55 } 56 } else if (bits(op1, 6, 5) == 0x1) { 57 return new WarnUnimplemented( 58 "Advanced SIMD data-processing", machInst); 59 } else if (bits(op1, 6, 4) == 0x4) { 60 if (bits(op1, 0) == 0) { 61 return new WarnUnimplemented( 62 "Advanced SIMD element or structure load/store", 63 machInst); 64 } else if (bits(op1, 2, 0) == 1) { 65 // Unallocated memory hint 66 return new NopInst(machInst); 67 } else if (bits(op1, 2, 0) == 5) { 68 const bool add = bits(machInst, 23); 69 const uint32_t imm12 = bits(machInst, 11, 0); 70 if (add) { 71 return new %(pli_iadd)s(machInst, INTREG_ZERO, 72 rn, add, imm12); 73 } else { 74 return new %(pli_isub)s(machInst, INTREG_ZERO, 75 rn, add, imm12); 76 } 77 } 78 } else if (bits(op1, 6, 4) == 0x5) { 79 if (bits(op1, 1, 0) == 0x1) { 80 const bool add = bits(machInst, 23); 81 const bool pldw = bits(machInst, 22); 82 const uint32_t imm12 = bits(machInst, 11, 0); 83 if (pldw) { 84 if (add) { 85 return new %(pldw_iadd)s(machInst, INTREG_ZERO, 86 rn, add, imm12); 87 } else { 88 return new %(pldw_isub)s(machInst, INTREG_ZERO, 89 rn, add, imm12); 90 } 91 } else { 92 if (add) { 93 return new %(pld_iadd)s(machInst, INTREG_ZERO, 94 rn, add, imm12); 95 } else { 96 return new %(pld_isub)s(machInst, INTREG_ZERO, 97 rn, add, imm12); 98 } 99 } 100 } else if (op1 == 0x57) { 101 switch (op2) { 102 case 0x1: 103 return new WarnUnimplemented("clrex", machInst); 104 case 0x4: 105 return new WarnUnimplemented("dsb", machInst); 106 case 0x5: 107 return new WarnUnimplemented("dmb", machInst); 108 case 0x6: 109 return new WarnUnimplemented("isb", machInst); 110 } 111 } 112 } else if (bits(op2, 0) == 0) { 113 switch (op1 & 0xf7) { 114 case 0x61: 115 // Unallocated memory hint 116 return new NopInst(machInst); 117 case 0x65: 118 { 119 const uint32_t imm5 = bits(machInst, 11, 7); 120 const uint32_t type = bits(machInst, 6, 5); 121 const bool add = bits(machInst, 23); 122 const IntRegIndex rm = 123 (IntRegIndex)(uint32_t)bits(machInst, 3, 0); 124 if (add) { 125 return new %(pli_radd)s(machInst, INTREG_ZERO, rn, 126 add, imm5, type, rm); 127 } else { 128 return new %(pli_rsub)s(machInst, INTREG_ZERO, rn, 129 add, imm5, type, rm); 130 } 131 } 132 case 0x71: 133 case 0x75: 134 { 135 const uint32_t imm5 = bits(machInst, 11, 7); 136 const uint32_t type = bits(machInst, 6, 5); 137 const bool add = bits(machInst, 23); 138 const bool pldw = bits(machInst, 22); 139 const IntRegIndex rm = 140 (IntRegIndex)(uint32_t)bits(machInst, 3, 0); 141 if (pldw) { 142 if (add) { 143 return new %(pldw_radd)s(machInst, INTREG_ZERO, 144 rn, add, imm5, 145 type, rm); 146 } else { 147 return new %(pldw_rsub)s(machInst, INTREG_ZERO, 148 rn, add, imm5, 149 type, rm); 150 } 151 } else { 152 if (add) { 153 return new %(pld_radd)s(machInst, INTREG_ZERO, 154 rn, add, imm5, 155 type, rm); 156 } else { 157 return new %(pld_rsub)s(machInst, INTREG_ZERO, 158 rn, add, imm5, 159 type, rm); 160 } 161 } 162 } 163 } 164 } 165 } else { 166 switch (bits(machInst, 26, 25)) { 167 case 0x0: 168 { 169 const uint32_t val = ((machInst >> 20) & 0x5); 170 if (val == 0x4) { 171 const uint32_t mode = bits(machInst, 4, 0); 172 switch (bits(machInst, 24, 21)) { 173 case 0x2: 174 return new %(srs)s(machInst, mode, 175 SrsOp::DecrementAfter, false); 176 case 0x3: 177 return new %(srs_w)s(machInst, mode, 178 SrsOp::DecrementAfter, true); 179 case 0x6: 180 return new %(srs_u)s(machInst, mode, 181 SrsOp::IncrementAfter, false); 182 case 0x7: 183 return new %(srs_uw)s(machInst, mode, 184 SrsOp::IncrementAfter, true); 185 case 0xa: 186 return new %(srs_p)s(machInst, mode, 187 SrsOp::DecrementBefore, false); 188 case 0xb: 189 return new %(srs_pw)s(machInst, mode, 190 SrsOp::DecrementBefore, true); 191 case 0xe: 192 return new %(srs_pu)s(machInst, mode, 193 SrsOp::IncrementBefore, false); 194 case 0xf: 195 return new %(srs_puw)s(machInst, mode, 196 SrsOp::IncrementBefore, true); 197 } 198 return new Unknown(machInst); 199 } else if (val == 0x1) { 200 switch (bits(machInst, 24, 21)) { 201 case 0x0: 202 return new %(rfe)s(machInst, rn, 203 RfeOp::DecrementAfter, false); 204 case 0x1: 205 return new %(rfe_w)s(machInst, rn, 206 RfeOp::DecrementAfter, true); 207 case 0x4: 208 return new %(rfe_u)s(machInst, rn, 209 RfeOp::IncrementAfter, false); 210 case 0x5: 211 return new %(rfe_uw)s(machInst, rn, 212 RfeOp::IncrementAfter, true); 213 case 0x8: 214 return new %(rfe_p)s(machInst, rn, 215 RfeOp::DecrementBefore, false); 216 case 0x9: 217 return new %(rfe_pw)s(machInst, rn, 218 RfeOp::DecrementBefore, true); 219 case 0xc: 220 return new %(rfe_pu)s(machInst, rn, 221 RfeOp::IncrementBefore, false); 222 case 0xd: 223 return new %(rfe_puw)s(machInst, rn, 224 RfeOp::IncrementBefore, true); 225 } 226 return new Unknown(machInst); 227 } 228 } 229 break; 230 case 0x1: 231 { 232 const uint32_t imm = 233 (sext<26>(bits(machInst, 23, 0) << 2)) | 234 (bits(machInst, 24) << 1); 235 return new BlxImm(machInst, imm); 236 } 237 case 0x2: 238 if (bits(op1, 0) == 1) { 239 if (rn == INTREG_PC) { 240 if (bits(op1, 4, 3) != 0x0) { 241 return new WarnUnimplemented( 242 "ldc, ldc2 (literal)", machInst); 243 } 244 } else { 245 if (op1 == 0xC3 || op1 == 0xC7) { 246 return new WarnUnimplemented( 247 "ldc, ldc2 (immediate)", machInst); 248 } 249 } 250 if (op1 == 0xC5) { 251 return new WarnUnimplemented("mrrc, mrrc2", machInst); 252 } 253 } else { 254 if (bits(op1, 4, 3) != 0 || bits(op1, 1) == 1) { 255 return new WarnUnimplemented("stc, stc2", machInst); 256 } else if (op1 == 0xC4) { 257 return new WarnUnimplemented("mcrr, mcrrc", machInst); 258 } 259 } 260 break; 261 case 0x3: 262 { 263 const bool op = bits(machInst, 4); 264 if (op) { 265 if (bits(op1, 0)) { 266 return new WarnUnimplemented( 267 "mrc, mrc2", machInst); 268 } else { 269 return new WarnUnimplemented( 270 "mcr, mcr2", machInst); 271 } 272 } else { 273 return new WarnUnimplemented("cdp, cdp2", machInst); 274 } 275 } 276 break; 277 } 278 } 279 return new Unknown(machInst); 280 } 281 ''' % { 282 "pli_iadd" : "PLI_" + loadImmClassName(False, True, False, 1), 283 "pli_isub" : "PLI_" + loadImmClassName(False, False, False, 1), 284 "pld_iadd" : "PLD_" + loadImmClassName(False, True, False, 1), 285 "pld_isub" : "PLD_" + loadImmClassName(False, False, False, 1), 286 "pldw_iadd" : "PLDW_" + loadImmClassName(False, True, False, 1), 287 "pldw_isub" : "PLDW_" + loadImmClassName(False, False, False, 1), 288 "pli_radd" : "PLI_" + loadRegClassName(False, True, False, 1), 289 "pli_rsub" : "PLI_" + loadRegClassName(False, False, False, 1), 290 "pld_radd" : "PLD_" + loadRegClassName(False, True, False, 1), 291 "pld_rsub" : "PLD_" + loadRegClassName(False, False, False, 1), 292 "pldw_radd" : "PLDW_" + loadRegClassName(False, True, False, 1), 293 "pldw_rsub" : "PLDW_" + loadRegClassName(False, False, False, 1), 294 "rfe" : "RFE_" + loadImmClassName(True, False, False, 8), 295 "rfe_w" : "RFE_" + loadImmClassName(True, False, True, 8), 296 "rfe_u" : "RFE_" + loadImmClassName(True, True, False, 8), 297 "rfe_uw" : "RFE_" + loadImmClassName(True, True, True, 8), 298 "rfe_p" : "RFE_" + loadImmClassName(False, False, False, 8), 299 "rfe_pw" : "RFE_" + loadImmClassName(False, False, True, 8), 300 "rfe_pu" : "RFE_" + loadImmClassName(False, True, False, 8), 301 "rfe_puw" : "RFE_" + loadImmClassName(False, True, True, 8), 302 "srs" : "SRS_" + storeImmClassName(True, False, False, 8), 303 "srs_w" : "SRS_" + storeImmClassName(True, False, True, 8), 304 "srs_u" : "SRS_" + storeImmClassName(True, True, False, 8), 305 "srs_uw" : "SRS_" + storeImmClassName(True, True, True, 8), 306 "srs_p" : "SRS_" + storeImmClassName(False, False, False, 8), 307 "srs_pw" : "SRS_" + storeImmClassName(False, False, True, 8), 308 "srs_pu" : "SRS_" + storeImmClassName(False, True, False, 8), 309 "srs_puw" : "SRS_" + storeImmClassName(False, True, True, 8) 310 }; 311}};
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