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// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#ifndef VM_ASSEMBLER_MIPS_H_
#define VM_ASSEMBLER_MIPS_H_
#ifndef VM_ASSEMBLER_H_
#error Do not include assembler_mips.h directly; use assembler.h instead.
#endif
#include "platform/assert.h"
#include "platform/utils.h"
#include "vm/constants_mips.h"
#include "vm/hash_map.h"
#include "vm/object.h"
#include "vm/simulator.h"
// References to documentation in this file refer to:
// "MIPS® Architecture For Programmers Volume I-A:
// Introduction to the MIPS32® Architecture" in short "VolI-A"
// and
// "MIPS® Architecture For Programmers Volume II-A:
// The MIPS32® Instruction Set" in short "VolII-A"
namespace dart {
// Forward declarations.
class RuntimeEntry;
class StubEntry;
class Immediate : public ValueObject {
public:
explicit Immediate(int32_t value) : value_(value) { }
Immediate(const Immediate& other) : ValueObject(), value_(other.value_) { }
Immediate& operator=(const Immediate& other) {
value_ = other.value_;
return *this;
}
private:
int32_t value_;
int32_t value() const { return value_; }
friend class Assembler;
};
class Address : public ValueObject {
public:
explicit Address(Register base, int32_t offset = 0)
: ValueObject(), base_(base), offset_(offset) { }
// This addressing mode does not exist.
Address(Register base, Register offset);
Address(const Address& other)
: ValueObject(), base_(other.base_), offset_(other.offset_) { }
Address& operator=(const Address& other) {
base_ = other.base_;
offset_ = other.offset_;
return *this;
}
uint32_t encoding() const {
ASSERT(Utils::IsInt(kImmBits, offset_));
uint16_t imm_value = static_cast<uint16_t>(offset_);
return (base_ << kRsShift) | imm_value;
}
static bool CanHoldOffset(int32_t offset) {
return Utils::IsInt(kImmBits, offset);
}
Register base() const { return base_; }
int32_t offset() const { return offset_; }
private:
Register base_;
int32_t offset_;
};
class FieldAddress : public Address {
public:
FieldAddress(Register base, int32_t disp)
: Address(base, disp - kHeapObjectTag) { }
FieldAddress(const FieldAddress& other) : Address(other) { }
FieldAddress& operator=(const FieldAddress& other) {
Address::operator=(other);
return *this;
}
};
class Label : public ValueObject {
public:
Label() : position_(0) { }
~Label() {
// Assert if label is being destroyed with unresolved branches pending.
ASSERT(!IsLinked());
}
// Returns the position for bound and linked labels. Cannot be used
// for unused labels.
intptr_t Position() const {
ASSERT(!IsUnused());
return IsBound() ? -position_ - kWordSize : position_ - kWordSize;
}
bool IsBound() const { return position_ < 0; }
bool IsUnused() const { return position_ == 0; }
bool IsLinked() const { return position_ > 0; }
private:
intptr_t position_;
void Reinitialize() {
position_ = 0;
}
void BindTo(intptr_t position) {
ASSERT(!IsBound());
position_ = -position - kWordSize;
ASSERT(IsBound());
}
void LinkTo(intptr_t position) {
ASSERT(!IsBound());
position_ = position + kWordSize;
ASSERT(IsLinked());
}
friend class Assembler;
DISALLOW_COPY_AND_ASSIGN(Label);
};
// There is no dedicated status register on MIPS, but Condition values are used
// and passed around by the intermediate language, so we need a Condition type.
// We delay code generation of a comparison that would result in a traditional
// condition code in the status register by keeping both register operands and
// the relational operator between them as the Condition.
class Condition : public ValueObject {
public:
enum Bits {
kLeftPos = 0,
kLeftSize = 6,
kRightPos = kLeftPos + kLeftSize,
kRightSize = 6,
kRelOpPos = kRightPos + kRightSize,
kRelOpSize = 4,
kImmPos = kRelOpPos + kRelOpSize,
kImmSize = 16,
};
class LeftBits : public BitField<Register, kLeftPos, kLeftSize> {};
class RightBits : public BitField<Register, kRightPos, kRightSize> {};
class RelOpBits : public BitField<RelationOperator, kRelOpPos, kRelOpSize> {};
class ImmBits : public BitField<uint16_t, kImmPos, kImmSize> {};
Register left() const { return LeftBits::decode(bits_); }
Register right() const { return RightBits::decode(bits_); }
RelationOperator rel_op() const { return RelOpBits::decode(bits_); }
int16_t imm() const { return static_cast<int16_t>(ImmBits::decode(bits_)); }
static bool IsValidImm(int32_t value) {
// We want both value and value + 1 to fit in an int16_t.
return (-0x08000 <= value) && (value < 0x7fff);
}
void set_rel_op(RelationOperator value) {
ASSERT(IsValidRelOp(value));
bits_ = RelOpBits::update(value, bits_);
}
// Uninitialized condition.
Condition() : ValueObject(), bits_(0) { }
// Copy constructor.
Condition(const Condition& other) : ValueObject(), bits_(other.bits_) { }
// Copy assignment operator.
Condition& operator=(const Condition& other) {
bits_ = other.bits_;
return *this;
}
Condition(Register left,
Register right,
RelationOperator rel_op,
int16_t imm = 0) {
// At most one constant, ZR or immediate.
ASSERT(!(((left == ZR) || (left == IMM)) &&
((right == ZR) || (right == IMM))));
// Non-zero immediate value is only allowed for IMM.
ASSERT((imm != 0) == ((left == IMM) || (right == IMM)));
set_left(left);
set_right(right);
set_rel_op(rel_op);
set_imm(imm);
}
private:
static bool IsValidRelOp(RelationOperator value) {
return (AL <= value) && (value <= ULE);
}
static bool IsValidRegister(Register value) {
return (ZR <= value) && (value <= IMM) && (value != AT);
}
void set_left(Register value) {
ASSERT(IsValidRegister(value));
bits_ = LeftBits::update(value, bits_);
}
void set_right(Register value) {
ASSERT(IsValidRegister(value));
bits_ = RightBits::update(value, bits_);
}
void set_imm(int16_t value) {
ASSERT(IsValidImm(value));
bits_ = ImmBits::update(static_cast<uint16_t>(value), bits_);
}
uword bits_;
};
class Assembler : public ValueObject {
public:
explicit Assembler(bool use_far_branches = false)
: buffer_(),
prologue_offset_(-1),
use_far_branches_(use_far_branches),
delay_slot_available_(false),
in_delay_slot_(false),
comments_(),
constant_pool_allowed_(true) { }
~Assembler() { }
void PopRegister(Register r) { Pop(r); }
void Bind(Label* label);
void Jump(Label* label) { b(label); }
// Misc. functionality
intptr_t CodeSize() const { return buffer_.Size(); }
intptr_t prologue_offset() const { return prologue_offset_; }
// Count the fixups that produce a pointer offset, without processing
// the fixups.
intptr_t CountPointerOffsets() const {
return buffer_.CountPointerOffsets();
}
const ZoneGrowableArray<intptr_t>& GetPointerOffsets() const {
return buffer_.pointer_offsets();
}
ObjectPoolWrapper& object_pool_wrapper() { return object_pool_wrapper_; }
RawObjectPool* MakeObjectPool() {
return object_pool_wrapper_.MakeObjectPool();
}
void FinalizeInstructions(const MemoryRegion& region) {
buffer_.FinalizeInstructions(region);
}
bool use_far_branches() const {
return FLAG_use_far_branches || use_far_branches_;
}
void set_use_far_branches(bool b) {
ASSERT(buffer_.Size() == 0);
use_far_branches_ = b;
}
void EnterFrame();
void LeaveFrameAndReturn();
// Set up a stub frame so that the stack traversal code can easily identify
// a stub frame.
void EnterStubFrame(intptr_t frame_size = 0);
void LeaveStubFrame();
// A separate macro for when a Ret immediately follows, so that we can use
// the branch delay slot.
void LeaveStubFrameAndReturn(Register ra = RA);
void UpdateAllocationStats(intptr_t cid,
Register temp_reg,
Heap::Space space,
bool inline_isolate = true);
void UpdateAllocationStatsWithSize(intptr_t cid,
Register size_reg,
Register temp_reg,
Heap::Space space,
bool inline_isolate = true);
void MaybeTraceAllocation(intptr_t cid,
Register temp_reg,
Label* trace,
bool inline_isolate = true);
// Inlined allocation of an instance of class 'cls', code has no runtime
// calls. Jump to 'failure' if the instance cannot be allocated here.
// Allocated instance is returned in 'instance_reg'.
// Only the tags field of the object is initialized.
void TryAllocate(const Class& cls,
Label* failure,
Register instance_reg,
Register temp_reg);
void TryAllocateArray(intptr_t cid,
intptr_t instance_size,
Label* failure,
Register instance,
Register end_address,
Register temp1,
Register temp2);
// Debugging and bringup support.
void Stop(const char* message);
void Unimplemented(const char* message);
void Untested(const char* message);
void Unreachable(const char* message);
static void InitializeMemoryWithBreakpoints(uword data, intptr_t length);
void Comment(const char* format, ...) PRINTF_ATTRIBUTE(2, 3);
static bool EmittingComments();
const Code::Comments& GetCodeComments() const;
static const char* RegisterName(Register reg);
static const char* FpuRegisterName(FpuRegister reg);
void SetPrologueOffset() {
if (prologue_offset_ == -1) {
prologue_offset_ = CodeSize();
}
}
// A utility to be able to assemble an instruction into the delay slot.
Assembler* delay_slot() {
ASSERT(delay_slot_available_);
ASSERT(buffer_.Load<int32_t>(buffer_.GetPosition() - sizeof(int32_t)) ==
Instr::kNopInstruction);
buffer_.Remit<int32_t>();
delay_slot_available_ = false;
in_delay_slot_ = true;
return this;
}
// CPU instructions in alphabetical order.
void addd(DRegister dd, DRegister ds, DRegister dt) {
// DRegisters start at the even FRegisters.
FRegister fd = static_cast<FRegister>(dd * 2);
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, fd, COP1_ADD);
}
void addiu(Register rt, Register rs, const Immediate& imm) {
ASSERT(Utils::IsInt(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(ADDIU, rs, rt, imm_value);
}
void addu(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, ADDU);
}
void and_(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, AND);
}
void andi(Register rt, Register rs, const Immediate& imm) {
ASSERT(Utils::IsUint(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(ANDI, rs, rt, imm_value);
}
// Unconditional branch.
void b(Label* l) {
beq(R0, R0, l);
}
void bal(Label *l) {
ASSERT(!in_delay_slot_);
EmitRegImmBranch(BGEZAL, R0, l);
EmitBranchDelayNop();
}
// Branch on floating point false.
void bc1f(Label* l) {
EmitFpuBranch(false, l);
EmitBranchDelayNop();
}
// Branch on floating point true.
void bc1t(Label* l) {
EmitFpuBranch(true, l);
EmitBranchDelayNop();
}
// Branch if equal.
void beq(Register rs, Register rt, Label* l) {
ASSERT(!in_delay_slot_);
EmitBranch(BEQ, rs, rt, l);
EmitBranchDelayNop();
}
// Branch if equal, likely taken.
// Delay slot executed only when branch taken.
void beql(Register rs, Register rt, Label* l) {
ASSERT(!in_delay_slot_);
EmitBranch(BEQL, rs, rt, l);
EmitBranchDelayNop();
}
// Branch if rs >= 0.
void bgez(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitRegImmBranch(BGEZ, rs, l);
EmitBranchDelayNop();
}
// Branch if rs >= 0, likely taken.
// Delay slot executed only when branch taken.
void bgezl(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitRegImmBranch(BGEZL, rs, l);
EmitBranchDelayNop();
}
// Branch if rs > 0.
void bgtz(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitBranch(BGTZ, rs, R0, l);
EmitBranchDelayNop();
}
// Branch if rs > 0, likely taken.
// Delay slot executed only when branch taken.
void bgtzl(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitBranch(BGTZL, rs, R0, l);
EmitBranchDelayNop();
}
// Branch if rs <= 0.
void blez(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitBranch(BLEZ, rs, R0, l);
EmitBranchDelayNop();
}
// Branch if rs <= 0, likely taken.
// Delay slot executed only when branch taken.
void blezl(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitBranch(BLEZL, rs, R0, l);
EmitBranchDelayNop();
}
// Branch if rs < 0.
void bltz(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitRegImmBranch(BLTZ, rs, l);
EmitBranchDelayNop();
}
// Branch if rs < 0, likely taken.
// Delay slot executed only when branch taken.
void bltzl(Register rs, Label* l) {
ASSERT(!in_delay_slot_);
EmitRegImmBranch(BLTZL, rs, l);
EmitBranchDelayNop();
}
// Branch if not equal.
void bne(Register rs, Register rt, Label* l) {
ASSERT(!in_delay_slot_); // Jump within a delay slot is not supported.
EmitBranch(BNE, rs, rt, l);
EmitBranchDelayNop();
}
// Branch if not equal, likely taken.
// Delay slot executed only when branch taken.
void bnel(Register rs, Register rt, Label* l) {
ASSERT(!in_delay_slot_); // Jump within a delay slot is not supported.
EmitBranch(BNEL, rs, rt, l);
EmitBranchDelayNop();
}
static int32_t BreakEncoding(int32_t code) {
ASSERT(Utils::IsUint(20, code));
return SPECIAL << kOpcodeShift |
code << kBreakCodeShift |
BREAK << kFunctionShift;
}
void break_(int32_t code) {
Emit(BreakEncoding(code));
}
static uword GetBreakInstructionFiller() {
return BreakEncoding(0);
}
// FPU compare, always false.
void cfd(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_F);
}
// FPU compare, true if unordered, i.e. one is NaN.
void cund(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_UN);
}
// FPU compare, true if equal.
void ceqd(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_EQ);
}
// FPU compare, true if unordered or equal.
void cueqd(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_UEQ);
}
// FPU compare, true if less than.
void coltd(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_OLT);
}
// FPU compare, true if unordered or less than.
void cultd(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_ULT);
}
// FPU compare, true if less or equal.
void coled(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_OLE);
}
// FPU compare, true if unordered or less or equal.
void culed(DRegister ds, DRegister dt) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, F0, COP1_C_ULE);
}
void clo(Register rd, Register rs) {
EmitRType(SPECIAL2, rs, rd, rd, 0, CLO);
}
void clz(Register rd, Register rs) {
EmitRType(SPECIAL2, rs, rd, rd, 0, CLZ);
}
// Convert a 32-bit float in fs to a 64-bit double in dd.
void cvtds(DRegister dd, FRegister fs) {
FRegister fd = static_cast<FRegister>(dd * 2);
EmitFpuRType(COP1, FMT_S, F0, fs, fd, COP1_CVT_D);
}
// Converts a 32-bit signed int in fs to a double in fd.
void cvtdw(DRegister dd, FRegister fs) {
FRegister fd = static_cast<FRegister>(dd * 2);
EmitFpuRType(COP1, FMT_W, F0, fs, fd, COP1_CVT_D);
}
// Converts a 64-bit signed int in fs to a double in fd.
void cvtdl(DRegister dd, DRegister ds) {
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister fd = static_cast<FRegister>(dd * 2);
EmitFpuRType(COP1, FMT_L, F0, fs, fd, COP1_CVT_D);
}
void cvtsd(FRegister fd, DRegister ds) {
FRegister fs = static_cast<FRegister>(ds * 2);
EmitFpuRType(COP1, FMT_D, F0, fs, fd, COP1_CVT_S);
}
void cvtwd(FRegister fd, DRegister ds) {
FRegister fs = static_cast<FRegister>(ds * 2);
EmitFpuRType(COP1, FMT_D, F0, fs, fd, COP1_CVT_W);
}
void div(Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, R0, 0, DIV);
}
void divd(DRegister dd, DRegister ds, DRegister dt) {
FRegister fd = static_cast<FRegister>(dd * 2);
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, fd, COP1_DIV);
}
void divu(Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, R0, 0, DIVU);
}
void jalr(Register rs, Register rd = RA) {
ASSERT(rs != rd);
ASSERT(!in_delay_slot_); // Jump within a delay slot is not supported.
EmitRType(SPECIAL, rs, R0, rd, 0, JALR);
EmitBranchDelayNop();
}
void jr(Register rs) {
ASSERT(!in_delay_slot_); // Jump within a delay slot is not supported.
EmitRType(SPECIAL, rs, R0, R0, 0, JR);
EmitBranchDelayNop();
}
void lb(Register rt, const Address& addr) {
EmitLoadStore(LB, rt, addr);
}
void lbu(Register rt, const Address& addr) {
EmitLoadStore(LBU, rt, addr);
}
void ldc1(DRegister dt, const Address& addr) {
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuLoadStore(LDC1, ft, addr);
}
void lh(Register rt, const Address& addr) {
EmitLoadStore(LH, rt, addr);
}
void lhu(Register rt, const Address& addr) {
EmitLoadStore(LHU, rt, addr);
}
void lui(Register rt, const Immediate& imm) {
ASSERT(Utils::IsUint(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(LUI, R0, rt, imm_value);
}
void lw(Register rt, const Address& addr) {
EmitLoadStore(LW, rt, addr);
}
void lwc1(FRegister ft, const Address& addr) {
EmitFpuLoadStore(LWC1, ft, addr);
}
void madd(Register rs, Register rt) {
EmitRType(SPECIAL2, rs, rt, R0, 0, MADD);
}
void maddu(Register rs, Register rt) {
EmitRType(SPECIAL2, rs, rt, R0, 0, MADDU);
}
void mfc1(Register rt, FRegister fs) {
Emit(COP1 << kOpcodeShift |
COP1_MF << kCop1SubShift |
rt << kRtShift |
fs << kFsShift);
}
void mfhi(Register rd) {
EmitRType(SPECIAL, R0, R0, rd, 0, MFHI);
}
void mflo(Register rd) {
EmitRType(SPECIAL, R0, R0, rd, 0, MFLO);
}
void mov(Register rd, Register rs) {
or_(rd, rs, ZR);
}
void movd(DRegister dd, DRegister ds) {
FRegister fd = static_cast<FRegister>(dd * 2);
FRegister fs = static_cast<FRegister>(ds * 2);
EmitFpuRType(COP1, FMT_D, F0, fs, fd, COP1_MOV);
}
// Move if floating point false.
void movf(Register rd, Register rs) {
EmitRType(SPECIAL, rs, R0, rd, 0, MOVCI);
}
void movn(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, MOVN);
}
// Move if floating point true.
void movt(Register rd, Register rs) {
EmitRType(SPECIAL, rs, R1, rd, 0, MOVCI);
}
// rd <- (rt == 0) ? rs : rd;
void movz(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, MOVZ);
}
void movs(FRegister fd, FRegister fs) {
EmitFpuRType(COP1, FMT_S, F0, fs, fd, COP1_MOV);
}
void mtc1(Register rt, FRegister fs) {
Emit(COP1 << kOpcodeShift |
COP1_MT << kCop1SubShift |
rt << kRtShift |
fs << kFsShift);
}
void mthi(Register rs) {
EmitRType(SPECIAL, rs, R0, R0, 0, MTHI);
}
void mtlo(Register rs) {
EmitRType(SPECIAL, rs, R0, R0, 0, MTLO);
}
void muld(DRegister dd, DRegister ds, DRegister dt) {
FRegister fd = static_cast<FRegister>(dd * 2);
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, fd, COP1_MUL);
}
void mult(Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, R0, 0, MULT);
}
void multu(Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, R0, 0, MULTU);
}
void nop() {
Emit(Instr::kNopInstruction);
}
void nor(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, NOR);
}
void or_(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, OR);
}
void ori(Register rt, Register rs, const Immediate& imm) {
ASSERT(Utils::IsUint(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(ORI, rs, rt, imm_value);
}
void sb(Register rt, const Address& addr) {
EmitLoadStore(SB, rt, addr);
}
void sdc1(DRegister dt, const Address& addr) {
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuLoadStore(SDC1, ft, addr);
}
void sh(Register rt, const Address& addr) {
EmitLoadStore(SH, rt, addr);
}
void sll(Register rd, Register rt, int sa) {
EmitRType(SPECIAL, R0, rt, rd, sa, SLL);
}
void sllv(Register rd, Register rt, Register rs) {
EmitRType(SPECIAL, rs, rt, rd, 0, SLLV);
}
void slt(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, SLT);
}
void slti(Register rt, Register rs, const Immediate& imm) {
ASSERT(Utils::IsInt(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(SLTI, rs, rt, imm_value);
}
// Although imm argument is int32_t, it is interpreted as an uint32_t.
// For example, -1 stands for 0xffffffffUL: it is encoded as 0xffff in the
// instruction imm field and is then sign extended back to 0xffffffffUL.
void sltiu(Register rt, Register rs, const Immediate& imm) {
ASSERT(Utils::IsInt(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(SLTIU, rs, rt, imm_value);
}
void sltu(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, SLTU);
}
void sqrtd(DRegister dd, DRegister ds) {
FRegister fd = static_cast<FRegister>(dd * 2);
FRegister fs = static_cast<FRegister>(ds * 2);
EmitFpuRType(COP1, FMT_D, F0, fs, fd, COP1_SQRT);
}
void sra(Register rd, Register rt, int sa) {
EmitRType(SPECIAL, R0, rt, rd, sa, SRA);
}
void srav(Register rd, Register rt, Register rs) {
EmitRType(SPECIAL, rs, rt, rd, 0, SRAV);
}
void srl(Register rd, Register rt, int sa) {
EmitRType(SPECIAL, R0, rt, rd, sa, SRL);
}
void srlv(Register rd, Register rt, Register rs) {
EmitRType(SPECIAL, rs, rt, rd, 0, SRLV);
}
void subd(DRegister dd, DRegister ds, DRegister dt) {
FRegister fd = static_cast<FRegister>(dd * 2);
FRegister fs = static_cast<FRegister>(ds * 2);
FRegister ft = static_cast<FRegister>(dt * 2);
EmitFpuRType(COP1, FMT_D, ft, fs, fd, COP1_SUB);
}
void subu(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, SUBU);
}
void sw(Register rt, const Address& addr) {
EmitLoadStore(SW, rt, addr);
}
void swc1(FRegister ft, const Address& addr) {
EmitFpuLoadStore(SWC1, ft, addr);
}
void xori(Register rt, Register rs, const Immediate& imm) {
ASSERT(Utils::IsUint(kImmBits, imm.value()));
const uint16_t imm_value = static_cast<uint16_t>(imm.value());
EmitIType(XORI, rs, rt, imm_value);
}
void xor_(Register rd, Register rs, Register rt) {
EmitRType(SPECIAL, rs, rt, rd, 0, XOR);
}
// Macros in alphabetical order.
// Addition of rs and rt with the result placed in rd.
// After, ro < 0 if there was signed overflow, ro >= 0 otherwise.
// rd and ro must not be TMP.
// ro must be different from all the other registers.
// If rd, rs, and rt are the same register, then a scratch register different
// from the other registers is needed.
void AdduDetectOverflow(Register rd, Register rs, Register rt, Register ro,
Register scratch = kNoRegister);
// ro must be different from rd and rs.
// rd and ro must not be TMP.
// If rd and rs are the same, a scratch register different from the other
// registers is needed.
void AddImmediateDetectOverflow(Register rd, Register rs, int32_t imm,
Register ro, Register scratch = kNoRegister) {
ASSERT(!in_delay_slot_);
LoadImmediate(rd, imm);
AdduDetectOverflow(rd, rs, rd, ro, scratch);
}
// Subtraction of rt from rs (rs - rt) with the result placed in rd.
// After, ro < 0 if there was signed overflow, ro >= 0 otherwise.
// None of rd, rs, rt, or ro may be TMP.
// ro must be different from the other registers.
void SubuDetectOverflow(Register rd, Register rs, Register rt, Register ro);
// ro must be different from rd and rs.
// None of rd, rs, rt, or ro may be TMP.
void SubImmediateDetectOverflow(Register rd, Register rs, int32_t imm,
Register ro) {
ASSERT(!in_delay_slot_);
LoadImmediate(rd, imm);
SubuDetectOverflow(rd, rs, rd, ro);
}
void Branch(const StubEntry& stub_entry, Register pp = PP);
void BranchLink(const StubEntry& stub_entry,
Patchability patchable = kNotPatchable);
void BranchLinkPatchable(const StubEntry& stub_entry);
void Drop(intptr_t stack_elements) {
ASSERT(stack_elements >= 0);
if (stack_elements > 0) {
addiu(SP, SP, Immediate(stack_elements * kWordSize));
}
}
void LoadPoolPointer(Register reg = PP) {
ASSERT(!in_delay_slot_);
CheckCodePointer();
lw(reg, FieldAddress(CODE_REG, Code::object_pool_offset()));
set_constant_pool_allowed(reg == PP);
}
void CheckCodePointer();
void RestoreCodePointer();
void LoadImmediate(Register rd, int32_t value) {
ASSERT(!in_delay_slot_);
if (Utils::IsInt(kImmBits, value)) {
addiu(rd, ZR, Immediate(value));
} else {
const uint16_t low = Utils::Low16Bits(value);
const uint16_t high = Utils::High16Bits(value);
lui(rd, Immediate(high));
if (low != 0) {
ori(rd, rd, Immediate(low));
}
}
}
void LoadImmediate(DRegister rd, double value) {
ASSERT(!in_delay_slot_);
FRegister frd = static_cast<FRegister>(rd * 2);
const int64_t ival = bit_cast<uint64_t, double>(value);
const int32_t low = Utils::Low32Bits(ival);
const int32_t high = Utils::High32Bits(ival);
if (low != 0) {
LoadImmediate(TMP, low);
mtc1(TMP, frd);
} else {
mtc1(ZR, frd);
}
if (high != 0) {
LoadImmediate(TMP, high);
mtc1(TMP, static_cast<FRegister>(frd + 1));
} else {
mtc1(ZR, static_cast<FRegister>(frd + 1));
}
}
void LoadImmediate(FRegister rd, float value) {
ASSERT(!in_delay_slot_);
const int32_t ival = bit_cast<int32_t, float>(value);
if (ival == 0) {
mtc1(ZR, rd);
} else {
LoadImmediate(TMP, ival);
mtc1(TMP, rd);
}
}
void AddImmediate(Register rd, Register rs, int32_t value) {
ASSERT(!in_delay_slot_);
if ((value == 0) && (rd == rs)) return;
// If value is 0, we still want to move rs to rd if they aren't the same.
if (Utils::IsInt(kImmBits, value)) {
addiu(rd, rs, Immediate(value));
} else {
LoadImmediate(TMP, value);
addu(rd, rs, TMP);
}
}
void AddImmediate(Register rd, int32_t value) {
ASSERT(!in_delay_slot_);
AddImmediate(rd, rd, value);
}
void AndImmediate(Register rd, Register rs, int32_t imm) {
ASSERT(!in_delay_slot_);
if (imm == 0) {
mov(rd, ZR);
return;
}
if (Utils::IsUint(kImmBits, imm)) {
andi(rd, rs, Immediate(imm));
} else {
LoadImmediate(TMP, imm);
and_(rd, rs, TMP);
}
}
void OrImmediate(Register rd, Register rs, int32_t imm) {
ASSERT(!in_delay_slot_);
if (imm == 0) {
mov(rd, rs);
return;
}
if (Utils::IsUint(kImmBits, imm)) {
ori(rd, rs, Immediate(imm));
} else {
LoadImmediate(TMP, imm);
or_(rd, rs, TMP);
}
}
void XorImmediate(Register rd, Register rs, int32_t imm) {
ASSERT(!in_delay_slot_);
if (imm == 0) {
mov(rd, rs);
return;
}
if (Utils::IsUint(kImmBits, imm)) {
xori(rd, rs, Immediate(imm));
} else {
LoadImmediate(TMP, imm);
xor_(rd, rs, TMP);
}
}
Register LoadConditionOperand(Register rd,
const Object& operand,
int16_t* imm) {
if (operand.IsSmi()) {
const int32_t val = reinterpret_cast<int32_t>(operand.raw());
if (val == 0) {
return ZR;
} else if (Condition::IsValidImm(val)) {
ASSERT(*imm == 0);
*imm = val;
return IMM;
}
}
LoadObject(rd, operand);
return rd;
}
// Branch to label if condition is true.
void BranchOnCondition(Condition cond, Label* l) {
ASSERT(!in_delay_slot_);
Register left = cond.left();
Register right = cond.right();
RelationOperator rel_op = cond.rel_op();
switch (rel_op) {
case NV: return;
case AL: b(l); return;
case EQ: // fall through.
case NE: {
if (left == IMM) {
addiu(AT, ZR, Immediate(cond.imm()));
left = AT;
} else if (right == IMM) {
addiu(AT, ZR, Immediate(cond.imm()));
right = AT;
}
if (rel_op == EQ) {
beq(left, right, l);
} else {
bne(left, right, l);
}
break;
}
case GT: {
if (left == ZR) {
bltz(right, l);
} else if (right == ZR) {
bgtz(left, l);
} else if (left == IMM) {
slti(AT, right, Immediate(cond.imm()));
bne(AT, ZR, l);
} else if (right == IMM) {
slti(AT, left, Immediate(cond.imm() + 1));
beq(AT, ZR, l);
} else {
slt(AT, right, left);
bne(AT, ZR, l);
}
break;
}
case GE: {
if (left == ZR) {
blez(right, l);
} else if (right == ZR) {
bgez(left, l);
} else if (left == IMM) {
slti(AT, right, Immediate(cond.imm() + 1));
bne(AT, ZR, l);
} else if (right == IMM) {
slti(AT, left, Immediate(cond.imm()));
beq(AT, ZR, l);
} else {
slt(AT, left, right);
beq(AT, ZR, l);
}
break;
}
case LT: {
if (left == ZR) {
bgtz(right, l);
} else if (right == ZR) {
bltz(left, l);
} else if (left == IMM) {
slti(AT, right, Immediate(cond.imm() + 1));
beq(AT, ZR, l);
} else if (right == IMM) {
slti(AT, left, Immediate(cond.imm()));
bne(AT, ZR, l);
} else {
slt(AT, left, right);
bne(AT, ZR, l);
}
break;
}
case LE: {
if (left == ZR) {
bgez(right, l);
} else if (right == ZR) {
blez(left, l);
} else if (left == IMM) {
slti(AT, right, Immediate(cond.imm()));
beq(AT, ZR, l);
} else if (right == IMM) {
slti(AT, left, Immediate(cond.imm() + 1));
bne(AT, ZR, l);
} else {
slt(AT, right, left);
beq(AT, ZR, l);
}
break;
}
case UGT: {
ASSERT((left != IMM) && (right != IMM)); // No unsigned constants used.
if (left == ZR) {
// NV: Never branch. Fall through.
} else if (right == ZR) {
bne(left, ZR, l);
} else {
sltu(AT, right, left);
bne(AT, ZR, l);
}
break;
}
case UGE: {
ASSERT((left != IMM) && (right != IMM)); // No unsigned constants used.
if (left == ZR) {
beq(right, ZR, l);
} else if (right == ZR) {
// AL: Always branch to l.
beq(ZR, ZR, l);
} else {
sltu(AT, left, right);
beq(AT, ZR, l);
}
break;
}
case ULT: {
ASSERT((left != IMM) && (right != IMM)); // No unsigned constants used.
if (left == ZR) {
bne(right, ZR, l);
} else if (right == ZR) {
// NV: Never branch. Fall through.
} else {
sltu(AT, left, right);
bne(AT, ZR, l);
}
break;
}
case ULE: {
ASSERT((left != IMM) && (right != IMM)); // No unsigned constants used.
if (left == ZR) {
// AL: Always branch to l.
beq(ZR, ZR, l);
} else if (right == ZR) {
beq(left, ZR, l);
} else {
sltu(AT, right, left);
beq(AT, ZR, l);
}
break;
}
default:
UNREACHABLE();
}
}
void BranchEqual(Register rd, Register rn, Label* l) {
beq(rd, rn, l);
}
void BranchEqual(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
beq(rd, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
beq(rd, CMPRES2, l);
}
}
void BranchEqual(Register rd, const Object& object, Label* l) {
ASSERT(!in_delay_slot_);
ASSERT(rd != CMPRES2);
LoadObject(CMPRES2, object);
beq(rd, CMPRES2, l);
}
void BranchNotEqual(Register rd, Register rn, Label* l) {
bne(rd, rn, l);
}
void BranchNotEqual(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
bne(rd, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
bne(rd, CMPRES2, l);
}
}
void BranchNotEqual(Register rd, const Object& object, Label* l) {
ASSERT(!in_delay_slot_);
ASSERT(rd != CMPRES2);
LoadObject(CMPRES2, object);
bne(rd, CMPRES2, l);
}
void BranchSignedGreater(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
slt(CMPRES2, rs, rd); // CMPRES2 = rd > rs ? 1 : 0.
bne(CMPRES2, ZR, l);
}
void BranchSignedGreater(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
bgtz(rd, l);
} else {
if (Utils::IsInt(kImmBits, imm.value() + 1)) {
slti(CMPRES2, rd, Immediate(imm.value() + 1));
beq(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchSignedGreater(rd, CMPRES2, l);
}
}
}
void BranchUnsignedGreater(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
sltu(CMPRES2, rs, rd);
bne(CMPRES2, ZR, l);
}
void BranchUnsignedGreater(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
BranchNotEqual(rd, Immediate(0), l);
} else {
if ((imm.value() != -1) && Utils::IsInt(kImmBits, imm.value() + 1)) {
sltiu(CMPRES2, rd, Immediate(imm.value() + 1));
beq(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchUnsignedGreater(rd, CMPRES2, l);
}
}
}
void BranchSignedGreaterEqual(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
slt(CMPRES2, rd, rs); // CMPRES2 = rd < rs ? 1 : 0.
beq(CMPRES2, ZR, l); // If CMPRES2 = 0, then rd >= rs.
}
void BranchSignedGreaterEqual(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
bgez(rd, l);
} else {
if (Utils::IsInt(kImmBits, imm.value())) {
slti(CMPRES2, rd, imm);
beq(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchSignedGreaterEqual(rd, CMPRES2, l);
}
}
}
void BranchUnsignedGreaterEqual(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
sltu(CMPRES2, rd, rs); // CMPRES2 = rd < rs ? 1 : 0.
beq(CMPRES2, ZR, l);
}
void BranchUnsignedGreaterEqual(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
b(l);
} else {
if (Utils::IsInt(kImmBits, imm.value())) {
sltiu(CMPRES2, rd, imm);
beq(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchUnsignedGreaterEqual(rd, CMPRES2, l);
}
}
}
void BranchSignedLess(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
BranchSignedGreater(rs, rd, l);
}
void BranchSignedLess(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
bltz(rd, l);
} else {
if (Utils::IsInt(kImmBits, imm.value())) {
slti(CMPRES2, rd, imm);
bne(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchSignedGreater(CMPRES2, rd, l);
}
}
}
void BranchUnsignedLess(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
BranchUnsignedGreater(rs, rd, l);
}
void BranchUnsignedLess(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
// Never branch. Fall through.
} else {
if (Utils::IsInt(kImmBits, imm.value())) {
sltiu(CMPRES2, rd, imm);
bne(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchUnsignedGreater(CMPRES2, rd, l);
}
}
}
void BranchSignedLessEqual(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
BranchSignedGreaterEqual(rs, rd, l);
}
void BranchSignedLessEqual(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
blez(rd, l);
} else {
if (Utils::IsInt(kImmBits, imm.value() + 1)) {
slti(CMPRES2, rd, Immediate(imm.value() + 1));
bne(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchSignedGreaterEqual(CMPRES2, rd, l);
}
}
}
void BranchUnsignedLessEqual(Register rd, Register rs, Label* l) {
ASSERT(!in_delay_slot_);
BranchUnsignedGreaterEqual(rs, rd, l);
}
void BranchUnsignedLessEqual(Register rd, const Immediate& imm, Label* l) {
ASSERT(!in_delay_slot_);
if (imm.value() == 0) {
beq(rd, ZR, l);
} else {
if ((imm.value() != -1) && Utils::IsInt(kImmBits, imm.value() + 1)) {
sltiu(CMPRES2, rd, Immediate(imm.value() + 1));
bne(CMPRES2, ZR, l);
} else {
ASSERT(rd != CMPRES2);
LoadImmediate(CMPRES2, imm.value());
BranchUnsignedGreaterEqual(CMPRES2, rd, l);
}
}
}
void Push(Register rt) {
ASSERT(!in_delay_slot_);
addiu(SP, SP, Immediate(-kWordSize));
sw(rt, Address(SP));
}
void Pop(Register rt) {
ASSERT(!in_delay_slot_);
lw(rt, Address(SP));
addiu(SP, SP, Immediate(kWordSize));
}
void Ret() {
jr(RA);
}
void SmiTag(Register reg) {
sll(reg, reg, kSmiTagSize);
}
void SmiTag(Register dst, Register src) {
sll(dst, src, kSmiTagSize);
}
void SmiUntag(Register reg) {
sra(reg, reg, kSmiTagSize);
}
void SmiUntag(Register dst, Register src) {
sra(dst, src, kSmiTagSize);
}
void LoadFromOffset(Register reg, Register base, int32_t offset) {
ASSERT(!in_delay_slot_);
if (Utils::IsInt(kImmBits, offset)) {
lw(reg, Address(base, offset));
} else {
LoadImmediate(TMP, offset);
addu(TMP, base, TMP);
lw(reg, Address(TMP, 0));
}
}
void LoadFieldFromOffset(Register reg, Register base, int32_t offset) {
LoadFromOffset(reg, base, offset - kHeapObjectTag);
}
void StoreToOffset(Register reg, Register base, int32_t offset) {
ASSERT(!in_delay_slot_);
if (Utils::IsInt(kImmBits, offset)) {
sw(reg, Address(base, offset));
} else {
LoadImmediate(TMP, offset);
addu(TMP, base, TMP);
sw(reg, Address(TMP, 0));
}
}
void StoreFieldToOffset(Register reg, Register base, int32_t offset) {
StoreToOffset(reg, base, offset - kHeapObjectTag);
}
void StoreDToOffset(DRegister reg, Register base, int32_t offset) {
ASSERT(!in_delay_slot_);
FRegister lo = static_cast<FRegister>(reg * 2);
FRegister hi = static_cast<FRegister>(reg * 2 + 1);
swc1(lo, Address(base, offset));
swc1(hi, Address(base, offset + kWordSize));
}
void LoadDFromOffset(DRegister reg, Register base, int32_t offset) {
ASSERT(!in_delay_slot_);
FRegister lo = static_cast<FRegister>(reg * 2);
FRegister hi = static_cast<FRegister>(reg * 2 + 1);
lwc1(lo, Address(base, offset));
lwc1(hi, Address(base, offset + kWordSize));
}
// dest gets the address of the following instruction. If temp is given,
// RA is preserved using it as a temporary.
void GetNextPC(Register dest, Register temp = kNoRegister);
void ReserveAlignedFrameSpace(intptr_t frame_space);
// Create a frame for calling into runtime that preserves all volatile
// registers. Frame's SP is guaranteed to be correctly aligned and
// frame_space bytes are reserved under it.
void EnterCallRuntimeFrame(intptr_t frame_space);
void LeaveCallRuntimeFrame();
void LoadObject(Register rd, const Object& object);
void LoadUniqueObject(Register rd, const Object& object);
void LoadFunctionFromCalleePool(Register dst,
const Function& function,
Register new_pp);
void LoadNativeEntry(Register rd,
const ExternalLabel* label,
Patchability patchable);
void PushObject(const Object& object);
void LoadIsolate(Register result);
void LoadClassId(Register result, Register object);
void LoadClassById(Register result, Register class_id);
void LoadClass(Register result, Register object);
void LoadClassIdMayBeSmi(Register result, Register object);
void LoadTaggedClassIdMayBeSmi(Register result, Register object);
void ComputeRange(Register result,
Register value,
Label* miss);
void UpdateRangeFeedback(Register value,
intptr_t index,
Register ic_data,
Register scratch,
Label* miss);
void StoreIntoObject(Register object, // Object we are storing into.
const Address& dest, // Where we are storing into.
Register value, // Value we are storing.
bool can_value_be_smi = true);
void StoreIntoObjectOffset(Register object,
int32_t offset,
Register value,
bool can_value_be_smi = true);
void StoreIntoObjectNoBarrier(Register object,
const Address& dest,
Register value);
void StoreIntoObjectNoBarrierOffset(Register object,
int32_t offset,
Register value);
void StoreIntoObjectNoBarrier(Register object,
const Address& dest,
const Object& value);
void StoreIntoObjectNoBarrierOffset(Register object,
int32_t offset,
const Object& value);
void CallRuntime(const RuntimeEntry& entry, intptr_t argument_count);
// Set up a Dart frame on entry with a frame pointer and PC information to
// enable easy access to the RawInstruction object of code corresponding
// to this frame.
void EnterDartFrame(intptr_t frame_size);
void LeaveDartFrame(RestorePP restore_pp = kRestoreCallerPP);
void LeaveDartFrameAndReturn(Register ra = RA);
// Set up a Dart frame for a function compiled for on-stack replacement.
// The frame layout is a normal Dart frame, but the frame is partially set
// up on entry (it is the frame of the unoptimized code).
void EnterOsrFrame(intptr_t extra_size);
Address ElementAddressForIntIndex(bool is_external,
intptr_t cid,
intptr_t index_scale,
Register array,
intptr_t index) const;
Address ElementAddressForRegIndex(bool is_load,
bool is_external,
intptr_t cid,
intptr_t index_scale,
Register array,
Register index);
static Address VMTagAddress() {
return Address(THR, Thread::vm_tag_offset());
}
// On some other platforms, we draw a distinction between safe and unsafe
// smis.
static bool IsSafe(const Object& object) { return true; }
static bool IsSafeSmi(const Object& object) { return object.IsSmi(); }
bool constant_pool_allowed() const {
return constant_pool_allowed_;
}
void set_constant_pool_allowed(bool b) {
constant_pool_allowed_ = b;
}
private:
AssemblerBuffer buffer_;
ObjectPoolWrapper object_pool_wrapper_;
intptr_t prologue_offset_;
bool use_far_branches_;
bool delay_slot_available_;
bool in_delay_slot_;
class CodeComment : public ZoneAllocated {
public:
CodeComment(intptr_t pc_offset, const String& comment)
: pc_offset_(pc_offset), comment_(comment) { }
intptr_t pc_offset() const { return pc_offset_; }
const String& comment() const { return comment_; }
private:
intptr_t pc_offset_;
const String& comment_;
DISALLOW_COPY_AND_ASSIGN(CodeComment);
};
GrowableArray<CodeComment*> comments_;
bool constant_pool_allowed_;
void BranchLink(const ExternalLabel* label);
void BranchLink(const Code& code, Patchability patchable);
bool CanLoadFromObjectPool(const Object& object) const;
void LoadWordFromPoolOffset(Register rd, int32_t offset, Register pp = PP);
void LoadObjectHelper(Register rd, const Object& object, bool is_unique);
void Emit(int32_t value) {
// Emitting an instruction clears the delay slot state.
in_delay_slot_ = false;
delay_slot_available_ = false;
AssemblerBuffer::EnsureCapacity ensured(&buffer_);
buffer_.Emit<int32_t>(value);
}
// Encode CPU instructions according to the types specified in
// Figures 4-1, 4-2 and 4-3 in VolI-A.
void EmitIType(Opcode opcode,
Register rs,
Register rt,
uint16_t imm) {
Emit(opcode << kOpcodeShift |
rs << kRsShift |
rt << kRtShift |
imm);
}
void EmitLoadStore(Opcode opcode, Register rt,
const Address &addr) {
Emit(opcode << kOpcodeShift |
rt << kRtShift |
addr.encoding());
}
void EmitFpuLoadStore(Opcode opcode, FRegister ft,
const Address &addr) {
Emit(opcode << kOpcodeShift |
ft << kFtShift |
addr.encoding());
}
void EmitRegImmType(Opcode opcode,
Register rs,
RtRegImm code,
uint16_t imm) {
Emit(opcode << kOpcodeShift |
rs << kRsShift |
code << kRtShift |
imm);
}
void EmitJType(Opcode opcode, uint32_t destination) {
UNIMPLEMENTED();
}
void EmitRType(Opcode opcode,
Register rs,
Register rt,
Register rd,
int sa,
SpecialFunction func) {
ASSERT(Utils::IsUint(5, sa));
Emit(opcode << kOpcodeShift |
rs << kRsShift |
rt << kRtShift |
rd << kRdShift |
sa << kSaShift |
func << kFunctionShift);
}
void EmitFpuRType(Opcode opcode,
Format fmt,
FRegister ft,
FRegister fs,
FRegister fd,
Cop1Function func) {
Emit(opcode << kOpcodeShift |
fmt << kFmtShift |
ft << kFtShift |
fs << kFsShift |
fd << kFdShift |
func << kCop1FnShift);
}
int32_t EncodeBranchOffset(int32_t offset, int32_t instr);
void EmitFarJump(int32_t offset, bool link);
void EmitFarBranch(Opcode b, Register rs, Register rt, int32_t offset);
void EmitFarRegImmBranch(RtRegImm b, Register rs, int32_t offset);
void EmitFarFpuBranch(bool kind, int32_t offset);
void EmitBranch(Opcode b, Register rs, Register rt, Label* label);
void EmitRegImmBranch(RtRegImm b, Register rs, Label* label);
void EmitFpuBranch(bool kind, Label *label);
void EmitBranchDelayNop() {
Emit(Instr::kNopInstruction); // Branch delay NOP.
delay_slot_available_ = true;
}
void StoreIntoObjectFilter(Register object, Register value, Label* no_update);
// Shorter filtering sequence that assumes that value is not a smi.
void StoreIntoObjectFilterNoSmi(Register object,
Register value,
Label* no_update);
DISALLOW_ALLOCATION();
DISALLOW_COPY_AND_ASSIGN(Assembler);
};
} // namespace dart
#endif // VM_ASSEMBLER_MIPS_H_