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android / platform / art / 3d21bdf / . / compiler / utils / arm64 / assembler_arm64.cc
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/*
* Copyright (C) 2014 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "assembler_arm64.h"
#include "base/logging.h"
#include "entrypoints/quick/quick_entrypoints.h"
#include "offsets.h"
#include "thread.h"
using namespace vixl; // NOLINT(build/namespaces)
namespace art {
namespace arm64 {
#ifdef ___
#error "ARM64 Assembler macro already defined."
#else
#define ___ vixl_masm_->
#endif
void Arm64Assembler::EmitSlowPaths() {
if (!exception_blocks_.empty()) {
for (size_t i = 0; i < exception_blocks_.size(); i++) {
EmitExceptionPoll(exception_blocks_.at(i));
}
}
___ FinalizeCode();
}
size_t Arm64Assembler::CodeSize() const {
return vixl_masm_->BufferCapacity() - vixl_masm_->RemainingBufferSpace();
}
void Arm64Assembler::FinalizeInstructions(const MemoryRegion& region) {
// Copy the instructions from the buffer.
MemoryRegion from(vixl_masm_->GetStartAddress<void*>(), CodeSize());
region.CopyFrom(0, from);
}
void Arm64Assembler::GetCurrentThread(ManagedRegister tr) {
___ Mov(reg_x(tr.AsArm64().AsXRegister()), reg_x(ETR));
}
void Arm64Assembler::GetCurrentThread(FrameOffset offset, ManagedRegister /* scratch */) {
StoreToOffset(ETR, SP, offset.Int32Value());
}
// See Arm64 PCS Section 5.2.2.1.
void Arm64Assembler::IncreaseFrameSize(size_t adjust) {
CHECK_ALIGNED(adjust, kStackAlignment);
AddConstant(SP, -adjust);
cfi().AdjustCFAOffset(adjust);
}
// See Arm64 PCS Section 5.2.2.1.
void Arm64Assembler::DecreaseFrameSize(size_t adjust) {
CHECK_ALIGNED(adjust, kStackAlignment);
AddConstant(SP, adjust);
cfi().AdjustCFAOffset(-adjust);
}
void Arm64Assembler::AddConstant(XRegister rd, int32_t value, Condition cond) {
AddConstant(rd, rd, value, cond);
}
void Arm64Assembler::AddConstant(XRegister rd, XRegister rn, int32_t value,
Condition cond) {
if ((cond == al) || (cond == nv)) {
// VIXL macro-assembler handles all variants.
___ Add(reg_x(rd), reg_x(rn), value);
} else {
// temp = rd + value
// rd = cond ? temp : rn
vixl::UseScratchRegisterScope temps(vixl_masm_);
temps.Exclude(reg_x(rd), reg_x(rn));
vixl::Register temp = temps.AcquireX();
___ Add(temp, reg_x(rn), value);
___ Csel(reg_x(rd), temp, reg_x(rd), cond);
}
}
void Arm64Assembler::StoreWToOffset(StoreOperandType type, WRegister source,
XRegister base, int32_t offset) {
switch (type) {
case kStoreByte:
___ Strb(reg_w(source), MEM_OP(reg_x(base), offset));
break;
case kStoreHalfword:
___ Strh(reg_w(source), MEM_OP(reg_x(base), offset));
break;
case kStoreWord:
___ Str(reg_w(source), MEM_OP(reg_x(base), offset));
break;
default:
LOG(FATAL) << "UNREACHABLE";
}
}
void Arm64Assembler::StoreToOffset(XRegister source, XRegister base, int32_t offset) {
CHECK_NE(source, SP);
___ Str(reg_x(source), MEM_OP(reg_x(base), offset));
}
void Arm64Assembler::StoreSToOffset(SRegister source, XRegister base, int32_t offset) {
___ Str(reg_s(source), MEM_OP(reg_x(base), offset));
}
void Arm64Assembler::StoreDToOffset(DRegister source, XRegister base, int32_t offset) {
___ Str(reg_d(source), MEM_OP(reg_x(base), offset));
}
void Arm64Assembler::Store(FrameOffset offs, ManagedRegister m_src, size_t size) {
Arm64ManagedRegister src = m_src.AsArm64();
if (src.IsNoRegister()) {
CHECK_EQ(0u, size);
} else if (src.IsWRegister()) {
CHECK_EQ(4u, size);
StoreWToOffset(kStoreWord, src.AsWRegister(), SP, offs.Int32Value());
} else if (src.IsXRegister()) {
CHECK_EQ(8u, size);
StoreToOffset(src.AsXRegister(), SP, offs.Int32Value());
} else if (src.IsSRegister()) {
StoreSToOffset(src.AsSRegister(), SP, offs.Int32Value());
} else {
CHECK(src.IsDRegister()) << src;
StoreDToOffset(src.AsDRegister(), SP, offs.Int32Value());
}
}
void Arm64Assembler::StoreRef(FrameOffset offs, ManagedRegister m_src) {
Arm64ManagedRegister src = m_src.AsArm64();
CHECK(src.IsXRegister()) << src;
StoreWToOffset(kStoreWord, src.AsOverlappingWRegister(), SP,
offs.Int32Value());
}
void Arm64Assembler::StoreRawPtr(FrameOffset offs, ManagedRegister m_src) {
Arm64ManagedRegister src = m_src.AsArm64();
CHECK(src.IsXRegister()) << src;
StoreToOffset(src.AsXRegister(), SP, offs.Int32Value());
}
void Arm64Assembler::StoreImmediateToFrame(FrameOffset offs, uint32_t imm,
ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
LoadImmediate(scratch.AsXRegister(), imm);
StoreWToOffset(kStoreWord, scratch.AsOverlappingWRegister(), SP,
offs.Int32Value());
}
void Arm64Assembler::StoreImmediateToThread64(ThreadOffset<8> offs, uint32_t imm,
ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
LoadImmediate(scratch.AsXRegister(), imm);
StoreToOffset(scratch.AsXRegister(), ETR, offs.Int32Value());
}
void Arm64Assembler::StoreStackOffsetToThread64(ThreadOffset<8> tr_offs,
FrameOffset fr_offs,
ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
AddConstant(scratch.AsXRegister(), SP, fr_offs.Int32Value());
StoreToOffset(scratch.AsXRegister(), ETR, tr_offs.Int32Value());
}
void Arm64Assembler::StoreStackPointerToThread64(ThreadOffset<8> tr_offs) {
vixl::UseScratchRegisterScope temps(vixl_masm_);
vixl::Register temp = temps.AcquireX();
___ Mov(temp, reg_x(SP));
___ Str(temp, MEM_OP(reg_x(ETR), tr_offs.Int32Value()));
}
void Arm64Assembler::StoreSpanning(FrameOffset dest_off, ManagedRegister m_source,
FrameOffset in_off, ManagedRegister m_scratch) {
Arm64ManagedRegister source = m_source.AsArm64();
Arm64ManagedRegister scratch = m_scratch.AsArm64();
StoreToOffset(source.AsXRegister(), SP, dest_off.Int32Value());
LoadFromOffset(scratch.AsXRegister(), SP, in_off.Int32Value());
StoreToOffset(scratch.AsXRegister(), SP, dest_off.Int32Value() + 8);
}
// Load routines.
void Arm64Assembler::LoadImmediate(XRegister dest, int32_t value,
Condition cond) {
if ((cond == al) || (cond == nv)) {
___ Mov(reg_x(dest), value);
} else {
// temp = value
// rd = cond ? temp : rd
if (value != 0) {
vixl::UseScratchRegisterScope temps(vixl_masm_);
temps.Exclude(reg_x(dest));
vixl::Register temp = temps.AcquireX();
___ Mov(temp, value);
___ Csel(reg_x(dest), temp, reg_x(dest), cond);
} else {
___ Csel(reg_x(dest), reg_x(XZR), reg_x(dest), cond);
}
}
}
void Arm64Assembler::LoadWFromOffset(LoadOperandType type, WRegister dest,
XRegister base, int32_t offset) {
switch (type) {
case kLoadSignedByte:
___ Ldrsb(reg_w(dest), MEM_OP(reg_x(base), offset));
break;
case kLoadSignedHalfword:
___ Ldrsh(reg_w(dest), MEM_OP(reg_x(base), offset));
break;
case kLoadUnsignedByte:
___ Ldrb(reg_w(dest), MEM_OP(reg_x(base), offset));
break;
case kLoadUnsignedHalfword:
___ Ldrh(reg_w(dest), MEM_OP(reg_x(base), offset));
break;
case kLoadWord:
___ Ldr(reg_w(dest), MEM_OP(reg_x(base), offset));
break;
default:
LOG(FATAL) << "UNREACHABLE";
}
}
// Note: We can extend this member by adding load type info - see
// sign extended A64 load variants.
void Arm64Assembler::LoadFromOffset(XRegister dest, XRegister base,
int32_t offset) {
CHECK_NE(dest, SP);
___ Ldr(reg_x(dest), MEM_OP(reg_x(base), offset));
}
void Arm64Assembler::LoadSFromOffset(SRegister dest, XRegister base,
int32_t offset) {
___ Ldr(reg_s(dest), MEM_OP(reg_x(base), offset));
}
void Arm64Assembler::LoadDFromOffset(DRegister dest, XRegister base,
int32_t offset) {
___ Ldr(reg_d(dest), MEM_OP(reg_x(base), offset));
}
void Arm64Assembler::Load(Arm64ManagedRegister dest, XRegister base,
int32_t offset, size_t size) {
if (dest.IsNoRegister()) {
CHECK_EQ(0u, size) << dest;
} else if (dest.IsWRegister()) {
CHECK_EQ(4u, size) << dest;
___ Ldr(reg_w(dest.AsWRegister()), MEM_OP(reg_x(base), offset));
} else if (dest.IsXRegister()) {
CHECK_NE(dest.AsXRegister(), SP) << dest;
if (size == 4u) {
___ Ldr(reg_w(dest.AsOverlappingWRegister()), MEM_OP(reg_x(base), offset));
} else {
CHECK_EQ(8u, size) << dest;
___ Ldr(reg_x(dest.AsXRegister()), MEM_OP(reg_x(base), offset));
}
} else if (dest.IsSRegister()) {
___ Ldr(reg_s(dest.AsSRegister()), MEM_OP(reg_x(base), offset));
} else {
CHECK(dest.IsDRegister()) << dest;
___ Ldr(reg_d(dest.AsDRegister()), MEM_OP(reg_x(base), offset));
}
}
void Arm64Assembler::Load(ManagedRegister m_dst, FrameOffset src, size_t size) {
return Load(m_dst.AsArm64(), SP, src.Int32Value(), size);
}
void Arm64Assembler::LoadFromThread64(ManagedRegister m_dst, ThreadOffset<8> src, size_t size) {
return Load(m_dst.AsArm64(), ETR, src.Int32Value(), size);
}
void Arm64Assembler::LoadRef(ManagedRegister m_dst, FrameOffset offs) {
Arm64ManagedRegister dst = m_dst.AsArm64();
CHECK(dst.IsXRegister()) << dst;
LoadWFromOffset(kLoadWord, dst.AsOverlappingWRegister(), SP, offs.Int32Value());
}
void Arm64Assembler::LoadRef(ManagedRegister m_dst, ManagedRegister m_base, MemberOffset offs,
bool poison_reference) {
Arm64ManagedRegister dst = m_dst.AsArm64();
Arm64ManagedRegister base = m_base.AsArm64();
CHECK(dst.IsXRegister() && base.IsXRegister());
LoadWFromOffset(kLoadWord, dst.AsOverlappingWRegister(), base.AsXRegister(),
offs.Int32Value());
if (kPoisonHeapReferences && poison_reference) {
WRegister ref_reg = dst.AsOverlappingWRegister();
___ Neg(reg_w(ref_reg), vixl::Operand(reg_w(ref_reg)));
}
}
void Arm64Assembler::LoadRawPtr(ManagedRegister m_dst, ManagedRegister m_base, Offset offs) {
Arm64ManagedRegister dst = m_dst.AsArm64();
Arm64ManagedRegister base = m_base.AsArm64();
CHECK(dst.IsXRegister() && base.IsXRegister());
// Remove dst and base form the temp list - higher level API uses IP1, IP0.
vixl::UseScratchRegisterScope temps(vixl_masm_);
temps.Exclude(reg_x(dst.AsXRegister()), reg_x(base.AsXRegister()));
___ Ldr(reg_x(dst.AsXRegister()), MEM_OP(reg_x(base.AsXRegister()), offs.Int32Value()));
}
void Arm64Assembler::LoadRawPtrFromThread64(ManagedRegister m_dst, ThreadOffset<8> offs) {
Arm64ManagedRegister dst = m_dst.AsArm64();
CHECK(dst.IsXRegister()) << dst;
LoadFromOffset(dst.AsXRegister(), ETR, offs.Int32Value());
}
// Copying routines.
void Arm64Assembler::Move(ManagedRegister m_dst, ManagedRegister m_src, size_t size) {
Arm64ManagedRegister dst = m_dst.AsArm64();
Arm64ManagedRegister src = m_src.AsArm64();
if (!dst.Equals(src)) {
if (dst.IsXRegister()) {
if (size == 4) {
CHECK(src.IsWRegister());
___ Mov(reg_w(dst.AsOverlappingWRegister()), reg_w(src.AsWRegister()));
} else {
if (src.IsXRegister()) {
___ Mov(reg_x(dst.AsXRegister()), reg_x(src.AsXRegister()));
} else {
___ Mov(reg_x(dst.AsXRegister()), reg_x(src.AsOverlappingXRegister()));
}
}
} else if (dst.IsWRegister()) {
CHECK(src.IsWRegister()) << src;
___ Mov(reg_w(dst.AsWRegister()), reg_w(src.AsWRegister()));
} else if (dst.IsSRegister()) {
CHECK(src.IsSRegister()) << src;
___ Fmov(reg_s(dst.AsSRegister()), reg_s(src.AsSRegister()));
} else {
CHECK(dst.IsDRegister()) << dst;
CHECK(src.IsDRegister()) << src;
___ Fmov(reg_d(dst.AsDRegister()), reg_d(src.AsDRegister()));
}
}
}
void Arm64Assembler::CopyRawPtrFromThread64(FrameOffset fr_offs,
ThreadOffset<8> tr_offs,
ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
LoadFromOffset(scratch.AsXRegister(), ETR, tr_offs.Int32Value());
StoreToOffset(scratch.AsXRegister(), SP, fr_offs.Int32Value());
}
void Arm64Assembler::CopyRawPtrToThread64(ThreadOffset<8> tr_offs,
FrameOffset fr_offs,
ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
LoadFromOffset(scratch.AsXRegister(), SP, fr_offs.Int32Value());
StoreToOffset(scratch.AsXRegister(), ETR, tr_offs.Int32Value());
}
void Arm64Assembler::CopyRef(FrameOffset dest, FrameOffset src,
ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
LoadWFromOffset(kLoadWord, scratch.AsOverlappingWRegister(),
SP, src.Int32Value());
StoreWToOffset(kStoreWord, scratch.AsOverlappingWRegister(),
SP, dest.Int32Value());
}
void Arm64Assembler::Copy(FrameOffset dest, FrameOffset src,
ManagedRegister m_scratch, size_t size) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
CHECK(size == 4 || size == 8) << size;
if (size == 4) {
LoadWFromOffset(kLoadWord, scratch.AsOverlappingWRegister(), SP, src.Int32Value());
StoreWToOffset(kStoreWord, scratch.AsOverlappingWRegister(), SP, dest.Int32Value());
} else if (size == 8) {
LoadFromOffset(scratch.AsXRegister(), SP, src.Int32Value());
StoreToOffset(scratch.AsXRegister(), SP, dest.Int32Value());
} else {
UNIMPLEMENTED(FATAL) << "We only support Copy() of size 4 and 8";
}
}
void Arm64Assembler::Copy(FrameOffset dest, ManagedRegister src_base, Offset src_offset,
ManagedRegister m_scratch, size_t size) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
Arm64ManagedRegister base = src_base.AsArm64();
CHECK(base.IsXRegister()) << base;
CHECK(scratch.IsXRegister() || scratch.IsWRegister()) << scratch;
CHECK(size == 4 || size == 8) << size;
if (size == 4) {
LoadWFromOffset(kLoadWord, scratch.AsWRegister(), base.AsXRegister(),
src_offset.Int32Value());
StoreWToOffset(kStoreWord, scratch.AsWRegister(), SP, dest.Int32Value());
} else if (size == 8) {
LoadFromOffset(scratch.AsXRegister(), base.AsXRegister(), src_offset.Int32Value());
StoreToOffset(scratch.AsXRegister(), SP, dest.Int32Value());
} else {
UNIMPLEMENTED(FATAL) << "We only support Copy() of size 4 and 8";
}
}
void Arm64Assembler::Copy(ManagedRegister m_dest_base, Offset dest_offs, FrameOffset src,
ManagedRegister m_scratch, size_t size) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
Arm64ManagedRegister base = m_dest_base.AsArm64();
CHECK(base.IsXRegister()) << base;
CHECK(scratch.IsXRegister() || scratch.IsWRegister()) << scratch;
CHECK(size == 4 || size == 8) << size;
if (size == 4) {
LoadWFromOffset(kLoadWord, scratch.AsWRegister(), SP, src.Int32Value());
StoreWToOffset(kStoreWord, scratch.AsWRegister(), base.AsXRegister(),
dest_offs.Int32Value());
} else if (size == 8) {
LoadFromOffset(scratch.AsXRegister(), SP, src.Int32Value());
StoreToOffset(scratch.AsXRegister(), base.AsXRegister(), dest_offs.Int32Value());
} else {
UNIMPLEMENTED(FATAL) << "We only support Copy() of size 4 and 8";
}
}
void Arm64Assembler::Copy(FrameOffset /*dst*/, FrameOffset /*src_base*/, Offset /*src_offset*/,
ManagedRegister /*mscratch*/, size_t /*size*/) {
UNIMPLEMENTED(FATAL) << "Unimplemented Copy() variant";
}
void Arm64Assembler::Copy(ManagedRegister m_dest, Offset dest_offset,
ManagedRegister m_src, Offset src_offset,
ManagedRegister m_scratch, size_t size) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
Arm64ManagedRegister src = m_src.AsArm64();
Arm64ManagedRegister dest = m_dest.AsArm64();
CHECK(dest.IsXRegister()) << dest;
CHECK(src.IsXRegister()) << src;
CHECK(scratch.IsXRegister() || scratch.IsWRegister()) << scratch;
CHECK(size == 4 || size == 8) << size;
if (size == 4) {
if (scratch.IsWRegister()) {
LoadWFromOffset(kLoadWord, scratch.AsWRegister(), src.AsXRegister(),
src_offset.Int32Value());
StoreWToOffset(kStoreWord, scratch.AsWRegister(), dest.AsXRegister(),
dest_offset.Int32Value());
} else {
LoadWFromOffset(kLoadWord, scratch.AsOverlappingWRegister(), src.AsXRegister(),
src_offset.Int32Value());
StoreWToOffset(kStoreWord, scratch.AsOverlappingWRegister(), dest.AsXRegister(),
dest_offset.Int32Value());
}
} else if (size == 8) {
LoadFromOffset(scratch.AsXRegister(), src.AsXRegister(), src_offset.Int32Value());
StoreToOffset(scratch.AsXRegister(), dest.AsXRegister(), dest_offset.Int32Value());
} else {
UNIMPLEMENTED(FATAL) << "We only support Copy() of size 4 and 8";
}
}
void Arm64Assembler::Copy(FrameOffset /*dst*/, Offset /*dest_offset*/,
FrameOffset /*src*/, Offset /*src_offset*/,
ManagedRegister /*scratch*/, size_t /*size*/) {
UNIMPLEMENTED(FATAL) << "Unimplemented Copy() variant";
}
void Arm64Assembler::MemoryBarrier(ManagedRegister m_scratch ATTRIBUTE_UNUSED) {
// TODO: Should we check that m_scratch is IP? - see arm.
___ Dmb(vixl::InnerShareable, vixl::BarrierAll);
}
void Arm64Assembler::SignExtend(ManagedRegister mreg, size_t size) {
Arm64ManagedRegister reg = mreg.AsArm64();
CHECK(size == 1 || size == 2) << size;
CHECK(reg.IsWRegister()) << reg;
if (size == 1) {
___ Sxtb(reg_w(reg.AsWRegister()), reg_w(reg.AsWRegister()));
} else {
___ Sxth(reg_w(reg.AsWRegister()), reg_w(reg.AsWRegister()));
}
}
void Arm64Assembler::ZeroExtend(ManagedRegister mreg, size_t size) {
Arm64ManagedRegister reg = mreg.AsArm64();
CHECK(size == 1 || size == 2) << size;
CHECK(reg.IsWRegister()) << reg;
if (size == 1) {
___ Uxtb(reg_w(reg.AsWRegister()), reg_w(reg.AsWRegister()));
} else {
___ Uxth(reg_w(reg.AsWRegister()), reg_w(reg.AsWRegister()));
}
}
void Arm64Assembler::VerifyObject(ManagedRegister /*src*/, bool /*could_be_null*/) {
// TODO: not validating references.
}
void Arm64Assembler::VerifyObject(FrameOffset /*src*/, bool /*could_be_null*/) {
// TODO: not validating references.
}
void Arm64Assembler::Call(ManagedRegister m_base, Offset offs, ManagedRegister m_scratch) {
Arm64ManagedRegister base = m_base.AsArm64();
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(base.IsXRegister()) << base;
CHECK(scratch.IsXRegister()) << scratch;
LoadFromOffset(scratch.AsXRegister(), base.AsXRegister(), offs.Int32Value());
___ Blr(reg_x(scratch.AsXRegister()));
}
void Arm64Assembler::JumpTo(ManagedRegister m_base, Offset offs, ManagedRegister m_scratch) {
Arm64ManagedRegister base = m_base.AsArm64();
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(base.IsXRegister()) << base;
CHECK(scratch.IsXRegister()) << scratch;
// Remove base and scratch form the temp list - higher level API uses IP1, IP0.
vixl::UseScratchRegisterScope temps(vixl_masm_);
temps.Exclude(reg_x(base.AsXRegister()), reg_x(scratch.AsXRegister()));
___ Ldr(reg_x(scratch.AsXRegister()), MEM_OP(reg_x(base.AsXRegister()), offs.Int32Value()));
___ Br(reg_x(scratch.AsXRegister()));
}
void Arm64Assembler::Call(FrameOffset base, Offset offs, ManagedRegister m_scratch) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
// Call *(*(SP + base) + offset)
LoadFromOffset(scratch.AsXRegister(), SP, base.Int32Value());
LoadFromOffset(scratch.AsXRegister(), scratch.AsXRegister(), offs.Int32Value());
___ Blr(reg_x(scratch.AsXRegister()));
}
void Arm64Assembler::CallFromThread64(ThreadOffset<8> /*offset*/, ManagedRegister /*scratch*/) {
UNIMPLEMENTED(FATAL) << "Unimplemented Call() variant";
}
void Arm64Assembler::CreateHandleScopeEntry(
ManagedRegister m_out_reg, FrameOffset handle_scope_offs, ManagedRegister m_in_reg,
bool null_allowed) {
Arm64ManagedRegister out_reg = m_out_reg.AsArm64();
Arm64ManagedRegister in_reg = m_in_reg.AsArm64();
// For now we only hold stale handle scope entries in x registers.
CHECK(in_reg.IsNoRegister() || in_reg.IsXRegister()) << in_reg;
CHECK(out_reg.IsXRegister()) << out_reg;
if (null_allowed) {
// Null values get a handle scope entry value of 0. Otherwise, the handle scope entry is
// the address in the handle scope holding the reference.
// e.g. out_reg = (handle == 0) ? 0 : (SP+handle_offset)
if (in_reg.IsNoRegister()) {
LoadWFromOffset(kLoadWord, out_reg.AsOverlappingWRegister(), SP,
handle_scope_offs.Int32Value());
in_reg = out_reg;
}
___ Cmp(reg_w(in_reg.AsOverlappingWRegister()), 0);
if (!out_reg.Equals(in_reg)) {
LoadImmediate(out_reg.AsXRegister(), 0, eq);
}
AddConstant(out_reg.AsXRegister(), SP, handle_scope_offs.Int32Value(), ne);
} else {
AddConstant(out_reg.AsXRegister(), SP, handle_scope_offs.Int32Value(), al);
}
}
void Arm64Assembler::CreateHandleScopeEntry(FrameOffset out_off, FrameOffset handle_scope_offset,
ManagedRegister m_scratch, bool null_allowed) {
Arm64ManagedRegister scratch = m_scratch.AsArm64();
CHECK(scratch.IsXRegister()) << scratch;
if (null_allowed) {
LoadWFromOffset(kLoadWord, scratch.AsOverlappingWRegister(), SP,
handle_scope_offset.Int32Value());
// Null values get a handle scope entry value of 0. Otherwise, the handle scope entry is
// the address in the handle scope holding the reference.
// e.g. scratch = (scratch == 0) ? 0 : (SP+handle_scope_offset)
___ Cmp(reg_w(scratch.AsOverlappingWRegister()), 0);
// Move this logic in add constants with flags.
AddConstant(scratch.AsXRegister(), SP, handle_scope_offset.Int32Value(), ne);
} else {
AddConstant(scratch.AsXRegister(), SP, handle_scope_offset.Int32Value(), al);
}
StoreToOffset(scratch.AsXRegister(), SP, out_off.Int32Value());
}
void Arm64Assembler::LoadReferenceFromHandleScope(ManagedRegister m_out_reg,
ManagedRegister m_in_reg) {
Arm64ManagedRegister out_reg = m_out_reg.AsArm64();
Arm64ManagedRegister in_reg = m_in_reg.AsArm64();
CHECK(out_reg.IsXRegister()) << out_reg;
CHECK(in_reg.IsXRegister()) << in_reg;
vixl::Label exit;
if (!out_reg.Equals(in_reg)) {
// FIXME: Who sets the flags here?
LoadImmediate(out_reg.AsXRegister(), 0, eq);
}
___ Cbz(reg_x(in_reg.AsXRegister()), &exit);
LoadFromOffset(out_reg.AsXRegister(), in_reg.AsXRegister(), 0);
___ Bind(&exit);
}
void Arm64Assembler::ExceptionPoll(ManagedRegister m_scratch, size_t stack_adjust) {
CHECK_ALIGNED(stack_adjust, kStackAlignment);
Arm64ManagedRegister scratch = m_scratch.AsArm64();
Arm64Exception *current_exception = new Arm64Exception(scratch, stack_adjust);
exception_blocks_.push_back(current_exception);
LoadFromOffset(scratch.AsXRegister(), ETR, Thread::ExceptionOffset<8>().Int32Value());
___ Cbnz(reg_x(scratch.AsXRegister()), current_exception->Entry());
}
void Arm64Assembler::EmitExceptionPoll(Arm64Exception *exception) {
vixl::UseScratchRegisterScope temps(vixl_masm_);
temps.Exclude(reg_x(exception->scratch_.AsXRegister()));
vixl::Register temp = temps.AcquireX();
// Bind exception poll entry.
___ Bind(exception->Entry());
if (exception->stack_adjust_ != 0) { // Fix up the frame.
DecreaseFrameSize(exception->stack_adjust_);
}
// Pass exception object as argument.
// Don't care about preserving X0 as this won't return.
___ Mov(reg_x(X0), reg_x(exception->scratch_.AsXRegister()));
___ Ldr(temp, MEM_OP(reg_x(ETR), QUICK_ENTRYPOINT_OFFSET(8, pDeliverException).Int32Value()));
// Move ETR(Callee saved) back to TR(Caller saved) reg. We use ETR on calls
// to external functions that might trash TR. We do not need the original
// ETR(X21) saved in BuildFrame().
___ Mov(reg_x(TR), reg_x(ETR));
___ Blr(temp);
// Call should never return.
___ Brk();
}
static inline dwarf::Reg DWARFReg(CPURegister reg) {
if (reg.IsFPRegister()) {
return dwarf::Reg::Arm64Fp(reg.code());
} else {
DCHECK_LT(reg.code(), 31u); // X0 - X30.
return dwarf::Reg::Arm64Core(reg.code());
}
}
void Arm64Assembler::SpillRegisters(vixl::CPURegList registers, int offset) {
int size = registers.RegisterSizeInBytes();
const Register sp = vixl_masm_->StackPointer();
while (registers.Count() >= 2) {
const CPURegister& dst0 = registers.PopLowestIndex();
const CPURegister& dst1 = registers.PopLowestIndex();
___ Stp(dst0, dst1, MemOperand(sp, offset));
cfi_.RelOffset(DWARFReg(dst0), offset);
cfi_.RelOffset(DWARFReg(dst1), offset + size);
offset += 2 * size;
}
if (!registers.IsEmpty()) {
const CPURegister& dst0 = registers.PopLowestIndex();
___ Str(dst0, MemOperand(sp, offset));
cfi_.RelOffset(DWARFReg(dst0), offset);
}
DCHECK(registers.IsEmpty());
}
void Arm64Assembler::UnspillRegisters(vixl::CPURegList registers, int offset) {
int size = registers.RegisterSizeInBytes();
const Register sp = vixl_masm_->StackPointer();
while (registers.Count() >= 2) {
const CPURegister& dst0 = registers.PopLowestIndex();
const CPURegister& dst1 = registers.PopLowestIndex();
___ Ldp(dst0, dst1, MemOperand(sp, offset));
cfi_.Restore(DWARFReg(dst0));
cfi_.Restore(DWARFReg(dst1));
offset += 2 * size;
}
if (!registers.IsEmpty()) {
const CPURegister& dst0 = registers.PopLowestIndex();
___ Ldr(dst0, MemOperand(sp, offset));
cfi_.Restore(DWARFReg(dst0));
}
DCHECK(registers.IsEmpty());
}
void Arm64Assembler::BuildFrame(size_t frame_size, ManagedRegister method_reg,
const std::vector<ManagedRegister>& callee_save_regs,
const ManagedRegisterEntrySpills& entry_spills) {
// Setup VIXL CPURegList for callee-saves.
CPURegList core_reg_list(CPURegister::kRegister, kXRegSize, 0);
CPURegList fp_reg_list(CPURegister::kFPRegister, kDRegSize, 0);
for (auto r : callee_save_regs) {
Arm64ManagedRegister reg = r.AsArm64();
if (reg.IsXRegister()) {
core_reg_list.Combine(reg_x(reg.AsXRegister()).code());
} else {
DCHECK(reg.IsDRegister());
fp_reg_list.Combine(reg_d(reg.AsDRegister()).code());
}
}
size_t core_reg_size = core_reg_list.TotalSizeInBytes();
size_t fp_reg_size = fp_reg_list.TotalSizeInBytes();
// Increase frame to required size.
DCHECK_ALIGNED(frame_size, kStackAlignment);
DCHECK_GE(frame_size, core_reg_size + fp_reg_size + kArm64PointerSize);
IncreaseFrameSize(frame_size);
// Save callee-saves.
SpillRegisters(core_reg_list, frame_size - core_reg_size);
SpillRegisters(fp_reg_list, frame_size - core_reg_size - fp_reg_size);
// Note: This is specific to JNI method frame.
// We will need to move TR(Caller saved in AAPCS) to ETR(Callee saved in AAPCS). The original
// (ETR)X21 has been saved on stack. In this way, we can restore TR later.
DCHECK(!core_reg_list.IncludesAliasOf(reg_x(TR)));
DCHECK(core_reg_list.IncludesAliasOf(reg_x(ETR)));
___ Mov(reg_x(ETR), reg_x(TR));
// Write ArtMethod*
DCHECK(X0 == method_reg.AsArm64().AsXRegister());
StoreToOffset(X0, SP, 0);
// Write out entry spills
int32_t offset = frame_size + kArm64PointerSize;
for (size_t i = 0; i < entry_spills.size(); ++i) {
Arm64ManagedRegister reg = entry_spills.at(i).AsArm64();
if (reg.IsNoRegister()) {
// only increment stack offset.
ManagedRegisterSpill spill = entry_spills.at(i);
offset += spill.getSize();
} else if (reg.IsXRegister()) {
StoreToOffset(reg.AsXRegister(), SP, offset);
offset += 8;
} else if (reg.IsWRegister()) {
StoreWToOffset(kStoreWord, reg.AsWRegister(), SP, offset);
offset += 4;
} else if (reg.IsDRegister()) {
StoreDToOffset(reg.AsDRegister(), SP, offset);
offset += 8;
} else if (reg.IsSRegister()) {
StoreSToOffset(reg.AsSRegister(), SP, offset);
offset += 4;
}
}
}
void Arm64Assembler::RemoveFrame(size_t frame_size,
const std::vector<ManagedRegister>& callee_save_regs) {
// Setup VIXL CPURegList for callee-saves.
CPURegList core_reg_list(CPURegister::kRegister, kXRegSize, 0);
CPURegList fp_reg_list(CPURegister::kFPRegister, kDRegSize, 0);
for (auto r : callee_save_regs) {
Arm64ManagedRegister reg = r.AsArm64();
if (reg.IsXRegister()) {
core_reg_list.Combine(reg_x(reg.AsXRegister()).code());
} else {
DCHECK(reg.IsDRegister());
fp_reg_list.Combine(reg_d(reg.AsDRegister()).code());
}
}
size_t core_reg_size = core_reg_list.TotalSizeInBytes();
size_t fp_reg_size = fp_reg_list.TotalSizeInBytes();
// For now we only check that the size of the frame is large enough to hold spills and method
// reference.
DCHECK_GE(frame_size, core_reg_size + fp_reg_size + kArm64PointerSize);
DCHECK_ALIGNED(frame_size, kStackAlignment);
// Note: This is specific to JNI method frame.
// Restore TR(Caller saved in AAPCS) from ETR(Callee saved in AAPCS).
DCHECK(!core_reg_list.IncludesAliasOf(reg_x(TR)));
DCHECK(core_reg_list.IncludesAliasOf(reg_x(ETR)));
___ Mov(reg_x(TR), reg_x(ETR));
cfi_.RememberState();
// Restore callee-saves.
UnspillRegisters(core_reg_list, frame_size - core_reg_size);
UnspillRegisters(fp_reg_list, frame_size - core_reg_size - fp_reg_size);
// Decrease frame size to start of callee saved regs.
DecreaseFrameSize(frame_size);
// Pop callee saved and return to LR.
___ Ret();
// The CFI should be restored for any code that follows the exit block.
cfi_.RestoreState();
cfi_.DefCFAOffset(frame_size);
}
} // namespace arm64
} // namespace art