// Copyright 2015, VIXL authors
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// * Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
// * Neither the name of ARM Limited nor the names of its contributors may be
// used to endorse or promote products derived from this software without
// specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS CONTRIBUTORS "AS IS" AND
// ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
// WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
// DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#ifndef VIXL_AARCH64_MACRO_ASSEMBLER_AARCH64_H_
#define VIXL_AARCH64_MACRO_ASSEMBLER_AARCH64_H_
#include <algorithm>
#include <limits>
#include "../code-generation-scopes-vixl.h"
#include "../globals-vixl.h"
#include "../macro-assembler-interface.h"
#include "assembler-aarch64.h"
#include "debugger-aarch64.h"
#include "instrument-aarch64.h"
// Required in order to generate debugging instructions for the simulator. This
// is needed regardless of whether the simulator is included or not, since
// generating simulator specific instructions is controlled at runtime.
#include "simulator-constants-aarch64.h"
#define LS_MACRO_LIST(V) \
V(Ldrb, Register&, rt, LDRB_w) \
V(Strb, Register&, rt, STRB_w) \
V(Ldrsb, Register&, rt, rt.Is64Bits() ? LDRSB_x : LDRSB_w) \
V(Ldrh, Register&, rt, LDRH_w) \
V(Strh, Register&, rt, STRH_w) \
V(Ldrsh, Register&, rt, rt.Is64Bits() ? LDRSH_x : LDRSH_w) \
V(Ldr, CPURegister&, rt, LoadOpFor(rt)) \
V(Str, CPURegister&, rt, StoreOpFor(rt)) \
V(Ldrsw, Register&, rt, LDRSW_x)
#define LSPAIR_MACRO_LIST(V) \
V(Ldp, CPURegister&, rt, rt2, LoadPairOpFor(rt, rt2)) \
V(Stp, CPURegister&, rt, rt2, StorePairOpFor(rt, rt2)) \
V(Ldpsw, CPURegister&, rt, rt2, LDPSW_x)
namespace vixl {
namespace aarch64 {
// Forward declaration
class MacroAssembler;
class UseScratchRegisterScope;
class Pool {
public:
explicit Pool(MacroAssembler* masm)
: checkpoint_(kNoCheckpointRequired), masm_(masm) {
Reset();
}
void Reset() {
checkpoint_ = kNoCheckpointRequired;
monitor_ = 0;
}
void Block() { monitor_++; }
void Release();
bool IsBlocked() const { return monitor_ != 0; }
static const ptrdiff_t kNoCheckpointRequired = PTRDIFF_MAX;
void SetNextCheckpoint(ptrdiff_t checkpoint);
ptrdiff_t GetCheckpoint() const { return checkpoint_; }
VIXL_DEPRECATED("GetCheckpoint", ptrdiff_t checkpoint() const) {
return GetCheckpoint();
}
enum EmitOption { kBranchRequired, kNoBranchRequired };
protected:
// Next buffer offset at which a check is required for this pool.
ptrdiff_t checkpoint_;
// Indicates whether the emission of this pool is blocked.
int monitor_;
// The MacroAssembler using this pool.
MacroAssembler* masm_;
};
class LiteralPool : public Pool {
public:
explicit LiteralPool(MacroAssembler* masm);
~LiteralPool();
void Reset();
void AddEntry(RawLiteral* literal);
bool IsEmpty() const { return entries_.empty(); }
size_t GetSize() const;
VIXL_DEPRECATED("GetSize", size_t Size() const) { return GetSize(); }
size_t GetMaxSize() const;
VIXL_DEPRECATED("GetMaxSize", size_t MaxSize() const) { return GetMaxSize(); }
size_t GetOtherPoolsMaxSize() const;
VIXL_DEPRECATED("GetOtherPoolsMaxSize", size_t OtherPoolsMaxSize() const) {
return GetOtherPoolsMaxSize();
}
void CheckEmitFor(size_t amount, EmitOption option = kBranchRequired);
// Check whether we need to emit the literal pool in order to be able to
// safely emit a branch with a given range.
void CheckEmitForBranch(size_t range);
void Emit(EmitOption option = kNoBranchRequired);
void SetNextRecommendedCheckpoint(ptrdiff_t offset);
ptrdiff_t GetNextRecommendedCheckpoint();
VIXL_DEPRECATED("GetNextRecommendedCheckpoint",
ptrdiff_t NextRecommendedCheckpoint()) {
return GetNextRecommendedCheckpoint();
}
void UpdateFirstUse(ptrdiff_t use_position);
void DeleteOnDestruction(RawLiteral* literal) {
deleted_on_destruction_.push_back(literal);
}
// Recommended not exact since the pool can be blocked for short periods.
static const ptrdiff_t kRecommendedLiteralPoolRange = 128 * KBytes;
private:
std::vector<RawLiteral*> entries_;
size_t size_;
ptrdiff_t first_use_;
// The parent class `Pool` provides a `checkpoint_`, which is the buffer
// offset before which a check *must* occur. This recommended checkpoint
// indicates when we would like to start emitting the constant pool. The
// MacroAssembler can, but does not have to, check the buffer when the
// checkpoint is reached.
ptrdiff_t recommended_checkpoint_;
std::vector<RawLiteral*> deleted_on_destruction_;
};
inline size_t LiteralPool::GetSize() const {
// Account for the pool header.
return size_ + kInstructionSize;
}
inline size_t LiteralPool::GetMaxSize() const {
// Account for the potential branch over the pool.
return GetSize() + kInstructionSize;
}
inline ptrdiff_t LiteralPool::GetNextRecommendedCheckpoint() {
return first_use_ + kRecommendedLiteralPoolRange;
}
class VeneerPool : public Pool {
public:
explicit VeneerPool(MacroAssembler* masm) : Pool(masm) {}
void Reset();
void Block() { monitor_++; }
void Release();
bool IsBlocked() const { return monitor_ != 0; }
bool IsEmpty() const { return unresolved_branches_.IsEmpty(); }
class BranchInfo {
public:
BranchInfo()
: first_unreacheable_pc_(0),
pc_offset_(0),
label_(NULL),
branch_type_(UnknownBranchType) {}
BranchInfo(ptrdiff_t offset, Label* label, ImmBranchType branch_type)
: pc_offset_(offset), label_(label), branch_type_(branch_type) {
first_unreacheable_pc_ =
pc_offset_ + Instruction::GetImmBranchForwardRange(branch_type_);
}
static bool IsValidComparison(const BranchInfo& branch_1,
const BranchInfo& branch_2) {
// BranchInfo are always compared against against other objects with
// the same branch type.
if (branch_1.branch_type_ != branch_2.branch_type_) {
return false;
}
// Since we should never have two branch infos with the same offsets, it
// first looks like we should check that offsets are different. However
// the operators may also be used to *search* for a branch info in the
// set.
bool same_offsets = (branch_1.pc_offset_ == branch_2.pc_offset_);
return (!same_offsets || ((branch_1.label_ == branch_2.label_) &&
(branch_1.first_unreacheable_pc_ ==
branch_2.first_unreacheable_pc_)));
}
// We must provide comparison operators to work with InvalSet.
bool operator==(const BranchInfo& other) const {
VIXL_ASSERT(IsValidComparison(*this, other));
return pc_offset_ == other.pc_offset_;
}
bool operator<(const BranchInfo& other) const {
VIXL_ASSERT(IsValidComparison(*this, other));
return pc_offset_ < other.pc_offset_;
}
bool operator<=(const BranchInfo& other) const {
VIXL_ASSERT(IsValidComparison(*this, other));
return pc_offset_ <= other.pc_offset_;
}
bool operator>(const BranchInfo& other) const {
VIXL_ASSERT(IsValidComparison(*this, other));
return pc_offset_ > other.pc_offset_;
}
// First instruction position that is not reachable by the branch using a
// positive branch offset.
ptrdiff_t first_unreacheable_pc_;
// Offset of the branch in the code generation buffer.
ptrdiff_t pc_offset_;
// The label branched to.
Label* label_;
ImmBranchType branch_type_;
};
bool BranchTypeUsesVeneers(ImmBranchType type) {
return (type != UnknownBranchType) && (type != UncondBranchType);
}
void RegisterUnresolvedBranch(ptrdiff_t branch_pos,
Label* label,
ImmBranchType branch_type);
void DeleteUnresolvedBranchInfoForLabel(Label* label);
bool ShouldEmitVeneer(int64_t first_unreacheable_pc, size_t amount);
bool ShouldEmitVeneers(size_t amount) {
return ShouldEmitVeneer(unresolved_branches_.GetFirstLimit(), amount);
}
void CheckEmitFor(size_t amount, EmitOption option = kBranchRequired);
void Emit(EmitOption option, size_t margin);
// The code size generated for a veneer. Currently one branch instruction.
// This is for code size checking purposes, and can be extended in the future
// for example if we decide to add nops between the veneers.
static const int kVeneerCodeSize = 1 * kInstructionSize;
// The maximum size of code other than veneers that can be generated when
// emitting a veneer pool. Currently there can be an additional branch to jump
// over the pool.
static const int kPoolNonVeneerCodeSize = 1 * kInstructionSize;
void UpdateNextCheckPoint() { SetNextCheckpoint(GetNextCheckPoint()); }
int GetNumberOfPotentialVeneers() const {
return static_cast<int>(unresolved_branches_.GetSize());
}
VIXL_DEPRECATED("GetNumberOfPotentialVeneers",
int NumberOfPotentialVeneers() const) {
return GetNumberOfPotentialVeneers();
}
size_t GetMaxSize() const {
return kPoolNonVeneerCodeSize +
unresolved_branches_.GetSize() * kVeneerCodeSize;
}
VIXL_DEPRECATED("GetMaxSize", size_t MaxSize() const) { return GetMaxSize(); }
size_t GetOtherPoolsMaxSize() const;
VIXL_DEPRECATED("GetOtherPoolsMaxSize", size_t OtherPoolsMaxSize() const) {
return GetOtherPoolsMaxSize();
}
static const int kNPreallocatedInfos = 4;
static const ptrdiff_t kInvalidOffset = PTRDIFF_MAX;
static const size_t kReclaimFrom = 128;
static const size_t kReclaimFactor = 16;
private:
typedef InvalSet<BranchInfo,
kNPreallocatedInfos,
ptrdiff_t,
kInvalidOffset,
kReclaimFrom,
kReclaimFactor>
BranchInfoTypedSetBase;
typedef InvalSetIterator<BranchInfoTypedSetBase> BranchInfoTypedSetIterBase;
class BranchInfoTypedSet : public BranchInfoTypedSetBase {
public:
BranchInfoTypedSet() : BranchInfoTypedSetBase() {}
ptrdiff_t GetFirstLimit() {
if (empty()) {
return kInvalidOffset;
}
return GetMinElementKey();
}
VIXL_DEPRECATED("GetFirstLimit", ptrdiff_t FirstLimit()) {
return GetFirstLimit();
}
};
class BranchInfoTypedSetIterator : public BranchInfoTypedSetIterBase {
public:
BranchInfoTypedSetIterator() : BranchInfoTypedSetIterBase(NULL) {}
explicit BranchInfoTypedSetIterator(BranchInfoTypedSet* typed_set)
: BranchInfoTypedSetIterBase(typed_set) {}
// TODO: Remove these and use the STL-like interface instead.
using BranchInfoTypedSetIterBase::Advance;
using BranchInfoTypedSetIterBase::Current;
};
class BranchInfoSet {
public:
void insert(BranchInfo branch_info) {
ImmBranchType type = branch_info.branch_type_;
VIXL_ASSERT(IsValidBranchType(type));
typed_set_[BranchIndexFromType(type)].insert(branch_info);
}
void erase(BranchInfo branch_info) {
if (IsValidBranchType(branch_info.branch_type_)) {
int index =
BranchInfoSet::BranchIndexFromType(branch_info.branch_type_);
typed_set_[index].erase(branch_info);
}
}
size_t GetSize() const {
size_t res = 0;
for (int i = 0; i < kNumberOfTrackedBranchTypes; i++) {
res += typed_set_[i].size();
}
return res;
}
VIXL_DEPRECATED("GetSize", size_t size() const) { return GetSize(); }
bool IsEmpty() const {
for (int i = 0; i < kNumberOfTrackedBranchTypes; i++) {
if (!typed_set_[i].empty()) {
return false;
}
}
return true;
}
VIXL_DEPRECATED("IsEmpty", bool empty() const) { return IsEmpty(); }
ptrdiff_t GetFirstLimit() {
ptrdiff_t res = kInvalidOffset;
for (int i = 0; i < kNumberOfTrackedBranchTypes; i++) {
res = std::min(res, typed_set_[i].GetFirstLimit());
}
return res;
}
VIXL_DEPRECATED("GetFirstLimit", ptrdiff_t FirstLimit()) {
return GetFirstLimit();
}
void Reset() {
for (int i = 0; i < kNumberOfTrackedBranchTypes; i++) {
typed_set_[i].clear();
}
}
static ImmBranchType BranchTypeFromIndex(int index) {
switch (index) {
case 0:
return CondBranchType;
case 1:
return CompareBranchType;
case 2:
return TestBranchType;
default:
VIXL_UNREACHABLE();
return UnknownBranchType;
}
}
static int BranchIndexFromType(ImmBranchType branch_type) {
switch (branch_type) {
case CondBranchType:
return 0;
case CompareBranchType:
return 1;
case TestBranchType:
return 2;
default:
VIXL_UNREACHABLE();
return 0;
}
}
bool IsValidBranchType(ImmBranchType branch_type) {
return (branch_type != UnknownBranchType) &&
(branch_type != UncondBranchType);
}
private:
static const int kNumberOfTrackedBranchTypes = 3;
BranchInfoTypedSet typed_set_[kNumberOfTrackedBranchTypes];
friend class VeneerPool;
friend class BranchInfoSetIterator;
};
class BranchInfoSetIterator {
public:
explicit BranchInfoSetIterator(BranchInfoSet* set) : set_(set) {
for (int i = 0; i < BranchInfoSet::kNumberOfTrackedBranchTypes; i++) {
new (&sub_iterator_[i])
BranchInfoTypedSetIterator(&(set_->typed_set_[i]));
}
}
VeneerPool::BranchInfo* Current() {
for (int i = 0; i < BranchInfoSet::kNumberOfTrackedBranchTypes; i++) {
if (!sub_iterator_[i].Done()) {
return sub_iterator_[i].Current();
}
}
VIXL_UNREACHABLE();
return NULL;
}
void Advance() {
VIXL_ASSERT(!Done());
for (int i = 0; i < BranchInfoSet::kNumberOfTrackedBranchTypes; i++) {
if (!sub_iterator_[i].Done()) {
sub_iterator_[i].Advance();
return;
}
}
VIXL_UNREACHABLE();
}
bool Done() const {
for (int i = 0; i < BranchInfoSet::kNumberOfTrackedBranchTypes; i++) {
if (!sub_iterator_[i].Done()) return false;
}
return true;
}
void AdvanceToNextType() {
VIXL_ASSERT(!Done());
for (int i = 0; i < BranchInfoSet::kNumberOfTrackedBranchTypes; i++) {
if (!sub_iterator_[i].Done()) {
sub_iterator_[i].Finish();
return;
}
}
VIXL_UNREACHABLE();
}
void DeleteCurrentAndAdvance() {
for (int i = 0; i < BranchInfoSet::kNumberOfTrackedBranchTypes; i++) {
if (!sub_iterator_[i].Done()) {
sub_iterator_[i].DeleteCurrentAndAdvance();
return;
}
}
}
private:
BranchInfoSet* set_;
BranchInfoTypedSetIterator
sub_iterator_[BranchInfoSet::kNumberOfTrackedBranchTypes];
};
ptrdiff_t GetNextCheckPoint() {
if (unresolved_branches_.IsEmpty()) {
return kNoCheckpointRequired;
} else {
return unresolved_branches_.GetFirstLimit();
}
}
VIXL_DEPRECATED("GetNextCheckPoint", ptrdiff_t NextCheckPoint()) {
return GetNextCheckPoint();
}
// Information about unresolved (forward) branches.
BranchInfoSet unresolved_branches_;
};
// Helper for common Emission checks.
// The macro-instruction maps to a single instruction.
class SingleEmissionCheckScope : public EmissionCheckScope {
public:
explicit SingleEmissionCheckScope(MacroAssemblerInterface* masm)
: EmissionCheckScope(masm, kInstructionSize) {}
};
// The macro instruction is a "typical" macro-instruction. Typical macro-
// instruction only emit a few instructions, a few being defined as 8 here.
class MacroEmissionCheckScope : public EmissionCheckScope {
public:
explicit MacroEmissionCheckScope(MacroAssemblerInterface* masm)
: EmissionCheckScope(masm, kTypicalMacroInstructionMaxSize) {}
private:
static const size_t kTypicalMacroInstructionMaxSize = 8 * kInstructionSize;
};
enum BranchType {
// Copies of architectural conditions.
// The associated conditions can be used in place of those, the code will
// take care of reinterpreting them with the correct type.
integer_eq = eq,
integer_ne = ne,
integer_hs = hs,
integer_lo = lo,
integer_mi = mi,
integer_pl = pl,
integer_vs = vs,
integer_vc = vc,
integer_hi = hi,
integer_ls = ls,
integer_ge = ge,
integer_lt = lt,
integer_gt = gt,
integer_le = le,
integer_al = al,
integer_nv = nv,
// These two are *different* from the architectural codes al and nv.
// 'always' is used to generate unconditional branches.
// 'never' is used to not generate a branch (generally as the inverse
// branch type of 'always).
always,
never,
// cbz and cbnz
reg_zero,
reg_not_zero,
// tbz and tbnz
reg_bit_clear,
reg_bit_set,
// Aliases.
kBranchTypeFirstCondition = eq,
kBranchTypeLastCondition = nv,
kBranchTypeFirstUsingReg = reg_zero,
kBranchTypeFirstUsingBit = reg_bit_clear
};
enum DiscardMoveMode { kDontDiscardForSameWReg, kDiscardForSameWReg };
// The macro assembler supports moving automatically pre-shifted immediates for
// arithmetic and logical instructions, and then applying a post shift in the
// instruction to undo the modification, in order to reduce the code emitted for
// an operation. For example:
//
// Add(x0, x0, 0x1f7de) => movz x16, 0xfbef; add x0, x0, x16, lsl #1.
//
// This optimisation can be only partially applied when the stack pointer is an
// operand or destination, so this enumeration is used to control the shift.
enum PreShiftImmMode {
kNoShift, // Don't pre-shift.
kLimitShiftForSP, // Limit pre-shift for add/sub extend use.
kAnyShift // Allow any pre-shift.
};
class MacroAssembler : public Assembler, public MacroAssemblerInterface {
public:
explicit MacroAssembler(
PositionIndependentCodeOption pic = PositionIndependentCode);
MacroAssembler(size_t capacity,
PositionIndependentCodeOption pic = PositionIndependentCode);
MacroAssembler(byte* buffer,
size_t capacity,
PositionIndependentCodeOption pic = PositionIndependentCode);
~MacroAssembler();
enum FinalizeOption {
kFallThrough, // There may be more code to execute after calling Finalize.
kUnreachable // Anything generated after calling Finalize is unreachable.
};
virtual vixl::internal::AssemblerBase* AsAssemblerBase() VIXL_OVERRIDE {
return this;
}
// TODO(pools): implement these functions.
virtual void EmitPoolHeader() VIXL_OVERRIDE {}
virtual void EmitPoolFooter() VIXL_OVERRIDE {}
virtual void EmitPaddingBytes(int n) VIXL_OVERRIDE { USE(n); }
virtual void EmitNopBytes(int n) VIXL_OVERRIDE { USE(n); }
// Start generating code from the beginning of the buffer, discarding any code
// and data that has already been emitted into the buffer.
//
// In order to avoid any accidental transfer of state, Reset ASSERTs that the
// constant pool is not blocked.
void Reset();
// Finalize a code buffer of generated instructions. This function must be
// called before executing or copying code from the buffer. By default,
// anything generated after this should not be reachable (the last instruction
// generated is an unconditional branch). If you need to generate more code,
// then set `option` to kFallThrough.
void FinalizeCode(FinalizeOption option = kUnreachable);
// Constant generation helpers.
// These functions return the number of instructions required to move the
// immediate into the destination register. Also, if the masm pointer is
// non-null, it generates the code to do so.
// The two features are implemented using one function to avoid duplication of
// the logic.
// The function can be used to evaluate the cost of synthesizing an
// instruction using 'mov immediate' instructions. A user might prefer loading
// a constant using the literal pool instead of using multiple 'mov immediate'
// instructions.
static int MoveImmediateHelper(MacroAssembler* masm,
const Register& rd,
uint64_t imm);
static bool OneInstrMoveImmediateHelper(MacroAssembler* masm,
const Register& dst,
int64_t imm);
// Logical macros.
void And(const Register& rd, const Register& rn, const Operand& operand);
void Ands(const Register& rd, const Register& rn, const Operand& operand);
void Bic(const Register& rd, const Register& rn, const Operand& operand);
void Bics(const Register& rd, const Register& rn, const Operand& operand);
void Orr(const Register& rd, const Register& rn, const Operand& operand);
void Orn(const Register& rd, const Register& rn, const Operand& operand);
void Eor(const Register& rd, const Register& rn, const Operand& operand);
void Eon(const Register& rd, const Register& rn, const Operand& operand);
void Tst(const Register& rn, const Operand& operand);
void LogicalMacro(const Register& rd,
const Register& rn,
const Operand& operand,
LogicalOp op);
// Add and sub macros.
void Add(const Register& rd,
const Register& rn,
const Operand& operand,
FlagsUpdate S = LeaveFlags);
void Adds(const Register& rd, const Register& rn, const Operand& operand);
void Sub(const Register& rd,
const Register& rn,
const Operand& operand,
FlagsUpdate S = LeaveFlags);
void Subs(const Register& rd, const Register& rn, const Operand& operand);
void Cmn(const Register& rn, const Operand& operand);
void Cmp(const Register& rn, const Operand& operand);
void Neg(const Register& rd, const Operand& operand);
void Negs(const Register& rd, const Operand& operand);
void AddSubMacro(const Register& rd,
const Register& rn,
const Operand& operand,
FlagsUpdate S,
AddSubOp op);
// Add/sub with carry macros.
void Adc(const Register& rd, const Register& rn, const Operand& operand);
void Adcs(const Register& rd, const Register& rn, const Operand& operand);
void Sbc(const Register& rd, const Register& rn, const Operand& operand);
void Sbcs(const Register& rd, const Register& rn, const Operand& operand);
void Ngc(const Register& rd, const Operand& operand);
void Ngcs(const Register& rd, const Operand& operand);
void AddSubWithCarryMacro(const Register& rd,
const Register& rn,
const Operand& operand,
FlagsUpdate S,
AddSubWithCarryOp op);
// Move macros.
void Mov(const Register& rd, uint64_t imm);
void Mov(const Register& rd,
const Operand& operand,
DiscardMoveMode discard_mode = kDontDiscardForSameWReg);
void Mvn(const Register& rd, uint64_t imm) {
Mov(rd, (rd.GetSizeInBits() == kXRegSize) ? ~imm : (~imm & kWRegMask));
}
void Mvn(const Register& rd, const Operand& operand);
// Try to move an immediate into the destination register in a single
// instruction. Returns true for success, and updates the contents of dst.
// Returns false, otherwise.
bool TryOneInstrMoveImmediate(const Register& dst, int64_t imm);
// Move an immediate into register dst, and return an Operand object for
// use with a subsequent instruction that accepts a shift. The value moved
// into dst is not necessarily equal to imm; it may have had a shifting
// operation applied to it that will be subsequently undone by the shift
// applied in the Operand.
Operand MoveImmediateForShiftedOp(const Register& dst,
int64_t imm,
PreShiftImmMode mode);
void Move(const GenericOperand& dst, const GenericOperand& src);
// Synthesises the address represented by a MemOperand into a register.
void ComputeAddress(const Register& dst, const MemOperand& mem_op);
// Conditional macros.
void Ccmp(const Register& rn,
const Operand& operand,
StatusFlags nzcv,
Condition cond);
void Ccmn(const Register& rn,
const Operand& operand,
StatusFlags nzcv,
Condition cond);
void ConditionalCompareMacro(const Register& rn,
const Operand& operand,
StatusFlags nzcv,
Condition cond,
ConditionalCompareOp op);
// On return, the boolean values pointed to will indicate whether `left` and
// `right` should be synthesised in a temporary register.
static void GetCselSynthesisInformation(const Register& rd,
const Operand& left,
const Operand& right,
bool* should_synthesise_left,
bool* should_synthesise_right) {
// Note that the helper does not need to look at the condition.
CselHelper(NULL,
rd,
left,
right,
eq,
should_synthesise_left,
should_synthesise_right);
}
void Csel(const Register& rd,
const Operand& left,
const Operand& right,
Condition cond) {
CselHelper(this, rd, left, right, cond);
}
// Load/store macros.
#define DECLARE_FUNCTION(FN, REGTYPE, REG, OP) \
void FN(const REGTYPE REG, const MemOperand& addr);
LS_MACRO_LIST(DECLARE_FUNCTION)
#undef DECLARE_FUNCTION
void LoadStoreMacro(const CPURegister& rt,
const MemOperand& addr,
LoadStoreOp op);
#define DECLARE_FUNCTION(FN, REGTYPE, REG, REG2, OP) \
void FN(const REGTYPE REG, const REGTYPE REG2, const MemOperand& addr);
LSPAIR_MACRO_LIST(DECLARE_FUNCTION)
#undef DECLARE_FUNCTION
void LoadStorePairMacro(const CPURegister& rt,
const CPURegister& rt2,
const MemOperand& addr,
LoadStorePairOp op);
void Prfm(PrefetchOperation op, const MemOperand& addr);
// Push or pop up to 4 registers of the same width to or from the stack,
// using the current stack pointer as set by SetStackPointer.
//
// If an argument register is 'NoReg', all further arguments are also assumed
// to be 'NoReg', and are thus not pushed or popped.
//
// Arguments are ordered such that "Push(a, b);" is functionally equivalent
// to "Push(a); Push(b);".
//
// It is valid to push the same register more than once, and there is no
// restriction on the order in which registers are specified.
//
// It is not valid to pop into the same register more than once in one
// operation, not even into the zero register.
//
// If the current stack pointer (as set by SetStackPointer) is sp, then it
// must be aligned to 16 bytes on entry and the total size of the specified
// registers must also be a multiple of 16 bytes.
//
// Even if the current stack pointer is not the system stack pointer (sp),
// Push (and derived methods) will still modify the system stack pointer in
// order to comply with ABI rules about accessing memory below the system
// stack pointer.
//
// Other than the registers passed into Pop, the stack pointer and (possibly)
// the system stack pointer, these methods do not modify any other registers.
void Push(const CPURegister& src0,
const CPURegister& src1 = NoReg,
const CPURegister& src2 = NoReg,
const CPURegister& src3 = NoReg);
void Pop(const CPURegister& dst0,
const CPURegister& dst1 = NoReg,
const CPURegister& dst2 = NoReg,
const CPURegister& dst3 = NoReg);
// Alternative forms of Push and Pop, taking a RegList or CPURegList that
// specifies the registers that are to be pushed or popped. Higher-numbered
// registers are associated with higher memory addresses (as in the A32 push
// and pop instructions).
//
// (Push|Pop)SizeRegList allow you to specify the register size as a
// parameter. Only kXRegSize, kWRegSize, kDRegSize and kSRegSize are
// supported.
//
// Otherwise, (Push|Pop)(CPU|X|W|D|S)RegList is preferred.
void PushCPURegList(CPURegList registers);
void PopCPURegList(CPURegList registers);
void PushSizeRegList(
RegList registers,
unsigned reg_size,
CPURegister::RegisterType type = CPURegister::kRegister) {
PushCPURegList(CPURegList(type, reg_size, registers));
}
void PopSizeRegList(RegList registers,
unsigned reg_size,
CPURegister::RegisterType type = CPURegister::kRegister) {
PopCPURegList(CPURegList(type, reg_size, registers));
}
void PushXRegList(RegList regs) { PushSizeRegList(regs, kXRegSize); }
void PopXRegList(RegList regs) { PopSizeRegList(regs, kXRegSize); }
void PushWRegList(RegList regs) { PushSizeRegList(regs, kWRegSize); }
void PopWRegList(RegList regs) { PopSizeRegList(regs, kWRegSize); }
void PushDRegList(RegList regs) {
PushSizeRegList(regs, kDRegSize, CPURegister::kVRegister);
}
void PopDRegList(RegList regs) {
PopSizeRegList(regs, kDRegSize, CPURegister::kVRegister);
}
void PushSRegList(RegList regs) {
PushSizeRegList(regs, kSRegSize, CPURegister::kVRegister);
}
void PopSRegList(RegList regs) {
PopSizeRegList(regs, kSRegSize, CPURegister::kVRegister);
}
// Push the specified register 'count' times.
void PushMultipleTimes(int count, Register src);
// Poke 'src' onto the stack. The offset is in bytes.
//
// If the current stack pointer (as set by SetStackPointer) is sp, then sp
// must be aligned to 16 bytes.
void Poke(const Register& src, const Operand& offset);
// Peek at a value on the stack, and put it in 'dst'. The offset is in bytes.
//
// If the current stack pointer (as set by SetStackPointer) is sp, then sp
// must be aligned to 16 bytes.
void Peek(const Register& dst, const Operand& offset);
// Alternative forms of Peek and Poke, taking a RegList or CPURegList that
// specifies the registers that are to be pushed or popped. Higher-numbered
// registers are associated with higher memory addresses.
//
// (Peek|Poke)SizeRegList allow you to specify the register size as a
// parameter. Only kXRegSize, kWRegSize, kDRegSize and kSRegSize are
// supported.
//
// Otherwise, (Peek|Poke)(CPU|X|W|D|S)RegList is preferred.
void PeekCPURegList(CPURegList registers, int64_t offset) {
LoadCPURegList(registers, MemOperand(StackPointer(), offset));
}
void PokeCPURegList(CPURegList registers, int64_t offset) {
StoreCPURegList(registers, MemOperand(StackPointer(), offset));
}
void PeekSizeRegList(
RegList registers,
int64_t offset,
unsigned reg_size,
CPURegister::RegisterType type = CPURegister::kRegister) {
PeekCPURegList(CPURegList(type, reg_size, registers), offset);
}
void PokeSizeRegList(
RegList registers,
int64_t offset,
unsigned reg_size,
CPURegister::RegisterType type = CPURegister::kRegister) {
PokeCPURegList(CPURegList(type, reg_size, registers), offset);
}
void PeekXRegList(RegList regs, int64_t offset) {
PeekSizeRegList(regs, offset, kXRegSize);
}
void PokeXRegList(RegList regs, int64_t offset) {
PokeSizeRegList(regs, offset, kXRegSize);
}
void PeekWRegList(RegList regs, int64_t offset) {
PeekSizeRegList(regs, offset, kWRegSize);
}
void PokeWRegList(RegList regs, int64_t offset) {
PokeSizeRegList(regs, offset, kWRegSize);
}
void PeekDRegList(RegList regs, int64_t offset) {
PeekSizeRegList(regs, offset, kDRegSize, CPURegister::kVRegister);
}
void PokeDRegList(RegList regs, int64_t offset) {
PokeSizeRegList(regs, offset, kDRegSize, CPURegister::kVRegister);
}
void PeekSRegList(RegList regs, int64_t offset) {
PeekSizeRegList(regs, offset, kSRegSize, CPURegister::kVRegister);
}
void PokeSRegList(RegList regs, int64_t offset) {
PokeSizeRegList(regs, offset, kSRegSize, CPURegister::kVRegister);
}
// Claim or drop stack space without actually accessing memory.
//
// If the current stack pointer (as set by SetStackPointer) is sp, then it
// must be aligned to 16 bytes and the size claimed or dropped must be a
// multiple of 16 bytes.
void Claim(const Operand& size);
void Drop(const Operand& size);
// Preserve the callee-saved registers (as defined by AAPCS64).
//
// Higher-numbered registers are pushed before lower-numbered registers, and
// thus get higher addresses.
// Floating-point registers are pushed before general-purpose registers, and
// thus get higher addresses.
//
// This method must not be called unless StackPointer() is sp, and it is
// aligned to 16 bytes.
void PushCalleeSavedRegisters();
// Restore the callee-saved registers (as defined by AAPCS64).
//
// Higher-numbered registers are popped after lower-numbered registers, and
// thus come from higher addresses.
// Floating-point registers are popped after general-purpose registers, and
// thus come from higher addresses.
//
// This method must not be called unless StackPointer() is sp, and it is
// aligned to 16 bytes.
void PopCalleeSavedRegisters();
void LoadCPURegList(CPURegList registers, const MemOperand& src);
void StoreCPURegList(CPURegList registers, const MemOperand& dst);
// Remaining instructions are simple pass-through calls to the assembler.
void Adr(const Register& rd, Label* label) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
adr(rd, label);
}
void Adrp(const Register& rd, Label* label) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
adrp(rd, label);
}
void Asr(const Register& rd, const Register& rn, unsigned shift) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
asr(rd, rn, shift);
}
void Asr(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
asrv(rd, rn, rm);
}
// Branch type inversion relies on these relations.
VIXL_STATIC_ASSERT((reg_zero == (reg_not_zero ^ 1)) &&
(reg_bit_clear == (reg_bit_set ^ 1)) &&
(always == (never ^ 1)));
BranchType InvertBranchType(BranchType type) {
if (kBranchTypeFirstCondition <= type && type <= kBranchTypeLastCondition) {
return static_cast<BranchType>(
InvertCondition(static_cast<Condition>(type)));
} else {
return static_cast<BranchType>(type ^ 1);
}
}
void B(Label* label, BranchType type, Register reg = NoReg, int bit = -1);
void B(Label* label);
void B(Label* label, Condition cond);
void B(Condition cond, Label* label) { B(label, cond); }
void Bfm(const Register& rd,
const Register& rn,
unsigned immr,
unsigned imms) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
bfm(rd, rn, immr, imms);
}
void Bfi(const Register& rd,
const Register& rn,
unsigned lsb,
unsigned width) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
bfi(rd, rn, lsb, width);
}
void Bfxil(const Register& rd,
const Register& rn,
unsigned lsb,
unsigned width) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
bfxil(rd, rn, lsb, width);
}
void Bind(Label* label);
// Bind a label to a specified offset from the start of the buffer.
void BindToOffset(Label* label, ptrdiff_t offset);
void Bl(Label* label) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
bl(label);
}
void Blr(const Register& xn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!xn.IsZero());
SingleEmissionCheckScope guard(this);
blr(xn);
}
void Br(const Register& xn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!xn.IsZero());
SingleEmissionCheckScope guard(this);
br(xn);
}
void Brk(int code = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
brk(code);
}
void Cbnz(const Register& rt, Label* label);
void Cbz(const Register& rt, Label* label);
void Cinc(const Register& rd, const Register& rn, Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
cinc(rd, rn, cond);
}
void Cinv(const Register& rd, const Register& rn, Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
cinv(rd, rn, cond);
}
void Clrex() {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
clrex();
}
void Cls(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
cls(rd, rn);
}
void Clz(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
clz(rd, rn);
}
void Cneg(const Register& rd, const Register& rn, Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
cneg(rd, rn, cond);
}
void Cset(const Register& rd, Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
cset(rd, cond);
}
void Csetm(const Register& rd, Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
csetm(rd, cond);
}
void Csinc(const Register& rd,
const Register& rn,
const Register& rm,
Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT((cond != al) && (cond != nv));
SingleEmissionCheckScope guard(this);
csinc(rd, rn, rm, cond);
}
void Csinv(const Register& rd,
const Register& rn,
const Register& rm,
Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT((cond != al) && (cond != nv));
SingleEmissionCheckScope guard(this);
csinv(rd, rn, rm, cond);
}
void Csneg(const Register& rd,
const Register& rn,
const Register& rm,
Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT((cond != al) && (cond != nv));
SingleEmissionCheckScope guard(this);
csneg(rd, rn, rm, cond);
}
void Dmb(BarrierDomain domain, BarrierType type) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
dmb(domain, type);
}
void Dsb(BarrierDomain domain, BarrierType type) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
dsb(domain, type);
}
void Extr(const Register& rd,
const Register& rn,
const Register& rm,
unsigned lsb) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
extr(rd, rn, rm, lsb);
}
void Fadd(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fadd(vd, vn, vm);
}
void Fccmp(const VRegister& vn,
const VRegister& vm,
StatusFlags nzcv,
Condition cond,
FPTrapFlags trap = DisableTrap) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT((cond != al) && (cond != nv));
SingleEmissionCheckScope guard(this);
FPCCompareMacro(vn, vm, nzcv, cond, trap);
}
void Fccmpe(const VRegister& vn,
const VRegister& vm,
StatusFlags nzcv,
Condition cond) {
Fccmp(vn, vm, nzcv, cond, EnableTrap);
}
void Fcmp(const VRegister& vn,
const VRegister& vm,
FPTrapFlags trap = DisableTrap) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
FPCompareMacro(vn, vm, trap);
}
void Fcmp(const VRegister& vn, double value, FPTrapFlags trap = DisableTrap);
void Fcmpe(const VRegister& vn, double value);
void Fcmpe(const VRegister& vn, const VRegister& vm) {
Fcmp(vn, vm, EnableTrap);
}
void Fcsel(const VRegister& vd,
const VRegister& vn,
const VRegister& vm,
Condition cond) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT((cond != al) && (cond != nv));
SingleEmissionCheckScope guard(this);
fcsel(vd, vn, vm, cond);
}
void Fcvt(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvt(vd, vn);
}
void Fcvtl(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtl(vd, vn);
}
void Fcvtl2(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtl2(vd, vn);
}
void Fcvtn(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtn(vd, vn);
}
void Fcvtn2(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtn2(vd, vn);
}
void Fcvtxn(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtxn(vd, vn);
}
void Fcvtxn2(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtxn2(vd, vn);
}
void Fcvtas(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtas(rd, vn);
}
void Fcvtau(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtau(rd, vn);
}
void Fcvtms(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtms(rd, vn);
}
void Fcvtmu(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtmu(rd, vn);
}
void Fcvtns(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtns(rd, vn);
}
void Fcvtnu(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtnu(rd, vn);
}
void Fcvtps(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtps(rd, vn);
}
void Fcvtpu(const Register& rd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtpu(rd, vn);
}
void Fcvtzs(const Register& rd, const VRegister& vn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtzs(rd, vn, fbits);
}
void Fcvtzu(const Register& rd, const VRegister& vn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fcvtzu(rd, vn, fbits);
}
void Fdiv(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fdiv(vd, vn, vm);
}
void Fmax(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmax(vd, vn, vm);
}
void Fmaxnm(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmaxnm(vd, vn, vm);
}
void Fmin(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmin(vd, vn, vm);
}
void Fminnm(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fminnm(vd, vn, vm);
}
void Fmov(const VRegister& vd, const VRegister& vn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
// Only emit an instruction if vd and vn are different, and they are both D
// registers. fmov(s0, s0) is not a no-op because it clears the top word of
// d0. Technically, fmov(d0, d0) is not a no-op either because it clears
// the top of q0, but VRegister does not currently support Q registers.
if (!vd.Is(vn) || !vd.Is64Bits()) {
fmov(vd, vn);
}
}
void Fmov(const VRegister& vd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
fmov(vd, rn);
}
void Fmov(const VRegister& vd, const XRegister& xn) {
Fmov(vd, Register(xn));
}
void Fmov(const VRegister& vd, const WRegister& wn) {
Fmov(vd, Register(wn));
}
void Fmov(const VRegister& vd, int index, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmov(vd, index, rn);
}
void Fmov(const Register& rd, const VRegister& vn, int index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmov(rd, vn, index);
}
// Provide explicit double and float interfaces for FP immediate moves, rather
// than relying on implicit C++ casts. This allows signalling NaNs to be
// preserved when the immediate matches the format of vd. Most systems convert
// signalling NaNs to quiet NaNs when converting between float and double.
void Fmov(VRegister vd, double imm);
void Fmov(VRegister vd, float imm);
// Provide a template to allow other types to be converted automatically.
template <typename T>
void Fmov(VRegister vd, T imm) {
VIXL_ASSERT(allow_macro_instructions_);
Fmov(vd, static_cast<double>(imm));
}
void Fmov(Register rd, VRegister vn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
fmov(rd, vn);
}
void Fmul(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmul(vd, vn, vm);
}
void Fnmul(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fnmul(vd, vn, vm);
}
void Fmadd(const VRegister& vd,
const VRegister& vn,
const VRegister& vm,
const VRegister& va) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmadd(vd, vn, vm, va);
}
void Fmsub(const VRegister& vd,
const VRegister& vn,
const VRegister& vm,
const VRegister& va) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fmsub(vd, vn, vm, va);
}
void Fnmadd(const VRegister& vd,
const VRegister& vn,
const VRegister& vm,
const VRegister& va) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fnmadd(vd, vn, vm, va);
}
void Fnmsub(const VRegister& vd,
const VRegister& vn,
const VRegister& vm,
const VRegister& va) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fnmsub(vd, vn, vm, va);
}
void Fsub(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fsub(vd, vn, vm);
}
void Hint(SystemHint code) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
hint(code);
}
void Hlt(int code) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
hlt(code);
}
void Isb() {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
isb();
}
void Ldar(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldar(rt, src);
}
void Ldarb(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldarb(rt, src);
}
void Ldarh(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldarh(rt, src);
}
void Ldaxp(const Register& rt, const Register& rt2, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rt.Aliases(rt2));
SingleEmissionCheckScope guard(this);
ldaxp(rt, rt2, src);
}
void Ldaxr(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldaxr(rt, src);
}
void Ldaxrb(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldaxrb(rt, src);
}
void Ldaxrh(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldaxrh(rt, src);
}
void Ldnp(const CPURegister& rt,
const CPURegister& rt2,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldnp(rt, rt2, src);
}
// Provide both double and float interfaces for FP immediate loads, rather
// than relying on implicit C++ casts. This allows signalling NaNs to be
// preserved when the immediate matches the format of fd. Most systems convert
// signalling NaNs to quiet NaNs when converting between float and double.
void Ldr(const VRegister& vt, double imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
RawLiteral* literal;
if (vt.IsD()) {
literal = new Literal<double>(imm,
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool);
} else {
literal = new Literal<float>(static_cast<float>(imm),
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool);
}
ldr(vt, literal);
}
void Ldr(const VRegister& vt, float imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
RawLiteral* literal;
if (vt.IsS()) {
literal = new Literal<float>(imm,
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool);
} else {
literal = new Literal<double>(static_cast<double>(imm),
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool);
}
ldr(vt, literal);
}
void Ldr(const VRegister& vt, uint64_t high64, uint64_t low64) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(vt.IsQ());
SingleEmissionCheckScope guard(this);
ldr(vt,
new Literal<uint64_t>(high64,
low64,
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool));
}
void Ldr(const Register& rt, uint64_t imm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rt.IsZero());
SingleEmissionCheckScope guard(this);
RawLiteral* literal;
if (rt.Is64Bits()) {
literal = new Literal<uint64_t>(imm,
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool);
} else {
VIXL_ASSERT(rt.Is32Bits());
VIXL_ASSERT(IsUint32(imm) || IsInt32(imm));
literal = new Literal<uint32_t>(static_cast<uint32_t>(imm),
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool);
}
ldr(rt, literal);
}
void Ldrsw(const Register& rt, uint32_t imm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rt.IsZero());
SingleEmissionCheckScope guard(this);
ldrsw(rt,
new Literal<uint32_t>(imm,
&literal_pool_,
RawLiteral::kDeletedOnPlacementByPool));
}
void Ldr(const CPURegister& rt, RawLiteral* literal) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldr(rt, literal);
}
void Ldrsw(const Register& rt, RawLiteral* literal) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldrsw(rt, literal);
}
void Ldxp(const Register& rt, const Register& rt2, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rt.Aliases(rt2));
SingleEmissionCheckScope guard(this);
ldxp(rt, rt2, src);
}
void Ldxr(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldxr(rt, src);
}
void Ldxrb(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldxrb(rt, src);
}
void Ldxrh(const Register& rt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ldxrh(rt, src);
}
void Lsl(const Register& rd, const Register& rn, unsigned shift) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
lsl(rd, rn, shift);
}
void Lsl(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
lslv(rd, rn, rm);
}
void Lsr(const Register& rd, const Register& rn, unsigned shift) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
lsr(rd, rn, shift);
}
void Lsr(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
lsrv(rd, rn, rm);
}
void Madd(const Register& rd,
const Register& rn,
const Register& rm,
const Register& ra) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT(!ra.IsZero());
SingleEmissionCheckScope guard(this);
madd(rd, rn, rm, ra);
}
void Mneg(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
mneg(rd, rn, rm);
}
void Mov(const Register& rd,
const Register& rn,
DiscardMoveMode discard_mode = kDontDiscardForSameWReg) {
VIXL_ASSERT(allow_macro_instructions_);
// Emit a register move only if the registers are distinct, or if they are
// not X registers.
//
// Note that mov(w0, w0) is not a no-op because it clears the top word of
// x0. A flag is provided (kDiscardForSameWReg) if a move between the same W
// registers is not required to clear the top word of the X register. In
// this case, the instruction is discarded.
//
// If the sp is an operand, add #0 is emitted, otherwise, orr #0.
if (!rd.Is(rn) ||
(rd.Is32Bits() && (discard_mode == kDontDiscardForSameWReg))) {
SingleEmissionCheckScope guard(this);
mov(rd, rn);
}
}
void Movk(const Register& rd, uint64_t imm, int shift = -1) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
SingleEmissionCheckScope guard(this);
movk(rd, imm, shift);
}
void Mrs(const Register& rt, SystemRegister sysreg) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rt.IsZero());
SingleEmissionCheckScope guard(this);
mrs(rt, sysreg);
}
void Msr(SystemRegister sysreg, const Register& rt) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rt.IsZero());
SingleEmissionCheckScope guard(this);
msr(sysreg, rt);
}
void Sys(int op1, int crn, int crm, int op2, const Register& rt = xzr) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
sys(op1, crn, crm, op2, rt);
}
void Dc(DataCacheOp op, const Register& rt) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
dc(op, rt);
}
void Ic(InstructionCacheOp op, const Register& rt) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ic(op, rt);
}
void Msub(const Register& rd,
const Register& rn,
const Register& rm,
const Register& ra) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT(!ra.IsZero());
SingleEmissionCheckScope guard(this);
msub(rd, rn, rm, ra);
}
void Mul(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
mul(rd, rn, rm);
}
void Nop() {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
nop();
}
void Rbit(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
rbit(rd, rn);
}
void Ret(const Register& xn = lr) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!xn.IsZero());
SingleEmissionCheckScope guard(this);
ret(xn);
}
void Rev(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
rev(rd, rn);
}
void Rev16(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
rev16(rd, rn);
}
void Rev32(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
rev32(rd, rn);
}
void Ror(const Register& rd, const Register& rs, unsigned shift) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rs.IsZero());
SingleEmissionCheckScope guard(this);
ror(rd, rs, shift);
}
void Ror(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
rorv(rd, rn, rm);
}
void Sbfiz(const Register& rd,
const Register& rn,
unsigned lsb,
unsigned width) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
sbfiz(rd, rn, lsb, width);
}
void Sbfm(const Register& rd,
const Register& rn,
unsigned immr,
unsigned imms) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
sbfm(rd, rn, immr, imms);
}
void Sbfx(const Register& rd,
const Register& rn,
unsigned lsb,
unsigned width) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
sbfx(rd, rn, lsb, width);
}
void Scvtf(const VRegister& vd, const Register& rn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
scvtf(vd, rn, fbits);
}
void Sdiv(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
sdiv(rd, rn, rm);
}
void Smaddl(const Register& rd,
const Register& rn,
const Register& rm,
const Register& ra) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT(!ra.IsZero());
SingleEmissionCheckScope guard(this);
smaddl(rd, rn, rm, ra);
}
void Smsubl(const Register& rd,
const Register& rn,
const Register& rm,
const Register& ra) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT(!ra.IsZero());
SingleEmissionCheckScope guard(this);
smsubl(rd, rn, rm, ra);
}
void Smull(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
smull(rd, rn, rm);
}
void Smulh(const Register& xd, const Register& xn, const Register& xm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!xd.IsZero());
VIXL_ASSERT(!xn.IsZero());
VIXL_ASSERT(!xm.IsZero());
SingleEmissionCheckScope guard(this);
smulh(xd, xn, xm);
}
void Stlr(const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
stlr(rt, dst);
}
void Stlrb(const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
stlrb(rt, dst);
}
void Stlrh(const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
stlrh(rt, dst);
}
void Stlxp(const Register& rs,
const Register& rt,
const Register& rt2,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
VIXL_ASSERT(!rs.Aliases(rt2));
SingleEmissionCheckScope guard(this);
stlxp(rs, rt, rt2, dst);
}
void Stlxr(const Register& rs, const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
SingleEmissionCheckScope guard(this);
stlxr(rs, rt, dst);
}
void Stlxrb(const Register& rs, const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
SingleEmissionCheckScope guard(this);
stlxrb(rs, rt, dst);
}
void Stlxrh(const Register& rs, const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
SingleEmissionCheckScope guard(this);
stlxrh(rs, rt, dst);
}
void Stnp(const CPURegister& rt,
const CPURegister& rt2,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
stnp(rt, rt2, dst);
}
void Stxp(const Register& rs,
const Register& rt,
const Register& rt2,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
VIXL_ASSERT(!rs.Aliases(rt2));
SingleEmissionCheckScope guard(this);
stxp(rs, rt, rt2, dst);
}
void Stxr(const Register& rs, const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
SingleEmissionCheckScope guard(this);
stxr(rs, rt, dst);
}
void Stxrb(const Register& rs, const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
SingleEmissionCheckScope guard(this);
stxrb(rs, rt, dst);
}
void Stxrh(const Register& rs, const Register& rt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rs.Aliases(dst.GetBaseRegister()));
VIXL_ASSERT(!rs.Aliases(rt));
SingleEmissionCheckScope guard(this);
stxrh(rs, rt, dst);
}
void Svc(int code) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
svc(code);
}
void Sxtb(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
sxtb(rd, rn);
}
void Sxth(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
sxth(rd, rn);
}
void Sxtw(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
sxtw(rd, rn);
}
void Tbl(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbl(vd, vn, vm);
}
void Tbl(const VRegister& vd,
const VRegister& vn,
const VRegister& vn2,
const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbl(vd, vn, vn2, vm);
}
void Tbl(const VRegister& vd,
const VRegister& vn,
const VRegister& vn2,
const VRegister& vn3,
const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbl(vd, vn, vn2, vn3, vm);
}
void Tbl(const VRegister& vd,
const VRegister& vn,
const VRegister& vn2,
const VRegister& vn3,
const VRegister& vn4,
const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbl(vd, vn, vn2, vn3, vn4, vm);
}
void Tbx(const VRegister& vd, const VRegister& vn, const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbx(vd, vn, vm);
}
void Tbx(const VRegister& vd,
const VRegister& vn,
const VRegister& vn2,
const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbx(vd, vn, vn2, vm);
}
void Tbx(const VRegister& vd,
const VRegister& vn,
const VRegister& vn2,
const VRegister& vn3,
const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbx(vd, vn, vn2, vn3, vm);
}
void Tbx(const VRegister& vd,
const VRegister& vn,
const VRegister& vn2,
const VRegister& vn3,
const VRegister& vn4,
const VRegister& vm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
tbx(vd, vn, vn2, vn3, vn4, vm);
}
void Tbnz(const Register& rt, unsigned bit_pos, Label* label);
void Tbz(const Register& rt, unsigned bit_pos, Label* label);
void Ubfiz(const Register& rd,
const Register& rn,
unsigned lsb,
unsigned width) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
ubfiz(rd, rn, lsb, width);
}
void Ubfm(const Register& rd,
const Register& rn,
unsigned immr,
unsigned imms) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
ubfm(rd, rn, immr, imms);
}
void Ubfx(const Register& rd,
const Register& rn,
unsigned lsb,
unsigned width) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
ubfx(rd, rn, lsb, width);
}
void Ucvtf(const VRegister& vd, const Register& rn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
ucvtf(vd, rn, fbits);
}
void Udiv(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
udiv(rd, rn, rm);
}
void Umaddl(const Register& rd,
const Register& rn,
const Register& rm,
const Register& ra) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT(!ra.IsZero());
SingleEmissionCheckScope guard(this);
umaddl(rd, rn, rm, ra);
}
void Umull(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
SingleEmissionCheckScope guard(this);
umull(rd, rn, rm);
}
void Umulh(const Register& xd, const Register& xn, const Register& xm) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!xd.IsZero());
VIXL_ASSERT(!xn.IsZero());
VIXL_ASSERT(!xm.IsZero());
SingleEmissionCheckScope guard(this);
umulh(xd, xn, xm);
}
void Umsubl(const Register& rd,
const Register& rn,
const Register& rm,
const Register& ra) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
VIXL_ASSERT(!rm.IsZero());
VIXL_ASSERT(!ra.IsZero());
SingleEmissionCheckScope guard(this);
umsubl(rd, rn, rm, ra);
}
void Unreachable() {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
if (generate_simulator_code_) {
hlt(kUnreachableOpcode);
} else {
// Branch to 0 to generate a segfault.
// lr - kInstructionSize is the address of the offending instruction.
blr(xzr);
}
}
void Uxtb(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
uxtb(rd, rn);
}
void Uxth(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
uxth(rd, rn);
}
void Uxtw(const Register& rd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
VIXL_ASSERT(!rd.IsZero());
VIXL_ASSERT(!rn.IsZero());
SingleEmissionCheckScope guard(this);
uxtw(rd, rn);
}
// NEON 3 vector register instructions.
#define NEON_3VREG_MACRO_LIST(V) \
V(add, Add) \
V(addhn, Addhn) \
V(addhn2, Addhn2) \
V(addp, Addp) \
V(and_, And) \
V(bic, Bic) \
V(bif, Bif) \
V(bit, Bit) \
V(bsl, Bsl) \
V(cmeq, Cmeq) \
V(cmge, Cmge) \
V(cmgt, Cmgt) \
V(cmhi, Cmhi) \
V(cmhs, Cmhs) \
V(cmtst, Cmtst) \
V(eor, Eor) \
V(fabd, Fabd) \
V(facge, Facge) \
V(facgt, Facgt) \
V(faddp, Faddp) \
V(fcmeq, Fcmeq) \
V(fcmge, Fcmge) \
V(fcmgt, Fcmgt) \
V(fmaxnmp, Fmaxnmp) \
V(fmaxp, Fmaxp) \
V(fminnmp, Fminnmp) \
V(fminp, Fminp) \
V(fmla, Fmla) \
V(fmls, Fmls) \
V(fmulx, Fmulx) \
V(frecps, Frecps) \
V(frsqrts, Frsqrts) \
V(mla, Mla) \
V(mls, Mls) \
V(mul, Mul) \
V(orn, Orn) \
V(orr, Orr) \
V(pmul, Pmul) \
V(pmull, Pmull) \
V(pmull2, Pmull2) \
V(raddhn, Raddhn) \
V(raddhn2, Raddhn2) \
V(rsubhn, Rsubhn) \
V(rsubhn2, Rsubhn2) \
V(saba, Saba) \
V(sabal, Sabal) \
V(sabal2, Sabal2) \
V(sabd, Sabd) \
V(sabdl, Sabdl) \
V(sabdl2, Sabdl2) \
V(saddl, Saddl) \
V(saddl2, Saddl2) \
V(saddw, Saddw) \
V(saddw2, Saddw2) \
V(shadd, Shadd) \
V(shsub, Shsub) \
V(smax, Smax) \
V(smaxp, Smaxp) \
V(smin, Smin) \
V(sminp, Sminp) \
V(smlal, Smlal) \
V(smlal2, Smlal2) \
V(smlsl, Smlsl) \
V(smlsl2, Smlsl2) \
V(smull, Smull) \
V(smull2, Smull2) \
V(sqadd, Sqadd) \
V(sqdmlal, Sqdmlal) \
V(sqdmlal2, Sqdmlal2) \
V(sqdmlsl, Sqdmlsl) \
V(sqdmlsl2, Sqdmlsl2) \
V(sqdmulh, Sqdmulh) \
V(sqdmull, Sqdmull) \
V(sqdmull2, Sqdmull2) \
V(sqrdmulh, Sqrdmulh) \
V(sqrshl, Sqrshl) \
V(sqshl, Sqshl) \
V(sqsub, Sqsub) \
V(srhadd, Srhadd) \
V(srshl, Srshl) \
V(sshl, Sshl) \
V(ssubl, Ssubl) \
V(ssubl2, Ssubl2) \
V(ssubw, Ssubw) \
V(ssubw2, Ssubw2) \
V(sub, Sub) \
V(subhn, Subhn) \
V(subhn2, Subhn2) \
V(trn1, Trn1) \
V(trn2, Trn2) \
V(uaba, Uaba) \
V(uabal, Uabal) \
V(uabal2, Uabal2) \
V(uabd, Uabd) \
V(uabdl, Uabdl) \
V(uabdl2, Uabdl2) \
V(uaddl, Uaddl) \
V(uaddl2, Uaddl2) \
V(uaddw, Uaddw) \
V(uaddw2, Uaddw2) \
V(uhadd, Uhadd) \
V(uhsub, Uhsub) \
V(umax, Umax) \
V(umaxp, Umaxp) \
V(umin, Umin) \
V(uminp, Uminp) \
V(umlal, Umlal) \
V(umlal2, Umlal2) \
V(umlsl, Umlsl) \
V(umlsl2, Umlsl2) \
V(umull, Umull) \
V(umull2, Umull2) \
V(uqadd, Uqadd) \
V(uqrshl, Uqrshl) \
V(uqshl, Uqshl) \
V(uqsub, Uqsub) \
V(urhadd, Urhadd) \
V(urshl, Urshl) \
V(ushl, Ushl) \
V(usubl, Usubl) \
V(usubl2, Usubl2) \
V(usubw, Usubw) \
V(usubw2, Usubw2) \
V(uzp1, Uzp1) \
V(uzp2, Uzp2) \
V(zip1, Zip1) \
V(zip2, Zip2)
#define DEFINE_MACRO_ASM_FUNC(ASM, MASM) \
void MASM(const VRegister& vd, const VRegister& vn, const VRegister& vm) { \
VIXL_ASSERT(allow_macro_instructions_); \
SingleEmissionCheckScope guard(this); \
ASM(vd, vn, vm); \
}
NEON_3VREG_MACRO_LIST(DEFINE_MACRO_ASM_FUNC)
#undef DEFINE_MACRO_ASM_FUNC
// NEON 2 vector register instructions.
#define NEON_2VREG_MACRO_LIST(V) \
V(abs, Abs) \
V(addp, Addp) \
V(addv, Addv) \
V(cls, Cls) \
V(clz, Clz) \
V(cnt, Cnt) \
V(fabs, Fabs) \
V(faddp, Faddp) \
V(fcvtas, Fcvtas) \
V(fcvtau, Fcvtau) \
V(fcvtms, Fcvtms) \
V(fcvtmu, Fcvtmu) \
V(fcvtns, Fcvtns) \
V(fcvtnu, Fcvtnu) \
V(fcvtps, Fcvtps) \
V(fcvtpu, Fcvtpu) \
V(fmaxnmp, Fmaxnmp) \
V(fmaxnmv, Fmaxnmv) \
V(fmaxp, Fmaxp) \
V(fmaxv, Fmaxv) \
V(fminnmp, Fminnmp) \
V(fminnmv, Fminnmv) \
V(fminp, Fminp) \
V(fminv, Fminv) \
V(fneg, Fneg) \
V(frecpe, Frecpe) \
V(frecpx, Frecpx) \
V(frinta, Frinta) \
V(frinti, Frinti) \
V(frintm, Frintm) \
V(frintn, Frintn) \
V(frintp, Frintp) \
V(frintx, Frintx) \
V(frintz, Frintz) \
V(frsqrte, Frsqrte) \
V(fsqrt, Fsqrt) \
V(mov, Mov) \
V(mvn, Mvn) \
V(neg, Neg) \
V(not_, Not) \
V(rbit, Rbit) \
V(rev16, Rev16) \
V(rev32, Rev32) \
V(rev64, Rev64) \
V(sadalp, Sadalp) \
V(saddlp, Saddlp) \
V(saddlv, Saddlv) \
V(smaxv, Smaxv) \
V(sminv, Sminv) \
V(sqabs, Sqabs) \
V(sqneg, Sqneg) \
V(sqxtn, Sqxtn) \
V(sqxtn2, Sqxtn2) \
V(sqxtun, Sqxtun) \
V(sqxtun2, Sqxtun2) \
V(suqadd, Suqadd) \
V(sxtl, Sxtl) \
V(sxtl2, Sxtl2) \
V(uadalp, Uadalp) \
V(uaddlp, Uaddlp) \
V(uaddlv, Uaddlv) \
V(umaxv, Umaxv) \
V(uminv, Uminv) \
V(uqxtn, Uqxtn) \
V(uqxtn2, Uqxtn2) \
V(urecpe, Urecpe) \
V(ursqrte, Ursqrte) \
V(usqadd, Usqadd) \
V(uxtl, Uxtl) \
V(uxtl2, Uxtl2) \
V(xtn, Xtn) \
V(xtn2, Xtn2)
#define DEFINE_MACRO_ASM_FUNC(ASM, MASM) \
void MASM(const VRegister& vd, const VRegister& vn) { \
VIXL_ASSERT(allow_macro_instructions_); \
SingleEmissionCheckScope guard(this); \
ASM(vd, vn); \
}
NEON_2VREG_MACRO_LIST(DEFINE_MACRO_ASM_FUNC)
#undef DEFINE_MACRO_ASM_FUNC
// NEON 2 vector register with immediate instructions.
#define NEON_2VREG_FPIMM_MACRO_LIST(V) \
V(fcmeq, Fcmeq) \
V(fcmge, Fcmge) \
V(fcmgt, Fcmgt) \
V(fcmle, Fcmle) \
V(fcmlt, Fcmlt)
#define DEFINE_MACRO_ASM_FUNC(ASM, MASM) \
void MASM(const VRegister& vd, const VRegister& vn, double imm) { \
VIXL_ASSERT(allow_macro_instructions_); \
SingleEmissionCheckScope guard(this); \
ASM(vd, vn, imm); \
}
NEON_2VREG_FPIMM_MACRO_LIST(DEFINE_MACRO_ASM_FUNC)
#undef DEFINE_MACRO_ASM_FUNC
// NEON by element instructions.
#define NEON_BYELEMENT_MACRO_LIST(V) \
V(fmul, Fmul) \
V(fmla, Fmla) \
V(fmls, Fmls) \
V(fmulx, Fmulx) \
V(mul, Mul) \
V(mla, Mla) \
V(mls, Mls) \
V(sqdmulh, Sqdmulh) \
V(sqrdmulh, Sqrdmulh) \
V(sqdmull, Sqdmull) \
V(sqdmull2, Sqdmull2) \
V(sqdmlal, Sqdmlal) \
V(sqdmlal2, Sqdmlal2) \
V(sqdmlsl, Sqdmlsl) \
V(sqdmlsl2, Sqdmlsl2) \
V(smull, Smull) \
V(smull2, Smull2) \
V(smlal, Smlal) \
V(smlal2, Smlal2) \
V(smlsl, Smlsl) \
V(smlsl2, Smlsl2) \
V(umull, Umull) \
V(umull2, Umull2) \
V(umlal, Umlal) \
V(umlal2, Umlal2) \
V(umlsl, Umlsl) \
V(umlsl2, Umlsl2)
#define DEFINE_MACRO_ASM_FUNC(ASM, MASM) \
void MASM(const VRegister& vd, \
const VRegister& vn, \
const VRegister& vm, \
int vm_index) { \
VIXL_ASSERT(allow_macro_instructions_); \
SingleEmissionCheckScope guard(this); \
ASM(vd, vn, vm, vm_index); \
}
NEON_BYELEMENT_MACRO_LIST(DEFINE_MACRO_ASM_FUNC)
#undef DEFINE_MACRO_ASM_FUNC
#define NEON_2VREG_SHIFT_MACRO_LIST(V) \
V(rshrn, Rshrn) \
V(rshrn2, Rshrn2) \
V(shl, Shl) \
V(shll, Shll) \
V(shll2, Shll2) \
V(shrn, Shrn) \
V(shrn2, Shrn2) \
V(sli, Sli) \
V(sqrshrn, Sqrshrn) \
V(sqrshrn2, Sqrshrn2) \
V(sqrshrun, Sqrshrun) \
V(sqrshrun2, Sqrshrun2) \
V(sqshl, Sqshl) \
V(sqshlu, Sqshlu) \
V(sqshrn, Sqshrn) \
V(sqshrn2, Sqshrn2) \
V(sqshrun, Sqshrun) \
V(sqshrun2, Sqshrun2) \
V(sri, Sri) \
V(srshr, Srshr) \
V(srsra, Srsra) \
V(sshll, Sshll) \
V(sshll2, Sshll2) \
V(sshr, Sshr) \
V(ssra, Ssra) \
V(uqrshrn, Uqrshrn) \
V(uqrshrn2, Uqrshrn2) \
V(uqshl, Uqshl) \
V(uqshrn, Uqshrn) \
V(uqshrn2, Uqshrn2) \
V(urshr, Urshr) \
V(ursra, Ursra) \
V(ushll, Ushll) \
V(ushll2, Ushll2) \
V(ushr, Ushr) \
V(usra, Usra)
#define DEFINE_MACRO_ASM_FUNC(ASM, MASM) \
void MASM(const VRegister& vd, const VRegister& vn, int shift) { \
VIXL_ASSERT(allow_macro_instructions_); \
SingleEmissionCheckScope guard(this); \
ASM(vd, vn, shift); \
}
NEON_2VREG_SHIFT_MACRO_LIST(DEFINE_MACRO_ASM_FUNC)
#undef DEFINE_MACRO_ASM_FUNC
void Bic(const VRegister& vd, const int imm8, const int left_shift = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
bic(vd, imm8, left_shift);
}
void Cmeq(const VRegister& vd, const VRegister& vn, int imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
cmeq(vd, vn, imm);
}
void Cmge(const VRegister& vd, const VRegister& vn, int imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
cmge(vd, vn, imm);
}
void Cmgt(const VRegister& vd, const VRegister& vn, int imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
cmgt(vd, vn, imm);
}
void Cmle(const VRegister& vd, const VRegister& vn, int imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
cmle(vd, vn, imm);
}
void Cmlt(const VRegister& vd, const VRegister& vn, int imm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
cmlt(vd, vn, imm);
}
void Dup(const VRegister& vd, const VRegister& vn, int index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
dup(vd, vn, index);
}
void Dup(const VRegister& vd, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
dup(vd, rn);
}
void Ext(const VRegister& vd,
const VRegister& vn,
const VRegister& vm,
int index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ext(vd, vn, vm, index);
}
void Ins(const VRegister& vd,
int vd_index,
const VRegister& vn,
int vn_index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ins(vd, vd_index, vn, vn_index);
}
void Ins(const VRegister& vd, int vd_index, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ins(vd, vd_index, rn);
}
void Ld1(const VRegister& vt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld1(vt, src);
}
void Ld1(const VRegister& vt, const VRegister& vt2, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld1(vt, vt2, src);
}
void Ld1(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld1(vt, vt2, vt3, src);
}
void Ld1(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld1(vt, vt2, vt3, vt4, src);
}
void Ld1(const VRegister& vt, int lane, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld1(vt, lane, src);
}
void Ld1r(const VRegister& vt, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld1r(vt, src);
}
void Ld2(const VRegister& vt, const VRegister& vt2, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld2(vt, vt2, src);
}
void Ld2(const VRegister& vt,
const VRegister& vt2,
int lane,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld2(vt, vt2, lane, src);
}
void Ld2r(const VRegister& vt, const VRegister& vt2, const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld2r(vt, vt2, src);
}
void Ld3(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld3(vt, vt2, vt3, src);
}
void Ld3(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
int lane,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld3(vt, vt2, vt3, lane, src);
}
void Ld3r(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld3r(vt, vt2, vt3, src);
}
void Ld4(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld4(vt, vt2, vt3, vt4, src);
}
void Ld4(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
int lane,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld4(vt, vt2, vt3, vt4, lane, src);
}
void Ld4r(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
const MemOperand& src) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ld4r(vt, vt2, vt3, vt4, src);
}
void Mov(const VRegister& vd,
int vd_index,
const VRegister& vn,
int vn_index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
mov(vd, vd_index, vn, vn_index);
}
void Mov(const VRegister& vd, const VRegister& vn, int index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
mov(vd, vn, index);
}
void Mov(const VRegister& vd, int vd_index, const Register& rn) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
mov(vd, vd_index, rn);
}
void Mov(const Register& rd, const VRegister& vn, int vn_index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
mov(rd, vn, vn_index);
}
void Movi(const VRegister& vd,
uint64_t imm,
Shift shift = LSL,
int shift_amount = 0);
void Movi(const VRegister& vd, uint64_t hi, uint64_t lo);
void Mvni(const VRegister& vd,
const int imm8,
Shift shift = LSL,
const int shift_amount = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
mvni(vd, imm8, shift, shift_amount);
}
void Orr(const VRegister& vd, const int imm8, const int left_shift = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
orr(vd, imm8, left_shift);
}
void Scvtf(const VRegister& vd, const VRegister& vn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
scvtf(vd, vn, fbits);
}
void Ucvtf(const VRegister& vd, const VRegister& vn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
ucvtf(vd, vn, fbits);
}
void Fcvtzs(const VRegister& vd, const VRegister& vn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtzs(vd, vn, fbits);
}
void Fcvtzu(const VRegister& vd, const VRegister& vn, int fbits = 0) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
fcvtzu(vd, vn, fbits);
}
void St1(const VRegister& vt, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st1(vt, dst);
}
void St1(const VRegister& vt, const VRegister& vt2, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st1(vt, vt2, dst);
}
void St1(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st1(vt, vt2, vt3, dst);
}
void St1(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st1(vt, vt2, vt3, vt4, dst);
}
void St1(const VRegister& vt, int lane, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st1(vt, lane, dst);
}
void St2(const VRegister& vt, const VRegister& vt2, const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st2(vt, vt2, dst);
}
void St3(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st3(vt, vt2, vt3, dst);
}
void St4(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st4(vt, vt2, vt3, vt4, dst);
}
void St2(const VRegister& vt,
const VRegister& vt2,
int lane,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st2(vt, vt2, lane, dst);
}
void St3(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
int lane,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st3(vt, vt2, vt3, lane, dst);
}
void St4(const VRegister& vt,
const VRegister& vt2,
const VRegister& vt3,
const VRegister& vt4,
int lane,
const MemOperand& dst) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
st4(vt, vt2, vt3, vt4, lane, dst);
}
void Smov(const Register& rd, const VRegister& vn, int vn_index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
smov(rd, vn, vn_index);
}
void Umov(const Register& rd, const VRegister& vn, int vn_index) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
umov(rd, vn, vn_index);
}
void Crc32b(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32b(rd, rn, rm);
}
void Crc32h(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32h(rd, rn, rm);
}
void Crc32w(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32w(rd, rn, rm);
}
void Crc32x(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32x(rd, rn, rm);
}
void Crc32cb(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32cb(rd, rn, rm);
}
void Crc32ch(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32ch(rd, rn, rm);
}
void Crc32cw(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32cw(rd, rn, rm);
}
void Crc32cx(const Register& rd, const Register& rn, const Register& rm) {
VIXL_ASSERT(allow_macro_instructions_);
SingleEmissionCheckScope guard(this);
crc32cx(rd, rn, rm);
}
template <typename T>
Literal<T>* CreateLiteralDestroyedWithPool(T value) {
return new Literal<T>(value,
&literal_pool_,
RawLiteral::kDeletedOnPoolDestruction);
}
template <typename T>
Literal<T>* CreateLiteralDestroyedWithPool(T high64, T low64) {
return new Literal<T>(high64,
low64,
&literal_pool_,
RawLiteral::kDeletedOnPoolDestruction);
}
// Push the system stack pointer (sp) down to allow the same to be done to
// the current stack pointer (according to StackPointer()). This must be
// called _before_ accessing the memory.
//
// This is necessary when pushing or otherwise adding things to the stack, to
// satisfy the AAPCS64 constraint that the memory below the system stack
// pointer is not accessed.
//
// This method asserts that StackPointer() is not sp, since the call does
// not make sense in that context.
//
// TODO: This method can only accept values of 'space' that can be encoded in
// one instruction. Refer to the implementation for details.
void BumpSystemStackPointer(const Operand& space);
virtual bool AllowMacroInstructions() const VIXL_OVERRIDE {
return allow_macro_instructions_;
}
virtual bool ArePoolsBlocked() const VIXL_OVERRIDE {
return IsLiteralPoolBlocked() && IsVeneerPoolBlocked();
}
void SetGenerateSimulatorCode(bool value) {
generate_simulator_code_ = value;
}
bool GenerateSimulatorCode() const { return generate_simulator_code_; }
size_t GetLiteralPoolSize() const { return literal_pool_.GetSize(); }
VIXL_DEPRECATED("GetLiteralPoolSize", size_t LiteralPoolSize() const) {
return GetLiteralPoolSize();
}
size_t GetLiteralPoolMaxSize() const { return literal_pool_.GetMaxSize(); }
VIXL_DEPRECATED("GetLiteralPoolMaxSize", size_t LiteralPoolMaxSize() const) {
return GetLiteralPoolMaxSize();
}
size_t GetVeneerPoolMaxSize() const { return veneer_pool_.GetMaxSize(); }
VIXL_DEPRECATED("GetVeneerPoolMaxSize", size_t VeneerPoolMaxSize() const) {
return GetVeneerPoolMaxSize();
}
// The number of unresolved branches that may require a veneer.
int GetNumberOfPotentialVeneers() const {
return veneer_pool_.GetNumberOfPotentialVeneers();
}
VIXL_DEPRECATED("GetNumberOfPotentialVeneers",
int NumberOfPotentialVeneers() const) {
return GetNumberOfPotentialVeneers();
}
ptrdiff_t GetNextCheckPoint() const {
ptrdiff_t next_checkpoint_for_pools =
std::min(literal_pool_.GetCheckpoint(), veneer_pool_.GetCheckpoint());
return std::min(next_checkpoint_for_pools,
static_cast<ptrdiff_t>(GetBuffer().GetCapacity()));
}
VIXL_DEPRECATED("GetNextCheckPoint", ptrdiff_t NextCheckPoint()) {
return GetNextCheckPoint();
}
void EmitLiteralPool(LiteralPool::EmitOption option) {
if (!literal_pool_.IsEmpty()) literal_pool_.Emit(option);
checkpoint_ = GetNextCheckPoint();
recommended_checkpoint_ = literal_pool_.GetNextRecommendedCheckpoint();
}
void CheckEmitFor(size_t amount);
void EnsureEmitFor(size_t amount) {
ptrdiff_t offset = amount;
ptrdiff_t max_pools_size =
literal_pool_.GetMaxSize() + veneer_pool_.GetMaxSize();
ptrdiff_t cursor = GetCursorOffset();
if ((cursor >= recommended_checkpoint_) ||
((cursor + offset + max_pools_size) >= checkpoint_)) {
CheckEmitFor(amount);
}
}
void CheckEmitPoolsFor(size_t amount);
virtual void EnsureEmitPoolsFor(size_t amount) VIXL_OVERRIDE {
ptrdiff_t offset = amount;
ptrdiff_t max_pools_size =
literal_pool_.GetMaxSize() + veneer_pool_.GetMaxSize();
ptrdiff_t cursor = GetCursorOffset();
if ((cursor >= recommended_checkpoint_) ||
((cursor + offset + max_pools_size) >= checkpoint_)) {
CheckEmitPoolsFor(amount);
}
}
// Set the current stack pointer, but don't generate any code.
void SetStackPointer(const Register& stack_pointer) {
VIXL_ASSERT(!GetScratchRegisterList()->IncludesAliasOf(stack_pointer));
sp_ = stack_pointer;
}
// Return the current stack pointer, as set by SetStackPointer.
const Register& StackPointer() const { return sp_; }
CPURegList* GetScratchRegisterList() { return &tmp_list_; }
VIXL_DEPRECATED("GetScratchRegisterList", CPURegList* TmpList()) {
return GetScratchRegisterList();
}
CPURegList* GetScratchFPRegisterList() { return &fptmp_list_; }
VIXL_DEPRECATED("GetScratchFPRegisterList", CPURegList* FPTmpList()) {
return GetScratchFPRegisterList();
}
// Get or set the current (most-deeply-nested) UseScratchRegisterScope.
void SetCurrentScratchRegisterScope(UseScratchRegisterScope* scope) {
current_scratch_scope_ = scope;
}
UseScratchRegisterScope* GetCurrentScratchRegisterScope() {
return current_scratch_scope_;
}
// Like printf, but print at run-time from generated code.
//
// The caller must ensure that arguments for floating-point placeholders
// (such as %e, %f or %g) are VRegisters in format 1S or 1D, and that
// arguments for integer placeholders are Registers.
//
// At the moment it is only possible to print the value of sp if it is the
// current stack pointer. Otherwise, the MacroAssembler will automatically
// update sp on every push (using BumpSystemStackPointer), so determining its
// value is difficult.
//
// Format placeholders that refer to more than one argument, or to a specific
// argument, are not supported. This includes formats like "%1$d" or "%.*d".
//
// This function automatically preserves caller-saved registers so that
// calling code can use Printf at any point without having to worry about
// corruption. The preservation mechanism generates a lot of code. If this is
// a problem, preserve the important registers manually and then call
// PrintfNoPreserve. Callee-saved registers are not used by Printf, and are
// implicitly preserved.
void Printf(const char* format,
CPURegister arg0 = NoCPUReg,
CPURegister arg1 = NoCPUReg,
CPURegister arg2 = NoCPUReg,
CPURegister arg3 = NoCPUReg);
// Like Printf, but don't preserve any caller-saved registers, not even 'lr'.
//
// The return code from the system printf call will be returned in x0.
void PrintfNoPreserve(const char* format,
const CPURegister& arg0 = NoCPUReg,
const CPURegister& arg1 = NoCPUReg,
const CPURegister& arg2 = NoCPUReg,
const CPURegister& arg3 = NoCPUReg);
// Trace control when running the debug simulator.
//
// For example:
//
// __ Trace(LOG_REGS, TRACE_ENABLE);
// Will add registers to the trace if it wasn't already the case.
//
// __ Trace(LOG_DISASM, TRACE_DISABLE);
// Will stop logging disassembly. It has no effect if the disassembly wasn't
// already being logged.
void Trace(TraceParameters parameters, TraceCommand command);
// Log the requested data independently of what is being traced.
//
// For example:
//
// __ Log(LOG_FLAGS)
// Will output the flags.
void Log(TraceParameters parameters);
// Enable or disable instrumentation when an Instrument visitor is attached to
// the simulator.
void EnableInstrumentation();
void DisableInstrumentation();
// Add a marker to the instrumentation data produced by an Instrument visitor.
// The name is a two character string that will be attached to the marker in
// the output data.
void AnnotateInstrumentation(const char* marker_name);
LiteralPool* GetLiteralPool() { return &literal_pool_; }
// Support for simulated runtime calls.
// `CallRuntime` requires variadic templating, that is only available from
// C++11.
#if __cplusplus >= 201103L
#define VIXL_HAS_MACROASSEMBLER_RUNTIME_CALL_SUPPORT
#endif // #if __cplusplus >= 201103L
#ifdef VIXL_HAS_MACROASSEMBLER_RUNTIME_CALL_SUPPORT
template <typename R, typename... P>
void CallRuntimeHelper(R (*function)(P...), RuntimeCallType call_type);
template <typename R, typename... P>
void CallRuntime(R (*function)(P...)) {
CallRuntimeHelper(function, kCallRuntime);
}
template <typename R, typename... P>
void TailCallRuntime(R (*function)(P...)) {
CallRuntimeHelper(function, kTailCallRuntime);
}
#endif // #ifdef VIXL_HAS_MACROASSEMBLER_RUNTIME_CALL_SUPPORT
protected:
void BlockLiteralPool() { literal_pool_.Block(); }
void ReleaseLiteralPool() { literal_pool_.Release(); }
bool IsLiteralPoolBlocked() const { return literal_pool_.IsBlocked(); }
void BlockVeneerPool() { veneer_pool_.Block(); }
void ReleaseVeneerPool() { veneer_pool_.Release(); }
bool IsVeneerPoolBlocked() const { return veneer_pool_.IsBlocked(); }
virtual void BlockPools() VIXL_OVERRIDE {
BlockLiteralPool();
BlockVeneerPool();
}
virtual void ReleasePools() VIXL_OVERRIDE {
ReleaseLiteralPool();
ReleaseVeneerPool();
}
// The scopes below need to able to block and release a particular pool.
// TODO: Consider removing those scopes or move them to
// code-generation-scopes-vixl.h.
friend class BlockPoolsScope;
friend class BlockLiteralPoolScope;
friend class BlockVeneerPoolScope;
virtual void SetAllowMacroInstructions(bool value) VIXL_OVERRIDE {
allow_macro_instructions_ = value;
}
// Helper used to query information about code generation and to generate
// code for `csel`.
// Here and for the related helpers below:
// - Code is generated when `masm` is not `NULL`.
// - On return and when set, `should_synthesise_left` and
// `should_synthesise_right` will indicate whether `left` and `right`
// should be synthesized in a temporary register.
static void CselHelper(MacroAssembler* masm,
const Register& rd,
Operand left,
Operand right,
Condition cond,
bool* should_synthesise_left = NULL,
bool* should_synthesise_right = NULL);
// The helper returns `true` if it can handle the specified arguments.
// Also see comments for `CselHelper()`.
static bool CselSubHelperTwoImmediates(MacroAssembler* masm,
const Register& rd,
int64_t left,
int64_t right,
Condition cond,
bool* should_synthesise_left,
bool* should_synthesise_right);
// See comments for `CselHelper()`.
static bool CselSubHelperTwoOrderedImmediates(MacroAssembler* masm,
const Register& rd,
int64_t left,
int64_t right,
Condition cond);
// See comments for `CselHelper()`.
static void CselSubHelperRightSmallImmediate(MacroAssembler* masm,
UseScratchRegisterScope* temps,
const Register& rd,
const Operand& left,
const Operand& right,
Condition cond,
bool* should_synthesise_left);
private:
// The actual Push and Pop implementations. These don't generate any code
// other than that required for the push or pop. This allows
// (Push|Pop)CPURegList to bundle together setup code for a large block of
// registers.
//
// Note that size is per register, and is specified in bytes.
void PushHelper(int count,
int size,
const CPURegister& src0,
const CPURegister& src1,
const CPURegister& src2,
const CPURegister& src3);
void PopHelper(int count,
int size,
const CPURegister& dst0,
const CPURegister& dst1,
const CPURegister& dst2,
const CPURegister& dst3);
void Movi16bitHelper(const VRegister& vd, uint64_t imm);
void Movi32bitHelper(const VRegister& vd, uint64_t imm);
void Movi64bitHelper(const VRegister& vd, uint64_t imm);
// Perform necessary maintenance operations before a push or pop.
//
// Note that size is per register, and is specified in bytes.
void PrepareForPush(int count, int size);
void PrepareForPop(int count, int size);
// The actual implementation of load and store operations for CPURegList.
enum LoadStoreCPURegListAction { kLoad, kStore };
void LoadStoreCPURegListHelper(LoadStoreCPURegListAction operation,
CPURegList registers,
const MemOperand& mem);
// Returns a MemOperand suitable for loading or storing a CPURegList at `dst`.
// This helper may allocate registers from `scratch_scope` and generate code
// to compute an intermediate address. The resulting MemOperand is only valid
// as long as `scratch_scope` remains valid.
MemOperand BaseMemOperandForLoadStoreCPURegList(
const CPURegList& registers,
const MemOperand& mem,
UseScratchRegisterScope* scratch_scope);
bool LabelIsOutOfRange(Label* label, ImmBranchType branch_type) {
return !Instruction::IsValidImmPCOffset(branch_type,
label->GetLocation() -
GetCursorOffset());
}
// Tell whether any of the macro instruction can be used. When false the
// MacroAssembler will assert if a method which can emit a variable number
// of instructions is called.
bool allow_macro_instructions_;
// Indicates whether we should generate simulator or native code.
bool generate_simulator_code_;
// The register to use as a stack pointer for stack operations.
Register sp_;
// Scratch registers available for use by the MacroAssembler.
CPURegList tmp_list_;
CPURegList fptmp_list_;
UseScratchRegisterScope* current_scratch_scope_;
LiteralPool literal_pool_;
VeneerPool veneer_pool_;
ptrdiff_t checkpoint_;
ptrdiff_t recommended_checkpoint_;
friend class Pool;
friend class LiteralPool;
};
inline size_t VeneerPool::GetOtherPoolsMaxSize() const {
return masm_->GetLiteralPoolMaxSize();
}
inline size_t LiteralPool::GetOtherPoolsMaxSize() const {
return masm_->GetVeneerPoolMaxSize();
}
inline void LiteralPool::SetNextRecommendedCheckpoint(ptrdiff_t offset) {
masm_->recommended_checkpoint_ =
std::min(masm_->recommended_checkpoint_, offset);
recommended_checkpoint_ = offset;
}
class InstructionAccurateScope : public ExactAssemblyScope {
public:
VIXL_DEPRECATED("ExactAssemblyScope",
InstructionAccurateScope(MacroAssembler* masm,
int64_t count,
SizePolicy size_policy = kExactSize))
: ExactAssemblyScope(masm, count * kInstructionSize, size_policy) {}
};
class BlockLiteralPoolScope {
public:
explicit BlockLiteralPoolScope(MacroAssembler* masm) : masm_(masm) {
masm_->BlockLiteralPool();
}
~BlockLiteralPoolScope() { masm_->ReleaseLiteralPool(); }
private:
MacroAssembler* masm_;
};
class BlockVeneerPoolScope {
public:
explicit BlockVeneerPoolScope(MacroAssembler* masm) : masm_(masm) {
masm_->BlockVeneerPool();
}
~BlockVeneerPoolScope() { masm_->ReleaseVeneerPool(); }
private:
MacroAssembler* masm_;
};
class BlockPoolsScope {
public:
explicit BlockPoolsScope(MacroAssembler* masm) : masm_(masm) {
masm_->BlockPools();
}
~BlockPoolsScope() { masm_->ReleasePools(); }
private:
MacroAssembler* masm_;
};
// This scope utility allows scratch registers to be managed safely. The
// MacroAssembler's GetScratchRegisterList() (and GetScratchFPRegisterList()) is
// used as a pool of scratch registers. These registers can be allocated on
// demand, and will be returned at the end of the scope.
//
// When the scope ends, the MacroAssembler's lists will be restored to their
// original state, even if the lists were modified by some other means.
class UseScratchRegisterScope {
public:
// This constructor implicitly calls `Open` to initialise the scope (`masm`
// must not be `NULL`), so it is ready to use immediately after it has been
// constructed.
explicit UseScratchRegisterScope(MacroAssembler* masm)
: masm_(NULL), parent_(NULL), old_available_(0), old_availablefp_(0) {
Open(masm);
}
// This constructor does not implicitly initialise the scope. Instead, the
// user is required to explicitly call the `Open` function before using the
// scope.
UseScratchRegisterScope()
: masm_(NULL), parent_(NULL), old_available_(0), old_availablefp_(0) {}
// This function performs the actual initialisation work.
void Open(MacroAssembler* masm);
// The destructor always implicitly calls the `Close` function.
~UseScratchRegisterScope() { Close(); }
// This function performs the cleaning-up work. It must succeed even if the
// scope has not been opened. It is safe to call multiple times.
void Close();
bool IsAvailable(const CPURegister& reg) const;
// Take a register from the appropriate temps list. It will be returned
// automatically when the scope ends.
Register AcquireW() {
return AcquireNextAvailable(masm_->GetScratchRegisterList()).W();
}
Register AcquireX() {
return AcquireNextAvailable(masm_->GetScratchRegisterList()).X();
}
VRegister AcquireS() {
return AcquireNextAvailable(masm_->GetScratchFPRegisterList()).S();
}
VRegister AcquireD() {
return AcquireNextAvailable(masm_->GetScratchFPRegisterList()).D();
}
Register AcquireRegisterOfSize(int size_in_bits);
Register AcquireSameSizeAs(const Register& reg) {
return AcquireRegisterOfSize(reg.GetSizeInBits());
}
VRegister AcquireVRegisterOfSize(int size_in_bits);
VRegister AcquireSameSizeAs(const VRegister& reg) {
return AcquireVRegisterOfSize(reg.GetSizeInBits());
}
CPURegister AcquireCPURegisterOfSize(int size_in_bits) {
return masm_->GetScratchRegisterList()->IsEmpty()
? CPURegister(AcquireVRegisterOfSize(size_in_bits))
: CPURegister(AcquireRegisterOfSize(size_in_bits));
}
// Explicitly release an acquired (or excluded) register, putting it back in
// the appropriate temps list.
void Release(const CPURegister& reg);
// Make the specified registers available as scratch registers for the
// duration of this scope.
void Include(const CPURegList& list);
void Include(const Register& reg1,
const Register& reg2 = NoReg,
const Register& reg3 = NoReg,
const Register& reg4 = NoReg);
void Include(const VRegister& reg1,
const VRegister& reg2 = NoVReg,
const VRegister& reg3 = NoVReg,
const VRegister& reg4 = NoVReg);
// Make sure that the specified registers are not available in this scope.
// This can be used to prevent helper functions from using sensitive
// registers, for example.
void Exclude(const CPURegList& list);
void Exclude(const Register& reg1,
const Register& reg2 = NoReg,
const Register& reg3 = NoReg,
const Register& reg4 = NoReg);
void Exclude(const VRegister& reg1,
const VRegister& reg2 = NoVReg,
const VRegister& reg3 = NoVReg,
const VRegister& reg4 = NoVReg);
void Exclude(const CPURegister& reg1,
const CPURegister& reg2 = NoCPUReg,
const CPURegister& reg3 = NoCPUReg,
const CPURegister& reg4 = NoCPUReg);
// Prevent any scratch registers from being used in this scope.
void ExcludeAll();
private:
static CPURegister AcquireNextAvailable(CPURegList* available);
static void ReleaseByCode(CPURegList* available, int code);
static void ReleaseByRegList(CPURegList* available, RegList regs);
static void IncludeByRegList(CPURegList* available, RegList exclude);
static void ExcludeByRegList(CPURegList* available, RegList exclude);
// The MacroAssembler maintains a list of available scratch registers, and
// also keeps track of the most recently-opened scope so that on destruction
// we can check that scopes do not outlive their parents.
MacroAssembler* masm_;
UseScratchRegisterScope* parent_;
// The state of the available lists at the start of this scope.
RegList old_available_; // kRegister
RegList old_availablefp_; // kVRegister
// Disallow copy constructor and operator=.
VIXL_DEBUG_NO_RETURN UseScratchRegisterScope(const UseScratchRegisterScope&) {
VIXL_UNREACHABLE();
}
VIXL_DEBUG_NO_RETURN void operator=(const UseScratchRegisterScope&) {
VIXL_UNREACHABLE();
}
};
// Variadic templating is only available from C++11.
#ifdef VIXL_HAS_MACROASSEMBLER_RUNTIME_CALL_SUPPORT
// `R` stands for 'return type', and `P` for 'parameter types'.
template <typename R, typename... P>
void MacroAssembler::CallRuntimeHelper(R (*function)(P...),
RuntimeCallType call_type) {
if (generate_simulator_code_) {
#ifdef VIXL_HAS_SIMULATED_RUNTIME_CALL_SUPPORT
uintptr_t runtime_call_wrapper_address = reinterpret_cast<uintptr_t>(
&(Simulator::RuntimeCallStructHelper<R, P...>::Wrapper));
uintptr_t function_address = reinterpret_cast<uintptr_t>(function);
EmissionCheckScope guard(this,
kRuntimeCallLength,
CodeBufferCheckScope::kExactSize);
Label start;
bind(&start);
{
ExactAssemblyScope scope(this, kInstructionSize);
hlt(kRuntimeCallOpcode);
}
VIXL_ASSERT(GetSizeOfCodeGeneratedSince(&start) ==
kRuntimeCallWrapperOffset);
dc(runtime_call_wrapper_address);
VIXL_ASSERT(GetSizeOfCodeGeneratedSince(&start) ==
kRuntimeCallFunctionOffset);
dc(function_address);
VIXL_ASSERT(GetSizeOfCodeGeneratedSince(&start) == kRuntimeCallTypeOffset);
dc32(call_type);
VIXL_ASSERT(GetSizeOfCodeGeneratedSince(&start) == kRuntimeCallLength);
#else
VIXL_UNREACHABLE();
#endif // #ifdef VIXL_HAS_SIMULATED_RUNTIME_CALL_SUPPORT
} else {
UseScratchRegisterScope temps(this);
Register temp = temps.AcquireX();
Mov(temp, reinterpret_cast<uint64_t>(function));
if (call_type == kTailCallRuntime) {
Br(temp);
} else {
VIXL_ASSERT(call_type == kCallRuntime);
Blr(temp);
}
}
}
#endif // #ifdef VIXL_HAS_MACROASSEMBLER_RUNTIME_CALL_SUPPORT
} // namespace aarch64
// Required InvalSet template specialisations.
// TODO: These template specialisations should not live in this file. Move
// VeneerPool out of the aarch64 namespace in order to share its implementation
// later.
template <>
inline ptrdiff_t InvalSet<aarch64::VeneerPool::BranchInfo,
aarch64::VeneerPool::kNPreallocatedInfos,
ptrdiff_t,
aarch64::VeneerPool::kInvalidOffset,
aarch64::VeneerPool::kReclaimFrom,
aarch64::VeneerPool::kReclaimFactor>::
GetKey(const aarch64::VeneerPool::BranchInfo& branch_info) {
return branch_info.first_unreacheable_pc_;
}
template <>
inline void InvalSet<aarch64::VeneerPool::BranchInfo,
aarch64::VeneerPool::kNPreallocatedInfos,
ptrdiff_t,
aarch64::VeneerPool::kInvalidOffset,
aarch64::VeneerPool::kReclaimFrom,
aarch64::VeneerPool::kReclaimFactor>::
SetKey(aarch64::VeneerPool::BranchInfo* branch_info, ptrdiff_t key) {
branch_info->first_unreacheable_pc_ = key;
}
} // namespace vixl
#endif // VIXL_AARCH64_MACRO_ASSEMBLER_AARCH64_H_