// -*- mode:c++ -*- // Copyright (c) 2010 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 = ''' #if FULL_SYSTEM fault = new SupervisorCall; #else fault = new SupervisorCall(machInst); #endif ''' svcIop = InstObjParams("svc", "Svc", "PredOp", { "code": svcCode, "predicate_test": predicateTest }, ["IsSyscall"]) header_output = BasicDeclare.subst(svcIop) decoder_output = BasicConstructor.subst(svcIop) exec_output = PredOpExecute.subst(svcIop) }}; let {{ header_output = decoder_output = exec_output = "" mrsCpsrCode = "Dest = (Cpsr | CondCodes) & 0xF8FF03DF" mrsCpsrIop = InstObjParams("mrs", "MrsCpsr", "MrsOp", { "code": mrsCpsrCode, "predicate_test": predicateTest }, []) 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 }, []) header_output += MrsDeclare.subst(mrsSpsrIop) decoder_output += MrsConstructor.subst(mrsSpsrIop) exec_output += PredOpExecute.subst(mrsSpsrIop) msrCpsrRegCode = ''' uint32_t newCpsr = cpsrWriteByInstr(Cpsr | CondCodes, Op1, byteMask, false); Cpsr = ~CondCodesMask & newCpsr; CondCodes = CondCodesMask & newCpsr; ''' msrCpsrRegIop = InstObjParams("msr", "MsrCpsrReg", "MsrRegOp", { "code": msrCpsrRegCode, "predicate_test": predicateTest }, []) 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 }, []) header_output += MsrRegDeclare.subst(msrSpsrRegIop) decoder_output += MsrRegConstructor.subst(msrSpsrRegIop) exec_output += PredOpExecute.subst(msrSpsrRegIop) msrCpsrImmCode = ''' uint32_t newCpsr = cpsrWriteByInstr(Cpsr | CondCodes, imm, byteMask, false); Cpsr = ~CondCodesMask & newCpsr; CondCodes = CondCodesMask & newCpsr; ''' msrCpsrImmIop = InstObjParams("msr", "MsrCpsrImm", "MsrImmOp", { "code": msrCpsrImmCode, "predicate_test": predicateTest }, []) 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 }, []) 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 = ''' uint8_t *opBytes = (uint8_t *)&Op1; uint32_t resTemp; uint8_t *destBytes = (uint8_t *)&resTemp; // This reverses the bytes and bits of the input, or so says the // internet. for (int i = 0; i < 4; i++) { uint32_t temp = opBytes[i]; temp = (temp * 0x0802 & 0x22110) | (temp * 0x8020 & 0x88440); destBytes[3 - i] = (temp * 0x10101) >> 16; } Dest = resTemp; ''' 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)) CondCodes = CondCodes | (1 << 27); else CondCodes = CondCodes; Dest = res; ''' ssatIop = InstObjParams("ssat", "Ssat", "RegImmRegShiftOp", { "code": ssatCode, "predicate_test": predicateTest }, []) 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)) CondCodes = CondCodes | (1 << 27); else CondCodes = CondCodes; Dest = res; ''' usatIop = InstObjParams("usat", "Usat", "RegImmRegShiftOp", { "code": usatCode, "predicate_test": predicateTest }, []) header_output += RegImmRegShiftOpDeclare.subst(usatIop) decoder_output += RegImmRegShiftOpConstructor.subst(usatIop) exec_output += PredOpExecute.subst(usatIop) ssat16Code = ''' int32_t res; uint32_t resTemp = 0; CondCodes = CondCodes; int32_t argLow = sext<16>(bits(Op1, 15, 0)); int32_t argHigh = sext<16>(bits(Op1, 31, 16)); if (satInt(res, argLow, imm)) CondCodes = CondCodes | (1 << 27); replaceBits(resTemp, 15, 0, res); if (satInt(res, argHigh, imm)) CondCodes = CondCodes | (1 << 27); replaceBits(resTemp, 31, 16, res); Dest = resTemp; ''' ssat16Iop = InstObjParams("ssat16", "Ssat16", "RegImmRegOp", { "code": ssat16Code, "predicate_test": predicateTest }, []) header_output += RegImmRegOpDeclare.subst(ssat16Iop) decoder_output += RegImmRegOpConstructor.subst(ssat16Iop) exec_output += PredOpExecute.subst(ssat16Iop) usat16Code = ''' int32_t res; uint32_t resTemp = 0; CondCodes = CondCodes; int32_t argLow = sext<16>(bits(Op1, 15, 0)); int32_t argHigh = sext<16>(bits(Op1, 31, 16)); if (uSatInt(res, argLow, imm)) CondCodes = CondCodes | (1 << 27); replaceBits(resTemp, 15, 0, res); if (uSatInt(res, argHigh, imm)) CondCodes = CondCodes | (1 << 27); replaceBits(resTemp, 31, 16, res); Dest = resTemp; ''' usat16Iop = InstObjParams("usat16", "Usat16", "RegImmRegOp", { "code": usat16Code, "predicate_test": predicateTest }, []) 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(CondCodes, 16 + 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) nopIop = InstObjParams("nop", "NopInst", "ArmStaticInst", "", []) header_output += BasicDeclare.subst(nopIop) decoder_output += BasicConstructor.subst(nopIop) exec_output += BasicExecute.subst(nopIop) 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) mrc15code = ''' CPSR cpsr = Cpsr; if (cpsr.mode == MODE_USER) #if FULL_SYSTEM return new UndefinedInstruction; #else return new UndefinedInstruction(false, mnemonic); #endif Dest = MiscOp1; ''' mrc15Iop = InstObjParams("mrc", "Mrc15", "RegRegOp", { "code": mrc15code, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(mrc15Iop) decoder_output += RegRegOpConstructor.subst(mrc15Iop) exec_output += PredOpExecute.subst(mrc15Iop) mcr15code = ''' CPSR cpsr = Cpsr; if (cpsr.mode == MODE_USER) #if FULL_SYSTEM return new UndefinedInstruction; #else return new UndefinedInstruction(false, mnemonic); #endif MiscDest = Op1; ''' mcr15Iop = InstObjParams("mcr", "Mcr15", "RegRegOp", { "code": mcr15code, "predicate_test": predicateTest }, []) header_output += RegRegOpDeclare.subst(mcr15Iop) decoder_output += RegRegOpConstructor.subst(mcr15Iop) exec_output += PredOpExecute.subst(mcr15Iop) enterxCode = ''' FNPC = NPC | (1ULL << PcJBitShift) | (1ULL << PcTBitShift); ''' 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 = ''' FNPC = (NPC & ~(1ULL << PcJBitShift)) | (1ULL << PcTBitShift); ''' 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; ''' setendIop = InstObjParams("setend", "Setend", "ImmOp", { "code": setendCode, "predicate_test": predicateTest }, []) header_output += ImmOpDeclare.subst(setendIop) decoder_output += ImmOpConstructor.subst(setendIop) exec_output += PredOpExecute.subst(setendIop) 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; 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) 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 }, []) header_output += ImmOpDeclare.subst(cpsIop) decoder_output += ImmOpConstructor.subst(cpsIop) exec_output += PredOpExecute.subst(cpsIop) }};