// Copyright 2017 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_WASM_BASELINE_LIFTOFF_REGISTER_H_
#define V8_WASM_BASELINE_LIFTOFF_REGISTER_H_
#include <iosfwd>
#include <memory>
#include "src/base/bits.h"
#include "src/wasm/baseline/liftoff-assembler-defs.h"
#include "src/wasm/wasm-opcodes.h"
namespace v8 {
namespace internal {
namespace wasm {
static constexpr bool kNeedI64RegPair = kPointerSize == 4;
enum RegClass : uint8_t {
kGpReg,
kFpReg,
// {kGpRegPair} equals {kNoReg} if {kNeedI64RegPair} is false.
kGpRegPair,
kNoReg = kGpRegPair + kNeedI64RegPair
};
enum RegPairHalf : uint8_t { kLowWord, kHighWord };
static inline constexpr bool needs_reg_pair(ValueType type) {
return kNeedI64RegPair && type == kWasmI64;
}
// TODO(clemensh): Use a switch once we require C++14 support.
static inline constexpr RegClass reg_class_for(ValueType type) {
return needs_reg_pair(type) // i64 on 32 bit
? kGpRegPair
: type == kWasmI32 || type == kWasmI64 // int types
? kGpReg
: type == kWasmF32 || type == kWasmF64 // float types
? kFpReg
: kNoReg; // other (unsupported) types
}
// Maximum code of a gp cache register.
static constexpr int kMaxGpRegCode =
8 * sizeof(kLiftoffAssemblerGpCacheRegs) -
base::bits::CountLeadingZeros(kLiftoffAssemblerGpCacheRegs);
// Maximum code of an fp cache register.
static constexpr int kMaxFpRegCode =
8 * sizeof(kLiftoffAssemblerFpCacheRegs) -
base::bits::CountLeadingZeros(kLiftoffAssemblerFpCacheRegs);
// LiftoffRegister encodes both gp and fp in a unified index space.
// [0 .. kMaxGpRegCode] encodes gp registers,
// [kMaxGpRegCode+1 .. kMaxGpRegCode + kMaxFpRegCode] encodes fp registers.
// I64 values on 32 bit platforms are stored in two registers, both encoded in
// the same LiftoffRegister value.
static constexpr int kAfterMaxLiftoffGpRegCode = kMaxGpRegCode + 1;
static constexpr int kAfterMaxLiftoffFpRegCode =
kAfterMaxLiftoffGpRegCode + kMaxFpRegCode + 1;
static constexpr int kAfterMaxLiftoffRegCode = kAfterMaxLiftoffFpRegCode;
static constexpr int kBitsPerLiftoffRegCode =
32 - base::bits::CountLeadingZeros<uint32_t>(kAfterMaxLiftoffRegCode - 1);
static constexpr int kBitsPerGpRegCode =
32 - base::bits::CountLeadingZeros<uint32_t>(kMaxGpRegCode);
static constexpr int kBitsPerGpRegPair = 1 + 2 * kBitsPerGpRegCode;
class LiftoffRegister {
static constexpr int needed_bits =
Max(kNeedI64RegPair ? kBitsPerGpRegPair : 0, kBitsPerLiftoffRegCode);
using storage_t = std::conditional<
needed_bits <= 8, uint8_t,
std::conditional<needed_bits <= 16, uint16_t, uint32_t>::type>::type;
static_assert(8 * sizeof(storage_t) >= needed_bits &&
8 * sizeof(storage_t) < 2 * needed_bits,
"right type has been chosen");
public:
explicit LiftoffRegister(Register reg) : LiftoffRegister(reg.code()) {
DCHECK_EQ(reg, gp());
}
explicit LiftoffRegister(DoubleRegister reg)
: LiftoffRegister(kAfterMaxLiftoffGpRegCode + reg.code()) {
DCHECK_EQ(reg, fp());
}
static LiftoffRegister from_liftoff_code(int code) {
DCHECK_LE(0, code);
DCHECK_GT(kAfterMaxLiftoffRegCode, code);
DCHECK_EQ(code, static_cast<storage_t>(code));
return LiftoffRegister(code);
}
static LiftoffRegister from_code(RegClass rc, int code) {
switch (rc) {
case kGpReg:
return LiftoffRegister(Register::from_code(code));
case kFpReg:
return LiftoffRegister(DoubleRegister::from_code(code));
default:
UNREACHABLE();
}
}
static LiftoffRegister ForPair(Register low, Register high) {
DCHECK(kNeedI64RegPair);
DCHECK_NE(low, high);
storage_t combined_code = low.code() | high.code() << kBitsPerGpRegCode |
1 << (2 * kBitsPerGpRegCode);
return LiftoffRegister(combined_code);
}
constexpr bool is_pair() const {
return kNeedI64RegPair && (code_ & (1 << (2 * kBitsPerGpRegCode))) != 0;
}
constexpr bool is_gp() const { return code_ < kAfterMaxLiftoffGpRegCode; }
constexpr bool is_fp() const {
return code_ >= kAfterMaxLiftoffGpRegCode &&
code_ < kAfterMaxLiftoffFpRegCode;
}
LiftoffRegister low() const { return LiftoffRegister(low_gp()); }
LiftoffRegister high() const { return LiftoffRegister(high_gp()); }
Register low_gp() const {
DCHECK(is_pair());
static constexpr storage_t kCodeMask = (1 << kBitsPerGpRegCode) - 1;
return Register::from_code(code_ & kCodeMask);
}
Register high_gp() const {
DCHECK(is_pair());
static constexpr storage_t kCodeMask = (1 << kBitsPerGpRegCode) - 1;
return Register::from_code((code_ >> kBitsPerGpRegCode) & kCodeMask);
}
Register gp() const {
DCHECK(is_gp());
return Register::from_code(code_);
}
DoubleRegister fp() const {
DCHECK(is_fp());
return DoubleRegister::from_code(code_ - kAfterMaxLiftoffGpRegCode);
}
uint32_t liftoff_code() const {
DCHECK(is_gp() || is_fp());
return code_;
}
RegClass reg_class() const {
return is_pair() ? kGpRegPair : is_gp() ? kGpReg : kFpReg;
}
bool operator==(const LiftoffRegister other) const {
DCHECK_EQ(is_pair(), other.is_pair());
return code_ == other.code_;
}
bool operator!=(const LiftoffRegister other) const {
DCHECK_EQ(is_pair(), other.is_pair());
return code_ != other.code_;
}
bool overlaps(const LiftoffRegister other) const {
if (is_pair()) return low().overlaps(other) || high().overlaps(other);
if (other.is_pair()) return *this == other.low() || *this == other.high();
return *this == other;
}
private:
storage_t code_;
explicit constexpr LiftoffRegister(storage_t code) : code_(code) {}
};
ASSERT_TRIVIALLY_COPYABLE(LiftoffRegister);
inline std::ostream& operator<<(std::ostream& os, LiftoffRegister reg) {
if (reg.is_pair()) {
return os << "<gp" << reg.low_gp().code() << "+" << reg.high_gp().code()
<< ">";
} else if (reg.is_gp()) {
return os << "gp" << reg.gp().code();
} else {
return os << "fp" << reg.fp().code();
}
}
class LiftoffRegList {
public:
static constexpr bool use_u16 = kAfterMaxLiftoffRegCode <= 16;
static constexpr bool use_u32 = !use_u16 && kAfterMaxLiftoffRegCode <= 32;
using storage_t = std::conditional<
use_u16, uint16_t,
std::conditional<use_u32, uint32_t, uint64_t>::type>::type;
static constexpr storage_t kGpMask = storage_t{kLiftoffAssemblerGpCacheRegs};
static constexpr storage_t kFpMask = storage_t{kLiftoffAssemblerFpCacheRegs}
<< kAfterMaxLiftoffGpRegCode;
constexpr LiftoffRegList() = default;
Register set(Register reg) { return set(LiftoffRegister(reg)).gp(); }
DoubleRegister set(DoubleRegister reg) {
return set(LiftoffRegister(reg)).fp();
}
LiftoffRegister set(LiftoffRegister reg) {
if (reg.is_pair()) {
regs_ |= storage_t{1} << reg.low().liftoff_code();
regs_ |= storage_t{1} << reg.high().liftoff_code();
} else {
regs_ |= storage_t{1} << reg.liftoff_code();
}
return reg;
}
LiftoffRegister clear(LiftoffRegister reg) {
if (reg.is_pair()) {
regs_ &= ~(storage_t{1} << reg.low().liftoff_code());
regs_ &= ~(storage_t{1} << reg.high().liftoff_code());
} else {
regs_ &= ~(storage_t{1} << reg.liftoff_code());
}
return reg;
}
bool has(LiftoffRegister reg) const {
if (reg.is_pair()) {
DCHECK_EQ(has(reg.low()), has(reg.high()));
reg = reg.low();
}
return (regs_ & (storage_t{1} << reg.liftoff_code())) != 0;
}
bool has(Register reg) const { return has(LiftoffRegister(reg)); }
bool has(DoubleRegister reg) const { return has(LiftoffRegister(reg)); }
constexpr bool is_empty() const { return regs_ == 0; }
constexpr unsigned GetNumRegsSet() const {
return base::bits::CountPopulation(regs_);
}
constexpr LiftoffRegList operator&(const LiftoffRegList other) const {
return LiftoffRegList(regs_ & other.regs_);
}
constexpr LiftoffRegList operator~() const {
return LiftoffRegList(~regs_ & (kGpMask | kFpMask));
}
constexpr bool operator==(const LiftoffRegList other) const {
return regs_ == other.regs_;
}
constexpr bool operator!=(const LiftoffRegList other) const {
return regs_ != other.regs_;
}
LiftoffRegister GetFirstRegSet() const {
DCHECK(!is_empty());
unsigned first_code = base::bits::CountTrailingZeros(regs_);
return LiftoffRegister::from_liftoff_code(first_code);
}
LiftoffRegister GetLastRegSet() const {
DCHECK(!is_empty());
unsigned last_code =
8 * sizeof(regs_) - 1 - base::bits::CountLeadingZeros(regs_);
return LiftoffRegister::from_liftoff_code(last_code);
}
LiftoffRegList MaskOut(const LiftoffRegList mask) const {
// Masking out is guaranteed to return a correct reg list, hence no checks
// needed.
return FromBits(regs_ & ~mask.regs_);
}
static LiftoffRegList FromBits(storage_t bits) {
DCHECK_EQ(bits, bits & (kGpMask | kFpMask));
return LiftoffRegList(bits);
}
template <storage_t bits>
static constexpr LiftoffRegList FromBits() {
static_assert(bits == (bits & (kGpMask | kFpMask)), "illegal reg list");
return LiftoffRegList(bits);
}
template <typename... Regs>
static LiftoffRegList ForRegs(Regs... regs) {
LiftoffRegList list;
for (LiftoffRegister reg : {LiftoffRegister(regs)...}) list.set(reg);
return list;
}
RegList GetGpList() { return regs_ & kGpMask; }
RegList GetFpList() { return (regs_ & kFpMask) >> kAfterMaxLiftoffGpRegCode; }
private:
storage_t regs_ = 0;
// Unchecked constructor. Only use for valid bits.
explicit constexpr LiftoffRegList(storage_t bits) : regs_(bits) {}
};
ASSERT_TRIVIALLY_COPYABLE(LiftoffRegList);
static constexpr LiftoffRegList kGpCacheRegList =
LiftoffRegList::FromBits<LiftoffRegList::kGpMask>();
static constexpr LiftoffRegList kFpCacheRegList =
LiftoffRegList::FromBits<LiftoffRegList::kFpMask>();
static constexpr LiftoffRegList GetCacheRegList(RegClass rc) {
return rc == kGpReg ? kGpCacheRegList : kFpCacheRegList;
}
inline std::ostream& operator<<(std::ostream& os, LiftoffRegList reglist) {
os << "{";
for (bool first = true; !reglist.is_empty(); first = false) {
LiftoffRegister reg = reglist.GetFirstRegSet();
reglist.clear(reg);
os << (first ? "" : ", ") << reg;
}
return os << "}";
}
} // namespace wasm
} // namespace internal
} // namespace v8
#endif // V8_WASM_BASELINE_LIFTOFF_REGISTER_H_