1 /* 2 * Copyright(c) 2015, 2016 Intel Corporation. 3 * 4 * This file is provided under a dual BSD/GPLv2 license. When using or 5 * redistributing this file, you may do so under either license. 6 * 7 * GPL LICENSE SUMMARY 8 * 9 * This program is free software; you can redistribute it and/or modify 10 * it under the terms of version 2 of the GNU General Public License as 11 * published by the Free Software Foundation. 12 * 13 * This program is distributed in the hope that it will be useful, but 14 * WITHOUT ANY WARRANTY; without even the implied warranty of 15 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 16 * General Public License for more details. 17 * 18 * BSD LICENSE 19 * 20 * Redistribution and use in source and binary forms, with or without 21 * modification, are permitted provided that the following conditions 22 * are met: 23 * 24 * - Redistributions of source code must retain the above copyright 25 * notice, this list of conditions and the following disclaimer. 26 * - Redistributions in binary form must reproduce the above copyright 27 * notice, this list of conditions and the following disclaimer in 28 * the documentation and/or other materials provided with the 29 * distribution. 30 * - Neither the name of Intel Corporation nor the names of its 31 * contributors may be used to endorse or promote products derived 32 * from this software without specific prior written permission. 33 * 34 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 35 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 36 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR 37 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT 38 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, 39 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT 40 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 41 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 42 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 43 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 44 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 45 * 46 */ 47 #include <asm/page.h> 48 49 #include "user_exp_rcv.h" 50 #include "trace.h" 51 #include "mmu_rb.h" 52 53 struct tid_group { 54 struct list_head list; 55 unsigned base; 56 u8 size; 57 u8 used; 58 u8 map; 59 }; 60 61 struct tid_rb_node { 62 struct mmu_rb_node mmu; 63 unsigned long phys; 64 struct tid_group *grp; 65 u32 rcventry; 66 dma_addr_t dma_addr; 67 bool freed; 68 unsigned npages; 69 struct page *pages[0]; 70 }; 71 72 struct tid_pageset { 73 u16 idx; 74 u16 count; 75 }; 76 77 #define EXP_TID_SET_EMPTY(set) (set.count == 0 && list_empty(&set.list)) 78 79 #define num_user_pages(vaddr, len) \ 80 (1 + (((((unsigned long)(vaddr) + \ 81 (unsigned long)(len) - 1) & PAGE_MASK) - \ 82 ((unsigned long)vaddr & PAGE_MASK)) >> PAGE_SHIFT)) 83 84 static void unlock_exp_tids(struct hfi1_ctxtdata *, struct exp_tid_set *, 85 struct hfi1_filedata *); 86 static u32 find_phys_blocks(struct page **, unsigned, struct tid_pageset *); 87 static int set_rcvarray_entry(struct file *, unsigned long, u32, 88 struct tid_group *, struct page **, unsigned); 89 static int tid_rb_insert(void *, struct mmu_rb_node *); 90 static void cacheless_tid_rb_remove(struct hfi1_filedata *fdata, 91 struct tid_rb_node *tnode); 92 static void tid_rb_remove(void *, struct mmu_rb_node *); 93 static int tid_rb_invalidate(void *, struct mmu_rb_node *); 94 static int program_rcvarray(struct file *, unsigned long, struct tid_group *, 95 struct tid_pageset *, unsigned, u16, struct page **, 96 u32 *, unsigned *, unsigned *); 97 static int unprogram_rcvarray(struct file *, u32, struct tid_group **); 98 static void clear_tid_node(struct hfi1_filedata *fd, struct tid_rb_node *node); 99 100 static struct mmu_rb_ops tid_rb_ops = { 101 .insert = tid_rb_insert, 102 .remove = tid_rb_remove, 103 .invalidate = tid_rb_invalidate 104 }; 105 106 static inline u32 rcventry2tidinfo(u32 rcventry) 107 { 108 u32 pair = rcventry & ~0x1; 109 110 return EXP_TID_SET(IDX, pair >> 1) | 111 EXP_TID_SET(CTRL, 1 << (rcventry - pair)); 112 } 113 114 static inline void exp_tid_group_init(struct exp_tid_set *set) 115 { 116 INIT_LIST_HEAD(&set->list); 117 set->count = 0; 118 } 119 120 static inline void tid_group_remove(struct tid_group *grp, 121 struct exp_tid_set *set) 122 { 123 list_del_init(&grp->list); 124 set->count--; 125 } 126 127 static inline void tid_group_add_tail(struct tid_group *grp, 128 struct exp_tid_set *set) 129 { 130 list_add_tail(&grp->list, &set->list); 131 set->count++; 132 } 133 134 static inline struct tid_group *tid_group_pop(struct exp_tid_set *set) 135 { 136 struct tid_group *grp = 137 list_first_entry(&set->list, struct tid_group, list); 138 list_del_init(&grp->list); 139 set->count--; 140 return grp; 141 } 142 143 static inline void tid_group_move(struct tid_group *group, 144 struct exp_tid_set *s1, 145 struct exp_tid_set *s2) 146 { 147 tid_group_remove(group, s1); 148 tid_group_add_tail(group, s2); 149 } 150 151 /* 152 * Initialize context and file private data needed for Expected 153 * receive caching. This needs to be done after the context has 154 * been configured with the eager/expected RcvEntry counts. 155 */ 156 int hfi1_user_exp_rcv_init(struct file *fp) 157 { 158 struct hfi1_filedata *fd = fp->private_data; 159 struct hfi1_ctxtdata *uctxt = fd->uctxt; 160 struct hfi1_devdata *dd = uctxt->dd; 161 unsigned tidbase; 162 int i, ret = 0; 163 164 spin_lock_init(&fd->tid_lock); 165 spin_lock_init(&fd->invalid_lock); 166 167 if (!uctxt->subctxt_cnt || !fd->subctxt) { 168 exp_tid_group_init(&uctxt->tid_group_list); 169 exp_tid_group_init(&uctxt->tid_used_list); 170 exp_tid_group_init(&uctxt->tid_full_list); 171 172 tidbase = uctxt->expected_base; 173 for (i = 0; i < uctxt->expected_count / 174 dd->rcv_entries.group_size; i++) { 175 struct tid_group *grp; 176 177 grp = kzalloc(sizeof(*grp), GFP_KERNEL); 178 if (!grp) { 179 /* 180 * If we fail here, the groups already 181 * allocated will be freed by the close 182 * call. 183 */ 184 ret = -ENOMEM; 185 goto done; 186 } 187 grp->size = dd->rcv_entries.group_size; 188 grp->base = tidbase; 189 tid_group_add_tail(grp, &uctxt->tid_group_list); 190 tidbase += dd->rcv_entries.group_size; 191 } 192 } 193 194 fd->entry_to_rb = kcalloc(uctxt->expected_count, 195 sizeof(struct rb_node *), 196 GFP_KERNEL); 197 if (!fd->entry_to_rb) 198 return -ENOMEM; 199 200 if (!HFI1_CAP_UGET_MASK(uctxt->flags, TID_UNMAP)) { 201 fd->invalid_tid_idx = 0; 202 fd->invalid_tids = kzalloc(uctxt->expected_count * 203 sizeof(u32), GFP_KERNEL); 204 if (!fd->invalid_tids) { 205 ret = -ENOMEM; 206 goto done; 207 } 208 209 /* 210 * Register MMU notifier callbacks. If the registration 211 * fails, continue without TID caching for this context. 212 */ 213 ret = hfi1_mmu_rb_register(fd, fd->mm, &tid_rb_ops, 214 dd->pport->hfi1_wq, 215 &fd->handler); 216 if (ret) { 217 dd_dev_info(dd, 218 "Failed MMU notifier registration %d\n", 219 ret); 220 ret = 0; 221 } 222 } 223 224 /* 225 * PSM does not have a good way to separate, count, and 226 * effectively enforce a limit on RcvArray entries used by 227 * subctxts (when context sharing is used) when TID caching 228 * is enabled. To help with that, we calculate a per-process 229 * RcvArray entry share and enforce that. 230 * If TID caching is not in use, PSM deals with usage on its 231 * own. In that case, we allow any subctxt to take all of the 232 * entries. 233 * 234 * Make sure that we set the tid counts only after successful 235 * init. 236 */ 237 spin_lock(&fd->tid_lock); 238 if (uctxt->subctxt_cnt && fd->handler) { 239 u16 remainder; 240 241 fd->tid_limit = uctxt->expected_count / uctxt->subctxt_cnt; 242 remainder = uctxt->expected_count % uctxt->subctxt_cnt; 243 if (remainder && fd->subctxt < remainder) 244 fd->tid_limit++; 245 } else { 246 fd->tid_limit = uctxt->expected_count; 247 } 248 spin_unlock(&fd->tid_lock); 249 done: 250 return ret; 251 } 252 253 int hfi1_user_exp_rcv_free(struct hfi1_filedata *fd) 254 { 255 struct hfi1_ctxtdata *uctxt = fd->uctxt; 256 struct tid_group *grp, *gptr; 257 258 if (!test_bit(HFI1_CTXT_SETUP_DONE, &uctxt->event_flags)) 259 return 0; 260 /* 261 * The notifier would have been removed when the process'es mm 262 * was freed. 263 */ 264 if (fd->handler) 265 hfi1_mmu_rb_unregister(fd->handler); 266 267 kfree(fd->invalid_tids); 268 269 if (!uctxt->cnt) { 270 if (!EXP_TID_SET_EMPTY(uctxt->tid_full_list)) 271 unlock_exp_tids(uctxt, &uctxt->tid_full_list, fd); 272 if (!EXP_TID_SET_EMPTY(uctxt->tid_used_list)) 273 unlock_exp_tids(uctxt, &uctxt->tid_used_list, fd); 274 list_for_each_entry_safe(grp, gptr, &uctxt->tid_group_list.list, 275 list) { 276 list_del_init(&grp->list); 277 kfree(grp); 278 } 279 hfi1_clear_tids(uctxt); 280 } 281 282 kfree(fd->entry_to_rb); 283 return 0; 284 } 285 286 /* 287 * Write an "empty" RcvArray entry. 288 * This function exists so the TID registaration code can use it 289 * to write to unused/unneeded entries and still take advantage 290 * of the WC performance improvements. The HFI will ignore this 291 * write to the RcvArray entry. 292 */ 293 static inline void rcv_array_wc_fill(struct hfi1_devdata *dd, u32 index) 294 { 295 /* 296 * Doing the WC fill writes only makes sense if the device is 297 * present and the RcvArray has been mapped as WC memory. 298 */ 299 if ((dd->flags & HFI1_PRESENT) && dd->rcvarray_wc) 300 writeq(0, dd->rcvarray_wc + (index * 8)); 301 } 302 303 /* 304 * RcvArray entry allocation for Expected Receives is done by the 305 * following algorithm: 306 * 307 * The context keeps 3 lists of groups of RcvArray entries: 308 * 1. List of empty groups - tid_group_list 309 * This list is created during user context creation and 310 * contains elements which describe sets (of 8) of empty 311 * RcvArray entries. 312 * 2. List of partially used groups - tid_used_list 313 * This list contains sets of RcvArray entries which are 314 * not completely used up. Another mapping request could 315 * use some of all of the remaining entries. 316 * 3. List of full groups - tid_full_list 317 * This is the list where sets that are completely used 318 * up go. 319 * 320 * An attempt to optimize the usage of RcvArray entries is 321 * made by finding all sets of physically contiguous pages in a 322 * user's buffer. 323 * These physically contiguous sets are further split into 324 * sizes supported by the receive engine of the HFI. The 325 * resulting sets of pages are stored in struct tid_pageset, 326 * which describes the sets as: 327 * * .count - number of pages in this set 328 * * .idx - starting index into struct page ** array 329 * of this set 330 * 331 * From this point on, the algorithm deals with the page sets 332 * described above. The number of pagesets is divided by the 333 * RcvArray group size to produce the number of full groups 334 * needed. 335 * 336 * Groups from the 3 lists are manipulated using the following 337 * rules: 338 * 1. For each set of 8 pagesets, a complete group from 339 * tid_group_list is taken, programmed, and moved to 340 * the tid_full_list list. 341 * 2. For all remaining pagesets: 342 * 2.1 If the tid_used_list is empty and the tid_group_list 343 * is empty, stop processing pageset and return only 344 * what has been programmed up to this point. 345 * 2.2 If the tid_used_list is empty and the tid_group_list 346 * is not empty, move a group from tid_group_list to 347 * tid_used_list. 348 * 2.3 For each group is tid_used_group, program as much as 349 * can fit into the group. If the group becomes fully 350 * used, move it to tid_full_list. 351 */ 352 int hfi1_user_exp_rcv_setup(struct file *fp, struct hfi1_tid_info *tinfo) 353 { 354 int ret = 0, need_group = 0, pinned; 355 struct hfi1_filedata *fd = fp->private_data; 356 struct hfi1_ctxtdata *uctxt = fd->uctxt; 357 struct hfi1_devdata *dd = uctxt->dd; 358 unsigned npages, ngroups, pageidx = 0, pageset_count, npagesets, 359 tididx = 0, mapped, mapped_pages = 0; 360 unsigned long vaddr = tinfo->vaddr; 361 struct page **pages = NULL; 362 u32 *tidlist = NULL; 363 struct tid_pageset *pagesets = NULL; 364 365 /* Get the number of pages the user buffer spans */ 366 npages = num_user_pages(vaddr, tinfo->length); 367 if (!npages) 368 return -EINVAL; 369 370 if (npages > uctxt->expected_count) { 371 dd_dev_err(dd, "Expected buffer too big\n"); 372 return -EINVAL; 373 } 374 375 /* Verify that access is OK for the user buffer */ 376 if (!access_ok(VERIFY_WRITE, (void __user *)vaddr, 377 npages * PAGE_SIZE)) { 378 dd_dev_err(dd, "Fail vaddr %p, %u pages, !access_ok\n", 379 (void *)vaddr, npages); 380 return -EFAULT; 381 } 382 383 pagesets = kcalloc(uctxt->expected_count, sizeof(*pagesets), 384 GFP_KERNEL); 385 if (!pagesets) 386 return -ENOMEM; 387 388 /* Allocate the array of struct page pointers needed for pinning */ 389 pages = kcalloc(npages, sizeof(*pages), GFP_KERNEL); 390 if (!pages) { 391 ret = -ENOMEM; 392 goto bail; 393 } 394 395 /* 396 * Pin all the pages of the user buffer. If we can't pin all the 397 * pages, accept the amount pinned so far and program only that. 398 * User space knows how to deal with partially programmed buffers. 399 */ 400 if (!hfi1_can_pin_pages(dd, fd->mm, fd->tid_n_pinned, npages)) { 401 ret = -ENOMEM; 402 goto bail; 403 } 404 405 pinned = hfi1_acquire_user_pages(fd->mm, vaddr, npages, true, pages); 406 if (pinned <= 0) { 407 ret = pinned; 408 goto bail; 409 } 410 fd->tid_n_pinned += npages; 411 412 /* Find sets of physically contiguous pages */ 413 npagesets = find_phys_blocks(pages, pinned, pagesets); 414 415 /* 416 * We don't need to access this under a lock since tid_used is per 417 * process and the same process cannot be in hfi1_user_exp_rcv_clear() 418 * and hfi1_user_exp_rcv_setup() at the same time. 419 */ 420 spin_lock(&fd->tid_lock); 421 if (fd->tid_used + npagesets > fd->tid_limit) 422 pageset_count = fd->tid_limit - fd->tid_used; 423 else 424 pageset_count = npagesets; 425 spin_unlock(&fd->tid_lock); 426 427 if (!pageset_count) 428 goto bail; 429 430 ngroups = pageset_count / dd->rcv_entries.group_size; 431 tidlist = kcalloc(pageset_count, sizeof(*tidlist), GFP_KERNEL); 432 if (!tidlist) { 433 ret = -ENOMEM; 434 goto nomem; 435 } 436 437 tididx = 0; 438 439 /* 440 * From this point on, we are going to be using shared (between master 441 * and subcontexts) context resources. We need to take the lock. 442 */ 443 mutex_lock(&uctxt->exp_lock); 444 /* 445 * The first step is to program the RcvArray entries which are complete 446 * groups. 447 */ 448 while (ngroups && uctxt->tid_group_list.count) { 449 struct tid_group *grp = 450 tid_group_pop(&uctxt->tid_group_list); 451 452 ret = program_rcvarray(fp, vaddr, grp, pagesets, 453 pageidx, dd->rcv_entries.group_size, 454 pages, tidlist, &tididx, &mapped); 455 /* 456 * If there was a failure to program the RcvArray 457 * entries for the entire group, reset the grp fields 458 * and add the grp back to the free group list. 459 */ 460 if (ret <= 0) { 461 tid_group_add_tail(grp, &uctxt->tid_group_list); 462 hfi1_cdbg(TID, 463 "Failed to program RcvArray group %d", ret); 464 goto unlock; 465 } 466 467 tid_group_add_tail(grp, &uctxt->tid_full_list); 468 ngroups--; 469 pageidx += ret; 470 mapped_pages += mapped; 471 } 472 473 while (pageidx < pageset_count) { 474 struct tid_group *grp, *ptr; 475 /* 476 * If we don't have any partially used tid groups, check 477 * if we have empty groups. If so, take one from there and 478 * put in the partially used list. 479 */ 480 if (!uctxt->tid_used_list.count || need_group) { 481 if (!uctxt->tid_group_list.count) 482 goto unlock; 483 484 grp = tid_group_pop(&uctxt->tid_group_list); 485 tid_group_add_tail(grp, &uctxt->tid_used_list); 486 need_group = 0; 487 } 488 /* 489 * There is an optimization opportunity here - instead of 490 * fitting as many page sets as we can, check for a group 491 * later on in the list that could fit all of them. 492 */ 493 list_for_each_entry_safe(grp, ptr, &uctxt->tid_used_list.list, 494 list) { 495 unsigned use = min_t(unsigned, pageset_count - pageidx, 496 grp->size - grp->used); 497 498 ret = program_rcvarray(fp, vaddr, grp, pagesets, 499 pageidx, use, pages, tidlist, 500 &tididx, &mapped); 501 if (ret < 0) { 502 hfi1_cdbg(TID, 503 "Failed to program RcvArray entries %d", 504 ret); 505 ret = -EFAULT; 506 goto unlock; 507 } else if (ret > 0) { 508 if (grp->used == grp->size) 509 tid_group_move(grp, 510 &uctxt->tid_used_list, 511 &uctxt->tid_full_list); 512 pageidx += ret; 513 mapped_pages += mapped; 514 need_group = 0; 515 /* Check if we are done so we break out early */ 516 if (pageidx >= pageset_count) 517 break; 518 } else if (WARN_ON(ret == 0)) { 519 /* 520 * If ret is 0, we did not program any entries 521 * into this group, which can only happen if 522 * we've screwed up the accounting somewhere. 523 * Warn and try to continue. 524 */ 525 need_group = 1; 526 } 527 } 528 } 529 unlock: 530 mutex_unlock(&uctxt->exp_lock); 531 nomem: 532 hfi1_cdbg(TID, "total mapped: tidpairs:%u pages:%u (%d)", tididx, 533 mapped_pages, ret); 534 if (tididx) { 535 spin_lock(&fd->tid_lock); 536 fd->tid_used += tididx; 537 spin_unlock(&fd->tid_lock); 538 tinfo->tidcnt = tididx; 539 tinfo->length = mapped_pages * PAGE_SIZE; 540 541 if (copy_to_user((void __user *)(unsigned long)tinfo->tidlist, 542 tidlist, sizeof(tidlist[0]) * tididx)) { 543 /* 544 * On failure to copy to the user level, we need to undo 545 * everything done so far so we don't leak resources. 546 */ 547 tinfo->tidlist = (unsigned long)&tidlist; 548 hfi1_user_exp_rcv_clear(fp, tinfo); 549 tinfo->tidlist = 0; 550 ret = -EFAULT; 551 goto bail; 552 } 553 } 554 555 /* 556 * If not everything was mapped (due to insufficient RcvArray entries, 557 * for example), unpin all unmapped pages so we can pin them nex time. 558 */ 559 if (mapped_pages != pinned) { 560 hfi1_release_user_pages(fd->mm, &pages[mapped_pages], 561 pinned - mapped_pages, 562 false); 563 fd->tid_n_pinned -= pinned - mapped_pages; 564 } 565 bail: 566 kfree(pagesets); 567 kfree(pages); 568 kfree(tidlist); 569 return ret > 0 ? 0 : ret; 570 } 571 572 int hfi1_user_exp_rcv_clear(struct file *fp, struct hfi1_tid_info *tinfo) 573 { 574 int ret = 0; 575 struct hfi1_filedata *fd = fp->private_data; 576 struct hfi1_ctxtdata *uctxt = fd->uctxt; 577 u32 *tidinfo; 578 unsigned tididx; 579 580 tidinfo = kcalloc(tinfo->tidcnt, sizeof(*tidinfo), GFP_KERNEL); 581 if (!tidinfo) 582 return -ENOMEM; 583 584 if (copy_from_user(tidinfo, (void __user *)(unsigned long) 585 tinfo->tidlist, sizeof(tidinfo[0]) * 586 tinfo->tidcnt)) { 587 ret = -EFAULT; 588 goto done; 589 } 590 591 mutex_lock(&uctxt->exp_lock); 592 for (tididx = 0; tididx < tinfo->tidcnt; tididx++) { 593 ret = unprogram_rcvarray(fp, tidinfo[tididx], NULL); 594 if (ret) { 595 hfi1_cdbg(TID, "Failed to unprogram rcv array %d", 596 ret); 597 break; 598 } 599 } 600 spin_lock(&fd->tid_lock); 601 fd->tid_used -= tididx; 602 spin_unlock(&fd->tid_lock); 603 tinfo->tidcnt = tididx; 604 mutex_unlock(&uctxt->exp_lock); 605 done: 606 kfree(tidinfo); 607 return ret; 608 } 609 610 int hfi1_user_exp_rcv_invalid(struct file *fp, struct hfi1_tid_info *tinfo) 611 { 612 struct hfi1_filedata *fd = fp->private_data; 613 struct hfi1_ctxtdata *uctxt = fd->uctxt; 614 unsigned long *ev = uctxt->dd->events + 615 (((uctxt->ctxt - uctxt->dd->first_user_ctxt) * 616 HFI1_MAX_SHARED_CTXTS) + fd->subctxt); 617 u32 *array; 618 int ret = 0; 619 620 if (!fd->invalid_tids) 621 return -EINVAL; 622 623 /* 624 * copy_to_user() can sleep, which will leave the invalid_lock 625 * locked and cause the MMU notifier to be blocked on the lock 626 * for a long time. 627 * Copy the data to a local buffer so we can release the lock. 628 */ 629 array = kcalloc(uctxt->expected_count, sizeof(*array), GFP_KERNEL); 630 if (!array) 631 return -EFAULT; 632 633 spin_lock(&fd->invalid_lock); 634 if (fd->invalid_tid_idx) { 635 memcpy(array, fd->invalid_tids, sizeof(*array) * 636 fd->invalid_tid_idx); 637 memset(fd->invalid_tids, 0, sizeof(*fd->invalid_tids) * 638 fd->invalid_tid_idx); 639 tinfo->tidcnt = fd->invalid_tid_idx; 640 fd->invalid_tid_idx = 0; 641 /* 642 * Reset the user flag while still holding the lock. 643 * Otherwise, PSM can miss events. 644 */ 645 clear_bit(_HFI1_EVENT_TID_MMU_NOTIFY_BIT, ev); 646 } else { 647 tinfo->tidcnt = 0; 648 } 649 spin_unlock(&fd->invalid_lock); 650 651 if (tinfo->tidcnt) { 652 if (copy_to_user((void __user *)tinfo->tidlist, 653 array, sizeof(*array) * tinfo->tidcnt)) 654 ret = -EFAULT; 655 } 656 kfree(array); 657 658 return ret; 659 } 660 661 static u32 find_phys_blocks(struct page **pages, unsigned npages, 662 struct tid_pageset *list) 663 { 664 unsigned pagecount, pageidx, setcount = 0, i; 665 unsigned long pfn, this_pfn; 666 667 if (!npages) 668 return 0; 669 670 /* 671 * Look for sets of physically contiguous pages in the user buffer. 672 * This will allow us to optimize Expected RcvArray entry usage by 673 * using the bigger supported sizes. 674 */ 675 pfn = page_to_pfn(pages[0]); 676 for (pageidx = 0, pagecount = 1, i = 1; i <= npages; i++) { 677 this_pfn = i < npages ? page_to_pfn(pages[i]) : 0; 678 679 /* 680 * If the pfn's are not sequential, pages are not physically 681 * contiguous. 682 */ 683 if (this_pfn != ++pfn) { 684 /* 685 * At this point we have to loop over the set of 686 * physically contiguous pages and break them down it 687 * sizes supported by the HW. 688 * There are two main constraints: 689 * 1. The max buffer size is MAX_EXPECTED_BUFFER. 690 * If the total set size is bigger than that 691 * program only a MAX_EXPECTED_BUFFER chunk. 692 * 2. The buffer size has to be a power of two. If 693 * it is not, round down to the closes power of 694 * 2 and program that size. 695 */ 696 while (pagecount) { 697 int maxpages = pagecount; 698 u32 bufsize = pagecount * PAGE_SIZE; 699 700 if (bufsize > MAX_EXPECTED_BUFFER) 701 maxpages = 702 MAX_EXPECTED_BUFFER >> 703 PAGE_SHIFT; 704 else if (!is_power_of_2(bufsize)) 705 maxpages = 706 rounddown_pow_of_two(bufsize) >> 707 PAGE_SHIFT; 708 709 list[setcount].idx = pageidx; 710 list[setcount].count = maxpages; 711 pagecount -= maxpages; 712 pageidx += maxpages; 713 setcount++; 714 } 715 pageidx = i; 716 pagecount = 1; 717 pfn = this_pfn; 718 } else { 719 pagecount++; 720 } 721 } 722 return setcount; 723 } 724 725 /** 726 * program_rcvarray() - program an RcvArray group with receive buffers 727 * @fp: file pointer 728 * @vaddr: starting user virtual address 729 * @grp: RcvArray group 730 * @sets: array of struct tid_pageset holding information on physically 731 * contiguous chunks from the user buffer 732 * @start: starting index into sets array 733 * @count: number of struct tid_pageset's to program 734 * @pages: an array of struct page * for the user buffer 735 * @tidlist: the array of u32 elements when the information about the 736 * programmed RcvArray entries is to be encoded. 737 * @tididx: starting offset into tidlist 738 * @pmapped: (output parameter) number of pages programmed into the RcvArray 739 * entries. 740 * 741 * This function will program up to 'count' number of RcvArray entries from the 742 * group 'grp'. To make best use of write-combining writes, the function will 743 * perform writes to the unused RcvArray entries which will be ignored by the 744 * HW. Each RcvArray entry will be programmed with a physically contiguous 745 * buffer chunk from the user's virtual buffer. 746 * 747 * Return: 748 * -EINVAL if the requested count is larger than the size of the group, 749 * -ENOMEM or -EFAULT on error from set_rcvarray_entry(), or 750 * number of RcvArray entries programmed. 751 */ 752 static int program_rcvarray(struct file *fp, unsigned long vaddr, 753 struct tid_group *grp, 754 struct tid_pageset *sets, 755 unsigned start, u16 count, struct page **pages, 756 u32 *tidlist, unsigned *tididx, unsigned *pmapped) 757 { 758 struct hfi1_filedata *fd = fp->private_data; 759 struct hfi1_ctxtdata *uctxt = fd->uctxt; 760 struct hfi1_devdata *dd = uctxt->dd; 761 u16 idx; 762 u32 tidinfo = 0, rcventry, useidx = 0; 763 int mapped = 0; 764 765 /* Count should never be larger than the group size */ 766 if (count > grp->size) 767 return -EINVAL; 768 769 /* Find the first unused entry in the group */ 770 for (idx = 0; idx < grp->size; idx++) { 771 if (!(grp->map & (1 << idx))) { 772 useidx = idx; 773 break; 774 } 775 rcv_array_wc_fill(dd, grp->base + idx); 776 } 777 778 idx = 0; 779 while (idx < count) { 780 u16 npages, pageidx, setidx = start + idx; 781 int ret = 0; 782 783 /* 784 * If this entry in the group is used, move to the next one. 785 * If we go past the end of the group, exit the loop. 786 */ 787 if (useidx >= grp->size) { 788 break; 789 } else if (grp->map & (1 << useidx)) { 790 rcv_array_wc_fill(dd, grp->base + useidx); 791 useidx++; 792 continue; 793 } 794 795 rcventry = grp->base + useidx; 796 npages = sets[setidx].count; 797 pageidx = sets[setidx].idx; 798 799 ret = set_rcvarray_entry(fp, vaddr + (pageidx * PAGE_SIZE), 800 rcventry, grp, pages + pageidx, 801 npages); 802 if (ret) 803 return ret; 804 mapped += npages; 805 806 tidinfo = rcventry2tidinfo(rcventry - uctxt->expected_base) | 807 EXP_TID_SET(LEN, npages); 808 tidlist[(*tididx)++] = tidinfo; 809 grp->used++; 810 grp->map |= 1 << useidx++; 811 idx++; 812 } 813 814 /* Fill the rest of the group with "blank" writes */ 815 for (; useidx < grp->size; useidx++) 816 rcv_array_wc_fill(dd, grp->base + useidx); 817 *pmapped = mapped; 818 return idx; 819 } 820 821 static int set_rcvarray_entry(struct file *fp, unsigned long vaddr, 822 u32 rcventry, struct tid_group *grp, 823 struct page **pages, unsigned npages) 824 { 825 int ret; 826 struct hfi1_filedata *fd = fp->private_data; 827 struct hfi1_ctxtdata *uctxt = fd->uctxt; 828 struct tid_rb_node *node; 829 struct hfi1_devdata *dd = uctxt->dd; 830 dma_addr_t phys; 831 832 /* 833 * Allocate the node first so we can handle a potential 834 * failure before we've programmed anything. 835 */ 836 node = kzalloc(sizeof(*node) + (sizeof(struct page *) * npages), 837 GFP_KERNEL); 838 if (!node) 839 return -ENOMEM; 840 841 phys = pci_map_single(dd->pcidev, 842 __va(page_to_phys(pages[0])), 843 npages * PAGE_SIZE, PCI_DMA_FROMDEVICE); 844 if (dma_mapping_error(&dd->pcidev->dev, phys)) { 845 dd_dev_err(dd, "Failed to DMA map Exp Rcv pages 0x%llx\n", 846 phys); 847 kfree(node); 848 return -EFAULT; 849 } 850 851 node->mmu.addr = vaddr; 852 node->mmu.len = npages * PAGE_SIZE; 853 node->phys = page_to_phys(pages[0]); 854 node->npages = npages; 855 node->rcventry = rcventry; 856 node->dma_addr = phys; 857 node->grp = grp; 858 node->freed = false; 859 memcpy(node->pages, pages, sizeof(struct page *) * npages); 860 861 if (!fd->handler) 862 ret = tid_rb_insert(fd, &node->mmu); 863 else 864 ret = hfi1_mmu_rb_insert(fd->handler, &node->mmu); 865 866 if (ret) { 867 hfi1_cdbg(TID, "Failed to insert RB node %u 0x%lx, 0x%lx %d", 868 node->rcventry, node->mmu.addr, node->phys, ret); 869 pci_unmap_single(dd->pcidev, phys, npages * PAGE_SIZE, 870 PCI_DMA_FROMDEVICE); 871 kfree(node); 872 return -EFAULT; 873 } 874 hfi1_put_tid(dd, rcventry, PT_EXPECTED, phys, ilog2(npages) + 1); 875 trace_hfi1_exp_tid_reg(uctxt->ctxt, fd->subctxt, rcventry, npages, 876 node->mmu.addr, node->phys, phys); 877 return 0; 878 } 879 880 static int unprogram_rcvarray(struct file *fp, u32 tidinfo, 881 struct tid_group **grp) 882 { 883 struct hfi1_filedata *fd = fp->private_data; 884 struct hfi1_ctxtdata *uctxt = fd->uctxt; 885 struct hfi1_devdata *dd = uctxt->dd; 886 struct tid_rb_node *node; 887 u8 tidctrl = EXP_TID_GET(tidinfo, CTRL); 888 u32 tididx = EXP_TID_GET(tidinfo, IDX) << 1, rcventry; 889 890 if (tididx >= uctxt->expected_count) { 891 dd_dev_err(dd, "Invalid RcvArray entry (%u) index for ctxt %u\n", 892 tididx, uctxt->ctxt); 893 return -EINVAL; 894 } 895 896 if (tidctrl == 0x3) 897 return -EINVAL; 898 899 rcventry = tididx + (tidctrl - 1); 900 901 node = fd->entry_to_rb[rcventry]; 902 if (!node || node->rcventry != (uctxt->expected_base + rcventry)) 903 return -EBADF; 904 905 if (grp) 906 *grp = node->grp; 907 908 if (!fd->handler) 909 cacheless_tid_rb_remove(fd, node); 910 else 911 hfi1_mmu_rb_remove(fd->handler, &node->mmu); 912 913 return 0; 914 } 915 916 static void clear_tid_node(struct hfi1_filedata *fd, struct tid_rb_node *node) 917 { 918 struct hfi1_ctxtdata *uctxt = fd->uctxt; 919 struct hfi1_devdata *dd = uctxt->dd; 920 921 trace_hfi1_exp_tid_unreg(uctxt->ctxt, fd->subctxt, node->rcventry, 922 node->npages, node->mmu.addr, node->phys, 923 node->dma_addr); 924 925 hfi1_put_tid(dd, node->rcventry, PT_INVALID, 0, 0); 926 /* 927 * Make sure device has seen the write before we unpin the 928 * pages. 929 */ 930 flush_wc(); 931 932 pci_unmap_single(dd->pcidev, node->dma_addr, node->mmu.len, 933 PCI_DMA_FROMDEVICE); 934 hfi1_release_user_pages(fd->mm, node->pages, node->npages, true); 935 fd->tid_n_pinned -= node->npages; 936 937 node->grp->used--; 938 node->grp->map &= ~(1 << (node->rcventry - node->grp->base)); 939 940 if (node->grp->used == node->grp->size - 1) 941 tid_group_move(node->grp, &uctxt->tid_full_list, 942 &uctxt->tid_used_list); 943 else if (!node->grp->used) 944 tid_group_move(node->grp, &uctxt->tid_used_list, 945 &uctxt->tid_group_list); 946 kfree(node); 947 } 948 949 /* 950 * As a simple helper for hfi1_user_exp_rcv_free, this function deals with 951 * clearing nodes in the non-cached case. 952 */ 953 static void unlock_exp_tids(struct hfi1_ctxtdata *uctxt, 954 struct exp_tid_set *set, 955 struct hfi1_filedata *fd) 956 { 957 struct tid_group *grp, *ptr; 958 int i; 959 960 list_for_each_entry_safe(grp, ptr, &set->list, list) { 961 list_del_init(&grp->list); 962 963 for (i = 0; i < grp->size; i++) { 964 if (grp->map & (1 << i)) { 965 u16 rcventry = grp->base + i; 966 struct tid_rb_node *node; 967 968 node = fd->entry_to_rb[rcventry - 969 uctxt->expected_base]; 970 if (!node || node->rcventry != rcventry) 971 continue; 972 973 cacheless_tid_rb_remove(fd, node); 974 } 975 } 976 } 977 } 978 979 /* 980 * Always return 0 from this function. A non-zero return indicates that the 981 * remove operation will be called and that memory should be unpinned. 982 * However, the driver cannot unpin out from under PSM. Instead, retain the 983 * memory (by returning 0) and inform PSM that the memory is going away. PSM 984 * will call back later when it has removed the memory from its list. 985 */ 986 static int tid_rb_invalidate(void *arg, struct mmu_rb_node *mnode) 987 { 988 struct hfi1_filedata *fdata = arg; 989 struct hfi1_ctxtdata *uctxt = fdata->uctxt; 990 struct tid_rb_node *node = 991 container_of(mnode, struct tid_rb_node, mmu); 992 993 if (node->freed) 994 return 0; 995 996 trace_hfi1_exp_tid_inval(uctxt->ctxt, fdata->subctxt, node->mmu.addr, 997 node->rcventry, node->npages, node->dma_addr); 998 node->freed = true; 999 1000 spin_lock(&fdata->invalid_lock); 1001 if (fdata->invalid_tid_idx < uctxt->expected_count) { 1002 fdata->invalid_tids[fdata->invalid_tid_idx] = 1003 rcventry2tidinfo(node->rcventry - uctxt->expected_base); 1004 fdata->invalid_tids[fdata->invalid_tid_idx] |= 1005 EXP_TID_SET(LEN, node->npages); 1006 if (!fdata->invalid_tid_idx) { 1007 unsigned long *ev; 1008 1009 /* 1010 * hfi1_set_uevent_bits() sets a user event flag 1011 * for all processes. Because calling into the 1012 * driver to process TID cache invalidations is 1013 * expensive and TID cache invalidations are 1014 * handled on a per-process basis, we can 1015 * optimize this to set the flag only for the 1016 * process in question. 1017 */ 1018 ev = uctxt->dd->events + 1019 (((uctxt->ctxt - uctxt->dd->first_user_ctxt) * 1020 HFI1_MAX_SHARED_CTXTS) + fdata->subctxt); 1021 set_bit(_HFI1_EVENT_TID_MMU_NOTIFY_BIT, ev); 1022 } 1023 fdata->invalid_tid_idx++; 1024 } 1025 spin_unlock(&fdata->invalid_lock); 1026 return 0; 1027 } 1028 1029 static int tid_rb_insert(void *arg, struct mmu_rb_node *node) 1030 { 1031 struct hfi1_filedata *fdata = arg; 1032 struct tid_rb_node *tnode = 1033 container_of(node, struct tid_rb_node, mmu); 1034 u32 base = fdata->uctxt->expected_base; 1035 1036 fdata->entry_to_rb[tnode->rcventry - base] = tnode; 1037 return 0; 1038 } 1039 1040 static void cacheless_tid_rb_remove(struct hfi1_filedata *fdata, 1041 struct tid_rb_node *tnode) 1042 { 1043 u32 base = fdata->uctxt->expected_base; 1044 1045 fdata->entry_to_rb[tnode->rcventry - base] = NULL; 1046 clear_tid_node(fdata, tnode); 1047 } 1048 1049 static void tid_rb_remove(void *arg, struct mmu_rb_node *node) 1050 { 1051 struct hfi1_filedata *fdata = arg; 1052 struct tid_rb_node *tnode = 1053 container_of(node, struct tid_rb_node, mmu); 1054 1055 cacheless_tid_rb_remove(fdata, tnode); 1056 } 1057