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linux-next/drivers/scsi/libsas/sas_expander.c
Christoph Hellwig 79855d1785 libsas: remove task_collector mode
The task_collector mode (or "latency_injector", (C) Dan Willians) is an
optional I/O path in libsas that queues up scsi commands instead of
directly sending it to the hardware.  It generall increases latencies
to in the optiomal case slightly reduce mmio traffic to the hardware.

Only the obsolete aic94xx driver and the mvsas driver allowed to use
it without recompiling the kernel, and most drivers didn't support it
at all.

Remove the giant blob of code to allow better optimizations for scsi-mq
in the future.

Signed-off-by: Christoph Hellwig <hch@lst.de>
Reviewed-by: Hannes Reinecke <hare@suse.de>
Acked-by: Dan Williams <dan.j.williams@intel.com>
2014-11-27 16:40:24 +01:00

2187 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(unsigned long _task)
{
struct sas_task *task = (void *) _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(struct domain_device *dev, void *req, int req_size,
void *resp, int resp_size)
{
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;
sg_init_one(&task->smp_task.smp_req, req, req_size);
sg_init_one(&task->smp_task.smp_resp, resp, resp_size);
task->task_done = smp_task_done;
task->slow_task->timer.data = (unsigned long) task;
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;
}
/* ---------- 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;
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 = kzalloc(sizeof(*ex->ex_phy)*ex->num_phys, 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(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
*/
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
* @ex: 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)
sas_port_delete(phy->port);
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_revalidate_domain -- revalidate the domain
* @port: port to the domain of interest
*
* 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);
while (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);
dev = NULL;
res = sas_find_bcast_dev(port_dev, &dev);
}
return res;
}
int sas_smp_handler(struct Scsi_Host *shost, struct sas_rphy *rphy,
struct request *req)
{
struct domain_device *dev;
int ret, type;
struct request *rsp = req->next_rq;
if (!rsp) {
printk("%s: space for a smp response is missing\n",
__func__);
return -EINVAL;
}
/* no rphy means no smp target support (ie aic94xx host) */
if (!rphy)
return sas_smp_host_handler(shost, req, rsp);
type = rphy->identify.device_type;
if (type != SAS_EDGE_EXPANDER_DEVICE &&
type != SAS_FANOUT_EXPANDER_DEVICE) {
printk("%s: can we send a smp request to a device?\n",
__func__);
return -EINVAL;
}
dev = sas_find_dev_by_rphy(rphy);
if (!dev) {
printk("%s: fail to find a domain_device?\n", __func__);
return -EINVAL;
}
/* do we need to support multiple segments? */
if (bio_multiple_segments(req->bio) ||
bio_multiple_segments(rsp->bio)) {
printk("%s: multiple segments req %u, rsp %u\n",
__func__, blk_rq_bytes(req), blk_rq_bytes(rsp));
return -EINVAL;
}
ret = smp_execute_task(dev, bio_data(req->bio), blk_rq_bytes(req),
bio_data(rsp->bio), blk_rq_bytes(rsp));
if (ret > 0) {
/* positive number is the untransferred residual */
rsp->resid_len = ret;
req->resid_len = 0;
ret = 0;
} else if (ret == 0) {
rsp->resid_len = 0;
req->resid_len = 0;
}
return ret;
}