounds to INT_MAX is explicitly different from an argument
bind(&handlePos);
{
// The argument is a positive number,
// that clamps to INT_MAX.
{
ScratchFloat32Scope scratch(asMasm());
ma_vcvt_F32_U32(input, scratch.uintOverlay());
ma_vxfer(VFPRegister(scratch).uintOverlay(), output);
}
ma_mov(output, output, SetCC);
ma_b(bail, Signed);
}
bind(&fin);
}
void MacroAssemblerARMCompat::profilerEnterFrame(Register framePtr,
Register scratch) {
asMasm().loadJSContext(scratch);
loadPtr(Address(scratch, offsetof(JSContext, profilingActivation_)), scratch);
storePtr(framePtr,
Address(scratch, JitActivation::offsetOfLastProfilingFrame()));
storePtr(ImmPtr(nullptr),
Address(scratch, JitActivation::offsetOfLastProfilingCallSite()));
}
void MacroAssemblerARMCompat::profilerExitFrame() {
jump(asMasm().runtime()->jitRuntime()->getProfilerExitFrameTail());
}
MacroAssembler& MacroAssemblerARM::asMasm() {
return *static_cast<MacroAssembler*>(this);
}
const MacroAssembler& MacroAssemblerARM::asMasm() const {
return *static_cast<const MacroAssembler*>(this);
}
MacroAssembler& MacroAssemblerARMCompat::asMasm() {
return *static_cast<MacroAssembler*>(this);
}
const MacroAssembler& MacroAssemblerARMCompat::asMasm() const {
return *static_cast<const MacroAssembler*>(this);
}
void MacroAssembler::subFromStackPtr(Imm32 imm32) {
ScratchRegisterScope scratch(*this);
if (imm32.value) {
ma_sub(imm32, sp, scratch);
}
}
//{{{ check_macroassembler_style
// ===============================================================
// MacroAssembler high-level usage.
void MacroAssembler::flush() { Assembler::flush(); }
void MacroAssembler::comment(const char* msg) { Assembler::comment(msg); }
// ===============================================================
// Stack manipulation functions.
size_t MacroAssembler::PushRegsInMaskSizeInBytes(LiveRegisterSet set) {
return set.gprs().size() * sizeof(intptr_t) + set.fpus().getPushSizeInBytes();
}
void MacroAssembler::PushRegsInMask(LiveRegisterSet set) {
mozilla::DebugOnly<size_t> framePushedInitial = framePushed();
int32_t diffF = set.fpus().getPushSizeInBytes();
int32_t diffG = set.gprs().size() * sizeof(intptr_t);
if (set.gprs().size() > 1) {
adjustFrame(diffG);
startDataTransferM(IsStore, StackPointer, DB, WriteBack);
for (GeneralRegisterBackwardIterator iter(set.gprs()); iter.more();
++iter) {
diffG -= sizeof(intptr_t);
transferReg(*iter);
}
finishDataTransfer();
} else {
reserveStack(diffG);
for (GeneralRegisterBackwardIterator iter(set.gprs()); iter.more();
++iter) {
diffG -= sizeof(intptr_t);
storePtr(*iter, Address(StackPointer, diffG));
}
}
MOZ_ASSERT(diffG == 0);
// It's possible that the logic is just fine as it is if the reduced set
// maps SIMD pairs to plain doubles and transferMultipleByRuns() stores
// and loads doubles.
#ifdef ENABLE_WASM_SIMD
# error "Needs more careful logic if SIMD is enabled"
#endif
adjustFrame(diffF);
diffF += transferMultipleByRuns(set.fpus(), IsStore, StackPointer, DB);
MOZ_ASSERT(diffF == 0);
MOZ_ASSERT(framePushed() - framePushedInitial ==
PushRegsInMaskSizeInBytes(set));
}
void MacroAssembler::storeRegsInMask(LiveRegisterSet set, Address dest,
Register scratch) {
mozilla::DebugOnly<size_t> offsetInitial = dest.offset;
int32_t diffF = set.fpus().getPushSizeInBytes();
int32_t diffG = set.gprs().size() * sizeof(intptr_t);
MOZ_ASSERT(dest.offset >= diffF + diffG);
if (set.gprs().size() > 1) {
computeEffectiveAddress(dest, scratch);
startDataTransferM(IsStore, scratch, DB, WriteBack);
for (GeneralRegisterBackwardIterator iter(set.gprs()); iter.more();
++iter) {
diffG -= sizeof(intptr_t);
dest.offset -= sizeof(intptr_t);
transferReg(*iter);
}
finishDataTransfer();
} else {
for (GeneralRegisterBackwardIterator iter(set.gprs()); iter.more();
++iter) {
diffG -= sizeof(intptr_t);
dest.offset -= sizeof(intptr_t);
storePtr(*iter, dest);
}
}
MOZ_ASSERT(diffG == 0);
(void)diffG;
// See above.
#ifdef ENABLE_WASM_SIMD
# error "Needs more careful logic if SIMD is enabled"
#endif
MOZ_ASSERT(diffF >= 0);
if (diffF > 0) {
computeEffectiveAddress(dest, scratch);
diffF += transferMultipleByRuns(set.fpus(), IsStore, scratch, DB);
}
MOZ_ASSERT(diffF == 0);
// "The amount of space actually used does not exceed what
// `PushRegsInMaskSizeInBytes` claims will be used."
MOZ_ASSERT(offsetInitial - dest.offset <= PushRegsInMaskSizeInBytes(set));
}
void MacroAssembler::PopRegsInMaskIgnore(LiveRegisterSet set,
LiveRegisterSet ignore) {
mozilla::DebugOnly<size_t> framePushedInitial = framePushed();
int32_t diffG = set.gprs().size() * sizeof(intptr_t);
int32_t diffF = set.fpus().getPushSizeInBytes();
const int32_t reservedG = diffG;
const int32_t reservedF = diffF;
// See above.
#ifdef ENABLE_WASM_SIMD
# error "Needs more careful logic if SIMD is enabled"
#endif
// ARM can load multiple registers at once, but only if we want back all
// the registers we previously saved to the stack.
if (ignore.emptyFloat()) {
diffF -= transferMultipleByRuns(set.fpus(), IsLoad, StackPointer, IA);
adjustFrame(-reservedF);
} else {
LiveFloatRegisterSet fpset(set.fpus().reduceSetForPush());
LiveFloatRegisterSet fpignore(ignore.fpus().reduceSetForPush());
for (FloatRegisterBackwardIterator iter(fpset); iter.more(); ++iter) {
diffF -= (*iter).size();
if (!fpignore.has(*iter)) {
loadDouble(Address(StackPointer, diffF), *iter);
}
}
freeStack(reservedF);
}
MOZ_ASSERT(diffF == 0);
if (set.gprs().size() > 1 && ignore.emptyGeneral()) {
startDataTransferM(IsLoad, StackPointer, IA, WriteBack);
for (GeneralRegisterBackwardIterator iter(set.gprs()); iter.more();
++iter) {
diffG -= sizeof(intptr_t);
transferReg(*iter);
}
finishDataTransfer();
adjustFrame(-reservedG);
} else {
for (GeneralRegisterBackwardIterator iter(set.gprs()); iter.more();
++iter) {
diffG -= sizeof(intptr_t);
if (!ignore.has(*iter)) {
loadPtr(Address(StackPointer, diffG), *iter);
}
}
freeStack(reservedG);
}
MOZ_ASSERT(diffG == 0);
MOZ_ASSERT(framePushedInitial - framePushed() ==
PushRegsInMaskSizeInBytes(set));
}
void MacroAssembler::Push(Register reg) {
push(reg);
adjustFrame(sizeof(intptr_t));
}
void MacroAssembler::Push(const Imm32 imm) {
push(imm);
adjustFrame(sizeof(intptr_t));
}
void MacroAssembler::Push(const ImmWord imm) {
push(imm);
adjustFrame(sizeof(intptr_t));
}
void MacroAssembler::Push(const ImmPtr imm) {
Push(ImmWord(uintptr_t(imm.value)));
}
void MacroAssembler::Push(const ImmGCPtr ptr) {
push(ptr);
adjustFrame(sizeof(intptr_t));
}
void MacroAssembler::Push(FloatRegister reg) {
VFPRegister r = VFPRegister(reg);
ma_vpush(VFPRegister(reg));
adjustFrame(r.size());
}
void MacroAssembler::PushBoxed(FloatRegister reg) {
MOZ_ASSERT(reg.isDouble());
Push(reg);
}
void MacroAssembler::Pop(Register reg) {
ma_pop(reg);
adjustFrame(-sizeof(intptr_t));
}
void MacroAssembler::Pop(FloatRegister reg) {
ma_vpop(reg);
adjustFrame(-reg.size());
}
void MacroAssembler::Pop(const ValueOperand& val) {
popValue(val);
adjustFrame(-sizeof(Value));
}
void MacroAssembler::PopStackPtr() {
as_dtr(IsLoad, 32, Offset, sp, DTRAddr(sp, DtrOffImm(0)));
adjustFrame(-sizeof(intptr_t));
}
void MacroAssembler::freeStackTo(uint32_t framePushed) {
MOZ_ASSERT(framePushed <= framePushed_);
ScratchRegisterScope scratch(*this);
ma_sub(FramePointer, Imm32(int32_t(framePushed)), sp, scratch, LeaveCC,
Always);
framePushed_ = framePushed;
}
// ===============================================================
// Simple call functions.
CodeOffset MacroAssembler::call(Register reg) {
as_blx(reg);
return CodeOffset(currentOffset());
}
CodeOffset MacroAssembler::call(Label* label) {
// For now, assume that it'll be nearby.
as_bl(label, Always);
return CodeOffset(currentOffset());
}
void MacroAssembler::call(ImmWord imm) { call(ImmPtr((void*)imm.value)); }
void MacroAssembler::call(ImmPtr imm) {
BufferOffset bo = m_buffer.nextOffset();
addPendingJump(bo, imm, RelocationKind::HARDCODED);
ma_call(imm);
}
CodeOffset MacroAssembler::call(wasm::SymbolicAddress imm) {
movePtr(imm, CallReg);
return call(CallReg);
}
void MacroAssembler::call(const Address& addr) {
loadPtr(addr, CallReg);
call(CallReg);
}
void MacroAssembler::call(JitCode* c) {
BufferOffset bo = m_buffer.nextOffset();
addPendingJump(bo, ImmPtr(c->raw()), RelocationKind::JITCODE);
ScratchRegisterScope scratch(*this);
ma_movPatchable(ImmPtr(c->raw()), scratch, Always);
callJitNoProfiler(scratch);
}
CodeOffset MacroAssembler::callWithPatch() {
// The caller ensures that the call is always in range using thunks (below)
// as necessary.
as_bl(BOffImm(), Always, /* documentation */ nullptr);
return CodeOffset(currentOffset());
}
void MacroAssembler::patchCall(uint32_t callerOffset, uint32_t calleeOffset) {
BufferOffset inst(callerOffset - 4);
BOffImm off = BufferOffset(calleeOffset).diffB<BOffImm>(inst);
MOZ_RELEASE_ASSERT(!off.isInvalid(),
"Failed to insert necessary far jump islands");
as_bl(off, Always, inst);
}
CodeOffset MacroAssembler::farJumpWithPatch() {
static_assert(32 * 1024 * 1024 - JumpImmediateRange >
wasm::MaxFuncs * 3 * sizeof(Instruction),
"always enough space for thunks");
// The goal of the thunk is to be able to jump to any address without the
// usual 32MiB branch range limitation. Additionally, to make the thunk
// simple to use, the thunk does not use the constant pool or require
// patching an absolute address. Instead, a relative offset is used which
// can be patched during compilation.
// Inhibit pools since these three words must be contiguous so that the offset
// calculations below are valid.
AutoForbidPoolsAndNops afp(this, 3);
// When pc is used, the read value is the address of the instruction + 8.
// This is exactly the address of the uint32 word we want to load.
ScratchRegisterScope scratch(*this);
ma_ldr(DTRAddr(pc, DtrOffImm(0)), scratch);
// Branch by making pc the destination register.
ma_add(pc, scratch, pc, LeaveCC, Always);
// Allocate space which will be patched by patchFarJump().
CodeOffset farJump(currentOffset());
writeInst(UINT32_MAX);
return farJump;
}
void MacroAssembler::patchFarJump(CodeOffset farJump, uint32_t targetOffset) {
uint32_t* u32 =
reinterpret_cast<uint32_t*>(editSrc(BufferOffset(farJump.offset())));
MOZ_ASSERT(*u32 == UINT32_MAX);
uint32_t addOffset = farJump.offset() - 4;
MOZ_ASSERT(editSrc(BufferOffset(addOffset))->is<InstALU>());
// When pc is read as the operand of the add, its value is the address of
// the add instruction + 8.
*u32 = (targetOffset - addOffset) - 8;
}
CodeOffset MacroAssembler::nopPatchableToCall() {
AutoForbidPoolsAndNops afp(this,
/* max number of instructions in scope = */ 1);
ma_nop();
return CodeOffset(currentOffset());
}
void MacroAssembler::patchNopToCall(uint8_t* call, uint8_t* target) {
uint8_t* inst = call - 4;
MOZ_ASSERT(reinterpret_cast<Instruction*>(inst)->is<InstBLImm>() ||
reinterpret_cast<Instruction*>(inst)->is<InstNOP>());
new (inst) InstBLImm(BOffImm(target - inst), Assembler::Always);
}
void MacroAssembler::patchCallToNop(uint8_t* call) {
uint8_t* inst = call - 4;
MOZ_ASSERT(reinterpret_cast<Instruction*>(inst)->is<InstBLImm>() ||
reinterpret_cast<Instruction*>(inst)->is<InstNOP>());
new (inst) InstNOP();
}
void MacroAssembler::pushReturnAddress() { push(lr); }
void MacroAssembler::popReturnAddress() { pop(lr); }
// ===============================================================
// ABI function calls.
void MacroAssembler::setupUnalignedABICall(Register scratch) {
setupNativeABICall();
dynamicAlignment_ = true;
ma_mov(sp, scratch);
// Force sp to be aligned.
as_bic(sp, sp, Imm8(ABIStackAlignment - 1));
ma_push(scratch);
}
void MacroAssembler::callWithABIPre(uint32_t* stackAdjust, bool callFromWasm) {
MOZ_ASSERT(inCall_);
uint32_t stackForCall = abiArgs_.stackBytesConsumedSoFar();
if (dynamicAlignment_) {
// sizeof(intptr_t) accounts for the saved stack pointer pushed by
// setupUnalignedABICall.
stackForCall += ComputeByteAlignment(stackForCall + sizeof(intptr_t),
ABIStackAlignment);
} else {
uint32_t alignmentAtPrologue = callFromWasm ? sizeof(wasm::Frame) : 0;
stackForCall += ComputeByteAlignment(
stackForCall + framePushed() + alignmentAtPrologue, ABIStackAlignment);
}
*stackAdjust = stackForCall;
reserveStack(stackForCall);
// Position all arguments.
{
enoughMemory_ &= moveResolver_.resolve();
if (!enoughMemory_) {
return;
}
MoveEmitter emitter(*this);
emitter.emit(moveResolver_);
emitter.finish();
}
assertStackAlignment(ABIStackAlignment);
// Save the lr register if we need to preserve it.
if (secondScratchReg_ != lr) {
ma_mov(lr, secondScratchReg_);
}
}
void MacroAssembler::callWithABIPost(uint32_t stackAdjust, ABIType result,
bool callFromWasm) {
if (secondScratchReg_ != lr) {
ma_mov(secondScratchReg_, lr);
}
// Calls to native functions in wasm pass through a thunk which already
// fixes up the return value for us.
if (!callFromWasm && !UseHardFpABI()) {
switch (result) {
case ABIType::Float64:
// Move double from r0/r1 to ReturnFloatReg.
ma_vxfer(r0, r1, ReturnDoubleReg);
break;
case ABIType::Float32:
// Move float32 from r0 to ReturnFloatReg.
ma_vxfer(r0, ReturnFloat32Reg);
break;
case ABIType::General:
case ABIType::Int64:
break;
default:
MOZ_CRASH("unexpected callWithABI result");
}
}
freeStack(stackAdjust);
if (dynamicAlignment_) {
// While the x86 supports pop esp, on ARM that isn't well defined, so
// just do it manually.
as_dtr(IsLoad, 32, Offset, sp, DTRAddr(sp, DtrOffImm(0)));
}
#ifdef DEBUG
MOZ_ASSERT(inCall_);
inCall_ = false;
#endif
}
void MacroAssembler::callWithABINoProfiler(Register fun, ABIType result) {
// Load the callee in r12, as above.
ma_mov(fun, r12);
uint32_t stackAdjust;
callWithABIPre(&stackAdjust);
call(r12);
callWithABIPost(stackAdjust, result);
}
void MacroAssembler::callWithABINoProfiler(const Address& fun, ABIType result) {
// Load the callee in r12, no instruction between the ldr and call should
// clobber it. Note that we can't use fun.base because it may be one of the
// IntArg registers clobbered before the call.
{
ScratchRegisterScope scratch(*this);
ma_ldr(fun, r12, scratch);
}
uint32_t stackAdjust;
callWithABIPre(&stackAdjust);
call(r12);
callWithABIPost(stackAdjust, result);
}
// ===============================================================
// Jit Frames.
uint32_t MacroAssembler::pushFakeReturnAddress(Register scratch) {
// On ARM any references to the pc, adds an additional 8 to it, which
// correspond to 2 instructions of 4 bytes. Thus we use an additional nop
// to pad until we reach the pushed pc.
//
// Note: In practice this should not be necessary, as this fake return
// address is never used for resuming any execution. Thus theoriticaly we
// could just do a Push(pc), and ignore the nop as well as the pool.
enterNoPool(2);
DebugOnly<uint32_t> offsetBeforePush = currentOffset();
Push(pc); // actually pushes $pc + 8.
ma_nop();
uint32_t pseudoReturnOffset = currentOffset();
leaveNoPool();
MOZ_ASSERT_IF(!oom(), pseudoReturnOffset - offsetBeforePush == 8);
return pseudoReturnOffset;
}
void MacroAssembler::enterFakeExitFrameForWasm(Register cxreg, Register scratch,
ExitFrameType type) {
enterFakeExitFrame(cxreg, scratch, type);
}
// ===============================================================
// Move instructions
void MacroAssembler::moveValue(const TypedOrValueRegister& src,
const ValueOperand& dest) {
if (src.hasValue()) {
moveValue(src.valueReg(), dest);
return;
}
MIRType type = src.type();
AnyRegister reg = src.typedReg();
if (!IsFloatingPointType(type)) {
if (reg.gpr() != dest.payloadReg()) {
mov(reg.gpr(), dest.payloadReg());
}
mov(ImmWord(MIRTypeToTag(type)), dest.typeReg());
return;
}
ScratchDoubleScope scratch(*this);
FloatRegister freg = reg.fpu();
if (type == MIRType::Float32) {
convertFloat32ToDouble(freg, scratch);
freg = scratch;
}
ma_vxfer(freg, dest.payloadReg(), dest.typeReg());
}
void MacroAssembler::moveValue(const ValueOperand& src,
const ValueOperand& dest) {
Register s0 = src.typeReg();
Register s1 = src.payloadReg();
Register d0 = dest.typeReg();
Register d1 = dest.payloadReg();
// Either one or both of the source registers could be the same as a
// destination register.
if (s1 == d0) {
if (s0 == d1) {
// If both are, this is just a swap of two registers.
ScratchRegisterScope scratch(*this);
MOZ_ASSERT(d1 != scratch);
MOZ_ASSERT(d0 != scratch);
ma_mov(d1, scratch);
ma_mov(d0, d1);
ma_mov(scratch, d0);
return;
}
// If only one is, copy that source first.
std::swap(s0, s1);
std::swap(d0, d1);
}
if (s0 != d0) {
ma_mov(s0, d0);
}
if (s1 != d1) {
ma_mov(s1, d1);
}
}
void MacroAssembler::moveValue(const Value& src, const ValueOperand& dest) {
ma_mov(Imm32(src.toNunboxTag()), dest.typeReg());
if (src.isGCThing()) {
ma_mov(ImmGCPtr(src.toGCThing()), dest.payloadReg());
} else {
ma_mov(Imm32(src.toNunboxPayload()), dest.payloadReg());
}
}
// ===============================================================
// Branch functions
void MacroAssembler::loadStoreBuffer(Register ptr, Register buffer) {
ma_lsr(Imm32(gc::ChunkShift), ptr, buffer);
ma_lsl(Imm32(gc::ChunkShift), buffer, buffer);
load32(Address(buffer, gc::ChunkStoreBufferOffset), buffer);
}
void MacroAssembler::branchPtrInNurseryChunk(Condition cond, Register ptr,
Register temp, Label* label) {
Maybe<SecondScratchRegisterScope> scratch2;
if (temp == Register::Invalid()) {
scratch2.emplace(*this);
temp = scratch2.ref();
}
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
MOZ_ASSERT(ptr != temp);
ma_lsr(Imm32(gc::ChunkShift), ptr, temp);
ma_lsl(Imm32(gc::ChunkShift), temp, temp);
loadPtr(Address(temp, gc::ChunkStoreBufferOffset), temp);
branchPtr(InvertCondition(cond), temp, ImmWord(0), label);
}
void MacroAssembler::branchValueIsNurseryCell(Condition cond,
const Address& address,
Register temp, Label* label) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
Label done;
branchTestGCThing(Assembler::NotEqual, address,
cond == Assembler::Equal ? &done : label);
loadPtr(ToPayload(address), temp);
SecondScratchRegisterScope scratch2(*this);
branchPtrInNurseryChunk(cond, temp, scratch2, label);
bind(&done);
}
void MacroAssembler::branchValueIsNurseryCell(Condition cond,
ValueOperand value, Register temp,
Label* label) {
MOZ_ASSERT(cond == Assembler::Equal || cond == Assembler::NotEqual);
Label done;
branchTestGCThing(Assembler::NotEqual, value,
cond == Assembler::Equal ? &done : label);
branchPtrInNurseryChunk(cond, value.payloadReg(), temp, label);
bind(&done);
}
void MacroAssembler::branchTestValue(Condition cond, const ValueOperand& lhs,
const Value& rhs, Label* label) {
MOZ_ASSERT(cond == Equal || cond == NotEqual);
// If cond == NotEqual, branch when a.payload != b.payload || a.tag !=
// b.tag. If the payloads are equal, compare the tags. If the payloads are
// not equal, short circuit true (NotEqual).
//
// If cand == Equal, branch when a.payload == b.payload && a.tag == b.tag.
// If the payloads are equal, compare the tags. If the payloads are not
// equal, short circuit false (NotEqual).
ScratchRegisterScope scratch(*this);
if (rhs.isGCThing()) {
ma_cmp(lhs.payloadReg(), ImmGCPtr(rhs.toGCThing()), scratch);
} else {
ma_cmp(lhs.payloadReg(), Imm32(rhs.toNunboxPayload()), scratch);
}
ma_cmp(lhs.typeReg(), Imm32(rhs.toNunboxTag()), scratch, Equal);
ma_b(label, cond);
}
// ========================================================================
// Memory access primitives.
template <typename T>
void MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value,
MIRType valueType, const T& dest) {
MOZ_ASSERT(valueType < MIRType::Value);
if (valueType == MIRType::Double) {
storeDouble(value.reg().typedReg().fpu(), dest);
return;
}
// Store the type tag.
storeTypeTag(ImmType(ValueTypeFromMIRType(valueType)), dest);
// Store the payload.
if (value.constant()) {
storePayload(value.value(), dest);
} else {
storePayload(value.reg().typedReg().gpr(), dest);
}
}
template void MacroAssembler::storeUnboxedValue(const ConstantOrRegister& value,
MIRType valueType,
const Address& dest);
template void MacroAssembler::storeUnboxedValue(
const ConstantOrRegister& value, MIRType valueType,
const BaseObjectElementIndex& dest);
FaultingCodeOffset MacroAssembler::wasmTrapInstruction() {
return FaultingCodeOffset(as_illegal_trap().getOffset());
}
void MacroAssembler::wasmBoundsCheck32(Condition cond, Register index,
Register boundsCheckLimit, Label* ok) {
as_cmp(index, O2Reg(boundsCheckLimit));
as_b(ok, cond);
if (JitOptions.spectreIndexMasking) {
ma_mov(boundsCheckLimit, index, LeaveCC, cond);
}
}
void MacroAssembler::wasmBoundsCheck32(Condition cond, Register index,
Address boundsCheckLimit, Label* ok) {
ScratchRegisterScope scratch(*this);
// We want to do a word load from
// [boundsCheckLimit.base, #+boundsCheckLimit.offset],
// but the offset might exceed 4095, so we can't use ma_ldr directly.
// ma_dataTransferN will handle this correctly, but needs a scratch reg as
// an address temporary for the big-offset case. The scratch reg is also
// used in all cases for the loaded value; that's OK.
ma_dataTransferN(IsLoad, /*size=*/32, /*IsSigned=*/false,
boundsCheckLimit.base, Imm32(boundsCheckLimit.offset),
scratch, scratch);
as_cmp(index, O2Reg(scratch));
as_b(ok, cond);
if (JitOptions.spectreIndexMasking) {
ma_mov(scratch, index, LeaveCC, cond);
}
}
void MacroAssembler::wasmBoundsCheck64(Condition cond, Register64 index,
Register64 boundsCheckLimit, Label* ok) {
Label notOk;
cmp32(index.high, Imm32(0));
j(Assembler::NonZero, ¬Ok);
wasmBoundsCheck32(cond, index.low, boundsCheckLimit.low, ok);
bind(¬Ok);
}
void MacroAssembler::wasmBoundsCheck64(Condition cond, Register64 index,
Address boundsCheckLimit, Label* ok) {
Label notOk;
cmp32(index.high, Imm32(0));
j(Assembler::NonZero, ¬Ok);
wasmBoundsCheck32(cond, index.low, boundsCheckLimit, ok);
bind(¬Ok);
}
void MacroAssembler::wasmTruncateDoubleToUInt32(FloatRegister input,
Register output,
bool isSaturating,
Label* oolEntry) {
wasmTruncateToInt32(input, output, MIRType::Double, /* isUnsigned= */ true,
isSaturating, oolEntry);
}
void MacroAssembler::wasmTruncateDoubleToInt32(FloatRegister input,
Register output,
bool isSaturating,
Label* oolEntry) {
wasmTruncateToInt32(input, output, MIRType::Double, /* isUnsigned= */ false,
isSaturating, oolEntry);
}
void MacroAssembler::wasmTruncateFloat32ToUInt32(FloatRegister input,
Register output,
bool isSaturating,
Label* oolEntry) {
wasmTruncateToInt32(input, output, MIRType::Float32, /* isUnsigned= */ true,
isSaturating, oolEntry);
}
void MacroAssembler::wasmTruncateFloat32ToInt32(FloatRegister input,
Register output,
bool isSaturating,
Label* oolEntry) {
wasmTruncateToInt32(input, output, MIRType::Float32, /* isUnsigned= */ false,
isSaturating, oolEntry);
}
void MacroAssembler::oolWasmTruncateCheckF32ToI32(FloatRegister input,
Register output,
TruncFlags flags,
wasm::BytecodeOffset off,
Label* rejoin) {
outOfLineWasmTruncateToIntCheck(input, MIRType::Float32, MIRType::Int32,
flags, rejoin, off);
}
void MacroAssembler::oolWasmTruncateCheckF64ToI32(FloatRegister input,
Register output,
TruncFlags flags,
wasm::BytecodeOffset off,
Label* rejoin) {
outOfLineWasmTruncateToIntCheck(input, MIRType::Double, MIRType::Int32, flags,
rejoin, off);
}
void MacroAssembler::oolWasmTruncateCheckF32ToI64(FloatRegister input,
Register64 output,
TruncFlags flags,
wasm::BytecodeOffset off,
Label* rejoin) {
outOfLineWasmTruncateToIntCheck(input, MIRType::Float32, MIRType::Int64,
flags, rejoin, off);
}
void MacroAssembler::oolWasmTruncateCheckF64ToI64(FloatRegister input,
Register64 output,
TruncFlags flags,
wasm::BytecodeOffset off,
Label* rejoin) {
outOfLineWasmTruncateToIntCheck(input, MIRType::Double, MIRType::Int64, flags,
rejoin, off);
}
void MacroAssembler::wasmLoad(const wasm::MemoryAccessDesc& access,
Register memoryBase, Register ptr,
Register ptrScratch, AnyRegister output) {
wasmLoadImpl(access, memoryBase, ptr, ptrScratch, output,
Register64::Invalid());
}
void MacroAssembler::wasmLoadI64(const wasm::MemoryAccessDesc& access,
Register memoryBase, Register ptr,
Register ptrScratch, Register64 output) {
MOZ_ASSERT_IF(access.isAtomic(), access.byteSize() <= 4);
wasmLoadImpl(access, memoryBase, ptr, ptrScratch, AnyRegister(), output);
}
void MacroAssembler::wasmStore(const wasm::MemoryAccessDesc& access,
AnyRegister value, Register memoryBase,
Register ptr, Register ptrScratch) {
wasmStoreImpl(access, value, Register64::Invalid(), memoryBase, ptr,
ptrScratch);
}
void MacroAssembler::wasmStoreI64(const wasm::MemoryAccessDesc& access,
Register64 value, Register memoryBase,
Register ptr, Register ptrScratch) {
MOZ_ASSERT(!access.isAtomic());
wasmStoreImpl(access, AnyRegister(), value, memoryBase, ptr, ptrScratch);
}
// ========================================================================
// Primitive atomic operations.
static Register ComputePointerForAtomic(MacroAssembler& masm,
const BaseIndex& src, Register r) {
Register base = src.base;
Register index = src.index;
uint32_t scale = Imm32::ShiftOf(src.scale).value;
int32_t offset = src.offset;
ScratchRegisterScope scratch(masm);
masm.as_add(r, base, lsl(index, scale));
if (offset != 0) {
masm.ma_add(r, Imm32(offset), r, scratch);
}
return r;
}
static Register ComputePointerForAtomic(MacroAssembler& masm,
const Address& src, Register r) {
ScratchRegisterScope scratch(masm);
if (src.offset == 0) {
return src.base;
}
masm.ma_add(src.base, Imm32(src.offset), r, scratch);
return r;
}
// General algorithm:
//
// ... ptr, <addr> ; compute address of item
// dmb
// L0 ldrex* output, [ptr]
// sxt* output, output, 0 ; sign-extend if applicable
// *xt* tmp, oldval, 0 ; sign-extend or zero-extend if applicable
// cmp output, tmp
// bne L1 ; failed - values are different
// strex* tmp, newval, [ptr]
// cmp tmp, 1
// beq L0 ; failed - location is dirty, retry
// L1 dmb
//
// However note that that discussion uses 'isb' as the trailing fence.
// I've not quite figured out why, and I've gone with dmb here which
// is safe. Also see the LLVM source, which uses 'dmb ish' generally.
// (Apple's Swift CPU apparently handles ish in a non-default, faster
// way.)
template <typename T>
static void CompareExchange(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Scalar::Type type, Synchronization sync,
const T& mem, Register oldval, Register newval,
Register output) {
bool signExtend = Scalar::isSignedIntType(type);
unsigned nbytes = Scalar::byteSize(type);
MOZ_ASSERT(nbytes <= 4);
Label again;
Label done;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
ScratchRegisterScope scratch(masm);
// NOTE: the generated code must match the assembly code in gen_cmpxchg in
// GenerateAtomicOperations.py
masm.memoryBarrierBefore(sync);
masm.bind(&again);
BufferOffset firstAccess;
switch (nbytes) {
case 1:
firstAccess = masm.as_ldrexb(output, ptr);
if (signExtend) {
masm.as_sxtb(output, output, 0);
masm.as_sxtb(scratch, oldval, 0);
} else {
masm.as_uxtb(scratch, oldval, 0);
}
break;
case 2:
firstAccess = masm.as_ldrexh(output, ptr);
if (signExtend) {
masm.as_sxth(output, output, 0);
masm.as_sxth(scratch, oldval, 0);
} else {
masm.as_uxth(scratch, oldval, 0);
}
break;
case 4:
firstAccess = masm.as_ldrex(output, ptr);
break;
default:
MOZ_CRASH();
}
if (access) {
masm.append(*access, js::wasm::TrapMachineInsnForLoad(nbytes),
FaultingCodeOffset(firstAccess.getOffset()));
}
if (nbytes < 4) {
masm.as_cmp(output, O2Reg(scratch));
} else {
masm.as_cmp(output, O2Reg(oldval));
}
masm.as_b(&done, MacroAssembler::NotEqual);
switch (nbytes) {
case 1:
masm.as_strexb(scratch, newval, ptr);
break;
case 2:
masm.as_strexh(scratch, newval, ptr);
break;
case 4:
masm.as_strex(scratch, newval, ptr);
break;
default:
MOZ_CRASH();
}
masm.as_cmp(scratch, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.bind(&done);
masm.memoryBarrierAfter(sync);
}
void MacroAssembler::compareExchange(Scalar::Type type, Synchronization sync,
const Address& address, Register oldval,
Register newval, Register output) {
CompareExchange(*this, nullptr, type, sync, address, oldval, newval, output);
}
void MacroAssembler::compareExchange(Scalar::Type type, Synchronization sync,
const BaseIndex& address, Register oldval,
Register newval, Register output) {
CompareExchange(*this, nullptr, type, sync, address, oldval, newval, output);
}
void MacroAssembler::wasmCompareExchange(const wasm::MemoryAccessDesc& access,
const Address& mem, Register oldval,
Register newval, Register output) {
CompareExchange(*this, &access, access.type(), access.sync(), mem, oldval,
newval, output);
}
void MacroAssembler::wasmCompareExchange(const wasm::MemoryAccessDesc& access,
const BaseIndex& mem, Register oldval,
Register newval, Register output) {
CompareExchange(*this, &access, access.type(), access.sync(), mem, oldval,
newval, output);
}
template <typename T>
static void AtomicExchange(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Scalar::Type type, Synchronization sync,
const T& mem, Register value, Register output) {
bool signExtend = Scalar::isSignedIntType(type);
unsigned nbytes = Scalar::byteSize(type);
MOZ_ASSERT(nbytes <= 4);
Label again;
Label done;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
ScratchRegisterScope scratch(masm);
// NOTE: the generated code must match the assembly code in gen_exchange in
// GenerateAtomicOperations.py
masm.memoryBarrierBefore(sync);
masm.bind(&again);
BufferOffset firstAccess;
switch (nbytes) {
case 1:
firstAccess = masm.as_ldrexb(output, ptr);
if (signExtend) {
masm.as_sxtb(output, output, 0);
}
masm.as_strexb(scratch, value, ptr);
break;
case 2:
firstAccess = masm.as_ldrexh(output, ptr);
if (signExtend) {
masm.as_sxth(output, output, 0);
}
masm.as_strexh(scratch, value, ptr);
break;
case 4:
firstAccess = masm.as_ldrex(output, ptr);
masm.as_strex(scratch, value, ptr);
break;
default:
MOZ_CRASH();
}
if (access) {
masm.append(*access, js::wasm::TrapMachineInsnForLoad(nbytes),
FaultingCodeOffset(firstAccess.getOffset()));
}
masm.as_cmp(scratch, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.bind(&done);
masm.memoryBarrierAfter(sync);
}
void MacroAssembler::atomicExchange(Scalar::Type type, Synchronization sync,
const Address& address, Register value,
Register output) {
AtomicExchange(*this, nullptr, type, sync, address, value, output);
}
void MacroAssembler::atomicExchange(Scalar::Type type, Synchronization sync,
const BaseIndex& address, Register value,
Register output) {
AtomicExchange(*this, nullptr, type, sync, address, value, output);
}
void MacroAssembler::wasmAtomicExchange(const wasm::MemoryAccessDesc& access,
const Address& mem, Register value,
Register output) {
AtomicExchange(*this, &access, access.type(), access.sync(), mem, value,
output);
}
void MacroAssembler::wasmAtomicExchange(const wasm::MemoryAccessDesc& access,
const BaseIndex& mem, Register value,
Register output) {
AtomicExchange(*this, &access, access.type(), access.sync(), mem, value,
output);
}
// General algorithm:
//
// ... ptr, <addr> ; compute address of item
// dmb
// L0 ldrex* output, [ptr]
// sxt* output, output, 0 ; sign-extend if applicable
// OP tmp, output, value ; compute value to store
// strex* tmp2, tmp, [ptr] ; tmp2 required by strex
// cmp tmp2, 1
// beq L0 ; failed - location is dirty, retry
// dmb ; ordering barrier required
//
// Also see notes above at compareExchange re the barrier strategy.
//
// Observe that the value being operated into the memory element need
// not be sign-extended because no OP will make use of bits to the
// left of the bits indicated by the width of the element, and neither
// output nor the bits stored are affected by OP.
template <typename T>
static void AtomicFetchOp(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Scalar::Type type, Synchronization sync, AtomicOp op,
const Register& value, const T& mem,
Register flagTemp, Register output) {
bool signExtend = Scalar::isSignedIntType(type);
unsigned nbytes = Scalar::byteSize(type);
MOZ_ASSERT(nbytes <= 4);
MOZ_ASSERT(flagTemp != InvalidReg);
MOZ_ASSERT(output != value);
Label again;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
// NOTE: the generated code must match the assembly code in gen_fetchop in
// GenerateAtomicOperations.py
masm.memoryBarrierBefore(sync);
ScratchRegisterScope scratch(masm);
masm.bind(&again);
BufferOffset firstAccess;
switch (nbytes) {
case 1:
firstAccess = masm.as_ldrexb(output, ptr);
if (signExtend) {
masm.as_sxtb(output, output, 0);
}
break;
case 2:
firstAccess = masm.as_ldrexh(output, ptr);
if (signExtend) {
masm.as_sxth(output, output, 0);
}
break;
case 4:
firstAccess = masm.as_ldrex(output, ptr);
break;
default:
MOZ_CRASH();
}
if (access) {
masm.append(*access, js::wasm::TrapMachineInsnForLoad(nbytes),
FaultingCodeOffset(firstAccess.getOffset()));
}
switch (op) {
case AtomicOp::Add:
masm.as_add(scratch, output, O2Reg(value));
break;
case AtomicOp::Sub:
masm.as_sub(scratch, output, O2Reg(value));
break;
case AtomicOp::And:
masm.as_and(scratch, output, O2Reg(value));
break;
case AtomicOp::Or:
masm.as_orr(scratch, output, O2Reg(value));
break;
case AtomicOp::Xor:
masm.as_eor(scratch, output, O2Reg(value));
break;
default:
MOZ_CRASH();
}
// Rd must differ from the two other arguments to strex.
switch (nbytes) {
case 1:
masm.as_strexb(flagTemp, scratch, ptr);
break;
case 2:
masm.as_strexh(flagTemp, scratch, ptr);
break;
case 4:
masm.as_strex(flagTemp, scratch, ptr);
break;
default:
MOZ_CRASH();
}
masm.as_cmp(flagTemp, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.memoryBarrierAfter(sync);
}
void MacroAssembler::atomicFetchOp(Scalar::Type type, Synchronization sync,
AtomicOp op, Register value,
const Address& mem, Register temp,
Register output) {
AtomicFetchOp(*this, nullptr, type, sync, op, value, mem, temp, output);
}
void MacroAssembler::atomicFetchOp(Scalar::Type type, Synchronization sync,
AtomicOp op, Register value,
const BaseIndex& mem, Register temp,
Register output) {
AtomicFetchOp(*this, nullptr, type, sync, op, value, mem, temp, output);
}
void MacroAssembler::wasmAtomicFetchOp(const wasm::MemoryAccessDesc& access,
AtomicOp op, Register value,
const Address& mem, Register temp,
Register output) {
AtomicFetchOp(*this, &access, access.type(), access.sync(), op, value, mem,
temp, output);
}
void MacroAssembler::wasmAtomicFetchOp(const wasm::MemoryAccessDesc& access,
AtomicOp op, Register value,
const BaseIndex& mem, Register temp,
Register output) {
AtomicFetchOp(*this, &access, access.type(), access.sync(), op, value, mem,
temp, output);
}
// Uses both scratch registers, one for the address and one for a temp,
// but needs two temps for strex:
//
// ... ptr, <addr> ; compute address of item
// dmb
// L0 ldrex* temp, [ptr]
// OP temp, temp, value ; compute value to store
// strex* temp2, temp, [ptr]
// cmp temp2, 1
// beq L0 ; failed - location is dirty, retry
// dmb ; ordering barrier required
template <typename T>
static void AtomicEffectOp(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Scalar::Type type, Synchronization sync, AtomicOp op,
const Register& value, const T& mem,
Register flagTemp) {
unsigned nbytes = Scalar::byteSize(type);
MOZ_ASSERT(nbytes <= 4);
MOZ_ASSERT(flagTemp != InvalidReg);
Label again;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
masm.memoryBarrierBefore(sync);
ScratchRegisterScope scratch(masm);
masm.bind(&again);
BufferOffset firstAccess;
switch (nbytes) {
case 1:
firstAccess = masm.as_ldrexb(scratch, ptr);
break;
case 2:
firstAccess = masm.as_ldrexh(scratch, ptr);
break;
case 4:
firstAccess = masm.as_ldrex(scratch, ptr);
break;
default:
MOZ_CRASH();
}
if (access) {
masm.append(*access, js::wasm::TrapMachineInsnForLoad(nbytes),
FaultingCodeOffset(firstAccess.getOffset()));
}
switch (op) {
case AtomicOp::Add:
masm.as_add(scratch, scratch, O2Reg(value));
break;
case AtomicOp::Sub:
masm.as_sub(scratch, scratch, O2Reg(value));
break;
case AtomicOp::And:
masm.as_and(scratch, scratch, O2Reg(value));
break;
case AtomicOp::Or:
masm.as_orr(scratch, scratch, O2Reg(value));
break;
case AtomicOp::Xor:
masm.as_eor(scratch, scratch, O2Reg(value));
break;
default:
MOZ_CRASH();
}
// Rd must differ from the two other arguments to strex.
switch (nbytes) {
case 1:
masm.as_strexb(flagTemp, scratch, ptr);
break;
case 2:
masm.as_strexh(flagTemp, scratch, ptr);
break;
case 4:
masm.as_strex(flagTemp, scratch, ptr);
break;
default:
MOZ_CRASH();
}
masm.as_cmp(flagTemp, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.memoryBarrierAfter(sync);
}
void MacroAssembler::wasmAtomicEffectOp(const wasm::MemoryAccessDesc& access,
AtomicOp op, Register value,
const Address& mem, Register temp) {
AtomicEffectOp(*this, &access, access.type(), access.sync(), op, value, mem,
temp);
}
void MacroAssembler::wasmAtomicEffectOp(const wasm::MemoryAccessDesc& access,
AtomicOp op, Register value,
const BaseIndex& mem, Register temp) {
AtomicEffectOp(*this, &access, access.type(), access.sync(), op, value, mem,
temp);
}
template <typename T>
static void AtomicLoad64(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Synchronization sync, const T& mem,
Register64 output) {
MOZ_ASSERT((output.low.code() & 1) == 0);
MOZ_ASSERT(output.low.code() + 1 == output.high.code());
masm.memoryBarrierBefore(sync);
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
BufferOffset load = masm.as_ldrexd(output.low, output.high, ptr);
if (access) {
masm.append(*access, js::wasm::TrapMachineInsn::Load64,
FaultingCodeOffset(load.getOffset()));
}
masm.as_clrex();
masm.memoryBarrierAfter(sync);
}
template <typename T>
static void WasmAtomicLoad64(MacroAssembler& masm,
const wasm::MemoryAccessDesc& access, const T& mem,
Register64 temp, Register64 output) {
MOZ_ASSERT(temp.low == InvalidReg && temp.high == InvalidReg);
AtomicLoad64(masm, &access, access.sync(), mem, output);
}
void MacroAssembler::wasmAtomicLoad64(const wasm::MemoryAccessDesc& access,
const Address& mem, Register64 temp,
Register64 output) {
WasmAtomicLoad64(*this, access, mem, temp, output);
}
void MacroAssembler::wasmAtomicLoad64(const wasm::MemoryAccessDesc& access,
const BaseIndex& mem, Register64 temp,
Register64 output) {
WasmAtomicLoad64(*this, access, mem, temp, output);
}
template <typename T>
static void CompareExchange64(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Synchronization sync, const T& mem,
Register64 expect, Register64 replace,
Register64 output) {
MOZ_ASSERT(expect != replace && replace != output && output != expect);
MOZ_ASSERT((replace.low.code() & 1) == 0);
MOZ_ASSERT(replace.low.code() + 1 == replace.high.code());
MOZ_ASSERT((output.low.code() & 1) == 0);
MOZ_ASSERT(output.low.code() + 1 == output.high.code());
Label again;
Label done;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
// NOTE: the generated code must match the assembly code in gen_cmpxchg in
// GenerateAtomicOperations.py
masm.memoryBarrierBefore(sync);
masm.bind(&again);
BufferOffset load = masm.as_ldrexd(output.low, output.high, ptr);
if (access) {
masm.append(*access, js::wasm::TrapMachineInsn::Load64,
FaultingCodeOffset(load.getOffset()));
}
masm.as_cmp(output.low, O2Reg(expect.low));
masm.as_cmp(output.high, O2Reg(expect.high), MacroAssembler::Equal);
masm.as_b(&done, MacroAssembler::NotEqual);
ScratchRegisterScope scratch(masm);
// Rd (temp) must differ from the two other arguments to strex.
masm.as_strexd(scratch, replace.low, replace.high, ptr);
masm.as_cmp(scratch, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.bind(&done);
masm.memoryBarrierAfter(sync);
}
void MacroAssembler::wasmCompareExchange64(const wasm::MemoryAccessDesc& access,
const Address& mem,
Register64 expect,
Register64 replace,
Register64 output) {
CompareExchange64(*this, &access, access.sync(), mem, expect, replace,
output);
}
void MacroAssembler::wasmCompareExchange64(const wasm::MemoryAccessDesc& access,
const BaseIndex& mem,
Register64 expect,
Register64 replace,
Register64 output) {
CompareExchange64(*this, &access, access.sync(), mem, expect, replace,
output);
}
void MacroAssembler::compareExchange64(Synchronization sync, const Address& mem,
Register64 expect, Register64 replace,
Register64 output) {
CompareExchange64(*this, nullptr, sync, mem, expect, replace, output);
}
void MacroAssembler::compareExchange64(Synchronization sync,
const BaseIndex& mem, Register64 expect,
Register64 replace, Register64 output) {
CompareExchange64(*this, nullptr, sync, mem, expect, replace, output);
}
template <typename T>
static void AtomicExchange64(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Synchronization sync, const T& mem,
Register64 value, Register64 output) {
MOZ_ASSERT(output != value);
MOZ_ASSERT((value.low.code() & 1) == 0);
MOZ_ASSERT(value.low.code() + 1 == value.high.code());
MOZ_ASSERT((output.low.code() & 1) == 0);
MOZ_ASSERT(output.low.code() + 1 == output.high.code());
Label again;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
masm.memoryBarrierBefore(sync);
masm.bind(&again);
BufferOffset load = masm.as_ldrexd(output.low, output.high, ptr);
if (access) {
masm.append(*access, js::wasm::TrapMachineInsn::Load64,
FaultingCodeOffset(load.getOffset()));
}
ScratchRegisterScope scratch(masm);
masm.as_strexd(scratch, value.low, value.high, ptr);
masm.as_cmp(scratch, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.memoryBarrierAfter(sync);
}
template <typename T>
static void WasmAtomicExchange64(MacroAssembler& masm,
const wasm::MemoryAccessDesc& access,
const T& mem, Register64 value,
Register64 output) {
AtomicExchange64(masm, &access, access.sync(), mem, value, output);
}
void MacroAssembler::wasmAtomicExchange64(const wasm::MemoryAccessDesc& access,
const Address& mem, Register64 value,
Register64 output) {
WasmAtomicExchange64(*this, access, mem, value, output);
}
void MacroAssembler::wasmAtomicExchange64(const wasm::MemoryAccessDesc& access,
const BaseIndex& mem,
Register64 value, Register64 output) {
WasmAtomicExchange64(*this, access, mem, value, output);
}
void MacroAssembler::atomicExchange64(Synchronization sync, const Address& mem,
Register64 value, Register64 output) {
AtomicExchange64(*this, nullptr, sync, mem, value, output);
}
void MacroAssembler::atomicExchange64(Synchronization sync,
const BaseIndex& mem, Register64 value,
Register64 output) {
AtomicExchange64(*this, nullptr, sync, mem, value, output);
}
template <typename T>
static void AtomicFetchOp64(MacroAssembler& masm,
const wasm::MemoryAccessDesc* access,
Synchronization sync, AtomicOp op, Register64 value,
const T& mem, Register64 temp, Register64 output) {
MOZ_ASSERT(temp.low != InvalidReg && temp.high != InvalidReg);
MOZ_ASSERT(output != value);
MOZ_ASSERT(temp != value);
MOZ_ASSERT((temp.low.code() & 1) == 0);
MOZ_ASSERT(temp.low.code() + 1 == temp.high.code());
// We could avoid this pair requirement but in that case we would end up
// with two moves in the loop to preserve the loaded value in output. The
// prize would be less register spilling around this op since the pair
// requirement will tend to force more spilling.
MOZ_ASSERT((output.low.code() & 1) == 0);
MOZ_ASSERT(output.low.code() + 1 == output.high.code());
Label again;
SecondScratchRegisterScope scratch2(masm);
Register ptr = ComputePointerForAtomic(masm, mem, scratch2);
masm.memoryBarrierBefore(sync);
masm.bind(&again);
BufferOffset load = masm.as_ldrexd(output.low, output.high, ptr);
if (access) {
masm.append(*access, js::wasm::TrapMachineInsn::Load64,
FaultingCodeOffset(load.getOffset()));
}
switch (op) {
case AtomicOp::Add:
masm.as_add(temp.low, output.low, O2Reg(value.low), SetCC);
masm.as_adc(temp.high, output.high, O2Reg(value.high));
break;
case AtomicOp::Sub:
masm.as_sub(temp.low, output.low, O2Reg(value.low), SetCC);
masm.as_sbc(temp.high, output.high, O2Reg(value.high));
break;
case AtomicOp::And:
masm.as_and(temp.low, output.low, O2Reg(value.low));
masm.as_and(temp.high, output.high, O2Reg(value.high));
break;
case AtomicOp::Or:
masm.as_orr(temp.low, output.low, O2Reg(value.low));
masm.as_orr(temp.high, output.high, O2Reg(value.high));
break;
case AtomicOp::Xor:
masm.as_eor(temp.low, output.low, O2Reg(value.low));
masm.as_eor(temp.high, output.high, O2Reg(value.high));
break;
}
ScratchRegisterScope scratch(masm);
// Rd (temp) must differ from the two other arguments to strex.
masm.as_strexd(scratch, temp.low, temp.high, ptr);
masm.as_cmp(scratch, Imm8(1));
masm.as_b(&again, MacroAssembler::Equal);
masm.memoryBarrierAfter(sync);
}
template <typename T>
static void WasmAtomicFetchOp64(MacroAssembler& masm,
const wasm::MemoryAccessDesc& access,
AtomicOp op, Register64 value, const T& mem,
Register64 temp, Register64 output) {
AtomicFetchOp64(masm, &access, access.sync(), op, value, mem, temp, output);
}
void MacroAssembler::wasmAtomicFetchOp64(const wasm::MemoryAccessDesc& access,
AtomicOp op, Register64 value,
const Address& mem, Register64 temp,
Register64 output) {
WasmAtomicFetchOp64(*this, access, op, value, mem, temp, output);
}
void MacroAssembler::wasmAtomicFetchOp64(const wasm::MemoryAccessDesc& access,
AtomicOp op, Register64 value,
const BaseIndex& mem, Register64 temp,
Register64 output) {
WasmAtomicFetchOp64(*this, access, op, value, mem, temp, output);
}
void MacroAssembler::atomicFetchOp64(Synchronization sync, AtomicOp op,
Register64 value, const Address& mem,
Register64 temp, Register64 output) {
AtomicFetchOp64(*this, nullptr, sync, op, value, mem, temp, output);
}
void MacroAssembler::atomicFetchOp64(Synchronization sync, AtomicOp op,
Register64 value, const BaseIndex& mem,
Register64 temp, Register64 output) {
AtomicFetchOp64(*this, nullptr, sync, op, value, mem, temp, output);
}
void MacroAssembler::atomicEffectOp64(Synchronization sync, AtomicOp op,
Register64 value, const Address& mem,
Register64 temp) {
AtomicFetchOp64(*this, nullptr, sync, op, value, mem, temp, temp);
}
void MacroAssembler::atomicEffectOp64(Synchronization sync, AtomicOp op,
Register64 value, const BaseIndex& mem,
Register64 temp) {
AtomicFetchOp64(*this, nullptr, sync, op, value, mem, temp, temp);
}
// ========================================================================
// JS atomic operations.
template <typename T>
static void CompareExchangeJS(MacroAssembler& masm, Scalar::Type arrayType,
Synchronization sync, const T& mem,
Register oldval, Register newval, Register temp,
AnyRegister output) {
if (arrayType == Scalar::Uint32) {
masm.compareExchange(arrayType, sync, mem, oldval, newval, temp);
masm.convertUInt32ToDouble(temp, output.fpu());
} else {
masm.compareExchange(arrayType, sync, mem, oldval, newval, output.gpr());
}
}
void MacroAssembler::compareExchangeJS(Scalar::Type arrayType,
Synchronization sync, const Address& mem,
Register oldval, Register newval,
Register temp, AnyRegister output) {
CompareExchangeJS(*this, arrayType, sync, mem, oldval, newval, temp, output);
}
void MacroAssembler::compareExchangeJS(Scalar::Type arrayType,
Synchronization sync,
const BaseIndex& mem, Register oldval,
Register newval, Register temp,
AnyRegister output) {
CompareExchangeJS(*this, arrayType, sync, mem, oldval, newval, temp, output);
}
template <typename T>
static void AtomicExchangeJS(MacroAssembler& masm, Scalar::Type arrayType,
Synchronization sync, const T& mem, Register value,
Register temp, AnyRegister output) {
if (arrayType == Scalar::Uint32) {
masm.atomicExchange(arrayType, sync, mem, value, temp);
masm.convertUInt32ToDouble(temp, output.fpu());
} else {
masm.atomicExchange(arrayType, sync, mem, value, output.gpr());
}
}
void MacroAssembler::atomicExchangeJS(Scalar::Type arrayType,
Synchronization sync, const Address& mem,
Register value, Register temp,
AnyRegister output) {
AtomicExchangeJS(*this, arrayType, sync, mem, value, temp, output);
}
void MacroAssembler::atomicExchangeJS(Scalar::Type arrayType,
Synchronization sync,
const BaseIndex& mem, Register value,
Register temp, AnyRegister output) {
AtomicExchangeJS(*this, arrayType, sync, mem, value, temp, output);
}
template <typename T>
static void AtomicFetchOpJS(MacroAssembler& masm, Scalar::Type arrayType,
Synchronization sync, AtomicOp op, Register value,
const T& mem, Register temp1, Register temp2,
AnyRegister output) {
if (arrayType == Scalar::Uint32) {
masm.atomicFetchOp(arrayType, sync, op, value, mem, temp2, temp1);
masm.convertUInt32ToDouble(temp1, output.fpu());
} else {
masm.atomicFetchOp(arrayType, sync, op, value, mem, temp1, output.gpr());
}
}
void MacroAssembler::atomicFetchOpJS(Scalar::Type arrayType,
Synchronization sync, AtomicOp op,
Register value, const Address& mem,
Register temp1, Register temp2,
AnyRegister output) {
AtomicFetchOpJS(*this, arrayType, sync, op, value, mem, temp1, temp2, output);
}
void MacroAssembler::atomicFetchOpJS(Scalar::Type arrayType,
Synchronization sync, AtomicOp op,
Register value, const BaseIndex& mem,
Register temp1, Register temp2,
AnyRegister output) {
AtomicFetchOpJS(*this, arrayType, sync, op, value, mem, temp1, temp2, output);
}
void MacroAssembler::atomicEffectOpJS(Scalar::Type arrayType,
Synchronization sync, AtomicOp op,
Register value, const BaseIndex& mem,
Register temp) {
AtomicEffectOp(*this, nullptr, arrayType, sync, op, value, mem, temp);
}
void MacroAssembler::atomicEffectOpJS(Scalar::Type arrayType,
Synchronization sync, AtomicOp op,
Register value, const Address& mem,
Register temp) {
AtomicEffectOp(*this, nullptr, arrayType, sync, op, value, mem, temp);
}
// ========================================================================
// Primitive atomic operations.
void MacroAssembler::atomicLoad64(Synchronization sync, const Address& mem,
Register64 output) {
AtomicLoad64(*this, nullptr, sync, mem, output);
}
void MacroAssembler::atomicLoad64(Synchronization sync, const BaseIndex& mem,
Register64 output) {
AtomicLoad64(*this, nullptr, sync, mem, output);
}
void MacroAssembler::atomicStore64(Synchronization sync, const Address& mem,
Register64 value, Register64 temp) {
AtomicExchange64(*this, nullptr, sync, mem, value, temp);
}
void MacroAssembler::atomicStore64(Synchronization sync, const BaseIndex& mem,
Register64 value, Register64 temp) {
AtomicExchange64(*this, nullptr, sync, mem, value, temp);
}
// ========================================================================
// Convert floating point.
bool MacroAssembler::convertUInt64ToDoubleNeedsTemp() { return false; }
void MacroAssembler::convertUInt64ToDouble(Register64 src, FloatRegister dest,
Register temp) {
MOZ_ASSERT(temp == Register::Invalid());
ScratchDoubleScope scratchDouble(*this);
convertUInt32ToDouble(src.high, dest);
{
ScratchRegisterScope scratch(*this);
movePtr(ImmPtr(&TO_DOUBLE_HIGH_SCALE), scratch);
ma_vldr(Operand(Address(scratch, 0)).toVFPAddr(), scratchDouble);
}
mulDouble(scratchDouble, dest);
convertUInt32ToDouble(src.low, scratchDouble);
addDouble(scratchDouble, dest);
}
void MacroAssembler::convertInt64ToDouble(Register64 src, FloatRegister dest) {
ScratchDoubleScope scratchDouble(*this);
convertInt32ToDouble(src.high, dest);
{
ScratchRegisterScope scratch(*this);
movePtr(ImmPtr(&TO_DOUBLE_HIGH_SCALE), scratch);
ma_vldr(Operand(Address(scratch, 0)).toVFPAddr(), scratchDouble);
}
mulDouble(scratchDouble, dest);
convertUInt32ToDouble(src.low, scratchDouble);
addDouble(scratchDouble, dest);
}
void MacroAssembler::convertIntPtrToDouble(Register src, FloatRegister dest) {
convertInt32ToDouble(src, dest);
}
extern "C" {
extern MOZ_EXPORT int64_t __aeabi_idivmod(int, int);
extern MOZ_EXPORT int64_t __aeabi_uidivmod(int, int);
}
inline void EmitRemainderOrQuotient(bool isRemainder, MacroAssembler& masm,
Register rhs, Register lhsOutput,
bool isUnsigned,
const LiveRegisterSet& volatileLiveRegs) {
// Currently this helper can't handle this situation.
MOZ_ASSERT(lhsOutput != rhs);
if (HasIDIV()) {
if (isRemainder) {
masm.remainder32(rhs, lhsOutput, isUnsigned);
} else {
masm.quotient32(rhs, lhsOutput, isUnsigned);
}
} else {
// Ensure that the output registers are saved and restored properly.
LiveRegisterSet liveRegs = volatileLiveRegs;
liveRegs.addUnchecked(ReturnRegVal0);
liveRegs.addUnchecked(ReturnRegVal1);
masm.PushRegsInMask(liveRegs);
using Fn = int64_t (*)(int, int);
{
ScratchRegisterScope scratch(masm);
masm.setupUnalignedABICall(scratch);
}
masm.passABIArg(lhsOutput);
masm.passABIArg(rhs);
if (isUnsigned) {
masm.callWithABI<Fn, __aeabi_uidivmod>(
ABIType::Int64, CheckUnsafeCallWithABI::DontCheckOther);
} else {
masm.callWithABI<Fn, __aeabi_idivmod>(
ABIType::Int64, CheckUnsafeCallWithABI::DontCheckOther);
}
if (isRemainder) {
masm.mov(ReturnRegVal1, lhsOutput);
} else {
masm.mov(ReturnRegVal0, lhsOutput);
}
LiveRegisterSet ignore;
ignore.add(lhsOutput);
masm.PopRegsInMaskIgnore(liveRegs, ignore);
}
}
void MacroAssembler::flexibleQuotient32(
Register rhs, Register srcDest, bool isUnsigned,
const LiveRegisterSet& volatileLiveRegs) {
EmitRemainderOrQuotient(false, *this, rhs, srcDest, isUnsigned,
volatileLiveRegs);
}
void MacroAssembler::flexibleRemainder32(
Register rhs, Register srcDest, bool isUnsigned,
const LiveRegisterSet& volatileLiveRegs) {
EmitRemainderOrQuotient(true, *this, rhs, srcDest, isUnsigned,
volatileLiveRegs);
}
void MacroAssembler::flexibleDivMod32(Register rhs, Register lhsOutput,
Register remOutput, bool isUnsigned,
const LiveRegisterSet& volatileLiveRegs) {
// Currently this helper can't handle this situation.
MOZ_ASSERT(lhsOutput != rhs);
if (HasIDIV()) {
mov(lhsOutput, remOutput);
remainder32(rhs, remOutput, isUnsigned);
quotient32(rhs, lhsOutput, isUnsigned);
} else {
// Ensure that the output registers are saved and restored properly.
LiveRegisterSet liveRegs = volatileLiveRegs;
liveRegs.addUnchecked(ReturnRegVal0);
liveRegs.addUnchecked(ReturnRegVal1);
PushRegsInMask(liveRegs);
using Fn = int64_t (*)(int, int);
{
ScratchRegisterScope scratch(*this);
setupUnalignedABICall(scratch);
}
passABIArg(lhsOutput);
passABIArg(rhs);
if (isUnsigned) {
callWithABI<Fn, __aeabi_uidivmod>(ABIType::Int64,
CheckUnsafeCallWithABI::DontCheckOther);
} else {
callWithABI<Fn, __aeabi_idivmod>(ABIType::Int64,
CheckUnsafeCallWithABI::DontCheckOther);
}
moveRegPair(ReturnRegVal0, ReturnRegVal1, lhsOutput, remOutput);
LiveRegisterSet ignore;
ignore.add(remOutput);
ignore.add(lhsOutput);
PopRegsInMaskIgnore(liveRegs, ignore);
}
}
CodeOffset MacroAssembler::moveNearAddressWithPatch(Register dest) {
return movWithPatch(ImmPtr(nullptr), dest);
}
void MacroAssembler::patchNearAddressMove(CodeLocationLabel loc,
CodeLocationLabel target) {
PatchDataWithValueCheck(loc, ImmPtr(target.raw()), ImmPtr(nullptr));
}
// ========================================================================
// Spectre Mitigations.
void MacroAssembler::speculationBarrier() {
// Spectre mitigation recommended by ARM for cases where csel/cmov cannot be
// used.
as_csdb();
}
void MacroAssembler::floorFloat32ToInt32(FloatRegister src, Register dest,
Label* fail) {
floorf(src, dest, fail);
}
void MacroAssembler::floorDoubleToInt32(FloatRegister src, Register dest,
Label* fail) {
floor(src, dest, fail);
}
void MacroAssembler::ceilFloat32ToInt32(FloatRegister src, Register dest,
Label* fail) {
ceilf(src, dest, fail);
}
void MacroAssembler::ceilDoubleToInt32(FloatRegister src, Register dest,
Label* fail) {
ceil(src, dest, fail);
}
void MacroAssembler::roundFloat32ToInt32(FloatRegister src, Register dest,
FloatRegister temp, Label* fail) {
roundf(src, dest, fail, temp);
}
void MacroAssembler::roundDoubleToInt32(FloatRegister src, Register dest,
FloatRegister temp, Label* fail) {
round(src, dest, fail, temp);
}
void MacroAssembler::truncFloat32ToInt32(FloatRegister src, Register dest,
Label* fail) {
truncf(src, dest, fail);
}
void MacroAssembler::truncDoubleToInt32(FloatRegister src, Register dest,
Label* fail) {
trunc(src, dest, fail);
}
void MacroAssembler::nearbyIntDouble(RoundingMode mode, FloatRegister src,
FloatRegister dest) {
MOZ_CRASH("not supported on this platform");
}
void MacroAssembler::nearbyIntFloat32(RoundingMode mode, FloatRegister src,
FloatRegister dest) {
MOZ_CRASH("not supported on this platform");
}
void MacroAssembler::copySignDouble(FloatRegister lhs, FloatRegister rhs,
FloatRegister output) {
MOZ_CRASH("not supported on this platform");
}
void MacroAssembler::shiftIndex32AndAdd(Register indexTemp32, int shift,
Register pointer) {
if (IsShiftInScaleRange(shift)) {
computeEffectiveAddress(
BaseIndex(pointer, indexTemp32, ShiftToScale(shift)), pointer);
return;
}
lshift32(Imm32(shift), indexTemp32);
addPtr(indexTemp32, pointer);
}
#ifdef ENABLE_WASM_TAIL_CALLS
void MacroAssembler::wasmMarkSlowCall() { ma_and(lr, lr, lr); }
const int32_t SlowCallMarker = 0xe00ee00e;
void MacroAssembler::wasmCheckSlowCallsite(Register ra, Label* notSlow,
Register temp1, Register temp2) {
MOZ_ASSERT(temp1 != temp2);
// Check if RA has slow marker.
load32(Address(ra, 0), temp2);
ma_mov(Imm32(SlowCallMarker), temp1, Always);
ma_cmp(temp2, temp1);
j(Assembler::NotEqual, notSlow);
}
#endif // ENABLE_WASM_TAIL_CALLS
//}}} check_macroassembler_style
void MacroAssemblerARM::wasmTruncateToInt32(FloatRegister input,
Register output, MIRType fromType,
bool isUnsigned, bool isSaturating,
Label* oolEntry) {
ScratchDoubleScope scratchScope(asMasm());
ScratchRegisterScope scratchReg(asMasm());
FloatRegister scratch = scratchScope.uintOverlay();
// ARM conversion instructions clamp the value to ensure it fits within the
// target's type bounds, so every time we see those, we need to check the
// input. A NaN check is not necessary because NaN is converted to zero and
// on a zero result we branch out of line to do further processing anyway.
if (isUnsigned) {
if (fromType == MIRType::Double) {
ma_vcvt_F64_U32(input, scratch);
} else if (fromType == MIRType::Float32) {
ma_vcvt_F32_U32(input, scratch);
} else {
MOZ_CRASH("unexpected type in visitWasmTruncateToInt32");
}
ma_vxfer(scratch, output);
if (!isSaturating) {
// int32_t(UINT32_MAX) == -1.
ma_cmp(output, Imm32(-1), scratchReg);
as_cmp(output, Imm8(0), Assembler::NotEqual);
ma_b(oolEntry, Assembler::Equal);
}
return;
}
// vcvt* converts NaN into 0, so check for NaNs here.
if (!isSaturating) {
if (fromType == MIRType::Double) {
asMasm().compareDouble(input, input);
} else if (fromType == MIRType::Float32) {
asMasm().compareFloat(input, input);
} else {
MOZ_CRASH("unexpected type in visitWasmTruncateToInt32");
}
ma_b(oolEntry, Assembler::VFP_Unordered);
}
scratch = scratchScope.sintOverlay();
if (fromType == MIRType::Double) {
ma_vcvt_F64_I32(input, scratch);
} else if (fromType == MIRType::Float32) {
ma_vcvt_F32_I32(input, scratch);
} else {
MOZ_CRASH("unexpected type in visitWasmTruncateToInt32");
}
ma_vxfer(scratch, output);
if (!isSaturating) {
ma_cmp(output, Imm32(INT32_MAX), scratchReg);
ma_cmp(output, Imm32(INT32_MIN), scratchReg, Assembler::NotEqual);
ma_b(oolEntry, Assembler::Equal);
}
}
void MacroAssemblerARM::outOfLineWasmTruncateToIntCheck(
FloatRegister input, MIRType fromType, MIRType toType, TruncFlags flags,
Label* rejoin, wasm::BytecodeOffset trapOffset) {
// On ARM, saturating truncation codegen handles saturating itself rather
// than relying on out-of-line fixup code.
if (flags & TRUNC_SATURATING) {
return;
}
bool isUnsigned = flags & TRUNC_UNSIGNED;
ScratchDoubleScope scratchScope(asMasm());
FloatRegister scratch;
// Eagerly take care of NaNs.
Label inputIsNaN;
if (fromType == MIRType::Double) {
asMasm().branchDouble(Assembler::DoubleUnordered, input, input,
&inputIsNaN);
} else if (fromType == MIRType::Float32) {
asMasm().branchFloat(Assembler::DoubleUnordered, input, input, &inputIsNaN);
} else {
MOZ_CRASH("unexpected type in visitOutOfLineWasmTruncateCheck");
}
// Handle special values.
Label fail;
// By default test for the following inputs and bail:
// signed: ] -Inf, INTXX_MIN - 1.0 ] and [ INTXX_MAX + 1.0 : +Inf [
// unsigned: ] -Inf, -1.0 ] and [ UINTXX_MAX + 1.0 : +Inf [
// Note: we cannot always represent those exact values. As a result
// this changes the actual comparison a bit.
double minValue, maxValue;
Assembler::DoubleCondition minCond = Assembler::DoubleLessThanOrEqual;
Assembler::DoubleCondition maxCond = Assembler::DoubleGreaterThanOrEqual;
if (toType == MIRType::Int64) {
if (isUnsigned) {
minValue = -1;
maxValue = double(UINT64_MAX) + 1.0;
} else {
// In the float32/double range there exists no value between
// INT64_MIN and INT64_MIN - 1.0. Making INT64_MIN the lower-bound.
minValue = double(INT64_MIN);
minCond = Assembler::DoubleLessThan;
maxValue = double(INT64_MAX) + 1.0;
}
} else {
if (isUnsigned) {
minValue = -1;
maxValue = double(UINT32_MAX) + 1.0;
} else {
if (fromType == MIRType::Float32) {
// In the float32 range there exists no value between
// INT32_MIN and INT32_MIN - 1.0. Making INT32_MIN the lower-bound.
minValue = double(INT32_MIN);
minCond = Assembler::DoubleLessThan;
} else {
minValue = double(INT32_MIN) - 1.0;
}
maxValue = double(INT32_MAX) + 1.0;
}
}
if (fromType == MIRType::Double) {
scratch = scratchScope.doubleOverlay();
asMasm().loadConstantDouble(minValue, scratch);
asMasm().branchDouble(minCond, input, scratch, &fail);
asMasm().loadConstantDouble(maxValue, scratch);
asMasm().branchDouble(maxCond, input, scratch, &fail);
} else {
MOZ_ASSERT(fromType == MIRType::Float32);
scratch = scratchScope.singleOverlay();
asMasm().loadConstantFloat32(float(minValue), scratch);
asMasm().branchFloat(minCond, input, scratch, &fail);
asMasm().loadConstantFloat32(float(maxValue), scratch);
asMasm().branchFloat(maxCond, input, scratch, &fail);
}
// We had an actual correct value, get back to where we were.
ma_b(rejoin);
// Handle errors.
bind(&fail);
asMasm().wasmTrap(wasm::Trap::IntegerOverflow, trapOffset);
bind(&inputIsNaN);
asMasm().wasmTrap(wasm::Trap::InvalidConversionToInteger, trapOffset);
}
void MacroAssemblerARM::wasmLoadImpl(const wasm::MemoryAccessDesc& access,
Register memoryBase, Register ptr,
Register ptrScratch, AnyRegister output,
Register64 out64) {
MOZ_ASSERT(memoryBase != ptr);
MOZ_ASSERT_IF(out64 != Register64::Invalid(), memoryBase != out64.high);
MOZ_ASSERT_IF(out64 != Register64::Invalid(), memoryBase != out64.low);
MOZ_ASSERT(ptr == ptrScratch);
MOZ_ASSERT(!access.isZeroExtendSimd128Load());
MOZ_ASSERT(!access.isSplatSimd128Load());
MOZ_ASSERT(!access.isWidenSimd128Load());
access.assertOffsetInGuardPages();
uint32_t offset = access.offset();
Scalar::Type type = access.type();
// Maybe add the offset.
if (offset || type == Scalar::Int64) {
ScratchRegisterScope scratch(asMasm());
if (offset) {
ma_add(Imm32(offset), ptr, scratch);
}
}
bool isSigned = type == Scalar::Int8 || type == Scalar::Int16 ||
type == Scalar::Int32 || type == Scalar::Int64;
unsigned byteSize = access.byteSize();
// NOTE: the generated code must match the assembly code in gen_load in
// GenerateAtomicOperations.py
asMasm().memoryBarrierBefore(access.sync());
BufferOffset load;
if (out64 != Register64::Invalid()) {
if (type == Scalar::Int64) {
static_assert(INT64LOW_OFFSET == 0);
load = ma_dataTransferN(IsLoad, 32, /* signed = */ false, memoryBase, ptr,
out64.low);
append(access, js::wasm::TrapMachineInsn::Load32,
FaultingCodeOffset(load.getOffset()));
as_add(ptr, ptr, Imm8(INT64HIGH_OFFSET));
load =
ma_dataTransferN(IsLoad, 32, isSigned, memoryBase, ptr, out64.high);
append(access, js::wasm::TrapMachineInsn::Load32,
FaultingCodeOffset(load.getOffset()));
} else {
load = ma_dataTransferN(IsLoad, byteSize * 8, isSigned, memoryBase, ptr,
out64.low);
append(access, js::wasm::TrapMachineInsnForLoad(byteSize),
FaultingCodeOffset(load.getOffset()));
if (isSigned) {
ma_asr(Imm32(31), out64.low, out64.high);
} else {
ma_mov(Imm32(0), out64.high);
}
}
} else {
bool isFloat = output.isFloat();
if (isFloat) {
MOZ_ASSERT((byteSize == 4) == output.fpu().isSingle());
ScratchRegisterScope scratch(asMasm());
FloatRegister dest = output.fpu();
ma_add(memoryBase, ptr, scratch);
// FP loads can't use VLDR as that has stringent alignment checks and will
// SIGBUS on unaligned accesses. Choose a different strategy depending on
// the available hardware. We don't gate Wasm on the presence of NEON.
if (HasNEON()) {
// NEON available: The VLD1 multiple-single-elements variant will only
// trap if SCTRL.A==1, but we already assume (for integer accesses) that
// the hardware/OS handles that transparently.
//
// An additional complication is that if we're targeting the high single
// then an unaligned load is not possible, and we may need to go via the
// FPR scratch.
if (byteSize == 4 && dest.code() & 1) {
ScratchFloat32Scope fscratch(asMasm());
load = as_vldr_unaligned(fscratch, scratch);
as_vmov(dest, fscratch);
} else {
load = as_vldr_unaligned(dest, scratch);
}
append(access, js::wasm::TrapMachineInsnForLoad(byteSize),
FaultingCodeOffset(load.getOffset()));
} else {
// NEON not available: Load to GPR scratch, move to FPR destination. We
// don't have adjacent scratches for the f64, so use individual LDRs,
// not LDRD.
SecondScratchRegisterScope scratch2(asMasm());
if (byteSize == 4) {
load = as_dtr(IsLoad, 32, Offset, scratch2,
DTRAddr(scratch, DtrOffImm(0)), Always);
as_vxfer(scratch2, InvalidReg, VFPRegister(dest), CoreToFloat,
Always);
append(access, js::wasm::TrapMachineInsn::Load32,
FaultingCodeOffset(load.getOffset()));
} else {
// The trap information is associated with the load of the high word,
// which must be done first. FIXME sewardj 20230825: is it still
// safe to skip the low word, now that we support wasm-gc?
load = as_dtr(IsLoad, 32, Offset, scratch2,
DTRAddr(scratch, DtrOffImm(4)), Always);
append(access, js::wasm::TrapMachineInsn::Load32,
FaultingCodeOffset(load.getOffset()));
as_dtr(IsLoad, 32, Offset, scratch, DTRAddr(scratch, DtrOffImm(0)),
Always);
as_vxfer(scratch, scratch2, VFPRegister(dest), CoreToFloat, Always);
}
}
} else {
load = ma_dataTransferN(IsLoad, byteSize * 8, isSigned, memoryBase, ptr,
output.gpr());
append(access, js::wasm::TrapMachineInsnForLoad(byteSize),
FaultingCodeOffset(load.getOffset()));
}
}
asMasm().memoryBarrierAfter(access.sync());
}
void MacroAssemblerARM::wasmStoreImpl(const wasm::MemoryAccessDesc& access,
AnyRegister value, Register64 val64,
Register memoryBase, Register ptr,
Register ptrScratch) {
static_assert(INT64LOW_OFFSET == 0);
static_assert(INT64HIGH_OFFSET == 4);
MOZ_ASSERT(ptr == ptrScratch);
access.assertOffsetInGuardPages();
uint32_t offset = access.offset();
unsigned byteSize = access.byteSize();
Scalar::Type type = access.type();
// Maybe add the offset.
if (offset || type == Scalar::Int64) {
ScratchRegisterScope scratch(asMasm());
// We need to store the high word of an Int64 first, so always adjust the
// pointer to point to the high word in this case. The adjustment is always
// OK because wasmMaxOffsetGuardLimit is computed so that we can add up to
// sizeof(LargestValue)-1 without skipping past the guard page, and we
// assert above that offset < wasmMaxOffsetGuardLimit.
if (type == Scalar::Int64) {
offset += INT64HIGH_OFFSET;
}
if (offset) {
ma_add(Imm32(offset), ptr, scratch);
}
}
// NOTE: the generated code must match the assembly code in gen_store in
// GenerateAtomicOperations.py
asMasm().memoryBarrierBefore(access.sync());
BufferOffset store;
if (type == Scalar::Int64) {
store = ma_dataTransferN(IsStore, 32 /* bits */, /* signed */ false,
memoryBase, ptr, val64.high);
append(access, js::wasm::TrapMachineInsn::Store32,
FaultingCodeOffset(store.getOffset()));
as_sub(ptr, ptr, Imm8(INT64HIGH_OFFSET));
store = ma_dataTransferN(IsStore, 32 /* bits */, /* signed */ true,
memoryBase, ptr, val64.low);
append(access, js::wasm::TrapMachineInsn::Store32,
FaultingCodeOffset(store.getOffset()));
} else {
if (value.isFloat()) {
ScratchRegisterScope scratch(asMasm());
FloatRegister val = value.fpu();
MOZ_ASSERT((byteSize == 4) == val.isSingle());
ma_add(memoryBase, ptr, scratch);
// See comments above at wasmLoadImpl for more about this logic.
if (HasNEON()) {
if (byteSize == 4 && (val.code() & 1)) {
ScratchFloat32Scope fscratch(asMasm());
as_vmov(fscratch, val);
store = as_vstr_unaligned(fscratch, scratch);
} else {
store = as_vstr_unaligned(val, scratch);
}
append(access, js::wasm::TrapMachineInsnForStore(byteSize),
FaultingCodeOffset(store.getOffset()));
} else {
// NEON not available: Move FPR to GPR scratch, store GPR. We have only
// one scratch to hold the value, so for f64 we must do two separate
// moves. That's OK - this is really a corner case. If we really cared
// we would pass in a temp to avoid the second move.
SecondScratchRegisterScope scratch2(asMasm());
if (byteSize == 4) {
as_vxfer(scratch2, InvalidReg, VFPRegister(val), FloatToCore, Always);
store = as_dtr(IsStore, 32, Offset, scratch2,
DTRAddr(scratch, DtrOffImm(0)), Always);
append(access, js::wasm::TrapMachineInsn::Store32,
FaultingCodeOffset(store.getOffset()));
} else {
// The trap information is associated with the store of the high word,
// which must be done first. FIXME sewardj 20230825: is it still
// safe to skip the low word, now that we support wasm-gc?
as_vxfer(scratch2, InvalidReg, VFPRegister(val).singleOverlay(1),
FloatToCore, Always);
store = as_dtr(IsStore, 32, Offset, scratch2,
DTRAddr(scratch, DtrOffImm(4)), Always);
append(access, js::wasm::TrapMachineInsn::Store32,
FaultingCodeOffset(store.getOffset()));
as_vxfer(scratch2, InvalidReg, VFPRegister(val).singleOverlay(0),
FloatToCore, Always);
as_dtr(IsStore, 32, Offset, scratch2, DTRAddr(scratch, DtrOffImm(0)),
Always);
}
}
} else {
bool isSigned = type == Scalar::Uint32 ||
type == Scalar::Int32; // see AsmJSStoreHeap;
Register val = value.gpr();
store = ma_dataTransferN(IsStore, 8 * byteSize /* bits */, isSigned,
memoryBase, ptr, val);
append(access, js::wasm::TrapMachineInsnForStore(byteSize),
FaultingCodeOffset(store.getOffset()));
}
}
asMasm().memoryBarrierAfter(access.sync());
}