//===-- HexagonDisassembler.cpp - Disassembler for Hexagon ISA ------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "Hexagon.h" #include "MCTargetDesc/HexagonBaseInfo.h" #include "MCTargetDesc/HexagonMCInstrInfo.h" #include "MCTargetDesc/HexagonMCTargetDesc.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCDisassembler.h" #include "llvm/MC/MCExpr.h" #include "llvm/MC/MCFixedLenDisassembler.h" #include "llvm/MC/MCInst.h" #include "llvm/MC/MCInstrDesc.h" #include "llvm/MC/MCSubtargetInfo.h" #include "llvm/Support/Debug.h" #include "llvm/Support/Endian.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/LEB128.h" #include "llvm/Support/TargetRegistry.h" #include "llvm/Support/raw_ostream.h" #include #include using namespace llvm; using namespace Hexagon; #define DEBUG_TYPE "hexagon-disassembler" // Pull DecodeStatus and its enum values into the global namespace. typedef llvm::MCDisassembler::DecodeStatus DecodeStatus; namespace { /// \brief Hexagon disassembler for all Hexagon platforms. class HexagonDisassembler : public MCDisassembler { public: std::unique_ptr CurrentBundle; HexagonDisassembler(MCSubtargetInfo const &STI, MCContext &Ctx) : MCDisassembler(STI, Ctx), CurrentBundle(new MCInst *) {} DecodeStatus getSingleInstruction(MCInst &Instr, MCInst &MCB, ArrayRef Bytes, uint64_t Address, raw_ostream &VStream, raw_ostream &CStream, bool &Complete) const; DecodeStatus getInstruction(MCInst &Instr, uint64_t &Size, ArrayRef Bytes, uint64_t Address, raw_ostream &VStream, raw_ostream &CStream) const override; }; } static DecodeStatus DecodeModRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t Address, const void *Decoder); static DecodeStatus DecodeCtrRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t Address, const void *Decoder); static DecodeStatus DecodeCtrRegs64RegisterClass(MCInst &Inst, unsigned RegNo, uint64_t Address, void const *Decoder); static unsigned GetSubinstOpcode(unsigned IClass, unsigned inst, unsigned &op, raw_ostream &os); static void AddSubinstOperands(MCInst *MI, unsigned opcode, unsigned inst); static const uint16_t IntRegDecoderTable[] = { Hexagon::R0, Hexagon::R1, Hexagon::R2, Hexagon::R3, Hexagon::R4, Hexagon::R5, Hexagon::R6, Hexagon::R7, Hexagon::R8, Hexagon::R9, Hexagon::R10, Hexagon::R11, Hexagon::R12, Hexagon::R13, Hexagon::R14, Hexagon::R15, Hexagon::R16, Hexagon::R17, Hexagon::R18, Hexagon::R19, Hexagon::R20, Hexagon::R21, Hexagon::R22, Hexagon::R23, Hexagon::R24, Hexagon::R25, Hexagon::R26, Hexagon::R27, Hexagon::R28, Hexagon::R29, Hexagon::R30, Hexagon::R31}; static const uint16_t PredRegDecoderTable[] = {Hexagon::P0, Hexagon::P1, Hexagon::P2, Hexagon::P3}; static DecodeStatus DecodeRegisterClass(MCInst &Inst, unsigned RegNo, const uint16_t Table[], size_t Size) { if (RegNo < Size) { Inst.addOperand(MCOperand::createReg(Table[RegNo])); return MCDisassembler::Success; } else return MCDisassembler::Fail; } static DecodeStatus DecodeIntRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t /*Address*/, void const *Decoder) { if (RegNo > 31) return MCDisassembler::Fail; unsigned Register = IntRegDecoderTable[RegNo]; Inst.addOperand(MCOperand::createReg(Register)); return MCDisassembler::Success; } static DecodeStatus DecodeCtrRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t /*Address*/, const void *Decoder) { static const uint16_t CtrlRegDecoderTable[] = { Hexagon::SA0, Hexagon::LC0, Hexagon::SA1, Hexagon::LC1, Hexagon::P3_0, Hexagon::NoRegister, Hexagon::C6, Hexagon::C7, Hexagon::USR, Hexagon::PC, Hexagon::UGP, Hexagon::GP, Hexagon::CS0, Hexagon::CS1, Hexagon::UPCL, Hexagon::UPCH}; if (RegNo >= sizeof(CtrlRegDecoderTable) / sizeof(CtrlRegDecoderTable[0])) return MCDisassembler::Fail; if (CtrlRegDecoderTable[RegNo] == Hexagon::NoRegister) return MCDisassembler::Fail; unsigned Register = CtrlRegDecoderTable[RegNo]; Inst.addOperand(MCOperand::createReg(Register)); return MCDisassembler::Success; } static DecodeStatus DecodeCtrRegs64RegisterClass(MCInst &Inst, unsigned RegNo, uint64_t /*Address*/, void const *Decoder) { static const uint16_t CtrlReg64DecoderTable[] = { Hexagon::C1_0, Hexagon::NoRegister, Hexagon::C3_2, Hexagon::NoRegister, Hexagon::NoRegister, Hexagon::NoRegister, Hexagon::C7_6, Hexagon::NoRegister, Hexagon::C9_8, Hexagon::NoRegister, Hexagon::C11_10, Hexagon::NoRegister, Hexagon::CS, Hexagon::NoRegister, Hexagon::UPC, Hexagon::NoRegister}; if (RegNo >= sizeof(CtrlReg64DecoderTable) / sizeof(CtrlReg64DecoderTable[0])) return MCDisassembler::Fail; if (CtrlReg64DecoderTable[RegNo] == Hexagon::NoRegister) return MCDisassembler::Fail; unsigned Register = CtrlReg64DecoderTable[RegNo]; Inst.addOperand(MCOperand::createReg(Register)); return MCDisassembler::Success; } static DecodeStatus DecodeModRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t /*Address*/, const void *Decoder) { unsigned Register = 0; switch (RegNo) { case 0: Register = Hexagon::M0; break; case 1: Register = Hexagon::M1; break; default: return MCDisassembler::Fail; } Inst.addOperand(MCOperand::createReg(Register)); return MCDisassembler::Success; } static DecodeStatus DecodeDoubleRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t /*Address*/, const void *Decoder) { static const uint16_t DoubleRegDecoderTable[] = { Hexagon::D0, Hexagon::D1, Hexagon::D2, Hexagon::D3, Hexagon::D4, Hexagon::D5, Hexagon::D6, Hexagon::D7, Hexagon::D8, Hexagon::D9, Hexagon::D10, Hexagon::D11, Hexagon::D12, Hexagon::D13, Hexagon::D14, Hexagon::D15}; return (DecodeRegisterClass(Inst, RegNo >> 1, DoubleRegDecoderTable, sizeof(DoubleRegDecoderTable))); } static DecodeStatus DecodePredRegsRegisterClass(MCInst &Inst, unsigned RegNo, uint64_t /*Address*/, void const *Decoder) { if (RegNo > 3) return MCDisassembler::Fail; unsigned Register = PredRegDecoderTable[RegNo]; Inst.addOperand(MCOperand::createReg(Register)); return MCDisassembler::Success; } #include "HexagonGenDisassemblerTables.inc" static MCDisassembler *createHexagonDisassembler(Target const &T, MCSubtargetInfo const &STI, MCContext &Ctx) { return new HexagonDisassembler(STI, Ctx); } extern "C" void LLVMInitializeHexagonDisassembler() { TargetRegistry::RegisterMCDisassembler(TheHexagonTarget, createHexagonDisassembler); } DecodeStatus HexagonDisassembler::getInstruction(MCInst &MI, uint64_t &Size, ArrayRef Bytes, uint64_t Address, raw_ostream &os, raw_ostream &cs) const { DecodeStatus Result = DecodeStatus::Success; bool Complete = false; Size = 0; *CurrentBundle = &MI; MI.setOpcode(Hexagon::BUNDLE); MI.addOperand(MCOperand::createImm(0)); while (Result == Success && Complete == false) { if (Bytes.size() < HEXAGON_INSTR_SIZE) return MCDisassembler::Fail; MCInst *Inst = new (getContext()) MCInst; Result = getSingleInstruction(*Inst, MI, Bytes, Address, os, cs, Complete); MI.addOperand(MCOperand::createInst(Inst)); Size += HEXAGON_INSTR_SIZE; Bytes = Bytes.slice(HEXAGON_INSTR_SIZE); } return Result; } DecodeStatus HexagonDisassembler::getSingleInstruction( MCInst &MI, MCInst &MCB, ArrayRef Bytes, uint64_t Address, raw_ostream &os, raw_ostream &cs, bool &Complete) const { assert(Bytes.size() >= HEXAGON_INSTR_SIZE); uint32_t Instruction = llvm::support::endian::read(Bytes.data()); auto BundleSize = HexagonMCInstrInfo::bundleSize(MCB); if ((Instruction & HexagonII::INST_PARSE_MASK) == HexagonII::INST_PARSE_LOOP_END) { if (BundleSize == 0) HexagonMCInstrInfo::setInnerLoop(MCB); else if (BundleSize == 1) HexagonMCInstrInfo::setOuterLoop(MCB); else return DecodeStatus::Fail; } DecodeStatus Result = DecodeStatus::Success; if ((Instruction & HexagonII::INST_PARSE_MASK) == HexagonII::INST_PARSE_DUPLEX) { // Determine the instruction class of each instruction in the duplex. unsigned duplexIClass, IClassLow, IClassHigh; duplexIClass = ((Instruction >> 28) & 0xe) | ((Instruction >> 13) & 0x1); switch (duplexIClass) { default: return MCDisassembler::Fail; case 0: IClassLow = HexagonII::HSIG_L1; IClassHigh = HexagonII::HSIG_L1; break; case 1: IClassLow = HexagonII::HSIG_L2; IClassHigh = HexagonII::HSIG_L1; break; case 2: IClassLow = HexagonII::HSIG_L2; IClassHigh = HexagonII::HSIG_L2; break; case 3: IClassLow = HexagonII::HSIG_A; IClassHigh = HexagonII::HSIG_A; break; case 4: IClassLow = HexagonII::HSIG_L1; IClassHigh = HexagonII::HSIG_A; break; case 5: IClassLow = HexagonII::HSIG_L2; IClassHigh = HexagonII::HSIG_A; break; case 6: IClassLow = HexagonII::HSIG_S1; IClassHigh = HexagonII::HSIG_A; break; case 7: IClassLow = HexagonII::HSIG_S2; IClassHigh = HexagonII::HSIG_A; break; case 8: IClassLow = HexagonII::HSIG_S1; IClassHigh = HexagonII::HSIG_L1; break; case 9: IClassLow = HexagonII::HSIG_S1; IClassHigh = HexagonII::HSIG_L2; break; case 10: IClassLow = HexagonII::HSIG_S1; IClassHigh = HexagonII::HSIG_S1; break; case 11: IClassLow = HexagonII::HSIG_S2; IClassHigh = HexagonII::HSIG_S1; break; case 12: IClassLow = HexagonII::HSIG_S2; IClassHigh = HexagonII::HSIG_L1; break; case 13: IClassLow = HexagonII::HSIG_S2; IClassHigh = HexagonII::HSIG_L2; break; case 14: IClassLow = HexagonII::HSIG_S2; IClassHigh = HexagonII::HSIG_S2; break; } // Set the MCInst to be a duplex instruction. Which one doesn't matter. MI.setOpcode(Hexagon::DuplexIClass0); // Decode each instruction in the duplex. // Create an MCInst for each instruction. unsigned instLow = Instruction & 0x1fff; unsigned instHigh = (Instruction >> 16) & 0x1fff; unsigned opLow; if (GetSubinstOpcode(IClassLow, instLow, opLow, os) != MCDisassembler::Success) return MCDisassembler::Fail; unsigned opHigh; if (GetSubinstOpcode(IClassHigh, instHigh, opHigh, os) != MCDisassembler::Success) return MCDisassembler::Fail; MCInst *MILow = new (getContext()) MCInst; MILow->setOpcode(opLow); MCInst *MIHigh = new (getContext()) MCInst; MIHigh->setOpcode(opHigh); AddSubinstOperands(MILow, opLow, instLow); AddSubinstOperands(MIHigh, opHigh, instHigh); // see ConvertToSubInst() in // lib/Target/Hexagon/MCTargetDesc/HexagonMCDuplexInfo.cpp // Add the duplex instruction MCInsts as operands to the passed in MCInst. MCOperand OPLow = MCOperand::createInst(MILow); MCOperand OPHigh = MCOperand::createInst(MIHigh); MI.addOperand(OPLow); MI.addOperand(OPHigh); Complete = true; } else { if ((Instruction & HexagonII::INST_PARSE_MASK) == HexagonII::INST_PARSE_PACKET_END) Complete = true; // Calling the auto-generated decoder function. Result = decodeInstruction(DecoderTable32, MI, Instruction, Address, this, STI); } return Result; } // These values are from HexagonGenMCCodeEmitter.inc and HexagonIsetDx.td enum subInstBinaryValues { V4_SA1_addi_BITS = 0x0000, V4_SA1_addi_MASK = 0x1800, V4_SA1_addrx_BITS = 0x1800, V4_SA1_addrx_MASK = 0x1f00, V4_SA1_addsp_BITS = 0x0c00, V4_SA1_addsp_MASK = 0x1c00, V4_SA1_and1_BITS = 0x1200, V4_SA1_and1_MASK = 0x1f00, V4_SA1_clrf_BITS = 0x1a70, V4_SA1_clrf_MASK = 0x1e70, V4_SA1_clrfnew_BITS = 0x1a50, V4_SA1_clrfnew_MASK = 0x1e70, V4_SA1_clrt_BITS = 0x1a60, V4_SA1_clrt_MASK = 0x1e70, V4_SA1_clrtnew_BITS = 0x1a40, V4_SA1_clrtnew_MASK = 0x1e70, V4_SA1_cmpeqi_BITS = 0x1900, V4_SA1_cmpeqi_MASK = 0x1f00, V4_SA1_combine0i_BITS = 0x1c00, V4_SA1_combine0i_MASK = 0x1d18, V4_SA1_combine1i_BITS = 0x1c08, V4_SA1_combine1i_MASK = 0x1d18, V4_SA1_combine2i_BITS = 0x1c10, V4_SA1_combine2i_MASK = 0x1d18, V4_SA1_combine3i_BITS = 0x1c18, V4_SA1_combine3i_MASK = 0x1d18, V4_SA1_combinerz_BITS = 0x1d08, V4_SA1_combinerz_MASK = 0x1d08, V4_SA1_combinezr_BITS = 0x1d00, V4_SA1_combinezr_MASK = 0x1d08, V4_SA1_dec_BITS = 0x1300, V4_SA1_dec_MASK = 0x1f00, V4_SA1_inc_BITS = 0x1100, V4_SA1_inc_MASK = 0x1f00, V4_SA1_seti_BITS = 0x0800, V4_SA1_seti_MASK = 0x1c00, V4_SA1_setin1_BITS = 0x1a00, V4_SA1_setin1_MASK = 0x1e40, V4_SA1_sxtb_BITS = 0x1500, V4_SA1_sxtb_MASK = 0x1f00, V4_SA1_sxth_BITS = 0x1400, V4_SA1_sxth_MASK = 0x1f00, V4_SA1_tfr_BITS = 0x1000, V4_SA1_tfr_MASK = 0x1f00, V4_SA1_zxtb_BITS = 0x1700, V4_SA1_zxtb_MASK = 0x1f00, V4_SA1_zxth_BITS = 0x1600, V4_SA1_zxth_MASK = 0x1f00, V4_SL1_loadri_io_BITS = 0x0000, V4_SL1_loadri_io_MASK = 0x1000, V4_SL1_loadrub_io_BITS = 0x1000, V4_SL1_loadrub_io_MASK = 0x1000, V4_SL2_deallocframe_BITS = 0x1f00, V4_SL2_deallocframe_MASK = 0x1fc0, V4_SL2_jumpr31_BITS = 0x1fc0, V4_SL2_jumpr31_MASK = 0x1fc4, V4_SL2_jumpr31_f_BITS = 0x1fc5, V4_SL2_jumpr31_f_MASK = 0x1fc7, V4_SL2_jumpr31_fnew_BITS = 0x1fc7, V4_SL2_jumpr31_fnew_MASK = 0x1fc7, V4_SL2_jumpr31_t_BITS = 0x1fc4, V4_SL2_jumpr31_t_MASK = 0x1fc7, V4_SL2_jumpr31_tnew_BITS = 0x1fc6, V4_SL2_jumpr31_tnew_MASK = 0x1fc7, V4_SL2_loadrb_io_BITS = 0x1000, V4_SL2_loadrb_io_MASK = 0x1800, V4_SL2_loadrd_sp_BITS = 0x1e00, V4_SL2_loadrd_sp_MASK = 0x1f00, V4_SL2_loadrh_io_BITS = 0x0000, V4_SL2_loadrh_io_MASK = 0x1800, V4_SL2_loadri_sp_BITS = 0x1c00, V4_SL2_loadri_sp_MASK = 0x1e00, V4_SL2_loadruh_io_BITS = 0x0800, V4_SL2_loadruh_io_MASK = 0x1800, V4_SL2_return_BITS = 0x1f40, V4_SL2_return_MASK = 0x1fc4, V4_SL2_return_f_BITS = 0x1f45, V4_SL2_return_f_MASK = 0x1fc7, V4_SL2_return_fnew_BITS = 0x1f47, V4_SL2_return_fnew_MASK = 0x1fc7, V4_SL2_return_t_BITS = 0x1f44, V4_SL2_return_t_MASK = 0x1fc7, V4_SL2_return_tnew_BITS = 0x1f46, V4_SL2_return_tnew_MASK = 0x1fc7, V4_SS1_storeb_io_BITS = 0x1000, V4_SS1_storeb_io_MASK = 0x1000, V4_SS1_storew_io_BITS = 0x0000, V4_SS1_storew_io_MASK = 0x1000, V4_SS2_allocframe_BITS = 0x1c00, V4_SS2_allocframe_MASK = 0x1e00, V4_SS2_storebi0_BITS = 0x1200, V4_SS2_storebi0_MASK = 0x1f00, V4_SS2_storebi1_BITS = 0x1300, V4_SS2_storebi1_MASK = 0x1f00, V4_SS2_stored_sp_BITS = 0x0a00, V4_SS2_stored_sp_MASK = 0x1e00, V4_SS2_storeh_io_BITS = 0x0000, V4_SS2_storeh_io_MASK = 0x1800, V4_SS2_storew_sp_BITS = 0x0800, V4_SS2_storew_sp_MASK = 0x1e00, V4_SS2_storewi0_BITS = 0x1000, V4_SS2_storewi0_MASK = 0x1f00, V4_SS2_storewi1_BITS = 0x1100, V4_SS2_storewi1_MASK = 0x1f00 }; static unsigned GetSubinstOpcode(unsigned IClass, unsigned inst, unsigned &op, raw_ostream &os) { switch (IClass) { case HexagonII::HSIG_L1: if ((inst & V4_SL1_loadri_io_MASK) == V4_SL1_loadri_io_BITS) op = Hexagon::V4_SL1_loadri_io; else if ((inst & V4_SL1_loadrub_io_MASK) == V4_SL1_loadrub_io_BITS) op = Hexagon::V4_SL1_loadrub_io; else { os << ""; return MCDisassembler::Fail; } break; case HexagonII::HSIG_L2: if ((inst & V4_SL2_deallocframe_MASK) == V4_SL2_deallocframe_BITS) op = Hexagon::V4_SL2_deallocframe; else if ((inst & V4_SL2_jumpr31_MASK) == V4_SL2_jumpr31_BITS) op = Hexagon::V4_SL2_jumpr31; else if ((inst & V4_SL2_jumpr31_f_MASK) == V4_SL2_jumpr31_f_BITS) op = Hexagon::V4_SL2_jumpr31_f; else if ((inst & V4_SL2_jumpr31_fnew_MASK) == V4_SL2_jumpr31_fnew_BITS) op = Hexagon::V4_SL2_jumpr31_fnew; else if ((inst & V4_SL2_jumpr31_t_MASK) == V4_SL2_jumpr31_t_BITS) op = Hexagon::V4_SL2_jumpr31_t; else if ((inst & V4_SL2_jumpr31_tnew_MASK) == V4_SL2_jumpr31_tnew_BITS) op = Hexagon::V4_SL2_jumpr31_tnew; else if ((inst & V4_SL2_loadrb_io_MASK) == V4_SL2_loadrb_io_BITS) op = Hexagon::V4_SL2_loadrb_io; else if ((inst & V4_SL2_loadrd_sp_MASK) == V4_SL2_loadrd_sp_BITS) op = Hexagon::V4_SL2_loadrd_sp; else if ((inst & V4_SL2_loadrh_io_MASK) == V4_SL2_loadrh_io_BITS) op = Hexagon::V4_SL2_loadrh_io; else if ((inst & V4_SL2_loadri_sp_MASK) == V4_SL2_loadri_sp_BITS) op = Hexagon::V4_SL2_loadri_sp; else if ((inst & V4_SL2_loadruh_io_MASK) == V4_SL2_loadruh_io_BITS) op = Hexagon::V4_SL2_loadruh_io; else if ((inst & V4_SL2_return_MASK) == V4_SL2_return_BITS) op = Hexagon::V4_SL2_return; else if ((inst & V4_SL2_return_f_MASK) == V4_SL2_return_f_BITS) op = Hexagon::V4_SL2_return_f; else if ((inst & V4_SL2_return_fnew_MASK) == V4_SL2_return_fnew_BITS) op = Hexagon::V4_SL2_return_fnew; else if ((inst & V4_SL2_return_t_MASK) == V4_SL2_return_t_BITS) op = Hexagon::V4_SL2_return_t; else if ((inst & V4_SL2_return_tnew_MASK) == V4_SL2_return_tnew_BITS) op = Hexagon::V4_SL2_return_tnew; else { os << ""; return MCDisassembler::Fail; } break; case HexagonII::HSIG_A: if ((inst & V4_SA1_addi_MASK) == V4_SA1_addi_BITS) op = Hexagon::V4_SA1_addi; else if ((inst & V4_SA1_addrx_MASK) == V4_SA1_addrx_BITS) op = Hexagon::V4_SA1_addrx; else if ((inst & V4_SA1_addsp_MASK) == V4_SA1_addsp_BITS) op = Hexagon::V4_SA1_addsp; else if ((inst & V4_SA1_and1_MASK) == V4_SA1_and1_BITS) op = Hexagon::V4_SA1_and1; else if ((inst & V4_SA1_clrf_MASK) == V4_SA1_clrf_BITS) op = Hexagon::V4_SA1_clrf; else if ((inst & V4_SA1_clrfnew_MASK) == V4_SA1_clrfnew_BITS) op = Hexagon::V4_SA1_clrfnew; else if ((inst & V4_SA1_clrt_MASK) == V4_SA1_clrt_BITS) op = Hexagon::V4_SA1_clrt; else if ((inst & V4_SA1_clrtnew_MASK) == V4_SA1_clrtnew_BITS) op = Hexagon::V4_SA1_clrtnew; else if ((inst & V4_SA1_cmpeqi_MASK) == V4_SA1_cmpeqi_BITS) op = Hexagon::V4_SA1_cmpeqi; else if ((inst & V4_SA1_combine0i_MASK) == V4_SA1_combine0i_BITS) op = Hexagon::V4_SA1_combine0i; else if ((inst & V4_SA1_combine1i_MASK) == V4_SA1_combine1i_BITS) op = Hexagon::V4_SA1_combine1i; else if ((inst & V4_SA1_combine2i_MASK) == V4_SA1_combine2i_BITS) op = Hexagon::V4_SA1_combine2i; else if ((inst & V4_SA1_combine3i_MASK) == V4_SA1_combine3i_BITS) op = Hexagon::V4_SA1_combine3i; else if ((inst & V4_SA1_combinerz_MASK) == V4_SA1_combinerz_BITS) op = Hexagon::V4_SA1_combinerz; else if ((inst & V4_SA1_combinezr_MASK) == V4_SA1_combinezr_BITS) op = Hexagon::V4_SA1_combinezr; else if ((inst & V4_SA1_dec_MASK) == V4_SA1_dec_BITS) op = Hexagon::V4_SA1_dec; else if ((inst & V4_SA1_inc_MASK) == V4_SA1_inc_BITS) op = Hexagon::V4_SA1_inc; else if ((inst & V4_SA1_seti_MASK) == V4_SA1_seti_BITS) op = Hexagon::V4_SA1_seti; else if ((inst & V4_SA1_setin1_MASK) == V4_SA1_setin1_BITS) op = Hexagon::V4_SA1_setin1; else if ((inst & V4_SA1_sxtb_MASK) == V4_SA1_sxtb_BITS) op = Hexagon::V4_SA1_sxtb; else if ((inst & V4_SA1_sxth_MASK) == V4_SA1_sxth_BITS) op = Hexagon::V4_SA1_sxth; else if ((inst & V4_SA1_tfr_MASK) == V4_SA1_tfr_BITS) op = Hexagon::V4_SA1_tfr; else if ((inst & V4_SA1_zxtb_MASK) == V4_SA1_zxtb_BITS) op = Hexagon::V4_SA1_zxtb; else if ((inst & V4_SA1_zxth_MASK) == V4_SA1_zxth_BITS) op = Hexagon::V4_SA1_zxth; else { os << ""; return MCDisassembler::Fail; } break; case HexagonII::HSIG_S1: if ((inst & V4_SS1_storeb_io_MASK) == V4_SS1_storeb_io_BITS) op = Hexagon::V4_SS1_storeb_io; else if ((inst & V4_SS1_storew_io_MASK) == V4_SS1_storew_io_BITS) op = Hexagon::V4_SS1_storew_io; else { os << ""; return MCDisassembler::Fail; } break; case HexagonII::HSIG_S2: if ((inst & V4_SS2_allocframe_MASK) == V4_SS2_allocframe_BITS) op = Hexagon::V4_SS2_allocframe; else if ((inst & V4_SS2_storebi0_MASK) == V4_SS2_storebi0_BITS) op = Hexagon::V4_SS2_storebi0; else if ((inst & V4_SS2_storebi1_MASK) == V4_SS2_storebi1_BITS) op = Hexagon::V4_SS2_storebi1; else if ((inst & V4_SS2_stored_sp_MASK) == V4_SS2_stored_sp_BITS) op = Hexagon::V4_SS2_stored_sp; else if ((inst & V4_SS2_storeh_io_MASK) == V4_SS2_storeh_io_BITS) op = Hexagon::V4_SS2_storeh_io; else if ((inst & V4_SS2_storew_sp_MASK) == V4_SS2_storew_sp_BITS) op = Hexagon::V4_SS2_storew_sp; else if ((inst & V4_SS2_storewi0_MASK) == V4_SS2_storewi0_BITS) op = Hexagon::V4_SS2_storewi0; else if ((inst & V4_SS2_storewi1_MASK) == V4_SS2_storewi1_BITS) op = Hexagon::V4_SS2_storewi1; else { os << ""; return MCDisassembler::Fail; } break; default: os << ""; return MCDisassembler::Fail; } return MCDisassembler::Success; } static unsigned getRegFromSubinstEncoding(unsigned encoded_reg) { if (encoded_reg < 8) return Hexagon::R0 + encoded_reg; else if (encoded_reg < 16) return Hexagon::R0 + encoded_reg + 8; return Hexagon::NoRegister; } static unsigned getDRegFromSubinstEncoding(unsigned encoded_dreg) { if (encoded_dreg < 4) return Hexagon::D0 + encoded_dreg; else if (encoded_dreg < 8) return Hexagon::D0 + encoded_dreg + 4; return Hexagon::NoRegister; } static void AddSubinstOperands(MCInst *MI, unsigned opcode, unsigned inst) { int64_t operand; MCOperand Op; switch (opcode) { case Hexagon::V4_SL2_deallocframe: case Hexagon::V4_SL2_jumpr31: case Hexagon::V4_SL2_jumpr31_f: case Hexagon::V4_SL2_jumpr31_fnew: case Hexagon::V4_SL2_jumpr31_t: case Hexagon::V4_SL2_jumpr31_tnew: case Hexagon::V4_SL2_return: case Hexagon::V4_SL2_return_f: case Hexagon::V4_SL2_return_fnew: case Hexagon::V4_SL2_return_t: case Hexagon::V4_SL2_return_tnew: // no operands for these instructions break; case Hexagon::V4_SS2_allocframe: // u 8-4{5_3} operand = ((inst & 0x1f0) >> 4) << 3; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SL1_loadri_io: // Rd 3-0, Rs 7-4, u 11-8{4_2} operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0xf00) >> 6; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SL1_loadrub_io: // Rd 3-0, Rs 7-4, u 11-8 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0xf00) >> 8; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SL2_loadrb_io: // Rd 3-0, Rs 7-4, u 10-8 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0x700) >> 8; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SL2_loadrh_io: case Hexagon::V4_SL2_loadruh_io: // Rd 3-0, Rs 7-4, u 10-8{3_1} operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = ((inst & 0x700) >> 8) << 1; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SL2_loadrd_sp: // Rdd 2-0, u 7-3{5_3} operand = getDRegFromSubinstEncoding(inst & 0x7); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = ((inst & 0x0f8) >> 3) << 3; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SL2_loadri_sp: // Rd 3-0, u 8-4{5_2} operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = ((inst & 0x1f0) >> 4) << 2; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_addi: // Rx 3-0 (x2), s7 10-4 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); MI->addOperand(Op); operand = SignExtend64<7>((inst & 0x7f0) >> 4); Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_addrx: // Rx 3-0 (x2), Rs 7-4 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); case Hexagon::V4_SA1_and1: case Hexagon::V4_SA1_dec: case Hexagon::V4_SA1_inc: case Hexagon::V4_SA1_sxtb: case Hexagon::V4_SA1_sxth: case Hexagon::V4_SA1_tfr: case Hexagon::V4_SA1_zxtb: case Hexagon::V4_SA1_zxth: // Rd 3-0, Rs 7-4 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_addsp: // Rd 3-0, u 9-4{6_2} operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = ((inst & 0x3f0) >> 4) << 2; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_seti: // Rd 3-0, u 9-4 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0x3f0) >> 4; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_clrf: case Hexagon::V4_SA1_clrfnew: case Hexagon::V4_SA1_clrt: case Hexagon::V4_SA1_clrtnew: case Hexagon::V4_SA1_setin1: // Rd 3-0 operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_cmpeqi: // Rs 7-4, u 1-0 operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = inst & 0x3; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_combine0i: case Hexagon::V4_SA1_combine1i: case Hexagon::V4_SA1_combine2i: case Hexagon::V4_SA1_combine3i: // Rdd 2-0, u 6-5 operand = getDRegFromSubinstEncoding(inst & 0x7); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0x060) >> 5; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SA1_combinerz: case Hexagon::V4_SA1_combinezr: // Rdd 2-0, Rs 7-4 operand = getDRegFromSubinstEncoding(inst & 0x7); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; case Hexagon::V4_SS1_storeb_io: // Rs 7-4, u 11-8, Rt 3-0 operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0xf00) >> 8; Op = MCOperand::createImm(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; case Hexagon::V4_SS1_storew_io: // Rs 7-4, u 11-8{4_2}, Rt 3-0 operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = ((inst & 0xf00) >> 8) << 2; Op = MCOperand::createImm(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; case Hexagon::V4_SS2_storebi0: case Hexagon::V4_SS2_storebi1: // Rs 7-4, u 3-0 operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = inst & 0xf; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SS2_storewi0: case Hexagon::V4_SS2_storewi1: // Rs 7-4, u 3-0{4_2} operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = (inst & 0xf) << 2; Op = MCOperand::createImm(operand); MI->addOperand(Op); break; case Hexagon::V4_SS2_stored_sp: // s 8-3{6_3}, Rtt 2-0 operand = SignExtend64<9>(((inst & 0x1f8) >> 3) << 3); Op = MCOperand::createImm(operand); MI->addOperand(Op); operand = getDRegFromSubinstEncoding(inst & 0x7); Op = MCOperand::createReg(operand); MI->addOperand(Op); case Hexagon::V4_SS2_storeh_io: // Rs 7-4, u 10-8{3_1}, Rt 3-0 operand = getRegFromSubinstEncoding((inst & 0xf0) >> 4); Op = MCOperand::createReg(operand); MI->addOperand(Op); operand = ((inst & 0x700) >> 8) << 1; Op = MCOperand::createImm(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; case Hexagon::V4_SS2_storew_sp: // u 8-4{5_2}, Rd 3-0 operand = ((inst & 0x1f0) >> 4) << 2; Op = MCOperand::createImm(operand); MI->addOperand(Op); operand = getRegFromSubinstEncoding(inst & 0xf); Op = MCOperand::createReg(operand); MI->addOperand(Op); break; default: // don't crash with an invalid subinstruction // llvm_unreachable("Invalid subinstruction in duplex instruction"); break; } }