// -*- mode:c++ -*- // Copyright (c) 2010-2013,2017-2018 ARM Limited // All rights reserved // // The license below extends only to copyright in the software and shall // not be construed as granting a license to any other intellectual // property including but not limited to intellectual property relating // to a hardware implementation of the functionality of the software // licensed hereunder. You may use the software subject to the license // terms below provided that you ensure that this notice is replicated // unmodified and in its entirety in all distributions of the software, // modified or unmodified, in source code or in binary form. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer; // redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution; // neither the name of the copyright holders nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // Authors: Gabe Black let {{ svcCode = ''' ThreadContext *tc = xc->tcBase(); const auto semihost_imm = Thumb? 0xAB : 0x123456; if (ArmSystem::haveSemihosting(tc) && imm == semihost_imm) { R0 = ArmSystem::callSemihosting32(tc, R0, R1); } else { fault = std::make_shared(machInst, imm); } ''' svcIop = InstObjParams("svc", "Svc", "ImmOp", { "code": svcCode, "predicate_test": predicateTest, "thumb_semihost": '0xAB', "arm_semihost": '0x123456' }, ["IsSyscall", "IsNonSpeculative", "IsSerializeAfter"]) header_output = ImmOpDeclare.subst(svcIop) decoder_output = SemihostConstructor.subst(svcIop) exec_output = PredOpExecute.subst(svcIop) hltCode = ''' ThreadContext *tc = xc->tcBase(); const auto semihost_imm = Thumb? 0x3C : 0xF000; if (ArmSystem::haveSemihosting(tc) && imm == semihost_imm) { R0 = ArmSystem::callSemihosting32(tc, R0, R1); } else { // HLT instructions aren't implemented, so treat them as undefined // instructions. fault = std::make_shared( machInst, false, mnemonic); } ''' hltIop = InstObjParams("hlt", "Hlt", "ImmOp", { "code": hltCode, "predicate_test": predicateTest, "thumb_semihost": '0x3C', "arm_semihost": '0xF000' }, ["IsNonSpeculative"]) header_output += ImmOpDeclare.subst(hltIop) decoder_output += SemihostConstructor.subst(hltIop) exec_output += PredOpExecute.subst(hltIop) smcCode = ''' HCR hcr = Hcr; CPSR cpsr = Cpsr; SCR scr = Scr; if ((cpsr.mode != MODE_USER) && FullSystem) { if (ArmSystem::haveVirtualization(xc->tcBase()) && !inSecureState(scr, cpsr) && (cpsr.mode != MODE_HYP) && hcr.tsc) { fault = std::make_shared(machInst, 0, EC_SMC_TO_HYP); } else { if (scr.scd) { fault = disabledFault(); } else { fault = std::make_shared(machInst); } } } else { fault = disabledFault(); } ''' smcIop = InstObjParams("smc", "Smc", "PredOp", { "code": smcCode, "predicate_test": predicateTest }, ["IsNonSpeculative", "IsSerializeAfter"]) header_output += BasicDeclare.subst(smcIop) decoder_output += BasicConstructor.subst(smcIop) exec_output += PredOpExecute.subst(smcIop) hvcCode = ''' CPSR cpsr = Cpsr; SCR scr = Scr; // Filter out the various cases where this instruction isn't defined if (!FullSystem || !ArmSystem::haveVirtualization(xc->tcBase()) || (cpsr.mode == MODE_USER) || (ArmSystem::haveSecurity(xc->tcBase()) && (!scr.ns || !scr.hce))) { fault = disabledFault(); } else { fault = std::make_shared(machInst, imm); } ''' hvcIop = InstObjParams("hvc", "Hvc", "ImmOp", { "code": hvcCode, "predicate_test": predicateTest }, ["IsNonSpeculative", "IsSerializeAfter"]) header_output += ImmOpDeclare.subst(hvcIop) decoder_output += ImmOpConstructor.subst(hvcIop) exec_output += PredOpExecute.subst(hvcIop) eretCode = ''' SCTLR sctlr = Sctlr; CPSR old_cpsr = Cpsr; old_cpsr.nz = CondCodesNZ; old_cpsr.c = CondCodesC; old_cpsr.v = CondCodesV; old_cpsr.ge = CondCodesGE; CPSR new_cpsr = cpsrWriteByInstr(old_cpsr, Spsr, Scr, Nsacr, 0xF, true, sctlr.nmfi, xc->tcBase()); Cpsr = ~CondCodesMask & new_cpsr; CondCodesNZ = new_cpsr.nz; CondCodesC = new_cpsr.c; CondCodesV = new_cpsr.v; CondCodesGE = new_cpsr.ge; NextThumb = (new_cpsr).t; NextJazelle = (new_cpsr).j; NextItState = (((new_cpsr).it2 << 2) & 0xFC) | ((new_cpsr).it1 & 0x3); NPC = (old_cpsr.mode == MODE_HYP) ? ElrHyp : LR; ''' eretIop = InstObjParams("eret", "Eret", "PredOp", { "code": eretCode, "predicate_test": predicateTest }, ["IsNonSpeculative", "IsSerializeAfter", "IsSquashAfter"]) header_output += BasicDeclare.subst(eretIop) decoder_output += BasicConstructor.subst(eretIop) exec_output += PredOpExecute.subst(eretIop) crcCode = ''' constexpr uint8_t size_bytes = %(sz)d; constexpr uint32_t poly = %(polynom)s; uint32_t data = htole(Op2); auto data_buffer = reinterpret_cast(&data); Dest = crc32( data_buffer, /* Message Register */ Op1, /* Initial Value of the CRC */ size_bytes /* Size of the original Message */ ); ''' def crc32Emit(mnem, implCode, castagnoli, size): global header_output, decoder_output, exec_output if castagnoli: # crc32c instructions poly = "0x1EDC6F41" else: # crc32 instructions poly = "0x04C11DB7" data = {'sz' : size, 'polynom': poly} instCode = implCode % data crcIop = InstObjParams(mnem, mnem.capitalize(), "RegRegRegOp", { "code": instCode, "predicate_test": predicateTest }, []) header_output += RegRegRegOpDeclare.subst(crcIop) decoder_output += RegRegRegOpConstructor.subst(crcIop) exec_output += PredOpExecute.subst(crcIop) crc32Emit("crc32b", crcCode, False, 1); crc32Emit("crc32h", crcCode, False, 2); crc32Emit("crc32w", crcCode, False, 4); crc32Emit("crc32cb", crcCode, True, 1); crc32Emit("crc32ch", crcCode, True, 2); crc32Emit("crc32cw", crcCode, True, 4); }}; let {{ header_output = decoder_output = exec_output = "" mrsCpsrCode = ''' CPSR cpsr = Cpsr; cpsr.nz = CondCodesNZ; cpsr.c = CondCodesC; cpsr.v = CondCodesV; cpsr.ge = CondCodesGE; Dest = cpsr & (cpsr.mode == MODE_USER ? ApsrMask : CpsrMask); ''' mrsCpsrIop = InstObjParams("mrs", "MrsCpsr", "MrsOp", { "code": mrsCpsrCode, "predicate_test": condPredicateTest }, ["IsSerializeBefore"]) header_output += MrsDeclare.subst(mrsCpsrIop) decoder_output += MrsConstructor.subst(mrsCpsrIop) exec_output += PredOpExecute.subst(mrsCpsrIop) mrsSpsrCode = "Dest = Spsr" mrsSpsrIop = InstObjParams("mrs", "MrsSpsr", "MrsOp", { "code": mrsSpsrCode, "predicate_test": predicateTest }, ["IsSerializeBefore"]) header_output += MrsDeclare.subst(mrsSpsrIop) decoder_output += MrsConstructor.subst(mrsSpsrIop) exec_output += PredOpExecute.subst(mrsSpsrIop) mrsBankedRegCode = ''' bool isIntReg; int regIdx; if (decodeMrsMsrBankedReg(byteMask, r, isIntReg, regIdx, Cpsr, Scr, Nsacr)) { if (isIntReg) { Dest = DecodedBankedIntReg; } else { Dest = xc->readMiscReg(regIdx); } } else { return std::make_shared(machInst, false, mnemonic); } ''' mrsBankedRegIop = InstObjParams("mrs", "MrsBankedReg", "MrsOp", { "code": mrsBankedRegCode, "predicate_test": predicateTest }, ["IsSerializeBefore"]) header_output += MrsBankedRegDeclare.subst(mrsBankedRegIop) decoder_output += MrsBankedRegConstructor.subst(mrsBankedRegIop) exec_output += PredOpExecute.subst(mrsBankedRegIop) msrBankedRegCode = ''' bool isIntReg; int regIdx; if (decodeMrsMsrBankedReg(byteMask, r, isIntReg, regIdx, Cpsr, Scr, Nsacr)) { if (isIntReg) { // This is a bit nasty, you would have thought that // DecodedBankedIntReg wouldn't be written to unless the // conditions on the IF statements above are met, however if // you look at the generated C code you'll find that they are. // However this is safe as DecodedBankedIntReg (which is used // in operands.isa to get the index of DecodedBankedIntReg) // will return INTREG_DUMMY if its not a valid integer // register, so redirecting the write to somewhere we don't // care about. DecodedBankedIntReg = Op1; } else { xc->setMiscReg(regIdx, Op1); } } else { return std::make_shared(machInst, false, mnemonic); } ''' msrBankedRegIop = InstObjParams("msr", "MsrBankedReg", "MsrRegOp", { "code": msrBankedRegCode, "predicate_test": predicateTest }, ["IsSerializeAfter", "IsNonSpeculative"]) header_output += MsrBankedRegDeclare.subst(msrBankedRegIop) decoder_output += MsrBankedRegConstructor.subst(msrBankedRegIop) exec_output += PredOpExecute.subst(msrBankedRegIop) msrCpsrRegCode = ''' SCTLR sctlr = Sctlr; CPSR old_cpsr = Cpsr; old_cpsr.nz = CondCodesNZ; old_cpsr.c = CondCodesC; old_cpsr.v = CondCodesV; old_cpsr.ge = CondCodesGE; CPSR new_cpsr = cpsrWriteByInstr(old_cpsr, Op1, Scr, Nsacr, byteMask, false, sctlr.nmfi, xc->tcBase()); Cpsr = ~CondCodesMask & new_cpsr; CondCodesNZ = new_cpsr.nz; CondCodesC = new_cpsr.c; CondCodesV = new_cpsr.v; CondCodesGE = new_cpsr.ge; ''' msrCpsrRegIop = InstObjParams("msr", "MsrCpsrReg", "MsrRegOp", { "code": msrCpsrRegCode, "predicate_test": condPredicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += MsrRegDeclare.subst(msrCpsrRegIop) decoder_output += MsrRegConstructor.subst(msrCpsrRegIop) exec_output += PredOpExecute.subst(msrCpsrRegIop) msrSpsrRegCode = "Spsr = spsrWriteByInstr(Spsr, Op1, byteMask, false);" msrSpsrRegIop = InstObjParams("msr", "MsrSpsrReg", "MsrRegOp", { "code": msrSpsrRegCode, "predicate_test": predicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += MsrRegDeclare.subst(msrSpsrRegIop) decoder_output += MsrRegConstructor.subst(msrSpsrRegIop) exec_output += PredOpExecute.subst(msrSpsrRegIop) msrCpsrImmCode = ''' SCTLR sctlr = Sctlr; CPSR old_cpsr = Cpsr; old_cpsr.nz = CondCodesNZ; old_cpsr.c = CondCodesC; old_cpsr.v = CondCodesV; old_cpsr.ge = CondCodesGE; CPSR new_cpsr = cpsrWriteByInstr(old_cpsr, imm, Scr, Nsacr, byteMask, false, sctlr.nmfi, xc->tcBase()); Cpsr = ~CondCodesMask & new_cpsr; CondCodesNZ = new_cpsr.nz; CondCodesC = new_cpsr.c; CondCodesV = new_cpsr.v; CondCodesGE = new_cpsr.ge; ''' msrCpsrImmIop = InstObjParams("msr", "MsrCpsrImm", "MsrImmOp", { "code": msrCpsrImmCode, "predicate_test": condPredicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += MsrImmDeclare.subst(msrCpsrImmIop) decoder_output += MsrImmConstructor.subst(msrCpsrImmIop) exec_output += PredOpExecute.subst(msrCpsrImmIop) msrSpsrImmCode = "Spsr = spsrWriteByInstr(Spsr, imm, byteMask, false);" msrSpsrImmIop = InstObjParams("msr", "MsrSpsrImm", "MsrImmOp", { "code": msrSpsrImmCode, "predicate_test": predicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += MsrImmDeclare.subst(msrSpsrImmIop) decoder_output += MsrImmConstructor.subst(msrSpsrImmIop) exec_output += PredOpExecute.subst(msrSpsrImmIop) revCode = ''' uint32_t val = Op1; Dest = swap_byte(val); ''' revIop = InstObjParams("rev", "Rev", "RegRegOp", { "code": revCode, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(revIop) decoder_output += RegRegOpConstructor.subst(revIop) exec_output += PredOpExecute.subst(revIop) rev16Code = ''' uint32_t val = Op1; Dest = (bits(val, 15, 8) << 0) | (bits(val, 7, 0) << 8) | (bits(val, 31, 24) << 16) | (bits(val, 23, 16) << 24); ''' rev16Iop = InstObjParams("rev16", "Rev16", "RegRegOp", { "code": rev16Code, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(rev16Iop) decoder_output += RegRegOpConstructor.subst(rev16Iop) exec_output += PredOpExecute.subst(rev16Iop) revshCode = ''' uint16_t val = Op1; Dest = sext<16>(swap_byte(val)); ''' revshIop = InstObjParams("revsh", "Revsh", "RegRegOp", { "code": revshCode, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(revshIop) decoder_output += RegRegOpConstructor.subst(revshIop) exec_output += PredOpExecute.subst(revshIop) rbitCode = ''' Dest = reverseBits(Op1); ''' rbitIop = InstObjParams("rbit", "Rbit", "RegRegOp", { "code": rbitCode, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(rbitIop) decoder_output += RegRegOpConstructor.subst(rbitIop) exec_output += PredOpExecute.subst(rbitIop) clzCode = ''' Dest = (Op1 == 0) ? 32 : (31 - findMsbSet(Op1)); ''' clzIop = InstObjParams("clz", "Clz", "RegRegOp", { "code": clzCode, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(clzIop) decoder_output += RegRegOpConstructor.subst(clzIop) exec_output += PredOpExecute.subst(clzIop) ssatCode = ''' int32_t operand = shift_rm_imm(Op1, shiftAmt, shiftType, 0); int32_t res; if (satInt(res, operand, imm)) CpsrQ = 1 << 27; Dest = res; ''' ssatIop = InstObjParams("ssat", "Ssat", "RegImmRegShiftOp", { "code": ssatCode, "predicate_test": pickPredicate(ssatCode) }, []) header_output += RegImmRegShiftOpDeclare.subst(ssatIop) decoder_output += RegImmRegShiftOpConstructor.subst(ssatIop) exec_output += PredOpExecute.subst(ssatIop) usatCode = ''' int32_t operand = shift_rm_imm(Op1, shiftAmt, shiftType, 0); int32_t res; if (uSatInt(res, operand, imm)) CpsrQ = 1 << 27; Dest = res; ''' usatIop = InstObjParams("usat", "Usat", "RegImmRegShiftOp", { "code": usatCode, "predicate_test": pickPredicate(usatCode) }, []) header_output += RegImmRegShiftOpDeclare.subst(usatIop) decoder_output += RegImmRegShiftOpConstructor.subst(usatIop) exec_output += PredOpExecute.subst(usatIop) ssat16Code = ''' int32_t res; uint32_t resTemp = 0; int32_t argLow = sext<16>(bits(Op1, 15, 0)); int32_t argHigh = sext<16>(bits(Op1, 31, 16)); if (satInt(res, argLow, imm)) CpsrQ = 1 << 27; replaceBits(resTemp, 15, 0, res); if (satInt(res, argHigh, imm)) CpsrQ = 1 << 27; replaceBits(resTemp, 31, 16, res); Dest = resTemp; ''' ssat16Iop = InstObjParams("ssat16", "Ssat16", "RegImmRegOp", { "code": ssat16Code, "predicate_test": pickPredicate(ssat16Code) }, []) header_output += RegImmRegOpDeclare.subst(ssat16Iop) decoder_output += RegImmRegOpConstructor.subst(ssat16Iop) exec_output += PredOpExecute.subst(ssat16Iop) usat16Code = ''' int32_t res; uint32_t resTemp = 0; int32_t argLow = sext<16>(bits(Op1, 15, 0)); int32_t argHigh = sext<16>(bits(Op1, 31, 16)); if (uSatInt(res, argLow, imm)) CpsrQ = 1 << 27; replaceBits(resTemp, 15, 0, res); if (uSatInt(res, argHigh, imm)) CpsrQ = 1 << 27; replaceBits(resTemp, 31, 16, res); Dest = resTemp; ''' usat16Iop = InstObjParams("usat16", "Usat16", "RegImmRegOp", { "code": usat16Code, "predicate_test": pickPredicate(usat16Code) }, []) header_output += RegImmRegOpDeclare.subst(usat16Iop) decoder_output += RegImmRegOpConstructor.subst(usat16Iop) exec_output += PredOpExecute.subst(usat16Iop) sxtbIop = InstObjParams("sxtb", "Sxtb", "RegImmRegOp", { "code": "Dest = sext<8>((uint8_t)(Op1_ud >> imm));", "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(sxtbIop) decoder_output += RegImmRegOpConstructor.subst(sxtbIop) exec_output += PredOpExecute.subst(sxtbIop) sxtabIop = InstObjParams("sxtab", "Sxtab", "RegRegRegImmOp", { "code": ''' Dest = sext<8>((uint8_t)(Op2_ud >> imm)) + Op1; ''', "predicate_test": predicateTest }, []) header_output += RegRegRegImmOpDeclare.subst(sxtabIop) decoder_output += RegRegRegImmOpConstructor.subst(sxtabIop) exec_output += PredOpExecute.subst(sxtabIop) sxtb16Code = ''' uint32_t resTemp = 0; replaceBits(resTemp, 15, 0, sext<8>(bits(Op1, imm + 7, imm))); replaceBits(resTemp, 31, 16, sext<8>(bits(Op1, (imm + 23) % 32, (imm + 16) % 32))); Dest = resTemp; ''' sxtb16Iop = InstObjParams("sxtb16", "Sxtb16", "RegImmRegOp", { "code": sxtb16Code, "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(sxtb16Iop) decoder_output += RegImmRegOpConstructor.subst(sxtb16Iop) exec_output += PredOpExecute.subst(sxtb16Iop) sxtab16Code = ''' uint32_t resTemp = 0; replaceBits(resTemp, 15, 0, sext<8>(bits(Op2, imm + 7, imm)) + bits(Op1, 15, 0)); replaceBits(resTemp, 31, 16, sext<8>(bits(Op2, (imm + 23) % 32, (imm + 16) % 32)) + bits(Op1, 31, 16)); Dest = resTemp; ''' sxtab16Iop = InstObjParams("sxtab16", "Sxtab16", "RegRegRegImmOp", { "code": sxtab16Code, "predicate_test": predicateTest }, []) header_output += RegRegRegImmOpDeclare.subst(sxtab16Iop) decoder_output += RegRegRegImmOpConstructor.subst(sxtab16Iop) exec_output += PredOpExecute.subst(sxtab16Iop) sxthCode = ''' uint64_t rotated = (uint32_t)Op1; rotated = (rotated | (rotated << 32)) >> imm; Dest = sext<16>((uint16_t)rotated); ''' sxthIop = InstObjParams("sxth", "Sxth", "RegImmRegOp", { "code": sxthCode, "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(sxthIop) decoder_output += RegImmRegOpConstructor.subst(sxthIop) exec_output += PredOpExecute.subst(sxthIop) sxtahCode = ''' uint64_t rotated = (uint32_t)Op2; rotated = (rotated | (rotated << 32)) >> imm; Dest = sext<16>((uint16_t)rotated) + Op1; ''' sxtahIop = InstObjParams("sxtah", "Sxtah", "RegRegRegImmOp", { "code": sxtahCode, "predicate_test": predicateTest }, []) header_output += RegRegRegImmOpDeclare.subst(sxtahIop) decoder_output += RegRegRegImmOpConstructor.subst(sxtahIop) exec_output += PredOpExecute.subst(sxtahIop) uxtbIop = InstObjParams("uxtb", "Uxtb", "RegImmRegOp", { "code": "Dest = (uint8_t)(Op1_ud >> imm);", "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(uxtbIop) decoder_output += RegImmRegOpConstructor.subst(uxtbIop) exec_output += PredOpExecute.subst(uxtbIop) uxtabIop = InstObjParams("uxtab", "Uxtab", "RegRegRegImmOp", { "code": "Dest = (uint8_t)(Op2_ud >> imm) + Op1;", "predicate_test": predicateTest }, []) header_output += RegRegRegImmOpDeclare.subst(uxtabIop) decoder_output += RegRegRegImmOpConstructor.subst(uxtabIop) exec_output += PredOpExecute.subst(uxtabIop) uxtb16Code = ''' uint32_t resTemp = 0; replaceBits(resTemp, 15, 0, (uint8_t)(bits(Op1, imm + 7, imm))); replaceBits(resTemp, 31, 16, (uint8_t)(bits(Op1, (imm + 23) % 32, (imm + 16) % 32))); Dest = resTemp; ''' uxtb16Iop = InstObjParams("uxtb16", "Uxtb16", "RegImmRegOp", { "code": uxtb16Code, "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(uxtb16Iop) decoder_output += RegImmRegOpConstructor.subst(uxtb16Iop) exec_output += PredOpExecute.subst(uxtb16Iop) uxtab16Code = ''' uint32_t resTemp = 0; replaceBits(resTemp, 15, 0, (uint8_t)(bits(Op2, imm + 7, imm)) + bits(Op1, 15, 0)); replaceBits(resTemp, 31, 16, (uint8_t)(bits(Op2, (imm + 23) % 32, (imm + 16) % 32)) + bits(Op1, 31, 16)); Dest = resTemp; ''' uxtab16Iop = InstObjParams("uxtab16", "Uxtab16", "RegRegRegImmOp", { "code": uxtab16Code, "predicate_test": predicateTest }, []) header_output += RegRegRegImmOpDeclare.subst(uxtab16Iop) decoder_output += RegRegRegImmOpConstructor.subst(uxtab16Iop) exec_output += PredOpExecute.subst(uxtab16Iop) uxthCode = ''' uint64_t rotated = (uint32_t)Op1; rotated = (rotated | (rotated << 32)) >> imm; Dest = (uint16_t)rotated; ''' uxthIop = InstObjParams("uxth", "Uxth", "RegImmRegOp", { "code": uxthCode, "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(uxthIop) decoder_output += RegImmRegOpConstructor.subst(uxthIop) exec_output += PredOpExecute.subst(uxthIop) uxtahCode = ''' uint64_t rotated = (uint32_t)Op2; rotated = (rotated | (rotated << 32)) >> imm; Dest = (uint16_t)rotated + Op1; ''' uxtahIop = InstObjParams("uxtah", "Uxtah", "RegRegRegImmOp", { "code": uxtahCode, "predicate_test": predicateTest }, []) header_output += RegRegRegImmOpDeclare.subst(uxtahIop) decoder_output += RegRegRegImmOpConstructor.subst(uxtahIop) exec_output += PredOpExecute.subst(uxtahIop) selCode = ''' uint32_t resTemp = 0; for (unsigned i = 0; i < 4; i++) { int low = i * 8; int high = low + 7; replaceBits(resTemp, high, low, bits(CondCodesGE, i) ? bits(Op1, high, low) : bits(Op2, high, low)); } Dest = resTemp; ''' selIop = InstObjParams("sel", "Sel", "RegRegRegOp", { "code": selCode, "predicate_test": predicateTest }, []) header_output += RegRegRegOpDeclare.subst(selIop) decoder_output += RegRegRegOpConstructor.subst(selIop) exec_output += PredOpExecute.subst(selIop) usad8Code = ''' uint32_t resTemp = 0; for (unsigned i = 0; i < 4; i++) { int low = i * 8; int high = low + 7; int32_t diff = bits(Op1, high, low) - bits(Op2, high, low); resTemp += ((diff < 0) ? -diff : diff); } Dest = resTemp; ''' usad8Iop = InstObjParams("usad8", "Usad8", "RegRegRegOp", { "code": usad8Code, "predicate_test": predicateTest }, []) header_output += RegRegRegOpDeclare.subst(usad8Iop) decoder_output += RegRegRegOpConstructor.subst(usad8Iop) exec_output += PredOpExecute.subst(usad8Iop) usada8Code = ''' uint32_t resTemp = 0; for (unsigned i = 0; i < 4; i++) { int low = i * 8; int high = low + 7; int32_t diff = bits(Op1, high, low) - bits(Op2, high, low); resTemp += ((diff < 0) ? -diff : diff); } Dest = Op3 + resTemp; ''' usada8Iop = InstObjParams("usada8", "Usada8", "RegRegRegRegOp", { "code": usada8Code, "predicate_test": predicateTest }, []) header_output += RegRegRegRegOpDeclare.subst(usada8Iop) decoder_output += RegRegRegRegOpConstructor.subst(usada8Iop) exec_output += PredOpExecute.subst(usada8Iop) bkptCode = ''' uint16_t imm16; if (!machInst.thumb) imm16 = ((bits(machInst, 19, 8) << 4) | bits(machInst, 3, 0)); else imm16 = bits(machInst, 7, 0); return softwareBreakpoint32(xc, imm16); ''' bkptIop = InstObjParams("bkpt", "BkptInst", "PredOp", bkptCode) header_output += BasicDeclare.subst(bkptIop) decoder_output += BasicConstructor.subst(bkptIop) exec_output += BasicExecute.subst(bkptIop) nopIop = InstObjParams("nop", "NopInst", "ArmStaticInst", "", ['IsNop']) header_output += BasicDeclare.subst(nopIop) decoder_output += BasicConstructor64.subst(nopIop) exec_output += BasicExecute.subst(nopIop) yieldIop = InstObjParams("yield", "YieldInst", "PredOp", \ { "code" : "", "predicate_test" : predicateTest }) header_output += BasicDeclare.subst(yieldIop) decoder_output += BasicConstructor.subst(yieldIop) exec_output += PredOpExecute.subst(yieldIop) wfeCode = ''' CPSR cpsr = Cpsr; SCR scr = Scr64; // WFE Sleeps if SevMailbox==0 and no unmasked interrupts are pending, ThreadContext *tc = xc->tcBase(); if (SevMailbox == 1) { SevMailbox = 0; PseudoInst::quiesceSkip(tc); } else if (tc->getCpuPtr()->getInterruptController( tc->threadId())->checkInterrupts(tc)) { PseudoInst::quiesceSkip(tc); } else { fault = trapWFx(tc, cpsr, scr, true); if (fault == NoFault) { PseudoInst::quiesce(tc); } else { PseudoInst::quiesceSkip(tc); } } ''' wfePredFixUpCode = ''' // WFE is predicated false, reset SevMailbox to reduce spurious sleeps // and SEV interrupts SevMailbox = 1; ''' wfeIop = InstObjParams("wfe", "WfeInst", "PredOp", \ { "code" : wfeCode, "pred_fixup" : wfePredFixUpCode, "predicate_test" : predicateTest }, ["IsNonSpeculative", "IsQuiesce", "IsSerializeAfter", "IsUnverifiable"]) header_output += BasicDeclare.subst(wfeIop) decoder_output += BasicConstructor.subst(wfeIop) exec_output += QuiescePredOpExecuteWithFixup.subst(wfeIop) wfiCode = ''' HCR hcr = Hcr; CPSR cpsr = Cpsr; SCR scr = Scr64; // WFI doesn't sleep if interrupts are pending (masked or not) ThreadContext *tc = xc->tcBase(); if (tc->getCpuPtr()->getInterruptController( tc->threadId())->checkWfiWake(hcr, cpsr, scr)) { PseudoInst::quiesceSkip(tc); } else { fault = trapWFx(tc, cpsr, scr, false); if (fault == NoFault) { PseudoInst::quiesce(tc); } else { PseudoInst::quiesceSkip(tc); } } tc->getCpuPtr()->clearInterrupt(tc->threadId(), INT_ABT, 0); ''' wfiIop = InstObjParams("wfi", "WfiInst", "PredOp", \ { "code" : wfiCode, "predicate_test" : predicateTest }, ["IsNonSpeculative", "IsQuiesce", "IsSerializeAfter", "IsUnverifiable"]) header_output += BasicDeclare.subst(wfiIop) decoder_output += BasicConstructor.subst(wfiIop) exec_output += QuiescePredOpExecute.subst(wfiIop) sevCode = ''' SevMailbox = 1; System *sys = xc->tcBase()->getSystemPtr(); for (int x = 0; x < sys->numContexts(); x++) { ThreadContext *oc = sys->getThreadContext(x); if (oc == xc->tcBase()) continue; // Wake CPU with interrupt if they were sleeping if (oc->readMiscReg(MISCREG_SEV_MAILBOX) == 0) { // Post Interrupt and wake cpu if needed oc->getCpuPtr()->postInterrupt(oc->threadId(), INT_SEV, 0); } } ''' sevIop = InstObjParams("sev", "SevInst", "PredOp", \ { "code" : sevCode, "predicate_test" : predicateTest }, ["IsNonSpeculative", "IsSquashAfter", "IsUnverifiable"]) header_output += BasicDeclare.subst(sevIop) decoder_output += BasicConstructor.subst(sevIop) exec_output += PredOpExecute.subst(sevIop) sevlCode = ''' SevMailbox = 1; ''' sevlIop = InstObjParams("sevl", "SevlInst", "PredOp", \ { "code" : sevlCode, "predicate_test" : predicateTest }, ["IsNonSpeculative", "IsSquashAfter", "IsUnverifiable"]) header_output += BasicDeclare.subst(sevlIop) decoder_output += BasicConstructor.subst(sevlIop) exec_output += BasicExecute.subst(sevlIop) itIop = InstObjParams("it", "ItInst", "PredOp", \ { "code" : ";", "predicate_test" : predicateTest }, []) header_output += BasicDeclare.subst(itIop) decoder_output += BasicConstructor.subst(itIop) exec_output += PredOpExecute.subst(itIop) unknownCode = ''' return std::make_shared(machInst, true); ''' unknownIop = InstObjParams("unknown", "Unknown", "UnknownOp", \ { "code": unknownCode, "predicate_test": predicateTest }) header_output += BasicDeclare.subst(unknownIop) decoder_output += BasicConstructor.subst(unknownIop) exec_output += PredOpExecute.subst(unknownIop) ubfxCode = ''' Dest = bits(Op1, imm2, imm1); ''' ubfxIop = InstObjParams("ubfx", "Ubfx", "RegRegImmImmOp", { "code": ubfxCode, "predicate_test": predicateTest }, []) header_output += RegRegImmImmOpDeclare.subst(ubfxIop) decoder_output += RegRegImmImmOpConstructor.subst(ubfxIop) exec_output += PredOpExecute.subst(ubfxIop) sbfxCode = ''' int32_t resTemp = bits(Op1, imm2, imm1); Dest = resTemp | -(resTemp & (1 << (imm2 - imm1))); ''' sbfxIop = InstObjParams("sbfx", "Sbfx", "RegRegImmImmOp", { "code": sbfxCode, "predicate_test": predicateTest }, []) header_output += RegRegImmImmOpDeclare.subst(sbfxIop) decoder_output += RegRegImmImmOpConstructor.subst(sbfxIop) exec_output += PredOpExecute.subst(sbfxIop) bfcCode = ''' Dest = Op1 & ~(mask(imm2 - imm1 + 1) << imm1); ''' bfcIop = InstObjParams("bfc", "Bfc", "RegRegImmImmOp", { "code": bfcCode, "predicate_test": predicateTest }, []) header_output += RegRegImmImmOpDeclare.subst(bfcIop) decoder_output += RegRegImmImmOpConstructor.subst(bfcIop) exec_output += PredOpExecute.subst(bfcIop) bfiCode = ''' uint32_t bitMask = (mask(imm2 - imm1 + 1) << imm1); Dest = ((Op1 << imm1) & bitMask) | (Dest & ~bitMask); ''' bfiIop = InstObjParams("bfi", "Bfi", "RegRegImmImmOp", { "code": bfiCode, "predicate_test": predicateTest }, []) header_output += RegRegImmImmOpDeclare.subst(bfiIop) decoder_output += RegRegImmImmOpConstructor.subst(bfiIop) exec_output += PredOpExecute.subst(bfiIop) mrc14code = ''' MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId( RegId(MiscRegClass, op1)).index(); bool can_read, undefined; std::tie(can_read, undefined) = canReadCoprocReg(miscReg, Scr, Cpsr); if (!can_read || undefined) { return std::make_shared(machInst, false, mnemonic); } if (mcrMrc14TrapToHyp((MiscRegIndex) op1, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm)) { return std::make_shared(machInst, imm, EC_TRAPPED_CP14_MCR_MRC); } Dest = MiscOp1; ''' mrc14Iop = InstObjParams("mrc", "Mrc14", "RegMiscRegImmOp", { "code": mrc14code, "predicate_test": predicateTest }, []) header_output += RegMiscRegImmOpDeclare.subst(mrc14Iop) decoder_output += RegMiscRegImmOpConstructor.subst(mrc14Iop) exec_output += PredOpExecute.subst(mrc14Iop) mcr14code = ''' MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId( RegId(MiscRegClass, dest)).index(); bool can_write, undefined; std::tie(can_write, undefined) = canWriteCoprocReg(miscReg, Scr, Cpsr); if (undefined || !can_write) { return std::make_shared(machInst, false, mnemonic); } if (mcrMrc14TrapToHyp(miscReg, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm)) { return std::make_shared(machInst, imm, EC_TRAPPED_CP14_MCR_MRC); } MiscDest = Op1; ''' mcr14Iop = InstObjParams("mcr", "Mcr14", "MiscRegRegImmOp", { "code": mcr14code, "predicate_test": predicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += MiscRegRegImmOpDeclare.subst(mcr14Iop) decoder_output += MiscRegRegImmOpConstructor.subst(mcr14Iop) exec_output += PredOpExecute.subst(mcr14Iop) mrc15code = ''' int preFlatOp1 = snsBankedIndex(op1, xc->tcBase()); MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId(RegId(MiscRegClass, preFlatOp1)).index(); bool hypTrap = mcrMrc15TrapToHyp(miscReg, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm); bool can_read, undefined; std::tie(can_read, undefined) = canReadCoprocReg(miscReg, Scr, Cpsr); // if we're in non secure PL1 mode then we can trap regargless of whether // the register is accessable, in other modes we trap if only if the register // IS accessable. if (undefined || (!can_read && !(hypTrap && !inUserMode(Cpsr) && !inSecureState(Scr, Cpsr)))) { return std::make_shared(machInst, false, mnemonic); } if (hypTrap) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCR_MRC); } Dest = MiscNsBankedOp1; ''' mrc15Iop = InstObjParams("mrc", "Mrc15", "RegMiscRegImmOp", { "code": mrc15code, "predicate_test": predicateTest }, []) header_output += RegMiscRegImmOpDeclare.subst(mrc15Iop) decoder_output += RegMiscRegImmOpConstructor.subst(mrc15Iop) exec_output += PredOpExecute.subst(mrc15Iop) mcr15code = ''' int preFlatDest = snsBankedIndex(dest, xc->tcBase()); MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId(RegId(MiscRegClass, preFlatDest)).index(); bool hypTrap = mcrMrc15TrapToHyp(miscReg, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm); bool can_write, undefined; std::tie(can_write, undefined) = canWriteCoprocReg(miscReg, Scr, Cpsr); // if we're in non secure PL1 mode then we can trap regargless of whether // the register is accessable, in other modes we trap if only if the register // IS accessable. if (undefined || (!can_write && !(hypTrap && !inUserMode(Cpsr) && !inSecureState(Scr, Cpsr)))) { return std::make_shared(machInst, false, mnemonic); } if (hypTrap) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCR_MRC); } MiscNsBankedDest = Op1; ''' mcr15Iop = InstObjParams("mcr", "Mcr15", "MiscRegRegImmOp", { "code": mcr15code, "predicate_test": predicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += MiscRegRegImmOpDeclare.subst(mcr15Iop) decoder_output += MiscRegRegImmOpConstructor.subst(mcr15Iop) exec_output += PredOpExecute.subst(mcr15Iop) mrrc15code = ''' int preFlatOp1 = snsBankedIndex(op1, xc->tcBase()); MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId(RegId(MiscRegClass, preFlatOp1)).index(); bool hypTrap = mcrrMrrc15TrapToHyp(miscReg, Cpsr, Scr, Hstr, Hcr, imm); bool can_read, undefined; std::tie(can_read, undefined) = canReadCoprocReg(miscReg, Scr, Cpsr); // if we're in non secure PL1 mode then we can trap regargless of whether // the register is accessable, in other modes we trap if only if the register // IS accessable. if (undefined || (!can_read && !(hypTrap && !inUserMode(Cpsr) && !inSecureState(Scr, Cpsr)))) { return std::make_shared(machInst, false, mnemonic); } if (hypTrap) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCRR_MRRC); } Dest = bits(MiscNsBankedOp164, 63, 32); Dest2 = bits(MiscNsBankedOp164, 31, 0); ''' mrrc15Iop = InstObjParams("mrrc", "Mrrc15", "MrrcOp", { "code": mrrc15code, "predicate_test": predicateTest }, []) header_output += MrrcOpDeclare.subst(mrrc15Iop) decoder_output += MrrcOpConstructor.subst(mrrc15Iop) exec_output += PredOpExecute.subst(mrrc15Iop) mcrr15code = ''' int preFlatDest = snsBankedIndex(dest, xc->tcBase()); MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId(RegId(MiscRegClass, preFlatDest)).index(); bool hypTrap = mcrrMrrc15TrapToHyp(miscReg, Cpsr, Scr, Hstr, Hcr, imm); bool can_write, undefined; std::tie(can_write, undefined) = canWriteCoprocReg(miscReg, Scr, Cpsr); // if we're in non secure PL1 mode then we can trap regargless of whether // the register is accessable, in other modes we trap if only if the register // IS accessable. if (undefined || (!can_write && !(hypTrap && !inUserMode(Cpsr) && !inSecureState(Scr, Cpsr)))) { return std::make_shared(machInst, false, mnemonic); } if (hypTrap) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCRR_MRRC); } MiscNsBankedDest64 = ((uint64_t) Op1 << 32) | Op2; ''' mcrr15Iop = InstObjParams("mcrr", "Mcrr15", "McrrOp", { "code": mcrr15code, "predicate_test": predicateTest }, []) header_output += McrrOpDeclare.subst(mcrr15Iop) decoder_output += McrrOpConstructor.subst(mcrr15Iop) exec_output += PredOpExecute.subst(mcrr15Iop) enterxCode = ''' NextThumb = true; NextJazelle = true; ''' enterxIop = InstObjParams("enterx", "Enterx", "PredOp", { "code": enterxCode, "predicate_test": predicateTest }, []) header_output += BasicDeclare.subst(enterxIop) decoder_output += BasicConstructor.subst(enterxIop) exec_output += PredOpExecute.subst(enterxIop) leavexCode = ''' NextThumb = true; NextJazelle = false; ''' leavexIop = InstObjParams("leavex", "Leavex", "PredOp", { "code": leavexCode, "predicate_test": predicateTest }, []) header_output += BasicDeclare.subst(leavexIop) decoder_output += BasicConstructor.subst(leavexIop) exec_output += PredOpExecute.subst(leavexIop) setendCode = ''' CPSR cpsr = Cpsr; cpsr.e = imm; Cpsr = cpsr; fault = checkSETENDEnabled(xc->tcBase(), cpsr); ''' setendIop = InstObjParams("setend", "Setend", "ImmOp", { "code": setendCode, "predicate_test": predicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += ImmOpDeclare.subst(setendIop) decoder_output += ImmOpConstructor.subst(setendIop) exec_output += PredOpExecute.subst(setendIop) clrexCode = ''' LLSCLock = 0; ''' clrexIop = InstObjParams("clrex", "Clrex","PredOp", { "code": clrexCode, "predicate_test": predicateTest },[]) header_output += BasicDeclare.subst(clrexIop) decoder_output += BasicConstructor.subst(clrexIop) exec_output += PredOpExecute.subst(clrexIop) McrDcCheckCode = ''' int preFlatDest = snsBankedIndex(dest, xc->tcBase()); MiscRegIndex miscReg = (MiscRegIndex) xc->tcBase()->flattenRegId( RegId(MiscRegClass, preFlatDest)).index(); bool hypTrap = mcrMrc15TrapToHyp(miscReg, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm); bool can_write, undefined; std::tie(can_write, undefined) = canWriteCoprocReg(miscReg, Scr, Cpsr); // if we're in non secure PL1 mode then we can trap regardless // of whether the register is accessible, in other modes we // trap if only if the register IS accessible. if (undefined || (!can_write & !(hypTrap & !inUserMode(Cpsr) & !inSecureState(Scr, Cpsr)))) { return std::make_shared(machInst, false, mnemonic); } if (hypTrap) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCR_MRC); } ''' McrDcimvacCode = ''' const Request::Flags memAccessFlags(ArmISA::TLB::MustBeOne | Request::INVALIDATE | Request::DST_POC); EA = Op1; ''' McrDcimvacIop = InstObjParams("mcr", "McrDcimvac", "MiscRegRegImmOp", {"memacc_code": McrDcCheckCode, "postacc_code": "", "ea_code": McrDcimvacCode, "predicate_test": predicateTest}, ['IsMemRef', 'IsStore']) header_output += MiscRegRegImmMemOpDeclare.subst(McrDcimvacIop) decoder_output += MiscRegRegImmOpConstructor.subst(McrDcimvacIop) exec_output += Mcr15Execute.subst(McrDcimvacIop) + \ Mcr15InitiateAcc.subst(McrDcimvacIop) + \ Mcr15CompleteAcc.subst(McrDcimvacIop) McrDccmvacCode = ''' const Request::Flags memAccessFlags(ArmISA::TLB::MustBeOne | Request::CLEAN | Request::DST_POC); EA = Op1; ''' McrDccmvacIop = InstObjParams("mcr", "McrDccmvac", "MiscRegRegImmOp", {"memacc_code": McrDcCheckCode, "postacc_code": "", "ea_code": McrDccmvacCode, "predicate_test": predicateTest}, ['IsMemRef', 'IsStore']) header_output += MiscRegRegImmMemOpDeclare.subst(McrDccmvacIop) decoder_output += MiscRegRegImmOpConstructor.subst(McrDccmvacIop) exec_output += Mcr15Execute.subst(McrDccmvacIop) + \ Mcr15InitiateAcc.subst(McrDccmvacIop) + \ Mcr15CompleteAcc.subst(McrDccmvacIop) McrDccmvauCode = ''' const Request::Flags memAccessFlags(ArmISA::TLB::MustBeOne | Request::CLEAN | Request::DST_POU); EA = Op1; ''' McrDccmvauIop = InstObjParams("mcr", "McrDccmvau", "MiscRegRegImmOp", {"memacc_code": McrDcCheckCode, "postacc_code": "", "ea_code": McrDccmvauCode, "predicate_test": predicateTest}, ['IsMemRef', 'IsStore']) header_output += MiscRegRegImmMemOpDeclare.subst(McrDccmvauIop) decoder_output += MiscRegRegImmOpConstructor.subst(McrDccmvauIop) exec_output += Mcr15Execute.subst(McrDccmvauIop) + \ Mcr15InitiateAcc.subst(McrDccmvauIop) + \ Mcr15CompleteAcc.subst(McrDccmvauIop) McrDccimvacCode = ''' const Request::Flags memAccessFlags(ArmISA::TLB::MustBeOne | Request::CLEAN | Request::INVALIDATE | Request::DST_POC); EA = Op1; ''' McrDccimvacIop = InstObjParams("mcr", "McrDccimvac", "MiscRegRegImmOp", {"memacc_code": McrDcCheckCode, "postacc_code": "", "ea_code": McrDccimvacCode, "predicate_test": predicateTest}, ['IsMemRef', 'IsStore']) header_output += MiscRegRegImmMemOpDeclare.subst(McrDccimvacIop) decoder_output += MiscRegRegImmOpConstructor.subst(McrDccimvacIop) exec_output += Mcr15Execute.subst(McrDccimvacIop) + \ Mcr15InitiateAcc.subst(McrDccimvacIop) + \ Mcr15CompleteAcc.subst(McrDccimvacIop) isbCode = ''' // If the barrier is due to a CP15 access check for hyp traps if ((imm != 0) && mcrMrc15TrapToHyp(MISCREG_CP15ISB, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm)) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCR_MRC); } ''' isbIop = InstObjParams("isb", "Isb", "ImmOp", {"code": isbCode, "predicate_test": predicateTest}, ['IsSquashAfter']) header_output += ImmOpDeclare.subst(isbIop) decoder_output += ImmOpConstructor.subst(isbIop) exec_output += PredOpExecute.subst(isbIop) dsbCode = ''' // If the barrier is due to a CP15 access check for hyp traps if ((imm != 0) && mcrMrc15TrapToHyp(MISCREG_CP15DSB, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm)) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCR_MRC); } ''' dsbIop = InstObjParams("dsb", "Dsb", "ImmOp", {"code": dsbCode, "predicate_test": predicateTest}, ['IsMemBarrier', 'IsSerializeAfter']) header_output += ImmOpDeclare.subst(dsbIop) decoder_output += ImmOpConstructor.subst(dsbIop) exec_output += PredOpExecute.subst(dsbIop) dmbCode = ''' // If the barrier is due to a CP15 access check for hyp traps if ((imm != 0) && mcrMrc15TrapToHyp(MISCREG_CP15DMB, Hcr, Cpsr, Scr, Hdcr, Hstr, Hcptr, imm)) { return std::make_shared(machInst, imm, EC_TRAPPED_CP15_MCR_MRC); } ''' dmbIop = InstObjParams("dmb", "Dmb", "ImmOp", {"code": dmbCode, "predicate_test": predicateTest}, ['IsMemBarrier']) header_output += ImmOpDeclare.subst(dmbIop) decoder_output += ImmOpConstructor.subst(dmbIop) exec_output += PredOpExecute.subst(dmbIop) dbgCode = ''' ''' dbgIop = InstObjParams("dbg", "Dbg", "PredOp", {"code": dbgCode, "predicate_test": predicateTest}) header_output += BasicDeclare.subst(dbgIop) decoder_output += BasicConstructor.subst(dbgIop) exec_output += PredOpExecute.subst(dbgIop) cpsCode = ''' uint32_t mode = bits(imm, 4, 0); uint32_t f = bits(imm, 5); uint32_t i = bits(imm, 6); uint32_t a = bits(imm, 7); bool setMode = bits(imm, 8); bool enable = bits(imm, 9); CPSR cpsr = Cpsr; SCTLR sctlr = Sctlr; if (cpsr.mode != MODE_USER) { if (enable) { if (f) cpsr.f = 0; if (i) cpsr.i = 0; if (a) cpsr.a = 0; } else { if (f && !sctlr.nmfi) cpsr.f = 1; if (i) cpsr.i = 1; if (a) cpsr.a = 1; } if (setMode) { cpsr.mode = mode; } } Cpsr = cpsr; ''' cpsIop = InstObjParams("cps", "Cps", "ImmOp", { "code": cpsCode, "predicate_test": predicateTest }, ["IsSerializeAfter","IsNonSpeculative"]) header_output += ImmOpDeclare.subst(cpsIop) decoder_output += ImmOpConstructor.subst(cpsIop) exec_output += PredOpExecute.subst(cpsIop) }};