tlb.cc revision 6023
1/* 2 * Copyright (c) 2001-2005 The Regents of The University of Michigan 3 * All rights reserved. 4 * 5 * Redistribution and use in source and binary forms, with or without 6 * modification, are permitted provided that the following conditions are 7 * met: redistributions of source code must retain the above copyright 8 * notice, this list of conditions and the following disclaimer; 9 * redistributions in binary form must reproduce the above copyright 10 * notice, this list of conditions and the following disclaimer in the 11 * documentation and/or other materials provided with the distribution; 12 * neither the name of the copyright holders nor the names of its 13 * contributors may be used to endorse or promote products derived from 14 * this software without specific prior written permission. 15 * 16 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 17 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 18 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 19 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 20 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 21 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 22 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 23 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 24 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 25 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 26 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 27 * 28 * Authors: Ali Saidi 29 */ 30 31#include <cstring> 32 33#include "arch/sparc/asi.hh" 34#include "arch/sparc/miscregfile.hh" 35#include "arch/sparc/tlb.hh" 36#include "base/bitfield.hh" 37#include "base/trace.hh" 38#include "cpu/thread_context.hh" 39#include "cpu/base.hh" 40#include "mem/packet_access.hh" 41#include "mem/request.hh" 42#include "sim/system.hh" 43 44/* @todo remove some of the magic constants. -- ali 45 * */ 46namespace SparcISA { 47 48TLB::TLB(const Params *p) 49 : BaseTLB(p), size(p->size), usedEntries(0), lastReplaced(0), 50 cacheValid(false) 51{ 52 // To make this work you'll have to change the hypervisor and OS 53 if (size > 64) 54 fatal("SPARC T1 TLB registers don't support more than 64 TLB entries"); 55 56 tlb = new TlbEntry[size]; 57 std::memset(tlb, 0, sizeof(TlbEntry) * size); 58 59 for (int x = 0; x < size; x++) 60 freeList.push_back(&tlb[x]); 61 62 c0_tsb_ps0 = 0; 63 c0_tsb_ps1 = 0; 64 c0_config = 0; 65 cx_tsb_ps0 = 0; 66 cx_tsb_ps1 = 0; 67 cx_config = 0; 68 sfsr = 0; 69 tag_access = 0; 70 sfar = 0; 71 cacheEntry[0] = NULL; 72 cacheEntry[1] = NULL; 73} 74 75void 76TLB::clearUsedBits() 77{ 78 MapIter i; 79 for (i = lookupTable.begin(); i != lookupTable.end(); i++) { 80 TlbEntry *t = i->second; 81 if (!t->pte.locked()) { 82 t->used = false; 83 usedEntries--; 84 } 85 } 86} 87 88 89void 90TLB::insert(Addr va, int partition_id, int context_id, bool real, 91 const PageTableEntry& PTE, int entry) 92{ 93 MapIter i; 94 TlbEntry *new_entry = NULL; 95// TlbRange tr; 96 int x; 97 98 cacheValid = false; 99 va &= ~(PTE.size()-1); 100 /* tr.va = va; 101 tr.size = PTE.size() - 1; 102 tr.contextId = context_id; 103 tr.partitionId = partition_id; 104 tr.real = real; 105*/ 106 107 DPRINTF(TLB, 108 "TLB: Inserting Entry; va=%#x pa=%#x pid=%d cid=%d r=%d entryid=%d\n", 109 va, PTE.paddr(), partition_id, context_id, (int)real, entry); 110 111 // Demap any entry that conflicts 112 for (x = 0; x < size; x++) { 113 if (tlb[x].range.real == real && 114 tlb[x].range.partitionId == partition_id && 115 tlb[x].range.va < va + PTE.size() - 1 && 116 tlb[x].range.va + tlb[x].range.size >= va && 117 (real || tlb[x].range.contextId == context_id )) 118 { 119 if (tlb[x].valid) { 120 freeList.push_front(&tlb[x]); 121 DPRINTF(TLB, "TLB: Conflicting entry %#X , deleting it\n", x); 122 123 tlb[x].valid = false; 124 if (tlb[x].used) { 125 tlb[x].used = false; 126 usedEntries--; 127 } 128 lookupTable.erase(tlb[x].range); 129 } 130 } 131 } 132 133/* 134 i = lookupTable.find(tr); 135 if (i != lookupTable.end()) { 136 i->second->valid = false; 137 if (i->second->used) { 138 i->second->used = false; 139 usedEntries--; 140 } 141 freeList.push_front(i->second); 142 DPRINTF(TLB, "TLB: Found conflicting entry %#X , deleting it\n", 143 i->second); 144 lookupTable.erase(i); 145 } 146*/ 147 148 if (entry != -1) { 149 assert(entry < size && entry >= 0); 150 new_entry = &tlb[entry]; 151 } else { 152 if (!freeList.empty()) { 153 new_entry = freeList.front(); 154 } else { 155 x = lastReplaced; 156 do { 157 ++x; 158 if (x == size) 159 x = 0; 160 if (x == lastReplaced) 161 goto insertAllLocked; 162 } while (tlb[x].pte.locked()); 163 lastReplaced = x; 164 new_entry = &tlb[x]; 165 } 166 /* 167 for (x = 0; x < size; x++) { 168 if (!tlb[x].valid || !tlb[x].used) { 169 new_entry = &tlb[x]; 170 break; 171 } 172 }*/ 173 } 174 175insertAllLocked: 176 // Update the last ently if their all locked 177 if (!new_entry) { 178 new_entry = &tlb[size-1]; 179 } 180 181 freeList.remove(new_entry); 182 if (new_entry->valid && new_entry->used) 183 usedEntries--; 184 if (new_entry->valid) 185 lookupTable.erase(new_entry->range); 186 187 188 assert(PTE.valid()); 189 new_entry->range.va = va; 190 new_entry->range.size = PTE.size() - 1; 191 new_entry->range.partitionId = partition_id; 192 new_entry->range.contextId = context_id; 193 new_entry->range.real = real; 194 new_entry->pte = PTE; 195 new_entry->used = true;; 196 new_entry->valid = true; 197 usedEntries++; 198 199 i = lookupTable.insert(new_entry->range, new_entry); 200 assert(i != lookupTable.end()); 201 202 // If all entries have their used bit set, clear it on them all, 203 // but the one we just inserted 204 if (usedEntries == size) { 205 clearUsedBits(); 206 new_entry->used = true; 207 usedEntries++; 208 } 209} 210 211 212TlbEntry* 213TLB::lookup(Addr va, int partition_id, bool real, int context_id, 214 bool update_used) 215{ 216 MapIter i; 217 TlbRange tr; 218 TlbEntry *t; 219 220 DPRINTF(TLB, "TLB: Looking up entry va=%#x pid=%d cid=%d r=%d\n", 221 va, partition_id, context_id, real); 222 // Assemble full address structure 223 tr.va = va; 224 tr.size = 1; 225 tr.contextId = context_id; 226 tr.partitionId = partition_id; 227 tr.real = real; 228 229 // Try to find the entry 230 i = lookupTable.find(tr); 231 if (i == lookupTable.end()) { 232 DPRINTF(TLB, "TLB: No valid entry found\n"); 233 return NULL; 234 } 235 236 // Mark the entries used bit and clear other used bits in needed 237 t = i->second; 238 DPRINTF(TLB, "TLB: Valid entry found pa: %#x size: %#x\n", t->pte.paddr(), 239 t->pte.size()); 240 241 // Update the used bits only if this is a real access (not a fake 242 // one from virttophys() 243 if (!t->used && update_used) { 244 t->used = true; 245 usedEntries++; 246 if (usedEntries == size) { 247 clearUsedBits(); 248 t->used = true; 249 usedEntries++; 250 } 251 } 252 253 return t; 254} 255 256void 257TLB::dumpAll() 258{ 259 MapIter i; 260 for (int x = 0; x < size; x++) { 261 if (tlb[x].valid) { 262 DPRINTFN("%4d: %#2x:%#2x %c %#4x %#8x %#8x %#16x\n", 263 x, tlb[x].range.partitionId, tlb[x].range.contextId, 264 tlb[x].range.real ? 'R' : ' ', tlb[x].range.size, 265 tlb[x].range.va, tlb[x].pte.paddr(), tlb[x].pte()); 266 } 267 } 268} 269 270void 271TLB::demapPage(Addr va, int partition_id, bool real, int context_id) 272{ 273 TlbRange tr; 274 MapIter i; 275 276 DPRINTF(IPR, "TLB: Demapping Page va=%#x pid=%#d cid=%d r=%d\n", 277 va, partition_id, context_id, real); 278 279 cacheValid = false; 280 281 // Assemble full address structure 282 tr.va = va; 283 tr.size = 1; 284 tr.contextId = context_id; 285 tr.partitionId = partition_id; 286 tr.real = real; 287 288 // Demap any entry that conflicts 289 i = lookupTable.find(tr); 290 if (i != lookupTable.end()) { 291 DPRINTF(IPR, "TLB: Demapped page\n"); 292 i->second->valid = false; 293 if (i->second->used) { 294 i->second->used = false; 295 usedEntries--; 296 } 297 freeList.push_front(i->second); 298 lookupTable.erase(i); 299 } 300} 301 302void 303TLB::demapContext(int partition_id, int context_id) 304{ 305 DPRINTF(IPR, "TLB: Demapping Context pid=%#d cid=%d\n", 306 partition_id, context_id); 307 cacheValid = false; 308 for (int x = 0; x < size; x++) { 309 if (tlb[x].range.contextId == context_id && 310 tlb[x].range.partitionId == partition_id) { 311 if (tlb[x].valid == true) { 312 freeList.push_front(&tlb[x]); 313 } 314 tlb[x].valid = false; 315 if (tlb[x].used) { 316 tlb[x].used = false; 317 usedEntries--; 318 } 319 lookupTable.erase(tlb[x].range); 320 } 321 } 322} 323 324void 325TLB::demapAll(int partition_id) 326{ 327 DPRINTF(TLB, "TLB: Demapping All pid=%#d\n", partition_id); 328 cacheValid = false; 329 for (int x = 0; x < size; x++) { 330 if (tlb[x].valid && !tlb[x].pte.locked() && 331 tlb[x].range.partitionId == partition_id) { 332 freeList.push_front(&tlb[x]); 333 tlb[x].valid = false; 334 if (tlb[x].used) { 335 tlb[x].used = false; 336 usedEntries--; 337 } 338 lookupTable.erase(tlb[x].range); 339 } 340 } 341} 342 343void 344TLB::invalidateAll() 345{ 346 cacheValid = false; 347 lookupTable.clear(); 348 349 for (int x = 0; x < size; x++) { 350 if (tlb[x].valid == true) 351 freeList.push_back(&tlb[x]); 352 tlb[x].valid = false; 353 tlb[x].used = false; 354 } 355 usedEntries = 0; 356} 357 358uint64_t 359TLB::TteRead(int entry) 360{ 361 if (entry >= size) 362 panic("entry: %d\n", entry); 363 364 assert(entry < size); 365 if (tlb[entry].valid) 366 return tlb[entry].pte(); 367 else 368 return (uint64_t)-1ll; 369} 370 371uint64_t 372TLB::TagRead(int entry) 373{ 374 assert(entry < size); 375 uint64_t tag; 376 if (!tlb[entry].valid) 377 return (uint64_t)-1ll; 378 379 tag = tlb[entry].range.contextId; 380 tag |= tlb[entry].range.va; 381 tag |= (uint64_t)tlb[entry].range.partitionId << 61; 382 tag |= tlb[entry].range.real ? ULL(1) << 60 : 0; 383 tag |= (uint64_t)~tlb[entry].pte._size() << 56; 384 return tag; 385} 386 387bool 388TLB::validVirtualAddress(Addr va, bool am) 389{ 390 if (am) 391 return true; 392 if (va >= StartVAddrHole && va <= EndVAddrHole) 393 return false; 394 return true; 395} 396 397void 398TLB::writeSfsr(bool write, ContextType ct, bool se, FaultTypes ft, int asi) 399{ 400 if (sfsr & 0x1) 401 sfsr = 0x3; 402 else 403 sfsr = 1; 404 405 if (write) 406 sfsr |= 1 << 2; 407 sfsr |= ct << 4; 408 if (se) 409 sfsr |= 1 << 6; 410 sfsr |= ft << 7; 411 sfsr |= asi << 16; 412} 413 414void 415TLB::writeTagAccess(Addr va, int context) 416{ 417 DPRINTF(TLB, "TLB: Writing Tag Access: va: %#X ctx: %#X value: %#X\n", 418 va, context, mbits(va, 63,13) | mbits(context,12,0)); 419 420 tag_access = mbits(va, 63,13) | mbits(context,12,0); 421} 422 423void 424TLB::writeSfsr(Addr a, bool write, ContextType ct, 425 bool se, FaultTypes ft, int asi) 426{ 427 DPRINTF(TLB, "TLB: Fault: A=%#x w=%d ct=%d ft=%d asi=%d\n", 428 a, (int)write, ct, ft, asi); 429 TLB::writeSfsr(write, ct, se, ft, asi); 430 sfar = a; 431} 432 433Fault 434TLB::translateInst(RequestPtr req, ThreadContext *tc) 435{ 436 uint64_t tlbdata = tc->readMiscRegNoEffect(MISCREG_TLB_DATA); 437 438 Addr vaddr = req->getVaddr(); 439 TlbEntry *e; 440 441 assert(req->getAsi() == ASI_IMPLICIT); 442 443 DPRINTF(TLB, "TLB: ITB Request to translate va=%#x size=%d\n", 444 vaddr, req->getSize()); 445 446 // Be fast if we can! 447 if (cacheValid && cacheState == tlbdata) { 448 if (cacheEntry[0]) { 449 if (cacheEntry[0]->range.va < vaddr + sizeof(MachInst) && 450 cacheEntry[0]->range.va + cacheEntry[0]->range.size >= vaddr) { 451 req->setPaddr(cacheEntry[0]->pte.translate(vaddr)); 452 return NoFault; 453 } 454 } else { 455 req->setPaddr(vaddr & PAddrImplMask); 456 return NoFault; 457 } 458 } 459 460 bool hpriv = bits(tlbdata,0,0); 461 bool red = bits(tlbdata,1,1); 462 bool priv = bits(tlbdata,2,2); 463 bool addr_mask = bits(tlbdata,3,3); 464 bool lsu_im = bits(tlbdata,4,4); 465 466 int part_id = bits(tlbdata,15,8); 467 int tl = bits(tlbdata,18,16); 468 int pri_context = bits(tlbdata,47,32); 469 int context; 470 ContextType ct; 471 int asi; 472 bool real = false; 473 474 DPRINTF(TLB, "TLB: priv:%d hpriv:%d red:%d lsuim:%d part_id: %#X\n", 475 priv, hpriv, red, lsu_im, part_id); 476 477 if (tl > 0) { 478 asi = ASI_N; 479 ct = Nucleus; 480 context = 0; 481 } else { 482 asi = ASI_P; 483 ct = Primary; 484 context = pri_context; 485 } 486 487 if ( hpriv || red ) { 488 cacheValid = true; 489 cacheState = tlbdata; 490 cacheEntry[0] = NULL; 491 req->setPaddr(vaddr & PAddrImplMask); 492 return NoFault; 493 } 494 495 // If the access is unaligned trap 496 if (vaddr & 0x3) { 497 writeSfsr(false, ct, false, OtherFault, asi); 498 return new MemAddressNotAligned; 499 } 500 501 if (addr_mask) 502 vaddr = vaddr & VAddrAMask; 503 504 if (!validVirtualAddress(vaddr, addr_mask)) { 505 writeSfsr(false, ct, false, VaOutOfRange, asi); 506 return new InstructionAccessException; 507 } 508 509 if (!lsu_im) { 510 e = lookup(vaddr, part_id, true); 511 real = true; 512 context = 0; 513 } else { 514 e = lookup(vaddr, part_id, false, context); 515 } 516 517 if (e == NULL || !e->valid) { 518 writeTagAccess(vaddr, context); 519 if (real) 520 return new InstructionRealTranslationMiss; 521 else 522#if FULL_SYSTEM 523 return new FastInstructionAccessMMUMiss; 524#else 525 return new FastInstructionAccessMMUMiss(req->getVaddr()); 526#endif 527 } 528 529 // were not priviledged accesing priv page 530 if (!priv && e->pte.priv()) { 531 writeTagAccess(vaddr, context); 532 writeSfsr(false, ct, false, PrivViolation, asi); 533 return new InstructionAccessException; 534 } 535 536 // cache translation date for next translation 537 cacheValid = true; 538 cacheState = tlbdata; 539 cacheEntry[0] = e; 540 541 req->setPaddr(e->pte.translate(vaddr)); 542 DPRINTF(TLB, "TLB: %#X -> %#X\n", vaddr, req->getPaddr()); 543 return NoFault; 544} 545 546Fault 547TLB::translateData(RequestPtr req, ThreadContext *tc, bool write) 548{ 549 /* 550 * @todo this could really use some profiling and fixing to make 551 * it faster! 552 */ 553 uint64_t tlbdata = tc->readMiscRegNoEffect(MISCREG_TLB_DATA); 554 Addr vaddr = req->getVaddr(); 555 Addr size = req->getSize(); 556 ASI asi; 557 asi = (ASI)req->getAsi(); 558 bool implicit = false; 559 bool hpriv = bits(tlbdata,0,0); 560 bool unaligned = vaddr & (size - 1); 561 562 DPRINTF(TLB, "TLB: DTB Request to translate va=%#x size=%d asi=%#x\n", 563 vaddr, size, asi); 564 565 if (lookupTable.size() != 64 - freeList.size()) 566 panic("Lookup table size: %d tlb size: %d\n", lookupTable.size(), 567 freeList.size()); 568 if (asi == ASI_IMPLICIT) 569 implicit = true; 570 571 // Only use the fast path here if there doesn't need to be an unaligned 572 // trap later 573 if (!unaligned) { 574 if (hpriv && implicit) { 575 req->setPaddr(vaddr & PAddrImplMask); 576 return NoFault; 577 } 578 579 // Be fast if we can! 580 if (cacheValid && cacheState == tlbdata) { 581 582 583 584 if (cacheEntry[0]) { 585 TlbEntry *ce = cacheEntry[0]; 586 Addr ce_va = ce->range.va; 587 if (cacheAsi[0] == asi && 588 ce_va < vaddr + size && ce_va + ce->range.size > vaddr && 589 (!write || ce->pte.writable())) { 590 req->setPaddr(ce->pte.translate(vaddr)); 591 if (ce->pte.sideffect() || (ce->pte.paddr() >> 39) & 1) 592 req->setFlags(Request::UNCACHEABLE); 593 DPRINTF(TLB, "TLB: %#X -> %#X\n", vaddr, req->getPaddr()); 594 return NoFault; 595 } // if matched 596 } // if cache entry valid 597 if (cacheEntry[1]) { 598 TlbEntry *ce = cacheEntry[1]; 599 Addr ce_va = ce->range.va; 600 if (cacheAsi[1] == asi && 601 ce_va < vaddr + size && ce_va + ce->range.size > vaddr && 602 (!write || ce->pte.writable())) { 603 req->setPaddr(ce->pte.translate(vaddr)); 604 if (ce->pte.sideffect() || (ce->pte.paddr() >> 39) & 1) 605 req->setFlags(Request::UNCACHEABLE); 606 DPRINTF(TLB, "TLB: %#X -> %#X\n", vaddr, req->getPaddr()); 607 return NoFault; 608 } // if matched 609 } // if cache entry valid 610 } 611 } 612 613 bool red = bits(tlbdata,1,1); 614 bool priv = bits(tlbdata,2,2); 615 bool addr_mask = bits(tlbdata,3,3); 616 bool lsu_dm = bits(tlbdata,5,5); 617 618 int part_id = bits(tlbdata,15,8); 619 int tl = bits(tlbdata,18,16); 620 int pri_context = bits(tlbdata,47,32); 621 int sec_context = bits(tlbdata,63,48); 622 623 bool real = false; 624 ContextType ct = Primary; 625 int context = 0; 626 627 TlbEntry *e; 628 629 DPRINTF(TLB, "TLB: priv:%d hpriv:%d red:%d lsudm:%d part_id: %#X\n", 630 priv, hpriv, red, lsu_dm, part_id); 631 632 if (implicit) { 633 if (tl > 0) { 634 asi = ASI_N; 635 ct = Nucleus; 636 context = 0; 637 } else { 638 asi = ASI_P; 639 ct = Primary; 640 context = pri_context; 641 } 642 } else { 643 // We need to check for priv level/asi priv 644 if (!priv && !hpriv && !AsiIsUnPriv(asi)) { 645 // It appears that context should be Nucleus in these cases? 646 writeSfsr(vaddr, write, Nucleus, false, IllegalAsi, asi); 647 return new PrivilegedAction; 648 } 649 650 if (!hpriv && AsiIsHPriv(asi)) { 651 writeSfsr(vaddr, write, Nucleus, false, IllegalAsi, asi); 652 return new DataAccessException; 653 } 654 655 if (AsiIsPrimary(asi)) { 656 context = pri_context; 657 ct = Primary; 658 } else if (AsiIsSecondary(asi)) { 659 context = sec_context; 660 ct = Secondary; 661 } else if (AsiIsNucleus(asi)) { 662 ct = Nucleus; 663 context = 0; 664 } else { // ???? 665 ct = Primary; 666 context = pri_context; 667 } 668 } 669 670 if (!implicit && asi != ASI_P && asi != ASI_S) { 671 if (AsiIsLittle(asi)) 672 panic("Little Endian ASIs not supported\n"); 673 674 //XXX It's unclear from looking at the documentation how a no fault 675 //load differs from a regular one, other than what happens concerning 676 //nfo and e bits in the TTE 677// if (AsiIsNoFault(asi)) 678// panic("No Fault ASIs not supported\n"); 679 680 if (AsiIsPartialStore(asi)) 681 panic("Partial Store ASIs not supported\n"); 682 683 if (AsiIsCmt(asi)) 684 panic("Cmt ASI registers not implmented\n"); 685 686 if (AsiIsInterrupt(asi)) 687 goto handleIntRegAccess; 688 if (AsiIsMmu(asi)) 689 goto handleMmuRegAccess; 690 if (AsiIsScratchPad(asi)) 691 goto handleScratchRegAccess; 692 if (AsiIsQueue(asi)) 693 goto handleQueueRegAccess; 694 if (AsiIsSparcError(asi)) 695 goto handleSparcErrorRegAccess; 696 697 if (!AsiIsReal(asi) && !AsiIsNucleus(asi) && !AsiIsAsIfUser(asi) && 698 !AsiIsTwin(asi) && !AsiIsBlock(asi) && !AsiIsNoFault(asi)) 699 panic("Accessing ASI %#X. Should we?\n", asi); 700 } 701 702 // If the asi is unaligned trap 703 if (unaligned) { 704 writeSfsr(vaddr, false, ct, false, OtherFault, asi); 705 return new MemAddressNotAligned; 706 } 707 708 if (addr_mask) 709 vaddr = vaddr & VAddrAMask; 710 711 if (!validVirtualAddress(vaddr, addr_mask)) { 712 writeSfsr(vaddr, false, ct, true, VaOutOfRange, asi); 713 return new DataAccessException; 714 } 715 716 if ((!lsu_dm && !hpriv && !red) || AsiIsReal(asi)) { 717 real = true; 718 context = 0; 719 } 720 721 if (hpriv && (implicit || (!AsiIsAsIfUser(asi) && !AsiIsReal(asi)))) { 722 req->setPaddr(vaddr & PAddrImplMask); 723 return NoFault; 724 } 725 726 e = lookup(vaddr, part_id, real, context); 727 728 if (e == NULL || !e->valid) { 729 writeTagAccess(vaddr, context); 730 DPRINTF(TLB, "TLB: DTB Failed to find matching TLB entry\n"); 731 if (real) 732 return new DataRealTranslationMiss; 733 else 734#if FULL_SYSTEM 735 return new FastDataAccessMMUMiss; 736#else 737 return new FastDataAccessMMUMiss(req->getVaddr()); 738#endif 739 740 } 741 742 if (!priv && e->pte.priv()) { 743 writeTagAccess(vaddr, context); 744 writeSfsr(vaddr, write, ct, e->pte.sideffect(), PrivViolation, asi); 745 return new DataAccessException; 746 } 747 748 if (write && !e->pte.writable()) { 749 writeTagAccess(vaddr, context); 750 writeSfsr(vaddr, write, ct, e->pte.sideffect(), OtherFault, asi); 751 return new FastDataAccessProtection; 752 } 753 754 if (e->pte.nofault() && !AsiIsNoFault(asi)) { 755 writeTagAccess(vaddr, context); 756 writeSfsr(vaddr, write, ct, e->pte.sideffect(), LoadFromNfo, asi); 757 return new DataAccessException; 758 } 759 760 if (e->pte.sideffect() && AsiIsNoFault(asi)) { 761 writeTagAccess(vaddr, context); 762 writeSfsr(vaddr, write, ct, e->pte.sideffect(), SideEffect, asi); 763 return new DataAccessException; 764 } 765 766 if (e->pte.sideffect() || (e->pte.paddr() >> 39) & 1) 767 req->setFlags(Request::UNCACHEABLE); 768 769 // cache translation date for next translation 770 cacheState = tlbdata; 771 if (!cacheValid) { 772 cacheEntry[1] = NULL; 773 cacheEntry[0] = NULL; 774 } 775 776 if (cacheEntry[0] != e && cacheEntry[1] != e) { 777 cacheEntry[1] = cacheEntry[0]; 778 cacheEntry[0] = e; 779 cacheAsi[1] = cacheAsi[0]; 780 cacheAsi[0] = asi; 781 if (implicit) 782 cacheAsi[0] = (ASI)0; 783 } 784 cacheValid = true; 785 req->setPaddr(e->pte.translate(vaddr)); 786 DPRINTF(TLB, "TLB: %#X -> %#X\n", vaddr, req->getPaddr()); 787 return NoFault; 788 789 /** Normal flow ends here. */ 790handleIntRegAccess: 791 if (!hpriv) { 792 writeSfsr(vaddr, write, Primary, true, IllegalAsi, asi); 793 if (priv) 794 return new DataAccessException; 795 else 796 return new PrivilegedAction; 797 } 798 799 if ((asi == ASI_SWVR_UDB_INTR_W && !write) || 800 (asi == ASI_SWVR_UDB_INTR_R && write)) { 801 writeSfsr(vaddr, write, Primary, true, IllegalAsi, asi); 802 return new DataAccessException; 803 } 804 805 goto regAccessOk; 806 807 808handleScratchRegAccess: 809 if (vaddr > 0x38 || (vaddr >= 0x20 && vaddr < 0x30 && !hpriv)) { 810 writeSfsr(vaddr, write, Primary, true, IllegalAsi, asi); 811 return new DataAccessException; 812 } 813 goto regAccessOk; 814 815handleQueueRegAccess: 816 if (!priv && !hpriv) { 817 writeSfsr(vaddr, write, Primary, true, IllegalAsi, asi); 818 return new PrivilegedAction; 819 } 820 if ((!hpriv && vaddr & 0xF) || vaddr > 0x3f8 || vaddr < 0x3c0) { 821 writeSfsr(vaddr, write, Primary, true, IllegalAsi, asi); 822 return new DataAccessException; 823 } 824 goto regAccessOk; 825 826handleSparcErrorRegAccess: 827 if (!hpriv) { 828 writeSfsr(vaddr, write, Primary, true, IllegalAsi, asi); 829 if (priv) 830 return new DataAccessException; 831 else 832 return new PrivilegedAction; 833 } 834 goto regAccessOk; 835 836 837regAccessOk: 838handleMmuRegAccess: 839 DPRINTF(TLB, "TLB: DTB Translating MM IPR access\n"); 840 req->setMmapedIpr(true); 841 req->setPaddr(req->getVaddr()); 842 return NoFault; 843}; 844 845Fault 846TLB::translateAtomic(RequestPtr req, ThreadContext *tc, Mode mode) 847{ 848 if (mode == Execute) 849 return translateInst(req, tc); 850 else 851 return translateData(req, tc, mode == Write); 852} 853 854void 855TLB::translateTiming(RequestPtr req, ThreadContext *tc, 856 Translation *translation, Mode mode) 857{ 858 assert(translation); 859 translation->finish(translateAtomic(req, tc, mode), req, tc, mode); 860} 861 862#if FULL_SYSTEM 863 864Tick 865TLB::doMmuRegRead(ThreadContext *tc, Packet *pkt) 866{ 867 Addr va = pkt->getAddr(); 868 ASI asi = (ASI)pkt->req->getAsi(); 869 uint64_t temp; 870 871 DPRINTF(IPR, "Memory Mapped IPR Read: asi=%#X a=%#x\n", 872 (uint32_t)pkt->req->getAsi(), pkt->getAddr()); 873 874 TLB *itb = tc->getITBPtr(); 875 876 switch (asi) { 877 case ASI_LSU_CONTROL_REG: 878 assert(va == 0); 879 pkt->set(tc->readMiscReg(MISCREG_MMU_LSU_CTRL)); 880 break; 881 case ASI_MMU: 882 switch (va) { 883 case 0x8: 884 pkt->set(tc->readMiscReg(MISCREG_MMU_P_CONTEXT)); 885 break; 886 case 0x10: 887 pkt->set(tc->readMiscReg(MISCREG_MMU_S_CONTEXT)); 888 break; 889 default: 890 goto doMmuReadError; 891 } 892 break; 893 case ASI_QUEUE: 894 pkt->set(tc->readMiscReg(MISCREG_QUEUE_CPU_MONDO_HEAD + 895 (va >> 4) - 0x3c)); 896 break; 897 case ASI_DMMU_CTXT_ZERO_TSB_BASE_PS0: 898 assert(va == 0); 899 pkt->set(c0_tsb_ps0); 900 break; 901 case ASI_DMMU_CTXT_ZERO_TSB_BASE_PS1: 902 assert(va == 0); 903 pkt->set(c0_tsb_ps1); 904 break; 905 case ASI_DMMU_CTXT_ZERO_CONFIG: 906 assert(va == 0); 907 pkt->set(c0_config); 908 break; 909 case ASI_IMMU_CTXT_ZERO_TSB_BASE_PS0: 910 assert(va == 0); 911 pkt->set(itb->c0_tsb_ps0); 912 break; 913 case ASI_IMMU_CTXT_ZERO_TSB_BASE_PS1: 914 assert(va == 0); 915 pkt->set(itb->c0_tsb_ps1); 916 break; 917 case ASI_IMMU_CTXT_ZERO_CONFIG: 918 assert(va == 0); 919 pkt->set(itb->c0_config); 920 break; 921 case ASI_DMMU_CTXT_NONZERO_TSB_BASE_PS0: 922 assert(va == 0); 923 pkt->set(cx_tsb_ps0); 924 break; 925 case ASI_DMMU_CTXT_NONZERO_TSB_BASE_PS1: 926 assert(va == 0); 927 pkt->set(cx_tsb_ps1); 928 break; 929 case ASI_DMMU_CTXT_NONZERO_CONFIG: 930 assert(va == 0); 931 pkt->set(cx_config); 932 break; 933 case ASI_IMMU_CTXT_NONZERO_TSB_BASE_PS0: 934 assert(va == 0); 935 pkt->set(itb->cx_tsb_ps0); 936 break; 937 case ASI_IMMU_CTXT_NONZERO_TSB_BASE_PS1: 938 assert(va == 0); 939 pkt->set(itb->cx_tsb_ps1); 940 break; 941 case ASI_IMMU_CTXT_NONZERO_CONFIG: 942 assert(va == 0); 943 pkt->set(itb->cx_config); 944 break; 945 case ASI_SPARC_ERROR_STATUS_REG: 946 pkt->set((uint64_t)0); 947 break; 948 case ASI_HYP_SCRATCHPAD: 949 case ASI_SCRATCHPAD: 950 pkt->set(tc->readMiscReg(MISCREG_SCRATCHPAD_R0 + (va >> 3))); 951 break; 952 case ASI_IMMU: 953 switch (va) { 954 case 0x0: 955 temp = itb->tag_access; 956 pkt->set(bits(temp,63,22) | bits(temp,12,0) << 48); 957 break; 958 case 0x18: 959 pkt->set(itb->sfsr); 960 break; 961 case 0x30: 962 pkt->set(itb->tag_access); 963 break; 964 default: 965 goto doMmuReadError; 966 } 967 break; 968 case ASI_DMMU: 969 switch (va) { 970 case 0x0: 971 temp = tag_access; 972 pkt->set(bits(temp,63,22) | bits(temp,12,0) << 48); 973 break; 974 case 0x18: 975 pkt->set(sfsr); 976 break; 977 case 0x20: 978 pkt->set(sfar); 979 break; 980 case 0x30: 981 pkt->set(tag_access); 982 break; 983 case 0x80: 984 pkt->set(tc->readMiscReg(MISCREG_MMU_PART_ID)); 985 break; 986 default: 987 goto doMmuReadError; 988 } 989 break; 990 case ASI_DMMU_TSB_PS0_PTR_REG: 991 pkt->set(MakeTsbPtr(Ps0, 992 tag_access, 993 c0_tsb_ps0, 994 c0_config, 995 cx_tsb_ps0, 996 cx_config)); 997 break; 998 case ASI_DMMU_TSB_PS1_PTR_REG: 999 pkt->set(MakeTsbPtr(Ps1, 1000 tag_access, 1001 c0_tsb_ps1, 1002 c0_config, 1003 cx_tsb_ps1, 1004 cx_config)); 1005 break; 1006 case ASI_IMMU_TSB_PS0_PTR_REG: 1007 pkt->set(MakeTsbPtr(Ps0, 1008 itb->tag_access, 1009 itb->c0_tsb_ps0, 1010 itb->c0_config, 1011 itb->cx_tsb_ps0, 1012 itb->cx_config)); 1013 break; 1014 case ASI_IMMU_TSB_PS1_PTR_REG: 1015 pkt->set(MakeTsbPtr(Ps1, 1016 itb->tag_access, 1017 itb->c0_tsb_ps1, 1018 itb->c0_config, 1019 itb->cx_tsb_ps1, 1020 itb->cx_config)); 1021 break; 1022 case ASI_SWVR_INTR_RECEIVE: 1023 { 1024 SparcISA::Interrupts * interrupts = 1025 dynamic_cast<SparcISA::Interrupts *>( 1026 tc->getCpuPtr()->getInterruptController()); 1027 pkt->set(interrupts->get_vec(IT_INT_VEC)); 1028 } 1029 break; 1030 case ASI_SWVR_UDB_INTR_R: 1031 { 1032 SparcISA::Interrupts * interrupts = 1033 dynamic_cast<SparcISA::Interrupts *>( 1034 tc->getCpuPtr()->getInterruptController()); 1035 temp = findMsbSet(interrupts->get_vec(IT_INT_VEC)); 1036 tc->getCpuPtr()->clearInterrupt(IT_INT_VEC, temp); 1037 pkt->set(temp); 1038 } 1039 break; 1040 default: 1041doMmuReadError: 1042 panic("need to impl DTB::doMmuRegRead() got asi=%#x, va=%#x\n", 1043 (uint32_t)asi, va); 1044 } 1045 pkt->makeAtomicResponse(); 1046 return tc->getCpuPtr()->ticks(1); 1047} 1048 1049Tick 1050TLB::doMmuRegWrite(ThreadContext *tc, Packet *pkt) 1051{ 1052 uint64_t data = gtoh(pkt->get<uint64_t>()); 1053 Addr va = pkt->getAddr(); 1054 ASI asi = (ASI)pkt->req->getAsi(); 1055 1056 Addr ta_insert; 1057 Addr va_insert; 1058 Addr ct_insert; 1059 int part_insert; 1060 int entry_insert = -1; 1061 bool real_insert; 1062 bool ignore; 1063 int part_id; 1064 int ctx_id; 1065 PageTableEntry pte; 1066 1067 DPRINTF(IPR, "Memory Mapped IPR Write: asi=%#X a=%#x d=%#X\n", 1068 (uint32_t)asi, va, data); 1069 1070 TLB *itb = tc->getITBPtr(); 1071 1072 switch (asi) { 1073 case ASI_LSU_CONTROL_REG: 1074 assert(va == 0); 1075 tc->setMiscReg(MISCREG_MMU_LSU_CTRL, data); 1076 break; 1077 case ASI_MMU: 1078 switch (va) { 1079 case 0x8: 1080 tc->setMiscReg(MISCREG_MMU_P_CONTEXT, data); 1081 break; 1082 case 0x10: 1083 tc->setMiscReg(MISCREG_MMU_S_CONTEXT, data); 1084 break; 1085 default: 1086 goto doMmuWriteError; 1087 } 1088 break; 1089 case ASI_QUEUE: 1090 assert(mbits(data,13,6) == data); 1091 tc->setMiscReg(MISCREG_QUEUE_CPU_MONDO_HEAD + 1092 (va >> 4) - 0x3c, data); 1093 break; 1094 case ASI_DMMU_CTXT_ZERO_TSB_BASE_PS0: 1095 assert(va == 0); 1096 c0_tsb_ps0 = data; 1097 break; 1098 case ASI_DMMU_CTXT_ZERO_TSB_BASE_PS1: 1099 assert(va == 0); 1100 c0_tsb_ps1 = data; 1101 break; 1102 case ASI_DMMU_CTXT_ZERO_CONFIG: 1103 assert(va == 0); 1104 c0_config = data; 1105 break; 1106 case ASI_IMMU_CTXT_ZERO_TSB_BASE_PS0: 1107 assert(va == 0); 1108 itb->c0_tsb_ps0 = data; 1109 break; 1110 case ASI_IMMU_CTXT_ZERO_TSB_BASE_PS1: 1111 assert(va == 0); 1112 itb->c0_tsb_ps1 = data; 1113 break; 1114 case ASI_IMMU_CTXT_ZERO_CONFIG: 1115 assert(va == 0); 1116 itb->c0_config = data; 1117 break; 1118 case ASI_DMMU_CTXT_NONZERO_TSB_BASE_PS0: 1119 assert(va == 0); 1120 cx_tsb_ps0 = data; 1121 break; 1122 case ASI_DMMU_CTXT_NONZERO_TSB_BASE_PS1: 1123 assert(va == 0); 1124 cx_tsb_ps1 = data; 1125 break; 1126 case ASI_DMMU_CTXT_NONZERO_CONFIG: 1127 assert(va == 0); 1128 cx_config = data; 1129 break; 1130 case ASI_IMMU_CTXT_NONZERO_TSB_BASE_PS0: 1131 assert(va == 0); 1132 itb->cx_tsb_ps0 = data; 1133 break; 1134 case ASI_IMMU_CTXT_NONZERO_TSB_BASE_PS1: 1135 assert(va == 0); 1136 itb->cx_tsb_ps1 = data; 1137 break; 1138 case ASI_IMMU_CTXT_NONZERO_CONFIG: 1139 assert(va == 0); 1140 itb->cx_config = data; 1141 break; 1142 case ASI_SPARC_ERROR_EN_REG: 1143 case ASI_SPARC_ERROR_STATUS_REG: 1144 inform("Ignoring write to SPARC ERROR regsiter\n"); 1145 break; 1146 case ASI_HYP_SCRATCHPAD: 1147 case ASI_SCRATCHPAD: 1148 tc->setMiscReg(MISCREG_SCRATCHPAD_R0 + (va >> 3), data); 1149 break; 1150 case ASI_IMMU: 1151 switch (va) { 1152 case 0x18: 1153 itb->sfsr = data; 1154 break; 1155 case 0x30: 1156 sext<59>(bits(data, 59,0)); 1157 itb->tag_access = data; 1158 break; 1159 default: 1160 goto doMmuWriteError; 1161 } 1162 break; 1163 case ASI_ITLB_DATA_ACCESS_REG: 1164 entry_insert = bits(va, 8,3); 1165 case ASI_ITLB_DATA_IN_REG: 1166 assert(entry_insert != -1 || mbits(va,10,9) == va); 1167 ta_insert = itb->tag_access; 1168 va_insert = mbits(ta_insert, 63,13); 1169 ct_insert = mbits(ta_insert, 12,0); 1170 part_insert = tc->readMiscReg(MISCREG_MMU_PART_ID); 1171 real_insert = bits(va, 9,9); 1172 pte.populate(data, bits(va,10,10) ? PageTableEntry::sun4v : 1173 PageTableEntry::sun4u); 1174 tc->getITBPtr()->insert(va_insert, part_insert, ct_insert, real_insert, 1175 pte, entry_insert); 1176 break; 1177 case ASI_DTLB_DATA_ACCESS_REG: 1178 entry_insert = bits(va, 8,3); 1179 case ASI_DTLB_DATA_IN_REG: 1180 assert(entry_insert != -1 || mbits(va,10,9) == va); 1181 ta_insert = tag_access; 1182 va_insert = mbits(ta_insert, 63,13); 1183 ct_insert = mbits(ta_insert, 12,0); 1184 part_insert = tc->readMiscReg(MISCREG_MMU_PART_ID); 1185 real_insert = bits(va, 9,9); 1186 pte.populate(data, bits(va,10,10) ? PageTableEntry::sun4v : 1187 PageTableEntry::sun4u); 1188 insert(va_insert, part_insert, ct_insert, real_insert, pte, 1189 entry_insert); 1190 break; 1191 case ASI_IMMU_DEMAP: 1192 ignore = false; 1193 ctx_id = -1; 1194 part_id = tc->readMiscReg(MISCREG_MMU_PART_ID); 1195 switch (bits(va,5,4)) { 1196 case 0: 1197 ctx_id = tc->readMiscReg(MISCREG_MMU_P_CONTEXT); 1198 break; 1199 case 1: 1200 ignore = true; 1201 break; 1202 case 3: 1203 ctx_id = 0; 1204 break; 1205 default: 1206 ignore = true; 1207 } 1208 1209 switch(bits(va,7,6)) { 1210 case 0: // demap page 1211 if (!ignore) 1212 tc->getITBPtr()->demapPage(mbits(va,63,13), part_id, 1213 bits(va,9,9), ctx_id); 1214 break; 1215 case 1: //demap context 1216 if (!ignore) 1217 tc->getITBPtr()->demapContext(part_id, ctx_id); 1218 break; 1219 case 2: 1220 tc->getITBPtr()->demapAll(part_id); 1221 break; 1222 default: 1223 panic("Invalid type for IMMU demap\n"); 1224 } 1225 break; 1226 case ASI_DMMU: 1227 switch (va) { 1228 case 0x18: 1229 sfsr = data; 1230 break; 1231 case 0x30: 1232 sext<59>(bits(data, 59,0)); 1233 tag_access = data; 1234 break; 1235 case 0x80: 1236 tc->setMiscReg(MISCREG_MMU_PART_ID, data); 1237 break; 1238 default: 1239 goto doMmuWriteError; 1240 } 1241 break; 1242 case ASI_DMMU_DEMAP: 1243 ignore = false; 1244 ctx_id = -1; 1245 part_id = tc->readMiscReg(MISCREG_MMU_PART_ID); 1246 switch (bits(va,5,4)) { 1247 case 0: 1248 ctx_id = tc->readMiscReg(MISCREG_MMU_P_CONTEXT); 1249 break; 1250 case 1: 1251 ctx_id = tc->readMiscReg(MISCREG_MMU_S_CONTEXT); 1252 break; 1253 case 3: 1254 ctx_id = 0; 1255 break; 1256 default: 1257 ignore = true; 1258 } 1259 1260 switch(bits(va,7,6)) { 1261 case 0: // demap page 1262 if (!ignore) 1263 demapPage(mbits(va,63,13), part_id, bits(va,9,9), ctx_id); 1264 break; 1265 case 1: //demap context 1266 if (!ignore) 1267 demapContext(part_id, ctx_id); 1268 break; 1269 case 2: 1270 demapAll(part_id); 1271 break; 1272 default: 1273 panic("Invalid type for IMMU demap\n"); 1274 } 1275 break; 1276 case ASI_SWVR_INTR_RECEIVE: 1277 { 1278 int msb; 1279 // clear all the interrupts that aren't set in the write 1280 SparcISA::Interrupts * interrupts = 1281 dynamic_cast<SparcISA::Interrupts *>( 1282 tc->getCpuPtr()->getInterruptController()); 1283 while (interrupts->get_vec(IT_INT_VEC) & data) { 1284 msb = findMsbSet(interrupts->get_vec(IT_INT_VEC) & data); 1285 tc->getCpuPtr()->clearInterrupt(IT_INT_VEC, msb); 1286 } 1287 } 1288 break; 1289 case ASI_SWVR_UDB_INTR_W: 1290 tc->getSystemPtr()->threadContexts[bits(data,12,8)]->getCpuPtr()-> 1291 postInterrupt(bits(data, 5, 0), 0); 1292 break; 1293 default: 1294doMmuWriteError: 1295 panic("need to impl DTB::doMmuRegWrite() got asi=%#x, va=%#x d=%#x\n", 1296 (uint32_t)pkt->req->getAsi(), pkt->getAddr(), data); 1297 } 1298 pkt->makeAtomicResponse(); 1299 return tc->getCpuPtr()->ticks(1); 1300} 1301 1302#endif 1303 1304void 1305TLB::GetTsbPtr(ThreadContext *tc, Addr addr, int ctx, Addr *ptrs) 1306{ 1307 uint64_t tag_access = mbits(addr,63,13) | mbits(ctx,12,0); 1308 TLB * itb = tc->getITBPtr(); 1309 ptrs[0] = MakeTsbPtr(Ps0, tag_access, 1310 c0_tsb_ps0, 1311 c0_config, 1312 cx_tsb_ps0, 1313 cx_config); 1314 ptrs[1] = MakeTsbPtr(Ps1, tag_access, 1315 c0_tsb_ps1, 1316 c0_config, 1317 cx_tsb_ps1, 1318 cx_config); 1319 ptrs[2] = MakeTsbPtr(Ps0, tag_access, 1320 itb->c0_tsb_ps0, 1321 itb->c0_config, 1322 itb->cx_tsb_ps0, 1323 itb->cx_config); 1324 ptrs[3] = MakeTsbPtr(Ps1, tag_access, 1325 itb->c0_tsb_ps1, 1326 itb->c0_config, 1327 itb->cx_tsb_ps1, 1328 itb->cx_config); 1329} 1330 1331uint64_t 1332TLB::MakeTsbPtr(TsbPageSize ps, uint64_t tag_access, uint64_t c0_tsb, 1333 uint64_t c0_config, uint64_t cX_tsb, uint64_t cX_config) 1334{ 1335 uint64_t tsb; 1336 uint64_t config; 1337 1338 if (bits(tag_access, 12,0) == 0) { 1339 tsb = c0_tsb; 1340 config = c0_config; 1341 } else { 1342 tsb = cX_tsb; 1343 config = cX_config; 1344 } 1345 1346 uint64_t ptr = mbits(tsb,63,13); 1347 bool split = bits(tsb,12,12); 1348 int tsb_size = bits(tsb,3,0); 1349 int page_size = (ps == Ps0) ? bits(config, 2,0) : bits(config,10,8); 1350 1351 if (ps == Ps1 && split) 1352 ptr |= ULL(1) << (13 + tsb_size); 1353 ptr |= (tag_access >> (9 + page_size * 3)) & mask(12+tsb_size, 4); 1354 1355 return ptr; 1356} 1357 1358void 1359TLB::serialize(std::ostream &os) 1360{ 1361 SERIALIZE_SCALAR(size); 1362 SERIALIZE_SCALAR(usedEntries); 1363 SERIALIZE_SCALAR(lastReplaced); 1364 1365 // convert the pointer based free list into an index based one 1366 int *free_list = (int*)malloc(sizeof(int) * size); 1367 int cntr = 0; 1368 std::list<TlbEntry*>::iterator i; 1369 i = freeList.begin(); 1370 while (i != freeList.end()) { 1371 free_list[cntr++] = ((size_t)*i - (size_t)tlb)/ sizeof(TlbEntry); 1372 i++; 1373 } 1374 SERIALIZE_SCALAR(cntr); 1375 SERIALIZE_ARRAY(free_list, cntr); 1376 1377 SERIALIZE_SCALAR(c0_tsb_ps0); 1378 SERIALIZE_SCALAR(c0_tsb_ps1); 1379 SERIALIZE_SCALAR(c0_config); 1380 SERIALIZE_SCALAR(cx_tsb_ps0); 1381 SERIALIZE_SCALAR(cx_tsb_ps1); 1382 SERIALIZE_SCALAR(cx_config); 1383 SERIALIZE_SCALAR(sfsr); 1384 SERIALIZE_SCALAR(tag_access); 1385 1386 for (int x = 0; x < size; x++) { 1387 nameOut(os, csprintf("%s.PTE%d", name(), x)); 1388 tlb[x].serialize(os); 1389 } 1390 SERIALIZE_SCALAR(sfar); 1391} 1392 1393void 1394TLB::unserialize(Checkpoint *cp, const std::string §ion) 1395{ 1396 int oldSize; 1397 1398 paramIn(cp, section, "size", oldSize); 1399 if (oldSize != size) 1400 panic("Don't support unserializing different sized TLBs\n"); 1401 UNSERIALIZE_SCALAR(usedEntries); 1402 UNSERIALIZE_SCALAR(lastReplaced); 1403 1404 int cntr; 1405 UNSERIALIZE_SCALAR(cntr); 1406 1407 int *free_list = (int*)malloc(sizeof(int) * cntr); 1408 freeList.clear(); 1409 UNSERIALIZE_ARRAY(free_list, cntr); 1410 for (int x = 0; x < cntr; x++) 1411 freeList.push_back(&tlb[free_list[x]]); 1412 1413 UNSERIALIZE_SCALAR(c0_tsb_ps0); 1414 UNSERIALIZE_SCALAR(c0_tsb_ps1); 1415 UNSERIALIZE_SCALAR(c0_config); 1416 UNSERIALIZE_SCALAR(cx_tsb_ps0); 1417 UNSERIALIZE_SCALAR(cx_tsb_ps1); 1418 UNSERIALIZE_SCALAR(cx_config); 1419 UNSERIALIZE_SCALAR(sfsr); 1420 UNSERIALIZE_SCALAR(tag_access); 1421 1422 lookupTable.clear(); 1423 for (int x = 0; x < size; x++) { 1424 tlb[x].unserialize(cp, csprintf("%s.PTE%d", section, x)); 1425 if (tlb[x].valid) 1426 lookupTable.insert(tlb[x].range, &tlb[x]); 1427 1428 } 1429 UNSERIALIZE_SCALAR(sfar); 1430} 1431 1432/* end namespace SparcISA */ } 1433 1434SparcISA::TLB * 1435SparcTLBParams::create() 1436{ 1437 return new SparcISA::TLB(this); 1438} 1439