tlb.cc revision 12356:e56e838c47cb
1/* 2 * Copyright (c) 2010-2013, 2016-2017 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 * Copyright (c) 2001-2005 The Regents of The University of Michigan 15 * All rights reserved. 16 * 17 * Redistribution and use in source and binary forms, with or without 18 * modification, are permitted provided that the following conditions are 19 * met: redistributions of source code must retain the above copyright 20 * notice, this list of conditions and the following disclaimer; 21 * redistributions in binary form must reproduce the above copyright 22 * notice, this list of conditions and the following disclaimer in the 23 * documentation and/or other materials provided with the distribution; 24 * neither the name of the copyright holders nor the names of its 25 * contributors may be used to endorse or promote products derived from 26 * this software without specific prior written permission. 27 * 28 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 29 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 30 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 31 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 32 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 33 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 34 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 35 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 36 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 37 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 38 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 39 * 40 * Authors: Ali Saidi 41 * Nathan Binkert 42 * Steve Reinhardt 43 */ 44 45#include "arch/arm/tlb.hh" 46 47#include <memory> 48#include <string> 49#include <vector> 50 51#include "arch/arm/faults.hh" 52#include "arch/arm/pagetable.hh" 53#include "arch/arm/stage2_lookup.hh" 54#include "arch/arm/stage2_mmu.hh" 55#include "arch/arm/system.hh" 56#include "arch/arm/table_walker.hh" 57#include "arch/arm/utility.hh" 58#include "arch/generic/mmapped_ipr.hh" 59#include "base/inifile.hh" 60#include "base/str.hh" 61#include "base/trace.hh" 62#include "cpu/base.hh" 63#include "cpu/thread_context.hh" 64#include "debug/Checkpoint.hh" 65#include "debug/TLB.hh" 66#include "debug/TLBVerbose.hh" 67#include "mem/page_table.hh" 68#include "mem/request.hh" 69#include "params/ArmTLB.hh" 70#include "sim/full_system.hh" 71#include "sim/process.hh" 72 73using namespace std; 74using namespace ArmISA; 75 76TLB::TLB(const ArmTLBParams *p) 77 : BaseTLB(p), table(new TlbEntry[p->size]), size(p->size), 78 isStage2(p->is_stage2), stage2Req(false), _attr(0), 79 directToStage2(false), tableWalker(p->walker), stage2Tlb(NULL), 80 stage2Mmu(NULL), test(nullptr), rangeMRU(1), 81 aarch64(false), aarch64EL(EL0), isPriv(false), isSecure(false), 82 isHyp(false), asid(0), vmid(0), dacr(0), 83 miscRegValid(false), miscRegContext(0), curTranType(NormalTran) 84{ 85 const ArmSystem *sys = dynamic_cast<const ArmSystem *>(p->sys); 86 87 tableWalker->setTlb(this); 88 89 // Cache system-level properties 90 haveLPAE = tableWalker->haveLPAE(); 91 haveVirtualization = tableWalker->haveVirtualization(); 92 haveLargeAsid64 = tableWalker->haveLargeAsid64(); 93 94 if (sys) 95 m5opRange = sys->m5opRange(); 96} 97 98TLB::~TLB() 99{ 100 delete[] table; 101} 102 103void 104TLB::init() 105{ 106 if (stage2Mmu && !isStage2) 107 stage2Tlb = stage2Mmu->stage2Tlb(); 108} 109 110void 111TLB::setMMU(Stage2MMU *m, MasterID master_id) 112{ 113 stage2Mmu = m; 114 tableWalker->setMMU(m, master_id); 115} 116 117bool 118TLB::translateFunctional(ThreadContext *tc, Addr va, Addr &pa) 119{ 120 updateMiscReg(tc); 121 122 if (directToStage2) { 123 assert(stage2Tlb); 124 return stage2Tlb->translateFunctional(tc, va, pa); 125 } 126 127 TlbEntry *e = lookup(va, asid, vmid, isHyp, isSecure, true, false, 128 aarch64 ? aarch64EL : EL1); 129 if (!e) 130 return false; 131 pa = e->pAddr(va); 132 return true; 133} 134 135Fault 136TLB::finalizePhysical(RequestPtr req, ThreadContext *tc, Mode mode) const 137{ 138 const Addr paddr = req->getPaddr(); 139 140 if (m5opRange.contains(paddr)) { 141 req->setFlags(Request::MMAPPED_IPR | Request::GENERIC_IPR); 142 req->setPaddr(GenericISA::iprAddressPseudoInst( 143 (paddr >> 8) & 0xFF, 144 paddr & 0xFF)); 145 } 146 147 return NoFault; 148} 149 150TlbEntry* 151TLB::lookup(Addr va, uint16_t asn, uint8_t vmid, bool hyp, bool secure, 152 bool functional, bool ignore_asn, uint8_t target_el) 153{ 154 155 TlbEntry *retval = NULL; 156 157 // Maintaining LRU array 158 int x = 0; 159 while (retval == NULL && x < size) { 160 if ((!ignore_asn && table[x].match(va, asn, vmid, hyp, secure, false, 161 target_el)) || 162 (ignore_asn && table[x].match(va, vmid, hyp, secure, target_el))) { 163 // We only move the hit entry ahead when the position is higher 164 // than rangeMRU 165 if (x > rangeMRU && !functional) { 166 TlbEntry tmp_entry = table[x]; 167 for (int i = x; i > 0; i--) 168 table[i] = table[i - 1]; 169 table[0] = tmp_entry; 170 retval = &table[0]; 171 } else { 172 retval = &table[x]; 173 } 174 break; 175 } 176 ++x; 177 } 178 179 DPRINTF(TLBVerbose, "Lookup %#x, asn %#x -> %s vmn 0x%x hyp %d secure %d " 180 "ppn %#x size: %#x pa: %#x ap:%d ns:%d nstid:%d g:%d asid: %d " 181 "el: %d\n", 182 va, asn, retval ? "hit" : "miss", vmid, hyp, secure, 183 retval ? retval->pfn : 0, retval ? retval->size : 0, 184 retval ? retval->pAddr(va) : 0, retval ? retval->ap : 0, 185 retval ? retval->ns : 0, retval ? retval->nstid : 0, 186 retval ? retval->global : 0, retval ? retval->asid : 0, 187 retval ? retval->el : 0); 188 189 return retval; 190} 191 192// insert a new TLB entry 193void 194TLB::insert(Addr addr, TlbEntry &entry) 195{ 196 DPRINTF(TLB, "Inserting entry into TLB with pfn:%#x size:%#x vpn: %#x" 197 " asid:%d vmid:%d N:%d global:%d valid:%d nc:%d xn:%d" 198 " ap:%#x domain:%#x ns:%d nstid:%d isHyp:%d\n", entry.pfn, 199 entry.size, entry.vpn, entry.asid, entry.vmid, entry.N, 200 entry.global, entry.valid, entry.nonCacheable, entry.xn, 201 entry.ap, static_cast<uint8_t>(entry.domain), entry.ns, entry.nstid, 202 entry.isHyp); 203 204 if (table[size - 1].valid) 205 DPRINTF(TLB, " - Replacing Valid entry %#x, asn %d vmn %d ppn %#x " 206 "size: %#x ap:%d ns:%d nstid:%d g:%d isHyp:%d el: %d\n", 207 table[size-1].vpn << table[size-1].N, table[size-1].asid, 208 table[size-1].vmid, table[size-1].pfn << table[size-1].N, 209 table[size-1].size, table[size-1].ap, table[size-1].ns, 210 table[size-1].nstid, table[size-1].global, table[size-1].isHyp, 211 table[size-1].el); 212 213 //inserting to MRU position and evicting the LRU one 214 215 for (int i = size - 1; i > 0; --i) 216 table[i] = table[i-1]; 217 table[0] = entry; 218 219 inserts++; 220 ppRefills->notify(1); 221} 222 223void 224TLB::printTlb() const 225{ 226 int x = 0; 227 TlbEntry *te; 228 DPRINTF(TLB, "Current TLB contents:\n"); 229 while (x < size) { 230 te = &table[x]; 231 if (te->valid) 232 DPRINTF(TLB, " * %s\n", te->print()); 233 ++x; 234 } 235} 236 237void 238TLB::flushAllSecurity(bool secure_lookup, uint8_t target_el, bool ignore_el) 239{ 240 DPRINTF(TLB, "Flushing all TLB entries (%s lookup)\n", 241 (secure_lookup ? "secure" : "non-secure")); 242 int x = 0; 243 TlbEntry *te; 244 while (x < size) { 245 te = &table[x]; 246 if (te->valid && secure_lookup == !te->nstid && 247 (te->vmid == vmid || secure_lookup) && 248 checkELMatch(target_el, te->el, ignore_el)) { 249 250 DPRINTF(TLB, " - %s\n", te->print()); 251 te->valid = false; 252 flushedEntries++; 253 } 254 ++x; 255 } 256 257 flushTlb++; 258 259 // If there's a second stage TLB (and we're not it) then flush it as well 260 // if we're currently in hyp mode 261 if (!isStage2 && isHyp) { 262 stage2Tlb->flushAllSecurity(secure_lookup, true); 263 } 264} 265 266void 267TLB::flushAllNs(bool hyp, uint8_t target_el, bool ignore_el) 268{ 269 DPRINTF(TLB, "Flushing all NS TLB entries (%s lookup)\n", 270 (hyp ? "hyp" : "non-hyp")); 271 int x = 0; 272 TlbEntry *te; 273 while (x < size) { 274 te = &table[x]; 275 if (te->valid && te->nstid && te->isHyp == hyp && 276 checkELMatch(target_el, te->el, ignore_el)) { 277 278 DPRINTF(TLB, " - %s\n", te->print()); 279 flushedEntries++; 280 te->valid = false; 281 } 282 ++x; 283 } 284 285 flushTlb++; 286 287 // If there's a second stage TLB (and we're not it) then flush it as well 288 if (!isStage2 && !hyp) { 289 stage2Tlb->flushAllNs(false, true); 290 } 291} 292 293void 294TLB::flushMvaAsid(Addr mva, uint64_t asn, bool secure_lookup, uint8_t target_el) 295{ 296 DPRINTF(TLB, "Flushing TLB entries with mva: %#x, asid: %#x " 297 "(%s lookup)\n", mva, asn, (secure_lookup ? 298 "secure" : "non-secure")); 299 _flushMva(mva, asn, secure_lookup, false, false, target_el); 300 flushTlbMvaAsid++; 301} 302 303void 304TLB::flushAsid(uint64_t asn, bool secure_lookup, uint8_t target_el) 305{ 306 DPRINTF(TLB, "Flushing TLB entries with asid: %#x (%s lookup)\n", asn, 307 (secure_lookup ? "secure" : "non-secure")); 308 309 int x = 0 ; 310 TlbEntry *te; 311 312 while (x < size) { 313 te = &table[x]; 314 if (te->valid && te->asid == asn && secure_lookup == !te->nstid && 315 (te->vmid == vmid || secure_lookup) && 316 checkELMatch(target_el, te->el, false)) { 317 318 te->valid = false; 319 DPRINTF(TLB, " - %s\n", te->print()); 320 flushedEntries++; 321 } 322 ++x; 323 } 324 flushTlbAsid++; 325} 326 327void 328TLB::flushMva(Addr mva, bool secure_lookup, bool hyp, uint8_t target_el) 329{ 330 DPRINTF(TLB, "Flushing TLB entries with mva: %#x (%s lookup)\n", mva, 331 (secure_lookup ? "secure" : "non-secure")); 332 _flushMva(mva, 0xbeef, secure_lookup, hyp, true, target_el); 333 flushTlbMva++; 334} 335 336void 337TLB::_flushMva(Addr mva, uint64_t asn, bool secure_lookup, bool hyp, 338 bool ignore_asn, uint8_t target_el) 339{ 340 TlbEntry *te; 341 // D5.7.2: Sign-extend address to 64 bits 342 mva = sext<56>(mva); 343 te = lookup(mva, asn, vmid, hyp, secure_lookup, false, ignore_asn, 344 target_el); 345 while (te != NULL) { 346 if (secure_lookup == !te->nstid) { 347 DPRINTF(TLB, " - %s\n", te->print()); 348 te->valid = false; 349 flushedEntries++; 350 } 351 te = lookup(mva, asn, vmid, hyp, secure_lookup, false, ignore_asn, 352 target_el); 353 } 354} 355 356void 357TLB::flushIpaVmid(Addr ipa, bool secure_lookup, bool hyp, uint8_t target_el) 358{ 359 assert(!isStage2); 360 stage2Tlb->_flushMva(ipa, 0xbeef, secure_lookup, hyp, true, target_el); 361} 362 363bool 364TLB::checkELMatch(uint8_t target_el, uint8_t tentry_el, bool ignore_el) 365{ 366 bool elMatch = true; 367 if (!ignore_el) { 368 if (target_el == 2 || target_el == 3) { 369 elMatch = (tentry_el == target_el); 370 } else { 371 elMatch = (tentry_el == 0) || (tentry_el == 1); 372 } 373 } 374 return elMatch; 375} 376 377void 378TLB::drainResume() 379{ 380 // We might have unserialized something or switched CPUs, so make 381 // sure to re-read the misc regs. 382 miscRegValid = false; 383} 384 385void 386TLB::takeOverFrom(BaseTLB *_otlb) 387{ 388 TLB *otlb = dynamic_cast<TLB*>(_otlb); 389 /* Make sure we actually have a valid type */ 390 if (otlb) { 391 _attr = otlb->_attr; 392 haveLPAE = otlb->haveLPAE; 393 directToStage2 = otlb->directToStage2; 394 stage2Req = otlb->stage2Req; 395 396 /* Sync the stage2 MMU if they exist in both 397 * the old CPU and the new 398 */ 399 if (!isStage2 && 400 stage2Tlb && otlb->stage2Tlb) { 401 stage2Tlb->takeOverFrom(otlb->stage2Tlb); 402 } 403 } else { 404 panic("Incompatible TLB type!"); 405 } 406} 407 408void 409TLB::serialize(CheckpointOut &cp) const 410{ 411 DPRINTF(Checkpoint, "Serializing Arm TLB\n"); 412 413 SERIALIZE_SCALAR(_attr); 414 SERIALIZE_SCALAR(haveLPAE); 415 SERIALIZE_SCALAR(directToStage2); 416 SERIALIZE_SCALAR(stage2Req); 417 418 int num_entries = size; 419 SERIALIZE_SCALAR(num_entries); 420 for (int i = 0; i < size; i++) 421 table[i].serializeSection(cp, csprintf("TlbEntry%d", i)); 422} 423 424void 425TLB::unserialize(CheckpointIn &cp) 426{ 427 DPRINTF(Checkpoint, "Unserializing Arm TLB\n"); 428 429 UNSERIALIZE_SCALAR(_attr); 430 UNSERIALIZE_SCALAR(haveLPAE); 431 UNSERIALIZE_SCALAR(directToStage2); 432 UNSERIALIZE_SCALAR(stage2Req); 433 434 int num_entries; 435 UNSERIALIZE_SCALAR(num_entries); 436 for (int i = 0; i < min(size, num_entries); i++) 437 table[i].unserializeSection(cp, csprintf("TlbEntry%d", i)); 438} 439 440void 441TLB::regStats() 442{ 443 BaseTLB::regStats(); 444 instHits 445 .name(name() + ".inst_hits") 446 .desc("ITB inst hits") 447 ; 448 449 instMisses 450 .name(name() + ".inst_misses") 451 .desc("ITB inst misses") 452 ; 453 454 instAccesses 455 .name(name() + ".inst_accesses") 456 .desc("ITB inst accesses") 457 ; 458 459 readHits 460 .name(name() + ".read_hits") 461 .desc("DTB read hits") 462 ; 463 464 readMisses 465 .name(name() + ".read_misses") 466 .desc("DTB read misses") 467 ; 468 469 readAccesses 470 .name(name() + ".read_accesses") 471 .desc("DTB read accesses") 472 ; 473 474 writeHits 475 .name(name() + ".write_hits") 476 .desc("DTB write hits") 477 ; 478 479 writeMisses 480 .name(name() + ".write_misses") 481 .desc("DTB write misses") 482 ; 483 484 writeAccesses 485 .name(name() + ".write_accesses") 486 .desc("DTB write accesses") 487 ; 488 489 hits 490 .name(name() + ".hits") 491 .desc("DTB hits") 492 ; 493 494 misses 495 .name(name() + ".misses") 496 .desc("DTB misses") 497 ; 498 499 accesses 500 .name(name() + ".accesses") 501 .desc("DTB accesses") 502 ; 503 504 flushTlb 505 .name(name() + ".flush_tlb") 506 .desc("Number of times complete TLB was flushed") 507 ; 508 509 flushTlbMva 510 .name(name() + ".flush_tlb_mva") 511 .desc("Number of times TLB was flushed by MVA") 512 ; 513 514 flushTlbMvaAsid 515 .name(name() + ".flush_tlb_mva_asid") 516 .desc("Number of times TLB was flushed by MVA & ASID") 517 ; 518 519 flushTlbAsid 520 .name(name() + ".flush_tlb_asid") 521 .desc("Number of times TLB was flushed by ASID") 522 ; 523 524 flushedEntries 525 .name(name() + ".flush_entries") 526 .desc("Number of entries that have been flushed from TLB") 527 ; 528 529 alignFaults 530 .name(name() + ".align_faults") 531 .desc("Number of TLB faults due to alignment restrictions") 532 ; 533 534 prefetchFaults 535 .name(name() + ".prefetch_faults") 536 .desc("Number of TLB faults due to prefetch") 537 ; 538 539 domainFaults 540 .name(name() + ".domain_faults") 541 .desc("Number of TLB faults due to domain restrictions") 542 ; 543 544 permsFaults 545 .name(name() + ".perms_faults") 546 .desc("Number of TLB faults due to permissions restrictions") 547 ; 548 549 instAccesses = instHits + instMisses; 550 readAccesses = readHits + readMisses; 551 writeAccesses = writeHits + writeMisses; 552 hits = readHits + writeHits + instHits; 553 misses = readMisses + writeMisses + instMisses; 554 accesses = readAccesses + writeAccesses + instAccesses; 555} 556 557void 558TLB::regProbePoints() 559{ 560 ppRefills.reset(new ProbePoints::PMU(getProbeManager(), "Refills")); 561} 562 563Fault 564TLB::translateSe(RequestPtr req, ThreadContext *tc, Mode mode, 565 Translation *translation, bool &delay, bool timing) 566{ 567 updateMiscReg(tc); 568 Addr vaddr_tainted = req->getVaddr(); 569 Addr vaddr = 0; 570 if (aarch64) 571 vaddr = purifyTaggedAddr(vaddr_tainted, tc, aarch64EL, ttbcr); 572 else 573 vaddr = vaddr_tainted; 574 Request::Flags flags = req->getFlags(); 575 576 bool is_fetch = (mode == Execute); 577 bool is_write = (mode == Write); 578 579 if (!is_fetch) { 580 assert(flags & MustBeOne); 581 if (sctlr.a || !(flags & AllowUnaligned)) { 582 if (vaddr & mask(flags & AlignmentMask)) { 583 // LPAE is always disabled in SE mode 584 return std::make_shared<DataAbort>( 585 vaddr_tainted, 586 TlbEntry::DomainType::NoAccess, is_write, 587 ArmFault::AlignmentFault, isStage2, 588 ArmFault::VmsaTran); 589 } 590 } 591 } 592 593 Addr paddr; 594 Process *p = tc->getProcessPtr(); 595 596 if (!p->pTable->translate(vaddr, paddr)) 597 return std::make_shared<GenericPageTableFault>(vaddr_tainted); 598 req->setPaddr(paddr); 599 600 return finalizePhysical(req, tc, mode); 601} 602 603Fault 604TLB::checkPermissions(TlbEntry *te, RequestPtr req, Mode mode) 605{ 606 Addr vaddr = req->getVaddr(); // 32-bit don't have to purify 607 Request::Flags flags = req->getFlags(); 608 bool is_fetch = (mode == Execute); 609 bool is_write = (mode == Write); 610 bool is_priv = isPriv && !(flags & UserMode); 611 612 // Get the translation type from the actuall table entry 613 ArmFault::TranMethod tranMethod = te->longDescFormat ? ArmFault::LpaeTran 614 : ArmFault::VmsaTran; 615 616 // If this is the second stage of translation and the request is for a 617 // stage 1 page table walk then we need to check the HCR.PTW bit. This 618 // allows us to generate a fault if the request targets an area marked 619 // as a device or strongly ordered. 620 if (isStage2 && req->isPTWalk() && hcr.ptw && 621 (te->mtype != TlbEntry::MemoryType::Normal)) { 622 return std::make_shared<DataAbort>( 623 vaddr, te->domain, is_write, 624 ArmFault::PermissionLL + te->lookupLevel, 625 isStage2, tranMethod); 626 } 627 628 // Generate an alignment fault for unaligned data accesses to device or 629 // strongly ordered memory 630 if (!is_fetch) { 631 if (te->mtype != TlbEntry::MemoryType::Normal) { 632 if (vaddr & mask(flags & AlignmentMask)) { 633 alignFaults++; 634 return std::make_shared<DataAbort>( 635 vaddr, TlbEntry::DomainType::NoAccess, is_write, 636 ArmFault::AlignmentFault, isStage2, 637 tranMethod); 638 } 639 } 640 } 641 642 if (te->nonCacheable) { 643 // Prevent prefetching from I/O devices. 644 if (req->isPrefetch()) { 645 // Here we can safely use the fault status for the short 646 // desc. format in all cases 647 return std::make_shared<PrefetchAbort>( 648 vaddr, ArmFault::PrefetchUncacheable, 649 isStage2, tranMethod); 650 } 651 } 652 653 if (!te->longDescFormat) { 654 switch ((dacr >> (static_cast<uint8_t>(te->domain) * 2)) & 0x3) { 655 case 0: 656 domainFaults++; 657 DPRINTF(TLB, "TLB Fault: Data abort on domain. DACR: %#x" 658 " domain: %#x write:%d\n", dacr, 659 static_cast<uint8_t>(te->domain), is_write); 660 if (is_fetch) { 661 // Use PC value instead of vaddr because vaddr might 662 // be aligned to cache line and should not be the 663 // address reported in FAR 664 return std::make_shared<PrefetchAbort>( 665 req->getPC(), 666 ArmFault::DomainLL + te->lookupLevel, 667 isStage2, tranMethod); 668 } else 669 return std::make_shared<DataAbort>( 670 vaddr, te->domain, is_write, 671 ArmFault::DomainLL + te->lookupLevel, 672 isStage2, tranMethod); 673 case 1: 674 // Continue with permissions check 675 break; 676 case 2: 677 panic("UNPRED domain\n"); 678 case 3: 679 return NoFault; 680 } 681 } 682 683 // The 'ap' variable is AP[2:0] or {AP[2,1],1b'0}, i.e. always three bits 684 uint8_t ap = te->longDescFormat ? te->ap << 1 : te->ap; 685 uint8_t hap = te->hap; 686 687 if (sctlr.afe == 1 || te->longDescFormat) 688 ap |= 1; 689 690 bool abt; 691 bool isWritable = true; 692 // If this is a stage 2 access (eg for reading stage 1 page table entries) 693 // then don't perform the AP permissions check, we stil do the HAP check 694 // below. 695 if (isStage2) { 696 abt = false; 697 } else { 698 switch (ap) { 699 case 0: 700 DPRINTF(TLB, "Access permissions 0, checking rs:%#x\n", 701 (int)sctlr.rs); 702 if (!sctlr.xp) { 703 switch ((int)sctlr.rs) { 704 case 2: 705 abt = is_write; 706 break; 707 case 1: 708 abt = is_write || !is_priv; 709 break; 710 case 0: 711 case 3: 712 default: 713 abt = true; 714 break; 715 } 716 } else { 717 abt = true; 718 } 719 break; 720 case 1: 721 abt = !is_priv; 722 break; 723 case 2: 724 abt = !is_priv && is_write; 725 isWritable = is_priv; 726 break; 727 case 3: 728 abt = false; 729 break; 730 case 4: 731 panic("UNPRED premissions\n"); 732 case 5: 733 abt = !is_priv || is_write; 734 isWritable = false; 735 break; 736 case 6: 737 case 7: 738 abt = is_write; 739 isWritable = false; 740 break; 741 default: 742 panic("Unknown permissions %#x\n", ap); 743 } 744 } 745 746 bool hapAbt = is_write ? !(hap & 2) : !(hap & 1); 747 bool xn = te->xn || (isWritable && sctlr.wxn) || 748 (ap == 3 && sctlr.uwxn && is_priv); 749 if (is_fetch && (abt || xn || 750 (te->longDescFormat && te->pxn && is_priv) || 751 (isSecure && te->ns && scr.sif))) { 752 permsFaults++; 753 DPRINTF(TLB, "TLB Fault: Prefetch abort on permission check. AP:%d " 754 "priv:%d write:%d ns:%d sif:%d sctlr.afe: %d \n", 755 ap, is_priv, is_write, te->ns, scr.sif,sctlr.afe); 756 // Use PC value instead of vaddr because vaddr might be aligned to 757 // cache line and should not be the address reported in FAR 758 return std::make_shared<PrefetchAbort>( 759 req->getPC(), 760 ArmFault::PermissionLL + te->lookupLevel, 761 isStage2, tranMethod); 762 } else if (abt | hapAbt) { 763 permsFaults++; 764 DPRINTF(TLB, "TLB Fault: Data abort on permission check. AP:%d priv:%d" 765 " write:%d\n", ap, is_priv, is_write); 766 return std::make_shared<DataAbort>( 767 vaddr, te->domain, is_write, 768 ArmFault::PermissionLL + te->lookupLevel, 769 isStage2 | !abt, tranMethod); 770 } 771 return NoFault; 772} 773 774 775Fault 776TLB::checkPermissions64(TlbEntry *te, RequestPtr req, Mode mode, 777 ThreadContext *tc) 778{ 779 assert(aarch64); 780 781 Addr vaddr_tainted = req->getVaddr(); 782 Addr vaddr = purifyTaggedAddr(vaddr_tainted, tc, aarch64EL, ttbcr); 783 784 Request::Flags flags = req->getFlags(); 785 bool is_fetch = (mode == Execute); 786 bool is_write = (mode == Write); 787 bool is_priv M5_VAR_USED = isPriv && !(flags & UserMode); 788 789 updateMiscReg(tc, curTranType); 790 791 // If this is the second stage of translation and the request is for a 792 // stage 1 page table walk then we need to check the HCR.PTW bit. This 793 // allows us to generate a fault if the request targets an area marked 794 // as a device or strongly ordered. 795 if (isStage2 && req->isPTWalk() && hcr.ptw && 796 (te->mtype != TlbEntry::MemoryType::Normal)) { 797 return std::make_shared<DataAbort>( 798 vaddr_tainted, te->domain, is_write, 799 ArmFault::PermissionLL + te->lookupLevel, 800 isStage2, ArmFault::LpaeTran); 801 } 802 803 // Generate an alignment fault for unaligned accesses to device or 804 // strongly ordered memory 805 if (!is_fetch) { 806 if (te->mtype != TlbEntry::MemoryType::Normal) { 807 if (vaddr & mask(flags & AlignmentMask)) { 808 alignFaults++; 809 return std::make_shared<DataAbort>( 810 vaddr_tainted, 811 TlbEntry::DomainType::NoAccess, is_write, 812 ArmFault::AlignmentFault, isStage2, 813 ArmFault::LpaeTran); 814 } 815 } 816 } 817 818 if (te->nonCacheable) { 819 // Prevent prefetching from I/O devices. 820 if (req->isPrefetch()) { 821 // Here we can safely use the fault status for the short 822 // desc. format in all cases 823 return std::make_shared<PrefetchAbort>( 824 vaddr_tainted, 825 ArmFault::PrefetchUncacheable, 826 isStage2, ArmFault::LpaeTran); 827 } 828 } 829 830 uint8_t ap = 0x3 & (te->ap); // 2-bit access protection field 831 bool grant = false; 832 833 uint8_t xn = te->xn; 834 uint8_t pxn = te->pxn; 835 bool r = !is_write && !is_fetch; 836 bool w = is_write; 837 bool x = is_fetch; 838 DPRINTF(TLBVerbose, "Checking permissions: ap:%d, xn:%d, pxn:%d, r:%d, " 839 "w:%d, x:%d\n", ap, xn, pxn, r, w, x); 840 841 if (isStage2) { 842 assert(ArmSystem::haveVirtualization(tc) && aarch64EL != EL2); 843 // In stage 2 we use the hypervisor access permission bits. 844 // The following permissions are described in ARM DDI 0487A.f 845 // D4-1802 846 uint8_t hap = 0x3 & te->hap; 847 if (is_fetch) { 848 // sctlr.wxn overrides the xn bit 849 grant = !sctlr.wxn && !xn; 850 } else if (is_write) { 851 grant = hap & 0x2; 852 } else { // is_read 853 grant = hap & 0x1; 854 } 855 } else { 856 switch (aarch64EL) { 857 case EL0: 858 { 859 uint8_t perm = (ap << 2) | (xn << 1) | pxn; 860 switch (perm) { 861 case 0: 862 case 1: 863 case 8: 864 case 9: 865 grant = x; 866 break; 867 case 4: 868 case 5: 869 grant = r || w || (x && !sctlr.wxn); 870 break; 871 case 6: 872 case 7: 873 grant = r || w; 874 break; 875 case 12: 876 case 13: 877 grant = r || x; 878 break; 879 case 14: 880 case 15: 881 grant = r; 882 break; 883 default: 884 grant = false; 885 } 886 } 887 break; 888 case EL1: 889 { 890 uint8_t perm = (ap << 2) | (xn << 1) | pxn; 891 switch (perm) { 892 case 0: 893 case 2: 894 grant = r || w || (x && !sctlr.wxn); 895 break; 896 case 1: 897 case 3: 898 case 4: 899 case 5: 900 case 6: 901 case 7: 902 // regions that are writeable at EL0 should not be 903 // executable at EL1 904 grant = r || w; 905 break; 906 case 8: 907 case 10: 908 case 12: 909 case 14: 910 grant = r || x; 911 break; 912 case 9: 913 case 11: 914 case 13: 915 case 15: 916 grant = r; 917 break; 918 default: 919 grant = false; 920 } 921 } 922 break; 923 case EL2: 924 case EL3: 925 { 926 uint8_t perm = (ap & 0x2) | xn; 927 switch (perm) { 928 case 0: 929 grant = r || w || (x && !sctlr.wxn) ; 930 break; 931 case 1: 932 grant = r || w; 933 break; 934 case 2: 935 grant = r || x; 936 break; 937 case 3: 938 grant = r; 939 break; 940 default: 941 grant = false; 942 } 943 } 944 break; 945 } 946 } 947 948 if (!grant) { 949 if (is_fetch) { 950 permsFaults++; 951 DPRINTF(TLB, "TLB Fault: Prefetch abort on permission check. " 952 "AP:%d priv:%d write:%d ns:%d sif:%d " 953 "sctlr.afe: %d\n", 954 ap, is_priv, is_write, te->ns, scr.sif, sctlr.afe); 955 // Use PC value instead of vaddr because vaddr might be aligned to 956 // cache line and should not be the address reported in FAR 957 return std::make_shared<PrefetchAbort>( 958 req->getPC(), 959 ArmFault::PermissionLL + te->lookupLevel, 960 isStage2, ArmFault::LpaeTran); 961 } else { 962 permsFaults++; 963 DPRINTF(TLB, "TLB Fault: Data abort on permission check. AP:%d " 964 "priv:%d write:%d\n", ap, is_priv, is_write); 965 return std::make_shared<DataAbort>( 966 vaddr_tainted, te->domain, is_write, 967 ArmFault::PermissionLL + te->lookupLevel, 968 isStage2, ArmFault::LpaeTran); 969 } 970 } 971 972 return NoFault; 973} 974 975Fault 976TLB::translateFs(RequestPtr req, ThreadContext *tc, Mode mode, 977 Translation *translation, bool &delay, bool timing, 978 TLB::ArmTranslationType tranType, bool functional) 979{ 980 // No such thing as a functional timing access 981 assert(!(timing && functional)); 982 983 updateMiscReg(tc, tranType); 984 985 Addr vaddr_tainted = req->getVaddr(); 986 Addr vaddr = 0; 987 if (aarch64) 988 vaddr = purifyTaggedAddr(vaddr_tainted, tc, aarch64EL, ttbcr); 989 else 990 vaddr = vaddr_tainted; 991 Request::Flags flags = req->getFlags(); 992 993 bool is_fetch = (mode == Execute); 994 bool is_write = (mode == Write); 995 bool long_desc_format = aarch64 || longDescFormatInUse(tc); 996 ArmFault::TranMethod tranMethod = long_desc_format ? ArmFault::LpaeTran 997 : ArmFault::VmsaTran; 998 999 req->setAsid(asid); 1000 1001 DPRINTF(TLBVerbose, "CPSR is priv:%d UserMode:%d secure:%d S1S2NsTran:%d\n", 1002 isPriv, flags & UserMode, isSecure, tranType & S1S2NsTran); 1003 1004 DPRINTF(TLB, "translateFs addr %#x, mode %d, st2 %d, scr %#x sctlr %#x " 1005 "flags %#lx tranType 0x%x\n", vaddr_tainted, mode, isStage2, 1006 scr, sctlr, flags, tranType); 1007 1008 if ((req->isInstFetch() && (!sctlr.i)) || 1009 ((!req->isInstFetch()) && (!sctlr.c))){ 1010 if (!req->isCacheMaintenance()) { 1011 req->setFlags(Request::UNCACHEABLE); 1012 } 1013 req->setFlags(Request::STRICT_ORDER); 1014 } 1015 if (!is_fetch) { 1016 assert(flags & MustBeOne); 1017 if (sctlr.a || !(flags & AllowUnaligned)) { 1018 if (vaddr & mask(flags & AlignmentMask)) { 1019 alignFaults++; 1020 return std::make_shared<DataAbort>( 1021 vaddr_tainted, 1022 TlbEntry::DomainType::NoAccess, is_write, 1023 ArmFault::AlignmentFault, isStage2, 1024 tranMethod); 1025 } 1026 } 1027 } 1028 1029 // If guest MMU is off or hcr.vm=0 go straight to stage2 1030 if ((isStage2 && !hcr.vm) || (!isStage2 && !sctlr.m)) { 1031 1032 req->setPaddr(vaddr); 1033 // When the MMU is off the security attribute corresponds to the 1034 // security state of the processor 1035 if (isSecure) 1036 req->setFlags(Request::SECURE); 1037 1038 // @todo: double check this (ARM ARM issue C B3.2.1) 1039 if (long_desc_format || sctlr.tre == 0 || nmrr.ir0 == 0 || 1040 nmrr.or0 == 0 || prrr.tr0 != 0x2) { 1041 if (!req->isCacheMaintenance()) { 1042 req->setFlags(Request::UNCACHEABLE); 1043 } 1044 req->setFlags(Request::STRICT_ORDER); 1045 } 1046 1047 // Set memory attributes 1048 TlbEntry temp_te; 1049 temp_te.ns = !isSecure; 1050 if (isStage2 || hcr.dc == 0 || isSecure || 1051 (isHyp && !(tranType & S1CTran))) { 1052 1053 temp_te.mtype = is_fetch ? TlbEntry::MemoryType::Normal 1054 : TlbEntry::MemoryType::StronglyOrdered; 1055 temp_te.innerAttrs = 0x0; 1056 temp_te.outerAttrs = 0x0; 1057 temp_te.shareable = true; 1058 temp_te.outerShareable = true; 1059 } else { 1060 temp_te.mtype = TlbEntry::MemoryType::Normal; 1061 temp_te.innerAttrs = 0x3; 1062 temp_te.outerAttrs = 0x3; 1063 temp_te.shareable = false; 1064 temp_te.outerShareable = false; 1065 } 1066 temp_te.setAttributes(long_desc_format); 1067 DPRINTF(TLBVerbose, "(No MMU) setting memory attributes: shareable: " 1068 "%d, innerAttrs: %d, outerAttrs: %d, isStage2: %d\n", 1069 temp_te.shareable, temp_te.innerAttrs, temp_te.outerAttrs, 1070 isStage2); 1071 setAttr(temp_te.attributes); 1072 1073 return testTranslation(req, mode, TlbEntry::DomainType::NoAccess); 1074 } 1075 1076 DPRINTF(TLBVerbose, "Translating %s=%#x context=%d\n", 1077 isStage2 ? "IPA" : "VA", vaddr_tainted, asid); 1078 // Translation enabled 1079 1080 TlbEntry *te = NULL; 1081 TlbEntry mergeTe; 1082 Fault fault = getResultTe(&te, req, tc, mode, translation, timing, 1083 functional, &mergeTe); 1084 // only proceed if we have a valid table entry 1085 if ((te == NULL) && (fault == NoFault)) delay = true; 1086 1087 // If we have the table entry transfer some of the attributes to the 1088 // request that triggered the translation 1089 if (te != NULL) { 1090 // Set memory attributes 1091 DPRINTF(TLBVerbose, 1092 "Setting memory attributes: shareable: %d, innerAttrs: %d, " 1093 "outerAttrs: %d, mtype: %d, isStage2: %d\n", 1094 te->shareable, te->innerAttrs, te->outerAttrs, 1095 static_cast<uint8_t>(te->mtype), isStage2); 1096 setAttr(te->attributes); 1097 1098 if (te->nonCacheable && !req->isCacheMaintenance()) 1099 req->setFlags(Request::UNCACHEABLE); 1100 1101 // Require requests to be ordered if the request goes to 1102 // strongly ordered or device memory (i.e., anything other 1103 // than normal memory requires strict order). 1104 if (te->mtype != TlbEntry::MemoryType::Normal) 1105 req->setFlags(Request::STRICT_ORDER); 1106 1107 Addr pa = te->pAddr(vaddr); 1108 req->setPaddr(pa); 1109 1110 if (isSecure && !te->ns) { 1111 req->setFlags(Request::SECURE); 1112 } 1113 if ((!is_fetch) && (vaddr & mask(flags & AlignmentMask)) && 1114 (te->mtype != TlbEntry::MemoryType::Normal)) { 1115 // Unaligned accesses to Device memory should always cause an 1116 // abort regardless of sctlr.a 1117 alignFaults++; 1118 return std::make_shared<DataAbort>( 1119 vaddr_tainted, 1120 TlbEntry::DomainType::NoAccess, is_write, 1121 ArmFault::AlignmentFault, isStage2, 1122 tranMethod); 1123 } 1124 1125 // Check for a trickbox generated address fault 1126 if (fault == NoFault) 1127 fault = testTranslation(req, mode, te->domain); 1128 } 1129 1130 if (fault == NoFault) { 1131 // Generate Illegal Inst Set State fault if IL bit is set in CPSR 1132 if (aarch64 && is_fetch && cpsr.il == 1) { 1133 return std::make_shared<IllegalInstSetStateFault>(); 1134 } 1135 1136 // Don't try to finalize a physical address unless the 1137 // translation has completed (i.e., there is a table entry). 1138 return te ? finalizePhysical(req, tc, mode) : NoFault; 1139 } else { 1140 return fault; 1141 } 1142} 1143 1144Fault 1145TLB::translateAtomic(RequestPtr req, ThreadContext *tc, Mode mode, 1146 TLB::ArmTranslationType tranType) 1147{ 1148 updateMiscReg(tc, tranType); 1149 1150 if (directToStage2) { 1151 assert(stage2Tlb); 1152 return stage2Tlb->translateAtomic(req, tc, mode, tranType); 1153 } 1154 1155 bool delay = false; 1156 Fault fault; 1157 if (FullSystem) 1158 fault = translateFs(req, tc, mode, NULL, delay, false, tranType); 1159 else 1160 fault = translateSe(req, tc, mode, NULL, delay, false); 1161 assert(!delay); 1162 return fault; 1163} 1164 1165Fault 1166TLB::translateFunctional(RequestPtr req, ThreadContext *tc, Mode mode, 1167 TLB::ArmTranslationType tranType) 1168{ 1169 updateMiscReg(tc, tranType); 1170 1171 if (directToStage2) { 1172 assert(stage2Tlb); 1173 return stage2Tlb->translateFunctional(req, tc, mode, tranType); 1174 } 1175 1176 bool delay = false; 1177 Fault fault; 1178 if (FullSystem) 1179 fault = translateFs(req, tc, mode, NULL, delay, false, tranType, true); 1180 else 1181 fault = translateSe(req, tc, mode, NULL, delay, false); 1182 assert(!delay); 1183 return fault; 1184} 1185 1186Fault 1187TLB::translateTiming(RequestPtr req, ThreadContext *tc, 1188 Translation *translation, Mode mode, TLB::ArmTranslationType tranType) 1189{ 1190 updateMiscReg(tc, tranType); 1191 1192 if (directToStage2) { 1193 assert(stage2Tlb); 1194 return stage2Tlb->translateTiming(req, tc, translation, mode, tranType); 1195 } 1196 1197 assert(translation); 1198 1199 return translateComplete(req, tc, translation, mode, tranType, isStage2); 1200} 1201 1202Fault 1203TLB::translateComplete(RequestPtr req, ThreadContext *tc, 1204 Translation *translation, Mode mode, TLB::ArmTranslationType tranType, 1205 bool callFromS2) 1206{ 1207 bool delay = false; 1208 Fault fault; 1209 if (FullSystem) 1210 fault = translateFs(req, tc, mode, translation, delay, true, tranType); 1211 else 1212 fault = translateSe(req, tc, mode, translation, delay, true); 1213 DPRINTF(TLBVerbose, "Translation returning delay=%d fault=%d\n", delay, fault != 1214 NoFault); 1215 // If we have a translation, and we're not in the middle of doing a stage 1216 // 2 translation tell the translation that we've either finished or its 1217 // going to take a while. By not doing this when we're in the middle of a 1218 // stage 2 translation we prevent marking the translation as delayed twice, 1219 // one when the translation starts and again when the stage 1 translation 1220 // completes. 1221 if (translation && (callFromS2 || !stage2Req || req->hasPaddr() || fault != NoFault)) { 1222 if (!delay) 1223 translation->finish(fault, req, tc, mode); 1224 else 1225 translation->markDelayed(); 1226 } 1227 return fault; 1228} 1229 1230BaseMasterPort* 1231TLB::getMasterPort() 1232{ 1233 return &stage2Mmu->getPort(); 1234} 1235 1236void 1237TLB::updateMiscReg(ThreadContext *tc, ArmTranslationType tranType) 1238{ 1239 // check if the regs have changed, or the translation mode is different. 1240 // NOTE: the tran type doesn't affect stage 2 TLB's as they only handle 1241 // one type of translation anyway 1242 if (miscRegValid && miscRegContext == tc->contextId() && 1243 ((tranType == curTranType) || isStage2)) { 1244 return; 1245 } 1246 1247 DPRINTF(TLBVerbose, "TLB variables changed!\n"); 1248 cpsr = tc->readMiscReg(MISCREG_CPSR); 1249 1250 // Dependencies: SCR/SCR_EL3, CPSR 1251 isSecure = inSecureState(tc) && 1252 !(tranType & HypMode) && !(tranType & S1S2NsTran); 1253 1254 const OperatingMode op_mode = (OperatingMode) (uint8_t)cpsr.mode; 1255 aarch64 = opModeIs64(op_mode) || 1256 (opModeToEL(op_mode) == EL0 && ELIs64(tc, EL1)); 1257 1258 if (aarch64) { // AArch64 1259 // determine EL we need to translate in 1260 switch (tranType) { 1261 case S1E0Tran: 1262 case S12E0Tran: 1263 aarch64EL = EL0; 1264 break; 1265 case S1E1Tran: 1266 case S12E1Tran: 1267 aarch64EL = EL1; 1268 break; 1269 case S1E2Tran: 1270 aarch64EL = EL2; 1271 break; 1272 case S1E3Tran: 1273 aarch64EL = EL3; 1274 break; 1275 case NormalTran: 1276 case S1CTran: 1277 case S1S2NsTran: 1278 case HypMode: 1279 aarch64EL = (ExceptionLevel) (uint8_t) cpsr.el; 1280 break; 1281 } 1282 1283 switch (aarch64EL) { 1284 case EL0: 1285 case EL1: 1286 { 1287 sctlr = tc->readMiscReg(MISCREG_SCTLR_EL1); 1288 ttbcr = tc->readMiscReg(MISCREG_TCR_EL1); 1289 uint64_t ttbr_asid = ttbcr.a1 ? 1290 tc->readMiscReg(MISCREG_TTBR1_EL1) : 1291 tc->readMiscReg(MISCREG_TTBR0_EL1); 1292 asid = bits(ttbr_asid, 1293 (haveLargeAsid64 && ttbcr.as) ? 63 : 55, 48); 1294 } 1295 break; 1296 case EL2: 1297 sctlr = tc->readMiscReg(MISCREG_SCTLR_EL2); 1298 ttbcr = tc->readMiscReg(MISCREG_TCR_EL2); 1299 asid = -1; 1300 break; 1301 case EL3: 1302 sctlr = tc->readMiscReg(MISCREG_SCTLR_EL3); 1303 ttbcr = tc->readMiscReg(MISCREG_TCR_EL3); 1304 asid = -1; 1305 break; 1306 } 1307 hcr = tc->readMiscReg(MISCREG_HCR_EL2); 1308 scr = tc->readMiscReg(MISCREG_SCR_EL3); 1309 isPriv = aarch64EL != EL0; 1310 if (haveVirtualization) { 1311 vmid = bits(tc->readMiscReg(MISCREG_VTTBR_EL2), 55, 48); 1312 isHyp = tranType & HypMode; 1313 isHyp &= (tranType & S1S2NsTran) == 0; 1314 isHyp &= (tranType & S1CTran) == 0; 1315 // Work out if we should skip the first stage of translation and go 1316 // directly to stage 2. This value is cached so we don't have to 1317 // compute it for every translation. 1318 stage2Req = isStage2 || 1319 (hcr.vm && !isHyp && !isSecure && 1320 !(tranType & S1CTran) && (aarch64EL < EL2) && 1321 !(tranType & S1E1Tran)); // <--- FIX THIS HACK 1322 directToStage2 = !isStage2 && stage2Req && !sctlr.m; 1323 } else { 1324 vmid = 0; 1325 isHyp = false; 1326 directToStage2 = false; 1327 stage2Req = false; 1328 } 1329 } else { // AArch32 1330 sctlr = tc->readMiscReg(flattenMiscRegNsBanked(MISCREG_SCTLR, tc, 1331 !isSecure)); 1332 ttbcr = tc->readMiscReg(flattenMiscRegNsBanked(MISCREG_TTBCR, tc, 1333 !isSecure)); 1334 scr = tc->readMiscReg(MISCREG_SCR); 1335 isPriv = cpsr.mode != MODE_USER; 1336 if (longDescFormatInUse(tc)) { 1337 uint64_t ttbr_asid = tc->readMiscReg( 1338 flattenMiscRegNsBanked(ttbcr.a1 ? MISCREG_TTBR1 1339 : MISCREG_TTBR0, 1340 tc, !isSecure)); 1341 asid = bits(ttbr_asid, 55, 48); 1342 } else { // Short-descriptor translation table format in use 1343 CONTEXTIDR context_id = tc->readMiscReg(flattenMiscRegNsBanked( 1344 MISCREG_CONTEXTIDR, tc,!isSecure)); 1345 asid = context_id.asid; 1346 } 1347 prrr = tc->readMiscReg(flattenMiscRegNsBanked(MISCREG_PRRR, tc, 1348 !isSecure)); 1349 nmrr = tc->readMiscReg(flattenMiscRegNsBanked(MISCREG_NMRR, tc, 1350 !isSecure)); 1351 dacr = tc->readMiscReg(flattenMiscRegNsBanked(MISCREG_DACR, tc, 1352 !isSecure)); 1353 hcr = tc->readMiscReg(MISCREG_HCR); 1354 1355 if (haveVirtualization) { 1356 vmid = bits(tc->readMiscReg(MISCREG_VTTBR), 55, 48); 1357 isHyp = cpsr.mode == MODE_HYP; 1358 isHyp |= tranType & HypMode; 1359 isHyp &= (tranType & S1S2NsTran) == 0; 1360 isHyp &= (tranType & S1CTran) == 0; 1361 if (isHyp) { 1362 sctlr = tc->readMiscReg(MISCREG_HSCTLR); 1363 } 1364 // Work out if we should skip the first stage of translation and go 1365 // directly to stage 2. This value is cached so we don't have to 1366 // compute it for every translation. 1367 stage2Req = hcr.vm && !isStage2 && !isHyp && !isSecure && 1368 !(tranType & S1CTran); 1369 directToStage2 = stage2Req && !sctlr.m; 1370 } else { 1371 vmid = 0; 1372 stage2Req = false; 1373 isHyp = false; 1374 directToStage2 = false; 1375 } 1376 } 1377 miscRegValid = true; 1378 miscRegContext = tc->contextId(); 1379 curTranType = tranType; 1380} 1381 1382Fault 1383TLB::getTE(TlbEntry **te, RequestPtr req, ThreadContext *tc, Mode mode, 1384 Translation *translation, bool timing, bool functional, 1385 bool is_secure, TLB::ArmTranslationType tranType) 1386{ 1387 bool is_fetch = (mode == Execute); 1388 bool is_write = (mode == Write); 1389 1390 Addr vaddr_tainted = req->getVaddr(); 1391 Addr vaddr = 0; 1392 ExceptionLevel target_el = aarch64 ? aarch64EL : EL1; 1393 if (aarch64) { 1394 vaddr = purifyTaggedAddr(vaddr_tainted, tc, target_el, ttbcr); 1395 } else { 1396 vaddr = vaddr_tainted; 1397 } 1398 *te = lookup(vaddr, asid, vmid, isHyp, is_secure, false, false, target_el); 1399 if (*te == NULL) { 1400 if (req->isPrefetch()) { 1401 // if the request is a prefetch don't attempt to fill the TLB or go 1402 // any further with the memory access (here we can safely use the 1403 // fault status for the short desc. format in all cases) 1404 prefetchFaults++; 1405 return std::make_shared<PrefetchAbort>( 1406 vaddr_tainted, ArmFault::PrefetchTLBMiss, isStage2); 1407 } 1408 1409 if (is_fetch) 1410 instMisses++; 1411 else if (is_write) 1412 writeMisses++; 1413 else 1414 readMisses++; 1415 1416 // start translation table walk, pass variables rather than 1417 // re-retreaving in table walker for speed 1418 DPRINTF(TLB, "TLB Miss: Starting hardware table walker for %#x(%d:%d)\n", 1419 vaddr_tainted, asid, vmid); 1420 Fault fault; 1421 fault = tableWalker->walk(req, tc, asid, vmid, isHyp, mode, 1422 translation, timing, functional, is_secure, 1423 tranType, stage2Req); 1424 // for timing mode, return and wait for table walk, 1425 if (timing || fault != NoFault) { 1426 return fault; 1427 } 1428 1429 *te = lookup(vaddr, asid, vmid, isHyp, is_secure, false, false, target_el); 1430 if (!*te) 1431 printTlb(); 1432 assert(*te); 1433 } else { 1434 if (is_fetch) 1435 instHits++; 1436 else if (is_write) 1437 writeHits++; 1438 else 1439 readHits++; 1440 } 1441 return NoFault; 1442} 1443 1444Fault 1445TLB::getResultTe(TlbEntry **te, RequestPtr req, ThreadContext *tc, Mode mode, 1446 Translation *translation, bool timing, bool functional, 1447 TlbEntry *mergeTe) 1448{ 1449 Fault fault; 1450 1451 if (isStage2) { 1452 // We are already in the stage 2 TLB. Grab the table entry for stage 1453 // 2 only. We are here because stage 1 translation is disabled. 1454 TlbEntry *s2Te = NULL; 1455 // Get the stage 2 table entry 1456 fault = getTE(&s2Te, req, tc, mode, translation, timing, functional, 1457 isSecure, curTranType); 1458 // Check permissions of stage 2 1459 if ((s2Te != NULL) && (fault = NoFault)) { 1460 if(aarch64) 1461 fault = checkPermissions64(s2Te, req, mode, tc); 1462 else 1463 fault = checkPermissions(s2Te, req, mode); 1464 } 1465 *te = s2Te; 1466 return fault; 1467 } 1468 1469 TlbEntry *s1Te = NULL; 1470 1471 Addr vaddr_tainted = req->getVaddr(); 1472 1473 // Get the stage 1 table entry 1474 fault = getTE(&s1Te, req, tc, mode, translation, timing, functional, 1475 isSecure, curTranType); 1476 // only proceed if we have a valid table entry 1477 if ((s1Te != NULL) && (fault == NoFault)) { 1478 // Check stage 1 permissions before checking stage 2 1479 if (aarch64) 1480 fault = checkPermissions64(s1Te, req, mode, tc); 1481 else 1482 fault = checkPermissions(s1Te, req, mode); 1483 if (stage2Req & (fault == NoFault)) { 1484 Stage2LookUp *s2Lookup = new Stage2LookUp(this, stage2Tlb, *s1Te, 1485 req, translation, mode, timing, functional, curTranType); 1486 fault = s2Lookup->getTe(tc, mergeTe); 1487 if (s2Lookup->isComplete()) { 1488 *te = mergeTe; 1489 // We've finished with the lookup so delete it 1490 delete s2Lookup; 1491 } else { 1492 // The lookup hasn't completed, so we can't delete it now. We 1493 // get round this by asking the object to self delete when the 1494 // translation is complete. 1495 s2Lookup->setSelfDelete(); 1496 } 1497 } else { 1498 // This case deals with an S1 hit (or bypass), followed by 1499 // an S2 hit-but-perms issue 1500 if (isStage2) { 1501 DPRINTF(TLBVerbose, "s2TLB: reqVa %#x, reqPa %#x, fault %p\n", 1502 vaddr_tainted, req->hasPaddr() ? req->getPaddr() : ~0, fault); 1503 if (fault != NoFault) { 1504 ArmFault *armFault = reinterpret_cast<ArmFault *>(fault.get()); 1505 armFault->annotate(ArmFault::S1PTW, false); 1506 armFault->annotate(ArmFault::OVA, vaddr_tainted); 1507 } 1508 } 1509 *te = s1Te; 1510 } 1511 } 1512 return fault; 1513} 1514 1515void 1516TLB::setTestInterface(SimObject *_ti) 1517{ 1518 if (!_ti) { 1519 test = nullptr; 1520 } else { 1521 TlbTestInterface *ti(dynamic_cast<TlbTestInterface *>(_ti)); 1522 fatal_if(!ti, "%s is not a valid ARM TLB tester\n", _ti->name()); 1523 test = ti; 1524 } 1525} 1526 1527Fault 1528TLB::testTranslation(RequestPtr req, Mode mode, TlbEntry::DomainType domain) 1529{ 1530 if (!test || !req->hasSize() || req->getSize() == 0) { 1531 return NoFault; 1532 } else { 1533 return test->translationCheck(req, isPriv, mode, domain); 1534 } 1535} 1536 1537Fault 1538TLB::testWalk(Addr pa, Addr size, Addr va, bool is_secure, Mode mode, 1539 TlbEntry::DomainType domain, LookupLevel lookup_level) 1540{ 1541 if (!test) { 1542 return NoFault; 1543 } else { 1544 return test->walkCheck(pa, size, va, is_secure, isPriv, mode, 1545 domain, lookup_level); 1546 } 1547} 1548 1549 1550ArmISA::TLB * 1551ArmTLBParams::create() 1552{ 1553 return new ArmISA::TLB(this); 1554} 1555