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gerrit-public.fairphone.software / platform / art / 3acee732f9475fbfc6b046e0044b764e7ff5ac01 / . / compiler / utils / mips / assembler_mips.cc
blob: 6fd65ee9a43efbec48739c59147c1fc7b19c42ad [file] [log] [blame]
/*
* Copyright (C) 2011 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "assembler_mips.h"
#include "base/bit_utils.h"
#include "base/casts.h"
#include "entrypoints/quick/quick_entrypoints.h"
#include "entrypoints/quick/quick_entrypoints_enum.h"
#include "memory_region.h"
#include "thread.h"
namespace art {
namespace mips {
std::ostream& operator<<(std::ostream& os, const DRegister& rhs) {
if (rhs >= D0 && rhs < kNumberOfDRegisters) {
os << "d" << static_cast<int>(rhs);
} else {
os << "DRegister[" << static_cast<int>(rhs) << "]";
}
return os;
}
void MipsAssembler::FinalizeCode() {
for (auto& exception_block : exception_blocks_) {
EmitExceptionPoll(&exception_block);
}
PromoteBranches();
}
void MipsAssembler::FinalizeInstructions(const MemoryRegion& region) {
size_t number_of_delayed_adjust_pcs = cfi().NumberOfDelayedAdvancePCs();
EmitBranches();
Assembler::FinalizeInstructions(region);
PatchCFI(number_of_delayed_adjust_pcs);
}
void MipsAssembler::PatchCFI(size_t number_of_delayed_adjust_pcs) {
if (cfi().NumberOfDelayedAdvancePCs() == 0u) {
DCHECK_EQ(number_of_delayed_adjust_pcs, 0u);
return;
}
typedef DebugFrameOpCodeWriterForAssembler::DelayedAdvancePC DelayedAdvancePC;
const auto data = cfi().ReleaseStreamAndPrepareForDelayedAdvancePC();
const std::vector<uint8_t>& old_stream = data.first;
const std::vector<DelayedAdvancePC>& advances = data.second;
// PCs recorded before EmitBranches() need to be adjusted.
// PCs recorded during EmitBranches() are already adjusted.
// Both ranges are separately sorted but they may overlap.
if (kIsDebugBuild) {
auto cmp = [](const DelayedAdvancePC& lhs, const DelayedAdvancePC& rhs) {
return lhs.pc < rhs.pc;
};
CHECK(std::is_sorted(advances.begin(), advances.begin() + number_of_delayed_adjust_pcs, cmp));
CHECK(std::is_sorted(advances.begin() + number_of_delayed_adjust_pcs, advances.end(), cmp));
}
// Append initial CFI data if any.
size_t size = advances.size();
DCHECK_NE(size, 0u);
cfi().AppendRawData(old_stream, 0u, advances[0].stream_pos);
// Emit PC adjustments interleaved with the old CFI stream.
size_t adjust_pos = 0u;
size_t late_emit_pos = number_of_delayed_adjust_pcs;
while (adjust_pos != number_of_delayed_adjust_pcs || late_emit_pos != size) {
size_t adjusted_pc = (adjust_pos != number_of_delayed_adjust_pcs)
? GetAdjustedPosition(advances[adjust_pos].pc)
: static_cast<size_t>(-1);
size_t late_emit_pc = (late_emit_pos != size)
? advances[late_emit_pos].pc
: static_cast<size_t>(-1);
size_t advance_pc = std::min(adjusted_pc, late_emit_pc);
DCHECK_NE(advance_pc, static_cast<size_t>(-1));
size_t entry = (adjusted_pc <= late_emit_pc) ? adjust_pos : late_emit_pos;
if (adjusted_pc <= late_emit_pc) {
++adjust_pos;
} else {
++late_emit_pos;
}
cfi().AdvancePC(advance_pc);
size_t end_pos = (entry + 1u == size) ? old_stream.size() : advances[entry + 1u].stream_pos;
cfi().AppendRawData(old_stream, advances[entry].stream_pos, end_pos);
}
}
void MipsAssembler::EmitBranches() {
CHECK(!overwriting_);
// Switch from appending instructions at the end of the buffer to overwriting
// existing instructions (branch placeholders) in the buffer.
overwriting_ = true;
for (auto& branch : branches_) {
EmitBranch(&branch);
}
overwriting_ = false;
}
void MipsAssembler::Emit(uint32_t value) {
if (overwriting_) {
// Branches to labels are emitted into their placeholders here.
buffer_.Store<uint32_t>(overwrite_location_, value);
overwrite_location_ += sizeof(uint32_t);
} else {
// Other instructions are simply appended at the end here.
AssemblerBuffer::EnsureCapacity ensured(&buffer_);
buffer_.Emit<uint32_t>(value);
}
}
void MipsAssembler::EmitR(int opcode, Register rs, Register rt, Register rd, int shamt, int funct) {
CHECK_NE(rs, kNoRegister);
CHECK_NE(rt, kNoRegister);
CHECK_NE(rd, kNoRegister);
uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
static_cast<uint32_t>(rs) << kRsShift |
static_cast<uint32_t>(rt) << kRtShift |
static_cast<uint32_t>(rd) << kRdShift |
shamt << kShamtShift |
funct;
Emit(encoding);
}
void MipsAssembler::EmitI(int opcode, Register rs, Register rt, uint16_t imm) {
CHECK_NE(rs, kNoRegister);
CHECK_NE(rt, kNoRegister);
uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
static_cast<uint32_t>(rs) << kRsShift |
static_cast<uint32_t>(rt) << kRtShift |
imm;
Emit(encoding);
}
void MipsAssembler::EmitI21(int opcode, Register rs, uint32_t imm21) {
CHECK_NE(rs, kNoRegister);
CHECK(IsUint<21>(imm21)) << imm21;
uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
static_cast<uint32_t>(rs) << kRsShift |
imm21;
Emit(encoding);
}
void MipsAssembler::EmitI26(int opcode, uint32_t imm26) {
CHECK(IsUint<26>(imm26)) << imm26;
uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift | imm26;
Emit(encoding);
}
void MipsAssembler::EmitFR(int opcode, int fmt, FRegister ft, FRegister fs, FRegister fd,
int funct) {
CHECK_NE(ft, kNoFRegister);
CHECK_NE(fs, kNoFRegister);
CHECK_NE(fd, kNoFRegister);
uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
fmt << kFmtShift |
static_cast<uint32_t>(ft) << kFtShift |
static_cast<uint32_t>(fs) << kFsShift |
static_cast<uint32_t>(fd) << kFdShift |
funct;
Emit(encoding);
}
void MipsAssembler::EmitFI(int opcode, int fmt, FRegister ft, uint16_t imm) {
CHECK_NE(ft, kNoFRegister);
uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
fmt << kFmtShift |
static_cast<uint32_t>(ft) << kFtShift |
imm;
Emit(encoding);
}
void MipsAssembler::Addu(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x21);
}
void MipsAssembler::Addiu(Register rt, Register rs, uint16_t imm16) {
EmitI(0x9, rs, rt, imm16);
}
void MipsAssembler::Subu(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x23);
}
void MipsAssembler::MultR2(Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x18);
}
void MipsAssembler::MultuR2(Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x19);
}
void MipsAssembler::DivR2(Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x1a);
}
void MipsAssembler::DivuR2(Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x1b);
}
void MipsAssembler::MulR2(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0x1c, rs, rt, rd, 0, 2);
}
void MipsAssembler::DivR2(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
DivR2(rs, rt);
Mflo(rd);
}
void MipsAssembler::ModR2(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
DivR2(rs, rt);
Mfhi(rd);
}
void MipsAssembler::DivuR2(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
DivuR2(rs, rt);
Mflo(rd);
}
void MipsAssembler::ModuR2(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
DivuR2(rs, rt);
Mfhi(rd);
}
void MipsAssembler::MulR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 2, 0x18);
}
void MipsAssembler::MuhR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 3, 0x18);
}
void MipsAssembler::MuhuR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 3, 0x19);
}
void MipsAssembler::DivR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 2, 0x1a);
}
void MipsAssembler::ModR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 3, 0x1a);
}
void MipsAssembler::DivuR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 2, 0x1b);
}
void MipsAssembler::ModuR6(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 3, 0x1b);
}
void MipsAssembler::And(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x24);
}
void MipsAssembler::Andi(Register rt, Register rs, uint16_t imm16) {
EmitI(0xc, rs, rt, imm16);
}
void MipsAssembler::Or(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x25);
}
void MipsAssembler::Ori(Register rt, Register rs, uint16_t imm16) {
EmitI(0xd, rs, rt, imm16);
}
void MipsAssembler::Xor(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x26);
}
void MipsAssembler::Xori(Register rt, Register rs, uint16_t imm16) {
EmitI(0xe, rs, rt, imm16);
}
void MipsAssembler::Nor(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x27);
}
void MipsAssembler::Movz(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0, rs, rt, rd, 0, 0x0A);
}
void MipsAssembler::Movn(Register rd, Register rs, Register rt) {
CHECK(!IsR6());
EmitR(0, rs, rt, rd, 0, 0x0B);
}
void MipsAssembler::Seleqz(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 0, 0x35);
}
void MipsAssembler::Selnez(Register rd, Register rs, Register rt) {
CHECK(IsR6());
EmitR(0, rs, rt, rd, 0, 0x37);
}
void MipsAssembler::ClzR6(Register rd, Register rs) {
CHECK(IsR6());
EmitR(0, rs, static_cast<Register>(0), rd, 0x01, 0x10);
}
void MipsAssembler::ClzR2(Register rd, Register rs) {
CHECK(!IsR6());
EmitR(0x1C, rs, rd, rd, 0, 0x20);
}
void MipsAssembler::CloR6(Register rd, Register rs) {
CHECK(IsR6());
EmitR(0, rs, static_cast<Register>(0), rd, 0x01, 0x11);
}
void MipsAssembler::CloR2(Register rd, Register rs) {
CHECK(!IsR6());
EmitR(0x1C, rs, rd, rd, 0, 0x21);
}
void MipsAssembler::Seb(Register rd, Register rt) {
EmitR(0x1f, static_cast<Register>(0), rt, rd, 0x10, 0x20);
}
void MipsAssembler::Seh(Register rd, Register rt) {
EmitR(0x1f, static_cast<Register>(0), rt, rd, 0x18, 0x20);
}
void MipsAssembler::Wsbh(Register rd, Register rt) {
EmitR(0x1f, static_cast<Register>(0), rt, rd, 2, 0x20);
}
void MipsAssembler::Bitswap(Register rd, Register rt) {
CHECK(IsR6());
EmitR(0x1f, static_cast<Register>(0), rt, rd, 0x0, 0x20);
}
void MipsAssembler::Sll(Register rd, Register rt, int shamt) {
CHECK(IsUint<5>(shamt)) << shamt;
EmitR(0, static_cast<Register>(0), rt, rd, shamt, 0x00);
}
void MipsAssembler::Srl(Register rd, Register rt, int shamt) {
CHECK(IsUint<5>(shamt)) << shamt;
EmitR(0, static_cast<Register>(0), rt, rd, shamt, 0x02);
}
void MipsAssembler::Rotr(Register rd, Register rt, int shamt) {
CHECK(IsUint<5>(shamt)) << shamt;
EmitR(0, static_cast<Register>(1), rt, rd, shamt, 0x02);
}
void MipsAssembler::Sra(Register rd, Register rt, int shamt) {
CHECK(IsUint<5>(shamt)) << shamt;
EmitR(0, static_cast<Register>(0), rt, rd, shamt, 0x03);
}
void MipsAssembler::Sllv(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 0, 0x04);
}
void MipsAssembler::Srlv(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 0, 0x06);
}
void MipsAssembler::Rotrv(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 1, 0x06);
}
void MipsAssembler::Srav(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 0, 0x07);
}
void MipsAssembler::Ext(Register rd, Register rt, int pos, int size) {
CHECK(IsUint<5>(pos)) << pos;
CHECK(0 < size && size <= 32) << size;
CHECK(0 < pos + size && pos + size <= 32) << pos << " + " << size;
EmitR(0x1f, rt, rd, static_cast<Register>(size - 1), pos, 0x00);
}
void MipsAssembler::Ins(Register rd, Register rt, int pos, int size) {
CHECK(IsUint<5>(pos)) << pos;
CHECK(0 < size && size <= 32) << size;
CHECK(0 < pos + size && pos + size <= 32) << pos << " + " << size;
EmitR(0x1f, rt, rd, static_cast<Register>(pos + size - 1), pos, 0x04);
}
void MipsAssembler::Lb(Register rt, Register rs, uint16_t imm16) {
EmitI(0x20, rs, rt, imm16);
}
void MipsAssembler::Lh(Register rt, Register rs, uint16_t imm16) {
EmitI(0x21, rs, rt, imm16);
}
void MipsAssembler::Lw(Register rt, Register rs, uint16_t imm16) {
EmitI(0x23, rs, rt, imm16);
}
void MipsAssembler::Lwl(Register rt, Register rs, uint16_t imm16) {
CHECK(!IsR6());
EmitI(0x22, rs, rt, imm16);
}
void MipsAssembler::Lwr(Register rt, Register rs, uint16_t imm16) {
CHECK(!IsR6());
EmitI(0x26, rs, rt, imm16);
}
void MipsAssembler::Lbu(Register rt, Register rs, uint16_t imm16) {
EmitI(0x24, rs, rt, imm16);
}
void MipsAssembler::Lhu(Register rt, Register rs, uint16_t imm16) {
EmitI(0x25, rs, rt, imm16);
}
void MipsAssembler::Lui(Register rt, uint16_t imm16) {
EmitI(0xf, static_cast<Register>(0), rt, imm16);
}
void MipsAssembler::Sync(uint32_t stype) {
EmitR(0, static_cast<Register>(0), static_cast<Register>(0), static_cast<Register>(0),
stype & 0x1f, 0xf);
}
void MipsAssembler::Mfhi(Register rd) {
CHECK(!IsR6());
EmitR(0, static_cast<Register>(0), static_cast<Register>(0), rd, 0, 0x10);
}
void MipsAssembler::Mflo(Register rd) {
CHECK(!IsR6());
EmitR(0, static_cast<Register>(0), static_cast<Register>(0), rd, 0, 0x12);
}
void MipsAssembler::Sb(Register rt, Register rs, uint16_t imm16) {
EmitI(0x28, rs, rt, imm16);
}
void MipsAssembler::Sh(Register rt, Register rs, uint16_t imm16) {
EmitI(0x29, rs, rt, imm16);
}
void MipsAssembler::Sw(Register rt, Register rs, uint16_t imm16) {
EmitI(0x2b, rs, rt, imm16);
}
void MipsAssembler::Swl(Register rt, Register rs, uint16_t imm16) {
CHECK(!IsR6());
EmitI(0x2a, rs, rt, imm16);
}
void MipsAssembler::Swr(Register rt, Register rs, uint16_t imm16) {
CHECK(!IsR6());
EmitI(0x2e, rs, rt, imm16);
}
void MipsAssembler::Slt(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x2a);
}
void MipsAssembler::Sltu(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x2b);
}
void MipsAssembler::Slti(Register rt, Register rs, uint16_t imm16) {
EmitI(0xa, rs, rt, imm16);
}
void MipsAssembler::Sltiu(Register rt, Register rs, uint16_t imm16) {
EmitI(0xb, rs, rt, imm16);
}
void MipsAssembler::B(uint16_t imm16) {
EmitI(0x4, static_cast<Register>(0), static_cast<Register>(0), imm16);
}
void MipsAssembler::Beq(Register rs, Register rt, uint16_t imm16) {
EmitI(0x4, rs, rt, imm16);
}
void MipsAssembler::Bne(Register rs, Register rt, uint16_t imm16) {
EmitI(0x5, rs, rt, imm16);
}
void MipsAssembler::Beqz(Register rt, uint16_t imm16) {
Beq(ZERO, rt, imm16);
}
void MipsAssembler::Bnez(Register rt, uint16_t imm16) {
Bne(ZERO, rt, imm16);
}
void MipsAssembler::Bltz(Register rt, uint16_t imm16) {
EmitI(0x1, rt, static_cast<Register>(0), imm16);
}
void MipsAssembler::Bgez(Register rt, uint16_t imm16) {
EmitI(0x1, rt, static_cast<Register>(0x1), imm16);
}
void MipsAssembler::Blez(Register rt, uint16_t imm16) {
EmitI(0x6, rt, static_cast<Register>(0), imm16);
}
void MipsAssembler::Bgtz(Register rt, uint16_t imm16) {
EmitI(0x7, rt, static_cast<Register>(0), imm16);
}
void MipsAssembler::Bc1f(int cc, uint16_t imm16) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitI(0x11, static_cast<Register>(0x8), static_cast<Register>(cc << 2), imm16);
}
void MipsAssembler::Bc1t(int cc, uint16_t imm16) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitI(0x11, static_cast<Register>(0x8), static_cast<Register>((cc << 2) | 1), imm16);
}
void MipsAssembler::J(uint32_t addr26) {
EmitI26(0x2, addr26);
}
void MipsAssembler::Jal(uint32_t addr26) {
EmitI26(0x3, addr26);
}
void MipsAssembler::Jalr(Register rd, Register rs) {
EmitR(0, rs, static_cast<Register>(0), rd, 0, 0x09);
}
void MipsAssembler::Jalr(Register rs) {
Jalr(RA, rs);
}
void MipsAssembler::Jr(Register rs) {
Jalr(ZERO, rs);
}
void MipsAssembler::Nal() {
EmitI(0x1, static_cast<Register>(0), static_cast<Register>(0x10), 0);
}
void MipsAssembler::Auipc(Register rs, uint16_t imm16) {
CHECK(IsR6());
EmitI(0x3B, rs, static_cast<Register>(0x1E), imm16);
}
void MipsAssembler::Addiupc(Register rs, uint32_t imm19) {
CHECK(IsR6());
CHECK(IsUint<19>(imm19)) << imm19;
EmitI21(0x3B, rs, imm19);
}
void MipsAssembler::Bc(uint32_t imm26) {
CHECK(IsR6());
EmitI26(0x32, imm26);
}
void MipsAssembler::Jic(Register rt, uint16_t imm16) {
CHECK(IsR6());
EmitI(0x36, static_cast<Register>(0), rt, imm16);
}
void MipsAssembler::Jialc(Register rt, uint16_t imm16) {
CHECK(IsR6());
EmitI(0x3E, static_cast<Register>(0), rt, imm16);
}
void MipsAssembler::Bltc(Register rs, Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
CHECK_NE(rt, ZERO);
CHECK_NE(rs, rt);
EmitI(0x17, rs, rt, imm16);
}
void MipsAssembler::Bltzc(Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rt, ZERO);
EmitI(0x17, rt, rt, imm16);
}
void MipsAssembler::Bgtzc(Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rt, ZERO);
EmitI(0x17, static_cast<Register>(0), rt, imm16);
}
void MipsAssembler::Bgec(Register rs, Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
CHECK_NE(rt, ZERO);
CHECK_NE(rs, rt);
EmitI(0x16, rs, rt, imm16);
}
void MipsAssembler::Bgezc(Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rt, ZERO);
EmitI(0x16, rt, rt, imm16);
}
void MipsAssembler::Blezc(Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rt, ZERO);
EmitI(0x16, static_cast<Register>(0), rt, imm16);
}
void MipsAssembler::Bltuc(Register rs, Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
CHECK_NE(rt, ZERO);
CHECK_NE(rs, rt);
EmitI(0x7, rs, rt, imm16);
}
void MipsAssembler::Bgeuc(Register rs, Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
CHECK_NE(rt, ZERO);
CHECK_NE(rs, rt);
EmitI(0x6, rs, rt, imm16);
}
void MipsAssembler::Beqc(Register rs, Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
CHECK_NE(rt, ZERO);
CHECK_NE(rs, rt);
EmitI(0x8, std::min(rs, rt), std::max(rs, rt), imm16);
}
void MipsAssembler::Bnec(Register rs, Register rt, uint16_t imm16) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
CHECK_NE(rt, ZERO);
CHECK_NE(rs, rt);
EmitI(0x18, std::min(rs, rt), std::max(rs, rt), imm16);
}
void MipsAssembler::Beqzc(Register rs, uint32_t imm21) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
EmitI21(0x36, rs, imm21);
}
void MipsAssembler::Bnezc(Register rs, uint32_t imm21) {
CHECK(IsR6());
CHECK_NE(rs, ZERO);
EmitI21(0x3E, rs, imm21);
}
void MipsAssembler::Bc1eqz(FRegister ft, uint16_t imm16) {
CHECK(IsR6());
EmitFI(0x11, 0x9, ft, imm16);
}
void MipsAssembler::Bc1nez(FRegister ft, uint16_t imm16) {
CHECK(IsR6());
EmitFI(0x11, 0xD, ft, imm16);
}
void MipsAssembler::EmitBcondR2(BranchCondition cond, Register rs, Register rt, uint16_t imm16) {
switch (cond) {
case kCondLTZ:
CHECK_EQ(rt, ZERO);
Bltz(rs, imm16);
break;
case kCondGEZ:
CHECK_EQ(rt, ZERO);
Bgez(rs, imm16);
break;
case kCondLEZ:
CHECK_EQ(rt, ZERO);
Blez(rs, imm16);
break;
case kCondGTZ:
CHECK_EQ(rt, ZERO);
Bgtz(rs, imm16);
break;
case kCondEQ:
Beq(rs, rt, imm16);
break;
case kCondNE:
Bne(rs, rt, imm16);
break;
case kCondEQZ:
CHECK_EQ(rt, ZERO);
Beqz(rs, imm16);
break;
case kCondNEZ:
CHECK_EQ(rt, ZERO);
Bnez(rs, imm16);
break;
case kCondF:
CHECK_EQ(rt, ZERO);
Bc1f(static_cast<int>(rs), imm16);
break;
case kCondT:
CHECK_EQ(rt, ZERO);
Bc1t(static_cast<int>(rs), imm16);
break;
case kCondLT:
case kCondGE:
case kCondLE:
case kCondGT:
case kCondLTU:
case kCondGEU:
case kUncond:
// We don't support synthetic R2 branches (preceded with slt[u]) at this level
// (R2 doesn't have branches to compare 2 registers using <, <=, >=, >).
LOG(FATAL) << "Unexpected branch condition " << cond;
UNREACHABLE();
}
}
void MipsAssembler::EmitBcondR6(BranchCondition cond, Register rs, Register rt, uint32_t imm16_21) {
switch (cond) {
case kCondLT:
Bltc(rs, rt, imm16_21);
break;
case kCondGE:
Bgec(rs, rt, imm16_21);
break;
case kCondLE:
Bgec(rt, rs, imm16_21);
break;
case kCondGT:
Bltc(rt, rs, imm16_21);
break;
case kCondLTZ:
CHECK_EQ(rt, ZERO);
Bltzc(rs, imm16_21);
break;
case kCondGEZ:
CHECK_EQ(rt, ZERO);
Bgezc(rs, imm16_21);
break;
case kCondLEZ:
CHECK_EQ(rt, ZERO);
Blezc(rs, imm16_21);
break;
case kCondGTZ:
CHECK_EQ(rt, ZERO);
Bgtzc(rs, imm16_21);
break;
case kCondEQ:
Beqc(rs, rt, imm16_21);
break;
case kCondNE:
Bnec(rs, rt, imm16_21);
break;
case kCondEQZ:
CHECK_EQ(rt, ZERO);
Beqzc(rs, imm16_21);
break;
case kCondNEZ:
CHECK_EQ(rt, ZERO);
Bnezc(rs, imm16_21);
break;
case kCondLTU:
Bltuc(rs, rt, imm16_21);
break;
case kCondGEU:
Bgeuc(rs, rt, imm16_21);
break;
case kCondF:
CHECK_EQ(rt, ZERO);
Bc1eqz(static_cast<FRegister>(rs), imm16_21);
break;
case kCondT:
CHECK_EQ(rt, ZERO);
Bc1nez(static_cast<FRegister>(rs), imm16_21);
break;
case kUncond:
LOG(FATAL) << "Unexpected branch condition " << cond;
UNREACHABLE();
}
}
void MipsAssembler::AddS(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x10, ft, fs, fd, 0x0);
}
void MipsAssembler::SubS(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x10, ft, fs, fd, 0x1);
}
void MipsAssembler::MulS(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x10, ft, fs, fd, 0x2);
}
void MipsAssembler::DivS(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x10, ft, fs, fd, 0x3);
}
void MipsAssembler::AddD(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x11, ft, fs, fd, 0x0);
}
void MipsAssembler::SubD(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x11, ft, fs, fd, 0x1);
}
void MipsAssembler::MulD(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x11, ft, fs, fd, 0x2);
}
void MipsAssembler::DivD(FRegister fd, FRegister fs, FRegister ft) {
EmitFR(0x11, 0x11, ft, fs, fd, 0x3);
}
void MipsAssembler::MovS(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x6);
}
void MipsAssembler::MovD(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x6);
}
void MipsAssembler::NegS(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x7);
}
void MipsAssembler::NegD(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x7);
}
void MipsAssembler::CunS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x31);
}
void MipsAssembler::CeqS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x32);
}
void MipsAssembler::CueqS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x33);
}
void MipsAssembler::ColtS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x34);
}
void MipsAssembler::CultS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x35);
}
void MipsAssembler::ColeS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x36);
}
void MipsAssembler::CuleS(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x10, ft, fs, static_cast<FRegister>(cc << 2), 0x37);
}
void MipsAssembler::CunD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x31);
}
void MipsAssembler::CeqD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x32);
}
void MipsAssembler::CueqD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x33);
}
void MipsAssembler::ColtD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x34);
}
void MipsAssembler::CultD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x35);
}
void MipsAssembler::ColeD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x36);
}
void MipsAssembler::CuleD(int cc, FRegister fs, FRegister ft) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitFR(0x11, 0x11, ft, fs, static_cast<FRegister>(cc << 2), 0x37);
}
void MipsAssembler::CmpUnS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x01);
}
void MipsAssembler::CmpEqS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x02);
}
void MipsAssembler::CmpUeqS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x03);
}
void MipsAssembler::CmpLtS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x04);
}
void MipsAssembler::CmpUltS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x05);
}
void MipsAssembler::CmpLeS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x06);
}
void MipsAssembler::CmpUleS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x07);
}
void MipsAssembler::CmpOrS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x11);
}
void MipsAssembler::CmpUneS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x12);
}
void MipsAssembler::CmpNeS(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x14, ft, fs, fd, 0x13);
}
void MipsAssembler::CmpUnD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x01);
}
void MipsAssembler::CmpEqD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x02);
}
void MipsAssembler::CmpUeqD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x03);
}
void MipsAssembler::CmpLtD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x04);
}
void MipsAssembler::CmpUltD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x05);
}
void MipsAssembler::CmpLeD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x06);
}
void MipsAssembler::CmpUleD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x07);
}
void MipsAssembler::CmpOrD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x11);
}
void MipsAssembler::CmpUneD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x12);
}
void MipsAssembler::CmpNeD(FRegister fd, FRegister fs, FRegister ft) {
CHECK(IsR6());
EmitFR(0x11, 0x15, ft, fs, fd, 0x13);
}
void MipsAssembler::Movf(Register rd, Register rs, int cc) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitR(0, rs, static_cast<Register>(cc << 2), rd, 0, 0x01);
}
void MipsAssembler::Movt(Register rd, Register rs, int cc) {
CHECK(!IsR6());
CHECK(IsUint<3>(cc)) << cc;
EmitR(0, rs, static_cast<Register>((cc << 2) | 1), rd, 0, 0x01);
}
void MipsAssembler::TruncLS(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x09);
}
void MipsAssembler::TruncLD(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x09);
}
void MipsAssembler::TruncWS(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x0D);
}
void MipsAssembler::TruncWD(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x0D);
}
void MipsAssembler::Cvtsw(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x14, static_cast<FRegister>(0), fs, fd, 0x20);
}
void MipsAssembler::Cvtdw(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x14, static_cast<FRegister>(0), fs, fd, 0x21);
}
void MipsAssembler::Cvtsd(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x20);
}
void MipsAssembler::Cvtds(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x21);
}
void MipsAssembler::Cvtsl(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x15, static_cast<FRegister>(0), fs, fd, 0x20);
}
void MipsAssembler::Cvtdl(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x15, static_cast<FRegister>(0), fs, fd, 0x21);
}
void MipsAssembler::Mfc1(Register rt, FRegister fs) {
EmitFR(0x11, 0x00, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
}
void MipsAssembler::Mtc1(Register rt, FRegister fs) {
EmitFR(0x11, 0x04, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
}
void MipsAssembler::Mfhc1(Register rt, FRegister fs) {
EmitFR(0x11, 0x03, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
}
void MipsAssembler::Mthc1(Register rt, FRegister fs) {
EmitFR(0x11, 0x07, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
}
void MipsAssembler::MoveFromFpuHigh(Register rt, FRegister fs) {
if (Is32BitFPU()) {
CHECK_EQ(fs % 2, 0) << fs;
Mfc1(rt, static_cast<FRegister>(fs + 1));
} else {
Mfhc1(rt, fs);
}
}
void MipsAssembler::MoveToFpuHigh(Register rt, FRegister fs) {
if (Is32BitFPU()) {
CHECK_EQ(fs % 2, 0) << fs;
Mtc1(rt, static_cast<FRegister>(fs + 1));
} else {
Mthc1(rt, fs);
}
}
void MipsAssembler::Lwc1(FRegister ft, Register rs, uint16_t imm16) {
EmitI(0x31, rs, static_cast<Register>(ft), imm16);
}
void MipsAssembler::Ldc1(FRegister ft, Register rs, uint16_t imm16) {
EmitI(0x35, rs, static_cast<Register>(ft), imm16);
}
void MipsAssembler::Swc1(FRegister ft, Register rs, uint16_t imm16) {
EmitI(0x39, rs, static_cast<Register>(ft), imm16);
}
void MipsAssembler::Sdc1(FRegister ft, Register rs, uint16_t imm16) {
EmitI(0x3d, rs, static_cast<Register>(ft), imm16);
}
void MipsAssembler::Break() {
EmitR(0, static_cast<Register>(0), static_cast<Register>(0),
static_cast<Register>(0), 0, 0xD);
}
void MipsAssembler::Nop() {
EmitR(0x0, static_cast<Register>(0), static_cast<Register>(0), static_cast<Register>(0), 0, 0x0);
}
void MipsAssembler::Move(Register rd, Register rs) {
Or(rd, rs, ZERO);
}
void MipsAssembler::Clear(Register rd) {
Move(rd, ZERO);
}
void MipsAssembler::Not(Register rd, Register rs) {
Nor(rd, rs, ZERO);
}
void MipsAssembler::Push(Register rs) {
IncreaseFrameSize(kMipsWordSize);
Sw(rs, SP, 0);
}
void MipsAssembler::Pop(Register rd) {
Lw(rd, SP, 0);
DecreaseFrameSize(kMipsWordSize);
}
void MipsAssembler::PopAndReturn(Register rd, Register rt) {
Lw(rd, SP, 0);
Jr(rt);
DecreaseFrameSize(kMipsWordSize);
}
void MipsAssembler::LoadConst32(Register rd, int32_t value) {
if (IsUint<16>(value)) {
// Use OR with (unsigned) immediate to encode 16b unsigned int.
Ori(rd, ZERO, value);
} else if (IsInt<16>(value)) {
// Use ADD with (signed) immediate to encode 16b signed int.
Addiu(rd, ZERO, value);
} else {
Lui(rd, High16Bits(value));
if (value & 0xFFFF)
Ori(rd, rd, Low16Bits(value));
}
}
void MipsAssembler::LoadConst64(Register reg_hi, Register reg_lo, int64_t value) {
uint32_t low = Low32Bits(value);
uint32_t high = High32Bits(value);
LoadConst32(reg_lo, low);
if (high != low) {
LoadConst32(reg_hi, high);
} else {
Move(reg_hi, reg_lo);
}
}
void MipsAssembler::StoreConst32ToOffset(int32_t value,
Register base,
int32_t offset,
Register temp) {
if (!IsInt<16>(offset)) {
CHECK_NE(temp, AT); // Must not use AT as temp, as not to overwrite the loaded value.
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
if (value == 0) {
temp = ZERO;
} else {
LoadConst32(temp, value);
}
Sw(temp, base, offset);
}
void MipsAssembler::StoreConst64ToOffset(int64_t value,
Register base,
int32_t offset,
Register temp) {
// IsInt<16> must be passed a signed value.
if (!IsInt<16>(offset) || !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize))) {
CHECK_NE(temp, AT); // Must not use AT as temp, as not to overwrite the loaded value.
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
uint32_t low = Low32Bits(value);
uint32_t high = High32Bits(value);
if (low == 0) {
Sw(ZERO, base, offset);
} else {
LoadConst32(temp, low);
Sw(temp, base, offset);
}
if (high == 0) {
Sw(ZERO, base, offset + kMipsWordSize);
} else {
if (high != low) {
LoadConst32(temp, high);
}
Sw(temp, base, offset + kMipsWordSize);
}
}
void MipsAssembler::LoadSConst32(FRegister r, int32_t value, Register temp) {
if (value == 0) {
temp = ZERO;
} else {
LoadConst32(temp, value);
}
Mtc1(temp, r);
}
void MipsAssembler::LoadDConst64(FRegister rd, int64_t value, Register temp) {
uint32_t low = Low32Bits(value);
uint32_t high = High32Bits(value);
if (low == 0) {
Mtc1(ZERO, rd);
} else {
LoadConst32(temp, low);
Mtc1(temp, rd);
}
if (high == 0) {
MoveToFpuHigh(ZERO, rd);
} else {
LoadConst32(temp, high);
MoveToFpuHigh(temp, rd);
}
}
void MipsAssembler::Addiu32(Register rt, Register rs, int32_t value, Register temp) {
if (IsInt<16>(value)) {
Addiu(rt, rs, value);
} else {
LoadConst32(temp, value);
Addu(rt, rs, temp);
}
}
void MipsAssembler::Branch::InitShortOrLong(MipsAssembler::Branch::OffsetBits offset_size,
MipsAssembler::Branch::Type short_type,
MipsAssembler::Branch::Type long_type) {
type_ = (offset_size <= branch_info_[short_type].offset_size) ? short_type : long_type;
}
void MipsAssembler::Branch::InitializeType(bool is_call, bool is_r6) {
OffsetBits offset_size = GetOffsetSizeNeeded(location_, target_);
if (is_r6) {
// R6
if (is_call) {
InitShortOrLong(offset_size, kR6Call, kR6LongCall);
} else if (condition_ == kUncond) {
InitShortOrLong(offset_size, kR6UncondBranch, kR6LongUncondBranch);
} else {
if (condition_ == kCondEQZ || condition_ == kCondNEZ) {
// Special case for beqzc/bnezc with longer offset than in other b<cond>c instructions.
type_ = (offset_size <= kOffset23) ? kR6CondBranch : kR6LongCondBranch;
} else {
InitShortOrLong(offset_size, kR6CondBranch, kR6LongCondBranch);
}
}
} else {
// R2
if (is_call) {
InitShortOrLong(offset_size, kCall, kLongCall);
} else if (condition_ == kUncond) {
InitShortOrLong(offset_size, kUncondBranch, kLongUncondBranch);
} else {
InitShortOrLong(offset_size, kCondBranch, kLongCondBranch);
}
}
old_type_ = type_;
}
bool MipsAssembler::Branch::IsNop(BranchCondition condition, Register lhs, Register rhs) {
switch (condition) {
case kCondLT:
case kCondGT:
case kCondNE:
case kCondLTU:
return lhs == rhs;
default:
return false;
}
}
bool MipsAssembler::Branch::IsUncond(BranchCondition condition, Register lhs, Register rhs) {
switch (condition) {
case kUncond:
return true;
case kCondGE:
case kCondLE:
case kCondEQ:
case kCondGEU:
return lhs == rhs;
default:
return false;
}
}
MipsAssembler::Branch::Branch(bool is_r6, uint32_t location, uint32_t target)
: old_location_(location),
location_(location),
target_(target),
lhs_reg_(0),
rhs_reg_(0),
condition_(kUncond) {
InitializeType(false, is_r6);
}
MipsAssembler::Branch::Branch(bool is_r6,
uint32_t location,
uint32_t target,
MipsAssembler::BranchCondition condition,
Register lhs_reg,
Register rhs_reg)
: old_location_(location),
location_(location),
target_(target),
lhs_reg_(lhs_reg),
rhs_reg_(rhs_reg),
condition_(condition) {
CHECK_NE(condition, kUncond);
switch (condition) {
case kCondLT:
case kCondGE:
case kCondLE:
case kCondGT:
case kCondLTU:
case kCondGEU:
// We don't support synthetic R2 branches (preceded with slt[u]) at this level
// (R2 doesn't have branches to compare 2 registers using <, <=, >=, >).
// We leave this up to the caller.
CHECK(is_r6);
FALLTHROUGH_INTENDED;
case kCondEQ:
case kCondNE:
// Require registers other than 0 not only for R6, but also for R2 to catch errors.
// To compare with 0, use dedicated kCond*Z conditions.
CHECK_NE(lhs_reg, ZERO);
CHECK_NE(rhs_reg, ZERO);
break;
case kCondLTZ:
case kCondGEZ:
case kCondLEZ:
case kCondGTZ:
case kCondEQZ:
case kCondNEZ:
// Require registers other than 0 not only for R6, but also for R2 to catch errors.
CHECK_NE(lhs_reg, ZERO);
CHECK_EQ(rhs_reg, ZERO);
break;
case kCondF:
case kCondT:
CHECK_EQ(rhs_reg, ZERO);
break;
case kUncond:
UNREACHABLE();
}
CHECK(!IsNop(condition, lhs_reg, rhs_reg));
if (IsUncond(condition, lhs_reg, rhs_reg)) {
// Branch condition is always true, make the branch unconditional.
condition_ = kUncond;
}
InitializeType(false, is_r6);
}
MipsAssembler::Branch::Branch(bool is_r6, uint32_t location, uint32_t target, Register indirect_reg)
: old_location_(location),
location_(location),
target_(target),
lhs_reg_(indirect_reg),
rhs_reg_(0),
condition_(kUncond) {
CHECK_NE(indirect_reg, ZERO);
CHECK_NE(indirect_reg, AT);
InitializeType(true, is_r6);
}
MipsAssembler::BranchCondition MipsAssembler::Branch::OppositeCondition(
MipsAssembler::BranchCondition cond) {
switch (cond) {
case kCondLT:
return kCondGE;
case kCondGE:
return kCondLT;
case kCondLE:
return kCondGT;
case kCondGT:
return kCondLE;
case kCondLTZ:
return kCondGEZ;
case kCondGEZ:
return kCondLTZ;
case kCondLEZ:
return kCondGTZ;
case kCondGTZ:
return kCondLEZ;
case kCondEQ:
return kCondNE;
case kCondNE:
return kCondEQ;
case kCondEQZ:
return kCondNEZ;
case kCondNEZ:
return kCondEQZ;
case kCondLTU:
return kCondGEU;
case kCondGEU:
return kCondLTU;
case kCondF:
return kCondT;
case kCondT:
return kCondF;
case kUncond:
LOG(FATAL) << "Unexpected branch condition " << cond;
}
UNREACHABLE();
}
MipsAssembler::Branch::Type MipsAssembler::Branch::GetType() const {
return type_;
}
MipsAssembler::BranchCondition MipsAssembler::Branch::GetCondition() const {
return condition_;
}
Register MipsAssembler::Branch::GetLeftRegister() const {
return static_cast<Register>(lhs_reg_);
}
Register MipsAssembler::Branch::GetRightRegister() const {
return static_cast<Register>(rhs_reg_);
}
uint32_t MipsAssembler::Branch::GetTarget() const {
return target_;
}
uint32_t MipsAssembler::Branch::GetLocation() const {
return location_;
}
uint32_t MipsAssembler::Branch::GetOldLocation() const {
return old_location_;
}
uint32_t MipsAssembler::Branch::GetLength() const {
return branch_info_[type_].length;
}
uint32_t MipsAssembler::Branch::GetOldLength() const {
return branch_info_[old_type_].length;
}
uint32_t MipsAssembler::Branch::GetSize() const {
return GetLength() * sizeof(uint32_t);
}
uint32_t MipsAssembler::Branch::GetOldSize() const {
return GetOldLength() * sizeof(uint32_t);
}
uint32_t MipsAssembler::Branch::GetEndLocation() const {
return GetLocation() + GetSize();
}
uint32_t MipsAssembler::Branch::GetOldEndLocation() const {
return GetOldLocation() + GetOldSize();
}
bool MipsAssembler::Branch::IsLong() const {
switch (type_) {
// R2 short branches.
case kUncondBranch:
case kCondBranch:
case kCall:
// R6 short branches.
case kR6UncondBranch:
case kR6CondBranch:
case kR6Call:
return false;
// R2 long branches.
case kLongUncondBranch:
case kLongCondBranch:
case kLongCall:
// R6 long branches.
case kR6LongUncondBranch:
case kR6LongCondBranch:
case kR6LongCall:
return true;
}
UNREACHABLE();
}
bool MipsAssembler::Branch::IsResolved() const {
return target_ != kUnresolved;
}
MipsAssembler::Branch::OffsetBits MipsAssembler::Branch::GetOffsetSize() const {
OffsetBits offset_size =
(type_ == kR6CondBranch && (condition_ == kCondEQZ || condition_ == kCondNEZ))
? kOffset23
: branch_info_[type_].offset_size;
return offset_size;
}
MipsAssembler::Branch::OffsetBits MipsAssembler::Branch::GetOffsetSizeNeeded(uint32_t location,
uint32_t target) {
// For unresolved targets assume the shortest encoding
// (later it will be made longer if needed).
if (target == kUnresolved)
return kOffset16;
int64_t distance = static_cast<int64_t>(target) - location;
// To simplify calculations in composite branches consisting of multiple instructions
// bump up the distance by a value larger than the max byte size of a composite branch.
distance += (distance >= 0) ? kMaxBranchSize : -kMaxBranchSize;
if (IsInt<kOffset16>(distance))
return kOffset16;
else if (IsInt<kOffset18>(distance))
return kOffset18;
else if (IsInt<kOffset21>(distance))
return kOffset21;
else if (IsInt<kOffset23>(distance))
return kOffset23;
else if (IsInt<kOffset28>(distance))
return kOffset28;
return kOffset32;
}
void MipsAssembler::Branch::Resolve(uint32_t target) {
target_ = target;
}
void MipsAssembler::Branch::Relocate(uint32_t expand_location, uint32_t delta) {
if (location_ > expand_location) {
location_ += delta;
}
if (!IsResolved()) {
return; // Don't know the target yet.
}
if (target_ > expand_location) {
target_ += delta;
}
}
void MipsAssembler::Branch::PromoteToLong() {
switch (type_) {
// R2 short branches.
case kUncondBranch:
type_ = kLongUncondBranch;
break;
case kCondBranch:
type_ = kLongCondBranch;
break;
case kCall:
type_ = kLongCall;
break;
// R6 short branches.
case kR6UncondBranch:
type_ = kR6LongUncondBranch;
break;
case kR6CondBranch:
type_ = kR6LongCondBranch;
break;
case kR6Call:
type_ = kR6LongCall;
break;
default:
// Note: 'type_' is already long.
break;
}
CHECK(IsLong());
}
uint32_t MipsAssembler::Branch::PromoteIfNeeded(uint32_t max_short_distance) {
// If the branch is still unresolved or already long, nothing to do.
if (IsLong() || !IsResolved()) {
return 0;
}
// Promote the short branch to long if the offset size is too small
// to hold the distance between location_ and target_.
if (GetOffsetSizeNeeded(location_, target_) > GetOffsetSize()) {
PromoteToLong();
uint32_t old_size = GetOldSize();
uint32_t new_size = GetSize();
CHECK_GT(new_size, old_size);
return new_size - old_size;
}
// The following logic is for debugging/testing purposes.
// Promote some short branches to long when it's not really required.
if (UNLIKELY(max_short_distance != std::numeric_limits<uint32_t>::max())) {
int64_t distance = static_cast<int64_t>(target_) - location_;
distance = (distance >= 0) ? distance : -distance;
if (distance >= max_short_distance) {
PromoteToLong();
uint32_t old_size = GetOldSize();
uint32_t new_size = GetSize();
CHECK_GT(new_size, old_size);
return new_size - old_size;
}
}
return 0;
}
uint32_t MipsAssembler::Branch::GetOffsetLocation() const {
return location_ + branch_info_[type_].instr_offset * sizeof(uint32_t);
}
uint32_t MipsAssembler::Branch::GetOffset() const {
CHECK(IsResolved());
uint32_t ofs_mask = 0xFFFFFFFF >> (32 - GetOffsetSize());
// Calculate the byte distance between instructions and also account for
// different PC-relative origins.
uint32_t offset = target_ - GetOffsetLocation() - branch_info_[type_].pc_org * sizeof(uint32_t);
// Prepare the offset for encoding into the instruction(s).
offset = (offset & ofs_mask) >> branch_info_[type_].offset_shift;
return offset;
}
MipsAssembler::Branch* MipsAssembler::GetBranch(uint32_t branch_id) {
CHECK_LT(branch_id, branches_.size());
return &branches_[branch_id];
}
const MipsAssembler::Branch* MipsAssembler::GetBranch(uint32_t branch_id) const {
CHECK_LT(branch_id, branches_.size());
return &branches_[branch_id];
}
void MipsAssembler::Bind(MipsLabel* label) {
CHECK(!label->IsBound());
uint32_t bound_pc = buffer_.Size();
// Walk the list of branches referring to and preceding this label.
// Store the previously unknown target addresses in them.
while (label->IsLinked()) {
uint32_t branch_id = label->Position();
Branch* branch = GetBranch(branch_id);
branch->Resolve(bound_pc);
uint32_t branch_location = branch->GetLocation();
// Extract the location of the previous branch in the list (walking the list backwards;
// the previous branch ID was stored in the space reserved for this branch).
uint32_t prev = buffer_.Load<uint32_t>(branch_location);
// On to the previous branch in the list...
label->position_ = prev;
}
// Now make the label object contain its own location (relative to the end of the preceding
// branch, if any; it will be used by the branches referring to and following this label).
label->prev_branch_id_plus_one_ = branches_.size();
if (label->prev_branch_id_plus_one_) {
uint32_t branch_id = label->prev_branch_id_plus_one_ - 1;
const Branch* branch = GetBranch(branch_id);
bound_pc -= branch->GetEndLocation();
}
label->BindTo(bound_pc);
}
uint32_t MipsAssembler::GetLabelLocation(MipsLabel* label) const {
CHECK(label->IsBound());
uint32_t target = label->Position();
if (label->prev_branch_id_plus_one_) {
// Get label location based on the branch preceding it.
uint32_t branch_id = label->prev_branch_id_plus_one_ - 1;
const Branch* branch = GetBranch(branch_id);
target += branch->GetEndLocation();
}
return target;
}
uint32_t MipsAssembler::GetAdjustedPosition(uint32_t old_position) {
// We can reconstruct the adjustment by going through all the branches from the beginning
// up to the old_position. Since we expect AdjustedPosition() to be called in a loop
// with increasing old_position, we can use the data from last AdjustedPosition() to
// continue where we left off and the whole loop should be O(m+n) where m is the number
// of positions to adjust and n is the number of branches.
if (old_position < last_old_position_) {
last_position_adjustment_ = 0;
last_old_position_ = 0;
last_branch_id_ = 0;
}
while (last_branch_id_ != branches_.size()) {
const Branch* branch = GetBranch(last_branch_id_);
if (branch->GetLocation() >= old_position + last_position_adjustment_) {
break;
}
last_position_adjustment_ += branch->GetSize() - branch->GetOldSize();
++last_branch_id_;
}
last_old_position_ = old_position;
return old_position + last_position_adjustment_;
}
void MipsAssembler::FinalizeLabeledBranch(MipsLabel* label) {
uint32_t length = branches_.back().GetLength();
if (!label->IsBound()) {
// Branch forward (to a following label), distance is unknown.
// The first branch forward will contain 0, serving as the terminator of
// the list of forward-reaching branches.
Emit(label->position_);
length--;
// Now make the label object point to this branch
// (this forms a linked list of branches preceding this label).
uint32_t branch_id = branches_.size() - 1;
label->LinkTo(branch_id);
}
// Reserve space for the branch.
while (length--) {
Nop();
}
}
void MipsAssembler::Buncond(MipsLabel* label) {
uint32_t target = label->IsBound() ? GetLabelLocation(label) : Branch::kUnresolved;
branches_.emplace_back(IsR6(), buffer_.Size(), target);
FinalizeLabeledBranch(label);
}
void MipsAssembler::Bcond(MipsLabel* label, BranchCondition condition, Register lhs, Register rhs) {
// If lhs = rhs, this can be a NOP.
if (Branch::IsNop(condition, lhs, rhs)) {
return;
}
uint32_t target = label->IsBound() ? GetLabelLocation(label) : Branch::kUnresolved;
branches_.emplace_back(IsR6(), buffer_.Size(), target, condition, lhs, rhs);
FinalizeLabeledBranch(label);
}
void MipsAssembler::Call(MipsLabel* label, Register indirect_reg) {
uint32_t target = label->IsBound() ? GetLabelLocation(label) : Branch::kUnresolved;
branches_.emplace_back(IsR6(), buffer_.Size(), target, indirect_reg);
FinalizeLabeledBranch(label);
}
void MipsAssembler::PromoteBranches() {
// Promote short branches to long as necessary.
bool changed;
do {
changed = false;
for (auto& branch : branches_) {
CHECK(branch.IsResolved());
uint32_t delta = branch.PromoteIfNeeded();
// If this branch has been promoted and needs to expand in size,
// relocate all branches by the expansion size.
if (delta) {
changed = true;
uint32_t expand_location = branch.GetLocation();
for (auto& branch2 : branches_) {
branch2.Relocate(expand_location, delta);
}
}
}
} while (changed);
// Account for branch expansion by resizing the code buffer
// and moving the code in it to its final location.
size_t branch_count = branches_.size();
if (branch_count > 0) {
// Resize.
Branch& last_branch = branches_[branch_count - 1];
uint32_t size_delta = last_branch.GetEndLocation() - last_branch.GetOldEndLocation();
uint32_t old_size = buffer_.Size();
buffer_.Resize(old_size + size_delta);
// Move the code residing between branch placeholders.
uint32_t end = old_size;
for (size_t i = branch_count; i > 0; ) {
Branch& branch = branches_[--i];
uint32_t size = end - branch.GetOldEndLocation();
buffer_.Move(branch.GetEndLocation(), branch.GetOldEndLocation(), size);
end = branch.GetOldLocation();
}
}
}
// Note: make sure branch_info_[] and EmitBranch() are kept synchronized.
const MipsAssembler::Branch::BranchInfo MipsAssembler::Branch::branch_info_[] = {
// R2 short branches.
{ 2, 0, 1, MipsAssembler::Branch::kOffset18, 2 }, // kUncondBranch
{ 2, 0, 1, MipsAssembler::Branch::kOffset18, 2 }, // kCondBranch
{ 5, 2, 0, MipsAssembler::Branch::kOffset16, 0 }, // kCall
// R2 long branches.
{ 9, 3, 1, MipsAssembler::Branch::kOffset32, 0 }, // kLongUncondBranch
{ 10, 4, 1, MipsAssembler::Branch::kOffset32, 0 }, // kLongCondBranch
{ 6, 1, 1, MipsAssembler::Branch::kOffset32, 0 }, // kLongCall
// R6 short branches.
{ 1, 0, 1, MipsAssembler::Branch::kOffset28, 2 }, // kR6UncondBranch
{ 2, 0, 1, MipsAssembler::Branch::kOffset18, 2 }, // kR6CondBranch
// Exception: kOffset23 for beqzc/bnezc.
{ 2, 0, 0, MipsAssembler::Branch::kOffset21, 2 }, // kR6Call
// R6 long branches.
{ 2, 0, 0, MipsAssembler::Branch::kOffset32, 0 }, // kR6LongUncondBranch
{ 3, 1, 0, MipsAssembler::Branch::kOffset32, 0 }, // kR6LongCondBranch
{ 3, 0, 0, MipsAssembler::Branch::kOffset32, 0 }, // kR6LongCall
};
// Note: make sure branch_info_[] and mitBranch() are kept synchronized.
void MipsAssembler::EmitBranch(MipsAssembler::Branch* branch) {
CHECK_EQ(overwriting_, true);
overwrite_location_ = branch->GetLocation();
uint32_t offset = branch->GetOffset();
BranchCondition condition = branch->GetCondition();
Register lhs = branch->GetLeftRegister();
Register rhs = branch->GetRightRegister();
switch (branch->GetType()) {
// R2 short branches.
case Branch::kUncondBranch:
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
B(offset);
Nop(); // TODO: improve by filling the delay slot.
break;
case Branch::kCondBranch:
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
EmitBcondR2(condition, lhs, rhs, offset);
Nop(); // TODO: improve by filling the delay slot.
break;
case Branch::kCall:
Nal();
Nop(); // TODO: is this NOP really needed here?
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Addiu(lhs, RA, offset);
Jalr(lhs);
Nop();
break;
// R2 long branches.
case Branch::kLongUncondBranch:
// To get the value of the PC register we need to use the NAL instruction.
// NAL clobbers the RA register. However, RA must be preserved if the
// method is compiled without the entry/exit sequences that would take care
// of preserving RA (typically, leaf methods don't preserve RA explicitly).
// So, we need to preserve RA in some temporary storage ourselves. The AT
// register can't be used for this because we need it to load a constant
// which will be added to the value that NAL stores in RA. And we can't
// use T9 for this in the context of the JNI compiler, which uses it
// as a scratch register (see InterproceduralScratchRegister()).
// If we were to add a 32-bit constant to RA using two ADDIU instructions,
// we'd also need to use the ROTR instruction, which requires no less than
// MIPSR2.
// Perhaps, we could use T8 or one of R2's multiplier/divider registers
// (LO or HI) or even a floating-point register, but that doesn't seem
// like a nice solution. We may want this to work on both R6 and pre-R6.
// For now simply use the stack for RA. This should be OK since for the
// vast majority of code a short PC-relative branch is sufficient.
// TODO: can this be improved?
Push(RA);
Nal();
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Lui(AT, High16Bits(offset));
Ori(AT, AT, Low16Bits(offset));
Addu(AT, AT, RA);
Lw(RA, SP, 0);
Jr(AT);
DecreaseFrameSize(kMipsWordSize);
break;
case Branch::kLongCondBranch:
// The comment on case 'Branch::kLongUncondBranch' applies here as well.
// Note: the opposite condition branch encodes 8 as the distance, which is equal to the
// number of instructions skipped:
// (PUSH(IncreaseFrameSize(ADDIU) + SW) + NAL + LUI + ORI + ADDU + LW + JR).
EmitBcondR2(Branch::OppositeCondition(condition), lhs, rhs, 8);
Push(RA);
Nal();
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Lui(AT, High16Bits(offset));
Ori(AT, AT, Low16Bits(offset));
Addu(AT, AT, RA);
Lw(RA, SP, 0);
Jr(AT);
DecreaseFrameSize(kMipsWordSize);
break;
case Branch::kLongCall:
Nal();
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Lui(AT, High16Bits(offset));
Ori(AT, AT, Low16Bits(offset));
Addu(lhs, AT, RA);
Jalr(lhs);
Nop();
break;
// R6 short branches.
case Branch::kR6UncondBranch:
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Bc(offset);
break;
case Branch::kR6CondBranch:
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
EmitBcondR6(condition, lhs, rhs, offset);
Nop(); // TODO: improve by filling the forbidden/delay slot.
break;
case Branch::kR6Call:
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Addiupc(lhs, offset);
Jialc(lhs, 0);
break;
// R6 long branches.
case Branch::kR6LongUncondBranch:
offset += (offset & 0x8000) << 1; // Account for sign extension in jic.
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Auipc(AT, High16Bits(offset));
Jic(AT, Low16Bits(offset));
break;
case Branch::kR6LongCondBranch:
EmitBcondR6(Branch::OppositeCondition(condition), lhs, rhs, 2);
offset += (offset & 0x8000) << 1; // Account for sign extension in jic.
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Auipc(AT, High16Bits(offset));
Jic(AT, Low16Bits(offset));
break;
case Branch::kR6LongCall:
offset += (offset & 0x8000) << 1; // Account for sign extension in addiu.
CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
Auipc(lhs, High16Bits(offset));
Addiu(lhs, lhs, Low16Bits(offset));
Jialc(lhs, 0);
break;
}
CHECK_EQ(overwrite_location_, branch->GetEndLocation());
CHECK_LT(branch->GetSize(), static_cast<uint32_t>(Branch::kMaxBranchSize));
}
void MipsAssembler::B(MipsLabel* label) {
Buncond(label);
}
void MipsAssembler::Jalr(MipsLabel* label, Register indirect_reg) {
Call(label, indirect_reg);
}
void MipsAssembler::Beq(Register rs, Register rt, MipsLabel* label) {
Bcond(label, kCondEQ, rs, rt);
}
void MipsAssembler::Bne(Register rs, Register rt, MipsLabel* label) {
Bcond(label, kCondNE, rs, rt);
}
void MipsAssembler::Beqz(Register rt, MipsLabel* label) {
Bcond(label, kCondEQZ, rt);
}
void MipsAssembler::Bnez(Register rt, MipsLabel* label) {
Bcond(label, kCondNEZ, rt);
}
void MipsAssembler::Bltz(Register rt, MipsLabel* label) {
Bcond(label, kCondLTZ, rt);
}
void MipsAssembler::Bgez(Register rt, MipsLabel* label) {
Bcond(label, kCondGEZ, rt);
}
void MipsAssembler::Blez(Register rt, MipsLabel* label) {
Bcond(label, kCondLEZ, rt);
}
void MipsAssembler::Bgtz(Register rt, MipsLabel* label) {
Bcond(label, kCondGTZ, rt);
}
void MipsAssembler::Blt(Register rs, Register rt, MipsLabel* label) {
if (IsR6()) {
Bcond(label, kCondLT, rs, rt);
} else if (!Branch::IsNop(kCondLT, rs, rt)) {
// Synthesize the instruction (not available on R2).
Slt(AT, rs, rt);
Bnez(AT, label);
}
}
void MipsAssembler::Bge(Register rs, Register rt, MipsLabel* label) {
if (IsR6()) {
Bcond(label, kCondGE, rs, rt);
} else if (Branch::IsUncond(kCondGE, rs, rt)) {
B(label);
} else {
// Synthesize the instruction (not available on R2).
Slt(AT, rs, rt);
Beqz(AT, label);
}
}
void MipsAssembler::Bltu(Register rs, Register rt, MipsLabel* label) {
if (IsR6()) {
Bcond(label, kCondLTU, rs, rt);
} else if (!Branch::IsNop(kCondLTU, rs, rt)) {
// Synthesize the instruction (not available on R2).
Sltu(AT, rs, rt);
Bnez(AT, label);
}
}
void MipsAssembler::Bgeu(Register rs, Register rt, MipsLabel* label) {
if (IsR6()) {
Bcond(label, kCondGEU, rs, rt);
} else if (Branch::IsUncond(kCondGEU, rs, rt)) {
B(label);
} else {
// Synthesize the instruction (not available on R2).
Sltu(AT, rs, rt);
Beqz(AT, label);
}
}
void MipsAssembler::Bc1f(int cc, MipsLabel* label) {
CHECK(IsUint<3>(cc)) << cc;
Bcond(label, kCondF, static_cast<Register>(cc), ZERO);
}
void MipsAssembler::Bc1t(int cc, MipsLabel* label) {
CHECK(IsUint<3>(cc)) << cc;
Bcond(label, kCondT, static_cast<Register>(cc), ZERO);
}
void MipsAssembler::Bc1eqz(FRegister ft, MipsLabel* label) {
Bcond(label, kCondF, static_cast<Register>(ft), ZERO);
}
void MipsAssembler::Bc1nez(FRegister ft, MipsLabel* label) {
Bcond(label, kCondT, static_cast<Register>(ft), ZERO);
}
void MipsAssembler::LoadFromOffset(LoadOperandType type, Register reg, Register base,
int32_t offset) {
// IsInt<16> must be passed a signed value.
if (!IsInt<16>(offset) ||
(type == kLoadDoubleword && !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
switch (type) {
case kLoadSignedByte:
Lb(reg, base, offset);
break;
case kLoadUnsignedByte:
Lbu(reg, base, offset);
break;
case kLoadSignedHalfword:
Lh(reg, base, offset);
break;
case kLoadUnsignedHalfword:
Lhu(reg, base, offset);
break;
case kLoadWord:
Lw(reg, base, offset);
break;
case kLoadDoubleword:
if (reg == base) {
// This will clobber the base when loading the lower register. Since we have to load the
// higher register as well, this will fail. Solution: reverse the order.
Lw(static_cast<Register>(reg + 1), base, offset + kMipsWordSize);
Lw(reg, base, offset);
} else {
Lw(reg, base, offset);
Lw(static_cast<Register>(reg + 1), base, offset + kMipsWordSize);
}
break;
default:
LOG(FATAL) << "UNREACHABLE";
}
}
void MipsAssembler::LoadSFromOffset(FRegister reg, Register base, int32_t offset) {
if (!IsInt<16>(offset)) {
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
Lwc1(reg, base, offset);
}
void MipsAssembler::LoadDFromOffset(FRegister reg, Register base, int32_t offset) {
// IsInt<16> must be passed a signed value.
if (!IsInt<16>(offset) ||
(!IsAligned<kMipsDoublewordSize>(offset) &&
!IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
if (offset & 0x7) {
if (Is32BitFPU()) {
Lwc1(reg, base, offset);
Lwc1(static_cast<FRegister>(reg + 1), base, offset + kMipsWordSize);
} else {
// 64-bit FPU.
Lwc1(reg, base, offset);
Lw(T8, base, offset + kMipsWordSize);
Mthc1(T8, reg);
}
} else {
Ldc1(reg, base, offset);
}
}
void MipsAssembler::EmitLoad(ManagedRegister m_dst, Register src_register, int32_t src_offset,
size_t size) {
MipsManagedRegister dst = m_dst.AsMips();
if (dst.IsNoRegister()) {
CHECK_EQ(0u, size) << dst;
} else if (dst.IsCoreRegister()) {
CHECK_EQ(kMipsWordSize, size) << dst;
LoadFromOffset(kLoadWord, dst.AsCoreRegister(), src_register, src_offset);
} else if (dst.IsRegisterPair()) {
CHECK_EQ(kMipsDoublewordSize, size) << dst;
LoadFromOffset(kLoadDoubleword, dst.AsRegisterPairLow(), src_register, src_offset);
} else if (dst.IsFRegister()) {
if (size == kMipsWordSize) {
LoadSFromOffset(dst.AsFRegister(), src_register, src_offset);
} else {
CHECK_EQ(kMipsDoublewordSize, size) << dst;
LoadDFromOffset(dst.AsFRegister(), src_register, src_offset);
}
}
}
void MipsAssembler::StoreToOffset(StoreOperandType type, Register reg, Register base,
int32_t offset) {
// IsInt<16> must be passed a signed value.
if (!IsInt<16>(offset) ||
(type == kStoreDoubleword && !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
switch (type) {
case kStoreByte:
Sb(reg, base, offset);
break;
case kStoreHalfword:
Sh(reg, base, offset);
break;
case kStoreWord:
Sw(reg, base, offset);
break;
case kStoreDoubleword:
CHECK_NE(reg, base);
CHECK_NE(static_cast<Register>(reg + 1), base);
Sw(reg, base, offset);
Sw(static_cast<Register>(reg + 1), base, offset + kMipsWordSize);
break;
default:
LOG(FATAL) << "UNREACHABLE";
}
}
void MipsAssembler::StoreSToOffset(FRegister reg, Register base, int32_t offset) {
if (!IsInt<16>(offset)) {
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
Swc1(reg, base, offset);
}
void MipsAssembler::StoreDToOffset(FRegister reg, Register base, int32_t offset) {
// IsInt<16> must be passed a signed value.
if (!IsInt<16>(offset) ||
(!IsAligned<kMipsDoublewordSize>(offset) &&
!IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
LoadConst32(AT, offset);
Addu(AT, AT, base);
base = AT;
offset = 0;
}
if (offset & 0x7) {
if (Is32BitFPU()) {
Swc1(reg, base, offset);
Swc1(static_cast<FRegister>(reg + 1), base, offset + kMipsWordSize);
} else {
// 64-bit FPU.
Mfhc1(T8, reg);
Swc1(reg, base, offset);
Sw(T8, base, offset + kMipsWordSize);
}
} else {
Sdc1(reg, base, offset);
}
}
static dwarf::Reg DWARFReg(Register reg) {
return dwarf::Reg::MipsCore(static_cast<int>(reg));
}
constexpr size_t kFramePointerSize = 4;
void MipsAssembler::BuildFrame(size_t frame_size, ManagedRegister method_reg,
const std::vector<ManagedRegister>& callee_save_regs,
const ManagedRegisterEntrySpills& entry_spills) {
CHECK_ALIGNED(frame_size, kStackAlignment);
DCHECK(!overwriting_);
// Increase frame to required size.
IncreaseFrameSize(frame_size);
// Push callee saves and return address.
int stack_offset = frame_size - kFramePointerSize;
StoreToOffset(kStoreWord, RA, SP, stack_offset);
cfi_.RelOffset(DWARFReg(RA), stack_offset);
for (int i = callee_save_regs.size() - 1; i >= 0; --i) {
stack_offset -= kFramePointerSize;
Register reg = callee_save_regs.at(i).AsMips().AsCoreRegister();
StoreToOffset(kStoreWord, reg, SP, stack_offset);
cfi_.RelOffset(DWARFReg(reg), stack_offset);
}
// Write out Method*.
StoreToOffset(kStoreWord, method_reg.AsMips().AsCoreRegister(), SP, 0);
// Write out entry spills.
int32_t offset = frame_size + kFramePointerSize;
for (size_t i = 0; i < entry_spills.size(); ++i) {
MipsManagedRegister reg = entry_spills.at(i).AsMips();
if (reg.IsNoRegister()) {
ManagedRegisterSpill spill = entry_spills.at(i);
offset += spill.getSize();
} else if (reg.IsCoreRegister()) {
StoreToOffset(kStoreWord, reg.AsCoreRegister(), SP, offset);
offset += kMipsWordSize;
} else if (reg.IsFRegister()) {
StoreSToOffset(reg.AsFRegister(), SP, offset);
offset += kMipsWordSize;
} else if (reg.IsDRegister()) {
StoreDToOffset(reg.AsOverlappingDRegisterLow(), SP, offset);
offset += kMipsDoublewordSize;
}
}
}
void MipsAssembler::RemoveFrame(size_t frame_size,
const std::vector<ManagedRegister>& callee_save_regs) {
CHECK_ALIGNED(frame_size, kStackAlignment);
DCHECK(!overwriting_);
cfi_.RememberState();
// Pop callee saves and return address.
int stack_offset = frame_size - (callee_save_regs.size() * kFramePointerSize) - kFramePointerSize;
for (size_t i = 0; i < callee_save_regs.size(); ++i) {
Register reg = callee_save_regs.at(i).AsMips().AsCoreRegister();
LoadFromOffset(kLoadWord, reg, SP, stack_offset);
cfi_.Restore(DWARFReg(reg));
stack_offset += kFramePointerSize;
}
LoadFromOffset(kLoadWord, RA, SP, stack_offset);
cfi_.Restore(DWARFReg(RA));
// Decrease frame to required size.
DecreaseFrameSize(frame_size);
// Then jump to the return address.
Jr(RA);
Nop();
// The CFI should be restored for any code that follows the exit block.
cfi_.RestoreState();
cfi_.DefCFAOffset(frame_size);
}
void MipsAssembler::IncreaseFrameSize(size_t adjust) {
CHECK_ALIGNED(adjust, kFramePointerSize);
Addiu32(SP, SP, -adjust);
cfi_.AdjustCFAOffset(adjust);
if (overwriting_) {
cfi_.OverrideDelayedPC(overwrite_location_);
}
}
void MipsAssembler::DecreaseFrameSize(size_t adjust) {
CHECK_ALIGNED(adjust, kFramePointerSize);
Addiu32(SP, SP, adjust);
cfi_.AdjustCFAOffset(-adjust);
if (overwriting_) {
cfi_.OverrideDelayedPC(overwrite_location_);
}
}
void MipsAssembler::Store(FrameOffset dest, ManagedRegister msrc, size_t size) {
MipsManagedRegister src = msrc.AsMips();
if (src.IsNoRegister()) {
CHECK_EQ(0u, size);
} else if (src.IsCoreRegister()) {
CHECK_EQ(kMipsWordSize, size);
StoreToOffset(kStoreWord, src.AsCoreRegister(), SP, dest.Int32Value());
} else if (src.IsRegisterPair()) {
CHECK_EQ(kMipsDoublewordSize, size);
StoreToOffset(kStoreWord, src.AsRegisterPairLow(), SP, dest.Int32Value());
StoreToOffset(kStoreWord, src.AsRegisterPairHigh(),
SP, dest.Int32Value() + kMipsWordSize);
} else if (src.IsFRegister()) {
if (size == kMipsWordSize) {
StoreSToOffset(src.AsFRegister(), SP, dest.Int32Value());
} else {
CHECK_EQ(kMipsDoublewordSize, size);
StoreDToOffset(src.AsFRegister(), SP, dest.Int32Value());
}
}
}
void MipsAssembler::StoreRef(FrameOffset dest, ManagedRegister msrc) {
MipsManagedRegister src = msrc.AsMips();
CHECK(src.IsCoreRegister());
StoreToOffset(kStoreWord, src.AsCoreRegister(), SP, dest.Int32Value());
}
void MipsAssembler::StoreRawPtr(FrameOffset dest, ManagedRegister msrc) {
MipsManagedRegister src = msrc.AsMips();
CHECK(src.IsCoreRegister());
StoreToOffset(kStoreWord, src.AsCoreRegister(), SP, dest.Int32Value());
}
void MipsAssembler::StoreImmediateToFrame(FrameOffset dest, uint32_t imm,
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadConst32(scratch.AsCoreRegister(), imm);
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
}
void MipsAssembler::StoreImmediateToThread32(ThreadOffset<kMipsWordSize> dest, uint32_t imm,
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
// Is this function even referenced anywhere else in the code?
LoadConst32(scratch.AsCoreRegister(), imm);
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), S1, dest.Int32Value());
}
void MipsAssembler::StoreStackOffsetToThread32(ThreadOffset<kMipsWordSize> thr_offs,
FrameOffset fr_offs,
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
Addiu32(scratch.AsCoreRegister(), SP, fr_offs.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(),
S1, thr_offs.Int32Value());
}
void MipsAssembler::StoreStackPointerToThread32(ThreadOffset<kMipsWordSize> thr_offs) {
StoreToOffset(kStoreWord, SP, S1, thr_offs.Int32Value());
}
void MipsAssembler::StoreSpanning(FrameOffset dest, ManagedRegister msrc,
FrameOffset in_off, ManagedRegister mscratch) {
MipsManagedRegister src = msrc.AsMips();
MipsManagedRegister scratch = mscratch.AsMips();
StoreToOffset(kStoreWord, src.AsCoreRegister(), SP, dest.Int32Value());
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, in_off.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value() + kMipsWordSize);
}
void MipsAssembler::Load(ManagedRegister mdest, FrameOffset src, size_t size) {
return EmitLoad(mdest, SP, src.Int32Value(), size);
}
void MipsAssembler::LoadFromThread32(ManagedRegister mdest,
ThreadOffset<kMipsWordSize> src, size_t size) {
return EmitLoad(mdest, S1, src.Int32Value(), size);
}
void MipsAssembler::LoadRef(ManagedRegister mdest, FrameOffset src) {
MipsManagedRegister dest = mdest.AsMips();
CHECK(dest.IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(), SP, src.Int32Value());
}
void MipsAssembler::LoadRef(ManagedRegister mdest, ManagedRegister base, MemberOffset offs,
bool unpoison_reference) {
MipsManagedRegister dest = mdest.AsMips();
CHECK(dest.IsCoreRegister() && base.AsMips().IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(),
base.AsMips().AsCoreRegister(), offs.Int32Value());
if (kPoisonHeapReferences && unpoison_reference) {
Subu(dest.AsCoreRegister(), ZERO, dest.AsCoreRegister());
}
}
void MipsAssembler::LoadRawPtr(ManagedRegister mdest, ManagedRegister base, Offset offs) {
MipsManagedRegister dest = mdest.AsMips();
CHECK(dest.IsCoreRegister() && base.AsMips().IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(),
base.AsMips().AsCoreRegister(), offs.Int32Value());
}
void MipsAssembler::LoadRawPtrFromThread32(ManagedRegister mdest,
ThreadOffset<kMipsWordSize> offs) {
MipsManagedRegister dest = mdest.AsMips();
CHECK(dest.IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(), S1, offs.Int32Value());
}
void MipsAssembler::SignExtend(ManagedRegister /*mreg*/, size_t /*size*/) {
UNIMPLEMENTED(FATAL) << "no sign extension necessary for mips";
}
void MipsAssembler::ZeroExtend(ManagedRegister /*mreg*/, size_t /*size*/) {
UNIMPLEMENTED(FATAL) << "no zero extension necessary for mips";
}
void MipsAssembler::Move(ManagedRegister mdest, ManagedRegister msrc, size_t size) {
MipsManagedRegister dest = mdest.AsMips();
MipsManagedRegister src = msrc.AsMips();
if (!dest.Equals(src)) {
if (dest.IsCoreRegister()) {
CHECK(src.IsCoreRegister()) << src;
Move(dest.AsCoreRegister(), src.AsCoreRegister());
} else if (dest.IsFRegister()) {
CHECK(src.IsFRegister()) << src;
if (size == kMipsWordSize) {
MovS(dest.AsFRegister(), src.AsFRegister());
} else {
CHECK_EQ(kMipsDoublewordSize, size);
MovD(dest.AsFRegister(), src.AsFRegister());
}
} else if (dest.IsDRegister()) {
CHECK(src.IsDRegister()) << src;
MovD(dest.AsOverlappingDRegisterLow(), src.AsOverlappingDRegisterLow());
} else {
CHECK(dest.IsRegisterPair()) << dest;
CHECK(src.IsRegisterPair()) << src;
// Ensure that the first move doesn't clobber the input of the second.
if (src.AsRegisterPairHigh() != dest.AsRegisterPairLow()) {
Move(dest.AsRegisterPairLow(), src.AsRegisterPairLow());
Move(dest.AsRegisterPairHigh(), src.AsRegisterPairHigh());
} else {
Move(dest.AsRegisterPairHigh(), src.AsRegisterPairHigh());
Move(dest.AsRegisterPairLow(), src.AsRegisterPairLow());
}
}
}
}
void MipsAssembler::CopyRef(FrameOffset dest, FrameOffset src, ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
}
void MipsAssembler::CopyRawPtrFromThread32(FrameOffset fr_offs,
ThreadOffset<kMipsWordSize> thr_offs,
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
S1, thr_offs.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(),
SP, fr_offs.Int32Value());
}
void MipsAssembler::CopyRawPtrToThread32(ThreadOffset<kMipsWordSize> thr_offs,
FrameOffset fr_offs,
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
SP, fr_offs.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(),
S1, thr_offs.Int32Value());
}
void MipsAssembler::Copy(FrameOffset dest, FrameOffset src, ManagedRegister mscratch, size_t size) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
CHECK(size == kMipsWordSize || size == kMipsDoublewordSize) << size;
if (size == kMipsWordSize) {
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
} else if (size == kMipsDoublewordSize) {
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value() + kMipsWordSize);
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value() + kMipsWordSize);
}
}
void MipsAssembler::Copy(FrameOffset dest, ManagedRegister src_base, Offset src_offset,
ManagedRegister mscratch, size_t size) {
Register scratch = mscratch.AsMips().AsCoreRegister();
CHECK_EQ(size, kMipsWordSize);
LoadFromOffset(kLoadWord, scratch, src_base.AsMips().AsCoreRegister(), src_offset.Int32Value());
StoreToOffset(kStoreWord, scratch, SP, dest.Int32Value());
}
void MipsAssembler::Copy(ManagedRegister dest_base, Offset dest_offset, FrameOffset src,
ManagedRegister mscratch, size_t size) {
Register scratch = mscratch.AsMips().AsCoreRegister();
CHECK_EQ(size, kMipsWordSize);
LoadFromOffset(kLoadWord, scratch, SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch, dest_base.AsMips().AsCoreRegister(), dest_offset.Int32Value());
}
void MipsAssembler::Copy(FrameOffset dest ATTRIBUTE_UNUSED,
FrameOffset src_base ATTRIBUTE_UNUSED,
Offset src_offset ATTRIBUTE_UNUSED,
ManagedRegister mscratch ATTRIBUTE_UNUSED,
size_t size ATTRIBUTE_UNUSED) {
UNIMPLEMENTED(FATAL) << "no MIPS implementation";
}
void MipsAssembler::Copy(ManagedRegister dest, Offset dest_offset,
ManagedRegister src, Offset src_offset,
ManagedRegister mscratch, size_t size) {
CHECK_EQ(size, kMipsWordSize);
Register scratch = mscratch.AsMips().AsCoreRegister();
LoadFromOffset(kLoadWord, scratch, src.AsMips().AsCoreRegister(), src_offset.Int32Value());
StoreToOffset(kStoreWord, scratch, dest.AsMips().AsCoreRegister(), dest_offset.Int32Value());
}
void MipsAssembler::Copy(FrameOffset dest ATTRIBUTE_UNUSED,
Offset dest_offset ATTRIBUTE_UNUSED,
FrameOffset src ATTRIBUTE_UNUSED,
Offset src_offset ATTRIBUTE_UNUSED,
ManagedRegister mscratch ATTRIBUTE_UNUSED,
size_t size ATTRIBUTE_UNUSED) {
UNIMPLEMENTED(FATAL) << "no MIPS implementation";
}
void MipsAssembler::MemoryBarrier(ManagedRegister) {
// TODO: sync?
UNIMPLEMENTED(FATAL) << "no MIPS implementation";
}
void MipsAssembler::CreateHandleScopeEntry(ManagedRegister mout_reg,
FrameOffset handle_scope_offset,
ManagedRegister min_reg,
bool null_allowed) {
MipsManagedRegister out_reg = mout_reg.AsMips();
MipsManagedRegister in_reg = min_reg.AsMips();
CHECK(in_reg.IsNoRegister() || in_reg.IsCoreRegister()) << in_reg;
CHECK(out_reg.IsCoreRegister()) << out_reg;
if (null_allowed) {
MipsLabel null_arg;
// 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()) {
LoadFromOffset(kLoadWord, out_reg.AsCoreRegister(),
SP, handle_scope_offset.Int32Value());
in_reg = out_reg;
}
if (!out_reg.Equals(in_reg)) {
LoadConst32(out_reg.AsCoreRegister(), 0);
}
Beqz(in_reg.AsCoreRegister(), &null_arg);
Addiu32(out_reg.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
Bind(&null_arg);
} else {
Addiu32(out_reg.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
}
}
void MipsAssembler::CreateHandleScopeEntry(FrameOffset out_off,
FrameOffset handle_scope_offset,
ManagedRegister mscratch,
bool null_allowed) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
if (null_allowed) {
MipsLabel null_arg;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), 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).
Beqz(scratch.AsCoreRegister(), &null_arg);
Addiu32(scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
Bind(&null_arg);
} else {
Addiu32(scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
}
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, out_off.Int32Value());
}
// Given a handle scope entry, load the associated reference.
void MipsAssembler::LoadReferenceFromHandleScope(ManagedRegister mout_reg,
ManagedRegister min_reg) {
MipsManagedRegister out_reg = mout_reg.AsMips();
MipsManagedRegister in_reg = min_reg.AsMips();
CHECK(out_reg.IsCoreRegister()) << out_reg;
CHECK(in_reg.IsCoreRegister()) << in_reg;
MipsLabel null_arg;
if (!out_reg.Equals(in_reg)) {
LoadConst32(out_reg.AsCoreRegister(), 0);
}
Beqz(in_reg.AsCoreRegister(), &null_arg);
LoadFromOffset(kLoadWord, out_reg.AsCoreRegister(),
in_reg.AsCoreRegister(), 0);
Bind(&null_arg);
}
void MipsAssembler::VerifyObject(ManagedRegister src ATTRIBUTE_UNUSED,
bool could_be_null ATTRIBUTE_UNUSED) {
// TODO: not validating references.
}
void MipsAssembler::VerifyObject(FrameOffset src ATTRIBUTE_UNUSED,
bool could_be_null ATTRIBUTE_UNUSED) {
// TODO: not validating references.
}
void MipsAssembler::Call(ManagedRegister mbase, Offset offset, ManagedRegister mscratch) {
MipsManagedRegister base = mbase.AsMips();
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(base.IsCoreRegister()) << base;
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
base.AsCoreRegister(), offset.Int32Value());
Jalr(scratch.AsCoreRegister());
Nop();
// TODO: place reference map on call.
}
void MipsAssembler::Call(FrameOffset base, Offset offset, ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
// Call *(*(SP + base) + offset)
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, base.Int32Value());
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
scratch.AsCoreRegister(), offset.Int32Value());
Jalr(scratch.AsCoreRegister());
Nop();
// TODO: place reference map on call.
}
void MipsAssembler::CallFromThread32(ThreadOffset<kMipsWordSize> offset ATTRIBUTE_UNUSED,
ManagedRegister mscratch ATTRIBUTE_UNUSED) {
UNIMPLEMENTED(FATAL) << "no mips implementation";
}
void MipsAssembler::GetCurrentThread(ManagedRegister tr) {
Move(tr.AsMips().AsCoreRegister(), S1);
}
void MipsAssembler::GetCurrentThread(FrameOffset offset,
ManagedRegister mscratch ATTRIBUTE_UNUSED) {
StoreToOffset(kStoreWord, S1, SP, offset.Int32Value());
}
void MipsAssembler::ExceptionPoll(ManagedRegister mscratch, size_t stack_adjust) {
MipsManagedRegister scratch = mscratch.AsMips();
exception_blocks_.emplace_back(scratch, stack_adjust);
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
S1, Thread::ExceptionOffset<kMipsWordSize>().Int32Value());
// TODO: on MIPS32R6 prefer Bnezc(scratch.AsCoreRegister(), slow.Entry());
// as the NAL instruction (occurring in long R2 branches) may become deprecated.
// For now use common for R2 and R6 instructions as this code must execute on both.
Bnez(scratch.AsCoreRegister(), exception_blocks_.back().Entry());
}
void MipsAssembler::EmitExceptionPoll(MipsExceptionSlowPath* exception) {
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 A0 as this call won't return.
CheckEntrypointTypes<kQuickDeliverException, void, mirror::Object*>();
Move(A0, exception->scratch_.AsCoreRegister());
// Set up call to Thread::Current()->pDeliverException.
LoadFromOffset(kLoadWord, T9, S1,
QUICK_ENTRYPOINT_OFFSET(kMipsWordSize, pDeliverException).Int32Value());
Jr(T9);
Nop();
// Call never returns.
Break();
}
} // namespace mips
} // namespace art