linux/drivers/scsi/libsas/sas_expander.c
Kees Cook 6396bb2215 treewide: kzalloc() -> kcalloc()
The kzalloc() function has a 2-factor argument form, kcalloc(). This
patch replaces cases of:

        kzalloc(a * b, gfp)

with:
        kcalloc(a * b, gfp)

as well as handling cases of:

        kzalloc(a * b * c, gfp)

with:

        kzalloc(array3_size(a, b, c), gfp)

as it's slightly less ugly than:

        kzalloc_array(array_size(a, b), c, gfp)

This does, however, attempt to ignore constant size factors like:

        kzalloc(4 * 1024, gfp)

though any constants defined via macros get caught up in the conversion.

Any factors with a sizeof() of "unsigned char", "char", and "u8" were
dropped, since they're redundant.

The Coccinelle script used for this was:

// Fix redundant parens around sizeof().
@@
type TYPE;
expression THING, E;
@@

(
  kzalloc(
-	(sizeof(TYPE)) * E
+	sizeof(TYPE) * E
  , ...)
|
  kzalloc(
-	(sizeof(THING)) * E
+	sizeof(THING) * E
  , ...)
)

// Drop single-byte sizes and redundant parens.
@@
expression COUNT;
typedef u8;
typedef __u8;
@@

(
  kzalloc(
-	sizeof(u8) * (COUNT)
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(__u8) * (COUNT)
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(char) * (COUNT)
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(unsigned char) * (COUNT)
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(u8) * COUNT
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(__u8) * COUNT
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(char) * COUNT
+	COUNT
  , ...)
|
  kzalloc(
-	sizeof(unsigned char) * COUNT
+	COUNT
  , ...)
)

// 2-factor product with sizeof(type/expression) and identifier or constant.
@@
type TYPE;
expression THING;
identifier COUNT_ID;
constant COUNT_CONST;
@@

(
- kzalloc
+ kcalloc
  (
-	sizeof(TYPE) * (COUNT_ID)
+	COUNT_ID, sizeof(TYPE)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(TYPE) * COUNT_ID
+	COUNT_ID, sizeof(TYPE)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(TYPE) * (COUNT_CONST)
+	COUNT_CONST, sizeof(TYPE)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(TYPE) * COUNT_CONST
+	COUNT_CONST, sizeof(TYPE)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(THING) * (COUNT_ID)
+	COUNT_ID, sizeof(THING)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(THING) * COUNT_ID
+	COUNT_ID, sizeof(THING)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(THING) * (COUNT_CONST)
+	COUNT_CONST, sizeof(THING)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(THING) * COUNT_CONST
+	COUNT_CONST, sizeof(THING)
  , ...)
)

// 2-factor product, only identifiers.
@@
identifier SIZE, COUNT;
@@

- kzalloc
+ kcalloc
  (
-	SIZE * COUNT
+	COUNT, SIZE
  , ...)

// 3-factor product with 1 sizeof(type) or sizeof(expression), with
// redundant parens removed.
@@
expression THING;
identifier STRIDE, COUNT;
type TYPE;
@@

(
  kzalloc(
-	sizeof(TYPE) * (COUNT) * (STRIDE)
+	array3_size(COUNT, STRIDE, sizeof(TYPE))
  , ...)
|
  kzalloc(
-	sizeof(TYPE) * (COUNT) * STRIDE
+	array3_size(COUNT, STRIDE, sizeof(TYPE))
  , ...)
|
  kzalloc(
-	sizeof(TYPE) * COUNT * (STRIDE)
+	array3_size(COUNT, STRIDE, sizeof(TYPE))
  , ...)
|
  kzalloc(
-	sizeof(TYPE) * COUNT * STRIDE
+	array3_size(COUNT, STRIDE, sizeof(TYPE))
  , ...)
|
  kzalloc(
-	sizeof(THING) * (COUNT) * (STRIDE)
+	array3_size(COUNT, STRIDE, sizeof(THING))
  , ...)
|
  kzalloc(
-	sizeof(THING) * (COUNT) * STRIDE
+	array3_size(COUNT, STRIDE, sizeof(THING))
  , ...)
|
  kzalloc(
-	sizeof(THING) * COUNT * (STRIDE)
+	array3_size(COUNT, STRIDE, sizeof(THING))
  , ...)
|
  kzalloc(
-	sizeof(THING) * COUNT * STRIDE
+	array3_size(COUNT, STRIDE, sizeof(THING))
  , ...)
)

// 3-factor product with 2 sizeof(variable), with redundant parens removed.
@@
expression THING1, THING2;
identifier COUNT;
type TYPE1, TYPE2;
@@

(
  kzalloc(
-	sizeof(TYPE1) * sizeof(TYPE2) * COUNT
+	array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2))
  , ...)
|
  kzalloc(
-	sizeof(TYPE1) * sizeof(THING2) * (COUNT)
+	array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2))
  , ...)
|
  kzalloc(
-	sizeof(THING1) * sizeof(THING2) * COUNT
+	array3_size(COUNT, sizeof(THING1), sizeof(THING2))
  , ...)
|
  kzalloc(
-	sizeof(THING1) * sizeof(THING2) * (COUNT)
+	array3_size(COUNT, sizeof(THING1), sizeof(THING2))
  , ...)
|
  kzalloc(
-	sizeof(TYPE1) * sizeof(THING2) * COUNT
+	array3_size(COUNT, sizeof(TYPE1), sizeof(THING2))
  , ...)
|
  kzalloc(
-	sizeof(TYPE1) * sizeof(THING2) * (COUNT)
+	array3_size(COUNT, sizeof(TYPE1), sizeof(THING2))
  , ...)
)

// 3-factor product, only identifiers, with redundant parens removed.
@@
identifier STRIDE, SIZE, COUNT;
@@

(
  kzalloc(
-	(COUNT) * STRIDE * SIZE
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	COUNT * (STRIDE) * SIZE
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	COUNT * STRIDE * (SIZE)
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	(COUNT) * (STRIDE) * SIZE
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	COUNT * (STRIDE) * (SIZE)
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	(COUNT) * STRIDE * (SIZE)
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	(COUNT) * (STRIDE) * (SIZE)
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
|
  kzalloc(
-	COUNT * STRIDE * SIZE
+	array3_size(COUNT, STRIDE, SIZE)
  , ...)
)

// Any remaining multi-factor products, first at least 3-factor products,
// when they're not all constants...
@@
expression E1, E2, E3;
constant C1, C2, C3;
@@

(
  kzalloc(C1 * C2 * C3, ...)
|
  kzalloc(
-	(E1) * E2 * E3
+	array3_size(E1, E2, E3)
  , ...)
|
  kzalloc(
-	(E1) * (E2) * E3
+	array3_size(E1, E2, E3)
  , ...)
|
  kzalloc(
-	(E1) * (E2) * (E3)
+	array3_size(E1, E2, E3)
  , ...)
|
  kzalloc(
-	E1 * E2 * E3
+	array3_size(E1, E2, E3)
  , ...)
)

// And then all remaining 2 factors products when they're not all constants,
// keeping sizeof() as the second factor argument.
@@
expression THING, E1, E2;
type TYPE;
constant C1, C2, C3;
@@

(
  kzalloc(sizeof(THING) * C2, ...)
|
  kzalloc(sizeof(TYPE) * C2, ...)
|
  kzalloc(C1 * C2 * C3, ...)
|
  kzalloc(C1 * C2, ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(TYPE) * (E2)
+	E2, sizeof(TYPE)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(TYPE) * E2
+	E2, sizeof(TYPE)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(THING) * (E2)
+	E2, sizeof(THING)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	sizeof(THING) * E2
+	E2, sizeof(THING)
  , ...)
|
- kzalloc
+ kcalloc
  (
-	(E1) * E2
+	E1, E2
  , ...)
|
- kzalloc
+ kcalloc
  (
-	(E1) * (E2)
+	E1, E2
  , ...)
|
- kzalloc
+ kcalloc
  (
-	E1 * E2
+	E1, E2
  , ...)
)

Signed-off-by: Kees Cook <keescook@chromium.org>
2018-06-12 16:19:22 -07:00

2192 lines
55 KiB
C

/*
* Serial Attached SCSI (SAS) Expander discovery and configuration
*
* Copyright (C) 2005 Adaptec, Inc. All rights reserved.
* Copyright (C) 2005 Luben Tuikov <luben_tuikov@adaptec.com>
*
* This file is licensed under GPLv2.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*
*/
#include <linux/scatterlist.h>
#include <linux/blkdev.h>
#include <linux/slab.h>
#include "sas_internal.h"
#include <scsi/sas_ata.h>
#include <scsi/scsi_transport.h>
#include <scsi/scsi_transport_sas.h>
#include "../scsi_sas_internal.h"
static int sas_discover_expander(struct domain_device *dev);
static int sas_configure_routing(struct domain_device *dev, u8 *sas_addr);
static int sas_configure_phy(struct domain_device *dev, int phy_id,
u8 *sas_addr, int include);
static int sas_disable_routing(struct domain_device *dev, u8 *sas_addr);
/* ---------- SMP task management ---------- */
static void smp_task_timedout(struct timer_list *t)
{
struct sas_task_slow *slow = from_timer(slow, t, timer);
struct sas_task *task = slow->task;
unsigned long flags;
spin_lock_irqsave(&task->task_state_lock, flags);
if (!(task->task_state_flags & SAS_TASK_STATE_DONE))
task->task_state_flags |= SAS_TASK_STATE_ABORTED;
spin_unlock_irqrestore(&task->task_state_lock, flags);
complete(&task->slow_task->completion);
}
static void smp_task_done(struct sas_task *task)
{
if (!del_timer(&task->slow_task->timer))
return;
complete(&task->slow_task->completion);
}
/* Give it some long enough timeout. In seconds. */
#define SMP_TIMEOUT 10
static int smp_execute_task_sg(struct domain_device *dev,
struct scatterlist *req, struct scatterlist *resp)
{
int res, retry;
struct sas_task *task = NULL;
struct sas_internal *i =
to_sas_internal(dev->port->ha->core.shost->transportt);
mutex_lock(&dev->ex_dev.cmd_mutex);
for (retry = 0; retry < 3; retry++) {
if (test_bit(SAS_DEV_GONE, &dev->state)) {
res = -ECOMM;
break;
}
task = sas_alloc_slow_task(GFP_KERNEL);
if (!task) {
res = -ENOMEM;
break;
}
task->dev = dev;
task->task_proto = dev->tproto;
task->smp_task.smp_req = *req;
task->smp_task.smp_resp = *resp;
task->task_done = smp_task_done;
task->slow_task->timer.function = smp_task_timedout;
task->slow_task->timer.expires = jiffies + SMP_TIMEOUT*HZ;
add_timer(&task->slow_task->timer);
res = i->dft->lldd_execute_task(task, GFP_KERNEL);
if (res) {
del_timer(&task->slow_task->timer);
SAS_DPRINTK("executing SMP task failed:%d\n", res);
break;
}
wait_for_completion(&task->slow_task->completion);
res = -ECOMM;
if ((task->task_state_flags & SAS_TASK_STATE_ABORTED)) {
SAS_DPRINTK("smp task timed out or aborted\n");
i->dft->lldd_abort_task(task);
if (!(task->task_state_flags & SAS_TASK_STATE_DONE)) {
SAS_DPRINTK("SMP task aborted and not done\n");
break;
}
}
if (task->task_status.resp == SAS_TASK_COMPLETE &&
task->task_status.stat == SAM_STAT_GOOD) {
res = 0;
break;
}
if (task->task_status.resp == SAS_TASK_COMPLETE &&
task->task_status.stat == SAS_DATA_UNDERRUN) {
/* no error, but return the number of bytes of
* underrun */
res = task->task_status.residual;
break;
}
if (task->task_status.resp == SAS_TASK_COMPLETE &&
task->task_status.stat == SAS_DATA_OVERRUN) {
res = -EMSGSIZE;
break;
}
if (task->task_status.resp == SAS_TASK_UNDELIVERED &&
task->task_status.stat == SAS_DEVICE_UNKNOWN)
break;
else {
SAS_DPRINTK("%s: task to dev %016llx response: 0x%x "
"status 0x%x\n", __func__,
SAS_ADDR(dev->sas_addr),
task->task_status.resp,
task->task_status.stat);
sas_free_task(task);
task = NULL;
}
}
mutex_unlock(&dev->ex_dev.cmd_mutex);
BUG_ON(retry == 3 && task != NULL);
sas_free_task(task);
return res;
}
static int smp_execute_task(struct domain_device *dev, void *req, int req_size,
void *resp, int resp_size)
{
struct scatterlist req_sg;
struct scatterlist resp_sg;
sg_init_one(&req_sg, req, req_size);
sg_init_one(&resp_sg, resp, resp_size);
return smp_execute_task_sg(dev, &req_sg, &resp_sg);
}
/* ---------- Allocations ---------- */
static inline void *alloc_smp_req(int size)
{
u8 *p = kzalloc(size, GFP_KERNEL);
if (p)
p[0] = SMP_REQUEST;
return p;
}
static inline void *alloc_smp_resp(int size)
{
return kzalloc(size, GFP_KERNEL);
}
static char sas_route_char(struct domain_device *dev, struct ex_phy *phy)
{
switch (phy->routing_attr) {
case TABLE_ROUTING:
if (dev->ex_dev.t2t_supp)
return 'U';
else
return 'T';
case DIRECT_ROUTING:
return 'D';
case SUBTRACTIVE_ROUTING:
return 'S';
default:
return '?';
}
}
static enum sas_device_type to_dev_type(struct discover_resp *dr)
{
/* This is detecting a failure to transmit initial dev to host
* FIS as described in section J.5 of sas-2 r16
*/
if (dr->attached_dev_type == SAS_PHY_UNUSED && dr->attached_sata_dev &&
dr->linkrate >= SAS_LINK_RATE_1_5_GBPS)
return SAS_SATA_PENDING;
else
return dr->attached_dev_type;
}
static void sas_set_ex_phy(struct domain_device *dev, int phy_id, void *rsp)
{
enum sas_device_type dev_type;
enum sas_linkrate linkrate;
u8 sas_addr[SAS_ADDR_SIZE];
struct smp_resp *resp = rsp;
struct discover_resp *dr = &resp->disc;
struct sas_ha_struct *ha = dev->port->ha;
struct expander_device *ex = &dev->ex_dev;
struct ex_phy *phy = &ex->ex_phy[phy_id];
struct sas_rphy *rphy = dev->rphy;
bool new_phy = !phy->phy;
char *type;
if (new_phy) {
if (WARN_ON_ONCE(test_bit(SAS_HA_ATA_EH_ACTIVE, &ha->state)))
return;
phy->phy = sas_phy_alloc(&rphy->dev, phy_id);
/* FIXME: error_handling */
BUG_ON(!phy->phy);
}
switch (resp->result) {
case SMP_RESP_PHY_VACANT:
phy->phy_state = PHY_VACANT;
break;
default:
phy->phy_state = PHY_NOT_PRESENT;
break;
case SMP_RESP_FUNC_ACC:
phy->phy_state = PHY_EMPTY; /* do not know yet */
break;
}
/* check if anything important changed to squelch debug */
dev_type = phy->attached_dev_type;
linkrate = phy->linkrate;
memcpy(sas_addr, phy->attached_sas_addr, SAS_ADDR_SIZE);
/* Handle vacant phy - rest of dr data is not valid so skip it */
if (phy->phy_state == PHY_VACANT) {
memset(phy->attached_sas_addr, 0, SAS_ADDR_SIZE);
phy->attached_dev_type = SAS_PHY_UNUSED;
if (!test_bit(SAS_HA_ATA_EH_ACTIVE, &ha->state)) {
phy->phy_id = phy_id;
goto skip;
} else
goto out;
}
phy->attached_dev_type = to_dev_type(dr);
if (test_bit(SAS_HA_ATA_EH_ACTIVE, &ha->state))
goto out;
phy->phy_id = phy_id;
phy->linkrate = dr->linkrate;
phy->attached_sata_host = dr->attached_sata_host;
phy->attached_sata_dev = dr->attached_sata_dev;
phy->attached_sata_ps = dr->attached_sata_ps;
phy->attached_iproto = dr->iproto << 1;
phy->attached_tproto = dr->tproto << 1;
/* help some expanders that fail to zero sas_address in the 'no
* device' case
*/
if (phy->attached_dev_type == SAS_PHY_UNUSED ||
phy->linkrate < SAS_LINK_RATE_1_5_GBPS)
memset(phy->attached_sas_addr, 0, SAS_ADDR_SIZE);
else
memcpy(phy->attached_sas_addr, dr->attached_sas_addr, SAS_ADDR_SIZE);
phy->attached_phy_id = dr->attached_phy_id;
phy->phy_change_count = dr->change_count;
phy->routing_attr = dr->routing_attr;
phy->virtual = dr->virtual;
phy->last_da_index = -1;
phy->phy->identify.sas_address = SAS_ADDR(phy->attached_sas_addr);
phy->phy->identify.device_type = dr->attached_dev_type;
phy->phy->identify.initiator_port_protocols = phy->attached_iproto;
phy->phy->identify.target_port_protocols = phy->attached_tproto;
if (!phy->attached_tproto && dr->attached_sata_dev)
phy->phy->identify.target_port_protocols = SAS_PROTOCOL_SATA;
phy->phy->identify.phy_identifier = phy_id;
phy->phy->minimum_linkrate_hw = dr->hmin_linkrate;
phy->phy->maximum_linkrate_hw = dr->hmax_linkrate;
phy->phy->minimum_linkrate = dr->pmin_linkrate;
phy->phy->maximum_linkrate = dr->pmax_linkrate;
phy->phy->negotiated_linkrate = phy->linkrate;
phy->phy->enabled = (phy->linkrate != SAS_PHY_DISABLED);
skip:
if (new_phy)
if (sas_phy_add(phy->phy)) {
sas_phy_free(phy->phy);
return;
}
out:
switch (phy->attached_dev_type) {
case SAS_SATA_PENDING:
type = "stp pending";
break;
case SAS_PHY_UNUSED:
type = "no device";
break;
case SAS_END_DEVICE:
if (phy->attached_iproto) {
if (phy->attached_tproto)
type = "host+target";
else
type = "host";
} else {
if (dr->attached_sata_dev)
type = "stp";
else
type = "ssp";
}
break;
case SAS_EDGE_EXPANDER_DEVICE:
case SAS_FANOUT_EXPANDER_DEVICE:
type = "smp";
break;
default:
type = "unknown";
}
/* this routine is polled by libata error recovery so filter
* unimportant messages
*/
if (new_phy || phy->attached_dev_type != dev_type ||
phy->linkrate != linkrate ||
SAS_ADDR(phy->attached_sas_addr) != SAS_ADDR(sas_addr))
/* pass */;
else
return;
/* if the attached device type changed and ata_eh is active,
* make sure we run revalidation when eh completes (see:
* sas_enable_revalidation)
*/
if (test_bit(SAS_HA_ATA_EH_ACTIVE, &ha->state))
set_bit(DISCE_REVALIDATE_DOMAIN, &dev->port->disc.pending);
SAS_DPRINTK("%sex %016llx phy%02d:%c:%X attached: %016llx (%s)\n",
test_bit(SAS_HA_ATA_EH_ACTIVE, &ha->state) ? "ata: " : "",
SAS_ADDR(dev->sas_addr), phy->phy_id,
sas_route_char(dev, phy), phy->linkrate,
SAS_ADDR(phy->attached_sas_addr), type);
}
/* check if we have an existing attached ata device on this expander phy */
struct domain_device *sas_ex_to_ata(struct domain_device *ex_dev, int phy_id)
{
struct ex_phy *ex_phy = &ex_dev->ex_dev.ex_phy[phy_id];
struct domain_device *dev;
struct sas_rphy *rphy;
if (!ex_phy->port)
return NULL;
rphy = ex_phy->port->rphy;
if (!rphy)
return NULL;
dev = sas_find_dev_by_rphy(rphy);
if (dev && dev_is_sata(dev))
return dev;
return NULL;
}
#define DISCOVER_REQ_SIZE 16
#define DISCOVER_RESP_SIZE 56
static int sas_ex_phy_discover_helper(struct domain_device *dev, u8 *disc_req,
u8 *disc_resp, int single)
{
struct discover_resp *dr;
int res;
disc_req[9] = single;
res = smp_execute_task(dev, disc_req, DISCOVER_REQ_SIZE,
disc_resp, DISCOVER_RESP_SIZE);
if (res)
return res;
dr = &((struct smp_resp *)disc_resp)->disc;
if (memcmp(dev->sas_addr, dr->attached_sas_addr, SAS_ADDR_SIZE) == 0) {
sas_printk("Found loopback topology, just ignore it!\n");
return 0;
}
sas_set_ex_phy(dev, single, disc_resp);
return 0;
}
int sas_ex_phy_discover(struct domain_device *dev, int single)
{
struct expander_device *ex = &dev->ex_dev;
int res = 0;
u8 *disc_req;
u8 *disc_resp;
disc_req = alloc_smp_req(DISCOVER_REQ_SIZE);
if (!disc_req)
return -ENOMEM;
disc_resp = alloc_smp_resp(DISCOVER_RESP_SIZE);
if (!disc_resp) {
kfree(disc_req);
return -ENOMEM;
}
disc_req[1] = SMP_DISCOVER;
if (0 <= single && single < ex->num_phys) {
res = sas_ex_phy_discover_helper(dev, disc_req, disc_resp, single);
} else {
int i;
for (i = 0; i < ex->num_phys; i++) {
res = sas_ex_phy_discover_helper(dev, disc_req,
disc_resp, i);
if (res)
goto out_err;
}
}
out_err:
kfree(disc_resp);
kfree(disc_req);
return res;
}
static int sas_expander_discover(struct domain_device *dev)
{
struct expander_device *ex = &dev->ex_dev;
int res = -ENOMEM;
ex->ex_phy = kcalloc(ex->num_phys, sizeof(*ex->ex_phy), GFP_KERNEL);
if (!ex->ex_phy)
return -ENOMEM;
res = sas_ex_phy_discover(dev, -1);
if (res)
goto out_err;
return 0;
out_err:
kfree(ex->ex_phy);
ex->ex_phy = NULL;
return res;
}
#define MAX_EXPANDER_PHYS 128
static void ex_assign_report_general(struct domain_device *dev,
struct smp_resp *resp)
{
struct report_general_resp *rg = &resp->rg;
dev->ex_dev.ex_change_count = be16_to_cpu(rg->change_count);
dev->ex_dev.max_route_indexes = be16_to_cpu(rg->route_indexes);
dev->ex_dev.num_phys = min(rg->num_phys, (u8)MAX_EXPANDER_PHYS);
dev->ex_dev.t2t_supp = rg->t2t_supp;
dev->ex_dev.conf_route_table = rg->conf_route_table;
dev->ex_dev.configuring = rg->configuring;
memcpy(dev->ex_dev.enclosure_logical_id, rg->enclosure_logical_id, 8);
}
#define RG_REQ_SIZE 8
#define RG_RESP_SIZE 32
static int sas_ex_general(struct domain_device *dev)
{
u8 *rg_req;
struct smp_resp *rg_resp;
int res;
int i;
rg_req = alloc_smp_req(RG_REQ_SIZE);
if (!rg_req)
return -ENOMEM;
rg_resp = alloc_smp_resp(RG_RESP_SIZE);
if (!rg_resp) {
kfree(rg_req);
return -ENOMEM;
}
rg_req[1] = SMP_REPORT_GENERAL;
for (i = 0; i < 5; i++) {
res = smp_execute_task(dev, rg_req, RG_REQ_SIZE, rg_resp,
RG_RESP_SIZE);
if (res) {
SAS_DPRINTK("RG to ex %016llx failed:0x%x\n",
SAS_ADDR(dev->sas_addr), res);
goto out;
} else if (rg_resp->result != SMP_RESP_FUNC_ACC) {
SAS_DPRINTK("RG:ex %016llx returned SMP result:0x%x\n",
SAS_ADDR(dev->sas_addr), rg_resp->result);
res = rg_resp->result;
goto out;
}
ex_assign_report_general(dev, rg_resp);
if (dev->ex_dev.configuring) {
SAS_DPRINTK("RG: ex %llx self-configuring...\n",
SAS_ADDR(dev->sas_addr));
schedule_timeout_interruptible(5*HZ);
} else
break;
}
out:
kfree(rg_req);
kfree(rg_resp);
return res;
}
static void ex_assign_manuf_info(struct domain_device *dev, void
*_mi_resp)
{
u8 *mi_resp = _mi_resp;
struct sas_rphy *rphy = dev->rphy;
struct sas_expander_device *edev = rphy_to_expander_device(rphy);
memcpy(edev->vendor_id, mi_resp + 12, SAS_EXPANDER_VENDOR_ID_LEN);
memcpy(edev->product_id, mi_resp + 20, SAS_EXPANDER_PRODUCT_ID_LEN);
memcpy(edev->product_rev, mi_resp + 36,
SAS_EXPANDER_PRODUCT_REV_LEN);
if (mi_resp[8] & 1) {
memcpy(edev->component_vendor_id, mi_resp + 40,
SAS_EXPANDER_COMPONENT_VENDOR_ID_LEN);
edev->component_id = mi_resp[48] << 8 | mi_resp[49];
edev->component_revision_id = mi_resp[50];
}
}
#define MI_REQ_SIZE 8
#define MI_RESP_SIZE 64
static int sas_ex_manuf_info(struct domain_device *dev)
{
u8 *mi_req;
u8 *mi_resp;
int res;
mi_req = alloc_smp_req(MI_REQ_SIZE);
if (!mi_req)
return -ENOMEM;
mi_resp = alloc_smp_resp(MI_RESP_SIZE);
if (!mi_resp) {
kfree(mi_req);
return -ENOMEM;
}
mi_req[1] = SMP_REPORT_MANUF_INFO;
res = smp_execute_task(dev, mi_req, MI_REQ_SIZE, mi_resp,MI_RESP_SIZE);
if (res) {
SAS_DPRINTK("MI: ex %016llx failed:0x%x\n",
SAS_ADDR(dev->sas_addr), res);
goto out;
} else if (mi_resp[2] != SMP_RESP_FUNC_ACC) {
SAS_DPRINTK("MI ex %016llx returned SMP result:0x%x\n",
SAS_ADDR(dev->sas_addr), mi_resp[2]);
goto out;
}
ex_assign_manuf_info(dev, mi_resp);
out:
kfree(mi_req);
kfree(mi_resp);
return res;
}
#define PC_REQ_SIZE 44
#define PC_RESP_SIZE 8
int sas_smp_phy_control(struct domain_device *dev, int phy_id,
enum phy_func phy_func,
struct sas_phy_linkrates *rates)
{
u8 *pc_req;
u8 *pc_resp;
int res;
pc_req = alloc_smp_req(PC_REQ_SIZE);
if (!pc_req)
return -ENOMEM;
pc_resp = alloc_smp_resp(PC_RESP_SIZE);
if (!pc_resp) {
kfree(pc_req);
return -ENOMEM;
}
pc_req[1] = SMP_PHY_CONTROL;
pc_req[9] = phy_id;
pc_req[10]= phy_func;
if (rates) {
pc_req[32] = rates->minimum_linkrate << 4;
pc_req[33] = rates->maximum_linkrate << 4;
}
res = smp_execute_task(dev, pc_req, PC_REQ_SIZE, pc_resp,PC_RESP_SIZE);
kfree(pc_resp);
kfree(pc_req);
return res;
}
static void sas_ex_disable_phy(struct domain_device *dev, int phy_id)
{
struct expander_device *ex = &dev->ex_dev;
struct ex_phy *phy = &ex->ex_phy[phy_id];
sas_smp_phy_control(dev, phy_id, PHY_FUNC_DISABLE, NULL);
phy->linkrate = SAS_PHY_DISABLED;
}
static void sas_ex_disable_port(struct domain_device *dev, u8 *sas_addr)
{
struct expander_device *ex = &dev->ex_dev;
int i;
for (i = 0; i < ex->num_phys; i++) {
struct ex_phy *phy = &ex->ex_phy[i];
if (phy->phy_state == PHY_VACANT ||
phy->phy_state == PHY_NOT_PRESENT)
continue;
if (SAS_ADDR(phy->attached_sas_addr) == SAS_ADDR(sas_addr))
sas_ex_disable_phy(dev, i);
}
}
static int sas_dev_present_in_domain(struct asd_sas_port *port,
u8 *sas_addr)
{
struct domain_device *dev;
if (SAS_ADDR(port->sas_addr) == SAS_ADDR(sas_addr))
return 1;
list_for_each_entry(dev, &port->dev_list, dev_list_node) {
if (SAS_ADDR(dev->sas_addr) == SAS_ADDR(sas_addr))
return 1;
}
return 0;
}
#define RPEL_REQ_SIZE 16
#define RPEL_RESP_SIZE 32
int sas_smp_get_phy_events(struct sas_phy *phy)
{
int res;
u8 *req;
u8 *resp;
struct sas_rphy *rphy = dev_to_rphy(phy->dev.parent);
struct domain_device *dev = sas_find_dev_by_rphy(rphy);
req = alloc_smp_req(RPEL_REQ_SIZE);
if (!req)
return -ENOMEM;
resp = alloc_smp_resp(RPEL_RESP_SIZE);
if (!resp) {
kfree(req);
return -ENOMEM;
}
req[1] = SMP_REPORT_PHY_ERR_LOG;
req[9] = phy->number;
res = smp_execute_task(dev, req, RPEL_REQ_SIZE,
resp, RPEL_RESP_SIZE);
if (res)
goto out;
phy->invalid_dword_count = scsi_to_u32(&resp[12]);
phy->running_disparity_error_count = scsi_to_u32(&resp[16]);
phy->loss_of_dword_sync_count = scsi_to_u32(&resp[20]);
phy->phy_reset_problem_count = scsi_to_u32(&resp[24]);
out:
kfree(req);
kfree(resp);
return res;
}
#ifdef CONFIG_SCSI_SAS_ATA
#define RPS_REQ_SIZE 16
#define RPS_RESP_SIZE 60
int sas_get_report_phy_sata(struct domain_device *dev, int phy_id,
struct smp_resp *rps_resp)
{
int res;
u8 *rps_req = alloc_smp_req(RPS_REQ_SIZE);
u8 *resp = (u8 *)rps_resp;
if (!rps_req)
return -ENOMEM;
rps_req[1] = SMP_REPORT_PHY_SATA;
rps_req[9] = phy_id;
res = smp_execute_task(dev, rps_req, RPS_REQ_SIZE,
rps_resp, RPS_RESP_SIZE);
/* 0x34 is the FIS type for the D2H fis. There's a potential
* standards cockup here. sas-2 explicitly specifies the FIS
* should be encoded so that FIS type is in resp[24].
* However, some expanders endian reverse this. Undo the
* reversal here */
if (!res && resp[27] == 0x34 && resp[24] != 0x34) {
int i;
for (i = 0; i < 5; i++) {
int j = 24 + (i*4);
u8 a, b;
a = resp[j + 0];
b = resp[j + 1];
resp[j + 0] = resp[j + 3];
resp[j + 1] = resp[j + 2];
resp[j + 2] = b;
resp[j + 3] = a;
}
}
kfree(rps_req);
return res;
}
#endif
static void sas_ex_get_linkrate(struct domain_device *parent,
struct domain_device *child,
struct ex_phy *parent_phy)
{
struct expander_device *parent_ex = &parent->ex_dev;
struct sas_port *port;
int i;
child->pathways = 0;
port = parent_phy->port;
for (i = 0; i < parent_ex->num_phys; i++) {
struct ex_phy *phy = &parent_ex->ex_phy[i];
if (phy->phy_state == PHY_VACANT ||
phy->phy_state == PHY_NOT_PRESENT)
continue;
if (SAS_ADDR(phy->attached_sas_addr) ==
SAS_ADDR(child->sas_addr)) {
child->min_linkrate = min(parent->min_linkrate,
phy->linkrate);
child->max_linkrate = max(parent->max_linkrate,
phy->linkrate);
child->pathways++;
sas_port_add_phy(port, phy->phy);
}
}
child->linkrate = min(parent_phy->linkrate, child->max_linkrate);
child->pathways = min(child->pathways, parent->pathways);
}
static struct domain_device *sas_ex_discover_end_dev(
struct domain_device *parent, int phy_id)
{
struct expander_device *parent_ex = &parent->ex_dev;
struct ex_phy *phy = &parent_ex->ex_phy[phy_id];
struct domain_device *child = NULL;
struct sas_rphy *rphy;
int res;
if (phy->attached_sata_host || phy->attached_sata_ps)
return NULL;
child = sas_alloc_device();
if (!child)
return NULL;
kref_get(&parent->kref);
child->parent = parent;
child->port = parent->port;
child->iproto = phy->attached_iproto;
memcpy(child->sas_addr, phy->attached_sas_addr, SAS_ADDR_SIZE);
sas_hash_addr(child->hashed_sas_addr, child->sas_addr);
if (!phy->port) {
phy->port = sas_port_alloc(&parent->rphy->dev, phy_id);
if (unlikely(!phy->port))
goto out_err;
if (unlikely(sas_port_add(phy->port) != 0)) {
sas_port_free(phy->port);
goto out_err;
}
}
sas_ex_get_linkrate(parent, child, phy);
sas_device_set_phy(child, phy->port);
#ifdef CONFIG_SCSI_SAS_ATA
if ((phy->attached_tproto & SAS_PROTOCOL_STP) || phy->attached_sata_dev) {
res = sas_get_ata_info(child, phy);
if (res)
goto out_free;
sas_init_dev(child);
res = sas_ata_init(child);
if (res)
goto out_free;
rphy = sas_end_device_alloc(phy->port);
if (!rphy)
goto out_free;
child->rphy = rphy;
get_device(&rphy->dev);
list_add_tail(&child->disco_list_node, &parent->port->disco_list);
res = sas_discover_sata(child);
if (res) {
SAS_DPRINTK("sas_discover_sata() for device %16llx at "
"%016llx:0x%x returned 0x%x\n",
SAS_ADDR(child->sas_addr),
SAS_ADDR(parent->sas_addr), phy_id, res);
goto out_list_del;
}
} else
#endif
if (phy->attached_tproto & SAS_PROTOCOL_SSP) {
child->dev_type = SAS_END_DEVICE;
rphy = sas_end_device_alloc(phy->port);
/* FIXME: error handling */
if (unlikely(!rphy))
goto out_free;
child->tproto = phy->attached_tproto;
sas_init_dev(child);
child->rphy = rphy;
get_device(&rphy->dev);
sas_fill_in_rphy(child, rphy);
list_add_tail(&child->disco_list_node, &parent->port->disco_list);
res = sas_discover_end_dev(child);
if (res) {
SAS_DPRINTK("sas_discover_end_dev() for device %16llx "
"at %016llx:0x%x returned 0x%x\n",
SAS_ADDR(child->sas_addr),
SAS_ADDR(parent->sas_addr), phy_id, res);
goto out_list_del;
}
} else {
SAS_DPRINTK("target proto 0x%x at %016llx:0x%x not handled\n",
phy->attached_tproto, SAS_ADDR(parent->sas_addr),
phy_id);
goto out_free;
}
list_add_tail(&child->siblings, &parent_ex->children);
return child;
out_list_del:
sas_rphy_free(child->rphy);
list_del(&child->disco_list_node);
spin_lock_irq(&parent->port->dev_list_lock);
list_del(&child->dev_list_node);
spin_unlock_irq(&parent->port->dev_list_lock);
out_free:
sas_port_delete(phy->port);
out_err:
phy->port = NULL;
sas_put_device(child);
return NULL;
}
/* See if this phy is part of a wide port */
static bool sas_ex_join_wide_port(struct domain_device *parent, int phy_id)
{
struct ex_phy *phy = &parent->ex_dev.ex_phy[phy_id];
int i;
for (i = 0; i < parent->ex_dev.num_phys; i++) {
struct ex_phy *ephy = &parent->ex_dev.ex_phy[i];
if (ephy == phy)
continue;
if (!memcmp(phy->attached_sas_addr, ephy->attached_sas_addr,
SAS_ADDR_SIZE) && ephy->port) {
sas_port_add_phy(ephy->port, phy->phy);
phy->port = ephy->port;
phy->phy_state = PHY_DEVICE_DISCOVERED;
return true;
}
}
return false;
}
static struct domain_device *sas_ex_discover_expander(
struct domain_device *parent, int phy_id)
{
struct sas_expander_device *parent_ex = rphy_to_expander_device(parent->rphy);
struct ex_phy *phy = &parent->ex_dev.ex_phy[phy_id];
struct domain_device *child = NULL;
struct sas_rphy *rphy;
struct sas_expander_device *edev;
struct asd_sas_port *port;
int res;
if (phy->routing_attr == DIRECT_ROUTING) {
SAS_DPRINTK("ex %016llx:0x%x:D <--> ex %016llx:0x%x is not "
"allowed\n",
SAS_ADDR(parent->sas_addr), phy_id,
SAS_ADDR(phy->attached_sas_addr),
phy->attached_phy_id);
return NULL;
}
child = sas_alloc_device();
if (!child)
return NULL;
phy->port = sas_port_alloc(&parent->rphy->dev, phy_id);
/* FIXME: better error handling */
BUG_ON(sas_port_add(phy->port) != 0);
switch (phy->attached_dev_type) {
case SAS_EDGE_EXPANDER_DEVICE:
rphy = sas_expander_alloc(phy->port,
SAS_EDGE_EXPANDER_DEVICE);
break;
case SAS_FANOUT_EXPANDER_DEVICE:
rphy = sas_expander_alloc(phy->port,
SAS_FANOUT_EXPANDER_DEVICE);
break;
default:
rphy = NULL; /* shut gcc up */
BUG();
}
port = parent->port;
child->rphy = rphy;
get_device(&rphy->dev);
edev = rphy_to_expander_device(rphy);
child->dev_type = phy->attached_dev_type;
kref_get(&parent->kref);
child->parent = parent;
child->port = port;
child->iproto = phy->attached_iproto;
child->tproto = phy->attached_tproto;
memcpy(child->sas_addr, phy->attached_sas_addr, SAS_ADDR_SIZE);
sas_hash_addr(child->hashed_sas_addr, child->sas_addr);
sas_ex_get_linkrate(parent, child, phy);
edev->level = parent_ex->level + 1;
parent->port->disc.max_level = max(parent->port->disc.max_level,
edev->level);
sas_init_dev(child);
sas_fill_in_rphy(child, rphy);
sas_rphy_add(rphy);
spin_lock_irq(&parent->port->dev_list_lock);
list_add_tail(&child->dev_list_node, &parent->port->dev_list);
spin_unlock_irq(&parent->port->dev_list_lock);
res = sas_discover_expander(child);
if (res) {
sas_rphy_delete(rphy);
spin_lock_irq(&parent->port->dev_list_lock);
list_del(&child->dev_list_node);
spin_unlock_irq(&parent->port->dev_list_lock);
sas_put_device(child);
return NULL;
}
list_add_tail(&child->siblings, &parent->ex_dev.children);
return child;
}
static int sas_ex_discover_dev(struct domain_device *dev, int phy_id)
{
struct expander_device *ex = &dev->ex_dev;
struct ex_phy *ex_phy = &ex->ex_phy[phy_id];
struct domain_device *child = NULL;
int res = 0;
/* Phy state */
if (ex_phy->linkrate == SAS_SATA_SPINUP_HOLD) {
if (!sas_smp_phy_control(dev, phy_id, PHY_FUNC_LINK_RESET, NULL))
res = sas_ex_phy_discover(dev, phy_id);
if (res)
return res;
}
/* Parent and domain coherency */
if (!dev->parent && (SAS_ADDR(ex_phy->attached_sas_addr) ==
SAS_ADDR(dev->port->sas_addr))) {
sas_add_parent_port(dev, phy_id);
return 0;
}
if (dev->parent && (SAS_ADDR(ex_phy->attached_sas_addr) ==
SAS_ADDR(dev->parent->sas_addr))) {
sas_add_parent_port(dev, phy_id);
if (ex_phy->routing_attr == TABLE_ROUTING)
sas_configure_phy(dev, phy_id, dev->port->sas_addr, 1);
return 0;
}
if (sas_dev_present_in_domain(dev->port, ex_phy->attached_sas_addr))
sas_ex_disable_port(dev, ex_phy->attached_sas_addr);
if (ex_phy->attached_dev_type == SAS_PHY_UNUSED) {
if (ex_phy->routing_attr == DIRECT_ROUTING) {
memset(ex_phy->attached_sas_addr, 0, SAS_ADDR_SIZE);
sas_configure_routing(dev, ex_phy->attached_sas_addr);
}
return 0;
} else if (ex_phy->linkrate == SAS_LINK_RATE_UNKNOWN)
return 0;
if (ex_phy->attached_dev_type != SAS_END_DEVICE &&
ex_phy->attached_dev_type != SAS_FANOUT_EXPANDER_DEVICE &&
ex_phy->attached_dev_type != SAS_EDGE_EXPANDER_DEVICE &&
ex_phy->attached_dev_type != SAS_SATA_PENDING) {
SAS_DPRINTK("unknown device type(0x%x) attached to ex %016llx "
"phy 0x%x\n", ex_phy->attached_dev_type,
SAS_ADDR(dev->sas_addr),
phy_id);
return 0;
}
res = sas_configure_routing(dev, ex_phy->attached_sas_addr);
if (res) {
SAS_DPRINTK("configure routing for dev %016llx "
"reported 0x%x. Forgotten\n",
SAS_ADDR(ex_phy->attached_sas_addr), res);
sas_disable_routing(dev, ex_phy->attached_sas_addr);
return res;
}
if (sas_ex_join_wide_port(dev, phy_id)) {
SAS_DPRINTK("Attaching ex phy%d to wide port %016llx\n",
phy_id, SAS_ADDR(ex_phy->attached_sas_addr));
return res;
}
switch (ex_phy->attached_dev_type) {
case SAS_END_DEVICE:
case SAS_SATA_PENDING:
child = sas_ex_discover_end_dev(dev, phy_id);
break;
case SAS_FANOUT_EXPANDER_DEVICE:
if (SAS_ADDR(dev->port->disc.fanout_sas_addr)) {
SAS_DPRINTK("second fanout expander %016llx phy 0x%x "
"attached to ex %016llx phy 0x%x\n",
SAS_ADDR(ex_phy->attached_sas_addr),
ex_phy->attached_phy_id,
SAS_ADDR(dev->sas_addr),
phy_id);
sas_ex_disable_phy(dev, phy_id);
break;
} else
memcpy(dev->port->disc.fanout_sas_addr,
ex_phy->attached_sas_addr, SAS_ADDR_SIZE);
/* fallthrough */
case SAS_EDGE_EXPANDER_DEVICE:
child = sas_ex_discover_expander(dev, phy_id);
break;
default:
break;
}
if (child) {
int i;
for (i = 0; i < ex->num_phys; i++) {
if (ex->ex_phy[i].phy_state == PHY_VACANT ||
ex->ex_phy[i].phy_state == PHY_NOT_PRESENT)
continue;
/*
* Due to races, the phy might not get added to the
* wide port, so we add the phy to the wide port here.
*/
if (SAS_ADDR(ex->ex_phy[i].attached_sas_addr) ==
SAS_ADDR(child->sas_addr)) {
ex->ex_phy[i].phy_state= PHY_DEVICE_DISCOVERED;
if (sas_ex_join_wide_port(dev, i))
SAS_DPRINTK("Attaching ex phy%d to wide port %016llx\n",
i, SAS_ADDR(ex->ex_phy[i].attached_sas_addr));
}
}
}
return res;
}
static int sas_find_sub_addr(struct domain_device *dev, u8 *sub_addr)
{
struct expander_device *ex = &dev->ex_dev;
int i;
for (i = 0; i < ex->num_phys; i++) {
struct ex_phy *phy = &ex->ex_phy[i];
if (phy->phy_state == PHY_VACANT ||
phy->phy_state == PHY_NOT_PRESENT)
continue;
if ((phy->attached_dev_type == SAS_EDGE_EXPANDER_DEVICE ||
phy->attached_dev_type == SAS_FANOUT_EXPANDER_DEVICE) &&
phy->routing_attr == SUBTRACTIVE_ROUTING) {
memcpy(sub_addr, phy->attached_sas_addr,SAS_ADDR_SIZE);
return 1;
}
}
return 0;
}
static int sas_check_level_subtractive_boundary(struct domain_device *dev)
{
struct expander_device *ex = &dev->ex_dev;
struct domain_device *child;
u8 sub_addr[8] = {0, };
list_for_each_entry(child, &ex->children, siblings) {
if (child->dev_type != SAS_EDGE_EXPANDER_DEVICE &&
child->dev_type != SAS_FANOUT_EXPANDER_DEVICE)
continue;
if (sub_addr[0] == 0) {
sas_find_sub_addr(child, sub_addr);
continue;
} else {
u8 s2[8];
if (sas_find_sub_addr(child, s2) &&
(SAS_ADDR(sub_addr) != SAS_ADDR(s2))) {
SAS_DPRINTK("ex %016llx->%016llx-?->%016llx "
"diverges from subtractive "
"boundary %016llx\n",
SAS_ADDR(dev->sas_addr),
SAS_ADDR(child->sas_addr),
SAS_ADDR(s2),
SAS_ADDR(sub_addr));
sas_ex_disable_port(child, s2);
}
}
}
return 0;
}
/**
* sas_ex_discover_devices - discover devices attached to this expander
* @dev: pointer to the expander domain device
* @single: if you want to do a single phy, else set to -1;
*
* Configure this expander for use with its devices and register the
* devices of this expander.
*/
static int sas_ex_discover_devices(struct domain_device *dev, int single)
{
struct expander_device *ex = &dev->ex_dev;
int i = 0, end = ex->num_phys;
int res = 0;
if (0 <= single && single < end) {
i = single;
end = i+1;
}
for ( ; i < end; i++) {
struct ex_phy *ex_phy = &ex->ex_phy[i];
if (ex_phy->phy_state == PHY_VACANT ||
ex_phy->phy_state == PHY_NOT_PRESENT ||
ex_phy->phy_state == PHY_DEVICE_DISCOVERED)
continue;
switch (ex_phy->linkrate) {
case SAS_PHY_DISABLED:
case SAS_PHY_RESET_PROBLEM:
case SAS_SATA_PORT_SELECTOR:
continue;
default:
res = sas_ex_discover_dev(dev, i);
if (res)
break;
continue;
}
}
if (!res)
sas_check_level_subtractive_boundary(dev);
return res;
}
static int sas_check_ex_subtractive_boundary(struct domain_device *dev)
{
struct expander_device *ex = &dev->ex_dev;
int i;
u8 *sub_sas_addr = NULL;
if (dev->dev_type != SAS_EDGE_EXPANDER_DEVICE)
return 0;
for (i = 0; i < ex->num_phys; i++) {
struct ex_phy *phy = &ex->ex_phy[i];
if (phy->phy_state == PHY_VACANT ||
phy->phy_state == PHY_NOT_PRESENT)
continue;
if ((phy->attached_dev_type == SAS_FANOUT_EXPANDER_DEVICE ||
phy->attached_dev_type == SAS_EDGE_EXPANDER_DEVICE) &&
phy->routing_attr == SUBTRACTIVE_ROUTING) {
if (!sub_sas_addr)
sub_sas_addr = &phy->attached_sas_addr[0];
else if (SAS_ADDR(sub_sas_addr) !=
SAS_ADDR(phy->attached_sas_addr)) {
SAS_DPRINTK("ex %016llx phy 0x%x "
"diverges(%016llx) on subtractive "
"boundary(%016llx). Disabled\n",
SAS_ADDR(dev->sas_addr), i,
SAS_ADDR(phy->attached_sas_addr),
SAS_ADDR(sub_sas_addr));
sas_ex_disable_phy(dev, i);
}
}
}
return 0;
}
static void sas_print_parent_topology_bug(struct domain_device *child,
struct ex_phy *parent_phy,
struct ex_phy *child_phy)
{
static const char *ex_type[] = {
[SAS_EDGE_EXPANDER_DEVICE] = "edge",
[SAS_FANOUT_EXPANDER_DEVICE] = "fanout",
};
struct domain_device *parent = child->parent;
sas_printk("%s ex %016llx phy 0x%x <--> %s ex %016llx "
"phy 0x%x has %c:%c routing link!\n",
ex_type[parent->dev_type],
SAS_ADDR(parent->sas_addr),
parent_phy->phy_id,
ex_type[child->dev_type],
SAS_ADDR(child->sas_addr),
child_phy->phy_id,
sas_route_char(parent, parent_phy),
sas_route_char(child, child_phy));
}
static int sas_check_eeds(struct domain_device *child,
struct ex_phy *parent_phy,
struct ex_phy *child_phy)
{
int res = 0;
struct domain_device *parent = child->parent;
if (SAS_ADDR(parent->port->disc.fanout_sas_addr) != 0) {
res = -ENODEV;
SAS_DPRINTK("edge ex %016llx phy S:0x%x <--> edge ex %016llx "
"phy S:0x%x, while there is a fanout ex %016llx\n",
SAS_ADDR(parent->sas_addr),
parent_phy->phy_id,
SAS_ADDR(child->sas_addr),
child_phy->phy_id,
SAS_ADDR(parent->port->disc.fanout_sas_addr));
} else if (SAS_ADDR(parent->port->disc.eeds_a) == 0) {
memcpy(parent->port->disc.eeds_a, parent->sas_addr,
SAS_ADDR_SIZE);
memcpy(parent->port->disc.eeds_b, child->sas_addr,
SAS_ADDR_SIZE);
} else if (((SAS_ADDR(parent->port->disc.eeds_a) ==
SAS_ADDR(parent->sas_addr)) ||
(SAS_ADDR(parent->port->disc.eeds_a) ==
SAS_ADDR(child->sas_addr)))
&&
((SAS_ADDR(parent->port->disc.eeds_b) ==
SAS_ADDR(parent->sas_addr)) ||
(SAS_ADDR(parent->port->disc.eeds_b) ==
SAS_ADDR(child->sas_addr))))
;
else {
res = -ENODEV;
SAS_DPRINTK("edge ex %016llx phy 0x%x <--> edge ex %016llx "
"phy 0x%x link forms a third EEDS!\n",
SAS_ADDR(parent->sas_addr),
parent_phy->phy_id,
SAS_ADDR(child->sas_addr),
child_phy->phy_id);
}
return res;
}
/* Here we spill over 80 columns. It is intentional.
*/
static int sas_check_parent_topology(struct domain_device *child)
{
struct expander_device *child_ex = &child->ex_dev;
struct expander_device *parent_ex;
int i;
int res = 0;
if (!child->parent)
return 0;
if (child->parent->dev_type != SAS_EDGE_EXPANDER_DEVICE &&
child->parent->dev_type != SAS_FANOUT_EXPANDER_DEVICE)
return 0;
parent_ex = &child->parent->ex_dev;
for (i = 0; i < parent_ex->num_phys; i++) {
struct ex_phy *parent_phy = &parent_ex->ex_phy[i];
struct ex_phy *child_phy;
if (parent_phy->phy_state == PHY_VACANT ||
parent_phy->phy_state == PHY_NOT_PRESENT)
continue;
if (SAS_ADDR(parent_phy->attached_sas_addr) != SAS_ADDR(child->sas_addr))
continue;
child_phy = &child_ex->ex_phy[parent_phy->attached_phy_id];
switch (child->parent->dev_type) {
case SAS_EDGE_EXPANDER_DEVICE:
if (child->dev_type == SAS_FANOUT_EXPANDER_DEVICE) {
if (parent_phy->routing_attr != SUBTRACTIVE_ROUTING ||
child_phy->routing_attr != TABLE_ROUTING) {
sas_print_parent_topology_bug(child, parent_phy, child_phy);
res = -ENODEV;
}
} else if (parent_phy->routing_attr == SUBTRACTIVE_ROUTING) {
if (child_phy->routing_attr == SUBTRACTIVE_ROUTING) {
res = sas_check_eeds(child, parent_phy, child_phy);
} else if (child_phy->routing_attr != TABLE_ROUTING) {
sas_print_parent_topology_bug(child, parent_phy, child_phy);
res = -ENODEV;
}
} else if (parent_phy->routing_attr == TABLE_ROUTING) {
if (child_phy->routing_attr == SUBTRACTIVE_ROUTING ||
(child_phy->routing_attr == TABLE_ROUTING &&
child_ex->t2t_supp && parent_ex->t2t_supp)) {
/* All good */;
} else {
sas_print_parent_topology_bug(child, parent_phy, child_phy);
res = -ENODEV;
}
}
break;
case SAS_FANOUT_EXPANDER_DEVICE:
if (parent_phy->routing_attr != TABLE_ROUTING ||
child_phy->routing_attr != SUBTRACTIVE_ROUTING) {
sas_print_parent_topology_bug(child, parent_phy, child_phy);
res = -ENODEV;
}
break;
default:
break;
}
}
return res;
}
#define RRI_REQ_SIZE 16
#define RRI_RESP_SIZE 44
static int sas_configure_present(struct domain_device *dev, int phy_id,
u8 *sas_addr, int *index, int *present)
{
int i, res = 0;
struct expander_device *ex = &dev->ex_dev;
struct ex_phy *phy = &ex->ex_phy[phy_id];
u8 *rri_req;
u8 *rri_resp;
*present = 0;
*index = 0;
rri_req = alloc_smp_req(RRI_REQ_SIZE);
if (!rri_req)
return -ENOMEM;
rri_resp = alloc_smp_resp(RRI_RESP_SIZE);
if (!rri_resp) {
kfree(rri_req);
return -ENOMEM;
}
rri_req[1] = SMP_REPORT_ROUTE_INFO;
rri_req[9] = phy_id;
for (i = 0; i < ex->max_route_indexes ; i++) {
*(__be16 *)(rri_req+6) = cpu_to_be16(i);
res = smp_execute_task(dev, rri_req, RRI_REQ_SIZE, rri_resp,
RRI_RESP_SIZE);
if (res)
goto out;
res = rri_resp[2];
if (res == SMP_RESP_NO_INDEX) {
SAS_DPRINTK("overflow of indexes: dev %016llx "
"phy 0x%x index 0x%x\n",
SAS_ADDR(dev->sas_addr), phy_id, i);
goto out;
} else if (res != SMP_RESP_FUNC_ACC) {
SAS_DPRINTK("%s: dev %016llx phy 0x%x index 0x%x "
"result 0x%x\n", __func__,
SAS_ADDR(dev->sas_addr), phy_id, i, res);
goto out;
}
if (SAS_ADDR(sas_addr) != 0) {
if (SAS_ADDR(rri_resp+16) == SAS_ADDR(sas_addr)) {
*index = i;
if ((rri_resp[12] & 0x80) == 0x80)
*present = 0;
else
*present = 1;
goto out;
} else if (SAS_ADDR(rri_resp+16) == 0) {
*index = i;
*present = 0;
goto out;
}
} else if (SAS_ADDR(rri_resp+16) == 0 &&
phy->last_da_index < i) {
phy->last_da_index = i;
*index = i;
*present = 0;
goto out;
}
}
res = -1;
out:
kfree(rri_req);
kfree(rri_resp);
return res;
}
#define CRI_REQ_SIZE 44
#define CRI_RESP_SIZE 8
static int sas_configure_set(struct domain_device *dev, int phy_id,
u8 *sas_addr, int index, int include)
{
int res;
u8 *cri_req;
u8 *cri_resp;
cri_req = alloc_smp_req(CRI_REQ_SIZE);
if (!cri_req)
return -ENOMEM;
cri_resp = alloc_smp_resp(CRI_RESP_SIZE);
if (!cri_resp) {
kfree(cri_req);
return -ENOMEM;
}
cri_req[1] = SMP_CONF_ROUTE_INFO;
*(__be16 *)(cri_req+6) = cpu_to_be16(index);
cri_req[9] = phy_id;
if (SAS_ADDR(sas_addr) == 0 || !include)
cri_req[12] |= 0x80;
memcpy(cri_req+16, sas_addr, SAS_ADDR_SIZE);
res = smp_execute_task(dev, cri_req, CRI_REQ_SIZE, cri_resp,
CRI_RESP_SIZE);
if (res)
goto out;
res = cri_resp[2];
if (res == SMP_RESP_NO_INDEX) {
SAS_DPRINTK("overflow of indexes: dev %016llx phy 0x%x "
"index 0x%x\n",
SAS_ADDR(dev->sas_addr), phy_id, index);
}
out:
kfree(cri_req);
kfree(cri_resp);
return res;
}
static int sas_configure_phy(struct domain_device *dev, int phy_id,
u8 *sas_addr, int include)
{
int index;
int present;
int res;
res = sas_configure_present(dev, phy_id, sas_addr, &index, &present);
if (res)
return res;
if (include ^ present)
return sas_configure_set(dev, phy_id, sas_addr, index,include);
return res;
}
/**
* sas_configure_parent - configure routing table of parent
* @parent: parent expander
* @child: child expander
* @sas_addr: SAS port identifier of device directly attached to child
* @include: whether or not to include @child in the expander routing table
*/
static int sas_configure_parent(struct domain_device *parent,
struct domain_device *child,
u8 *sas_addr, int include)
{
struct expander_device *ex_parent = &parent->ex_dev;
int res = 0;
int i;
if (parent->parent) {
res = sas_configure_parent(parent->parent, parent, sas_addr,
include);
if (res)
return res;
}
if (ex_parent->conf_route_table == 0) {
SAS_DPRINTK("ex %016llx has self-configuring routing table\n",
SAS_ADDR(parent->sas_addr));
return 0;
}
for (i = 0; i < ex_parent->num_phys; i++) {
struct ex_phy *phy = &ex_parent->ex_phy[i];
if ((phy->routing_attr == TABLE_ROUTING) &&
(SAS_ADDR(phy->attached_sas_addr) ==
SAS_ADDR(child->sas_addr))) {
res = sas_configure_phy(parent, i, sas_addr, include);
if (res)
return res;
}
}
return res;
}
/**
* sas_configure_routing - configure routing
* @dev: expander device
* @sas_addr: port identifier of device directly attached to the expander device
*/
static int sas_configure_routing(struct domain_device *dev, u8 *sas_addr)
{
if (dev->parent)
return sas_configure_parent(dev->parent, dev, sas_addr, 1);
return 0;
}
static int sas_disable_routing(struct domain_device *dev, u8 *sas_addr)
{
if (dev->parent)
return sas_configure_parent(dev->parent, dev, sas_addr, 0);
return 0;
}
/**
* sas_discover_expander - expander discovery
* @dev: pointer to expander domain device
*
* See comment in sas_discover_sata().
*/
static int sas_discover_expander(struct domain_device *dev)
{
int res;
res = sas_notify_lldd_dev_found(dev);
if (res)
return res;
res = sas_ex_general(dev);
if (res)
goto out_err;
res = sas_ex_manuf_info(dev);
if (res)
goto out_err;
res = sas_expander_discover(dev);
if (res) {
SAS_DPRINTK("expander %016llx discovery failed(0x%x)\n",
SAS_ADDR(dev->sas_addr), res);
goto out_err;
}
sas_check_ex_subtractive_boundary(dev);
res = sas_check_parent_topology(dev);
if (res)
goto out_err;
return 0;
out_err:
sas_notify_lldd_dev_gone(dev);
return res;
}
static int sas_ex_level_discovery(struct asd_sas_port *port, const int level)
{
int res = 0;
struct domain_device *dev;
list_for_each_entry(dev, &port->dev_list, dev_list_node) {
if (dev->dev_type == SAS_EDGE_EXPANDER_DEVICE ||
dev->dev_type == SAS_FANOUT_EXPANDER_DEVICE) {
struct sas_expander_device *ex =
rphy_to_expander_device(dev->rphy);
if (level == ex->level)
res = sas_ex_discover_devices(dev, -1);
else if (level > 0)
res = sas_ex_discover_devices(port->port_dev, -1);
}
}
return res;
}
static int sas_ex_bfs_disc(struct asd_sas_port *port)
{
int res;
int level;
do {
level = port->disc.max_level;
res = sas_ex_level_discovery(port, level);
mb();
} while (level < port->disc.max_level);
return res;
}
int sas_discover_root_expander(struct domain_device *dev)
{
int res;
struct sas_expander_device *ex = rphy_to_expander_device(dev->rphy);
res = sas_rphy_add(dev->rphy);
if (res)
goto out_err;
ex->level = dev->port->disc.max_level; /* 0 */
res = sas_discover_expander(dev);
if (res)
goto out_err2;
sas_ex_bfs_disc(dev->port);
return res;
out_err2:
sas_rphy_remove(dev->rphy);
out_err:
return res;
}
/* ---------- Domain revalidation ---------- */
static int sas_get_phy_discover(struct domain_device *dev,
int phy_id, struct smp_resp *disc_resp)
{
int res;
u8 *disc_req;
disc_req = alloc_smp_req(DISCOVER_REQ_SIZE);
if (!disc_req)
return -ENOMEM;
disc_req[1] = SMP_DISCOVER;
disc_req[9] = phy_id;
res = smp_execute_task(dev, disc_req, DISCOVER_REQ_SIZE,
disc_resp, DISCOVER_RESP_SIZE);
if (res)
goto out;
else if (disc_resp->result != SMP_RESP_FUNC_ACC) {
res = disc_resp->result;
goto out;
}
out:
kfree(disc_req);
return res;
}
static int sas_get_phy_change_count(struct domain_device *dev,
int phy_id, int *pcc)
{
int res;
struct smp_resp *disc_resp;
disc_resp = alloc_smp_resp(DISCOVER_RESP_SIZE);
if (!disc_resp)
return -ENOMEM;
res = sas_get_phy_discover(dev, phy_id, disc_resp);
if (!res)
*pcc = disc_resp->disc.change_count;
kfree(disc_resp);
return res;
}
static int sas_get_phy_attached_dev(struct domain_device *dev, int phy_id,
u8 *sas_addr, enum sas_device_type *type)
{
int res;
struct smp_resp *disc_resp;
struct discover_resp *dr;
disc_resp = alloc_smp_resp(DISCOVER_RESP_SIZE);
if (!disc_resp)
return -ENOMEM;
dr = &disc_resp->disc;
res = sas_get_phy_discover(dev, phy_id, disc_resp);
if (res == 0) {
memcpy(sas_addr, disc_resp->disc.attached_sas_addr, 8);
*type = to_dev_type(dr);
if (*type == 0)
memset(sas_addr, 0, 8);
}
kfree(disc_resp);
return res;
}
static int sas_find_bcast_phy(struct domain_device *dev, int *phy_id,
int from_phy, bool update)
{
struct expander_device *ex = &dev->ex_dev;
int res = 0;
int i;
for (i = from_phy; i < ex->num_phys; i++) {
int phy_change_count = 0;
res = sas_get_phy_change_count(dev, i, &phy_change_count);
switch (res) {
case SMP_RESP_PHY_VACANT:
case SMP_RESP_NO_PHY:
continue;
case SMP_RESP_FUNC_ACC:
break;
default:
return res;
}
if (phy_change_count != ex->ex_phy[i].phy_change_count) {
if (update)
ex->ex_phy[i].phy_change_count =
phy_change_count;
*phy_id = i;
return 0;
}
}
return 0;
}
static int sas_get_ex_change_count(struct domain_device *dev, int *ecc)
{
int res;
u8 *rg_req;
struct smp_resp *rg_resp;
rg_req = alloc_smp_req(RG_REQ_SIZE);
if (!rg_req)
return -ENOMEM;
rg_resp = alloc_smp_resp(RG_RESP_SIZE);
if (!rg_resp) {
kfree(rg_req);
return -ENOMEM;
}
rg_req[1] = SMP_REPORT_GENERAL;
res = smp_execute_task(dev, rg_req, RG_REQ_SIZE, rg_resp,
RG_RESP_SIZE);
if (res)
goto out;
if (rg_resp->result != SMP_RESP_FUNC_ACC) {
res = rg_resp->result;
goto out;
}
*ecc = be16_to_cpu(rg_resp->rg.change_count);
out:
kfree(rg_resp);
kfree(rg_req);
return res;
}
/**
* sas_find_bcast_dev - find the device issue BROADCAST(CHANGE).
* @dev:domain device to be detect.
* @src_dev: the device which originated BROADCAST(CHANGE).
*
* Add self-configuration expander support. Suppose two expander cascading,
* when the first level expander is self-configuring, hotplug the disks in
* second level expander, BROADCAST(CHANGE) will not only be originated
* in the second level expander, but also be originated in the first level
* expander (see SAS protocol SAS 2r-14, 7.11 for detail), it is to say,
* expander changed count in two level expanders will all increment at least
* once, but the phy which chang count has changed is the source device which
* we concerned.
*/
static int sas_find_bcast_dev(struct domain_device *dev,
struct domain_device **src_dev)
{
struct expander_device *ex = &dev->ex_dev;
int ex_change_count = -1;
int phy_id = -1;
int res;
struct domain_device *ch;
res = sas_get_ex_change_count(dev, &ex_change_count);
if (res)
goto out;
if (ex_change_count != -1 && ex_change_count != ex->ex_change_count) {
/* Just detect if this expander phys phy change count changed,
* in order to determine if this expander originate BROADCAST,
* and do not update phy change count field in our structure.
*/
res = sas_find_bcast_phy(dev, &phy_id, 0, false);
if (phy_id != -1) {
*src_dev = dev;
ex->ex_change_count = ex_change_count;
SAS_DPRINTK("Expander phy change count has changed\n");
return res;
} else
SAS_DPRINTK("Expander phys DID NOT change\n");
}
list_for_each_entry(ch, &ex->children, siblings) {
if (ch->dev_type == SAS_EDGE_EXPANDER_DEVICE || ch->dev_type == SAS_FANOUT_EXPANDER_DEVICE) {
res = sas_find_bcast_dev(ch, src_dev);
if (*src_dev)
return res;
}
}
out:
return res;
}
static void sas_unregister_ex_tree(struct asd_sas_port *port, struct domain_device *dev)
{
struct expander_device *ex = &dev->ex_dev;
struct domain_device *child, *n;
list_for_each_entry_safe(child, n, &ex->children, siblings) {
set_bit(SAS_DEV_GONE, &child->state);
if (child->dev_type == SAS_EDGE_EXPANDER_DEVICE ||
child->dev_type == SAS_FANOUT_EXPANDER_DEVICE)
sas_unregister_ex_tree(port, child);
else
sas_unregister_dev(port, child);
}
sas_unregister_dev(port, dev);
}
static void sas_unregister_devs_sas_addr(struct domain_device *parent,
int phy_id, bool last)
{
struct expander_device *ex_dev = &parent->ex_dev;
struct ex_phy *phy = &ex_dev->ex_phy[phy_id];
struct domain_device *child, *n, *found = NULL;
if (last) {
list_for_each_entry_safe(child, n,
&ex_dev->children, siblings) {
if (SAS_ADDR(child->sas_addr) ==
SAS_ADDR(phy->attached_sas_addr)) {
set_bit(SAS_DEV_GONE, &child->state);
if (child->dev_type == SAS_EDGE_EXPANDER_DEVICE ||
child->dev_type == SAS_FANOUT_EXPANDER_DEVICE)
sas_unregister_ex_tree(parent->port, child);
else
sas_unregister_dev(parent->port, child);
found = child;
break;
}
}
sas_disable_routing(parent, phy->attached_sas_addr);
}
memset(phy->attached_sas_addr, 0, SAS_ADDR_SIZE);
if (phy->port) {
sas_port_delete_phy(phy->port, phy->phy);
sas_device_set_phy(found, phy->port);
if (phy->port->num_phys == 0)
list_add_tail(&phy->port->del_list,
&parent->port->sas_port_del_list);
phy->port = NULL;
}
}
static int sas_discover_bfs_by_root_level(struct domain_device *root,
const int level)
{
struct expander_device *ex_root = &root->ex_dev;
struct domain_device *child;
int res = 0;
list_for_each_entry(child, &ex_root->children, siblings) {
if (child->dev_type == SAS_EDGE_EXPANDER_DEVICE ||
child->dev_type == SAS_FANOUT_EXPANDER_DEVICE) {
struct sas_expander_device *ex =
rphy_to_expander_device(child->rphy);
if (level > ex->level)
res = sas_discover_bfs_by_root_level(child,
level);
else if (level == ex->level)
res = sas_ex_discover_devices(child, -1);
}
}
return res;
}
static int sas_discover_bfs_by_root(struct domain_device *dev)
{
int res;
struct sas_expander_device *ex = rphy_to_expander_device(dev->rphy);
int level = ex->level+1;
res = sas_ex_discover_devices(dev, -1);
if (res)
goto out;
do {
res = sas_discover_bfs_by_root_level(dev, level);
mb();
level += 1;
} while (level <= dev->port->disc.max_level);
out:
return res;
}
static int sas_discover_new(struct domain_device *dev, int phy_id)
{
struct ex_phy *ex_phy = &dev->ex_dev.ex_phy[phy_id];
struct domain_device *child;
int res;
SAS_DPRINTK("ex %016llx phy%d new device attached\n",
SAS_ADDR(dev->sas_addr), phy_id);
res = sas_ex_phy_discover(dev, phy_id);
if (res)
return res;
if (sas_ex_join_wide_port(dev, phy_id))
return 0;
res = sas_ex_discover_devices(dev, phy_id);
if (res)
return res;
list_for_each_entry(child, &dev->ex_dev.children, siblings) {
if (SAS_ADDR(child->sas_addr) ==
SAS_ADDR(ex_phy->attached_sas_addr)) {
if (child->dev_type == SAS_EDGE_EXPANDER_DEVICE ||
child->dev_type == SAS_FANOUT_EXPANDER_DEVICE)
res = sas_discover_bfs_by_root(child);
break;
}
}
return res;
}
static bool dev_type_flutter(enum sas_device_type new, enum sas_device_type old)
{
if (old == new)
return true;
/* treat device directed resets as flutter, if we went
* SAS_END_DEVICE to SAS_SATA_PENDING the link needs recovery
*/
if ((old == SAS_SATA_PENDING && new == SAS_END_DEVICE) ||
(old == SAS_END_DEVICE && new == SAS_SATA_PENDING))
return true;
return false;
}
static int sas_rediscover_dev(struct domain_device *dev, int phy_id, bool last)
{
struct expander_device *ex = &dev->ex_dev;
struct ex_phy *phy = &ex->ex_phy[phy_id];
enum sas_device_type type = SAS_PHY_UNUSED;
u8 sas_addr[8];
int res;
memset(sas_addr, 0, 8);
res = sas_get_phy_attached_dev(dev, phy_id, sas_addr, &type);
switch (res) {
case SMP_RESP_NO_PHY:
phy->phy_state = PHY_NOT_PRESENT;
sas_unregister_devs_sas_addr(dev, phy_id, last);
return res;
case SMP_RESP_PHY_VACANT:
phy->phy_state = PHY_VACANT;
sas_unregister_devs_sas_addr(dev, phy_id, last);
return res;
case SMP_RESP_FUNC_ACC:
break;
case -ECOMM:
break;
default:
return res;
}
if ((SAS_ADDR(sas_addr) == 0) || (res == -ECOMM)) {
phy->phy_state = PHY_EMPTY;
sas_unregister_devs_sas_addr(dev, phy_id, last);
return res;
} else if (SAS_ADDR(sas_addr) == SAS_ADDR(phy->attached_sas_addr) &&
dev_type_flutter(type, phy->attached_dev_type)) {
struct domain_device *ata_dev = sas_ex_to_ata(dev, phy_id);
char *action = "";
sas_ex_phy_discover(dev, phy_id);
if (ata_dev && phy->attached_dev_type == SAS_SATA_PENDING)
action = ", needs recovery";
SAS_DPRINTK("ex %016llx phy 0x%x broadcast flutter%s\n",
SAS_ADDR(dev->sas_addr), phy_id, action);
return res;
}
/* delete the old link */
if (SAS_ADDR(phy->attached_sas_addr) &&
SAS_ADDR(sas_addr) != SAS_ADDR(phy->attached_sas_addr)) {
SAS_DPRINTK("ex %016llx phy 0x%x replace %016llx\n",
SAS_ADDR(dev->sas_addr), phy_id,
SAS_ADDR(phy->attached_sas_addr));
sas_unregister_devs_sas_addr(dev, phy_id, last);
}
return sas_discover_new(dev, phy_id);
}
/**
* sas_rediscover - revalidate the domain.
* @dev:domain device to be detect.
* @phy_id: the phy id will be detected.
*
* NOTE: this process _must_ quit (return) as soon as any connection
* errors are encountered. Connection recovery is done elsewhere.
* Discover process only interrogates devices in order to discover the
* domain.For plugging out, we un-register the device only when it is
* the last phy in the port, for other phys in this port, we just delete it
* from the port.For inserting, we do discovery when it is the
* first phy,for other phys in this port, we add it to the port to
* forming the wide-port.
*/
static int sas_rediscover(struct domain_device *dev, const int phy_id)
{
struct expander_device *ex = &dev->ex_dev;
struct ex_phy *changed_phy = &ex->ex_phy[phy_id];
int res = 0;
int i;
bool last = true; /* is this the last phy of the port */
SAS_DPRINTK("ex %016llx phy%d originated BROADCAST(CHANGE)\n",
SAS_ADDR(dev->sas_addr), phy_id);
if (SAS_ADDR(changed_phy->attached_sas_addr) != 0) {
for (i = 0; i < ex->num_phys; i++) {
struct ex_phy *phy = &ex->ex_phy[i];
if (i == phy_id)
continue;
if (SAS_ADDR(phy->attached_sas_addr) ==
SAS_ADDR(changed_phy->attached_sas_addr)) {
SAS_DPRINTK("phy%d part of wide port with "
"phy%d\n", phy_id, i);
last = false;
break;
}
}
res = sas_rediscover_dev(dev, phy_id, last);
} else
res = sas_discover_new(dev, phy_id);
return res;
}
/**
* sas_ex_revalidate_domain - revalidate the domain
* @port_dev: port domain device.
*
* NOTE: this process _must_ quit (return) as soon as any connection
* errors are encountered. Connection recovery is done elsewhere.
* Discover process only interrogates devices in order to discover the
* domain.
*/
int sas_ex_revalidate_domain(struct domain_device *port_dev)
{
int res;
struct domain_device *dev = NULL;
res = sas_find_bcast_dev(port_dev, &dev);
if (res == 0 && dev) {
struct expander_device *ex = &dev->ex_dev;
int i = 0, phy_id;
do {
phy_id = -1;
res = sas_find_bcast_phy(dev, &phy_id, i, true);
if (phy_id == -1)
break;
res = sas_rediscover(dev, phy_id);
i = phy_id + 1;
} while (i < ex->num_phys);
}
return res;
}
void sas_smp_handler(struct bsg_job *job, struct Scsi_Host *shost,
struct sas_rphy *rphy)
{
struct domain_device *dev;
unsigned int rcvlen = 0;
int ret = -EINVAL;
/* no rphy means no smp target support (ie aic94xx host) */
if (!rphy)
return sas_smp_host_handler(job, shost);
switch (rphy->identify.device_type) {
case SAS_EDGE_EXPANDER_DEVICE:
case SAS_FANOUT_EXPANDER_DEVICE:
break;
default:
printk("%s: can we send a smp request to a device?\n",
__func__);
goto out;
}
dev = sas_find_dev_by_rphy(rphy);
if (!dev) {
printk("%s: fail to find a domain_device?\n", __func__);
goto out;
}
/* do we need to support multiple segments? */
if (job->request_payload.sg_cnt > 1 ||
job->reply_payload.sg_cnt > 1) {
printk("%s: multiple segments req %u, rsp %u\n",
__func__, job->request_payload.payload_len,
job->reply_payload.payload_len);
goto out;
}
ret = smp_execute_task_sg(dev, job->request_payload.sg_list,
job->reply_payload.sg_list);
if (ret >= 0) {
/* bsg_job_done() requires the length received */
rcvlen = job->reply_payload.payload_len - ret;
ret = 0;
}
out:
bsg_job_done(job, ret, rcvlen);
}