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mirror_zfs/module/zfs/vdev_raidz.c
George Wilson 493fcce9be
Provide macros for setting and getting blkptr birth times 
There exist a couple of macros that are used to update the blkptr birth
times but they can often be confusing. For example, the
BP_PHYSICAL_BIRTH() macro will provide either the physical birth time
if it is set or else return back the logical birth time. The
complement to this macro is BP_SET_BIRTH() which will set the logical
birth time and set the physical birth time if they are not the same.
Consumers may get confused when they are trying to get the physical
birth time and use the BP_PHYSICAL_BIRTH() macro only to find out that
the logical birth time is what is actually returned.

This change cleans up these macros and makes them symmetrical. The same
functionally is preserved but the name is changed. Instead of calling
BP_PHYSICAL_BIRTH(), consumer can now call BP_GET_BIRTH(). In
additional to cleaning up this naming conventions, two new sets of
macros are introduced -- BP_[SET|GET]_LOGICAL_BIRTH() and
BP_[SET|GET]_PHYSICAL_BIRTH.  These new macros allow the consumer to
get and set the specific birth time.

As part of the cleanup, the unused GRID macros have been removed and
that portion of the blkptr are currently unused.

Reviewed-by: Matthew Ahrens <mahrens@delphix.com>
Reviewed-by: Alexander Motin <mav@FreeBSD.org>
Reviewed-by: Mark Maybee <mark.maybee@delphix.com>
Signed-off-by: George Wilson <gwilson@delphix.com>
Closes #15962
2024-03-25 15:01:54 -07:00

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/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or https://opensource.org/licenses/CDDL-1.0.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright (c) 2005, 2010, Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2012, 2020 by Delphix. All rights reserved.
* Copyright (c) 2016 Gvozden Nešković. All rights reserved.
*/
#include <sys/zfs_context.h>
#include <sys/spa.h>
#include <sys/spa_impl.h>
#include <sys/zap.h>
#include <sys/vdev_impl.h>
#include <sys/metaslab_impl.h>
#include <sys/zio.h>
#include <sys/zio_checksum.h>
#include <sys/dmu_tx.h>
#include <sys/abd.h>
#include <sys/zfs_rlock.h>
#include <sys/fs/zfs.h>
#include <sys/fm/fs/zfs.h>
#include <sys/vdev_raidz.h>
#include <sys/vdev_raidz_impl.h>
#include <sys/vdev_draid.h>
#include <sys/uberblock_impl.h>
#include <sys/dsl_scan.h>
#ifdef ZFS_DEBUG
#include <sys/vdev.h> /* For vdev_xlate() in vdev_raidz_io_verify() */
#endif
/*
* Virtual device vector for RAID-Z.
*
* This vdev supports single, double, and triple parity. For single parity,
* we use a simple XOR of all the data columns. For double or triple parity,
* we use a special case of Reed-Solomon coding. This extends the
* technique described in "The mathematics of RAID-6" by H. Peter Anvin by
* drawing on the system described in "A Tutorial on Reed-Solomon Coding for
* Fault-Tolerance in RAID-like Systems" by James S. Plank on which the
* former is also based. The latter is designed to provide higher performance
* for writes.
*
* Note that the Plank paper claimed to support arbitrary N+M, but was then
* amended six years later identifying a critical flaw that invalidates its
* claims. Nevertheless, the technique can be adapted to work for up to
* triple parity. For additional parity, the amendment "Note: Correction to
* the 1997 Tutorial on Reed-Solomon Coding" by James S. Plank and Ying Ding
* is viable, but the additional complexity means that write performance will
* suffer.
*
* All of the methods above operate on a Galois field, defined over the
* integers mod 2^N. In our case we choose N=8 for GF(8) so that all elements
* can be expressed with a single byte. Briefly, the operations on the
* field are defined as follows:
*
* o addition (+) is represented by a bitwise XOR
* o subtraction (-) is therefore identical to addition: A + B = A - B
* o multiplication of A by 2 is defined by the following bitwise expression:
*
* (A * 2)_7 = A_6
* (A * 2)_6 = A_5
* (A * 2)_5 = A_4
* (A * 2)_4 = A_3 + A_7
* (A * 2)_3 = A_2 + A_7
* (A * 2)_2 = A_1 + A_7
* (A * 2)_1 = A_0
* (A * 2)_0 = A_7
*
* In C, multiplying by 2 is therefore ((a << 1) ^ ((a & 0x80) ? 0x1d : 0)).
* As an aside, this multiplication is derived from the error correcting
* primitive polynomial x^8 + x^4 + x^3 + x^2 + 1.
*
* Observe that any number in the field (except for 0) can be expressed as a
* power of 2 -- a generator for the field. We store a table of the powers of
* 2 and logs base 2 for quick look ups, and exploit the fact that A * B can
* be rewritten as 2^(log_2(A) + log_2(B)) (where '+' is normal addition rather
* than field addition). The inverse of a field element A (A^-1) is therefore
* A ^ (255 - 1) = A^254.
*
* The up-to-three parity columns, P, Q, R over several data columns,
* D_0, ... D_n-1, can be expressed by field operations:
*
* P = D_0 + D_1 + ... + D_n-2 + D_n-1
* Q = 2^n-1 * D_0 + 2^n-2 * D_1 + ... + 2^1 * D_n-2 + 2^0 * D_n-1
* = ((...((D_0) * 2 + D_1) * 2 + ...) * 2 + D_n-2) * 2 + D_n-1
* R = 4^n-1 * D_0 + 4^n-2 * D_1 + ... + 4^1 * D_n-2 + 4^0 * D_n-1
* = ((...((D_0) * 4 + D_1) * 4 + ...) * 4 + D_n-2) * 4 + D_n-1
*
* We chose 1, 2, and 4 as our generators because 1 corresponds to the trivial
* XOR operation, and 2 and 4 can be computed quickly and generate linearly-
* independent coefficients. (There are no additional coefficients that have
* this property which is why the uncorrected Plank method breaks down.)
*
* See the reconstruction code below for how P, Q and R can used individually
* or in concert to recover missing data columns.
*/
#define VDEV_RAIDZ_P 0
#define VDEV_RAIDZ_Q 1
#define VDEV_RAIDZ_R 2
#define VDEV_RAIDZ_MUL_2(x) (((x) << 1) ^ (((x) & 0x80) ? 0x1d : 0))
#define VDEV_RAIDZ_MUL_4(x) (VDEV_RAIDZ_MUL_2(VDEV_RAIDZ_MUL_2(x)))
/*
* We provide a mechanism to perform the field multiplication operation on a
* 64-bit value all at once rather than a byte at a time. This works by
* creating a mask from the top bit in each byte and using that to
* conditionally apply the XOR of 0x1d.
*/
#define VDEV_RAIDZ_64MUL_2(x, mask) \
{ \
(mask) = (x) & 0x8080808080808080ULL; \
(mask) = ((mask) << 1) - ((mask) >> 7); \
(x) = (((x) << 1) & 0xfefefefefefefefeULL) ^ \
((mask) & 0x1d1d1d1d1d1d1d1dULL); \
}
#define VDEV_RAIDZ_64MUL_4(x, mask) \
{ \
VDEV_RAIDZ_64MUL_2((x), mask); \
VDEV_RAIDZ_64MUL_2((x), mask); \
}
/*
* Big Theory Statement for how a RAIDZ VDEV is expanded
*
* An existing RAIDZ VDEV can be expanded by attaching a new disk. Expansion
* works with all three RAIDZ parity choices, including RAIDZ1, 2, or 3. VDEVs
* that have been previously expanded can be expanded again.
*
* The RAIDZ VDEV must be healthy (must be able to write to all the drives in
* the VDEV) when an expansion starts. And the expansion will pause if any
* disk in the VDEV fails, and resume once the VDEV is healthy again. All other
* operations on the pool can continue while an expansion is in progress (e.g.
* read/write, snapshot, zpool add, etc). Except zpool checkpoint, zpool trim,
* and zpool initialize which can't be run during an expansion. Following a
* reboot or export/import, the expansion resumes where it left off.
*
* == Reflowing the Data ==
*
* The expansion involves reflowing (copying) the data from the current set
* of disks to spread it across the new set which now has one more disk. This
* reflow operation is similar to reflowing text when the column width of a
* text editor window is expanded. The text doesnt change but the location of
* the text changes to accommodate the new width. An example reflow result for
* a 4-wide RAIDZ1 to a 5-wide is shown below.
*
* Reflow End State
* Each letter indicates a parity group (logical stripe)
*
* Before expansion After Expansion
* D1 D2 D3 D4 D1 D2 D3 D4 D5
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | A | A | A | A | | A | A | A | A | B |
* | 1| 2| 3| 4| | 1| 2| 3| 4| 5|
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | B | B | C | C | | B | C | C | C | C |
* | 5| 6| 7| 8| | 6| 7| 8| 9| 10|
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | C | C | D | D | | D | D | E | E | E |
* | 9| 10| 11| 12| | 11| 12| 13| 14| 15|
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | E | E | E | E | --> | E | F | F | G | G |
* | 13| 14| 15| 16| | 16| 17| 18|p 19| 20|
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | F | F | G | G | | G | G | H | H | H |
* | 17| 18| 19| 20| | 21| 22| 23| 24| 25|
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | G | G | H | H | | H | I | I | J | J |
* | 21| 22| 23| 24| | 26| 27| 28| 29| 30|
* +------+------+------+------+ +------+------+------+------+------+
* | | | | | | | | | | |
* | H | H | I | I | | J | J | | | K |
* | 25| 26| 27| 28| | 31| 32| 33| 34| 35|
* +------+------+------+------+ +------+------+------+------+------+
*
* This reflow approach has several advantages. There is no need to read or
* modify the block pointers or recompute any block checksums. The reflow
* doesnt need to know where the parity sectors reside. We can read and write
* data sequentially and the copy can occur in a background thread in open
* context. The design also allows for fast discovery of what data to copy.
*
* The VDEV metaslabs are processed, one at a time, to copy the block data to
* have it flow across all the disks. The metaslab is disabled for allocations
* during the copy. As an optimization, we only copy the allocated data which
* can be determined by looking at the metaslab range tree. During the copy we
* must maintain the redundancy guarantees of the RAIDZ VDEV (i.e., we still
* need to be able to survive losing parity count disks). This means we
* cannot overwrite data during the reflow that would be needed if a disk is
* lost.
*
* After the reflow completes, all newly-written blocks will have the new
* layout, i.e., they will have the parity to data ratio implied by the new
* number of disks in the RAIDZ group. Even though the reflow copies all of
* the allocated space (data and parity), it is only rearranged, not changed.
*
* This act of reflowing the data has a few implications about blocks
* that were written before the reflow completes:
*
* - Old blocks will still use the same amount of space (i.e., they will have
* the parity to data ratio implied by the old number of disks in the RAIDZ
* group).
* - Reading old blocks will be slightly slower than before the reflow, for
* two reasons. First, we will have to read from all disks in the RAIDZ
* VDEV, rather than being able to skip the children that contain only
* parity of this block (because the data of a single block is now spread
* out across all the disks). Second, in most cases there will be an extra
* bcopy, needed to rearrange the data back to its original layout in memory.
*
* == Scratch Area ==
*
* As we copy the block data, we can only progress to the point that writes
* will not overlap with blocks whose progress has not yet been recorded on
* disk. Since partially-copied rows are always read from the old location,
* we need to stop one row before the sector-wise overlap, to prevent any
* row-wise overlap. For example, in the diagram above, when we reflow sector
* B6 it will overwite the original location for B5.
*
* To get around this, a scratch space is used so that we can start copying
* without risking data loss by overlapping the row. As an added benefit, it
* improves performance at the beginning of the reflow, but that small perf
* boost wouldn't be worth the complexity on its own.
*
* Ideally we want to copy at least 2 * (new_width)^2 so that we have a
* separation of 2*(new_width+1) and a chunk size of new_width+2. With the max
* RAIDZ width of 255 and 4K sectors this would be 2MB per disk. In practice
* the widths will likely be single digits so we can get a substantial chuck
* size using only a few MB of scratch per disk.
*
* The scratch area is persisted to disk which holds a large amount of reflowed
* state. We can always read the partially written stripes when a disk fails or
* the copy is interrupted (crash) during the initial copying phase and also
* get past a small chunk size restriction. At a minimum, the scratch space
* must be large enough to get us to the point that one row does not overlap
* itself when moved (i.e new_width^2). But going larger is even better. We
* use the 3.5 MiB reserved "boot" space that resides after the ZFS disk labels
* as our scratch space to handle overwriting the initial part of the VDEV.
*
* 0 256K 512K 4M
* +------+------+-----------------------+-----------------------------
* | VDEV | VDEV | Boot Block (3.5M) | Allocatable space ...
* | L0 | L1 | Reserved | (Metaslabs)
* +------+------+-----------------------+-------------------------------
* Scratch Area
*
* == Reflow Progress Updates ==
* After the initial scratch-based reflow, the expansion process works
* similarly to device removal. We create a new open context thread which
* reflows the data, and periodically kicks off sync tasks to update logical
* state. In this case, state is the committed progress (offset of next data
* to copy). We need to persist the completed offset on disk, so that if we
* crash we know which format each VDEV offset is in.
*
* == Time Dependent Geometry ==
*
* In non-expanded RAIDZ, blocks are read from disk in a column by column
* fashion. For a multi-row block, the second sector is in the first column
* not in the second column. This allows us to issue full reads for each
* column directly into the request buffer. The block data is thus laid out
* sequentially in a column-by-column fashion.
*
* For example, in the before expansion diagram above, one logical block might
* be sectors G19-H26. The parity is in G19,H23; and the data is in
* G20,H24,G21,H25,G22,H26.
*
* After a block is reflowed, the sectors that were all in the original column
* data can now reside in different columns. When reading from an expanded
* VDEV, we need to know the logical stripe width for each block so we can
* reconstitute the blocks data after the reads are completed. Likewise,
* when we perform the combinatorial reconstruction we need to know the
* original width so we can retry combinations from the past layouts.
*
* Time dependent geometry is what we call having blocks with different layouts
* (stripe widths) in the same VDEV. This time-dependent geometry uses the
* blocks birth time (+ the time expansion ended) to establish the correct
* width for a given block. After an expansion completes, we record the time
* for blocks written with a particular width (geometry).
*
* == On Disk Format Changes ==
*
* New pool feature flag, 'raidz_expansion' whose reference count is the number
* of RAIDZ VDEVs that have been expanded.
*
* The blocks on expanded RAIDZ VDEV can have different logical stripe widths.
*
* Since the uberblock can point to arbitrary blocks, which might be on the
* expanding RAIDZ, and might or might not have been expanded. We need to know
* which way a block is laid out before reading it. This info is the next
* offset that needs to be reflowed and we persist that in the uberblock, in
* the new ub_raidz_reflow_info field, as opposed to the MOS or the vdev label.
* After the expansion is complete, we then use the raidz_expand_txgs array
* (see below) to determine how to read a block and the ub_raidz_reflow_info
* field no longer required.
*
* The uberblock's ub_raidz_reflow_info field also holds the scratch space
* state (i.e., active or not) which is also required before reading a block
* during the initial phase of reflowing the data.
*
* The top-level RAIDZ VDEV has two new entries in the nvlist:
*
* 'raidz_expand_txgs' array: logical stripe widths by txg are recorded here
* and used after the expansion is complete to
* determine how to read a raidz block
* 'raidz_expanding' boolean: present during reflow and removed after completion
* used during a spa import to resume an unfinished
* expansion
*
* And finally the VDEVs top zap adds the following informational entries:
* VDEV_TOP_ZAP_RAIDZ_EXPAND_STATE
* VDEV_TOP_ZAP_RAIDZ_EXPAND_START_TIME
* VDEV_TOP_ZAP_RAIDZ_EXPAND_END_TIME
* VDEV_TOP_ZAP_RAIDZ_EXPAND_BYTES_COPIED
*/
/*
* For testing only: pause the raidz expansion after reflowing this amount.
* (accessed by ZTS and ztest)
*/
#ifdef _KERNEL
static
#endif /* _KERNEL */
unsigned long raidz_expand_max_reflow_bytes = 0;
/*
* For testing only: pause the raidz expansion at a certain point.
*/
uint_t raidz_expand_pause_point = 0;
/*
* Maximum amount of copy io's outstanding at once.
*/
static unsigned long raidz_expand_max_copy_bytes = 10 * SPA_MAXBLOCKSIZE;
/*
* Apply raidz map abds aggregation if the number of rows in the map is equal
* or greater than the value below.
*/
static unsigned long raidz_io_aggregate_rows = 4;
/*
* Automatically start a pool scrub when a RAIDZ expansion completes in
* order to verify the checksums of all blocks which have been copied
* during the expansion. Automatic scrubbing is enabled by default and
* is strongly recommended.
*/
static int zfs_scrub_after_expand = 1;
static void
vdev_raidz_row_free(raidz_row_t *rr)
{
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_size != 0)
abd_free(rc->rc_abd);
if (rc->rc_orig_data != NULL)
abd_free(rc->rc_orig_data);
}
if (rr->rr_abd_empty != NULL)
abd_free(rr->rr_abd_empty);
kmem_free(rr, offsetof(raidz_row_t, rr_col[rr->rr_scols]));
}
void
vdev_raidz_map_free(raidz_map_t *rm)
{
for (int i = 0; i < rm->rm_nrows; i++)
vdev_raidz_row_free(rm->rm_row[i]);
if (rm->rm_nphys_cols) {
for (int i = 0; i < rm->rm_nphys_cols; i++) {
if (rm->rm_phys_col[i].rc_abd != NULL)
abd_free(rm->rm_phys_col[i].rc_abd);
}
kmem_free(rm->rm_phys_col, sizeof (raidz_col_t) *
rm->rm_nphys_cols);
}
ASSERT3P(rm->rm_lr, ==, NULL);
kmem_free(rm, offsetof(raidz_map_t, rm_row[rm->rm_nrows]));
}
static void
vdev_raidz_map_free_vsd(zio_t *zio)
{
raidz_map_t *rm = zio->io_vsd;
vdev_raidz_map_free(rm);
}
static int
vdev_raidz_reflow_compare(const void *x1, const void *x2)
{
const reflow_node_t *l = x1;
const reflow_node_t *r = x2;
return (TREE_CMP(l->re_txg, r->re_txg));
}
const zio_vsd_ops_t vdev_raidz_vsd_ops = {
.vsd_free = vdev_raidz_map_free_vsd,
};
raidz_row_t *
vdev_raidz_row_alloc(int cols)
{
raidz_row_t *rr =
kmem_zalloc(offsetof(raidz_row_t, rr_col[cols]), KM_SLEEP);
rr->rr_cols = cols;
rr->rr_scols = cols;
for (int c = 0; c < cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
rc->rc_shadow_devidx = INT_MAX;
rc->rc_shadow_offset = UINT64_MAX;
rc->rc_allow_repair = 1;
}
return (rr);
}
static void
vdev_raidz_map_alloc_write(zio_t *zio, raidz_map_t *rm, uint64_t ashift)
{
int c;
int nwrapped = 0;
uint64_t off = 0;
raidz_row_t *rr = rm->rm_row[0];
ASSERT3U(zio->io_type, ==, ZIO_TYPE_WRITE);
ASSERT3U(rm->rm_nrows, ==, 1);
/*
* Pad any parity columns with additional space to account for skip
* sectors.
*/
if (rm->rm_skipstart < rr->rr_firstdatacol) {
ASSERT0(rm->rm_skipstart);
nwrapped = rm->rm_nskip;
} else if (rr->rr_scols < (rm->rm_skipstart + rm->rm_nskip)) {
nwrapped =
(rm->rm_skipstart + rm->rm_nskip) % rr->rr_scols;
}
/*
* Optional single skip sectors (rc_size == 0) will be handled in
* vdev_raidz_io_start_write().
*/
int skipped = rr->rr_scols - rr->rr_cols;
/* Allocate buffers for the parity columns */
for (c = 0; c < rr->rr_firstdatacol; c++) {
raidz_col_t *rc = &rr->rr_col[c];
/*
* Parity columns will pad out a linear ABD to account for
* the skip sector. A linear ABD is used here because
* parity calculations use the ABD buffer directly to calculate
* parity. This avoids doing a memcpy back to the ABD after the
* parity has been calculated. By issuing the parity column
* with the skip sector we can reduce contention on the child
* VDEV queue locks (vq_lock).
*/
if (c < nwrapped) {
rc->rc_abd = abd_alloc_linear(
rc->rc_size + (1ULL << ashift), B_FALSE);
abd_zero_off(rc->rc_abd, rc->rc_size, 1ULL << ashift);
skipped++;
} else {
rc->rc_abd = abd_alloc_linear(rc->rc_size, B_FALSE);
}
}
for (off = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
abd_t *abd = abd_get_offset_struct(&rc->rc_abdstruct,
zio->io_abd, off, rc->rc_size);
/*
* Generate I/O for skip sectors to improve aggregation
* continuity. We will use gang ABD's to reduce contention
* on the child VDEV queue locks (vq_lock) by issuing
* a single I/O that contains the data and skip sector.
*
* It is important to make sure that rc_size is not updated
* even though we are adding a skip sector to the ABD. When
* calculating the parity in vdev_raidz_generate_parity_row()
* the rc_size is used to iterate through the ABD's. We can
* not have zero'd out skip sectors used for calculating
* parity for raidz, because those same sectors are not used
* during reconstruction.
*/
if (c >= rm->rm_skipstart && skipped < rm->rm_nskip) {
rc->rc_abd = abd_alloc_gang();
abd_gang_add(rc->rc_abd, abd, B_TRUE);
abd_gang_add(rc->rc_abd,
abd_get_zeros(1ULL << ashift), B_TRUE);
skipped++;
} else {
rc->rc_abd = abd;
}
off += rc->rc_size;
}
ASSERT3U(off, ==, zio->io_size);
ASSERT3S(skipped, ==, rm->rm_nskip);
}
static void
vdev_raidz_map_alloc_read(zio_t *zio, raidz_map_t *rm)
{
int c;
raidz_row_t *rr = rm->rm_row[0];
ASSERT3U(rm->rm_nrows, ==, 1);
/* Allocate buffers for the parity columns */
for (c = 0; c < rr->rr_firstdatacol; c++)
rr->rr_col[c].rc_abd =
abd_alloc_linear(rr->rr_col[c].rc_size, B_FALSE);
for (uint64_t off = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
rc->rc_abd = abd_get_offset_struct(&rc->rc_abdstruct,
zio->io_abd, off, rc->rc_size);
off += rc->rc_size;
}
}
/*
* Divides the IO evenly across all child vdevs; usually, dcols is
* the number of children in the target vdev.
*
* Avoid inlining the function to keep vdev_raidz_io_start(), which
* is this functions only caller, as small as possible on the stack.
*/
noinline raidz_map_t *
vdev_raidz_map_alloc(zio_t *zio, uint64_t ashift, uint64_t dcols,
uint64_t nparity)
{
raidz_row_t *rr;
/* The starting RAIDZ (parent) vdev sector of the block. */
uint64_t b = zio->io_offset >> ashift;
/* The zio's size in units of the vdev's minimum sector size. */
uint64_t s = zio->io_size >> ashift;
/* The first column for this stripe. */
uint64_t f = b % dcols;
/* The starting byte offset on each child vdev. */
uint64_t o = (b / dcols) << ashift;
uint64_t acols, scols;
raidz_map_t *rm =
kmem_zalloc(offsetof(raidz_map_t, rm_row[1]), KM_SLEEP);
rm->rm_nrows = 1;
/*
* "Quotient": The number of data sectors for this stripe on all but
* the "big column" child vdevs that also contain "remainder" data.
*/
uint64_t q = s / (dcols - nparity);
/*
* "Remainder": The number of partial stripe data sectors in this I/O.
* This will add a sector to some, but not all, child vdevs.
*/
uint64_t r = s - q * (dcols - nparity);
/* The number of "big columns" - those which contain remainder data. */
uint64_t bc = (r == 0 ? 0 : r + nparity);
/*
* The total number of data and parity sectors associated with
* this I/O.
*/
uint64_t tot = s + nparity * (q + (r == 0 ? 0 : 1));
/*
* acols: The columns that will be accessed.
* scols: The columns that will be accessed or skipped.
*/
if (q == 0) {
/* Our I/O request doesn't span all child vdevs. */
acols = bc;
scols = MIN(dcols, roundup(bc, nparity + 1));
} else {
acols = dcols;
scols = dcols;
}
ASSERT3U(acols, <=, scols);
rr = vdev_raidz_row_alloc(scols);
rm->rm_row[0] = rr;
rr->rr_cols = acols;
rr->rr_bigcols = bc;
rr->rr_firstdatacol = nparity;
#ifdef ZFS_DEBUG
rr->rr_offset = zio->io_offset;
rr->rr_size = zio->io_size;
#endif
uint64_t asize = 0;
for (uint64_t c = 0; c < scols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
uint64_t col = f + c;
uint64_t coff = o;
if (col >= dcols) {
col -= dcols;
coff += 1ULL << ashift;
}
rc->rc_devidx = col;
rc->rc_offset = coff;
if (c >= acols)
rc->rc_size = 0;
else if (c < bc)
rc->rc_size = (q + 1) << ashift;
else
rc->rc_size = q << ashift;
asize += rc->rc_size;
}
ASSERT3U(asize, ==, tot << ashift);
rm->rm_nskip = roundup(tot, nparity + 1) - tot;
rm->rm_skipstart = bc;
/*
* If all data stored spans all columns, there's a danger that parity
* will always be on the same device and, since parity isn't read
* during normal operation, that device's I/O bandwidth won't be
* used effectively. We therefore switch the parity every 1MB.
*
* ... at least that was, ostensibly, the theory. As a practical
* matter unless we juggle the parity between all devices evenly, we
* won't see any benefit. Further, occasional writes that aren't a
* multiple of the LCM of the number of children and the minimum
* stripe width are sufficient to avoid pessimal behavior.
* Unfortunately, this decision created an implicit on-disk format
* requirement that we need to support for all eternity, but only
* for single-parity RAID-Z.
*
* If we intend to skip a sector in the zeroth column for padding
* we must make sure to note this swap. We will never intend to
* skip the first column since at least one data and one parity
* column must appear in each row.
*/
ASSERT(rr->rr_cols >= 2);
ASSERT(rr->rr_col[0].rc_size == rr->rr_col[1].rc_size);
if (rr->rr_firstdatacol == 1 && (zio->io_offset & (1ULL << 20))) {
uint64_t devidx = rr->rr_col[0].rc_devidx;
o = rr->rr_col[0].rc_offset;
rr->rr_col[0].rc_devidx = rr->rr_col[1].rc_devidx;
rr->rr_col[0].rc_offset = rr->rr_col[1].rc_offset;
rr->rr_col[1].rc_devidx = devidx;
rr->rr_col[1].rc_offset = o;
if (rm->rm_skipstart == 0)
rm->rm_skipstart = 1;
}
if (zio->io_type == ZIO_TYPE_WRITE) {
vdev_raidz_map_alloc_write(zio, rm, ashift);
} else {
vdev_raidz_map_alloc_read(zio, rm);
}
/* init RAIDZ parity ops */
rm->rm_ops = vdev_raidz_math_get_ops();
return (rm);
}
/*
* Everything before reflow_offset_synced should have been moved to the new
* location (read and write completed). However, this may not yet be reflected
* in the on-disk format (e.g. raidz_reflow_sync() has been called but the
* uberblock has not yet been written). If reflow is not in progress,
* reflow_offset_synced should be UINT64_MAX. For each row, if the row is
* entirely before reflow_offset_synced, it will come from the new location.
* Otherwise this row will come from the old location. Therefore, rows that
* straddle the reflow_offset_synced will come from the old location.
*
* For writes, reflow_offset_next is the next offset to copy. If a sector has
* been copied, but not yet reflected in the on-disk progress
* (reflow_offset_synced), it will also be written to the new (already copied)
* offset.
*/
noinline raidz_map_t *
vdev_raidz_map_alloc_expanded(zio_t *zio,
uint64_t ashift, uint64_t physical_cols, uint64_t logical_cols,
uint64_t nparity, uint64_t reflow_offset_synced,
uint64_t reflow_offset_next, boolean_t use_scratch)
{
abd_t *abd = zio->io_abd;
uint64_t offset = zio->io_offset;
uint64_t size = zio->io_size;
/* The zio's size in units of the vdev's minimum sector size. */
uint64_t s = size >> ashift;
/*
* "Quotient": The number of data sectors for this stripe on all but
* the "big column" child vdevs that also contain "remainder" data.
* AKA "full rows"
*/
uint64_t q = s / (logical_cols - nparity);
/*
* "Remainder": The number of partial stripe data sectors in this I/O.
* This will add a sector to some, but not all, child vdevs.
*/
uint64_t r = s - q * (logical_cols - nparity);
/* The number of "big columns" - those which contain remainder data. */
uint64_t bc = (r == 0 ? 0 : r + nparity);
/*
* The total number of data and parity sectors associated with
* this I/O.
*/
uint64_t tot = s + nparity * (q + (r == 0 ? 0 : 1));
/* How many rows contain data (not skip) */
uint64_t rows = howmany(tot, logical_cols);
int cols = MIN(tot, logical_cols);
raidz_map_t *rm =
kmem_zalloc(offsetof(raidz_map_t, rm_row[rows]),
KM_SLEEP);
rm->rm_nrows = rows;
rm->rm_nskip = roundup(tot, nparity + 1) - tot;
rm->rm_skipstart = bc;
uint64_t asize = 0;
for (uint64_t row = 0; row < rows; row++) {
boolean_t row_use_scratch = B_FALSE;
raidz_row_t *rr = vdev_raidz_row_alloc(cols);
rm->rm_row[row] = rr;
/* The starting RAIDZ (parent) vdev sector of the row. */
uint64_t b = (offset >> ashift) + row * logical_cols;
/*
* If we are in the middle of a reflow, and the copying has
* not yet completed for any part of this row, then use the
* old location of this row. Note that reflow_offset_synced
* reflects the i/o that's been completed, because it's
* updated by a synctask, after zio_wait(spa_txg_zio[]).
* This is sufficient for our check, even if that progress
* has not yet been recorded to disk (reflected in
* spa_ubsync). Also note that we consider the last row to
* be "full width" (`cols`-wide rather than `bc`-wide) for
* this calculation. This causes a tiny bit of unnecessary
* double-writes but is safe and simpler to calculate.
*/
int row_phys_cols = physical_cols;
if (b + cols > reflow_offset_synced >> ashift)
row_phys_cols--;
else if (use_scratch)
row_use_scratch = B_TRUE;
/* starting child of this row */
uint64_t child_id = b % row_phys_cols;
/* The starting byte offset on each child vdev. */
uint64_t child_offset = (b / row_phys_cols) << ashift;
/*
* Note, rr_cols is the entire width of the block, even
* if this row is shorter. This is needed because parity
* generation (for Q and R) needs to know the entire width,
* because it treats the short row as though it was
* full-width (and the "phantom" sectors were zero-filled).
*
* Another approach to this would be to set cols shorter
* (to just the number of columns that we might do i/o to)
* and have another mechanism to tell the parity generation
* about the "entire width". Reconstruction (at least
* vdev_raidz_reconstruct_general()) would also need to
* know about the "entire width".
*/
rr->rr_firstdatacol = nparity;
#ifdef ZFS_DEBUG
/*
* note: rr_size is PSIZE, not ASIZE
*/
rr->rr_offset = b << ashift;
rr->rr_size = (rr->rr_cols - rr->rr_firstdatacol) << ashift;
#endif
for (int c = 0; c < rr->rr_cols; c++, child_id++) {
if (child_id >= row_phys_cols) {
child_id -= row_phys_cols;
child_offset += 1ULL << ashift;
}
raidz_col_t *rc = &rr->rr_col[c];
rc->rc_devidx = child_id;
rc->rc_offset = child_offset;
/*
* Get this from the scratch space if appropriate.
* This only happens if we crashed in the middle of
* raidz_reflow_scratch_sync() (while it's running,
* the rangelock prevents us from doing concurrent
* io), and even then only during zpool import or
* when the pool is imported readonly.
*/
if (row_use_scratch)
rc->rc_offset -= VDEV_BOOT_SIZE;
uint64_t dc = c - rr->rr_firstdatacol;
if (c < rr->rr_firstdatacol) {
rc->rc_size = 1ULL << ashift;
/*
* Parity sectors' rc_abd's are set below
* after determining if this is an aggregation.
*/
} else if (row == rows - 1 && bc != 0 && c >= bc) {
/*
* Past the end of the block (even including
* skip sectors). This sector is part of the
* map so that we have full rows for p/q parity
* generation.
*/
rc->rc_size = 0;
rc->rc_abd = NULL;
} else {
/* "data column" (col excluding parity) */
uint64_t off;
if (c < bc || r == 0) {
off = dc * rows + row;
} else {
off = r * rows +
(dc - r) * (rows - 1) + row;
}
rc->rc_size = 1ULL << ashift;
rc->rc_abd = abd_get_offset_struct(
&rc->rc_abdstruct, abd, off << ashift,
rc->rc_size);
}
if (rc->rc_size == 0)
continue;
/*
* If any part of this row is in both old and new
* locations, the primary location is the old
* location. If this sector was already copied to the
* new location, we need to also write to the new,
* "shadow" location.
*
* Note, `row_phys_cols != physical_cols` indicates
* that the primary location is the old location.
* `b+c < reflow_offset_next` indicates that the copy
* to the new location has been initiated. We know
* that the copy has completed because we have the
* rangelock, which is held exclusively while the
* copy is in progress.
*/
if (row_use_scratch ||
(row_phys_cols != physical_cols &&
b + c < reflow_offset_next >> ashift)) {
rc->rc_shadow_devidx = (b + c) % physical_cols;
rc->rc_shadow_offset =
((b + c) / physical_cols) << ashift;
if (row_use_scratch)
rc->rc_shadow_offset -= VDEV_BOOT_SIZE;
}
asize += rc->rc_size;
}
/*
* See comment in vdev_raidz_map_alloc()
*/
if (rr->rr_firstdatacol == 1 && rr->rr_cols > 1 &&
(offset & (1ULL << 20))) {
ASSERT(rr->rr_cols >= 2);
ASSERT(rr->rr_col[0].rc_size == rr->rr_col[1].rc_size);
int devidx0 = rr->rr_col[0].rc_devidx;
uint64_t offset0 = rr->rr_col[0].rc_offset;
int shadow_devidx0 = rr->rr_col[0].rc_shadow_devidx;
uint64_t shadow_offset0 =
rr->rr_col[0].rc_shadow_offset;
rr->rr_col[0].rc_devidx = rr->rr_col[1].rc_devidx;
rr->rr_col[0].rc_offset = rr->rr_col[1].rc_offset;
rr->rr_col[0].rc_shadow_devidx =
rr->rr_col[1].rc_shadow_devidx;
rr->rr_col[0].rc_shadow_offset =
rr->rr_col[1].rc_shadow_offset;
rr->rr_col[1].rc_devidx = devidx0;
rr->rr_col[1].rc_offset = offset0;
rr->rr_col[1].rc_shadow_devidx = shadow_devidx0;
rr->rr_col[1].rc_shadow_offset = shadow_offset0;
}
}
ASSERT3U(asize, ==, tot << ashift);
/*
* Determine if the block is contiguous, in which case we can use
* an aggregation.
*/
if (rows >= raidz_io_aggregate_rows) {
rm->rm_nphys_cols = physical_cols;
rm->rm_phys_col =
kmem_zalloc(sizeof (raidz_col_t) * rm->rm_nphys_cols,
KM_SLEEP);
/*
* Determine the aggregate io's offset and size, and check
* that the io is contiguous.
*/
for (int i = 0;
i < rm->rm_nrows && rm->rm_phys_col != NULL; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
raidz_col_t *prc =
&rm->rm_phys_col[rc->rc_devidx];
if (rc->rc_size == 0)
continue;
if (prc->rc_size == 0) {
ASSERT0(prc->rc_offset);
prc->rc_offset = rc->rc_offset;
} else if (prc->rc_offset + prc->rc_size !=
rc->rc_offset) {
/*
* This block is not contiguous and
* therefore can't be aggregated.
* This is expected to be rare, so
* the cost of allocating and then
* freeing rm_phys_col is not
* significant.
*/
kmem_free(rm->rm_phys_col,
sizeof (raidz_col_t) *
rm->rm_nphys_cols);
rm->rm_phys_col = NULL;
rm->rm_nphys_cols = 0;
break;
}
prc->rc_size += rc->rc_size;
}
}
}
if (rm->rm_phys_col != NULL) {
/*
* Allocate aggregate ABD's.
*/
for (int i = 0; i < rm->rm_nphys_cols; i++) {
raidz_col_t *prc = &rm->rm_phys_col[i];
prc->rc_devidx = i;
if (prc->rc_size == 0)
continue;
prc->rc_abd =
abd_alloc_linear(rm->rm_phys_col[i].rc_size,
B_FALSE);
}
/*
* Point the parity abd's into the aggregate abd's.
*/
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_firstdatacol; c++) {
raidz_col_t *rc = &rr->rr_col[c];
raidz_col_t *prc =
&rm->rm_phys_col[rc->rc_devidx];
rc->rc_abd =
abd_get_offset_struct(&rc->rc_abdstruct,
prc->rc_abd,
rc->rc_offset - prc->rc_offset,
rc->rc_size);
}
}
} else {
/*
* Allocate new abd's for the parity sectors.
*/
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_firstdatacol; c++) {
raidz_col_t *rc = &rr->rr_col[c];
rc->rc_abd =
abd_alloc_linear(rc->rc_size,
B_TRUE);
}
}
}
/* init RAIDZ parity ops */
rm->rm_ops = vdev_raidz_math_get_ops();
return (rm);
}
struct pqr_struct {
uint64_t *p;
uint64_t *q;
uint64_t *r;
};
static int
vdev_raidz_p_func(void *buf, size_t size, void *private)
{
struct pqr_struct *pqr = private;
const uint64_t *src = buf;
int cnt = size / sizeof (src[0]);
ASSERT(pqr->p && !pqr->q && !pqr->r);
for (int i = 0; i < cnt; i++, src++, pqr->p++)
*pqr->p ^= *src;
return (0);
}
static int
vdev_raidz_pq_func(void *buf, size_t size, void *private)
{
struct pqr_struct *pqr = private;
const uint64_t *src = buf;
uint64_t mask;
int cnt = size / sizeof (src[0]);
ASSERT(pqr->p && pqr->q && !pqr->r);
for (int i = 0; i < cnt; i++, src++, pqr->p++, pqr->q++) {
*pqr->p ^= *src;
VDEV_RAIDZ_64MUL_2(*pqr->q, mask);
*pqr->q ^= *src;
}
return (0);
}
static int
vdev_raidz_pqr_func(void *buf, size_t size, void *private)
{
struct pqr_struct *pqr = private;
const uint64_t *src = buf;
uint64_t mask;
int cnt = size / sizeof (src[0]);
ASSERT(pqr->p && pqr->q && pqr->r);
for (int i = 0; i < cnt; i++, src++, pqr->p++, pqr->q++, pqr->r++) {
*pqr->p ^= *src;
VDEV_RAIDZ_64MUL_2(*pqr->q, mask);
*pqr->q ^= *src;
VDEV_RAIDZ_64MUL_4(*pqr->r, mask);
*pqr->r ^= *src;
}
return (0);
}
static void
vdev_raidz_generate_parity_p(raidz_row_t *rr)
{
uint64_t *p = abd_to_buf(rr->rr_col[VDEV_RAIDZ_P].rc_abd);
for (int c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
abd_t *src = rr->rr_col[c].rc_abd;
if (c == rr->rr_firstdatacol) {
abd_copy_to_buf(p, src, rr->rr_col[c].rc_size);
} else {
struct pqr_struct pqr = { p, NULL, NULL };
(void) abd_iterate_func(src, 0, rr->rr_col[c].rc_size,
vdev_raidz_p_func, &pqr);
}
}
}
static void
vdev_raidz_generate_parity_pq(raidz_row_t *rr)
{
uint64_t *p = abd_to_buf(rr->rr_col[VDEV_RAIDZ_P].rc_abd);
uint64_t *q = abd_to_buf(rr->rr_col[VDEV_RAIDZ_Q].rc_abd);
uint64_t pcnt = rr->rr_col[VDEV_RAIDZ_P].rc_size / sizeof (p[0]);
ASSERT(rr->rr_col[VDEV_RAIDZ_P].rc_size ==
rr->rr_col[VDEV_RAIDZ_Q].rc_size);
for (int c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
abd_t *src = rr->rr_col[c].rc_abd;
uint64_t ccnt = rr->rr_col[c].rc_size / sizeof (p[0]);
if (c == rr->rr_firstdatacol) {
ASSERT(ccnt == pcnt || ccnt == 0);
abd_copy_to_buf(p, src, rr->rr_col[c].rc_size);
(void) memcpy(q, p, rr->rr_col[c].rc_size);
for (uint64_t i = ccnt; i < pcnt; i++) {
p[i] = 0;
q[i] = 0;
}
} else {
struct pqr_struct pqr = { p, q, NULL };
ASSERT(ccnt <= pcnt);
(void) abd_iterate_func(src, 0, rr->rr_col[c].rc_size,
vdev_raidz_pq_func, &pqr);
/*
* Treat short columns as though they are full of 0s.
* Note that there's therefore nothing needed for P.
*/
uint64_t mask;
for (uint64_t i = ccnt; i < pcnt; i++) {
VDEV_RAIDZ_64MUL_2(q[i], mask);
}
}
}
}
static void
vdev_raidz_generate_parity_pqr(raidz_row_t *rr)
{
uint64_t *p = abd_to_buf(rr->rr_col[VDEV_RAIDZ_P].rc_abd);
uint64_t *q = abd_to_buf(rr->rr_col[VDEV_RAIDZ_Q].rc_abd);
uint64_t *r = abd_to_buf(rr->rr_col[VDEV_RAIDZ_R].rc_abd);
uint64_t pcnt = rr->rr_col[VDEV_RAIDZ_P].rc_size / sizeof (p[0]);
ASSERT(rr->rr_col[VDEV_RAIDZ_P].rc_size ==
rr->rr_col[VDEV_RAIDZ_Q].rc_size);
ASSERT(rr->rr_col[VDEV_RAIDZ_P].rc_size ==
rr->rr_col[VDEV_RAIDZ_R].rc_size);
for (int c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
abd_t *src = rr->rr_col[c].rc_abd;
uint64_t ccnt = rr->rr_col[c].rc_size / sizeof (p[0]);
if (c == rr->rr_firstdatacol) {
ASSERT(ccnt == pcnt || ccnt == 0);
abd_copy_to_buf(p, src, rr->rr_col[c].rc_size);
(void) memcpy(q, p, rr->rr_col[c].rc_size);
(void) memcpy(r, p, rr->rr_col[c].rc_size);
for (uint64_t i = ccnt; i < pcnt; i++) {
p[i] = 0;
q[i] = 0;
r[i] = 0;
}
} else {
struct pqr_struct pqr = { p, q, r };
ASSERT(ccnt <= pcnt);
(void) abd_iterate_func(src, 0, rr->rr_col[c].rc_size,
vdev_raidz_pqr_func, &pqr);
/*
* Treat short columns as though they are full of 0s.
* Note that there's therefore nothing needed for P.
*/
uint64_t mask;
for (uint64_t i = ccnt; i < pcnt; i++) {
VDEV_RAIDZ_64MUL_2(q[i], mask);
VDEV_RAIDZ_64MUL_4(r[i], mask);
}
}
}
}
/*
* Generate RAID parity in the first virtual columns according to the number of
* parity columns available.
*/
void
vdev_raidz_generate_parity_row(raidz_map_t *rm, raidz_row_t *rr)
{
if (rr->rr_cols == 0) {
/*
* We are handling this block one row at a time (because
* this block has a different logical vs physical width,
* due to RAIDZ expansion), and this is a pad-only row,
* which has no parity.
*/
return;
}
/* Generate using the new math implementation */
if (vdev_raidz_math_generate(rm, rr) != RAIDZ_ORIGINAL_IMPL)
return;
switch (rr->rr_firstdatacol) {
case 1:
vdev_raidz_generate_parity_p(rr);
break;
case 2:
vdev_raidz_generate_parity_pq(rr);
break;
case 3:
vdev_raidz_generate_parity_pqr(rr);
break;
default:
cmn_err(CE_PANIC, "invalid RAID-Z configuration");
}
}
void
vdev_raidz_generate_parity(raidz_map_t *rm)
{
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
vdev_raidz_generate_parity_row(rm, rr);
}
}
static int
vdev_raidz_reconst_p_func(void *dbuf, void *sbuf, size_t size, void *private)
{
(void) private;
uint64_t *dst = dbuf;
uint64_t *src = sbuf;
int cnt = size / sizeof (src[0]);
for (int i = 0; i < cnt; i++) {
dst[i] ^= src[i];
}
return (0);
}
static int
vdev_raidz_reconst_q_pre_func(void *dbuf, void *sbuf, size_t size,
void *private)
{
(void) private;
uint64_t *dst = dbuf;
uint64_t *src = sbuf;
uint64_t mask;
int cnt = size / sizeof (dst[0]);
for (int i = 0; i < cnt; i++, dst++, src++) {
VDEV_RAIDZ_64MUL_2(*dst, mask);
*dst ^= *src;
}
return (0);
}
static int
vdev_raidz_reconst_q_pre_tail_func(void *buf, size_t size, void *private)
{
(void) private;
uint64_t *dst = buf;
uint64_t mask;
int cnt = size / sizeof (dst[0]);
for (int i = 0; i < cnt; i++, dst++) {
/* same operation as vdev_raidz_reconst_q_pre_func() on dst */
VDEV_RAIDZ_64MUL_2(*dst, mask);
}
return (0);
}
struct reconst_q_struct {
uint64_t *q;
int exp;
};
static int
vdev_raidz_reconst_q_post_func(void *buf, size_t size, void *private)
{
struct reconst_q_struct *rq = private;
uint64_t *dst = buf;
int cnt = size / sizeof (dst[0]);
for (int i = 0; i < cnt; i++, dst++, rq->q++) {
int j;
uint8_t *b;
*dst ^= *rq->q;
for (j = 0, b = (uint8_t *)dst; j < 8; j++, b++) {
*b = vdev_raidz_exp2(*b, rq->exp);
}
}
return (0);
}
struct reconst_pq_struct {
uint8_t *p;
uint8_t *q;
uint8_t *pxy;
uint8_t *qxy;
int aexp;
int bexp;
};
static int
vdev_raidz_reconst_pq_func(void *xbuf, void *ybuf, size_t size, void *private)
{
struct reconst_pq_struct *rpq = private;
uint8_t *xd = xbuf;
uint8_t *yd = ybuf;
for (int i = 0; i < size;
i++, rpq->p++, rpq->q++, rpq->pxy++, rpq->qxy++, xd++, yd++) {
*xd = vdev_raidz_exp2(*rpq->p ^ *rpq->pxy, rpq->aexp) ^
vdev_raidz_exp2(*rpq->q ^ *rpq->qxy, rpq->bexp);
*yd = *rpq->p ^ *rpq->pxy ^ *xd;
}
return (0);
}
static int
vdev_raidz_reconst_pq_tail_func(void *xbuf, size_t size, void *private)
{
struct reconst_pq_struct *rpq = private;
uint8_t *xd = xbuf;
for (int i = 0; i < size;
i++, rpq->p++, rpq->q++, rpq->pxy++, rpq->qxy++, xd++) {
/* same operation as vdev_raidz_reconst_pq_func() on xd */
*xd = vdev_raidz_exp2(*rpq->p ^ *rpq->pxy, rpq->aexp) ^
vdev_raidz_exp2(*rpq->q ^ *rpq->qxy, rpq->bexp);
}
return (0);
}
static void
vdev_raidz_reconstruct_p(raidz_row_t *rr, int *tgts, int ntgts)
{
int x = tgts[0];
abd_t *dst, *src;
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT)
zfs_dbgmsg("reconstruct_p(rm=%px x=%u)", rr, x);
ASSERT3U(ntgts, ==, 1);
ASSERT3U(x, >=, rr->rr_firstdatacol);
ASSERT3U(x, <, rr->rr_cols);
ASSERT3U(rr->rr_col[x].rc_size, <=, rr->rr_col[VDEV_RAIDZ_P].rc_size);
src = rr->rr_col[VDEV_RAIDZ_P].rc_abd;
dst = rr->rr_col[x].rc_abd;
abd_copy_from_buf(dst, abd_to_buf(src), rr->rr_col[x].rc_size);
for (int c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
uint64_t size = MIN(rr->rr_col[x].rc_size,
rr->rr_col[c].rc_size);
src = rr->rr_col[c].rc_abd;
if (c == x)
continue;
(void) abd_iterate_func2(dst, src, 0, 0, size,
vdev_raidz_reconst_p_func, NULL);
}
}
static void
vdev_raidz_reconstruct_q(raidz_row_t *rr, int *tgts, int ntgts)
{
int x = tgts[0];
int c, exp;
abd_t *dst, *src;
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT)
zfs_dbgmsg("reconstruct_q(rm=%px x=%u)", rr, x);
ASSERT(ntgts == 1);
ASSERT(rr->rr_col[x].rc_size <= rr->rr_col[VDEV_RAIDZ_Q].rc_size);
for (c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
uint64_t size = (c == x) ? 0 : MIN(rr->rr_col[x].rc_size,
rr->rr_col[c].rc_size);
src = rr->rr_col[c].rc_abd;
dst = rr->rr_col[x].rc_abd;
if (c == rr->rr_firstdatacol) {
abd_copy(dst, src, size);
if (rr->rr_col[x].rc_size > size) {
abd_zero_off(dst, size,
rr->rr_col[x].rc_size - size);
}
} else {
ASSERT3U(size, <=, rr->rr_col[x].rc_size);
(void) abd_iterate_func2(dst, src, 0, 0, size,
vdev_raidz_reconst_q_pre_func, NULL);
(void) abd_iterate_func(dst,
size, rr->rr_col[x].rc_size - size,
vdev_raidz_reconst_q_pre_tail_func, NULL);
}
}
src = rr->rr_col[VDEV_RAIDZ_Q].rc_abd;
dst = rr->rr_col[x].rc_abd;
exp = 255 - (rr->rr_cols - 1 - x);
struct reconst_q_struct rq = { abd_to_buf(src), exp };
(void) abd_iterate_func(dst, 0, rr->rr_col[x].rc_size,
vdev_raidz_reconst_q_post_func, &rq);
}
static void
vdev_raidz_reconstruct_pq(raidz_row_t *rr, int *tgts, int ntgts)
{
uint8_t *p, *q, *pxy, *qxy, tmp, a, b, aexp, bexp;
abd_t *pdata, *qdata;
uint64_t xsize, ysize;
int x = tgts[0];
int y = tgts[1];
abd_t *xd, *yd;
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT)
zfs_dbgmsg("reconstruct_pq(rm=%px x=%u y=%u)", rr, x, y);
ASSERT(ntgts == 2);
ASSERT(x < y);
ASSERT(x >= rr->rr_firstdatacol);
ASSERT(y < rr->rr_cols);
ASSERT(rr->rr_col[x].rc_size >= rr->rr_col[y].rc_size);
/*
* Move the parity data aside -- we're going to compute parity as
* though columns x and y were full of zeros -- Pxy and Qxy. We want to
* reuse the parity generation mechanism without trashing the actual
* parity so we make those columns appear to be full of zeros by
* setting their lengths to zero.
*/
pdata = rr->rr_col[VDEV_RAIDZ_P].rc_abd;
qdata = rr->rr_col[VDEV_RAIDZ_Q].rc_abd;
xsize = rr->rr_col[x].rc_size;
ysize = rr->rr_col[y].rc_size;
rr->rr_col[VDEV_RAIDZ_P].rc_abd =
abd_alloc_linear(rr->rr_col[VDEV_RAIDZ_P].rc_size, B_TRUE);
rr->rr_col[VDEV_RAIDZ_Q].rc_abd =
abd_alloc_linear(rr->rr_col[VDEV_RAIDZ_Q].rc_size, B_TRUE);
rr->rr_col[x].rc_size = 0;
rr->rr_col[y].rc_size = 0;
vdev_raidz_generate_parity_pq(rr);
rr->rr_col[x].rc_size = xsize;
rr->rr_col[y].rc_size = ysize;
p = abd_to_buf(pdata);
q = abd_to_buf(qdata);
pxy = abd_to_buf(rr->rr_col[VDEV_RAIDZ_P].rc_abd);
qxy = abd_to_buf(rr->rr_col[VDEV_RAIDZ_Q].rc_abd);
xd = rr->rr_col[x].rc_abd;
yd = rr->rr_col[y].rc_abd;
/*
* We now have:
* Pxy = P + D_x + D_y
* Qxy = Q + 2^(ndevs - 1 - x) * D_x + 2^(ndevs - 1 - y) * D_y
*
* We can then solve for D_x:
* D_x = A * (P + Pxy) + B * (Q + Qxy)
* where
* A = 2^(x - y) * (2^(x - y) + 1)^-1
* B = 2^(ndevs - 1 - x) * (2^(x - y) + 1)^-1
*
* With D_x in hand, we can easily solve for D_y:
* D_y = P + Pxy + D_x
*/
a = vdev_raidz_pow2[255 + x - y];
b = vdev_raidz_pow2[255 - (rr->rr_cols - 1 - x)];
tmp = 255 - vdev_raidz_log2[a ^ 1];
aexp = vdev_raidz_log2[vdev_raidz_exp2(a, tmp)];
bexp = vdev_raidz_log2[vdev_raidz_exp2(b, tmp)];
ASSERT3U(xsize, >=, ysize);
struct reconst_pq_struct rpq = { p, q, pxy, qxy, aexp, bexp };
(void) abd_iterate_func2(xd, yd, 0, 0, ysize,
vdev_raidz_reconst_pq_func, &rpq);
(void) abd_iterate_func(xd, ysize, xsize - ysize,
vdev_raidz_reconst_pq_tail_func, &rpq);
abd_free(rr->rr_col[VDEV_RAIDZ_P].rc_abd);
abd_free(rr->rr_col[VDEV_RAIDZ_Q].rc_abd);
/*
* Restore the saved parity data.
*/
rr->rr_col[VDEV_RAIDZ_P].rc_abd = pdata;
rr->rr_col[VDEV_RAIDZ_Q].rc_abd = qdata;
}
/*
* In the general case of reconstruction, we must solve the system of linear
* equations defined by the coefficients used to generate parity as well as
* the contents of the data and parity disks. This can be expressed with
* vectors for the original data (D) and the actual data (d) and parity (p)
* and a matrix composed of the identity matrix (I) and a dispersal matrix (V):
*
* __ __ __ __
* | | __ __ | p_0 |
* | V | | D_0 | | p_m-1 |
* | | x | : | = | d_0 |
* | I | | D_n-1 | | : |
* | | ~~ ~~ | d_n-1 |
* ~~ ~~ ~~ ~~
*
* I is simply a square identity matrix of size n, and V is a vandermonde
* matrix defined by the coefficients we chose for the various parity columns
* (1, 2, 4). Note that these values were chosen both for simplicity, speedy
* computation as well as linear separability.
*
* __ __ __ __
* | 1 .. 1 1 1 | | p_0 |
* | 2^n-1 .. 4 2 1 | __ __ | : |
* | 4^n-1 .. 16 4 1 | | D_0 | | p_m-1 |
* | 1 .. 0 0 0 | | D_1 | | d_0 |
* | 0 .. 0 0 0 | x | D_2 | = | d_1 |
* | : : : : | | : | | d_2 |
* | 0 .. 1 0 0 | | D_n-1 | | : |
* | 0 .. 0 1 0 | ~~ ~~ | : |
* | 0 .. 0 0 1 | | d_n-1 |
* ~~ ~~ ~~ ~~
*
* Note that I, V, d, and p are known. To compute D, we must invert the
* matrix and use the known data and parity values to reconstruct the unknown
* data values. We begin by removing the rows in V|I and d|p that correspond
* to failed or missing columns; we then make V|I square (n x n) and d|p
* sized n by removing rows corresponding to unused parity from the bottom up
* to generate (V|I)' and (d|p)'. We can then generate the inverse of (V|I)'
* using Gauss-Jordan elimination. In the example below we use m=3 parity
* columns, n=8 data columns, with errors in d_1, d_2, and p_1:
* __ __
* | 1 1 1 1 1 1 1 1 |
* | 128 64 32 16 8 4 2 1 | <-----+-+-- missing disks
* | 19 205 116 29 64 16 4 1 | / /
* | 1 0 0 0 0 0 0 0 | / /
* | 0 1 0 0 0 0 0 0 | <--' /
* (V|I) = | 0 0 1 0 0 0 0 0 | <---'
* | 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 1 1 1 1 1 1 1 1 |
* | 128 64 32 16 8 4 2 1 |
* | 19 205 116 29 64 16 4 1 |
* | 1 0 0 0 0 0 0 0 |
* | 0 1 0 0 0 0 0 0 |
* (V|I)' = | 0 0 1 0 0 0 0 0 |
* | 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 |
* ~~ ~~
*
* Here we employ Gauss-Jordan elimination to find the inverse of (V|I)'. We
* have carefully chosen the seed values 1, 2, and 4 to ensure that this
* matrix is not singular.
* __ __
* | 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 |
* | 19 205 116 29 64 16 4 1 0 1 0 0 0 0 0 0 |
* | 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 |
* | 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 |
* | 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 |
* | 19 205 116 29 64 16 4 1 0 1 0 0 0 0 0 0 |
* | 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 |
* | 0 1 1 0 0 0 0 0 1 0 1 1 1 1 1 1 |
* | 0 205 116 0 0 0 0 0 0 1 19 29 64 16 4 1 |
* | 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 |
* | 0 1 1 0 0 0 0 0 1 0 1 1 1 1 1 1 |
* | 0 0 185 0 0 0 0 0 205 1 222 208 141 221 201 204 |
* | 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 |
* | 0 1 1 0 0 0 0 0 1 0 1 1 1 1 1 1 |
* | 0 0 1 0 0 0 0 0 166 100 4 40 158 168 216 209 |
* | 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 1 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 |
* | 0 1 0 0 0 0 0 0 167 100 5 41 159 169 217 208 |
* | 0 0 1 0 0 0 0 0 166 100 4 40 158 168 216 209 |
* | 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 |
* ~~ ~~
* __ __
* | 0 0 1 0 0 0 0 0 |
* | 167 100 5 41 159 169 217 208 |
* | 166 100 4 40 158 168 216 209 |
* (V|I)'^-1 = | 0 0 0 1 0 0 0 0 |
* | 0 0 0 0 1 0 0 0 |
* | 0 0 0 0 0 1 0 0 |
* | 0 0 0 0 0 0 1 0 |
* | 0 0 0 0 0 0 0 1 |
* ~~ ~~
*
* We can then simply compute D = (V|I)'^-1 x (d|p)' to discover the values
* of the missing data.
*
* As is apparent from the example above, the only non-trivial rows in the
* inverse matrix correspond to the data disks that we're trying to
* reconstruct. Indeed, those are the only rows we need as the others would
* only be useful for reconstructing data known or assumed to be valid. For
* that reason, we only build the coefficients in the rows that correspond to
* targeted columns.
*/
static void
vdev_raidz_matrix_init(raidz_row_t *rr, int n, int nmap, int *map,
uint8_t **rows)
{
int i, j;
int pow;
ASSERT(n == rr->rr_cols - rr->rr_firstdatacol);
/*
* Fill in the missing rows of interest.
*/
for (i = 0; i < nmap; i++) {
ASSERT3S(0, <=, map[i]);
ASSERT3S(map[i], <=, 2);
pow = map[i] * n;
if (pow > 255)
pow -= 255;
ASSERT(pow <= 255);
for (j = 0; j < n; j++) {
pow -= map[i];
if (pow < 0)
pow += 255;
rows[i][j] = vdev_raidz_pow2[pow];
}
}
}
static void
vdev_raidz_matrix_invert(raidz_row_t *rr, int n, int nmissing, int *missing,
uint8_t **rows, uint8_t **invrows, const uint8_t *used)
{
int i, j, ii, jj;
uint8_t log;
/*
* Assert that the first nmissing entries from the array of used
* columns correspond to parity columns and that subsequent entries
* correspond to data columns.
*/
for (i = 0; i < nmissing; i++) {
ASSERT3S(used[i], <, rr->rr_firstdatacol);
}
for (; i < n; i++) {
ASSERT3S(used[i], >=, rr->rr_firstdatacol);
}
/*
* First initialize the storage where we'll compute the inverse rows.
*/
for (i = 0; i < nmissing; i++) {
for (j = 0; j < n; j++) {
invrows[i][j] = (i == j) ? 1 : 0;
}
}
/*
* Subtract all trivial rows from the rows of consequence.
*/
for (i = 0; i < nmissing; i++) {
for (j = nmissing; j < n; j++) {
ASSERT3U(used[j], >=, rr->rr_firstdatacol);
jj = used[j] - rr->rr_firstdatacol;
ASSERT3S(jj, <, n);
invrows[i][j] = rows[i][jj];
rows[i][jj] = 0;
}
}
/*
* For each of the rows of interest, we must normalize it and subtract
* a multiple of it from the other rows.
*/
for (i = 0; i < nmissing; i++) {
for (j = 0; j < missing[i]; j++) {
ASSERT0(rows[i][j]);
}
ASSERT3U(rows[i][missing[i]], !=, 0);
/*
* Compute the inverse of the first element and multiply each
* element in the row by that value.
*/
log = 255 - vdev_raidz_log2[rows[i][missing[i]]];
for (j = 0; j < n; j++) {
rows[i][j] = vdev_raidz_exp2(rows[i][j], log);
invrows[i][j] = vdev_raidz_exp2(invrows[i][j], log);
}
for (ii = 0; ii < nmissing; ii++) {
if (i == ii)
continue;
ASSERT3U(rows[ii][missing[i]], !=, 0);
log = vdev_raidz_log2[rows[ii][missing[i]]];
for (j = 0; j < n; j++) {
rows[ii][j] ^=
vdev_raidz_exp2(rows[i][j], log);
invrows[ii][j] ^=
vdev_raidz_exp2(invrows[i][j], log);
}
}
}
/*
* Verify that the data that is left in the rows are properly part of
* an identity matrix.
*/
for (i = 0; i < nmissing; i++) {
for (j = 0; j < n; j++) {
if (j == missing[i]) {
ASSERT3U(rows[i][j], ==, 1);
} else {
ASSERT0(rows[i][j]);
}
}
}
}
static void
vdev_raidz_matrix_reconstruct(raidz_row_t *rr, int n, int nmissing,
int *missing, uint8_t **invrows, const uint8_t *used)
{
int i, j, x, cc, c;
uint8_t *src;
uint64_t ccount;
uint8_t *dst[VDEV_RAIDZ_MAXPARITY] = { NULL };
uint64_t dcount[VDEV_RAIDZ_MAXPARITY] = { 0 };
uint8_t log = 0;
uint8_t val;
int ll;
uint8_t *invlog[VDEV_RAIDZ_MAXPARITY];
uint8_t *p, *pp;
size_t psize;
psize = sizeof (invlog[0][0]) * n * nmissing;
p = kmem_alloc(psize, KM_SLEEP);
for (pp = p, i = 0; i < nmissing; i++) {
invlog[i] = pp;
pp += n;
}
for (i = 0; i < nmissing; i++) {
for (j = 0; j < n; j++) {
ASSERT3U(invrows[i][j], !=, 0);
invlog[i][j] = vdev_raidz_log2[invrows[i][j]];
}
}
for (i = 0; i < n; i++) {
c = used[i];
ASSERT3U(c, <, rr->rr_cols);
ccount = rr->rr_col[c].rc_size;
ASSERT(ccount >= rr->rr_col[missing[0]].rc_size || i > 0);
if (ccount == 0)
continue;
src = abd_to_buf(rr->rr_col[c].rc_abd);
for (j = 0; j < nmissing; j++) {
cc = missing[j] + rr->rr_firstdatacol;
ASSERT3U(cc, >=, rr->rr_firstdatacol);
ASSERT3U(cc, <, rr->rr_cols);
ASSERT3U(cc, !=, c);
dcount[j] = rr->rr_col[cc].rc_size;
if (dcount[j] != 0)
dst[j] = abd_to_buf(rr->rr_col[cc].rc_abd);
}
for (x = 0; x < ccount; x++, src++) {
if (*src != 0)
log = vdev_raidz_log2[*src];
for (cc = 0; cc < nmissing; cc++) {
if (x >= dcount[cc])
continue;
if (*src == 0) {
val = 0;
} else {
if ((ll = log + invlog[cc][i]) >= 255)
ll -= 255;
val = vdev_raidz_pow2[ll];
}
if (i == 0)
dst[cc][x] = val;
else
dst[cc][x] ^= val;
}
}
}
kmem_free(p, psize);
}
static void
vdev_raidz_reconstruct_general(raidz_row_t *rr, int *tgts, int ntgts)
{
int n, i, c, t, tt;
int nmissing_rows;
int missing_rows[VDEV_RAIDZ_MAXPARITY];
int parity_map[VDEV_RAIDZ_MAXPARITY];
uint8_t *p, *pp;
size_t psize;
uint8_t *rows[VDEV_RAIDZ_MAXPARITY];
uint8_t *invrows[VDEV_RAIDZ_MAXPARITY];
uint8_t *used;
abd_t **bufs = NULL;
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT)
zfs_dbgmsg("reconstruct_general(rm=%px ntgts=%u)", rr, ntgts);
/*
* Matrix reconstruction can't use scatter ABDs yet, so we allocate
* temporary linear ABDs if any non-linear ABDs are found.
*/
for (i = rr->rr_firstdatacol; i < rr->rr_cols; i++) {
ASSERT(rr->rr_col[i].rc_abd != NULL);
if (!abd_is_linear(rr->rr_col[i].rc_abd)) {
bufs = kmem_alloc(rr->rr_cols * sizeof (abd_t *),
KM_PUSHPAGE);
for (c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
raidz_col_t *col = &rr->rr_col[c];
bufs[c] = col->rc_abd;
if (bufs[c] != NULL) {
col->rc_abd = abd_alloc_linear(
col->rc_size, B_TRUE);
abd_copy(col->rc_abd, bufs[c],
col->rc_size);
}
}
break;
}
}
n = rr->rr_cols - rr->rr_firstdatacol;
/*
* Figure out which data columns are missing.
*/
nmissing_rows = 0;
for (t = 0; t < ntgts; t++) {
if (tgts[t] >= rr->rr_firstdatacol) {
missing_rows[nmissing_rows++] =
tgts[t] - rr->rr_firstdatacol;
}
}
/*
* Figure out which parity columns to use to help generate the missing
* data columns.
*/
for (tt = 0, c = 0, i = 0; i < nmissing_rows; c++) {
ASSERT(tt < ntgts);
ASSERT(c < rr->rr_firstdatacol);
/*
* Skip any targeted parity columns.
*/
if (c == tgts[tt]) {
tt++;
continue;
}
parity_map[i] = c;
i++;
}
psize = (sizeof (rows[0][0]) + sizeof (invrows[0][0])) *
nmissing_rows * n + sizeof (used[0]) * n;
p = kmem_alloc(psize, KM_SLEEP);
for (pp = p, i = 0; i < nmissing_rows; i++) {
rows[i] = pp;
pp += n;
invrows[i] = pp;
pp += n;
}
used = pp;
for (i = 0; i < nmissing_rows; i++) {
used[i] = parity_map[i];
}
for (tt = 0, c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
if (tt < nmissing_rows &&
c == missing_rows[tt] + rr->rr_firstdatacol) {
tt++;
continue;
}
ASSERT3S(i, <, n);
used[i] = c;
i++;
}
/*
* Initialize the interesting rows of the matrix.
*/
vdev_raidz_matrix_init(rr, n, nmissing_rows, parity_map, rows);
/*
* Invert the matrix.
*/
vdev_raidz_matrix_invert(rr, n, nmissing_rows, missing_rows, rows,
invrows, used);
/*
* Reconstruct the missing data using the generated matrix.
*/
vdev_raidz_matrix_reconstruct(rr, n, nmissing_rows, missing_rows,
invrows, used);
kmem_free(p, psize);
/*
* copy back from temporary linear abds and free them
*/
if (bufs) {
for (c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
raidz_col_t *col = &rr->rr_col[c];
if (bufs[c] != NULL) {
abd_copy(bufs[c], col->rc_abd, col->rc_size);
abd_free(col->rc_abd);
}
col->rc_abd = bufs[c];
}
kmem_free(bufs, rr->rr_cols * sizeof (abd_t *));
}
}
static void
vdev_raidz_reconstruct_row(raidz_map_t *rm, raidz_row_t *rr,
const int *t, int nt)
{
int tgts[VDEV_RAIDZ_MAXPARITY], *dt;
int ntgts;
int i, c, ret;
int nbadparity, nbaddata;
int parity_valid[VDEV_RAIDZ_MAXPARITY];
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT) {
zfs_dbgmsg("reconstruct(rm=%px nt=%u cols=%u md=%u mp=%u)",
rr, nt, (int)rr->rr_cols, (int)rr->rr_missingdata,
(int)rr->rr_missingparity);
}
nbadparity = rr->rr_firstdatacol;
nbaddata = rr->rr_cols - nbadparity;
ntgts = 0;
for (i = 0, c = 0; c < rr->rr_cols; c++) {
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT) {
zfs_dbgmsg("reconstruct(rm=%px col=%u devid=%u "
"offset=%llx error=%u)",
rr, c, (int)rr->rr_col[c].rc_devidx,
(long long)rr->rr_col[c].rc_offset,
(int)rr->rr_col[c].rc_error);
}
if (c < rr->rr_firstdatacol)
parity_valid[c] = B_FALSE;
if (i < nt && c == t[i]) {
tgts[ntgts++] = c;
i++;
} else if (rr->rr_col[c].rc_error != 0) {
tgts[ntgts++] = c;
} else if (c >= rr->rr_firstdatacol) {
nbaddata--;
} else {
parity_valid[c] = B_TRUE;
nbadparity--;
}
}
ASSERT(ntgts >= nt);
ASSERT(nbaddata >= 0);
ASSERT(nbaddata + nbadparity == ntgts);
dt = &tgts[nbadparity];
/* Reconstruct using the new math implementation */
ret = vdev_raidz_math_reconstruct(rm, rr, parity_valid, dt, nbaddata);
if (ret != RAIDZ_ORIGINAL_IMPL)
return;
/*
* See if we can use any of our optimized reconstruction routines.
*/
switch (nbaddata) {
case 1:
if (parity_valid[VDEV_RAIDZ_P]) {
vdev_raidz_reconstruct_p(rr, dt, 1);
return;
}
ASSERT(rr->rr_firstdatacol > 1);
if (parity_valid[VDEV_RAIDZ_Q]) {
vdev_raidz_reconstruct_q(rr, dt, 1);
return;
}
ASSERT(rr->rr_firstdatacol > 2);
break;
case 2:
ASSERT(rr->rr_firstdatacol > 1);
if (parity_valid[VDEV_RAIDZ_P] &&
parity_valid[VDEV_RAIDZ_Q]) {
vdev_raidz_reconstruct_pq(rr, dt, 2);
return;
}
ASSERT(rr->rr_firstdatacol > 2);
break;
}
vdev_raidz_reconstruct_general(rr, tgts, ntgts);
}
static int
vdev_raidz_open(vdev_t *vd, uint64_t *asize, uint64_t *max_asize,
uint64_t *logical_ashift, uint64_t *physical_ashift)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
uint64_t nparity = vdrz->vd_nparity;
int c;
int lasterror = 0;
int numerrors = 0;
ASSERT(nparity > 0);
if (nparity > VDEV_RAIDZ_MAXPARITY ||
vd->vdev_children < nparity + 1) {
vd->vdev_stat.vs_aux = VDEV_AUX_BAD_LABEL;
return (SET_ERROR(EINVAL));
}
vdev_open_children(vd);
for (c = 0; c < vd->vdev_children; c++) {
vdev_t *cvd = vd->vdev_child[c];
if (cvd->vdev_open_error != 0) {
lasterror = cvd->vdev_open_error;
numerrors++;
continue;
}
*asize = MIN(*asize - 1, cvd->vdev_asize - 1) + 1;
*max_asize = MIN(*max_asize - 1, cvd->vdev_max_asize - 1) + 1;
*logical_ashift = MAX(*logical_ashift, cvd->vdev_ashift);
}
for (c = 0; c < vd->vdev_children; c++) {
vdev_t *cvd = vd->vdev_child[c];
if (cvd->vdev_open_error != 0)
continue;
*physical_ashift = vdev_best_ashift(*logical_ashift,
*physical_ashift, cvd->vdev_physical_ashift);
}
if (vd->vdev_rz_expanding) {
*asize *= vd->vdev_children - 1;
*max_asize *= vd->vdev_children - 1;
vd->vdev_min_asize = *asize;
} else {
*asize *= vd->vdev_children;
*max_asize *= vd->vdev_children;
}
if (numerrors > nparity) {
vd->vdev_stat.vs_aux = VDEV_AUX_NO_REPLICAS;
return (lasterror);
}
return (0);
}
static void
vdev_raidz_close(vdev_t *vd)
{
for (int c = 0; c < vd->vdev_children; c++) {
if (vd->vdev_child[c] != NULL)
vdev_close(vd->vdev_child[c]);
}
}
/*
* Return the logical width to use, given the txg in which the allocation
* happened. Note that BP_GET_BIRTH() is usually the txg in which the
* BP was allocated. Remapped BP's (that were relocated due to device
* removal, see remap_blkptr_cb()), will have a more recent physical birth
* which reflects when the BP was relocated, but we can ignore these because
* they can't be on RAIDZ (device removal doesn't support RAIDZ).
*/
static uint64_t
vdev_raidz_get_logical_width(vdev_raidz_t *vdrz, uint64_t txg)
{
reflow_node_t lookup = {
.re_txg = txg,
};
avl_index_t where;
uint64_t width;
mutex_enter(&vdrz->vd_expand_lock);
reflow_node_t *re = avl_find(&vdrz->vd_expand_txgs, &lookup, &where);
if (re != NULL) {
width = re->re_logical_width;
} else {
re = avl_nearest(&vdrz->vd_expand_txgs, where, AVL_BEFORE);
if (re != NULL)
width = re->re_logical_width;
else
width = vdrz->vd_original_width;
}
mutex_exit(&vdrz->vd_expand_lock);
return (width);
}
/*
* Note: If the RAIDZ vdev has been expanded, older BP's may have allocated
* more space due to the lower data-to-parity ratio. In this case it's
* important to pass in the correct txg. Note that vdev_gang_header_asize()
* relies on a constant asize for psize=SPA_GANGBLOCKSIZE=SPA_MINBLOCKSIZE,
* regardless of txg. This is assured because for a single data sector, we
* allocate P+1 sectors regardless of width ("cols", which is at least P+1).
*/
static uint64_t
vdev_raidz_asize(vdev_t *vd, uint64_t psize, uint64_t txg)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
uint64_t asize;
uint64_t ashift = vd->vdev_top->vdev_ashift;
uint64_t cols = vdrz->vd_original_width;
uint64_t nparity = vdrz->vd_nparity;
cols = vdev_raidz_get_logical_width(vdrz, txg);
asize = ((psize - 1) >> ashift) + 1;
asize += nparity * ((asize + cols - nparity - 1) / (cols - nparity));
asize = roundup(asize, nparity + 1) << ashift;
#ifdef ZFS_DEBUG
uint64_t asize_new = ((psize - 1) >> ashift) + 1;
uint64_t ncols_new = vdrz->vd_physical_width;
asize_new += nparity * ((asize_new + ncols_new - nparity - 1) /
(ncols_new - nparity));
asize_new = roundup(asize_new, nparity + 1) << ashift;
VERIFY3U(asize_new, <=, asize);
#endif
return (asize);
}
/*
* The allocatable space for a raidz vdev is N * sizeof(smallest child)
* so each child must provide at least 1/Nth of its asize.
*/
static uint64_t
vdev_raidz_min_asize(vdev_t *vd)
{
return ((vd->vdev_min_asize + vd->vdev_children - 1) /
vd->vdev_children);
}
void
vdev_raidz_child_done(zio_t *zio)
{
raidz_col_t *rc = zio->io_private;
ASSERT3P(rc->rc_abd, !=, NULL);
rc->rc_error = zio->io_error;
rc->rc_tried = 1;
rc->rc_skipped = 0;
}
static void
vdev_raidz_shadow_child_done(zio_t *zio)
{
raidz_col_t *rc = zio->io_private;
rc->rc_shadow_error = zio->io_error;
}
static void
vdev_raidz_io_verify(zio_t *zio, raidz_map_t *rm, raidz_row_t *rr, int col)
{
(void) rm;
#ifdef ZFS_DEBUG
range_seg64_t logical_rs, physical_rs, remain_rs;
logical_rs.rs_start = rr->rr_offset;
logical_rs.rs_end = logical_rs.rs_start +
vdev_raidz_asize(zio->io_vd, rr->rr_size,
BP_GET_BIRTH(zio->io_bp));
raidz_col_t *rc = &rr->rr_col[col];
vdev_t *cvd = zio->io_vd->vdev_child[rc->rc_devidx];
vdev_xlate(cvd, &logical_rs, &physical_rs, &remain_rs);
ASSERT(vdev_xlate_is_empty(&remain_rs));
if (vdev_xlate_is_empty(&physical_rs)) {
/*
* If we are in the middle of expansion, the
* physical->logical mapping is changing so vdev_xlate()
* can't give us a reliable answer.
*/
return;
}
ASSERT3U(rc->rc_offset, ==, physical_rs.rs_start);
ASSERT3U(rc->rc_offset, <, physical_rs.rs_end);
/*
* It would be nice to assert that rs_end is equal
* to rc_offset + rc_size but there might be an
* optional I/O at the end that is not accounted in
* rc_size.
*/
if (physical_rs.rs_end > rc->rc_offset + rc->rc_size) {
ASSERT3U(physical_rs.rs_end, ==, rc->rc_offset +
rc->rc_size + (1 << zio->io_vd->vdev_top->vdev_ashift));
} else {
ASSERT3U(physical_rs.rs_end, ==, rc->rc_offset + rc->rc_size);
}
#endif
}
static void
vdev_raidz_io_start_write(zio_t *zio, raidz_row_t *rr)
{
vdev_t *vd = zio->io_vd;
raidz_map_t *rm = zio->io_vsd;
vdev_raidz_generate_parity_row(rm, rr);
for (int c = 0; c < rr->rr_scols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
vdev_t *cvd = vd->vdev_child[rc->rc_devidx];
/* Verify physical to logical translation */
vdev_raidz_io_verify(zio, rm, rr, c);
if (rc->rc_size == 0)
continue;
ASSERT3U(rc->rc_offset + rc->rc_size, <,
cvd->vdev_psize - VDEV_LABEL_END_SIZE);
ASSERT3P(rc->rc_abd, !=, NULL);
zio_nowait(zio_vdev_child_io(zio, NULL, cvd,
rc->rc_offset, rc->rc_abd,
abd_get_size(rc->rc_abd), zio->io_type,
zio->io_priority, 0, vdev_raidz_child_done, rc));
if (rc->rc_shadow_devidx != INT_MAX) {
vdev_t *cvd2 = vd->vdev_child[rc->rc_shadow_devidx];
ASSERT3U(
rc->rc_shadow_offset + abd_get_size(rc->rc_abd), <,
cvd2->vdev_psize - VDEV_LABEL_END_SIZE);
zio_nowait(zio_vdev_child_io(zio, NULL, cvd2,
rc->rc_shadow_offset, rc->rc_abd,
abd_get_size(rc->rc_abd),
zio->io_type, zio->io_priority, 0,
vdev_raidz_shadow_child_done, rc));
}
}
}
/*
* Generate optional I/Os for skip sectors to improve aggregation contiguity.
* This only works for vdev_raidz_map_alloc() (not _expanded()).
*/
static void
raidz_start_skip_writes(zio_t *zio)
{
vdev_t *vd = zio->io_vd;
uint64_t ashift = vd->vdev_top->vdev_ashift;
raidz_map_t *rm = zio->io_vsd;
ASSERT3U(rm->rm_nrows, ==, 1);
raidz_row_t *rr = rm->rm_row[0];
for (int c = 0; c < rr->rr_scols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
vdev_t *cvd = vd->vdev_child[rc->rc_devidx];
if (rc->rc_size != 0)
continue;
ASSERT3P(rc->rc_abd, ==, NULL);
ASSERT3U(rc->rc_offset, <,
cvd->vdev_psize - VDEV_LABEL_END_SIZE);
zio_nowait(zio_vdev_child_io(zio, NULL, cvd, rc->rc_offset,
NULL, 1ULL << ashift, zio->io_type, zio->io_priority,
ZIO_FLAG_NODATA | ZIO_FLAG_OPTIONAL, NULL, NULL));
}
}
static void
vdev_raidz_io_start_read_row(zio_t *zio, raidz_row_t *rr, boolean_t forceparity)
{
vdev_t *vd = zio->io_vd;
/*
* Iterate over the columns in reverse order so that we hit the parity
* last -- any errors along the way will force us to read the parity.
*/
for (int c = rr->rr_cols - 1; c >= 0; c--) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_size == 0)
continue;
vdev_t *cvd = vd->vdev_child[rc->rc_devidx];
if (!vdev_readable(cvd)) {
if (c >= rr->rr_firstdatacol)
rr->rr_missingdata++;
else
rr->rr_missingparity++;
rc->rc_error = SET_ERROR(ENXIO);
rc->rc_tried = 1; /* don't even try */
rc->rc_skipped = 1;
continue;
}
if (vdev_dtl_contains(cvd, DTL_MISSING, zio->io_txg, 1)) {
if (c >= rr->rr_firstdatacol)
rr->rr_missingdata++;
else
rr->rr_missingparity++;
rc->rc_error = SET_ERROR(ESTALE);
rc->rc_skipped = 1;
continue;
}
if (forceparity ||
c >= rr->rr_firstdatacol || rr->rr_missingdata > 0 ||
(zio->io_flags & (ZIO_FLAG_SCRUB | ZIO_FLAG_RESILVER))) {
zio_nowait(zio_vdev_child_io(zio, NULL, cvd,
rc->rc_offset, rc->rc_abd, rc->rc_size,
zio->io_type, zio->io_priority, 0,
vdev_raidz_child_done, rc));
}
}
}
static void
vdev_raidz_io_start_read_phys_cols(zio_t *zio, raidz_map_t *rm)
{
vdev_t *vd = zio->io_vd;
for (int i = 0; i < rm->rm_nphys_cols; i++) {
raidz_col_t *prc = &rm->rm_phys_col[i];
if (prc->rc_size == 0)
continue;
ASSERT3U(prc->rc_devidx, ==, i);
vdev_t *cvd = vd->vdev_child[i];
if (!vdev_readable(cvd)) {
prc->rc_error = SET_ERROR(ENXIO);
prc->rc_tried = 1; /* don't even try */
prc->rc_skipped = 1;
continue;
}
if (vdev_dtl_contains(cvd, DTL_MISSING, zio->io_txg, 1)) {
prc->rc_error = SET_ERROR(ESTALE);
prc->rc_skipped = 1;
continue;
}
zio_nowait(zio_vdev_child_io(zio, NULL, cvd,
prc->rc_offset, prc->rc_abd, prc->rc_size,
zio->io_type, zio->io_priority, 0,
vdev_raidz_child_done, prc));
}
}
static void
vdev_raidz_io_start_read(zio_t *zio, raidz_map_t *rm)
{
/*
* If there are multiple rows, we will be hitting
* all disks, so go ahead and read the parity so
* that we are reading in decent size chunks.
*/
boolean_t forceparity = rm->rm_nrows > 1;
if (rm->rm_phys_col) {
vdev_raidz_io_start_read_phys_cols(zio, rm);
} else {
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
vdev_raidz_io_start_read_row(zio, rr, forceparity);
}
}
}
/*
* Start an IO operation on a RAIDZ VDev
*
* Outline:
* - For write operations:
* 1. Generate the parity data
* 2. Create child zio write operations to each column's vdev, for both
* data and parity.
* 3. If the column skips any sectors for padding, create optional dummy
* write zio children for those areas to improve aggregation continuity.
* - For read operations:
* 1. Create child zio read operations to each data column's vdev to read
* the range of data required for zio.
* 2. If this is a scrub or resilver operation, or if any of the data
* vdevs have had errors, then create zio read operations to the parity
* columns' VDevs as well.
*/
static void
vdev_raidz_io_start(zio_t *zio)
{
vdev_t *vd = zio->io_vd;
vdev_t *tvd = vd->vdev_top;
vdev_raidz_t *vdrz = vd->vdev_tsd;
raidz_map_t *rm;
uint64_t logical_width = vdev_raidz_get_logical_width(vdrz,
BP_GET_BIRTH(zio->io_bp));
if (logical_width != vdrz->vd_physical_width) {
zfs_locked_range_t *lr = NULL;
uint64_t synced_offset = UINT64_MAX;
uint64_t next_offset = UINT64_MAX;
boolean_t use_scratch = B_FALSE;
/*
* Note: when the expansion is completing, we set
* vre_state=DSS_FINISHED (in raidz_reflow_complete_sync())
* in a later txg than when we last update spa_ubsync's state
* (see the end of spa_raidz_expand_thread()). Therefore we
* may see vre_state!=SCANNING before
* VDEV_TOP_ZAP_RAIDZ_EXPAND_STATE=DSS_FINISHED is reflected
* on disk, but the copying progress has been synced to disk
* (and reflected in spa_ubsync). In this case it's fine to
* treat the expansion as completed, since if we crash there's
* no additional copying to do.
*/
if (vdrz->vn_vre.vre_state == DSS_SCANNING) {
ASSERT3P(vd->vdev_spa->spa_raidz_expand, ==,
&vdrz->vn_vre);
lr = zfs_rangelock_enter(&vdrz->vn_vre.vre_rangelock,
zio->io_offset, zio->io_size, RL_READER);
use_scratch =
(RRSS_GET_STATE(&vd->vdev_spa->spa_ubsync) ==
RRSS_SCRATCH_VALID);
synced_offset =
RRSS_GET_OFFSET(&vd->vdev_spa->spa_ubsync);
next_offset = vdrz->vn_vre.vre_offset;
/*
* If we haven't resumed expanding since importing the
* pool, vre_offset won't have been set yet. In
* this case the next offset to be copied is the same
* as what was synced.
*/
if (next_offset == UINT64_MAX) {
next_offset = synced_offset;
}
}
if (use_scratch) {
zfs_dbgmsg("zio=%px %s io_offset=%llu offset_synced="
"%lld next_offset=%lld use_scratch=%u",
zio,
zio->io_type == ZIO_TYPE_WRITE ? "WRITE" : "READ",
(long long)zio->io_offset,
(long long)synced_offset,
(long long)next_offset,
use_scratch);
}
rm = vdev_raidz_map_alloc_expanded(zio,
tvd->vdev_ashift, vdrz->vd_physical_width,
logical_width, vdrz->vd_nparity,
synced_offset, next_offset, use_scratch);
rm->rm_lr = lr;
} else {
rm = vdev_raidz_map_alloc(zio,
tvd->vdev_ashift, logical_width, vdrz->vd_nparity);
}
rm->rm_original_width = vdrz->vd_original_width;
zio->io_vsd = rm;
zio->io_vsd_ops = &vdev_raidz_vsd_ops;
if (zio->io_type == ZIO_TYPE_WRITE) {
for (int i = 0; i < rm->rm_nrows; i++) {
vdev_raidz_io_start_write(zio, rm->rm_row[i]);
}
if (logical_width == vdrz->vd_physical_width) {
raidz_start_skip_writes(zio);
}
} else {
ASSERT(zio->io_type == ZIO_TYPE_READ);
vdev_raidz_io_start_read(zio, rm);
}
zio_execute(zio);
}
/*
* Report a checksum error for a child of a RAID-Z device.
*/
void
vdev_raidz_checksum_error(zio_t *zio, raidz_col_t *rc, abd_t *bad_data)
{
vdev_t *vd = zio->io_vd->vdev_child[rc->rc_devidx];
if (!(zio->io_flags & ZIO_FLAG_SPECULATIVE) &&
zio->io_priority != ZIO_PRIORITY_REBUILD) {
zio_bad_cksum_t zbc;
raidz_map_t *rm = zio->io_vsd;
zbc.zbc_has_cksum = 0;
zbc.zbc_injected = rm->rm_ecksuminjected;
mutex_enter(&vd->vdev_stat_lock);
vd->vdev_stat.vs_checksum_errors++;
mutex_exit(&vd->vdev_stat_lock);
(void) zfs_ereport_post_checksum(zio->io_spa, vd,
&zio->io_bookmark, zio, rc->rc_offset, rc->rc_size,
rc->rc_abd, bad_data, &zbc);
}
}
/*
* We keep track of whether or not there were any injected errors, so that
* any ereports we generate can note it.
*/
static int
raidz_checksum_verify(zio_t *zio)
{
zio_bad_cksum_t zbc = {0};
raidz_map_t *rm = zio->io_vsd;
int ret = zio_checksum_error(zio, &zbc);
if (ret != 0 && zbc.zbc_injected != 0)
rm->rm_ecksuminjected = 1;
return (ret);
}
/*
* Generate the parity from the data columns. If we tried and were able to
* read the parity without error, verify that the generated parity matches the
* data we read. If it doesn't, we fire off a checksum error. Return the
* number of such failures.
*/
static int
raidz_parity_verify(zio_t *zio, raidz_row_t *rr)
{
abd_t *orig[VDEV_RAIDZ_MAXPARITY];
int c, ret = 0;
raidz_map_t *rm = zio->io_vsd;
raidz_col_t *rc;
blkptr_t *bp = zio->io_bp;
enum zio_checksum checksum = (bp == NULL ? zio->io_prop.zp_checksum :
(BP_IS_GANG(bp) ? ZIO_CHECKSUM_GANG_HEADER : BP_GET_CHECKSUM(bp)));
if (checksum == ZIO_CHECKSUM_NOPARITY)
return (ret);
for (c = 0; c < rr->rr_firstdatacol; c++) {
rc = &rr->rr_col[c];
if (!rc->rc_tried || rc->rc_error != 0)
continue;
orig[c] = rc->rc_abd;
ASSERT3U(abd_get_size(rc->rc_abd), ==, rc->rc_size);
rc->rc_abd = abd_alloc_linear(rc->rc_size, B_FALSE);
}
/*
* Verify any empty sectors are zero filled to ensure the parity
* is calculated correctly even if these non-data sectors are damaged.
*/
if (rr->rr_nempty && rr->rr_abd_empty != NULL)
ret += vdev_draid_map_verify_empty(zio, rr);
/*
* Regenerates parity even for !tried||rc_error!=0 columns. This
* isn't harmful but it does have the side effect of fixing stuff
* we didn't realize was necessary (i.e. even if we return 0).
*/
vdev_raidz_generate_parity_row(rm, rr);
for (c = 0; c < rr->rr_firstdatacol; c++) {
rc = &rr->rr_col[c];
if (!rc->rc_tried || rc->rc_error != 0)
continue;
if (abd_cmp(orig[c], rc->rc_abd) != 0) {
zfs_dbgmsg("found error on col=%u devidx=%u off %llx",
c, (int)rc->rc_devidx, (u_longlong_t)rc->rc_offset);
vdev_raidz_checksum_error(zio, rc, orig[c]);
rc->rc_error = SET_ERROR(ECKSUM);
ret++;
}
abd_free(orig[c]);
}
return (ret);
}
static int
vdev_raidz_worst_error(raidz_row_t *rr)
{
int error = 0;
for (int c = 0; c < rr->rr_cols; c++) {
error = zio_worst_error(error, rr->rr_col[c].rc_error);
error = zio_worst_error(error, rr->rr_col[c].rc_shadow_error);
}
return (error);
}
static void
vdev_raidz_io_done_verified(zio_t *zio, raidz_row_t *rr)
{
int unexpected_errors = 0;
int parity_errors = 0;
int parity_untried = 0;
int data_errors = 0;
ASSERT3U(zio->io_type, ==, ZIO_TYPE_READ);
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_error) {
if (c < rr->rr_firstdatacol)
parity_errors++;
else
data_errors++;
if (!rc->rc_skipped)
unexpected_errors++;
} else if (c < rr->rr_firstdatacol && !rc->rc_tried) {
parity_untried++;
}
if (rc->rc_force_repair)
unexpected_errors++;
}
/*
* If we read more parity disks than were used for
* reconstruction, confirm that the other parity disks produced
* correct data.
*
* Note that we also regenerate parity when resilvering so we
* can write it out to failed devices later.
*/
if (parity_errors + parity_untried <
rr->rr_firstdatacol - data_errors ||
(zio->io_flags & ZIO_FLAG_RESILVER)) {
int n = raidz_parity_verify(zio, rr);
unexpected_errors += n;
}
if (zio->io_error == 0 && spa_writeable(zio->io_spa) &&
(unexpected_errors > 0 || (zio->io_flags & ZIO_FLAG_RESILVER))) {
/*
* Use the good data we have in hand to repair damaged children.
*/
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
vdev_t *vd = zio->io_vd;
vdev_t *cvd = vd->vdev_child[rc->rc_devidx];
if (!rc->rc_allow_repair) {
continue;
} else if (!rc->rc_force_repair &&
(rc->rc_error == 0 || rc->rc_size == 0)) {
continue;
}
zfs_dbgmsg("zio=%px repairing c=%u devidx=%u "
"offset=%llx",
zio, c, rc->rc_devidx, (long long)rc->rc_offset);
zio_nowait(zio_vdev_child_io(zio, NULL, cvd,
rc->rc_offset, rc->rc_abd, rc->rc_size,
ZIO_TYPE_WRITE,
zio->io_priority == ZIO_PRIORITY_REBUILD ?
ZIO_PRIORITY_REBUILD : ZIO_PRIORITY_ASYNC_WRITE,
ZIO_FLAG_IO_REPAIR | (unexpected_errors ?
ZIO_FLAG_SELF_HEAL : 0), NULL, NULL));
}
}
/*
* Scrub or resilver i/o's: overwrite any shadow locations with the
* good data. This ensures that if we've already copied this sector,
* it will be corrected if it was damaged. This writes more than is
* necessary, but since expansion is paused during scrub/resilver, at
* most a single row will have a shadow location.
*/
if (zio->io_error == 0 && spa_writeable(zio->io_spa) &&
(zio->io_flags & (ZIO_FLAG_RESILVER | ZIO_FLAG_SCRUB))) {
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
vdev_t *vd = zio->io_vd;
if (rc->rc_shadow_devidx == INT_MAX || rc->rc_size == 0)
continue;
vdev_t *cvd = vd->vdev_child[rc->rc_shadow_devidx];
/*
* Note: We don't want to update the repair stats
* because that would incorrectly indicate that there
* was bad data to repair, which we aren't sure about.
* By clearing the SCAN_THREAD flag, we prevent this
* from happening, despite having the REPAIR flag set.
* We need to set SELF_HEAL so that this i/o can't be
* bypassed by zio_vdev_io_start().
*/
zio_t *cio = zio_vdev_child_io(zio, NULL, cvd,
rc->rc_shadow_offset, rc->rc_abd, rc->rc_size,
ZIO_TYPE_WRITE, ZIO_PRIORITY_ASYNC_WRITE,
ZIO_FLAG_IO_REPAIR | ZIO_FLAG_SELF_HEAL,
NULL, NULL);
cio->io_flags &= ~ZIO_FLAG_SCAN_THREAD;
zio_nowait(cio);
}
}
}
static void
raidz_restore_orig_data(raidz_map_t *rm)
{
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_need_orig_restore) {
abd_copy(rc->rc_abd,
rc->rc_orig_data, rc->rc_size);
rc->rc_need_orig_restore = B_FALSE;
}
}
}
}
/*
* During raidz_reconstruct() for expanded VDEV, we need special consideration
* failure simulations. See note in raidz_reconstruct() on simulating failure
* of a pre-expansion device.
*
* Treating logical child i as failed, return TRUE if the given column should
* be treated as failed. The idea of logical children allows us to imagine
* that a disk silently failed before a RAIDZ expansion (reads from this disk
* succeed but return the wrong data). Since the expansion doesn't verify
* checksums, the incorrect data will be moved to new locations spread among
* the children (going diagonally across them).
*
* Higher "logical child failures" (values of `i`) indicate these
* "pre-expansion failures". The first physical_width values imagine that a
* current child failed; the next physical_width-1 values imagine that a
* child failed before the most recent expansion; the next physical_width-2
* values imagine a child failed in the expansion before that, etc.
*/
static boolean_t
raidz_simulate_failure(int physical_width, int original_width, int ashift,
int i, raidz_col_t *rc)
{
uint64_t sector_id =
physical_width * (rc->rc_offset >> ashift) +
rc->rc_devidx;
for (int w = physical_width; w >= original_width; w--) {
if (i < w) {
return (sector_id % w == i);
} else {
i -= w;
}
}
ASSERT(!"invalid logical child id");
return (B_FALSE);
}
/*
* returns EINVAL if reconstruction of the block will not be possible
* returns ECKSUM if this specific reconstruction failed
* returns 0 on successful reconstruction
*/
static int
raidz_reconstruct(zio_t *zio, int *ltgts, int ntgts, int nparity)
{
raidz_map_t *rm = zio->io_vsd;
int physical_width = zio->io_vd->vdev_children;
int original_width = (rm->rm_original_width != 0) ?
rm->rm_original_width : physical_width;
int dbgmsg = zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT;
if (dbgmsg) {
zfs_dbgmsg("raidz_reconstruct_expanded(zio=%px ltgts=%u,%u,%u "
"ntgts=%u", zio, ltgts[0], ltgts[1], ltgts[2], ntgts);
}
/* Reconstruct each row */
for (int r = 0; r < rm->rm_nrows; r++) {
raidz_row_t *rr = rm->rm_row[r];
int my_tgts[VDEV_RAIDZ_MAXPARITY]; /* value is child id */
int t = 0;
int dead = 0;
int dead_data = 0;
if (dbgmsg)
zfs_dbgmsg("raidz_reconstruct_expanded(row=%u)", r);
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
ASSERT0(rc->rc_need_orig_restore);
if (rc->rc_error != 0) {
dead++;
if (c >= nparity)
dead_data++;
continue;
}
if (rc->rc_size == 0)
continue;
for (int lt = 0; lt < ntgts; lt++) {
if (raidz_simulate_failure(physical_width,
original_width,
zio->io_vd->vdev_top->vdev_ashift,
ltgts[lt], rc)) {
if (rc->rc_orig_data == NULL) {
rc->rc_orig_data =
abd_alloc_linear(
rc->rc_size, B_TRUE);
abd_copy(rc->rc_orig_data,
rc->rc_abd, rc->rc_size);
}
rc->rc_need_orig_restore = B_TRUE;
dead++;
if (c >= nparity)
dead_data++;
/*
* Note: simulating failure of a
* pre-expansion device can hit more
* than one column, in which case we
* might try to simulate more failures
* than can be reconstructed, which is
* also more than the size of my_tgts.
* This check prevents accessing past
* the end of my_tgts. The "dead >
* nparity" check below will fail this
* reconstruction attempt.
*/
if (t < VDEV_RAIDZ_MAXPARITY) {
my_tgts[t++] = c;
if (dbgmsg) {
zfs_dbgmsg("simulating "
"failure of col %u "
"devidx %u", c,
(int)rc->rc_devidx);
}
}
break;
}
}
}
if (dead > nparity) {
/* reconstruction not possible */
if (dbgmsg) {
zfs_dbgmsg("reconstruction not possible; "
"too many failures");
}
raidz_restore_orig_data(rm);
return (EINVAL);
}
if (dead_data > 0)
vdev_raidz_reconstruct_row(rm, rr, my_tgts, t);
}
/* Check for success */
if (raidz_checksum_verify(zio) == 0) {
/* Reconstruction succeeded - report errors */
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_need_orig_restore) {
/*
* Note: if this is a parity column,
* we don't really know if it's wrong.
* We need to let
* vdev_raidz_io_done_verified() check
* it, and if we set rc_error, it will
* think that it is a "known" error
* that doesn't need to be checked
* or corrected.
*/
if (rc->rc_error == 0 &&
c >= rr->rr_firstdatacol) {
vdev_raidz_checksum_error(zio,
rc, rc->rc_orig_data);
rc->rc_error =
SET_ERROR(ECKSUM);
}
rc->rc_need_orig_restore = B_FALSE;
}
}
vdev_raidz_io_done_verified(zio, rr);
}
zio_checksum_verified(zio);
if (dbgmsg) {
zfs_dbgmsg("reconstruction successful "
"(checksum verified)");
}
return (0);
}
/* Reconstruction failed - restore original data */
raidz_restore_orig_data(rm);
if (dbgmsg) {
zfs_dbgmsg("raidz_reconstruct_expanded(zio=%px) checksum "
"failed", zio);
}
return (ECKSUM);
}
/*
* Iterate over all combinations of N bad vdevs and attempt a reconstruction.
* Note that the algorithm below is non-optimal because it doesn't take into
* account how reconstruction is actually performed. For example, with
* triple-parity RAID-Z the reconstruction procedure is the same if column 4
* is targeted as invalid as if columns 1 and 4 are targeted since in both
* cases we'd only use parity information in column 0.
*
* The order that we find the various possible combinations of failed
* disks is dictated by these rules:
* - Examine each "slot" (the "i" in tgts[i])
* - Try to increment this slot (tgts[i] += 1)
* - if we can't increment because it runs into the next slot,
* reset our slot to the minimum, and examine the next slot
*
* For example, with a 6-wide RAIDZ3, and no known errors (so we have to choose
* 3 columns to reconstruct), we will generate the following sequence:
*
* STATE ACTION
* 0 1 2 special case: skip since these are all parity
* 0 1 3 first slot: reset to 0; middle slot: increment to 2
* 0 2 3 first slot: increment to 1
* 1 2 3 first: reset to 0; middle: reset to 1; last: increment to 4
* 0 1 4 first: reset to 0; middle: increment to 2
* 0 2 4 first: increment to 1
* 1 2 4 first: reset to 0; middle: increment to 3
* 0 3 4 first: increment to 1
* 1 3 4 first: increment to 2
* 2 3 4 first: reset to 0; middle: reset to 1; last: increment to 5
* 0 1 5 first: reset to 0; middle: increment to 2
* 0 2 5 first: increment to 1
* 1 2 5 first: reset to 0; middle: increment to 3
* 0 3 5 first: increment to 1
* 1 3 5 first: increment to 2
* 2 3 5 first: reset to 0; middle: increment to 4
* 0 4 5 first: increment to 1
* 1 4 5 first: increment to 2
* 2 4 5 first: increment to 3
* 3 4 5 done
*
* This strategy works for dRAID but is less efficient when there are a large
* number of child vdevs and therefore permutations to check. Furthermore,
* since the raidz_map_t rows likely do not overlap, reconstruction would be
* possible as long as there are no more than nparity data errors per row.
* These additional permutations are not currently checked but could be as
* a future improvement.
*
* Returns 0 on success, ECKSUM on failure.
*/
static int
vdev_raidz_combrec(zio_t *zio)
{
int nparity = vdev_get_nparity(zio->io_vd);
raidz_map_t *rm = zio->io_vsd;
int physical_width = zio->io_vd->vdev_children;
int original_width = (rm->rm_original_width != 0) ?
rm->rm_original_width : physical_width;
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
int total_errors = 0;
for (int c = 0; c < rr->rr_cols; c++) {
if (rr->rr_col[c].rc_error)
total_errors++;
}
if (total_errors > nparity)
return (vdev_raidz_worst_error(rr));
}
for (int num_failures = 1; num_failures <= nparity; num_failures++) {
int tstore[VDEV_RAIDZ_MAXPARITY + 2];
int *ltgts = &tstore[1]; /* value is logical child ID */
/*
* Determine number of logical children, n. See comment
* above raidz_simulate_failure().
*/
int n = 0;
for (int w = physical_width;
w >= original_width; w--) {
n += w;
}
ASSERT3U(num_failures, <=, nparity);
ASSERT3U(num_failures, <=, VDEV_RAIDZ_MAXPARITY);
/* Handle corner cases in combrec logic */
ltgts[-1] = -1;
for (int i = 0; i < num_failures; i++) {
ltgts[i] = i;
}
ltgts[num_failures] = n;
for (;;) {
int err = raidz_reconstruct(zio, ltgts, num_failures,
nparity);
if (err == EINVAL) {
/*
* Reconstruction not possible with this #
* failures; try more failures.
*/
break;
} else if (err == 0)
return (0);
/* Compute next targets to try */
for (int t = 0; ; t++) {
ASSERT3U(t, <, num_failures);
ltgts[t]++;
if (ltgts[t] == n) {
/* try more failures */
ASSERT3U(t, ==, num_failures - 1);
if (zfs_flags &
ZFS_DEBUG_RAIDZ_RECONSTRUCT) {
zfs_dbgmsg("reconstruction "
"failed for num_failures="
"%u; tried all "
"combinations",
num_failures);
}
break;
}
ASSERT3U(ltgts[t], <, n);
ASSERT3U(ltgts[t], <=, ltgts[t + 1]);
/*
* If that spot is available, we're done here.
* Try the next combination.
*/
if (ltgts[t] != ltgts[t + 1])
break; // found next combination
/*
* Otherwise, reset this tgt to the minimum,
* and move on to the next tgt.
*/
ltgts[t] = ltgts[t - 1] + 1;
ASSERT3U(ltgts[t], ==, t);
}
/* Increase the number of failures and keep trying. */
if (ltgts[num_failures - 1] == n)
break;
}
}
if (zfs_flags & ZFS_DEBUG_RAIDZ_RECONSTRUCT)
zfs_dbgmsg("reconstruction failed for all num_failures");
return (ECKSUM);
}
void
vdev_raidz_reconstruct(raidz_map_t *rm, const int *t, int nt)
{
for (uint64_t row = 0; row < rm->rm_nrows; row++) {
raidz_row_t *rr = rm->rm_row[row];
vdev_raidz_reconstruct_row(rm, rr, t, nt);
}
}
/*
* Complete a write IO operation on a RAIDZ VDev
*
* Outline:
* 1. Check for errors on the child IOs.
* 2. Return, setting an error code if too few child VDevs were written
* to reconstruct the data later. Note that partial writes are
* considered successful if they can be reconstructed at all.
*/
static void
vdev_raidz_io_done_write_impl(zio_t *zio, raidz_row_t *rr)
{
int normal_errors = 0;
int shadow_errors = 0;
ASSERT3U(rr->rr_missingparity, <=, rr->rr_firstdatacol);
ASSERT3U(rr->rr_missingdata, <=, rr->rr_cols - rr->rr_firstdatacol);
ASSERT3U(zio->io_type, ==, ZIO_TYPE_WRITE);
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_error != 0) {
ASSERT(rc->rc_error != ECKSUM); /* child has no bp */
normal_errors++;
}
if (rc->rc_shadow_error != 0) {
ASSERT(rc->rc_shadow_error != ECKSUM);
shadow_errors++;
}
}
/*
* Treat partial writes as a success. If we couldn't write enough
* columns to reconstruct the data, the I/O failed. Otherwise, good
* enough. Note that in the case of a shadow write (during raidz
* expansion), depending on if we crash, either the normal (old) or
* shadow (new) location may become the "real" version of the block,
* so both locations must have sufficient redundancy.
*
* Now that we support write reallocation, it would be better
* to treat partial failure as real failure unless there are
* no non-degraded top-level vdevs left, and not update DTLs
* if we intend to reallocate.
*/
if (normal_errors > rr->rr_firstdatacol ||
shadow_errors > rr->rr_firstdatacol) {
zio->io_error = zio_worst_error(zio->io_error,
vdev_raidz_worst_error(rr));
}
}
static void
vdev_raidz_io_done_reconstruct_known_missing(zio_t *zio, raidz_map_t *rm,
raidz_row_t *rr)
{
int parity_errors = 0;
int parity_untried = 0;
int data_errors = 0;
int total_errors = 0;
ASSERT3U(rr->rr_missingparity, <=, rr->rr_firstdatacol);
ASSERT3U(rr->rr_missingdata, <=, rr->rr_cols - rr->rr_firstdatacol);
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
/*
* If scrubbing and a replacing/sparing child vdev determined
* that not all of its children have an identical copy of the
* data, then clear the error so the column is treated like
* any other read and force a repair to correct the damage.
*/
if (rc->rc_error == ECKSUM) {
ASSERT(zio->io_flags & ZIO_FLAG_SCRUB);
vdev_raidz_checksum_error(zio, rc, rc->rc_abd);
rc->rc_force_repair = 1;
rc->rc_error = 0;
}
if (rc->rc_error) {
if (c < rr->rr_firstdatacol)
parity_errors++;
else
data_errors++;
total_errors++;
} else if (c < rr->rr_firstdatacol && !rc->rc_tried) {
parity_untried++;
}
}
/*
* If there were data errors and the number of errors we saw was
* correctable -- less than or equal to the number of parity disks read
* -- reconstruct based on the missing data.
*/
if (data_errors != 0 &&
total_errors <= rr->rr_firstdatacol - parity_untried) {
/*
* We either attempt to read all the parity columns or
* none of them. If we didn't try to read parity, we
* wouldn't be here in the correctable case. There must
* also have been fewer parity errors than parity
* columns or, again, we wouldn't be in this code path.
*/
ASSERT(parity_untried == 0);
ASSERT(parity_errors < rr->rr_firstdatacol);
/*
* Identify the data columns that reported an error.
*/
int n = 0;
int tgts[VDEV_RAIDZ_MAXPARITY];
for (int c = rr->rr_firstdatacol; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_error != 0) {
ASSERT(n < VDEV_RAIDZ_MAXPARITY);
tgts[n++] = c;
}
}
ASSERT(rr->rr_firstdatacol >= n);
vdev_raidz_reconstruct_row(rm, rr, tgts, n);
}
}
/*
* Return the number of reads issued.
*/
static int
vdev_raidz_read_all(zio_t *zio, raidz_row_t *rr)
{
vdev_t *vd = zio->io_vd;
int nread = 0;
rr->rr_missingdata = 0;
rr->rr_missingparity = 0;
/*
* If this rows contains empty sectors which are not required
* for a normal read then allocate an ABD for them now so they
* may be read, verified, and any needed repairs performed.
*/
if (rr->rr_nempty != 0 && rr->rr_abd_empty == NULL)
vdev_draid_map_alloc_empty(zio, rr);
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_tried || rc->rc_size == 0)
continue;
zio_nowait(zio_vdev_child_io(zio, NULL,
vd->vdev_child[rc->rc_devidx],
rc->rc_offset, rc->rc_abd, rc->rc_size,
zio->io_type, zio->io_priority, 0,
vdev_raidz_child_done, rc));
nread++;
}
return (nread);
}
/*
* We're here because either there were too many errors to even attempt
* reconstruction (total_errors == rm_first_datacol), or vdev_*_combrec()
* failed. In either case, there is enough bad data to prevent reconstruction.
* Start checksum ereports for all children which haven't failed.
*/
static void
vdev_raidz_io_done_unrecoverable(zio_t *zio)
{
raidz_map_t *rm = zio->io_vsd;
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
vdev_t *cvd = zio->io_vd->vdev_child[rc->rc_devidx];
if (rc->rc_error != 0)
continue;
zio_bad_cksum_t zbc;
zbc.zbc_has_cksum = 0;
zbc.zbc_injected = rm->rm_ecksuminjected;
mutex_enter(&cvd->vdev_stat_lock);
cvd->vdev_stat.vs_checksum_errors++;
mutex_exit(&cvd->vdev_stat_lock);
(void) zfs_ereport_start_checksum(zio->io_spa,
cvd, &zio->io_bookmark, zio, rc->rc_offset,
rc->rc_size, &zbc);
}
}
}
void
vdev_raidz_io_done(zio_t *zio)
{
raidz_map_t *rm = zio->io_vsd;
ASSERT(zio->io_bp != NULL);
if (zio->io_type == ZIO_TYPE_WRITE) {
for (int i = 0; i < rm->rm_nrows; i++) {
vdev_raidz_io_done_write_impl(zio, rm->rm_row[i]);
}
} else {
if (rm->rm_phys_col) {
/*
* This is an aggregated read. Copy the data and status
* from the aggregate abd's to the individual rows.
*/
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
for (int c = 0; c < rr->rr_cols; c++) {
raidz_col_t *rc = &rr->rr_col[c];
if (rc->rc_tried || rc->rc_size == 0)
continue;
raidz_col_t *prc =
&rm->rm_phys_col[rc->rc_devidx];
rc->rc_error = prc->rc_error;
rc->rc_tried = prc->rc_tried;
rc->rc_skipped = prc->rc_skipped;
if (c >= rr->rr_firstdatacol) {
/*
* Note: this is slightly faster
* than using abd_copy_off().
*/
char *physbuf = abd_to_buf(
prc->rc_abd);
void *physloc = physbuf +
rc->rc_offset -
prc->rc_offset;
abd_copy_from_buf(rc->rc_abd,
physloc, rc->rc_size);
}
}
}
}
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
vdev_raidz_io_done_reconstruct_known_missing(zio,
rm, rr);
}
if (raidz_checksum_verify(zio) == 0) {
for (int i = 0; i < rm->rm_nrows; i++) {
raidz_row_t *rr = rm->rm_row[i];
vdev_raidz_io_done_verified(zio, rr);
}
zio_checksum_verified(zio);
} else {
/*
* A sequential resilver has no checksum which makes
* combinatoral reconstruction impossible. This code
* path is unreachable since raidz_checksum_verify()
* has no checksum to verify and must succeed.
*/
ASSERT3U(zio->io_priority, !=, ZIO_PRIORITY_REBUILD);
/*
* This isn't a typical situation -- either we got a
* read error or a child silently returned bad data.
* Read every block so we can try again with as much
* data and parity as we can track down. If we've
* already been through once before, all children will
* be marked as tried so we'll proceed to combinatorial
* reconstruction.
*/
int nread = 0;
for (int i = 0; i < rm->rm_nrows; i++) {
nread += vdev_raidz_read_all(zio,
rm->rm_row[i]);
}
if (nread != 0) {
/*
* Normally our stage is VDEV_IO_DONE, but if
* we've already called redone(), it will have
* changed to VDEV_IO_START, in which case we
* don't want to call redone() again.
*/
if (zio->io_stage != ZIO_STAGE_VDEV_IO_START)
zio_vdev_io_redone(zio);
return;
}
/*
* It would be too expensive to try every possible
* combination of failed sectors in every row, so
* instead we try every combination of failed current or
* past physical disk. This means that if the incorrect
* sectors were all on Nparity disks at any point in the
* past, we will find the correct data. The only known
* case where this is less durable than a non-expanded
* RAIDZ, is if we have a silent failure during
* expansion. In that case, one block could be
* partially in the old format and partially in the
* new format, so we'd lost some sectors from the old
* format and some from the new format.
*
* e.g. logical_width=4 physical_width=6
* the 15 (6+5+4) possible failed disks are:
* width=6 child=0
* width=6 child=1
* width=6 child=2
* width=6 child=3
* width=6 child=4
* width=6 child=5
* width=5 child=0
* width=5 child=1
* width=5 child=2
* width=5 child=3
* width=5 child=4
* width=4 child=0
* width=4 child=1
* width=4 child=2
* width=4 child=3
* And we will try every combination of Nparity of these
* failing.
*
* As a first pass, we can generate every combo,
* and try reconstructing, ignoring any known
* failures. If any row has too many known + simulated
* failures, then we bail on reconstructing with this
* number of simulated failures. As an improvement,
* we could detect the number of whole known failures
* (i.e. we have known failures on these disks for
* every row; the disks never succeeded), and
* subtract that from the max # failures to simulate.
* We could go even further like the current
* combrec code, but that doesn't seem like it
* gains us very much. If we simulate a failure
* that is also a known failure, that's fine.
*/
zio->io_error = vdev_raidz_combrec(zio);
if (zio->io_error == ECKSUM &&
!(zio->io_flags & ZIO_FLAG_SPECULATIVE)) {
vdev_raidz_io_done_unrecoverable(zio);
}
}
}
if (rm->rm_lr != NULL) {
zfs_rangelock_exit(rm->rm_lr);
rm->rm_lr = NULL;
}
}
static void
vdev_raidz_state_change(vdev_t *vd, int faulted, int degraded)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
if (faulted > vdrz->vd_nparity)
vdev_set_state(vd, B_FALSE, VDEV_STATE_CANT_OPEN,
VDEV_AUX_NO_REPLICAS);
else if (degraded + faulted != 0)
vdev_set_state(vd, B_FALSE, VDEV_STATE_DEGRADED, VDEV_AUX_NONE);
else
vdev_set_state(vd, B_FALSE, VDEV_STATE_HEALTHY, VDEV_AUX_NONE);
}
/*
* Determine if any portion of the provided block resides on a child vdev
* with a dirty DTL and therefore needs to be resilvered. The function
* assumes that at least one DTL is dirty which implies that full stripe
* width blocks must be resilvered.
*/
static boolean_t
vdev_raidz_need_resilver(vdev_t *vd, const dva_t *dva, size_t psize,
uint64_t phys_birth)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
/*
* If we're in the middle of a RAIDZ expansion, this block may be in
* the old and/or new location. For simplicity, always resilver it.
*/
if (vdrz->vn_vre.vre_state == DSS_SCANNING)
return (B_TRUE);
uint64_t dcols = vd->vdev_children;
uint64_t nparity = vdrz->vd_nparity;
uint64_t ashift = vd->vdev_top->vdev_ashift;
/* The starting RAIDZ (parent) vdev sector of the block. */
uint64_t b = DVA_GET_OFFSET(dva) >> ashift;
/* The zio's size in units of the vdev's minimum sector size. */
uint64_t s = ((psize - 1) >> ashift) + 1;
/* The first column for this stripe. */
uint64_t f = b % dcols;
/* Unreachable by sequential resilver. */
ASSERT3U(phys_birth, !=, TXG_UNKNOWN);
if (!vdev_dtl_contains(vd, DTL_PARTIAL, phys_birth, 1))
return (B_FALSE);
if (s + nparity >= dcols)
return (B_TRUE);
for (uint64_t c = 0; c < s + nparity; c++) {
uint64_t devidx = (f + c) % dcols;
vdev_t *cvd = vd->vdev_child[devidx];
/*
* dsl_scan_need_resilver() already checked vd with
* vdev_dtl_contains(). So here just check cvd with
* vdev_dtl_empty(), cheaper and a good approximation.
*/
if (!vdev_dtl_empty(cvd, DTL_PARTIAL))
return (B_TRUE);
}
return (B_FALSE);
}
static void
vdev_raidz_xlate(vdev_t *cvd, const range_seg64_t *logical_rs,
range_seg64_t *physical_rs, range_seg64_t *remain_rs)
{
(void) remain_rs;
vdev_t *raidvd = cvd->vdev_parent;
ASSERT(raidvd->vdev_ops == &vdev_raidz_ops);
vdev_raidz_t *vdrz = raidvd->vdev_tsd;
if (vdrz->vn_vre.vre_state == DSS_SCANNING) {
/*
* We're in the middle of expansion, in which case the
* translation is in flux. Any answer we give may be wrong
* by the time we return, so it isn't safe for the caller to
* act on it. Therefore we say that this range isn't present
* on any children. The only consumers of this are "zpool
* initialize" and trimming, both of which are "best effort"
* anyway.
*/
physical_rs->rs_start = physical_rs->rs_end = 0;
remain_rs->rs_start = remain_rs->rs_end = 0;
return;
}
uint64_t width = vdrz->vd_physical_width;
uint64_t tgt_col = cvd->vdev_id;
uint64_t ashift = raidvd->vdev_top->vdev_ashift;
/* make sure the offsets are block-aligned */
ASSERT0(logical_rs->rs_start % (1 << ashift));
ASSERT0(logical_rs->rs_end % (1 << ashift));
uint64_t b_start = logical_rs->rs_start >> ashift;
uint64_t b_end = logical_rs->rs_end >> ashift;
uint64_t start_row = 0;
if (b_start > tgt_col) /* avoid underflow */
start_row = ((b_start - tgt_col - 1) / width) + 1;
uint64_t end_row = 0;
if (b_end > tgt_col)
end_row = ((b_end - tgt_col - 1) / width) + 1;
physical_rs->rs_start = start_row << ashift;
physical_rs->rs_end = end_row << ashift;
ASSERT3U(physical_rs->rs_start, <=, logical_rs->rs_start);
ASSERT3U(physical_rs->rs_end - physical_rs->rs_start, <=,
logical_rs->rs_end - logical_rs->rs_start);
}
static void
raidz_reflow_sync(void *arg, dmu_tx_t *tx)
{
spa_t *spa = arg;
int txgoff = dmu_tx_get_txg(tx) & TXG_MASK;
vdev_raidz_expand_t *vre = spa->spa_raidz_expand;
/*
* Ensure there are no i/os to the range that is being committed.
*/
uint64_t old_offset = RRSS_GET_OFFSET(&spa->spa_uberblock);
ASSERT3U(vre->vre_offset_pertxg[txgoff], >=, old_offset);
mutex_enter(&vre->vre_lock);
uint64_t new_offset =
MIN(vre->vre_offset_pertxg[txgoff], vre->vre_failed_offset);
/*
* We should not have committed anything that failed.
*/
VERIFY3U(vre->vre_failed_offset, >=, old_offset);
mutex_exit(&vre->vre_lock);
zfs_locked_range_t *lr = zfs_rangelock_enter(&vre->vre_rangelock,
old_offset, new_offset - old_offset,
RL_WRITER);
/*
* Update the uberblock that will be written when this txg completes.
*/
RAIDZ_REFLOW_SET(&spa->spa_uberblock,
RRSS_SCRATCH_INVALID_SYNCED_REFLOW, new_offset);
vre->vre_offset_pertxg[txgoff] = 0;
zfs_rangelock_exit(lr);
mutex_enter(&vre->vre_lock);
vre->vre_bytes_copied += vre->vre_bytes_copied_pertxg[txgoff];
vre->vre_bytes_copied_pertxg[txgoff] = 0;
mutex_exit(&vre->vre_lock);
vdev_t *vd = vdev_lookup_top(spa, vre->vre_vdev_id);
VERIFY0(zap_update(spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_BYTES_COPIED,
sizeof (vre->vre_bytes_copied), 1, &vre->vre_bytes_copied, tx));
}
static void
raidz_reflow_complete_sync(void *arg, dmu_tx_t *tx)
{
spa_t *spa = arg;
vdev_raidz_expand_t *vre = spa->spa_raidz_expand;
vdev_t *raidvd = vdev_lookup_top(spa, vre->vre_vdev_id);
vdev_raidz_t *vdrz = raidvd->vdev_tsd;
for (int i = 0; i < TXG_SIZE; i++)
VERIFY0(vre->vre_offset_pertxg[i]);
reflow_node_t *re = kmem_zalloc(sizeof (*re), KM_SLEEP);
re->re_txg = tx->tx_txg + TXG_CONCURRENT_STATES;
re->re_logical_width = vdrz->vd_physical_width;
mutex_enter(&vdrz->vd_expand_lock);
avl_add(&vdrz->vd_expand_txgs, re);
mutex_exit(&vdrz->vd_expand_lock);
vdev_t *vd = vdev_lookup_top(spa, vre->vre_vdev_id);
/*
* Dirty the config so that the updated ZPOOL_CONFIG_RAIDZ_EXPAND_TXGS
* will get written (based on vd_expand_txgs).
*/
vdev_config_dirty(vd);
/*
* Before we change vre_state, the on-disk state must reflect that we
* have completed all copying, so that vdev_raidz_io_start() can use
* vre_state to determine if the reflow is in progress. See also the
* end of spa_raidz_expand_thread().
*/
VERIFY3U(RRSS_GET_OFFSET(&spa->spa_ubsync), ==,
raidvd->vdev_ms_count << raidvd->vdev_ms_shift);
vre->vre_end_time = gethrestime_sec();
vre->vre_state = DSS_FINISHED;
uint64_t state = vre->vre_state;
VERIFY0(zap_update(spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_STATE,
sizeof (state), 1, &state, tx));
uint64_t end_time = vre->vre_end_time;
VERIFY0(zap_update(spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_END_TIME,
sizeof (end_time), 1, &end_time, tx));
spa->spa_uberblock.ub_raidz_reflow_info = 0;
spa_history_log_internal(spa, "raidz vdev expansion completed", tx,
"%s vdev %llu new width %llu", spa_name(spa),
(unsigned long long)vd->vdev_id,
(unsigned long long)vd->vdev_children);
spa->spa_raidz_expand = NULL;
raidvd->vdev_rz_expanding = B_FALSE;
spa_async_request(spa, SPA_ASYNC_INITIALIZE_RESTART);
spa_async_request(spa, SPA_ASYNC_TRIM_RESTART);
spa_async_request(spa, SPA_ASYNC_AUTOTRIM_RESTART);
spa_notify_waiters(spa);
/*
* While we're in syncing context take the opportunity to
* setup a scrub. All the data has been sucessfully copied
* but we have not validated any checksums.
*/
pool_scan_func_t func = POOL_SCAN_SCRUB;
if (zfs_scrub_after_expand && dsl_scan_setup_check(&func, tx) == 0)
dsl_scan_setup_sync(&func, tx);
}
/*
* Struct for one copy zio.
*/
typedef struct raidz_reflow_arg {
vdev_raidz_expand_t *rra_vre;
zfs_locked_range_t *rra_lr;
uint64_t rra_txg;
} raidz_reflow_arg_t;
/*
* The write of the new location is done.
*/
static void
raidz_reflow_write_done(zio_t *zio)
{
raidz_reflow_arg_t *rra = zio->io_private;
vdev_raidz_expand_t *vre = rra->rra_vre;
abd_free(zio->io_abd);
mutex_enter(&vre->vre_lock);
if (zio->io_error != 0) {
/* Force a reflow pause on errors */
vre->vre_failed_offset =
MIN(vre->vre_failed_offset, rra->rra_lr->lr_offset);
}
ASSERT3U(vre->vre_outstanding_bytes, >=, zio->io_size);
vre->vre_outstanding_bytes -= zio->io_size;
if (rra->rra_lr->lr_offset + rra->rra_lr->lr_length <
vre->vre_failed_offset) {
vre->vre_bytes_copied_pertxg[rra->rra_txg & TXG_MASK] +=
zio->io_size;
}
cv_signal(&vre->vre_cv);
mutex_exit(&vre->vre_lock);
zfs_rangelock_exit(rra->rra_lr);
kmem_free(rra, sizeof (*rra));
spa_config_exit(zio->io_spa, SCL_STATE, zio->io_spa);
}
/*
* The read of the old location is done. The parent zio is the write to
* the new location. Allow it to start.
*/
static void
raidz_reflow_read_done(zio_t *zio)
{
raidz_reflow_arg_t *rra = zio->io_private;
vdev_raidz_expand_t *vre = rra->rra_vre;
/*
* If the read failed, or if it was done on a vdev that is not fully
* healthy (e.g. a child that has a resilver in progress), we may not
* have the correct data. Note that it's OK if the write proceeds.
* It may write garbage but the location is otherwise unused and we
* will retry later due to vre_failed_offset.
*/
if (zio->io_error != 0 || !vdev_dtl_empty(zio->io_vd, DTL_MISSING)) {
zfs_dbgmsg("reflow read failed off=%llu size=%llu txg=%llu "
"err=%u partial_dtl_empty=%u missing_dtl_empty=%u",
(long long)rra->rra_lr->lr_offset,
(long long)rra->rra_lr->lr_length,
(long long)rra->rra_txg,
zio->io_error,
vdev_dtl_empty(zio->io_vd, DTL_PARTIAL),
vdev_dtl_empty(zio->io_vd, DTL_MISSING));
mutex_enter(&vre->vre_lock);
/* Force a reflow pause on errors */
vre->vre_failed_offset =
MIN(vre->vre_failed_offset, rra->rra_lr->lr_offset);
mutex_exit(&vre->vre_lock);
}
zio_nowait(zio_unique_parent(zio));
}
static void
raidz_reflow_record_progress(vdev_raidz_expand_t *vre, uint64_t offset,
dmu_tx_t *tx)
{
int txgoff = dmu_tx_get_txg(tx) & TXG_MASK;
spa_t *spa = dmu_tx_pool(tx)->dp_spa;
if (offset == 0)
return;
mutex_enter(&vre->vre_lock);
ASSERT3U(vre->vre_offset, <=, offset);
vre->vre_offset = offset;
mutex_exit(&vre->vre_lock);
if (vre->vre_offset_pertxg[txgoff] == 0) {
dsl_sync_task_nowait(dmu_tx_pool(tx), raidz_reflow_sync,
spa, tx);
}
vre->vre_offset_pertxg[txgoff] = offset;
}
static boolean_t
vdev_raidz_expand_child_replacing(vdev_t *raidz_vd)
{
for (int i = 0; i < raidz_vd->vdev_children; i++) {
/* Quick check if a child is being replaced */
if (!raidz_vd->vdev_child[i]->vdev_ops->vdev_op_leaf)
return (B_TRUE);
}
return (B_FALSE);
}
static boolean_t
raidz_reflow_impl(vdev_t *vd, vdev_raidz_expand_t *vre, range_tree_t *rt,
dmu_tx_t *tx)
{
spa_t *spa = vd->vdev_spa;
int ashift = vd->vdev_top->vdev_ashift;
uint64_t offset, size;
if (!range_tree_find_in(rt, 0, vd->vdev_top->vdev_asize,
&offset, &size)) {
return (B_FALSE);
}
ASSERT(IS_P2ALIGNED(offset, 1 << ashift));
ASSERT3U(size, >=, 1 << ashift);
uint64_t length = 1 << ashift;
int txgoff = dmu_tx_get_txg(tx) & TXG_MASK;
uint64_t blkid = offset >> ashift;
int old_children = vd->vdev_children - 1;
/*
* We can only progress to the point that writes will not overlap
* with blocks whose progress has not yet been recorded on disk.
* Since partially-copied rows are still read from the old location,
* we need to stop one row before the sector-wise overlap, to prevent
* row-wise overlap.
*
* Note that even if we are skipping over a large unallocated region,
* we can't move the on-disk progress to `offset`, because concurrent
* writes/allocations could still use the currently-unallocated
* region.
*/
uint64_t ubsync_blkid =
RRSS_GET_OFFSET(&spa->spa_ubsync) >> ashift;
uint64_t next_overwrite_blkid = ubsync_blkid +
ubsync_blkid / old_children - old_children;
VERIFY3U(next_overwrite_blkid, >, ubsync_blkid);
if (blkid >= next_overwrite_blkid) {
raidz_reflow_record_progress(vre,
next_overwrite_blkid << ashift, tx);
return (B_TRUE);
}
range_tree_remove(rt, offset, length);
raidz_reflow_arg_t *rra = kmem_zalloc(sizeof (*rra), KM_SLEEP);
rra->rra_vre = vre;
rra->rra_lr = zfs_rangelock_enter(&vre->vre_rangelock,
offset, length, RL_WRITER);
rra->rra_txg = dmu_tx_get_txg(tx);
raidz_reflow_record_progress(vre, offset + length, tx);
mutex_enter(&vre->vre_lock);
vre->vre_outstanding_bytes += length;
mutex_exit(&vre->vre_lock);
/*
* SCL_STATE will be released when the read and write are done,
* by raidz_reflow_write_done().
*/
spa_config_enter(spa, SCL_STATE, spa, RW_READER);
/* check if a replacing vdev was added, if so treat it as an error */
if (vdev_raidz_expand_child_replacing(vd)) {
zfs_dbgmsg("replacing vdev encountered, reflow paused at "
"offset=%llu txg=%llu",
(long long)rra->rra_lr->lr_offset,
(long long)rra->rra_txg);
mutex_enter(&vre->vre_lock);
vre->vre_failed_offset =
MIN(vre->vre_failed_offset, rra->rra_lr->lr_offset);
cv_signal(&vre->vre_cv);
mutex_exit(&vre->vre_lock);
/* drop everything we acquired */
zfs_rangelock_exit(rra->rra_lr);
kmem_free(rra, sizeof (*rra));
spa_config_exit(spa, SCL_STATE, spa);
return (B_TRUE);
}
zio_t *pio = spa->spa_txg_zio[txgoff];
abd_t *abd = abd_alloc_for_io(length, B_FALSE);
zio_t *write_zio = zio_vdev_child_io(pio, NULL,
vd->vdev_child[blkid % vd->vdev_children],
(blkid / vd->vdev_children) << ashift,
abd, length,
ZIO_TYPE_WRITE, ZIO_PRIORITY_REMOVAL,
ZIO_FLAG_CANFAIL,
raidz_reflow_write_done, rra);
zio_nowait(zio_vdev_child_io(write_zio, NULL,
vd->vdev_child[blkid % old_children],
(blkid / old_children) << ashift,
abd, length,
ZIO_TYPE_READ, ZIO_PRIORITY_REMOVAL,
ZIO_FLAG_CANFAIL,
raidz_reflow_read_done, rra));
return (B_FALSE);
}
/*
* For testing (ztest specific)
*/
static void
raidz_expand_pause(uint_t pause_point)
{
while (raidz_expand_pause_point != 0 &&
raidz_expand_pause_point <= pause_point)
delay(hz);
}
static void
raidz_scratch_child_done(zio_t *zio)
{
zio_t *pio = zio->io_private;
mutex_enter(&pio->io_lock);
pio->io_error = zio_worst_error(pio->io_error, zio->io_error);
mutex_exit(&pio->io_lock);
}
/*
* Reflow the beginning portion of the vdev into an intermediate scratch area
* in memory and on disk. This operation must be persisted on disk before we
* proceed to overwrite the beginning portion with the reflowed data.
*
* This multi-step task can fail to complete if disk errors are encountered
* and we can return here after a pause (waiting for disk to become healthy).
*/
static void
raidz_reflow_scratch_sync(void *arg, dmu_tx_t *tx)
{
vdev_raidz_expand_t *vre = arg;
spa_t *spa = dmu_tx_pool(tx)->dp_spa;
zio_t *pio;
int error;
spa_config_enter(spa, SCL_STATE, FTAG, RW_READER);
vdev_t *raidvd = vdev_lookup_top(spa, vre->vre_vdev_id);
int ashift = raidvd->vdev_ashift;
uint64_t write_size = P2ALIGN(VDEV_BOOT_SIZE, 1 << ashift);
uint64_t logical_size = write_size * raidvd->vdev_children;
uint64_t read_size =
P2ROUNDUP(DIV_ROUND_UP(logical_size, (raidvd->vdev_children - 1)),
1 << ashift);
/*
* The scratch space must be large enough to get us to the point
* that one row does not overlap itself when moved. This is checked
* by vdev_raidz_attach_check().
*/
VERIFY3U(write_size, >=, raidvd->vdev_children << ashift);
VERIFY3U(write_size, <=, VDEV_BOOT_SIZE);
VERIFY3U(write_size, <=, read_size);
zfs_locked_range_t *lr = zfs_rangelock_enter(&vre->vre_rangelock,
0, logical_size, RL_WRITER);
abd_t **abds = kmem_alloc(raidvd->vdev_children * sizeof (abd_t *),
KM_SLEEP);
for (int i = 0; i < raidvd->vdev_children; i++) {
abds[i] = abd_alloc_linear(read_size, B_FALSE);
}
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_PRE_SCRATCH_1);
/*
* If we have already written the scratch area then we must read from
* there, since new writes were redirected there while we were paused
* or the original location may have been partially overwritten with
* reflowed data.
*/
if (RRSS_GET_STATE(&spa->spa_ubsync) == RRSS_SCRATCH_VALID) {
VERIFY3U(RRSS_GET_OFFSET(&spa->spa_ubsync), ==, logical_size);
/*
* Read from scratch space.
*/
pio = zio_root(spa, NULL, NULL, ZIO_FLAG_CANFAIL);
for (int i = 0; i < raidvd->vdev_children; i++) {
/*
* Note: zio_vdev_child_io() adds VDEV_LABEL_START_SIZE
* to the offset to calculate the physical offset to
* write to. Passing in a negative offset makes us
* access the scratch area.
*/
zio_nowait(zio_vdev_child_io(pio, NULL,
raidvd->vdev_child[i],
VDEV_BOOT_OFFSET - VDEV_LABEL_START_SIZE, abds[i],
write_size, ZIO_TYPE_READ, ZIO_PRIORITY_ASYNC_READ,
ZIO_FLAG_CANFAIL, raidz_scratch_child_done, pio));
}
error = zio_wait(pio);
if (error != 0) {
zfs_dbgmsg("reflow: error %d reading scratch location",
error);
goto io_error_exit;
}
goto overwrite;
}
/*
* Read from original location.
*/
pio = zio_root(spa, NULL, NULL, ZIO_FLAG_CANFAIL);
for (int i = 0; i < raidvd->vdev_children - 1; i++) {
ASSERT0(vdev_is_dead(raidvd->vdev_child[i]));
zio_nowait(zio_vdev_child_io(pio, NULL, raidvd->vdev_child[i],
0, abds[i], read_size, ZIO_TYPE_READ,
ZIO_PRIORITY_ASYNC_READ, ZIO_FLAG_CANFAIL,
raidz_scratch_child_done, pio));
}
error = zio_wait(pio);
if (error != 0) {
zfs_dbgmsg("reflow: error %d reading original location", error);
io_error_exit:
for (int i = 0; i < raidvd->vdev_children; i++)
abd_free(abds[i]);
kmem_free(abds, raidvd->vdev_children * sizeof (abd_t *));
zfs_rangelock_exit(lr);
spa_config_exit(spa, SCL_STATE, FTAG);
return;
}
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_PRE_SCRATCH_2);
/*
* Reflow in memory.
*/
uint64_t logical_sectors = logical_size >> ashift;
for (int i = raidvd->vdev_children - 1; i < logical_sectors; i++) {
int oldchild = i % (raidvd->vdev_children - 1);
uint64_t oldoff = (i / (raidvd->vdev_children - 1)) << ashift;
int newchild = i % raidvd->vdev_children;
uint64_t newoff = (i / raidvd->vdev_children) << ashift;
/* a single sector should not be copying over itself */
ASSERT(!(newchild == oldchild && newoff == oldoff));
abd_copy_off(abds[newchild], abds[oldchild],
newoff, oldoff, 1 << ashift);
}
/*
* Verify that we filled in everything we intended to (write_size on
* each child).
*/
VERIFY0(logical_sectors % raidvd->vdev_children);
VERIFY3U((logical_sectors / raidvd->vdev_children) << ashift, ==,
write_size);
/*
* Write to scratch location (boot area).
*/
pio = zio_root(spa, NULL, NULL, ZIO_FLAG_CANFAIL);
for (int i = 0; i < raidvd->vdev_children; i++) {
/*
* Note: zio_vdev_child_io() adds VDEV_LABEL_START_SIZE to
* the offset to calculate the physical offset to write to.
* Passing in a negative offset lets us access the boot area.
*/
zio_nowait(zio_vdev_child_io(pio, NULL, raidvd->vdev_child[i],
VDEV_BOOT_OFFSET - VDEV_LABEL_START_SIZE, abds[i],
write_size, ZIO_TYPE_WRITE, ZIO_PRIORITY_ASYNC_WRITE,
ZIO_FLAG_CANFAIL, raidz_scratch_child_done, pio));
}
error = zio_wait(pio);
if (error != 0) {
zfs_dbgmsg("reflow: error %d writing scratch location", error);
goto io_error_exit;
}
pio = zio_root(spa, NULL, NULL, 0);
zio_flush(pio, raidvd);
zio_wait(pio);
zfs_dbgmsg("reflow: wrote %llu bytes (logical) to scratch area",
(long long)logical_size);
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_PRE_SCRATCH_3);
/*
* Update uberblock to indicate that scratch space is valid. This is
* needed because after this point, the real location may be
* overwritten. If we crash, we need to get the data from the
* scratch space, rather than the real location.
*
* Note: ub_timestamp is bumped so that vdev_uberblock_compare()
* will prefer this uberblock.
*/
RAIDZ_REFLOW_SET(&spa->spa_ubsync, RRSS_SCRATCH_VALID, logical_size);
spa->spa_ubsync.ub_timestamp++;
ASSERT0(vdev_uberblock_sync_list(&spa->spa_root_vdev, 1,
&spa->spa_ubsync, ZIO_FLAG_CONFIG_WRITER));
if (spa_multihost(spa))
mmp_update_uberblock(spa, &spa->spa_ubsync);
zfs_dbgmsg("reflow: uberblock updated "
"(txg %llu, SCRATCH_VALID, size %llu, ts %llu)",
(long long)spa->spa_ubsync.ub_txg,
(long long)logical_size,
(long long)spa->spa_ubsync.ub_timestamp);
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_SCRATCH_VALID);
/*
* Overwrite with reflow'ed data.
*/
overwrite:
pio = zio_root(spa, NULL, NULL, ZIO_FLAG_CANFAIL);
for (int i = 0; i < raidvd->vdev_children; i++) {
zio_nowait(zio_vdev_child_io(pio, NULL, raidvd->vdev_child[i],
0, abds[i], write_size, ZIO_TYPE_WRITE,
ZIO_PRIORITY_ASYNC_WRITE, ZIO_FLAG_CANFAIL,
raidz_scratch_child_done, pio));
}
error = zio_wait(pio);
if (error != 0) {
/*
* When we exit early here and drop the range lock, new
* writes will go into the scratch area so we'll need to
* read from there when we return after pausing.
*/
zfs_dbgmsg("reflow: error %d writing real location", error);
/*
* Update the uberblock that is written when this txg completes.
*/
RAIDZ_REFLOW_SET(&spa->spa_uberblock, RRSS_SCRATCH_VALID,
logical_size);
goto io_error_exit;
}
pio = zio_root(spa, NULL, NULL, 0);
zio_flush(pio, raidvd);
zio_wait(pio);
zfs_dbgmsg("reflow: overwrote %llu bytes (logical) to real location",
(long long)logical_size);
for (int i = 0; i < raidvd->vdev_children; i++)
abd_free(abds[i]);
kmem_free(abds, raidvd->vdev_children * sizeof (abd_t *));
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_SCRATCH_REFLOWED);
/*
* Update uberblock to indicate that the initial part has been
* reflow'ed. This is needed because after this point (when we exit
* the rangelock), we allow regular writes to this region, which will
* be written to the new location only (because reflow_offset_next ==
* reflow_offset_synced). If we crashed and re-copied from the
* scratch space, we would lose the regular writes.
*/
RAIDZ_REFLOW_SET(&spa->spa_ubsync, RRSS_SCRATCH_INVALID_SYNCED,
logical_size);
spa->spa_ubsync.ub_timestamp++;
ASSERT0(vdev_uberblock_sync_list(&spa->spa_root_vdev, 1,
&spa->spa_ubsync, ZIO_FLAG_CONFIG_WRITER));
if (spa_multihost(spa))
mmp_update_uberblock(spa, &spa->spa_ubsync);
zfs_dbgmsg("reflow: uberblock updated "
"(txg %llu, SCRATCH_NOT_IN_USE, size %llu, ts %llu)",
(long long)spa->spa_ubsync.ub_txg,
(long long)logical_size,
(long long)spa->spa_ubsync.ub_timestamp);
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_SCRATCH_POST_REFLOW_1);
/*
* Update progress.
*/
vre->vre_offset = logical_size;
zfs_rangelock_exit(lr);
spa_config_exit(spa, SCL_STATE, FTAG);
int txgoff = dmu_tx_get_txg(tx) & TXG_MASK;
vre->vre_offset_pertxg[txgoff] = vre->vre_offset;
vre->vre_bytes_copied_pertxg[txgoff] = vre->vre_bytes_copied;
/*
* Note - raidz_reflow_sync() will update the uberblock state to
* RRSS_SCRATCH_INVALID_SYNCED_REFLOW
*/
raidz_reflow_sync(spa, tx);
raidz_expand_pause(RAIDZ_EXPAND_PAUSE_SCRATCH_POST_REFLOW_2);
}
/*
* We crashed in the middle of raidz_reflow_scratch_sync(); complete its work
* here. No other i/o can be in progress, so we don't need the vre_rangelock.
*/
void
vdev_raidz_reflow_copy_scratch(spa_t *spa)
{
vdev_raidz_expand_t *vre = spa->spa_raidz_expand;
uint64_t logical_size = RRSS_GET_OFFSET(&spa->spa_uberblock);
ASSERT3U(RRSS_GET_STATE(&spa->spa_uberblock), ==, RRSS_SCRATCH_VALID);
spa_config_enter(spa, SCL_STATE, FTAG, RW_READER);
vdev_t *raidvd = vdev_lookup_top(spa, vre->vre_vdev_id);
ASSERT0(logical_size % raidvd->vdev_children);
uint64_t write_size = logical_size / raidvd->vdev_children;
zio_t *pio;
/*
* Read from scratch space.
*/
abd_t **abds = kmem_alloc(raidvd->vdev_children * sizeof (abd_t *),
KM_SLEEP);
for (int i = 0; i < raidvd->vdev_children; i++) {
abds[i] = abd_alloc_linear(write_size, B_FALSE);
}
pio = zio_root(spa, NULL, NULL, 0);
for (int i = 0; i < raidvd->vdev_children; i++) {
/*
* Note: zio_vdev_child_io() adds VDEV_LABEL_START_SIZE to
* the offset to calculate the physical offset to write to.
* Passing in a negative offset lets us access the boot area.
*/
zio_nowait(zio_vdev_child_io(pio, NULL, raidvd->vdev_child[i],
VDEV_BOOT_OFFSET - VDEV_LABEL_START_SIZE, abds[i],
write_size, ZIO_TYPE_READ,
ZIO_PRIORITY_ASYNC_READ, 0,
raidz_scratch_child_done, pio));
}
zio_wait(pio);
/*
* Overwrite real location with reflow'ed data.
*/
pio = zio_root(spa, NULL, NULL, 0);
for (int i = 0; i < raidvd->vdev_children; i++) {
zio_nowait(zio_vdev_child_io(pio, NULL, raidvd->vdev_child[i],
0, abds[i], write_size, ZIO_TYPE_WRITE,
ZIO_PRIORITY_ASYNC_WRITE, 0,
raidz_scratch_child_done, pio));
}
zio_wait(pio);
pio = zio_root(spa, NULL, NULL, 0);
zio_flush(pio, raidvd);
zio_wait(pio);
zfs_dbgmsg("reflow recovery: overwrote %llu bytes (logical) "
"to real location", (long long)logical_size);
for (int i = 0; i < raidvd->vdev_children; i++)
abd_free(abds[i]);
kmem_free(abds, raidvd->vdev_children * sizeof (abd_t *));
/*
* Update uberblock.
*/
RAIDZ_REFLOW_SET(&spa->spa_ubsync,
RRSS_SCRATCH_INVALID_SYNCED_ON_IMPORT, logical_size);
spa->spa_ubsync.ub_timestamp++;
VERIFY0(vdev_uberblock_sync_list(&spa->spa_root_vdev, 1,
&spa->spa_ubsync, ZIO_FLAG_CONFIG_WRITER));
if (spa_multihost(spa))
mmp_update_uberblock(spa, &spa->spa_ubsync);
zfs_dbgmsg("reflow recovery: uberblock updated "
"(txg %llu, SCRATCH_NOT_IN_USE, size %llu, ts %llu)",
(long long)spa->spa_ubsync.ub_txg,
(long long)logical_size,
(long long)spa->spa_ubsync.ub_timestamp);
dmu_tx_t *tx = dmu_tx_create_assigned(spa->spa_dsl_pool,
spa_first_txg(spa));
int txgoff = dmu_tx_get_txg(tx) & TXG_MASK;
vre->vre_offset = logical_size;
vre->vre_offset_pertxg[txgoff] = vre->vre_offset;
vre->vre_bytes_copied_pertxg[txgoff] = vre->vre_bytes_copied;
/*
* Note that raidz_reflow_sync() will update the uberblock once more
*/
raidz_reflow_sync(spa, tx);
dmu_tx_commit(tx);
spa_config_exit(spa, SCL_STATE, FTAG);
}
static boolean_t
spa_raidz_expand_thread_check(void *arg, zthr_t *zthr)
{
(void) zthr;
spa_t *spa = arg;
return (spa->spa_raidz_expand != NULL &&
!spa->spa_raidz_expand->vre_waiting_for_resilver);
}
/*
* RAIDZ expansion background thread
*
* Can be called multiple times if the reflow is paused
*/
static void
spa_raidz_expand_thread(void *arg, zthr_t *zthr)
{
spa_t *spa = arg;
vdev_raidz_expand_t *vre = spa->spa_raidz_expand;
if (RRSS_GET_STATE(&spa->spa_ubsync) == RRSS_SCRATCH_VALID)
vre->vre_offset = 0;
else
vre->vre_offset = RRSS_GET_OFFSET(&spa->spa_ubsync);
/* Reflow the begining portion using the scratch area */
if (vre->vre_offset == 0) {
VERIFY0(dsl_sync_task(spa_name(spa),
NULL, raidz_reflow_scratch_sync,
vre, 0, ZFS_SPACE_CHECK_NONE));
/* if we encountered errors then pause */
if (vre->vre_offset == 0) {
mutex_enter(&vre->vre_lock);
vre->vre_waiting_for_resilver = B_TRUE;
mutex_exit(&vre->vre_lock);
return;
}
}
spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER);
vdev_t *raidvd = vdev_lookup_top(spa, vre->vre_vdev_id);
uint64_t guid = raidvd->vdev_guid;
/* Iterate over all the remaining metaslabs */
for (uint64_t i = vre->vre_offset >> raidvd->vdev_ms_shift;
i < raidvd->vdev_ms_count &&
!zthr_iscancelled(zthr) &&
vre->vre_failed_offset == UINT64_MAX; i++) {
metaslab_t *msp = raidvd->vdev_ms[i];
metaslab_disable(msp);
mutex_enter(&msp->ms_lock);
/*
* The metaslab may be newly created (for the expanded
* space), in which case its trees won't exist yet,
* so we need to bail out early.
*/
if (msp->ms_new) {
mutex_exit(&msp->ms_lock);
metaslab_enable(msp, B_FALSE, B_FALSE);
continue;
}
VERIFY0(metaslab_load(msp));
/*
* We want to copy everything except the free (allocatable)
* space. Note that there may be a little bit more free
* space (e.g. in ms_defer), and it's fine to copy that too.
*/
range_tree_t *rt = range_tree_create(NULL, RANGE_SEG64,
NULL, 0, 0);
range_tree_add(rt, msp->ms_start, msp->ms_size);
range_tree_walk(msp->ms_allocatable, range_tree_remove, rt);
mutex_exit(&msp->ms_lock);
/*
* Force the last sector of each metaslab to be copied. This
* ensures that we advance the on-disk progress to the end of
* this metaslab while the metaslab is disabled. Otherwise, we
* could move past this metaslab without advancing the on-disk
* progress, and then an allocation to this metaslab would not
* be copied.
*/
int sectorsz = 1 << raidvd->vdev_ashift;
uint64_t ms_last_offset = msp->ms_start +
msp->ms_size - sectorsz;
if (!range_tree_contains(rt, ms_last_offset, sectorsz)) {
range_tree_add(rt, ms_last_offset, sectorsz);
}
/*
* When we are resuming from a paused expansion (i.e.
* when importing a pool with a expansion in progress),
* discard any state that we have already processed.
*/
range_tree_clear(rt, 0, vre->vre_offset);
while (!zthr_iscancelled(zthr) &&
!range_tree_is_empty(rt) &&
vre->vre_failed_offset == UINT64_MAX) {
/*
* We need to periodically drop the config lock so that
* writers can get in. Additionally, we can't wait
* for a txg to sync while holding a config lock
* (since a waiting writer could cause a 3-way deadlock
* with the sync thread, which also gets a config
* lock for reader). So we can't hold the config lock
* while calling dmu_tx_assign().
*/
spa_config_exit(spa, SCL_CONFIG, FTAG);
/*
* If requested, pause the reflow when the amount
* specified by raidz_expand_max_reflow_bytes is reached
*
* This pause is only used during testing or debugging.
*/
while (raidz_expand_max_reflow_bytes != 0 &&
raidz_expand_max_reflow_bytes <=
vre->vre_bytes_copied && !zthr_iscancelled(zthr)) {
delay(hz);
}
mutex_enter(&vre->vre_lock);
while (vre->vre_outstanding_bytes >
raidz_expand_max_copy_bytes) {
cv_wait(&vre->vre_cv, &vre->vre_lock);
}
mutex_exit(&vre->vre_lock);
dmu_tx_t *tx =
dmu_tx_create_dd(spa_get_dsl(spa)->dp_mos_dir);
VERIFY0(dmu_tx_assign(tx, TXG_WAIT));
uint64_t txg = dmu_tx_get_txg(tx);
/*
* Reacquire the vdev_config lock. Theoretically, the
* vdev_t that we're expanding may have changed.
*/
spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER);
raidvd = vdev_lookup_top(spa, vre->vre_vdev_id);
boolean_t needsync =
raidz_reflow_impl(raidvd, vre, rt, tx);
dmu_tx_commit(tx);
if (needsync) {
spa_config_exit(spa, SCL_CONFIG, FTAG);
txg_wait_synced(spa->spa_dsl_pool, txg);
spa_config_enter(spa, SCL_CONFIG, FTAG,
RW_READER);
}
}
spa_config_exit(spa, SCL_CONFIG, FTAG);
metaslab_enable(msp, B_FALSE, B_FALSE);
range_tree_vacate(rt, NULL, NULL);
range_tree_destroy(rt);
spa_config_enter(spa, SCL_CONFIG, FTAG, RW_READER);
raidvd = vdev_lookup_top(spa, vre->vre_vdev_id);
}
spa_config_exit(spa, SCL_CONFIG, FTAG);
/*
* The txg_wait_synced() here ensures that all reflow zio's have
* completed, and vre_failed_offset has been set if necessary. It
* also ensures that the progress of the last raidz_reflow_sync() is
* written to disk before raidz_reflow_complete_sync() changes the
* in-memory vre_state. vdev_raidz_io_start() uses vre_state to
* determine if a reflow is in progress, in which case we may need to
* write to both old and new locations. Therefore we can only change
* vre_state once this is not necessary, which is once the on-disk
* progress (in spa_ubsync) has been set past any possible writes (to
* the end of the last metaslab).
*/
txg_wait_synced(spa->spa_dsl_pool, 0);
if (!zthr_iscancelled(zthr) &&
vre->vre_offset == raidvd->vdev_ms_count << raidvd->vdev_ms_shift) {
/*
* We are not being canceled or paused, so the reflow must be
* complete. In that case also mark it as completed on disk.
*/
ASSERT3U(vre->vre_failed_offset, ==, UINT64_MAX);
VERIFY0(dsl_sync_task(spa_name(spa), NULL,
raidz_reflow_complete_sync, spa,
0, ZFS_SPACE_CHECK_NONE));
(void) vdev_online(spa, guid, ZFS_ONLINE_EXPAND, NULL);
} else {
/*
* Wait for all copy zio's to complete and for all the
* raidz_reflow_sync() synctasks to be run.
*/
spa_history_log_internal(spa, "reflow pause",
NULL, "offset=%llu failed_offset=%lld",
(long long)vre->vre_offset,
(long long)vre->vre_failed_offset);
mutex_enter(&vre->vre_lock);
if (vre->vre_failed_offset != UINT64_MAX) {
/*
* Reset progress so that we will retry everything
* after the point that something failed.
*/
vre->vre_offset = vre->vre_failed_offset;
vre->vre_failed_offset = UINT64_MAX;
vre->vre_waiting_for_resilver = B_TRUE;
}
mutex_exit(&vre->vre_lock);
}
}
void
spa_start_raidz_expansion_thread(spa_t *spa)
{
ASSERT3P(spa->spa_raidz_expand_zthr, ==, NULL);
spa->spa_raidz_expand_zthr = zthr_create("raidz_expand",
spa_raidz_expand_thread_check, spa_raidz_expand_thread,
spa, defclsyspri);
}
void
raidz_dtl_reassessed(vdev_t *vd)
{
spa_t *spa = vd->vdev_spa;
if (spa->spa_raidz_expand != NULL) {
vdev_raidz_expand_t *vre = spa->spa_raidz_expand;
/*
* we get called often from vdev_dtl_reassess() so make
* sure it's our vdev and any replacing is complete
*/
if (vd->vdev_top->vdev_id == vre->vre_vdev_id &&
!vdev_raidz_expand_child_replacing(vd->vdev_top)) {
mutex_enter(&vre->vre_lock);
if (vre->vre_waiting_for_resilver) {
vdev_dbgmsg(vd, "DTL reassessed, "
"continuing raidz expansion");
vre->vre_waiting_for_resilver = B_FALSE;
zthr_wakeup(spa->spa_raidz_expand_zthr);
}
mutex_exit(&vre->vre_lock);
}
}
}
int
vdev_raidz_attach_check(vdev_t *new_child)
{
vdev_t *raidvd = new_child->vdev_parent;
uint64_t new_children = raidvd->vdev_children;
/*
* We use the "boot" space as scratch space to handle overwriting the
* initial part of the vdev. If it is too small, then this expansion
* is not allowed. This would be very unusual (e.g. ashift > 13 and
* >200 children).
*/
if (new_children << raidvd->vdev_ashift > VDEV_BOOT_SIZE) {
return (EINVAL);
}
return (0);
}
void
vdev_raidz_attach_sync(void *arg, dmu_tx_t *tx)
{
vdev_t *new_child = arg;
spa_t *spa = new_child->vdev_spa;
vdev_t *raidvd = new_child->vdev_parent;
vdev_raidz_t *vdrz = raidvd->vdev_tsd;
ASSERT3P(raidvd->vdev_ops, ==, &vdev_raidz_ops);
ASSERT3P(raidvd->vdev_top, ==, raidvd);
ASSERT3U(raidvd->vdev_children, >, vdrz->vd_original_width);
ASSERT3U(raidvd->vdev_children, ==, vdrz->vd_physical_width + 1);
ASSERT3P(raidvd->vdev_child[raidvd->vdev_children - 1], ==,
new_child);
spa_feature_incr(spa, SPA_FEATURE_RAIDZ_EXPANSION, tx);
vdrz->vd_physical_width++;
VERIFY0(spa->spa_uberblock.ub_raidz_reflow_info);
vdrz->vn_vre.vre_vdev_id = raidvd->vdev_id;
vdrz->vn_vre.vre_offset = 0;
vdrz->vn_vre.vre_failed_offset = UINT64_MAX;
spa->spa_raidz_expand = &vdrz->vn_vre;
zthr_wakeup(spa->spa_raidz_expand_zthr);
/*
* Dirty the config so that ZPOOL_CONFIG_RAIDZ_EXPANDING will get
* written to the config.
*/
vdev_config_dirty(raidvd);
vdrz->vn_vre.vre_start_time = gethrestime_sec();
vdrz->vn_vre.vre_end_time = 0;
vdrz->vn_vre.vre_state = DSS_SCANNING;
vdrz->vn_vre.vre_bytes_copied = 0;
uint64_t state = vdrz->vn_vre.vre_state;
VERIFY0(zap_update(spa->spa_meta_objset,
raidvd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_STATE,
sizeof (state), 1, &state, tx));
uint64_t start_time = vdrz->vn_vre.vre_start_time;
VERIFY0(zap_update(spa->spa_meta_objset,
raidvd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_START_TIME,
sizeof (start_time), 1, &start_time, tx));
(void) zap_remove(spa->spa_meta_objset,
raidvd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_END_TIME, tx);
(void) zap_remove(spa->spa_meta_objset,
raidvd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_BYTES_COPIED, tx);
spa_history_log_internal(spa, "raidz vdev expansion started", tx,
"%s vdev %llu new width %llu", spa_name(spa),
(unsigned long long)raidvd->vdev_id,
(unsigned long long)raidvd->vdev_children);
}
int
vdev_raidz_load(vdev_t *vd)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
int err;
uint64_t state = DSS_NONE;
uint64_t start_time = 0;
uint64_t end_time = 0;
uint64_t bytes_copied = 0;
if (vd->vdev_top_zap != 0) {
err = zap_lookup(vd->vdev_spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_STATE,
sizeof (state), 1, &state);
if (err != 0 && err != ENOENT)
return (err);
err = zap_lookup(vd->vdev_spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_START_TIME,
sizeof (start_time), 1, &start_time);
if (err != 0 && err != ENOENT)
return (err);
err = zap_lookup(vd->vdev_spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_END_TIME,
sizeof (end_time), 1, &end_time);
if (err != 0 && err != ENOENT)
return (err);
err = zap_lookup(vd->vdev_spa->spa_meta_objset,
vd->vdev_top_zap, VDEV_TOP_ZAP_RAIDZ_EXPAND_BYTES_COPIED,
sizeof (bytes_copied), 1, &bytes_copied);
if (err != 0 && err != ENOENT)
return (err);
}
/*
* If we are in the middle of expansion, vre_state should have
* already been set by vdev_raidz_init().
*/
EQUIV(vdrz->vn_vre.vre_state == DSS_SCANNING, state == DSS_SCANNING);
vdrz->vn_vre.vre_state = (dsl_scan_state_t)state;
vdrz->vn_vre.vre_start_time = start_time;
vdrz->vn_vre.vre_end_time = end_time;
vdrz->vn_vre.vre_bytes_copied = bytes_copied;
return (0);
}
int
spa_raidz_expand_get_stats(spa_t *spa, pool_raidz_expand_stat_t *pres)
{
vdev_raidz_expand_t *vre = spa->spa_raidz_expand;
if (vre == NULL) {
/* no removal in progress; find most recent completed */
for (int c = 0; c < spa->spa_root_vdev->vdev_children; c++) {
vdev_t *vd = spa->spa_root_vdev->vdev_child[c];
if (vd->vdev_ops == &vdev_raidz_ops) {
vdev_raidz_t *vdrz = vd->vdev_tsd;
if (vdrz->vn_vre.vre_end_time != 0 &&
(vre == NULL ||
vdrz->vn_vre.vre_end_time >
vre->vre_end_time)) {
vre = &vdrz->vn_vre;
}
}
}
}
if (vre == NULL) {
return (SET_ERROR(ENOENT));
}
pres->pres_state = vre->vre_state;
pres->pres_expanding_vdev = vre->vre_vdev_id;
vdev_t *vd = vdev_lookup_top(spa, vre->vre_vdev_id);
pres->pres_to_reflow = vd->vdev_stat.vs_alloc;
mutex_enter(&vre->vre_lock);
pres->pres_reflowed = vre->vre_bytes_copied;
for (int i = 0; i < TXG_SIZE; i++)
pres->pres_reflowed += vre->vre_bytes_copied_pertxg[i];
mutex_exit(&vre->vre_lock);
pres->pres_start_time = vre->vre_start_time;
pres->pres_end_time = vre->vre_end_time;
pres->pres_waiting_for_resilver = vre->vre_waiting_for_resilver;
return (0);
}
/*
* Initialize private RAIDZ specific fields from the nvlist.
*/
static int
vdev_raidz_init(spa_t *spa, nvlist_t *nv, void **tsd)
{
uint_t children;
nvlist_t **child;
int error = nvlist_lookup_nvlist_array(nv,
ZPOOL_CONFIG_CHILDREN, &child, &children);
if (error != 0)
return (SET_ERROR(EINVAL));
uint64_t nparity;
if (nvlist_lookup_uint64(nv, ZPOOL_CONFIG_NPARITY, &nparity) == 0) {
if (nparity == 0 || nparity > VDEV_RAIDZ_MAXPARITY)
return (SET_ERROR(EINVAL));
/*
* Previous versions could only support 1 or 2 parity
* device.
*/
if (nparity > 1 && spa_version(spa) < SPA_VERSION_RAIDZ2)
return (SET_ERROR(EINVAL));
else if (nparity > 2 && spa_version(spa) < SPA_VERSION_RAIDZ3)
return (SET_ERROR(EINVAL));
} else {
/*
* We require the parity to be specified for SPAs that
* support multiple parity levels.
*/
if (spa_version(spa) >= SPA_VERSION_RAIDZ2)
return (SET_ERROR(EINVAL));
/*
* Otherwise, we default to 1 parity device for RAID-Z.
*/
nparity = 1;
}
vdev_raidz_t *vdrz = kmem_zalloc(sizeof (*vdrz), KM_SLEEP);
vdrz->vn_vre.vre_vdev_id = -1;
vdrz->vn_vre.vre_offset = UINT64_MAX;
vdrz->vn_vre.vre_failed_offset = UINT64_MAX;
mutex_init(&vdrz->vn_vre.vre_lock, NULL, MUTEX_DEFAULT, NULL);
cv_init(&vdrz->vn_vre.vre_cv, NULL, CV_DEFAULT, NULL);
zfs_rangelock_init(&vdrz->vn_vre.vre_rangelock, NULL, NULL);
mutex_init(&vdrz->vd_expand_lock, NULL, MUTEX_DEFAULT, NULL);
avl_create(&vdrz->vd_expand_txgs, vdev_raidz_reflow_compare,
sizeof (reflow_node_t), offsetof(reflow_node_t, re_link));
vdrz->vd_physical_width = children;
vdrz->vd_nparity = nparity;
/* note, the ID does not exist when creating a pool */
(void) nvlist_lookup_uint64(nv, ZPOOL_CONFIG_ID,
&vdrz->vn_vre.vre_vdev_id);
boolean_t reflow_in_progress =
nvlist_exists(nv, ZPOOL_CONFIG_RAIDZ_EXPANDING);
if (reflow_in_progress) {
spa->spa_raidz_expand = &vdrz->vn_vre;
vdrz->vn_vre.vre_state = DSS_SCANNING;
}
vdrz->vd_original_width = children;
uint64_t *txgs;
unsigned int txgs_size = 0;
error = nvlist_lookup_uint64_array(nv, ZPOOL_CONFIG_RAIDZ_EXPAND_TXGS,
&txgs, &txgs_size);
if (error == 0) {
for (int i = 0; i < txgs_size; i++) {
reflow_node_t *re = kmem_zalloc(sizeof (*re), KM_SLEEP);
re->re_txg = txgs[txgs_size - i - 1];
re->re_logical_width = vdrz->vd_physical_width - i;
if (reflow_in_progress)
re->re_logical_width--;
avl_add(&vdrz->vd_expand_txgs, re);
}
vdrz->vd_original_width = vdrz->vd_physical_width - txgs_size;
}
if (reflow_in_progress) {
vdrz->vd_original_width--;
zfs_dbgmsg("reflow_in_progress, %u wide, %d prior expansions",
children, txgs_size);
}
*tsd = vdrz;
return (0);
}
static void
vdev_raidz_fini(vdev_t *vd)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
if (vd->vdev_spa->spa_raidz_expand == &vdrz->vn_vre)
vd->vdev_spa->spa_raidz_expand = NULL;
reflow_node_t *re;
void *cookie = NULL;
avl_tree_t *tree = &vdrz->vd_expand_txgs;
while ((re = avl_destroy_nodes(tree, &cookie)) != NULL)
kmem_free(re, sizeof (*re));
avl_destroy(&vdrz->vd_expand_txgs);
mutex_destroy(&vdrz->vd_expand_lock);
mutex_destroy(&vdrz->vn_vre.vre_lock);
cv_destroy(&vdrz->vn_vre.vre_cv);
zfs_rangelock_fini(&vdrz->vn_vre.vre_rangelock);
kmem_free(vdrz, sizeof (*vdrz));
}
/*
* Add RAIDZ specific fields to the config nvlist.
*/
static void
vdev_raidz_config_generate(vdev_t *vd, nvlist_t *nv)
{
ASSERT3P(vd->vdev_ops, ==, &vdev_raidz_ops);
vdev_raidz_t *vdrz = vd->vdev_tsd;
/*
* Make sure someone hasn't managed to sneak a fancy new vdev
* into a crufty old storage pool.
*/
ASSERT(vdrz->vd_nparity == 1 ||
(vdrz->vd_nparity <= 2 &&
spa_version(vd->vdev_spa) >= SPA_VERSION_RAIDZ2) ||
(vdrz->vd_nparity <= 3 &&
spa_version(vd->vdev_spa) >= SPA_VERSION_RAIDZ3));
/*
* Note that we'll add these even on storage pools where they
* aren't strictly required -- older software will just ignore
* it.
*/
fnvlist_add_uint64(nv, ZPOOL_CONFIG_NPARITY, vdrz->vd_nparity);
if (vdrz->vn_vre.vre_state == DSS_SCANNING) {
fnvlist_add_boolean(nv, ZPOOL_CONFIG_RAIDZ_EXPANDING);
}
mutex_enter(&vdrz->vd_expand_lock);
if (!avl_is_empty(&vdrz->vd_expand_txgs)) {
uint64_t count = avl_numnodes(&vdrz->vd_expand_txgs);
uint64_t *txgs = kmem_alloc(sizeof (uint64_t) * count,
KM_SLEEP);
uint64_t i = 0;
for (reflow_node_t *re = avl_first(&vdrz->vd_expand_txgs);
re != NULL; re = AVL_NEXT(&vdrz->vd_expand_txgs, re)) {
txgs[i++] = re->re_txg;
}
fnvlist_add_uint64_array(nv, ZPOOL_CONFIG_RAIDZ_EXPAND_TXGS,
txgs, count);
kmem_free(txgs, sizeof (uint64_t) * count);
}
mutex_exit(&vdrz->vd_expand_lock);
}
static uint64_t
vdev_raidz_nparity(vdev_t *vd)
{
vdev_raidz_t *vdrz = vd->vdev_tsd;
return (vdrz->vd_nparity);
}
static uint64_t
vdev_raidz_ndisks(vdev_t *vd)
{
return (vd->vdev_children);
}
vdev_ops_t vdev_raidz_ops = {
.vdev_op_init = vdev_raidz_init,
.vdev_op_fini = vdev_raidz_fini,
.vdev_op_open = vdev_raidz_open,
.vdev_op_close = vdev_raidz_close,
.vdev_op_asize = vdev_raidz_asize,
.vdev_op_min_asize = vdev_raidz_min_asize,
.vdev_op_min_alloc = NULL,
.vdev_op_io_start = vdev_raidz_io_start,
.vdev_op_io_done = vdev_raidz_io_done,
.vdev_op_state_change = vdev_raidz_state_change,
.vdev_op_need_resilver = vdev_raidz_need_resilver,
.vdev_op_hold = NULL,
.vdev_op_rele = NULL,
.vdev_op_remap = NULL,
.vdev_op_xlate = vdev_raidz_xlate,
.vdev_op_rebuild_asize = NULL,
.vdev_op_metaslab_init = NULL,
.vdev_op_config_generate = vdev_raidz_config_generate,
.vdev_op_nparity = vdev_raidz_nparity,
.vdev_op_ndisks = vdev_raidz_ndisks,
.vdev_op_type = VDEV_TYPE_RAIDZ, /* name of this vdev type */
.vdev_op_leaf = B_FALSE /* not a leaf vdev */
};
/* BEGIN CSTYLED */
ZFS_MODULE_PARAM(zfs_vdev, raidz_, expand_max_reflow_bytes, ULONG, ZMOD_RW,
"For testing, pause RAIDZ expansion after reflowing this many bytes");
ZFS_MODULE_PARAM(zfs_vdev, raidz_, expand_max_copy_bytes, ULONG, ZMOD_RW,
"Max amount of concurrent i/o for RAIDZ expansion");
ZFS_MODULE_PARAM(zfs_vdev, raidz_, io_aggregate_rows, ULONG, ZMOD_RW,
"For expanded RAIDZ, aggregate reads that have more rows than this");
ZFS_MODULE_PARAM(zfs, zfs_, scrub_after_expand, INT, ZMOD_RW,
"For expanded RAIDZ, automatically start a pool scrub when expansion "
"completes");
/* END CSTYLED */
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