1 /* 2 * Copyright (c) 2011-2018 The DragonFly Project. All rights reserved. 3 * 4 * This code is derived from software contributed to The DragonFly Project 5 * by Matthew Dillon <dillon@dragonflybsd.org> 6 * by Venkatesh Srinivas <vsrinivas@dragonflybsd.org> 7 * 8 * Redistribution and use in source and binary forms, with or without 9 * modification, are permitted provided that the following conditions 10 * are met: 11 * 12 * 1. Redistributions of source code must retain the above copyright 13 * notice, this list of conditions and the following disclaimer. 14 * 2. Redistributions in binary form must reproduce the above copyright 15 * notice, this list of conditions and the following disclaimer in 16 * the documentation and/or other materials provided with the 17 * distribution. 18 * 3. Neither the name of The DragonFly Project nor the names of its 19 * contributors may be used to endorse or promote products derived 20 * from this software without specific, prior written permission. 21 * 22 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS 23 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT 24 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS 25 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE 26 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, 27 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING, 28 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 29 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 30 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 31 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT 32 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 33 * SUCH DAMAGE. 34 */ 35 #include <sys/param.h> 36 #include <sys/systm.h> 37 #include <sys/kernel.h> 38 #include <sys/proc.h> 39 #include <sys/mount.h> 40 41 #include "hammer2.h" 42 43 #define FREEMAP_DEBUG 0 44 45 struct hammer2_fiterate { 46 hammer2_off_t bpref; 47 hammer2_off_t bnext; 48 int loops; 49 int relaxed; 50 }; 51 52 typedef struct hammer2_fiterate hammer2_fiterate_t; 53 54 static int hammer2_freemap_try_alloc(hammer2_chain_t **parentp, 55 hammer2_blockref_t *bref, int radix, 56 hammer2_fiterate_t *iter, hammer2_tid_t mtid); 57 static void hammer2_freemap_init(hammer2_dev_t *hmp, 58 hammer2_key_t key, hammer2_chain_t *chain); 59 static int hammer2_bmap_alloc(hammer2_dev_t *hmp, 60 hammer2_bmap_data_t *bmap, uint16_t class, 61 int n, int sub_key, int radix, hammer2_key_t *basep); 62 static int hammer2_freemap_iterate(hammer2_chain_t **parentp, 63 hammer2_chain_t **chainp, 64 hammer2_fiterate_t *iter); 65 66 /* 67 * Calculate the device offset for the specified FREEMAP_NODE or FREEMAP_LEAF 68 * bref. Return a combined media offset and physical size radix. Freemap 69 * chains use fixed storage offsets in the 4MB reserved area at the 70 * beginning of each 1GB zone. 71 * 72 * Rotate between eight possibilities. Theoretically this means we have seven 73 * good freemaps in case of a crash which we can use as a base for the fixup 74 * scan at mount-time. 75 */ 76 static 77 int 78 hammer2_freemap_reserve(hammer2_chain_t *chain, int radix) 79 { 80 hammer2_blockref_t *bref = &chain->bref; 81 hammer2_off_t off; 82 int index; 83 int index_inc; 84 size_t bytes; 85 86 /* 87 * Physical allocation size. 88 */ 89 bytes = (size_t)1 << radix; 90 91 /* 92 * Calculate block selection index 0..7 of current block. If this 93 * is the first allocation of the block (verses a modification of an 94 * existing block), we use index 0, otherwise we use the next rotating 95 * index. 96 */ 97 if ((bref->data_off & ~HAMMER2_OFF_MASK_RADIX) == 0) { 98 index = 0; 99 } else { 100 off = bref->data_off & ~HAMMER2_OFF_MASK_RADIX & 101 HAMMER2_SEGMASK; 102 off = off / HAMMER2_PBUFSIZE; 103 KKASSERT(off >= HAMMER2_ZONE_FREEMAP_00 && 104 off < HAMMER2_ZONE_FREEMAP_END); 105 index = (int)(off - HAMMER2_ZONE_FREEMAP_00) / 106 HAMMER2_ZONE_FREEMAP_INC; 107 KKASSERT(index >= 0 && index < HAMMER2_NFREEMAPS); 108 if (++index == HAMMER2_NFREEMAPS) 109 index = 0; 110 } 111 112 /* 113 * Calculate the block offset of the reserved block. This will 114 * point into the 4MB reserved area at the base of the appropriate 115 * 2GB zone, once added to the FREEMAP_x selection above. 116 */ 117 index_inc = index * HAMMER2_ZONE_FREEMAP_INC; 118 119 switch(bref->keybits) { 120 /* case HAMMER2_FREEMAP_LEVEL6_RADIX: not applicable */ 121 case HAMMER2_FREEMAP_LEVEL5_RADIX: /* 4EB */ 122 KKASSERT(bref->type == HAMMER2_BREF_TYPE_FREEMAP_NODE); 123 KKASSERT(bytes == HAMMER2_FREEMAP_LEVELN_PSIZE); 124 off = H2FMBASE(bref->key, HAMMER2_FREEMAP_LEVEL5_RADIX) + 125 (index_inc + HAMMER2_ZONE_FREEMAP_00 + 126 HAMMER2_ZONEFM_LEVEL5) * HAMMER2_PBUFSIZE; 127 break; 128 case HAMMER2_FREEMAP_LEVEL4_RADIX: /* 16PB */ 129 KKASSERT(bref->type == HAMMER2_BREF_TYPE_FREEMAP_NODE); 130 KKASSERT(bytes == HAMMER2_FREEMAP_LEVELN_PSIZE); 131 off = H2FMBASE(bref->key, HAMMER2_FREEMAP_LEVEL4_RADIX) + 132 (index_inc + HAMMER2_ZONE_FREEMAP_00 + 133 HAMMER2_ZONEFM_LEVEL4) * HAMMER2_PBUFSIZE; 134 break; 135 case HAMMER2_FREEMAP_LEVEL3_RADIX: /* 64TB */ 136 KKASSERT(bref->type == HAMMER2_BREF_TYPE_FREEMAP_NODE); 137 KKASSERT(bytes == HAMMER2_FREEMAP_LEVELN_PSIZE); 138 off = H2FMBASE(bref->key, HAMMER2_FREEMAP_LEVEL3_RADIX) + 139 (index_inc + HAMMER2_ZONE_FREEMAP_00 + 140 HAMMER2_ZONEFM_LEVEL3) * HAMMER2_PBUFSIZE; 141 break; 142 case HAMMER2_FREEMAP_LEVEL2_RADIX: /* 256GB */ 143 KKASSERT(bref->type == HAMMER2_BREF_TYPE_FREEMAP_NODE); 144 KKASSERT(bytes == HAMMER2_FREEMAP_LEVELN_PSIZE); 145 off = H2FMBASE(bref->key, HAMMER2_FREEMAP_LEVEL2_RADIX) + 146 (index_inc + HAMMER2_ZONE_FREEMAP_00 + 147 HAMMER2_ZONEFM_LEVEL2) * HAMMER2_PBUFSIZE; 148 break; 149 case HAMMER2_FREEMAP_LEVEL1_RADIX: /* 1GB */ 150 KKASSERT(bref->type == HAMMER2_BREF_TYPE_FREEMAP_LEAF); 151 KKASSERT(bytes == HAMMER2_FREEMAP_LEVELN_PSIZE); 152 off = H2FMBASE(bref->key, HAMMER2_FREEMAP_LEVEL1_RADIX) + 153 (index_inc + HAMMER2_ZONE_FREEMAP_00 + 154 HAMMER2_ZONEFM_LEVEL1) * HAMMER2_PBUFSIZE; 155 break; 156 default: 157 panic("freemap: bad radix(2) %p %d\n", bref, bref->keybits); 158 /* NOT REACHED */ 159 off = (hammer2_off_t)-1; 160 break; 161 } 162 bref->data_off = off | radix; 163 #if FREEMAP_DEBUG 164 kprintf("FREEMAP BLOCK TYPE %d %016jx/%d DATA_OFF=%016jx\n", 165 bref->type, bref->key, bref->keybits, bref->data_off); 166 #endif 167 return (0); 168 } 169 170 /* 171 * Normal freemap allocator 172 * 173 * Use available hints to allocate space using the freemap. Create missing 174 * freemap infrastructure on-the-fly as needed (including marking initial 175 * allocations using the iterator as allocated, instantiating new 2GB zones, 176 * and dealing with the end-of-media edge case). 177 * 178 * ip and bpref are only used as a heuristic to determine locality of 179 * reference. bref->key may also be used heuristically. 180 * 181 * This function is a NOP if bytes is 0. 182 */ 183 int 184 hammer2_freemap_alloc(hammer2_chain_t *chain, size_t bytes) 185 { 186 hammer2_dev_t *hmp = chain->hmp; 187 hammer2_blockref_t *bref = &chain->bref; 188 hammer2_chain_t *parent; 189 hammer2_tid_t mtid; 190 int radix; 191 int error; 192 unsigned int hindex; 193 hammer2_fiterate_t iter; 194 195 /* 196 * If allocating or downsizing to zero we just get rid of whatever 197 * data_off we had. 198 */ 199 if (bytes == 0) { 200 chain->bref.data_off = 0; 201 return 0; 202 } 203 204 KKASSERT(hmp->spmp); 205 mtid = hammer2_trans_sub(hmp->spmp); 206 207 /* 208 * Validate the allocation size. It must be a power of 2. 209 * 210 * For now require that the caller be aware of the minimum 211 * allocation (1K). 212 */ 213 radix = hammer2_getradix(bytes); 214 KKASSERT((size_t)1 << radix == bytes); 215 216 if (bref->type == HAMMER2_BREF_TYPE_FREEMAP_NODE || 217 bref->type == HAMMER2_BREF_TYPE_FREEMAP_LEAF) { 218 /* 219 * Freemap blocks themselves are assigned from the reserve 220 * area, not allocated from the freemap. 221 */ 222 error = hammer2_freemap_reserve(chain, radix); 223 224 return error; 225 } 226 227 KKASSERT(bytes >= HAMMER2_ALLOC_MIN && bytes <= HAMMER2_ALLOC_MAX); 228 229 /* 230 * Calculate the starting point for our allocation search. 231 * 232 * Each freemap leaf is dedicated to a specific freemap_radix. 233 * The freemap_radix can be more fine-grained than the device buffer 234 * radix which results in inodes being grouped together in their 235 * own segment, terminal-data (16K or less) and initial indirect 236 * block being grouped together, and then full-indirect and full-data 237 * blocks (64K) being grouped together. 238 * 239 * The single most important aspect of this is the inode grouping 240 * because that is what allows 'find' and 'ls' and other filesystem 241 * topology operations to run fast. 242 */ 243 #if 0 244 if (bref->data_off & ~HAMMER2_OFF_MASK_RADIX) 245 bpref = bref->data_off & ~HAMMER2_OFF_MASK_RADIX; 246 else if (trans->tmp_bpref) 247 bpref = trans->tmp_bpref; 248 else if (trans->tmp_ip) 249 bpref = trans->tmp_ip->chain->bref.data_off; 250 else 251 #endif 252 /* 253 * Heuristic tracking index. We would like one for each distinct 254 * bref type if possible. heur_freemap[] has room for two classes 255 * for each type. At a minimum we have to break-up our heuristic 256 * by device block sizes. 257 */ 258 hindex = HAMMER2_PBUFRADIX - HAMMER2_LBUFRADIX; 259 KKASSERT(hindex < HAMMER2_FREEMAP_HEUR_NRADIX); 260 hindex += bref->type * HAMMER2_FREEMAP_HEUR_NRADIX; 261 hindex &= HAMMER2_FREEMAP_HEUR_TYPES * HAMMER2_FREEMAP_HEUR_NRADIX - 1; 262 KKASSERT(hindex < HAMMER2_FREEMAP_HEUR_SIZE); 263 264 iter.bpref = hmp->heur_freemap[hindex]; 265 iter.relaxed = hmp->freemap_relaxed; 266 267 /* 268 * Make sure bpref is in-bounds. It's ok if bpref covers a zone's 269 * reserved area, the try code will iterate past it. 270 */ 271 if (iter.bpref > hmp->total_size) 272 iter.bpref = hmp->total_size - 1; 273 274 /* 275 * Iterate the freemap looking for free space before and after. 276 */ 277 parent = &hmp->fchain; 278 hammer2_chain_ref(parent); 279 hammer2_chain_lock(parent, HAMMER2_RESOLVE_ALWAYS); 280 error = HAMMER2_ERROR_EAGAIN; 281 iter.bnext = iter.bpref; 282 iter.loops = 0; 283 284 while (error == HAMMER2_ERROR_EAGAIN) { 285 error = hammer2_freemap_try_alloc(&parent, bref, radix, 286 &iter, mtid); 287 } 288 hmp->freemap_relaxed |= iter.relaxed; /* heuristical, SMP race ok */ 289 hmp->heur_freemap[hindex] = iter.bnext; 290 hammer2_chain_unlock(parent); 291 hammer2_chain_drop(parent); 292 293 return (error); 294 } 295 296 static int 297 hammer2_freemap_try_alloc(hammer2_chain_t **parentp, 298 hammer2_blockref_t *bref, int radix, 299 hammer2_fiterate_t *iter, hammer2_tid_t mtid) 300 { 301 hammer2_dev_t *hmp = (*parentp)->hmp; 302 hammer2_off_t l0size; 303 hammer2_off_t l1size; 304 hammer2_off_t l1mask; 305 hammer2_key_t key_dummy; 306 hammer2_chain_t *chain; 307 hammer2_off_t key; 308 size_t bytes; 309 uint16_t class; 310 int error; 311 312 /* 313 * Calculate the number of bytes being allocated, the number 314 * of contiguous bits of bitmap being allocated, and the bitmap 315 * mask. 316 * 317 * WARNING! cpu hardware may mask bits == 64 -> 0 and blow up the 318 * mask calculation. 319 */ 320 bytes = (size_t)1 << radix; 321 class = (bref->type << 8) | HAMMER2_PBUFRADIX; 322 323 /* 324 * Lookup the level1 freemap chain, creating and initializing one 325 * if necessary. Intermediate levels will be created automatically 326 * when necessary by hammer2_chain_create(). 327 */ 328 key = H2FMBASE(iter->bnext, HAMMER2_FREEMAP_LEVEL1_RADIX); 329 l0size = HAMMER2_FREEMAP_LEVEL0_SIZE; 330 l1size = HAMMER2_FREEMAP_LEVEL1_SIZE; 331 l1mask = l1size - 1; 332 333 chain = hammer2_chain_lookup(parentp, &key_dummy, key, key + l1mask, 334 &error, 335 HAMMER2_LOOKUP_ALWAYS | 336 HAMMER2_LOOKUP_MATCHIND); 337 338 if (chain == NULL) { 339 /* 340 * Create the missing leaf, be sure to initialize 341 * the auxillary freemap tracking information in 342 * the bref.check.freemap structure. 343 */ 344 #if 0 345 kprintf("freemap create L1 @ %016jx bpref %016jx\n", 346 key, iter->bpref); 347 #endif 348 error = hammer2_chain_create(parentp, &chain, NULL, hmp->spmp, 349 HAMMER2_METH_DEFAULT, 350 key, HAMMER2_FREEMAP_LEVEL1_RADIX, 351 HAMMER2_BREF_TYPE_FREEMAP_LEAF, 352 HAMMER2_FREEMAP_LEVELN_PSIZE, 353 mtid, 0, 0); 354 KKASSERT(error == 0); 355 if (error == 0) { 356 hammer2_chain_modify(chain, mtid, 0, 0); 357 bzero(&chain->data->bmdata[0], 358 HAMMER2_FREEMAP_LEVELN_PSIZE); 359 chain->bref.check.freemap.bigmask = (uint32_t)-1; 360 chain->bref.check.freemap.avail = l1size; 361 /* bref.methods should already be inherited */ 362 363 hammer2_freemap_init(hmp, key, chain); 364 } 365 } else if (chain->error) { 366 /* 367 * Error during lookup. 368 */ 369 kprintf("hammer2_freemap_try_alloc: %016jx: error %s\n", 370 (intmax_t)bref->data_off, 371 hammer2_error_str(chain->error)); 372 error = HAMMER2_ERROR_EIO; 373 } else if ((chain->bref.check.freemap.bigmask & 374 ((size_t)1 << radix)) == 0) { 375 /* 376 * Already flagged as not having enough space 377 */ 378 error = HAMMER2_ERROR_ENOSPC; 379 } else { 380 /* 381 * Modify existing chain to setup for adjustment. 382 */ 383 hammer2_chain_modify(chain, mtid, 0, 0); 384 } 385 386 /* 387 * Scan 4MB entries. 388 */ 389 if (error == 0) { 390 hammer2_bmap_data_t *bmap; 391 hammer2_key_t base_key; 392 int count; 393 int start; 394 int n; 395 396 KKASSERT(chain->bref.type == HAMMER2_BREF_TYPE_FREEMAP_LEAF); 397 start = (int)((iter->bnext - key) >> 398 HAMMER2_FREEMAP_LEVEL0_RADIX); 399 KKASSERT(start >= 0 && start < HAMMER2_FREEMAP_COUNT); 400 hammer2_chain_modify(chain, mtid, 0, 0); 401 402 error = HAMMER2_ERROR_ENOSPC; 403 for (count = 0; count < HAMMER2_FREEMAP_COUNT; ++count) { 404 int availchk; 405 406 if (start + count >= HAMMER2_FREEMAP_COUNT && 407 start - count < 0) { 408 break; 409 } 410 411 /* 412 * Calculate bmap pointer from thart starting index 413 * forwards. 414 * 415 * NOTE: bmap pointer is invalid if n >= FREEMAP_COUNT. 416 */ 417 n = start + count; 418 bmap = &chain->data->bmdata[n]; 419 420 if (n >= HAMMER2_FREEMAP_COUNT) { 421 availchk = 0; 422 } else if (bmap->avail) { 423 availchk = 1; 424 } else if (radix < HAMMER2_FREEMAP_BLOCK_RADIX && 425 (bmap->linear & HAMMER2_FREEMAP_BLOCK_MASK)) { 426 availchk = 1; 427 } else { 428 availchk = 0; 429 } 430 431 /* 432 * Try to allocate from a matching freemap class 433 * superblock. If we are in relaxed mode we allocate 434 * from any freemap class superblock. 435 */ 436 if (availchk && 437 (bmap->class == 0 || bmap->class == class || 438 iter->relaxed)) { 439 base_key = key + n * l0size; 440 error = hammer2_bmap_alloc(hmp, bmap, 441 class, n, 442 (int)bref->key, 443 radix, 444 &base_key); 445 if (error != HAMMER2_ERROR_ENOSPC) { 446 key = base_key; 447 break; 448 } 449 } 450 451 /* 452 * Calculate bmap pointer from the starting index 453 * backwards (locality). 454 * 455 * Must recalculate after potentially having called 456 * hammer2_bmap_alloc() above in case chain was 457 * reallocated. 458 * 459 * NOTE: bmap pointer is invalid if n < 0. 460 */ 461 n = start - count; 462 bmap = &chain->data->bmdata[n]; 463 if (n < 0) { 464 availchk = 0; 465 } else if (bmap->avail) { 466 availchk = 1; 467 } else if (radix < HAMMER2_FREEMAP_BLOCK_RADIX && 468 (bmap->linear & HAMMER2_FREEMAP_BLOCK_MASK)) { 469 availchk = 1; 470 } else { 471 availchk = 0; 472 } 473 474 /* 475 * Try to allocate from a matching freemap class 476 * superblock. If we are in relaxed mode we allocate 477 * from any freemap class superblock. 478 */ 479 if (availchk && 480 (bmap->class == 0 || bmap->class == class || 481 iter->relaxed)) { 482 base_key = key + n * l0size; 483 error = hammer2_bmap_alloc(hmp, bmap, 484 class, n, 485 (int)bref->key, 486 radix, 487 &base_key); 488 if (error != HAMMER2_ERROR_ENOSPC) { 489 key = base_key; 490 break; 491 } 492 } 493 } 494 495 /* 496 * We only know for sure that we can clear the bitmap bit 497 * if we scanned the entire array (start == 0) in relaxed 498 * mode. 499 */ 500 if (error == HAMMER2_ERROR_ENOSPC && 501 start == 0 && 502 iter->relaxed) 503 { 504 chain->bref.check.freemap.bigmask &= 505 (uint32_t)~((size_t)1 << radix); 506 } 507 /* XXX also scan down from original count */ 508 } 509 510 if (error == 0) { 511 /* 512 * Assert validity. Must be beyond the static allocator used 513 * by newfs_hammer2 (and thus also beyond the aux area), 514 * not go past the volume size, and must not be in the 515 * reserved segment area for a zone. 516 */ 517 KKASSERT(key >= hmp->voldata.allocator_beg && 518 key + bytes <= hmp->total_size); 519 KKASSERT((key & HAMMER2_ZONE_MASK64) >= HAMMER2_ZONE_SEG); 520 bref->data_off = key | radix; 521 522 /* 523 * Record dedupability. The dedup bits are cleared 524 * when bulkfree transitions the freemap from 11->10, 525 * and asserted to be clear on the 10->00 transition. 526 * 527 * We must record the bitmask with the chain locked 528 * at the time we set the allocation bits to avoid 529 * racing a bulkfree. 530 */ 531 if (bref->type == HAMMER2_BREF_TYPE_DATA) 532 hammer2_io_dedup_set(hmp, bref); 533 #if 0 534 kprintf("alloc cp=%p %016jx %016jx using %016jx\n", 535 chain, 536 bref->key, bref->data_off, chain->bref.data_off); 537 #endif 538 } else if (error == HAMMER2_ERROR_ENOSPC) { 539 /* 540 * Return EAGAIN with next iteration in iter->bnext, or 541 * return ENOSPC if the allocation map has been exhausted. 542 */ 543 error = hammer2_freemap_iterate(parentp, &chain, iter); 544 } 545 546 /* 547 * Cleanup 548 */ 549 if (chain) { 550 hammer2_chain_unlock(chain); 551 hammer2_chain_drop(chain); 552 } 553 return (error); 554 } 555 556 /* 557 * Allocate (1<<radix) bytes from the bmap whos base data offset is (*basep). 558 * 559 * If the linear iterator is mid-block we use it directly (the bitmap should 560 * already be marked allocated), otherwise we search for a block in the 561 * bitmap that fits the allocation request. 562 * 563 * A partial bitmap allocation sets the minimum bitmap granularity (16KB) 564 * to fully allocated and adjusts the linear allocator to allow the 565 * remaining space to be allocated. 566 * 567 * sub_key is the lower 32 bits of the chain->bref.key for the chain whos 568 * bref is being allocated. If the radix represents an allocation >= 16KB 569 * (aka HAMMER2_FREEMAP_BLOCK_RADIX) we try to use this key to select the 570 * blocks directly out of the bmap. 571 */ 572 static 573 int 574 hammer2_bmap_alloc(hammer2_dev_t *hmp, hammer2_bmap_data_t *bmap, 575 uint16_t class, int n, int sub_key, 576 int radix, hammer2_key_t *basep) 577 { 578 size_t size; 579 size_t bgsize; 580 int bmradix; 581 hammer2_bitmap_t bmmask; 582 int offset; 583 int i; 584 int j; 585 586 /* 587 * Take into account 2-bits per block when calculating bmradix. 588 */ 589 size = (size_t)1 << radix; 590 591 if (radix <= HAMMER2_FREEMAP_BLOCK_RADIX) { 592 bmradix = 2; 593 /* (16K) 2 bits per allocation block */ 594 } else { 595 bmradix = (hammer2_bitmap_t)2 << 596 (radix - HAMMER2_FREEMAP_BLOCK_RADIX); 597 /* (32K-256K) 4, 8, 16, 32 bits per allocation block */ 598 } 599 600 /* 601 * Use the linear iterator to pack small allocations, otherwise 602 * fall-back to finding a free 16KB chunk. The linear iterator 603 * is only valid when *NOT* on a freemap chunking boundary (16KB). 604 * If it is the bitmap must be scanned. It can become invalid 605 * once we pack to the boundary. We adjust it after a bitmap 606 * allocation only for sub-16KB allocations (so the perfectly good 607 * previous value can still be used for fragments when 16KB+ 608 * allocations are made inbetween fragmentary allocations). 609 * 610 * Beware of hardware artifacts when bmradix == 64 (intermediate 611 * result can wind up being '1' instead of '0' if hardware masks 612 * bit-count & 63). 613 * 614 * NOTE: j needs to be even in the j= calculation. As an artifact 615 * of the /2 division, our bitmask has to clear bit 0. 616 * 617 * NOTE: TODO this can leave little unallocatable fragments lying 618 * around. 619 */ 620 if (((uint32_t)bmap->linear & HAMMER2_FREEMAP_BLOCK_MASK) + size <= 621 HAMMER2_FREEMAP_BLOCK_SIZE && 622 (bmap->linear & HAMMER2_FREEMAP_BLOCK_MASK) && 623 bmap->linear < HAMMER2_SEGSIZE) { 624 /* 625 * Use linear iterator if it is not block-aligned to avoid 626 * wasting space. 627 * 628 * Calculate the bitmapq[] index (i) and calculate the 629 * shift count within the 64-bit bitmapq[] entry. 630 * 631 * The freemap block size is 16KB, but each bitmap 632 * entry is two bits so use a little trick to get 633 * a (j) shift of 0, 2, 4, ... 62 in 16KB chunks. 634 */ 635 KKASSERT(bmap->linear >= 0 && 636 bmap->linear + size <= HAMMER2_SEGSIZE && 637 (bmap->linear & (HAMMER2_ALLOC_MIN - 1)) == 0); 638 offset = bmap->linear; 639 i = offset / (HAMMER2_SEGSIZE / HAMMER2_BMAP_ELEMENTS); 640 j = (offset / (HAMMER2_FREEMAP_BLOCK_SIZE / 2)) & 62; 641 bmmask = (bmradix == HAMMER2_BMAP_BITS_PER_ELEMENT) ? 642 HAMMER2_BMAP_ALLONES : 643 ((hammer2_bitmap_t)1 << bmradix) - 1; 644 bmmask <<= j; 645 bmap->linear = offset + size; 646 } else { 647 /* 648 * Try to index a starting point based on sub_key. This 649 * attempts to restore sequential block ordering on-disk 650 * whenever possible, even if data is committed out of 651 * order. 652 * 653 * i - Index bitmapq[], full data range represented is 654 * HAMMER2_BMAP_SIZE. 655 * 656 * j - Index within bitmapq[i], full data range represented is 657 * HAMMER2_BMAP_INDEX_SIZE. 658 * 659 * WARNING! 660 */ 661 i = -1; 662 j = -1; 663 664 switch(class >> 8) { 665 case HAMMER2_BREF_TYPE_DATA: 666 if (radix >= HAMMER2_FREEMAP_BLOCK_RADIX) { 667 i = (sub_key & HAMMER2_BMAP_MASK) / 668 (HAMMER2_BMAP_SIZE / HAMMER2_BMAP_ELEMENTS); 669 j = (sub_key & HAMMER2_BMAP_INDEX_MASK) / 670 (HAMMER2_BMAP_INDEX_SIZE / 671 HAMMER2_BMAP_BLOCKS_PER_ELEMENT); 672 j = j * 2; 673 } 674 break; 675 case HAMMER2_BREF_TYPE_INODE: 676 break; 677 default: 678 break; 679 } 680 if (i >= 0) { 681 KKASSERT(i < HAMMER2_BMAP_ELEMENTS && 682 j < 2 * HAMMER2_BMAP_BLOCKS_PER_ELEMENT); 683 KKASSERT(j + bmradix <= HAMMER2_BMAP_BITS_PER_ELEMENT); 684 bmmask = (bmradix == HAMMER2_BMAP_BITS_PER_ELEMENT) ? 685 HAMMER2_BMAP_ALLONES : 686 ((hammer2_bitmap_t)1 << bmradix) - 1; 687 bmmask <<= j; 688 689 if ((bmap->bitmapq[i] & bmmask) == 0) 690 goto success; 691 } 692 693 /* 694 * General element scan. 695 * 696 * WARNING: (j) is iterating a bit index (by 2's) 697 */ 698 for (i = 0; i < HAMMER2_BMAP_ELEMENTS; ++i) { 699 bmmask = (bmradix == HAMMER2_BMAP_BITS_PER_ELEMENT) ? 700 HAMMER2_BMAP_ALLONES : 701 ((hammer2_bitmap_t)1 << bmradix) - 1; 702 for (j = 0; 703 j < HAMMER2_BMAP_BITS_PER_ELEMENT; 704 j += bmradix) { 705 if ((bmap->bitmapq[i] & bmmask) == 0) 706 goto success; 707 bmmask <<= bmradix; 708 } 709 } 710 /*fragments might remain*/ 711 /*KKASSERT(bmap->avail == 0);*/ 712 return (HAMMER2_ERROR_ENOSPC); 713 success: 714 offset = i * (HAMMER2_SEGSIZE / HAMMER2_BMAP_ELEMENTS) + 715 (j * (HAMMER2_FREEMAP_BLOCK_SIZE / 2)); 716 if (size & HAMMER2_FREEMAP_BLOCK_MASK) 717 bmap->linear = offset + size; 718 } 719 720 /* 8 x (64/2) -> 256 x 16K -> 4MB */ 721 KKASSERT(i >= 0 && i < HAMMER2_BMAP_ELEMENTS); 722 723 /* 724 * Optimize the buffer cache to avoid unnecessary read-before-write 725 * operations. 726 * 727 * The device block size could be larger than the allocation size 728 * so the actual bitmap test is somewhat more involved. We have 729 * to use a compatible buffer size for this operation. 730 */ 731 if ((bmap->bitmapq[i] & bmmask) == 0 && 732 HAMMER2_PBUFSIZE != size) { 733 size_t psize = HAMMER2_PBUFSIZE; 734 hammer2_off_t pmask = (hammer2_off_t)psize - 1; 735 int pbmradix = (hammer2_bitmap_t)2 << 736 (HAMMER2_PBUFRADIX - 737 HAMMER2_FREEMAP_BLOCK_RADIX); 738 hammer2_bitmap_t pbmmask; 739 int pradix = hammer2_getradix(psize); 740 741 pbmmask = (pbmradix == HAMMER2_BMAP_BITS_PER_ELEMENT) ? 742 HAMMER2_BMAP_ALLONES : 743 ((hammer2_bitmap_t)1 << pbmradix) - 1; 744 while ((pbmmask & bmmask) == 0) 745 pbmmask <<= pbmradix; 746 747 #if 0 748 kprintf("%016jx mask %016jx %016jx %016jx (%zd/%zd)\n", 749 *basep + offset, bmap->bitmapq[i], 750 pbmmask, bmmask, size, psize); 751 #endif 752 753 if ((bmap->bitmapq[i] & pbmmask) == 0) { 754 hammer2_io_t *dio; 755 756 hammer2_io_newnz(hmp, class >> 8, 757 (*basep + (offset & ~pmask)) | 758 pradix, psize, &dio); 759 hammer2_io_putblk(&dio); 760 } 761 } 762 763 #if 0 764 /* 765 * When initializing a new inode segment also attempt to initialize 766 * an adjacent segment. Be careful not to index beyond the array 767 * bounds. 768 * 769 * We do this to try to localize inode accesses to improve 770 * directory scan rates. XXX doesn't improve scan rates. 771 */ 772 if (size == HAMMER2_INODE_BYTES) { 773 if (n & 1) { 774 if (bmap[-1].radix == 0 && bmap[-1].avail) 775 bmap[-1].radix = radix; 776 } else { 777 if (bmap[1].radix == 0 && bmap[1].avail) 778 bmap[1].radix = radix; 779 } 780 } 781 #endif 782 /* 783 * Calculate the bitmap-granular change in bgsize for the volume 784 * header. We cannot use the fine-grained change here because 785 * the bulkfree code can't undo it. If the bitmap element is already 786 * marked allocated it has already been accounted for. 787 */ 788 if (radix < HAMMER2_FREEMAP_BLOCK_RADIX) { 789 if (bmap->bitmapq[i] & bmmask) 790 bgsize = 0; 791 else 792 bgsize = HAMMER2_FREEMAP_BLOCK_SIZE; 793 } else { 794 bgsize = size; 795 } 796 797 /* 798 * Adjust the bitmap, set the class (it might have been 0), 799 * and available bytes, update the allocation offset (*basep) 800 * from the L0 base to the actual offset. 801 * 802 * Do not override the class if doing a relaxed class allocation. 803 * 804 * avail must reflect the bitmap-granular availability. The allocator 805 * tests will also check the linear iterator. 806 */ 807 bmap->bitmapq[i] |= bmmask; 808 if (bmap->class == 0) 809 bmap->class = class; 810 bmap->avail -= bgsize; 811 *basep += offset; 812 813 /* 814 * Adjust the volume header's allocator_free parameter. This 815 * parameter has to be fixed up by bulkfree which has no way to 816 * figure out sub-16K chunking, so it must be adjusted by the 817 * bitmap-granular size. 818 */ 819 if (bgsize) { 820 hammer2_voldata_lock(hmp); 821 hammer2_voldata_modify(hmp); 822 hmp->voldata.allocator_free -= bgsize; 823 hammer2_voldata_unlock(hmp); 824 } 825 826 return(0); 827 } 828 829 /* 830 * Initialize a freemap for the storage area (in bytes) that begins at (key). 831 */ 832 static 833 void 834 hammer2_freemap_init(hammer2_dev_t *hmp, hammer2_key_t key, 835 hammer2_chain_t *chain) 836 { 837 hammer2_off_t lokey; 838 hammer2_off_t hikey; 839 hammer2_bmap_data_t *bmap; 840 int count; 841 842 /* 843 * Calculate the portion of the 1GB map that should be initialized 844 * as free. Portions below or after will be initialized as allocated. 845 * SEGMASK-align the areas so we don't have to worry about sub-scans 846 * or endianess when using memset. 847 * 848 * WARNING! It is possible for lokey to be larger than hikey if the 849 * entire 2GB segment is within the static allocation. 850 */ 851 /* 852 * (1) Ensure that all statically allocated space from newfs_hammer2 853 * is marked allocated, and take it up to the level1 base for 854 * this key. 855 */ 856 lokey = (hmp->voldata.allocator_beg + HAMMER2_SEGMASK64) & 857 ~HAMMER2_SEGMASK64; 858 if (lokey < H2FMBASE(key, HAMMER2_FREEMAP_LEVEL1_RADIX)) 859 lokey = H2FMBASE(key, HAMMER2_FREEMAP_LEVEL1_RADIX); 860 861 /* 862 * (2) Ensure that the reserved area is marked allocated (typically 863 * the first 4MB of each 2GB area being represented). Since 864 * each LEAF represents 1GB of storage and the zone is 2GB, we 865 * have to adjust lowkey upward every other LEAF sequentially. 866 */ 867 if (lokey < H2FMZONEBASE(key) + HAMMER2_ZONE_SEG64) 868 lokey = H2FMZONEBASE(key) + HAMMER2_ZONE_SEG64; 869 870 /* 871 * (3) Ensure that any trailing space at the end-of-volume is marked 872 * allocated. 873 */ 874 hikey = key + HAMMER2_FREEMAP_LEVEL1_SIZE; 875 if (hikey > hmp->total_size) { 876 hikey = hmp->total_size & ~HAMMER2_SEGMASK64; 877 } 878 879 /* 880 * Heuristic highest possible value 881 */ 882 chain->bref.check.freemap.avail = HAMMER2_FREEMAP_LEVEL1_SIZE; 883 bmap = &chain->data->bmdata[0]; 884 885 /* 886 * Initialize bitmap (bzero'd by caller) 887 */ 888 for (count = 0; count < HAMMER2_FREEMAP_COUNT; ++count) { 889 if (key < lokey || key >= hikey) { 890 memset(bmap->bitmapq, -1, 891 sizeof(bmap->bitmapq)); 892 bmap->avail = 0; 893 bmap->linear = HAMMER2_SEGSIZE; 894 chain->bref.check.freemap.avail -= 895 HAMMER2_FREEMAP_LEVEL0_SIZE; 896 } else { 897 bmap->avail = HAMMER2_FREEMAP_LEVEL0_SIZE; 898 } 899 key += HAMMER2_FREEMAP_LEVEL0_SIZE; 900 ++bmap; 901 } 902 } 903 904 /* 905 * The current Level 1 freemap has been exhausted, iterate to the next 906 * one, return ENOSPC if no freemaps remain. 907 * 908 * At least two loops are required. If we are not in relaxed mode and 909 * we run out of storage we enter relaxed mode and do a third loop. 910 * The relaxed mode is recorded back in the hmp so once we enter the mode 911 * we remain relaxed until stuff begins to get freed and only do 2 loops. 912 * 913 * XXX this should rotate back to the beginning to handle freed-up space 914 * XXX or use intermediate entries to locate free space. TODO 915 */ 916 static int 917 hammer2_freemap_iterate(hammer2_chain_t **parentp, hammer2_chain_t **chainp, 918 hammer2_fiterate_t *iter) 919 { 920 hammer2_dev_t *hmp = (*parentp)->hmp; 921 922 iter->bnext &= ~HAMMER2_FREEMAP_LEVEL1_MASK; 923 iter->bnext += HAMMER2_FREEMAP_LEVEL1_SIZE; 924 if (iter->bnext >= hmp->total_size) { 925 iter->bnext = 0; 926 if (++iter->loops >= 2) { 927 if (iter->relaxed == 0) 928 iter->relaxed = 1; 929 else 930 return (HAMMER2_ERROR_ENOSPC); 931 } 932 } 933 return(HAMMER2_ERROR_EAGAIN); 934 } 935 936 /* 937 * Adjust the bit-pattern for data in the freemap bitmap according to 938 * (how). This code is called from on-mount recovery to fixup (mark 939 * as allocated) blocks whos freemap upates might not have been committed 940 * in the last crash and is used by the bulk freemap scan to stage frees. 941 * 942 * WARNING! Cannot be called with a empty-data bref (radix == 0). 943 * 944 * XXX currently disabled when how == 0 (the normal real-time case). At 945 * the moment we depend on the bulk freescan to actually free blocks. It 946 * will still call this routine with a non-zero how to stage possible frees 947 * and to do the actual free. 948 */ 949 void 950 hammer2_freemap_adjust(hammer2_dev_t *hmp, hammer2_blockref_t *bref, 951 int how) 952 { 953 hammer2_off_t data_off = bref->data_off; 954 hammer2_chain_t *chain; 955 hammer2_chain_t *parent; 956 hammer2_bmap_data_t *bmap; 957 hammer2_key_t key; 958 hammer2_key_t key_dummy; 959 hammer2_off_t l1size; 960 hammer2_off_t l1mask; 961 hammer2_tid_t mtid; 962 hammer2_bitmap_t *bitmap; 963 const hammer2_bitmap_t bmmask00 = 0; 964 hammer2_bitmap_t bmmask01; 965 hammer2_bitmap_t bmmask10; 966 hammer2_bitmap_t bmmask11; 967 size_t bytes; 968 uint16_t class; 969 int radix; 970 int start; 971 int count; 972 int modified = 0; 973 int error; 974 size_t bgsize = 0; 975 976 KKASSERT(how == HAMMER2_FREEMAP_DORECOVER); 977 978 KKASSERT(hmp->spmp); 979 mtid = hammer2_trans_sub(hmp->spmp); 980 981 radix = (int)data_off & HAMMER2_OFF_MASK_RADIX; 982 KKASSERT(radix != 0); 983 data_off &= ~HAMMER2_OFF_MASK_RADIX; 984 KKASSERT(radix <= HAMMER2_RADIX_MAX); 985 986 if (radix) 987 bytes = (size_t)1 << radix; 988 else 989 bytes = 0; 990 class = (bref->type << 8) | HAMMER2_PBUFRADIX; 991 992 /* 993 * We can't adjust the freemap for data allocations made by 994 * newfs_hammer2. 995 */ 996 if (data_off < hmp->voldata.allocator_beg) 997 return; 998 999 KKASSERT((data_off & HAMMER2_ZONE_MASK64) >= HAMMER2_ZONE_SEG); 1000 1001 /* 1002 * Lookup the level1 freemap chain. The chain must exist. 1003 */ 1004 key = H2FMBASE(data_off, HAMMER2_FREEMAP_LEVEL1_RADIX); 1005 l1size = HAMMER2_FREEMAP_LEVEL1_SIZE; 1006 l1mask = l1size - 1; 1007 1008 parent = &hmp->fchain; 1009 hammer2_chain_ref(parent); 1010 hammer2_chain_lock(parent, HAMMER2_RESOLVE_ALWAYS); 1011 1012 chain = hammer2_chain_lookup(&parent, &key_dummy, key, key + l1mask, 1013 &error, 1014 HAMMER2_LOOKUP_ALWAYS | 1015 HAMMER2_LOOKUP_MATCHIND); 1016 1017 /* 1018 * Stop early if we are trying to free something but no leaf exists. 1019 */ 1020 if (chain == NULL && how != HAMMER2_FREEMAP_DORECOVER) { 1021 kprintf("hammer2_freemap_adjust: %016jx: no chain\n", 1022 (intmax_t)bref->data_off); 1023 goto done; 1024 } 1025 if (chain->error) { 1026 kprintf("hammer2_freemap_adjust: %016jx: error %s\n", 1027 (intmax_t)bref->data_off, 1028 hammer2_error_str(chain->error)); 1029 hammer2_chain_unlock(chain); 1030 hammer2_chain_drop(chain); 1031 chain = NULL; 1032 goto done; 1033 } 1034 1035 /* 1036 * Create any missing leaf(s) if we are doing a recovery (marking 1037 * the block(s) as being allocated instead of being freed). Be sure 1038 * to initialize the auxillary freemap tracking info in the 1039 * bref.check.freemap structure. 1040 */ 1041 if (chain == NULL && how == HAMMER2_FREEMAP_DORECOVER) { 1042 error = hammer2_chain_create(&parent, &chain, NULL, hmp->spmp, 1043 HAMMER2_METH_DEFAULT, 1044 key, HAMMER2_FREEMAP_LEVEL1_RADIX, 1045 HAMMER2_BREF_TYPE_FREEMAP_LEAF, 1046 HAMMER2_FREEMAP_LEVELN_PSIZE, 1047 mtid, 0, 0); 1048 1049 if (hammer2_debug & 0x0040) { 1050 kprintf("fixup create chain %p %016jx:%d\n", 1051 chain, chain->bref.key, chain->bref.keybits); 1052 } 1053 1054 if (error == 0) { 1055 error = hammer2_chain_modify(chain, mtid, 0, 0); 1056 KKASSERT(error == 0); 1057 bzero(&chain->data->bmdata[0], 1058 HAMMER2_FREEMAP_LEVELN_PSIZE); 1059 chain->bref.check.freemap.bigmask = (uint32_t)-1; 1060 chain->bref.check.freemap.avail = l1size; 1061 /* bref.methods should already be inherited */ 1062 1063 hammer2_freemap_init(hmp, key, chain); 1064 } 1065 /* XXX handle error */ 1066 } 1067 1068 #if FREEMAP_DEBUG 1069 kprintf("FREEMAP ADJUST TYPE %d %016jx/%d DATA_OFF=%016jx\n", 1070 chain->bref.type, chain->bref.key, 1071 chain->bref.keybits, chain->bref.data_off); 1072 #endif 1073 1074 /* 1075 * Calculate the bitmask (runs in 2-bit pairs). 1076 */ 1077 start = ((int)(data_off >> HAMMER2_FREEMAP_BLOCK_RADIX) & 15) * 2; 1078 bmmask01 = (hammer2_bitmap_t)1 << start; 1079 bmmask10 = (hammer2_bitmap_t)2 << start; 1080 bmmask11 = (hammer2_bitmap_t)3 << start; 1081 1082 /* 1083 * Fixup the bitmap. Partial blocks cannot be fully freed unless 1084 * a bulk scan is able to roll them up. 1085 */ 1086 if (radix < HAMMER2_FREEMAP_BLOCK_RADIX) { 1087 count = 1; 1088 #if 0 1089 if (how == HAMMER2_FREEMAP_DOREALFREE) 1090 how = HAMMER2_FREEMAP_DOMAYFREE; 1091 #endif 1092 } else { 1093 count = 1 << (radix - HAMMER2_FREEMAP_BLOCK_RADIX); 1094 } 1095 1096 /* 1097 * [re]load the bmap and bitmap pointers. Each bmap entry covers 1098 * a 4MB swath. The bmap itself (LEVEL1) covers 2GB. 1099 * 1100 * Be sure to reset the linear iterator to ensure that the adjustment 1101 * is not ignored. 1102 */ 1103 again: 1104 bmap = &chain->data->bmdata[(int)(data_off >> HAMMER2_SEGRADIX) & 1105 (HAMMER2_FREEMAP_COUNT - 1)]; 1106 bitmap = &bmap->bitmapq[(int)(data_off >> (HAMMER2_SEGRADIX - 3)) & 7]; 1107 1108 if (modified) 1109 bmap->linear = 0; 1110 1111 while (count) { 1112 KKASSERT(bmmask11); 1113 if (how == HAMMER2_FREEMAP_DORECOVER) { 1114 /* 1115 * Recovery request, mark as allocated. 1116 */ 1117 if ((*bitmap & bmmask11) != bmmask11) { 1118 if (modified == 0) { 1119 hammer2_chain_modify(chain, mtid, 0, 0); 1120 modified = 1; 1121 goto again; 1122 } 1123 if ((*bitmap & bmmask11) == bmmask00) { 1124 bmap->avail -= 1125 HAMMER2_FREEMAP_BLOCK_SIZE; 1126 bgsize += HAMMER2_FREEMAP_BLOCK_SIZE; 1127 } 1128 if (bmap->class == 0) 1129 bmap->class = class; 1130 *bitmap |= bmmask11; 1131 if (hammer2_debug & 0x0040) { 1132 kprintf("hammer2_freemap_adjust: " 1133 "fixup type=%02x " 1134 "block=%016jx/%zd\n", 1135 bref->type, data_off, bytes); 1136 } 1137 } else { 1138 /* 1139 kprintf("hammer2_freemap_adjust: good " 1140 "type=%02x block=%016jx/%zd\n", 1141 bref->type, data_off, bytes); 1142 */ 1143 } 1144 } 1145 #if 0 1146 /* 1147 * XXX this stuff doesn't work, avail is miscalculated and 1148 * code 10 means something else now. 1149 */ 1150 else if ((*bitmap & bmmask11) == bmmask11) { 1151 /* 1152 * Mayfree/Realfree request and bitmap is currently 1153 * marked as being fully allocated. 1154 */ 1155 if (!modified) { 1156 hammer2_chain_modify(chain, 0); 1157 modified = 1; 1158 goto again; 1159 } 1160 if (how == HAMMER2_FREEMAP_DOREALFREE) 1161 *bitmap &= ~bmmask11; 1162 else 1163 *bitmap = (*bitmap & ~bmmask11) | bmmask10; 1164 } else if ((*bitmap & bmmask11) == bmmask10) { 1165 /* 1166 * Mayfree/Realfree request and bitmap is currently 1167 * marked as being possibly freeable. 1168 */ 1169 if (how == HAMMER2_FREEMAP_DOREALFREE) { 1170 if (!modified) { 1171 hammer2_chain_modify(chain, 0); 1172 modified = 1; 1173 goto again; 1174 } 1175 *bitmap &= ~bmmask11; 1176 } 1177 } else { 1178 /* 1179 * 01 - Not implemented, currently illegal state 1180 * 00 - Not allocated at all, illegal free. 1181 */ 1182 panic("hammer2_freemap_adjust: " 1183 "Illegal state %08x(%08x)", 1184 *bitmap, *bitmap & bmmask11); 1185 } 1186 #endif 1187 --count; 1188 bmmask01 <<= 2; 1189 bmmask10 <<= 2; 1190 bmmask11 <<= 2; 1191 } 1192 #if 0 1193 #if HAMMER2_BMAP_ELEMENTS != 8 1194 #error "hammer2_freemap.c: HAMMER2_BMAP_ELEMENTS expected to be 8" 1195 #endif 1196 if (how == HAMMER2_FREEMAP_DOREALFREE && modified) { 1197 bmap->avail += 1 << radix; 1198 KKASSERT(bmap->avail <= HAMMER2_SEGSIZE); 1199 if (bmap->avail == HAMMER2_SEGSIZE && 1200 bmap->bitmapq[0] == 0 && 1201 bmap->bitmapq[1] == 0 && 1202 bmap->bitmapq[2] == 0 && 1203 bmap->bitmapq[3] == 0 && 1204 bmap->bitmapq[4] == 0 && 1205 bmap->bitmapq[5] == 0 && 1206 bmap->bitmapq[6] == 0 && 1207 bmap->bitmapq[7] == 0) { 1208 key = H2FMBASE(data_off, HAMMER2_FREEMAP_LEVEL0_RADIX); 1209 kprintf("Freeseg %016jx\n", (intmax_t)key); 1210 bmap->class = 0; 1211 } 1212 } 1213 #endif 1214 1215 /* 1216 * chain->bref.check.freemap.bigmask (XXX) 1217 * 1218 * Setting bigmask is a hint to the allocation code that there might 1219 * be something allocatable. We also set this in recovery... it 1220 * doesn't hurt and we might want to use the hint for other validation 1221 * operations later on. 1222 * 1223 * We could calculate the largest possible allocation and set the 1224 * radii that could fit, but its easier just to set bigmask to -1. 1225 */ 1226 if (modified) { 1227 chain->bref.check.freemap.bigmask = -1; 1228 hmp->freemap_relaxed = 0; /* reset heuristic */ 1229 } 1230 1231 hammer2_chain_unlock(chain); 1232 hammer2_chain_drop(chain); 1233 done: 1234 hammer2_chain_unlock(parent); 1235 hammer2_chain_drop(parent); 1236 1237 if (bgsize) { 1238 hammer2_voldata_lock(hmp); 1239 hammer2_voldata_modify(hmp); 1240 hmp->voldata.allocator_free -= bgsize; 1241 hammer2_voldata_unlock(hmp); 1242 } 1243 } 1244 1245 /* 1246 * Validate the freemap, in three stages. 1247 * 1248 * stage-1 ALLOCATED -> POSSIBLY FREE 1249 * POSSIBLY FREE -> POSSIBLY FREE (type corrected) 1250 * 1251 * This transitions bitmap entries from ALLOCATED to POSSIBLY FREE. 1252 * The POSSIBLY FREE state does not mean that a block is actually free 1253 * and may be transitioned back to ALLOCATED in stage-2. 1254 * 1255 * This is typically done during normal filesystem operations when 1256 * something is deleted or a block is replaced. 1257 * 1258 * This is done by bulkfree in-bulk after a memory-bounded meta-data 1259 * scan to try to determine what might be freeable. 1260 * 1261 * This can be done unconditionally through a freemap scan when the 1262 * intention is to brute-force recover the proper state of the freemap. 1263 * 1264 * stage-2 POSSIBLY FREE -> ALLOCATED (scan metadata topology) 1265 * 1266 * This is done by bulkfree during a meta-data scan to ensure that 1267 * all blocks still actually allocated by the filesystem are marked 1268 * as such. 1269 * 1270 * NOTE! Live filesystem transitions to POSSIBLY FREE can occur while 1271 * the bulkfree stage-2 and stage-3 is running. The live filesystem 1272 * will use the alternative POSSIBLY FREE type (2) to prevent 1273 * stage-3 from improperly transitioning unvetted possibly-free 1274 * blocks to FREE. 1275 * 1276 * stage-3 POSSIBLY FREE (type 1) -> FREE (scan freemap) 1277 * 1278 * This is done by bulkfree to finalize POSSIBLY FREE states. 1279 * 1280 */ 1281