// // Instruction.hpp // Clock Signal // // Created by Thomas Harte on 15/01/21. // Copyright © 2021 Thomas Harte. All rights reserved. // #ifndef InstructionSets_PowerPC_Instruction_h #define InstructionSets_PowerPC_Instruction_h #include namespace InstructionSet { namespace PowerPC { enum class CacheLine: uint32_t { Instruction = 0b01100, Data = 0b1101, Minimum = 0b01110, Maximum = 0b01111, }; /// Provides the meaning of individual bits within the condition register; /// bits are counted in IBM/Motorola order, so *bit 0 is the most significant.* enum class Condition: uint32_t { // CR0 Negative = 0, // LT Positive = 1, // GT Zero = 2, // EQ SummaryOverflow = 3, // SO // CR1 FPException = 4, // FX FPEnabledException = 5, // FEX FPInvalidException = 6, // VX FPOverflowException = 7, // OX // CRs2–7 fill out the condition register. }; enum class BranchOption: uint32_t { // Naming convention: // // Dec_ prefix => decrement the CTR; // condition starting NotZero or Zero => test CTR; // condition ending Set or Clear => test the condition bit. Dec_NotZeroAndClear = 0b0000, Dec_ZeroAndClear = 0b0001, Clear = 0b0010, Dec_NotZeroAndSet = 0b0100, Dec_ZeroAndSet = 0b0101, Set = 0b0110, Dec_NotZero = 0b1000, Dec_Zero = 0b1001, Always = 0b1010, }; /// @returns @c 0 if reg == 0; @c ~0 otherwise. /// @discussion Provides a branchless way to substitute the value 0 for the value of r0 /// in affected instructions. Assumes arithmetic shifts. template constexpr IntT is_zero_mask(uint32_t reg) { return ~IntT((int(reg) - 1) >> 5); } enum class Operation: uint8_t { Undefined, // // MARK: - 601-exclusive instructions. // // A lot of them are carry-overs from POWER, left in place // due to the tight original development timeline. // // These are not part of the PowerPC architecture. /// Absolute. /// abs abs. abso abso. /// rD(), rA() [oe(), rc()] absx, /// Cache line compute size. /// clcs /// rD(), rA() clcs, /// Divide. /// div div. divo divo. /// rD(), rA(), rB() [rc(), oe()] divx, /// Divide short. /// divs divs. divso divso. /// rD(), rA(), rB() [rc(), eo()] divsx, /// Difference or zero. /// doz doz. dozo dozo. /// rD(), rA(), rB() [rc(), oe()] dozx, /// Difference or zero immediate. /// dozi /// rD(), rA(), simm() dozi, /// Load string and compare byte indexed. /// lscbx lsxbx. /// rD(), rA(), rB() [rc()] lscbxx, /// Mask generate. /// maskg maskg. /// rA(), rS(), rB() [rc()] maskgx, /// Mask insert from register. /// maskir maskir. /// rA(), rS(), rB() [rc()] maskirx, /// Multiply. /// mul mul. mulo mulo. /// rA(), rB(), rD() mulx, nabsx, rlmix, rribx, slex, sleqx, sliqx, slliqx, sllqx, slqx, sraiqx, sraqx, srex, sreax, sreqx, sriqx, srliqx, srlqx, srqx, // // MARK: - 32- and 64-bit PowerPC instructions. // /// Add. /// add add. addo addo. /// rD(), rA(), rB() [rc(), oe()] addx, /// Add carrying. /// addc addc. addco addco. /// rD(), rA(), rB() [rc(), oe()] addcx, /// Add extended. /// adde adde. addeo addeo. /// rD(), rA(), rB() [rc(), eo()] addex, /// Add immediate. /// addi /// rD(), rA(), simm() addi, /// Add immediate carrying. /// addic /// rD(), rA(), simm() addic, /// Add immediate carrying and record. /// addic. /// rD(), rA(), simm() addic_, /// Add immediate shifted. /// addis. /// rD(), rA(), simm() addis, /// Add to minus one. /// addme addme. addmeo addmeo. /// rD(), rA() [rc(), oe()] addmex, /// Add to zero extended. /// addze addze. addzeo addzeo. /// rD(), rA() [rc(), oe()] addzex, /// And. /// and, and. /// rA(), rS(), rB() [rc()] andx, /// And with complement. /// andc, andc. /// rA(), rS(), rB() [rc()] andcx, /// And immediate. /// andi. /// rA(), rS(), uimm() andi_, /// And immediate shifted. /// andis. /// rA(), rS(), uimm() andis_, /// Branch unconditional. /// b bl ba bla /// li() [aa(), lk()] bx, /// Branch conditional. /// bne bne+ beq bdnzt+ bdnzf bdnzt bdnzfla ... /// bo(), bi(), bd() [aa(), lk()] bcx, /// Branch conditional to count register. /// bctr bctrl bnectrl bnectrl bltctr blectr ... /// bo(), bi() [aa(), lk()] bcctrx, /// Branch conditional to link register. /// blr blrl bltlr blelrl bnelrl ... /// bo(), bi() [aa(), lk()] bclrx, /// Compare /// cmp /// crfD(), l(), rA(), rB() cmp, /// Compare immediate. /// cmpi /// crfD(), l(), rA(), simm() cmpi, /// Compare logical. /// cmpl /// crfD(), l(), rA(), rB() cmpl, /// Compare logical immediate. /// cmpli /// crfD(), l(), rA(), uimm() cmpli, /// Count leading zero words. /// cntlzw cntlzw. /// rA(), rS() [rc()] cntlzwx, /// Condition register and. /// crand /// crbD(), crbA(), crbB() crand, /// Condition register and with complement. /// crandc /// crbD(), crbA(), crbB() crandc, /// Condition register equivalent. /// creqv /// crbD(), crbA(), crbB() creqv, /// Condition register nand. /// crnand /// crbD(), crbA(), crbB() crnand, /// Condition register nor. /// crnor /// crbD(), crbA(), crbB() crnor, /// Condition register or. /// cror /// crbD(), crbA(), crbB() cror, /// Condition register or with complement. /// crorc /// crbD(), crbA(), crbB() crorc, /// Condition register xor. /// crxor /// crbD(), crbA(), crbB() crxor, /// Data cache block flush. /// dcbf /// rA(), rB() dcbf, /// Data cache block store. /// dcbst /// rA(), rB() dcbst, /// Data cache block touch. /// dcbt /// rA(), rB() dcbt, /// Data cache block touch for store. /// dcbtst /// rA(), rB() dcbtst, /// Data cache block set to zero. /// dcbz /// rA(), rB() dcbz, /// Divide word. /// divw divw. divwo divwo. /// rD(), rA(), rB() [rc(), oe()] divwx, /// Divide word unsigned. /// divwu divwu. divwuo divwuo. /// rD(), rA(), rB() [rc(), oe()] divwux, /// External control in word indexed. /// eciwx /// rD(), rA(), rB() eciwx, /// External control out word indexed. /// ecowx /// rS(), rA(), rB() ecowx, /// Enforce in-order execition of I/O /// eieio eieio, /// Equivalent. /// eqv eqv. /// rA(), rS(), rB() [rc()] eqvx, /// Extend sign byte. /// extsb extsb. /// rA(), rS() [rc()] extsbx, /// Extend sign half-word. /// extsh extsh. /// rA(), rS() [rc()] extshx, /// Floating point absolute. /// fabs fabs. /// frD(), frB() [rc()] fabsx, /// Floating point add. /// fadd fadd. /// frD(), frA(), frB() [rc()] faddx, /// Floating point add single precision. /// fadds fadds. /// frD(), frA(), frB() [rc()] faddsx, /// Floating point compare ordered. /// fcmpo /// crfD(), frA(), frB() fcmpo, /// Floating point compare unordered. /// fcmpu /// crfD(), frA(), frB() fcmpu, /// Floating point convert to integer word. /// fctiw fctiw. /// frD(), frB() [rc()] fctiwx, /// Floating point convert to integer word with round towards zero. /// fctiw fctiw. /// frD(), frB() [rc()] fctiwzx, /// Floating point divide. /// fdiv fdiv. /// frD(), frA(), frB() [rc()] fdivx, /// Floating point divide single precision. /// fdiv fdiv. /// frD(), frA(), frB() [rc()] fdivsx, /// Floating point multiply add. /// fmadd fmadd. /// frD(), frA(), frC(), frB() [rc()] fmaddx, /// Floating point multiply add single precision. /// fmadds fmadds. /// frD(), frA(), frC(), frB() [rc()] fmaddsx, /// Floating point register move. /// fmr fmr. /// frD(), frB() [rc()] fmrx, /// Floating point multiply subtract. /// fmsub fmsub. /// frD(), frA(), frC(), frB() [rc()] fmsubx, /// Floating point multiply subtract single precision. /// fmsubx fmsubx. /// frD(), frA(), frC(), frB() [rc()] fmsubsx, /// Floating point multiply. /// fmul fmul. /// frD(), frA(), frC() [rc()] fmulx, /// Floating point multiply single precision. /// fmuls fmuls. /// frD(), frA(), frC() [rc()] fmulsx, /// Floating negative absolute value. /// fnabs fnabs. /// frD(), frB() [rc()] fnabsx, /// Floating negative. /// fneg fneg. /// frD(), frB() [rc()] fnegx, /// Floating point negative multiply add. /// fnmadd fnmadd. /// frD(), frA(), frC(), frB() [rc()] fnmaddx, /// Floating point negative multiply add single precision. /// fnmadds fnmadds. /// frD(), frA(), frC(), frB() [rc()] fnmaddsx, /// Floating point negative multiply subtract. /// fnmsub fnmsub. /// frD(), frA(), frC(), frB() [rc()] fnmsubx, /// Floating point negative multiply add. /// fnmsubs fnmsubs. /// frD(), frA(), frC(), frB() [rc()] fnmsubsx, /// Floating point round to single precision. /// frsp frsp. /// frD(), frB() [rc()] frspx, fsubx, fsubsx, /// Instruction cache block invalidate. /// icbi /// rA(), rB() icbi, /// Instruction synchronise. /// isync isync, /// Load byte and zero. /// lbz /// rD(), d() [ rA() ] lbz, /// Load byte and zero with update. /// lbz /// rD(), d() [ rA() ] lbzu, /// Load byte and zero with update indexed. /// lbzux /// rD(), rA(), rB() lbzux, /// Load byte and zero indexed. /// lbzx /// rD(), rA(), rB() lbzx, /// Load floating point double precision. /// lfd /// frD(), d() [ rA() ] lfd, /// Load floating point double precision with update. /// lfdu /// frD(), d() [ rA() ] lfdu, /// Load floating point double precision with update indexed. /// lfdux /// frD(), rA(), rB() lfdux, /// Load floating point double precision indexed. /// lfdx /// frD(), rA(), rB() lfdx, /// Load floating point single precision. /// lfs /// frD(), d() [ rA() ] lfs, /// Load floating point single precision with update. /// lfsu /// frD(), d() [ rA() ] lfsu, /// Load floating point single precision with update indexed. /// lfsux /// frD(), rA(), rB() lfsux, /// Load floating point single precision indexed. /// lfsx /// frD(), rA(), rB() lfsx, /// Load half word algebraic. /// lha /// rD(), d() [ rA() ] lha, /// Load half word algebraic with update. /// lha /// rD(), d() [ rA() ] lhau, /// Load half-word algebraic with update indexed. /// lhaux /// rD(), rA(), rB() lhaux, /// Load half-word algebraic indexed. /// lhax /// rD(), rA(), rB() lhax, /// Load half word byte-reverse indexed. /// lhbrx /// rD(), rA(), rB() lhbrx, /// Load half word and zero. /// lhz /// rD(), d() [ rA() ] lhz, /// Load half-word and zero with update. /// lhzu /// rD(), d() [ rA() ] lhzu, /// Load half-word and zero with update indexed. /// lhzux /// rD(), rA(), rB() lhzux, /// Load half-word and zero indexed. /// lhzx /// rD(), rA(), rB() lhzx, /// Load multiple word. /// lmw /// rD(), d() [ rA() ] lmw, /// Load string word immediate. /// lswi /// rD(), rA(), nb() lswi, /// Load string word indexed. /// lswx /// rD(), rA(), rB() lswx, /// Load word and reserve indexed. /// lwarx /// rD(), rA(), rB() lwarx, /// Load word byte-reverse indexed. /// lwbrx /// rD(), rA(), rB() lwbrx, /// Load word and zero. /// lwz /// rD(), d() [ rA() ] lwz, /// Load word and zero with update. /// lwzu /// rD(), d() [ rA() ] lwzu, /// Load word and zero with update indexed. /// lwzux lwzux, /// Load word and zero indexed. /// lwzx lwzx, /// Move condition register field. /// mcrf /// crfD(), crfS() mcrf, /// Move to condition register from FPSCR. /// mcrfs /// crfD(), crfS() mcrfs, /// Move to condition register from XER. /// mcrxr /// crfD() mcrxr, /// Move from condition register. /// mfcr /// rD() mfcr, /// Move from FPSCR. /// mffs mffs. /// frD() [rc()] mffsx, /// Move from machine state register. /// mfmsr /// rD() mfmsr, /// Move from special purpose record. /// mfmsr /// rD(), spr() mfspr, /// Move from segment register. /// mfsr /// rD(), sr() mfsr, /// Move from segment register indirect. /// mfsrin /// rD(), rB() mfsrin, /// Move to condition register fields. /// mtcrf /// rS(), crm() mtcrf, /// Move to FPSCR bit 0. /// mtfsb0 mtfsb0. /// crbD() mtfsb0x, /// Move to FPSCR bit 1. /// mtfsb1 mtfsb1. /// crbD() mtfsb1x, /// Move to FPSCR fields. /// mtfsf mtfsf. /// fm(), frB() [rc()] mtfsfx, /// Move to FPSCR field immediate. /// mtfsfi mtfsfi. /// crfD(), imm() mtfsfix, /// Move to FPSCR. /// mtfs /// frS() mtmsr, /// Move to special purpose record. /// mtmsr /// rD(), spr() mtspr, /// Move to segment register. /// mfsr /// sr(), rS() mtsr, /// Move to segment register indirect. /// mtsrin /// rD(), rB() mtsrin, /// Multiply high word. /// mulhw mulgw. /// rD(), rA(), rB(), rc() mulhwx, /// Multiply high word unsigned. /// mulhwu mulhwu. /// rD(), rA(), rB(), rc() mulhwux, /// Multiply low immediate. mulli, /// Multiply low word. /// mullw mullw. mullwo mullwo. /// rA(), rB(), rD() mullwx, nandx, negx, norx, orx, orcx, ori, oris, rfi, rlwimix, /// Rotate left word immediate then AND with mask. /// rlwinm rlwinm. /// rA(), rS(), sh(), mb(), me(), rc() rlwinmx, /// Rotate left word then AND with mask /// rlwimi rlwimi. /// rA(), rB(), rS(), mb(), me(), rc() rlwnmx, /// System call. /// sc sc, /// Shift left word. /// slw slw. /// rA(), rS(), rB() [rc()] slwx, /// Shift right algebraic word. /// sraw sraw. /// rA(), rS(), rB() [rc()] srawx, /// Shift right algebraic word immediate. /// srawi srawi. /// rA(), rS(), sh() [rc()] srawix, /// Shift right word. /// srw srw. /// rA(), rS(), rB() [rc()] srwx, /// Store byte. /// stb /// rS(), d() [ rA() ] stb, /// Store byte with update. /// stbu /// rS(), d() [ rA() ] stbu, /// Store byte with update indexed. /// stbux /// rS(), rA(), rB() stbux, /// Store byte indexed. /// stbx /// rS(), rA(), rB() stbx, /// Store floating point double precision. /// stfd /// frS(), d() [ rA() ] stfd, /// Store floating point double precision with update. /// stfdu /// frS(), d() [ rA() ] stfdu, /// Store floating point double precision with update indexed. /// stfdux /// frS(), rA(), rB() stfdux, /// Store floating point double precision indexed. /// stfdux /// frS(), rA(), rB() stfdx, /// Store floating point single precision. /// stfs /// frS(), d() [ rA() ] stfs, /// Store floating point single precision with update. /// stfsu /// frS(), d() [ rA() ] stfsu, /// Store floating point single precision with update indexed. /// stfsux /// frS(), rA(), rB() stfsux, /// Store floating point single precisionindexed. /// stfsx /// frS(), rA(), rB() stfsx, /// Store half word. /// sth /// rS(), d() [ rA() ] sth, /// Store half word byte-reverse indexed. /// sthbrx /// rS(), rA(), rB() sthbrx, /// Store half word with update. /// sthu /// rS(), d() [ rA() ] sthu, /// Store half-word with update indexed. /// sthux /// rS(), rA(), rB() sthux, /// Store half-word indexed. /// sthx /// rS(), rA(), rB() sthx, /// Store multiple word. /// stmw /// rS(), d() [ rA() ] stmw, /// Store string word immediate. /// stswi /// rS(), rA(), nb() stswi, /// Store string word indexed. /// stswx /// rS(), rA(), rB() stswx, /// Store word. /// stw /// rS(), d() [ rA() ] stw, /// Store word byte-reverse indexed. /// stwbrx /// rS(), rA(), rB() stwbrx, /// Store word conditional. /// stwcx. /// rS(), rA(), rB() stwcx_, /// Store word with update. /// stwu /// rS(), d() [ rA() ] stwu, /// Store word with update indexed. /// stwux /// rS(), rA(), rB() stwux, /// Store word indexed. /// stwx /// rS(), rA(), rB() stwx, subfx, /// Subtract from carrying. /// subfc subfc. subfco subfco. subfcx, subfex, /// Subtract from immediate carrying subfic, subfmex, subfzex, sync, /// Trap word. /// tw tweq tweqi twge twgei ... /// to(), rA(), rB() tw, /// Trap word immediate. /// twi /// to(), rA(), simm() twi, /// Xor. /// xor xor. /// rA(), rS(), rB() [rc()] xorx, /// Xor immediate. /// xori /// rA(), rs(), uimm() xori, /// Xor immediate shifted. /// xoris /// rA(), rS(), uimm() xoris, // // MARK: - 32-bit, supervisor level. // /// Data cache block invalidate. /// dcbi /// rA(), rB() dcbi, // // MARK: - Supervisor, optional. // /// Translation lookaside buffer invalidate all. /// tlbia tlbia, /// Translation lookaside buffer invalidate entry. /// tlbie /// rB() tlbie, /// Translation lookaside buffer synchronise. /// tlbsync tlbsync, // // MARK: - Optional. // /// Floaring point reciprocal estimate single precision. /// fres fres. /// frD(), frB() [rc()] fresx, /// Floating point reciprocal square root estimation. /// frsqrte frsqrte. /// frD(), frB() [rc()] frsqrtex, /// Floating point select. /// fsel fsel. /// frD(), frA(), frC(), frB() [rc()] fselx, fsqrtx, /// Move from time base. /// mftb /// rD(), tbr() mftb, slbia, slbie, /// Store floating point as integer word indexed. /// stfiwx /// frS(), rA(), rB() stfiwx, // // MARK: - 64-bit only PowerPC instructions. // cntlzdx, /// Divide double word. /// divd divd. divdo divdo. /// rD(), rA(), rB() [rc(), oe()] divdx, /// Divide double word unsigned. /// divdu divdu. divduo divduo. /// rD(), rA(), rB() [rc(), oe()] divdux, /// Extend sign word. /// extsw extsw. /// rA(), rS() [rc()] extswx, /// Floating point convert from integer double word. /// fcfid fcfid. /// frD(), frB() [rc()] fcfidx, /// Floating point convert to integer double word. /// fctid fctid. /// frD(), frB() [rc()] fctidx, /// Floating point convert to integer double word with round towards zero. /// fctid fctid. /// frD(), frB() [rc()] fctidzx, tdi, mulhdux, ldx, sldx, ldux, td, mulhdx, ldarx, /// Store double. /// std /// rS(), ds() [ rA() ] std, /// Store double word conditional indexed. /// stdcx. /// rS(), rA(), rB() stdcx_, /// Store double word with update. /// stdu /// rS(), ds() [ rA() ] stdu, /// Store double word with update indexed. /// stdux /// rS(), rA(), rB() stdux, /// Store double word indexed. /// stdx /// rS(), rA(), rB() stdx, mulld, /// Load word algebraic. /// lwa /// rD(), rA(), rB() lwa, /// Load word algebraic with update indexed. /// lwaux /// rD(), rA(), rB() lwaux, /// Load word algebraic indexed. /// lwax /// rD(), rA(), rB() lwax, sradix, srdx, /// Shift right algebraic double word. /// srad srad, /// rA(), rS(), rB() [rc()] sradx, fsqrtsx }; /*! Holds a decoded PowerPC instruction. Implementation note: because the PowerPC encoding is particularly straightforward, only the operation has been decoded ahead of time; all other fields are decoded on-demand. It would be possible to partition the ordering of Operations into user followed by supervisor, eliminating the storage necessary for a flag, but it wouldn't save anything due to alignment. */ struct Instruction { Operation operation = Operation::Undefined; bool is_supervisor = false; uint32_t opcode = 0; Instruction() noexcept {} Instruction(uint32_t opcode) noexcept : opcode(opcode) {} Instruction(Operation operation, uint32_t opcode, bool is_supervisor = false) noexcept : operation(operation), is_supervisor(is_supervisor), opcode(opcode) {} // Instruction fields are decoded below; naming is a compromise between // Motorola's documentation and IBM's. // // I've dutifully implemented various synonyms with unique entry points, // in order to capture that information here rather than thrusting it upon // the reader of whatever implementation may follow. // Currently omitted: OPCD and XO, which I think are unnecessary given that // full decoding has already occurred. /// Immediate field used to specify an unsigned 16-bit integer. uint16_t uimm() const { return uint16_t(opcode & 0xffff); } /// Immediate field used to specify a signed 16-bit integer. int16_t simm() const { return int16_t(opcode & 0xffff); } /// Immediate field used to specify a signed 16-bit integer. int16_t d() const { return int16_t(opcode & 0xffff); } /// Immediate field used to specify a signed 14-bit integer [64-bit only]. int16_t ds() const { return int16_t(opcode & 0xfffc); } /// Immediate field used as data to be placed into a field in the floating point status and condition register. int32_t imm() const { return (opcode >> 12) & 0xf; } /// Specifies the conditions on which to trap. int32_t to() const { return (opcode >> 21) & 0x1f; } /// Register source A or destination. uint32_t rA() const { return (opcode >> 16) & 0x1f; } /// Register source B. uint32_t rB() const { return (opcode >> 11) & 0x1f; } /// Register destination. uint32_t rD() const { return (opcode >> 21) & 0x1f; } /// Register source. uint32_t rS() const { return (opcode >> 21) & 0x1f; } /// Floating point register source A. uint32_t frA() const { return (opcode >> 16) & 0x1f; } /// Floating point register source B. uint32_t frB() const { return (opcode >> 11) & 0x1f; } /// Floating point register source C. uint32_t frC() const { return (opcode >> 6) & 0x1f; } /// Floating point register source. uint32_t frS() const { return (opcode >> 21) & 0x1f; } /// Floating point register destination. uint32_t frD() const { return (opcode >> 21) & 0x1f; } /// Branch conditional options as per PowerPC spec, i.e. options + branch-prediction flag. uint32_t bo() const { return (opcode >> 21) & 0x1f; } /// Just the branch options, with the branch prediction flag severed. BranchOption branch_options() const { return BranchOption((opcode >> 22) & 0xf); } /// Just the branch-prediction hint; @c 0 => expect untaken; @c non-0 => expect take. uint32_t branch_prediction_hint() const { return opcode & 0x200000; } /// Source condition register bit for branch conditionals. uint32_t bi() const { return (opcode >> 16) & 0x1f; } /// Branch displacement; provided as already sign extended. int16_t bd() const { return int16_t(opcode & 0xfffc); } /// Specifies the first 1 bit of a 32/64-bit mask for rotate operations. uint32_t mb() const { return (opcode >> 6) & 0x1f; } /// Specifies the first 1 bit of a 32/64-bit mask for rotate operations. uint32_t me() const { return (opcode >> 1) & 0x1f; } /// Condition register source bit A. uint32_t crbA() const { return (opcode >> 16) & 0x1f; } /// Condition register source bit B. uint32_t crbB() const { return (opcode >> 11) & 0x1f; } /// Condition register (or floating point status & condition register) destination bit. uint32_t crbD() const { return (opcode >> 21) & 0x1f; } /// Condition register (or floating point status & condition register) destination field. uint32_t crfD() const { return (opcode >> 23) & 0x07; } /// Condition register (or floating point status & condition register) source field. uint32_t crfS() const { return (opcode >> 18) & 0x07; } /// Mask identifying fields to be updated by mtcrf. uint32_t crm() const { return (opcode >> 12) & 0xff; } /// Mask identifying fields to be updated by mtfsf. uint32_t fm() const { return (opcode >> 17) & 0xff; } /// Specifies the number of bytes to move in an immediate string load or store. uint32_t nb() const { // Map nb == 0 to 32, branchlessly, given that this is // a five-bit field. const uint32_t nb = (opcode >> 11) & 0x1f; return ((nb - 1) & 31) + 1; } /// Specifies a shift amount. uint32_t sh() const { return (opcode >> 11) & 0x1f; } /// Specifies one of the 16 segment registers [32-bit only]. uint32_t sr() const { return (opcode >> 16) & 0xf; } /// A 24-bit signed number; provided as already sign extended. int32_t li() const { constexpr uint32_t extensions[2] = { 0x0000'0000, 0xfc00'0000 }; const uint32_t value = (opcode & 0x03ff'fffc) | extensions[(opcode >> 25) & 1]; return int32_t(value); } /// Absolute address bit; @c 0 or @c non-0. uint32_t aa() const { return opcode & 0x02; } /// Link bit; @c 0 or @c non-0. uint32_t lk() const { return opcode & 0x01; } /// Record bit; @c 0 or @c non-0. uint32_t rc() const { return opcode & 0x01; } /// Whether to compare 32-bit or 64-bit numbers [for 64-bit implementations only]; @c 0 or @c non-0. uint32_t l() const { return opcode & 0x200000; } /// Enables setting of OV and SO in the XER; @c 0 or @c non-0. uint32_t oe() const { return opcode & 0x400; } /// Identifies a special purpose register. uint32_t spr() const { return (opcode >> 11) & 0x3ff; } /// Identifies a time base register. uint32_t tbr() const { return (opcode >> 11) & 0x3ff; } }; // Sanity check on Instruction size. static_assert(sizeof(Instruction) <= 8); } } #endif /* InstructionSets_PowerPC_Instruction_h */