blob: b74b2b6906f0c6ec48862cd69175db5e32113d06 [file] [log] [blame]
// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#ifndef RUNTIME_VM_CONSTANTS_X64_H_
#define RUNTIME_VM_CONSTANTS_X64_H_
#ifndef RUNTIME_VM_CONSTANTS_H_
#error Do not include constants_x64.h directly; use constants.h instead.
#endif
#include "platform/assert.h"
#include "platform/globals.h"
#include "vm/constants_base.h"
namespace dart {
enum Register {
RAX = 0,
RCX = 1,
RDX = 2,
RBX = 3,
RSP = 4,
RBP = 5,
RSI = 6,
RDI = 7,
R8 = 8,
R9 = 9,
R10 = 10,
R11 = 11,
R12 = 12,
R13 = 13,
R14 = 14,
R15 = 15,
kNumberOfCpuRegisters = 16,
kNoRegister = -1, // Signals an illegal register.
};
enum ByteRegister {
AL = 0,
CL = 1,
DL = 2,
BL = 3,
AH = 4,
CH = 5,
DH = 6,
BH = 7,
SPL = 4 | 0x10,
BPL = 5 | 0x10,
SIL = 6 | 0x10,
DIL = 7 | 0x10,
R8B = 8,
R9B = 9,
R10B = 10,
R11B = 11,
R12B = 12,
R13B = 13,
R14B = 14,
R15B = 15,
kNoByteRegister = -1 // Signals an illegal register.
};
inline ByteRegister ByteRegisterOf(Register reg) {
if (RSP <= reg && reg <= RDI) {
return static_cast<ByteRegister>(reg | 0x10);
} else {
return static_cast<ByteRegister>(reg);
}
}
enum XmmRegister {
XMM0 = 0,
XMM1 = 1,
XMM2 = 2,
XMM3 = 3,
XMM4 = 4,
XMM5 = 5,
XMM6 = 6,
XMM7 = 7,
XMM8 = 8,
XMM9 = 9,
XMM10 = 10,
XMM11 = 11,
XMM12 = 12,
XMM13 = 13,
XMM14 = 14,
XMM15 = 15,
kNumberOfXmmRegisters = 16,
kNoXmmRegister = -1 // Signals an illegal register.
};
// Architecture independent aliases.
typedef XmmRegister FpuRegister;
const FpuRegister FpuTMP = XMM15;
const int kNumberOfFpuRegisters = kNumberOfXmmRegisters;
const FpuRegister kNoFpuRegister = kNoXmmRegister;
extern const char* cpu_reg_names[kNumberOfCpuRegisters];
extern const char* fpu_reg_names[kNumberOfXmmRegisters];
enum RexBits {
REX_NONE = 0,
REX_B = 1 << 0,
REX_X = 1 << 1,
REX_R = 1 << 2,
REX_W = 1 << 3,
REX_PREFIX = 1 << 6
};
// Register aliases.
const Register TMP = R11; // Used as scratch register by the assembler.
const Register TMP2 = kNoRegister; // No second assembler scratch register.
// Caches object pool pointer in generated code.
const Register PP = R15;
const Register SPREG = RSP; // Stack pointer register.
const Register FPREG = RBP; // Frame pointer register.
const Register ARGS_DESC_REG = R10; // Arguments descriptor register.
const Register CODE_REG = R12;
const Register THR = R14; // Caches current thread in generated code.
const Register CALLEE_SAVED_TEMP = RBX;
// ABI for catch-clause entry point.
const Register kExceptionObjectReg = RAX;
const Register kStackTraceObjectReg = RDX;
// ABI for write barrier stub.
const Register kWriteBarrierObjectReg = RDX;
const Register kWriteBarrierValueReg = RAX;
const Register kWriteBarrierSlotReg = R13;
// ABI for allocation stubs.
const Register kAllocationStubTypeArgumentsReg = RDX;
// ABI for instantiation stubs.
struct InstantiationABI {
static const Register kUninstantiatedTypeArgumentsReg = RBX;
static const Register kInstantiatorTypeArgumentsReg = RDX;
static const Register kFunctionTypeArgumentsReg = RCX;
static const Register kResultTypeArgumentsReg = RAX;
static const Register kResultTypeReg = RAX;
};
// Calling convention when calling TypeTestingStub and SubtypeTestCacheStub.
struct TypeTestABI {
static const Register kInstanceReg = RAX;
static const Register kDstTypeReg = RBX;
static const Register kInstantiatorTypeArgumentsReg = RDX;
static const Register kFunctionTypeArgumentsReg = RCX;
static const Register kSubtypeTestCacheReg = R9;
static const Register kScratchReg = RSI;
static const intptr_t kAbiRegisters =
(1 << kInstanceReg) | (1 << kDstTypeReg) |
(1 << kInstantiatorTypeArgumentsReg) | (1 << kFunctionTypeArgumentsReg) |
(1 << kSubtypeTestCacheReg) | (1 << kScratchReg);
// For call to InstanceOfStub.
static const Register kResultReg = RAX;
};
// ABI for InitStaticFieldStub.
struct InitStaticFieldABI {
static const Register kFieldReg = RAX;
static const Register kResultReg = RAX;
};
// ABI for InitInstanceFieldStub.
struct InitInstanceFieldABI {
static const Register kInstanceReg = RBX;
static const Register kFieldReg = RDX;
static const Register kResultReg = RAX;
};
// Registers used inside the implementation of InitLateInstanceFieldStub.
struct InitLateInstanceFieldInternalRegs {
static const Register kFunctionReg = RAX;
static const Register kAddressReg = RCX;
static const Register kScratchReg = RSI;
};
// ABI for ThrowStub.
struct ThrowABI {
static const Register kExceptionReg = RAX;
};
// ABI for ReThrowStub.
struct ReThrowABI {
static const Register kExceptionReg = RAX;
static const Register kStackTraceReg = RBX;
};
// ABI for AssertBooleanStub.
struct AssertBooleanABI {
static const Register kObjectReg = RAX;
};
// ABI for RangeErrorStub.
struct RangeErrorABI {
static const Register kLengthReg = RAX;
static const Register kIndexReg = RBX;
};
// ABI for AllocateMint*Stub.
struct AllocateMintABI {
static const Register kResultReg = RAX;
static const Register kTempReg = RBX;
};
// ABI for Allocate<TypedData>ArrayStub.
struct AllocateTypedDataArrayABI {
static const Register kLengthReg = RAX;
static const Register kResultReg = RAX;
};
// Registers used inside the implementation of type testing stubs.
struct TTSInternalRegs {
static const Register kInstanceTypeArgumentsReg = RSI;
static const Register kScratchReg = R8;
static const intptr_t kInternalRegisters =
(1 << kInstanceTypeArgumentsReg) | (1 << kScratchReg);
};
// TODO(regis): Add ABIs for type testing stubs and is-type test stubs instead
// of reusing the constants of the instantiation stubs ABI.
typedef uint32_t RegList;
const RegList kAllCpuRegistersList = 0xFFFF;
const RegList kAllFpuRegistersList = 0xFFFF;
const RegList kReservedCpuRegisters =
(1 << SPREG) | (1 << FPREG) | (1 << TMP) | (1 << PP) | (1 << THR);
constexpr intptr_t kNumberOfReservedCpuRegisters = 5;
// CPU registers available to Dart allocator.
const RegList kDartAvailableCpuRegs =
kAllCpuRegistersList & ~kReservedCpuRegisters;
constexpr int kNumberOfDartAvailableCpuRegs =
kNumberOfCpuRegisters - kNumberOfReservedCpuRegisters;
constexpr int kStoreBufferWrapperSize = 13;
enum ScaleFactor {
TIMES_1 = 0,
TIMES_2 = 1,
TIMES_4 = 2,
TIMES_8 = 3,
// Note that Intel addressing does not support this addressing.
// > Scale factor — A value of 2, 4, or 8 that is multiplied by the index
// > value.
// https://software.intel.com/en-us/download/intel-64-and-ia-32-architectures-sdm-combined-volumes-1-2a-2b-2c-2d-3a-3b-3c-3d-and-4
// 3.7.5 Specifying an Offset
TIMES_16 = 4,
TIMES_HALF_WORD_SIZE = kWordSizeLog2 - 1
};
#define R(reg) (1 << (reg))
class CallingConventions {
public:
#if defined(TARGET_OS_WINDOWS)
static const Register kArg1Reg = RCX;
static const Register kArg2Reg = RDX;
static const Register kArg3Reg = R8;
static const Register kArg4Reg = R9;
static const Register ArgumentRegisters[];
static const intptr_t kArgumentRegisters =
R(kArg1Reg) | R(kArg2Reg) | R(kArg3Reg) | R(kArg4Reg);
static const intptr_t kNumArgRegs = 4;
static const XmmRegister FpuArgumentRegisters[];
static const intptr_t kFpuArgumentRegisters =
R(XMM0) | R(XMM1) | R(XMM2) | R(XMM3);
static const intptr_t kNumFpuArgRegs = 4;
static const intptr_t kPointerToReturnStructRegister = kArg1Reg;
// can ArgumentRegisters[i] and XmmArgumentRegisters[i] both be used at the
// same time? (Windows no, rest yes)
static const bool kArgumentIntRegXorFpuReg = true;
static const intptr_t kShadowSpaceBytes = 4 * kWordSize;
static const intptr_t kVolatileCpuRegisters =
R(RAX) | R(RCX) | R(RDX) | R(R8) | R(R9) | R(R10) | R(R11);
static const intptr_t kVolatileXmmRegisters =
R(XMM0) | R(XMM1) | R(XMM2) | R(XMM3) | R(XMM4) | R(XMM5);
static const intptr_t kCalleeSaveCpuRegisters =
R(RBX) | R(RSI) | R(RDI) | R(R12) | R(R13) | R(R14) | R(R15);
static const intptr_t kCalleeSaveXmmRegisters =
R(XMM6) | R(XMM7) | R(XMM8) | R(XMM9) | R(XMM10) | R(XMM11) | R(XMM12) |
R(XMM13) | R(XMM14) | R(XMM15);
static const XmmRegister xmmFirstNonParameterReg = XMM4;
// Windows x64 ABI specifies that small objects are passed in registers.
// Otherwise they are passed by reference.
static const size_t kRegisterTransferLimit = 16;
static constexpr Register kReturnReg = RAX;
static constexpr Register kSecondReturnReg = kNoRegister;
static constexpr FpuRegister kReturnFpuReg = XMM0;
// Whether larger than wordsize arguments are aligned to even registers.
static constexpr AlignmentStrategy kArgumentRegisterAlignment =
kAlignedToWordSize;
// How stack arguments are aligned.
static constexpr AlignmentStrategy kArgumentStackAlignment =
kAlignedToWordSize;
// How fields in composites are aligned.
static constexpr AlignmentStrategy kFieldAlignment = kAlignedToValueSize;
// Whether 1 or 2 byte-sized arguments or return values are passed extended
// to 4 bytes.
static constexpr ExtensionStrategy kReturnRegisterExtension = kNotExtended;
static constexpr ExtensionStrategy kArgumentRegisterExtension = kNotExtended;
static constexpr ExtensionStrategy kArgumentStackExtension = kNotExtended;
#else
static const Register kArg1Reg = RDI;
static const Register kArg2Reg = RSI;
static const Register kArg3Reg = RDX;
static const Register kArg4Reg = RCX;
static const Register kArg5Reg = R8;
static const Register kArg6Reg = R9;
static const Register ArgumentRegisters[];
static const intptr_t kArgumentRegisters = R(kArg1Reg) | R(kArg2Reg) |
R(kArg3Reg) | R(kArg4Reg) |
R(kArg5Reg) | R(kArg6Reg);
static const intptr_t kNumArgRegs = 6;
static const Register kPointerToReturnStructRegister = kArg1Reg;
static const XmmRegister FpuArgumentRegisters[];
static const intptr_t kFpuArgumentRegisters = R(XMM0) | R(XMM1) | R(XMM2) |
R(XMM3) | R(XMM4) | R(XMM5) |
R(XMM6) | R(XMM7);
static const intptr_t kNumFpuArgRegs = 8;
// can ArgumentRegisters[i] and XmmArgumentRegisters[i] both be used at the
// same time? (Windows no, rest yes)
static const bool kArgumentIntRegXorFpuReg = false;
static const intptr_t kShadowSpaceBytes = 0;
static const intptr_t kVolatileCpuRegisters = R(RAX) | R(RCX) | R(RDX) |
R(RSI) | R(RDI) | R(R8) |
R(R9) | R(R10) | R(R11);
static const intptr_t kVolatileXmmRegisters =
R(XMM0) | R(XMM1) | R(XMM2) | R(XMM3) | R(XMM4) | R(XMM5) | R(XMM6) |
R(XMM7) | R(XMM8) | R(XMM9) | R(XMM10) | R(XMM11) | R(XMM12) | R(XMM13) |
R(XMM14) | R(XMM15);
static const intptr_t kCalleeSaveCpuRegisters =
R(RBX) | R(R12) | R(R13) | R(R14) | R(R15);
static const intptr_t kCalleeSaveXmmRegisters = 0;
static const XmmRegister xmmFirstNonParameterReg = XMM8;
static constexpr Register kReturnReg = RAX;
static constexpr Register kSecondReturnReg = kNoRegister;
static constexpr FpuRegister kReturnFpuReg = XMM0;
// Whether larger than wordsize arguments are aligned to even registers.
static constexpr AlignmentStrategy kArgumentRegisterAlignment =
kAlignedToWordSize;
// How stack arguments are aligned.
static constexpr AlignmentStrategy kArgumentStackAlignment =
kAlignedToWordSize;
// How fields in composites are aligned.
static constexpr AlignmentStrategy kFieldAlignment = kAlignedToValueSize;
// Whether 1 or 2 byte-sized arguments or return values are passed extended
// to 4 bytes.
// Note that `kReturnRegisterExtension != kArgumentRegisterExtension`, which
// effectively means that the caller is responsable for truncating and
// extending both arguments and return value.
static constexpr ExtensionStrategy kReturnRegisterExtension = kNotExtended;
static constexpr ExtensionStrategy kArgumentRegisterExtension = kExtendedTo4;
static constexpr ExtensionStrategy kArgumentStackExtension = kExtendedTo4;
#endif
COMPILE_ASSERT((kArgumentRegisters & kReservedCpuRegisters) == 0);
static constexpr Register kFirstCalleeSavedCpuReg = RBX;
static constexpr Register kFirstNonArgumentRegister = RAX;
static constexpr Register kSecondNonArgumentRegister = RBX;
static constexpr Register kStackPointerRegister = SPREG;
COMPILE_ASSERT(((R(kFirstCalleeSavedCpuReg)) & kCalleeSaveCpuRegisters) != 0);
COMPILE_ASSERT(
((R(kFirstNonArgumentRegister) | R(kSecondNonArgumentRegister)) &
(kArgumentRegisters | R(kPointerToReturnStructRegister))) == 0);
};
#undef R
class Instr {
public:
static const uint8_t kHltInstruction = 0xF4;
// We prefer not to use the int3 instruction since it conflicts with gdb.
static const uint8_t kBreakPointInstruction = kHltInstruction;
static const int kBreakPointInstructionSize = 1;
static const uint8_t kGdbBreakpointInstruction = 0xcc;
bool IsBreakPoint() {
ASSERT(kBreakPointInstructionSize == 1);
return (*reinterpret_cast<const uint8_t*>(this)) == kBreakPointInstruction;
}
// Instructions are read out of a code stream. The only way to get a
// reference to an instruction is to convert a pointer. There is no way
// to allocate or create instances of class Instr.
// Use the At(pc) function to create references to Instr.
static Instr* At(uword pc) { return reinterpret_cast<Instr*>(pc); }
private:
DISALLOW_ALLOCATION();
// We need to prevent the creation of instances of class Instr.
DISALLOW_IMPLICIT_CONSTRUCTORS(Instr);
};
// The largest multibyte nop we will emit. This could go up to 15 if it
// becomes important to us.
const int MAX_NOP_SIZE = 8;
const uword kBreakInstructionFiller = 0xCCCCCCCCCCCCCCCCL;
} // namespace dart
#endif // RUNTIME_VM_CONSTANTS_X64_H_