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// AsmJit - Machine code generation for C++
//
// * Official AsmJit Home Page: https://asmjit.com
// * Official Github Repository: https://github.com/asmjit/asmjit
//
// Copyright (c) 2008-2020 The AsmJit Authors
//
// This software is provided 'as-is', without any express or implied
// warranty. In no event will the authors be held liable for any damages
// arising from the use of this software.
//
// Permission is granted to anyone to use this software for any purpose,
// including commercial applications, and to alter it and redistribute it
// freely, subject to the following restrictions:
//
// 1. The origin of this software must not be misrepresented; you must not
// claim that you wrote the original software. If you use this software
// in a product, an acknowledgment in the product documentation would be
// appreciated but is not required.
// 2. Altered source versions must be plainly marked as such, and must not be
// misrepresented as being the original software.
// 3. This notice may not be removed or altered from any source distribution.
#ifndef ASMJIT_CORE_FUNC_H_INCLUDED
#define ASMJIT_CORE_FUNC_H_INCLUDED
#include "../core/archtraits.h"
#include "../core/environment.h"
#include "../core/operand.h"
#include "../core/type.h"
#include "../core/support.h"
ASMJIT_BEGIN_NAMESPACE
//! \addtogroup asmjit_function
//! \{
// ============================================================================
// [asmjit::CallConv]
// ============================================================================
//! Function calling convention.
//!
//! Function calling convention is a scheme that defines how function parameters
//! are passed and how function returns its result. AsmJit defines a variety of
//! architecture and OS specific calling conventions and also provides a compile
//! time detection to make the code-generation easier.
struct CallConv {
//! Calling convention id, see \ref Id.
uint8_t _id;
//! Architecture identifier, see \ref Environment::Arch.
uint8_t _arch;
//! Register assignment strategy, see \ref Strategy.
uint8_t _strategy;
//! Red zone size (AMD64 == 128 bytes).
uint8_t _redZoneSize;
//! Spill zone size (WIN-X64 == 32 bytes).
uint8_t _spillZoneSize;
//! Natural stack alignment as defined by OS/ABI.
uint8_t _naturalStackAlignment;
//! Flags.
uint16_t _flags;
//! Size to save/restore per register group.
uint8_t _saveRestoreRegSize[BaseReg::kGroupVirt];
//! Alignment of save/restore groups.
uint8_t _saveRestoreAlignment[BaseReg::kGroupVirt];
//! Mask of all passed registers, per group.
uint32_t _passedRegs[BaseReg::kGroupVirt];
//! Mask of all preserved registers, per group.
uint32_t _preservedRegs[BaseReg::kGroupVirt];
//! Internal limits of AsmJit's CallConv.
enum Limits : uint32_t {
//! Maximum number of register arguments per register group.
//!
//! \note This is not really AsmJit's limitatation, it's just the number
//! that makes sense considering all common calling conventions. Usually
//! even conventions that use registers to pass function arguments are
//! limited to 8 and less arguments passed via registers per group.
kMaxRegArgsPerGroup = 16
};
//! Passed registers' order.
union RegOrder {
//! Passed registers, ordered.
uint8_t id[kMaxRegArgsPerGroup];
//! Packed IDs in `uint32_t` array.
uint32_t packed[(kMaxRegArgsPerGroup + 3) / 4];
};
//! Passed registers' order, per register group.
RegOrder _passedOrder[BaseReg::kGroupVirt];
//! Calling convention id.
//!
//! Calling conventions can be divided into the following groups:
//!
//! - Universal - calling conventions are applicable to any target. They
//! will be converted to a target dependent calling convention at runtime
//! by \ref init(). The purpose of these conventions is to make using
//! functions less target dependent and closer to how they are declared
//! in C and C++.
//!
//! - Target specific - calling conventions that are used by a particular
//! architecture and ABI. For example Windows 64-bit calling convention
//! and AMD64 SystemV calling convention.
enum Id : uint32_t {
//! None or invalid (can't be used).
kIdNone = 0,
// ------------------------------------------------------------------------
// [Universal Calling Conventions]
// ------------------------------------------------------------------------
//! Standard function call or explicit `__cdecl` where it can be specified.
//!
//! This is a universal calling convention, which is used to initialize
//! specific calling connventions based on architecture, platform, and its ABI.
kIdCDecl = 1,
//! `__stdcall` on targets that support this calling convention (X86).
//!
//! \note This calling convention is only supported on 32-bit X86. If used
//! on environment that doesn't support this calling convention it will be
//! replaced by \ref kIdCDecl.
kIdStdCall = 2,
//! `__fastcall` on targets that support this calling convention (X86).
//!
//! \note This calling convention is only supported on 32-bit X86. If used
//! on environment that doesn't support this calling convention it will be
//! replaced by \ref kIdCDecl.
kIdFastCall = 3,
//! `__vectorcall` on targets that support this calling convention (X86/X64).
//!
//! \note This calling convention is only supported on 32-bit and 64-bit
//! X86 architecture on Windows platform. If used on environment that doesn't
//! support this calling it will be replaced by \ref kIdCDecl.
kIdVectorCall = 4,
//! `__thiscall` on targets that support this calling convention (X86).
//!
//! \note This calling convention is only supported on 32-bit X86 Windows
//! platform. If used on environment that doesn't support this calling
//! convention it will be replaced by \ref kIdCDecl.
kIdThisCall = 5,
//! `__attribute__((regparm(1)))` convention (GCC and Clang).
kIdRegParm1 = 6,
//! `__attribute__((regparm(2)))` convention (GCC and Clang).
kIdRegParm2 = 7,
//! `__attribute__((regparm(3)))` convention (GCC and Clang).
kIdRegParm3 = 8,
//! Soft-float calling convention (ARM).
//!
//! Floating point arguments are passed via general purpose registers.
kIdSoftFloat = 9,
//! Hard-float calling convention (ARM).
//!
//! Floating point arguments are passed via SIMD registers.
kIdHardFloat = 10,
//! AsmJit specific calling convention designed for calling functions
//! inside a multimedia code that don't use many registers internally,
//! but are long enough to be called and not inlined. These functions are
//! usually used to calculate trigonometric functions, logarithms, etc...
kIdLightCall2 = 16,
kIdLightCall3 = 17,
kIdLightCall4 = 18,
// ------------------------------------------------------------------------
// [ABI-Specific Calling Conventions]
// ------------------------------------------------------------------------
//! X64 System-V calling convention.
kIdX64SystemV = 32,
//! X64 Windows calling convention.
kIdX64Windows = 33,
// ------------------------------------------------------------------------
// [Host]
// ------------------------------------------------------------------------
//! Host calling convention detected at compile-time.
kIdHost =
#if ASMJIT_ARCH_ARM == 32 && defined(__SOFTFP__)
kIdSoftFloat
#elif ASMJIT_ARCH_ARM == 32 && !defined(__SOFTFP__)
kIdHardFloat
#else
kIdCDecl
#endif
#ifndef ASMJIT_NO_DEPRECATE
, kIdHostCDecl = kIdCDecl
, kIdHostStdCall = kIdStdCall
, kIdHostFastCall = kIdFastCall
, kIdHostLightCall2 = kIdLightCall2
, kIdHostLightCall3 = kIdLightCall3
, kIdHostLightCall4 = kIdLightCall4
#endif // !ASMJIT_NO_DEPRECATE
};
//! Strategy used to assign registers to function arguments.
//!
//! This is AsmJit specific. It basically describes how AsmJit should convert
//! the function arguments defined by `FuncSignature` into register IDs and
//! stack offsets. The default strategy `kStrategyDefault` assigns registers
//! and then stack whereas `kStrategyWin64` strategy does register shadowing
//! as defined by WIN64 calling convention - it applies to 64-bit calling
//! conventions only.
enum Strategy : uint32_t {
//! Default register assignment strategy.
kStrategyDefault = 0,
//! Windows 64-bit ABI register assignment strategy.
kStrategyX64Windows = 1,
//! Windows 64-bit __vectorcall register assignment strategy.
kStrategyX64VectorCall = 2,
//! Number of assignment strategies.
kStrategyCount = 3
};
//! Calling convention flags.
enum Flags : uint32_t {
//! Callee is responsible for cleaning up the stack.
kFlagCalleePopsStack = 0x0001u,
//! Pass vector arguments indirectly (as a pointer).
kFlagIndirectVecArgs = 0x0002u,
//! Pass F32 and F64 arguments via VEC128 register.
kFlagPassFloatsByVec = 0x0004u,
//! Pass MMX and vector arguments via stack if the function has variable arguments.
kFlagPassVecByStackIfVA = 0x0008u,
//! MMX registers are passed and returned via GP registers.
kFlagPassMmxByGp = 0x0010u,
//! MMX registers are passed and returned via XMM registers.
kFlagPassMmxByXmm = 0x0020u,
//! Calling convention can be used with variable arguments.
kFlagVarArgCompatible = 0x0080u
};
//! \name Construction & Destruction
//! \{
//! Initializes this calling convention to the given `ccId` based on the
//! `environment`.
//!
//! See \ref Id and \ref Environment for more details.
ASMJIT_API Error init(uint32_t ccId, const Environment& environment) noexcept;
//! Resets this CallConv struct into a defined state.
//!
//! It's recommended to reset the \ref CallConv struct in case you would
//! like create a custom calling convention as it prevents from using an
//! uninitialized data (CallConv doesn't have a constructor that would
//! initialize it, it's just a struct).
inline void reset() noexcept {
memset(this, 0, sizeof(*this));
memset(_passedOrder, 0xFF, sizeof(_passedOrder));
}
//! \}
//! \name Accessors
//! \{
//! Returns the calling convention id, see `Id`.
inline uint32_t id() const noexcept { return _id; }
//! Sets the calling convention id, see `Id`.
inline void setId(uint32_t id) noexcept { _id = uint8_t(id); }
//! Returns the calling function architecture id.
inline uint32_t arch() const noexcept { return _arch; }
//! Sets the calling function architecture id.
inline void setArch(uint32_t arch) noexcept { _arch = uint8_t(arch); }
//! Returns the strategy used to assign registers to arguments, see `Strategy`.
inline uint32_t strategy() const noexcept { return _strategy; }
//! Sets the strategy used to assign registers to arguments, see `Strategy`.
inline void setStrategy(uint32_t strategy) noexcept { _strategy = uint8_t(strategy); }
//! Tests whether the calling convention has the given `flag` set.
inline bool hasFlag(uint32_t flag) const noexcept { return (uint32_t(_flags) & flag) != 0; }
//! Returns the calling convention flags, see `Flags`.
inline uint32_t flags() const noexcept { return _flags; }
//! Adds the calling convention flags, see `Flags`.
inline void setFlags(uint32_t flag) noexcept { _flags = uint16_t(flag); };
//! Adds the calling convention flags, see `Flags`.
inline void addFlags(uint32_t flags) noexcept { _flags = uint16_t(_flags | flags); };
//! Tests whether this calling convention specifies 'RedZone'.
inline bool hasRedZone() const noexcept { return _redZoneSize != 0; }
//! Tests whether this calling convention specifies 'SpillZone'.
inline bool hasSpillZone() const noexcept { return _spillZoneSize != 0; }
//! Returns size of 'RedZone'.
inline uint32_t redZoneSize() const noexcept { return _redZoneSize; }
//! Returns size of 'SpillZone'.
inline uint32_t spillZoneSize() const noexcept { return _spillZoneSize; }
//! Sets size of 'RedZone'.
inline void setRedZoneSize(uint32_t size) noexcept { _redZoneSize = uint8_t(size); }
//! Sets size of 'SpillZone'.
inline void setSpillZoneSize(uint32_t size) noexcept { _spillZoneSize = uint8_t(size); }
//! Returns a natural stack alignment.
inline uint32_t naturalStackAlignment() const noexcept { return _naturalStackAlignment; }
//! Sets a natural stack alignment.
//!
//! This function can be used to override the default stack alignment in case
//! that you know that it's alignment is different. For example it allows to
//! implement custom calling conventions that guarantee higher stack alignment.
inline void setNaturalStackAlignment(uint32_t value) noexcept { _naturalStackAlignment = uint8_t(value); }
//! Returns the size of a register (or its part) to be saved and restored of the given `group`.
inline uint32_t saveRestoreRegSize(uint32_t group) const noexcept { return _saveRestoreRegSize[group]; }
//! Sets the size of a vector register (or its part) to be saved and restored.
inline void setSaveRestoreRegSize(uint32_t group, uint32_t size) noexcept { _saveRestoreRegSize[group] = uint8_t(size); }
//! Returns the alignment of a save-restore area of the given `group`.
inline uint32_t saveRestoreAlignment(uint32_t group) const noexcept { return _saveRestoreAlignment[group]; }
//! Sets the alignment of a save-restore area of the given `group`.
inline void setSaveRestoreAlignment(uint32_t group, uint32_t alignment) noexcept { _saveRestoreAlignment[group] = uint8_t(alignment); }
//! Returns the order of passed registers of the given `group`, see \ref BaseReg::RegGroup.
inline const uint8_t* passedOrder(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _passedOrder[group].id;
}
//! Returns the mask of passed registers of the given `group`, see \ref BaseReg::RegGroup.
inline uint32_t passedRegs(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _passedRegs[group];
}
inline void _setPassedPacked(uint32_t group, uint32_t p0, uint32_t p1, uint32_t p2, uint32_t p3) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_passedOrder[group].packed[0] = p0;
_passedOrder[group].packed[1] = p1;
_passedOrder[group].packed[2] = p2;
_passedOrder[group].packed[3] = p3;
}
//! Resets the order and mask of passed registers.
inline void setPassedToNone(uint32_t group) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_setPassedPacked(group, 0xFFFFFFFFu, 0xFFFFFFFFu, 0xFFFFFFFFu, 0xFFFFFFFFu);
_passedRegs[group] = 0u;
}
//! Sets the order and mask of passed registers.
inline void setPassedOrder(uint32_t group, uint32_t a0, uint32_t a1 = 0xFF, uint32_t a2 = 0xFF, uint32_t a3 = 0xFF, uint32_t a4 = 0xFF, uint32_t a5 = 0xFF, uint32_t a6 = 0xFF, uint32_t a7 = 0xFF) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
// NOTE: This should always be called with all arguments known at compile time,
// so even if it looks scary it should be translated into few instructions.
_setPassedPacked(group, Support::bytepack32_4x8(a0, a1, a2, a3),
Support::bytepack32_4x8(a4, a5, a6, a7),
0xFFFFFFFFu,
0xFFFFFFFFu);
_passedRegs[group] = (a0 != 0xFF ? 1u << a0 : 0u) |
(a1 != 0xFF ? 1u << a1 : 0u) |
(a2 != 0xFF ? 1u << a2 : 0u) |
(a3 != 0xFF ? 1u << a3 : 0u) |
(a4 != 0xFF ? 1u << a4 : 0u) |
(a5 != 0xFF ? 1u << a5 : 0u) |
(a6 != 0xFF ? 1u << a6 : 0u) |
(a7 != 0xFF ? 1u << a7 : 0u) ;
}
//! Returns preserved register mask of the given `group`, see \ref BaseReg::RegGroup.
inline uint32_t preservedRegs(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _preservedRegs[group];
}
//! Sets preserved register mask of the given `group`, see \ref BaseReg::RegGroup.
inline void setPreservedRegs(uint32_t group, uint32_t regs) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_preservedRegs[group] = regs;
}
//! \}
};
// ============================================================================
// [asmjit::FuncSignature]
// ============================================================================
//! Function signature.
//!
//! Contains information about function return type, count of arguments and
//! their TypeIds. Function signature is a low level structure which doesn't
//! contain platform specific or calling convention specific information.
struct FuncSignature {
//! Calling convention id.
uint8_t _callConv;
//! Count of arguments.
uint8_t _argCount;
//! Index of a first VA or `kNoVarArgs`.
uint8_t _vaIndex;
//! Return value TypeId.
uint8_t _ret;
//! Function arguments TypeIds.
const uint8_t* _args;
enum : uint8_t {
//! Doesn't have variable number of arguments (`...`).
kNoVarArgs = 0xFF
};
//! \name Initializtion & Reset
//! \{
//! Initializes the function signature.
inline void init(uint32_t ccId, uint32_t vaIndex, uint32_t ret, const uint8_t* args, uint32_t argCount) noexcept {
ASMJIT_ASSERT(ccId <= 0xFF);
ASMJIT_ASSERT(argCount <= 0xFF);
_callConv = uint8_t(ccId);
_argCount = uint8_t(argCount);
_vaIndex = uint8_t(vaIndex);
_ret = uint8_t(ret);
_args = args;
}
inline void reset() noexcept { memset(this, 0, sizeof(*this)); }
//! \}
//! \name Accessors
//! \{
//! Returns the calling convention.
inline uint32_t callConv() const noexcept { return _callConv; }
//! Sets the calling convention to `ccId`;
inline void setCallConv(uint32_t ccId) noexcept { _callConv = uint8_t(ccId); }
//! Tests whether the function has variable number of arguments (...).
inline bool hasVarArgs() const noexcept { return _vaIndex != kNoVarArgs; }
//! Returns the variable arguments (...) index, `kNoVarArgs` if none.
inline uint32_t vaIndex() const noexcept { return _vaIndex; }
//! Sets the variable arguments (...) index to `index`.
inline void setVaIndex(uint32_t index) noexcept { _vaIndex = uint8_t(index); }
//! Resets the variable arguments index (making it a non-va function).
inline void resetVaIndex() noexcept { _vaIndex = kNoVarArgs; }
//! Returns the number of function arguments.
inline uint32_t argCount() const noexcept { return _argCount; }
inline bool hasRet() const noexcept { return _ret != Type::kIdVoid; }
//! Returns the return value type.
inline uint32_t ret() const noexcept { return _ret; }
//! Returns the type of the argument at index `i`.
inline uint32_t arg(uint32_t i) const noexcept {
ASMJIT_ASSERT(i < _argCount);
return _args[i];
}
//! Returns the array of function arguments' types.
inline const uint8_t* args() const noexcept { return _args; }
//! \}
};
// ============================================================================
// [asmjit::FuncSignatureT]
// ============================================================================
template<typename... RET_ARGS>
class FuncSignatureT : public FuncSignature {
public:
inline FuncSignatureT(uint32_t ccId = CallConv::kIdHost, uint32_t vaIndex = kNoVarArgs) noexcept {
static const uint8_t ret_args[] = { (uint8_t(Type::IdOfT<RET_ARGS>::kTypeId))... };
init(ccId, vaIndex, ret_args[0], ret_args + 1, uint32_t(ASMJIT_ARRAY_SIZE(ret_args) - 1));
}
};
// ============================================================================
// [asmjit::FuncSignatureBuilder]
// ============================================================================
//! Function signature builder.
class FuncSignatureBuilder : public FuncSignature {
public:
uint8_t _builderArgList[Globals::kMaxFuncArgs];
//! \name Initializtion & Reset
//! \{
inline FuncSignatureBuilder(uint32_t ccId = CallConv::kIdHost, uint32_t vaIndex = kNoVarArgs) noexcept {
init(ccId, vaIndex, Type::kIdVoid, _builderArgList, 0);
}
//! \}
//! \name Accessors
//! \{
//! Sets the return type to `retType`.
inline void setRet(uint32_t retType) noexcept { _ret = uint8_t(retType); }
//! Sets the return type based on `T`.
template<typename T>
inline void setRetT() noexcept { setRet(Type::IdOfT<T>::kTypeId); }
//! Sets the argument at index `index` to `argType`.
inline void setArg(uint32_t index, uint32_t argType) noexcept {
ASMJIT_ASSERT(index < _argCount);
_builderArgList[index] = uint8_t(argType);
}
//! Sets the argument at index `i` to the type based on `T`.
template<typename T>
inline void setArgT(uint32_t index) noexcept { setArg(index, Type::IdOfT<T>::kTypeId); }
//! Appends an argument of `type` to the function prototype.
inline void addArg(uint32_t type) noexcept {
ASMJIT_ASSERT(_argCount < Globals::kMaxFuncArgs);
_builderArgList[_argCount++] = uint8_t(type);
}
//! Appends an argument of type based on `T` to the function prototype.
template<typename T>
inline void addArgT() noexcept { addArg(Type::IdOfT<T>::kTypeId); }
//! \}
};
// ============================================================================
// [asmjit::FuncValue]
// ============================================================================
//! Argument or return value (or its part) as defined by `FuncSignature`, but
//! with register or stack address (and other metadata) assigned.
struct FuncValue {
uint32_t _data;
enum Parts : uint32_t {
kTypeIdShift = 0, //!< TypeId shift.
kTypeIdMask = 0x000000FFu, //!< TypeId mask.
kFlagIsReg = 0x00000100u, //!< Passed by register.
kFlagIsStack = 0x00000200u, //!< Passed by stack.
kFlagIsIndirect = 0x00000400u, //!< Passed indirectly by reference (internally a pointer).
kFlagIsDone = 0x00000800u, //!< Used internally by arguments allocator.
kStackOffsetShift = 12, //!< Stack offset shift.
kStackOffsetMask = 0xFFFFF000u, //!< Stack offset mask (must occupy MSB bits).
kRegIdShift = 16, //!< RegId shift.
kRegIdMask = 0x00FF0000u, //!< RegId mask.
kRegTypeShift = 24, //!< RegType shift.
kRegTypeMask = 0xFF000000u //!< RegType mask.
};
//! \name Initializtion & Reset
//! \{
// These initialize the whole `FuncValue` to either register or stack. Useful
// when you know all of these properties and wanna just set it up.
//! Initializes the `typeId` of this `FuncValue`.
inline void initTypeId(uint32_t typeId) noexcept {
_data = typeId << kTypeIdShift;
}
inline void initReg(uint32_t regType, uint32_t regId, uint32_t typeId, uint32_t flags = 0) noexcept {
_data = (regType << kRegTypeShift) | (regId << kRegIdShift) | (typeId << kTypeIdShift) | kFlagIsReg | flags;
}
inline void initStack(int32_t offset, uint32_t typeId) noexcept {
_data = (uint32_t(offset) << kStackOffsetShift) | (typeId << kTypeIdShift) | kFlagIsStack;
}
//! Resets the value to its unassigned state.
inline void reset() noexcept { _data = 0; }
//! \}
//! \name Assign
//! \{
// These initialize only part of `FuncValue`, useful when building `FuncValue`
// incrementally. The caller should first init the type-id by caliing `initTypeId`
// and then continue building either register or stack.
inline void assignRegData(uint32_t regType, uint32_t regId) noexcept {
ASMJIT_ASSERT((_data & (kRegTypeMask | kRegIdMask)) == 0);
_data |= (regType << kRegTypeShift) | (regId << kRegIdShift) | kFlagIsReg;
}
inline void assignStackOffset(int32_t offset) noexcept {
ASMJIT_ASSERT((_data & kStackOffsetMask) == 0);
_data |= (uint32_t(offset) << kStackOffsetShift) | kFlagIsStack;
}
//! \}
//! \name Accessors
//! \{
inline explicit operator bool() const noexcept { return _data != 0; }
inline void _replaceValue(uint32_t mask, uint32_t value) noexcept { _data = (_data & ~mask) | value; }
//! Tests whether the `FuncValue` has a flag `flag` set.
inline bool hasFlag(uint32_t flag) const noexcept { return (_data & flag) != 0; }
//! Adds `flags` to `FuncValue`.
inline void addFlags(uint32_t flags) noexcept { _data |= flags; }
//! Clears `flags` of `FuncValue`.
inline void clearFlags(uint32_t flags) noexcept { _data &= ~flags; }
//! Tests whether the value is initialized (i.e. contains a valid data).
inline bool isInitialized() const noexcept { return _data != 0; }
//! Tests whether the argument is passed by register.
inline bool isReg() const noexcept { return hasFlag(kFlagIsReg); }
//! Tests whether the argument is passed by stack.
inline bool isStack() const noexcept { return hasFlag(kFlagIsStack); }
//! Tests whether the argument is passed by register.
inline bool isAssigned() const noexcept { return hasFlag(kFlagIsReg | kFlagIsStack); }
//! Tests whether the argument is passed through a pointer (used by WIN64 to pass XMM|YMM|ZMM).
inline bool isIndirect() const noexcept { return hasFlag(kFlagIsIndirect); }
//! Tests whether the argument was already processed (used internally).
inline bool isDone() const noexcept { return hasFlag(kFlagIsDone); }
//! Returns a register type of the register used to pass function argument or return value.
inline uint32_t regType() const noexcept { return (_data & kRegTypeMask) >> kRegTypeShift; }
//! Sets a register type of the register used to pass function argument or return value.
inline void setRegType(uint32_t regType) noexcept { _replaceValue(kRegTypeMask, regType << kRegTypeShift); }
//! Returns a physical id of the register used to pass function argument or return value.
inline uint32_t regId() const noexcept { return (_data & kRegIdMask) >> kRegIdShift; }
//! Sets a physical id of the register used to pass function argument or return value.
inline void setRegId(uint32_t regId) noexcept { _replaceValue(kRegIdMask, regId << kRegIdShift); }
//! Returns a stack offset of this argument.
inline int32_t stackOffset() const noexcept { return int32_t(_data & kStackOffsetMask) >> kStackOffsetShift; }
//! Sets a stack offset of this argument.
inline void setStackOffset(int32_t offset) noexcept { _replaceValue(kStackOffsetMask, uint32_t(offset) << kStackOffsetShift); }
//! Tests whether the argument or return value has associated `Type::Id`.
inline bool hasTypeId() const noexcept { return (_data & kTypeIdMask) != 0; }
//! Returns a TypeId of this argument or return value.
inline uint32_t typeId() const noexcept { return (_data & kTypeIdMask) >> kTypeIdShift; }
//! Sets a TypeId of this argument or return value.
inline void setTypeId(uint32_t typeId) noexcept { _replaceValue(kTypeIdMask, typeId << kTypeIdShift); }
//! \}
};
// ============================================================================
// [asmjit::FuncValuePack]
// ============================================================================
//! Contains multiple `FuncValue` instances in an array so functions that use
//! multiple registers for arguments or return values can represent all inputs
//! and outputs.
struct FuncValuePack {
public:
//! Values data.
FuncValue _values[Globals::kMaxValuePack];
inline void reset() noexcept {
for (size_t i = 0; i < Globals::kMaxValuePack; i++)
_values[i].reset();
}
//! Calculates how many values are in the pack, checking for non-values
//! from the end.
inline uint32_t count() const noexcept {
uint32_t n = Globals::kMaxValuePack;
while (n && !_values[n - 1])
n--;
return n;
}
inline FuncValue* values() noexcept { return _values; }
inline const FuncValue* values() const noexcept { return _values; }
inline void resetValue(size_t index) noexcept {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
_values[index].reset();
}
inline bool hasValue(size_t index) noexcept {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
return _values[index].isInitialized();
}
inline void assignReg(size_t index, const BaseReg& reg, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
ASMJIT_ASSERT(reg.isPhysReg());
_values[index].initReg(reg.type(), reg.id(), typeId);
}
inline void assignReg(size_t index, uint32_t regType, uint32_t regId, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
_values[index].initReg(regType, regId, typeId);
}
inline void assignStack(size_t index, int32_t offset, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
_values[index].initStack(offset, typeId);
}
inline FuncValue& operator[](size_t index) {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
return _values[index];
}
inline const FuncValue& operator[](size_t index) const {
ASMJIT_ASSERT(index < Globals::kMaxValuePack);
return _values[index];
}
};
// ============================================================================
// [asmjit::FuncDetail]
// ============================================================================
//! Function detail - CallConv and expanded FuncSignature.
//!
//! Function detail is architecture and OS dependent representation of a function.
//! It contains calling convention and expanded function signature so all
//! arguments have assigned either register type & id or stack address.
class FuncDetail {
public:
//! Calling convention.
CallConv _callConv;
//! Number of function arguments.
uint8_t _argCount;
//! Variable arguments index of `kNoVarArgs`.
uint8_t _vaIndex;
//! Reserved for future use.
uint16_t _reserved;
//! Registers that contains arguments.
uint32_t _usedRegs[BaseReg::kGroupVirt];
//! Size of arguments passed by stack.
uint32_t _argStackSize;
//! Function return value(s).
FuncValuePack _rets;
//! Function arguments.
FuncValuePack _args[Globals::kMaxFuncArgs];
enum : uint8_t {
//! Doesn't have variable number of arguments (`...`).
kNoVarArgs = 0xFF
};
//! \name Construction & Destruction
//! \{
inline FuncDetail() noexcept { reset(); }
inline FuncDetail(const FuncDetail& other) noexcept = default;
//! Initializes this `FuncDetail` to the given signature.
ASMJIT_API Error init(const FuncSignature& signature, const Environment& environment) noexcept;
inline void reset() noexcept { memset(this, 0, sizeof(*this)); }
//! \}
//! \name Accessors
//! \{
//! Returns the function's calling convention, see `CallConv`.
inline const CallConv& callConv() const noexcept { return _callConv; }
//! Returns the associated calling convention flags, see `CallConv::Flags`.
inline uint32_t flags() const noexcept { return _callConv.flags(); }
//! Checks whether a CallConv `flag` is set, see `CallConv::Flags`.
inline bool hasFlag(uint32_t ccFlag) const noexcept { return _callConv.hasFlag(ccFlag); }
//! Tests whether the function has a return value.
inline bool hasRet() const noexcept { return bool(_rets[0]); }
//! Returns the number of function arguments.
inline uint32_t argCount() const noexcept { return _argCount; }
//! Returns function return values.
inline FuncValuePack& retPack() noexcept { return _rets; }
//! Returns function return values.
inline const FuncValuePack& retPack() const noexcept { return _rets; }
//! Returns a function return value associated with the given `valueIndex`.
inline FuncValue& ret(size_t valueIndex = 0) noexcept { return _rets[valueIndex]; }
//! Returns a function return value associated with the given `valueIndex` (const).
inline const FuncValue& ret(size_t valueIndex = 0) const noexcept { return _rets[valueIndex]; }
//! Returns function argument packs array.
inline FuncValuePack* argPacks() noexcept { return _args; }
//! Returns function argument packs array (const).
inline const FuncValuePack* argPacks() const noexcept { return _args; }
//! Returns function argument pack at the given `argIndex`.
inline FuncValuePack& argPack(size_t argIndex) noexcept {
ASMJIT_ASSERT(argIndex < Globals::kMaxFuncArgs);
return _args[argIndex];
}
//! Returns function argument pack at the given `argIndex` (const).
inline const FuncValuePack& argPack(size_t argIndex) const noexcept {
ASMJIT_ASSERT(argIndex < Globals::kMaxFuncArgs);
return _args[argIndex];
}
//! Returns an argument at `valueIndex` from the argument pack at the given `argIndex`.
inline FuncValue& arg(size_t argIndex, size_t valueIndex = 0) noexcept {
ASMJIT_ASSERT(argIndex < Globals::kMaxFuncArgs);
return _args[argIndex][valueIndex];
}
//! Returns an argument at `valueIndex` from the argument pack at the given `argIndex` (const).
inline const FuncValue& arg(size_t argIndex, size_t valueIndex = 0) const noexcept {
ASMJIT_ASSERT(argIndex < Globals::kMaxFuncArgs);
return _args[argIndex][valueIndex];
}
//! Resets an argument at the given `argIndex`.
//!
//! If the argument is a parameter pack (has multiple values) all values are reset.
inline void resetArg(size_t argIndex) noexcept {
ASMJIT_ASSERT(argIndex < Globals::kMaxFuncArgs);
_args[argIndex].reset();
}
//! Tests whether the function has variable arguments.
inline bool hasVarArgs() const noexcept { return _vaIndex != kNoVarArgs; }
//! Returns an index of a first variable argument.
inline uint32_t vaIndex() const noexcept { return _vaIndex; }
//! Tests whether the function passes one or more argument by stack.
inline bool hasStackArgs() const noexcept { return _argStackSize != 0; }
//! Returns stack size needed for function arguments passed on the stack.
inline uint32_t argStackSize() const noexcept { return _argStackSize; }
//! Returns red zone size.
inline uint32_t redZoneSize() const noexcept { return _callConv.redZoneSize(); }
//! Returns spill zone size.
inline uint32_t spillZoneSize() const noexcept { return _callConv.spillZoneSize(); }
//! Returns natural stack alignment.
inline uint32_t naturalStackAlignment() const noexcept { return _callConv.naturalStackAlignment(); }
//! Returns a mask of all passed registers of the given register `group`.
inline uint32_t passedRegs(uint32_t group) const noexcept { return _callConv.passedRegs(group); }
//! Returns a mask of all preserved registers of the given register `group`.
inline uint32_t preservedRegs(uint32_t group) const noexcept { return _callConv.preservedRegs(group); }
//! Returns a mask of all used registers of the given register `group`.
inline uint32_t usedRegs(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _usedRegs[group];
}
//! Adds `regs` to the mask of used registers of the given register `group`.
inline void addUsedRegs(uint32_t group, uint32_t regs) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_usedRegs[group] |= regs;
}
//! \}
};
// ============================================================================
// [asmjit::FuncFrame]
// ============================================================================
//! Function frame.
//!
//! Function frame is used directly by prolog and epilog insertion (PEI) utils.
//! It provides information necessary to insert a proper and ABI comforming
//! prolog and epilog. Function frame calculation is based on `CallConv` and
//! other function attributes.
//!
//! Function Frame Structure
//! ------------------------
//!
//! Various properties can contribute to the size and structure of the function
//! frame. The function frame in most cases won't use all of the properties
//! illustrated (for example Spill Zone and Red Zone are never used together).
//!
//! ```
//! +-----------------------------+
//! | Arguments Passed by Stack |
//! +-----------------------------+
//! | Spill Zone |
//! +-----------------------------+ <- Stack offset (args) starts from here.
//! | Return Address, if Pushed |
//! +-----------------------------+ <- Stack pointer (SP) upon entry.
//! | Save/Restore Stack. |
//! +-----------------------------+-----------------------------+
//! | Local Stack | |
//! +-----------------------------+ Final Stack |
//! | Call Stack | |
//! +-----------------------------+-----------------------------+ <- SP after prolog.
//! | Red Zone |
//! +-----------------------------+
//! ```
class FuncFrame {
public:
enum Tag : uint32_t {
//! Tag used to inform that some offset is invalid.
kTagInvalidOffset = 0xFFFFFFFFu
};
//! Attributes are designed in a way that all are initially false, and user
//! or FuncFrame finalizer adds them when necessary.
enum Attributes : uint32_t {
//! Function has variable number of arguments.
kAttrHasVarArgs = 0x00000001u,
//! Preserve frame pointer (don't omit FP).
kAttrHasPreservedFP = 0x00000010u,
//! Function calls other functions (is not leaf).
kAttrHasFuncCalls = 0x00000020u,
//! Use AVX instead of SSE for all operations (X86).
kAttrX86AvxEnabled = 0x00010000u,
//! Emit VZEROUPPER instruction in epilog (X86).
kAttrX86AvxCleanup = 0x00020000u,
//! Emit EMMS instruction in epilog (X86).
kAttrX86MmxCleanup = 0x00040000u,
//! Function has aligned save/restore of vector registers.
kAttrAlignedVecSR = 0x40000000u,
//! FuncFrame is finalized and can be used by PEI.
kAttrIsFinalized = 0x80000000u
};
//! Function attributes.
uint32_t _attributes;
//! Architecture, see \ref Environment::Arch.
uint8_t _arch;
//! SP register ID (to access call stack and local stack).
uint8_t _spRegId;
//! SA register ID (to access stack arguments).
uint8_t _saRegId;
//! Red zone size (copied from CallConv).
uint8_t _redZoneSize;
//! Spill zone size (copied from CallConv).
uint8_t _spillZoneSize;
//! Natural stack alignment (copied from CallConv).
uint8_t _naturalStackAlignment;
//! Minimum stack alignment to turn on dynamic alignment.
uint8_t _minDynamicAlignment;
//! Call stack alignment.
uint8_t _callStackAlignment;
//! Local stack alignment.
uint8_t _localStackAlignment;
//! Final stack alignment.
uint8_t _finalStackAlignment;
//! Adjustment of the stack before returning (X86-STDCALL).
uint16_t _calleeStackCleanup;
//! Call stack size.
uint32_t _callStackSize;
//! Local stack size.
uint32_t _localStackSize;
//! Final stack size (sum of call stack and local stack).
uint32_t _finalStackSize;
//! Local stack offset (non-zero only if call stack is used).
uint32_t _localStackOffset;
//! Offset relative to SP that contains previous SP (before alignment).
uint32_t _daOffset;
//! Offset of the first stack argument relative to SP.
uint32_t _saOffsetFromSP;
//! Offset of the first stack argument relative to SA (_saRegId or FP).
uint32_t _saOffsetFromSA;
//! Local stack adjustment in prolog/epilog.
uint32_t _stackAdjustment;
//! Registers that are dirty.
uint32_t _dirtyRegs[BaseReg::kGroupVirt];
//! Registers that must be preserved (copied from CallConv).
uint32_t _preservedRegs[BaseReg::kGroupVirt];
//! Size to save/restore per register group.
uint8_t _saveRestoreRegSize[BaseReg::kGroupVirt];
//! Alignment of save/restore area per register group.
uint8_t _saveRestoreAlignment[BaseReg::kGroupVirt];
//! Stack size required to save registers with push/pop.
uint16_t _pushPopSaveSize;
//! Stack size required to save extra registers that cannot use push/pop.
uint16_t _extraRegSaveSize;
//! Offset where registers saved/restored via push/pop are stored
uint32_t _pushPopSaveOffset;
//! Offset where extra ragisters that cannot use push/pop are stored.
uint32_t _extraRegSaveOffset;
//! \name Construction & Destruction
//! \{
inline FuncFrame() noexcept { reset(); }
inline FuncFrame(const FuncFrame& other) noexcept = default;
ASMJIT_API Error init(const FuncDetail& func) noexcept;
inline void reset() noexcept {
memset(this, 0, sizeof(FuncFrame));
_spRegId = BaseReg::kIdBad;
_saRegId = BaseReg::kIdBad;
_daOffset = kTagInvalidOffset;
}
//! \}
//! \name Accessors
//! \{
//! Returns the target architecture of the function frame.
inline uint32_t arch() const noexcept { return _arch; }
//! Returns function frame attributes, see `Attributes`.
inline uint32_t attributes() const noexcept { return _attributes; }
//! Checks whether the FuncFame contains an attribute `attr`.
inline bool hasAttribute(uint32_t attr) const noexcept { return (_attributes & attr) != 0; }
//! Adds attributes `attrs` to the FuncFrame.
inline void addAttributes(uint32_t attrs) noexcept { _attributes |= attrs; }
//! Clears attributes `attrs` from the FrameFrame.
inline void clearAttributes(uint32_t attrs) noexcept { _attributes &= ~attrs; }
//! Tests whether the function has variable number of arguments.
inline bool hasVarArgs() const noexcept { return hasAttribute(kAttrHasVarArgs); }
//! Sets the variable arguments flag.
inline void setVarArgs() noexcept { addAttributes(kAttrHasVarArgs); }
//! Resets variable arguments flag.
inline void resetVarArgs() noexcept { clearAttributes(kAttrHasVarArgs); }
//! Tests whether the function preserves frame pointer (EBP|ESP on X86).
inline bool hasPreservedFP() const noexcept { return hasAttribute(kAttrHasPreservedFP); }
//! Enables preserved frame pointer.
inline void setPreservedFP() noexcept { addAttributes(kAttrHasPreservedFP); }
//! Disables preserved frame pointer.
inline void resetPreservedFP() noexcept { clearAttributes(kAttrHasPreservedFP); }
//! Tests whether the function calls other functions.
inline bool hasFuncCalls() const noexcept { return hasAttribute(kAttrHasFuncCalls); }
//! Sets `kFlagHasCalls` to true.
inline void setFuncCalls() noexcept { addAttributes(kAttrHasFuncCalls); }
//! Sets `kFlagHasCalls` to false.
inline void resetFuncCalls() noexcept { clearAttributes(kAttrHasFuncCalls); }
//! Tests whether the function contains AVX cleanup - 'vzeroupper' instruction in epilog.
inline bool hasAvxCleanup() const noexcept { return hasAttribute(kAttrX86AvxCleanup); }
//! Enables AVX cleanup.
inline void setAvxCleanup() noexcept { addAttributes(kAttrX86AvxCleanup); }
//! Disables AVX cleanup.
inline void resetAvxCleanup() noexcept { clearAttributes(kAttrX86AvxCleanup); }
//! Tests whether the function contains AVX cleanup - 'vzeroupper' instruction in epilog.
inline bool isAvxEnabled() const noexcept { return hasAttribute(kAttrX86AvxEnabled); }
//! Enables AVX cleanup.
inline void setAvxEnabled() noexcept { addAttributes(kAttrX86AvxEnabled); }
//! Disables AVX cleanup.
inline void resetAvxEnabled() noexcept { clearAttributes(kAttrX86AvxEnabled); }
//! Tests whether the function contains MMX cleanup - 'emms' instruction in epilog.
inline bool hasMmxCleanup() const noexcept { return hasAttribute(kAttrX86MmxCleanup); }
//! Enables MMX cleanup.
inline void setMmxCleanup() noexcept { addAttributes(kAttrX86MmxCleanup); }
//! Disables MMX cleanup.
inline void resetMmxCleanup() noexcept { clearAttributes(kAttrX86MmxCleanup); }
//! Tests whether the function uses call stack.
inline bool hasCallStack() const noexcept { return _callStackSize != 0; }
//! Tests whether the function uses local stack.
inline bool hasLocalStack() const noexcept { return _localStackSize != 0; }
//! Tests whether vector registers can be saved and restored by using aligned reads and writes.
inline bool hasAlignedVecSR() const noexcept { return hasAttribute(kAttrAlignedVecSR); }
//! Tests whether the function has to align stack dynamically.
inline bool hasDynamicAlignment() const noexcept { return _finalStackAlignment >= _minDynamicAlignment; }
//! Tests whether the calling convention specifies 'RedZone'.
inline bool hasRedZone() const noexcept { return _redZoneSize != 0; }
//! Tests whether the calling convention specifies 'SpillZone'.
inline bool hasSpillZone() const noexcept { return _spillZoneSize != 0; }
//! Returns the size of 'RedZone'.
inline uint32_t redZoneSize() const noexcept { return _redZoneSize; }
//! Returns the size of 'SpillZone'.
inline uint32_t spillZoneSize() const noexcept { return _spillZoneSize; }
//! Returns natural stack alignment (guaranteed stack alignment upon entry).
inline uint32_t naturalStackAlignment() const noexcept { return _naturalStackAlignment; }
//! Returns natural stack alignment (guaranteed stack alignment upon entry).
inline uint32_t minDynamicAlignment() const noexcept { return _minDynamicAlignment; }
//! Tests whether the callee must adjust SP before returning (X86-STDCALL only)
inline bool hasCalleeStackCleanup() const noexcept { return _calleeStackCleanup != 0; }
//! Returns home many bytes of the stack the the callee must adjust before returning (X86-STDCALL only)
inline uint32_t calleeStackCleanup() const noexcept { return _calleeStackCleanup; }
//! Returns call stack alignment.
inline uint32_t callStackAlignment() const noexcept { return _callStackAlignment; }
//! Returns local stack alignment.
inline uint32_t localStackAlignment() const noexcept { return _localStackAlignment; }
//! Returns final stack alignment (the maximum value of call, local, and natural stack alignments).
inline uint32_t finalStackAlignment() const noexcept { return _finalStackAlignment; }
//! Sets call stack alignment.
//!
//! \note This also updates the final stack alignment.
inline void setCallStackAlignment(uint32_t alignment) noexcept {
_callStackAlignment = uint8_t(alignment);
_finalStackAlignment = Support::max(_naturalStackAlignment, _callStackAlignment, _localStackAlignment);
}
//! Sets local stack alignment.
//!
//! \note This also updates the final stack alignment.
inline void setLocalStackAlignment(uint32_t value) noexcept {
_localStackAlignment = uint8_t(value);
_finalStackAlignment = Support::max(_naturalStackAlignment, _callStackAlignment, _localStackAlignment);
}
//! Combines call stack alignment with `alignment`, updating it to the greater value.
//!
//! \note This also updates the final stack alignment.
inline void updateCallStackAlignment(uint32_t alignment) noexcept {
_callStackAlignment = uint8_t(Support::max<uint32_t>(_callStackAlignment, alignment));
_finalStackAlignment = Support::max(_finalStackAlignment, _callStackAlignment);
}
//! Combines local stack alignment with `alignment`, updating it to the greater value.
//!
//! \note This also updates the final stack alignment.
inline void updateLocalStackAlignment(uint32_t alignment) noexcept {
_localStackAlignment = uint8_t(Support::max<uint32_t>(_localStackAlignment, alignment));
_finalStackAlignment = Support::max(_finalStackAlignment, _localStackAlignment);
}
//! Returns call stack size.
inline uint32_t callStackSize() const noexcept { return _callStackSize; }
//! Returns local stack size.
inline uint32_t localStackSize() const noexcept { return _localStackSize; }
//! Sets call stack size.
inline void setCallStackSize(uint32_t size) noexcept { _callStackSize = size; }
//! Sets local stack size.
inline void setLocalStackSize(uint32_t size) noexcept { _localStackSize = size; }
//! Combines call stack size with `size`, updating it to the greater value.
inline void updateCallStackSize(uint32_t size) noexcept { _callStackSize = Support::max(_callStackSize, size); }
//! Combines local stack size with `size`, updating it to the greater value.
inline void updateLocalStackSize(uint32_t size) noexcept { _localStackSize = Support::max(_localStackSize, size); }
//! Returns final stack size (only valid after the FuncFrame is finalized).
inline uint32_t finalStackSize() const noexcept { return _finalStackSize; }
//! Returns an offset to access the local stack (non-zero only if call stack is used).
inline uint32_t localStackOffset() const noexcept { return _localStackOffset; }
//! Tests whether the function prolog/epilog requires a memory slot for storing unaligned SP.
inline bool hasDAOffset() const noexcept { return _daOffset != kTagInvalidOffset; }
//! Returns a memory offset used to store DA (dynamic alignment) slot (relative to SP).
inline uint32_t daOffset() const noexcept { return _daOffset; }
inline uint32_t saOffset(uint32_t regId) const noexcept {
return regId == _spRegId ? saOffsetFromSP()
: saOffsetFromSA();
}
inline uint32_t saOffsetFromSP() const noexcept { return _saOffsetFromSP; }
inline uint32_t saOffsetFromSA() const noexcept { return _saOffsetFromSA; }
//! Returns mask of registers of the given register `group` that are modified
//! by the function. The engine would then calculate which registers must be
//! saved & restored by the function by using the data provided by the calling
//! convention.
inline uint32_t dirtyRegs(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _dirtyRegs[group];
}
//! Sets which registers (as a mask) are modified by the function.
//!
//! \remarks Please note that this will completely overwrite the existing
//! register mask, use `addDirtyRegs()` to modify the existing register
//! mask.
inline void setDirtyRegs(uint32_t group, uint32_t regs) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_dirtyRegs[group] = regs;
}
//! Adds which registers (as a mask) are modified by the function.
inline void addDirtyRegs(uint32_t group, uint32_t regs) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_dirtyRegs[group] |= regs;
}
//! \overload
inline void addDirtyRegs(const BaseReg& reg) noexcept {
ASMJIT_ASSERT(reg.id() < Globals::kMaxPhysRegs);
addDirtyRegs(reg.group(), Support::bitMask(reg.id()));
}
//! \overload
template<typename... Args>
ASMJIT_INLINE void addDirtyRegs(const BaseReg& reg, Args&&... args) noexcept {
addDirtyRegs(reg);
addDirtyRegs(std::forward<Args>(args)...);
}
inline void setAllDirty() noexcept {
for (size_t i = 0; i < ASMJIT_ARRAY_SIZE(_dirtyRegs); i++)
_dirtyRegs[i] = 0xFFFFFFFFu;
}
inline void setAllDirty(uint32_t group) noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
_dirtyRegs[group] = 0xFFFFFFFFu;
}
//! Returns a calculated mask of registers of the given `group` that will be
//! saved and restored in the function's prolog and epilog, respectively. The
//! register mask is calculated from both `dirtyRegs` (provided by user) and
//! `preservedMask` (provided by the calling convention).
inline uint32_t savedRegs(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _dirtyRegs[group] & _preservedRegs[group];
}
//! Returns the mask of preserved registers of the given register `group`.
//!
//! Preserved registers are those that must survive the function call
//! unmodified. The function can only modify preserved registers it they
//! are saved and restored in funciton's prolog and epilog, respectively.
inline uint32_t preservedRegs(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _preservedRegs[group];
}
inline uint32_t saveRestoreRegSize(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _saveRestoreRegSize[group];
}
inline uint32_t saveRestoreAlignment(uint32_t group) const noexcept {
ASMJIT_ASSERT(group < BaseReg::kGroupVirt);
return _saveRestoreAlignment[group];
}
inline bool hasSARegId() const noexcept { return _saRegId != BaseReg::kIdBad; }
inline uint32_t saRegId() const noexcept { return _saRegId; }
inline void setSARegId(uint32_t regId) { _saRegId = uint8_t(regId); }
inline void resetSARegId() { setSARegId(BaseReg::kIdBad); }
//! Returns stack size required to save/restore registers via push/pop.
inline uint32_t pushPopSaveSize() const noexcept { return _pushPopSaveSize; }
//! Returns an offset to the stack where registers are saved via push/pop.
inline uint32_t pushPopSaveOffset() const noexcept { return _pushPopSaveOffset; }
//! Returns stack size required to save/restore extra registers that don't
//! use push/pop/
//!
//! \note On X86 this covers all registers except GP registers, on other
//! architectures it can be always zero (for example AArch64 saves all
//! registers via push/pop like instructions, so this would be zero).
inline uint32_t extraRegSaveSize() const noexcept { return _extraRegSaveSize; }
//! Returns an offset to the stack where extra registers are saved.
inline uint32_t extraRegSaveOffset() const noexcept { return _extraRegSaveOffset; }
//! Tests whether the functions contains stack adjustment.
inline bool hasStackAdjustment() const noexcept { return _stackAdjustment != 0; }
//! Returns function's stack adjustment used in function's prolog and epilog.
//!
//! If the returned value is zero it means that the stack is not adjusted.
//! This can mean both that the stack is not used and/or the stack is only
//! adjusted by instructions that pust/pop registers into/from stack.
inline uint32_t stackAdjustment() const noexcept { return _stackAdjustment; }
//! \}
//! \name Finaliztion
//! \{
ASMJIT_API Error finalize() noexcept;
//! \}
};
// ============================================================================
// [asmjit::FuncArgsAssignment]
// ============================================================================
//! A helper class that can be used to assign a physical register for each
//! function argument. Use with `BaseEmitter::emitArgsAssignment()`.
class FuncArgsAssignment {
public:
//! Function detail.
const FuncDetail* _funcDetail;
//! Register that can be used to access arguments passed by stack.
uint8_t _saRegId;
//! Reserved for future use.
uint8_t _reserved[3];
//! Mapping of each function argument.
FuncValuePack _argPacks[Globals::kMaxFuncArgs];
//! \name Construction & Destruction
//! \{
inline explicit FuncArgsAssignment(const FuncDetail* fd = nullptr) noexcept { reset(fd); }
inline FuncArgsAssignment(const FuncArgsAssignment& other) noexcept {
memcpy(this, &other, sizeof(*this));
}
inline void reset(const FuncDetail* fd = nullptr) noexcept {
_funcDetail = fd;
_saRegId = uint8_t(BaseReg::kIdBad);
memset(_reserved, 0, sizeof(_reserved));
memset(_argPacks, 0, sizeof(_argPacks));
}
//! \}
//! \name Accessors
//! \{
inline const FuncDetail* funcDetail() const noexcept { return _funcDetail; }
inline void setFuncDetail(const FuncDetail* fd) noexcept { _funcDetail = fd; }
inline bool hasSARegId() const noexcept { return _saRegId != BaseReg::kIdBad; }
inline uint32_t saRegId() const noexcept { return _saRegId; }
inline void setSARegId(uint32_t regId) { _saRegId = uint8_t(regId); }
inline void resetSARegId() { _saRegId = uint8_t(BaseReg::kIdBad); }
inline FuncValue& arg(size_t argIndex, size_t valueIndex) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
return _argPacks[argIndex][valueIndex];
}
inline const FuncValue& arg(size_t argIndex, size_t valueIndex) const noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
return _argPacks[argIndex][valueIndex];
}
inline bool isAssigned(size_t argIndex, size_t valueIndex) const noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
return _argPacks[argIndex][valueIndex].isAssigned();
}
inline void assignReg(size_t argIndex, const BaseReg& reg, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
ASMJIT_ASSERT(reg.isPhysReg());
_argPacks[argIndex][0].initReg(reg.type(), reg.id(), typeId);
}
inline void assignReg(size_t argIndex, uint32_t regType, uint32_t regId, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
_argPacks[argIndex][0].initReg(regType, regId, typeId);
}
inline void assignStack(size_t argIndex, int32_t offset, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
_argPacks[argIndex][0].initStack(offset, typeId);
}
inline void assignRegInPack(size_t argIndex, size_t valueIndex, const BaseReg& reg, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
ASMJIT_ASSERT(reg.isPhysReg());
_argPacks[argIndex][valueIndex].initReg(reg.type(), reg.id(), typeId);
}
inline void assignRegInPack(size_t argIndex, size_t valueIndex, uint32_t regType, uint32_t regId, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
_argPacks[argIndex][valueIndex].initReg(regType, regId, typeId);
}
inline void assignStackInPack(size_t argIndex, size_t valueIndex, int32_t offset, uint32_t typeId = Type::kIdVoid) noexcept {
ASMJIT_ASSERT(argIndex < ASMJIT_ARRAY_SIZE(_argPacks));
_argPacks[argIndex][valueIndex].initStack(offset, typeId);
}
// NOTE: All `assignAll()` methods are shortcuts to assign all arguments at
// once, however, since registers are passed all at once these initializers
// don't provide any way to pass TypeId and/or to keep any argument between
// the arguments passed unassigned.
inline void _assignAllInternal(size_t argIndex, const BaseReg& reg) noexcept {
assignReg(argIndex, reg);
}
template<typename... Args>
inline void _assignAllInternal(size_t argIndex, const BaseReg& reg, Args&&... args) noexcept {
assignReg(argIndex, reg);
_assignAllInternal(argIndex + 1, std::forward<Args>(args)...);
}
template<typename... Args>
inline void assignAll(Args&&... args) noexcept {
_assignAllInternal(0, std::forward<Args>(args)...);
}
//! \}
//! \name Utilities
//! \{
//! Update `FuncFrame` based on function's arguments assignment.
//!
//! \note You MUST call this in orher to use `BaseEmitter::emitArgsAssignment()`,
//! otherwise the FuncFrame would not contain the information necessary to
//! assign all arguments into the registers and/or stack specified.
ASMJIT_API Error updateFuncFrame(FuncFrame& frame) const noexcept;
//! \}
};
//! \}
ASMJIT_END_NAMESPACE
#endif // ASMJIT_CORE_FUNC_H_INCLUDED