//===- subzero/src/IceTargetLoweringX8632Traits.h - x86-32 traits -*- C++ -*-=// // // The Subzero Code Generator // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// \brief Declares the X8632 Target Lowering Traits. /// //===----------------------------------------------------------------------===// #ifndef SUBZERO_SRC_ICETARGETLOWERINGX8632TRAITS_H #define SUBZERO_SRC_ICETARGETLOWERINGX8632TRAITS_H #include "IceAssembler.h" #include "IceConditionCodesX8632.h" #include "IceDefs.h" #include "IceInst.h" #include "IceInstX8632.def" #include "IceOperand.h" #include "IceRegistersX8632.h" #include "IceTargetLowering.h" #include "IceTargetLoweringX8632.def" #include "IceTargetLoweringX86RegClass.h" #include namespace Ice { namespace X8632 { using namespace ::Ice::X86; template struct Insts; template class TargetX86Base; template class AssemblerX86Base; class TargetX8632; struct TargetX8632Traits { //---------------------------------------------------------------------------- // ______ ______ __ __ // /\ __ \/\ ___\/\ "-./ \ // \ \ __ \ \___ \ \ \-./\ \ // \ \_\ \_\/\_____\ \_\ \ \_\ // \/_/\/_/\/_____/\/_/ \/_/ // //---------------------------------------------------------------------------- static constexpr ::Ice::Assembler::AssemblerKind AsmKind = ::Ice::Assembler::Asm_X8632; static constexpr bool Is64Bit = false; static constexpr bool HasPopa = true; static constexpr bool HasPusha = true; static constexpr bool UsesX87 = true; static constexpr ::Ice::RegX8632::GPRRegister Last8BitGPR = ::Ice::RegX8632::GPRRegister::Encoded_Reg_ebx; enum ScaleFactor { TIMES_1 = 0, TIMES_2 = 1, TIMES_4 = 2, TIMES_8 = 3 }; using GPRRegister = ::Ice::RegX8632::GPRRegister; using ByteRegister = ::Ice::RegX8632::ByteRegister; using XmmRegister = ::Ice::RegX8632::XmmRegister; using X87STRegister = ::Ice::RegX8632::X87STRegister; using Cond = ::Ice::CondX86; using RegisterSet = ::Ice::RegX8632; static constexpr RegisterSet::AllRegisters StackPtr = RegX8632::Reg_esp; static constexpr RegisterSet::AllRegisters FramePtr = RegX8632::Reg_ebp; static constexpr GPRRegister Encoded_Reg_Accumulator = RegX8632::Encoded_Reg_eax; static constexpr GPRRegister Encoded_Reg_Counter = RegX8632::Encoded_Reg_ecx; static constexpr FixupKind FK_PcRel = llvm::ELF::R_386_PC32; static constexpr FixupKind FK_Abs = llvm::ELF::R_386_32; static constexpr FixupKind FK_Gotoff = llvm::ELF::R_386_GOTOFF; static constexpr FixupKind FK_GotPC = llvm::ELF::R_386_GOTPC; class Operand { public: Operand(const Operand &other) : fixup_(other.fixup_), length_(other.length_) { memmove(&encoding_[0], &other.encoding_[0], other.length_); } Operand &operator=(const Operand &other) { length_ = other.length_; fixup_ = other.fixup_; memmove(&encoding_[0], &other.encoding_[0], other.length_); return *this; } uint8_t mod() const { return (encoding_at(0) >> 6) & 3; } GPRRegister rm() const { return static_cast(encoding_at(0) & 7); } ScaleFactor scale() const { return static_cast((encoding_at(1) >> 6) & 3); } GPRRegister index() const { return static_cast((encoding_at(1) >> 3) & 7); } GPRRegister base() const { return static_cast(encoding_at(1) & 7); } int8_t disp8() const { assert(length_ >= 2); return static_cast(encoding_[length_ - 1]); } int32_t disp32() const { assert(length_ >= 5); // TODO(stichnot): This method is not currently used. Delete it along // with other unused methods, or use a safe version of bitCopy(). llvm::report_fatal_error("Unexpected call to disp32()"); // return Utils::bitCopy(encoding_[length_ - 4]); } AssemblerFixup *fixup() const { return fixup_; } protected: Operand() : fixup_(nullptr), length_(0) {} // Needed by subclass Address. void SetModRM(int mod, GPRRegister rm) { assert((mod & ~3) == 0); encoding_[0] = (mod << 6) | rm; length_ = 1; } void SetSIB(ScaleFactor scale, GPRRegister index, GPRRegister base) { assert(length_ == 1); assert((scale & ~3) == 0); encoding_[1] = (scale << 6) | (index << 3) | base; length_ = 2; } void SetDisp8(int8_t disp) { assert(length_ == 1 || length_ == 2); encoding_[length_++] = static_cast(disp); } void SetDisp32(int32_t disp) { assert(length_ == 1 || length_ == 2); intptr_t disp_size = sizeof(disp); memmove(&encoding_[length_], &disp, disp_size); length_ += disp_size; } void SetFixup(AssemblerFixup *fixup) { fixup_ = fixup; } private: AssemblerFixup *fixup_; uint8_t encoding_[6]; uint8_t length_; explicit Operand(GPRRegister reg) : fixup_(nullptr) { SetModRM(3, reg); } /// Get the operand encoding byte at the given index. uint8_t encoding_at(intptr_t index) const { assert(index >= 0 && index < length_); return encoding_[index]; } /// Returns whether or not this operand is really the given register in /// disguise. Used from the assembler to generate better encodings. bool IsRegister(GPRRegister reg) const { return ((encoding_[0] & 0xF8) == 0xC0) // Addressing mode is register only. && ((encoding_[0] & 0x07) == reg); // Register codes match. } friend class AssemblerX86Base; }; class Address : public Operand { Address() = delete; public: Address(const Address &other) : Operand(other) {} Address &operator=(const Address &other) { Operand::operator=(other); return *this; } Address(GPRRegister Base, int32_t Disp, AssemblerFixup *Fixup) { if (Fixup == nullptr && Disp == 0 && Base != RegX8632::Encoded_Reg_ebp) { SetModRM(0, Base); if (Base == RegX8632::Encoded_Reg_esp) SetSIB(TIMES_1, RegX8632::Encoded_Reg_esp, Base); } else if (Fixup == nullptr && Utils::IsInt(8, Disp)) { SetModRM(1, Base); if (Base == RegX8632::Encoded_Reg_esp) SetSIB(TIMES_1, RegX8632::Encoded_Reg_esp, Base); SetDisp8(Disp); } else { SetModRM(2, Base); if (Base == RegX8632::Encoded_Reg_esp) SetSIB(TIMES_1, RegX8632::Encoded_Reg_esp, Base); SetDisp32(Disp); if (Fixup) SetFixup(Fixup); } } Address(GPRRegister Index, ScaleFactor Scale, int32_t Disp, AssemblerFixup *Fixup) { assert(Index != RegX8632::Encoded_Reg_esp); // Illegal addressing mode. SetModRM(0, RegX8632::Encoded_Reg_esp); SetSIB(Scale, Index, RegX8632::Encoded_Reg_ebp); SetDisp32(Disp); if (Fixup) SetFixup(Fixup); } Address(GPRRegister Base, GPRRegister Index, ScaleFactor Scale, int32_t Disp, AssemblerFixup *Fixup) { assert(Index != RegX8632::Encoded_Reg_esp); // Illegal addressing mode. if (Fixup == nullptr && Disp == 0 && Base != RegX8632::Encoded_Reg_ebp) { SetModRM(0, RegX8632::Encoded_Reg_esp); SetSIB(Scale, Index, Base); } else if (Fixup == nullptr && Utils::IsInt(8, Disp)) { SetModRM(1, RegX8632::Encoded_Reg_esp); SetSIB(Scale, Index, Base); SetDisp8(Disp); } else { SetModRM(2, RegX8632::Encoded_Reg_esp); SetSIB(Scale, Index, Base); SetDisp32(Disp); if (Fixup) SetFixup(Fixup); } } /// Generate an absolute address expression on x86-32. Address(RelocOffsetT Offset, AssemblerFixup *Fixup) { SetModRM(0, RegX8632::Encoded_Reg_ebp); // Use the Offset in the displacement for now. If we decide to process // fixups later, we'll need to patch up the emitted displacement. SetDisp32(Offset); if (Fixup) SetFixup(Fixup); } static Address ofConstPool(Assembler *Asm, const Constant *Imm) { AssemblerFixup *Fixup = Asm->createFixup(llvm::ELF::R_386_32, Imm); const RelocOffsetT Offset = 0; return Address(Offset, Fixup); } }; //---------------------------------------------------------------------------- // __ ______ __ __ ______ ______ __ __ __ ______ // /\ \ /\ __ \/\ \ _ \ \/\ ___\/\ == \/\ \/\ "-.\ \/\ ___\ // \ \ \___\ \ \/\ \ \ \/ ".\ \ \ __\\ \ __<\ \ \ \ \-. \ \ \__ \ // \ \_____\ \_____\ \__/".~\_\ \_____\ \_\ \_\ \_\ \_\\"\_\ \_____\ // \/_____/\/_____/\/_/ \/_/\/_____/\/_/ /_/\/_/\/_/ \/_/\/_____/ // //---------------------------------------------------------------------------- enum InstructionSet { Begin, // SSE2 is the PNaCl baseline instruction set. SSE2 = Begin, SSE4_1, End }; static const char *TargetName; static constexpr Type WordType = IceType_i32; static const char *getRegName(RegNumT RegNum) { static const char *const RegNames[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ name, REGX8632_TABLE #undef X }; RegNum.assertIsValid(); return RegNames[RegNum]; } static GPRRegister getEncodedGPR(RegNumT RegNum) { static const GPRRegister GPRRegs[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ GPRRegister(isGPR ? encode : GPRRegister::Encoded_Not_GPR), REGX8632_TABLE #undef X }; RegNum.assertIsValid(); assert(GPRRegs[RegNum] != GPRRegister::Encoded_Not_GPR); return GPRRegs[RegNum]; } static ByteRegister getEncodedByteReg(RegNumT RegNum) { static const ByteRegister ByteRegs[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ ByteRegister(is8 ? encode : ByteRegister::Encoded_Not_ByteReg), REGX8632_TABLE #undef X }; RegNum.assertIsValid(); assert(ByteRegs[RegNum] != ByteRegister::Encoded_Not_ByteReg); return ByteRegs[RegNum]; } static bool isXmm(RegNumT RegNum) { static const bool IsXmm[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ isXmm, REGX8632_TABLE #undef X }; return IsXmm[RegNum]; } static XmmRegister getEncodedXmm(RegNumT RegNum) { static const XmmRegister XmmRegs[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ XmmRegister(isXmm ? encode : XmmRegister::Encoded_Not_Xmm), REGX8632_TABLE #undef X }; RegNum.assertIsValid(); assert(XmmRegs[RegNum] != XmmRegister::Encoded_Not_Xmm); return XmmRegs[RegNum]; } static uint32_t getEncoding(RegNumT RegNum) { static const uint32_t Encoding[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ encode, REGX8632_TABLE #undef X }; RegNum.assertIsValid(); return Encoding[RegNum]; } static RegNumT getBaseReg(RegNumT RegNum) { static const RegNumT BaseRegs[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ RegisterSet::base, REGX8632_TABLE #undef X }; RegNum.assertIsValid(); return BaseRegs[RegNum]; } private: static RegisterSet::AllRegisters getFirstGprForType(Type Ty) { switch (Ty) { default: llvm_unreachable("Invalid type for GPR."); case IceType_i1: case IceType_i8: return RegisterSet::Reg_al; case IceType_i16: return RegisterSet::Reg_ax; case IceType_i32: return RegisterSet::Reg_eax; } } public: // Return a register in RegNum's alias set that is suitable for Ty. static RegNumT getGprForType(Type Ty, RegNumT RegNum) { assert(RegNum.hasValue()); if (!isScalarIntegerType(Ty)) { return RegNum; } // [abcd]h registers are not convertible to their ?l, ?x, and e?x versions. switch (RegNum) { default: break; case RegisterSet::Reg_ah: case RegisterSet::Reg_bh: case RegisterSet::Reg_ch: case RegisterSet::Reg_dh: assert(isByteSizedType(Ty)); return RegNum; } const RegisterSet::AllRegisters FirstGprForType = getFirstGprForType(Ty); switch (RegNum) { default: llvm::report_fatal_error("Unknown register."); #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ case RegisterSet::val: { \ if (!isGPR) \ return RegisterSet::val; \ assert((is32) || (is16) || (is8) || \ getBaseReg(RegisterSet::val) == RegisterSet::Reg_esp); \ constexpr RegisterSet::AllRegisters FirstGprWithRegNumSize = \ (((is32) || RegisterSet::val == RegisterSet::Reg_esp) \ ? RegisterSet::Reg_eax \ : (((is16) || RegisterSet::val == RegisterSet::Reg_sp) \ ? RegisterSet::Reg_ax \ : RegisterSet::Reg_al)); \ const RegNumT NewRegNum = \ RegNumT::fixme(RegNum - FirstGprWithRegNumSize + FirstGprForType); \ assert(getBaseReg(RegNum) == getBaseReg(NewRegNum) && \ "Error involving " #val); \ return NewRegNum; \ } REGX8632_TABLE #undef X } } private: /// SizeOf is used to obtain the size of an initializer list as a constexpr /// expression. This is only needed until our C++ library is updated to /// C++ 14 -- which defines constexpr members to std::initializer_list. class SizeOf { SizeOf(const SizeOf &) = delete; SizeOf &operator=(const SizeOf &) = delete; public: constexpr SizeOf() : Size(0) {} template explicit constexpr SizeOf(T...) : Size(__length::value) {} constexpr SizeT size() const { return Size; } private: template struct __length { static constexpr std::size_t value = 1 + __length::value; }; template struct __length { static constexpr std::size_t value = 1; }; const std::size_t Size; }; public: static void initRegisterSet( const ::Ice::ClFlags & /*Flags*/, std::array *TypeToRegisterSet, std::array *RegisterAliases) { SmallBitVector IntegerRegistersI32(RegisterSet::Reg_NUM); SmallBitVector IntegerRegistersI16(RegisterSet::Reg_NUM); SmallBitVector IntegerRegistersI8(RegisterSet::Reg_NUM); SmallBitVector FloatRegisters(RegisterSet::Reg_NUM); SmallBitVector VectorRegisters(RegisterSet::Reg_NUM); SmallBitVector Trunc64To8Registers(RegisterSet::Reg_NUM); SmallBitVector Trunc32To8Registers(RegisterSet::Reg_NUM); SmallBitVector Trunc16To8Registers(RegisterSet::Reg_NUM); SmallBitVector Trunc8RcvrRegisters(RegisterSet::Reg_NUM); SmallBitVector AhRcvrRegisters(RegisterSet::Reg_NUM); SmallBitVector InvalidRegisters(RegisterSet::Reg_NUM); static constexpr struct { uint16_t Val; unsigned Is64 : 1; unsigned Is32 : 1; unsigned Is16 : 1; unsigned Is8 : 1; unsigned IsXmm : 1; unsigned Is64To8 : 1; unsigned Is32To8 : 1; unsigned Is16To8 : 1; unsigned IsTrunc8Rcvr : 1; unsigned IsAhRcvr : 1; #define NUM_ALIASES_BITS 2 SizeT NumAliases : (NUM_ALIASES_BITS + 1); uint16_t Aliases[1 << NUM_ALIASES_BITS]; #undef NUM_ALIASES_BITS } X8632RegTable[RegisterSet::Reg_NUM] = { #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ { \ RegisterSet::val, \ is64, \ is32, \ is16, \ is8, \ isXmm, \ is64To8, \ is32To8, \ is16To8, \ isTrunc8Rcvr, \ isAhRcvr, \ (SizeOf aliases).size(), \ aliases, \ }, REGX8632_TABLE #undef X }; for (SizeT ii = 0; ii < llvm::array_lengthof(X8632RegTable); ++ii) { const auto &Entry = X8632RegTable[ii]; (IntegerRegistersI32)[Entry.Val] = Entry.Is32; (IntegerRegistersI16)[Entry.Val] = Entry.Is16; (IntegerRegistersI8)[Entry.Val] = Entry.Is8; (FloatRegisters)[Entry.Val] = Entry.IsXmm; (VectorRegisters)[Entry.Val] = Entry.IsXmm; (Trunc64To8Registers)[Entry.Val] = Entry.Is64To8; (Trunc32To8Registers)[Entry.Val] = Entry.Is32To8; (Trunc16To8Registers)[Entry.Val] = Entry.Is16To8; (Trunc8RcvrRegisters)[Entry.Val] = Entry.IsTrunc8Rcvr; (AhRcvrRegisters)[Entry.Val] = Entry.IsAhRcvr; (*RegisterAliases)[Entry.Val].resize(RegisterSet::Reg_NUM); for (SizeT J = 0; J < Entry.NumAliases; J++) { SizeT Alias = Entry.Aliases[J]; assert(!(*RegisterAliases)[Entry.Val][Alias] && "Duplicate alias"); (*RegisterAliases)[Entry.Val].set(Alias); } (*RegisterAliases)[Entry.Val].set(Entry.Val); } (*TypeToRegisterSet)[RC_void] = InvalidRegisters; (*TypeToRegisterSet)[RC_i1] = IntegerRegistersI8; (*TypeToRegisterSet)[RC_i8] = IntegerRegistersI8; (*TypeToRegisterSet)[RC_i16] = IntegerRegistersI16; (*TypeToRegisterSet)[RC_i32] = IntegerRegistersI32; (*TypeToRegisterSet)[RC_i64] = InvalidRegisters; (*TypeToRegisterSet)[RC_f32] = FloatRegisters; (*TypeToRegisterSet)[RC_f64] = FloatRegisters; (*TypeToRegisterSet)[RC_v4i1] = VectorRegisters; (*TypeToRegisterSet)[RC_v8i1] = VectorRegisters; (*TypeToRegisterSet)[RC_v16i1] = VectorRegisters; (*TypeToRegisterSet)[RC_v16i8] = VectorRegisters; (*TypeToRegisterSet)[RC_v8i16] = VectorRegisters; (*TypeToRegisterSet)[RC_v4i32] = VectorRegisters; (*TypeToRegisterSet)[RC_v4f32] = VectorRegisters; (*TypeToRegisterSet)[RCX86_Is64To8] = Trunc64To8Registers; (*TypeToRegisterSet)[RCX86_Is32To8] = Trunc32To8Registers; (*TypeToRegisterSet)[RCX86_Is16To8] = Trunc16To8Registers; (*TypeToRegisterSet)[RCX86_IsTrunc8Rcvr] = Trunc8RcvrRegisters; (*TypeToRegisterSet)[RCX86_IsAhRcvr] = AhRcvrRegisters; } static SmallBitVector getRegisterSet(const ::Ice::ClFlags & /*Flags*/, TargetLowering::RegSetMask Include, TargetLowering::RegSetMask Exclude) { SmallBitVector Registers(RegisterSet::Reg_NUM); #define X(val, encode, name, base, scratch, preserved, stackptr, frameptr, \ isGPR, is64, is32, is16, is8, isXmm, is64To8, is32To8, is16To8, \ isTrunc8Rcvr, isAhRcvr, aliases) \ if (scratch && (Include & ::Ice::TargetLowering::RegSet_CallerSave)) \ Registers[RegisterSet::val] = true; \ if (preserved && (Include & ::Ice::TargetLowering::RegSet_CalleeSave)) \ Registers[RegisterSet::val] = true; \ if (stackptr && (Include & ::Ice::TargetLowering::RegSet_StackPointer)) \ Registers[RegisterSet::val] = true; \ if (frameptr && (Include & ::Ice::TargetLowering::RegSet_FramePointer)) \ Registers[RegisterSet::val] = true; \ if (scratch && (Exclude & ::Ice::TargetLowering::RegSet_CallerSave)) \ Registers[RegisterSet::val] = false; \ if (preserved && (Exclude & ::Ice::TargetLowering::RegSet_CalleeSave)) \ Registers[RegisterSet::val] = false; \ if (stackptr && (Exclude & ::Ice::TargetLowering::RegSet_StackPointer)) \ Registers[RegisterSet::val] = false; \ if (frameptr && (Exclude & ::Ice::TargetLowering::RegSet_FramePointer)) \ Registers[RegisterSet::val] = false; REGX8632_TABLE #undef X return Registers; } static RegNumT getRaxOrDie() { llvm::report_fatal_error("no rax in non-64-bit mode."); } static RegNumT getRdxOrDie() { llvm::report_fatal_error("no rdx in non-64-bit mode."); } // x86-32 calling convention: // // * The first four arguments of vector type, regardless of their position // relative to the other arguments in the argument list, are placed in // registers xmm0 - xmm3. // // This intends to match the section "IA-32 Function Calling Convention" of // the document "OS X ABI Function Call Guide" by Apple. /// The maximum number of arguments to pass in XMM registers static constexpr uint32_t X86_MAX_XMM_ARGS = 4; /// The maximum number of arguments to pass in GPR registers static constexpr uint32_t X86_MAX_GPR_ARGS = 0; /// Whether scalar floating point arguments are passed in XMM registers static constexpr bool X86_PASS_SCALAR_FP_IN_XMM = false; /// Get the register for a given argument slot in the XMM registers. static RegNumT getRegisterForXmmArgNum(uint32_t ArgNum) { // TODO(sehr): Change to use the CCArg technique used in ARM32. static_assert(RegisterSet::Reg_xmm0 + 1 == RegisterSet::Reg_xmm1, "Inconsistency between XMM register numbers and ordinals"); if (ArgNum >= X86_MAX_XMM_ARGS) { return RegNumT(); } return RegNumT::fixme(RegisterSet::Reg_xmm0 + ArgNum); } /// Get the register for a given argument slot in the GPRs. static RegNumT getRegisterForGprArgNum(Type Ty, uint32_t ArgNum) { assert(Ty == IceType_i64 || Ty == IceType_i32); (void)Ty; (void)ArgNum; return RegNumT(); } // Given the absolute argument position and argument position by type, return // the register index to assign it to. static SizeT getArgIndex(SizeT argPos, SizeT argPosByType) { (void)argPos; return argPosByType; }; /// The number of bits in a byte static constexpr uint32_t X86_CHAR_BIT = 8; /// Stack alignment. This is defined in IceTargetLoweringX8632.cpp because it /// is used as an argument to std::max(), and the default std::less has an /// operator(T const&, T const&) which requires this member to have an /// address. static const uint32_t X86_STACK_ALIGNMENT_BYTES; /// Size of the return address on the stack static constexpr uint32_t X86_RET_IP_SIZE_BYTES = 4; /// The number of different NOP instructions static constexpr uint32_t X86_NUM_NOP_VARIANTS = 5; /// \name Limits for unrolling memory intrinsics. /// @{ static constexpr uint32_t MEMCPY_UNROLL_LIMIT = 8; static constexpr uint32_t MEMMOVE_UNROLL_LIMIT = 8; static constexpr uint32_t MEMSET_UNROLL_LIMIT = 8; /// @} /// Value is in bytes. Return Value adjusted to the next highest multiple of /// the stack alignment. static uint32_t applyStackAlignment(uint32_t Value) { return Utils::applyAlignment(Value, X86_STACK_ALIGNMENT_BYTES); } /// Return the type which the elements of the vector have in the X86 /// representation of the vector. static Type getInVectorElementType(Type Ty) { assert(isVectorType(Ty)); assert(static_cast(Ty) < TableTypeX8632AttributesSize); return TableTypeX8632Attributes[Ty].InVectorElementType; } // Note: The following data structures are defined in // IceTargetLoweringX8632.cpp. /// The following table summarizes the logic for lowering the fcmp /// instruction. There is one table entry for each of the 16 conditions. /// /// The first four columns describe the case when the operands are floating /// point scalar values. A comment in lowerFcmp() describes the lowering /// template. In the most general case, there is a compare followed by two /// conditional branches, because some fcmp conditions don't map to a single /// x86 conditional branch. However, in many cases it is possible to swap the /// operands in the comparison and have a single conditional branch. Since /// it's quite tedious to validate the table by hand, good execution tests are /// helpful. /// /// The last two columns describe the case when the operands are vectors of /// floating point values. For most fcmp conditions, there is a clear mapping /// to a single x86 cmpps instruction variant. Some fcmp conditions require /// special code to handle and these are marked in the table with a /// Cmpps_Invalid predicate. /// {@ static const struct TableFcmpType { uint32_t Default; bool SwapScalarOperands; Cond::BrCond C1, C2; bool SwapVectorOperands; Cond::CmppsCond Predicate; } TableFcmp[]; static const size_t TableFcmpSize; /// @} /// The following table summarizes the logic for lowering the icmp instruction /// for i32 and narrower types. Each icmp condition has a clear mapping to an /// x86 conditional branch instruction. /// {@ static const struct TableIcmp32Type { Cond::BrCond Mapping; } TableIcmp32[]; static const size_t TableIcmp32Size; /// @} /// The following table summarizes the logic for lowering the icmp instruction /// for the i64 type. For Eq and Ne, two separate 32-bit comparisons and /// conditional branches are needed. For the other conditions, three separate /// conditional branches are needed. /// {@ static const struct TableIcmp64Type { Cond::BrCond C1, C2, C3; } TableIcmp64[]; static const size_t TableIcmp64Size; /// @} static Cond::BrCond getIcmp32Mapping(InstIcmp::ICond Cond) { assert(static_cast(Cond) < TableIcmp32Size); return TableIcmp32[Cond].Mapping; } static const struct TableTypeX8632AttributesType { Type InVectorElementType; } TableTypeX8632Attributes[]; static const size_t TableTypeX8632AttributesSize; //---------------------------------------------------------------------------- // __ __ __ ______ ______ // /\ \/\ "-.\ \/\ ___\/\__ _\ // \ \ \ \ \-. \ \___ \/_/\ \/ // \ \_\ \_\\"\_\/\_____\ \ \_\ // \/_/\/_/ \/_/\/_____/ \/_/ // //---------------------------------------------------------------------------- using Traits = TargetX8632Traits; using Insts = ::Ice::X8632::Insts; using TargetLowering = ::Ice::X8632::TargetX86Base; using ConcreteTarget = ::Ice::X8632::TargetX8632; using Assembler = ::Ice::X8632::AssemblerX86Base; /// X86Operand extends the Operand hierarchy. Its subclasses are X86OperandMem /// and VariableSplit. class X86Operand : public ::Ice::Operand { X86Operand() = delete; X86Operand(const X86Operand &) = delete; X86Operand &operator=(const X86Operand &) = delete; public: enum OperandKindX8632 { k__Start = ::Ice::Operand::kTarget, kMem, kSplit }; using ::Ice::Operand::dump; void dump(const Cfg *, Ostream &Str) const override; protected: X86Operand(OperandKindX8632 Kind, Type Ty) : Operand(static_cast<::Ice::Operand::OperandKind>(Kind), Ty) {} }; /// X86OperandMem represents the m32 addressing mode, with optional base and /// index registers, a constant offset, and a fixed shift value for the index /// register. class X86OperandMem : public X86Operand { X86OperandMem() = delete; X86OperandMem(const X86OperandMem &) = delete; X86OperandMem &operator=(const X86OperandMem &) = delete; public: enum SegmentRegisters { DefaultSegment = -1, #define X(val, name, prefix) val, SEG_REGX8632_TABLE #undef X SegReg_NUM }; static X86OperandMem *create(Cfg *Func, Type Ty, Variable *Base, Constant *Offset, Variable *Index = nullptr, uint16_t Shift = 0, SegmentRegisters SegmentReg = DefaultSegment, bool IsRebased = false) { return new (Func->allocate()) X86OperandMem( Func, Ty, Base, Offset, Index, Shift, SegmentReg, IsRebased); } static X86OperandMem *create(Cfg *Func, Type Ty, Variable *Base, Constant *Offset, bool IsRebased) { constexpr Variable *NoIndex = nullptr; constexpr uint16_t NoShift = 0; return new (Func->allocate()) X86OperandMem( Func, Ty, Base, Offset, NoIndex, NoShift, DefaultSegment, IsRebased); } Variable *getBase() const { return Base; } Constant *getOffset() const { return Offset; } Variable *getIndex() const { return Index; } uint16_t getShift() const { return Shift; } SegmentRegisters getSegmentRegister() const { return SegmentReg; } void emitSegmentOverride(Assembler *Asm) const; bool getIsRebased() const { return IsRebased; } Address toAsmAddress(Assembler *Asm, const Ice::TargetLowering *Target, bool LeaAddr = false) const; void emit(const Cfg *Func) const override; using X86Operand::dump; void dump(const Cfg *Func, Ostream &Str) const override; static bool classof(const Operand *Operand) { return Operand->getKind() == static_cast(kMem); } private: X86OperandMem(Cfg *Func, Type Ty, Variable *Base, Constant *Offset, Variable *Index, uint16_t Shift, SegmentRegisters SegmentReg, bool IsRebased); Variable *const Base; Constant *const Offset; Variable *const Index; const uint16_t Shift; const SegmentRegisters SegmentReg : 16; const bool IsRebased; }; /// VariableSplit is a way to treat an f64 memory location as a pair of i32 /// locations (Low and High). This is needed for some cases of the Bitcast /// instruction. Since it's not possible for integer registers to access the /// XMM registers and vice versa, the lowering forces the f64 to be spilled to /// the stack and then accesses through the VariableSplit. // TODO(jpp): remove references to VariableSplit from IceInstX86Base as 64bit // targets can natively handle these. class VariableSplit : public X86Operand { VariableSplit() = delete; VariableSplit(const VariableSplit &) = delete; VariableSplit &operator=(const VariableSplit &) = delete; public: enum Portion { Low, High }; static VariableSplit *create(Cfg *Func, Variable *Var, Portion Part) { return new (Func->allocate()) VariableSplit(Func, Var, Part); } int32_t getOffset() const { return Part == High ? 4 : 0; } Address toAsmAddress(const Cfg *Func) const; void emit(const Cfg *Func) const override; using X86Operand::dump; void dump(const Cfg *Func, Ostream &Str) const override; static bool classof(const Operand *Operand) { return Operand->getKind() == static_cast(kSplit); } private: VariableSplit(Cfg *Func, Variable *Var, Portion Part) : X86Operand(kSplit, IceType_i32), Var(Var), Part(Part) { assert(Var->getType() == IceType_f64); Vars = Func->allocateArrayOf(1); Vars[0] = Var; NumVars = 1; } Variable *Var; Portion Part; }; // Note: The following data structures are defined in IceInstX8632.cpp. static const struct InstBrAttributesType { Cond::BrCond Opposite; const char *DisplayString; const char *EmitString; } InstBrAttributes[]; static const struct InstCmppsAttributesType { const char *EmitString; } InstCmppsAttributes[]; static const struct TypeAttributesType { const char *CvtString; // i (integer), s (single FP), d (double FP) const char *SdSsString; // ss, sd, or const char *PdPsString; // ps, pd, or const char *SpSdString; // ss, sd, ps, pd, or const char *IntegralString; // b, w, d, or const char *UnpackString; // bw, wd, dq, or const char *PackString; // wb, dw, or const char *WidthString; // b, w, l, q, or const char *FldString; // s, l, or } TypeAttributes[]; static const char *InstSegmentRegNames[]; static uint8_t InstSegmentPrefixes[]; }; using Traits = ::Ice::X8632::TargetX8632Traits; } // end of namespace X8632 } // end of namespace Ice #endif // SUBZERO_SRC_ICETARGETLOWERINGX8632TRAITS_H