#ifndef xx #define xx(op, name, mode, alt, kreg, ktype) OP_##op, #endif // first row is the opcode // second row is the disassembly name // third row is the disassembly flags // fourth row is the alternative opcode if all 256 constant registers are exhausted. // fifth row is the constant register index in the opcode // sixth row is the constant register type. // OP_PARAM and OP_CMPS need special treatment because they encode this information in the instruction. xx(NOP, nop, NOP, NOP, 0, 0) // no operation // Load constants. xx(LI, li, LI, NOP, 0, 0) // load immediate signed 16-bit constant xx(LK, lk, LKI, NOP, 0, 0) // load integer constant xx(LKF, lk, LKF, NOP, 0, 0) // load float constant xx(LKS, lk, LKS, NOP, 0, 0) // load string constant xx(LKP, lk, LKP, NOP, 0, 0) // load pointer constant xx(LK_R, lk, RIRII8, NOP, 0, 0) // load integer constant indexed xx(LKF_R, lk, RFRII8, NOP, 0, 0) // load float constant indexed xx(LKS_R, lk, RSRII8, NOP, 0, 0) // load string constant indexed xx(LKP_R, lk, RPRII8, NOP, 0, 0) // load pointer constant indexed xx(LFP, lf, LFP, NOP, 0, 0) // load frame pointer xx(META, meta, RPRP, NOP, 0, 0) // load a class's meta data address xx(CLSS, clss, RPRP, NOP, 0, 0) // load a class's descriptor address // Load from memory. rA = *(rB + rkC) xx(LB, lb, RIRPKI, LB_R, 4, REGT_INT) // load byte xx(LB_R, lb, RIRPRI, NOP, 0, 0) xx(LH, lh, RIRPKI, LH_R, 4, REGT_INT) // load halfword xx(LH_R, lh, RIRPRI, NOP, 0, 0) xx(LW, lw, RIRPKI, LW_R, 4, REGT_INT) // load word xx(LW_R, lw, RIRPRI, NOP, 0, 0) xx(LBU, lbu, RIRPKI, LBU_R, 4, REGT_INT) // load byte unsigned xx(LBU_R, lbu, RIRPRI, NOP, 0, 0) xx(LHU, lhu, RIRPKI, LHU_R, 4, REGT_INT) // load halfword unsigned xx(LHU_R, lhu, RIRPRI, NOP, 0, 0) xx(LSP, lsp, RFRPKI, LSP_R, 4, REGT_INT) // load single-precision fp xx(LSP_R, lsp, RFRPRI, NOP, 0, 0) xx(LDP, ldp, RFRPKI, LDP_R, 4, REGT_INT) // load double-precision fp xx(LDP_R, ldp, RFRPRI, NOP, 0, 0) xx(LS, ls, RSRPKI, LS_R, 4, REGT_INT) // load string xx(LS_R, ls, RSRPRI, NOP, 0, 0) xx(LO, lo, RPRPKI, LO_R, 4, REGT_INT) // load object xx(LO_R, lo, RPRPRI, NOP, 0, 0) xx(LP, lp, RPRPKI, LP_R, 4, REGT_INT) // load pointer xx(LP_R, lp, RPRPRI, NOP, 0, 0) xx(LV2, lv2, RVRPKI, LV2_R, 4, REGT_INT) // load vector2 xx(LV2_R, lv2, RVRPRI, NOP, 0, 0) xx(LV3, lv3, RVRPKI, LV3_R, 4, REGT_INT) // load vector3 xx(LV3_R, lv3, RVRPRI, NOP, 0, 0) xx(LV4, lv4, RVRPKI, LV4_R, 4, REGT_INT) // load vector4 xx(LV4_R, lv4, RVRPRI, NOP, 0, 0) xx(LCS, lcs, RSRPKI, LCS_R, 4, REGT_INT) // load string from char ptr. xx(LCS_R, lcs, RSRPRI, NOP, 0, 0) xx(LFV2, lfv2, RVRPKI, LFV2_R, 4, REGT_INT) // load fvector2 xx(LFV2_R, lfv2, RVRPRI, NOP, 0, 0) xx(LFV3, lfv3, RVRPKI, LFV3_R, 4, REGT_INT) // load fvector3 xx(LFV3_R, lfv3, RVRPRI, NOP, 0, 0) xx(LFV4, lfv4, RVRPKI, LFV4_R, 4, REGT_INT) // load fvector4 xx(LFV4_R, lfv4, RVRPRI, NOP, 0, 0) xx(LBIT, lbit, RIRPI8, NOP, 0, 0) // rA = !!(*rB & C) -- *rB is a byte // Store instructions. *(rA + rkC) = rB xx(SB, sb, RPRIKI, SB_R, 4, REGT_INT) // store byte xx(SB_R, sb, RPRIRI, NOP, 0, 0) xx(SH, sh, RPRIKI, SH_R, 4, REGT_INT) // store halfword xx(SH_R, sh, RPRIRI, NOP, 0, 0) xx(SW, sw, RPRIKI, SW_R, 4, REGT_INT) // store word xx(SW_R, sw, RPRIRI, NOP, 0, 0) xx(SSP, ssp, RPRFKI, SSP_R, 4, REGT_INT) // store single-precision fp xx(SSP_R, ssp, RPRFRI, NOP, 0, 0) xx(SDP, sdp, RPRFKI, SDP_R, 4, REGT_INT) // store double-precision fp xx(SDP_R, sdp, RPRFRI, NOP, 0, 0) xx(SS, ss, RPRSKI, SS_R, 4, REGT_INT) // store string xx(SS_R, ss, RPRSRI, NOP, 0, 0) xx(SP, sp, RPRPKI, SP_R, 4, REGT_INT) // store pointer xx(SP_R, sp, RPRPRI, NOP, 0, 0) xx(SO, so, RPRPKI, SO_R, 4, REGT_INT) // store object pointer with write barrier (only needed for non thinkers and non types) xx(SO_R, so, RPRPRI, NOP, 0, 0) xx(SV2, sv2, RPRVKI, SV2_R, 4, REGT_INT) // store vector2 xx(SV2_R, sv2, RPRVRI, NOP, 0, 0) xx(SV3, sv3, RPRVKI, SV3_R, 4, REGT_INT) // store vector3 xx(SV3_R, sv3, RPRVRI, NOP, 0, 0) xx(SV4, sv4, RPRVKI, SV4_R, 4, REGT_INT) // store vector4 xx(SV4_R, sv4, RPRVRI, NOP, 0, 0) xx(SFV2, sfv2, RPRVKI, SFV2_R, 4, REGT_INT) // store fvector2 xx(SFV2_R, sfv2, RPRVRI, NOP, 0, 0) xx(SFV3, sfv3, RPRVKI, SFV3_R, 4, REGT_INT) // store fvector3 xx(SFV3_R, sfv3, RPRVRI, NOP, 0, 0) xx(SFV4, sfv4, RPRVKI, SFV4_R, 4, REGT_INT) // store fvector4 xx(SFV4_R, sfv4, RPRVRI, NOP, 0, 0) xx(SBIT, sbit, RPRII8, NOP, 0, 0) // *rA |= C if rB is true, *rA &= ~C otherwise // Move instructions. xx(MOVE, mov, RIRI, NOP, 0, 0) // dA = dB xx(MOVEF, mov, RFRF, NOP, 0, 0) // fA = fB xx(MOVES, mov, RSRS, NOP, 0, 0) // sA = sB xx(MOVEA, mov, RPRP, NOP, 0, 0) // aA = aB xx(MOVEV2, mov2, RFRF, NOP, 0, 0) // fA = fB (2 elements) xx(MOVEV3, mov3, RFRF, NOP, 0, 0) // fA = fB (3 elements) xx(MOVEV4, mov4, RFRF, NOP, 0, 0) // fA = fB (4 elements) xx(CAST, cast, CAST, NOP, 0, 0) // xA = xB, conversion specified by C xx(CASTB, castb, CAST, NOP, 0, 0) // xA = !!xB, type specified by C xx(DYNCAST_R, dyncast, RPRPRP, NOP, 0, 0) // aA = dyn_cast(aB); xx(DYNCAST_K, dyncast, RPRPKP, NOP, 0, 0) // aA = dyn_cast(aB); xx(DYNCASTC_R, dyncastc, RPRPRP, NOP, 0, 0) // aA = dyn_cast(aB); for class types xx(DYNCASTC_K, dyncastc, RPRPKP, NOP, 0, 0) // aA = dyn_cast(aB); // Control flow. xx(TEST, test, RII16, NOP, 0, 0) // if (dA != BC) then pc++ xx(TESTN, testn, RII16, NOP, 0, 0) // if (dA != -BC) then pc++ xx(JMP, jmp, I24, NOP, 0, 0) // pc += ABC -- The ABC fields contain a signed 24-bit offset. xx(IJMP, ijmp, RII16, NOP, 0, 0) // pc += dA + BC -- BC is a signed offset. The target instruction must be a JMP. xx(PARAM, param, __BCP, NOP, 0, 0) // push parameter encoded in BC for function call (B=regtype, C=regnum) xx(PARAMI, parami, I24, NOP, 0, 0) // push immediate, signed integer for function call xx(CALL, call, RPI8I8, NOP, 0, 0) // Call function pkA with parameter count B and expected result count C xx(CALL_K, call, KPI8I8, CALL, 1, REGT_POINTER) xx(VTBL, vtbl, RPRPI8, NOP, 0, 0) // dereferences a virtual method table. xx(SCOPE, scope, RPI8, NOP, 0, 0) // Scope check at runtime. xx(RESULT, result, __BCP, NOP, 0, 0) // Result should go in register encoded in BC (in caller, after CALL) xx(RET, ret, I8BCP, NOP, 0, 0) // Copy value from register encoded in BC to return value A, possibly returning xx(RETI, reti, I8I16, NOP, 0, 0) // Copy immediate from BC to return value A, possibly returning //xx(TRY, try, I24, NOP, 0, 0) // When an exception is thrown, start searching for a handler at pc + ABC //xx(UNTRY, untry, I8, NOP, 0, 0) // Pop A entries off the exception stack xx(THROW, throw, THROW, NOP, 0, 0) // A == 0: Throw exception object pB // A == 1: Throw exception object pkB // A >= 2: Throw VM exception of type BC //xx(CATCH, catch, CATCH, NOP, 0, 0) // A == 0: continue search on next try // A == 1: continue execution at instruction immediately following CATCH (catches any exception) // A == 2: (pB == ) then pc++ ; next instruction must JMP to another CATCH // A == 3: (pkB == ) then pc++ ; next instruction must JMP to another CATCH // for A > 0, exception is stored in pC xx(BOUND, bound, RII16, NOP, 0, 0) // if rA < 0 or rA >= BC, throw exception xx(BOUND_K, bound, LKI, NOP, 0, 0) // if rA < 0 or rA >= const[BC], throw exception xx(BOUND_R, bound, RIRI, NOP, 0, 0) // if rA < 0 or rA >= rB, throw exception // String instructions. xx(CONCAT, concat, RSRSRS, NOP, 0, 0) // sA = sB..sC xx(LENS, lens, RIRS, NOP, 0, 0) // dA = sB.Length xx(CMPS, cmps, I8RXRX, NOP, 0, 0) // if ((skB op skC) != (A & 1)) then pc++ // Integer math. xx(SLL_RR, sll, RIRIRI, NOP, 0, 0) // dA = dkB << diC xx(SLL_RI, sll, RIRII8, NOP, 0, 0) xx(SLL_KR, sll, RIKIRI, SLL_RR, 2, REGT_INT) xx(SRL_RR, srl, RIRIRI, NOP, 0, 0) // dA = dkB >> diC -- unsigned xx(SRL_RI, srl, RIRII8, NOP, 0, 0) xx(SRL_KR, srl, RIKIRI, SRL_RR, 2, REGT_INT) xx(SRA_RR, sra, RIRIRI, NOP, 0, 0) // dA = dkB >> diC -- signed xx(SRA_RI, sra, RIRII8, NOP, 0, 0) xx(SRA_KR, sra, RIKIRI, SRA_RR, 2, REGT_INT) xx(ADD_RR, add, RIRIRI, NOP, 0, 0) // dA = dB + dkC xx(ADD_RK, add, RIRIKI, ADD_RR, 4, REGT_INT) xx(ADDI, addi, RIRIIs, NOP, 0, 0) // dA = dB + C -- C is a signed 8-bit constant xx(SUB_RR, sub, RIRIRI, NOP, 0, 0) // dA = dkB - dkC xx(SUB_RK, sub, RIRIKI, SUB_RR, 4, REGT_INT) xx(SUB_KR, sub, RIKIRI, SUB_RR, 2, REGT_INT) xx(MUL_RR, mul, RIRIRI, NOP, 0, 0) // dA = dB * dkC xx(MUL_RK, mul, RIRIKI, MUL_RR, 4, REGT_INT) xx(DIV_RR, div, RIRIRI, NOP, 0, 0) // dA = dkB / dkC (signed) xx(DIV_RK, div, RIRIKI, DIV_RR, 4, REGT_INT) xx(DIV_KR, div, RIKIRI, DIV_RR, 2, REGT_INT) xx(DIVU_RR, divu, RIRIRI, NOP, 0, 0) // dA = dkB / dkC (unsigned) xx(DIVU_RK, divu, RIRIKI, DIVU_RR,4, REGT_INT) xx(DIVU_KR, divu, RIKIRI, DIVU_RR,2, REGT_INT) xx(MOD_RR, mod, RIRIRI, NOP, 0, 0) // dA = dkB % dkC (signed) xx(MOD_RK, mod, RIRIKI, MOD_RR, 4, REGT_INT) xx(MOD_KR, mod, RIKIRI, MOD_RR, 2, REGT_INT) xx(MODU_RR, modu, RIRIRI, NOP, 0, 0) // dA = dkB % dkC (unsigned) xx(MODU_RK, modu, RIRIKI, MODU_RR,4, REGT_INT) xx(MODU_KR, modu, RIKIRI, MODU_RR,2, REGT_INT) xx(AND_RR, and, RIRIRI, NOP, 0, 0) // dA = dB & dkC xx(AND_RK, and, RIRIKI, AND_RR, 4, REGT_INT) xx(OR_RR, or, RIRIRI, NOP, 0, 0) // dA = dB | dkC xx(OR_RK, or, RIRIKI, OR_RR, 4, REGT_INT) xx(XOR_RR, xor, RIRIRI, NOP, 0, 0) // dA = dB ^ dkC xx(XOR_RK, xor, RIRIKI, XOR_RR, 4, REGT_INT) xx(MIN_RR, min, RIRIRI, NOP, 0, 0) // dA = min(dB,dkC) xx(MIN_RK, min, RIRIKI, MIN_RR, 4, REGT_INT) xx(MAX_RR, max, RIRIRI, NOP, 0, 0) // dA = max(dB,dkC) xx(MAX_RK, max, RIRIKI, MAX_RR, 4, REGT_INT) xx(MINU_RR, minu, RIRIRI, NOP, 0, 0) // dA = min(dB,dkC) unsigned xx(MINU_RK, minu, RIRIKI, MIN_RR, 4, REGT_INT) xx(MAXU_RR, maxu, RIRIRI, NOP, 0, 0) // dA = max(dB,dkC) unsigned xx(MAXU_RK, maxu, RIRIKI, MAX_RR, 4, REGT_INT) xx(ABS, abs, RIRI, NOP, 0, 0) // dA = abs(dB) xx(NEG, neg, RIRI, NOP, 0, 0) // dA = -dB xx(NOT, not, RIRI, NOP, 0, 0) // dA = ~dB xx(EQ_R, beq, CIRR, NOP, 0, 0) // if ((dB == dkC) != A) then pc++ xx(EQ_K, beq, CIRK, EQ_R, 4, REGT_INT) xx(LT_RR, blt, CIRR, NOP, 0, 0) // if ((dkB < dkC) != A) then pc++ xx(LT_RK, blt, CIRK, LT_RR, 4, REGT_INT) xx(LT_KR, blt, CIKR, LT_RR, 2, REGT_INT) xx(LE_RR, ble, CIRR, NOP, 0, 0) // if ((dkB <= dkC) != A) then pc++ xx(LE_RK, ble, CIRK, LE_RR, 4, REGT_INT) xx(LE_KR, ble, CIKR, LE_RR, 2, REGT_INT) xx(LTU_RR, bltu, CIRR, NOP, 0, 0) // if ((dkB < dkC) != A) then pc++ -- unsigned xx(LTU_RK, bltu, CIRK, LTU_RR, 4, REGT_INT) xx(LTU_KR, bltu, CIKR, LTU_RR, 2, REGT_INT) xx(LEU_RR, bleu, CIRR, NOP, 0, 0) // if ((dkB <= dkC) != A) then pc++ -- unsigned xx(LEU_RK, bleu, CIRK, LEU_RR, 4, REGT_INT) xx(LEU_KR, bleu, CIKR, LEU_RR, 2, REGT_INT) // Double-precision floating point math. xx(ADDF_RR, add, RFRFRF, NOP, 0, 0) // fA = fB + fkC xx(ADDF_RK, add, RFRFKF, ADDF_RR,4, REGT_FLOAT) xx(SUBF_RR, sub, RFRFRF, NOP, 0, 0) // fA = fkB - fkC xx(SUBF_RK, sub, RFRFKF, SUBF_RR,4, REGT_FLOAT) xx(SUBF_KR, sub, RFKFRF, SUBF_RR,2, REGT_FLOAT) xx(MULF_RR, mul, RFRFRF, NOP, 0, 0) // fA = fB * fkC xx(MULF_RK, mul, RFRFKF, MULF_RR,4, REGT_FLOAT) xx(DIVF_RR, div, RFRFRF, NOP, 0, 0) // fA = fkB / fkC xx(DIVF_RK, div, RFRFKF, DIVF_RR,4, REGT_FLOAT) xx(DIVF_KR, div, RFKFRF, DIVF_RR,2, REGT_FLOAT) xx(MODF_RR, mod, RFRFRF, NOP, 0, 0) // fA = fkB % fkC xx(MODF_RK, mod, RFRFKF, MODF_RR,4, REGT_FLOAT) xx(MODF_KR, mod, RFKFRF, MODF_RR,4, REGT_FLOAT) xx(POWF_RR, pow, RFRFRF, NOP, 0, 0) // fA = fkB ** fkC xx(POWF_RK, pow, RFRFKF, POWF_RR,4, REGT_FLOAT) xx(POWF_KR, pow, RFKFRF, POWF_RR,2, REGT_FLOAT) xx(MINF_RR, min, RFRFRF, NOP, 0, 0) // fA = min(fB)fkC) xx(MINF_RK, min, RFRFKF, MINF_RR,4, REGT_FLOAT) xx(MAXF_RR, max, RFRFRF, NOP, 0, 0) // fA = max(fB)fkC) xx(MAXF_RK, max, RFRFKF, MAXF_RR,4, REGT_FLOAT) xx(ATAN2, atan2, RFRFRF, NOP, 0, 0) // fA = atan2(fB,fC) result is in degrees xx(FLOP, flop, RFRFI8, NOP, 0, 0) // fA = f(fB) where function is selected by C xx(EQF_R, beq, CFRR, NOP, 0, 0) // if ((fB == fkC) != (A & 1)) then pc++ xx(EQF_K, beq, CFRK, EQF_R, 4, REGT_FLOAT) xx(LTF_RR, blt, CFRR, NOP, 0, 0) // if ((fkB < fkC) != (A & 1)) then pc++ xx(LTF_RK, blt, CFRK, LTF_RR, 4, REGT_FLOAT) xx(LTF_KR, blt, CFKR, LTF_RR, 2, REGT_FLOAT) xx(LEF_RR, ble, CFRR, NOP, 0, 0) // if ((fkb <= fkC) != (A & 1)) then pc++ xx(LEF_RK, ble, CFRK, LEF_RR, 4, REGT_FLOAT) xx(LEF_KR, ble, CFKR, LEF_RR, 2, REGT_FLOAT) // Vector math. (2D) xx(NEGV2, negv2, RVRV, NOP, 0, 0) // vA = -vB xx(ADDV2_RR, addv2, RVRVRV, NOP, 0, 0) // vA = vB + vkC xx(SUBV2_RR, subv2, RVRVRV, NOP, 0, 0) // vA = vkB - vkC xx(DOTV2_RR, dotv2, RVRVRV, NOP, 0, 0) // va = vB dot vkC xx(MULVF2_RR, mulv2, RVRVRF, NOP, 0, 0) // vA = vkB * fkC xx(MULVF2_RK, mulv2, RVRVKF, MULVF2_RR,4, REGT_FLOAT) xx(DIVVF2_RR, divv2, RVRVRF, NOP, 0, 0) // vA = vkB / fkC xx(DIVVF2_RK, divv2, RVRVKF, DIVVF2_RR,4, REGT_FLOAT) xx(LENV2, lenv2, RFRV, NOP, 0, 0) // fA = vB.Length xx(EQV2_R, beqv2, CVRR, NOP, 0, 0) // if ((vB == vkC) != A) then pc++ (inexact if A & 32) xx(EQV2_K, beqv2, CVRK, NOP, 0, 0) // this will never be used. // Vector math (3D) xx(NEGV3, negv3, RVRV, NOP, 0, 0) // vA = -vB xx(ADDV3_RR, addv3, RVRVRV, NOP, 0, 0) // vA = vB + vkC xx(SUBV3_RR, subv3, RVRVRV, NOP, 0, 0) // vA = vkB - vkC xx(DOTV3_RR, dotv3, RVRVRV, NOP, 0, 0) // va = vB dot vkC xx(CROSSV_RR, crossv, RVRVRV, NOP, 0, 0) // vA = vkB cross vkC xx(MULVF3_RR, mulv3, RVRVRF, NOP, 0, 0) // vA = vkB * fkC xx(MULVF3_RK, mulv3, RVRVKF, MULVF3_RR,4, REGT_FLOAT) xx(DIVVF3_RR, divv3, RVRVRF, NOP, 0, 0) // vA = vkB / fkC xx(DIVVF3_RK, divv3, RVRVKF, DIVVF3_RR,4, REGT_FLOAT) xx(LENV3, lenv3, RFRV, NOP, 0, 0) // fA = vB.Length xx(EQV3_R, beqv3, CVRR, NOP, 0, 0) // if ((vB == vkC) != A) then pc++ (inexact if A & 33) xx(EQV3_K, beqv3, CVRK, NOP, 0, 0) // this will never be used. // Vector math (4D) xx(NEGV4, negv4, RVRV, NOP, 0, 0) // vA = -vB xx(ADDV4_RR, addv4, RVRVRV, NOP, 0, 0) // vA = vB + vkC xx(SUBV4_RR, subv4, RVRVRV, NOP, 0, 0) // vA = vkB - vkC xx(DOTV4_RR, dotv4, RVRVRV, NOP, 0, 0) // va = vB dot vkC xx(MULVF4_RR, mulv4, RVRVRF, NOP, 0, 0) // vA = vkB * fkC xx(MULVF4_RK, mulv4, RVRVKF, MULVF4_RR, 4, REGT_FLOAT) xx(DIVVF4_RR, divv4, RVRVRF, NOP, 0, 0) // vA = vkB / fkC xx(DIVVF4_RK, divv4, RVRVKF, DIVVF4_RR, 4, REGT_FLOAT) xx(LENV4, lenv4, RFRV, NOP, 0, 0) // fA = vB.Length xx(EQV4_R, beqv4, CVRR, NOP, 0, 0) // if ((vB == vkC) != A) then pc++ (inexact if A & 33) xx(EQV4_K, beqv4, CVRK, NOP, 0, 0) // this will never be used. // Quaternion math xx(MULQQ_RR, mulqq, RVRVRV, NOP, 0, 0) // qA = qB * qC xx(MULQV3_RR, mulqv3, RVRVRV, NOP, 0, 0) // qA = qB * vC // Pointer math. xx(ADDA_RR, add, RPRPRI, NOP, 0, 0) // pA = pB + dkC xx(ADDA_RK, add, RPRPKI, ADDA_RR,4, REGT_INT) xx(SUBA, sub, RIRPRP, NOP, 0, 0) // dA = pB - pC xx(EQA_R, beq, CPRR, NOP, 0, 0) // if ((pB == pkC) != A) then pc++ xx(EQA_K, beq, CPRK, EQA_R, 4, REGT_POINTER) #undef xx