Defcon/hook_lib/asmjit/core/operand.h
MatrixMMOfficial 9631e4ca40 Initial commit
2023-11-26 08:54:06 -05:00

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// This file is part of AsmJit project <https://asmjit.com>
//
// See asmjit.h or LICENSE.md for license and copyright information
// SPDX-License-Identifier: Zlib
#ifndef ASMJIT_CORE_OPERAND_H_INCLUDED
#define ASMJIT_CORE_OPERAND_H_INCLUDED
#include "../core/archcommons.h"
#include "../core/support.h"
#include "../core/type.h"
ASMJIT_BEGIN_NAMESPACE
//! \addtogroup asmjit_assembler
//! \{
//! Operand type used by \ref Operand_.
enum class OperandType : uint32_t {
//! Not an operand or not initialized.
kNone = 0,
//! Operand is a register.
kReg = 1,
//! Operand is a memory.
kMem = 2,
//! Operand is an immediate value.
kImm = 3,
//! Operand is a label.
kLabel = 4,
//! Maximum value of `OperandType`.
kMaxValue = kLabel
};
static_assert(uint32_t(OperandType::kMem) == uint32_t(OperandType::kReg) + 1,
"AsmJit requires that `OperandType::kMem` equals to `OperandType::kReg + 1`");
//! Register mask is a convenience typedef that describes a mask where each bit describes a physical register id
//! in the same \ref RegGroup. At the moment 32 bits are enough as AsmJit doesn't support any architecture that
//! would provide more than 32 registers for a register group.
typedef uint32_t RegMask;
//! Register type.
//!
//! Provides a unique type that can be used to identify a register or its view.
enum class RegType : uint8_t {
//! No register - unused, invalid, multiple meanings.
kNone = 0,
//! This is not a register type. This value is reserved for a \ref Label that used in \ref BaseMem as a base.
//!
//! Label tag is used as a sub-type, forming a unique signature across all operand types as 0x1 is never associated
//! with any register type. This means that a memory operand's BASE register can be constructed from virtually any
//! operand (register vs. label) by just assigning its type (register type or label-tag) and operand id.
kLabelTag = 1,
//! Universal type describing program counter (PC) or instruction pointer (IP) register, if the target architecture
//! actually exposes it as a separate register type, which most modern targets do.
kPC = 2,
//! 8-bit low general purpose register (X86).
kGp8Lo = 3,
//! 8-bit high general purpose register (X86).
kGp8Hi = 4,
//! 16-bit general purpose register (X86).
kGp16 = 5,
//! 32-bit general purpose register (X86|ARM).
kGp32 = 6,
//! 64-bit general purpose register (X86|ARM).
kGp64 = 7,
//! 8-bit view of a vector register (ARM).
kVec8 = 8,
//! 16-bit view of a vector register (ARM).
kVec16 = 9,
//! 32-bit view of a vector register (ARM).
kVec32 = 10,
//! 64-bit view of a vector register (ARM).
//!
//! \note This is never used for MMX registers on X86, MMX registers have its own category.
kVec64 = 11,
//! 128-bit view of a vector register (X86|ARM).
kVec128 = 12,
//! 256-bit view of a vector register (X86).
kVec256 = 13,
//! 512-bit view of a vector register (X86).
kVec512 = 14,
//! 1024-bit view of a vector register (future).
kVec1024 = 15,
//! View of a vector register, which width is implementation specific (AArch64).
kVecNLen = 16,
//! Mask register (X86).
kMask = 17,
//! Start of architecture dependent register types.
kExtra = 18,
// X86 Specific Register Types
// ---------------------------
// X86 Specific Register Types
// ===========================
//! Instruction pointer (RIP), only addressable in \ref x86::Mem in 64-bit targets.
kX86_Rip = kPC,
//! Low GPB register (AL, BL, CL, DL, ...).
kX86_GpbLo = kGp8Lo,
//! High GPB register (AH, BH, CH, DH only).
kX86_GpbHi = kGp8Hi,
//! GPW register.
kX86_Gpw = kGp16,
//! GPD register.
kX86_Gpd = kGp32,
//! GPQ register (64-bit).
kX86_Gpq = kGp64,
//! XMM register (SSE+).
kX86_Xmm = kVec128,
//! YMM register (AVX+).
kX86_Ymm = kVec256,
//! ZMM register (AVX512+).
kX86_Zmm = kVec512,
//! K register (AVX512+).
kX86_KReg = kMask,
//! MMX register.
kX86_Mm = kExtra + 0,
//! Segment register (None, ES, CS, SS, DS, FS, GS).
kX86_SReg = kExtra + 1,
//! Control register (CR).
kX86_CReg = kExtra + 2,
//! Debug register (DR).
kX86_DReg = kExtra + 3,
//! FPU (x87) register.
kX86_St = kExtra + 4,
//! Bound register (BND).
kX86_Bnd = kExtra + 5,
//! TMM register (AMX_TILE)
kX86_Tmm = kExtra + 6,
// ARM Specific Register Types
// ===========================
//! Program pointer (PC) register (AArch64).
kARM_PC = kPC,
//! 32-bit general purpose register (R or W).
kARM_GpW = kGp32,
//! 64-bit general purpose register (X).
kARM_GpX = kGp64,
//! 8-bit view of VFP/ASIMD register (B).
kARM_VecB = kVec8,
//! 16-bit view of VFP/ASIMD register (H).
kARM_VecH = kVec16,
//! 32-bit view of VFP/ASIMD register (S).
kARM_VecS = kVec32,
//! 64-bit view of VFP/ASIMD register (D).
kARM_VecD = kVec64,
//! 128-bit view of VFP/ASIMD register (Q|V).
kARM_VecV = kVec128,
//! Maximum value of `RegType`.
kMaxValue = 31
};
ASMJIT_DEFINE_ENUM_COMPARE(RegType)
//! Register group.
//!
//! Provides a unique value that identifies groups of registers and their views.
enum class RegGroup : uint8_t {
//! General purpose register group compatible with all backends.
kGp = 0,
//! Vector register group compatible with all backends.
//!
//! Describes X86 XMM|YMM|ZMM registers ARM/AArch64 V registers.
kVec = 1,
//! Extra virtual group #2 that can be used by Compiler for register allocation.
kExtraVirt2 = 2,
//! Extra virtual group #3 that can be used by Compiler for register allocation.
kExtraVirt3 = 3,
//! Program counter group.
kPC = 4,
//! Extra non-virtual group that can be used by registers not managed by Compiler.
kExtraNonVirt = 5,
// X86 Specific Register Groups
// ----------------------------
//! K register group (KReg) - maps to \ref RegGroup::kExtraVirt2 (X86, X86_64).
kX86_K = kExtraVirt2,
//! MMX register group (MM) - maps to \ref RegGroup::kExtraVirt3 (X86, X86_64).
kX86_MM = kExtraVirt3,
//! Instruction pointer (X86, X86_64).
kX86_Rip = kPC,
//! Segment register group (X86, X86_64).
kX86_SReg = kExtraNonVirt + 0,
//! CR register group (X86, X86_64).
kX86_CReg = kExtraNonVirt + 1,
//! DR register group (X86, X86_64).
kX86_DReg = kExtraNonVirt + 2,
//! FPU register group (X86, X86_64).
kX86_St = kExtraNonVirt + 3,
//! BND register group (X86, X86_64).
kX86_Bnd = kExtraNonVirt + 4,
//! TMM register group (X86, X86_64).
kX86_Tmm = kExtraNonVirt + 5,
//! First group - only used in loops.
k0 = 0,
//! Last value of a virtual register that is managed by \ref BaseCompiler.
kMaxVirt = Globals::kNumVirtGroups - 1,
//! Maximum value of `RegGroup`.
kMaxValue = 15
};
ASMJIT_DEFINE_ENUM_COMPARE(RegGroup)
typedef Support::EnumValues<RegGroup, RegGroup::kGp, RegGroup::kMaxVirt> RegGroupVirtValues;
//! Operand signature is a 32-bit number describing \ref Operand and some of its payload.
//!
//! In AsmJit operand signature is used to store additional payload of register, memory, and immediate operands.
//! In practice the biggest pressure on OperandSignature is from \ref BaseMem and architecture specific memory
//! operands that need to store additional payload that cannot be stored elsewhere as values of all other members
//! are fully specified by \ref BaseMem.
struct OperandSignature {
//! \name Constants
//! \{
enum : uint32_t {
// Operand type (3 least significant bits).
// |........|........|........|.....XXX|
kOpTypeShift = 0,
kOpTypeMask = 0x07u << kOpTypeShift,
// Register type (5 bits).
// |........|........|........|XXXXX...|
kRegTypeShift = 3,
kRegTypeMask = 0x1Fu << kRegTypeShift,
// Register group (4 bits).
// |........|........|....XXXX|........|
kRegGroupShift = 8,
kRegGroupMask = 0x0Fu << kRegGroupShift,
// Memory base type (5 bits).
// |........|........|........|XXXXX...|
kMemBaseTypeShift = 3,
kMemBaseTypeMask = 0x1Fu << kMemBaseTypeShift,
// Memory index type (5 bits).
// |........|........|...XXXXX|........|
kMemIndexTypeShift = 8,
kMemIndexTypeMask = 0x1Fu << kMemIndexTypeShift,
// Memory base+index combined (10 bits).
// |........|........|...XXXXX|XXXXX...|
kMemBaseIndexShift = 3,
kMemBaseIndexMask = 0x3FFu << kMemBaseIndexShift,
// This memory operand represents a home-slot or stack (Compiler) (1 bit).
// |........|........|..X.....|........|
kMemRegHomeShift = 13,
kMemRegHomeFlag = 0x01u << kMemRegHomeShift,
// Immediate type (1 bit).
// |........|........|........|....X...|
kImmTypeShift = 3,
kImmTypeMask = 0x01u << kImmTypeShift,
// Predicate used by either registers or immediate values (4 bits).
// |........|XXXX....|........|........|
kPredicateShift = 20,
kPredicateMask = 0x0Fu << kPredicateShift,
// Operand size (8 most significant bits).
// |XXXXXXXX|........|........|........|
kSizeShift = 24,
kSizeMask = 0xFFu << kSizeShift
};
//! \}
//! \name Members
//! \{
uint32_t _bits;
//! \}
//! \name Overloaded Operators
//!
//! Overloaded operators make `OperandSignature` behave like regular integer.
//!
//! \{
inline constexpr bool operator!() const noexcept { return _bits != 0; }
inline constexpr explicit operator bool() const noexcept { return _bits != 0; }
inline OperandSignature& operator|=(uint32_t x) noexcept { _bits |= x; return *this; }
inline OperandSignature& operator&=(uint32_t x) noexcept { _bits &= x; return *this; }
inline OperandSignature& operator^=(uint32_t x) noexcept { _bits ^= x; return *this; }
inline OperandSignature& operator|=(const OperandSignature& other) noexcept { return operator|=(other._bits); }
inline OperandSignature& operator&=(const OperandSignature& other) noexcept { return operator&=(other._bits); }
inline OperandSignature& operator^=(const OperandSignature& other) noexcept { return operator^=(other._bits); }
inline constexpr OperandSignature operator~() const noexcept { return OperandSignature{~_bits}; }
inline constexpr OperandSignature operator|(uint32_t x) const noexcept { return OperandSignature{_bits | x}; }
inline constexpr OperandSignature operator&(uint32_t x) const noexcept { return OperandSignature{_bits & x}; }
inline constexpr OperandSignature operator^(uint32_t x) const noexcept { return OperandSignature{_bits ^ x}; }
inline constexpr OperandSignature operator|(const OperandSignature& other) const noexcept { return OperandSignature{_bits | other._bits}; }
inline constexpr OperandSignature operator&(const OperandSignature& other) const noexcept { return OperandSignature{_bits & other._bits}; }
inline constexpr OperandSignature operator^(const OperandSignature& other) const noexcept { return OperandSignature{_bits ^ other._bits}; }
inline constexpr bool operator==(uint32_t x) const noexcept { return _bits == x; }
inline constexpr bool operator!=(uint32_t x) const noexcept { return _bits != x; }
inline constexpr bool operator==(const OperandSignature& other) const noexcept { return _bits == other._bits; }
inline constexpr bool operator!=(const OperandSignature& other) const noexcept { return _bits != other._bits; }
//! \}
//! \name Accessors
//! \{
inline void reset() noexcept { _bits = 0; }
inline constexpr uint32_t bits() const noexcept { return _bits; }
inline void setBits(uint32_t bits) noexcept { _bits = bits; }
template<uint32_t kFieldMask, uint32_t kFieldShift = Support::ConstCTZ<kFieldMask>::value>
inline constexpr bool hasField() const noexcept {
return (_bits & kFieldMask) != 0;
}
template<uint32_t kFieldMask, uint32_t kFieldShift = Support::ConstCTZ<kFieldMask>::value>
inline constexpr bool hasField(uint32_t value) const noexcept {
return (_bits & kFieldMask) != value << kFieldShift;
}
template<uint32_t kFieldMask, uint32_t kFieldShift = Support::ConstCTZ<kFieldMask>::value>
inline constexpr uint32_t getField() const noexcept {
return (_bits >> kFieldShift) & (kFieldMask >> kFieldShift);
}
template<uint32_t kFieldMask, uint32_t kFieldShift = Support::ConstCTZ<kFieldMask>::value>
inline void setField(uint32_t value) noexcept {
ASMJIT_ASSERT((value & ~(kFieldMask >> kFieldShift)) == 0);
_bits = (_bits & ~kFieldMask) | (value << kFieldShift);
}
inline constexpr OperandSignature subset(uint32_t mask) const noexcept { return OperandSignature{_bits & mask}; }
template<uint32_t kFieldMask>
inline constexpr bool matchesSignature(const OperandSignature& signature) const noexcept {
return (_bits & kFieldMask) == signature._bits;
}
template<uint32_t kFieldMask>
inline constexpr bool matchesFields(uint32_t bits) const noexcept {
return (_bits & kFieldMask) == bits;
}
template<uint32_t kFieldMask>
inline constexpr bool matchesFields(const OperandSignature& fields) const noexcept {
return (_bits & kFieldMask) == fields._bits;
}
inline constexpr bool isValid() const noexcept { return _bits != 0; }
inline constexpr OperandType opType() const noexcept { return (OperandType)getField<kOpTypeMask>(); }
inline constexpr RegType regType() const noexcept { return (RegType)getField<kRegTypeMask>(); }
inline constexpr RegGroup regGroup() const noexcept { return (RegGroup)getField<kRegGroupMask>(); }
inline constexpr RegType memBaseType() const noexcept { return (RegType)getField<kMemBaseTypeMask>(); }
inline constexpr RegType memIndexType() const noexcept { return (RegType)getField<kMemIndexTypeMask>(); }
inline constexpr uint32_t predicate() const noexcept { return getField<kPredicateMask>(); }
inline constexpr uint32_t size() const noexcept { return getField<kSizeMask>(); }
inline void setOpType(OperandType opType) noexcept { setField<kOpTypeMask>(uint32_t(opType)); }
inline void setRegType(RegType regType) noexcept { setField<kRegTypeMask>(uint32_t(regType)); }
inline void setRegGroup(RegGroup regGroup) noexcept { setField<kRegGroupMask>(uint32_t(regGroup)); }
inline void setMemBaseType(RegGroup baseType) noexcept { setField<kMemBaseTypeMask>(uint32_t(baseType)); }
inline void setMemIndexType(RegGroup indexType) noexcept { setField<kMemIndexTypeMask>(uint32_t(indexType)); }
inline void setPredicate(uint32_t predicate) noexcept { setField<kPredicateMask>(predicate); }
inline void setSize(uint32_t size) noexcept { setField<kSizeMask>(size); }
//! \}
//! \name Static Constructors
//! \{
static inline constexpr OperandSignature fromBits(uint32_t bits) noexcept {
return OperandSignature{bits};
}
template<uint32_t kFieldMask, typename T>
static inline constexpr OperandSignature fromValue(const T& value) noexcept {
return OperandSignature{uint32_t(value) << Support::ConstCTZ<kFieldMask>::value};
}
static inline constexpr OperandSignature fromOpType(OperandType opType) noexcept {
return OperandSignature{uint32_t(opType) << kOpTypeShift};
}
static inline constexpr OperandSignature fromRegType(RegType regType) noexcept {
return OperandSignature{uint32_t(regType) << kRegTypeShift};
}
static inline constexpr OperandSignature fromRegGroup(RegGroup regGroup) noexcept {
return OperandSignature{uint32_t(regGroup) << kRegGroupShift};
}
static inline constexpr OperandSignature fromRegTypeAndGroup(RegType regType, RegGroup regGroup) noexcept {
return fromRegType(regType) | fromRegGroup(regGroup);
}
static inline constexpr OperandSignature fromMemBaseType(RegType baseType) noexcept {
return OperandSignature{uint32_t(baseType) << kMemBaseTypeShift};
}
static inline constexpr OperandSignature fromMemIndexType(RegType indexType) noexcept {
return OperandSignature{uint32_t(indexType) << kMemIndexTypeShift};
}
static inline constexpr OperandSignature fromPredicate(uint32_t predicate) noexcept {
return OperandSignature{predicate << kPredicateShift};
}
static inline constexpr OperandSignature fromSize(uint32_t size) noexcept {
return OperandSignature{size << kSizeShift};
}
//! \}
};
//! Base class representing an operand in AsmJit (non-default constructed version).
//!
//! Contains no initialization code and can be used safely to define an array of operands that won't be initialized.
//! This is a \ref Operand base structure designed to be statically initialized, static const, or to be used by user
//! code to define an array of operands without having them default initialized at construction time.
//!
//! The key difference between \ref Operand and \ref Operand_ is:
//!
//! ```
//! Operand_ xArray[10]; // Not initialized, contains garbage.
//! Operand_ yArray[10] {}; // All operands initialized to none explicitly (zero initialized).
//! Operand yArray[10]; // All operands initialized to none implicitly (zero initialized).
//! ```
struct Operand_ {
//! \name Types
//! \{
typedef OperandSignature Signature;
//! \}
//! \name Constants
//! \{
// Indexes to `_data` array.
enum DataIndex : uint32_t {
kDataMemIndexId = 0,
kDataMemOffsetLo = 1,
kDataImmValueLo = ASMJIT_ARCH_LE ? 0 : 1,
kDataImmValueHi = ASMJIT_ARCH_LE ? 1 : 0
};
//! Constants useful for VirtId <-> Index translation.
enum VirtIdConstants : uint32_t {
//! Minimum valid packed-id.
kVirtIdMin = 256,
//! Maximum valid packed-id, excludes Globals::kInvalidId.
kVirtIdMax = Globals::kInvalidId - 1,
//! Count of valid packed-ids.
kVirtIdCount = uint32_t(kVirtIdMax - kVirtIdMin + 1)
};
//! \}
//! \name Members
//! \{
//! Provides operand type and additional payload.
Signature _signature;
//! Either base id as used by memory operand or any id as used by others.
uint32_t _baseId;
//! Data specific to the operand type.
//!
//! The reason we don't use union is that we have `constexpr` constructors that construct operands and other
//!`constexpr` functions that return whether another Operand or something else. These cannot generally work with
//! unions so we also cannot use `union` if we want to be standard compliant.
uint32_t _data[2];
//! \}
//! Tests whether the given `id` is a valid virtual register id. Since AsmJit supports both physical and virtual
//! registers it must be able to distinguish between these two. The idea is that physical registers are always
//! limited in size, so virtual identifiers start from `kVirtIdMin` and end at `kVirtIdMax`.
static inline bool isVirtId(uint32_t id) noexcept { return id - kVirtIdMin < uint32_t(kVirtIdCount); }
//! Converts a real-id into a packed-id that can be stored in Operand.
static inline uint32_t indexToVirtId(uint32_t id) noexcept { return id + kVirtIdMin; }
//! Converts a packed-id back to real-id.
static inline uint32_t virtIdToIndex(uint32_t id) noexcept { return id - kVirtIdMin; }
//! \name Construction & Destruction
//! \{
//! \cond INTERNAL
//! Initializes a `BaseReg` operand from `signature` and register `id`.
inline void _initReg(const Signature& signature, uint32_t id) noexcept {
_signature = signature;
_baseId = id;
_data[0] = 0;
_data[1] = 0;
}
//! \endcond
//! Initializes the operand from `other` operand (used by operator overloads).
inline void copyFrom(const Operand_& other) noexcept { memcpy(this, &other, sizeof(Operand_)); }
//! Resets the `Operand` to none.
//!
//! None operand is defined the following way:
//! - Its signature is zero (OperandType::kNone, and the rest zero as well).
//! - Its id is `0`.
//! - The reserved8_4 field is set to `0`.
//! - The reserved12_4 field is set to zero.
//!
//! In other words, reset operands have all members set to zero. Reset operand must match the Operand state
//! right after its construction. Alternatively, if you have an array of operands, you can simply use `memset()`.
//!
//! ```
//! using namespace asmjit;
//!
//! Operand a;
//! Operand b;
//! assert(a == b);
//!
//! b = x86::eax;
//! assert(a != b);
//!
//! b.reset();
//! assert(a == b);
//!
//! memset(&b, 0, sizeof(Operand));
//! assert(a == b);
//! ```
inline void reset() noexcept {
_signature.reset();
_baseId = 0;
_data[0] = 0;
_data[1] = 0;
}
//! \}
//! \name Overloaded Operators
//! \{
//! Tests whether this operand is the same as `other`.
inline constexpr bool operator==(const Operand_& other) const noexcept { return equals(other); }
//! Tests whether this operand is not the same as `other`.
inline constexpr bool operator!=(const Operand_& other) const noexcept { return !equals(other); }
//! \}
//! \name Cast
//! \{
//! Casts this operand to `T` type.
template<typename T>
inline T& as() noexcept { return static_cast<T&>(*this); }
//! Casts this operand to `T` type (const).
template<typename T>
inline const T& as() const noexcept { return static_cast<const T&>(*this); }
//! \}
//! \name Accessors
//! \{
//! Tests whether the operand's signature matches the signature of the `other` operand.
inline constexpr bool hasSignature(const Operand_& other) const noexcept { return _signature == other._signature; }
//! Tests whether the operand's signature matches the given signature `sign`.
inline constexpr bool hasSignature(const Signature& other) const noexcept { return _signature == other; }
//! Returns operand signature as unsigned 32-bit integer.
//!
//! Signature is first 4 bytes of the operand data. It's used mostly for operand checking as it's
//! much faster to check packed 4 bytes at once than having to check these bytes individually.
inline constexpr Signature signature() const noexcept { return _signature; }
//! Sets the operand signature, see `signature()`.
//!
//! \note Improper use of `setSignature()` can lead to hard-to-debug errors.
inline void setSignature(const Signature& signature) noexcept { _signature = signature; }
//! Returns the type of the operand, see `OpType`.
inline constexpr OperandType opType() const noexcept { return _signature.opType(); }
//! Tests whether the operand is none (`OperandType::kNone`).
inline constexpr bool isNone() const noexcept { return _signature == Signature::fromBits(0); }
//! Tests whether the operand is a register (`OperandType::kReg`).
inline constexpr bool isReg() const noexcept { return opType() == OperandType::kReg; }
//! Tests whether the operand is a memory location (`OperandType::kMem`).
inline constexpr bool isMem() const noexcept { return opType() == OperandType::kMem; }
//! Tests whether the operand is an immediate (`OperandType::kImm`).
inline constexpr bool isImm() const noexcept { return opType() == OperandType::kImm; }
//! Tests whether the operand is a label (`OperandType::kLabel`).
inline constexpr bool isLabel() const noexcept { return opType() == OperandType::kLabel; }
//! Tests whether the operand is a physical register.
inline constexpr bool isPhysReg() const noexcept { return isReg() && _baseId < 0xFFu; }
//! Tests whether the operand is a virtual register.
inline constexpr bool isVirtReg() const noexcept { return isReg() && _baseId > 0xFFu; }
//! Tests whether the operand specifies a size (i.e. the size is not zero).
inline constexpr bool hasSize() const noexcept { return _signature.hasField<Signature::kSizeMask>(); }
//! Tests whether the size of the operand matches `size`.
inline constexpr bool hasSize(uint32_t s) const noexcept { return size() == s; }
//! Returns the size of the operand in bytes.
//!
//! The value returned depends on the operand type:
//! * None - Should always return zero size.
//! * Reg - Should always return the size of the register. If the register size depends on architecture
//! (like `x86::CReg` and `x86::DReg`) the size returned should be the greatest possible (so it
//! should return 64-bit size in such case).
//! * Mem - Size is optional and will be in most cases zero.
//! * Imm - Should always return zero size.
//! * Label - Should always return zero size.
inline constexpr uint32_t size() const noexcept { return _signature.getField<Signature::kSizeMask>(); }
//! Returns the operand id.
//!
//! The value returned should be interpreted accordingly to the operand type:
//! * None - Should be `0`.
//! * Reg - Physical or virtual register id.
//! * Mem - Multiple meanings - BASE address (register or label id), or high value of a 64-bit absolute address.
//! * Imm - Should be `0`.
//! * Label - Label id if it was created by using `newLabel()` or `Globals::kInvalidId` if the label is invalid or
//! not initialized.
inline constexpr uint32_t id() const noexcept { return _baseId; }
//! Tests whether the operand is 100% equal to `other` operand.
//!
//! \note This basically performs a binary comparison, if aby bit is
//! different the operands are not equal.
inline constexpr bool equals(const Operand_& other) const noexcept {
return (_signature == other._signature) &
(_baseId == other._baseId ) &
(_data[0] == other._data[0] ) &
(_data[1] == other._data[1] ) ;
}
//! Tests whether the operand is a register matching the given register `type`.
inline constexpr bool isReg(RegType type) const noexcept {
return _signature.subset(Signature::kOpTypeMask | Signature::kRegTypeMask) == (Signature::fromOpType(OperandType::kReg) | Signature::fromRegType(type));
}
//! Tests whether the operand is register and of register `type` and `id`.
inline constexpr bool isReg(RegType type, uint32_t id) const noexcept {
return isReg(type) && this->id() == id;
}
//! Tests whether the operand is a register or memory.
inline constexpr bool isRegOrMem() const noexcept {
return Support::isBetween<uint32_t>(uint32_t(opType()), uint32_t(OperandType::kReg), uint32_t(OperandType::kMem));
}
//! \}
};
//! Base class representing an operand in AsmJit (default constructed version).
class Operand : public Operand_ {
public:
//! \name Construction & Destruction
//! \{
//! Creates `kOpNone` operand having all members initialized to zero.
inline constexpr Operand() noexcept
: Operand_{ Signature::fromOpType(OperandType::kNone), 0u, { 0u, 0u }} {}
//! Creates a cloned `other` operand.
inline constexpr Operand(const Operand& other) noexcept = default;
//! Creates a cloned `other` operand.
inline constexpr explicit Operand(const Operand_& other)
: Operand_(other) {}
//! Creates an operand initialized to raw `[u0, u1, u2, u3]` values.
inline constexpr Operand(Globals::Init_, const Signature& u0, uint32_t u1, uint32_t u2, uint32_t u3) noexcept
: Operand_{ u0, u1, { u2, u3 }} {}
//! Creates an uninitialized operand (dangerous).
inline explicit Operand(Globals::NoInit_) noexcept {}
//! \}
//! \name Overloaded Operators
//! \{
inline Operand& operator=(const Operand& other) noexcept = default;
inline Operand& operator=(const Operand_& other) noexcept { return operator=(static_cast<const Operand&>(other)); }
//! \}
//! \name Clone
//! \{
//! Clones this operand and returns its copy.
inline constexpr Operand clone() const noexcept { return Operand(*this); }
//! \}
};
static_assert(sizeof(Operand) == 16, "asmjit::Operand must be exactly 16 bytes long");
//! Label (jump target or data location).
//!
//! Label represents a location in code typically used as a jump target, but may be also a reference to some data or
//! a static variable. Label has to be explicitly created by BaseEmitter.
//!
//! Example of using labels:
//!
//! ```
//! // Create some emitter (for example x86::Assembler).
//! x86::Assembler a;
//!
//! // Create Label instance.
//! Label L1 = a.newLabel();
//!
//! // ... your code ...
//!
//! // Using label.
//! a.jump(L1);
//!
//! // ... your code ...
//!
//! // Bind label to the current position, see `BaseEmitter::bind()`.
//! a.bind(L1);
//! ```
class Label : public Operand {
public:
//! \name Construction & Destruction
//! \{
//! Creates a label operand without ID (you must set the ID to make it valid).
inline constexpr Label() noexcept
: Operand(Globals::Init, Signature::fromOpType(OperandType::kLabel), Globals::kInvalidId, 0, 0) {}
//! Creates a cloned label operand of `other`.
inline constexpr Label(const Label& other) noexcept
: Operand(other) {}
//! Creates a label operand of the given `id`.
inline constexpr explicit Label(uint32_t id) noexcept
: Operand(Globals::Init, Signature::fromOpType(OperandType::kLabel), id, 0, 0) {}
inline explicit Label(Globals::NoInit_) noexcept
: Operand(Globals::NoInit) {}
//! Resets the label, will reset all properties and set its ID to `Globals::kInvalidId`.
inline void reset() noexcept {
_signature = Signature::fromOpType(OperandType::kLabel);
_baseId = Globals::kInvalidId;
_data[0] = 0;
_data[1] = 0;
}
//! \}
//! \name Overloaded Operators
//! \{
inline Label& operator=(const Label& other) noexcept = default;
//! \}
//! \name Accessors
//! \{
//! Tests whether the label was created by CodeHolder and/or an attached emitter.
inline constexpr bool isValid() const noexcept { return _baseId != Globals::kInvalidId; }
//! Sets the label `id`.
inline void setId(uint32_t id) noexcept { _baseId = id; }
//! \}
};
//! \cond INTERNAL
//! Default register traits.
struct BaseRegTraits {
enum : uint32_t {
//! \ref TypeId representing this register type, could be \ref TypeId::kVoid if such type doesn't exist.
kTypeId = uint32_t(TypeId::kVoid),
//! RegType is not valid by default.
kValid = 0,
//! Count of registers (0 if none).
kCount = 0,
//! Zero type by default (defeaults to None).
kType = uint32_t(RegType::kNone),
//! Zero group by default (defaults to GP).
kGroup = uint32_t(RegGroup::kGp),
//! No size by default.
kSize = 0,
//! Empty signature by default (not even having operand type set to register).
kSignature = 0
};
};
//! \endcond
//! Physical or virtual register operand.
class BaseReg : public Operand {
public:
//! \name Constants
//! \{
enum : uint32_t {
//! None or any register (mostly internal).
kIdBad = 0xFFu,
kBaseSignatureMask =
Signature::kOpTypeMask |
Signature::kRegTypeMask |
Signature::kRegGroupMask |
Signature::kSizeMask,
kTypeNone = uint32_t(RegType::kNone),
kSignature = Signature::fromOpType(OperandType::kReg).bits()
};
//! \}
//! \name Construction & Destruction
//! \{
//! Creates a dummy register operand.
inline constexpr BaseReg() noexcept
: Operand(Globals::Init, Signature::fromOpType(OperandType::kReg), kIdBad, 0, 0) {}
//! Creates a new register operand which is the same as `other` .
inline constexpr BaseReg(const BaseReg& other) noexcept
: Operand(other) {}
//! Creates a new register operand compatible with `other`, but with a different `id`.
inline constexpr BaseReg(const BaseReg& other, uint32_t id) noexcept
: Operand(Globals::Init, other._signature, id, 0, 0) {}
//! Creates a register initialized to the given `signature` and `id`.
inline constexpr BaseReg(const Signature& signature, uint32_t id) noexcept
: Operand(Globals::Init, signature, id, 0, 0) {}
inline explicit BaseReg(Globals::NoInit_) noexcept
: Operand(Globals::NoInit) {}
//! \}
//! \name Overloaded Operators
//! \{
inline BaseReg& operator=(const BaseReg& other) noexcept = default;
//! \}
//! \name Accessors
//! \{
//! Returns base signature of the register associated with each register type.
//!
//! Base signature only contains the operand type, register type, register group, and register size. It doesn't
//! contain element type, predicate, or other architecture-specific data. Base signature is a signature that is
//! provided by architecture-specific `RegTraits`, like \ref x86::RegTraits.
inline constexpr OperandSignature baseSignature() const noexcept { return _signature & kBaseSignatureMask; }
//! Tests whether the operand's base signature matches the given signature `sign`.
inline constexpr bool hasBaseSignature(uint32_t signature) const noexcept { return baseSignature() == signature; }
//! Tests whether the operand's base signature matches the given signature `sign`.
inline constexpr bool hasBaseSignature(const OperandSignature& signature) const noexcept { return baseSignature() == signature; }
//! Tests whether the operand's base signature matches the base signature of the `other` operand.
inline constexpr bool hasBaseSignature(const BaseReg& other) const noexcept { return baseSignature() == other.baseSignature(); }
//! Tests whether this register is the same as `other`.
//!
//! This is just an optimization. Registers by default only use the first 8 bytes of Operand data, so this method
//! takes advantage of this knowledge and only compares these 8 bytes. If both operands were created correctly
//! both \ref equals() and \ref isSame() should give the same answer, however, if any of these two contains garbage
//! or other metadata in the upper 8 bytes then \ref isSame() may return `true` in cases in which \ref equals()
//! returns false.
inline constexpr bool isSame(const BaseReg& other) const noexcept {
return (_signature == other._signature) & (_baseId == other._baseId);
}
//! Tests whether the register is valid (either virtual or physical).
inline constexpr bool isValid() const noexcept { return (_signature != 0) & (_baseId != kIdBad); }
//! Tests whether this is a physical register.
inline constexpr bool isPhysReg() const noexcept { return _baseId < kIdBad; }
//! Tests whether this is a virtual register.
inline constexpr bool isVirtReg() const noexcept { return _baseId > kIdBad; }
//! Tests whether the register type matches `type` - same as `isReg(type)`, provided for convenience.
inline constexpr bool isType(RegType type) const noexcept { return _signature.subset(Signature::kRegTypeMask) == Signature::fromRegType(type); }
//! Tests whether the register group matches `group`.
inline constexpr bool isGroup(RegGroup group) const noexcept { return _signature.subset(Signature::kRegGroupMask) == Signature::fromRegGroup(group); }
//! Tests whether the register is a general purpose register (any size).
inline constexpr bool isGp() const noexcept { return isGroup(RegGroup::kGp); }
//! Tests whether the register is a vector register.
inline constexpr bool isVec() const noexcept { return isGroup(RegGroup::kVec); }
using Operand_::isReg;
//! Same as `isType()`, provided for convenience.
inline constexpr bool isReg(RegType rType) const noexcept { return isType(rType); }
//! Tests whether the register type matches `type` and register id matches `id`.
inline constexpr bool isReg(RegType rType, uint32_t id) const noexcept { return isType(rType) && this->id() == id; }
//! Returns the register type.
inline constexpr RegType type() const noexcept { return _signature.regType(); }
//! Returns the register group.
inline constexpr RegGroup group() const noexcept { return _signature.regGroup(); }
//! Returns operation predicate of the register (ARM/AArch64).
//!
//! The meaning depends on architecture, for example on ARM hardware this describes \ref arm::ShiftOp
//! of the register.
inline constexpr uint32_t predicate() const noexcept { return _signature.getField<Signature::kPredicateMask>(); }
//! Sets operation predicate of the register to `predicate` (ARM/AArch64).
//!
//! The meaning depends on architecture, for example on ARM hardware this describes \ref arm::ShiftOp
//! of the register.
inline void setPredicate(uint32_t predicate) noexcept { _signature.setField<Signature::kPredicateMask>(predicate); }
//! Resets shift operation type of the register to the default value (ARM/AArch64).
inline void resetPredicate() noexcept { _signature.setField<Signature::kPredicateMask>(0); }
//! Clones the register operand.
inline constexpr BaseReg clone() const noexcept { return BaseReg(*this); }
//! Casts this register to `RegT` by also changing its signature.
//!
//! \note Improper use of `cloneAs()` can lead to hard-to-debug errors.
template<typename RegT>
inline constexpr RegT cloneAs() const noexcept { return RegT(Signature(RegT::kSignature), id()); }
//! Casts this register to `other` by also changing its signature.
//!
//! \note Improper use of `cloneAs()` can lead to hard-to-debug errors.
template<typename RegT>
inline constexpr RegT cloneAs(const RegT& other) const noexcept { return RegT(other.signature(), id()); }
//! Sets the register id to `id`.
inline void setId(uint32_t id) noexcept { _baseId = id; }
//! Sets a 32-bit operand signature based on traits of `RegT`.
template<typename RegT>
inline void setSignatureT() noexcept { _signature = RegT::kSignature; }
//! Sets the register `signature` and `id`.
inline void setSignatureAndId(const OperandSignature& signature, uint32_t id) noexcept {
_signature = signature;
_baseId = id;
}
//! \}
//! \name Static Functions
//! \{
//! Tests whether the `op` operand is a general purpose register.
static inline bool isGp(const Operand_& op) noexcept {
// Check operand type and register group. Not interested in register type and size.
return op.signature().subset(Signature::kOpTypeMask | Signature::kRegGroupMask) == (Signature::fromOpType(OperandType::kReg) | Signature::fromRegGroup(RegGroup::kGp));
}
//! Tests whether the `op` operand is a vector register.
static inline bool isVec(const Operand_& op) noexcept {
// Check operand type and register group. Not interested in register type and size.
return op.signature().subset(Signature::kOpTypeMask | Signature::kRegGroupMask) == (Signature::fromOpType(OperandType::kReg) | Signature::fromRegGroup(RegGroup::kVec));
}
//! Tests whether the `op` is a general purpose register of the given `id`.
static inline bool isGp(const Operand_& op, uint32_t id) noexcept { return bool(unsigned(isGp(op)) & unsigned(op.id() == id)); }
//! Tests whether the `op` is a vector register of the given `id`.
static inline bool isVec(const Operand_& op, uint32_t id) noexcept { return bool(unsigned(isVec(op)) & unsigned(op.id() == id)); }
//! \}
};
//! RegOnly is 8-byte version of `BaseReg` that allows to store either register or nothing.
//!
//! It's designed to decrease the space consumed by an extra "operand" in \ref BaseEmitter and \ref InstNode.
struct RegOnly {
//! \name Types
//! \{
typedef OperandSignature Signature;
//! \}
//! Operand signature - only \ref OperandType::kNone and \ref OperandType::kReg are supported.
Signature _signature;
//! Physical or virtual register id.
uint32_t _id;
//! \name Construction & Destruction
//! \{
//! Initializes the `RegOnly` instance to hold register `signature` and `id`.
inline void init(const OperandSignature& signature, uint32_t id) noexcept {
_signature = signature;
_id = id;
}
inline void init(const BaseReg& reg) noexcept { init(reg.signature(), reg.id()); }
inline void init(const RegOnly& reg) noexcept { init(reg.signature(), reg.id()); }
//! Resets the `RegOnly` members to zeros (none).
inline void reset() noexcept { init(Signature::fromBits(0), 0); }
//! \}
//! \name Accessors
//! \{
//! Tests whether this ExtraReg is none (same as calling `Operand_::isNone()`).
inline constexpr bool isNone() const noexcept { return _signature == 0; }
//! Tests whether the register is valid (either virtual or physical).
inline constexpr bool isReg() const noexcept { return _signature != 0; }
//! Tests whether this is a physical register.
inline constexpr bool isPhysReg() const noexcept { return _id < BaseReg::kIdBad; }
//! Tests whether this is a virtual register (used by `BaseCompiler`).
inline constexpr bool isVirtReg() const noexcept { return _id > BaseReg::kIdBad; }
//! Returns the register signature or 0 if no register is assigned.
inline constexpr OperandSignature signature() const noexcept { return _signature; }
//! Returns the register id.
//!
//! \note Always check whether the register is assigned before using the returned identifier as
//! non-assigned `RegOnly` instance would return zero id, which is still a valid register id.
inline constexpr uint32_t id() const noexcept { return _id; }
//! Sets the register id.
inline void setId(uint32_t id) noexcept { _id = id; }
//! Returns the register type.
inline constexpr RegType type() const noexcept { return _signature.regType(); }
//! Returns the register group.
inline constexpr RegGroup group() const noexcept { return _signature.regGroup(); }
//! \}
//! \name Utilities
//! \{
//! Converts this ExtraReg to a real `RegT` operand.
template<typename RegT>
inline constexpr RegT toReg() const noexcept { return RegT(_signature, _id); }
//! \}
};
//! \cond INTERNAL
//! Adds a template specialization for `REG_TYPE` into the local `RegTraits`.
#define ASMJIT_DEFINE_REG_TRAITS(REG, REG_TYPE, GROUP, SIZE, COUNT, TYPE_ID) \
template<> \
struct RegTraits<REG_TYPE> { \
typedef REG RegT; \
\
static constexpr uint32_t kValid = 1; \
static constexpr uint32_t kCount = COUNT; \
static constexpr RegType kType = REG_TYPE; \
static constexpr RegGroup kGroup = GROUP; \
static constexpr uint32_t kSize = SIZE; \
static constexpr TypeId kTypeId = TYPE_ID; \
\
static constexpr uint32_t kSignature = \
(OperandSignature::fromOpType(OperandType::kReg) | \
OperandSignature::fromRegType(kType) | \
OperandSignature::fromRegGroup(kGroup) | \
OperandSignature::fromSize(kSize)).bits(); \
\
}
//! Adds constructors and member functions to a class that implements abstract register. Abstract register is register
//! that doesn't have type or signature yet, it's a base class like `x86::Reg` or `arm::Reg`.
#define ASMJIT_DEFINE_ABSTRACT_REG(REG, BASE) \
public: \
/*! Default constructor that only setups basics. */ \
inline constexpr REG() noexcept \
: BASE(Signature{kSignature}, kIdBad) {} \
\
/*! Makes a copy of the `other` register operand. */ \
inline constexpr REG(const REG& other) noexcept \
: BASE(other) {} \
\
/*! Makes a copy of the `other` register having id set to `id` */ \
inline constexpr REG(const BaseReg& other, uint32_t id) noexcept \
: BASE(other, id) {} \
\
/*! Creates a register based on `signature` and `id`. */ \
inline constexpr REG(const OperandSignature& sgn, uint32_t id) noexcept \
: BASE(sgn, id) {} \
\
/*! Creates a completely uninitialized REG register operand (garbage). */ \
inline explicit REG(Globals::NoInit_) noexcept \
: BASE(Globals::NoInit) {} \
\
/*! Creates a new register from register type and id. */ \
static inline REG fromTypeAndId(RegType type, uint32_t id) noexcept { \
return REG(signatureOf(type), id); \
} \
\
/*! Clones the register operand. */ \
inline constexpr REG clone() const noexcept { return REG(*this); } \
\
inline REG& operator=(const REG& other) noexcept = default;
//! Adds constructors and member functions to a class that implements final register. Final registers MUST HAVE a valid
//! signature.
#define ASMJIT_DEFINE_FINAL_REG(REG, BASE, TRAITS) \
public: \
static constexpr RegType kThisType = TRAITS::kType; \
static constexpr RegGroup kThisGroup = TRAITS::kGroup; \
static constexpr uint32_t kThisSize = TRAITS::kSize; \
static constexpr uint32_t kSignature = TRAITS::kSignature; \
\
ASMJIT_DEFINE_ABSTRACT_REG(REG, BASE) \
\
/*! Creates a register operand having its id set to `id`. */ \
inline constexpr explicit REG(uint32_t id) noexcept \
: BASE(Signature{kSignature}, id) {}
//! \endcond
//! Base class for all memory operands.
//!
//! The data is split into the following parts:
//!
//! - BASE - Base register or label - requires 36 bits total. 4 bits are used to encode the type of the BASE operand
//! (label vs. register type) and the remaining 32 bits define the BASE id, which can be a physical or virtual
//! register index. If BASE type is zero, which is never used as a register type and label doesn't use it as well
//! then BASE field contains a high DWORD of a possible 64-bit absolute address, which is possible on X64.
//!
//! - INDEX - Index register (or theoretically Label, which doesn't make sense). Encoding is similar to BASE - it
//! also requires 36 bits and splits the encoding to INDEX type (4 bits defining the register type) and 32-bit id.
//!
//! - OFFSET - A relative offset of the address. Basically if BASE is specified the relative displacement adjusts
//! BASE and an optional INDEX. if BASE is not specified then the OFFSET should be considered as ABSOLUTE address
//! (at least on X86). In that case its low 32 bits are stored in DISPLACEMENT field and the remaining high 32
//! bits are stored in BASE.
//!
//! - OTHER - There is rest 8 bits that can be used for whatever purpose. For example \ref x86::Mem operand uses
//! these bits to store segment override prefix and index shift (or scale).
class BaseMem : public Operand {
public:
//! \name Construction & Destruction
//! \{
//! Creates a default `BaseMem` operand, that points to [0].
inline constexpr BaseMem() noexcept
: Operand(Globals::Init, Signature::fromOpType(OperandType::kMem), 0, 0, 0) {}
//! Creates a `BaseMem` operand that is a clone of `other`.
inline constexpr BaseMem(const BaseMem& other) noexcept
: Operand(other) {}
//! Creates a `BaseMem` operand from `baseReg` and `offset`.
//!
//! \note This is an architecture independent constructor that can be used to create an architecture
//! independent memory operand to be used in portable code that can handle multiple architectures.
inline constexpr explicit BaseMem(const BaseReg& baseReg, int32_t offset = 0) noexcept
: Operand(Globals::Init,
Signature::fromOpType(OperandType::kMem) | Signature::fromMemBaseType(baseReg.type()),
baseReg.id(),
0,
uint32_t(offset)) {}
//! \cond INTERNAL
//! Creates a `BaseMem` operand from 4 integers as used by `Operand_` struct.
inline constexpr BaseMem(const OperandSignature& u0, uint32_t baseId, uint32_t indexId, int32_t offset) noexcept
: Operand(Globals::Init, u0, baseId, indexId, uint32_t(offset)) {}
//! \endcond
//! Creates a completely uninitialized `BaseMem` operand.
inline explicit BaseMem(Globals::NoInit_) noexcept
: Operand(Globals::NoInit) {}
//! Resets the memory operand - after the reset the memory points to [0].
inline void reset() noexcept {
_signature = Signature::fromOpType(OperandType::kMem);
_baseId = 0;
_data[0] = 0;
_data[1] = 0;
}
//! \}
//! \name Overloaded Operators
//! \{
inline BaseMem& operator=(const BaseMem& other) noexcept { copyFrom(other); return *this; }
//! \}
//! \name Accessors
//! \{
//! Clones the memory operand.
inline constexpr BaseMem clone() const noexcept { return BaseMem(*this); }
//! Creates a new copy of this memory operand adjusted by `off`.
inline BaseMem cloneAdjusted(int64_t off) const noexcept {
BaseMem result(*this);
result.addOffset(off);
return result;
}
//! Tests whether this memory operand is a register home (only used by \ref asmjit_compiler)
inline constexpr bool isRegHome() const noexcept { return _signature.hasField<Signature::kMemRegHomeFlag>(); }
//! Mark this memory operand as register home (only used by \ref asmjit_compiler).
inline void setRegHome() noexcept { _signature |= Signature::kMemRegHomeFlag; }
//! Marks this operand to not be a register home (only used by \ref asmjit_compiler).
inline void clearRegHome() noexcept { _signature &= ~Signature::kMemRegHomeFlag; }
//! Tests whether the memory operand has a BASE register or label specified.
inline constexpr bool hasBase() const noexcept {
return (_signature & Signature::kMemBaseTypeMask) != 0;
}
//! Tests whether the memory operand has an INDEX register specified.
inline constexpr bool hasIndex() const noexcept {
return (_signature & Signature::kMemIndexTypeMask) != 0;
}
//! Tests whether the memory operand has BASE or INDEX register.
inline constexpr bool hasBaseOrIndex() const noexcept {
return (_signature & Signature::kMemBaseIndexMask) != 0;
}
//! Tests whether the memory operand has BASE and INDEX register.
inline constexpr bool hasBaseAndIndex() const noexcept {
return (_signature & Signature::kMemBaseTypeMask) != 0 && (_signature & Signature::kMemIndexTypeMask) != 0;
}
//! Tests whether the BASE operand is a label.
inline constexpr bool hasBaseLabel() const noexcept {
return _signature.subset(Signature::kMemBaseTypeMask) == Signature::fromMemBaseType(RegType::kLabelTag);
}
//! Tests whether the BASE operand is a register (registers start after `RegType::kLabelTag`).
inline constexpr bool hasBaseReg() const noexcept {
return _signature.subset(Signature::kMemBaseTypeMask).bits() > Signature::fromMemBaseType(RegType::kLabelTag).bits();
}
//! Tests whether the INDEX operand is a register (registers start after `RegType::kLabelTag`).
inline constexpr bool hasIndexReg() const noexcept {
return _signature.subset(Signature::kMemIndexTypeMask).bits() > Signature::fromMemIndexType(RegType::kLabelTag).bits();
}
//! Returns the type of the BASE register (0 if this memory operand doesn't use the BASE register).
//!
//! \note If the returned type is one (a value never associated to a register type) the BASE is not register, but it
//! is a label. One equals to `kLabelTag`. You should always check `hasBaseLabel()` before using `baseId()` result.
inline constexpr RegType baseType() const noexcept { return _signature.memBaseType(); }
//! Returns the type of an INDEX register (0 if this memory operand doesn't
//! use the INDEX register).
inline constexpr RegType indexType() const noexcept { return _signature.memIndexType(); }
//! This is used internally for BASE+INDEX validation.
inline constexpr uint32_t baseAndIndexTypes() const noexcept { return _signature.getField<Signature::kMemBaseIndexMask>(); }
//! Returns both BASE (4:0 bits) and INDEX (9:5 bits) types combined into a single value.
//!
//! \remarks Returns id of the BASE register or label (if the BASE was specified as label).
inline constexpr uint32_t baseId() const noexcept { return _baseId; }
//! Returns the id of the INDEX register.
inline constexpr uint32_t indexId() const noexcept { return _data[kDataMemIndexId]; }
//! Sets the id of the BASE register (without modifying its type).
inline void setBaseId(uint32_t id) noexcept { _baseId = id; }
//! Sets the id of the INDEX register (without modifying its type).
inline void setIndexId(uint32_t id) noexcept { _data[kDataMemIndexId] = id; }
//! Sets the base register to type and id of the given `base` operand.
inline void setBase(const BaseReg& base) noexcept { return _setBase(base.type(), base.id()); }
//! Sets the index register to type and id of the given `index` operand.
inline void setIndex(const BaseReg& index) noexcept { return _setIndex(index.type(), index.id()); }
//! \cond INTERNAL
inline void _setBase(RegType type, uint32_t id) noexcept {
_signature.setField<Signature::kMemBaseTypeMask>(uint32_t(type));
_baseId = id;
}
inline void _setIndex(RegType type, uint32_t id) noexcept {
_signature.setField<Signature::kMemIndexTypeMask>(uint32_t(type));
_data[kDataMemIndexId] = id;
}
//! \endcond
//! Resets the memory operand's BASE register or label.
inline void resetBase() noexcept { _setBase(RegType::kNone, 0); }
//! Resets the memory operand's INDEX register.
inline void resetIndex() noexcept { _setIndex(RegType::kNone, 0); }
//! Sets the memory operand size (in bytes).
inline void setSize(uint32_t size) noexcept { _signature.setField<Signature::kSizeMask>(size); }
//! Tests whether the memory operand has a 64-bit offset or absolute address.
//!
//! If this is true then `hasBase()` must always report false.
inline constexpr bool isOffset64Bit() const noexcept { return baseType() == RegType::kNone; }
//! Tests whether the memory operand has a non-zero offset or absolute address.
inline constexpr bool hasOffset() const noexcept {
return (_data[kDataMemOffsetLo] | uint32_t(_baseId & Support::bitMaskFromBool<uint32_t>(isOffset64Bit()))) != 0;
}
//! Returns either relative offset or absolute address as 64-bit integer.
inline constexpr int64_t offset() const noexcept {
return isOffset64Bit() ? int64_t(uint64_t(_data[kDataMemOffsetLo]) | (uint64_t(_baseId) << 32))
: int64_t(int32_t(_data[kDataMemOffsetLo])); // Sign extend 32-bit offset.
}
//! Returns a 32-bit low part of a 64-bit offset or absolute address.
inline constexpr int32_t offsetLo32() const noexcept { return int32_t(_data[kDataMemOffsetLo]); }
//! Returns a 32-but high part of a 64-bit offset or absolute address.
//!
//! \note This function is UNSAFE and returns garbage if `isOffset64Bit()`
//! returns false. Never use it blindly without checking it first.
inline constexpr int32_t offsetHi32() const noexcept { return int32_t(_baseId); }
//! Sets a 64-bit offset or an absolute address to `offset`.
//!
//! \note This functions attempts to set both high and low parts of a 64-bit offset, however, if the operand has
//! a BASE register it will store only the low 32 bits of the offset / address as there is no way to store both
//! BASE and 64-bit offset, and there is currently no architecture that has such capability targeted by AsmJit.
inline void setOffset(int64_t offset) noexcept {
uint32_t lo = uint32_t(uint64_t(offset) & 0xFFFFFFFFu);
uint32_t hi = uint32_t(uint64_t(offset) >> 32);
uint32_t hiMsk = Support::bitMaskFromBool<uint32_t>(isOffset64Bit());
_data[kDataMemOffsetLo] = lo;
_baseId = (hi & hiMsk) | (_baseId & ~hiMsk);
}
//! Sets a low 32-bit offset to `offset` (don't use without knowing how BaseMem works).
inline void setOffsetLo32(int32_t offset) noexcept { _data[kDataMemOffsetLo] = uint32_t(offset); }
//! Adjusts the offset by `offset`.
//!
//! \note This is a fast function that doesn't use the HI 32-bits of a 64-bit offset. Use it only if you know that
//! there is a BASE register and the offset is only 32 bits anyway.
//! Adjusts the memory operand offset by a `offset`.
inline void addOffset(int64_t offset) noexcept {
if (isOffset64Bit()) {
int64_t result = offset + int64_t(uint64_t(_data[kDataMemOffsetLo]) | (uint64_t(_baseId) << 32));
_data[kDataMemOffsetLo] = uint32_t(uint64_t(result) & 0xFFFFFFFFu);
_baseId = uint32_t(uint64_t(result) >> 32);
}
else {
_data[kDataMemOffsetLo] += uint32_t(uint64_t(offset) & 0xFFFFFFFFu);
}
}
//! Adds `offset` to a low 32-bit offset part (don't use without knowing how BaseMem works).
inline void addOffsetLo32(int32_t offset) noexcept { _data[kDataMemOffsetLo] += uint32_t(offset); }
//! Resets the memory offset to zero.
inline void resetOffset() noexcept { setOffset(0); }
//! Resets the lo part of the memory offset to zero (don't use without knowing how BaseMem works).
inline void resetOffsetLo32() noexcept { setOffsetLo32(0); }
//! \}
};
//! Type of the an immediate value.
enum class ImmType : uint32_t {
//! Immediate is integer.
kInt = 0,
//! Immediate is a floating point stored as double-precision.
kDouble = 1
};
//! Immediate operands are encoded with instruction data.
class Imm : public Operand {
public:
//! \cond INTERNAL
template<typename T>
struct IsConstexprConstructibleAsImmType
: public std::integral_constant<bool, std::is_enum<T>::value ||
std::is_pointer<T>::value ||
std::is_integral<T>::value ||
std::is_function<T>::value> {};
template<typename T>
struct IsConvertibleToImmType
: public std::integral_constant<bool, IsConstexprConstructibleAsImmType<T>::value ||
std::is_floating_point<T>::value> {};
//! \endcond
//! \name Construction & Destruction
//! \{
//! Creates a new immediate value (initial value is 0).
inline constexpr Imm() noexcept
: Operand(Globals::Init, Signature::fromOpType(OperandType::kImm), 0, 0, 0) {}
//! Creates a new immediate value from `other`.
inline constexpr Imm(const Imm& other) noexcept
: Operand(other) {}
//! Creates a new immediate value from ARM/AArch64 specific `shift`.
inline constexpr Imm(const arm::Shift& shift) noexcept
: Operand(Globals::Init,
Signature::fromOpType(OperandType::kImm) | Signature::fromPredicate(uint32_t(shift.op())),
0,
Support::unpackU32At0(shift.value()),
Support::unpackU32At1(shift.value())) {}
//! Creates a new signed immediate value, assigning the value to `val` and an architecture-specific predicate
//! to `predicate`.
//!
//! \note Predicate is currently only used by ARM architectures.
template<typename T, typename = typename std::enable_if<IsConstexprConstructibleAsImmType<typename std::decay<T>::type>::value>::type>
inline constexpr Imm(const T& val, const uint32_t predicate = 0) noexcept
: Operand(Globals::Init,
Signature::fromOpType(OperandType::kImm) | Signature::fromPredicate(predicate),
0,
Support::unpackU32At0(int64_t(val)),
Support::unpackU32At1(int64_t(val))) {}
inline Imm(const float& val, const uint32_t predicate = 0) noexcept
: Operand(Globals::Init,
Signature::fromOpType(OperandType::kImm) | Signature::fromPredicate(predicate),
0,
0,
0) { setValue(val); }
inline Imm(const double& val, const uint32_t predicate = 0) noexcept
: Operand(Globals::Init,
Signature::fromOpType(OperandType::kImm) | Signature::fromPredicate(predicate),
0,
0,
0) { setValue(val); }
inline explicit Imm(Globals::NoInit_) noexcept
: Operand(Globals::NoInit) {}
//! \}
//! \name Overloaded Operators
//! \{
//! Assigns the value of the `other` operand to this immediate.
inline Imm& operator=(const Imm& other) noexcept { copyFrom(other); return *this; }
//! \}
//! \name Accessors
//! \{
//! Returns immediate type.
inline constexpr ImmType type() const noexcept { return (ImmType)_signature.getField<Signature::kImmTypeMask>(); }
//! Sets the immediate type to `type`.
inline void setType(ImmType type) noexcept { _signature.setField<Signature::kImmTypeMask>(uint32_t(type)); }
//! Resets immediate type to \ref ImmType::kInt.
inline void resetType() noexcept { setType(ImmType::kInt); }
//! Returns operation predicate of the immediate.
//!
//! The meaning depends on architecture, for example on ARM hardware this describes \ref arm::ShiftOp
//! of the immediate.
inline constexpr uint32_t predicate() const noexcept { return _signature.getField<Signature::kPredicateMask>(); }
//! Sets operation predicate of the immediate to `predicate`.
//!
//! The meaning depends on architecture, for example on ARM hardware this describes \ref arm::ShiftOp
//! of the immediate.
inline void setPredicate(uint32_t predicate) noexcept { _signature.setField<Signature::kPredicateMask>(predicate); }
//! Resets the shift operation type of the immediate to the default value (no operation).
inline void resetPredicate() noexcept { _signature.setField<Signature::kPredicateMask>(0); }
//! Returns the immediate value as `int64_t`, which is the internal format Imm uses.
inline constexpr int64_t value() const noexcept {
return int64_t((uint64_t(_data[kDataImmValueHi]) << 32) | _data[kDataImmValueLo]);
}
//! Tests whether this immediate value is integer of any size.
inline constexpr uint32_t isInt() const noexcept { return type() == ImmType::kInt; }
//! Tests whether this immediate value is a double precision floating point value.
inline constexpr uint32_t isDouble() const noexcept { return type() == ImmType::kDouble; }
//! Tests whether the immediate can be casted to 8-bit signed integer.
inline constexpr bool isInt8() const noexcept { return type() == ImmType::kInt && Support::isInt8(value()); }
//! Tests whether the immediate can be casted to 8-bit unsigned integer.
inline constexpr bool isUInt8() const noexcept { return type() == ImmType::kInt && Support::isUInt8(value()); }
//! Tests whether the immediate can be casted to 16-bit signed integer.
inline constexpr bool isInt16() const noexcept { return type() == ImmType::kInt && Support::isInt16(value()); }
//! Tests whether the immediate can be casted to 16-bit unsigned integer.
inline constexpr bool isUInt16() const noexcept { return type() == ImmType::kInt && Support::isUInt16(value()); }
//! Tests whether the immediate can be casted to 32-bit signed integer.
inline constexpr bool isInt32() const noexcept { return type() == ImmType::kInt && Support::isInt32(value()); }
//! Tests whether the immediate can be casted to 32-bit unsigned integer.
inline constexpr bool isUInt32() const noexcept { return type() == ImmType::kInt && _data[kDataImmValueHi] == 0; }
//! Returns the immediate value casted to `T`.
//!
//! The value is masked before it's casted to `T` so the returned value is simply the representation of `T`
//! considering the original value's lowest bits.
template<typename T>
inline T valueAs() const noexcept { return Support::immediateToT<T>(value()); }
//! Returns low 32-bit signed integer.
inline constexpr int32_t int32Lo() const noexcept { return int32_t(_data[kDataImmValueLo]); }
//! Returns high 32-bit signed integer.
inline constexpr int32_t int32Hi() const noexcept { return int32_t(_data[kDataImmValueHi]); }
//! Returns low 32-bit signed integer.
inline constexpr uint32_t uint32Lo() const noexcept { return _data[kDataImmValueLo]; }
//! Returns high 32-bit signed integer.
inline constexpr uint32_t uint32Hi() const noexcept { return _data[kDataImmValueHi]; }
//! Sets immediate value to `val`, the value is casted to a signed 64-bit integer.
template<typename T>
inline void setValue(const T& val) noexcept {
_setValueInternal(Support::immediateFromT(val), std::is_floating_point<T>::value ? ImmType::kDouble : ImmType::kInt);
}
inline void _setValueInternal(int64_t val, ImmType type) noexcept {
setType(type);
_data[kDataImmValueHi] = uint32_t(uint64_t(val) >> 32);
_data[kDataImmValueLo] = uint32_t(uint64_t(val) & 0xFFFFFFFFu);
}
//! \}
//! \name Utilities
//! \{
//! Clones the immediate operand.
inline constexpr Imm clone() const noexcept { return Imm(*this); }
inline void signExtend8Bits() noexcept { setValue(int64_t(valueAs<int8_t>())); }
inline void signExtend16Bits() noexcept { setValue(int64_t(valueAs<int16_t>())); }
inline void signExtend32Bits() noexcept { setValue(int64_t(valueAs<int32_t>())); }
inline void zeroExtend8Bits() noexcept { setValue(valueAs<uint8_t>()); }
inline void zeroExtend16Bits() noexcept { setValue(valueAs<uint16_t>()); }
inline void zeroExtend32Bits() noexcept { _data[kDataImmValueHi] = 0u; }
//! \}
};
//! Creates a new immediate operand.
template<typename T>
static inline constexpr Imm imm(const T& val) noexcept { return Imm(val); }
//! \}
namespace Globals {
//! \ingroup asmjit_assembler
//!
//! A default-constructed operand of `Operand_::kOpNone` type.
static constexpr const Operand none;
}
//! \cond INTERNAL
namespace Support {
template<typename T, bool kIsImm>
struct ForwardOpImpl {
static inline const T& forward(const T& value) noexcept { return value; }
};
template<typename T>
struct ForwardOpImpl<T, true> {
static inline Imm forward(const T& value) noexcept { return Imm(value); }
};
//! Either forwards operand T or returns a new operand that wraps it if T is a type convertible to operand.
//! At the moment this is only used to convert integers, floats, and enumarations to \ref Imm operands.
template<typename T>
struct ForwardOp : public ForwardOpImpl<T, Imm::IsConvertibleToImmType<typename std::decay<T>::type>::value> {};
} // {Support}
//! \endcond
ASMJIT_END_NAMESPACE
#endif // ASMJIT_CORE_OPERAND_H_INCLUDED