| blob | f4f6cd6ad020e63a6166d3389720ecfb2de30f48 |
1 /*
2 * Block driver for the QCOW version 2 format
3 *
4 * Copyright (c) 2004-2006 Fabrice Bellard
5 *
6 * Permission is hereby granted, free of charge, to any person obtaining a copy
7 * of this software and associated documentation files (the "Software"), to deal
8 * in the Software without restriction, including without limitation the rights
9 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
10 * copies of the Software, and to permit persons to whom the Software is
11 * furnished to do so, subject to the following conditions:
12 *
13 * The above copyright notice and this permission notice shall be included in
14 * all copies or substantial portions of the Software.
15 *
16 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
17 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
18 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
19 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
20 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
21 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
22 * THE SOFTWARE.
23 */
26 #include <zlib.h>
37 {
43 }
47 #ifdef DEBUG_ALLOC2
49 #endif
57 }
62 }
68 }
72 }
75 fail:
76 /*
77 * If the write in the l1_table failed the image may contain a partially
78 * overwritten l1_table. In this case it would be better to clear the
79 * l1_table in memory to avoid possible image corruption.
80 */
84 }
88 {
99 /* Do a sanity check on min_size before trying to calculate new_l1_size
100 * (this prevents overflows during the while loop for the calculation of
101 * new_l1_size) */
104 }
109 /* Bump size up to reduce the number of times we have to grow */
113 }
116 }
117 }
122 }
124 #ifdef DEBUG_ALLOC2
127 #endif
133 }
138 }
140 /* write new table (align to cluster) */
146 }
151 }
153 /* the L1 position has not yet been updated, so these clusters must
154 * indeed be completely free */
159 }
171 /* set new table */
179 }
187 QCOW2_DISCARD_OTHER);
189 fail:
192 QCOW2_DISCARD_OTHER);
194 }
196 /*
197 * l2_load
198 *
199 * @bs: The BlockDriverState
200 * @offset: A guest offset, used to calculate what slice of the L2
201 * table to load.
202 * @l2_offset: Offset to the L2 table in the image file.
203 * @l2_slice: Location to store the pointer to the L2 slice.
204 *
205 * Loads a L2 slice into memory (L2 slices are the parts of L2 tables
206 * that are loaded by the qcow2 cache). If the slice is in the cache,
207 * the cache is used; otherwise the L2 slice is loaded from the image
208 * file.
209 */
212 {
219 }
221 /*
222 * Writes an L1 entry to disk (note that depending on the alignment
223 * requirements this function may write more that just one entry in
224 * order to prevent bdrv_pwrite from performing a read-modify-write)
225 */
227 {
238 }
243 }
249 }
257 }
260 }
262 /*
263 * l2_allocate
264 *
265 * Allocate a new l2 entry in the file. If l1_index points to an already
266 * used entry in the L2 table (i.e. we are doing a copy on write for the L2
267 * table) copy the contents of the old L2 table into the newly allocated one.
268 * Otherwise the new table is initialized with zeros.
269 *
270 */
273 {
285 /* allocate a new l2 entry */
291 }
293 /* The offset must fit in the offset field of the L1 table entry */
296 /* If we're allocating the table at offset 0 then something is wrong */
302 }
307 }
309 /* allocate a new entry in the l2 cache */
321 }
324 /* if there was no old l2 table, clear the new slice */
331 /* if there was an old l2 table, read a slice from the disk */
337 }
342 }
344 /* write the l2 slice to the file */
350 }
355 }
357 /* update the L1 entry */
363 }
368 fail:
372 }
376 QCOW2_DISCARD_ALWAYS);
377 }
379 }
381 /*
382 * For a given L2 entry, count the number of contiguous subclusters of
383 * the same type starting from @sc_from. Compressed clusters are
384 * treated as if they were divided into subclusters of size
385 * s->subcluster_size.
386 *
387 * Return the number of contiguous subclusters and set @type to the
388 * subcluster type.
389 *
390 * If the L2 entry is invalid return -errno and set @type to
391 * QCOW2_SUBCLUSTER_INVALID.
392 */
398 {
408 }
428 }
429 }
431 /*
432 * Return the number of contiguous subclusters of the exact same type
433 * in a given L2 slice, starting from cluster @l2_index, subcluster
434 * @sc_index. Allocated subclusters are required to be contiguous in
435 * the image file.
436 * At most @nb_clusters are checked (note that this means clusters,
437 * not subclusters).
438 * Compressed clusters are always processed one by one but for the
439 * purpose of this count they are treated as if they were divided into
440 * subclusters of size s->subcluster_size.
441 * On failure return -errno and update @l2_index to point to the
442 * invalid entry.
443 */
447 {
465 }
468 /* Compressed clusters are always processed one by one */
470 }
482 }
483 }
485 /* Stop if there are type changes before the end of the cluster */
488 }
489 }
492 }
494 static int coroutine_fn GRAPH_RDLOCK
497 {
502 }
508 }
510 /*
511 * We never deal with requests that don't satisfy
512 * bdrv_check_qiov_request(), and aligning requests to clusters never
513 * breaks this condition. So, do some assertions before calling
514 * bs->drv->bdrv_co_preadv_part() which has int64_t arguments.
515 */
518 /* Cast qiov->size to uint64_t to silence a compiler warning on -m32 */
522 /*
523 * Call .bdrv_co_readv() directly instead of using the public block-layer
524 * interface. This avoids double I/O throttling and request tracking,
525 * which can lead to deadlock when block layer copy-on-read is enabled.
526 */
532 }
535 }
537 static int coroutine_fn GRAPH_RDLOCK
540 {
546 }
552 }
559 }
562 }
565 /*
566 * get_host_offset
567 *
568 * For a given offset of the virtual disk find the equivalent host
569 * offset in the qcow2 file and store it in *host_offset. Neither
570 * offset needs to be aligned to a cluster boundary.
571 *
572 * If the cluster is unallocated then *host_offset will be 0.
573 * If the cluster is compressed then *host_offset will contain the l2 entry.
574 *
575 * On entry, *bytes is the maximum number of contiguous bytes starting at
576 * offset that we are interested in.
577 *
578 * On exit, *bytes is the number of bytes starting at offset that have the same
579 * subcluster type and (if applicable) are stored contiguously in the image
580 * file. The subcluster type is stored in *subcluster_type.
581 * Compressed clusters are always processed one by one.
582 *
583 * Returns 0 on success, -errno in error cases.
584 */
588 {
595 QCow2SubclusterType type;
601 /* compute how many bytes there are between the start of the cluster
602 * containing offset and the end of the l2 slice that contains
603 * the entry pointing to it */
604 bytes_available =
610 }
614 /* seek to the l2 offset in the l1 table */
620 }
626 }
633 }
635 /* load the l2 slice in memory */
640 }
642 /* find the cluster offset for the given disk offset */
650 /* bytes_needed <= *bytes + offset_in_cluster, both of which are unsigned
651 * integers; the minimum cluster size is 512, so this assertion is always
652 * true */
659 " in pre-v3 image (L2 offset: %#" PRIx64
663 }
670 "entry found in image with external data "
675 }
688 "Cluster allocation offset %#"
689 PRIx64 " unaligned (L2 offset: %#" PRIx64
694 }
697 "External data file host cluster offset %#"
698 PRIx64 " does not match guest cluster "
699 "offset: %#" PRIx64
704 }
706 }
709 }
719 }
724 out:
727 }
729 /* bytes_available <= bytes_needed <= *bytes + offset_in_cluster;
730 * subtracting offset_in_cluster will therefore definitely yield something
731 * not exceeding UINT_MAX */
739 fail:
742 }
744 /*
745 * get_cluster_table
746 *
747 * for a given disk offset, load (and allocate if needed)
748 * the appropriate slice of its l2 table.
749 *
750 * the cluster index in the l2 slice is given to the caller.
751 *
752 * Returns 0 on success, -errno in failure case
753 */
757 {
764 /* seek to the l2 offset in the l1 table */
771 }
772 }
781 }
784 /* First allocate a new L2 table (and do COW if needed) */
788 }
790 /* Then decrease the refcount of the old table */
793 QCOW2_DISCARD_OTHER);
794 }
796 /* Get the offset of the newly-allocated l2 table */
799 }
801 /* load the l2 slice in memory */
805 }
807 /* find the cluster offset for the given disk offset */
815 }
817 /*
818 * alloc_compressed_cluster_offset
819 *
820 * For a given offset on the virtual disk, allocate a new compressed cluster
821 * and put the host offset of the cluster into *host_offset. If a cluster is
822 * already allocated at the offset, return an error.
823 *
824 * Return 0 on success and -errno in error cases
825 */
826 int coroutine_fn GRAPH_RDLOCK
829 {
838 }
843 }
845 /* Compression can't overwrite anything. Fail if the cluster was already
846 * allocated. */
851 }
857 }
859 nb_csectors =
863 /* The offset and size must fit in their fields of the L2 table entry */
870 /* update L2 table */
872 /* compressed clusters never have the copied flag */
879 }
884 }
886 static int coroutine_fn GRAPH_RDLOCK
888 {
896 QEMUIOVector qiov;
905 }
907 /* If we have to read both the start and end COW regions and the
908 * middle region is not too large then perform just one read
909 * operation */
914 /* If we have to do two reads, add some padding in the middle
915 * if necessary to make sure that the end region is optimally
916 * aligned. */
922 }
924 /* Reserve a buffer large enough to store all the data that we're
925 * going to read */
929 }
930 /* The part of the buffer where the end region is located */
936 data_bytes)
940 /* First we read the existing data from both COW regions. We
941 * either read the whole region in one go, or the start and end
942 * regions separately. */
951 }
956 }
959 }
961 /* Encrypt the data if necessary before writing it */
969 }
977 }
978 }
980 /* And now we can write everything. If we have the guest data we
981 * can write everything in one single operation */
986 }
990 }
991 /* NOTE: we have a write_aio blkdebug event here followed by
992 * a cow_write one in do_perform_cow_write(), but there's only
993 * one single I/O operation */
997 /* If there's no guest data then write both COW regions separately */
1003 }
1008 }
1010 fail:
1013 /*
1014 * Before we update the L2 table to actually point to the new cluster, we
1015 * need to be sure that the refcounts have been increased and COW was
1016 * handled.
1017 */
1020 }
1025 }
1029 {
1042 }
1044 /* copy content of unmodified sectors */
1048 }
1050 /* Update L2 table. */
1053 }
1057 }
1062 }
1070 /* if two concurrent writes happen to the same unallocated cluster
1071 * each write allocates separate cluster and writes data concurrently.
1072 * The first one to complete updates l2 table with pointer to its
1073 * cluster the second one has to do RMW (which is done above by
1074 * perform_cow()), update l2 table with its cluster pointer and free
1075 * old cluster. This is what this loop does */
1078 }
1080 /* The offset must fit in the offset field of the L2 table entry */
1085 /* Update bitmap with the subclusters that were just written */
1091 /* Narrow written_from and written_to down to the current cluster */
1100 }
1101 }
1106 /*
1107 * If this was a COW, we need to decrease the refcount of the old cluster.
1108 *
1109 * Don't discard clusters that reach a refcount of 0 (e.g. compressed
1110 * clusters), the next write will reuse them anyway.
1111 */
1115 }
1116 }
1119 err:
1122 }
1124 /**
1125 * Frees the allocated clusters because the request failed and they won't
1126 * actually be linked.
1127 */
1129 {
1134 QCOW2_DISCARD_NEVER);
1135 }
1136 }
1138 /*
1139 * For a given write request, create a new QCowL2Meta structure, add
1140 * it to @m and the BDRVQcow2State.cluster_allocs list. If the write
1141 * request does not need copy-on-write or changes to the L2 metadata
1142 * then this function does nothing.
1143 *
1144 * @host_cluster_offset points to the beginning of the first cluster.
1145 *
1146 * @guest_offset and @bytes indicate the offset and length of the
1147 * request.
1148 *
1149 * @l2_slice contains the L2 entries of all clusters involved in this
1150 * write request.
1151 *
1152 * If @keep_old is true it means that the clusters were already
1153 * allocated and will be overwritten. If false then the clusters are
1154 * new and we have to decrease the reference count of the old ones.
1155 *
1156 * Returns 0 on success, -errno on failure.
1157 */
1163 {
1172 QCow2SubclusterType type;
1178 /* Check the type of all affected subclusters */
1189 /* Is any of the subclusters of type != QCOW2_SUBCLUSTER_NORMAL ? */
1192 }
1194 /* If we can't skip the cow we can still look for invalid entries */
1196 }
1201 "entry found (L2 offset: %#" PRIx64
1205 }
1206 }
1210 }
1212 /* Get the L2 entry of the first cluster */
1227 /* Skip all leading zero and unallocated subclusters */
1229 cow_start_from =
1233 }
1241 }
1253 }
1254 }
1256 /* Get the L2 entry of the last cluster */
1273 /* Skip all trailing zero and unallocated subclusters */
1275 cow_end_to -=
1278 }
1286 }
1298 }
1299 }
1314 },
1318 },
1319 };
1325 }
1327 /*
1328 * Returns true if writing to the cluster pointed to by @l2_entry
1329 * requires a new allocation (that is, if the cluster is unallocated
1330 * or has refcount > 1 and therefore cannot be written in-place).
1331 */
1333 {
1339 }
1340 /* fallthrough */
1347 }
1348 }
1350 /*
1351 * Returns the number of contiguous clusters that can be written to
1352 * using one single write request, starting from @l2_index.
1353 * At most @nb_clusters are checked.
1354 *
1355 * If @new_alloc is true this counts clusters that are either
1356 * unallocated, or allocated but with refcount > 1 (so they need to be
1357 * newly allocated and COWed).
1358 *
1359 * If @new_alloc is false this counts clusters that are already
1360 * allocated and can be overwritten in-place (this includes clusters
1361 * of type QCOW2_CLUSTER_ZERO_ALLOC).
1362 */
1366 {
1376 }
1380 }
1382 }
1383 }
1387 }
1389 /*
1390 * Check if there already is an AIO write request in flight which allocates
1391 * the same cluster. In this case we need to wait until the previous
1392 * request has completed and updated the L2 table accordingly.
1393 *
1394 * Returns:
1395 * 0 if there was no dependency. *cur_bytes indicates the number of
1396 * bytes from guest_offset that can be read before the next
1397 * dependency must be processed (or the request is complete)
1398 *
1399 * -EAGAIN if we had to wait for another request, previously gathered
1400 * information on cluster allocation may be invalid now. The caller
1401 * must start over anyway, so consider *cur_bytes undefined.
1402 */
1406 {
1419 /* No intersection */
1421 }
1426 {
1427 /*
1428 * Clusters intersect but COW areas don't. And cluster itself is
1429 * already allocated. So, there is no actual conflict.
1430 */
1432 }
1434 /* Conflict */
1437 /* Stop at the start of a running allocation */
1441 }
1443 /*
1444 * Stop if an l2meta already exists. After yielding, it wouldn't
1445 * be valid any more, so we'd have to clean up the old L2Metas
1446 * and deal with requests depending on them before starting to
1447 * gather new ones. Not worth the trouble.
1448 */
1452 }
1455 /*
1456 * Wait for the dependency to complete. We need to recheck
1457 * the free/allocated clusters when we continue.
1458 */
1461 }
1462 }
1464 /* Make sure that existing clusters and new allocations are only used up to
1465 * the next dependency if we shortened the request above */
1469 }
1471 /*
1472 * Checks how many already allocated clusters that don't require a new
1473 * allocation there are at the given guest_offset (up to *bytes).
1474 * If *host_offset is not INV_OFFSET, only physically contiguous clusters
1475 * beginning at this host offset are counted.
1476 *
1477 * Note that guest_offset may not be cluster aligned. In this case, the
1478 * returned *host_offset points to exact byte referenced by guest_offset and
1479 * therefore isn't cluster aligned as well.
1480 *
1481 * Returns:
1482 * 0: if no allocated clusters are available at the given offset.
1483 * *bytes is normally unchanged. It is set to 0 if the cluster
1484 * is allocated and can be overwritten in-place but doesn't have
1485 * the right physical offset.
1486 *
1487 * 1: if allocated clusters that can be overwritten in place are
1488 * available at the requested offset. *bytes may have decreased
1489 * and describes the length of the area that can be written to.
1490 *
1491 * -errno: in error cases
1492 */
1496 {
1511 /*
1512 * Calculate the number of clusters to look for. We stop at L2 slice
1513 * boundaries to keep things simple.
1514 */
1515 nb_clusters =
1520 /* Limit total byte count to BDRV_REQUEST_MAX_BYTES */
1523 /* Find L2 entry for the first involved cluster */
1527 }
1541 }
1543 /* If a specific host_offset is required, check it */
1548 }
1550 /* We keep all QCOW_OFLAG_COPIED clusters */
1564 }
1569 }
1571 /* Cleanup */
1572 out:
1575 /* Only return a host offset if we actually made progress. Otherwise we
1576 * would make requirements for handle_alloc() that it can't fulfill */
1579 }
1582 }
1584 /*
1585 * Allocates new clusters for the given guest_offset.
1586 *
1587 * At most *nb_clusters are allocated, and on return *nb_clusters is updated to
1588 * contain the number of clusters that have been allocated and are contiguous
1589 * in the image file.
1590 *
1591 * If *host_offset is not INV_OFFSET, it specifies the offset in the image file
1592 * at which the new clusters must start. *nb_clusters can be 0 on return in
1593 * this case if the cluster at host_offset is already in use. If *host_offset
1594 * is INV_OFFSET, the clusters can be allocated anywhere in the image file.
1595 *
1596 * *host_offset is updated to contain the offset into the image file at which
1597 * the first allocated cluster starts.
1598 *
1599 * Return 0 on success and -errno in error cases. -EAGAIN means that the
1600 * function has been waiting for another request and the allocation must be
1601 * restarted, but the whole request should not be failed.
1602 */
1607 {
1618 }
1620 /* Allocate new clusters */
1627 }
1634 }
1637 }
1638 }
1640 /*
1641 * Allocates new clusters for an area that is either still unallocated or
1642 * cannot be overwritten in-place. If *host_offset is not INV_OFFSET,
1643 * clusters are only allocated if the new allocation can match the specified
1644 * host offset.
1645 *
1646 * Note that guest_offset may not be cluster aligned. In this case, the
1647 * returned *host_offset points to exact byte referenced by guest_offset and
1648 * therefore isn't cluster aligned as well.
1649 *
1650 * Returns:
1651 * 0: if no clusters could be allocated. *bytes is set to 0,
1652 * *host_offset is left unchanged.
1653 *
1654 * 1: if new clusters were allocated. *bytes may be decreased if the
1655 * new allocation doesn't cover all of the requested area.
1656 * *host_offset is updated to contain the host offset of the first
1657 * newly allocated cluster.
1658 *
1659 * -errno: in error cases
1660 */
1664 {
1677 /*
1678 * Calculate the number of clusters to look for. We stop at L2 slice
1679 * boundaries to keep things simple.
1680 */
1681 nb_clusters =
1686 /* Limit total allocation byte count to BDRV_REQUEST_MAX_BYTES */
1689 /* Find L2 entry for the first involved cluster */
1693 }
1698 /* This function is only called when there were no non-COW clusters, so if
1699 * we can't find any unallocated or COW clusters either, something is
1700 * wrong with our code. */
1703 /* Allocate at a given offset in the image file */
1710 }
1712 /* Can't extend contiguous allocation */
1717 }
1721 /*
1722 * Save info needed for meta data update.
1723 *
1724 * requested_bytes: Number of bytes from the start of the first
1725 * newly allocated cluster to the end of the (possibly shortened
1726 * before) write request.
1727 *
1728 * avail_bytes: Number of bytes from the start of the first
1729 * newly allocated to the end of the last newly allocated cluster.
1730 *
1731 * nb_bytes: The number of bytes from the start of the first
1732 * newly allocated cluster to the end of the area that the write
1733 * request actually writes to (excluding COW at the end)
1734 */
1747 }
1751 out:
1754 }
1756 /*
1757 * For a given area on the virtual disk defined by @offset and @bytes,
1758 * find the corresponding area on the qcow2 image, allocating new
1759 * clusters (or subclusters) if necessary. The result can span a
1760 * combination of allocated and previously unallocated clusters.
1761 *
1762 * Note that offset may not be cluster aligned. In this case, the returned
1763 * *host_offset points to exact byte referenced by offset and therefore
1764 * isn't cluster aligned as well.
1765 *
1766 * On return, @host_offset is set to the beginning of the requested
1767 * area. This area is guaranteed to be contiguous on the qcow2 file
1768 * but it can be smaller than initially requested. In this case @bytes
1769 * is updated with the actual size.
1770 *
1771 * If any clusters or subclusters were allocated then @m contains a
1772 * list with the information of all the affected regions. Note that
1773 * this can happen regardless of whether this function succeeds or
1774 * not. The caller is responsible for updating the L2 metadata of the
1775 * allocated clusters (on success) or freeing them (on failure), and
1776 * for clearing the contents of @m afterwards in both cases.
1777 *
1778 * If the request conflicts with another write request in flight, the coroutine
1779 * is queued and will be reentered when the dependency has completed.
1780 *
1781 * Return 0 on success and -errno in error cases
1782 */
1787 {
1796 again:
1808 }
1817 }
1821 }
1825 /*
1826 * Now start gathering as many contiguous clusters as possible:
1827 *
1828 * 1. Check for overlaps with in-flight allocations
1829 *
1830 * a) Overlap not in the first cluster -> shorten this request and
1831 * let the caller handle the rest in its next loop iteration.
1832 *
1833 * b) Real overlaps of two requests. Yield and restart the search
1834 * for contiguous clusters (the situation could have changed
1835 * while we were sleeping)
1836 *
1837 * c) TODO: Request starts in the same cluster as the in-flight
1838 * allocation ends. Shorten the COW of the in-fight allocation,
1839 * set cluster_offset to write to the same cluster and set up
1840 * the right synchronisation between the in-flight request and
1841 * the new one.
1842 */
1845 /* Currently handle_dependencies() doesn't yield if we already had
1846 * an allocation. If it did, we would have to clean up the L2Meta
1847 * structs before starting over. */
1855 /* handle_dependencies() may have decreased cur_bytes (shortened
1856 * the allocations below) so that the next dependency is processed
1857 * correctly during the next loop iteration. */
1858 }
1860 /*
1861 * 2. Count contiguous COPIED clusters.
1862 */
1870 }
1872 /*
1873 * 3. If the request still hasn't completed, allocate new clusters,
1874 * considering any cluster_offset of steps 1c or 2.
1875 */
1884 }
1885 }
1894 }
1896 /*
1897 * This discards as many clusters of nb_clusters as possible at once (i.e.
1898 * all clusters in the same L2 slice) and returns the number of discarded
1899 * clusters.
1900 */
1904 {
1914 }
1916 /* Limit nb_clusters to one L2 slice */
1925 QCow2ClusterType cluster_type =
1932 /*
1933 * If full_discard is true, the cluster should not read back as zeroes,
1934 * but rather fall through to the backing file.
1935 *
1936 * If full_discard is false, make sure that a discarded area reads back
1937 * as zeroes for v3 images (we cannot do it for v2 without actually
1938 * writing a zero-filled buffer). We can skip the operation if the
1939 * cluster is already marked as zero, or if it's unallocated and we
1940 * don't have a backing file.
1941 *
1942 * TODO We might want to use bdrv_block_status(bs) here, but we're
1943 * holding s->lock, so that doesn't work today.
1944 */
1953 }
1961 }
1964 }
1965 }
1966 }
1970 }
1972 /* First remove L2 entries */
1977 }
1979 /* Then decrease the refcount */
1984 /* If we keep the reference, pass on the discard still */
1987 }
1988 }
1993 }
1998 {
2005 /* Caller must pass aligned values, except at image end */
2014 /* Each L2 slice is handled by its own loop iteration */
2017 full_discard);
2021 }
2025 }
2028 fail:
2033 }
2035 /*
2036 * This zeroes as many clusters of nb_clusters as possible at once (i.e.
2037 * all clusters in the same L2 slice) and returns the number of zeroed
2038 * clusters.
2039 */
2040 static int coroutine_fn
2043 {
2053 }
2055 /* Limit nb_clusters to one L2 slice */
2072 }
2076 }
2078 /* First update L2 entries */
2083 }
2085 /* Then decrease the refcount */
2088 }
2089 }
2094 }
2096 static int coroutine_fn
2099 {
2105 /* For full clusters use zero_in_l2_slice() instead */
2113 }
2124 }
2134 }
2137 out:
2141 }
2145 {
2153 /* If we have to stay in sync with an external data file, zero out
2154 * s->data_file first. */
2160 }
2161 }
2163 /* Caller must pass aligned values, except at image end */
2168 /*
2169 * The zero flag is only supported by version 3 and newer. However, if we
2170 * have no backing file, we can resort to discard in version 2.
2171 */
2176 }
2178 }
2194 }
2195 }
2197 /* Each L2 slice is handled by its own loop iteration */
2205 }
2209 }
2215 }
2216 }
2219 fail:
2224 }
2226 /*
2227 * Expands all zero clusters in a specific L1 table (or deallocates them, for
2228 * non-backed non-pre-allocated zero clusters).
2229 *
2230 * l1_entries and *visited_l1_entries are used to keep track of progress for
2231 * status_cb(). l1_entries contains the total number of L1 entries and
2232 * *visited_l1_entries counts all visited L1 entries.
2233 */
2239 {
2247 /* qcow2_downgrade() is not allowed in images with subclusters */
2254 /* inactive L2 tables require a buffer to be stored in when loading
2255 * them from disk */
2259 }
2260 }
2267 /* unallocated */
2271 }
2273 }
2281 }
2287 }
2293 /* get active L2 tables from cache */
2297 /* load inactive L2 tables from disk */
2300 }
2303 }
2308 QCow2ClusterType cluster_type =
2314 }
2318 /*
2319 * not backed; therefore we can simply deallocate the
2320 * cluster. No need to call set_l2_bitmap(), this
2321 * function doesn't support images with subclusters.
2322 */
2326 }
2332 }
2334 /* The offset must fit in the offset field */
2338 /* For shared L2 tables, set the refcount accordingly
2339 * (it is already 1 and needs to be l2_refcount) */
2343 QCOW2_DISCARD_OTHER);
2346 QCOW2_DISCARD_OTHER);
2348 }
2349 }
2350 }
2356 "Cluster allocation offset "
2362 QCOW2_DISCARD_ALWAYS);
2363 }
2366 }
2373 QCOW2_DISCARD_ALWAYS);
2374 }
2376 }
2383 QCOW2_DISCARD_ALWAYS);
2384 }
2386 }
2392 }
2393 /*
2394 * No need to call set_l2_bitmap() after set_l2_entry() because
2395 * this function doesn't support images with subclusters.
2396 */
2398 }
2404 }
2413 }
2419 }
2420 }
2421 }
2422 }
2427 }
2428 }
2432 fail:
2438 }
2439 }
2441 }
2443 /*
2444 * For backed images, expands all zero clusters on the image. For non-backed
2445 * images, deallocates all non-pre-allocated zero clusters (and claims the
2446 * allocation for pre-allocated ones). This is important for downgrading to a
2447 * qcow2 version which doesn't yet support metadata zero clusters.
2448 */
2452 {
2463 }
2464 }
2471 }
2473 /* Inactive L1 tables may point to active L2 tables - therefore it is
2474 * necessary to flush the L2 table cache before trying to access the L2
2475 * tables pointed to by inactive L1 entries (else we might try to expand
2476 * zero clusters that have already been expanded); furthermore, it is also
2477 * necessary to empty the L2 table cache, since it may contain tables which
2478 * are now going to be modified directly on disk, bypassing the cache.
2479 * qcow2_cache_empty() does both for us. */
2483 }
2497 }
2505 }
2513 }
2517 }
2524 }
2525 }
2529 fail:
2532 }
2536 {
2547 }