//===----- HexagonMCChecker.cpp - Instruction bundle checking -------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This implements the checking of insns inside a bundle according to the // packet constraint rules of the Hexagon ISA. // //===----------------------------------------------------------------------===// #include "MCTargetDesc/HexagonMCChecker.h" #include "MCTargetDesc/HexagonBaseInfo.h" #include "MCTargetDesc/HexagonMCInstrInfo.h" #include "MCTargetDesc/HexagonMCShuffler.h" #include "MCTargetDesc/HexagonMCTargetDesc.h" #include "llvm/ADT/Twine.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCInst.h" #include "llvm/MC/MCInstrDesc.h" #include "llvm/MC/MCRegisterInfo.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/SourceMgr.h" #include using namespace llvm; static cl::opt RelaxNVChecks("relax-nv-checks", cl::init(false), cl::ZeroOrMore, cl::Hidden, cl::desc("Relax checks of new-value validity")); const HexagonMCChecker::PredSense HexagonMCChecker::Unconditional(Hexagon::NoRegister, false); void HexagonMCChecker::init() { // Initialize read-only registers set. ReadOnly.insert(Hexagon::PC); ReadOnly.insert(Hexagon::C9_8); // Figure out the loop-registers definitions. if (HexagonMCInstrInfo::isInnerLoop(MCB)) { Defs[Hexagon::SA0].insert(Unconditional); // FIXME: define or change SA0? Defs[Hexagon::LC0].insert(Unconditional); } if (HexagonMCInstrInfo::isOuterLoop(MCB)) { Defs[Hexagon::SA1].insert(Unconditional); // FIXME: define or change SA0? Defs[Hexagon::LC1].insert(Unconditional); } if (HexagonMCInstrInfo::isBundle(MCB)) // Unfurl a bundle. for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCB)) { MCInst const &Inst = *I.getInst(); if (HexagonMCInstrInfo::isDuplex(MCII, Inst)) { init(*Inst.getOperand(0).getInst()); init(*Inst.getOperand(1).getInst()); } else init(Inst); } else init(MCB); } void HexagonMCChecker::initReg(MCInst const &MCI, unsigned R, unsigned &PredReg, bool &isTrue) { if (HexagonMCInstrInfo::isPredicated(MCII, MCI) && isPredicateRegister(R)) { // Note an used predicate register. PredReg = R; isTrue = HexagonMCInstrInfo::isPredicatedTrue(MCII, MCI); // Note use of new predicate register. if (HexagonMCInstrInfo::isPredicatedNew(MCII, MCI)) NewPreds.insert(PredReg); } else // Note register use. Super-registers are not tracked directly, // but their components. for (MCRegAliasIterator SRI(R, &RI, !MCSubRegIterator(R, &RI).isValid()); SRI.isValid(); ++SRI) if (!MCSubRegIterator(*SRI, &RI).isValid()) // Skip super-registers used indirectly. Uses.insert(*SRI); } void HexagonMCChecker::init(MCInst const &MCI) { const MCInstrDesc &MCID = HexagonMCInstrInfo::getDesc(MCII, MCI); unsigned PredReg = Hexagon::NoRegister; bool isTrue = false; // Get used registers. for (unsigned i = MCID.getNumDefs(); i < MCID.getNumOperands(); ++i) if (MCI.getOperand(i).isReg()) initReg(MCI, MCI.getOperand(i).getReg(), PredReg, isTrue); for (unsigned i = 0; i < MCID.getNumImplicitUses(); ++i) initReg(MCI, MCID.getImplicitUses()[i], PredReg, isTrue); // Get implicit register definitions. if (const MCPhysReg *ImpDef = MCID.getImplicitDefs()) for (; *ImpDef; ++ImpDef) { unsigned R = *ImpDef; if (Hexagon::R31 != R && MCID.isCall()) // Any register other than the LR and the PC are actually volatile ones // as defined by the ABI, not modified implicitly by the call insn. continue; if (Hexagon::PC == R) // Branches are the only insns that can change the PC, // otherwise a read-only register. continue; if (Hexagon::USR_OVF == R) // Many insns change the USR implicitly, but only one or another flag. // The instruction table models the USR.OVF flag, which can be // implicitly modified more than once, but cannot be modified in the // same packet with an instruction that modifies is explicitly. Deal // with such situations individually. SoftDefs.insert(R); else if (isPredicateRegister(R) && HexagonMCInstrInfo::isPredicateLate(MCII, MCI)) // Include implicit late predicates. LatePreds.insert(R); else Defs[R].insert(PredSense(PredReg, isTrue)); } // Figure out explicit register definitions. for (unsigned i = 0; i < MCID.getNumDefs(); ++i) { unsigned R = MCI.getOperand(i).getReg(), S = Hexagon::NoRegister; // USR has subregisters (while C8 does not for technical reasons), so // reset R to USR, since we know how to handle multiple defs of USR, // taking into account its subregisters. if (R == Hexagon::C8) R = Hexagon::USR; // Note register definitions, direct ones as well as indirect side-effects. // Super-registers are not tracked directly, but their components. for (MCRegAliasIterator SRI(R, &RI, !MCSubRegIterator(R, &RI).isValid()); SRI.isValid(); ++SRI) { if (MCSubRegIterator(*SRI, &RI).isValid()) // Skip super-registers defined indirectly. continue; if (R == *SRI) { if (S == R) // Avoid scoring the defined register multiple times. continue; else // Note that the defined register has already been scored. S = R; } if (Hexagon::P3_0 != R && Hexagon::P3_0 == *SRI) // P3:0 is a special case, since multiple predicate register definitions // in a packet is allowed as the equivalent of their logical "and". // Only an explicit definition of P3:0 is noted as such; if a // side-effect, then note as a soft definition. SoftDefs.insert(*SRI); else if (HexagonMCInstrInfo::isPredicateLate(MCII, MCI) && isPredicateRegister(*SRI)) // Some insns produce predicates too late to be used in the same packet. LatePreds.insert(*SRI); else if (i == 0 && HexagonMCInstrInfo::getType(MCII, MCI) == HexagonII::TypeCVI_VM_TMP_LD) // Temporary loads should be used in the same packet, but don't commit // results, so it should be disregarded if another insn changes the same // register. // TODO: relies on the impossibility of a current and a temporary loads // in the same packet. TmpDefs.insert(*SRI); else if (i <= 1 && HexagonMCInstrInfo::hasNewValue2(MCII, MCI)) // vshuff(Vx, Vy, Rx) <- Vx(0) and Vy(1) are both source and // destination registers with this instruction. same for vdeal(Vx,Vy,Rx) Uses.insert(*SRI); else Defs[*SRI].insert(PredSense(PredReg, isTrue)); } } // Figure out definitions of new predicate registers. if (HexagonMCInstrInfo::isPredicatedNew(MCII, MCI)) for (unsigned i = MCID.getNumDefs(); i < MCID.getNumOperands(); ++i) if (MCI.getOperand(i).isReg()) { unsigned P = MCI.getOperand(i).getReg(); if (isPredicateRegister(P)) NewPreds.insert(P); } } HexagonMCChecker::HexagonMCChecker(MCContext &Context, MCInstrInfo const &MCII, MCSubtargetInfo const &STI, MCInst &mcb, MCRegisterInfo const &ri, bool ReportErrors) : Context(Context), MCB(mcb), RI(ri), MCII(MCII), STI(STI), ReportErrors(ReportErrors) { init(); } HexagonMCChecker::HexagonMCChecker(HexagonMCChecker const &Other, MCSubtargetInfo const &STI, bool CopyReportErrors) : Context(Other.Context), MCB(Other.MCB), RI(Other.RI), MCII(Other.MCII), STI(STI), ReportErrors(CopyReportErrors ? Other.ReportErrors : false) {} bool HexagonMCChecker::check(bool FullCheck) { bool chkP = checkPredicates(); bool chkNV = checkNewValues(); bool chkR = checkRegisters(); bool chkRRO = checkRegistersReadOnly(); checkRegisterCurDefs(); bool chkS = checkSolo(); bool chkSh = true; if (FullCheck) chkSh = checkShuffle(); bool chkSl = true; if (FullCheck) chkSl = checkSlots(); bool chkAXOK = checkAXOK(); bool chkCofMax1 = checkCOFMax1(); bool chkHWLoop = checkHWLoop(); bool chk = chkP && chkNV && chkR && chkRRO && chkS && chkSh && chkSl && chkAXOK && chkCofMax1 && chkHWLoop; return chk; } static bool isDuplexAGroup(unsigned Opcode) { switch (Opcode) { case Hexagon::SA1_addi: case Hexagon::SA1_addrx: case Hexagon::SA1_addsp: case Hexagon::SA1_and1: case Hexagon::SA1_clrf: case Hexagon::SA1_clrfnew: case Hexagon::SA1_clrt: case Hexagon::SA1_clrtnew: case Hexagon::SA1_cmpeqi: case Hexagon::SA1_combine0i: case Hexagon::SA1_combine1i: case Hexagon::SA1_combine2i: case Hexagon::SA1_combine3i: case Hexagon::SA1_combinerz: case Hexagon::SA1_combinezr: case Hexagon::SA1_dec: case Hexagon::SA1_inc: case Hexagon::SA1_seti: case Hexagon::SA1_setin1: case Hexagon::SA1_sxtb: case Hexagon::SA1_sxth: case Hexagon::SA1_tfr: case Hexagon::SA1_zxtb: case Hexagon::SA1_zxth: return true; break; default: return false; } } static bool isNeitherAnorX(MCInstrInfo const &MCII, MCInst const &ID) { unsigned Result = 0; unsigned Type = HexagonMCInstrInfo::getType(MCII, ID); if (Type == HexagonII::TypeDUPLEX) { unsigned subInst0Opcode = ID.getOperand(0).getInst()->getOpcode(); unsigned subInst1Opcode = ID.getOperand(1).getInst()->getOpcode(); Result += !isDuplexAGroup(subInst0Opcode); Result += !isDuplexAGroup(subInst1Opcode); } else Result += Type != HexagonII::TypeALU32_2op && Type != HexagonII::TypeALU32_3op && Type != HexagonII::TypeALU32_ADDI && Type != HexagonII::TypeS_2op && Type != HexagonII::TypeS_3op && (Type != HexagonII::TypeALU64 || HexagonMCInstrInfo::isFloat(MCII, ID)); return Result != 0; } bool HexagonMCChecker::checkAXOK() { MCInst const *HasSoloAXInst = nullptr; for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { if (HexagonMCInstrInfo::isSoloAX(MCII, I)) { HasSoloAXInst = &I; } } if (!HasSoloAXInst) return true; for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { if (&I != HasSoloAXInst && isNeitherAnorX(MCII, I)) { reportError( HasSoloAXInst->getLoc(), Twine("Instruction can only be in a packet with ALU or non-FPU XTYPE " "instructions")); reportError(I.getLoc(), Twine("Not an ALU or non-FPU XTYPE instruction")); return false; } } return true; } void HexagonMCChecker::reportBranchErrors() { for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { MCInstrDesc const &Desc = HexagonMCInstrInfo::getDesc(MCII, I); if (Desc.isBranch() || Desc.isCall() || Desc.isReturn()) reportNote(I.getLoc(), "Branching instruction"); } } bool HexagonMCChecker::checkHWLoop() { if (!HexagonMCInstrInfo::isInnerLoop(MCB) && !HexagonMCInstrInfo::isOuterLoop(MCB)) return true; for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { MCInstrDesc const &Desc = HexagonMCInstrInfo::getDesc(MCII, I); if (Desc.isBranch() || Desc.isCall() || Desc.isReturn()) { reportError(MCB.getLoc(), "Branches cannot be in a packet with hardware loops"); reportBranchErrors(); return false; } } return true; } bool HexagonMCChecker::checkCOFMax1() { SmallVector BranchLocations; for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { MCInstrDesc const &Desc = HexagonMCInstrInfo::getDesc(MCII, I); if (Desc.isBranch() || Desc.isCall() || Desc.isReturn()) BranchLocations.push_back(&I); } for (unsigned J = 0, N = BranchLocations.size(); J < N; ++J) { MCInst const &I = *BranchLocations[J]; if (HexagonMCInstrInfo::isCofMax1(MCII, I)) { bool Relax1 = HexagonMCInstrInfo::isCofRelax1(MCII, I); bool Relax2 = HexagonMCInstrInfo::isCofRelax2(MCII, I); if (N > 1 && !Relax1 && !Relax2) { reportError(I.getLoc(), "Instruction may not be in a packet with other branches"); reportBranchErrors(); return false; } if (N > 1 && J == 0 && !Relax1) { reportError(I.getLoc(), "Instruction may not be the first branch in packet"); reportBranchErrors(); return false; } if (N > 1 && J == 1 && !Relax2) { reportError(I.getLoc(), "Instruction may not be the second branch in packet"); reportBranchErrors(); return false; } } } return true; } bool HexagonMCChecker::checkSlots() { unsigned slotsUsed = 0; for (auto HMI : HexagonMCInstrInfo::bundleInstructions(MCB)) { MCInst const &MCI = *HMI.getInst(); if (HexagonMCInstrInfo::isImmext(MCI)) continue; if (HexagonMCInstrInfo::isDuplex(MCII, MCI)) slotsUsed += 2; else ++slotsUsed; } if (slotsUsed > HEXAGON_PACKET_SIZE) { reportError("invalid instruction packet: out of slots"); return false; } return true; } // Check legal use of predicate registers. bool HexagonMCChecker::checkPredicates() { // Check for proper use of new predicate registers. for (const auto &I : NewPreds) { unsigned P = I; if (!Defs.count(P) || LatePreds.count(P)) { // Error out if the new predicate register is not defined, // or defined "late" // (e.g., "{ if (p3.new)... ; p3 = sp1loop0(#r7:2, Rs) }"). reportErrorNewValue(P); return false; } } // Check for proper use of auto-anded of predicate registers. for (const auto &I : LatePreds) { unsigned P = I; if (LatePreds.count(P) > 1 || Defs.count(P)) { // Error out if predicate register defined "late" multiple times or // defined late and regularly defined // (e.g., "{ p3 = sp1loop0(...); p3 = cmp.eq(...) }". reportErrorRegisters(P); return false; } } return true; } // Check legal use of new values. bool HexagonMCChecker::checkNewValues() { for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { if (!HexagonMCInstrInfo::isNewValue(MCII, I)) continue; auto Consumer = HexagonMCInstrInfo::predicateInfo(MCII, I); bool Branch = HexagonMCInstrInfo::getDesc(MCII, I).isBranch(); MCOperand const &Op = HexagonMCInstrInfo::getNewValueOperand(MCII, I); assert(Op.isReg()); auto Producer = registerProducer(Op.getReg(), Consumer); if (std::get<0>(Producer) == nullptr) { reportError(I.getLoc(), "New value register consumer has no producer"); return false; } if (!RelaxNVChecks) { // Checks that statically prove correct new value consumption if (std::get<2>(Producer).isPredicated() && (!Consumer.isPredicated() || llvm::HexagonMCInstrInfo::getType(MCII, I) == HexagonII::TypeNCJ)) { reportNote( std::get<0>(Producer)->getLoc(), "Register producer is predicated and consumer is unconditional"); reportError(I.getLoc(), "Instruction does not have a valid new register producer"); return false; } if (std::get<2>(Producer).Register != Hexagon::NoRegister && std::get<2>(Producer).Register != Consumer.Register) { reportNote(std::get<0>(Producer)->getLoc(), "Register producer does not use the same predicate " "register as the consumer"); reportError(I.getLoc(), "Instruction does not have a valid new register producer"); return false; } } if (std::get<2>(Producer).Register == Consumer.Register && Consumer.PredicatedTrue != std::get<2>(Producer).PredicatedTrue) { reportNote( std::get<0>(Producer)->getLoc(), "Register producer has the opposite predicate sense as consumer"); reportError(I.getLoc(), "Instruction does not have a valid new register producer"); return false; } MCInstrDesc const &Desc = HexagonMCInstrInfo::getDesc(MCII, *std::get<0>(Producer)); if (Desc.OpInfo[std::get<1>(Producer)].RegClass == Hexagon::DoubleRegsRegClassID) { reportNote(std::get<0>(Producer)->getLoc(), "Double registers cannot be new-value producers"); reportError(I.getLoc(), "Instruction does not have a valid new register producer"); return false; } if ((Desc.mayLoad() && std::get<1>(Producer) == 1) || (Desc.mayStore() && std::get<1>(Producer) == 0)) { unsigned Mode = HexagonMCInstrInfo::getAddrMode(MCII, *std::get<0>(Producer)); StringRef ModeError; if (Mode == HexagonII::AbsoluteSet) ModeError = "Absolute-set"; if (Mode == HexagonII::PostInc) ModeError = "Auto-increment"; if (!ModeError.empty()) { reportNote(std::get<0>(Producer)->getLoc(), ModeError + " registers cannot be a new-value " "producer"); reportError(I.getLoc(), "Instruction does not have a valid new register producer"); return false; } } if (Branch && HexagonMCInstrInfo::isFloat(MCII, *std::get<0>(Producer))) { reportNote(std::get<0>(Producer)->getLoc(), "FPU instructions cannot be new-value producers for jumps"); reportError(I.getLoc(), "Instruction does not have a valid new register producer"); return false; } } return true; } bool HexagonMCChecker::checkRegistersReadOnly() { for (auto I : HexagonMCInstrInfo::bundleInstructions(MCB)) { MCInst const &Inst = *I.getInst(); unsigned Defs = HexagonMCInstrInfo::getDesc(MCII, Inst).getNumDefs(); for (unsigned j = 0; j < Defs; ++j) { MCOperand const &Operand = Inst.getOperand(j); assert(Operand.isReg() && "Def is not a register"); unsigned Register = Operand.getReg(); if (ReadOnly.find(Register) != ReadOnly.end()) { reportError(Inst.getLoc(), "Cannot write to read-only register `" + Twine(RI.getName(Register)) + "'"); return false; } } } return true; } bool HexagonMCChecker::registerUsed(unsigned Register) { for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) for (unsigned j = HexagonMCInstrInfo::getDesc(MCII, I).getNumDefs(), n = I.getNumOperands(); j < n; ++j) { MCOperand const &Operand = I.getOperand(j); if (Operand.isReg() && Operand.getReg() == Register) return true; } return false; } std::tuple HexagonMCChecker::registerProducer( unsigned Register, HexagonMCInstrInfo::PredicateInfo ConsumerPredicate) { std::tuple WrongSense; for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { MCInstrDesc const &Desc = HexagonMCInstrInfo::getDesc(MCII, I); auto ProducerPredicate = HexagonMCInstrInfo::predicateInfo(MCII, I); for (unsigned J = 0, N = Desc.getNumDefs(); J < N; ++J) for (auto K = MCRegAliasIterator(I.getOperand(J).getReg(), &RI, true); K.isValid(); ++K) if (*K == Register) { if (RelaxNVChecks || (ProducerPredicate.Register == ConsumerPredicate.Register && (ProducerPredicate.Register == Hexagon::NoRegister || ProducerPredicate.PredicatedTrue == ConsumerPredicate.PredicatedTrue))) return std::make_tuple(&I, J, ProducerPredicate); std::get<0>(WrongSense) = &I; std::get<1>(WrongSense) = J; std::get<2>(WrongSense) = ProducerPredicate; } if (Register == Hexagon::VTMP && HexagonMCInstrInfo::hasTmpDst(MCII, I)) return std::make_tuple(&I, 0, HexagonMCInstrInfo::PredicateInfo()); } return WrongSense; } void HexagonMCChecker::checkRegisterCurDefs() { for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { if (HexagonMCInstrInfo::isCVINew(MCII, I) && HexagonMCInstrInfo::getDesc(MCII, I).mayLoad()) { unsigned Register = I.getOperand(0).getReg(); if (!registerUsed(Register)) reportWarning("Register `" + Twine(RI.getName(Register)) + "' used with `.cur' " "but not used in the same packet"); } } } // Check for legal register uses and definitions. bool HexagonMCChecker::checkRegisters() { // Check for proper register definitions. for (const auto &I : Defs) { unsigned R = I.first; if (isLoopRegister(R) && Defs.count(R) > 1 && (HexagonMCInstrInfo::isInnerLoop(MCB) || HexagonMCInstrInfo::isOuterLoop(MCB))) { // Error out for definitions of loop registers at the end of a loop. reportError("loop-setup and some branch instructions " "cannot be in the same packet"); return false; } if (SoftDefs.count(R)) { // Error out for explicit changes to registers also weakly defined // (e.g., "{ usr = r0; r0 = sfadd(...) }"). unsigned UsrR = Hexagon::USR; // Silence warning about mixed types in ?:. unsigned BadR = RI.isSubRegister(Hexagon::USR, R) ? UsrR : R; reportErrorRegisters(BadR); return false; } if (!isPredicateRegister(R) && Defs[R].size() > 1) { // Check for multiple register definitions. PredSet &PM = Defs[R]; // Check for multiple unconditional register definitions. if (PM.count(Unconditional)) { // Error out on an unconditional change when there are any other // changes, conditional or not. unsigned UsrR = Hexagon::USR; unsigned BadR = RI.isSubRegister(Hexagon::USR, R) ? UsrR : R; reportErrorRegisters(BadR); return false; } // Check for multiple conditional register definitions. for (const auto &J : PM) { PredSense P = J; // Check for multiple uses of the same condition. if (PM.count(P) > 1) { // Error out on conditional changes based on the same predicate // (e.g., "{ if (!p0) r0 =...; if (!p0) r0 =... }"). reportErrorRegisters(R); return false; } // Check for the use of the complementary condition. P.second = !P.second; if (PM.count(P) && PM.size() > 2) { // Error out on conditional changes based on the same predicate // multiple times // (e.g., "if (p0) r0 =...; if (!p0) r0 =... }; if (!p0) r0 =..."). reportErrorRegisters(R); return false; } } } } // Check for use of temporary definitions. for (const auto &I : TmpDefs) { unsigned R = I; if (!Uses.count(R)) { // special case for vhist bool vHistFound = false; for (auto const &HMI : HexagonMCInstrInfo::bundleInstructions(MCB)) { if (HexagonMCInstrInfo::getType(MCII, *HMI.getInst()) == HexagonII::TypeCVI_HIST) { vHistFound = true; // vhist() implicitly uses ALL REGxx.tmp break; } } // Warn on an unused temporary definition. if (!vHistFound) { reportWarning("register `" + Twine(RI.getName(R)) + "' used with `.tmp' but not used in the same packet"); return true; } } } return true; } // Check for legal use of solo insns. bool HexagonMCChecker::checkSolo() { if (HexagonMCInstrInfo::bundleSize(MCB) > 1) for (auto const &I : HexagonMCInstrInfo::bundleInstructions(MCII, MCB)) { if (HexagonMCInstrInfo::isSolo(MCII, I)) { reportError(I.getLoc(), "Instruction is marked `isSolo' and " "cannot have other instructions in " "the same packet"); return false; } } return true; } bool HexagonMCChecker::checkShuffle() { HexagonMCShuffler MCSDX(Context, ReportErrors, MCII, STI, MCB); return MCSDX.check(); } void HexagonMCChecker::compoundRegisterMap(unsigned &Register) { switch (Register) { default: break; case Hexagon::R15: Register = Hexagon::R23; break; case Hexagon::R14: Register = Hexagon::R22; break; case Hexagon::R13: Register = Hexagon::R21; break; case Hexagon::R12: Register = Hexagon::R20; break; case Hexagon::R11: Register = Hexagon::R19; break; case Hexagon::R10: Register = Hexagon::R18; break; case Hexagon::R9: Register = Hexagon::R17; break; case Hexagon::R8: Register = Hexagon::R16; break; } } void HexagonMCChecker::reportErrorRegisters(unsigned Register) { reportError("register `" + Twine(RI.getName(Register)) + "' modified more than once"); } void HexagonMCChecker::reportErrorNewValue(unsigned Register) { reportError("register `" + Twine(RI.getName(Register)) + "' used with `.new' " "but not validly modified in the same packet"); } void HexagonMCChecker::reportError(Twine const &Msg) { reportError(MCB.getLoc(), Msg); } void HexagonMCChecker::reportError(SMLoc Loc, Twine const &Msg) { if (ReportErrors) Context.reportError(Loc, Msg); } void HexagonMCChecker::reportNote(SMLoc Loc, llvm::Twine const &Msg) { if (ReportErrors) { auto SM = Context.getSourceManager(); if (SM) SM->PrintMessage(Loc, SourceMgr::DK_Note, Msg); } } void HexagonMCChecker::reportWarning(Twine const &Msg) { if (ReportErrors) Context.reportWarning(MCB.getLoc(), Msg); }