1 // SPDX-License-Identifier: MIT 2 /* 3 * Copyright © 2024 Intel Corporation 4 */ 5 6 #include "xe_bo.h" 7 #include "xe_gt_tlb_invalidation.h" 8 #include "xe_migrate.h" 9 #include "xe_module.h" 10 #include "xe_pt.h" 11 #include "xe_svm.h" 12 #include "xe_ttm_vram_mgr.h" 13 #include "xe_vm.h" 14 #include "xe_vm_types.h" 15 16 static bool xe_svm_range_in_vram(struct xe_svm_range *range) 17 { 18 /* 19 * Advisory only check whether the range is currently backed by VRAM 20 * memory. 21 */ 22 23 struct drm_gpusvm_range_flags flags = { 24 /* Pairs with WRITE_ONCE in drm_gpusvm.c */ 25 .__flags = READ_ONCE(range->base.flags.__flags), 26 }; 27 28 return flags.has_devmem_pages; 29 } 30 31 static bool xe_svm_range_has_vram_binding(struct xe_svm_range *range) 32 { 33 /* Not reliable without notifier lock */ 34 return xe_svm_range_in_vram(range) && range->tile_present; 35 } 36 37 static struct xe_vm *gpusvm_to_vm(struct drm_gpusvm *gpusvm) 38 { 39 return container_of(gpusvm, struct xe_vm, svm.gpusvm); 40 } 41 42 static struct xe_vm *range_to_vm(struct drm_gpusvm_range *r) 43 { 44 return gpusvm_to_vm(r->gpusvm); 45 } 46 47 static unsigned long xe_svm_range_start(struct xe_svm_range *range) 48 { 49 return drm_gpusvm_range_start(&range->base); 50 } 51 52 static unsigned long xe_svm_range_end(struct xe_svm_range *range) 53 { 54 return drm_gpusvm_range_end(&range->base); 55 } 56 57 static unsigned long xe_svm_range_size(struct xe_svm_range *range) 58 { 59 return drm_gpusvm_range_size(&range->base); 60 } 61 62 #define range_debug(r__, operaton__) \ 63 vm_dbg(&range_to_vm(&(r__)->base)->xe->drm, \ 64 "%s: asid=%u, gpusvm=%p, vram=%d,%d, seqno=%lu, " \ 65 "start=0x%014lx, end=0x%014lx, size=%lu", \ 66 (operaton__), range_to_vm(&(r__)->base)->usm.asid, \ 67 (r__)->base.gpusvm, \ 68 xe_svm_range_in_vram((r__)) ? 1 : 0, \ 69 xe_svm_range_has_vram_binding((r__)) ? 1 : 0, \ 70 (r__)->base.notifier_seq, \ 71 xe_svm_range_start((r__)), xe_svm_range_end((r__)), \ 72 xe_svm_range_size((r__))) 73 74 void xe_svm_range_debug(struct xe_svm_range *range, const char *operation) 75 { 76 range_debug(range, operation); 77 } 78 79 static void *xe_svm_devm_owner(struct xe_device *xe) 80 { 81 return xe; 82 } 83 84 static struct drm_gpusvm_range * 85 xe_svm_range_alloc(struct drm_gpusvm *gpusvm) 86 { 87 struct xe_svm_range *range; 88 89 range = kzalloc(sizeof(*range), GFP_KERNEL); 90 if (!range) 91 return NULL; 92 93 INIT_LIST_HEAD(&range->garbage_collector_link); 94 xe_vm_get(gpusvm_to_vm(gpusvm)); 95 96 return &range->base; 97 } 98 99 static void xe_svm_range_free(struct drm_gpusvm_range *range) 100 { 101 xe_vm_put(range_to_vm(range)); 102 kfree(range); 103 } 104 105 static struct xe_svm_range *to_xe_range(struct drm_gpusvm_range *r) 106 { 107 return container_of(r, struct xe_svm_range, base); 108 } 109 110 static void 111 xe_svm_garbage_collector_add_range(struct xe_vm *vm, struct xe_svm_range *range, 112 const struct mmu_notifier_range *mmu_range) 113 { 114 struct xe_device *xe = vm->xe; 115 116 range_debug(range, "GARBAGE COLLECTOR ADD"); 117 118 drm_gpusvm_range_set_unmapped(&range->base, mmu_range); 119 120 spin_lock(&vm->svm.garbage_collector.lock); 121 if (list_empty(&range->garbage_collector_link)) 122 list_add_tail(&range->garbage_collector_link, 123 &vm->svm.garbage_collector.range_list); 124 spin_unlock(&vm->svm.garbage_collector.lock); 125 126 queue_work(xe_device_get_root_tile(xe)->primary_gt->usm.pf_wq, 127 &vm->svm.garbage_collector.work); 128 } 129 130 static u8 131 xe_svm_range_notifier_event_begin(struct xe_vm *vm, struct drm_gpusvm_range *r, 132 const struct mmu_notifier_range *mmu_range, 133 u64 *adj_start, u64 *adj_end) 134 { 135 struct xe_svm_range *range = to_xe_range(r); 136 struct xe_device *xe = vm->xe; 137 struct xe_tile *tile; 138 u8 tile_mask = 0; 139 u8 id; 140 141 xe_svm_assert_in_notifier(vm); 142 143 range_debug(range, "NOTIFIER"); 144 145 /* Skip if already unmapped or if no binding exist */ 146 if (range->base.flags.unmapped || !range->tile_present) 147 return 0; 148 149 range_debug(range, "NOTIFIER - EXECUTE"); 150 151 /* Adjust invalidation to range boundaries */ 152 *adj_start = min(xe_svm_range_start(range), mmu_range->start); 153 *adj_end = max(xe_svm_range_end(range), mmu_range->end); 154 155 /* 156 * XXX: Ideally would zap PTEs in one shot in xe_svm_invalidate but the 157 * invalidation code can't correctly cope with sparse ranges or 158 * invalidations spanning multiple ranges. 159 */ 160 for_each_tile(tile, xe, id) 161 if (xe_pt_zap_ptes_range(tile, vm, range)) { 162 tile_mask |= BIT(id); 163 range->tile_invalidated |= BIT(id); 164 } 165 166 return tile_mask; 167 } 168 169 static void 170 xe_svm_range_notifier_event_end(struct xe_vm *vm, struct drm_gpusvm_range *r, 171 const struct mmu_notifier_range *mmu_range) 172 { 173 struct drm_gpusvm_ctx ctx = { .in_notifier = true, }; 174 175 xe_svm_assert_in_notifier(vm); 176 177 drm_gpusvm_range_unmap_pages(&vm->svm.gpusvm, r, &ctx); 178 if (!xe_vm_is_closed(vm) && mmu_range->event == MMU_NOTIFY_UNMAP) 179 xe_svm_garbage_collector_add_range(vm, to_xe_range(r), 180 mmu_range); 181 } 182 183 static void xe_svm_invalidate(struct drm_gpusvm *gpusvm, 184 struct drm_gpusvm_notifier *notifier, 185 const struct mmu_notifier_range *mmu_range) 186 { 187 struct xe_vm *vm = gpusvm_to_vm(gpusvm); 188 struct xe_device *xe = vm->xe; 189 struct xe_tile *tile; 190 struct drm_gpusvm_range *r, *first; 191 struct xe_gt_tlb_invalidation_fence 192 fence[XE_MAX_TILES_PER_DEVICE * XE_MAX_GT_PER_TILE]; 193 u64 adj_start = mmu_range->start, adj_end = mmu_range->end; 194 u8 tile_mask = 0; 195 u8 id; 196 u32 fence_id = 0; 197 long err; 198 199 xe_svm_assert_in_notifier(vm); 200 201 vm_dbg(&gpusvm_to_vm(gpusvm)->xe->drm, 202 "INVALIDATE: asid=%u, gpusvm=%p, seqno=%lu, start=0x%016lx, end=0x%016lx, event=%d", 203 vm->usm.asid, gpusvm, notifier->notifier.invalidate_seq, 204 mmu_range->start, mmu_range->end, mmu_range->event); 205 206 /* Adjust invalidation to notifier boundaries */ 207 adj_start = max(drm_gpusvm_notifier_start(notifier), adj_start); 208 adj_end = min(drm_gpusvm_notifier_end(notifier), adj_end); 209 210 first = drm_gpusvm_range_find(notifier, adj_start, adj_end); 211 if (!first) 212 return; 213 214 /* 215 * PTs may be getting destroyed so not safe to touch these but PT should 216 * be invalidated at this point in time. Regardless we still need to 217 * ensure any dma mappings are unmapped in the here. 218 */ 219 if (xe_vm_is_closed(vm)) 220 goto range_notifier_event_end; 221 222 /* 223 * XXX: Less than ideal to always wait on VM's resv slots if an 224 * invalidation is not required. Could walk range list twice to figure 225 * out if an invalidations is need, but also not ideal. 226 */ 227 err = dma_resv_wait_timeout(xe_vm_resv(vm), 228 DMA_RESV_USAGE_BOOKKEEP, 229 false, MAX_SCHEDULE_TIMEOUT); 230 XE_WARN_ON(err <= 0); 231 232 r = first; 233 drm_gpusvm_for_each_range(r, notifier, adj_start, adj_end) 234 tile_mask |= xe_svm_range_notifier_event_begin(vm, r, mmu_range, 235 &adj_start, 236 &adj_end); 237 if (!tile_mask) 238 goto range_notifier_event_end; 239 240 xe_device_wmb(xe); 241 242 for_each_tile(tile, xe, id) { 243 if (tile_mask & BIT(id)) { 244 int err; 245 246 xe_gt_tlb_invalidation_fence_init(tile->primary_gt, 247 &fence[fence_id], true); 248 249 err = xe_gt_tlb_invalidation_range(tile->primary_gt, 250 &fence[fence_id], 251 adj_start, 252 adj_end, 253 vm->usm.asid); 254 if (WARN_ON_ONCE(err < 0)) 255 goto wait; 256 ++fence_id; 257 258 if (!tile->media_gt) 259 continue; 260 261 xe_gt_tlb_invalidation_fence_init(tile->media_gt, 262 &fence[fence_id], true); 263 264 err = xe_gt_tlb_invalidation_range(tile->media_gt, 265 &fence[fence_id], 266 adj_start, 267 adj_end, 268 vm->usm.asid); 269 if (WARN_ON_ONCE(err < 0)) 270 goto wait; 271 ++fence_id; 272 } 273 } 274 275 wait: 276 for (id = 0; id < fence_id; ++id) 277 xe_gt_tlb_invalidation_fence_wait(&fence[id]); 278 279 range_notifier_event_end: 280 r = first; 281 drm_gpusvm_for_each_range(r, notifier, adj_start, adj_end) 282 xe_svm_range_notifier_event_end(vm, r, mmu_range); 283 } 284 285 static int __xe_svm_garbage_collector(struct xe_vm *vm, 286 struct xe_svm_range *range) 287 { 288 struct dma_fence *fence; 289 290 range_debug(range, "GARBAGE COLLECTOR"); 291 292 xe_vm_lock(vm, false); 293 fence = xe_vm_range_unbind(vm, range); 294 xe_vm_unlock(vm); 295 if (IS_ERR(fence)) 296 return PTR_ERR(fence); 297 dma_fence_put(fence); 298 299 drm_gpusvm_range_remove(&vm->svm.gpusvm, &range->base); 300 301 return 0; 302 } 303 304 static int xe_svm_garbage_collector(struct xe_vm *vm) 305 { 306 struct xe_svm_range *range; 307 int err; 308 309 lockdep_assert_held_write(&vm->lock); 310 311 if (xe_vm_is_closed_or_banned(vm)) 312 return -ENOENT; 313 314 spin_lock(&vm->svm.garbage_collector.lock); 315 for (;;) { 316 range = list_first_entry_or_null(&vm->svm.garbage_collector.range_list, 317 typeof(*range), 318 garbage_collector_link); 319 if (!range) 320 break; 321 322 list_del(&range->garbage_collector_link); 323 spin_unlock(&vm->svm.garbage_collector.lock); 324 325 err = __xe_svm_garbage_collector(vm, range); 326 if (err) { 327 drm_warn(&vm->xe->drm, 328 "Garbage collection failed: %pe\n", 329 ERR_PTR(err)); 330 xe_vm_kill(vm, true); 331 return err; 332 } 333 334 spin_lock(&vm->svm.garbage_collector.lock); 335 } 336 spin_unlock(&vm->svm.garbage_collector.lock); 337 338 return 0; 339 } 340 341 static void xe_svm_garbage_collector_work_func(struct work_struct *w) 342 { 343 struct xe_vm *vm = container_of(w, struct xe_vm, 344 svm.garbage_collector.work); 345 346 down_write(&vm->lock); 347 xe_svm_garbage_collector(vm); 348 up_write(&vm->lock); 349 } 350 351 static struct xe_vram_region *page_to_vr(struct page *page) 352 { 353 return container_of(page_pgmap(page), struct xe_vram_region, pagemap); 354 } 355 356 static struct xe_tile *vr_to_tile(struct xe_vram_region *vr) 357 { 358 return container_of(vr, struct xe_tile, mem.vram); 359 } 360 361 static u64 xe_vram_region_page_to_dpa(struct xe_vram_region *vr, 362 struct page *page) 363 { 364 u64 dpa; 365 struct xe_tile *tile = vr_to_tile(vr); 366 u64 pfn = page_to_pfn(page); 367 u64 offset; 368 369 xe_tile_assert(tile, is_device_private_page(page)); 370 xe_tile_assert(tile, (pfn << PAGE_SHIFT) >= vr->hpa_base); 371 372 offset = (pfn << PAGE_SHIFT) - vr->hpa_base; 373 dpa = vr->dpa_base + offset; 374 375 return dpa; 376 } 377 378 enum xe_svm_copy_dir { 379 XE_SVM_COPY_TO_VRAM, 380 XE_SVM_COPY_TO_SRAM, 381 }; 382 383 static int xe_svm_copy(struct page **pages, dma_addr_t *dma_addr, 384 unsigned long npages, const enum xe_svm_copy_dir dir) 385 { 386 struct xe_vram_region *vr = NULL; 387 struct xe_tile *tile; 388 struct dma_fence *fence = NULL; 389 unsigned long i; 390 #define XE_VRAM_ADDR_INVALID ~0x0ull 391 u64 vram_addr = XE_VRAM_ADDR_INVALID; 392 int err = 0, pos = 0; 393 bool sram = dir == XE_SVM_COPY_TO_SRAM; 394 395 /* 396 * This flow is complex: it locates physically contiguous device pages, 397 * derives the starting physical address, and performs a single GPU copy 398 * to for every 8M chunk in a DMA address array. Both device pages and 399 * DMA addresses may be sparsely populated. If either is NULL, a copy is 400 * triggered based on the current search state. The last GPU copy is 401 * waited on to ensure all copies are complete. 402 */ 403 404 for (i = 0; i < npages; ++i) { 405 struct page *spage = pages[i]; 406 struct dma_fence *__fence; 407 u64 __vram_addr; 408 bool match = false, chunk, last; 409 410 #define XE_MIGRATE_CHUNK_SIZE SZ_8M 411 chunk = (i - pos) == (XE_MIGRATE_CHUNK_SIZE / PAGE_SIZE); 412 last = (i + 1) == npages; 413 414 /* No CPU page and no device pages queue'd to copy */ 415 if (!dma_addr[i] && vram_addr == XE_VRAM_ADDR_INVALID) 416 continue; 417 418 if (!vr && spage) { 419 vr = page_to_vr(spage); 420 tile = vr_to_tile(vr); 421 } 422 XE_WARN_ON(spage && page_to_vr(spage) != vr); 423 424 /* 425 * CPU page and device page valid, capture physical address on 426 * first device page, check if physical contiguous on subsequent 427 * device pages. 428 */ 429 if (dma_addr[i] && spage) { 430 __vram_addr = xe_vram_region_page_to_dpa(vr, spage); 431 if (vram_addr == XE_VRAM_ADDR_INVALID) { 432 vram_addr = __vram_addr; 433 pos = i; 434 } 435 436 match = vram_addr + PAGE_SIZE * (i - pos) == __vram_addr; 437 } 438 439 /* 440 * Mismatched physical address, 8M copy chunk, or last page - 441 * trigger a copy. 442 */ 443 if (!match || chunk || last) { 444 /* 445 * Extra page for first copy if last page and matching 446 * physical address. 447 */ 448 int incr = (match && last) ? 1 : 0; 449 450 if (vram_addr != XE_VRAM_ADDR_INVALID) { 451 if (sram) { 452 vm_dbg(&tile->xe->drm, 453 "COPY TO SRAM - 0x%016llx -> 0x%016llx, NPAGES=%ld", 454 vram_addr, (u64)dma_addr[pos], i - pos + incr); 455 __fence = xe_migrate_from_vram(tile->migrate, 456 i - pos + incr, 457 vram_addr, 458 dma_addr + pos); 459 } else { 460 vm_dbg(&tile->xe->drm, 461 "COPY TO VRAM - 0x%016llx -> 0x%016llx, NPAGES=%ld", 462 (u64)dma_addr[pos], vram_addr, i - pos + incr); 463 __fence = xe_migrate_to_vram(tile->migrate, 464 i - pos + incr, 465 dma_addr + pos, 466 vram_addr); 467 } 468 if (IS_ERR(__fence)) { 469 err = PTR_ERR(__fence); 470 goto err_out; 471 } 472 473 dma_fence_put(fence); 474 fence = __fence; 475 } 476 477 /* Setup physical address of next device page */ 478 if (dma_addr[i] && spage) { 479 vram_addr = __vram_addr; 480 pos = i; 481 } else { 482 vram_addr = XE_VRAM_ADDR_INVALID; 483 } 484 485 /* Extra mismatched device page, copy it */ 486 if (!match && last && vram_addr != XE_VRAM_ADDR_INVALID) { 487 if (sram) { 488 vm_dbg(&tile->xe->drm, 489 "COPY TO SRAM - 0x%016llx -> 0x%016llx, NPAGES=%d", 490 vram_addr, (u64)dma_addr[pos], 1); 491 __fence = xe_migrate_from_vram(tile->migrate, 1, 492 vram_addr, 493 dma_addr + pos); 494 } else { 495 vm_dbg(&tile->xe->drm, 496 "COPY TO VRAM - 0x%016llx -> 0x%016llx, NPAGES=%d", 497 (u64)dma_addr[pos], vram_addr, 1); 498 __fence = xe_migrate_to_vram(tile->migrate, 1, 499 dma_addr + pos, 500 vram_addr); 501 } 502 if (IS_ERR(__fence)) { 503 err = PTR_ERR(__fence); 504 goto err_out; 505 } 506 507 dma_fence_put(fence); 508 fence = __fence; 509 } 510 } 511 } 512 513 err_out: 514 /* Wait for all copies to complete */ 515 if (fence) { 516 dma_fence_wait(fence, false); 517 dma_fence_put(fence); 518 } 519 520 return err; 521 #undef XE_MIGRATE_CHUNK_SIZE 522 #undef XE_VRAM_ADDR_INVALID 523 } 524 525 static int xe_svm_copy_to_devmem(struct page **pages, dma_addr_t *dma_addr, 526 unsigned long npages) 527 { 528 return xe_svm_copy(pages, dma_addr, npages, XE_SVM_COPY_TO_VRAM); 529 } 530 531 static int xe_svm_copy_to_ram(struct page **pages, dma_addr_t *dma_addr, 532 unsigned long npages) 533 { 534 return xe_svm_copy(pages, dma_addr, npages, XE_SVM_COPY_TO_SRAM); 535 } 536 537 static struct xe_bo *to_xe_bo(struct drm_gpusvm_devmem *devmem_allocation) 538 { 539 return container_of(devmem_allocation, struct xe_bo, devmem_allocation); 540 } 541 542 static void xe_svm_devmem_release(struct drm_gpusvm_devmem *devmem_allocation) 543 { 544 struct xe_bo *bo = to_xe_bo(devmem_allocation); 545 546 xe_bo_put_async(bo); 547 } 548 549 static u64 block_offset_to_pfn(struct xe_vram_region *vr, u64 offset) 550 { 551 return PHYS_PFN(offset + vr->hpa_base); 552 } 553 554 static struct drm_buddy *tile_to_buddy(struct xe_tile *tile) 555 { 556 return &tile->mem.vram.ttm.mm; 557 } 558 559 static int xe_svm_populate_devmem_pfn(struct drm_gpusvm_devmem *devmem_allocation, 560 unsigned long npages, unsigned long *pfn) 561 { 562 struct xe_bo *bo = to_xe_bo(devmem_allocation); 563 struct ttm_resource *res = bo->ttm.resource; 564 struct list_head *blocks = &to_xe_ttm_vram_mgr_resource(res)->blocks; 565 struct drm_buddy_block *block; 566 int j = 0; 567 568 list_for_each_entry(block, blocks, link) { 569 struct xe_vram_region *vr = block->private; 570 struct xe_tile *tile = vr_to_tile(vr); 571 struct drm_buddy *buddy = tile_to_buddy(tile); 572 u64 block_pfn = block_offset_to_pfn(vr, drm_buddy_block_offset(block)); 573 int i; 574 575 for (i = 0; i < drm_buddy_block_size(buddy, block) >> PAGE_SHIFT; ++i) 576 pfn[j++] = block_pfn + i; 577 } 578 579 return 0; 580 } 581 582 static const struct drm_gpusvm_devmem_ops gpusvm_devmem_ops = { 583 .devmem_release = xe_svm_devmem_release, 584 .populate_devmem_pfn = xe_svm_populate_devmem_pfn, 585 .copy_to_devmem = xe_svm_copy_to_devmem, 586 .copy_to_ram = xe_svm_copy_to_ram, 587 }; 588 589 static const struct drm_gpusvm_ops gpusvm_ops = { 590 .range_alloc = xe_svm_range_alloc, 591 .range_free = xe_svm_range_free, 592 .invalidate = xe_svm_invalidate, 593 }; 594 595 static const unsigned long fault_chunk_sizes[] = { 596 SZ_2M, 597 SZ_64K, 598 SZ_4K, 599 }; 600 601 /** 602 * xe_svm_init() - SVM initialize 603 * @vm: The VM. 604 * 605 * Initialize SVM state which is embedded within the VM. 606 * 607 * Return: 0 on success, negative error code on error. 608 */ 609 int xe_svm_init(struct xe_vm *vm) 610 { 611 int err; 612 613 spin_lock_init(&vm->svm.garbage_collector.lock); 614 INIT_LIST_HEAD(&vm->svm.garbage_collector.range_list); 615 INIT_WORK(&vm->svm.garbage_collector.work, 616 xe_svm_garbage_collector_work_func); 617 618 err = drm_gpusvm_init(&vm->svm.gpusvm, "Xe SVM", &vm->xe->drm, 619 current->mm, xe_svm_devm_owner(vm->xe), 0, 620 vm->size, xe_modparam.svm_notifier_size * SZ_1M, 621 &gpusvm_ops, fault_chunk_sizes, 622 ARRAY_SIZE(fault_chunk_sizes)); 623 if (err) 624 return err; 625 626 drm_gpusvm_driver_set_lock(&vm->svm.gpusvm, &vm->lock); 627 628 return 0; 629 } 630 631 /** 632 * xe_svm_close() - SVM close 633 * @vm: The VM. 634 * 635 * Close SVM state (i.e., stop and flush all SVM actions). 636 */ 637 void xe_svm_close(struct xe_vm *vm) 638 { 639 xe_assert(vm->xe, xe_vm_is_closed(vm)); 640 flush_work(&vm->svm.garbage_collector.work); 641 } 642 643 /** 644 * xe_svm_fini() - SVM finalize 645 * @vm: The VM. 646 * 647 * Finalize SVM state which is embedded within the VM. 648 */ 649 void xe_svm_fini(struct xe_vm *vm) 650 { 651 xe_assert(vm->xe, xe_vm_is_closed(vm)); 652 653 drm_gpusvm_fini(&vm->svm.gpusvm); 654 } 655 656 static bool xe_svm_range_is_valid(struct xe_svm_range *range, 657 struct xe_tile *tile, 658 bool devmem_only) 659 { 660 /* 661 * Advisory only check whether the range currently has a valid mapping, 662 * READ_ONCE pairs with WRITE_ONCE in xe_pt.c 663 */ 664 return ((READ_ONCE(range->tile_present) & 665 ~READ_ONCE(range->tile_invalidated)) & BIT(tile->id)) && 666 (!devmem_only || xe_svm_range_in_vram(range)); 667 } 668 669 static struct xe_vram_region *tile_to_vr(struct xe_tile *tile) 670 { 671 return &tile->mem.vram; 672 } 673 674 static int xe_svm_alloc_vram(struct xe_vm *vm, struct xe_tile *tile, 675 struct xe_svm_range *range, 676 const struct drm_gpusvm_ctx *ctx) 677 { 678 struct mm_struct *mm = vm->svm.gpusvm.mm; 679 struct xe_vram_region *vr = tile_to_vr(tile); 680 struct drm_buddy_block *block; 681 struct list_head *blocks; 682 struct xe_bo *bo; 683 ktime_t end = 0; 684 int err; 685 686 range_debug(range, "ALLOCATE VRAM"); 687 688 if (!mmget_not_zero(mm)) 689 return -EFAULT; 690 mmap_read_lock(mm); 691 692 retry: 693 bo = xe_bo_create_locked(tile_to_xe(tile), NULL, NULL, 694 xe_svm_range_size(range), 695 ttm_bo_type_device, 696 XE_BO_FLAG_VRAM_IF_DGFX(tile) | 697 XE_BO_FLAG_CPU_ADDR_MIRROR); 698 if (IS_ERR(bo)) { 699 err = PTR_ERR(bo); 700 if (xe_vm_validate_should_retry(NULL, err, &end)) 701 goto retry; 702 goto unlock; 703 } 704 705 drm_gpusvm_devmem_init(&bo->devmem_allocation, 706 vm->xe->drm.dev, mm, 707 &gpusvm_devmem_ops, 708 &tile->mem.vram.dpagemap, 709 xe_svm_range_size(range)); 710 711 blocks = &to_xe_ttm_vram_mgr_resource(bo->ttm.resource)->blocks; 712 list_for_each_entry(block, blocks, link) 713 block->private = vr; 714 715 xe_bo_get(bo); 716 err = drm_gpusvm_migrate_to_devmem(&vm->svm.gpusvm, &range->base, 717 &bo->devmem_allocation, ctx); 718 if (err) 719 xe_svm_devmem_release(&bo->devmem_allocation); 720 721 xe_bo_unlock(bo); 722 xe_bo_put(bo); 723 724 unlock: 725 mmap_read_unlock(mm); 726 mmput(mm); 727 728 return err; 729 } 730 731 static bool supports_4K_migration(struct xe_device *xe) 732 { 733 if (xe->info.vram_flags & XE_VRAM_FLAGS_NEED64K) 734 return false; 735 736 return true; 737 } 738 739 static bool xe_svm_range_needs_migrate_to_vram(struct xe_svm_range *range, 740 struct xe_vma *vma) 741 { 742 struct xe_vm *vm = range_to_vm(&range->base); 743 u64 range_size = xe_svm_range_size(range); 744 745 if (!range->base.flags.migrate_devmem) 746 return false; 747 748 if (xe_svm_range_in_vram(range)) { 749 drm_dbg(&vm->xe->drm, "Range is already in VRAM\n"); 750 return false; 751 } 752 753 if (range_size <= SZ_64K && !supports_4K_migration(vm->xe)) { 754 drm_dbg(&vm->xe->drm, "Platform doesn't support SZ_4K range migration\n"); 755 return false; 756 } 757 758 return true; 759 } 760 761 /** 762 * xe_svm_handle_pagefault() - SVM handle page fault 763 * @vm: The VM. 764 * @vma: The CPU address mirror VMA. 765 * @tile: The tile upon the fault occurred. 766 * @fault_addr: The GPU fault address. 767 * @atomic: The fault atomic access bit. 768 * 769 * Create GPU bindings for a SVM page fault. Optionally migrate to device 770 * memory. 771 * 772 * Return: 0 on success, negative error code on error. 773 */ 774 int xe_svm_handle_pagefault(struct xe_vm *vm, struct xe_vma *vma, 775 struct xe_tile *tile, u64 fault_addr, 776 bool atomic) 777 { 778 struct drm_gpusvm_ctx ctx = { 779 .read_only = xe_vma_read_only(vma), 780 .devmem_possible = IS_DGFX(vm->xe) && 781 IS_ENABLED(CONFIG_DRM_XE_DEVMEM_MIRROR), 782 .check_pages_threshold = IS_DGFX(vm->xe) && 783 IS_ENABLED(CONFIG_DRM_XE_DEVMEM_MIRROR) ? SZ_64K : 0, 784 .devmem_only = atomic && IS_DGFX(vm->xe) && 785 IS_ENABLED(CONFIG_DRM_XE_DEVMEM_MIRROR), 786 .timeslice_ms = atomic && IS_DGFX(vm->xe) && 787 IS_ENABLED(CONFIG_DRM_XE_DEVMEM_MIRROR) ? 5 : 0, 788 }; 789 struct xe_svm_range *range; 790 struct drm_gpusvm_range *r; 791 struct drm_exec exec; 792 struct dma_fence *fence; 793 int migrate_try_count = ctx.devmem_only ? 3 : 1; 794 ktime_t end = 0; 795 int err; 796 797 lockdep_assert_held_write(&vm->lock); 798 xe_assert(vm->xe, xe_vma_is_cpu_addr_mirror(vma)); 799 800 retry: 801 /* Always process UNMAPs first so view SVM ranges is current */ 802 err = xe_svm_garbage_collector(vm); 803 if (err) 804 return err; 805 806 r = drm_gpusvm_range_find_or_insert(&vm->svm.gpusvm, fault_addr, 807 xe_vma_start(vma), xe_vma_end(vma), 808 &ctx); 809 if (IS_ERR(r)) 810 return PTR_ERR(r); 811 812 if (ctx.devmem_only && !r->flags.migrate_devmem) 813 return -EACCES; 814 815 range = to_xe_range(r); 816 if (xe_svm_range_is_valid(range, tile, ctx.devmem_only)) 817 return 0; 818 819 range_debug(range, "PAGE FAULT"); 820 821 if (--migrate_try_count >= 0 && 822 xe_svm_range_needs_migrate_to_vram(range, vma)) { 823 err = xe_svm_alloc_vram(vm, tile, range, &ctx); 824 ctx.timeslice_ms <<= 1; /* Double timeslice if we have to retry */ 825 if (err) { 826 if (migrate_try_count || !ctx.devmem_only) { 827 drm_dbg(&vm->xe->drm, 828 "VRAM allocation failed, falling back to retrying fault, asid=%u, errno=%pe\n", 829 vm->usm.asid, ERR_PTR(err)); 830 goto retry; 831 } else { 832 drm_err(&vm->xe->drm, 833 "VRAM allocation failed, retry count exceeded, asid=%u, errno=%pe\n", 834 vm->usm.asid, ERR_PTR(err)); 835 return err; 836 } 837 } 838 } 839 840 range_debug(range, "GET PAGES"); 841 err = drm_gpusvm_range_get_pages(&vm->svm.gpusvm, r, &ctx); 842 /* Corner where CPU mappings have changed */ 843 if (err == -EOPNOTSUPP || err == -EFAULT || err == -EPERM) { 844 ctx.timeslice_ms <<= 1; /* Double timeslice if we have to retry */ 845 if (migrate_try_count > 0 || !ctx.devmem_only) { 846 if (err == -EOPNOTSUPP) { 847 range_debug(range, "PAGE FAULT - EVICT PAGES"); 848 drm_gpusvm_range_evict(&vm->svm.gpusvm, 849 &range->base); 850 } 851 drm_dbg(&vm->xe->drm, 852 "Get pages failed, falling back to retrying, asid=%u, gpusvm=%p, errno=%pe\n", 853 vm->usm.asid, &vm->svm.gpusvm, ERR_PTR(err)); 854 range_debug(range, "PAGE FAULT - RETRY PAGES"); 855 goto retry; 856 } else { 857 drm_err(&vm->xe->drm, 858 "Get pages failed, retry count exceeded, asid=%u, gpusvm=%p, errno=%pe\n", 859 vm->usm.asid, &vm->svm.gpusvm, ERR_PTR(err)); 860 } 861 } 862 if (err) { 863 range_debug(range, "PAGE FAULT - FAIL PAGE COLLECT"); 864 goto err_out; 865 } 866 867 range_debug(range, "PAGE FAULT - BIND"); 868 869 retry_bind: 870 drm_exec_init(&exec, 0, 0); 871 drm_exec_until_all_locked(&exec) { 872 err = drm_exec_lock_obj(&exec, vm->gpuvm.r_obj); 873 drm_exec_retry_on_contention(&exec); 874 if (err) { 875 drm_exec_fini(&exec); 876 goto err_out; 877 } 878 879 fence = xe_vm_range_rebind(vm, vma, range, BIT(tile->id)); 880 if (IS_ERR(fence)) { 881 drm_exec_fini(&exec); 882 err = PTR_ERR(fence); 883 if (err == -EAGAIN) { 884 ctx.timeslice_ms <<= 1; /* Double timeslice if we have to retry */ 885 range_debug(range, "PAGE FAULT - RETRY BIND"); 886 goto retry; 887 } 888 if (xe_vm_validate_should_retry(&exec, err, &end)) 889 goto retry_bind; 890 goto err_out; 891 } 892 } 893 drm_exec_fini(&exec); 894 895 dma_fence_wait(fence, false); 896 dma_fence_put(fence); 897 898 err_out: 899 900 return err; 901 } 902 903 /** 904 * xe_svm_has_mapping() - SVM has mappings 905 * @vm: The VM. 906 * @start: Start address. 907 * @end: End address. 908 * 909 * Check if an address range has SVM mappings. 910 * 911 * Return: True if address range has a SVM mapping, False otherwise 912 */ 913 bool xe_svm_has_mapping(struct xe_vm *vm, u64 start, u64 end) 914 { 915 return drm_gpusvm_has_mapping(&vm->svm.gpusvm, start, end); 916 } 917 918 /** 919 * xe_svm_bo_evict() - SVM evict BO to system memory 920 * @bo: BO to evict 921 * 922 * SVM evict BO to system memory. GPU SVM layer ensures all device pages 923 * are evicted before returning. 924 * 925 * Return: 0 on success standard error code otherwise 926 */ 927 int xe_svm_bo_evict(struct xe_bo *bo) 928 { 929 return drm_gpusvm_evict_to_ram(&bo->devmem_allocation); 930 } 931 932 #if IS_ENABLED(CONFIG_DRM_XE_DEVMEM_MIRROR) 933 static struct drm_pagemap_device_addr 934 xe_drm_pagemap_device_map(struct drm_pagemap *dpagemap, 935 struct device *dev, 936 struct page *page, 937 unsigned int order, 938 enum dma_data_direction dir) 939 { 940 struct device *pgmap_dev = dpagemap->dev; 941 enum drm_interconnect_protocol prot; 942 dma_addr_t addr; 943 944 if (pgmap_dev == dev) { 945 addr = xe_vram_region_page_to_dpa(page_to_vr(page), page); 946 prot = XE_INTERCONNECT_VRAM; 947 } else { 948 addr = DMA_MAPPING_ERROR; 949 prot = 0; 950 } 951 952 return drm_pagemap_device_addr_encode(addr, prot, order, dir); 953 } 954 955 static const struct drm_pagemap_ops xe_drm_pagemap_ops = { 956 .device_map = xe_drm_pagemap_device_map, 957 }; 958 959 /** 960 * xe_devm_add: Remap and provide memmap backing for device memory 961 * @tile: tile that the memory region belongs to 962 * @vr: vram memory region to remap 963 * 964 * This remap device memory to host physical address space and create 965 * struct page to back device memory 966 * 967 * Return: 0 on success standard error code otherwise 968 */ 969 int xe_devm_add(struct xe_tile *tile, struct xe_vram_region *vr) 970 { 971 struct xe_device *xe = tile_to_xe(tile); 972 struct device *dev = &to_pci_dev(xe->drm.dev)->dev; 973 struct resource *res; 974 void *addr; 975 int ret; 976 977 res = devm_request_free_mem_region(dev, &iomem_resource, 978 vr->usable_size); 979 if (IS_ERR(res)) { 980 ret = PTR_ERR(res); 981 return ret; 982 } 983 984 vr->pagemap.type = MEMORY_DEVICE_PRIVATE; 985 vr->pagemap.range.start = res->start; 986 vr->pagemap.range.end = res->end; 987 vr->pagemap.nr_range = 1; 988 vr->pagemap.ops = drm_gpusvm_pagemap_ops_get(); 989 vr->pagemap.owner = xe_svm_devm_owner(xe); 990 addr = devm_memremap_pages(dev, &vr->pagemap); 991 992 vr->dpagemap.dev = dev; 993 vr->dpagemap.ops = &xe_drm_pagemap_ops; 994 995 if (IS_ERR(addr)) { 996 devm_release_mem_region(dev, res->start, resource_size(res)); 997 ret = PTR_ERR(addr); 998 drm_err(&xe->drm, "Failed to remap tile %d memory, errno %pe\n", 999 tile->id, ERR_PTR(ret)); 1000 return ret; 1001 } 1002 vr->hpa_base = res->start; 1003 1004 drm_dbg(&xe->drm, "Added tile %d memory [%llx-%llx] to devm, remapped to %pr\n", 1005 tile->id, vr->io_start, vr->io_start + vr->usable_size, res); 1006 return 0; 1007 } 1008 #else 1009 int xe_devm_add(struct xe_tile *tile, struct xe_vram_region *vr) 1010 { 1011 return 0; 1012 } 1013 #endif 1014 1015 /** 1016 * xe_svm_flush() - SVM flush 1017 * @vm: The VM. 1018 * 1019 * Flush all SVM actions. 1020 */ 1021 void xe_svm_flush(struct xe_vm *vm) 1022 { 1023 if (xe_vm_in_fault_mode(vm)) 1024 flush_work(&vm->svm.garbage_collector.work); 1025 } 1026