../i386/intel/pmap.c

Bug Summary

File:	obj-scan-build/../i386/intel/pmap.c
Location:	line 1570, column 11
Description:	Dereference of null pointer (loaded from variable 'pte')

Annotated Source Code

* Mach Operating System

* Permission to use, copy, modify and distribute this software and its

* documentation is hereby granted, provided that both the copyright

* notice and this permission notice appear in all copies of the

* software, derivative works or modified versions, and any portions

* thereof, and that both notices appear in supporting documentation.

* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"

* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR

* ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.

* Carnegie Mellon requests users of this software to return to

* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU

* School of Computer Science

* Carnegie Mellon University

* Pittsburgh PA 15213-3890

* any improvements or extensions that they make and grant Carnegie Mellon

* the rights to redistribute these changes.

* File: pmap.c

* Author: Avadis Tevanian, Jr., Michael Wayne Young

* (These guys wrote the Vax version)

* Physical Map management code for Intel i386, and i486.

* Manages physical address maps.

* In addition to hardware address maps, this

* module is called upon to provide software-use-only

* maps which may or may not be stored in the same

* form as hardware maps. These pseudo-maps are

* used to store intermediate results from copy

* operations to and from address spaces.

* Since the information managed by this module is

* also stored by the logical address mapping module,

* this module may throw away valid virtual-to-physical

* mappings at almost any time. However, invalidations

* of virtual-to-physical mappings must be done as

* requested.

* In order to cope with hardware architectures which

* make virtual-to-physical map invalidates expensive,

* this module may delay invalidate or reduced protection

* operations until such time as they are actually

* necessary. This module is given full information as

* to which processors are currently using which maps,

* and to when physical maps must be made correct.

#include <string.h>

#include <mach/machine/vm_types.h>

#include <mach/boolean.h>

#include <kern/debug.h>

#include <kern/printf.h>

#include <kern/thread.h>

#include <kern/slab.h>

#include <kern/lock.h>

#include <vm/pmap.h>

#include <vm/vm_map.h>

#include <vm/vm_kern.h>

#include <i3861/vm_param.h>

#include <mach/vm_prot.h>

#include <vm/vm_object.h>

#include <vm/vm_page.h>

#include <vm/vm_user.h>

#include <mach/machine/vm_param.h>

#include <mach/xen.h>

#include <machine/thread.h>

#include <i3861/cpu_number.h>

#include <i3861/proc_reg.h>

#include <i3861/locore.h>

#include <i3861/model_dep.h>

#ifdef MACH_PSEUDO_PHYS

#define WRITE_PTE(pte_p, pte_entry)*(pte_p) = (pte_entry); *(pte_p) = pte_entry?pa_to_ma(pte_entry):0;

#else /* MACH_PSEUDO_PHYS */

#define WRITE_PTE(pte_p, pte_entry)*(pte_p) = (pte_entry); *(pte_p) = (pte_entry);

#endif /* MACH_PSEUDO_PHYS */

* Private data structures.

* For each vm_page_t, there is a list of all currently

* valid virtual mappings of that page. An entry is

100

* a pv_entry_t; the list is the pv_table.

101

102

103

typedef struct pv_entry {

104

struct pv_entry *next; /* next pv_entry */

105

pmap_t pmap; /* pmap where mapping lies */

106

vm_offset_t va; /* virtual address for mapping */

107

} *pv_entry_t;

108

109

#define PV_ENTRY_NULL((pv_entry_t) 0) ((pv_entry_t) 0)

110

111

pv_entry_t pv_head_table; /* array of entries, one per page */

112

113

114

* pv_list entries are kept on a list that can only be accessed

115

* with the pmap system locked (at SPLVM, not in the cpus_active set).

116

* The list is refilled from the pv_list_cache if it becomes empty.

117

118

pv_entry_t pv_free_list; /* free list at SPLVM */

119

decl_simple_lock_data(, pv_free_list_lock)

120

121

#define PV_ALLOC(pv_e){ ; if ((pv_e = pv_free_list) != 0) { pv_free_list = pv_e->
next; } ; } { \

122

simple_lock(&pv_free_list_lock); \

123

if ((pv_e = pv_free_list) != 0) { \

124

pv_free_list = pv_e->next; \

125

} \

126

simple_unlock(&pv_free_list_lock); \

127

}

128

129

#define PV_FREE(pv_e){ ; pv_e->next = pv_free_list; pv_free_list = pv_e; ; } { \

130

simple_lock(&pv_free_list_lock); \

131

pv_e->next = pv_free_list; \

132

pv_free_list = pv_e; \

133

simple_unlock(&pv_free_list_lock); \

134

}

135

136

struct kmem_cache pv_list_cache; /* cache of pv_entry structures */

137

138

139

* Each entry in the pv_head_table is locked by a bit in the

140

* pv_lock_table. The lock bits are accessed by the physical

141

* address of the page they lock.

142

143

144

char *pv_lock_table; /* pointer to array of bits */

145

#define pv_lock_table_size(n)(((n)+8 -1)/8) (((n)+BYTE_SIZE8-1)/BYTE_SIZE8)

146

147

/* Has pmap_init completed? */

148

boolean_t pmap_initialized = FALSE((boolean_t) 0);

149

150

151

* Range of kernel virtual addresses available for kernel memory mapping.

152

* Does not include the virtual addresses used to map physical memory 1-1.

153

* Initialized by pmap_bootstrap.

154

155

vm_offset_t kernel_virtual_start;

156

vm_offset_t kernel_virtual_end;

157

158

159

* Index into pv_head table, its lock bits, and the modify/reference

160

* bits starting at phys_first_addr.

161

162

#define pa_index(pa)((((vm_size_t)(pa - phys_first_addr)) >> 12)) (atop(pa - phys_first_addr)(((vm_size_t)(pa - phys_first_addr)) >> 12))

163

164

#define pai_to_pvh(pai)(&pv_head_table[pai]) (&pv_head_table[pai])

165

#define lock_pvh_pai(pai)(bit_lock(pai, pv_lock_table)) (bit_lock(pai, pv_lock_table))

166

#define unlock_pvh_pai(pai)(bit_unlock(pai, pv_lock_table)) (bit_unlock(pai, pv_lock_table))

167

168

169

* Array of physical page attribites for managed pages.

170

* One byte per physical page.

171

172

char *pmap_phys_attributes;

173

174

175

* Physical page attributes. Copy bits from PTE definition.

176

177

#define PHYS_MODIFIED0x00000040 INTEL_PTE_MOD0x00000040 /* page modified */

178

#define PHYS_REFERENCED0x00000020 INTEL_PTE_REF0x00000020 /* page referenced */

179

180

181

* Amount of virtual memory mapped by one

182

* page-directory entry.

183

184

#define PDE_MAPPED_SIZE(((vm_offset_t)(1) << 22)) (pdenum2lin(1)((vm_offset_t)(1) << 22))

185

186

187

* We allocate page table pages directly from the VM system

188

* through this object. It maps physical memory.

189

190

vm_object_t pmap_object = VM_OBJECT_NULL((vm_object_t) 0);

191

192

193

* Locking and TLB invalidation

194

195

196

197

* Locking Protocols:

198

199

* There are two structures in the pmap module that need locking:

200

* the pmaps themselves, and the per-page pv_lists (which are locked

201

* by locking the pv_lock_table entry that corresponds to the pv_head

202

* for the list in question.) Most routines want to lock a pmap and

203

* then do operations in it that require pv_list locking -- however

204

* pmap_remove_all and pmap_copy_on_write operate on a physical page

205

* basis and want to do the locking in the reverse order, i.e. lock

206

* a pv_list and then go through all the pmaps referenced by that list.

207

* To protect against deadlock between these two cases, the pmap_lock

208

* is used. There are three different locking protocols as a result:

209

210

* 1. pmap operations only (pmap_extract, pmap_access, ...) Lock only

211

* the pmap.

212

213

* 2. pmap-based operations (pmap_enter, pmap_remove, ...) Get a read

214

* lock on the pmap_lock (shared read), then lock the pmap

215

* and finally the pv_lists as needed [i.e. pmap lock before

216

* pv_list lock.]

217

218

* 3. pv_list-based operations (pmap_remove_all, pmap_copy_on_write, ...)

219

* Get a write lock on the pmap_lock (exclusive write); this

220

* also guaranteees exclusive access to the pv_lists. Lock the

221

* pmaps as needed.

222

223

* At no time may any routine hold more than one pmap lock or more than

224

* one pv_list lock. Because interrupt level routines can allocate

225

* mbufs and cause pmap_enter's, the pmap_lock and the lock on the

226

* kernel_pmap can only be held at splvm.

227

228

229

#if NCPUS1 > 1

230

231

* We raise the interrupt level to splvm, to block interprocessor

232

* interrupts during pmap operations. We must take the CPU out of

233

* the cpus_active set while interrupts are blocked.

234

235

#define SPLVM(spl)((void)(spl)) { \

236

spl = splvm(); \

237

i_bit_clear(cpu_number()(0), &cpus_active); \

238

}

239

240

#define SPLX(spl)((void)(spl)) { \

241

i_bit_set(cpu_number()(0), &cpus_active); \

242

splx(spl); \

243

}

244

245

246

* Lock on pmap system

247

248

lock_data_t pmap_system_lock;

249

250

#define PMAP_READ_LOCK(pmap, spl)((void)(spl)) { \

251

SPLVM(spl)((void)(spl)); \

252

lock_read(&pmap_system_lock); \

253

simple_lock(&(pmap)->lock); \

254

}

255

256

#define PMAP_WRITE_LOCK(spl)((void)(spl)) { \

257

SPLVM(spl)((void)(spl)); \

258

lock_write(&pmap_system_lock); \

259

}

260

261

#define PMAP_READ_UNLOCK(pmap, spl)((void)(spl)) { \

262

simple_unlock(&(pmap)->lock); \

263

lock_read_done(&pmap_system_lock)lock_done(&pmap_system_lock); \

264

SPLX(spl)((void)(spl)); \

265

}

266

267

#define PMAP_WRITE_UNLOCK(spl)((void)(spl)) { \

268

lock_write_done(&pmap_system_lock)lock_done(&pmap_system_lock); \

269

SPLX(spl)((void)(spl)); \

270

}

271

272

#define PMAP_WRITE_TO_READ_LOCK(pmap) { \

273

simple_lock(&(pmap)->lock); \

274

lock_write_to_read(&pmap_system_lock); \

275

}

276

277

#define LOCK_PVH(index) (lock_pvh_pai(index)(bit_lock(index, pv_lock_table)))

278

279

#define UNLOCK_PVH(index) (unlock_pvh_pai(index)(bit_unlock(index, pv_lock_table)))

280

281

#define PMAP_UPDATE_TLBS(pmap, s, e){ if ((pmap)->cpus_using) { { (void) ((pmap)); (void) ((s)
); (void) ((e)); ({ register unsigned long _temp__ = (({ register
unsigned long _temp__; asm volatile("mov %%cr3, %0" : "=r" (
_temp__)); _temp__; })); asm volatile("mov %0, %%cr3" : : "r"
(_temp__) : "memory"); }); }; } } \

282

{ \

283

cpu_set cpu_mask = 1 << cpu_number()(0); \

284

cpu_set users; \

285

286

/* Since the pmap is locked, other updates are locked */ \

287

/* out, and any pmap_activate has finished. */ \

288

289

/* find other cpus using the pmap */ \

290

users = (pmap)->cpus_using & ~cpu_mask; \

291

if (users) { \

292

/* signal them, and wait for them to finish */ \

293

/* using the pmap */ \

294

signal_cpus(users, (pmap), (s), (e)); \

295

while ((pmap)->cpus_using & cpus_active & ~cpu_mask) \

296

continue; \

297

} \

298

299

/* invalidate our own TLB if pmap is in use */ \

300

if ((pmap)->cpus_using & cpu_mask) { \

301

INVALIDATE_TLB((pmap), (s), (e)){ (void) ((pmap)); (void) ((s)); (void) ((e)); ({ register unsigned
long _temp__ = (({ register unsigned long _temp__; asm volatile
("mov %%cr3, %0" : "=r" (_temp__)); _temp__; })); asm volatile
("mov %0, %%cr3" : : "r" (_temp__) : "memory"); }); }; \

302

} \

303

}

304

305

#else /* NCPUS > 1 */

306

307

#define SPLVM(spl)((void)(spl)) ((void)(spl))

308

#define SPLX(spl)((void)(spl)) ((void)(spl))

309

310

#define PMAP_READ_LOCK(pmap, spl)((void)(spl)) SPLVM(spl)((void)(spl))

311

#define PMAP_WRITE_LOCK(spl)((void)(spl)) SPLVM(spl)((void)(spl))

312

#define PMAP_READ_UNLOCK(pmap, spl)((void)(spl)) SPLX(spl)((void)(spl))

313

#define PMAP_WRITE_UNLOCK(spl)((void)(spl)) SPLX(spl)((void)(spl))

314

#define PMAP_WRITE_TO_READ_LOCK(pmap)

315

316

#define LOCK_PVH(index)

317

#define UNLOCK_PVH(index)

318

319

320

/* invalidate our own TLB if pmap is in use */ \

321

if ((pmap)->cpus_using) { \

322

323

} \

324

}

325

326

#endif /* NCPUS > 1 */

327

328

#define MAX_TBIS_SIZE32 32 /* > this -> TBIA */ /* XXX */

329

330

#ifdef MACH_PV_PAGETABLES

331

#if 1

332

#define INVALIDATE_TLB(pmap, s, e){ (void) (pmap); (void) (s); (void) (e); ({ register unsigned
long _temp__ = (({ register unsigned long _temp__; asm volatile
("mov %%cr3, %0" : "=r" (_temp__)); _temp__; })); asm volatile
("mov %0, %%cr3" : : "r" (_temp__) : "memory"); }); } hyp_mmuext_op_void(MMUEXT_TLB_FLUSH_LOCAL)

333

#else

334

335

if (__builtin_constant_p((e) - (s)) \

336

&& (e) - (s) == PAGE_SIZE(1 << 12)) \

337

hyp_invlpg((pmap) == kernel_pmap ? kvtolin(s)((vm_offset_t)(s) - 0xC0000000UL + ((0xc0000000UL))) : (s)); \

338

else \

339

hyp_mmuext_op_void(MMUEXT_TLB_FLUSH_LOCAL); \

340

} while(0)

341

#endif

342

#else /* MACH_PV_PAGETABLES */

343

#if 0

344

/* It is hard to know when a TLB flush becomes less expensive than a bunch of

345

* invlpgs. But it surely is more expensive than just one invlpg. */

346

347

if (__builtin_constant_p((e) - (s)) \

348

&& (e) - (s) == PAGE_SIZE(1 << 12)) \

349

invlpg_linear(s)({ asm volatile( "movw %w1,%%es\n" "\tinvlpg %%es:(%0)\n" "\tmovw %w2,%%es"
:: "r" (s), "q" (0x38), "q" ((0x10 | 0))); }); \

350

else \

351

flush_tlb()({ register unsigned long _temp__ = (({ register unsigned long
_temp__; asm volatile("mov %%cr3, %0" : "=r" (_temp__)); _temp__
; })); asm volatile("mov %0, %%cr3" : : "r" (_temp__) : "memory"
); }); \

352

}

353

#else

354

355

(void) (pmap); \

356

(void) (s); \

357

(void) (e); \

358

359

}

360

#endif

361

#endif /* MACH_PV_PAGETABLES */

362

363

364

#if NCPUS1 > 1

365

366

* Structures to keep track of pending TLB invalidations

367

368

369

#define UPDATE_LIST_SIZE 4

370

371

struct pmap_update_item {

372

pmap_t pmap; /* pmap to invalidate */

373

vm_offset_t start; /* start address to invalidate */

374

vm_offset_t end; /* end address to invalidate */

375

} ;

376

377

typedef struct pmap_update_item *pmap_update_item_t;

378

379

380

* List of pmap updates. If the list overflows,

381

* the last entry is changed to invalidate all.

382

383

struct pmap_update_list {

384

decl_simple_lock_data(, lock)

385

int count;

386

struct pmap_update_item item[UPDATE_LIST_SIZE];

387

} ;

388

typedef struct pmap_update_list *pmap_update_list_t;

389

390

struct pmap_update_list cpu_update_list[NCPUS1];

391

392

#endif /* NCPUS > 1 */

393

394

395

* Other useful macros.

396

397

#define current_pmap()((((active_threads[(0)])->task->map)->pmap)) (vm_map_pmap(current_thread()->task->map)(((active_threads[(0)])->task->map)->pmap))

398

#define pmap_in_use(pmap, cpu)(((pmap)->cpus_using & (1 << (cpu))) != 0) (((pmap)->cpus_using & (1 << (cpu))) != 0)

399

400

struct pmap kernel_pmap_store;

401

pmap_t kernel_pmap;

402

403

struct kmem_cache pmap_cache; /* cache of pmap structures */

404

405

int pmap_debug = 0; /* flag for debugging prints */

406

407

#if 0

408

int ptes_per_vm_page1; /* number of hardware ptes needed

409

to map one VM page. */

410

#else

411

#define ptes_per_vm_page1 1

412

#endif

413

414

unsigned int inuse_ptepages_count = 0; /* debugging */

415

416

extern char end;

417

418

419

* Pointer to the basic page directory for the kernel.

420

* Initialized by pmap_bootstrap().

421

422

pt_entry_t *kernel_page_dir;

423

424

void pmap_remove_range(); /* forward */

425

#if NCPUS1 > 1

426

void signal_cpus(); /* forward */

427

#endif /* NCPUS > 1 */

428

429

static inline pt_entry_t *

430

pmap_pde(pmap_t pmap, vm_offset_t addr)

431

{

432

if (pmap == kernel_pmap)

433

addr = kvtolin(addr)((vm_offset_t)(addr) - 0xC0000000UL + ((0xc0000000UL)));

434

return &pmap->dirbase[lin2pdenum(addr)(((addr) >> 22) & 0x3ff)];

435

}

436

437

438

* Given an offset and a map, compute the address of the

439

* pte. If the address is invalid with respect to the map

440

* then PT_ENTRY_NULL is returned (and the map may need to grow).

441

442

* This is only used internally.

443

444

pt_entry_t *

445

pmap_pte(pmap_t pmap, vm_offset_t addr)

446

{

447

pt_entry_t *ptp;

448

pt_entry_t pte;

449

450

if (pmap->dirbase == 0)

451

return(PT_ENTRY_NULL((pt_entry_t *) 0));

452

pte = *pmap_pde(pmap, addr);

453

if ((pte & INTEL_PTE_VALID0x00000001) == 0)

454

return(PT_ENTRY_NULL((pt_entry_t *) 0));

455

ptp = (pt_entry_t *)ptetokv(pte)(((vm_offset_t)(((pte) & 0xfffff000)) + 0xC0000000UL));

456

return(&ptp[ptenum(addr)(((addr) >> 12) & 0x3ff)]);

457

}

458

459

#define DEBUG_PTE_PAGE0 0

460

461

#if DEBUG_PTE_PAGE0

462

void ptep_check(ptep)

463

ptep_t ptep;

464

{

465

pt_entry_t *pte, *epte;

466

int ctu, ctw;

467

468

/* check the use and wired counts */

469

if (ptep == PTE_PAGE_NULL)

470

return;

471

pte = pmap_pte(ptep->pmap, ptep->va);

472

epte = pte + INTEL_PGBYTES4096/sizeof(pt_entry_t);

473

ctu = 0;

474

ctw = 0;

475

while (pte < epte) {

476

if (pte->pfn != 0) {

477

ctu++;

478

if (pte->wired)

479

ctw++;

480

}

481

pte += ptes_per_vm_page1;

482

}

483

484

if (ctu != ptep->use_count || ctw != ptep->wired_count) {

485

printf("use %d wired %d - actual use %d wired %d\n",

486

ptep->use_count, ptep->wired_count, ctu, ctw);

487

panic("pte count");

488

}

489

}

490

#endif /* DEBUG_PTE_PAGE */

491

492

493

* Map memory at initialization. The physical addresses being

494

* mapped are not managed and are never unmapped.

495

496

* For now, VM is already on, we only need to map the

497

* specified memory.

498

499

vm_offset_t pmap_map(virt, start, end, prot)

500

vm_offset_t virt;

501

vm_offset_t start;

502

vm_offset_t end;

503

int prot;

504

{

505

int ps;

506

507

ps = PAGE_SIZE(1 << 12);

508

while (start < end) {

509

pmap_enter(kernel_pmap, virt, start, prot, FALSE((boolean_t) 0));

510

virt += ps;

511

start += ps;

512

}

513

return(virt);

514

}

515

516

517

* Back-door routine for mapping kernel VM at initialization.

518

* Useful for mapping memory outside the range

519

* [phys_first_addr, phys_last_addr) (i.e., devices).

520

* Otherwise like pmap_map.

521

522

vm_offset_t pmap_map_bd(virt, start, end, prot)

523

vm_offset_t virt;

524

vm_offset_t start;

525

vm_offset_t end;

526

vm_prot_t prot;

527

{

528

pt_entry_t template;

529

pt_entry_t *pte;

530

int spl;

531

#ifdef MACH_PV_PAGETABLES

532

int n, i = 0;

533

struct mmu_update update[HYP_BATCH_MMU_UPDATES];

534

#endif /* MACH_PV_PAGETABLES */

535

536

template = pa_to_pte(start)((start) & 0xfffff000)

537

| INTEL_PTE_NCACHE0x00000010|INTEL_PTE_WTHRU0x00000008

538

| INTEL_PTE_VALID0x00000001;

539

if (CPU_HAS_FEATURE(CPU_FEATURE_PGE)(cpu_features[(13) / 32] & (1 << ((13) % 32))))

540

template |= INTEL_PTE_GLOBAL0x00000100;

541

if (prot & VM_PROT_WRITE((vm_prot_t) 0x02))

542

template |= INTEL_PTE_WRITE0x00000002;

543

544

PMAP_READ_LOCK(pmap, spl)((void)(spl));

545

while (start < end) {

546

pte = pmap_pte(kernel_pmap, virt);

547

if (pte == PT_ENTRY_NULL((pt_entry_t *) 0))

548

panic("pmap_map_bd: Invalid kernel address\n");

549

#ifdef MACH_PV_PAGETABLES

550

update[i].ptr = kv_to_ma(pte);

551

update[i].val = pa_to_ma(template);

552

i++;

553

if (i == HYP_BATCH_MMU_UPDATES) {

554

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), i, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

555

if (n != i)

556

panic("couldn't pmap_map_bd\n");

557

i = 0;

558

}

559

#else /* MACH_PV_PAGETABLES */

560

WRITE_PTE(pte, template)*(pte) = (template);

561

#endif /* MACH_PV_PAGETABLES */

562

pte_increment_pa(template)((template) += 0xfff +1);

563

virt += PAGE_SIZE(1 << 12);

564

start += PAGE_SIZE(1 << 12);

565

}

566

#ifdef MACH_PV_PAGETABLES

567

if (i > HYP_BATCH_MMU_UPDATES)

568

panic("overflowed array in pmap_map_bd");

569

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), i, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

570

if (n != i)

571

panic("couldn't pmap_map_bd\n");

572

#endif /* MACH_PV_PAGETABLES */

573

PMAP_READ_UNLOCK(pmap, spl)((void)(spl));

574

return(virt);

575

}

576

577

578

* Bootstrap the system enough to run with virtual memory.

579

* Allocate the kernel page directory and page tables,

580

* and direct-map all physical memory.

581

* Called with mapping off.

582

583

void pmap_bootstrap()

584

{

585

586

* Mapping is turned off; we must reference only physical addresses.

587

* The load image of the system is to be mapped 1-1 physical = virtual.

588

589

590

591

* Set ptes_per_vm_page for general use.

592

593

#if 0

594

ptes_per_vm_page1 = PAGE_SIZE(1 << 12) / INTEL_PGBYTES4096;

595

#endif

596

597

598

* The kernel's pmap is statically allocated so we don't

599

* have to use pmap_create, which is unlikely to work

600

* correctly at this part of the boot sequence.

601

602

603

kernel_pmap = &kernel_pmap_store;

604

605

#if NCPUS1 > 1

606

lock_init(&pmap_system_lock, FALSE((boolean_t) 0)); /* NOT a sleep lock */

607

#endif /* NCPUS > 1 */

608

609

simple_lock_init(&kernel_pmap->lock);

610

611

kernel_pmap->ref_count = 1;

612

613

614

* Determine the kernel virtual address range.

615

* It starts at the end of the physical memory

616

* mapped into the kernel address space,

617

* and extends to a stupid arbitrary limit beyond that.

618

619

kernel_virtual_start = phystokv(phys_last_addr)((vm_offset_t)(phys_last_addr) + 0xC0000000UL);

620

kernel_virtual_end = phystokv(phys_last_addr)((vm_offset_t)(phys_last_addr) + 0xC0000000UL) + VM_KERNEL_MAP_SIZE(192 * 1024 * 1024);

621

622

if (kernel_virtual_end < kernel_virtual_start

623

|| kernel_virtual_end > VM_MAX_KERNEL_ADDRESS((0xffffffffUL) - ((0xc0000000UL)) + 0xC0000000UL))

624

kernel_virtual_end = VM_MAX_KERNEL_ADDRESS((0xffffffffUL) - ((0xc0000000UL)) + 0xC0000000UL);

625

626

627

* Allocate and clear a kernel page directory.

628

629

/* Note: initial Xen mapping holds at least 512kB free mapped page.

630

* We use that for directly building our linear mapping. */

631

#if PAE

632

{

633

vm_offset_t addr;

634

init_alloc_aligned(PDPNUM1 * INTEL_PGBYTES4096, &addr);

635

kernel_pmap->dirbase = kernel_page_dir = (pt_entry_t*)phystokv(addr)((vm_offset_t)(addr) + 0xC0000000UL);

636

}

637

kernel_pmap->pdpbase = (pt_entry_t*)phystokv(pmap_grab_page())((vm_offset_t)(pmap_grab_page()) + 0xC0000000UL);

638

{

639

int i;

640

for (i = 0; i < PDPNUM1; i++)

641

WRITE_PTE(&kernel_pmap->pdpbase[i], pa_to_pte(_kvtophys((void *) kernel_pmap->dirbase + i * INTEL_PGBYTES)) | INTEL_PTE_VALID)*(&kernel_pmap->pdpbase[i]) = (((((vm_offset_t)((void *
) kernel_pmap->dirbase + i * 4096) - 0xC0000000UL)) & 0xfffff000
) | 0x00000001);;

642

}

643

#else /* PAE */

644

kernel_pmap->dirbase = kernel_page_dir = (pt_entry_t*)phystokv(pmap_grab_page())((vm_offset_t)(pmap_grab_page()) + 0xC0000000UL);

645

#endif /* PAE */

646

{

647

int i;

648

for (i = 0; i < NPDES(1 * ((((unsigned long)(1)) << 12)/sizeof(pt_entry_t))); i++)

649

kernel_pmap->dirbase[i] = 0;

650

}

651

652

#ifdef MACH_PV_PAGETABLES

653

/* We don't actually deal with the CR3 register content at all */

654

hyp_vm_assist(VMASST_CMD_enable, VMASST_TYPE_pae_extended_cr3);

655

656

* Xen may only provide as few as 512KB extra bootstrap linear memory,

657

* which is far from enough to map all available memory, so we need to

658

* map more bootstrap linear memory. We here map 1 (resp. 4 for PAE)

659

* other L1 table(s), thus 4MiB extra memory (resp. 8MiB), which is

660

* enough for a pagetable mapping 4GiB.

661

662

#ifdef PAE

663

#define NSUP_L1 4

664

#else

665

#define NSUP_L1 1

666

#endif

667

pt_entry_t *l1_map[NSUP_L1];

668

{

669

pt_entry_t *base = (pt_entry_t*) boot_info.pt_base;

670

vm_offset_t la;

671

int n_l1map;

672

for (n_l1map = 0, la = VM_MIN_KERNEL_ADDRESS0xC0000000UL; la >= VM_MIN_KERNEL_ADDRESS0xC0000000UL; la += NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)) * PAGE_SIZE(1 << 12)) {

673

#ifdef PAE

674

pt_entry_t *l2_map = (pt_entry_t*) ptetokv(base[lin2pdpnum(la)])(((vm_offset_t)(((base[lin2pdpnum(la)]) & 0xfffff000)) + 0xC0000000UL
));

675

#else /* PAE */

676

pt_entry_t *l2_map = base;

677

#endif /* PAE */

678

/* Like lin2pdenum, but works with non-contiguous boot L3 */

679

l2_map += (la >> PDESHIFT22) & PDEMASK0x3ff;

680

if (!(*l2_map & INTEL_PTE_VALID0x00000001)) {

681

struct mmu_update update;

682

int j, n;

683

684

l1_map[n_l1map] = (pt_entry_t*) phystokv(pmap_grab_page())((vm_offset_t)(pmap_grab_page()) + 0xC0000000UL);

685

for (j = 0; j < NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)); j++)

686

l1_map[n_l1map][j] = (((pt_entry_t)pfn_to_mfn(lin2pdenum(la - VM_MIN_KERNEL_ADDRESS)(((la - 0xC0000000UL) >> 22) & 0x3ff) * NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)) + j)) << PAGE_SHIFT12) | INTEL_PTE_VALID0x00000001 | INTEL_PTE_WRITE0x00000002;

687

pmap_set_page_readonly_init(l1_map[n_l1map]);

688

if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, kv_to_mfn (l1_map[n_l1map])))

689

panic("couldn't pin page %p(%p)", l1_map[n_l1map], (vm_offset_t) kv_to_ma (l1_map[n_l1map]));

690

update.ptr = kv_to_ma(l2_map);

691

update.val = kv_to_ma(l1_map[n_l1map]) | INTEL_PTE_VALID0x00000001 | INTEL_PTE_WRITE0x00000002;

692

hyp_mmu_update(kv_to_la(&update), 1, kv_to_la(&n), DOMID_SELF);

693

if (n != 1)

694

panic("couldn't complete bootstrap map");

695

/* added the last L1 table, can stop */

696

if (++n_l1map >= NSUP_L1)

697

break;

698

}

699

}

700

}

701

#endif /* MACH_PV_PAGETABLES */

702

703

704

* Allocate and set up the kernel page tables.

705

706

{

707

vm_offset_t va;

708

pt_entry_t global = CPU_HAS_FEATURE(CPU_FEATURE_PGE)(cpu_features[(13) / 32] & (1 << ((13) % 32))) ? INTEL_PTE_GLOBAL0x00000100 : 0;

709

710

711

* Map virtual memory for all known physical memory, 1-1,

712

* from phys_first_addr to phys_last_addr.

713

* Make any mappings completely in the kernel's text segment read-only.

714

715

* Also allocate some additional all-null page tables afterwards

716

* for kernel virtual memory allocation,

717

* because this PMAP module is too stupid

718

* to allocate new kernel page tables later.

719

* XX fix this

720

721

for (va = phystokv(phys_first_addr)((vm_offset_t)(phys_first_addr) + 0xC0000000UL); va >= phystokv(phys_first_addr)((vm_offset_t)(phys_first_addr) + 0xC0000000UL) && va < kernel_virtual_end; )

722

{

723

pt_entry_t *pde = kernel_page_dir + lin2pdenum(kvtolin(va))(((((vm_offset_t)(va) - 0xC0000000UL + ((0xc0000000UL)))) >>
22) & 0x3ff);

724

pt_entry_t *ptable = (pt_entry_t*)phystokv(pmap_grab_page())((vm_offset_t)(pmap_grab_page()) + 0xC0000000UL);

725

pt_entry_t *pte;

726

727

/* Initialize the page directory entry. */

728

WRITE_PTE(pde, pa_to_pte((vm_offset_t)_kvtophys(ptable))*(pde) = ((((vm_offset_t)((vm_offset_t)(ptable) - 0xC0000000UL
)) & 0xfffff000) | 0x00000001 | 0x00000002);

729

| INTEL_PTE_VALID | INTEL_PTE_WRITE)*(pde) = ((((vm_offset_t)((vm_offset_t)(ptable) - 0xC0000000UL
)) & 0xfffff000) | 0x00000001 | 0x00000002);;

730

731

/* Initialize the page table. */

732

for (pte = ptable; (va < phystokv(phys_last_addr)((vm_offset_t)(phys_last_addr) + 0xC0000000UL)) && (pte < ptable+NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t))); pte++)

733

{

734

if ((pte - ptable) < ptenum(va)(((va) >> 12) & 0x3ff))

735

{

736

WRITE_PTE(pte, 0)*(pte) = (0);;

737

}

738

else

739

#ifdef MACH_PV_PAGETABLES

740

if (va == (vm_offset_t) &hyp_shared_info)

741

{

742

*pte = boot_info.shared_info | INTEL_PTE_VALID0x00000001 | INTEL_PTE_WRITE0x00000002;

743

va += INTEL_PGBYTES4096;

744

}

745

else

746

#endif /* MACH_PV_PAGETABLES */

747

{

748

extern char _start[], etext[];

749

750

if (((va >= (vm_offset_t) _start)

751

&& (va + INTEL_PGBYTES4096 <= (vm_offset_t)etext))

752

#ifdef MACH_PV_PAGETABLES

753

|| (va >= (vm_offset_t) boot_info.pt_base

754

&& (va + INTEL_PGBYTES4096 <=

755

(vm_offset_t) ptable + INTEL_PGBYTES4096))

756

#endif /* MACH_PV_PAGETABLES */

757

)

758

{

759

WRITE_PTE(pte, pa_to_pte(_kvtophys(va))*(pte) = (((((vm_offset_t)(va) - 0xC0000000UL)) & 0xfffff000
) | 0x00000001 | global);

760

| INTEL_PTE_VALID | global)*(pte) = (((((vm_offset_t)(va) - 0xC0000000UL)) & 0xfffff000
) | 0x00000001 | global);;

761

}

762

else

763

{

764

#ifdef MACH_PV_PAGETABLES

765

/* Keep supplementary L1 pages read-only */

766

int i;

767

for (i = 0; i < NSUP_L1; i++)

768

if (va == (vm_offset_t) l1_map[i]) {

769

WRITE_PTE(pte, pa_to_pte(_kvtophys(va))*(pte) = (((((vm_offset_t)(va) - 0xC0000000UL)) & 0xfffff000
) | 0x00000001 | global);

770

| INTEL_PTE_VALID | global)*(pte) = (((((vm_offset_t)(va) - 0xC0000000UL)) & 0xfffff000
) | 0x00000001 | global);;

771

break;

772

}

773

if (i == NSUP_L1)

774

#endif /* MACH_PV_PAGETABLES */

775

WRITE_PTE(pte, pa_to_pte(_kvtophys(va))*(pte) = (((((vm_offset_t)(va) - 0xC0000000UL)) & 0xfffff000
) | 0x00000001 | 0x00000002 | global);

776

777

778

}

779

va += INTEL_PGBYTES4096;

780

}

781

}

782

for (; pte < ptable+NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)); pte++)

783

{

784

WRITE_PTE(pte, 0)*(pte) = (0);;

785

va += INTEL_PGBYTES4096;

786

}

787

#ifdef MACH_PV_PAGETABLES

788

pmap_set_page_readonly_init(ptable);

789

if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, kv_to_mfn (ptable)))

790

panic("couldn't pin page %p(%p)\n", ptable, (vm_offset_t) kv_to_ma (ptable));

791

#endif /* MACH_PV_PAGETABLES */

792

}

793

}

794

795

/* Architecture-specific code will turn on paging

796

soon after we return from here. */

797

}

798

799

#ifdef MACH_PV_PAGETABLES

800

/* These are only required because of Xen security policies */

801

802

/* Set back a page read write */

803

void pmap_set_page_readwrite(void *_vaddr) {

804

vm_offset_t vaddr = (vm_offset_t) _vaddr;

805

vm_offset_t paddr = kvtophys(vaddr);

806

vm_offset_t canon_vaddr = phystokv(paddr)((vm_offset_t)(paddr) + 0xC0000000UL);

807

if (hyp_do_update_va_mapping (kvtolin(vaddr)((vm_offset_t)(vaddr) - 0xC0000000UL + ((0xc0000000UL))), pa_to_pte (pa_to_ma(paddr))((pa_to_ma(paddr)) & 0xfffff000) | INTEL_PTE_VALID0x00000001 | INTEL_PTE_WRITE0x00000002, UVMF_NONE))

808

panic("couldn't set hiMMU readwrite for addr %p(%p)\n", vaddr, (vm_offset_t) pa_to_ma (paddr));

809

if (canon_vaddr != vaddr)

810

if (hyp_do_update_va_mapping (kvtolin(canon_vaddr)((vm_offset_t)(canon_vaddr) - 0xC0000000UL + ((0xc0000000UL))
), pa_to_pte (pa_to_ma(paddr))((pa_to_ma(paddr)) & 0xfffff000) | INTEL_PTE_VALID0x00000001 | INTEL_PTE_WRITE0x00000002, UVMF_NONE))

811

panic("couldn't set hiMMU readwrite for paddr %p(%p)\n", canon_vaddr, (vm_offset_t) pa_to_ma (paddr));

812

}

813

814

/* Set a page read only (so as to pin it for instance) */

815

void pmap_set_page_readonly(void *_vaddr) {

816

vm_offset_t vaddr = (vm_offset_t) _vaddr;

817

vm_offset_t paddr = kvtophys(vaddr);

818

vm_offset_t canon_vaddr = phystokv(paddr)((vm_offset_t)(paddr) + 0xC0000000UL);

819

if (*pmap_pde(kernel_pmap, vaddr) & INTEL_PTE_VALID0x00000001) {

820

821

panic("couldn't set hiMMU readonly for vaddr %p(%p)\n", vaddr, (vm_offset_t) pa_to_ma (paddr));

822

}

823

if (canon_vaddr != vaddr &&

824

*pmap_pde(kernel_pmap, canon_vaddr) & INTEL_PTE_VALID0x00000001) {

825

826

panic("couldn't set hiMMU readonly for vaddr %p canon_vaddr %p paddr %p (%p)\n", vaddr, canon_vaddr, paddr, (vm_offset_t) pa_to_ma (paddr));

827

}

828

}

829

830

/* This needs to be called instead of pmap_set_page_readonly as long as RC3

831

* still points to the bootstrap dirbase, to also fix the bootstrap table. */

832

void pmap_set_page_readonly_init(void *_vaddr) {

833

vm_offset_t vaddr = (vm_offset_t) _vaddr;

834

#if PAE

835

pt_entry_t *pdpbase = (void*) boot_info.pt_base;

836

/* The bootstrap table does not necessarily use contiguous pages for the pde tables */

837

pt_entry_t *dirbase = (void*) ptetokv(pdpbase[lin2pdpnum(vaddr)])(((vm_offset_t)(((pdpbase[lin2pdpnum(vaddr)]) & 0xfffff000
)) + 0xC0000000UL));

838

#else

839

pt_entry_t *dirbase = (void*) boot_info.pt_base;

840

#endif

841

pt_entry_t *pte = &dirbase[lin2pdenum(vaddr)(((vaddr) >> 22) & 0x3ff) & PTEMASK0x3ff];

842

/* Modify our future kernel map (can't use update_va_mapping for this)... */

843

if (*pmap_pde(kernel_pmap, vaddr) & INTEL_PTE_VALID0x00000001) {

844

if (!hyp_mmu_update_la (kvtolin(vaddr)((vm_offset_t)(vaddr) - 0xC0000000UL + ((0xc0000000UL))), pa_to_pte (kv_to_ma(vaddr))((kv_to_ma(vaddr)) & 0xfffff000) | INTEL_PTE_VALID0x00000001))

845

panic("couldn't set hiMMU readonly for vaddr %p(%p)\n", vaddr, (vm_offset_t) kv_to_ma (vaddr));

846

}

847

/* ... and the bootstrap map. */

848

if (*pte & INTEL_PTE_VALID0x00000001) {

849

if (hyp_do_update_va_mapping (vaddr, pa_to_pte (kv_to_ma(vaddr))((kv_to_ma(vaddr)) & 0xfffff000) | INTEL_PTE_VALID0x00000001, UVMF_NONE))

850

panic("couldn't set MMU readonly for vaddr %p(%p)\n", vaddr, (vm_offset_t) kv_to_ma (vaddr));

851

}

852

}

853

854

void pmap_clear_bootstrap_pagetable(pt_entry_t *base) {

855

int i;

856

pt_entry_t *dir;

857

vm_offset_t va = 0;

858

#if PAE

859

int j;

860

#endif /* PAE */

861

if (!hyp_mmuext_op_mfn (MMUEXT_UNPIN_TABLE, kv_to_mfn(base)))

862

panic("pmap_clear_bootstrap_pagetable: couldn't unpin page %p(%p)\n", base, (vm_offset_t) kv_to_ma(base));

863

#if PAE

864

for (j = 0; j < PDPNUM1; j++)

865

{

866

pt_entry_t pdpe = base[j];

867

if (pdpe & INTEL_PTE_VALID0x00000001) {

868

dir = (pt_entry_t *) ptetokv(pdpe)(((vm_offset_t)(((pdpe) & 0xfffff000)) + 0xC0000000UL));

869

#else /* PAE */

870

dir = base;

871

#endif /* PAE */

872

for (i = 0; i < NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)); i++) {

873

pt_entry_t pde = dir[i];

874

unsigned long pfn = atop(pte_to_pa(pde))(((vm_size_t)(((pde) & 0xfffff000))) >> 12);

875

void *pgt = (void*) phystokv(ptoa(pfn))((vm_offset_t)(((vm_offset_t)((pfn) << 12))) + 0xC0000000UL
);

876

if (pde & INTEL_PTE_VALID0x00000001)

877

hyp_free_page(pfn, pgt);

878

va += NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)) * INTEL_PGBYTES4096;

879

if (va >= HYP_VIRT_START)

880

break;

881

}

882

#if PAE

883

hyp_free_page(atop(_kvtophys(dir))(((vm_size_t)(((vm_offset_t)(dir) - 0xC0000000UL))) >> 12
), dir);

884

} else

885

va += NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)) * NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t)) * INTEL_PGBYTES4096;

886

if (va >= HYP_VIRT_START)

887

break;

888

}

889

#endif /* PAE */

890

hyp_free_page(atop(_kvtophys(base))(((vm_size_t)(((vm_offset_t)(base) - 0xC0000000UL))) >>
12), base);

891

}

892

#endif /* MACH_PV_PAGETABLES */

893

894

void pmap_virtual_space(startp, endp)

895

vm_offset_t *startp;

896

vm_offset_t *endp;

897

{

898

*startp = kernel_virtual_start;

899

*endp = kernel_virtual_end;

900

}

901

902

903

* Initialize the pmap module.

904

* Called by vm_init, to initialize any structures that the pmap

905

* system needs to map virtual memory.

906

907

void pmap_init()

908

{

909

long npages;

910

vm_offset_t addr;

911

vm_size_t s;

912

#if NCPUS1 > 1

913

int i;

914

#endif /* NCPUS > 1 */

915

916

917

* Allocate memory for the pv_head_table and its lock bits,

918

* the modify bit array, and the pte_page table.

919

920

921

npages = atop(phys_last_addr - phys_first_addr)(((vm_size_t)(phys_last_addr - phys_first_addr)) >> 12);

922

s = (vm_size_t) (sizeof(struct pv_entry) * npages

923

+ pv_lock_table_size(npages)(((npages)+8 -1)/8)

924

+ npages);

925

926

s = round_page(s)((vm_offset_t)((((vm_offset_t)(s)) + ((1 << 12)-1)) &
~((1 << 12)-1)));

927

if (kmem_alloc_wired(kernel_map, &addr, s) != KERN_SUCCESS0)

928

panic("pmap_init");

929

memset((char *) addr, 0, s);

930

931

932

* Allocate the structures first to preserve word-alignment.

933

934

pv_head_table = (pv_entry_t) addr;

935

addr = (vm_offset_t) (pv_head_table + npages);

936

937

pv_lock_table = (char *) addr;

938

addr = (vm_offset_t) (pv_lock_table + pv_lock_table_size(npages)(((npages)+8 -1)/8));

939

940

pmap_phys_attributes = (char *) addr;

941

942

943

* Create the cache of physical maps,

944

* and of the physical-to-virtual entries.

945

946

s = (vm_size_t) sizeof(struct pmap);

947

kmem_cache_init(&pmap_cache, "pmap", s, 0, NULL((void *) 0), NULL((void *) 0), NULL((void *) 0), 0);

948

s = (vm_size_t) sizeof(struct pv_entry);

949

kmem_cache_init(&pv_list_cache, "pv_entry", s, 0, NULL((void *) 0), NULL((void *) 0), NULL((void *) 0), 0);

950

951

#if NCPUS1 > 1

952

953

* Set up the pmap request lists

954

955

for (i = 0; i < NCPUS1; i++) {

956

pmap_update_list_t up = &cpu_update_list[i];

957

958

simple_lock_init(&up->lock);

959

up->count = 0;

960

}

961

#endif /* NCPUS > 1 */

962

963

964

* Indicate that the PMAP module is now fully initialized.

965

966

pmap_initialized = TRUE((boolean_t) 1);

967

}

968

969

#define valid_page(x)(pmap_initialized && pmap_valid_page(x)) (pmap_initialized && pmap_valid_page(x))

970

971

boolean_t pmap_verify_free(phys)

972

vm_offset_t phys;

973

{

974

pv_entry_t pv_h;

975

int pai;

976

int spl;

977

boolean_t result;

978

979

assert(phys != vm_page_fictitious_addr)({ if (!(phys != vm_page_fictitious_addr)) Assert("phys != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 979); });

980

if (!pmap_initialized)

981

return(TRUE((boolean_t) 1));

982

983

if (!pmap_valid_page(phys))

984

return(FALSE((boolean_t) 0));

985

986

PMAP_WRITE_LOCK(spl)((void)(spl));

987

988

pai = pa_index(phys)((((vm_size_t)(phys - phys_first_addr)) >> 12));

989

pv_h = pai_to_pvh(pai)(&pv_head_table[pai]);

990

991

result = (pv_h->pmap == PMAP_NULL((pmap_t) 0));

992

PMAP_WRITE_UNLOCK(spl)((void)(spl));

993

994

return(result);

995

}

996

997

998

* Routine: pmap_page_table_page_alloc

999

1000

* Allocates a new physical page to be used as a page-table page.

1001

1002

* Must be called with the pmap system and the pmap unlocked,

1003

* since these must be unlocked to use vm_page_grab.

1004

1005

vm_offset_t

1006

pmap_page_table_page_alloc()

1007

{

1008

vm_page_t m;

1009

vm_offset_t pa;

1010

1011

check_simple_locks();

1012

1013

1014

* We cannot allocate the pmap_object in pmap_init,

1015

* because it is called before the cache package is up.

1016

* Allocate it now if it is missing.

1017

1018

if (pmap_object == VM_OBJECT_NULL((vm_object_t) 0))

1019

pmap_object = vm_object_allocate(phys_last_addr - phys_first_addr);

1020

1021

1022

* Allocate a VM page for the level 2 page table entries.

1023

1024

while ((m = vm_page_grab(FALSE((boolean_t) 0))) == VM_PAGE_NULL((vm_page_t) 0))

1025

VM_PAGE_WAIT((void (*)()) 0)vm_page_wait((void (*)()) 0);

1026

1027

1028

* Map the page to its physical address so that it

1029

* can be found later.

1030

1031

pa = m->phys_addr;

1032

vm_object_lock(pmap_object);

1033

vm_page_insert(m, pmap_object, pa);

1034

vm_page_lock_queues();

1035

vm_page_wire(m);

1036

inuse_ptepages_count++;

1037

vm_page_unlock_queues();

1038

vm_object_unlock(pmap_object);

1039

1040

1041

* Zero the page.

1042

1043

memset((void *)phystokv(pa)((vm_offset_t)(pa) + 0xC0000000UL), 0, PAGE_SIZE(1 << 12));

1044

1045

return pa;

1046

}

1047

1048

#ifdef MACH_XEN

1049

void pmap_map_mfn(void *_addr, unsigned long mfn) {

1050

vm_offset_t addr = (vm_offset_t) _addr;

1051

pt_entry_t *pte, *pdp;

1052

vm_offset_t ptp;

1053

pt_entry_t ma = ((pt_entry_t) mfn) << PAGE_SHIFT12;

1054

1055

/* Add a ptp if none exist yet for this pte */

1056

if ((pte = pmap_pte(kernel_pmap, addr)) == PT_ENTRY_NULL((pt_entry_t *) 0)) {

1057

ptp = phystokv(pmap_page_table_page_alloc())((vm_offset_t)(pmap_page_table_page_alloc()) + 0xC0000000UL);

1058

#ifdef MACH_PV_PAGETABLES

1059

pmap_set_page_readonly((void*) ptp);

1060

if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, pa_to_mfn(ptp)))

1061

panic("couldn't pin page %p(%p)\n",ptp,(vm_offset_t) kv_to_ma(ptp));

1062

#endif /* MACH_PV_PAGETABLES */

1063

pdp = pmap_pde(kernel_pmap, addr);

1064

1065

#ifdef MACH_PV_PAGETABLES

1066

if (!hyp_mmu_update_pte(kv_to_ma(pdp),

1067

pa_to_pte(kv_to_ma(ptp))((kv_to_ma(ptp)) & 0xfffff000) | INTEL_PTE_VALID0x00000001

1068

| INTEL_PTE_USER0x00000004

1069

| INTEL_PTE_WRITE0x00000002))

1070

panic("%s:%d could not set pde %p(%p) to %p(%p)\n",__FILE__"../i386/intel/pmap.c",__LINE__1070,kvtophys((vm_offset_t)pdp),(vm_offset_t) kv_to_ma(pdp), ptp, (vm_offset_t) pa_to_ma(ptp));

1071

#else /* MACH_PV_PAGETABLES */

1072

*pdp = pa_to_pte(kvtophys(ptp))((kvtophys(ptp)) & 0xfffff000) | INTEL_PTE_VALID0x00000001

1073

| INTEL_PTE_USER0x00000004

1074

| INTEL_PTE_WRITE0x00000002;

1075

#endif /* MACH_PV_PAGETABLES */

1076

pte = pmap_pte(kernel_pmap, addr);

1077

}

1078

1079

#ifdef MACH_PV_PAGETABLES

1080

if (!hyp_mmu_update_pte(kv_to_ma(pte), ma | INTEL_PTE_VALID0x00000001 | INTEL_PTE_WRITE0x00000002))

1081

panic("%s:%d could not set pte %p(%p) to %p(%p)\n",__FILE__"../i386/intel/pmap.c",__LINE__1081,pte,(vm_offset_t) kv_to_ma(pte), ma, ma_to_pa(ma));

1082

#else /* MACH_PV_PAGETABLES */

1083

/* Note: in this case, mfn is actually a pfn. */

1084

WRITE_PTE(pte, ma | INTEL_PTE_VALID | INTEL_PTE_WRITE)*(pte) = (ma | 0x00000001 | 0x00000002);;

1085

#endif /* MACH_PV_PAGETABLES */

1086

}

1087

#endif /* MACH_XEN */

1088

1089

1090

* Deallocate a page-table page.

1091

* The page-table page must have all mappings removed,

1092

* and be removed from its page directory.

1093

1094

void

1095

pmap_page_table_page_dealloc(pa)

1096

vm_offset_t pa;

1097

{

1098

vm_page_t m;

1099

1100

vm_object_lock(pmap_object);

1101

m = vm_page_lookup(pmap_object, pa);

1102

vm_page_lock_queues();

1103

vm_page_free(m);

1104

inuse_ptepages_count--;

1105

vm_page_unlock_queues();

1106

vm_object_unlock(pmap_object);

1107

}

1108

1109

1110

* Create and return a physical map.

1111

1112

* If the size specified for the map

1113

* is zero, the map is an actual physical

1114

* map, and may be referenced by the

1115

* hardware.

1116

1117

* If the size specified is non-zero,

1118

* the map will be used in software only, and

1119

* is bounded by that size.

1120

1121

pmap_t pmap_create(size)

1122

vm_size_t size;

1123

{

1124

pmap_t p;

1125

pmap_statistics_t stats;

1126

1127

1128

* A software use-only map doesn't even need a map.

1129

1130

1131

if (size != 0) {

1132

return(PMAP_NULL((pmap_t) 0));

1133

}

1134

1135

1136

* Allocate a pmap struct from the pmap_cache. Then allocate

1137

* the page descriptor table.

1138

1139

1140

p = (pmap_t) kmem_cache_alloc(&pmap_cache);

1141

if (p == PMAP_NULL((pmap_t) 0))

1142

panic("pmap_create");

1143

1144

if (kmem_alloc_wired(kernel_map,

1145

(vm_offset_t *)&p->dirbase, PDPNUM1 * INTEL_PGBYTES4096)

1146

!= KERN_SUCCESS0)

1147

panic("pmap_create");

1148

1149

memcpy(p->dirbase, kernel_page_dir, PDPNUM1 * INTEL_PGBYTES4096);

1150

#ifdef LINUX_DEV

1151

#if VM_MIN_KERNEL_ADDRESS0xC0000000UL != 0

1152

/* Do not map BIOS in user tasks */

1153

p->dirbase[lin2pdenum(LINEAR_MIN_KERNEL_ADDRESS - VM_MIN_KERNEL_ADDRESS)(((((0xc0000000UL)) - 0xC0000000UL) >> 22) & 0x3ff)] = 0;

1154

#endif

1155

#endif

1156

#ifdef MACH_PV_PAGETABLES

1157

{

1158

int i;

1159

for (i = 0; i < PDPNUM1; i++)

1160

pmap_set_page_readonly((void*) p->dirbase + i * INTEL_PGBYTES4096);

1161

}

1162

#endif /* MACH_PV_PAGETABLES */

1163

1164

#if PAE

1165

if (kmem_alloc_wired(kernel_map,

1166

(vm_offset_t *)&p->pdpbase, INTEL_PGBYTES4096)

1167

!= KERN_SUCCESS0)

1168

panic("pmap_create");

1169

{

1170

int i;

1171

for (i = 0; i < PDPNUM1; i++)

1172

WRITE_PTE(&p->pdpbase[i], pa_to_pte(kvtophys((vm_offset_t) p->dirbase + i * INTEL_PGBYTES)) | INTEL_PTE_VALID)*(&p->pdpbase[i]) = (((kvtophys((vm_offset_t) p->dirbase
+ i * 4096)) & 0xfffff000) | 0x00000001);;

1173

}

1174

#ifdef MACH_PV_PAGETABLES

1175

pmap_set_page_readonly(p->pdpbase);

1176

#endif /* MACH_PV_PAGETABLES */

1177

#endif /* PAE */

1178

1179

p->ref_count = 1;

1180

1181

simple_lock_init(&p->lock);

1182

p->cpus_using = 0;

1183

1184

1185

* Initialize statistics.

1186

1187

1188

stats = &p->stats;

1189

stats->resident_count = 0;

1190

stats->wired_count = 0;

1191

1192

return(p);

1193

}

1194

1195

1196

* Retire the given physical map from service.

1197

* Should only be called if the map contains

1198

* no valid mappings.

1199

1200

1201

void pmap_destroy(p)

1202

pmap_t p;

1203

{

1204

pt_entry_t *pdep;

1205

vm_offset_t pa;

1206

int c, s;

1207

vm_page_t m;

1208

1209

if (p == PMAP_NULL((pmap_t) 0))

1210

return;

1211

1212

SPLVM(s)((void)(s));

1213

simple_lock(&p->lock);

1214

c = --p->ref_count;

1215

simple_unlock(&p->lock);

1216

SPLX(s)((void)(s));

1217

1218

if (c != 0) {

1219

return; /* still in use */

1220

}

1221

1222

1223

* Free the memory maps, then the

1224

* pmap structure.

1225

1226

for (pdep = p->dirbase;

1227

pdep < &p->dirbase[lin2pdenum(LINEAR_MIN_KERNEL_ADDRESS)(((((0xc0000000UL))) >> 22) & 0x3ff)];

1228

pdep += ptes_per_vm_page1) {

1229

if (*pdep & INTEL_PTE_VALID0x00000001) {

1230

pa = pte_to_pa(*pdep)((*pdep) & 0xfffff000);

1231

vm_object_lock(pmap_object);

1232

m = vm_page_lookup(pmap_object, pa);

1233

if (m == VM_PAGE_NULL((vm_page_t) 0))

1234

panic("pmap_destroy: pte page not in object");

1235

vm_page_lock_queues();

1236

#ifdef MACH_PV_PAGETABLES

1237

if (!hyp_mmuext_op_mfn (MMUEXT_UNPIN_TABLE, pa_to_mfn(pa)))

1238

panic("pmap_destroy: couldn't unpin page %p(%p)\n", pa, (vm_offset_t) kv_to_ma(pa));

1239

pmap_set_page_readwrite((void*) phystokv(pa)((vm_offset_t)(pa) + 0xC0000000UL));

1240

#endif /* MACH_PV_PAGETABLES */

1241

vm_page_free(m);

1242

inuse_ptepages_count--;

1243

vm_page_unlock_queues();

1244

vm_object_unlock(pmap_object);

1245

}

1246

}

1247

#ifdef MACH_PV_PAGETABLES

1248

{

1249

int i;

1250

for (i = 0; i < PDPNUM1; i++)

1251

pmap_set_page_readwrite((void*) p->dirbase + i * INTEL_PGBYTES4096);

1252

}

1253

#endif /* MACH_PV_PAGETABLES */

1254

kmem_free(kernel_map, (vm_offset_t)p->dirbase, PDPNUM1 * INTEL_PGBYTES4096);

1255

#if PAE

1256

#ifdef MACH_PV_PAGETABLES

1257

pmap_set_page_readwrite(p->pdpbase);

1258

#endif /* MACH_PV_PAGETABLES */

1259

kmem_free(kernel_map, (vm_offset_t)p->pdpbase, INTEL_PGBYTES4096);

1260

#endif /* PAE */

1261

kmem_cache_free(&pmap_cache, (vm_offset_t) p);

1262

}

1263

1264

1265

* Add a reference to the specified pmap.

1266

1267

1268

void pmap_reference(p)

1269

pmap_t p;

1270

{

1271

int s;

1272

if (p != PMAP_NULL((pmap_t) 0)) {

1273

SPLVM(s)((void)(s));

1274

simple_lock(&p->lock);

1275

p->ref_count++;

1276

simple_unlock(&p->lock);

1277

SPLX(s)((void)(s));

1278

}

1279

}

1280

1281

1282

* Remove a range of hardware page-table entries.

1283

* The entries given are the first (inclusive)

1284

* and last (exclusive) entries for the VM pages.

1285

* The virtual address is the va for the first pte.

1286

1287

* The pmap must be locked.

1288

* If the pmap is not the kernel pmap, the range must lie

1289

* entirely within one pte-page. This is NOT checked.

1290

* Assumes that the pte-page exists.

1291

1292

1293

/* static */

1294

void pmap_remove_range(pmap, va, spte, epte)

1295

pmap_t pmap;

1296

vm_offset_t va;

1297

pt_entry_t *spte;

1298

pt_entry_t *epte;

1299

{

1300

pt_entry_t *cpte;

1301

int num_removed, num_unwired;

1302

int pai;

1303

vm_offset_t pa;

1304

#ifdef MACH_PV_PAGETABLES

1305

int n, ii = 0;

1306

struct mmu_update update[HYP_BATCH_MMU_UPDATES];

1307

#endif /* MACH_PV_PAGETABLES */

1308

1309

#if DEBUG_PTE_PAGE0

1310

if (pmap != kernel_pmap)

1311

ptep_check(get_pte_page(spte));

1312

#endif /* DEBUG_PTE_PAGE */

1313

num_removed = 0;

1314

num_unwired = 0;

1315

1316

for (cpte = spte; cpte < epte;

1317

cpte += ptes_per_vm_page1, va += PAGE_SIZE(1 << 12)) {

1318

1319

if (*cpte == 0)

1320

continue;

1321

pa = pte_to_pa(*cpte)((*cpte) & 0xfffff000);

1322

1323

num_removed++;

1324

if (*cpte & INTEL_PTE_WIRED0x00000200)

1325

num_unwired++;

1326

1327

if (!valid_page(pa)(pmap_initialized && pmap_valid_page(pa))) {

1328

1329

1330

* Outside range of managed physical memory.

1331

* Just remove the mappings.

1332

1333

int i = ptes_per_vm_page1;

1334

pt_entry_t *lpte = cpte;

1335

do {

1336

#ifdef MACH_PV_PAGETABLES

1337

update[ii].ptr = kv_to_ma(lpte);

1338

update[ii].val = 0;

1339

ii++;

1340

if (ii == HYP_BATCH_MMU_UPDATES) {

1341

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), ii, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

1342

if (n != ii)

1343

panic("couldn't pmap_remove_range\n");

1344

ii = 0;

1345

}

1346

#else /* MACH_PV_PAGETABLES */

1347

*lpte = 0;

1348

#endif /* MACH_PV_PAGETABLES */

1349

lpte++;

1350

} while (--i > 0);

1351

continue;

1352

}

1353

1354

pai = pa_index(pa)((((vm_size_t)(pa - phys_first_addr)) >> 12));

1355

LOCK_PVH(pai);

1356

1357

1358

* Get the modify and reference bits.

1359

1360

{

1361

int i;

1362

pt_entry_t *lpte;

1363

1364

i = ptes_per_vm_page1;

1365

lpte = cpte;

1366

do {

1367

pmap_phys_attributes[pai] |=

1368

*lpte & (PHYS_MODIFIED0x00000040|PHYS_REFERENCED0x00000020);

1369

#ifdef MACH_PV_PAGETABLES

1370

update[ii].ptr = kv_to_ma(lpte);

1371

update[ii].val = 0;

1372

ii++;

1373

if (ii == HYP_BATCH_MMU_UPDATES) {

1374

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), ii, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

1375

if (n != ii)

1376

panic("couldn't pmap_remove_range\n");

1377

ii = 0;

1378

}

1379

#else /* MACH_PV_PAGETABLES */

1380

*lpte = 0;

1381

#endif /* MACH_PV_PAGETABLES */

1382

lpte++;

1383

} while (--i > 0);

1384

}

1385

1386

1387

* Remove the mapping from the pvlist for

1388

* this physical page.

1389

1390

{

1391

pv_entry_t pv_h, prev, cur;

1392

1393

pv_h = pai_to_pvh(pai)(&pv_head_table[pai]);

1394

if (pv_h->pmap == PMAP_NULL((pmap_t) 0)) {

1395

panic("pmap_remove: null pv_list!");

1396

}

1397

if (pv_h->va == va && pv_h->pmap == pmap) {

1398

1399

* Header is the pv_entry. Copy the next one

1400

* to header and free the next one (we cannot

1401

* free the header)

1402

1403

cur = pv_h->next;

1404

if (cur != PV_ENTRY_NULL((pv_entry_t) 0)) {

1405

*pv_h = *cur;

1406

PV_FREE(cur){ ; cur->next = pv_free_list; pv_free_list = cur; ; };

1407

}

1408

else {

1409

pv_h->pmap = PMAP_NULL((pmap_t) 0);

1410

}

1411

}

1412

else {

1413

cur = pv_h;

1414

do {

1415

prev = cur;

1416

if ((cur = prev->next) == PV_ENTRY_NULL((pv_entry_t) 0)) {

1417

panic("pmap-remove: mapping not in pv_list!");

1418

}

1419

} while (cur->va != va || cur->pmap != pmap);

1420

prev->next = cur->next;

1421

PV_FREE(cur){ ; cur->next = pv_free_list; pv_free_list = cur; ; };

1422

}

1423

UNLOCK_PVH(pai);

1424

}

1425

}

1426

1427

#ifdef MACH_PV_PAGETABLES

1428

if (ii > HYP_BATCH_MMU_UPDATES)

1429

panic("overflowed array in pmap_remove_range");

1430

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), ii, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

1431

if (n != ii)

1432

panic("couldn't pmap_remove_range\n");

1433

#endif /* MACH_PV_PAGETABLES */

1434

1435

1436

* Update the counts

1437

1438

pmap->stats.resident_count -= num_removed;

1439

pmap->stats.wired_count -= num_unwired;

1440

}

1441

1442

1443

* Remove the given range of addresses

1444

* from the specified map.

1445

1446

* It is assumed that the start and end are properly

1447

* rounded to the hardware page size.

1448

1449

1450

void pmap_remove(map, s, e)

1451

pmap_t map;

1452

vm_offset_t s, e;

1453

{

1454

int spl;

1455

pt_entry_t *pde;

1456

pt_entry_t *spte, *epte;

1457

vm_offset_t l;

1458

vm_offset_t _s = s;

1459

1460

if (map == PMAP_NULL((pmap_t) 0))

1461

return;

1462

1463

PMAP_READ_LOCK(map, spl)((void)(spl));

1464

1465

pde = pmap_pde(map, s);

1466

while (s < e) {

1467

l = (s + PDE_MAPPED_SIZE(((vm_offset_t)(1) << 22))) & ~(PDE_MAPPED_SIZE(((vm_offset_t)(1) << 22))-1);

1468

if (l > e)

1469

l = e;

1470

if (*pde & INTEL_PTE_VALID0x00000001) {

1471

spte = (pt_entry_t *)ptetokv(*pde)(((vm_offset_t)(((*pde) & 0xfffff000)) + 0xC0000000UL));

1472

spte = &spte[ptenum(s)(((s) >> 12) & 0x3ff)];

1473

epte = &spte[intel_btop(l-s)(((unsigned long)(l-s)) >> 12)];

1474

pmap_remove_range(map, s, spte, epte);

1475

}

1476

s = l;

1477

pde++;

1478

}

1479

PMAP_UPDATE_TLBS(map, _s, e){ if ((map)->cpus_using) { { (void) ((map)); (void) ((_s))
; (void) ((e)); ({ register unsigned long _temp__ = (({ register
unsigned long _temp__; asm volatile("mov %%cr3, %0" : "=r" (
_temp__)); _temp__; })); asm volatile("mov %0, %%cr3" : : "r"
(_temp__) : "memory"); }); }; } };

1480

1481

PMAP_READ_UNLOCK(map, spl)((void)(spl));

1482

}

1483

1484

1485

* Routine: pmap_page_protect

1486

1487

* Function:

1488

* Lower the permission for all mappings to a given

1489

* page.

1490

1491

void pmap_page_protect(phys, prot)

1492

vm_offset_t phys;

1493

vm_prot_t prot;

1494

{

1495

pv_entry_t pv_h, prev;

1496

pv_entry_t pv_e;

1497

pt_entry_t *pte;

1498

int pai;

1499

pmap_t pmap;

1500

int spl;

1501

boolean_t remove;

1502

1503

assert(phys != vm_page_fictitious_addr)({ if (!(phys != vm_page_fictitious_addr)) Assert("phys != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 1503); });

1504

if (!valid_page(phys)(pmap_initialized && pmap_valid_page(phys))) {

Taking false branch

→

1505

1506

* Not a managed page.

1507

1508

return;

1509

}

1510

1511

1512

* Determine the new protection.

1513

1514

switch (prot) {

←

Control jumps to the 'default' case at line 1521

→

1515

case VM_PROT_READ((vm_prot_t) 0x01):

1516

case VM_PROT_READ((vm_prot_t) 0x01)|VM_PROT_EXECUTE((vm_prot_t) 0x04):

1517

remove = FALSE((boolean_t) 0);

1518

break;

1519

case VM_PROT_ALL(((vm_prot_t) 0x01)|((vm_prot_t) 0x02)|((vm_prot_t) 0x04)):

1520

return; /* nothing to do */

1521

default:

1522

remove = TRUE((boolean_t) 1);

1523

break;

←

Execution continues on line 1531

→

1524

}

1525

1526

1527

* Lock the pmap system first, since we will be changing

1528

* several pmaps.

1529

1530

1531

PMAP_WRITE_LOCK(spl)((void)(spl));

1532

1533

pai = pa_index(phys)((((vm_size_t)(phys - phys_first_addr)) >> 12));

1534

pv_h = pai_to_pvh(pai)(&pv_head_table[pai]);

1535

1536

1537

* Walk down PV list, changing or removing all mappings.

1538

* We do not have to lock the pv_list because we have

1539

* the entire pmap system locked.

1540

1541

if (pv_h->pmap != PMAP_NULL((pmap_t) 0)) {

←

Taking true branch

→

1542

1543

prev = pv_e = pv_h;

1544

do {

←

Loop condition is true. Execution continues on line 1545

→

←

Loop condition is true. Execution continues on line 1545

→

←

Loop condition is true. Execution continues on line 1545

→

1545

vm_offset_t va;

1546

1547

pmap = pv_e->pmap;

1548

1549

* Lock the pmap to block pmap_extract and similar routines.

1550

1551

simple_lock(&pmap->lock);

1552

1553

va = pv_e->va;

1554

pte = pmap_pte(pmap, va);

1555

1556

1557

* Consistency checks.

1558

1559

/* assert(*pte & INTEL_PTE_VALID); XXX */

1560

/* assert(pte_to_phys(*pte) == phys); */

1561

1562

1563

* Remove the mapping if new protection is NONE

1564

* or if write-protecting a kernel mapping.

1565

1566

if (remove || pmap == kernel_pmap) {

1567

1568

* Remove the mapping, collecting any modify bits.

1569

1570

if (*pte & INTEL_PTE_WIRED0x00000200)

Taking false branch

Taking false branch

Taking false branch

Dereference of null pointer (loaded from variable 'pte')

1571

panic("pmap_remove_all removing a wired page");

1572

1573

{

1574

int i = ptes_per_vm_page1;

1575

1576

do {

←

Loop condition is false. Exiting loop

→

←

Loop condition is false. Exiting loop

→

←

Loop condition is false. Exiting loop

→

1577

pmap_phys_attributes[pai] |=

1578

*pte & (PHYS_MODIFIED0x00000040|PHYS_REFERENCED0x00000020);

1579

#ifdef MACH_PV_PAGETABLES

1580

if (!hyp_mmu_update_pte(kv_to_ma(pte++), 0))

1581

panic("%s:%d could not clear pte %p\n",__FILE__"../i386/intel/pmap.c",__LINE__1581,pte-1);

1582

#else /* MACH_PV_PAGETABLES */

1583

*pte++ = 0;

1584

#endif /* MACH_PV_PAGETABLES */

1585

} while (--i > 0);

1586

}

1587

1588

pmap->stats.resident_count--;

1589

1590

1591

* Remove the pv_entry.

1592

1593

if (pv_e == pv_h) {

Taking true branch

Taking true branch

Taking true branch

1594

1595

* Fix up head later.

1596

1597

pv_h->pmap = PMAP_NULL((pmap_t) 0);

1598

}

1599

else {

1600

1601

* Delete this entry.

1602

1603

prev->next = pv_e->next;

1604

PV_FREE(pv_e){ ; pv_e->next = pv_free_list; pv_free_list = pv_e; ; };

1605

}

1606

}

1607

else {

1608

1609

* Write-protect.

1610

1611

int i = ptes_per_vm_page1;

1612

1613

do {

1614

#ifdef MACH_PV_PAGETABLES

1615

if (!hyp_mmu_update_pte(kv_to_ma(pte), *pte & ~INTEL_PTE_WRITE0x00000002))

1616

panic("%s:%d could not disable write on pte %p\n",__FILE__"../i386/intel/pmap.c",__LINE__1616,pte);

1617

#else /* MACH_PV_PAGETABLES */

1618

*pte &= ~INTEL_PTE_WRITE0x00000002;

1619

#endif /* MACH_PV_PAGETABLES */

1620

pte++;

1621

} while (--i > 0);

1622

1623

1624

* Advance prev.

1625

1626

prev = pv_e;

1627

}

1628

PMAP_UPDATE_TLBS(pmap, va, va + PAGE_SIZE){ if ((pmap)->cpus_using) { { (void) ((pmap)); (void) ((va
)); (void) ((va + (1 << 12))); ({ register unsigned long
_temp__ = (({ register unsigned long _temp__; asm volatile("mov %%cr3, %0"
: "=r" (_temp__)); _temp__; })); asm volatile("mov %0, %%cr3"
: : "r" (_temp__) : "memory"); }); }; } };

1629

1630

simple_unlock(&pmap->lock);

1631

1632

} while ((pv_e = prev->next) != PV_ENTRY_NULL((pv_entry_t) 0));

1633

1634

1635

* If pv_head mapping was removed, fix it up.

1636

1637

if (pv_h->pmap == PMAP_NULL((pmap_t) 0)) {

1638

pv_e = pv_h->next;

1639

if (pv_e != PV_ENTRY_NULL((pv_entry_t) 0)) {

1640

*pv_h = *pv_e;

1641

PV_FREE(pv_e){ ; pv_e->next = pv_free_list; pv_free_list = pv_e; ; };

1642

}

1643

}

1644

}

1645

1646

PMAP_WRITE_UNLOCK(spl)((void)(spl));

1647

}

1648

1649

1650

* Set the physical protection on the

1651

* specified range of this map as requested.

1652

* Will not increase permissions.

1653

1654

void pmap_protect(map, s, e, prot)

1655

pmap_t map;

1656

vm_offset_t s, e;

1657

vm_prot_t prot;

1658

{

1659

pt_entry_t *pde;

1660

pt_entry_t *spte, *epte;

1661

vm_offset_t l;

1662

int spl;

1663

vm_offset_t _s = s;

1664

1665

if (map == PMAP_NULL((pmap_t) 0))

1666

return;

1667

1668

1669

* Determine the new protection.

1670

1671

switch (prot) {

1672

case VM_PROT_READ((vm_prot_t) 0x01):

1673

case VM_PROT_READ((vm_prot_t) 0x01)|VM_PROT_EXECUTE((vm_prot_t) 0x04):

1674

break;

1675

case VM_PROT_READ((vm_prot_t) 0x01)|VM_PROT_WRITE((vm_prot_t) 0x02):

1676

case VM_PROT_ALL(((vm_prot_t) 0x01)|((vm_prot_t) 0x02)|((vm_prot_t) 0x04)):

1677

return; /* nothing to do */

1678

default:

1679

pmap_remove(map, s, e);

1680

return;

1681

}

1682

1683

1684

* If write-protecting in the kernel pmap,

1685

* remove the mappings; the i386 ignores

1686

* the write-permission bit in kernel mode.

1687

1688

* XXX should be #if'd for i386

1689

1690

if (map == kernel_pmap) {

1691

pmap_remove(map, s, e);

1692

return;

1693

}

1694

1695

SPLVM(spl)((void)(spl));

1696

simple_lock(&map->lock);

1697

1698

pde = pmap_pde(map, s);

1699

while (s < e) {

1700

l = (s + PDE_MAPPED_SIZE(((vm_offset_t)(1) << 22))) & ~(PDE_MAPPED_SIZE(((vm_offset_t)(1) << 22))-1);

1701

if (l > e)

1702

l = e;

1703

if (*pde & INTEL_PTE_VALID0x00000001) {

1704

spte = (pt_entry_t *)ptetokv(*pde)(((vm_offset_t)(((*pde) & 0xfffff000)) + 0xC0000000UL));

1705

spte = &spte[ptenum(s)(((s) >> 12) & 0x3ff)];

1706

epte = &spte[intel_btop(l-s)(((unsigned long)(l-s)) >> 12)];

1707

1708

#ifdef MACH_PV_PAGETABLES

1709

int n, i = 0;

1710

struct mmu_update update[HYP_BATCH_MMU_UPDATES];

1711

#endif /* MACH_PV_PAGETABLES */

1712

1713

while (spte < epte) {

1714

if (*spte & INTEL_PTE_VALID0x00000001) {

1715

#ifdef MACH_PV_PAGETABLES

1716

update[i].ptr = kv_to_ma(spte);

1717

update[i].val = *spte & ~INTEL_PTE_WRITE0x00000002;

1718

i++;

1719

if (i == HYP_BATCH_MMU_UPDATES) {

1720

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), i, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

1721

if (n != i)

1722

panic("couldn't pmap_protect\n");

1723

i = 0;

1724

}

1725

#else /* MACH_PV_PAGETABLES */

1726

*spte &= ~INTEL_PTE_WRITE0x00000002;

1727

#endif /* MACH_PV_PAGETABLES */

1728

}

1729

spte++;

1730

}

1731

#ifdef MACH_PV_PAGETABLES

1732

if (i > HYP_BATCH_MMU_UPDATES)

1733

panic("overflowed array in pmap_protect");

1734

hyp_mmu_update(kvtolin(&update)((vm_offset_t)(&update) - 0xC0000000UL + ((0xc0000000UL))
), i, kvtolin(&n)((vm_offset_t)(&n) - 0xC0000000UL + ((0xc0000000UL))), DOMID_SELF);

1735

if (n != i)

1736

panic("couldn't pmap_protect\n");

1737

#endif /* MACH_PV_PAGETABLES */

1738

}

1739

s = l;

1740

pde++;

1741

}

1742

1743

1744

simple_unlock(&map->lock);

1745

SPLX(spl)((void)(spl));

1746

}

1747

1748

1749

* Insert the given physical page (p) at

1750

* the specified virtual address (v) in the

1751

* target physical map with the protection requested.

1752

1753

* If specified, the page will be wired down, meaning

1754

* that the related pte can not be reclaimed.

1755

1756

* NB: This is the only routine which MAY NOT lazy-evaluate

1757

* or lose information. That is, this routine must actually

1758

* insert this page into the given map NOW.

1759

1760

void pmap_enter(pmap, v, pa, prot, wired)

1761

pmap_t pmap;

1762

vm_offset_t v;

1763

vm_offset_t pa;

1764

vm_prot_t prot;

1765

boolean_t wired;

1766

{

1767

pt_entry_t *pte;

1768

pv_entry_t pv_h;

1769

int i, pai;

1770

pv_entry_t pv_e;

1771

pt_entry_t template;

1772

int spl;

1773

vm_offset_t old_pa;

1774

1775

assert(pa != vm_page_fictitious_addr)({ if (!(pa != vm_page_fictitious_addr)) Assert("pa != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 1775); });

1776

if (pmap_debug) printf("pmap(%lx, %lx)\n", v, pa);

1777

if (pmap == PMAP_NULL((pmap_t) 0))

1778

return;

1779

1780

#if !MACH_KDB0

1781

if (pmap == kernel_pmap && (v < kernel_virtual_start || v >= kernel_virtual_end))

1782

panic("pmap_enter(%p, %p) falls in physical memory area!\n", v, pa);

1783

#endif

1784

if (pmap == kernel_pmap && (prot & VM_PROT_WRITE((vm_prot_t) 0x02)) == 0

1785

&& !wired /* hack for io_wire */ ) {

1786

1787

* Because the 386 ignores write protection in kernel mode,

1788

* we cannot enter a read-only kernel mapping, and must

1789

* remove an existing mapping if changing it.

1790

1791

* XXX should be #if'd for i386

1792

1793

PMAP_READ_LOCK(pmap, spl)((void)(spl));

1794

1795

pte = pmap_pte(pmap, v);

1796

if (pte != PT_ENTRY_NULL((pt_entry_t *) 0) && *pte != 0) {

1797

1798

* Invalidate the translation buffer,

1799

* then remove the mapping.

1800

1801

pmap_remove_range(pmap, v, pte,

1802

pte + ptes_per_vm_page1);

1803

PMAP_UPDATE_TLBS(pmap, v, v + PAGE_SIZE){ if ((pmap)->cpus_using) { { (void) ((pmap)); (void) ((v)
); (void) ((v + (1 << 12))); ({ register unsigned long _temp__
= (({ register unsigned long _temp__; asm volatile("mov %%cr3, %0"
: "=r" (_temp__)); _temp__; })); asm volatile("mov %0, %%cr3"
: : "r" (_temp__) : "memory"); }); }; } };

1804

}

1805

PMAP_READ_UNLOCK(pmap, spl)((void)(spl));

1806

return;

1807

}

1808

1809

1810

* Must allocate a new pvlist entry while we're unlocked;

1811

* Allocating may cause pageout (which will lock the pmap system).

1812

* If we determine we need a pvlist entry, we will unlock

1813

* and allocate one. Then we will retry, throughing away

1814

* the allocated entry later (if we no longer need it).

1815

1816

pv_e = PV_ENTRY_NULL((pv_entry_t) 0);

1817

Retry:

1818

PMAP_READ_LOCK(pmap, spl)((void)(spl));

1819

1820

1821

* Expand pmap to include this pte. Assume that

1822

* pmap is always expanded to include enough hardware

1823

* pages to map one VM page.

1824

1825

1826

while ((pte = pmap_pte(pmap, v)) == PT_ENTRY_NULL((pt_entry_t *) 0)) {

1827

1828

* Need to allocate a new page-table page.

1829

1830

vm_offset_t ptp;

1831

pt_entry_t *pdp;

1832

int i;

1833

1834

if (pmap == kernel_pmap) {

1835

1836

* Would have to enter the new page-table page in

1837

* EVERY pmap.

1838

1839

panic("pmap_expand kernel pmap to %#x", v);

1840

}

1841

1842

1843

* Unlock the pmap and allocate a new page-table page.

1844

1845

PMAP_READ_UNLOCK(pmap, spl)((void)(spl));

1846

1847

ptp = phystokv(pmap_page_table_page_alloc())((vm_offset_t)(pmap_page_table_page_alloc()) + 0xC0000000UL);

1848

1849

1850

* Re-lock the pmap and check that another thread has

1851

* not already allocated the page-table page. If it

1852

* has, discard the new page-table page (and try

1853

* again to make sure).

1854

1855

PMAP_READ_LOCK(pmap, spl)((void)(spl));

1856

1857

if (pmap_pte(pmap, v) != PT_ENTRY_NULL((pt_entry_t *) 0)) {

1858

1859

* Oops...

1860

1861

PMAP_READ_UNLOCK(pmap, spl)((void)(spl));

1862

pmap_page_table_page_dealloc(kvtophys(ptp));

1863

PMAP_READ_LOCK(pmap, spl)((void)(spl));

1864

continue;

1865

}

1866

1867

1868

* Enter the new page table page in the page directory.

1869

1870

i = ptes_per_vm_page1;

1871

/*XX pdp = &pmap->dirbase[pdenum(v) & ~(i-1)];*/

1872

pdp = pmap_pde(pmap, v);

1873

do {

1874

#ifdef MACH_PV_PAGETABLES

1875

pmap_set_page_readonly((void *) ptp);

1876

if (!hyp_mmuext_op_mfn (MMUEXT_PIN_L1_TABLE, kv_to_mfn(ptp)))

1877

panic("couldn't pin page %p(%p)\n",ptp,(vm_offset_t) kv_to_ma(ptp));

1878

if (!hyp_mmu_update_pte(pa_to_ma(kvtophys((vm_offset_t)pdp)),

1879

pa_to_pte(pa_to_ma(kvtophys(ptp)))((pa_to_ma(kvtophys(ptp))) & 0xfffff000) | INTEL_PTE_VALID0x00000001

1880

| INTEL_PTE_USER0x00000004

1881

| INTEL_PTE_WRITE0x00000002))

1882

panic("%s:%d could not set pde %p(%p,%p) to %p(%p,%p) %p\n",__FILE__"../i386/intel/pmap.c",__LINE__1882, pdp, kvtophys((vm_offset_t)pdp), (vm_offset_t) pa_to_ma(kvtophys((vm_offset_t)pdp)), ptp, kvtophys(ptp), (vm_offset_t) pa_to_ma(kvtophys(ptp)), (vm_offset_t) pa_to_pte(kv_to_ma(ptp))((kv_to_ma(ptp)) & 0xfffff000));

1883

#else /* MACH_PV_PAGETABLES */

1884

*pdp = pa_to_pte(kvtophys(ptp))((kvtophys(ptp)) & 0xfffff000) | INTEL_PTE_VALID0x00000001

1885

| INTEL_PTE_USER0x00000004

1886

| INTEL_PTE_WRITE0x00000002;

1887

#endif /* MACH_PV_PAGETABLES */

1888

pdp++;

1889

ptp += INTEL_PGBYTES4096;

1890

} while (--i > 0);

1891

1892

1893

* Now, get the address of the page-table entry.

1894

1895

continue;

1896

}

1897

1898

1899

* Special case if the physical page is already mapped

1900

* at this address.

1901

1902

old_pa = pte_to_pa(*pte)((*pte) & 0xfffff000);

1903

if (*pte && old_pa == pa) {

1904

1905

* May be changing its wired attribute or protection

1906

1907

1908

if (wired && !(*pte & INTEL_PTE_WIRED0x00000200))

1909

pmap->stats.wired_count++;

1910

else if (!wired && (*pte & INTEL_PTE_WIRED0x00000200))

1911

pmap->stats.wired_count--;

1912

1913

template = pa_to_pte(pa)((pa) & 0xfffff000) | INTEL_PTE_VALID0x00000001;

1914

if (pmap != kernel_pmap)

1915

template |= INTEL_PTE_USER0x00000004;

1916

if (prot & VM_PROT_WRITE((vm_prot_t) 0x02))

1917

template |= INTEL_PTE_WRITE0x00000002;

1918

if (machine_slot[cpu_number()(0)].cpu_type >= CPU_TYPE_I486((cpu_type_t) 17)

1919

&& pa >= phys_last_addr)

1920

template |= INTEL_PTE_NCACHE0x00000010|INTEL_PTE_WTHRU0x00000008;

1921

if (wired)

1922

template |= INTEL_PTE_WIRED0x00000200;

1923

i = ptes_per_vm_page1;

1924

do {

1925

if (*pte & INTEL_PTE_MOD0x00000040)

1926

template |= INTEL_PTE_MOD0x00000040;

1927

#ifdef MACH_PV_PAGETABLES

1928

if (!hyp_mmu_update_pte(kv_to_ma(pte), pa_to_ma(template)))

1929

panic("%s:%d could not set pte %p to %p\n",__FILE__"../i386/intel/pmap.c",__LINE__1929,pte,template);

1930

#else /* MACH_PV_PAGETABLES */

1931

WRITE_PTE(pte, template)*(pte) = (template);

1932

#endif /* MACH_PV_PAGETABLES */

1933

pte++;

1934

pte_increment_pa(template)((template) += 0xfff +1);

1935

} while (--i > 0);

1936

1937

}

1938

else {

1939

1940

1941

* Remove old mapping from the PV list if necessary.

1942

1943

if (*pte) {

1944

1945

* Don't free the pte page if removing last

1946

* mapping - we will immediately replace it.

1947

1948

pmap_remove_range(pmap, v, pte,

1949

pte + ptes_per_vm_page1);

1950

1951

}

1952

1953

if (valid_page(pa)(pmap_initialized && pmap_valid_page(pa))) {

1954

1955

1956

* Enter the mapping in the PV list for this

1957

* physical page.

1958

1959

1960

pai = pa_index(pa)((((vm_size_t)(pa - phys_first_addr)) >> 12));

1961

LOCK_PVH(pai);

1962

pv_h = pai_to_pvh(pai)(&pv_head_table[pai]);

1963

1964

if (pv_h->pmap == PMAP_NULL((pmap_t) 0)) {

1965

1966

* No mappings yet

1967

1968

pv_h->va = v;

1969

pv_h->pmap = pmap;

1970

pv_h->next = PV_ENTRY_NULL((pv_entry_t) 0);

1971

}

1972

else {

1973

#if DEBUG

1974

{

1975

/* check that this mapping is not already there */

1976

pv_entry_t e = pv_h;

1977

while (e != PV_ENTRY_NULL((pv_entry_t) 0)) {

1978

if (e->pmap == pmap && e->va == v)

1979

panic("pmap_enter: already in pv_list");

1980

e = e->next;

1981

}

1982

}

1983

#endif /* DEBUG */

1984

1985

1986

* Add new pv_entry after header.

1987

1988

if (pv_e == PV_ENTRY_NULL((pv_entry_t) 0)) {

1989

PV_ALLOC(pv_e){ ; if ((pv_e = pv_free_list) != 0) { pv_free_list = pv_e->
next; } ; };

1990

if (pv_e == PV_ENTRY_NULL((pv_entry_t) 0)) {

1991

UNLOCK_PVH(pai);

1992

PMAP_READ_UNLOCK(pmap, spl)((void)(spl));

1993

1994

1995

* Refill from cache.

1996

1997

pv_e = (pv_entry_t) kmem_cache_alloc(&pv_list_cache);

1998

goto Retry;

1999

}

2000

}

2001

pv_e->va = v;

2002

pv_e->pmap = pmap;

2003

pv_e->next = pv_h->next;

2004

pv_h->next = pv_e;

2005

2006

* Remember that we used the pvlist entry.

2007

2008

pv_e = PV_ENTRY_NULL((pv_entry_t) 0);

2009

}

2010

UNLOCK_PVH(pai);

2011

}

2012

2013

2014

* And count the mapping.

2015

2016

2017

pmap->stats.resident_count++;

2018

if (wired)

2019

pmap->stats.wired_count++;

2020

2021

2022

* Build a template to speed up entering -

2023

* only the pfn changes.

2024

2025

template = pa_to_pte(pa)((pa) & 0xfffff000) | INTEL_PTE_VALID0x00000001;

2026

if (pmap != kernel_pmap)

2027

template |= INTEL_PTE_USER0x00000004;

2028

if (prot & VM_PROT_WRITE((vm_prot_t) 0x02))

2029

template |= INTEL_PTE_WRITE0x00000002;

2030

if (machine_slot[cpu_number()(0)].cpu_type >= CPU_TYPE_I486((cpu_type_t) 17)

2031

&& pa >= phys_last_addr)

2032

template |= INTEL_PTE_NCACHE0x00000010|INTEL_PTE_WTHRU0x00000008;

2033

if (wired)

2034

template |= INTEL_PTE_WIRED0x00000200;

2035

i = ptes_per_vm_page1;

2036

do {

2037

#ifdef MACH_PV_PAGETABLES

2038

if (!(hyp_mmu_update_pte(kv_to_ma(pte), pa_to_ma(template))))

2039

panic("%s:%d could not set pte %p to %p\n",__FILE__"../i386/intel/pmap.c",__LINE__2039,pte,template);

2040

#else /* MACH_PV_PAGETABLES */

2041

WRITE_PTE(pte, template)*(pte) = (template);

2042

#endif /* MACH_PV_PAGETABLES */

2043

pte++;

2044

pte_increment_pa(template)((template) += 0xfff +1);

2045

} while (--i > 0);

2046

}

2047

2048

if (pv_e != PV_ENTRY_NULL((pv_entry_t) 0)) {

2049

PV_FREE(pv_e){ ; pv_e->next = pv_free_list; pv_free_list = pv_e; ; };

2050

}

2051

2052

PMAP_READ_UNLOCK(pmap, spl)((void)(spl));

2053

}

2054

2055

2056

* Routine: pmap_change_wiring

2057

* Function: Change the wiring attribute for a map/virtual-address

2058

* pair.

2059

* In/out conditions:

2060

* The mapping must already exist in the pmap.

2061

2062

void pmap_change_wiring(map, v, wired)

2063

pmap_t map;

2064

vm_offset_t v;

2065

boolean_t wired;

2066

{

2067

pt_entry_t *pte;

2068

int i;

2069

int spl;

2070

2071

2072

* We must grab the pmap system lock because we may

2073

* change a pte_page queue.

2074

2075

PMAP_READ_LOCK(map, spl)((void)(spl));

2076

2077

if ((pte = pmap_pte(map, v)) == PT_ENTRY_NULL((pt_entry_t *) 0))

2078

panic("pmap_change_wiring: pte missing");

2079

2080

if (wired && !(*pte & INTEL_PTE_WIRED0x00000200)) {

2081

2082

* wiring down mapping

2083

2084

map->stats.wired_count++;

2085

i = ptes_per_vm_page1;

2086

do {

2087

*pte++ |= INTEL_PTE_WIRED0x00000200;

2088

} while (--i > 0);

2089

}

2090

else if (!wired && (*pte & INTEL_PTE_WIRED0x00000200)) {

2091

2092

* unwiring mapping

2093

2094

map->stats.wired_count--;

2095

i = ptes_per_vm_page1;

2096

do {

2097

#ifdef MACH_PV_PAGETABLES

2098

if (!(hyp_mmu_update_pte(kv_to_ma(pte), *pte & ~INTEL_PTE_WIRED0x00000200)))

2099

panic("%s:%d could not wire down pte %p\n",__FILE__"../i386/intel/pmap.c",__LINE__2099,pte);

2100

#else /* MACH_PV_PAGETABLES */

2101

*pte &= ~INTEL_PTE_WIRED0x00000200;

2102

#endif /* MACH_PV_PAGETABLES */

2103

pte++;

2104

} while (--i > 0);

2105

}

2106

2107

PMAP_READ_UNLOCK(map, spl)((void)(spl));

2108

}

2109

2110

2111

* Routine: pmap_extract

2112

* Function:

2113

* Extract the physical page address associated

2114

* with the given map/virtual_address pair.

2115

2116

2117

vm_offset_t pmap_extract(pmap, va)

2118

pmap_t pmap;

2119

vm_offset_t va;

2120

{

2121

pt_entry_t *pte;

2122

vm_offset_t pa;

2123

int spl;

2124

2125

SPLVM(spl)((void)(spl));

2126

simple_lock(&pmap->lock);

2127

if ((pte = pmap_pte(pmap, va)) == PT_ENTRY_NULL((pt_entry_t *) 0))

2128

pa = (vm_offset_t) 0;

2129

else if (!(*pte & INTEL_PTE_VALID0x00000001))

2130

pa = (vm_offset_t) 0;

2131

else

2132

pa = pte_to_pa(*pte)((*pte) & 0xfffff000) + (va & INTEL_OFFMASK0xfff);

2133

simple_unlock(&pmap->lock);

2134

SPLX(spl)((void)(spl));

2135

return(pa);

2136

}

2137

2138

2139

* Copy the range specified by src_addr/len

2140

* from the source map to the range dst_addr/len

2141

* in the destination map.

2142

2143

* This routine is only advisory and need not do anything.

2144

2145

#if 0

2146

void pmap_copy(dst_pmap, src_pmap, dst_addr, len, src_addr)

2147

pmap_t dst_pmap;

2148

pmap_t src_pmap;

2149

vm_offset_t dst_addr;

2150

vm_size_t len;

2151

vm_offset_t src_addr;

2152

{

2153

}

2154

#endif /* 0 */

2155

2156

2157

* Routine: pmap_collect

2158

* Function:

2159

* Garbage collects the physical map system for

2160

* pages which are no longer used.

2161

* Success need not be guaranteed -- that is, there

2162

* may well be pages which are not referenced, but

2163

* others may be collected.

2164

* Usage:

2165

* Called by the pageout daemon when pages are scarce.

2166

2167

void pmap_collect(p)

2168

pmap_t p;

2169

{

2170

pt_entry_t *pdp, *ptp;

2171

pt_entry_t *eptp;

2172

vm_offset_t pa;

2173

int spl, wired;

2174

2175

if (p == PMAP_NULL((pmap_t) 0))

2176

return;

2177

2178

if (p == kernel_pmap)

2179

return;

2180

2181

2182

* Garbage collect map.

2183

2184

PMAP_READ_LOCK(p, spl)((void)(spl));

2185

for (pdp = p->dirbase;

2186

pdp < &p->dirbase[lin2pdenum(LINEAR_MIN_KERNEL_ADDRESS)(((((0xc0000000UL))) >> 22) & 0x3ff)];

2187

pdp += ptes_per_vm_page1)

2188

{

2189

if (*pdp & INTEL_PTE_VALID0x00000001) {

2190

2191

pa = pte_to_pa(*pdp)((*pdp) & 0xfffff000);

2192

ptp = (pt_entry_t *)phystokv(pa)((vm_offset_t)(pa) + 0xC0000000UL);

2193

eptp = ptp + NPTES((((unsigned long)(1)) << 12)/sizeof(pt_entry_t))*ptes_per_vm_page1;

2194

2195

2196

* If the pte page has any wired mappings, we cannot

2197

* free it.

2198

2199

wired = 0;

2200

{

2201

pt_entry_t *ptep;

2202

for (ptep = ptp; ptep < eptp; ptep++) {

2203

if (*ptep & INTEL_PTE_WIRED0x00000200) {

2204

wired = 1;

2205

break;

2206

}

2207

}

2208

}

2209

if (!wired) {

2210

2211

* Remove the virtual addresses mapped by this pte page.

2212

2213

{ /*XXX big hack*/

2214

vm_offset_t va = pdenum2lin(pdp - p->dirbase)((vm_offset_t)(pdp - p->dirbase) << 22);

2215

if (p == kernel_pmap)

2216

va = lintokv(va)((vm_offset_t)(va) - ((0xc0000000UL)) + 0xC0000000UL);

2217

pmap_remove_range(p,

2218

va,

2219

ptp,

2220

eptp);

2221

}

2222

2223

2224

* Invalidate the page directory pointer.

2225

2226

{

2227

int i = ptes_per_vm_page1;

2228

pt_entry_t *pdep = pdp;

2229

do {

2230

#ifdef MACH_PV_PAGETABLES

2231

unsigned long pte = *pdep;

2232

void *ptable = (void*) ptetokv(pte)(((vm_offset_t)(((pte) & 0xfffff000)) + 0xC0000000UL));

2233

if (!(hyp_mmu_update_pte(pa_to_ma(kvtophys((vm_offset_t)pdep++)), 0)))

2234

panic("%s:%d could not clear pde %p\n",__FILE__"../i386/intel/pmap.c",__LINE__2234,pdep-1);

2235

if (!hyp_mmuext_op_mfn (MMUEXT_UNPIN_TABLE, kv_to_mfn(ptable)))

2236

panic("couldn't unpin page %p(%p)\n", ptable, (vm_offset_t) pa_to_ma(kvtophys((vm_offset_t)ptable)));

2237

pmap_set_page_readwrite(ptable);

2238

#else /* MACH_PV_PAGETABLES */

2239

*pdep++ = 0;

2240

#endif /* MACH_PV_PAGETABLES */

2241

} while (--i > 0);

2242

}

2243

2244

PMAP_READ_UNLOCK(p, spl)((void)(spl));

2245

2246

2247

* And free the pte page itself.

2248

2249

{

2250

vm_page_t m;

2251

2252

vm_object_lock(pmap_object);

2253

m = vm_page_lookup(pmap_object, pa);

2254

if (m == VM_PAGE_NULL((vm_page_t) 0))

2255

panic("pmap_collect: pte page not in object");

2256

vm_page_lock_queues();

2257

vm_page_free(m);

2258

inuse_ptepages_count--;

2259

vm_page_unlock_queues();

2260

vm_object_unlock(pmap_object);

2261

}

2262

2263

PMAP_READ_LOCK(p, spl)((void)(spl));

2264

}

2265

}

2266

}

2267

PMAP_UPDATE_TLBS(p, VM_MIN_ADDRESS, VM_MAX_ADDRESS){ if ((p)->cpus_using) { { (void) ((p)); (void) (((0))); (
void) (((0xc0000000UL))); ({ register unsigned long _temp__ =
(({ register unsigned long _temp__; asm volatile("mov %%cr3, %0"
: "=r" (_temp__)); _temp__; })); asm volatile("mov %0, %%cr3"
: : "r" (_temp__) : "memory"); }); }; } };

2268

2269

PMAP_READ_UNLOCK(p, spl)((void)(spl));

2270

return;

2271

2272

}

2273

2274

2275

* Routine: pmap_activate

2276

* Function:

2277

* Binds the given physical map to the given

2278

* processor, and returns a hardware map description.

2279

2280

#if 0

2281

void pmap_activate(my_pmap, th, my_cpu)

2282

2283

thread_t th;

2284

int my_cpu;

2285

{

2286

PMAP_ACTIVATE(my_pmap, th, my_cpu);

2287

}

2288

#endif /* 0 */

2289

2290

2291

* Routine: pmap_deactivate

2292

* Function:

2293

* Indicates that the given physical map is no longer

2294

* in use on the specified processor. (This is a macro

2295

* in pmap.h)

2296

2297

#if 0

2298

void pmap_deactivate(pmap, th, which_cpu)

2299

pmap_t pmap;

2300

thread_t th;

2301

int which_cpu;

2302

{

2303

PMAP_DEACTIVATE(pmap, th, which_cpu);

2304

}

2305

#endif /* 0 */

2306

2307

2308

* Routine: pmap_kernel

2309

* Function:

2310

* Returns the physical map handle for the kernel.

2311

2312

#if 0

2313

pmap_t pmap_kernel()(kernel_pmap)

2314

{

2315

return (kernel_pmap);

2316

}

2317

#endif /* 0 */

2318

2319

2320

* pmap_zero_page zeros the specified (machine independent) page.

2321

* See machine/phys.c or machine/phys.s for implementation.

2322

2323

#if 0

2324

pmap_zero_page(phys)

2325

2326

{

2327

2328

2329

assert(phys != vm_page_fictitious_addr)({ if (!(phys != vm_page_fictitious_addr)) Assert("phys != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 2329); });

2330

i = PAGE_SIZE(1 << 12) / INTEL_PGBYTES4096;

2331

phys = intel_pfn(phys);

2332

2333

while (i--)

2334

zero_phys(phys++);

2335

}

2336

#endif /* 0 */

2337

2338

2339

* pmap_copy_page copies the specified (machine independent) page.

2340

* See machine/phys.c or machine/phys.s for implementation.

2341

2342

#if 0

2343

pmap_copy_page(src, dst)

2344

vm_offset_t src, dst;

2345

{

2346

int i;

2347

2348

assert(src != vm_page_fictitious_addr)({ if (!(src != vm_page_fictitious_addr)) Assert("src != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 2348); });

2349

assert(dst != vm_page_fictitious_addr)({ if (!(dst != vm_page_fictitious_addr)) Assert("dst != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 2349); });

2350

i = PAGE_SIZE(1 << 12) / INTEL_PGBYTES4096;

2351

2352

while (i--) {

2353

copy_phys(intel_pfn(src), intel_pfn(dst));

2354

src += INTEL_PGBYTES4096;

2355

dst += INTEL_PGBYTES4096;

2356

}

2357

}

2358

#endif /* 0 */

2359

2360

2361

* Routine: pmap_pageable

2362

* Function:

2363

* Make the specified pages (by pmap, offset)

2364

* pageable (or not) as requested.

2365

2366

* A page which is not pageable may not take

2367

* a fault; therefore, its page table entry

2368

* must remain valid for the duration.

2369

2370

* This routine is merely advisory; pmap_enter

2371

* will specify that these pages are to be wired

2372

* down (or not) as appropriate.

2373

2374

void

2375

pmap_pageable(pmap, start, end, pageable)

2376

pmap_t pmap;

2377

vm_offset_t start;

2378

vm_offset_t end;

2379

boolean_t pageable;

2380

{

2381

}

2382

2383

2384

* Clear specified attribute bits.

2385

2386

void

2387

phys_attribute_clear(phys, bits)

2388

vm_offset_t phys;

2389

int bits;

2390

{

2391

pv_entry_t pv_h;

2392

pv_entry_t pv_e;

2393

pt_entry_t *pte;

2394

int pai;

2395

pmap_t pmap;

2396

int spl;

2397

2398

assert(phys != vm_page_fictitious_addr)({ if (!(phys != vm_page_fictitious_addr)) Assert("phys != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 2398); });

2399

if (!valid_page(phys)(pmap_initialized && pmap_valid_page(phys))) {

2400

2401

* Not a managed page.

2402

2403

return;

2404

}

2405

2406

2407

* Lock the pmap system first, since we will be changing

2408

* several pmaps.

2409

2410

2411

PMAP_WRITE_LOCK(spl)((void)(spl));

2412

2413

pai = pa_index(phys)((((vm_size_t)(phys - phys_first_addr)) >> 12));

2414

pv_h = pai_to_pvh(pai)(&pv_head_table[pai]);

2415

2416

2417

* Walk down PV list, clearing all modify or reference bits.

2418

* We do not have to lock the pv_list because we have

2419

* the entire pmap system locked.

2420

2421

if (pv_h->pmap != PMAP_NULL((pmap_t) 0)) {

2422

2423

* There are some mappings.

2424

2425

for (pv_e = pv_h; pv_e != PV_ENTRY_NULL((pv_entry_t) 0); pv_e = pv_e->next) {

2426

vm_offset_t va;

2427

2428

pmap = pv_e->pmap;

2429

2430

* Lock the pmap to block pmap_extract and similar routines.

2431

2432

simple_lock(&pmap->lock);

2433

2434

va = pv_e->va;

2435

pte = pmap_pte(pmap, va);

2436

2437

#if 0

2438

2439

* Consistency checks.

2440

2441

assert(*pte & INTEL_PTE_VALID)({ if (!(*pte & 0x00000001)) Assert("*pte & INTEL_PTE_VALID"
, "../i386/intel/pmap.c", 2441); });

2442

/* assert(pte_to_phys(*pte) == phys); */

2443

#endif

2444

2445

2446

* Clear modify or reference bits.

2447

2448

{

2449

int i = ptes_per_vm_page1;

2450

do {

2451

#ifdef MACH_PV_PAGETABLES

2452

if (!(hyp_mmu_update_pte(kv_to_ma(pte), *pte & ~bits)))

2453

panic("%s:%d could not clear bits %lx from pte %p\n",__FILE__"../i386/intel/pmap.c",__LINE__2453,bits,pte);

2454

#else /* MACH_PV_PAGETABLES */

2455

*pte &= ~bits;

2456

#endif /* MACH_PV_PAGETABLES */

2457

} while (--i > 0);

2458

}

2459

2460

simple_unlock(&pmap->lock);

2461

}

2462

}

2463

2464

pmap_phys_attributes[pai] &= ~bits;

2465

2466

PMAP_WRITE_UNLOCK(spl)((void)(spl));

2467

}

2468

2469

2470

* Check specified attribute bits.

2471

2472

boolean_t

2473

phys_attribute_test(phys, bits)

2474

vm_offset_t phys;

2475

int bits;

2476

{

2477

pv_entry_t pv_h;

2478

pv_entry_t pv_e;

2479

pt_entry_t *pte;

2480

int pai;

2481

pmap_t pmap;

2482

int spl;

2483

2484

assert(phys != vm_page_fictitious_addr)({ if (!(phys != vm_page_fictitious_addr)) Assert("phys != vm_page_fictitious_addr"
, "../i386/intel/pmap.c", 2484); });

2485

if (!valid_page(phys)(pmap_initialized && pmap_valid_page(phys))) {

2486

2487

* Not a managed page.

2488

2489

return (FALSE((boolean_t) 0));

2490

}

2491

2492

2493

* Lock the pmap system first, since we will be checking

2494

* several pmaps.

2495

2496

2497

PMAP_WRITE_LOCK(spl)((void)(spl));

2498

2499

pai = pa_index(phys)((((vm_size_t)(phys - phys_first_addr)) >> 12));

2500

pv_h = pai_to_pvh(pai)(&pv_head_table[pai]);

2501

2502

if (pmap_phys_attributes[pai] & bits) {

2503

PMAP_WRITE_UNLOCK(spl)((void)(spl));

2504

return (TRUE((boolean_t) 1));

2505

}

2506

2507

2508

* Walk down PV list, checking all mappings.

2509

* We do not have to lock the pv_list because we have

2510

* the entire pmap system locked.

2511

2512

if (pv_h->pmap != PMAP_NULL((pmap_t) 0)) {

2513

2514

* There are some mappings.

2515

2516

for (pv_e = pv_h; pv_e != PV_ENTRY_NULL((pv_entry_t) 0); pv_e = pv_e->next) {

2517

2518

pmap = pv_e->pmap;

2519

2520

* Lock the pmap to block pmap_extract and similar routines.

2521

2522

simple_lock(&pmap->lock);

2523

2524

{

2525

vm_offset_t va;

2526

2527

va = pv_e->va;

2528

pte = pmap_pte(pmap, va);

2529

2530

#if 0

2531

2532

* Consistency checks.

2533

2534

assert(*pte & INTEL_PTE_VALID)({ if (!(*pte & 0x00000001)) Assert("*pte & INTEL_PTE_VALID"
, "../i386/intel/pmap.c", 2534); });

2535

/* assert(pte_to_phys(*pte) == phys); */

2536

#endif

2537

}

2538

2539

2540

* Check modify or reference bits.

2541

2542

{

2543

int i = ptes_per_vm_page1;

2544

2545

do {

2546

if (*pte & bits) {

2547

simple_unlock(&pmap->lock);

2548

PMAP_WRITE_UNLOCK(spl)((void)(spl));

2549

return (TRUE((boolean_t) 1));

2550

}

2551

} while (--i > 0);

2552

}

2553

simple_unlock(&pmap->lock);

2554

}

2555

}

2556

PMAP_WRITE_UNLOCK(spl)((void)(spl));

2557

return (FALSE((boolean_t) 0));

2558

}

2559

2560

2561

* Clear the modify bits on the specified physical page.

2562

2563

2564

void pmap_clear_modify(phys)

2565

vm_offset_t phys;

2566

{

2567

phys_attribute_clear(phys, PHYS_MODIFIED0x00000040);

2568

}

2569

2570

2571

* pmap_is_modified:

2572

2573

* Return whether or not the specified physical page is modified

2574

* by any physical maps.

2575

2576

2577

boolean_t pmap_is_modified(phys)

2578

vm_offset_t phys;

2579

{

2580

return (phys_attribute_test(phys, PHYS_MODIFIED0x00000040));

2581

}

2582

2583

2584

* pmap_clear_reference:

2585

2586

* Clear the reference bit on the specified physical page.

2587

2588

2589

void pmap_clear_reference(phys)

2590

vm_offset_t phys;

2591

{

2592

phys_attribute_clear(phys, PHYS_REFERENCED0x00000020);

2593

}

2594

2595

2596

* pmap_is_referenced:

2597

2598

* Return whether or not the specified physical page is referenced

2599

* by any physical maps.

2600

2601

2602

boolean_t pmap_is_referenced(phys)

2603

vm_offset_t phys;

2604

{

2605

return (phys_attribute_test(phys, PHYS_REFERENCED0x00000020));

2606

}

2607

2608

#if NCPUS1 > 1

2609

2610

* TLB Coherence Code (TLB "shootdown" code)

2611

2612

* Threads that belong to the same task share the same address space and

2613

* hence share a pmap. However, they may run on distinct cpus and thus

2614

* have distinct TLBs that cache page table entries. In order to guarantee

2615

* the TLBs are consistent, whenever a pmap is changed, all threads that

2616

* are active in that pmap must have their TLB updated. To keep track of

2617

* this information, the set of cpus that are currently using a pmap is

2618

* maintained within each pmap structure (cpus_using). Pmap_activate() and

2619

* pmap_deactivate add and remove, respectively, a cpu from this set.

2620

* Since the TLBs are not addressable over the bus, each processor must

2621

* flush its own TLB; a processor that needs to invalidate another TLB

2622

* needs to interrupt the processor that owns that TLB to signal the

2623

* update.

2624

2625

* Whenever a pmap is updated, the lock on that pmap is locked, and all

2626

* cpus using the pmap are signaled to invalidate. All threads that need

2627

* to activate a pmap must wait for the lock to clear to await any updates

2628

* in progress before using the pmap. They must ACQUIRE the lock to add

2629

* their cpu to the cpus_using set. An implicit assumption made

2630

* throughout the TLB code is that all kernel code that runs at or higher

2631

* than splvm blocks out update interrupts, and that such code does not

2632

* touch pageable pages.

2633

2634

* A shootdown interrupt serves another function besides signaling a

2635

* processor to invalidate. The interrupt routine (pmap_update_interrupt)

2636

* waits for the both the pmap lock (and the kernel pmap lock) to clear,

2637

* preventing user code from making implicit pmap updates while the

2638

* sending processor is performing its update. (This could happen via a

2639

* user data write reference that turns on the modify bit in the page

2640

* table). It must wait for any kernel updates that may have started

2641

* concurrently with a user pmap update because the IPC code

2642

* changes mappings.

2643

* Spinning on the VALUES of the locks is sufficient (rather than

2644

* having to acquire the locks) because any updates that occur subsequent

2645

* to finding the lock unlocked will be signaled via another interrupt.

2646

* (This assumes the interrupt is cleared before the low level interrupt code

2647

* calls pmap_update_interrupt()).

2648

2649

* The signaling processor must wait for any implicit updates in progress

2650

* to terminate before continuing with its update. Thus it must wait for an

2651

* acknowledgement of the interrupt from each processor for which such

2652

* references could be made. For maintaining this information, a set

2653

* cpus_active is used. A cpu is in this set if and only if it can

2654

* use a pmap. When pmap_update_interrupt() is entered, a cpu is removed from

2655

* this set; when all such cpus are removed, it is safe to update.

2656

2657

* Before attempting to acquire the update lock on a pmap, a cpu (A) must

2658

* be at least at the priority of the interprocessor interrupt

2659

* (splip<=splvm). Otherwise, A could grab a lock and be interrupted by a

2660

* kernel update; it would spin forever in pmap_update_interrupt() trying

2661

* to acquire the user pmap lock it had already acquired. Furthermore A

2662

* must remove itself from cpus_active. Otherwise, another cpu holding

2663

* the lock (B) could be in the process of sending an update signal to A,

2664

* and thus be waiting for A to remove itself from cpus_active. If A is

2665

* spinning on the lock at priority this will never happen and a deadlock

2666

* will result.

2667

2668

2669

2670

* Signal another CPU that it must flush its TLB

2671

2672

void signal_cpus(use_list, pmap, start, end)

2673

cpu_set use_list;

2674

pmap_t pmap;

2675

vm_offset_t start, end;

2676

{

2677

int which_cpu, j;

2678

pmap_update_list_t update_list_p;

2679

2680

while ((which_cpu = ffs(use_list)) != 0) {

2681

which_cpu -= 1; /* convert to 0 origin */

2682

2683

update_list_p = &cpu_update_list[which_cpu];

2684

simple_lock(&update_list_p->lock);

2685

2686

j = update_list_p->count;

2687

if (j >= UPDATE_LIST_SIZE) {

2688

2689

* list overflowed. Change last item to

2690

* indicate overflow.

2691

2692

update_list_p->item[UPDATE_LIST_SIZE-1].pmap = kernel_pmap;

2693

update_list_p->item[UPDATE_LIST_SIZE-1].start = VM_MIN_ADDRESS(0);

2694

update_list_p->item[UPDATE_LIST_SIZE-1].end = VM_MAX_KERNEL_ADDRESS((0xffffffffUL) - ((0xc0000000UL)) + 0xC0000000UL);

2695

}

2696

else {

2697

update_list_p->item[j].pmap = pmap;

2698

update_list_p->item[j].start = start;

2699

update_list_p->item[j].end = end;

2700

update_list_p->count = j+1;

2701

}

2702

cpu_update_needed[which_cpu] = TRUE((boolean_t) 1);

2703

simple_unlock(&update_list_p->lock);

2704

2705

if ((cpus_idle & (1 << which_cpu)) == 0)

2706

interrupt_processor(which_cpu);

2707

use_list &= ~(1 << which_cpu);

2708

}

2709

}

2710

2711

void process_pmap_updates(my_pmap)

2712

pmap_t my_pmap;

2713

{

2714

int my_cpu = cpu_number()(0);

2715

pmap_update_list_t update_list_p;

2716

int j;

2717

pmap_t pmap;

2718

2719

update_list_p = &cpu_update_list[my_cpu];

2720

simple_lock(&update_list_p->lock);

2721

2722

for (j = 0; j < update_list_p->count; j++) {

2723

pmap = update_list_p->item[j].pmap;

2724

if (pmap == my_pmap ||

2725

pmap == kernel_pmap) {

2726

2727

INVALIDATE_TLB(pmap,{ (void) (pmap); (void) (update_list_p->item[j].start); (void
) (update_list_p->item[j].end); ({ register unsigned long _temp__
= (({ register unsigned long _temp__; asm volatile("mov %%cr3, %0"
: "=r" (_temp__)); _temp__; })); asm volatile("mov %0, %%cr3"
: : "r" (_temp__) : "memory"); }); }

2728

update_list_p->item[j].start,{ (void) (pmap); (void) (update_list_p->item[j].start); (void
) (update_list_p->item[j].end); ({ register unsigned long _temp__
= (({ register unsigned long _temp__; asm volatile("mov %%cr3, %0"
: "=r" (_temp__)); _temp__; })); asm volatile("mov %0, %%cr3"
: : "r" (_temp__) : "memory"); }); }

2729

update_list_p->item[j].end){ (void) (pmap); (void) (update_list_p->item[j].start); (void
) (update_list_p->item[j].end); ({ register unsigned long _temp__
= (({ register unsigned long _temp__; asm volatile("mov %%cr3, %0"
: "=r" (_temp__)); _temp__; })); asm volatile("mov %0, %%cr3"
: : "r" (_temp__) : "memory"); }); };

2730

}

2731

}

2732

update_list_p->count = 0;

2733

cpu_update_needed[my_cpu] = FALSE((boolean_t) 0);

2734

simple_unlock(&update_list_p->lock);

2735

}

2736

2737

2738

* Interrupt routine for TBIA requested from other processor.

2739

2740

void pmap_update_interrupt(void)

2741

{

2742

int my_cpu;

2743

pmap_t my_pmap;

2744

int s;

2745

2746

my_cpu = cpu_number()(0);

2747

2748

2749

* Exit now if we're idle. We'll pick up the update request

2750

* when we go active, and we must not put ourselves back in

2751

* the active set because we'll never process the interrupt

2752

* while we're idle (thus hanging the system).

2753

2754

if (cpus_idle & (1 << my_cpu))

2755

return;

2756

2757

if (current_thread()(active_threads[(0)]) == THREAD_NULL((thread_t) 0))

2758

my_pmap = kernel_pmap;

2759

else {

2760

my_pmap = current_pmap()((((active_threads[(0)])->task->map)->pmap));

2761

if (!pmap_in_use(my_pmap, my_cpu)(((my_pmap)->cpus_using & (1 << (my_cpu))) != 0))

2762

my_pmap = kernel_pmap;

2763

}

2764

2765

2766

* Raise spl to splvm (above splip) to block out pmap_extract

2767

* from IO code (which would put this cpu back in the active

2768

* set).

2769

2770

s = splvm();

2771

2772

do {

2773

2774

2775

* Indicate that we're not using either user or kernel

2776

* pmap.

2777

2778

i_bit_clear(my_cpu, &cpus_active);

2779

2780

2781

* Wait for any pmap updates in progress, on either user

2782

* or kernel pmap.

2783

2784

while (*(volatile int *)&my_pmap->lock.lock_data ||

2785

*(volatile int *)&kernel_pmap->lock.lock_data)

2786

continue;

2787

2788

process_pmap_updates(my_pmap);

2789

2790

i_bit_set(my_cpu, &cpus_active);

2791

2792

} while (cpu_update_needed[my_cpu]);

2793

2794

splx(s);

2795

}

2796

#else /* NCPUS > 1 */

2797

2798

* Dummy routine to satisfy external reference.

2799

2800

void pmap_update_interrupt()

2801

{

2802

/* should never be called. */

2803

}

2804

#endif /* NCPUS > 1 */

2805

2806

#if defined(__i386__1)

2807

/* Unmap page 0 to trap NULL references. */

2808

void

2809

pmap_unmap_page_zero ()

2810

{

2811

int *pte;

2812

2813

pte = (int *) pmap_pte (kernel_pmap, 0);

2814

if (!pte)

2815

return;

2816

assert (pte)({ if (!(pte)) Assert("pte", "../i386/intel/pmap.c", 2816); }
);

2817

#ifdef MACH_PV_PAGETABLES

2818

if (!hyp_mmu_update_pte(kv_to_ma(pte), 0))

2819

printf("couldn't unmap page 0\n");

2820

#else /* MACH_PV_PAGETABLES */

2821

*pte = 0;

2822

INVALIDATE_TLB(kernel_pmap, 0, PAGE_SIZE){ (void) (kernel_pmap); (void) (0); (void) ((1 << 12));
({ register unsigned long _temp__ = (({ register unsigned long
_temp__; asm volatile("mov %%cr3, %0" : "=r" (_temp__)); _temp__
; })); asm volatile("mov %0, %%cr3" : : "r" (_temp__) : "memory"
); }); };

2823

#endif /* MACH_PV_PAGETABLES */

2824

}

2825

#endif /* __i386__ */