dart-sdk/runtime/vm/constants_x64.h
Daco Harkes 1854bb00c6 [vm/ffi] Support varargs in the backend
On ARM64 macos and ios, when varargs are used, the first vararg blocks
all cpu and fpu registers.

On Windows x64, when varargs are used, floating point arguments are
passed _both_ in the integer and double register.

The Windows logic requires a new kind of native location:
`BothNativeLocations`, which signals that a value needs to be copied
to both locations before an FFI call, and can be copied from any of
the two locations when getting an FFI callback.
TEST=runtime/vm/compiler/ffi/unit_tests/variadic_double/x64_win.expect

Note that integer arguments already block out the corresponding xmm
registers on Windows x64.

On System-V, an upper bound of the number of XMM registers used must
be passed in AL. (Not reflected in the unit tests here, but will be in
the dependent CL.)

On ARM (32 bit), using varargs forces the calling convention to be in
softfp mode even on hardfp supported devices.

On RISC-V, the FPU registers are blocked when using varargs.

TEST=runtime/vm/compiler/ffi/native_calling_convention_test.cc
Test outputs in: runtime/vm/compiler/ffi/unit_tests/variadic_*
Run test with `tools/test.py ffi_unit`.

Bug: https://github.com/dart-lang/sdk/issues/38578
Change-Id: Ic568f8156c1c28ac3d6a2144805edf8caaa0169c
Cq-Include-Trybots: luci.dart.try:vm-precomp-ffi-qemu-linux-release-arm-try
Reviewed-on: https://dart-review.googlesource.com/c/sdk/+/278342
Reviewed-by: Ryan Macnak <rmacnak@google.com>
2023-01-20 10:30:41 +00:00

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// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#ifndef 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 "platform/utils.h"
#include "vm/constants_base.h"
namespace dart {
#define R(reg) (static_cast<RegList>(1) << (reg))
enum Register {
RAX = 0,
RCX = 1,
RDX = 2,
RBX = 3,
RSP = 4, // SP
RBP = 5, // FP
RSI = 6,
RDI = 7,
R8 = 8,
R9 = 9,
R10 = 10,
R11 = 11, // TMP
R12 = 12, // CODE_REG
R13 = 13,
R14 = 14, // THR
R15 = 15, // PP
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,
kNumberOfByteRegisters = 16,
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 kFpuRegisterSize = 16;
typedef simd128_value_t fpu_register_t;
const int kNumberOfFpuRegisters = kNumberOfXmmRegisters;
const FpuRegister kNoFpuRegister = kNoXmmRegister;
extern const char* const cpu_reg_names[kNumberOfCpuRegisters];
extern const char* const cpu_reg_abi_names[kNumberOfCpuRegisters];
extern const char* const cpu_reg_byte_names[kNumberOfByteRegisters];
extern const char* const 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 IC_DATA_REG = RBX; // ICData/MegamorphicCache register.
const Register ARGS_DESC_REG = R10; // Arguments descriptor register.
const Register CODE_REG = R12;
// Set when calling Dart functions in JIT mode, used by LazyCompileStub.
const Register FUNCTION_REG = RAX;
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;
// Common ABI for shared slow path stubs.
struct SharedSlowPathStubABI {
static const Register kResultReg = RAX;
};
// 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;
static const Register kScratchReg = R9;
};
// Registers in addition to those listed in InstantiationABI used inside the
// implementation of the InstantiateTypeArguments stubs.
struct InstantiateTAVInternalRegs {
// The set of registers that must be pushed/popped when probing a hash-based
// cache due to overlap with the registers in InstantiationABI.
static const intptr_t kSavedRegisters = 0;
// Additional registers used to probe hash-based caches.
static const Register kEntryStartReg = R10;
static const Register kProbeMaskReg = R13;
static const Register kProbeDistanceReg = R8;
static const Register kCurrentEntryIndexReg = RSI;
};
// Registers in addition to those listed in TypeTestABI used inside the
// implementation of type testing stubs that are _not_ preserved.
struct TTSInternalRegs {
static const Register kInstanceTypeArgumentsReg = RSI;
static const Register kScratchReg = R8;
static const Register kSubTypeArgumentReg = R10;
static const Register kSuperTypeArgumentReg = R13;
// Must be pushed/popped whenever generic type arguments are being checked as
// they overlap with registers in TypeTestABI.
static const intptr_t kSavedTypeArgumentRegisters = 0;
static const intptr_t kInternalRegisters =
((1 << kInstanceTypeArgumentsReg) | (1 << kScratchReg) |
(1 << kSubTypeArgumentReg) | (1 << kSuperTypeArgumentReg)) &
~kSavedTypeArgumentRegisters;
};
// Registers in addition to those listed in TypeTestABI used inside the
// implementation of subtype test cache stubs that are _not_ preserved.
struct STCInternalRegs {
static const Register kCacheEntryReg = RDI;
static const Register kInstanceCidOrSignatureReg = R10;
static const Register kInstanceInstantiatorTypeArgumentsReg = R13;
static const intptr_t kInternalRegisters =
(1 << kCacheEntryReg) | (1 << kInstanceCidOrSignatureReg) |
(1 << kInstanceInstantiatorTypeArgumentsReg);
};
// 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;
// For calls to InstanceOfStub.
static const Register kInstanceOfResultReg = kInstanceReg;
// For calls to SubtypeNTestCacheStub. Must not overlap with any other
// registers above, for it is also used internally as kNullReg in those stubs.
static const Register kSubtypeTestCacheResultReg = R8;
// No registers need saving across SubtypeTestCacheStub calls.
static const intptr_t kSubtypeTestCacheStubCallerSavedRegisters = 0;
static const intptr_t kPreservedAbiRegisters =
(1 << kInstanceReg) | (1 << kDstTypeReg) |
(1 << kInstantiatorTypeArgumentsReg) | (1 << kFunctionTypeArgumentsReg);
static const intptr_t kNonPreservedAbiRegisters =
TTSInternalRegs::kInternalRegisters |
STCInternalRegs::kInternalRegisters | (1 << kSubtypeTestCacheReg) |
(1 << kScratchReg) | (1 << kSubtypeTestCacheResultReg) | (1 << CODE_REG);
static const intptr_t kAbiRegisters =
kPreservedAbiRegisters | kNonPreservedAbiRegisters;
};
// Calling convention when calling AssertSubtypeStub.
struct AssertSubtypeABI {
static const Register kSubTypeReg = RAX;
static const Register kSuperTypeReg = RBX;
static const Register kInstantiatorTypeArgumentsReg = RDX;
static const Register kFunctionTypeArgumentsReg = RCX;
static const Register kDstNameReg = R9;
static const intptr_t kAbiRegisters =
(1 << kSubTypeReg) | (1 << kSuperTypeReg) |
(1 << kInstantiatorTypeArgumentsReg) | (1 << kFunctionTypeArgumentsReg) |
(1 << kDstNameReg);
// No result register, as AssertSubtype is only run for side effect
// (throws if the subtype check fails).
};
// ABI for InitStaticFieldStub.
struct InitStaticFieldABI {
static const Register kFieldReg = RDX;
static const Register kResultReg = RAX;
};
// Registers used inside the implementation of InitLateStaticFieldStub.
struct InitLateStaticFieldInternalRegs {
static const Register kAddressReg = RCX;
static const Register kScratchReg = RSI;
};
// 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 kAddressReg = RCX;
static const Register kScratchReg = RSI;
};
// ABI for LateInitializationError stubs.
struct LateInitializationErrorABI {
static const Register kFieldReg = 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 AllocateObjectStub.
struct AllocateObjectABI {
static const Register kResultReg = RAX;
static const Register kTypeArgumentsReg = RDX;
static const Register kTagsReg = R8;
};
// ABI for AllocateClosureStub.
struct AllocateClosureABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kFunctionReg = RBX;
static const Register kContextReg = RDX;
static const Register kScratchReg = R13;
};
// ABI for AllocateMintShared*Stub.
struct AllocateMintABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kTempReg = RBX;
};
// ABI for Allocate{Mint,Double,Float32x4,Float64x2}Stub.
struct AllocateBoxABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kTempReg = RBX;
};
// ABI for AllocateArrayStub.
struct AllocateArrayABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kLengthReg = R10;
static const Register kTypeArgumentsReg = RBX;
};
// ABI for AllocateRecordStub.
struct AllocateRecordABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kShapeReg = RBX;
static const Register kTemp1Reg = RDX;
static const Register kTemp2Reg = RCX;
};
// ABI for AllocateSmallRecordStub (AllocateRecord2, AllocateRecord2Named,
// AllocateRecord3, AllocateRecord3Named).
struct AllocateSmallRecordABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kShapeReg = R10;
static const Register kValue0Reg = RBX;
static const Register kValue1Reg = RDX;
static const Register kValue2Reg = RCX;
static const Register kTempReg = RDI;
};
// ABI for AllocateTypedDataArrayStub.
struct AllocateTypedDataArrayABI {
static const Register kResultReg = AllocateObjectABI::kResultReg;
static const Register kLengthReg = kResultReg;
};
// ABI for BoxDoubleStub.
struct BoxDoubleStubABI {
static const FpuRegister kValueReg = XMM0;
static const Register kTempReg = RBX;
static const Register kResultReg = RAX;
};
// ABI for DoubleToIntegerStub.
struct DoubleToIntegerStubABI {
static const FpuRegister kInputReg = XMM0;
static const Register kRecognizedKindReg = RAX;
static const Register kResultReg = RAX;
};
// ABI for SuspendStub (AwaitStub, AwaitWithTypeCheckStub, YieldAsyncStarStub,
// SuspendSyncStarAtStartStub, SuspendSyncStarAtYieldStub).
struct SuspendStubABI {
static const Register kArgumentReg = RAX;
static const Register kTypeArgsReg = RDX; // Can be the same as kTempReg
static const Register kTempReg = RDX;
static const Register kFrameSizeReg = RCX;
static const Register kSuspendStateReg = RBX;
static const Register kFunctionDataReg = R8;
static const Register kSrcFrameReg = RSI;
static const Register kDstFrameReg = RDI;
// Number of bytes to skip after
// suspend stub return address in order to resume.
// X64: mov rsp, rbp; pop rbp; ret
static const intptr_t kResumePcDistance = 5;
};
// ABI for InitSuspendableFunctionStub (InitAsyncStub, InitAsyncStarStub,
// InitSyncStarStub).
struct InitSuspendableFunctionStubABI {
static const Register kTypeArgsReg = RAX;
};
// ABI for ResumeStub
struct ResumeStubABI {
static const Register kSuspendStateReg = RBX;
static const Register kTempReg = RDX;
// Registers for the frame copying (the 1st part).
static const Register kFrameSizeReg = RCX;
static const Register kSrcFrameReg = RSI;
static const Register kDstFrameReg = RDI;
// Registers for control transfer.
// (the 2nd part, can reuse registers from the 1st part)
static const Register kResumePcReg = RCX;
// Can also reuse kSuspendStateReg but should not conflict with CODE_REG/PP.
static const Register kExceptionReg = RSI;
static const Register kStackTraceReg = RDI;
};
// ABI for ReturnStub (ReturnAsyncStub, ReturnAsyncNotFutureStub,
// ReturnAsyncStarStub).
struct ReturnStubABI {
static const Register kSuspendStateReg = RBX;
};
// ABI for AsyncExceptionHandlerStub.
struct AsyncExceptionHandlerStubABI {
static const Register kSuspendStateReg = RBX;
};
// ABI for CloneSuspendStateStub.
struct CloneSuspendStateStubABI {
static const Register kSourceReg = RAX;
static const Register kDestinationReg = RBX;
static const Register kTempReg = RDX;
static const Register kFrameSizeReg = RCX;
static const Register kSrcFrameReg = RSI;
static const Register kDstFrameReg = RDI;
};
// ABI for DispatchTableNullErrorStub and consequently for all dispatch
// table calls (though normal functions will not expect or use this
// register). This ABI is added to distinguish memory corruption errors from
// null errors.
struct DispatchTableNullErrorABI {
static const Register kClassIdReg = RCX;
};
typedef uint32_t RegList;
const RegList kAllCpuRegistersList = 0xFFFF;
const RegList kAllFpuRegistersList = 0xFFFF;
const RegList kReservedCpuRegisters =
R(SPREG) | R(FPREG) | R(TMP) | R(PP) | R(THR);
constexpr intptr_t kNumberOfReservedCpuRegisters =
Utils::CountOneBits32(kReservedCpuRegisters);
// CPU registers available to Dart allocator.
const RegList kDartAvailableCpuRegs =
kAllCpuRegistersList & ~kReservedCpuRegisters;
constexpr int kNumberOfDartAvailableCpuRegs =
kNumberOfCpuRegisters - kNumberOfReservedCpuRegisters;
// Low numbered registers sometimes require fewer prefixes.
constexpr int kRegisterAllocationBias = 0;
constexpr int kStoreBufferWrapperSize = 13;
#if defined(DART_TARGET_OS_WINDOWS)
const RegList kAbiPreservedCpuRegs =
R(RBX) | R(RSI) | R(RDI) | R(R12) | R(R13) | R(R14) | R(R15);
const RegList kAbiVolatileFpuRegs =
R(XMM0) | R(XMM1) | R(XMM2) | R(XMM3) | R(XMM4) | R(XMM5);
#else
const RegList kAbiPreservedCpuRegs = R(RBX) | R(R12) | R(R13) | R(R14) | R(R15);
const RegList kAbiVolatileFpuRegs = kAllFpuRegistersList;
#endif
// Registers available to Dart that are not preserved by runtime calls.
const RegList kDartVolatileCpuRegs =
kDartAvailableCpuRegs & ~kAbiPreservedCpuRegs;
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,
// We can't include vm/compiler/runtime_api.h, so just be explicit instead
// of using (dart::)kWordSizeLog2.
#if defined(TARGET_ARCH_IS_64_BIT)
// Used for Smi-boxed indices.
TIMES_HALF_WORD_SIZE = kInt64SizeLog2 - 1,
// Used for unboxed indices.
TIMES_WORD_SIZE = kInt64SizeLog2,
#else
#error "Unexpected word size"
#endif
#if !defined(DART_COMPRESSED_POINTERS)
TIMES_COMPRESSED_WORD_SIZE = TIMES_WORD_SIZE,
#else
TIMES_COMPRESSED_WORD_SIZE = TIMES_HALF_WORD_SIZE,
#endif
// Used for Smi-boxed indices.
TIMES_COMPRESSED_HALF_WORD_SIZE = TIMES_COMPRESSED_WORD_SIZE - 1,
};
class CallingConventions {
public:
#if defined(DART_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 Register kPointerToReturnStructRegisterCall = kArg1Reg;
static const XmmRegister FpuArgumentRegisters[];
static const intptr_t kFpuArgumentRegisters =
R(XMM0) | R(XMM1) | R(XMM2) | R(XMM3);
static const intptr_t kNumFpuArgRegs = 4;
// Whether ArgumentRegisters[i] prevents using XmmArgumentRegisters[i] at the
// same time and vice versa.
static const bool kArgumentIntRegXorFpuReg = true;
// AL not set on vararg calls in Windows.
static const Register kVarArgFpuRegisterCount = kNoRegister;
// > The x64 Application Binary Interface (ABI) uses a four-register
// > fast-call calling convention by default. Space is allocated on the call
// > stack as a shadow store for callees to save those registers.
// https://docs.microsoft.com/en-us/cpp/build/x64-calling-convention?view=msvc-160
//
// The caller allocates this space. The caller should also reclaim this space
// after the call to restore the stack to its original state if needed.
//
// This is also known as home space.
// https://devblogs.microsoft.com/oldnewthing/20160623-00/?p=93735
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 RegList kVolatileXmmRegisters = kAbiVolatileFpuRegs;
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 = RDX;
static constexpr FpuRegister kReturnFpuReg = XMM0;
static constexpr Register kPointerToReturnStructRegisterReturn = kReturnReg;
// Whether larger than wordsize arguments are aligned to even registers.
static constexpr AlignmentStrategy kArgumentRegisterAlignment =
kAlignedToWordSize;
static constexpr AlignmentStrategy kArgumentRegisterAlignmentVarArgs =
kArgumentRegisterAlignment;
// How stack arguments are aligned.
static constexpr AlignmentStrategy kArgumentStackAlignment =
kAlignedToWordSize;
// How fields in compounds 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 kPointerToReturnStructRegisterCall = 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;
// Whether ArgumentRegisters[i] prevents using XmmArgumentRegisters[i] at the
// same time and vice versa.
static const bool kArgumentIntRegXorFpuReg = false;
// > For calls that may call functions that use varargs or stdargs
// > (prototype-less calls or calls to functions containing ellipsis (...) in
// > the declaration) %al16 is used as hidden argument to specify the number
// > of vector registers used. The contents of %al do not need to match
// > exactly the number of registers, but must be an upper bound on the number
// > of vector registers used and is in the range 08 inclusive.
// System V ABI spec.
static const Register kVarArgFpuRegisterCount = RAX;
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 RegList kVolatileXmmRegisters = kAbiVolatileFpuRegs;
static const intptr_t kCalleeSaveXmmRegisters = 0;
static const XmmRegister xmmFirstNonParameterReg = XMM8;
static constexpr Register kReturnReg = RAX;
static constexpr Register kSecondReturnReg = RDX;
static constexpr FpuRegister kReturnFpuReg = XMM0;
static constexpr FpuRegister kSecondReturnFpuReg = XMM1;
static constexpr Register kPointerToReturnStructRegisterReturn = kReturnReg;
// Whether larger than wordsize arguments are aligned to even registers.
static constexpr AlignmentStrategy kArgumentRegisterAlignment =
kAlignedToWordSize;
static constexpr AlignmentStrategy kArgumentRegisterAlignmentVarArgs =
kArgumentRegisterAlignment;
// How stack arguments are aligned.
static constexpr AlignmentStrategy kArgumentStackAlignment =
kAlignedToWordSize;
// How fields in compounds 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
static const intptr_t kCalleeSaveCpuRegisters = kAbiPreservedCpuRegs;
COMPILE_ASSERT((kArgumentRegisters & kReservedCpuRegisters) == 0);
static constexpr Register kFfiAnyNonAbiRegister = R12;
static constexpr Register kFirstNonArgumentRegister = RAX;
static constexpr Register kSecondNonArgumentRegister = RBX;
static constexpr Register kStackPointerRegister = SPREG;
COMPILE_ASSERT(((R(kFfiAnyNonAbiRegister)) & kCalleeSaveCpuRegisters) != 0);
COMPILE_ASSERT(
((R(kFirstNonArgumentRegister) | R(kSecondNonArgumentRegister)) &
(kArgumentRegisters | R(kPointerToReturnStructRegisterCall))) == 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 uint64_t kBreakInstructionFiller = 0xCCCCCCCCCCCCCCCCL;
} // namespace dart
#endif // RUNTIME_VM_CONSTANTS_X64_H_