pmap.c revision 209908
1/*- 2 * Copyright (C) 2007-2009 Semihalf, Rafal Jaworowski <raj@semihalf.com> 3 * Copyright (C) 2006 Semihalf, Marian Balakowicz <m8@semihalf.com> 4 * All rights reserved. 5 * 6 * Redistribution and use in source and binary forms, with or without 7 * modification, are permitted provided that the following conditions 8 * are met: 9 * 1. Redistributions of source code must retain the above copyright 10 * notice, this list of conditions and the following disclaimer. 11 * 2. Redistributions in binary form must reproduce the above copyright 12 * notice, this list of conditions and the following disclaimer in the 13 * documentation and/or other materials provided with the distribution. 14 * 15 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 16 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 17 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN 18 * NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 19 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED 20 * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR 21 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF 22 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING 23 * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS 24 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 25 * 26 * Some hw specific parts of this pmap were derived or influenced 27 * by NetBSD's ibm4xx pmap module. More generic code is shared with 28 * a few other pmap modules from the FreeBSD tree. 29 */ 30 31 /* 32 * VM layout notes: 33 * 34 * Kernel and user threads run within one common virtual address space 35 * defined by AS=0. 36 * 37 * Virtual address space layout: 38 * ----------------------------- 39 * 0x0000_0000 - 0xafff_ffff : user process 40 * 0xb000_0000 - 0xbfff_ffff : pmap_mapdev()-ed area (PCI/PCIE etc.) 41 * 0xc000_0000 - 0xc0ff_ffff : kernel reserved 42 * 0xc000_0000 - data_end : kernel code+data, env, metadata etc. 43 * 0xc100_0000 - 0xfeef_ffff : KVA 44 * 0xc100_0000 - 0xc100_3fff : reserved for page zero/copy 45 * 0xc100_4000 - 0xc200_3fff : reserved for ptbl bufs 46 * 0xc200_4000 - 0xc200_8fff : guard page + kstack0 47 * 0xc200_9000 - 0xfeef_ffff : actual free KVA space 48 * 0xfef0_0000 - 0xffff_ffff : I/O devices region 49 */ 50 51#include <sys/cdefs.h> 52__FBSDID("$FreeBSD: head/sys/powerpc/booke/pmap.c 209908 2010-07-11 21:08:29Z raj $"); 53 54#include <sys/types.h> 55#include <sys/param.h> 56#include <sys/malloc.h> 57#include <sys/ktr.h> 58#include <sys/proc.h> 59#include <sys/user.h> 60#include <sys/queue.h> 61#include <sys/systm.h> 62#include <sys/kernel.h> 63#include <sys/msgbuf.h> 64#include <sys/lock.h> 65#include <sys/mutex.h> 66#include <sys/smp.h> 67#include <sys/vmmeter.h> 68 69#include <vm/vm.h> 70#include <vm/vm_page.h> 71#include <vm/vm_kern.h> 72#include <vm/vm_pageout.h> 73#include <vm/vm_extern.h> 74#include <vm/vm_object.h> 75#include <vm/vm_param.h> 76#include <vm/vm_map.h> 77#include <vm/vm_pager.h> 78#include <vm/uma.h> 79 80#include <machine/cpu.h> 81#include <machine/pcb.h> 82#include <machine/platform.h> 83 84#include <machine/tlb.h> 85#include <machine/spr.h> 86#include <machine/vmparam.h> 87#include <machine/md_var.h> 88#include <machine/mmuvar.h> 89#include <machine/pmap.h> 90#include <machine/pte.h> 91 92#include "mmu_if.h" 93 94#define DEBUG 95#undef DEBUG 96 97#ifdef DEBUG 98#define debugf(fmt, args...) printf(fmt, ##args) 99#else 100#define debugf(fmt, args...) 101#endif 102 103#define TODO panic("%s: not implemented", __func__); 104 105#include "opt_sched.h" 106#ifndef SCHED_4BSD 107#error "e500 only works with SCHED_4BSD which uses a global scheduler lock." 108#endif 109extern struct mtx sched_lock; 110 111extern int dumpsys_minidump; 112 113extern unsigned char _etext[]; 114extern unsigned char _end[]; 115 116/* Kernel physical load address. */ 117extern uint32_t kernload; 118vm_offset_t kernstart; 119vm_size_t kernsize; 120 121/* Message buffer and tables. */ 122static vm_offset_t data_start; 123static vm_size_t data_end; 124 125/* Phys/avail memory regions. */ 126static struct mem_region *availmem_regions; 127static int availmem_regions_sz; 128static struct mem_region *physmem_regions; 129static int physmem_regions_sz; 130 131/* Reserved KVA space and mutex for mmu_booke_zero_page. */ 132static vm_offset_t zero_page_va; 133static struct mtx zero_page_mutex; 134 135static struct mtx tlbivax_mutex; 136 137/* 138 * Reserved KVA space for mmu_booke_zero_page_idle. This is used 139 * by idle thred only, no lock required. 140 */ 141static vm_offset_t zero_page_idle_va; 142 143/* Reserved KVA space and mutex for mmu_booke_copy_page. */ 144static vm_offset_t copy_page_src_va; 145static vm_offset_t copy_page_dst_va; 146static struct mtx copy_page_mutex; 147 148/**************************************************************************/ 149/* PMAP */ 150/**************************************************************************/ 151 152static void mmu_booke_enter_locked(mmu_t, pmap_t, vm_offset_t, vm_page_t, 153 vm_prot_t, boolean_t); 154 155unsigned int kptbl_min; /* Index of the first kernel ptbl. */ 156unsigned int kernel_ptbls; /* Number of KVA ptbls. */ 157 158/* 159 * If user pmap is processed with mmu_booke_remove and the resident count 160 * drops to 0, there are no more pages to remove, so we need not continue. 161 */ 162#define PMAP_REMOVE_DONE(pmap) \ 163 ((pmap) != kernel_pmap && (pmap)->pm_stats.resident_count == 0) 164 165extern void tlb_lock(uint32_t *); 166extern void tlb_unlock(uint32_t *); 167extern void tid_flush(tlbtid_t); 168 169/**************************************************************************/ 170/* TLB and TID handling */ 171/**************************************************************************/ 172 173/* Translation ID busy table */ 174static volatile pmap_t tidbusy[MAXCPU][TID_MAX + 1]; 175 176/* 177 * TLB0 capabilities (entry, way numbers etc.). These can vary between e500 178 * core revisions and should be read from h/w registers during early config. 179 */ 180uint32_t tlb0_entries; 181uint32_t tlb0_ways; 182uint32_t tlb0_entries_per_way; 183 184#define TLB0_ENTRIES (tlb0_entries) 185#define TLB0_WAYS (tlb0_ways) 186#define TLB0_ENTRIES_PER_WAY (tlb0_entries_per_way) 187 188#define TLB1_ENTRIES 16 189 190/* In-ram copy of the TLB1 */ 191static tlb_entry_t tlb1[TLB1_ENTRIES]; 192 193/* Next free entry in the TLB1 */ 194static unsigned int tlb1_idx; 195 196static tlbtid_t tid_alloc(struct pmap *); 197 198static void tlb_print_entry(int, uint32_t, uint32_t, uint32_t, uint32_t); 199 200static int tlb1_set_entry(vm_offset_t, vm_offset_t, vm_size_t, uint32_t); 201static void tlb1_write_entry(unsigned int); 202static int tlb1_iomapped(int, vm_paddr_t, vm_size_t, vm_offset_t *); 203static vm_size_t tlb1_mapin_region(vm_offset_t, vm_offset_t, vm_size_t); 204 205static vm_size_t tsize2size(unsigned int); 206static unsigned int size2tsize(vm_size_t); 207static unsigned int ilog2(unsigned int); 208 209static void set_mas4_defaults(void); 210 211static inline void tlb0_flush_entry(vm_offset_t); 212static inline unsigned int tlb0_tableidx(vm_offset_t, unsigned int); 213 214/**************************************************************************/ 215/* Page table management */ 216/**************************************************************************/ 217 218/* Data for the pv entry allocation mechanism */ 219static uma_zone_t pvzone; 220static struct vm_object pvzone_obj; 221static int pv_entry_count = 0, pv_entry_max = 0, pv_entry_high_water = 0; 222 223#define PV_ENTRY_ZONE_MIN 2048 /* min pv entries in uma zone */ 224 225#ifndef PMAP_SHPGPERPROC 226#define PMAP_SHPGPERPROC 200 227#endif 228 229static void ptbl_init(void); 230static struct ptbl_buf *ptbl_buf_alloc(void); 231static void ptbl_buf_free(struct ptbl_buf *); 232static void ptbl_free_pmap_ptbl(pmap_t, pte_t *); 233 234static pte_t *ptbl_alloc(mmu_t, pmap_t, unsigned int); 235static void ptbl_free(mmu_t, pmap_t, unsigned int); 236static void ptbl_hold(mmu_t, pmap_t, unsigned int); 237static int ptbl_unhold(mmu_t, pmap_t, unsigned int); 238 239static vm_paddr_t pte_vatopa(mmu_t, pmap_t, vm_offset_t); 240static pte_t *pte_find(mmu_t, pmap_t, vm_offset_t); 241static void pte_enter(mmu_t, pmap_t, vm_page_t, vm_offset_t, uint32_t); 242static int pte_remove(mmu_t, pmap_t, vm_offset_t, uint8_t); 243 244static pv_entry_t pv_alloc(void); 245static void pv_free(pv_entry_t); 246static void pv_insert(pmap_t, vm_offset_t, vm_page_t); 247static void pv_remove(pmap_t, vm_offset_t, vm_page_t); 248 249/* Number of kva ptbl buffers, each covering one ptbl (PTBL_PAGES). */ 250#define PTBL_BUFS (128 * 16) 251 252struct ptbl_buf { 253 TAILQ_ENTRY(ptbl_buf) link; /* list link */ 254 vm_offset_t kva; /* va of mapping */ 255}; 256 257/* ptbl free list and a lock used for access synchronization. */ 258static TAILQ_HEAD(, ptbl_buf) ptbl_buf_freelist; 259static struct mtx ptbl_buf_freelist_lock; 260 261/* Base address of kva space allocated fot ptbl bufs. */ 262static vm_offset_t ptbl_buf_pool_vabase; 263 264/* Pointer to ptbl_buf structures. */ 265static struct ptbl_buf *ptbl_bufs; 266 267void pmap_bootstrap_ap(volatile uint32_t *); 268 269/* 270 * Kernel MMU interface 271 */ 272static void mmu_booke_change_wiring(mmu_t, pmap_t, vm_offset_t, boolean_t); 273static void mmu_booke_clear_modify(mmu_t, vm_page_t); 274static void mmu_booke_clear_reference(mmu_t, vm_page_t); 275static void mmu_booke_copy(mmu_t, pmap_t, pmap_t, vm_offset_t, 276 vm_size_t, vm_offset_t); 277static void mmu_booke_copy_page(mmu_t, vm_page_t, vm_page_t); 278static void mmu_booke_enter(mmu_t, pmap_t, vm_offset_t, vm_page_t, 279 vm_prot_t, boolean_t); 280static void mmu_booke_enter_object(mmu_t, pmap_t, vm_offset_t, vm_offset_t, 281 vm_page_t, vm_prot_t); 282static void mmu_booke_enter_quick(mmu_t, pmap_t, vm_offset_t, vm_page_t, 283 vm_prot_t); 284static vm_paddr_t mmu_booke_extract(mmu_t, pmap_t, vm_offset_t); 285static vm_page_t mmu_booke_extract_and_hold(mmu_t, pmap_t, vm_offset_t, 286 vm_prot_t); 287static void mmu_booke_init(mmu_t); 288static boolean_t mmu_booke_is_modified(mmu_t, vm_page_t); 289static boolean_t mmu_booke_is_prefaultable(mmu_t, pmap_t, vm_offset_t); 290static boolean_t mmu_booke_is_referenced(mmu_t, vm_page_t); 291static boolean_t mmu_booke_ts_referenced(mmu_t, vm_page_t); 292static vm_offset_t mmu_booke_map(mmu_t, vm_offset_t *, vm_offset_t, vm_offset_t, 293 int); 294static int mmu_booke_mincore(mmu_t, pmap_t, vm_offset_t, 295 vm_paddr_t *); 296static void mmu_booke_object_init_pt(mmu_t, pmap_t, vm_offset_t, 297 vm_object_t, vm_pindex_t, vm_size_t); 298static boolean_t mmu_booke_page_exists_quick(mmu_t, pmap_t, vm_page_t); 299static void mmu_booke_page_init(mmu_t, vm_page_t); 300static int mmu_booke_page_wired_mappings(mmu_t, vm_page_t); 301static void mmu_booke_pinit(mmu_t, pmap_t); 302static void mmu_booke_pinit0(mmu_t, pmap_t); 303static void mmu_booke_protect(mmu_t, pmap_t, vm_offset_t, vm_offset_t, 304 vm_prot_t); 305static void mmu_booke_qenter(mmu_t, vm_offset_t, vm_page_t *, int); 306static void mmu_booke_qremove(mmu_t, vm_offset_t, int); 307static void mmu_booke_release(mmu_t, pmap_t); 308static void mmu_booke_remove(mmu_t, pmap_t, vm_offset_t, vm_offset_t); 309static void mmu_booke_remove_all(mmu_t, vm_page_t); 310static void mmu_booke_remove_write(mmu_t, vm_page_t); 311static void mmu_booke_zero_page(mmu_t, vm_page_t); 312static void mmu_booke_zero_page_area(mmu_t, vm_page_t, int, int); 313static void mmu_booke_zero_page_idle(mmu_t, vm_page_t); 314static void mmu_booke_activate(mmu_t, struct thread *); 315static void mmu_booke_deactivate(mmu_t, struct thread *); 316static void mmu_booke_bootstrap(mmu_t, vm_offset_t, vm_offset_t); 317static void *mmu_booke_mapdev(mmu_t, vm_offset_t, vm_size_t); 318static void mmu_booke_unmapdev(mmu_t, vm_offset_t, vm_size_t); 319static vm_offset_t mmu_booke_kextract(mmu_t, vm_offset_t); 320static void mmu_booke_kenter(mmu_t, vm_offset_t, vm_offset_t); 321static void mmu_booke_kremove(mmu_t, vm_offset_t); 322static boolean_t mmu_booke_dev_direct_mapped(mmu_t, vm_offset_t, vm_size_t); 323static void mmu_booke_sync_icache(mmu_t, pmap_t, vm_offset_t, 324 vm_size_t); 325static vm_offset_t mmu_booke_dumpsys_map(mmu_t, struct pmap_md *, 326 vm_size_t, vm_size_t *); 327static void mmu_booke_dumpsys_unmap(mmu_t, struct pmap_md *, 328 vm_size_t, vm_offset_t); 329static struct pmap_md *mmu_booke_scan_md(mmu_t, struct pmap_md *); 330 331static mmu_method_t mmu_booke_methods[] = { 332 /* pmap dispatcher interface */ 333 MMUMETHOD(mmu_change_wiring, mmu_booke_change_wiring), 334 MMUMETHOD(mmu_clear_modify, mmu_booke_clear_modify), 335 MMUMETHOD(mmu_clear_reference, mmu_booke_clear_reference), 336 MMUMETHOD(mmu_copy, mmu_booke_copy), 337 MMUMETHOD(mmu_copy_page, mmu_booke_copy_page), 338 MMUMETHOD(mmu_enter, mmu_booke_enter), 339 MMUMETHOD(mmu_enter_object, mmu_booke_enter_object), 340 MMUMETHOD(mmu_enter_quick, mmu_booke_enter_quick), 341 MMUMETHOD(mmu_extract, mmu_booke_extract), 342 MMUMETHOD(mmu_extract_and_hold, mmu_booke_extract_and_hold), 343 MMUMETHOD(mmu_init, mmu_booke_init), 344 MMUMETHOD(mmu_is_modified, mmu_booke_is_modified), 345 MMUMETHOD(mmu_is_prefaultable, mmu_booke_is_prefaultable), 346 MMUMETHOD(mmu_is_referenced, mmu_booke_is_referenced), 347 MMUMETHOD(mmu_ts_referenced, mmu_booke_ts_referenced), 348 MMUMETHOD(mmu_map, mmu_booke_map), 349 MMUMETHOD(mmu_mincore, mmu_booke_mincore), 350 MMUMETHOD(mmu_object_init_pt, mmu_booke_object_init_pt), 351 MMUMETHOD(mmu_page_exists_quick,mmu_booke_page_exists_quick), 352 MMUMETHOD(mmu_page_init, mmu_booke_page_init), 353 MMUMETHOD(mmu_page_wired_mappings, mmu_booke_page_wired_mappings), 354 MMUMETHOD(mmu_pinit, mmu_booke_pinit), 355 MMUMETHOD(mmu_pinit0, mmu_booke_pinit0), 356 MMUMETHOD(mmu_protect, mmu_booke_protect), 357 MMUMETHOD(mmu_qenter, mmu_booke_qenter), 358 MMUMETHOD(mmu_qremove, mmu_booke_qremove), 359 MMUMETHOD(mmu_release, mmu_booke_release), 360 MMUMETHOD(mmu_remove, mmu_booke_remove), 361 MMUMETHOD(mmu_remove_all, mmu_booke_remove_all), 362 MMUMETHOD(mmu_remove_write, mmu_booke_remove_write), 363 MMUMETHOD(mmu_sync_icache, mmu_booke_sync_icache), 364 MMUMETHOD(mmu_zero_page, mmu_booke_zero_page), 365 MMUMETHOD(mmu_zero_page_area, mmu_booke_zero_page_area), 366 MMUMETHOD(mmu_zero_page_idle, mmu_booke_zero_page_idle), 367 MMUMETHOD(mmu_activate, mmu_booke_activate), 368 MMUMETHOD(mmu_deactivate, mmu_booke_deactivate), 369 370 /* Internal interfaces */ 371 MMUMETHOD(mmu_bootstrap, mmu_booke_bootstrap), 372 MMUMETHOD(mmu_dev_direct_mapped,mmu_booke_dev_direct_mapped), 373 MMUMETHOD(mmu_mapdev, mmu_booke_mapdev), 374 MMUMETHOD(mmu_kenter, mmu_booke_kenter), 375 MMUMETHOD(mmu_kextract, mmu_booke_kextract), 376/* MMUMETHOD(mmu_kremove, mmu_booke_kremove), */ 377 MMUMETHOD(mmu_unmapdev, mmu_booke_unmapdev), 378 379 /* dumpsys() support */ 380 MMUMETHOD(mmu_dumpsys_map, mmu_booke_dumpsys_map), 381 MMUMETHOD(mmu_dumpsys_unmap, mmu_booke_dumpsys_unmap), 382 MMUMETHOD(mmu_scan_md, mmu_booke_scan_md), 383 384 { 0, 0 } 385}; 386 387static mmu_def_t booke_mmu = { 388 MMU_TYPE_BOOKE, 389 mmu_booke_methods, 390 0 391}; 392MMU_DEF(booke_mmu); 393 394static inline void 395tlb_miss_lock(void) 396{ 397#ifdef SMP 398 struct pcpu *pc; 399 400 if (!smp_started) 401 return; 402 403 SLIST_FOREACH(pc, &cpuhead, pc_allcpu) { 404 if (pc != pcpup) { 405 406 CTR3(KTR_PMAP, "%s: tlb miss LOCK of CPU=%d, " 407 "tlb_lock=%p", __func__, pc->pc_cpuid, pc->pc_booke_tlb_lock); 408 409 KASSERT((pc->pc_cpuid != PCPU_GET(cpuid)), 410 ("tlb_miss_lock: tried to lock self")); 411 412 tlb_lock(pc->pc_booke_tlb_lock); 413 414 CTR1(KTR_PMAP, "%s: locked", __func__); 415 } 416 } 417#endif 418} 419 420static inline void 421tlb_miss_unlock(void) 422{ 423#ifdef SMP 424 struct pcpu *pc; 425 426 if (!smp_started) 427 return; 428 429 SLIST_FOREACH(pc, &cpuhead, pc_allcpu) { 430 if (pc != pcpup) { 431 CTR2(KTR_PMAP, "%s: tlb miss UNLOCK of CPU=%d", 432 __func__, pc->pc_cpuid); 433 434 tlb_unlock(pc->pc_booke_tlb_lock); 435 436 CTR1(KTR_PMAP, "%s: unlocked", __func__); 437 } 438 } 439#endif 440} 441 442/* Return number of entries in TLB0. */ 443static __inline void 444tlb0_get_tlbconf(void) 445{ 446 uint32_t tlb0_cfg; 447 448 tlb0_cfg = mfspr(SPR_TLB0CFG); 449 tlb0_entries = tlb0_cfg & TLBCFG_NENTRY_MASK; 450 tlb0_ways = (tlb0_cfg & TLBCFG_ASSOC_MASK) >> TLBCFG_ASSOC_SHIFT; 451 tlb0_entries_per_way = tlb0_entries / tlb0_ways; 452} 453 454/* Initialize pool of kva ptbl buffers. */ 455static void 456ptbl_init(void) 457{ 458 int i; 459 460 CTR3(KTR_PMAP, "%s: s (ptbl_bufs = 0x%08x size 0x%08x)", __func__, 461 (uint32_t)ptbl_bufs, sizeof(struct ptbl_buf) * PTBL_BUFS); 462 CTR3(KTR_PMAP, "%s: s (ptbl_buf_pool_vabase = 0x%08x size = 0x%08x)", 463 __func__, ptbl_buf_pool_vabase, PTBL_BUFS * PTBL_PAGES * PAGE_SIZE); 464 465 mtx_init(&ptbl_buf_freelist_lock, "ptbl bufs lock", NULL, MTX_DEF); 466 TAILQ_INIT(&ptbl_buf_freelist); 467 468 for (i = 0; i < PTBL_BUFS; i++) { 469 ptbl_bufs[i].kva = ptbl_buf_pool_vabase + i * PTBL_PAGES * PAGE_SIZE; 470 TAILQ_INSERT_TAIL(&ptbl_buf_freelist, &ptbl_bufs[i], link); 471 } 472} 473 474/* Get a ptbl_buf from the freelist. */ 475static struct ptbl_buf * 476ptbl_buf_alloc(void) 477{ 478 struct ptbl_buf *buf; 479 480 mtx_lock(&ptbl_buf_freelist_lock); 481 buf = TAILQ_FIRST(&ptbl_buf_freelist); 482 if (buf != NULL) 483 TAILQ_REMOVE(&ptbl_buf_freelist, buf, link); 484 mtx_unlock(&ptbl_buf_freelist_lock); 485 486 CTR2(KTR_PMAP, "%s: buf = %p", __func__, buf); 487 488 return (buf); 489} 490 491/* Return ptbl buff to free pool. */ 492static void 493ptbl_buf_free(struct ptbl_buf *buf) 494{ 495 496 CTR2(KTR_PMAP, "%s: buf = %p", __func__, buf); 497 498 mtx_lock(&ptbl_buf_freelist_lock); 499 TAILQ_INSERT_TAIL(&ptbl_buf_freelist, buf, link); 500 mtx_unlock(&ptbl_buf_freelist_lock); 501} 502 503/* 504 * Search the list of allocated ptbl bufs and find on list of allocated ptbls 505 */ 506static void 507ptbl_free_pmap_ptbl(pmap_t pmap, pte_t *ptbl) 508{ 509 struct ptbl_buf *pbuf; 510 511 CTR2(KTR_PMAP, "%s: ptbl = %p", __func__, ptbl); 512 513 PMAP_LOCK_ASSERT(pmap, MA_OWNED); 514 515 TAILQ_FOREACH(pbuf, &pmap->pm_ptbl_list, link) 516 if (pbuf->kva == (vm_offset_t)ptbl) { 517 /* Remove from pmap ptbl buf list. */ 518 TAILQ_REMOVE(&pmap->pm_ptbl_list, pbuf, link); 519 520 /* Free corresponding ptbl buf. */ 521 ptbl_buf_free(pbuf); 522 break; 523 } 524} 525 526/* Allocate page table. */ 527static pte_t * 528ptbl_alloc(mmu_t mmu, pmap_t pmap, unsigned int pdir_idx) 529{ 530 vm_page_t mtbl[PTBL_PAGES]; 531 vm_page_t m; 532 struct ptbl_buf *pbuf; 533 unsigned int pidx; 534 pte_t *ptbl; 535 int i; 536 537 CTR4(KTR_PMAP, "%s: pmap = %p su = %d pdir_idx = %d", __func__, pmap, 538 (pmap == kernel_pmap), pdir_idx); 539 540 KASSERT((pdir_idx <= (VM_MAXUSER_ADDRESS / PDIR_SIZE)), 541 ("ptbl_alloc: invalid pdir_idx")); 542 KASSERT((pmap->pm_pdir[pdir_idx] == NULL), 543 ("pte_alloc: valid ptbl entry exists!")); 544 545 pbuf = ptbl_buf_alloc(); 546 if (pbuf == NULL) 547 panic("pte_alloc: couldn't alloc kernel virtual memory"); 548 549 ptbl = (pte_t *)pbuf->kva; 550 551 CTR2(KTR_PMAP, "%s: ptbl kva = %p", __func__, ptbl); 552 553 /* Allocate ptbl pages, this will sleep! */ 554 for (i = 0; i < PTBL_PAGES; i++) { 555 pidx = (PTBL_PAGES * pdir_idx) + i; 556 while ((m = vm_page_alloc(NULL, pidx, 557 VM_ALLOC_NOOBJ | VM_ALLOC_WIRED)) == NULL) { 558 559 PMAP_UNLOCK(pmap); 560 vm_page_unlock_queues(); 561 VM_WAIT; 562 vm_page_lock_queues(); 563 PMAP_LOCK(pmap); 564 } 565 mtbl[i] = m; 566 } 567 568 /* Map allocated pages into kernel_pmap. */ 569 mmu_booke_qenter(mmu, (vm_offset_t)ptbl, mtbl, PTBL_PAGES); 570 571 /* Zero whole ptbl. */ 572 bzero((caddr_t)ptbl, PTBL_PAGES * PAGE_SIZE); 573 574 /* Add pbuf to the pmap ptbl bufs list. */ 575 TAILQ_INSERT_TAIL(&pmap->pm_ptbl_list, pbuf, link); 576 577 return (ptbl); 578} 579 580/* Free ptbl pages and invalidate pdir entry. */ 581static void 582ptbl_free(mmu_t mmu, pmap_t pmap, unsigned int pdir_idx) 583{ 584 pte_t *ptbl; 585 vm_paddr_t pa; 586 vm_offset_t va; 587 vm_page_t m; 588 int i; 589 590 CTR4(KTR_PMAP, "%s: pmap = %p su = %d pdir_idx = %d", __func__, pmap, 591 (pmap == kernel_pmap), pdir_idx); 592 593 KASSERT((pdir_idx <= (VM_MAXUSER_ADDRESS / PDIR_SIZE)), 594 ("ptbl_free: invalid pdir_idx")); 595 596 ptbl = pmap->pm_pdir[pdir_idx]; 597 598 CTR2(KTR_PMAP, "%s: ptbl = %p", __func__, ptbl); 599 600 KASSERT((ptbl != NULL), ("ptbl_free: null ptbl")); 601 602 /* 603 * Invalidate the pdir entry as soon as possible, so that other CPUs 604 * don't attempt to look up the page tables we are releasing. 605 */ 606 mtx_lock_spin(&tlbivax_mutex); 607 tlb_miss_lock(); 608 609 pmap->pm_pdir[pdir_idx] = NULL; 610 611 tlb_miss_unlock(); 612 mtx_unlock_spin(&tlbivax_mutex); 613 614 for (i = 0; i < PTBL_PAGES; i++) { 615 va = ((vm_offset_t)ptbl + (i * PAGE_SIZE)); 616 pa = pte_vatopa(mmu, kernel_pmap, va); 617 m = PHYS_TO_VM_PAGE(pa); 618 vm_page_free_zero(m); 619 atomic_subtract_int(&cnt.v_wire_count, 1); 620 mmu_booke_kremove(mmu, va); 621 } 622 623 ptbl_free_pmap_ptbl(pmap, ptbl); 624} 625 626/* 627 * Decrement ptbl pages hold count and attempt to free ptbl pages. 628 * Called when removing pte entry from ptbl. 629 * 630 * Return 1 if ptbl pages were freed. 631 */ 632static int 633ptbl_unhold(mmu_t mmu, pmap_t pmap, unsigned int pdir_idx) 634{ 635 pte_t *ptbl; 636 vm_paddr_t pa; 637 vm_page_t m; 638 int i; 639 640 CTR4(KTR_PMAP, "%s: pmap = %p su = %d pdir_idx = %d", __func__, pmap, 641 (pmap == kernel_pmap), pdir_idx); 642 643 KASSERT((pdir_idx <= (VM_MAXUSER_ADDRESS / PDIR_SIZE)), 644 ("ptbl_unhold: invalid pdir_idx")); 645 KASSERT((pmap != kernel_pmap), 646 ("ptbl_unhold: unholding kernel ptbl!")); 647 648 ptbl = pmap->pm_pdir[pdir_idx]; 649 650 //debugf("ptbl_unhold: ptbl = 0x%08x\n", (u_int32_t)ptbl); 651 KASSERT(((vm_offset_t)ptbl >= VM_MIN_KERNEL_ADDRESS), 652 ("ptbl_unhold: non kva ptbl")); 653 654 /* decrement hold count */ 655 for (i = 0; i < PTBL_PAGES; i++) { 656 pa = pte_vatopa(mmu, kernel_pmap, 657 (vm_offset_t)ptbl + (i * PAGE_SIZE)); 658 m = PHYS_TO_VM_PAGE(pa); 659 m->wire_count--; 660 } 661 662 /* 663 * Free ptbl pages if there are no pte etries in this ptbl. 664 * wire_count has the same value for all ptbl pages, so check the last 665 * page. 666 */ 667 if (m->wire_count == 0) { 668 ptbl_free(mmu, pmap, pdir_idx); 669 670 //debugf("ptbl_unhold: e (freed ptbl)\n"); 671 return (1); 672 } 673 674 return (0); 675} 676 677/* 678 * Increment hold count for ptbl pages. This routine is used when a new pte 679 * entry is being inserted into the ptbl. 680 */ 681static void 682ptbl_hold(mmu_t mmu, pmap_t pmap, unsigned int pdir_idx) 683{ 684 vm_paddr_t pa; 685 pte_t *ptbl; 686 vm_page_t m; 687 int i; 688 689 CTR3(KTR_PMAP, "%s: pmap = %p pdir_idx = %d", __func__, pmap, 690 pdir_idx); 691 692 KASSERT((pdir_idx <= (VM_MAXUSER_ADDRESS / PDIR_SIZE)), 693 ("ptbl_hold: invalid pdir_idx")); 694 KASSERT((pmap != kernel_pmap), 695 ("ptbl_hold: holding kernel ptbl!")); 696 697 ptbl = pmap->pm_pdir[pdir_idx]; 698 699 KASSERT((ptbl != NULL), ("ptbl_hold: null ptbl")); 700 701 for (i = 0; i < PTBL_PAGES; i++) { 702 pa = pte_vatopa(mmu, kernel_pmap, 703 (vm_offset_t)ptbl + (i * PAGE_SIZE)); 704 m = PHYS_TO_VM_PAGE(pa); 705 m->wire_count++; 706 } 707} 708 709/* Allocate pv_entry structure. */ 710pv_entry_t 711pv_alloc(void) 712{ 713 pv_entry_t pv; 714 715 pv_entry_count++; 716 if (pv_entry_count > pv_entry_high_water) 717 pagedaemon_wakeup(); 718 pv = uma_zalloc(pvzone, M_NOWAIT); 719 720 return (pv); 721} 722 723/* Free pv_entry structure. */ 724static __inline void 725pv_free(pv_entry_t pve) 726{ 727 728 pv_entry_count--; 729 uma_zfree(pvzone, pve); 730} 731 732 733/* Allocate and initialize pv_entry structure. */ 734static void 735pv_insert(pmap_t pmap, vm_offset_t va, vm_page_t m) 736{ 737 pv_entry_t pve; 738 739 //int su = (pmap == kernel_pmap); 740 //debugf("pv_insert: s (su = %d pmap = 0x%08x va = 0x%08x m = 0x%08x)\n", su, 741 // (u_int32_t)pmap, va, (u_int32_t)m); 742 743 pve = pv_alloc(); 744 if (pve == NULL) 745 panic("pv_insert: no pv entries!"); 746 747 pve->pv_pmap = pmap; 748 pve->pv_va = va; 749 750 /* add to pv_list */ 751 PMAP_LOCK_ASSERT(pmap, MA_OWNED); 752 mtx_assert(&vm_page_queue_mtx, MA_OWNED); 753 754 TAILQ_INSERT_TAIL(&m->md.pv_list, pve, pv_link); 755 756 //debugf("pv_insert: e\n"); 757} 758 759/* Destroy pv entry. */ 760static void 761pv_remove(pmap_t pmap, vm_offset_t va, vm_page_t m) 762{ 763 pv_entry_t pve; 764 765 //int su = (pmap == kernel_pmap); 766 //debugf("pv_remove: s (su = %d pmap = 0x%08x va = 0x%08x)\n", su, (u_int32_t)pmap, va); 767 768 PMAP_LOCK_ASSERT(pmap, MA_OWNED); 769 mtx_assert(&vm_page_queue_mtx, MA_OWNED); 770 771 /* find pv entry */ 772 TAILQ_FOREACH(pve, &m->md.pv_list, pv_link) { 773 if ((pmap == pve->pv_pmap) && (va == pve->pv_va)) { 774 /* remove from pv_list */ 775 TAILQ_REMOVE(&m->md.pv_list, pve, pv_link); 776 if (TAILQ_EMPTY(&m->md.pv_list)) 777 vm_page_flag_clear(m, PG_WRITEABLE); 778 779 /* free pv entry struct */ 780 pv_free(pve); 781 break; 782 } 783 } 784 785 //debugf("pv_remove: e\n"); 786} 787 788/* 789 * Clean pte entry, try to free page table page if requested. 790 * 791 * Return 1 if ptbl pages were freed, otherwise return 0. 792 */ 793static int 794pte_remove(mmu_t mmu, pmap_t pmap, vm_offset_t va, uint8_t flags) 795{ 796 unsigned int pdir_idx = PDIR_IDX(va); 797 unsigned int ptbl_idx = PTBL_IDX(va); 798 vm_page_t m; 799 pte_t *ptbl; 800 pte_t *pte; 801 802 //int su = (pmap == kernel_pmap); 803 //debugf("pte_remove: s (su = %d pmap = 0x%08x va = 0x%08x flags = %d)\n", 804 // su, (u_int32_t)pmap, va, flags); 805 806 ptbl = pmap->pm_pdir[pdir_idx]; 807 KASSERT(ptbl, ("pte_remove: null ptbl")); 808 809 pte = &ptbl[ptbl_idx]; 810 811 if (pte == NULL || !PTE_ISVALID(pte)) 812 return (0); 813 814 if (PTE_ISWIRED(pte)) 815 pmap->pm_stats.wired_count--; 816 817 /* Handle managed entry. */ 818 if (PTE_ISMANAGED(pte)) { 819 /* Get vm_page_t for mapped pte. */ 820 m = PHYS_TO_VM_PAGE(PTE_PA(pte)); 821 822 if (PTE_ISMODIFIED(pte)) 823 vm_page_dirty(m); 824 825 if (PTE_ISREFERENCED(pte)) 826 vm_page_flag_set(m, PG_REFERENCED); 827 828 pv_remove(pmap, va, m); 829 } 830 831 mtx_lock_spin(&tlbivax_mutex); 832 tlb_miss_lock(); 833 834 tlb0_flush_entry(va); 835 pte->flags = 0; 836 pte->rpn = 0; 837 838 tlb_miss_unlock(); 839 mtx_unlock_spin(&tlbivax_mutex); 840 841 pmap->pm_stats.resident_count--; 842 843 if (flags & PTBL_UNHOLD) { 844 //debugf("pte_remove: e (unhold)\n"); 845 return (ptbl_unhold(mmu, pmap, pdir_idx)); 846 } 847 848 //debugf("pte_remove: e\n"); 849 return (0); 850} 851 852/* 853 * Insert PTE for a given page and virtual address. 854 */ 855static void 856pte_enter(mmu_t mmu, pmap_t pmap, vm_page_t m, vm_offset_t va, uint32_t flags) 857{ 858 unsigned int pdir_idx = PDIR_IDX(va); 859 unsigned int ptbl_idx = PTBL_IDX(va); 860 pte_t *ptbl, *pte; 861 862 CTR4(KTR_PMAP, "%s: su = %d pmap = %p va = %p", __func__, 863 pmap == kernel_pmap, pmap, va); 864 865 /* Get the page table pointer. */ 866 ptbl = pmap->pm_pdir[pdir_idx]; 867 868 if (ptbl == NULL) { 869 /* Allocate page table pages. */ 870 ptbl = ptbl_alloc(mmu, pmap, pdir_idx); 871 } else { 872 /* 873 * Check if there is valid mapping for requested 874 * va, if there is, remove it. 875 */ 876 pte = &pmap->pm_pdir[pdir_idx][ptbl_idx]; 877 if (PTE_ISVALID(pte)) { 878 pte_remove(mmu, pmap, va, PTBL_HOLD); 879 } else { 880 /* 881 * pte is not used, increment hold count 882 * for ptbl pages. 883 */ 884 if (pmap != kernel_pmap) 885 ptbl_hold(mmu, pmap, pdir_idx); 886 } 887 } 888 889 /* 890 * Insert pv_entry into pv_list for mapped page if part of managed 891 * memory. 892 */ 893 if ((m->flags & PG_FICTITIOUS) == 0) { 894 if ((m->flags & PG_UNMANAGED) == 0) { 895 flags |= PTE_MANAGED; 896 897 /* Create and insert pv entry. */ 898 pv_insert(pmap, va, m); 899 } 900 } 901 902 pmap->pm_stats.resident_count++; 903 904 mtx_lock_spin(&tlbivax_mutex); 905 tlb_miss_lock(); 906 907 tlb0_flush_entry(va); 908 if (pmap->pm_pdir[pdir_idx] == NULL) { 909 /* 910 * If we just allocated a new page table, hook it in 911 * the pdir. 912 */ 913 pmap->pm_pdir[pdir_idx] = ptbl; 914 } 915 pte = &(pmap->pm_pdir[pdir_idx][ptbl_idx]); 916 pte->rpn = VM_PAGE_TO_PHYS(m) & ~PTE_PA_MASK; 917 pte->flags |= (PTE_VALID | flags); 918 919 tlb_miss_unlock(); 920 mtx_unlock_spin(&tlbivax_mutex); 921} 922 923/* Return the pa for the given pmap/va. */ 924static vm_paddr_t 925pte_vatopa(mmu_t mmu, pmap_t pmap, vm_offset_t va) 926{ 927 vm_paddr_t pa = 0; 928 pte_t *pte; 929 930 pte = pte_find(mmu, pmap, va); 931 if ((pte != NULL) && PTE_ISVALID(pte)) 932 pa = (PTE_PA(pte) | (va & PTE_PA_MASK)); 933 return (pa); 934} 935 936/* Get a pointer to a PTE in a page table. */ 937static pte_t * 938pte_find(mmu_t mmu, pmap_t pmap, vm_offset_t va) 939{ 940 unsigned int pdir_idx = PDIR_IDX(va); 941 unsigned int ptbl_idx = PTBL_IDX(va); 942 943 KASSERT((pmap != NULL), ("pte_find: invalid pmap")); 944 945 if (pmap->pm_pdir[pdir_idx]) 946 return (&(pmap->pm_pdir[pdir_idx][ptbl_idx])); 947 948 return (NULL); 949} 950 951/**************************************************************************/ 952/* PMAP related */ 953/**************************************************************************/ 954 955/* 956 * This is called during e500_init, before the system is really initialized. 957 */ 958static void 959mmu_booke_bootstrap(mmu_t mmu, vm_offset_t start, vm_offset_t kernelend) 960{ 961 vm_offset_t phys_kernelend; 962 struct mem_region *mp, *mp1; 963 int cnt, i, j; 964 u_int s, e, sz; 965 u_int phys_avail_count; 966 vm_size_t physsz, hwphyssz, kstack0_sz; 967 vm_offset_t kernel_pdir, kstack0, va; 968 vm_paddr_t kstack0_phys; 969 void *dpcpu; 970 pte_t *pte; 971 972 debugf("mmu_booke_bootstrap: entered\n"); 973 974 /* Initialize invalidation mutex */ 975 mtx_init(&tlbivax_mutex, "tlbivax", NULL, MTX_SPIN); 976 977 /* Read TLB0 size and associativity. */ 978 tlb0_get_tlbconf(); 979 980 /* Align kernel start and end address (kernel image). */ 981 kernstart = trunc_page(start); 982 data_start = round_page(kernelend); 983 kernsize = data_start - kernstart; 984 985 data_end = data_start; 986 987 /* Allocate space for the message buffer. */ 988 msgbufp = (struct msgbuf *)data_end; 989 data_end += MSGBUF_SIZE; 990 debugf(" msgbufp at 0x%08x end = 0x%08x\n", (uint32_t)msgbufp, 991 data_end); 992 993 data_end = round_page(data_end); 994 995 /* Allocate the dynamic per-cpu area. */ 996 dpcpu = (void *)data_end; 997 data_end += DPCPU_SIZE; 998 dpcpu_init(dpcpu, 0); 999 1000 /* Allocate space for ptbl_bufs. */ 1001 ptbl_bufs = (struct ptbl_buf *)data_end; 1002 data_end += sizeof(struct ptbl_buf) * PTBL_BUFS; 1003 debugf(" ptbl_bufs at 0x%08x end = 0x%08x\n", (uint32_t)ptbl_bufs, 1004 data_end); 1005 1006 data_end = round_page(data_end); 1007 1008 /* Allocate PTE tables for kernel KVA. */ 1009 kernel_pdir = data_end; 1010 kernel_ptbls = (VM_MAX_KERNEL_ADDRESS - VM_MIN_KERNEL_ADDRESS + 1011 PDIR_SIZE - 1) / PDIR_SIZE; 1012 data_end += kernel_ptbls * PTBL_PAGES * PAGE_SIZE; 1013 debugf(" kernel ptbls: %d\n", kernel_ptbls); 1014 debugf(" kernel pdir at 0x%08x end = 0x%08x\n", kernel_pdir, data_end); 1015 1016 debugf(" data_end: 0x%08x\n", data_end); 1017 if (data_end - kernstart > 0x1000000) { 1018 data_end = (data_end + 0x3fffff) & ~0x3fffff; 1019 tlb1_mapin_region(kernstart + 0x1000000, 1020 kernload + 0x1000000, data_end - kernstart - 0x1000000); 1021 } else 1022 data_end = (data_end + 0xffffff) & ~0xffffff; 1023 1024 debugf(" updated data_end: 0x%08x\n", data_end); 1025 1026 kernsize += data_end - data_start; 1027 1028 /* 1029 * Clear the structures - note we can only do it safely after the 1030 * possible additional TLB1 translations are in place (above) so that 1031 * all range up to the currently calculated 'data_end' is covered. 1032 */ 1033 memset((void *)ptbl_bufs, 0, sizeof(struct ptbl_buf) * PTBL_SIZE); 1034 memset((void *)kernel_pdir, 0, kernel_ptbls * PTBL_PAGES * PAGE_SIZE); 1035 1036 /*******************************************************/ 1037 /* Set the start and end of kva. */ 1038 /*******************************************************/ 1039 virtual_avail = round_page(data_end); 1040 virtual_end = VM_MAX_KERNEL_ADDRESS; 1041 1042 /* Allocate KVA space for page zero/copy operations. */ 1043 zero_page_va = virtual_avail; 1044 virtual_avail += PAGE_SIZE; 1045 zero_page_idle_va = virtual_avail; 1046 virtual_avail += PAGE_SIZE; 1047 copy_page_src_va = virtual_avail; 1048 virtual_avail += PAGE_SIZE; 1049 copy_page_dst_va = virtual_avail; 1050 virtual_avail += PAGE_SIZE; 1051 debugf("zero_page_va = 0x%08x\n", zero_page_va); 1052 debugf("zero_page_idle_va = 0x%08x\n", zero_page_idle_va); 1053 debugf("copy_page_src_va = 0x%08x\n", copy_page_src_va); 1054 debugf("copy_page_dst_va = 0x%08x\n", copy_page_dst_va); 1055 1056 /* Initialize page zero/copy mutexes. */ 1057 mtx_init(&zero_page_mutex, "mmu_booke_zero_page", NULL, MTX_DEF); 1058 mtx_init(©_page_mutex, "mmu_booke_copy_page", NULL, MTX_DEF); 1059 1060 /* Allocate KVA space for ptbl bufs. */ 1061 ptbl_buf_pool_vabase = virtual_avail; 1062 virtual_avail += PTBL_BUFS * PTBL_PAGES * PAGE_SIZE; 1063 debugf("ptbl_buf_pool_vabase = 0x%08x end = 0x%08x\n", 1064 ptbl_buf_pool_vabase, virtual_avail); 1065 1066 /* Calculate corresponding physical addresses for the kernel region. */ 1067 phys_kernelend = kernload + kernsize; 1068 debugf("kernel image and allocated data:\n"); 1069 debugf(" kernload = 0x%08x\n", kernload); 1070 debugf(" kernstart = 0x%08x\n", kernstart); 1071 debugf(" kernsize = 0x%08x\n", kernsize); 1072 1073 if (sizeof(phys_avail) / sizeof(phys_avail[0]) < availmem_regions_sz) 1074 panic("mmu_booke_bootstrap: phys_avail too small"); 1075 1076 /* 1077 * Remove kernel physical address range from avail regions list. Page 1078 * align all regions. Non-page aligned memory isn't very interesting 1079 * to us. Also, sort the entries for ascending addresses. 1080 */ 1081 1082 /* Retrieve phys/avail mem regions */ 1083 mem_regions(&physmem_regions, &physmem_regions_sz, 1084 &availmem_regions, &availmem_regions_sz); 1085 sz = 0; 1086 cnt = availmem_regions_sz; 1087 debugf("processing avail regions:\n"); 1088 for (mp = availmem_regions; mp->mr_size; mp++) { 1089 s = mp->mr_start; 1090 e = mp->mr_start + mp->mr_size; 1091 debugf(" %08x-%08x -> ", s, e); 1092 /* Check whether this region holds all of the kernel. */ 1093 if (s < kernload && e > phys_kernelend) { 1094 availmem_regions[cnt].mr_start = phys_kernelend; 1095 availmem_regions[cnt++].mr_size = e - phys_kernelend; 1096 e = kernload; 1097 } 1098 /* Look whether this regions starts within the kernel. */ 1099 if (s >= kernload && s < phys_kernelend) { 1100 if (e <= phys_kernelend) 1101 goto empty; 1102 s = phys_kernelend; 1103 } 1104 /* Now look whether this region ends within the kernel. */ 1105 if (e > kernload && e <= phys_kernelend) { 1106 if (s >= kernload) 1107 goto empty; 1108 e = kernload; 1109 } 1110 /* Now page align the start and size of the region. */ 1111 s = round_page(s); 1112 e = trunc_page(e); 1113 if (e < s) 1114 e = s; 1115 sz = e - s; 1116 debugf("%08x-%08x = %x\n", s, e, sz); 1117 1118 /* Check whether some memory is left here. */ 1119 if (sz == 0) { 1120 empty: 1121 memmove(mp, mp + 1, 1122 (cnt - (mp - availmem_regions)) * sizeof(*mp)); 1123 cnt--; 1124 mp--; 1125 continue; 1126 } 1127 1128 /* Do an insertion sort. */ 1129 for (mp1 = availmem_regions; mp1 < mp; mp1++) 1130 if (s < mp1->mr_start) 1131 break; 1132 if (mp1 < mp) { 1133 memmove(mp1 + 1, mp1, (char *)mp - (char *)mp1); 1134 mp1->mr_start = s; 1135 mp1->mr_size = sz; 1136 } else { 1137 mp->mr_start = s; 1138 mp->mr_size = sz; 1139 } 1140 } 1141 availmem_regions_sz = cnt; 1142 1143 /*******************************************************/ 1144 /* Steal physical memory for kernel stack from the end */ 1145 /* of the first avail region */ 1146 /*******************************************************/ 1147 kstack0_sz = KSTACK_PAGES * PAGE_SIZE; 1148 kstack0_phys = availmem_regions[0].mr_start + 1149 availmem_regions[0].mr_size; 1150 kstack0_phys -= kstack0_sz; 1151 availmem_regions[0].mr_size -= kstack0_sz; 1152 1153 /*******************************************************/ 1154 /* Fill in phys_avail table, based on availmem_regions */ 1155 /*******************************************************/ 1156 phys_avail_count = 0; 1157 physsz = 0; 1158 hwphyssz = 0; 1159 TUNABLE_ULONG_FETCH("hw.physmem", (u_long *) &hwphyssz); 1160 1161 debugf("fill in phys_avail:\n"); 1162 for (i = 0, j = 0; i < availmem_regions_sz; i++, j += 2) { 1163 1164 debugf(" region: 0x%08x - 0x%08x (0x%08x)\n", 1165 availmem_regions[i].mr_start, 1166 availmem_regions[i].mr_start + 1167 availmem_regions[i].mr_size, 1168 availmem_regions[i].mr_size); 1169 1170 if (hwphyssz != 0 && 1171 (physsz + availmem_regions[i].mr_size) >= hwphyssz) { 1172 debugf(" hw.physmem adjust\n"); 1173 if (physsz < hwphyssz) { 1174 phys_avail[j] = availmem_regions[i].mr_start; 1175 phys_avail[j + 1] = 1176 availmem_regions[i].mr_start + 1177 hwphyssz - physsz; 1178 physsz = hwphyssz; 1179 phys_avail_count++; 1180 } 1181 break; 1182 } 1183 1184 phys_avail[j] = availmem_regions[i].mr_start; 1185 phys_avail[j + 1] = availmem_regions[i].mr_start + 1186 availmem_regions[i].mr_size; 1187 phys_avail_count++; 1188 physsz += availmem_regions[i].mr_size; 1189 } 1190 physmem = btoc(physsz); 1191 1192 /* Calculate the last available physical address. */ 1193 for (i = 0; phys_avail[i + 2] != 0; i += 2) 1194 ; 1195 Maxmem = powerpc_btop(phys_avail[i + 1]); 1196 1197 debugf("Maxmem = 0x%08lx\n", Maxmem); 1198 debugf("phys_avail_count = %d\n", phys_avail_count); 1199 debugf("physsz = 0x%08x physmem = %ld (0x%08lx)\n", physsz, physmem, 1200 physmem); 1201 1202 /*******************************************************/ 1203 /* Initialize (statically allocated) kernel pmap. */ 1204 /*******************************************************/ 1205 PMAP_LOCK_INIT(kernel_pmap); 1206 kptbl_min = VM_MIN_KERNEL_ADDRESS / PDIR_SIZE; 1207 1208 debugf("kernel_pmap = 0x%08x\n", (uint32_t)kernel_pmap); 1209 debugf("kptbl_min = %d, kernel_ptbls = %d\n", kptbl_min, kernel_ptbls); 1210 debugf("kernel pdir range: 0x%08x - 0x%08x\n", 1211 kptbl_min * PDIR_SIZE, (kptbl_min + kernel_ptbls) * PDIR_SIZE - 1); 1212 1213 /* Initialize kernel pdir */ 1214 for (i = 0; i < kernel_ptbls; i++) 1215 kernel_pmap->pm_pdir[kptbl_min + i] = 1216 (pte_t *)(kernel_pdir + (i * PAGE_SIZE * PTBL_PAGES)); 1217 1218 for (i = 0; i < MAXCPU; i++) { 1219 kernel_pmap->pm_tid[i] = TID_KERNEL; 1220 1221 /* Initialize each CPU's tidbusy entry 0 with kernel_pmap */ 1222 tidbusy[i][0] = kernel_pmap; 1223 } 1224 1225 /* 1226 * Fill in PTEs covering kernel code and data. They are not required 1227 * for address translation, as this area is covered by static TLB1 1228 * entries, but for pte_vatopa() to work correctly with kernel area 1229 * addresses. 1230 */ 1231 for (va = KERNBASE; va < data_end; va += PAGE_SIZE) { 1232 pte = &(kernel_pmap->pm_pdir[PDIR_IDX(va)][PTBL_IDX(va)]); 1233 pte->rpn = kernload + (va - KERNBASE); 1234 pte->flags = PTE_M | PTE_SR | PTE_SW | PTE_SX | PTE_WIRED | 1235 PTE_VALID; 1236 } 1237 /* Mark kernel_pmap active on all CPUs */ 1238 kernel_pmap->pm_active = ~0; 1239 1240 /*******************************************************/ 1241 /* Final setup */ 1242 /*******************************************************/ 1243 1244 /* Enter kstack0 into kernel map, provide guard page */ 1245 kstack0 = virtual_avail + KSTACK_GUARD_PAGES * PAGE_SIZE; 1246 thread0.td_kstack = kstack0; 1247 thread0.td_kstack_pages = KSTACK_PAGES; 1248 1249 debugf("kstack_sz = 0x%08x\n", kstack0_sz); 1250 debugf("kstack0_phys at 0x%08x - 0x%08x\n", 1251 kstack0_phys, kstack0_phys + kstack0_sz); 1252 debugf("kstack0 at 0x%08x - 0x%08x\n", kstack0, kstack0 + kstack0_sz); 1253 1254 virtual_avail += KSTACK_GUARD_PAGES * PAGE_SIZE + kstack0_sz; 1255 for (i = 0; i < KSTACK_PAGES; i++) { 1256 mmu_booke_kenter(mmu, kstack0, kstack0_phys); 1257 kstack0 += PAGE_SIZE; 1258 kstack0_phys += PAGE_SIZE; 1259 } 1260 1261 debugf("virtual_avail = %08x\n", virtual_avail); 1262 debugf("virtual_end = %08x\n", virtual_end); 1263 1264 debugf("mmu_booke_bootstrap: exit\n"); 1265} 1266 1267void 1268pmap_bootstrap_ap(volatile uint32_t *trcp __unused) 1269{ 1270 int i; 1271 1272 /* 1273 * Finish TLB1 configuration: the BSP already set up its TLB1 and we 1274 * have the snapshot of its contents in the s/w tlb1[] table, so use 1275 * these values directly to (re)program AP's TLB1 hardware. 1276 */ 1277 for (i = 0; i < tlb1_idx; i ++) { 1278 /* Skip invalid entries */ 1279 if (!(tlb1[i].mas1 & MAS1_VALID)) 1280 continue; 1281 1282 tlb1_write_entry(i); 1283 } 1284 1285 set_mas4_defaults(); 1286} 1287 1288/* 1289 * Get the physical page address for the given pmap/virtual address. 1290 */ 1291static vm_paddr_t 1292mmu_booke_extract(mmu_t mmu, pmap_t pmap, vm_offset_t va) 1293{ 1294 vm_paddr_t pa; 1295 1296 PMAP_LOCK(pmap); 1297 pa = pte_vatopa(mmu, pmap, va); 1298 PMAP_UNLOCK(pmap); 1299 1300 return (pa); 1301} 1302 1303/* 1304 * Extract the physical page address associated with the given 1305 * kernel virtual address. 1306 */ 1307static vm_paddr_t 1308mmu_booke_kextract(mmu_t mmu, vm_offset_t va) 1309{ 1310 1311 return (pte_vatopa(mmu, kernel_pmap, va)); 1312} 1313 1314/* 1315 * Initialize the pmap module. 1316 * Called by vm_init, to initialize any structures that the pmap 1317 * system needs to map virtual memory. 1318 */ 1319static void 1320mmu_booke_init(mmu_t mmu) 1321{ 1322 int shpgperproc = PMAP_SHPGPERPROC; 1323 1324 /* 1325 * Initialize the address space (zone) for the pv entries. Set a 1326 * high water mark so that the system can recover from excessive 1327 * numbers of pv entries. 1328 */ 1329 pvzone = uma_zcreate("PV ENTRY", sizeof(struct pv_entry), NULL, NULL, 1330 NULL, NULL, UMA_ALIGN_PTR, UMA_ZONE_VM | UMA_ZONE_NOFREE); 1331 1332 TUNABLE_INT_FETCH("vm.pmap.shpgperproc", &shpgperproc); 1333 pv_entry_max = shpgperproc * maxproc + cnt.v_page_count; 1334 1335 TUNABLE_INT_FETCH("vm.pmap.pv_entries", &pv_entry_max); 1336 pv_entry_high_water = 9 * (pv_entry_max / 10); 1337 1338 uma_zone_set_obj(pvzone, &pvzone_obj, pv_entry_max); 1339 1340 /* Pre-fill pvzone with initial number of pv entries. */ 1341 uma_prealloc(pvzone, PV_ENTRY_ZONE_MIN); 1342 1343 /* Initialize ptbl allocation. */ 1344 ptbl_init(); 1345} 1346 1347/* 1348 * Map a list of wired pages into kernel virtual address space. This is 1349 * intended for temporary mappings which do not need page modification or 1350 * references recorded. Existing mappings in the region are overwritten. 1351 */ 1352static void 1353mmu_booke_qenter(mmu_t mmu, vm_offset_t sva, vm_page_t *m, int count) 1354{ 1355 vm_offset_t va; 1356 1357 va = sva; 1358 while (count-- > 0) { 1359 mmu_booke_kenter(mmu, va, VM_PAGE_TO_PHYS(*m)); 1360 va += PAGE_SIZE; 1361 m++; 1362 } 1363} 1364 1365/* 1366 * Remove page mappings from kernel virtual address space. Intended for 1367 * temporary mappings entered by mmu_booke_qenter. 1368 */ 1369static void 1370mmu_booke_qremove(mmu_t mmu, vm_offset_t sva, int count) 1371{ 1372 vm_offset_t va; 1373 1374 va = sva; 1375 while (count-- > 0) { 1376 mmu_booke_kremove(mmu, va); 1377 va += PAGE_SIZE; 1378 } 1379} 1380 1381/* 1382 * Map a wired page into kernel virtual address space. 1383 */ 1384static void 1385mmu_booke_kenter(mmu_t mmu, vm_offset_t va, vm_offset_t pa) 1386{ 1387 unsigned int pdir_idx = PDIR_IDX(va); 1388 unsigned int ptbl_idx = PTBL_IDX(va); 1389 uint32_t flags; 1390 pte_t *pte; 1391 1392 KASSERT(((va >= VM_MIN_KERNEL_ADDRESS) && 1393 (va <= VM_MAX_KERNEL_ADDRESS)), ("mmu_booke_kenter: invalid va")); 1394 1395 flags = 0; 1396 flags |= (PTE_SR | PTE_SW | PTE_SX | PTE_WIRED | PTE_VALID); 1397 flags |= PTE_M; 1398 1399 pte = &(kernel_pmap->pm_pdir[pdir_idx][ptbl_idx]); 1400 1401 mtx_lock_spin(&tlbivax_mutex); 1402 tlb_miss_lock(); 1403 1404 if (PTE_ISVALID(pte)) { 1405 1406 CTR1(KTR_PMAP, "%s: replacing entry!", __func__); 1407 1408 /* Flush entry from TLB0 */ 1409 tlb0_flush_entry(va); 1410 } 1411 1412 pte->rpn = pa & ~PTE_PA_MASK; 1413 pte->flags = flags; 1414 1415 //debugf("mmu_booke_kenter: pdir_idx = %d ptbl_idx = %d va=0x%08x " 1416 // "pa=0x%08x rpn=0x%08x flags=0x%08x\n", 1417 // pdir_idx, ptbl_idx, va, pa, pte->rpn, pte->flags); 1418 1419 /* Flush the real memory from the instruction cache. */ 1420 if ((flags & (PTE_I | PTE_G)) == 0) { 1421 __syncicache((void *)va, PAGE_SIZE); 1422 } 1423 1424 tlb_miss_unlock(); 1425 mtx_unlock_spin(&tlbivax_mutex); 1426} 1427 1428/* 1429 * Remove a page from kernel page table. 1430 */ 1431static void 1432mmu_booke_kremove(mmu_t mmu, vm_offset_t va) 1433{ 1434 unsigned int pdir_idx = PDIR_IDX(va); 1435 unsigned int ptbl_idx = PTBL_IDX(va); 1436 pte_t *pte; 1437 1438// CTR2(KTR_PMAP,("%s: s (va = 0x%08x)\n", __func__, va)); 1439 1440 KASSERT(((va >= VM_MIN_KERNEL_ADDRESS) && 1441 (va <= VM_MAX_KERNEL_ADDRESS)), 1442 ("mmu_booke_kremove: invalid va")); 1443 1444 pte = &(kernel_pmap->pm_pdir[pdir_idx][ptbl_idx]); 1445 1446 if (!PTE_ISVALID(pte)) { 1447 1448 CTR1(KTR_PMAP, "%s: invalid pte", __func__); 1449 1450 return; 1451 } 1452 1453 mtx_lock_spin(&tlbivax_mutex); 1454 tlb_miss_lock(); 1455 1456 /* Invalidate entry in TLB0, update PTE. */ 1457 tlb0_flush_entry(va); 1458 pte->flags = 0; 1459 pte->rpn = 0; 1460 1461 tlb_miss_unlock(); 1462 mtx_unlock_spin(&tlbivax_mutex); 1463} 1464 1465/* 1466 * Initialize pmap associated with process 0. 1467 */ 1468static void 1469mmu_booke_pinit0(mmu_t mmu, pmap_t pmap) 1470{ 1471 1472 mmu_booke_pinit(mmu, pmap); 1473 PCPU_SET(curpmap, pmap); 1474} 1475 1476/* 1477 * Initialize a preallocated and zeroed pmap structure, 1478 * such as one in a vmspace structure. 1479 */ 1480static void 1481mmu_booke_pinit(mmu_t mmu, pmap_t pmap) 1482{ 1483 int i; 1484 1485 CTR4(KTR_PMAP, "%s: pmap = %p, proc %d '%s'", __func__, pmap, 1486 curthread->td_proc->p_pid, curthread->td_proc->p_comm); 1487 1488 KASSERT((pmap != kernel_pmap), ("pmap_pinit: initializing kernel_pmap")); 1489 1490 PMAP_LOCK_INIT(pmap); 1491 for (i = 0; i < MAXCPU; i++) 1492 pmap->pm_tid[i] = TID_NONE; 1493 pmap->pm_active = 0; 1494 bzero(&pmap->pm_stats, sizeof(pmap->pm_stats)); 1495 bzero(&pmap->pm_pdir, sizeof(pte_t *) * PDIR_NENTRIES); 1496 TAILQ_INIT(&pmap->pm_ptbl_list); 1497} 1498 1499/* 1500 * Release any resources held by the given physical map. 1501 * Called when a pmap initialized by mmu_booke_pinit is being released. 1502 * Should only be called if the map contains no valid mappings. 1503 */ 1504static void 1505mmu_booke_release(mmu_t mmu, pmap_t pmap) 1506{ 1507 1508 KASSERT(pmap->pm_stats.resident_count == 0, 1509 ("pmap_release: pmap resident count %ld != 0", 1510 pmap->pm_stats.resident_count)); 1511 1512 PMAP_LOCK_DESTROY(pmap); 1513} 1514 1515/* 1516 * Insert the given physical page at the specified virtual address in the 1517 * target physical map with the protection requested. If specified the page 1518 * will be wired down. 1519 */ 1520static void 1521mmu_booke_enter(mmu_t mmu, pmap_t pmap, vm_offset_t va, vm_page_t m, 1522 vm_prot_t prot, boolean_t wired) 1523{ 1524 1525 vm_page_lock_queues(); 1526 PMAP_LOCK(pmap); 1527 mmu_booke_enter_locked(mmu, pmap, va, m, prot, wired); 1528 vm_page_unlock_queues(); 1529 PMAP_UNLOCK(pmap); 1530} 1531 1532static void 1533mmu_booke_enter_locked(mmu_t mmu, pmap_t pmap, vm_offset_t va, vm_page_t m, 1534 vm_prot_t prot, boolean_t wired) 1535{ 1536 pte_t *pte; 1537 vm_paddr_t pa; 1538 uint32_t flags; 1539 int su, sync; 1540 1541 pa = VM_PAGE_TO_PHYS(m); 1542 su = (pmap == kernel_pmap); 1543 sync = 0; 1544 1545 //debugf("mmu_booke_enter_locked: s (pmap=0x%08x su=%d tid=%d m=0x%08x va=0x%08x " 1546 // "pa=0x%08x prot=0x%08x wired=%d)\n", 1547 // (u_int32_t)pmap, su, pmap->pm_tid, 1548 // (u_int32_t)m, va, pa, prot, wired); 1549 1550 if (su) { 1551 KASSERT(((va >= virtual_avail) && 1552 (va <= VM_MAX_KERNEL_ADDRESS)), 1553 ("mmu_booke_enter_locked: kernel pmap, non kernel va")); 1554 } else { 1555 KASSERT((va <= VM_MAXUSER_ADDRESS), 1556 ("mmu_booke_enter_locked: user pmap, non user va")); 1557 } 1558 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) != 0 || 1559 (m->oflags & VPO_BUSY) != 0 || VM_OBJECT_LOCKED(m->object), 1560 ("mmu_booke_enter_locked: page %p is not busy", m)); 1561 1562 PMAP_LOCK_ASSERT(pmap, MA_OWNED); 1563 1564 /* 1565 * If there is an existing mapping, and the physical address has not 1566 * changed, must be protection or wiring change. 1567 */ 1568 if (((pte = pte_find(mmu, pmap, va)) != NULL) && 1569 (PTE_ISVALID(pte)) && (PTE_PA(pte) == pa)) { 1570 1571 /* 1572 * Before actually updating pte->flags we calculate and 1573 * prepare its new value in a helper var. 1574 */ 1575 flags = pte->flags; 1576 flags &= ~(PTE_UW | PTE_UX | PTE_SW | PTE_SX | PTE_MODIFIED); 1577 1578 /* Wiring change, just update stats. */ 1579 if (wired) { 1580 if (!PTE_ISWIRED(pte)) { 1581 flags |= PTE_WIRED; 1582 pmap->pm_stats.wired_count++; 1583 } 1584 } else { 1585 if (PTE_ISWIRED(pte)) { 1586 flags &= ~PTE_WIRED; 1587 pmap->pm_stats.wired_count--; 1588 } 1589 } 1590 1591 if (prot & VM_PROT_WRITE) { 1592 /* Add write permissions. */ 1593 flags |= PTE_SW; 1594 if (!su) 1595 flags |= PTE_UW; 1596 1597 if ((flags & PTE_MANAGED) != 0) 1598 vm_page_flag_set(m, PG_WRITEABLE); 1599 } else { 1600 /* Handle modified pages, sense modify status. */ 1601 1602 /* 1603 * The PTE_MODIFIED flag could be set by underlying 1604 * TLB misses since we last read it (above), possibly 1605 * other CPUs could update it so we check in the PTE 1606 * directly rather than rely on that saved local flags 1607 * copy. 1608 */ 1609 if (PTE_ISMODIFIED(pte)) 1610 vm_page_dirty(m); 1611 } 1612 1613 if (prot & VM_PROT_EXECUTE) { 1614 flags |= PTE_SX; 1615 if (!su) 1616 flags |= PTE_UX; 1617 1618 /* 1619 * Check existing flags for execute permissions: if we 1620 * are turning execute permissions on, icache should 1621 * be flushed. 1622 */ 1623 if ((pte->flags & (PTE_UX | PTE_SX)) == 0) 1624 sync++; 1625 } 1626 1627 flags &= ~PTE_REFERENCED; 1628 1629 /* 1630 * The new flags value is all calculated -- only now actually 1631 * update the PTE. 1632 */ 1633 mtx_lock_spin(&tlbivax_mutex); 1634 tlb_miss_lock(); 1635 1636 tlb0_flush_entry(va); 1637 pte->flags = flags; 1638 1639 tlb_miss_unlock(); 1640 mtx_unlock_spin(&tlbivax_mutex); 1641 1642 } else { 1643 /* 1644 * If there is an existing mapping, but it's for a different 1645 * physical address, pte_enter() will delete the old mapping. 1646 */ 1647 //if ((pte != NULL) && PTE_ISVALID(pte)) 1648 // debugf("mmu_booke_enter_locked: replace\n"); 1649 //else 1650 // debugf("mmu_booke_enter_locked: new\n"); 1651 1652 /* Now set up the flags and install the new mapping. */ 1653 flags = (PTE_SR | PTE_VALID); 1654 flags |= PTE_M; 1655 1656 if (!su) 1657 flags |= PTE_UR; 1658 1659 if (prot & VM_PROT_WRITE) { 1660 flags |= PTE_SW; 1661 if (!su) 1662 flags |= PTE_UW; 1663 1664 if ((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0) 1665 vm_page_flag_set(m, PG_WRITEABLE); 1666 } 1667 1668 if (prot & VM_PROT_EXECUTE) { 1669 flags |= PTE_SX; 1670 if (!su) 1671 flags |= PTE_UX; 1672 } 1673 1674 /* If its wired update stats. */ 1675 if (wired) { 1676 pmap->pm_stats.wired_count++; 1677 flags |= PTE_WIRED; 1678 } 1679 1680 pte_enter(mmu, pmap, m, va, flags); 1681 1682 /* Flush the real memory from the instruction cache. */ 1683 if (prot & VM_PROT_EXECUTE) 1684 sync++; 1685 } 1686 1687 if (sync && (su || pmap == PCPU_GET(curpmap))) { 1688 __syncicache((void *)va, PAGE_SIZE); 1689 sync = 0; 1690 } 1691} 1692 1693/* 1694 * Maps a sequence of resident pages belonging to the same object. 1695 * The sequence begins with the given page m_start. This page is 1696 * mapped at the given virtual address start. Each subsequent page is 1697 * mapped at a virtual address that is offset from start by the same 1698 * amount as the page is offset from m_start within the object. The 1699 * last page in the sequence is the page with the largest offset from 1700 * m_start that can be mapped at a virtual address less than the given 1701 * virtual address end. Not every virtual page between start and end 1702 * is mapped; only those for which a resident page exists with the 1703 * corresponding offset from m_start are mapped. 1704 */ 1705static void 1706mmu_booke_enter_object(mmu_t mmu, pmap_t pmap, vm_offset_t start, 1707 vm_offset_t end, vm_page_t m_start, vm_prot_t prot) 1708{ 1709 vm_page_t m; 1710 vm_pindex_t diff, psize; 1711 1712 psize = atop(end - start); 1713 m = m_start; 1714 vm_page_lock_queues(); 1715 PMAP_LOCK(pmap); 1716 while (m != NULL && (diff = m->pindex - m_start->pindex) < psize) { 1717 mmu_booke_enter_locked(mmu, pmap, start + ptoa(diff), m, 1718 prot & (VM_PROT_READ | VM_PROT_EXECUTE), FALSE); 1719 m = TAILQ_NEXT(m, listq); 1720 } 1721 vm_page_unlock_queues(); 1722 PMAP_UNLOCK(pmap); 1723} 1724 1725static void 1726mmu_booke_enter_quick(mmu_t mmu, pmap_t pmap, vm_offset_t va, vm_page_t m, 1727 vm_prot_t prot) 1728{ 1729 1730 vm_page_lock_queues(); 1731 PMAP_LOCK(pmap); 1732 mmu_booke_enter_locked(mmu, pmap, va, m, 1733 prot & (VM_PROT_READ | VM_PROT_EXECUTE), FALSE); 1734 vm_page_unlock_queues(); 1735 PMAP_UNLOCK(pmap); 1736} 1737 1738/* 1739 * Remove the given range of addresses from the specified map. 1740 * 1741 * It is assumed that the start and end are properly rounded to the page size. 1742 */ 1743static void 1744mmu_booke_remove(mmu_t mmu, pmap_t pmap, vm_offset_t va, vm_offset_t endva) 1745{ 1746 pte_t *pte; 1747 uint8_t hold_flag; 1748 1749 int su = (pmap == kernel_pmap); 1750 1751 //debugf("mmu_booke_remove: s (su = %d pmap=0x%08x tid=%d va=0x%08x endva=0x%08x)\n", 1752 // su, (u_int32_t)pmap, pmap->pm_tid, va, endva); 1753 1754 if (su) { 1755 KASSERT(((va >= virtual_avail) && 1756 (va <= VM_MAX_KERNEL_ADDRESS)), 1757 ("mmu_booke_remove: kernel pmap, non kernel va")); 1758 } else { 1759 KASSERT((va <= VM_MAXUSER_ADDRESS), 1760 ("mmu_booke_remove: user pmap, non user va")); 1761 } 1762 1763 if (PMAP_REMOVE_DONE(pmap)) { 1764 //debugf("mmu_booke_remove: e (empty)\n"); 1765 return; 1766 } 1767 1768 hold_flag = PTBL_HOLD_FLAG(pmap); 1769 //debugf("mmu_booke_remove: hold_flag = %d\n", hold_flag); 1770 1771 vm_page_lock_queues(); 1772 PMAP_LOCK(pmap); 1773 for (; va < endva; va += PAGE_SIZE) { 1774 pte = pte_find(mmu, pmap, va); 1775 if ((pte != NULL) && PTE_ISVALID(pte)) 1776 pte_remove(mmu, pmap, va, hold_flag); 1777 } 1778 PMAP_UNLOCK(pmap); 1779 vm_page_unlock_queues(); 1780 1781 //debugf("mmu_booke_remove: e\n"); 1782} 1783 1784/* 1785 * Remove physical page from all pmaps in which it resides. 1786 */ 1787static void 1788mmu_booke_remove_all(mmu_t mmu, vm_page_t m) 1789{ 1790 pv_entry_t pv, pvn; 1791 uint8_t hold_flag; 1792 1793 vm_page_lock_queues(); 1794 for (pv = TAILQ_FIRST(&m->md.pv_list); pv != NULL; pv = pvn) { 1795 pvn = TAILQ_NEXT(pv, pv_link); 1796 1797 PMAP_LOCK(pv->pv_pmap); 1798 hold_flag = PTBL_HOLD_FLAG(pv->pv_pmap); 1799 pte_remove(mmu, pv->pv_pmap, pv->pv_va, hold_flag); 1800 PMAP_UNLOCK(pv->pv_pmap); 1801 } 1802 vm_page_flag_clear(m, PG_WRITEABLE); 1803 vm_page_unlock_queues(); 1804} 1805 1806/* 1807 * Map a range of physical addresses into kernel virtual address space. 1808 */ 1809static vm_offset_t 1810mmu_booke_map(mmu_t mmu, vm_offset_t *virt, vm_offset_t pa_start, 1811 vm_offset_t pa_end, int prot) 1812{ 1813 vm_offset_t sva = *virt; 1814 vm_offset_t va = sva; 1815 1816 //debugf("mmu_booke_map: s (sva = 0x%08x pa_start = 0x%08x pa_end = 0x%08x)\n", 1817 // sva, pa_start, pa_end); 1818 1819 while (pa_start < pa_end) { 1820 mmu_booke_kenter(mmu, va, pa_start); 1821 va += PAGE_SIZE; 1822 pa_start += PAGE_SIZE; 1823 } 1824 *virt = va; 1825 1826 //debugf("mmu_booke_map: e (va = 0x%08x)\n", va); 1827 return (sva); 1828} 1829 1830/* 1831 * The pmap must be activated before it's address space can be accessed in any 1832 * way. 1833 */ 1834static void 1835mmu_booke_activate(mmu_t mmu, struct thread *td) 1836{ 1837 pmap_t pmap; 1838 1839 pmap = &td->td_proc->p_vmspace->vm_pmap; 1840 1841 CTR5(KTR_PMAP, "%s: s (td = %p, proc = '%s', id = %d, pmap = 0x%08x)", 1842 __func__, td, td->td_proc->p_comm, td->td_proc->p_pid, pmap); 1843 1844 KASSERT((pmap != kernel_pmap), ("mmu_booke_activate: kernel_pmap!")); 1845 1846 mtx_lock_spin(&sched_lock); 1847 1848 atomic_set_int(&pmap->pm_active, PCPU_GET(cpumask)); 1849 PCPU_SET(curpmap, pmap); 1850 1851 if (pmap->pm_tid[PCPU_GET(cpuid)] == TID_NONE) 1852 tid_alloc(pmap); 1853 1854 /* Load PID0 register with pmap tid value. */ 1855 mtspr(SPR_PID0, pmap->pm_tid[PCPU_GET(cpuid)]); 1856 __asm __volatile("isync"); 1857 1858 mtx_unlock_spin(&sched_lock); 1859 1860 CTR3(KTR_PMAP, "%s: e (tid = %d for '%s')", __func__, 1861 pmap->pm_tid[PCPU_GET(cpuid)], td->td_proc->p_comm); 1862} 1863 1864/* 1865 * Deactivate the specified process's address space. 1866 */ 1867static void 1868mmu_booke_deactivate(mmu_t mmu, struct thread *td) 1869{ 1870 pmap_t pmap; 1871 1872 pmap = &td->td_proc->p_vmspace->vm_pmap; 1873 1874 CTR5(KTR_PMAP, "%s: td=%p, proc = '%s', id = %d, pmap = 0x%08x", 1875 __func__, td, td->td_proc->p_comm, td->td_proc->p_pid, pmap); 1876 1877 atomic_clear_int(&pmap->pm_active, PCPU_GET(cpumask)); 1878 PCPU_SET(curpmap, NULL); 1879} 1880 1881/* 1882 * Copy the range specified by src_addr/len 1883 * from the source map to the range dst_addr/len 1884 * in the destination map. 1885 * 1886 * This routine is only advisory and need not do anything. 1887 */ 1888static void 1889mmu_booke_copy(mmu_t mmu, pmap_t dst_pmap, pmap_t src_pmap, 1890 vm_offset_t dst_addr, vm_size_t len, vm_offset_t src_addr) 1891{ 1892 1893} 1894 1895/* 1896 * Set the physical protection on the specified range of this map as requested. 1897 */ 1898static void 1899mmu_booke_protect(mmu_t mmu, pmap_t pmap, vm_offset_t sva, vm_offset_t eva, 1900 vm_prot_t prot) 1901{ 1902 vm_offset_t va; 1903 vm_page_t m; 1904 pte_t *pte; 1905 1906 if ((prot & VM_PROT_READ) == VM_PROT_NONE) { 1907 mmu_booke_remove(mmu, pmap, sva, eva); 1908 return; 1909 } 1910 1911 if (prot & VM_PROT_WRITE) 1912 return; 1913 1914 vm_page_lock_queues(); 1915 PMAP_LOCK(pmap); 1916 for (va = sva; va < eva; va += PAGE_SIZE) { 1917 if ((pte = pte_find(mmu, pmap, va)) != NULL) { 1918 if (PTE_ISVALID(pte)) { 1919 m = PHYS_TO_VM_PAGE(PTE_PA(pte)); 1920 1921 mtx_lock_spin(&tlbivax_mutex); 1922 tlb_miss_lock(); 1923 1924 /* Handle modified pages. */ 1925 if (PTE_ISMODIFIED(pte) && PTE_ISMANAGED(pte)) 1926 vm_page_dirty(m); 1927 1928 tlb0_flush_entry(va); 1929 pte->flags &= ~(PTE_UW | PTE_SW | PTE_MODIFIED); 1930 1931 tlb_miss_unlock(); 1932 mtx_unlock_spin(&tlbivax_mutex); 1933 } 1934 } 1935 } 1936 PMAP_UNLOCK(pmap); 1937 vm_page_unlock_queues(); 1938} 1939 1940/* 1941 * Clear the write and modified bits in each of the given page's mappings. 1942 */ 1943static void 1944mmu_booke_remove_write(mmu_t mmu, vm_page_t m) 1945{ 1946 pv_entry_t pv; 1947 pte_t *pte; 1948 1949 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 1950 ("mmu_booke_remove_write: page %p is not managed", m)); 1951 1952 /* 1953 * If the page is not VPO_BUSY, then PG_WRITEABLE cannot be set by 1954 * another thread while the object is locked. Thus, if PG_WRITEABLE 1955 * is clear, no page table entries need updating. 1956 */ 1957 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 1958 if ((m->oflags & VPO_BUSY) == 0 && 1959 (m->flags & PG_WRITEABLE) == 0) 1960 return; 1961 vm_page_lock_queues(); 1962 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 1963 PMAP_LOCK(pv->pv_pmap); 1964 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL) { 1965 if (PTE_ISVALID(pte)) { 1966 m = PHYS_TO_VM_PAGE(PTE_PA(pte)); 1967 1968 mtx_lock_spin(&tlbivax_mutex); 1969 tlb_miss_lock(); 1970 1971 /* Handle modified pages. */ 1972 if (PTE_ISMODIFIED(pte)) 1973 vm_page_dirty(m); 1974 1975 /* Flush mapping from TLB0. */ 1976 pte->flags &= ~(PTE_UW | PTE_SW | PTE_MODIFIED); 1977 1978 tlb_miss_unlock(); 1979 mtx_unlock_spin(&tlbivax_mutex); 1980 } 1981 } 1982 PMAP_UNLOCK(pv->pv_pmap); 1983 } 1984 vm_page_flag_clear(m, PG_WRITEABLE); 1985 vm_page_unlock_queues(); 1986} 1987 1988static void 1989mmu_booke_sync_icache(mmu_t mmu, pmap_t pm, vm_offset_t va, vm_size_t sz) 1990{ 1991 pte_t *pte; 1992 pmap_t pmap; 1993 vm_page_t m; 1994 vm_offset_t addr; 1995 vm_paddr_t pa; 1996 int active, valid; 1997 1998 va = trunc_page(va); 1999 sz = round_page(sz); 2000 2001 vm_page_lock_queues(); 2002 pmap = PCPU_GET(curpmap); 2003 active = (pm == kernel_pmap || pm == pmap) ? 1 : 0; 2004 while (sz > 0) { 2005 PMAP_LOCK(pm); 2006 pte = pte_find(mmu, pm, va); 2007 valid = (pte != NULL && PTE_ISVALID(pte)) ? 1 : 0; 2008 if (valid) 2009 pa = PTE_PA(pte); 2010 PMAP_UNLOCK(pm); 2011 if (valid) { 2012 if (!active) { 2013 /* Create a mapping in the active pmap. */ 2014 addr = 0; 2015 m = PHYS_TO_VM_PAGE(pa); 2016 PMAP_LOCK(pmap); 2017 pte_enter(mmu, pmap, m, addr, 2018 PTE_SR | PTE_VALID | PTE_UR); 2019 __syncicache((void *)addr, PAGE_SIZE); 2020 pte_remove(mmu, pmap, addr, PTBL_UNHOLD); 2021 PMAP_UNLOCK(pmap); 2022 } else 2023 __syncicache((void *)va, PAGE_SIZE); 2024 } 2025 va += PAGE_SIZE; 2026 sz -= PAGE_SIZE; 2027 } 2028 vm_page_unlock_queues(); 2029} 2030 2031/* 2032 * Atomically extract and hold the physical page with the given 2033 * pmap and virtual address pair if that mapping permits the given 2034 * protection. 2035 */ 2036static vm_page_t 2037mmu_booke_extract_and_hold(mmu_t mmu, pmap_t pmap, vm_offset_t va, 2038 vm_prot_t prot) 2039{ 2040 pte_t *pte; 2041 vm_page_t m; 2042 uint32_t pte_wbit; 2043 vm_paddr_t pa; 2044 2045 m = NULL; 2046 pa = 0; 2047 PMAP_LOCK(pmap); 2048retry: 2049 pte = pte_find(mmu, pmap, va); 2050 if ((pte != NULL) && PTE_ISVALID(pte)) { 2051 if (pmap == kernel_pmap) 2052 pte_wbit = PTE_SW; 2053 else 2054 pte_wbit = PTE_UW; 2055 2056 if ((pte->flags & pte_wbit) || ((prot & VM_PROT_WRITE) == 0)) { 2057 if (vm_page_pa_tryrelock(pmap, PTE_PA(pte), &pa)) 2058 goto retry; 2059 m = PHYS_TO_VM_PAGE(PTE_PA(pte)); 2060 vm_page_hold(m); 2061 } 2062 } 2063 2064 PA_UNLOCK_COND(pa); 2065 PMAP_UNLOCK(pmap); 2066 return (m); 2067} 2068 2069/* 2070 * Initialize a vm_page's machine-dependent fields. 2071 */ 2072static void 2073mmu_booke_page_init(mmu_t mmu, vm_page_t m) 2074{ 2075 2076 TAILQ_INIT(&m->md.pv_list); 2077} 2078 2079/* 2080 * mmu_booke_zero_page_area zeros the specified hardware page by 2081 * mapping it into virtual memory and using bzero to clear 2082 * its contents. 2083 * 2084 * off and size must reside within a single page. 2085 */ 2086static void 2087mmu_booke_zero_page_area(mmu_t mmu, vm_page_t m, int off, int size) 2088{ 2089 vm_offset_t va; 2090 2091 /* XXX KASSERT off and size are within a single page? */ 2092 2093 mtx_lock(&zero_page_mutex); 2094 va = zero_page_va; 2095 2096 mmu_booke_kenter(mmu, va, VM_PAGE_TO_PHYS(m)); 2097 bzero((caddr_t)va + off, size); 2098 mmu_booke_kremove(mmu, va); 2099 2100 mtx_unlock(&zero_page_mutex); 2101} 2102 2103/* 2104 * mmu_booke_zero_page zeros the specified hardware page. 2105 */ 2106static void 2107mmu_booke_zero_page(mmu_t mmu, vm_page_t m) 2108{ 2109 2110 mmu_booke_zero_page_area(mmu, m, 0, PAGE_SIZE); 2111} 2112 2113/* 2114 * mmu_booke_copy_page copies the specified (machine independent) page by 2115 * mapping the page into virtual memory and using memcopy to copy the page, 2116 * one machine dependent page at a time. 2117 */ 2118static void 2119mmu_booke_copy_page(mmu_t mmu, vm_page_t sm, vm_page_t dm) 2120{ 2121 vm_offset_t sva, dva; 2122 2123 sva = copy_page_src_va; 2124 dva = copy_page_dst_va; 2125 2126 mtx_lock(©_page_mutex); 2127 mmu_booke_kenter(mmu, sva, VM_PAGE_TO_PHYS(sm)); 2128 mmu_booke_kenter(mmu, dva, VM_PAGE_TO_PHYS(dm)); 2129 memcpy((caddr_t)dva, (caddr_t)sva, PAGE_SIZE); 2130 mmu_booke_kremove(mmu, dva); 2131 mmu_booke_kremove(mmu, sva); 2132 mtx_unlock(©_page_mutex); 2133} 2134 2135/* 2136 * mmu_booke_zero_page_idle zeros the specified hardware page by mapping it 2137 * into virtual memory and using bzero to clear its contents. This is intended 2138 * to be called from the vm_pagezero process only and outside of Giant. No 2139 * lock is required. 2140 */ 2141static void 2142mmu_booke_zero_page_idle(mmu_t mmu, vm_page_t m) 2143{ 2144 vm_offset_t va; 2145 2146 va = zero_page_idle_va; 2147 mmu_booke_kenter(mmu, va, VM_PAGE_TO_PHYS(m)); 2148 bzero((caddr_t)va, PAGE_SIZE); 2149 mmu_booke_kremove(mmu, va); 2150} 2151 2152/* 2153 * Return whether or not the specified physical page was modified 2154 * in any of physical maps. 2155 */ 2156static boolean_t 2157mmu_booke_is_modified(mmu_t mmu, vm_page_t m) 2158{ 2159 pte_t *pte; 2160 pv_entry_t pv; 2161 boolean_t rv; 2162 2163 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 2164 ("mmu_booke_is_modified: page %p is not managed", m)); 2165 rv = FALSE; 2166 2167 /* 2168 * If the page is not VPO_BUSY, then PG_WRITEABLE cannot be 2169 * concurrently set while the object is locked. Thus, if PG_WRITEABLE 2170 * is clear, no PTEs can be modified. 2171 */ 2172 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2173 if ((m->oflags & VPO_BUSY) == 0 && 2174 (m->flags & PG_WRITEABLE) == 0) 2175 return (rv); 2176 vm_page_lock_queues(); 2177 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2178 PMAP_LOCK(pv->pv_pmap); 2179 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL && 2180 PTE_ISVALID(pte)) { 2181 if (PTE_ISMODIFIED(pte)) 2182 rv = TRUE; 2183 } 2184 PMAP_UNLOCK(pv->pv_pmap); 2185 if (rv) 2186 break; 2187 } 2188 vm_page_unlock_queues(); 2189 return (rv); 2190} 2191 2192/* 2193 * Return whether or not the specified virtual address is eligible 2194 * for prefault. 2195 */ 2196static boolean_t 2197mmu_booke_is_prefaultable(mmu_t mmu, pmap_t pmap, vm_offset_t addr) 2198{ 2199 2200 return (FALSE); 2201} 2202 2203/* 2204 * Return whether or not the specified physical page was referenced 2205 * in any physical maps. 2206 */ 2207static boolean_t 2208mmu_booke_is_referenced(mmu_t mmu, vm_page_t m) 2209{ 2210 pte_t *pte; 2211 pv_entry_t pv; 2212 boolean_t rv; 2213 2214 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 2215 ("mmu_booke_is_referenced: page %p is not managed", m)); 2216 rv = FALSE; 2217 vm_page_lock_queues(); 2218 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2219 PMAP_LOCK(pv->pv_pmap); 2220 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL && 2221 PTE_ISVALID(pte)) { 2222 if (PTE_ISREFERENCED(pte)) 2223 rv = TRUE; 2224 } 2225 PMAP_UNLOCK(pv->pv_pmap); 2226 if (rv) 2227 break; 2228 } 2229 vm_page_unlock_queues(); 2230 return (rv); 2231} 2232 2233/* 2234 * Clear the modify bits on the specified physical page. 2235 */ 2236static void 2237mmu_booke_clear_modify(mmu_t mmu, vm_page_t m) 2238{ 2239 pte_t *pte; 2240 pv_entry_t pv; 2241 2242 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 2243 ("mmu_booke_clear_modify: page %p is not managed", m)); 2244 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2245 KASSERT((m->oflags & VPO_BUSY) == 0, 2246 ("mmu_booke_clear_modify: page %p is busy", m)); 2247 2248 /* 2249 * If the page is not PG_WRITEABLE, then no PTEs can be modified. 2250 * If the object containing the page is locked and the page is not 2251 * VPO_BUSY, then PG_WRITEABLE cannot be concurrently set. 2252 */ 2253 if ((m->flags & PG_WRITEABLE) == 0) 2254 return; 2255 vm_page_lock_queues(); 2256 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2257 PMAP_LOCK(pv->pv_pmap); 2258 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL && 2259 PTE_ISVALID(pte)) { 2260 mtx_lock_spin(&tlbivax_mutex); 2261 tlb_miss_lock(); 2262 2263 if (pte->flags & (PTE_SW | PTE_UW | PTE_MODIFIED)) { 2264 tlb0_flush_entry(pv->pv_va); 2265 pte->flags &= ~(PTE_SW | PTE_UW | PTE_MODIFIED | 2266 PTE_REFERENCED); 2267 } 2268 2269 tlb_miss_unlock(); 2270 mtx_unlock_spin(&tlbivax_mutex); 2271 } 2272 PMAP_UNLOCK(pv->pv_pmap); 2273 } 2274 vm_page_unlock_queues(); 2275} 2276 2277/* 2278 * Return a count of reference bits for a page, clearing those bits. 2279 * It is not necessary for every reference bit to be cleared, but it 2280 * is necessary that 0 only be returned when there are truly no 2281 * reference bits set. 2282 * 2283 * XXX: The exact number of bits to check and clear is a matter that 2284 * should be tested and standardized at some point in the future for 2285 * optimal aging of shared pages. 2286 */ 2287static int 2288mmu_booke_ts_referenced(mmu_t mmu, vm_page_t m) 2289{ 2290 pte_t *pte; 2291 pv_entry_t pv; 2292 int count; 2293 2294 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 2295 ("mmu_booke_ts_referenced: page %p is not managed", m)); 2296 count = 0; 2297 vm_page_lock_queues(); 2298 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2299 PMAP_LOCK(pv->pv_pmap); 2300 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL && 2301 PTE_ISVALID(pte)) { 2302 if (PTE_ISREFERENCED(pte)) { 2303 mtx_lock_spin(&tlbivax_mutex); 2304 tlb_miss_lock(); 2305 2306 tlb0_flush_entry(pv->pv_va); 2307 pte->flags &= ~PTE_REFERENCED; 2308 2309 tlb_miss_unlock(); 2310 mtx_unlock_spin(&tlbivax_mutex); 2311 2312 if (++count > 4) { 2313 PMAP_UNLOCK(pv->pv_pmap); 2314 break; 2315 } 2316 } 2317 } 2318 PMAP_UNLOCK(pv->pv_pmap); 2319 } 2320 vm_page_unlock_queues(); 2321 return (count); 2322} 2323 2324/* 2325 * Clear the reference bit on the specified physical page. 2326 */ 2327static void 2328mmu_booke_clear_reference(mmu_t mmu, vm_page_t m) 2329{ 2330 pte_t *pte; 2331 pv_entry_t pv; 2332 2333 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 2334 ("mmu_booke_clear_reference: page %p is not managed", m)); 2335 vm_page_lock_queues(); 2336 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2337 PMAP_LOCK(pv->pv_pmap); 2338 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL && 2339 PTE_ISVALID(pte)) { 2340 if (PTE_ISREFERENCED(pte)) { 2341 mtx_lock_spin(&tlbivax_mutex); 2342 tlb_miss_lock(); 2343 2344 tlb0_flush_entry(pv->pv_va); 2345 pte->flags &= ~PTE_REFERENCED; 2346 2347 tlb_miss_unlock(); 2348 mtx_unlock_spin(&tlbivax_mutex); 2349 } 2350 } 2351 PMAP_UNLOCK(pv->pv_pmap); 2352 } 2353 vm_page_unlock_queues(); 2354} 2355 2356/* 2357 * Change wiring attribute for a map/virtual-address pair. 2358 */ 2359static void 2360mmu_booke_change_wiring(mmu_t mmu, pmap_t pmap, vm_offset_t va, boolean_t wired) 2361{ 2362 pte_t *pte; 2363 2364 PMAP_LOCK(pmap); 2365 if ((pte = pte_find(mmu, pmap, va)) != NULL) { 2366 if (wired) { 2367 if (!PTE_ISWIRED(pte)) { 2368 pte->flags |= PTE_WIRED; 2369 pmap->pm_stats.wired_count++; 2370 } 2371 } else { 2372 if (PTE_ISWIRED(pte)) { 2373 pte->flags &= ~PTE_WIRED; 2374 pmap->pm_stats.wired_count--; 2375 } 2376 } 2377 } 2378 PMAP_UNLOCK(pmap); 2379} 2380 2381/* 2382 * Return true if the pmap's pv is one of the first 16 pvs linked to from this 2383 * page. This count may be changed upwards or downwards in the future; it is 2384 * only necessary that true be returned for a small subset of pmaps for proper 2385 * page aging. 2386 */ 2387static boolean_t 2388mmu_booke_page_exists_quick(mmu_t mmu, pmap_t pmap, vm_page_t m) 2389{ 2390 pv_entry_t pv; 2391 int loops; 2392 boolean_t rv; 2393 2394 KASSERT((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) == 0, 2395 ("mmu_booke_page_exists_quick: page %p is not managed", m)); 2396 loops = 0; 2397 rv = FALSE; 2398 vm_page_lock_queues(); 2399 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2400 if (pv->pv_pmap == pmap) { 2401 rv = TRUE; 2402 break; 2403 } 2404 if (++loops >= 16) 2405 break; 2406 } 2407 vm_page_unlock_queues(); 2408 return (rv); 2409} 2410 2411/* 2412 * Return the number of managed mappings to the given physical page that are 2413 * wired. 2414 */ 2415static int 2416mmu_booke_page_wired_mappings(mmu_t mmu, vm_page_t m) 2417{ 2418 pv_entry_t pv; 2419 pte_t *pte; 2420 int count = 0; 2421 2422 if ((m->flags & PG_FICTITIOUS) != 0) 2423 return (count); 2424 vm_page_lock_queues(); 2425 TAILQ_FOREACH(pv, &m->md.pv_list, pv_link) { 2426 PMAP_LOCK(pv->pv_pmap); 2427 if ((pte = pte_find(mmu, pv->pv_pmap, pv->pv_va)) != NULL) 2428 if (PTE_ISVALID(pte) && PTE_ISWIRED(pte)) 2429 count++; 2430 PMAP_UNLOCK(pv->pv_pmap); 2431 } 2432 vm_page_unlock_queues(); 2433 return (count); 2434} 2435 2436static int 2437mmu_booke_dev_direct_mapped(mmu_t mmu, vm_offset_t pa, vm_size_t size) 2438{ 2439 int i; 2440 vm_offset_t va; 2441 2442 /* 2443 * This currently does not work for entries that 2444 * overlap TLB1 entries. 2445 */ 2446 for (i = 0; i < tlb1_idx; i ++) { 2447 if (tlb1_iomapped(i, pa, size, &va) == 0) 2448 return (0); 2449 } 2450 2451 return (EFAULT); 2452} 2453 2454vm_offset_t 2455mmu_booke_dumpsys_map(mmu_t mmu, struct pmap_md *md, vm_size_t ofs, 2456 vm_size_t *sz) 2457{ 2458 vm_paddr_t pa, ppa; 2459 vm_offset_t va; 2460 vm_size_t gran; 2461 2462 /* Raw physical memory dumps don't have a virtual address. */ 2463 if (md->md_vaddr == ~0UL) { 2464 /* We always map a 256MB page at 256M. */ 2465 gran = 256 * 1024 * 1024; 2466 pa = md->md_paddr + ofs; 2467 ppa = pa & ~(gran - 1); 2468 ofs = pa - ppa; 2469 va = gran; 2470 tlb1_set_entry(va, ppa, gran, _TLB_ENTRY_IO); 2471 if (*sz > (gran - ofs)) 2472 *sz = gran - ofs; 2473 return (va + ofs); 2474 } 2475 2476 /* Minidumps are based on virtual memory addresses. */ 2477 va = md->md_vaddr + ofs; 2478 if (va >= kernstart + kernsize) { 2479 gran = PAGE_SIZE - (va & PAGE_MASK); 2480 if (*sz > gran) 2481 *sz = gran; 2482 } 2483 return (va); 2484} 2485 2486void 2487mmu_booke_dumpsys_unmap(mmu_t mmu, struct pmap_md *md, vm_size_t ofs, 2488 vm_offset_t va) 2489{ 2490 2491 /* Raw physical memory dumps don't have a virtual address. */ 2492 if (md->md_vaddr == ~0UL) { 2493 tlb1_idx--; 2494 tlb1[tlb1_idx].mas1 = 0; 2495 tlb1[tlb1_idx].mas2 = 0; 2496 tlb1[tlb1_idx].mas3 = 0; 2497 tlb1_write_entry(tlb1_idx); 2498 return; 2499 } 2500 2501 /* Minidumps are based on virtual memory addresses. */ 2502 /* Nothing to do... */ 2503} 2504 2505struct pmap_md * 2506mmu_booke_scan_md(mmu_t mmu, struct pmap_md *prev) 2507{ 2508 static struct pmap_md md; 2509 pte_t *pte; 2510 vm_offset_t va; 2511 2512 if (dumpsys_minidump) { 2513 md.md_paddr = ~0UL; /* Minidumps use virtual addresses. */ 2514 if (prev == NULL) { 2515 /* 1st: kernel .data and .bss. */ 2516 md.md_index = 1; 2517 md.md_vaddr = trunc_page((uintptr_t)_etext); 2518 md.md_size = round_page((uintptr_t)_end) - md.md_vaddr; 2519 return (&md); 2520 } 2521 switch (prev->md_index) { 2522 case 1: 2523 /* 2nd: msgbuf and tables (see pmap_bootstrap()). */ 2524 md.md_index = 2; 2525 md.md_vaddr = data_start; 2526 md.md_size = data_end - data_start; 2527 break; 2528 case 2: 2529 /* 3rd: kernel VM. */ 2530 va = prev->md_vaddr + prev->md_size; 2531 /* Find start of next chunk (from va). */ 2532 while (va < virtual_end) { 2533 /* Don't dump the buffer cache. */ 2534 if (va >= kmi.buffer_sva && 2535 va < kmi.buffer_eva) { 2536 va = kmi.buffer_eva; 2537 continue; 2538 } 2539 pte = pte_find(mmu, kernel_pmap, va); 2540 if (pte != NULL && PTE_ISVALID(pte)) 2541 break; 2542 va += PAGE_SIZE; 2543 } 2544 if (va < virtual_end) { 2545 md.md_vaddr = va; 2546 va += PAGE_SIZE; 2547 /* Find last page in chunk. */ 2548 while (va < virtual_end) { 2549 /* Don't run into the buffer cache. */ 2550 if (va == kmi.buffer_sva) 2551 break; 2552 pte = pte_find(mmu, kernel_pmap, va); 2553 if (pte == NULL || !PTE_ISVALID(pte)) 2554 break; 2555 va += PAGE_SIZE; 2556 } 2557 md.md_size = va - md.md_vaddr; 2558 break; 2559 } 2560 md.md_index = 3; 2561 /* FALLTHROUGH */ 2562 default: 2563 return (NULL); 2564 } 2565 } else { /* minidumps */ 2566 mem_regions(&physmem_regions, &physmem_regions_sz, 2567 &availmem_regions, &availmem_regions_sz); 2568 2569 if (prev == NULL) { 2570 /* first physical chunk. */ 2571 md.md_paddr = physmem_regions[0].mr_start; 2572 md.md_size = physmem_regions[0].mr_size; 2573 md.md_vaddr = ~0UL; 2574 md.md_index = 1; 2575 } else if (md.md_index < physmem_regions_sz) { 2576 md.md_paddr = physmem_regions[md.md_index].mr_start; 2577 md.md_size = physmem_regions[md.md_index].mr_size; 2578 md.md_vaddr = ~0UL; 2579 md.md_index++; 2580 } else { 2581 /* There's no next physical chunk. */ 2582 return (NULL); 2583 } 2584 } 2585 2586 return (&md); 2587} 2588 2589/* 2590 * Map a set of physical memory pages into the kernel virtual address space. 2591 * Return a pointer to where it is mapped. This routine is intended to be used 2592 * for mapping device memory, NOT real memory. 2593 */ 2594static void * 2595mmu_booke_mapdev(mmu_t mmu, vm_offset_t pa, vm_size_t size) 2596{ 2597 void *res; 2598 uintptr_t va; 2599 vm_size_t sz; 2600 2601 va = (pa >= 0x80000000) ? pa : (0xe2000000 + pa); 2602 res = (void *)va; 2603 2604 do { 2605 sz = 1 << (ilog2(size) & ~1); 2606 if (bootverbose) 2607 printf("Wiring VA=%x to PA=%x (size=%x), " 2608 "using TLB1[%d]\n", va, pa, sz, tlb1_idx); 2609 tlb1_set_entry(va, pa, sz, _TLB_ENTRY_IO); 2610 size -= sz; 2611 pa += sz; 2612 va += sz; 2613 } while (size > 0); 2614 2615 return (res); 2616} 2617 2618/* 2619 * 'Unmap' a range mapped by mmu_booke_mapdev(). 2620 */ 2621static void 2622mmu_booke_unmapdev(mmu_t mmu, vm_offset_t va, vm_size_t size) 2623{ 2624 vm_offset_t base, offset; 2625 2626 /* 2627 * Unmap only if this is inside kernel virtual space. 2628 */ 2629 if ((va >= VM_MIN_KERNEL_ADDRESS) && (va <= VM_MAX_KERNEL_ADDRESS)) { 2630 base = trunc_page(va); 2631 offset = va & PAGE_MASK; 2632 size = roundup(offset + size, PAGE_SIZE); 2633 kmem_free(kernel_map, base, size); 2634 } 2635} 2636 2637/* 2638 * mmu_booke_object_init_pt preloads the ptes for a given object into the 2639 * specified pmap. This eliminates the blast of soft faults on process startup 2640 * and immediately after an mmap. 2641 */ 2642static void 2643mmu_booke_object_init_pt(mmu_t mmu, pmap_t pmap, vm_offset_t addr, 2644 vm_object_t object, vm_pindex_t pindex, vm_size_t size) 2645{ 2646 2647 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 2648 KASSERT(object->type == OBJT_DEVICE || object->type == OBJT_SG, 2649 ("mmu_booke_object_init_pt: non-device object")); 2650} 2651 2652/* 2653 * Perform the pmap work for mincore. 2654 */ 2655static int 2656mmu_booke_mincore(mmu_t mmu, pmap_t pmap, vm_offset_t addr, 2657 vm_paddr_t *locked_pa) 2658{ 2659 2660 TODO; 2661 return (0); 2662} 2663 2664/**************************************************************************/ 2665/* TID handling */ 2666/**************************************************************************/ 2667 2668/* 2669 * Allocate a TID. If necessary, steal one from someone else. 2670 * The new TID is flushed from the TLB before returning. 2671 */ 2672static tlbtid_t 2673tid_alloc(pmap_t pmap) 2674{ 2675 tlbtid_t tid; 2676 int thiscpu; 2677 2678 KASSERT((pmap != kernel_pmap), ("tid_alloc: kernel pmap")); 2679 2680 CTR2(KTR_PMAP, "%s: s (pmap = %p)", __func__, pmap); 2681 2682 thiscpu = PCPU_GET(cpuid); 2683 2684 tid = PCPU_GET(tid_next); 2685 if (tid > TID_MAX) 2686 tid = TID_MIN; 2687 PCPU_SET(tid_next, tid + 1); 2688 2689 /* If we are stealing TID then clear the relevant pmap's field */ 2690 if (tidbusy[thiscpu][tid] != NULL) { 2691 2692 CTR2(KTR_PMAP, "%s: warning: stealing tid %d", __func__, tid); 2693 2694 tidbusy[thiscpu][tid]->pm_tid[thiscpu] = TID_NONE; 2695 2696 /* Flush all entries from TLB0 matching this TID. */ 2697 tid_flush(tid); 2698 } 2699 2700 tidbusy[thiscpu][tid] = pmap; 2701 pmap->pm_tid[thiscpu] = tid; 2702 __asm __volatile("msync; isync"); 2703 2704 CTR3(KTR_PMAP, "%s: e (%02d next = %02d)", __func__, tid, 2705 PCPU_GET(tid_next)); 2706 2707 return (tid); 2708} 2709 2710/**************************************************************************/ 2711/* TLB0 handling */ 2712/**************************************************************************/ 2713 2714static void 2715tlb_print_entry(int i, uint32_t mas1, uint32_t mas2, uint32_t mas3, 2716 uint32_t mas7) 2717{ 2718 int as; 2719 char desc[3]; 2720 tlbtid_t tid; 2721 vm_size_t size; 2722 unsigned int tsize; 2723 2724 desc[2] = '\0'; 2725 if (mas1 & MAS1_VALID) 2726 desc[0] = 'V'; 2727 else 2728 desc[0] = ' '; 2729 2730 if (mas1 & MAS1_IPROT) 2731 desc[1] = 'P'; 2732 else 2733 desc[1] = ' '; 2734 2735 as = (mas1 & MAS1_TS_MASK) ? 1 : 0; 2736 tid = MAS1_GETTID(mas1); 2737 2738 tsize = (mas1 & MAS1_TSIZE_MASK) >> MAS1_TSIZE_SHIFT; 2739 size = 0; 2740 if (tsize) 2741 size = tsize2size(tsize); 2742 2743 debugf("%3d: (%s) [AS=%d] " 2744 "sz = 0x%08x tsz = %d tid = %d mas1 = 0x%08x " 2745 "mas2(va) = 0x%08x mas3(pa) = 0x%08x mas7 = 0x%08x\n", 2746 i, desc, as, size, tsize, tid, mas1, mas2, mas3, mas7); 2747} 2748 2749/* Convert TLB0 va and way number to tlb0[] table index. */ 2750static inline unsigned int 2751tlb0_tableidx(vm_offset_t va, unsigned int way) 2752{ 2753 unsigned int idx; 2754 2755 idx = (way * TLB0_ENTRIES_PER_WAY); 2756 idx += (va & MAS2_TLB0_ENTRY_IDX_MASK) >> MAS2_TLB0_ENTRY_IDX_SHIFT; 2757 return (idx); 2758} 2759 2760/* 2761 * Invalidate TLB0 entry. 2762 */ 2763static inline void 2764tlb0_flush_entry(vm_offset_t va) 2765{ 2766 2767 CTR2(KTR_PMAP, "%s: s va=0x%08x", __func__, va); 2768 2769 mtx_assert(&tlbivax_mutex, MA_OWNED); 2770 2771 __asm __volatile("tlbivax 0, %0" :: "r"(va & MAS2_EPN_MASK)); 2772 __asm __volatile("isync; msync"); 2773 __asm __volatile("tlbsync; msync"); 2774 2775 CTR1(KTR_PMAP, "%s: e", __func__); 2776} 2777 2778/* Print out contents of the MAS registers for each TLB0 entry */ 2779void 2780tlb0_print_tlbentries(void) 2781{ 2782 uint32_t mas0, mas1, mas2, mas3, mas7; 2783 int entryidx, way, idx; 2784 2785 debugf("TLB0 entries:\n"); 2786 for (way = 0; way < TLB0_WAYS; way ++) 2787 for (entryidx = 0; entryidx < TLB0_ENTRIES_PER_WAY; entryidx++) { 2788 2789 mas0 = MAS0_TLBSEL(0) | MAS0_ESEL(way); 2790 mtspr(SPR_MAS0, mas0); 2791 __asm __volatile("isync"); 2792 2793 mas2 = entryidx << MAS2_TLB0_ENTRY_IDX_SHIFT; 2794 mtspr(SPR_MAS2, mas2); 2795 2796 __asm __volatile("isync; tlbre"); 2797 2798 mas1 = mfspr(SPR_MAS1); 2799 mas2 = mfspr(SPR_MAS2); 2800 mas3 = mfspr(SPR_MAS3); 2801 mas7 = mfspr(SPR_MAS7); 2802 2803 idx = tlb0_tableidx(mas2, way); 2804 tlb_print_entry(idx, mas1, mas2, mas3, mas7); 2805 } 2806} 2807 2808/**************************************************************************/ 2809/* TLB1 handling */ 2810/**************************************************************************/ 2811 2812/* 2813 * TLB1 mapping notes: 2814 * 2815 * TLB1[0] CCSRBAR 2816 * TLB1[1] Kernel text and data. 2817 * TLB1[2-15] Additional kernel text and data mappings (if required), PCI 2818 * windows, other devices mappings. 2819 */ 2820 2821/* 2822 * Write given entry to TLB1 hardware. 2823 * Use 32 bit pa, clear 4 high-order bits of RPN (mas7). 2824 */ 2825static void 2826tlb1_write_entry(unsigned int idx) 2827{ 2828 uint32_t mas0, mas7; 2829 2830 //debugf("tlb1_write_entry: s\n"); 2831 2832 /* Clear high order RPN bits */ 2833 mas7 = 0; 2834 2835 /* Select entry */ 2836 mas0 = MAS0_TLBSEL(1) | MAS0_ESEL(idx); 2837 //debugf("tlb1_write_entry: mas0 = 0x%08x\n", mas0); 2838 2839 mtspr(SPR_MAS0, mas0); 2840 __asm __volatile("isync"); 2841 mtspr(SPR_MAS1, tlb1[idx].mas1); 2842 __asm __volatile("isync"); 2843 mtspr(SPR_MAS2, tlb1[idx].mas2); 2844 __asm __volatile("isync"); 2845 mtspr(SPR_MAS3, tlb1[idx].mas3); 2846 __asm __volatile("isync"); 2847 mtspr(SPR_MAS7, mas7); 2848 __asm __volatile("isync; tlbwe; isync; msync"); 2849 2850 //debugf("tlb1_write_entry: e\n"); 2851} 2852 2853/* 2854 * Return the largest uint value log such that 2^log <= num. 2855 */ 2856static unsigned int 2857ilog2(unsigned int num) 2858{ 2859 int lz; 2860 2861 __asm ("cntlzw %0, %1" : "=r" (lz) : "r" (num)); 2862 return (31 - lz); 2863} 2864 2865/* 2866 * Convert TLB TSIZE value to mapped region size. 2867 */ 2868static vm_size_t 2869tsize2size(unsigned int tsize) 2870{ 2871 2872 /* 2873 * size = 4^tsize KB 2874 * size = 4^tsize * 2^10 = 2^(2 * tsize - 10) 2875 */ 2876 2877 return ((1 << (2 * tsize)) * 1024); 2878} 2879 2880/* 2881 * Convert region size (must be power of 4) to TLB TSIZE value. 2882 */ 2883static unsigned int 2884size2tsize(vm_size_t size) 2885{ 2886 2887 return (ilog2(size) / 2 - 5); 2888} 2889 2890/* 2891 * Register permanent kernel mapping in TLB1. 2892 * 2893 * Entries are created starting from index 0 (current free entry is 2894 * kept in tlb1_idx) and are not supposed to be invalidated. 2895 */ 2896static int 2897tlb1_set_entry(vm_offset_t va, vm_offset_t pa, vm_size_t size, 2898 uint32_t flags) 2899{ 2900 uint32_t ts, tid; 2901 int tsize; 2902 2903 if (tlb1_idx >= TLB1_ENTRIES) { 2904 printf("tlb1_set_entry: TLB1 full!\n"); 2905 return (-1); 2906 } 2907 2908 /* Convert size to TSIZE */ 2909 tsize = size2tsize(size); 2910 2911 tid = (TID_KERNEL << MAS1_TID_SHIFT) & MAS1_TID_MASK; 2912 /* XXX TS is hard coded to 0 for now as we only use single address space */ 2913 ts = (0 << MAS1_TS_SHIFT) & MAS1_TS_MASK; 2914 2915 /* XXX LOCK tlb1[] */ 2916 2917 tlb1[tlb1_idx].mas1 = MAS1_VALID | MAS1_IPROT | ts | tid; 2918 tlb1[tlb1_idx].mas1 |= ((tsize << MAS1_TSIZE_SHIFT) & MAS1_TSIZE_MASK); 2919 tlb1[tlb1_idx].mas2 = (va & MAS2_EPN_MASK) | flags; 2920 2921 /* Set supervisor RWX permission bits */ 2922 tlb1[tlb1_idx].mas3 = (pa & MAS3_RPN) | MAS3_SR | MAS3_SW | MAS3_SX; 2923 2924 tlb1_write_entry(tlb1_idx++); 2925 2926 /* XXX UNLOCK tlb1[] */ 2927 2928 /* 2929 * XXX in general TLB1 updates should be propagated between CPUs, 2930 * since current design assumes to have the same TLB1 set-up on all 2931 * cores. 2932 */ 2933 return (0); 2934} 2935 2936static int 2937tlb1_entry_size_cmp(const void *a, const void *b) 2938{ 2939 const vm_size_t *sza; 2940 const vm_size_t *szb; 2941 2942 sza = a; 2943 szb = b; 2944 if (*sza > *szb) 2945 return (-1); 2946 else if (*sza < *szb) 2947 return (1); 2948 else 2949 return (0); 2950} 2951 2952/* 2953 * Map in contiguous RAM region into the TLB1 using maximum of 2954 * KERNEL_REGION_MAX_TLB_ENTRIES entries. 2955 * 2956 * If necessary round up last entry size and return total size 2957 * used by all allocated entries. 2958 */ 2959vm_size_t 2960tlb1_mapin_region(vm_offset_t va, vm_offset_t pa, vm_size_t size) 2961{ 2962 vm_size_t entry_size[KERNEL_REGION_MAX_TLB_ENTRIES]; 2963 vm_size_t mapped_size, sz, esz; 2964 unsigned int log; 2965 int i; 2966 2967 CTR4(KTR_PMAP, "%s: region size = 0x%08x va = 0x%08x pa = 0x%08x", 2968 __func__, size, va, pa); 2969 2970 mapped_size = 0; 2971 sz = size; 2972 memset(entry_size, 0, sizeof(entry_size)); 2973 2974 /* Calculate entry sizes. */ 2975 for (i = 0; i < KERNEL_REGION_MAX_TLB_ENTRIES && sz > 0; i++) { 2976 2977 /* Largest region that is power of 4 and fits within size */ 2978 log = ilog2(sz) / 2; 2979 esz = 1 << (2 * log); 2980 2981 /* If this is last entry cover remaining size. */ 2982 if (i == KERNEL_REGION_MAX_TLB_ENTRIES - 1) { 2983 while (esz < sz) 2984 esz = esz << 2; 2985 } 2986 2987 entry_size[i] = esz; 2988 mapped_size += esz; 2989 if (esz < sz) 2990 sz -= esz; 2991 else 2992 sz = 0; 2993 } 2994 2995 /* Sort entry sizes, required to get proper entry address alignment. */ 2996 qsort(entry_size, KERNEL_REGION_MAX_TLB_ENTRIES, 2997 sizeof(vm_size_t), tlb1_entry_size_cmp); 2998 2999 /* Load TLB1 entries. */ 3000 for (i = 0; i < KERNEL_REGION_MAX_TLB_ENTRIES; i++) { 3001 esz = entry_size[i]; 3002 if (!esz) 3003 break; 3004 3005 CTR5(KTR_PMAP, "%s: entry %d: sz = 0x%08x (va = 0x%08x " 3006 "pa = 0x%08x)", __func__, tlb1_idx, esz, va, pa); 3007 3008 tlb1_set_entry(va, pa, esz, _TLB_ENTRY_MEM); 3009 3010 va += esz; 3011 pa += esz; 3012 } 3013 3014 CTR3(KTR_PMAP, "%s: mapped size 0x%08x (wasted space 0x%08x)", 3015 __func__, mapped_size, mapped_size - size); 3016 3017 return (mapped_size); 3018} 3019 3020/* 3021 * TLB1 initialization routine, to be called after the very first 3022 * assembler level setup done in locore.S. 3023 */ 3024void 3025tlb1_init(vm_offset_t ccsrbar) 3026{ 3027 uint32_t mas0; 3028 3029 /* TLB1[1] is used to map the kernel. Save that entry. */ 3030 mas0 = MAS0_TLBSEL(1) | MAS0_ESEL(1); 3031 mtspr(SPR_MAS0, mas0); 3032 __asm __volatile("isync; tlbre"); 3033 3034 tlb1[1].mas1 = mfspr(SPR_MAS1); 3035 tlb1[1].mas2 = mfspr(SPR_MAS2); 3036 tlb1[1].mas3 = mfspr(SPR_MAS3); 3037 3038 /* Map in CCSRBAR in TLB1[0] */ 3039 tlb1_idx = 0; 3040 tlb1_set_entry(CCSRBAR_VA, ccsrbar, CCSRBAR_SIZE, _TLB_ENTRY_IO); 3041 /* 3042 * Set the next available TLB1 entry index. Note TLB[1] is reserved 3043 * for initial mapping of kernel text+data, which was set early in 3044 * locore, we need to skip this [busy] entry. 3045 */ 3046 tlb1_idx = 2; 3047 3048 /* Setup TLB miss defaults */ 3049 set_mas4_defaults(); 3050} 3051 3052/* 3053 * Setup MAS4 defaults. 3054 * These values are loaded to MAS0-2 on a TLB miss. 3055 */ 3056static void 3057set_mas4_defaults(void) 3058{ 3059 uint32_t mas4; 3060 3061 /* Defaults: TLB0, PID0, TSIZED=4K */ 3062 mas4 = MAS4_TLBSELD0; 3063 mas4 |= (TLB_SIZE_4K << MAS4_TSIZED_SHIFT) & MAS4_TSIZED_MASK; 3064#ifdef SMP 3065 mas4 |= MAS4_MD; 3066#endif 3067 mtspr(SPR_MAS4, mas4); 3068 __asm __volatile("isync"); 3069} 3070 3071/* 3072 * Print out contents of the MAS registers for each TLB1 entry 3073 */ 3074void 3075tlb1_print_tlbentries(void) 3076{ 3077 uint32_t mas0, mas1, mas2, mas3, mas7; 3078 int i; 3079 3080 debugf("TLB1 entries:\n"); 3081 for (i = 0; i < TLB1_ENTRIES; i++) { 3082 3083 mas0 = MAS0_TLBSEL(1) | MAS0_ESEL(i); 3084 mtspr(SPR_MAS0, mas0); 3085 3086 __asm __volatile("isync; tlbre"); 3087 3088 mas1 = mfspr(SPR_MAS1); 3089 mas2 = mfspr(SPR_MAS2); 3090 mas3 = mfspr(SPR_MAS3); 3091 mas7 = mfspr(SPR_MAS7); 3092 3093 tlb_print_entry(i, mas1, mas2, mas3, mas7); 3094 } 3095} 3096 3097/* 3098 * Print out contents of the in-ram tlb1 table. 3099 */ 3100void 3101tlb1_print_entries(void) 3102{ 3103 int i; 3104 3105 debugf("tlb1[] table entries:\n"); 3106 for (i = 0; i < TLB1_ENTRIES; i++) 3107 tlb_print_entry(i, tlb1[i].mas1, tlb1[i].mas2, tlb1[i].mas3, 0); 3108} 3109 3110/* 3111 * Return 0 if the physical IO range is encompassed by one of the 3112 * the TLB1 entries, otherwise return related error code. 3113 */ 3114static int 3115tlb1_iomapped(int i, vm_paddr_t pa, vm_size_t size, vm_offset_t *va) 3116{ 3117 uint32_t prot; 3118 vm_paddr_t pa_start; 3119 vm_paddr_t pa_end; 3120 unsigned int entry_tsize; 3121 vm_size_t entry_size; 3122 3123 *va = (vm_offset_t)NULL; 3124 3125 /* Skip invalid entries */ 3126 if (!(tlb1[i].mas1 & MAS1_VALID)) 3127 return (EINVAL); 3128 3129 /* 3130 * The entry must be cache-inhibited, guarded, and r/w 3131 * so it can function as an i/o page 3132 */ 3133 prot = tlb1[i].mas2 & (MAS2_I | MAS2_G); 3134 if (prot != (MAS2_I | MAS2_G)) 3135 return (EPERM); 3136 3137 prot = tlb1[i].mas3 & (MAS3_SR | MAS3_SW); 3138 if (prot != (MAS3_SR | MAS3_SW)) 3139 return (EPERM); 3140 3141 /* The address should be within the entry range. */ 3142 entry_tsize = (tlb1[i].mas1 & MAS1_TSIZE_MASK) >> MAS1_TSIZE_SHIFT; 3143 KASSERT((entry_tsize), ("tlb1_iomapped: invalid entry tsize")); 3144 3145 entry_size = tsize2size(entry_tsize); 3146 pa_start = tlb1[i].mas3 & MAS3_RPN; 3147 pa_end = pa_start + entry_size - 1; 3148 3149 if ((pa < pa_start) || ((pa + size) > pa_end)) 3150 return (ERANGE); 3151 3152 /* Return virtual address of this mapping. */ 3153 *va = (tlb1[i].mas2 & MAS2_EPN_MASK) + (pa - pa_start); 3154 return (0); 3155} 3156