466 lines
20 KiB
Diff
466 lines
20 KiB
Diff
From 3daca05a8f845d2a389a6cf767314bcb72109578 Mon Sep 17 00:00:00 2001
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From: Hanna Reitz <hreitz@redhat.com>
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Date: Tue, 5 Apr 2022 15:46:50 +0200
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Subject: [PATCH 08/11] qcow2: Improve refcount structure rebuilding
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RH-Author: Hanna Reitz <hreitz@redhat.com>
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RH-MergeRequest: 173: qcow2: Improve refcount structure rebuilding
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RH-Commit: [1/4] 586e7a0fc3cb7cc2296b544ffcef34d8395fa74c
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RH-Bugzilla: 2072242
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RH-Acked-by: Miroslav Rezanina <mrezanin@redhat.com>
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RH-Acked-by: Eric Blake <eblake@redhat.com>
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RH-Acked-by: Stefan Hajnoczi <stefanha@redhat.com>
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When rebuilding the refcount structures (when qemu-img check -r found
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errors with refcount = 0, but reference count > 0), the new refcount
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table defaults to being put at the image file end[1]. There is no good
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reason for that except that it means we will not have to rewrite any
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refblocks we already wrote to disk.
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Changing the code to rewrite those refblocks is not too difficult,
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though, so let us do that. That is beneficial for images on block
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devices, where we cannot really write beyond the end of the image file.
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Use this opportunity to add extensive comments to the code, and refactor
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it a bit, getting rid of the backwards-jumping goto.
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[1] Unless there is something allocated in the area pointed to by the
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last refblock, so we have to write that refblock. In that case, we
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try to put the reftable in there.
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Buglink: https://bugzilla.redhat.com/show_bug.cgi?id=1519071
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Closes: https://gitlab.com/qemu-project/qemu/-/issues/941
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Reviewed-by: Eric Blake <eblake@redhat.com>
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Signed-off-by: Hanna Reitz <hreitz@redhat.com>
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Message-Id: <20220405134652.19278-2-hreitz@redhat.com>
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(cherry picked from commit a8c07ec287554dcefd33733f0e5888a281ddc95e)
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Signed-off-by: Hanna Reitz <hreitz@redhat.com>
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---
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block/qcow2-refcount.c | 332 +++++++++++++++++++++++++++++------------
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1 file changed, 235 insertions(+), 97 deletions(-)
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diff --git a/block/qcow2-refcount.c b/block/qcow2-refcount.c
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index 4614572252..555d8ba5ac 100644
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--- a/block/qcow2-refcount.c
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+++ b/block/qcow2-refcount.c
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@@ -2435,111 +2435,140 @@ static int64_t alloc_clusters_imrt(BlockDriverState *bs,
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}
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/*
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- * Creates a new refcount structure based solely on the in-memory information
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- * given through *refcount_table. All necessary allocations will be reflected
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- * in that array.
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+ * Helper function for rebuild_refcount_structure().
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*
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- * On success, the old refcount structure is leaked (it will be covered by the
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- * new refcount structure).
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+ * Scan the range of clusters [first_cluster, end_cluster) for allocated
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+ * clusters and write all corresponding refblocks to disk. The refblock
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+ * and allocation data is taken from the in-memory refcount table
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+ * *refcount_table[] (of size *nb_clusters), which is basically one big
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+ * (unlimited size) refblock for the whole image.
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+ *
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+ * For these refblocks, clusters are allocated using said in-memory
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+ * refcount table. Care is taken that these allocations are reflected
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+ * in the refblocks written to disk.
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+ *
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+ * The refblocks' offsets are written into a reftable, which is
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+ * *on_disk_reftable_ptr[] (of size *on_disk_reftable_entries_ptr). If
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+ * that reftable is of insufficient size, it will be resized to fit.
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+ * This reftable is not written to disk.
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+ *
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+ * (If *on_disk_reftable_ptr is not NULL, the entries within are assumed
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+ * to point to existing valid refblocks that do not need to be allocated
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+ * again.)
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+ *
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+ * Return whether the on-disk reftable array was resized (true/false),
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+ * or -errno on error.
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*/
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-static int rebuild_refcount_structure(BlockDriverState *bs,
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- BdrvCheckResult *res,
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- void **refcount_table,
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- int64_t *nb_clusters)
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+static int rebuild_refcounts_write_refblocks(
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+ BlockDriverState *bs, void **refcount_table, int64_t *nb_clusters,
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+ int64_t first_cluster, int64_t end_cluster,
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+ uint64_t **on_disk_reftable_ptr, uint32_t *on_disk_reftable_entries_ptr
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+ )
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{
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BDRVQcow2State *s = bs->opaque;
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- int64_t first_free_cluster = 0, reftable_offset = -1, cluster = 0;
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+ int64_t cluster;
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int64_t refblock_offset, refblock_start, refblock_index;
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- uint32_t reftable_size = 0;
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- uint64_t *on_disk_reftable = NULL;
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+ int64_t first_free_cluster = 0;
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+ uint64_t *on_disk_reftable = *on_disk_reftable_ptr;
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+ uint32_t on_disk_reftable_entries = *on_disk_reftable_entries_ptr;
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void *on_disk_refblock;
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- int ret = 0;
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- struct {
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- uint64_t reftable_offset;
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- uint32_t reftable_clusters;
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- } QEMU_PACKED reftable_offset_and_clusters;
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-
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- qcow2_cache_empty(bs, s->refcount_block_cache);
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+ bool reftable_grown = false;
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+ int ret;
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-write_refblocks:
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- for (; cluster < *nb_clusters; cluster++) {
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+ for (cluster = first_cluster; cluster < end_cluster; cluster++) {
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+ /* Check all clusters to find refblocks that contain non-zero entries */
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if (!s->get_refcount(*refcount_table, cluster)) {
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continue;
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}
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+ /*
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+ * This cluster is allocated, so we need to create a refblock
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+ * for it. The data we will write to disk is just the
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+ * respective slice from *refcount_table, so it will contain
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+ * accurate refcounts for all clusters belonging to this
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+ * refblock. After we have written it, we will therefore skip
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+ * all remaining clusters in this refblock.
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+ */
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+
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refblock_index = cluster >> s->refcount_block_bits;
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refblock_start = refblock_index << s->refcount_block_bits;
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- /* Don't allocate a cluster in a refblock already written to disk */
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- if (first_free_cluster < refblock_start) {
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- first_free_cluster = refblock_start;
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- }
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- refblock_offset = alloc_clusters_imrt(bs, 1, refcount_table,
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- nb_clusters, &first_free_cluster);
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- if (refblock_offset < 0) {
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- fprintf(stderr, "ERROR allocating refblock: %s\n",
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- strerror(-refblock_offset));
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- res->check_errors++;
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- ret = refblock_offset;
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- goto fail;
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- }
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+ if (on_disk_reftable_entries > refblock_index &&
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+ on_disk_reftable[refblock_index])
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+ {
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+ /*
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+ * We can get here after a `goto write_refblocks`: We have a
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+ * reftable from a previous run, and the refblock is already
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+ * allocated. No need to allocate it again.
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+ */
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+ refblock_offset = on_disk_reftable[refblock_index];
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+ } else {
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+ int64_t refblock_cluster_index;
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- if (reftable_size <= refblock_index) {
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- uint32_t old_reftable_size = reftable_size;
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- uint64_t *new_on_disk_reftable;
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+ /* Don't allocate a cluster in a refblock already written to disk */
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+ if (first_free_cluster < refblock_start) {
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+ first_free_cluster = refblock_start;
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+ }
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+ refblock_offset = alloc_clusters_imrt(bs, 1, refcount_table,
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+ nb_clusters,
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+ &first_free_cluster);
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+ if (refblock_offset < 0) {
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+ fprintf(stderr, "ERROR allocating refblock: %s\n",
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+ strerror(-refblock_offset));
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+ return refblock_offset;
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+ }
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- reftable_size = ROUND_UP((refblock_index + 1) * REFTABLE_ENTRY_SIZE,
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- s->cluster_size) / REFTABLE_ENTRY_SIZE;
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- new_on_disk_reftable = g_try_realloc(on_disk_reftable,
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- reftable_size *
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- REFTABLE_ENTRY_SIZE);
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- if (!new_on_disk_reftable) {
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- res->check_errors++;
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- ret = -ENOMEM;
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- goto fail;
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+ refblock_cluster_index = refblock_offset / s->cluster_size;
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+ if (refblock_cluster_index >= end_cluster) {
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+ /*
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+ * We must write the refblock that holds this refblock's
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+ * refcount
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+ */
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+ end_cluster = refblock_cluster_index + 1;
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}
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- on_disk_reftable = new_on_disk_reftable;
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- memset(on_disk_reftable + old_reftable_size, 0,
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- (reftable_size - old_reftable_size) * REFTABLE_ENTRY_SIZE);
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+ if (on_disk_reftable_entries <= refblock_index) {
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+ on_disk_reftable_entries =
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+ ROUND_UP((refblock_index + 1) * REFTABLE_ENTRY_SIZE,
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+ s->cluster_size) / REFTABLE_ENTRY_SIZE;
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+ on_disk_reftable =
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+ g_try_realloc(on_disk_reftable,
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+ on_disk_reftable_entries *
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+ REFTABLE_ENTRY_SIZE);
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+ if (!on_disk_reftable) {
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+ return -ENOMEM;
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+ }
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- /* The offset we have for the reftable is now no longer valid;
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- * this will leak that range, but we can easily fix that by running
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- * a leak-fixing check after this rebuild operation */
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- reftable_offset = -1;
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- } else {
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- assert(on_disk_reftable);
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- }
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- on_disk_reftable[refblock_index] = refblock_offset;
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+ memset(on_disk_reftable + *on_disk_reftable_entries_ptr, 0,
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+ (on_disk_reftable_entries -
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+ *on_disk_reftable_entries_ptr) *
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+ REFTABLE_ENTRY_SIZE);
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- /* If this is apparently the last refblock (for now), try to squeeze the
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- * reftable in */
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- if (refblock_index == (*nb_clusters - 1) >> s->refcount_block_bits &&
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- reftable_offset < 0)
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- {
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- uint64_t reftable_clusters = size_to_clusters(s, reftable_size *
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- REFTABLE_ENTRY_SIZE);
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- reftable_offset = alloc_clusters_imrt(bs, reftable_clusters,
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- refcount_table, nb_clusters,
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- &first_free_cluster);
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- if (reftable_offset < 0) {
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- fprintf(stderr, "ERROR allocating reftable: %s\n",
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- strerror(-reftable_offset));
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- res->check_errors++;
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- ret = reftable_offset;
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- goto fail;
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+ *on_disk_reftable_ptr = on_disk_reftable;
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+ *on_disk_reftable_entries_ptr = on_disk_reftable_entries;
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+
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+ reftable_grown = true;
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+ } else {
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+ assert(on_disk_reftable);
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}
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+ on_disk_reftable[refblock_index] = refblock_offset;
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}
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+ /* Refblock is allocated, write it to disk */
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+
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ret = qcow2_pre_write_overlap_check(bs, 0, refblock_offset,
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s->cluster_size, false);
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if (ret < 0) {
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fprintf(stderr, "ERROR writing refblock: %s\n", strerror(-ret));
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- goto fail;
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+ return ret;
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}
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- /* The size of *refcount_table is always cluster-aligned, therefore the
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- * write operation will not overflow */
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+ /*
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+ * The refblock is simply a slice of *refcount_table.
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+ * Note that the size of *refcount_table is always aligned to
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+ * whole clusters, so the write operation will not result in
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+ * out-of-bounds accesses.
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+ */
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on_disk_refblock = (void *)((char *) *refcount_table +
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refblock_index * s->cluster_size);
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@@ -2547,23 +2576,99 @@ write_refblocks:
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s->cluster_size);
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if (ret < 0) {
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fprintf(stderr, "ERROR writing refblock: %s\n", strerror(-ret));
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- goto fail;
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+ return ret;
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}
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- /* Go to the end of this refblock */
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+ /* This refblock is done, skip to its end */
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cluster = refblock_start + s->refcount_block_size - 1;
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}
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- if (reftable_offset < 0) {
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- uint64_t post_refblock_start, reftable_clusters;
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+ return reftable_grown;
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+}
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+
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+/*
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+ * Creates a new refcount structure based solely on the in-memory information
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+ * given through *refcount_table (this in-memory information is basically just
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+ * the concatenation of all refblocks). All necessary allocations will be
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+ * reflected in that array.
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+ *
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+ * On success, the old refcount structure is leaked (it will be covered by the
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+ * new refcount structure).
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+ */
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+static int rebuild_refcount_structure(BlockDriverState *bs,
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+ BdrvCheckResult *res,
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+ void **refcount_table,
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+ int64_t *nb_clusters)
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+{
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+ BDRVQcow2State *s = bs->opaque;
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+ int64_t reftable_offset = -1;
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+ int64_t reftable_length = 0;
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+ int64_t reftable_clusters;
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+ int64_t refblock_index;
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+ uint32_t on_disk_reftable_entries = 0;
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+ uint64_t *on_disk_reftable = NULL;
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+ int ret = 0;
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+ int reftable_size_changed = 0;
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+ struct {
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+ uint64_t reftable_offset;
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+ uint32_t reftable_clusters;
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+ } QEMU_PACKED reftable_offset_and_clusters;
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+
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+ qcow2_cache_empty(bs, s->refcount_block_cache);
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+
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+ /*
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+ * For each refblock containing entries, we try to allocate a
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+ * cluster (in the in-memory refcount table) and write its offset
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+ * into on_disk_reftable[]. We then write the whole refblock to
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+ * disk (as a slice of the in-memory refcount table).
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+ * This is done by rebuild_refcounts_write_refblocks().
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+ *
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+ * Once we have scanned all clusters, we try to find space for the
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+ * reftable. This will dirty the in-memory refcount table (i.e.
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+ * make it differ from the refblocks we have already written), so we
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+ * need to run rebuild_refcounts_write_refblocks() again for the
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+ * range of clusters where the reftable has been allocated.
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+ *
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+ * This second run might make the reftable grow again, in which case
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+ * we will need to allocate another space for it, which is why we
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+ * repeat all this until the reftable stops growing.
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+ *
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+ * (This loop will terminate, because with every cluster the
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+ * reftable grows, it can accomodate a multitude of more refcounts,
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+ * so that at some point this must be able to cover the reftable
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+ * and all refblocks describing it.)
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+ *
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+ * We then convert the reftable to big-endian and write it to disk.
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+ *
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+ * Note that we never free any reftable allocations. Doing so would
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+ * needlessly complicate the algorithm: The eventual second check
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+ * run we do will clean up all leaks we have caused.
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+ */
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+
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+ reftable_size_changed =
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+ rebuild_refcounts_write_refblocks(bs, refcount_table, nb_clusters,
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+ 0, *nb_clusters,
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+ &on_disk_reftable,
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+ &on_disk_reftable_entries);
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+ if (reftable_size_changed < 0) {
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+ res->check_errors++;
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+ ret = reftable_size_changed;
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+ goto fail;
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+ }
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+
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+ /*
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+ * There was no reftable before, so rebuild_refcounts_write_refblocks()
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+ * must have increased its size (from 0 to something).
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+ */
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+ assert(reftable_size_changed);
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+
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+ do {
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+ int64_t reftable_start_cluster, reftable_end_cluster;
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+ int64_t first_free_cluster = 0;
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+
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+ reftable_length = on_disk_reftable_entries * REFTABLE_ENTRY_SIZE;
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+ reftable_clusters = size_to_clusters(s, reftable_length);
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- post_refblock_start = ROUND_UP(*nb_clusters, s->refcount_block_size);
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- reftable_clusters =
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- size_to_clusters(s, reftable_size * REFTABLE_ENTRY_SIZE);
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- /* Not pretty but simple */
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- if (first_free_cluster < post_refblock_start) {
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- first_free_cluster = post_refblock_start;
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- }
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reftable_offset = alloc_clusters_imrt(bs, reftable_clusters,
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refcount_table, nb_clusters,
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&first_free_cluster);
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@@ -2575,24 +2680,55 @@ write_refblocks:
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goto fail;
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}
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- goto write_refblocks;
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- }
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+ /*
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+ * We need to update the affected refblocks, so re-run the
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+ * write_refblocks loop for the reftable's range of clusters.
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+ */
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+ assert(offset_into_cluster(s, reftable_offset) == 0);
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+ reftable_start_cluster = reftable_offset / s->cluster_size;
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+ reftable_end_cluster = reftable_start_cluster + reftable_clusters;
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+ reftable_size_changed =
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+ rebuild_refcounts_write_refblocks(bs, refcount_table, nb_clusters,
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+ reftable_start_cluster,
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+ reftable_end_cluster,
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+ &on_disk_reftable,
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+ &on_disk_reftable_entries);
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+ if (reftable_size_changed < 0) {
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+ res->check_errors++;
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+ ret = reftable_size_changed;
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+ goto fail;
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+ }
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+
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+ /*
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+ * If the reftable size has changed, we will need to find a new
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+ * allocation, repeating the loop.
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+ */
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+ } while (reftable_size_changed);
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- for (refblock_index = 0; refblock_index < reftable_size; refblock_index++) {
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+ /* The above loop must have run at least once */
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+ assert(reftable_offset >= 0);
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+
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+ /*
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+ * All allocations are done, all refblocks are written, convert the
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+ * reftable to big-endian and write it to disk.
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+ */
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+
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+ for (refblock_index = 0; refblock_index < on_disk_reftable_entries;
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+ refblock_index++)
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+ {
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cpu_to_be64s(&on_disk_reftable[refblock_index]);
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}
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- ret = qcow2_pre_write_overlap_check(bs, 0, reftable_offset,
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- reftable_size * REFTABLE_ENTRY_SIZE,
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+ ret = qcow2_pre_write_overlap_check(bs, 0, reftable_offset, reftable_length,
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false);
|
|
if (ret < 0) {
|
|
fprintf(stderr, "ERROR writing reftable: %s\n", strerror(-ret));
|
|
goto fail;
|
|
}
|
|
|
|
- assert(reftable_size < INT_MAX / REFTABLE_ENTRY_SIZE);
|
|
+ assert(reftable_length < INT_MAX);
|
|
ret = bdrv_pwrite(bs->file, reftable_offset, on_disk_reftable,
|
|
- reftable_size * REFTABLE_ENTRY_SIZE);
|
|
+ reftable_length);
|
|
if (ret < 0) {
|
|
fprintf(stderr, "ERROR writing reftable: %s\n", strerror(-ret));
|
|
goto fail;
|
|
@@ -2601,7 +2737,7 @@ write_refblocks:
|
|
/* Enter new reftable into the image header */
|
|
reftable_offset_and_clusters.reftable_offset = cpu_to_be64(reftable_offset);
|
|
reftable_offset_and_clusters.reftable_clusters =
|
|
- cpu_to_be32(size_to_clusters(s, reftable_size * REFTABLE_ENTRY_SIZE));
|
|
+ cpu_to_be32(reftable_clusters);
|
|
ret = bdrv_pwrite_sync(bs->file,
|
|
offsetof(QCowHeader, refcount_table_offset),
|
|
&reftable_offset_and_clusters,
|
|
@@ -2611,12 +2747,14 @@ write_refblocks:
|
|
goto fail;
|
|
}
|
|
|
|
- for (refblock_index = 0; refblock_index < reftable_size; refblock_index++) {
|
|
+ for (refblock_index = 0; refblock_index < on_disk_reftable_entries;
|
|
+ refblock_index++)
|
|
+ {
|
|
be64_to_cpus(&on_disk_reftable[refblock_index]);
|
|
}
|
|
s->refcount_table = on_disk_reftable;
|
|
s->refcount_table_offset = reftable_offset;
|
|
- s->refcount_table_size = reftable_size;
|
|
+ s->refcount_table_size = on_disk_reftable_entries;
|
|
update_max_refcount_table_index(s);
|
|
|
|
return 0;
|
|
--
|
|
2.27.0
|
|
|