isa.cc revision 10037:5cac77888310
1/* 2 * Copyright (c) 2010-2013 ARM Limited 3 * All rights reserved 4 * 5 * The license below extends only to copyright in the software and shall 6 * not be construed as granting a license to any other intellectual 7 * property including but not limited to intellectual property relating 8 * to a hardware implementation of the functionality of the software 9 * licensed hereunder. You may use the software subject to the license 10 * terms below provided that you ensure that this notice is replicated 11 * unmodified and in its entirety in all distributions of the software, 12 * modified or unmodified, in source code or in binary form. 13 * 14 * Redistribution and use in source and binary forms, with or without 15 * modification, are permitted provided that the following conditions are 16 * met: redistributions of source code must retain the above copyright 17 * notice, this list of conditions and the following disclaimer; 18 * redistributions in binary form must reproduce the above copyright 19 * notice, this list of conditions and the following disclaimer in the 20 * documentation and/or other materials provided with the distribution; 21 * neither the name of the copyright holders nor the names of its 22 * contributors may be used to endorse or promote products derived from 23 * this software without specific prior written permission. 24 * 25 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 26 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 27 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 28 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 29 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 30 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 31 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 32 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 33 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 34 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 35 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 36 * 37 * Authors: Gabe Black 38 * Ali Saidi 39 */ 40 41#include "arch/arm/isa.hh" 42#include "arch/arm/system.hh" 43#include "cpu/checker/cpu.hh" 44#include "debug/Arm.hh" 45#include "debug/MiscRegs.hh" 46#include "params/ArmISA.hh" 47#include "sim/faults.hh" 48#include "sim/stat_control.hh" 49#include "sim/system.hh" 50 51namespace ArmISA 52{ 53 54 55/** 56 * Some registers aliase with others, and therefore need to be translated. 57 * For each entry: 58 * The first value is the misc register that is to be looked up 59 * the second value is the lower part of the translation 60 * the third the upper part 61 */ 62const struct ISA::MiscRegInitializerEntry 63 ISA::MiscRegSwitch[miscRegTranslateMax] = { 64 {MISCREG_CSSELR_EL1, {MISCREG_CSSELR, 0}}, 65 {MISCREG_SCTLR_EL1, {MISCREG_SCTLR, 0}}, 66 {MISCREG_SCTLR_EL2, {MISCREG_HSCTLR, 0}}, 67 {MISCREG_ACTLR_EL1, {MISCREG_ACTLR, 0}}, 68 {MISCREG_ACTLR_EL2, {MISCREG_HACTLR, 0}}, 69 {MISCREG_CPACR_EL1, {MISCREG_CPACR, 0}}, 70 {MISCREG_CPTR_EL2, {MISCREG_HCPTR, 0}}, 71 {MISCREG_HCR_EL2, {MISCREG_HCR, 0}}, 72 {MISCREG_MDCR_EL2, {MISCREG_HDCR, 0}}, 73 {MISCREG_HSTR_EL2, {MISCREG_HSTR, 0}}, 74 {MISCREG_HACR_EL2, {MISCREG_HACR, 0}}, 75 {MISCREG_TTBR0_EL1, {MISCREG_TTBR0, 0}}, 76 {MISCREG_TTBR1_EL1, {MISCREG_TTBR1, 0}}, 77 {MISCREG_TTBR0_EL2, {MISCREG_HTTBR, 0}}, 78 {MISCREG_VTTBR_EL2, {MISCREG_VTTBR, 0}}, 79 {MISCREG_TCR_EL1, {MISCREG_TTBCR, 0}}, 80 {MISCREG_TCR_EL2, {MISCREG_HTCR, 0}}, 81 {MISCREG_VTCR_EL2, {MISCREG_VTCR, 0}}, 82 {MISCREG_AFSR0_EL1, {MISCREG_ADFSR, 0}}, 83 {MISCREG_AFSR1_EL1, {MISCREG_AIFSR, 0}}, 84 {MISCREG_AFSR0_EL2, {MISCREG_HADFSR, 0}}, 85 {MISCREG_AFSR1_EL2, {MISCREG_HAIFSR, 0}}, 86 {MISCREG_ESR_EL2, {MISCREG_HSR, 0}}, 87 {MISCREG_FAR_EL1, {MISCREG_DFAR, MISCREG_IFAR}}, 88 {MISCREG_FAR_EL2, {MISCREG_HDFAR, MISCREG_HIFAR}}, 89 {MISCREG_HPFAR_EL2, {MISCREG_HPFAR, 0}}, 90 {MISCREG_PAR_EL1, {MISCREG_PAR, 0}}, 91 {MISCREG_MAIR_EL1, {MISCREG_PRRR, MISCREG_NMRR}}, 92 {MISCREG_MAIR_EL2, {MISCREG_HMAIR0, MISCREG_HMAIR1}}, 93 {MISCREG_AMAIR_EL1, {MISCREG_AMAIR0, MISCREG_AMAIR1}}, 94 {MISCREG_VBAR_EL1, {MISCREG_VBAR, 0}}, 95 {MISCREG_VBAR_EL2, {MISCREG_HVBAR, 0}}, 96 {MISCREG_CONTEXTIDR_EL1, {MISCREG_CONTEXTIDR, 0}}, 97 {MISCREG_TPIDR_EL0, {MISCREG_TPIDRURW, 0}}, 98 {MISCREG_TPIDRRO_EL0, {MISCREG_TPIDRURO, 0}}, 99 {MISCREG_TPIDR_EL1, {MISCREG_TPIDRPRW, 0}}, 100 {MISCREG_TPIDR_EL2, {MISCREG_HTPIDR, 0}}, 101 {MISCREG_TEECR32_EL1, {MISCREG_TEECR, 0}}, 102 {MISCREG_CNTFRQ_EL0, {MISCREG_CNTFRQ, 0}}, 103 {MISCREG_CNTPCT_EL0, {MISCREG_CNTPCT, 0}}, 104 {MISCREG_CNTVCT_EL0, {MISCREG_CNTVCT, 0}}, 105 {MISCREG_CNTVOFF_EL2, {MISCREG_CNTVOFF, 0}}, 106 {MISCREG_CNTKCTL_EL1, {MISCREG_CNTKCTL, 0}}, 107 {MISCREG_CNTHCTL_EL2, {MISCREG_CNTHCTL, 0}}, 108 {MISCREG_CNTP_TVAL_EL0, {MISCREG_CNTP_TVAL, 0}}, 109 {MISCREG_CNTP_CTL_EL0, {MISCREG_CNTP_CTL, 0}}, 110 {MISCREG_CNTP_CVAL_EL0, {MISCREG_CNTP_CVAL, 0}}, 111 {MISCREG_CNTV_TVAL_EL0, {MISCREG_CNTV_TVAL, 0}}, 112 {MISCREG_CNTV_CTL_EL0, {MISCREG_CNTV_CTL, 0}}, 113 {MISCREG_CNTV_CVAL_EL0, {MISCREG_CNTV_CVAL, 0}}, 114 {MISCREG_CNTHP_TVAL_EL2, {MISCREG_CNTHP_TVAL, 0}}, 115 {MISCREG_CNTHP_CTL_EL2, {MISCREG_CNTHP_CTL, 0}}, 116 {MISCREG_CNTHP_CVAL_EL2, {MISCREG_CNTHP_CVAL, 0}}, 117 {MISCREG_DACR32_EL2, {MISCREG_DACR, 0}}, 118 {MISCREG_IFSR32_EL2, {MISCREG_IFSR, 0}}, 119 {MISCREG_TEEHBR32_EL1, {MISCREG_TEEHBR, 0}}, 120 {MISCREG_SDER32_EL3, {MISCREG_SDER, 0}} 121}; 122 123 124ISA::ISA(Params *p) 125 : SimObject(p), system(NULL), lookUpMiscReg(NUM_MISCREGS, {0,0}) 126{ 127 SCTLR sctlr; 128 sctlr = 0; 129 miscRegs[MISCREG_SCTLR_RST] = sctlr; 130 131 system = dynamic_cast<ArmSystem *>(p->system); 132 DPRINTFN("ISA system set to: %p %p\n", system, p->system); 133 134 // Cache system-level properties 135 if (FullSystem && system) { 136 haveSecurity = system->haveSecurity(); 137 haveLPAE = system->haveLPAE(); 138 haveVirtualization = system->haveVirtualization(); 139 haveLargeAsid64 = system->haveLargeAsid64(); 140 physAddrRange64 = system->physAddrRange64(); 141 } else { 142 haveSecurity = haveLPAE = haveVirtualization = false; 143 haveLargeAsid64 = false; 144 physAddrRange64 = 32; // dummy value 145 } 146 147 /** Fill in the miscReg translation table */ 148 for (uint32_t i = 0; i < miscRegTranslateMax; i++) { 149 struct MiscRegLUTEntry new_entry; 150 151 uint32_t select = MiscRegSwitch[i].index; 152 new_entry = MiscRegSwitch[i].entry; 153 154 lookUpMiscReg[select] = new_entry; 155 } 156 157 preUnflattenMiscReg(); 158 159 clear(); 160} 161 162const ArmISAParams * 163ISA::params() const 164{ 165 return dynamic_cast<const Params *>(_params); 166} 167 168void 169ISA::clear() 170{ 171 const Params *p(params()); 172 173 SCTLR sctlr_rst = miscRegs[MISCREG_SCTLR_RST]; 174 memset(miscRegs, 0, sizeof(miscRegs)); 175 176 // Initialize configurable default values 177 miscRegs[MISCREG_MIDR] = p->midr; 178 miscRegs[MISCREG_MIDR_EL1] = p->midr; 179 miscRegs[MISCREG_VPIDR] = p->midr; 180 181 if (FullSystem && system->highestELIs64()) { 182 // Initialize AArch64 state 183 clear64(p); 184 return; 185 } 186 187 // Initialize AArch32 state... 188 189 CPSR cpsr = 0; 190 cpsr.mode = MODE_USER; 191 miscRegs[MISCREG_CPSR] = cpsr; 192 updateRegMap(cpsr); 193 194 SCTLR sctlr = 0; 195 sctlr.te = (bool) sctlr_rst.te; 196 sctlr.nmfi = (bool) sctlr_rst.nmfi; 197 sctlr.v = (bool) sctlr_rst.v; 198 sctlr.u = 1; 199 sctlr.xp = 1; 200 sctlr.rao2 = 1; 201 sctlr.rao3 = 1; 202 sctlr.rao4 = 0xf; // SCTLR[6:3] 203 miscRegs[MISCREG_SCTLR_NS] = sctlr; 204 miscRegs[MISCREG_SCTLR_RST] = sctlr_rst; 205 miscRegs[MISCREG_HCPTR] = 0; 206 207 // Start with an event in the mailbox 208 miscRegs[MISCREG_SEV_MAILBOX] = 1; 209 210 // Separate Instruction and Data TLBs 211 miscRegs[MISCREG_TLBTR] = 1; 212 213 MVFR0 mvfr0 = 0; 214 mvfr0.advSimdRegisters = 2; 215 mvfr0.singlePrecision = 2; 216 mvfr0.doublePrecision = 2; 217 mvfr0.vfpExceptionTrapping = 0; 218 mvfr0.divide = 1; 219 mvfr0.squareRoot = 1; 220 mvfr0.shortVectors = 1; 221 mvfr0.roundingModes = 1; 222 miscRegs[MISCREG_MVFR0] = mvfr0; 223 224 MVFR1 mvfr1 = 0; 225 mvfr1.flushToZero = 1; 226 mvfr1.defaultNaN = 1; 227 mvfr1.advSimdLoadStore = 1; 228 mvfr1.advSimdInteger = 1; 229 mvfr1.advSimdSinglePrecision = 1; 230 mvfr1.advSimdHalfPrecision = 1; 231 mvfr1.vfpHalfPrecision = 1; 232 miscRegs[MISCREG_MVFR1] = mvfr1; 233 234 // Reset values of PRRR and NMRR are implementation dependent 235 236 // @todo: PRRR and NMRR in secure state? 237 miscRegs[MISCREG_PRRR_NS] = 238 (1 << 19) | // 19 239 (0 << 18) | // 18 240 (0 << 17) | // 17 241 (1 << 16) | // 16 242 (2 << 14) | // 15:14 243 (0 << 12) | // 13:12 244 (2 << 10) | // 11:10 245 (2 << 8) | // 9:8 246 (2 << 6) | // 7:6 247 (2 << 4) | // 5:4 248 (1 << 2) | // 3:2 249 0; // 1:0 250 miscRegs[MISCREG_NMRR_NS] = 251 (1 << 30) | // 31:30 252 (0 << 26) | // 27:26 253 (0 << 24) | // 25:24 254 (3 << 22) | // 23:22 255 (2 << 20) | // 21:20 256 (0 << 18) | // 19:18 257 (0 << 16) | // 17:16 258 (1 << 14) | // 15:14 259 (0 << 12) | // 13:12 260 (2 << 10) | // 11:10 261 (0 << 8) | // 9:8 262 (3 << 6) | // 7:6 263 (2 << 4) | // 5:4 264 (0 << 2) | // 3:2 265 0; // 1:0 266 267 miscRegs[MISCREG_CPACR] = 0; 268 269 270 miscRegs[MISCREG_ID_PFR0] = p->id_pfr0; 271 miscRegs[MISCREG_ID_PFR1] = p->id_pfr1; 272 273 miscRegs[MISCREG_ID_MMFR0] = p->id_mmfr0; 274 miscRegs[MISCREG_ID_MMFR1] = p->id_mmfr1; 275 miscRegs[MISCREG_ID_MMFR2] = p->id_mmfr2; 276 miscRegs[MISCREG_ID_MMFR3] = p->id_mmfr3; 277 278 miscRegs[MISCREG_ID_ISAR0] = p->id_isar0; 279 miscRegs[MISCREG_ID_ISAR1] = p->id_isar1; 280 miscRegs[MISCREG_ID_ISAR2] = p->id_isar2; 281 miscRegs[MISCREG_ID_ISAR3] = p->id_isar3; 282 miscRegs[MISCREG_ID_ISAR4] = p->id_isar4; 283 miscRegs[MISCREG_ID_ISAR5] = p->id_isar5; 284 285 miscRegs[MISCREG_FPSID] = p->fpsid; 286 287 if (haveLPAE) { 288 TTBCR ttbcr = miscRegs[MISCREG_TTBCR_NS]; 289 ttbcr.eae = 0; 290 miscRegs[MISCREG_TTBCR_NS] = ttbcr; 291 // Enforce consistency with system-level settings 292 miscRegs[MISCREG_ID_MMFR0] = (miscRegs[MISCREG_ID_MMFR0] & ~0xf) | 0x5; 293 } 294 295 if (haveSecurity) { 296 miscRegs[MISCREG_SCTLR_S] = sctlr; 297 miscRegs[MISCREG_SCR] = 0; 298 miscRegs[MISCREG_VBAR_S] = 0; 299 } else { 300 // we're always non-secure 301 miscRegs[MISCREG_SCR] = 1; 302 } 303 304 //XXX We need to initialize the rest of the state. 305} 306 307void 308ISA::clear64(const ArmISAParams *p) 309{ 310 CPSR cpsr = 0; 311 Addr rvbar = system->resetAddr64(); 312 switch (system->highestEL()) { 313 // Set initial EL to highest implemented EL using associated stack 314 // pointer (SP_ELx); set RVBAR_ELx to implementation defined reset 315 // value 316 case EL3: 317 cpsr.mode = MODE_EL3H; 318 miscRegs[MISCREG_RVBAR_EL3] = rvbar; 319 break; 320 case EL2: 321 cpsr.mode = MODE_EL2H; 322 miscRegs[MISCREG_RVBAR_EL2] = rvbar; 323 break; 324 case EL1: 325 cpsr.mode = MODE_EL1H; 326 miscRegs[MISCREG_RVBAR_EL1] = rvbar; 327 break; 328 default: 329 panic("Invalid highest implemented exception level"); 330 break; 331 } 332 333 // Initialize rest of CPSR 334 cpsr.daif = 0xf; // Mask all interrupts 335 cpsr.ss = 0; 336 cpsr.il = 0; 337 miscRegs[MISCREG_CPSR] = cpsr; 338 updateRegMap(cpsr); 339 340 // Initialize other control registers 341 miscRegs[MISCREG_MPIDR_EL1] = 0x80000000; 342 if (haveSecurity) { 343 miscRegs[MISCREG_SCTLR_EL3] = 0x30c50870; 344 miscRegs[MISCREG_SCR_EL3] = 0x00000030; // RES1 fields 345 // @todo: uncomment this to enable Virtualization 346 // } else if (haveVirtualization) { 347 // miscRegs[MISCREG_SCTLR_EL2] = 0x30c50870; 348 } else { 349 miscRegs[MISCREG_SCTLR_EL1] = 0x30c50870; 350 // Always non-secure 351 miscRegs[MISCREG_SCR_EL3] = 1; 352 } 353 354 // Initialize configurable id registers 355 miscRegs[MISCREG_ID_AA64AFR0_EL1] = p->id_aa64afr0_el1; 356 miscRegs[MISCREG_ID_AA64AFR1_EL1] = p->id_aa64afr1_el1; 357 miscRegs[MISCREG_ID_AA64DFR0_EL1] = p->id_aa64dfr0_el1; 358 miscRegs[MISCREG_ID_AA64DFR1_EL1] = p->id_aa64dfr1_el1; 359 miscRegs[MISCREG_ID_AA64ISAR0_EL1] = p->id_aa64isar0_el1; 360 miscRegs[MISCREG_ID_AA64ISAR1_EL1] = p->id_aa64isar1_el1; 361 miscRegs[MISCREG_ID_AA64MMFR0_EL1] = p->id_aa64mmfr0_el1; 362 miscRegs[MISCREG_ID_AA64MMFR1_EL1] = p->id_aa64mmfr1_el1; 363 miscRegs[MISCREG_ID_AA64PFR0_EL1] = p->id_aa64pfr0_el1; 364 miscRegs[MISCREG_ID_AA64PFR1_EL1] = p->id_aa64pfr1_el1; 365 366 // Enforce consistency with system-level settings... 367 368 // EL3 369 // (no AArch32/64 interprocessing support for now) 370 miscRegs[MISCREG_ID_AA64PFR0_EL1] = insertBits( 371 miscRegs[MISCREG_ID_AA64PFR0_EL1], 15, 12, 372 haveSecurity ? 0x1 : 0x0); 373 // EL2 374 // (no AArch32/64 interprocessing support for now) 375 miscRegs[MISCREG_ID_AA64PFR0_EL1] = insertBits( 376 miscRegs[MISCREG_ID_AA64PFR0_EL1], 11, 8, 377 haveVirtualization ? 0x1 : 0x0); 378 // Large ASID support 379 miscRegs[MISCREG_ID_AA64MMFR0_EL1] = insertBits( 380 miscRegs[MISCREG_ID_AA64MMFR0_EL1], 7, 4, 381 haveLargeAsid64 ? 0x2 : 0x0); 382 // Physical address size 383 miscRegs[MISCREG_ID_AA64MMFR0_EL1] = insertBits( 384 miscRegs[MISCREG_ID_AA64MMFR0_EL1], 3, 0, 385 encodePhysAddrRange64(physAddrRange64)); 386} 387 388MiscReg 389ISA::readMiscRegNoEffect(int misc_reg) const 390{ 391 assert(misc_reg < NumMiscRegs); 392 393 int flat_idx = flattenMiscIndex(misc_reg); // Note: indexes of AArch64 394 // registers are left unchanged 395 MiscReg val; 396 397 if (lookUpMiscReg[flat_idx].lower == 0 || flat_idx == MISCREG_SPSR 398 || flat_idx == MISCREG_SCTLR_EL1) { 399 if (flat_idx == MISCREG_SPSR) 400 flat_idx = flattenMiscIndex(MISCREG_SPSR); 401 if (flat_idx == MISCREG_SCTLR_EL1) 402 flat_idx = flattenMiscIndex(MISCREG_SCTLR); 403 val = miscRegs[flat_idx]; 404 } else 405 if (lookUpMiscReg[flat_idx].upper > 0) 406 val = ((miscRegs[lookUpMiscReg[flat_idx].lower] & mask(32)) 407 | (miscRegs[lookUpMiscReg[flat_idx].upper] << 32)); 408 else 409 val = miscRegs[lookUpMiscReg[flat_idx].lower]; 410 411 return val; 412} 413 414 415MiscReg 416ISA::readMiscReg(int misc_reg, ThreadContext *tc) 417{ 418 CPSR cpsr = 0; 419 PCState pc = 0; 420 SCR scr = 0; 421 422 if (misc_reg == MISCREG_CPSR) { 423 cpsr = miscRegs[misc_reg]; 424 pc = tc->pcState(); 425 cpsr.j = pc.jazelle() ? 1 : 0; 426 cpsr.t = pc.thumb() ? 1 : 0; 427 return cpsr; 428 } 429 430#ifndef NDEBUG 431 if (!miscRegInfo[misc_reg][MISCREG_IMPLEMENTED]) { 432 if (miscRegInfo[misc_reg][MISCREG_WARN_NOT_FAIL]) 433 warn("Unimplemented system register %s read.\n", 434 miscRegName[misc_reg]); 435 else 436 panic("Unimplemented system register %s read.\n", 437 miscRegName[misc_reg]); 438 } 439#endif 440 441 switch (unflattenMiscReg(misc_reg)) { 442 case MISCREG_HCR: 443 { 444 if (!haveVirtualization) 445 return 0; 446 else 447 return readMiscRegNoEffect(MISCREG_HCR); 448 } 449 case MISCREG_CPACR: 450 { 451 const uint32_t ones = (uint32_t)(-1); 452 CPACR cpacrMask = 0; 453 // Only cp10, cp11, and ase are implemented, nothing else should 454 // be readable? (straight copy from the write code) 455 cpacrMask.cp10 = ones; 456 cpacrMask.cp11 = ones; 457 cpacrMask.asedis = ones; 458 459 // Security Extensions may limit the readability of CPACR 460 if (haveSecurity) { 461 scr = readMiscRegNoEffect(MISCREG_SCR); 462 cpsr = readMiscRegNoEffect(MISCREG_CPSR); 463 if (scr.ns && (cpsr.mode != MODE_MON)) { 464 NSACR nsacr = readMiscRegNoEffect(MISCREG_NSACR); 465 // NB: Skipping the full loop, here 466 if (!nsacr.cp10) cpacrMask.cp10 = 0; 467 if (!nsacr.cp11) cpacrMask.cp11 = 0; 468 } 469 } 470 MiscReg val = readMiscRegNoEffect(MISCREG_CPACR); 471 val &= cpacrMask; 472 DPRINTF(MiscRegs, "Reading misc reg %s: %#x\n", 473 miscRegName[misc_reg], val); 474 return val; 475 } 476 case MISCREG_MPIDR: 477 cpsr = readMiscRegNoEffect(MISCREG_CPSR); 478 scr = readMiscRegNoEffect(MISCREG_SCR); 479 if ((cpsr.mode == MODE_HYP) || inSecureState(scr, cpsr)) { 480 return getMPIDR(system, tc); 481 } else { 482 return readMiscReg(MISCREG_VMPIDR, tc); 483 } 484 break; 485 case MISCREG_MPIDR_EL1: 486 // @todo in the absence of v8 virtualization support just return MPIDR_EL1 487 return getMPIDR(system, tc) & 0xffffffff; 488 case MISCREG_VMPIDR: 489 // top bit defined as RES1 490 return readMiscRegNoEffect(misc_reg) | 0x80000000; 491 case MISCREG_ID_AFR0: // not implemented, so alias MIDR 492 case MISCREG_ID_DFR0: // not implemented, so alias MIDR 493 case MISCREG_REVIDR: // not implemented, so alias MIDR 494 case MISCREG_MIDR: 495 cpsr = readMiscRegNoEffect(MISCREG_CPSR); 496 scr = readMiscRegNoEffect(MISCREG_SCR); 497 if ((cpsr.mode == MODE_HYP) || inSecureState(scr, cpsr)) { 498 return readMiscRegNoEffect(misc_reg); 499 } else { 500 return readMiscRegNoEffect(MISCREG_VPIDR); 501 } 502 break; 503 case MISCREG_JOSCR: // Jazelle trivial implementation, RAZ/WI 504 case MISCREG_JMCR: // Jazelle trivial implementation, RAZ/WI 505 case MISCREG_JIDR: // Jazelle trivial implementation, RAZ/WI 506 case MISCREG_AIDR: // AUX ID set to 0 507 case MISCREG_TCMTR: // No TCM's 508 return 0; 509 510 case MISCREG_CLIDR: 511 warn_once("The clidr register always reports 0 caches.\n"); 512 warn_once("clidr LoUIS field of 0b001 to match current " 513 "ARM implementations.\n"); 514 return 0x00200000; 515 case MISCREG_CCSIDR: 516 warn_once("The ccsidr register isn't implemented and " 517 "always reads as 0.\n"); 518 break; 519 case MISCREG_CTR: 520 { 521 //all caches have the same line size in gem5 522 //4 byte words in ARM 523 unsigned lineSizeWords = 524 tc->getSystemPtr()->cacheLineSize() / 4; 525 unsigned log2LineSizeWords = 0; 526 527 while (lineSizeWords >>= 1) { 528 ++log2LineSizeWords; 529 } 530 531 CTR ctr = 0; 532 //log2 of minimun i-cache line size (words) 533 ctr.iCacheLineSize = log2LineSizeWords; 534 //b11 - gem5 uses pipt 535 ctr.l1IndexPolicy = 0x3; 536 //log2 of minimum d-cache line size (words) 537 ctr.dCacheLineSize = log2LineSizeWords; 538 //log2 of max reservation size (words) 539 ctr.erg = log2LineSizeWords; 540 //log2 of max writeback size (words) 541 ctr.cwg = log2LineSizeWords; 542 //b100 - gem5 format is ARMv7 543 ctr.format = 0x4; 544 545 return ctr; 546 } 547 case MISCREG_ACTLR: 548 warn("Not doing anything for miscreg ACTLR\n"); 549 break; 550 case MISCREG_PMCR: 551 case MISCREG_PMCCNTR: 552 case MISCREG_PMSELR: 553 warn("Not doing anything for read to miscreg %s\n", 554 miscRegName[misc_reg]); 555 break; 556 case MISCREG_CPSR_Q: 557 panic("shouldn't be reading this register seperately\n"); 558 case MISCREG_FPSCR_QC: 559 return readMiscRegNoEffect(MISCREG_FPSCR) & ~FpscrQcMask; 560 case MISCREG_FPSCR_EXC: 561 return readMiscRegNoEffect(MISCREG_FPSCR) & ~FpscrExcMask; 562 case MISCREG_FPSR: 563 { 564 const uint32_t ones = (uint32_t)(-1); 565 FPSCR fpscrMask = 0; 566 fpscrMask.ioc = ones; 567 fpscrMask.dzc = ones; 568 fpscrMask.ofc = ones; 569 fpscrMask.ufc = ones; 570 fpscrMask.ixc = ones; 571 fpscrMask.idc = ones; 572 fpscrMask.qc = ones; 573 fpscrMask.v = ones; 574 fpscrMask.c = ones; 575 fpscrMask.z = ones; 576 fpscrMask.n = ones; 577 return readMiscRegNoEffect(MISCREG_FPSCR) & (uint32_t)fpscrMask; 578 } 579 case MISCREG_FPCR: 580 { 581 const uint32_t ones = (uint32_t)(-1); 582 FPSCR fpscrMask = 0; 583 fpscrMask.ioe = ones; 584 fpscrMask.dze = ones; 585 fpscrMask.ofe = ones; 586 fpscrMask.ufe = ones; 587 fpscrMask.ixe = ones; 588 fpscrMask.ide = ones; 589 fpscrMask.len = ones; 590 fpscrMask.stride = ones; 591 fpscrMask.rMode = ones; 592 fpscrMask.fz = ones; 593 fpscrMask.dn = ones; 594 fpscrMask.ahp = ones; 595 return readMiscRegNoEffect(MISCREG_FPSCR) & (uint32_t)fpscrMask; 596 } 597 case MISCREG_NZCV: 598 { 599 CPSR cpsr = 0; 600 cpsr.nz = tc->readIntReg(INTREG_CONDCODES_NZ); 601 cpsr.c = tc->readIntReg(INTREG_CONDCODES_C); 602 cpsr.v = tc->readIntReg(INTREG_CONDCODES_V); 603 return cpsr; 604 } 605 case MISCREG_DAIF: 606 { 607 CPSR cpsr = 0; 608 cpsr.daif = (uint8_t) ((CPSR) miscRegs[MISCREG_CPSR]).daif; 609 return cpsr; 610 } 611 case MISCREG_SP_EL0: 612 { 613 return tc->readIntReg(INTREG_SP0); 614 } 615 case MISCREG_SP_EL1: 616 { 617 return tc->readIntReg(INTREG_SP1); 618 } 619 case MISCREG_SP_EL2: 620 { 621 return tc->readIntReg(INTREG_SP2); 622 } 623 case MISCREG_SPSEL: 624 { 625 return miscRegs[MISCREG_CPSR] & 0x1; 626 } 627 case MISCREG_CURRENTEL: 628 { 629 return miscRegs[MISCREG_CPSR] & 0xc; 630 } 631 case MISCREG_L2CTLR: 632 { 633 // mostly unimplemented, just set NumCPUs field from sim and return 634 L2CTLR l2ctlr = 0; 635 // b00:1CPU to b11:4CPUs 636 l2ctlr.numCPUs = tc->getSystemPtr()->numContexts() - 1; 637 return l2ctlr; 638 } 639 case MISCREG_DBGDIDR: 640 /* For now just implement the version number. 641 * Return 0 as we don't support debug architecture yet. 642 */ 643 return 0; 644 case MISCREG_DBGDSCRint: 645 return 0; 646 case MISCREG_ISR: 647 return tc->getCpuPtr()->getInterruptController()->getISR( 648 readMiscRegNoEffect(MISCREG_HCR), 649 readMiscRegNoEffect(MISCREG_CPSR), 650 readMiscRegNoEffect(MISCREG_SCR)); 651 case MISCREG_ISR_EL1: 652 return tc->getCpuPtr()->getInterruptController()->getISR( 653 readMiscRegNoEffect(MISCREG_HCR_EL2), 654 readMiscRegNoEffect(MISCREG_CPSR), 655 readMiscRegNoEffect(MISCREG_SCR_EL3)); 656 case MISCREG_DCZID_EL0: 657 return 0x04; // DC ZVA clear 64-byte chunks 658 case MISCREG_HCPTR: 659 { 660 MiscReg val = readMiscRegNoEffect(misc_reg); 661 // The trap bit associated with CP14 is defined as RAZ 662 val &= ~(1 << 14); 663 // If a CP bit in NSACR is 0 then the corresponding bit in 664 // HCPTR is RAO/WI 665 bool secure_lookup = haveSecurity && 666 inSecureState(readMiscRegNoEffect(MISCREG_SCR), 667 readMiscRegNoEffect(MISCREG_CPSR)); 668 if (!secure_lookup) { 669 MiscReg mask = readMiscRegNoEffect(MISCREG_NSACR); 670 val |= (mask ^ 0x7FFF) & 0xBFFF; 671 } 672 // Set the bits for unimplemented coprocessors to RAO/WI 673 val |= 0x33FF; 674 return (val); 675 } 676 case MISCREG_HDFAR: // alias for secure DFAR 677 return readMiscRegNoEffect(MISCREG_DFAR_S); 678 case MISCREG_HIFAR: // alias for secure IFAR 679 return readMiscRegNoEffect(MISCREG_IFAR_S); 680 case MISCREG_HVBAR: // bottom bits reserved 681 return readMiscRegNoEffect(MISCREG_HVBAR) & 0xFFFFFFE0; 682 case MISCREG_SCTLR: // Some bits hardwired 683 // The FI field (bit 21) is common between S/NS versions of the register 684 return (readMiscRegNoEffect(MISCREG_SCTLR_S) & (1 << 21)) | 685 (readMiscRegNoEffect(misc_reg) & 0x72DD39FF) | 0x00C00818; // V8 SCTLR 686 case MISCREG_SCTLR_EL1: 687 // The FI field (bit 21) is common between S/NS versions of the register 688 return (readMiscRegNoEffect(MISCREG_SCTLR_S) & (1 << 21)) | 689 (readMiscRegNoEffect(misc_reg) & 0x37DDDBFF) | 0x30D00800; // V8 SCTLR_EL1 690 case MISCREG_SCTLR_EL3: 691 // The FI field (bit 21) is common between S/NS versions of the register 692 return (readMiscRegNoEffect(MISCREG_SCTLR_S) & (1 << 21)) | 693 (readMiscRegNoEffect(misc_reg) & 0x32CD183F) | 0x30C50830; // V8 SCTLR_EL3 694 case MISCREG_HSCTLR: // FI comes from SCTLR 695 { 696 uint32_t mask = 1 << 27; 697 return (readMiscRegNoEffect(MISCREG_HSCTLR) & ~mask) | 698 (readMiscRegNoEffect(MISCREG_SCTLR) & mask); 699 } 700 case MISCREG_SCR: 701 { 702 CPSR cpsr = readMiscRegNoEffect(MISCREG_CPSR); 703 if (cpsr.width) { 704 return readMiscRegNoEffect(MISCREG_SCR); 705 } else { 706 return readMiscRegNoEffect(MISCREG_SCR_EL3); 707 } 708 } 709 // Generic Timer registers 710 case MISCREG_CNTFRQ: 711 case MISCREG_CNTFRQ_EL0: 712 inform_once("Read CNTFREQ_EL0 frequency\n"); 713 return getSystemCounter(tc)->freq(); 714 case MISCREG_CNTPCT: 715 case MISCREG_CNTPCT_EL0: 716 return getSystemCounter(tc)->value(); 717 case MISCREG_CNTVCT: 718 return getSystemCounter(tc)->value(); 719 case MISCREG_CNTVCT_EL0: 720 return getSystemCounter(tc)->value(); 721 case MISCREG_CNTP_CVAL: 722 case MISCREG_CNTP_CVAL_EL0: 723 return getArchTimer(tc, tc->cpuId())->compareValue(); 724 case MISCREG_CNTP_TVAL: 725 case MISCREG_CNTP_TVAL_EL0: 726 return getArchTimer(tc, tc->cpuId())->timerValue(); 727 case MISCREG_CNTP_CTL: 728 case MISCREG_CNTP_CTL_EL0: 729 return getArchTimer(tc, tc->cpuId())->control(); 730 // PL1 phys. timer, secure 731 // AArch64 732 case MISCREG_CNTPS_CVAL_EL1: 733 case MISCREG_CNTPS_TVAL_EL1: 734 case MISCREG_CNTPS_CTL_EL1: 735 // PL2 phys. timer, non-secure 736 // AArch32 737 case MISCREG_CNTHCTL: 738 case MISCREG_CNTHP_CVAL: 739 case MISCREG_CNTHP_TVAL: 740 case MISCREG_CNTHP_CTL: 741 // AArch64 742 case MISCREG_CNTHCTL_EL2: 743 case MISCREG_CNTHP_CVAL_EL2: 744 case MISCREG_CNTHP_TVAL_EL2: 745 case MISCREG_CNTHP_CTL_EL2: 746 // Virtual timer 747 // AArch32 748 case MISCREG_CNTV_CVAL: 749 case MISCREG_CNTV_TVAL: 750 case MISCREG_CNTV_CTL: 751 // AArch64 752 // case MISCREG_CNTV_CVAL_EL2: 753 // case MISCREG_CNTV_TVAL_EL2: 754 // case MISCREG_CNTV_CTL_EL2: 755 panic("Generic Timer register not implemented\n"); 756 break; 757 758 } 759 return readMiscRegNoEffect(misc_reg); 760} 761 762void 763ISA::setMiscRegNoEffect(int misc_reg, const MiscReg &val) 764{ 765 assert(misc_reg < NumMiscRegs); 766 767 int flat_idx = flattenMiscIndex(misc_reg); // Note: indexes of AArch64 768 // registers are left unchanged 769 770 int flat_idx2 = lookUpMiscReg[flat_idx].upper; 771 772 if (flat_idx2 > 0) { 773 miscRegs[lookUpMiscReg[flat_idx].lower] = bits(val, 31, 0); 774 miscRegs[flat_idx2] = bits(val, 63, 32); 775 DPRINTF(MiscRegs, "Writing to misc reg %d (%d:%d) : %#x\n", 776 misc_reg, flat_idx, flat_idx2, val); 777 } else { 778 if (flat_idx == MISCREG_SPSR) 779 flat_idx = flattenMiscIndex(MISCREG_SPSR); 780 else if (flat_idx == MISCREG_SCTLR_EL1) 781 flat_idx = flattenMiscIndex(MISCREG_SCTLR); 782 else 783 flat_idx = (lookUpMiscReg[flat_idx].lower > 0) ? 784 lookUpMiscReg[flat_idx].lower : flat_idx; 785 miscRegs[flat_idx] = val; 786 DPRINTF(MiscRegs, "Writing to misc reg %d (%d) : %#x\n", 787 misc_reg, flat_idx, val); 788 } 789} 790 791void 792ISA::setMiscReg(int misc_reg, const MiscReg &val, ThreadContext *tc) 793{ 794 795 MiscReg newVal = val; 796 int x; 797 bool secure_lookup; 798 bool hyp; 799 System *sys; 800 ThreadContext *oc; 801 uint8_t target_el; 802 uint16_t asid; 803 SCR scr; 804 805 if (misc_reg == MISCREG_CPSR) { 806 updateRegMap(val); 807 808 809 CPSR old_cpsr = miscRegs[MISCREG_CPSR]; 810 int old_mode = old_cpsr.mode; 811 CPSR cpsr = val; 812 if (old_mode != cpsr.mode) { 813 tc->getITBPtr()->invalidateMiscReg(); 814 tc->getDTBPtr()->invalidateMiscReg(); 815 } 816 817 DPRINTF(Arm, "Updating CPSR from %#x to %#x f:%d i:%d a:%d mode:%#x\n", 818 miscRegs[misc_reg], cpsr, cpsr.f, cpsr.i, cpsr.a, cpsr.mode); 819 PCState pc = tc->pcState(); 820 pc.nextThumb(cpsr.t); 821 pc.nextJazelle(cpsr.j); 822 823 // Follow slightly different semantics if a CheckerCPU object 824 // is connected 825 CheckerCPU *checker = tc->getCheckerCpuPtr(); 826 if (checker) { 827 tc->pcStateNoRecord(pc); 828 } else { 829 tc->pcState(pc); 830 } 831 } else { 832#ifndef NDEBUG 833 if (!miscRegInfo[misc_reg][MISCREG_IMPLEMENTED]) { 834 if (miscRegInfo[misc_reg][MISCREG_WARN_NOT_FAIL]) 835 warn("Unimplemented system register %s write with %#x.\n", 836 miscRegName[misc_reg], val); 837 else 838 panic("Unimplemented system register %s write with %#x.\n", 839 miscRegName[misc_reg], val); 840 } 841#endif 842 switch (unflattenMiscReg(misc_reg)) { 843 case MISCREG_CPACR: 844 { 845 846 const uint32_t ones = (uint32_t)(-1); 847 CPACR cpacrMask = 0; 848 // Only cp10, cp11, and ase are implemented, nothing else should 849 // be writable 850 cpacrMask.cp10 = ones; 851 cpacrMask.cp11 = ones; 852 cpacrMask.asedis = ones; 853 854 // Security Extensions may limit the writability of CPACR 855 if (haveSecurity) { 856 scr = readMiscRegNoEffect(MISCREG_SCR); 857 CPSR cpsr = readMiscRegNoEffect(MISCREG_CPSR); 858 if (scr.ns && (cpsr.mode != MODE_MON)) { 859 NSACR nsacr = readMiscRegNoEffect(MISCREG_NSACR); 860 // NB: Skipping the full loop, here 861 if (!nsacr.cp10) cpacrMask.cp10 = 0; 862 if (!nsacr.cp11) cpacrMask.cp11 = 0; 863 } 864 } 865 866 MiscReg old_val = readMiscRegNoEffect(MISCREG_CPACR); 867 newVal &= cpacrMask; 868 newVal |= old_val & ~cpacrMask; 869 DPRINTF(MiscRegs, "Writing misc reg %s: %#x\n", 870 miscRegName[misc_reg], newVal); 871 } 872 break; 873 case MISCREG_CPACR_EL1: 874 { 875 const uint32_t ones = (uint32_t)(-1); 876 CPACR cpacrMask = 0; 877 cpacrMask.tta = ones; 878 cpacrMask.fpen = ones; 879 newVal &= cpacrMask; 880 DPRINTF(MiscRegs, "Writing misc reg %s: %#x\n", 881 miscRegName[misc_reg], newVal); 882 } 883 break; 884 case MISCREG_CPTR_EL2: 885 { 886 const uint32_t ones = (uint32_t)(-1); 887 CPTR cptrMask = 0; 888 cptrMask.tcpac = ones; 889 cptrMask.tta = ones; 890 cptrMask.tfp = ones; 891 newVal &= cptrMask; 892 cptrMask = 0; 893 cptrMask.res1_13_12_el2 = ones; 894 cptrMask.res1_9_0_el2 = ones; 895 newVal |= cptrMask; 896 DPRINTF(MiscRegs, "Writing misc reg %s: %#x\n", 897 miscRegName[misc_reg], newVal); 898 } 899 break; 900 case MISCREG_CPTR_EL3: 901 { 902 const uint32_t ones = (uint32_t)(-1); 903 CPTR cptrMask = 0; 904 cptrMask.tcpac = ones; 905 cptrMask.tta = ones; 906 cptrMask.tfp = ones; 907 newVal &= cptrMask; 908 DPRINTF(MiscRegs, "Writing misc reg %s: %#x\n", 909 miscRegName[misc_reg], newVal); 910 } 911 break; 912 case MISCREG_CSSELR: 913 warn_once("The csselr register isn't implemented.\n"); 914 return; 915 916 case MISCREG_DC_ZVA_Xt: 917 warn("Calling DC ZVA! Not Implemeted! Expect WEIRD results\n"); 918 return; 919 920 case MISCREG_FPSCR: 921 { 922 const uint32_t ones = (uint32_t)(-1); 923 FPSCR fpscrMask = 0; 924 fpscrMask.ioc = ones; 925 fpscrMask.dzc = ones; 926 fpscrMask.ofc = ones; 927 fpscrMask.ufc = ones; 928 fpscrMask.ixc = ones; 929 fpscrMask.idc = ones; 930 fpscrMask.ioe = ones; 931 fpscrMask.dze = ones; 932 fpscrMask.ofe = ones; 933 fpscrMask.ufe = ones; 934 fpscrMask.ixe = ones; 935 fpscrMask.ide = ones; 936 fpscrMask.len = ones; 937 fpscrMask.stride = ones; 938 fpscrMask.rMode = ones; 939 fpscrMask.fz = ones; 940 fpscrMask.dn = ones; 941 fpscrMask.ahp = ones; 942 fpscrMask.qc = ones; 943 fpscrMask.v = ones; 944 fpscrMask.c = ones; 945 fpscrMask.z = ones; 946 fpscrMask.n = ones; 947 newVal = (newVal & (uint32_t)fpscrMask) | 948 (readMiscRegNoEffect(MISCREG_FPSCR) & 949 ~(uint32_t)fpscrMask); 950 tc->getDecoderPtr()->setContext(newVal); 951 } 952 break; 953 case MISCREG_FPSR: 954 { 955 const uint32_t ones = (uint32_t)(-1); 956 FPSCR fpscrMask = 0; 957 fpscrMask.ioc = ones; 958 fpscrMask.dzc = ones; 959 fpscrMask.ofc = ones; 960 fpscrMask.ufc = ones; 961 fpscrMask.ixc = ones; 962 fpscrMask.idc = ones; 963 fpscrMask.qc = ones; 964 fpscrMask.v = ones; 965 fpscrMask.c = ones; 966 fpscrMask.z = ones; 967 fpscrMask.n = ones; 968 newVal = (newVal & (uint32_t)fpscrMask) | 969 (readMiscRegNoEffect(MISCREG_FPSCR) & 970 ~(uint32_t)fpscrMask); 971 misc_reg = MISCREG_FPSCR; 972 } 973 break; 974 case MISCREG_FPCR: 975 { 976 const uint32_t ones = (uint32_t)(-1); 977 FPSCR fpscrMask = 0; 978 fpscrMask.ioe = ones; 979 fpscrMask.dze = ones; 980 fpscrMask.ofe = ones; 981 fpscrMask.ufe = ones; 982 fpscrMask.ixe = ones; 983 fpscrMask.ide = ones; 984 fpscrMask.len = ones; 985 fpscrMask.stride = ones; 986 fpscrMask.rMode = ones; 987 fpscrMask.fz = ones; 988 fpscrMask.dn = ones; 989 fpscrMask.ahp = ones; 990 newVal = (newVal & (uint32_t)fpscrMask) | 991 (readMiscRegNoEffect(MISCREG_FPSCR) & 992 ~(uint32_t)fpscrMask); 993 misc_reg = MISCREG_FPSCR; 994 } 995 break; 996 case MISCREG_CPSR_Q: 997 { 998 assert(!(newVal & ~CpsrMaskQ)); 999 newVal = readMiscRegNoEffect(MISCREG_CPSR) | newVal; 1000 misc_reg = MISCREG_CPSR; 1001 } 1002 break; 1003 case MISCREG_FPSCR_QC: 1004 { 1005 newVal = readMiscRegNoEffect(MISCREG_FPSCR) | 1006 (newVal & FpscrQcMask); 1007 misc_reg = MISCREG_FPSCR; 1008 } 1009 break; 1010 case MISCREG_FPSCR_EXC: 1011 { 1012 newVal = readMiscRegNoEffect(MISCREG_FPSCR) | 1013 (newVal & FpscrExcMask); 1014 misc_reg = MISCREG_FPSCR; 1015 } 1016 break; 1017 case MISCREG_FPEXC: 1018 { 1019 // vfpv3 architecture, section B.6.1 of DDI04068 1020 // bit 29 - valid only if fpexc[31] is 0 1021 const uint32_t fpexcMask = 0x60000000; 1022 newVal = (newVal & fpexcMask) | 1023 (readMiscRegNoEffect(MISCREG_FPEXC) & ~fpexcMask); 1024 } 1025 break; 1026 case MISCREG_HCR: 1027 { 1028 if (!haveVirtualization) 1029 return; 1030 } 1031 break; 1032 case MISCREG_IFSR: 1033 { 1034 // ARM ARM (ARM DDI 0406C.b) B4.1.96 1035 const uint32_t ifsrMask = 1036 mask(31, 13) | mask(11, 11) | mask(8, 6); 1037 newVal = newVal & ~ifsrMask; 1038 } 1039 break; 1040 case MISCREG_DFSR: 1041 { 1042 // ARM ARM (ARM DDI 0406C.b) B4.1.52 1043 const uint32_t dfsrMask = mask(31, 14) | mask(8, 8); 1044 newVal = newVal & ~dfsrMask; 1045 } 1046 break; 1047 case MISCREG_AMAIR0: 1048 case MISCREG_AMAIR1: 1049 { 1050 // ARM ARM (ARM DDI 0406C.b) B4.1.5 1051 // Valid only with LPAE 1052 if (!haveLPAE) 1053 return; 1054 DPRINTF(MiscRegs, "Writing AMAIR: %#x\n", newVal); 1055 } 1056 break; 1057 case MISCREG_SCR: 1058 tc->getITBPtr()->invalidateMiscReg(); 1059 tc->getDTBPtr()->invalidateMiscReg(); 1060 break; 1061 case MISCREG_SCTLR: 1062 { 1063 DPRINTF(MiscRegs, "Writing SCTLR: %#x\n", newVal); 1064 MiscRegIndex sctlr_idx; 1065 scr = readMiscRegNoEffect(MISCREG_SCR); 1066 if (haveSecurity && !scr.ns) { 1067 sctlr_idx = MISCREG_SCTLR_S; 1068 } else { 1069 sctlr_idx = MISCREG_SCTLR_NS; 1070 // The FI field (bit 21) is common between S/NS versions 1071 // of the register, we store this in the secure copy of 1072 // the reg 1073 miscRegs[MISCREG_SCTLR_S] &= ~(1 << 21); 1074 miscRegs[MISCREG_SCTLR_S] |= newVal & (1 << 21); 1075 } 1076 SCTLR sctlr = miscRegs[sctlr_idx]; 1077 SCTLR new_sctlr = newVal; 1078 new_sctlr.nmfi = ((bool)sctlr.nmfi) && !haveVirtualization; 1079 miscRegs[sctlr_idx] = (MiscReg)new_sctlr; 1080 tc->getITBPtr()->invalidateMiscReg(); 1081 tc->getDTBPtr()->invalidateMiscReg(); 1082 1083 // Check if all CPUs are booted with caches enabled 1084 // so we can stop enforcing coherency of some kernel 1085 // structures manually. 1086 sys = tc->getSystemPtr(); 1087 for (x = 0; x < sys->numContexts(); x++) { 1088 oc = sys->getThreadContext(x); 1089 // @todo: double check this for security 1090 SCTLR other_sctlr = oc->readMiscRegNoEffect(MISCREG_SCTLR); 1091 if (!other_sctlr.c && oc->status() != ThreadContext::Halted) 1092 return; 1093 } 1094 1095 for (x = 0; x < sys->numContexts(); x++) { 1096 oc = sys->getThreadContext(x); 1097 oc->getDTBPtr()->allCpusCaching(); 1098 oc->getITBPtr()->allCpusCaching(); 1099 1100 // If CheckerCPU is connected, need to notify it. 1101 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1102 if (checker) { 1103 checker->getDTBPtr()->allCpusCaching(); 1104 checker->getITBPtr()->allCpusCaching(); 1105 } 1106 } 1107 return; 1108 } 1109 1110 case MISCREG_MIDR: 1111 case MISCREG_ID_PFR0: 1112 case MISCREG_ID_PFR1: 1113 case MISCREG_ID_MMFR0: 1114 case MISCREG_ID_MMFR1: 1115 case MISCREG_ID_MMFR2: 1116 case MISCREG_ID_MMFR3: 1117 case MISCREG_ID_ISAR0: 1118 case MISCREG_ID_ISAR1: 1119 case MISCREG_ID_ISAR2: 1120 case MISCREG_ID_ISAR3: 1121 case MISCREG_ID_ISAR4: 1122 case MISCREG_ID_ISAR5: 1123 1124 case MISCREG_MPIDR: 1125 case MISCREG_FPSID: 1126 case MISCREG_TLBTR: 1127 case MISCREG_MVFR0: 1128 case MISCREG_MVFR1: 1129 1130 case MISCREG_ID_AA64AFR0_EL1: 1131 case MISCREG_ID_AA64AFR1_EL1: 1132 case MISCREG_ID_AA64DFR0_EL1: 1133 case MISCREG_ID_AA64DFR1_EL1: 1134 case MISCREG_ID_AA64ISAR0_EL1: 1135 case MISCREG_ID_AA64ISAR1_EL1: 1136 case MISCREG_ID_AA64MMFR0_EL1: 1137 case MISCREG_ID_AA64MMFR1_EL1: 1138 case MISCREG_ID_AA64PFR0_EL1: 1139 case MISCREG_ID_AA64PFR1_EL1: 1140 // ID registers are constants. 1141 return; 1142 1143 // TLBI all entries, EL0&1 inner sharable (ignored) 1144 case MISCREG_TLBIALLIS: 1145 case MISCREG_TLBIALL: // TLBI all entries, EL0&1, 1146 assert32(tc); 1147 target_el = 1; // el 0 and 1 are handled together 1148 scr = readMiscReg(MISCREG_SCR, tc); 1149 secure_lookup = haveSecurity && !scr.ns; 1150 sys = tc->getSystemPtr(); 1151 for (x = 0; x < sys->numContexts(); x++) { 1152 oc = sys->getThreadContext(x); 1153 assert(oc->getITBPtr() && oc->getDTBPtr()); 1154 oc->getITBPtr()->flushAllSecurity(secure_lookup, target_el); 1155 oc->getDTBPtr()->flushAllSecurity(secure_lookup, target_el); 1156 1157 // If CheckerCPU is connected, need to notify it of a flush 1158 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1159 if (checker) { 1160 checker->getITBPtr()->flushAllSecurity(secure_lookup, 1161 target_el); 1162 checker->getDTBPtr()->flushAllSecurity(secure_lookup, 1163 target_el); 1164 } 1165 } 1166 return; 1167 // TLBI all entries, EL0&1, instruction side 1168 case MISCREG_ITLBIALL: 1169 assert32(tc); 1170 target_el = 1; // el 0 and 1 are handled together 1171 scr = readMiscReg(MISCREG_SCR, tc); 1172 secure_lookup = haveSecurity && !scr.ns; 1173 tc->getITBPtr()->flushAllSecurity(secure_lookup, target_el); 1174 return; 1175 // TLBI all entries, EL0&1, data side 1176 case MISCREG_DTLBIALL: 1177 assert32(tc); 1178 target_el = 1; // el 0 and 1 are handled together 1179 scr = readMiscReg(MISCREG_SCR, tc); 1180 secure_lookup = haveSecurity && !scr.ns; 1181 tc->getDTBPtr()->flushAllSecurity(secure_lookup, target_el); 1182 return; 1183 // TLBI based on VA, EL0&1 inner sharable (ignored) 1184 case MISCREG_TLBIMVAIS: 1185 case MISCREG_TLBIMVA: 1186 assert32(tc); 1187 target_el = 1; // el 0 and 1 are handled together 1188 scr = readMiscReg(MISCREG_SCR, tc); 1189 secure_lookup = haveSecurity && !scr.ns; 1190 sys = tc->getSystemPtr(); 1191 for (x = 0; x < sys->numContexts(); x++) { 1192 oc = sys->getThreadContext(x); 1193 assert(oc->getITBPtr() && oc->getDTBPtr()); 1194 oc->getITBPtr()->flushMvaAsid(mbits(newVal, 31, 12), 1195 bits(newVal, 7,0), 1196 secure_lookup, target_el); 1197 oc->getDTBPtr()->flushMvaAsid(mbits(newVal, 31, 12), 1198 bits(newVal, 7,0), 1199 secure_lookup, target_el); 1200 1201 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1202 if (checker) { 1203 checker->getITBPtr()->flushMvaAsid(mbits(newVal, 31, 12), 1204 bits(newVal, 7,0), secure_lookup, target_el); 1205 checker->getDTBPtr()->flushMvaAsid(mbits(newVal, 31, 12), 1206 bits(newVal, 7,0), secure_lookup, target_el); 1207 } 1208 } 1209 return; 1210 // TLBI by ASID, EL0&1, inner sharable 1211 case MISCREG_TLBIASIDIS: 1212 case MISCREG_TLBIASID: 1213 assert32(tc); 1214 target_el = 1; // el 0 and 1 are handled together 1215 scr = readMiscReg(MISCREG_SCR, tc); 1216 secure_lookup = haveSecurity && !scr.ns; 1217 sys = tc->getSystemPtr(); 1218 for (x = 0; x < sys->numContexts(); x++) { 1219 oc = sys->getThreadContext(x); 1220 assert(oc->getITBPtr() && oc->getDTBPtr()); 1221 oc->getITBPtr()->flushAsid(bits(newVal, 7,0), 1222 secure_lookup, target_el); 1223 oc->getDTBPtr()->flushAsid(bits(newVal, 7,0), 1224 secure_lookup, target_el); 1225 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1226 if (checker) { 1227 checker->getITBPtr()->flushAsid(bits(newVal, 7,0), 1228 secure_lookup, target_el); 1229 checker->getDTBPtr()->flushAsid(bits(newVal, 7,0), 1230 secure_lookup, target_el); 1231 } 1232 } 1233 return; 1234 // TLBI by address, EL0&1, inner sharable (ignored) 1235 case MISCREG_TLBIMVAAIS: 1236 case MISCREG_TLBIMVAA: 1237 assert32(tc); 1238 target_el = 1; // el 0 and 1 are handled together 1239 scr = readMiscReg(MISCREG_SCR, tc); 1240 secure_lookup = haveSecurity && !scr.ns; 1241 hyp = 0; 1242 tlbiMVA(tc, newVal, secure_lookup, hyp, target_el); 1243 return; 1244 // TLBI by address, EL2, hypervisor mode 1245 case MISCREG_TLBIMVAH: 1246 case MISCREG_TLBIMVAHIS: 1247 assert32(tc); 1248 target_el = 1; // aarch32, use hyp bit 1249 scr = readMiscReg(MISCREG_SCR, tc); 1250 secure_lookup = haveSecurity && !scr.ns; 1251 hyp = 1; 1252 tlbiMVA(tc, newVal, secure_lookup, hyp, target_el); 1253 return; 1254 // TLBI by address and asid, EL0&1, instruction side only 1255 case MISCREG_ITLBIMVA: 1256 assert32(tc); 1257 target_el = 1; // el 0 and 1 are handled together 1258 scr = readMiscReg(MISCREG_SCR, tc); 1259 secure_lookup = haveSecurity && !scr.ns; 1260 tc->getITBPtr()->flushMvaAsid(mbits(newVal, 31, 12), 1261 bits(newVal, 7,0), secure_lookup, target_el); 1262 return; 1263 // TLBI by address and asid, EL0&1, data side only 1264 case MISCREG_DTLBIMVA: 1265 assert32(tc); 1266 target_el = 1; // el 0 and 1 are handled together 1267 scr = readMiscReg(MISCREG_SCR, tc); 1268 secure_lookup = haveSecurity && !scr.ns; 1269 tc->getDTBPtr()->flushMvaAsid(mbits(newVal, 31, 12), 1270 bits(newVal, 7,0), secure_lookup, target_el); 1271 return; 1272 // TLBI by ASID, EL0&1, instrution side only 1273 case MISCREG_ITLBIASID: 1274 assert32(tc); 1275 target_el = 1; // el 0 and 1 are handled together 1276 scr = readMiscReg(MISCREG_SCR, tc); 1277 secure_lookup = haveSecurity && !scr.ns; 1278 tc->getITBPtr()->flushAsid(bits(newVal, 7,0), secure_lookup, 1279 target_el); 1280 return; 1281 // TLBI by ASID EL0&1 data size only 1282 case MISCREG_DTLBIASID: 1283 assert32(tc); 1284 target_el = 1; // el 0 and 1 are handled together 1285 scr = readMiscReg(MISCREG_SCR, tc); 1286 secure_lookup = haveSecurity && !scr.ns; 1287 tc->getDTBPtr()->flushAsid(bits(newVal, 7,0), secure_lookup, 1288 target_el); 1289 return; 1290 // Invalidate entire Non-secure Hyp/Non-Hyp Unified TLB 1291 case MISCREG_TLBIALLNSNH: 1292 case MISCREG_TLBIALLNSNHIS: 1293 assert32(tc); 1294 target_el = 1; // el 0 and 1 are handled together 1295 hyp = 0; 1296 tlbiALLN(tc, hyp, target_el); 1297 return; 1298 // TLBI all entries, EL2, hyp, 1299 case MISCREG_TLBIALLH: 1300 case MISCREG_TLBIALLHIS: 1301 assert32(tc); 1302 target_el = 1; // aarch32, use hyp bit 1303 hyp = 1; 1304 tlbiALLN(tc, hyp, target_el); 1305 return; 1306 // AArch64 TLBI: invalidate all entries EL3 1307 case MISCREG_TLBI_ALLE3IS: 1308 case MISCREG_TLBI_ALLE3: 1309 assert64(tc); 1310 target_el = 3; 1311 secure_lookup = true; 1312 tlbiALL(tc, secure_lookup, target_el); 1313 return; 1314 // @todo: uncomment this to enable Virtualization 1315 // case MISCREG_TLBI_ALLE2IS: 1316 // case MISCREG_TLBI_ALLE2: 1317 // TLBI all entries, EL0&1 1318 case MISCREG_TLBI_ALLE1IS: 1319 case MISCREG_TLBI_ALLE1: 1320 // AArch64 TLBI: invalidate all entries, stage 1, current VMID 1321 case MISCREG_TLBI_VMALLE1IS: 1322 case MISCREG_TLBI_VMALLE1: 1323 // AArch64 TLBI: invalidate all entries, stages 1 & 2, current VMID 1324 case MISCREG_TLBI_VMALLS12E1IS: 1325 case MISCREG_TLBI_VMALLS12E1: 1326 // @todo: handle VMID and stage 2 to enable Virtualization 1327 assert64(tc); 1328 target_el = 1; // el 0 and 1 are handled together 1329 scr = readMiscReg(MISCREG_SCR, tc); 1330 secure_lookup = haveSecurity && !scr.ns; 1331 tlbiALL(tc, secure_lookup, target_el); 1332 return; 1333 // AArch64 TLBI: invalidate by VA and ASID, stage 1, current VMID 1334 // VAEx(IS) and VALEx(IS) are the same because TLBs only store entries 1335 // from the last level of translation table walks 1336 // @todo: handle VMID to enable Virtualization 1337 // TLBI all entries, EL0&1 1338 case MISCREG_TLBI_VAE3IS_Xt: 1339 case MISCREG_TLBI_VAE3_Xt: 1340 // TLBI by VA, EL3 regime stage 1, last level walk 1341 case MISCREG_TLBI_VALE3IS_Xt: 1342 case MISCREG_TLBI_VALE3_Xt: 1343 assert64(tc); 1344 target_el = 3; 1345 asid = 0xbeef; // does not matter, tlbi is global 1346 secure_lookup = true; 1347 tlbiVA(tc, newVal, asid, secure_lookup, target_el); 1348 return; 1349 // TLBI by VA, EL2 1350 case MISCREG_TLBI_VAE2IS_Xt: 1351 case MISCREG_TLBI_VAE2_Xt: 1352 // TLBI by VA, EL2, stage1 last level walk 1353 case MISCREG_TLBI_VALE2IS_Xt: 1354 case MISCREG_TLBI_VALE2_Xt: 1355 assert64(tc); 1356 target_el = 2; 1357 asid = 0xbeef; // does not matter, tlbi is global 1358 scr = readMiscReg(MISCREG_SCR, tc); 1359 secure_lookup = haveSecurity && !scr.ns; 1360 tlbiVA(tc, newVal, asid, secure_lookup, target_el); 1361 return; 1362 // TLBI by VA EL1 & 0, stage1, ASID, current VMID 1363 case MISCREG_TLBI_VAE1IS_Xt: 1364 case MISCREG_TLBI_VAE1_Xt: 1365 case MISCREG_TLBI_VALE1IS_Xt: 1366 case MISCREG_TLBI_VALE1_Xt: 1367 assert64(tc); 1368 asid = bits(newVal, 63, 48); 1369 target_el = 1; // el 0 and 1 are handled together 1370 scr = readMiscReg(MISCREG_SCR, tc); 1371 secure_lookup = haveSecurity && !scr.ns; 1372 tlbiVA(tc, newVal, asid, secure_lookup, target_el); 1373 return; 1374 // AArch64 TLBI: invalidate by ASID, stage 1, current VMID 1375 // @todo: handle VMID to enable Virtualization 1376 case MISCREG_TLBI_ASIDE1IS_Xt: 1377 case MISCREG_TLBI_ASIDE1_Xt: 1378 assert64(tc); 1379 target_el = 1; // el 0 and 1 are handled together 1380 scr = readMiscReg(MISCREG_SCR, tc); 1381 secure_lookup = haveSecurity && !scr.ns; 1382 sys = tc->getSystemPtr(); 1383 for (x = 0; x < sys->numContexts(); x++) { 1384 oc = sys->getThreadContext(x); 1385 assert(oc->getITBPtr() && oc->getDTBPtr()); 1386 asid = bits(newVal, 63, 48); 1387 if (haveLargeAsid64) 1388 asid &= mask(8); 1389 oc->getITBPtr()->flushAsid(asid, secure_lookup, target_el); 1390 oc->getDTBPtr()->flushAsid(asid, secure_lookup, target_el); 1391 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1392 if (checker) { 1393 checker->getITBPtr()->flushAsid(asid, 1394 secure_lookup, target_el); 1395 checker->getDTBPtr()->flushAsid(asid, 1396 secure_lookup, target_el); 1397 } 1398 } 1399 return; 1400 // AArch64 TLBI: invalidate by VA, ASID, stage 1, current VMID 1401 // VAAE1(IS) and VAALE1(IS) are the same because TLBs only store 1402 // entries from the last level of translation table walks 1403 // @todo: handle VMID to enable Virtualization 1404 case MISCREG_TLBI_VAAE1IS_Xt: 1405 case MISCREG_TLBI_VAAE1_Xt: 1406 case MISCREG_TLBI_VAALE1IS_Xt: 1407 case MISCREG_TLBI_VAALE1_Xt: 1408 assert64(tc); 1409 target_el = 1; // el 0 and 1 are handled together 1410 scr = readMiscReg(MISCREG_SCR, tc); 1411 secure_lookup = haveSecurity && !scr.ns; 1412 sys = tc->getSystemPtr(); 1413 for (x = 0; x < sys->numContexts(); x++) { 1414 // @todo: extra controls on TLBI broadcast? 1415 oc = sys->getThreadContext(x); 1416 assert(oc->getITBPtr() && oc->getDTBPtr()); 1417 Addr va = ((Addr) bits(newVal, 43, 0)) << 12; 1418 oc->getITBPtr()->flushMva(va, 1419 secure_lookup, false, target_el); 1420 oc->getDTBPtr()->flushMva(va, 1421 secure_lookup, false, target_el); 1422 1423 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1424 if (checker) { 1425 checker->getITBPtr()->flushMva(va, 1426 secure_lookup, false, target_el); 1427 checker->getDTBPtr()->flushMva(va, 1428 secure_lookup, false, target_el); 1429 } 1430 } 1431 return; 1432 // AArch64 TLBI: invalidate by IPA, stage 2, current VMID 1433 case MISCREG_TLBI_IPAS2LE1IS_Xt: 1434 case MISCREG_TLBI_IPAS2LE1_Xt: 1435 case MISCREG_TLBI_IPAS2E1IS_Xt: 1436 case MISCREG_TLBI_IPAS2E1_Xt: 1437 assert64(tc); 1438 // @todo: implement these as part of Virtualization 1439 warn("Not doing anything for write of miscreg ITLB_IPAS2\n"); 1440 return; 1441 case MISCREG_ACTLR: 1442 warn("Not doing anything for write of miscreg ACTLR\n"); 1443 break; 1444 case MISCREG_PMCR: 1445 { 1446 // Performance counters not implemented. Instead, interpret 1447 // a reset command to this register to reset the simulator 1448 // statistics. 1449 // PMCR_E | PMCR_P | PMCR_C 1450 const int ResetAndEnableCounters = 0x7; 1451 if (newVal == ResetAndEnableCounters) { 1452 inform("Resetting all simobject stats\n"); 1453 Stats::schedStatEvent(false, true); 1454 break; 1455 } 1456 } 1457 case MISCREG_PMCCNTR: 1458 case MISCREG_PMSELR: 1459 warn("Not doing anything for write to miscreg %s\n", 1460 miscRegName[misc_reg]); 1461 break; 1462 case MISCREG_HSTR: // TJDBX, now redifined to be RES0 1463 { 1464 HSTR hstrMask = 0; 1465 hstrMask.tjdbx = 1; 1466 newVal &= ~((uint32_t) hstrMask); 1467 break; 1468 } 1469 case MISCREG_HCPTR: 1470 { 1471 // If a CP bit in NSACR is 0 then the corresponding bit in 1472 // HCPTR is RAO/WI. Same applies to NSASEDIS 1473 secure_lookup = haveSecurity && 1474 inSecureState(readMiscRegNoEffect(MISCREG_SCR), 1475 readMiscRegNoEffect(MISCREG_CPSR)); 1476 if (!secure_lookup) { 1477 MiscReg oldValue = readMiscRegNoEffect(MISCREG_HCPTR); 1478 MiscReg mask = (readMiscRegNoEffect(MISCREG_NSACR) ^ 0x7FFF) & 0xBFFF; 1479 newVal = (newVal & ~mask) | (oldValue & mask); 1480 } 1481 break; 1482 } 1483 case MISCREG_HDFAR: // alias for secure DFAR 1484 misc_reg = MISCREG_DFAR_S; 1485 break; 1486 case MISCREG_HIFAR: // alias for secure IFAR 1487 misc_reg = MISCREG_IFAR_S; 1488 break; 1489 case MISCREG_ATS1CPR: 1490 case MISCREG_ATS1CPW: 1491 case MISCREG_ATS1CUR: 1492 case MISCREG_ATS1CUW: 1493 case MISCREG_ATS12NSOPR: 1494 case MISCREG_ATS12NSOPW: 1495 case MISCREG_ATS12NSOUR: 1496 case MISCREG_ATS12NSOUW: 1497 case MISCREG_ATS1HR: 1498 case MISCREG_ATS1HW: 1499 { 1500 RequestPtr req = new Request; 1501 unsigned flags = 0; 1502 BaseTLB::Mode mode = BaseTLB::Read; 1503 TLB::ArmTranslationType tranType = TLB::NormalTran; 1504 Fault fault; 1505 switch(misc_reg) { 1506 case MISCREG_ATS1CPR: 1507 flags = TLB::MustBeOne; 1508 tranType = TLB::S1CTran; 1509 mode = BaseTLB::Read; 1510 break; 1511 case MISCREG_ATS1CPW: 1512 flags = TLB::MustBeOne; 1513 tranType = TLB::S1CTran; 1514 mode = BaseTLB::Write; 1515 break; 1516 case MISCREG_ATS1CUR: 1517 flags = TLB::MustBeOne | TLB::UserMode; 1518 tranType = TLB::S1CTran; 1519 mode = BaseTLB::Read; 1520 break; 1521 case MISCREG_ATS1CUW: 1522 flags = TLB::MustBeOne | TLB::UserMode; 1523 tranType = TLB::S1CTran; 1524 mode = BaseTLB::Write; 1525 break; 1526 case MISCREG_ATS12NSOPR: 1527 if (!haveSecurity) 1528 panic("Security Extensions required for ATS12NSOPR"); 1529 flags = TLB::MustBeOne; 1530 tranType = TLB::S1S2NsTran; 1531 mode = BaseTLB::Read; 1532 break; 1533 case MISCREG_ATS12NSOPW: 1534 if (!haveSecurity) 1535 panic("Security Extensions required for ATS12NSOPW"); 1536 flags = TLB::MustBeOne; 1537 tranType = TLB::S1S2NsTran; 1538 mode = BaseTLB::Write; 1539 break; 1540 case MISCREG_ATS12NSOUR: 1541 if (!haveSecurity) 1542 panic("Security Extensions required for ATS12NSOUR"); 1543 flags = TLB::MustBeOne | TLB::UserMode; 1544 tranType = TLB::S1S2NsTran; 1545 mode = BaseTLB::Read; 1546 break; 1547 case MISCREG_ATS12NSOUW: 1548 if (!haveSecurity) 1549 panic("Security Extensions required for ATS12NSOUW"); 1550 flags = TLB::MustBeOne | TLB::UserMode; 1551 tranType = TLB::S1S2NsTran; 1552 mode = BaseTLB::Write; 1553 break; 1554 case MISCREG_ATS1HR: // only really useful from secure mode. 1555 flags = TLB::MustBeOne; 1556 tranType = TLB::HypMode; 1557 mode = BaseTLB::Read; 1558 break; 1559 case MISCREG_ATS1HW: 1560 flags = TLB::MustBeOne; 1561 tranType = TLB::HypMode; 1562 mode = BaseTLB::Write; 1563 break; 1564 } 1565 // If we're in timing mode then doing the translation in 1566 // functional mode then we're slightly distorting performance 1567 // results obtained from simulations. The translation should be 1568 // done in the same mode the core is running in. NOTE: This 1569 // can't be an atomic translation because that causes problems 1570 // with unexpected atomic snoop requests. 1571 warn("Translating via MISCREG(%d) in functional mode! Fix Me!\n", misc_reg); 1572 req->setVirt(0, val, 1, flags, Request::funcMasterId, 1573 tc->pcState().pc()); 1574 req->setThreadContext(tc->contextId(), tc->threadId()); 1575 fault = tc->getDTBPtr()->translateFunctional(req, tc, mode, tranType); 1576 TTBCR ttbcr = readMiscRegNoEffect(MISCREG_TTBCR); 1577 HCR hcr = readMiscRegNoEffect(MISCREG_HCR); 1578 1579 MiscReg newVal; 1580 if (fault == NoFault) { 1581 Addr paddr = req->getPaddr(); 1582 if (haveLPAE && (ttbcr.eae || tranType & TLB::HypMode || 1583 ((tranType & TLB::S1S2NsTran) && hcr.vm) )) { 1584 newVal = (paddr & mask(39, 12)) | 1585 (tc->getDTBPtr()->getAttr()); 1586 } else { 1587 newVal = (paddr & 0xfffff000) | 1588 (tc->getDTBPtr()->getAttr()); 1589 } 1590 DPRINTF(MiscRegs, 1591 "MISCREG: Translated addr 0x%08x: PAR: 0x%08x\n", 1592 val, newVal); 1593 } else { 1594 ArmFault *armFault = reinterpret_cast<ArmFault *>(fault.get()); 1595 // Set fault bit and FSR 1596 FSR fsr = armFault->getFsr(tc); 1597 1598 newVal = ((fsr >> 9) & 1) << 11; 1599 if (newVal) { 1600 // LPAE - rearange fault status 1601 newVal |= ((fsr >> 0) & 0x3f) << 1; 1602 } else { 1603 // VMSA - rearange fault status 1604 newVal |= ((fsr >> 0) & 0xf) << 1; 1605 newVal |= ((fsr >> 10) & 0x1) << 5; 1606 newVal |= ((fsr >> 12) & 0x1) << 6; 1607 } 1608 newVal |= 0x1; // F bit 1609 newVal |= ((armFault->iss() >> 7) & 0x1) << 8; 1610 newVal |= armFault->isStage2() ? 0x200 : 0; 1611 DPRINTF(MiscRegs, 1612 "MISCREG: Translated addr 0x%08x fault fsr %#x: PAR: 0x%08x\n", 1613 val, fsr, newVal); 1614 } 1615 delete req; 1616 setMiscRegNoEffect(MISCREG_PAR, newVal); 1617 return; 1618 } 1619 case MISCREG_TTBCR: 1620 { 1621 TTBCR ttbcr = readMiscRegNoEffect(MISCREG_TTBCR); 1622 const uint32_t ones = (uint32_t)(-1); 1623 TTBCR ttbcrMask = 0; 1624 TTBCR ttbcrNew = newVal; 1625 1626 // ARM DDI 0406C.b, ARMv7-32 1627 ttbcrMask.n = ones; // T0SZ 1628 if (haveSecurity) { 1629 ttbcrMask.pd0 = ones; 1630 ttbcrMask.pd1 = ones; 1631 } 1632 ttbcrMask.epd0 = ones; 1633 ttbcrMask.irgn0 = ones; 1634 ttbcrMask.orgn0 = ones; 1635 ttbcrMask.sh0 = ones; 1636 ttbcrMask.ps = ones; // T1SZ 1637 ttbcrMask.a1 = ones; 1638 ttbcrMask.epd1 = ones; 1639 ttbcrMask.irgn1 = ones; 1640 ttbcrMask.orgn1 = ones; 1641 ttbcrMask.sh1 = ones; 1642 if (haveLPAE) 1643 ttbcrMask.eae = ones; 1644 1645 if (haveLPAE && ttbcrNew.eae) { 1646 newVal = newVal & ttbcrMask; 1647 } else { 1648 newVal = (newVal & ttbcrMask) | (ttbcr & (~ttbcrMask)); 1649 } 1650 } 1651 case MISCREG_TTBR0: 1652 case MISCREG_TTBR1: 1653 { 1654 TTBCR ttbcr = readMiscRegNoEffect(MISCREG_TTBCR); 1655 if (haveLPAE) { 1656 if (ttbcr.eae) { 1657 // ARMv7 bit 63-56, 47-40 reserved, UNK/SBZP 1658 // ARMv8 AArch32 bit 63-56 only 1659 uint64_t ttbrMask = mask(63,56) | mask(47,40); 1660 newVal = (newVal & (~ttbrMask)); 1661 } 1662 } 1663 } 1664 case MISCREG_CONTEXTIDR: 1665 case MISCREG_PRRR: 1666 case MISCREG_NMRR: 1667 case MISCREG_MAIR0: 1668 case MISCREG_MAIR1: 1669 case MISCREG_DACR: 1670 case MISCREG_VTTBR: 1671 case MISCREG_SCR_EL3: 1672 case MISCREG_SCTLR_EL1: 1673 case MISCREG_SCTLR_EL2: 1674 case MISCREG_SCTLR_EL3: 1675 case MISCREG_TCR_EL1: 1676 case MISCREG_TCR_EL2: 1677 case MISCREG_TCR_EL3: 1678 case MISCREG_TTBR0_EL1: 1679 case MISCREG_TTBR1_EL1: 1680 case MISCREG_TTBR0_EL2: 1681 case MISCREG_TTBR0_EL3: 1682 tc->getITBPtr()->invalidateMiscReg(); 1683 tc->getDTBPtr()->invalidateMiscReg(); 1684 break; 1685 case MISCREG_NZCV: 1686 { 1687 CPSR cpsr = val; 1688 1689 tc->setIntReg(INTREG_CONDCODES_NZ, cpsr.nz); 1690 tc->setIntReg(INTREG_CONDCODES_C, cpsr.c); 1691 tc->setIntReg(INTREG_CONDCODES_V, cpsr.v); 1692 } 1693 break; 1694 case MISCREG_DAIF: 1695 { 1696 CPSR cpsr = miscRegs[MISCREG_CPSR]; 1697 cpsr.daif = (uint8_t) ((CPSR) newVal).daif; 1698 newVal = cpsr; 1699 misc_reg = MISCREG_CPSR; 1700 } 1701 break; 1702 case MISCREG_SP_EL0: 1703 tc->setIntReg(INTREG_SP0, newVal); 1704 break; 1705 case MISCREG_SP_EL1: 1706 tc->setIntReg(INTREG_SP1, newVal); 1707 break; 1708 case MISCREG_SP_EL2: 1709 tc->setIntReg(INTREG_SP2, newVal); 1710 break; 1711 case MISCREG_SPSEL: 1712 { 1713 CPSR cpsr = miscRegs[MISCREG_CPSR]; 1714 cpsr.sp = (uint8_t) ((CPSR) newVal).sp; 1715 newVal = cpsr; 1716 misc_reg = MISCREG_CPSR; 1717 } 1718 break; 1719 case MISCREG_CURRENTEL: 1720 { 1721 CPSR cpsr = miscRegs[MISCREG_CPSR]; 1722 cpsr.el = (uint8_t) ((CPSR) newVal).el; 1723 newVal = cpsr; 1724 misc_reg = MISCREG_CPSR; 1725 } 1726 break; 1727 case MISCREG_AT_S1E1R_Xt: 1728 case MISCREG_AT_S1E1W_Xt: 1729 case MISCREG_AT_S1E0R_Xt: 1730 case MISCREG_AT_S1E0W_Xt: 1731 case MISCREG_AT_S1E2R_Xt: 1732 case MISCREG_AT_S1E2W_Xt: 1733 case MISCREG_AT_S12E1R_Xt: 1734 case MISCREG_AT_S12E1W_Xt: 1735 case MISCREG_AT_S12E0R_Xt: 1736 case MISCREG_AT_S12E0W_Xt: 1737 case MISCREG_AT_S1E3R_Xt: 1738 case MISCREG_AT_S1E3W_Xt: 1739 { 1740 RequestPtr req = new Request; 1741 unsigned flags = 0; 1742 BaseTLB::Mode mode = BaseTLB::Read; 1743 TLB::ArmTranslationType tranType = TLB::NormalTran; 1744 Fault fault; 1745 switch(misc_reg) { 1746 case MISCREG_AT_S1E1R_Xt: 1747 flags = TLB::MustBeOne; 1748 tranType = TLB::S1CTran; 1749 mode = BaseTLB::Read; 1750 break; 1751 case MISCREG_AT_S1E1W_Xt: 1752 flags = TLB::MustBeOne; 1753 tranType = TLB::S1CTran; 1754 mode = BaseTLB::Write; 1755 break; 1756 case MISCREG_AT_S1E0R_Xt: 1757 flags = TLB::MustBeOne | TLB::UserMode; 1758 tranType = TLB::S1CTran; 1759 mode = BaseTLB::Read; 1760 break; 1761 case MISCREG_AT_S1E0W_Xt: 1762 flags = TLB::MustBeOne | TLB::UserMode; 1763 tranType = TLB::S1CTran; 1764 mode = BaseTLB::Write; 1765 break; 1766 case MISCREG_AT_S1E2R_Xt: 1767 flags = TLB::MustBeOne; 1768 tranType = TLB::HypMode; 1769 mode = BaseTLB::Read; 1770 break; 1771 case MISCREG_AT_S1E2W_Xt: 1772 flags = TLB::MustBeOne; 1773 tranType = TLB::HypMode; 1774 mode = BaseTLB::Write; 1775 break; 1776 case MISCREG_AT_S12E0R_Xt: 1777 flags = TLB::MustBeOne | TLB::UserMode; 1778 tranType = TLB::S1S2NsTran; 1779 mode = BaseTLB::Read; 1780 break; 1781 case MISCREG_AT_S12E0W_Xt: 1782 flags = TLB::MustBeOne | TLB::UserMode; 1783 tranType = TLB::S1S2NsTran; 1784 mode = BaseTLB::Write; 1785 break; 1786 case MISCREG_AT_S12E1R_Xt: 1787 flags = TLB::MustBeOne; 1788 tranType = TLB::S1S2NsTran; 1789 mode = BaseTLB::Read; 1790 break; 1791 case MISCREG_AT_S12E1W_Xt: 1792 flags = TLB::MustBeOne; 1793 tranType = TLB::S1S2NsTran; 1794 mode = BaseTLB::Write; 1795 break; 1796 case MISCREG_AT_S1E3R_Xt: 1797 flags = TLB::MustBeOne; 1798 tranType = TLB::HypMode; // There is no TZ mode defined. 1799 mode = BaseTLB::Read; 1800 break; 1801 case MISCREG_AT_S1E3W_Xt: 1802 flags = TLB::MustBeOne; 1803 tranType = TLB::HypMode; // There is no TZ mode defined. 1804 mode = BaseTLB::Write; 1805 break; 1806 } 1807 // If we're in timing mode then doing the translation in 1808 // functional mode then we're slightly distorting performance 1809 // results obtained from simulations. The translation should be 1810 // done in the same mode the core is running in. NOTE: This 1811 // can't be an atomic translation because that causes problems 1812 // with unexpected atomic snoop requests. 1813 warn("Translating via MISCREG(%d) in functional mode! Fix Me!\n", misc_reg); 1814 req->setVirt(0, val, 1, flags, Request::funcMasterId, 1815 tc->pcState().pc()); 1816 req->setThreadContext(tc->contextId(), tc->threadId()); 1817 fault = tc->getDTBPtr()->translateFunctional(req, tc, mode, 1818 tranType); 1819 1820 MiscReg newVal; 1821 if (fault == NoFault) { 1822 Addr paddr = req->getPaddr(); 1823 uint64_t attr = tc->getDTBPtr()->getAttr(); 1824 uint64_t attr1 = attr >> 56; 1825 if (!attr1 || attr1 ==0x44) { 1826 attr |= 0x100; 1827 attr &= ~ uint64_t(0x80); 1828 } 1829 newVal = (paddr & mask(47, 12)) | attr; 1830 DPRINTF(MiscRegs, 1831 "MISCREG: Translated addr %#x: PAR_EL1: %#xx\n", 1832 val, newVal); 1833 } else { 1834 ArmFault *armFault = reinterpret_cast<ArmFault *>(fault.get()); 1835 // Set fault bit and FSR 1836 FSR fsr = armFault->getFsr(tc); 1837 1838 newVal = ((fsr >> 9) & 1) << 11; 1839 // rearange fault status 1840 newVal |= ((fsr >> 0) & 0x3f) << 1; 1841 newVal |= 0x1; // F bit 1842 newVal |= ((armFault->iss() >> 7) & 0x1) << 8; 1843 newVal |= armFault->isStage2() ? 0x200 : 0; 1844 DPRINTF(MiscRegs, 1845 "MISCREG: Translated addr %#x fault fsr %#x: PAR: %#x\n", 1846 val, fsr, newVal); 1847 } 1848 delete req; 1849 setMiscRegNoEffect(MISCREG_PAR_EL1, newVal); 1850 return; 1851 } 1852 case MISCREG_SPSR_EL3: 1853 case MISCREG_SPSR_EL2: 1854 case MISCREG_SPSR_EL1: 1855 // Force bits 23:21 to 0 1856 newVal = val & ~(0x7 << 21); 1857 break; 1858 case MISCREG_L2CTLR: 1859 warn("miscreg L2CTLR (%s) written with %#x. ignored...\n", 1860 miscRegName[misc_reg], uint32_t(val)); 1861 break; 1862 1863 // Generic Timer registers 1864 case MISCREG_CNTFRQ: 1865 case MISCREG_CNTFRQ_EL0: 1866 getSystemCounter(tc)->setFreq(val); 1867 break; 1868 case MISCREG_CNTP_CVAL: 1869 case MISCREG_CNTP_CVAL_EL0: 1870 getArchTimer(tc, tc->cpuId())->setCompareValue(val); 1871 break; 1872 case MISCREG_CNTP_TVAL: 1873 case MISCREG_CNTP_TVAL_EL0: 1874 getArchTimer(tc, tc->cpuId())->setTimerValue(val); 1875 break; 1876 case MISCREG_CNTP_CTL: 1877 case MISCREG_CNTP_CTL_EL0: 1878 getArchTimer(tc, tc->cpuId())->setControl(val); 1879 break; 1880 // PL1 phys. timer, secure 1881 // AArch64 1882 case MISCREG_CNTPS_CVAL_EL1: 1883 case MISCREG_CNTPS_TVAL_EL1: 1884 case MISCREG_CNTPS_CTL_EL1: 1885 // PL2 phys. timer, non-secure 1886 // AArch32 1887 case MISCREG_CNTHCTL: 1888 case MISCREG_CNTHP_CVAL: 1889 case MISCREG_CNTHP_TVAL: 1890 case MISCREG_CNTHP_CTL: 1891 // AArch64 1892 case MISCREG_CNTHCTL_EL2: 1893 case MISCREG_CNTHP_CVAL_EL2: 1894 case MISCREG_CNTHP_TVAL_EL2: 1895 case MISCREG_CNTHP_CTL_EL2: 1896 // Virtual timer 1897 // AArch32 1898 case MISCREG_CNTV_CVAL: 1899 case MISCREG_CNTV_TVAL: 1900 case MISCREG_CNTV_CTL: 1901 // AArch64 1902 // case MISCREG_CNTV_CVAL_EL2: 1903 // case MISCREG_CNTV_TVAL_EL2: 1904 // case MISCREG_CNTV_CTL_EL2: 1905 panic("Generic Timer register not implemented\n"); 1906 break; 1907 } 1908 } 1909 setMiscRegNoEffect(misc_reg, newVal); 1910} 1911 1912void 1913ISA::tlbiVA(ThreadContext *tc, MiscReg newVal, uint8_t asid, bool secure_lookup, 1914 uint8_t target_el) 1915{ 1916 if (haveLargeAsid64) 1917 asid &= mask(8); 1918 Addr va = ((Addr) bits(newVal, 43, 0)) << 12; 1919 System *sys = tc->getSystemPtr(); 1920 for (int x = 0; x < sys->numContexts(); x++) { 1921 ThreadContext *oc = sys->getThreadContext(x); 1922 assert(oc->getITBPtr() && oc->getDTBPtr()); 1923 oc->getITBPtr()->flushMvaAsid(va, asid, 1924 secure_lookup, target_el); 1925 oc->getDTBPtr()->flushMvaAsid(va, asid, 1926 secure_lookup, target_el); 1927 1928 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1929 if (checker) { 1930 checker->getITBPtr()->flushMvaAsid( 1931 va, asid, secure_lookup, target_el); 1932 checker->getDTBPtr()->flushMvaAsid( 1933 va, asid, secure_lookup, target_el); 1934 } 1935 } 1936} 1937 1938void 1939ISA::tlbiALL(ThreadContext *tc, bool secure_lookup, uint8_t target_el) 1940{ 1941 System *sys = tc->getSystemPtr(); 1942 for (int x = 0; x < sys->numContexts(); x++) { 1943 ThreadContext *oc = sys->getThreadContext(x); 1944 assert(oc->getITBPtr() && oc->getDTBPtr()); 1945 oc->getITBPtr()->flushAllSecurity(secure_lookup, target_el); 1946 oc->getDTBPtr()->flushAllSecurity(secure_lookup, target_el); 1947 1948 // If CheckerCPU is connected, need to notify it of a flush 1949 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1950 if (checker) { 1951 checker->getITBPtr()->flushAllSecurity(secure_lookup, 1952 target_el); 1953 checker->getDTBPtr()->flushAllSecurity(secure_lookup, 1954 target_el); 1955 } 1956 } 1957} 1958 1959void 1960ISA::tlbiALLN(ThreadContext *tc, bool hyp, uint8_t target_el) 1961{ 1962 System *sys = tc->getSystemPtr(); 1963 for (int x = 0; x < sys->numContexts(); x++) { 1964 ThreadContext *oc = sys->getThreadContext(x); 1965 assert(oc->getITBPtr() && oc->getDTBPtr()); 1966 oc->getITBPtr()->flushAllNs(hyp, target_el); 1967 oc->getDTBPtr()->flushAllNs(hyp, target_el); 1968 1969 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1970 if (checker) { 1971 checker->getITBPtr()->flushAllNs(hyp, target_el); 1972 checker->getDTBPtr()->flushAllNs(hyp, target_el); 1973 } 1974 } 1975} 1976 1977void 1978ISA::tlbiMVA(ThreadContext *tc, MiscReg newVal, bool secure_lookup, bool hyp, 1979 uint8_t target_el) 1980{ 1981 System *sys = tc->getSystemPtr(); 1982 for (int x = 0; x < sys->numContexts(); x++) { 1983 ThreadContext *oc = sys->getThreadContext(x); 1984 assert(oc->getITBPtr() && oc->getDTBPtr()); 1985 oc->getITBPtr()->flushMva(mbits(newVal, 31,12), 1986 secure_lookup, hyp, target_el); 1987 oc->getDTBPtr()->flushMva(mbits(newVal, 31,12), 1988 secure_lookup, hyp, target_el); 1989 1990 CheckerCPU *checker = oc->getCheckerCpuPtr(); 1991 if (checker) { 1992 checker->getITBPtr()->flushMva(mbits(newVal, 31,12), 1993 secure_lookup, hyp, target_el); 1994 checker->getDTBPtr()->flushMva(mbits(newVal, 31,12), 1995 secure_lookup, hyp, target_el); 1996 } 1997 } 1998} 1999 2000::GenericTimer::SystemCounter * 2001ISA::getSystemCounter(ThreadContext *tc) 2002{ 2003 ::GenericTimer::SystemCounter *cnt = ((ArmSystem *) tc->getSystemPtr())-> 2004 getSystemCounter(); 2005 if (cnt == NULL) { 2006 panic("System counter not available\n"); 2007 } 2008 return cnt; 2009} 2010 2011::GenericTimer::ArchTimer * 2012ISA::getArchTimer(ThreadContext *tc, int cpu_id) 2013{ 2014 ::GenericTimer::ArchTimer *timer = ((ArmSystem *) tc->getSystemPtr())-> 2015 getArchTimer(cpu_id); 2016 if (timer == NULL) { 2017 panic("Architected timer not available\n"); 2018 } 2019 return timer; 2020} 2021 2022} 2023 2024ArmISA::ISA * 2025ArmISAParams::create() 2026{ 2027 return new ArmISA::ISA(this); 2028} 2029