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提交 d58de038 编写于 作者: G George Joseph 提交者: Jean Delvare
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hwmon: Driver for Andigilog aSC7621 family monitoring chips 

Hwmon driver for Andigilog aSC7621 family monitoring chips.
Signed-off-by: NGeorge Joseph <george.joseph@fairview5.com>
Acked-by: NHans de Goede <hdegoede@redhat.com>
Signed-off-by: NJean Delvare <khali@linux-fr.org>
上级 23244985
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Kernel driver asc7621
==================
Supported chips:
Andigilog aSC7621 and aSC7621a
Prefix: 'asc7621'
Addresses scanned: I2C 0x2c, 0x2d, 0x2e
Datasheet: http://www.fairview5.com/linux/asc7621/asc7621.pdf
Author:
George Joseph
Description provided by Dave Pivin @ Andigilog:
Andigilog has both the PECI and pre-PECI versions of the Heceta-6, as
Intel calls them. Heceta-6e has high frequency PWM and Heceta-6p has
added PECI and a 4th thermal zone. The Andigilog aSC7611 is the
Heceta-6e part and aSC7621 is the Heceta-6p part. They are both in
volume production, shipping to Intel and their subs.
We have enhanced both parts relative to the governing Intel
specification. First enhancement is temperature reading resolution. We
have used registers below 20h for vendor-specific functions in addition
to those in the Intel-specified vendor range.
Our conversion process produces a result that is reported as two bytes.
The fan speed control uses this finer value to produce a "step-less" fan
PWM output. These two bytes are "read-locked" to guarantee that once a
high or low byte is read, the other byte is locked-in until after the
next read of any register. So to get an atomic reading, read high or low
byte, then the very next read should be the opposite byte. Our data
sheet says 10-bits of resolution, although you may find the lower bits
are active, they are not necessarily reliable or useful externally. We
chose not to mask them.
We employ significant filtering that is user tunable as described in the
data sheet. Our temperature reports and fan PWM outputs are very smooth
when compared to the competition, in addition to the higher resolution
temperature reports. The smoother PWM output does not require user
intervention.
We offer GPIO features on the former VID pins. These are open-drain
outputs or inputs and may be used as general purpose I/O or as alarm
outputs that are based on temperature limits. These are in 19h and 1Ah.
We offer flexible mapping of temperature readings to thermal zones. Any
temperature may be mapped to any zone, which has a default assignment
that follows Intel's specs.
Since there is a fan to zone assignment that allows for the "hotter" of
a set of zones to control the PWM of an individual fan, but there is no
indication to the user, we have added an indicator that shows which zone
is currently controlling the PWM for a given fan. This is in register
00h.
Both remote diode temperature readings may be given an offset value such
that the reported reading as well as the temperature used to determine
PWM may be offset for system calibration purposes.
PECI Extended configuration allows for having more than two domains per
PECI address and also provides an enabling function for each PECI
address. One could use our flexible zone assignment to have a zone
assigned to up to 4 PECI addresses. This is not possible in the default
Intel configuration. This would be useful in multi-CPU systems with
individual fans on each that would benefit from individual fan control.
This is in register 0Eh.
The tachometer measurement system is flexible and able to adapt to many
fan types. We can also support pulse-stretched PWM so that 3-wire fans
may be used. These characteristics are in registers 04h to 07h.
Finally, we have added a tach disable function that turns off the tach
measurement system for individual tachs in order to save power. That is
in register 75h.
--
aSC7621 Product Description
The aSC7621 has a two wire digital interface compatible with SMBus 2.0.
Using a 10-bit ADC, the aSC7621 measures the temperature of two remote diode
connected transistors as well as its own die. Support for Platform
Environmental Control Interface (PECI) is included.
Using temperature information from these four zones, an automatic fan speed
control algorithm is employed to minimize acoustic impact while achieving
recommended CPU temperature under varying operational loads.
To set fan speed, the aSC7621 has three independent pulse width modulation
(PWM) outputs that are controlled by one, or a combination of three,
temperature zones. Both high- and low-frequency PWM ranges are supported.
The aSC7621 also includes a digital filter that can be invoked to smooth
temperature readings for better control of fan speed and minimum acoustic
impact.
The aSC7621 has tachometer inputs to measure fan speed on up to four fans.
Limit and status registers for all measured values are included to alert
the system host that any measurements are outside of programmed limits
via status registers.
System voltages of VCCP, 2.5V, 3.3V, 5.0V, and 12V motherboard power are
monitored efficiently with internal scaling resistors.
Features
- Supports PECI interface and monitors internal and remote thermal diodes
- 2-wire, SMBus 2.0 compliant, serial interface
- 10-bit ADC
- Monitors VCCP, 2.5V, 3.3V, 5.0V, and 12V motherboard/processor supplies
- Programmable autonomous fan control based on temperature readings
- Noise filtering of temperature reading for fan speed control
- 0.25C digital temperature sensor resolution
- 3 PWM fan speed control outputs for 2-, 3- or 4-wire fans and up to 4 fan
tachometer inputs
- Enhanced measured temperature to Temperature Zone assignment.
- Provides high and low PWM frequency ranges
- 3 GPIO pins for custom use
- 24-Lead QSOP package
Configuration Notes
===================
Except where noted below, the sysfs entries created by this driver follow
the standards defined in "sysfs-interface".
temp1_source
0 (default) peci_legacy = 0, Remote 1 Temperature
peci_legacy = 1, PECI Processor Temperature 0
1 Remote 1 Temperature
2 Remote 2 Temperature
3 Internal Temperature
4 PECI Processor Temperature 0
5 PECI Processor Temperature 1
6 PECI Processor Temperature 2
7 PECI Processor Temperature 3
temp2_source
0 (default) Internal Temperature
1 Remote 1 Temperature
2 Remote 2 Temperature
3 Internal Temperature
4 PECI Processor Temperature 0
5 PECI Processor Temperature 1
6 PECI Processor Temperature 2
7 PECI Processor Temperature 3
temp3_source
0 (default) Remote 2 Temperature
1 Remote 1 Temperature
2 Remote 2 Temperature
3 Internal Temperature
4 PECI Processor Temperature 0
5 PECI Processor Temperature 1
6 PECI Processor Temperature 2
7 PECI Processor Temperature 3
temp4_source
0 (default) peci_legacy = 0, PECI Processor Temperature 0
peci_legacy = 1, Remote 1 Temperature
1 Remote 1 Temperature
2 Remote 2 Temperature
3 Internal Temperature
4 PECI Processor Temperature 0
5 PECI Processor Temperature 1
6 PECI Processor Temperature 2
7 PECI Processor Temperature 3
temp[1-4]_smoothing_enable
temp[1-4]_smoothing_time
Smooths spikes in temp readings caused by noise.
Valid values in milliseconds are:
35000
17600
11800
7000
4400
3000
1600
800
temp[1-4]_crit
When the corresponding zone temperature reaches this value,
ALL pwm outputs will got to 100%.
temp[5-8]_input
temp[5-8]_enable
The aSC7621 can also read temperatures provided by the processor
via the PECI bus. Usually these are "core" temps and are relative
to the point where the automatic thermal control circuit starts
throttling. This means that these are usually negative numbers.
pwm[1-3]_enable
0 Fan off.
1 Fan on manual control.
2 Fan on automatic control and will run at the minimum pwm
if the temperature for the zone is below the minimum.
3 Fan on automatic control but will be off if the temperature
for the zone is below the minimum.
4-254 Ignored.
255 Fan on full.
pwm[1-3]_auto_channels
Bitmap as described in sysctl-interface with the following
exceptions...
Only the following combination of zones (and their corresponding masks)
are valid:
1
2
3
2,3
1,2,3
4
1,2,3,4
Special values:
0 Disabled.
16 Fan on manual control.
31 Fan on full.
pwm[1-3]_invert
When set, inverts the meaning of pwm[1-3].
i.e. when pwm = 0, the fan will be on full and
when pwm = 255 the fan will be off.
pwm[1-3]_freq
PWM frequency in Hz
Valid values in Hz are:
10
15
23
30 (default)
38
47
62
94
23000
24000
25000
26000
27000
28000
29000
30000
Setting any other value will be ignored.
peci_enable
Enables or disables PECI
peci_avg
Input filter average time.
0 0 Sec. (no Smoothing) (default)
1 0.25 Sec.
2 0.5 Sec.
3 1.0 Sec.
4 2.0 Sec.
5 4.0 Sec.
6 8.0 Sec.
7 0.0 Sec.
peci_legacy
0 Standard Mode (default)
Remote Diode 1 reading is associated with
Temperature Zone 1, PECI is associated with
Zone 4
1 Legacy Mode
PECI is associated with Temperature Zone 1,
Remote Diode 1 is associated with Zone 4
peci_diode
Diode filter
0 0.25 Sec.
1 1.1 Sec.
2 2.4 Sec. (default)
3 3.4 Sec.
4 5.0 Sec.
5 6.8 Sec.
6 10.2 Sec.
7 16.4 Sec.
peci_4domain
Four domain enable
0 1 or 2 Domains for enabled processors (default)
1 3 or 4 Domains for enabled processors
peci_domain
Domain
0 Processor contains a single domain (0) (default)
1 Processor contains two domains (0,1)
MAINTAINERS
浏览文件 @ d58de038
......@@ -966,6 +966,13 @@ W: http://www.arm.linux.org.uk/
S: Maintained
F: arch/arm/vfp/
ASC7621 HARDWARE MONITOR DRIVER
M: George Joseph <george.joseph@fairview5.com>
L: lm-sensors@lm-sensors.org
S: Maintained
F: Documentation/hwmon/asc7621
F: drivers/hwmon/asc7621.c
ASUS ACPI EXTRAS DRIVER
M: Corentin Chary <corentincj@iksaif.net>
M: Karol Kozimor <sziwan@users.sourceforge.net>
......
drivers/hwmon/Kconfig
浏览文件 @ d58de038
......@@ -226,6 +226,19 @@ config SENSORS_ADT7475
This driver can also be build as a module. If so, the module
will be called adt7475.
config SENSORS_ASC7621
tristate "Andigilog aSC7621"
depends on HWMON && I2C
help
If you say yes here you get support for the aSC7621
family of SMBus sensors chip found on most Intel X48, X38, 975,
965 and 945 desktop boards. Currently supported chips:
aSC7621
aSC7621a
This driver can also be built as a module. If so, the module
will be called asc7621.
config SENSORS_K8TEMP
tristate "AMD Athlon64/FX or Opteron temperature sensor"
depends on X86 && PCI && EXPERIMENTAL
......
drivers/hwmon/Makefile
浏览文件 @ d58de038
......@@ -36,6 +36,7 @@ obj-$(CONFIG_SENSORS_ADT7473) += adt7473.o
obj-$(CONFIG_SENSORS_ADT7475) += adt7475.o
obj-$(CONFIG_SENSORS_APPLESMC) += applesmc.o
obj-$(CONFIG_SENSORS_AMS) += ams/
obj-$(CONFIG_SENSORS_ASC7621) += asc7621.o
obj-$(CONFIG_SENSORS_ATXP1) += atxp1.o
obj-$(CONFIG_SENSORS_CORETEMP) += coretemp.o
obj-$(CONFIG_SENSORS_DME1737) += dme1737.o
......
drivers/hwmon/asc7621.c 0 → 100644
浏览文件 @ d58de038
/*
* asc7621.c - Part of lm_sensors, Linux kernel modules for hardware monitoring
* Copyright (c) 2007, 2010 George Joseph <george.joseph@fairview5.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., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <linux/module.h>
#include <linux/init.h>
#include <linux/slab.h>
#include <linux/jiffies.h>
#include <linux/i2c.h>
#include <linux/hwmon.h>
#include <linux/hwmon-sysfs.h>
#include <linux/err.h>
#include <linux/mutex.h>
/* Addresses to scan */
static unsigned short normal_i2c[] = {
0x2c, 0x2d, 0x2e, I2C_CLIENT_END
};
enum asc7621_type {
asc7621,
asc7621a
};
#define INTERVAL_HIGH (HZ + HZ / 2)
#define INTERVAL_LOW (1 * 60 * HZ)
#define PRI_NONE 0
#define PRI_LOW 1
#define PRI_HIGH 2
#define FIRST_CHIP asc7621
#define LAST_CHIP asc7621a
struct asc7621_chip {
char *name;
enum asc7621_type chip_type;
u8 company_reg;
u8 company_id;
u8 verstep_reg;
u8 verstep_id;
unsigned short *addresses;
};
static struct asc7621_chip asc7621_chips[] = {
{
.name = "asc7621",
.chip_type = asc7621,
.company_reg = 0x3e,
.company_id = 0x61,
.verstep_reg = 0x3f,
.verstep_id = 0x6c,
.addresses = normal_i2c,
},
{
.name = "asc7621a",
.chip_type = asc7621a,
.company_reg = 0x3e,
.company_id = 0x61,
.verstep_reg = 0x3f,
.verstep_id = 0x6d,
.addresses = normal_i2c,
},
};
/*
* Defines the highest register to be used, not the count.
* The actual count will probably be smaller because of gaps
* in the implementation (unused register locations).
* This define will safely set the array size of both the parameter
* and data arrays.
* This comes from the data sheet register description table.
*/
#define LAST_REGISTER 0xff
struct asc7621_data {
struct i2c_client client;
struct device *class_dev;
struct mutex update_lock;
int valid; /* !=0 if following fields are valid */
unsigned long last_high_reading; /* In jiffies */
unsigned long last_low_reading; /* In jiffies */
/*
* Registers we care about occupy the corresponding index
* in the array. Registers we don't care about are left
* at 0.
*/
u8 reg[LAST_REGISTER + 1];
};
/*
* Macro to get the parent asc7621_param structure
* from a sensor_device_attribute passed into the
* show/store functions.
*/
#define to_asc7621_param(_sda) \
container_of(_sda, struct asc7621_param, sda)
/*
* Each parameter to be retrieved needs an asc7621_param structure
* allocated. It contains the sensor_device_attribute structure
* and the control info needed to retrieve the value from the register map.
*/
struct asc7621_param {
struct sensor_device_attribute sda;
u8 priority;
u8 msb[3];
u8 lsb[3];
u8 mask[3];
u8 shift[3];
};
/*
* This is the map that ultimately indicates whether we'll be
* retrieving a register value or not, and at what frequency.
*/
static u8 asc7621_register_priorities[255];
static struct asc7621_data *asc7621_update_device(struct device *dev);
static inline u8 read_byte(struct i2c_client *client, u8 reg)
{
int res = i2c_smbus_read_byte_data(client, reg);
if (res < 0) {
dev_err(&client->dev,
"Unable to read from register 0x%02x.\n", reg);
return 0;
};
return res & 0xff;
}
static inline int write_byte(struct i2c_client *client, u8 reg, u8 data)
{
int res = i2c_smbus_write_byte_data(client, reg, data);
if (res < 0) {
dev_err(&client->dev,
"Unable to write value 0x%02x to register 0x%02x.\n",
data, reg);
};
return res;
}
/*
* Data Handlers
* Each function handles the formatting, storage
* and retrieval of like parameters.
*/
#define SETUP_SHOW_data_param(d, a) \
struct sensor_device_attribute *sda = to_sensor_dev_attr(a); \
struct asc7621_data *data = asc7621_update_device(d); \
struct asc7621_param *param = to_asc7621_param(sda)
#define SETUP_STORE_data_param(d, a) \
struct sensor_device_attribute *sda = to_sensor_dev_attr(a); \
struct i2c_client *client = to_i2c_client(d); \
struct asc7621_data *data = i2c_get_clientdata(client); \
struct asc7621_param *param = to_asc7621_param(sda)
/*
* u8 is just what it sounds like...an unsigned byte with no
* special formatting.
*/
static ssize_t show_u8(struct device *dev, struct device_attribute *attr,
char *buf)
{
SETUP_SHOW_data_param(dev, attr);
return sprintf(buf, "%u\n", data->reg[param->msb[0]]);
}
static ssize_t store_u8(struct device *dev, struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
reqval = SENSORS_LIMIT(reqval, 0, 255);
mutex_lock(&data->update_lock);
data->reg[param->msb[0]] = reqval;
write_byte(client, param->msb[0], reqval);
mutex_unlock(&data->update_lock);
return count;
}
/*
* Many of the config values occupy only a few bits of a register.
*/
static ssize_t show_bitmask(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
return sprintf(buf, "%u\n",
(data->reg[param->msb[0]] >> param->
shift[0]) & param->mask[0]);
}
static ssize_t store_bitmask(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
u8 currval;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
reqval = SENSORS_LIMIT(reqval, 0, param->mask[0]);
reqval = (reqval & param->mask[0]) << param->shift[0];
mutex_lock(&data->update_lock);
currval = read_byte(client, param->msb[0]);
reqval |= (currval & ~(param->mask[0] << param->shift[0]));
data->reg[param->msb[0]] = reqval;
write_byte(client, param->msb[0], reqval);
mutex_unlock(&data->update_lock);
return count;
}
/*
* 16 bit fan rpm values
* reported by the device as the number of 11.111us periods (90khz)
* between full fan rotations. Therefore...
* RPM = (90000 * 60) / register value
*/
static ssize_t show_fan16(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u16 regval;
mutex_lock(&data->update_lock);
regval = (data->reg[param->msb[0]] << 8) | data->reg[param->lsb[0]];
mutex_unlock(&data->update_lock);
return sprintf(buf, "%u\n",
(regval == 0 ? -1 : (regval) ==
0xffff ? 0 : 5400000 / regval));
}
static ssize_t store_fan16(struct device *dev,
struct device_attribute *attr, const char *buf,
size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
reqval =
(SENSORS_LIMIT((reqval) <= 0 ? 0 : 5400000 / (reqval), 0, 65534));
mutex_lock(&data->update_lock);
data->reg[param->msb[0]] = (reqval >> 8) & 0xff;
data->reg[param->lsb[0]] = reqval & 0xff;
write_byte(client, param->msb[0], data->reg[param->msb[0]]);
write_byte(client, param->lsb[0], data->reg[param->lsb[0]]);
mutex_unlock(&data->update_lock);
return count;
}
/*
* Voltages are scaled in the device so that the nominal voltage
* is 3/4ths of the 0-255 range (i.e. 192).
* If all voltages are 'normal' then all voltage registers will
* read 0xC0. This doesn't help us if we don't have a point of refernce.
* The data sheet however provides us with the full scale value for each
* which is stored in in_scaling. The sda->index parameter value provides
* the index into in_scaling.
*
* NOTE: The chip expects the first 2 inputs be 2.5 and 2.25 volts
* respectively. That doesn't mean that's what the motherboard provides. :)
*/
static int asc7621_in_scaling[] = {
3320, 3000, 4380, 6640, 16000
};
static ssize_t show_in10(struct device *dev, struct device_attribute *attr,
char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u16 regval;
u8 nr = sda->index;
mutex_lock(&data->update_lock);
regval = (data->reg[param->msb[0]] * asc7621_in_scaling[nr]) / 256;
/* The LSB value is a 2-bit scaling of the MSB's LSbit value.
* I.E. If the maximim voltage for this input is 6640 millivolts then
* a MSB register value of 0 = 0mv and 255 = 6640mv.
* A 1 step change therefore represents 25.9mv (6640 / 256).
* The extra 2-bits therefore represent increments of 6.48mv.
*/
regval += ((asc7621_in_scaling[nr] / 256) / 4) *
(data->reg[param->lsb[0]] >> 6);
mutex_unlock(&data->update_lock);
return sprintf(buf, "%u\n", regval);
}
/* 8 bit voltage values (the mins and maxs) */
static ssize_t show_in8(struct device *dev, struct device_attribute *attr,
char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 nr = sda->index;
return sprintf(buf, "%u\n",
((data->reg[param->msb[0]] *
asc7621_in_scaling[nr]) / 256));
}
static ssize_t store_in8(struct device *dev, struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
u8 nr = sda->index;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
reqval = SENSORS_LIMIT(reqval, 0, asc7621_in_scaling[nr]);
reqval = (reqval * 255 + 128) / asc7621_in_scaling[nr];
mutex_lock(&data->update_lock);
data->reg[param->msb[0]] = reqval;
write_byte(client, param->msb[0], reqval);
mutex_unlock(&data->update_lock);
return count;
}
static ssize_t show_temp8(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
return sprintf(buf, "%d\n", ((s8) data->reg[param->msb[0]]) * 1000);
}
static ssize_t store_temp8(struct device *dev,
struct device_attribute *attr, const char *buf,
size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
s8 temp;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
reqval = SENSORS_LIMIT(reqval, -127000, 127000);
temp = reqval / 1000;
mutex_lock(&data->update_lock);
data->reg[param->msb[0]] = temp;
write_byte(client, param->msb[0], temp);
mutex_unlock(&data->update_lock);
return count;
}
/*
* Temperatures that occupy 2 bytes always have the whole
* number of degrees in the MSB with some part of the LSB
* indicating fractional degrees.
*/
/* mmmmmmmm.llxxxxxx */
static ssize_t show_temp10(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 msb, lsb;
int temp;
mutex_lock(&data->update_lock);
msb = data->reg[param->msb[0]];
lsb = (data->reg[param->lsb[0]] >> 6) & 0x03;
temp = (((s8) msb) * 1000) + (lsb * 250);
mutex_unlock(&data->update_lock);
return sprintf(buf, "%d\n", temp);
}
/* mmmmmm.ll */
static ssize_t show_temp62(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 regval = data->reg[param->msb[0]];
int temp = ((s8) (regval & 0xfc) * 1000) + ((regval & 0x03) * 250);
return sprintf(buf, "%d\n", temp);
}
static ssize_t store_temp62(struct device *dev,
struct device_attribute *attr, const char *buf,
size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval, i, f;
s8 temp;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
reqval = SENSORS_LIMIT(reqval, -32000, 31750);
i = reqval / 1000;
f = reqval - (i * 1000);
temp = i << 2;
temp |= f / 250;
mutex_lock(&data->update_lock);
data->reg[param->msb[0]] = temp;
write_byte(client, param->msb[0], temp);
mutex_unlock(&data->update_lock);
return count;
}
/*
* The aSC7621 doesn't provide an "auto_point2". Instead, you
* specify the auto_point1 and a range. To keep with the sysfs
* hwmon specs, we synthesize the auto_point_2 from them.
*/
static u32 asc7621_range_map[] = {
2000, 2500, 3330, 4000, 5000, 6670, 8000, 10000,
13330, 16000, 20000, 26670, 32000, 40000, 53330, 80000,
};
static ssize_t show_ap2_temp(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
long auto_point1;
u8 regval;
int temp;
mutex_lock(&data->update_lock);
auto_point1 = ((s8) data->reg[param->msb[1]]) * 1000;
regval =
((data->reg[param->msb[0]] >> param->shift[0]) & param->mask[0]);
temp = auto_point1 + asc7621_range_map[SENSORS_LIMIT(regval, 0, 15)];
mutex_unlock(&data->update_lock);
return sprintf(buf, "%d\n", temp);
}
static ssize_t store_ap2_temp(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval, auto_point1;
int i;
u8 currval, newval = 0;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
mutex_lock(&data->update_lock);
auto_point1 = data->reg[param->msb[1]] * 1000;
reqval = SENSORS_LIMIT(reqval, auto_point1 + 2000, auto_point1 + 80000);
for (i = ARRAY_SIZE(asc7621_range_map) - 1; i >= 0; i--) {
if (reqval >= auto_point1 + asc7621_range_map[i]) {
newval = i;
break;
}
}
newval = (newval & param->mask[0]) << param->shift[0];
currval = read_byte(client, param->msb[0]);
newval |= (currval & ~(param->mask[0] << param->shift[0]));
data->reg[param->msb[0]] = newval;
write_byte(client, param->msb[0], newval);
mutex_unlock(&data->update_lock);
return count;
}
static ssize_t show_pwm_ac(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 config, altbit, regval;
u8 map[] = {
0x01, 0x02, 0x04, 0x1f, 0x00, 0x06, 0x07, 0x10,
0x08, 0x0f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f
};
mutex_lock(&data->update_lock);
config = (data->reg[param->msb[0]] >> param->shift[0]) & param->mask[0];
altbit = (data->reg[param->msb[1]] >> param->shift[1]) & param->mask[1];
regval = config | (altbit << 3);
mutex_unlock(&data->update_lock);
return sprintf(buf, "%u\n", map[SENSORS_LIMIT(regval, 0, 15)]);
}
static ssize_t store_pwm_ac(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
unsigned long reqval;
u8 currval, config, altbit, newval;
u16 map[] = {
0x04, 0x00, 0x01, 0xff, 0x02, 0xff, 0x05, 0x06,
0x08, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x0f,
0x07, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x03,
};
if (strict_strtoul(buf, 10, &reqval))
return -EINVAL;
if (reqval > 31)
return -EINVAL;
reqval = map[reqval];
if (reqval == 0xff)
return -EINVAL;
config = reqval & 0x07;
altbit = (reqval >> 3) & 0x01;
config = (config & param->mask[0]) << param->shift[0];
altbit = (altbit & param->mask[1]) << param->shift[1];
mutex_lock(&data->update_lock);
currval = read_byte(client, param->msb[0]);
newval = config | (currval & ~(param->mask[0] << param->shift[0]));
newval = altbit | (newval & ~(param->mask[1] << param->shift[1]));
data->reg[param->msb[0]] = newval;
write_byte(client, param->msb[0], newval);
mutex_unlock(&data->update_lock);
return count;
}
static ssize_t show_pwm_enable(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 config, altbit, minoff, val, newval;
mutex_lock(&data->update_lock);
config = (data->reg[param->msb[0]] >> param->shift[0]) & param->mask[0];
altbit = (data->reg[param->msb[1]] >> param->shift[1]) & param->mask[1];
minoff = (data->reg[param->msb[2]] >> param->shift[2]) & param->mask[2];
mutex_unlock(&data->update_lock);
val = config | (altbit << 3);
newval = 0;
if (val == 3 || val >= 10)
newval = 255;
else if (val == 4)
newval = 0;
else if (val == 7)
newval = 1;
else if (minoff == 1)
newval = 2;
else
newval = 3;
return sprintf(buf, "%u\n", newval);
}
static ssize_t store_pwm_enable(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
u8 currval, config, altbit, newval, minoff = 255;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
switch (reqval) {
case 0:
newval = 0x04;
break;
case 1:
newval = 0x07;
break;
case 2:
newval = 0x00;
minoff = 1;
break;
case 3:
newval = 0x00;
minoff = 0;
break;
case 255:
newval = 0x03;
break;
default:
return -EINVAL;
}
config = newval & 0x07;
altbit = (newval >> 3) & 0x01;
mutex_lock(&data->update_lock);
config = (config & param->mask[0]) << param->shift[0];
altbit = (altbit & param->mask[1]) << param->shift[1];
currval = read_byte(client, param->msb[0]);
newval = config | (currval & ~(param->mask[0] << param->shift[0]));
newval = altbit | (newval & ~(param->mask[1] << param->shift[1]));
data->reg[param->msb[0]] = newval;
write_byte(client, param->msb[0], newval);
if (minoff < 255) {
minoff = (minoff & param->mask[2]) << param->shift[2];
currval = read_byte(client, param->msb[2]);
newval =
minoff | (currval & ~(param->mask[2] << param->shift[2]));
data->reg[param->msb[2]] = newval;
write_byte(client, param->msb[2], newval);
}
mutex_unlock(&data->update_lock);
return count;
}
static u32 asc7621_pwm_freq_map[] = {
10, 15, 23, 30, 38, 47, 62, 94,
23000, 24000, 25000, 26000, 27000, 28000, 29000, 30000
};
static ssize_t show_pwm_freq(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 regval =
(data->reg[param->msb[0]] >> param->shift[0]) & param->mask[0];
regval = SENSORS_LIMIT(regval, 0, 15);
return sprintf(buf, "%u\n", asc7621_pwm_freq_map[regval]);
}
static ssize_t store_pwm_freq(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
unsigned long reqval;
u8 currval, newval = 255;
int i;
if (strict_strtoul(buf, 10, &reqval))
return -EINVAL;
for (i = 0; i < ARRAY_SIZE(asc7621_pwm_freq_map); i++) {
if (reqval == asc7621_pwm_freq_map[i]) {
newval = i;
break;
}
}
if (newval == 255)
return -EINVAL;
newval = (newval & param->mask[0]) << param->shift[0];
mutex_lock(&data->update_lock);
currval = read_byte(client, param->msb[0]);
newval |= (currval & ~(param->mask[0] << param->shift[0]));
data->reg[param->msb[0]] = newval;
write_byte(client, param->msb[0], newval);
mutex_unlock(&data->update_lock);
return count;
}
static u32 asc7621_pwm_auto_spinup_map[] = {
0, 100, 250, 400, 700, 1000, 2000, 4000
};
static ssize_t show_pwm_ast(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 regval =
(data->reg[param->msb[0]] >> param->shift[0]) & param->mask[0];
regval = SENSORS_LIMIT(regval, 0, 7);
return sprintf(buf, "%u\n", asc7621_pwm_auto_spinup_map[regval]);
}
static ssize_t store_pwm_ast(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
u8 currval, newval = 255;
u32 i;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
for (i = 0; i < ARRAY_SIZE(asc7621_pwm_auto_spinup_map); i++) {
if (reqval == asc7621_pwm_auto_spinup_map[i]) {
newval = i;
break;
}
}
if (newval == 255)
return -EINVAL;
newval = (newval & param->mask[0]) << param->shift[0];
mutex_lock(&data->update_lock);
currval = read_byte(client, param->msb[0]);
newval |= (currval & ~(param->mask[0] << param->shift[0]));
data->reg[param->msb[0]] = newval;
write_byte(client, param->msb[0], newval);
mutex_unlock(&data->update_lock);
return count;
}
static u32 asc7621_temp_smoothing_time_map[] = {
35000, 17600, 11800, 7000, 4400, 3000, 1600, 800
};
static ssize_t show_temp_st(struct device *dev,
struct device_attribute *attr, char *buf)
{
SETUP_SHOW_data_param(dev, attr);
u8 regval =
(data->reg[param->msb[0]] >> param->shift[0]) & param->mask[0];
regval = SENSORS_LIMIT(regval, 0, 7);
return sprintf(buf, "%u\n", asc7621_temp_smoothing_time_map[regval]);
}
static ssize_t store_temp_st(struct device *dev,
struct device_attribute *attr,
const char *buf, size_t count)
{
SETUP_STORE_data_param(dev, attr);
long reqval;
u8 currval, newval = 255;
u32 i;
if (strict_strtol(buf, 10, &reqval))
return -EINVAL;
for (i = 0; i < ARRAY_SIZE(asc7621_temp_smoothing_time_map); i++) {
if (reqval == asc7621_temp_smoothing_time_map[i]) {
newval = i;
break;
}
}
if (newval == 255)
return -EINVAL;
newval = (newval & param->mask[0]) << param->shift[0];
mutex_lock(&data->update_lock);
currval = read_byte(client, param->msb[0]);
newval |= (currval & ~(param->mask[0] << param->shift[0]));
data->reg[param->msb[0]] = newval;
write_byte(client, param->msb[0], newval);
mutex_unlock(&data->update_lock);
return count;
}
/*
* End of data handlers
*
* These defines do nothing more than make the table easier
* to read when wrapped at column 80.
*/
/*
* Creates a variable length array inititalizer.
* VAA(1,3,5,7) would produce {1,3,5,7}
*/
#define VAA(args...) {args}
#define PREAD(name, n, pri, rm, rl, m, s, r) \
{.sda = SENSOR_ATTR(name, S_IRUGO, show_##r, NULL, n), \
.priority = pri, .msb[0] = rm, .lsb[0] = rl, .mask[0] = m, \
.shift[0] = s,}
#define PWRITE(name, n, pri, rm, rl, m, s, r) \
{.sda = SENSOR_ATTR(name, S_IRUGO | S_IWUSR, show_##r, store_##r, n), \
.priority = pri, .msb[0] = rm, .lsb[0] = rl, .mask[0] = m, \
.shift[0] = s,}
/*
* PWRITEM assumes that the initializers for the .msb, .lsb, .mask and .shift
* were created using the VAA macro.
*/
#define PWRITEM(name, n, pri, rm, rl, m, s, r) \
{.sda = SENSOR_ATTR(name, S_IRUGO | S_IWUSR, show_##r, store_##r, n), \
.priority = pri, .msb = rm, .lsb = rl, .mask = m, .shift = s,}
static struct asc7621_param asc7621_params[] = {
PREAD(in0_input, 0, PRI_HIGH, 0x20, 0x13, 0, 0, in10),
PREAD(in1_input, 1, PRI_HIGH, 0x21, 0x18, 0, 0, in10),
PREAD(in2_input, 2, PRI_HIGH, 0x22, 0x11, 0, 0, in10),
PREAD(in3_input, 3, PRI_HIGH, 0x23, 0x12, 0, 0, in10),
PREAD(in4_input, 4, PRI_HIGH, 0x24, 0x14, 0, 0, in10),
PWRITE(in0_min, 0, PRI_LOW, 0x44, 0, 0, 0, in8),
PWRITE(in1_min, 1, PRI_LOW, 0x46, 0, 0, 0, in8),
PWRITE(in2_min, 2, PRI_LOW, 0x48, 0, 0, 0, in8),
PWRITE(in3_min, 3, PRI_LOW, 0x4a, 0, 0, 0, in8),
PWRITE(in4_min, 4, PRI_LOW, 0x4c, 0, 0, 0, in8),
PWRITE(in0_max, 0, PRI_LOW, 0x45, 0, 0, 0, in8),
PWRITE(in1_max, 1, PRI_LOW, 0x47, 0, 0, 0, in8),
PWRITE(in2_max, 2, PRI_LOW, 0x49, 0, 0, 0, in8),
PWRITE(in3_max, 3, PRI_LOW, 0x4b, 0, 0, 0, in8),
PWRITE(in4_max, 4, PRI_LOW, 0x4d, 0, 0, 0, in8),
PREAD(in0_alarm, 0, PRI_LOW, 0x41, 0, 0x01, 0, bitmask),
PREAD(in1_alarm, 1, PRI_LOW, 0x41, 0, 0x01, 1, bitmask),
PREAD(in2_alarm, 2, PRI_LOW, 0x41, 0, 0x01, 2, bitmask),
PREAD(in3_alarm, 3, PRI_LOW, 0x41, 0, 0x01, 3, bitmask),
PREAD(in4_alarm, 4, PRI_LOW, 0x42, 0, 0x01, 0, bitmask),
PREAD(fan1_input, 0, PRI_HIGH, 0x29, 0x28, 0, 0, fan16),
PREAD(fan2_input, 1, PRI_HIGH, 0x2b, 0x2a, 0, 0, fan16),
PREAD(fan3_input, 2, PRI_HIGH, 0x2d, 0x2c, 0, 0, fan16),
PREAD(fan4_input, 3, PRI_HIGH, 0x2f, 0x2e, 0, 0, fan16),
PWRITE(fan1_min, 0, PRI_LOW, 0x55, 0x54, 0, 0, fan16),
PWRITE(fan2_min, 1, PRI_LOW, 0x57, 0x56, 0, 0, fan16),
PWRITE(fan3_min, 2, PRI_LOW, 0x59, 0x58, 0, 0, fan16),
PWRITE(fan4_min, 3, PRI_LOW, 0x5b, 0x5a, 0, 0, fan16),
PREAD(fan1_alarm, 0, PRI_LOW, 0x42, 0, 0x01, 0, bitmask),
PREAD(fan2_alarm, 1, PRI_LOW, 0x42, 0, 0x01, 1, bitmask),
PREAD(fan3_alarm, 2, PRI_LOW, 0x42, 0, 0x01, 2, bitmask),
PREAD(fan4_alarm, 3, PRI_LOW, 0x42, 0, 0x01, 3, bitmask),
PREAD(temp1_input, 0, PRI_HIGH, 0x25, 0x10, 0, 0, temp10),
PREAD(temp2_input, 1, PRI_HIGH, 0x26, 0x15, 0, 0, temp10),
PREAD(temp3_input, 2, PRI_HIGH, 0x27, 0x16, 0, 0, temp10),
PREAD(temp4_input, 3, PRI_HIGH, 0x33, 0x17, 0, 0, temp10),
PREAD(temp5_input, 4, PRI_HIGH, 0xf7, 0xf6, 0, 0, temp10),
PREAD(temp6_input, 5, PRI_HIGH, 0xf9, 0xf8, 0, 0, temp10),
PREAD(temp7_input, 6, PRI_HIGH, 0xfb, 0xfa, 0, 0, temp10),
PREAD(temp8_input, 7, PRI_HIGH, 0xfd, 0xfc, 0, 0, temp10),
PWRITE(temp1_min, 0, PRI_LOW, 0x4e, 0, 0, 0, temp8),
PWRITE(temp2_min, 1, PRI_LOW, 0x50, 0, 0, 0, temp8),
PWRITE(temp3_min, 2, PRI_LOW, 0x52, 0, 0, 0, temp8),
PWRITE(temp4_min, 3, PRI_LOW, 0x34, 0, 0, 0, temp8),
PWRITE(temp1_max, 0, PRI_LOW, 0x4f, 0, 0, 0, temp8),
PWRITE(temp2_max, 1, PRI_LOW, 0x51, 0, 0, 0, temp8),
PWRITE(temp3_max, 2, PRI_LOW, 0x53, 0, 0, 0, temp8),
PWRITE(temp4_max, 3, PRI_LOW, 0x35, 0, 0, 0, temp8),
PREAD(temp1_alarm, 0, PRI_LOW, 0x41, 0, 0x01, 4, bitmask),
PREAD(temp2_alarm, 1, PRI_LOW, 0x41, 0, 0x01, 5, bitmask),
PREAD(temp3_alarm, 2, PRI_LOW, 0x41, 0, 0x01, 6, bitmask),
PREAD(temp4_alarm, 3, PRI_LOW, 0x43, 0, 0x01, 0, bitmask),
PWRITE(temp1_source, 0, PRI_LOW, 0x02, 0, 0x07, 4, bitmask),
PWRITE(temp2_source, 1, PRI_LOW, 0x02, 0, 0x07, 0, bitmask),
PWRITE(temp3_source, 2, PRI_LOW, 0x03, 0, 0x07, 4, bitmask),
PWRITE(temp4_source, 3, PRI_LOW, 0x03, 0, 0x07, 0, bitmask),
PWRITE(temp1_smoothing_enable, 0, PRI_LOW, 0x62, 0, 0x01, 3, bitmask),
PWRITE(temp2_smoothing_enable, 1, PRI_LOW, 0x63, 0, 0x01, 7, bitmask),
PWRITE(temp3_smoothing_enable, 2, PRI_LOW, 0x64, 0, 0x01, 3, bitmask),
PWRITE(temp4_smoothing_enable, 3, PRI_LOW, 0x3c, 0, 0x01, 3, bitmask),
PWRITE(temp1_smoothing_time, 0, PRI_LOW, 0x62, 0, 0x07, 0, temp_st),
PWRITE(temp2_smoothing_time, 1, PRI_LOW, 0x63, 0, 0x07, 4, temp_st),
PWRITE(temp3_smoothing_time, 2, PRI_LOW, 0x63, 0, 0x07, 0, temp_st),
PWRITE(temp4_smoothing_time, 3, PRI_LOW, 0x3c, 0, 0x07, 0, temp_st),
PWRITE(temp1_auto_point1_temp_hyst, 0, PRI_LOW, 0x6d, 0, 0x0f, 4,
bitmask),
PWRITE(temp2_auto_point1_temp_hyst, 1, PRI_LOW, 0x6d, 0, 0x0f, 0,
bitmask),
PWRITE(temp3_auto_point1_temp_hyst, 2, PRI_LOW, 0x6e, 0, 0x0f, 4,
bitmask),
PWRITE(temp4_auto_point1_temp_hyst, 3, PRI_LOW, 0x6e, 0, 0x0f, 0,
bitmask),
PREAD(temp1_auto_point2_temp_hyst, 0, PRI_LOW, 0x6d, 0, 0x0f, 4,
bitmask),
PREAD(temp2_auto_point2_temp_hyst, 1, PRI_LOW, 0x6d, 0, 0x0f, 0,
bitmask),
PREAD(temp3_auto_point2_temp_hyst, 2, PRI_LOW, 0x6e, 0, 0x0f, 4,
bitmask),
PREAD(temp4_auto_point2_temp_hyst, 3, PRI_LOW, 0x6e, 0, 0x0f, 0,
bitmask),
PWRITE(temp1_auto_point1_temp, 0, PRI_LOW, 0x67, 0, 0, 0, temp8),
PWRITE(temp2_auto_point1_temp, 1, PRI_LOW, 0x68, 0, 0, 0, temp8),
PWRITE(temp3_auto_point1_temp, 2, PRI_LOW, 0x69, 0, 0, 0, temp8),
PWRITE(temp4_auto_point1_temp, 3, PRI_LOW, 0x3b, 0, 0, 0, temp8),
PWRITEM(temp1_auto_point2_temp, 0, PRI_LOW, VAA(0x5f, 0x67), VAA(0),
VAA(0x0f), VAA(4), ap2_temp),
PWRITEM(temp2_auto_point2_temp, 1, PRI_LOW, VAA(0x60, 0x68), VAA(0),
VAA(0x0f), VAA(4), ap2_temp),
PWRITEM(temp3_auto_point2_temp, 2, PRI_LOW, VAA(0x61, 0x69), VAA(0),
VAA(0x0f), VAA(4), ap2_temp),
PWRITEM(temp4_auto_point2_temp, 3, PRI_LOW, VAA(0x3c, 0x3b), VAA(0),
VAA(0x0f), VAA(4), ap2_temp),
PWRITE(temp1_crit, 0, PRI_LOW, 0x6a, 0, 0, 0, temp8),
PWRITE(temp2_crit, 1, PRI_LOW, 0x6b, 0, 0, 0, temp8),
PWRITE(temp3_crit, 2, PRI_LOW, 0x6c, 0, 0, 0, temp8),
PWRITE(temp4_crit, 3, PRI_LOW, 0x3d, 0, 0, 0, temp8),
PWRITE(temp5_enable, 4, PRI_LOW, 0x0e, 0, 0x01, 0, bitmask),
PWRITE(temp6_enable, 5, PRI_LOW, 0x0e, 0, 0x01, 1, bitmask),
PWRITE(temp7_enable, 6, PRI_LOW, 0x0e, 0, 0x01, 2, bitmask),
PWRITE(temp8_enable, 7, PRI_LOW, 0x0e, 0, 0x01, 3, bitmask),
PWRITE(remote1_offset, 0, PRI_LOW, 0x1c, 0, 0, 0, temp62),
PWRITE(remote2_offset, 1, PRI_LOW, 0x1d, 0, 0, 0, temp62),
PWRITE(pwm1, 0, PRI_HIGH, 0x30, 0, 0, 0, u8),
PWRITE(pwm2, 1, PRI_HIGH, 0x31, 0, 0, 0, u8),
PWRITE(pwm3, 2, PRI_HIGH, 0x32, 0, 0, 0, u8),
PWRITE(pwm1_invert, 0, PRI_LOW, 0x5c, 0, 0x01, 4, bitmask),
PWRITE(pwm2_invert, 1, PRI_LOW, 0x5d, 0, 0x01, 4, bitmask),
PWRITE(pwm3_invert, 2, PRI_LOW, 0x5e, 0, 0x01, 4, bitmask),
PWRITEM(pwm1_enable, 0, PRI_LOW, VAA(0x5c, 0x5c, 0x62), VAA(0, 0, 0),
VAA(0x07, 0x01, 0x01), VAA(5, 3, 5), pwm_enable),
PWRITEM(pwm2_enable, 1, PRI_LOW, VAA(0x5d, 0x5d, 0x62), VAA(0, 0, 0),
VAA(0x07, 0x01, 0x01), VAA(5, 3, 6), pwm_enable),
PWRITEM(pwm3_enable, 2, PRI_LOW, VAA(0x5e, 0x5e, 0x62), VAA(0, 0, 0),
VAA(0x07, 0x01, 0x01), VAA(5, 3, 7), pwm_enable),
PWRITEM(pwm1_auto_channels, 0, PRI_LOW, VAA(0x5c, 0x5c), VAA(0, 0),
VAA(0x07, 0x01), VAA(5, 3), pwm_ac),
PWRITEM(pwm2_auto_channels, 1, PRI_LOW, VAA(0x5d, 0x5d), VAA(0, 0),
VAA(0x07, 0x01), VAA(5, 3), pwm_ac),
PWRITEM(pwm3_auto_channels, 2, PRI_LOW, VAA(0x5e, 0x5e), VAA(0, 0),
VAA(0x07, 0x01), VAA(5, 3), pwm_ac),
PWRITE(pwm1_auto_point1_pwm, 0, PRI_LOW, 0x64, 0, 0, 0, u8),
PWRITE(pwm2_auto_point1_pwm, 1, PRI_LOW, 0x65, 0, 0, 0, u8),
PWRITE(pwm3_auto_point1_pwm, 2, PRI_LOW, 0x66, 0, 0, 0, u8),
PWRITE(pwm1_auto_point2_pwm, 0, PRI_LOW, 0x38, 0, 0, 0, u8),
PWRITE(pwm2_auto_point2_pwm, 1, PRI_LOW, 0x39, 0, 0, 0, u8),
PWRITE(pwm3_auto_point2_pwm, 2, PRI_LOW, 0x3a, 0, 0, 0, u8),
PWRITE(pwm1_freq, 0, PRI_LOW, 0x5f, 0, 0x0f, 0, pwm_freq),
PWRITE(pwm2_freq, 1, PRI_LOW, 0x60, 0, 0x0f, 0, pwm_freq),
PWRITE(pwm3_freq, 2, PRI_LOW, 0x61, 0, 0x0f, 0, pwm_freq),
PREAD(pwm1_auto_zone_assigned, 0, PRI_LOW, 0, 0, 0x03, 2, bitmask),
PREAD(pwm2_auto_zone_assigned, 1, PRI_LOW, 0, 0, 0x03, 4, bitmask),
PREAD(pwm3_auto_zone_assigned, 2, PRI_LOW, 0, 0, 0x03, 6, bitmask),
PWRITE(pwm1_auto_spinup_time, 0, PRI_LOW, 0x5c, 0, 0x07, 0, pwm_ast),
PWRITE(pwm2_auto_spinup_time, 1, PRI_LOW, 0x5d, 0, 0x07, 0, pwm_ast),
PWRITE(pwm3_auto_spinup_time, 2, PRI_LOW, 0x5e, 0, 0x07, 0, pwm_ast),
PWRITE(peci_enable, 0, PRI_LOW, 0x40, 0, 0x01, 4, bitmask),
PWRITE(peci_avg, 0, PRI_LOW, 0x36, 0, 0x07, 0, bitmask),
PWRITE(peci_domain, 0, PRI_LOW, 0x36, 0, 0x01, 3, bitmask),
PWRITE(peci_legacy, 0, PRI_LOW, 0x36, 0, 0x01, 4, bitmask),
PWRITE(peci_diode, 0, PRI_LOW, 0x0e, 0, 0x07, 4, bitmask),
PWRITE(peci_4domain, 0, PRI_LOW, 0x0e, 0, 0x01, 4, bitmask),
};
static struct asc7621_data *asc7621_update_device(struct device *dev)
{
struct i2c_client *client = to_i2c_client(dev);
struct asc7621_data *data = i2c_get_clientdata(client);
int i;
/*
* The asc7621 chips guarantee consistent reads of multi-byte values
* regardless of the order of the reads. No special logic is needed
* so we can just read the registers in whatever order they appear
* in the asc7621_params array.
*/
mutex_lock(&data->update_lock);
/* Read all the high priority registers */
if (!data->valid ||
time_after(jiffies, data->last_high_reading + INTERVAL_HIGH)) {
for (i = 0; i < ARRAY_SIZE(asc7621_register_priorities); i++) {
if (asc7621_register_priorities[i] == PRI_HIGH) {
data->reg[i] =
i2c_smbus_read_byte_data(client, i) & 0xff;
}
}
data->last_high_reading = jiffies;
}; /* last_reading */
/* Read all the low priority registers. */
if (!data->valid ||
time_after(jiffies, data->last_low_reading + INTERVAL_LOW)) {
for (i = 0; i < ARRAY_SIZE(asc7621_params); i++) {
if (asc7621_register_priorities[i] == PRI_LOW) {
data->reg[i] =
i2c_smbus_read_byte_data(client, i) & 0xff;
}
}
data->last_low_reading = jiffies;
}; /* last_reading */
data->valid = 1;
mutex_unlock(&data->update_lock);
return data;
}
/*
* Standard detection and initialization below
*
* Helper function that checks if an address is valid
* for a particular chip.
*/
static inline int valid_address_for_chip(int chip_type, int address)
{
int i;
for (i = 0; asc7621_chips[chip_type].addresses[i] != I2C_CLIENT_END;
i++) {
if (asc7621_chips[chip_type].addresses[i] == address)
return 1;
}
return 0;
}
static void asc7621_init_client(struct i2c_client *client)
{
int value;
/* Warn if part was not "READY" */
value = read_byte(client, 0x40);
if (value & 0x02) {
dev_err(&client->dev,
"Client (%d,0x%02x) config is locked.\n",
i2c_adapter_id(client->adapter), client->addr);
};
if (!(value & 0x04)) {
dev_err(&client->dev, "Client (%d,0x%02x) is not ready.\n",
i2c_adapter_id(client->adapter), client->addr);
};
/*
* Start monitoring
*
* Try to clear LOCK, Set START, save everything else
*/
value = (value & ~0x02) | 0x01;
write_byte(client, 0x40, value & 0xff);
}
static int
asc7621_probe(struct i2c_client *client, const struct i2c_device_id *id)
{
struct asc7621_data *data;
int i, err;
if (!i2c_check_functionality(client->adapter, I2C_FUNC_SMBUS_BYTE_DATA))
return -EIO;
data = kzalloc(sizeof(struct asc7621_data), GFP_KERNEL);
if (data == NULL)
return -ENOMEM;
i2c_set_clientdata(client, data);
data->valid = 0;
mutex_init(&data->update_lock);
/* Initialize the asc7621 chip */
asc7621_init_client(client);
/* Create the sysfs entries */
for (i = 0; i < ARRAY_SIZE(asc7621_params); i++) {
err =
device_create_file(&client->dev,
&(asc7621_params[i].sda.dev_attr));
if (err)
goto exit_remove;
}
data->class_dev = hwmon_device_register(&client->dev);
if (IS_ERR(data->class_dev)) {
err = PTR_ERR(data->class_dev);
goto exit_remove;
}
return 0;
exit_remove:
for (i = 0; i < ARRAY_SIZE(asc7621_params); i++) {
device_remove_file(&client->dev,
&(asc7621_params[i].sda.dev_attr));
}
i2c_set_clientdata(client, NULL);
kfree(data);
return err;
}
static int asc7621_detect(struct i2c_client *client,
struct i2c_board_info *info)
{
struct i2c_adapter *adapter = client->adapter;
int company, verstep, chip_index;
struct device *dev;
dev = &client->dev;
if (!i2c_check_functionality(adapter, I2C_FUNC_SMBUS_BYTE_DATA))
return -ENODEV;
for (chip_index = FIRST_CHIP; chip_index <= LAST_CHIP; chip_index++) {
if (!valid_address_for_chip(chip_index, client->addr))
continue;
company = read_byte(client,
asc7621_chips[chip_index].company_reg);
verstep = read_byte(client,
asc7621_chips[chip_index].verstep_reg);
if (company == asc7621_chips[chip_index].company_id &&
verstep == asc7621_chips[chip_index].verstep_id) {
strlcpy(client->name, asc7621_chips[chip_index].name,
I2C_NAME_SIZE);
strlcpy(info->type, asc7621_chips[chip_index].name,
I2C_NAME_SIZE);
dev_info(&adapter->dev, "Matched %s\n",
asc7621_chips[chip_index].name);
return 0;
}
}
return -ENODEV;
}
static int asc7621_remove(struct i2c_client *client)
{
struct asc7621_data *data = i2c_get_clientdata(client);
int i;
hwmon_device_unregister(data->class_dev);
for (i = 0; i < ARRAY_SIZE(asc7621_params); i++) {
device_remove_file(&client->dev,
&(asc7621_params[i].sda.dev_attr));
}
i2c_set_clientdata(client, NULL);
kfree(data);
return 0;
}
static const struct i2c_device_id asc7621_id[] = {
{"asc7621", asc7621},
{"asc7621a", asc7621a},
{},
};
MODULE_DEVICE_TABLE(i2c, asc7621_id);
static struct i2c_driver asc7621_driver = {
.class = I2C_CLASS_HWMON,
.driver = {
.name = "asc7621",
},
.probe = asc7621_probe,
.remove = asc7621_remove,
.id_table = asc7621_id,
.detect = asc7621_detect,
.address_list = normal_i2c,
};
static int __init sm_asc7621_init(void)
{
int i, j;
/*
* Collect all the registers needed into a single array.
* This way, if a register isn't actually used for anything,
* we don't retrieve it.
*/
for (i = 0; i < ARRAY_SIZE(asc7621_params); i++) {
for (j = 0; j < ARRAY_SIZE(asc7621_params[i].msb); j++)
asc7621_register_priorities[asc7621_params[i].msb[j]] =
asc7621_params[i].priority;
for (j = 0; j < ARRAY_SIZE(asc7621_params[i].lsb); j++)
asc7621_register_priorities[asc7621_params[i].lsb[j]] =
asc7621_params[i].priority;
}
return i2c_add_driver(&asc7621_driver);
}
static void __exit sm_asc7621_exit(void)
{
i2c_del_driver(&asc7621_driver);
}
MODULE_LICENSE("GPL");
MODULE_AUTHOR("George Joseph");
MODULE_DESCRIPTION("Andigilog aSC7621 and aSC7621a driver");
module_init(sm_asc7621_init);
module_exit(sm_asc7621_exit);
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