//===- subzero/src/IceInstX8632.cpp - X86-32 instruction implementation ---===// // // The Subzero Code Generator // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// \brief Defines X8632 specific data related to X8632 Instructions and /// Instruction traits. /// /// These are declared in the IceTargetLoweringX8632Traits.h header file. This /// file also defines X8632 operand specific methods (dump and emit.) /// //===----------------------------------------------------------------------===// #include "IceInstX8632.h" #include "IceAssemblerX8632.h" #include "IceCfg.h" #include "IceCfgNode.h" #include "IceConditionCodesX8632.h" #include "IceInst.h" #include "IceRegistersX8632.h" #include "IceTargetLoweringX8632.h" #include "IceOperand.h" namespace Ice { namespace X8632 { const TargetX8632Traits::InstBrAttributesType TargetX8632Traits::InstBrAttributes[] = { #define X(val, encode, opp, dump, emit) \ { X8632::Traits::Cond::opp, dump, emit } \ , ICEINSTX8632BR_TABLE #undef X }; const TargetX8632Traits::InstCmppsAttributesType TargetX8632Traits::InstCmppsAttributes[] = { #define X(val, emit) \ { emit } \ , ICEINSTX8632CMPPS_TABLE #undef X }; const TargetX8632Traits::TypeAttributesType TargetX8632Traits::TypeAttributes[] = { #define X(tag, elty, cvt, sdss, pdps, spsd, int_, unpack, pack, width, fld) \ { cvt, sdss, pdps, spsd, int_, unpack, pack, width, fld } \ , ICETYPEX8632_TABLE #undef X }; const char *TargetX8632Traits::InstSegmentRegNames[] = { #define X(val, name, prefix) name, SEG_REGX8632_TABLE #undef X }; uint8_t TargetX8632Traits::InstSegmentPrefixes[] = { #define X(val, name, prefix) prefix, SEG_REGX8632_TABLE #undef X }; void TargetX8632Traits::X86Operand::dump(const Cfg *, Ostream &Str) const { if (BuildDefs::dump()) Str << ""; } TargetX8632Traits::X86OperandMem::X86OperandMem( Cfg *Func, Type Ty, Variable *Base, Constant *Offset, Variable *Index, uint16_t Shift, SegmentRegisters SegmentReg, bool IsRebased) : X86Operand(kMem, Ty), Base(Base), Offset(Offset), Index(Index), Shift(Shift), SegmentReg(SegmentReg), IsRebased(IsRebased) { assert(Shift <= 3); Vars = nullptr; NumVars = 0; if (Base) ++NumVars; if (Index) ++NumVars; if (NumVars) { Vars = Func->allocateArrayOf(NumVars); SizeT I = 0; if (Base) Vars[I++] = Base; if (Index) Vars[I++] = Index; assert(I == NumVars); } } namespace { int32_t getRematerializableOffset(Variable *Var, const Ice::X8632::TargetX8632 *Target) { int32_t Disp = Var->getStackOffset(); const auto RegNum = Var->getRegNum(); if (RegNum == Target->getFrameReg()) { Disp += Target->getFrameFixedAllocaOffset(); } else if (RegNum != Target->getStackReg()) { llvm::report_fatal_error("Unexpected rematerializable register type"); } return Disp; } void validateMemOperandPIC(const TargetX8632Traits::X86OperandMem *Mem, bool UseNonsfi) { if (!BuildDefs::asserts()) return; const bool HasCR = Mem->getOffset() && llvm::isa(Mem->getOffset()); (void)HasCR; const bool IsRebased = Mem->getIsRebased(); (void)IsRebased; if (UseNonsfi) assert(HasCR == IsRebased); else assert(!IsRebased); } } // end of anonymous namespace void TargetX8632Traits::X86OperandMem::emit(const Cfg *Func) const { if (!BuildDefs::dump()) return; const bool UseNonsfi = getFlags().getUseNonsfi(); validateMemOperandPIC(this, UseNonsfi); const auto *Target = static_cast(Func->getTarget()); // If the base is rematerializable, we need to replace it with the correct // physical register (esp or ebp), and update the Offset. int32_t Disp = 0; if (getBase() && getBase()->isRematerializable()) { Disp += getRematerializableOffset(getBase(), Target); } // The index should never be rematerializable. But if we ever allow it, then // we should make sure the rematerialization offset is shifted by the Shift // value. if (getIndex()) assert(!getIndex()->isRematerializable()); Ostream &Str = Func->getContext()->getStrEmit(); if (SegmentReg != DefaultSegment) { assert(SegmentReg >= 0 && SegmentReg < SegReg_NUM); Str << "%" << X8632::Traits::InstSegmentRegNames[SegmentReg] << ":"; } // Emit as Offset(Base,Index,1<(getOffset())) { if (getBase() == nullptr || CI->getValue() || Disp != 0) // Emit a non-zero offset without a leading '$'. Str << CI->getValue() + Disp; } else if (const auto *CR = llvm::dyn_cast(getOffset())) { // TODO(sehr): ConstantRelocatable still needs updating for // rematerializable base/index and Disp. assert(Disp == 0); CR->emitWithoutPrefix(Target, UseNonsfi ? "@GOTOFF" : ""); } else { llvm_unreachable("Invalid offset type for x86 mem operand"); } if (getBase() || getIndex()) { Str << "("; if (getBase()) getBase()->emit(Func); if (getIndex()) { Str << ","; getIndex()->emit(Func); if (getShift()) Str << "," << (1u << getShift()); } Str << ")"; } } void TargetX8632Traits::X86OperandMem::dump(const Cfg *Func, Ostream &Str) const { if (!BuildDefs::dump()) return; if (SegmentReg != DefaultSegment) { assert(SegmentReg >= 0 && SegmentReg < SegReg_NUM); Str << X8632::Traits::InstSegmentRegNames[SegmentReg] << ":"; } bool Dumped = false; Str << "["; int32_t Disp = 0; const auto *Target = static_cast(Func->getTarget()); if (getBase() && getBase()->isRematerializable()) { Disp += getRematerializableOffset(getBase(), Target); } if (getBase()) { if (Func) getBase()->dump(Func); else getBase()->dump(Str); Dumped = true; } if (getIndex()) { assert(!getIndex()->isRematerializable()); if (getBase()) Str << "+"; if (getShift() > 0) Str << (1u << getShift()) << "*"; if (Func) getIndex()->dump(Func); else getIndex()->dump(Str); Dumped = true; } if (Disp) { if (Disp > 0) Str << "+"; Str << Disp; Dumped = true; } // Pretty-print the Offset. bool OffsetIsZero = false; bool OffsetIsNegative = false; if (getOffset() == nullptr) { OffsetIsZero = true; } else if (const auto *CI = llvm::dyn_cast(getOffset())) { OffsetIsZero = (CI->getValue() == 0); OffsetIsNegative = (static_cast(CI->getValue()) < 0); } else { assert(llvm::isa(getOffset())); } if (Dumped) { if (!OffsetIsZero) { // Suppress if Offset is known to be 0 if (!OffsetIsNegative) // Suppress if Offset is known to be negative Str << "+"; getOffset()->dump(Func, Str); } } else { // There is only the offset. getOffset()->dump(Func, Str); } Str << "]"; } void TargetX8632Traits::X86OperandMem::emitSegmentOverride( TargetX8632Traits::Assembler *Asm) const { if (SegmentReg != DefaultSegment) { assert(SegmentReg >= 0 && SegmentReg < SegReg_NUM); Asm->emitSegmentOverride(X8632::Traits::InstSegmentPrefixes[SegmentReg]); } } TargetX8632Traits::Address TargetX8632Traits::X86OperandMem::toAsmAddress( TargetX8632Traits::Assembler *Asm, const Ice::TargetLowering *TargetLowering, bool /*IsLeaAddr*/) const { const auto *Target = static_cast(TargetLowering); const bool UseNonsfi = getFlags().getUseNonsfi(); validateMemOperandPIC(this, UseNonsfi); int32_t Disp = 0; if (getBase() && getBase()->isRematerializable()) { Disp += getRematerializableOffset(getBase(), Target); } // The index should never be rematerializable. But if we ever allow it, then // we should make sure the rematerialization offset is shifted by the Shift // value. if (getIndex()) assert(!getIndex()->isRematerializable()); AssemblerFixup *Fixup = nullptr; // Determine the offset (is it relocatable?) if (getOffset()) { if (const auto *CI = llvm::dyn_cast(getOffset())) { Disp += static_cast(CI->getValue()); } else if (const auto CR = llvm::dyn_cast(getOffset())) { Disp += CR->getOffset(); Fixup = Asm->createFixup(Target->getAbsFixup(), CR); } else { llvm_unreachable("Unexpected offset type"); } } // Now convert to the various possible forms. if (getBase() && getIndex()) { return X8632::Traits::Address(getEncodedGPR(getBase()->getRegNum()), getEncodedGPR(getIndex()->getRegNum()), X8632::Traits::ScaleFactor(getShift()), Disp, Fixup); } else if (getBase()) { return X8632::Traits::Address(getEncodedGPR(getBase()->getRegNum()), Disp, Fixup); } else if (getIndex()) { return X8632::Traits::Address(getEncodedGPR(getIndex()->getRegNum()), X8632::Traits::ScaleFactor(getShift()), Disp, Fixup); } else { return X8632::Traits::Address(Disp, Fixup); } } TargetX8632Traits::Address TargetX8632Traits::VariableSplit::toAsmAddress(const Cfg *Func) const { assert(!Var->hasReg()); const ::Ice::TargetLowering *Target = Func->getTarget(); int32_t Offset = Var->getStackOffset() + getOffset(); return X8632::Traits::Address(getEncodedGPR(Target->getFrameOrStackReg()), Offset, AssemblerFixup::NoFixup); } void TargetX8632Traits::VariableSplit::emit(const Cfg *Func) const { if (!BuildDefs::dump()) return; Ostream &Str = Func->getContext()->getStrEmit(); assert(!Var->hasReg()); // The following is copied/adapted from TargetX8632::emitVariable(). const ::Ice::TargetLowering *Target = Func->getTarget(); constexpr Type Ty = IceType_i32; int32_t Offset = Var->getStackOffset() + getOffset(); if (Offset) Str << Offset; Str << "(%" << Target->getRegName(Target->getFrameOrStackReg(), Ty) << ")"; } void TargetX8632Traits::VariableSplit::dump(const Cfg *Func, Ostream &Str) const { if (!BuildDefs::dump()) return; switch (Part) { case Low: Str << "low"; break; case High: Str << "high"; break; } Str << "("; if (Func) Var->dump(Func); else Var->dump(Str); Str << ")"; } } // namespace X8632 } // end of namespace Ice X86INSTS_DEFINE_STATIC_DATA(X8632, X8632::Traits)