/* * Copyright (C) 2014 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ART_COMPILER_UTILS_X86_64_MANAGED_REGISTER_X86_64_H_ #define ART_COMPILER_UTILS_X86_64_MANAGED_REGISTER_X86_64_H_ #include "constants_x86_64.h" #include "dwarf/register.h" #include "utils/managed_register.h" namespace art { namespace x86_64 { // Values for register pairs. // The registers in kReservedCpuRegistersArray in x86.cc are not used in pairs. // The table kRegisterPairs in x86.cc must be kept in sync with this enum. enum RegisterPair { RAX_RDX = 0, RAX_RCX = 1, RAX_RBX = 2, RAX_RDI = 3, RDX_RCX = 4, RDX_RBX = 5, RDX_RDI = 6, RCX_RBX = 7, RCX_RDI = 8, RBX_RDI = 9, kNumberOfRegisterPairs = 10, kNoRegisterPair = -1, }; std::ostream& operator<<(std::ostream& os, const RegisterPair& reg); const int kNumberOfCpuRegIds = kNumberOfCpuRegisters; const int kNumberOfCpuAllocIds = kNumberOfCpuRegisters; const int kNumberOfXmmRegIds = kNumberOfFloatRegisters; const int kNumberOfXmmAllocIds = kNumberOfFloatRegisters; const int kNumberOfX87RegIds = kNumberOfX87Registers; const int kNumberOfX87AllocIds = kNumberOfX87Registers; const int kNumberOfPairRegIds = kNumberOfRegisterPairs; const int kNumberOfRegIds = kNumberOfCpuRegIds + kNumberOfXmmRegIds + kNumberOfX87RegIds + kNumberOfPairRegIds; const int kNumberOfAllocIds = kNumberOfCpuAllocIds + kNumberOfXmmAllocIds + kNumberOfX87RegIds; // Register ids map: // [0..R[ cpu registers (enum Register) // [R..X[ xmm registers (enum XmmRegister) // [X..S[ x87 registers (enum X87Register) // [S..P[ register pairs (enum RegisterPair) // where // R = kNumberOfCpuRegIds // X = R + kNumberOfXmmRegIds // S = X + kNumberOfX87RegIds // P = X + kNumberOfRegisterPairs // Allocation ids map: // [0..R[ cpu registers (enum Register) // [R..X[ xmm registers (enum XmmRegister) // [X..S[ x87 registers (enum X87Register) // where // R = kNumberOfCpuRegIds // X = R + kNumberOfXmmRegIds // S = X + kNumberOfX87RegIds // An instance of class 'ManagedRegister' represents a single cpu register (enum // Register), an xmm register (enum XmmRegister), or a pair of cpu registers // (enum RegisterPair). // 'ManagedRegister::NoRegister()' provides an invalid register. // There is a one-to-one mapping between ManagedRegister and register id. class X86_64ManagedRegister : public ManagedRegister { public: CpuRegister AsCpuRegister() const { CHECK(IsCpuRegister()); return CpuRegister(static_cast(id_)); } XmmRegister AsXmmRegister() const { CHECK(IsXmmRegister()); return XmmRegister(static_cast(id_ - kNumberOfCpuRegIds)); } X87Register AsX87Register() const { CHECK(IsX87Register()); return static_cast(id_ - (kNumberOfCpuRegIds + kNumberOfXmmRegIds)); } CpuRegister AsRegisterPairLow() const { CHECK(IsRegisterPair()); // Appropriate mapping of register ids allows to use AllocIdLow(). return FromRegId(AllocIdLow()).AsCpuRegister(); } CpuRegister AsRegisterPairHigh() const { CHECK(IsRegisterPair()); // Appropriate mapping of register ids allows to use AllocIdHigh(). return FromRegId(AllocIdHigh()).AsCpuRegister(); } bool IsCpuRegister() const { CHECK(IsValidManagedRegister()); return (0 <= id_) && (id_ < kNumberOfCpuRegIds); } bool IsXmmRegister() const { CHECK(IsValidManagedRegister()); const int test = id_ - kNumberOfCpuRegIds; return (0 <= test) && (test < kNumberOfXmmRegIds); } bool IsX87Register() const { CHECK(IsValidManagedRegister()); const int test = id_ - (kNumberOfCpuRegIds + kNumberOfXmmRegIds); return (0 <= test) && (test < kNumberOfX87RegIds); } bool IsRegisterPair() const { CHECK(IsValidManagedRegister()); const int test = id_ - (kNumberOfCpuRegIds + kNumberOfXmmRegIds + kNumberOfX87RegIds); return (0 <= test) && (test < kNumberOfPairRegIds); } void Print(std::ostream& os) const; // Returns true if the two managed-registers ('this' and 'other') overlap. // Either managed-register may be the NoRegister. If both are the NoRegister // then false is returned. bool Overlaps(const X86_64ManagedRegister& other) const; static X86_64ManagedRegister FromCpuRegister(Register r) { CHECK_NE(r, kNoRegister); return FromRegId(r); } static X86_64ManagedRegister FromXmmRegister(FloatRegister r) { return FromRegId(r + kNumberOfCpuRegIds); } static X86_64ManagedRegister FromX87Register(X87Register r) { CHECK_NE(r, kNoX87Register); return FromRegId(r + kNumberOfCpuRegIds + kNumberOfXmmRegIds); } static X86_64ManagedRegister FromRegisterPair(RegisterPair r) { CHECK_NE(r, kNoRegisterPair); return FromRegId(r + (kNumberOfCpuRegIds + kNumberOfXmmRegIds + kNumberOfX87RegIds)); } private: bool IsValidManagedRegister() const { return (0 <= id_) && (id_ < kNumberOfRegIds); } int RegId() const { CHECK(!IsNoRegister()); return id_; } int AllocId() const { CHECK(IsValidManagedRegister() && !IsRegisterPair()); CHECK_LT(id_, kNumberOfAllocIds); return id_; } int AllocIdLow() const; int AllocIdHigh() const; friend class ManagedRegister; explicit X86_64ManagedRegister(int reg_id) : ManagedRegister(reg_id) {} static X86_64ManagedRegister FromRegId(int reg_id) { X86_64ManagedRegister reg(reg_id); CHECK(reg.IsValidManagedRegister()); return reg; } }; std::ostream& operator<<(std::ostream& os, const X86_64ManagedRegister& reg); } // namespace x86_64 inline x86_64::X86_64ManagedRegister ManagedRegister::AsX86_64() const { x86_64::X86_64ManagedRegister reg(id_); CHECK(reg.IsNoRegister() || reg.IsValidManagedRegister()); return reg; } } // namespace art #endif // ART_COMPILER_UTILS_X86_64_MANAGED_REGISTER_X86_64_H_