nut/drivers/asem.c

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2015-04-30 13:53:36 +00:00
/* asem.c - driver for ASEM PB 1300 hardware, accessible through i2c.
Copyright (C) 2014 Giuseppe Corbelli <giuseppe.corbelli@copanitalia.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
ASEM SPA contributed with support and documentation.
Copan Italia SPA funded the development.
There are 2 versions of the charger. Older one is based on Max1667,
newer one is a custom solution. Both are on address 0x09.
To be compatible with both versions just read bit 15 of address 0x13
to have online/on battery status.
Battery monitor is a BQ2060 at address 0x0B.
Beware that the SystemIO memory used by the i2c controller is reserved by ACPI.
On Linux, as of 3.5.x kernel only a native driver (i2c_i801) is available,
so you need to boot with acpi_enforce_resources=lax option.
*/
/* Depends on i2c-dev.h, Linux only */
#include <stdio.h>
#include <errno.h>
#include <unistd.h>
#include <linux/i2c-dev.h>
#include "main.h"
#ifndef __STR__
# define __STR__(x) #x
#endif
#ifndef __XSTR__
# define __XSTR__(x) __STR__(x)
#endif
#define DRIVER_NAME "ASEM"
#define DRIVER_VERSION "0.10"
/* Valid on ASEM PB1300 UPS */
#define BQ2060_ADDRESS 0x0B
#define CHARGER_ADDRESS 0x09
#define CMD_DEVICENAME 0x21
#define LOW_BATTERY_THRESHOLD 25
#define HIGH_BATTERY_THRESHOLD 75
#define ACCESS_DEVICE(fd, address) \
if (ioctl(fd, I2C_SLAVE, address) < 0) { \
fatal_with_errno(EXIT_FAILURE, "Failed to acquire bus access and/or talk to slave 0x%02X", address); \
}
static unsigned long lb_threshold = LOW_BATTERY_THRESHOLD;
static unsigned long hb_threshold = HIGH_BATTERY_THRESHOLD;
static char *valid_devicename_data[] = {
"ASEM SPA",
NULL
};
upsdrv_info_t upsdrv_info = {
DRIVER_NAME,
DRIVER_VERSION,
"Giuseppe Corbelli <giuseppe.corbelli@copanitalia.com>",
DRV_EXPERIMENTAL,
{NULL}
};
void upsdrv_initinfo(void)
{
__s32 i2c_status;
__u8 buffer[10];
unsigned short year, month, day;
ACCESS_DEVICE(upsfd, BQ2060_ADDRESS);
/* Set capacity mode in mA(h) */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x03);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not read BatteryMode word data");
}
/* Clear 15th bit */
i2c_status = i2c_smbus_write_word_data(upsfd, 0x03, i2c_status & ~0x8000);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not set BatteryMode word data");
}
/* Device name */
memset(buffer, 0, 10);
i2c_status = i2c_smbus_read_block_data(upsfd, 0x21, buffer);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not read DeviceName block data");
}
upsdebugx(1, "UPS model %s", (char *) buffer);
dstate_setinfo("ups.model", "%s", (char *) buffer);
/* Manufacturing date */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x1B);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not read ManufactureDate word data");
}
/* (Year - 1980) * 512 */
year = (i2c_status >> 9) & 0x000000FF;
/* Month * 32 */
month = (i2c_status >> 4) & 0x0000001F;
day = i2c_status & 0x0000001F;
upsdebugx(1, "UPS manufacturing date %d-%02d-%02d (%d)", year + 1980, month, day, i2c_status);
dstate_setinfo("ups.mfr.date", "%d-%02d-%02d", year + 1980, month, day);
/* Device chemistry */
memset(buffer, 0, 10);
i2c_status = i2c_smbus_read_block_data(upsfd, 0x22, buffer);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not read DeviceChemistry block data");
}
upsdebugx(1, "Battery chemistry %s", (char *) buffer);
dstate_setinfo("battery.type", "%s", (char *) buffer);
/* Serial number */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x1C);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not read SerialNumber block data");
}
upsdebugx(1, "Serial Number %d", i2c_status);
dstate_setinfo("ups.serial", "%d", i2c_status);
}
void upsdrv_updateinfo(void)
{
static char online;
static char discharging;
static char fully_charged;
static unsigned short charge_percentage;
static unsigned short voltage;
static unsigned short capacity;
static signed short current;
static __s32 i2c_status;
static __s32 temperature;
static __s32 runtime_to_empty;
ACCESS_DEVICE(upsfd, CHARGER_ADDRESS);
/* Charger only supplies online/offline status */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x13);
if (i2c_status == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read charger status word at address 0x13");
return;
}
online = (i2c_status & 0x8000) != 0;
upsdebugx(3, "Charger status 0x%02X, online %d", i2c_status, online);
ACCESS_DEVICE(upsfd, BQ2060_ADDRESS);
i2c_status = i2c_smbus_read_word_data(upsfd, 0x16);
if (i2c_status == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read bq2060 status word at address 0x16");
return;
}
upsdebugx(3, "bq2060 status 0x04%X", i2c_status);
/* Busy, leave data as stale, try next time */
if (i2c_status & 0x0001) {
dstate_datastale();
upslogx(LOG_NOTICE, "bq2060 is busy");
return;
}
/* Error, leave data as stale, try next time */
if (i2c_status & 0x000F) {
dstate_datastale();
upslogx(LOG_WARNING, "bq2060 returned error code 0x%02X", i2c_status & 0x000F);
return;
}
discharging = (i2c_status & 0x0040);
fully_charged = (i2c_status & 0x0020);
/* Charge percentage */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x0D);
if (i2c_status == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read charge percentage from bq2060 at address 0x0D");
return;
}
charge_percentage = i2c_status & 0xFFFF;
upsdebugx(3, "Charge percentage %03d", charge_percentage);
/* Battery voltage in mV */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x09);
if (i2c_status == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read voltage from bq2060 at address 0x09");
return;
}
voltage = i2c_status & 0x0000FFFF;
upsdebugx(3, "Battery voltage %d mV", voltage);
/* Temperature in °K */
temperature = i2c_smbus_read_word_data(upsfd, 0x08);
if (temperature == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read temperature from bq2060 at address 0x08");
return;
}
upsdebugx(3, "Temperature %4.1f K", temperature / 10.0);
/* Current load in mA, positive for charge, negative for discharge */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x0A);
if (i2c_status == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read current from bq2060 at address 0x0A");
return;
}
current = i2c_status & 0x0000FFFF;
upsdebugx(3, "Current %d mA", current);
/* Current capacity */
i2c_status = i2c_smbus_read_word_data(upsfd, 0x0F);
if (i2c_status == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read RemainingCapacity word data");
return;
}
capacity = i2c_status & 0x0000FFFF;
upsdebugx(3, "Current capacity %d mAh", capacity);
/* Expected runtime capacity, averaged by gauge */
runtime_to_empty = i2c_smbus_read_word_data(upsfd, 0x12);
if (runtime_to_empty == -1) {
dstate_datastale();
upslogx(LOG_ERR, "Could not read AverageTimeToEmpty word data");
return;
}
upsdebugx(3, "Expected run-time to empty %d m", runtime_to_empty);
status_init();
status_set(online ? "OL" : "OB");
if (!discharging & !fully_charged)
status_set("CHRG");
else if (discharging && current < 0)
status_set("DISCHRG");
if (charge_percentage >= hb_threshold)
status_set("HB");
else if (charge_percentage <= lb_threshold)
status_set("LB");
/* In V */
dstate_setinfo("battery.voltage", "%2.3f", voltage / 1000.0);
/* In mAh */
dstate_setinfo("battery.current", "%2.3f", current / 1000.0);
dstate_setinfo("battery.charge", "%d", charge_percentage);
/* In mAh */
dstate_setinfo("battery.capacity", "%2.3f", capacity / 1000.0);
/* In °C */
dstate_setinfo("ups.temperature", "%4.1f", (temperature / 10.0) - 273.15);
/* In seconds */
dstate_setinfo("battery.runtime", "%d", runtime_to_empty * 60);
status_commit();
dstate_dataok();
}
void upsdrv_shutdown(void)
{
/* tell the UPS to shut down, then return - DO NOT SLEEP HERE */
/* maybe try to detect the UPS here, but try a shutdown even if
it doesn't respond at first if possible */
/* replace with a proper shutdown function */
fatalx(EXIT_FAILURE, "shutdown not supported");
/* you may have to check the line status since the commands
for toggling power are frequently different for OL vs. OB */
/* OL: this must power cycle the load if possible */
/* OB: the load must remain off until the power returns */
}
void upsdrv_help(void)
{
/* Redundant */
printf("\nASEM options\n");
printf(" HIGH/low battery thresholds\n");
printf(" lb = " __XSTR__(LOW_BATTERY_THRESHOLD) " (battery is low under this level)\n");
printf(" hb = " __XSTR__(HIGH_BATTERY_THRESHOLD) " (battery is high above this level)\n");
}
/* list flags and values that you want to receive via -x */
void upsdrv_makevartable(void)
{
addvar(VAR_VALUE, "lb", "Low battery threshold, default " __XSTR__(LOW_BATTERY_THRESHOLD));
addvar(VAR_VALUE, "hb", "High battery threshold, default " __XSTR__(HIGH_BATTERY_THRESHOLD));
}
void upsdrv_initups(void)
{
__s32 i2c_status;
__u8 DeviceName_buffer[10];
unsigned int i;
unsigned long x;
char *DeviceName;
char *option;
upsfd = open(device_path, O_RDWR);
if (upsfd < 0) {
fatal_with_errno(EXIT_FAILURE, "Could not open device port '%s'", device_path);
}
ACCESS_DEVICE(upsfd, BQ2060_ADDRESS);
/* Get ManufacturerName */
memset(DeviceName_buffer, 0, 10);
i2c_status = i2c_smbus_read_block_data(upsfd, 0x20, DeviceName_buffer);
if (i2c_status == -1) {
fatal_with_errno(EXIT_FAILURE, "Could not read DeviceName block data");
}
i = 0;
while ( (DeviceName = valid_devicename_data[i++]) ) {
if (0 == memcmp(DeviceName, DeviceName_buffer, i2c_status))
break;
}
if (!DeviceName) {
fatal_with_errno(EXIT_FAILURE, "Device '%s' unknown", (char *) DeviceName_buffer);
}
upsdebugx(1, "Found device '%s' on port '%s'", (char *) DeviceName, device_path);
dstate_setinfo("ups.mfr", "%s", (char *) DeviceName);
option = getval("lb");
if (option) {
x = strtoul(option, NULL, 0);
if ((x == 0) && (errno != 0)) {
upslogx(LOG_WARNING, "Invalid value specified for low battery threshold: '%s'", option);
} else {
lb_threshold = x;
}
}
option = getval("hb");
if (option) {
x = strtoul(option, NULL, 0);
if ((x == 0) && (errno != 0)) {
upslogx(LOG_WARNING, "Invalid value specified for high battery threshold: '%s'", option);
} else if ((x < 1) || (x > 100)) {
upslogx(LOG_WARNING, "Invalid value specified for high battery threshold: '%s' (must be 1 < hb <= 100)", option);
} else {
hb_threshold = x;
}
}
/* Invalid values specified */
if (lb_threshold > hb_threshold) {
upslogx(LOG_WARNING, "lb > hb specified in options. Returning to defaults.");
lb_threshold = LOW_BATTERY_THRESHOLD;
hb_threshold = HIGH_BATTERY_THRESHOLD;
}
upslogx(LOG_NOTICE, "High battery threshold is %lu, low battery threshold is %lu", lb_threshold, hb_threshold);
}
void upsdrv_cleanup(void)
{
close(upsfd);
}