/*
* Parallel SCSI (SPI) transport specific attributes exported to sysfs.
*
* Copyright (c) 2003 Silicon Graphics, Inc. All rights reserved.
* Copyright (c) 2004, 2005 James Bottomley <James.Bottomley@SteelEye.com>
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include <linux/ctype.h>
#include <linux/init.h>
#include <linux/module.h>
#include <linux/workqueue.h>
#include <asm/semaphore.h>
#include <scsi/scsi.h>
#include "scsi_priv.h"
#include <scsi/scsi_device.h>
#include <scsi/scsi_host.h>
#include <scsi/scsi_request.h>
#include <scsi/scsi_eh.h>
#include <scsi/scsi_transport.h>
#include <scsi/scsi_transport_spi.h>
#define SPI_PRINTK(x, l, f, a...) dev_printk(l, &(x)->dev, f , ##a)
#define SPI_NUM_ATTRS 10 /* increase this if you add attributes */
#define SPI_OTHER_ATTRS 1 /* Increase this if you add "always
* on" attributes */
#define SPI_HOST_ATTRS 1
#define SPI_MAX_ECHO_BUFFER_SIZE 4096
/* Private data accessors (keep these out of the header file) */
#define spi_dv_pending(x) (((struct spi_transport_attrs *)&(x)->starget_data)->dv_pending)
#define spi_dv_sem(x) (((struct spi_transport_attrs *)&(x)->starget_data)->dv_sem)
struct spi_internal {
struct scsi_transport_template t;
struct spi_function_template *f;
/* The actual attributes */
struct class_device_attribute private_attrs[SPI_NUM_ATTRS];
/* The array of null terminated pointers to attributes
* needed by scsi_sysfs.c */
struct class_device_attribute *attrs[SPI_NUM_ATTRS + SPI_OTHER_ATTRS + 1];
struct class_device_attribute private_host_attrs[SPI_HOST_ATTRS];
struct class_device_attribute *host_attrs[SPI_HOST_ATTRS + 1];
};
#define to_spi_internal(tmpl) container_of(tmpl, struct spi_internal, t)
static const int ppr_to_ps[] = {
/* The PPR values 0-6 are reserved, fill them in when
* the committee defines them */
-1, /* 0x00 */
-1, /* 0x01 */
-1, /* 0x02 */
-1, /* 0x03 */
-1, /* 0x04 */
-1, /* 0x05 */
-1, /* 0x06 */
3125, /* 0x07 */
6250, /* 0x08 */
12500, /* 0x09 */
25000, /* 0x0a */
30300, /* 0x0b */
50000, /* 0x0c */
};
/* The PPR values at which you calculate the period in ns by multiplying
* by 4 */
#define SPI_STATIC_PPR 0x0c
static int sprint_frac(char *dest, int value, int denom)
{
int frac = value % denom;
int result = sprintf(dest, "%d", value / denom);
if (frac == 0)
return result;
dest[result++] = '.';
do {
denom /= 10;
sprintf(dest + result, "%d", frac / denom);
result++;
frac %= denom;
} while (frac);
dest[result++] = '\0';
return result;
}
static struct {
enum spi_signal_type value;
char *name;
} signal_types[] = {
{ SPI_SIGNAL_UNKNOWN, "unknown" },
{ SPI_SIGNAL_SE, "SE" },
{ SPI_SIGNAL_LVD, "LVD" },
{ SPI_SIGNAL_HVD, "HVD" },
};
static inline const char *spi_signal_to_string(enum spi_signal_type type)
{
int i;
for (i = 0; i < sizeof(signal_types)/sizeof(signal_types[0]); i++) {
if (type == signal_types[i].value)
return signal_types[i].name;
}
return NULL;
}
static inline enum spi_signal_type spi_signal_to_value(const char *name)
{
int i, len;
for (i = 0; i < sizeof(signal_types)/sizeof(signal_types[0]); i++) {
len = strlen(signal_types[i].name);
if (strncmp(name, signal_types[i].name, len) == 0 &&
(name[len] == '\n' || name[len] == '\0'))
return signal_types[i].value;
}
return SPI_SIGNAL_UNKNOWN;
}
static int spi_host_setup(struct device *dev)
{
struct Scsi_Host *shost = dev_to_shost(dev);
spi_signalling(shost) = SPI_SIGNAL_UNKNOWN;
return 0;
}
static DECLARE_TRANSPORT_CLASS(spi_host_class,
"spi_host",
spi_host_setup,
NULL,
NULL);
static int spi_host_match(struct attribute_container *cont,
struct device *dev)
{
struct Scsi_Host *shost;
struct spi_internal *i;
if (!scsi_is_host_device(dev))
return 0;
shost = dev_to_shost(dev);
if (!shost->transportt || shost->transportt->host_attrs.ac.class
!= &spi_host_class.class)
return 0;
i = to_spi_internal(shost->transportt);
return &i->t.host_attrs.ac == cont;
}
static int spi_device_configure(struct device *dev)
{
struct scsi_device *sdev = to_scsi_device(dev);
struct scsi_target *starget = sdev->sdev_target;
/* Populate the target capability fields with the values
* gleaned from the device inquiry */
spi_support_sync(starget) = scsi_device_sync(sdev);
spi_support_wide(starget) = scsi_device_wide(sdev);
spi_support_dt(starget) = scsi_device_dt(sdev);
spi_support_dt_only(starget) = scsi_device_dt_only(sdev);
spi_support_ius(starget) = scsi_device_ius(sdev);
spi_support_qas(starget) = scsi_device_qas(sdev);
return 0;
}
static int spi_setup_transport_attrs(struct device *dev)
{
struct scsi_target *starget = to_scsi_target(dev);
spi_period(starget) = -1; /* illegal value */
spi_offset(starget) = 0; /* async */
spi_width(starget) = 0; /* narrow */
spi_iu(starget) = 0; /* no IU */
spi_dt(starget) = 0; /* ST */
spi_qas(starget) = 0;
spi_wr_flow(starget) = 0;
spi_rd_strm(starget) = 0;
spi_rti(starget) = 0;
spi_pcomp_en(starget) = 0;
spi_dv_pending(starget) = 0;
spi_initial_dv(starget) = 0;
init_MUTEX(&spi_dv_sem(starget));
return 0;
}
#define spi_transport_show_function(field, format_string) \
\
static ssize_t \
show_spi_transport_##field(struct class_device *cdev, char *buf) \
{ \
struct scsi_target *starget = transport_class_to_starget(cdev); \
struct Scsi_Host *shost = dev_to_shost(starget->dev.parent); \
struct spi_transport_attrs *tp; \
struct spi_internal *i = to_spi_internal(shost->transportt); \
tp = (struct spi_transport_attrs *)&starget->starget_data; \
if (i->f->get_##field) \
i->f->get_##field(starget); \
return snprintf(buf, 20, format_string, tp->field); \
}
#define spi_transport_store_function(field, format_string) \
static ssize_t \
store_spi_transport_##field(struct class_device *cdev, const char *buf, \
size_t count) \
{ \
int val; \
struct scsi_target *starget = transport_class_to_starget(cdev); \
struct Scsi_Host *shost = dev_to_shost(starget->dev.parent); \
struct spi_internal *i = to_spi_internal(shost->transportt); \
\
val = simple_strtoul(buf, NULL, 0); \
i->f->set_##field(starget, val); \
return count; \
}
#define spi_transport_rd_attr(field, format_string) \
spi_transport_show_function(field, format_string) \
spi_transport_store_function(field, format_string) \
static CLASS_DEVICE_ATTR(field, S_IRUGO | S_IWUSR, \
show_spi_transport_##field, \
store_spi_transport_##field);
/* The Parallel SCSI Tranport Attributes: */
spi_transport_rd_attr(offset, "%d\n");
spi_transport_rd_attr(width, "%d\n");
spi_transport_rd_attr(iu, "%d\n");
spi_transport_rd_attr(dt, "%d\n");
spi_transport_rd_attr(qas, "%d\n");
spi_transport_rd_attr(wr_flow, "%d\n");
spi_transport_rd_attr(rd_strm, "%d\n");
spi_transport_rd_attr(rti, "%d\n");
spi_transport_rd_attr(pcomp_en, "%d\n");
static ssize_t
store_spi_revalidate(struct class_device *cdev, const char *buf, size_t count)
{
struct scsi_target *starget = transport_class_to_starget(cdev);
/* FIXME: we're relying on an awful lot of device internals
* here. We really need a function to get the first available
* child */
struct device *dev = container_of(starget->dev.children.next, struct device, node);
struct scsi_device *sdev = to_scsi_device(dev);
spi_dv_device(sdev);
return count;
}
static CLASS_DEVICE_ATTR(revalidate, S_IWUSR, NULL, store_spi_revalidate);
/* Translate the period into ns according to the current spec
* for SDTR/PPR messages */
static ssize_t show_spi_transport_period(struct class_device *cdev, char *buf)
{
struct scsi_target *starget = transport_class_to_starget(cdev);
struct Scsi_Host *shost = dev_to_shost(starget->dev.parent);
struct spi_transport_attrs *tp;
int len, picosec;
struct spi_internal *i = to_spi_internal(shost->transportt);
tp = (struct spi_transport_attrs *)&starget->starget_data;
if (i->f->get_period)
i->f->get_period(starget);
if (tp->period < 0 || tp->period > 0xff) {
picosec = -1;
} else if (tp->period <= SPI_STATIC_PPR) {
picosec = ppr_to_ps[tp->period];
} else {
picosec = tp->period * 4000;
}
if (picosec == -1) {
len = sprintf(buf, "reserved");
} else {
len = sprint_frac(buf, picosec, 1000);
}
buf[len++] = '\n';
buf[len] = '\0';
return len;
}
static ssize_t
store_spi_transport_period(struct class_device *cdev, const char *buf,
size_t count)
{
struct scsi_target *starget = transport_class_to_starget(cdev);
struct Scsi_Host *shost = dev_to_shost(starget->dev.parent);
struct spi_internal *i = to_spi_internal(shost->transportt);
int j, picosec, period = -1;
char *endp;
picosec = simple_strtoul(buf, &endp, 10) * 1000;
if (*endp == '.') {
int mult = 100;
do {
endp++;
if (!isdigit(*endp))
break;
picosec += (*endp - '0') * mult;
mult /= 10;
} while (mult > 0);
}
for (j = 0; j <= SPI_STATIC_PPR; j++) {
if (ppr_to_ps[j] < picosec)
continue;
period = j;
break;
}
if (period == -1)
period = picosec / 4000;
if (period > 0xff)
period = 0xff;
i->f->set_period(starget, period);
return count;
}
static CLASS_DEVICE_ATTR(period, S_IRUGO | S_IWUSR,
show_spi_transport_period,
store_spi_transport_period);
static ssize_t show_spi_host_signalling(struct class_device *cdev, char *buf)
{
struct Scsi_Host *shost = transport_class_to_shost(cdev);
struct spi_internal *i = to_spi_internal(shost->transportt);
if (i->f->get_signalling)
i->f->get_signalling(shost);
return sprintf(buf, "%s\n", spi_signal_to_string(spi_signalling(shost)));
}
static ssize_t store_spi_host_signalling(struct class_device *cdev,
const char *buf, size_t count)
{
struct Scsi_Host *shost = transport_class_to_shost(cdev);
struct spi_internal *i = to_spi_internal(shost->transportt);
enum spi_signal_type type = spi_signal_to_value(buf);
if (type != SPI_SIGNAL_UNKNOWN)
i->f->set_signalling(shost, type);
return count;
}
static CLASS_DEVICE_ATTR(signalling, S_IRUGO | S_IWUSR,
show_spi_host_signalling,
store_spi_host_signalling);
#define DV_SET(x, y) \
if(i->f->set_##x) \
i->f->set_##x(sdev->sdev_target, y)
#define DV_LOOPS 3
#define DV_TIMEOUT (10*HZ)
#define DV_RETRIES 3 /* should only need at most
* two cc/ua clears */
enum spi_compare_returns {
SPI_COMPARE_SUCCESS,
SPI_COMPARE_FAILURE,
SPI_COMPARE_SKIP_TEST,
};
/* This is for read/write Domain Validation: If the device supports
* an echo buffer, we do read/write tests to it */
static enum spi_compare_returns
spi_dv_device_echo_buffer(struct scsi_request *sreq, u8 *buffer,
u8 *ptr, const int retries)
{
struct scsi_device *sdev = sreq->sr_device;
int len = ptr - buffer;
int j, k, r;
unsigned int pattern = 0x0000ffff;
const char spi_write_buffer[] = {
WRITE_BUFFER, 0x0a, 0, 0, 0, 0, 0, len >> 8, len & 0xff, 0
};
const char spi_read_buffer[] = {
READ_BUFFER, 0x0a, 0, 0, 0, 0, 0, len >> 8, len & 0xff, 0
};
/* set up the pattern buffer. Doesn't matter if we spill
* slightly beyond since that's where the read buffer is */
for (j = 0; j < len; ) {
/* fill the buffer with counting (test a) */
for ( ; j < min(len, 32); j++)
buffer[j] = j;
k = j;
/* fill the buffer with alternating words of 0x0 and
* 0xffff (test b) */
for ( ; j < min(len, k + 32); j += 2) {
u16 *word = (u16 *)&buffer[j];
*word = (j & 0x02) ? 0x0000 : 0xffff;
}
k = j;
/* fill with crosstalk (alternating 0x5555 0xaaa)
* (test c) */
for ( ; j < min(len, k + 32); j += 2) {
u16 *word = (u16 *)&buffer[j];
*word = (j & 0x02) ? 0x5555 : 0xaaaa;
}
k = j;
/* fill with shifting bits (test d) */
for ( ; j < min(len, k + 32); j += 4) {
u32 *word = (unsigned int *)&buffer[j];
u32 roll = (pattern & 0x80000000) ? 1 : 0;
*word = pattern;
pattern = (pattern << 1) | roll;
}
/* don't bother with random data (test e) */
}
for (r = 0; r < retries; r++) {
sreq->sr_cmd_len = 0; /* wait_req to fill in */
sreq->sr_data_direction = DMA_TO_DEVICE;
scsi_wait_req(sreq, spi_write_buffer, buffer, len,
DV_TIMEOUT, DV_RETRIES);
if(sreq->sr_result || !scsi_device_online(sdev)) {
struct scsi_sense_hdr sshdr;
scsi_device_set_state(sdev, SDEV_QUIESCE);
if (scsi_request_normalize_sense(sreq, &sshdr)
&& sshdr.sense_key == ILLEGAL_REQUEST
/* INVALID FIELD IN CDB */
&& sshdr.asc == 0x24 && sshdr.ascq == 0x00)
/* This would mean that the drive lied
* to us about supporting an echo
* buffer (unfortunately some Western
* Digital drives do precisely this)
*/
return SPI_COMPARE_SKIP_TEST;
SPI_PRINTK(sdev->sdev_target, KERN_ERR, "Write Buffer failure %x\n", sreq->sr_result);
return SPI_COMPARE_FAILURE;
}
memset(ptr, 0, len);
sreq->sr_cmd_len = 0; /* wait_req to fill in */
sreq->sr_data_direction = DMA_FROM_DEVICE;
scsi_wait_req(sreq, spi_read_buffer, ptr, len,
DV_TIMEOUT, DV_RETRIES);
scsi_device_set_state(sdev, SDEV_QUIESCE);
if (memcmp(buffer, ptr, len) != 0)
return SPI_COMPARE_FAILURE;
}
return SPI_COMPARE_SUCCESS;
}
/* This is for the simplest form of Domain Validation: a read test
* on the inquiry data from the device */
static enum spi_compare_returns
spi_dv_device_compare_inquiry(struct scsi_request *sreq, u8 *buffer,
u8 *ptr, const int retries)
{
int r;
const int len = sreq->sr_device->inquiry_len;
struct scsi_device *sdev = sreq->sr_device;
const char spi_inquiry[] = {
INQUIRY, 0, 0, 0, len, 0
};
for (r = 0; r < retries; r++) {
sreq->sr_cmd_len = 0; /* wait_req to fill in */
sreq->sr_data_direction = DMA_FROM_DEVICE;
memset(ptr, 0, len);
scsi_wait_req(sreq, spi_inquiry, ptr, len,
DV_TIMEOUT, DV_RETRIES);
if(sreq->sr_result || !scsi_device_online(sdev)) {
scsi_device_set_state(sdev, SDEV_QUIESCE);
return SPI_COMPARE_FAILURE;
}
/* If we don't have the inquiry data already, the
* first read gets it */
if (ptr == buffer) {
ptr += len;
--r;
continue;
}
if (memcmp(buffer, ptr, len) != 0)
/* failure */
return SPI_COMPARE_FAILURE;
}
return SPI_COMPARE_SUCCESS;
}
static enum spi_compare_returns
spi_dv_retrain(struct scsi_request *sreq, u8 *buffer, u8 *ptr,
enum spi_compare_returns
(*compare_fn)(struct scsi_request *, u8 *, u8 *, int))
{
struct spi_internal *i = to_spi_internal(sreq->sr_host->transportt);
struct scsi_device *sdev = sreq->sr_device;
int period = 0, prevperiod = 0;
enum spi_compare_returns retval;
for (;;) {
int newperiod;
retval = compare_fn(sreq, buffer, ptr, DV_LOOPS);
if (retval == SPI_COMPARE_SUCCESS
|| retval == SPI_COMPARE_SKIP_TEST)
break;
/* OK, retrain, fallback */
if (i->f->get_period)
i->f->get_period(sdev->sdev_target);
newperiod = spi_period(sdev->sdev_target);
period = newperiod > period ? newperiod : period;
if (period < 0x0d)
period++;
else
period += period >> 1;
if (unlikely(period > 0xff || period == prevperiod)) {
/* Total failure; set to async and return */
SPI_PRINTK(sdev->sdev_target, KERN_ERR, "Domain Validation Failure, dropping back to Asynchronous\n");
DV_SET(offset, 0);
return SPI_COMPARE_FAILURE;
}
SPI_PRINTK(sdev->sdev_target, KERN_ERR, "Domain Validation detected failure, dropping back\n");
DV_SET(period, period);
prevperiod = period;
}
return retval;
}
static int
spi_dv_device_get_echo_buffer(struct scsi_request *sreq, u8 *buffer)
{
int l;
/* first off do a test unit ready. This can error out
* because of reservations or some other reason. If it
* fails, the device won't let us write to the echo buffer
* so just return failure */
const char spi_test_unit_ready[] = {
TEST_UNIT_READY, 0, 0, 0, 0, 0
};
const char spi_read_buffer_descriptor[] = {
READ_BUFFER, 0x0b, 0, 0, 0, 0, 0, 0, 4, 0
};
sreq->sr_cmd_len = 0;
sreq->sr_data_direction = DMA_NONE;
/* We send a set of three TURs to clear any outstanding
* unit attention conditions if they exist (Otherwise the
* buffer tests won't be happy). If the TUR still fails
* (reservation conflict, device not ready, etc) just
* skip the write tests */
for (l = 0; ; l++) {
scsi_wait_req(sreq, spi_test_unit_ready, NULL, 0,
DV_TIMEOUT, DV_RETRIES);
if(sreq->sr_result) {
if(l >= 3)
return 0;
} else {
/* TUR succeeded */
break;
}
}
sreq->sr_cmd_len = 0;
sreq->sr_data_direction = DMA_FROM_DEVICE;
scsi_wait_req(sreq, spi_read_buffer_descriptor, buffer, 4,
DV_TIMEOUT, DV_RETRIES);
if (sreq->sr_result)
/* Device has no echo buffer */
return 0;
return buffer[3] + ((buffer[2] & 0x1f) << 8);
}
static void
spi_dv_device_internal(struct scsi_request *sreq, u8 *buffer)
{
struct spi_internal *i = to_spi_internal(sreq->sr_host->transportt);
struct scsi_device *sdev = sreq->sr_device;
int len = sdev->inquiry_len;
/* first set us up for narrow async */
DV_SET(offset, 0);
DV_SET(width, 0);
if (spi_dv_device_compare_inquiry(sreq, buffer, buffer, DV_LOOPS)
!= SPI_COMPARE_SUCCESS) {
SPI_PRINTK(sdev->sdev_target, KERN_ERR, "Domain Validation Initial Inquiry Failed\n");
/* FIXME: should probably offline the device here? */
return;
}
/* test width */
if (i->f->set_width && sdev->wdtr) {
i->f->set_width(sdev->sdev_target, 1);
if (spi_dv_device_compare_inquiry(sreq, buffer,
buffer + len,
DV_LOOPS)
!= SPI_COMPARE_SUCCESS) {
SPI_PRINTK(sdev->sdev_target, KERN_ERR, "Wide Transfers Fail\n");
i->f->set_width(sdev->sdev_target, 0);
}
}
if (!i->f->set_period)
return;
/* device can't handle synchronous */
if(!sdev->ppr && !sdev->sdtr)
return;
/* see if the device has an echo buffer. If it does we can
* do the SPI pattern write tests */
len = 0;
if (sdev->ppr)
len = spi_dv_device_get_echo_buffer(sreq, buffer);
retry:
/* now set up to the maximum */
DV_SET(offset, 255);
DV_SET(period, 1);
if (len == 0) {
SPI_PRINTK(sdev->sdev_target, KERN_INFO, "Domain Validation skipping write tests\n");
spi_dv_retrain(sreq, buffer, buffer + len,
spi_dv_device_compare_inquiry);
return;
}
if (len > SPI_MAX_ECHO_BUFFER_SIZE) {
SPI_PRINTK(sdev->sdev_target, KERN_WARNING, "Echo buffer size %d is too big, trimming to %d\n", len, SPI_MAX_ECHO_BUFFER_SIZE);
len = SPI_MAX_ECHO_BUFFER_SIZE;
}
if (spi_dv_retrain(sreq, buffer, buffer + len,
spi_dv_device_echo_buffer)
== SPI_COMPARE_SKIP_TEST) {
/* OK, the stupid drive can't do a write echo buffer
* test after all, fall back to the read tests */
len = 0;
goto retry;
}
}
/** spi_dv_device - Do Domain Validation on the device
* @sdev: scsi device to validate
*
* Performs the domain validation on the given device in the
* current execution thread. Since DV operations may sleep,
* the current thread must have user context. Also no SCSI
* related locks that would deadlock I/O issued by the DV may
* be held.
*/
void
spi_dv_device(struct scsi_device *sdev)
{
struct scsi_request *sreq = scsi_allocate_request(sdev, GFP_KERNEL);
struct scsi_target *starget = sdev->sdev_target;
u8 *buffer;
const int len = SPI_MAX_ECHO_BUFFER_SIZE*2;
if (unlikely(!sreq))
return;
if (unlikely(scsi_device_get(sdev)))
goto out_free_req;
buffer = kmalloc(len, GFP_KERNEL);
if (unlikely(!buffer))
goto out_put;
memset(buffer, 0, len);
/* We need to verify that the actual device will quiesce; the
* later target quiesce is just a nice to have */
if (unlikely(scsi_device_quiesce(sdev)))
goto out_free;
scsi_target_quiesce(starget);
spi_dv_pending(starget) = 1;
down(&spi_dv_sem(starget));
SPI_PRINTK(starget, KERN_INFO, "Beginning Domain Validation\n");
spi_dv_device_internal(sreq, buffer);
SPI_PRINTK(starget, KERN_INFO, "Ending Domain Validation\n");
up(&spi_dv_sem(starget));
spi_dv_pending(starget) = 0;
scsi_target_resume(starget);
spi_initial_dv(starget) = 1;
out_free:
kfree(buffer);
out_put:
scsi_device_put(sdev);
out_free_req:
scsi_release_request(sreq);
}
EXPORT_SYMBOL(spi_dv_device);
struct work_queue_wrapper {
struct work_struct work;
struct scsi_device *sdev;
};
static void
spi_dv_device_work_wrapper(void *data)
{
struct work_queue_wrapper *wqw = (struct work_queue_wrapper *)data;
struct scsi_device *sdev = wqw->sdev;
kfree(wqw);
spi_dv_device(sdev);
spi_dv_pending(sdev->sdev_target) = 0;
scsi_device_put(sdev);
}
/**
* spi_schedule_dv_device - schedule domain validation to occur on the device
* @sdev: The device to validate
*
* Identical to spi_dv_device() above, except that the DV will be
* scheduled to occur in a workqueue later. All memory allocations
* are atomic, so may be called from any context including those holding
* SCSI locks.
*/
void
spi_schedule_dv_device(struct scsi_device *sdev)
{
struct work_queue_wrapper *wqw =
kmalloc(sizeof(struct work_queue_wrapper), GFP_ATOMIC);
if (unlikely(!wqw))
return;
if (unlikely(spi_dv_pending(sdev->sdev_target))) {
kfree(wqw);
return;
}
/* Set pending early (dv_device doesn't check it, only sets it) */
spi_dv_pending(sdev->sdev_target) = 1;
if (unlikely(scsi_device_get(sdev))) {
kfree(wqw);
spi_dv_pending(sdev->sdev_target) = 0;
return;
}
INIT_WORK(&wqw->work, spi_dv_device_work_wrapper, wqw);
wqw->sdev = sdev;
schedule_work(&wqw->work);
}
EXPORT_SYMBOL(spi_schedule_dv_device);
/**
* spi_display_xfer_agreement - Print the current target transfer agreement
* @starget: The target for which to display the agreement
*
* Each SPI port is required to maintain a transfer agreement for each
* other port on the bus. This function prints a one-line summary of
* the current agreement; more detailed information is available in sysfs.
*/
void spi_display_xfer_agreement(struct scsi_target *starget)
{
struct spi_transport_attrs *tp;
tp = (struct spi_transport_attrs *)&starget->starget_data;
if (tp->offset > 0 && tp->period > 0) {
unsigned int picosec, kb100;
char *scsi = "FAST-?";
char tmp[8];
if (tp->period <= SPI_STATIC_PPR) {
picosec = ppr_to_ps[tp->period];
switch (tp->period) {
case 7: scsi = "FAST-320"; break;
case 8: scsi = "FAST-160"; break;
case 9: scsi = "FAST-80"; break;
case 10:
case 11: scsi = "FAST-40"; break;
case 12: scsi = "FAST-20"; break;
}
} else {
picosec = tp->period * 4000;
if (tp->period < 25)
scsi = "FAST-20";
else if (tp->period < 50)
scsi = "FAST-10";
else
scsi = "FAST-5";
}
kb100 = (10000000 + picosec / 2) / picosec;
if (tp->width)
kb100 *= 2;
sprint_frac(tmp, picosec, 1000);
dev_info(&starget->dev,
"%s %sSCSI %d.%d MB/s %s%s%s (%s ns, offset %d)\n",
scsi, tp->width ? "WIDE " : "", kb100/10, kb100 % 10,
tp->dt ? "DT" : "ST", tp->iu ? " IU" : "",
tp->qas ? " QAS" : "", tmp, tp->offset);
} else {
dev_info(&starget->dev, "%sasynchronous.\n",
tp->width ? "wide " : "");
}
}
EXPORT_SYMBOL(spi_display_xfer_agreement);
#define SETUP_ATTRIBUTE(field) \
i->private_attrs[count] = class_device_attr_##field; \
if (!i->f->set_##field) { \
i->private_attrs[count].attr.mode = S_IRUGO; \
i->private_attrs[count].store = NULL; \
} \
i->attrs[count] = &i->private_attrs[count]; \
if (i->f->show_##field) \
count++
#define SETUP_HOST_ATTRIBUTE(field) \
i->private_host_attrs[count] = class_device_attr_##field; \
if (!i->f->set_##field) { \
i->private_host_attrs[count].attr.mode = S_IRUGO; \
i->private_host_attrs[count].store = NULL; \
} \
i->host_attrs[count] = &i->private_host_attrs[count]; \
count++
static int spi_device_match(struct attribute_container *cont,
struct device *dev)
{
struct scsi_device *sdev;
struct Scsi_Host *shost;
if (!scsi_is_sdev_device(dev))
return 0;
sdev = to_scsi_device(dev);
shost = sdev->host;
if (!shost->transportt || shost->transportt->host_attrs.ac.class
!= &spi_host_class.class)
return 0;
/* Note: this class has no device attributes, so it has
* no per-HBA allocation and thus we don't need to distinguish
* the attribute containers for the device */
return 1;
}
static int spi_target_match(struct attribute_container *cont,
struct device *dev)
{
struct Scsi_Host *shost;
struct spi_internal *i;
if (!scsi_is_target_device(dev))
return 0;
shost = dev_to_shost(dev->parent);
if (!shost->transportt || shost->transportt->host_attrs.ac.class
!= &spi_host_class.class)
return 0;
i = to_spi_internal(shost->transportt);
return &i->t.target_attrs.ac == cont;
}
static DECLARE_TRANSPORT_CLASS(spi_transport_class,
"spi_transport",
spi_setup_transport_attrs,
NULL,
NULL);
static DECLARE_ANON_TRANSPORT_CLASS(spi_device_class,
spi_device_match,
spi_device_configure);
struct scsi_transport_template *
spi_attach_transport(struct spi_function_template *ft)
{
struct spi_internal *i = kmalloc(sizeof(struct spi_internal),
GFP_KERNEL);
int count = 0;
if (unlikely(!i))
return NULL;
memset(i, 0, sizeof(struct spi_internal));
i->t.target_attrs.ac.class = &spi_transport_class.class;
i->t.target_attrs.ac.attrs = &i->attrs[0];
i->t.target_attrs.ac.match = spi_target_match;
transport_container_register(&i->t.target_attrs);
i->t.target_size = sizeof(struct spi_transport_attrs);
i->t.host_attrs.ac.class = &spi_host_class.class;
i->t.host_attrs.ac.attrs = &i->host_attrs[0];
i->t.host_attrs.ac.match = spi_host_match;
transport_container_register(&i->t.host_attrs);
i->t.host_size = sizeof(struct spi_host_attrs);
i->f = ft;
SETUP_ATTRIBUTE(period);
SETUP_ATTRIBUTE(offset);
SETUP_ATTRIBUTE(width);
SETUP_ATTRIBUTE(iu);
SETUP_ATTRIBUTE(dt);
SETUP_ATTRIBUTE(qas);
SETUP_ATTRIBUTE(wr_flow);
SETUP_ATTRIBUTE(rd_strm);
SETUP_ATTRIBUTE(rti);
SETUP_ATTRIBUTE(pcomp_en);
/* if you add an attribute but forget to increase SPI_NUM_ATTRS
* this bug will trigger */
BUG_ON(count > SPI_NUM_ATTRS);
i->attrs[count++] = &class_device_attr_revalidate;
i->attrs[count] = NULL;
count = 0;
SETUP_HOST_ATTRIBUTE(signalling);
BUG_ON(count > SPI_HOST_ATTRS);
i->host_attrs[count] = NULL;
return &i->t;
}
EXPORT_SYMBOL(spi_attach_transport);
void spi_release_transport(struct scsi_transport_template *t)
{
struct spi_internal *i = to_spi_internal(t);
transport_container_unregister(&i->t.target_attrs);
transport_container_unregister(&i->t.host_attrs);
kfree(i);
}
EXPORT_SYMBOL(spi_release_transport);
static __init int spi_transport_init(void)
{
int error = transport_class_register(&spi_transport_class);
if (error)
return error;
error = anon_transport_class_register(&spi_device_class);
return transport_class_register(&spi_host_class);
}
static void __exit spi_transport_exit(void)
{
transport_class_unregister(&spi_transport_class);
anon_transport_class_unregister(&spi_device_class);
transport_class_unregister(&spi_host_class);
}
MODULE_AUTHOR("Martin Hicks");
MODULE_DESCRIPTION("SPI Transport Attributes");
MODULE_LICENSE("GPL");
module_init(spi_transport_init);
module_exit(spi_transport_exit);