1 /* $NetBSD: pmap.c,v 1.112 2026/06/17 15:08:54 rkujawa Exp $ */ 2 3 /* 4 * Copyright 2001 Wasabi Systems, Inc. 5 * All rights reserved. 6 * 7 * Written by Eduardo Horvath and Simon Burge for Wasabi Systems, Inc. 8 * 9 * Redistribution and use in source and binary forms, with or without 10 * modification, are permitted provided that the following conditions 11 * are met: 12 * 1. Redistributions of source code must retain the above copyright 13 * notice, this list of conditions and the following disclaimer. 14 * 2. Redistributions in binary form must reproduce the above copyright 15 * notice, this list of conditions and the following disclaimer in the 16 * documentation and/or other materials provided with the distribution. 17 * 3. All advertising materials mentioning features or use of this software 18 * must display the following acknowledgement: 19 * This product includes software developed for the NetBSD Project by 20 * Wasabi Systems, Inc. 21 * 4. The name of Wasabi Systems, Inc. may not be used to endorse 22 * or promote products derived from this software without specific prior 23 * written permission. 24 * 25 * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND 26 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 27 * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 28 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL WASABI SYSTEMS, INC 29 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 30 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 31 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 32 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 33 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 34 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 35 * POSSIBILITY OF SUCH DAMAGE. 36 */ 37 38 /* 39 * Copyright (C) 1995, 1996 Wolfgang Solfrank. 40 * Copyright (C) 1995, 1996 TooLs GmbH. 41 * All rights reserved. 42 * 43 * Redistribution and use in source and binary forms, with or without 44 * modification, are permitted provided that the following conditions 45 * are met: 46 * 1. Redistributions of source code must retain the above copyright 47 * notice, this list of conditions and the following disclaimer. 48 * 2. Redistributions in binary form must reproduce the above copyright 49 * notice, this list of conditions and the following disclaimer in the 50 * documentation and/or other materials provided with the distribution. 51 * 3. All advertising materials mentioning features or use of this software 52 * must display the following acknowledgement: 53 * This product includes software developed by TooLs GmbH. 54 * 4. The name of TooLs GmbH may not be used to endorse or promote products 55 * derived from this software without specific prior written permission. 56 * 57 * THIS SOFTWARE IS PROVIDED BY TOOLS GMBH ``AS IS'' AND ANY EXPRESS OR 58 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 59 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 60 * IN NO EVENT SHALL TOOLS GMBH BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 61 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, 62 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; 63 * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, 64 * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR 65 * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF 66 * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 67 */ 68 69 #include <sys/cdefs.h> 70 __KERNEL_RCSID(0, "$NetBSD: pmap.c,v 1.112 2026/06/17 15:08:54 rkujawa Exp $"); 71 72 #ifdef _KERNEL_OPT 73 #include "opt_ddb.h" 74 #include "opt_pmap.h" 75 #include "opt_ppcarch.h" 76 #endif 77 78 #include <sys/param.h> 79 #include <sys/cpu.h> 80 #include <sys/device.h> 81 #include <sys/kmem.h> 82 #include <sys/pool.h> 83 #include <sys/proc.h> 84 #include <sys/queue.h> 85 #include <sys/systm.h> 86 87 #include <uvm/uvm.h> 88 89 #include <machine/powerpc.h> 90 91 #include <powerpc/pcb.h> 92 93 #include <powerpc/spr.h> 94 #include <powerpc/ibm4xx/spr.h> 95 96 #include <powerpc/ibm4xx/cpu.h> 97 #include <powerpc/ibm4xx/tlb.h> 98 99 /* 100 * kernmap is an array of PTEs large enough to map in 101 * 4GB. At 16KB/page it is 256K entries or 2MB. 102 */ 103 #define KERNMAP_SIZE ((0xffffffffU / PAGE_SIZE) + 1) 104 void *kernmap; 105 106 #define MINCTX 2 107 #define NUMCTX 256 108 109 volatile struct pmap *ctxbusy[NUMCTX]; 110 111 #define TLBF_USED 0x1 112 #define TLBF_REF 0x2 113 #define TLBF_LOCKED 0x4 114 #define TLB_LOCKED(i) (tlb_info[(i)].ti_flags & TLBF_LOCKED) 115 116 typedef struct tlb_info_s { 117 char ti_flags; 118 char ti_ctx; /* TLB_PID assiciated with the entry */ 119 u_int ti_va; 120 } tlb_info_t; 121 122 volatile tlb_info_t tlb_info[NTLB]; 123 /* We'll use a modified FIFO replacement policy cause it's cheap */ 124 volatile int tlbnext; 125 126 static int tlb_nreserved = 0; 127 static int pmap_bootstrap_done = 0; 128 129 /* Event counters */ 130 struct evcnt tlbmiss_ev = EVCNT_INITIALIZER(EVCNT_TYPE_TRAP, 131 NULL, "cpu", "tlbmiss"); 132 struct evcnt tlbflush_ev = EVCNT_INITIALIZER(EVCNT_TYPE_TRAP, 133 NULL, "cpu", "tlbflush"); 134 struct evcnt tlbenter_ev = EVCNT_INITIALIZER(EVCNT_TYPE_TRAP, 135 NULL, "cpu", "tlbenter"); 136 EVCNT_ATTACH_STATIC(tlbmiss_ev); 137 EVCNT_ATTACH_STATIC(tlbflush_ev); 138 EVCNT_ATTACH_STATIC(tlbenter_ev); 139 140 struct pmap kernel_pmap_; 141 struct pmap *const kernel_pmap_ptr = &kernel_pmap_; 142 143 static int npgs; 144 static u_int nextavail; 145 #ifndef MSGBUFADDR 146 extern paddr_t msgbuf_paddr; 147 #endif 148 149 static struct mem_region *mem, *avail; 150 151 /* 152 * This is a cache of referenced/modified bits. 153 * Bits herein are shifted by ATTRSHFT. 154 */ 155 static char *pmap_attrib; 156 157 #define PV_WIRED 0x1 158 #define PV_WIRE(pv) ((pv)->pv_va |= PV_WIRED) 159 #define PV_UNWIRE(pv) ((pv)->pv_va &= ~PV_WIRED) 160 #define PV_ISWIRED(pv) ((pv)->pv_va & PV_WIRED) 161 #define PV_VA(pv) ((pv)->pv_va & ~PV_WIRED) 162 #define PV_CMPVA(va,pv) (!(PV_VA(pv) ^ (va))) 163 164 struct pv_entry { 165 struct pv_entry *pv_next; /* Linked list of mappings */ 166 struct pmap *pv_pm; 167 vaddr_t pv_va; /* virtual address of mapping */ 168 }; 169 170 /* Each index corresponds to TLB_SIZE_* value. */ 171 static size_t tlbsize[] = { 172 1024, /* TLB_SIZE_1K */ 173 4096, /* TLB_SIZE_4K */ 174 16384, /* TLB_SIZE_16K */ 175 65536, /* TLB_SIZE_64K */ 176 262144, /* TLB_SIZE_256K */ 177 1048576, /* TLB_SIZE_1M */ 178 #ifdef PPC_IBM440 179 0, /* encoding 6 unused on 440 (no 4M page size) */ 180 #else 181 4194304, /* TLB_SIZE_4M */ 182 #endif 183 16777216, /* TLB_SIZE_16M */ 184 }; 185 186 #ifdef PPC_IBM440 187 static struct tlb44_resv { 188 uint64_t tr_pa; /* 36-bit physical address */ 189 vaddr_t tr_va; 190 psize_t tr_size; 191 } tlb44_resv[NTLB]; 192 #endif 193 194 struct pv_entry *pv_table; 195 static struct pool pv_pool; 196 197 static int pmap_initialized; 198 199 static void ctx_flush(int); 200 201 struct pv_entry *pa_to_pv(paddr_t); 202 static inline char *pa_to_attr(paddr_t); 203 204 static inline volatile u_int *pte_find(struct pmap *, vaddr_t); 205 static inline int pte_enter(struct pmap *, vaddr_t, u_int); 206 207 static inline int pmap_enter_pv(struct pmap *, vaddr_t, paddr_t, int); 208 static void pmap_remove_pv(struct pmap *, vaddr_t, paddr_t); 209 210 static inline void tlb_invalidate_entry(int); 211 212 #ifndef PPC_IBM440 213 static int ppc4xx_tlb_size_mask(size_t, int *, int *); 214 #endif 215 216 217 struct pv_entry * 218 pa_to_pv(paddr_t pa) 219 { 220 uvm_physseg_t bank; 221 psize_t pg; 222 223 bank = uvm_physseg_find(atop(pa), &pg); 224 if (bank == UVM_PHYSSEG_TYPE_INVALID) 225 return NULL; 226 return &uvm_physseg_get_pmseg(bank)->pvent[pg]; 227 } 228 229 static inline char * 230 pa_to_attr(paddr_t pa) 231 { 232 uvm_physseg_t bank; 233 psize_t pg; 234 235 bank = uvm_physseg_find(atop(pa), &pg); 236 if (bank == UVM_PHYSSEG_TYPE_INVALID) 237 return NULL; 238 return &uvm_physseg_get_pmseg(bank)->attrs[pg]; 239 } 240 241 /* 242 * Insert PTE into page table. 243 */ 244 static inline int 245 pte_enter(struct pmap *pm, vaddr_t va, u_int pte) 246 { 247 int seg = STIDX(va), ptn = PTIDX(va); 248 u_int oldpte; 249 250 if (!pm->pm_ptbl[seg]) { 251 /* Don't allocate a page to clear a non-existent mapping. */ 252 if (!pte) 253 return 0; 254 255 vaddr_t km = uvm_km_alloc(kernel_map, PAGE_SIZE, 0, 256 UVM_KMF_WIRED | UVM_KMF_ZERO | UVM_KMF_NOWAIT); 257 258 if (__predict_false(km == 0)) 259 return ENOMEM; 260 261 pm->pm_ptbl[seg] = (u_int *)km; 262 } 263 oldpte = pm->pm_ptbl[seg][ptn]; 264 pm->pm_ptbl[seg][ptn] = pte; 265 266 /* Flush entry. */ 267 ppc4xx_tlb_flush(va, pm->pm_ctx); 268 if (oldpte != pte) { 269 if (pte == 0) 270 pm->pm_stats.resident_count--; 271 else 272 pm->pm_stats.resident_count++; 273 } 274 return 0; 275 } 276 277 /* 278 * Get a pointer to a PTE in a page table. 279 */ 280 volatile u_int * 281 pte_find(struct pmap *pm, vaddr_t va) 282 { 283 int seg = STIDX(va), ptn = PTIDX(va); 284 285 if (pm->pm_ptbl[seg]) 286 return &pm->pm_ptbl[seg][ptn]; 287 288 return NULL; 289 } 290 291 /* 292 * This is called during initppc, before the system is really initialized. 293 */ 294 void 295 pmap_bootstrap(u_int kernelstart, u_int kernelend) 296 { 297 struct mem_region *mp, *mp1; 298 int cnt, i; 299 u_int s, e, sz; 300 301 tlbnext = tlb_nreserved; 302 303 /* 304 * Allocate the kernel page table at the end of 305 * kernel space so it's in the locked TTE. 306 */ 307 kernmap = (void *)kernelend; 308 309 /* 310 * Initialize kernel page table. 311 */ 312 for (i = 0; i < STSZ; i++) 313 pmap_kernel()->pm_ptbl[i] = NULL; 314 ctxbusy[0] = ctxbusy[1] = pmap_kernel(); 315 316 /* 317 * Announce page-size to the VM-system 318 */ 319 uvmexp.pagesize = NBPG; 320 uvm_md_init(); 321 322 /* 323 * Get memory. 324 */ 325 mem_regions(&mem, &avail); 326 for (mp = mem; mp->size; mp++) { 327 physmem += btoc(mp->size); 328 printf("+%lx,", mp->size); 329 } 330 printf("\n"); 331 ppc4xx_tlb_init(); 332 /* 333 * Count the number of available entries. 334 */ 335 for (cnt = 0, mp = avail; mp->size; mp++) 336 cnt++; 337 338 /* 339 * Page align all regions. 340 * Non-page aligned memory isn't very interesting to us. 341 * Also, sort the entries for ascending addresses. 342 */ 343 kernelstart &= ~PGOFSET; 344 kernelend = (kernelend + PGOFSET) & ~PGOFSET; 345 for (mp = avail; mp->size; mp++) { 346 s = mp->start; 347 e = mp->start + mp->size; 348 printf("%08x-%08x -> ", s, e); 349 /* 350 * Check whether this region holds all of the kernel. 351 */ 352 if (s < kernelstart && e > kernelend) { 353 avail[cnt].start = kernelend; 354 avail[cnt++].size = e - kernelend; 355 e = kernelstart; 356 } 357 /* 358 * Look whether this regions starts within the kernel. 359 */ 360 if (s >= kernelstart && s < kernelend) { 361 if (e <= kernelend) 362 goto empty; 363 s = kernelend; 364 } 365 /* 366 * Now look whether this region ends within the kernel. 367 */ 368 if (e > kernelstart && e <= kernelend) { 369 if (s >= kernelstart) 370 goto empty; 371 e = kernelstart; 372 } 373 /* 374 * Now page align the start and size of the region. 375 */ 376 s = round_page(s); 377 e = trunc_page(e); 378 if (e < s) 379 e = s; 380 sz = e - s; 381 printf("%08x-%08x = %x\n", s, e, sz); 382 /* 383 * Check whether some memory is left here. 384 */ 385 if (sz == 0) { 386 empty: 387 memmove(mp, mp + 1, 388 (cnt - (mp - avail)) * sizeof(*mp)); 389 cnt--; 390 mp--; 391 continue; 392 } 393 /* 394 * Do an insertion sort. 395 */ 396 npgs += btoc(sz); 397 for (mp1 = avail; mp1 < mp; mp1++) 398 if (s < mp1->start) 399 break; 400 if (mp1 < mp) { 401 memmove(mp1 + 1, mp1, (char *)mp - (char *)mp1); 402 mp1->start = s; 403 mp1->size = sz; 404 } else { 405 mp->start = s; 406 mp->size = sz; 407 } 408 } 409 410 /* 411 * We cannot do pmap_steal_memory here, 412 * since we don't run with translation enabled yet. 413 */ 414 #ifndef MSGBUFADDR 415 /* 416 * allow for msgbuf 417 */ 418 sz = round_page(MSGBUFSIZE); 419 mp = NULL; 420 for (mp1 = avail; mp1->size; mp1++) 421 if (mp1->size >= sz) 422 mp = mp1; 423 if (mp == NULL) 424 panic("not enough memory?"); 425 426 npgs -= btoc(sz); 427 msgbuf_paddr = mp->start + mp->size - sz; 428 mp->size -= sz; 429 if (mp->size <= 0) 430 memmove(mp, mp + 1, (cnt - (mp - avail)) * sizeof(*mp)); 431 #endif 432 433 for (mp = avail; mp->size; mp++) 434 uvm_page_physload(atop(mp->start), atop(mp->start + mp->size), 435 atop(mp->start), atop(mp->start + mp->size), 436 VM_FREELIST_DEFAULT); 437 438 /* 439 * Initialize kernel pmap and hardware. 440 */ 441 /* Setup TLB pid allocator so it knows we alreadu using PID 1 */ 442 pmap_kernel()->pm_ctx = KERNEL_PID; 443 nextavail = avail->start; 444 445 pmap_bootstrap_done = 1; 446 } 447 448 /* 449 * Restrict given range to physical memory 450 * 451 * (Used by /dev/mem) 452 */ 453 void 454 pmap_real_memory(paddr_t *start, psize_t *size) 455 { 456 struct mem_region *mp; 457 458 for (mp = mem; mp->size; mp++) { 459 if (*start + *size > mp->start && 460 *start < mp->start + mp->size) { 461 if (*start < mp->start) { 462 *size -= mp->start - *start; 463 *start = mp->start; 464 } 465 if (*start + *size > mp->start + mp->size) 466 *size = mp->start + mp->size - *start; 467 return; 468 } 469 } 470 *size = 0; 471 } 472 473 /* 474 * Initialize anything else for pmap handling. 475 * Called during vm_init(). 476 */ 477 void 478 pmap_init(void) 479 { 480 struct pv_entry *pv; 481 vsize_t sz; 482 vaddr_t addr; 483 int bank, i, s; 484 char *attr; 485 486 sz = (vsize_t)((sizeof(struct pv_entry) + 1) * npgs); 487 sz = round_page(sz); 488 addr = uvm_km_alloc(kernel_map, sz, 0, UVM_KMF_WIRED | UVM_KMF_ZERO); 489 490 s = splvm(); 491 492 pv = pv_table = (struct pv_entry *)addr; 493 for (i = npgs; --i >= 0;) 494 pv++->pv_pm = NULL; 495 pmap_attrib = (char *)pv; 496 memset(pv, 0, npgs); 497 498 pv = pv_table; 499 attr = pmap_attrib; 500 for (bank = uvm_physseg_get_first(); uvm_physseg_valid_p(bank); 501 bank = uvm_physseg_get_next(bank)) { 502 sz = uvm_physseg_get_end(bank) - uvm_physseg_get_start(bank); 503 uvm_physseg_get_pmseg(bank)->pvent = pv; 504 uvm_physseg_get_pmseg(bank)->attrs = attr; 505 pv += sz; 506 attr += sz; 507 } 508 509 pmap_initialized = 1; 510 511 splx(s); 512 513 /* Setup a pool for additional pvlist structures */ 514 pool_init(&pv_pool, sizeof(struct pv_entry), 0, 0, 0, "pv_entry", 515 NULL, IPL_VM); 516 } 517 518 /* 519 * How much virtual space is available to the kernel? 520 */ 521 void 522 pmap_virtual_space(vaddr_t *start, vaddr_t *end) 523 { 524 525 *start = (vaddr_t) VM_MIN_KERNEL_ADDRESS; 526 *end = (vaddr_t) VM_MAX_KERNEL_ADDRESS; 527 } 528 529 #ifdef PMAP_GROWKERNEL 530 /* 531 * Preallocate kernel page tables to a specified VA. 532 * This simply loops through the first TTE for each 533 * page table from the beginning of the kernel pmap, 534 * reads the entry, and if the result is 535 * zero (either invalid entry or no page table) it stores 536 * a zero there, populating page tables in the process. 537 * This is not the most efficient technique but i don't 538 * expect it to be called that often. 539 */ 540 extern struct vm_page *vm_page_alloc1(void); 541 extern void vm_page_free1(struct vm_page *); 542 543 vaddr_t kbreak = VM_MIN_KERNEL_ADDRESS; 544 545 vaddr_t 546 pmap_growkernel(vaddr_t maxkvaddr) 547 { 548 struct pmap *pm = pmap_kernel(); 549 paddr_t pg; 550 int seg, s; 551 552 s = splvm(); 553 554 /* Align with the start of a page table */ 555 for (kbreak &= ~(PTMAP - 1); kbreak < maxkvaddr; kbreak += PTMAP) { 556 seg = STIDX(kbreak); 557 558 if (pte_find(pm, kbreak)) 559 continue; 560 561 if (uvm.page_init_done) 562 pg = (paddr_t)VM_PAGE_TO_PHYS(vm_page_alloc1()); 563 else if (!uvm_page_physget(&pg)) 564 panic("pmap_growkernel: no memory"); 565 if (!pg) 566 panic("pmap_growkernel: no pages"); 567 pmap_zero_page((paddr_t)pg); 568 569 /* XXX This is based on all phymem being addressable */ 570 pm->pm_ptbl[seg] = (u_int *)pg; 571 } 572 573 splx(s); 574 575 return kbreak; 576 } 577 578 /* 579 * vm_page_alloc1: 580 * 581 * Allocate and return a memory cell with no associated object. 582 */ 583 struct vm_page * 584 vm_page_alloc1(void) 585 { 586 struct vm_page *pg; 587 588 pg = uvm_pagealloc(NULL, 0, NULL, UVM_PGA_USERESERVE); 589 if (pg) { 590 pg->wire_count = 1; /* no mappings yet */ 591 pg->flags &= ~PG_BUSY; /* never busy */ 592 } 593 return pg; 594 } 595 596 /* 597 * vm_page_free1: 598 * 599 * Returns the given page to the free list, 600 * disassociating it with any VM object. 601 * 602 * Object and page must be locked prior to entry. 603 */ 604 void 605 vm_page_free1(struct vm_page *pg) 606 { 607 608 KASSERTMSG(pg->flags == (PG_CLEAN | PG_FAKE), 609 "invalid page pg = %p, pa = %" PRIxPADDR, 610 pg, VM_PAGE_TO_PHYS(pg)); 611 612 pg->flags |= PG_BUSY; 613 pg->wire_count = 0; 614 uvm_pagefree(pg); 615 } 616 #endif 617 618 /* 619 * Create and return a physical map. 620 */ 621 struct pmap * 622 pmap_create(void) 623 { 624 struct pmap *pm; 625 626 pm = kmem_alloc(sizeof(*pm), KM_SLEEP); 627 memset(pm, 0, sizeof(*pm)); 628 pm->pm_refs = 1; 629 return pm; 630 } 631 632 /* 633 * Add a reference to the given pmap. 634 */ 635 void 636 pmap_reference(struct pmap *pm) 637 { 638 639 pm->pm_refs++; 640 } 641 642 /* 643 * Retire the given pmap from service. 644 * Should only be called if the map contains no valid mappings. 645 */ 646 void 647 pmap_destroy(struct pmap *pm) 648 { 649 int i; 650 651 if (--pm->pm_refs > 0) 652 return; 653 KASSERT(pm->pm_stats.resident_count == 0); 654 KASSERT(pm->pm_stats.wired_count == 0); 655 for (i = 0; i < STSZ; i++) 656 if (pm->pm_ptbl[i]) { 657 uvm_km_free(kernel_map, (vaddr_t)pm->pm_ptbl[i], 658 PAGE_SIZE, UVM_KMF_WIRED); 659 pm->pm_ptbl[i] = NULL; 660 } 661 if (pm->pm_ctx) 662 ctx_free(pm); 663 kmem_free(pm, sizeof(*pm)); 664 } 665 666 /* 667 * Copy the range specified by src_addr/len 668 * from the source map to the range dst_addr/len 669 * in the destination map. 670 * 671 * This routine is only advisory and need not do anything. 672 */ 673 void 674 pmap_copy(struct pmap *dst_pmap, struct pmap *src_pmap, vaddr_t dst_addr, 675 vsize_t len, vaddr_t src_addr) 676 { 677 } 678 679 /* 680 * Require that all active physical maps contain no 681 * incorrect entries NOW. 682 */ 683 void 684 pmap_update(struct pmap *pmap) 685 { 686 } 687 688 /* 689 * Fill the given physical page with zeroes. 690 */ 691 void 692 pmap_zero_page(paddr_t pa) 693 { 694 int i; 695 696 #ifdef PPC_4XX_NOCACHE 697 memset((void *)pa, 0, PAGE_SIZE); 698 #else 699 700 for (i = PAGE_SIZE/CACHELINESIZE; i > 0; i--) { 701 __asm volatile ("dcbz 0,%0" : : "r" (pa)); 702 pa += CACHELINESIZE; 703 } 704 #endif 705 } 706 707 /* 708 * Copy the given physical source page to its destination. 709 */ 710 void 711 pmap_copy_page(paddr_t src, paddr_t dst) 712 { 713 714 #ifdef PPC_IBM440 715 ibm4xx_blkcpy((void *)dst, (void *)src, PAGE_SIZE, true); 716 #else 717 memcpy((void *)dst, (void *)src, PAGE_SIZE); 718 #endif 719 dcache_wbinv_page(dst); 720 } 721 722 static inline int 723 pmap_enter_pv(struct pmap *pm, vaddr_t va, paddr_t pa, int flags) 724 { 725 struct pv_entry *pv, *npv; 726 int s; 727 728 KASSERT(pmap_initialized); 729 730 s = splvm(); 731 732 pv = pa_to_pv(pa); 733 if (!pv->pv_pm) { 734 /* 735 * No entries yet, use header as the first entry. 736 */ 737 pv->pv_va = va; 738 pv->pv_pm = pm; 739 pv->pv_next = NULL; 740 } else { 741 /* 742 * There is at least one other VA mapping this page. 743 * Place this entry after the header. 744 */ 745 npv = pool_get(&pv_pool, PR_NOWAIT); 746 if (npv == NULL) { 747 if ((flags & PMAP_CANFAIL) == 0) 748 panic("pmap_enter_pv: failed"); 749 splx(s); 750 return ENOMEM; 751 } 752 npv->pv_va = va; 753 npv->pv_pm = pm; 754 npv->pv_next = pv->pv_next; 755 pv->pv_next = npv; 756 pv = npv; 757 } 758 if (flags & PMAP_WIRED) { 759 PV_WIRE(pv); 760 pm->pm_stats.wired_count++; 761 } 762 763 splx(s); 764 765 return 0; 766 } 767 768 static void 769 pmap_remove_pv(struct pmap *pm, vaddr_t va, paddr_t pa) 770 { 771 struct pv_entry *pv, *npv; 772 773 /* 774 * Remove from the PV table. 775 */ 776 pv = pa_to_pv(pa); 777 if (!pv) 778 return; 779 780 /* 781 * If it is the first entry on the list, it is actually 782 * in the header and we must copy the following entry up 783 * to the header. Otherwise we must search the list for 784 * the entry. In either case we free the now unused entry. 785 */ 786 if (pm == pv->pv_pm && PV_CMPVA(va, pv)) { 787 if (PV_ISWIRED(pv)) 788 pm->pm_stats.wired_count--; 789 if ((npv = pv->pv_next)) { 790 *pv = *npv; 791 pool_put(&pv_pool, npv); 792 } else 793 pv->pv_pm = NULL; 794 } else { 795 for (; (npv = pv->pv_next) != NULL; pv = npv) 796 if (pm == npv->pv_pm && PV_CMPVA(va, npv)) 797 break; 798 if (npv) { 799 pv->pv_next = npv->pv_next; 800 if (PV_ISWIRED(npv)) { 801 pm->pm_stats.wired_count--; 802 } 803 pool_put(&pv_pool, npv); 804 } 805 } 806 } 807 808 /* 809 * Insert physical page at pa into the given pmap at virtual address va. 810 */ 811 int 812 pmap_enter(struct pmap *pm, vaddr_t va, paddr_t pa, vm_prot_t prot, u_int flags) 813 { 814 u_int tte; 815 bool managed; 816 int s; 817 818 /* 819 * Have to remove any existing mapping first. 820 */ 821 pmap_remove(pm, va, va + PAGE_SIZE); 822 823 if (flags & PMAP_WIRED) 824 flags |= prot; 825 826 managed = uvm_pageismanaged(pa); 827 828 /* 829 * Generate TTE. 830 */ 831 tte = TTE_PA(pa); 832 /* XXXX -- need to support multiple page sizes. */ 833 tte |= TTE_SZ_16K; 834 835 KASSERT((flags & (PMAP_NOCACHE | PME_WRITETHROUG)) != 836 (PMAP_NOCACHE | PME_WRITETHROUG)); 837 838 if (flags & PMAP_NOCACHE) { 839 /* Must be I/O mapping */ 840 tte |= TTE_I | TTE_G; 841 } 842 #ifdef PPC_4XX_NOCACHE 843 tte |= TTE_I; 844 #else 845 else if (flags & PME_WRITETHROUG) { 846 /* Uncached and writethrough are not compatible */ 847 tte |= TTE_W; 848 } 849 #endif 850 851 if (pm == pmap_kernel()) 852 tte |= TTE_ZONE(ZONE_PRIV); 853 else 854 tte |= TTE_ZONE(ZONE_USER); 855 856 if (flags & VM_PROT_WRITE) 857 tte |= TTE_WR; 858 859 if (flags & VM_PROT_EXECUTE) 860 tte |= TTE_EX; 861 862 /* 863 * Now record mapping for later back-translation. 864 */ 865 if (pmap_initialized && managed) { 866 char *attr; 867 868 if (pmap_enter_pv(pm, va, pa, flags)) { 869 /* Could not enter pv on a managed page */ 870 return ENOMEM; 871 } 872 873 /* Now set attributes. */ 874 attr = pa_to_attr(pa); 875 KASSERT(attr); 876 if (flags & VM_PROT_ALL) 877 *attr |= PMAP_ATTR_REF; 878 if (flags & VM_PROT_WRITE) 879 *attr |= PMAP_ATTR_CHG; 880 } 881 882 s = splvm(); 883 884 /* Insert page into page table. */ 885 if (__predict_false(pte_enter(pm, va, tte))) { 886 if (__predict_false((flags & PMAP_CANFAIL) == 0)) 887 panic("%s: pte_enter", __func__); 888 splx(s); 889 return ENOMEM; 890 } 891 892 /* If this is a real fault, enter it in the tlb */ 893 if (tte && ((flags & PMAP_WIRED) == 0)) { 894 int s2 = splhigh(); 895 ppc4xx_tlb_enter(pm->pm_ctx, va, tte); 896 splx(s2); 897 } 898 899 splx(s); 900 901 /* Flush the real memory from the instruction cache. */ 902 if ((prot & VM_PROT_EXECUTE) && (tte & TTE_I) == 0) 903 __syncicache((void *)pa, PAGE_SIZE); 904 905 return 0; 906 } 907 908 void 909 pmap_unwire(struct pmap *pm, vaddr_t va) 910 { 911 struct pv_entry *pv; 912 paddr_t pa; 913 int s; 914 915 if (!pmap_extract(pm, va, &pa)) 916 return; 917 918 pv = pa_to_pv(pa); 919 if (!pv) 920 return; 921 922 s = splvm(); 923 924 while (pv != NULL) { 925 if (pm == pv->pv_pm && PV_CMPVA(va, pv)) { 926 if (PV_ISWIRED(pv)) { 927 PV_UNWIRE(pv); 928 pm->pm_stats.wired_count--; 929 } 930 break; 931 } 932 pv = pv->pv_next; 933 } 934 935 splx(s); 936 } 937 938 void 939 pmap_kenter_pa(vaddr_t va, paddr_t pa, vm_prot_t prot, u_int flags) 940 { 941 struct pmap *pm = pmap_kernel(); 942 u_int tte; 943 int s; 944 945 /* 946 * Generate TTE. 947 * 948 * XXXX 949 * 950 * Since the kernel does not handle execution privileges properly, 951 * we will handle read and execute permissions together. 952 */ 953 tte = 0; 954 if (prot & VM_PROT_ALL) { 955 tte = TTE_PA(pa) | TTE_EX | TTE_ZONE(ZONE_PRIV); 956 /* XXXX -- need to support multiple page sizes. */ 957 tte |= TTE_SZ_16K; 958 959 KASSERT((flags & (PMAP_NOCACHE | PME_WRITETHROUG)) != 960 (PMAP_NOCACHE | PME_WRITETHROUG)); 961 962 if (flags & PMAP_NOCACHE) 963 /* Must be I/O mapping */ 964 tte |= TTE_I | TTE_G; 965 #ifdef PPC_4XX_NOCACHE 966 tte |= TTE_I; 967 #else 968 else if (prot & PME_WRITETHROUG) { 969 /* Uncached and writethrough are not compatible */ 970 tte |= TTE_W; 971 } 972 #endif 973 if (prot & VM_PROT_WRITE) 974 tte |= TTE_WR; 975 } 976 977 s = splvm(); 978 979 /* Insert page into page table. */ 980 if (__predict_false(pte_enter(pm, va, tte))) 981 panic("%s: pte_enter", __func__); 982 983 splx(s); 984 } 985 986 void 987 pmap_kremove(vaddr_t va, vsize_t len) 988 { 989 990 while (len > 0) { 991 (void)pte_enter(pmap_kernel(), va, 0); /* never fail */ 992 va += PAGE_SIZE; 993 len -= PAGE_SIZE; 994 } 995 } 996 997 /* 998 * Remove the given range of mapping entries. 999 */ 1000 void 1001 pmap_remove(struct pmap *pm, vaddr_t va, vaddr_t endva) 1002 { 1003 paddr_t pa; 1004 volatile u_int *ptp; 1005 int s; 1006 1007 s = splvm(); 1008 1009 while (va < endva) { 1010 if ((ptp = pte_find(pm, va)) && (pa = *ptp)) { 1011 pa = TTE_PA(pa); 1012 pmap_remove_pv(pm, va, pa); 1013 *ptp = 0; 1014 ppc4xx_tlb_flush(va, pm->pm_ctx); 1015 pm->pm_stats.resident_count--; 1016 } 1017 va += PAGE_SIZE; 1018 } 1019 1020 splx(s); 1021 } 1022 1023 /* 1024 * Get the physical page address for the given pmap/virtual address. 1025 */ 1026 bool 1027 pmap_extract(struct pmap *pm, vaddr_t va, paddr_t *pap) 1028 { 1029 int seg = STIDX(va), ptn = PTIDX(va); 1030 u_int pa = 0; 1031 int s; 1032 1033 s = splvm(); 1034 1035 if (pm->pm_ptbl[seg] && (pa = pm->pm_ptbl[seg][ptn]) && pap) 1036 *pap = TTE_PA(pa) | (va & PGOFSET); 1037 1038 splx(s); 1039 1040 return pa != 0; 1041 } 1042 1043 /* 1044 * Lower the protection on the specified range of this pmap. 1045 * 1046 * There are only two cases: either the protection is going to 0, 1047 * or it is going to read-only. 1048 */ 1049 void 1050 pmap_protect(struct pmap *pm, vaddr_t sva, vaddr_t eva, vm_prot_t prot) 1051 { 1052 volatile u_int *ptp; 1053 int s, bic; 1054 1055 if ((prot & VM_PROT_READ) == 0) { 1056 pmap_remove(pm, sva, eva); 1057 return; 1058 } 1059 bic = 0; 1060 if ((prot & VM_PROT_WRITE) == 0) 1061 bic |= TTE_WR; 1062 if ((prot & VM_PROT_EXECUTE) == 0) 1063 bic |= TTE_EX; 1064 if (bic == 0) 1065 return; 1066 1067 s = splvm(); 1068 1069 while (sva < eva) { 1070 if ((ptp = pte_find(pm, sva)) != NULL) { 1071 *ptp &= ~bic; 1072 ppc4xx_tlb_flush(sva, pm->pm_ctx); 1073 } 1074 sva += PAGE_SIZE; 1075 } 1076 1077 splx(s); 1078 } 1079 1080 bool 1081 pmap_check_attr(struct vm_page *pg, u_int mask, int clear) 1082 { 1083 paddr_t pa; 1084 char *attr; 1085 int s, rv; 1086 1087 /* 1088 * First modify bits in cache. 1089 */ 1090 pa = VM_PAGE_TO_PHYS(pg); 1091 attr = pa_to_attr(pa); 1092 if (attr == NULL) 1093 return false; 1094 1095 s = splvm(); 1096 1097 rv = (*attr & mask) != 0; 1098 if (clear) { 1099 *attr &= ~mask; 1100 pmap_page_protect(pg, 1101 mask == PMAP_ATTR_CHG ? VM_PROT_READ : 0); 1102 } 1103 1104 splx(s); 1105 1106 return rv; 1107 } 1108 1109 1110 /* 1111 * Lower the protection on the specified physical page. 1112 * 1113 * There are only two cases: either the protection is going to 0, 1114 * or it is going to read-only. 1115 */ 1116 void 1117 pmap_page_protect(struct vm_page *pg, vm_prot_t prot) 1118 { 1119 struct pv_entry *pvh, *pv, *npv; 1120 struct pmap *pm; 1121 paddr_t pa = VM_PAGE_TO_PHYS(pg); 1122 vaddr_t va; 1123 1124 pvh = pa_to_pv(pa); 1125 if (pvh == NULL) 1126 return; 1127 1128 /* Handle extra pvs which may be deleted in the operation */ 1129 for (pv = pvh->pv_next; pv; pv = npv) { 1130 npv = pv->pv_next; 1131 1132 pm = pv->pv_pm; 1133 va = PV_VA(pv); 1134 pmap_protect(pm, va, va + PAGE_SIZE, prot); 1135 } 1136 1137 /* Now check the head pv */ 1138 if (pvh->pv_pm) { 1139 pv = pvh; 1140 pm = pv->pv_pm; 1141 va = PV_VA(pv); 1142 pmap_protect(pm, va, va + PAGE_SIZE, prot); 1143 } 1144 } 1145 1146 /* 1147 * Activate the address space for the specified process. If the process 1148 * is the current process, load the new MMU context. 1149 */ 1150 void 1151 pmap_activate(struct lwp *l) 1152 { 1153 #if 0 1154 struct pcb *pcb = lwp_getpcb(l); 1155 pmap_t pmap = l->l_proc->p_vmspace->vm_map.pmap; 1156 1157 /* 1158 * XXX Normally performed in cpu_lwp_fork(). 1159 */ 1160 printf("pmap_activate(%p), pmap=%p\n",l,pmap); 1161 pcb->pcb_pm = pmap; 1162 #endif 1163 } 1164 1165 /* 1166 * Deactivate the specified process's address space. 1167 */ 1168 void 1169 pmap_deactivate(struct lwp *l) 1170 { 1171 } 1172 1173 /* 1174 * Synchronize caches corresponding to [addr, addr+len) in p. 1175 */ 1176 void 1177 pmap_procwr(struct proc *p, vaddr_t va, size_t len) 1178 { 1179 struct pmap *pm = p->p_vmspace->vm_map.pmap; 1180 1181 if (__predict_true(p == curproc)) { 1182 int msr, ctx, pid; 1183 1184 /* 1185 * Take it easy! TLB miss handler takes care of us. 1186 */ 1187 1188 /* 1189 * Need to turn off IMMU and switch to user context. 1190 * (icbi uses DMMU). 1191 */ 1192 1193 if (!(ctx = pm->pm_ctx)) { 1194 /* No context -- assign it one */ 1195 ctx_alloc(pm); 1196 ctx = pm->pm_ctx; 1197 } 1198 1199 __asm volatile ( 1200 "mfmsr %[msr];" 1201 "li %[pid],0x20;" /* Turn off IMMU */ 1202 "andc %[pid],%[msr],%[pid];" 1203 "ori %[pid],%[pid],0x10;" /* Turn on DMMU for sure */ 1204 "mtmsr %[pid];" 1205 "isync;" 1206 MFPID(%[pid]) 1207 MTPID(%[ctx]) 1208 "isync;" 1209 "1:" 1210 "dcbst 0,%[va];" 1211 "icbi 0,%[va];" 1212 "add %[va],%[va],%[size];" 1213 "sub. %[len],%[len],%[size];" 1214 "bge 1b;" 1215 "sync;" 1216 MTPID(%[pid]) 1217 "mtmsr %[msr];" 1218 "isync;" 1219 : [msr] "=&r" (msr), [pid] "=&r" (pid) 1220 : [ctx] "r" (ctx), [va] "r" (va), [len] "r" (len), 1221 [size] "r" (CACHELINESIZE)); 1222 } else { 1223 paddr_t pa; 1224 vaddr_t tva, eva; 1225 int tlen; 1226 1227 /* 1228 * For p != curproc, we cannot rely upon TLB miss handler in 1229 * user context. Therefore, extract pa and operate against it. 1230 * 1231 * Note that va below VM_MIN_KERNEL_ADDRESS is reserved for 1232 * direct mapping. 1233 */ 1234 1235 for (tva = va; len > 0; tva = eva, len -= tlen) { 1236 eva = uimin(tva + len, trunc_page(tva + PAGE_SIZE)); 1237 tlen = eva - tva; 1238 if (!pmap_extract(pm, tva, &pa)) { 1239 /* XXX should be already unmapped */ 1240 continue; 1241 } 1242 __syncicache((void *)pa, tlen); 1243 } 1244 } 1245 } 1246 1247 static inline void 1248 tlb_invalidate_entry(int i) 1249 { 1250 #if defined(PMAP_TLBDEBUG) && !defined(PPC_IBM440) 1251 /* 1252 * Clear only TLBHI[V] bit so that we can track invalidated entry. 1253 */ 1254 register_t msr, pid, hi; 1255 1256 KASSERT(mfspr(SPR_PID) == KERNEL_PID); 1257 1258 __asm volatile ( 1259 "mfmsr %[msr];" 1260 "li %[pid],0;" 1261 "mtmsr %[pid];" 1262 MFPID(%[pid]) 1263 "tlbre %[hi],%[i],0;" 1264 "andc %[hi],%[hi],%[valid];" 1265 "tlbwe %[hi],%[i],0;" 1266 MTPID(%[pid]) 1267 "mtmsr %[msr];" 1268 "isync;" 1269 : [msr] "=&r" (msr), [pid] "=&r" (pid), [hi] "=&r" (hi) 1270 : [i] "r" (i), [valid] "r" (TLB_VALID)); 1271 #else 1272 /* 1273 * Just clear entire TLBHI register. 1274 */ 1275 __asm volatile ( 1276 "tlbwe %0,%1,0;" 1277 "isync;" 1278 : : "r" (0), "r" (i)); 1279 #endif 1280 1281 tlb_info[i].ti_ctx = 0; 1282 tlb_info[i].ti_flags = 0; 1283 } 1284 1285 /* This has to be done in real mode !!! */ 1286 void 1287 ppc4xx_tlb_flush(vaddr_t va, int pid) 1288 { 1289 u_long msr, i, found; 1290 1291 /* If there's no context then it can't be mapped. */ 1292 if (!pid) 1293 return; 1294 1295 #ifdef PPC_IBM440 1296 /* 1297 * PID and space come from MMUCR, not the PID SPR!!! 1298 */ 1299 { 1300 u_long omm, tmp; 1301 1302 __asm volatile ( 1303 "mfmsr %[msr];" 1304 "wrteei 0;" 1305 MFMMUCR(%[omm]) 1306 "andc %[tmp],%[omm],%[clr];" 1307 "or %[tmp],%[tmp],%[stspid];" 1308 MTMMUCR(%[tmp]) 1309 "isync;" 1310 "tlbsx. %[i],0,%[va];" 1311 MTMMUCR(%[omm]) 1312 "mtmsr %[msr];" 1313 "isync;" 1314 "li %[found],1;" 1315 "beq 1f;" 1316 "li %[found],0;" 1317 "1:" 1318 : [i] "=&r" (i), [found] "=&r" (found), 1319 [msr] "=&r" (msr), [omm] "=&r" (omm), 1320 [tmp] "=&r" (tmp) 1321 : [va] "r" (va), 1322 [stspid] "r" (MMUCR_STS | (pid & MMUCR_STID)), 1323 [clr] "r" (MMUCR_STS | MMUCR_STID) 1324 : "cr0"); 1325 } 1326 #else 1327 __asm volatile ( 1328 MFPID(%[found]) /* Save PID */ 1329 "mfmsr %[msr];" /* Save MSR */ 1330 "li %[i],0;" /* Now clear MSR */ 1331 "mtmsr %[i];" 1332 "isync;" 1333 MTPID(%[pid]) /* Set PID */ 1334 "isync;" 1335 "tlbsx. %[i],0,%[va];" /* Search TLB */ 1336 "isync;" 1337 MTPID(%[found]) /* Restore PID */ 1338 "mtmsr %[msr];" /* Restore MSR */ 1339 "isync;" 1340 "li %[found],1;" 1341 "beq 1f;" 1342 "li %[found],0;" 1343 "1:" 1344 : [i] "=&r" (i), [found] "=&r" (found), [msr] "=&r" (msr) 1345 : [va] "r" (va), [pid] "r" (pid)); 1346 #endif 1347 1348 if (found && !TLB_LOCKED(i)) { 1349 /* Now flush translation */ 1350 tlb_invalidate_entry(i); 1351 tlbnext = i; 1352 /* Successful flushes */ 1353 tlbflush_ev.ev_count++; 1354 } 1355 } 1356 1357 void 1358 ppc4xx_tlb_flush_all(void) 1359 { 1360 u_long i; 1361 1362 for (i = 0; i < NTLB; i++) 1363 if (!TLB_LOCKED(i)) 1364 tlb_invalidate_entry(i); 1365 1366 __asm volatile ("isync"); 1367 } 1368 1369 /* Find a TLB entry to evict. */ 1370 static int 1371 ppc4xx_tlb_find_victim(void) 1372 { 1373 int flags; 1374 1375 for (;;) { 1376 if (++tlbnext >= NTLB) 1377 tlbnext = tlb_nreserved; 1378 flags = tlb_info[tlbnext].ti_flags; 1379 if (!(flags & TLBF_USED) || 1380 (flags & (TLBF_LOCKED | TLBF_REF)) == 0) { 1381 u_long va, stack = (u_long)&va; 1382 1383 if (!((tlb_info[tlbnext].ti_va ^ stack) & 1384 (~PGOFSET)) && 1385 (tlb_info[tlbnext].ti_ctx == KERNEL_PID) && 1386 (flags & TLBF_USED)) { 1387 /* Kernel stack page */ 1388 flags |= TLBF_REF; 1389 tlb_info[tlbnext].ti_flags = flags; 1390 } else { 1391 /* Found it! */ 1392 return tlbnext; 1393 } 1394 } else 1395 tlb_info[tlbnext].ti_flags = (flags & ~TLBF_REF); 1396 } 1397 } 1398 1399 #ifdef PPC_IBM440 1400 /* 1401 * Convert the 40x-style software TTE permission/attribute bits into 1402 * 440 TLB word 2. 1403 */ 1404 static inline u_int 1405 tte_to_tlb44_word2(u_int pte) 1406 { 1407 u_int w2; 1408 1409 w2 = TLB44_WIMG(pte) | TLB44_SR; 1410 if (pte & TTE_WR) 1411 w2 |= TLB44_SW; 1412 if (pte & TTE_EX) 1413 w2 |= TLB44_SX; 1414 if (((pte & TTE_ZSEL_MASK) >> TTE_ZSEL_SHFT) == ZONE_USER) { 1415 w2 |= TLB44_UR; 1416 if (pte & TTE_WR) 1417 w2 |= TLB44_UW; 1418 if (pte & TTE_EX) 1419 w2 |= TLB44_UX; 1420 } 1421 return w2; 1422 } 1423 #endif /* PPC_IBM440 */ 1424 1425 void 1426 ppc4xx_tlb_enter(int ctx, vaddr_t va, u_int pte) 1427 { 1428 #ifdef PPC_IBM440 1429 u_long w0, w1, w2, omm, tmp, i; 1430 paddr_t pa; 1431 int msr, sz; 1432 #else 1433 u_long hi, lo, i; 1434 paddr_t pa; 1435 int msr, pid, sz; 1436 #endif 1437 1438 tlbenter_ev.ev_count++; 1439 1440 sz = (pte & TTE_SZ_MASK) >> TTE_SZ_SHIFT; 1441 pa = (pte & TTE_RPN_MASK(sz)); 1442 #ifdef PPC_IBM440 1443 w0 = (va & ~(tlbsize[sz] - 1)) | (sz << TLB44_SIZE_SHFT) | 1444 TLB44_V | TLB44_TS; 1445 w1 = pa; /* ERPN=0: RAM is below 4GB */ 1446 w2 = tte_to_tlb44_word2(pte); 1447 #else 1448 hi = (va & TLB_EPN_MASK) | (sz << TLB_SIZE_SHFT) | TLB_VALID; 1449 lo = (pte & ~TLB_RPN_MASK) | pa; 1450 lo |= ppc4xx_tlbflags(va, pa); 1451 #endif 1452 1453 i = ppc4xx_tlb_find_victim(); 1454 1455 KASSERTMSG(i >= tlb_nreserved && i < NTLB, 1456 "invalid entry %ld", i); 1457 1458 tlb_info[i].ti_va = (va & TLB_EPN_MASK); 1459 tlb_info[i].ti_ctx = ctx; 1460 tlb_info[i].ti_flags = TLBF_USED | TLBF_REF; 1461 1462 #ifdef PPC_IBM440 1463 /* 1464 * ID is taken from MMUCR[STID] when word 0 is written. 1465 */ 1466 __asm volatile ( 1467 "mfmsr %[msr];" 1468 "wrteei 0;" 1469 MFMMUCR(%[omm]) 1470 "andc %[tmp],%[omm],%[clr];" 1471 "or %[tmp],%[tmp],%[ctx];" 1472 MTMMUCR(%[tmp]) 1473 "isync;" 1474 "tlbwe %[w2],%[i],2;" 1475 "tlbwe %[w1],%[i],1;" 1476 "tlbwe %[w0],%[i],0;" 1477 "isync;" 1478 MTMMUCR(%[omm]) 1479 "mtmsr %[msr];" 1480 "isync;" 1481 : [msr] "=&r" (msr), [omm] "=&r" (omm), 1482 [tmp] "=&r" (tmp) 1483 : [ctx] "r" (ctx & MMUCR_STID), 1484 [clr] "r" (MMUCR_STS | MMUCR_STID), [i] "r" (i), 1485 [w0] "r" (w0), [w1] "r" (w1), [w2] "r" (w2)); 1486 #else 1487 __asm volatile ( 1488 "mfmsr %[msr];" /* Save MSR */ 1489 "li %[pid],0;" 1490 "mtmsr %[pid];" /* Clear MSR */ 1491 "isync;" 1492 "tlbwe %[pid],%[i],0;" /* Invalidate old entry. */ 1493 MFPID(%[pid]) /* Save old PID */ 1494 MTPID(%[ctx]) /* Load translation ctx */ 1495 "isync;" 1496 "tlbwe %[lo],%[i],1;" /* Set TLB */ 1497 "tlbwe %[hi],%[i],0;" 1498 "isync;" 1499 MTPID(%[pid]) /* Restore PID */ 1500 "mtmsr %[msr];" /* and MSR */ 1501 "isync;" 1502 : [msr] "=&r" (msr), [pid] "=&r" (pid) 1503 : [ctx] "r" (ctx), [i] "r" (i), [lo] "r" (lo), [hi] "r" (hi)); 1504 #endif 1505 } 1506 1507 void 1508 ppc4xx_tlb_init(void) 1509 { 1510 int i; 1511 1512 /* Mark reserved TLB entries */ 1513 for (i = 0; i < tlb_nreserved; i++) { 1514 tlb_info[i].ti_flags = TLBF_LOCKED | TLBF_USED; 1515 tlb_info[i].ti_ctx = KERNEL_PID; 1516 } 1517 1518 #ifndef PPC_IBM440 1519 /* Setup security zones */ 1520 /* Z0 - accessible by kernel only if TLB entry permissions allow 1521 * Z1,Z2 - access is controlled by TLB entry permissions 1522 * Z3 - full access regardless of TLB entry permissions 1523 */ 1524 1525 __asm volatile ( 1526 "mtspr %0,%1;" 1527 "isync;" 1528 : : "K" (SPR_ZPR), "r" (0x1b000000)); 1529 #endif 1530 } 1531 1532 #ifndef PPC_IBM440 1533 /* 1534 * ppc4xx_tlb_size_mask: 1535 * 1536 * Roundup size to supported page size, return TLBHI mask and real size. 1537 */ 1538 static int 1539 ppc4xx_tlb_size_mask(size_t size, int *mask, int *rsiz) 1540 { 1541 int i; 1542 1543 for (i = 0; i < __arraycount(tlbsize); i++) 1544 if (size <= tlbsize[i]) { 1545 *mask = (i << TLB_SIZE_SHFT); 1546 *rsiz = tlbsize[i]; 1547 return 0; 1548 } 1549 return EINVAL; 1550 } 1551 #endif /* !PPC_IBM440 */ 1552 1553 /* 1554 * ppc4xx_tlb_mapiodev: 1555 * 1556 * Lookup virtual address of mapping previously entered via 1557 * ppc4xx_tlb_reserve. Search TLB directly so that we don't 1558 * need to waste extra storage for reserved mappings. Note 1559 * that reading TLBHI also sets PID, but all reserved mappings 1560 * use KERNEL_PID, so the side effect is nil. 1561 */ 1562 void * 1563 ppc4xx_tlb_mapiodev(paddr_t base, psize_t len) 1564 { 1565 #ifdef PPC_IBM440 1566 int i, j; 1567 1568 /* 1569 * Match against the 32-bit (on-chip bus) address; the ERPN 1570 * extension is recorded in the reserved-mapping table only. 1571 */ 1572 for (i = 0; i < tlb_nreserved; i++) { 1573 const uint32_t pa32 = (uint32_t)tlb44_resv[i].tr_pa; 1574 uint64_t end_pa; 1575 vaddr_t va, end_va; 1576 bool grew; 1577 1578 if (tlb44_resv[i].tr_size == 0) 1579 continue; 1580 if (base < pa32 || base >= pa32 + tlb44_resv[i].tr_size) 1581 continue; 1582 1583 va = tlb44_resv[i].tr_va + (base - pa32); 1584 end_pa = tlb44_resv[i].tr_pa + tlb44_resv[i].tr_size; 1585 end_va = tlb44_resv[i].tr_va + tlb44_resv[i].tr_size; 1586 1587 do { 1588 if (base + len <= (uint32_t)end_pa) 1589 return (void *)va; 1590 grew = false; 1591 for (j = 0; j < tlb_nreserved; j++) { 1592 if (tlb44_resv[j].tr_size != 0 && 1593 tlb44_resv[j].tr_pa == end_pa && 1594 tlb44_resv[j].tr_va == end_va) { 1595 end_pa += tlb44_resv[j].tr_size; 1596 end_va += tlb44_resv[j].tr_size; 1597 grew = true; 1598 break; 1599 } 1600 } 1601 } while (grew); 1602 /* run ended before covering len; no other entry can */ 1603 return NULL; 1604 } 1605 1606 return NULL; 1607 #else 1608 paddr_t pa; 1609 vaddr_t va; 1610 u_int lo, hi, sz; 1611 int i; 1612 1613 /* tlb_nreserved is only allowed to grow, so this is safe. */ 1614 for (i = 0; i < tlb_nreserved; i++) { 1615 __asm volatile ( 1616 "tlbre %[lo],%[i],1;" /* TLBLO */ 1617 "tlbre %[hi],%[i],0;" /* TLBHI */ 1618 : [lo] "=&r" (lo), [hi] "=&r" (hi) 1619 : [i] "r" (i)); 1620 1621 KASSERT(hi & TLB_VALID); 1622 KASSERT(mfspr(SPR_PID) == KERNEL_PID); 1623 1624 pa = (lo & TLB_RPN_MASK); 1625 if (base < pa) 1626 continue; 1627 1628 sz = tlbsize[(hi & TLB_SIZE_MASK) >> TLB_SIZE_SHFT]; 1629 if (base + len > pa + sz) 1630 continue; 1631 1632 va = (hi & TLB_EPN_MASK) + (base & (sz - 1)); /* sz = 2^n */ 1633 return (void *)va; 1634 } 1635 1636 return NULL; 1637 #endif 1638 } 1639 1640 #ifdef PPC_IBM440 1641 bool 1642 ppc44x_tlb_reverse(vaddr_t va, paddr_t *pap) 1643 { 1644 int i; 1645 1646 for (i = 0; i < tlb_nreserved; i++) { 1647 if (tlb44_resv[i].tr_size == 0) 1648 continue; 1649 if (va >= tlb44_resv[i].tr_va && 1650 va < tlb44_resv[i].tr_va + tlb44_resv[i].tr_size) { 1651 *pap = (uint32_t)tlb44_resv[i].tr_pa + 1652 (va - tlb44_resv[i].tr_va); 1653 return true; 1654 } 1655 } 1656 return false; 1657 } 1658 1659 void 1660 ppc44x_tlb_boot_reserved(int n) 1661 { 1662 1663 KASSERT(tlb_nreserved == 0); 1664 KASSERT(n < NTLB); 1665 1666 /* zero-size entries never match in ppc4xx_tlb_mapiodev() */ 1667 tlb_nreserved = n; 1668 } 1669 1670 void 1671 ppc44x_tlb_reserve(uint64_t pa, vaddr_t va, size_t size, int flags) 1672 { 1673 static const struct { 1674 size_t size; 1675 int enc; 1676 } sizetab[] = { 1677 { 0x00000400, TLB_SIZE_1K }, 1678 { 0x00001000, TLB_SIZE_4K }, 1679 { 0x00004000, TLB_SIZE_16K }, 1680 { 0x00010000, TLB_SIZE_64K }, 1681 { 0x00040000, TLB_SIZE_256K }, 1682 { 0x00100000, TLB_SIZE_1M }, 1683 { 0x01000000, TLB_SIZE_16M }, 1684 { 0x10000000, TLB44_SIZE_256M }, 1685 }; 1686 u_long w0, w1, w2, msr, omm, tmp; 1687 size_t rsize = 0; 1688 int i, enc = -1; 1689 1690 /* Called before pmap_bootstrap(), va outside kernel space. */ 1691 KASSERT(va < VM_MIN_KERNEL_ADDRESS || va >= VM_MAX_KERNEL_ADDRESS); 1692 KASSERT(!pmap_bootstrap_done); 1693 KASSERT(tlb_nreserved < NTLB); 1694 1695 for (i = 0; i < __arraycount(sizetab); i++) 1696 if (size <= sizetab[i].size) { 1697 rsize = sizetab[i].size; 1698 enc = sizetab[i].enc; 1699 break; 1700 } 1701 if (enc < 0) 1702 panic("ppc44x_tlb_reserve: entry %d, %zuB too large", 1703 tlb_nreserved, size); 1704 1705 pa &= ~(uint64_t)(rsize - 1); 1706 va &= ~(rsize - 1); 1707 1708 w0 = va | TLB44_V | TLB44_TS | (enc << TLB44_SIZE_SHFT); 1709 w1 = (u_long)pa | ((u_long)(pa >> 32) & TLB44_ERPN_MASK); 1710 w2 = TLB44_WIMG(flags) | TLB44_SR | TLB44_SW; 1711 if (flags & TLB_EX) 1712 w2 |= TLB44_SX; 1713 #ifdef PPC_4XX_NOCACHE 1714 w2 |= TLB44_I; 1715 #endif 1716 1717 tlb44_resv[tlb_nreserved].tr_pa = pa; 1718 tlb44_resv[tlb_nreserved].tr_va = va; 1719 tlb44_resv[tlb_nreserved].tr_size = rsize; 1720 1721 __asm volatile ( 1722 "mfmsr %[msr];" 1723 "wrteei 0;" 1724 MFMMUCR(%[omm]) 1725 "andc %[tmp],%[omm],%[clr];" 1726 "ori %[tmp],%[tmp],%[pid];" 1727 MTMMUCR(%[tmp]) 1728 "isync;" 1729 "tlbwe %[w2],%[i],2;" 1730 "tlbwe %[w1],%[i],1;" 1731 "tlbwe %[w0],%[i],0;" 1732 "isync;" 1733 MTMMUCR(%[omm]) 1734 "mtmsr %[msr];" 1735 "isync;" 1736 : [msr] "=&r" (msr), [omm] "=&r" (omm), [tmp] "=&r" (tmp) 1737 : [pid] "K" (KERNEL_PID), 1738 [clr] "r" (MMUCR_STS | MMUCR_STID), [i] "r" (tlb_nreserved), 1739 [w0] "r" (w0), [w1] "r" (w1), [w2] "r" (w2)); 1740 1741 tlb_nreserved++; 1742 } 1743 1744 /* 1745 * Pin a TS=0 identity entry for a 256MB chunk of RAM. 1746 * Should be enough for everyone. 1747 */ 1748 void 1749 ppc44x_tlb_reserve_ts0(paddr_t pa) 1750 { 1751 const size_t size = 0x10000000; /* 256MB */ 1752 u_long w0, w1, w2, msr, omm, tmp; 1753 1754 KASSERT(!pmap_bootstrap_done); 1755 KASSERT(tlb_nreserved < NTLB); 1756 KASSERT((pa & (size - 1)) == 0); 1757 1758 w0 = (u_long)pa | TLB44_V | (TLB44_SIZE_256M << TLB44_SIZE_SHFT); 1759 w1 = (u_long)pa; /* ERPN = 0: RAM is below 4GB */ 1760 w2 = TLB44_SR | TLB44_SW | TLB44_SX; 1761 #ifdef PPC_4XX_NOCACHE 1762 w2 |= TLB44_I; 1763 #endif 1764 1765 __asm volatile ( 1766 "mfmsr %[msr];" 1767 "wrteei 0;" 1768 MFMMUCR(%[omm]) 1769 "andc %[tmp],%[omm],%[clr];" /* STS = 0, STID = 0 */ 1770 MTMMUCR(%[tmp]) 1771 "isync;" 1772 "tlbwe %[w2],%[i],2;" 1773 "tlbwe %[w1],%[i],1;" 1774 "tlbwe %[w0],%[i],0;" 1775 "isync;" 1776 MTMMUCR(%[omm]) 1777 "mtmsr %[msr];" 1778 "isync;" 1779 : [msr] "=&r" (msr), [omm] "=&r" (omm), [tmp] "=&r" (tmp) 1780 : [clr] "r" (MMUCR_STS | MMUCR_STID), [i] "r" (tlb_nreserved), 1781 [w0] "r" (w0), [w1] "r" (w1), [w2] "r" (w2)); 1782 1783 tlb_nreserved++; 1784 } 1785 1786 void 1787 ppc4xx_tlb_reserve(paddr_t pa, vaddr_t va, size_t size, int flags) 1788 { 1789 1790 ppc44x_tlb_reserve((uint64_t)pa, va, size, flags); 1791 } 1792 #else /* !PPC_IBM440 */ 1793 /* 1794 * ppc4xx_tlb_reserve: 1795 * 1796 * Map physical range to kernel virtual chunk via reserved TLB entry. 1797 */ 1798 void 1799 ppc4xx_tlb_reserve(paddr_t pa, vaddr_t va, size_t size, int flags) 1800 { 1801 u_int lo, hi; 1802 int szmask, rsize; 1803 1804 /* Called before pmap_bootstrap(), va outside kernel space. */ 1805 KASSERT(va < VM_MIN_KERNEL_ADDRESS || va >= VM_MAX_KERNEL_ADDRESS); 1806 KASSERT(!pmap_bootstrap_done); 1807 KASSERT(tlb_nreserved < NTLB); 1808 1809 /* Resolve size. */ 1810 if (ppc4xx_tlb_size_mask(size, &szmask, &rsize) != 0) 1811 panic("ppc4xx_tlb_reserve: entry %d, %zuB too large", 1812 size, tlb_nreserved); 1813 1814 /* Real size will be power of two >= 1024, so this is OK. */ 1815 pa &= ~(rsize - 1); /* RPN */ 1816 va &= ~(rsize - 1); /* EPN */ 1817 1818 lo = pa | TLB_WR | flags; 1819 hi = va | TLB_VALID | szmask; 1820 1821 #ifdef PPC_4XX_NOCACHE 1822 lo |= TLB_I; 1823 #endif 1824 1825 __asm volatile ( 1826 "tlbwe %[lo],%[i],1;" /* write TLBLO */ 1827 "tlbwe %[hi],%[i],0;" /* write TLBHI */ 1828 "isync;" 1829 : : [i] "r" (tlb_nreserved), [lo] "r" (lo), [hi] "r" (hi)); 1830 1831 tlb_nreserved++; 1832 } 1833 #endif /* PPC_IBM440 */ 1834 1835 /* 1836 * We should pass the ctx in from trap code. 1837 */ 1838 int 1839 pmap_tlbmiss(vaddr_t va, int ctx) 1840 { 1841 volatile u_int *pte; 1842 u_long tte; 1843 1844 tlbmiss_ev.ev_count++; 1845 1846 /* 1847 * We will reserve 0 upto VM_MIN_KERNEL_ADDRESS for va == pa mappings. 1848 * Physical RAM is expected to live in this range, care must be taken 1849 * to not clobber 0 upto ${physmem} with device mappings in machdep 1850 * code. 1851 */ 1852 if (ctx != KERNEL_PID || 1853 (va >= VM_MIN_KERNEL_ADDRESS && va < VM_MAX_KERNEL_ADDRESS)) { 1854 pte = pte_find((struct pmap *)__UNVOLATILE(ctxbusy[ctx]), va); 1855 if (pte == NULL) { 1856 /* 1857 * Map unmanaged addresses directly for 1858 * kernel access 1859 */ 1860 return 1; 1861 } 1862 tte = *pte; 1863 if (tte == 0) 1864 return 1; 1865 } else { 1866 /* Create a 16MB writable mapping. */ 1867 tte = TTE_PA(va) | TTE_ZONE(ZONE_PRIV) | TTE_SZ_16M | TTE_WR; 1868 #ifdef PPC_4XX_NOCACHE 1869 tte |= TTE_I; 1870 #endif 1871 } 1872 ppc4xx_tlb_enter(ctx, va, tte); 1873 1874 return 0; 1875 } 1876 1877 /* 1878 * Flush all the entries matching a context from the TLB. 1879 */ 1880 static void 1881 ctx_flush(int cnum) 1882 { 1883 int i; 1884 1885 /* We gotta steal this context */ 1886 for (i = tlb_nreserved; i < NTLB; i++) { 1887 if (tlb_info[i].ti_ctx == cnum) { 1888 /* Can't steal ctx if it has locked/reserved entry. */ 1889 KASSERTMSG(!TLB_LOCKED(i) && i >= tlb_nreserved, 1890 "locked/reserved entry %d for ctx %d", 1891 i, cnum); 1892 /* 1893 * Invalidate particular TLB entry regardless of 1894 * locked status 1895 */ 1896 tlb_invalidate_entry(i); 1897 } 1898 } 1899 } 1900 1901 /* 1902 * Allocate a context. If necessary, steal one from someone else. 1903 * 1904 * The new context is flushed from the TLB before returning. 1905 */ 1906 int 1907 ctx_alloc(struct pmap *pm) 1908 { 1909 static int next = MINCTX; 1910 int cnum, s; 1911 1912 KASSERT(pm != pmap_kernel()); 1913 1914 s = splvm(); 1915 1916 /* Find a likely context. */ 1917 cnum = next; 1918 do { 1919 if (++cnum >= NUMCTX) 1920 cnum = MINCTX; 1921 } while (ctxbusy[cnum] != NULL && cnum != next); 1922 1923 /* Now clean it out */ 1924 if (cnum < MINCTX) 1925 cnum = MINCTX; /* Never steal ctx 0 or 1 */ 1926 ctx_flush(cnum); 1927 1928 if (ctxbusy[cnum]) { 1929 #ifdef DEBUG 1930 /* We should identify this pmap and clear it */ 1931 printf("Warning: stealing context %d\n", cnum); 1932 #endif 1933 ctxbusy[cnum]->pm_ctx = 0; 1934 } 1935 ctxbusy[cnum] = pm; 1936 next = cnum; 1937 1938 splx(s); 1939 1940 pm->pm_ctx = cnum; 1941 1942 return cnum; 1943 } 1944 1945 /* 1946 * Give away a context. 1947 */ 1948 void 1949 ctx_free(struct pmap *pm) 1950 { 1951 int oldctx; 1952 1953 oldctx = pm->pm_ctx; 1954 1955 if (oldctx == 0) 1956 panic("ctx_free: freeing kernel context"); 1957 1958 KASSERTMSG(ctxbusy[oldctx] == pm, 1959 "ctxbusy[%d] = %p, pm->pm_ctx = %p", 1960 oldctx, ctxbusy[oldctx], pm); 1961 1962 /* We should verify it has not been stolen and reallocated... */ 1963 ctxbusy[oldctx] = NULL; 1964 ctx_flush(oldctx); 1965 } 1966 1967 #ifdef DEBUG 1968 /* 1969 * Test ref/modify handling. 1970 */ 1971 void pmap_testout(void); 1972 void 1973 pmap_testout(void) 1974 { 1975 struct vm_page *pg; 1976 vaddr_t va; 1977 paddr_t pa; 1978 volatile int *loc; 1979 int ref, mod, val = 0; 1980 1981 /* Allocate a page */ 1982 va = (vaddr_t)uvm_km_alloc(kernel_map, PAGE_SIZE, 0, 1983 UVM_KMF_WIRED | UVM_KMF_ZERO); 1984 loc = (int *)va; 1985 1986 pmap_extract(pmap_kernel(), va, &pa); 1987 pg = PHYS_TO_VM_PAGE(pa); 1988 pmap_unwire(pmap_kernel(), va); 1989 1990 pmap_kremove(va, PAGE_SIZE); 1991 pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0); 1992 pmap_update(pmap_kernel()); 1993 1994 /* Now clear reference and modify */ 1995 ref = pmap_clear_reference(pg); 1996 mod = pmap_clear_modify(pg); 1997 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 1998 (void *)(u_long)va, (long)pa, ref, mod); 1999 2000 /* Check it's properly cleared */ 2001 ref = pmap_is_referenced(pg); 2002 mod = pmap_is_modified(pg); 2003 printf("Checking cleared page: ref %d, mod %d\n", ref, mod); 2004 2005 /* Reference page */ 2006 val = *loc; 2007 2008 ref = pmap_is_referenced(pg); 2009 mod = pmap_is_modified(pg); 2010 printf("Referenced page: ref %d, mod %d val %x\n", ref, mod, val); 2011 2012 /* Now clear reference and modify */ 2013 ref = pmap_clear_reference(pg); 2014 mod = pmap_clear_modify(pg); 2015 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2016 (void *)(u_long)va, (long)pa, ref, mod); 2017 2018 /* Modify page */ 2019 *loc = 1; 2020 2021 ref = pmap_is_referenced(pg); 2022 mod = pmap_is_modified(pg); 2023 printf("Modified page: ref %d, mod %d\n", ref, mod); 2024 2025 /* Now clear reference and modify */ 2026 ref = pmap_clear_reference(pg); 2027 mod = pmap_clear_modify(pg); 2028 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2029 (void *)(u_long)va, (long)pa, ref, mod); 2030 2031 /* Check it's properly cleared */ 2032 ref = pmap_is_referenced(pg); 2033 mod = pmap_is_modified(pg); 2034 printf("Checking cleared page: ref %d, mod %d\n", ref, mod); 2035 2036 /* Modify page */ 2037 *loc = 1; 2038 2039 ref = pmap_is_referenced(pg); 2040 mod = pmap_is_modified(pg); 2041 printf("Modified page: ref %d, mod %d\n", ref, mod); 2042 2043 /* Check pmap_protect() */ 2044 pmap_protect(pmap_kernel(), va, va + PAGE_SIZE, VM_PROT_READ); 2045 pmap_update(pmap_kernel()); 2046 ref = pmap_is_referenced(pg); 2047 mod = pmap_is_modified(pg); 2048 printf("pmap_protect(VM_PROT_READ): ref %d, mod %d\n", ref, mod); 2049 2050 /* Now clear reference and modify */ 2051 ref = pmap_clear_reference(pg); 2052 mod = pmap_clear_modify(pg); 2053 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2054 (void *)(u_long)va, (long)pa, ref, mod); 2055 2056 /* Reference page */ 2057 val = *loc; 2058 2059 ref = pmap_is_referenced(pg); 2060 mod = pmap_is_modified(pg); 2061 printf("Referenced page: ref %d, mod %d val %x\n", ref, mod, val); 2062 2063 /* Now clear reference and modify */ 2064 ref = pmap_clear_reference(pg); 2065 mod = pmap_clear_modify(pg); 2066 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2067 (void *)(u_long)va, (long)pa, ref, mod); 2068 2069 /* Modify page */ 2070 #if 0 2071 pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0); 2072 pmap_update(pmap_kernel()); 2073 #endif 2074 *loc = 1; 2075 2076 ref = pmap_is_referenced(pg); 2077 mod = pmap_is_modified(pg); 2078 printf("Modified page: ref %d, mod %d\n", ref, mod); 2079 2080 /* Check pmap_protect() */ 2081 pmap_protect(pmap_kernel(), va, va + PAGE_SIZE, VM_PROT_NONE); 2082 pmap_update(pmap_kernel()); 2083 ref = pmap_is_referenced(pg); 2084 mod = pmap_is_modified(pg); 2085 printf("pmap_protect(): ref %d, mod %d\n", ref, mod); 2086 2087 /* Now clear reference and modify */ 2088 ref = pmap_clear_reference(pg); 2089 mod = pmap_clear_modify(pg); 2090 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2091 (void *)(u_long)va, (long)pa, ref, mod); 2092 2093 /* Reference page */ 2094 val = *loc; 2095 2096 ref = pmap_is_referenced(pg); 2097 mod = pmap_is_modified(pg); 2098 printf("Referenced page: ref %d, mod %d val %x\n", ref, mod, val); 2099 2100 /* Now clear reference and modify */ 2101 ref = pmap_clear_reference(pg); 2102 mod = pmap_clear_modify(pg); 2103 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2104 (void *)(u_long)va, (long)pa, ref, mod); 2105 2106 /* Modify page */ 2107 #if 0 2108 pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0); 2109 pmap_update(pmap_kernel()); 2110 #endif 2111 *loc = 1; 2112 2113 ref = pmap_is_referenced(pg); 2114 mod = pmap_is_modified(pg); 2115 printf("Modified page: ref %d, mod %d\n", ref, mod); 2116 2117 /* Check pmap_pag_protect() */ 2118 pmap_page_protect(pg, VM_PROT_READ); 2119 ref = pmap_is_referenced(pg); 2120 mod = pmap_is_modified(pg); 2121 printf("pmap_page_protect(VM_PROT_READ): ref %d, mod %d\n", ref, mod); 2122 2123 /* Now clear reference and modify */ 2124 ref = pmap_clear_reference(pg); 2125 mod = pmap_clear_modify(pg); 2126 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2127 (void *)(u_long)va, (long)pa, ref, mod); 2128 2129 /* Reference page */ 2130 val = *loc; 2131 2132 ref = pmap_is_referenced(pg); 2133 mod = pmap_is_modified(pg); 2134 printf("Referenced page: ref %d, mod %d val %x\n", ref, mod, val); 2135 2136 /* Now clear reference and modify */ 2137 ref = pmap_clear_reference(pg); 2138 mod = pmap_clear_modify(pg); 2139 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2140 (void *)(u_long)va, (long)pa, ref, mod); 2141 2142 /* Modify page */ 2143 #if 0 2144 pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0); 2145 pmap_update(pmap_kernel()); 2146 #endif 2147 *loc = 1; 2148 2149 ref = pmap_is_referenced(pg); 2150 mod = pmap_is_modified(pg); 2151 printf("Modified page: ref %d, mod %d\n", ref, mod); 2152 2153 /* Check pmap_pag_protect() */ 2154 pmap_page_protect(pg, VM_PROT_NONE); 2155 ref = pmap_is_referenced(pg); 2156 mod = pmap_is_modified(pg); 2157 printf("pmap_page_protect(): ref %d, mod %d\n", ref, mod); 2158 2159 /* Now clear reference and modify */ 2160 ref = pmap_clear_reference(pg); 2161 mod = pmap_clear_modify(pg); 2162 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2163 (void *)(u_long)va, (long)pa, ref, mod); 2164 2165 2166 /* Reference page */ 2167 val = *loc; 2168 2169 ref = pmap_is_referenced(pg); 2170 mod = pmap_is_modified(pg); 2171 printf("Referenced page: ref %d, mod %d val %x\n", ref, mod, val); 2172 2173 /* Now clear reference and modify */ 2174 ref = pmap_clear_reference(pg); 2175 mod = pmap_clear_modify(pg); 2176 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2177 (void *)(u_long)va, (long)pa, ref, mod); 2178 2179 /* Modify page */ 2180 #if 0 2181 pmap_enter(pmap_kernel(), va, pa, VM_PROT_ALL, 0); 2182 pmap_update(pmap_kernel()); 2183 #endif 2184 *loc = 1; 2185 2186 ref = pmap_is_referenced(pg); 2187 mod = pmap_is_modified(pg); 2188 printf("Modified page: ref %d, mod %d\n", ref, mod); 2189 2190 /* Unmap page */ 2191 pmap_remove(pmap_kernel(), va, va + PAGE_SIZE); 2192 pmap_update(pmap_kernel()); 2193 ref = pmap_is_referenced(pg); 2194 mod = pmap_is_modified(pg); 2195 printf("Unmapped page: ref %d, mod %d\n", ref, mod); 2196 2197 /* Now clear reference and modify */ 2198 ref = pmap_clear_reference(pg); 2199 mod = pmap_clear_modify(pg); 2200 printf("Clearing page va %p pa %lx: ref %d, mod %d\n", 2201 (void *)(u_long)va, (long)pa, ref, mod); 2202 2203 /* Check it's properly cleared */ 2204 ref = pmap_is_referenced(pg); 2205 mod = pmap_is_modified(pg); 2206 printf("Checking cleared page: ref %d, mod %d\n", ref, mod); 2207 2208 pmap_remove(pmap_kernel(), va, va + PAGE_SIZE); 2209 pmap_kenter_pa(va, pa, VM_PROT_ALL, 0); 2210 uvm_km_free(kernel_map, (vaddr_t)va, PAGE_SIZE, UVM_KMF_WIRED); 2211 } 2212 #endif 2213