linux_old1/drivers/w1/slaves/w1_therm.c

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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* w1_therm.c
*
* Copyright (c) 2004 Evgeniy Polyakov <zbr@ioremap.net>
*/
#include <asm/types.h>
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/sched.h>
#include <linux/device.h>
#include <linux/types.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <linux/hwmon.h>
#include <linux/w1.h>
#define W1_THERM_DS18S20 0x10
#define W1_THERM_DS1822 0x22
#define W1_THERM_DS18B20 0x28
#define W1_THERM_DS1825 0x3B
#define W1_THERM_DS28EA00 0x42
/* Allow the strong pullup to be disabled, but default to enabled.
* If it was disabled a parasite powered device might not get the require
* current to do a temperature conversion. If it is enabled parasite powered
* devices have a better chance of getting the current required.
* In case the parasite power-detection is not working (seems to be the case
* for some DS18S20) the strong pullup can also be forced, regardless of the
* power state of the devices.
*
* Summary of options:
* - strong_pullup = 0 Disable strong pullup completely
* - strong_pullup = 1 Enable automatic strong pullup detection
* - strong_pullup = 2 Force strong pullup
*/
static int w1_strong_pullup = 1;
module_param_named(strong_pullup, w1_strong_pullup, int, 0);
struct w1_therm_family_data {
uint8_t rom[9];
atomic_t refcnt;
};
struct therm_info {
u8 rom[9];
u8 crc;
u8 verdict;
};
/* return the address of the refcnt in the family data */
#define THERM_REFCNT(family_data) \
(&((struct w1_therm_family_data *)family_data)->refcnt)
static int w1_therm_add_slave(struct w1_slave *sl)
{
sl->family_data = kzalloc(sizeof(struct w1_therm_family_data),
GFP_KERNEL);
if (!sl->family_data)
return -ENOMEM;
atomic_set(THERM_REFCNT(sl->family_data), 1);
return 0;
}
static void w1_therm_remove_slave(struct w1_slave *sl)
{
int refcnt = atomic_sub_return(1, THERM_REFCNT(sl->family_data));
while (refcnt) {
msleep(1000);
refcnt = atomic_read(THERM_REFCNT(sl->family_data));
}
kfree(sl->family_data);
sl->family_data = NULL;
}
static ssize_t w1_slave_show(struct device *device,
W1: w1_therm fix user buffer overflow and cat Fixed data reading bug by replacing binary attribute with device one. Switching the sysfs read from bin_attribute to device_attribute. The data is far under PAGE_SIZE so the binary interface isn't required. As the device_attribute interface will make one call to w1_therm_read per file open and buffer, the result is, the following problems go away. buffer overflow: Execute a short read on w1_slave and w1_therm_read_bin would still return the full string size worth of data clobbering the user space buffer when it returned. Switching to device_attribute avoids the buffer overflow problems. With the snprintf formatted output dealing with short reads without doing a conversion per read would have been difficult. bad behavior: `cat w1_slave` would cause two temperature conversions to take place. Previously the code assumed W1_SLAVE_DATA_SIZE would be returned with each read. It would not return 0 unless the offset was less than W1_SLAVE_DATA_SIZE. The result was the first read did a temperature conversion, filled the buffer and returned, the offset in the second read would be less than W1_SLAVE_DATA_SIZE and also fill the buffer and return, the third read would finnally have a big enough offset to return 0 and cause cat to stop. Now w1_therm_read will be called at most once per open. Signed-off-by: David Fries <david@fries.net> Signed-off-by: Evgeniy Polyakov <johnpol@2ka.mipt.ru> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2008-10-16 13:04:51 +08:00
struct device_attribute *attr, char *buf);
static ssize_t w1_slave_store(struct device *device,
struct device_attribute *attr, const char *buf, size_t size);
static ssize_t w1_seq_show(struct device *device,
struct device_attribute *attr, char *buf);
static DEVICE_ATTR_RW(w1_slave);
static DEVICE_ATTR_RO(w1_seq);
static struct attribute *w1_therm_attrs[] = {
&dev_attr_w1_slave.attr,
NULL,
};
static struct attribute *w1_ds28ea00_attrs[] = {
&dev_attr_w1_slave.attr,
&dev_attr_w1_seq.attr,
NULL,
};
ATTRIBUTE_GROUPS(w1_therm);
ATTRIBUTE_GROUPS(w1_ds28ea00);
#if IS_REACHABLE(CONFIG_HWMON)
static int w1_read_temp(struct device *dev, u32 attr, int channel,
long *val);
static umode_t w1_is_visible(const void *_data, enum hwmon_sensor_types type,
u32 attr, int channel)
{
return attr == hwmon_temp_input ? 0444 : 0;
}
static int w1_read(struct device *dev, enum hwmon_sensor_types type,
u32 attr, int channel, long *val)
{
switch (type) {
case hwmon_temp:
return w1_read_temp(dev, attr, channel, val);
default:
return -EOPNOTSUPP;
}
}
static const u32 w1_temp_config[] = {
HWMON_T_INPUT,
0
};
static const struct hwmon_channel_info w1_temp = {
.type = hwmon_temp,
.config = w1_temp_config,
};
static const struct hwmon_channel_info *w1_info[] = {
&w1_temp,
NULL
};
static const struct hwmon_ops w1_hwmon_ops = {
.is_visible = w1_is_visible,
.read = w1_read,
};
static const struct hwmon_chip_info w1_chip_info = {
.ops = &w1_hwmon_ops,
.info = w1_info,
};
#define W1_CHIPINFO (&w1_chip_info)
#else
#define W1_CHIPINFO NULL
#endif
static struct w1_family_ops w1_therm_fops = {
.add_slave = w1_therm_add_slave,
.remove_slave = w1_therm_remove_slave,
.groups = w1_therm_groups,
.chip_info = W1_CHIPINFO,
};
static struct w1_family_ops w1_ds28ea00_fops = {
.add_slave = w1_therm_add_slave,
.remove_slave = w1_therm_remove_slave,
.groups = w1_ds28ea00_groups,
.chip_info = W1_CHIPINFO,
};
static struct w1_family w1_therm_family_DS18S20 = {
.fid = W1_THERM_DS18S20,
.fops = &w1_therm_fops,
};
static struct w1_family w1_therm_family_DS18B20 = {
.fid = W1_THERM_DS18B20,
.fops = &w1_therm_fops,
};
static struct w1_family w1_therm_family_DS1822 = {
.fid = W1_THERM_DS1822,
.fops = &w1_therm_fops,
};
static struct w1_family w1_therm_family_DS28EA00 = {
.fid = W1_THERM_DS28EA00,
.fops = &w1_ds28ea00_fops,
};
static struct w1_family w1_therm_family_DS1825 = {
.fid = W1_THERM_DS1825,
.fops = &w1_therm_fops,
};
struct w1_therm_family_converter {
u8 broken;
u16 reserved;
struct w1_family *f;
int (*convert)(u8 rom[9]);
int (*precision)(struct device *device, int val);
int (*eeprom)(struct device *device);
};
/* write configuration to eeprom */
static inline int w1_therm_eeprom(struct device *device);
/* Set precision for conversion */
static inline int w1_DS18B20_precision(struct device *device, int val);
static inline int w1_DS18S20_precision(struct device *device, int val);
/* The return value is millidegrees Centigrade. */
static inline int w1_DS18B20_convert_temp(u8 rom[9]);
static inline int w1_DS18S20_convert_temp(u8 rom[9]);
static struct w1_therm_family_converter w1_therm_families[] = {
{
.f = &w1_therm_family_DS18S20,
.convert = w1_DS18S20_convert_temp,
.precision = w1_DS18S20_precision,
.eeprom = w1_therm_eeprom
},
{
.f = &w1_therm_family_DS1822,
.convert = w1_DS18B20_convert_temp,
.precision = w1_DS18S20_precision,
.eeprom = w1_therm_eeprom
},
{
.f = &w1_therm_family_DS18B20,
.convert = w1_DS18B20_convert_temp,
.precision = w1_DS18B20_precision,
.eeprom = w1_therm_eeprom
},
{
.f = &w1_therm_family_DS28EA00,
.convert = w1_DS18B20_convert_temp,
.precision = w1_DS18S20_precision,
.eeprom = w1_therm_eeprom
},
{
.f = &w1_therm_family_DS1825,
.convert = w1_DS18B20_convert_temp,
.precision = w1_DS18S20_precision,
.eeprom = w1_therm_eeprom
}
};
static inline int w1_therm_eeprom(struct device *device)
{
struct w1_slave *sl = dev_to_w1_slave(device);
struct w1_master *dev = sl->master;
u8 rom[9], external_power;
int ret, max_trying = 10;
u8 *family_data = sl->family_data;
if (!sl->family_data) {
ret = -ENODEV;
goto error;
}
/* prevent the slave from going away in sleep */
atomic_inc(THERM_REFCNT(family_data));
ret = mutex_lock_interruptible(&dev->bus_mutex);
if (ret != 0)
goto dec_refcnt;
memset(rom, 0, sizeof(rom));
while (max_trying--) {
if (!w1_reset_select_slave(sl)) {
unsigned int tm = 10;
unsigned long sleep_rem;
/* check if in parasite mode */
w1_write_8(dev, W1_READ_PSUPPLY);
external_power = w1_read_8(dev);
if (w1_reset_select_slave(sl))
continue;
/* 10ms strong pullup/delay after the copy command */
if (w1_strong_pullup == 2 ||
(!external_power && w1_strong_pullup))
w1_next_pullup(dev, tm);
w1_write_8(dev, W1_COPY_SCRATCHPAD);
if (external_power) {
mutex_unlock(&dev->bus_mutex);
sleep_rem = msleep_interruptible(tm);
if (sleep_rem != 0) {
ret = -EINTR;
goto dec_refcnt;
}
ret = mutex_lock_interruptible(&dev->bus_mutex);
if (ret != 0)
goto dec_refcnt;
} else if (!w1_strong_pullup) {
sleep_rem = msleep_interruptible(tm);
if (sleep_rem != 0) {
ret = -EINTR;
goto mt_unlock;
}
}
break;
}
}
mt_unlock:
mutex_unlock(&dev->bus_mutex);
dec_refcnt:
atomic_dec(THERM_REFCNT(family_data));
error:
return ret;
}
/* DS18S20 does not feature configuration register */
static inline int w1_DS18S20_precision(struct device *device, int val)
{
return 0;
}
static inline int w1_DS18B20_precision(struct device *device, int val)
{
struct w1_slave *sl = dev_to_w1_slave(device);
struct w1_master *dev = sl->master;
u8 rom[9], crc;
int ret, max_trying = 10;
u8 *family_data = sl->family_data;
uint8_t precision_bits;
uint8_t mask = 0x60;
if (val > 12 || val < 9) {
pr_warn("Unsupported precision\n");
ret = -EINVAL;
goto error;
}
if (!sl->family_data) {
ret = -ENODEV;
goto error;
}
/* prevent the slave from going away in sleep */
atomic_inc(THERM_REFCNT(family_data));
ret = mutex_lock_interruptible(&dev->bus_mutex);
if (ret != 0)
goto dec_refcnt;
memset(rom, 0, sizeof(rom));
/* translate precision to bitmask (see datasheet page 9) */
switch (val) {
case 9:
precision_bits = 0x00;
break;
case 10:
precision_bits = 0x20;
break;
case 11:
precision_bits = 0x40;
break;
case 12:
default:
precision_bits = 0x60;
break;
}
while (max_trying--) {
crc = 0;
if (!w1_reset_select_slave(sl)) {
int count = 0;
/* read values to only alter precision bits */
w1_write_8(dev, W1_READ_SCRATCHPAD);
count = w1_read_block(dev, rom, 9);
if (count != 9)
dev_warn(device, "w1_read_block() returned %u instead of 9.\n", count);
crc = w1_calc_crc8(rom, 8);
if (rom[8] == crc) {
rom[4] = (rom[4] & ~mask) | (precision_bits & mask);
if (!w1_reset_select_slave(sl)) {
w1_write_8(dev, W1_WRITE_SCRATCHPAD);
w1_write_8(dev, rom[2]);
w1_write_8(dev, rom[3]);
w1_write_8(dev, rom[4]);
break;
}
}
}
}
mutex_unlock(&dev->bus_mutex);
dec_refcnt:
atomic_dec(THERM_REFCNT(family_data));
error:
return ret;
}
static inline int w1_DS18B20_convert_temp(u8 rom[9])
{
s16 t = le16_to_cpup((__le16 *)rom);
return t*1000/16;
}
static inline int w1_DS18S20_convert_temp(u8 rom[9])
{
int t, h;
if (!rom[7])
return 0;
if (rom[1] == 0)
t = ((s32)rom[0] >> 1)*1000;
else
t = 1000*(-1*(s32)(0x100-rom[0]) >> 1);
t -= 250;
h = 1000*((s32)rom[7] - (s32)rom[6]);
h /= (s32)rom[7];
t += h;
return t;
}
static inline int w1_convert_temp(u8 rom[9], u8 fid)
{
int i;
for (i = 0; i < ARRAY_SIZE(w1_therm_families); ++i)
if (w1_therm_families[i].f->fid == fid)
return w1_therm_families[i].convert(rom);
return 0;
}
static ssize_t w1_slave_store(struct device *device,
struct device_attribute *attr, const char *buf,
size_t size)
{
int val, ret;
struct w1_slave *sl = dev_to_w1_slave(device);
int i;
ret = kstrtoint(buf, 0, &val);
if (ret)
return ret;
for (i = 0; i < ARRAY_SIZE(w1_therm_families); ++i) {
if (w1_therm_families[i].f->fid == sl->family->fid) {
/* zero value indicates to write current configuration to eeprom */
if (val == 0)
ret = w1_therm_families[i].eeprom(device);
else
ret = w1_therm_families[i].precision(device, val);
break;
}
}
return ret ? : size;
}
static ssize_t read_therm(struct device *device,
struct w1_slave *sl, struct therm_info *info)
{
struct w1_master *dev = sl->master;
u8 external_power;
int ret, max_trying = 10;
u8 *family_data = sl->family_data;
if (!family_data) {
ret = -ENODEV;
goto error;
}
/* prevent the slave from going away in sleep */
atomic_inc(THERM_REFCNT(family_data));
ret = mutex_lock_interruptible(&dev->bus_mutex);
if (ret != 0)
goto dec_refcnt;
memset(info->rom, 0, sizeof(info->rom));
while (max_trying--) {
info->verdict = 0;
info->crc = 0;
if (!w1_reset_select_slave(sl)) {
int count = 0;
unsigned int tm = 750;
unsigned long sleep_rem;
w1_write_8(dev, W1_READ_PSUPPLY);
external_power = w1_read_8(dev);
if (w1_reset_select_slave(sl))
continue;
/* 750ms strong pullup (or delay) after the convert */
if (w1_strong_pullup == 2 ||
(!external_power && w1_strong_pullup))
w1_next_pullup(dev, tm);
w1_write_8(dev, W1_CONVERT_TEMP);
if (external_power) {
W1: split master mutex to avoid deadlocks. The 'mutex' in struct w1_master is use for two very different purposes. Firstly it protects various data structures such as the list of all slaves. Secondly it protects the w1 buss against concurrent accesses. This can lead to deadlocks when the ->probe code called while adding a slave needs to talk on the bus, as is the case for power_supply devices. ds2780 and ds2781 drivers contain a work around to track which process hold the lock simply to avoid this deadlock. bq27000 doesn't have that work around and so deadlocks. There are other possible deadlocks involving sysfs. When removing a device the sysfs s_active lock is held, so the lock that protects the slave list must take precedence over s_active. However when access power_supply attributes via sysfs, the s_active lock must take precedence over the lock that protects accesses to the bus. So to avoid deadlocks between w1 slaves and sysfs, these must be two separate locks. Making them separate means that the work around in ds2780 and ds2781 can be removed. So this patch: - adds a new mutex: "bus_mutex" which serialises access to the bus. - takes in mutex in w1_search and ds1wm_search while they access the bus for searching. The mutex is dropped before calling the callback which adds the slave. - changes all slaves to use bus_mutex instead of mutex to protect access to the bus - removes w1_ds2790_io_nolock and w1_ds2781_io_nolock, and the related code from drivers/power/ds278[01]_battery.c which calls them. Signed-off-by: NeilBrown <neilb@suse.de> Acked-by: Evgeniy Polyakov <zbr@ioremap.net> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-05-18 13:59:52 +08:00
mutex_unlock(&dev->bus_mutex);
sleep_rem = msleep_interruptible(tm);
if (sleep_rem != 0) {
ret = -EINTR;
goto dec_refcnt;
}
ret = mutex_lock_interruptible(&dev->bus_mutex);
if (ret != 0)
goto dec_refcnt;
} else if (!w1_strong_pullup) {
sleep_rem = msleep_interruptible(tm);
if (sleep_rem != 0) {
ret = -EINTR;
goto mt_unlock;
}
}
if (!w1_reset_select_slave(sl)) {
w1_write_8(dev, W1_READ_SCRATCHPAD);
count = w1_read_block(dev, info->rom, 9);
if (count != 9) {
W1: w1_therm fix user buffer overflow and cat Fixed data reading bug by replacing binary attribute with device one. Switching the sysfs read from bin_attribute to device_attribute. The data is far under PAGE_SIZE so the binary interface isn't required. As the device_attribute interface will make one call to w1_therm_read per file open and buffer, the result is, the following problems go away. buffer overflow: Execute a short read on w1_slave and w1_therm_read_bin would still return the full string size worth of data clobbering the user space buffer when it returned. Switching to device_attribute avoids the buffer overflow problems. With the snprintf formatted output dealing with short reads without doing a conversion per read would have been difficult. bad behavior: `cat w1_slave` would cause two temperature conversions to take place. Previously the code assumed W1_SLAVE_DATA_SIZE would be returned with each read. It would not return 0 unless the offset was less than W1_SLAVE_DATA_SIZE. The result was the first read did a temperature conversion, filled the buffer and returned, the offset in the second read would be less than W1_SLAVE_DATA_SIZE and also fill the buffer and return, the third read would finnally have a big enough offset to return 0 and cause cat to stop. Now w1_therm_read will be called at most once per open. Signed-off-by: David Fries <david@fries.net> Signed-off-by: Evgeniy Polyakov <johnpol@2ka.mipt.ru> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2008-10-16 13:04:51 +08:00
dev_warn(device, "w1_read_block() "
"returned %u instead of 9.\n",
count);
}
info->crc = w1_calc_crc8(info->rom, 8);
if (info->rom[8] == info->crc)
info->verdict = 1;
}
}
if (info->verdict)
break;
}
mt_unlock:
mutex_unlock(&dev->bus_mutex);
dec_refcnt:
atomic_dec(THERM_REFCNT(family_data));
error:
return ret;
}
static ssize_t w1_slave_show(struct device *device,
struct device_attribute *attr, char *buf)
{
struct w1_slave *sl = dev_to_w1_slave(device);
struct therm_info info;
u8 *family_data = sl->family_data;
int ret, i;
ssize_t c = PAGE_SIZE;
u8 fid = sl->family->fid;
ret = read_therm(device, sl, &info);
if (ret)
return ret;
for (i = 0; i < 9; ++i)
c -= snprintf(buf + PAGE_SIZE - c, c, "%02x ", info.rom[i]);
W1: w1_therm fix user buffer overflow and cat Fixed data reading bug by replacing binary attribute with device one. Switching the sysfs read from bin_attribute to device_attribute. The data is far under PAGE_SIZE so the binary interface isn't required. As the device_attribute interface will make one call to w1_therm_read per file open and buffer, the result is, the following problems go away. buffer overflow: Execute a short read on w1_slave and w1_therm_read_bin would still return the full string size worth of data clobbering the user space buffer when it returned. Switching to device_attribute avoids the buffer overflow problems. With the snprintf formatted output dealing with short reads without doing a conversion per read would have been difficult. bad behavior: `cat w1_slave` would cause two temperature conversions to take place. Previously the code assumed W1_SLAVE_DATA_SIZE would be returned with each read. It would not return 0 unless the offset was less than W1_SLAVE_DATA_SIZE. The result was the first read did a temperature conversion, filled the buffer and returned, the offset in the second read would be less than W1_SLAVE_DATA_SIZE and also fill the buffer and return, the third read would finnally have a big enough offset to return 0 and cause cat to stop. Now w1_therm_read will be called at most once per open. Signed-off-by: David Fries <david@fries.net> Signed-off-by: Evgeniy Polyakov <johnpol@2ka.mipt.ru> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2008-10-16 13:04:51 +08:00
c -= snprintf(buf + PAGE_SIZE - c, c, ": crc=%02x %s\n",
info.crc, (info.verdict) ? "YES" : "NO");
if (info.verdict)
memcpy(family_data, info.rom, sizeof(info.rom));
else
dev_warn(device, "Read failed CRC check\n");
for (i = 0; i < 9; ++i)
c -= snprintf(buf + PAGE_SIZE - c, c, "%02x ",
((u8 *)family_data)[i]);
W1: w1_therm fix user buffer overflow and cat Fixed data reading bug by replacing binary attribute with device one. Switching the sysfs read from bin_attribute to device_attribute. The data is far under PAGE_SIZE so the binary interface isn't required. As the device_attribute interface will make one call to w1_therm_read per file open and buffer, the result is, the following problems go away. buffer overflow: Execute a short read on w1_slave and w1_therm_read_bin would still return the full string size worth of data clobbering the user space buffer when it returned. Switching to device_attribute avoids the buffer overflow problems. With the snprintf formatted output dealing with short reads without doing a conversion per read would have been difficult. bad behavior: `cat w1_slave` would cause two temperature conversions to take place. Previously the code assumed W1_SLAVE_DATA_SIZE would be returned with each read. It would not return 0 unless the offset was less than W1_SLAVE_DATA_SIZE. The result was the first read did a temperature conversion, filled the buffer and returned, the offset in the second read would be less than W1_SLAVE_DATA_SIZE and also fill the buffer and return, the third read would finnally have a big enough offset to return 0 and cause cat to stop. Now w1_therm_read will be called at most once per open. Signed-off-by: David Fries <david@fries.net> Signed-off-by: Evgeniy Polyakov <johnpol@2ka.mipt.ru> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2008-10-16 13:04:51 +08:00
c -= snprintf(buf + PAGE_SIZE - c, c, "t=%d\n",
w1_convert_temp(info.rom, fid));
ret = PAGE_SIZE - c;
return ret;
}
#if IS_REACHABLE(CONFIG_HWMON)
static int w1_read_temp(struct device *device, u32 attr, int channel,
long *val)
{
struct w1_slave *sl = dev_get_drvdata(device);
struct therm_info info;
u8 fid = sl->family->fid;
int ret;
switch (attr) {
case hwmon_temp_input:
ret = read_therm(device, sl, &info);
if (ret)
return ret;
if (!info.verdict) {
ret = -EIO;
return ret;
}
*val = w1_convert_temp(info.rom, fid);
ret = 0;
break;
default:
ret = -EOPNOTSUPP;
break;
}
return ret;
}
#endif
#define W1_42_CHAIN 0x99
#define W1_42_CHAIN_OFF 0x3C
#define W1_42_CHAIN_OFF_INV 0xC3
#define W1_42_CHAIN_ON 0x5A
#define W1_42_CHAIN_ON_INV 0xA5
#define W1_42_CHAIN_DONE 0x96
#define W1_42_CHAIN_DONE_INV 0x69
#define W1_42_COND_READ 0x0F
#define W1_42_SUCCESS_CONFIRM_BYTE 0xAA
#define W1_42_FINISHED_BYTE 0xFF
static ssize_t w1_seq_show(struct device *device,
struct device_attribute *attr, char *buf)
{
struct w1_slave *sl = dev_to_w1_slave(device);
ssize_t c = PAGE_SIZE;
int rv;
int i;
u8 ack;
u64 rn;
struct w1_reg_num *reg_num;
int seq = 0;
mutex_lock(&sl->master->bus_mutex);
/* Place all devices in CHAIN state */
if (w1_reset_bus(sl->master))
goto error;
w1_write_8(sl->master, W1_SKIP_ROM);
w1_write_8(sl->master, W1_42_CHAIN);
w1_write_8(sl->master, W1_42_CHAIN_ON);
w1_write_8(sl->master, W1_42_CHAIN_ON_INV);
msleep(sl->master->pullup_duration);
/* check for acknowledgment */
ack = w1_read_8(sl->master);
if (ack != W1_42_SUCCESS_CONFIRM_BYTE)
goto error;
/* In case the bus fails to send 0xFF, limit*/
for (i = 0; i <= 64; i++) {
if (w1_reset_bus(sl->master))
goto error;
w1_write_8(sl->master, W1_42_COND_READ);
rv = w1_read_block(sl->master, (u8 *)&rn, 8);
reg_num = (struct w1_reg_num *) &rn;
if (reg_num->family == W1_42_FINISHED_BYTE)
break;
if (sl->reg_num.id == reg_num->id)
seq = i;
w1_write_8(sl->master, W1_42_CHAIN);
w1_write_8(sl->master, W1_42_CHAIN_DONE);
w1_write_8(sl->master, W1_42_CHAIN_DONE_INV);
w1_read_block(sl->master, &ack, sizeof(ack));
/* check for acknowledgment */
ack = w1_read_8(sl->master);
if (ack != W1_42_SUCCESS_CONFIRM_BYTE)
goto error;
}
/* Exit from CHAIN state */
if (w1_reset_bus(sl->master))
goto error;
w1_write_8(sl->master, W1_SKIP_ROM);
w1_write_8(sl->master, W1_42_CHAIN);
w1_write_8(sl->master, W1_42_CHAIN_OFF);
w1_write_8(sl->master, W1_42_CHAIN_OFF_INV);
/* check for acknowledgment */
ack = w1_read_8(sl->master);
if (ack != W1_42_SUCCESS_CONFIRM_BYTE)
goto error;
mutex_unlock(&sl->master->bus_mutex);
c -= snprintf(buf + PAGE_SIZE - c, c, "%d\n", seq);
return PAGE_SIZE - c;
error:
mutex_unlock(&sl->master->bus_mutex);
return -EIO;
}
static int __init w1_therm_init(void)
{
int err, i;
for (i = 0; i < ARRAY_SIZE(w1_therm_families); ++i) {
err = w1_register_family(w1_therm_families[i].f);
if (err)
w1_therm_families[i].broken = 1;
}
return 0;
}
static void __exit w1_therm_fini(void)
{
int i;
for (i = 0; i < ARRAY_SIZE(w1_therm_families); ++i)
if (!w1_therm_families[i].broken)
w1_unregister_family(w1_therm_families[i].f);
}
module_init(w1_therm_init);
module_exit(w1_therm_fini);
MODULE_AUTHOR("Evgeniy Polyakov <zbr@ioremap.net>");
MODULE_DESCRIPTION("Driver for 1-wire Dallas network protocol, temperature family.");
MODULE_LICENSE("GPL");
MODULE_ALIAS("w1-family-" __stringify(W1_THERM_DS18S20));
MODULE_ALIAS("w1-family-" __stringify(W1_THERM_DS1822));
MODULE_ALIAS("w1-family-" __stringify(W1_THERM_DS18B20));
MODULE_ALIAS("w1-family-" __stringify(W1_THERM_DS1825));
MODULE_ALIAS("w1-family-" __stringify(W1_THERM_DS28EA00));