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src/sys/dev/softraid_raid6.c

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/* $OpenBSD: softraid_raid6.c,v 1.72 2021/05/16 15:12:37 deraadt Exp $ */
/*
* Copyright (c) 2009 Marco Peereboom <marco@peereboom.us>
* Copyright (c) 2009 Jordan Hargrave <jordan@openbsd.org>
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include "bio.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/buf.h>
#include <sys/device.h>
#include <sys/ioctl.h>
#include <sys/malloc.h>
#include <sys/kernel.h>
#include <sys/disk.h>
#include <sys/rwlock.h>
#include <sys/queue.h>
#include <sys/fcntl.h>
#include <sys/mount.h>
#include <sys/sensors.h>
#include <sys/stat.h>
#include <sys/task.h>
#include <sys/conf.h>
#include <sys/uio.h>
#include <scsi/scsi_all.h>
#include <scsi/scsiconf.h>
#include <scsi/scsi_disk.h>
#include <dev/softraidvar.h>
uint8_t *gf_map[256];
uint8_t gf_pow[768];
int gf_log[256];
/* RAID 6 functions. */
int sr_raid6_create(struct sr_discipline *, struct bioc_createraid *,
int, int64_t);
int sr_raid6_assemble(struct sr_discipline *, struct bioc_createraid *,
int, void *);
int sr_raid6_init(struct sr_discipline *);
int sr_raid6_rw(struct sr_workunit *);
int sr_raid6_openings(struct sr_discipline *);
void sr_raid6_intr(struct buf *);
int sr_raid6_wu_done(struct sr_workunit *);
void sr_raid6_set_chunk_state(struct sr_discipline *, int, int);
void sr_raid6_set_vol_state(struct sr_discipline *);
void sr_raid6_xorp(void *, void *, int);
void sr_raid6_xorq(void *, void *, int, int);
int sr_raid6_addio(struct sr_workunit *wu, int, daddr_t, long,
void *, int, int, void *, void *, int);
void sr_raid6_scrub(struct sr_discipline *);
int sr_failio(struct sr_workunit *);
void gf_init(void);
uint8_t gf_inv(uint8_t);
int gf_premul(uint8_t);
uint8_t gf_mul(uint8_t, uint8_t);
#define SR_NOFAIL 0x00
#define SR_FAILX (1L << 0)
#define SR_FAILY (1L << 1)
#define SR_FAILP (1L << 2)
#define SR_FAILQ (1L << 3)
struct sr_raid6_opaque {
int gn;
void *pbuf;
void *qbuf;
};
/* discipline initialisation. */
void
sr_raid6_discipline_init(struct sr_discipline *sd)
{
/* Initialize GF256 tables. */
gf_init();
/* Fill out discipline members. */
sd->sd_type = SR_MD_RAID6;
strlcpy(sd->sd_name, "RAID 6", sizeof(sd->sd_name));
sd->sd_capabilities = SR_CAP_SYSTEM_DISK | SR_CAP_AUTO_ASSEMBLE |
SR_CAP_REDUNDANT;
sd->sd_max_wu = SR_RAID6_NOWU;
/* Setup discipline specific function pointers. */
sd->sd_assemble = sr_raid6_assemble;
sd->sd_create = sr_raid6_create;
sd->sd_openings = sr_raid6_openings;
sd->sd_scsi_rw = sr_raid6_rw;
sd->sd_scsi_intr = sr_raid6_intr;
sd->sd_scsi_wu_done = sr_raid6_wu_done;
sd->sd_set_chunk_state = sr_raid6_set_chunk_state;
sd->sd_set_vol_state = sr_raid6_set_vol_state;
}
int
sr_raid6_create(struct sr_discipline *sd, struct bioc_createraid *bc,
int no_chunk, int64_t coerced_size)
{
if (no_chunk < 4) {
sr_error(sd->sd_sc, "%s requires four or more chunks",
sd->sd_name);
return EINVAL;
}
/*
* XXX add variable strip size later even though MAXPHYS is really
* the clever value, users like * to tinker with that type of stuff.
*/
sd->sd_meta->ssdi.ssd_strip_size = MAXPHYS;
sd->sd_meta->ssdi.ssd_size = (coerced_size &
~(((u_int64_t)sd->sd_meta->ssdi.ssd_strip_size >>
DEV_BSHIFT) - 1)) * (no_chunk - 2);
return sr_raid6_init(sd);
}
int
sr_raid6_assemble(struct sr_discipline *sd, struct bioc_createraid *bc,
int no_chunk, void *data)
{
return sr_raid6_init(sd);
}
int
sr_raid6_init(struct sr_discipline *sd)
{
/* Initialise runtime values. */
sd->mds.mdd_raid6.sr6_strip_bits =
sr_validate_stripsize(sd->sd_meta->ssdi.ssd_strip_size);
if (sd->mds.mdd_raid6.sr6_strip_bits == -1) {
sr_error(sd->sd_sc, "invalid strip size");
return EINVAL;
}
/* only if stripsize <= MAXPHYS */
sd->sd_max_ccb_per_wu = max(6, 2 * sd->sd_meta->ssdi.ssd_chunk_no);
return 0;
}
int
sr_raid6_openings(struct sr_discipline *sd)
{
return (sd->sd_max_wu >> 1); /* 2 wu's per IO */
}
void
sr_raid6_set_chunk_state(struct sr_discipline *sd, int c, int new_state)
{
int old_state, s;
/* XXX this is for RAID 0 */
DNPRINTF(SR_D_STATE, "%s: %s: %s: sr_raid_set_chunk_state %d -> %d\n",
DEVNAME(sd->sd_sc), sd->sd_meta->ssd_devname,
sd->sd_vol.sv_chunks[c]->src_meta.scmi.scm_devname, c, new_state);
/* ok to go to splbio since this only happens in error path */
s = splbio();
old_state = sd->sd_vol.sv_chunks[c]->src_meta.scm_status;
/* multiple IOs to the same chunk that fail will come through here */
if (old_state == new_state)
goto done;
switch (old_state) {
case BIOC_SDONLINE:
switch (new_state) {
case BIOC_SDOFFLINE:
case BIOC_SDSCRUB:
break;
default:
goto die;
}
break;
case BIOC_SDOFFLINE:
if (new_state == BIOC_SDREBUILD) {
;
} else
goto die;
break;
case BIOC_SDSCRUB:
switch (new_state) {
case BIOC_SDONLINE:
case BIOC_SDOFFLINE:
break;
default:
goto die;
}
break;
case BIOC_SDREBUILD:
switch (new_state) {
case BIOC_SDONLINE:
case BIOC_SDOFFLINE:
break;
default:
goto die;
}
break;
default:
die:
splx(s); /* XXX */
panic("%s: %s: %s: invalid chunk state transition %d -> %d",
DEVNAME(sd->sd_sc),
sd->sd_meta->ssd_devname,
sd->sd_vol.sv_chunks[c]->src_meta.scmi.scm_devname,
old_state, new_state);
/* NOTREACHED */
}
sd->sd_vol.sv_chunks[c]->src_meta.scm_status = new_state;
sd->sd_set_vol_state(sd);
sd->sd_must_flush = 1;
task_add(systq, &sd->sd_meta_save_task);
done:
splx(s);
}
void
sr_raid6_set_vol_state(struct sr_discipline *sd)
{
int states[SR_MAX_STATES];
int new_state, i, s, nd;
int old_state = sd->sd_vol_status;
/* XXX this is for RAID 0 */
DNPRINTF(SR_D_STATE, "%s: %s: sr_raid_set_vol_state\n",
DEVNAME(sd->sd_sc), sd->sd_meta->ssd_devname);
nd = sd->sd_meta->ssdi.ssd_chunk_no;
for (i = 0; i < SR_MAX_STATES; i++)
states[i] = 0;
for (i = 0; i < nd; i++) {
s = sd->sd_vol.sv_chunks[i]->src_meta.scm_status;
if (s >= SR_MAX_STATES)
panic("%s: %s: %s: invalid chunk state",
DEVNAME(sd->sd_sc),
sd->sd_meta->ssd_devname,
sd->sd_vol.sv_chunks[i]->src_meta.scmi.scm_devname);
states[s]++;
}
if (states[BIOC_SDONLINE] == nd)
new_state = BIOC_SVONLINE;
else if (states[BIOC_SDONLINE] < nd - 2)
new_state = BIOC_SVOFFLINE;
else if (states[BIOC_SDSCRUB] != 0)
new_state = BIOC_SVSCRUB;
else if (states[BIOC_SDREBUILD] != 0)
new_state = BIOC_SVREBUILD;
else if (states[BIOC_SDONLINE] < nd)
new_state = BIOC_SVDEGRADED;
else {
printf("old_state = %d, ", old_state);
for (i = 0; i < nd; i++)
printf("%d = %d, ", i,
sd->sd_vol.sv_chunks[i]->src_meta.scm_status);
panic("invalid new_state");
}
DNPRINTF(SR_D_STATE, "%s: %s: sr_raid_set_vol_state %d -> %d\n",
DEVNAME(sd->sd_sc), sd->sd_meta->ssd_devname,
old_state, new_state);
switch (old_state) {
case BIOC_SVONLINE:
switch (new_state) {
case BIOC_SVONLINE: /* can go to same state */
case BIOC_SVOFFLINE:
case BIOC_SVDEGRADED:
case BIOC_SVREBUILD: /* happens on boot */
break;
default:
goto die;
}
break;
case BIOC_SVOFFLINE:
/* XXX this might be a little too much */
goto die;
case BIOC_SVDEGRADED:
switch (new_state) {
case BIOC_SVOFFLINE:
case BIOC_SVREBUILD:
case BIOC_SVDEGRADED: /* can go to the same state */
break;
default:
goto die;
}
break;
case BIOC_SVBUILDING:
switch (new_state) {
case BIOC_SVONLINE:
case BIOC_SVOFFLINE:
case BIOC_SVBUILDING: /* can go to the same state */
break;
default:
goto die;
}
break;
case BIOC_SVSCRUB:
switch (new_state) {
case BIOC_SVONLINE:
case BIOC_SVOFFLINE:
case BIOC_SVDEGRADED:
case BIOC_SVSCRUB: /* can go to same state */
break;
default:
goto die;
}
break;
case BIOC_SVREBUILD:
switch (new_state) {
case BIOC_SVONLINE:
case BIOC_SVOFFLINE:
case BIOC_SVDEGRADED:
case BIOC_SVREBUILD: /* can go to the same state */
break;
default:
goto die;
}
break;
default:
die:
panic("%s: %s: invalid volume state transition %d -> %d",
DEVNAME(sd->sd_sc), sd->sd_meta->ssd_devname,
old_state, new_state);
/* NOTREACHED */
}
sd->sd_vol_status = new_state;
}
/* modes:
* readq: sr_raid6_addio(i, lba, length, NULL, SCSI_DATA_IN,
* 0, qbuf, NULL, 0);
* readp: sr_raid6_addio(i, lba, length, NULL, SCSI_DATA_IN,
* 0, pbuf, NULL, 0);
* readx: sr_raid6_addio(i, lba, length, NULL, SCSI_DATA_IN,
* 0, pbuf, qbuf, gf_pow[i]);
*/
int
sr_raid6_rw(struct sr_workunit *wu)
{
struct sr_workunit *wu_r = NULL;
struct sr_discipline *sd = wu->swu_dis;
struct scsi_xfer *xs = wu->swu_xs;
struct sr_chunk *scp;
int s, fail, i, gxinv, pxinv;
daddr_t blkno, lba;
int64_t chunk_offs, lbaoffs, offset, strip_offs;
int64_t strip_no, strip_size, strip_bits, row_size;
int64_t fchunk, no_chunk, chunk, qchunk, pchunk;
long length, datalen;
void *pbuf, *data, *qbuf;
/* blkno and scsi error will be handled by sr_validate_io */
if (sr_validate_io(wu, &blkno, "sr_raid6_rw"))
goto bad;
strip_size = sd->sd_meta->ssdi.ssd_strip_size;
strip_bits = sd->mds.mdd_raid6.sr6_strip_bits;
no_chunk = sd->sd_meta->ssdi.ssd_chunk_no - 2;
row_size = (no_chunk << strip_bits) >> DEV_BSHIFT;
data = xs->data;
datalen = xs->datalen;
lbaoffs = blkno << DEV_BSHIFT;
if (xs->flags & SCSI_DATA_OUT) {
if ((wu_r = sr_scsi_wu_get(sd, SCSI_NOSLEEP)) == NULL){
printf("%s: can't get wu_r", DEVNAME(sd->sd_sc));
goto bad;
}
wu_r->swu_state = SR_WU_INPROGRESS;
wu_r->swu_flags |= SR_WUF_DISCIPLINE;
}
wu->swu_blk_start = 0;
while (datalen != 0) {
strip_no = lbaoffs >> strip_bits;
strip_offs = lbaoffs & (strip_size - 1);
chunk_offs = (strip_no / no_chunk) << strip_bits;
offset = chunk_offs + strip_offs;
/* get size remaining in this stripe */
length = MIN(strip_size - strip_offs, datalen);
/* map disk offset to parity/data drive */
chunk = strip_no % no_chunk;
qchunk = (no_chunk + 1) - ((strip_no / no_chunk) % (no_chunk+2));
if (qchunk == 0)
pchunk = no_chunk + 1;
else
pchunk = qchunk - 1;
if (chunk >= pchunk)
chunk++;
if (chunk >= qchunk)
chunk++;
lba = offset >> DEV_BSHIFT;
/* XXX big hammer.. exclude I/O from entire stripe */
if (wu->swu_blk_start == 0)
wu->swu_blk_start = (strip_no / no_chunk) * row_size;
wu->swu_blk_end = (strip_no / no_chunk) * row_size + (row_size - 1);
fail = 0;
fchunk = -1;
/* Get disk-fail flags */
for (i=0; i< no_chunk+2; i++) {
scp = sd->sd_vol.sv_chunks[i];
switch (scp->src_meta.scm_status) {
case BIOC_SDOFFLINE:
case BIOC_SDREBUILD:
case BIOC_SDHOTSPARE:
if (i == qchunk)
fail |= SR_FAILQ;
else if (i == pchunk)
fail |= SR_FAILP;
else if (i == chunk)
fail |= SR_FAILX;
else {
/* dual data-disk failure */
fail |= SR_FAILY;
fchunk = i;
}
break;
}
}
if (xs->flags & SCSI_DATA_IN) {
if (!(fail & SR_FAILX)) {
/* drive is good. issue single read request */
if (sr_raid6_addio(wu, chunk, lba, length,
data, xs->flags, 0, NULL, NULL, 0))
goto bad;
} else if (fail & SR_FAILP) {
/* Dx, P failed */
printf("Disk %llx offline, "
"regenerating Dx+P\n", chunk);
gxinv = gf_inv(gf_pow[chunk]);
/* Calculate: Dx = (Q^Dz*gz)*inv(gx) */
memset(data, 0, length);
if (sr_raid6_addio(wu, qchunk, lba, length,
NULL, SCSI_DATA_IN, 0, NULL, data, gxinv))
goto bad;
/* Read Dz * gz * inv(gx) */
for (i = 0; i < no_chunk+2; i++) {
if (i == qchunk || i == pchunk || i == chunk)
continue;
if (sr_raid6_addio(wu, i, lba, length,
NULL, SCSI_DATA_IN, 0, NULL, data,
gf_mul(gf_pow[i], gxinv)))
goto bad;
}
/* data will contain correct value on completion */
} else if (fail & SR_FAILY) {
/* Dx, Dy failed */
printf("Disk %llx & %llx offline, "
"regenerating Dx+Dy\n", chunk, fchunk);
gxinv = gf_inv(gf_pow[chunk] ^ gf_pow[fchunk]);
pxinv = gf_mul(gf_pow[fchunk], gxinv);
/* read Q * inv(gx + gy) */
memset(data, 0, length);
if (sr_raid6_addio(wu, qchunk, lba, length,
NULL, SCSI_DATA_IN, 0, NULL, data, gxinv))
goto bad;
/* read P * gy * inv(gx + gy) */
if (sr_raid6_addio(wu, pchunk, lba, length,
NULL, SCSI_DATA_IN, 0, NULL, data, pxinv))
goto bad;
/* Calculate: Dx*gx^Dy*gy = Q^(Dz*gz) ; Dx^Dy = P^Dz
* Q: sr_raid6_xorp(qbuf, --, length);
* P: sr_raid6_xorp(pbuf, --, length);
* Dz: sr_raid6_xorp(pbuf, --, length);
* sr_raid6_xorq(qbuf, --, length, gf_pow[i]);
*/
for (i = 0; i < no_chunk+2; i++) {
if (i == qchunk || i == pchunk ||
i == chunk || i == fchunk)
continue;
/* read Dz * (gz + gy) * inv(gx + gy) */
if (sr_raid6_addio(wu, i, lba, length,
NULL, SCSI_DATA_IN, 0, NULL, data,
pxinv ^ gf_mul(gf_pow[i], gxinv)))
goto bad;
}
} else {
/* Two cases: single disk (Dx) or (Dx+Q)
* Dx = Dz ^ P (same as RAID5)
*/
printf("Disk %llx offline, "
"regenerating Dx%s\n", chunk,
fail & SR_FAILQ ? "+Q" : " single");
/* Calculate: Dx = P^Dz
* P: sr_raid6_xorp(data, ---, length);
* Dz: sr_raid6_xorp(data, ---, length);
*/
memset(data, 0, length);
for (i = 0; i < no_chunk+2; i++) {
if (i != chunk && i != qchunk) {
/* Read Dz */
if (sr_raid6_addio(wu, i, lba,
length, NULL, SCSI_DATA_IN,
0, data, NULL, 0))
goto bad;
}
}
/* data will contain correct value on completion */
}
} else {
/* XXX handle writes to failed/offline disk? */
if (fail & (SR_FAILX|SR_FAILQ|SR_FAILP))
goto bad;
/*
* initialize pbuf with contents of new data to be
* written. This will be XORed with old data and old
* parity in the intr routine. The result in pbuf
* is the new parity data.
*/
qbuf = sr_block_get(sd, length);
if (qbuf == NULL)
goto bad;
pbuf = sr_block_get(sd, length);
if (pbuf == NULL)
goto bad;
/* Calculate P = Dn; Q = gn * Dn */
if (gf_premul(gf_pow[chunk]))
goto bad;
sr_raid6_xorp(pbuf, data, length);
sr_raid6_xorq(qbuf, data, length, gf_pow[chunk]);
/* Read old data: P ^= Dn' ; Q ^= (gn * Dn') */
if (sr_raid6_addio(wu_r, chunk, lba, length, NULL,
SCSI_DATA_IN, 0, pbuf, qbuf, gf_pow[chunk]))
goto bad;
/* Read old xor-parity: P ^= P' */
if (sr_raid6_addio(wu_r, pchunk, lba, length, NULL,
SCSI_DATA_IN, 0, pbuf, NULL, 0))
goto bad;
/* Read old q-parity: Q ^= Q' */
if (sr_raid6_addio(wu_r, qchunk, lba, length, NULL,
SCSI_DATA_IN, 0, qbuf, NULL, 0))
goto bad;
/* write new data */
if (sr_raid6_addio(wu, chunk, lba, length, data,
xs->flags, 0, NULL, NULL, 0))
goto bad;
/* write new xor-parity */
if (sr_raid6_addio(wu, pchunk, lba, length, pbuf,
xs->flags, SR_CCBF_FREEBUF, NULL, NULL, 0))
goto bad;
/* write new q-parity */
if (sr_raid6_addio(wu, qchunk, lba, length, qbuf,
xs->flags, SR_CCBF_FREEBUF, NULL, NULL, 0))
goto bad;
}
/* advance to next block */
lbaoffs += length;
datalen -= length;
data += length;
}
s = splbio();
if (wu_r) {
/* collide write request with reads */
wu_r->swu_blk_start = wu->swu_blk_start;
wu_r->swu_blk_end = wu->swu_blk_end;
wu->swu_state = SR_WU_DEFERRED;
wu_r->swu_collider = wu;
TAILQ_INSERT_TAIL(&sd->sd_wu_defq, wu, swu_link);
wu = wu_r;
}
splx(s);
sr_schedule_wu(wu);
return (0);
bad:
/* XXX - can leak pbuf/qbuf on error. */
/* wu is unwound by sr_wu_put */
if (wu_r)
sr_scsi_wu_put(sd, wu_r);
return (1);
}
/* Handle failure I/O completion */
int
sr_failio(struct sr_workunit *wu)
{
struct sr_discipline *sd = wu->swu_dis;
struct sr_ccb *ccb;
if (!(wu->swu_flags & SR_WUF_FAIL))
return (0);
/* Wu is a 'fake'.. don't do real I/O just intr */
TAILQ_INSERT_TAIL(&sd->sd_wu_pendq, wu, swu_link);
TAILQ_FOREACH(ccb, &wu->swu_ccb, ccb_link)
sr_raid6_intr(&ccb->ccb_buf);
return (1);
}
void
sr_raid6_intr(struct buf *bp)
{
struct sr_ccb *ccb = (struct sr_ccb *)bp;
struct sr_workunit *wu = ccb->ccb_wu;
struct sr_discipline *sd = wu->swu_dis;
struct sr_raid6_opaque *pq = ccb->ccb_opaque;
int s;
DNPRINTF(SR_D_INTR, "%s: sr_raid6_intr bp %p xs %p\n",
DEVNAME(sd->sd_sc), bp, wu->swu_xs);
s = splbio();
sr_ccb_done(ccb);
/* XOR data to result. */
if (ccb->ccb_state == SR_CCB_OK && pq) {
if (pq->pbuf)
/* Calculate xor-parity */
sr_raid6_xorp(pq->pbuf, ccb->ccb_buf.b_data,
ccb->ccb_buf.b_bcount);
if (pq->qbuf)
/* Calculate q-parity */
sr_raid6_xorq(pq->qbuf, ccb->ccb_buf.b_data,
ccb->ccb_buf.b_bcount, pq->gn);
free(pq, M_DEVBUF, 0);
ccb->ccb_opaque = NULL;
}
/* Free allocated data buffer. */
if (ccb->ccb_flags & SR_CCBF_FREEBUF) {
sr_block_put(sd, ccb->ccb_buf.b_data, ccb->ccb_buf.b_bcount);
ccb->ccb_buf.b_data = NULL;
}
sr_wu_done(wu);
splx(s);
}
int
sr_raid6_wu_done(struct sr_workunit *wu)
{
struct sr_discipline *sd = wu->swu_dis;
struct scsi_xfer *xs = wu->swu_xs;
/* XXX - we have no way of propagating errors... */
if (wu->swu_flags & SR_WUF_DISCIPLINE)
return SR_WU_OK;
/* XXX - This is insufficient for RAID 6. */
if (wu->swu_ios_succeeded > 0) {
xs->error = XS_NOERROR;
return SR_WU_OK;
}
if (xs->flags & SCSI_DATA_IN) {
printf("%s: retrying read on block %lld\n",
sd->sd_meta->ssd_devname, (long long)wu->swu_blk_start);
sr_wu_release_ccbs(wu);
wu->swu_state = SR_WU_RESTART;
if (sd->sd_scsi_rw(wu) == 0)
return SR_WU_RESTART;
} else {
printf("%s: permanently fail write on block %lld\n",
sd->sd_meta->ssd_devname, (long long)wu->swu_blk_start);
}
wu->swu_state = SR_WU_FAILED;
xs->error = XS_DRIVER_STUFFUP;
return SR_WU_FAILED;
}
int
sr_raid6_addio(struct sr_workunit *wu, int chunk, daddr_t blkno,
long len, void *data, int xsflags, int ccbflags, void *pbuf,
void *qbuf, int gn)
{
struct sr_discipline *sd = wu->swu_dis;
struct sr_ccb *ccb;
struct sr_raid6_opaque *pqbuf;
DNPRINTF(SR_D_DIS, "sr_raid6_addio: %s %d.%lld %ld %p:%p\n",
(xsflags & SCSI_DATA_IN) ? "read" : "write", chunk,
(long long)blkno, len, pbuf, qbuf);
/* Allocate temporary buffer. */
if (data == NULL) {
data = sr_block_get(sd, len);
if (data == NULL)
return (-1);
ccbflags |= SR_CCBF_FREEBUF;
}
ccb = sr_ccb_rw(sd, chunk, blkno, len, data, xsflags, ccbflags);
if (ccb == NULL) {
if (ccbflags & SR_CCBF_FREEBUF)
sr_block_put(sd, data, len);
return (-1);
}
if (pbuf || qbuf) {
/* XXX - can leak data and ccb on failure. */
if (qbuf && gf_premul(gn))
return (-1);
/* XXX - should be preallocated? */
pqbuf = malloc(sizeof(struct sr_raid6_opaque),
M_DEVBUF, M_ZERO | M_NOWAIT);
if (pqbuf == NULL) {
sr_ccb_put(ccb);
return (-1);
}
pqbuf->pbuf = pbuf;
pqbuf->qbuf = qbuf;
pqbuf->gn = gn;
ccb->ccb_opaque = pqbuf;
}
sr_wu_enqueue_ccb(wu, ccb);
return (0);
}
/* Perform RAID6 parity calculation.
* P=xor parity, Q=GF256 parity, D=data, gn=disk# */
void
sr_raid6_xorp(void *p, void *d, int len)
{
uint32_t *pbuf = p, *data = d;
len >>= 2;
while (len--)
*pbuf++ ^= *data++;
}
void
sr_raid6_xorq(void *q, void *d, int len, int gn)
{
uint32_t *qbuf = q, *data = d, x;
uint8_t *gn_map = gf_map[gn];
len >>= 2;
while (len--) {
x = *data++;
*qbuf++ ^= (((uint32_t)gn_map[x & 0xff]) |
((uint32_t)gn_map[(x >> 8) & 0xff] << 8) |
((uint32_t)gn_map[(x >> 16) & 0xff] << 16) |
((uint32_t)gn_map[(x >> 24) & 0xff] << 24));
}
}
/* Create GF256 log/pow tables: polynomial = 0x11D */
void
gf_init(void)
{
int i;
uint8_t p = 1;
/* use 2N pow table to avoid using % in multiply */
for (i=0; i<256; i++) {
gf_log[p] = i;
gf_pow[i] = gf_pow[i+255] = p;
p = ((p << 1) ^ ((p & 0x80) ? 0x1D : 0x00));
}
gf_log[0] = 512;
}
uint8_t
gf_inv(uint8_t a)
{
return gf_pow[255 - gf_log[a]];
}
uint8_t
gf_mul(uint8_t a, uint8_t b)
{
return gf_pow[gf_log[a] + gf_log[b]];
}
/* Precalculate multiplication tables for drive gn */
int
gf_premul(uint8_t gn)
{
int i;
if (gf_map[gn] != NULL)
return (0);
if ((gf_map[gn] = malloc(256, M_DEVBUF, M_ZERO | M_NOWAIT)) == NULL)
return (-1);
for (i=0; i<256; i++)
gf_map[gn][i] = gf_pow[gf_log[i] + gf_log[gn]];
return (0);
}
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